2016-10-24 14:03:01 +05:30
!--------------------------------------------------------------------------------------------------
2012-07-30 19:36:22 +05:30
!> @author Martin Diehl, Max-Planck-Institut für Eisenforschung GmbH
!> @author Philip Eisenlohr, Max-Planck-Institut für Eisenforschung GmbH
!> @brief Utilities used by the different spectral solver variants
!--------------------------------------------------------------------------------------------------
2015-12-16 02:15:54 +05:30
module spectral_utilities
2019-03-25 23:47:10 +05:30
use , intrinsic :: iso_c_binding
2018-05-17 15:34:21 +05:30
#include <petsc/finclude/petscsys.h>
use PETScSys
2019-03-25 23:47:10 +05:30
use prec , only : &
pReal , &
pStringLen
use math , only : &
math_I3
2012-10-24 17:01:40 +05:30
2019-03-25 23:47:10 +05:30
implicit none
private
include 'fftw3-mpi.f03'
2015-10-15 00:06:19 +05:30
2019-03-25 23:47:10 +05:30
logical , public :: cutBack = . false . !< cut back of BVP solver in case convergence is not achieved or a material point is terminally ill
integer , public , parameter :: maxPhaseFields = 2
integer , public :: nActiveFields = 0
2015-10-15 00:06:19 +05:30
2015-06-03 23:00:31 +05:30
!--------------------------------------------------------------------------------------------------
! field labels information
2019-03-25 23:47:10 +05:30
enum , bind ( c )
enumerator :: &
FIELD_UNDEFINED_ID , &
FIELD_MECH_ID , &
FIELD_THERMAL_ID , &
FIELD_DAMAGE_ID
end enum
2015-10-15 00:06:19 +05:30
2013-05-08 21:22:29 +05:30
!--------------------------------------------------------------------------------------------------
! grid related information information
2019-03-25 23:47:10 +05:30
real ( pReal ) , public :: wgt !< weighting factor 1/Nelems
2015-10-15 00:06:19 +05:30
2012-07-23 15:42:31 +05:30
!--------------------------------------------------------------------------------------------------
! variables storing information for spectral method and FFTW
2019-03-25 23:47:10 +05:30
integer , public :: grid1Red !< grid(1)/2
real ( C_DOUBLE ) , public , dimension ( : , : , : , : , : ) , pointer :: tensorField_real !< real representation (some stress or deformation) of field_fourier
complex ( C_DOUBLE_COMPLEX ) , public , dimension ( : , : , : , : , : ) , pointer :: tensorField_fourier !< field on which the Fourier transform operates
real ( C_DOUBLE ) , public , dimension ( : , : , : , : ) , pointer :: vectorField_real !< vector field real representation for fftw
complex ( C_DOUBLE_COMPLEX ) , public , dimension ( : , : , : , : ) , pointer :: vectorField_fourier !< vector field fourier representation for fftw
real ( C_DOUBLE ) , public , dimension ( : , : , : ) , pointer :: scalarField_real !< scalar field real representation for fftw
complex ( C_DOUBLE_COMPLEX ) , public , dimension ( : , : , : ) , pointer :: scalarField_fourier !< scalar field fourier representation for fftw
complex ( pReal ) , private , dimension ( : , : , : , : , : , : , : ) , allocatable :: gamma_hat !< gamma operator (field) for spectral method
complex ( pReal ) , private , dimension ( : , : , : , : ) , allocatable :: xi1st !< wave vector field for first derivatives
complex ( pReal ) , private , dimension ( : , : , : , : ) , allocatable :: xi2nd !< wave vector field for second derivatives
real ( pReal ) , private , dimension ( 3 , 3 , 3 , 3 ) :: C_ref !< mechanic reference stiffness
real ( pReal ) , protected , public , dimension ( 3 ) :: scaledGeomSize !< scaled geometry size for calculation of divergence (Basic, Basic PETSc)
2015-10-15 00:06:19 +05:30
2012-11-12 19:44:39 +05:30
!--------------------------------------------------------------------------------------------------
! plans for FFTW
2019-03-25 23:47:10 +05:30
type ( C_PTR ) , private :: &
planTensorForth , & !< FFTW MPI plan P(x) to P(k)
planTensorBack , & !< FFTW MPI plan F(k) to F(x)
planVectorForth , & !< FFTW MPI plan v(x) to v(k)
planVectorBack , & !< FFTW MPI plan v(k) to v(x)
planScalarForth , & !< FFTW MPI plan s(x) to s(k)
planScalarBack !< FFTW MPI plan s(k) to s(x)
2012-11-12 19:44:39 +05:30
2012-07-23 15:42:31 +05:30
!--------------------------------------------------------------------------------------------------
2012-10-24 17:01:40 +05:30
! variables controlling debugging
2019-03-25 23:47:10 +05:30
logical , private :: &
debugGeneral , & !< general debugging of spectral solver
debugRotation , & !< also printing out results in lab frame
debugPETSc !< use some in debug defined options for more verbose PETSc solution
2012-07-23 15:42:31 +05:30
2012-07-25 19:31:39 +05:30
!--------------------------------------------------------------------------------------------------
2012-08-03 14:55:48 +05:30
! derived types
2019-03-25 23:47:10 +05:30
type , public :: tSolutionState !< return type of solution from spectral solver variants
integer :: &
iterationsNeeded = 0
logical :: &
converged = . true . , &
stagConverged = . true . , &
termIll = . false .
end type tSolutionState
type , public :: tBoundaryCondition !< set of parameters defining a boundary condition
real ( pReal ) , dimension ( 3 , 3 ) :: values = 0.0_pReal , &
maskFloat = 0.0_pReal
logical , dimension ( 3 , 3 ) :: maskLogical = . false .
character ( len = 64 ) :: myType = 'None'
end type tBoundaryCondition
type , public :: tLoadCase
real ( pReal ) , dimension ( 3 , 3 ) :: rotation = math_I3 !< rotation of BC
type ( tBoundaryCondition ) :: stress , & !< stress BC
deformation !< deformation BC (Fdot or L)
real ( pReal ) :: time = 0.0_pReal !< length of increment
integer :: incs = 0 , & !< number of increments
outputfrequency = 1 , & !< frequency of result writes
restartfrequency = 0 , & !< frequency of restart writes
logscale = 0 !< linear/logarithmic time inc flag
logical :: followFormerTrajectory = . true . !< follow trajectory of former loadcase
integer ( kind ( FIELD_UNDEFINED_ID ) ) , allocatable :: ID ( : )
end type tLoadCase
type , public :: tSolutionParams !< @todo use here the type definition for a full loadcase
real ( pReal ) , dimension ( 3 , 3 ) :: stress_mask , stress_BC , rotation_BC
real ( pReal ) :: timeinc
real ( pReal ) :: timeincOld
end type tSolutionParams
2019-03-26 12:06:55 +05:30
type , private :: tNumerics
2019-03-25 23:47:10 +05:30
real ( pReal ) :: &
FFTW_timelimit !< timelimit for FFTW plan creation, see www.fftw.org
integer :: &
2019-03-26 12:06:55 +05:30
divergence_correction !< scale divergence/curl calculation: [0: no correction, 1: size scaled to 1, 2: size scaled to Npoints]
2019-03-25 23:47:10 +05:30
logical :: &
2019-03-26 12:06:55 +05:30
memory_efficient !< calculate gamma operator on the fly
2019-03-25 23:47:10 +05:30
character ( len = pStringLen ) :: &
2019-03-26 12:06:55 +05:30
spectral_derivative , & !< approximation used for derivatives in Fourier space
FFTW_plan_mode , & !< FFTW plan mode, see www.fftw.org
2019-03-25 23:47:10 +05:30
PETSc_defaultOptions , &
PETSc_options
end type tNumerics
type ( tNumerics ) :: num ! numerics parameters. Better name?
enum , bind ( c )
enumerator :: &
DERIVATIVE_CONTINUOUS_ID , &
DERIVATIVE_CENTRAL_DIFF_ID , &
DERIVATIVE_FWBW_DIFF_ID
end enum
integer ( kind ( DERIVATIVE_CONTINUOUS_ID ) ) :: &
spectral_derivative_ID
public :: &
utilities_init , &
utilities_updateGamma , &
utilities_FFTtensorForward , &
utilities_FFTtensorBackward , &
utilities_FFTvectorForward , &
utilities_FFTvectorBackward , &
utilities_FFTscalarForward , &
utilities_FFTscalarBackward , &
utilities_fourierGammaConvolution , &
utilities_fourierGreenConvolution , &
utilities_divergenceRMS , &
utilities_curlRMS , &
utilities_fourierScalarGradient , &
utilities_fourierVectorDivergence , &
utilities_fourierVectorGradient , &
utilities_fourierTensorDivergence , &
utilities_maskedCompliance , &
utilities_constitutiveResponse , &
utilities_calculateRate , &
utilities_forwardField , &
utilities_updateIPcoords , &
FIELD_UNDEFINED_ID , &
FIELD_MECH_ID , &
FIELD_THERMAL_ID , &
FIELD_DAMAGE_ID
private :: &
utilities_getFreqDerivative
2012-08-03 14:55:48 +05:30
2015-10-15 00:06:19 +05:30
contains
2012-07-19 22:54:56 +05:30
2012-08-03 14:55:48 +05:30
!--------------------------------------------------------------------------------------------------
2012-11-12 19:44:39 +05:30
!> @brief allocates all neccessary fields, sets debug flags, create plans for FFTW
2018-02-17 03:11:07 +05:30
!> @details Sets the debug levels for general, divergence, restart, and FFTW from the bitwise coding
2012-08-09 18:34:56 +05:30
!> provided by the debug module to logicals.
2018-02-17 03:11:07 +05:30
!> Allocate all fields used by FFTW and create the corresponding plans depending on the debug
2012-08-09 18:34:56 +05:30
!> level chosen.
!> Initializes FFTW.
