Mon Jan 8 03:21:31 UTC 2024 I: starting to build apbs/bullseye/armhf on jenkins on '2024-01-08 03:21' Mon Jan 8 03:21:32 UTC 2024 I: The jenkins build log is/was available at https://jenkins.debian.net/userContent/reproducible/debian/build_service/armhf_17/10471/console.log Mon Jan 8 03:21:32 UTC 2024 I: Downloading source for bullseye/apbs=3.0.0+dfsg1-3 --2024-01-08 03:21:32-- http://cdn-fastly.deb.debian.org/debian/pool/main/a/apbs/apbs_3.0.0%2bdfsg1-3.dsc Connecting to 78.137.99.97:3128... connected. Proxy request sent, awaiting response... 200 OK Length: 2292 (2.2K) [text/prs.lines.tag] Saving to: ‘apbs_3.0.0+dfsg1-3.dsc’ 0K .. 100% 356M=0s 2024-01-08 03:21:32 (356 MB/s) - ‘apbs_3.0.0+dfsg1-3.dsc’ saved [2292/2292] Mon Jan 8 03:21:32 UTC 2024 I: apbs_3.0.0+dfsg1-3.dsc -----BEGIN PGP SIGNED MESSAGE----- Hash: SHA256 Format: 3.0 (quilt) Source: apbs Binary: apbs, python3-apbslib, libapbs-dev, libapbs3, apbs-data Architecture: any all Version: 3.0.0+dfsg1-3 Maintainer: Debichem Team Uploaders: Michael Banck Homepage: http://www.poissonboltzmann.org/ Standards-Version: 4.5.0 Vcs-Browser: https://salsa.debian.org/debichem-team/apbs Vcs-Git: https://salsa.debian.org/debichem-team/apbs.git Testsuite: autopkgtest Testsuite-Triggers: python3 Build-Depends: cmake, debhelper-compat (= 13), dh-python, libmaloc-dev, mpi-default-dev, python3, python3-dev, python3-setuptools, swig, zlib1g-dev Package-List: apbs deb science optional arch=any apbs-data deb science optional arch=all libapbs-dev deb libdevel optional arch=any libapbs3 deb libs optional arch=any python3-apbslib deb python optional arch=any Checksums-Sha1: 976730bac6bbaa26cdef8d0d5be5c1bf3c63240e 90469528 apbs_3.0.0+dfsg1.orig.tar.xz 7fd00c61349ff3e8d4e912871d6b9066b2ef3c50 14280 apbs_3.0.0+dfsg1-3.debian.tar.xz Checksums-Sha256: bbb2b3f7c14773e6c3535a6af6f5ac40370f4fc62e1fb1c2fe7c39051a8cc5cd 90469528 apbs_3.0.0+dfsg1.orig.tar.xz c9573aab7b2d26f4925c82a597bf4658c33dab324a99f245c46247cb8f43ca37 14280 apbs_3.0.0+dfsg1-3.debian.tar.xz Files: 9f14961e11c5da2f3c5e4979ff29a34c 90469528 apbs_3.0.0+dfsg1.orig.tar.xz 6c5ce01351dda9673668ca8af404f631 14280 apbs_3.0.0+dfsg1-3.debian.tar.xz -----BEGIN PGP SIGNATURE----- iQIzBAEBCAAdFiEEI8mpPlhYGekSbQo2Vz7x5L1aAfoFAl8ZZG0ACgkQVz7x5L1a AfrqfBAAmumN7x/OQHeUwrF9MD6nv4nvS2qUzcJjsSUPBN7mqrQQFk7377zf05PX ZIlAweH1hnBC3j7Ofg5+onHZXQ5zOQuklKsry/sC9J25ACggDd3uxOXhX1B0K/9W 3o9M+688jVMFvkqNmnOFyzsL5hO5bVoDzuuq4KCUaCUUgol++ARWX1SoOcPlALie 10XN7Jx4+qYvqsslbT5XGHP0ZpPZnIgIWz3kAZtbhlK8LX1NnvUxd+brcQlnJHKH SujUv8TEJj8S3uq3BvHQmcJUNF5QaY/QpoQincN0dRJ/LHOSfSOs3HB2NoaSrwP3 +rL8i+AMY93lolZUTTiZERmgxzbsB0eTKJ/02hJgtECQU66tVYt2xX2BJyh6EqY4 /B5Mynyby4gHByghvNyXBuVE3LUE6iLo2lDJxdybWs/uVuT4v0PItXeq/YUFP/rM 66oQhWL0KW7SsyQRxocTzEovZ0mMPa2+xfSgzNsB9TD+9iYjWrxHVyLflrtOm4g6 Rtw9rvw8J1xYScI74Q1dGfnS2qme5DFU02/vSFeRElfU7SIleGQ0dDu3jNLggwF4 MQ8pb6DR5sffdottNjYKwAht5Xowhf/QZFmSIOX9OU1S+BITCM04fqSWk0+PubDN hhsKV1PqQZI+wKxa+xRCaUmqr0wSEvJZm+5roti04Qj84f+dB60= =sm1b -----END PGP SIGNATURE----- Mon Jan 8 03:21:32 UTC 2024 I: Checking whether the package is not for us Mon Jan 8 03:21:32 UTC 2024 I: Starting 1st build on remote node virt32b-armhf-rb.debian.net. Mon Jan 8 03:21:32 UTC 2024 I: Preparing to do remote build '1' on virt32b-armhf-rb.debian.net. Mon Jan 8 05:22:07 UTC 2024 I: Deleting $TMPDIR on virt32b-armhf-rb.debian.net. I: pbuilder: network access will be disabled during build I: Current time: Sun Jan 7 15:22:06 -12 2024 I: pbuilder-time-stamp: 1704684126 I: Building the build Environment I: extracting base tarball [/var/cache/pbuilder/bullseye-reproducible-base.tgz] I: copying local configuration W: --override-config is not set; not updating apt.conf Read the manpage for details. I: mounting /proc filesystem I: mounting /sys filesystem I: creating /{dev,run}/shm I: mounting /dev/pts filesystem I: redirecting /dev/ptmx to /dev/pts/ptmx I: policy-rc.d already exists I: Copying source file I: copying [apbs_3.0.0+dfsg1-3.dsc] I: copying [./apbs_3.0.0+dfsg1.orig.tar.xz] I: copying [./apbs_3.0.0+dfsg1-3.debian.tar.xz] I: Extracting source gpgv: unknown type of key resource 'trustedkeys.kbx' gpgv: keyblock resource '/tmp/dpkg-verify-sig.dKCoGfGS/trustedkeys.kbx': General error gpgv: Signature made Thu Jul 23 10:20:29 2020 gpgv: using RSA key 23C9A93E585819E9126D0A36573EF1E4BD5A01FA gpgv: Can't check signature: No public key dpkg-source: warning: failed to verify signature on ./apbs_3.0.0+dfsg1-3.dsc dpkg-source: info: extracting apbs in apbs-3.0.0+dfsg1 dpkg-source: info: unpacking apbs_3.0.0+dfsg1.orig.tar.xz dpkg-source: info: unpacking apbs_3.0.0+dfsg1-3.debian.tar.xz dpkg-source: info: using patch list from debian/patches/series dpkg-source: info: applying wrong-path-for-interpreter.patch dpkg-source: info: applying debian_testfiles.patch dpkg-source: info: applying debian_make.patch dpkg-source: info: applying fix_spelling_errors.patch dpkg-source: info: applying shared_library_soname.patch dpkg-source: info: applying python3.patch dpkg-source: info: applying link_libapbs_routines.patch I: using fakeroot in build. I: Installing the build-deps I: user script /srv/workspace/pbuilder/23160/tmp/hooks/D02_print_environment starting I: set BUILDDIR='/build/reproducible-path' BUILDUSERGECOS='first user,first room,first work-phone,first home-phone,first other' BUILDUSERNAME='pbuilder1' BUILD_ARCH='armhf' DEBIAN_FRONTEND='noninteractive' DEB_BUILD_OPTIONS='buildinfo=+all reproducible=+all,-fixfilepath parallel=3 ' DISTRIBUTION='bullseye' HOME='/root' HOST_ARCH='armhf' IFS=' ' INVOCATION_ID='186e0ed6d64e4fa597d988a3e6eaaa23' LANG='C' LANGUAGE='en_US:en' LC_ALL='C' MAIL='/var/mail/root' OPTIND='1' PATH='/usr/sbin:/usr/bin:/sbin:/bin:/usr/games' PBCURRENTCOMMANDLINEOPERATION='build' PBUILDER_OPERATION='build' PBUILDER_PKGDATADIR='/usr/share/pbuilder' PBUILDER_PKGLIBDIR='/usr/lib/pbuilder' PBUILDER_SYSCONFDIR='/etc' PPID='23160' PS1='# ' PS2='> ' PS4='+ ' PWD='/' SHELL='/bin/bash' SHLVL='2' SUDO_COMMAND='/usr/bin/timeout -k 18.1h 18h /usr/bin/ionice -c 3 /usr/bin/nice /usr/sbin/pbuilder --build --configfile /srv/reproducible-results/rbuild-debian/r-b-build.PxhV4VLr/pbuilderrc_JI5K --distribution bullseye --hookdir /etc/pbuilder/first-build-hooks --debbuildopts -b --basetgz /var/cache/pbuilder/bullseye-reproducible-base.tgz --buildresult /srv/reproducible-results/rbuild-debian/r-b-build.PxhV4VLr/b1 --logfile b1/build.log apbs_3.0.0+dfsg1-3.dsc' SUDO_GID='112' SUDO_UID='106' SUDO_USER='jenkins' TERM='unknown' TZ='/usr/share/zoneinfo/Etc/GMT+12' USER='root' _='/usr/bin/systemd-run' http_proxy='http://10.0.0.15:3142/' I: uname -a Linux virt32b 6.1.0-17-armmp-lpae #1 SMP Debian 6.1.69-1 (2023-12-30) armv7l GNU/Linux I: ls -l /bin total 3580 -rwxr-xr-x 1 root root 816764 Mar 27 2022 bash -rwxr-xr-x 3 root root 26052 Jul 20 2020 bunzip2 -rwxr-xr-x 3 root root 26052 Jul 20 2020 bzcat lrwxrwxrwx 1 root root 6 Jul 20 2020 bzcmp -> bzdiff -rwxr-xr-x 1 root root 2225 Jul 20 2020 bzdiff lrwxrwxrwx 1 root root 6 Jul 20 2020 bzegrep -> bzgrep -rwxr-xr-x 1 root root 4877 Sep 4 2019 bzexe lrwxrwxrwx 1 root root 6 Jul 20 2020 bzfgrep -> bzgrep -rwxr-xr-x 1 root root 3775 Jul 20 2020 bzgrep -rwxr-xr-x 3 root root 26052 Jul 20 2020 bzip2 -rwxr-xr-x 1 root root 9636 Jul 20 2020 bzip2recover lrwxrwxrwx 1 root root 6 Jul 20 2020 bzless -> bzmore -rwxr-xr-x 1 root root 1297 Jul 20 2020 bzmore -rwxr-xr-x 1 root root 26668 Sep 22 2020 cat -rwxr-xr-x 1 root root 43104 Sep 22 2020 chgrp -rwxr-xr-x 1 root root 38984 Sep 22 2020 chmod -rwxr-xr-x 1 root root 43112 Sep 22 2020 chown -rwxr-xr-x 1 root root 92616 Sep 22 2020 cp -rwxr-xr-x 1 root root 75524 Dec 10 2020 dash -rwxr-xr-x 1 root root 75880 Sep 22 2020 date -rwxr-xr-x 1 root root 55436 Sep 22 2020 dd -rwxr-xr-x 1 root root 59912 Sep 22 2020 df -rwxr-xr-x 1 root root 96764 Sep 22 2020 dir -rwxr-xr-x 1 root root 55012 Jan 20 2022 dmesg lrwxrwxrwx 1 root root 8 Nov 7 2019 dnsdomainname -> hostname lrwxrwxrwx 1 root root 8 Nov 7 2019 domainname -> hostname -rwxr-xr-x 1 root root 22508 Sep 22 2020 echo -rwxr-xr-x 1 root root 28 Jan 25 2023 egrep -rwxr-xr-x 1 root root 22496 Sep 22 2020 false -rwxr-xr-x 1 root root 28 Jan 25 2023 fgrep -rwxr-xr-x 1 root root 47492 Jan 20 2022 findmnt -rwsr-xr-x 1 root root 26076 Feb 26 2021 fusermount -rwxr-xr-x 1 root root 124508 Jan 25 2023 grep -rwxr-xr-x 2 root root 2346 Apr 10 2022 gunzip -rwxr-xr-x 1 root root 6447 Apr 10 2022 gzexe -rwxr-xr-x 1 root root 64212 Apr 10 2022 gzip -rwxr-xr-x 1 root root 13784 Nov 7 2019 hostname -rwxr-xr-x 1 root root 43180 Sep 22 2020 ln -rwxr-xr-x 1 root root 35068 Feb 7 2020 login -rwxr-xr-x 1 root root 96764 Sep 22 2020 ls -rwxr-xr-x 1 root root 99940 Jan 20 2022 lsblk -rwxr-xr-x 1 root root 51408 Sep 22 2020 mkdir -rwxr-xr-x 1 root root 43184 Sep 22 2020 mknod -rwxr-xr-x 1 root root 30780 Sep 22 2020 mktemp -rwxr-xr-x 1 root root 34408 Jan 20 2022 more -rwsr-xr-x 1 root root 34400 Jan 20 2022 mount -rwxr-xr-x 1 root root 9824 Jan 20 2022 mountpoint -rwxr-xr-x 1 root root 88524 Sep 22 2020 mv lrwxrwxrwx 1 root root 8 Nov 7 2019 nisdomainname -> hostname lrwxrwxrwx 1 root root 14 Dec 16 2021 pidof -> /sbin/killall5 -rwxr-xr-x 1 root root 26652 Sep 22 2020 pwd lrwxrwxrwx 1 root root 4 Mar 27 2022 rbash -> bash -rwxr-xr-x 1 root root 30740 Sep 22 2020 readlink -rwxr-xr-x 1 root root 43104 Sep 22 2020 rm -rwxr-xr-x 1 root root 30732 Sep 22 2020 rmdir -rwxr-xr-x 1 root root 14144 Sep 27 2020 run-parts -rwxr-xr-x 1 root root 76012 Dec 22 2018 sed lrwxrwxrwx 1 root root 4 Jan 7 09:26 sh -> dash -rwxr-xr-x 1 root root 22532 Sep 22 2020 sleep -rwxr-xr-x 1 root root 55360 Sep 22 2020 stty -rwsr-xr-x 1 root root 46704 Jan 20 2022 su -rwxr-xr-x 1 root root 22532 Sep 22 2020 sync -rwxr-xr-x 1 root root 340872 Feb 17 2021 tar -rwxr-xr-x 1 root root 9808 Sep 27 2020 tempfile -rwxr-xr-x 1 root root 67696 Sep 22 2020 touch -rwxr-xr-x 1 root root 22496 Sep 22 2020 true -rwxr-xr-x 1 root root 9636 Feb 26 2021 ulockmgr_server -rwsr-xr-x 1 root root 22108 Jan 20 2022 umount -rwxr-xr-x 1 root root 22520 Sep 22 2020 uname -rwxr-xr-x 2 root root 2346 Apr 10 2022 uncompress -rwxr-xr-x 1 root root 96764 Sep 22 2020 vdir -rwxr-xr-x 1 root root 38512 Jan 20 2022 wdctl lrwxrwxrwx 1 root root 8 Nov 7 2019 ypdomainname -> hostname -rwxr-xr-x 1 root root 1984 Apr 10 2022 zcat -rwxr-xr-x 1 root root 1678 Apr 10 2022 zcmp -rwxr-xr-x 1 root root 5898 Apr 10 2022 zdiff -rwxr-xr-x 1 root root 29 Apr 10 2022 zegrep -rwxr-xr-x 1 root root 29 Apr 10 2022 zfgrep -rwxr-xr-x 1 root root 2081 Apr 10 2022 zforce -rwxr-xr-x 1 root root 8049 Apr 10 2022 zgrep -rwxr-xr-x 1 root root 2206 Apr 10 2022 zless -rwxr-xr-x 1 root root 1842 Apr 10 2022 zmore -rwxr-xr-x 1 root root 4577 Apr 10 2022 znew I: user script /srv/workspace/pbuilder/23160/tmp/hooks/D02_print_environment finished -> Attempting to satisfy build-dependencies -> Creating pbuilder-satisfydepends-dummy package Package: pbuilder-satisfydepends-dummy Version: 0.invalid.0 Architecture: armhf Maintainer: Debian Pbuilder Team Description: Dummy package to satisfy dependencies with aptitude - created by pbuilder This package was created automatically by pbuilder to satisfy the build-dependencies of the package being currently built. Depends: cmake, debhelper-compat (= 13), dh-python, libmaloc-dev, mpi-default-dev, python3, python3-dev, python3-setuptools, swig, zlib1g-dev dpkg-deb: building package 'pbuilder-satisfydepends-dummy' in '/tmp/satisfydepends-aptitude/pbuilder-satisfydepends-dummy.deb'. Selecting previously unselected package pbuilder-satisfydepends-dummy. (Reading database ... 17486 files and directories currently installed.) Preparing to unpack .../pbuilder-satisfydepends-dummy.deb ... Unpacking pbuilder-satisfydepends-dummy (0.invalid.0) ... dpkg: pbuilder-satisfydepends-dummy: dependency problems, but configuring anyway as you requested: pbuilder-satisfydepends-dummy depends on cmake; however: Package cmake is not installed. pbuilder-satisfydepends-dummy depends on debhelper-compat (= 13); however: Package debhelper-compat is not installed. pbuilder-satisfydepends-dummy depends on dh-python; however: Package dh-python is not installed. pbuilder-satisfydepends-dummy depends on libmaloc-dev; however: Package libmaloc-dev is not installed. pbuilder-satisfydepends-dummy depends on mpi-default-dev; however: Package mpi-default-dev is not installed. pbuilder-satisfydepends-dummy depends on python3; however: Package python3 is not installed. pbuilder-satisfydepends-dummy depends on python3-dev; however: Package python3-dev is not installed. pbuilder-satisfydepends-dummy depends on python3-setuptools; however: Package python3-setuptools is not installed. pbuilder-satisfydepends-dummy depends on swig; however: Package swig is not installed. pbuilder-satisfydepends-dummy depends on zlib1g-dev; however: Package zlib1g-dev is not installed. Setting up pbuilder-satisfydepends-dummy (0.invalid.0) ... Reading package lists... Building dependency tree... Reading state information... Initializing package states... Writing extended state information... Building tag database... pbuilder-satisfydepends-dummy is already installed at the requested version (0.invalid.0) pbuilder-satisfydepends-dummy is already installed at the requested version (0.invalid.0) The following NEW packages will be installed: autoconf{a} automake{a} autopoint{a} autotools-dev{a} bsdextrautils{a} cmake{a} cmake-data{a} debhelper{a} dh-autoreconf{a} dh-python{a} dh-strip-nondeterminism{a} dwz{a} file{a} gettext{a} gettext-base{a} gfortran-10{a} groff-base{a} ibverbs-providers{a} intltool-debian{a} libarchive-zip-perl{a} libarchive13{a} libbrotli1{a} libbsd0{a} libcbor0{a} libcurl4{a} libdebhelper-perl{a} libedit2{a} libelf1{a} libevent-2.1-7{a} libevent-core-2.1-7{a} libevent-dev{a} libevent-extra-2.1-7{a} libevent-openssl-2.1-7{a} libevent-pthreads-2.1-7{a} libexpat1{a} libexpat1-dev{a} libfabric1{a} libfido2-1{a} libfile-stripnondeterminism-perl{a} libgfortran-10-dev{a} libgfortran5{a} libhwloc-dev{a} libhwloc-plugins{a} libhwloc15{a} libibverbs-dev{a} libibverbs1{a} libicu67{a} libjs-jquery{a} libjs-jquery-ui{a} libjs-sphinxdoc{a} libjs-underscore{a} libjsoncpp24{a} libldap-2.4-2{a} libltdl-dev{a} libltdl7{a} libmagic-mgc{a} libmagic1{a} libmaloc-dev{a} libmaloc1{a} libmd0{a} libmpdec3{a} libncurses6{a} libnghttp2-14{a} libnl-3-200{a} libnl-3-dev{a} libnl-route-3-200{a} libnl-route-3-dev{a} libnuma-dev{a} libnuma1{a} libopenmpi-dev{a} libopenmpi3{a} libpciaccess0{a} libpipeline1{a} libpmix-dev{a} libpmix2{a} libprocps8{a} libpsl5{a} libpython3-dev{a} libpython3-stdlib{a} libpython3.9{a} libpython3.9-dev{a} libpython3.9-minimal{a} libpython3.9-stdlib{a} librdmacm1{a} libreadline8{a} librhash0{a} librtmp1{a} libsasl2-2{a} libsasl2-modules-db{a} libsigsegv2{a} libssh2-1{a} libsub-override-perl{a} libtool{a} libuchardet0{a} libuv1{a} libx11-6{a} libx11-data{a} libxau6{a} libxcb1{a} libxdmcp6{a} libxext6{a} libxml2{a} libxnvctrl0{a} m4{a} man-db{a} media-types{a} mpi-default-dev{a} ocl-icd-libopencl1{a} openmpi-bin{a} openmpi-common{a} openssh-client{a} po-debconf{a} procps{a} python3{a} python3-dev{a} python3-distutils{a} python3-lib2to3{a} python3-minimal{a} python3-pkg-resources{a} python3-setuptools{a} python3.9{a} python3.9-dev{a} python3.9-minimal{a} readline-common{a} sensible-utils{a} swig{a} swig4.0{a} tzdata{a} zlib1g-dev{a} The following packages are RECOMMENDED but will NOT be installed: ca-certificates curl javascript-common libarchive-cpio-perl libcoarrays-openmpi-dev libgpm2 libldap-common libmail-sendmail-perl libsasl2-modules lynx psmisc publicsuffix wget xauth 0 packages upgraded, 129 newly installed, 0 to remove and 0 not upgraded. Need to get 57.2 MB of archives. After unpacking 201 MB will be used. Writing extended state information... Get: 1 http://deb.debian.org/debian bullseye/main armhf bsdextrautils armhf 2.36.1-8+deb11u1 [139 kB] Get: 2 http://deb.debian.org/debian bullseye/main armhf libuchardet0 armhf 0.0.7-1 [65.0 kB] Get: 3 http://deb.debian.org/debian bullseye/main armhf groff-base armhf 1.22.4-6 [847 kB] Get: 4 http://deb.debian.org/debian bullseye/main armhf libpipeline1 armhf 1.5.3-1 [30.1 kB] Get: 5 http://deb.debian.org/debian bullseye/main armhf man-db armhf 2.9.4-2 [1319 kB] Get: 6 http://deb.debian.org/debian bullseye/main armhf libpython3.9-minimal armhf 3.9.2-1 [790 kB] Get: 7 http://deb.debian.org/debian bullseye/main armhf libexpat1 armhf 2.2.10-2+deb11u5 [78.4 kB] Get: 8 http://deb.debian.org/debian bullseye/main armhf python3.9-minimal armhf 3.9.2-1 [1630 kB] Get: 9 http://deb.debian.org/debian bullseye/main armhf python3-minimal armhf 3.9.2-3 [38.2 kB] Get: 10 http://deb.debian.org/debian bullseye/main armhf media-types all 4.0.0 [30.3 kB] Get: 11 http://deb.debian.org/debian bullseye/main armhf tzdata all 2021a-1+deb11u10 [286 kB] Get: 12 http://deb.debian.org/debian bullseye/main armhf libmpdec3 armhf 2.5.1-1 [74.9 kB] Get: 13 http://deb.debian.org/debian bullseye/main armhf readline-common all 8.1-1 [73.7 kB] Get: 14 http://deb.debian.org/debian bullseye/main armhf libreadline8 armhf 8.1-1 [147 kB] Get: 15 http://deb.debian.org/debian bullseye/main armhf libpython3.9-stdlib armhf 3.9.2-1 [1608 kB] Get: 16 http://deb.debian.org/debian bullseye/main armhf python3.9 armhf 3.9.2-1 [466 kB] Get: 17 http://deb.debian.org/debian bullseye/main armhf libpython3-stdlib armhf 3.9.2-3 [21.4 kB] Get: 18 http://deb.debian.org/debian bullseye/main armhf python3 armhf 3.9.2-3 [37.9 kB] Get: 19 http://deb.debian.org/debian bullseye/main armhf libncurses6 armhf 6.2+20201114-2+deb11u2 [80.6 kB] Get: 20 http://deb.debian.org/debian bullseye/main armhf libprocps8 armhf 2:3.3.17-5 [60.7 kB] Get: 21 http://deb.debian.org/debian bullseye/main armhf procps armhf 2:3.3.17-5 [492 kB] Get: 22 http://deb.debian.org/debian bullseye/main armhf sensible-utils all 0.0.14 [14.8 kB] Get: 23 http://deb.debian.org/debian bullseye/main armhf libmagic-mgc armhf 1:5.39-3+deb11u1 [273 kB] Get: 24 http://deb.debian.org/debian bullseye/main armhf libmagic1 armhf 1:5.39-3+deb11u1 [120 kB] Get: 25 http://deb.debian.org/debian bullseye/main armhf file armhf 1:5.39-3+deb11u1 [68.2 kB] Get: 26 http://deb.debian.org/debian bullseye/main armhf gettext-base armhf 0.21-4 [171 kB] Get: 27 http://deb.debian.org/debian bullseye/main armhf libmd0 armhf 1.0.3-3 [27.4 kB] Get: 28 http://deb.debian.org/debian bullseye/main armhf libbsd0 armhf 0.11.3-1+deb11u1 [103 kB] Get: 29 http://deb.debian.org/debian bullseye/main armhf libedit2 armhf 3.1-20191231-2+b1 [81.1 kB] Get: 30 http://deb.debian.org/debian bullseye/main armhf libcbor0 armhf 0.5.0+dfsg-2 [19.6 kB] Get: 31 http://deb.debian.org/debian bullseye/main armhf libfido2-1 armhf 1.6.0-2 [48.0 kB] Get: 32 http://deb.debian.org/debian bullseye/main armhf openssh-client armhf 1:8.4p1-5+deb11u2 [844 kB] Get: 33 http://deb.debian.org/debian bullseye/main armhf libsigsegv2 armhf 2.13-1 [34.0 kB] Get: 34 http://deb.debian.org/debian bullseye/main armhf m4 armhf 1.4.18-5 [192 kB] Get: 35 http://deb.debian.org/debian bullseye/main armhf autoconf all 2.69-14 [313 kB] Get: 36 http://deb.debian.org/debian bullseye/main armhf autotools-dev all 20180224.1+nmu1 [77.1 kB] Get: 37 http://deb.debian.org/debian bullseye/main armhf automake all 1:1.16.3-2 [814 kB] Get: 38 http://deb.debian.org/debian bullseye/main armhf autopoint all 0.21-4 [510 kB] Get: 39 http://deb.debian.org/debian bullseye/main armhf cmake-data all 3.18.4-2+deb11u1 [1725 kB] Get: 40 http://deb.debian.org/debian bullseye/main armhf libicu67 armhf 67.1-7 [8319 kB] Get: 41 http://deb.debian.org/debian bullseye/main armhf libxml2 armhf 2.9.10+dfsg-6.7+deb11u4 [602 kB] Get: 42 http://deb.debian.org/debian bullseye/main armhf libarchive13 armhf 3.4.3-2+deb11u1 [303 kB] Get: 43 http://deb.debian.org/debian bullseye/main armhf libbrotli1 armhf 1.0.9-2+b2 [262 kB] Get: 44 http://deb.debian.org/debian bullseye/main armhf libsasl2-modules-db armhf 2.1.27+dfsg-2.1+deb11u1 [67.7 kB] Get: 45 http://deb.debian.org/debian bullseye/main armhf libsasl2-2 armhf 2.1.27+dfsg-2.1+deb11u1 [99.2 kB] Get: 46 http://deb.debian.org/debian bullseye/main armhf libldap-2.4-2 armhf 2.4.57+dfsg-3+deb11u1 [210 kB] Get: 47 http://deb.debian.org/debian bullseye/main armhf libnghttp2-14 armhf 1.43.0-1 [65.6 kB] Get: 48 http://deb.debian.org/debian bullseye/main armhf libpsl5 armhf 0.21.0-1.2 [56.1 kB] Get: 49 http://deb.debian.org/debian bullseye/main armhf librtmp1 armhf 2.4+20151223.gitfa8646d.1-2+b2 [55.2 kB] Get: 50 http://deb.debian.org/debian bullseye/main armhf libssh2-1 armhf 1.9.0-2 [143 kB] Get: 51 http://deb.debian.org/debian bullseye/main armhf libcurl4 armhf 7.74.0-1.3+deb11u9 [314 kB] Get: 52 http://deb.debian.org/debian bullseye/main armhf libjsoncpp24 armhf 1.9.4-4 [68.5 kB] Get: 53 http://deb.debian.org/debian bullseye/main armhf librhash0 armhf 1.4.1-2 [144 kB] Get: 54 http://deb.debian.org/debian bullseye/main armhf libuv1 armhf 1.40.0-2 [120 kB] Get: 55 http://deb.debian.org/debian bullseye/main armhf cmake armhf 3.18.4-2+deb11u1 [3534 kB] Get: 56 http://deb.debian.org/debian bullseye/main armhf libdebhelper-perl all 13.3.4 [189 kB] Get: 57 http://deb.debian.org/debian bullseye/main armhf libtool all 2.4.6-15 [513 kB] Get: 58 http://deb.debian.org/debian bullseye/main armhf dh-autoreconf all 20 [17.1 kB] Get: 59 http://deb.debian.org/debian bullseye/main armhf libarchive-zip-perl all 1.68-1 [104 kB] Get: 60 http://deb.debian.org/debian bullseye/main armhf libsub-override-perl all 0.09-2 [10.2 kB] Get: 61 http://deb.debian.org/debian bullseye/main armhf libfile-stripnondeterminism-perl all 1.12.0-1 [26.3 kB] Get: 62 http://deb.debian.org/debian bullseye/main armhf dh-strip-nondeterminism all 1.12.0-1 [15.4 kB] Get: 63 http://deb.debian.org/debian bullseye/main armhf libelf1 armhf 0.183-1 [161 kB] Get: 64 http://deb.debian.org/debian bullseye/main armhf dwz armhf 0.13+20210201-1 [179 kB] Get: 65 http://deb.debian.org/debian bullseye/main armhf gettext armhf 0.21-4 [1243 kB] Get: 66 http://deb.debian.org/debian bullseye/main armhf intltool-debian all 0.35.0+20060710.5 [26.8 kB] Get: 67 http://deb.debian.org/debian bullseye/main armhf po-debconf all 1.0.21+nmu1 [248 kB] Get: 68 http://deb.debian.org/debian bullseye/main armhf debhelper all 13.3.4 [1049 kB] Get: 69 http://deb.debian.org/debian bullseye/main armhf python3-lib2to3 all 3.9.2-1 [77.8 kB] Get: 70 http://deb.debian.org/debian bullseye/main armhf python3-distutils all 3.9.2-1 [143 kB] Get: 71 http://deb.debian.org/debian bullseye/main armhf dh-python all 4.20201102+nmu1 [99.4 kB] Get: 72 http://deb.debian.org/debian bullseye/main armhf libgfortran5 armhf 10.2.1-6 [237 kB] Get: 73 http://deb.debian.org/debian bullseye/main armhf libgfortran-10-dev armhf 10.2.1-6 [289 kB] Get: 74 http://deb.debian.org/debian bullseye/main armhf gfortran-10 armhf 10.2.1-6 [7123 kB] Get: 75 http://deb.debian.org/debian bullseye/main armhf libnl-3-200 armhf 3.4.0-1+b1 [55.5 kB] Get: 76 http://deb.debian.org/debian bullseye/main armhf libnl-route-3-200 armhf 3.4.0-1+b1 [136 kB] Get: 77 http://deb.debian.org/debian bullseye/main armhf libibverbs1 armhf 33.2-1 [53.0 kB] Get: 78 http://deb.debian.org/debian bullseye/main armhf ibverbs-providers armhf 33.2-1 [25.4 kB] Get: 79 http://deb.debian.org/debian bullseye/main armhf libevent-2.1-7 armhf 2.1.12-stable-1 [169 kB] Get: 80 http://deb.debian.org/debian bullseye/main armhf libevent-core-2.1-7 armhf 2.1.12-stable-1 [127 kB] Get: 81 http://deb.debian.org/debian bullseye/main armhf libevent-extra-2.1-7 armhf 2.1.12-stable-1 [101 kB] Get: 82 http://deb.debian.org/debian bullseye/main armhf libevent-pthreads-2.1-7 armhf 2.1.12-stable-1 [56.8 kB] Get: 83 http://deb.debian.org/debian bullseye/main armhf libevent-openssl-2.1-7 armhf 2.1.12-stable-1 [61.6 kB] Get: 84 http://deb.debian.org/debian bullseye/main armhf libevent-dev armhf 2.1.12-stable-1 [296 kB] Get: 85 http://deb.debian.org/debian bullseye/main armhf libexpat1-dev armhf 2.2.10-2+deb11u5 [126 kB] Get: 86 http://deb.debian.org/debian bullseye/main armhf librdmacm1 armhf 33.2-1 [60.8 kB] Get: 87 http://deb.debian.org/debian bullseye/main armhf libfabric1 armhf 1.11.0-2 [319 kB] Get: 88 http://deb.debian.org/debian bullseye/main armhf libhwloc15 armhf 2.4.1+dfsg-1 [125 kB] Get: 89 http://deb.debian.org/debian bullseye/main armhf libnuma1 armhf 2.0.12-1+b1 [22.7 kB] Get: 90 http://deb.debian.org/debian bullseye/main armhf libnuma-dev armhf 2.0.12-1+b1 [37.0 kB] Get: 91 http://deb.debian.org/debian bullseye/main armhf libltdl7 armhf 2.4.6-15 [388 kB] Get: 92 http://deb.debian.org/debian bullseye/main armhf libltdl-dev armhf 2.4.6-15 [159 kB] Get: 93 http://deb.debian.org/debian bullseye/main armhf libhwloc-dev armhf 2.4.1+dfsg-1 [208 kB] Get: 94 http://deb.debian.org/debian bullseye/main armhf libpciaccess0 armhf 0.16-1 [51.0 kB] Get: 95 http://deb.debian.org/debian bullseye/main armhf libxau6 armhf 1:1.0.9-1 [19.0 kB] Get: 96 http://deb.debian.org/debian bullseye/main armhf libxdmcp6 armhf 1:1.1.2-3 [24.9 kB] Get: 97 http://deb.debian.org/debian bullseye/main armhf libxcb1 armhf 1.14-3 [136 kB] Get: 98 http://deb.debian.org/debian bullseye/main armhf libx11-data all 2:1.7.2-1+deb11u1 [311 kB] Get: 99 http://deb.debian.org/debian bullseye/main armhf libx11-6 armhf 2:1.7.2-1+deb11u1 [711 kB] Get: 100 http://deb.debian.org/debian bullseye/main armhf libxext6 armhf 2:1.3.3-1.1 [47.8 kB] Get: 101 http://deb.debian.org/debian bullseye/main armhf libxnvctrl0 armhf 470.141.03-1~deb11u1 [26.4 kB] Get: 102 http://deb.debian.org/debian bullseye/main armhf ocl-icd-libopencl1 armhf 2.2.14-2 [39.7 kB] Get: 103 http://deb.debian.org/debian bullseye/main armhf libhwloc-plugins armhf 2.4.1+dfsg-1 [19.7 kB] Get: 104 http://deb.debian.org/debian bullseye/main armhf libnl-3-dev armhf 3.4.0-1+b1 [97.1 kB] Get: 105 http://deb.debian.org/debian bullseye/main armhf libnl-route-3-dev armhf 3.4.0-1+b1 [160 kB] Get: 106 http://deb.debian.org/debian bullseye/main armhf libibverbs-dev armhf 33.2-1 [183 kB] Get: 107 http://deb.debian.org/debian bullseye/main armhf libjs-jquery all 3.5.1+dfsg+~3.5.5-7 [315 kB] Get: 108 http://deb.debian.org/debian bullseye/main armhf libjs-jquery-ui all 1.12.1+dfsg-8+deb11u1 [232 kB] Get: 109 http://deb.debian.org/debian bullseye/main armhf libjs-underscore all 1.9.1~dfsg-3 [100 kB] Get: 110 http://deb.debian.org/debian bullseye/main armhf libjs-sphinxdoc all 3.4.3-2 [127 kB] Get: 111 http://deb.debian.org/debian bullseye/main armhf libmaloc1 armhf 1.5-1 [79.8 kB] Get: 112 http://deb.debian.org/debian bullseye/main armhf libmaloc-dev armhf 1.5-1 [109 kB] Get: 113 http://deb.debian.org/debian bullseye/main armhf libpmix2 armhf 4.0.0-4.1 [487 kB] Get: 114 http://deb.debian.org/debian bullseye/main armhf libopenmpi3 armhf 4.1.0-10 [1831 kB] Get: 115 http://deb.debian.org/debian bullseye/main armhf openmpi-common all 4.1.0-10 [179 kB] Get: 116 http://deb.debian.org/debian bullseye/main armhf zlib1g-dev armhf 1:1.2.11.dfsg-2+deb11u2 [185 kB] Get: 117 http://deb.debian.org/debian bullseye/main armhf libpmix-dev armhf 4.0.0-4.1 [618 kB] Get: 118 http://deb.debian.org/debian bullseye/main armhf openmpi-bin armhf 4.1.0-10 [206 kB] Get: 119 http://deb.debian.org/debian bullseye/main armhf libopenmpi-dev armhf 4.1.0-10 [1143 kB] Get: 120 http://deb.debian.org/debian bullseye/main armhf libpython3.9 armhf 3.9.2-1 [1447 kB] Get: 121 http://deb.debian.org/debian bullseye/main armhf libpython3.9-dev armhf 3.9.2-1 [3160 kB] Get: 122 http://deb.debian.org/debian bullseye/main armhf libpython3-dev armhf 3.9.2-3 [21.7 kB] Get: 123 http://deb.debian.org/debian bullseye/main armhf mpi-default-dev armhf 1.13 [5476 B] Get: 124 http://deb.debian.org/debian bullseye/main armhf python3.9-dev armhf 3.9.2-1 [515 kB] Get: 125 http://deb.debian.org/debian bullseye/main armhf python3-dev armhf 3.9.2-3 [24.8 kB] Get: 126 http://deb.debian.org/debian bullseye/main armhf python3-pkg-resources all 52.0.0-4 [190 kB] Get: 127 http://deb.debian.org/debian bullseye/main armhf python3-setuptools all 52.0.0-4 [366 kB] Get: 128 http://deb.debian.org/debian bullseye/main armhf swig4.0 armhf 4.0.2-1 [1327 kB] Get: 129 http://deb.debian.org/debian bullseye/main armhf swig all 4.0.2-1 [330 kB] Fetched 57.2 MB in 6s (9127 kB/s) debconf: delaying package configuration, since apt-utils is not installed Selecting previously unselected package bsdextrautils. (Reading database ... (Reading database ... 5% (Reading database ... 10% (Reading database ... 15% (Reading database ... 20% (Reading database ... 25% (Reading database ... 30% (Reading database ... 35% (Reading database ... 40% (Reading database ... 45% (Reading database ... 50% (Reading database ... 55% (Reading database ... 60% (Reading database ... 65% (Reading database ... 70% (Reading database ... 75% (Reading database ... 80% (Reading database ... 85% (Reading database ... 90% (Reading database ... 95% (Reading database ... 100% (Reading database ... 17486 files and directories currently installed.) Preparing to unpack .../0-bsdextrautils_2.36.1-8+deb11u1_armhf.deb ... Unpacking bsdextrautils (2.36.1-8+deb11u1) ... Selecting previously unselected package libuchardet0:armhf. Preparing to unpack .../1-libuchardet0_0.0.7-1_armhf.deb ... Unpacking libuchardet0:armhf (0.0.7-1) ... Selecting previously unselected package groff-base. Preparing to unpack .../2-groff-base_1.22.4-6_armhf.deb ... Unpacking groff-base (1.22.4-6) ... Selecting previously unselected package libpipeline1:armhf. Preparing to unpack .../3-libpipeline1_1.5.3-1_armhf.deb ... Unpacking libpipeline1:armhf (1.5.3-1) ... Selecting previously unselected package man-db. Preparing to unpack .../4-man-db_2.9.4-2_armhf.deb ... Unpacking man-db (2.9.4-2) ... Selecting previously unselected package libpython3.9-minimal:armhf. Preparing to unpack .../5-libpython3.9-minimal_3.9.2-1_armhf.deb ... Unpacking libpython3.9-minimal:armhf (3.9.2-1) ... Selecting previously unselected package libexpat1:armhf. Preparing to unpack .../6-libexpat1_2.2.10-2+deb11u5_armhf.deb ... Unpacking libexpat1:armhf (2.2.10-2+deb11u5) ... Selecting previously unselected package python3.9-minimal. Preparing to unpack .../7-python3.9-minimal_3.9.2-1_armhf.deb ... Unpacking python3.9-minimal (3.9.2-1) ... Setting up libpython3.9-minimal:armhf (3.9.2-1) ... Setting up libexpat1:armhf (2.2.10-2+deb11u5) ... Setting up python3.9-minimal (3.9.2-1) ... Selecting previously unselected package python3-minimal. (Reading database ... (Reading database ... 5% (Reading database ... 10% (Reading database ... 15% (Reading database ... 20% (Reading database ... 25% (Reading database ... 30% (Reading database ... 35% (Reading database ... 40% (Reading database ... 45% (Reading database ... 50% (Reading database ... 55% (Reading database ... 60% (Reading database ... 65% (Reading database ... 70% (Reading database ... 75% (Reading database ... 80% (Reading database ... 85% (Reading database ... 90% (Reading database ... 95% (Reading database ... 100% (Reading database ... 18353 files and directories currently installed.) Preparing to unpack .../0-python3-minimal_3.9.2-3_armhf.deb ... Unpacking python3-minimal (3.9.2-3) ... Selecting previously unselected package media-types. Preparing to unpack .../1-media-types_4.0.0_all.deb ... Unpacking media-types (4.0.0) ... Selecting previously unselected package tzdata. Preparing to unpack .../2-tzdata_2021a-1+deb11u10_all.deb ... Unpacking tzdata (2021a-1+deb11u10) ... Selecting previously unselected package libmpdec3:armhf. Preparing to unpack .../3-libmpdec3_2.5.1-1_armhf.deb ... Unpacking libmpdec3:armhf (2.5.1-1) ... Selecting previously unselected package readline-common. Preparing to unpack .../4-readline-common_8.1-1_all.deb ... Unpacking readline-common (8.1-1) ... Selecting previously unselected package libreadline8:armhf. Preparing to unpack .../5-libreadline8_8.1-1_armhf.deb ... Unpacking libreadline8:armhf (8.1-1) ... Selecting previously unselected package libpython3.9-stdlib:armhf. Preparing to unpack .../6-libpython3.9-stdlib_3.9.2-1_armhf.deb ... Unpacking libpython3.9-stdlib:armhf (3.9.2-1) ... Selecting previously unselected package python3.9. Preparing to unpack .../7-python3.9_3.9.2-1_armhf.deb ... Unpacking python3.9 (3.9.2-1) ... Selecting previously unselected package libpython3-stdlib:armhf. Preparing to unpack .../8-libpython3-stdlib_3.9.2-3_armhf.deb ... Unpacking libpython3-stdlib:armhf (3.9.2-3) ... Setting up python3-minimal (3.9.2-3) ... Selecting previously unselected package python3. (Reading database ... (Reading database ... 5% (Reading database ... 10% (Reading database ... 15% (Reading database ... 20% (Reading database ... 25% (Reading database ... 30% (Reading database ... 35% (Reading database ... 40% (Reading database ... 45% (Reading database ... 50% (Reading database ... 55% (Reading database ... 60% (Reading database ... 65% (Reading database ... 70% (Reading database ... 75% (Reading database ... 80% (Reading database ... 85% (Reading database ... 90% (Reading database ... 95% (Reading database ... 100% (Reading database ... 20636 files and directories currently installed.) Preparing to unpack .../000-python3_3.9.2-3_armhf.deb ... Unpacking python3 (3.9.2-3) ... Selecting previously unselected package libncurses6:armhf. Preparing to unpack .../001-libncurses6_6.2+20201114-2+deb11u2_armhf.deb ... Unpacking libncurses6:armhf (6.2+20201114-2+deb11u2) ... Selecting previously unselected package libprocps8:armhf. Preparing to unpack .../002-libprocps8_2%3a3.3.17-5_armhf.deb ... Unpacking libprocps8:armhf (2:3.3.17-5) ... Selecting previously unselected package procps. Preparing to unpack .../003-procps_2%3a3.3.17-5_armhf.deb ... Unpacking procps (2:3.3.17-5) ... Selecting previously unselected package sensible-utils. Preparing to unpack .../004-sensible-utils_0.0.14_all.deb ... Unpacking sensible-utils (0.0.14) ... Selecting previously unselected package libmagic-mgc. Preparing to unpack .../005-libmagic-mgc_1%3a5.39-3+deb11u1_armhf.deb ... Unpacking libmagic-mgc (1:5.39-3+deb11u1) ... Selecting previously unselected package libmagic1:armhf. Preparing to unpack .../006-libmagic1_1%3a5.39-3+deb11u1_armhf.deb ... Unpacking libmagic1:armhf (1:5.39-3+deb11u1) ... Selecting previously unselected package file. Preparing to unpack .../007-file_1%3a5.39-3+deb11u1_armhf.deb ... Unpacking file (1:5.39-3+deb11u1) ... Selecting previously unselected package gettext-base. Preparing to unpack .../008-gettext-base_0.21-4_armhf.deb ... Unpacking gettext-base (0.21-4) ... Selecting previously unselected package libmd0:armhf. Preparing to unpack .../009-libmd0_1.0.3-3_armhf.deb ... Unpacking libmd0:armhf (1.0.3-3) ... Selecting previously unselected package libbsd0:armhf. Preparing to unpack .../010-libbsd0_0.11.3-1+deb11u1_armhf.deb ... Unpacking libbsd0:armhf (0.11.3-1+deb11u1) ... Selecting previously unselected package libedit2:armhf. Preparing to unpack .../011-libedit2_3.1-20191231-2+b1_armhf.deb ... Unpacking libedit2:armhf (3.1-20191231-2+b1) ... Selecting previously unselected package libcbor0:armhf. Preparing to unpack .../012-libcbor0_0.5.0+dfsg-2_armhf.deb ... Unpacking libcbor0:armhf (0.5.0+dfsg-2) ... Selecting previously unselected package libfido2-1:armhf. Preparing to unpack .../013-libfido2-1_1.6.0-2_armhf.deb ... Unpacking libfido2-1:armhf (1.6.0-2) ... Selecting previously unselected package openssh-client. Preparing to unpack .../014-openssh-client_1%3a8.4p1-5+deb11u2_armhf.deb ... Unpacking openssh-client (1:8.4p1-5+deb11u2) ... Selecting previously unselected package libsigsegv2:armhf. Preparing to unpack .../015-libsigsegv2_2.13-1_armhf.deb ... Unpacking libsigsegv2:armhf (2.13-1) ... Selecting previously unselected package m4. Preparing to unpack .../016-m4_1.4.18-5_armhf.deb ... Unpacking m4 (1.4.18-5) ... Selecting previously unselected package autoconf. Preparing to unpack .../017-autoconf_2.69-14_all.deb ... Unpacking autoconf (2.69-14) ... Selecting previously unselected package autotools-dev. Preparing to unpack .../018-autotools-dev_20180224.1+nmu1_all.deb ... Unpacking autotools-dev (20180224.1+nmu1) ... 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Selecting previously unselected package libbrotli1:armhf. Preparing to unpack .../025-libbrotli1_1.0.9-2+b2_armhf.deb ... Unpacking libbrotli1:armhf (1.0.9-2+b2) ... Selecting previously unselected package libsasl2-modules-db:armhf. Preparing to unpack .../026-libsasl2-modules-db_2.1.27+dfsg-2.1+deb11u1_armhf.deb ... Unpacking libsasl2-modules-db:armhf (2.1.27+dfsg-2.1+deb11u1) ... Selecting previously unselected package libsasl2-2:armhf. Preparing to unpack .../027-libsasl2-2_2.1.27+dfsg-2.1+deb11u1_armhf.deb ... Unpacking libsasl2-2:armhf (2.1.27+dfsg-2.1+deb11u1) ... Selecting previously unselected package libldap-2.4-2:armhf. Preparing to unpack .../028-libldap-2.4-2_2.4.57+dfsg-3+deb11u1_armhf.deb ... Unpacking libldap-2.4-2:armhf (2.4.57+dfsg-3+deb11u1) ... Selecting previously unselected package libnghttp2-14:armhf. Preparing to unpack .../029-libnghttp2-14_1.43.0-1_armhf.deb ... Unpacking libnghttp2-14:armhf (1.43.0-1) ... Selecting previously unselected package libpsl5:armhf. 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Setting up libsasl2-modules-db:armhf (2.1.27+dfsg-2.1+deb11u1) ... Setting up tzdata (2021a-1+deb11u10) ... Current default time zone: 'Etc/UTC' Local time is now: Mon Jan 8 03:27:05 UTC 2024. Universal Time is now: Mon Jan 8 03:27:05 UTC 2024. Run 'dpkg-reconfigure tzdata' if you wish to change it. Setting up autotools-dev (20180224.1+nmu1) ... Setting up libuv1:armhf (1.40.0-2) ... Setting up libexpat1-dev:armhf (2.2.10-2+deb11u5) ... Setting up libx11-data (2:1.7.2-1+deb11u1) ... Setting up librtmp1:armhf (2.4+20151223.gitfa8646d.1-2+b2) ... Setting up libncurses6:armhf (6.2+20201114-2+deb11u2) ... Setting up libsigsegv2:armhf (2.13-1) ... Setting up libhwloc15:armhf (2.4.1+dfsg-1) ... Setting up libevent-core-2.1-7:armhf (2.1.12-stable-1) ... Setting up libevent-2.1-7:armhf (2.1.12-stable-1) ... Setting up autopoint (0.21-4) ... Setting up libltdl7:armhf (2.4.6-15) ... Setting up libsasl2-2:armhf (2.1.27+dfsg-2.1+deb11u1) ... Setting up libgfortran5:armhf (10.2.1-6) ... 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Setting up libprocps8:armhf (2:3.3.17-5) ... Setting up libjs-underscore (1.9.1~dfsg-3) ... Setting up libevent-pthreads-2.1-7:armhf (2.1.12-stable-1) ... Setting up libfile-stripnondeterminism-perl (1.12.0-1) ... Setting up libxdmcp6:armhf (1:1.1.2-3) ... Setting up libevent-extra-2.1-7:armhf (2.1.12-stable-1) ... Setting up libxcb1:armhf (1.14-3) ... Setting up gettext (0.21-4) ... Setting up swig (4.0.2-1) ... Setting up libtool (2.4.6-15) ... Setting up libarchive13:armhf (3.4.3-2+deb11u1) ... Setting up libedit2:armhf (3.1-20191231-2+b1) ... Setting up libreadline8:armhf (8.1-1) ... Setting up libevent-openssl-2.1-7:armhf (2.1.12-stable-1) ... Setting up libldap-2.4-2:armhf (2.4.57+dfsg-3+deb11u1) ... Setting up m4 (1.4.18-5) ... Setting up intltool-debian (0.35.0+20060710.5) ... Setting up libnuma-dev:armhf (2.0.12-1+b1) ... Setting up libnl-route-3-200:armhf (3.4.0-1+b1) ... Setting up libjs-jquery-ui (1.12.1+dfsg-8+deb11u1) ... Setting up libevent-dev (2.1.12-stable-1) ... Setting up gfortran-10 (10.2.1-6) ... Setting up libjs-sphinxdoc (3.4.3-2) ... Setting up autoconf (2.69-14) ... Setting up dh-strip-nondeterminism (1.12.0-1) ... Setting up dwz (0.13+20210201-1) ... Setting up libnl-3-dev:armhf (3.4.0-1+b1) ... Setting up groff-base (1.22.4-6) ... Setting up procps (2:3.3.17-5) ... Setting up libcurl4:armhf (7.74.0-1.3+deb11u9) ... Setting up libx11-6:armhf (2:1.7.2-1+deb11u1) ... Setting up libpython3.9-stdlib:armhf (3.9.2-1) ... Setting up libpython3-stdlib:armhf (3.9.2-3) ... Setting up automake (1:1.16.3-2) ... update-alternatives: using /usr/bin/automake-1.16 to provide /usr/bin/automake (automake) in auto mode Setting up libmaloc1 (1.5-1) ... Setting up libibverbs1:armhf (33.2-1) ... Setting up ibverbs-providers:armhf (33.2-1) ... Setting up openssh-client (1:8.4p1-5+deb11u2) ... Setting up po-debconf (1.0.21+nmu1) ... Setting up libxext6:armhf (2:1.3.3-1.1) ... Setting up man-db (2.9.4-2) ... Not building database; man-db/auto-update is not 'true'. Setting up libxnvctrl0:armhf (470.141.03-1~deb11u1) ... Setting up dh-autoreconf (20) ... Setting up libnl-route-3-dev:armhf (3.4.0-1+b1) ... Setting up libltdl-dev:armhf (2.4.6-15) ... Setting up libpython3.9:armhf (3.9.2-1) ... Setting up cmake (3.18.4-2+deb11u1) ... Setting up libhwloc-dev:armhf (2.4.1+dfsg-1) ... Setting up libmaloc-dev (1.5-1) ... Setting up python3.9 (3.9.2-1) ... Setting up librdmacm1:armhf (33.2-1) ... Setting up libpython3.9-dev:armhf (3.9.2-1) ... Setting up debhelper (13.3.4) ... Setting up python3 (3.9.2-3) ... Setting up libibverbs-dev:armhf (33.2-1) ... Setting up libhwloc-plugins:armhf (2.4.1+dfsg-1) ... Setting up python3.9-dev (3.9.2-1) ... Setting up python3-lib2to3 (3.9.2-1) ... Setting up python3-pkg-resources (52.0.0-4) ... Setting up python3-distutils (3.9.2-1) ... Setting up dh-python (4.20201102+nmu1) ... Setting up libfabric1 (1.11.0-2) ... Setting up libpython3-dev:armhf (3.9.2-3) ... Setting up python3-setuptools (52.0.0-4) ... Setting up libpmix2:armhf (4.0.0-4.1) ... Setting up libopenmpi3:armhf (4.1.0-10) ... Setting up python3-dev (3.9.2-3) ... Setting up libpmix-dev:armhf (4.0.0-4.1) ... Setting up openmpi-bin (4.1.0-10) ... update-alternatives: using /usr/bin/mpirun.openmpi to provide /usr/bin/mpirun (mpirun) in auto mode update-alternatives: using /usr/bin/mpicc.openmpi to provide /usr/bin/mpicc (mpi) in auto mode Setting up libopenmpi-dev:armhf (4.1.0-10) ... update-alternatives: using /usr/lib/arm-linux-gnueabihf/openmpi/include to provide /usr/include/arm-linux-gnueabihf/mpi (mpi-arm-linux-gnueabihf) in auto mode Setting up mpi-default-dev (1.13) ... Processing triggers for libc-bin (2.31-13+deb11u6) ... Reading package lists... Building dependency tree... Reading state information... Reading extended state information... Initializing package states... Writing extended state information... Building tag database... -> Finished parsing the build-deps Reading package lists... Building dependency tree... Reading state information... fakeroot is already the newest version (1.25.3-1.1). 0 upgraded, 0 newly installed, 0 to remove and 0 not upgraded. I: Building the package I: Running cd /build/reproducible-path/apbs-3.0.0+dfsg1/ && env PATH="/usr/sbin:/usr/bin:/sbin:/bin:/usr/games" HOME="/nonexistent/first-build" dpkg-buildpackage -us -uc -b && env PATH="/usr/sbin:/usr/bin:/sbin:/bin:/usr/games" HOME="/nonexistent/first-build" dpkg-genchanges -S > ../apbs_3.0.0+dfsg1-3_source.changes dpkg-buildpackage: info: source package apbs dpkg-buildpackage: info: source version 3.0.0+dfsg1-3 dpkg-buildpackage: info: source distribution unstable dpkg-buildpackage: info: source changed by Drew Parsons dpkg-source --before-build . dpkg-buildpackage: info: host architecture armhf fakeroot debian/rules clean dh clean --with python3 debian/rules override_dh_auto_clean make[1]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1' dh_auto_clean --sourcedir=apbs make[1]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1' dh_clean debian/rules build dh build --with python3 dh_update_autotools_config dh_autoreconf debian/rules override_dh_auto_configure make[1]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1' dh_auto_configure --sourcedir=apbs -- \ -DCMAKE_BUILD_TYPE=None -DCMAKE_SKIP_RPATH=On \ -DBUILD_DOC=Off -DBUILD_TOOLS=On \ -DENABLE_OPENMP=On -DENABLE_MPI=On \ -DENABLE_PYTHON=On -DBUILD_SHARED_LIBS=On \ -DENABLE_READLINE=Off -DENABLE_ZLIB=On \ -DFETK_PATH=/usr -DENABLE_FETK=Off cd obj-arm-linux-gnueabihf && cmake -DCMAKE_INSTALL_PREFIX=/usr -DCMAKE_BUILD_TYPE=None -DCMAKE_INSTALL_SYSCONFDIR=/etc -DCMAKE_INSTALL_LOCALSTATEDIR=/var -DCMAKE_EXPORT_NO_PACKAGE_REGISTRY=ON -DCMAKE_FIND_PACKAGE_NO_PACKAGE_REGISTRY=ON -DCMAKE_INSTALL_RUNSTATEDIR=/run -DCMAKE_SKIP_INSTALL_ALL_DEPENDENCY=ON "-GUnix Makefiles" -DCMAKE_VERBOSE_MAKEFILE=ON -DCMAKE_INSTALL_LIBDIR=lib/arm-linux-gnueabihf -DCMAKE_BUILD_TYPE=None -DCMAKE_SKIP_RPATH=On -DBUILD_DOC=Off -DBUILD_TOOLS=On -DENABLE_OPENMP=On -DENABLE_MPI=On -DENABLE_PYTHON=On -DBUILD_SHARED_LIBS=On -DENABLE_READLINE=Off -DENABLE_ZLIB=On -DFETK_PATH=/usr -DENABLE_FETK=Off ../apbs CMake Deprecation Warning at CMakeLists.txt:10 (cmake_policy): The OLD behavior for policy CMP0054 will be removed from a future version of CMake. The cmake-policies(7) manual explains that the OLD behaviors of all policies are deprecated and that a policy should be set to OLD only under specific short-term circumstances. Projects should be ported to the NEW behavior and not rely on setting a policy to OLD. -- The C compiler identification is GNU 10.2.1 -- The CXX compiler identification is GNU 10.2.1 -- Detecting C compiler ABI info -- Detecting C compiler ABI info - done -- Check for working C compiler: /usr/bin/cc - skipped -- Detecting C compile features -- Detecting C compile features - done -- Detecting CXX compiler ABI info -- Detecting CXX compiler ABI info - done -- Check for working CXX compiler: /usr/bin/c++ - skipped -- Detecting CXX compile features -- Detecting CXX compile features - done -- Setting project paths -- Setting lookup paths for headers and libraries -- Computing machine epsilon values -- Floating point epsilon is 2.220446e-16 -- Double precision epsilon is 2.220446e-16 -- Looking for time -- Looking for time - found -- Looking for rand -- Looking for rand - found -- Looking for srand -- Looking for srand - found -- Checking for MPI -- Found MPI_C: /usr/lib/arm-linux-gnueabihf/openmpi/lib/libmpi.so (found version "3.1") -- Found MPI_CXX: /usr/lib/arm-linux-gnueabihf/openmpi/lib/libmpi_cxx.so (found version "3.1") -- Found MPI: TRUE (found version "3.1") -- MPI support enabled -- Inline functions enabled -- Verbose debugging mode enabled -- Checking for OpenMP -- Found OpenMP_C: -fopenmp (found version "4.5") -- Found OpenMP_CXX: -fopenmp (found version "4.5") -- Found OpenMP: TRUE (found version "4.5") -- OpenMP support enabled -- Adding apbs_generic -- With source files nosh.c;mgparm.c;femparm.c;pbamparm.c;pbsamparm.c;pbeparm.c;bemparm.c;geoflowparm.c;apolparm.c;vacc.c;valist.c;vatom.c;vpbe.c;vcap.c;vclist.c;vstring.c;vparam.c;vgreen.c -- With external header files nosh.h;mgparm.h;femparm.h;pbamparm.h;pbsamparm.h;pbeparm.h;bemparm.h;geoflowparm.h;apolparm.h;vacc.h;valist.h;vatom.h;vpbe.h;vcap.h;vclist.h;vstring.h;vparam.h;vgreen.h;vmatrix.h;vhal.h;vunit.h -- With internal header files -- With library dependencies m;stdc++;/usr/lib/arm-linux-gnueabihf/openmpi/lib/libmpi.so;maloc;-fopenmp -- Added apbs_generic -- Adding apbs_pmgc -- With source files buildAd.c;buildBd.c;buildGd.c;buildPd.c;cgd.c;gsd.c;matvecd.c;mgcsd.c;mgdrvd.c;mgsubd.c;mikpckd.c;mlinpckd.c;mypdec.c;newtond.c;newdrvd.c;powerd.c;smoothd.c;mgfasd.c -- With external header files buildAd.h;buildBd.h;buildGd.h;buildPd.h;cgd.h;gsd.h;matvecd.h;mgcsd.h;mgdrvd.h;mgsubd.h;mikpckd.h;mlinpckd.h;mypdec.h;newtond.h;newdrvd.h;powerd.h;smoothd.h;mgfasd.h -- With internal header files -- With library dependencies m;stdc++;/usr/lib/arm-linux-gnueabihf/openmpi/lib/libmpi.so;maloc;-fopenmp -- Added apbs_pmgc -- Adding apbs_mg -- With source files vgrid.c;vmgrid.c;vopot.c;vpmg.c;vpmgp.c -- With external header files vgrid.h;vmgrid.h;vopot.h;vpmg.h;vpmgp.h -- With internal header files -- With library dependencies m;stdc++;/usr/lib/arm-linux-gnueabihf/openmpi/lib/libmpi.so;maloc;-fopenmp;apbs_generic;apbs_pmgc -- Added apbs_mg -- Adding apbs_routines -- With source files routines.c -- With external header files -- With internal header files -- With library dependencies m;stdc++;/usr/lib/arm-linux-gnueabihf/openmpi/lib/libmpi.so;maloc;-fopenmp -- Added apbs_routines -- External Headers: -- -- APBS Libraries: m;stdc++;/usr/lib/arm-linux-gnueabihf/openmpi/lib/libmpi.so;maloc;-fopenmp -- Internal Libraries: apbs_generic;apbs_pmgc;apbs_mg;apbs_routines -- -- -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -- Supplemental tools enabled -- Building mesh -- libraries: apbs_generic;apbs_mg;apbs_pmgc -- Building manip -- libraries: apbs_generic;apbs_mg;apbs_pmgc -- Found SWIG: /usr/bin/swig4.0 (found version "4.0.2") -- Found Python3: /usr/bin/python3.9 (found version "3.9.2") found components: Interpreter Development Development.Module Development.Embed -- ******* Python3 FOUND -- ***** Python3 include path is: /usr/include/python3.9 -- ***** Python3 library path is: /usr/lib/arm-linux-gnueabihf/libpython3.9.so -- ***** Python3 library dir is: /usr/lib/arm-linux-gnueabihf -- Found Python3: /usr/bin/python3.9 (found version "3.9.2") found components: Interpreter -- ******* Python3 FOUND /usr/bin/python3.9 -- TEST born_test COMMAND /usr/bin/python3.9 /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tests/apbs_tester.py -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tests/test_cases.cfg -e /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/apbs -t born -- TEST actin-dimer-auto_test COMMAND /usr/bin/python3.9 /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tests/apbs_tester.py -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tests/test_cases.cfg -e /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/apbs -t actin-dimer-auto -- TEST actin-dimer-parallel_test COMMAND /usr/bin/python3.9 /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tests/apbs_tester.py -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tests/test_cases.cfg -e /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/apbs -t actin-dimer-parallel -- TEST alkanes_test COMMAND /usr/bin/python3.9 /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tests/apbs_tester.py -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tests/test_cases.cfg -e /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/apbs -t alkanes -- TEST FKBP_test COMMAND /usr/bin/python3.9 /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tests/apbs_tester.py -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tests/test_cases.cfg -e /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/apbs -t FKBP -- TEST hca-bind_test COMMAND /usr/bin/python3.9 /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tests/apbs_tester.py -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tests/test_cases.cfg -e /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/apbs -t hca-bind -- TEST ionize_test COMMAND /usr/bin/python3.9 /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tests/apbs_tester.py -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tests/test_cases.cfg -e /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/apbs -t ionize -- TEST ion-pmf_test COMMAND /usr/bin/python3.9 /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tests/apbs_tester.py -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tests/test_cases.cfg -e /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/apbs -t ion-pmf -- TEST pka-lig_test COMMAND /usr/bin/python3.9 /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tests/apbs_tester.py -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tests/test_cases.cfg -e /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/apbs -t pka-lig -- TEST point-pmf_test COMMAND /usr/bin/python3.9 /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tests/apbs_tester.py -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tests/test_cases.cfg -e /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/apbs -t point-pmf -- TEST solv_test COMMAND /usr/bin/python3.9 /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tests/apbs_tester.py -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tests/test_cases.cfg -e /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/apbs -t solv -- TEST protein-rna_test COMMAND /usr/bin/python3.9 /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tests/apbs_tester.py -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tests/test_cases.cfg -e /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/apbs -t protein-rna -- Configuring done -- Generating done CMake Warning: Manually-specified variables were not used by the project: CMAKE_EXPORT_NO_PACKAGE_REGISTRY ENABLE_READLINE ENABLE_ZLIB FETK_PATH -- Build files have been written to: /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf make[1]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1' debian/rules override_dh_auto_build make[1]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1' dh_auto_build --sourcedir=apbs cd obj-arm-linux-gnueabihf && make -j3 "INSTALL=install --strip-program=true" VERBOSE=1 make[2]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' /usr/bin/cmake -S/build/reproducible-path/apbs-3.0.0+dfsg1/apbs -B/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf --check-build-system CMakeFiles/Makefile.cmake 0 /usr/bin/cmake -E cmake_progress_start /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/CMakeFiles /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf//CMakeFiles/progress.marks make -f CMakeFiles/Makefile2 all make[3]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' make -f src/pmgc/CMakeFiles/apbs_pmgc.dir/build.make src/pmgc/CMakeFiles/apbs_pmgc.dir/depend make -f src/generic/CMakeFiles/apbs_generic.dir/build.make src/generic/CMakeFiles/apbs_generic.dir/depend make -f tools/python/CMakeFiles/apbslib_swig_compilation.dir/build.make tools/python/CMakeFiles/apbslib_swig_compilation.dir/depend make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf && /usr/bin/cmake -E cmake_depends "Unix Makefiles" /build/reproducible-path/apbs-3.0.0+dfsg1/apbs /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/pmgc /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/pmgc /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/pmgc/CMakeFiles/apbs_pmgc.dir/DependInfo.cmake --color= make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf && /usr/bin/cmake -E cmake_depends "Unix Makefiles" /build/reproducible-path/apbs-3.0.0+dfsg1/apbs /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/python /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/python /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/python/CMakeFiles/apbslib_swig_compilation.dir/DependInfo.cmake --color= make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf && /usr/bin/cmake -E cmake_depends "Unix Makefiles" /build/reproducible-path/apbs-3.0.0+dfsg1/apbs /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/generic /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/generic /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/generic/CMakeFiles/apbs_generic.dir/DependInfo.cmake --color= Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/python/CMakeFiles/apbslib_swig_compilation.dir/DependInfo.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/python/CMakeFiles/apbslib_swig_compilation.dir/depend.internal". Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/python/CMakeFiles/CMakeDirectoryInformation.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/python/CMakeFiles/apbslib_swig_compilation.dir/depend.internal". Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/generic/CMakeFiles/apbs_generic.dir/DependInfo.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/generic/CMakeFiles/apbs_generic.dir/depend.internal". Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/generic/CMakeFiles/CMakeDirectoryInformation.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/generic/CMakeFiles/apbs_generic.dir/depend.internal". Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/pmgc/CMakeFiles/apbs_pmgc.dir/DependInfo.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/pmgc/CMakeFiles/apbs_pmgc.dir/depend.internal". Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/pmgc/CMakeFiles/CMakeDirectoryInformation.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/pmgc/CMakeFiles/apbs_pmgc.dir/depend.internal". Scanning dependencies of target apbslib_swig_compilation make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' make -f tools/python/CMakeFiles/apbslib_swig_compilation.dir/build.make tools/python/CMakeFiles/apbslib_swig_compilation.dir/build make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' [ 1%] Swig compile apbslib.i for python cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/python && /usr/bin/cmake -E make_directory /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/python /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/python/CMakeFiles/_apbslib.dir cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/python && /usr/bin/cmake -E touch /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/python/CMakeFiles/_apbslib.dir/apbslibPYTHON.stamp Scanning dependencies of target apbs_generic make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' make -f src/generic/CMakeFiles/apbs_generic.dir/build.make src/generic/CMakeFiles/apbs_generic.dir/build make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/python && /usr/bin/cmake -E env SWIG_LIB=/usr/share/swig4.0 /usr/bin/swig4.0 -python -outdir /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/python -interface _apbslib -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -I/usr/include/python3.9 -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/python -o /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/python/CMakeFiles/_apbslib.dir/apbslibPYTHON_wrap.c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/python/apbslib.i [ 2%] Building C object src/generic/CMakeFiles/apbs_generic.dir/nosh.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/generic && /usr/bin/cc -Dapbs_generic_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_generic.dir/nosh.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/generic/nosh.c Scanning dependencies of target apbs_pmgc make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' make -f src/pmgc/CMakeFiles/apbs_pmgc.dir/build.make src/pmgc/CMakeFiles/apbs_pmgc.dir/build make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' [ 3%] Building C object src/pmgc/CMakeFiles/apbs_pmgc.dir/buildAd.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/pmgc && /usr/bin/cc -Dapbs_pmgc_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_pmgc.dir/buildAd.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/pmgc/buildAd.c [ 4%] Building C object src/pmgc/CMakeFiles/apbs_pmgc.dir/buildBd.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/pmgc && /usr/bin/cc -Dapbs_pmgc_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_pmgc.dir/buildBd.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/pmgc/buildBd.c make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' [ 4%] Built target apbslib_swig_compilation [ 5%] Building C object src/pmgc/CMakeFiles/apbs_pmgc.dir/buildGd.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/pmgc && /usr/bin/cc -Dapbs_pmgc_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_pmgc.dir/buildGd.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/pmgc/buildGd.c [ 6%] Building C object src/pmgc/CMakeFiles/apbs_pmgc.dir/buildPd.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/pmgc && /usr/bin/cc -Dapbs_pmgc_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_pmgc.dir/buildPd.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/pmgc/buildPd.c [ 8%] Building C object src/generic/CMakeFiles/apbs_generic.dir/mgparm.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/generic && /usr/bin/cc -Dapbs_generic_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_generic.dir/mgparm.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/generic/mgparm.c [ 9%] Building C object src/generic/CMakeFiles/apbs_generic.dir/femparm.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/generic && /usr/bin/cc -Dapbs_generic_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_generic.dir/femparm.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/generic/femparm.c [ 10%] Building C object src/generic/CMakeFiles/apbs_generic.dir/pbamparm.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/generic && /usr/bin/cc -Dapbs_generic_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_generic.dir/pbamparm.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/generic/pbamparm.c [ 11%] Building C object src/pmgc/CMakeFiles/apbs_pmgc.dir/cgd.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/pmgc && /usr/bin/cc -Dapbs_pmgc_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_pmgc.dir/cgd.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/pmgc/cgd.c [ 12%] Building C object src/pmgc/CMakeFiles/apbs_pmgc.dir/gsd.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/pmgc && /usr/bin/cc -Dapbs_pmgc_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_pmgc.dir/gsd.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/pmgc/gsd.c [ 13%] Building C object src/generic/CMakeFiles/apbs_generic.dir/pbsamparm.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/generic && /usr/bin/cc -Dapbs_generic_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_generic.dir/pbsamparm.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/generic/pbsamparm.c [ 15%] Building C object src/generic/CMakeFiles/apbs_generic.dir/pbeparm.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/generic && /usr/bin/cc -Dapbs_generic_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_generic.dir/pbeparm.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/generic/pbeparm.c [ 16%] Building C object src/pmgc/CMakeFiles/apbs_pmgc.dir/matvecd.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/pmgc && /usr/bin/cc -Dapbs_pmgc_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_pmgc.dir/matvecd.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/pmgc/matvecd.c [ 17%] Building C object src/generic/CMakeFiles/apbs_generic.dir/bemparm.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/generic && /usr/bin/cc -Dapbs_generic_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_generic.dir/bemparm.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/generic/bemparm.c [ 18%] Building C object src/generic/CMakeFiles/apbs_generic.dir/geoflowparm.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/generic && /usr/bin/cc -Dapbs_generic_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_generic.dir/geoflowparm.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/generic/geoflowparm.c [ 19%] Building C object src/generic/CMakeFiles/apbs_generic.dir/apolparm.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/generic && /usr/bin/cc -Dapbs_generic_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_generic.dir/apolparm.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/generic/apolparm.c [ 20%] Building C object src/generic/CMakeFiles/apbs_generic.dir/vacc.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/generic && /usr/bin/cc -Dapbs_generic_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_generic.dir/vacc.