more systematic name

src/homogenization.f90

@@ -250,8 +250,8 @@ subroutine homogenization_mechanical_response(Delta_t,cell_start,cell_end)
   !$OMP PARALLEL DO PRIVATE(en,ho,co,NiterationMPstate,converged,doneAndHappy)
   do ce = cell_start, cell_end
 
-    en = material_homogenizationEntry(ce)
-    ho = material_homogenizationID(ce)
+    en = material_entry_homogenization(ce)
+    ho = material_ID_homogenization(ce)
 
     call phase_restore(ce,.false.) ! wrong name (is more a forward function)
 
@@ -303,9 +303,9 @@ subroutine homogenization_thermal_response(Delta_t,cell_start,cell_end)
   !$OMP PARALLEL DO PRIVATE(ho)
   do ce = cell_start, cell_end
     if (terminallyIll) continue
-    ho = material_homogenizationID(ce)
+    ho = material_ID_homogenization(ce)
     do co = 1, homogenization_Nconstituents(ho)
-      if (.not. phase_thermal_constitutive(Delta_t,material_phaseID(co,ce),material_phaseEntry(co,ce))) then
+      if (.not. phase_thermal_constitutive(Delta_t,material_ID_phase(co,ce),material_entry_phase(co,ce))) then
         if (.not. terminallyIll) print*, ' Cell ', ce, ' terminally ill'
         terminallyIll = .true.
       end if
@@ -333,7 +333,7 @@ subroutine homogenization_mechanical_response2(Delta_t,FEsolving_execIP,FEsolvin
   elementLooping3: do el = FEsolving_execElem(1),FEsolving_execElem(2)
     IpLooping3: do ip = FEsolving_execIP(1),FEsolving_execIP(2)
       ce = (el-1)*discretization_nIPs + ip
-      ho = material_homogenizationID(ce)
+      ho = material_ID_homogenization(ce)
       do co = 1, homogenization_Nconstituents(ho)
         call crystallite_orientations(co,ip,el)
       end do

src/homogenization_damage.f90

@@ -47,7 +47,7 @@ module subroutine damage_init()
   allocate(current(configHomogenizations%length))
 
   do ho = 1, configHomogenizations%length
-    Nmembers = count(material_homogenizationID == ho)
+    Nmembers = count(material_ID_homogenization == ho)
     allocate(current(ho)%phi(Nmembers), source=1.0_pReal)
     configHomogenization => configHomogenizations%get_dict(ho)
     associate(prm => param(ho))
@@ -95,9 +95,9 @@ module subroutine damage_partition(ce)
   integer :: co
 
 
-  if (damageState_h(material_homogenizationID(ce))%sizeState < 1) return
-  phi = damagestate_h(material_homogenizationID(ce))%state(1,material_homogenizationEntry(ce))
-  do co = 1, homogenization_Nconstituents(material_homogenizationID(ce))
+  if (damageState_h(material_ID_homogenization(ce))%sizeState < 1) return
+  phi = damagestate_h(material_ID_homogenization(ce))%state(1,material_entry_homogenization(ce))
+  do co = 1, homogenization_Nconstituents(material_ID_homogenization(ce))
     call phase_set_phi(phi,co,ce)
   end do
 
@@ -161,8 +161,8 @@ module subroutine homogenization_set_phi(phi,ce)
     en
 
 
-  ho = material_homogenizationID(ce)
-  en = material_homogenizationEntry(ce)
+  ho = material_ID_homogenization(ce)
+  en = material_entry_homogenization(ce)
   damagestate_h(ho)%state(1,en) = phi
   current(ho)%phi(en) = phi
 

src/homogenization_mechanical.f90

@@ -99,10 +99,10 @@ module subroutine mechanical_partition(subF,ce)
     ce
 
   integer :: co
-  real(pReal), dimension (3,3,homogenization_Nconstituents(material_homogenizationID(ce))) :: Fs
+  real(pReal), dimension (3,3,homogenization_Nconstituents(material_ID_homogenization(ce))) :: Fs
 
 
-  chosenHomogenization: select case(mechanical_type(material_homogenizationID(ce)))
+  chosenHomogenization: select case(mechanical_type(material_ID_homogenization(ce)))
 
     case (MECHANICAL_PASS_ID) chosenHomogenization
       Fs(1:3,1:3,1) = subF
@@ -115,7 +115,7 @@ module subroutine mechanical_partition(subF,ce)
 
   end select chosenHomogenization
 
-  do co = 1,homogenization_Nconstituents(material_homogenizationID(ce))
+  do co = 1,homogenization_Nconstituents(material_ID_homogenization(ce))
     call phase_set_F(Fs(1:3,1:3,co),co,ce)
   end do
 
