!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> A Module For Performing Distributed Sparse Matrix Operations. MODULE PSMatrixModule USE DataTypesModule, ONLY : NTREAL, MPINTREAL, NTCOMPLEX, MPINTCOMPLEX, & & MPINTINTEGER, NTLONG USE ErrorModule, ONLY : Error_t, ConstructError, SetGenericError, & & CheckMPIError USE LoggingModule, ONLY : EnterSubLog, ExitSubLog, WriteElement, & & WriteListElement, WriteHeader USE MatrixMarketModule, ONLY : ParseMMHeader, MM_COMPLEX, WriteMMSize, & & WriteMMLine, MAX_LINE_LENGTH USE MatrixReduceModule, ONLY : ReduceHelper_t, ReduceAndComposeMatrix, & & ReduceAndSumMatrix USE PermutationModule, ONLY : Permutation_t, ConstructDefaultPermutation USE ProcessGridModule, ONLY : ProcessGrid_t, global_grid, IsRoot, & & SplitProcessGrid USE SMatrixModule, ONLY : Matrix_lsr, Matrix_lsc, DestructMatrix, & & PrintMatrix, TransposeMatrix, ConjugateMatrix, SplitMatrix, & & ComposeMatrix, ConvertMatrixType, MatrixToTripletList, & & ConstructMatrixFromTripletList, ConstructEmptyMatrix USE TimerModule, ONLY : StartTimer, StopTimer USE TripletModule, ONLY : Triplet_r, Triplet_c, GetMPITripletType_r, & & GetMPITripletType_c USE TripletListModule, ONLY : TripletList_r, TripletList_c, & & ConstructTripletList, & & DestructTripletList, SortTripletList, AppendToTripletList, & & SymmetrizeTripletList, GetTripletAt, RedistributeTripletLists, & & ShiftTripletList USE NTMPIModule IMPLICIT NONE PRIVATE !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> A datatype for a distributed blocked CSR matrix. TYPE, PUBLIC :: Matrix_ps !> Number of matrix rows/columns for full matrix, scaled for process grid. INTEGER :: logical_matrix_dimension !> Number of matrix rows/columns for the full matrix, unscaled. INTEGER :: actual_matrix_dimension !! Local Storage !> A 2D array of local CSR matrices. TYPE(Matrix_lsr), DIMENSION(:,:), ALLOCATABLE :: local_data_r !> A 2D array of local CSC matrices. TYPE(Matrix_lsc), DIMENSION(:,:), ALLOCATABLE :: local_data_c INTEGER :: start_column !< first column stored locally. INTEGER :: end_column !< last column stored locally is less than this. INTEGER :: start_row !< first row stored locally. INTEGER :: end_row !< last row stored locally is less than this. INTEGER :: local_columns !< number of local columns. INTEGER :: local_rows !< number of local rows. TYPE(ProcessGrid_t), POINTER :: process_grid !< process grid to operate on LOGICAL :: is_complex !< true if the matrix data is true. END TYPE Matrix_ps !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !! Constructors/Destructors PUBLIC :: ConstructEmptyMatrix PUBLIC :: DestructMatrix PUBLIC :: CopyMatrix PUBLIC :: SetMatrixProcessGrid !! File I/O PUBLIC :: ConstructMatrixFromMatrixMarket PUBLIC :: ConstructMatrixFromBinary PUBLIC :: WriteMatrixToMatrixMarket PUBLIC :: WriteMatrixToBinary !! Fill In Special Matrices PUBLIC :: FillMatrixFromTripletList PUBLIC :: FillMatrixIdentity PUBLIC :: FillMatrixPermutation !! Basic Accessors PUBLIC :: GetMatrixActualDimension PUBLIC :: GetMatrixLogicalDimension PUBLIC :: GetMatrixTripletList PUBLIC :: GetMatrixBlock PUBLIC :: GetMatrixSlice !! Printing To The Console PUBLIC :: PrintMatrix PUBLIC :: PrintMatrixInformation !! Utilities PUBLIC :: ConvertMatrixToReal PUBLIC :: ConvertMatrixToComplex PUBLIC :: GetMatrixLoadBalance PUBLIC :: GetMatrixSize PUBLIC :: FilterMatrix PUBLIC :: MergeMatrixLocalBlocks PUBLIC :: SplitMatrixToLocalBlocks PUBLIC :: TransposeMatrix PUBLIC :: ConjugateMatrix PUBLIC :: CommSplitMatrix PUBLIC :: ResizeMatrix PUBLIC :: GatherMatrixToProcess !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! INTERFACE ConstructEmptyMatrix MODULE PROCEDURE ConstructEmptyMatrix_ps MODULE PROCEDURE ConstructEmptyMatrix_ps_cp END INTERFACE ConstructEmptyMatrix INTERFACE DestructMatrix MODULE PROCEDURE DestructMatrix_ps END INTERFACE DestructMatrix INTERFACE CopyMatrix MODULE PROCEDURE CopyMatrix_ps END INTERFACE CopyMatrix INTERFACE ConstructMatrixFromMatrixMarket MODULE PROCEDURE ConstructMatrixFromMatrixMarket_ps END INTERFACE ConstructMatrixFromMatrixMarket INTERFACE ConstructMatrixFromBinary MODULE PROCEDURE ConstructMatrixFromBinary_ps END INTERFACE ConstructMatrixFromBinary INTERFACE WriteMatrixToMatrixMarket MODULE PROCEDURE WriteMatrixToMatrixMarket_ps END INTERFACE WriteMatrixToMatrixMarket INTERFACE WriteMatrixToBinary MODULE PROCEDURE WriteMatrixToBinary_ps END INTERFACE WriteMatrixToBinary INTERFACE FillMatrixFromTripletList MODULE PROCEDURE FillMatrixFromTripletList_psr MODULE PROCEDURE FillMatrixFromTripletList_psc END INTERFACE FillMatrixFromTripletList INTERFACE FillMatrixIdentity MODULE PROCEDURE FillMatrixIdentity_ps END INTERFACE FillMatrixIdentity INTERFACE FillMatrixPermutation MODULE PROCEDURE FillMatrixPermutation_ps END INTERFACE FillMatrixPermutation INTERFACE GetMatrixActualDimension MODULE PROCEDURE GetMatrixActualDimension_ps END INTERFACE GetMatrixActualDimension INTERFACE GetMatrixLogicalDimension MODULE PROCEDURE GetMatrixLogicalDimension_ps END INTERFACE GetMatrixLogicalDimension INTERFACE GetMatrixTripletList MODULE PROCEDURE GetMatrixTripletList_psr MODULE PROCEDURE GetMatrixTripletList_psc END INTERFACE GetMatrixTripletList INTERFACE GetMatrixBlock MODULE PROCEDURE GetMatrixBlock_psr MODULE PROCEDURE GetMatrixBlock_psc END INTERFACE GetMatrixBlock INTERFACE PrintMatrix MODULE PROCEDURE PrintMatrix_ps END INTERFACE PrintMatrix INTERFACE PrintMatrixInformation MODULE PROCEDURE PrintMatrixInformation_ps END INTERFACE PrintMatrixInformation INTERFACE GetMatrixLoadBalance MODULE PROCEDURE GetMatrixLoadBalance_ps END INTERFACE GetMatrixLoadBalance INTERFACE GetMatrixSize MODULE PROCEDURE GetMatrixSize_ps END INTERFACE GetMatrixSize INTERFACE FilterMatrix MODULE PROCEDURE FilterMatrix_ps END INTERFACE FilterMatrix INTERFACE RedistributeData MODULE PROCEDURE RedistributeData_psr MODULE PROCEDURE RedistributeData_psc END INTERFACE RedistributeData INTERFACE MergeMatrixLocalBlocks MODULE PROCEDURE MergeMatrixLocalBlocks_psr MODULE PROCEDURE MergeMatrixLocalBlocks_psc END INTERFACE MergeMatrixLocalBlocks INTERFACE SplitMatrixToLocalBlocks MODULE PROCEDURE SplitMatrixToLocalBlocks_psr MODULE PROCEDURE SplitMatrixToLocalBlocks_psc END INTERFACE SplitMatrixToLocalBlocks INTERFACE TransposeMatrix MODULE PROCEDURE TransposeMatrix_ps END INTERFACE TransposeMatrix INTERFACE ConjugateMatrix MODULE PROCEDURE ConjugateMatrix_ps END INTERFACE ConjugateMatrix INTERFACE CommSplitMatrix MODULE PROCEDURE CommSplitMatrix_ps END INTERFACE CommSplitMatrix INTERFACE GatherMatrixToProcess MODULE PROCEDURE GatherMatrixToProcess_psr_id MODULE PROCEDURE GatherMatrixToProcess_psr_all MODULE PROCEDURE GatherMatrixToProcess_psc_id MODULE PROCEDURE GatherMatrixToProcess_psc_all END INTERFACE GatherMatrixToProcess CONTAINS!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Construct an empty sparse, distributed, matrix. SUBROUTINE ConstructEmptyMatrix_ps(this, matrix_dim_, process_grid_in, & & is_complex_in) !> The matrix to be constructed. TYPE(Matrix_ps), INTENT(INOUT) :: this !> The dimension of the full matrix. INTEGER, INTENT(IN) :: matrix_dim_ !> True if you want to use complex numbers. LOGICAL, INTENT(IN), OPTIONAL :: is_complex_in !