Marc 2019.1 is new standard version

This commit is contained in:
Franz Roters 2020-07-14 12:10:43 +02:00
parent 76ae160352
commit 78c1b9c745
25 changed files with 24992 additions and 1 deletions

2
env/CONFIG vendored
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@ -2,4 +2,4 @@
set DAMASK_NUM_THREADS = 4 set DAMASK_NUM_THREADS = 4
set MSC_ROOT = /opt/msc set MSC_ROOT = /opt/msc
set MARC_VERSION = 2019 set MARC_VERSION = 2019.1

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@ -0,0 +1,52 @@
#!/bin/ksh
# 1st arg: $DIR
# 2nd arg: $DIRJOB
# 3rd arg: $user
# 4th arg: $program
DIR=$1
user=$3
program=$4
usernoext=$user
usernoext=`dirname $usernoext`/`$BASENAME $usernoext .f`
usernoext=`dirname $usernoext`/`$BASENAME $usernoext .F`
usernoext=`dirname $usernoext`/`$BASENAME $usernoext .for`
usernoext=`dirname $usernoext`/`$BASENAME $usernoext .f90`
# add BLAS options for linking
BLAS="%BLAS%"
. $DIR/tools/include
DIRJOB=$2
cd $DIRJOB
echo "Compiling and linking user subroutine $user on host `hostname`"
echo "program: $program"
$DFORTHIGHMP $user || \
{
echo "$0: compile failed for $user"
exit 1
}
/bin/rm $program 2>/dev/null
userobj=$usernoext.o
$LOAD ${program} $DIR/lib/main.o\
$DIR/lib/blkdta.o $DIR/lib/comm?.o \
${userobj-} \
$DIR/lib/srclib.a \
$MNFLIBS \
$MDUSER \
../lib/mdsrc.a \
../lib/mcvfit.a \
$STUBS \
${SOLVERLIBS} \
$TKLIBS \
$MRCLIBS \
$METISLIBS \
$BLAS \
$SYSLIBS || \
{
echo "$0: link failed for $usernoext.o on host `hostname`"
exit 1
}
/bin/rm $userobj
/bin/rm $DIRJOB/*.mod

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#!/bin/ksh
# 1st arg: $DIR
# 2nd arg: $DIRJOB
# 3rd arg: $user
# 4th arg: $program
DIR=$1
user=$3
program=$4
usernoext=$user
usernoext=`dirname $usernoext`/`$BASENAME $usernoext .f`
usernoext=`dirname $usernoext`/`$BASENAME $usernoext .F`
usernoext=`dirname $usernoext`/`$BASENAME $usernoext .for`
usernoext=`dirname $usernoext`/`$BASENAME $usernoext .f90`
# add BLAS options for linking
BLAS="%BLAS%"
. $DIR/tools/include
DIRJOB=$2
cd $DIRJOB
echo "Compiling and linking user subroutine $user on host `hostname`"
echo "program: $program"
$DFORTRANLOWMP $user || \
{
echo "$0: compile failed for $user"
exit 1
}
/bin/rm $program 2>/dev/null
userobj=$usernoext.o
$LOAD ${program} $DIR/lib/main.o\
$DIR/lib/blkdta.o $DIR/lib/comm?.o \
${userobj-} \
$DIR/lib/srclib.a \
$MNFLIBS \
$MDUSER \
../lib/mdsrc.a \
../lib/mcvfit.a \
$STUBS \
${SOLVERLIBS} \
$TKLIBS \
$MRCLIBS \
$METISLIBS \
$BLAS \
$SYSLIBS || \
{
echo "$0: link failed for $usernoext.o on host `hostname`"
exit 1
}
/bin/rm $userobj
/bin/rm $DIRJOB/*.mod

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#!/bin/ksh
# 1st arg: $DIR
# 2nd arg: $DIRJOB
# 3rd arg: $user
# 4th arg: $program
DIR=$1
user=$3
program=$4
usernoext=$user
usernoext=`dirname $usernoext`/`$BASENAME $usernoext .f`
usernoext=`dirname $usernoext`/`$BASENAME $usernoext .F`
usernoext=`dirname $usernoext`/`$BASENAME $usernoext .for`
usernoext=`dirname $usernoext`/`$BASENAME $usernoext .f90`
# add BLAS options for linking
BLAS="%BLAS%"
. $DIR/tools/include
DIRJOB=$2
cd $DIRJOB
echo "Compiling and linking user subroutine $user on host `hostname`"
echo "program: $program"
$DFORTRANMP $user || \
{
echo "$0: compile failed for $user"
exit 1
}
/bin/rm $program 2>/dev/null
userobj=$usernoext.o
$LOAD ${program} $DIR/lib/main.o\
$DIR/lib/blkdta.o $DIR/lib/comm?.o \
${userobj-} \
$DIR/lib/srclib.a \
$MNFLIBS \
$MDUSER \
../lib/mdsrc.a \
../lib/mcvfit.a \
$STUBS \
${SOLVERLIBS} \
$TKLIBS \
$MRCLIBS \
$METISLIBS \
$BLAS \
$SYSLIBS || \
{
echo "$0: link failed for $usernoext.o on host `hostname`"
exit 1
}
/bin/rm $userobj
/bin/rm $DIRJOB/*.mod

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#!/bin/ksh
# 1st arg: $DIR
# 2nd arg: $DIRJOB
# 3rd arg: $user
# 4th arg: $program
DIR=$1
user=$3
program=$4
. $DIR/tools/include
DIRJOB=$2
cd $DIRJOB
echo "Compiling and linking user subroutine $user.f on host `hostname`"
echo "program: $program"
$FORTRAN $user.f || \
{
echo "$0: compile failed for $user.f"
exit 1
}
/bin/rm $program 2>/dev/null
userobj=$user.o
$LOAD ${program} $DIR/lib/main.o\
$DIR/lib/blkdta.o $DIR/lib/comm?.o \
${userobj-} \
$DIR/lib/srclib.a \
$MNFLIBS \
$MDUSER \
../lib/mdsrc.a \
../lib/mcvfit.a \
$STUBS \
${SOLVERLIBS} \
$TKLIBS \
$MRCLIBS \
$METISLIBS \
$SYSLIBS || \
{
echo "$0: link failed for $user.o on host `hostname`"
exit 1
}
/bin/rm $userobj

