diff options
-rw-r--r-- | src/H5Dchunk.c | 37 | ||||
-rw-r--r-- | src/H5Dmpio.c | 149 | ||||
-rw-r--r-- | testpar/t_filters_parallel.c | 5036 | ||||
-rw-r--r-- | testpar/t_filters_parallel.h | 333 |
4 files changed, 4626 insertions, 929 deletions
diff --git a/src/H5Dchunk.c b/src/H5Dchunk.c index e3f6410..e64a60f 100644 --- a/src/H5Dchunk.c +++ b/src/H5Dchunk.c @@ -2933,8 +2933,41 @@ H5D__chunk_lookup(const H5D_t *dset, const hsize_t *scaled, H5F_set_coll_md_read(idx_info.f, temp_cmr); #endif /* H5_HAVE_PARALLEL */ - /* Cache the information retrieved */ - H5D__chunk_cinfo_cache_update(&dset->shared->cache.chunk.last, udata); + /* + * Cache the information retrieved. + * + * Note that if we are writing to the dataset in parallel and filters + * are involved, we skip caching this information as it is highly likely + * that the chunk information will be invalidated as a result of the + * filter operation (e.g. the chunk gets re-allocated to a different + * address in the file and/or gets re-allocated with a different size). + * If we were to cache this information, subsequent reads/writes would + * retrieve the invalid information and cause a variety of issues. + * + * It has been verified that in the serial library, when writing to chunks + * with the real chunk cache disabled and with filters involved, the + * functions within this file are correctly called in such a manner that + * this single chunk cache is always updated correctly. Therefore, this + * check is not needed for the serial library. + * + * This is an ugly and potentially frail check, but the + * H5D__chunk_cinfo_cache_reset() function is not currently available + * to functions outside of this file, so outside functions can not + * invalidate this single chunk cache. Even if the function were available, + * this check prevents us from doing the work of going through and caching + * each chunk in the write operation, when we're only going to invalidate + * the cache at the end of a parallel write anyway. + * + * - JTH (7/13/2018) + */ +#ifdef H5_HAVE_PARALLEL + if ( !( (H5F_HAS_FEATURE(idx_info.f, H5FD_FEAT_HAS_MPI)) + && (H5F_INTENT(dset->oloc.file) & H5F_ACC_RDWR) + && dset->shared->dcpl_cache.pline.nused + ) + ) +#endif + H5D__chunk_cinfo_cache_update(&dset->shared->cache.chunk.last, udata); } /* end if */ } /* end else */ diff --git a/src/H5Dmpio.c b/src/H5Dmpio.c index bc37840..d721ae6 100644 --- a/src/H5Dmpio.c +++ b/src/H5Dmpio.c @@ -234,7 +234,7 @@ static herr_t H5D__chunk_redistribute_shared_chunks(const H5D_io_info_t *io_info H5D_filtered_collective_io_info_t *local_chunk_array, size_t *local_chunk_array_num_entries); static herr_t H5D__mpio_array_gatherv(void *local_array, size_t local_array_num_entries, size_t array_entry_size, void **gathered_array, size_t *gathered_array_num_entries, - int nprocs, hbool_t allgather, int root, MPI_Comm comm, int (*sort_func)(const void *, const void *)); + hbool_t allgather, int root, MPI_Comm comm, int (*sort_func)(const void *, const void *)); static herr_t H5D__mpio_filtered_collective_write_type( H5D_filtered_collective_io_info_t *chunk_list, size_t num_entries, MPI_Datatype *new_mem_type, hbool_t *mem_type_derived, @@ -418,19 +418,16 @@ done: * Function: H5D__mpio_array_gatherv * * Purpose: Given an array, specified in local_array, by each processor - * calling this function, gathers each array into a single + * calling this function, collects each array into a single * array which is then either gathered to the processor * specified by root, when allgather is false, or is * distributed back to all processors when allgather is true. * - * The size of each entry and number of entries in the array - * contributed by an individual processor should be specified - * in array_entry_size and local_array_num_entries, + * The number of entries in the array contributed by an + * individual processor and the size of each entry should be + * specified in local_array_num_entries and array_entry_size, * respectively. * - * The number of processors participating in the gather - * operation should be specified for nprocs. - * * The MPI communicator to use should be specified for comm. * * If the sort_func argument is supplied, the array is sorted @@ -448,14 +445,13 @@ done: static herr_t H5D__mpio_array_gatherv(void *local_array, size_t local_array_num_entries, size_t array_entry_size, void **_gathered_array, size_t *_gathered_array_num_entries, - int nprocs, hbool_t allgather, int root, MPI_Comm comm, int (*sort_func)(const void *, const void *)) + hbool_t