2012-08-03 14:55:48 +05:30
!--------------------------------------------------------------------------------------------------
2019-03-25 14:06:59 +05:30
subroutine utilities_init
2019-03-25 23:47:10 +05:30
use IO , only : &
IO_error , &
IO_warning , &
IO_lc
use numerics , only : &
petsc_defaultOptions , &
petsc_options
use debug , only : &
debug_level , &
debug_SPECTRAL , &
debug_LEVELBASIC , &
debug_SPECTRALDIVERGENCE , &
debug_SPECTRALFFTW , &
debug_SPECTRALPETSC , &
debug_SPECTRALROTATION
use config , only : &
config_numerics
use debug , only : &
PETSCDEBUG
use math
use mesh , only : &
grid , &
grid3 , &
grid3Offset , &
geomSize
implicit none
PetscErrorCode :: ierr
integer :: i , j , k , &
FFTW_planner_flag
integer , dimension ( 3 ) :: k_s
type ( C_PTR ) :: &
tensorField , & !< field containing data for FFTW in real and fourier space (in place)
vectorField , & !< field containing data for FFTW in real space when debugging FFTW (no in place)
scalarField !< field containing data for FFTW in real space when debugging FFTW (no in place)
integer ( C_INTPTR_T ) , dimension ( 3 ) :: gridFFTW
integer ( C_INTPTR_T ) :: alloc_local , local_K , local_K_offset
integer ( C_INTPTR_T ) , parameter :: &
scalarSize = 1_C_INTPTR_T , &
vecSize = 3_C_INTPTR_T , &
tensorSize = 9_C_INTPTR_T
write ( 6 , '(/,a)' ) ' <<<+- spectral_utilities init -+>>>'
write ( 6 , '(/,a)' ) ' Diehl, Diploma Thesis TU München, 2010'
write ( 6 , '(a)' ) ' https://doi.org/10.13140/2.1.3234.3840'
write ( 6 , '(/,a)' ) ' Eisenlohr et al., International Journal of Plasticity 46:37– 53, 2013'
write ( 6 , '(a)' ) ' https://doi.org/10.1016/j.ijplas.2012.09.012'
write ( 6 , '(/,a)' ) ' Shanthraj et al., International Journal of Plasticity 66:31– 45, 2015'
write ( 6 , '(a)' ) ' https://doi.org/10.1016/j.ijplas.2014.02.006'
write ( 6 , '(/,a)' ) ' Shanthraj et al., Handbook of Mechanics of Materials, 2019'
write ( 6 , '(a)' ) ' https://doi.org/10.1007/978-981-10-6855-3_80'
2012-07-19 22:54:56 +05:30
!--------------------------------------------------------------------------------------------------
2012-07-23 15:42:31 +05:30
! set debugging parameters
2019-03-25 23:47:10 +05:30
debugGeneral = iand ( debug_level ( debug_SPECTRAL ) , debug_LEVELBASIC ) / = 0
debugRotation = iand ( debug_level ( debug_SPECTRAL ) , debug_SPECTRALROTATION ) / = 0
debugPETSc = iand ( debug_level ( debug_SPECTRAL ) , debug_SPECTRALPETSC ) / = 0
if ( debugPETSc ) write ( 6 , '(3(/,a),/)' ) &
' Initializing PETSc with debug options: ' , &
trim ( PETScDebug ) , &
' add more using the PETSc_Options keyword in numerics.config ' ; flush ( 6 )
call PETScOptionsClear ( PETSC_NULL_OPTIONS , ierr )
CHKERRQ ( ierr )
if ( debugPETSc ) call PETScOptionsInsertString ( PETSC_NULL_OPTIONS , trim ( PETSCDEBUG ) , ierr )
CHKERRQ ( ierr )
call PETScOptionsInsertString ( PETSC_NULL_OPTIONS , trim ( petsc_defaultOptions ) , ierr )
CHKERRQ ( ierr )
call PETScOptionsInsertString ( PETSC_NULL_OPTIONS , trim ( petsc_options ) , ierr )
CHKERRQ ( ierr )
grid1Red = grid ( 1 ) / 2 + 1
wgt = 1.0 / real ( product ( grid ) , pReal )
write ( 6 , '(/,a,3(i12 ))' ) ' grid a b c: ' , grid
write ( 6 , '(a,3(es12.5))' ) ' size x y z: ' , geomSize
num % memory_efficient = config_numerics % getInt ( 'memory_efficient' , defaultVal = 1 ) > 0
num % FFTW_timelimit = config_numerics % getFloat ( 'fftw_timelimit' , defaultVal = - 1.0 )
num % divergence_correction = config_numerics % getInt ( 'divergence_correction' , defaultVal = 2 )
num % spectral_derivative = config_numerics % getString ( 'spectral_derivative' , defaultVal = 'continuous' )
2019-03-29 13:18:32 +05:30
num % FFTW_plan_mode = config_numerics % getString ( 'fftw_plan_mode' , defaultVal = 'FFTW_MEASURE' )
2019-03-25 23:47:10 +05:30
if ( num % divergence_correction < 0 . or . num % divergence_correction > 2 ) &
call IO_error ( 301 , ext_msg = 'divergence_correction' )
select case ( num % spectral_derivative )
case ( 'continuous' )
spectral_derivative_ID = DERIVATIVE_CONTINUOUS_ID
case ( 'central_difference' )
spectral_derivative_ID = DERIVATIVE_CENTRAL_DIFF_ID
case ( 'fwbw_difference' )
spectral_derivative_ID = DERIVATIVE_FWBW_DIFF_ID
case default
call IO_error ( 892 , ext_msg = trim ( num % spectral_derivative ) )
end select
2015-12-14 23:42:09 +05:30
2013-05-08 21:22:29 +05:30
!--------------------------------------------------------------------------------------------------
2015-09-11 14:22:03 +05:30
! scale dimension to calculate either uncorrected, dimension-independent, or dimension- and
! resolution-independent divergence
2019-03-25 23:47:10 +05:30
if ( num % divergence_correction == 1 ) then
do j = 1 , 3
if ( j / = minloc ( geomSize , 1 ) . and . j / = maxloc ( geomSize , 1 ) ) &
scaledGeomSize = geomSize / geomSize ( j )
enddo
elseif ( num % divergence_correction == 2 ) then
do j = 1 , 3
if ( j / = int ( minloc ( geomSize / real ( grid , pReal ) , 1 ) ) &
. and . j / = int ( maxloc ( geomSize / real ( grid , pReal ) , 1 ) ) ) &
scaledGeomSize = geomSize / geomSize ( j ) * real ( grid ( j ) , pReal )
enddo
else
scaledGeomSize = geomSize
endif
select case ( IO_lc ( num % FFTW_plan_mode ) ) ! setting parameters for the plan creation of FFTW. Basically a translation from fftw3.f
2019-03-29 13:18:32 +05:30
case ( 'fftw_estimate' ) ! ordered from slow execution (but fast plan creation) to fast execution
FFTW_planner_flag = FFTW_ESTIMATE
case ( 'fftw_measure' )
FFTW_planner_flag = FFTW_MEASURE
case ( 'fftw_patient' )
FFTW_planner_flag = FFTW_PATIENT
case ( 'fftw_exhaustive' )
FFTW_planner_flag = FFTW_EXHAUSTIVE
2019-03-25 23:47:10 +05:30
case default
call IO_warning ( warning_ID = 47 , ext_msg = trim ( IO_lc ( num % FFTW_plan_mode ) ) )
2019-03-29 13:18:32 +05:30
FFTW_planner_flag = FFTW_MEASURE
2019-03-25 23:47:10 +05:30
end select
2019-03-25 20:24:51 +05:30
2019-03-25 22:58:07 +05:30
!--------------------------------------------------------------------------------------------------
! general initialization of FFTW (see manual on fftw.org for more details)
2019-03-25 23:47:10 +05:30
if ( pReal / = C_DOUBLE . or . kind ( 1 ) / = C_INT ) call IO_error ( 0 , ext_msg = 'Fortran to C' ) ! check for correct precision in C
call fftw_set_timelimit ( num % FFTW_timelimit ) ! set timelimit for plan creation
if ( debugGeneral ) write ( 6 , '(/,a)' ) ' FFTW initialized' ; flush ( 6 )
2019-03-25 22:58:07 +05:30
2012-07-19 22:54:56 +05:30
!--------------------------------------------------------------------------------------------------
2015-03-25 21:36:19 +05:30
! MPI allocation
2019-03-25 23:47:10 +05:30
gridFFTW = int ( grid , C_INTPTR_T )
alloc_local = fftw_mpi_local_size_3d ( gridFFTW ( 3 ) , gridFFTW ( 2 ) , gridFFTW ( 1 ) / 2 + 1 , &
PETSC_COMM_WORLD , local_K , local_K_offset )
allocate ( xi1st ( 3 , grid1Red , grid ( 2 ) , grid3 ) , source = cmplx ( 0.0_pReal , 0.0_pReal , pReal ) ) ! frequencies for first derivatives, only half the size for first dimension
allocate ( xi2nd ( 3 , grid1Red , grid ( 2 ) , grid3 ) , source = cmplx ( 0.0_pReal , 0.0_pReal , pReal ) ) ! frequencies for second derivatives, only half the size for first dimension
tensorField = fftw_alloc_complex ( tensorSize * alloc_local )
call c_f_pointer ( tensorField , tensorField_real , [ 3_C_INTPTR_T , 3_C_INTPTR_T , &
2_C_INTPTR_T * ( gridFFTW ( 1 ) / 2_C_INTPTR_T + 1_C_INTPTR_T ) , gridFFTW ( 2 ) , local_K ] ) ! place a pointer for a real tensor representation
call c_f_pointer ( tensorField , tensorField_fourier , [ 3_C_INTPTR_T , 3_C_INTPTR_T , &
gridFFTW ( 1 ) / 2_C_INTPTR_T + 1_C_INTPTR_T , gridFFTW ( 2 ) , local_K ] ) ! place a pointer for a fourier tensor representation
vectorField = fftw_alloc_complex ( vecSize * alloc_local )
call c_f_pointer ( vectorField , vectorField_real , [ 3_C_INTPTR_T , &
2_C_INTPTR_T * ( gridFFTW ( 1 ) / 2_C_INTPTR_T + 1_C_INTPTR_T ) , gridFFTW ( 2 ) , local_K ] ) ! place a pointer for a real vector representation
call c_f_pointer ( vectorField , vectorField_fourier , [ 3_C_INTPTR_T , &
gridFFTW ( 1 ) / 2_C_INTPTR_T + 1_C_INTPTR_T , gridFFTW ( 2 ) , local_K ] ) ! place a pointer for a fourier vector representation
scalarField = fftw_alloc_complex ( scalarSize * alloc_local ) ! allocate data for real representation (no in place transform)
call c_f_pointer ( scalarField , scalarField_real , &
[ 2_C_INTPTR_T * ( gridFFTW ( 1 ) / 2_C_INTPTR_T + 1 ) , gridFFTW ( 2 ) , local_K ] ) ! place a pointer for a real scalar representation
call c_f_pointer ( scalarField , scalarField_fourier , &
[ gridFFTW ( 1 ) / 2_C_INTPTR_T + 1 , gridFFTW ( 2 ) , local_K ] ) ! place a pointer for a fourier scarlar representation
2015-10-15 00:06:19 +05:30
2015-06-03 23:00:31 +05:30
!--------------------------------------------------------------------------------------------------
! tensor MPI fftw plans
2019-03-25 23:47:10 +05:30
planTensorForth = fftw_mpi_plan_many_dft_r2c ( 3 , [ gridFFTW ( 3 ) , gridFFTW ( 2 ) , gridFFTW ( 1 ) ] , & ! dimension, logical length in each dimension in reversed order
tensorSize , FFTW_MPI_DEFAULT_BLOCK , FFTW_MPI_DEFAULT_BLOCK , & ! no. of transforms, default iblock and oblock
tensorField_real , tensorField_fourier , & ! input data, output data
PETSC_COMM_WORLD , FFTW_planner_flag ) ! use all processors, planer precision
if ( . not . C_ASSOCIATED ( planTensorForth ) ) call IO_error ( 810 , ext_msg = 'planTensorForth' )