@@ -136,7 +136,7 @@ module subroutine mechanical_homogenize(Delta_t,ce)
 
   homogenization_P(1:3,1:3,ce)            = phase_P(1,ce)*material_v(1,ce)
   homogenization_dPdF(1:3,1:3,1:3,1:3,ce) = phase_mechanical_dPdF(Delta_t,1,ce)*material_v(1,ce)
-  do co = 2, homogenization_Nconstituents(material_homogenizationID(ce))
+  do co = 2, homogenization_Nconstituents(material_ID_homogenization(ce))
     homogenization_P(1:3,1:3,ce)            = homogenization_P(1:3,1:3,ce) &
                                             + phase_P(co,ce)*material_v(co,ce)
     homogenization_dPdF(1:3,1:3,1:3,1:3,ce) = homogenization_dPdF(1:3,1:3,1:3,1:3,ce) &
@@ -161,13 +161,13 @@ module function mechanical_updateState(subdt,subF,ce) result(doneAndHappy)
   logical, dimension(2) :: doneAndHappy
 
   integer :: co
-  real(pReal) :: dPdFs(3,3,3,3,homogenization_Nconstituents(material_homogenizationID(ce)))
-  real(pReal) :: Fs(3,3,homogenization_Nconstituents(material_homogenizationID(ce)))
-  real(pReal) :: Ps(3,3,homogenization_Nconstituents(material_homogenizationID(ce)))
+  real(pReal) :: dPdFs(3,3,3,3,homogenization_Nconstituents(material_ID_homogenization(ce)))
+  real(pReal) :: Fs(3,3,homogenization_Nconstituents(material_ID_homogenization(ce)))
+  real(pReal) :: Ps(3,3,homogenization_Nconstituents(material_ID_homogenization(ce)))
 
 
-  if (mechanical_type(material_homogenizationID(ce)) == MECHANICAL_RGC_ID) then
-      do co = 1, homogenization_Nconstituents(material_homogenizationID(ce))
+  if (mechanical_type(material_ID_homogenization(ce)) == MECHANICAL_RGC_ID) then
+      do co = 1, homogenization_Nconstituents(material_ID_homogenization(ce))
         dPdFs(:,:,:,:,co) = phase_mechanical_dPdF(subdt,co,ce)
         Fs(:,:,co)        = phase_F(co,ce)
         Ps(:,:,co)        = phase_P(co,ce)

src/homogenization_mechanical_RGC.f90

@@ -162,7 +162,7 @@ module subroutine RGC_init()
     prm%D_alpha  = homogMech%get_as1dFloat('D_alpha', requiredSize=3)
     prm%a_g      = homogMech%get_as1dFloat('a_g',     requiredSize=3)
 
-    Nmembers = count(material_homogenizationID == ho)
+    Nmembers = count(material_ID_homogenization == ho)
     nIntFaceTot = 3*(  (prm%N_constituents(1)-1)*prm%N_constituents(2)*prm%N_constituents(3) &
                       + prm%N_constituents(1)*(prm%N_constituents(2)-1)*prm%N_constituents(3) &
                       + prm%N_constituents(1)*prm%N_constituents(2)*(prm%N_constituents(3)-1))
@@ -208,10 +208,10 @@ module subroutine RGC_partitionDeformation(F,avgF,ce)
   integer,     dimension(3) :: iGrain3
   integer ::  iGrain,iFace,i,j,ho,en
 
-  associate(prm => param(material_homogenizationID(ce)))
+  associate(prm => param(material_ID_homogenization(ce)))
 
-  ho = material_homogenizationID(ce)
-  en = material_homogenizationEntry(ce)
+  ho = material_ID_homogenization(ce)
+  en = material_entry_homogenization(ce)
 !--------------------------------------------------------------------------------------------------
 ! compute the deformation gradient of individual grains due to relaxations
   F = 0.0_pReal
@@ -263,8 +263,8 @@ module function RGC_updateState(P,F,avgF,dt,dPdF,ce) result(doneAndHappy)
     return
   end if zeroTimeStep
 
-  ho  = material_homogenizationID(ce)
-  en = material_homogenizationEntry(ce)
+  ho  = material_ID_homogenization(ce)
+  en = material_entry_homogenization(ce)
 
   associate(stt => state(ho), st0 => state0(ho), dst => dependentState(ho), prm => param(ho))
 
@@ -652,7 +652,7 @@ module function RGC_updateState(P,F,avgF,dt,dPdF,ce) result(doneAndHappy)
 
     real(pReal), dimension(6,6) :: C
 
-    C = phase_homogenizedC66(material_phaseID(co,ce),material_phaseEntry(co,ce))                    ! damage not included!
+    C = phase_homogenizedC66(material_ID_phase(co,ce),material_entry_phase(co,ce))                  ! damage not included!
 
     equivalentMu = lattice_isotropic_mu(C,'isostrain')
 

src/homogenization_mechanical_isostrain.f90

@@ -25,7 +25,7 @@ module subroutine isostrain_init
   do ho = 1, size(mechanical_type)
     if (mechanical_type(ho) /= MECHANICAL_ISOSTRAIN_ID) cycle
 
-    Nmembers = count(material_homogenizationID == ho)
+    Nmembers = count(material_ID_homogenization == ho)
     homogState(ho)%sizeState = 0
     allocate(homogState(ho)%state0(0,Nmembers))
     allocate(homogState(ho)%state (0,Nmembers))

src/homogenization_mechanical_pass.f90

@@ -28,7 +28,7 @@ module subroutine pass_init()
     if (homogenization_Nconstituents(ho) /= 1) &
       call IO_error(211,ext_msg='(pass) with N_constituents !=1')
 
-    Nmembers = count(material_homogenizationID == ho)
+    Nmembers = count(material_ID_homogenization == ho)
     homogState(ho)%sizeState = 0
     allocate(homogState(ho)%state0(0,Nmembers))
     allocate(homogState(ho)%state (0,Nmembers))

src/homogenization_thermal.f90

@@ -50,8 +50,8 @@ module subroutine thermal_init()
   allocate(current(configHomogenizations%length))
 
   do ho = 1, configHomogenizations%length
-    allocate(current(ho)%T(count(material_homogenizationID==ho)), source=T_ROOM)
-    allocate(current(ho)%dot_T(count(material_homogenizationID==ho)), source=0.0_pReal)
+    allocate(current(ho)%T(count(material_ID_homogenization==ho)), source=T_ROOM)
+    allocate(current(ho)%dot_T(count(material_ID_homogenization==ho)), source=0.0_pReal)
     configHomogenization => configHomogenizations%get_dict(ho)
     associate(prm => param(ho))
 