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#
# General definitions for the Marc 2019 FP1 version
#
# EM64T
#
# Linux RedHat 7.1, 7.3 / SuSE 11 SP4, 12 SP1
#
# 64 bit MPI version
#
# Intel(R) Fortran Intel(R) 64 Compiler XE for applications
# running on Intel(R) 64, Version 17.0.5.239 Build 20170817
#
# Intel(R) C Intel(R) 64 Compiler XE for applications
# running on Intel(R) 64, Version 17.0.5.239 Build 20170817
#
# To check the O/S level, type:
# uname -a
#
# Distributed parallel MPI libraries:
# 1) HP MPI 2.3
# To check the mpi version, type:
# mpirun -version
# 2) Intel MPI 2017.1
# To check the mpi version, type:
# mpiexec.hydra -version
#
# To check the Compiler level, type using the compiler
# installation path:
# ifort -V
# icc -V
#
# REMARKS : This file contains the definitions of variables used during
# compilation loading and use of the MARC programmes . The
# current machine type is identified by means of the variable
# MACHINE , defined below.
#
#
# MPI_ROOT: root directory in which mpi shared libraries, etc. are located
# DIRJOB : directory in which spawned jobs should look for Marc input
# MPI_ARCH: system architecture
# MPI_EPATH: path where executable resides
#
REVISION="VERSION, BUILD"
HOSTNAME=`hostname`
# find available memory in Mbyte on the machine
# can be set explicitly
MEMLIMIT=`free -m | awk '/Mem:/ {print $2}'`
# set _OEM_NASTRAN to 1 for MD Nastran build
# override _OEM_NASTRAN setting with MARC_MD_NASTRAN environment variable
_OEM_NASTRAN="${MARC_MD_NASTRAN:-0}"
# uncomment the following line for an autoforge build
#AUTOFORGE=1
AUTOFORGE=0
export AUTOFORGE
# integer size
if test "$MARC_INTEGER_SIZE" = "" ; then
INTEGER_PATH=
else
INTEGER_PATH=/$MARC_INTEGER_SIZE
fi
FCOMP=ifort
INTELPATH="/opt/intel/compilers_and_libraries_2017/linux"
# find the root directory of the compiler installation:
# - if ifort is found in $PATH, then the root directory is derived
# from the path to ifort
# - if ifort is not found in $PATH, the root directory is assumed
# to be $INTELPATH and the directory in which ifort is found is
# added to $PATH
FCOMPPATH=`which "$FCOMP" 2>/dev/null`
if test -n "$FCOMPPATH"; then
# derive the root directory from $FCOMPPATH
FCOMPROOT="${FCOMPPATH%/bin/intel64/$FCOMP}"
if test "$FCOMPROOT" = "$FCOMPPATH"; then
FCOMPROOT="${FCOMPPATH%/bin/$FCOMP}"
fi
if test "$FCOMPROOT" = "$FCOMPPATH"; then
FCOMPROOT=
fi
elif test -d "$INTELPATH"; then
# check for compiler in $INTELPATH
if test -d "$INTELPATH/bin/intel64" -a \
-x "$INTELPATH/bin/intel64/$FCOMP" ; then
FCOMPROOT="$INTELPATH"
PATH="$INTELPATH/bin/intel64:$PATH"
elif test -d "$INTELPATH/bin" -a \
-x "$INTELPATH/bin/$FCOMP"; then
FCOMPROOT="$INTELPATH"
PATH="$INTELPATH/bin:$PATH"
else
FCOMPROOT=
fi
else
FCOMPROOT=
fi
# DAMASK uses the HDF5 compiler wrapper around the Intel compiler
H5FC="$(h5fc -shlib -show)"
HDF5_LIB=${H5FC//ifort/}
FCOMP="$H5FC -DDAMASK_HDF5"
# AEM
if test "$MARCDLLOUTDIR" = ""; then
DLLOUTDIR="$MARC_LIB"
else
DLLOUTDIR="$MARCDLLOUTDIR"
fi
# settings for MKL
if test "$IMKLDIR" = ""; then
MARC_MKL="$FCOMPROOT/mkl/lib/intel64"
else
MARC_MKL=$IMKLDIR/lib/intel64
fi
#
# settings for Metis
#
METIS="-I$METIS_SOURCE/include"
METISLIBS="$METISLIB_DIR/libmarcddm.a $METISLIB_DIR/libmarcmetis.a "
#
# settings for MPI
#
# RCP and RSH are used for parallel network runs
# replace with similar commands like rsh if needed
RCP=/usr/bin/scp
RSH=/usr/bin/ssh
#
MPI_DEFAULT=intelmpi
MPI_OTHER=hpmpi
MPITYPE=$MPI_DEFAULT
if test $AUTOFORGE
then
if test $AUTOFORGE = 1
then
MPITYPE=none
fi
fi
# overrule MPITYPE setting with environmental variable MARC_MPITYPE
if test $MARC_MPITYPE
then
MPITYPE=$MARC_MPITYPE
fi
# always set MPITYPE to none for MD Nastran
if test "$_OEM_NASTRAN" -ne 0
then
MPITYPE=none
fi
# Edit following lines to build with GPGPU version of BCS Solver for
# NVIDIA platforms
#BCSGPUSOLVER=NONE
BCSGPUSOLVER=BCSGPU
# Edit following lines to set the openssl library
if test "$OPENSSL" != "NONE"
then
OPENSSL_LIB="$MARC_LIB/libcrypto.a"
fi
OPENSSL_INCLUDE=-I"$MARC_OPENSSL/include/"
MARCHDF_HDF=HDF
#MARCHDF_HDF=NONE
if test "$MARCHDF_HDF" = "HDF"; then
HDF_INCLUDE="-I$MARC_HDF/include"
HDF_LIBS="$MARC_LIB/libhdf5_fortran.so.100 $MARC_LIB/libhdf5.so.101"
fi
# activate contact component build if flagged
AEM_DLL=0
if test "$AEM_BUILD" = "ON" ; then
AEM_DLL=1
LINK_MARC_DLL="-shared -fPIC"
EXT_DLL="so"
MPITYPE=none
MPI_OTHER=
BCSGPUSOLVER=NONE
MUMPSSOLVER=NONE
CASISOLVER=NONE
fi
SOLVERFLAGS=
if test "$BCSGPUSOLVER" = BCSGPU
then
SOLVERFLAGS="$SOLVERFLAGS -DBCSGPU -DCUDA"
BCS_DIR=bcsgpusolver
else
BCS_DIR=bcssolver
fi
#
# settings for MPI
#
DDM=
if test $MPITYPE != none
then
if test $MPITYPE = hpmpi
then
FCOMPMPI=mpif90
export MPI_ROOT=$MARC_HPMPI
export MPI_REMSH=$RSH
export MPI_F77=$FCOMP
ARCHITECTURE=linux_amd64
DDM="-I$MPI_ROOT/include/64 -DDDM -DHPMPI"
MPI_CLEAN=
export MPI_EPATH=$MARC_BIN
export LD_LIBRARY_PATH=$MPI_ROOT/lib/$ARCHITECTURE:$MARC_LIB:$MARC_LIB_SHARED:$LD_LIBRARY_PATH
export MPIHPSPECIAL="-e MPI_FLAGS=E,T,y1"
# Below line is moved in run_marc file
# export MPIHPSPECIAL="$MPIHPSPECIAL -e LD_LIBRARY_PATH=$LD_LIBRARY_PATH"
export MPIHPSPECIAL="$MPIHPSPECIAL -e BINDIR=$MARC_BIN"
if test -n "$MSC_LICENSE_FILE"
then
export MPIHPSPECIAL="$MPIHPSPECIAL -e MSC_LICENSE_FILE=$MSC_LICENSE_FILE"
fi
if test -n "$LM_LICENSE_FILE"
then
export MPIHPSPECIAL="$MPIHPSPECIAL -e LM_LICENSE_FILE=$LM_LICENSE_FILE"
fi
export MPIHPSPECIAL="$MPIHPSPECIAL -e MPI_LIC_CHECKER=$MPI_ROOT/bin/licensing/amd64_s8/lichk.x"
RUN_JOB2="$MPI_ROOT/bin/mpirun ${MPIRUNOPTIONS} -prot -f "
RUN_JOB1="$MPI_ROOT/bin/mpirun ${MPIRUNOPTIONS} -prot -w $MPIHPSPECIAL -np "
RUN_JOB0=
fi
if test $MPITYPE = intelmpi
then
INTELMPI_VERSION=HYDRA
FCOMPMPI=mpiifort
MPI_ROOT=$MARC_INTELMPI
DDM="-I${MPI_ROOT}/include -DDDM"
PATH=$MPI_ROOT/bin:$PATH
export PATH
LD_LIBRARY_PATH=$MPI_ROOT/lib:$LD_LIBRARY_PATH
export LD_LIBRARY_PATH
if test $INTELMPI_VERSION = HYDRA
then
RUN_JOB1="${MPI_ROOT}/bin/mpiexec.hydra -genvall -n "
RUN_JOB2="${MPI_ROOT}/bin/mpiexec.hydra -genvall"
else
RUN_JOB1="${MPI_ROOT}/bin/mpiexec -n "
RUN_JOB2="${MPI_ROOT}/bin/mpiexec -configfile "
fi
RUN_JOB0=
MPI_CLEAN=
MPI_EPATH=$MARC_BIN
MPIR_HOME=$MPI_ROOT
MPICH_F77=$FCOMP
MPICH_F77LINKER=$FCOMP
export MPI_ROOT MPI_EPATH MPIR_HOME MPICH_F77 MPICH_F77LINKER
I_MPI_PIN_DOMAIN=node
export I_MPI_PIN_DOMAIN
fi
else
MPI_ROOT=$MARC_DUMMYMPI
export MPI_ROOT=$MARC_DUMMYMPI
DDM="-I$MPI_ROOT/include"
fi
#
# variables for the "maintain" script
#
MACHINENAME=LINUX
MACHINE64BIT=yes
MACHINE=Linux_EM64T
DEV=/dev/tape
GETLOG="whoami"
CLEAR="clear"
MY_UNAME=`uname -a`
# Edit following 2 lines to build with VKI Solver
#VKISOLVER=VKI
VKISOLVER=NONE
# Edit following 2 lines to build with CASI Solver
CASISOLVER=CASI
if test "$MARC_CASISOLVER" = "NONE" ; then
CASISOLVER=NONE
fi
#CASISOLVER=NONE
# Edit following 2 lines to build with MF2 Solver
MF2SOLVER=NONE
#MF2SOLVER=SERIAL
#MF2SOLVER=MF2PARALLEL
# Edit following lines to build with Intel(c) Multithreaded solver (PARDISO)
#INTELSOLVER=NONE
INTELSOLVER=PARDISO
# Edit following lines to build with MUMPS
if test "$MARC_INTEGER_SIZE" = "i4" ; then
#MUMPSSOLVER=NONE
MUMPSSOLVER=MUMPS
else
#MUMPSSOLVER=NONE
MUMPSSOLVER=MUMPS
fi
# Edit following 2 lines to build MARC dynamic shared library
MARC_DLL=MARC_DLL
MARC_DLL=NONE
# always set VKISOLVER, CASISOLVER, BCSGPUSOLVER, and MARC_DLL to NONE for MD Nastran
if test "$_OEM_NASTRAN" -ne 0
then
VKISOLVER=NONE
CASISOLVER=NONE
MF2SOLVER=NONE
INTELSOLVER=NONE
MUMPSSOLVER=NONE
BCSGPUSOLVER=NONE
MARC_DLL=NONE
fi
if test "$AEM_DLL" -eq 1
then
VKISOLVER=NONE
CASISOLVER=NONE
MF2SOLVER=NONE
INTELSOLVER=NONE
MUMPSSOLVER=NONE
BCSGPUSOLVER=NONE
fi
#
# define Fortran and C compile syntax
#
if test "$VKISOLVER" = VKI
then
SOLVERFLAGS="$SOLVERFLAGS -DVKI"
fi
if test "$CASISOLVER" = CASI
then
SOLVERFLAGS="$SOLVERFLAGS -DCASI"
fi
if test "$MF2SOLVER" = MF2PARALLEL
then
SOLVERFLAGS="$SOLVERFLAGS -DMF2PARALLEL"
fi
if test "$MF2SOLVER" = MF2SERIAL
then
SOLVERFLAGS="$SOLVERFLAGS -DMF2SERIAL"
fi
if test "$INTELSOLVER" = PARDISO
then
SOLVERFLAGS="$SOLVERFLAGS -DPARDISO"
fi
if test "$MUMPSSOLVER" = MUMPS
then
SOLVERFLAGS="$SOLVERFLAGS -DMUMPS"
fi
if test "$MARC_DLL" = MARC_DLL
then
SOLVERFLAGS="$SOLVERFLAGS -DMARC_DLL"
fi
LINK_OPT=
DEBUG_OPT=
C_DEBUG_OPT=
#Uncomment following line to build Marc in debuggable mode
MARCDEBUG=
#MARCDEBUG="ON"
if test "$MARCDEBUG" = "ON"
then
LINK_OPT="-debug -traceback"
DEBUG_OPT="-debug -traceback"
C_DEBUG_OPT="-debug -traceback"
fi
MARCCHECK=
#MARCCHECK="ON"
if test "$MARCCHECK" = "ON"
then
DEBUG_OPT="$DEBUG_OPT -fpe0 -fp-stack-check -check all -ftrapuv "
C_DEBUG_OPT="$C_DEBUG_OPT -fp-stack-check -check-uninit -Wformat -ftrapuv "
fi
MARCCODECOV=
#MARCCODECOV="ON"
MARCCODEPROF=
#MARCCODEPROF="ON"
if test "$MARC_INTEGER_SIZE" = "i4" ; then
I8FFLAGS=
I8DEFINES=
I8CDEFINES=
else
I8FFLAGS="-i8 -integer-size 64"
I8DEFINES="-DI64 -DINT=8"
I8CDEFINES="-U_DOUBLE -D_SINGLE"
fi
MTHREAD=OPENMP
if test "$MARC_OPENMP" = "NONE" ; then
MTHREAD=NONE
fi
#MTHREAD=NONE
if test "$_OEM_NASTRAN" -ne 0
then
MTHREAD=NONE
fi
if test "$AEM_DLL" -eq 1
then
MTHREAD=NONE
CASISOLVER=NONE
VKISOLVER=NONE
MF2SOLVER=NONE
INTELSOLVER=NONE
BCSGPUSOLVER=NONE
OPENSSL_LIB=
MARC_DLL=NONE
METISLIBS=
fi
OMP_COMPAT=NO
OMP_COMPAT=YES
if test "$MTHREAD" = "NONE"
then
OMP_COMPAT=NO
fi
CDEFINES=
FDEFINES=
if test "$_OEM_NASTRAN" -ne 0
then
CDEFINES="$CDEFINES -D_OEM_NASTRAN"
FDEFINES="$FDEFINES -D_OEM_NASTRAN"
fi
FDEFINES="$FDEFINES -D_IMPLICITNONE"
if test "$_OEM_NASTRAN" -eq 0
then
FDEFINES="$FDEFINES -DMKL -DOPENMP"
fi
if test "$OMP_COMPAT" = "YES"
then
FDEFINES="$FDEFINES -DOMP_COMPAT"
fi
# -D_MSCMARC
FDEFINES="$FDEFINES -D_MSCMARC $DEBUG_OPT $MARC_SIMUFACT"
CDEFINES="$CDEFINES -D_MSCMARC $C_DEBUG_OPT $I8CDEFINES"
if test "$AEM_DLL" -eq 1
then
FDEFINES="$FDEFINES -D_AEMNL -DAAA"
CDEFINES="$CDEFINES -D_AEMNL -DAAA"
fi
CINCL="-I$MARC_SOURCE/mdsrc -I$MARC_SOURCE/csource $METIS -I$LAPI_IMPORTS/common/include"
if test "$_OEM_NASTRAN" -ne 0
then
CINCL="$CINCL -I../../include"
fi
CC_OPT=
if test "$MTHREAD" = "OPENMP"
then
CC_OPT=" $CC_OPT -qopenmp"
fi
CC="icc -c $CC_OPT -O1 $I8DEFINES -DLinux -DLINUX -DLinux_intel $CDEFINES $CINCL $SOLVERFLAGS $OPENSSL_INCLUDE "
CCLOW="icc -c $CC_OPT -O0 $I8DEFINES -DLinux -DLINUX -DLinux_intel $CDEFINES $CINCL $SOLVERFLAGS $OPENSSL_INCLUDE "
CCHIGH="icc -c $CC_OPT -O3 $I8DEFINES -DLinux -DLINUX -DLinux_intel $CDEFINES $CINCL $SOLVERFLAGS $OPENSSL_INCLUDE "
if test "$MARCDEBUG" = "ON"
then
CC="icc -c $CC_OPT -DLinux $I8DEFINES -DLINUX -DLinux_intel $CDEFINES $CINCL $SOLVERFLAGS $OPENSSL_INCLUDE "