planTensorBack = fftw_mpi_plan_many_dft_c2r ( 3 , [ gridFFTW ( 3 ) , gridFFTW ( 2 ) , gridFFTW ( 1 ) ] , & ! dimension, logical length in each dimension in reversed order
tensorSize , FFTW_MPI_DEFAULT_BLOCK , FFTW_MPI_DEFAULT_BLOCK , & ! no. of transforms, default iblock and oblock
tensorField_fourier , tensorField_real , & ! input data, output data
PETSC_COMM_WORLD , FFTW_planner_flag ) ! all processors, planer precision
if ( . not . C_ASSOCIATED ( planTensorBack ) ) call IO_error ( 810 , ext_msg = 'planTensorBack' )
2015-10-15 00:06:19 +05:30
2015-03-13 03:58:33 +05:30
!--------------------------------------------------------------------------------------------------
2015-06-03 23:00:31 +05:30
! vector MPI fftw plans
2019-03-25 23:47:10 +05:30
planVectorForth = fftw_mpi_plan_many_dft_r2c ( 3 , [ gridFFTW ( 3 ) , gridFFTW ( 2 ) , gridFFTW ( 1 ) ] , & ! dimension, logical length in each dimension in reversed order
vecSize , FFTW_MPI_DEFAULT_BLOCK , FFTW_MPI_DEFAULT_BLOCK , & ! no. of transforms, default iblock and oblock
vectorField_real , vectorField_fourier , & ! input data, output data
PETSC_COMM_WORLD , FFTW_planner_flag ) ! use all processors, planer precision
if ( . not . C_ASSOCIATED ( planVectorForth ) ) call IO_error ( 810 , ext_msg = 'planVectorForth' )
planVectorBack = fftw_mpi_plan_many_dft_c2r ( 3 , [ gridFFTW ( 3 ) , gridFFTW ( 2 ) , gridFFTW ( 1 ) ] , & ! dimension, logical length in each dimension in reversed order
vecSize , FFTW_MPI_DEFAULT_BLOCK , FFTW_MPI_DEFAULT_BLOCK , & ! no. of transforms, default iblock and oblock
vectorField_fourier , vectorField_real , & ! input data, output data
PETSC_COMM_WORLD , FFTW_planner_flag ) ! all processors, planer precision
if ( . not . C_ASSOCIATED ( planVectorBack ) ) call IO_error ( 810 , ext_msg = 'planVectorBack' )
2015-10-15 00:06:19 +05:30
2015-06-03 23:00:31 +05:30
!--------------------------------------------------------------------------------------------------
2015-10-15 00:06:19 +05:30
! scalar MPI fftw plans
2019-03-25 23:47:10 +05:30
planScalarForth = fftw_mpi_plan_many_dft_r2c ( 3 , [ gridFFTW ( 3 ) , gridFFTW ( 2 ) , gridFFTW ( 1 ) ] , & ! dimension, logical length in each dimension in reversed order
scalarSize , FFTW_MPI_DEFAULT_BLOCK , FFTW_MPI_DEFAULT_BLOCK , & ! no. of transforms, default iblock and oblock
scalarField_real , scalarField_fourier , & ! input data, output data
PETSC_COMM_WORLD , FFTW_planner_flag ) ! use all processors, planer precision
if ( . not . C_ASSOCIATED ( planScalarForth ) ) call IO_error ( 810 , ext_msg = 'planScalarForth' )
planScalarBack = fftw_mpi_plan_many_dft_c2r ( 3 , [ gridFFTW ( 3 ) , gridFFTW ( 2 ) , gridFFTW ( 1 ) ] , & ! dimension, logical length in each dimension in reversed order, no. of transforms
scalarSize , FFTW_MPI_DEFAULT_BLOCK , FFTW_MPI_DEFAULT_BLOCK , & ! no. of transforms, default iblock and oblock
scalarField_fourier , scalarField_real , & ! input data, output data
PETSC_COMM_WORLD , FFTW_planner_flag ) ! use all processors, planer precision
if ( . not . C_ASSOCIATED ( planScalarBack ) ) call IO_error ( 810 , ext_msg = 'planScalarBack' )
2012-07-19 22:54:56 +05:30
!--------------------------------------------------------------------------------------------------
2012-07-23 15:42:31 +05:30
! calculation of discrete angular frequencies, ordered as in FFTW (wrap around)
2019-03-25 23:47:10 +05:30
do k = grid3Offset + 1 , grid3Offset + grid3
k_s ( 3 ) = k - 1
if ( k > grid ( 3 ) / 2 + 1 ) k_s ( 3 ) = k_s ( 3 ) - grid ( 3 ) ! running from 0,1,...,N/2,N/2+1,-N/2,-N/2+1,...,-1
do j = 1 , grid ( 2 )
k_s ( 2 ) = j - 1
if ( j > grid ( 2 ) / 2 + 1 ) k_s ( 2 ) = k_s ( 2 ) - grid ( 2 ) ! running from 0,1,...,N/2,N/2+1,-N/2,-N/2+1,...,-1
do i = 1 , grid1Red
k_s ( 1 ) = i - 1 ! symmetry, junst running from 0,1,...,N/2,N/2+1
xi2nd ( 1 : 3 , i , j , k - grid3Offset ) = utilities_getFreqDerivative ( k_s )
where ( mod ( grid , 2 ) == 0 . and . [ i , j , k ] == grid / 2 + 1 . and . &
spectral_derivative_ID == DERIVATIVE_CONTINUOUS_ID ) ! for even grids, set the Nyquist Freq component to 0.0
xi1st ( 1 : 3 , i , j , k - grid3Offset ) = cmplx ( 0.0_pReal , 0.0_pReal , pReal )
elsewhere
xi1st ( 1 : 3 , i , j , k - grid3Offset ) = xi2nd ( 1 : 3 , i , j , k - grid3Offset )
endwhere
enddo ; enddo ; enddo
if ( num % memory_efficient ) then ! allocate just single fourth order tensor
allocate ( gamma_hat ( 3 , 3 , 3 , 3 , 1 , 1 , 1 ) , source = cmplx ( 0.0_pReal , 0.0_pReal , pReal ) )
else ! precalculation of gamma_hat field
allocate ( gamma_hat ( 3 , 3 , 3 , 3 , grid1Red , grid ( 2 ) , grid3 ) , source = cmplx ( 0.0_pReal , 0.0_pReal , pReal ) )
endif
2012-08-03 14:55:48 +05:30
2012-10-24 17:01:40 +05:30
end subroutine utilities_init
2012-07-26 19:28:47 +05:30
2019-03-26 12:06:55 +05:30
!---------------------------------------------------------------------------------------------------
2018-02-17 03:11:07 +05:30
!> @brief updates reference stiffness and potentially precalculated gamma operator
2012-08-09 18:34:56 +05:30
!> @details Sets the current reference stiffness to the stiffness given as an argument.
!> If the gamma operator is precalculated, it is calculated with this stiffness.
2018-02-17 03:11:07 +05:30
!> In case of an on-the-fly calculation, only the reference stiffness is updated.
2012-10-24 17:01:40 +05:30
!> Also writes out the current reference stiffness for restart.
2019-03-26 12:06:55 +05:30
!---------------------------------------------------------------------------------------------------
2012-10-24 17:01:40 +05:30
subroutine utilities_updateGamma ( C , saveReference )
2019-03-09 03:46:56 +05:30
use IO , only : &
IO_open_jobFile_binary
use numerics , only : &
worldrank
use mesh , only : &
grid3Offset , &
grid3 , &
grid
use math , only : &
math_det33 , &
math_invert2
implicit none
real ( pReal ) , intent ( in ) , dimension ( 3 , 3 , 3 , 3 ) :: C !< input stiffness to store as reference stiffness
logical , intent ( in ) :: saveReference !< save reference stiffness to file for restart
complex ( pReal ) , dimension ( 3 , 3 ) :: temp33_complex , xiDyad_cmplx
real ( pReal ) , dimension ( 6 , 6 ) :: A , A_inv
integer :: &
i , j , k , &
l , m , n , o , &
fileUnit
logical :: err
C_ref = C
2019-03-26 16:43:47 +05:30
if ( saveReference . and . worldrank == 0 ) then
write ( 6 , '(/,a)' ) ' writing reference stiffness to file'
flush ( 6 )
fileUnit = IO_open_jobFile_binary ( 'C_ref' , 'w' )
write ( fileUnit ) C_ref ; close ( fileUnit )
2019-03-09 03:46:56 +05:30
endif
2019-03-25 14:06:59 +05:30
if ( . not . num % memory_efficient ) then
2019-03-25 20:24:51 +05:30
gamma_hat = cmplx ( 0.0_pReal , 0.0_pReal , pReal ) ! for the singular point and any non invertible A
2019-03-09 03:46:56 +05:30
do k = grid3Offset + 1 , grid3Offset + grid3 ; do j = 1 , grid ( 2 ) ; do i = 1 , grid1Red
2019-03-25 20:24:51 +05:30
if ( any ( [ i , j , k ] / = 1 ) ) then ! singular point at xi=(0.0,0.0,0.0) i.e. i=j=k=1
2019-03-09 03:46:56 +05:30
forall ( l = 1 : 3 , m = 1 : 3 ) &
xiDyad_cmplx ( l , m ) = conjg ( - xi1st ( l , i , j , k - grid3Offset ) ) * xi1st ( m , i , j , k - grid3Offset )
forall ( l = 1 : 3 , m = 1 : 3 ) &
temp33_complex ( l , m ) = sum ( cmplx ( C_ref ( l , 1 : 3 , m , 1 : 3 ) , 0.0_pReal ) * xiDyad_cmplx )
A ( 1 : 3 , 1 : 3 ) = real ( temp33_complex ) ; A ( 4 : 6 , 4 : 6 ) = real ( temp33_complex )
A ( 1 : 3 , 4 : 6 ) = aimag ( temp33_complex ) ; A ( 4 : 6 , 1 : 3 ) = - aimag ( temp33_complex )
if ( abs ( math_det33 ( A ( 1 : 3 , 1 : 3 ) ) ) > 1e-16 ) then
call math_invert2 ( A_inv , err , A )
temp33_complex = cmplx ( A_inv ( 1 : 3 , 1 : 3 ) , A_inv ( 1 : 3 , 4 : 6 ) , pReal )
forall ( l = 1 : 3 , m = 1 : 3 , n = 1 : 3 , o = 1 : 3 ) &
gamma_hat ( l , m , n , o , i , j , k - grid3Offset ) = temp33_complex ( l , n ) * &
2015-12-14 23:42:09 +05:30
conjg ( - xi1st ( o , i , j , k - grid3Offset ) ) * xi1st ( m , i , j , k - grid3Offset )
2019-03-09 03:46:56 +05:30
endif
endif
enddo ; enddo ; enddo
endif
2012-10-24 17:01:40 +05:30
end subroutine utilities_updateGamma
2019-03-09 03:46:56 +05:30
2012-08-03 14:55:48 +05:30
!--------------------------------------------------------------------------------------------------
2015-09-11 18:35:46 +05:30
!> @brief forward FFT of data in field_real to field_fourier
!> @details Does an unweighted filtered FFT transform from real to complex
2012-08-03 14:55:48 +05:30
!--------------------------------------------------------------------------------------------------
2019-03-25 14:06:59 +05:30
subroutine utilities_FFTtensorForward
2019-03-25 23:47:10 +05:30
implicit none
2013-03-07 01:04:30 +05:30
2019-03-25 23:47:10 +05:30
call fftw_mpi_execute_dft_r2c ( planTensorForth , tensorField_real , tensorField_fourier )
2015-10-15 00:06:19 +05:30
2015-06-03 23:00:31 +05:30
end subroutine utilities_FFTtensorForward
2012-07-26 19:28:47 +05:30
2012-08-09 18:34:56 +05:30
!--------------------------------------------------------------------------------------------------
!> @brief backward FFT of data in field_fourier to field_real
2015-09-11 14:22:03 +05:30
!> @details Does an weighted inverse FFT transform from complex to real
2012-08-09 18:34:56 +05:30
!--------------------------------------------------------------------------------------------------
2019-03-25 14:06:59 +05:30
subroutine utilities_FFTtensorBackward
2019-03-25 23:47:10 +05:30
implicit none
2013-04-10 15:49:16 +05:30
2019-03-25 23:47:10 +05:30
call fftw_mpi_execute_dft_c2r ( planTensorBack , tensorField_fourier , tensorField_real )
