!************************************************************ ! ! This example shows how to read and write variable-length ! datatypes to a dataset. The program first writes two ! variable-length integer arrays to a dataset then closes ! the file. Next, it reopens the file, reads back the data, ! and outputs it to the screen. ! ! The data structure is a matrix which is has 2 rows ! and the number of columns varies in each row, for ! this example row 1 has LEN0 columns and row 2 has LEN1 columns ! ! This file is intended for use with HDF5 Library version 1.8 ! with --enable-fortran2003 ! !************************************************************ PROGRAM main USE HDF5 USE ISO_C_BINDING IMPLICIT NONE CHARACTER(LEN=18), PARAMETER :: filename = "h5ex_t_vlen_F03.h5" CHARACTER(LEN=3) , PARAMETER :: dataset = "DS1" INTEGER, PARAMETER :: LEN0 = 3 INTEGER, PARAMETER :: LEN1 = 12 INTEGER(HID_T) :: file, filetype, memtype, space, dset ! Handles INTEGER :: hdferr INTEGER(HSIZE_T), DIMENSION(1:2) :: maxdims INTEGER :: i, j ! vl data TYPE vl INTEGER, DIMENSION(:), POINTER :: data END TYPE vl TYPE(vl), DIMENSION(:), ALLOCATABLE :: ptr TYPE(hvl_t), DIMENSION(1:2), TARGET :: wdata ! Array of vlen structures TYPE(hvl_t), DIMENSION(1:2), TARGET :: rdata ! Pointer to vlen structures INTEGER(hsize_t), DIMENSION(1:1) :: dims = (/2/) INTEGER, DIMENSION(:), POINTER :: ptr_r TYPE(C_PTR) :: f_ptr ! ! Initialize FORTRAN interface. ! CALL h5open_f(hdferr) ! ! Initialize variable-length data. wdata(1) is a countdown of ! length LEN0, wdata(2) is a Fibonacci sequence of length LEN1. ! wdata(1)%len = LEN0 wdata(2)%len = LEN1 ALLOCATE( ptr(1:2) ) ALLOCATE( ptr(1)%data(1:wdata(1)%len) ) ALLOCATE( ptr(2)%data(1:wdata(2)%len) ) DO i=1, wdata(1)%len ptr(1)%data(i) = wdata(1)%len - i + 1 ! 3 2 1 ENDDO wdata(1)%p = C_LOC(ptr(1)%data(1)) ptr(2)%data(1:2) = 1 DO i = 3, wdata(2)%len ptr(2)%data(i) = ptr(2)%data(i-1) + ptr(2)%data(i-2) ! (1 1 2 3 5 8 etc.) ENDDO wdata(2)%p = C_LOC(ptr(2)%data(1)) ! ! Create a new file using the default properties. ! CALL h5fcreate_f(filename, H5F_ACC_TRUNC_F, file, hdferr) ! ! Create variable-length datatype for file and memory. ! CALL h5tvlen_create_f(H5T_STD_I32LE, filetype, hdferr) CALL h5tvlen_create_f(H5T_NATIVE_INTEGER, memtype, hdferr) ! ! Create dataspace. ! CALL h5screate_simple_f(1, dims, space, hdferr) ! ! Create the dataset and write the variable-length data to it. ! CALL h5dcreate_f(file, dataset, filetype, space, dset, hdferr) f_ptr = C_LOC(wdata(1)) CALL h5dwrite_f(dset, memtype, f_ptr, hdferr) CALL h5dclose_f(dset , hdferr) CALL h5sclose_f(space, hdferr) CALL h5tclose_f(filetype, hdferr) CALL h5tclose_f(memtype, hdferr) CALL h5fclose_f(file , hdferr) DEALLOCATE(ptr) ! ! Now we begin the read section of this example. ! ! Open file and dataset. ! CALL h5fopen_f(filename, H5F_ACC_RDONLY_F, file, hdferr) CALL h5dopen_f(file, dataset, dset, hdferr) ! ! Get dataspace and allocate memory for array of vlen structures. ! This does not actually allocate memory for the vlen data, that ! will be done by the library. ! CALL h5dget_space_f(dset, space, hdferr) CALL h5sget_simple_extent_dims_f(space, dims, maxdims, hdferr) ! ! Create the memory datatype. ! CALL h5tvlen_create_f(H5T_NATIVE_INTEGER, memtype, hdferr) ! ! Read the data. ! f_ptr = C_LOC(rdata(1)) CALL h5dread_f(dset, memtype, f_ptr, hdferr) ! ! Output the variable-length data to the screen. ! DO i = 1, dims(1) WRITE(*,'(A,"(",I0,"):",/,"{")', ADVANCE="no") dataset,i CALL c_f_pointer(rdata(i)%p, ptr_r, [rdata(i)%len] ) DO j = 1, rdata(i)%len WRITE(*,'(1X,I0)', ADVANCE='no') ptr_r(j) IF ( j .LT. rdata(i)%len) WRITE(*,'(",")', ADVANCE='no') ENDDO WRITE(*,'( " }")') ENDDO ! ! Close and release resources. Note the use of H5Dvlen_reclaim ! removes the need to manually deallocate the previously allocated ! data. ! CALL h5dvlen_reclaim_f(memtype, space, H5P_DEFAULT_F, f_ptr, hdferr) CALL h5dclose_f(dset , hdferr) CALL h5sclose_f(space, hdferr) CALL h5tclose_f(memtype, hdferr) CALL h5fclose_f(file , hdferr) END PROGRAM main