!-------------------------------------------------------------------------------------------------- !> @author Franz Roters, Max-Planck-Institut für Eisenforschung GmbH !> @author Philip Eisenlohr, Max-Planck-Institut für Eisenforschung GmbH !> @author Denny Tjahjanto, Max-Planck-Institut für Eisenforschung GmbH !> @brief homogenization manager, organizing deformation partitioning and stress homogenization !-------------------------------------------------------------------------------------------------- module homogenization use prec use math use constants use IO use config use material use phase use discretization use HDF5 use HDF5_utilities use result use crystal implicit none(type,external) private type :: tState integer :: & sizeState = 0 !< size of state ! http://stackoverflow.com/questions/3948210 real(pREAL), pointer, dimension(:,:), contiguous :: & !< is basically an allocatable+target, but in a type needs to be pointer state0, & state end type enum, bind(c); enumerator :: & THERMAL_UNDEFINED_ID, & THERMAL_PASS_ID, & THERMAL_ISOTEMPERATURE_ID end enum integer(kind(THERMAL_UNDEFINED_ID)), dimension(:), allocatable :: & thermal_type !< type of each homogenization type(tState), allocatable, dimension(:), public :: & homogState, & damageState_h logical, allocatable, dimension(:) :: & thermal_active, & damage_active logical, public :: & terminallyIll = .false. !< at least one material point is terminally ill !-------------------------------------------------------------------------------------------------- ! General variables for the homogenization at a material point real(pREAL), dimension(:,:,:), allocatable, public :: & homogenization_F0, & !< def grad of IP at start of FE increment homogenization_F !< def grad of IP to be reached at end of FE increment real(pREAL), dimension(:,:,:), allocatable, public :: & !, protected :: & Issue with ifort homogenization_P !< first P--K stress of IP real(pREAL), dimension(:,:,:,:,:), allocatable, public :: & !, protected :: & homogenization_dPdF !< tangent of first P--K stress at IP !-------------------------------------------------------------------------------------------------- type :: tNumerics integer :: & nMPstate !< materialpoint state loop limit end type tNumerics type(tNumerics) :: num !-------------------------------------------------------------------------------------------------- interface module subroutine mechanical_init() end subroutine mechanical_init module subroutine thermal_init() end subroutine thermal_init module subroutine damage_init() end subroutine damage_init module subroutine mechanical_partition(subF,ce) real(pREAL), intent(in), dimension(3,3) :: & subF integer, intent(in) :: & ce end subroutine mechanical_partition module subroutine thermal_partition(ce) integer, intent(in) :: ce end subroutine thermal_partition module subroutine damage_partition(ce) integer, intent(in) :: ce end subroutine damage_partition module subroutine mechanical_homogenize(Delta_t,ce) real(pREAL), intent(in) :: Delta_t integer, intent(in) :: & ce !< cell end subroutine mechanical_homogenize module subroutine mechanical_result(group_base,ho) character(len=*), intent(in) :: group_base integer, intent(in) :: ho end subroutine mechanical_result module subroutine damage_result(ho,group) integer, intent(in) :: ho character(len=*), intent(in) :: group end subroutine damage_result module subroutine thermal_result(ho,group) integer, intent(in) :: ho character(len=*), intent(in) :: group end subroutine thermal_result module function mechanical_updateState(subdt,subF,ce) result(doneAndHappy) real(pREAL), intent(in) :: & subdt !< current time step real(pREAL), intent(in), dimension(3,3) :: & subF integer, intent(in) :: & ce !< cell logical, dimension(2) :: doneAndHappy end function mechanical_updateState module function homogenization_thermal_active() result(active) logical :: active end function homogenization_thermal_active module function homogenization_mu_T(ce) result(mu) integer, intent(in) :: ce real(pREAL) :: mu end function homogenization_mu_T module function homogenization_K_T(ce) result(K) integer, intent(in) :: ce real(pREAL), dimension(3,3) :: K end function homogenization_K_T module function homogenization_f_T(ce) result(f) integer, intent(in) :: ce real(pREAL) :: f end function homogenization_f_T module subroutine homogenization_thermal_setField(T,dot_T, ce) integer, intent(in) :: ce real(pREAL), intent(in) :: T, dot_T end subroutine homogenization_thermal_setField module function homogenization_damage_active() result(active) logical :: active end function homogenization_damage_active module function homogenization_mu_phi(ce) result(mu) integer, intent(in) :: ce real(pREAL) :: mu end function homogenization_mu_phi module function homogenization_K_phi(ce) result(K) integer, intent(in) :: ce real(pREAL), dimension(3,3) :: K end function homogenization_K_phi module function homogenization_f_phi(phi,ce) result(f) integer, intent(in) :: ce real(pREAL), intent(in) :: phi real(pREAL) :: f end function homogenization_f_phi module subroutine homogenization_set_phi(phi,ce) integer, intent(in) :: ce real(pREAL), intent(in) :: & phi end subroutine homogenization_set_phi end interface public :: & homogenization_init, & homogenization_mechanical_response, & homogenization_mechanical_response2, & homogenization_thermal_response, & homogenization_thermal_active, & homogenization_mu_T, & homogenization_K_T, & homogenization_f_T, & homogenization_thermal_setfield, & homogenization_damage_active, & homogenization_mu_phi, & homogenization_K_phi, & homogenization_f_phi, & homogenization_set_phi, & homogenization_forward, & homogenization_result, & homogenization_restartRead, & homogenization_restartWrite contains !