@@ -104,9 +104,9 @@ module subroutine thermal_partition(ce)
   integer :: co
 
 
-  T     = current(material_homogenizationID(ce))%T(material_homogenizationEntry(ce))
-  dot_T = current(material_homogenizationID(ce))%dot_T(material_homogenizationEntry(ce))
-  do co = 1, homogenization_Nconstituents(material_homogenizationID(ce))
+  T     = current(material_ID_homogenization(ce))%T(material_entry_homogenization(ce))
+  dot_T = current(material_ID_homogenization(ce))%dot_T(material_entry_homogenization(ce))
+  do co = 1, homogenization_Nconstituents(material_ID_homogenization(ce))
     call phase_thermal_setField(T,dot_T,co,ce)
   end do
 
@@ -125,7 +125,7 @@ module function homogenization_mu_T(ce) result(mu)
 
 
   mu = phase_mu_T(1,ce)*material_v(1,ce)
-  do co = 2, homogenization_Nconstituents(material_homogenizationID(ce))
+  do co = 2, homogenization_Nconstituents(material_ID_homogenization(ce))
     mu = mu + phase_mu_T(co,ce)*material_v(co,ce)
   end do
 
@@ -144,7 +144,7 @@ module function homogenization_K_T(ce) result(K)
 
 
   K = phase_K_T(1,ce)*material_v(1,ce)
-  do co = 2, homogenization_Nconstituents(material_homogenizationID(ce))
+  do co = 2, homogenization_Nconstituents(material_ID_homogenization(ce))
     K = K + phase_K_T(co,ce)*material_v(co,ce)
   end do
 
@@ -162,9 +162,9 @@ module function homogenization_f_T(ce) result(f)
   integer :: co
 
 
-  f = phase_f_T(material_phaseID(1,ce),material_phaseEntry(1,ce))*material_v(1,ce)
-  do co = 2, homogenization_Nconstituents(material_homogenizationID(ce))
-    f = f + phase_f_T(material_phaseID(co,ce),material_phaseEntry(co,ce))*material_v(co,ce)
+  f = phase_f_T(material_ID_phase(1,ce),material_entry_phase(1,ce))*material_v(1,ce)
+  do co = 2, homogenization_Nconstituents(material_ID_homogenization(ce))
+    f = f + phase_f_T(material_ID_phase(co,ce),material_entry_phase(co,ce))*material_v(co,ce)
   end do
 
 end function homogenization_f_T
@@ -179,8 +179,8 @@ module subroutine homogenization_thermal_setField(T,dot_T, ce)
   real(pReal), intent(in) :: T, dot_T
 
 
-  current(material_homogenizationID(ce))%T(material_homogenizationEntry(ce)) = T
-  current(material_homogenizationID(ce))%dot_T(material_homogenizationEntry(ce)) = dot_T
+  current(material_ID_homogenization(ce))%T(material_entry_homogenization(ce)) = T
+  current(material_ID_homogenization(ce))%dot_T(material_entry_homogenization(ce)) = dot_T
   call thermal_partition(ce)
 
 end subroutine homogenization_thermal_setField

src/material.f90

@@ -39,11 +39,11 @@ module material
     material_name_homogenization                                                                    !< name of each homogenization
 
   integer, dimension(:),   allocatable, public, protected :: &                                      ! (cell)
-    material_homogenizationID, &                                                                    ! TODO: rename to material_ID_homogenization
-    material_homogenizationEntry                                                                    ! TODO: rename to material_entry_homogenization
+    material_ID_homogenization, &                                                                   !< Number of the homogenization
+    material_entry_homogenization                                                                   !< Position in array of used homogenization
   integer, dimension(:,:), allocatable, public, protected :: &                                      ! (constituent,cell)
-    material_phaseID, &                                                                             ! TODO: rename to material_ID_phase
-    material_phaseEntry                                                                             ! TODO: rename to material_entry_phase
+    material_ID_phase, &                                                                            !< Number of the phase
+    material_entry_phase                                                                            !< Position in array of used phase
 
   real(pReal), dimension(:,:), allocatable, public, protected :: &
     material_v                                                                                      ! fraction
@@ -70,8 +70,8 @@ subroutine material_init(restart)
 
   if (.not. restart) then
     call result_openJobFile
-    call result_mapping_phase(material_phaseID,material_phaseEntry,material_name_phase)
-    call result_mapping_homogenization(material_homogenizationID,material_homogenizationEntry,material_name_homogenization)
+    call result_mapping_phase(material_ID_phase,material_entry_phase,material_name_phase)
+    call result_mapping_homogenization(material_ID_homogenization,material_entry_homogenization,material_name_homogenization)
     call result_closeJobFile
   end if
 
@@ -166,11 +166,11 @@ subroutine parse()
   allocate(counterPhase(phases%length),source=0)
   allocate(counterHomogenization(homogenizations%length),source=0)
 
-  allocate(material_homogenizationID(discretization_Ncells),source=0)
-  allocate(material_homogenizationEntry(discretization_Ncells),source=0)
+  allocate(material_ID_homogenization(discretization_Ncells),source=0)
+  allocate(material_entry_homogenization(discretization_Ncells),source=0)
 
