changed tools for voronoi tessellation to match new specification (file extension and resolution). Also renamed the files, because the space characters cause trouble

improved reconstruct.f90 and spectral_post.py, both files work now under linux

added make_reconstruct.py, small shell script for using f2py
This commit is contained in:
Martin Diehl 2011-01-07 14:37:05 +00:00
parent ccc6aac10b
commit 322cbd2597
5 changed files with 375 additions and 120 deletions

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@ -0,0 +1,8 @@
#!/bin/bash
# This script is used to compile the python module used for geometry reconstruction.
# It uses the fortran wrapper f2py that is included in the numpy package to construct the
# module reconstruct.so out of the fortran code reconstruct.f90
# written by M. Diehl, m.diehl@mpie.de
f2py -c -m reconstruct reconstruct.f90

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@ -1,14 +1,12 @@
! -*- f90 -*-
subroutine simple(defgrad,res_x,res_y,res_z,geomdimension,current_configuration)
implicit none
! *** Precision of real and integer variables ***
integer, parameter :: pReal = selected_real_kind(15) ! 15 significant digits, up to 1e+-300
integer, parameter :: pInt = selected_int_kind(9) ! up to +- 1e9
integer(pInt) i,j,k
integer(pInt) res_x, res_y, res_z
integer(pInt), dimension(3) :: resolution
real(pReal) , dimension(3) :: geomdimension
real(pReal) , dimension(3,3) :: temp33_Real
integer, parameter :: pDouble = selected_real_kind(15,50)
integer i,j,k
integer res_x, res_y, res_z
integer, dimension(3) :: resolution
real*8, dimension(3) :: geomdimension
real*8, dimension(3,3) :: temp33_Real
real*8 current_configuration(res_x, res_y, res_z,3)
real*8 defgrad(res_x, res_y, res_z,3,3)
!f2py intent(in) res_x, res_y, res_z
@ -19,29 +17,263 @@ subroutine simple(defgrad,res_x,res_y,res_z,geomdimension,current_configuration)
!f2py depend(res_x, res_y, res_z) defgrad
resolution(1) = res_x; resolution(2) = res_y; resolution(3) = res_z
print*, defgrad
do k = 1, resolution(3); do j = 1, resolution(2); do i = 1, resolution(1)
if((k==1).and.(j==1).and.(i==1)) then
temp33_Real =0.0_pReal
temp33_Real =0.0_pDouble
else
if((j==1).and.(i==1)) then
temp33_Real(1,:) = temp33_Real(1,:) + matmul(defgrad(i,j,k,:,:),&
(/0.0_pReal,0.0_pReal,(real(resolution(3), pReal)/geomdimension(3))/))
(/0.0_pDouble,0.0_pDouble,geomdimension(3)/(real(resolution(3)))/))
temp33_Real(2,:) = temp33_Real(1,:)
temp33_Real(3,:) = temp33_Real(1,:)
current_configuration(i,j,k,:) = temp33_Real(1,:)
else
if(i==1) then
temp33_Real(2,:) = temp33_Real(2,:) + matmul(defgrad(i,j,k,:,:),&
(/0.0_pReal,(real(resolution(2),pReal)/geomdimension(2)),0.0_pReal/))
(/0.0_pDouble,geomdimension(2)/(real(resolution(2))),0.0_pDouble/))
temp33_Real(3,:) = temp33_Real(2,:)
current_configuration(i,j,k,:) = temp33_Real(2,:)
else
temp33_Real(3,:) = temp33_Real(3,:) + matmul(defgrad(i,j,k,:,:),&
(/(real(resolution(1), pReal)/geomdimension(1)),0.0_pReal,0.0_pReal/))
(/geomdimension(1)/(real(resolution(1))),0.0_pDouble,0.0_pDouble/))
current_configuration(i,j,k,:) = temp33_Real(3,:)
endif
endif
endif
!print*, current_configuration
enddo; enddo; enddo
end subroutine simple
subroutine advanced(defgrad,res_x,res_y,res_z,geomdimension,current_configuration)
implicit none
integer, parameter :: pDouble = selected_real_kind(15,50)
integer i,j,k,l
integer a,b,c
integer res_x, res_y, res_z
integer, dimension(3) :: resolution
real*8, dimension(3) :: geomdimension
real*8, dimension(3,3) :: temp33_Real, defgrad_av !matrix, stores 3 times a 3dim position vector
real*8 current_configuration(res_x, res_y, res_z,3)
real*8 defgrad(res_x, res_y, res_z,3,3)
! some declarations for the wrapping to python
!f2py intent(in) res_x, res_y, res_z
!f2py intent(in) geomdimension
!f2py intent(out) current_configuration
!f2py intent(in) defgrad
!f2py depend(res_x, res_y, res_z) current_configuration
!f2py depend(res_x, res_y, res_z) defgrad
do i=1, 3; do j=1,3 !
