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! Copyright 2011 Max-Planck-Institut für Eisenforschung GmbH
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!
! This file is part of DAMASK,
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! the Düsseldorf Advanced MAterial Simulation Kit.
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!
! DAMASK is free software: you can redistribute it and/or modify
! it under the terms of the GNU General Public License as published by
! the Free Software Foundation, either version 3 of the License, or
! (at your option) any later version.
!
! DAMASK is distributed in the hope that it will be useful,
! but WITHOUT ANY WARRANTY; without even the implied warranty of
! MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
! GNU General Public License for more details.
!
! You should have received a copy of the GNU General Public License
! along with DAMASK. If not, see <http://www.gnu.org/licenses/>.
!
!##############################################################
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!* $Id$
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!***************************************
!* Module: CRYSTALLITE *
!***************************************
!* contains: *
!* - _init *
!* - materialpoint_stressAndItsTangent *
!* - _partitionDeformation *
!* - _updateState *
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!* - _stressAndItsTangent *
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!* - _postResults *
!***************************************
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MODULE crystallite
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use prec , only : pReal , pInt
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implicit none
private :: crystallite_integrateStateFPI , &
crystallite_integrateStateEuler , &
crystallite_integrateStateAdaptiveEuler , &
crystallite_integrateStateRK4 , &
crystallite_integrateStateRKCK45 , &
crystallite_updateTemperature , &
crystallite_updateState
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! ****************************************************************
! *** General variables for the crystallite calculation ***
! ****************************************************************
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integer ( pInt ) crystallite_maxSizePostResults
integer ( pInt ) , dimension ( : ) , allocatable :: crystallite_sizePostResults
integer ( pInt ) , dimension ( : , : ) , allocatable :: crystallite_sizePostResult
character ( len = 64 ) , dimension ( : , : ) , allocatable :: crystallite_output ! name of each post result output
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integer ( pInt ) , dimension ( : , : , : ) , allocatable :: &
crystallite_symmetryID ! crystallographic symmetry 1=cubic 2=hexagonal, needed in all orientation calcs
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real ( pReal ) , dimension ( : , : , : ) , allocatable :: &
crystallite_dt , & ! requested time increment of each grain
crystallite_subdt , & ! substepped time increment of each grain
crystallite_subFrac , & ! already calculated fraction of increment
crystallite_subStep , & ! size of next integration step
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crystallite_statedamper , & ! damping for state update
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crystallite_Temperature , & ! Temp of each grain
crystallite_partionedTemperature0 , & ! Temp of each grain at start of homog inc
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crystallite_subTemperature0 , & ! Temp of each grain at start of crystallite inc
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crystallite_dotTemperature ! evolution of Temperature of each grain
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real ( pReal ) , dimension ( : , : , : , : ) , allocatable :: &
crystallite_Tstar_v , & ! current 2nd Piola-Kirchhoff stress vector (end of converged time step)
crystallite_Tstar0_v , & ! 2nd Piola-Kirchhoff stress vector at start of FE inc
crystallite_partionedTstar0_v , & ! 2nd Piola-Kirchhoff stress vector at start of homog inc
crystallite_subTstar0_v , & ! 2nd Piola-Kirchhoff stress vector at start of crystallite inc
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crystallite_orientation , & ! orientation as quaternion
crystallite_orientation0 , & ! initial orientation as quaternion
crystallite_rotation ! grain rotation away from initial orientation as axis-angle (in degrees)
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real ( pReal ) , dimension ( : , : , : , : , : ) , allocatable :: &
crystallite_Fe , & ! current "elastic" def grad (end of converged time step)
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crystallite_subFe0 , & ! "elastic" def grad at start of crystallite inc
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crystallite_Fp , & ! current plastic def grad (end of converged time step)
crystallite_invFp , & ! inverse of current plastic def grad (end of converged time step)
crystallite_Fp0 , & ! plastic def grad at start of FE inc
crystallite_partionedFp0 , & ! plastic def grad at start of homog inc
crystallite_subFp0 , & ! plastic def grad at start of crystallite inc
crystallite_F0 , & ! def grad at start of FE inc
crystallite_partionedF , & ! def grad to be reached at end of homog inc
crystallite_partionedF0 , & ! def grad at start of homog inc
crystallite_subF , & ! def grad to be reached at end of crystallite inc
crystallite_subF0 , & ! def grad at start of crystallite inc
crystallite_Lp , & ! current plastic velocitiy grad (end of converged time step)
crystallite_Lp0 , & ! plastic velocitiy grad at start of FE inc
crystallite_partionedLp0 , & ! plastic velocity grad at start of homog inc
crystallite_subLp0 , & ! plastic velocity grad at start of crystallite inc
crystallite_P , & ! 1st Piola-Kirchhoff stress per grain
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crystallite_disorientation ! disorientation between two neighboring ips (only calculated for single grain IPs)
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real ( pReal ) , dimension ( : , : , : , : , : , : , : ) , allocatable :: &
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crystallite_dPdF , & ! current individual dPdF per grain (end of converged time step)
crystallite_dPdF0 , & ! individual dPdF per grain at start of FE inc
crystallite_partioneddPdF0 , & ! individual dPdF per grain at start of homog inc
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crystallite_fallbackdPdF ! dPdF fallback for non-converged grains (elastic prediction)
logical , dimension ( : , : , : ) , allocatable :: &
crystallite_localConstitution , & ! indicates this grain to have purely local constitutive law
crystallite_requested , & ! flag to request crystallite calculation
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crystallite_todo , & ! flag to indicate need for further computation
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
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crystallite_converged ! convergence flag
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CONTAINS
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!********************************************************************
! allocate and initialize per grain variables
!********************************************************************
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subroutine crystallite_init ( Temperature )
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!*** variables and functions from other modules ***!
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use , intrinsic :: iso_fortran_env ! to get compiler_version and compiler_options (at least for gfortran 4.6 at the moment)
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use debug , only : debug_info , &
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debug_reset , &
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debug_what , &
debug_crystallite , &
debug_levelBasic
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use math , only : math_I3 , &
math_EulerToR , &
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math_inv33 , &
math_transpose33 , &
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math_mul33xx33 , &
math_mul33x33
use FEsolving , only : FEsolving_execElem , &
FEsolving_execIP
use mesh , only : mesh_element , &
mesh_NcpElems , &
mesh_maxNips , &
mesh_maxNipNeighbors
use IO
use material
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use lattice , only : lattice_symmetryType
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use constitutive , only : constitutive_microstructure
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use constitutive_phenopowerlaw , only : constitutive_phenopowerlaw_label , &
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constitutive_phenopowerlaw_structure
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use constitutive_titanmod , only : constitutive_titanmod_label , &
constitutive_titanmod_structure
use constitutive_dislotwin , only : constitutive_dislotwin_label , &
constitutive_dislotwin_structure
use constitutive_nonlocal , only : constitutive_nonlocal_label , &
constitutive_nonlocal_structure
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implicit none
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integer ( pInt ) , parameter :: myFile = 200_pInt , &
maxNchunks = 2_pInt
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!*** input variables ***!
real ( pReal ) Temperature
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!*** output variables ***!
!*** local variables ***!
integer ( pInt ) , dimension ( 1 + 2 * maxNchunks ) :: positions
integer ( pInt ) g , & ! grain number
i , & ! integration point number
e , & ! element number
gMax , & ! maximum number of grains
iMax , & ! maximum number of integration points
eMax , & ! maximum number of elements
nMax , & ! maximum number of ip neighbors
myNgrains , & ! number of grains in current IP
section , &
j , &
p , &
output , &
mySize , &
myStructure , & ! lattice structure
myPhase , &
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myMat
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character ( len = 64 ) tag
character ( len = 1024 ) line
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
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!$OMP CRITICAL (write2out)
write ( 6 , * )
write ( 6 , * ) '<<<+- crystallite init -+>>>'
write ( 6 , * ) '$Id$'
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#include "compilation_info.f90"
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
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!$OMP END CRITICAL (write2out)
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gMax = homogenization_maxNgrains
iMax = mesh_maxNips
eMax = mesh_NcpElems
nMax = mesh_maxNipNeighbors
allocate ( crystallite_Temperature ( gMax , iMax , eMax ) ) ; crystallite_Temperature = Temperature
allocate ( crystallite_partionedTemperature0 ( gMax , iMax , eMax ) ) ; crystallite_partionedTemperature0 = 0.0_pReal
allocate ( crystallite_subTemperature0 ( gMax , iMax , eMax ) ) ; crystallite_subTemperature0 = 0.0_pReal
allocate ( crystallite_dotTemperature ( gMax , iMax , eMax ) ) ; crystallite_dotTemperature = 0.0_pReal
allocate ( crystallite_Tstar0_v ( 6 , gMax , iMax , eMax ) ) ; crystallite_Tstar0_v = 0.0_pReal
allocate ( crystallite_partionedTstar0_v ( 6 , gMax , iMax , eMax ) ) ; crystallite_partionedTstar0_v = 0.0_pReal
allocate ( crystallite_subTstar0_v ( 6 , gMax , iMax , eMax ) ) ; crystallite_subTstar0_v = 0.0_pReal
allocate ( crystallite_Tstar_v ( 6 , gMax , iMax , eMax ) ) ; crystallite_Tstar_v = 0.0_pReal
allocate ( crystallite_P ( 3 , 3 , gMax , iMax , eMax ) ) ; crystallite_P = 0.0_pReal
allocate ( crystallite_F0 ( 3 , 3 , gMax , iMax , eMax ) ) ; crystallite_F0 = 0.0_pReal
allocate ( crystallite_partionedF0 ( 3 , 3 , gMax , iMax , eMax ) ) ; crystallite_partionedF0 = 0.0_pReal
allocate ( crystallite_partionedF ( 3 , 3 , gMax , iMax , eMax ) ) ; crystallite_partionedF = 0.0_pReal
allocate ( crystallite_subF0 ( 3 , 3 , gMax , iMax , eMax ) ) ; crystallite_subF0 = 0.0_pReal
allocate ( crystallite_subF ( 3 , 3 , gMax , iMax , eMax ) ) ; crystallite_subF = 0.0_pReal
allocate ( crystallite_Fp0 ( 3 , 3 , gMax , iMax , eMax ) ) ; crystallite_Fp0 = 0.0_pReal
allocate ( crystallite_partionedFp0 ( 3 , 3 , gMax , iMax , eMax ) ) ; crystallite_partionedFp0 = 0.0_pReal
allocate ( crystallite_subFp0 ( 3 , 3 , gMax , iMax , eMax ) ) ; crystallite_subFp0 = 0.0_pReal
allocate ( crystallite_Fp ( 3 , 3 , gMax , iMax , eMax ) ) ; crystallite_Fp = 0.0_pReal
allocate ( crystallite_invFp ( 3 , 3 , gMax , iMax , eMax ) ) ; crystallite_invFp = 0.0_pReal
allocate ( crystallite_Fe ( 3 , 3 , gMax , iMax , eMax ) ) ; crystallite_Fe = 0.0_pReal
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allocate ( crystallite_subFe0 ( 3 , 3 , gMax , iMax , eMax ) ) ; crystallite_subFe0 = 0.0_pReal
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allocate ( crystallite_Lp0 ( 3 , 3 , gMax , iMax , eMax ) ) ; crystallite_Lp0 = 0.0_pReal
allocate ( crystallite_partionedLp0 ( 3 , 3 , gMax , iMax , eMax ) ) ; crystallite_partionedLp0 = 0.0_pReal
allocate ( crystallite_subLp0 ( 3 , 3 , gMax , iMax , eMax ) ) ; crystallite_subLp0 = 0.0_pReal
allocate ( crystallite_Lp ( 3 , 3 , gMax , iMax , eMax ) ) ; crystallite_Lp = 0.0_pReal
allocate ( crystallite_dPdF ( 3 , 3 , 3 , 3 , gMax , iMax , eMax ) ) ; crystallite_dPdF = 0.0_pReal
allocate ( crystallite_dPdF0 ( 3 , 3 , 3 , 3 , gMax , iMax , eMax ) ) ; crystallite_dPdF0 = 0.0_pReal
allocate ( crystallite_partioneddPdF0 ( 3 , 3 , 3 , 3 , gMax , iMax , eMax ) ) ; crystallite_partioneddPdF0 = 0.0_pReal
allocate ( crystallite_fallbackdPdF ( 3 , 3 , 3 , 3 , gMax , iMax , eMax ) ) ; crystallite_fallbackdPdF = 0.0_pReal
allocate ( crystallite_dt ( gMax , iMax , eMax ) ) ; crystallite_dt = 0.0_pReal
allocate ( crystallite_subdt ( gMax , iMax , eMax ) ) ; crystallite_subdt = 0.0_pReal
allocate ( crystallite_subFrac ( gMax , iMax , eMax ) ) ; crystallite_subFrac = 0.0_pReal
allocate ( crystallite_subStep ( gMax , iMax , eMax ) ) ; crystallite_subStep = 0.0_pReal
allocate ( crystallite_statedamper ( gMax , iMax , eMax ) ) ; crystallite_statedamper = 1.0_pReal
allocate ( crystallite_orientation ( 4 , gMax , iMax , eMax ) ) ; crystallite_orientation = 0.0_pReal
allocate ( crystallite_orientation0 ( 4 , gMax , iMax , eMax ) ) ; crystallite_orientation0 = 0.0_pReal
allocate ( crystallite_rotation ( 4 , gMax , iMax , eMax ) ) ; crystallite_rotation = 0.0_pReal
allocate ( crystallite_disorientation ( 4 , nMax , gMax , iMax , eMax ) ) ; crystallite_disorientation = 0.0_pReal
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allocate ( crystallite_symmetryID ( gMax , iMax , eMax ) ) ; crystallite_symmetryID = 0_pInt
allocate ( crystallite_localConstitution ( gMax , iMax , eMax ) ) ; crystallite_localConstitution = . true .
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allocate ( crystallite_requested ( gMax , iMax , eMax ) ) ; crystallite_requested = . false .
allocate ( crystallite_todo ( gMax , iMax , eMax ) ) ; crystallite_todo = . false .
allocate ( crystallite_converged ( gMax , iMax , eMax ) ) ; crystallite_converged = . true .
allocate ( crystallite_output ( maxval ( crystallite_Noutput ) , &
material_Ncrystallite ) ) ; crystallite_output = ''
allocate ( crystallite_sizePostResults ( material_Ncrystallite ) ) ; crystallite_sizePostResults = 0_pInt
allocate ( crystallite_sizePostResult ( maxval ( crystallite_Noutput ) , &
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material_Ncrystallite ) ) ; crystallite_sizePostResult = 0_pInt
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if ( . not . IO_open_jobFile_stat ( myFile , material_localFileExt ) ) then ! no local material configuration present...
call IO_open_file ( myFile , material_configFile ) ! ...open material.config file
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endif
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line = ''
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section = 0_pInt
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do while ( IO_lc ( IO_getTag ( line , '<' , '>' ) ) / = material_partCrystallite ) ! wind forward to <crystallite>
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read ( myFile , '(a1024)' , END = 100 ) line
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enddo
do ! read thru sections of phase part
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read ( myFile , '(a1024)' , END = 100 ) line
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if ( IO_isBlank ( line ) ) cycle ! skip empty lines
if ( IO_getTag ( line , '<' , '>' ) / = '' ) exit ! stop at next part
if ( IO_getTag ( line , '[' , ']' ) / = '' ) then ! next section
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section = section + 1_pInt
output = 0_pInt ! reset output counter
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endif
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if ( section > 0_pInt ) then
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positions = IO_stringPos ( line , maxNchunks )
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tag = IO_lc ( IO_stringValue ( line , positions , 1_pInt ) ) ! extract key
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select case ( tag )
case ( '(output)' )
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output = output + 1_pInt
crystallite_output ( output , section ) = IO_lc ( IO_stringValue ( line , positions , 2_pInt ) )
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end select
endif
enddo
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100 close ( myFile )
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do i = 1_pInt , material_Ncrystallite ! sanity checks
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enddo
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do i = 1_pInt , material_Ncrystallite
do j = 1_pInt , crystallite_Noutput ( i )
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select case ( crystallite_output ( j , i ) )
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case ( 'phase' , 'texture' , 'volume' )
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mySize = 1_pInt
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case ( 'orientation' , 'grainrotation' ) ! orientation as quaternion, or deviation from initial grain orientation in axis-angle form (angle in degrees)
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mySize = 4_pInt
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case ( 'eulerangles' ) ! Bunge (3-1-3) Euler angles
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mySize = 3_pInt
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case ( 'defgrad' , 'f' , 'fe' , 'fp' , 'lp' , 'e' , 'ee' , 'p' , 'firstpiola' , '1stpiola' , 's' , 'tstar' , 'secondpiola' , '2ndpiola' )
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mySize = 9_pInt
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case ( 'elasmatrix' )
mySize = 36_pInt
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case default
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mySize = 0_pInt
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end select
if ( mySize > 0_pInt ) then ! any meaningful output found
crystallite_sizePostResult ( j , i ) = mySize
crystallite_sizePostResults ( i ) = crystallite_sizePostResults ( i ) + mySize
endif
enddo
enddo
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crystallite_maxSizePostResults = 0_pInt
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do j = 1_pInt , material_Nmicrostructure
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if ( microstructure_active ( j ) ) &
crystallite_maxSizePostResults = max ( crystallite_maxSizePostResults , &
crystallite_sizePostResults ( microstructure_crystallite ( j ) ) )
enddo
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! write description file for crystallite output
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call IO_write_jobFile ( myFile , 'outputCrystallite' )
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do p = 1_pInt , material_Ncrystallite
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write ( myFile , * )
write ( myFile , '(a)' ) '[' / / trim ( crystallite_name ( p ) ) / / ']'
write ( myFile , * )
do e = 1_pInt , crystallite_Noutput ( p )
write ( myFile , '(a,i4)' ) trim ( crystallite_output ( e , p ) ) / / char ( 9 ) , crystallite_sizePostResult ( e , p )
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enddo
enddo
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close ( myFile )
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openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
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!$OMP PARALLEL PRIVATE(myNgrains,myPhase,myMat,myStructure)
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!$OMP DO
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do e = FEsolving_execElem ( 1 ) , FEsolving_execElem ( 2 ) ! iterate over all cp elements
myNgrains = homogenization_Ngrains ( mesh_element ( 3 , e ) ) ! look up homogenization-->grainCount
do i = FEsolving_execIP ( 1 , e ) , FEsolving_execIP ( 2 , e ) ! iterate over IPs of this element
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do g = 1_pInt , myNgrains
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
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crystallite_Fp0 ( 1 : 3 , 1 : 3 , g , i , e ) = math_EulerToR ( material_EulerAngles ( 1 : 3 , g , i , e ) ) ! plastic def gradient reflects init orientation
crystallite_F0 ( 1 : 3 , 1 : 3 , g , i , e ) = math_I3
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crystallite_localConstitution ( g , i , e ) = phase_localConstitution ( material_phase ( g , i , e ) )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
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!$OMP FLUSH(crystallite_Fp0)
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crystallite_Fe ( 1 : 3 , 1 : 3 , g , i , e ) = math_transpose33 ( crystallite_Fp0 ( 1 : 3 , 1 : 3 , g , i , e ) )
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crystallite_Fp ( 1 : 3 , 1 : 3 , g , i , e ) = crystallite_Fp0 ( 1 : 3 , 1 : 3 , g , i , e )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
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enddo
enddo
enddo
!$OMP ENDDO
crystallite_partionedTemperature0 = Temperature ! isothermal assumption
crystallite_partionedFp0 = crystallite_Fp0
crystallite_partionedF0 = crystallite_F0
crystallite_partionedF = crystallite_F0
crystallite_requested = . true .
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! Initialize crystallite_symmetryID(g,i,e)
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!$OMP DO
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do e = FEsolving_execElem ( 1 ) , FEsolving_execElem ( 2 )
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myNgrains = homogenization_Ngrains ( mesh_element ( 3 , e ) )
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do i = FEsolving_execIP ( 1 , e ) , FEsolving_execIP ( 2 , e )
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do g = 1_pInt , myNgrains
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myPhase = material_phase ( g , i , e )
myMat = phase_constitutionInstance ( myPhase )
select case ( phase_constitution ( myPhase ) )
case ( constitutive_phenopowerlaw_label )
myStructure = constitutive_phenopowerlaw_structure ( myMat )
case ( constitutive_titanmod_label )
myStructure = constitutive_titanmod_structure ( myMat )
case ( constitutive_dislotwin_label )
myStructure = constitutive_dislotwin_structure ( myMat )
case ( constitutive_nonlocal_label )
myStructure = constitutive_nonlocal_structure ( myMat )
case default
myStructure = - 1_pInt ! does this happen for j2 material?
end select
if ( myStructure > 0_pInt ) then
crystallite_symmetryID ( g , i , e ) = lattice_symmetryType ( myStructure ) ! structure = 1(fcc) or 2(bcc) => 1; 3(hex)=>2
endif
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enddo
enddo
enddo
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!$OMP ENDDO
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!$OMP END PARALLEL
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call crystallite_orientations ( )
crystallite_orientation0 = crystallite_orientation ! Store initial orientations for calculation of grain rotations
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!$OMP PARALLEL DO PRIVATE(myNgrains)
do e = FEsolving_execElem ( 1 ) , FEsolving_execElem ( 2 )
myNgrains = homogenization_Ngrains ( mesh_element ( 3 , e ) )
do i = FEsolving_execIP ( 1 , e ) , FEsolving_execIP ( 2 , e )
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do g = 1_pInt , myNgrains
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call constitutive_microstructure ( crystallite_Temperature ( g , i , e ) , crystallite_Fe ( 1 : 3 , 1 : 3 , g , i , e ) , &
crystallite_Fp ( 1 : 3 , 1 : 3 , g , i , e ) , g , i , e ) ! update dependent state variables to be consistent with basic states
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enddo
enddo
enddo
!$OMP END PARALLEL DO
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call crystallite_stressAndItsTangent ( . true . ) ! request elastic answers
crystallite_fallbackdPdF = crystallite_dPdF ! use initial elastic stiffness as fallback
! *** Output to MARC output file ***
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if ( iand ( debug_what ( debug_crystallite ) , debug_levelBasic ) / = 0_pInt ) then
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!$OMP CRITICAL (write2out)
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write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_Temperature: ' , shape ( crystallite_Temperature )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_dotTemperature: ' , shape ( crystallite_dotTemperature )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_Fe: ' , shape ( crystallite_Fe )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_Fp: ' , shape ( crystallite_Fp )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_Lp: ' , shape ( crystallite_Lp )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_F0: ' , shape ( crystallite_F0 )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_Fp0: ' , shape ( crystallite_Fp0 )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_Lp0: ' , shape ( crystallite_Lp0 )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_partionedF: ' , shape ( crystallite_partionedF )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_partionedTemp0: ' , shape ( crystallite_partionedTemperature0 )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_partionedF0: ' , shape ( crystallite_partionedF0 )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_partionedFp0: ' , shape ( crystallite_partionedFp0 )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_partionedLp0: ' , shape ( crystallite_partionedLp0 )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_subF: ' , shape ( crystallite_subF )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_subTemperature0: ' , shape ( crystallite_subTemperature0 )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_symmetryID: ' , shape ( crystallite_symmetryID )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_subF0: ' , shape ( crystallite_subF0 )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_subFe0: ' , shape ( crystallite_subFe0 )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_subFp0: ' , shape ( crystallite_subFp0 )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_subLp0: ' , shape ( crystallite_subLp0 )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_P: ' , shape ( crystallite_P )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_Tstar_v: ' , shape ( crystallite_Tstar_v )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_Tstar0_v: ' , shape ( crystallite_Tstar0_v )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_partionedTstar0_v: ' , shape ( crystallite_partionedTstar0_v )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_subTstar0_v: ' , shape ( crystallite_subTstar0_v )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_dPdF: ' , shape ( crystallite_dPdF )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_dPdF0: ' , shape ( crystallite_dPdF0 )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_partioneddPdF0: ' , shape ( crystallite_partioneddPdF0 )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_fallbackdPdF: ' , shape ( crystallite_fallbackdPdF )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_orientation: ' , shape ( crystallite_orientation )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_orientation0: ' , shape ( crystallite_orientation0 )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_rotation: ' , shape ( crystallite_rotation )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_disorientation: ' , shape ( crystallite_disorientation )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_dt: ' , shape ( crystallite_dt )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_subdt: ' , shape ( crystallite_subdt )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_subFrac: ' , shape ( crystallite_subFrac )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_subStep: ' , shape ( crystallite_subStep )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_stateDamper: ' , shape ( crystallite_stateDamper )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_localConstitution: ' , shape ( crystallite_localConstitution )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_requested: ' , shape ( crystallite_requested )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_todo: ' , shape ( crystallite_todo )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_converged: ' , shape ( crystallite_converged )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_sizePostResults: ' , shape ( crystallite_sizePostResults )
write ( 6 , '(a35,1x,7(i8,1x))' ) 'crystallite_sizePostResult: ' , shape ( crystallite_sizePostResult )
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write ( 6 , * )
write ( 6 , * ) 'Number of nonlocal grains: ' , count ( . not . crystallite_localConstitution )
call flush ( 6 )
!$OMP END CRITICAL (write2out)
endif
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call debug_info
call debug_reset
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end subroutine crystallite_init
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!********************************************************************
! calculate stress (P) and tangent (dPdF) for crystallites
!********************************************************************
subroutine crystallite_stressAndItsTangent ( updateJaco )
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!*** variables and functions from other modules ***!