-------------------------------------------------------------------------------------------------- !> @brief module initialization !-------------------------------------------------------------------------------------------------- subroutine homogenization_init() type(tDict) , pointer :: & num_homog, & num_homogGeneric print'(/,1x,a)', '<<<+- homogenization init -+>>>'; flush(IO_STDOUT) allocate(homogState (size(material_name_homogenization))) allocate(damageState_h (size(material_name_homogenization))) call parseHomogenization() num_homog => config_numerics%get_dict('homogenization',defaultVal=emptyDict) num_homogGeneric => num_homog%get_dict('generic',defaultVal=emptyDict) num%nMPstate = num_homogGeneric%get_asInt('nMPstate',defaultVal=10) if (num%nMPstate < 1) call IO_error(301,ext_msg='nMPstate') call mechanical_init() call thermal_init() call damage_init() end subroutine homogenization_init !-------------------------------------------------------------------------------------------------- !> @brief !-------------------------------------------------------------------------------------------------- subroutine homogenization_mechanical_response(Delta_t,cell_start,cell_end) real(pREAL), intent(in) :: Delta_t !< time increment integer, intent(in) :: & cell_start, cell_end integer :: & NiterationMPstate, & co, ce, ho, en logical :: & converged logical, dimension(2) :: & doneAndHappy !$OMP PARALLEL DO PRIVATE(en,ho,co,NiterationMPstate,converged,doneAndHappy) do ce = cell_start, cell_end en = material_entry_homogenization(ce) ho = material_ID_homogenization(ce) call phase_restore(ce,.false.) ! wrong name (is more a forward function) if (homogState(ho)%sizeState > 0) homogState(ho)%state(:,en) = homogState(ho)%state0(:,en) if (damageState_h(ho)%sizeState > 0) damageState_h(ho)%state(:,en) = damageState_h(ho)%state0(:,en) call damage_partition(ce) doneAndHappy = [.false.,.true.] NiterationMPstate = 0 convergenceLooping: do while (.not. (terminallyIll .or. doneAndHappy(1)) & .and. NiterationMPstate < num%nMPstate) NiterationMPstate = NiterationMPstate + 1 call mechanical_partition(homogenization_F(1:3,1:3,ce),ce) converged = all([(phase_mechanical_constitutive(Delta_t,co,ce),co=1,homogenization_Nconstituents(ho))]) if (converged) then doneAndHappy = mechanical_updateState(Delta_t,homogenization_F(1:3,1:3,ce),ce) converged = all(doneAndHappy) else doneAndHappy = [.true.,.false.] end if end do convergenceLooping converged = converged .and. all([(phase_damage_constitutive(Delta_t,co,ce),co=1,homogenization_Nconstituents(ho))]) if (.not. converged) then if (.not. terminallyIll) print*, ' Cell ', ce, ' terminally ill' terminallyIll = .true. end if end do !$OMP END PARALLEL DO end subroutine homogenization_mechanical_response !-------------------------------------------------------------------------------------------------- !> @brief !-------------------------------------------------------------------------------------------------- subroutine homogenization_thermal_response(Delta_t,cell_start,cell_end) real(pREAL), intent(in) :: Delta_t !< time increment integer, intent(in) :: & cell_start, cell_end integer :: & co, ce, ho !$OMP PARALLEL DO PRIVATE(ho) do ce = cell_start, cell_end if (terminallyIll) continue ho = material_ID_homogenization(ce) do co = 1, homogenization_Nconstituents(ho) if (.not. phase_thermal_constitutive(Delta_t,material_ID_phase(co,ce),material_entry_phase(co,ce))) then if (.not. terminallyIll) print*, ' Cell ', ce, ' terminally ill' terminallyIll = .true. end if end do end do !$OMP END PARALLEL DO end subroutine homogenization_thermal_response !-------------------------------------------------------------------------------------------------- !> @brief !-------------------------------------------------------------------------------------------------- subroutine homogenization_mechanical_response2(Delta_t,FEsolving_execIP,FEsolving_execElem) real(pREAL), intent(in) :: Delta_t !< time increment integer, dimension(2), intent(in) :: FEsolving_execElem, FEsolving_execIP integer :: & ip, & !< integration point number el, & !< element number co, ce, ho !$OMP PARALLEL DO PRIVATE(ho,ce) elementLooping3: do el = FEsolving_execElem(1),FEsolving_execElem(2) IpLooping3: do ip = FEsolving_execIP(1),FEsolving_execIP(2) ce = (el-1)*discretization_nIPs + ip ho = material_ID_homogenization(ce) do co = 1, homogenization_Nconstituents(ho) call crystallite_orientations(co,ip,el) end do call mechanical_homogenize(Delta_t,ce) end do IpLooping3 end do elementLooping3 !