> A process grid to host the matrix. TYPE(ProcessGrid_t), INTENT(IN), TARGET, OPTIONAL :: process_grid_in !! Local Variables TYPE(Matrix_lsr) :: zeromatrix_r TYPE(Matrix_lsc) :: zeromatrix_c CALL DestructMatrix(this) !! Process Grid IF (PRESENT(process_grid_in)) THEN this%process_grid => process_grid_in ELSE this%process_grid => global_grid END IF !! Complex determination IF (PRESENT(is_complex_in)) THEN this%is_complex = is_complex_in ELSE this%is_complex = .FALSE. END IF !! Matrix Dimensions this%actual_matrix_dimension = matrix_dim_ this%logical_matrix_dimension = CalculateScaledDimension(this, matrix_dim_) !! Full Local Data Size Description this%local_rows = & & this%logical_matrix_dimension/this%process_grid%num_process_rows this%local_columns = & & this%logical_matrix_dimension/this%process_grid%num_process_columns !! Which Block Does This Process Hold? this%start_row = this%local_rows * this%process_grid%my_row + 1 this%end_row = this%start_row + this%local_rows this%start_column = this%local_columns * this%process_grid%my_column + 1 this%end_column = this%start_column + this%local_columns !! Build local storage IF (this%is_complex) THEN ALLOCATE(this%local_data_c(this%process_grid%number_of_blocks_rows, & & this%process_grid%number_of_blocks_columns)) zeromatrix_c = Matrix_lsc(this%local_rows, this%local_columns) CALL SplitMatrixToLocalBlocks(this, zeromatrix_c) CALL DestructMatrix(zeromatrix_c) ELSE ALLOCATE(this%local_data_r(this%process_grid%number_of_blocks_rows, & & this%process_grid%number_of_blocks_columns)) zeromatrix_r = Matrix_lsr(this%local_rows, this%local_columns) CALL SplitMatrixToLocalBlocks(this, zeromatrix_r) CALL DestructMatrix(zeromatrix_r) END IF END SUBROUTINE ConstructEmptyMatrix_ps !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Construct an empty sparse, distributed, matrix using another matrix !> to determine the parameters. Note that no data is copied, the matrix !> will be empty. SUBROUTINE ConstructEmptyMatrix_ps_cp(this, reference_matrix) !! Parameters !> The matrix to be constructed. TYPE(Matrix_ps), INTENT(INOUT) :: this !> The reference matrix to take parameters from. TYPE(Matrix_ps), INTENT(IN) :: reference_matrix CALL ConstructEmptyMatrix(this, reference_matrix%actual_matrix_dimension, & & reference_matrix%process_grid, reference_matrix%is_complex) END SUBROUTINE ConstructEmptyMatrix_ps_cp !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Destruct a distributed sparse matrix. PURE SUBROUTINE DestructMatrix_ps(this) !> The matrix to destruct. TYPE(Matrix_ps), INTENT(INOUT) :: this !! Local Data INTEGER :: II, JJ IF (ALLOCATED(this%local_data_r)) THEN DO II = 1, SIZE(this%local_data_r,DIM=1) DO JJ = 1, SIZE(this%local_data_r,DIM=2) CALL DestructMatrix(this%local_data_r(II,JJ)) END DO END DO DEALLOCATE(this%local_data_r) END IF IF (ALLOCATED(this%local_data_c)) THEN DO II = 1, SIZE(this%local_data_c,DIM=1) DO JJ = 1, SIZE(this%local_data_c,DIM=2) CALL DestructMatrix(this%local_data_c(II,JJ)) END DO END DO DEALLOCATE(this%local_data_c) END IF END SUBROUTINE DestructMatrix_ps !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Copy a distributed sparse matrix in a safe way. SUBROUTINE CopyMatrix_ps(matA, matB) !> The matrix to copy. TYPE(Matrix_ps), INTENT(IN) :: matA !> matB = matA. TYPE(Matrix_ps), INTENT(INOUT) :: matB CALL DestructMatrix(matB) matB = matA END SUBROUTINE CopyMatrix_ps !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> When you want to change the process grid of a matrix, you can call !> this routine with the new process grid value. Data will be automatically !> redistributed. SUBROUTINE SetMatrixProcessGrid(this, grid) !> The matrix to set the grid of. TYPE(Matrix_ps), INTENT(INOUT) :: this !> The grid to set it to. TYPE(ProcessGrid_t), INTENT(IN) :: grid !! Local variables TYPE(TripletList_r) :: triplet_list_r TYPE(TripletList_c) :: triplet_list_c TYPE(Matrix_ps) :: new_mat !! Get the data in a triplet list CALL ConstructTripletList(triplet_list_c) CALL ConstructTripletList(triplet_list_r) IF (this%process_grid%my_slice .EQ. 0) THEN IF (this%is_complex) THEN CALL GetMatrixTripletList(this, triplet_list_c) ELSE CALL GetMatrixTripletList(this, triplet_list_r) END IF END IF !! Fill The New Matrix CALL ConstructEmptyMatrix(new_mat, this%actual_matrix_dimension, grid, & & this%is_complex) IF (this%is_complex) THEN CALL FillMatrixFromTripletList(new_mat, triplet_list_c) ELSE CALL FillMatrixFromTripletList(new_mat, triplet_list_r) END IF !! Copy back to finish CALL CopyMatrix(new_mat, this) !! Cleanup CALL DestructMatrix(new_mat) CALL DestructTripletList(triplet_list_c) CALL DestructTripletList(triplet_list_r) END SUBROUTINE SetMatrixProcessGrid !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Construct distributed sparse matrix from a matrix market file in parallel. !> Read \cite boisvert1996matrix for the details. RECURSIVE SUBROUTINE ConstructMatrixFromMatrixMarket_ps(this, file_name, & & process_grid_in) !> The file being constructed. TYPE(Matrix_ps), INTENT(INOUT) :: this !> Grid to distribute the matrix on. TYPE(ProcessGrid_t), INTENT(IN), OPTIONAL :: process_grid_in !> The name of the file to read. CHARACTER(len=*), INTENT(IN) :: file_name INTEGER, PARAMETER :: MAX_LINE_LENGTH = 100 !! File Handles INTEGER :: local_file_handler INTEGER :: mpi_file_handler !! About the matrix market file. INTEGER :: sparsity_type, data_type, pattern_type !! Reading The File TYPE(TripletList_r) :: triplet_list_r TYPE(Triplet_r) :: temp_triplet_r TYPE(TripletList_c) :: triplet_list_c TYPE(Triplet_c) :: temp_triplet_c INTEGER :: matrix_rows, matrix_columns, total_values !! Length Variables INTEGER :: header_length INTEGER(KIND=MPI_OFFSET_KIND) :: total_file_size INTEGER(KIND=MPI_OFFSET_KIND) :: local_offset INTEGER(KIND=MPI_OFFSET_KIND) :: local_data_size INTEGER(KIND=MPI_OFFSET_KIND) :: local_data_size_plus_buffer INTEGER :: current_line_length !! Input Buffers CHARACTER(len=MAX_LINE_LENGTH) :: input_buffer CHARACTER(len=:), ALLOCATABLE :: mpi_input_buffer CHARACTER(len=MAX_LINE_LENGTH) :: temp_substring !! Temporary Variables REAL(NTREAL) :: realval, cval INTEGER :: bytes_per_character LOGICAL :: found_comment_line INTEGER :: message_status(MPI_STATUS_SIZE) INTEGER :: full_buffer_counter LOGICAL :: end_of_buffer LOGICAL :: header_success INTEGER :: ierr TYPE(Error_t) :: err IF (.NOT. PRESENT(process_grid_in)) THEN CALL ConstructMatrixFromMatrixMarket(this, file_name, global_grid) ELSE CALL ConstructError(err) !! Setup Involves Just The Root Opening And Reading Parameter Data CALL StartTimer("MPI Read Text") CALL MPI_Type_size(MPI_CHARACTER, bytes_per_character, ierr) IF (IsRoot(process_grid_in)) THEN header_length = 0 local_file_handler = 16 OPEN(local_file_handler, file=file_name, iostat=ierr, status="old") IF (ierr .NE. 0) THEN CALL SetGenericError(err, TRIM(file_name)//" doesn't exist", & & .TRUE.) END IF !! Parse the header. READ(local_file_handler,fmt='(A)') input_buffer header_success = ParseMMHeader(input_buffer, sparsity_type, & & data_type, pattern_type) IF (.NOT. header_success) THEN CALL SetGenericError(err, "Invalid File Header", .TRUE.) END IF header_length = header_length + LEN_TRIM(input_buffer) + 1 !! First Read In The Comment Lines found_comment_line = .TRUE. DO WHILE (found_comment_line) READ(local_file_handler,fmt='(A)') input_buffer !! +1 for newline header_length = header_length + LEN_TRIM(input_buffer) + 1 IF (.NOT. input_buffer(1:1) .EQ. '%') THEN found_comment_line = .FALSE. END IF END DO !! Get The Matrix Parameters READ(input_buffer,*) matrix_rows, matrix_columns, total_values CLOSE(local_file_handler) END IF !! Broadcast Parameters CALL MPI_Bcast(matrix_rows, 1, MPINTINTEGER, process_grid_in%RootID, & & process_grid_in%global_comm, ierr) CALL MPI_Bcast(matrix_columns, 1, MPINTINTEGER, process_grid_in%RootID, & & process_grid_in%global_comm, ierr) CALL MPI_Bcast(total_values, 1, MPINTINTEGER, process_grid_in%RootID, & & process_grid_in%global_comm, ierr) CALL MPI_Bcast(header_length, 1, MPINTINTEGER, process_grid_in%RootID, & & process_grid_in%global_comm, ierr) CALL MPI_Bcast(sparsity_type, 1, MPINTINTEGER, process_grid_in%RootID, & & process_grid_in%global_comm, ierr) CALL MPI_Bcast(data_type, 1, MPINTINTEGER, process_grid_in%RootID, & & process_grid_in%global_comm, ierr) CALL MPI_Bcast(pattern_type, 1, MPINTINTEGER, process_grid_in%RootID, & & process_grid_in%global_comm, ierr) !! Build Local Storage CALL ConstructEmptyMatrix(this, matrix_rows, process_grid_in, & & is_complex_in = (data_type .EQ. MM_COMPLEX)) !! Global read CALL MPI_File_open(this%process_grid%global_comm, file_name, & & MPI_MODE_RDONLY, MPI_INFO_NULL,mpi_file_handler,ierr) CALL MPI_File_get_size(mpi_file_handler,total_file_size,ierr) !! Compute Offsets And Data Size local_data_size = (total_file_size - bytes_per_character*header_length)/& & this%process_grid%total_processors IF (local_data_size .LT. 2*MAX_LINE_LENGTH) THEN local_data_size = 2*MAX_LINE_LENGTH END IF local_offset = bytes_per_character*header_length + & local_data_size*this%process_grid%global_rank !! Check if this processor has any work to do, and set the appropriate !! buffer size. We also add some buffer space, so you can read beyond !! your local data size in case the local data read ends in the middle !! of a line. IF (local_offset .LT. total_file_size) THEN local_data_size_plus_buffer = local_data_size + & & MAX_LINE_LENGTH*bytes_per_character IF (local_offset + local_data_size_plus_buffer .GT. & & total_file_size) THEN local_data_size_plus_buffer = total_file_size - local_offset END IF IF (this%process_grid%global_rank .EQ. & & this%process_grid%total_processors-1) THEN local_data_size_plus_buffer = total_file_size - local_offset END IF ELSE local_data_size_plus_buffer = 0 END IF !! A buffer to read the data into. ALLOCATE(CHARACTER(LEN=local_data_size_plus_buffer) :: mpi_input_buffer) !! Do Actual Reading CALL MPI_File_read_at_all(mpi_file_handler, local_offset, & & mpi_input_buffer, INT(local_data_size_plus_buffer), & & MPI_CHARACTER, message_status, ierr) !! Trim Off The Half Read Line At The Start IF (.NOT. this%process_grid%global_rank .EQ. & & this%process_grid%RootID) THEN full_buffer_counter = INDEX(mpi_input_buffer,new_LINE('A')) + 1 ELSE full_buffer_counter = 1 END IF !! Read By Line end_of_buffer = .FALSE. IF (local_data_size_plus_buffer .EQ. 0) THEN end_of_buffer = .TRUE. END IF IF (this%is_complex) THEN CALL ConstructTripletList(triplet_list_c) ELSE CALL ConstructTripletList(triplet_list_r) END IF DO WHILE(.NOT. end_of_buffer) current_line_length = INDEX(mpi_input_buffer(full_buffer_counter:),& new_LINE('A')) IF (current_line_length .EQ. 0) THEN !! Hit The End Of The Buffer end_of_buffer = .TRUE. ELSE temp_substring = mpi_input_buffer(full_buffer_counter: & & full_buffer_counter+current_line_length-1) IF (current_line_length .GT. 1) THEN IF (data_type .EQ. MM_COMPLEX) THEN READ(temp_substring(:current_line_length-1),*) & & temp_triplet_c%index_row, & & temp_triplet_c%index_column, & & realval, cval temp_triplet_c%point_value = & & CMPLX(realval, cval, KIND=NTCOMPLEX) CALL AppendToTripletList(triplet_list_c, temp_triplet_c) ELSE READ(temp_substring(:current_line_length-1),*) & & temp_triplet_r%index_row, & & temp_triplet_r%index_column, & & temp_triplet_r%point_value CALL AppendToTripletList(triplet_list_r, temp_triplet_r) END IF END IF IF (full_buffer_counter + current_line_length .GE. & & local_data_size+2) THEN IF (.NOT. this%process_grid%global_rank .EQ. & & this%process_grid%total_processors-1) THEN end_of_buffer = .TRUE. END IF END IF full_buffer_counter = full_buffer_counter + current_line_length END IF END DO !! Cleanup CALL MPI_File_close(mpi_file_handler,ierr) CALL StopTimer("MPI Read Text") CALL MPI_Barrier(this%process_grid%global_comm,ierr) !! Redistribute The Matrix IF (this%is_complex) THEN CALL SymmetrizeTripletList(triplet_list_c, pattern_type) CALL FillMatrixFromTripletList(this,triplet_list_c) CALL DestructTripletList(triplet_list_c) ELSE CALL SymmetrizeTripletList(triplet_list_r, pattern_type) CALL FillMatrixFromTripletList(this,triplet_list_r) CALL DestructTripletList(triplet_list_r) END IF DEALLOCATE(mpi_input_buffer) END IF END SUBROUTINE ConstructMatrixFromMatrixMarket_ps !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Construct a distributed sparse matrix from a binary file in parallel. !> Faster than text, so this is good for check pointing. RECURSIVE SUBROUTINE ConstructMatrixFromBinary_ps(this, file_name, & & process_grid_in) !> The file being constructed. TYPE(Matrix_ps), INTENT(INOUT) :: this !> Grid to distribute the matrix on. TYPE(ProcessGrid_t), INTENT(IN), OPTIONAL :: process_grid_in !> The name of the file to read. CHARACTER(len=*), INTENT(IN) :: file_name !! Local Data INTEGER :: triplet_mpi_type TYPE(TripletList_r) :: triplet_list_r TYPE(TripletList_c) :: triplet_list_c !! File Handles INTEGER :: mpi_file_handler !! Reading The File INTEGER :: matrix_rows, matrix_columns, total_values, complex_flag INTEGER, DIMENSION(4) :: matrix_information INTEGER :: local_triplets INTEGER(KIND=MPI_OFFSET_KIND) :: local_offset INTEGER(KIND=MPI_OFFSET_KIND) :: header_size INTEGER :: bytes_per_int, bytes_per_data !! Temporary variables INTEGER :: message_status(MPI_STATUS_SIZE) INTEGER :: ierr TYPE(Error_t) :: err LOGICAL :: error_occured IF (.NOT. PRESENT(process_grid_in)) THEN CALL ConstructMatrixFromBinary(this, file_name, global_grid) ELSE CALL ConstructError(err) CALL StartTimer("MPI Read Binary") CALL MPI_File_open(process_grid_in%global_comm, file_name, & & MPI_MODE_RDONLY, MPI_INFO_NULL, mpi_file_handler, ierr) error_occured = CheckMPIError(err, TRIM(file_name)//" doesn't exist", & & ierr, .TRUE.) !! Get The Matrix Parameters IF (IsRoot(process_grid_in)) THEN local_offset = 0 CALL MPI_File_read_at(mpi_file_handler, local_offset, & & matrix_information, 4, MPINTINTEGER, message_status, ierr) matrix_rows = matrix_information(1) matrix_columns = matrix_information(2) total_values = matrix_information(3) complex_flag = matrix_information(4) END IF !! Broadcast Parameters CALL MPI_Bcast(matrix_rows, 1, MPINTINTEGER, process_grid_in%RootID, & & process_grid_in%global_comm, ierr) CALL MPI_Bcast(matrix_columns, 1, MPINTINTEGER, process_grid_in%RootID, & & process_grid_in%global_comm, ierr) CALL MPI_Bcast(total_values, 1, MPINTINTEGER ,process_grid_in%RootID, & & process_grid_in%global_comm, ierr) CALL MPI_Bcast(complex_flag, 1, MPINTINTEGER ,process_grid_in%RootID, & & process_grid_in%global_comm, ierr) !! Build Local Storage IF (complex_flag .EQ. 1) THEN CALL ConstructEmptyMatrix(this, matrix_rows, process_grid_in, & & is_complex_in=.TRUE.) ELSE CALL ConstructEmptyMatrix(this, matrix_rows, process_grid_in, & & is_complex_in=.FALSE.) END IF CALL MPI_Type_extent(MPINTINTEGER,bytes_per_int,ierr) IF (this%is_complex) THEN CALL MPI_Type_extent(MPINTCOMPLEX,bytes_per_data,ierr) triplet_mpi_type = GetMPITripletType_c() ELSE CALL MPI_Type_extent(MPINTREAL,bytes_per_data,ierr) triplet_mpi_type = GetMPITripletType_r() END IF !! Compute Offset local_triplets = total_values/this%process_grid%total_processors local_offset = local_triplets * (this%process_grid%global_rank) header_size = 4 * bytes_per_int IF (this%process_grid%global_rank .EQ. & & this%process_grid%total_processors - 1) THEN local_triplets = INT(total_values) - INT(local_offset) END IF local_offset = local_offset*(bytes_per_int*2+bytes_per_data) + & & header_size !! Do The Actual Reading CALL MPI_File_set_view(mpi_file_handler,local_offset,triplet_mpi_type,& & triplet_mpi_type,"native",MPI_INFO_NULL,ierr) IF (this%is_complex) THEN CALL ConstructTripletList(triplet_list_c, local_triplets) CALL MPI_File_read_all(mpi_file_handler, triplet_list_c%DATA, & & local_triplets, triplet_mpi_type, message_status, ierr) ELSE CALL ConstructTripletList(triplet_list_r, local_triplets) CALL MPI_File_read_all(mpi_file_handler, triplet_list_r%DATA, & & local_triplets, triplet_mpi_type, message_status, ierr) END IF CALL MPI_File_close(mpi_file_handler,ierr) CALL StopTimer("MPI Read Binary") IF (this%is_complex) THEN CALL FillMatrixFromTripletList(this,triplet_list_c) CALL DestructTripletList(triplet_list_c) ELSE CALL FillMatrixFromTripletList(this,triplet_list_r) CALL DestructTripletList(triplet_list_r) END IF END IF END SUBROUTINE ConstructMatrixFromBinary_ps !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Save a distributed sparse matrix to a binary file. !