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use numerics , only : subStepMinCryst , &
subStepSizeCryst , &
stepIncreaseCryst , &
pert_Fg , &
pert_method , &
nCryst , &
numerics_integrator , &
numerics_integrationMode , &
relevantStrain , &
Lp_frac , &
analyticJaco , &
time_sensitive
use debug , only : debug_what , &
debug_crystallite , &
debug_levelBasic , &
debug_levelExtensive , &
debug_levelSelective , &
debug_e , &
debug_i , &
debug_g , &
debug_CrystalliteLoopDistribution
use IO , only : IO_warning
use math , only : math_inv33 , &
math_identity2nd , &
math_transpose33 , &
math_mul33x33 , &
math_mul66x6 , &
math_Mandel6to33 , &
math_Mandel33to6 , &
math_I3 , &
math_Plain3333to99 , &
math_Plain99to3333 , &
math_mul99x99 , &
math_Mandel66to3333 , &
math_mul3333xx33 , &
math_invert , &
math_mul3333xx3333 , &
math_spectralDecompositionSym33
use FEsolving , only : FEsolving_execElem , &
FEsolving_execIP
use mesh , only : mesh_element , &
mesh_NcpElems , &
mesh_maxNips
use material , only : homogenization_Ngrains , &
homogenization_maxNgrains
use constitutive , only : constitutive_sizeState , &
constitutive_sizeDotState , &
constitutive_state , &
constitutive_state_backup , &
constitutive_subState0 , &
constitutive_partionedState0 , &
constitutive_homogenizedC , &
constitutive_dotState , &
constitutive_dotState_backup , &
constitutive_LpAndItsTangent
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implicit none
!*** input variables ***!
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logical , intent ( in ) :: updateJaco ! flag indicating wehther we want to update the Jacobian (stiffness) or not
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!*** local variables ***!
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real ( pReal ) myPert , & ! perturbation with correct sign
formerSubStep
real ( pReal ) , dimension ( 3 , 3 ) :: invFp , & ! inverse of the plastic deformation gradient
Fe_guess , & ! guess for elastic deformation gradient
Tstar ! 2nd Piola-Kirchhoff stress tensor
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real ( pReal ) , dimension ( 3 , 3 , 3 , 3 , homogenization_maxNgrains , mesh_maxNips , mesh_NcpElems ) :: &
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dPdF_perturbation1 , &
dPdF_perturbation2
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real ( pReal ) , dimension ( 3 , 3 , homogenization_maxNgrains , mesh_maxNips , mesh_NcpElems ) :: &
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F_backup , &
Fp_backup , &
InvFp_backup , &
Fe_backup , &
Lp_backup , &
P_backup
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real ( pReal ) , dimension ( 6 , homogenization_maxNgrains , mesh_maxNips , mesh_NcpElems ) :: &
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Tstar_v_backup
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real ( pReal ) , dimension ( homogenization_maxNgrains , mesh_maxNips , mesh_NcpElems ) :: &
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Temperature_backup
integer ( pInt ) NiterationCrystallite , & ! number of iterations in crystallite loop
e , & ! element index
i , & ! integration point index
g , & ! grain index
k , &
l , &
h , &
o , &
p , &
j , &
perturbation , & ! loop counter for forward,backward perturbation mode
myNgrains , &
mySizeState , &
mySizeDotState
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logical , dimension ( homogenization_maxNgrains , mesh_maxNips , mesh_NcpElems ) :: &
convergenceFlag_backup
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! local variables used for calculating analytic Jacobian
real ( pReal ) , dimension ( 3 , 3 ) :: Fp_exp1 , &
Fp_exp2 , &
Fp_inv_current , &
dSdFe_mat1 , &
dSdFe_mat2 , &
Lp_constitutive , &
Eigvec , &
V_dir , &
phi_mat , &
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Fpinv_rate , &
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FDot_temp , &
Rot_mat , &
Fp0 , &
Fp_inv_0 , &
Lp0 , &
Lp_current , &
Fe0
real ( pReal ) , dimension ( 3 , 3 , 3 , 3 ) :: C , &
dSdFe , &
dLp_dT , &
Tensor1 , &
Tensor2 , &
Tensor3 , &
Tensor4 , &
Tensor5 , &
dFedF , &
dSdF
real ( pReal ) , dimension ( 9 , 9 ) :: dLp_dT_constitutive , &
A99 , &
A_inv99 , &
C99 , &
dFedF99 , &
dFedF_old99
real ( pReal ) , dimension ( 3 ) :: Eigval
real ( pReal ) :: dt , &
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fixedpt_error , &
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counter
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integer ( pInt ) :: AnzNegEW , &
fixedpt_iter
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logical :: error
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! --+>> INITIALIZE TO STARTING CONDITION <<+--
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if ( iand ( debug_what ( debug_crystallite ) , debug_levelBasic ) / = 0_pInt &
. and . debug_e > 0 . and . debug_e < = mesh_NcpElems &
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. and . debug_i > 0 . and . debug_i < = mesh_maxNips &
. and . debug_g > 0 . and . debug_g < = homogenization_maxNgrains ) then
!$OMP CRITICAL (write2out)
write ( 6 , * )
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write ( 6 , '(a,i8,1x,i2,1x,i3)' ) '<< CRYST >> crystallite start at el ip g ' , debug_e , debug_i , debug_g
write ( 6 , '(a,/,12x,f14.9)' ) '<< CRYST >> Temp0' , crystallite_partionedTemperature0 ( debug_g , debug_i , debug_e )
write ( 6 , '(a,/,3(12x,3(f14.9,1x)/))' ) '<< CRYST >> F0 ' , &
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math_transpose33 ( crystallite_partionedF0 ( 1 : 3 , 1 : 3 , debug_g , debug_i , debug_e ) )
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write ( 6 , '(a,/,3(12x,3(f14.9,1x)/))' ) '<< CRYST >> Fp0' , &
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math_transpose33 ( crystallite_partionedFp0 ( 1 : 3 , 1 : 3 , debug_g , debug_i , debug_e ) )
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write ( 6 , '(a,/,3(12x,3(f14.9,1x)/))' ) '<< CRYST >> Lp0' , &
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math_transpose33 ( crystallite_partionedLp0 ( 1 : 3 , 1 : 3 , debug_g , debug_i , debug_e ) )
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!$OMP END CRITICAL (write2out)
endif
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crystallite_subStep = 0.0_pReal
!$OMP PARALLEL DO PRIVATE(myNgrains)
do e = FEsolving_execElem ( 1 ) , FEsolving_execElem ( 2 ) ! iterate over elements to be processed
myNgrains = homogenization_Ngrains ( mesh_element ( 3 , e ) )
do i = FEsolving_execIP ( 1 , e ) , FEsolving_execIP ( 2 , e ) ! iterate over IPs of this element to be processed
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do g = 1_pInt , myNgrains
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if ( crystallite_requested ( g , i , e ) ) then ! initialize restoration point of ...
crystallite_subTemperature0 ( g , i , e ) = crystallite_partionedTemperature0 ( g , i , e ) ! ...temperature
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
constitutive_subState0 ( g , i , e ) % p = constitutive_partionedState0 ( g , i , e ) % p ! ...microstructure
crystallite_subFp0 ( 1 : 3 , 1 : 3 , g , i , e ) = crystallite_partionedFp0 ( 1 : 3 , 1 : 3 , g , i , e ) ! ...plastic def grad
crystallite_subLp0 ( 1 : 3 , 1 : 3 , g , i , e ) = crystallite_partionedLp0 ( 1 : 3 , 1 : 3 , g , i , e ) ! ...plastic velocity grad
crystallite_dPdF0 ( 1 : 3 , 1 : 3 , 1 : 3 , 1 : 3 , g , i , e ) = crystallite_partioneddPdF0 ( 1 : 3 , 1 : 3 , 1 : 3 , 1 : 3 , g , i , e ) ! ...stiffness
crystallite_subF0 ( 1 : 3 , 1 : 3 , g , i , e ) = crystallite_partionedF0 ( 1 : 3 , 1 : 3 , g , i , e ) ! ...def grad
crystallite_subTstar0_v ( 1 : 6 , g , i , e ) = crystallite_partionedTstar0_v ( 1 : 6 , g , i , e ) !...2nd PK stress
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crystallite_subFe0 ( 1 : 3 , 1 : 3 , g , i , e ) = math_mul33x33 ( crystallite_subF0 ( 1 : 3 , 1 : 3 , g , i , e ) , &
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math_inv33 ( crystallite_subFp0 ( 1 : 3 , 1 : 3 , g , i , e ) ) ) ! only needed later on for stiffness calculation
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crystallite_subFrac ( g , i , e ) = 0.0_pReal
crystallite_subStep ( g , i , e ) = 1.0_pReal / subStepSizeCryst
crystallite_todo ( g , i , e ) = . true .
crystallite_converged ( g , i , e ) = . false . ! pretend failed step of twice the required size
endif
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enddo
enddo
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enddo
!$OMP END PARALLEL DO
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! --+>> CRYSTALLITE CUTBACK LOOP <<+--
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NiterationCrystallite = 0_pInt
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numerics_integrationMode = 1_pInt
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do while ( any ( crystallite_subStep ( : , : , FEsolving_execELem ( 1 ) : FEsolving_execElem ( 2 ) ) > subStepMinCryst ) ) ! cutback loop for crystallites
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!$OMP PARALLEL DO PRIVATE(myNgrains,formerSubStep)
do e = FEsolving_execElem ( 1 ) , FEsolving_execElem ( 2 ) ! iterate over elements to be processed
myNgrains = homogenization_Ngrains ( mesh_element ( 3 , e ) )
do i = FEsolving_execIP ( 1 , e ) , FEsolving_execIP ( 2 , e ) ! iterate over IPs of this element to be processed
do g = 1 , myNgrains
! --- wind forward ---
if ( crystallite_converged ( g , i , e ) ) then
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#ifndef _OPENMP
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if ( iand ( debug_what ( debug_crystallite ) , debug_levelBasic ) / = 0_pInt &
. and . ( ( e == debug_e . and . i == debug_i . and . g == debug_g ) &
. or . . not . iand ( debug_what ( debug_crystallite ) , debug_levelSelective ) / = 0_pInt ) ) then
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write ( 6 , '(a,f12.8,a,f12.8,a)' ) '<< CRYST >> winding forward from ' , &
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crystallite_subFrac ( g , i , e ) , ' to current crystallite_subfrac ' , &
crystallite_subFrac ( g , i , e ) + crystallite_subStep ( g , i , e ) , ' in crystallite_stressAndItsTangent'
write ( 6 , * )
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endif
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#endif
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crystallite_subFrac ( g , i , e ) = crystallite_subFrac ( g , i , e ) + crystallite_subStep ( g , i , e )
formerSubStep = crystallite_subStep ( g , i , e )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
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!$OMP FLUSH(crystallite_subFrac)
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crystallite_subStep ( g , i , e ) = min ( 1.0_pReal - crystallite_subFrac ( g , i , e ) , &
stepIncreaseCryst * crystallite_subStep ( g , i , e ) )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
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!$OMP FLUSH(crystallite_subStep)
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if ( crystallite_subStep ( g , i , e ) > subStepMinCryst ) then
crystallite_subTemperature0 ( g , i , e ) = crystallite_Temperature ( g , i , e ) ! wind forward...
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
crystallite_subF0 ( 1 : 3 , 1 : 3 , g , i , e ) = crystallite_subF ( 1 : 3 , 1 : 3 , g , i , e ) ! ...def grad
crystallite_subFp0 ( 1 : 3 , 1 : 3 , g , i , e ) = crystallite_Fp ( 1 : 3 , 1 : 3 , g , i , e ) ! ...plastic def grad
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crystallite_subFe0 ( 1 : 3 , 1 : 3 , g , i , e ) = math_mul33x33 ( crystallite_subF ( 1 : 3 , 1 : 3 , g , i , e ) , crystallite_invFp ( 1 : 3 , 1 : 3 , g , i , e ) ) ! only needed later on for stiffness calculation
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
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crystallite_subLp0 ( 1 : 3 , 1 : 3 , g , i , e ) = crystallite_Lp ( 1 : 3 , 1 : 3 , g , i , e ) ! ...plastic velocity gradient
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constitutive_subState0 ( g , i , e ) % p = constitutive_state ( g , i , e ) % p ! ...microstructure
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
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crystallite_subTstar0_v ( 1 : 6 , g , i , e ) = crystallite_Tstar_v ( 1 : 6 , g , i , e ) ! ...2nd PK stress
!$OMP FLUSH(crystallite_subF0)
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elseif ( formerSubStep > subStepMinCryst ) then ! this crystallite just converged
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if ( iand ( debug_what ( debug_crystallite ) , debug_levelBasic ) / = 0_pInt ) then
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!$OMP CRITICAL (distributionCrystallite)
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debug_CrystalliteLoopDistribution ( min ( nCryst + 1_pInt , NiterationCrystallite ) ) = &
debug_CrystalliteLoopDistribution ( min ( nCryst + 1_pInt , NiterationCrystallite ) ) + 1_pInt
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!$OMP END CRITICAL (distributionCrystallite)
endif
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endif
! --- cutback ---
else
crystallite_subStep ( g , i , e ) = subStepSizeCryst * crystallite_subStep ( g , i , e ) ! cut step in half and restore...
crystallite_Temperature ( g , i , e ) = crystallite_subTemperature0 ( g , i , e ) ! ...temperature
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
crystallite_Fp ( 1 : 3 , 1 : 3 , g , i , e ) = crystallite_subFp0 ( 1 : 3 , 1 : 3 , g , i , e ) ! ...plastic def grad
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crystallite_invFp ( 1 : 3 , 1 : 3 , g , i , e ) = math_inv33 ( crystallite_Fp ( 1 : 3 , 1 : 3 , g , i , e ) )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
crystallite_Lp ( 1 : 3 , 1 : 3 , g , i , e ) = crystallite_subLp0 ( 1 : 3 , 1 : 3 , g , i , e ) ! ...plastic velocity grad
constitutive_state ( g , i , e ) % p = constitutive_subState0 ( g , i , e ) % p ! ...microstructure
crystallite_Tstar_v ( 1 : 6 , g , i , e ) = crystallite_subTstar0_v ( 1 : 6 , g , i , e ) ! ...2nd PK stress
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! cant restore dotState here, since not yet calculated in first cutback after initialization
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!$OMP FLUSH(crystallite_invFp)
#ifndef _OPENMP
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if ( iand ( debug_what ( debug_crystallite ) , debug_levelBasic ) / = 0_pInt &
. and . ( ( e == debug_e . and . i == debug_i . and . g == debug_g ) &
. or . . not . iand ( debug_what ( debug_crystallite ) , debug_levelSelective ) / = 0_pInt ) ) then
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write ( 6 , '(a,f12.8)' ) '<< CRYST >> cutback step in crystallite_stressAndItsTangent with new crystallite_subStep: ' , &
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crystallite_subStep ( g , i , e )
write ( 6 , * )
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endif
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#endif
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endif
! --- prepare for integration ---
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
!$OMP FLUSH(crystallite_subStep)
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crystallite_todo ( g , i , e ) = crystallite_subStep ( g , i , e ) > subStepMinCryst ! still on track or already done (beyond repair)
if ( crystallite_todo ( g , i , e ) ) then
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
crystallite_subF ( 1 : 3 , 1 : 3 , g , i , e ) = crystallite_subF0 ( 1 : 3 , 1 : 3 , g , i , e ) &
+ crystallite_subStep ( g , i , e ) &
* ( crystallite_partionedF ( 1 : 3 , 1 : 3 , g , i , e ) - crystallite_partionedF0 ( 1 : 3 , 1 : 3 , g , i , e ) )
!$OMP FLUSH(crystallite_subF)
crystallite_Fe ( 1 : 3 , 1 : 3 , g , i , e ) = math_mul33x33 ( crystallite_subF ( 1 : 3 , 1 : 3 , g , i , e ) , crystallite_invFp ( 1 : 3 , 1 : 3 , g , i , e ) )
crystallite_subdt ( g , i , e ) = crystallite_subStep ( g , i , e ) * crystallite_dt ( g , i , e )
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crystallite_converged ( g , i , e ) = . false . ! start out non-converged
endif
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enddo
enddo
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enddo
!$OMP END PARALLEL DO
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2011-08-02 16:59:08 +05:30
! --- integrate --- requires fully defined state array (basic + dependent state)
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if ( any ( crystallite_todo ) ) then
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select case ( numerics_integrator ( numerics_integrationMode ) )
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case ( 1_pInt )
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call crystallite_integrateStateFPI ( )
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case ( 2_pInt )
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call crystallite_integrateStateEuler ( )
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case ( 3_pInt )
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call crystallite_integrateStateAdaptiveEuler ( )
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case ( 4_pInt )
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call crystallite_integrateStateRK4 ( )
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case ( 5_pInt )
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call crystallite_integrateStateRKCK45 ( )
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endselect
endif
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NiterationCrystallite = NiterationCrystallite + 1_pInt
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enddo ! cutback loop
! --+>> CHECK FOR NON-CONVERGED CRYSTALLITES <<+--
!$OMP PARALLEL DO PRIVATE(myNgrains,invFp,Fe_guess,Tstar)
do e = FEsolving_execElem ( 1 ) , FEsolving_execElem ( 2 ) ! iterate over elements to be processed
myNgrains = homogenization_Ngrains ( mesh_element ( 3 , e ) )
do i = FEsolving_execIP ( 1 , e ) , FEsolving_execIP ( 2 , e ) ! iterate over IPs of this element to be processed
do g = 1 , myNgrains
if ( . not . crystallite_converged ( g , i , e ) ) then ! respond fully elastically (might be not required due to becoming terminally ill anyway)
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invFp = math_inv33 ( crystallite_partionedFp0 ( 1 : 3 , 1 : 3 , g , i , e ) )
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Fe_guess = math_mul33x33 ( crystallite_partionedF ( 1 : 3 , 1 : 3 , g , i , e ) , invFp )
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Tstar = math_Mandel6to33 ( math_mul66x6 ( 0.5_pReal * constitutive_homogenizedC ( g , i , e ) , &
math_Mandel33to6 ( math_mul33x33 ( transpose ( Fe_guess ) , Fe_guess ) - math_I3 ) ) )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
crystallite_P ( 1 : 3 , 1 : 3 , g , i , e ) = math_mul33x33 ( Fe_guess , math_mul33x33 ( Tstar , transpose ( invFp ) ) )
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endif
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#ifndef _OPENMP
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if ( iand ( debug_what ( debug_crystallite ) , debug_levelBasic ) / = 0_pInt &
. and . ( ( e == debug_e . and . i == debug_i . and . g == debug_g ) &
. or . . not . iand ( debug_what ( debug_crystallite ) , debug_levelSelective ) / = 0_pInt ) ) then
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write ( 6 , '(a,i8,1x,i2,1x,i3)' ) '<< CRYST >> central solution of cryst_StressAndTangent at el ip g ' , e , i , g
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write ( 6 , * )
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write ( 6 , '(a,/,3(12x,3(f12.4,1x)/))' ) '<< CRYST >> P / MPa' , math_transpose33 ( crystallite_P ( 1 : 3 , 1 : 3 , g , i , e ) ) / 1.0e6_pReal
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write ( 6 , '(a,/,3(12x,3(f14.9,1x)/))' ) '<< CRYST >> Fp' , math_transpose33 ( crystallite_Fp ( 1 : 3 , 1 : 3 , g , i , e ) )
write ( 6 , '(a,/,3(12x,3(f14.9,1x)/))' ) '<< CRYST >> Lp' , math_transpose33 ( crystallite_Lp ( 1 : 3 , 1 : 3 , g , i , e ) )
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write ( 6 , * )
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endif
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#endif
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enddo
enddo
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enddo
!$OMP END PARALLEL DO
2009-06-16 14:33:30 +05:30
2010-11-03 22:52:48 +05:30
! --+>> STIFFNESS CALCULATION <<+--
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if ( updateJaco ) then ! Jacobian required
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if ( . not . analyticJaco ) then ! Calculate Jacobian using perturbations
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numerics_integrationMode = 2_pInt
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2011-11-04 18:14:50 +05:30
2010-11-03 22:52:48 +05:30
! --- BACKUP ---
!$OMP PARALLEL DO PRIVATE(myNgrains,mySizeState,mySizeDotState)
do e = FEsolving_execElem ( 1 ) , FEsolving_execElem ( 2 ) ! iterate over elements to be processed
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myNgrains = homogenization_Ngrains ( mesh_element ( 3 , e ) )
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do i = FEsolving_execIP ( 1 , e ) , FEsolving_execIP ( 2 , e ) ! iterate over IPs of this element to be processed
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do g = 1 , myNgrains
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mySizeState = constitutive_sizeState ( g , i , e ) ! number of state variables for this grain
mySizeDotState = constitutive_sizeDotState ( g , i , e ) ! number of dotStates for this grain
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constitutive_state_backup ( g , i , e ) % p ( 1 : mySizeState ) = &
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constitutive_state ( g , i , e ) % p ( 1 : mySizeState ) ! remember unperturbed, converged state, ...
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constitutive_dotState_backup ( g , i , e ) % p ( 1 : mySizeDotState ) = &
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constitutive_dotState ( g , i , e ) % p ( 1 : mySizeDotState ) ! ... dotStates, ...
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enddo ; enddo ; enddo
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!$OMP END PARALLEL DO
Temperature_backup = crystallite_Temperature ! ... Temperature, ...