defgrad_av(i,j) = sum(defgrad(:,:,:,i,j)) /real(res_x*res_y*res_z)
enddo; enddo
current_configuration(i,j,k,:) = 0.0_pDouble
do l=1,6 ! do 6 different paths, by using 3 'master edges'
select case(l)
case (1)
a = 1; b = 2; c = 3
case (2)
a = 1; b = 3; c = 2
case (3)
a = 2; b = 1; c = 3
case (4)
a = 2; b = 3; c = 1
case (5)
a = 3; b = 1; c = 2
case (6)
a = 3; b = 2; c = 1
end select
resolution(a) = res_x; resolution(b) = res_y; resolution(c) = res_z
do k = 1, resolution(c); do j = 1, resolution(b); do i = 1, resolution(a)
if((k==1).and.(j==1).and.(i==1)) then ! first FP
temp33_Real = 0.0_pDouble ! all positions set to zero
else
if((j==1).and.(i==1)) then ! all FPs on the 'master edge'
temp33_Real(1,:) = temp33_Real(1,:) + matmul((defgrad(i,j,k-1,:,:)+defgrad(i,j,k-1,:,:))/2.0_pDouble,& !using the average defgrad of the current step
(/0.0_pDouble,0.0_pDouble,geomdimension(c)/(real(resolution(c)))/))
temp33_Real(2,:) = temp33_Real(1,:)
temp33_Real(3,:) = temp33_Real(1,:)
current_configuration(i,j,k,:) = current_configuration(i,j,k,:) + temp33_Real(1,:)
else
if(i==1) then
temp33_Real(2,:) = temp33_Real(2,:) + matmul((defgrad(i,j-1,k,:,:)+defgrad(i,j,k,:,:))/2.0_pDouble,&
(/0.0_pDouble,geomdimension(b)/(real(resolution(b))),0.0_pDouble/))
temp33_Real(3,:) = temp33_Real(2,:)
current_configuration(i,j,k,:) = current_configuration(i,j,k,:) + temp33_Real(2,:)
else
temp33_Real(3,:) = temp33_Real(3,:) + matmul((defgrad(i-1,j,k,:,:)+defgrad(i,j,k,:,:))/2.0_pDouble,&
(/geomdimension(a)/(real(resolution(a))),0.0_pDouble,0.0_pDouble/))
current_configuration(i,j,k,:) = current_configuration(i,j,k,:) + temp33_Real(3,:)
endif
endif
endif
enddo; enddo; enddo ! end of one reconstruction
enddo ! end of 6 reconstructions with different pathes
current_configuration = current_configuration/6.0_pDouble
end subroutine advanced
subroutine mesh(inter,res_x,res_y,res_z,gdim,meshgeom)
implicit none
integer, parameter :: pDouble = selected_real_kind(15,50)
integer i,j,k
integer res_x, res_y, res_z
integer, dimension(3) :: resolution
real*8, dimension(3) :: gdim
real*8 inter(res_x, res_y, res_z,3)
real*8 configuration(res_x+2, res_y+2, res_z+2,3)
real*8 meshgeom(res_x+1, res_y+1, res_z+1,3)
!f2py intent(in) res_x, res_y, res_z
!f2py intent(in) inter
!f2py intent(out) meshgeom
!f2py intent(in) gdim
!f2py depend(res_x, res_y, res_z) inter
!f2py depend(res_x, res_y, res_z) meshgeom
meshgeom = 0.0_pDouble
configuration = 0.0_pDouble
resolution(1) = res_x; resolution(2) = res_y; resolution(3) = res_z
do k = 1, resolution(3)+1; do j = 1, resolution(2)+1; do i = 1, resolution(1)+1
if((i==1).and.(j==1).and.(k==1)) then
configuration(i,j,k,:)=inter(res_x,res_y,res_z,:)-gdim
configuration(res_x+2,j,k,:)=inter(i,res_y,res_z,:)+(/1.0,-1.0,-1.0/)*gdim
configuration(i,res_y+2,k,:)=inter(res_x,j,res_z,:)+(/-1.0,1.0,-1.0/)*gdim
configuration(i,j,res_z+2,:)=inter(res_x,res_y,k,:)+(/-1.0,-1.0,1.0/)*gdim
configuration(res_x+2,res_y+2,k,:)=inter(i,j,res_z,:)+(/1.0,1.0,-1.0/)*gdim
configuration(i,res_y+2,res_z+2,:)=inter(res_x,j,k,:)+(/-1.0,1.0,1.0/)*gdim