> Faster than text, so this is good for check pointing. SUBROUTINE WriteMatrixToBinary_ps(this,file_name) !> The Matrix to write. TYPE(Matrix_ps), INTENT(IN) :: this !> The name of the file to write to. CHARACTER(len=*), INTENT(IN) :: file_name !! Local Data INTEGER :: triplet_mpi_type IF (this%is_complex) THEN triplet_mpi_type = GetMPITripletType_c() CALL WriteMatrixToBinary_psc(this, file_name, triplet_mpi_type) ELSE triplet_mpi_type = GetMPITripletType_r() CALL WriteMatrixToBinary_psr(this, file_name, triplet_mpi_type) END IF END SUBROUTINE WriteMatrixToBinary_ps !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Implementation of write to binary. SUBROUTINE WriteMatrixToBinary_psr(this, file_name, triplet_mpi_type) !> The Matrix to write. TYPE(Matrix_ps), INTENT(IN) :: this !> The name of the file to write to. CHARACTER(len=*), INTENT(IN) :: file_name !> The triplet type, which distinguishes real and complex triplets. INTEGER, INTENT(IN) :: triplet_mpi_type !! Local Data TYPE(TripletList_r) :: triplet_list TYPE(Matrix_lsr) :: merged_local_data INCLUDE "distributed_includes/WriteMatrixToBinary.f90" END SUBROUTINE WriteMatrixToBinary_psr !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Implementation of write to binary. SUBROUTINE WriteMatrixToBinary_psc(this, file_name, triplet_mpi_type) !> The Matrix to write. TYPE(Matrix_ps), INTENT(IN) :: this !> The name of the file to write to. CHARACTER(len=*), INTENT(IN) :: file_name !> The triplet type, which distinguishes real and complex triplets. INTEGER, INTENT(IN) :: triplet_mpi_type !! Local Data TYPE(TripletList_c) :: triplet_list TYPE(Matrix_lsc) :: merged_local_data INCLUDE "distributed_includes/WriteMatrixToBinary.f90" END SUBROUTINE WriteMatrixToBinary_psc !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Write a distributed sparse matrix to a matrix market file. !> Read \cite boisvert1996matrix for the details. SUBROUTINE WriteMatrixToMatrixMarket_ps(this,file_name) !> The Matrix to write. TYPE(Matrix_ps), INTENT(IN) :: this !> The name of the file to write to. CHARACTER(len=*), INTENT(IN) :: file_name IF (this%is_complex) THEN CALL WriteMatrixToMatrixMarket_psc(this, file_name) ELSE CALL WriteMatrixToMatrixMarket_psr(this, file_name) END IF END SUBROUTINE WriteMatrixToMatrixMarket_ps !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Write to matrix market implementation for real data. SUBROUTINE WriteMatrixToMatrixMarket_psr(this,file_name) !> The Matrix to write. TYPE(Matrix_ps), INTENT(IN) :: this !> The name of the file to write to. CHARACTER(len=*), INTENT(IN) :: file_name !! Local Data TYPE(TripletList_r) :: triplet_list TYPE(Matrix_lsr) :: merged_local_data #include "distributed_includes/WriteToMatrixMarket.f90" END SUBROUTINE WriteMatrixToMatrixMarket_psr !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Write to matrix market implementation for complex data. SUBROUTINE WriteMatrixToMatrixMarket_psc(this,file_name) !> The Matrix to write. TYPE(Matrix_ps), INTENT(IN) :: this !> The name of the file to write to. CHARACTER(len=*), INTENT(IN) :: file_name !! Local Data TYPE(TripletList_c) :: triplet_list TYPE(Matrix_lsc) :: merged_local_data #define ISCOMPLEX #include "distributed_includes/WriteToMatrixMarket.f90" #undef ISCOMPLEX END SUBROUTINE WriteMatrixToMatrixMarket_psc !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> This routine fills in a matrix based on local triplet lists. Each process !> should pass in triplet lists with global coordinates. It does not matter !> where each triplet is stored, as long as global coordinates are given. !> However, if you explicitly set prepartitioned_in to True, all data must be !> on the correct process. In that case, there is no communication required. SUBROUTINE FillMatrixFromTripletList_psr(this, triplet_list, & & preduplicated_in, prepartitioned_in) !> The matrix to fill. TYPE(Matrix_ps) :: this !> The triplet list of values. TYPE(TripletList_r) :: triplet_list !> If lists are preduplicated across slices set this to true. LOGICAL, INTENT(IN), OPTIONAL :: preduplicated_in !> If all lists only contain local matrix elements set this to true. LOGICAL, INTENT(IN), OPTIONAL :: prepartitioned_in !! Local Data TYPE(Matrix_ps) :: temp_matrix TYPE(TripletList_r) :: shifted TYPE(TripletList_r) :: sorted_triplet_list TYPE(Matrix_lsr) :: local_matrix TYPE(Matrix_lsr) :: gathered_matrix !! Local Data TYPE(Permutation_t) :: basic_permutation REAL(NTREAL), PARAMETER :: threshold = 0.0_NTREAL LOGICAL :: preduplicated LOGICAL :: prepartitioned IF (this%is_complex) THEN CALL ConvertMatrixToReal(this, temp_matrix) CALL CopyMatrix(temp_matrix, this) CALL DestructMatrix(temp_matrix) END IF INCLUDE "distributed_includes/FillMatrixFromTripletList.f90" END SUBROUTINE FillMatrixFromTripletList_psr !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> This routine fills in a matrix based on local triplet lists. Each process !> should pass in triplet lists with global coordinates. It does not matter !> where each triplet is stored, as long as global coordinates are given. !> However, if you explicitly set prepartitioned_in to True, all data must be !> on the correct process. In that case, there is no communication required. SUBROUTINE FillMatrixFromTripletList_psc(this, triplet_list, & & preduplicated_in, prepartitioned_in) !> The matrix to fill. TYPE(Matrix_ps) :: this !> The triplet list of values. TYPE(TripletList_c) :: triplet_list !> If lists are preduplicated across slices set this to true. LOGICAL, INTENT(IN), OPTIONAL :: preduplicated_in !> If all lists only contain local matrix elements set this to true. LOGICAL, INTENT(IN), OPTIONAL :: prepartitioned_in !! Local Data TYPE(TripletList_c) :: shifted TYPE(TripletList_c) :: sorted_triplet_list TYPE(Matrix_lsc) :: local_matrix TYPE(Matrix_lsc) :: gathered_matrix !! Local Data TYPE(Matrix_ps) :: temp_matrix TYPE(Permutation_t) :: basic_permutation REAL(NTREAL), PARAMETER :: threshold = 0.0_NTREAL LOGICAL :: preduplicated LOGICAL :: prepartitioned IF (.NOT. this%is_complex) THEN CALL ConvertMatrixToComplex(this, temp_matrix) CALL CopyMatrix(temp_matrix, this) CALL DestructMatrix(temp_matrix) END IF INCLUDE "distributed_includes/FillMatrixFromTripletList.f90" END SUBROUTINE FillMatrixFromTripletList_psc !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Fill in the values of a distributed matrix with the identity matrix. SUBROUTINE FillMatrixIdentity_ps(this) !> The matrix being filled. TYPE(Matrix_ps), INTENT(INOUT) :: this IF (this%is_complex) THEN CALL FillMatrixIdentity_psc(this) ELSE CALL FillMatrixIdentity_psr(this) END IF END SUBROUTINE FillMatrixIdentity_ps !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Fill in the values of a distributed matrix with the identity matrix. SUBROUTINE FillMatrixIdentity_psr(this) !> The matrix being filled. TYPE(Matrix_ps), INTENT(INOUT) :: this !! Local Data TYPE(TripletList_r) :: triplet_list INCLUDE "distributed_includes/FillMatrixIdentity.f90" END SUBROUTINE FillMatrixIdentity_psr !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Fill in the values of a distributed matrix with the identity matrix. SUBROUTINE FillMatrixIdentity_psc(this) !> The matrix being filled. TYPE(Matrix_ps), INTENT(INOUT) :: this !! Local Data TYPE(TripletList_c) :: triplet_list INCLUDE "distributed_includes/FillMatrixIdentity.f90" END SUBROUTINE FillMatrixIdentity_psc !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Fill in the values of a distributed matrix with a permutation. !> If you do not specify permuterows, will default to permuting rows. SUBROUTINE FillMatrixPermutation_ps(this, permutation_vector, permute_rows_in) !> The matrix being filled. TYPE(Matrix_ps), INTENT(INOUT) :: this !> Describes for each row/column, where it goes. INTEGER, DIMENSION(:), INTENT(IN) :: permutation_vector !