F_backup = crystallite_subF ! ... and kinematics
Fp_backup = crystallite_Fp
InvFp_backup = crystallite_invFp
Fe_backup = crystallite_Fe
Lp_backup = crystallite_Lp
Tstar_v_backup = crystallite_Tstar_v
P_backup = crystallite_P
convergenceFlag_backup = crystallite_converged
2009-12-15 13:50:31 +05:30
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! --- CALCULATE STATE AND STRESS FOR PERTURBATION ---
dPdF_perturbation1 = crystallite_dPdF0 ! initialize stiffness with known good values from last increment
dPdF_perturbation2 = crystallite_dPdF0 ! initialize stiffness with known good values from last increment
do perturbation = 1 , 2 ! forward and backward perturbation
if ( iand ( pert_method , perturbation ) > 0 ) then ! mask for desired direction
myPert = - pert_Fg * ( - 1.0_pReal ) ** perturbation ! set perturbation step
do k = 1 , 3 ; do l = 1 , 3 ! ...alter individual components
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#ifndef _OPENMP
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if ( iand ( debug_what ( debug_crystallite ) , debug_levelExtensive ) / = 0_pInt ) then
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!$OMP CRITICAL (write2out)
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write ( 6 , '(a,2(1x,i1),1x,a)' ) '<< CRYST >> [[[[[[ Stiffness perturbation' , k , l , ']]]]]]'
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write ( 6 , * )
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!$OMP END CRITICAL (write2out)
endif
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#endif
2010-11-03 22:52:48 +05:30
2011-11-04 18:14:50 +05:30
! --- INITIALIZE UNPERTURBED STATE ---
select case ( numerics_integrator ( numerics_integrationMode ) )
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case ( 1_pInt ) ! Fix-point method: restore to last converged state at end of subinc, since this is probably closest to perturbed state
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!$OMP PARALLEL DO PRIVATE(myNgrains,mySizeState,mySizeDotState)
do e = FEsolving_execElem ( 1 ) , FEsolving_execElem ( 2 )
myNgrains = homogenization_Ngrains ( mesh_element ( 3 , e ) )
do i = FEsolving_execIP ( 1 , e ) , FEsolving_execIP ( 2 , e )
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do g = 1_pInt , myNgrains
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mySizeState = constitutive_sizeState ( g , i , e )
mySizeDotState = constitutive_sizeDotState ( g , i , e )
constitutive_state ( g , i , e ) % p ( 1 : mySizeState ) = constitutive_state_backup ( g , i , e ) % p ( 1 : mySizeState )
constitutive_dotState ( g , i , e ) % p ( 1 : mySizeDotState ) = constitutive_dotState_backup ( g , i , e ) % p ( 1 : mySizeDotState )
enddo ; enddo ; enddo
!OMP END PARALLEL DO
crystallite_Temperature = Temperature_backup
crystallite_Fp = Fp_backup
crystallite_invFp = InvFp_backup
crystallite_Fe = Fe_backup
crystallite_Lp = Lp_backup
crystallite_Tstar_v = Tstar_v_backup
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case ( 2_pInt , 3_pInt ) ! explicit Euler methods: nothing to restore (except for F), since we are only doing a stress integration step
case ( 4_pInt , 5_pInt ) ! explicit Runge-Kutta methods: restore to start of subinc, since we are doing a full integration of state and stress
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!$OMP PARALLEL DO PRIVATE(myNgrains,mySizeState,mySizeDotState)
do e = FEsolving_execElem ( 1 ) , FEsolving_execElem ( 2 )
myNgrains = homogenization_Ngrains ( mesh_element ( 3 , e ) )
do i = FEsolving_execIP ( 1 , e ) , FEsolving_execIP ( 2 , e )
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do g = 1_pInt , myNgrains
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mySizeState = constitutive_sizeState ( g , i , e )
mySizeDotState = constitutive_sizeDotState ( g , i , e )
constitutive_state ( g , i , e ) % p ( 1 : mySizeState ) = constitutive_subState0 ( g , i , e ) % p ( 1 : mySizeState )
constitutive_dotState ( g , i , e ) % p ( 1 : mySizeDotState ) = constitutive_dotState_backup ( g , i , e ) % p ( 1 : mySizeDotState )
enddo ; enddo ; enddo
!OMP END PARALLEL DO
crystallite_Temperature = crystallite_subTemperature0
crystallite_Fp = crystallite_subFp0
crystallite_Fe = crystallite_subFe0
crystallite_Tstar_v = crystallite_subTstar0_v
end select
! --- PERTURB EITHER FORWARD OR BACKWARD ---
crystallite_subF = F_backup
crystallite_subF ( k , l , : , : , : ) = crystallite_subF ( k , l , : , : , : ) + myPert
crystallite_converged = convergenceFlag_backup
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crystallite_todo = crystallite_requested . and . crystallite_converged
where ( crystallite_todo ) crystallite_converged = . false . ! start out non-converged
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select case ( numerics_integrator ( numerics_integrationMode ) )
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case ( 1_pInt )
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call crystallite_integrateStateFPI ( )
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case ( 2_pInt )
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call crystallite_integrateStateEuler ( )
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case ( 3_pInt )
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call crystallite_integrateStateAdaptiveEuler ( )
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case ( 4_pInt )
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call crystallite_integrateStateRK4 ( )
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case ( 5_pInt )
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call crystallite_integrateStateRKCK45 ( )
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end select
!OMP PARALLEL DO PRIVATE(myNgrains)
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do e = FEsolving_execElem ( 1 ) , FEsolving_execElem ( 2 )
myNgrains = homogenization_Ngrains ( mesh_element ( 3 , e ) )
do i = FEsolving_execIP ( 1 , e ) , FEsolving_execIP ( 2 , e )
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do g = 1_pInt , myNgrains
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if ( crystallite_requested ( g , i , e ) . and . crystallite_converged ( g , i , e ) ) then ! converged state warrants stiffness update
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select case ( perturbation )
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case ( 1_pInt )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
dPdF_perturbation1 ( 1 : 3 , 1 : 3 , k , l , g , i , e ) = ( crystallite_P ( 1 : 3 , 1 : 3 , g , i , e ) - P_backup ( 1 : 3 , 1 : 3 , g , i , e ) ) / myPert ! tangent dP_ij/dFg_kl
2012-02-13 19:48:07 +05:30
case ( 2_pInt )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
dPdF_perturbation2 ( 1 : 3 , 1 : 3 , k , l , g , i , e ) = ( crystallite_P ( 1 : 3 , 1 : 3 , g , i , e ) - P_backup ( 1 : 3 , 1 : 3 , g , i , e ) ) / myPert ! tangent dP_ij/dFg_kl
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end select
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endif
enddo ; enddo ; enddo
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!OMP END PARALLEL DO
enddo ; enddo ! k,l loop
endif
enddo ! perturbation direction
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! --- STIFFNESS ACCORDING TO PERTURBATION METHOD AND CONVERGENCE ---
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2010-11-03 22:52:48 +05:30
!$OMP PARALLEL DO PRIVATE(myNgrains)
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do e = FEsolving_execElem ( 1 ) , FEsolving_execElem ( 2 )
myNgrains = homogenization_Ngrains ( mesh_element ( 3 , e ) )
do i = FEsolving_execIP ( 1 , e ) , FEsolving_execIP ( 2 , e )
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do g = 1_pInt , myNgrains
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if ( crystallite_requested ( g , i , e ) . and . convergenceFlag_backup ( g , i , e ) ) then ! central solution converged
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select case ( pert_method )
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case ( 1_pInt )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
crystallite_dPdF ( 1 : 3 , 1 : 3 , 1 : 3 , 1 : 3 , g , i , e ) = dPdF_perturbation1 ( 1 : 3 , 1 : 3 , 1 : 3 , 1 : 3 , g , i , e )
2012-02-13 19:48:07 +05:30
case ( 2_pInt )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
crystallite_dPdF ( 1 : 3 , 1 : 3 , 1 : 3 , 1 : 3 , g , i , e ) = dPdF_perturbation2 ( 1 : 3 , 1 : 3 , 1 : 3 , 1 : 3 , g , i , e )
2012-02-13 19:48:07 +05:30
case ( 3_pInt )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
crystallite_dPdF ( 1 : 3 , 1 : 3 , 1 : 3 , 1 : 3 , g , i , e ) = 0.5_pReal * ( dPdF_perturbation1 ( 1 : 3 , 1 : 3 , 1 : 3 , 1 : 3 , g , i , e ) &
+ dPdF_perturbation2 ( 1 : 3 , 1 : 3 , 1 : 3 , 1 : 3 , g , i , e ) )
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end select
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elseif ( crystallite_requested ( g , i , e ) . and . . not . convergenceFlag_backup ( g , i , e ) ) then ! central solution did not converge
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
crystallite_dPdF ( 1 : 3 , 1 : 3 , 1 : 3 , 1 : 3 , g , i , e ) = crystallite_fallbackdPdF ( 1 : 3 , 1 : 3 , 1 : 3 , 1 : 3 , g , i , e ) ! use (elastic) fallback
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endif
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enddo
enddo
enddo
!$OMP END PARALLEL DO
2010-11-03 22:52:48 +05:30
2011-11-04 18:14:50 +05:30
! --- RESTORE ---
!$OMP PARALLEL DO PRIVATE(myNgrains,mySizeState,mySizeDotState)
do e = FEsolving_execElem ( 1 ) , FEsolving_execElem ( 2 )
myNgrains = homogenization_Ngrains ( mesh_element ( 3 , e ) )
do i = FEsolving_execIP ( 1 , e ) , FEsolving_execIP ( 2 , e )
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do g = 1_pInt , myNgrains
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mySizeState = constitutive_sizeState ( g , i , e )
mySizeDotState = constitutive_sizeDotState ( g , i , e )
constitutive_state ( g , i , e ) % p ( 1 : mySizeState ) = constitutive_state_backup ( g , i , e ) % p ( 1 : mySizeState )
constitutive_dotState ( g , i , e ) % p ( 1 : mySizeDotState ) = constitutive_dotState_backup ( g , i , e ) % p ( 1 : mySizeDotState )
enddo ; enddo ; enddo
!OMP END PARALLEL DO
crystallite_Temperature = Temperature_backup
crystallite_subF = F_backup
crystallite_Fp = Fp_backup
crystallite_invFp = InvFp_backup
crystallite_Fe = Fe_backup
crystallite_Lp = Lp_backup
crystallite_Tstar_v = Tstar_v_backup
crystallite_P = P_backup
crystallite_converged = convergenceFlag_backup
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else ! Calculate Jacobian using analytical expression
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! --- CALCULATE ANALYTIC dPdF ---
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!$OMP PARALLEL DO PRIVATE(myNgrains,Fp_inv_0,C,Eigval,Eigvec,Fp_exp1,Fp_exp2,Fp_inv_current,&
!$OMP dSdFe_mat1,dSdFe_mat2,Fpinv_rate,FDot_temp,counter,phi_mat,Tensor1,Tensor2,Tensor3,Tensor4,&
!$OMP Tensor5,V_dir,dLp_dT_constitutive,dLp_dT,C99,A99,A_inv99,AnzNegEW,error,&
!$OMP dFedF99,dFedF_old99,dFedF,fixedpt_iter,fixedpt_error,dSdF)
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do e = FEsolving_execElem ( 1 ) , FEsolving_execElem ( 2 ) ! iterate over elements to be processed
myNgrains = homogenization_Ngrains ( mesh_element ( 3 , e ) )
do i = FEsolving_execIP ( 1 , e ) , FEsolving_execIP ( 2 , e ) ! iterate over IPs of this element to be processed
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do g = 1_pInt , myNgrains
Fp_inv_0 = math_inv33 ( crystallite_subFp0 ( 1 : 3 , 1 : 3 , g , i , e ) )
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C = math_Mandel66to3333 ( constitutive_homogenizedC ( g , i , e ) )
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call math_spectralDecompositionSym33 ( - ( 1.0_pReal - Lp_frac ) * crystallite_subdt ( g , i , e ) * 0.5_pReal &
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* crystallite_subLp0 ( 1 : 3 , 1 : 3 , g , i , e ) , Eigval , Eigvec , error )
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Fp_exp1 = 0.0_pReal
Fp_exp1 ( 1 , 1 ) = exp ( Eigval ( 1 ) )
Fp_exp1 ( 2 , 2 ) = exp ( Eigval ( 2 ) )
Fp_exp1 ( 3 , 3 ) = exp ( Eigval ( 3 ) )
Fp_exp1 = math_mul33x33 ( math_mul33x33 ( Eigvec , Fp_exp1 ) , math_transpose33 ( Eigvec ) ) ! exp(-(1-Lp_frac)*Lp old*dt/2)
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call math_spectralDecompositionSym33 ( - ( Lp_frac ) * crystallite_subdt ( g , i , e ) * 0.5_pReal * &
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crystallite_Lp ( 1 : 3 , 1 : 3 , g , i , e ) , Eigval , Eigvec , error )
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Fp_exp2 = 0.0_pReal
Fp_exp2 ( 1 , 1 ) = exp ( Eigval ( 1 ) )
Fp_exp2 ( 2 , 2 ) = exp ( Eigval ( 2 ) )
Fp_exp2 ( 3 , 3 ) = exp ( Eigval ( 3 ) )
Fp_exp2 = math_mul33x33 ( math_mul33x33 ( Eigvec , Fp_exp2 ) , math_transpose33 ( Eigvec ) ) ! exp(-(Lp_frac)*Lp current*dt/2)
Fp_inv_current = math_mul33x33 ( math_mul33x33 ( math_mul33x33 ( math_mul33x33 ( Fp_inv_0 , &
Fp_exp1 ) , Fp_exp2 ) , Fp_exp2 ) , Fp_exp1 ) ! Fp current^-1 = Fp old^-1 * exp(-(1-Lp_frac)*Lp old*dt/2) * exp(-(Lp_frac)*Lp current*dt) * exp(-(1-Lp_frac)*Lp old*dt/2)
dSdFe_mat2 = math_mul33x33 ( math_mul33x33 ( Fp_exp1 , Fp_exp2 ) , Eigvec )
dSdFe_mat1 = math_mul33x33 ( math_mul33x33 ( crystallite_subF ( 1 : 3 , 1 : 3 , g , i , e ) , Fp_inv_0 ) , dSdFe_mat2 )
dSdFe_mat2 = math_transpose33 ( dSdFe_mat2 )
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Fpinv_rate = - math_mul33x33 ( crystallite_subF ( 1 : 3 , 1 : 3 , g , i , e ) , math_mul33x33 ( Fp_inv_current , &
( 1.0_pReal - Lp_frac ) * crystallite_subLp0 ( 1 : 3 , 1 : 3 , g , i , e ) + Lp_frac * crystallite_Lp ( 1 : 3 , 1 : 3 , g , i , e ) ) ) ! F * dFp^-1 = F * dFp^-1/dt *dt... dFp may overshoot dF by small ammount as
FDot_temp = crystallite_subF ( 1 : 3 , 1 : 3 , g , i , e ) - crystallite_F0 ( 1 : 3 , 1 : 3 , g , i , e ) ! dF = dFe + dFp is not strictly enforced (can result in small oscillations in dP/dF)
2012-02-27 23:10:28 +05:30
counter = 0.0_pReal
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phi_mat = 0.0_pReal
do h = 1_pInt , 3_pInt ; do j = 1_pInt , 3_pInt
if ( Eigval ( h ) == Eigval ( j ) ) then
phi_mat ( h , j ) = 1.0_pReal
else
phi_mat ( h , j ) = sinh ( Eigval ( h ) - Eigval ( j ) ) / ( Eigval ( h ) - Eigval ( j ) )
endif
if ( abs ( FDot_temp ( h , j ) ) . lt . relevantStrain ) then
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counter = counter + 1.0_pReal
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FDot_temp ( h , j ) = 0.0_pReal
else
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FDot_temp ( h , j ) = crystallite_dt ( g , i , e ) / FDot_temp ( h , j )
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endif
enddo ; enddo
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if ( counter . lt . 9.0_pReal ) then
FDot_temp = FDot_temp / ( 9.0_pReal - counter )
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endif
Tensor1 = 0.0_pReal
Tensor2 = 0.0_pReal
Tensor3 = 0.0_pReal
Tensor4 = 0.0_pReal
do h = 1_pInt , 3_pInt ; do j = 1_pInt , 3_pInt
V_dir = 0.0_pReal
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V_dir ( h , j ) = - Lp_frac * crystallite_subdt ( g , i , e )
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V_dir = math_mul33x33 ( math_mul33x33 ( math_transpose33 ( Eigvec ) , V_dir ) , Eigvec )
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if ( time_sensitive ) then
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Tensor1 ( h , j , 1 : 3 , 1 : 3 ) = Fpinv_rate ( h , j ) * FDot_temp ! assuming dF_old = dF_new... need full-rank Tensor1 otherwise. good only for unidirectional loading
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endif
Tensor1 ( h , j , h , 1 : 3 ) = Tensor1 ( h , j , h , 1 : 3 ) + Fp_inv_current ( 1 : 3 , j ) ! dF_im/dF_kl * (Fp current^-1)_mj + d(Fp current^-1)_ij/dt * dt/Fdot_kl
Tensor2 ( 1 : 3 , 1 : 3 , h , j ) = math_mul33x33 ( math_mul33x33 ( dSdFe_mat1 , V_dir * phi_mat ) , dSdFe_mat2 )
Tensor3 ( h , j , 1 : 3 , 1 : 3 ) = math_mul33x33 ( C ( h , j , 1 : 3 , 1 : 3 ) , &
math_transpose33 ( crystallite_subFe0 ( 1 : 3 , 1 : 3 , g , i , e ) ) ) ! dS_ij/dFe_kl
enddo ; enddo
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call constitutive_LpAndItsTangent ( Lp_constitutive , dLp_dT_constitutive , &
crystallite_Tstar_v ( 1 : 6 , g , i , e ) , crystallite_Temperature ( g , i , e ) , g , i , e )
dLp_dT = math_Plain99to3333 ( dLp_dT_constitutive )
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Tensor4 = math_mul3333xx3333 ( math_mul3333xx3333 ( Tensor2 , dLp_dT ) , Tensor3 ) ! applying chain rule to get F_im * dFp^-1_mj/dFe_kl
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A99 = math_identity2nd ( 9_pInt ) - math_Plain3333to99 ( Tensor4 )
C99 = math_Plain3333to99 ( Tensor1 ) ! [I - F_im * dFp^-1_mj/dFe_op]*dFe_op/dF_kl = dF_im/dF_kl * (Fp current^-1)_mj + d(Fp current^-1)_ij/dt * dt/Fdot_kl
call math_invert ( 9_pInt , A99 , A_inv99 , AnzNegEW , error )
dFedF99 = math_mul99x99 ( A_inv99 , C99 ) ! solve for dFe_ij/dF_kl
fixedpt_iter = 1_pInt
fixedpt_error = 1.0_pReal
do while ( ( fixedpt_iter . lt . 10_pInt ) . and . ( fixedpt_error . gt . 1e-20_pReal ) ) ! if solution is not accurate, use as estimate for better solution
dFedF_old99 = dFedF99
A99 = math_mul99x99 ( A_inv99 , A99 )
C99 = dFedF_old99
call math_invert ( 9_pInt , A99 , A_inv99 , AnzNegEW , error )
dFedF99 = math_mul99x99 ( A_inv99 , C99 )
fixedpt_error = maxval ( abs ( dFedF99 - dFedF_old99 ) )
fixedpt_iter = fixedpt_iter + 1_pInt
enddo
dFedF = math_Plain99to3333 ( dFedF99 )
do o = 1_pInt , 3_pInt ; do p = 1_pInt , 3_pInt
dFedF ( 1 : 3 , 1 : 3 , o , p ) = math_transpose33 ( dFedF ( 1 : 3 , 1 : 3 , o , p ) )
enddo ; enddo
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Tensor4 = math_mul3333xx3333 ( Tensor4 , dFedF )
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dSdF = math_mul3333xx3333 ( Tensor3 , dFedF ) ! dS/dF = dS/dFe * dFe/dF
do o = 1_pInt , 3_pInt ; do p = 1_pInt , 3_pInt
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crystallite_dPdF ( 1 : 3 , 1 : 3 , o , p , g , i , e ) = math_mul33x33 ( math_mul33x33 ( math_transpose33 ( &
dFedF ( 1 : 3 , 1 : 3 , o , p ) ) , math_Mandel6to33 ( crystallite_Tstar_v ) ) , math_transpose33 ( &
Fp_inv_current ) ) + & ! dP/dF = dFe/dF * S * Fp^-T...
math_mul33x33 ( math_mul33x33 ( math_mul33x33 ( crystallite_subF ( 1 : 3 , 1 : 3 , g , i , e ) , &
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Fp_inv_current ) , math_Mandel6to33 ( crystallite_Tstar_v ) ) , math_transpose33 ( &
math_mul33x33 ( math_inv33 ( crystallite_subF ( 1 : 3 , 1 : 3 , g , i , e ) ) , Tensor4 ( 1 : 3 , 1 : 3 , o , p ) &
+ Fpinv_rate * FDot_temp ( o , p ) ) ) ) & ! + Fe * S * dFp^-T/dF...
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+ math_mul33x33 ( math_mul33x33 ( crystallite_subF ( 1 : 3 , 1 : 3 , g , i , e ) , Fp_inv_current ) , &
math_mul33x33 ( dSdF ( 1 : 3 , 1 : 3 , o , p ) , math_transpose33 ( Fp_inv_current ) ) ) ! + Fe * dS/dF * Fp^-T
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enddo ; enddo
enddo ; enddo ; enddo
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!$OMP END PARALLEL DO
2012-02-23 01:41:09 +05:30
endif
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
endif ! jacobian calculation
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2012-03-09 01:55:28 +05:30
end subroutine crystallite_stressAndItsTangent
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!********************************************************************
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! integrate stress, state and Temperature with
! 4h order explicit Runge Kutta method
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!********************************************************************
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subroutine crystallite_integrateStateRK4 ( gg , ii , ee )
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!*** variables and functions from other modules ***!
use prec , only : pInt , &
pReal
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use numerics , only : numerics_integrationMode
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use debug , only : debug_what , &
debug_crystallite , &
debug_levelBasic , &
debug_levelExtensive , &
debug_levelSelective , &
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debug_e , &
debug_i , &
debug_g , &
debug_StateLoopDistribution
use FEsolving , only : FEsolving_execElem , &
FEsolving_execIP
use mesh , only : mesh_element , &
mesh_NcpElems , &
mesh_maxNips
use material , only : homogenization_Ngrains , &
homogenization_maxNgrains
use constitutive , only : constitutive_sizeDotState , &
constitutive_state , &
constitutive_subState0 , &
constitutive_dotState , &
constitutive_RK4dotState , &
constitutive_collectDotState , &
constitutive_dotTemperature , &
constitutive_microstructure
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implicit none
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2012-01-26 18:18:59 +05:30
real ( pReal ) , dimension ( 4 ) , parameter :: timeStepFraction = ( / 0.5_pReal , 0.5_pReal , 1.0_pReal , 1.0_pReal / ) ! factor giving the fraction of the original timestep used for Runge Kutta Integration
real ( pReal ) , dimension ( 4 ) , parameter :: weight = ( / 1.0_pReal , 2.0_pReal , 2.0_pReal , 1.0_pReal / ) ! weight of slope used for Runge Kutta integration
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!*** input variables ***!
integer ( pInt ) , optional , intent ( in ) :: ee , & ! element index
ii , & ! integration point index
gg ! grain index
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!*** output variables ***!
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!*** local variables ***!
integer ( pInt ) e , & ! element index in element loop
i , & ! integration point index in ip loop
g , & ! grain index in grain loop
n , &
mySizeDotState
integer ( pInt ) , dimension ( 2 ) :: eIter ! bounds for element iteration
integer ( pInt ) , dimension ( 2 , mesh_NcpElems ) :: iIter , & ! bounds for ip iteration
gIter ! bounds for grain iteration
real ( pReal ) , dimension ( homogenization_maxNgrains , mesh_maxNips , mesh_NcpElems ) :: &
RK4dotTemperature ! evolution of Temperature of each grain for Runge Kutta integration
logical singleRun ! flag indicating computation for single (g,i,e) triple
if ( present ( ee ) . and . present ( ii ) . and . present ( gg ) ) then
eIter = ee
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
iIter ( 1 : 2 , ee ) = ii
gIter ( 1 : 2 , ee ) = gg
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singleRun = . true .
else
eIter = FEsolving_execElem ( 1 : 2 )
do e = eIter ( 1 ) , eIter ( 2 )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
iIter ( 1 : 2 , e ) = FEsolving_execIP ( 1 : 2 , e )
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gIter ( 1 : 2 , e ) = [ 1_pInt , homogenization_Ngrains ( mesh_element ( 3 , e ) ) ]
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enddo
singleRun = . false .
endif
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! --- RESET DOTSTATE ---
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!$OMP PARALLEL PRIVATE(mySizeDotState)
!$OMP DO
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
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constitutive_dotState ( g , i , e ) % p = 0.0_pReal ! reset dotState to zero
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enddo ; enddo ; enddo
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!$OMP ENDDO
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! --- FIRST RUNGE KUTTA STEP ---
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RK4dotTemperature = 0.0_pReal ! initialize Runge-Kutta dotTemperature
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!$OMP DO
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
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constitutive_RK4dotState ( g , i , e ) % p = 0.0_pReal ! initialize Runge-Kutta dotState
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if ( crystallite_todo ( g , i , e ) ) then
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
call constitutive_collectDotState ( crystallite_Tstar_v ( 1 : 6 , g , i , e ) , crystallite_Fe , crystallite_Fp , &
2011-02-25 15:23:20 +05:30
crystallite_Temperature ( g , i , e ) , crystallite_subdt ( g , i , e ) , crystallite_orientation , g , i , e )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
crystallite_dotTemperature ( g , i , e ) = constitutive_dotTemperature ( crystallite_Tstar_v ( 1 : 6 , g , i , e ) , &
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crystallite_Temperature ( g , i , e ) , g , i , e )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
endif
enddo ; enddo ; enddo
!$OMP ENDDO
!$OMP DO
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
if ( crystallite_todo ( g , i , e ) ) then
if ( any ( constitutive_dotState ( g , i , e ) % p / = constitutive_dotState ( g , i , e ) % p ) & ! NaN occured in dotState
. or . crystallite_dotTemperature ( g , i , e ) / = crystallite_dotTemperature ( g , i , e ) ) then ! NaN occured in dotTemperature
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if ( . not . crystallite_localConstitution ( g , i , e ) ) then ! if broken non-local...