configuration(res_x+2,j,res_z+2,:)=inter(i,res_y,k,:)+(/1.0,-1.0,1.0/)*gdim
configuration(res_x+2,res_y+2,res_z+2,:)=inter(i,j,k,:)+gdim
endif
if((i==1).and.(j==1).and.(k/=1)) then
configuration(1,1,k,:)=inter(res_x,res_y,k-1,:)+(/-1.0,-1.0,0.0/)*gdim
configuration(res_x+2,1,k,:)=inter(1,res_y,k-1,:)+(/1.0,-1.0,0.0/)*gdim
configuration(1,res_y+2,k,:)=inter(res_x,1,k-1,:)+(/-1.0,1.0,0.0/)*gdim
configuration(res_x+2,res_y+2,k,:)=inter(1,1,k-1,:)+(/1.0,1.0,0.0/)*gdim
endif
if((i==1).and.(j/=1).and.(k==1)) then
configuration(1,j,1,:)=inter(res_x,j-1,res_z,:)+(/-1.0,0.0,-1.0/)*gdim
configuration(res_x+2,j,1,:)=inter(1,j-1,res_z,:)+(/1.0,0.0,-1.0/)*gdim
configuration(1,j,res_z+2,:)=inter(res_x,j-1,1,:)+(/-1.0,0.0,1.0/)*gdim
configuration(res_x+2,j,res_z+2,:)=inter(1,j-1,1,:)+(/1.0,0.0,1.0/)*gdim
endif
if((i/=1).and.(j==1).and.(k==1)) then
configuration(i,1,1,:)=inter(i-1,res_y,res_z,:)+(/0.0,-1.0,-1.0/)*gdim
configuration(i,1,res_z+2,:)=inter(i-1,res_y,1,:)+(/0.0,-1.0,1.0/)*gdim
configuration(i,res_y+2,1,:)=inter(i-1,1,res_z,:)+(/0.0,1.0,-1.0/)*gdim
configuration(i,res_y+2,res_z+2,:)=inter(i-1,1,1,:)+(/0.0,1.0,1.0/)*gdim
endif
if((i/=1).and.(j/=1).and.(k==1)) then
configuration(i,j,1,:)=inter(i-1,j-1,res_z,:)+(/0.0,0.0,-1.0/)*gdim
configuration(i,j,res_z+2,:)=inter(i-1,j-1,1,:)+(/0.0,0.0,1.0/)*gdim
endif
if((i==1).and.(j/=1).and.(k/=1)) then
configuration(1,j,k,:)=inter(res_x,j-1,k-1,:)+(/-1.0,0.0,0.0/)*gdim
configuration(res_x+2,j,k,:)=inter(i,j-1,k-1,:)+(/1.0,0.0,0.0/)*gdim
endif
if((i/=1).and.(j==1).and.(k/=1)) then
configuration(i,1,k,:)=inter(i-1,res_y,k-1,:)+(/0.0,-1.0,0.0/)*gdim
configuration(i,res_y+2,k,:)=inter(i-1,1,k-1,:)+(/0.0,1.0,0.0/)*gdim
endif
if((i/=1).and.(j/=1).and.(k/=1)) then
configuration(i,j,k,:)=inter(i-1,j-1,k-1,:)
endif
enddo; enddo; enddo
do k = 1, resolution(3)+1; do j = 1, resolution(2)+1; do i = 1, resolution(1)+1
meshgeom(i,j,k,:)=((configuration(i,j,k,:) +configuration(i+1,j,k,:))&
+(configuration(i,j+1,k,:) +configuration(i,j,k+1,:))&
+(configuration(i+1,j+1,k,:) +configuration(i,j+1,k+1,:))&
+(configuration(i+1,j,k+1,:) +configuration(i+1,j+1,k+1,:)))/8.0_pDouble
enddo; enddo; enddo
end subroutine mesh
!below some code I used for gmsh postprocessing. Might be helpful
!!gmsh output
! character(len=1024) :: nriter
! character(len=1024) :: nrstep
! character(len=1024) :: nrloadcase
! real(pReal), dimension(:,:,:,:), allocatable :: displacement
! real(pReal), dimension(3,3) :: temp33_Real2
! real(pReal), dimension(3,3,3) :: Eigenvectorbasis
! real(pReal), dimension(3) :: Eigenvalue
! real(pReal) determinant
!!gmsh output
!!Postprocessing (gsmh output)
! do k = 1, resolution(3); do j = 1, resolution(2); do i = 1, resolution(1)
! if((k==1).and.(j==1).and.(i==1)) then
! temp33_Real =0.0_pReal
! else
! if((j==1).and.(i==1)) then
! temp33_Real(1,:) = temp33_Real(1,:) + math_mul33x3(defgrad(i,j,k,:,:),&
! (/0.0_pReal,0.0_pReal,(real(resolution(3))/meshdimension(3))/))
! temp33_Real(2,:) = temp33_Real(1,:)
! temp33_Real(3,:) = temp33_Real(1,:)
! displacement(i,j,k,:) = temp33_Real(1,:)
! else
! if(i==1) then