CCLOW="icc $CC_OPT -c -DLinux $I8DEFINES -DLINUX -DLinux_intel $CDEFINES $CINCL $SOLVERFLAGS $OPENSSL_INCLUDE "
CCHIGH="icc $CC_OPT -c -DLinux $I8DEFINES -DLINUX -DLinux_intel $CDEFINES $CINCL $SOLVERFLAGS $OPENSSL_INCLUDE "
fi
LOAD_CC="icc $CC_OPT -O1 -DLinux -DLINUX -DLinux_intel"
CCT="$CC"
CCTLOW="$CCLOW"
CCTHIGH="$CCHIGH"
#PROFILE="-Mprof=func"
#PROFILE="-Mprof=lines"
#PROFILE="-Mprof=func,mpi"
PROFILE=
#PROFILE="-init=snan,arrays -CB -traceback -fpe0 -fp-stack-check -check all -check uninit -ftrapuv"
if test "$MARCCODECOV" = "ON"
then
PROFILE="-prof-gen=srcpos"
fi
if test "$MARCCODEPROF" = "ON"
then
PROFILE=" $PROFILE -pg"
fi
FORT_OPT="-c -implicitnone -stand f08 -standard-semantics -assume nostd_mod_proc_name -safe_cray_ptr -mp1 -WB -fp-model source"
if test "$MTHREAD" = "OPENMP"
then
FORT_OPT=" $FORT_OPT -qopenmp"
if test "$OMP_COMPAT" = "YES"
then
FORT_OPT=" $FORT_OPT -qopenmp-threadprivate=compat"
fi
else
# FORT_OPT=" $FORT_OPT -auto "
FORT_OPT=" $FORT_OPT -save -zero"
fi
if test "$MARCHDF_HDF" = "HDF"; then
FORT_OPT="$FORT_OPT -DMARCHDF=$MARCHDF_HDF"
fi
FORTLOW="$FCOMP $FORT_OPT $PROFILE -O0 $I8FFLAGS -I$MARC_SOURCE/common \
$MUMPS_INCLUDE $I8DEFINES -DLinux -DLINUX -DLinux_intel $FDEFINES $DDM $SOLVERFLAGS -I$KDTREE2_MOD"
FORTRAN="$FCOMP $FORT_OPT $PROFILE -O1 $I8FFLAGS -I$MARC_SOURCE/common \
$MUMPS_INCLUDE $I8DEFINES -DLinux -DLINUX -DLinux_intel $FDEFINES $DDM $SOLVERFLAGS -I$KDTREE2_MOD"
FORTHIGH="$FCOMP $FORT_OPT $PROFILE -fno-alias -O3 $I8FFLAGS -I$MARC_SOURCE/common \
$MUMPS_INCLUDE $I8DEFINES -DLinux -DLINUX -DLinux_intel $FDEFINES $DDM $SOLVERFLAGS -I$KDTREE2_MOD"
FORTNA="$FCOMP $FORT_OPT -fno-alias -O3 $I8FFLAGS -I$MARC_SOURCE/common \
$MUMPS_INCLUDE $I8DEFINES -DLinux -DLINUX -DLinux_intel $FDEFINES $DDM"
# for compiling free form f90 files. high opt, integer(4)
FORTF90="$FCOMP -c -O3"
# determine DAMASK version
if test -n "$DAMASK_USER"; then
DAMASKROOT=`dirname $DAMASK_USER`/..
read DAMASKVERSION < $DAMASKROOT/VERSION
DAMASKVERSION="'"$DAMASKVERSION"'"
else
DAMASKVERSION="'N/A'"
fi
# DAMASK compiler calls: additional flags are in line 2 OpenMP flags in line 3
DFORTLOWMP="$FCOMP -c -O0 -qno-offload -implicitnone -stand f08 -standard-semantics -assume nostd_mod_proc_name -safe_cray_ptr $PROFILE -zero -mp1 -WB $I8FFLAGS -I$MARC_SOURCE/common \
-fpp -ftz -diag-disable 5268 -warn declarations -warn general -warn usage -warn interfaces -warn ignore_loc -warn alignments -DMarc4DAMASK=2019 -DDAMASKVERSION=$DAMASKVERSION \
-qopenmp -qopenmp-threadprivate=compat\
$MUMPS_INCLUDE $I8DEFINES -DLinux -DLINUX -DLinux_intel $FDEFINES $DDM $SOLVERFLAGS -I$KDTREE2_MOD"
DFORTRANMP="$FCOMP -c -O1 -qno-offload -implicitnone -stand f08 -standard-semantics -assume nostd_mod_proc_name -safe_cray_ptr $PROFILE -zero -mp1 -WB $I8FFLAGS -I$MARC_SOURCE/common \
-fpp -ftz -diag-disable 5268 -warn declarations -warn general -warn usage -warn interfaces -warn ignore_loc -warn alignments -DMarc4DAMASK=2019 -DDAMASKVERSION=$DAMASKVERSION \
-qopenmp -qopenmp-threadprivate=compat\
$MUMPS_INCLUDE $I8DEFINES -DLinux -DLINUX -DLinux_intel $FDEFINES $DDM $SOLVERFLAGS -I$KDTREE2_MOD"
DFORTHIGHMP="$FCOMP -c -O3 -qno-offload -implicitnone -stand f08 -standard-semantics -assume nostd_mod_proc_name -safe_cray_ptr $PROFILE -zero -mp1 -WB $I8FFLAGS -I$MARC_SOURCE/common \
-fpp -ftz -diag-disable 5268 -warn declarations -warn general -warn usage -warn interfaces -warn ignore_loc -warn alignments -DMarc4DAMASK=2019 -DDAMASKVERSION=$DAMASKVERSION \
-qopenmp -qopenmp-threadprivate=compat\
$MUMPS_INCLUDE $I8DEFINES -DLinux -DLINUX -DLinux_intel $FDEFINES $DDM $SOLVERFLAGS -I$KDTREE2_MOD"
if test "$MARCDEBUG" = "ON"
then
FORTLOW="$FCOMP $FORT_OPT $PROFILE $I8FFLAGS -I$MARC_SOURCE/common \
$MUMPS_INCLUDE $I8DEFINES -DLinux -DLINUX -DLinux_intel $FDEFINES $DDM $SOLVERFLAGS -I$KDTREE2_MOD"
FORTRAN="$FCOMP $FORT_OPT $PROFILE $I8FFLAGS -I$MARC_SOURCE/common \
$MUMPS_INCLUDE $I8DEFINES -DLinux -DLINUX -DLinux_intel $FDEFINES $DDM $SOLVERFLAGS -I$KDTREE2_MOD"
FORTHIGH="$FCOMP $FORT_OPT $PROFILE -fno-alias $I8FFLAGS -I$MARC_SOURCE/common \
$MUMPS_INCLUDE $I8DEFINES -DLinux -DLINUX -DLinux_intel $FDEFINES $DDM $SOLVERFLAGS -I$KDTREE2_MOD"
FORTNA="$FCOMP $FORT_OPT -fno-alias $I8FFLAGS -I$MARC_SOURCE/common \
$MUMPS_INCLUDE $I8DEFINES -DLinux -DLINUX -DLinux_intel $FDEFINES $DDM"
fi
FORTLOWT="$FORTLOW"
FORTRANT="$FORTRAN"
FORTHIGHT="$FORTHIGH"
FORTRANMNF="$FCOMP -c $FDEFINES "
CCMNF="icc -c -O1 -DLinux -DLINUX -DLinux_intel -Dport2egcs -I$MARC_SOURCE/marctoadams/mnf/include -D_LARGEFILE64_SOURCE"
if test $MPITYPE != none
then
if test $MPITYPE = hpmpi
then
LOAD="$MPI_ROOT/bin/$FCOMPMPI ${LOADOPTIONS} -L$MPI_ROOT/lib/$ARCHITECTURE $PROFILE $LINK_OPT -o "
LOADT="$MPI_ROOT/bin/$FCOMPMPI ${LOADOPTIONS} -L$MPI_ROOT/lib/$ARCHITECTURE $PROFILE $LINK_OPT -o "
fi
# Uncomment the following lines to turn on the tracer and commnet out the next 5 lines
# if test $MPITYPE = intelmpi
# then
# INCLUDEMPI="-I$MPI_ROOT/include -I$VT_ROOT/include"
# LOAD="$MPI_ROOT/bin/$FCOMPMPI $PROFILE $INCLUDEMPI -g -t=log $LINK_OPT -o "
# LOADT="$MPI_ROOT/bin/$FCOMPMPI $PROFILE $INCLUDEMPI -g -t=log $LINK_OPT -o "
# fi
if test $MPITYPE = intelmpi
then
LOAD="ifort $PROFILE $LINK_OPT -o "
LOADT="ifort $PROFILE $LINK_OPT -o "
fi
else
LOAD="$FCOMP $LINK_OPT -o "
LOADT="$FCOMP $LINK_OPT -o "
fi
if test "$MARC_DLL" = MARC_DLL
then
FORTLOW="$FORTLOW -fpp -fPIC"
FORTRAN="$FORTRAN -fpp -fPIC"
FORTHIGH="$FORTHIGH -fpp -fPIC"
FORTRANMNF="$FORTRANMNF -fpp -fPIC"
CC="$CC -fPIC"
CCMNF="$CCMNF -fPIC"
LINK_EXE_MARC="-L$MARC_LIB -lmarc -L$MARC_LIB_SHARED -lguide -lpthread"
LINK_MARC_DLL="-shared -fPIC"
LOAD_DLL=$LOAD
LOADT_DLL=$LOADT
EXT_DLL="so"
fi
if test "$AEM_DLL" -eq 1
then
FORTLOW="$FORTLOW -fpp -fPIC"
FORTRAN="$FORTRAN -fpp -fPIC"
FORTHIGH="$FORTHIGH -fpp -fPIC"
FORTRANMNF="$FORTRANMNF -fpp -fPIC"
CC="$CC -fPIC"
CCMNF="$CCMNF -fPIC"
LINK_EXE_MARC="-L$MARC_LIB -lmarc -L$MARC_LIB_SHARED -lguide"
LINK_MARC_DLL="-shared -fPIC"
LOAD_DLL=$LOAD
LOADT_DLL=$LOADT
EXT_DLL="so"
fi
XLIBS="-L/usr/X11/lib -lX11 "
#
# define archive and ranlib syntax
#
ARC="ar rvl"
ARD="ar dvl"
ARX="ar xl"
RAN=""
#
# choose which libraries you want to use ( e.g. blas )
#
if test "$VKISOLVER" = VKI
then
VKISOLVERLIBS="$MARC_LIB/vkisolver.a"
else
VKISOLVERLIBS=
fi
if test "$CASISOLVER" = CASI
then
CASISOLVERLIBS="$CASILIB_DIR/libmarccasi.a $CASILIB_DIR/libcasi.a"
else
CASISOLVERLIBS=
fi
MF2SOLVERLIBS=
if test "$MF2SOLVER" = MF2PARALLEL
then
MF2SOLVERLIBS="$MARC_LIB/mf2parallel/libseq.a \
$MARC_LIB/mf2parallel/libsym.a \
$MARC_LIB/mf2parallel/libmet.a \
$MARC_LIB/mf2parallel/libmf2.a \
$MARC_LIB/mf2parallel/libgauss.a \
$MARC_LIB/mf2parallel/libmf2.a \
$MARC_LIB/mf2parallel/libgauss.a \
$MARC_LIB/mf2parallel/libnum.a \
$MARC_LIB/mf2parallel/libutl.a \
$MARC_LIB/mf2parallel/libr8.a \
$MARC_LIB/mf2parallel/libz.a "
fi
if test "$MUMPSSOLVER" = MUMPS
then
MUMPSSOLVERLIBS="$MUMPSLIB_DIR/libmumps.a"
if test $MPITYPE = none
then
MUMPSSOLVERLIBS2=
echo hello > /dev/null
fi
if test $MPITYPE = intelmpi
then
MUMPSSOLVERLIBS="$MUMPSLIB_DIR/libmumps_intelmpi.a"
if test "$MARC_INTEGER_SIZE" = "i4" ; then
MUMPSSOLVERLIBS2=" $MARC_MKL/libmkl_blacs_intelmpi_lp64.a "
else
MUMPSSOLVERLIBS2=" $MARC_MKL/libmkl_blacs_intelmpi_ilp64.a "
fi
fi
if test $MPITYPE = hpmpi
then
MUMPSSOLVERLIBS="$MUMPSLIB_DIR/libmumps_hpmpi.a"
if test "$MARC_INTEGER_SIZE" = "i4" ; then
MUMPSSOLVERLIBS2=" $MARC_MKL/libmkl_blacs_intelmpi_lp64.a"
else
MUMPSSOLVERLIBS2=" $MARC_MKL/libmkl_blacs_intelmpi_ilp64.a"
fi
fi
else
MUMPSSOLVERLIBS=
MUMPSSOLVERLIBS2=
fi
if test "$BCSGPUSOLVER" = BCSGPU
then
BCSSOLVERLIBS="${BCSLIB_DIR}/bcsgpulib.a "
MARCCUDALIBS1="-L${BCSLIB_DIR}/cuda_dummy -lmarccuda "
MARCCUDALIBS2="-L${BCSLIB_DIR}/cuda -lmarccuda "
MARCCUDALIBS=$MARCCUDALIBS1
else
BCSSOLVERLIBS="${MARC_LIB}/bcslib.a "
fi
if test "$AEM_DLL" -eq 1
then
BCSSOLVERLIBS=
fi
if test "$MARC_INTEGER_SIZE" = "i4" ; then
MKLLIB="$MARC_MKL/libmkl_scalapack_lp64.a -Wl,--start-group $MARC_MKL/libmkl_intel_lp64.a $MARC_MKL/libmkl_intel_thread.a $MARC_MKL/libmkl_core.a $MARC_MKL/libmkl_blacs_intelmpi_lp64.a $MUMPSSOLVERLIBS2 -Wl,--end-group"
else
MKLLIB="$MARC_MKL/libmkl_scalapack_ilp64.a -Wl,--start-group $MARC_MKL/libmkl_intel_ilp64.a $MARC_MKL/libmkl_intel_thread.a $MARC_MKL/libmkl_core.a $MARC_MKL/libmkl_blacs_intelmpi_ilp64.a $MUMPSSOLVERLIBS2 -Wl,--end-group"
fi
SECLIBS="-L$MARC_LIB -llapi"
SOLVERLIBS="${BCSSOLVERLIBS} ${VKISOLVERLIBS} ${CASISOLVERLIBS} ${MF2SOLVERLIBS} \
$MKLLIB -L$MARC_MKL -liomp5 \
$MARC_LIB/blas_src.a ${ACSI_LIB}/ACSI_MarcLib.a $KDTREE2_LIB/kdtree2.a $HDF5_LIB"
SOLVERLIBS_DLL=${SOLVERLIBS}
if test "$AEM_DLL" -eq 1
then
SOLVERLIBS_DLL="$MKLLIB -L$MARC_MKL -liomp5 $MARC_LIB/blas_src.a"
fi
MRCLIBS="$MARC_LIB/clib.a ${CASISOLVERLIBS}"
MRCLIBSPAR="$MARC_LIB/clib.a"
STUBS="$MARC_LIB/stubs.a "
MNFLIBS="$MARC_LIB/libmnf.a"
MDUSER="$MARC_LIB/md_user.a"
if test "X$MARC_SIMUFACT" != "X"
then
SFLIB="-L$SFMATDIR -lMBA_Grain"
else
SFLIB=" "
fi
OPENMP="-qopenmp"
if test "$AEM_DLL" -eq 1
then
LOAD_DLL=$LOAD
OPENMP=
LIBMNF=
OPENSSL=NONE
fi
SYSLIBS=" $OPENMP -lpthread -cxxlib"
# Uncomment the following lines to turn on the trace and comment out the next 4 lines
# if test $MPITYPE = intelmpi
# then
# SYSLIBS="-L${VT_ROOT}/lib -lVT -ldwarf -lelf -lm -lpthread \
# -L${MPI_ROOT}/lib64 -lmpi -lmpiif -lmpigi -lrt"
# fi
if test $MPITYPE = intelmpi
then
SYSLIBS="-L${MPI_ROOT}/lib -lmpi_mt -lmpifort -lrt $OPENMP -threads -lpthread -cxxlib"
fi
SYSLIBSPAR=" "
MARC_DLL_CODES="runmarc.f"
BLAS_SRC="dzero.f icopy.f izero.f"
if test "$_OEM_NASTRAN" -ne 0
then
if test "$MARC_INTEGER_SIZE" = "i4" ; then
BLAS_SRC="$BLAS_SRC dsctr.f zsctr.f dzasum.f daxpyi.f zaxpyi.f dgthr.f zgthr.f"
else
BLAS_SRC="ALL"
fi
fi
LOW_OPT_CODES="are163.f contro.f ndext.f omarc.f omarca.f omarcb.f omarcc.f \
omars.f fixbc.f triang.f bet049.f norst3.f eldata.f \
elec*.f elct*.f fmeig.f oada00.f ogeig.f updtrbe2.f cycrota.f \
cordef.f ogpk.f ogtan.f eldam.f formrbe3.f \
inertie.f em_sso072.f cn_fol3d_qpatch6.f cosim_begin.f"
if test "$MARC_INTEGER_SIZE" = "i8" ; then
LOW_OPT_CODES="$LOW_OPT_CODES bbcseg.f"
fi
HIGH_OPT_CODES="dpsmsa1.f dpsmsa2.f dpsmsa3.f dpsmsa4.f dpsmsa5.f dpsmsa6.f \
dpsmsa7.f dpsmsa8.f dpsmsa9.f dpsmsa10.f dpsmsa11.f dpsmsa12.f \
dpsmsa13.f dpsmsa14.f dpsmsa15.f dpsmsa16.f dpsmsah.f tpsmsah.f cn_qsort4_11.f \
prei11.f prei12.f prei31.f prei32.f prei41.f prei42.f prei61.f prei62.f \
prei1n.f prei2n.f cgfullnts1.f cgfullnts2.f cg1n.f cg2n.f cg3n.f \
cg4n.f cg5n.f cg6n.f cgnn.f sortab.f sortab1.f triann1.f preinv_nts.f "
MAXNUM=1000000