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!$OMP CRITICAL (checkTodo)
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crystallite_todo = crystallite_todo . and . crystallite_localConstitution ! ...all non-locals skipped
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!$OMP END CRITICAL (checkTodo)
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else ! if broken local...
crystallite_todo ( g , i , e ) = . false . ! ... skip this one next time
endif
endif
endif
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enddo ; enddo ; enddo
!$OMP ENDDO
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! --- SECOND TO FOURTH RUNGE KUTTA STEP PLUS FINAL INTEGRATION ---
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do n = 1_pInt , 4_pInt
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! --- state update ---
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!$OMP DO
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
2010-10-01 17:48:49 +05:30
if ( crystallite_todo ( g , i , e ) ) then
mySizeDotState = constitutive_sizeDotState ( g , i , e )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
if ( n < 4 ) then
constitutive_RK4dotState ( g , i , e ) % p = constitutive_RK4dotState ( g , i , e ) % p + weight ( n ) * constitutive_dotState ( g , i , e ) % p
RK4dotTemperature ( g , i , e ) = RK4dotTemperature ( g , i , e ) + weight ( n ) * crystallite_dotTemperature ( g , i , e )
elseif ( n == 4 ) then
2012-01-11 22:26:35 +05:30
constitutive_dotState ( g , i , e ) % p = ( constitutive_RK4dotState ( g , i , e ) % p + &
weight ( n ) * constitutive_dotState ( g , i , e ) % p ) / 6.0_pReal ! use weighted RKdotState for final integration
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
crystallite_dotTemperature ( g , i , e ) = ( RK4dotTemperature ( g , i , e ) + weight ( n ) * crystallite_dotTemperature ( g , i , e ) ) / 6.0_pReal
2010-10-26 19:34:33 +05:30
endif
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
endif
enddo ; enddo ; enddo
!$OMP ENDDO
!$OMP DO
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
if ( crystallite_todo ( g , i , e ) ) then
mySizeDotState = constitutive_sizeDotState ( g , i , e )
2010-10-01 17:48:49 +05:30
constitutive_state ( g , i , e ) % p ( 1 : mySizeDotState ) = constitutive_subState0 ( g , i , e ) % p ( 1 : mySizeDotState ) &
+ constitutive_dotState ( g , i , e ) % p ( 1 : mySizeDotState ) * crystallite_subdt ( g , i , e ) * timeStepFraction ( n )
crystallite_Temperature ( g , i , e ) = crystallite_subTemperature0 ( g , i , e ) &
+ crystallite_dotTemperature ( g , i , e ) * crystallite_subdt ( g , i , e ) * timeStepFraction ( n )
endif
enddo ; enddo ; enddo
2010-11-03 22:52:48 +05:30
!$OMP ENDDO
2010-10-01 17:48:49 +05:30
! --- update dependent states ---
2010-11-03 22:52:48 +05:30
!$OMP DO
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
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if ( crystallite_todo ( g , i , e ) ) then
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call constitutive_microstructure ( crystallite_Temperature ( g , i , e ) , crystallite_Fe ( 1 : 3 , 1 : 3 , g , i , e ) , &
crystallite_Fp ( 1 : 3 , 1 : 3 , g , i , e ) , g , i , e ) ! update dependent state variables to be consistent with basic states
2010-10-01 17:48:49 +05:30
endif
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enddo ; enddo ; enddo
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!$OMP ENDDO
2010-10-01 17:48:49 +05:30
! --- stress integration ---
2010-11-03 22:52:48 +05:30
!$OMP DO
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
2010-10-01 17:48:49 +05:30
if ( crystallite_todo ( g , i , e ) ) then
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if ( crystallite_integrateStress ( g , i , e , timeStepFraction ( n ) ) ) then ! fraction of original times step
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if ( n == 4 ) then ! final integration step
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#ifndef _OPENMP
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if ( iand ( debug_what ( debug_crystallite ) , debug_levelExtensive ) / = 0_pInt &
. and . ( ( e == debug_e . and . i == debug_i . and . g == debug_g ) &
. or . . not . iand ( debug_what ( debug_crystallite ) , debug_levelSelective ) / = 0_pInt ) ) then
2010-10-01 17:48:49 +05:30
mySizeDotState = constitutive_sizeDotState ( g , i , e )
2012-02-01 00:48:55 +05:30
write ( 6 , '(a,i8,1x,i2,1x,i3)' ) '<< CRYST >> updateState at el ip g ' , e , i , g
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write ( 6 , * )
2012-02-01 00:48:55 +05:30
write ( 6 , '(a,/,(12x,12(e12.5,1x)))' ) '<< CRYST >> dotState' , constitutive_dotState ( g , i , e ) % p ( 1 : mySizeDotState )
2011-03-29 12:57:19 +05:30
write ( 6 , * )
2012-02-01 00:48:55 +05:30
write ( 6 , '(a,/,(12x,12(e12.5,1x)))' ) '<< CRYST >> new state' , constitutive_state ( g , i , e ) % p ( 1 : mySizeDotState )
2011-03-29 12:57:19 +05:30
write ( 6 , * )
2010-10-01 17:48:49 +05:30
endif
2011-03-29 12:57:19 +05:30
#endif
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crystallite_converged ( g , i , e ) = . true . ! ... converged per definition
crystallite_todo ( g , i , e ) = . false . ! ... integration done
2012-03-09 01:55:28 +05:30
if ( iand ( debug_what ( debug_crystallite ) , debug_levelBasic ) / = 0_pInt ) then
2011-03-21 16:01:17 +05:30
!$OMP CRITICAL (distributionState)
debug_StateLoopDistribution ( n , numerics_integrationMode ) = &
debug_StateLoopDistribution ( n , numerics_integrationMode ) + 1
!$OMP END CRITICAL (distributionState)
endif
2010-10-01 17:48:49 +05:30
endif
2012-03-09 01:55:28 +05:30
else ! broken stress integration
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if ( . not . crystallite_localConstitution ( g , i , e ) ) then ! if broken non-local...
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!$OMP CRITICAL (checkTodo)
2010-10-01 17:48:49 +05:30
crystallite_todo = crystallite_todo . and . crystallite_localConstitution ! ...all non-locals skipped
2010-11-03 22:52:48 +05:30
!$OMP END CRITICAL (checkTodo)
2010-10-01 17:48:49 +05:30
else ! if broken local...
crystallite_todo ( g , i , e ) = . false . ! ... skip this one next time
endif
endif
endif
2010-10-26 19:34:33 +05:30
constitutive_dotState ( g , i , e ) % p = 0.0_pReal ! reset dotState to zero
2010-10-01 17:48:49 +05:30
enddo ; enddo ; enddo
2010-11-03 22:52:48 +05:30
!$OMP ENDDO
2010-10-01 17:48:49 +05:30
! --- dot state and RK dot state---
if ( n < 4 ) then
2010-11-03 22:52:48 +05:30
!$OMP DO
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
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if ( crystallite_todo ( g , i , e ) ) then
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
call constitutive_collectDotState ( crystallite_Tstar_v ( 1 : 6 , g , i , e ) , crystallite_Fe , crystallite_Fp , &
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crystallite_Temperature ( g , i , e ) , timeStepFraction ( n ) * crystallite_subdt ( g , i , e ) , & ! fraction of original timestep
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crystallite_orientation , g , i , e )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
crystallite_dotTemperature ( g , i , e ) = constitutive_dotTemperature ( crystallite_Tstar_v ( 1 : 6 , g , i , e ) , &
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crystallite_Temperature ( g , i , e ) , g , i , e )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
endif
enddo ; enddo ; enddo
!$OMP ENDDO
!$OMP DO
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
if ( crystallite_todo ( g , i , e ) ) then
if ( any ( constitutive_dotState ( g , i , e ) % p / = constitutive_dotState ( g , i , e ) % p ) & ! NaN occured in dotState
. or . crystallite_dotTemperature ( g , i , e ) / = crystallite_dotTemperature ( g , i , e ) ) then ! NaN occured in dotTemperature
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if ( . not . crystallite_localConstitution ( g , i , e ) ) then ! if broken non-local...
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!$OMP CRITICAL (checkTodo)
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crystallite_todo = crystallite_todo . and . crystallite_localConstitution ! ...all non-locals skipped
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!$OMP END CRITICAL (checkTodo)
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else ! if broken local...
crystallite_todo ( g , i , e ) = . false . ! ... skip this one next time
endif
endif
endif
enddo ; enddo ; enddo
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!$OMP ENDDO
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endif
enddo
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!$OMP END PARALLEL
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! --- CHECK CONVERGENCE ---
crystallite_todo = . false . ! done with integration
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if ( . not . singleRun ) then ! if not requesting Integration of just a single IP
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if ( any ( . not . crystallite_converged . and . . not . crystallite_localConstitution ) ) then ! any non-local not yet converged (or broken)...
crystallite_converged = crystallite_converged . and . crystallite_localConstitution ! ...restart all non-local as not converged
endif
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endif
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end subroutine crystallite_integrateStateRK4
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!********************************************************************
! integrate stress, state and Temperature with
! 5th order Runge-Kutta Cash-Karp method with adaptive step size
! (use 5th order solution to advance = "local extrapolation")
!********************************************************************
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subroutine crystallite_integrateStateRKCK45 ( gg , ii , ee )
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!*** variables and functions from other modules ***!
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use debug , only : debug_what , &
debug_crystallite , &
debug_levelBasic , &
debug_levelExtensive , &
debug_levelSelective , &
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debug_e , &
debug_i , &
debug_g , &
debug_StateLoopDistribution
use numerics , only : rTol_crystalliteState , &
rTol_crystalliteTemperature , &
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numerics_integrationMode
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use FEsolving , only : FEsolving_execElem , &
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FEsolving_execIP
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use mesh , only : mesh_element , &
mesh_NcpElems , &
mesh_maxNips
use material , only : homogenization_Ngrains , &
homogenization_maxNgrains
use constitutive , only : constitutive_sizeDotState , &
constitutive_maxSizeDotState , &
constitutive_state , &
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constitutive_aTolState , &
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constitutive_subState0 , &
constitutive_dotState , &
constitutive_RKCK45dotState , &
constitutive_collectDotState , &
constitutive_dotTemperature , &
constitutive_microstructure
implicit none
!*** input variables ***!
integer ( pInt ) , optional , intent ( in ) :: ee , & ! element index
ii , & ! integration point index
gg ! grain index
!*** local variables ***!
integer ( pInt ) e , & ! element index in element loop
i , & ! integration point index in ip loop
g , & ! grain index in grain loop
n , & ! stage index in integration stage loop
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mySizeDotState , & ! size of dot State
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s ! state index
integer ( pInt ) , dimension ( 2 ) :: eIter ! bounds for element iteration
integer ( pInt ) , dimension ( 2 , mesh_NcpElems ) :: iIter , & ! bounds for ip iteration
gIter ! bounds for grain iteration
real ( pReal ) , dimension ( 6 , homogenization_maxNgrains , mesh_maxNips , mesh_NcpElems ) :: &
RKCK45dotTemperature ! evolution of Temperature of each grain for Runge Kutta Cash Karp integration
real ( pReal ) , dimension ( 5 , 5 ) :: a ! coefficients in Butcher tableau (used for preliminary integration in stages 2 to 6)
real ( pReal ) , dimension ( 6 ) :: b , db ! coefficients in Butcher tableau (used for final integration and error estimate)
real ( pReal ) , dimension ( 5 ) :: c ! coefficients in Butcher tableau (fractions of original time step in stages 2 to 6)
real ( pReal ) , dimension ( constitutive_maxSizeDotState , homogenization_maxNgrains , mesh_maxNips , mesh_NcpElems ) :: &
stateResiduum , & ! residuum from evolution in micrstructure
relStateResiduum ! relative residuum from evolution in microstructure
real ( pReal ) , dimension ( homogenization_maxNgrains , mesh_maxNips , mesh_NcpElems ) :: &
temperatureResiduum , & ! residuum from evolution in temperature
relTemperatureResiduum ! relative residuum from evolution in temperature
logical singleRun ! flag indicating computation for single (g,i,e) triple
! --- FILL BUTCHER TABLEAU ---
a = 0.0_pReal
b = 0.0_pReal
db = 0.0_pReal
c = 0.0_pReal
a ( 1 , 1 ) = 0.2_pReal
a ( 1 , 2 ) = 0.075_pReal
a ( 2 , 2 ) = 0.225_pReal
a ( 1 , 3 ) = 0.3_pReal
a ( 2 , 3 ) = - 0.9_pReal
a ( 3 , 3 ) = 1.2_pReal
a ( 1 , 4 ) = - 1 1.0_pReal / 5 4.0_pReal
a ( 2 , 4 ) = 2.5_pReal
a ( 3 , 4 ) = - 7 0.0_pReal / 2 7.0_pReal
a ( 4 , 4 ) = 3 5.0_pReal / 2 7.0_pReal
a ( 1 , 5 ) = 163 1.0_pReal / 5529 6.0_pReal
a ( 2 , 5 ) = 17 5.0_pReal / 51 2.0_pReal
a ( 3 , 5 ) = 57 5.0_pReal / 1382 4.0_pReal
a ( 4 , 5 ) = 4427 5.0_pReal / 11059 2.0_pReal
a ( 5 , 5 ) = 25 3.0_pReal / 409 6.0_pReal
b ( 1 ) = 3 7.0_pReal / 37 8.0_pReal
b ( 3 ) = 25 0.0_pReal / 62 1.0_pReal
b ( 4 ) = 12 5.0_pReal / 59 4.0_pReal
b ( 6 ) = 51 2.0_pReal / 177 1.0_pReal
db ( 1 ) = b ( 1 ) - 282 5.0_pReal / 2764 8.0_pReal
db ( 3 ) = b ( 3 ) - 1857 5.0_pReal / 4838 4.0_pReal
db ( 4 ) = b ( 4 ) - 1352 5.0_pReal / 5529 6.0_pReal
db ( 5 ) = - 27 7.0_pReal / 1433 6.0_pReal
db ( 6 ) = b ( 6 ) - 0.25_pReal
c ( 1 ) = 0.2_pReal
c ( 2 ) = 0.3_pReal
c ( 3 ) = 0.6_pReal
c ( 4 ) = 1.0_pReal
c ( 5 ) = 0.875_pReal
! --- LOOP ITERATOR FOR ELEMENT, GRAIN, IP ---
if ( present ( ee ) . and . present ( ii ) . and . present ( gg ) ) then
eIter = ee
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
iIter ( 1 : 2 , ee ) = ii
gIter ( 1 : 2 , ee ) = gg
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singleRun = . true .
else
eIter = FEsolving_execElem ( 1 : 2 )
do e = eIter ( 1 ) , eIter ( 2 )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
iIter ( 1 : 2 , e ) = FEsolving_execIP ( 1 : 2 , e )
2012-02-21 22:01:37 +05:30
gIter ( 1 : 2 , e ) = [ 1_pInt , homogenization_Ngrains ( mesh_element ( 3 , e ) ) ]
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enddo
singleRun = . false .
endif
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! --- RESET DOTSTATE ---
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!$OMP PARALLEL PRIVATE(mySizeDotState)
2010-10-01 17:48:49 +05:30
2010-11-03 22:52:48 +05:30
!$OMP DO
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
2010-10-26 19:34:33 +05:30
constitutive_dotState ( g , i , e ) % p = 0.0_pReal ! reset dotState to zero
enddo ; enddo ; enddo
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!$OMP ENDDO
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! --- FIRST RUNGE KUTTA STEP ---
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#ifndef _OPENMP
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if ( iand ( debug_what ( debug_crystallite ) , debug_levelExtensive ) / = 0_pInt ) then
2012-02-01 00:48:55 +05:30
write ( 6 , '(a,1x,i1)' ) '<< CRYST >> RUNGE KUTTA STEP' , 1
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endif
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#endif
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!$OMP DO
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
2010-10-01 17:48:49 +05:30
if ( crystallite_todo ( g , i , e ) ) then
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
call constitutive_collectDotState ( crystallite_Tstar_v ( 1 : 6 , g , i , e ) , crystallite_Fe , crystallite_Fp , &
2011-02-25 15:23:20 +05:30
crystallite_Temperature ( g , i , e ) , crystallite_subdt ( g , i , e ) , crystallite_orientation , g , i , e )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
crystallite_dotTemperature ( g , i , e ) = constitutive_dotTemperature ( crystallite_Tstar_v ( 1 : 6 , g , i , e ) , &
2010-10-01 17:48:49 +05:30
crystallite_Temperature ( g , i , e ) , g , i , e )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
endif
2011-03-29 12:57:19 +05:30
enddo ; enddo ; enddo
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
!$OMP ENDDO
!$OMP DO
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
if ( crystallite_todo ( g , i , e ) ) then
if ( any ( constitutive_dotState ( g , i , e ) % p / = constitutive_dotState ( g , i , e ) % p ) & ! NaN occured in dotState
. or . crystallite_dotTemperature ( g , i , e ) / = crystallite_dotTemperature ( g , i , e ) ) then ! NaN occured in dotTemperature
2010-10-01 17:48:49 +05:30
if ( . not . crystallite_localConstitution ( g , i , e ) ) then ! if broken non-local...
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!$OMP CRITICAL (checkTodo)
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crystallite_todo = crystallite_todo . and . crystallite_localConstitution ! ...all non-locals skipped
2010-11-03 22:52:48 +05:30
!$OMP END CRITICAL (checkTodo)
2010-10-01 17:48:49 +05:30
else ! if broken local...
crystallite_todo ( g , i , e ) = . false . ! ... skip this one next time
endif
endif
endif
enddo ; enddo ; enddo
2010-11-03 22:52:48 +05:30
!$OMP ENDDO
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! --- SECOND TO SIXTH RUNGE KUTTA STEP ---
2012-02-21 22:01:37 +05:30
do n = 1_pInt , 5_pInt
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! --- state update ---
2010-11-03 22:52:48 +05:30
!$OMP DO
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
2010-10-01 17:48:49 +05:30
if ( crystallite_todo ( g , i , e ) ) then
2010-11-03 22:52:48 +05:30
mySizeDotState = constitutive_sizeDotState ( g , i , e )
2010-10-26 19:34:33 +05:30
constitutive_RKCK45dotState ( n , g , i , e ) % p = constitutive_dotState ( g , i , e ) % p ! store Runge-Kutta dotState
RKCK45dotTemperature ( n , g , i , e ) = crystallite_dotTemperature ( g , i , e ) ! store Runge-Kutta dotTemperature
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
endif
enddo ; enddo ; enddo
!$OMP ENDDO
!$OMP DO
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
if ( crystallite_todo ( g , i , e ) ) then
if ( n == 1 ) then ! NEED TO DO THE ADDITION IN THIS LENGTHY WAY BECAUSE OF PARALLELIZATION (CAN'T USE A REDUCTION CLAUSE ON A POINTER OR USER DEFINED TYPE)
constitutive_dotState ( g , i , e ) % p = a ( 1 , 1 ) * constitutive_RKCK45dotState ( 1 , g , i , e ) % p
crystallite_dotTemperature ( g , i , e ) = a ( 1 , 1 ) * RKCK45dotTemperature ( 1 , g , i , e )
elseif ( n == 2 ) then
constitutive_dotState ( g , i , e ) % p = a ( 1 , 2 ) * constitutive_RKCK45dotState ( 1 , g , i , e ) % p &
+ a ( 2 , 2 ) * constitutive_RKCK45dotState ( 2 , g , i , e ) % p
crystallite_dotTemperature ( g , i , e ) = a ( 1 , 2 ) * RKCK45dotTemperature ( 1 , g , i , e ) &
+ a ( 2 , 2 ) * RKCK45dotTemperature ( 2 , g , i , e )
elseif ( n == 3 ) then
constitutive_dotState ( g , i , e ) % p = a ( 1 , 3 ) * constitutive_RKCK45dotState ( 1 , g , i , e ) % p &
+ a ( 2 , 3 ) * constitutive_RKCK45dotState ( 2 , g , i , e ) % p &
+ a ( 3 , 3 ) * constitutive_RKCK45dotState ( 3 , g , i , e ) % p
crystallite_dotTemperature ( g , i , e ) = a ( 1 , 3 ) * RKCK45dotTemperature ( 1 , g , i , e ) &
+ a ( 2 , 3 ) * RKCK45dotTemperature ( 2 , g , i , e ) &
+ a ( 3 , 3 ) * RKCK45dotTemperature ( 3 , g , i , e )
elseif ( n == 4 ) then
constitutive_dotState ( g , i , e ) % p = a ( 1 , 4 ) * constitutive_RKCK45dotState ( 1 , g , i , e ) % p &
+ a ( 2 , 4 ) * constitutive_RKCK45dotState ( 2 , g , i , e ) % p &
+ a ( 3 , 4 ) * constitutive_RKCK45dotState ( 3 , g , i , e ) % p &
+ a ( 4 , 4 ) * constitutive_RKCK45dotState ( 4 , g , i , e ) % p
crystallite_dotTemperature ( g , i , e ) = a ( 1 , 4 ) * RKCK45dotTemperature ( 1 , g , i , e ) &
+ a ( 2 , 4 ) * RKCK45dotTemperature ( 2 , g , i , e ) &
+ a ( 3 , 4 ) * RKCK45dotTemperature ( 3 , g , i , e ) &
+ a ( 4 , 4 ) * RKCK45dotTemperature ( 4 , g , i , e )
elseif ( n == 5 ) then
constitutive_dotState ( g , i , e ) % p = a ( 1 , 5 ) * constitutive_RKCK45dotState ( 1 , g , i , e ) % p &
+ a ( 2 , 5 ) * constitutive_RKCK45dotState ( 2 , g , i , e ) % p &
+ a ( 3 , 5 ) * constitutive_RKCK45dotState ( 3 , g , i , e ) % p &
+ a ( 4 , 5 ) * constitutive_RKCK45dotState ( 4 , g , i , e ) % p &
+ a ( 5 , 5 ) * constitutive_RKCK45dotState ( 5 , g , i , e ) % p
crystallite_dotTemperature ( g , i , e ) = a ( 1 , 5 ) * RKCK45dotTemperature ( 1 , g , i , e ) &
+ a ( 2 , 5 ) * RKCK45dotTemperature ( 2 , g , i , e ) &
+ a ( 3 , 5 ) * RKCK45dotTemperature ( 3 , g , i , e ) &
+ a ( 4 , 5 ) * RKCK45dotTemperature ( 4 , g , i , e ) &
+ a ( 5 , 5 ) * RKCK45dotTemperature ( 5 , g , i , e )
endif
endif
enddo ; enddo ; enddo
!$OMP ENDDO
!$OMP DO
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
if ( crystallite_todo ( g , i , e ) ) then
mySizeDotState = constitutive_sizeDotState ( g , i , e )
2010-11-03 22:52:48 +05:30
constitutive_state ( g , i , e ) % p ( 1 : mySizeDotState ) = constitutive_subState0 ( g , i , e ) % p ( 1 : mySizeDotState ) &
+ constitutive_dotState ( g , i , e ) % p ( 1 : mySizeDotState ) * crystallite_subdt ( g , i , e )
2010-10-01 17:48:49 +05:30
crystallite_Temperature ( g , i , e ) = crystallite_subTemperature0 ( g , i , e ) &
+ crystallite_dotTemperature ( g , i , e ) * crystallite_subdt ( g , i , e )
endif
enddo ; enddo ; enddo
2010-11-19 22:59:29 +05:30
!$OMP ENDDO
2010-10-01 17:48:49 +05:30
! --- update dependent states ---
2010-11-03 22:52:48 +05:30
!$OMP DO
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
2010-10-01 17:48:49 +05:30
if ( crystallite_todo ( g , i , e ) ) then
2012-01-17 15:56:57 +05:30
call constitutive_microstructure ( crystallite_Temperature ( g , i , e ) , crystallite_Fe ( 1 : 3 , 1 : 3 , g , i , e ) , &
crystallite_Fp ( 1 : 3 , 1 : 3 , g , i , e ) , g , i , e ) ! update dependent state variables to be consistent with basic states
2010-10-01 17:48:49 +05:30
endif
2010-10-26 19:34:33 +05:30
constitutive_dotState ( g , i , e ) % p = 0.0_pReal ! reset dotState to zero
enddo ; enddo ; enddo
2010-11-03 22:52:48 +05:30
!$OMP ENDDO
2010-10-01 17:48:49 +05:30
! --- stress integration ---
2010-11-03 22:52:48 +05:30
!$OMP DO
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
2010-10-01 17:48:49 +05:30
if ( crystallite_todo ( g , i , e ) ) then
2011-02-23 13:59:51 +05:30
if ( . not . crystallite_integrateStress ( g , i , e , c ( n ) ) ) then ! fraction of original time step
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if ( . not . crystallite_localConstitution ( g , i , e ) ) then ! if broken non-local...
2010-11-03 22:52:48 +05:30
!$OMP CRITICAL (checkTodo)
2010-10-01 17:48:49 +05:30
crystallite_todo = crystallite_todo . and . crystallite_localConstitution ! ...all non-locals skipped
2010-11-03 22:52:48 +05:30
!$OMP END CRITICAL (checkTodo)
2010-10-01 17:48:49 +05:30
else ! if broken local...
crystallite_todo ( g , i , e ) = . false . ! ... skip this one next time
endif
endif
endif
enddo ; enddo ; enddo
2010-11-03 22:52:48 +05:30
!$OMP ENDDO
2010-11-11 21:46:05 +05:30
2010-10-01 17:48:49 +05:30
! --- dot state and RK dot state---
2011-03-29 12:57:19 +05:30
#ifndef _OPENMP
2012-03-09 01:55:28 +05:30
if ( iand ( debug_what ( debug_crystallite ) , debug_levelExtensive ) / = 0_pInt ) then
write ( 6 , '(a,1x,i1)' ) '<< CRYST >> RUNGE KUTTA STEP' , n + 1_pInt
2010-11-11 18:44:53 +05:30
endif
2011-03-29 12:57:19 +05:30
#endif
2010-11-03 22:52:48 +05:30
!$OMP DO
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
2010-10-01 17:48:49 +05:30
if ( crystallite_todo ( g , i , e ) ) then
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
call constitutive_collectDotState ( crystallite_Tstar_v ( 1 : 6 , g , i , e ) , crystallite_Fe , crystallite_Fp , &
2011-02-25 15:23:20 +05:30
crystallite_Temperature ( g , i , e ) , c ( n ) * crystallite_subdt ( g , i , e ) , & ! fraction of original timestep
2010-10-15 18:49:26 +05:30
crystallite_orientation , g , i , e )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
crystallite_dotTemperature ( g , i , e ) = constitutive_dotTemperature ( crystallite_Tstar_v ( 1 : 6 , g , i , e ) , &
2010-10-01 17:48:49 +05:30
crystallite_Temperature ( g , i , e ) , g , i , e )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
endif
enddo ; enddo ; enddo
!$OMP ENDDO
!$OMP DO
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
if ( crystallite_todo ( g , i , e ) ) then
2010-10-01 17:48:49 +05:30
if ( any ( constitutive_dotState ( g , i , e ) % p / = constitutive_dotState ( g , i , e ) % p ) & ! NaN occured in dotState
. or . crystallite_dotTemperature ( g , i , e ) / = crystallite_dotTemperature ( g , i , e ) ) then ! NaN occured in dotTemperature
if ( . not . crystallite_localConstitution ( g , i , e ) ) then ! if broken non-local...