! temp33_Real(2,:) = temp33_Real(2,:) + math_mul33x3(defgrad(i,j,k,:,:),&
! (/0.0_pReal,(real(resolution(2))/meshdimension(2)),0.0_pReal/))
! temp33_Real(3,:) = temp33_Real(2,:)
! displacement(i,j,k,:) = temp33_Real(2,:)
! else
! temp33_Real(3,:) = temp33_Real(3,:) + math_mul33x3(defgrad(i,j,k,:,:),&
! (/(real(resolution(1))/meshdimension(1)),0.0_pReal,0.0_pReal/))
! displacement(i,j,k,:) = temp33_Real(3,:)
! endif
! endif
! endif
! enddo; enddo; enddo
! write(nrloadcase, *) loadcase; write(nriter, *) iter; write(nrstep, *) steps
! open(589,file = 'stress' //trim(adjustl(nrloadcase))//'-'//trim(adjustl(nrstep))//'-'//trim(adjustl(nriter))//'_cpfem.msh')
! open(588,file = 'logstrain'//trim(adjustl(nrloadcase))//'-'//trim(adjustl(nrstep))//'-'//trim(adjustl(nriter))//'_cpfem.msh')
! write(589, '(4(A, /), I10)'), '$MeshFormat', '2.1 0 8', '$EndMeshFormat', '$Nodes', prodnn
! write(588, '(4(A, /), I10)'), '$MeshFormat', '2.1 0 8', '$EndMeshFormat', '$Nodes', prodnn
! ielem = 0_pInt
! do k = 1, resolution(3); do j = 1, resolution(2); do i = 1, resolution(1)
! ielem = ielem + 1
! write(589, '(I10, 3(tr2, E12.6))'), ielem, displacement(i,j,k,:) !for deformed configuration
! write(588, '(I10, 3(tr2, E12.6))'), ielem, displacement(i,j,k,:)
!! write(589, '(4(I10,tr2))'), ielem, i-1,j-1,k-1 !for undeformed configuration
!!write(588, '(4(I10,tr2))'), ielem, i-1,j-1,k-1
! enddo; enddo; enddo
! write(589, '(2(A, /), I10)'), '$EndNodes', '$Elements', prodnn
! write(588, '(2(A, /), I10)'), '$EndNodes', '$Elements', prodnn
! do i = 1, prodnn
! write(589, '(I10, A, I10)'), i, ' 15 2 1 2', i
! write(588, '(I10, A, I10)'), i, ' 15 2 1 2', i
! enddo
! write(589, '(A)'), '$EndElements'
! write(588, '(A)'), '$EndElements'
! write(589, '(8(A, /), I10)'), '$NodeData', '1','"'//trim(adjustl('stress'//trim(adjustl(nrloadcase))//'-'//&
! trim(adjustl(nrstep))//'-'//trim(adjustl(nriter))//'_cpfem.msh'))//'"','1','0.0', '3', '0', '9', prodnn
! write(588, '(8(A, /), I10)'), '$NodeData', '1','"'//trim(adjustl('logstrain'//trim(adjustl(nrloadcase))//'-'//&
! trim(adjustl(nrstep))//'-'//trim(adjustl(nriter))//'_cpfem.msh'))//'"','1','0.0', '3', '0', '9', prodnn
! ielem = 0_pInt
! do k = 1, resolution(3); do j = 1, resolution(2); do i = 1, resolution(1)
! ielem = ielem + 1
! write(589, '(i10, 9(tr2, E14.8))'), ielem, cstress_field(i,j,k,:,:)
! call math_pDecomposition(defgrad(i,j,k,:,:),temp33_Real2,temp33_Real,errmatinv) !store R in temp33_Real
! call math_invert3x3(temp33_Real, temp33_Real2, determinant, errmatinv) !inverse of R in temp33_Real2
! temp33_Real = math_mul33x33(defgrad(i,j,k,:,:), temp33_Real2) ! v = F o inv(R), store in temp33_Real
! call math_spectral1(temp33_Real,Eigenvalue(1), Eigenvalue(2), Eigenvalue(3),&
! Eigenvectorbasis(1,:,:),Eigenvectorbasis(2,:,:),Eigenvectorbasis(3,:,:))
! eigenvalue = log(sqrt(eigenvalue))
! temp33_Real = eigenvalue(1)*Eigenvectorbasis(1,:,:)+eigenvalue(2)*Eigenvectorbasis(2,:,:)+eigenvalue(3)*Eigenvectorbasis(3,:,:)
! write(588, '(i10, 9(tr2, E14.8))'), ielem, temp33_Real
! enddo; enddo; enddo
! write(589, *), '$EndNodeData'