tensorField_real = tensorField_real * wgt ! normalize the result by number of elements
2012-08-03 14:55:48 +05:30
2015-06-03 23:00:31 +05:30
end subroutine utilities_FFTtensorBackward
2012-07-26 19:28:47 +05:30
2015-06-03 23:00:31 +05:30
!--------------------------------------------------------------------------------------------------
2015-09-11 14:22:03 +05:30
!> @brief forward FFT of data in scalarField_real to scalarField_fourier
2015-09-11 18:35:46 +05:30
!> @details Does an unweighted filtered FFT transform from real to complex
2015-06-03 23:00:31 +05:30
!--------------------------------------------------------------------------------------------------
2019-03-25 14:06:59 +05:30
subroutine utilities_FFTscalarForward
2019-03-25 23:47:10 +05:30
implicit none
2015-10-15 00:06:19 +05:30
2019-03-25 23:47:10 +05:30
call fftw_mpi_execute_dft_r2c ( planScalarForth , scalarField_real , scalarField_fourier )
2015-06-03 23:00:31 +05:30
end subroutine utilities_FFTscalarForward
2015-09-24 23:08:49 +05:30
2015-06-03 23:00:31 +05:30
!--------------------------------------------------------------------------------------------------
2015-09-11 14:22:03 +05:30
!> @brief backward FFT of data in scalarField_fourier to scalarField_real
!> @details Does an weighted inverse FFT transform from complex to real
2015-06-03 23:00:31 +05:30
!--------------------------------------------------------------------------------------------------
2019-03-25 14:06:59 +05:30
subroutine utilities_FFTscalarBackward
2019-03-25 23:47:10 +05:30
implicit none
2015-09-11 14:22:03 +05:30
2019-03-25 23:47:10 +05:30
call fftw_mpi_execute_dft_c2r ( planScalarBack , scalarField_fourier , scalarField_real )
scalarField_real = scalarField_real * wgt ! normalize the result by number of elements
2015-06-03 23:00:31 +05:30
end subroutine utilities_FFTscalarBackward
2015-09-24 23:08:49 +05:30
2015-06-03 23:00:31 +05:30
!--------------------------------------------------------------------------------------------------
!> @brief forward FFT of data in field_real to field_fourier with highest freqs. removed
2015-09-11 14:22:03 +05:30
!> @details Does an unweighted filtered FFT transform from real to complex.
2015-06-03 23:00:31 +05:30
!--------------------------------------------------------------------------------------------------
2019-03-25 14:06:59 +05:30
subroutine utilities_FFTvectorForward
2019-03-25 23:47:10 +05:30
implicit none
2015-09-11 18:35:46 +05:30
2019-03-25 23:47:10 +05:30
call fftw_mpi_execute_dft_r2c ( planVectorForth , vectorField_real , vectorField_fourier )
2015-06-03 23:00:31 +05:30
end subroutine utilities_FFTvectorForward
2015-09-24 23:08:49 +05:30
2015-06-03 23:00:31 +05:30
!--------------------------------------------------------------------------------------------------
!> @brief backward FFT of data in field_fourier to field_real
2015-09-11 14:22:03 +05:30
!> @details Does an weighted inverse FFT transform from complex to real
2015-06-03 23:00:31 +05:30
!--------------------------------------------------------------------------------------------------
2019-03-25 14:06:59 +05:30
subroutine utilities_FFTvectorBackward
2019-03-25 23:47:10 +05:30
implicit none
2015-09-11 14:22:03 +05:30
2019-03-25 23:47:10 +05:30
call fftw_mpi_execute_dft_c2r ( planVectorBack , vectorField_fourier , vectorField_real )
vectorField_real = vectorField_real * wgt ! normalize the result by number of elements
2015-06-03 23:00:31 +05:30
end subroutine utilities_FFTvectorBackward
2012-07-26 19:28:47 +05:30
2013-07-26 21:55:37 +05:30
2012-07-30 19:36:22 +05:30
!--------------------------------------------------------------------------------------------------
2012-10-24 17:01:40 +05:30
!> @brief doing convolution gamma_hat * field_real, ensuring that average value = fieldAim
2012-07-30 19:36:22 +05:30
!--------------------------------------------------------------------------------------------------
2015-06-03 23:00:31 +05:30
subroutine utilities_fourierGammaConvolution ( fieldAim )
2019-03-09 12:17:01 +05:30
use math , only : &
math_det33 , &
math_invert2
use mesh , only : &
grid3 , &
grid , &
grid3Offset
implicit none
real ( pReal ) , intent ( in ) , dimension ( 3 , 3 ) :: fieldAim !< desired average value of the field after convolution
complex ( pReal ) , dimension ( 3 , 3 ) :: temp33_complex , xiDyad_cmplx
real ( pReal ) , dimension ( 6 , 6 ) :: A , A_inv
integer :: &
i , j , k , &
l , m , n , o
logical :: err
write ( 6 , '(/,a)' ) ' ... doing gamma convolution ...............................................'
flush ( 6 )
2015-10-15 00:06:19 +05:30
2012-07-19 22:54:56 +05:30
!--------------------------------------------------------------------------------------------------
2013-04-18 22:10:49 +05:30
! do the actual spectral method calculation (mechanical equilibrium)
2019-03-25 14:06:59 +05:30
memoryEfficient : if ( num % memory_efficient ) then
2019-03-09 12:17:01 +05:30
do k = 1 , grid3 ; do j = 1 , grid ( 2 ) ; do i = 1 , grid1Red
2019-03-25 23:47:10 +05:30
if ( any ( [ i , j , k + grid3Offset ] / = 1 ) ) then ! singular point at xi=(0.0,0.0,0.0) i.e. i=j=k=1
2019-03-09 12:17:01 +05:30
forall ( l = 1 : 3 , m = 1 : 3 ) &
xiDyad_cmplx ( l , m ) = conjg ( - xi1st ( l , i , j , k ) ) * xi1st ( m , i , j , k )
forall ( l = 1 : 3 , m = 1 : 3 ) &
temp33_complex ( l , m ) = sum ( cmplx ( C_ref ( l , 1 : 3 , m , 1 : 3 ) , 0.0_pReal ) * xiDyad_cmplx )
A ( 1 : 3 , 1 : 3 ) = real ( temp33_complex ) ; A ( 4 : 6 , 4 : 6 ) = real ( temp33_complex )
A ( 1 : 3 , 4 : 6 ) = aimag ( temp33_complex ) ; A ( 4 : 6 , 1 : 3 ) = - aimag ( temp33_complex )
if ( abs ( math_det33 ( A ( 1 : 3 , 1 : 3 ) ) ) > 1e-16 ) then
call math_invert2 ( A_inv , err , A )
temp33_complex = cmplx ( A_inv ( 1 : 3 , 1 : 3 ) , A_inv ( 1 : 3 , 4 : 6 ) , pReal )
forall ( l = 1 : 3 , m = 1 : 3 , n = 1 : 3 , o = 1 : 3 ) &
gamma_hat ( l , m , n , o , 1 , 1 , 1 ) = temp33_complex ( l , n ) * conjg ( - xi1st ( o , i , j , k ) ) * xi1st ( m , i , j , k )
else
gamma_hat ( 1 : 3 , 1 : 3 , 1 : 3 , 1 : 3 , 1 , 1 , 1 ) = cmplx ( 0.0_pReal , 0.0_pReal , pReal )
endif
forall ( l = 1 : 3 , m = 1 : 3 ) &
temp33_Complex ( l , m ) = sum ( gamma_hat ( l , m , 1 : 3 , 1 : 3 , 1 , 1 , 1 ) * tensorField_fourier ( 1 : 3 , 1 : 3 , i , j , k ) )
tensorField_fourier ( 1 : 3 , 1 : 3 , i , j , k ) = temp33_Complex
endif
enddo ; enddo ; enddo
else memoryEfficient
do k = 1 , grid3 ; do j = 1 , grid ( 2 ) ; do i = 1 , grid1Red
forall ( l = 1 : 3 , m = 1 : 3 ) &
temp33_Complex ( l , m ) = sum ( gamma_hat ( l , m , 1 : 3 , 1 : 3 , i , j , k ) * tensorField_fourier ( 1 : 3 , 1 : 3 , i , j , k ) )
tensorField_fourier ( 1 : 3 , 1 : 3 , i , j , k ) = temp33_Complex
enddo ; enddo ; enddo
endif memoryEfficient
if ( grid3Offset == 0 ) tensorField_fourier ( 1 : 3 , 1 : 3 , 1 , 1 , 1 ) = cmplx ( fieldAim / wgt , 0.0_pReal , pReal )
2012-07-30 19:36:22 +05:30
2015-06-03 23:00:31 +05:30
end subroutine utilities_fourierGammaConvolution
2015-10-15 00:06:19 +05:30
2015-09-24 23:08:49 +05:30
2015-06-03 23:00:31 +05:30
!--------------------------------------------------------------------------------------------------
!> @brief doing convolution DamageGreenOp_hat * field_real
!--------------------------------------------------------------------------------------------------
subroutine utilities_fourierGreenConvolution ( D_ref , mobility_ref , deltaT )
2019-03-07 11:31:09 +05:30
use math , only : &
math_mul33x3 , &
PI
use mesh , only : &
grid , &
grid3
implicit none
real ( pReal ) , dimension ( 3 , 3 ) , intent ( in ) :: D_ref
real ( pReal ) , intent ( in ) :: mobility_ref , deltaT
complex ( pReal ) :: GreenOp_hat
2019-03-25 22:58:07 +05:30
integer :: i , j , k
2019-03-07 11:31:09 +05:30
2015-06-03 23:00:31 +05:30
!--------------------------------------------------------------------------------------------------
! do the actual spectral method calculation
2019-03-25 22:58:07 +05:30
do k = 1 , grid3 ; do j = 1 , grid ( 2 ) ; do i = 1 , grid1Red
2019-03-07 11:31:09 +05:30
GreenOp_hat = cmplx ( 1.0_pReal , 0.0_pReal , pReal ) / &
( cmplx ( mobility_ref , 0.0_pReal , pReal ) + cmplx ( deltaT , 0.0_pReal ) * &
2019-03-25 23:47:10 +05:30
sum ( conjg ( xi1st ( 1 : 3 , i , j , k ) ) * matmul ( cmplx ( D_ref , 0.0_pReal ) , xi1st ( 1 : 3 , i , j , k ) ) ) )
2019-03-07 11:31:09 +05:30
scalarField_fourier ( i , j , k ) = scalarField_fourier ( i , j , k ) * GreenOp_hat
enddo ; enddo ; enddo
2015-06-03 23:00:31 +05:30
end subroutine utilities_fourierGreenConvolution
2012-07-30 19:36:22 +05:30
2015-09-24 23:08:49 +05:30
2012-07-30 19:36:22 +05:30
!--------------------------------------------------------------------------------------------------
!> @brief calculate root mean square of divergence of field_fourier
!--------------------------------------------------------------------------------------------------
2015-10-15 00:06:19 +05:30
real ( pReal ) function utilities_divergenceRMS ( )
2019-03-07 11:31:09 +05:30
use IO , only : &
IO_error
use mesh , only : &
geomSize , &
grid , &
grid3
2012-10-24 17:01:40 +05:30
2019-03-07 11:31:09 +05:30
implicit none
2019-03-25 22:58:07 +05:30
integer :: i , j , k , ierr
2019-03-07 11:31:09 +05:30
complex ( pReal ) , dimension ( 3 ) :: rescaledGeom
2012-07-30 19:36:22 +05:30
2019-03-07 11:31:09 +05:30
write ( 6 , '(/,a)' ) ' ... calculating divergence ................................................'