2010-11-03 22:52:48 +05:30
!$OMP CRITICAL (checkTodo)
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crystallite_todo = crystallite_todo . and . crystallite_localConstitution ! ...all non-locals skipped
2010-11-03 22:52:48 +05:30
!$OMP END CRITICAL (checkTodo)
2010-10-01 17:48:49 +05:30
else ! if broken local...
crystallite_todo ( g , i , e ) = . false . ! ... skip this one next time
endif
endif
endif
enddo ; enddo ; enddo
2010-11-03 22:52:48 +05:30
!$OMP ENDDO
2010-10-01 17:48:49 +05:30
enddo
! --- STATE UPDATE WITH ERROR ESTIMATE FOR STATE AND TEMPERATURE ---
relStateResiduum = 0.0_pReal
relTemperatureResiduum = 0.0_pReal
2010-11-03 22:52:48 +05:30
!$OMP DO
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
2010-10-01 17:48:49 +05:30
if ( crystallite_todo ( g , i , e ) ) then
2010-11-03 22:52:48 +05:30
mySizeDotState = constitutive_sizeDotState ( g , i , e )
2010-10-27 14:18:04 +05:30
constitutive_RKCK45dotState ( 6 , g , i , e ) % p = constitutive_dotState ( g , i , e ) % p ! store Runge-Kutta dotState
RKCK45dotTemperature ( 6 , g , i , e ) = crystallite_dotTemperature ( g , i , e ) ! store Runge-Kutta dotTemperature
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
endif
enddo ; enddo ; enddo
!$OMP ENDDO
2010-10-01 17:48:49 +05:30
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
!$OMP DO
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
if ( crystallite_todo ( g , i , e ) ) then
mySizeDotState = constitutive_sizeDotState ( g , i , e )
2010-10-01 17:48:49 +05:30
! --- absolute residuum in state and temperature ---
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
! NEED TO DO THE ADDITION IN THIS LENGTHY WAY BECAUSE OF PARALLELIZATION
! CAN'T USE A REDUCTION CLAUSE ON A POINTER OR USER DEFINED TYPE
2010-10-01 17:48:49 +05:30
2012-03-09 01:55:28 +05:30
stateResiduum ( 1 : mySizeDotState , g , i , e ) = &
( db ( 1 ) * constitutive_RKCK45dotState ( 1 , g , i , e ) % p ( 1 : mySizeDotState ) &
+ db ( 2 ) * constitutive_RKCK45dotState ( 2 , g , i , e ) % p ( 1 : mySizeDotState ) &
+ db ( 3 ) * constitutive_RKCK45dotState ( 3 , g , i , e ) % p ( 1 : mySizeDotState ) &
+ db ( 4 ) * constitutive_RKCK45dotState ( 4 , g , i , e ) % p ( 1 : mySizeDotState ) &
+ db ( 5 ) * constitutive_RKCK45dotState ( 5 , g , i , e ) % p ( 1 : mySizeDotState ) &
+ db ( 6 ) * constitutive_RKCK45dotState ( 6 , g , i , e ) % p ( 1 : mySizeDotState ) ) &
* crystallite_subdt ( g , i , e )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
temperatureResiduum ( g , i , e ) = ( db ( 1 ) * RKCK45dotTemperature ( 1 , g , i , e ) &
+ db ( 2 ) * RKCK45dotTemperature ( 2 , g , i , e ) &
+ db ( 3 ) * RKCK45dotTemperature ( 3 , g , i , e ) &
+ db ( 4 ) * RKCK45dotTemperature ( 4 , g , i , e ) &
+ db ( 5 ) * RKCK45dotTemperature ( 5 , g , i , e ) &
+ db ( 6 ) * RKCK45dotTemperature ( 6 , g , i , e ) ) &
* crystallite_subdt ( g , i , e )
2010-10-01 17:48:49 +05:30
! --- dot state and dot temperature ---
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
constitutive_dotState ( g , i , e ) % p = b ( 1 ) * constitutive_RKCK45dotState ( 1 , g , i , e ) % p &
+ b ( 2 ) * constitutive_RKCK45dotState ( 2 , g , i , e ) % p &
+ b ( 3 ) * constitutive_RKCK45dotState ( 3 , g , i , e ) % p &
+ b ( 4 ) * constitutive_RKCK45dotState ( 4 , g , i , e ) % p &
+ b ( 5 ) * constitutive_RKCK45dotState ( 5 , g , i , e ) % p &
+ b ( 6 ) * constitutive_RKCK45dotState ( 6 , g , i , e ) % p
crystallite_dotTemperature ( g , i , e ) = b ( 1 ) * RKCK45dotTemperature ( 1 , g , i , e ) &
+ b ( 2 ) * RKCK45dotTemperature ( 2 , g , i , e ) &
+ b ( 3 ) * RKCK45dotTemperature ( 3 , g , i , e ) &
+ b ( 4 ) * RKCK45dotTemperature ( 4 , g , i , e ) &
+ b ( 5 ) * RKCK45dotTemperature ( 5 , g , i , e ) &
+ b ( 6 ) * RKCK45dotTemperature ( 6 , g , i , e )
endif
enddo ; enddo ; enddo
!$OMP ENDDO
2010-10-01 17:48:49 +05:30
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
! --- state and temperature update ---
2010-10-01 17:48:49 +05:30
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
!$OMP DO
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
if ( crystallite_todo ( g , i , e ) ) then
mySizeDotState = constitutive_sizeDotState ( g , i , e )
2010-11-03 22:52:48 +05:30
constitutive_state ( g , i , e ) % p ( 1 : mySizeDotState ) = constitutive_subState0 ( g , i , e ) % p ( 1 : mySizeDotState ) &
+ constitutive_dotState ( g , i , e ) % p ( 1 : mySizeDotState ) * crystallite_subdt ( g , i , e )
2010-10-01 17:48:49 +05:30
crystallite_Temperature ( g , i , e ) = crystallite_subTemperature0 ( g , i , e ) &
+ crystallite_dotTemperature ( g , i , e ) * crystallite_subdt ( g , i , e )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
endif
enddo ; enddo ; enddo
!$OMP ENDDO
! --- relative residui and state convergence ---
!$OMP DO
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
if ( crystallite_todo ( g , i , e ) ) then
mySizeDotState = constitutive_sizeDotState ( g , i , e )
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forall ( s = 1_pInt : mySizeDotState , abs ( constitutive_state ( g , i , e ) % p ( s ) ) > 0.0_pReal ) &
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relStateResiduum ( s , g , i , e ) = stateResiduum ( s , g , i , e ) / constitutive_state ( g , i , e ) % p ( s )
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if ( crystallite_Temperature ( g , i , e ) > 0 ) &
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relTemperatureResiduum ( g , i , e ) = temperatureResiduum ( g , i , e ) / crystallite_Temperature ( g , i , e )
2010-10-15 20:27:13 +05:30
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
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!$OMP FLUSH(relStateResiduum,relTemperatureResiduum)
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crystallite_todo ( g , i , e ) = &
( all ( abs ( relStateResiduum ( : , g , i , e ) ) < rTol_crystalliteState &
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. or . abs ( stateResiduum ( 1 : mySizeDotState , g , i , e ) ) < constitutive_aTolState ( g , i , e ) % p ( 1 : mySizeDotState ) ) &
2010-10-26 19:34:33 +05:30
. and . abs ( relTemperatureResiduum ( g , i , e ) ) < rTol_crystalliteTemperature )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
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#ifndef _OPENMP
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if ( iand ( debug_what ( debug_crystallite ) , debug_levelExtensive ) / = 0_pInt &
. and . ( ( e == debug_e . and . i == debug_i . and . g == debug_g ) &
. or . . not . iand ( debug_what ( debug_crystallite ) , debug_levelSelective ) / = 0_pInt ) ) then
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write ( 6 , '(a,i8,1x,i3,1x,i3)' ) '<< CRYST >> updateState at el ip g ' , e , i , g
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write ( 6 , * )
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write ( 6 , '(a,/,(12x,12(f12.1,1x)))' ) '<< CRYST >> absolute residuum tolerance' , &
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stateResiduum ( 1 : mySizeDotState , g , i , e ) / constitutive_aTolState ( g , i , e ) % p ( 1 : mySizeDotState )
write ( 6 , * )
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write ( 6 , '(a,/,(12x,12(f12.1,1x)))' ) '<< CRYST >> relative residuum tolerance' , &
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relStateResiduum ( 1 : mySizeDotState , g , i , e ) / rTol_crystalliteState
write ( 6 , * )
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write ( 6 , '(a,/,(12x,12(e12.5,1x)))' ) '<< CRYST >> dotState' , constitutive_dotState ( g , i , e ) % p ( 1 : mySizeDotState )
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write ( 6 , * )
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write ( 6 , '(a,/,(12x,12(e12.5,1x)))' ) '<< CRYST >> new state' , constitutive_state ( g , i , e ) % p ( 1 : mySizeDotState )
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write ( 6 , * )
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endif
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#endif
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endif
enddo ; enddo ; enddo
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!$OMP ENDDO
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! --- UPDATE DEPENDENT STATES IF RESIDUUM BELOW TOLERANCE ---
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!$OMP DO
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
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if ( crystallite_todo ( g , i , e ) ) then
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call constitutive_microstructure ( crystallite_Temperature ( g , i , e ) , crystallite_Fe ( 1 : 3 , 1 : 3 , g , i , e ) , &
crystallite_Fp ( 1 : 3 , 1 : 3 , g , i , e ) , g , i , e ) ! update dependent state variables to be consistent with basic states
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endif
enddo ; enddo ; enddo
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!$OMP ENDDO
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! --- FINAL STRESS INTEGRATION STEP IF RESIDUUM BELOW TOLERANCE ---
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!$OMP DO
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
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if ( crystallite_todo ( g , i , e ) ) then
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if ( crystallite_integrateStress ( g , i , e ) ) then
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crystallite_converged ( g , i , e ) = . true . ! ... converged per definitionem
crystallite_todo ( g , i , e ) = . false . ! ... integration done
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if ( iand ( debug_what ( debug_crystallite ) , debug_levelBasic ) / = 0_pInt ) then
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!$OMP CRITICAL (distributionState)
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debug_StateLoopDistribution ( 6 , numerics_integrationMode ) = &
debug_StateLoopDistribution ( 6 , numerics_integrationMode ) + 1_pInt
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!$OMP END CRITICAL (distributionState)
endif
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else
if ( . not . crystallite_localConstitution ( g , i , e ) ) then ! if broken non-local...
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!$OMP CRITICAL (checkTodo)
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crystallite_todo = crystallite_todo . and . crystallite_localConstitution ! ...all non-locals skipped
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!$OMP END CRITICAL (checkTodo)
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endif
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endif
endif
enddo ; enddo ; enddo
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!$OMP ENDDO
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2010-11-03 22:52:48 +05:30
!$OMP END PARALLEL
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! --- nonlocal convergence check ---
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#ifndef _OPENMP
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if ( iand ( debug_what ( debug_crystallite ) , debug_levelExtensive ) / = 0_pInt ) then
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write ( 6 , '(a,i8,a,i2)' ) '<< CRYST >> ' , count ( crystallite_converged ( : , : , : ) ) , ' grains converged'
write ( 6 , * )
endif
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#endif
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if ( . not . singleRun ) then ! if not requesting Integration of just a single IP
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if ( any ( . not . crystallite_converged . and . . not . crystallite_localConstitution ) ) then ! any non-local not yet converged (or broken)...
crystallite_converged = crystallite_converged . and . crystallite_localConstitution ! ...restart all non-local as not converged
endif
endif
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end subroutine crystallite_integrateStateRKCK45
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!********************************************************************
! integrate stress, state and Temperature with
! 1nd order Euler method with adaptive step size
!********************************************************************
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subroutine crystallite_integrateStateAdaptiveEuler ( gg , ii , ee )
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!*** variables and functions from other modules ***!
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use debug , only : debug_what , &
debug_crystallite , &
debug_levelBasic , &
debug_levelExtensive , &
debug_levelSelective , &
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debug_e , &
debug_i , &
debug_g , &
debug_StateLoopDistribution
use numerics , only : rTol_crystalliteState , &
rTol_crystalliteTemperature , &
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numerics_integrationMode
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use FEsolving , only : FEsolving_execElem , &
FEsolving_execIP
use mesh , only : mesh_element , &
mesh_NcpElems , &
mesh_maxNips
use material , only : homogenization_Ngrains , &
homogenization_maxNgrains
use constitutive , only : constitutive_sizeDotState , &
constitutive_maxSizeDotState , &
constitutive_state , &
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constitutive_aTolState , &
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constitutive_subState0 , &
constitutive_dotState , &
constitutive_collectDotState , &
constitutive_dotTemperature , &
constitutive_microstructure
implicit none
!*** input variables ***!
integer ( pInt ) , optional , intent ( in ) :: ee , & ! element index
ii , & ! integration point index
gg ! grain index
!*** local variables ***!
integer ( pInt ) e , & ! element index in element loop
i , & ! integration point index in ip loop
g , & ! grain index in grain loop
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mySizeDotState , & ! size of dot State
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s ! state index
integer ( pInt ) , dimension ( 2 ) :: eIter ! bounds for element iteration
integer ( pInt ) , dimension ( 2 , mesh_NcpElems ) :: iIter , & ! bounds for ip iteration
gIter ! bounds for grain iteration
real ( pReal ) , dimension ( constitutive_maxSizeDotState , homogenization_maxNgrains , mesh_maxNips , mesh_NcpElems ) :: &
stateResiduum , & ! residuum from evolution in micrstructure
relStateResiduum ! relative residuum from evolution in microstructure
real ( pReal ) , dimension ( homogenization_maxNgrains , mesh_maxNips , mesh_NcpElems ) :: &
temperatureResiduum , & ! residuum from evolution in temperature
relTemperatureResiduum ! relative residuum from evolution in temperature
logical singleRun ! flag indicating computation for single (g,i,e) triple
! --- LOOP ITERATOR FOR ELEMENT, GRAIN, IP ---
if ( present ( ee ) . and . present ( ii ) . and . present ( gg ) ) then
eIter = ee
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
iIter ( 1 : 2 , ee ) = ii
gIter ( 1 : 2 , ee ) = gg
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singleRun = . true .
else
eIter = FEsolving_execElem ( 1 : 2 )
do e = eIter ( 1 ) , eIter ( 2 )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
iIter ( 1 : 2 , e ) = FEsolving_execIP ( 1 : 2 , e )
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gIter ( 1 : 2 , e ) = [ 1_pInt , homogenization_Ngrains ( mesh_element ( 3 , e ) ) ]
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enddo
singleRun = . false .
endif
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!$OMP PARALLEL PRIVATE(mySizeDotState)
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if ( numerics_integrationMode < 2 ) then
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! --- RESET DOTSTATE ---
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!$OMP DO
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
constitutive_dotState ( g , i , e ) % p = 0.0_pReal ! reset dotState to zero
enddo ; enddo ; enddo
!$OMP ENDDO
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2011-11-04 18:14:50 +05:30
! --- DOT STATE AND TEMPERATURE (EULER INTEGRATION) ---
stateResiduum = 0.0_pReal
!$OMP DO
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
if ( crystallite_todo ( g , i , e ) ) then
call constitutive_collectDotState ( crystallite_Tstar_v ( 1 : 6 , g , i , e ) , crystallite_Fe , crystallite_Fp , &
crystallite_Temperature ( g , i , e ) , crystallite_subdt ( g , i , e ) , crystallite_orientation , g , i , e )
crystallite_dotTemperature ( g , i , e ) = constitutive_dotTemperature ( crystallite_Tstar_v ( 1 : 6 , g , i , e ) , &
crystallite_Temperature ( g , i , e ) , g , i , e )
endif
enddo ; enddo ; enddo
!$OMP ENDDO
!$OMP DO
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
if ( crystallite_todo ( g , i , e ) ) then
if ( any ( constitutive_dotState ( g , i , e ) % p / = constitutive_dotState ( g , i , e ) % p ) & ! NaN occured in dotState
. or . crystallite_dotTemperature ( g , i , e ) / = crystallite_dotTemperature ( g , i , e ) ) then ! NaN occured in dotTemperature
if ( . not . crystallite_localConstitution ( g , i , e ) ) then ! if broken non-local...
!$OMP CRITICAL (checkTodo)
crystallite_todo = crystallite_todo . and . crystallite_localConstitution ! ...all non-locals skipped
!$OMP END CRITICAL (checkTodo)
else ! if broken local...
crystallite_todo ( g , i , e ) = . false . ! ... skip this one next time
endif
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endif
endif
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enddo ; enddo ; enddo
!$OMP ENDDO
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2011-11-04 18:14:50 +05:30
! --- STATE UPDATE (EULER INTEGRATION) ---
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2011-11-04 18:14:50 +05:30
!$OMP DO
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
if ( crystallite_todo ( g , i , e ) ) then
mySizeDotState = constitutive_sizeDotState ( g , i , e )
stateResiduum ( 1 : mySizeDotState , g , i , e ) = - 0.5_pReal * constitutive_dotState ( g , i , e ) % p * crystallite_subdt ( g , i , e ) ! contribution to absolute residuum in state and temperature
temperatureResiduum ( g , i , e ) = - 0.5_pReal * crystallite_dotTemperature ( g , i , e ) * crystallite_subdt ( g , i , e )
constitutive_state ( g , i , e ) % p ( 1 : mySizeDotState ) = constitutive_subState0 ( g , i , e ) % p ( 1 : mySizeDotState ) &
+ constitutive_dotState ( g , i , e ) % p ( 1 : mySizeDotState ) * crystallite_subdt ( g , i , e )
crystallite_Temperature ( g , i , e ) = crystallite_subTemperature0 ( g , i , e ) &
+ crystallite_dotTemperature ( g , i , e ) * crystallite_subdt ( g , i , e )
endif
enddo ; enddo ; enddo
!$OMP ENDDO
2010-10-01 17:48:49 +05:30
2011-11-04 18:14:50 +05:30
! --- UPDATE DEPENDENT STATES (EULER INTEGRATION) ---
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2011-11-04 18:14:50 +05:30
!$OMP DO
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
if ( crystallite_todo ( g , i , e ) ) then
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call constitutive_microstructure ( crystallite_Temperature ( g , i , e ) , crystallite_Fe ( 1 : 3 , 1 : 3 , g , i , e ) , &
crystallite_Fp ( 1 : 3 , 1 : 3 , g , i , e ) , g , i , e ) ! update dependent state variables to be consistent with basic states
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endif
constitutive_dotState ( g , i , e ) % p = 0.0_pReal ! reset dotState to zero
enddo ; enddo ; enddo
!$OMP ENDDO
endif
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! --- STRESS INTEGRATION (EULER INTEGRATION) ---
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!$OMP DO
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
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if ( crystallite_todo ( g , i , e ) ) then
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if ( . not . crystallite_integrateStress ( g , i , e ) ) then
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if ( . not . crystallite_localConstitution ( g , i , e ) ) then ! if broken non-local...
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!$OMP CRITICAL (checkTodo)
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crystallite_todo = crystallite_todo . and . crystallite_localConstitution ! ...all non-locals skipped
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!$OMP END CRITICAL (checkTodo)
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else ! if broken local...
crystallite_todo ( g , i , e ) = . false . ! ... skip this one next time
endif
endif
endif
enddo ; enddo ; enddo
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!$OMP ENDDO
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! --- DOT STATE AND TEMPERATURE (HEUN METHOD) ---
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!$OMP DO
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
2010-10-01 17:48:49 +05:30
if ( crystallite_todo ( g , i , e ) ) then
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
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call constitutive_collectDotState ( crystallite_Tstar_v ( 1 : 6 , g , i , e ) , crystallite_Fe , crystallite_Fp , &
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crystallite_Temperature ( g , i , e ) , crystallite_subdt ( g , i , e ) , crystallite_orientation , g , i , e )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
crystallite_dotTemperature ( g , i , e ) = constitutive_dotTemperature ( crystallite_Tstar_v ( 1 : 6 , g , i , e ) , &
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crystallite_Temperature ( g , i , e ) , g , i , e )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
endif
enddo ; enddo ; enddo
!$OMP ENDDO
!$OMP DO
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
if ( crystallite_todo ( g , i , e ) ) then
if ( any ( constitutive_dotState ( g , i , e ) % p / = constitutive_dotState ( g , i , e ) % p ) & ! NaN occured in dotState
. or . crystallite_dotTemperature ( g , i , e ) / = crystallite_dotTemperature ( g , i , e ) ) then ! NaN occured in dotTemperature
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if ( . not . crystallite_localConstitution ( g , i , e ) ) then ! if broken non-local...
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!$OMP CRITICAL (checkTodo)
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crystallite_todo = crystallite_todo . and . crystallite_localConstitution ! ...all non-locals skipped
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!$OMP END CRITICAL (checkTodo)
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else ! if broken local...
crystallite_todo ( g , i , e ) = . false . ! ... skip this one next time
endif
endif
endif
enddo ; enddo ; enddo
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!$OMP ENDDO
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! --- ERROR ESTIMATE FOR STATE AND TEMPERATURE (HEUN METHOD) ---
relStateResiduum = 0.0_pReal
relTemperatureResiduum = 0.0_pReal
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!$OMP DO
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
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if ( crystallite_todo ( g , i , e ) ) then
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mySizeDotState = constitutive_sizeDotState ( g , i , e )
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! --- contribution of heun step to absolute residui ---
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stateResiduum ( 1 : mySizeDotState , g , i , e ) = stateResiduum ( 1 : mySizeDotState , g , i , e ) &
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+ 0.5_pReal * constitutive_dotState ( g , i , e ) % p * crystallite_subdt ( g , i , e ) ! contribution to absolute residuum in state and temperature
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temperatureResiduum ( g , i , e ) = temperatureResiduum ( g , i , e ) &
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+ 0.5_pReal * crystallite_dotTemperature ( g , i , e ) * crystallite_subdt ( g , i , e )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
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!$OMP FLUSH(stateResiduum,temperatureResiduum)
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! --- relative residui ---
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forall ( s = 1_pInt : mySizeDotState , abs ( constitutive_state ( g , i , e ) % p ( s ) ) > 0.0_pReal ) &
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relStateResiduum ( s , g , i , e ) = stateResiduum ( s , g , i , e ) / constitutive_state ( g , i , e ) % p ( s )
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if ( crystallite_Temperature ( g , i , e ) > 0_pInt ) &
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relTemperatureResiduum ( g , i , e ) = temperatureResiduum ( g , i , e ) / crystallite_Temperature ( g , i , e )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
!$OMP FLUSH(relStateResiduum,relTemperatureResiduum)
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#ifndef _OPENMP
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if ( iand ( debug_what ( debug_crystallite ) , debug_levelExtensive ) / = 0_pInt &
. and . ( ( e == debug_e . and . i == debug_i . and . g == debug_g ) &
. or . . not . iand ( debug_what ( debug_crystallite ) , debug_levelSelective ) / = 0_pInt ) ) then
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write ( 6 , '(a,i8,1x,i2,1x,i3)' ) '<< CRYST >> updateState at el ip g ' , e , i , g
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write ( 6 , * )
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write ( 6 , '(a,/,(12x,12(f12.1,1x)))' ) '<< CRYST >> absolute residuum tolerance' , &
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stateResiduum ( 1 : mySizeDotState , g , i , e ) / constitutive_aTolState ( g , i , e ) % p ( 1 : mySizeDotState )
write ( 6 , * )
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write ( 6 , '(a,/,(12x,12(f12.1,1x)))' ) '<< CRYST >> relative residuum tolerance' , &
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relStateResiduum ( 1 : mySizeDotState , g , i , e ) / rTol_crystalliteState
write ( 6 , * )
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write ( 6 , '(a,/,(12x,12(e12.5,1x)))' ) '<< CRYST >> dotState' , constitutive_dotState ( g , i , e ) % p ( 1 : mySizeDotState ) &
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- 2.0_pReal * stateResiduum ( 1 : mySizeDotState , g , i , e ) / crystallite_subdt ( g , i , e ) ! calculate former dotstate from higher order solution and state residuum
write ( 6 , * )
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write ( 6 , '(a,/,(12x,12(e12.5,1x)))' ) '<< CRYST >> new state' , constitutive_state ( g , i , e ) % p ( 1 : mySizeDotState )
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write ( 6 , * )
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endif
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#endif
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! --- converged ? ---
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if ( all ( abs ( relStateResiduum ( : , g , i , e ) ) < rTol_crystalliteState &
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. or . abs ( stateResiduum ( 1 : mySizeDotState , g , i , e ) ) < constitutive_aTolState ( g , i , e ) % p ( 1 : mySizeDotState ) ) &
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. and . abs ( relTemperatureResiduum ( g , i , e ) ) < rTol_crystalliteTemperature ) then
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crystallite_converged ( g , i , e ) = . true . ! ... converged per definitionem
crystallite_todo ( g , i , e ) = . false . ! ... integration done
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if ( iand ( debug_what ( debug_crystallite ) , debug_levelBasic ) / = 0_pInt ) then
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!$OMP CRITICAL (distributionState)
debug_StateLoopDistribution ( 2 , numerics_integrationMode ) = debug_StateLoopDistribution ( 2 , numerics_integrationMode ) + 1
!$OMP END CRITICAL (distributionState)
endif
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endif
endif
enddo ; enddo ; enddo
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!$OMP ENDDO
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2010-11-03 22:52:48 +05:30
!$OMP END PARALLEL
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! --- NONLOCAL CONVERGENCE CHECK ---
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#ifndef _OPENMP
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if ( iand ( debug_what ( debug_crystallite ) , debug_levelExtensive ) / = 0_pInt ) then
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write ( 6 , '(a,i8,a,i2)' ) '<< CRYST >> ' , count ( crystallite_converged ( : , : , : ) ) , ' grains converged'
write ( 6 , * )
endif
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#endif
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if ( . not . singleRun ) then ! if not requesting Integration of just a single IP
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if ( any ( . not . crystallite_converged . and . . not . crystallite_localConstitution ) ) then ! any non-local not yet converged (or broken)...
crystallite_converged = crystallite_converged . and . crystallite_localConstitution ! ...restart all non-local as not converged
endif
endif
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end subroutine crystallite_integrateStateAdaptiveEuler
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!********************************************************************
! integrate stress, state and Temperature with
! 1st order explicit Euler method
!********************************************************************
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subroutine crystallite_integrateStateEuler ( gg , ii , ee )
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!*** variables and functions from other modules ***!