! write(588, *), '$EndNodeData'
! close(589); close(588); close(540)
! enddo ! end looping over steps in current loadcase
! enddo ! end looping over loadcases
! close(539); close(538)

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@ -1,100 +1,115 @@
#!/usr/bin/python
# -*- coding: iso-8859-1 -*-
# This script is used for the post processing of the results achieved by the spectral method.
# As it reads in the data coming from "materialpoint_results", it can be adopted to the data
# computed using the FEM solvers. Until now, its capable to handle elements with one IP in a regular order
# written by M. Diehl, m.diehl@mpie.de
import array
import struct
#import numpy
print('post processing for mpie_spectral')
import numpy
import reconstruct
filename ='results.out'
results = open(filename, 'rb')
print('filename:', filename)
position=0
#this funtion finds a string value in the given file for a given keyword, also returns the position
def searchNameForKeyword(searchstring, file):
file.seek(0,0)
begin = file.read(2048).find(searchstring) + len(searchstring) # function will return -1 if string is not found
file.seek(begin -len(searchstring) -4) # position of header (Fortran specific, 4 bit long on msuws4
header = file.read(4) # store header. header will be repeated, thus it allows us to determine the length of the searchstring
file.seek(begin,0) # go back to starting postion
length = file.read(2048).find(header) # find header(footer) a second time
file.seek(begin,0)
return file.read(length), results.tell() # return searchstring and maximum position in file
#this funtion finds a string value in the given file for a given keyword
def searchNameForKeyword(searchstring, file, maxpos):
#this funtion finds an integer value in the given file for a given keyword, works similar as "searchNameForKeyword"
def searchValueForKeyword(searchstring, file):
results.seek(0,0)
begin = file.read(2048).find(searchstring) + len(searchstring) # function will return -1 if string isnt found
file.seek(begin -len(searchstring) -4) #position of header
header = file.read(4) #store header
begin = file.read(2048).find(searchstring) + len(searchstring)
file.seek(begin,0)
length = file.read(2048).find(header)
file.seek(begin,0)
name = file.read(length)
return name, max(maxpos,results.tell())
#this funtion finds an integer value in the given file for a given keyword
def searchValueForKeyword(searchstring, file, maxpos):
results.seek(0,0)
begin = file.read(2048).find(searchstring) + len(searchstring) # function will return -1 if string isnt found
file.seek(begin,0)
value = array.array('i',[0])
value = struct.unpack('i',results.read(4))[0]
return value, max(maxpos,results.tell())
return value, results.tell()
#finds the value for the three integers followed the given keyword
def searchArrayForKeyword(searchstring, file, maxpos):
values = array.array('i',[0,0,0])
results.seek(0,0)
begin = results.read(2048).find(searchstring) + len(searchstring) #end position of string "resolution"
pos = results.read(60).find(b'a')
results.seek(begin+pos+2,0) #why two, not 1??