> If true permute rows, false permute columns. LOGICAL, OPTIONAL, INTENT(IN) :: permute_rows_in !! Local Data LOGICAL :: permute_rows !! Figure out what type of permutation IF (PRESENT(permute_rows_in) .AND. permute_rows_in .EQV. .FALSE.) THEN permute_rows = .FALSE. ELSE permute_rows = .TRUE. END IF IF (this%is_complex) THEN CALL FillMatrixPermutation_psc(this, permutation_vector, permute_rows) ELSE CALL FillMatrixPermutation_psr(this, permutation_vector, permute_rows) END IF END SUBROUTINE FillMatrixPermutation_ps !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Fill permutation implementation. SUBROUTINE FillMatrixPermutation_psr(this, permutation_vector, rows) !> The matrix being filled. TYPE(Matrix_ps), INTENT(INOUT) :: this !> Describes for each row/column, where it goes. INTEGER, DIMENSION(:), INTENT(IN) :: permutation_vector !> If true permute rows, false permute columns. LOGICAL, INTENT(IN) :: rows !! Local Data TYPE(TripletList_r) :: triplet_list INCLUDE "distributed_includes/FillMatrixPermutation.f90" END SUBROUTINE FillMatrixPermutation_psr !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Fill permutation implementation. SUBROUTINE FillMatrixPermutation_psc(this, permutation_vector, rows) !> The matrix being filled. TYPE(Matrix_ps), INTENT(INOUT) :: this !> Describes for each row/column, where it goes. INTEGER, DIMENSION(:), INTENT(IN) :: permutation_vector !> If true permute rows, false permute columns. LOGICAL, INTENT(IN) :: rows !! Local Data TYPE(TripletList_c) :: triplet_list INCLUDE "distributed_includes/FillMatrixPermutation.f90" END SUBROUTINE FillMatrixPermutation_psc !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Extracts a triplet list of the data that is stored on this process. !> Data is returned with absolute coordinates. SUBROUTINE GetMatrixTripletList_psr(this, triplet_list) !> The distributed sparse matrix. TYPE(Matrix_ps), INTENT(IN) :: this !> The list to fill. TYPE(TripletList_r), INTENT(INOUT) :: triplet_list !! Local Data TYPE(Matrix_ps) :: working_matrix TYPE(Matrix_lsr) :: merged_local_data IF (this%is_complex) THEN CALL ConvertMatrixToReal(this, working_matrix) ELSE CALL CopyMatrix(this, working_matrix) END IF INCLUDE "distributed_includes/GetMatrixTripletList.f90" END SUBROUTINE GetMatrixTripletList_psr !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Extracts a triplet list of the data that is stored on this process. !> Data is returned with absolute coordinates. SUBROUTINE GetMatrixTripletList_psc(this, triplet_list) !> The distributed sparse matrix. TYPE(Matrix_ps), INTENT(IN) :: this !> The list to fill. TYPE(TripletList_c), INTENT(INOUT) :: triplet_list !! Local Data TYPE(Matrix_ps) :: working_matrix TYPE(Matrix_lsc) :: merged_local_data IF (.NOT. this%is_complex) THEN CALL ConvertMatrixToComplex(this, working_matrix) ELSE CALL CopyMatrix(this, working_matrix) END IF INCLUDE "distributed_includes/GetMatrixTripletList.f90" END SUBROUTINE GetMatrixTripletList_psc !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Extract an arbitrary block of a matrix into a triplet list. Block is !> defined by the row/column start/end values. !> This is slower than GetMatrixTripletList, because communication is required !> Data is returned with absolute coordinates. SUBROUTINE GetMatrixBlock_psr(this, triplet_list, start_row, end_row, & & start_column, end_column) !> The distributed sparse matrix. TYPE(Matrix_ps), INTENT(IN) :: this !> The list to fill. TYPE(TripletList_r), INTENT(INOUT) :: triplet_list !> The starting row for data to store on this process. INTEGER :: start_row !> The ending row for data to store on this process. INTEGER :: end_row !> The starting col for data to store on this process INTEGER :: start_column !> The ending col for data to store on this process INTEGER :: end_column !! Local Data TYPE(Matrix_ps) :: working_matrix TYPE(Matrix_lsr) :: merged_local_data TYPE(TripletList_r) :: local_triplet_list !! Send Buffer REAL(NTREAL), DIMENSION(:), ALLOCATABLE :: send_buffer_val !! Receive Buffer REAL(NTREAL), DIMENSION(:), ALLOCATABLE :: recv_buffer_val !! Temp Values TYPE(Triplet_r) :: temp_triplet !! Local Data INTEGER, DIMENSION(:), ALLOCATABLE :: row_start_list INTEGER, DIMENSION(:), ALLOCATABLE :: column_start_list INTEGER, DIMENSION(:), ALLOCATABLE :: row_end_list INTEGER, DIMENSION(:), ALLOCATABLE :: column_end_list !! Send Buffer INTEGER, DIMENSION(:), ALLOCATABLE :: send_per_proc INTEGER, DIMENSION(:), ALLOCATABLE :: send_buffer_offsets INTEGER, DIMENSION(:), ALLOCATABLE :: send_buffer_row INTEGER, DIMENSION(:), ALLOCATABLE :: send_buffer_col !! Receive Buffer INTEGER, DIMENSION(:), ALLOCATABLE :: recv_buffer_offsets INTEGER, DIMENSION(:), ALLOCATABLE :: recv_per_proc INTEGER, DIMENSION(:), ALLOCATABLE :: recv_buffer_row INTEGER, DIMENSION(:), ALLOCATABLE :: recv_buffer_col !! Temporary INTEGER :: II, PP INTEGER :: ierr IF (this%is_complex) THEN CALL ConvertMatrixToReal(this, working_matrix) ELSE CALL CopyMatrix(this, working_matrix) END IF #define MPIDATATYPE MPINTREAL #include "distributed_includes/GetMatrixBlock.f90" #undef MPIDATATYPE END SUBROUTINE GetMatrixBlock_psr !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Extract an arbitrary block of a matrix into a triplet list. Block is !> defined by the row/column start/end values. !> This is slower than GetMatrixTripletList, because communication is required !> Data is returned with absolute coordinates. SUBROUTINE GetMatrixBlock_psc(this, triplet_list, start_row, end_row, & & start_column, end_column) !> The distributed sparse matrix. TYPE(Matrix_ps), INTENT(IN) :: this !> The list to fill. TYPE(TripletList_c), INTENT(INOUT) :: triplet_list !> The starting row for data to store on this process. INTEGER :: start_row !> The ending row for data to store on this process. INTEGER :: end_row !> The starting col for data to store on this process INTEGER :: start_column !> The ending col for data to store on this process INTEGER :: end_column !! Local Data TYPE(Matrix_ps) :: working_matrix TYPE(Matrix_lsc) :: merged_local_data TYPE(TripletList_c) :: local_triplet_list !! Send Buffer COMPLEX(NTCOMPLEX), DIMENSION(:), ALLOCATABLE :: send_buffer_val !! Receive Buffer COMPLEX(NTCOMPLEX), DIMENSION(:), ALLOCATABLE :: recv_buffer_val !! Temp Values TYPE(Triplet_c) :: temp_triplet !! Local Data INTEGER, DIMENSION(:), ALLOCATABLE :: row_start_list INTEGER, DIMENSION(:), ALLOCATABLE :: column_start_list INTEGER, DIMENSION(:), ALLOCATABLE :: row_end_list INTEGER, DIMENSION(:), ALLOCATABLE :: column_end_list !! Send Buffer INTEGER, DIMENSION(:), ALLOCATABLE :: send_per_proc INTEGER, DIMENSION(:), ALLOCATABLE :: send_buffer_offsets INTEGER, DIMENSION(:), ALLOCATABLE :: send_buffer_row INTEGER, DIMENSION(:), ALLOCATABLE :: send_buffer_col !! Receive Buffer INTEGER, DIMENSION(:), ALLOCATABLE :: recv_buffer_offsets INTEGER, DIMENSION(:), ALLOCATABLE :: recv_per_proc INTEGER, DIMENSION(:), ALLOCATABLE :: recv_buffer_row INTEGER, DIMENSION(:), ALLOCATABLE :: recv_buffer_col !! Temporary INTEGER :: II, PP INTEGER :: ierr IF (.NOT. this%is_complex) THEN CALL ConvertMatrixToComplex(this, working_matrix) ELSE CALL CopyMatrix(this, working_matrix) END IF #define MPIDATATYPE MPINTCOMPLEX #include "distributed_includes/GetMatrixBlock.f90" #undef MPIDATATYPE END SUBROUTINE GetMatrixBlock_psc !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Copy an arbitrary slice from a matrix into a new smaller matrix. !> NTPoly only works with square matrices, so if the number of rows and !> columns is different the matrix is resized to the maximum size. SUBROUTINE GetMatrixSlice(this, submatrix, start_row, end_row, & & start_column, end_column) !> The distributed sparse matrix. TYPE(Matrix_ps), INTENT(IN) :: this !> The slice to fill. TYPE(Matrix_ps), INTENT(INOUT) :: submatrix !> The starting row to include in this matrix. INTEGER :: start_row !