-  allocate(material_phaseID(homogenization_maxNconstituents,discretization_Ncells),source=0)
-  allocate(material_phaseEntry(homogenization_maxNconstituents,discretization_Ncells),source=0)
+  allocate(material_ID_phase(homogenization_maxNconstituents,discretization_Ncells),source=0)
+  allocate(material_entry_phase(homogenization_maxNconstituents,discretization_Ncells),source=0)
 
 
   ! build mappings
@@ -181,9 +181,9 @@ subroutine parse()
 
     do ip = 1, discretization_nIPs
       ce = (el-1)*discretization_nIPs + ip
-      material_homogenizationID(ce) = ho
+      material_ID_homogenization(ce) = ho
       counterHomogenization(ho) = counterHomogenization(ho) + 1
-      material_homogenizationEntry(ce) = counterHomogenization(ho)
+      material_entry_homogenization(ce) = counterHomogenization(ho)
     end do
 
     do co = 1, size(ph_of(ma,:)>0)
@@ -193,9 +193,9 @@ subroutine parse()
 
       do ip = 1, discretization_nIPs
         ce = (el-1)*discretization_nIPs + ip
-        material_phaseID(co,ce) = ph
+        material_ID_phase(co,ce) = ph
         counterPhase(ph) = counterPhase(ph) + 1
-        material_phaseEntry(co,ce) = counterPhase(ph)
+        material_entry_phase(co,ce) = counterPhase(ph)
         material_v(co,ce) = v
       end do
 

src/phase.f90

@@ -419,14 +419,14 @@ subroutine phase_init
     if (any(phase_lattice(ph) == ['hP','tI'])) &
       phase_cOverA(ph) = phase%get_asFloat('c/a')
     phase_rho(ph) = phase%get_asFloat('rho',defaultVal=0.0_pReal)
-    allocate(phase_O_0(ph)%data(count(material_phaseID==ph)))
+    allocate(phase_O_0(ph)%data(count(material_ID_phase==ph)))
   end do
 
-  do ce = 1, size(material_phaseID,2)
+  do ce = 1, size(material_ID_phase,2)
     ma = discretization_materialAt((ce-1)/discretization_nIPs+1)
-    do co = 1,homogenization_Nconstituents(material_homogenizationID(ce))
-      ph = material_phaseID(co,ce)
-      phase_O_0(ph)%data(material_phaseEntry(co,ce)) = material_O_0(ma)%data(co)
+    do co = 1,homogenization_Nconstituents(material_ID_homogenization(ce))
+      ph = material_ID_phase(co,ce)
+      phase_O_0(ph)%data(material_entry_phase(co,ce)) = material_O_0(ma)%data(co)
     end do
   end do
 
@@ -586,9 +586,9 @@ subroutine crystallite_init()
   do el = 1, discretization_Nelems
     do ip = 1, discretization_nIPs
       ce = (el-1)*discretization_nIPs + ip
-      do co = 1,homogenization_Nconstituents(material_homogenizationID(ce))
-        en = material_phaseEntry(co,ce)
-        ph = material_phaseID(co,ce)
+      do co = 1,homogenization_Nconstituents(material_ID_homogenization(ce))
+        en = material_entry_phase(co,ce)
+        ph = material_ID_phase(co,ce)
         call crystallite_orientations(co,ip,el)
         call plastic_dependentState(ph,en)                                                          ! update dependent state variables to be consistent with basic states
      end do
@@ -613,13 +613,13 @@ subroutine crystallite_orientations(co,ip,el)
   integer :: ph, en
 
 
-  ph = material_phaseID(co,(el-1)*discretization_nIPs + ip)
-  en = material_phaseEntry(co,(el-1)*discretization_nIPs + ip)
+  ph = material_ID_phase(co,(el-1)*discretization_nIPs + ip)
+  en = material_entry_phase(co,(el-1)*discretization_nIPs + ip)
 
   call phase_O(ph)%data(en)%fromMatrix(transpose(math_rotationalPart(mechanical_F_e(ph,en))))
 
-  if (plasticState(material_phaseID(1,(el-1)*discretization_nIPs + ip))%nonlocal) &
-    call plastic_nonlocal_updateCompatibility(phase_O,material_phaseID(1,(el-1)*discretization_nIPs + ip),ip,el)
+  if (plasticState(material_ID_phase(1,(el-1)*discretization_nIPs + ip))%nonlocal) &
+    call plastic_nonlocal_updateCompatibility(phase_O,material_ID_phase(1,(el-1)*discretization_nIPs + ip),ip,el)
 
 
 end subroutine crystallite_orientations
@@ -640,8 +640,8 @@ function crystallite_push33ToRef(co,ce, tensor33)
   integer :: ph, en
 
 
-  ph = material_phaseID(co,ce)
-  en = material_phaseEntry(co,ce)
+  ph = material_ID_phase(co,ce)
+  en = material_entry_phase(co,ce)
   T = matmul(phase_O_0(ph)%data(en)%asMatrix(),transpose(math_inv33(phase_F(co,ce))))               ! ToDo: initial orientation correct?
 
   crystallite_push33ToRef = matmul(transpose(T),matmul(tensor33,T))

src/phase_damage.f90

@@ -96,7 +96,7 @@ module subroutine damage_init()
   damage_active = .false.
   do ph = 1,phases%length
 