values[0]=struct.unpack('i',results.read(4))[0]
maxpos=max(maxpos,results.tell())
results.seek(begin,0)
pos = results.read(60).find(b'b')
results.seek(begin+pos+1,0)
values[1]=struct.unpack('i',results.read(4))[0]
maxpos=max(maxpos,results.tell())
results.seek(begin,0)
pos = results.read(60).find(b'c')
results.seek(begin+pos+1,0)
values[2]=struct.unpack('i',results.read(4))[0]
maxpos=max(maxpos,results.tell())
return values, maxpos
#finds the value for the three integers (a,b,c) following the given keyword
def searchIntegerArrayForKeyword(searchstring, file):
values = array.array('i',[0,0,0])
file.seek(0,0)
begin = file.read(2048).find(searchstring) + len(searchstring) #end position of string "searchstring"
pos = file.read(60).find('a')
file.seek(begin+pos+2,0) #why 2, not 1??
values[0]=struct.unpack('i',file.read(4))[0]
maxpos=file.tell()
file.seek(begin,0)
pos = file.read(60).find('b')
file.seek(begin+pos+1,0)
values[1]=struct.unpack('i',file.read(4))[0]
maxpos = max(maxpos,file.tell())
file.seek(begin,0)
pos = file.read(60).find('c')
file.seek(begin+pos+1,0)
values[2]=struct.unpack('i',file.read(4))[0]
maxpos=max(maxpos,file.tell())
return values, maxpos
#finds the value for the three doubles followed the given keyword
def searchFarrayForKeyword(searchstring, file, maxpos):
values = array.array('d',[0,0,0])
results.seek(0,0)
begin = results.read(2048).find(searchstring) + len(searchstring) #end position of string "resolution"
pos = results.read(60).find(b'x')
results.seek(begin+pos+2,0) #why two, not 1??
values[0]=struct.unpack('d',results.read(8))[0]
maxpos=max(maxpos,results.tell())
results.seek(begin,0)
pos = results.read(60).find(b'y')
results.seek(begin+pos+1,0)
values[1]=struct.unpack('d',results.read(8))[0]
maxpos=max(maxpos,results.tell())
results.seek(begin,0)
pos = results.read(60).find(b'z')
results.seek(begin+pos+1,0)
values[2]=struct.unpack('d',results.read(8))[0]
maxpos=max(maxpos,results.tell())
return values, maxpos
#finds the value for the three doubles (x,y,z) following the given keyword
def searchDoubleArrayForKeyword(searchstring, file):
values = array.array('d',[0,0,0])
file.seek(0,0)
begin = file.read(2048).find(searchstring) + len(searchstring)
pos = file.read(60).find('x')
file.seek(begin+pos+2,0)
values[0]=struct.unpack('d',file.read(8))[0]
maxpos=file.tell()
file.seek(begin,0)
pos = file.read(60).find('y')
file.seek(begin+pos+1,0)
values[1] = struct.unpack('d',file.read(8))[0]
maxpos = max(maxpos,file.tell())
file.seek(begin,0)
pos = file.read(60).find('z')
file.seek(begin+pos+1,0)
values[2] = struct.unpack('d',file.read(8))[0]
maxpos = max(maxpos,file.tell())
return values, maxpos
print '*********************************************************************************'
print 'Post Processing for Material subroutine for BVP solution using spectral method'
print '*********************************************************************************\n'
loadcase, position = searchNameForKeyword(b'Loadcase ', results, position)
workingdir, position = searchNameForKeyword(b'Workingdir ', results, position)
jobname, position = searchNameForKeyword(b'JobName ', results, position)
totalincs, position = searchValueForKeyword(b'totalincs ', results, position)
materialpoint_sizeResults, position = searchValueForKeyword(b'materialpoint_sizeResults ', results, position)
resolution, position = searchArrayForKeyword(b'resolution ', results, position)
geomdimension, position = searchFarrayForKeyword(b'geomdimension ', results, position)
position=position+4 +13*8
results.seek(position,0)
tnsr = array.array('d',[0,0,0,0,0,0,0,0,0])
tnsr[0]=struct.unpack('d',results.read(8))[0]
tnsr[1]=struct.unpack('d',results.read(8))[0]