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/generic/vacc.c [ 22%] Building C object src/generic/CMakeFiles/apbs_generic.dir/valist.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/generic && /usr/bin/cc -Dapbs_generic_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_generic.dir/valist.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/generic/valist.c [ 23%] Building C object src/generic/CMakeFiles/apbs_generic.dir/vatom.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/generic && /usr/bin/cc -Dapbs_generic_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_generic.dir/vatom.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/generic/vatom.c [ 24%] Building C object src/generic/CMakeFiles/apbs_generic.dir/vpbe.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/generic && /usr/bin/cc -Dapbs_generic_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_generic.dir/vpbe.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/generic/vpbe.c [ 25%] Building C object src/pmgc/CMakeFiles/apbs_pmgc.dir/mgcsd.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/pmgc && /usr/bin/cc -Dapbs_pmgc_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_pmgc.dir/mgcsd.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/pmgc/mgcsd.c [ 26%] Building C object src/generic/CMakeFiles/apbs_generic.dir/vcap.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/generic && /usr/bin/cc -Dapbs_generic_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_generic.dir/vcap.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/generic/vcap.c [ 27%] Building C object src/pmgc/CMakeFiles/apbs_pmgc.dir/mgdrvd.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/pmgc && /usr/bin/cc -Dapbs_pmgc_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_pmgc.dir/mgdrvd.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/pmgc/mgdrvd.c [ 29%] Building C object src/generic/CMakeFiles/apbs_generic.dir/vclist.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/generic && /usr/bin/cc -Dapbs_generic_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_generic.dir/vclist.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/generic/vclist.c [ 30%] Building C object src/pmgc/CMakeFiles/apbs_pmgc.dir/mgsubd.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/pmgc && /usr/bin/cc -Dapbs_pmgc_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_pmgc.dir/mgsubd.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/pmgc/mgsubd.c [ 31%] Building C object src/generic/CMakeFiles/apbs_generic.dir/vstring.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/generic && /usr/bin/cc -Dapbs_generic_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_generic.dir/vstring.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/generic/vstring.c [ 32%] Building C object src/generic/CMakeFiles/apbs_generic.dir/vparam.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/generic && /usr/bin/cc -Dapbs_generic_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_generic.dir/vparam.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/generic/vparam.c [ 33%] Building C object src/pmgc/CMakeFiles/apbs_pmgc.dir/mikpckd.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/pmgc && /usr/bin/cc -Dapbs_pmgc_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_pmgc.dir/mikpckd.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/pmgc/mikpckd.c [ 34%] Building C object src/generic/CMakeFiles/apbs_generic.dir/vgreen.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/generic && /usr/bin/cc -Dapbs_generic_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_generic.dir/vgreen.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/generic/vgreen.c [ 36%] Building C object src/pmgc/CMakeFiles/apbs_pmgc.dir/mlinpckd.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/pmgc && /usr/bin/cc -Dapbs_pmgc_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_pmgc.dir/mlinpckd.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/pmgc/mlinpckd.c [ 37%] Linking C shared library ../../lib/libapbs_generic.so cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/generic && /usr/bin/cmake -E cmake_link_script CMakeFiles/apbs_generic.dir/link.txt --verbose=1 /usr/bin/cc -fPIC -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -Wl,-z,relro -Wl,-z,now -Wl,--as-needed -shared -Wl,-soname,libapbs_generic.so.3 -o ../../lib/libapbs_generic.so.3 CMakeFiles/apbs_generic.dir/nosh.c.o CMakeFiles/apbs_generic.dir/mgparm.c.o CMakeFiles/apbs_generic.dir/femparm.c.o CMakeFiles/apbs_generic.dir/pbamparm.c.o CMakeFiles/apbs_generic.dir/pbsamparm.c.o CMakeFiles/apbs_generic.dir/pbeparm.c.o CMakeFiles/apbs_generic.dir/bemparm.c.o CMakeFiles/apbs_generic.dir/geoflowparm.c.o CMakeFiles/apbs_generic.dir/apolparm.c.o CMakeFiles/apbs_generic.dir/vacc.c.o CMakeFiles/apbs_generic.dir/valist.c.o CMakeFiles/apbs_generic.dir/vatom.c.o CMakeFiles/apbs_generic.dir/vpbe.c.o CMakeFiles/apbs_generic.dir/vcap.c.o CMakeFiles/apbs_generic.dir/vclist.c.o CMakeFiles/apbs_generic.dir/vstring.c.o CMakeFiles/apbs_generic.dir/vparam.c.o CMakeFiles/apbs_generic.dir/vgreen.c.o -lm -lstdc++ /usr/lib/arm-linux-gnueabihf/openmpi/lib/libmpi.so -lmaloc -fopenmp cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/generic && /usr/bin/cmake -E cmake_symlink_library ../../lib/libapbs_generic.so.3 ../../lib/libapbs_generic.so.3 ../../lib/libapbs_generic.so make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' [ 37%] Built target apbs_generic [ 38%] Building C object src/pmgc/CMakeFiles/apbs_pmgc.dir/mypdec.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/pmgc && /usr/bin/cc -Dapbs_pmgc_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_pmgc.dir/mypdec.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/pmgc/mypdec.c [ 39%] Building C object src/pmgc/CMakeFiles/apbs_pmgc.dir/newtond.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/pmgc && /usr/bin/cc -Dapbs_pmgc_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_pmgc.dir/newtond.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/pmgc/newtond.c [ 40%] Building C object src/pmgc/CMakeFiles/apbs_pmgc.dir/newdrvd.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/pmgc && /usr/bin/cc -Dapbs_pmgc_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_pmgc.dir/newdrvd.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/pmgc/newdrvd.c [ 41%] Building C object src/pmgc/CMakeFiles/apbs_pmgc.dir/powerd.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/pmgc && /usr/bin/cc -Dapbs_pmgc_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_pmgc.dir/powerd.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/pmgc/powerd.c [ 43%] Building C object src/pmgc/CMakeFiles/apbs_pmgc.dir/smoothd.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/pmgc && /usr/bin/cc -Dapbs_pmgc_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_pmgc.dir/smoothd.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/pmgc/smoothd.c [ 44%] Building C object src/pmgc/CMakeFiles/apbs_pmgc.dir/mgfasd.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/pmgc && /usr/bin/cc -Dapbs_pmgc_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_pmgc.dir/mgfasd.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/pmgc/mgfasd.c [ 45%] Linking C shared library ../../lib/libapbs_pmgc.so cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/pmgc && /usr/bin/cmake -E cmake_link_script CMakeFiles/apbs_pmgc.dir/link.txt --verbose=1 /usr/bin/cc -fPIC -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -Wl,-z,relro -Wl,-z,now -Wl,--as-needed -shared -Wl,-soname,libapbs_pmgc.so.3 -o ../../lib/libapbs_pmgc.so.3 CMakeFiles/apbs_pmgc.dir/buildAd.c.o CMakeFiles/apbs_pmgc.dir/buildBd.c.o CMakeFiles/apbs_pmgc.dir/buildGd.c.o CMakeFiles/apbs_pmgc.dir/buildPd.c.o CMakeFiles/apbs_pmgc.dir/cgd.c.o CMakeFiles/apbs_pmgc.dir/gsd.c.o CMakeFiles/apbs_pmgc.dir/matvecd.c.o CMakeFiles/apbs_pmgc.dir/mgcsd.c.o CMakeFiles/apbs_pmgc.dir/mgdrvd.c.o CMakeFiles/apbs_pmgc.dir/mgsubd.c.o CMakeFiles/apbs_pmgc.dir/mikpckd.c.o CMakeFiles/apbs_pmgc.dir/mlinpckd.c.o CMakeFiles/apbs_pmgc.dir/mypdec.c.o CMakeFiles/apbs_pmgc.dir/newtond.c.o CMakeFiles/apbs_pmgc.dir/newdrvd.c.o CMakeFiles/apbs_pmgc.dir/powerd.c.o CMakeFiles/apbs_pmgc.dir/smoothd.c.o CMakeFiles/apbs_pmgc.dir/mgfasd.c.o -lm -lstdc++ /usr/lib/arm-linux-gnueabihf/openmpi/lib/libmpi.so -lmaloc -fopenmp cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/pmgc && /usr/bin/cmake -E cmake_symlink_library ../../lib/libapbs_pmgc.so.3 ../../lib/libapbs_pmgc.so.3 ../../lib/libapbs_pmgc.so make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' [ 45%] Built target apbs_pmgc make -f src/mg/CMakeFiles/apbs_mg.dir/build.make src/mg/CMakeFiles/apbs_mg.dir/depend make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf && /usr/bin/cmake -E cmake_depends "Unix Makefiles" /build/reproducible-path/apbs-3.0.0+dfsg1/apbs /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/mg /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/mg /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/mg/CMakeFiles/apbs_mg.dir/DependInfo.cmake --color= Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/mg/CMakeFiles/apbs_mg.dir/DependInfo.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/mg/CMakeFiles/apbs_mg.dir/depend.internal". Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/mg/CMakeFiles/CMakeDirectoryInformation.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/mg/CMakeFiles/apbs_mg.dir/depend.internal". Scanning dependencies of target apbs_mg make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' make -f src/mg/CMakeFiles/apbs_mg.dir/build.make src/mg/CMakeFiles/apbs_mg.dir/build make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' [ 47%] Building C object src/mg/CMakeFiles/apbs_mg.dir/vopot.c.o [ 47%] Building C object src/mg/CMakeFiles/apbs_mg.dir/vgrid.c.o [ 48%] Building C object src/mg/CMakeFiles/apbs_mg.dir/vmgrid.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/mg && /usr/bin/cc -Dapbs_mg_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_mg.dir/vgrid.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/mg/vgrid.c cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/mg && /usr/bin/cc -Dapbs_mg_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_mg.dir/vopot.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/mg/vopot.c cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/mg && /usr/bin/cc -Dapbs_mg_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_mg.dir/vmgrid.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/mg/vmgrid.c In file included from /usr/include/maloc/maloc.h:38, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/mg/vgrid.h:67, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/mg/vgrid.c:57: /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/mg/vgrid.c: In function 'Vgrid_readDX': /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/mg/vgrid.c:751:31: warning: format '%lu' expects argument of type 'long unsigned int *', but argument 3 has type 'size_t *' {aka 'unsigned int *'} [-Wformat=] 751 | VJMPERR1(1 == sscanf(tok, "%lu", &itmp)); | ^~~~~ ~~~~~ | | | size_t * {aka unsigned int *} /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/mg/vgrid.c:751:34: note: format string is defined here 751 | VJMPERR1(1 == sscanf(tok, "%lu", &itmp)); | ~~^ | | | long unsigned int * | %u /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/mg/vgrid.c: In function 'Vgrid_readDXBIN': /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/mg/vgrid.c:853:3: warning: ignoring return value of 'fgets' declared with attribute 'warn_unused_result' [-Wunused-result] 853 | fgets(tok, VMAX_BUFSIZE, fd); | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~ [ 50%] Building C object src/mg/CMakeFiles/apbs_mg.dir/vpmg.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/mg && /usr/bin/cc -Dapbs_mg_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_mg.dir/vpmg.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/mg/vpmg.c [ 51%] Building C object src/mg/CMakeFiles/apbs_mg.dir/vpmgp.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/mg && /usr/bin/cc -Dapbs_mg_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_mg.dir/vpmgp.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/mg/vpmgp.c [ 52%] Linking C shared library ../../lib/libapbs_mg.so cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/mg && /usr/bin/cmake -E cmake_link_script CMakeFiles/apbs_mg.dir/link.txt --verbose=1 /usr/bin/cc -fPIC -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -Wl,-z,relro -Wl,-z,now -Wl,--as-needed -shared -Wl,-soname,libapbs_mg.so.3 -o ../../lib/libapbs_mg.so.3 CMakeFiles/apbs_mg.dir/vgrid.c.o CMakeFiles/apbs_mg.dir/vmgrid.c.o CMakeFiles/apbs_mg.dir/vopot.c.o CMakeFiles/apbs_mg.dir/vpmg.c.o CMakeFiles/apbs_mg.dir/vpmgp.c.o -lm -lstdc++ /usr/lib/arm-linux-gnueabihf/openmpi/lib/libmpi.so -lmaloc -fopenmp ../../lib/libapbs_generic.so.3 ../../lib/libapbs_pmgc.so.3 -lm -lstdc++ /usr/lib/arm-linux-gnueabihf/openmpi/lib/libmpi.so -lmaloc -fopenmp cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/mg && /usr/bin/cmake -E cmake_symlink_library ../../lib/libapbs_mg.so.3 ../../lib/libapbs_mg.so.3 ../../lib/libapbs_mg.so make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' [ 52%] Built target apbs_mg make -f src/CMakeFiles/apbs_routines.dir/build.make src/CMakeFiles/apbs_routines.dir/depend make -f tools/mesh/CMakeFiles/uhbd_asc2bin.dir/build.make tools/mesh/CMakeFiles/uhbd_asc2bin.dir/depend make -f tools/mesh/CMakeFiles/del2dx.dir/build.make tools/mesh/CMakeFiles/del2dx.dir/depend make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf && /usr/bin/cmake -E cmake_depends "Unix Makefiles" /build/reproducible-path/apbs-3.0.0+dfsg1/apbs /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/CMakeFiles/apbs_routines.dir/DependInfo.cmake --color= make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf && /usr/bin/cmake -E cmake_depends "Unix Makefiles" /build/reproducible-path/apbs-3.0.0+dfsg1/apbs /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/uhbd_asc2bin.dir/DependInfo.cmake --color= make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf && /usr/bin/cmake -E cmake_depends "Unix Makefiles" /build/reproducible-path/apbs-3.0.0+dfsg1/apbs /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/del2dx.dir/DependInfo.cmake --color= Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/del2dx.dir/DependInfo.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/del2dx.dir/depend.internal". Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/CMakeFiles/apbs_routines.dir/DependInfo.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/CMakeFiles/apbs_routines.dir/depend.internal". Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/CMakeFiles/CMakeDirectoryInformation.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/CMakeFiles/apbs_routines.dir/depend.internal". Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/CMakeDirectoryInformation.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/del2dx.dir/depend.internal". Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/uhbd_asc2bin.dir/DependInfo.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/uhbd_asc2bin.dir/depend.internal". Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/CMakeDirectoryInformation.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/uhbd_asc2bin.dir/depend.internal". Scanning dependencies of target del2dx make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' make -f tools/mesh/CMakeFiles/del2dx.dir/build.make tools/mesh/CMakeFiles/del2dx.dir/build Scanning dependencies of target apbs_routines Scanning dependencies of target uhbd_asc2bin make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' make -f src/CMakeFiles/apbs_routines.dir/build.make src/CMakeFiles/apbs_routines.dir/build make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' make -f tools/mesh/CMakeFiles/uhbd_asc2bin.dir/build.make tools/mesh/CMakeFiles/uhbd_asc2bin.dir/build make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' [ 53%] Building C object tools/mesh/CMakeFiles/del2dx.dir/del2dx.c.o [ 55%] Building C object tools/mesh/CMakeFiles/uhbd_asc2bin.dir/uhbd_asc2bin.c.o [ 55%] Building C object src/CMakeFiles/apbs_routines.dir/routines.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh && /usr/bin/cc -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fopenmp -o CMakeFiles/del2dx.dir/del2dx.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/del2dx.c cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src && /usr/bin/cc -Dapbs_routines_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/apbs_routines.dir/routines.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.c cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh && /usr/bin/cc -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fopenmp -o CMakeFiles/uhbd_asc2bin.dir/uhbd_asc2bin.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/uhbd_asc2bin.c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/uhbd_asc2bin.c: In function 'main': /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/uhbd_asc2bin.c:30:5: warning: ignoring return value of 'scanf' declared with attribute 'warn_unused_result' [-Wunused-result] 30 | scanf("%s", flnm); | ^~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/uhbd_asc2bin.c:42:5: warning: ignoring return value of 'scanf' declared with attribute 'warn_unused_result' [-Wunused-result] 42 | scanf("%s", newfile); | ^~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/uhbd_asc2bin.c:54:5: warning: ignoring return value of 'fscanf' declared with attribute 'warn_unused_result' [-Wunused-result] 54 | fscanf(inFile, "%s", title); | ^~~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/uhbd_asc2bin.c:57:5: warning: ignoring return value of 'fscanf' declared with attribute 'warn_unused_result' [-Wunused-result] 57 | fscanf(inFile, "%lf", &scale); | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/uhbd_asc2bin.c:60:5: warning: ignoring return value of 'fscanf' declared with attribute 'warn_unused_result' [-Wunused-result] 60 | fscanf(inFile, "%lf", &dum2); | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/uhbd_asc2bin.c:63:5: warning: ignoring return value of 'fscanf' declared with attribute 'warn_unused_result' [-Wunused-result] 63 | fscanf(inFile, "%d", &grdflg); | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/uhbd_asc2bin.c:66:5: warning: ignoring return value of 'fscanf' declared with attribute 'warn_unused_result' [-Wunused-result] 66 | fscanf(inFile, "%d", &idum2); | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/uhbd_asc2bin.c:69:5: warning: ignoring return value of 'fscanf' declared with attribute 'warn_unused_result' [-Wunused-result] 69 | fscanf(inFile, "%d", &km); | ^~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/uhbd_asc2bin.c:72:5: warning: ignoring return value of 'fscanf' declared with attribute 'warn_unused_result' [-Wunused-result] 72 | fscanf(inFile, "%d", &one); | ^~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/uhbd_asc2bin.c:75:5: warning: ignoring return value of 'fscanf' declared with attribute 'warn_unused_result' [-Wunused-result] 75 | fscanf(inFile, "%d", &km); | ^~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/uhbd_asc2bin.c:78:5: warning: ignoring return value of 'fscanf' declared with attribute 'warn_unused_result' [-Wunused-result] 78 | fscanf(inFile, "%d", &im); | ^~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/uhbd_asc2bin.c:81:5: warning: ignoring return value of 'fscanf' declared with attribute 'warn_unused_result' [-Wunused-result] 81 | fscanf(inFile, "%d", &jm); | ^~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/uhbd_asc2bin.c:84:5: warning: ignoring return value of 'fscanf' declared with attribute 'warn_unused_result' [-Wunused-result] 84 | fscanf(inFile, "%d", &km); | ^~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/uhbd_asc2bin.c:87:5: warning: ignoring return value of 'fscanf' declared with attribute 'warn_unused_result' [-Wunused-result] 87 | fscanf(inFile, "%lf", &h); | ^~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/uhbd_asc2bin.c:90:5: warning: ignoring return value of 'fscanf' declared with attribute 'warn_unused_result' [-Wunused-result] 90 | fscanf(inFile, "%lf", &ox); | ^~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/uhbd_asc2bin.c:93:5: warning: ignoring return value of 'fscanf' declared with attribute 'warn_unused_result' [-Wunused-result] 93 | fscanf(inFile, "%lf", &oy); | ^~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/uhbd_asc2bin.c:96:5: warning: ignoring return value of 'fscanf' declared with attribute 'warn_unused_result' [-Wunused-result] 96 | fscanf(inFile, "%lf", &oz); | ^~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/uhbd_asc2bin.c:99:5: warning: ignoring return value of 'fscanf' declared with attribute 'warn_unused_result' [-Wunused-result] 99 | fscanf(inFile, "%lf", &dum3); | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/uhbd_asc2bin.c:102:5: warning: ignoring return value of 'fscanf' declared with attribute 'warn_unused_result' [-Wunused-result] 102 | fscanf(inFile, "%lf", &dum4); | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/uhbd_asc2bin.c:105:5: warning: ignoring return value of 'fscanf' declared with attribute 'warn_unused_result' [-Wunused-result] 105 | fscanf(inFile, "%lf", &dum5); | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/uhbd_asc2bin.c:108:5: warning: ignoring return value of 'fscanf' declared with attribute 'warn_unused_result' [-Wunused-result] 108 | fscanf(inFile, "%lf", &dum6); | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/uhbd_asc2bin.c:111:5: warning: ignoring return value of 'fscanf' declared with attribute 'warn_unused_result' [-Wunused-result] 111 | fscanf(inFile, "%lf", &dum7); | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/uhbd_asc2bin.c:114:5: warning: ignoring return value of 'fscanf' declared with attribute 'warn_unused_result' [-Wunused-result] 114 | fscanf(inFile, "%lf", &dum8); | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/uhbd_asc2bin.c:117:5: warning: ignoring return value of 'fscanf' declared with attribute 'warn_unused_result' [-Wunused-result] 117 | fscanf(inFile, "%d", &idum3); | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/uhbd_asc2bin.c:120:5: warning: ignoring return value of 'fscanf' declared with attribute 'warn_unused_result' [-Wunused-result] 120 | fscanf(inFile, "%d", &idum4); | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/uhbd_asc2bin.c:125:9: warning: ignoring return value of 'fscanf' declared with attribute 'warn_unused_result' [-Wunused-result] 125 | fscanf(inFile, "%d", &kk); | ^~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/uhbd_asc2bin.c:128:9: warning: ignoring return value of 'fscanf' declared with attribute 'warn_unused_result' [-Wunused-result] 128 | fscanf(inFile, "%d", &im); | ^~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/uhbd_asc2bin.c:131:9: warning: ignoring return value of 'fscanf' declared with attribute 'warn_unused_result' [-Wunused-result] 131 | fscanf(inFile, "%d", &jm); | ^~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/uhbd_asc2bin.c:138:17: warning: ignoring return value of 'fscanf' declared with attribute 'warn_unused_result' [-Wunused-result] 138 | fscanf(inFile, "%lf", RAT3(grid, i, j, k)); | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/del2dx.c: In function 'main': /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/del2dx.c:76:2: warning: ignoring return value of 'fread' declared with attribute 'warn_unused_result' [-Wunused-result] 76 | fread(&igrid, 1, sizeof(int), pfile); | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/del2dx.c:89:2: warning: ignoring return value of 'fread' declared with attribute 'warn_unused_result' [-Wunused-result] 89 | fread(buffer, 1, sizeof(char) * 10, pfile); | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/del2dx.c:97:2: warning: ignoring return value of 'fread' declared with attribute 'warn_unused_result' [-Wunused-result] 97 | fread(data, tot_grid, sizeof(float), pfile); | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/del2dx.c:103:2: warning: ignoring return value of 'fread' declared with attribute 'warn_unused_result' [-Wunused-result] 103 | fread(&scale, 1, sizeof(float), pfile); | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/del2dx.c:106:2: warning: ignoring return value of 'fread' declared with attribute 'warn_unused_result' [-Wunused-result] 106 | fread(oldmid, 3, sizeof(float), pfile); | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ [ 56%] Linking C executable ../bin/uhbd_asc2bin cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh && /usr/bin/cmake -E cmake_link_script CMakeFiles/uhbd_asc2bin.dir/link.txt --verbose=1 /usr/bin/cc -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -Wl,-z,relro -Wl,-z,now -Wl,--as-needed -Wl,--no-as-needed CMakeFiles/uhbd_asc2bin.dir/uhbd_asc2bin.c.o -o ../bin/uhbd_asc2bin ../../lib/libapbs_mg.so.3 ../../lib/libapbs_pmgc.so.3 ../../lib/libapbs_generic.so.3 -lm -lstdc++ /usr/lib/arm-linux-gnueabihf/openmpi/lib/libmpi.so -lmaloc -fopenmp [ 58%] Linking C executable ../bin/del2dx cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh && /usr/bin/cmake -E cmake_link_script CMakeFiles/del2dx.dir/link.txt --verbose=1 /usr/bin/cc -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -Wl,-z,relro -Wl,-z,now -Wl,--as-needed -Wl,--no-as-needed CMakeFiles/del2dx.dir/del2dx.c.o -o ../bin/del2dx ../../lib/libapbs_mg.so.3 ../../lib/libapbs_pmgc.so.3 ../../lib/libapbs_generic.so.3 -lm -lstdc++ /usr/lib/arm-linux-gnueabihf/openmpi/lib/libmpi.so -lmaloc -fopenmp make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' [ 58%] Built target uhbd_asc2bin make -f tools/mesh/CMakeFiles/smooth.dir/build.make tools/mesh/CMakeFiles/smooth.dir/depend make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf && /usr/bin/cmake -E cmake_depends "Unix Makefiles" /build/reproducible-path/apbs-3.0.0+dfsg1/apbs /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/smooth.dir/DependInfo.cmake --color= [ 58%] Built target del2dx make -f tools/mesh/CMakeFiles/dxmath.dir/build.make tools/mesh/CMakeFiles/dxmath.dir/depend make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf && /usr/bin/cmake -E cmake_depends "Unix Makefiles" /build/reproducible-path/apbs-3.0.0+dfsg1/apbs /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/dxmath.dir/DependInfo.cmake --color= Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/smooth.dir/DependInfo.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/smooth.dir/depend.internal". Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/CMakeDirectoryInformation.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/smooth.dir/depend.internal". Scanning dependencies of target smooth make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' make -f tools/mesh/CMakeFiles/smooth.dir/build.make tools/mesh/CMakeFiles/smooth.dir/build make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/dxmath.dir/DependInfo.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/dxmath.dir/depend.internal". Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/CMakeDirectoryInformation.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/dxmath.dir/depend.internal". Scanning dependencies of target dxmath make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' make -f tools/mesh/CMakeFiles/dxmath.dir/build.make tools/mesh/CMakeFiles/dxmath.dir/build make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' [ 59%] Building C object tools/mesh/CMakeFiles/smooth.dir/smooth.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh && /usr/bin/cc -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fopenmp -o CMakeFiles/smooth.dir/smooth.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/smooth.c [ 60%] Building C object tools/mesh/CMakeFiles/dxmath.dir/dxmath.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh && /usr/bin/cc -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fopenmp -o CMakeFiles/dxmath.dir/dxmath.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/dxmath.c [ 61%] Linking C executable ../bin/smooth cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh && /usr/bin/cmake -E cmake_link_script CMakeFiles/smooth.dir/link.txt --verbose=1 [ 62%] Linking C executable ../bin/dxmath cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh && /usr/bin/cmake -E cmake_link_script CMakeFiles/dxmath.dir/link.txt --verbose=1 /usr/bin/cc -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -Wl,-z,relro -Wl,-z,now -Wl,--as-needed -Wl,--no-as-needed CMakeFiles/smooth.dir/smooth.c.o -o ../bin/smooth ../../lib/libapbs_mg.so.3 ../../lib/libapbs_pmgc.so.3 ../../lib/libapbs_generic.so.3 -lm -lstdc++ /usr/lib/arm-linux-gnueabihf/openmpi/lib/libmpi.so -lmaloc -fopenmp /usr/bin/cc -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -Wl,-z,relro -Wl,-z,now -Wl,--as-needed -Wl,--no-as-needed CMakeFiles/dxmath.dir/dxmath.c.o -o ../bin/dxmath ../../lib/libapbs_mg.so.3 ../../lib/libapbs_pmgc.so.3 ../../lib/libapbs_generic.so.3 -lm -lstdc++ /usr/lib/arm-linux-gnueabihf/openmpi/lib/libmpi.so -lmaloc -fopenmp make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' [ 62%] Built target smooth make -f tools/mesh/CMakeFiles/mgmesh.dir/build.make tools/mesh/CMakeFiles/mgmesh.dir/depend make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf && /usr/bin/cmake -E cmake_depends "Unix Makefiles" /build/reproducible-path/apbs-3.0.0+dfsg1/apbs /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/mgmesh.dir/DependInfo.cmake --color= [ 62%] Built target dxmath make -f tools/mesh/CMakeFiles/mergedx2.dir/build.make tools/mesh/CMakeFiles/mergedx2.dir/depend make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf && /usr/bin/cmake -E cmake_depends "Unix Makefiles" /build/reproducible-path/apbs-3.0.0+dfsg1/apbs /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/mergedx2.dir/DependInfo.cmake --color= Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/mgmesh.dir/DependInfo.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/mgmesh.dir/depend.internal". Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/CMakeDirectoryInformation.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/mgmesh.dir/depend.internal". Scanning dependencies of target mgmesh make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' make -f tools/mesh/CMakeFiles/mgmesh.dir/build.make tools/mesh/CMakeFiles/mgmesh.dir/build make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/mergedx2.dir/DependInfo.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/mergedx2.dir/depend.internal". Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/CMakeDirectoryInformation.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/mergedx2.dir/depend.internal". Scanning dependencies of target mergedx2 /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.c: In function 'writematMG': make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.c:1840:30: warning: '%s' directive writing 3 bytes into a region of size between 0 and 1023 [-Wformat-overflow=] 1840 | sprintf(outpath, "%s.%s", writematstem, "mat"); | ^~ ~~~~~ In file included from /usr/include/stdio.h:867, from /usr/include/maloc/maloc_base.h:80, from /usr/include/maloc/maloc.h:38, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/apbs.h:67, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.h:64, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.c:54: /usr/include/arm-linux-gnueabihf/bits/stdio2.h:36:10: note: '__builtin___sprintf_chk' output between 5 and 1028 bytes into a destination of size 1024 36 | return __builtin___sprintf_chk (__s, __USE_FORTIFY_LEVEL - 1, | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ 37 | __bos (__s), __fmt, __va_arg_pack ()); | ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ make -f tools/mesh/CMakeFiles/mergedx2.dir/build.make tools/mesh/CMakeFiles/mergedx2.dir/build make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' [ 63%] Building C object tools/mesh/CMakeFiles/mgmesh.dir/mgmesh.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh && /usr/bin/cc -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fopenmp -o CMakeFiles/mgmesh.dir/mgmesh.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/mgmesh.c [ 65%] Building C object tools/mesh/CMakeFiles/mergedx2.dir/mergedx2.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh && /usr/bin/cc -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fopenmp -o CMakeFiles/mergedx2.dir/mergedx2.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/mergedx2.c [ 66%] Linking C executable ../bin/mgmesh cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh && /usr/bin/cmake -E cmake_link_script CMakeFiles/mgmesh.dir/link.txt --verbose=1 /usr/bin/cc -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -Wl,-z,relro -Wl,-z,now -Wl,--as-needed -Wl,--no-as-needed CMakeFiles/mgmesh.dir/mgmesh.c.o -o ../bin/mgmesh ../../lib/libapbs_mg.so.3 ../../lib/libapbs_pmgc.so.3 ../../lib/libapbs_generic.so.3 -lm -lstdc++ /usr/lib/arm-linux-gnueabihf/openmpi/lib/libmpi.so -lmaloc -fopenmp make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' [ 66%] Built target mgmesh make -f tools/mesh/CMakeFiles/multivalue.dir/build.make tools/mesh/CMakeFiles/multivalue.dir/depend make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf && /usr/bin/cmake -E cmake_depends "Unix Makefiles" /build/reproducible-path/apbs-3.0.0+dfsg1/apbs /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/multivalue.dir/DependInfo.cmake --color= /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.c: In function 'writedataMG': /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.c:2676:30: warning: '%s' directive writing 5 bytes into a region of size between 0 and 1023 [-Wformat-overflow=] 2676 | sprintf(outpath, "%s.%s", writestem, "dxbin"); | ^~ ~~~~~~~ In file included from /usr/include/stdio.h:867, from /usr/include/maloc/maloc_base.h:80, from /usr/include/maloc/maloc.h:38, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/apbs.h:67, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.h:64, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.c:54: /usr/include/arm-linux-gnueabihf/bits/stdio2.h:36:10: note: '__builtin___sprintf_chk' output between 7 and 1030 bytes into a destination of size 1024 36 | return __builtin___sprintf_chk (__s, __USE_FORTIFY_LEVEL - 1, | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ 37 | __bos (__s), __fmt, __va_arg_pack ()); | ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.c:2720:38: warning: '%s' directive writing 3 bytes into a region of size between 0 and 1023 [-Wformat-overflow=] 2720 | sprintf(outpath, "%s.%s", writestem, "txt"); | ^~ ~~~~~ In file included from /usr/include/stdio.h:867, from /usr/include/maloc/maloc_base.h:80, from /usr/include/maloc/maloc.h:38, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/apbs.h:67, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.h:64, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.c:54: /usr/include/arm-linux-gnueabihf/bits/stdio2.h:36:10: note: '__builtin___sprintf_chk' output between 5 and 1028 bytes into a destination of size 1024 36 | return __builtin___sprintf_chk (__s, __USE_FORTIFY_LEVEL - 1, | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ 37 | __bos (__s), __fmt, __va_arg_pack ()); | ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.c:2711:38: warning: '%s' directive writing 5 bytes into a region of size between 0 and 1023 [-Wformat-overflow=] 2711 | sprintf(outpath, "%s.%s", writestem, "dx.gz"); | ^~ ~~~~~~~ In file included from /usr/include/stdio.h:867, from /usr/include/maloc/maloc_base.h:80, from /usr/include/maloc/maloc.h:38, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/apbs.h:67, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.h:64, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.c:54: /usr/include/arm-linux-gnueabihf/bits/stdio2.h:36:10: note: '__builtin___sprintf_chk' output between 7 and 1030 bytes into a destination of size 1024 36 | return __builtin___sprintf_chk (__s, __USE_FORTIFY_LEVEL - 1, | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ 37 | __bos (__s), __fmt, __va_arg_pack ()); | ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.c:2694:38: warning: '%s' directive writing 4 bytes into a region of size between 0 and 1023 [-Wformat-overflow=] 2694 | sprintf(outpath, "%s.%s", writestem, "mcsf"); | ^~ ~~~~~~ In file included from /usr/include/stdio.h:867, from /usr/include/maloc/maloc_base.h:80, from /usr/include/maloc/maloc.h:38, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/apbs.h:67, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.h:64, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.c:54: /usr/include/arm-linux-gnueabihf/bits/stdio2.h:36:10: note: '__builtin___sprintf_chk' output between 6 and 1029 bytes into a destination of size 1024 36 | return __builtin___sprintf_chk (__s, __USE_FORTIFY_LEVEL - 1, | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ 37 | __bos (__s), __fmt, __va_arg_pack ()); | ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.c:2687:38: warning: '%s' directive writing 3 bytes into a region of size between 0 and 1023 [-Wformat-overflow=] 2687 | sprintf(outpath, "%s.%s", writestem, "ucd"); | ^~ ~~~~~ In file included from /usr/include/stdio.h:867, from /usr/include/maloc/maloc_base.h:80, from /usr/include/maloc/maloc.h:38, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/apbs.h:67, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.h:64, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.c:54: /usr/include/arm-linux-gnueabihf/bits/stdio2.h:36:10: note: '__builtin___sprintf_chk' output between 5 and 1028 bytes into a destination of size 1024 36 | return __builtin___sprintf_chk (__s, __USE_FORTIFY_LEVEL - 1, | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ 37 | __bos (__s), __fmt, __va_arg_pack ()); | ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.c:2701:38: warning: '%s' directive writing 3 bytes into a region of size between 0 and 1023 [-Wformat-overflow=] 2701 | sprintf(outpath, "%s.%s", writestem, "grd"); | ^~ ~~~~~ In file included from /usr/include/stdio.h:867, from /usr/include/maloc/maloc_base.h:80, from /usr/include/maloc/maloc.h:38, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/apbs.h:67, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.h:64, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.c:54: /usr/include/arm-linux-gnueabihf/bits/stdio2.h:36:10: note: '__builtin___sprintf_chk' output between 5 and 1028 bytes into a destination of size 1024 36 | return __builtin___sprintf_chk (__s, __USE_FORTIFY_LEVEL - 1, | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ 37 | __bos (__s), __fmt, __va_arg_pack ()); | ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.c:2666:38: warning: '%s' directive writing 2 bytes into a region of size between 0 and 1023 [-Wformat-overflow=] 2666 | sprintf(outpath, "%s.%s", writestem, "dx"); | ^~ ~~~~ In file included from /usr/include/stdio.h:867, from /usr/include/maloc/maloc_base.h:80, from /usr/include/maloc/maloc.h:38, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/apbs.h:67, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.h:64, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.c:54: /usr/include/arm-linux-gnueabihf/bits/stdio2.h:36:10: note: '__builtin___sprintf_chk' output between 4 and 1027 bytes into a destination of size 1024 36 | return __builtin___sprintf_chk (__s, __USE_FORTIFY_LEVEL - 1, | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ 37 | __bos (__s), __fmt, __va_arg_pack ()); | ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/multivalue.dir/DependInfo.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/multivalue.dir/depend.internal". 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Scanning dependencies of target multivalue make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' make -f tools/mesh/CMakeFiles/multivalue.dir/build.make tools/mesh/CMakeFiles/multivalue.dir/build make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' [ 67%] Building C object tools/mesh/CMakeFiles/multivalue.dir/multivalue.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh && /usr/bin/cc -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fopenmp -o CMakeFiles/multivalue.dir/multivalue.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/multivalue.c [ 68%] Linking C executable ../bin/multivalue cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh && /usr/bin/cmake -E cmake_link_script CMakeFiles/multivalue.dir/link.txt --verbose=1 /usr/bin/cc -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -Wl,-z,relro -Wl,-z,now -Wl,--as-needed -Wl,--no-as-needed CMakeFiles/multivalue.dir/multivalue.c.o -o ../bin/multivalue ../../lib/libapbs_mg.so.3 ../../lib/libapbs_pmgc.so.3 ../../lib/libapbs_generic.so.3 -lm -lstdc++ /usr/lib/arm-linux-gnueabihf/openmpi/lib/libmpi.so -lmaloc -fopenmp [ 69%] Linking C executable ../bin/mergedx2 cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh && /usr/bin/cmake -E cmake_link_script CMakeFiles/mergedx2.dir/link.txt --verbose=1 /usr/bin/cc -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -Wl,-z,relro -Wl,-z,now -Wl,--as-needed -Wl,--no-as-needed CMakeFiles/mergedx2.dir/mergedx2.c.o -o ../bin/mergedx2 ../../lib/libapbs_mg.so.3 ../../lib/libapbs_pmgc.so.3 ../../lib/libapbs_generic.so.3 -lm -lstdc++ /usr/lib/arm-linux-gnueabihf/openmpi/lib/libmpi.so -lmaloc -fopenmp make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' [ 69%] Built target multivalue make -f tools/mesh/CMakeFiles/value.dir/build.make tools/mesh/CMakeFiles/value.dir/depend make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf && /usr/bin/cmake -E cmake_depends "Unix Makefiles" /build/reproducible-path/apbs-3.0.0+dfsg1/apbs /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/value.dir/DependInfo.cmake --color= Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/value.dir/DependInfo.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/value.dir/depend.internal". Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/CMakeDirectoryInformation.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/value.dir/depend.internal". Scanning dependencies of target value make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' make -f tools/mesh/CMakeFiles/value.dir/build.make tools/mesh/CMakeFiles/value.dir/build make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' [ 70%] Building C object tools/mesh/CMakeFiles/value.dir/value.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh && /usr/bin/cc -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fopenmp -o CMakeFiles/value.dir/value.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/value.c [ 70%] Built target mergedx2 make -f tools/mesh/CMakeFiles/similarity.dir/build.make tools/mesh/CMakeFiles/similarity.dir/depend make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf && /usr/bin/cmake -E cmake_depends "Unix Makefiles" /build/reproducible-path/apbs-3.0.0+dfsg1/apbs /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/similarity.dir/DependInfo.cmake --color= Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/similarity.dir/DependInfo.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/similarity.dir/depend.internal". 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Scanning dependencies of target similarity make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' make -f tools/mesh/CMakeFiles/similarity.dir/build.make tools/mesh/CMakeFiles/similarity.dir/build make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' [ 72%] Building C object tools/mesh/CMakeFiles/similarity.dir/similarity.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh && /usr/bin/cc -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fopenmp -o CMakeFiles/similarity.dir/similarity.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/similarity.c [ 73%] Linking C executable ../bin/value cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh && /usr/bin/cmake -E cmake_link_script CMakeFiles/value.dir/link.txt --verbose=1 /usr/bin/cc -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -Wl,-z,relro -Wl,-z,now -Wl,--as-needed -Wl,--no-as-needed CMakeFiles/value.dir/value.c.o -o ../bin/value ../../lib/libapbs_mg.so.3 ../../lib/libapbs_pmgc.so.3 ../../lib/libapbs_generic.so.3 -lm -lstdc++ /usr/lib/arm-linux-gnueabihf/openmpi/lib/libmpi.so -lmaloc -fopenmp make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' [ 73%] Built target value make -f tools/mesh/CMakeFiles/analysis.dir/build.make tools/mesh/CMakeFiles/analysis.dir/depend make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf && /usr/bin/cmake -E cmake_depends "Unix Makefiles" /build/reproducible-path/apbs-3.0.0+dfsg1/apbs /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/analysis.dir/DependInfo.cmake --color= Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/analysis.dir/DependInfo.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/analysis.dir/depend.internal". Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/CMakeDirectoryInformation.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/analysis.dir/depend.internal". Scanning dependencies of target analysis make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' make -f tools/mesh/CMakeFiles/analysis.dir/build.make tools/mesh/CMakeFiles/analysis.dir/build make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' [ 74%] Building C object tools/mesh/CMakeFiles/analysis.dir/analysis.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh && /usr/bin/cc -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fopenmp -o CMakeFiles/analysis.dir/analysis.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/analysis.c [ 75%] Linking C executable ../bin/similarity cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh && /usr/bin/cmake -E cmake_link_script CMakeFiles/similarity.dir/link.txt --verbose=1 /usr/bin/cc -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -Wl,-z,relro -Wl,-z,now -Wl,--as-needed -Wl,--no-as-needed CMakeFiles/similarity.dir/similarity.c.o -o ../bin/similarity ../../lib/libapbs_mg.so.3 ../../lib/libapbs_pmgc.so.3 ../../lib/libapbs_generic.so.3 -lm -lstdc++ /usr/lib/arm-linux-gnueabihf/openmpi/lib/libmpi.so -lmaloc -fopenmp [ 76%] Linking C executable ../bin/analysis cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh && /usr/bin/cmake -E cmake_link_script CMakeFiles/analysis.dir/link.txt --verbose=1 /usr/bin/cc -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -Wl,-z,relro -Wl,-z,now -Wl,--as-needed -Wl,--no-as-needed CMakeFiles/analysis.dir/analysis.c.o -o ../bin/analysis ../../lib/libapbs_mg.so.3 ../../lib/libapbs_pmgc.so.3 ../../lib/libapbs_generic.so.3 -lm -lstdc++ /usr/lib/arm-linux-gnueabihf/openmpi/lib/libmpi.so -lmaloc -fopenmp [ 77%] Linking C shared library ../lib/libapbs_routines.so cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src && /usr/bin/cmake -E cmake_link_script CMakeFiles/apbs_routines.dir/link.txt --verbose=1 /usr/bin/cc -fPIC -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -Wl,-z,relro -Wl,-z,now -Wl,--as-needed -shared -Wl,-soname,libapbs_routines.so.3 -o ../lib/libapbs_routines.so.3 CMakeFiles/apbs_routines.dir/routines.c.o -lm -lstdc++ /usr/lib/arm-linux-gnueabihf/openmpi/lib/libmpi.so -lmaloc -fopenmp ../lib/libapbs_mg.so.3 ../lib/libapbs_generic.so.3 ../lib/libapbs_pmgc.so.3 -lm -lstdc++ /usr/lib/arm-linux-gnueabihf/openmpi/lib/libmpi.so -lmaloc -fopenmp make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' [ 77%] Built target similarity make -f tools/mesh/CMakeFiles/tensor2dx.dir/build.make tools/mesh/CMakeFiles/tensor2dx.dir/depend make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf && /usr/bin/cmake -E cmake_depends "Unix Makefiles" /build/reproducible-path/apbs-3.0.0+dfsg1/apbs /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/tensor2dx.dir/DependInfo.cmake --color= Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/tensor2dx.dir/DependInfo.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/tensor2dx.dir/depend.internal". Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/CMakeDirectoryInformation.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/tensor2dx.dir/depend.internal". Scanning dependencies of target tensor2dx make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' make -f tools/mesh/CMakeFiles/tensor2dx.dir/build.make tools/mesh/CMakeFiles/tensor2dx.dir/build make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src && /usr/bin/cmake -E cmake_symlink_library ../lib/libapbs_routines.so.3 ../lib/libapbs_routines.so.3 ../lib/libapbs_routines.so [ 79%] Building C object tools/mesh/CMakeFiles/tensor2dx.dir/tensor2dx.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh && /usr/bin/cc -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fopenmp -o CMakeFiles/tensor2dx.dir/tensor2dx.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/tensor2dx.c make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' [ 79%] Built target apbs_routines [ 79%] Built target analysis make -f tools/mesh/CMakeFiles/benchmark.dir/build.make tools/mesh/CMakeFiles/benchmark.dir/depend make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' make -f tools/mesh/CMakeFiles/dx2mol.dir/build.make tools/mesh/CMakeFiles/dx2mol.dir/depend cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf && /usr/bin/cmake -E cmake_depends "Unix Makefiles" /build/reproducible-path/apbs-3.0.0+dfsg1/apbs /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/benchmark.dir/DependInfo.cmake --color= make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf && /usr/bin/cmake -E cmake_depends "Unix Makefiles" /build/reproducible-path/apbs-3.0.0+dfsg1/apbs /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/dx2mol.dir/DependInfo.cmake --color= Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/benchmark.dir/DependInfo.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/benchmark.dir/depend.internal". Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/CMakeDirectoryInformation.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/benchmark.dir/depend.internal". Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/dx2mol.dir/DependInfo.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/dx2mol.dir/depend.internal". Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/CMakeDirectoryInformation.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/dx2mol.dir/depend.internal". Scanning dependencies of target benchmark make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' make -f tools/mesh/CMakeFiles/benchmark.dir/build.make tools/mesh/CMakeFiles/benchmark.dir/build Scanning dependencies of target dx2mol make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' make -f tools/mesh/CMakeFiles/dx2mol.dir/build.make tools/mesh/CMakeFiles/dx2mol.dir/build make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' [ 80%] Building C object tools/mesh/CMakeFiles/benchmark.dir/benchmark.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh && /usr/bin/cc -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fopenmp -o CMakeFiles/benchmark.dir/benchmark.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/benchmark.c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/tensor2dx.c: In function 'main': /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/tensor2dx.c:97:2: warning: ignoring return value of 'fscanf' declared with attribute 'warn_unused_result' [-Wunused-result] 97 | fscanf(pfile1,"%lf %lf %lf",&origin_xyz[0],&origin_xyz[1],&origin_xyz[2]); | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/tensor2dx.c:98:2: warning: ignoring return value of 'fscanf' declared with attribute 'warn_unused_result' [-Wunused-result] 98 | fscanf(pfile1,"%lf %lf %lf",&gspace[0],&gspace[1],&gspace[2]); | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/tensor2dx.c:137:7: warning: ignoring return value of 'fscanf' declared with attribute 'warn_unused_result' [-Wunused-result] 137 | fscanf(pfile2,"%i %i %i",&itmp[0],&itmp[1],&itmp[2]); | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ [ 81%] Building C object tools/mesh/CMakeFiles/dx2mol.dir/dx2mol.c.o /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/tensor2dx.c:138:3: warning: ignoring return value of 'fscanf' declared with attribute 'warn_unused_result' [-Wunused-result] 138 | fscanf(pfile2,"%lf %lf %lf",&datapt[0],&tmp[1],&tmp[2]); | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/tensor2dx.c:139:3: warning: ignoring return value of 'fscanf' declared with attribute 'warn_unused_result' [-Wunused-result] 139 | fscanf(pfile2,"%lf %lf %lf",&tmp[0],&datapt[1],&tmp[2]); | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/tensor2dx.c:140:3: warning: ignoring return value of 'fscanf' declared with attribute 'warn_unused_result' [-Wunused-result] 140 | fscanf(pfile2,"%lf %lf %lf",&tmp[0],&tmp[1],&datapt[2]); | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/tensor2dx.c:155:7: warning: ignoring return value of 'fscanf' declared with attribute 'warn_unused_result' [-Wunused-result] 155 | fscanf(pfile2,"%i %i %i",&itmp[0],&itmp[1],&itmp[2]); | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/tensor2dx.c:156:3: warning: ignoring return value of 'fscanf' declared with attribute 'warn_unused_result' [-Wunused-result] 156 | fscanf(pfile2,"%lf %lf %lf",&datapt[0],&tmp[1],&tmp[2]); | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/tensor2dx.c:157:3: warning: ignoring return value of 'fscanf' declared with attribute 'warn_unused_result' [-Wunused-result] 157 | fscanf(pfile2,"%lf %lf %lf",&tmp[0],&datapt[1],&tmp[2]); | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/tensor2dx.c:158:3: warning: ignoring return value of 'fscanf' declared with attribute 'warn_unused_result' [-Wunused-result] 158 | fscanf(pfile2,"%lf %lf %lf",&tmp[0],&tmp[1],&datapt[2]); | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh && /usr/bin/cc -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fopenmp -o CMakeFiles/dx2mol.dir/dx2mol.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/dx2mol.c [ 82%] Linking C executable ../bin/tensor2dx cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh && /usr/bin/cmake -E cmake_link_script CMakeFiles/tensor2dx.dir/link.txt --verbose=1 /usr/bin/cc -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -Wl,-z,relro -Wl,-z,now -Wl,--as-needed -Wl,--no-as-needed CMakeFiles/tensor2dx.dir/tensor2dx.c.o -o ../bin/tensor2dx ../../lib/libapbs_mg.so.3 ../../lib/libapbs_pmgc.so.3 ../../lib/libapbs_generic.so.3 -lm -lstdc++ /usr/lib/arm-linux-gnueabihf/openmpi/lib/libmpi.so -lmaloc -fopenmp [ 83%] Linking C executable ../bin/dx2mol cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh && /usr/bin/cmake -E cmake_link_script CMakeFiles/dx2mol.dir/link.txt --verbose=1 /usr/bin/cc -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -Wl,-z,relro -Wl,-z,now -Wl,--as-needed -Wl,--no-as-needed CMakeFiles/dx2mol.dir/dx2mol.c.o -o ../bin/dx2mol ../../lib/libapbs_mg.so.3 ../../lib/libapbs_pmgc.so.3 ../../lib/libapbs_generic.so.3 -lm -lstdc++ /usr/lib/arm-linux-gnueabihf/openmpi/lib/libmpi.so -lmaloc -fopenmp [ 84%] Linking C executable ../bin/benchmark cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh && /usr/bin/cmake -E cmake_link_script CMakeFiles/benchmark.dir/link.txt --verbose=1 /usr/bin/cc -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -Wl,-z,relro -Wl,-z,now -Wl,--as-needed -Wl,--no-as-needed CMakeFiles/benchmark.dir/benchmark.c.o -o ../bin/benchmark ../../lib/libapbs_mg.so.3 ../../lib/libapbs_pmgc.so.3 ../../lib/libapbs_generic.so.3 -lm -lstdc++ /usr/lib/arm-linux-gnueabihf/openmpi/lib/libmpi.so -lmaloc -fopenmp make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' [ 84%] Built target tensor2dx make -f tools/mesh/CMakeFiles/mergedx.dir/build.make tools/mesh/CMakeFiles/mergedx.dir/depend make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf && /usr/bin/cmake -E cmake_depends "Unix Makefiles" /build/reproducible-path/apbs-3.0.0+dfsg1/apbs /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/mergedx.dir/DependInfo.cmake --color= Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/mergedx.dir/DependInfo.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/mergedx.dir/depend.internal". Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/CMakeDirectoryInformation.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/mergedx.dir/depend.internal". Scanning dependencies of target mergedx make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' make -f tools/mesh/CMakeFiles/mergedx.dir/build.make tools/mesh/CMakeFiles/mergedx.dir/build make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' [ 86%] Building C object tools/mesh/CMakeFiles/mergedx.dir/mergedx.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh && /usr/bin/cc -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fopenmp -o CMakeFiles/mergedx.dir/mergedx.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/mergedx.c [ 86%] Built target dx2mol make -f tools/mesh/CMakeFiles/dx2uhbd.dir/build.make tools/mesh/CMakeFiles/dx2uhbd.dir/depend make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf && /usr/bin/cmake -E cmake_depends "Unix Makefiles" /build/reproducible-path/apbs-3.0.0+dfsg1/apbs /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/dx2uhbd.dir/DependInfo.cmake --color= make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/dx2uhbd.dir/DependInfo.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/dx2uhbd.dir/depend.internal". Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/CMakeDirectoryInformation.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh/CMakeFiles/dx2uhbd.dir/depend.internal". [ 86%] Built target benchmark make -f tools/manip/CMakeFiles/born.dir/build.make tools/manip/CMakeFiles/born.dir/depend make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf && /usr/bin/cmake -E cmake_depends "Unix Makefiles" /build/reproducible-path/apbs-3.0.0+dfsg1/apbs /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/manip /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/manip /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/manip/CMakeFiles/born.dir/DependInfo.cmake --color= Scanning dependencies of target dx2uhbd make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' make -f tools/mesh/CMakeFiles/dx2uhbd.dir/build.make tools/mesh/CMakeFiles/dx2uhbd.dir/build make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/manip/CMakeFiles/born.dir/DependInfo.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/manip/CMakeFiles/born.dir/depend.internal". Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/manip/CMakeFiles/CMakeDirectoryInformation.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/manip/CMakeFiles/born.dir/depend.internal". [ 87%] Building C object tools/mesh/CMakeFiles/dx2uhbd.dir/dx2uhbd.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh && /usr/bin/cc -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fopenmp -o CMakeFiles/dx2uhbd.dir/dx2uhbd.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/mesh/dx2uhbd.c Scanning dependencies of target born make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' make -f tools/manip/CMakeFiles/born.dir/build.make tools/manip/CMakeFiles/born.dir/build make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' [ 88%] Building C object tools/manip/CMakeFiles/born.dir/born.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/manip && /usr/bin/cc -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fopenmp -o CMakeFiles/born.dir/born.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/manip/born.c [ 89%] Linking C executable ../bin/dx2uhbd cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh && /usr/bin/cmake -E cmake_link_script CMakeFiles/dx2uhbd.dir/link.txt --verbose=1 /usr/bin/cc -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -Wl,-z,relro -Wl,-z,now -Wl,--as-needed -Wl,--no-as-needed CMakeFiles/dx2uhbd.dir/dx2uhbd.c.o -o ../bin/dx2uhbd ../../lib/libapbs_mg.so.3 ../../lib/libapbs_pmgc.so.3 ../../lib/libapbs_generic.so.3 -lm -lstdc++ /usr/lib/arm-linux-gnueabihf/openmpi/lib/libmpi.so -lmaloc -fopenmp [ 90%] Linking C executable ../bin/born cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/manip && /usr/bin/cmake -E cmake_link_script CMakeFiles/born.dir/link.txt --verbose=1 /usr/bin/cc -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -Wl,-z,relro -Wl,-z,now -Wl,--as-needed -Wl,--no-as-needed CMakeFiles/born.dir/born.c.o -o ../bin/born ../../lib/libapbs_mg.so.3 ../../lib/libapbs_pmgc.so.3 ../../lib/libapbs_generic.so.3 -lm -lstdc++ /usr/lib/arm-linux-gnueabihf/openmpi/lib/libmpi.so -lmaloc -fopenmp make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' [ 90%] Built target dx2uhbd make -f tools/manip/CMakeFiles/coulomb.dir/build.make tools/manip/CMakeFiles/coulomb.dir/depend make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf && /usr/bin/cmake -E cmake_depends "Unix Makefiles" /build/reproducible-path/apbs-3.0.0+dfsg1/apbs /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/manip /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/manip /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/manip/CMakeFiles/coulomb.dir/DependInfo.cmake --color= Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/manip/CMakeFiles/coulomb.dir/DependInfo.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/manip/CMakeFiles/coulomb.dir/depend.internal". Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/manip/CMakeFiles/CMakeDirectoryInformation.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/manip/CMakeFiles/coulomb.dir/depend.internal". Scanning dependencies of target coulomb make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' make -f tools/manip/CMakeFiles/coulomb.dir/build.make tools/manip/CMakeFiles/coulomb.dir/build make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' [ 91%] Building C object tools/manip/CMakeFiles/coulomb.dir/coulomb.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/manip && /usr/bin/cc -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fopenmp -o CMakeFiles/coulomb.dir/coulomb.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/manip/coulomb.c make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' [ 91%] Built target born make -f tools/python/CMakeFiles/_apbslib.dir/build.make tools/python/CMakeFiles/_apbslib.dir/depend make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf && /usr/bin/cmake -E cmake_depends "Unix Makefiles" /build/reproducible-path/apbs-3.0.0+dfsg1/apbs /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/python /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/python /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/python/CMakeFiles/_apbslib.dir/DependInfo.cmake --color= Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/python/CMakeFiles/_apbslib.dir/DependInfo.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/python/CMakeFiles/_apbslib.dir/depend.internal". Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/python/CMakeFiles/CMakeDirectoryInformation.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/python/CMakeFiles/_apbslib.dir/depend.internal". [ 93%] Linking C executable ../bin/mergedx cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/mesh && /usr/bin/cmake -E cmake_link_script CMakeFiles/mergedx.dir/link.txt --verbose=1 Scanning dependencies of target _apbslib /usr/bin/cc -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -Wl,-z,relro -Wl,-z,now -Wl,--as-needed -Wl,--no-as-needed CMakeFiles/mergedx.dir/mergedx.c.o -o ../bin/mergedx ../../lib/libapbs_mg.so.3 ../../lib/libapbs_pmgc.so.3 ../../lib/libapbs_generic.so.3 -lm -lstdc++ /usr/lib/arm-linux-gnueabihf/openmpi/lib/libmpi.so -lmaloc -fopenmp make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' make -f tools/python/CMakeFiles/_apbslib.dir/build.make tools/python/CMakeFiles/_apbslib.dir/build make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' [ 94%] Building C object tools/python/CMakeFiles/_apbslib.dir/CMakeFiles/_apbslib.dir/apbslibPYTHON_wrap.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/python && /usr/bin/cc -D_apbslib_EXPORTS -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -I/usr/include/python3.9 -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/python -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fPIC -fopenmp -o CMakeFiles/_apbslib.dir/CMakeFiles/_apbslib.dir/apbslibPYTHON_wrap.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/python/CMakeFiles/_apbslib.dir/apbslibPYTHON_wrap.c [ 95%] Linking C executable ../bin/coulomb cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/manip && /usr/bin/cmake -E cmake_link_script CMakeFiles/coulomb.dir/link.txt --verbose=1 /usr/bin/cc -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -Wl,-z,relro -Wl,-z,now -Wl,--as-needed -Wl,--no-as-needed CMakeFiles/coulomb.dir/coulomb.c.o -o ../bin/coulomb ../../lib/libapbs_mg.so.3 ../../lib/libapbs_pmgc.so.3 ../../lib/libapbs_generic.so.3 -lm -lstdc++ /usr/lib/arm-linux-gnueabihf/openmpi/lib/libmpi.so -lmaloc -fopenmp make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' [ 95%] Built target mergedx make -f src/CMakeFiles/apbs.dir/build.make src/CMakeFiles/apbs.dir/depend make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf && /usr/bin/cmake -E cmake_depends "Unix Makefiles" /build/reproducible-path/apbs-3.0.0+dfsg1/apbs /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/CMakeFiles/apbs.dir/DependInfo.cmake --color= Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/CMakeFiles/apbs.dir/DependInfo.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/CMakeFiles/apbs.dir/depend.internal". Dependee "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/CMakeFiles/CMakeDirectoryInformation.cmake" is newer than depender "/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src/CMakeFiles/apbs.dir/depend.internal". Scanning dependencies of target apbs make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' make -f src/CMakeFiles/apbs.dir/build.make src/CMakeFiles/apbs.dir/build make[4]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' [ 96%] Building C object src/CMakeFiles/apbs.dir/main.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src && /usr/bin/cc -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fopenmp -o CMakeFiles/apbs.dir/main.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/main.c make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' [ 96%] Built target coulomb [ 97%] Building C object src/CMakeFiles/apbs.dir/routines.c.o cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src && /usr/bin/cc -I/usr/lib/arm-linux-gnueabihf/openmpi/include/openmpi -I/usr/lib/arm-linux-gnueabihf/openmpi/include -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src -I/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/include -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -fopenmp -o CMakeFiles/apbs.dir/routines.c.o -c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.c /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/main.c: In function 'main': /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/main.c:288:64: warning: macro "__DATE__" might prevent reproducible builds [-Wdate-time] 288 | Vnm_tprint( 1, "This executable compiled on %s at %s\n\n", __DATE__, __TIME__); | ^~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/main.c:288:74: warning: macro "__TIME__" might prevent reproducible builds [-Wdate-time] 288 | Vnm_tprint( 1, "This executable compiled on %s at %s\n\n", __DATE__, __TIME__); | ^~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.c: In function 'writematMG': /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.c:1840:30: warning: '%s' directive writing 3 bytes into a region of size between 0 and 1023 [-Wformat-overflow=] 1840 | sprintf(outpath, "%s.%s", writematstem, "mat"); | ^~ ~~~~~ In file included from /usr/include/stdio.h:867, from /usr/include/maloc/maloc_base.h:80, from /usr/include/maloc/maloc.h:38, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/apbs.h:67, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.h:64, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.c:54: /usr/include/arm-linux-gnueabihf/bits/stdio2.h:36:10: note: '__builtin___sprintf_chk' output between 5 and 1028 bytes into a destination of size 1024 36 | return __builtin___sprintf_chk (__s, __USE_FORTIFY_LEVEL - 1, | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ 37 | __bos (__s), __fmt, __va_arg_pack ()); | ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.c: In function 'writedataMG': /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.c:2676:30: warning: '%s' directive writing 5 bytes into a region of size between 0 and 1023 [-Wformat-overflow=] 2676 | sprintf(outpath, "%s.%s", writestem, "dxbin"); | ^~ ~~~~~~~ In file included from /usr/include/stdio.h:867, from /usr/include/maloc/maloc_base.h:80, from /usr/include/maloc/maloc.h:38, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/apbs.h:67, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.h:64, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.c:54: /usr/include/arm-linux-gnueabihf/bits/stdio2.h:36:10: note: '__builtin___sprintf_chk' output between 7 and 1030 bytes into a destination of size 1024 36 | return __builtin___sprintf_chk (__s, __USE_FORTIFY_LEVEL - 1, | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ 37 | __bos (__s), __fmt, __va_arg_pack ()); | ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.c:2720:38: warning: '%s' directive writing 3 bytes into a region of size between 0 and 1023 [-Wformat-overflow=] 2720 | sprintf(outpath, "%s.%s", writestem, "txt"); | ^~ ~~~~~ In file included from /usr/include/stdio.h:867, from /usr/include/maloc/maloc_base.h:80, from /usr/include/maloc/maloc.h:38, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/apbs.h:67, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.h:64, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.c:54: /usr/include/arm-linux-gnueabihf/bits/stdio2.h:36:10: note: '__builtin___sprintf_chk' output between 5 and 1028 bytes into a destination of size 1024 36 | return __builtin___sprintf_chk (__s, __USE_FORTIFY_LEVEL - 1, | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ 37 | __bos (__s), __fmt, __va_arg_pack ()); | ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.c:2711:38: warning: '%s' directive writing 5 bytes into a region of size between 0 and 1023 [-Wformat-overflow=] 2711 | sprintf(outpath, "%s.%s", writestem, "dx.gz"); | ^~ ~~~~~~~ In file included from /usr/include/stdio.h:867, from /usr/include/maloc/maloc_base.h:80, from /usr/include/maloc/maloc.h:38, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/apbs.h:67, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.h:64, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.c:54: /usr/include/arm-linux-gnueabihf/bits/stdio2.h:36:10: note: '__builtin___sprintf_chk' output between 7 and 1030 bytes into a destination of size 1024 36 | return __builtin___sprintf_chk (__s, __USE_FORTIFY_LEVEL - 1, | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ 37 | __bos (__s), __fmt, __va_arg_pack ()); | ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.c:2694:38: warning: '%s' directive writing 4 bytes into a region of size between 0 and 1023 [-Wformat-overflow=] 2694 | sprintf(outpath, "%s.%s", writestem, "mcsf"); | ^~ ~~~~~~ In file included from /usr/include/stdio.h:867, from /usr/include/maloc/maloc_base.h:80, from /usr/include/maloc/maloc.h:38, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/apbs.h:67, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.h:64, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.c:54: /usr/include/arm-linux-gnueabihf/bits/stdio2.h:36:10: note: '__builtin___sprintf_chk' output between 6 and 1029 bytes into a destination of size 1024 36 | return __builtin___sprintf_chk (__s, __USE_FORTIFY_LEVEL - 1, | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ 37 | __bos (__s), __fmt, __va_arg_pack ()); | ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.c:2687:38: warning: '%s' directive writing 3 bytes into a region of size between 0 and 1023 [-Wformat-overflow=] 2687 | sprintf(outpath, "%s.%s", writestem, "ucd"); | ^~ ~~~~~ In file included from /usr/include/stdio.h:867, from /usr/include/maloc/maloc_base.h:80, from /usr/include/maloc/maloc.h:38, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/apbs.h:67, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.h:64, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.c:54: /usr/include/arm-linux-gnueabihf/bits/stdio2.h:36:10: note: '__builtin___sprintf_chk' output between 5 and 1028 bytes into a destination of size 1024 36 | return __builtin___sprintf_chk (__s, __USE_FORTIFY_LEVEL - 1, | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ 37 | __bos (__s), __fmt, __va_arg_pack ()); | ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.c:2701:38: warning: '%s' directive writing 3 bytes into a region of size between 0 and 1023 [-Wformat-overflow=] 2701 | sprintf(outpath, "%s.%s", writestem, "grd"); | ^~ ~~~~~ In file included from /usr/include/stdio.h:867, from /usr/include/maloc/maloc_base.h:80, from /usr/include/maloc/maloc.h:38, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/apbs.h:67, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.h:64, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.c:54: /usr/include/arm-linux-gnueabihf/bits/stdio2.h:36:10: note: '__builtin___sprintf_chk' output between 5 and 1028 bytes into a destination of size 1024 36 | return __builtin___sprintf_chk (__s, __USE_FORTIFY_LEVEL - 1, | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ 37 | __bos (__s), __fmt, __va_arg_pack ()); | ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.c:2666:38: warning: '%s' directive writing 2 bytes into a region of size between 0 and 1023 [-Wformat-overflow=] 2666 | sprintf(outpath, "%s.%s", writestem, "dx"); | ^~ ~~~~ In file included from /usr/include/stdio.h:867, from /usr/include/maloc/maloc_base.h:80, from /usr/include/maloc/maloc.h:38, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/apbs.h:67, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.h:64, from /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/src/routines.c:54: /usr/include/arm-linux-gnueabihf/bits/stdio2.h:36:10: note: '__builtin___sprintf_chk' output between 4 and 1027 bytes into a destination of size 1024 36 | return __builtin___sprintf_chk (__s, __USE_FORTIFY_LEVEL - 1, | ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ 37 | __bos (__s), __fmt, __va_arg_pack ()); | ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ [ 98%] Linking C executable ../bin/apbs cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/src && /usr/bin/cmake -E cmake_link_script CMakeFiles/apbs.dir/link.txt --verbose=1 /usr/bin/cc -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -Wl,-z,relro -Wl,-z,now -Wl,--as-needed -Wl,--no-as-needed -rdynamic CMakeFiles/apbs.dir/main.c.o CMakeFiles/apbs.dir/routines.c.o -o ../bin/apbs -lm -lstdc++ /usr/lib/arm-linux-gnueabihf/openmpi/lib/libmpi.so -lmaloc -fopenmp ../lib/libapbs_routines.so.3 -lm -lstdc++ /usr/lib/arm-linux-gnueabihf/openmpi/lib/libmpi.so -lmaloc -fopenmp ../lib/libapbs_mg.so.3 ../lib/libapbs_generic.so.3 ../lib/libapbs_pmgc.so.3 -lm -lstdc++ /usr/lib/arm-linux-gnueabihf/openmpi/lib/libmpi.so -lmaloc -fopenmp make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' [ 98%] Built target apbs [100%] Linking C shared library ../../lib/_apbslib.so cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/python && /usr/bin/cmake -E cmake_link_script CMakeFiles/_apbslib.dir/link.txt --verbose=1 /usr/bin/cc -fPIC -g -O2 -fdebug-prefix-map=/build/reproducible-path/apbs-3.0.0+dfsg1=. -fstack-protector-strong -Wformat -Werror=format-security -Wdate-time -D_FORTIFY_SOURCE=2 -fcommon -Wdate-time -D_FORTIFY_SOURCE=2 -fPIC -O3 -DNDEBUG -Wl,-z,relro -Wl,-z,now -Wl,--as-needed -shared -Wl,-soname,_apbslib.so -o ../../lib/_apbslib.so CMakeFiles/_apbslib.dir/CMakeFiles/_apbslib.dir/apbslibPYTHON_wrap.c.o -lm -lstdc++ /usr/lib/arm-linux-gnueabihf/openmpi/lib/libmpi.so -lmaloc -fopenmp ../../lib/libapbs_routines.so.3 /usr/lib/arm-linux-gnueabihf/libpython3.9.so ../../lib/libapbs_mg.so.3 ../../lib/libapbs_generic.so.3 ../../lib/libapbs_pmgc.so.3 -lm -lstdc++ /usr/lib/arm-linux-gnueabihf/openmpi/lib/libmpi.so -lmaloc -fopenmp cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/python && /usr/bin/cmake -E copy /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/python/apbslib.py /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/../pdb2pqr/pdb2pka cd /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/tools/python && /usr/bin/cmake -E copy /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/lib/_apbslib.so /build/reproducible-path/apbs-3.0.0+dfsg1/apbs/../pdb2pqr/pdb2pka make[4]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' [100%] Built target _apbslib make[3]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' /usr/bin/cmake -E cmake_progress_start /build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/CMakeFiles 0 make[2]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' make[1]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1' debian/rules override_dh_auto_test make[1]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1' (cd apbs/tests; PATH=/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/bin:${PATH} LD_LIBRARY_PATH=/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf/lib:${LD_LIBRARY_PATH} PYTHONPATH=${PYTHONPATH}:/build/reproducible-path/apbs-3.0.0+dfsg1/apbs/tools/manip python3 apbs_tester.py -c test_cases.cfg; rm -rf __pycache__) Testing all sections The following sections will be tested: born, actin-dimer-auto, actin-dimer-parallel, alkanes, FKBP, hca-bind, ionize, ion-pmf, pka-lig, point-pmf, solv, protein-rna ================================================================================ Running tests for born section -------------------------------------------------------------------------------- Testing forces from apbs-forces.in Checking forces for input file apbs-forces.inChecking Polar ForcesChecking Apolar ForcesElapsed time: 0.045794 seconds -------------------------------------------------------------------------------- -------------------------------------------------------------------------------- Testing input file apbs-mol-auto.in BINARY: apbs INPUT: apbs-mol-auto.in ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-mol-auto.in... rank 0 size 1... Parsed input file. Got paths for 1 molecules Reading XML-format atom data from ion.xml. Valist_readXML: Warning Warning Warning Warning Warning Valist_readXML: The use of XML input files with parameter Valist_readXML: files is currently not supported. Valist_readXML: Warning Warning Warning Warning Warning 1 atoms Centered at (0.000e+00, 0.000e+00, 0.000e+00) Net charge 1.00e+00 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (solvated): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.262 MB total, 61.262 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.781 x 0.781 x 0.781 Grid lengths: 50.000 x 50.000 x 50.000 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 9.607073836227E+02 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (solvated): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.262 MB total, 122.067 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.383 x 0.383 x 0.383 Grid lengths: 24.495 x 24.495 x 24.495 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.200266567971E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #3 (solvated): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.262 MB total, 122.067 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.188 x 0.188 x 0.188 Grid lengths: 12.000 x 12.000 x 12.000 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Potential to be written to potential.dx.gz Total electrostatic energy = 4.732245131587E+03 kJ/mol Calculating forces... Writing potential to potential-PE0.dx.gz ---------------------------------------- CALCULATION #4 (reference): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.189 MB total, 122.067 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.781 x 0.781 x 0.781 Grid lengths: 50.000 x 50.000 x 50.000 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 1.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.190871482831E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #5 (reference): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.189 MB total, 122.067 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.383 x 0.383 x 0.383 Grid lengths: 24.495 x 24.495 x 24.495 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 1.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.430874049735E+03 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #6 (reference): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.189 MB total, 122.067 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.188 x 0.188 x 0.188 Grid lengths: 12.000 x 12.000 x 12.000 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 1.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 4.962018684215E+03 kJ/mol Calculating forces... ---------------------------------------- PRINT STATEMENTS print energy 1 (solvated) - 2 (reference) end Local net energy (PE 0) = -2.297735526282E+02 kJ/mol Global net ELEC energy = -2.297735526282E+02 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 1 molecules Final memory usage: 0.001 MB total, 122.067 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-mol-auto.out RESULT 960.7073836227 RESULT 2200.266567971 RESULT 4732.245131587 RESULT 1190.871482831 RESULT 2430.874049735 RESULT 4962.018684215 RESULT -229.7735526282 Testing computed result 9.607073836227E+02 against expected result 9.607074E+02 *** PASSED *** Testing computed result 2.200266567971E+03 against expected result 2.200267E+03 *** PASSED *** Testing computed result 4.732245131587E+03 against expected result 4.732245E+03 *** PASSED *** Testing computed result 1.190871482831E+03 against expected result 1.190871E+03 *** PASSED *** Testing computed result 2.430874049735E+03 against expected result 2.430874E+03 *** PASSED *** Testing computed result 4.962018684215E+03 against expected result 4.962019E+03 *** PASSED *** Testing computed result -2.297735526282E+02 against expected result -2.297735E+02 *** PASSED *** Elapsed time: 9.848117 seconds -------------------------------------------------------------------------------- -------------------------------------------------------------------------------- Testing input file apbs-smol-auto.in BINARY: apbs INPUT: apbs-smol-auto.in ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-smol-auto.in... rank 0 size 1... Parsed input file. Got paths for 1 molecules Reading XML-format atom data from ion.xml. Valist_readXML: Warning Warning Warning Warning Warning Valist_readXML: The use of XML input files with parameter Valist_readXML: files is currently not supported. Valist_readXML: Warning Warning Warning Warning Warning 1 atoms Centered at (0.000e+00, 0.000e+00, 0.000e+00) Net charge 1.00e+00 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (solvated): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.262 MB total, 61.262 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.781 x 0.781 x 0.781 Grid lengths: 50.000 x 50.000 x 50.000 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 9.532928767450E+02 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (solvated): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.262 MB total, 122.067 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.383 x 0.383 x 0.383 Grid lengths: 24.495 x 24.495 x 24.495 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.201243880085E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #3 (solvated): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.262 MB total, 122.067 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.188 x 0.188 x 0.188 Grid lengths: 12.000 x 12.000 x 12.000 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 4.733006258977E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #4 (reference): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.189 MB total, 122.067 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.781 x 0.781 x 0.781 Grid lengths: 50.000 x 50.000 x 50.000 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 1.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.190871482831E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #5 (reference): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.189 MB total, 122.067 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.383 x 0.383 x 0.383 Grid lengths: 24.495 x 24.495 x 24.495 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 1.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.430874049735E+03 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #6 (reference): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.189 MB total, 122.067 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.188 x 0.188 x 0.188 Grid lengths: 12.000 x 12.000 x 12.000 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 1.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 4.962018684215E+03 kJ/mol Calculating forces... ---------------------------------------- PRINT STATEMENTS print energy 1 (solvated) - 2 (reference) end Local net energy (PE 0) = -2.290124252387E+02 kJ/mol Global net ELEC energy = -2.290124252387E+02 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 1 molecules Final memory usage: 0.001 MB total, 122.067 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-smol-auto.out RESULT 953.292876745 RESULT 2201.243880085 RESULT 4733.006258977 RESULT 1190.871482831 RESULT 2430.874049735 RESULT 4962.018684215 RESULT -229.0124252387 Testing computed result 9.532928767450E+02 against expected result 9.532929E+02 *** PASSED *** Testing computed result 2.201243880085E+03 against expected result 2.201244E+03 *** PASSED *** Testing computed result 4.733006258977E+03 against expected result 4.733006E+03 *** PASSED *** Testing computed result 1.190871482831E+03 against expected result 1.190871E+03 *** PASSED *** Testing computed result 2.430874049735E+03 against expected result 2.430874E+03 *** PASSED *** Testing computed result 4.962018684215E+03 against expected result 4.962019E+03 *** PASSED *** Testing computed result -2.290124252387E+02 against expected result -2.290124E+02 *** PASSED *** Elapsed time: 7.395001 seconds -------------------------------------------------------------------------------- -------------------------------------------------------------------------------- Testing input file apbs-mol-parallel.in Splitting the input file into 4 separate files using the inputgen utility BINARY: apbs INPUT: apbs-mol-parallel-PE0.in ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-mol-parallel-PE0.in... rank 0 size 1... Parsed input file. Got paths for 1 molecules Reading XML-format atom data from ion.xml. Valist_readXML: Warning Warning Warning Warning Warning Valist_readXML: The use of XML input files with parameter Valist_readXML: files is currently not supported. Valist_readXML: Warning Warning Warning Warning Warning 1 atoms Centered at (0.000e+00, 0.000e+00, 0.000e+00) Net charge 1.00e+00 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (solvated): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.262 MB total, 61.262 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.781 x 0.781 x 0.781 Grid lengths: 50.000 x 50.000 x 50.000 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.401768459022E+02 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (solvated): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.262 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.296 x 0.296 x 0.383 Grid lengths: 18.944 x 18.944 x 24.495 Grid center: (-2.411, -2.411, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 8.142935592471E+02 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #3 (solvated): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.262 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.112 x 0.112 x 0.188 Grid lengths: 7.178 x 7.178 x 12.000 Grid center: (-2.411, -2.411, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.485255308186E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #4 (reference): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.189 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.781 x 0.781 x 0.781 Grid lengths: 50.000 x 50.000 x 50.000 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 1.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.977178707009E+02 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #5 (reference): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.189 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.296 x 0.296 x 0.383 Grid lengths: 18.944 x 18.944 x 24.495 Grid center: (-2.411, -2.411, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 1.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 8.799304557588E+02 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #6 (reference): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.189 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.112 x 0.112 x 0.188 Grid lengths: 7.178 x 7.178 x 12.000 Grid center: (-2.411, -2.411, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 1.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.542873949131E+03 kJ/mol Calculating forces... ---------------------------------------- PRINT STATEMENTS print energy 1 (solvated) - 2 (reference) end Local net energy (PE 0) = -5.761864094552E+01 kJ/mol Global net ELEC energy = -5.761864094552E+01 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 1 molecules Final memory usage: 0.001 MB total, 122.067 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-mol-parallel-PE0.out Processor 0 results: 2.401768459022E+02 8.142935592471E+02 1.485255308186E+03 2.977178707009E+02 8.799304557588E+02 1.542873949131E+03 -5.761864094552E+01 BINARY: apbs INPUT: apbs-mol-parallel-PE1.in ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-mol-parallel-PE1.in... rank 0 size 1... Parsed input file. Got paths for 1 molecules Reading XML-format atom data from ion.xml. Valist_readXML: Warning Warning Warning Warning Warning Valist_readXML: The use of XML input files with parameter Valist_readXML: files is currently not supported. Valist_readXML: Warning Warning Warning Warning Warning 1 atoms Centered at (0.000e+00, 0.000e+00, 0.000e+00) Net charge 1.00e+00 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (solvated): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.262 MB total, 61.262 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.781 x 0.781 x 0.781 Grid lengths: 50.000 x 50.000 x 50.000 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.401768459022E+02 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (solvated): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.262 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.296 x 0.296 x 0.383 Grid lengths: 18.944 x 18.944 x 24.495 Grid center: (2.411, -2.411, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 8.142778312125E+02 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #3 (solvated): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.262 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.112 x 0.112 x 0.188 Grid lengths: 7.178 x 7.178 x 12.000 Grid center: (2.411, -2.411, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.485246667424E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #4 (reference): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.189 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.781 x 0.781 x 0.781 Grid lengths: 50.000 x 50.000 x 50.000 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 1.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.977178707009E+02 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #5 (reference): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.189 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.296 x 0.296 x 0.383 Grid lengths: 18.944 x 18.944 x 24.495 Grid center: (2.411, -2.411, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 1.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 8.799304557588E+02 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #6 (reference): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.189 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.112 x 0.112 x 0.188 Grid lengths: 7.178 x 7.178 x 12.000 Grid center: (2.411, -2.411, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 1.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.542873949131E+03 kJ/mol Calculating forces... ---------------------------------------- PRINT STATEMENTS print energy 1 (solvated) - 2 (reference) end Local net energy (PE 0) = -5.762728170718E+01 kJ/mol Global net ELEC energy = -5.762728170718E+01 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 1 molecules Final memory usage: 0.001 MB total, 122.067 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-mol-parallel-PE1.out Processor 1 results: 2.401768459022E+02 8.142778312125E+02 1.485246667424E+03 2.977178707009E+02 8.799304557588E+02 1.542873949131E+03 -5.762728170718E+01 BINARY: apbs INPUT: apbs-mol-parallel-PE2.in ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-mol-parallel-PE2.in... rank 0 size 1... Parsed input file. Got paths for 1 molecules Reading XML-format atom data from ion.xml. Valist_readXML: Warning Warning Warning Warning Warning Valist_readXML: The use of XML input files with parameter Valist_readXML: files is currently not supported. Valist_readXML: Warning Warning Warning Warning Warning 1 atoms Centered at (0.000e+00, 0.000e+00, 0.000e+00) Net charge 1.00e+00 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (solvated): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.262 MB total, 61.262 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.781 x 0.781 x 0.781 Grid lengths: 50.000 x 50.000 x 50.000 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.401768459091E+02 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (solvated): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.262 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.296 x 0.296 x 0.383 Grid lengths: 18.944 x 18.944 x 24.495 Grid center: (-2.411, 2.411, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 8.142935605696E+02 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #3 (solvated): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.262 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.112 x 0.112 x 0.188 Grid lengths: 7.178 x 7.178 x 12.000 Grid center: (-2.411, 2.411, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.485255306569E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #4 (reference): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.189 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.781 x 0.781 x 0.781 Grid lengths: 50.000 x 50.000 x 50.000 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 1.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.977178707146E+02 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #5 (reference): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.189 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.296 x 0.296 x 0.383 Grid lengths: 18.944 x 18.944 x 24.495 Grid center: (-2.411, 2.411, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 1.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 8.799304557596E+02 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #6 (reference): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.189 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.112 x 0.112 x 0.188 Grid lengths: 7.178 x 7.178 x 12.000 Grid center: (-2.411, 2.411, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 1.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.542873949141E+03 kJ/mol Calculating forces... ---------------------------------------- PRINT STATEMENTS print energy 1 (solvated) - 2 (reference) end Local net energy (PE 0) = -5.761864257239E+01 kJ/mol Global net ELEC energy = -5.761864257239E+01 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 1 molecules Final memory usage: 0.001 MB total, 122.067 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-mol-parallel-PE2.out Processor 2 results: 2.401768459091E+02 8.142935605696E+02 1.485255306569E+03 2.977178707146E+02 8.799304557596E+02 1.542873949141E+03 -5.761864257239E+01 BINARY: apbs INPUT: apbs-mol-parallel-PE3.in ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-mol-parallel-PE3.in... rank 0 size 1... Parsed input file. Got paths for 1 molecules Reading XML-format atom data from ion.xml. Valist_readXML: Warning Warning Warning Warning Warning Valist_readXML: The use of XML input files with parameter Valist_readXML: files is currently not supported. Valist_readXML: Warning Warning Warning Warning Warning 1 atoms Centered at (0.000e+00, 0.000e+00, 0.000e+00) Net charge 1.00e+00 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (solvated): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.262 MB total, 61.262 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.781 x 0.781 x 0.781 Grid lengths: 50.000 x 50.000 x 50.000 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.401768459091E+02 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (solvated): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.262 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.296 x 0.296 x 0.383 Grid lengths: 18.944 x 18.944 x 24.495 Grid center: (2.411, 2.411, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 8.142778325440E+02 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #3 (solvated): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.262 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.112 x 0.112 x 0.188 Grid lengths: 7.178 x 7.178 x 12.000 Grid center: (2.411, 2.411, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.485246665692E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #4 (reference): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.189 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.781 x 0.781 x 0.781 Grid lengths: 50.000 x 50.000 x 50.000 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 1.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.977178707146E+02 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #5 (reference): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.189 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.296 x 0.296 x 0.383 Grid lengths: 18.944 x 18.944 x 24.495 Grid center: (2.411, 2.411, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 1.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 8.799304557596E+02 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #6 (reference): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.189 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.112 x 0.112 x 0.188 Grid lengths: 7.178 x 7.178 x 12.000 Grid center: (2.411, 2.411, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 1.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.542873949141E+03 kJ/mol Calculating forces... ---------------------------------------- PRINT STATEMENTS print energy 1 (solvated) - 2 (reference) end Local net energy (PE 0) = -5.762728344954E+01 kJ/mol Global net ELEC energy = -5.762728344954E+01 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 1 molecules Final memory usage: 0.001 MB total, 122.067 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-mol-parallel-PE3.out Processor 3 results: 2.401768459091E+02 8.142778325440E+02 1.485246665692E+03 2.977178707146E+02 8.799304557596E+02 1.542873949141E+03 -5.762728344954E+01 RESULT 960.7073836226 RESULT 3257.1427835731997 RESULT 5941.0039478710005 RESULT 1190.8714828309999 RESULT 3519.7218230368003 RESULT 6171.495796544 RESULT -230.49184867463003 Testing computed result 9.607073836226E+02 against expected result 9.607074E+02 *** PASSED *** Testing computed result 3.257142783573E+03 against expected result 3.257143E+03 *** PASSED *** Testing computed result 5.941003947871E+03 against expected result 5.941004E+03 *** PASSED *** Testing computed result 1.190871482831E+03 against expected result 1.190871E+03 *** PASSED *** Testing computed result 3.519721823037E+03 against expected result 3.519722E+03 *** PASSED *** Testing computed result 6.171495796544E+03 against expected result 6.171496E+03 *** PASSED *** Testing computed result -2.304918486746E+02 against expected result -2.304918E+02 *** PASSED *** Elapsed time: 46.267046 seconds -------------------------------------------------------------------------------- -------------------------------------------------------------------------------- Testing input file apbs-smol-parallel.in Splitting the input file into 4 separate files using the inputgen utility BINARY: apbs INPUT: apbs-smol-parallel-PE0.in ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-smol-parallel-PE0.in... rank 0 size 1... Parsed input file. Got paths for 1 molecules Reading XML-format atom data from ion.xml. Valist_readXML: Warning Warning Warning Warning Warning Valist_readXML: The use of XML input files with parameter Valist_readXML: files is currently not supported. Valist_readXML: Warning Warning Warning Warning Warning 1 atoms Centered at (0.000e+00, 0.000e+00, 0.000e+00) Net charge 1.00e+00 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (solvated): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.262 MB total, 61.262 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.781 x 0.781 x 0.781 Grid lengths: 50.000 x 50.000 x 50.000 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.383232191816E+02 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (solvated): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.262 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.296 x 0.296 x 0.383 Grid lengths: 18.944 x 18.944 x 24.495 Grid center: (-2.411, -2.411, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 8.145369591602E+02 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #3 (solvated): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.262 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.112 x 0.112 x 0.188 Grid lengths: 7.178 x 7.178 x 12.000 Grid center: (-2.411, -2.411, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.485524998001E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #4 (reference): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.189 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.781 x 0.781 x 0.781 Grid lengths: 50.000 x 50.000 x 50.000 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 1.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.977178707009E+02 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #5 (reference): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.189 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.296 x 0.296 x 0.383 Grid lengths: 18.944 x 18.944 x 24.495 Grid center: (-2.411, -2.411, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 1.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 8.799304557588E+02 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #6 (reference): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.189 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.112 x 0.112 x 0.188 Grid lengths: 7.178 x 7.178 x 12.000 Grid center: (-2.411, -2.411, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 1.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.542873949131E+03 kJ/mol Calculating forces... ---------------------------------------- PRINT STATEMENTS print energy 1 (solvated) - 2 (reference) end Local net energy (PE 0) = -5.734895113069E+01 kJ/mol Global net ELEC energy = -5.734895113069E+01 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 1 molecules Final memory usage: 0.001 MB total, 122.067 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-smol-parallel-PE0.out Processor 0 results: 2.383232191816E+02 8.145369591602E+02 1.485524998001E+03 2.977178707009E+02 8.799304557588E+02 1.542873949131E+03 -5.734895113069E+01 BINARY: apbs INPUT: apbs-smol-parallel-PE1.in ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-smol-parallel-PE1.in... rank 0 size 1... Parsed input file. Got paths for 1 molecules Reading XML-format atom data from ion.xml. Valist_readXML: Warning Warning Warning Warning Warning Valist_readXML: The use of XML input files with parameter Valist_readXML: files is currently not supported. Valist_readXML: Warning Warning Warning Warning Warning 1 atoms Centered at (0.000e+00, 0.000e+00, 0.000e+00) Net charge 1.00e+00 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (solvated): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.262 MB total, 61.262 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.781 x 0.781 x 0.781 Grid lengths: 50.000 x 50.000 x 50.000 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.383232191816E+02 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (solvated): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.262 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.296 x 0.296 x 0.383 Grid lengths: 18.944 x 18.944 x 24.495 Grid center: (2.411, -2.411, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 8.145419898332E+02 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #3 (solvated): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.262 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.112 x 0.112 x 0.188 Grid lengths: 7.178 x 7.178 x 12.000 Grid center: (2.411, -2.411, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.485529328612E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #4 (reference): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.189 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.781 x 0.781 x 0.781 Grid lengths: 50.000 x 50.000 x 50.000 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 1.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.977178707009E+02 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #5 (reference): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.189 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.296 x 0.296 x 0.383 Grid lengths: 18.944 x 18.944 x 24.495 Grid center: (2.411, -2.411, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 1.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 8.799304557588E+02 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #6 (reference): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.189 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.112 x 0.112 x 0.188 Grid lengths: 7.178 x 7.178 x 12.000 Grid center: (2.411, -2.411, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 1.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.542873949131E+03 kJ/mol Calculating forces... ---------------------------------------- PRINT STATEMENTS print energy 1 (solvated) - 2 (reference) end Local net energy (PE 0) = -5.734462051928E+01 kJ/mol Global net ELEC energy = -5.734462051928E+01 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 1 molecules Final memory usage: 0.001 MB total, 122.067 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-smol-parallel-PE1.out Processor 1 results: 2.383232191816E+02 8.145419898332E+02 1.485529328612E+03 2.977178707009E+02 8.799304557588E+02 1.542873949131E+03 -5.734462051928E+01 BINARY: apbs INPUT: apbs-smol-parallel-PE2.in ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-smol-parallel-PE2.in... rank 0 size 1... Parsed input file. Got paths for 1 molecules Reading XML-format atom data from ion.xml. Valist_readXML: Warning Warning Warning Warning Warning Valist_readXML: The use of XML input files with parameter Valist_readXML: files is currently not supported. Valist_readXML: Warning Warning Warning Warning Warning 1 atoms Centered at (0.000e+00, 0.000e+00, 0.000e+00) Net charge 1.00e+00 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (solvated): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.262 MB total, 61.262 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.781 x 0.781 x 0.781 Grid lengths: 50.000 x 50.000 x 50.000 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.383232191909E+02 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (solvated): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.262 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.296 x 0.296 x 0.383 Grid lengths: 18.944 x 18.944 x 24.495 Grid center: (-2.411, 2.411, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 8.145369593489E+02 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #3 (solvated): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.262 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.112 x 0.112 x 0.188 Grid lengths: 7.178 x 7.178 x 12.000 Grid center: (-2.411, 2.411, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.485524997676E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #4 (reference): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.189 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.781 x 0.781 x 0.781 Grid lengths: 50.000 x 50.000 x 50.000 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 1.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.977178707146E+02 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #5 (reference): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.189 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.296 x 0.296 x 0.383 Grid lengths: 18.944 x 18.944 x 24.495 Grid center: (-2.411, 2.411, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 1.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 8.799304557596E+02 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #6 (reference): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.189 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.112 x 0.112 x 0.188 Grid lengths: 7.178 x 7.178 x 12.000 Grid center: (-2.411, 2.411, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 1.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.542873949141E+03 kJ/mol Calculating forces... ---------------------------------------- PRINT STATEMENTS print energy 1 (solvated) - 2 (reference) end Local net energy (PE 0) = -5.734895146550E+01 kJ/mol Global net ELEC energy = -5.734895146550E+01 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 1 molecules Final memory usage: 0.001 MB total, 122.067 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-smol-parallel-PE2.out Processor 2 results: 2.383232191909E+02 8.145369593489E+02 1.485524997676E+03 2.977178707146E+02 8.799304557596E+02 1.542873949141E+03 -5.734895146550E+01 BINARY: apbs INPUT: apbs-smol-parallel-PE3.in ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-smol-parallel-PE3.in... rank 0 size 1... Parsed input file. Got paths for 1 molecules Reading XML-format atom data from ion.xml. Valist_readXML: Warning Warning Warning Warning Warning Valist_readXML: The use of XML input files with parameter Valist_readXML: files is currently not supported. Valist_readXML: Warning Warning Warning Warning Warning 1 atoms Centered at (0.000e+00, 0.000e+00, 0.000e+00) Net charge 1.00e+00 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (solvated): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.262 MB total, 61.262 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.781 x 0.781 x 0.781 Grid lengths: 50.000 x 50.000 x 50.000 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.383232191909E+02 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (solvated): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.262 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.296 x 0.296 x 0.383 Grid lengths: 18.944 x 18.944 x 24.495 Grid center: (2.411, 2.411, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 8.145419900310E+02 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #3 (solvated): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.262 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.112 x 0.112 x 0.188 Grid lengths: 7.178 x 7.178 x 12.000 Grid center: (2.411, 2.411, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.485529328301E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #4 (reference): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.189 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.781 x 0.781 x 0.781 Grid lengths: 50.000 x 50.000 x 50.000 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 1.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.977178707146E+02 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #5 (reference): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.189 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.296 x 0.296 x 0.383 Grid lengths: 18.944 x 18.944 x 24.495 Grid center: (2.411, 2.411, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 1.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 8.799304557596E+02 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #6 (reference): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.189 MB total, 122.067 MB high water Using cubic spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 1 Grid dimensions: 65 x 65 x 65 Grid spacings: 0.112 x 0.112 x 0.188 Grid lengths: 7.178 x 7.178 x 12.000 Grid center: (2.411, 2.411, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 1.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.542873949141E+03 kJ/mol Calculating forces... ---------------------------------------- PRINT STATEMENTS print energy 1 (solvated) - 2 (reference) end Local net energy (PE 0) = -5.734462084052E+01 kJ/mol Global net ELEC energy = -5.734462084052E+01 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 1 molecules Final memory usage: 0.001 MB total, 122.067 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-smol-parallel-PE3.out Processor 3 results: 2.383232191909E+02 8.145419900310E+02 1.485529328301E+03 2.977178707146E+02 8.799304557596E+02 1.542873949141E+03 -5.734462084052E+01 RESULT 953.292876745 RESULT 3258.1578983732998 RESULT 5942.108652589999 RESULT 1190.8714828309999 RESULT 3519.7218230368003 RESULT 6171.495796544 RESULT -229.38714395599 Testing computed result 9.532928767450E+02 against expected result 9.532929E+02 *** PASSED *** Testing computed result 3.258157898373E+03 against expected result 3.258158E+03 *** PASSED *** Testing computed result 5.942108652590E+03 against expected result 5.942109E+03 *** PASSED *** Testing computed result 1.190871482831E+03 against expected result 1.190871E+03 *** PASSED *** Testing computed result 3.519721823037E+03 against expected result 3.519722E+03 *** PASSED *** Testing computed result 6.171495796544E+03 against expected result 6.171496E+03 *** PASSED *** Testing computed result -2.293871439560E+02 against expected result -2.293871E+02 *** PASSED *** Elapsed time: 44.724096 seconds -------------------------------------------------------------------------------- Total elapsed time: 108.280054 seconds Test results have been logged -------------------------------------------------------------------------------- Running tests for actin-dimer-auto section -------------------------------------------------------------------------------- Testing input file apbs-mol-auto.in BINARY: apbs INPUT: apbs-mol-auto.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-mol-auto.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from mol1.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 5877 atoms Centered at (1.535e+01, -3.100e-02, 2.993e+00) Net charge -1.20e+01 e Reading PQR-format atom data from mol2.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 5877 atoms Centered at (-1.404e+01, -3.356e+00, 3.049e+01) Net charge -1.20e+01 e Reading PQR-format atom data from complex.pqr. 11754 atoms Centered at (2.518e+00, -2.465e+00, 1.674e+01) Net charge -2.40e+01 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (mol1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.5959 A Current memory usage: 1004.896 MB total, 1004.896 MB high water Using linear spline charge discretization. Grid dimensions: 161 x 161 x 161 Grid spacings: 0.975 x 0.756 x 1.012 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.400 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.527617850342E+05 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (mol1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.5959 A Current memory usage: 1004.896 MB total, 1995.284 MB high water Using linear spline charge discretization. Grid dimensions: 161 x 161 x 161 Grid spacings: 0.700 x 0.569 x 0.725 Grid lengths: 112.000 x 91.000 x 116.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.400 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.919510754196E+05 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #3 (mol2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.5959 A Current memory usage: 1005.881 MB total, 1995.284 MB high water Using linear spline charge discretization. Grid dimensions: 161 x 161 x 161 Grid spacings: 0.975 x 0.756 x 1.012 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.400 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.527671844880E+05 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #4 (mol2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.5959 A Current memory usage: 1005.881 MB total, 1997.252 MB high water Using linear spline charge discretization. Grid dimensions: 161 x 161 x 161 Grid spacings: 0.700 x 0.569 x 0.725 Grid lengths: 112.000 x 91.000 x 116.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.400 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.915468859278E+05 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #5 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.5959 A Current memory usage: 1018.381 MB total, 1997.252 MB high water Using linear spline charge discretization. Grid dimensions: 161 x 161 x 161 Grid spacings: 0.975 x 0.756 x 1.012 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.400 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 3.056317807611E+05 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #6 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.5959 A Current memory usage: 1018.381 MB total, 2013.407 MB high water Using linear spline charge discretization. Grid dimensions: 161 x 161 x 161 Grid spacings: 0.700 x 0.569 x 0.725 Grid lengths: 112.000 x 91.000 x 116.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.400 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 5.836028296532E+05 kJ/mol Calculating forces... ---------------------------------------- PRINT STATEMENTS print energy 3 (complex) - 2 (mol2) - 1 (mol1) end Local net energy (PE 0) = 1.048683058628E+02 kJ/mol Global net ELEC energy = 1.048683058628E+02 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 2013.407 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-mol-auto.out RESULT 152761.7850342 RESULT 291951.0754196 RESULT 152767.184488 RESULT 291546.8859278 RESULT 305631.7807611 RESULT 583602.8296532 RESULT 104.8683058628 Testing computed result 1.527617850342E+05 against expected result 1.527618E+05 *** PASSED *** Testing computed result 2.919510754196E+05 against expected result 2.919511E+05 *** PASSED *** Testing computed result 1.527671844880E+05 against expected result 1.527672E+05 *** PASSED *** Testing computed result 2.915468859278E+05 against expected result 2.915469E+05 *** PASSED *** Testing computed result 3.056317807611E+05 against expected result 3.056318E+05 *** PASSED *** Testing computed result 5.836028296532E+05 against expected result 5.836028E+05 *** PASSED *** Testing computed result 1.048683058628E+02 against expected result 1.048683E+02 *** PASSED *** Elapsed time: 567.284879 seconds -------------------------------------------------------------------------------- -------------------------------------------------------------------------------- Testing input file apbs-smol-auto.in BINARY: apbs INPUT: apbs-smol-auto.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-smol-auto.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from mol1.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 5877 atoms Centered at (1.535e+01, -3.100e-02, 2.993e+00) Net charge -1.20e+01 e Reading PQR-format atom data from mol2.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 5877 atoms Centered at (-1.404e+01, -3.356e+00, 3.049e+01) Net charge -1.20e+01 e Reading PQR-format atom data from complex.pqr. 11754 atoms Centered at (2.518e+00, -2.465e+00, 1.674e+01) Net charge -2.40e+01 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (mol1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.5959 A Current memory usage: 1004.896 MB total, 1004.896 MB high water Using linear spline charge discretization. Grid dimensions: 161 x 161 x 161 Grid spacings: 0.975 x 0.756 x 1.012 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.400 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.528632421825E+05 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (mol1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.5959 A Current memory usage: 1004.896 MB total, 1995.284 MB high water Using linear spline charge discretization. Grid dimensions: 161 x 161 x 161 Grid spacings: 0.700 x 0.569 x 0.725 Grid lengths: 112.000 x 91.000 x 116.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.400 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.920618662320E+05 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #3 (mol2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.5959 A Current memory usage: 1005.881 MB total, 1995.284 MB high water Using linear spline charge discretization. Grid dimensions: 161 x 161 x 161 Grid spacings: 0.975 x 0.756 x 1.012 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.400 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.529297900572E+05 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #4 (mol2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.5959 A Current memory usage: 1005.881 MB total, 1997.252 MB high water Using linear spline charge discretization. Grid dimensions: 161 x 161 x 161 Grid spacings: 0.700 x 0.569 x 0.725 Grid lengths: 112.000 x 91.000 x 116.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.400 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.916592202835E+05 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #5 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.5959 A Current memory usage: 1018.381 MB total, 1997.252 MB high water Using linear spline charge discretization. Grid dimensions: 161 x 161 x 161 Grid spacings: 0.975 x 0.756 x 1.012 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.400 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 3.059244262535E+05 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #6 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.5959 A Current memory usage: 1018.381 MB total, 2013.407 MB high water Using linear spline charge discretization. Grid dimensions: 161 x 161 x 161 Grid spacings: 0.700 x 0.569 x 0.725 Grid lengths: 112.000 x 91.000 x 116.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.400 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 5.838306706232E+05 kJ/mol Calculating forces... ---------------------------------------- PRINT STATEMENTS print energy 3 (complex) - 2 (mol2) - 1 (mol1) end Local net energy (PE 0) = 1.095841077691E+02 kJ/mol Global net ELEC energy = 1.095841077691E+02 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 2013.407 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-smol-auto.out RESULT 152863.2421825 RESULT 292061.866232 RESULT 152929.7900572 RESULT 291659.2202835 RESULT 305924.4262535 RESULT 583830.6706232 RESULT 109.5841077691 Testing computed result 1.528632421825E+05 against expected result 1.528632E+05 *** PASSED *** Testing computed result 2.920618662320E+05 against expected result 2.920619E+05 *** PASSED *** Testing computed result 1.529297900572E+05 against expected result 1.529298E+05 *** PASSED *** Testing computed result 2.916592202835E+05 against expected result 2.916592E+05 *** PASSED *** Testing computed result 3.059244262535E+05 against expected result 3.059244E+05 *** PASSED *** Testing computed result 5.838306706232E+05 against expected result 5.838307E+05 *** PASSED *** Testing computed result 1.095841077691E+02 against expected result 1.095841E+02 *** PASSED *** Elapsed time: 410.481336 seconds -------------------------------------------------------------------------------- Total elapsed time: 977.766215 seconds Test results have been logged -------------------------------------------------------------------------------- Running tests for actin-dimer-parallel section -------------------------------------------------------------------------------- Testing input file apbs-mol-parallel.in Splitting the input file into 8 separate files using the inputgen utility BINARY: apbs INPUT: apbs-mol-parallel-PE0.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-mol-parallel-PE0.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from mol1.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 5877 atoms Centered at (1.535e+01, -3.100e-02, 2.993e+00) Net charge -1.20e+01 e Reading PQR-format atom data from mol2.