View File

@ -0,0 +1,788 @@
#
# General definitions for the Marc 2019 FP1 version
#
# EM64T
#
# Linux RedHat 7.1, 7.3 / SuSE 11 SP4, 12 SP1
#
# 64 bit MPI version
#
# Intel(R) Fortran Intel(R) 64 Compiler XE for applications
# running on Intel(R) 64, Version 17.0.5.239 Build 20170817
#
# Intel(R) C Intel(R) 64 Compiler XE for applications
# running on Intel(R) 64, Version 17.0.5.239 Build 20170817
#
# To check the O/S level, type:
# uname -a
#
# Distributed parallel MPI libraries:
# 1) HP MPI 2.3
# To check the mpi version, type:
# mpirun -version
# 2) Intel MPI 2017.1
# To check the mpi version, type:
# mpiexec.hydra -version
#
# To check the Compiler level, type using the compiler
# installation path:
# ifort -V
# icc -V
#
# REMARKS : This file contains the definitions of variables used during
# compilation loading and use of the MARC programmes . The
# current machine type is identified by means of the variable
# MACHINE , defined below.
#
#
# MPI_ROOT: root directory in which mpi shared libraries, etc. are located
# DIRJOB : directory in which spawned jobs should look for Marc input
# MPI_ARCH: system architecture
# MPI_EPATH: path where executable resides
#
REVISION="VERSION, BUILD"
HOSTNAME=`hostname`
# find available memory in Mbyte on the machine
# can be set explicitly
MEMLIMIT=`free -m | awk '/Mem:/ {print $2}'`
# set _OEM_NASTRAN to 1 for MD Nastran build
# override _OEM_NASTRAN setting with MARC_MD_NASTRAN environment variable
_OEM_NASTRAN="${MARC_MD_NASTRAN:-0}"
# uncomment the following line for an autoforge build
#AUTOFORGE=1
AUTOFORGE=0
export AUTOFORGE
# integer size
if test "$MARC_INTEGER_SIZE" = "" ; then
INTEGER_PATH=
else
INTEGER_PATH=/$MARC_INTEGER_SIZE
fi
FCOMP=ifort
INTELPATH="/opt/intel/compilers_and_libraries_2017/linux"
# find the root directory of the compiler installation:
# - if ifort is found in $PATH, then the root directory is derived
# from the path to ifort
# - if ifort is not found in $PATH, the root directory is assumed
# to be $INTELPATH and the directory in which ifort is found is
# added to $PATH
FCOMPPATH=`which "$FCOMP" 2>/dev/null`
if test -n "$FCOMPPATH"; then
# derive the root directory from $FCOMPPATH
FCOMPROOT="${FCOMPPATH%/bin/intel64/$FCOMP}"
if test "$FCOMPROOT" = "$FCOMPPATH"; then
FCOMPROOT="${FCOMPPATH%/bin/$FCOMP}"
fi
if test "$FCOMPROOT" = "$FCOMPPATH"; then
FCOMPROOT=
fi
elif test -d "$INTELPATH"; then
# check for compiler in $INTELPATH
if test -d "$INTELPATH/bin/intel64" -a \
-x "$INTELPATH/bin/intel64/$FCOMP" ; then
FCOMPROOT="$INTELPATH"
PATH="$INTELPATH/bin/intel64:$PATH"
elif test -d "$INTELPATH/bin" -a \
-x "$INTELPATH/bin/$FCOMP"; then
FCOMPROOT="$INTELPATH"
PATH="$INTELPATH/bin:$PATH"
else
FCOMPROOT=
fi
else
FCOMPROOT=
fi
# AEM
if test "$MARCDLLOUTDIR" = ""; then
DLLOUTDIR="$MARC_LIB"
else
DLLOUTDIR="$MARCDLLOUTDIR"
fi
# settings for MKL
if test "$IMKLDIR" = ""; then
MARC_MKL="$FCOMPROOT/mkl/lib/intel64"
else
MARC_MKL=$IMKLDIR/lib/intel64
fi
#
# settings for Metis
#
METIS="-I$METIS_SOURCE/include"
METISLIBS="$METISLIB_DIR/libmarcddm.a $METISLIB_DIR/libmarcmetis.a "
#
# settings for MPI
#
# RCP and RSH are used for parallel network runs
# replace with similar commands like rsh if needed
RCP=/usr/bin/scp
RSH=/usr/bin/ssh
#
MPI_DEFAULT=intelmpi
MPI_OTHER=hpmpi
MPITYPE=$MPI_DEFAULT
if test $AUTOFORGE
then
if test $AUTOFORGE = 1
then
MPITYPE=none
fi
fi
# overrule MPITYPE setting with environmental variable MARC_MPITYPE
if test $MARC_MPITYPE
then
MPITYPE=$MARC_MPITYPE
fi
# always set MPITYPE to none for MD Nastran
if test "$_OEM_NASTRAN" -ne 0
then
MPITYPE=none
fi
# Edit following lines to build with GPGPU version of BCS Solver for
# NVIDIA platforms
#BCSGPUSOLVER=NONE
BCSGPUSOLVER=BCSGPU
# Edit following lines to set the openssl library
if test "$OPENSSL" != "NONE"
then
OPENSSL_LIB="$MARC_LIB/libcrypto.a"
fi
OPENSSL_INCLUDE=-I"$MARC_OPENSSL/include/"
MARCHDF_HDF=HDF
#MARCHDF_HDF=NONE
if test "$MARCHDF_HDF" = "HDF"; then
HDF_INCLUDE="-I$MARC_HDF/include"
HDF_LIBS="$MARC_LIB/libhdf5_fortran.so.100 $MARC_LIB/libhdf5.so.101"
fi
# activate contact component build if flagged
AEM_DLL=0
if test "$AEM_BUILD" = "ON" ; then
AEM_DLL=1
LINK_MARC_DLL="-shared -fPIC"
EXT_DLL="so"
MPITYPE=none
MPI_OTHER=
BCSGPUSOLVER=NONE
MUMPSSOLVER=NONE
CASISOLVER=NONE
fi
SOLVERFLAGS=
if test "$BCSGPUSOLVER" = BCSGPU
then
SOLVERFLAGS="$SOLVERFLAGS -DBCSGPU -DCUDA"
BCS_DIR=bcsgpusolver
else
BCS_DIR=bcssolver
fi
#
# settings for MPI
#
DDM=
if test $MPITYPE != none
then
if test $MPITYPE = hpmpi
then
FCOMPMPI=mpif90
export MPI_ROOT=$MARC_HPMPI
export MPI_REMSH=$RSH
export MPI_F77=$FCOMP
ARCHITECTURE=linux_amd64
DDM="-I$MPI_ROOT/include/64 -DDDM -DHPMPI"
MPI_CLEAN=
export MPI_EPATH=$MARC_BIN
export LD_LIBRARY_PATH=$MPI_ROOT/lib/$ARCHITECTURE:$MARC_LIB:$MARC_LIB_SHARED:$LD_LIBRARY_PATH
export MPIHPSPECIAL="-e MPI_FLAGS=E,T,y1"
# Below line is moved in run_marc file
# export MPIHPSPECIAL="$MPIHPSPECIAL -e LD_LIBRARY_PATH=$LD_LIBRARY_PATH"
export MPIHPSPECIAL="$MPIHPSPECIAL -e BINDIR=$MARC_BIN"
if test -n "$MSC_LICENSE_FILE"
then
export MPIHPSPECIAL="$MPIHPSPECIAL -e MSC_LICENSE_FILE=$MSC_LICENSE_FILE"
fi
if test -n "$LM_LICENSE_FILE"
then
export MPIHPSPECIAL="$MPIHPSPECIAL -e LM_LICENSE_FILE=$LM_LICENSE_FILE"
fi
export MPIHPSPECIAL="$MPIHPSPECIAL -e MPI_LIC_CHECKER=$MPI_ROOT/bin/licensing/amd64_s8/lichk.x"
RUN_JOB2="$MPI_ROOT/bin/mpirun ${MPIRUNOPTIONS} -prot -f "
RUN_JOB1="$MPI_ROOT/bin/mpirun ${MPIRUNOPTIONS} -prot -w $MPIHPSPECIAL -np "
RUN_JOB0=
fi
if test $MPITYPE = intelmpi
then
INTELMPI_VERSION=HYDRA
FCOMPMPI=mpiifort
MPI_ROOT=$MARC_INTELMPI
DDM="-I${MPI_ROOT}/include -DDDM"
PATH=$MPI_ROOT/bin:$PATH
export PATH
LD_LIBRARY_PATH=$MPI_ROOT/lib:$LD_LIBRARY_PATH
export LD_LIBRARY_PATH
if test $INTELMPI_VERSION = HYDRA
then
RUN_JOB1="${MPI_ROOT}/bin/mpiexec.hydra -genvall -n "
RUN_JOB2="${MPI_ROOT}/bin/mpiexec.hydra -genvall"
else
RUN_JOB1="${MPI_ROOT}/bin/mpiexec -n "
RUN_JOB2="${MPI_ROOT}/bin/mpiexec -configfile "
fi
RUN_JOB0=
MPI_CLEAN=
MPI_EPATH=$MARC_BIN
MPIR_HOME=$MPI_ROOT
MPICH_F77=$FCOMP
MPICH_F77LINKER=$FCOMP
export MPI_ROOT MPI_EPATH MPIR_HOME MPICH_F77 MPICH_F77LINKER
I_MPI_PIN_DOMAIN=node
export I_MPI_PIN_DOMAIN
fi
else
MPI_ROOT=$MARC_DUMMYMPI
export MPI_ROOT=$MARC_DUMMYMPI
DDM="-I$MPI_ROOT/include"
fi
#
# variables for the "maintain" script
#
MACHINENAME=LINUX
MACHINE64BIT=yes
MACHINE=Linux_EM64T
DEV=/dev/tape
GETLOG="whoami"
CLEAR="clear"
MY_UNAME=`uname -a`
# Edit following 2 lines to build with VKI Solver
#VKISOLVER=VKI
VKISOLVER=NONE
# Edit following 2 lines to build with CASI Solver
CASISOLVER=CASI
if test "$MARC_CASISOLVER" = "NONE" ; then
CASISOLVER=NONE
fi
#CASISOLVER=NONE
# Edit following 2 lines to build with MF2 Solver
MF2SOLVER=NONE
#MF2SOLVER=SERIAL
#MF2SOLVER=MF2PARALLEL
# Edit following lines to build with Intel(c) Multithreaded solver (PARDISO)
#INTELSOLVER=NONE
INTELSOLVER=PARDISO
# Edit following lines to build with MUMPS
if test "$MARC_INTEGER_SIZE" = "i4" ; then
#MUMPSSOLVER=NONE
MUMPSSOLVER=MUMPS
else
#MUMPSSOLVER=NONE
MUMPSSOLVER=MUMPS
fi
# Edit following 2 lines to build MARC dynamic shared library
MARC_DLL=MARC_DLL
MARC_DLL=NONE
# always set VKISOLVER, CASISOLVER, BCSGPUSOLVER, and MARC_DLL to NONE for MD Nastran
if test "$_OEM_NASTRAN" -ne 0
then
VKISOLVER=NONE
CASISOLVER=NONE
MF2SOLVER=NONE
INTELSOLVER=NONE
MUMPSSOLVER=NONE
BCSGPUSOLVER=NONE
MARC_DLL=NONE
fi
if test "$AEM_DLL" -eq 1
then
VKISOLVER=NONE
CASISOLVER=NONE
MF2SOLVER=NONE
INTELSOLVER=NONE
MUMPSSOLVER=NONE
BCSGPUSOLVER=NONE
fi
#
# define Fortran and C compile syntax
#
if test "$VKISOLVER" = VKI
then
SOLVERFLAGS="$SOLVERFLAGS -DVKI"
fi
if test "$CASISOLVER" = CASI
then
SOLVERFLAGS="$SOLVERFLAGS -DCASI"
fi
if test "$MF2SOLVER" = MF2PARALLEL
then
SOLVERFLAGS="$SOLVERFLAGS -DMF2PARALLEL"
fi
if test "$MF2SOLVER" = MF2SERIAL
then
SOLVERFLAGS="$SOLVERFLAGS -DMF2SERIAL"
fi
if test "$INTELSOLVER" = PARDISO
then
SOLVERFLAGS="$SOLVERFLAGS -DPARDISO"
fi
if test "$MUMPSSOLVER" = MUMPS
then
SOLVERFLAGS="$SOLVERFLAGS -DMUMPS"
fi
if test "$MARC_DLL" = MARC_DLL
then
SOLVERFLAGS="$SOLVERFLAGS -DMARC_DLL"
fi
LINK_OPT=
DEBUG_OPT=
C_DEBUG_OPT=
#Uncomment following line to build Marc in debuggable mode
MARCDEBUG=
#MARCDEBUG="ON"
if test "$MARCDEBUG" = "ON"
then
LINK_OPT="-debug -traceback"
DEBUG_OPT="-debug -traceback"
C_DEBUG_OPT="-debug -traceback"
fi
MARCCHECK=
#MARCCHECK="ON"
if test "$MARCCHECK" = "ON"
then
DEBUG_OPT="$DEBUG_OPT -fpe0 -fp-stack-check -check all -ftrapuv "
C_DEBUG_OPT="$C_DEBUG_OPT -fp-stack-check -check-uninit -Wformat -ftrapuv "
fi
MARCCODECOV=
#MARCCODECOV="ON"
MARCCODEPROF=
#MARCCODEPROF="ON"
if test "$MARC_INTEGER_SIZE" = "i4" ; then
I8FFLAGS=
I8DEFINES=
I8CDEFINES=
else
I8FFLAGS="-i8"
I8DEFINES="-DI64"
I8CDEFINES="-U_DOUBLE -D_SINGLE"
fi
MTHREAD=OPENMP
if test "$MARC_OPENMP" = "NONE" ; then
MTHREAD=NONE
fi
#MTHREAD=NONE
if test "$_OEM_NASTRAN" -ne 0
then
MTHREAD=NONE
fi
if test "$AEM_DLL" -eq 1
then
MTHREAD=NONE
CASISOLVER=NONE
VKISOLVER=NONE
MF2SOLVER=NONE
INTELSOLVER=NONE
BCSGPUSOLVER=NONE
OPENSSL_LIB=
MARC_DLL=NONE
METISLIBS=
fi
OMP_COMPAT=NO
OMP_COMPAT=YES
if test "$MTHREAD" = "NONE"
then
OMP_COMPAT=NO
fi
CDEFINES=
FDEFINES=
if test "$_OEM_NASTRAN" -ne 0
then
CDEFINES="$CDEFINES -D_OEM_NASTRAN"
FDEFINES="$FDEFINES -D_OEM_NASTRAN"
fi
FDEFINES="$FDEFINES -D_IMPLICITNONE"
if test "$_OEM_NASTRAN" -eq 0
then
FDEFINES="$FDEFINES -DMKL -DOPENMP"
fi
if test "$OMP_COMPAT" = "YES"
then
FDEFINES="$FDEFINES -DOMP_COMPAT"
fi
# -D_MSCMARC
FDEFINES="$FDEFINES -D_MSCMARC $DEBUG_OPT $MARC_SIMUFACT"
CDEFINES="$CDEFINES -D_MSCMARC $C_DEBUG_OPT $I8CDEFINES"
if test "$AEM_DLL" -eq 1
then
FDEFINES="$FDEFINES -D_AEMNL -DAAA"
CDEFINES="$CDEFINES -D_AEMNL -DAAA"
fi
CINCL="-I$MARC_SOURCE/mdsrc -I$MARC_SOURCE/csource $METIS -I$LAPI_IMPORTS/common/include"
if test "$_OEM_NASTRAN" -ne 0
then
CINCL="$CINCL -I../../include"
fi
CC_OPT=
if test "$MTHREAD" = "OPENMP"
then
CC_OPT=" $CC_OPT -qopenmp"
fi
CC="icc -c $CC_OPT -O1 $I8DEFINES -DLinux -DLINUX -DLinux_intel $CDEFINES $CINCL $SOLVERFLAGS $OPENSSL_INCLUDE "
CCLOW="icc -c $CC_OPT -O0 $I8DEFINES -DLinux -DLINUX -DLinux_intel $CDEFINES $CINCL $SOLVERFLAGS $OPENSSL_INCLUDE "
CCHIGH="icc -c $CC_OPT -O3 $I8DEFINES -DLinux -DLINUX -DLinux_intel $CDEFINES $CINCL $SOLVERFLAGS $OPENSSL_INCLUDE "
if test "$MARCDEBUG" = "ON"
then
CC="icc -c $CC_OPT -DLinux $I8DEFINES -DLINUX -DLinux_intel $CDEFINES $CINCL $SOLVERFLAGS $OPENSSL_INCLUDE "
CCLOW="icc $CC_OPT -c -DLinux $I8DEFINES -DLINUX -DLinux_intel $CDEFINES $CINCL $SOLVERFLAGS $OPENSSL_INCLUDE "
CCHIGH="icc $CC_OPT -c -DLinux $I8DEFINES -DLINUX -DLinux_intel $CDEFINES $CINCL $SOLVERFLAGS $OPENSSL_INCLUDE "
fi
LOAD_CC="icc $CC_OPT -O1 -DLinux -DLINUX -DLinux_intel"
CCT="$CC"
CCTLOW="$CCLOW"
CCTHIGH="$CCHIGH"
#PROFILE="-Mprof=func"
#PROFILE="-Mprof=lines"
#PROFILE="-Mprof=func,mpi"
PROFILE=
#PROFILE="-init=snan,arrays -CB -traceback -fpe0 -fp-stack-check -check all -check uninit -ftrapuv"
if test "$MARCCODECOV" = "ON"
then
PROFILE="-prof-gen=srcpos"
fi
if test "$MARCCODEPROF" = "ON"
then
PROFILE=" $PROFILE -pg"
fi
FORT_OPT="-c -assume byterecl -safe_cray_ptr -mp1 -WB -fp-model source"
if test "$MTHREAD" = "OPENMP"
then
FORT_OPT=" $FORT_OPT -qopenmp"
if test "$OMP_COMPAT" = "YES"
then
FORT_OPT=" $FORT_OPT -qopenmp-threadprivate=compat"
fi
else
# FORT_OPT=" $FORT_OPT -auto "
FORT_OPT=" $FORT_OPT -save -zero"
fi
if test "$MARCHDF_HDF" = "HDF"; then
FORT_OPT="$FORT_OPT -DMARCHDF_HDF=$MARCHDF_HDF $HDF_INCLUDE"
fi
FORTLOW="$FCOMP $FORT_OPT $PROFILE -O0 $I8FFLAGS -I$MARC_SOURCE/common \
$MUMPS_INCLUDE $I8DEFINES -DLinux -DLINUX -DLinux_intel $FDEFINES $DDM $SOLVERFLAGS -I$KDTREE2_MOD"
FORTRAN="$FCOMP $FORT_OPT $PROFILE -O1 $I8FFLAGS -I$MARC_SOURCE/common \
$MUMPS_INCLUDE $I8DEFINES -DLinux -DLINUX -DLinux_intel $FDEFINES $DDM $SOLVERFLAGS -I$KDTREE2_MOD"
FORTHIGH="$FCOMP $FORT_OPT $PROFILE -fno-alias -O3 $I8FFLAGS -I$MARC_SOURCE/common \
$MUMPS_INCLUDE $I8DEFINES -DLinux -DLINUX -DLinux_intel $FDEFINES $DDM $SOLVERFLAGS -I$KDTREE2_MOD"
FORTNA="$FCOMP $FORT_OPT -fno-alias -O3 $I8FFLAGS -I$MARC_SOURCE/common \
$MUMPS_INCLUDE $I8DEFINES -DLinux -DLINUX -DLinux_intel $FDEFINES $DDM"
# for compiling free form f90 files. high opt, integer(4)
FORTF90="$FCOMP -c -O3"
if test "$MARCDEBUG" = "ON"
then
FORTLOW="$FCOMP $FORT_OPT $PROFILE $I8FFLAGS -I$MARC_SOURCE/common \
$MUMPS_INCLUDE $I8DEFINES -DLinux -DLINUX -DLinux_intel $FDEFINES $DDM $SOLVERFLAGS -I$KDTREE2_MOD"
FORTRAN="$FCOMP $FORT_OPT $PROFILE $I8FFLAGS -I$MARC_SOURCE/common \
$MUMPS_INCLUDE $I8DEFINES -DLinux -DLINUX -DLinux_intel $FDEFINES $DDM $SOLVERFLAGS -I$KDTREE2_MOD"
FORTHIGH="$FCOMP $FORT_OPT $PROFILE -fno-alias $I8FFLAGS -I$MARC_SOURCE/common \
$MUMPS_INCLUDE $I8DEFINES -DLinux -DLINUX -DLinux_intel $FDEFINES $DDM $SOLVERFLAGS -I$KDTREE2_MOD"
FORTNA="$FCOMP $FORT_OPT -fno-alias $I8FFLAGS -I$MARC_SOURCE/common \
$MUMPS_INCLUDE $I8DEFINES -DLinux -DLINUX -DLinux_intel $FDEFINES $DDM"
fi
FORTLOWT="$FORTLOW"
FORTRANT="$FORTRAN"
FORTHIGHT="$FORTHIGH"
FORTRANMNF="$FCOMP -c $FDEFINES "
CCMNF="icc -c -O1 -DLinux -DLINUX -DLinux_intel -Dport2egcs -I$MARC_SOURCE/marctoadams/mnf/include -D_LARGEFILE64_SOURCE"
if test $MPITYPE != none
then
if test $MPITYPE = hpmpi
then
LOAD="$MPI_ROOT/bin/$FCOMPMPI ${LOADOPTIONS} -L$MPI_ROOT/lib/$ARCHITECTURE $PROFILE $LINK_OPT -o "
LOADT="$MPI_ROOT/bin/$FCOMPMPI ${LOADOPTIONS} -L$MPI_ROOT/lib/$ARCHITECTURE $PROFILE $LINK_OPT -o "
fi
# Uncomment the following lines to turn on the tracer and commnet out the next 5 lines
# if test $MPITYPE = intelmpi
# then
# INCLUDEMPI="-I$MPI_ROOT/include -I$VT_ROOT/include"
# LOAD="$MPI_ROOT/bin/$FCOMPMPI $PROFILE $INCLUDEMPI -g -t=log $LINK_OPT -o "
# LOADT="$MPI_ROOT/bin/$FCOMPMPI $PROFILE $INCLUDEMPI -g -t=log $LINK_OPT -o "
# fi
if test $MPITYPE = intelmpi
then
LOAD="ifort $PROFILE $LINK_OPT -o "
LOADT="ifort $PROFILE $LINK_OPT -o "
fi
else
LOAD="$FCOMP $LINK_OPT -o "
LOADT="$FCOMP $LINK_OPT -o "
fi
if test "$MARC_DLL" = MARC_DLL
then
FORTLOW="$FORTLOW -fpp -fPIC"
FORTRAN="$FORTRAN -fpp -fPIC"
FORTHIGH="$FORTHIGH -fpp -fPIC"
FORTRANMNF="$FORTRANMNF -fpp -fPIC"
CC="$CC -fPIC"
CCMNF="$CCMNF -fPIC"
LINK_EXE_MARC="-L$MARC_LIB -lmarc -L$MARC_LIB_SHARED -lguide -lpthread"
LINK_MARC_DLL="-shared -fPIC"
LOAD_DLL=$LOAD
LOADT_DLL=$LOADT
EXT_DLL="so"
fi
if test "$AEM_DLL" -eq 1
then
FORTLOW="$FORTLOW -fpp -fPIC"
FORTRAN="$FORTRAN -fpp -fPIC"
FORTHIGH="$FORTHIGH -fpp -fPIC"
FORTRANMNF="$FORTRANMNF -fpp -fPIC"
CC="$CC -fPIC"
CCMNF="$CCMNF -fPIC"
LINK_EXE_MARC="-L$MARC_LIB -lmarc -L$MARC_LIB_SHARED -lguide"
LINK_MARC_DLL="-shared -fPIC"
LOAD_DLL=$LOAD
LOADT_DLL=$LOADT
EXT_DLL="so"
fi
XLIBS="-L/usr/X11/lib -lX11 "
#
# define archive and ranlib syntax
#
ARC="ar rvl"
ARD="ar dvl"
ARX="ar xl"
RAN=""
#
# choose which libraries you want to use ( e.g. blas )
#
if test "$VKISOLVER" = VKI
then
VKISOLVERLIBS="$MARC_LIB/vkisolver.a"
else
VKISOLVERLIBS=
fi
if test "$CASISOLVER" = CASI
then
CASISOLVERLIBS="$CASILIB_DIR/libmarccasi.a $CASILIB_DIR/libcasi.a"
else
CASISOLVERLIBS=
fi
MF2SOLVERLIBS=
if test "$MF2SOLVER" = MF2PARALLEL
then
MF2SOLVERLIBS="$MARC_LIB/mf2parallel/libseq.a \
$MARC_LIB/mf2parallel/libsym.a \
$MARC_LIB/mf2parallel/libmet.a \
$MARC_LIB/mf2parallel/libmf2.a \
$MARC_LIB/mf2parallel/libgauss.a \
$MARC_LIB/mf2parallel/libmf2.a \
$MARC_LIB/mf2parallel/libgauss.a \
$MARC_LIB/mf2parallel/libnum.a \
$MARC_LIB/mf2parallel/libutl.a \
$MARC_LIB/mf2parallel/libr8.a \
$MARC_LIB/mf2parallel/libz.a "
fi
if test "$MUMPSSOLVER" = MUMPS
then
MUMPSSOLVERLIBS="$MUMPSLIB_DIR/libmumps.a"
if test $MPITYPE = none
then
MUMPSSOLVERLIBS2=
echo hello > /dev/null
fi
if test $MPITYPE = intelmpi
then
MUMPSSOLVERLIBS="$MUMPSLIB_DIR/libmumps_intelmpi.a"
if test "$MARC_INTEGER_SIZE" = "i4" ; then
MUMPSSOLVERLIBS2=" $MARC_MKL/libmkl_blacs_intelmpi_lp64.a "
else
MUMPSSOLVERLIBS2=" $MARC_MKL/libmkl_blacs_intelmpi_ilp64.a "
fi
fi
if test $MPITYPE = hpmpi
then
MUMPSSOLVERLIBS="$MUMPSLIB_DIR/libmumps_hpmpi.a"
if test "$MARC_INTEGER_SIZE" = "i4" ; then
MUMPSSOLVERLIBS2=" $MARC_MKL/libmkl_blacs_intelmpi_lp64.a"
else
MUMPSSOLVERLIBS2=" $MARC_MKL/libmkl_blacs_intelmpi_ilp64.a"
fi
fi
else
MUMPSSOLVERLIBS=
MUMPSSOLVERLIBS2=
fi
if test "$BCSGPUSOLVER" = BCSGPU
then
BCSSOLVERLIBS="${BCSLIB_DIR}/bcsgpulib.a "
MARCCUDALIBS1="-L${BCSLIB_DIR}/cuda_dummy -lmarccuda "
MARCCUDALIBS2="-L${BCSLIB_DIR}/cuda -lmarccuda "
MARCCUDALIBS=$MARCCUDALIBS1
else
BCSSOLVERLIBS="${MARC_LIB}/bcslib.a "
fi
if test "$AEM_DLL" -eq 1
then
BCSSOLVERLIBS=
fi
if test "$MARC_INTEGER_SIZE" = "i4" ; then
MKLLIB="$MARC_MKL/libmkl_scalapack_lp64.a -Wl,--start-group $MARC_MKL/libmkl_intel_lp64.a $MARC_MKL/libmkl_intel_thread.a $MARC_MKL/libmkl_core.a $MUMPSSOLVERLIBS2 -Wl,--end-group"
else
MKLLIB="$MARC_MKL/libmkl_scalapack_ilp64.a -Wl,--start-group $MARC_MKL/libmkl_intel_ilp64.a $MARC_MKL/libmkl_intel_thread.a $MARC_MKL/libmkl_core.a $MUMPSSOLVERLIBS2 -Wl,--end-group"
fi
SECLIBS="-L$MARC_LIB -llapi"
SOLVERLIBS="${BCSSOLVERLIBS} ${VKISOLVERLIBS} ${CASISOLVERLIBS} ${MF2SOLVERLIBS} \
$MKLLIB -L$MARC_MKL -liomp5 \
$MARC_LIB/blas_src.a ${ACSI_LIB}/ACSI_MarcLib.a $KDTREE2_LIB/kdtree2.a $HDF_LIBS"
SOLVERLIBS_DLL=${SOLVERLIBS}
if test "$AEM_DLL" -eq 1
then
SOLVERLIBS_DLL="$MKLLIB -L$MARC_MKL -liomp5 $MARC_LIB/blas_src.a"
fi
MRCLIBS="$MARC_LIB/clib.a ${CASISOLVERLIBS}"
MRCLIBSPAR="$MARC_LIB/clib.a"
STUBS="$MARC_LIB/stubs.a "
MNFLIBS="$MARC_LIB/libmnf.a"
MDUSER="$MARC_LIB/md_user.a"
if test "X$MARC_SIMUFACT" != "X"
then
SFLIB="-L$SFMATDIR -lMBA_Grain"
else
SFLIB=" "
fi
OPENMP="-qopenmp"
if test "$AEM_DLL" -eq 1
then
LOAD_DLL=$LOAD
OPENMP=
LIBMNF=
OPENSSL=NONE
fi
SYSLIBS=" $OPENMP -lpthread -shared-intel -cxxlib"
# Uncomment the following lines to turn on the trace and comment out the next 4 lines
# if test $MPITYPE = intelmpi
# then
# SYSLIBS="-L${VT_ROOT}/lib -lVT -ldwarf -lelf -lm -lpthread \
# -L${MPI_ROOT}/lib64 -lmpi -lmpiif -lmpigi -lrt"
# fi
if test $MPITYPE = intelmpi
then
SYSLIBS="-L${MPI_ROOT}/lib -lmpi_mt -lmpifort -lrt $OPENMP -threads -lpthread -shared-intel -cxxlib"
fi
SYSLIBSPAR=" "
MARC_DLL_CODES="runmarc.f"
BLAS_SRC="dzero.f icopy.f izero.f"
if test "$_OEM_NASTRAN" -ne 0
then
if test "$MARC_INTEGER_SIZE" = "i4" ; then
BLAS_SRC="$BLAS_SRC dsctr.f zsctr.f dzasum.f daxpyi.f zaxpyi.f dgthr.f zgthr.f"
else
BLAS_SRC="ALL"
fi
fi
LOW_OPT_CODES="are163.f contro.f ndext.f omarc.f omarca.f omarcb.f omarcc.f \
omars.f fixbc.f triang.f bet049.f norst3.f eldata.f \
elec*.f elct*.f fmeig.f oada00.f ogeig.f updtrbe2.f cycrota.f \
cordef.f ogpk.f ogtan.f eldam.f formrbe3.f \
inertie.f em_sso072.f cn_fol3d_qpatch6.f cosim_begin.f"
if test "$MARC_INTEGER_SIZE" = "i8" ; then
LOW_OPT_CODES="$LOW_OPT_CODES bbcseg.f"
fi
HIGH_OPT_CODES="dpsmsa1.f dpsmsa2.f dpsmsa3.f dpsmsa4.f dpsmsa5.f dpsmsa6.f \
dpsmsa7.f dpsmsa8.f dpsmsa9.f dpsmsa10.f dpsmsa11.f dpsmsa12.f \
dpsmsa13.f dpsmsa14.f dpsmsa15.f dpsmsa16.f dpsmsah.f tpsmsah.f cn_qsort4_11.f \
prei11.f prei12.f prei31.f prei32.f prei41.f prei42.f prei61.f prei62.f \
prei1n.f prei2n.f cgfullnts1.f cgfullnts2.f cg1n.f cg2n.f cg3n.f \
cg4n.f cg5n.f cg6n.f cgnn.f sortab.f sortab1.f triann1.f preinv_nts.f "
MAXNUM=1000000