tnsr[2]=struct.unpack('d',results.read(8))[0]
tnsr[3]=struct.unpack('d',results.read(8))[0]
tnsr[4]=struct.unpack('d',results.read(8))[0]
print(tnsr)
#reading in the header of the results file
filename ='32x32x32x100.out'
print 'Results Filename:', filename
results = open(filename, 'rb')
loadcase, position = searchNameForKeyword('Loadcase', results)
workingdir, temp = searchNameForKeyword('Workingdir', results)
position = max(temp, position)
jobname, temp = searchNameForKeyword('JobName', results)
position = max(temp, position)
totalincs, temp = searchValueForKeyword('totalincs', results)
position = max(temp, position)
materialpoint_sizeResults, temp = searchValueForKeyword('materialpoint_sizeResults', results)
position = max(temp, position)
resolution, temp = searchIntegerArrayForKeyword('resolution', results)
position = max(temp, position)
geomdimension, temp = searchDoubleArrayForKeyword('geomdimension', results)
print 'Load case:', loadcase
print 'Workingdir:', workingdir
print 'Job Name:', jobname
print 'Total No. of Increments:', totalincs
print 'Materialpoint_sizeResults:', materialpoint_sizeResults
print 'Resolution:', resolution
print 'Geomdimension', geomdimension
print 'Position in File:', position
# Ended reading of header
# Now starting to read information concerning output of materialpoint_results(:,1,:)
filename = jobname[0:len(jobname)-5]+'.outputCrystallite'
outputCrystallite = open(filename, 'r')
# ended reading of header. now starting to read information concerning output
#filename = jobname[0:len(jobname)-5]+b'.outputCrystallite'
#outputCrystallite = open(filename, 'r')
# some funtions that might be useful
def InCharCount(location, character):
subj = file(location, "r")
body = subj.read()

View File

@ -18,7 +18,7 @@ program voronoi
print*, '******************************************************************************'
print*, ''
print*, 'generates:'
print*, ' * mesh file "_GIVEN_NAME_.mesh": Geometrical information for solver'
print*, ' * geom file "_GIVEN_NAME_.geom": Geometrical information for solver'
print*, ' * material file "material.config": Orientation information for solver'
print*, ' * "_GIVEN_NAME_.spectral": combined information for solver'
print*, 'optional output:'
@ -37,7 +37,7 @@ program voronoi
read(*, *), c
write(*, '(A)', advance = 'NO') 'Please enter No. of Grains: '
read(*, *), N_Seeds
write(*, '(A)', advance = 'NO') 'Please enter name of mesh file: '
write(*, '(A)', advance = 'NO') 'Please enter name of geometry file: '
read(*, *), name
write(*, '(A)', advance = 'NO') 'Should the visualization files be generated (y/n)? '
read(*, *), choice
@ -55,7 +55,7 @@ program voronoi
format2 = '(A, I'//trim(N_Digits)//', A)'
do i = 1, N_Seeds
write(20, trim(format)), '[Grain', i, ']'
write(20, '(A)'), 'crystallite 1'
write(20, '(A)'), 'crystallite 1'
write(20, trim(format2)), '(constituent) phase 1 texture ', i, ' fraction 1.0'
end do
@ -77,8 +77,8 @@ program voronoi
print*, ''
print*, 'material config file is written out'
!write header of mesh file, should be done before the following change of variables
open(20, file = ((trim(name))//'.mesh'))
!write header of geom file, should be done before the following change of variables
open(20, file = ((trim(name))//'.geom'))
write(20, '(A, I2, A, I2, A, I2)'), 'resolution a ', 2**a, ' b ', 2**b, ' c ', 2**c
write(20, '(A, I4, A, I4, A, I4)'), 'dimension x ', 2**a, ' y ', 2**b, ' z ', 2**c
write(20, '(A)'), 'homogenization 1'
@ -163,16 +163,16 @@ program voronoi
do i = 1, abc
j = grainMap(i)
write(20, trim(format)), grainEuler(j*3-2), grainEuler(j*3-1), grainEuler(j*3), &
&mod((i-1), a)+1, mod(((i-1)/a), b)+1, mod(((i-1)/(ab)), c)+1, &
&j, ' 1'
&mod((i-1), a)+1, mod(((i-1)/a), b)+1, mod(((i-1)/(ab)), c)+1, &