-    Nmembers = count(material_phaseID == ph)
+    Nmembers = count(material_ID_phase == ph)
 
     allocate(current(ph)%phi(Nmembers),source=1.0_pReal)
 
@@ -137,8 +137,8 @@ module function phase_damage_constitutive(Delta_t,co,ce) result(converged_)
     ph, en
 
 
-  ph = material_phaseID(co,ce)
-  en = material_phaseEntry(co,ce)
+  ph = material_ID_phase(co,ce)
+  en = material_entry_phase(co,ce)
 
   converged_ = .not. integrateDamageState(Delta_t,ph,en)
 
@@ -176,10 +176,10 @@ module subroutine damage_restore(ce)
     co
 
 
-  do co = 1,homogenization_Nconstituents(material_homogenizationID(ce))
-    if (damageState(material_phaseID(co,ce))%sizeState > 0) &
-    damageState(material_phaseID(co,ce))%state( :,material_phaseEntry(co,ce)) = &
-      damageState(material_phaseID(co,ce))%state0(:,material_phaseEntry(co,ce))
+  do co = 1,homogenization_Nconstituents(material_ID_homogenization(ce))
+    if (damageState(material_ID_phase(co,ce))%sizeState > 0) &
+    damageState(material_ID_phase(co,ce))%state( :,material_entry_phase(co,ce)) = &
+      damageState(material_ID_phase(co,ce))%state0(:,material_entry_phase(co,ce))
   end do
 
 end subroutine damage_restore
@@ -200,8 +200,8 @@ module function phase_f_phi(phi,co,ce) result(f)
     ph, &
     en
 
-  ph = material_phaseID(co,ce)
-  en = material_phaseEntry(co,ce)
+  ph = material_ID_phase(co,ce)
+  en = material_entry_phase(co,ce)
 
   select case(phase_damage(ph))
     case(DAMAGE_ISOBRITTLE_ID,DAMAGE_ANISOBRITTLE_ID)
@@ -400,7 +400,7 @@ module function phase_mu_phi(co,ce) result(mu)
   real(pReal) :: mu
 
 
-  mu = param(material_phaseID(co,ce))%mu
+  mu = param(material_ID_phase(co,ce))%mu
 
 end function phase_mu_phi
 
@@ -414,7 +414,7 @@ module function phase_K_phi(co,ce) result(K)
   real(pReal), dimension(3,3) :: K
 
 
-  K = crystallite_push33ToRef(co,ce,param(material_phaseID(co,ce))%l_c**2*math_I3)
+  K = crystallite_push33ToRef(co,ce,param(material_ID_phase(co,ce))%l_c**2*math_I3)
 
 end function phase_K_phi
 
@@ -498,7 +498,7 @@ module subroutine phase_set_phi(phi,co,ce)
   integer, intent(in) :: ce, co
 
 
-  current(material_phaseID(co,ce))%phi(material_phaseEntry(co,ce)) = phi
+  current(material_ID_phase(co,ce))%phi(material_entry_phase(co,ce)) = phi
 
 end subroutine phase_set_phi
 

src/phase_damage_anisobrittle.f90

@@ -89,7 +89,7 @@ module function anisobrittle_init() result(mySources)
         if (any(prm%g_crit <  0.0_pReal)) extmsg = trim(extmsg)//' g_crit'
         if (any(prm%s_crit <  0.0_pReal)) extmsg = trim(extmsg)//' s_crit'
 
-        Nmembers = count(material_phaseID==ph)
+        Nmembers = count(material_ID_phase==ph)
         call phase_allocateState(damageState(ph),Nmembers,1,1,0)
         damageState(ph)%atol = src%get_asFloat('atol_phi',defaultVal=1.0e-9_pReal)
         if (any(damageState(ph)%atol < 0.0_pReal)) extmsg = trim(extmsg)//' atol_phi'

src/phase_damage_isobrittle.f90

@@ -73,7 +73,7 @@ module function isobrittle_init() result(mySources)
         ! sanity checks
         if (prm%W_crit <= 0.0_pReal) extmsg = trim(extmsg)//' W_crit'
 
-        Nmembers = count(material_phaseID==ph)
+        Nmembers = count(material_ID_phase==ph)
         call phase_allocateState(damageState(ph),Nmembers,1,0,1)
         damageState(ph)%atol = src%get_asFloat('atol_phi',defaultVal=1.0e-9_pReal)
         if (any(damageState(ph)%atol < 0.0_pReal)) extmsg = trim(extmsg)//' atol_phi'

src/phase_mechanical.f90

@@ -237,7 +237,7 @@ module subroutine mechanical_init(phases)
   allocate(phase_mechanical_S0(phases%length))
 
   do ph = 1, phases%length
-    Nmembers = count(material_phaseID == ph)
+    Nmembers = count(material_ID_phase == ph)
 
     allocate(phase_mechanical_Fe(ph)%data(3,3,Nmembers))
     allocate(phase_mechanical_Fi(ph)%data(3,3,Nmembers))
@@ -260,11 +260,11 @@ module subroutine mechanical_init(phases)
 #endif
   end do
 