flush ( 6 )
2016-09-03 17:57:56 +05:30
2019-03-07 11:31:09 +05:30
rescaledGeom = cmplx ( geomSize / scaledGeomSize , 0.0_pReal )
2013-04-10 15:49:16 +05:30
2012-07-19 22:54:56 +05:30
!--------------------------------------------------------------------------------------------------
2012-07-26 19:28:47 +05:30
! calculating RMS divergence criterion in Fourier space
2019-03-07 11:31:09 +05:30
utilities_divergenceRMS = 0.0_pReal
2019-03-25 22:58:07 +05:30
do k = 1 , grid3 ; do j = 1 , grid ( 2 )
do i = 2 , grid1Red - 1 ! Has somewhere a conj. complex counterpart. Therefore count it twice.
2019-03-07 11:31:09 +05:30
utilities_divergenceRMS = utilities_divergenceRMS &
+ 2.0_pReal * ( sum ( real ( matmul ( tensorField_fourier ( 1 : 3 , 1 : 3 , i , j , k ) , & ! (sqrt(real(a)**2 + aimag(a)**2))**2 = real(a)**2 + aimag(a)**2. do not take square root and square again
conjg ( - xi1st ( 1 : 3 , i , j , k ) ) * rescaledGeom ) ) ** 2.0_pReal ) & ! --> sum squared L_2 norm of vector
+ sum ( aimag ( matmul ( tensorField_fourier ( 1 : 3 , 1 : 3 , i , j , k ) , &
conjg ( - xi1st ( 1 : 3 , i , j , k ) ) * rescaledGeom ) ) ** 2.0_pReal ) )
enddo
utilities_divergenceRMS = utilities_divergenceRMS & ! these two layers (DC and Nyquist) do not have a conjugate complex counterpart (if grid(1) /= 1)
+ sum ( real ( matmul ( tensorField_fourier ( 1 : 3 , 1 : 3 , 1 , j , k ) , &
conjg ( - xi1st ( 1 : 3 , 1 , j , k ) ) * rescaledGeom ) ) ** 2.0_pReal ) &
+ sum ( aimag ( matmul ( tensorField_fourier ( 1 : 3 , 1 : 3 , 1 , j , k ) , &
conjg ( - xi1st ( 1 : 3 , 1 , j , k ) ) * rescaledGeom ) ) ** 2.0_pReal ) &
+ sum ( real ( matmul ( tensorField_fourier ( 1 : 3 , 1 : 3 , grid1Red , j , k ) , &
conjg ( - xi1st ( 1 : 3 , grid1Red , j , k ) ) * rescaledGeom ) ) ** 2.0_pReal ) &
+ sum ( aimag ( matmul ( tensorField_fourier ( 1 : 3 , 1 : 3 , grid1Red , j , k ) , &
conjg ( - xi1st ( 1 : 3 , grid1Red , j , k ) ) * rescaledGeom ) ) ** 2.0_pReal )
enddo ; enddo
2019-03-25 22:58:07 +05:30
if ( grid ( 1 ) == 1 ) utilities_divergenceRMS = utilities_divergenceRMS * 0.5_pReal ! counted twice in case of grid(1) == 1
2019-03-07 11:31:09 +05:30
call MPI_Allreduce ( MPI_IN_PLACE , utilities_divergenceRMS , 1 , MPI_DOUBLE , MPI_SUM , PETSC_COMM_WORLD , ierr )
2019-03-25 22:58:07 +05:30
if ( ierr / = 0 ) call IO_error ( 894 , ext_msg = 'utilities_divergenceRMS' )
2019-03-07 11:31:09 +05:30
utilities_divergenceRMS = sqrt ( utilities_divergenceRMS ) * wgt ! RMS in real space calculated with Parsevals theorem from Fourier space
2012-10-24 17:01:40 +05:30
end function utilities_divergenceRMS
2015-10-15 00:06:19 +05:30
2013-03-06 20:01:13 +05:30
!--------------------------------------------------------------------------------------------------
!> @brief calculate max of curl of field_fourier
!--------------------------------------------------------------------------------------------------
real ( pReal ) function utilities_curlRMS ( )
2019-03-07 11:31:09 +05:30
use IO , only : &
IO_error
use mesh , only : &
geomSize , &
grid , &
grid3
implicit none
2019-03-25 22:58:07 +05:30
integer :: i , j , k , l , ierr
2019-03-07 11:31:09 +05:30
complex ( pReal ) , dimension ( 3 , 3 ) :: curl_fourier
complex ( pReal ) , dimension ( 3 ) :: rescaledGeom
write ( 6 , '(/,a)' ) ' ... calculating curl ......................................................'
flush ( 6 )
rescaledGeom = cmplx ( geomSize / scaledGeomSize , 0.0_pReal )
2016-05-27 15:16:34 +05:30
!--------------------------------------------------------------------------------------------------
2013-03-06 20:01:13 +05:30
! calculating max curl criterion in Fourier space
2019-03-07 11:31:09 +05:30
utilities_curlRMS = 0.0_pReal
2019-03-25 22:58:07 +05:30
do k = 1 , grid3 ; do j = 1 , grid ( 2 ) ;
do i = 2 , grid1Red - 1
do l = 1 , 3
2019-03-07 11:31:09 +05:30
curl_fourier ( l , 1 ) = ( + tensorField_fourier ( l , 3 , i , j , k ) * xi1st ( 2 , i , j , k ) * rescaledGeom ( 2 ) &
- tensorField_fourier ( l , 2 , i , j , k ) * xi1st ( 3 , i , j , k ) * rescaledGeom ( 3 ) )
curl_fourier ( l , 2 ) = ( + tensorField_fourier ( l , 1 , i , j , k ) * xi1st ( 3 , i , j , k ) * rescaledGeom ( 3 ) &
- tensorField_fourier ( l , 3 , i , j , k ) * xi1st ( 1 , i , j , k ) * rescaledGeom ( 1 ) )
curl_fourier ( l , 3 ) = ( + tensorField_fourier ( l , 2 , i , j , k ) * xi1st ( 1 , i , j , k ) * rescaledGeom ( 1 ) &
- tensorField_fourier ( l , 1 , i , j , k ) * xi1st ( 2 , i , j , k ) * rescaledGeom ( 2 ) )
enddo
utilities_curlRMS = utilities_curlRMS &
+ 2.0_pReal * sum ( real ( curl_fourier ) ** 2.0_pReal + aimag ( curl_fourier ) ** 2.0_pReal ) ! Has somewhere a conj. complex counterpart. Therefore count it twice.