$OMP END PARALLEL DO end subroutine homogenization_mechanical_response2 !-------------------------------------------------------------------------------------------------- !> @brief writes homogenization results to HDF5 output file !-------------------------------------------------------------------------------------------------- subroutine homogenization_result integer :: ho character(len=:), allocatable :: group_base,group call result_closeGroup(result_addGroup('current/homogenization/')) do ho=1,size(material_name_homogenization) group_base = 'current/homogenization/'//trim(material_name_homogenization(ho)) call result_closeGroup(result_addGroup(group_base)) call mechanical_result(group_base,ho) if (damage_active(ho)) then group = trim(group_base)//'/damage' call result_closeGroup(result_addGroup(group)) call damage_result(ho,group) end if if (thermal_active(ho)) then group = trim(group_base)//'/thermal' call result_closeGroup(result_addGroup(group)) call thermal_result(ho,group) end if end do end subroutine homogenization_result !-------------------------------------------------------------------------------------------------- !> @brief Forward data after successful increment. ! ToDo: Any guessing for the current states possible? !-------------------------------------------------------------------------------------------------- subroutine homogenization_forward integer :: ho do ho = 1, size(material_name_homogenization) homogState (ho)%state0 = homogState (ho)%state if (damageState_h(ho)%sizeState > 0) & damageState_h(ho)%state0 = damageState_h(ho)%state end do end subroutine homogenization_forward !-------------------------------------------------------------------------------------------------- !-------------------------------------------------------------------------------------------------- subroutine homogenization_restartWrite(fileHandle) integer(HID_T), intent(in) :: fileHandle integer(HID_T), dimension(2) :: groupHandle integer :: ho groupHandle(1) = HDF5_addGroup(fileHandle,'homogenization') do ho = 1, size(material_name_homogenization) groupHandle(2) = HDF5_addGroup(groupHandle(1),material_name_homogenization(ho)) call HDF5_write(homogState(ho)%state,groupHandle(2),'omega_mechanical') ! ToDo: should be done by mech if (damageState_h(ho)%sizeState > 0) & call HDF5_write(damageState_h(ho)%state,groupHandle(2),'omega_damage') ! ToDo: should be done by mech call HDF5_closeGroup(groupHandle(2)) end do call HDF5_closeGroup(groupHandle(1)) end subroutine homogenization_restartWrite !-------------------------------------------------------------------------------------------------- !-------------------------------------------------------------------------------------------------- subroutine homogenization_restartRead(fileHandle) integer(HID_T), intent(in) :: fileHandle integer(HID_T), dimension(2) :: groupHandle integer :: ho groupHandle(1) = HDF5_openGroup(fileHandle,'homogenization') do ho = 1, size(material_name_homogenization) groupHandle(2) = HDF5_openGroup(groupHandle(1),material_name_homogenization(ho)) call HDF5_read(homogState(ho)%state0,groupHandle(2),'omega_mechanical') ! ToDo: should be done by mech if (damageState_h(ho)%sizeState > 0) & call HDF5_read(damageState_h(ho)%state0,groupHandle(2),'omega_damage') ! ToDo: should be done by mech call HDF5_closeGroup(groupHandle(2)) end do call HDF5_closeGroup(groupHandle(1)) end subroutine homogenization_restartRead !-------------------------------------------------------------------------------------------------- !> @brief parses the homogenization part from the material configuration !-------------------------------------------------------------------------------------------------- subroutine parseHomogenization type(tDict), pointer :: & material_homogenization, & homog, & homogThermal, & homogDamage integer :: h material_homogenization => config_material%get_dict('homogenization') allocate(thermal_type(size(material_name_homogenization)),source=THERMAL_UNDEFINED_ID) allocate(thermal_active(size(material_name_homogenization)),source=.false.) allocate(damage_active(size(material_name_homogenization)),source=.false.) do h=1, size(material_name_homogenization) homog => material_homogenization%get_dict(h) if (homog%contains('thermal')) then homogThermal => homog%get_dict('thermal') select case (homogThermal%get_asStr('type')) case('pass') thermal_type(h) = THERMAL_PASS_ID thermal_active(h) = .true. case('isotemperature') thermal_type(h) = THERMAL_ISOTEMPERATURE_ID thermal_active(h) = .true. case default call IO_error(500,ext_msg=homogThermal%get_asStr('type')) end select end if if (homog%contains('damage')) then homogDamage => homog%get_dict('damage') select case (homogDamage%get_asStr('type')) case('pass') damage_active(h) = .true. case default call IO_error(500,ext_msg=homogDamage%get_asStr('type')) end select end if end do end subroutine parseHomogenization end module homogenization