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 5877 atoms Centered at (-1.404e+01, -3.356e+00, 3.049e+01) Net charge -1.20e+01 e Reading PQR-format atom data from complex.pqr. 11754 atoms Centered at (2.518e+00, -2.465e+00, 1.674e+01) Net charge -2.40e+01 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (mol1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 251.247 MB total, 251.247 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.335181353180E+03 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #2 (mol1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 251.247 MB total, 487.987 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (-20.091, -20.834, -6.674) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.307364282738E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #3 (mol2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 252.233 MB total, 487.987 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.892640552270E+03 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #4 (mol2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 252.233 MB total, 489.955 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (-20.091, -20.834, -6.674) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.287357981689E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #5 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 264.732 MB total, 489.955 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 4.237489755360E+03 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #6 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 264.732 MB total, 506.110 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (-20.091, -20.834, -6.674) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Potential to be written to pot.dx Total electrostatic energy = 3.595556713401E+04 kJ/mol Calculating forces... Writing potential to pot-PE0.dx ---------------------------------------- PRINT STATEMENTS print energy 3 (complex) - 1 (mol1) - 2 (mol2) end Local net energy (PE 0) = 8.344489735027E+00 kJ/mol Global net ELEC energy = 8.344489735027E+00 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 506.110 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-mol-parallel-PE0.out Processor 0 results: 1.335181353180E+03 1.307364282738E+04 2.892640552270E+03 2.287357981689E+04 4.237489755360E+03 3.595556713401E+04 8.344489735027E+00 BINARY: apbs INPUT: apbs-mol-parallel-PE1.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-mol-parallel-PE1.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from mol1.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 5877 atoms Centered at (1.535e+01, -3.100e-02, 2.993e+00) Net charge -1.20e+01 e Reading PQR-format atom data from mol2.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 5877 atoms Centered at (-1.404e+01, -3.356e+00, 3.049e+01) Net charge -1.20e+01 e Reading PQR-format atom data from complex.pqr. 11754 atoms Centered at (2.518e+00, -2.465e+00, 1.674e+01) Net charge -2.40e+01 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (mol1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 251.247 MB total, 251.247 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.161150884899E+04 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #2 (mol1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 251.247 MB total, 487.987 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (25.127, -20.834, -6.674) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 9.271349239954E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #3 (mol2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 252.233 MB total, 487.987 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = -1.084559511557E-01 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #4 (mol2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 252.233 MB total, 489.955 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (25.127, -20.834, -6.674) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = -9.159185455930E-02 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #5 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 264.732 MB total, 489.955 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.161009682231E+04 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #6 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 264.732 MB total, 506.110 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (25.127, -20.834, -6.674) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Potential to be written to pot.dx Total electrostatic energy = 9.271249973273E+04 kJ/mol Calculating forces... Writing potential to pot-PE0.dx ---------------------------------------- PRINT STATEMENTS print energy 3 (complex) - 1 (mol1) - 2 (mol2) end Local net energy (PE 0) = -9.010749548383E-01 kJ/mol Global net ELEC energy = -9.010749548383E-01 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 506.110 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-mol-parallel-PE1.out Processor 1 results: 1.161150884899E+04 9.271349239954E+04 1.084559511557E-01 9.159185455930E-02 1.161009682231E+04 9.271249973273E+04 -9.010749548383E-01 BINARY: apbs INPUT: apbs-mol-parallel-PE2.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-mol-parallel-PE2.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from mol1.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 5877 atoms Centered at (1.535e+01, -3.100e-02, 2.993e+00) Net charge -1.20e+01 e Reading PQR-format atom data from mol2.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 5877 atoms Centered at (-1.404e+01, -3.356e+00, 3.049e+01) Net charge -1.20e+01 e Reading PQR-format atom data from complex.pqr. 11754 atoms Centered at (2.518e+00, -2.465e+00, 1.674e+01) Net charge -2.40e+01 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (mol1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 251.247 MB total, 251.247 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = -1.533327920982E+01 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #2 (mol1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 251.247 MB total, 487.987 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (-20.091, 15.905, -6.674) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 3.349327483109E+02 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #3 (mol2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 252.233 MB total, 487.987 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 4.753646268927E+03 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #4 (mol2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 252.233 MB total, 489.955 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (-20.091, 15.905, -6.674) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 3.716901575464E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #5 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 264.732 MB total, 489.955 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 4.760706267384E+03 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #6 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 264.732 MB total, 506.110 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (-20.091, 15.905, -6.674) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Potential to be written to pot.dx Total electrostatic energy = 3.753396861378E+04 kJ/mol Calculating forces... Writing potential to pot-PE0.dx ---------------------------------------- PRINT STATEMENTS print energy 3 (complex) - 1 (mol1) - 2 (mol2) end Local net energy (PE 0) = 3.002011083291E+01 kJ/mol Global net ELEC energy = 3.002011083291E+01 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 506.110 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-mol-parallel-PE2.out Processor 2 results: 1.533327920982E+01 3.349327483109E+02 4.753646268927E+03 3.716901575464E+04 4.760706267384E+03 3.753396861378E+04 3.002011083291E+01 BINARY: apbs INPUT: apbs-mol-parallel-PE3.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-mol-parallel-PE3.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from mol1.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 5877 atoms Centered at (1.535e+01, -3.100e-02, 2.993e+00) Net charge -1.20e+01 e Reading PQR-format atom data from mol2.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 5877 atoms Centered at (-1.404e+01, -3.356e+00, 3.049e+01) Net charge -1.20e+01 e Reading PQR-format atom data from complex.pqr. 11754 atoms Centered at (2.518e+00, -2.465e+00, 1.674e+01) Net charge -2.40e+01 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (mol1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 251.247 MB total, 251.247 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.803290534287E+04 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #2 (mol1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 251.247 MB total, 487.987 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (25.127, 15.905, -6.674) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.400275505449E+05 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #3 (mol2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 252.233 MB total, 487.987 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = -8.150603559111E-01 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #4 (mol2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 252.233 MB total, 489.955 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (25.127, 15.905, -6.674) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = -8.573366340513E-01 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #5 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 264.732 MB total, 489.955 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.804039178218E+04 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #6 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 264.732 MB total, 506.110 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (25.127, 15.905, -6.674) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Potential to be written to pot.dx Total electrostatic energy = 1.400354034488E+05 kJ/mol Calculating forces... Writing potential to pot-PE0.dx ---------------------------------------- PRINT STATEMENTS print energy 3 (complex) - 1 (mol1) - 2 (mol2) end Local net energy (PE 0) = 8.710240552123E+00 kJ/mol Global net ELEC energy = 8.710240552123E+00 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 506.110 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-mol-parallel-PE3.out Processor 3 results: 1.803290534287E+04 1.400275505449E+05 8.150603559111E-01 8.573366340513E-01 1.804039178218E+04 1.400354034488E+05 8.710240552123E+00 BINARY: apbs INPUT: apbs-mol-parallel-PE4.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-mol-parallel-PE4.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from mol1.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 5877 atoms Centered at (1.535e+01, -3.100e-02, 2.993e+00) Net charge -1.20e+01 e Reading PQR-format atom data from mol2.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 5877 atoms Centered at (-1.404e+01, -3.356e+00, 3.049e+01) Net charge -1.20e+01 e Reading PQR-format atom data from complex.pqr. 11754 atoms Centered at (2.518e+00, -2.465e+00, 1.674e+01) Net charge -2.40e+01 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (mol1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 251.247 MB total, 251.247 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 4.015087619451E+02 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #2 (mol1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 251.247 MB total, 487.987 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (-20.091, -20.834, 40.159) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 3.216054441666E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #3 (mol2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 252.233 MB total, 487.987 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.620207421716E+04 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #4 (mol2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 252.233 MB total, 489.955 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (-20.091, -20.834, 40.159) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.273875050379E+05 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #5 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 264.732 MB total, 489.955 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.666622027749E+04 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #6 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 264.732 MB total, 506.110 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (-20.091, -20.834, 40.159) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Potential to be written to pot.dx Total electrostatic energy = 1.306246439444E+05 kJ/mol Calculating forces... Writing potential to pot-PE0.dx ---------------------------------------- PRINT STATEMENTS print energy 3 (complex) - 1 (mol1) - 2 (mol2) end Local net energy (PE 0) = 2.108446480102E+01 kJ/mol Global net ELEC energy = 2.108446480102E+01 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 506.110 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-mol-parallel-PE4.out Processor 4 results: 4.015087619451E+02 3.216054441666E+03 1.620207421716E+04 1.273875050379E+05 1.666622027749E+04 1.306246439444E+05 2.108446480102E+01 BINARY: apbs INPUT: apbs-mol-parallel-PE5.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-mol-parallel-PE5.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from mol1.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 5877 atoms Centered at (1.535e+01, -3.100e-02, 2.993e+00) Net charge -1.20e+01 e Reading PQR-format atom data from mol2.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 5877 atoms Centered at (-1.404e+01, -3.356e+00, 3.049e+01) Net charge -1.20e+01 e Reading PQR-format atom data from complex.pqr. 11754 atoms Centered at (2.518e+00, -2.465e+00, 1.674e+01) Net charge -2.40e+01 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (mol1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 251.247 MB total, 251.247 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.100112513614E+03 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #2 (mol1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 251.247 MB total, 487.987 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (25.127, -20.834, 40.159) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.662571883858E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #3 (mol2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 252.233 MB total, 487.987 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = -4.370921758038E-01 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #4 (mol2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 252.233 MB total, 489.955 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (25.127, -20.834, 40.159) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = -4.013366922344E-01 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #5 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 264.732 MB total, 489.955 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.115105077953E+03 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #6 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 264.732 MB total, 506.110 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (25.127, -20.834, 40.159) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Potential to be written to pot.dx Total electrostatic energy = 1.662768924081E+04 kJ/mol Calculating forces... Writing potential to pot-PE0.dx ---------------------------------------- PRINT STATEMENTS print energy 3 (complex) - 1 (mol1) - 2 (mol2) end Local net energy (PE 0) = 2.371738924664E+00 kJ/mol Global net ELEC energy = 2.371738924664E+00 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 506.110 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-mol-parallel-PE5.out Processor 5 results: 2.100112513614E+03 1.662571883858E+04 4.370921758038E-01 4.013366922344E-01 2.115105077953E+03 1.662768924081E+04 2.371738924664E+00 BINARY: apbs INPUT: apbs-mol-parallel-PE6.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-mol-parallel-PE6.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from mol1.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 5877 atoms Centered at (1.535e+01, -3.100e-02, 2.993e+00) Net charge -1.20e+01 e Reading PQR-format atom data from mol2.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 5877 atoms Centered at (-1.404e+01, -3.356e+00, 3.049e+01) Net charge -1.20e+01 e Reading PQR-format atom data from complex.pqr. 11754 atoms Centered at (2.518e+00, -2.465e+00, 1.674e+01) Net charge -2.40e+01 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (mol1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 251.247 MB total, 251.247 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = -2.817378781616E+00 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #2 (mol1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 251.247 MB total, 487.987 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (-20.091, 15.905, 40.159) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = -1.959534462269E+00 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #3 (mol2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 252.233 MB total, 487.987 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.176793266728E+04 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #4 (mol2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 252.233 MB total, 489.955 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (-20.091, 15.905, 40.159) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 9.643533578081E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #5 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 264.732 MB total, 489.955 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.176229449467E+04 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #6 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 264.732 MB total, 506.110 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (-20.091, 15.905, 40.159) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Potential to be written to pot.dx Total electrostatic energy = 9.643148330287E+04 kJ/mol Calculating forces... Writing potential to pot-PE0.dx ---------------------------------------- PRINT STATEMENTS print energy 3 (complex) - 1 (mol1) - 2 (mol2) end Local net energy (PE 0) = -1.892943480823E+00 kJ/mol Global net ELEC energy = -1.892943480823E+00 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 506.110 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-mol-parallel-PE6.out Processor 6 results: 2.817378781616E+00 1.959534462269E+00 1.176793266728E+04 9.643533578081E+04 1.176229449467E+04 9.643148330287E+04 -1.892943480823E+00 BINARY: apbs INPUT: apbs-mol-parallel-PE7.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-mol-parallel-PE7.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from mol1.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 5877 atoms Centered at (1.535e+01, -3.100e-02, 2.993e+00) Net charge -1.20e+01 e Reading PQR-format atom data from mol2.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 5877 atoms Centered at (-1.404e+01, -3.356e+00, 3.049e+01) Net charge -1.20e+01 e Reading PQR-format atom data from complex.pqr. 11754 atoms Centered at (2.518e+00, -2.465e+00, 1.674e+01) Net charge -2.40e+01 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (mol1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 251.247 MB total, 251.247 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.428230292158E+03 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #2 (mol1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 251.247 MB total, 487.987 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (25.127, 15.905, 40.159) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.199832997920E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #3 (mol2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 252.233 MB total, 487.987 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 3.881300088062E+02 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #4 (mol2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 252.233 MB total, 489.955 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (25.127, 15.905, 40.159) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 4.152799174875E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #5 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 264.732 MB total, 489.955 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.847712854852E+03 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #6 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 264.732 MB total, 506.110 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (25.127, 15.905, 40.159) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Potential to be written to pot.dx Total electrostatic energy = 2.618156668929E+04 kJ/mol Calculating forces... Writing potential to pot-PE0.dx ---------------------------------------- PRINT STATEMENTS print energy 3 (complex) - 1 (mol1) - 2 (mol2) end Local net energy (PE 0) = 3.043753521011E+01 kJ/mol Global net ELEC energy = 3.043753521011E+01 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 506.110 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-mol-parallel-PE7.out Processor 7 results: 2.428230292158E+03 2.199832997920E+04 3.881300088062E+02 4.152799174875E+03 2.847712854852E+03 2.618156668929E+04 3.043753521011E+01 RESULT 35927.59777074854 RESULT 287991.6813140391 RESULT 36005.78432292607 RESULT 288019.58583029587 RESULT 72040.017332199 RESULT 576102.8221066899 RESULT 98.1745616201927 Testing computed result 3.592759777075E+04 against expected result 3.592760E+04 *** PASSED *** Testing computed result 2.879916813140E+05 against expected result 2.879917E+05 *** PASSED *** Testing computed result 3.600578432293E+04 against expected result 3.600578E+04 *** PASSED *** Testing computed result 2.880195858303E+05 against expected result 2.880196E+05 *** PASSED *** Testing computed result 7.204001733220E+04 against expected result 7.204002E+04 *** PASSED *** Testing computed result 5.761028221067E+05 against expected result 5.761028E+05 *** PASSED *** Testing computed result 9.817456162019E+01 against expected result 9.817456E+01 *** PASSED *** Elapsed time: 1676.544934 seconds -------------------------------------------------------------------------------- -------------------------------------------------------------------------------- Testing input file apbs-smol-parallel.in Splitting the input file into 8 separate files using the inputgen utility BINARY: apbs INPUT: apbs-smol-parallel-PE0.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-smol-parallel-PE0.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from mol1.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 5877 atoms Centered at (1.535e+01, -3.100e-02, 2.993e+00) Net charge -1.20e+01 e Reading PQR-format atom data from mol2.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 5877 atoms Centered at (-1.404e+01, -3.356e+00, 3.049e+01) Net charge -1.20e+01 e Reading PQR-format atom data from complex.pqr. 11754 atoms Centered at (2.518e+00, -2.465e+00, 1.674e+01) Net charge -2.40e+01 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (mol1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 251.247 MB total, 251.247 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.371266245949E+03 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #2 (mol1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 251.247 MB total, 487.987 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (-20.091, -20.834, -6.674) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.306912276054E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #3 (mol2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 252.233 MB total, 487.987 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.977036667733E+03 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #4 (mol2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 252.233 MB total, 489.955 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (-20.091, -20.834, -6.674) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.288057348250E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #5 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 264.732 MB total, 489.955 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 4.356039288708E+03 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #6 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 264.732 MB total, 506.110 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (-20.091, -20.834, -6.674) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Potential to be written to pot.dx Total electrostatic energy = 3.595842845220E+04 kJ/mol Calculating forces... Writing potential to pot-PE0.dx ---------------------------------------- PRINT STATEMENTS print energy 3 (complex) - 1 (mol1) - 2 (mol2) end Local net energy (PE 0) = 8.732209150865E+00 kJ/mol Global net ELEC energy = 8.732209150865E+00 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 506.110 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-smol-parallel-PE0.out Processor 0 results: 1.371266245949E+03 1.306912276054E+04 2.977036667733E+03 2.288057348250E+04 4.356039288708E+03 3.595842845220E+04 8.732209150865E+00 BINARY: apbs INPUT: apbs-smol-parallel-PE1.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-smol-parallel-PE1.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from mol1.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 5877 atoms Centered at (1.535e+01, -3.100e-02, 2.993e+00) Net charge -1.20e+01 e Reading PQR-format atom data from mol2.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 5877 atoms Centered at (-1.404e+01, -3.356e+00, 3.049e+01) Net charge -1.20e+01 e Reading PQR-format atom data from complex.pqr. 11754 atoms Centered at (2.518e+00, -2.465e+00, 1.674e+01) Net charge -2.40e+01 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (mol1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 251.247 MB total, 251.247 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.183935033618E+04 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #2 (mol1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 251.247 MB total, 487.987 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (25.127, -20.834, -6.674) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 9.276168507128E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #3 (mol2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 252.233 MB total, 487.987 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = -1.420924995464E-01 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #4 (mol2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 252.233 MB total, 489.955 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (25.127, -20.834, -6.674) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = -1.129046670919E-01 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #5 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 264.732 MB total, 489.955 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.183791435221E+04 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #6 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 264.732 MB total, 506.110 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (25.127, -20.834, -6.674) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Potential to be written to pot.dx Total electrostatic energy = 9.276041697078E+04 kJ/mol Calculating forces... Writing potential to pot-PE0.dx ---------------------------------------- PRINT STATEMENTS print energy 3 (complex) - 1 (mol1) - 2 (mol2) end Local net energy (PE 0) = -1.155195837104E+00 kJ/mol Global net ELEC energy = -1.155195837104E+00 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 506.110 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-smol-parallel-PE1.out Processor 1 results: 1.183935033618E+04 9.276168507128E+04 1.420924995464E-01 1.129046670919E-01 1.183791435221E+04 9.276041697078E+04 -1.155195837104E+00 BINARY: apbs INPUT: apbs-smol-parallel-PE2.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-smol-parallel-PE2.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from mol1.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 5877 atoms Centered at (1.535e+01, -3.100e-02, 2.993e+00) Net charge -1.20e+01 e Reading PQR-format atom data from mol2.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 5877 atoms Centered at (-1.404e+01, -3.356e+00, 3.049e+01) Net charge -1.20e+01 e Reading PQR-format atom data from complex.pqr. 11754 atoms Centered at (2.518e+00, -2.465e+00, 1.674e+01) Net charge -2.40e+01 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (mol1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 251.247 MB total, 251.247 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = -9.992726432058E+00 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #2 (mol1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 251.247 MB total, 487.987 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (-20.091, 15.905, -6.674) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 3.375960934473E+02 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #3 (mol2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 252.233 MB total, 487.987 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 4.863608503641E+03 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #4 (mol2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 252.233 MB total, 489.955 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (-20.091, 15.905, -6.674) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 3.720602537782E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #5 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 264.732 MB total, 489.955 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 4.896854387650E+03 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #6 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 264.732 MB total, 506.110 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (-20.091, 15.905, -6.674) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Potential to be written to pot.dx Total electrostatic energy = 3.757590620855E+04 kJ/mol Calculating forces... Writing potential to pot-PE0.dx ---------------------------------------- PRINT STATEMENTS print energy 3 (complex) - 1 (mol1) - 2 (mol2) end Local net energy (PE 0) = 3.228473728523E+01 kJ/mol Global net ELEC energy = 3.228473728523E+01 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 506.110 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-smol-parallel-PE2.out Processor 2 results: 9.992726432058E+00 3.375960934473E+02 4.863608503641E+03 3.720602537782E+04 4.896854387650E+03 3.757590620855E+04 3.228473728523E+01 BINARY: apbs INPUT: apbs-smol-parallel-PE3.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-smol-parallel-PE3.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from mol1.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 5877 atoms Centered at (1.535e+01, -3.100e-02, 2.993e+00) Net charge -1.20e+01 e Reading PQR-format atom data from mol2.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 5877 atoms Centered at (-1.404e+01, -3.356e+00, 3.049e+01) Net charge -1.20e+01 e Reading PQR-format atom data from complex.pqr. 11754 atoms Centered at (2.518e+00, -2.465e+00, 1.674e+01) Net charge -2.40e+01 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (mol1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 251.247 MB total, 251.247 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.826846317904E+04 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #2 (mol1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 251.247 MB total, 487.987 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (25.127, 15.905, -6.674) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.401007397614E+05 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #3 (mol2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 252.233 MB total, 487.987 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = -9.966525690477E-01 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #4 (mol2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 252.233 MB total, 489.955 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (25.127, 15.905, -6.674) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = -8.961424692860E-01 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #5 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 264.732 MB total, 489.955 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.827933209233E+04 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #6 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 264.732 MB total, 506.110 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (25.127, 15.905, -6.674) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Potential to be written to pot.dx Total electrostatic energy = 1.401092487740E+05 kJ/mol Calculating forces... Writing potential to pot-PE0.dx ---------------------------------------- PRINT STATEMENTS print energy 3 (complex) - 1 (mol1) - 2 (mol2) end Local net energy (PE 0) = 9.405155087970E+00 kJ/mol Global net ELEC energy = 9.405155087970E+00 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 506.110 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-smol-parallel-PE3.out Processor 3 results: 1.826846317904E+04 1.401007397614E+05 9.966525690477E-01 8.961424692860E-01 1.827933209233E+04 1.401092487740E+05 9.405155087970E+00 BINARY: apbs INPUT: apbs-smol-parallel-PE4.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-smol-parallel-PE4.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from mol1.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 5877 atoms Centered at (1.535e+01, -3.100e-02, 2.993e+00) Net charge -1.20e+01 e Reading PQR-format atom data from mol2.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 5877 atoms Centered at (-1.404e+01, -3.356e+00, 3.049e+01) Net charge -1.20e+01 e Reading PQR-format atom data from complex.pqr. 11754 atoms Centered at (2.518e+00, -2.465e+00, 1.674e+01) Net charge -2.40e+01 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (mol1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 251.247 MB total, 251.247 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 4.021998204986E+02 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #2 (mol1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 251.247 MB total, 487.987 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (-20.091, -20.834, 40.159) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 3.215581388579E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #3 (mol2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 252.233 MB total, 487.987 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.644646339930E+04 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #4 (mol2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 252.233 MB total, 489.955 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (-20.091, -20.834, 40.159) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.274227930024E+05 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #5 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 264.732 MB total, 489.955 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.689865332202E+04 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #6 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 264.732 MB total, 506.110 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (-20.091, -20.834, 40.159) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Potential to be written to pot.dx Total electrostatic energy = 1.306747503910E+05 kJ/mol Calculating forces... Writing potential to pot-PE0.dx ---------------------------------------- PRINT STATEMENTS print energy 3 (complex) - 1 (mol1) - 2 (mol2) end Local net energy (PE 0) = 3.637600005489E+01 kJ/mol Global net ELEC energy = 3.637600005489E+01 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 506.110 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-smol-parallel-PE4.out Processor 4 results: 4.021998204986E+02 3.215581388579E+03 1.644646339930E+04 1.274227930024E+05 1.689865332202E+04 1.306747503910E+05 3.637600005489E+01 BINARY: apbs INPUT: apbs-smol-parallel-PE5.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-smol-parallel-PE5.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from mol1.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 5877 atoms Centered at (1.535e+01, -3.100e-02, 2.993e+00) Net charge -1.20e+01 e Reading PQR-format atom data from mol2.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 5877 atoms Centered at (-1.404e+01, -3.356e+00, 3.049e+01) Net charge -1.20e+01 e Reading PQR-format atom data from complex.pqr. 11754 atoms Centered at (2.518e+00, -2.465e+00, 1.674e+01) Net charge -2.40e+01 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (mol1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 251.247 MB total, 251.247 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.187673595319E+03 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #2 (mol1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 251.247 MB total, 487.987 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (25.127, -20.834, 40.159) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.663590032901E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #3 (mol2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 252.233 MB total, 487.987 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = -4.710032885061E-01 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #4 (mol2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 252.233 MB total, 489.955 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (25.127, -20.834, 40.159) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = -4.849499127484E-01 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #5 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 264.732 MB total, 489.955 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.189033693728E+03 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #6 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 264.732 MB total, 506.110 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (25.127, -20.834, 40.159) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Potential to be written to pot.dx Total electrostatic energy = 1.663641996916E+04 kJ/mol Calculating forces... Writing potential to pot-PE0.dx ---------------------------------------- PRINT STATEMENTS print energy 3 (complex) - 1 (mol1) - 2 (mol2) end Local net energy (PE 0) = 1.004590063272E+00 kJ/mol Global net ELEC energy = 1.004590063272E+00 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 506.110 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-smol-parallel-PE5.out Processor 5 results: 2.187673595319E+03 1.663590032901E+04 4.710032885061E-01 4.849499127484E-01 2.189033693728E+03 1.663641996916E+04 1.004590063272E+00 BINARY: apbs INPUT: apbs-smol-parallel-PE6.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-smol-parallel-PE6.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from mol1.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 5877 atoms Centered at (1.535e+01, -3.100e-02, 2.993e+00) Net charge -1.20e+01 e Reading PQR-format atom data from mol2.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 5877 atoms Centered at (-1.404e+01, -3.356e+00, 3.049e+01) Net charge -1.20e+01 e Reading PQR-format atom data from complex.pqr. 11754 atoms Centered at (2.518e+00, -2.465e+00, 1.674e+01) Net charge -2.40e+01 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (mol1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 251.247 MB total, 251.247 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = -4.897659240526E+00 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #2 (mol1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 251.247 MB total, 487.987 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (-20.091, 15.905, 40.159) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = -2.552765434658E+00 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #3 (mol2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 252.233 MB total, 487.987 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.200266111088E+04 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #4 (mol2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 252.233 MB total, 489.955 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (-20.091, 15.905, 40.159) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 9.646358551314E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #5 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 264.732 MB total, 489.955 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.199560371894E+04 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #6 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 264.732 MB total, 506.110 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (-20.091, 15.905, 40.159) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Potential to be written to pot.dx Total electrostatic energy = 9.645933328248E+04 kJ/mol Calculating forces... Writing potential to pot-PE0.dx ---------------------------------------- PRINT STATEMENTS print energy 3 (complex) - 1 (mol1) - 2 (mol2) end Local net energy (PE 0) = -1.699465221449E+00 kJ/mol Global net ELEC energy = -1.699465221449E+00 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 506.110 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-smol-parallel-PE6.out Processor 6 results: 4.897659240526E+00 2.552765434658E+00 1.200266111088E+04 9.646358551314E+04 1.199560371894E+04 9.645933328248E+04 -1.699465221449E+00 BINARY: apbs INPUT: apbs-smol-parallel-PE7.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-smol-parallel-PE7.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from mol1.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 5877 atoms Centered at (1.535e+01, -3.100e-02, 2.993e+00) Net charge -1.20e+01 e Reading PQR-format atom data from mol2.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 5877 atoms Centered at (-1.404e+01, -3.356e+00, 3.049e+01) Net charge -1.20e+01 e Reading PQR-format atom data from complex.pqr. 11754 atoms Centered at (2.518e+00, -2.465e+00, 1.674e+01) Net charge -2.40e+01 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (mol1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 251.247 MB total, 251.247 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.521894873214E+03 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #2 (mol1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 251.247 MB total, 487.987 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (25.127, 15.905, 40.159) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.200161660501E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #3 (mol2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 252.233 MB total, 487.987 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 4.033680106430E+02 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #4 (mol2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 252.233 MB total, 489.955 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (25.127, 15.905, 40.159) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 4.154432431334E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #5 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 264.732 MB total, 489.955 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 1.625 x 1.260 x 1.688 Grid lengths: 156.000 x 121.000 x 162.000 Grid center: (2.518, -2.465, 16.742) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.960165191413E+03 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #6 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.608 A Current memory usage: 264.732 MB total, 506.110 MB high water Using linear spline charge discretization. Partition overlap fraction = 0.1 Processor array = 2 x 2 x 2 Grid dimensions: 97 x 97 x 97 Grid spacings: 0.696 x 0.565 x 0.720 Grid lengths: 66.783 x 54.261 x 69.168 Grid center: (25.127, 15.905, 40.159) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Potential to be written to pot.dx Total electrostatic energy = 2.618664307349E+04 kJ/mol Calculating forces... Writing potential to pot-PE0.dx ---------------------------------------- PRINT STATEMENTS print energy 3 (complex) - 1 (mol1) - 2 (mol2) end Local net energy (PE 0) = 3.059403714563E+01 kJ/mol Global net ELEC energy = 3.059403714563E+01 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 506.110 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-smol-parallel-PE7.out Processor 7 results: 2.521894873214E+03 2.200161660501E+04 4.033680106430E+02 4.154432431334E+03 2.960165191413E+03 2.618664307349E+04 3.059403714563E+01 RESULT 36605.73843587318 RESULT 288124.794774701 RESULT 36694.74744055409 RESULT 288128.90380424313 RESULT 73413.59604699901 RESULT 576361.14712166 RESULT 115.542067729304 Testing computed result 3.660573843587E+04 against expected result 3.660574E+04 *** PASSED *** Testing computed result 2.881247947747E+05 against expected result 2.881248E+05 *** PASSED *** Testing computed result 3.669474744055E+04 against expected result 3.669475E+04 *** PASSED *** Testing computed result 2.881289038042E+05 against expected result 2.881289E+05 *** PASSED *** Testing computed result 7.341359604700E+04 against expected result 7.341360E+04 *** PASSED *** Testing computed result 5.763611471217E+05 against expected result 5.763611E+05 *** PASSED *** Testing computed result 1.155420677293E+02 against expected result 1.155421E+02 *** PASSED *** Elapsed time: 864.250831 seconds -------------------------------------------------------------------------------- Total elapsed time: 2540.795765 seconds Test results have been logged -------------------------------------------------------------------------------- Running tests for alkanes section -------------------------------------------------------------------------------- Testing input file alkanes.in BINARY: apbs INPUT: alkanes.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file alkanes.in... rank 0 size 1... Parsed input file. Reading parameter data from parm.dat. Got paths for 11 molecules Reading PDB-format atom data from 2-methylbutane.pdb. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 17 atoms Centered at (0.000e+00, 0.000e+00, 0.000e+00) Net charge 4.33e+00 e Reading PDB-format atom data from butane.pdb. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 14 atoms Centered at (3.917e+00, 7.025e-01, -8.575e+00) Net charge 3.51e+00 e Reading PDB-format atom data from cyclohexane.pdb. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 18 atoms Centered at (1.123e+00, 5.880e-01, 7.680e-01) Net charge 4.93e+00 e Reading PDB-format atom data from cyclopentane.pdb. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 13 atoms Centered at (1.320e+00, 5.255e-01, 1.289e+00) Net charge 3.88e+00 e Reading PDB-format atom data from ethane.pdb. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 8 atoms Centered at (2.210e-01, -2.100e-02, 7.650e-01) Net charge 1.87e+00 e Reading PDB-format atom data from hexane.pdb. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 20 atoms Centered at (4.951e+00, -9.500e-03, -8.406e+00) Net charge 5.16e+00 e Reading PDB-format atom data from isobutane.pdb. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 14 atoms Centered at (1.859e+01, 1.864e+01, 1.921e+01) Net charge 3.51e+00 e Reading PDB-format atom data from methane.pdb. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 5 atoms Centered at (1.803e+01, 1.779e+01, 1.782e+01) Net charge 1.05e+00 e Reading PDB-format atom data from neopentane.pdb. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 17 atoms Centered at (1.867e+01, 1.894e+01, 1.920e+01) Net charge 4.33e+00 e Reading PDB-format atom data from pentane.pdb. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 17 atoms Centered at (4.460e+00, 1.615e-01, -8.566e+00) Net charge 4.33e+00 e Reading PDB-format atom data from propane.pdb. 11 atoms Centered at (1.836e+01, 1.896e+01, 1.861e+01) Net charge 2.69e+00 e Preparing to run 11 PBE calculations. ---------------------------------------- CALCULATION #1 (solvated-2-methylbutane): APOLAR Solvent Accessible Surface Area (SASA) for each atom: SASA for atom 0: 3.815624614267E+00 SASA for atom 1: 0.000000000000E+00 SASA for atom 2: 6.122920124655E-01 SASA for atom 3: 3.957497153740E+00 SASA for atom 4: 4.308445014544E+00 SASA for atom 5: 1.843264951960E+01 SASA for atom 6: 1.837011296483E+01 SASA for atom 7: 1.666599184724E+01 SASA for atom 8: 1.480031796315E+01 SASA for atom 9: 1.603020354037E+01 SASA for atom 10: 1.473778140838E+01 SASA for atom 11: 1.611879699297E+01 SASA for atom 12: 1.810954398660E+01 SASA for atom 13: 1.420100931324E+01 SASA for atom 14: 1.437298483886E+01 SASA for atom 15: 1.814081226399E+01 SASA for atom 16: 2.152820898091E+01 Total solvent accessible surface area: 214.202 A^2 Surface tension*area energies (gamma * SASA) for each atom: Surface tension*area energy for atom 0: 3.243280922127E-02 Surface tension*area energy for atom 1: 0.000000000000E+00 Surface tension*area energy for atom 2: 5.204482105957E-03 Surface tension*area energy for atom 3: 3.363872580679E-02 Surface tension*area energy for atom 4: 3.662178262362E-02 Surface tension*area energy for atom 5: 1.566775209166E-01 Surface tension*area energy for atom 6: 1.561459602010E-01 Surface tension*area energy for atom 7: 1.416609307015E-01 Surface tension*area energy for atom 8: 1.258027026868E-01 Surface tension*area energy for atom 9: 1.362567300932E-01 Surface tension*area energy for atom 10: 1.252711419712E-01 Surface tension*area energy for atom 11: 1.370097744402E-01 Surface tension*area energy for atom 12: 1.539311238861E-01 Surface tension*area energy for atom 13: 1.207085791625E-01 Surface tension*area energy for atom 14: 1.221703711303E-01 Surface tension*area energy for atom 15: 1.541969042439E-01 Surface tension*area energy for atom 16: 1.829897763377E-01 Total surface tension energy: 1.82072 kJ/mol Total solvent accessible volume: 253.665 A^3 Total pressure*volume energy: 60.7274 kJ/mol WCA dispersion Energies for each atom: WCA energy for atom 0: -6.271287875274E+00 WCA energy for atom 1: -5.600872869478E+00 WCA energy for atom 2: -5.773775123943E+00 WCA energy for atom 3: -6.072801488986E+00 WCA energy for atom 4: -6.378470721845E+00 WCA energy for atom 5: -1.573474558351E+00 WCA energy for atom 6: -1.582338715648E+00 WCA energy for atom 7: -1.504044838266E+00 WCA energy for atom 8: -1.351002262819E+00 WCA energy for atom 9: -1.437367175239E+00 WCA energy for atom 10: -1.384626257493E+00 WCA energy for atom 11: -1.468867560891E+00 WCA energy for atom 12: -1.557005662832E+00 WCA energy for atom 13: -1.473759654043E+00 WCA energy for atom 14: -1.502261431335E+00 WCA energy for atom 15: -1.550940901474E+00 WCA energy for atom 16: -1.667828659696E+00 Total WCA energy: -48.1507 kJ/mol Total non-polar energy = 1.439739455792E+01 kJ/mol ---------------------------------------- CALCULATION #2 (solvated-butane): APOLAR Solvent Accessible Surface Area (SASA) for each atom: SASA for atom 0: 4.405515699447E+00 SASA for atom 1: 8.213673337951E-01 SASA for atom 2: 8.064333822716E-01 SASA for atom 3: 4.375647796400E+00 SASA for atom 4: 1.855251124959E+01 SASA for atom 5: 2.147609518526E+01 SASA for atom 6: 1.852645435176E+01 SASA for atom 7: 1.660345529247E+01 SASA for atom 8: 1.658782115377E+01 SASA for atom 9: 1.658260977421E+01 SASA for atom 10: 1.658260977421E+01 SASA for atom 11: 2.145003828744E+01 SASA for atom 12: 1.852124297220E+01 SASA for atom 13: 1.856293400871E+01 Total solvent accessible surface area: 193.855 A^2 Surface tension*area energies (gamma * SASA) for each atom: Surface tension*area energy for atom 0: 3.744688344530E-02 Surface tension*area energy for atom 1: 6.981622337259E-03 Surface tension*area energy for atom 2: 6.854683749309E-03 Surface tension*area energy for atom 3: 3.719300626940E-02 Surface tension*area energy for atom 4: 1.576963456215E-01 Surface tension*area energy for atom 5: 1.825468090747E-01 Surface tension*area energy for atom 6: 1.574748619900E-01 Surface tension*area energy for atom 7: 1.411293699860E-01 Surface tension*area energy for atom 8: 1.409964798071E-01 Surface tension*area energy for atom 9: 1.409521830808E-01 Surface tension*area energy for atom 10: 1.409521830808E-01 Surface tension*area energy for atom 11: 1.823253254433E-01 Surface tension*area energy for atom 12: 1.574305652637E-01 Surface tension*area energy for atom 13: 1.577849390741E-01 Total surface tension energy: 1.64777 kJ/mol Total solvent accessible volume: 217.863 A^3 Total pressure*volume energy: 52.1564 kJ/mol WCA dispersion Energies for each atom: WCA energy for atom 0: -6.728858147814E+00 WCA energy for atom 1: -6.204037472587E+00 WCA energy for atom 2: -6.202937735018E+00 WCA energy for atom 3: -6.728762249931E+00 WCA energy for atom 4: -1.623549989062E+00 WCA energy for atom 5: -1.709092300778E+00 WCA energy for atom 6: -1.625196457114E+00 WCA energy for atom 7: -1.484289341167E+00 WCA energy for atom 8: -1.485410538626E+00 WCA energy for atom 9: -1.485593139015E+00 WCA energy for atom 10: -1.484878734279E+00 WCA energy for atom 11: -1.708585062695E+00 WCA energy for atom 12: -1.625094916482E+00 WCA energy for atom 13: -1.624416805392E+00 Total WCA energy: -41.7207 kJ/mol Total non-polar energy = 1.208346456826E+01 kJ/mol ---------------------------------------- CALCULATION #3 (solvated-cyclohexane): APOLAR Solvent Accessible Surface Area (SASA) for each atom: SASA for atom 0: 7.840324549863E-01 SASA for atom 1: 8.064333822716E-01 SASA for atom 2: 8.288343095569E-01 SASA for atom 3: 7.840324549863E-01 SASA for atom 4: 7.989664065098E-01 SASA for atom 5: 8.363012853187E-01 SASA for atom 6: 2.001169752764E+01 SASA for atom 7: 1.616048802948E+01 SASA for atom 8: 2.001169752764E+01 SASA for atom 9: 1.619175630687E+01 SASA for atom 10: 1.616048802948E+01 SASA for atom 11: 1.993352683418E+01 SASA for atom 12: 2.001169752764E+01 SASA for atom 13: 1.618133354774E+01 SASA for atom 14: 1.617091078861E+01 SASA for atom 15: 2.001690890721E+01 SASA for atom 16: 1.993873821374E+01 SASA for atom 17: 1.617091078861E+01 Total solvent accessible surface area: 221.799 A^2 Surface tension*area energies (gamma * SASA) for each atom: Surface tension*area energy for atom 0: 6.664275867383E-03 Surface tension*area energy for atom 1: 6.854683749309E-03 Surface tension*area energy for atom 2: 7.045091631234E-03 Surface tension*area energy for atom 3: 6.664275867383E-03 Surface tension*area energy for atom 4: 6.791214455333E-03 Surface tension*area energy for atom 5: 7.108560925209E-03 Surface tension*area energy for atom 6: 1.700994289850E-01 Surface tension*area energy for atom 7: 1.373641482506E-01 Surface tension*area energy for atom 8: 1.700994289850E-01 Surface tension*area energy for atom 9: 1.376299286084E-01 Surface tension*area energy for atom 10: 1.373641482506E-01 Surface tension*area energy for atom 11: 1.694349780905E-01 Surface tension*area energy for atom 12: 1.700994289850E-01 Surface tension*area energy for atom 13: 1.375413351558E-01 Surface tension*area energy for atom 14: 1.374527417032E-01 Surface tension*area energy for atom 15: 1.701437257113E-01 Surface tension*area energy for atom 16: 1.694792748168E-01 Surface tension*area energy for atom 17: 1.374527417032E-01 Total surface tension energy: 1.88529 kJ/mol Total solvent accessible volume: 267.435 A^3 Total pressure*volume energy: 64.0239 kJ/mol WCA dispersion Energies for each atom: WCA energy for atom 0: -5.793234697241E+00 WCA energy for atom 1: -5.784370526583E+00 WCA energy for atom 2: -5.791799130412E+00 WCA energy for atom 3: -5.788504399087E+00 WCA energy for atom 4: -5.797319672490E+00 WCA energy for atom 5: -5.787358035342E+00 WCA energy for atom 6: -1.523887929614E+00 WCA energy for atom 7: -1.413678912317E+00 WCA energy for atom 8: -1.521751604392E+00 WCA energy for atom 9: -1.414741802525E+00 WCA energy for atom 10: -1.413367854344E+00 WCA energy for atom 11: -1.523407238081E+00 WCA energy for atom 12: -1.523000623583E+00 WCA energy for atom 13: -1.413922068538E+00 WCA energy for atom 14: -1.416316744211E+00 WCA energy for atom 15: -1.524577474659E+00 WCA energy for atom 16: -1.523300410052E+00 WCA energy for atom 17: -1.414522566061E+00 Total WCA energy: -52.3691 kJ/mol Total non-polar energy = 1.354016672221E+01 kJ/mol ---------------------------------------- CALCULATION #4 (solvated-cyclopentane): APOLAR Solvent Accessible Surface Area (SASA) for each atom: SASA for atom 0: 9.490526193215E+00 SASA for atom 1: 9.512927120500E+00 SASA for atom 2: 2.299828534626E+00 SASA for atom 3: 1.919012770776E+00 SASA for atom 4: 2.307295510388E+00 SASA for atom 5: 2.325838699632E+01 SASA for atom 6: 2.325838699632E+01 SASA for atom 7: 2.045987617019E+01 SASA for atom 8: 2.067875411190E+01 SASA for atom 9: 2.028790064456E+01 SASA for atom 10: 1.897463299431E+01 SASA for atom 11: 2.048593306801E+01 SASA for atom 12: 2.070481100972E+01 Total solvent accessible surface area: 193.638 A^2 Surface tension*area energies (gamma * SASA) for each atom: Surface tension*area energy for atom 0: 8.066947264233E-02 Surface tension*area energy for atom 1: 8.085988052425E-02 Surface tension*area energy for atom 2: 1.954854254432E-02 Surface tension*area energy for atom 3: 1.631160855160E-02 Surface tension*area energy for atom 4: 1.961201183830E-02 Surface tension*area energy for atom 5: 1.976962894687E-01 Surface tension*area energy for atom 6: 1.976962894687E-01 Surface tension*area energy for atom 7: 1.739089474466E-01 Surface tension*area energy for atom 8: 1.757694099511E-01 Surface tension*area energy for atom 9: 1.724471554788E-01 Surface tension*area energy for atom 10: 1.612843804516E-01 Surface tension*area energy for atom 11: 1.741304310781E-01 Surface tension*area energy for atom 12: 1.759908935826E-01 Total surface tension energy: 1.64593 kJ/mol Total solvent accessible volume: 217.998 A^3 Total pressure*volume energy: 52.1887 kJ/mol WCA dispersion Energies for each atom: WCA energy for atom 0: -6.343496616804E+00 WCA energy for atom 1: -6.327869601807E+00 WCA energy for atom 2: -6.334858040579E+00 WCA energy for atom 3: -6.296075406417E+00 WCA energy for atom 4: -6.345600816761E+00 WCA energy for atom 5: -1.663697465126E+00 WCA energy for atom 6: -1.662444032853E+00 WCA energy for atom 7: -1.572325104493E+00 WCA energy for atom 8: -1.604626551065E+00 WCA energy for atom 9: -1.586431484963E+00 WCA energy for atom 10: -1.554291291374E+00 WCA energy for atom 11: -1.574315220751E+00 WCA energy for atom 12: -1.604941679892E+00 Total WCA energy: -44.471 kJ/mol Total non-polar energy = 9.363673200142E+00 kJ/mol ---------------------------------------- CALCULATION #5 (solvated-ethane): APOLAR Solvent Accessible Surface Area (SASA) for each atom: SASA for atom 0: 5.995981536705E+00 SASA for atom 1: 5.966113633657E+00 SASA for atom 2: 2.121552620704E+01 SASA for atom 3: 2.124158310486E+01 SASA for atom 4: 2.125200586399E+01 SASA for atom 5: 2.123116034573E+01 SASA for atom 6: 2.125200586399E+01 SASA for atom 7: 2.127285138225E+01 Total solvent accessible surface area: 139.427 A^2 Surface tension*area energies (gamma * SASA) for each atom: Surface tension*area energy for atom 0: 5.096584306199E-02 Surface tension*area energy for atom 1: 5.071196588609E-02 Surface tension*area energy for atom 2: 1.803319727598E-01 Surface tension*area energy for atom 3: 1.805534563913E-01 Surface tension*area energy for atom 4: 1.806420498439E-01 Surface tension*area energy for atom 5: 1.804648629387E-01 Surface tension*area energy for atom 6: 1.806420498439E-01 Surface tension*area energy for atom 7: 1.808192367491E-01 Total surface tension energy: 1.18513 kJ/mol Total solvent accessible volume: 140.346 A^3 Total pressure*volume energy: 33.5988 kJ/mol WCA dispersion Energies for each atom: WCA energy for atom 0: -7.360066353115E+00 WCA energy for atom 1: -7.355483516201E+00 WCA energy for atom 2: -1.776106201066E+00 WCA energy for atom 3: -1.773973940651E+00 WCA energy for atom 4: -1.775401936843E+00 WCA energy for atom 5: -1.773464835521E+00 WCA energy for atom 6: -1.774382856097E+00 WCA energy for atom 7: -1.772366599434E+00 Total WCA energy: -25.3612 kJ/mol Total non-polar energy = 9.422717598546E+00 kJ/mol ---------------------------------------- CALCULATION #6 (solvated-hexane): APOLAR Solvent Accessible Surface Area (SASA) for each atom: SASA for atom 0: 4.405515699447E+00 SASA for atom 1: 8.213673337951E-01 SASA for atom 2: 3.285469335181E-01 SASA for atom 3: 2.986790304710E-01 SASA for atom 4: 1.855251124959E+01 SASA for atom 5: 2.147609518526E+01 SASA for atom 6: 1.852645435176E+01 SASA for atom 7: 1.655655287639E+01 SASA for atom 8: 1.655134149682E+01 SASA for atom 9: 1.360170066332E+01 SASA for atom 10: 1.357043238593E+01 SASA for atom 11: 1.381536722546E+01 SASA for atom 12: 1.384142412329E+01 SASA for atom 13: 7.765654792245E-01 SASA for atom 14: 1.684839013200E+01 SASA for atom 15: 1.682233323417E+01 SASA for atom 16: 4.166572475070E+00 SASA for atom 17: 2.179398933870E+01 SASA for atom 18: 1.877660057086E+01 SASA for atom 19: 1.876096643216E+01 Total solvent accessible surface area: 250.291 A^2 Surface tension*area energies (gamma * SASA) for each atom: Surface tension*area energy for atom 0: 3.744688344530E-02 Surface tension*area energy for atom 1: 6.981622337259E-03 Surface tension*area energy for atom 2: 2.792648934903E-03 Surface tension*area energy for atom 3: 2.538771759003E-03 Surface tension*area energy for atom 4: 1.576963456215E-01 Surface tension*area energy for atom 5: 1.825468090747E-01 Surface tension*area energy for atom 6: 1.574748619900E-01 Surface tension*area energy for atom 7: 1.407306994493E-01 Surface tension*area energy for atom 8: 1.406864027230E-01 Surface tension*area energy for atom 9: 1.156144556382E-01 Surface tension*area energy for atom 10: 1.153486752804E-01 Surface tension*area energy for atom 11: 1.174306214164E-01 Surface tension*area energy for atom 12: 1.176521050479E-01 Surface tension*area energy for atom 13: 6.600806573408E-03 Surface tension*area energy for atom 14: 1.432113161220E-01 Surface tension*area energy for atom 15: 1.429898324905E-01 Surface tension*area energy for atom 16: 3.541586603809E-02 Surface tension*area energy for atom 17: 1.852489093789E-01 Surface tension*area energy for atom 18: 1.596011048523E-01 Surface tension*area energy for atom 19: 1.594682146734E-01 Total surface tension energy: 2.12748 kJ/mol Total solvent accessible volume: 298.053 A^3 Total pressure*volume energy: 71.3539 kJ/mol WCA dispersion Energies for each atom: WCA energy for atom 0: -6.635406071935E+00 WCA energy for atom 1: -5.957247427848E+00 WCA energy for atom 2: -5.524801144538E+00 WCA energy for atom 3: -5.522294168859E+00 WCA energy for atom 4: -1.605314409440E+00 WCA energy for atom 5: -1.701051761776E+00 WCA energy for atom 6: -1.606669162773E+00 WCA energy for atom 7: -1.442505934938E+00 WCA energy for atom 8: -1.443059002759E+00 WCA energy for atom 9: -1.328947132810E+00 WCA energy for atom 10: -1.328906972440E+00 WCA energy for atom 11: -1.331566344214E+00 WCA energy for atom 12: -1.328041776815E+00 WCA energy for atom 13: -5.937562025661E+00 WCA energy for atom 14: -1.442277774427E+00 WCA energy for atom 15: -1.442777091510E+00 WCA energy for atom 16: -6.602262542378E+00 WCA energy for atom 17: -1.698172146664E+00 WCA energy for atom 18: -1.600970858835E+00 WCA energy for atom 19: -1.600841970217E+00 Total WCA energy: -57.0807 kJ/mol Total non-polar energy = 1.640068943201E+01 kJ/mol ---------------------------------------- CALCULATION #7 (solvated-isobutane): APOLAR Solvent Accessible Surface Area (SASA) for each atom: SASA for atom 0: 3.464676753463E+00 SASA for atom 1: 1.984493338158E+01 SASA for atom 2: 1.778643845361E+01 SASA for atom 3: 1.671289426332E+01 SASA for atom 4: 0.000000000000E+00 SASA for atom 5: 3.531879535319E+00 SASA for atom 6: 1.673895116114E+01 SASA for atom 7: 1.793756846098E+01 SASA for atom 8: 1.973549441072E+01 SASA for atom 9: 1.710895911022E+01 SASA for atom 10: 4.599657069253E+00 SASA for atom 11: 1.937069784121E+01 SASA for atom 12: 1.654613011726E+01 SASA for atom 13: 1.936548646165E+01 Total solvent accessible surface area: 192.744 A^2 Surface tension*area energies (gamma * SASA) for each atom: Surface tension*area energy for atom 0: 2.944975240444E-02 Surface tension*area energy for atom 1: 1.686819337434E-01 Surface tension*area energy for atom 2: 1.511847268556E-01 Surface tension*area energy for atom 3: 1.420596012382E-01 Surface tension*area energy for atom 4: 0.000000000000E+00 Surface tension*area energy for atom 5: 3.002097605021E-02 Surface tension*area energy for atom 6: 1.422810848697E-01 Surface tension*area energy for atom 7: 1.524693319183E-01 Surface tension*area energy for atom 8: 1.677517024912E-01 Surface tension*area energy for atom 9: 1.454261524369E-01 Surface tension*area energy for atom 10: 3.909708508865E-02 Surface tension*area energy for atom 11: 1.646509316503E-01 Surface tension*area energy for atom 12: 1.406421059967E-01 Surface tension*area energy for atom 13: 1.646066349240E-01 Total surface tension energy: 1.63832 kJ/mol Total solvent accessible volume: 218.943 A^3 Total pressure*volume energy: 52.415 kJ/mol WCA dispersion Energies for each atom: WCA energy for atom 0: -6.381016335247E+00 WCA energy for atom 1: -1.612317964554E+00 WCA energy for atom 2: -1.588013719598E+00 WCA energy for atom 3: -1.532162371190E+00 WCA energy for atom 4: -5.987950445279E+00 WCA energy for atom 5: -6.393089030861E+00 WCA energy for atom 6: -1.533454887042E+00 WCA energy for atom 7: -1.587650918485E+00 WCA energy for atom 8: -1.614083521570E+00 WCA energy for atom 9: -1.442402031577E+00 WCA energy for atom 10: -6.408813541353E+00 WCA energy for atom 11: -1.605830214390E+00 WCA energy for atom 12: -1.529385873788E+00 WCA energy for atom 13: -1.605662490385E+00 Total WCA energy: -40.8218 kJ/mol Total non-polar energy = 1.323144287435E+01 kJ/mol ---------------------------------------- CALCULATION #8 (solvated-methane): APOLAR Solvent Accessible Surface Area (SASA) for each atom: SASA for atom 0: 1.231304303117E+01 SASA for atom 1: 2.323233009850E+01 SASA for atom 2: 2.345641941977E+01 SASA for atom 3: 2.377431357320E+01 SASA for atom 4: 2.264344420771E+01 Total solvent accessible surface area: 105.42 A^2 Surface tension*area energies (gamma * SASA) for each atom: Surface tension*area energy for atom 0: 1.046608657649E-01 Surface tension*area energy for atom 1: 1.974748058372E-01 Surface tension*area energy for atom 2: 1.993795650680E-01 Surface tension*area energy for atom 3: 2.020816653722E-01 Surface tension*area energy for atom 4: 1.924692757655E-01 Total surface tension energy: 0.896066 kJ/mol Total solvent accessible volume: 95.985 A^3 Total pressure*volume energy: 22.9788 kJ/mol WCA dispersion Energies for each atom: WCA energy for atom 0: -8.133807570805E+00 WCA energy for atom 1: -1.962181541765E+00 WCA energy for atom 2: -1.964078319162E+00 WCA energy for atom 3: -1.963015006647E+00 WCA energy for atom 4: -1.957425549100E+00 Total WCA energy: -15.9805 kJ/mol Total non-polar energy = 7.894367190329E+00 kJ/mol ---------------------------------------- CALCULATION #9 (solvated-neopentane): APOLAR Solvent Accessible Surface Area (SASA) for each atom: SASA for atom 0: 2.441701074100E+00 SASA for atom 1: 1.663993494942E+01 SASA for atom 2: 1.715586152630E+01 SASA for atom 3: 1.645753666466E+01 SASA for atom 4: 0.000000000000E+00 SASA for atom 5: 2.389432243768E+00 SASA for atom 6: 1.638457735076E+01 SASA for atom 7: 1.667641460637E+01 SASA for atom 8: 1.721839808108E+01 SASA for atom 9: 2.419300146815E+00 SASA for atom 10: 1.640021148945E+01 SASA for atom 11: 1.666599184724E+01 SASA for atom 12: 1.719234118325E+01 SASA for atom 13: 2.449168049862E+00 SASA for atom 14: 1.723403221977E+01 SASA for atom 15: 1.639500010989E+01 SASA for atom 16: 1.663472356985E+01 Total solvent accessible surface area: 210.755 A^2 Surface tension*area energies (gamma * SASA) for each atom: Surface tension*area energy for atom 0: 2.075445912985E-02 Surface tension*area energy for atom 1: 1.414394470700E-01 Surface tension*area energy for atom 2: 1.458248229736E-01 Surface tension*area energy for atom 3: 1.398890616496E-01 Surface tension*area energy for atom 4: 0.000000000000E+00 Surface tension*area energy for atom 5: 2.031017407203E-02 Surface tension*area energy for atom 6: 1.392689074814E-01 Surface tension*area energy for atom 7: 1.417495241541E-01 Surface tension*area energy for atom 8: 1.463563836891E-01 Surface tension*area energy for atom 9: 2.056405124793E-02 Surface tension*area energy for atom 10: 1.394017976603E-01 Surface tension*area energy for atom 11: 1.416609307015E-01 Surface tension*area energy for atom 12: 1.461349000577E-01 Surface tension*area energy for atom 13: 2.081792842383E-02 Surface tension*area energy for atom 14: 1.464892738680E-01 Surface tension*area energy for atom 15: 1.393575009340E-01 Surface tension*area energy for atom 16: 1.413951503437E-01 Total surface tension energy: 1.79141 kJ/mol Total solvent accessible volume: 251.127 A^3 Total pressure*volume energy: 60.1198 kJ/mol WCA dispersion Energies for each atom: WCA energy for atom 0: -6.011082520236E+00 WCA energy for atom 1: -1.497367782613E+00 WCA energy for atom 2: -1.498546483218E+00 WCA energy for atom 3: -1.492562171495E+00 WCA energy for atom 4: -5.447325863939E+00 WCA energy for atom 5: -6.004516149175E+00 WCA energy for atom 6: -1.492776531092E+00 WCA energy for atom 7: -1.496078170066E+00 WCA energy for atom 8: -1.501529655270E+00 WCA energy for atom 9: -5.996267554365E+00 WCA energy for atom 10: -1.492194267752E+00 WCA energy for atom 11: -1.496027211216E+00 WCA energy for atom 12: -1.500561393960E+00 WCA energy for atom 13: -6.000218612907E+00 WCA energy for atom 14: -1.500859921426E+00 WCA energy for atom 15: -1.492908499790E+00 WCA energy for atom 16: -1.494057174414E+00 Total WCA energy: -47.4149 kJ/mol Total non-polar energy = 1.449633815052E+01 kJ/mol ---------------------------------------- CALCULATION #10 (solvated-pentane): APOLAR Solvent Accessible Surface Area (SASA) for each atom: SASA for atom 0: 4.405515699447E+00 SASA for atom 1: 8.213673337951E-01 SASA for atom 2: 3.285469335181E-01 SASA for atom 3: 7.466975761774E-01 SASA for atom 4: 1.855251124959E+01 SASA for atom 5: 2.147609518526E+01 SASA for atom 6: 1.852645435176E+01 SASA for atom 7: 1.655655287639E+01 SASA for atom 8: 1.655134149682E+01 SASA for atom 9: 1.360170066332E+01 SASA for atom 10: 1.357043238593E+01 SASA for atom 11: 1.685881289113E+01 SASA for atom 12: 1.687444702982E+01 SASA for atom 13: 4.196440378117E+00 SASA for atom 14: 1.881308022781E+01 SASA for atom 15: 1.882350298694E+01 SASA for atom 16: 2.182004623652E+01 Total solvent accessible surface area: 222.524 A^2 Surface tension*area energies (gamma * SASA) for each atom: Surface tension*area energy for atom 0: 3.744688344530E-02 Surface tension*area energy for atom 1: 6.981622337259E-03 Surface tension*area energy for atom 2: 2.792648934903E-03 Surface tension*area energy for atom 3: 6.346929397508E-03 Surface tension*area energy for atom 4: 1.576963456215E-01 Surface tension*area energy for atom 5: 1.825468090747E-01 Surface tension*area energy for atom 6: 1.574748619900E-01 Surface tension*area energy for atom 7: 1.407306994493E-01 Surface tension*area energy for atom 8: 1.406864027230E-01 Surface tension*area energy for atom 9: 1.156144556382E-01 Surface tension*area energy for atom 10: 1.153486752804E-01 Surface tension*area energy for atom 11: 1.432999095746E-01 Surface tension*area energy for atom 12: 1.434327997535E-01 Surface tension*area energy for atom 13: 3.566974321399E-02 Surface tension*area energy for atom 14: 1.599111819364E-01 Surface tension*area energy for atom 15: 1.599997753890E-01 Surface tension*area energy for atom 16: 1.854703930104E-01 Total surface tension energy: 1.89145 kJ/mol Total solvent accessible volume: 258.93 A^3 Total pressure*volume energy: 61.9878 kJ/mol WCA dispersion Energies for each atom: WCA energy for atom 0: -6.655804319869E+00 WCA energy for atom 1: -6.027315962813E+00 WCA energy for atom 2: -5.696430965386E+00 WCA energy for atom 3: -6.016749084714E+00 WCA energy for atom 4: -1.608595384643E+00 WCA energy for atom 5: -1.703300955380E+00 WCA energy for atom 6: -1.609931495887E+00 WCA energy for atom 7: -1.457107525189E+00 WCA energy for atom 8: -1.457741620594E+00 WCA energy for atom 9: -1.354235498709E+00 WCA energy for atom 10: -1.354106470090E+00 WCA energy for atom 11: -1.456736412636E+00 WCA energy for atom 12: -1.455995435596E+00 WCA energy for atom 13: -6.633650611186E+00 WCA energy for atom 14: -1.605996088477E+00 WCA energy for atom 15: -1.606549890103E+00 WCA energy for atom 16: -1.700042300035E+00 Total WCA energy: -49.4003 kJ/mol Total non-polar energy = 1.447900211546E+01 kJ/mol ---------------------------------------- CALCULATION #11 (solvated-propane): APOLAR Solvent Accessible Surface Area (SASA) for each atom: SASA for atom 0: 3.173464698754E+00 SASA for atom 1: 1.931858404557E+01 SASA for atom 2: 2.014198201675E+01 SASA for atom 3: 2.149694070352E+01 SASA for atom 4: 1.904078819252E+00 SASA for atom 5: 2.067354273233E+01 SASA for atom 6: 1.937590922077E+01 SASA for atom 7: 3.098794941136E+00 SASA for atom 8: 1.942802301642E+01 SASA for atom 9: 1.973028303116E+01 SASA for atom 10: 2.204934693736E+01 Total solvent accessible surface area: 170.391 A^2 Surface tension*area energies (gamma * SASA) for each atom: Surface tension*area energy for atom 0: 2.697444993941E-02 Surface tension*area energy for atom 1: 1.642079643873E-01 Surface tension*area energy for atom 2: 1.712068471424E-01 Surface tension*area energy for atom 3: 1.827239959799E-01 Surface tension*area energy for atom 4: 1.618466996365E-02 Surface tension*area energy for atom 5: 1.757251132248E-01 Surface tension*area energy for atom 6: 1.646952283766E-01 Surface tension*area energy for atom 7: 2.633975699966E-02 Surface tension*area energy for atom 8: 1.651381956396E-01 Surface tension*area energy for atom 9: 1.677074057649E-01 Surface tension*area energy for atom 10: 1.874194489675E-01 Total surface tension energy: 1.44832 kJ/mol Total solvent accessible volume: 183.573 A^3 Total pressure*volume energy: 43.9474 kJ/mol WCA dispersion Energies for each atom: WCA energy for atom 0: -6.818670105515E+00 WCA energy for atom 1: -1.641297645338E+00 WCA energy for atom 2: -1.649584120441E+00 WCA energy for atom 3: -1.711408141255E+00 WCA energy for atom 4: -6.624720142882E+00 WCA energy for atom 5: -1.610117050515E+00 WCA energy for atom 6: -1.596858009746E+00 WCA energy for atom 7: -6.816460624835E+00 WCA energy for atom 8: -1.642782751806E+00 WCA energy for atom 9: -1.645779566650E+00 WCA energy for atom 10: -1.714436154542E+00 Total WCA energy: -33.4721 kJ/mol Total non-polar energy = 1.192358496286E+01 kJ/mol ---------------------------------------- PRINT STATEMENTS print APOL energy 1 (solvated-2-methylbutane) end Global net APOL energy = 1.439739455792E+01 kJ/mol print APOL energy 2 (solvated-butane) end Global net APOL energy = 1.208346456826E+01 kJ/mol print APOL energy 3 (solvated-cyclohexane) end Global net APOL energy = 1.354016672221E+01 kJ/mol print APOL energy 4 (solvated-cyclopentane) end Global net APOL energy = 9.363673200142E+00 kJ/mol print APOL energy 5 (solvated-ethane) end Global net APOL energy = 9.422717598546E+00 kJ/mol print APOL energy 6 (solvated-hexane) end Global net APOL energy = 1.640068943201E+01 kJ/mol print APOL energy 7 (solvated-isobutane) end Global net APOL energy = 1.323144287435E+01 kJ/mol print APOL energy 8 (solvated-methane) end Global net APOL energy = 7.894367190329E+00 kJ/mol print APOL energy 9 (solvated-neopentane) end Global net APOL energy = 1.449633815052E+01 kJ/mol print APOL energy 10 (solvated-pentane) end Global net APOL energy = 1.447900211546E+01 kJ/mol print APOL energy 11 (solvated-propane) end Global net APOL energy = 1.192358496286E+01 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 11 molecules Final memory usage: 0.001 MB total, 2.204 MB high water Thanks for using APBS! Checking for intermidiate energies in input file alkanes.out RESULT 14.39739455792 RESULT 12.08346456826 RESULT 13.54016672221 RESULT 9.363673200142 RESULT 9.422717598546 RESULT 16.40068943201 RESULT 13.23144287435 RESULT 7.894367190329 RESULT 14.49633815052 RESULT 14.47900211546 RESULT 11.92358496286 Testing computed result 1.439739455792E+01 against expected result 1.439739E+01 *** PASSED *** Testing computed result 1.208346456826E+01 against expected result 1.208346E+01 *** PASSED *** Testing computed result 1.354016672221E+01 against expected result 1.354017E+01 *** PASSED *** Testing computed result 9.363673200142E+00 against expected result 9.363673E+00 *** PASSED *** Testing computed result 9.422717598546E+00 against expected result 9.422718E+00 *** PASSED *** Testing computed result 1.640068943201E+01 against expected result 1.640069E+01 *** PASSED *** Testing computed result 1.323144287435E+01 against expected result 1.323144E+01 *** PASSED *** Testing computed result 7.894367190329E+00 against expected result 7.894367E+00 *** PASSED *** Testing computed result 1.449633815052E+01 against expected result 1.449634E+01 *** PASSED *** Testing computed result 1.447900211546E+01 against expected result 1.447900E+01 *** PASSED *** Testing computed result 1.192358496286E+01 against expected result 1.192358E+01 *** PASSED *** Elapsed time: 65.899641 seconds -------------------------------------------------------------------------------- Total elapsed time: 65.899641 seconds Test results have been logged -------------------------------------------------------------------------------- Running tests for FKBP section -------------------------------------------------------------------------------- Testing input file 1d7h-dmso-mol.in BINARY: apbs INPUT: 1d7h-dmso-mol.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file 1d7h-dmso-mol.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from 1d7h-dmso-complex.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 1673 atoms Centered at (2.587e+01, 1.835e+01, 1.911e+01) Net charge 9.91e-01 e Reading PQR-format atom data from dmso-min.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 10 atoms Centered at (1.775e+01, 1.777e+01, 2.049e+01) Net charge 2.78e-17 e Reading PQR-format atom data from 1d7h-min.pqr. 1663 atoms Centered at (2.587e+01, 1.835e+01, 1.911e+01) Net charge 9.91e-01 e Preparing to run 12 PBE calculations. ---------------------------------------- CALCULATION #1 (complex-solv-coarse): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 30.4176 A Current memory usage: 102.625 MB total, 102.625 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 1.500 x 1.500 x 1.500 Grid lengths: 96.000 x 96.000 x 96.000 Grid center: (25.875, 18.349, 19.112) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 1.060899690259E+04 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #2 (complex-solv-fine): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 30.4176 A Current memory usage: 102.625 MB total, 182.834 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.225 x 0.225 x 0.225 Grid lengths: 14.400 x 14.400 x 14.400 Grid center: (17.751, 17.770, 20.492) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 4.276523673491E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #3 (complex-ref-coarse): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 4.87072 A Current memory usage: 102.625 MB total, 182.834 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 1.500 x 1.500 x 1.500 Grid lengths: 96.000 x 96.000 x 96.000 Grid center: (25.875, 18.349, 19.112) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 2.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 1.399234956777E+04 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #4 (complex-ref-fine): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 4.87072 A Current memory usage: 102.625 MB total, 182.834 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.225 x 0.225 x 0.225 Grid lengths: 14.400 x 14.400 x 14.400 Grid center: (17.751, 17.770, 20.492) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 2.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 4.610066575192E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #5 (dmso-solv-coarse): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 30.4176 A Current memory usage: 62.396 MB total, 182.834 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 1.500 x 1.500 x 1.500 Grid lengths: 96.000 x 96.000 x 96.000 Grid center: (17.751, 17.770, 20.492) Multigrid levels: 5 Molecule ID: 2 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 3.961107503213E+01 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #6 (dmso-solv-fine): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 30.4176 A Current memory usage: 62.396 MB total, 182.834 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.225 x 0.225 x 0.225 Grid lengths: 14.400 x 14.400 x 14.400 Grid center: (17.751, 17.770, 20.492) Multigrid levels: 5 Molecule ID: 2 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 7.121048606059E+02 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #7 (dmso-ref-coarse): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 4.87072 A Current memory usage: 62.396 MB total, 182.834 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 1.500 x 1.500 x 1.500 Grid lengths: 96.000 x 96.000 x 96.000 Grid center: (17.751, 17.770, 20.492) Multigrid levels: 5 Molecule ID: 2 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 2.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 6.751571424823E+01 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #8 (dmso-ref-fine): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 4.87072 A Current memory usage: 62.396 MB total, 182.834 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.225 x 0.225 x 0.225 Grid lengths: 14.400 x 14.400 x 14.400 Grid center: (17.751, 17.770, 20.492) Multigrid levels: 5 Molecule ID: 2 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 2.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 7.339101343121E+02 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #9 (1d7h-solv-coarse): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 30.4176 A Current memory usage: 102.404 MB total, 182.834 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 1.500 x 1.500 x 1.500 Grid lengths: 96.000 x 96.000 x 96.000 Grid center: (25.875, 18.349, 19.112) Multigrid levels: 5 Molecule ID: 3 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 1.058410584089E+04 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #10 (1d7h-solv-fine): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 30.4176 A Current memory usage: 102.404 MB total, 182.834 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.225 x 0.225 x 0.225 Grid lengths: 14.400 x 14.400 x 14.400 Grid center: (17.751, 17.770, 20.492) Multigrid levels: 5 Molecule ID: 3 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 4.205385249581E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #11 (1d7h-ref-coarse): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 4.87072 A Current memory usage: 102.404 MB total, 182.834 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 1.500 x 1.500 x 1.500 Grid lengths: 96.000 x 96.000 x 96.000 Grid center: (25.875, 18.349, 19.112) Multigrid levels: 5 Molecule ID: 3 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 2.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 1.395961902233E+04 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #12 (1d7h-ref-fine): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 4.87072 A Current memory usage: 102.404 MB total, 182.834 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.225 x 0.225 x 0.225 Grid lengths: 14.400 x 14.400 x 14.400 Grid center: (17.751, 17.770, 20.492) Multigrid levels: 5 Molecule ID: 3 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 2.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 4.538248433997E+04 kJ/mol Calculating forces... ---------------------------------------- PRINT STATEMENTS print energy 2 (complex-solv-fine) - 4 (complex-ref-fine) end Local net energy (PE 0) = -3.335429017008E+03 kJ/mol Global net ELEC energy = -3.335429017008E+03 kJ/mol print energy 6 (dmso-solv-fine) - 8 (dmso-ref-fine) end Local net energy (PE 0) = -2.180527370616E+01 kJ/mol Global net ELEC energy = -2.180527370616E+01 kJ/mol print energy 10 (1d7h-solv-fine) - 12 (1d7h-ref-fine) end Local net energy (PE 0) = -3.328631844166E+03 kJ/mol Global net ELEC energy = -3.328631844166E+03 kJ/mol print energy 2 (complex-solv-fine) - 4 (complex-ref-fine) - 6 (dmso-solv-fine) + 8 (dmso-ref-fine) - 10 (1d7h-solv-fine) + 12 (1d7h-ref-fine) end Local net energy (PE 0) = 1.500810086371E+01 kJ/mol Global net ELEC energy = 1.500810086371E+01 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 182.834 MB high water Thanks for using APBS! Checking for intermidiate energies in input file 1d7h-dmso-mol.out RESULT 10608.99690259 RESULT 42765.23673491 RESULT 13992.34956777 RESULT 46100.66575192 RESULT 39.61107503213 RESULT 712.1048606059 RESULT 67.51571424823 RESULT 733.9101343121 RESULT 10584.10584089 RESULT 42053.85249581 RESULT 13959.61902233 RESULT 45382.48433997 RESULT -3335.429017008 RESULT -21.80527370616 RESULT -3328.631844166 RESULT 15.00810086371 Testing computed result 1.060899690259E+04 against expected result 1.060900E+04 *** PASSED *** Testing computed result 4.276523673491E+04 against expected result 4.276524E+04 *** PASSED *** Testing computed result 1.399234956777E+04 against expected result 1.399235E+04 *** PASSED *** Testing computed result 4.610066575192E+04 against expected result 4.610067E+04 *** PASSED *** Testing computed result 3.961107503213E+01 against expected result 3.961108E+01 *** PASSED *** Testing computed result 7.121048606059E+02 against expected result 7.121049E+02 *** PASSED *** Testing computed result 6.751571424823E+01 against expected result 6.751571E+01 *** PASSED *** Testing computed result 7.339101343121E+02 against expected result 7.339101E+02 *** PASSED *** Testing computed result 1.058410584089E+04 against expected result 1.058411E+04 *** PASSED *** Testing computed result 4.205385249581E+04 against expected result 4.205385E+04 *** PASSED *** Testing computed result 1.395961902233E+04 against expected result 1.395962E+04 *** PASSED *** Testing computed result 4.538248433997E+04 against expected result 4.538248E+04 *** PASSED *** Testing computed result 1.500810086371E+01 against expected result 1.500810E+01 *** PASSED *** Elapsed time: 43.145388 seconds -------------------------------------------------------------------------------- -------------------------------------------------------------------------------- Testing input file 1d7h-dmso-smol.in BINARY: apbs INPUT: 1d7h-dmso-smol.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file 1d7h-dmso-smol.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from 1d7h-dmso-complex.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 1673 atoms Centered at (2.587e+01, 1.835e+01, 1.911e+01) Net charge 9.91e-01 e Reading PQR-format atom data from dmso-min.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 10 atoms Centered at (1.775e+01, 1.777e+01, 2.049e+01) Net charge 2.78e-17 e Reading PQR-format atom data from 1d7h-min.pqr. 1663 atoms Centered at (2.587e+01, 1.835e+01, 1.911e+01) Net charge 9.91e-01 e Preparing to run 12 PBE calculations. ---------------------------------------- CALCULATION #1 (complex-solv-coarse): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 30.4176 A Current memory usage: 102.625 MB total, 102.625 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 1.500 x 1.500 x 1.500 Grid lengths: 96.000 x 96.000 x 96.000 Grid center: (25.875, 18.349, 19.112) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 1.074948704824E+04 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #2 (complex-solv-fine): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 30.4176 A Current memory usage: 102.625 MB total, 182.834 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.225 x 0.225 x 0.225 Grid lengths: 14.400 x 14.400 x 14.400 Grid center: (17.751, 17.770, 20.492) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 4.289487256481E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #3 (complex-ref-coarse): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 4.87072 A Current memory usage: 102.625 MB total, 182.834 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 1.500 x 1.500 x 1.500 Grid lengths: 96.000 x 96.000 x 96.000 Grid center: (25.875, 18.349, 19.112) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 2.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 1.399234956777E+04 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #4 (complex-ref-fine): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 4.87072 A Current memory usage: 102.625 MB total, 182.834 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.225 x 0.225 x 0.225 Grid lengths: 14.400 x 14.400 x 14.400 Grid center: (17.751, 17.770, 20.492) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 2.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 4.610066575192E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #5 (dmso-solv-coarse): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 30.4176 A Current memory usage: 62.396 MB total, 182.834 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 1.500 x 1.500 x 1.500 Grid lengths: 96.000 x 96.000 x 96.000 Grid center: (17.751, 17.770, 20.492) Multigrid levels: 5 Molecule ID: 2 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 3.719709905887E+01 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #6 (dmso-solv-fine): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 30.4176 A Current memory usage: 62.396 MB total, 182.834 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.225 x 0.225 x 0.225 Grid lengths: 14.400 x 14.400 x 14.400 Grid center: (17.751, 17.770, 20.492) Multigrid levels: 5 Molecule ID: 2 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 7.125747080979E+02 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #7 (dmso-ref-coarse): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 4.87072 A Current memory usage: 62.396 MB total, 182.834 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 1.500 x 1.500 x 1.500 Grid lengths: 96.000 x 96.000 x 96.000 Grid center: (17.751, 17.770, 20.492) Multigrid levels: 5 Molecule ID: 2 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 2.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 6.751571424823E+01 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #8 (dmso-ref-fine): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 4.87072 A Current memory usage: 62.396 MB total, 182.834 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.225 x 0.225 x 0.225 Grid lengths: 14.400 x 14.400 x 14.400 Grid center: (17.751, 17.770, 20.492) Multigrid levels: 5 Molecule ID: 2 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 2.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 7.339101343121E+02 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #9 (1d7h-solv-coarse): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 30.4176 A Current memory usage: 102.404 MB total, 182.834 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 1.500 x 1.500 x 1.500 Grid lengths: 96.000 x 96.000 x 96.000 Grid center: (25.875, 18.349, 19.112) Multigrid levels: 5 Molecule ID: 3 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 1.071654753674E+04 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #10 (1d7h-solv-fine): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 30.4176 A Current memory usage: 102.404 MB total, 182.834 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.225 x 0.225 x 0.225 Grid lengths: 14.400 x 14.400 x 14.400 Grid center: (17.751, 17.770, 20.492) Multigrid levels: 5 Molecule ID: 3 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 4.218178203716E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #11 (1d7h-ref-coarse): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 4.87072 A Current memory usage: 102.404 MB total, 182.834 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 1.500 x 1.500 x 1.500 Grid lengths: 96.000 x 96.000 x 96.000 Grid center: (25.875, 18.349, 19.112) Multigrid levels: 5 Molecule ID: 3 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 2.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 1.395961902233E+04 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #12 (1d7h-ref-fine): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 4.87072 A Current memory usage: 102.404 MB total, 182.834 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.225 x 0.225 x 0.225 Grid lengths: 14.400 x 14.400 x 14.400 Grid center: (17.751, 17.770, 20.492) Multigrid levels: 5 Molecule ID: 3 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 2.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 4.538248433997E+04 kJ/mol Calculating forces... ---------------------------------------- PRINT STATEMENTS print energy 2 (complex-solv-fine) - 4 (complex-ref-fine) end Local net energy (PE 0) = -3.205793187109E+03 kJ/mol Global net ELEC energy = -3.205793187109E+03 kJ/mol print energy 6 (dmso-solv-fine) - 8 (dmso-ref-fine) end Local net energy (PE 0) = -2.133542621421E+01 kJ/mol Global net ELEC energy = -2.133542621421E+01 kJ/mol print energy 10 (1d7h-solv-fine) - 12 (1d7h-ref-fine) end Local net energy (PE 0) = -3.200702302816E+03 kJ/mol Global net ELEC energy = -3.200702302816E+03 kJ/mol print energy 2 (complex-solv-fine) - 4 (complex-ref-fine) - 6 (dmso-solv-fine) + 8 (dmso-ref-fine) - 10 (1d7h-solv-fine) + 12 (1d7h-ref-fine) end Local net energy (PE 0) = 1.624454192073E+01 kJ/mol Global net ELEC energy = 1.624454192073E+01 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 182.834 MB high water Thanks for using APBS! Checking for intermidiate energies in input file 1d7h-dmso-smol.out RESULT 10749.48704824 RESULT 42894.87256481 RESULT 13992.34956777 RESULT 46100.66575192 RESULT 37.19709905887 RESULT 712.5747080979 RESULT 67.51571424823 RESULT 733.9101343121 RESULT 10716.54753674 RESULT 42181.78203716 RESULT 13959.61902233 RESULT 45382.48433997 RESULT -3205.793187109 RESULT -21.33542621421 RESULT -3200.702302816 RESULT 16.24454192073 Testing computed result 1.074948704824E+04 against expected result 1.074949E+04 *** PASSED *** Testing computed result 4.289487256481E+04 against expected result 4.289487E+04 *** PASSED *** Testing computed result 1.399234956777E+04 against expected result 1.399235E+04 *** PASSED *** Testing computed result 4.610066575192E+04 against expected result 4.610067E+04 *** PASSED *** Testing computed result 3.719709905887E+01 against expected result 3.719710E+01 *** PASSED *** Testing computed result 7.125747080979E+02 against expected result 7.125747E+02 *** PASSED *** Testing computed result 6.751571424823E+01 against expected result 6.751571E+01 *** PASSED *** Testing computed result 7.339101343121E+02 against expected result 7.339101E+02 *** PASSED *** Testing computed result 1.071654753674E+04 against expected result 1.071655E+04 *** PASSED *** Testing computed result 4.218178203716E+04 against expected result 4.218178E+04 *** PASSED *** Testing computed result 1.395961902233E+04 against expected result 1.395962E+04 *** PASSED *** Testing computed result 4.538248433997E+04 against expected result 4.538248E+04 *** PASSED *** Testing computed result 1.624454192073E+01 against expected result 1.624454E+01 *** PASSED *** Elapsed time: 39.473177 seconds -------------------------------------------------------------------------------- -------------------------------------------------------------------------------- Testing input file 1d7i-dss-mol.in BINARY: apbs INPUT: 1d7i-dss-mol.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file 1d7i-dss-mol.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from 1d7i-dss-complex.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 1677 atoms Centered at (2.526e+01, 1.899e+01, 1.912e+01) Net charge 9.91e-01 e Reading PQR-format atom data from dss-min.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 14 atoms Centered at (1.734e+01, 1.921e+01, 2.050e+01) Net charge -8.33e-17 e Reading PQR-format atom data from 1d7i-min.pqr. 1663 atoms Centered at (2.526e+01, 1.899e+01, 1.912e+01) Net charge 9.91e-01 e Preparing to run 12 PBE calculations. ---------------------------------------- CALCULATION #1 (complex-solv-coarse): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 30.4176 A Current memory usage: 102.869 MB total, 102.869 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 1.500 x 1.500 x 1.500 Grid lengths: 96.000 x 96.000 x 96.000 Grid center: (25.264, 18.988, 19.122) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 9.160578033846E+03 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #2 (complex-solv-fine): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 30.4176 A Current memory usage: 102.869 MB total, 183.200 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.225 x 0.225 x 0.225 Grid lengths: 14.400 x 14.400 x 14.400 Grid center: (17.340, 19.211, 20.503) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 3.955701871716E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #3 (complex-ref-coarse): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 4.87072 A Current memory usage: 102.869 MB total, 183.200 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 1.500 x 1.500 x 1.500 Grid lengths: 96.000 x 96.000 x 96.000 Grid center: (25.264, 18.988, 19.122) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 2.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 1.264965939588E+04 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #4 (complex-ref-fine): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 4.87072 A Current memory usage: 102.869 MB total, 183.200 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.225 x 0.225 x 0.225 Grid lengths: 14.400 x 14.400 x 14.400 Grid center: (17.340, 19.211, 20.503) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 2.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 4.301801664829E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #5 (dss-solv-coarse): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 30.4176 A Current memory usage: 62.482 MB total, 183.200 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 1.500 x 1.500 x 1.500 Grid lengths: 96.000 x 96.000 x 96.000 Grid center: (17.340, 19.211, 20.503) Multigrid levels: 5 Molecule ID: 2 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 9.431133325426E+01 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #6 (dss-solv-fine): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 30.4176 A Current memory usage: 62.482 MB total, 183.200 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.225 x 0.225 x 0.225 Grid lengths: 14.400 x 14.400 x 14.400 Grid center: (17.340, 19.211, 20.503) Multigrid levels: 5 Molecule ID: 2 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 1.677348113184E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #7 (dss-ref-coarse): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 4.87072 A Current memory usage: 62.482 MB total, 183.200 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 1.500 x 1.500 x 1.500 Grid lengths: 96.000 x 96.000 x 96.000 Grid center: (17.340, 19.211, 20.503) Multigrid levels: 5 Molecule ID: 2 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 2.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 1.171079106781E+02 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #8 (dss-ref-fine): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 4.87072 A Current memory usage: 62.482 MB total, 183.200 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.225 x 0.225 x 0.225 Grid lengths: 14.400 x 14.400 x 14.400 Grid center: (17.340, 19.211, 20.503) Multigrid levels: 5 Molecule ID: 2 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 2.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 1.697869784185E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #9 (1d7i-solv-coarse): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 30.4176 A Current memory usage: 102.566 MB total, 183.200 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 1.500 x 1.500 x 1.500 Grid lengths: 96.000 x 96.000 x 96.000 Grid center: (25.264, 18.988, 19.122) Multigrid levels: 5 Molecule ID: 3 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 9.040108332204E+03 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #10 (1d7i-solv-fine): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 30.4176 A Current memory usage: 102.566 MB total, 183.200 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.225 x 0.225 x 0.225 Grid lengths: 14.400 x 14.400 x 14.400 Grid center: (17.340, 19.211, 20.503) Multigrid levels: 5 Molecule ID: 3 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 3.787747796627E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #11 (1d7i-ref-coarse): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 4.87072 A Current memory usage: 102.566 MB total, 183.200 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 1.500 x 1.500 x 1.500 Grid lengths: 96.000 x 96.000 x 96.000 Grid center: (25.264, 18.988, 19.122) Multigrid levels: 5 Molecule ID: 3 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 2.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 1.252495566243E+04 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #12 (1d7i-ref-fine): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 4.87072 A Current memory usage: 102.566 MB total, 183.200 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.225 x 0.225 x 0.225 Grid lengths: 14.400 x 14.400 x 14.400 Grid center: (17.340, 19.211, 20.503) Multigrid levels: 5 Molecule ID: 3 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 2.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 4.133237922574E+04 kJ/mol Calculating forces... ---------------------------------------- PRINT STATEMENTS print energy 2 (complex-solv-fine) - 4 (complex-ref-fine) end Local net energy (PE 0) = -3.460997931137E+03 kJ/mol Global net ELEC energy = -3.460997931137E+03 kJ/mol print energy 6 (dss-solv-fine) - 8 (dss-ref-fine) end Local net energy (PE 0) = -2.052167100108E+01 kJ/mol Global net ELEC energy = -2.052167100108E+01 kJ/mol print energy 10 (1d7i-solv-fine) - 12 (1d7i-ref-fine) end Local net energy (PE 0) = -3.454901259473E+03 kJ/mol Global net ELEC energy = -3.454901259473E+03 kJ/mol print energy 2 (complex-solv-fine) - 4 (complex-ref-fine) - 6 (dss-solv-fine) + 8 (dss-ref-fine) - 10 (1d7i-solv-fine) + 12 (1d7i-ref-fine) end Local net energy (PE 0) = 1.442499933668E+01 kJ/mol Global net ELEC energy = 1.442499933668E+01 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 183.200 MB high water Thanks for using APBS! Checking for intermidiate energies in input file 1d7i-dss-mol.out RESULT 9160.578033846 RESULT 39557.01871716 RESULT 12649.65939588 RESULT 43018.01664829 RESULT 94.31133325426 RESULT 1677.348113184 RESULT 117.1079106781 RESULT 1697.869784185 RESULT 9040.108332204 RESULT 37877.47796627 RESULT 12524.95566243 RESULT 41332.37922574 RESULT -3460.997931137 RESULT -20.52167100108 RESULT -3454.901259473 RESULT 14.42499933668 Testing computed result 9.160578033846E+03 against expected result 9.160578E+03 *** PASSED *** Testing computed result 3.955701871716E+04 against expected result 3.955702E+04 *** PASSED *** Testing computed result 1.264965939588E+04 against expected result 1.264966E+04 *** PASSED *** Testing computed result 4.301801664829E+04 against expected result 4.301802E+04 *** PASSED *** Testing computed result 9.431133325426E+01 against expected result 9.431133E+01 *** PASSED *** Testing computed result 1.677348113184E+03 against expected result 1.677348E+03 *** PASSED *** Testing computed result 1.171079106781E+02 against expected result 1.171079E+02 *** PASSED *** Testing computed result 1.697869784185E+03 against expected result 1.697870E+03 *** PASSED *** Testing computed result 9.040108332204E+03 against expected result 9.040108E+03 *** PASSED *** Testing computed result 3.787747796627E+04 against expected result 3.787748E+04 *** PASSED *** Testing computed result 1.252495566243E+04 against expected result 1.252496E+04 *** PASSED *** Testing computed result 4.133237922574E+04 against expected result 4.133238E+04 *** PASSED *** Testing computed result 1.442499933668E+01 against expected result 1.442501E+01 *** PASSED *** Elapsed time: 42.676327 seconds -------------------------------------------------------------------------------- -------------------------------------------------------------------------------- Testing input file 1d7i-dss-smol.in BINARY: apbs INPUT: 1d7i-dss-smol.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file 1d7i-dss-smol.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from 1d7i-dss-complex.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 1677 atoms Centered at (2.526e+01, 1.899e+01, 1.912e+01) Net charge 9.91e-01 e Reading PQR-format atom data from dss-min.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 14 atoms Centered at (1.734e+01, 1.921e+01, 2.050e+01) Net charge -8.33e-17 e Reading PQR-format atom data from 1d7i-min.pqr. 1663 atoms Centered at (2.526e+01, 1.899e+01, 1.912e+01) Net charge 9.91e-01 e Preparing to run 12 PBE calculations. ---------------------------------------- CALCULATION #1 (complex-solv-coarse): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 30.4176 A Current memory usage: 102.869 MB total, 102.869 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 1.500 x 1.500 x 1.500 Grid lengths: 96.000 x 96.000 x 96.000 Grid center: (25.264, 18.988, 19.122) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 9.634884642408E+03 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #2 (complex-solv-fine): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 30.4176 A Current memory usage: 102.869 MB total, 183.200 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.225 x 0.225 x 0.225 Grid lengths: 14.400 x 14.400 x 14.400 Grid center: (17.340, 19.211, 20.503) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 4.003177540425E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #3 (complex-ref-coarse): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 4.87072 A Current memory usage: 102.869 MB total, 183.200 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 1.500 x 1.500 x 1.500 Grid lengths: 96.000 x 96.000 x 96.000 Grid center: (25.264, 18.988, 19.122) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 2.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 1.264965939588E+04 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #4 (complex-ref-fine): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 4.87072 A Current memory usage: 102.869 MB total, 183.200 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.225 x 0.225 x 0.225 Grid lengths: 14.400 x 14.400 x 14.400 Grid center: (17.340, 19.211, 20.503) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 2.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 4.301801664829E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #5 (dss-solv-coarse): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 30.4176 A Current memory usage: 62.482 MB total, 183.200 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 1.500 x 1.500 x 1.500 Grid lengths: 96.000 x 96.000 x 96.000 Grid center: (17.340, 19.211, 20.503) Multigrid levels: 5 Molecule ID: 2 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 7.942232645345E+01 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #6 (dss-solv-fine): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 30.4176 A Current memory usage: 62.482 MB total, 183.200 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.225 x 0.225 x 0.225 Grid lengths: 14.400 x 14.400 x 14.400 Grid center: (17.340, 19.211, 20.503) Multigrid levels: 5 Molecule ID: 2 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 1.677798535473E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #7 (dss-ref-coarse): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 4.87072 A Current memory usage: 62.482 MB total, 183.200 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 1.500 x 1.500 x 1.500 Grid lengths: 96.000 x 96.000 x 96.000 Grid center: (17.340, 19.211, 20.503) Multigrid levels: 5 Molecule ID: 2 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 2.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 1.171079106781E+02 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #8 (dss-ref-fine): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 4.87072 A Current memory usage: 62.482 MB total, 183.200 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.225 x 0.225 x 0.225 Grid lengths: 14.400 x 14.400 x 14.400 Grid center: (17.340, 19.211, 20.503) Multigrid levels: 5 Molecule ID: 2 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 2.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 1.697869784185E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #9 (1d7i-solv-coarse): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 30.4176 A Current memory usage: 102.566 MB total, 183.200 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 1.500 x 1.500 x 1.500 Grid lengths: 96.000 x 96.000 x 96.000 Grid center: (25.264, 18.988, 19.122) Multigrid levels: 5 Molecule ID: 3 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 9.507068451372E+03 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #10 (1d7i-solv-fine): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 30.4176 A Current memory usage: 102.566 MB total, 183.200 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.225 x 0.225 x 0.225 Grid lengths: 14.400 x 14.400 x 14.400 Grid center: (17.340, 19.211, 20.503) Multigrid levels: 5 Molecule ID: 3 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 3.835075772299E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #11 (1d7i-ref-coarse): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 4.87072 A Current memory usage: 102.566 MB total, 183.200 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 1.500 x 1.500 x 1.500 Grid lengths: 96.000 x 96.000 x 96.000 Grid center: (25.264, 18.988, 19.122) Multigrid levels: 5 Molecule ID: 3 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 2.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 1.252495566243E+04 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #12 (1d7i-ref-fine): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 4.87072 A Current memory usage: 102.566 MB total, 183.200 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.225 x 0.225 x 0.225 Grid lengths: 14.400 x 14.400 x 14.400 Grid center: (17.340, 19.211, 20.503) Multigrid levels: 5 Molecule ID: 3 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.010 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.010 M concentration 2.000 A-radius, -1.000 e-charge, 0.010 M concentration Solute dielectric: 2.000 Solvent dielectric: 2.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 4.133237922574E+04 kJ/mol Calculating forces... ---------------------------------------- PRINT STATEMENTS print energy 2 (complex-solv-fine) - 4 (complex-ref-fine) end Local net energy (PE 0) = -2.986241244040E+03 kJ/mol Global net ELEC energy = -2.986241244040E+03 kJ/mol print energy 6 (dss-solv-fine) - 8 (dss-ref-fine) end Local net energy (PE 0) = -2.007124871262E+01 kJ/mol Global net ELEC energy = -2.007124871262E+01 kJ/mol print energy 10 (1d7i-solv-fine) - 12 (1d7i-ref-fine) end Local net energy (PE 0) = -2.981621502756E+03 kJ/mol Global net ELEC energy = -2.981621502756E+03 kJ/mol print energy 2 (complex-solv-fine) - 4 (complex-ref-fine) - 6 (dss-solv-fine) + 8 (dss-ref-fine) - 10 (1d7i-solv-fine) + 12 (1d7i-ref-fine) end Local net energy (PE 0) = 1.545150742844E+01 kJ/mol Global net ELEC energy = 1.545150742844E+01 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 183.200 MB high water Thanks for using APBS! Checking for intermidiate energies in input file 1d7i-dss-smol.out RESULT 9634.884642408 RESULT 40031.77540425 RESULT 12649.65939588 RESULT 43018.01664829 RESULT 79.42232645345 RESULT 1677.798535473 RESULT 117.1079106781 RESULT 1697.869784185 RESULT 9507.068451372 RESULT 38350.75772299 RESULT 12524.95566243 RESULT 41332.37922574 RESULT -2986.24124404 RESULT -20.07124871262 RESULT -2981.621502756 RESULT 15.45150742844 Testing computed result 9.634884642408E+03 against expected result 9.634885E+03 *** PASSED *** Testing computed result 4.003177540425E+04 against expected result 4.003178E+04 *** PASSED *** Testing computed result 1.264965939588E+04 against expected result 1.264966E+04 *** PASSED *** Testing computed result 4.301801664829E+04 against expected result 4.301802E+04 *** PASSED *** Testing computed result 7.942232645345E+01 against expected result 7.942233E+01 *** PASSED *** Testing computed result 1.677798535473E+03 against expected result 1.677799E+03 *** PASSED *** Testing computed result 1.171079106781E+02 against expected result 1.171079E+02 *** PASSED *** Testing computed result 1.697869784185E+03 against expected result 1.697870E+03 *** PASSED *** Testing computed result 9.507068451372E+03 against expected result 9.507068E+03 *** PASSED *** Testing computed result 3.835075772299E+04 against expected result 3.835076E+04 *** PASSED *** Testing computed result 1.252495566243E+04 against expected result 1.252496E+04 *** PASSED *** Testing computed result 4.133237922574E+04 against expected result 4.133238E+04 *** PASSED *** Testing computed result 1.545150742844E+01 against expected result 1.545150E+01 *** PASSED *** Elapsed time: 39.694572 seconds -------------------------------------------------------------------------------- Total elapsed time: 164.989464 seconds Test results have been logged -------------------------------------------------------------------------------- Running tests for hca-bind section -------------------------------------------------------------------------------- Testing input file apbs-mol.in BINARY: apbs INPUT: apbs-mol.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-mol.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from acet.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 18 atoms Centered at (-6.028e+00, 3.898e+00, 1.518e+01) Net charge -1.00e+00 e Reading PQR-format atom data from hca.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 2482 atoms Centered at (-7.196e+00, 4.070e-01, 1.704e+01) Net charge 1.00e+00 e Reading PQR-format atom data from complex.pqr. 2500 atoms Centered at (-7.196e+00, 4.070e-01, 1.704e+01) Net charge -1.02e-14 e Preparing to run 9 PBE calculations. ---------------------------------------- CALCULATION #1 (acet): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 62.632 MB total, 62.632 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 1.500 x 1.500 x 1.500 Grid lengths: 96.000 x 96.000 x 96.000 Grid center: (-6.028, 3.898, 15.179) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.213600726771E+02 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (acet): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 62.632 MB total, 123.513 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.581 x 0.581 x 0.581 Grid lengths: 37.181 x 37.181 x 37.181 Grid center: (-6.028, 3.898, 15.179) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.825764811255E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #3 (acet): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 62.632 MB total, 123.513 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.225 x 0.225 x 0.225 Grid lengths: 14.400 x 14.400 x 14.400 Grid center: (-6.028, 3.898, 15.179) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 6.458471211905E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #4 (hca): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 127.616 MB total, 127.616 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 1.500 x 1.500 x 1.500 Grid lengths: 96.000 x 96.000 x 96.000 Grid center: (-6.028, 3.898, 15.179) Multigrid levels: 5 Molecule ID: 2 Linearized traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.093606095527E+04 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #5 (hca): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 127.616 MB total, 207.303 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.581 x 0.581 x 0.581 Grid lengths: 37.181 x 37.181 x 37.181 Grid center: (-6.028, 3.898, 15.179) Multigrid levels: 5 Molecule ID: 2 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.515433544464E+05 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #6 (hca): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 127.616 MB total, 207.303 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.225 x 0.225 x 0.225 Grid lengths: 14.400 x 14.400 x 14.400 Grid center: (-6.028, 3.898, 15.179) Multigrid levels: 5 Molecule ID: 2 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.786369323561E+05 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #7 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 127.915 MB total, 207.303 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 1.500 x 1.500 x 1.500 Grid lengths: 96.000 x 96.000 x 96.000 Grid center: (-6.028, 3.898, 15.179) Multigrid levels: 5 Molecule ID: 3 Linearized traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.105322784838E+04 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #8 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 127.915 MB total, 207.713 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.581 x 0.581 x 0.581 Grid lengths: 37.181 x 37.181 x 37.181 Grid center: (-6.028, 3.898, 15.179) Multigrid levels: 5 Molecule ID: 3 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.533304996252E+05 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #9 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 127.915 MB total, 207.713 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.225 x 0.225 x 0.225 Grid lengths: 14.400 x 14.400 x 14.400 Grid center: (-6.028, 3.898, 15.179) Multigrid levels: 5 Molecule ID: 3 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.850429388099E+05 kJ/mol Calculating forces... ---------------------------------------- PRINT STATEMENTS print energy 3 (complex) - 1 (acet) - 2 (hca) end Local net energy (PE 0) = -5.246475812665E+01 kJ/mol Global net ELEC energy = -5.246475812665E+01 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 207.713 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-mol.out RESULT 221.3600726771 RESULT 1825.764811255 RESULT 6458.471211905 RESULT 20936.06095527 RESULT 151543.3544464 RESULT 178636.9323561 RESULT 21053.22784838 RESULT 153330.4996252 RESULT 185042.9388099 RESULT -52.46475812665 Testing computed result 2.213600726771E+02 against expected result 2.213601E+02 *** PASSED *** Testing computed result 1.825764811255E+03 against expected result 1.825765E+03 *** PASSED *** Testing computed result 6.458471211905E+03 against expected result 6.458471E+03 *** PASSED *** Testing computed result 2.093606095527E+04 against expected result 2.093606E+04 *** PASSED *** Testing computed result 1.515433544464E+05 against expected result 1.515434E+05 *** PASSED *** Testing computed result 1.786369323561E+05 against expected result 1.786369E+05 *** PASSED *** Testing computed result 2.105322784838E+04 against expected result 2.105323E+04 *** PASSED *** Testing computed result 1.533304996252E+05 against expected result 1.533305E+05 *** PASSED *** Testing computed result 1.850429388099E+05 against expected result 1.850429E+05 *** PASSED *** Testing computed result -5.246475812665E+01 against expected result -5.246476E+01 *** PASSED *** Elapsed time: 40.375168 seconds -------------------------------------------------------------------------------- -------------------------------------------------------------------------------- Testing input file apbs-smol.in BINARY: apbs INPUT: apbs-smol.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-smol.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from acet.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 18 atoms Centered at (-6.028e+00, 3.898e+00, 1.518e+01) Net charge -1.00e+00 e Reading PQR-format atom data from hca.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 2482 atoms Centered at (-7.196e+00, 4.070e-01, 1.704e+01) Net charge 1.00e+00 e Reading PQR-format atom data from complex.pqr. 2500 atoms Centered at (-7.196e+00, 4.070e-01, 1.704e+01) Net charge -1.02e-14 e Preparing to run 9 PBE calculations. ---------------------------------------- CALCULATION #1 (acet): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 62.632 MB total, 62.632 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 1.500 x 1.500 x 1.500 Grid lengths: 96.000 x 96.000 x 96.000 Grid center: (-6.028, 3.898, 15.179) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.884888131017E+02 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (acet): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 62.632 MB total, 123.513 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.581 x 0.581 x 0.581 Grid lengths: 37.181 x 37.181 x 37.181 Grid center: (-6.028, 3.898, 15.179) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.820045922544E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #3 (acet): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 62.632 MB total, 123.513 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.225 x 0.225 x 0.225 Grid lengths: 14.400 x 14.400 x 14.400 Grid center: (-6.028, 3.898, 15.179) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 6.460002606908E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #4 (hca): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 127.616 MB total, 127.616 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 1.500 x 1.500 x 1.500 Grid lengths: 96.000 x 96.000 x 96.000 Grid center: (-6.028, 3.898, 15.179) Multigrid levels: 5 Molecule ID: 2 Linearized traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.189161497021E+04 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #5 (hca): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 127.616 MB total, 207.303 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.581 x 0.581 x 0.581 Grid lengths: 37.181 x 37.181 x 37.181 Grid center: (-6.028, 3.898, 15.179) Multigrid levels: 5 Molecule ID: 2 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.520000494925E+05 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #6 (hca): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 127.616 MB total, 207.303 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.225 x 0.225 x 0.225 Grid lengths: 14.400 x 14.400 x 14.400 Grid center: (-6.028, 3.898, 15.179) Multigrid levels: 5 Molecule ID: 2 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.790436191580E+05 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #7 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 127.915 MB total, 207.303 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 1.500 x 1.500 x 1.500 Grid lengths: 96.000 x 96.000 x 96.000 Grid center: (-6.028, 3.898, 15.179) Multigrid levels: 5 Molecule ID: 3 Linearized traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.195842512312E+04 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #8 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 127.915 MB total, 207.713 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.581 x 0.581 x 0.581 Grid lengths: 37.181 x 37.181 x 37.181 Grid center: (-6.028, 3.898, 15.179) Multigrid levels: 5 Molecule ID: 3 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.537771604355E+05 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #9 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 127.915 MB total, 207.713 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.225 x 0.225 x 0.225 Grid lengths: 14.400 x 14.400 x 14.400 Grid center: (-6.028, 3.898, 15.179) Multigrid levels: 5 Molecule ID: 3 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.540 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.854495619747E+05 kJ/mol Calculating forces... ---------------------------------------- PRINT STATEMENTS print energy 3 (complex) - 1 (acet) - 2 (hca) end Local net energy (PE 0) = -5.405979017066E+01 kJ/mol Global net ELEC energy = -5.405979017066E+01 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 207.713 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-smol.out RESULT 188.4888131017 RESULT 1820.045922544 RESULT 6460.002606908 RESULT 21891.61497021 RESULT 152000.0494925 RESULT 179043.619158 RESULT 21958.42512312 RESULT 153777.1604355 RESULT 185449.5619747 RESULT -54.05979017066 Testing computed result 1.884888131017E+02 against expected result 1.884888E+02 *** PASSED *** Testing computed result 1.820045922544E+03 against expected result 1.820046E+03 *** PASSED *** Testing computed result 6.460002606908E+03 against expected result 6.460003E+03 *** PASSED *** Testing computed result 2.189161497021E+04 against expected result 2.189161E+04 *** PASSED *** Testing computed result 1.520000494925E+05 against expected result 1.520000E+05 *** PASSED *** Testing computed result 1.790436191580E+05 against expected result 1.790436E+05 *** PASSED *** Testing computed result 2.195842512312E+04 against expected result 2.195843E+04 *** PASSED *** Testing computed result 1.537771604355E+05 against expected result 1.537772E+05 *** PASSED *** Testing computed result 1.854495619747E+05 against expected result 1.854496E+05 *** PASSED *** Testing computed result -5.405979017066E+01 against expected result -5.405978E+01 *** PASSED *** Elapsed time: 35.715974 seconds -------------------------------------------------------------------------------- Total elapsed time: 76.091142 seconds Test results have been logged -------------------------------------------------------------------------------- Running tests for ionize section -------------------------------------------------------------------------------- Testing input file apbs-mol.in BINARY: apbs INPUT: apbs-mol.in ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-mol.