enddo
2019-03-25 22:58:07 +05:30
do l = 1 , 3
2019-03-07 11:31:09 +05:30
curl_fourier = ( + tensorField_fourier ( l , 3 , 1 , j , k ) * xi1st ( 2 , 1 , j , k ) * rescaledGeom ( 2 ) &
- tensorField_fourier ( l , 2 , 1 , j , k ) * xi1st ( 3 , 1 , j , k ) * rescaledGeom ( 3 ) )
curl_fourier = ( + tensorField_fourier ( l , 1 , 1 , j , k ) * xi1st ( 3 , 1 , j , k ) * rescaledGeom ( 3 ) &
- tensorField_fourier ( l , 3 , 1 , j , k ) * xi1st ( 1 , 1 , j , k ) * rescaledGeom ( 1 ) )
curl_fourier = ( + tensorField_fourier ( l , 2 , 1 , j , k ) * xi1st ( 1 , 1 , j , k ) * rescaledGeom ( 1 ) &
- tensorField_fourier ( l , 1 , 1 , j , k ) * xi1st ( 2 , 1 , j , k ) * rescaledGeom ( 2 ) )
enddo
utilities_curlRMS = utilities_curlRMS &
+ sum ( real ( curl_fourier ) ** 2.0_pReal + aimag ( curl_fourier ) ** 2.0_pReal ) ! this layer (DC) does not have a conjugate complex counterpart (if grid(1) /= 1)
2019-03-25 22:58:07 +05:30
do l = 1 , 3
2019-03-07 11:31:09 +05:30
curl_fourier = ( + tensorField_fourier ( l , 3 , grid1Red , j , k ) * xi1st ( 2 , grid1Red , j , k ) * rescaledGeom ( 2 ) &
- tensorField_fourier ( l , 2 , grid1Red , j , k ) * xi1st ( 3 , grid1Red , j , k ) * rescaledGeom ( 3 ) )
curl_fourier = ( + tensorField_fourier ( l , 1 , grid1Red , j , k ) * xi1st ( 3 , grid1Red , j , k ) * rescaledGeom ( 3 ) &
- tensorField_fourier ( l , 3 , grid1Red , j , k ) * xi1st ( 1 , grid1Red , j , k ) * rescaledGeom ( 1 ) )
curl_fourier = ( + tensorField_fourier ( l , 2 , grid1Red , j , k ) * xi1st ( 1 , grid1Red , j , k ) * rescaledGeom ( 1 ) &
- tensorField_fourier ( l , 1 , grid1Red , j , k ) * xi1st ( 2 , grid1Red , j , k ) * rescaledGeom ( 2 ) )
enddo
utilities_curlRMS = utilities_curlRMS &
+ sum ( real ( curl_fourier ) ** 2.0_pReal + aimag ( curl_fourier ) ** 2.0_pReal ) ! this layer (Nyquist) does not have a conjugate complex counterpart (if grid(1) /= 1)
enddo ; enddo
call MPI_Allreduce ( MPI_IN_PLACE , utilities_curlRMS , 1 , MPI_DOUBLE , MPI_SUM , PETSC_COMM_WORLD , ierr )
2019-03-25 22:58:07 +05:30
if ( ierr / = 0 ) call IO_error ( 894 , ext_msg = 'utilities_curlRMS' )
2019-03-07 11:31:09 +05:30
utilities_curlRMS = sqrt ( utilities_curlRMS ) * wgt
2019-03-25 22:58:07 +05:30
if ( grid ( 1 ) == 1 ) utilities_curlRMS = utilities_curlRMS * 0.5_pReal ! counted twice in case of grid(1) == 1
2013-03-06 20:01:13 +05:30
end function utilities_curlRMS
2012-07-24 22:37:10 +05:30
2012-07-30 19:36:22 +05:30
!--------------------------------------------------------------------------------------------------
2013-04-18 22:10:49 +05:30
!> @brief calculates mask compliance tensor used to adjust F to fullfill stress BC
2012-07-30 19:36:22 +05:30
!--------------------------------------------------------------------------------------------------
2012-10-24 17:01:40 +05:30
function utilities_maskedCompliance ( rot_BC , mask_stress , C )
2019-03-25 23:47:10 +05:30
use , intrinsic :: &
IEEE_arithmetic
use IO , only : &
IO_error
use math , only : &
math_3333to99 , &
math_99to3333 , &
math_rotate_forward3333 , &
math_rotate_forward33 , &
math_invert2
implicit none
real ( pReal ) , dimension ( 3 , 3 , 3 , 3 ) :: utilities_maskedCompliance !< masked compliance
real ( pReal ) , intent ( in ) , dimension ( 3 , 3 , 3 , 3 ) :: C !< current average stiffness
real ( pReal ) , intent ( in ) , dimension ( 3 , 3 ) :: rot_BC !< rotation of load frame
logical , intent ( in ) , dimension ( 3 , 3 ) :: mask_stress !< mask of stress BC
integer :: j , k , m , n
logical , dimension ( 9 ) :: mask_stressVector
real ( pReal ) , dimension ( 9 , 9 ) :: temp99_Real
integer :: size_reduced = 0
real ( pReal ) , dimension ( : , : ) , allocatable :: &
s_reduced , & !< reduced compliance matrix (depending on number of stress BC)
c_reduced , & !< reduced stiffness (depending on number of stress BC)
sTimesC !< temp variable to check inversion
logical :: errmatinv
character ( len = 1024 ) :: formatString
mask_stressVector = reshape ( transpose ( mask_stress ) , [ 9 ] )
size_reduced = count ( mask_stressVector )
if ( size_reduced > 0 ) then
allocate ( c_reduced ( size_reduced , size_reduced ) , source = 0.0_pReal )
allocate ( s_reduced ( size_reduced , size_reduced ) , source = 0.0_pReal )
allocate ( sTimesC ( size_reduced , size_reduced ) , source = 0.0_pReal )
temp99_Real = math_3333to99 ( math_rotate_forward3333 ( C , rot_BC ) )
if ( debugGeneral ) then
write ( 6 , '(/,a)' ) ' ... updating masked compliance ............................................'
write ( 6 , '(/,a,/,9(9(2x,f12.7,1x)/))' , advance = 'no' ) ' Stiffness C (load) / GPa =' , &
transpose ( temp99_Real ) * 1.0e-9_pReal
flush ( 6 )
endif
k = 0 ! calculate reduced stiffness
2019-03-25 22:58:07 +05:30
do n = 1 , 9
2012-07-30 19:36:22 +05:30
if ( mask_stressVector ( n ) ) then
2019-03-25 22:58:07 +05:30
k = k + 1
j = 0
do m = 1 , 9
2012-07-30 19:36:22 +05:30
if ( mask_stressVector ( m ) ) then
2019-03-25 22:58:07 +05:30
j = j + 1
2019-03-25 23:47:10 +05:30
c_reduced ( k , j ) = temp99_Real ( n , m )
endif ; enddo ; endif ; enddo
call math_invert2 ( s_reduced , errmatinv , c_reduced ) ! invert reduced stiffness
if ( any ( IEEE_is_NaN ( s_reduced ) ) ) errmatinv = . true .
if ( errmatinv ) call IO_error ( error_ID = 400 , ext_msg = 'utilities_maskedCompliance' )
temp99_Real = 0.0_pReal ! fill up compliance with zeros
k = 0
do n = 1 , 9
if ( mask_stressVector ( n ) ) then
k = k + 1
j = 0
do m = 1 , 9
if ( mask_stressVector ( m ) ) then
j = j + 1
temp99_Real ( n , m ) = s_reduced ( k , j )
endif ; enddo ; endif ; enddo
2015-10-15 00:06:19 +05:30
2012-10-24 17:01:40 +05:30
!--------------------------------------------------------------------------------------------------
2013-03-07 01:04:30 +05:30
! check if inversion was successful
2019-03-25 23:47:10 +05:30
sTimesC = matmul ( c_reduced , s_reduced )
do m = 1 , size_reduced
do n = 1 , size_reduced
errmatinv = errmatinv &
. or . ( m == n . and . abs ( sTimesC ( m , n ) - 1.0_pReal ) > 1.0e-12_pReal ) & ! diagonal elements of S*C should be 1
. or . ( m / = n . and . abs ( sTimesC ( m , n ) ) > 1.0e-12_pReal ) ! off-diagonal elements of S*C should be 0
enddo
enddo
if ( debugGeneral . or . errmatinv ) then
write ( formatString , '(i2)' ) size_reduced
formatString = '(/,a,/,' / / trim ( formatString ) / / '(' / / trim ( formatString ) / / '(2x,es9.2,1x)/))'
write ( 6 , trim ( formatString ) , advance = 'no' ) ' C * S (load) ' , &
transpose ( matmul ( c_reduced , s_reduced ) )
write ( 6 , trim ( formatString ) , advance = 'no' ) ' S (load) ' , transpose ( s_reduced )
if ( errmatinv ) call IO_error ( error_ID = 400 , ext_msg = 'utilities_maskedCompliance' )
endif
else
temp99_real = 0.0_pReal
endif
if ( debugGeneral ) then
write ( 6 , '(/,a,/,9(9(2x,f10.5,1x)/),/)' , advance = 'no' ) &
' Masked Compliance (load) * GPa =' , transpose ( temp99_Real ) * 1.0e9_pReal
flush ( 6 )
endif
utilities_maskedCompliance = math_99to3333 ( temp99_Real )
2012-10-24 17:01:40 +05:30
2015-10-15 00:06:19 +05:30
end function utilities_maskedCompliance
2012-10-24 17:01:40 +05:30
2015-06-03 23:00:31 +05:30
!--------------------------------------------------------------------------------------------------
!> @brief calculate scalar gradient in fourier field
!--------------------------------------------------------------------------------------------------
subroutine utilities_fourierScalarGradient ( )
2019-03-07 11:31:09 +05:30
use mesh , only : &
grid3 , &
grid
implicit none
2019-03-25 22:58:07 +05:30
integer :: i , j , k
2019-03-07 11:31:09 +05:30
vectorField_fourier = cmplx ( 0.0_pReal , 0.0_pReal , pReal )
2019-03-25 22:58:07 +05:30
forall ( k = 1 : grid3 , j = 1 : grid ( 2 ) , i = 1 : grid1Red ) &
2019-03-07 11:31:09 +05:30
vectorField_fourier ( 1 : 3 , i , j , k ) = scalarField_fourier ( i , j , k ) * xi1st ( 1 : 3 , i , j , k )
2015-06-03 23:00:31 +05:30
end subroutine utilities_fourierScalarGradient
!--------------------------------------------------------------------------------------------------
!> @brief calculate vector divergence in fourier field
!--------------------------------------------------------------------------------------------------
subroutine utilities_fourierVectorDivergence ( )
2019-03-07 11:31:09 +05:30
use mesh , only : &
grid3 , &
grid
implicit none
2019-03-25 22:58:07 +05:30
integer :: i , j , k
2019-03-07 11:31:09 +05:30
scalarField_fourier = cmplx ( 0.0_pReal , 0.0_pReal , pReal )
2019-03-25 22:58:07 +05:30
forall ( k = 1 : grid3 , j = 1 : grid ( 2 ) , i = 1 : grid1Red ) &
2019-03-25 23:47:10 +05:30
scalarField_fourier ( i , j , k ) = scalarField_fourier ( i , j , k ) &
+ sum ( vectorField_fourier ( 1 : 3 , i , j , k ) * conjg ( - xi1st ( 1 : 3 , i , j , k ) ) )
2019-03-07 11:31:09 +05:30
2015-06-03 23:00:31 +05:30
end subroutine utilities_fourierVectorDivergence
2015-09-11 18:35:46 +05:30
2015-12-14 23:42:09 +05:30
!--------------------------------------------------------------------------------------------------
!> @brief calculate vector gradient in fourier field
!--------------------------------------------------------------------------------------------------
subroutine utilities_fourierVectorGradient ( )
2019-03-07 11:31:09 +05:30
use mesh , only : &
grid3 , &
grid
implicit none
2019-03-25 22:58:07 +05:30
integer :: i , j , k , m , n
2019-03-07 11:31:09 +05:30
tensorField_fourier = cmplx ( 0.0_pReal , 0.0_pReal , pReal )
2019-03-25 22:58:07 +05:30
do k = 1 , grid3 ; do j = 1 , grid ( 2 ) ; do i = 1 , grid1Red
do m = 1 , 3 ; do n = 1 , 3
2019-03-07 11:31:09 +05:30
tensorField_fourier ( m , n , i , j , k ) = vectorField_fourier ( m , i , j , k ) * xi1st ( n , i , j , k )
enddo ; enddo
enddo ; enddo ; enddo
2015-12-14 23:42:09 +05:30
end subroutine utilities_fourierVectorGradient
!--------------------------------------------------------------------------------------------------
!> @brief calculate tensor divergence in fourier field
!--------------------------------------------------------------------------------------------------
subroutine utilities_fourierTensorDivergence ( )
2019-03-07 11:31:09 +05:30
use mesh , only : &
grid3 , &
grid
implicit none
2019-03-25 22:58:07 +05:30
integer :: i , j , k , m , n
2019-03-07 11:31:09 +05:30
vectorField_fourier = cmplx ( 0.0_pReal , 0.0_pReal , pReal )
2019-03-25 22:58:07 +05:30
do k = 1 , grid3 ; do j = 1 , grid ( 2 ) ; do i = 1 , grid1Red
do m = 1 , 3 ; do n = 1 , 3
2019-03-25 23:47:10 +05:30
vectorField_fourier ( m , i , j , k ) = vectorField_fourier ( m , i , j , k ) &
+ tensorField_fourier ( m , n , i , j , k ) * conjg ( - xi1st ( n , i , j , k ) )
2019-03-07 11:31:09 +05:30
enddo ; enddo
enddo ; enddo ; enddo
2015-12-14 23:42:09 +05:30
end subroutine utilities_fourierTensorDivergence
2012-10-24 17:01:40 +05:30
!--------------------------------------------------------------------------------------------------
2018-02-16 20:06:18 +05:30
!> @brief calculate constitutive response from materialpoint_F0 to F during timeinc
2012-10-24 17:01:40 +05:30
!--------------------------------------------------------------------------------------------------
2018-02-16 20:06:18 +05:30
subroutine utilities_constitutiveResponse ( P , P_av , C_volAvg , C_minmaxAvg , &
F , timeinc , rotation_BC )
2019-03-07 11:31:09 +05:30
use IO , only : &
IO_error
use numerics , only : &
worldrank
use debug , only : &
debug_reset , &
debug_info
use math , only : &
math_rotate_forward33 , &
math_det33
use mesh , only : &
grid , &
grid3
use homogenization , only : &
materialpoint_F , &
materialpoint_P , &
materialpoint_dPdF , &
materialpoint_stressAndItsTangent
2018-02-16 20:06:18 +05:30
2019-03-07 11:31:09 +05:30
implicit none
real ( pReal ) , intent ( out ) , dimension ( 3 , 3 , 3 , 3 ) :: C_volAvg , C_minmaxAvg !< average stiffness
real ( pReal ) , intent ( out ) , dimension ( 3 , 3 ) :: P_av !< average PK stress
real ( pReal ) , intent ( out ) , dimension ( 3 , 3 , grid ( 1 ) , grid ( 2 ) , grid3 ) :: P !< PK stress
real ( pReal ) , intent ( in ) , dimension ( 3 , 3 , grid ( 1 ) , grid ( 2 ) , grid3 ) :: F !< deformation gradient target
real ( pReal ) , intent ( in ) :: timeinc !< loading time
real ( pReal ) , intent ( in ) , dimension ( 3 , 3 ) :: rotation_BC !< rotation of load frame
2018-02-16 20:06:18 +05:30
2019-03-07 11:31:09 +05:30
2019-03-25 22:58:07 +05:30
integer :: &
2019-03-07 11:31:09 +05:30
i , ierr
real ( pReal ) , dimension ( 3 , 3 , 3 , 3 ) :: dPdF_max , dPdF_min
real ( pReal ) :: dPdF_norm_max , dPdF_norm_min
real ( pReal ) , dimension ( 2 ) :: valueAndRank !< pair of min/max norm of dPdF to synchronize min/max of dPdF
2018-02-16 20:06:18 +05:30
2019-03-07 11:31:09 +05:30
write ( 6 , '(/,a)' ) ' ... evaluating constitutive response ......................................'