-  do ce = 1, size(material_phaseID,2)
+  do ce = 1, size(material_ID_phase,2)
     ma = discretization_materialAt((ce-1)/discretization_nIPs+1)
-    do co = 1,homogenization_Nconstituents(material_homogenizationID(ce))
-      ph = material_phaseID(co,ce)
-      en = material_phaseEntry(co,ce)
+    do co = 1,homogenization_Nconstituents(material_ID_homogenization(ce))
+      ph = material_ID_phase(co,ce)
+      en = material_entry_phase(co,ce)
       phase_mechanical_F(ph)%data(1:3,1:3,en)  = math_I3
       phase_mechanical_Fp(ph)%data(1:3,1:3,en) = material_O_0(ma)%data(co)%asMatrix()              ! Fp reflects initial orientation (see 10.1016/j.actamat.2006.01.005)
       phase_mechanical_Fe(ph)%data(1:3,1:3,en) = matmul(material_V_e_0(ma)%data(1:3,1:3,co), &
@@ -1005,11 +1005,11 @@ module function phase_mechanical_constitutive(Delta_t,co,ce) result(converged_)
     subLi0, &
     subF0, &
     subF
-  real(pReal), dimension(plasticState(material_phaseID(co,ce))%sizeState) :: subState0
+  real(pReal), dimension(plasticState(material_ID_phase(co,ce))%sizeState) :: subState0
 
 
-  ph = material_phaseID(co,ce)
-  en = material_phaseEntry(co,ce)
+  ph = material_ID_phase(co,ce)
+  en = material_entry_phase(co,ce)
 
   subState0 = plasticState(ph)%state0(:,en)
   subLi0 = phase_mechanical_Li0(ph)%data(1:3,1:3,en)
@@ -1082,9 +1082,9 @@ module subroutine mechanical_restore(ce,includeL)
     co, ph, en
 
 
-  do co = 1,homogenization_Nconstituents(material_homogenizationID(ce))
-    ph = material_phaseID(co,ce)
-    en = material_phaseEntry(co,ce)
+  do co = 1,homogenization_Nconstituents(material_ID_homogenization(ce))
+    ph = material_ID_phase(co,ce)
+    en = material_entry_phase(co,ce)
     if (includeL) then
       phase_mechanical_Lp(ph)%data(1:3,1:3,en) = phase_mechanical_Lp0(ph)%data(1:3,1:3,en)
       phase_mechanical_Li(ph)%data(1:3,1:3,en) = phase_mechanical_Li0(ph)%data(1:3,1:3,en)
@@ -1133,8 +1133,8 @@ module function phase_mechanical_dPdF(Delta_t,co,ce) result(dPdF)
   logical :: error
 
 
-  ph = material_phaseID(co,ce)
-  en = material_phaseEntry(co,ce)
+  ph = material_ID_phase(co,ce)
+  en = material_entry_phase(co,ce)
 
   call phase_hooke_SandItsTangents(devNull,dSdFe,dSdFi, &
                                    phase_mechanical_Fe(ph)%data(1:3,1:3,en), &
@@ -1328,7 +1328,7 @@ module function phase_P(co,ce) result(P)
   real(pReal), dimension(3,3) :: P
 
 
-  P = phase_mechanical_P(material_phaseID(co,ce))%data(1:3,1:3,material_phaseEntry(co,ce))
+  P = phase_mechanical_P(material_ID_phase(co,ce))%data(1:3,1:3,material_entry_phase(co,ce))
 
 end function phase_P
 
@@ -1342,7 +1342,7 @@ module function phase_F(co,ce) result(F)
   real(pReal), dimension(3,3) :: F
 
 
-  F = phase_mechanical_F(material_phaseID(co,ce))%data(1:3,1:3,material_phaseEntry(co,ce))
+  F = phase_mechanical_F(material_ID_phase(co,ce))%data(1:3,1:3,material_entry_phase(co,ce))
 
 end function phase_F
 
@@ -1356,7 +1356,7 @@ module subroutine phase_set_F(F,co,ce)
   integer, intent(in) :: co, ce
 
 
-  phase_mechanical_F(material_phaseID(co,ce))%data(1:3,1:3,material_phaseEntry(co,ce)) = F
+  phase_mechanical_F(material_ID_phase(co,ce))%data(1:3,1:3,material_entry_phase(co,ce)) = F
 
 end subroutine phase_set_F
 

src/phase_mechanical_plastic_dislotungsten.f90

@@ -219,7 +219,7 @@ module function plastic_dislotungsten_init() result(myPlasticity)
 
 !--------------------------------------------------------------------------------------------------
 ! allocate state arrays
-    Nmembers = count(material_phaseID == ph)
+    Nmembers = count(material_ID_phase == ph)
     sizeDotState = size(['rho_mob ','rho_dip ','gamma_sl']) * prm%sum_N_sl
     sizeState = sizeDotState
 

src/phase_mechanical_plastic_dislotwin.f90

@@ -380,7 +380,7 @@ module function plastic_dislotwin_init() result(myPlasticity)
 
 !--------------------------------------------------------------------------------------------------
 ! allocate state arrays
-    Nmembers  = count(material_phaseID == ph)
+    Nmembers  = count(material_ID_phase == ph)
     sizeDotState = size(['rho_mob ','rho_dip ','gamma_sl']) * prm%sum_N_sl &
                  + size(['f_tw'])                           * prm%sum_N_tw &
                  + size(['f_tr'])                           * prm%sum_N_tr

src/phase_mechanical_plastic_isotropic.f90

@@ -118,7 +118,7 @@ module function plastic_isotropic_init() result(myPlasticity)
 