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading XML-format atom data from acetic-acid.xml. Valist_readXML: Warning Warning Warning Warning Warning Valist_readXML: The use of XML input files with parameter Valist_readXML: files is currently not supported. Valist_readXML: Warning Warning Warning Warning Warning 8 atoms Centered at (0.000e+00, -1.535e-01, 1.287e+00) Net charge -1.67e-16 e Reading XML-format atom data from acetate.xml. Valist_readXML: Warning Warning Warning Warning Warning Valist_readXML: The use of XML input files with parameter Valist_readXML: files is currently not supported. Valist_readXML: Warning Warning Warning Warning Warning 8 atoms Centered at (0.000e+00, -1.535e-01, 1.287e+00) Net charge -1.00e+00 e Reading XML-format atom data from proton.xml. Valist_readXML: Warning Warning Warning Warning Warning Valist_readXML: The use of XML input files with parameter Valist_readXML: files is currently not supported. Valist_readXML: Warning Warning Warning Warning Warning 1 atoms Centered at (1.780e-01, -1.286e+00, 2.937e+00) Net charge 1.00e+00 e Preparing to run 12 PBE calculations. ---------------------------------------- CALCULATION #1 (acetic-solv): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 7.76163 A Current memory usage: 61.581 MB total, 61.581 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.188 x 0.188 x 0.188 Grid lengths: 12.000 x 12.000 x 12.000 Grid center: (0.000, -0.154, 1.287) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.150 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.150 M concentration 2.000 A-radius, -1.000 e-charge, 0.150 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 293.000 K Electrostatic energies will be calculated Total electrostatic energy = 5.823898055191E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (acetic-solv): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 7.76163 A Current memory usage: 61.581 MB total, 122.371 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.094 x 0.094 x 0.094 Grid lengths: 6.000 x 6.000 x 6.000 Grid center: (0.000, -0.154, 1.287) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.150 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.150 M concentration 2.000 A-radius, -1.000 e-charge, 0.150 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 293.000 K Electrostatic energies will be calculated Total electrostatic energy = 9.793274462353E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #3 (acetic-ref): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 61.405 MB total, 122.371 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.188 x 0.188 x 0.188 Grid lengths: 12.000 x 12.000 x 12.000 Grid center: (0.000, -0.154, 1.287) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 2.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 293.000 K Electrostatic energies will be calculated Total electrostatic energy = 5.846917564309E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #4 (acetic-ref): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 61.405 MB total, 122.371 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.094 x 0.094 x 0.094 Grid lengths: 6.000 x 6.000 x 6.000 Grid center: (0.000, -0.154, 1.287) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 2.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 293.000 K Electrostatic energies will be calculated Total electrostatic energy = 9.815953282539E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #5 (acetate-solv): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 7.76163 A Current memory usage: 61.581 MB total, 122.371 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.188 x 0.188 x 0.188 Grid lengths: 12.000 x 12.000 x 12.000 Grid center: (0.000, -0.154, 1.287) Multigrid levels: 5 Molecule ID: 2 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.150 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.150 M concentration 2.000 A-radius, -1.000 e-charge, 0.150 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 293.000 K Electrostatic energies will be calculated Total electrostatic energy = 8.219846763777E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #6 (acetate-solv): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 7.76163 A Current memory usage: 61.581 MB total, 122.371 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.094 x 0.094 x 0.094 Grid lengths: 6.000 x 6.000 x 6.000 Grid center: (0.000, -0.154, 1.287) Multigrid levels: 5 Molecule ID: 2 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.150 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.150 M concentration 2.000 A-radius, -1.000 e-charge, 0.150 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 293.000 K Electrostatic energies will be calculated Total electrostatic energy = 1.392741988698E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #7 (acetate-ref): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 61.405 MB total, 122.371 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.188 x 0.188 x 0.188 Grid lengths: 12.000 x 12.000 x 12.000 Grid center: (0.000, -0.154, 1.287) Multigrid levels: 5 Molecule ID: 2 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 2.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 293.000 K Electrostatic energies will be calculated Total electrostatic energy = 8.420373979905E+03 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #8 (acetate-ref): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 61.405 MB total, 122.371 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.094 x 0.094 x 0.094 Grid lengths: 6.000 x 6.000 x 6.000 Grid center: (0.000, -0.154, 1.287) Multigrid levels: 5 Molecule ID: 2 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 2.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 293.000 K Electrostatic energies will be calculated Total electrostatic energy = 1.412716615065E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #9 (proton-solv): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 7.76163 A Current memory usage: 61.410 MB total, 122.371 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.188 x 0.188 x 0.188 Grid lengths: 12.000 x 12.000 x 12.000 Grid center: (0.000, -0.154, 1.287) Multigrid levels: 5 Molecule ID: 3 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.150 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.150 M concentration 2.000 A-radius, -1.000 e-charge, 0.150 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 293.000 K Electrostatic energies will be calculated Total electrostatic energy = 3.862359524598E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #10 (proton-solv): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 7.76163 A Current memory usage: 61.410 MB total, 122.371 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.094 x 0.094 x 0.094 Grid lengths: 6.000 x 6.000 x 6.000 Grid center: (0.000, -0.154, 1.287) Multigrid levels: 5 Molecule ID: 3 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.150 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.150 M concentration 2.000 A-radius, -1.000 e-charge, 0.150 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 293.000 K Electrostatic energies will be calculated Total electrostatic energy = 6.288156251610E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #11 (proton-ref): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 61.371 MB total, 122.371 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.188 x 0.188 x 0.188 Grid lengths: 12.000 x 12.000 x 12.000 Grid center: (0.000, -0.154, 1.287) Multigrid levels: 5 Molecule ID: 3 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 2.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 293.000 K Electrostatic energies will be calculated Total electrostatic energy = 4.162533113906E+03 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #12 (proton-ref): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 61.371 MB total, 122.371 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.094 x 0.094 x 0.094 Grid lengths: 6.000 x 6.000 x 6.000 Grid center: (0.000, -0.154, 1.287) Multigrid levels: 5 Molecule ID: 3 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 2.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 293.000 K Electrostatic energies will be calculated Total electrostatic energy = 6.585616091973E+03 kJ/mol Calculating forces... ---------------------------------------- PRINT STATEMENTS print energy 1 (acetic-solv) - 2 (acetic-ref) end Local net energy (PE 0) = -2.267882018629E+01 kJ/mol Global net ELEC energy = -2.267882018629E+01 kJ/mol print energy 3 (acetate-solv) - 4 (acetate-ref) end Local net energy (PE 0) = -1.997462636633E+02 kJ/mol Global net ELEC energy = -1.997462636633E+02 kJ/mol print energy 5 (proton-solv) - 6 (proton-ref) end Local net energy (PE 0) = -2.974598403628E+02 kJ/mol Global net ELEC energy = -2.974598403628E+02 kJ/mol print energy 3 (acetate-solv) - 4 (acetate-ref) + 5 (proton-solv) - 6 (proton-ref) - 1 (acetic-solv) + 2 (acetic-ref) end Local net energy (PE 0) = -4.745272838398E+02 kJ/mol Global net ELEC energy = -4.745272838398E+02 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 122.371 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-mol.out RESULT 5823.898055191 RESULT 9793.274462353 RESULT 5846.917564309 RESULT 9815.953282539 RESULT 8219.846763777 RESULT 13927.41988698 RESULT 8420.373979905 RESULT 14127.16615065 RESULT 3862.359524598 RESULT 6288.15625161 RESULT 4162.533113906 RESULT 6585.616091973 RESULT -22.67882018629 RESULT -199.7462636633 RESULT -297.4598403628 RESULT -474.5272838398 Testing computed result 5.823898055191E+03 against expected result 5.823898E+03 *** PASSED *** Testing computed result 9.793274462353E+03 against expected result 9.793274E+03 *** PASSED *** Testing computed result 5.846917564309E+03 against expected result 5.846918E+03 *** PASSED *** Testing computed result 9.815953282539E+03 against expected result 9.815953E+03 *** PASSED *** Testing computed result 8.219846763777E+03 against expected result 8.219847E+03 *** PASSED *** Testing computed result 1.392741988698E+04 against expected result 1.392742E+04 *** PASSED *** Testing computed result 8.420373979905E+03 against expected result 8.420374E+03 *** PASSED *** Testing computed result 1.412716615065E+04 against expected result 1.412717E+04 *** PASSED *** Testing computed result 3.862359524598E+03 against expected result 3.862360E+03 *** PASSED *** Testing computed result 6.288156251610E+03 against expected result 6.288156E+03 *** PASSED *** Testing computed result 4.162533113906E+03 against expected result 4.162533E+03 *** PASSED *** Testing computed result 6.585616091973E+03 against expected result 6.585616E+03 *** PASSED *** Testing computed result -2.267882018629E+01 against expected result -2.267882E+01 *** PASSED *** Testing computed result -1.997462636633E+02 against expected result -1.997463E+02 *** PASSED *** Testing computed result -2.974598403628E+02 against expected result -2.974598E+02 *** PASSED *** Testing computed result -4.745272838398E+02 against expected result -4.745273E+02 *** PASSED *** Elapsed time: 13.907971 seconds -------------------------------------------------------------------------------- -------------------------------------------------------------------------------- Testing input file apbs-smol.in BINARY: apbs INPUT: apbs-smol.in ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-smol.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading XML-format atom data from acetic-acid.xml. Valist_readXML: Warning Warning Warning Warning Warning Valist_readXML: The use of XML input files with parameter Valist_readXML: files is currently not supported. Valist_readXML: Warning Warning Warning Warning Warning 8 atoms Centered at (0.000e+00, -1.535e-01, 1.287e+00) Net charge -1.67e-16 e Reading XML-format atom data from acetate.xml. Valist_readXML: Warning Warning Warning Warning Warning Valist_readXML: The use of XML input files with parameter Valist_readXML: files is currently not supported. Valist_readXML: Warning Warning Warning Warning Warning 8 atoms Centered at (0.000e+00, -1.535e-01, 1.287e+00) Net charge -1.00e+00 e Reading XML-format atom data from proton.xml. Valist_readXML: Warning Warning Warning Warning Warning Valist_readXML: The use of XML input files with parameter Valist_readXML: files is currently not supported. Valist_readXML: Warning Warning Warning Warning Warning 1 atoms Centered at (1.780e-01, -1.286e+00, 2.937e+00) Net charge 1.00e+00 e Preparing to run 12 PBE calculations. ---------------------------------------- CALCULATION #1 (acetic-solv): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 7.76163 A Current memory usage: 61.581 MB total, 61.581 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.188 x 0.188 x 0.188 Grid lengths: 12.000 x 12.000 x 12.000 Grid center: (0.000, -0.154, 1.287) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.150 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.150 M concentration 2.000 A-radius, -1.000 e-charge, 0.150 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 293.000 K Electrostatic energies will be calculated Total electrostatic energy = 5.824172730822E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (acetic-solv): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 7.76163 A Current memory usage: 61.581 MB total, 122.371 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.094 x 0.094 x 0.094 Grid lengths: 6.000 x 6.000 x 6.000 Grid center: (0.000, -0.154, 1.287) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.150 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.150 M concentration 2.000 A-radius, -1.000 e-charge, 0.150 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 293.000 K Electrostatic energies will be calculated Total electrostatic energy = 9.793622759239E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #3 (acetic-ref): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 61.405 MB total, 122.371 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.188 x 0.188 x 0.188 Grid lengths: 12.000 x 12.000 x 12.000 Grid center: (0.000, -0.154, 1.287) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 2.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 293.000 K Electrostatic energies will be calculated Total electrostatic energy = 5.846917564309E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #4 (acetic-ref): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 61.405 MB total, 122.371 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.094 x 0.094 x 0.094 Grid lengths: 6.000 x 6.000 x 6.000 Grid center: (0.000, -0.154, 1.287) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 2.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 293.000 K Electrostatic energies will be calculated Total electrostatic energy = 9.815953282539E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #5 (acetate-solv): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 7.76163 A Current memory usage: 61.581 MB total, 122.371 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.188 x 0.188 x 0.188 Grid lengths: 12.000 x 12.000 x 12.000 Grid center: (0.000, -0.154, 1.287) Multigrid levels: 5 Molecule ID: 2 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.150 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.150 M concentration 2.000 A-radius, -1.000 e-charge, 0.150 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 293.000 K Electrostatic energies will be calculated Total electrostatic energy = 8.221328580569E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #6 (acetate-solv): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 7.76163 A Current memory usage: 61.581 MB total, 122.371 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.094 x 0.094 x 0.094 Grid lengths: 6.000 x 6.000 x 6.000 Grid center: (0.000, -0.154, 1.287) Multigrid levels: 5 Molecule ID: 2 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.150 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.150 M concentration 2.000 A-radius, -1.000 e-charge, 0.150 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 293.000 K Electrostatic energies will be calculated Total electrostatic energy = 1.392867783119E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #7 (acetate-ref): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 61.405 MB total, 122.371 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.188 x 0.188 x 0.188 Grid lengths: 12.000 x 12.000 x 12.000 Grid center: (0.000, -0.154, 1.287) Multigrid levels: 5 Molecule ID: 2 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 2.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 293.000 K Electrostatic energies will be calculated Total electrostatic energy = 8.420373979905E+03 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #8 (acetate-ref): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 61.405 MB total, 122.371 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.094 x 0.094 x 0.094 Grid lengths: 6.000 x 6.000 x 6.000 Grid center: (0.000, -0.154, 1.287) Multigrid levels: 5 Molecule ID: 2 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 2.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 293.000 K Electrostatic energies will be calculated Total electrostatic energy = 1.412716615065E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #9 (proton-solv): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 7.76163 A Current memory usage: 61.410 MB total, 122.371 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.188 x 0.188 x 0.188 Grid lengths: 12.000 x 12.000 x 12.000 Grid center: (0.000, -0.154, 1.287) Multigrid levels: 5 Molecule ID: 3 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.150 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.150 M concentration 2.000 A-radius, -1.000 e-charge, 0.150 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 293.000 K Electrostatic energies will be calculated Total electrostatic energy = 3.863066835285E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #10 (proton-solv): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 7.76163 A Current memory usage: 61.410 MB total, 122.371 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.094 x 0.094 x 0.094 Grid lengths: 6.000 x 6.000 x 6.000 Grid center: (0.000, -0.154, 1.287) Multigrid levels: 5 Molecule ID: 3 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.150 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.150 M concentration 2.000 A-radius, -1.000 e-charge, 0.150 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 293.000 K Electrostatic energies will be calculated Total electrostatic energy = 6.289649216644E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #11 (proton-ref): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 61.371 MB total, 122.371 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.188 x 0.188 x 0.188 Grid lengths: 12.000 x 12.000 x 12.000 Grid center: (0.000, -0.154, 1.287) Multigrid levels: 5 Molecule ID: 3 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 2.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 293.000 K Electrostatic energies will be calculated Total electrostatic energy = 4.162533113906E+03 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #12 (proton-ref): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 61.371 MB total, 122.371 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.094 x 0.094 x 0.094 Grid lengths: 6.000 x 6.000 x 6.000 Grid center: (0.000, -0.154, 1.287) Multigrid levels: 5 Molecule ID: 3 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 2.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 293.000 K Electrostatic energies will be calculated Total electrostatic energy = 6.585616091973E+03 kJ/mol Calculating forces... ---------------------------------------- PRINT STATEMENTS print energy 1 (acetic-solv) - 2 (acetic-ref) end Local net energy (PE 0) = -2.233052329981E+01 kJ/mol Global net ELEC energy = -2.233052329981E+01 kJ/mol print energy 3 (acetate-solv) - 4 (acetate-ref) end Local net energy (PE 0) = -1.984883194538E+02 kJ/mol Global net ELEC energy = -1.984883194538E+02 kJ/mol print energy 5 (proton-solv) - 6 (proton-ref) end Local net energy (PE 0) = -2.959668753288E+02 kJ/mol Global net ELEC energy = -2.959668753288E+02 kJ/mol print energy 3 (acetate-solv) - 4 (acetate-ref) + 5 (proton-solv) - 6 (proton-ref) - 1 (acetic-solv) + 2 (acetic-ref) end Local net energy (PE 0) = -4.721246714828E+02 kJ/mol Global net ELEC energy = -4.721246714828E+02 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 122.371 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-smol.out RESULT 5824.172730822 RESULT 9793.622759239 RESULT 5846.917564309 RESULT 9815.953282539 RESULT 8221.328580569 RESULT 13928.67783119 RESULT 8420.373979905 RESULT 14127.16615065 RESULT 3863.066835285 RESULT 6289.649216644 RESULT 4162.533113906 RESULT 6585.616091973 RESULT -22.33052329981 RESULT -198.4883194538 RESULT -295.9668753288 RESULT -472.1246714828 Testing computed result 5.824172730822E+03 against expected result 5.824173E+03 *** PASSED *** Testing computed result 9.793622759239E+03 against expected result 9.793623E+03 *** PASSED *** Testing computed result 5.846917564309E+03 against expected result 5.846918E+03 *** PASSED *** Testing computed result 9.815953282539E+03 against expected result 9.815953E+03 *** PASSED *** Testing computed result 8.221328580569E+03 against expected result 8.221329E+03 *** PASSED *** Testing computed result 1.392867783119E+04 against expected result 1.392868E+04 *** PASSED *** Testing computed result 8.420373979905E+03 against expected result 8.420374E+03 *** PASSED *** Testing computed result 1.412716615065E+04 against expected result 1.412717E+04 *** PASSED *** Testing computed result 3.863066835285E+03 against expected result 3.863067E+03 *** PASSED *** Testing computed result 6.289649216644E+03 against expected result 6.289649E+03 *** PASSED *** Testing computed result 4.162533113906E+03 against expected result 4.162533E+03 *** PASSED *** Testing computed result 6.585616091973E+03 against expected result 6.585616E+03 *** PASSED *** Testing computed result -2.233052329981E+01 against expected result -2.233050E+01 *** PASSED *** Testing computed result -1.984883194538E+02 against expected result -1.984883E+02 *** PASSED *** Testing computed result -2.959668753288E+02 against expected result -2.959669E+02 *** PASSED *** Testing computed result -4.721246714828E+02 against expected result -4.721247E+02 *** PASSED *** Elapsed time: 12.622965 seconds -------------------------------------------------------------------------------- Total elapsed time: 26.530936 seconds Test results have been logged -------------------------------------------------------------------------------- Running tests for ion-pmf section -------------------------------------------------------------------------------- Testing input file ion-pmf.in BINARY: apbs INPUT: ion-pmf.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file ion-pmf.in... rank 0 size 1... Parsed input file. Reading parameter data from parm.dat. Got paths for 1 molecules Reading PDB-format atom data from ion-pmf.pdb. Vpmg_ibForce: No force for zero ionic strength! Vpmg_ibForce: No force for zero ionic strength! 2 atoms Centered at (-1.000e+00, 0.000e+00, 0.000e+00) Net charge 2.00e+00 e Preparing to run 3 PBE calculations. ---------------------------------------- CALCULATION #1 (solv): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.094 MB total, 61.094 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.210 x 0.210 x 0.210 Grid lengths: 13.440 x 13.440 x 13.440 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 78.540 Using spline-based surface definition;window = 0.300 Temperature: 298.150 K Electrostatic energies will be calculated All-atom solvent forces will be calculated Total electrostatic energy = 7.839535983197E+03 kJ/mol Calculating forces... Printing per-atom forces for molecule 1 (kJ/mol/A) Legend: tot n -- total force for atom n qf n -- fixed charge force for atom n db n -- dielectric boundary force for atom n ib n -- ionic boundary force for atom n mgF tot 0 -3.760e+03 -4.398e-05 -7.763e-05 mgF qf 0 -3.767e+03 -1.730e-05 -2.384e-05 mgF ib 0 0.000e+00 0.000e+00 0.000e+00 mgF db 0 6.148e+00 -2.668e-05 -5.379e-05 mgF tot 1 -3.596e+03 -5.403e-05 -1.012e-04 mgF qf 1 -3.598e+03 -2.253e-05 -3.831e-05 mgF ib 1 0.000e+00 0.000e+00 0.000e+00 mgF db 1 2.883e+00 -3.150e-05 -6.291e-05 Vpmg_ibForce: No force for zero ionic strength! Vpmg_ibForce: No force for zero ionic strength! ---------------------------------------- CALCULATION #2 (ref): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.095 MB total, 61.134 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.210 x 0.210 x 0.210 Grid lengths: 13.440 x 13.440 x 13.440 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 0 ion species (0.000 M ionic strength): Solute dielectric: 1.000 Solvent dielectric: 1.000 Using spline-based surface definition;window = 0.300 Temperature: 298.150 K Electrostatic energies will be calculated All-atom solvent forces will be calculated Total electrostatic energy = 8.964727588811E+03 kJ/mol Calculating forces... Printing per-atom forces for molecule 1 (kJ/mol/A) Legend: tot n -- total force for atom n qf n -- fixed charge force for atom n db n -- dielectric boundary force for atom n ib n -- ionic boundary force for atom n mgF tot 0 -3.850e+03 -4.055e-06 -7.703e-06 mgF qf 0 -3.850e+03 -4.055e-06 -7.703e-06 mgF ib 0 0.000e+00 0.000e+00 0.000e+00 mgF db 0 0.000e+00 0.000e+00 0.000e+00 mgF tot 1 -3.514e+03 -4.163e-06 -7.690e-06 mgF qf 1 -3.514e+03 -4.163e-06 -7.690e-06 mgF ib 1 0.000e+00 0.000e+00 0.000e+00 mgF db 1 0.000e+00 0.000e+00 0.000e+00 ---------------------------------------- CALCULATION #3 (asolv): APOLAR Printing per atom forces (kJ/mol/A) Legend: tot n -- Total force for atom n sasa n -- SASA force for atom n sav n -- SAV force for atom n wca n -- WCA force for atom n gamma 0.000720 pressure 0.000000 bconc 0.033000 tot 0 2.715e-02 9.130e-07 9.130e-07 sasa 0 -1.100e+01 0.000e+00 0.000e+00 sav 0 0.000e+00 0.000e+00 0.000e+00 wca 0 -5.827e-01 -2.767e-05 -2.767e-05 tot 1 -2.723e-02 9.133e-07 9.133e-07 sasa 1 1.112e+01 0.000e+00 0.000e+00 sav 1 0.000e+00 0.000e+00 0.000e+00 wca 1 5.827e-01 -2.767e-05 -2.767e-05 Solvent Accessible Surface Area (SASA) for each atom: SASA for atom 0: 1.153275282828E+02 SASA for atom 1: 1.153114143344E+02 Total solvent accessible surface area: 230.639 A^2 Surface tension*area energies (gamma * SASA) for each atom: Surface tension*area energy for atom 0: 8.303582036361E-02 Surface tension*area energy for atom 1: 8.302421832080E-02 Total surface tension energy: 0.16606 kJ/mol Total solvent accessible volume: 0 A^3 Total pressure*volume energy: 0 kJ/mol WCA dispersion Energies for each atom: WCA energy for atom 0: -6.909718359932E+00 WCA energy for atom 1: -6.909422551724E+00 Total WCA energy: -13.8191 kJ/mol Total non-polar energy = -1.365308087297E+01 kJ/mol ---------------------------------------- PRINT STATEMENTS print energy 1 (solv) - 2 (ref) end Local net energy (PE 0) = -1.125191605614E+03 kJ/mol Global net ELEC energy = -1.125191605614E+03 kJ/mol print force 1 (solv) - 2 (ref) end Printing per-atom forces (kJ/mol/A). Legend: tot n -- Total force for atom n qf n -- Fixed charge force for atom n db n -- Dielectric boundary force for atom n ib n -- Ionic boundary force for atom n tot all -- Total force for system qf 0 8.398642197666E+01 -1.324564548552E-05 -1.613435632529E-05 ib 0 0.000000000000E+00 0.000000000000E+00 0.000000000000E+00 db 0 6.148357059184E+00 -2.667517425897E-05 -5.378919678211E-05 tot 0 9.013477903584E+01 -3.992081974449E-05 -6.992355310740E-05 qf 1 -8.466423642736E+01 -1.836748045969E-05 -3.062224428458E-05 ib 1 0.000000000000E+00 0.000000000000E+00 0.000000000000E+00 db 1 2.882739230548E+00 -3.149946357588E-05 -6.291495506459E-05 tot 1 -8.178149719681E+01 -4.986694403557E-05 -9.353719934917E-05 tot all 8.353281839029E+00 -8.978776378007E-05 -1.634607524566E-04 print APOL energy 1 (asolv) end Global net APOL energy = -1.365308087297E+01 kJ/mol print APOL force 1 (asolv) end Printing per atom forces (kJ/mol/A) Legend: tot n -- Total force for atom n sasa n -- SASA force for atom n sav n -- SAV force for atom n wca n -- WCA force for atom n tot all -- Total force for system sasa 0 -1.099776974333E+01 0.000000000000E+00 0.000000000000E+00 sav 0 0.000000000000E+00 0.000000000000E+00 0.000000000000E+00 wca 0 -5.826577086437E-01 -2.766670515801E-05 -2.766670515838E-05 tot 0 -1.158042745197E+01 -2.766670515801E-05 -2.766670515838E-05 sasa 1 1.111862435589E+01 0.000000000000E+00 0.000000000000E+00 sav 1 0.000000000000E+00 0.000000000000E+00 0.000000000000E+00 wca 1 5.826560767576E-01 -2.767485007141E-05 -2.767485007183E-05 tot 1 1.170128043265E+01 -2.767485007141E-05 -2.767485007183E-05 tot all 1.208529806779E-01 -5.534155522943E-05 -5.534155523021E-05 ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 1 molecules Final memory usage: 60.711 MB total, 62.228 MB high water Thanks for using APBS! Checking for intermidiate energies in input file ion-pmf.out RESULT 7839.535983197 RESULT 8964.727588811 RESULT -1125.191605614 RESULT -13.65308087297 Testing computed result 7.839535983197E+03 against expected result 7.839536E+03 *** PASSED *** Testing computed result 8.964727588811E+03 against expected result 8.964728E+03 *** PASSED *** Testing computed result -1.125191605614E+03 against expected result -1.125192E+03 *** PASSED *** Elapsed time: 38.233613 seconds -------------------------------------------------------------------------------- Total elapsed time: 38.233613 seconds Test results have been logged -------------------------------------------------------------------------------- Running tests for pka-lig section -------------------------------------------------------------------------------- Testing input file apbs-mol-vdw.in BINARY: apbs INPUT: apbs-mol-vdw.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-mol-vdw.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from bx6_7_lig_apbs.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 47 atoms Centered at (2.482e+01, -3.315e+01, 2.154e+01) Net charge 1.11e-16 e Reading PQR-format atom data from bx6_7_apo_apbs.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 3423 atoms Centered at (2.897e+01, -3.251e+01, 2.702e+01) Net charge 1.00e+00 e Reading PQR-format atom data from bx6_7_bin_apbs.pqr. 3470 atoms Centered at (2.897e+01, -3.251e+01, 2.702e+01) Net charge 1.00e+00 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (lig-coarse): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 203.811 MB total, 203.811 MB high water Using linear spline charge discretization. Grid dimensions: 97 x 97 x 97 Grid spacings: 0.729 x 0.729 x 0.729 Grid lengths: 70.000 x 70.000 x 70.000 Grid center: (28.969, -32.507, 27.022) Multigrid levels: 4 Molecule ID: 1 Linearized traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.224988750664E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (lig-fine): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 203.811 MB total, 405.040 MB high water Using linear spline charge discretization. Grid dimensions: 97 x 97 x 97 Grid spacings: 0.250 x 0.250 x 0.250 Grid lengths: 24.000 x 24.000 x 24.000 Grid center: (24.822, -33.153, 21.545) Multigrid levels: 4 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.049695084686E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #3 (pka-coarse): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 270.381 MB total, 405.040 MB high water Using linear spline charge discretization. Grid dimensions: 97 x 97 x 97 Grid spacings: 0.729 x 0.729 x 0.729 Grid lengths: 70.000 x 70.000 x 70.000 Grid center: (28.969, -32.507, 27.022) Multigrid levels: 4 Molecule ID: 2 Linearized traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.818450789522E+05 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #4 (pka-fine): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 270.381 MB total, 491.899 MB high water Using linear spline charge discretization. Grid dimensions: 97 x 97 x 97 Grid spacings: 0.250 x 0.250 x 0.250 Grid lengths: 24.000 x 24.000 x 24.000 Grid center: (24.822, -33.153, 21.545) Multigrid levels: 4 Molecule ID: 2 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 3.008254338259E+05 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #5 (complex-coarse): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 271.059 MB total, 491.899 MB high water Using linear spline charge discretization. Grid dimensions: 97 x 97 x 97 Grid spacings: 0.729 x 0.729 x 0.729 Grid lengths: 70.000 x 70.000 x 70.000 Grid center: (28.969, -32.507, 27.022) Multigrid levels: 4 Molecule ID: 3 Linearized traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.840918409896E+05 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #6 (complex-fine): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 271.059 MB total, 492.811 MB high water Using linear spline charge discretization. Grid dimensions: 97 x 97 x 97 Grid spacings: 0.250 x 0.250 x 0.250 Grid lengths: 24.000 x 24.000 x 24.000 Grid center: (24.822, -33.153, 21.545) Multigrid levels: 4 Molecule ID: 3 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 3.113304681884E+05 kJ/mol Calculating forces... ---------------------------------------- PRINT STATEMENTS print energy 6 (complex-fine) - 2 (lig-fine) - 4 (pka-fine) end Local net energy (PE 0) = 8.083515648730E+00 kJ/mol Global net ELEC energy = 8.083515648730E+00 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 492.811 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-mol-vdw.out RESULT 2224.988750664 RESULT 10496.95084686 RESULT 181845.0789522 RESULT 300825.4338259 RESULT 184091.8409896 RESULT 311330.4681884 RESULT 8.08351564873 Testing computed result 2.224988750664E+03 against expected result 2.224989E+03 *** PASSED *** Testing computed result 1.049695084686E+04 against expected result 1.049695E+04 *** PASSED *** Testing computed result 1.818450789522E+05 against expected result 1.818451E+05 *** PASSED *** Testing computed result 3.008254338259E+05 against expected result 3.008254E+05 *** PASSED *** Testing computed result 1.840918409896E+05 against expected result 1.840918E+05 *** PASSED *** Testing computed result 3.113304681884E+05 against expected result 3.113305E+05 *** PASSED *** Testing computed result 8.083515648730E+00 against expected result 8.083516E+00 *** PASSED *** Elapsed time: 60.661750 seconds -------------------------------------------------------------------------------- -------------------------------------------------------------------------------- Testing input file apbs-smol-vdw.in BINARY: apbs INPUT: apbs-smol-vdw.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-smol-vdw.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from bx6_7_lig_apbs.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 47 atoms Centered at (2.482e+01, -3.315e+01, 2.154e+01) Net charge 1.11e-16 e Reading PQR-format atom data from bx6_7_apo_apbs.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 3423 atoms Centered at (2.897e+01, -3.251e+01, 2.702e+01) Net charge 1.00e+00 e Reading PQR-format atom data from bx6_7_bin_apbs.pqr. 3470 atoms Centered at (2.897e+01, -3.251e+01, 2.702e+01) Net charge 1.00e+00 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (lig-coarse): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 203.811 MB total, 203.811 MB high water Using linear spline charge discretization. Grid dimensions: 97 x 97 x 97 Grid spacings: 0.729 x 0.729 x 0.729 Grid lengths: 70.000 x 70.000 x 70.000 Grid center: (28.969, -32.507, 27.022) Multigrid levels: 4 Molecule ID: 1 Linearized traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.226793167046E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (lig-fine): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 203.811 MB total, 405.040 MB high water Using linear spline charge discretization. Grid dimensions: 97 x 97 x 97 Grid spacings: 0.250 x 0.250 x 0.250 Grid lengths: 24.000 x 24.000 x 24.000 Grid center: (24.822, -33.153, 21.545) Multigrid levels: 4 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.050504485887E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #3 (pka-coarse): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 270.381 MB total, 405.040 MB high water Using linear spline charge discretization. Grid dimensions: 97 x 97 x 97 Grid spacings: 0.729 x 0.729 x 0.729 Grid lengths: 70.000 x 70.000 x 70.000 Grid center: (28.969, -32.507, 27.022) Multigrid levels: 4 Molecule ID: 2 Linearized traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.827976621645E+05 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #4 (pka-fine): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 270.381 MB total, 491.899 MB high water Using linear spline charge discretization. Grid dimensions: 97 x 97 x 97 Grid spacings: 0.250 x 0.250 x 0.250 Grid lengths: 24.000 x 24.000 x 24.000 Grid center: (24.822, -33.153, 21.545) Multigrid levels: 4 Molecule ID: 2 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 3.017228546773E+05 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #5 (complex-coarse): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 271.059 MB total, 491.899 MB high water Using linear spline charge discretization. Grid dimensions: 97 x 97 x 97 Grid spacings: 0.729 x 0.729 x 0.729 Grid lengths: 70.000 x 70.000 x 70.000 Grid center: (28.969, -32.507, 27.022) Multigrid levels: 4 Molecule ID: 3 Linearized traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.850819075387E+05 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #6 (complex-fine): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 271.059 MB total, 492.811 MB high water Using linear spline charge discretization. Grid dimensions: 97 x 97 x 97 Grid spacings: 0.250 x 0.250 x 0.250 Grid lengths: 24.000 x 24.000 x 24.000 Grid center: (24.822, -33.153, 21.545) Multigrid levels: 4 Molecule ID: 3 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 3.122488625388E+05 kJ/mol Calculating forces... ---------------------------------------- PRINT STATEMENTS print energy 6 (complex-fine) - 2 (lig-fine) - 4 (pka-fine) end Local net energy (PE 0) = 2.096300255723E+01 kJ/mol Global net ELEC energy = 2.096300255723E+01 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 492.811 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-smol-vdw.out RESULT 2226.793167046 RESULT 10505.04485887 RESULT 182797.6621645 RESULT 301722.8546773 RESULT 185081.9075387 RESULT 312248.8625388 RESULT 20.96300255723 Testing computed result 2.226793167046E+03 against expected result 2.226793E+03 *** PASSED *** Testing computed result 1.050504485887E+04 against expected result 1.050504E+04 *** PASSED *** Testing computed result 1.827976621645E+05 against expected result 1.827977E+05 *** PASSED *** Testing computed result 3.017228546773E+05 against expected result 3.017229E+05 *** PASSED *** Testing computed result 1.850819075387E+05 against expected result 1.850819E+05 *** PASSED *** Testing computed result 3.122488625388E+05 against expected result 3.122489E+05 *** PASSED *** Testing computed result 2.096300255723E+01 against expected result 2.096296E+01 *** PASSED *** Elapsed time: 48.492073 seconds -------------------------------------------------------------------------------- -------------------------------------------------------------------------------- Testing input file apbs-mol-surf.in BINARY: apbs INPUT: apbs-mol-surf.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-mol-surf.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from bx6_7_lig_apbs.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 47 atoms Centered at (2.482e+01, -3.315e+01, 2.154e+01) Net charge 1.11e-16 e Reading PQR-format atom data from bx6_7_apo_apbs.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 3423 atoms Centered at (2.897e+01, -3.251e+01, 2.702e+01) Net charge 1.00e+00 e Reading PQR-format atom data from bx6_7_bin_apbs.pqr. 3470 atoms Centered at (2.897e+01, -3.251e+01, 2.702e+01) Net charge 1.00e+00 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (lig-coarse): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 203.396 MB total, 203.396 MB high water Using linear spline charge discretization. Grid dimensions: 97 x 97 x 97 Grid spacings: 0.729 x 0.729 x 0.729 Grid lengths: 70.000 x 70.000 x 70.000 Grid center: (28.969, -32.507, 27.022) Multigrid levels: 4 Molecule ID: 1 Linearized traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.244350164274E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (lig-fine): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 203.396 MB total, 404.625 MB high water Using linear spline charge discretization. Grid dimensions: 97 x 97 x 97 Grid spacings: 0.250 x 0.250 x 0.250 Grid lengths: 24.000 x 24.000 x 24.000 Grid center: (24.822, -33.153, 21.545) Multigrid levels: 4 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.052149475373E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #3 (pka-coarse): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 230.750 MB total, 404.625 MB high water Using linear spline charge discretization. Grid dimensions: 97 x 97 x 97 Grid spacings: 0.729 x 0.729 x 0.729 Grid lengths: 70.000 x 70.000 x 70.000 Grid center: (28.969, -32.507, 27.022) Multigrid levels: 4 Molecule ID: 2 Linearized traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.862615690066E+05 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #4 (pka-fine): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 230.750 MB total, 452.268 MB high water Using linear spline charge discretization. Grid dimensions: 97 x 97 x 97 Grid spacings: 0.250 x 0.250 x 0.250 Grid lengths: 24.000 x 24.000 x 24.000 Grid center: (24.822, -33.153, 21.545) Multigrid levels: 4 Molecule ID: 2 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 3.051810884053E+05 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #5 (complex-coarse): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 230.854 MB total, 452.268 MB high water Using linear spline charge discretization. Grid dimensions: 97 x 97 x 97 Grid spacings: 0.729 x 0.729 x 0.729 Grid lengths: 70.000 x 70.000 x 70.000 Grid center: (28.969, -32.507, 27.022) Multigrid levels: 4 Molecule ID: 3 Linearized traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.886625455219E+05 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #6 (complex-fine): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 230.854 MB total, 452.606 MB high water Using linear spline charge discretization. Grid dimensions: 97 x 97 x 97 Grid spacings: 0.250 x 0.250 x 0.250 Grid lengths: 24.000 x 24.000 x 24.000 Grid center: (24.822, -33.153, 21.545) Multigrid levels: 4 Molecule ID: 3 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 3.158218439277E+05 kJ/mol Calculating forces... ---------------------------------------- PRINT STATEMENTS print energy 6 (complex-fine) - 2 (lig-fine) - 4 (pka-fine) end Local net energy (PE 0) = 1.192607686581E+02 kJ/mol Global net ELEC energy = 1.192607686581E+02 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 452.606 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-mol-surf.out RESULT 2244.350164274 RESULT 10521.49475373 RESULT 186261.5690066 RESULT 305181.0884053 RESULT 188662.5455219 RESULT 315821.8439277 RESULT 119.2607686581 Testing computed result 2.244350164274E+03 against expected result 2.244350E+03 *** PASSED *** Testing computed result 1.052149475373E+04 against expected result 1.052149E+04 *** PASSED *** Testing computed result 1.862615690066E+05 against expected result 1.862616E+05 *** PASSED *** Testing computed result 3.051810884053E+05 against expected result 3.051811E+05 *** PASSED *** Testing computed result 1.886625455219E+05 against expected result 1.886625E+05 *** PASSED *** Testing computed result 3.158218439277E+05 against expected result 3.158218E+05 *** PASSED *** Testing computed result 1.192607686581E+02 against expected result 1.192608E+02 *** PASSED *** Elapsed time: 47.880378 seconds -------------------------------------------------------------------------------- -------------------------------------------------------------------------------- Testing input file apbs-smol-surf.in BINARY: apbs INPUT: apbs-smol-surf.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-smol-surf.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from bx6_7_lig_apbs.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 47 atoms Centered at (2.482e+01, -3.315e+01, 2.154e+01) Net charge 1.11e-16 e Reading PQR-format atom data from bx6_7_apo_apbs.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 3423 atoms Centered at (2.897e+01, -3.251e+01, 2.702e+01) Net charge 1.00e+00 e Reading PQR-format atom data from bx6_7_bin_apbs.pqr. 3470 atoms Centered at (2.897e+01, -3.251e+01, 2.702e+01) Net charge 1.00e+00 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (lig-coarse): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 203.396 MB total, 203.396 MB high water Using linear spline charge discretization. Grid dimensions: 97 x 97 x 97 Grid spacings: 0.729 x 0.729 x 0.729 Grid lengths: 70.000 x 70.000 x 70.000 Grid center: (28.969, -32.507, 27.022) Multigrid levels: 4 Molecule ID: 1 Linearized traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.251466789420E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (lig-fine): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 203.396 MB total, 404.625 MB high water Using linear spline charge discretization. Grid dimensions: 97 x 97 x 97 Grid spacings: 0.250 x 0.250 x 0.250 Grid lengths: 24.000 x 24.000 x 24.000 Grid center: (24.822, -33.153, 21.545) Multigrid levels: 4 Molecule ID: 1 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.052814502873E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #3 (pka-coarse): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 230.750 MB total, 404.625 MB high water Using linear spline charge discretization. Grid dimensions: 97 x 97 x 97 Grid spacings: 0.729 x 0.729 x 0.729 Grid lengths: 70.000 x 70.000 x 70.000 Grid center: (28.969, -32.507, 27.022) Multigrid levels: 4 Molecule ID: 2 Linearized traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.864071689626E+05 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #4 (pka-fine): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 230.750 MB total, 452.268 MB high water Using linear spline charge discretization. Grid dimensions: 97 x 97 x 97 Grid spacings: 0.250 x 0.250 x 0.250 Grid lengths: 24.000 x 24.000 x 24.000 Grid center: (24.822, -33.153, 21.545) Multigrid levels: 4 Molecule ID: 2 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 3.053319953673E+05 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #5 (complex-coarse): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 230.854 MB total, 452.268 MB high water Using linear spline charge discretization. Grid dimensions: 97 x 97 x 97 Grid spacings: 0.729 x 0.729 x 0.729 Grid lengths: 70.000 x 70.000 x 70.000 Grid center: (28.969, -32.507, 27.022) Multigrid levels: 4 Molecule ID: 3 Linearized traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.888027142979E+05 kJ/mol Calculating forces... [focusFillBound()]: WARNING: Unusually large potential values detected on the focusing boundary! Convergence not guaranteed for NPBE/NRPBE calculations! ---------------------------------------- CALCULATION #6 (complex-fine): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 230.854 MB total, 452.606 MB high water Using linear spline charge discretization. Grid dimensions: 97 x 97 x 97 Grid spacings: 0.250 x 0.250 x 0.250 Grid lengths: 24.000 x 24.000 x 24.000 Grid center: (24.822, -33.153, 21.545) Multigrid levels: 4 Molecule ID: 3 Linearized traditional PBE Boundary conditions from focusing 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 3.159690177241E+05 kJ/mol Calculating forces... ---------------------------------------- PRINT STATEMENTS print energy 6 (complex-fine) - 2 (lig-fine) - 4 (pka-fine) end Local net energy (PE 0) = 1.088773280806E+02 kJ/mol Global net ELEC energy = 1.088773280806E+02 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 452.606 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-smol-surf.out RESULT 2251.46678942 RESULT 10528.14502873 RESULT 186407.1689626 RESULT 305331.9953673 RESULT 188802.7142979 RESULT 315969.0177241 RESULT 108.8773280806 Testing computed result 2.251466789420E+03 against expected result 2.251467E+03 *** PASSED *** Testing computed result 1.052814502873E+04 against expected result 1.052815E+04 *** PASSED *** Testing computed result 1.864071689626E+05 against expected result 1.864072E+05 *** PASSED *** Testing computed result 3.053319953673E+05 against expected result 3.053320E+05 *** PASSED *** Testing computed result 1.888027142979E+05 against expected result 1.888027E+05 *** PASSED *** Testing computed result 3.159690177241E+05 against expected result 3.159690E+05 *** PASSED *** Testing computed result 1.088773280806E+02 against expected result 1.088773E+02 *** PASSED *** Elapsed time: 42.869977 seconds -------------------------------------------------------------------------------- Total elapsed time: 199.904178 seconds Test results have been logged -------------------------------------------------------------------------------- Running tests for point-pmf section -------------------------------------------------------------------------------- Testing input file complex-0_1.in BINARY: apbs INPUT: complex-0_1.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file complex-0_1.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from mol0.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 1 atoms Centered at (-3.000e+00, 0.000e+00, 0.000e+00) Net charge 1.00e+00 e Reading PQR-format atom data from mol1.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 1 atoms Centered at (-2.000e+00, 0.000e+00, 0.000e+00) Net charge 1.00e+00 e Reading PQR-format atom data from complex-0_1.pqr. 2 atoms Centered at (-2.500e+00, 0.000e+00, 0.000e+00) Net charge 2.00e+00 e Preparing to run 3 PBE calculations. ---------------------------------------- CALCULATION #1 (point1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.059 MB total, 61.059 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.210 x 0.210 x 0.210 Grid lengths: 13.440 x 13.440 x 13.440 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 0 ion species (0.000 M ionic strength): Solute dielectric: 78.540 Solvent dielectric: 78.540 Using spline-based surface definition;window = 0.300 Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 9.776035707281E+01 kJ/mol Fixed charge energy = 97.7604 kJ/mol Mobile charge energy = 0 kJ/mol Dielectric energy = 96.5336 kJ/mol Per-atom energies: Atom 0: 9.776035707281E+01 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (point2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.059 MB total, 61.066 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.210 x 0.210 x 0.210 Grid lengths: 13.440 x 13.440 x 13.440 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 2 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 0 ion species (0.000 M ionic strength): Solute dielectric: 78.540 Solvent dielectric: 78.540 Using spline-based surface definition;window = 0.300 Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 8.975920687031E+01 kJ/mol Fixed charge energy = 89.7592 kJ/mol Mobile charge energy = 0 kJ/mol Dielectric energy = 88.6151 kJ/mol Per-atom energies: Atom 0: 8.975920687031E+01 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #3 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.059 MB total, 61.066 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.210 x 0.210 x 0.210 Grid lengths: 13.440 x 13.440 x 13.440 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 3 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 0 ion species (0.000 M ionic strength): Solute dielectric: 78.540 Solvent dielectric: 78.540 Using spline-based surface definition;window = 0.300 Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.058277719334E+02 kJ/mol Fixed charge energy = 205.828 kJ/mol Mobile charge energy = 0 kJ/mol Dielectric energy = 201.106 kJ/mol Per-atom energies: Atom 0: 1.069144350786E+02 kJ/mol Atom 1: 9.891333685475E+01 kJ/mol Calculating forces... ---------------------------------------- PRINT STATEMENTS print energy 3 (complex) - 1 (point1) - 2 (point2) end Local net energy (PE 0) = 1.830820799027E+01 kJ/mol Global net ELEC energy = 1.830820799027E+01 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 61.066 MB high water Thanks for using APBS! Checking for intermidiate energies in input file complex-0_1.out RESULT 97.76035707281 RESULT 89.75920687031 RESULT 205.8277719334 RESULT 0.0 RESULT 0.0 RESULT 0.0 RESULT 97.7604 RESULT 89.7592 RESULT 205.828 RESULT 96.5336 RESULT 88.6151 RESULT 201.106 RESULT 18.30820799027 Testing computed result 9.776035707281E+01 against expected result 9.776036E+01 *** PASSED *** Testing computed result 8.975920687031E+01 against expected result 8.975921E+01 *** PASSED *** Testing computed result 2.058277719334E+02 against expected result 2.058278E+02 *** PASSED *** Testing computed result 9.776040000000E+01 against expected result 9.776040E+01 *** PASSED *** Testing computed result 8.975920000000E+01 against expected result 8.975920E+01 *** PASSED *** Testing computed result 2.058280000000E+02 against expected result 2.058280E+02 *** PASSED *** Testing computed result 9.653360000000E+01 against expected result 9.653360E+01 *** PASSED *** Testing computed result 8.861510000000E+01 against expected result 8.861510E+01 *** PASSED *** Testing computed result 2.011060000000E+02 against expected result 2.011060E+02 *** PASSED *** Testing computed result 1.830820799027E+01 against expected result 1.830821E+01 *** PASSED *** Elapsed time: 2.873420 seconds -------------------------------------------------------------------------------- -------------------------------------------------------------------------------- Testing input file complex-0_2.in BINARY: apbs INPUT: complex-0_2.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file complex-0_2.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from mol0.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 1 atoms Centered at (-3.000e+00, 0.000e+00, 0.000e+00) Net charge 1.00e+00 e Reading PQR-format atom data from mol2.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 1 atoms Centered at (-1.000e+00, 0.000e+00, 0.000e+00) Net charge 1.00e+00 e Reading PQR-format atom data from complex-0_2.pqr. 2 atoms Centered at (-2.000e+00, 0.000e+00, 0.000e+00) Net charge 2.00e+00 e Preparing to run 3 PBE calculations. ---------------------------------------- CALCULATION #1 (point1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.059 MB total, 61.059 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.210 x 0.210 x 0.210 Grid lengths: 13.440 x 13.440 x 13.440 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 0 ion species (0.000 M ionic strength): Solute dielectric: 78.540 Solvent dielectric: 78.540 Using spline-based surface definition;window = 0.300 Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 9.776035707281E+01 kJ/mol Fixed charge energy = 97.7604 kJ/mol Mobile charge energy = 0 kJ/mol Dielectric energy = 96.5336 kJ/mol Per-atom energies: Atom 0: 9.776035707281E+01 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (point2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.059 MB total, 61.066 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.210 x 0.210 x 0.210 Grid lengths: 13.440 x 13.440 x 13.440 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 2 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 0 ion species (0.000 M ionic strength): Solute dielectric: 78.540 Solvent dielectric: 78.540 Using spline-based surface definition;window = 0.300 Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.017611498797E+02 kJ/mol Fixed charge energy = 101.761 kJ/mol Mobile charge energy = 0 kJ/mol Dielectric energy = 100.656 kJ/mol Per-atom energies: Atom 0: 1.017611498797E+02 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #3 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.059 MB total, 61.066 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.210 x 0.210 x 0.210 Grid lengths: 13.440 x 13.440 x 13.440 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 3 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 0 ion species (0.000 M ionic strength): Solute dielectric: 78.540 Solvent dielectric: 78.540 Using spline-based surface definition;window = 0.300 Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.084282010393E+02 kJ/mol Fixed charge energy = 208.428 kJ/mol Mobile charge energy = 0 kJ/mol Dielectric energy = 203.83 kJ/mol Per-atom energies: Atom 0: 1.022136878480E+02 kJ/mol Atom 1: 1.062145131913E+02 kJ/mol Calculating forces... ---------------------------------------- PRINT STATEMENTS print energy 3 (complex) - 1 (point1) - 2 (point2) end Local net energy (PE 0) = 8.906694086750E+00 kJ/mol Global net ELEC energy = 8.906694086750E+00 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 61.066 MB high water Thanks for using APBS! Checking for intermidiate energies in input file complex-0_2.out RESULT 97.76035707281 RESULT 101.7611498797 RESULT 208.4282010393 RESULT 0.0 RESULT 0.0 RESULT 0.0 RESULT 97.7604 RESULT 101.761 RESULT 208.428 RESULT 96.5336 RESULT 100.656 RESULT 203.83 RESULT 8.90669408675 Testing computed result 9.776035707281E+01 against expected result 9.776036E+01 *** PASSED *** Testing computed result 1.017611498797E+02 against expected result 1.017611E+02 *** PASSED *** Testing computed result 2.084282010393E+02 against expected result 2.084282E+02 *** PASSED *** Testing computed result 9.776040000000E+01 against expected result 9.776040E+01 *** PASSED *** Testing computed result 1.017610000000E+02 against expected result 1.017610E+02 *** PASSED *** Testing computed result 2.084280000000E+02 against expected result 2.084280E+02 *** PASSED *** Testing computed result 9.653360000000E+01 against expected result 9.653360E+01 *** PASSED *** Testing computed result 1.006560000000E+02 against expected result 1.006560E+02 *** PASSED *** Testing computed result 2.038300000000E+02 against expected result 2.038300E+02 *** PASSED *** Testing computed result 8.906694086750E+00 against expected result 8.906694E+00 *** PASSED *** Elapsed time: 2.846432 seconds -------------------------------------------------------------------------------- -------------------------------------------------------------------------------- Testing input file complex-0_3.in BINARY: apbs INPUT: complex-0_3.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file complex-0_3.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from mol0.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 1 atoms Centered at (-3.000e+00, 0.000e+00, 0.000e+00) Net charge 1.00e+00 e Reading PQR-format atom data from mol3.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 1 atoms Centered at (0.000e+00, 0.000e+00, 0.000e+00) Net charge 1.00e+00 e Reading PQR-format atom data from complex-0_3.pqr. 2 atoms Centered at (-1.500e+00, 0.000e+00, 0.000e+00) Net charge 2.00e+00 e Preparing to run 3 PBE calculations. ---------------------------------------- CALCULATION #1 (point1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.059 MB total, 61.059 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.210 x 0.210 x 0.210 Grid lengths: 13.440 x 13.440 x 13.440 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 0 ion species (0.000 M ionic strength): Solute dielectric: 78.540 Solvent dielectric: 78.540 Using spline-based surface definition;window = 0.300 Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 9.776035707281E+01 kJ/mol Fixed charge energy = 97.7604 kJ/mol Mobile charge energy = 0 kJ/mol Dielectric energy = 96.5336 kJ/mol Per-atom energies: Atom 0: 9.776035707281E+01 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (point2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.059 MB total, 61.066 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.210 x 0.210 x 0.210 Grid lengths: 13.440 x 13.440 x 13.440 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 2 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 0 ion species (0.000 M ionic strength): Solute dielectric: 78.540 Solvent dielectric: 78.540 Using spline-based surface definition;window = 0.300 Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.337661883222E+02 kJ/mol Fixed charge energy = 133.766 kJ/mol Mobile charge energy = 0 kJ/mol Dielectric energy = 132.672 kJ/mol Per-atom energies: Atom 0: 1.337661883222E+02 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #3 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.059 MB total, 61.066 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.210 x 0.210 x 0.210 Grid lengths: 13.440 x 13.440 x 13.440 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 3 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 0 ion species (0.000 M ionic strength): Solute dielectric: 78.540 Solvent dielectric: 78.540 Using spline-based surface definition;window = 0.300 Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.374361452120E+02 kJ/mol Fixed charge energy = 237.436 kJ/mol Mobile charge energy = 0 kJ/mol Dielectric energy = 232.924 kJ/mol Per-atom energies: Atom 0: 1.007151570480E+02 kJ/mol Atom 1: 1.367209881640E+02 kJ/mol Calculating forces... ---------------------------------------- PRINT STATEMENTS print energy 3 (complex) - 1 (point1) - 2 (point2) end Local net energy (PE 0) = 5.909599816984E+00 kJ/mol Global net ELEC energy = 5.909599816984E+00 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 61.066 MB high water Thanks for using APBS! Checking for intermidiate energies in input file complex-0_3.out RESULT 97.76035707281 RESULT 133.7661883222 RESULT 237.436145212 RESULT 0.0 RESULT 0.0 RESULT 0.0 RESULT 97.7604 RESULT 133.766 RESULT 237.436 RESULT 96.5336 RESULT 132.672 RESULT 232.924 RESULT 5.909599816984 Testing computed result 9.776035707281E+01 against expected result 9.776036E+01 *** PASSED *** Testing computed result 1.337661883222E+02 against expected result 1.337662E+02 *** PASSED *** Testing computed result 2.374361452120E+02 against expected result 2.374361E+02 *** PASSED *** Testing computed result 9.776040000000E+01 against expected result 9.776040E+01 *** PASSED *** Testing computed result 1.337660000000E+02 against expected result 1.337660E+02 *** PASSED *** Testing computed result 2.374360000000E+02 against expected result 2.374360E+02 *** PASSED *** Testing computed result 9.653360000000E+01 against expected result 9.653360E+01 *** PASSED *** Testing computed result 1.326720000000E+02 against expected result 1.326720E+02 *** PASSED *** Testing computed result 2.329240000000E+02 against expected result 2.329240E+02 *** PASSED *** Testing computed result 5.909599816984E+00 against expected result 5.909600E+00 *** PASSED *** Elapsed time: 2.860451 seconds -------------------------------------------------------------------------------- -------------------------------------------------------------------------------- Testing input file complex-0_4.in BINARY: apbs INPUT: complex-0_4.