flush ( 6 )
materialpoint_F = reshape ( F , [ 3 , 3 , 1 , product ( grid ( 1 : 2 ) ) * grid3 ] ) ! set materialpoint target F to estimated field
call debug_reset ( ) ! this has no effect on rank >0
call materialpoint_stressAndItsTangent ( . true . , timeinc ) ! calculate P field
P = reshape ( materialpoint_P , [ 3 , 3 , grid ( 1 ) , grid ( 2 ) , grid3 ] )
P_av = sum ( sum ( sum ( P , dim = 5 ) , dim = 4 ) , dim = 3 ) * wgt ! average of P
call MPI_Allreduce ( MPI_IN_PLACE , P_av , 9 , MPI_DOUBLE , MPI_SUM , PETSC_COMM_WORLD , ierr )
if ( debugRotation ) &
write ( 6 , '(/,a,/,3(3(2x,f12.4,1x)/))' , advance = 'no' ) ' Piola--Kirchhoff stress (lab) / MPa =' , &
transpose ( P_av ) * 1.e-6_pReal
P_av = math_rotate_forward33 ( P_av , rotation_BC )
write ( 6 , '(/,a,/,3(3(2x,f12.4,1x)/))' , advance = 'no' ) ' Piola--Kirchhoff stress / MPa =' , &
transpose ( P_av ) * 1.e-6_pReal
flush ( 6 )
dPdF_max = 0.0_pReal
dPdF_norm_max = 0.0_pReal
dPdF_min = huge ( 1.0_pReal )
dPdF_norm_min = huge ( 1.0_pReal )
2019-03-25 22:58:07 +05:30
do i = 1 , product ( grid ( 1 : 2 ) ) * grid3
2019-03-07 11:31:09 +05:30
if ( dPdF_norm_max < sum ( materialpoint_dPdF ( 1 : 3 , 1 : 3 , 1 : 3 , 1 : 3 , 1 , i ) ** 2.0_pReal ) ) then
dPdF_max = materialpoint_dPdF ( 1 : 3 , 1 : 3 , 1 : 3 , 1 : 3 , 1 , i )
dPdF_norm_max = sum ( materialpoint_dPdF ( 1 : 3 , 1 : 3 , 1 : 3 , 1 : 3 , 1 , i ) ** 2.0_pReal )
endif
if ( dPdF_norm_min > sum ( materialpoint_dPdF ( 1 : 3 , 1 : 3 , 1 : 3 , 1 : 3 , 1 , i ) ** 2.0_pReal ) ) then
dPdF_min = materialpoint_dPdF ( 1 : 3 , 1 : 3 , 1 : 3 , 1 : 3 , 1 , i )
dPdF_norm_min = sum ( materialpoint_dPdF ( 1 : 3 , 1 : 3 , 1 : 3 , 1 : 3 , 1 , i ) ** 2.0_pReal )
endif
end do
valueAndRank = [ dPdF_norm_max , real ( worldrank , pReal ) ]
call MPI_Allreduce ( MPI_IN_PLACE , valueAndRank , 1 , MPI_2DOUBLE_PRECISION , MPI_MAXLOC , PETSC_COMM_WORLD , ierr )
2019-03-25 22:58:07 +05:30
if ( ierr / = 0 ) call IO_error ( 894 , ext_msg = 'MPI_Allreduce max' )
2019-03-07 11:31:09 +05:30
call MPI_Bcast ( dPdF_max , 81 , MPI_DOUBLE , int ( valueAndRank ( 2 ) ) , PETSC_COMM_WORLD , ierr )
2019-03-25 22:58:07 +05:30
if ( ierr / = 0 ) call IO_error ( 894 , ext_msg = 'MPI_Bcast max' )
2019-03-07 11:31:09 +05:30
valueAndRank = [ dPdF_norm_min , real ( worldrank , pReal ) ]
call MPI_Allreduce ( MPI_IN_PLACE , valueAndRank , 1 , MPI_2DOUBLE_PRECISION , MPI_MINLOC , PETSC_COMM_WORLD , ierr )
2019-03-25 22:58:07 +05:30
if ( ierr / = 0 ) call IO_error ( 894 , ext_msg = 'MPI_Allreduce min' )
2019-03-07 11:31:09 +05:30
call MPI_Bcast ( dPdF_min , 81 , MPI_DOUBLE , int ( valueAndRank ( 2 ) ) , PETSC_COMM_WORLD , ierr )
2019-03-25 22:58:07 +05:30
if ( ierr / = 0 ) call IO_error ( 894 , ext_msg = 'MPI_Bcast min' )
2019-03-07 11:31:09 +05:30
C_minmaxAvg = 0.5_pReal * ( dPdF_max + dPdF_min )
C_volAvg = sum ( sum ( materialpoint_dPdF , dim = 6 ) , dim = 5 )
call MPI_Allreduce ( MPI_IN_PLACE , C_volAvg , 81 , MPI_DOUBLE , MPI_SUM , PETSC_COMM_WORLD , ierr )
C_volAvg = C_volAvg * wgt
call debug_info ( ) ! this has no effect on rank >0
2015-10-15 00:06:19 +05:30
2012-10-24 17:01:40 +05:30
end subroutine utilities_constitutiveResponse
2012-07-30 19:36:22 +05:30
2012-10-24 17:01:40 +05:30
!--------------------------------------------------------------------------------------------------
!> @brief calculates forward rate, either guessing or just add delta/timeinc
!--------------------------------------------------------------------------------------------------
2018-02-16 20:06:18 +05:30
pure function utilities_calculateRate ( heterogeneous , field0 , field , dt , avRate )
2019-03-07 11:31:09 +05:30
use mesh , only : &
grid3 , &
grid
implicit none
real ( pReal ) , intent ( in ) , dimension ( 3 , 3 ) :: &
avRate !< homogeneous addon
real ( pReal ) , intent ( in ) :: &
dt !< timeinc between field0 and field
logical , intent ( in ) :: &
heterogeneous !< calculate field of rates
real ( pReal ) , intent ( in ) , dimension ( 3 , 3 , grid ( 1 ) , grid ( 2 ) , grid3 ) :: &
field0 , & !< data of previous step
field !< data of current step
real ( pReal ) , dimension ( 3 , 3 , grid ( 1 ) , grid ( 2 ) , grid3 ) :: &
utilities_calculateRate
if ( heterogeneous ) then
utilities_calculateRate = ( field - field0 ) / dt
else
utilities_calculateRate = spread ( spread ( spread ( avRate , 3 , grid ( 1 ) ) , 4 , grid ( 2 ) ) , 5 , grid3 )
endif
2012-08-09 18:34:56 +05:30
2012-10-24 17:01:40 +05:30
end function utilities_calculateRate
2012-10-02 20:56:56 +05:30
2012-10-24 17:01:40 +05:30
!--------------------------------------------------------------------------------------------------
2015-10-15 00:06:19 +05:30
!> @brief forwards a field with a pointwise given rate, if aim is given,
2013-01-08 15:42:03 +05:30
!> ensures that the average matches the aim
2012-10-24 17:01:40 +05:30
!--------------------------------------------------------------------------------------------------
2015-03-25 21:36:19 +05:30
function utilities_forwardField ( timeinc , field_lastInc , rate , aim )
2019-03-07 11:42:35 +05:30
use mesh , only : &
grid3 , &
grid
2015-10-15 00:06:19 +05:30
2019-03-07 11:42:35 +05:30
implicit none
real ( pReal ) , intent ( in ) :: &
timeinc !< timeinc of current step
real ( pReal ) , intent ( in ) , dimension ( 3 , 3 , grid ( 1 ) , grid ( 2 ) , grid3 ) :: &
field_lastInc , & !< initial field
rate !< rate by which to forward
real ( pReal ) , intent ( in ) , optional , dimension ( 3 , 3 ) :: &
aim !< average field value aim
real ( pReal ) , dimension ( 3 , 3 , grid ( 1 ) , grid ( 2 ) , grid3 ) :: &
utilities_forwardField
real ( pReal ) , dimension ( 3 , 3 ) :: fieldDiff !< <a + adot*t> - aim
PetscErrorCode :: ierr
utilities_forwardField = field_lastInc + rate * timeinc
if ( present ( aim ) ) then !< correct to match average
fieldDiff = sum ( sum ( sum ( utilities_forwardField , dim = 5 ) , dim = 4 ) , dim = 3 ) * wgt
call MPI_Allreduce ( MPI_IN_PLACE , fieldDiff , 9 , MPI_DOUBLE , MPI_SUM , PETSC_COMM_WORLD , ierr )
fieldDiff = fieldDiff - aim
utilities_forwardField = utilities_forwardField - &
spread ( spread ( spread ( fieldDiff , 3 , grid ( 1 ) ) , 4 , grid ( 2 ) ) , 5 , grid3 )
endif
2012-10-02 20:56:56 +05:30
2012-10-24 17:01:40 +05:30
end function utilities_forwardField
2012-10-02 20:56:56 +05:30
2012-08-07 22:53:13 +05:30
2012-10-24 17:01:40 +05:30
!--------------------------------------------------------------------------------------------------
!> @brief calculates filter for fourier convolution depending on type given in numerics.config
2016-02-08 22:03:17 +05:30
!> @details this is the full operator to calculate derivatives, i.e. 2 \pi i k for the
! standard approach
2012-10-24 17:01:40 +05:30