> The ending row to include in this matrix. INTEGER :: end_row !> The starting column to include in this matrix. INTEGER :: start_column !> The last column to include in this matrix. INTEGER :: end_column !! Get a triplet list with the values IF (this%is_complex) THEN CALL GetMatrixSlice_psc(this, submatrix, start_row, end_row, & & start_column, end_column) ELSE CALL GetMatrixSlice_psr(this, submatrix, start_row, end_row, & & start_column, end_column) END IF END SUBROUTINE GetMatrixSlice !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Implements slice matrix for real types. SUBROUTINE GetMatrixSlice_psr(this, submatrix, start_row, end_row, & & start_column, end_column) !> The distributed sparse matrix. TYPE(Matrix_ps), INTENT(IN) :: this !> The slice to fill. TYPE(Matrix_ps), INTENT(INOUT) :: submatrix !> The starting row to include in this matrix. INTEGER :: start_row !> The ending row to include in this matrix. INTEGER :: end_row !> The starting column to include in this matrix. INTEGER :: start_column !> The last column to include in this matrix. INTEGER :: end_column #define TLISTTYPE TripletList_r #define TTYPE Triplet_r #include "distributed_includes/SliceMatrix.f90" #undef TLISTTYPE #undef TTYPE END SUBROUTINE GetMatrixSlice_psr !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Implements slice matrix for complex types. SUBROUTINE GetMatrixSlice_psc(this, submatrix, start_row, end_row, & & start_column, end_column) !> The distributed sparse matrix. TYPE(Matrix_ps), INTENT(IN) :: this !> The slice to fill. TYPE(Matrix_ps), INTENT(INOUT) :: submatrix !> The starting row to include in this matrix. INTEGER :: start_row !> The ending row to include in this matrix. INTEGER :: end_row !> The starting column to include in this matrix. INTEGER :: start_column !> The last column to include in this matrix. INTEGER :: end_column #define TLISTTYPE TripletList_c #define TTYPE Triplet_c #include "distributed_includes/SliceMatrix.f90" #undef TLISTTYPE #undef TTYPE END SUBROUTINE GetMatrixSlice_psc !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Get the actual dimension of the matrix. PURE FUNCTION GetMatrixActualDimension_ps(this) RESULT(DIMENSION) !> The matrix. TYPE(Matrix_ps), INTENT(IN) :: this !> Dimension of the matrix INTEGER :: DIMENSION DIMENSION = this%actual_matrix_dimension END FUNCTION GetMatrixActualDimension_ps !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Get the logical dimension of the matrix. !> Includes padding. PURE FUNCTION GetMatrixLogicalDimension_ps(this) RESULT(DIMENSION) !> The matrix. TYPE(Matrix_ps), INTENT(IN) :: this !> Dimension of the matrix INTEGER :: DIMENSION DIMENSION = this%logical_matrix_dimension END FUNCTION GetMatrixLogicalDimension_ps !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Print out information about a distributed sparse matrix. !> Sparsity, and load balancing information. SUBROUTINE PrintMatrixInformation_ps(this) !> This the matrix to print information about. TYPE(Matrix_ps), INTENT(IN) :: this !! Local Data INTEGER :: min_size, max_size REAL(NTREAL) :: sparsity CALL GetMatrixLoadBalance(this,min_size,max_size) sparsity = REAL(GetMatrixSize(this),KIND=NTREAL) / & & (REAL(this%actual_matrix_dimension,KIND=NTREAL)**2) CALL WriteHeader("Load_Balance") CALL EnterSubLog CALL WriteListElement(key="min_size", VALUE=min_size) CALL WriteListElement(key="max_size", VALUE=max_size) CALL ExitSubLog CALL WriteElement(key="Dimension",VALUE=this%actual_matrix_dimension) CALL WriteElement(key="Sparsity", VALUE=sparsity) END SUBROUTINE PrintMatrixInformation_ps !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Print out a distributed sparse matrix. !> This is a serial print routine, and should probably only be used for debug !> purposes. SUBROUTINE PrintMatrix_ps(this, file_name_in) !> The matrix to print. TYPE(Matrix_ps) :: this !> Optionally, you can pass a file to print to instead of the console. CHARACTER(len=*), OPTIONAL, INTENT(IN) :: file_name_in IF (this%is_complex) THEN IF (PRESENT(file_name_in)) THEN CALL PrintMatrix_psc(this, file_name_in) ELSE CALL PrintMatrix_psc(this) END IF ELSE IF (PRESENT(file_name_in)) THEN CALL PrintMatrix_psr(this, file_name_in) ELSE CALL PrintMatrix_psr(this) END IF END IF END SUBROUTINE PrintMatrix_ps !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Print matrix implementation (real). SUBROUTINE PrintMatrix_psr(this, file_name_in) !> The matrix to print. TYPE(Matrix_ps) :: this !> Optionally, you can pass a file to print to instead of the console. CHARACTER(len=*), OPTIONAL, INTENT(IN) :: file_name_in !! Temporary Variables TYPE(Matrix_lsr) :: local_mat INCLUDE "distributed_includes/PrintMatrix.f90" END SUBROUTINE PrintMatrix_psr !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Print matrix implementation (complex). SUBROUTINE PrintMatrix_psc(this, file_name_in) !> The matrix to print. TYPE(Matrix_ps) :: this !> Optionally, you can pass a file to print to instead of the console. CHARACTER(len=*), OPTIONAL, INTENT(IN) :: file_name_in !! Temporary Variables TYPE(Matrix_lsc) :: local_mat INCLUDE "distributed_includes/PrintMatrix.f90" END SUBROUTINE PrintMatrix_psc !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> A utility routine that filters a sparse matrix. !> All (absolute) values below the threshold are set to zero. SUBROUTINE FilterMatrix_ps(this, threshold) !> The matrix to filter. TYPE(Matrix_ps), INTENT(INOUT) :: this !> Threshold (absolute) values below this are filtered REAL(NTREAL), INTENT(IN) :: threshold IF (this%is_complex) THEN CALL FilterMatrix_psc(this, threshold) ELSE CALL FilterMatrix_psr(this, threshold) END IF END SUBROUTINE FilterMatrix_ps !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Filter matrix implementation (real). SUBROUTINE FilterMatrix_psr(this, threshold) !> The matrix to filter. TYPE(Matrix_ps), INTENT(INOUT) :: this !> Threshold (absolute) values below this are filtered REAL(NTREAL), INTENT(IN) :: threshold !! Local Variables TYPE(TripletList_r) :: triplet_list TYPE(TripletList_r) :: new_list TYPE(Triplet_r) :: temporary INCLUDE "distributed_includes/FilterMatrix.f90" END SUBROUTINE FilterMatrix_psr !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Filter matrix implementation (real). SUBROUTINE FilterMatrix_psc(this, threshold) !> The matrix to filter. TYPE(Matrix_ps), INTENT(INOUT) :: this !> Threshold (absolute) values below this are filtered REAL(NTREAL), INTENT(IN) :: threshold !! Local Variables TYPE(TripletList_c) :: triplet_list TYPE(TripletList_c) :: new_list TYPE(Triplet_c) :: temporary INCLUDE "distributed_includes/FilterMatrix.f90" END SUBROUTINE FilterMatrix_psc !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Get the total number of non-zero entries in the distributed sparse matrix. FUNCTION GetMatrixSize_ps(this) RESULT(total_size) !> The matrix to calculate the number of non-zero entries of. TYPE(Matrix_ps), INTENT(IN) :: this !> The number of non-zero entries in the matrix. INTEGER(NTLONG) :: total_size !! Local Data REAL(NTREAL) :: local_size REAL(NTREAL) :: temp_size TYPE(Matrix_lsc) :: merged_local_data_c TYPE(Matrix_lsr) :: merged_local_data_r INTEGER :: ierr !! Merge all the local data IF (this%is_complex) THEN CALL MergeMatrixLocalBlocks(this, merged_local_data_c) local_size = SIZE(merged_local_data_c%values) CALL DestructMatrix(merged_local_data_c) ELSE CALL MergeMatrixLocalBlocks(this, merged_local_data_r) local_size = SIZE(merged_local_data_r%values) CALL DestructMatrix(merged_local_data_r) END IF !! Global Sum CALL MPI_Allreduce(local_size,temp_size,1,MPINTREAL,MPI_SUM,& & this%process_grid%within_slice_comm, ierr) total_size = INT(temp_size, kind=NTLONG) END FUNCTION GetMatrixSize_ps !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Get a measure of how load balanced this matrix is. For each process, the !