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file complex-0_4.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from mol0.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 1 atoms Centered at (-3.000e+00, 0.000e+00, 0.000e+00) Net charge 1.00e+00 e Reading PQR-format atom data from mol4.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 1 atoms Centered at (1.000e+00, 0.000e+00, 0.000e+00) Net charge 1.00e+00 e Reading PQR-format atom data from complex-0_4.pqr. 2 atoms Centered at (-1.000e+00, 0.000e+00, 0.000e+00) Net charge 2.00e+00 e Preparing to run 3 PBE calculations. ---------------------------------------- CALCULATION #1 (point1): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.059 MB total, 61.059 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.210 x 0.210 x 0.210 Grid lengths: 13.440 x 13.440 x 13.440 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 0 ion species (0.000 M ionic strength): Solute dielectric: 78.540 Solvent dielectric: 78.540 Using spline-based surface definition;window = 0.300 Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 9.776035707281E+01 kJ/mol Fixed charge energy = 97.7604 kJ/mol Mobile charge energy = 0 kJ/mol Dielectric energy = 96.5336 kJ/mol Per-atom energies: Atom 0: 9.776035707281E+01 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (point2): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.059 MB total, 61.066 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.210 x 0.210 x 0.210 Grid lengths: 13.440 x 13.440 x 13.440 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 2 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 0 ion species (0.000 M ionic strength): Solute dielectric: 78.540 Solvent dielectric: 78.540 Using spline-based surface definition;window = 0.300 Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 1.017611498797E+02 kJ/mol Fixed charge energy = 101.761 kJ/mol Mobile charge energy = 0 kJ/mol Dielectric energy = 100.654 kJ/mol Per-atom energies: Atom 0: 1.017611498797E+02 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #3 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (0 A) for exclusion function Debye length: 0 A Current memory usage: 61.059 MB total, 61.066 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.210 x 0.210 x 0.210 Grid lengths: 13.440 x 13.440 x 13.440 Grid center: (0.000, 0.000, 0.000) Multigrid levels: 5 Molecule ID: 3 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 0 ion species (0.000 M ionic strength): Solute dielectric: 78.540 Solvent dielectric: 78.540 Using spline-based surface definition;window = 0.300 Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.039516519000E+02 kJ/mol Fixed charge energy = 203.952 kJ/mol Mobile charge energy = 0 kJ/mol Dielectric energy = 199.493 kJ/mol Per-atom energies: Atom 0: 9.997541697022E+01 kJ/mol Atom 1: 1.039762349297E+02 kJ/mol Calculating forces... ---------------------------------------- PRINT STATEMENTS print energy 3 (complex) - 1 (point1) - 2 (point2) end Local net energy (PE 0) = 4.430144947418E+00 kJ/mol Global net ELEC energy = 4.430144947418E+00 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 61.066 MB high water Thanks for using APBS! Checking for intermidiate energies in input file complex-0_4.out RESULT 97.76035707281 RESULT 101.7611498797 RESULT 203.9516519 RESULT 0.0 RESULT 0.0 RESULT 0.0 RESULT 97.7604 RESULT 101.761 RESULT 203.952 RESULT 96.5336 RESULT 100.654 RESULT 199.493 RESULT 4.430144947418 Testing computed result 9.776035707281E+01 against expected result 9.776036E+01 *** PASSED *** Testing computed result 1.017611498797E+02 against expected result 1.017611E+02 *** PASSED *** Testing computed result 2.039516519000E+02 against expected result 2.039517E+02 *** PASSED *** Testing computed result 9.776040000000E+01 against expected result 9.776040E+01 *** PASSED *** Testing computed result 1.017610000000E+02 against expected result 1.017610E+02 *** PASSED *** Testing computed result 2.039520000000E+02 against expected result 2.039520E+02 *** PASSED *** Testing computed result 9.653360000000E+01 against expected result 9.653360E+01 *** PASSED *** Testing computed result 1.006540000000E+02 against expected result 1.006540E+02 *** PASSED *** Testing computed result 1.994930000000E+02 against expected result 1.994930E+02 *** PASSED *** Testing computed result 4.430144947418E+00 against expected result 4.430145E+00 *** PASSED *** Elapsed time: 2.869993 seconds -------------------------------------------------------------------------------- Total elapsed time: 11.450296 seconds Test results have been logged -------------------------------------------------------------------------------- Running tests for solv section -------------------------------------------------------------------------------- Testing input file apbs-mol.in BINARY: apbs INPUT: apbs-mol.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-mol.in... rank 0 size 1... Parsed input file. Got paths for 2 molecules Reading PQR-format atom data from methanol.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 3 atoms Centered at (3.086e-01, 0.000e+00, -2.417e-01) Net charge 5.55e-17 e Reading PQR-format atom data from methoxide.pqr. 2 atoms Centered at (0.000e+00, 0.000e+00, -1.279e-01) Net charge -1.00e+00 e Preparing to run 4 PBE calculations. ---------------------------------------- CALCULATION #1 (methanol-solv): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 61.247 MB total, 61.247 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.250 x 0.250 x 0.250 Grid lengths: 16.000 x 16.000 x 16.000 Grid center: (0.309, 0.000, -0.242) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 1.847663548071E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (methanol-ref): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 61.247 MB total, 61.316 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.250 x 0.250 x 0.250 Grid lengths: 16.000 x 16.000 x 16.000 Grid center: (0.309, 0.000, -0.242) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 1.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 1.883912182952E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #3 (methoxide-solv): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 61.243 MB total, 61.316 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.250 x 0.250 x 0.250 Grid lengths: 16.000 x 16.000 x 16.000 Grid center: (0.000, 0.000, -0.128) Multigrid levels: 5 Molecule ID: 2 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 2.732623683321E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #4 (methoxide-ref): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 61.243 MB total, 61.316 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.250 x 0.250 x 0.250 Grid lengths: 16.000 x 16.000 x 16.000 Grid center: (0.000, 0.000, -0.128) Multigrid levels: 5 Molecule ID: 2 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 1.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 3.123035854133E+03 kJ/mol Calculating forces... ---------------------------------------- PRINT STATEMENTS print energy 1 (methanol-solv) - 2 (methanol-ref) end Local net energy (PE 0) = -3.624863488074E+01 kJ/mol Global net ELEC energy = -3.624863488074E+01 kJ/mol print energy 3 (methoxide-solv) - 4 (methoxide-ref) end Local net energy (PE 0) = -3.904121708125E+02 kJ/mol Global net ELEC energy = -3.904121708125E+02 kJ/mol print energy 3 (methoxide-solv) - 4 (methoxide-ref) - 1 (methanol-solv) + 2 (methanol-ref) end Local net energy (PE 0) = -3.541635359318E+02 kJ/mol Global net ELEC energy = -3.541635359318E+02 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 2 molecules Final memory usage: 0.001 MB total, 61.316 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-mol.out RESULT 1847.663548071 RESULT 1883.912182952 RESULT 2732.623683321 RESULT 3123.035854133 RESULT -36.24863488074 RESULT -390.4121708125 RESULT -354.1635359318 Testing computed result 1.847663548071E+03 against expected result 1.847664E+03 *** PASSED *** Testing computed result 1.883912182952E+03 against expected result 1.883912E+03 *** PASSED *** Testing computed result 2.732623683321E+03 against expected result 2.732624E+03 *** PASSED *** Testing computed result 3.123035854133E+03 against expected result 3.123036E+03 *** PASSED *** Testing computed result -3.624863488074E+01 against expected result -3.624863E+01 *** PASSED *** Testing computed result -3.904121708125E+02 against expected result -3.904121E+02 *** PASSED *** Testing computed result -3.541635359318E+02 against expected result -3.541635E+02 *** PASSED *** Elapsed time: 5.100401 seconds -------------------------------------------------------------------------------- -------------------------------------------------------------------------------- Testing input file apbs-smol.in BINARY: apbs INPUT: apbs-smol.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-smol.in... rank 0 size 1... Parsed input file. Got paths for 2 molecules Reading PQR-format atom data from methanol.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 3 atoms Centered at (3.086e-01, 0.000e+00, -2.417e-01) Net charge 5.55e-17 e Reading PQR-format atom data from methoxide.pqr. 2 atoms Centered at (0.000e+00, 0.000e+00, -1.279e-01) Net charge -1.00e+00 e Preparing to run 4 PBE calculations. ---------------------------------------- CALCULATION #1 (methanol-solv): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 61.247 MB total, 61.247 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.250 x 0.250 x 0.250 Grid lengths: 16.000 x 16.000 x 16.000 Grid center: (0.309, 0.000, -0.242) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 1.847860440020E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (methanol-ref): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 61.247 MB total, 61.316 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.250 x 0.250 x 0.250 Grid lengths: 16.000 x 16.000 x 16.000 Grid center: (0.309, 0.000, -0.242) Multigrid levels: 5 Molecule ID: 1 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 1.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 1.885436377745E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #3 (methoxide-solv): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 61.243 MB total, 61.316 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.250 x 0.250 x 0.250 Grid lengths: 16.000 x 16.000 x 16.000 Grid center: (0.000, 0.000, -0.128) Multigrid levels: 5 Molecule ID: 2 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 78.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 2.734040568569E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #4 (methoxide-ref): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 0 A Current memory usage: 61.243 MB total, 61.316 MB high water Using linear spline charge discretization. Grid dimensions: 65 x 65 x 65 Grid spacings: 0.250 x 0.250 x 0.250 Grid lengths: 16.000 x 16.000 x 16.000 Grid center: (0.000, 0.000, -0.128) Multigrid levels: 5 Molecule ID: 2 Linearized traditional PBE Multiple Debye-Huckel sphere boundary conditions 2 ion species (0.000 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.000 M concentration 2.000 A-radius, -1.000 e-charge, 0.000 M concentration Solute dielectric: 2.000 Solvent dielectric: 1.000 Using "molecular" surface definition;harmonic average smoothing Solvent probe radius: 0.000 A Temperature: 300.000 K Electrostatic energies will be calculated Total electrostatic energy = 3.125279428954E+03 kJ/mol Calculating forces... ---------------------------------------- PRINT STATEMENTS print energy 1 (methanol-solv) - 2 (methanol-ref) end Local net energy (PE 0) = -3.757593772493E+01 kJ/mol Global net ELEC energy = -3.757593772493E+01 kJ/mol print energy 3 (methoxide-solv) - 4 (methoxide-ref) end Local net energy (PE 0) = -3.912388603848E+02 kJ/mol Global net ELEC energy = -3.912388603848E+02 kJ/mol print energy 3 (methoxide-solv) - 4 (methoxide-ref) - 1 (methanol-solv) + 2 (methanol-ref) end Local net energy (PE 0) = -3.536629226599E+02 kJ/mol Global net ELEC energy = -3.536629226599E+02 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 2 molecules Final memory usage: 0.001 MB total, 61.316 MB high water Thanks for using APBS! Creating file now: apbs-0.025.in Creating file now: apbs-0.050.in Creating file now: apbs-0.075.in Creating file now: apbs-0.100.in Creating file now: apbs-0.125.in Creating file now: apbs-0.150.in Creating file now: apbs-0.175.in Creating file now: apbs-0.200.in Creating file now: apbs-0.225.in Creating file now: apbs-0.250.in Creating file now: apbs-0.275.in Creating file now: apbs-0.300.in Creating file now: apbs-0.325.in Creating file now: apbs-0.400.in Creating file now: apbs-0.500.in Creating file now: apbs-0.600.in Creating file now: apbs-0.700.in Creating file now: apbs-0.800.in Creating file_2 now: dxmath-0.025.in Creating file_2 now: dxmath-0.050.in Creating file_2 now: dxmath-0.075.in Creating file_2 now: dxmath-0.100.in Creating file_2 now: dxmath-0.125.in Creating file_2 now: dxmath-0.150.in Creating file_2 now: dxmath-0.175.in Creating file_2 now: dxmath-0.200.in Creating file_2 now: dxmath-0.225.in Creating file_2 now: dxmath-0.250.in Creating file_2 now: dxmath-0.275.in Creating file_2 now: dxmath-0.300.in Creating file_2 now: dxmath-0.325.in Creating file_2 now: dxmath-0.400.in Creating file_2 now: dxmath-0.500.in Creating file_2 now: dxmath-0.600.in Creating file_2 now: dxmath-0.700.in Creating file_2 now: dxmath-0.800.in Checking for intermidiate energies in input file apbs-smol.out RESULT 1847.86044002 RESULT 1885.436377745 RESULT 2734.040568569 RESULT 3125.279428954 RESULT -37.57593772493 RESULT -391.2388603848 RESULT -353.6629226599 Testing computed result 1.847860440020E+03 against expected result 1.847860E+03 *** PASSED *** Testing computed result 1.885436377745E+03 against expected result 1.885436E+03 *** PASSED *** Testing computed result 2.734040568569E+03 against expected result 2.734041E+03 *** PASSED *** Testing computed result 3.125279428954E+03 against expected result 3.125279E+03 *** PASSED *** Testing computed result -3.757593772493E+01 against expected result -3.757594E+01 *** PASSED *** Testing computed result -3.912388603848E+02 against expected result -3.912388E+02 *** PASSED *** Testing computed result -3.536629226599E+02 against expected result -3.536629E+02 *** PASSED *** Elapsed time: 4.378477 seconds -------------------------------------------------------------------------------- Total elapsed time: 9.478878 seconds Test results have been logged -------------------------------------------------------------------------------- Running tests for protein-rna section -------------------------------------------------------------------------------- Testing input file apbs-0.025.in BINARY: apbs INPUT: apbs-0.025.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-0.025.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from model_outNB.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 998 atoms Centered at (1.382e+01, 5.283e+00, 8.258e+00) Net charge -1.40e+01 e Reading PQR-format atom data from model_outNpep.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 379 atoms Centered at (1.753e+01, -1.723e+00, 1.470e+01) Net charge 4.00e+00 e Reading PQR-format atom data from model_outBoxB19.pqr. 619 atoms Centered at (1.306e+01, 7.586e+00, 4.177e+00) Net charge -1.80e+01 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 19.4227 A Current memory usage: 204.865 MB total, 204.865 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.025 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.025 M concentration 2.000 A-radius, -1.000 e-charge, 0.025 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 3.186122223752E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 19.4227 A Current memory usage: 204.865 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.025 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.025 M concentration 2.000 A-radius, -1.000 e-charge, 0.025 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-complex-0.025.dx Ion number density to be written to ndens-complex-0.025.dx Total electrostatic energy = 3.662855899462E+04 kJ/mol Calculating forces... Writing charge density to qdens-complex-0.025-PE0.dx Writing number density to ndens-complex-0.025-PE0.dx ---------------------------------------- CALCULATION #3 (peptide): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 19.4227 A Current memory usage: 196.345 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.025 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.025 M concentration 2.000 A-radius, -1.000 e-charge, 0.025 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 8.477786964834E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #4 (peptide): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 19.4227 A Current memory usage: 196.345 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.025 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.025 M concentration 2.000 A-radius, -1.000 e-charge, 0.025 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-pep-0.025.dx Ion number density to be written to ndens-pep-0.025.dx Total electrostatic energy = 1.000545153104E+04 kJ/mol Calculating forces... Writing charge density to qdens-pep-0.025-PE0.dx Writing number density to ndens-pep-0.025-PE0.dx ---------------------------------------- CALCULATION #5 (rna): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 19.4227 A Current memory usage: 200.941 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.025 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.025 M concentration 2.000 A-radius, -1.000 e-charge, 0.025 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.329205982055E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #6 (rna): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 19.4227 A Current memory usage: 200.941 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.025 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.025 M concentration 2.000 A-radius, -1.000 e-charge, 0.025 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-rna-0.025.dx Ion number density to be written to ndens-rna-0.025.dx Total electrostatic energy = 2.653636629928E+04 kJ/mol Calculating forces... Writing charge density to qdens-rna-0.025-PE0.dx Writing number density to ndens-rna-0.025-PE0.dx ---------------------------------------- PRINT STATEMENTS print energy 1 (complex) - 2 (peptide) - 3 (rna) end Local net energy (PE 0) = 8.674116429352E+01 kJ/mol Global net ELEC energy = 8.674116429352E+01 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 406.244 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-0.out RESULT 31861.22223752 RESULT 36628.55899462 RESULT 8477.786964834 RESULT 10005.45153104 RESULT 23292.05982055 RESULT 26536.36629928 RESULT 86.74116429352 Testing computed result 3.186122223752E+04 against expected result 3.186122E+04 *** PASSED *** Testing computed result 3.662855899462E+04 against expected result 3.662856E+04 *** PASSED *** Testing computed result 8.477786964834E+03 against expected result 8.477787E+03 *** PASSED *** Testing computed result 1.000545153104E+04 against expected result 1.000545E+04 *** PASSED *** Testing computed result 2.329205982055E+04 against expected result 2.329206E+04 *** PASSED *** Testing computed result 2.653636629928E+04 against expected result 2.653637E+04 *** PASSED *** Testing computed result 8.674116429352E+01 against expected result 8.674116E+01 *** PASSED *** Elapsed time: 54.540751 seconds -------------------------------------------------------------------------------- -------------------------------------------------------------------------------- Testing input file apbs-0.050.in BINARY: apbs INPUT: apbs-0.050.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-0.050.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from model_outNB.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 998 atoms Centered at (1.382e+01, 5.283e+00, 8.258e+00) Net charge -1.40e+01 e Reading PQR-format atom data from model_outNpep.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 379 atoms Centered at (1.753e+01, -1.723e+00, 1.470e+01) Net charge 4.00e+00 e Reading PQR-format atom data from model_outBoxB19.pqr. 619 atoms Centered at (1.306e+01, 7.586e+00, 4.177e+00) Net charge -1.80e+01 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.7339 A Current memory usage: 204.865 MB total, 204.865 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 3.184763478312E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.7339 A Current memory usage: 204.865 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-complex-0.050.dx Ion number density to be written to ndens-complex-0.050.dx Total electrostatic energy = 3.661493366846E+04 kJ/mol Calculating forces... Writing charge density to qdens-complex-0.050-PE0.dx Writing number density to ndens-complex-0.050-PE0.dx ---------------------------------------- CALCULATION #3 (peptide): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.7339 A Current memory usage: 196.345 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 8.475252516617E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #4 (peptide): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.7339 A Current memory usage: 196.345 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-pep-0.050.dx Ion number density to be written to ndens-pep-0.050.dx Total electrostatic energy = 1.000292179294E+04 kJ/mol Calculating forces... Writing charge density to qdens-pep-0.050-PE0.dx Writing number density to ndens-pep-0.050-PE0.dx ---------------------------------------- CALCULATION #5 (rna): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.7339 A Current memory usage: 200.941 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.327168361816E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #6 (rna): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 13.7339 A Current memory usage: 200.941 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.050 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.050 M concentration 2.000 A-radius, -1.000 e-charge, 0.050 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-rna-0.050.dx Ion number density to be written to ndens-rna-0.050.dx Total electrostatic energy = 2.651594350839E+04 kJ/mol Calculating forces... Writing charge density to qdens-rna-0.050-PE0.dx Writing number density to ndens-rna-0.050-PE0.dx ---------------------------------------- PRINT STATEMENTS print energy 1 (complex) - 2 (peptide) - 3 (rna) end Local net energy (PE 0) = 9.606836713865E+01 kJ/mol Global net ELEC energy = 9.606836713865E+01 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 406.244 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-0.out RESULT 31847.63478312 RESULT 36614.93366846 RESULT 8475.252516617 RESULT 10002.92179294 RESULT 23271.68361816 RESULT 26515.94350839 RESULT 96.06836713865 Testing computed result 3.184763478312E+04 against expected result 3.184763E+04 *** PASSED *** Testing computed result 3.661493366846E+04 against expected result 3.661493E+04 *** PASSED *** Testing computed result 8.475252516617E+03 against expected result 8.475253E+03 *** PASSED *** Testing computed result 1.000292179294E+04 against expected result 1.000292E+04 *** PASSED *** Testing computed result 2.327168361816E+04 against expected result 2.327168E+04 *** PASSED *** Testing computed result 2.651594350839E+04 against expected result 2.651594E+04 *** PASSED *** Testing computed result 9.606836713865E+01 against expected result 9.606837E+01 *** PASSED *** Elapsed time: 54.496780 seconds -------------------------------------------------------------------------------- -------------------------------------------------------------------------------- Testing input file apbs-0.075.in BINARY: apbs INPUT: apbs-0.075.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-0.075.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from model_outNB.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 998 atoms Centered at (1.382e+01, 5.283e+00, 8.258e+00) Net charge -1.40e+01 e Reading PQR-format atom data from model_outNpep.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 379 atoms Centered at (1.753e+01, -1.723e+00, 1.470e+01) Net charge 4.00e+00 e Reading PQR-format atom data from model_outBoxB19.pqr. 619 atoms Centered at (1.306e+01, 7.586e+00, 4.177e+00) Net charge -1.80e+01 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 11.2137 A Current memory usage: 204.865 MB total, 204.865 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.075 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.075 M concentration 2.000 A-radius, -1.000 e-charge, 0.075 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 3.184033569905E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 11.2137 A Current memory usage: 204.865 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.075 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.075 M concentration 2.000 A-radius, -1.000 e-charge, 0.075 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-complex-0.075.dx Ion number density to be written to ndens-complex-0.075.dx Total electrostatic energy = 3.660761530545E+04 kJ/mol Calculating forces... Writing charge density to qdens-complex-0.075-PE0.dx Writing number density to ndens-complex-0.075-PE0.dx ---------------------------------------- CALCULATION #3 (peptide): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 11.2137 A Current memory usage: 196.345 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.075 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.075 M concentration 2.000 A-radius, -1.000 e-charge, 0.075 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 8.473669396547E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #4 (peptide): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 11.2137 A Current memory usage: 196.345 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.075 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.075 M concentration 2.000 A-radius, -1.000 e-charge, 0.075 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-pep-0.075.dx Ion number density to be written to ndens-pep-0.075.dx Total electrostatic energy = 1.000134276339E+04 kJ/mol Calculating forces... Writing charge density to qdens-pep-0.075-PE0.dx Writing number density to ndens-pep-0.075-PE0.dx ---------------------------------------- CALCULATION #5 (rna): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 11.2137 A Current memory usage: 200.941 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.075 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.075 M concentration 2.000 A-radius, -1.000 e-charge, 0.075 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.326088212207E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #6 (rna): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 11.2137 A Current memory usage: 200.941 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.075 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.075 M concentration 2.000 A-radius, -1.000 e-charge, 0.075 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-rna-0.075.dx Ion number density to be written to ndens-rna-0.075.dx Total electrostatic energy = 2.650511882057E+04 kJ/mol Calculating forces... Writing charge density to qdens-rna-0.075-PE0.dx Writing number density to ndens-rna-0.075-PE0.dx ---------------------------------------- PRINT STATEMENTS print energy 1 (complex) - 2 (peptide) - 3 (rna) end Local net energy (PE 0) = 1.011537214883E+02 kJ/mol Global net ELEC energy = 1.011537214883E+02 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 406.244 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-0.out RESULT 31840.33569905 RESULT 36607.61530545 RESULT 8473.669396547 RESULT 10001.34276339 RESULT 23260.88212207 RESULT 26505.11882057 RESULT 101.1537214883 Testing computed result 3.184033569905E+04 against expected result 3.184034E+04 *** PASSED *** Testing computed result 3.660761530545E+04 against expected result 3.660762E+04 *** PASSED *** Testing computed result 8.473669396547E+03 against expected result 8.473669E+03 *** PASSED *** Testing computed result 1.000134276339E+04 against expected result 1.000134E+04 *** PASSED *** Testing computed result 2.326088212207E+04 against expected result 2.326088E+04 *** PASSED *** Testing computed result 2.650511882057E+04 against expected result 2.650512E+04 *** PASSED *** Testing computed result 1.011537214883E+02 against expected result 1.011537E+02 *** PASSED *** Elapsed time: 54.784074 seconds -------------------------------------------------------------------------------- -------------------------------------------------------------------------------- Testing input file apbs-0.100.in BINARY: apbs INPUT: apbs-0.100.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-0.100.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from model_outNB.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 998 atoms Centered at (1.382e+01, 5.283e+00, 8.258e+00) Net charge -1.40e+01 e Reading PQR-format atom data from model_outNpep.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 379 atoms Centered at (1.753e+01, -1.723e+00, 1.470e+01) Net charge 4.00e+00 e Reading PQR-format atom data from model_outBoxB19.pqr. 619 atoms Centered at (1.306e+01, 7.586e+00, 4.177e+00) Net charge -1.80e+01 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 9.71135 A Current memory usage: 204.865 MB total, 204.865 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.100 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.100 M concentration 2.000 A-radius, -1.000 e-charge, 0.100 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 3.183548000794E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 9.71135 A Current memory usage: 204.865 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.100 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.100 M concentration 2.000 A-radius, -1.000 e-charge, 0.100 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-complex-0.100.dx Ion number density to be written to ndens-complex-0.100.dx Total electrostatic energy = 3.660274809589E+04 kJ/mol Calculating forces... Writing charge density to qdens-complex-0.100-PE0.dx Writing number density to ndens-complex-0.100-PE0.dx ---------------------------------------- CALCULATION #3 (peptide): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 9.71135 A Current memory usage: 196.345 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.100 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.100 M concentration 2.000 A-radius, -1.000 e-charge, 0.100 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 8.472507235893E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #4 (peptide): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 9.71135 A Current memory usage: 196.345 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.100 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.100 M concentration 2.000 A-radius, -1.000 e-charge, 0.100 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-pep-0.100.dx Ion number density to be written to ndens-pep-0.100.dx Total electrostatic energy = 1.000018407412E+04 kJ/mol Calculating forces... Writing charge density to qdens-pep-0.100-PE0.dx Writing number density to ndens-pep-0.100-PE0.dx ---------------------------------------- CALCULATION #5 (rna): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 9.71135 A Current memory usage: 200.941 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.100 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.100 M concentration 2.000 A-radius, -1.000 e-charge, 0.100 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.325372656922E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #6 (rna): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 9.71135 A Current memory usage: 200.941 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.100 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.100 M concentration 2.000 A-radius, -1.000 e-charge, 0.100 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-rna-0.100.dx Ion number density to be written to ndens-rna-0.100.dx Total electrostatic energy = 2.649794981016E+04 kJ/mol Calculating forces... Writing charge density to qdens-rna-0.100-PE0.dx Writing number density to ndens-rna-0.100-PE0.dx ---------------------------------------- PRINT STATEMENTS print energy 1 (complex) - 2 (peptide) - 3 (rna) end Local net energy (PE 0) = 1.046142116108E+02 kJ/mol Global net ELEC energy = 1.046142116108E+02 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 406.244 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-0.out RESULT 31835.48000794 RESULT 36602.74809589 RESULT 8472.507235893 RESULT 10000.18407412 RESULT 23253.72656922 RESULT 26497.94981016 RESULT 104.6142116108 Testing computed result 3.183548000794E+04 against expected result 3.183548E+04 *** PASSED *** Testing computed result 3.660274809589E+04 against expected result 3.660275E+04 *** PASSED *** Testing computed result 8.472507235893E+03 against expected result 8.472507E+03 *** PASSED *** Testing computed result 1.000018407412E+04 against expected result 1.000018E+04 *** PASSED *** Testing computed result 2.325372656922E+04 against expected result 2.325373E+04 *** PASSED *** Testing computed result 2.649794981016E+04 against expected result 2.649795E+04 *** PASSED *** Testing computed result 1.046142116108E+02 against expected result 1.046142E+02 *** PASSED *** Elapsed time: 54.754565 seconds -------------------------------------------------------------------------------- -------------------------------------------------------------------------------- Testing input file apbs-0.125.in BINARY: apbs INPUT: apbs-0.125.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-0.125.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from model_outNB.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 998 atoms Centered at (1.382e+01, 5.283e+00, 8.258e+00) Net charge -1.40e+01 e Reading PQR-format atom data from model_outNpep.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 379 atoms Centered at (1.753e+01, -1.723e+00, 1.470e+01) Net charge 4.00e+00 e Reading PQR-format atom data from model_outBoxB19.pqr. 619 atoms Centered at (1.306e+01, 7.586e+00, 4.177e+00) Net charge -1.80e+01 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 8.6861 A Current memory usage: 204.865 MB total, 204.865 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.125 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.125 M concentration 2.000 A-radius, -1.000 e-charge, 0.125 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 3.183190100647E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 8.6861 A Current memory usage: 204.865 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.125 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.125 M concentration 2.000 A-radius, -1.000 e-charge, 0.125 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-complex-0.125.dx Ion number density to be written to ndens-complex-0.125.dx Total electrostatic energy = 3.659916161996E+04 kJ/mol Calculating forces... Writing charge density to qdens-complex-0.125-PE0.dx Writing number density to ndens-complex-0.125-PE0.dx ---------------------------------------- CALCULATION #3 (peptide): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 8.6861 A Current memory usage: 196.345 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.125 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.125 M concentration 2.000 A-radius, -1.000 e-charge, 0.125 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 8.471585837513E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #4 (peptide): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 8.6861 A Current memory usage: 196.345 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.125 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.125 M concentration 2.000 A-radius, -1.000 e-charge, 0.125 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-pep-0.125.dx Ion number density to be written to ndens-pep-0.125.dx Total electrostatic energy = 9.999265654586E+03 kJ/mol Calculating forces... Writing charge density to qdens-pep-0.125-PE0.dx Writing number density to ndens-pep-0.125-PE0.dx ---------------------------------------- CALCULATION #5 (rna): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 8.6861 A Current memory usage: 200.941 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.125 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.125 M concentration 2.000 A-radius, -1.000 e-charge, 0.125 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.324845847155E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #6 (rna): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 8.6861 A Current memory usage: 200.941 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.125 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.125 M concentration 2.000 A-radius, -1.000 e-charge, 0.125 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-rna-0.125.dx Ion number density to be written to ndens-rna-0.125.dx Total electrostatic energy = 2.649267328362E+04 kJ/mol Calculating forces... Writing charge density to qdens-rna-0.125-PE0.dx Writing number density to ndens-rna-0.125-PE0.dx ---------------------------------------- PRINT STATEMENTS print energy 1 (complex) - 2 (peptide) - 3 (rna) end Local net energy (PE 0) = 1.072226817611E+02 kJ/mol Global net ELEC energy = 1.072226817611E+02 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 406.244 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-0.out RESULT 31831.90100647 RESULT 36599.16161996 RESULT 8471.585837513 RESULT 9999.265654586 RESULT 23248.45847155 RESULT 26492.67328362 RESULT 107.2226817611 Testing computed result 3.183190100647E+04 against expected result 3.183190E+04 *** PASSED *** Testing computed result 3.659916161996E+04 against expected result 3.659916E+04 *** PASSED *** Testing computed result 8.471585837513E+03 against expected result 8.471586E+03 *** PASSED *** Testing computed result 9.999265654586E+03 against expected result 9.999266E+03 *** PASSED *** Testing computed result 2.324845847155E+04 against expected result 2.324846E+04 *** PASSED *** Testing computed result 2.649267328362E+04 against expected result 2.649267E+04 *** PASSED *** Testing computed result 1.072226817611E+02 against expected result 1.072227E+02 *** PASSED *** Elapsed time: 56.058373 seconds -------------------------------------------------------------------------------- -------------------------------------------------------------------------------- Testing input file apbs-0.150.in BINARY: apbs INPUT: apbs-0.150.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-0.150.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from model_outNB.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 998 atoms Centered at (1.382e+01, 5.283e+00, 8.258e+00) Net charge -1.40e+01 e Reading PQR-format atom data from model_outNpep.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 379 atoms Centered at (1.753e+01, -1.723e+00, 1.470e+01) Net charge 4.00e+00 e Reading PQR-format atom data from model_outBoxB19.pqr. 619 atoms Centered at (1.306e+01, 7.586e+00, 4.177e+00) Net charge -1.80e+01 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 7.92928 A Current memory usage: 204.865 MB total, 204.865 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.150 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.150 M concentration 2.000 A-radius, -1.000 e-charge, 0.150 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 3.182909678356E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 7.92928 A Current memory usage: 204.865 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.150 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.150 M concentration 2.000 A-radius, -1.000 e-charge, 0.150 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-complex-0.150.dx Ion number density to be written to ndens-complex-0.150.dx Total electrostatic energy = 3.659635228953E+04 kJ/mol Calculating forces... Writing charge density to qdens-complex-0.150-PE0.dx Writing number density to ndens-complex-0.150-PE0.dx ---------------------------------------- CALCULATION #3 (peptide): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 7.92928 A Current memory usage: 196.345 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.150 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.150 M concentration 2.000 A-radius, -1.000 e-charge, 0.150 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 8.470821300868E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #4 (peptide): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 7.92928 A Current memory usage: 196.345 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.150 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.150 M concentration 2.000 A-radius, -1.000 e-charge, 0.150 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-pep-0.150.dx Ion number density to be written to ndens-pep-0.150.dx Total electrostatic energy = 9.998503715551E+03 kJ/mol Calculating forces... Writing charge density to qdens-pep-0.150-PE0.dx Writing number density to ndens-pep-0.150-PE0.dx ---------------------------------------- CALCULATION #5 (rna): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 7.92928 A Current memory usage: 200.941 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.150 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.150 M concentration 2.000 A-radius, -1.000 e-charge, 0.150 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.324433086171E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #6 (rna): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 7.92928 A Current memory usage: 200.941 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.150 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.150 M concentration 2.000 A-radius, -1.000 e-charge, 0.150 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-rna-0.150.dx Ion number density to be written to ndens-rna-0.150.dx Total electrostatic energy = 2.648854016160E+04 kJ/mol Calculating forces... Writing charge density to qdens-rna-0.150-PE0.dx Writing number density to ndens-rna-0.150-PE0.dx ---------------------------------------- PRINT STATEMENTS print energy 1 (complex) - 2 (peptide) - 3 (rna) end Local net energy (PE 0) = 1.093084123761E+02 kJ/mol Global net ELEC energy = 1.093084123761E+02 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 406.244 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-0.out RESULT 31829.09678356 RESULT 36596.35228953 RESULT 8470.821300868 RESULT 9998.503715551 RESULT 23244.33086171 RESULT 26488.5401616 RESULT 109.3084123761 Testing computed result 3.182909678356E+04 against expected result 3.182910E+04 *** PASSED *** Testing computed result 3.659635228953E+04 against expected result 3.659635E+04 *** PASSED *** Testing computed result 8.470821300868E+03 against expected result 8.470821E+03 *** PASSED *** Testing computed result 9.998503715551E+03 against expected result 9.998504E+03 *** PASSED *** Testing computed result 2.324433086171E+04 against expected result 2.324433E+04 *** PASSED *** Testing computed result 2.648854016160E+04 against expected result 2.648854E+04 *** PASSED *** Testing computed result 1.093084123761E+02 against expected result 1.093084E+02 *** PASSED *** Elapsed time: 56.044251 seconds -------------------------------------------------------------------------------- -------------------------------------------------------------------------------- Testing input file apbs-0.175.in BINARY: apbs INPUT: apbs-0.175.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-0.175.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from model_outNB.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 998 atoms Centered at (1.382e+01, 5.283e+00, 8.258e+00) Net charge -1.40e+01 e Reading PQR-format atom data from model_outNpep.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 379 atoms Centered at (1.753e+01, -1.723e+00, 1.470e+01) Net charge 4.00e+00 e Reading PQR-format atom data from model_outBoxB19.pqr. 619 atoms Centered at (1.306e+01, 7.586e+00, 4.177e+00) Net charge -1.80e+01 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 7.34109 A Current memory usage: 204.865 MB total, 204.865 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.175 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.175 M concentration 2.000 A-radius, -1.000 e-charge, 0.175 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 3.182680817429E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 7.34109 A Current memory usage: 204.865 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.175 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.175 M concentration 2.000 A-radius, -1.000 e-charge, 0.175 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-complex-0.175.dx Ion number density to be written to ndens-complex-0.175.dx Total electrostatic energy = 3.659406006570E+04 kJ/mol Calculating forces... Writing charge density to qdens-complex-0.175-PE0.dx Writing number density to ndens-complex-0.175-PE0.dx ---------------------------------------- CALCULATION #3 (peptide): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 7.34109 A Current memory usage: 196.345 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.175 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.175 M concentration 2.000 A-radius, -1.000 e-charge, 0.175 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 8.470167484600E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #4 (peptide): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 7.34109 A Current memory usage: 196.345 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.175 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.175 M concentration 2.000 A-radius, -1.000 e-charge, 0.175 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-pep-0.175.dx Ion number density to be written to ndens-pep-0.175.dx Total electrostatic energy = 9.997852199372E+03 kJ/mol Calculating forces... Writing charge density to qdens-pep-0.175-PE0.dx Writing number density to ndens-pep-0.175-PE0.dx ---------------------------------------- CALCULATION #5 (rna): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 7.34109 A Current memory usage: 200.941 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.175 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.175 M concentration 2.000 A-radius, -1.000 e-charge, 0.175 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.324096101131E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #6 (rna): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 7.34109 A Current memory usage: 200.941 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.175 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.175 M concentration 2.000 A-radius, -1.000 e-charge, 0.175 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-rna-0.175.dx Ion number density to be written to ndens-rna-0.175.dx Total electrostatic energy = 2.648516662194E+04 kJ/mol Calculating forces... Writing charge density to qdens-rna-0.175-PE0.dx Writing number density to ndens-rna-0.175-PE0.dx ---------------------------------------- PRINT STATEMENTS print energy 1 (complex) - 2 (peptide) - 3 (rna) end Local net energy (PE 0) = 1.110412443877E+02 kJ/mol Global net ELEC energy = 1.110412443877E+02 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 406.244 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-0.out RESULT 31826.80817429 RESULT 36594.0600657 RESULT 8470.1674846 RESULT 9997.852199372 RESULT 23240.96101131 RESULT 26485.16662194 RESULT 111.0412443877 Testing computed result 3.182680817429E+04 against expected result 3.182681E+04 *** PASSED *** Testing computed result 3.659406006570E+04 against expected result 3.659406E+04 *** PASSED *** Testing computed result 8.470167484600E+03 against expected result 8.470167E+03 *** PASSED *** Testing computed result 9.997852199372E+03 against expected result 9.997852E+03 *** PASSED *** Testing computed result 2.324096101131E+04 against expected result 2.324096E+04 *** PASSED *** Testing computed result 2.648516662194E+04 against expected result 2.648517E+04 *** PASSED *** Testing computed result 1.110412443877E+02 against expected result 1.110412E+02 *** PASSED *** Elapsed time: 55.235691 seconds -------------------------------------------------------------------------------- -------------------------------------------------------------------------------- Testing input file apbs-0.200.in BINARY: apbs INPUT: apbs-0.200.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-0.200.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from model_outNB.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 998 atoms Centered at (1.382e+01, 5.283e+00, 8.258e+00) Net charge -1.40e+01 e Reading PQR-format atom data from model_outNpep.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 379 atoms Centered at (1.753e+01, -1.723e+00, 1.470e+01) Net charge 4.00e+00 e Reading PQR-format atom data from model_outBoxB19.pqr. 619 atoms Centered at (1.306e+01, 7.586e+00, 4.177e+00) Net charge -1.80e+01 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 6.86696 A Current memory usage: 204.865 MB total, 204.865 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.200 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.200 M concentration 2.000 A-radius, -1.000 e-charge, 0.200 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 3.182488501939E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 6.86696 A Current memory usage: 204.865 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.200 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.200 M concentration 2.000 A-radius, -1.000 e-charge, 0.200 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-complex-0.200.dx Ion number density to be written to ndens-complex-0.200.dx Total electrostatic energy = 3.659213428941E+04 kJ/mol Calculating forces... Writing charge density to qdens-complex-0.200-PE0.dx Writing number density to ndens-complex-0.200-PE0.dx ---------------------------------------- CALCULATION #3 (peptide): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 6.86696 A Current memory usage: 196.345 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.200 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.200 M concentration 2.000 A-radius, -1.000 e-charge, 0.200 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 8.469596195763E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #4 (peptide): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 6.86696 A Current memory usage: 196.345 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.200 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.200 M concentration 2.000 A-radius, -1.000 e-charge, 0.200 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-pep-0.200.dx Ion number density to be written to ndens-pep-0.200.dx Total electrostatic energy = 9.997282974485E+03 kJ/mol Calculating forces... Writing charge density to qdens-pep-0.200-PE0.dx Writing number density to ndens-pep-0.200-PE0.dx ---------------------------------------- CALCULATION #5 (rna): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 6.86696 A Current memory usage: 200.941 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.200 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.200 M concentration 2.000 A-radius, -1.000 e-charge, 0.200 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.323812822097E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #6 (rna): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 6.86696 A Current memory usage: 200.941 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.200 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.200 M concentration 2.000 A-radius, -1.000 e-charge, 0.200 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-rna-0.200.dx Ion number density to be written to ndens-rna-0.200.dx Total electrostatic energy = 2.648233134327E+04 kJ/mol Calculating forces... Writing charge density to qdens-rna-0.200-PE0.dx Writing number density to ndens-rna-0.200-PE0.dx ---------------------------------------- PRINT STATEMENTS print energy 1 (complex) - 2 (peptide) - 3 (rna) end Local net energy (PE 0) = 1.125199716537E+02 kJ/mol Global net ELEC energy = 1.125199716537E+02 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 406.244 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-0.out RESULT 31824.88501939 RESULT 36592.13428941 RESULT 8469.596195763 RESULT 9997.282974485 RESULT 23238.12822097 RESULT 26482.33134327 RESULT 112.5199716537 Testing computed result 3.182488501939E+04 against expected result 3.182489E+04 *** PASSED *** Testing computed result 3.659213428941E+04 against expected result 3.659213E+04 *** PASSED *** Testing computed result 8.469596195763E+03 against expected result 8.469596E+03 *** PASSED *** Testing computed result 9.997282974485E+03 against expected result 9.997283E+03 *** PASSED *** Testing computed result 2.323812822097E+04 against expected result 2.323813E+04 *** PASSED *** Testing computed result 2.648233134327E+04 against expected result 2.648233E+04 *** PASSED *** Testing computed result 1.125199716537E+02 against expected result 1.125200E+02 *** PASSED *** Elapsed time: 55.070014 seconds -------------------------------------------------------------------------------- -------------------------------------------------------------------------------- Testing input file apbs-0.225.in BINARY: apbs INPUT: apbs-0.225.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-0.225.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from model_outNB.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 998 atoms Centered at (1.382e+01, 5.283e+00, 8.258e+00) Net charge -1.40e+01 e Reading PQR-format atom data from model_outNpep.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 379 atoms Centered at (1.753e+01, -1.723e+00, 1.470e+01) Net charge 4.00e+00 e Reading PQR-format atom data from model_outBoxB19.pqr. 619 atoms Centered at (1.306e+01, 7.586e+00, 4.177e+00) Net charge -1.80e+01 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 6.47423 A Current memory usage: 204.865 MB total, 204.865 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.225 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.225 M concentration 2.000 A-radius, -1.000 e-charge, 0.225 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 3.182323306491E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 6.47423 A Current memory usage: 204.865 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.225 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.225 M concentration 2.000 A-radius, -1.000 e-charge, 0.225 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-complex-0.225.dx Ion number density to be written to ndens-complex-0.225.dx Total electrostatic energy = 3.659048040133E+04 kJ/mol Calculating forces... Writing charge density to qdens-complex-0.225-PE0.dx Writing number density to ndens-complex-0.225-PE0.dx ---------------------------------------- CALCULATION #3 (peptide): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 6.47423 A Current memory usage: 196.345 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.225 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.225 M concentration 2.000 A-radius, -1.000 e-charge, 0.225 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 8.469088900775E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #4 (peptide): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 6.47423 A Current memory usage: 196.345 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.225 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.225 M concentration 2.000 A-radius, -1.000 e-charge, 0.225 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-pep-0.225.dx Ion number density to be written to ndens-pep-0.225.dx Total electrostatic energy = 9.996777552566E+03 kJ/mol Calculating forces... Writing charge density to qdens-pep-0.225-PE0.dx Writing number density to ndens-pep-0.225-PE0.dx ---------------------------------------- CALCULATION #5 (rna): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 6.47423 A Current memory usage: 200.941 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.225 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.225 M concentration 2.000 A-radius, -1.000 e-charge, 0.225 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.323569434544E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #6 (rna): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 6.47423 A Current memory usage: 200.941 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.225 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.225 M concentration 2.000 A-radius, -1.000 e-charge, 0.225 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-rna-0.225.dx Ion number density to be written to ndens-rna-0.225.dx Total electrostatic energy = 2.647989580221E+04 kJ/mol Calculating forces... Writing charge density to qdens-rna-0.225-PE0.dx Writing number density to ndens-rna-0.225-PE0.dx ---------------------------------------- PRINT STATEMENTS print energy 1 (complex) - 2 (peptide) - 3 (rna) end Local net energy (PE 0) = 1.138070465620E+02 kJ/mol Global net ELEC energy = 1.138070465620E+02 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 406.244 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-0.out RESULT 31823.23306491 RESULT 36590.48040133 RESULT 8469.088900775 RESULT 9996.777552566 RESULT 23235.69434544 RESULT 26479.89580221 RESULT 113.807046562 Testing computed result 3.182323306491E+04 against expected result 3.182323E+04 *** PASSED *** Testing computed result 3.659048040133E+04 against expected result 3.659048E+04 *** PASSED *** Testing computed result 8.469088900775E+03 against expected result 8.469089E+03 *** PASSED *** Testing computed result 9.996777552566E+03 against expected result 9.996778E+03 *** PASSED *** Testing computed result 2.323569434544E+04 against expected result 2.323569E+04 *** PASSED *** Testing computed result 2.647989580221E+04 against expected result 2.647990E+04 *** PASSED *** Testing computed result 1.138070465620E+02 against expected result 1.138070E+02 *** PASSED *** Elapsed time: 54.858842 seconds -------------------------------------------------------------------------------- -------------------------------------------------------------------------------- Testing input file apbs-0.250.in BINARY: apbs INPUT: apbs-0.250.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-0.250.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from model_outNB.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 998 atoms Centered at (1.382e+01, 5.283e+00, 8.258e+00) Net charge -1.40e+01 e Reading PQR-format atom data from model_outNpep.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 379 atoms Centered at (1.753e+01, -1.723e+00, 1.470e+01) Net charge 4.00e+00 e Reading PQR-format atom data from model_outBoxB19.pqr. 619 atoms Centered at (1.306e+01, 7.586e+00, 4.177e+00) Net charge -1.80e+01 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 6.142 A Current memory usage: 204.865 MB total, 204.865 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.250 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.250 M concentration 2.000 A-radius, -1.000 e-charge, 0.250 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 3.182178954360E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 6.142 A Current memory usage: 204.865 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.250 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.250 M concentration 2.000 A-radius, -1.000 e-charge, 0.250 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-complex-0.250.dx Ion number density to be written to ndens-complex-0.250.dx Total electrostatic energy = 3.658903543806E+04 kJ/mol Calculating forces... Writing charge density to qdens-complex-0.250-PE0.dx Writing number density to ndens-complex-0.250-PE0.dx ---------------------------------------- CALCULATION #3 (peptide): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 6.142 A Current memory usage: 196.345 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.250 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.250 M concentration 2.000 A-radius, -1.000 e-charge, 0.250 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 8.468632740499E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #4 (peptide): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 6.142 A Current memory usage: 196.345 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.250 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.250 M concentration 2.000 A-radius, -1.000 e-charge, 0.250 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-pep-0.250.dx Ion number density to be written to ndens-pep-0.250.dx Total electrostatic energy = 9.996323108319E+03 kJ/mol Calculating forces... Writing charge density to qdens-pep-0.250-PE0.dx Writing number density to ndens-pep-0.250-PE0.dx ---------------------------------------- CALCULATION #5 (rna): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 6.142 A Current memory usage: 200.941 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.250 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.250 M concentration 2.000 A-radius, -1.000 e-charge, 0.250 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.323356752071E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #6 (rna): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 6.142 A Current memory usage: 200.941 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.250 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.250 M concentration 2.000 A-radius, -1.000 e-charge, 0.250 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-rna-0.250.dx Ion number density to be written to ndens-rna-0.250.dx Total electrostatic energy = 2.647776789284E+04 kJ/mol Calculating forces... Writing charge density to qdens-rna-0.250-PE0.dx Writing number density to ndens-rna-0.250-PE0.dx ---------------------------------------- PRINT STATEMENTS print energy 1 (complex) - 2 (peptide) - 3 (rna) end Local net energy (PE 0) = 1.149444369078E+02 kJ/mol Global net ELEC energy = 1.149444369078E+02 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 406.244 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-0.out RESULT 31821.7895436 RESULT 36589.03543806 RESULT 8468.632740499 RESULT 9996.323108319 RESULT 23233.56752071 RESULT 26477.76789284 RESULT 114.9444369078 Testing computed result 3.182178954360E+04 against expected result 3.182179E+04 *** PASSED *** Testing computed result 3.658903543806E+04 against expected result 3.658904E+04 *** PASSED *** Testing computed result 8.468632740499E+03 against expected result 8.468633E+03 *** PASSED *** Testing computed result 9.996323108319E+03 against expected result 9.996323E+03 *** PASSED *** Testing computed result 2.323356752071E+04 against expected result 2.323357E+04 *** PASSED *** Testing computed result 2.647776789284E+04 against expected result 2.647777E+04 *** PASSED *** Testing computed result 1.149444369078E+02 against expected result 1.149444E+02 *** PASSED *** Elapsed time: 55.164776 seconds -------------------------------------------------------------------------------- -------------------------------------------------------------------------------- Testing input file apbs-0.275.in BINARY: apbs INPUT: apbs-0.275.