 !--------------------------------------------------------------------------------------------------
 ! allocate state arrays
-    Nmembers = count(material_phaseID == ph)
+    Nmembers = count(material_ID_phase == ph)
     sizeDotState = size(['xi'])
     sizeState = sizeDotState
 

src/phase_mechanical_plastic_kinehardening.f90

@@ -173,7 +173,7 @@ module function plastic_kinehardening_init() result(myPlasticity)
 
 !--------------------------------------------------------------------------------------------------
 ! allocate state arrays
-    Nmembers = count(material_phaseID == ph)
+    Nmembers = count(material_ID_phase == ph)
     sizeDotState   = size(['xi   ','chi  ', 'gamma']) * prm%sum_N_sl
     sizeDeltaState = size(['sgn_gamma',   'chi_0    ',    'gamma_0  ']) * prm%sum_N_sl
     sizeState = sizeDotState + sizeDeltaState

src/phase_mechanical_plastic_none.f90

@@ -31,7 +31,7 @@ module function plastic_none_init() result(myPlasticity)
   phases => config_material%get_dict('phase')
   do ph = 1, phases%length
     if (.not. myPlasticity(ph)) cycle
-    call phase_allocateState(plasticState(ph),count(material_phaseID == ph),0,0,0)
+    call phase_allocateState(plasticState(ph),count(material_ID_phase == ph),0,0,0)
   end do
 
 end function plastic_none_init

src/phase_mechanical_plastic_nonlocal.f90

@@ -394,7 +394,7 @@ module function plastic_nonlocal_init() result(myPlasticity)
 
 !--------------------------------------------------------------------------------------------------
 ! allocate state arrays
-    Nmembers  = count(material_phaseID == ph)
+    Nmembers  = count(material_ID_phase == ph)
     sizeDotState = size([   'rhoSglEdgePosMobile   ','rhoSglEdgeNegMobile   ', &
                             'rhoSglScrewPosMobile  ','rhoSglScrewNegMobile  ', &
                             'rhoSglEdgePosImmobile ','rhoSglEdgeNegImmobile ', &
@@ -522,7 +522,7 @@ module function plastic_nonlocal_init() result(myPlasticity)
     if (.not. myPlasticity(ph)) cycle
 
     phase => phases%get_dict(ph)
-    Nmembers = count(material_phaseID == ph)
+    Nmembers = count(material_ID_phase == ph)
     l = 0
     do t = 1,4
       do s = 1,param(ph)%sum_N_sl
@@ -662,8 +662,8 @@ module subroutine nonlocal_dependentState(ph, en)
       neighbor_ip = geom(ph)%IPneighborhood(2,n,en)
 
       if (neighbor_el > 0 .and. neighbor_ip > 0) then
-        if (material_phaseID(1,(neighbor_el-1)*discretization_nIPs + neighbor_ip) == ph) then
-            no = material_phaseEntry(1,(neighbor_el-1)*discretization_nIPs + neighbor_ip)
+        if (material_ID_phase(1,(neighbor_el-1)*discretization_nIPs + neighbor_ip) == ph) then
+            no = material_entry_phase(1,(neighbor_el-1)*discretization_nIPs + neighbor_ip)
             nRealNeighbors = nRealNeighbors + 1.0_pReal
             rho_neighbor0 = getRho0(ph,no)
 
@@ -1251,8 +1251,8 @@ function rhoDotFlux(timestep,ph,en)
       neighbor_el = geom(ph)%IPneighborhood(1,n,en)
       neighbor_ip = geom(ph)%IPneighborhood(2,n,en)
       neighbor_n  = geom(ph)%IPneighborhood(3,n,en)
-      np = material_phaseID(1,(neighbor_el-1)*discretization_nIPs + neighbor_ip)
-      no = material_phaseEntry(1,(neighbor_el-1)*discretization_nIPs + neighbor_ip)
+      np = material_ID_phase(1,(neighbor_el-1)*discretization_nIPs + neighbor_ip)
+      no = material_entry_phase(1,(neighbor_el-1)*discretization_nIPs + neighbor_ip)
 
       opposite_neighbor = n + mod(n,2) - mod(n+1,2)
       opposite_el = geom(ph)%IPneighborhood(1,opposite_neighbor,en)
@@ -1399,7 +1399,7 @@ module subroutine plastic_nonlocal_updateCompatibility(orientation,ph,ip,el)
   associate(prm => param(ph))
     ns = prm%sum_N_sl
 
-    en = material_phaseEntry(1,(el-1)*discretization_nIPs + ip)
+    en = material_entry_phase(1,(el-1)*discretization_nIPs + ip)
     !*** start out fully compatible
     my_compatibility = 0.0_pReal
     forall(s1 = 1:ns) my_compatibility(:,s1,s1,:) = 1.0_pReal
@@ -1407,8 +1407,8 @@ module subroutine plastic_nonlocal_updateCompatibility(orientation,ph,ip,el)
     neighbors: do n = 1,nIPneighbors
       neighbor_e = IPneighborhood(1,n,ip,el)
       neighbor_i = IPneighborhood(2,n,ip,el)
-      neighbor_me = material_phaseEntry(1,(neighbor_e-1)*discretization_nIPs + neighbor_i)
-      neighbor_phase = material_phaseID(1,(neighbor_e-1)*discretization_nIPs + neighbor_i)
+      neighbor_me = material_entry_phase(1,(neighbor_e-1)*discretization_nIPs + neighbor_i)
+      neighbor_phase = material_ID_phase(1,(neighbor_e-1)*discretization_nIPs + neighbor_i)
 
       if (neighbor_e <= 0 .or. neighbor_i <= 0) then
         !* FREE SURFACE
@@ -1467,7 +1467,7 @@ module subroutine plastic_nonlocal_updateCompatibility(orientation,ph,ip,el)
 
     end do neighbors
 
-    dependentState(ph)%compatibility(:,:,:,:,material_phaseEntry(1,(el-1)*discretization_nIPs + ip)) = my_compatibility
+    dependentState(ph)%compatibility(:,:,:,:,material_entry_phase(1,(el-1)*discretization_nIPs + ip)) = my_compatibility
 
   end associate
 
@@ -1772,14 +1772,14 @@ subroutine storeGeometry(ph)
   areaNormal = reshape(IPareaNormal,[3,nIPneighbors,nCell])
   coords = reshape(discretization_IPcoords,[3,nCell])
 