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#!/bin/sh
# This script opens a window running an editor.
# The command to invoke the editor is specified during DAMASK installation
%EDITOR% $*

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@ -0,0 +1,18 @@
#!/bin/sh
# This script opens a window running an editor. The default window is an
# xterm, and the default editor is vi. These may be customized.
dir=
for d in /usr/bin /usr/bin/X11; do
if test -x "$d/xterm"; then
dir="$d"
break
fi
done
if test -z "$dir"; then
echo "$0: Could not find xterm"
exit 1
fi
"$dir/xterm" -T "vi $*" -n "vi $*" -e vi $*

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@ -0,0 +1,8 @@
#!/bin/sh
if [ "$1" = "" ]; then
echo "usage: $0 job_name"
exit 1
fi
echo STOP > $1.cnt

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@ -0,0 +1,8 @@
#!/bin/sh
if [ "$1" = "" ]; then
echo "usage: $0 job_name"
exit 1
fi
echo STOP > $1.cnt

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@ -0,0 +1,8 @@
#!/bin/sh
if [ "$1" = "" ]; then
echo "usage: $0 job_name"
exit 1
fi
echo STOP > $1.cnt

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@ -0,0 +1,8 @@
#!/bin/sh
if [ "$1" = "" ]; then
echo "usage: $0 job_name"
exit 1
fi
echo STOP > $1.cnt