!--------------------------------------------------------------------------------------------------
2015-12-14 23:42:09 +05:30
pure function utilities_getFreqDerivative ( k_s )
2019-03-07 11:42:35 +05:30
use math , only : &
PI
use mesh , only : &
geomSize , &
grid
2015-12-14 23:42:09 +05:30
2019-03-07 11:42:35 +05:30
implicit none
2019-03-25 22:58:07 +05:30
integer , intent ( in ) , dimension ( 3 ) :: k_s !< indices of frequency
complex ( pReal ) , dimension ( 3 ) :: utilities_getFreqDerivative
2019-03-07 11:42:35 +05:30
select case ( spectral_derivative_ID )
case ( DERIVATIVE_CONTINUOUS_ID )
utilities_getFreqDerivative = cmplx ( 0.0_pReal , 2.0_pReal * PI * real ( k_s , pReal ) / geomSize , pReal )
case ( DERIVATIVE_CENTRAL_DIFF_ID )
utilities_getFreqDerivative = cmplx ( 0.0_pReal , sin ( 2.0_pReal * PI * real ( k_s , pReal ) / real ( grid , pReal ) ) , pReal ) / &
cmplx ( 2.0_pReal * geomSize / real ( grid , pReal ) , 0.0_pReal , pReal )
case ( DERIVATIVE_FWBW_DIFF_ID )
utilities_getFreqDerivative ( 1 ) = &
cmplx ( cos ( 2.0_pReal * PI * real ( k_s ( 1 ) , pReal ) / real ( grid ( 1 ) , pReal ) ) - 1.0_pReal , &
sin ( 2.0_pReal * PI * real ( k_s ( 1 ) , pReal ) / real ( grid ( 1 ) , pReal ) ) , pReal ) * &
cmplx ( cos ( 2.0_pReal * PI * real ( k_s ( 2 ) , pReal ) / real ( grid ( 2 ) , pReal ) ) + 1.0_pReal , &
sin ( 2.0_pReal * PI * real ( k_s ( 2 ) , pReal ) / real ( grid ( 2 ) , pReal ) ) , pReal ) * &
cmplx ( cos ( 2.0_pReal * PI * real ( k_s ( 3 ) , pReal ) / real ( grid ( 3 ) , pReal ) ) + 1.0_pReal , &
sin ( 2.0_pReal * PI * real ( k_s ( 3 ) , pReal ) / real ( grid ( 3 ) , pReal ) ) , pReal ) / &
cmplx ( 4.0_pReal * geomSize ( 1 ) / real ( grid ( 1 ) , pReal ) , 0.0_pReal , pReal )
utilities_getFreqDerivative ( 2 ) = &
cmplx ( cos ( 2.0_pReal * PI * real ( k_s ( 1 ) , pReal ) / real ( grid ( 1 ) , pReal ) ) + 1.0_pReal , &
sin ( 2.0_pReal * PI * real ( k_s ( 1 ) , pReal ) / real ( grid ( 1 ) , pReal ) ) , pReal ) * &
cmplx ( cos ( 2.0_pReal * PI * real ( k_s ( 2 ) , pReal ) / real ( grid ( 2 ) , pReal ) ) - 1.0_pReal , &
sin ( 2.0_pReal * PI * real ( k_s ( 2 ) , pReal ) / real ( grid ( 2 ) , pReal ) ) , pReal ) * &
cmplx ( cos ( 2.0_pReal * PI * real ( k_s ( 3 ) , pReal ) / real ( grid ( 3 ) , pReal ) ) + 1.0_pReal , &
sin ( 2.0_pReal * PI * real ( k_s ( 3 ) , pReal ) / real ( grid ( 3 ) , pReal ) ) , pReal ) / &
cmplx ( 4.0_pReal * geomSize ( 2 ) / real ( grid ( 2 ) , pReal ) , 0.0_pReal , pReal )
utilities_getFreqDerivative ( 3 ) = &
cmplx ( cos ( 2.0_pReal * PI * real ( k_s ( 1 ) , pReal ) / real ( grid ( 1 ) , pReal ) ) + 1.0_pReal , &
sin ( 2.0_pReal * PI * real ( k_s ( 1 ) , pReal ) / real ( grid ( 1 ) , pReal ) ) , pReal ) * &
cmplx ( cos ( 2.0_pReal * PI * real ( k_s ( 2 ) , pReal ) / real ( grid ( 2 ) , pReal ) ) + 1.0_pReal , &
sin ( 2.0_pReal * PI * real ( k_s ( 2 ) , pReal ) / real ( grid ( 2 ) , pReal ) ) , pReal ) * &
cmplx ( cos ( 2.0_pReal * PI * real ( k_s ( 3 ) , pReal ) / real ( grid ( 3 ) , pReal ) ) - 1.0_pReal , &
sin ( 2.0_pReal * PI * real ( k_s ( 3 ) , pReal ) / real ( grid ( 3 ) , pReal ) ) , pReal ) / &
cmplx ( 4.0_pReal * geomSize ( 3 ) / real ( grid ( 3 ) , pReal ) , 0.0_pReal , pReal )
end select
2012-07-25 19:31:39 +05:30
2015-12-14 23:42:09 +05:30
end function utilities_getFreqDerivative
2012-10-02 20:56:56 +05:30
2015-03-13 03:58:33 +05:30
!--------------------------------------------------------------------------------------------------
!> @brief calculate coordinates in current configuration for given defgrad field
! using integration in Fourier space. Similar as in mesh.f90, but using data already defined for
! convolution
!--------------------------------------------------------------------------------------------------
subroutine utilities_updateIPcoords ( F )
2019-03-07 11:42:35 +05:30
use prec , only : &
cNeq
use IO , only : &
IO_error
use math , only : &
math_mul33x3
use mesh , only : &
grid , &
grid3 , &
grid3Offset , &
geomSize , &
mesh_ipCoordinates
implicit none
real ( pReal ) , dimension ( 3 , 3 , grid ( 1 ) , grid ( 2 ) , grid3 ) , intent ( in ) :: F
2019-03-25 22:58:07 +05:30
integer :: i , j , k , m , ierr
2019-03-07 11:42:35 +05:30
real ( pReal ) , dimension ( 3 ) :: step , offset_coords
real ( pReal ) , dimension ( 3 , 3 ) :: Favg
!--------------------------------------------------------------------------------------------------
! integration in Fourier space
tensorField_real = 0.0_pReal
tensorField_real ( 1 : 3 , 1 : 3 , 1 : grid ( 1 ) , 1 : grid ( 2 ) , 1 : grid3 ) = F
call utilities_FFTtensorForward ( )
call utilities_fourierTensorDivergence ( )
2019-03-25 22:58:07 +05:30
do k = 1 , grid3 ; do j = 1 , grid ( 2 ) ; do i = 1 , grid1Red
2019-03-10 13:38:54 +05:30
if ( any ( cNeq ( xi1st ( 1 : 3 , i , j , k ) , cmplx ( 0.0 , 0.0 , pReal ) ) ) ) &
2019-03-07 11:42:35 +05:30
vectorField_fourier ( 1 : 3 , i , j , k ) = vectorField_fourier ( 1 : 3 , i , j , k ) / &
sum ( conjg ( - xi1st ( 1 : 3 , i , j , k ) ) * xi1st ( 1 : 3 , i , j , k ) )
enddo ; enddo ; enddo
call fftw_mpi_execute_dft_c2r ( planVectorBack , vectorField_fourier , vectorField_real )
vectorField_real = vectorField_real * wgt
!--------------------------------------------------------------------------------------------------
! average F
2019-03-25 22:58:07 +05:30
if ( grid3Offset == 0 ) Favg = real ( tensorField_fourier ( 1 : 3 , 1 : 3 , 1 , 1 , 1 ) , pReal ) * wgt
2019-03-07 11:42:35 +05:30
call MPI_Bcast ( Favg , 9 , MPI_DOUBLE , 0 , PETSC_COMM_WORLD , ierr )
2019-03-25 22:58:07 +05:30
if ( ierr / = 0 ) call IO_error ( 894 , ext_msg = 'update_IPcoords' )
2019-03-07 11:42:35 +05:30
!--------------------------------------------------------------------------------------------------
! add average to fluctuation and put (0,0,0) on (0,0,0)
step = geomSize / real ( grid , pReal )
2019-03-25 22:58:07 +05:30
if ( grid3Offset == 0 ) offset_coords = vectorField_real ( 1 : 3 , 1 , 1 , 1 )
2019-03-07 11:42:35 +05:30
call MPI_Bcast ( offset_coords , 3 , MPI_DOUBLE , 0 , PETSC_COMM_WORLD , ierr )
2019-03-25 22:58:07 +05:30
if ( ierr / = 0 ) call IO_error ( 894 , ext_msg = 'update_IPcoords' )
2019-03-07 11:42:35 +05:30
offset_coords = math_mul33x3 ( Favg , step / 2.0_pReal ) - offset_coords
2019-03-25 22:58:07 +05:30
m = 1
do k = 1 , grid3 ; do j = 1 , grid ( 2 ) ; do i = 1 , grid ( 1 )
2019-03-07 11:42:35 +05:30
mesh_ipCoordinates ( 1 : 3 , 1 , m ) = vectorField_real ( 1 : 3 , i , j , k ) &
+ offset_coords &
2019-03-25 22:58:07 +05:30
+ math_mul33x3 ( Favg , step * real ( [ i , j , k + grid3Offset ] - 1 , pReal ) )
m = m + 1
2019-03-07 11:42:35 +05:30
enddo ; enddo ; enddo
2015-03-13 03:58:33 +05:30
end subroutine utilities_updateIPcoords
2015-12-16 02:15:54 +05:30
end module spectral_utilities