> number of non-zero entries is calculated. Then, this function returns !> the max and min of those values. SUBROUTINE GetMatrixLoadBalance_ps(this, min_size, max_size) !> The matrix to compute the measure on. TYPE(Matrix_ps), INTENT(IN) :: this !> The minimum entries contained on a single process. INTEGER, INTENT(OUT) :: min_size !> The maximum entries contained on a single process. INTEGER, INTENT(OUT) :: max_size !! Local Data INTEGER :: local_size TYPE(Matrix_lsc) :: merged_local_data_c TYPE(Matrix_lsr) :: merged_local_data_r INTEGER :: ierr !! Merge all the local data IF (this%is_complex) THEN CALL MergeMatrixLocalBlocks(this, merged_local_data_c) local_size = SIZE(merged_local_data_c%values) CALL DestructMatrix(merged_local_data_c) ELSE CALL MergeMatrixLocalBlocks(this, merged_local_data_r) local_size = SIZE(merged_local_data_r%values) CALL DestructMatrix(merged_local_data_r) END IF !! Global Reduce CALL MPI_Allreduce(local_size,max_size,1,MPINTINTEGER,MPI_MAX,& & this%process_grid%within_slice_comm, ierr) CALL MPI_Allreduce(local_size,min_size,1,MPINTINTEGER,MPI_MIN,& & this%process_grid%within_slice_comm, ierr) END SUBROUTINE GetMatrixLoadBalance_ps !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Transpose a sparse matrix. Note that this is a pure transpose, there is !> no complex conjugate performed. SUBROUTINE TransposeMatrix_ps(AMat, TransMat) !> The matrix to transpose. TYPE(Matrix_ps), INTENT(IN) :: AMat !> TransMat = A^T . TYPE(Matrix_ps), INTENT(OUT) :: TransMat IF (AMat%is_complex) THEN CALL TransposeMatrix_psc(AMat, TransMat) ELSE CALL TransposeMatrix_psr(AMat, TransMat) END IF END SUBROUTINE TransposeMatrix_ps !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Transpose implementation (real). SUBROUTINE TransposeMatrix_psr(AMat, TransMat) !> The matrix to transpose. TYPE(Matrix_ps), INTENT(IN) :: AMat !> TransMat = A^T . TYPE(Matrix_ps), INTENT(OUT) :: TransMat !! Local Variables TYPE(TripletList_r) :: triplet_list TYPE(TripletList_r) :: new_list TYPE(Triplet_r) :: temporary, temporary_t INCLUDE "distributed_includes/TransposeMatrix.f90" END SUBROUTINE TransposeMatrix_psr !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Transpose implementation (complex). SUBROUTINE TransposeMatrix_psc(AMat, TransMat) !> The matrix to transpose. TYPE(Matrix_ps), INTENT(IN) :: AMat !> TransMat = A^T . TYPE(Matrix_ps), INTENT(OUT) :: TransMat !! Local Variables TYPE(TripletList_c) :: triplet_list TYPE(TripletList_c) :: new_list TYPE(Triplet_c) :: temporary, temporary_t INCLUDE "distributed_includes/TransposeMatrix.f90" END SUBROUTINE TransposeMatrix_psc !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Every value in the matrix is changed into its complex conjugate. PURE SUBROUTINE ConjugateMatrix_ps(this) !> The matrix to compute the complex conjugate of. TYPE(Matrix_ps), INTENT(INOUT) :: this !! Local Variables TYPE(Matrix_lsc) :: local_matrix IF (this%is_complex) THEN CALL MergeMatrixLocalBlocks(this, local_matrix) CALL ConjugateMatrix(local_matrix) CALL SplitMatrixToLocalBlocks(this, local_matrix) CALL DestructMatrix(local_matrix) END IF END SUBROUTINE ConjugateMatrix_ps !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Split the current communicator, and give each group a complete copy of this SUBROUTINE CommSplitMatrix_ps(this, split_mat, my_color, split_slice) !> The matrix to split. TYPE(Matrix_ps), INTENT(INOUT) :: this !> A copy of the matrix hosted on a small process grid. TYPE(Matrix_ps), INTENT(INOUT) :: split_mat !> Distinguishes between the two groups. INTEGER, INTENT(OUT) :: my_color !> If we split along the slice direction, this is True LOGICAL, INTENT(OUT) :: split_slice IF (this%is_complex) THEN CALL CommSplitMatrix_psc(this, split_mat, my_color, split_slice) ELSE CALL CommSplitMatrix_psr(this, split_mat, my_color, split_slice) END IF END SUBROUTINE CommSplitMatrix_ps !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Split implementation for real data. SUBROUTINE CommSplitMatrix_psr(this, split_mat, my_color, split_slice) !> The matrix to split. TYPE(Matrix_ps), INTENT(INOUT) :: this !> A copy of the matrix hosted on a small process grid. TYPE(Matrix_ps), INTENT(INOUT) :: split_mat !> Distinguishes between the two groups. INTEGER, INTENT(OUT) :: my_color !> If we split along the slice direction, this is True. LOGICAL, INTENT(OUT) :: split_slice !! For Data Redistribution TYPE(TripletList_r) :: full_list, new_list TYPE(TripletList_r), DIMENSION(:), ALLOCATABLE :: send_list INCLUDE "distributed_includes/CommSplitMatrix.f90" END SUBROUTINE CommSplitMatrix_psr !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Split implementation for complex data. SUBROUTINE CommSplitMatrix_psc(this, split_mat, my_color, split_slice) !> The matrix to split. TYPE(Matrix_ps), INTENT(INOUT) :: this !> A copy of the matrix hosted on a small process grid. TYPE(Matrix_ps), INTENT(INOUT) :: split_mat !> Distinguishes between the two groups. INTEGER, INTENT(OUT) :: my_color !> If we split along the slice direction, this is True. LOGICAL, INTENT(OUT) :: split_slice !! For Data Redistribution TYPE(TripletList_c) :: full_list, new_list TYPE(TripletList_c), DIMENSION(:), ALLOCATABLE :: send_list INCLUDE "distributed_includes/CommSplitMatrix.f90" END SUBROUTINE CommSplitMatrix_psc !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Redistribute the data in a matrix based on row, column list !> This will redistribute the data so that the local data are entries in !> the rows and columns list. The order of the row list and column list matter !> because local data is filled in the same order. SUBROUTINE RedistributeData_psr(this,index_lookup,reverse_index_lookup,& & initial_triplet_list,sorted_triplet_list) !> The matrix to redistribute TYPE(Matrix_ps), INTENT(INOUT) :: this !> Lookup describing how data is distributed. INTEGER, DIMENSION(:), INTENT(IN) :: index_lookup !> Reverse Lookup describing how data is distributed. INTEGER, DIMENSION(:), INTENT(IN) :: reverse_index_lookup !> The current triplet list of global coordinates. TYPE(TripletList_r), INTENT(IN) :: initial_triplet_list !> returns an allocated triplet list with local coordinates in sorted order. TYPE(TripletList_r), INTENT(OUT) :: sorted_triplet_list !! Local Data TYPE(TripletList_r) :: gathered_list TYPE(TripletList_r), DIMENSION(this%process_grid%slice_size) :: & & send_triplet_lists TYPE(Triplet_r) :: temp_triplet INCLUDE "distributed_includes/RedistributeData.f90" END SUBROUTINE RedistributeData_psr !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Redistribute the data in a matrix based on row, column list !> This will redistribute the data so that the local data are entries in !> the rows and columns list. The order of the row list and column list matter !> because local data is filled in the same order. SUBROUTINE RedistributeData_psc(this,index_lookup,reverse_index_lookup,& & initial_triplet_list,sorted_triplet_list) !> The matrix to redistribute TYPE(Matrix_ps), INTENT(INOUT) :: this !> Lookup describing how data is distributed. INTEGER, DIMENSION(:), INTENT(IN) :: index_lookup !> Reverse Lookup describing how data is distributed. INTEGER, DIMENSION(:), INTENT(IN) :: reverse_index_lookup !> The current triplet list of global coordinates. TYPE(TripletList_c), INTENT(IN) :: initial_triplet_list !> returns an allocated triplet list with local coordinates in sorted order. TYPE(TripletList_c), INTENT(OUT) :: sorted_triplet_list !! Local Data TYPE(TripletList_c) :: gathered_list TYPE(TripletList_c), DIMENSION(this%process_grid%slice_size) :: & & send_triplet_lists TYPE(Triplet_c) :: temp_triplet INCLUDE "distributed_includes/RedistributeData.f90" END SUBROUTINE RedistributeData_psc !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Calculate a matrix size that can be divided by the number of processors. PURE FUNCTION CalculateScaledDimension(this, matrix_dim) RESULT(scaled_dim) !