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-0.275.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from model_outNB.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 998 atoms Centered at (1.382e+01, 5.283e+00, 8.258e+00) Net charge -1.40e+01 e Reading PQR-format atom data from model_outNpep.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 379 atoms Centered at (1.753e+01, -1.723e+00, 1.470e+01) Net charge 4.00e+00 e Reading PQR-format atom data from model_outBoxB19.pqr. 619 atoms Centered at (1.306e+01, 7.586e+00, 4.177e+00) Net charge -1.80e+01 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 5.85617 A Current memory usage: 204.865 MB total, 204.865 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.275 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.275 M concentration 2.000 A-radius, -1.000 e-charge, 0.275 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 3.182051070674E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 5.85617 A Current memory usage: 204.865 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.275 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.275 M concentration 2.000 A-radius, -1.000 e-charge, 0.275 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-complex-0.275.dx Ion number density to be written to ndens-complex-0.275.dx Total electrostatic energy = 3.658775551975E+04 kJ/mol Calculating forces... Writing charge density to qdens-complex-0.275-PE0.dx Writing number density to ndens-complex-0.275-PE0.dx ---------------------------------------- CALCULATION #3 (peptide): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 5.85617 A Current memory usage: 196.345 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.275 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.275 M concentration 2.000 A-radius, -1.000 e-charge, 0.275 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 8.468218414737E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #4 (peptide): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 5.85617 A Current memory usage: 196.345 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.275 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.275 M concentration 2.000 A-radius, -1.000 e-charge, 0.275 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-pep-0.275.dx Ion number density to be written to ndens-pep-0.275.dx Total electrostatic energy = 9.995910367297E+03 kJ/mol Calculating forces... Writing charge density to qdens-pep-0.275-PE0.dx Writing number density to ndens-pep-0.275-PE0.dx ---------------------------------------- CALCULATION #5 (rna): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 5.85617 A Current memory usage: 200.941 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.275 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.275 M concentration 2.000 A-radius, -1.000 e-charge, 0.275 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.323168374787E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #6 (rna): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 5.85617 A Current memory usage: 200.941 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.275 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.275 M concentration 2.000 A-radius, -1.000 e-charge, 0.275 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-rna-0.275.dx Ion number density to be written to ndens-rna-0.275.dx Total electrostatic energy = 2.647588345522E+04 kJ/mol Calculating forces... Writing charge density to qdens-rna-0.275-PE0.dx Writing number density to ndens-rna-0.275-PE0.dx ---------------------------------------- PRINT STATEMENTS print energy 1 (complex) - 2 (peptide) - 3 (rna) end Local net energy (PE 0) = 1.159616972339E+02 kJ/mol Global net ELEC energy = 1.159616972339E+02 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 406.244 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-0.out RESULT 31820.51070674 RESULT 36587.75551975 RESULT 8468.218414737 RESULT 9995.910367297 RESULT 23231.68374787 RESULT 26475.88345522 RESULT 115.9616972339 Testing computed result 3.182051070674E+04 against expected result 3.182051E+04 *** PASSED *** Testing computed result 3.658775551975E+04 against expected result 3.658776E+04 *** PASSED *** Testing computed result 8.468218414737E+03 against expected result 8.468218E+03 *** PASSED *** Testing computed result 9.995910367297E+03 against expected result 9.995910E+03 *** PASSED *** Testing computed result 2.323168374787E+04 against expected result 2.323168E+04 *** PASSED *** Testing computed result 2.647588345522E+04 against expected result 2.647588E+04 *** PASSED *** Testing computed result 1.159616972339E+02 against expected result 1.159617E+02 *** PASSED *** Elapsed time: 55.905075 seconds -------------------------------------------------------------------------------- -------------------------------------------------------------------------------- Testing input file apbs-0.300.in BINARY: apbs INPUT: apbs-0.300.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-0.300.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from model_outNB.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 998 atoms Centered at (1.382e+01, 5.283e+00, 8.258e+00) Net charge -1.40e+01 e Reading PQR-format atom data from model_outNpep.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 379 atoms Centered at (1.753e+01, -1.723e+00, 1.470e+01) Net charge 4.00e+00 e Reading PQR-format atom data from model_outBoxB19.pqr. 619 atoms Centered at (1.306e+01, 7.586e+00, 4.177e+00) Net charge -1.80e+01 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 5.60685 A Current memory usage: 204.865 MB total, 204.865 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.300 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.300 M concentration 2.000 A-radius, -1.000 e-charge, 0.300 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 3.181936493519E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 5.60685 A Current memory usage: 204.865 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.300 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.300 M concentration 2.000 A-radius, -1.000 e-charge, 0.300 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-complex-0.300.dx Ion number density to be written to ndens-complex-0.300.dx Total electrostatic energy = 3.658660893678E+04 kJ/mol Calculating forces... Writing charge density to qdens-complex-0.300-PE0.dx Writing number density to ndens-complex-0.300-PE0.dx ---------------------------------------- CALCULATION #3 (peptide): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 5.60685 A Current memory usage: 196.345 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.300 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.300 M concentration 2.000 A-radius, -1.000 e-charge, 0.300 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 8.467838971928E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #4 (peptide): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 5.60685 A Current memory usage: 196.345 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.300 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.300 M concentration 2.000 A-radius, -1.000 e-charge, 0.300 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-pep-0.300.dx Ion number density to be written to ndens-pep-0.300.dx Total electrostatic energy = 9.995532397856E+03 kJ/mol Calculating forces... Writing charge density to qdens-pep-0.300-PE0.dx Writing number density to ndens-pep-0.300-PE0.dx ---------------------------------------- CALCULATION #5 (rna): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 5.60685 A Current memory usage: 200.941 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.300 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.300 M concentration 2.000 A-radius, -1.000 e-charge, 0.300 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.322999676177E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #6 (rna): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 5.60685 A Current memory usage: 200.941 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.300 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.300 M concentration 2.000 A-radius, -1.000 e-charge, 0.300 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-rna-0.300.dx Ion number density to be written to ndens-rna-0.300.dx Total electrostatic energy = 2.647419611346E+04 kJ/mol Calculating forces... Writing charge density to qdens-rna-0.300-PE0.dx Writing number density to ndens-rna-0.300-PE0.dx ---------------------------------------- PRINT STATEMENTS print energy 1 (complex) - 2 (peptide) - 3 (rna) end Local net energy (PE 0) = 1.168804254687E+02 kJ/mol Global net ELEC energy = 1.168804254687E+02 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 406.244 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-0.out RESULT 31819.36493519 RESULT 36586.60893678 RESULT 8467.838971928 RESULT 9995.532397856 RESULT 23229.99676177 RESULT 26474.19611346 RESULT 116.8804254687 Testing computed result 3.181936493519E+04 against expected result 3.181936E+04 *** PASSED *** Testing computed result 3.658660893678E+04 against expected result 3.658661E+04 *** PASSED *** Testing computed result 8.467838971928E+03 against expected result 8.467839E+03 *** PASSED *** Testing computed result 9.995532397856E+03 against expected result 9.995532E+03 *** PASSED *** Testing computed result 2.322999676177E+04 against expected result 2.323000E+04 *** PASSED *** Testing computed result 2.647419611346E+04 against expected result 2.647420E+04 *** PASSED *** Testing computed result 1.168804254687E+02 against expected result 1.168804E+02 *** PASSED *** Elapsed time: 56.991329 seconds -------------------------------------------------------------------------------- -------------------------------------------------------------------------------- Testing input file apbs-0.325.in BINARY: apbs INPUT: apbs-0.325.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-0.325.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from model_outNB.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 998 atoms Centered at (1.382e+01, 5.283e+00, 8.258e+00) Net charge -1.40e+01 e Reading PQR-format atom data from model_outNpep.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 379 atoms Centered at (1.753e+01, -1.723e+00, 1.470e+01) Net charge 4.00e+00 e Reading PQR-format atom data from model_outBoxB19.pqr. 619 atoms Centered at (1.306e+01, 7.586e+00, 4.177e+00) Net charge -1.80e+01 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 5.38689 A Current memory usage: 204.865 MB total, 204.865 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.325 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.325 M concentration 2.000 A-radius, -1.000 e-charge, 0.325 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 3.181832869046E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 5.38689 A Current memory usage: 204.865 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.325 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.325 M concentration 2.000 A-radius, -1.000 e-charge, 0.325 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-complex-0.325.dx Ion number density to be written to ndens-complex-0.325.dx Total electrostatic energy = 3.658557208654E+04 kJ/mol Calculating forces... Writing charge density to qdens-complex-0.325-PE0.dx Writing number density to ndens-complex-0.325-PE0.dx ---------------------------------------- CALCULATION #3 (peptide): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 5.38689 A Current memory usage: 196.345 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.325 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.325 M concentration 2.000 A-radius, -1.000 e-charge, 0.325 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 8.467489074881E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #4 (peptide): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 5.38689 A Current memory usage: 196.345 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.325 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.325 M concentration 2.000 A-radius, -1.000 e-charge, 0.325 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-pep-0.325.dx Ion number density to be written to ndens-pep-0.325.dx Total electrostatic energy = 9.995183878464E+03 kJ/mol Calculating forces... Writing charge density to qdens-pep-0.325-PE0.dx Writing number density to ndens-pep-0.325-PE0.dx ---------------------------------------- CALCULATION #5 (rna): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 5.38689 A Current memory usage: 200.941 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.325 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.325 M concentration 2.000 A-radius, -1.000 e-charge, 0.325 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.322847209567E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #6 (rna): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 5.38689 A Current memory usage: 200.941 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.325 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.325 M concentration 2.000 A-radius, -1.000 e-charge, 0.325 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-rna-0.325.dx Ion number density to be written to ndens-rna-0.325.dx Total electrostatic energy = 2.647267132259E+04 kJ/mol Calculating forces... Writing charge density to qdens-rna-0.325-PE0.dx Writing number density to ndens-rna-0.325-PE0.dx ---------------------------------------- PRINT STATEMENTS print energy 1 (complex) - 2 (peptide) - 3 (rna) end Local net energy (PE 0) = 1.177168854907E+02 kJ/mol Global net ELEC energy = 1.177168854907E+02 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 406.244 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-0.out RESULT 31818.32869046 RESULT 36585.57208654 RESULT 8467.489074881 RESULT 9995.183878464 RESULT 23228.47209567 RESULT 26472.67132259 RESULT 117.7168854907 Testing computed result 3.181832869046E+04 against expected result 3.181833E+04 *** PASSED *** Testing computed result 3.658557208654E+04 against expected result 3.658557E+04 *** PASSED *** Testing computed result 8.467489074881E+03 against expected result 8.467489E+03 *** PASSED *** Testing computed result 9.995183878464E+03 against expected result 9.995184E+03 *** PASSED *** Testing computed result 2.322847209567E+04 against expected result 2.322847E+04 *** PASSED *** Testing computed result 2.647267132259E+04 against expected result 2.647267E+04 *** PASSED *** Testing computed result 1.177168854907E+02 against expected result 1.177169E+02 *** PASSED *** Elapsed time: 54.882402 seconds -------------------------------------------------------------------------------- -------------------------------------------------------------------------------- Testing input file apbs-0.400.in BINARY: apbs INPUT: apbs-0.400.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-0.400.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from model_outNB.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 998 atoms Centered at (1.382e+01, 5.283e+00, 8.258e+00) Net charge -1.40e+01 e Reading PQR-format atom data from model_outNpep.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 379 atoms Centered at (1.753e+01, -1.723e+00, 1.470e+01) Net charge 4.00e+00 e Reading PQR-format atom data from model_outBoxB19.pqr. 619 atoms Centered at (1.306e+01, 7.586e+00, 4.177e+00) Net charge -1.80e+01 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 4.85568 A Current memory usage: 204.865 MB total, 204.865 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.400 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.400 M concentration 2.000 A-radius, -1.000 e-charge, 0.400 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 3.181571629593E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 4.85568 A Current memory usage: 204.865 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.400 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.400 M concentration 2.000 A-radius, -1.000 e-charge, 0.400 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-complex-0.400.dx Ion number density to be written to ndens-complex-0.400.dx Total electrostatic energy = 3.658295870300E+04 kJ/mol Calculating forces... Writing charge density to qdens-complex-0.400-PE0.dx Writing number density to ndens-complex-0.400-PE0.dx ---------------------------------------- CALCULATION #3 (peptide): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 4.85568 A Current memory usage: 196.345 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.400 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.400 M concentration 2.000 A-radius, -1.000 e-charge, 0.400 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 8.466578740909E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #4 (peptide): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 4.85568 A Current memory usage: 196.345 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.400 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.400 M concentration 2.000 A-radius, -1.000 e-charge, 0.400 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-pep-0.400.dx Ion number density to be written to ndens-pep-0.400.dx Total electrostatic energy = 9.994277216885E+03 kJ/mol Calculating forces... Writing charge density to qdens-pep-0.400-PE0.dx Writing number density to ndens-pep-0.400-PE0.dx ---------------------------------------- CALCULATION #5 (rna): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 4.85568 A Current memory usage: 200.941 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.400 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.400 M concentration 2.000 A-radius, -1.000 e-charge, 0.400 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.322463613929E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #6 (rna): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 4.85568 A Current memory usage: 200.941 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.400 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.400 M concentration 2.000 A-radius, -1.000 e-charge, 0.400 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-rna-0.400.dx Ion number density to be written to ndens-rna-0.400.dx Total electrostatic energy = 2.646883588223E+04 kJ/mol Calculating forces... Writing charge density to qdens-rna-0.400-PE0.dx Writing number density to ndens-rna-0.400-PE0.dx ---------------------------------------- PRINT STATEMENTS print energy 1 (complex) - 2 (peptide) - 3 (rna) end Local net energy (PE 0) = 1.198456038802E+02 kJ/mol Global net ELEC energy = 1.198456038802E+02 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 406.244 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-0.out RESULT 31815.71629593 RESULT 36582.958703 RESULT 8466.578740909 RESULT 9994.277216885 RESULT 23224.63613929 RESULT 26468.83588223 RESULT 119.8456038802 Testing computed result 3.181571629593E+04 against expected result 3.181572E+04 *** PASSED *** Testing computed result 3.658295870300E+04 against expected result 3.658296E+04 *** PASSED *** Testing computed result 8.466578740909E+03 against expected result 8.466579E+03 *** PASSED *** Testing computed result 9.994277216885E+03 against expected result 9.994277E+03 *** PASSED *** Testing computed result 2.322463613929E+04 against expected result 2.322464E+04 *** PASSED *** Testing computed result 2.646883588223E+04 against expected result 2.646884E+04 *** PASSED *** Testing computed result 1.198456038802E+02 against expected result 1.198456E+02 *** PASSED *** Elapsed time: 55.370712 seconds -------------------------------------------------------------------------------- -------------------------------------------------------------------------------- Testing input file apbs-0.500.in BINARY: apbs INPUT: apbs-0.500.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-0.500.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from model_outNB.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 998 atoms Centered at (1.382e+01, 5.283e+00, 8.258e+00) Net charge -1.40e+01 e Reading PQR-format atom data from model_outNpep.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 379 atoms Centered at (1.753e+01, -1.723e+00, 1.470e+01) Net charge 4.00e+00 e Reading PQR-format atom data from model_outBoxB19.pqr. 619 atoms Centered at (1.306e+01, 7.586e+00, 4.177e+00) Net charge -1.80e+01 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 4.34305 A Current memory usage: 204.865 MB total, 204.865 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.500 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.500 M concentration 2.000 A-radius, -1.000 e-charge, 0.500 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 3.181302243781E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 4.34305 A Current memory usage: 204.865 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.500 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.500 M concentration 2.000 A-radius, -1.000 e-charge, 0.500 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-complex-0.500.dx Ion number density to be written to ndens-complex-0.500.dx Total electrostatic energy = 3.658026461575E+04 kJ/mol Calculating forces... Writing charge density to qdens-complex-0.500-PE0.dx Writing number density to ndens-complex-0.500-PE0.dx ---------------------------------------- CALCULATION #3 (peptide): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 4.34305 A Current memory usage: 196.345 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.500 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.500 M concentration 2.000 A-radius, -1.000 e-charge, 0.500 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 8.465598755475E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #4 (peptide): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 4.34305 A Current memory usage: 196.345 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.500 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.500 M concentration 2.000 A-radius, -1.000 e-charge, 0.500 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-pep-0.500.dx Ion number density to be written to ndens-pep-0.500.dx Total electrostatic energy = 9.993301332440E+03 kJ/mol Calculating forces... Writing charge density to qdens-pep-0.500-PE0.dx Writing number density to ndens-pep-0.500-PE0.dx ---------------------------------------- CALCULATION #5 (rna): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 4.34305 A Current memory usage: 200.941 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.500 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.500 M concentration 2.000 A-radius, -1.000 e-charge, 0.500 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.322070101887E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #6 (rna): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 4.34305 A Current memory usage: 200.941 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.500 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.500 M concentration 2.000 A-radius, -1.000 e-charge, 0.500 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-rna-0.500.dx Ion number density to be written to ndens-rna-0.500.dx Total electrostatic energy = 2.646490251594E+04 kJ/mol Calculating forces... Writing charge density to qdens-rna-0.500-PE0.dx Writing number density to ndens-rna-0.500-PE0.dx ---------------------------------------- PRINT STATEMENTS print energy 1 (complex) - 2 (peptide) - 3 (rna) end Local net energy (PE 0) = 1.220607673699E+02 kJ/mol Global net ELEC energy = 1.220607673699E+02 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 406.244 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-0.out RESULT 31813.02243781 RESULT 36580.26461575 RESULT 8465.598755475 RESULT 9993.30133244 RESULT 23220.70101887 RESULT 26464.90251594 RESULT 122.0607673699 Testing computed result 3.181302243781E+04 against expected result 3.181302E+04 *** PASSED *** Testing computed result 3.658026461575E+04 against expected result 3.658026E+04 *** PASSED *** Testing computed result 8.465598755475E+03 against expected result 8.465599E+03 *** PASSED *** Testing computed result 9.993301332440E+03 against expected result 9.993301E+03 *** PASSED *** Testing computed result 2.322070101887E+04 against expected result 2.322070E+04 *** PASSED *** Testing computed result 2.646490251594E+04 against expected result 2.646490E+04 *** PASSED *** Testing computed result 1.220607673699E+02 against expected result 1.220608E+02 *** PASSED *** Elapsed time: 55.531890 seconds -------------------------------------------------------------------------------- -------------------------------------------------------------------------------- Testing input file apbs-0.600.in BINARY: apbs INPUT: apbs-0.600.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-0.600.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from model_outNB.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 998 atoms Centered at (1.382e+01, 5.283e+00, 8.258e+00) Net charge -1.40e+01 e Reading PQR-format atom data from model_outNpep.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 379 atoms Centered at (1.753e+01, -1.723e+00, 1.470e+01) Net charge 4.00e+00 e Reading PQR-format atom data from model_outBoxB19.pqr. 619 atoms Centered at (1.306e+01, 7.586e+00, 4.177e+00) Net charge -1.80e+01 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 3.96464 A Current memory usage: 204.865 MB total, 204.865 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.600 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.600 M concentration 2.000 A-radius, -1.000 e-charge, 0.600 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 3.181090090954E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 3.96464 A Current memory usage: 204.865 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.600 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.600 M concentration 2.000 A-radius, -1.000 e-charge, 0.600 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-complex-0.600.dx Ion number density to be written to ndens-complex-0.600.dx Total electrostatic energy = 3.657814345443E+04 kJ/mol Calculating forces... Writing charge density to qdens-complex-0.600-PE0.dx Writing number density to ndens-complex-0.600-PE0.dx ---------------------------------------- CALCULATION #3 (peptide): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 3.96464 A Current memory usage: 196.345 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.600 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.600 M concentration 2.000 A-radius, -1.000 e-charge, 0.600 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 8.464799341688E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #4 (peptide): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 3.96464 A Current memory usage: 196.345 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.600 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.600 M concentration 2.000 A-radius, -1.000 e-charge, 0.600 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-pep-0.600.dx Ion number density to be written to ndens-pep-0.600.dx Total electrostatic energy = 9.992505379555E+03 kJ/mol Calculating forces... Writing charge density to qdens-pep-0.600-PE0.dx Writing number density to ndens-pep-0.600-PE0.dx ---------------------------------------- CALCULATION #5 (rna): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 3.96464 A Current memory usage: 200.941 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.600 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.600 M concentration 2.000 A-radius, -1.000 e-charge, 0.600 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.321762631365E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #6 (rna): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 3.96464 A Current memory usage: 200.941 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.600 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.600 M concentration 2.000 A-radius, -1.000 e-charge, 0.600 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-rna-0.600.dx Ion number density to be written to ndens-rna-0.600.dx Total electrostatic energy = 2.646183001839E+04 kJ/mol Calculating forces... Writing charge density to qdens-rna-0.600-PE0.dx Writing number density to ndens-rna-0.600-PE0.dx ---------------------------------------- PRINT STATEMENTS print energy 1 (complex) - 2 (peptide) - 3 (rna) end Local net energy (PE 0) = 1.238080564885E+02 kJ/mol Global net ELEC energy = 1.238080564885E+02 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 406.244 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-0.out RESULT 31810.90090954 RESULT 36578.14345443 RESULT 8464.799341688 RESULT 9992.505379555 RESULT 23217.62631365 RESULT 26461.83001839 RESULT 123.8080564885 Testing computed result 3.181090090954E+04 against expected result 3.181090E+04 *** PASSED *** Testing computed result 3.657814345443E+04 against expected result 3.657814E+04 *** PASSED *** Testing computed result 8.464799341688E+03 against expected result 8.464799E+03 *** PASSED *** Testing computed result 9.992505379555E+03 against expected result 9.992505E+03 *** PASSED *** Testing computed result 2.321762631365E+04 against expected result 2.321763E+04 *** PASSED *** Testing computed result 2.646183001839E+04 against expected result 2.646183E+04 *** PASSED *** Testing computed result 1.238080564885E+02 against expected result 1.238081E+02 *** PASSED *** Elapsed time: 55.918019 seconds -------------------------------------------------------------------------------- -------------------------------------------------------------------------------- Testing input file apbs-0.700.in BINARY: apbs INPUT: apbs-0.700.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-0.700.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from model_outNB.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 998 atoms Centered at (1.382e+01, 5.283e+00, 8.258e+00) Net charge -1.40e+01 e Reading PQR-format atom data from model_outNpep.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 379 atoms Centered at (1.753e+01, -1.723e+00, 1.470e+01) Net charge 4.00e+00 e Reading PQR-format atom data from model_outBoxB19.pqr. 619 atoms Centered at (1.306e+01, 7.586e+00, 4.177e+00) Net charge -1.80e+01 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 3.67055 A Current memory usage: 204.865 MB total, 204.865 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.700 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.700 M concentration 2.000 A-radius, -1.000 e-charge, 0.700 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 3.180915789156E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 3.67055 A Current memory usage: 204.865 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.700 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.700 M concentration 2.000 A-radius, -1.000 e-charge, 0.700 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-complex-0.700.dx Ion number density to be written to ndens-complex-0.700.dx Total electrostatic energy = 3.657640108752E+04 kJ/mol Calculating forces... Writing charge density to qdens-complex-0.700-PE0.dx Writing number density to ndens-complex-0.700-PE0.dx ---------------------------------------- CALCULATION #3 (peptide): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 3.67055 A Current memory usage: 196.345 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.700 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.700 M concentration 2.000 A-radius, -1.000 e-charge, 0.700 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 8.464126109756E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #4 (peptide): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 3.67055 A Current memory usage: 196.345 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.700 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.700 M concentration 2.000 A-radius, -1.000 e-charge, 0.700 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-pep-0.700.dx Ion number density to be written to ndens-pep-0.700.dx Total electrostatic energy = 9.991835140855E+03 kJ/mol Calculating forces... Writing charge density to qdens-pep-0.700-PE0.dx Writing number density to ndens-pep-0.700-PE0.dx ---------------------------------------- CALCULATION #5 (rna): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 3.67055 A Current memory usage: 200.941 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.700 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.700 M concentration 2.000 A-radius, -1.000 e-charge, 0.700 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.321512352191E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #6 (rna): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 3.67055 A Current memory usage: 200.941 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.700 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.700 M concentration 2.000 A-radius, -1.000 e-charge, 0.700 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-rna-0.700.dx Ion number density to be written to ndens-rna-0.700.dx Total electrostatic energy = 2.645932953757E+04 kJ/mol Calculating forces... Writing charge density to qdens-rna-0.700-PE0.dx Writing number density to ndens-rna-0.700-PE0.dx ---------------------------------------- PRINT STATEMENTS print energy 1 (complex) - 2 (peptide) - 3 (rna) end Local net energy (PE 0) = 1.252364090878E+02 kJ/mol Global net ELEC energy = 1.252364090878E+02 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 406.244 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-0.out RESULT 31809.15789156 RESULT 36576.40108752 RESULT 8464.126109756 RESULT 9991.835140855 RESULT 23215.12352191 RESULT 26459.32953757 RESULT 125.2364090878 Testing computed result 3.180915789156E+04 against expected result 3.180916E+04 *** PASSED *** Testing computed result 3.657640108752E+04 against expected result 3.657640E+04 *** PASSED *** Testing computed result 8.464126109756E+03 against expected result 8.464126E+03 *** PASSED *** Testing computed result 9.991835140855E+03 against expected result 9.991835E+03 *** PASSED *** Testing computed result 2.321512352191E+04 against expected result 2.321512E+04 *** PASSED *** Testing computed result 2.645932953757E+04 against expected result 2.645933E+04 *** PASSED *** Testing computed result 1.252364090878E+02 against expected result 1.252364E+02 *** PASSED *** Elapsed time: 55.098165 seconds -------------------------------------------------------------------------------- -------------------------------------------------------------------------------- Testing input file apbs-0.800.in BINARY: apbs INPUT: apbs-0.800.in asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. ---------------------------------------------------------------------- APBS -- Adaptive Poisson-Boltzmann Solver Version 3.0 Nathan A. Baker (nathan.baker@pnnl.gov) Pacific Northwest National Laboratory Additional contributing authors listed in the code documentation. Copyright (c) 2010-2020 Battelle Memorial Institute. Developed at the Pacific Northwest National Laboratory, operated by Battelle Memorial Institute, Pacific Northwest Division for the U.S. Department of Energy. Portions Copyright (c) 2002-2010, Washington University in St. Louis. Portions Copyright (c) 2002-2020, Nathan A. Baker. Portions Copyright (c) 1999-2002, The Regents of the University of California. Portions Copyright (c) 1995, Michael Holst. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the developer nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ---------------------------------------------------------------------- APBS uses FETK (the Finite Element ToolKit) to solve the Poisson-Boltzmann equation numerically. FETK is a portable collection of finite element modeling class libraries developed by the Michael Holst research group and written in an object-oriented form of C. FEtk is designed to solve general coupled systems of nonlinear partial differential equations using adaptive finite element methods, inexact Newton methods, and algebraic multilevel methods. More information about FEtk may be found at . ---------------------------------------------------------------------- APBS also uses Aqua to solve the Poisson-Boltzmann equation numerically. Aqua is a modified form of the Holst group PMG library which has been modified by Patrice Koehl for improved efficiency and memory usage when solving the Poisson-Boltzmann equation. ---------------------------------------------------------------------- Please cite your use of APBS as: Baker NA, Sept D, Joseph S, Holst MJ, McCammon JA. Electrostatics of nanosystems: application to microtubules and the ribosome. Proc. Natl. Acad. Sci. USA 98, 10037-10041 2001. This executable compiled on Jul 23 2020 at 09:35:23 Parsing input file apbs-0.800.in... rank 0 size 1... Parsed input file. Got paths for 3 molecules Reading PQR-format atom data from model_outNB.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 998 atoms Centered at (1.382e+01, 5.283e+00, 8.258e+00) Net charge -1.40e+01 e Reading PQR-format atom data from model_outNpep.pqr. asc_getToken: Error occurred (bailing out). Vio_scanf: Format problem with input. 379 atoms Centered at (1.753e+01, -1.723e+00, 1.470e+01) Net charge 4.00e+00 e Reading PQR-format atom data from model_outBoxB19.pqr. 619 atoms Centered at (1.306e+01, 7.586e+00, 4.177e+00) Net charge -1.80e+01 e Preparing to run 6 PBE calculations. ---------------------------------------- CALCULATION #1 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 3.43348 A Current memory usage: 204.865 MB total, 204.865 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.800 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.800 M concentration 2.000 A-radius, -1.000 e-charge, 0.800 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 3.180768241803E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #2 (complex): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 3.43348 A Current memory usage: 204.865 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 1 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.800 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.800 M concentration 2.000 A-radius, -1.000 e-charge, 0.800 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-complex-0.800.dx Ion number density to be written to ndens-complex-0.800.dx Total electrostatic energy = 3.657492640520E+04 kJ/mol Calculating forces... Writing charge density to qdens-complex-0.800-PE0.dx Writing number density to ndens-complex-0.800-PE0.dx ---------------------------------------- CALCULATION #3 (peptide): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 3.43348 A Current memory usage: 196.345 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.800 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.800 M concentration 2.000 A-radius, -1.000 e-charge, 0.800 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 8.463546035019E+03 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #4 (peptide): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 3.43348 A Current memory usage: 196.345 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 2 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.800 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.800 M concentration 2.000 A-radius, -1.000 e-charge, 0.800 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-pep-0.800.dx Ion number density to be written to ndens-pep-0.800.dx Total electrostatic energy = 9.991257699113E+03 kJ/mol Calculating forces... Writing charge density to qdens-pep-0.800-PE0.dx Writing number density to ndens-pep-0.800-PE0.dx ---------------------------------------- CALCULATION #5 (rna): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 3.43348 A Current memory usage: 200.941 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.572 x 0.643 Grid lengths: 45.332 x 54.950 x 82.263 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Single Debye-Huckel sphere boundary conditions 2 ion species (0.800 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.800 M concentration 2.000 A-radius, -1.000 e-charge, 0.800 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Total electrostatic energy = 2.321302636223E+04 kJ/mol Calculating forces... ---------------------------------------- CALCULATION #6 (rna): MULTIGRID Setting up problem... Vpbe_ctor: Using max ion radius (2 A) for exclusion function Debye length: 3.43348 A Current memory usage: 200.941 MB total, 406.244 MB high water Using cubic spline charge discretization. Grid dimensions: 65 x 97 x 129 Grid spacings: 0.708 x 0.545 x 0.534 Grid lengths: 45.332 x 52.323 x 68.390 Grid center: (13.822, 5.283, 8.258) Multigrid levels: 4 Molecule ID: 3 Nonlinear traditional PBE Boundary conditions from focusing 2 ion species (0.800 M ionic strength): 2.000 A-radius, 1.000 e-charge, 0.800 M concentration 2.000 A-radius, -1.000 e-charge, 0.800 M concentration Solute dielectric: 4.000 Solvent dielectric: 80.000 Using "molecular" surface definition; no smoothing Solvent probe radius: 1.400 A Temperature: 298.150 K Electrostatic energies will be calculated Ion charge density to be written to qdens-rna-0.800.dx Ion number density to be written to ndens-rna-0.800.dx Total electrostatic energy = 2.645723464562E+04 kJ/mol Calculating forces... Writing charge density to qdens-rna-0.800-PE0.dx Writing number density to ndens-rna-0.800-PE0.dx ---------------------------------------- PRINT STATEMENTS print energy 1 (complex) - 2 (peptide) - 3 (rna) end Local net energy (PE 0) = 1.264340604648E+02 kJ/mol Global net ELEC energy = 1.264340604648E+02 kJ/mol ---------------------------------------- CLEANING UP AND SHUTTING DOWN... Destroying force arrays. No energy arrays to destroy. Destroying multigrid structures. Destroying 3 molecules Final memory usage: 0.001 MB total, 406.244 MB high water Thanks for using APBS! Checking for intermidiate energies in input file apbs-0.out RESULT 31807.68241803 RESULT 36574.9264052 RESULT 8463.546035019 RESULT 9991.257699113 RESULT 23213.02636223 RESULT 26457.23464562 RESULT 126.4340604648 Testing computed result 3.180768241803E+04 against expected result 3.180768E+04 *** PASSED *** Testing computed result 3.657492640520E+04 against expected result 3.657493E+04 *** PASSED *** Testing computed result 8.463546035019E+03 against expected result 8.463546E+03 *** PASSED *** Testing computed result 9.991257699113E+03 against expected result 9.991258E+03 *** PASSED *** Testing computed result 2.321302636223E+04 against expected result 2.321303E+04 *** PASSED *** Testing computed result 2.645723464562E+04 against expected result 2.645723E+04 *** PASSED *** Testing computed result 1.264340604648E+02 against expected result 1.264341E+02 *** PASSED *** Elapsed time: 55.370650 seconds -------------------------------------------------------------------------------- Total elapsed time: 996.076359 seconds Test results have been logged -------------------------------------------------------------------------------- make[1]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1' create-stamp debian/debhelper-build-stamp fakeroot debian/rules binary dh binary --with python3 dh_testroot dh_prep dh_installdirs debian/rules override_dh_auto_install make[1]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1' dh_auto_install --sourcedir=apbs --destdir=/build/reproducible-path/apbs-3.0.0+dfsg1/debian/tmp/ cd obj-arm-linux-gnueabihf && make -j3 install DESTDIR=/build/reproducible-path/apbs-3.0.0\+dfsg1/debian/tmp AM_UPDATE_INFO_DIR=no "INSTALL=install --strip-program=true" make[2]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' /usr/bin/cmake -S/build/reproducible-path/apbs-3.0.0+dfsg1/apbs -B/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf --check-build-system CMakeFiles/Makefile.cmake 0 make -f CMakeFiles/Makefile2 preinstall make[3]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' make[3]: Nothing to be done for 'preinstall'. make[3]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' Install the project... /usr/bin/cmake -P cmake_install.cmake -- Install configuration: "Release" -- Installing: /build/reproducible-path/apbs-3.0.0+dfsg1/debian/tmp/usr/share/apbs/doc -- Installing: /build/reproducible-path/apbs-3.0.0+dfsg1/debian/tmp/usr/share/apbs/doc/release_procedure.md -- Installing: /build/reproducible-path/apbs-3.0.0+dfsg1/debian/tmp/usr/share/apbs/doc/ChangeLog.md -- Installing: /build/reproducible-path/apbs-3.0.0+dfsg1/debian/tmp/usr/share/apbs/doc/icons -- Installing: /build/reproducible-path/apbs-3.0.0+dfsg1/debian/tmp/usr/share/apbs/doc/icons/APBS_64.png -- Installing: /build/reproducible-path/apbs-3.0.0+dfsg1/debian/tmp/usr/share/apbs/doc/icons/APBS_16.png -- Installing: 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Installing: /build/reproducible-path/apbs-3.0.0+dfsg1/debian/tmp/usr/include/apbs/pmgc/mgsubd.h -- Installing: /build/reproducible-path/apbs-3.0.0+dfsg1/debian/tmp/usr/include/apbs/pmgc/mikpckd.h -- Installing: /build/reproducible-path/apbs-3.0.0+dfsg1/debian/tmp/usr/include/apbs/pmgc/mlinpckd.h -- Installing: /build/reproducible-path/apbs-3.0.0+dfsg1/debian/tmp/usr/include/apbs/pmgc/mypdec.h -- Installing: /build/reproducible-path/apbs-3.0.0+dfsg1/debian/tmp/usr/include/apbs/pmgc/newtond.h -- Installing: /build/reproducible-path/apbs-3.0.0+dfsg1/debian/tmp/usr/include/apbs/pmgc/newdrvd.h -- Installing: /build/reproducible-path/apbs-3.0.0+dfsg1/debian/tmp/usr/include/apbs/pmgc/powerd.h -- Installing: /build/reproducible-path/apbs-3.0.0+dfsg1/debian/tmp/usr/include/apbs/pmgc/smoothd.h -- Installing: /build/reproducible-path/apbs-3.0.0+dfsg1/debian/tmp/usr/include/apbs/pmgc/mgfasd.h -- Installing: /build/reproducible-path/apbs-3.0.0+dfsg1/debian/tmp/usr/lib/arm-linux-gnueabihf/libapbs_pmgc.so.3 -- Installing: /build/reproducible-path/apbs-3.0.0+dfsg1/debian/tmp/usr/lib/arm-linux-gnueabihf/libapbs_pmgc.so -- Installing: /build/reproducible-path/apbs-3.0.0+dfsg1/debian/tmp/usr/include/apbs/mg/vgrid.h -- Installing: /build/reproducible-path/apbs-3.0.0+dfsg1/debian/tmp/usr/include/apbs/mg/vmgrid.h -- Installing: /build/reproducible-path/apbs-3.0.0+dfsg1/debian/tmp/usr/include/apbs/mg/vopot.h -- Installing: /build/reproducible-path/apbs-3.0.0+dfsg1/debian/tmp/usr/include/apbs/mg/vpmg.h -- Installing: /build/reproducible-path/apbs-3.0.0+dfsg1/debian/tmp/usr/include/apbs/mg/vpmgp.h -- Installing: /build/reproducible-path/apbs-3.0.0+dfsg1/debian/tmp/usr/lib/arm-linux-gnueabihf/libapbs_mg.so.3 -- Installing: /build/reproducible-path/apbs-3.0.0+dfsg1/debian/tmp/usr/lib/arm-linux-gnueabihf/libapbs_mg.so make[2]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1/obj-arm-linux-gnueabihf' make[1]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1' dh_install dh_installdocs dh_installchangelogs dh_installman dh_python3 I: dh_python3 fs:343: renaming _apbslib.so to _apbslib.cpython-39-arm-linux-gnueabihf.so dh_lintian dh_perl dh_link dh_strip_nondeterminism dh_compress debian/rules override_dh_fixperms-indep make[1]: Entering directory '/build/reproducible-path/apbs-3.0.0+dfsg1' dh_fixperms for example in FKBP/1d7h-dmso/UHBD/pqr2qcd \ ion-pmf/runme.sh \ point-pmf/runme.sh \ protein-rna/postprocess.sh \ protein-rna/test.sh \ helix/Run_membrane-helix.sh \ protein-rna/run_apdx_files.sh; \ do \ chmod +x debian/apbs-data/usr/share/apbs/examples/${example}; \ done for script in amber2charmm.sh \ param/pdb2pqr/amber2uhbd.sh \ qcd2pqr.awk; \ do \ chmod a+x debian/apbs-data/usr/share/apbs/tools/conversion/${script}; \ done make[1]: Leaving directory '/build/reproducible-path/apbs-3.0.0+dfsg1' dh_fixperms -Napbs-data dh_missing dh_dwz -a dwz: debian/libapbs3/usr/lib/arm-linux-gnueabihf/libapbs_pmgc.so.3: DWARF compression not beneficial - old size 148748 new size 149537 dh_strip -a dh_makeshlibs -a dh_shlibdeps -a dpkg-shlibdeps: warning: package could avoid a useless dependency if debian/apbs/usr/lib/apbs/tools/bin/bin/similarity debian/apbs/usr/lib/apbs/tools/bin/bin/uhbd_asc2bin debian/apbs/usr/lib/apbs/tools/bin/bin/analysis debian/apbs/usr/lib/apbs/tools/bin/bin/mergedx debian/apbs/usr/lib/apbs/tools/bin/bin/del2dx debian/apbs/usr/lib/apbs/tools/bin/bin/value debian/apbs/usr/lib/apbs/tools/bin/bin/dxmath debian/apbs/usr/lib/apbs/tools/bin/bin/mgmesh debian/apbs/usr/lib/apbs/tools/bin/bin/coulomb debian/apbs/usr/bin/apbs debian/apbs/usr/lib/apbs/tools/bin/bin/born debian/apbs/usr/lib/apbs/tools/bin/bin/dx2uhbd debian/apbs/usr/lib/apbs/tools/bin/bin/mergedx2 debian/apbs/usr/lib/apbs/tools/bin/bin/dx2mol debian/apbs/usr/lib/apbs/tools/bin/bin/benchmark debian/apbs/usr/lib/apbs/tools/bin/bin/tensor2dx debian/apbs/usr/lib/apbs/tools/bin/bin/smooth debian/apbs/usr/lib/apbs/tools/bin/bin/multivalue were not linked against libapbs_pmgc.so.3 (they use none of the library's symbols) dpkg-shlibdeps: warning: package could avoid a useless dependency if debian/apbs/usr/lib/apbs/tools/bin/bin/similarity debian/apbs/usr/lib/apbs/tools/bin/bin/uhbd_asc2bin debian/apbs/usr/lib/apbs/tools/bin/bin/analysis debian/apbs/usr/lib/apbs/tools/bin/bin/mergedx debian/apbs/usr/lib/apbs/tools/bin/bin/del2dx debian/apbs/usr/lib/apbs/tools/bin/bin/value debian/apbs/usr/lib/apbs/tools/bin/bin/dxmath debian/apbs/usr/lib/apbs/tools/bin/bin/mgmesh debian/apbs/usr/lib/apbs/tools/bin/bin/coulomb debian/apbs/usr/bin/apbs debian/apbs/usr/lib/apbs/tools/bin/bin/born debian/apbs/usr/lib/apbs/tools/bin/bin/dx2uhbd debian/apbs/usr/lib/apbs/tools/bin/bin/mergedx2 debian/apbs/usr/lib/apbs/tools/bin/bin/dx2mol debian/apbs/usr/lib/apbs/tools/bin/bin/benchmark debian/apbs/usr/lib/apbs/tools/bin/bin/tensor2dx debian/apbs/usr/lib/apbs/tools/bin/bin/smooth debian/apbs/usr/lib/apbs/tools/bin/bin/multivalue were not linked against libmpi.so.40 (they use none of the library's symbols) dpkg-shlibdeps: warning: package could avoid a useless dependency if debian/apbs/usr/lib/apbs/tools/bin/bin/similarity debian/apbs/usr/lib/apbs/tools/bin/bin/uhbd_asc2bin debian/apbs/usr/lib/apbs/tools/bin/bin/analysis debian/apbs/usr/lib/apbs/tools/bin/bin/mergedx debian/apbs/usr/lib/apbs/tools/bin/bin/del2dx debian/apbs/usr/lib/apbs/tools/bin/bin/value debian/apbs/usr/lib/apbs/tools/bin/bin/dxmath debian/apbs/usr/lib/apbs/tools/bin/bin/mgmesh debian/apbs/usr/lib/apbs/tools/bin/bin/coulomb debian/apbs/usr/bin/apbs debian/apbs/usr/lib/apbs/tools/bin/bin/born debian/apbs/usr/lib/apbs/tools/bin/bin/dx2uhbd debian/apbs/usr/lib/apbs/tools/bin/bin/mergedx2 debian/apbs/usr/lib/apbs/tools/bin/bin/dx2mol debian/apbs/usr/lib/apbs/tools/bin/bin/benchmark debian/apbs/usr/lib/apbs/tools/bin/bin/tensor2dx debian/apbs/usr/lib/apbs/tools/bin/bin/smooth debian/apbs/usr/lib/apbs/tools/bin/bin/multivalue were not linked against libstdc++.so.6 (they use none of the library's symbols) dpkg-shlibdeps: warning: package could avoid a useless dependency if debian/apbs/usr/lib/apbs/tools/bin/bin/similarity debian/apbs/usr/lib/apbs/tools/bin/bin/uhbd_asc2bin debian/apbs/usr/lib/apbs/tools/bin/bin/analysis debian/apbs/usr/lib/apbs/tools/bin/bin/mergedx debian/apbs/usr/lib/apbs/tools/bin/bin/del2dx debian/apbs/usr/lib/apbs/tools/bin/bin/value debian/apbs/usr/lib/apbs/tools/bin/bin/dxmath debian/apbs/usr/lib/apbs/tools/bin/bin/mgmesh debian/apbs/usr/lib/apbs/tools/bin/bin/coulomb debian/apbs/usr/bin/apbs debian/apbs/usr/lib/apbs/tools/bin/bin/born debian/apbs/usr/lib/apbs/tools/bin/bin/dx2uhbd debian/apbs/usr/lib/apbs/tools/bin/bin/mergedx2 debian/apbs/usr/lib/apbs/tools/bin/bin/dx2mol debian/apbs/usr/lib/apbs/tools/bin/bin/benchmark debian/apbs/usr/lib/apbs/tools/bin/bin/tensor2dx debian/apbs/usr/lib/apbs/tools/bin/bin/smooth debian/apbs/usr/lib/apbs/tools/bin/bin/multivalue were not linked against libgomp.so.1 (they use none of the library's symbols) dpkg-shlibdeps: warning: package could avoid a useless dependency if debian/apbs/usr/lib/apbs/tools/bin/bin/similarity debian/apbs/usr/lib/apbs/tools/bin/bin/uhbd_asc2bin debian/apbs/usr/lib/apbs/tools/bin/bin/analysis debian/apbs/usr/lib/apbs/tools/bin/bin/mergedx debian/apbs/usr/lib/apbs/tools/bin/bin/del2dx debian/apbs/usr/lib/apbs/tools/bin/bin/value debian/apbs/usr/lib/apbs/tools/bin/bin/dxmath debian/apbs/usr/lib/apbs/tools/bin/bin/mgmesh debian/apbs/usr/lib/apbs/tools/bin/bin/coulomb debian/apbs/usr/bin/apbs debian/apbs/usr/lib/apbs/tools/bin/bin/born debian/apbs/usr/lib/apbs/tools/bin/bin/dx2uhbd debian/apbs/usr/lib/apbs/tools/bin/bin/mergedx2 debian/apbs/usr/lib/apbs/tools/bin/bin/dx2mol debian/apbs/usr/lib/apbs/tools/bin/bin/benchmark debian/apbs/usr/lib/apbs/tools/bin/bin/tensor2dx debian/apbs/usr/lib/apbs/tools/bin/bin/smooth debian/apbs/usr/lib/apbs/tools/bin/bin/multivalue were not linked against libpthread.so.0 (they use none of the library's symbols) dpkg-shlibdeps: warning: package could avoid a useless dependency if debian/apbs/usr/bin/apbs was not linked against libapbs_routines.so.3 (it uses none of the library's symbols) dh_installdeb dh_gencontrol dpkg-gencontrol: warning: Depends field of package libapbs-dev: substitution variable ${shlibs:Depends} used, but is not defined dpkg-gencontrol: warning: package python3-apbslib: substitution variable ${python3:Provides} unused, but is defined dpkg-gencontrol: warning: package python3-apbslib: substitution variable ${python3:Versions} unused, but is defined dpkg-gencontrol: warning: package python3-apbslib: substitution variable ${python3:Provides} unused, but is defined dpkg-gencontrol: warning: package python3-apbslib: substitution variable ${python3:Versions} unused, but is defined dh_md5sums dh_builddeb dpkg-deb: building package 'libapbs3-dbgsym' in '../libapbs3-dbgsym_3.0.0+dfsg1-3_armhf.deb'. dpkg-deb: building package 'python3-apbslib-dbgsym' in '../python3-apbslib-dbgsym_3.0.0+dfsg1-3_armhf.deb'. dpkg-deb: building package 'apbs' in '../apbs_3.0.0+dfsg1-3_armhf.deb'. dpkg-deb: building package 'libapbs-dev' in '../libapbs-dev_3.0.0+dfsg1-3_armhf.deb'. dpkg-deb: building package 'apbs-dbgsym' in '../apbs-dbgsym_3.0.0+dfsg1-3_armhf.deb'. dpkg-deb: building package 'apbs-data' in '../apbs-data_3.0.0+dfsg1-3_all.deb'. dpkg-deb: building package 'python3-apbslib' in '../python3-apbslib_3.0.0+dfsg1-3_armhf.deb'. dpkg-deb: building package 'libapbs3' in '../libapbs3_3.0.0+dfsg1-3_armhf.deb'. dpkg-genbuildinfo --build=binary dpkg-genchanges --build=binary >../apbs_3.0.0+dfsg1-3_armhf.changes dpkg-genchanges: info: binary-only upload (no source code included) dpkg-source --after-build . dpkg-buildpackage: info: binary-only upload (no source included) dpkg-genchanges: info: not including original source code in upload I: copying local configuration I: unmounting dev/ptmx filesystem I: unmounting dev/pts filesystem I: unmounting dev/shm filesystem I: unmounting proc filesystem I: unmounting sys filesystem I: cleaning the build env I: removing directory /srv/workspace/pbuilder/23160 and its subdirectories I: Current time: Sun Jan 7 17:09:56 -12 2024 I: pbuilder-time-stamp: 1704690596 Mon Jan 8 05:22:10 UTC 2024 I: 1st build successful. Starting 2nd build on remote node virt64b-armhf-rb.debian.net. Mon Jan 8 05:22:10 UTC 2024 I: Preparing to do remote build '2' on virt64b-armhf-rb.debian.net. Mon Jan 8 08:55:56 UTC 2024 I: Deleting $TMPDIR on virt64b-armhf-rb.debian.net. Mon Jan 8 08:55:59 UTC 2024 I: apbs_3.0.0+dfsg1-3_armhf.changes: Format: 1.8 Date: Thu, 23 Jul 2020 17:35:23 +0800 Source: apbs Binary: apbs apbs-data apbs-dbgsym libapbs-dev libapbs3 libapbs3-dbgsym python3-apbslib python3-apbslib-dbgsym Architecture: all armhf Version: 3.0.0+dfsg1-3 Distribution: unstable Urgency: medium Maintainer: Debichem Team Changed-By: Drew Parsons Description: apbs - Adaptive Poisson Boltzmann Solver apbs-data - data files for APBS (Adaptive Poisson Boltzmann Solver) libapbs-dev - Adaptive Poisson Boltzmann Solver libapbs3 - Adaptive Poisson Boltzmann Solver python3-apbslib - Adaptive Poisson Boltzmann Solver Closes: 956998 Changes: apbs (3.0.0+dfsg1-3) unstable; urgency=medium . * Team upload. * use -fcommon in CFLAGS to aid build with gcc-10 (managing multiple definitions of common variables). Closes: #956998. * provide python path to inputgen for build-time tests Checksums-Sha1: 2c4cae9e23f0a3933052a7ab5c791ee0b23a1d19 226054036 apbs-data_3.0.0+dfsg1-3_all.deb 437c510fe423fccfdbdff46fcdf59ac407fc8597 150680 apbs-dbgsym_3.0.0+dfsg1-3_armhf.deb 59db018b7f1eb1f5caf68fffcd456d1bc3367c8e 10330 apbs_3.0.0+dfsg1-3_armhf.buildinfo b7abd15ef256392e6d33c63133fe15eac8622036 78452 apbs_3.0.0+dfsg1-3_armhf.deb 33c923e8df862d36da10919b4633743fc87ba482 66312 libapbs-dev_3.0.0+dfsg1-3_armhf.deb 4a200f12fa223a09f51e5ead8dcb61cf48af2240 517500 libapbs3-dbgsym_3.0.0+dfsg1-3_armhf.deb baadaff77879227e2ef1d57dfd983dd597c8ad92 215104 libapbs3_3.0.0+dfsg1-3_armhf.deb 31c8c3d5a296310089b5484d6675921302e0f8a3 157116 python3-apbslib-dbgsym_3.0.0+dfsg1-3_armhf.deb ccb41d2901f2b05ee0beb531e017a63a12c3fb0a 98876 python3-apbslib_3.0.0+dfsg1-3_armhf.deb Checksums-Sha256: f507c4ef0a8d899d09e72e417d9cf0e0b47ef8e1074d1855c237f79bd58b9bab 226054036 apbs-data_3.0.0+dfsg1-3_all.deb db1daf3e2b9582474ecf1babc803af8baace78c1e901d2f94eda7e72202773e0 150680 apbs-dbgsym_3.0.0+dfsg1-3_armhf.deb 79e6a8f04743c983bd5c539eed3dd99fbe44a48449cd7de663981eb5b214c633 10330 apbs_3.0.0+dfsg1-3_armhf.buildinfo 7aa8196c18bc50ae59a001c84608d511365324bced27547151a4df44a8f41b3b 78452 apbs_3.0.0+dfsg1-3_armhf.deb 5f2c92503af73778172823745966d698505289b6f1355d4762b0d0a49eae7d3e 66312 libapbs-dev_3.0.0+dfsg1-3_armhf.deb 88c2c6ba4e917de6933be8d40009ec5e72fae78a01a12cab29c7fd6c9218ad16 517500 libapbs3-dbgsym_3.0.0+dfsg1-3_armhf.deb 7481a43399abf1461e2f917b13f8ed0ad60bbd505a0f161da9950911bfaac755 215104 libapbs3_3.0.0+dfsg1-3_armhf.deb 659bca17965119703ed43b623ec6117bef3cc9f3272febbd6e44ac39df878a17 157116 python3-apbslib-dbgsym_3.0.0+dfsg1-3_armhf.deb 973f46edd4388c09787c20a70f9c77a8de521ce27f35ce87a7390a241e4ed90c 98876 python3-apbslib_3.0.0+dfsg1-3_armhf.deb Files: efe39fb66072236bbd44b855bd6adfd1 226054036 science optional apbs-data_3.0.0+dfsg1-3_all.deb aec9e52af137eebf716292f3f873b8e1 150680 debug optional apbs-dbgsym_3.0.0+dfsg1-3_armhf.deb ba71c2da9162aba634c3378b703a93bb 10330 science optional apbs_3.0.0+dfsg1-3_armhf.buildinfo f6b368384fdb2d7a36d6154b5e846a86 78452 science optional apbs_3.0.0+dfsg1-3_armhf.deb 686fd59d452b8837e34a0f61fa49a2c4 66312 libdevel optional libapbs-dev_3.0.0+dfsg1-3_armhf.deb 1c0731a6357931f15ddde136c32d8a01 517500 debug optional libapbs3-dbgsym_3.0.0+dfsg1-3_armhf.deb c5f7e47c9c4fc893e4306febf64268d2 215104 libs optional libapbs3_3.0.0+dfsg1-3_armhf.deb acca7639e805699d8399027302dac4e4 157116 debug optional python3-apbslib-dbgsym_3.0.0+dfsg1-3_armhf.deb 4770e2f8ce8b8319254161c605116a44 98876 python optional python3-apbslib_3.0.0+dfsg1-3_armhf.deb Mon Jan 8 08:56:00 UTC 2024 I: diffoscope 240 will be used to compare the two builds: # Profiling output for: /usr/bin/diffoscope --timeout 7200 --html /srv/reproducible-results/rbuild-debian/r-b-build.PxhV4VLr/apbs_3.0.0+dfsg1-3.diffoscope.html --text /srv/reproducible-results/rbuild-debian/r-b-build.PxhV4VLr/apbs_3.0.0+dfsg1-3.diffoscope.txt --json /srv/reproducible-results/rbuild-debian/r-b-build.PxhV4VLr/apbs_3.0.0+dfsg1-3.diffoscope.json --profile=- /srv/reproducible-results/rbuild-debian/r-b-build.PxhV4VLr/b1/apbs_3.0.0+dfsg1-3_armhf.changes /srv/reproducible-results/rbuild-debian/r-b-build.PxhV4VLr/b2/apbs_3.0.0+dfsg1-3_armhf.changes ## close_archive (total time: 0.000s) 0.000s 4 calls diffoscope.comparators.tar.TarContainer 0.000s 4 calls diffoscope.comparators.xz.XzContainer ## command (total time: 75.190s) 71.635s 6 calls xz 3.510s 16 calls diff 0.021s 8 calls cmp 0.021s 8 calls cmp (external) 0.003s 27 calls cmp (internal) ## compare_files (cumulative) (total time: 264.661s) 83.683s 1 call abc.DotChangesFile 83.624s 1 call abc.DebFile 82.685s 2 calls abc.XzFile 10.989s 1 call abc.DebDataTarFile 3.611s 11 calls abc.TextFile 0.048s 1 call abc.TarFile 0.021s 1 call abc.Md5sumsFile ## container_extract (total time: 78.960s) 71.635s 6 calls diffoscope.comparators.xz.XzContainer 6.408s 1102 calls diffoscope.comparators.deb.DebTarContainer 0.913s 8 calls diffoscope.comparators.deb.DebContainer 0.004s 6 calls diffoscope.comparators.tar.TarContainer ## diff (total time: 0.036s) 0.036s 183 calls linediff ## has_same_content_as (total time: 0.027s) 0.019s 8 calls abc.DebFile 0.004s 1 call abc.DebDataTarFile 0.003s 13 calls abc.TextFile 0.000s 1 call diffoscope.comparators.utils.libarchive.LibarchiveSymlink 0.000s 2 calls abc.Md5sumsFile 0.000s 2 calls abc.XzFile 0.000s 1 call abc.DotChangesFile 0.000s 1 call abc.TarFile ## main (total time: 98.623s) 96.922s 2 calls outputs 1.701s 1 call cleanup ## open_archive (total time: 0.000s) 0.000s 6 calls diffoscope.comparators.xz.XzContainer 0.000s 4 calls diffoscope.comparators.tar.TarContainer 0.000s 2 calls diffoscope.comparators.deb.DebContainer 0.000s 2 calls diffoscope.comparators.deb.DebTarContainer ## output (total time: 0.635s) 0.568s 1 call html 0.037s 1 call text 0.031s 1 call json ## recognizes (total time: 12.622s) 12.315s 12 calls diffoscope.comparators.binary.FilesystemFile 0.257s 1020 calls diffoscope.comparators.utils.libarchive.LibarchiveMember 0.027s 432 calls diffoscope.comparators.debian.DebControlMember 0.022s 256 calls diffoscope.comparators.utils.archive.ArchiveMember 0.000s 10 calls abc.DotChangesFile 0.000s 16 calls abc.Md5sumsFile 0.000s 4 calls diffoscope.comparators.utils.libarchive.LibarchiveSymlink ## specialize (total time: 0.301s) 0.301s 29 calls specialize Mon Jan 8 08:57:39 UTC 2024 E: apbs failed to build reproducibly in bullseye on armhf. Mon Jan 8 08:57:39 UTC 2024 E: diffoscope 240 found issues, please check https://tests.reproducible-builds.org/debian/dbd/bullseye/armhf/apbs_3.0.0+dfsg1-3.diffoscope.html Mon Jan 8 08:57:47 UTC 2024 I: Submitting .buildinfo files to external archives: Mon Jan 8 08:57:47 UTC 2024 I: Submitting 12K b1/apbs_3.0.0+dfsg1-3_armhf.buildinfo.asc Mon Jan 8 08:57:48 UTC 2024 I: Submitting 12K b2/apbs_3.0.0+dfsg1-3_armhf.buildinfo.asc Mon Jan 8 08:57:49 UTC 2024 I: Done submitting .buildinfo files to http://buildinfo.debian.net/api/submit. Mon Jan 8 08:57:49 UTC 2024 I: Done submitting .buildinfo files. Mon Jan 8 08:57:49 UTC 2024 I: Removing signed apbs_3.0.0+dfsg1-3_armhf.buildinfo.asc files: removed './b1/apbs_3.0.0+dfsg1-3_armhf.buildinfo.asc' removed './b2/apbs_3.0.0+dfsg1-3_armhf.buildinfo.asc'