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use numerics , only : numerics_integrationMode
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use debug , only : debug_what , &
debug_crystallite , &
debug_levelBasic , &
debug_levelExtensive , &
debug_levelSelective , &
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debug_e , &
debug_i , &
debug_g , &
debug_StateLoopDistribution
use FEsolving , only : FEsolving_execElem , &
FEsolving_execIP
use mesh , only : mesh_element , &
mesh_NcpElems
use material , only : homogenization_Ngrains
use constitutive , only : constitutive_sizeDotState , &
constitutive_state , &
constitutive_subState0 , &
constitutive_dotState , &
constitutive_collectDotState , &
constitutive_dotTemperature , &
constitutive_microstructure
implicit none
!*** input variables ***!
integer ( pInt ) , optional , intent ( in ) :: ee , & ! element index
ii , & ! integration point index
gg ! grain index
!*** local variables ***!
integer ( pInt ) e , & ! element index in element loop
i , & ! integration point index in ip loop
g , & ! grain index in grain loop
mySizeDotState
integer ( pInt ) , dimension ( 2 ) :: eIter ! bounds for element iteration
integer ( pInt ) , dimension ( 2 , mesh_NcpElems ) :: iIter , & ! bounds for ip iteration
gIter ! bounds for grain iteration
logical singleRun ! flag indicating computation for single (g,i,e) triple
if ( present ( ee ) . and . present ( ii ) . and . present ( gg ) ) then
eIter = ee
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
iIter ( 1 : 2 , ee ) = ii
gIter ( 1 : 2 , ee ) = gg
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singleRun = . true .
else
eIter = FEsolving_execElem ( 1 : 2 )
do e = eIter ( 1 ) , eIter ( 2 )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
iIter ( 1 : 2 , e ) = FEsolving_execIP ( 1 : 2 , e )
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gIter ( 1 : 2 , e ) = [ 1_pInt , homogenization_Ngrains ( mesh_element ( 3 , e ) ) ]
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enddo
singleRun = . false .
endif
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!$OMP PARALLEL PRIVATE(mySizeDotState)
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if ( numerics_integrationMode < 2 ) then
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2011-11-04 18:14:50 +05:30
! --- RESET DOTSTATE ---
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2011-11-04 18:14:50 +05:30
!$OMP DO
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
constitutive_dotState ( g , i , e ) % p = 0.0_pReal ! reset dotState to zero
enddo ; enddo ; enddo
!$OMP ENDDO
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2011-11-04 18:14:50 +05:30
! --- DOT STATE AND TEMPERATURE ---
!$OMP DO
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
if ( crystallite_todo ( g , i , e ) ) then
call constitutive_collectDotState ( crystallite_Tstar_v ( 1 : 6 , g , i , e ) , crystallite_Fe , crystallite_Fp , &
crystallite_Temperature ( g , i , e ) , crystallite_subdt ( g , i , e ) , crystallite_orientation , g , i , e )
crystallite_dotTemperature ( g , i , e ) = constitutive_dotTemperature ( crystallite_Tstar_v ( 1 : 6 , g , i , e ) , &
crystallite_Temperature ( g , i , e ) , g , i , e )
endif
enddo ; enddo ; enddo
!$OMP ENDDO
!$OMP DO
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
if ( crystallite_todo ( g , i , e ) ) then
if ( any ( constitutive_dotState ( g , i , e ) % p / = constitutive_dotState ( g , i , e ) % p ) & ! NaN occured in dotState
. or . crystallite_dotTemperature ( g , i , e ) / = crystallite_dotTemperature ( g , i , e ) ) then ! NaN occured in dotTemperature
if ( . not . crystallite_localConstitution ( g , i , e ) ) then ! if broken non-local...
!$OMP CRITICAL (checkTodo)
crystallite_todo = crystallite_todo . and . crystallite_localConstitution ! ...all non-locals skipped
!$OMP END CRITICAL (checkTodo)
else ! if broken local...
crystallite_todo ( g , i , e ) = . false . ! ... skip this one next time
endif
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endif
endif
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enddo ; enddo ; enddo
!$OMP ENDDO
2010-10-01 17:48:49 +05:30
2011-11-04 18:14:50 +05:30
! --- UPDATE STATE AND TEMPERATURE ---
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2011-11-04 18:14:50 +05:30
!$OMP DO
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
if ( crystallite_todo ( g , i , e ) ) then
mySizeDotState = constitutive_sizeDotState ( g , i , e )
constitutive_state ( g , i , e ) % p ( 1 : mySizeDotState ) = constitutive_subState0 ( g , i , e ) % p ( 1 : mySizeDotState ) &
+ constitutive_dotState ( g , i , e ) % p ( 1 : mySizeDotState ) * crystallite_subdt ( g , i , e )
crystallite_Temperature ( g , i , e ) = crystallite_subTemperature0 ( g , i , e ) &
+ crystallite_dotTemperature ( g , i , e ) * crystallite_subdt ( g , i , e )
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#ifndef _OPENMP
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if ( iand ( debug_what ( debug_crystallite ) , debug_levelExtensive ) / = 0_pInt &
. and . ( ( e == debug_e . and . i == debug_i . and . g == debug_g ) &
. or . . not . iand ( debug_what ( debug_crystallite ) , debug_levelSelective ) / = 0_pInt ) ) then
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write ( 6 , '(a,i8,1x,i2,1x,i3)' ) '<< CRYST >> updateState at el ip g ' , e , i , g
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write ( 6 , * )
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write ( 6 , '(a,/,(12x,12(e12.5,1x)))' ) '<< CRYST >> dotState' , constitutive_dotState ( g , i , e ) % p ( 1 : mySizeDotState )
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write ( 6 , * )
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write ( 6 , '(a,/,(12x,12(e12.5,1x)))' ) '<< CRYST >> new state' , constitutive_state ( g , i , e ) % p ( 1 : mySizeDotState )
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write ( 6 , * )
endif
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#endif
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endif
enddo ; enddo ; enddo
!$OMP ENDDO
2010-10-01 17:48:49 +05:30
2011-11-04 18:14:50 +05:30
! --- UPDATE DEPENDENT STATES ---
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2011-11-04 18:14:50 +05:30
!$OMP DO
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
if ( crystallite_todo ( g , i , e ) ) then
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call constitutive_microstructure ( crystallite_Temperature ( g , i , e ) , crystallite_Fe ( 1 : 3 , 1 : 3 , g , i , e ) , &
crystallite_Fp ( 1 : 3 , 1 : 3 , g , i , e ) , g , i , e ) ! update dependent state variables to be consistent with basic states
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endif
enddo ; enddo ; enddo
!$OMP ENDDO
endif
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! --- STRESS INTEGRATION ---
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!$OMP DO
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
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if ( crystallite_todo ( g , i , e ) ) then
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if ( crystallite_integrateStress ( g , i , e ) ) then
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crystallite_converged ( g , i , e ) = . true .
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if ( iand ( debug_what ( debug_crystallite ) , debug_levelBasic ) / = 0_pInt ) then
2011-03-21 16:01:17 +05:30
!$OMP CRITICAL (distributionState)
debug_StateLoopDistribution ( 1 , numerics_integrationMode ) = debug_StateLoopDistribution ( 1 , numerics_integrationMode ) + 1
!$OMP END CRITICAL (distributionState)
endif
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else ! broken stress integration
if ( . not . crystallite_localConstitution ( g , i , e ) ) then ! if broken non-local...
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!$OMP CRITICAL (checkTodo)
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crystallite_todo = crystallite_todo . and . crystallite_localConstitution ! ...all non-locals skipped
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!$OMP END CRITICAL (checkTodo)
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endif
endif
endif
enddo ; enddo ; enddo
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!$OMP ENDDO
!$OMP END PARALLEL
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! --- CHECK NON-LOCAL CONVERGENCE ---
crystallite_todo = . false . ! done with integration
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if ( . not . singleRun ) then ! if not requesting Integration of just a single IP
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if ( any ( . not . crystallite_converged . and . . not . crystallite_localConstitution ) ) then ! any non-local not yet converged (or broken)...
crystallite_converged = crystallite_converged . and . crystallite_localConstitution ! ...restart all non-local as not converged
endif
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endif
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end subroutine crystallite_integrateStateEuler
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!********************************************************************
! integrate stress, state and Temperature with
! adaptive 1st order explicit Euler method
! using Fixed Point Iteration to adapt the stepsize
!********************************************************************
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subroutine crystallite_integrateStateFPI ( gg , ii , ee )
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!*** variables and functions from other modules ***!
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use debug , only : debug_what , &
debug_crystallite , &
debug_levelBasic , &
debug_levelExtensive , &
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debug_StateLoopDistribution
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use numerics , only : nState , &
numerics_integrationMode
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use FEsolving , only : FEsolving_execElem , &
FEsolving_execIP
use mesh , only : mesh_element , &
mesh_NcpElems
use material , only : homogenization_Ngrains
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use constitutive , only : constitutive_dotState , &
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constitutive_collectDotState , &
constitutive_dotTemperature , &
constitutive_microstructure , &
constitutive_previousDotState , &
constitutive_previousDotState2
implicit none
!*** input variables ***!
integer ( pInt ) , optional , intent ( in ) :: ee , & ! element index
ii , & ! integration point index
gg ! grain index
!*** output variables ***!
!*** local variables ***!
integer ( pInt ) NiterationState , & ! number of iterations in state loop
e , & ! element index in element loop
i , & ! integration point index in ip loop
g ! grain index in grain loop
integer ( pInt ) , dimension ( 2 ) :: eIter ! bounds for element iteration
integer ( pInt ) , dimension ( 2 , mesh_NcpElems ) :: iIter , & ! bounds for ip iteration
gIter ! bounds for grain iteration
real ( pReal ) dot_prod12 , &
dot_prod22
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
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logical singleRun , & ! flag indicating computation for single (g,i,e) triple
stateConverged , & ! flag indicating convergence of state integration
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temperatureConverged , & ! flag indicating convergence of temperature integration
stateUpdateDone , & ! flag indicating successfull state update
temperatureUpdateDone ! flag indicating successfull temperature update
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if ( present ( ee ) . and . present ( ii ) . and . present ( gg ) ) then
eIter = ee
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
iIter ( 1 : 2 , ee ) = ii
gIter ( 1 : 2 , ee ) = gg
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singleRun = . true .
else
eIter = FEsolving_execElem ( 1 : 2 )
do e = eIter ( 1 ) , eIter ( 2 )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
iIter ( 1 : 2 , e ) = FEsolving_execIP ( 1 : 2 , e )
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gIter ( 1 : 2 , e ) = [ 1_pInt , homogenization_Ngrains ( mesh_element ( 3 , e ) ) ]
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enddo
singleRun = . false .
endif
! --+>> PREGUESS FOR STATE <<+--
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! --- RESET DOTSTATE ---
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!$OMP PARALLEL
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!$OMP DO
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
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constitutive_dotState ( g , i , e ) % p = 0.0_pReal ! reset dotState to zero
constitutive_previousDotState ( g , i , e ) % p = 0.0_pReal
constitutive_previousDotState2 ( g , i , e ) % p = 0.0_pReal
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enddo ; enddo ; enddo
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!$OMP ENDDO
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! --- DOT STATES ---
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!$OMP DO
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
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if ( crystallite_todo ( g , i , e ) ) then
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
call constitutive_collectDotState ( crystallite_Tstar_v ( 1 : 6 , g , i , e ) , crystallite_Fe , crystallite_Fp , &
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crystallite_Temperature ( g , i , e ) , crystallite_subdt ( g , i , e ) , crystallite_orientation , g , i , e )
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endif
enddo ; enddo ; enddo
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!$OMP ENDDO
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! --- STATE & TEMPERATURE UPDATE ---
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!$OMP SINGLE
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crystallite_statedamper = 1.0_pReal
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!$OMP END SINGLE
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!$OMP DO PRIVATE(stateUpdateDone,temperatureUpdateDone,stateConverged,temperatureConverged)
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
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if ( crystallite_todo ( g , i , e ) ) then
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call crystallite_updateState ( stateUpdateDone , stateConverged , g , i , e ) ! update state
call crystallite_updateTemperature ( temperatureUpdateDone , temperatureConverged , g , i , e ) ! update temperature
crystallite_todo ( g , i , e ) = stateUpdateDone . and . temperatureUpdateDone
if ( ( . not . stateUpdateDone . or . . not . temperatureUpdateDone ) &
. and . . not . crystallite_localConstitution ( g , i , e ) ) then ! if updateState or updateTemperature signals broken non-local...
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!$OMP CRITICAL (checkTodo)
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crystallite_todo = crystallite_todo . and . crystallite_localConstitution ! ...all non-locals skipped
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!$OMP END CRITICAL (checkTodo)
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endif
endif
enddo ; enddo ; enddo
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!$OMP ENDDO
2010-10-01 17:48:49 +05:30
2010-10-26 19:34:33 +05:30
! --- UPDATE DEPENDENT STATES ---
2010-11-03 22:52:48 +05:30
!$OMP DO
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
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if ( crystallite_todo ( g , i , e ) ) then
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call constitutive_microstructure ( crystallite_Temperature ( g , i , e ) , crystallite_Fe ( 1 : 3 , 1 : 3 , g , i , e ) , &
crystallite_Fp ( 1 : 3 , 1 : 3 , g , i , e ) , g , i , e ) ! update dependent state variables to be consistent with basic states
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endif
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constitutive_previousDotState2 ( g , i , e ) % p = constitutive_previousDotState ( g , i , e ) % p ! age previous dotState
constitutive_previousDotState ( g , i , e ) % p = constitutive_dotState ( g , i , e ) % p ! age previous dotState
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constitutive_dotState ( g , i , e ) % p = 0.0_pReal ! reset dotState to zero
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enddo ; enddo ; enddo
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!$OMP ENDDO
2011-03-21 20:00:10 +05:30
!$OMP END PARALLEL
2010-10-26 19:34:33 +05:30
2011-03-29 12:57:19 +05:30
2010-10-01 17:48:49 +05:30
! --+>> STATE LOOP <<+--
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NiterationState = 0_pInt
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do while ( any ( crystallite_todo ) . and . NiterationState < nState ) ! convergence loop for crystallite
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NiterationState = NiterationState + 1_pInt
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!$OMP PARALLEL
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! --- STRESS INTEGRATION ---
2010-11-19 22:59:29 +05:30
2010-11-03 22:52:48 +05:30
!$OMP DO
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
2010-10-01 17:48:49 +05:30
if ( crystallite_todo ( g , i , e ) ) then
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
if ( . not . crystallite_integrateStress ( g , i , e ) ) then ! if broken ...
if ( . not . crystallite_localConstitution ( g , i , e ) ) then ! ... and non-local...
!$OMP CRITICAL (checkTodo)
crystallite_todo = crystallite_todo . and . crystallite_localConstitution ! ... then all non-locals skipped
!$OMP END CRITICAL (checkTodo)
else ! ... and local...
crystallite_todo ( g , i , e ) = . false . ! ... then skip only me
endif
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endif
endif
enddo ; enddo ; enddo
2010-11-03 22:52:48 +05:30
!$OMP ENDDO
2010-10-01 17:48:49 +05:30
2012-03-09 01:55:28 +05:30
2011-03-29 12:57:19 +05:30
#ifndef _OPENMP
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if ( iand ( debug_what ( debug_crystallite ) , debug_levelExtensive ) / = 0_pInt ) then
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write ( 6 , '(a,i8,a)' ) '<< CRYST >> ' , count ( crystallite_todo ( : , : , : ) ) , ' grains todo after stress integration'
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endif
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#endif
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! --- DOT STATES ---
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!$OMP DO
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
2010-10-01 17:48:49 +05:30
if ( crystallite_todo ( g , i , e ) ) then
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
call constitutive_collectDotState ( crystallite_Tstar_v ( 1 : 6 , g , i , e ) , crystallite_Fe , crystallite_Fp , &
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crystallite_Temperature ( g , i , e ) , crystallite_subdt ( g , i , e ) , crystallite_orientation , g , i , e )
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endif
enddo ; enddo ; enddo
2010-11-03 22:52:48 +05:30
!$OMP ENDDO
2010-10-01 17:48:49 +05:30
! --- STATE & TEMPERATURE UPDATE ---
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!$OMP SINGLE
crystallite_statedamper = 1.0_pReal
!$OMP END SINGLE
2011-03-29 12:57:19 +05:30
!$OMP DO PRIVATE(dot_prod12,dot_prod22,stateUpdateDone,temperatureUpdateDone,stateConverged,temperatureConverged)
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
2010-10-01 17:48:49 +05:30
if ( crystallite_todo ( g , i , e ) ) then
2010-11-19 22:59:29 +05:30
2010-10-01 17:48:49 +05:30
! --- state damper ---
dot_prod12 = dot_product ( constitutive_dotState ( g , i , e ) % p - constitutive_previousDotState ( g , i , e ) % p , &
constitutive_previousDotState ( g , i , e ) % p - constitutive_previousDotState2 ( g , i , e ) % p )
dot_prod22 = dot_product ( constitutive_previousDotState ( g , i , e ) % p - constitutive_previousDotState2 ( g , i , e ) % p , &
constitutive_previousDotState ( g , i , e ) % p - constitutive_previousDotState2 ( g , i , e ) % p )
if ( dot_prod22 > 0.0_pReal &
. and . ( dot_prod12 < 0.0_pReal &
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
. or . dot_product ( constitutive_dotState ( g , i , e ) % p , constitutive_previousDotState ( g , i , e ) % p ) < 0.0_pReal ) ) then
2010-10-01 17:48:49 +05:30
crystallite_statedamper ( g , i , e ) = 0.75_pReal + 0.25_pReal * tanh ( 2.0_pReal + 4.0_pReal * dot_prod12 / dot_prod22 )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
!$OMP FLUSH(crystallite_statedamper)
endif
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! --- updates ---
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call crystallite_updateState ( stateUpdateDone , stateConverged , g , i , e ) ! update state
call crystallite_updateTemperature ( temperatureUpdateDone , temperatureConverged , g , i , e ) ! update temperature
crystallite_todo ( g , i , e ) = stateUpdateDone . and . temperatureUpdateDone
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
crystallite_converged ( g , i , e ) = stateConverged . and . temperatureConverged
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if ( ( . not . stateUpdateDone . or . . not . temperatureUpdateDone ) &
. and . . not . crystallite_localConstitution ( g , i , e ) ) then ! if updateState or updateTemperature signals broken non-local...
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!$OMP CRITICAL (checkTodo)
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crystallite_todo = crystallite_todo . and . crystallite_localConstitution ! ...all non-locals skipped
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!$OMP END CRITICAL (checkTodo)
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
elseif ( stateConverged . and . temperatureConverged ) then ! check (private) logicals "stateConverged" and "temperatureConverged" instead of (shared) "crystallite_converged", so no need to flush the "crystallite_converged" array
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if ( iand ( debug_what ( debug_crystallite ) , debug_levelBasic ) / = 0_pInt ) then
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!$OMP CRITICAL (distributionState)
debug_StateLoopDistribution ( NiterationState , numerics_integrationMode ) = &
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debug_StateLoopDistribution ( NiterationState , numerics_integrationMode ) + 1_pInt
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!$OMP END CRITICAL (distributionState)
endif
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endif
endif
enddo ; enddo ; enddo
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!$OMP ENDDO
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! --- UPDATE DEPENDENT STATES ---
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!$OMP DO
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
do e = eIter ( 1 ) , eIter ( 2 ) ; do i = iIter ( 1 , e ) , iIter ( 2 , e ) ; do g = gIter ( 1 , e ) , gIter ( 2 , e ) ! iterate over elements, ips and grains
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if ( crystallite_todo ( g , i , e ) ) then
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call constitutive_microstructure ( crystallite_Temperature ( g , i , e ) , crystallite_Fe ( 1 : 3 , 1 : 3 , g , i , e ) , &
crystallite_Fp ( 1 : 3 , 1 : 3 , g , i , e ) , g , i , e ) ! update dependent state variables to be consistent with basic states
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endif
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constitutive_previousDotState2 ( g , i , e ) % p = constitutive_previousDotState ( g , i , e ) % p ! age previous dotState
constitutive_previousDotState ( g , i , e ) % p = constitutive_dotState ( g , i , e ) % p ! age previous dotState
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constitutive_dotState ( g , i , e ) % p = 0.0_pReal ! reset dotState to zero
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enddo ; enddo ; enddo
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!$OMP ENDDO
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!$OMP END PARALLEL
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#ifndef _OPENMP
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if ( iand ( debug_what ( debug_crystallite ) , debug_levelExtensive ) / = 0_pInt ) then
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write ( 6 , '(a,i8,a,i2)' ) '<< CRYST >> ' , count ( crystallite_converged ( : , : , : ) ) , &
' grains converged after state integration no. ' , NiterationState
write ( 6 , * )
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endif
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#endif
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! --- CONVERGENCE CHECK ---
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if ( . not . singleRun ) then ! if not requesting Integration of just a single IP
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if ( any ( . not . crystallite_converged . and . . not . crystallite_localConstitution ) ) then ! any non-local not yet converged (or broken)...
crystallite_converged = crystallite_converged . and . crystallite_localConstitution ! ...restart all non-local as not converged
endif
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endif
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crystallite_todo = crystallite_todo . and . . not . crystallite_converged ! skip all converged
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2011-03-29 12:57:19 +05:30
#ifndef _OPENMP
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if ( iand ( debug_what ( debug_crystallite ) , debug_levelExtensive ) / = 0_pInt ) then
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write ( 6 , '(a,i8,a)' ) '<< CRYST >> ' , count ( crystallite_converged ( : , : , : ) ) , ' grains converged after non-local check'
write ( 6 , '(a,i8,a,i2)' ) '<< CRYST >> ' , count ( crystallite_todo ( : , : , : ) ) , ' grains todo after state integration no. ' , &
NiterationState
write ( 6 , * )
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endif
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#endif
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enddo ! crystallite convergence loop
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end subroutine crystallite_integrateStateFPI
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!********************************************************************
! update the internal state of the constitutive law
! and tell whether state has converged
!********************************************************************
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
subroutine crystallite_updateState ( done , converged , g , i , e )
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!*** variables and functions from other modules ***!
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use numerics , only : rTol_crystalliteState
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use constitutive , only : constitutive_dotState , &
constitutive_previousDotState , &
constitutive_sizeDotState , &
constitutive_subState0 , &
constitutive_state , &
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constitutive_aTolState , &
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constitutive_microstructure
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use debug , only : debug_what , &
debug_crystallite , &
debug_levelBasic , &
debug_levelExtensive , &
debug_levelSelective , &
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debug_e , &
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debug_i , &
debug_g
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!*** input variables ***!
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
integer ( pInt ) , intent ( in ) :: e , & ! element index
i , & ! integration point index
g ! grain index
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!*** output variables ***!
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
logical , intent ( out ) :: converged , & ! flag indicating if state converged
done ! flag indicating if state was updated
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!*** local variables ***!
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
real ( pReal ) , dimension ( constitutive_sizeDotState ( g , i , e ) ) :: &
residuum , & ! residuum from evolution of microstructure
dotState , & ! local copy of dotState
state ! local copy of relevant part of state
2010-10-01 17:48:49 +05:30
integer ( pInt ) mySize
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
!* start out as not done and not converged
!* and make local copies of state and dotState (needed for parallelization, since no chance of flushing a pointer)
done = . false .
converged = . false .