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#!/bin/sh
#
# The exit status of this script is read by Mentat.
# Normal exit status is 0.
#
DIR=/nethome/f.roters/temp/msc/marc2019.1
if test $MARCDIR1
then
DIR=$MARCDIR1
fi
if test -z "$DIR"; then
REALCOM="`ls -l $0 |awk '{ print $NF; }'`"
DIRSCRIPT=`dirname $REALCOM`
case $DIRSCRIPT in
\/*)
;;
*)
DIRSCRIPT=`pwd`/$DIRSCRIPT
;;
esac
. $DIRSCRIPT/getarch
DIR="$MENTAT_MARCDIR"
fi
SRCEXT=.f
SRCEXTC=.F
RSTEXT=.t08
PSTEXT=.t19
PSTEXTB=.t16
VWFCEXT=.vfs
slv=$1
version=$2
ndom_fea_solver=$3
ndom_preprocessor=$4
hostfile=$5
compat=$6
job=$7
srcfile=$8
srcmeth=$9
shift 9 # cannot use $10, $11, ...
restart=$1
postfile=$2
viewfactorsfile=$3
copy_datfile="-ci $4"
copy_postfile="-cr $5"
scr_dir=$6
dcoup=$7
assem_recov_nthread=$8
nthread=$9
shift 9 # cannot use $10, $11, ...
nsolver=$1
mode=$2
gpu=$3
if [ "$slv" != "" -a "$slv" != "marc" -a "$slv" != "datfit" ]; then
slv="-iam sfm"
fi
if [ "$slv" == "marc" ]; then
slv=""
fi
if [ "$slv" == "datfit" ]; then
slv="-iam datfit"
fi
if [ "$ndom_fea_solver" != "" -a "$ndom_fea_solver" != "1" ]; then
nprocds="-nprocds $ndom_fea_solver"
else
nprocd=""
if [ "$ndom_preprocessor" != "" -a "$ndom_preprocessor" != "1" ]; then
nprocd="-nprocd $ndom_preprocessor"
else
nprocd=""
fi
fi
if [ "$srcfile" != "" -a "$srcfile" != "-" ]; then
srcfile=`echo $srcfile | sed "s/$SRCEXT$//" | sed "s/$SRCEXTC$//"`
case "$srcmeth" in
-)
srcfile="-u $srcfile"
;;
compsave)
srcfile="-u $srcfile -save y"
;;
runsaved)
srcfile="-prog $srcfile"
;;
esac
else
srcfile=""
fi
if [ "$restart" != "" -a "$restart" != "-" ]; then
restart=`echo $restart | sed "s/$RSTEXT$//"`
restart="-r $restart"
else
restart=""
fi
if [ "$postfile" != "" -a "$postfile" != "-" ]; then
postfile=`echo $postfile | sed "s/$PSTEXT$//"`
postfile=`echo $postfile | sed "s/$PSTEXTB$//"`
postfile="-pid $postfile"
else
postfile=""
fi
if [ "$viewfactorsfile" != "" -a "$viewfactorsfile" != "-" ]; then
viewfactorsfile=`echo $viewfactorsfile | sed "s/$VWFCEXT$//"`
viewfactorsfile="-vf $viewfactorsfile"
else
viewfactorsfile=""
fi
if [ "$hostfile" != "" -a "$hostfile" != "-" ]; then
hostfile="-ho $hostfile"
else
hostfile=""
fi
if [ "$compat" != "" -a "$compat" != "-" ]; then
compat="-co $compat"
else
compat=""
fi
if [ "$scr_dir" != "" -a "$scr_dir" != "-" ]; then
scr_dir="-sd $scr_dir"
else
scr_dir=""
fi
if [ "$dcoup" != "" -a "$dcoup" != "0" ]; then
dcoup="-dcoup $dcoup"
else
dcoup=""
fi
if [ "$assem_recov_nthread" != "" -a "$assem_recov_nthread" != "1" ]; then
assem_recov_nthread="-nthread_elem $assem_recov_nthread"
else
assem_recov_nthread=""
fi
if [ "$nthread" != "" -a "$nthread" != "0" -a "$nthread" != "1" ]; then
nthread="-nthread $nthread"
else
nthread=""
fi
if [ "$nsolver" != "" -a "$nsolver" != "0" ]; then
nsolver="-nsolver $nsolver"
else
nsolver=""
fi
case "$mode" in
4) mode="-mo i4" ;;
8) mode="-mo i8" ;;
*) mode= ;;
esac
if [ "$gpu" != "" -a "$gpu" != "-" ]; then
gpu="-gpu $gpu"
else
gpu=""
fi
rm -f $job.cnt
rm -f $job.sts
rm -f $job.out
rm -f $job.log
# To prevent a mismatch with the python version used by the solver
# do *not* prepend $MENTAT_INSTALL_DIR/python/bin to environment variable PATH
# unset environment variables PYTHONHOME and PYTHONPATH
unset PYTHONHOME
unset PYTHONPATH
"${DIR}/tools/run_marc" $slv -j $job -v n -b y $nprocds $nprocd \
$srcfile $restart $postfile $viewfactorsfile $hostfile \
$compat $copy_datfile $copy_postfile $scr_dir $dcoup \
$assem_recov_nthread $nthread $nsolver $mode $gpu > /dev/null 2>&1
sleep 1
exit 0

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@ -0,0 +1,191 @@
#!/bin/sh
#
# The exit status of this script is read by Mentat.
# Normal exit status is 0.
#
DIR=%INSTALLDIR%/marc%VERSION%
if test $MARCDIR1
then
DIR=$MARCDIR1
fi
if test -z "$DIR"; then
REALCOM="`ls -l $0 |awk '{ print $NF; }'`"
DIRSCRIPT=`dirname $REALCOM`
case $DIRSCRIPT in
\/*)
;;
*)
DIRSCRIPT=`pwd`/$DIRSCRIPT
;;
esac
. $DIRSCRIPT/getarch
DIR="$MENTAT_MARCDIR"
fi
SRCEXT=.f
SRCEXTC=.F
RSTEXT=.t08
PSTEXT=.t19
PSTEXTB=.t16
VWFCEXT=.vfs
slv=$1
version=$2
ndom_fea_solver=$3
ndom_preprocessor=$4
hostfile=$5
compat=$6
job=$7
srcfile=$8
srcmeth=$9
shift 9 # cannot use $10, $11, ...
restart=$1
postfile=$2
viewfactorsfile=$3
copy_datfile="-ci $4"
copy_postfile="-cr $5"
scr_dir=$6
dcoup=$7
assem_recov_nthread=$8
nthread=$9
shift 9 # cannot use $10, $11, ...
nsolver=$1
mode=$2
gpu=$3
if [ "$slv" != "" -a "$slv" != "marc" -a "$slv" != "datfit" ]; then
slv="-iam sfm"
fi
if [ "$slv" = "marc" ]; then
slv=""
fi
if [ "$slv" = "datfit" ]; then
slv="-iam datfit"
fi
if [ "$ndom_fea_solver" != "" -a "$ndom_fea_solver" != "1" ]; then
nprocds="-nprocds $ndom_fea_solver"
else
nprocd=""
if [ "$ndom_preprocessor" != "" -a "$ndom_preprocessor" != "1" ]; then
nprocd="-nprocd $ndom_preprocessor"
else
nprocd=""
fi
fi
if [ "$srcfile" != "" -a "$srcfile" != "-" ]; then
srcfile=`echo $srcfile | sed "s/$SRCEXT$//" | sed "s/$SRCEXTC$//"`
case "$srcmeth" in
-)
srcfile="-u $srcfile"
;;
compsave)
srcfile="-u $srcfile -save y"
;;
runsaved)
srcfile=${srcfile%.*}".marc"
srcfile="-prog $srcfile"
;;
esac
else
srcfile=""
fi
if [ "$restart" != "" -a "$restart" != "-" ]; then
restart=`echo $restart | sed "s/$RSTEXT$//"`
restart="-r $restart"
else
restart=""
fi
if [ "$postfile" != "" -a "$postfile" != "-" ]; then
postfile=`echo $postfile | sed "s/$PSTEXT$//"`
postfile=`echo $postfile | sed "s/$PSTEXTB$//"`
postfile="-pid $postfile"
else
postfile=""
fi
if [ "$viewfactorsfile" != "" -a "$viewfactorsfile" != "-" ]; then
viewfactorsfile=`echo $viewfactorsfile | sed "s/$VWFCEXT$//"`
viewfactorsfile="-vf $viewfactorsfile"
else
viewfactorsfile=""
fi
if [ "$hostfile" != "" -a "$hostfile" != "-" ]; then
hostfile="-ho $hostfile"
else
hostfile=""
fi
if [ "$compat" != "" -a "$compat" != "-" ]; then
compat="-co $compat"
else
compat=""
fi
if [ "$scr_dir" != "" -a "$scr_dir" != "-" ]; then
scr_dir="-sd $scr_dir"
else
scr_dir=""
fi
if [ "$dcoup" != "" -a "$dcoup" != "0" ]; then
dcoup="-dcoup $dcoup"
else
dcoup=""
fi
if [ "$assem_recov_nthread" != "" -a "$assem_recov_nthread" != "1" ]; then
assem_recov_nthread="-nthread_elem $assem_recov_nthread"
else
assem_recov_nthread=""
fi
if [ "$nthread" != "" -a "$nthread" != "0" -a "$nthread" != "1" ]; then
nthread="-nthread $nthread"
else
nthread=""
fi
if [ "$nsolver" != "" -a "$nsolver" != "0" ]; then
nsolver="-nsolver $nsolver"
else
nsolver=""
fi
case "$mode" in
4) mode="-mo i4" ;;
8) mode="-mo i8" ;;
*) mode= ;;
esac
if [ "$gpu" != "" -a "$gpu" != "-" ]; then
gpu="-gpu $gpu"
else
gpu=""
fi
rm -f $job.cnt
rm -f $job.sts
rm -f $job.out
rm -f $job.log
# To prevent a mismatch with the python version used by the solver
# do *not* prepend $MENTAT_INSTALL_DIR/python/bin to environment variable PATH
# unset environment variables PYTHONHOME and PYTHONPATH
unset PYTHONHOME
unset PYTHONPATH
"${DIR}/tools/run_damask_hmp" $slv -j $job -v n -b y $nprocds $nprocd \
$srcfile $restart $postfile $viewfactorsfile $hostfile \
$compat $copy_datfile $copy_postfile $scr_dir $dcoup \
$assem_recov_nthread $nthread $nsolver $mode $gpu > /dev/null 2>&1
sleep 1
exit 0

View File

@ -0,0 +1,191 @@
#!/bin/sh
#
# The exit status of this script is read by Mentat.
# Normal exit status is 0.
#
DIR=%INSTALLDIR%/marc%VERSION%
if test $MARCDIR1
then
DIR=$MARCDIR1
fi
if test -z "$DIR"; then
REALCOM="`ls -l $0 |awk '{ print $NF; }'`"
DIRSCRIPT=`dirname $REALCOM`
case $DIRSCRIPT in
\/*)
;;
*)
DIRSCRIPT=`pwd`/$DIRSCRIPT
;;
esac
. $DIRSCRIPT/getarch
DIR="$MENTAT_MARCDIR"
fi
SRCEXT=.f
SRCEXTC=.F
RSTEXT=.t08
PSTEXT=.t19
PSTEXTB=.t16
VWFCEXT=.vfs
slv=$1
version=$2
ndom_fea_solver=$3
ndom_preprocessor=$4
hostfile=$5
compat=$6
job=$7
srcfile=$8
srcmeth=$9
shift 9 # cannot use $10, $11, ...
restart=$1
postfile=$2
viewfactorsfile=$3
copy_datfile="-ci $4"
copy_postfile="-cr $5"
scr_dir=$6
dcoup=$7
assem_recov_nthread=$8
nthread=$9
shift 9 # cannot use $10, $11, ...
nsolver=$1
mode=$2
gpu=$3
if [ "$slv" != "" -a "$slv" != "marc" -a "$slv" != "datfit" ]; then
slv="-iam sfm"
fi
if [ "$slv" = "marc" ]; then
slv=""
fi
if [ "$slv" = "datfit" ]; then
slv="-iam datfit"
fi
if [ "$ndom_fea_solver" != "" -a "$ndom_fea_solver" != "1" ]; then
nprocds="-nprocds $ndom_fea_solver"
else
nprocd=""
if [ "$ndom_preprocessor" != "" -a "$ndom_preprocessor" != "1" ]; then
nprocd="-nprocd $ndom_preprocessor"
else
nprocd=""
fi
fi
if [ "$srcfile" != "" -a "$srcfile" != "-" ]; then
srcfile=`echo $srcfile | sed "s/$SRCEXT$//" | sed "s/$SRCEXTC$//"`
case "$srcmeth" in
-)
srcfile="-u $srcfile"
;;
compsave)
srcfile="-u $srcfile -save y"
;;
runsaved)
srcfile=${srcfile%.*}".marc"
srcfile="-prog $srcfile"
;;
esac
else
srcfile=""
fi
if [ "$restart" != "" -a "$restart" != "-" ]; then
restart=`echo $restart | sed "s/$RSTEXT$//"`
restart="-r $restart"
else
restart=""
fi
if [ "$postfile" != "" -a "$postfile" != "-" ]; then
postfile=`echo $postfile | sed "s/$PSTEXT$//"`
postfile=`echo $postfile | sed "s/$PSTEXTB$//"`
postfile="-pid $postfile"
else
postfile=""
fi
if [ "$viewfactorsfile" != "" -a "$viewfactorsfile" != "-" ]; then
viewfactorsfile=`echo $viewfactorsfile | sed "s/$VWFCEXT$//"`
viewfactorsfile="-vf $viewfactorsfile"
else
viewfactorsfile=""
fi
if [ "$hostfile" != "" -a "$hostfile" != "-" ]; then
hostfile="-ho $hostfile"
else
hostfile=""
fi
if [ "$compat" != "" -a "$compat" != "-" ]; then
compat="-co $compat"
else
compat=""
fi
if [ "$scr_dir" != "" -a "$scr_dir" != "-" ]; then
scr_dir="-sd $scr_dir"
else
scr_dir=""
fi
if [ "$dcoup" != "" -a "$dcoup" != "0" ]; then
dcoup="-dcoup $dcoup"
else
dcoup=""
fi
if [ "$assem_recov_nthread" != "" -a "$assem_recov_nthread" != "1" ]; then
assem_recov_nthread="-nthread_elem $assem_recov_nthread"
else
assem_recov_nthread=""
fi
if [ "$nthread" != "" -a "$nthread" != "0" -a "$nthread" != "1" ]; then
nthread="-nthread $nthread"
else
nthread=""
fi
if [ "$nsolver" != "" -a "$nsolver" != "0" ]; then
nsolver="-nsolver $nsolver"
else
nsolver=""
fi
case "$mode" in
4) mode="-mo i4" ;;
8) mode="-mo i8" ;;
*) mode= ;;
esac
if [ "$gpu" != "" -a "$gpu" != "-" ]; then
gpu="-gpu $gpu"
else
gpu=""
fi
rm -f $job.cnt
rm -f $job.sts
rm -f $job.out
rm -f $job.log
# To prevent a mismatch with the python version used by the solver
# do *not* prepend $MENTAT_INSTALL_DIR/python/bin to environment variable PATH
# unset environment variables PYTHONHOME and PYTHONPATH
unset PYTHONHOME
unset PYTHONPATH
"${DIR}/tools/run_damask_mp" $slv -j $job -v n -b y $nprocds $nprocd \
$srcfile $restart $postfile $viewfactorsfile $hostfile \
$compat $copy_datfile $copy_postfile $scr_dir $dcoup \
$assem_recov_nthread $nthread $nsolver $mode $gpu > /dev/null 2>&1
sleep 1
exit 0