> The matrix we are calculating for. TYPE(Matrix_ps), INTENT(IN) :: this !> The dimension of the actual matrix. INTEGER, INTENT(IN) :: matrix_dim !> A new dimension which includes padding. INTEGER :: scaled_dim !! Local Data INTEGER :: size_ratio INTEGER :: lcm lcm = this%process_grid%block_multiplier* & & this%process_grid%num_process_slices* & & this%process_grid%num_process_columns* & & this%process_grid%num_process_rows size_ratio = matrix_dim/lcm IF (size_ratio * lcm .EQ. matrix_dim) THEN scaled_dim = matrix_dim ELSE scaled_dim = (size_ratio + 1)*(lcm) END IF END FUNCTION CalculateScaledDimension !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Take a local matrix, and use it to fill the local block matrix structure. PURE SUBROUTINE SplitMatrixToLocalBlocks_psr(this, matrix_to_split) !> The distributed sparse matrix to split into. TYPE(Matrix_ps), INTENT(INOUT) :: this !> The matrix to split up. TYPE(Matrix_lsr), INTENT(IN) :: matrix_to_split #define LOCALMATRIX this%local_data_r #include "distributed_includes/SplitMatrixToLocalBlocks.f90" #undef LOCALMATRIX END SUBROUTINE SplitMatrixToLocalBlocks_psr !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Take a local matrix, and use it to fill the local block matrix structure. PURE SUBROUTINE SplitMatrixToLocalBlocks_psc(this, matrix_to_split) !> The distributed sparse matrix to split into. TYPE(Matrix_ps), INTENT(INOUT) :: this !> The matrix to split up. TYPE(Matrix_lsc), INTENT(IN) :: matrix_to_split #define LOCALMATRIX this%local_data_c #include "distributed_includes/SplitMatrixToLocalBlocks.f90" #undef LOCALMATRIX END SUBROUTINE SplitMatrixToLocalBlocks_psc !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Merge together the local matrix blocks into one big matrix. PURE SUBROUTINE MergeMatrixLocalBlocks_psr(this, merged_matrix) !> The distributed sparse matrix to merge from. TYPE(Matrix_ps), INTENT(IN) :: this !> The merged matrix. TYPE(Matrix_lsr), INTENT(INOUT) :: merged_matrix #define LOCALMATRIX this%local_data_r #include "distributed_includes/MergeMatrixLocalBlocks.f90" #undef LOCALMATRIX END SUBROUTINE MergeMatrixLocalBlocks_psr !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Merge together the local matrix blocks into one big matrix. PURE SUBROUTINE MergeMatrixLocalBlocks_psc(this, merged_matrix) !> The distributed sparse matrix to merge from. TYPE(Matrix_ps), INTENT(IN) :: this !> The merged matrix. TYPE(Matrix_lsc), INTENT(INOUT) :: merged_matrix #define LOCALMATRIX this%local_data_c #include "distributed_includes/MergeMatrixLocalBlocks.f90" #undef LOCALMATRIX END SUBROUTINE MergeMatrixLocalBlocks_psc !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Converts the current matrix to a real type matrix. SUBROUTINE ConvertMatrixToReal(in, out) !> The matrix to convert. TYPE(Matrix_ps), INTENT(IN) :: in !> Real version of the matrix. TYPE(Matrix_ps), INTENT(INOUT) :: out LOGICAL, PARAMETER :: convert_to_complex = .FALSE. !! Local Variables TYPE(Matrix_lsc) :: local_matrix TYPE(Matrix_lsr) :: converted_matrix INCLUDE "distributed_includes/ConvertMatrixType.f90" END SUBROUTINE ConvertMatrixToReal !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Converts the current matrix to a complex type matrix. SUBROUTINE ConvertMatrixToComplex(in, out) !> The matrix to convert. TYPE(Matrix_ps), INTENT(IN) :: in !> Complex version of the matrix. TYPE(Matrix_ps), INTENT(INOUT) :: out LOGICAL, PARAMETER :: convert_to_complex = .TRUE. !! Local Variables TYPE(Matrix_lsr) :: local_matrix TYPE(Matrix_lsc) :: converted_matrix INCLUDE "distributed_includes/ConvertMatrixType.f90" END SUBROUTINE ConvertMatrixToComplex !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Change the size of a matrix. !> If the new size is smaller, then values outside that range are deleted. !> IF the new size is bigger, zero padding is applied. !> Warning: this requires a full data redistribution. SUBROUTINE ResizeMatrix(this, new_size) !> The matrix to resize. TYPE(Matrix_ps), INTENT(INOUT) :: this !> The new size of the matrix. INTEGER, INTENT(IN) :: new_size IF (this%is_complex) THEN CALL ResizeMatrix_psc(this, new_size) ELSE CALL ResizeMatrix_psr(this, new_size) END IF END SUBROUTINE ResizeMatrix !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Change the size of a matrix implementation (real). SUBROUTINE ResizeMatrix_psr(this, new_size) !> The matrix to resize. TYPE(Matrix_ps), INTENT(INOUT) :: this !> The new size of the matrix. INTEGER, INTENT(IN) :: new_size !! Local Variables TYPE(TripletList_r) :: tlist, pruned TYPE(Triplet_r) :: temp INCLUDE "distributed_includes/ResizeMatrix.f90" END SUBROUTINE ResizeMatrix_psr !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> Change the size of a matrix implementation (real). SUBROUTINE ResizeMatrix_psc(this, new_size) !> The matrix to resize. TYPE(Matrix_ps), INTENT(INOUT) :: this !> The new size of the matrix. INTEGER, INTENT(IN) :: new_size !! Local Variables TYPE(TripletList_c) :: tlist, pruned TYPE(Triplet_c) :: temp INCLUDE "distributed_includes/ResizeMatrix.f90" END SUBROUTINE ResizeMatrix_psc !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> This subroutine gathers the entire matrix into a local matrix on the !> given process. The process id is a within_slice id, so the data will !> still be replicated across slices. SUBROUTINE GatherMatrixToProcess_psr_id(this, local_mat, within_slice_id) !> The matrix to gather. TYPE(Matrix_ps), INTENT(INOUT) :: this !> The full matrix, stored in a local matrix. TYPE(Matrix_lsr), INTENT(INOUT) :: local_mat !> Which process to gather on. INTEGER, INTENT(IN) :: within_slice_id !! Local Variables TYPE(TripletList_r) :: tlist, sorted TYPE(TripletList_r), DIMENSION(:), ALLOCATABLE :: slist INCLUDE "distributed_includes/GatherMatrixToProcess.f90" END SUBROUTINE GatherMatrixToProcess_psr_id !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> This subroutine gathers the entire matrix into a local matrix on to !> every process. SUBROUTINE GatherMatrixToProcess_psr_all(this, local_mat) !> The matrix to gather. TYPE(Matrix_ps), INTENT(INOUT) :: this !> The full matrix, stored in a local matrix. TYPE(Matrix_lsr), INTENT(INOUT) :: local_mat !! Local Variables TYPE(Matrix_lsr) :: local, localT TYPE(Matrix_lsr) :: merged_columns TYPE(Matrix_lsr) :: merged_columnsT TYPE(Matrix_lsr) :: gathered INCLUDE "distributed_includes/GatherMatrixToAll.f90" END SUBROUTINE GatherMatrixToProcess_psr_all !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> This subroutine gathers the entire matrix into a local matrix on the !> given process. The process id is a within_slice id, so the data will !> still be replicated across slices. SUBROUTINE GatherMatrixToProcess_psc_id(this, local_mat, within_slice_id) !> The matrix to gather. TYPE(Matrix_ps), INTENT(INOUT) :: this !> The full matrix, stored in a local matrix. TYPE(Matrix_lsc), INTENT(INOUT) :: local_mat !> Which process to gather on. INTEGER, INTENT(IN) :: within_slice_id !! Local Variables TYPE(TripletList_c) :: tlist, sorted TYPE(TripletList_c), DIMENSION(:), ALLOCATABLE :: slist INCLUDE "distributed_includes/GatherMatrixToProcess.f90" END SUBROUTINE GatherMatrixToProcess_psc_id !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !> This subroutine gathers the entire matrix into a local matrix on to !> every process. SUBROUTINE GatherMatrixToProcess_psc_all(this, local_mat) !> The matrix to gather. TYPE(Matrix_ps), INTENT(INOUT) :: this !> The full matrix, stored in a local matrix. TYPE(Matrix_lsc), INTENT(INOUT) :: local_mat !! Local Variables TYPE(Matrix_lsc) :: local, localT TYPE(Matrix_lsc) :: merged_columns TYPE(Matrix_lsc) :: merged_columnsT TYPE(Matrix_lsc) :: gathered INCLUDE "distributed_includes/GatherMatrixToAll.f90" END SUBROUTINE GatherMatrixToProcess_psc_all !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! END MODULE PSMatrixModule