2010-10-01 17:48:49 +05:30
mySize = constitutive_sizeDotState ( g , i , e )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
dotState ( 1 : mySize ) = constitutive_dotState ( g , i , e ) % p ( 1 : mySize )
state ( 1 : mySize ) = constitutive_state ( g , i , e ) % p ( 1 : mySize )
2010-10-01 17:48:49 +05:30
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
!* correct dotState, calculate residuum and check if it is valid
2010-10-01 17:48:49 +05:30
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
dotState ( 1 : mySize ) = constitutive_dotState ( g , i , e ) % p ( 1 : mySize ) * crystallite_statedamper ( g , i , e ) &
+ constitutive_previousDotState ( g , i , e ) % p ( 1 : mySize ) * ( 1.0_pReal - crystallite_statedamper ( g , i , e ) )
residuum = constitutive_state ( g , i , e ) % p ( 1 : mySize ) - constitutive_subState0 ( g , i , e ) % p ( 1 : mySize ) &
- dotState ( 1 : mySize ) * crystallite_subdt ( g , i , e )
if ( any ( residuum / = residuum ) ) then ! if NaN occured then return without changing the state
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#ifndef _OPENMP
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if ( iand ( debug_what ( debug_crystallite ) , debug_levelBasic ) / = 0_pInt ) then
2012-02-01 00:48:55 +05:30
write ( 6 , '(a,i8,1x,i2,1x,i3)' ) '<< CRYST >> updateState encountered NaN at el ip g ' , e , i , g
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endif
#endif
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return
endif
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
!* update state and set convergence flag to true if residuum is below relative/absolute tolerance, otherwise set it to false
2010-10-01 17:48:49 +05:30
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
state ( 1 : mySize ) = state ( 1 : mySize ) - residuum
done = . true .
converged = all ( abs ( residuum ) < constitutive_aTolState ( g , i , e ) % p ( 1 : mySize ) &
. or . abs ( residuum ) < rTol_crystalliteState * abs ( state ( 1 : mySize ) ) )
2011-03-29 12:57:19 +05:30
#ifndef _OPENMP
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if ( iand ( debug_what ( debug_crystallite ) , debug_levelExtensive ) / = 0_pInt &
. and . ( ( e == debug_e . and . i == debug_i . and . g == debug_g ) &
. or . . not . iand ( debug_what ( debug_crystallite ) , debug_levelSelective ) / = 0_pInt ) ) then
2011-03-29 12:57:19 +05:30
if ( converged ) then
2012-02-01 00:48:55 +05:30
write ( 6 , '(a,i8,1x,i2,1x,i3)' ) '<< CRYST >> updateState converged at el ip g ' , e , i , g
2011-03-29 12:57:19 +05:30
else
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write ( 6 , '(a,i8,1x,i2,1x,i3)' ) '<< CRYST >> updateState did not converge at el ip g ' , e , i , g
2011-03-29 12:57:19 +05:30
endif
write ( 6 , * )
write ( 6 , '(a,f6.1)' ) '<< CRYST >> crystallite_statedamper ' , crystallite_statedamper ( g , i , e )
write ( 6 , * )
2012-02-01 00:48:55 +05:30
write ( 6 , '(a,/,(12x,12(e12.5,1x)))' ) '<< CRYST >> dotState' , dotState ( 1 : mySize )
2011-03-29 12:57:19 +05:30
write ( 6 , * )
2012-02-01 00:48:55 +05:30
write ( 6 , '(a,/,(12x,12(e12.5,1x)))' ) '<< CRYST >> new state' , state ( 1 : mySize )
2011-03-29 12:57:19 +05:30
write ( 6 , * )
2010-10-01 17:48:49 +05:30
endif
2011-03-29 12:57:19 +05:30
#endif
2010-10-01 17:48:49 +05:30
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
!* sync global state and dotState with local copies
constitutive_dotState ( g , i , e ) % p ( 1 : mySize ) = dotState ( 1 : mySize )
constitutive_state ( g , i , e ) % p ( 1 : mySize ) = state ( 1 : mySize )
2012-03-09 01:55:28 +05:30
end subroutine crystallite_updateState
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!********************************************************************
! update the temperature of the grain
! and tell whether it has converged
!********************************************************************
2012-03-09 01:55:28 +05:30
subroutine crystallite_updateTemperature ( done , converged , g , i , e )
2010-10-01 17:48:49 +05:30
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
!*** variables and functions from other modules ***!
use numerics , only : rTol_crystalliteTemperature
use constitutive , only : constitutive_dotTemperature
2012-03-09 01:55:28 +05:30
use debug , only : debug_what , &
debug_crystallite , &
debug_levelBasic
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
!*** input variables ***!
integer ( pInt ) , intent ( in ) :: e , & ! element index
i , & ! integration point index
g ! grain index
2010-10-01 17:48:49 +05:30
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
!*** output variables ***!
logical , intent ( out ) :: converged , & ! flag indicating if temperature converged
done ! flag indicating if temperature was updated
2010-10-01 17:48:49 +05:30
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
!*** local variables ***!
real ( pReal ) residuum ! residuum from evolution of temperature
2009-07-22 21:37:19 +05:30
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
!* start out as not done and not converged
done = . false .
converged = . false .
!* correct dotState, calculate residuum and check if it is valid
!* (if NaN occured then return without changing the temperature)
residuum = crystallite_Temperature ( g , i , e ) - crystallite_subTemperature0 ( g , i , e ) &
- constitutive_dotTemperature ( crystallite_Tstar_v ( 1 : 6 , g , i , e ) , crystallite_Temperature ( g , i , e ) , g , i , e ) &
* crystallite_subdt ( g , i , e )
if ( residuum / = residuum ) then
2011-03-29 12:57:19 +05:30
#ifndef _OPENMP
2012-03-09 01:55:28 +05:30
if ( iand ( debug_what ( debug_crystallite ) , debug_levelBasic ) / = 0_pInt ) then
2012-02-01 00:48:55 +05:30
write ( 6 , '(a,i8,1x,i2,1x,i3)' ) '<< CRYST >> updateTemperature encountered NaN at el ip g ' , e , i , g
2011-03-21 16:01:17 +05:30
endif
2011-03-29 12:57:19 +05:30
#endif
2011-03-21 16:01:17 +05:30
return
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
endif
2009-07-22 21:37:19 +05:30
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
!* update temperature and set convergence flag to true if residuum is below relative tolerance (or zero Kelvin), otherwise set it to false
crystallite_Temperature ( g , i , e ) = crystallite_Temperature ( g , i , e ) - residuum
done = . true .
!$OMP FLUSH(crystallite_Temperature)
converged = ( crystallite_Temperature ( g , i , e ) == 0.0_pReal &
. or . abs ( residuum ) < rTol_crystalliteTemperature * crystallite_Temperature ( g , i , e ) )
2012-03-09 01:55:28 +05:30
end subroutine crystallite_updateTemperature
2009-07-22 21:37:19 +05:30
2009-05-07 21:57:36 +05:30
!***********************************************************************
2009-05-28 22:08:40 +05:30
!*** calculation of stress (P) with time integration ***
!*** based on a residuum in Lp and intermediate ***
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!*** acceleration of the Newton-Raphson correction ***
!***********************************************************************
2010-11-03 22:52:48 +05:30
function crystallite_integrateStress ( &
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g , & ! grain number
i , & ! integration point number
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e , & ! element number
2012-01-26 18:18:59 +05:30
timeFraction &
2010-10-01 17:48:49 +05:30
)
2010-09-06 21:36:41 +05:30
2009-05-07 21:57:36 +05:30
2012-03-09 01:55:28 +05:30
use prec , only : pLongInt
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
use numerics , only : nStress , &
aTol_crystalliteStress , &
rTol_crystalliteStress , &
iJacoLpresiduum , &
relevantStrain , &
numerics_integrationMode
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use debug , only : debug_what , &
debug_crystallite , &
debug_levelBasic , &
debug_levelExtensive , &
debug_levelSelective , &
2012-02-21 22:01:37 +05:30
debug_e , &
debug_i , &
debug_g , &
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
debug_cumLpCalls , &
debug_cumLpTicks , &
debug_StressLoopDistribution , &
debug_LeapfrogBreakDistribution
2012-02-21 22:01:37 +05:30
use constitutive , only : constitutive_LpAndItsTangent , &
constitutive_homogenizedC
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
use math , only : math_mul33x33 , &
2011-11-04 18:27:12 +05:30
math_mul33xx33 , &
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
math_mul66x6 , &
math_mul99x99 , &
2012-01-26 19:20:00 +05:30
math_transpose33 , &
math_inv33 , &
math_invert33 , &
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
math_invert , &
2012-01-26 19:20:00 +05:30
math_det33 , &
2011-08-02 16:59:08 +05:30
math_norm33 , &
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
math_I3 , &
math_identity2nd , &
math_Mandel66to3333 , &
math_Mandel6to33 , &
math_mandel33to6
2009-05-07 21:57:36 +05:30
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
implicit none
2009-05-07 21:57:36 +05:30
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
!*** input variables ***!
integer ( pInt ) , intent ( in ) :: e , & ! element index
i , & ! integration point index
g ! grain index
2012-01-26 18:18:59 +05:30
real ( pReal ) , optional , intent ( in ) :: timeFraction ! fraction of timestep
2010-10-01 17:48:49 +05:30
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
!*** output variables ***!
logical crystallite_integrateStress ! flag indicating if integration suceeded
2009-08-28 19:20:47 +05:30
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
!*** local variables ***!
real ( pReal ) , dimension ( 3 , 3 ) :: Fg_new , & ! deformation gradient at end of timestep
Fp_current , & ! plastic deformation gradient at start of timestep
Fp_new , & ! plastic deformation gradient at end of timestep
Fe_new , & ! elastic deformation gradient at end of timestep
invFp_new , & ! inverse of Fp_new
invFp_current , & ! inverse of Fp_current
Lpguess , & ! current guess for plastic velocity gradient
Lpguess_old , & ! known last good guess for plastic velocity gradient
Lp_constitutive , & ! plastic velocity gradient resulting from constitutive law
residuum , & ! current residuum of plastic velocity gradient
residuum_old , & ! last residuum of plastic velocity gradient
2011-11-04 18:27:12 +05:30
deltaLp , & ! direction of next guess
gradientR , & ! derivative of the residuum norm
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
A , &
B , &
BT , &
AB , &
BTA
real ( pReal ) , dimension ( 6 ) :: Tstar_v ! 2nd Piola-Kirchhoff Stress in Mandel-Notation
2011-08-02 16:59:08 +05:30
real ( pReal ) , dimension ( 9 , 9 ) :: dLp_dT_constitutive , & ! partial derivative of plastic velocity gradient calculated by constitutive law
dT_dLp , & ! partial derivative of 2nd Piola-Kirchhoff stress
dR_dLp , & ! partial derivative of residuum (Jacobian for NEwton-Raphson scheme)
inv_dR_dLp ! inverse of dRdLp
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
real ( pReal ) , dimension ( 3 , 3 , 3 , 3 ) :: C ! 4th rank elasticity tensor
real ( pReal ) , dimension ( 6 , 6 ) :: C_66 ! simplified 2nd rank elasticity tensor
real ( pReal ) p_hydro , & ! volumetric part of 2nd Piola-Kirchhoff Stress
det , & ! determinant
2011-11-04 18:27:12 +05:30
expectedImprovement , &
2011-08-02 16:59:08 +05:30
steplength0 , &
steplength , &
steplength_max , &
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
dt ! time increment
logical error ! flag indicating an error
integer ( pInt ) NiterationStress , & ! number of stress integrations
dummy , &
h , &
j , &
k , &
l , &
m , &
n , &
jacoCounter ! counter to check for Jacobian update
integer ( pLongInt ) tick , &
tock , &
tickrate , &
maxticks
2011-08-02 16:59:08 +05:30
2009-05-28 22:08:40 +05:30
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
!* be pessimistic
crystallite_integrateStress = . false .
2011-03-29 12:57:19 +05:30
#ifndef _OPENMP
2012-03-09 01:55:28 +05:30
if ( iand ( debug_what ( debug_crystallite ) , debug_levelExtensive ) / = 0_pInt &
. and . ( ( e == debug_e . and . i == debug_i . and . g == debug_g ) &
. or . . not . iand ( debug_what ( debug_crystallite ) , debug_levelSelective ) / = 0_pInt ) ) then
2012-02-01 00:48:55 +05:30
write ( 6 , '(a,i8,1x,i2,1x,i3)' ) '<< CRYST >> integrateStress at el ip g ' , e , i , g
2011-03-21 16:01:17 +05:30
endif
2011-03-29 12:57:19 +05:30
#endif
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
!* only integrate over fraction of timestep?
2012-01-26 18:18:59 +05:30
if ( present ( timeFraction ) ) then
dt = crystallite_subdt ( g , i , e ) * timeFraction
Fg_new = crystallite_subF0 ( 1 : 3 , 1 : 3 , g , i , e ) + ( crystallite_subF ( 1 : 3 , 1 : 3 , g , i , e ) - crystallite_subF0 ( 1 : 3 , 1 : 3 , g , i , e ) ) * timeFraction
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
else
dt = crystallite_subdt ( g , i , e )
Fg_new = crystallite_subF ( 1 : 3 , 1 : 3 , g , i , e )
endif
2009-05-28 22:08:40 +05:30
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
!* feed local variables
Fp_current = crystallite_subFp0 ( 1 : 3 , 1 : 3 , g , i , e )
Lpguess_old = crystallite_Lp ( 1 : 3 , 1 : 3 , g , i , e ) ! consider present Lp good (i.e. worth remembering) ...
Lpguess = crystallite_Lp ( 1 : 3 , 1 : 3 , g , i , e ) ! ... and take it as first guess
!* inversion of Fp_current...
2012-01-26 19:20:00 +05:30
invFp_current = math_inv33 ( Fp_current )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
if ( all ( invFp_current == 0.0_pReal ) ) then ! ... failed?
2011-03-29 12:57:19 +05:30
#ifndef _OPENMP
2012-03-09 01:55:28 +05:30
if ( iand ( debug_what ( debug_crystallite ) , debug_levelBasic ) / = 0_pInt ) then
2012-02-01 00:48:55 +05:30
write ( 6 , '(a,i8,1x,i2,1x,i3)' ) '<< CRYST >> integrateStress failed on invFp_current inversion at el ip g ' , e , i , g
2012-03-09 01:55:28 +05:30
if ( iand ( debug_what ( debug_crystallite ) , debug_levelSelective ) > 0_pInt &
. and . ( ( e == debug_e . and . i == debug_i . and . g == debug_g ) &
. or . . not . iand ( debug_what ( debug_crystallite ) , debug_levelSelective ) / = 0_pInt ) ) then
2011-03-29 12:57:19 +05:30
write ( 6 , * )
2012-02-01 00:48:55 +05:30
write ( 6 , '(a,/,3(12x,3(f12.7,1x)/))' ) '<< CRYST >> invFp_new' , math_transpose33 ( invFp_new ( 1 : 3 , 1 : 3 ) )
2011-03-29 12:57:19 +05:30
endif
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
endif
2011-03-29 12:57:19 +05:30
#endif
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
return
endif
A = math_mul33x33 ( transpose ( invFp_current ) , math_mul33x33 ( transpose ( Fg_new ) , math_mul33x33 ( Fg_new , invFp_current ) ) )
2009-05-28 22:08:40 +05:30
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
!* get elasticity tensor
C_66 = constitutive_homogenizedC ( g , i , e )
C = math_Mandel66to3333 ( C_66 )
2011-08-02 16:59:08 +05:30
!* start LpLoop with normal step length
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
NiterationStress = 0_pInt
2011-08-02 16:59:08 +05:30
steplength0 = 1.0_pReal
steplength = steplength0
steplength_max = 1 6.0_pReal
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
jacoCounter = 0_pInt
2009-05-07 21:57:36 +05:30
2009-05-28 22:08:40 +05:30
LpLoop : do
2012-02-21 22:01:37 +05:30
NiterationStress = NiterationStress + 1_pInt
2009-05-28 22:08:40 +05:30
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
!* too many loops required ?
if ( NiterationStress > nStress ) then
2011-03-29 12:57:19 +05:30
#ifndef _OPENMP
2012-03-09 01:55:28 +05:30
if ( iand ( debug_what ( debug_crystallite ) , debug_levelBasic ) / = 0_pInt ) then
2012-02-01 00:48:55 +05:30
write ( 6 , '(a,i8,1x,i2,1x,i3)' ) '<< CRYST >> integrateStress reached loop limit at el ip g ' , e , i , g
2011-03-29 12:57:19 +05:30
write ( 6 , * )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
endif
2011-03-29 12:57:19 +05:30
#endif
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
return
endif
2009-05-28 22:08:40 +05:30
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
B = math_I3 - dt * Lpguess
2012-01-26 19:20:00 +05:30
BT = math_transpose33 ( B )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
AB = math_mul33x33 ( A , B )
BTA = math_mul33x33 ( BT , A )
2009-05-28 22:08:40 +05:30
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
!* calculate 2nd Piola-Kirchhoff stress tensor
Tstar_v = 0.5_pReal * math_mul66x6 ( C_66 , math_mandel33to6 ( math_mul33x33 ( BT , AB ) - math_I3 ) )
p_hydro = sum ( Tstar_v ( 1 : 3 ) ) / 3.0_pReal
2012-02-21 22:01:37 +05:30
forall ( n = 1_pInt : 3_pInt ) Tstar_v ( n ) = Tstar_v ( n ) - p_hydro ! get deviatoric stress tensor
2009-05-28 22:08:40 +05:30
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
!* calculate plastic velocity gradient and its tangent according to constitutive law
2012-03-09 01:55:28 +05:30
if ( iand ( debug_what ( debug_crystallite ) , debug_levelBasic ) / = 0_pInt ) then
2011-03-21 16:01:17 +05:30
call system_clock ( count = tick , count_rate = tickrate , count_max = maxticks )
endif
2011-08-02 16:59:08 +05:30
call constitutive_LpAndItsTangent ( Lp_constitutive , dLp_dT_constitutive , Tstar_v , crystallite_Temperature ( g , i , e ) , g , i , e )
2012-03-09 01:55:28 +05:30
if ( iand ( debug_what ( debug_crystallite ) , debug_levelBasic ) / = 0_pInt ) then
2011-03-21 16:01:17 +05:30
call system_clock ( count = tock , count_rate = tickrate , count_max = maxticks )
!$OMP CRITICAL (debugTimingLpTangent)
debug_cumLpCalls = debug_cumLpCalls + 1_pInt
debug_cumLpTicks = debug_cumLpTicks + tock - tick
!$OMP FLUSH (debug_cumLpTicks)
if ( tock < tick ) debug_cumLpTicks = debug_cumLpTicks + maxticks
!$OMP END CRITICAL (debugTimingLpTangent)
endif
2010-11-19 22:59:29 +05:30
2011-03-29 12:57:19 +05:30
#ifndef _OPENMP
2012-03-09 01:55:28 +05:30
if ( iand ( debug_what ( debug_crystallite ) , debug_levelSelective ) / = 0_pInt &
. and . ( ( e == debug_e . and . i == debug_i . and . g == debug_g ) &
. or . . not . iand ( debug_what ( debug_crystallite ) , debug_levelSelective ) / = 0_pInt ) &
2011-03-21 16:01:17 +05:30
. and . numerics_integrationMode == 1_pInt ) then
2011-03-29 12:57:19 +05:30
write ( 6 , '(a,i3)' ) '<< CRYST >> iteration ' , NiterationStress
write ( 6 , * )
2012-02-01 00:48:55 +05:30
write ( 6 , '(a,/,3(12x,3(e20.7,1x)/))' ) '<< CRYST >> Lp_constitutive' , math_transpose33 ( Lp_constitutive )
write ( 6 , '(a,/,3(12x,3(e20.7,1x)/))' ) '<< CRYST >> Lpguess' , math_transpose33 ( Lpguess )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
endif
2011-03-29 12:57:19 +05:30
#endif
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
!* update current residuum and check for convergence of loop
residuum = Lpguess - Lp_constitutive
2011-08-02 16:59:08 +05:30
if ( . not . ( any ( residuum / = residuum ) ) . and . & ! exclude any NaN in residuum
2009-05-28 22:08:40 +05:30
( maxval ( abs ( residuum ) ) < aTol_crystalliteStress . or . & ! below absolute tolerance .or.
2011-08-02 16:59:08 +05:30
( any ( abs ( dt * Lpguess ) > relevantStrain ) . and . & ! worth checking? .and.
maxval ( abs ( residuum / Lpguess ) , abs ( dt * Lpguess ) > relevantStrain ) < rTol_crystalliteStress & ! below relative tolerance
2009-05-07 21:57:36 +05:30
) &
2009-05-28 22:08:40 +05:30
) &
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
) then
exit LpLoop
endif
2011-08-02 16:59:08 +05:30
!* NaN occured at regular speed -> return
if ( steplength > = steplength0 . and . any ( residuum / = residuum ) ) then
2011-03-29 12:57:19 +05:30
#ifndef _OPENMP
2012-03-09 01:55:28 +05:30
if ( iand ( debug_what ( debug_crystallite ) , debug_levelBasic ) / = 0_pInt ) then
2012-02-01 00:48:55 +05:30
write ( 6 , '(a,i8,1x,i2,1x,i3,a,i3,a)' ) '<< CRYST >> integrateStress encountered NaN at el ip g ' , e , i , g , &
2011-03-29 12:57:19 +05:30
' ; iteration ' , NiterationStress , &
' >> returning..!'
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
endif
2011-03-29 12:57:19 +05:30
#endif
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
return
2011-08-02 16:59:08 +05:30
endif
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
2011-08-02 16:59:08 +05:30
if ( NiterationStress > 1_pInt ) then
!* not at regular speed
if ( steplength < = steplength0 ) then
!* Armijo rule is fullfilled (norm of residuum was reduced by at least 0.01 of what was expected)
2011-11-04 18:27:12 +05:30
if ( math_norm33 ( residuum ) < = math_norm33 ( residuum_old ) + 0.01_pReal * steplength * expectedImprovement ) then
2011-08-02 16:59:08 +05:30
!* reduced step length -> return to normal step length
if ( steplength < steplength0 ) then
steplength = steplength0
!* normal step length without change in sign of residuum -> accelerate if not yet at maximum speed
elseif ( sum ( residuum * residuum_old ) > = 0.0_pReal . and . steplength + 1_pInt < = steplength_max ) then
steplength = steplength + 1.0_pReal
endif
!* Armijo rule not fullfilled -> try smaller step size in same direction
else
steplength = 0.5_pReal * steplength
Lpguess = Lpguess_old + steplength * deltaLp
cycle LpLoop
endif
!* at high-speed
else
!* no NaN, Armijo rule fullfilled, and sign of residuum did not change -> accelerate if not yet at maximum speed
if ( . not . any ( residuum / = residuum ) &
2011-11-04 18:27:12 +05:30
. and . math_norm33 ( residuum ) < = math_norm33 ( residuum_old ) + 0.01_pReal * steplength * expectedImprovement &
2011-08-02 16:59:08 +05:30
. and . sum ( residuum * residuum_old ) > = 0.0_pReal ) then
if ( steplength + 1_pInt < = steplength_max ) then
steplength = steplength + 1.0_pReal
endif
!* something went wrong at accelerated speed? -> return to regular speed and try again
else
2011-03-29 12:57:19 +05:30
#ifndef _OPENMP
2012-03-09 01:55:28 +05:30
if ( iand ( debug_what ( debug_crystallite ) , debug_levelExtensive ) / = 0_pInt ) then
2012-02-01 00:48:55 +05:30
write ( 6 , '(a,i8,1x,i2,1x,i3,1x,a,i3)' ) '<< CRYST >> integrateStress encountered high-speed crash at el ip g ' , e , i , g , &
2011-08-02 16:59:08 +05:30
'; iteration ' , NiterationStress
endif
2011-03-29 12:57:19 +05:30
#endif
2011-08-02 16:59:08 +05:30
!* NaN occured -> use old guess and residuum
if ( any ( residuum / = residuum ) ) then
Lpguess = Lpguess_old
residuum = residuum_old
endif
steplength_max = steplength - 1.0_pReal ! limit acceleration
steplength = steplength0 ! grinding halt
jacoCounter = 0_pInt ! reset counter for Jacobian update (we want to do an update next time!)