&j, ' 1'
end do
print*, 'mesh files are written out'
print*, 'geometry files are written out'
!write visualization files (in case wanted)
if (choice == 'y' .or. choice == 'Y') then
print*, 'for more information on gmsh: http://geuz.org/gmsh/'
! write full mesh out
! write full geometry out
open(20, file = ((trim(name))//'_3Dfull.msh'))
write(20, '(A, /, A, /, A, /, A, /, I10)'), '$MeshFormat', '2.1 0 8', '$EndMeshFormat', '$Nodes', abc
do i = 1, abc
@ -213,7 +213,7 @@ program voronoi
write(20, *), '$EndNodeData'
close(20)
! write 2d mesh out
! write 2d geometry out
open(20, file = ((trim(name))//'_2D.msh'))
write(20, '(A, /, A, /, A, /, A, /, I10)'), '$MeshFormat', '2.1 0 8', '$EndMeshFormat', '$Nodes', ab
do i = 1, ab

View File

@ -18,7 +18,7 @@ program voronoi
print*, '******************************************************************************'
print*, ''
print*, 'generates:'
print*, ' * mesh file "_GIVEN_NAME_.mesh": Geometrical information for solver'
print*, ' * geometry file "_GIVEN_NAME_.geom": Geometrical information for solver'
print*, ' * material file "material.config": Orientation information for solver'
print*, 'optional output:'
print*, ' * view file "_GIVEN_NAME_2D.msh": Information for visualization in gmsh'
@ -36,7 +36,7 @@ program voronoi
read(*, *), c
write(*, '(A)', advance = 'NO') 'Please enter No. of Grains: '
read(*, *), N_Seeds
write(*, '(A)', advance = 'NO') 'Please enter name of mesh file: '
write(*, '(A)', advance = 'NO') 'Please enter name of geometry file: '
read(*, *), name
write(*, '(A)', advance = 'NO') 'Should the visualization files be generated (y/n)? '
read(*, *), choice
@ -53,7 +53,7 @@ program voronoi
format2 = '(A, I'//trim(N_Digits)//', A)'
do i = 1, N_Seeds
write(20, trim(format)), '[Grain', i, ']'
write(20, '(A)'), 'crystallite 1'
write(20, '(A)'), 'crystallite 1'
write(20, trim(format2)), '(constituent) phase 1 texture ', i, ' fraction 1.0'
end do
@ -75,8 +75,8 @@ program voronoi
print*, ''
print*, 'material config file is written out'
!write header of mesh file, should be done before the following change of variables
open(20, file = ((trim(name))//'.mesh'))
!write header of geometry file, should be done before the following change of variables
open(20, file = ((trim(name))//'.geom'))
write(20, '(A, I2, A, I2, A, I2)'), 'resolution a ', 2**a, ' b ', 2**b, ' c ', 2**c
write(20, '(A, I4, A, I4, A, I4)'), 'dimension x ', 2**a, ' y ', 2**b, ' z ', 2**c
write(20, '(A)'), 'homogenization 1'
@ -128,8 +128,8 @@ program voronoi
coordinates(3) = mod(((seedpoint)/(ab)), c) +1
do j = 1, i
if((coordinates(1) == seedmap(j*3 -2)) .and. &
&(coordinates(2) == seedmap(j*3 -1)) .and. &
&(coordinates(3) == seedmap(j*3 -0))) seed = .true.
&(coordinates(2) == seedmap(j*3 -1)) .and. &
&(coordinates(3) == seedmap(j*3 -0))) seed = .true.
end do
if (.not.seed) then
seedmap(i*3 +1) = coordinates(1)
@ -168,13 +168,13 @@ program voronoi
end do
close(20)
print*, 'voronoi tesselation finished'
print*, 'mesh file is written out'
print*, 'geometry file is written out'
!write visualization files (in case wanted)
if (choice == 'y' .or. choice == 'Y') then
print*, 'for more information on gmsh: http://geuz.org/gmsh/'
! write full mesh out
! write full geometry out
open(20, file = ((trim(name))//'_3D.msh'))
write(20, '(A, /, A, /, A, /, A, /, I10)'), '$MeshFormat', '2.1 0 8', '$EndMeshFormat', '$Nodes', abc_Red
do j = 1, abc_Red
@ -194,7 +194,7 @@ program voronoi
write(20, *), '$EndNodeData'
close(20)
! write 2d mesh out
! write 2d geometry out
open(20, file = ((trim(name))//'_2D.msh'))
write(20, '(A, /, A, /, A, /, A, /, I10)'), '$MeshFormat', '2.1 0 8', '$EndMeshFormat', '$Nodes', ab
do i = 1, ab