View File

@ -0,0 +1,191 @@
#!/bin/sh
#
# The exit status of this script is read by Mentat.
# Normal exit status is 0.
#
DIR=%INSTALLDIR%/marc%VERSION%
if test $MARCDIR1
then
DIR=$MARCDIR1
fi
if test -z "$DIR"; then
REALCOM="`ls -l $0 |awk '{ print $NF; }'`"
DIRSCRIPT=`dirname $REALCOM`
case $DIRSCRIPT in
\/*)
;;
*)
DIRSCRIPT=`pwd`/$DIRSCRIPT
;;
esac
. $DIRSCRIPT/getarch
DIR="$MENTAT_MARCDIR"
fi
SRCEXT=.f
SRCEXTC=.F
RSTEXT=.t08
PSTEXT=.t19
PSTEXTB=.t16
VWFCEXT=.vfs
slv=$1
version=$2
ndom_fea_solver=$3
ndom_preprocessor=$4
hostfile=$5
compat=$6
job=$7
srcfile=$8
srcmeth=$9
shift 9 # cannot use $10, $11, ...
restart=$1
postfile=$2
viewfactorsfile=$3
copy_datfile="-ci $4"
copy_postfile="-cr $5"
scr_dir=$6
dcoup=$7
assem_recov_nthread=$8
nthread=$9
shift 9 # cannot use $10, $11, ...
nsolver=$1
mode=$2
gpu=$3
if [ "$slv" != "" -a "$slv" != "marc" -a "$slv" != "datfit" ]; then
slv="-iam sfm"
fi
if [ "$slv" = "marc" ]; then
slv=""
fi
if [ "$slv" = "datfit" ]; then
slv="-iam datfit"
fi
if [ "$ndom_fea_solver" != "" -a "$ndom_fea_solver" != "1" ]; then
nprocds="-nprocds $ndom_fea_solver"
else
nprocd=""
if [ "$ndom_preprocessor" != "" -a "$ndom_preprocessor" != "1" ]; then
nprocd="-nprocd $ndom_preprocessor"
else
nprocd=""
fi
fi
if [ "$srcfile" != "" -a "$srcfile" != "-" ]; then
srcfile=`echo $srcfile | sed "s/$SRCEXT$//" | sed "s/$SRCEXTC$//"`
case "$srcmeth" in
-)
srcfile="-u $srcfile"
;;
compsave)
srcfile="-u $srcfile -save y"
;;
runsaved)
srcfile=${srcfile%.*}".marc"
srcfile="-prog $srcfile"
;;
esac
else
srcfile=""
fi
if [ "$restart" != "" -a "$restart" != "-" ]; then
restart=`echo $restart | sed "s/$RSTEXT$//"`
restart="-r $restart"
else
restart=""
fi
if [ "$postfile" != "" -a "$postfile" != "-" ]; then
postfile=`echo $postfile | sed "s/$PSTEXT$//"`
postfile=`echo $postfile | sed "s/$PSTEXTB$//"`
postfile="-pid $postfile"
else
postfile=""
fi
if [ "$viewfactorsfile" != "" -a "$viewfactorsfile" != "-" ]; then
viewfactorsfile=`echo $viewfactorsfile | sed "s/$VWFCEXT$//"`
viewfactorsfile="-vf $viewfactorsfile"
else
viewfactorsfile=""
fi
if [ "$hostfile" != "" -a "$hostfile" != "-" ]; then
hostfile="-ho $hostfile"
else
hostfile=""
fi
if [ "$compat" != "" -a "$compat" != "-" ]; then
compat="-co $compat"
else
compat=""
fi
if [ "$scr_dir" != "" -a "$scr_dir" != "-" ]; then
scr_dir="-sd $scr_dir"
else
scr_dir=""
fi
if [ "$dcoup" != "" -a "$dcoup" != "0" ]; then
dcoup="-dcoup $dcoup"
else
dcoup=""
fi
if [ "$assem_recov_nthread" != "" -a "$assem_recov_nthread" != "1" ]; then
assem_recov_nthread="-nthread_elem $assem_recov_nthread"
else
assem_recov_nthread=""
fi
if [ "$nthread" != "" -a "$nthread" != "0" -a "$nthread" != "1" ]; then
nthread="-nthread $nthread"
else
nthread=""
fi
if [ "$nsolver" != "" -a "$nsolver" != "0" ]; then
nsolver="-nsolver $nsolver"
else
nsolver=""
fi
case "$mode" in
4) mode="-mo i4" ;;
8) mode="-mo i8" ;;
*) mode= ;;
esac
if [ "$gpu" != "" -a "$gpu" != "-" ]; then
gpu="-gpu $gpu"
else
gpu=""
fi
rm -f $job.cnt
rm -f $job.sts
rm -f $job.out
rm -f $job.log
# To prevent a mismatch with the python version used by the solver
# do *not* prepend $MENTAT_INSTALL_DIR/python/bin to environment variable PATH
# unset environment variables PYTHONHOME and PYTHONPATH
unset PYTHONHOME
unset PYTHONPATH
"${DIR}/tools/run_damask_lmp" $slv -j $job -v n -b y $nprocds $nprocd \
$srcfile $restart $postfile $viewfactorsfile $hostfile \
$compat $copy_datfile $copy_postfile $scr_dir $dcoup \
$assem_recov_nthread $nthread $nsolver $mode $gpu > /dev/null 2>&1
sleep 1
exit 0