2012-03-09 01:55:28 +05:30
if ( iand ( debug_what ( debug_crystallite ) , debug_levelBasic ) / = 0_pInt ) then
2011-08-02 16:59:08 +05:30
!$OMP CRITICAL (distributionLeapfrogBreak)
debug_LeapfrogBreakDistribution ( NiterationStress , numerics_integrationMode ) = &
2012-02-21 22:01:37 +05:30
debug_LeapfrogBreakDistribution ( NiterationStress , numerics_integrationMode ) + 1_pInt
2011-08-02 16:59:08 +05:30
!$OMP END CRITICAL (distributionLeapfrogBreak)
endif
endif
2011-03-21 16:01:17 +05:30
endif
2011-08-02 16:59:08 +05:30
endif
!* calculate Jacobian for correction term and remember current residuum and Lpguess
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
2011-08-02 16:59:08 +05:30
if ( mod ( jacoCounter , iJacoLpresiduum ) == 0_pInt ) then
dT_dLp = 0.0_pReal
2012-02-21 22:01:37 +05:30
do h = 1_pInt , 3_pInt ; do j = 1_pInt , 3_pInt ; do k = 1_pInt , 3_pInt ; do l = 1_pInt , 3_pInt ; do m = 1_pInt , 3_pInt
2011-08-02 16:59:08 +05:30
dT_dLp ( 3 * ( h - 1 ) + j , 3 * ( k - 1 ) + l ) = dT_dLp ( 3 * ( h - 1 ) + j , 3 * ( k - 1 ) + l ) + C ( h , j , l , m ) * AB ( k , m ) + C ( h , j , m , l ) * BTA ( m , k )
enddo ; enddo ; enddo ; enddo ; enddo
dT_dLp = - 0.5_pReal * dt * dT_dLp
2012-02-13 19:48:07 +05:30
dR_dLp = math_identity2nd ( 9_pInt ) - math_mul99x99 ( dLp_dT_constitutive , dT_dLp )
2011-08-02 16:59:08 +05:30
inv_dR_dLp = 0.0_pReal
2012-02-13 19:48:07 +05:30
call math_invert ( 9_pInt , dR_dLp , inv_dR_dLp , dummy , error ) ! invert dR/dLp --> dLp/dR
2011-08-02 16:59:08 +05:30
if ( error ) then
2011-03-29 12:57:19 +05:30
#ifndef _OPENMP
2012-03-09 01:55:28 +05:30
if ( iand ( debug_what ( debug_crystallite ) , debug_levelBasic ) / = 0_pInt ) then
2012-02-01 00:48:55 +05:30
write ( 6 , '(a,i8,1x,i2,1x,i3,a,i3)' ) '<< CRYST >> integrateStress failed on dR/dLp inversion at el ip g ' , e , i , g
2012-03-09 01:55:28 +05:30
if ( iand ( debug_what ( debug_crystallite ) , debug_levelExtensive ) / = 0_pInt &
. and . ( ( e == debug_e . and . i == debug_i . and . g == debug_g ) &
. or . . not . iand ( debug_what ( debug_crystallite ) , debug_levelSelective ) / = 0_pInt ) ) then
2011-08-02 16:59:08 +05:30
write ( 6 , * )
2012-02-01 00:48:55 +05:30
write ( 6 , '(a,/,9(12x,9(e15.3,1x)/))' ) '<< CRYST >> dR_dLp' , transpose ( dR_dLp )
write ( 6 , '(a,/,9(12x,9(e15.3,1x)/))' ) '<< CRYST >> dT_dLp' , transpose ( dT_dLp )
write ( 6 , '(a,/,9(12x,9(e15.3,1x)/))' ) '<< CRYST >> dLp_dT_constitutive' , transpose ( dLp_dT_constitutive )
write ( 6 , '(a,/,3(12x,3(e20.7,1x)/))' ) '<< CRYST >> AB' , math_transpose33 ( AB )
write ( 6 , '(a,/,3(12x,3(e20.7,1x)/))' ) '<< CRYST >> BTA' , math_transpose33 ( BTA )
write ( 6 , '(a,/,3(12x,3(e20.7,1x)/))' ) '<< CRYST >> Lp_constitutive' , math_transpose33 ( Lp_constitutive )
write ( 6 , '(a,/,3(12x,3(e20.7,1x)/))' ) '<< CRYST >> Lpguess' , math_transpose33 ( Lpguess )
2011-03-29 12:57:19 +05:30
endif
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
endif
2011-08-02 16:59:08 +05:30
#endif
return
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
endif
2011-08-02 16:59:08 +05:30
deltaLp = 0.0_pReal
2012-02-21 22:01:37 +05:30
do k = 1_pInt , 3_pInt ; do l = 1_pInt , 3_pInt ; do m = 1_pInt , 3_pInt ; do n = 1_pInt , 3_pInt
deltaLp ( k , l ) = deltaLp ( k , l ) - inv_dR_dLp ( 3_pInt * ( k - 1_pInt ) + l , 3_pInt * ( m - 1_pInt ) + n ) * residuum ( m , n )
2011-08-02 16:59:08 +05:30
enddo ; enddo ; enddo ; enddo
2011-11-04 18:27:12 +05:30
gradientR = 0.0_pReal
2012-02-21 22:01:37 +05:30
do k = 1_pInt , 3_pInt ; do l = 1_pInt , 3_pInt ; do m = 1_pInt , 3_pInt ; do n = 1_pInt , 3_pInt
gradientR ( k , l ) = gradientR ( k , l ) + dR_dLp ( 3 * ( k - 1 ) + l , 3_pInt * ( m - 1_pInt ) + n ) * residuum ( m , n )
2011-08-02 16:59:08 +05:30
enddo ; enddo ; enddo ; enddo
2011-11-04 18:27:12 +05:30
gradientR = gradientR / math_norm33 ( gradientR )
expectedImprovement = math_mul33xx33 ( deltaLp , gradientR )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
endif
2011-08-02 16:59:08 +05:30
jacoCounter = jacoCounter + 1_pInt ! increase counter for jaco update
residuum_old = residuum
Lpguess_old = Lpguess
Lpguess = Lpguess + steplength * deltaLp
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
enddo LpLoop
!* calculate new plastic and elastic deformation gradient
invFp_new = math_mul33x33 ( invFp_current , B )
2012-01-26 19:20:00 +05:30
invFp_new = invFp_new / math_det33 ( invFp_new ) ** ( 1.0_pReal / 3.0_pReal ) ! regularize by det
call math_invert33 ( invFp_new , Fp_new , det , error )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
if ( error ) then
2011-03-29 12:57:19 +05:30
#ifndef _OPENMP
2012-03-09 01:55:28 +05:30
if ( iand ( debug_what ( debug_crystallite ) , debug_levelBasic ) / = 0_pInt ) then
2012-02-21 22:01:37 +05:30
write ( 6 , '(a,i8,1x,i2,1x,i3,a,i3)' ) '<< CRYST >> integrateStress failed on invFp_new inversion at el ip g ' , &
e , i , g , ' ; iteration ' , NiterationStress
2012-03-09 01:55:28 +05:30
if ( iand ( debug_what ( debug_crystallite ) , debug_levelExtensive ) / = 0_pInt &
. and . ( ( e == debug_e . and . i == debug_i . and . g == debug_g ) &
. or . . not . iand ( debug_what ( debug_crystallite ) , debug_levelSelective ) / = 0_pInt ) ) then
2011-03-29 12:57:19 +05:30
write ( 6 , * )
2012-02-01 00:48:55 +05:30
write ( 6 , '(a,/,3(12x,3(f12.7,1x)/))' ) '<< CRYST >> invFp_new' , math_transpose33 ( invFp_new )
2011-03-29 12:57:19 +05:30
endif
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
endif
2011-03-29 12:57:19 +05:30
#endif
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
return
endif
Fe_new = math_mul33x33 ( Fg_new , invFp_new ) ! calc resulting Fe
!* add volumetric component to 2nd Piola-Kirchhoff stress and calculate 1st Piola-Kirchhoff stress
2012-02-21 22:01:37 +05:30
forall ( n = 1_pInt : 3_pInt ) Tstar_v ( n ) = Tstar_v ( n ) + p_hydro
2012-01-26 19:20:00 +05:30
crystallite_P ( 1 : 3 , 1 : 3 , g , i , e ) = math_mul33x33 ( Fe_new , math_mul33x33 ( math_Mandel6to33 ( Tstar_v ) , math_transpose33 ( invFp_new ) ) )
2009-05-28 22:08:40 +05:30
2009-05-07 21:57:36 +05:30
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
!* store local values in global variables
crystallite_Lp ( 1 : 3 , 1 : 3 , g , i , e ) = Lpguess
crystallite_Tstar_v ( 1 : 6 , g , i , e ) = Tstar_v
crystallite_Fp ( 1 : 3 , 1 : 3 , g , i , e ) = Fp_new
crystallite_Fe ( 1 : 3 , 1 : 3 , g , i , e ) = Fe_new
crystallite_invFp ( 1 : 3 , 1 : 3 , g , i , e ) = invFp_new
!* set return flag to true
crystallite_integrateStress = . true .
2011-03-29 12:57:19 +05:30
#ifndef _OPENMP
2012-03-09 01:55:28 +05:30
if ( iand ( debug_what ( debug_crystallite ) , debug_levelExtensive ) / = 0_pInt &
. and . ( ( e == debug_e . and . i == debug_i . and . g == debug_g ) &
. or . . not . iand ( debug_what ( debug_crystallite ) , debug_levelSelective ) / = 0_pInt ) &
2011-03-21 16:01:17 +05:30
. and . numerics_integrationMode == 1_pInt ) then
2012-02-21 22:01:37 +05:30
write ( 6 , '(a,/,3(12x,3(f12.7,1x)/))' ) '<< CRYST >> P / MPa' , math_transpose33 ( crystallite_P ( 1 : 3 , 1 : 3 , g , i , e ) ) / 1.0e6_pReal
2012-02-01 00:48:55 +05:30
write ( 6 , '(a,/,3(12x,3(f12.7,1x)/))' ) '<< CRYST >> Cauchy / MPa' , &
2012-02-21 22:01:37 +05:30
math_mul33x33 ( crystallite_P ( 1 : 3 , 1 : 3 , g , i , e ) , math_transpose33 ( Fg_new ) ) / 1.0e6_pReal / math_det33 ( Fg_new )
2012-02-01 00:48:55 +05:30
write ( 6 , '(a,/,3(12x,3(f12.7,1x)/))' ) '<< CRYST >> Fe Lp Fe^-1' , &
2012-02-21 22:01:37 +05:30
math_transpose33 ( math_mul33x33 ( Fe_new , math_mul33x33 ( crystallite_Lp ( 1 : 3 , 1 : 3 , g , i , e ) , math_inv33 ( Fe_new ) ) ) ) ! transpose to get correct print out order
2012-02-01 00:48:55 +05:30
write ( 6 , '(a,/,3(12x,3(f12.7,1x)/))' ) '<< CRYST >> Fp' , math_transpose33 ( crystallite_Fp ( 1 : 3 , 1 : 3 , g , i , e ) )
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
endif
2011-03-29 12:57:19 +05:30
#endif
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
2012-03-09 01:55:28 +05:30
if ( iand ( debug_what ( debug_crystallite ) , debug_levelBasic ) / = 0_pInt ) then
2011-03-21 16:01:17 +05:30
!$OMP CRITICAL (distributionStress)
debug_StressLoopDistribution ( NiterationStress , numerics_integrationMode ) = &
2012-02-21 22:01:37 +05:30
debug_StressLoopDistribution ( NiterationStress , numerics_integrationMode ) + 1_pInt
2011-03-21 16:01:17 +05:30
!$OMP END CRITICAL (distributionStress)
endif
2009-05-07 21:57:36 +05:30
2012-03-09 01:55:28 +05:30
end function crystallite_integrateStress
2009-05-28 22:08:40 +05:30
2009-05-07 21:57:36 +05:30
2009-12-18 21:16:33 +05:30
!********************************************************************
2010-04-28 22:49:58 +05:30
! calculates orientations and disorientations (in case of single grain ips)
2009-12-18 21:16:33 +05:30
!********************************************************************
2012-03-09 01:55:28 +05:30
subroutine crystallite_orientations
2009-12-18 21:16:33 +05:30
!*** variables and functions from other modules ***!
2012-03-09 01:55:28 +05:30
2010-02-19 19:14:38 +05:30
use math , only : math_pDecomposition , &
2010-03-18 17:53:17 +05:30
math_RtoQuaternion , &
2010-04-28 22:49:58 +05:30
math_QuaternionDisorientation , &
2010-05-11 20:36:21 +05:30
math_qConj
2010-02-19 19:14:38 +05:30
use FEsolving , only : FEsolving_execElem , &
FEsolving_execIP
use IO , only : IO_warning
use material , only : material_phase , &
homogenization_Ngrains , &
2010-10-12 18:38:54 +05:30
phase_localConstitution , &
phase_constitutionInstance
2010-02-19 19:14:38 +05:30
use mesh , only : mesh_element , &
mesh_ipNeighborhood , &
FE_NipNeighbors
2010-10-12 18:38:54 +05:30
use constitutive_nonlocal , only : constitutive_nonlocal_structure , &
constitutive_nonlocal_updateCompatibility
2009-12-18 21:16:33 +05:30
implicit none
!*** input variables ***!
!*** output variables ***!
!*** local variables ***!
2010-02-19 19:14:38 +05:30
integer ( pInt ) e , & ! element index
i , & ! integration point index
g , & ! grain index
n , & ! neighbor index
neighboring_e , & ! element index of my neighbor
neighboring_i , & ! integration point index of my neighbor
2010-10-12 18:38:54 +05:30
myPhase , & ! phase
neighboringPhase , &
myInstance , & ! instance of constitution
neighboringInstance , &
myStructure , & ! lattice structure
neighboringStructure
2010-03-18 17:53:17 +05:30
real ( pReal ) , dimension ( 3 , 3 ) :: U , R
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
real ( pReal ) , dimension ( 4 ) :: orientation
2009-12-18 21:16:33 +05:30
logical error
2010-10-12 18:38:54 +05:30
! --- CALCULATE ORIENTATION AND LATTICE ROTATION ---
2009-12-18 21:16:33 +05:30
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
!$OMP PARALLEL DO PRIVATE(error,U,R,orientation)
2010-02-19 19:14:38 +05:30
do e = FEsolving_execElem ( 1 ) , FEsolving_execElem ( 2 )
do i = FEsolving_execIP ( 1 , e ) , FEsolving_execIP ( 2 , e )
2012-02-21 22:01:37 +05:30
do g = 1_pInt , homogenization_Ngrains ( mesh_element ( 3 , e ) )
2010-10-12 18:38:54 +05:30
2010-11-11 18:44:53 +05:30
call math_pDecomposition ( crystallite_Fe ( 1 : 3 , 1 : 3 , g , i , e ) , U , R , error ) ! polar decomposition of Fe
2010-02-19 19:14:38 +05:30
if ( error ) then
2012-02-13 19:48:07 +05:30
call IO_warning ( 650_pInt , e , i , g )
orientation = [ 1.0_pReal , 0.0_pReal , 0.0_pReal , 0.0_pReal ] ! fake orientation
2010-02-19 19:14:38 +05:30
else
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
orientation = math_RtoQuaternion ( transpose ( R ) )
2010-02-19 19:14:38 +05:30
endif
2011-04-15 00:39:44 +05:30
crystallite_rotation ( 1 : 4 , g , i , e ) = math_QuaternionDisorientation ( crystallite_orientation0 ( 1 : 4 , g , i , e ) , & ! active rotation from ori0
orientation , & ! to current orientation
0_pInt ) ! we don't want symmetry here
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
2011-03-17 16:16:17 +05:30
crystallite_orientation ( 1 : 4 , g , i , e ) = orientation
2010-04-12 16:44:36 +05:30
enddo
enddo
enddo
2010-11-19 22:59:29 +05:30
!$OMP END PARALLEL DO
2010-10-12 18:38:54 +05:30
! --- UPDATE SOME ADDITIONAL VARIABLES THAT ARE NEEDED FOR NONLOCAL MATERIAL ---
! --- we use crystallite_orientation from above, so need a seperate loop
2011-12-06 22:28:17 +05:30
!$OMP PARALLEL DO PRIVATE(myPhase,myInstance,myStructure,neighboring_e,neighboring_i,neighboringPhase,&
!$OMP neighboringInstance,neighboringStructure)
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do e = FEsolving_execElem ( 1 ) , FEsolving_execElem ( 2 )
do i = FEsolving_execIP ( 1 , e ) , FEsolving_execIP ( 2 , e )
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myPhase = material_phase ( 1 , i , e ) ! get my phase
if ( . not . phase_localConstitution ( myPhase ) ) then ! if nonlocal model
myInstance = phase_constitutionInstance ( myPhase )
myStructure = constitutive_nonlocal_structure ( myInstance ) ! get my crystal structure
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! --- calculate disorientation between me and my neighbor ---
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do n = 1_pInt , FE_NipNeighbors ( mesh_element ( 2 , e ) ) ! loop through my neighbors
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neighboring_e = mesh_ipNeighborhood ( 1 , n , i , e )
neighboring_i = mesh_ipNeighborhood ( 2 , n , i , e )
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if ( ( neighboring_e > 0 ) . and . ( neighboring_i > 0 ) ) then ! if neighbor exists
neighboringPhase = material_phase ( 1 , neighboring_i , neighboring_e ) ! get my neighbor's phase
if ( . not . phase_localConstitution ( neighboringPhase ) ) then ! neighbor got also nonlocal constitution
neighboringInstance = phase_constitutionInstance ( neighboringPhase )
neighboringStructure = constitutive_nonlocal_structure ( neighboringInstance ) ! get my neighbor's crystal structure
if ( myStructure == neighboringStructure ) then ! if my neighbor has same crystal structure like me
crystallite_disorientation ( : , n , 1 , i , e ) = &
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math_QuaternionDisorientation ( crystallite_orientation ( 1 : 4 , 1 , i , e ) , &
crystallite_orientation ( 1 : 4 , 1 , neighboring_i , neighboring_e ) , &
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crystallite_symmetryID ( 1 , i , e ) ) ! calculate disorientation
else ! for neighbor with different phase
crystallite_disorientation ( : , n , 1 , i , e ) = ( / 0.0_pReal , 1.0_pReal , 0.0_pReal , 0.0_pReal / ) ! 180 degree rotation about 100 axis
endif
else ! for neighbor with local constitution
crystallite_disorientation ( : , n , 1 , i , e ) = ( / - 1.0_pReal , 0.0_pReal , 0.0_pReal , 0.0_pReal / ) ! homomorphic identity
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endif
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else ! no existing neighbor
crystallite_disorientation ( : , n , 1 , i , e ) = ( / - 1.0_pReal , 0.0_pReal , 0.0_pReal , 0.0_pReal / ) ! homomorphic identity
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endif
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enddo
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! --- calculate compatibility and transmissivity between me and my neighbor ---
call constitutive_nonlocal_updateCompatibility ( crystallite_orientation , i , e )
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endif
enddo
enddo
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!$OMP END PARALLEL DO
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end subroutine crystallite_orientations
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!********************************************************************
! return results of particular grain
!********************************************************************
function crystallite_postResults ( &
dt , & ! time increment
g , & ! grain number
i , & ! integration point number
e & ! element number
)
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!*** variables and functions from other modules ***!
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use math , only : math_QuaternionToEuler , &
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math_QuaternionToAxisAngle , &
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math_mul33x33 , &
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math_transpose33 , &
math_det33 , &
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math_I3 , &
inDeg , &
math_Mandel6to33
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use mesh , only : mesh_element , &
mesh_ipVolume
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use material , only : microstructure_crystallite , &
crystallite_Noutput , &
material_phase , &
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material_texture , &
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homogenization_Ngrains
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use constitutive , only : constitutive_sizePostResults , &
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constitutive_postResults , &
constitutive_homogenizedC
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implicit none
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!*** input variables ***!
integer ( pInt ) , intent ( in ) :: e , & ! element index
i , & ! integration point index
g ! grain index
constitutive_nonlocal:
- read in activation energy for dislocation glide from material.config
- changed naming of dDipMin/Max to dLower/dUpper
- added new outputs: rho_dot, rho_dot_dip, rho_dot_gen, rho_dot_sgl2dip, rho_dot_dip2sgl, rho_dot_ann_ath, rho_dot_ann_the, rho_dot_flux, d_upper_edge, d_upper_screw, d_upper_dot_edge, d_upper_dot_screw
- poisson's ratio is now calculated from elastic constants
- microstrucutre has state as first argument, since this is our output variable
- periodic boundary conditions are taken into account for fluxes and internal stresses. for the moment, flag has to be set in constitutive_nonlocal.
- corrected calculation for dipole formation by glide
- added terms for dipole formation/annihilation by stress decrease/increase
constitutive:
- passing of arguments is adapted for constitutive_nonlocal model
crystallite:
- in stiffness calculation: call to collect_dotState used wrong arguments
- crystallite_postResults uses own Tstar_v and temperature, no need for passing them from materialpoint_postResults
homogenization:
- crystallite_postResults uses own Tstar_v and temperature, no need for passing them from materialpoint_postResults
IO:
- changed error message 229
material.config:
- changed example for nonlocal constitution according to constitutive_nonlocal
all:
- added some flush statements
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real ( pReal ) , intent ( in ) :: dt ! time increment
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!*** output variables ***!
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real ( pReal ) , dimension ( 1 + crystallite_sizePostResults ( microstructure_crystallite ( mesh_element ( 4 , e ) ) ) + &
1 + constitutive_sizePostResults ( g , i , e ) ) :: crystallite_postResults
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!*** local variables ***!
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real ( pReal ) , dimension ( 3 , 3 ) :: Ee
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real ( pReal ) detF
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integer ( pInt ) o , c , crystID , mySize
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crystID = microstructure_crystallite ( mesh_element ( 4 , e ) )
crystallite_postResults = 0.0_pReal
c = 0_pInt
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crystallite_postResults ( c + 1 ) = real ( crystallite_sizePostResults ( crystID ) , pReal ) ! size of results from cryst
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
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c = c + 1_pInt
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do o = 1_pInt , crystallite_Noutput ( crystID )
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mySize = 0_pInt
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select case ( crystallite_output ( o , crystID ) )
case ( 'phase' )
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mySize = 1_pInt
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crystallite_postResults ( c + 1 ) = real ( material_phase ( g , i , e ) , pReal ) ! phaseID of grain
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case ( 'texture' )
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mySize = 1_pInt
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crystallite_postResults ( c + 1 ) = real ( material_texture ( g , i , e ) , pReal ) ! textureID of grain
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case ( 'volume' )
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mySize = 1_pInt
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detF = math_det33 ( crystallite_partionedF ( 1 : 3 , 1 : 3 , g , i , e ) ) ! V_current = det(F) * V_reference
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crystallite_postResults ( c + 1 ) = detF * mesh_ipVolume ( i , e ) / homogenization_Ngrains ( mesh_element ( 3 , e ) ) ! grain volume (not fraction but absolute)
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case ( 'orientation' )
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mySize = 4_pInt
crystallite_postResults ( c + 1 : c + mySize ) = crystallite_orientation ( 1 : 4 , g , i , e ) ! grain orientation as quaternion
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case ( 'eulerangles' )
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mySize = 3_pInt
crystallite_postResults ( c + 1 : c + mySize ) = inDeg * math_QuaternionToEuler ( crystallite_orientation ( 1 : 4 , g , i , e ) ) ! grain orientation as Euler angles in degree
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case ( 'grainrotation' )
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mySize = 4_pInt
crystallite_postResults ( c + 1 : c + mySize ) = math_QuaternionToAxisAngle ( crystallite_rotation ( 1 : 4 , g , i , e ) ) ! grain rotation away from initial orientation as axis-angle
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
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crystallite_postResults ( c + 4 ) = inDeg * crystallite_postResults ( c + 4 ) ! angle in degree
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! remark: tensor output is of the form 11,12,13, 21,22,23, 31,32,33
! thus row index i is slow, while column index j is fast. reminder: "row is slow"
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case ( 'defgrad' , 'f' )
mySize = 9_pInt
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crystallite_postResults ( c + 1 : c + mySize ) = reshape ( math_transpose33 ( crystallite_partionedF ( 1 : 3 , 1 : 3 , g , i , e ) ) , [ mySize ] )
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case ( 'e' )
mySize = 9_pInt
crystallite_postResults ( c + 1 : c + mySize ) = 0.5_pReal * reshape ( ( math_mul33x33 ( &
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math_transpose33 ( crystallite_partionedF ( 1 : 3 , 1 : 3 , g , i , e ) ) , &
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crystallite_partionedF ( 1 : 3 , 1 : 3 , g , i , e ) ) - math_I3 ) , [ mySize ] )
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case ( 'fe' )
mySize = 9_pInt
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crystallite_postResults ( c + 1 : c + mySize ) = reshape ( math_transpose33 ( crystallite_Fe ( 1 : 3 , 1 : 3 , g , i , e ) ) , [ mySize ] )
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case ( 'ee' )
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Ee = 0.5_pReal * ( math_mul33x33 ( math_transpose33 ( crystallite_Fe ( 1 : 3 , 1 : 3 , g , i , e ) ) , crystallite_Fe ( 1 : 3 , 1 : 3 , g , i , e ) ) - math_I3 )
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mySize = 9_pInt
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crystallite_postResults ( c + 1 : c + mySize ) = reshape ( Ee , [ mySize ] )
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case ( 'fp' )
mySize = 9_pInt
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crystallite_postResults ( c + 1 : c + mySize ) = reshape ( math_transpose33 ( crystallite_Fp ( 1 : 3 , 1 : 3 , g , i , e ) ) , [ mySize ] )
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case ( 'lp' )
mySize = 9_pInt
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crystallite_postResults ( c + 1 : c + mySize ) = reshape ( math_transpose33 ( crystallite_Lp ( 1 : 3 , 1 : 3 , g , i , e ) ) , [ mySize ] )
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case ( 'p' , 'firstpiola' , '1stpiola' )
mySize = 9_pInt
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crystallite_postResults ( c + 1 : c + mySize ) = reshape ( math_transpose33 ( crystallite_P ( 1 : 3 , 1 : 3 , g , i , e ) ) , [ mySize ] )
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case ( 's' , 'tstar' , 'secondpiola' , '2ndpiola' )
mySize = 9_pInt
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crystallite_postResults ( c + 1 : c + mySize ) = reshape ( math_Mandel6to33 ( crystallite_Tstar_v ( 1 : 6 , g , i , e ) ) , [ mySize ] )
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case ( 'elasmatrix' )
mySize = 36_pInt
crystallite_postResults ( c + 1 : c + mySize ) = reshape ( constitutive_homogenizedC ( g , i , e ) , ( / mySize / ) )
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end select
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c = c + mySize
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enddo
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crystallite_postResults ( c + 1 ) = real ( constitutive_sizePostResults ( g , i , e ) , pReal ) ! size of constitutive results
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
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c = c + 1_pInt
crystallite_postResults ( c + 1 : c + constitutive_sizePostResults ( g , i , e ) ) = constitutive_postResults ( crystallite_Tstar_v ( 1 : 6 , g , i , e ) , &
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crystallite_Fe , &
openmp parallelization working again (at least for j2 and nonlocal constitutive model).
In order to keep it like that, please follow these simple rules:
DON'T use implicit array subscripts:
example: real, dimension(3,3) :: A,B
A(:,2) = B(:,1) <--- DON'T USE
A(1:3,2) = B(1:3,1) <--- BETTER USE
In many cases the use of explicit array subscripts is inevitable for parallelization. Additionally, it is an easy means to prevent memory leaks.
Enclose all write statements with the following:
!$OMP CRITICAL (write2out)
<your write statement>
!$OMP END CRITICAL (write2out)
Whenever you change something in the code and are not sure if it affects parallelization and leads to nonconforming behavior, please ask me and/or Franz to check this.
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crystallite_Temperature ( g , i , e ) , &
dt , g , i , e )
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c = c + constitutive_sizePostResults ( g , i , e )
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end function crystallite_postResults
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END MODULE
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!##############################################################