-  do ce = 1, size(material_homogenizationEntry,1)
+  do ce = 1, size(material_entry_homogenization,1)
     do co = 1, homogenization_maxNconstituents
-      if (material_phaseID(co,ce) == ph) then
-        geom(ph)%V_0(material_phaseEntry(co,ce)) = V(ce)
-        geom(ph)%IPneighborhood(:,:,material_phaseEntry(co,ce)) = neighborhood(:,:,ce)
-        geom(ph)%IParea(:,material_phaseEntry(co,ce)) = area(:,ce)
-        geom(ph)%IPareaNormal(:,:,material_phaseEntry(co,ce)) = areaNormal(:,:,ce)
-        geom(ph)%IPcoordinates(:,material_phaseEntry(co,ce)) = coords(:,ce)
+      if (material_ID_phase(co,ce) == ph) then
+        geom(ph)%V_0(material_entry_phase(co,ce)) = V(ce)
+        geom(ph)%IPneighborhood(:,:,material_entry_phase(co,ce)) = neighborhood(:,:,ce)
+        geom(ph)%IParea(:,material_entry_phase(co,ce)) = area(:,ce)
+        geom(ph)%IPareaNormal(:,:,material_entry_phase(co,ce)) = areaNormal(:,:,ce)
+        geom(ph)%IPcoordinates(:,material_entry_phase(co,ce)) = coords(:,ce)
       end if
     end do
   end do

src/phase_mechanical_plastic_phenopowerlaw.f90

@@ -227,7 +227,7 @@ module function plastic_phenopowerlaw_init() result(myPlasticity)
 
 !--------------------------------------------------------------------------------------------------
 ! allocate state arrays
-    Nmembers = count(material_phaseID == ph)
+    Nmembers = count(material_ID_phase == ph)
     sizeDotState = size(['xi_sl   ','gamma_sl']) * prm%sum_N_sl &
                  + size(['xi_tw   ','gamma_tw']) * prm%sum_N_tw
     sizeState = sizeDotState

src/phase_thermal.f90

@@ -99,7 +99,7 @@ module subroutine thermal_init(phases)
   allocate(param(phases%length))
 
   do ph = 1, phases%length
-    Nmembers = count(material_phaseID == ph)
+    Nmembers = count(material_ID_phase == ph)
     allocate(current(ph)%T(Nmembers),source=T_ROOM)
     allocate(current(ph)%dot_T(Nmembers),source=0.0_pReal)
     phase => phases%get_dict(ph)
@@ -212,8 +212,8 @@ module function phase_mu_T(co,ce) result(mu)
   real(pReal) :: mu
 
 
-  mu = phase_rho(material_phaseID(co,ce)) &
-     * param(material_phaseID(co,ce))%C_p
+  mu = phase_rho(material_ID_phase(co,ce)) &
+     * param(material_ID_phase(co,ce))%C_p
 
 end function phase_mu_T
 
@@ -227,7 +227,7 @@ module function phase_K_T(co,ce) result(K)
   real(pReal), dimension(3,3) :: K
 
 
-  K = crystallite_push33ToRef(co,ce,param(material_phaseID(co,ce))%K)
+  K = crystallite_push33ToRef(co,ce,param(material_ID_phase(co,ce))%K)
 
 end function phase_K_T
 
@@ -352,8 +352,8 @@ module subroutine phase_thermal_setField(T,dot_T, co,ce)
   integer, intent(in) :: ce, co
 
 
-  current(material_phaseID(co,ce))%T(material_phaseEntry(co,ce)) = T
-  current(material_phaseID(co,ce))%dot_T(material_phaseEntry(co,ce)) = dot_T
+  current(material_ID_phase(co,ce))%T(material_entry_phase(co,ce)) = T
+  current(material_ID_phase(co,ce))%dot_T(material_entry_phase(co,ce)) = dot_T
 
 end subroutine phase_thermal_setField
 

src/phase_thermal_dissipation.f90

@@ -57,7 +57,7 @@ module function dissipation_init(source_length) result(mySources)
           src => sources%get_dict(so)
 
           prm%kappa = src%get_asFloat('kappa')
-          Nmembers = count(material_phaseID == ph)
+          Nmembers = count(material_ID_phase == ph)
           call phase_allocateState(thermalState(ph)%p(so),Nmembers,0,0,0)
 
         end associate

src/phase_thermal_externalheat.f90

@@ -63,7 +63,7 @@ module function externalheat_init(source_length) result(mySources)
 
           prm%f = table(src,'t','f')
 
-          Nmembers = count(material_phaseID == ph)
+          Nmembers = count(material_ID_phase == ph)
           call phase_allocateState(thermalState(ph)%p(so),Nmembers,1,1,0)
         end associate
       end if