File diff suppressed because it is too large Load Diff

File diff suppressed because it is too large Load Diff

439
src/marc/include/concom2019.1 vendored Normal file
View File

@ -0,0 +1,439 @@
! common block definition file taken from respective MSC.Marc release and reformated to free format
!***********************************************************************
!
! File: concom.cmn
!
! MSC.Marc include file
!
integer &
iacous, iasmbl, iautth, ibear, icompl, iconj, icreep, ideva, idyn, idynt,&
ielas, ielcma, ielect, iform, ifour, iharm, ihcps, iheat, iheatt, ihresp,&
ijoule, ilem, ilnmom, iloren, inc, incext, incsub, ipass, iplres, ipois,&
ipoist, irpflo, ismall, ismalt, isoil, ispect, ispnow, istore, iswep, ithcrp,&
itherm, iupblg, iupdat, jacflg, jel, jparks, largst, lfond, loadup, loaduq,&
lodcor, lovl, lsub, magnet, ncycle, newtnt, newton, noshr, linear, ivscpl,&
icrpim, iradrt, ipshft, itshr, iangin, iupmdr, iconjf, jincfl, jpermg, jhour,&
isolvr, jritz, jtable, jshell, jdoubl, jform, jcentr, imini, kautth, iautof,&
ibukty, iassum, icnstd, icnstt, kmakmas, imethvp, iradrte, iradrtp, iupdate, iupdatp,&
ncycnt, marmen , idynme, ihavca, ispf, kmini, imixex, largtt, kdoela, iautofg,&
ipshftp, idntrc, ipore, jtablm, jtablc, isnecma, itrnspo, imsdif, jtrnspo, mcnear,&
imech, imecht, ielcmat, ielectt, magnett, imsdift, noplas, jtabls, jactch, jtablth,&
kgmsto , jpzo, ifricsh, iremkin, iremfor, ishearp, jspf, machining, jlshell, icompsol,&
iupblgfo, jcondir, nstcrp, nactive, ipassref, nstspnt, ibeart, icheckmpc, noline, icuring,&
ishrink, ioffsflg, isetoff, ioffsetm,iharmt, inc_incdat, iautspc, ibrake, icbush, istream_input,&
iprsinp, ivlsinp, ifirst_time,ipin_m, jgnstr_glb, imarc_return,iqvcinp, nqvceid, istpnx, imicro1,&
iaxisymm, jbreakglue,iglstif, jfastasm,iwear, iwearcf, imixmeth, ielcmadyn, idinout, igena_meth,&
magf_meth, non_assumed, iredoboudry, ioffsz0,icomplt, mesh_dual, iactrp, mgnewton, iusedens,igsigd0,&
iaem, icosim, inodels, nlharm, iampini, iphasetr, inonlcl, inonlct, iforminp,ispecerror,&
icsprg, imol, imolt, idatafit,iharmpar, inclcase, imultifreq,init_elas
dimension :: ideva(60)
integer num_concom
parameter(num_concom=258)
common/marc_concom/&
iacous, iasmbl, iautth, ibear, icompl, iconj, icreep, ideva, idyn, idynt,&
ielas, ielcma, ielect, iform, ifour, iharm, ihcps, iheat, iheatt, ihresp,&
ijoule, ilem, ilnmom, iloren, inc, incext, incsub, ipass, iplres, ipois,&
ipoist, irpflo, ismall, ismalt, isoil, ispect, ispnow, istore, iswep, ithcrp,&
itherm, iupblg, iupdat, jacflg, jel, jparks, largst, lfond, loadup, loaduq,&
lodcor, lovl, lsub, magnet, ncycle, newtnt, newton, noshr, linear, ivscpl,&
icrpim, iradrt, ipshft, itshr, iangin, iupmdr, iconjf, jincfl, jpermg, jhour,&
isolvr, jritz, jtable, jshell, jdoubl, jform, jcentr, imini, kautth, iautof,&
ibukty, iassum, icnstd, icnstt, kmakmas, imethvp, iradrte, iradrtp, iupdate, iupdatp,&
ncycnt, marmen, idynme, ihavca, ispf, kmini, imixex, largtt, kdoela, iautofg,&
ipshftp, idntrc, ipore, jtablm, jtablc, isnecma, itrnspo, imsdif, jtrnspo, mcnear,&
imech, imecht, ielcmat, ielectt, magnett, imsdift, noplas, jtabls, jactch, jtablth,&
kgmsto , jpzo, ifricsh, iremkin, iremfor, ishearp, jspf, machining, jlshell, icompsol,&
iupblgfo, jcondir, nstcrp, nactive, ipassref, nstspnt, ibeart, icheckmpc, noline, icuring,&
ishrink, ioffsflg, isetoff, ioffsetm,iharmt, inc_incdat, iautspc, ibrake, icbush, istream_input,&
iprsinp, ivlsinp, ifirst_time,ipin_m, jgnstr_glb, imarc_return,iqvcinp, nqvceid, istpnx, imicro1,&
iaxisymm, jbreakglue,iglstif, jfastasm,iwear, iwearcf, imixmeth, ielcmadyn, idinout, igena_meth,&
magf_meth, non_assumed, iredoboudry, ioffsz0,icomplt, mesh_dual, iactrp, mgnewton, iusedens,igsigd0,&
iaem, icosim, inodels, nlharm, iampini, iphasetr, inonlcl, inonlct, iforminp,ispecerror,&
icsprg, imol, imolt, idatafit,iharmpar, inclcase, imultifreq,init_elas
!
! comments of variables:
!
! iacous Control flag for acoustic analysis. Input data.
! iacous=1 modal acoustic analysis.
! iacous=2 harmonic acoustic-structural analysis.
! iasmbl Control flag to indicate that operator matrix should be
! recalculated.
! iautth Control flag for AUTO THERM option.
! ibear Control flag for bearing analysis. Input data.
! icompl Control variable to indicate that a complex analysis is
! being performed. Either a Harmonic analysis with damping,
! or a harmonic electro-magnetic analysis. Input data.
! iconj Flag for EBE conjugate gradient solver (=solver 1, retired)
! Also used for VKI iterative solver.
! icreep Control flag for creep analysis. Input data.
! ideva(60) - debug print out flag
! 1 print element stiffness matrices, mass matrix
! 2 output matrices used in tying
! 3 force the solution of a nonpositive definite matrix
! 4 print info of connections to each node
! 5 info of gap convergence, internal heat generated, contact
! touching and separation
! 6 nodal value array during rezoning
! 7 tying info in CONRAD GAP option, fluid element numbers in
! CHANNEL option
! 8 output incremental displacements in local coord. system
! 9 latent heat output
! 10 stress-strain in local coord. system
! 11 additional info on interlaminar stress
! 12 output right hand side and solution vector
! 13 info of CPU resources used and memory available on NT
! 14 info of mesh adaption process, 2D outline information
! info of penetration checking for remeshing
! save .fem files after afmesh3d meshing
! 15 surface energy balance flag
! 16 print info regarding pyrolysis
! 17 print info of "streamline topology"
! 18 print mesh data changes after remeshing
! 19 print material flow stress data read in from *.mat file
! if unit flag is on, print out flow stress after conversion
! 20 print information on table input
! 21 print out information regarding kinematic boundary conditions
! 22 print out information regarding dist loads, point loads, film
! and foundations
! 23 print out information about automatic domain decomposition
! 24 print out iteration information in SuperForm status report file
! 25 print out information for ablation
! 26 print out information for films - Table input
! 27 print out the tying forces
! 28 print out for CASI solver, convection,
! 29 DDM single file debug printout
! 30 print out cavity debug info
! 31 print out welding related info
! 32 prints categorized DDM memory usage
! 33 print out the cutting info regarding machining feature
! 34 print out the list of quantities which can be defined via a table
! and for each quantity the supported independent variables
! 35 print out detailed coupling region info
! 36 print out solver debug info level 1 (Least Detailed)
! 37 print out solver debug info level 1 (Medium Detailed)
! 38 print out solver debug info level 1 (Very Detailed)
! 39 print detailed memory allocation info
! 40 print out marc-adams debug info
! 41 output rezone mapping post file for debugging
! 42 output post file after calling oprofos() for debugging
! 43 debug printout for vcct
! 44 debug printout for progressive failure
! 45 print out automatically generated midside node coordinates (arecrd)
! 46 print out message about routine and location, where the ibort is raised (ibort_inc)
! 47 print out summary message of element variables on a
! group-basis after all the automatic changes have been
! made (em_ellibp)
! 48 Automatically generate check results based on max and min vals.
! These vals are stored in the checkr file, which is inserted
! into the *dat file by the generate_check_results script from /marc/tools
! 49 Automatically generate check results based on the real calculated values
! at the sppecified check result locations.
! These vals are stored in the checkr file, which is inserted
! into the *dat file by the update_check_results script from /marc/tools
! 50 generate a file containing the resistance or capacity matrix;
! this file can be used to compare results with a reference file
! 51 print out detailed information for segment-to-segment contact
! 52 print out detailed relative displacement information
! for uniaxial sliding contact
! 53 print out detailed sliding direction information for
! uniaxial sliding contact
! 54 print out detailed information for edges attached to a curve
! 55 print information related to viscoelasticity calculations
! 56 print out detailed information for element coloring for multithreading
! 57 print out extra overheads due to multi-threading.
! These overhead includes (i) time and (ii) memory.
! The memory report will be summed over all the children.
!
!
! 58 debug output for ELSTO usage
!
! idyn Control flag for dynamics. Input data.
! 1 = eigenvalue extraction and / or modal superposition
! 2 = Newmark Beta and Single Step Houbolt (ssh with idynme=1)
! 3 = Houbolt
! 4 = Central difference
! 5 = Newer central difference
! idynt Copy of idyn at begining of increment
! ielas Control flag for ELASTIC analysis. Input data.
! Set by user or automatically turned on by Fourier option.
! Implies that each load case is treated separately.
! In Adaptive meshing analysis , forces re-analysis until
! convergence obtained.
! Also seriously misused to indicate no convergence.
! = 1 elastic option with fourier analysis
! = 2 elastic option without fourier analysis
! =-1 no convergence in recycles or max # increments reached
! Set to 1 if ELASTIC or SUBSTRUC parameter cards are used,
! or if fourier option is used.
! Then set to 2 if not fourier analysis.
! ielcma Control flag for electromagnetic analysis. Input data.
! ielcma = 1 Harmonic formulation
! ielcma = 2 Transient formulation
! ielect Control flag for electrostatic option. Input data.
! iform Control flag indicating that contact will be performed.
! ifour Control flag for Fourier analysis.
! 0 = Odd and even terms.
! 1 = symmetric (cosine) terms
! 2 = antisymmetric (sine) terms.
! iharm Control flag to indicate that a harmonic analysis will
! be performed. May change between passes.
! ihcps Control flag for coupled thermal - stress analysis.
! iheat Control flag for heat transfer analysis. Input data.
! iheatt Permanent control flag for heat transfer analysis.
! Note in coupled analysis iheatt will remain as one,
! but iheat will be zero in stress pass.
! ihresp Control flag to indicate to perform a harmonic subincrement.
! ijoule Control flag for Joule heating.
! ilem Control flag to determin which vector is to be transformed.
! Control flag to see where one is:
! ilem = 1 - elem.f
! ilem = 2 - initst.f
! ilem = 3 - pressr.f
! ilem = 3 - fstif.f
! ilem = 4 - jflux.f
! ilem = 4 - strass.f
! ilem = 5 - mass.f
! ilem = 5 - osolty.f
! ilnmom Control flag for soil - pore pressure calculation. Input data.
! ilnmom = 0 - perform only pore pressure calculation.
! = 1 - couples pore pressure - displacement analysis
! iloren Control flag for DeLorenzi J-Integral evaluation. Input data.
! inc Increment number.
! incext Control flag indicating that currently working on a
! subincrement.
! Could be due to harmonics , damping component (bearing),
! stiffness component (bearing), auto therm creep or
! old viscoplaticity
! incsub Sub-increment number.
! ipass Control flag for which part of coupled analysis.
! ipass = -1 - reset to base values
! ipass = 0 - do nothing
! ipass = 1 - stress part
! ipass = 2 - heat transfer part
! iplres Flag indicating that either second matrix is stored.
! dynamic analysis - mass matrix
! heat transfer - specific heat matrix
! buckle - initial stress stiffness
! ipois Control flag indicating Poisson type analysis
! ipois = 1 for heat transfer
! = 1 for heat transfer part of coupled
! = 1 for bearing
! = 1 for electrostatic
! = 1 for magnetostatic
! ipoist Permanent copy of ipois. In coupled analysis , ipois = 0
! in stress portion, yet ipoist will still =1.
! irpflo global flag for rigid plastic flow analysis
! = 1 eularian formulation
! = 2 regular formulation; rigid material present in the analysis
! ismall control flag to indicate small displacement analysis. input data.
! ismall = 0 - large disp included.
! ismall = 1 - small displacement.
! the flag is changing between passes.
! ismalt permanent copy of ismall . in heat transfer portion of
! coupled analysis ismall =0 , but ismalt remains the same.
! isoil control flag indicating that soil / pore pressure
! calculation . input data.
! ispect control flag for response spectrum calculation. input data.
! ispnow control flag to indicate to perform a spectrum response
! calculation now.
! istore store stresses flag.
! istore = 0 in elem.f and if first pass of creep
! convergence checking in ogetst.f
! or harmonic analysis or thruc.f if not
! converged.
! iswep control flag for eigenvalue analysis.
! iswep=1 - go do extraction process
! ithcrp control flag for auto therm creep option. input data.
! itherm control flag for either temperature dependent material
! properties and/or thermal loads.
! iupblg control flag for follower force option. input data.
! iupdat control flag for update lagrange option for current element.
! jacflg control flag for lanczos iteration method. input data.
! jel control flag indicating that total load applied in
! increment, ignore previous solution.
! jel = 1 in increment 0
! = 1 if elastic or fourier
! = 1 in subincrements with elastic and adaptive
! jparks control flag for j integral by parks method. input data.
! largst control flag for finite strain plasticity. input data.
! lfond control variable that indicates if doing elastic
! foundation or film calculation. influences whether
! this is volumetric or surface integration.
! loadup control flag that indicates that nonlinearity occurred
! during previous increment.
! loaduq control flag that indicates that nonlinearity occurred.
! lodcor control flag for switching on the residual load correction.
! notice in input stage lodcor=0 means no loadcor,
! after omarc lodcor=1 means no loadcor
! lovl control flag for determining which "overlay" is to
! be called from ellib.
! lovl = 1 omarc
! = 2 oaread
! = 3 opress
! = 4 oasemb
! = 5 osolty
! = 6 ogetst
! = 7 oscinc
! = 8 odynam
! = 9 opmesh
! = 10 omesh2
! = 11 osetz
! = 12 oass
! = 13 oincdt
! = 14 oasmas
! = 15 ofluas
! = 16 ofluso
! = 17 oshtra
! = 18 ocass
! = 19 osoltc
! = 20 orezon
! = 21 otest
! = 22 oeigen
! lsub control variable to determine which part of element
! assembly function is being done.
! lsub = 1 - no longer used
! = 2 - beta*
! = 3 - cons*
! = 4 - ldef*
! = 5 - posw*
! = 6 - theta*
! = 7 - tmarx*
! = 8 - geom*
! magnet control flag for magnetostatic analysis. input data.
! ncycle cycle number. accumulated in osolty.f
! note first time through oasemb.f , ncycle = 0.
! newtnt control flag for permanent copy of newton.
! newton iteration type. input data.
! newton : = 1 full newton raphson
! 2 modified newton raphson
! 3 newton raphson with strain correct.
! 4 direct substitution
! 5 direct substitution followed by n.r.
! 6 direct substitution with line search
! 7 full newton raphson with secant initial stress
! 8 secant method
! 9 full newton raphson with line search
! noshr control flag for calculation interlaminar shears for
! elements 22,45, and 75. input data.
!ees
!
! jactch = 1 or 2 if elements are activated or deactivated
! = 3 if elements are adaptively remeshed or rezoned
! = 0 normally / reset to 0 when assembly is done
! ifricsh = 0 call to fricsh in otest not needed
! = 1 call to fricsh (nodal friction) in otest needed
! iremkin = 0 remove deactivated kinematic boundary conditions
! immediately - only in new input format (this is default)
! = 1 remove deactivated kinematic boundary conditions
! gradually - only in new input format
! iremfor = 0 remove force boundary conditions immediately -
! only in new input format (this is default)
! = 1 remove force boundary conditions gradually -
! only in new input format (this is default)
! ishearp set to 1 if shear panel elements are present in the model
!
! jspf = 0 not in spf loadcase
! > 0 in spf loadcase (jspf=1 during first increment)
! machining = 1 if the metal cutting feature is used, for memory allocation purpose
! = 0 (default) if no metal cutting feature required
!
! jlshell = 1 if there is a shell element in the mesh
! icompsol = 1 if there is a composite solid element in the mesh
! iupblgfo = 1 if follower force for point loads
! jcondir = 1 if contact priority option is used
! nstcrp = 0 (default) steady state creep flag (undocumented feature.
! if not 0, turns off special ncycle = 0 code in radial.f)
! nactive = number of active passes, if =1 then it's not a coupled analysis
! ipassref = reference ipass, if not in a multiphysics pass ipass=ipassref
! icheckmpc = value of mpc-check parameter option
! noline = set to 1 in osolty if no line seacrh should be done in ogetst
! icuring = set to 1 if the curing is included for the heat transfer analysis.
! ishrink = set to 1 if shrinkage strain is included for mechancial analysis.
! ioffsflg = 1 for small displacement beam/shell offsets
! = 2 for large displacement beam/shell offsets
! isetoff = 0 - do not apply beam/shell offsets
! = 1 - apply beam/shell offsets
! ioffsetm = min. value of offset flag
! iharmt = 1 global flag if a coupled analysis contains an harmonic pass
! inc_incdat = flag to record increment number of a new loadcase in incdat.f
! iautspc = flag for AutoSPC option
! ibrake = brake squeal in this increment
! icbush = set to 1 if cbush elements present in model
! istream_input = set to 1 for streaming input calling Marc as library
! iprsinp = set to 1 if pressure input, introduced so other variables
! such as h could be a function of pressure
! ivlsinp = set to 1 if velocity input, introduced so other variables
! such as h could be a function of velocity
! ipin_m = # of beam element with PIN flag
! jgnstr_glb = global control over pre or fast integrated composite shells
! imarc_return = Marc return flag for streaming input control
! iqvcimp = if non-zero, then the number of QVECT boundary conditions
! nqvceid = number of QVECT boundary conditions, where emisivity/absorbtion id entered
! istpnx = 1 if to stop at end of increment
! imicro1 = 1 if micro1 interface is used
! iaxisymm = set to 1 if axisymmetric analysis
! jbreakglue = set to 1 if breaking glued option is used
! iglstif = 1 if ddm and global stiffness matrix formed (sgi solver 6 or solver9)
! jfastasm = 1 do fast assembly using SuperForm code
! iwear = set to 1 if wear model, set to 2 if wear model and coordinates updated
! iwearcf = set to 1 to store nodal coefficient of friction for wear calculation
! imixmeth = set=1 then use nonlinear mixture material - allocate memory
! ielcmadyn = flag for magnetodynamics
! 0 - electromagnetics using newmark beta
! 1 - transient magnetics using backward euler
! idinout = flag to control if inside out elements should be deactivated
! igena_meth = 0 - generalized alpha parameters depend on whether or not contact
! is flagged (dynamic,7)
! 10 - generalized alpha parameters are optimized for a contact
! analysis (dynamic,8)
! 11 - generalized alpha parameters are optimized for an analysis
! without contact (dynamic,8)
! magf_meth = - Method to compute force in magnetostatic - structural
! = 1 - Virtual work method based on finite difference for the force computation
! = 2 - Maxwell stress tensor
! = 3 - Virtual work method based on local derivative for the force computation
! non_assumed = 1 no assumed strain formulation (forced)
! iredoboudry set to 1 if contact boundary needs to be recalculated
! ioffsz0 = 1 if composite are used with reference position.ne.0
! icomplt = 1 global flag if a coupled analysis contains an complex pass
! mesh_dual = 1 two independent meshes are used in magnetodynamic/thermal/structural
! one for magnetodynamic and the other for the remaining passes
! iactrp = 1 in an analysis with global remeshing, include inactive
! rigid bodies on post file
! mgnewton = 1 Use full Newton Raphson iteration for magnetostatic pass
!
! iusedens > 0 if mass density is used in the analysis (dynamics, mass dependent loading)
! igsigd0 = 1 set varselem(igsigd) to zero in next oasemb
! iaem = 1 if marc is called from aem (0 - off - default)
! icosim = 1 if marc is used in co-simulation software (ADAMS-MARC)
! inodels = 1 nodal integration elements 239/240/241 present
! nlharm = 0 harmonic subincrements are linear
! = 1 harmonic subincrements are nonlinear
! iampini = 0 amplitude of previous harmonic subinc is initial estimate (default)
! = 1 zero amplitude is initial estimate
! iphasetr = 1 phase transformation material model is used
! iforminp flag indicating that contact is switched on via the CONTACT
! option in the input file (as opposed to the case that contact
! is switched on internally due to cyclic symmetry or model
! section creation)
! ispecerror = a+10*b (only for spectrum response analysis with missing mass option)
! a=0 or a=1 (modal shape with non-zero shift)
! b=0 or b=1 (recover with new assembly of stiffness matrix)
! icsprg = set to 1 if spring elements present in model
! imol Control flag for molecualr diffusion pass
! imolt Permanent control flag for molecualr diffusion pass
! Note in coupled analysis imolt will remain as one,
! but imol will be zero in stress pass or thermal pass.
! idatafit = run Marc to fit parameters
! iharmpar = 1 if harmonic parameter option is used
! inclcase load case increment use for cyclic plasticity data fitting
! imultifreq flag to indicate how many harmonic magnetodynamic passes are computed in coupled
! magnetodynamic/thermal(/structural) analyses.
! 0 or 1 one pass 2 two passes 3 or more is not supported
! init_elas use elastic stress-strain law as the material tangent for
! the first cycle of an increment
!
!***********************************************************************
!$omp threadprivate(/marc_concom/)
!!

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! common block definition file taken from respective MSC.Marc release and reformated to free format
!***********************************************************************
!
! File: creeps.cmn
!
! MSC.Marc include file
!
real(pReal) cptim,timinc,timinc_p,timinc_s,timincm,timinc_a,timinc_b
integer icfte,icfst,icfeq,icftm,icetem,mcreep,jcreep,icpa,icftmp,icfstr,&
icfqcp,icfcpm,icrppr,icrcha,icpb,iicpmt,iicpa
real(pReal) time_beg_lcase,time_beg_inc,fractol,time_beg_pst
real(pReal) fraction_donn,timinc_ol2
!
integer num_creepsr,num_creepsi,num_creeps2r
parameter(num_creepsr=7)
parameter(num_creepsi=17)
parameter(num_creeps2r=6)
common/marc_creeps/cptim,timinc,timinc_p,timinc_s,timincm,timinc_a,timinc_b,icfte,icfst,&
icfeq,icftm,icetem,mcreep,jcreep,icpa,icftmp,icfstr,icfqcp,icfcpm,icrppr,icrcha,icpb,iicpmt,iicpa
common/marc_creeps2/time_beg_lcase,time_beg_inc,fractol,time_beg_pst,fraction_donn,timinc_ol2
!
! cptim Total time at begining of increment.
! timinc Incremental time for this step.
! icfte Local copy number of slopes of creep strain rate function
! versus temperature. Is -1 if exponent law used.
! icfst Local copy number of slopes of creep strain rate function
! versus equivalent stress. Is -1 if exponent law used.
! icfeq Local copy number of slopes of creep strain rate function
! versus equivalent strain. Is -1 if exponent law used.
! icftm Local copy number of slopes of creep strain rate function
! versus time. Is -1 if exponent law used.
! icetem Element number that needs to be checked for creep convergence
! or, if negative, the number of elements that need to
! be checked. In the latter case the elements to check
! are stored in ielcp.
! mcreep Maximum nuber of iterations for explicit creep.
! jcreep Counter of number of iterations for explicit creep
! procedure. jcreep must be .le. mcreep
! icpa Pointer to constant in creep strain rate expression.
! icftmp Pointer to temperature dependent creep strain rate data.
! icfstr Pointer to equivalent stress dependent creep strain rate data.
! icfqcp Pointer to equivalent creep strain dependent creep strain
! rate data.
! icfcpm Pointer to equivalent creep strain rate dependent
! creep strain rate data.
! icrppr Permanent copy of icreep
! icrcha Control flag for creep convergence checking , if set to
! 1 then testing on absolute change in stress and creep
! strain, not relative testing. Input data.
! icpb Pointer to storage of material id cross reference numbers.
! iicpmt
! iicpa Pointer to constant in creep strain rate expression
!
! time_beg_lcase time at the beginning of the current load case
! time_beg_inc time at the beginning of the current increment
! fractol fraction of loadcase or increment time when we
! consider it to be finished
! time_beg_pst time corresponding to first increment to be
! read in from thermal post file for auto step
!
! timinc_old Time step of the previous increment
!
!***********************************************************************
!!$omp threadprivate(/marc_creeps/)
!!$omp threadprivate(/marc_creeps2/)
!!