allgather, int root, MPI_Comm comm, int (*sort_func)(const void *, const void *)) { size_t gathered_array_num_entries = 0; /* The size of the newly-constructed array */ - size_t i; void *gathered_array = NULL; /* The newly-constructed array returned to the caller */ - int *receive_counts_array = NULL; /* Array containing number of entries each process is contributing */ - int *displacements_array = NULL; /* Array of displacements where each process places its data in the final array */ - int mpi_code; + int *receive_counts_array = NULL; /* Array containing number of entries each processor is contributing */ + int *displacements_array = NULL; /* Array of displacements where each processor places its data in the final array */ + int mpi_code, mpi_rank, mpi_size; int sendcount; herr_t ret_value = SUCCEED; @@ -464,34 +460,62 @@ H5D__mpio_array_gatherv(void *local_array, size_t local_array_num_entries, HDassert(_gathered_array); HDassert(_gathered_array_num_entries); - /* Determine the size of the end result array */ + MPI_Comm_size(comm, &mpi_size); + MPI_Comm_rank(comm, &mpi_rank); + + /* + * Determine the size of the end result array by collecting the number + * of entries contributed by each processor into a single total. + */ if (MPI_SUCCESS != (mpi_code = MPI_Allreduce(&local_array_num_entries, &gathered_array_num_entries, 1, MPI_INT, MPI_SUM, comm))) HMPI_GOTO_ERROR(FAIL, "MPI_Allreduce failed", mpi_code) - /* If 0 entries resulted from the collective operation, no one is writing anything */ + /* If 0 entries resulted from the collective operation, no processor is contributing anything and there is nothing to do */ if (gathered_array_num_entries > 0) { - if (NULL == (gathered_array = H5MM_malloc(gathered_array_num_entries * array_entry_size))) - HGOTO_ERROR(H5E_DATASET, H5E_CANTALLOC, FAIL, "couldn't allocate gathered array") + /* + * If gathering to all processors, all processors need to allocate space for the resulting array, as well as + * the receive counts and displacements arrays for the collective MPI_Allgatherv call. Otherwise, only the + * root processor needs to allocate the space for an MPI_Gatherv call. + */ + if (allgather || (mpi_rank == root)) { + if (NULL == (gathered_array = H5MM_malloc(gathered_array_num_entries * array_entry_size))) + HGOTO_ERROR(H5E_DATASET, H5E_CANTALLOC, FAIL, "couldn't allocate gathered array") - if (NULL == (receive_counts_array = (int *) H5MM_malloc((size_t) nprocs * sizeof(int)))) - HGOTO_ERROR(H5E_DATASET, H5E_CANTALLOC, FAIL, "couldn't allocate receive counts array") + if (NULL == (receive_counts_array = (int *) H5MM_malloc((size_t) mpi_size * sizeof(int)))) + HGOTO_ERROR(H5E_DATASET, H5E_CANTALLOC, FAIL, "couldn't allocate receive counts array") - if (NULL == (displacements_array = (int *) H5MM_malloc((size_t) nprocs * sizeof(int)))) - HGOTO_ERROR(H5E_DATASET, H5E_CANTALLOC, FAIL, "couldn't allocate receive displacements array") + if (NULL == (displacements_array = (int *) H5MM_malloc((size_t) mpi_size * sizeof(int)))) + HGOTO_ERROR(H5E_DATASET, H5E_CANTALLOC, FAIL, "couldn't allocate receive displacements array") + } /* end if */ - /* Inform each process of how many entries each other process is contributing to the resulting array */ - if (MPI_SUCCESS != (mpi_code = MPI_Allgather(&local_array_num_entries, 1, MPI_INT, receive_counts_array, 1, MPI_INT, comm))) - HMPI_GOTO_ERROR(FAIL, "MPI_Allgather failed", mpi_code) + /* + * If gathering to all processors, inform each processor of how many entries each other processor is + * contributing to the resulting array by collecting the counts into each processor's "receive counts" + * array. Otherwise, inform only the root processor of how many entries each other processor is contributing. + */ + if (allgather) { + if (MPI_SUCCESS != (mpi_code = MPI_Allgather(&local_array_num_entries, 1, MPI_INT, receive_counts_array, 1, MPI_INT, comm))) + HMPI_GOTO_ERROR(FAIL, "MPI_Allgather failed", mpi_code) + } /* end if */ + else { + if (MPI_SUCCESS != (mpi_code = MPI_Gather(&local_array_num_entries, 1, MPI_INT, receive_counts_array, 1, MPI_INT, root, comm))) + HMPI_GOTO_ERROR(FAIL, "MPI_Gather failed", mpi_code) + } /* end else */ - /* Multiply each receive count by the size of the array entry, since the data is sent as bytes */ - for (i = 0; i < (size_t) nprocs; i++) - H5_CHECKED_ASSIGN(receive_counts_array[i], int, (size_t) receive_counts_array[i] * array_entry_size, size_t); + if (allgather || (mpi_rank == root)) { + size_t i; - /* Set receive buffer offsets for MPI_Allgatherv */ - displacements_array[0] = 0; - for (i = 1; i < (size_t) nprocs; i++) - displacements_array[i] = displacements_array[i - 1] + receive_counts_array[i - 1]; + /* Multiply each receive count by the size of the array entry, since the data is sent as bytes. */ + for (i = 0; i < (size_t) mpi_size; i++) + H5_CHECKED_ASSIGN(receive_counts_array[i], int, (size_t) receive_counts_array[i] * array_entry_size, size_t); + /* Set receive buffer offsets for the collective MPI_Allgatherv/MPI_Gatherv call. */ + displacements_array[0] = 0; + for (i = 1; i < (size_t) mpi_size; i++) + displacements_array[i] = displacements_array[i - 1] + receive_counts_array[i - 1]; + } /* end if */ + + /* As the data is sent as bytes, calculate the true sendcount for the data. */ H5_CHECKED_ASSIGN(sendcount, int, local_array_num_entries * array_entry_size, size_t); if (allgather) { @@ -502,10 +526,11 @@ H5D__mpio_array_gatherv(void *local_array, size_t local_array_num_entries, else { if (MPI_SUCCESS != (mpi_code = MPI_Gatherv(local_array, sendcount, MPI_BYTE, gathered_array, receive_counts_array, displacements_array, MPI_BYTE, root, comm))) - HMPI_GOTO_ERROR(FAIL, "MPI_Allgatherv failed", mpi_code) + HMPI_GOTO_ERROR(FAIL, "MPI_Gatherv failed", mpi_code) } /* end else */ - if (sort_func) HDqsort(gathered_array, gathered_array_num_entries, array_entry_size, sort_func); + if (sort_func && (allgather || (mpi_rank == root))) + HDqsort(gathered_array, gathered_array_num_entries, array_entry_size, sort_func); } /* end if */ *_gathered_array = gathered_array; @@ -1295,8 +1320,7 @@ H5D__link_chunk_filtered_collective_io(H5D_io_info_t *io_info, const H5D_type_in * of the chunks in the file. */ if (H5D__mpio_array_gatherv(chunk_list, chunk_list_num_entries, sizeof(H5D_filtered_collective_io_info_t), - (void **) &collective_chunk_list, &collective_chunk_list_num_entries, mpi_size, - true, 0, io_info->comm, NULL) < 0) + (void **) &collective_chunk_list, &collective_chunk_list_num_entries, true, 0, io_info->comm, NULL) < 0) HGOTO_ERROR(H5E_DATASET, H5E_CANTGATHER, FAIL, "couldn't gather new chunk sizes") /* Collectively re-allocate the modified chunks (from each process) in the file */ @@ -1768,8 +1792,7 @@ H5D__multi_chunk_filtered_collective_io(H5D_io_info_t *io_info, const H5D_type_i * of the chunks in the file */ if (H5D__mpio_array_gatherv(&chunk_list[i], have_chunk_to_process ? 1 : 0, sizeof(H5D_filtered_collective_io_info_t), - (void **) &collective_chunk_list, &collective_chunk_list_num_entries, mpi_size, - true, 0, io_info->comm, NULL) < 0) + (void **) &collective_chunk_list, &collective_chunk_list_num_entries, true, 0, io_info->comm, NULL) < 0) HGOTO_ERROR(H5E_DATASET, H5E_CANTGATHER, FAIL, "couldn't gather new chunk sizes") /* Participate in the collective re-allocation of all chunks modified @@ -2655,8 +2678,8 @@ H5D__chunk_redistribute_shared_chunks(const H5D_io_info_t *io_info, const H5D_ty * call, the gathered list will initially be sorted in increasing order of chunk offset in the file. */ if (H5D__mpio_array_gatherv(local_chunk_array, *local_chunk_array_num_entries, sizeof(H5D_filtered_collective_io_info_t), - (void **) &shared_chunks_info_array, &shared_chunks_info_array_num_entries, mpi_size, - false, 0, io_info->comm, H5D__cmp_filtered_collective_io_info_entry) < 0) + (void **) &shared_chunks_info_array, &shared_chunks_info_array_num_entries, false, 0, + io_info->comm, H5D__cmp_filtered_collective_io_info_entry) < 0) HGOTO_ERROR(H5E_DATASET, H5E_CANTGATHER, FAIL, "couldn't gather array") /* Rank 0 redistributes any shared chunks to new owners as necessary */ @@ -2981,7 +3004,7 @@ H5D__filtered_collective_chunk_entry_io(H5D_filtered_collective_io_info_t *chunk { H5D_chunk_info_t *chunk_info = NULL; H5S_sel_iter_t *mem_iter = NULL; /* Memory iterator for H5D__scatter_mem/H5D__gather_mem */ - unsigned char *mod_data = NULL; /* Chunk modification data sent by a process to a chunk's owner */ + H5S_sel_iter_t *file_iter = NULL; H5Z_EDC_t err_detect; /* Error detection info */ H5Z_cb_t filter_cb; /* I/O filter callback function */ unsigned filter_mask = 0; @@ -2989,11 +3012,13 @@ H5D__filtered_collective_chunk_entry_io(H5D_filtered_collective_io_info_t *chunk hssize_t extent_npoints; hsize_t true_chunk_size; hbool_t mem_iter_init = FALSE; + hbool_t file_iter_init = FALSE; size_t buf_size; size_t i; H5S_t *dataspace = NULL; /* Other process' dataspace for the chunk */ - void *tmp_gath_buf = NULL; /* Temporary gather buffer for owner of the chunk to gather into from - application write buffer before scattering out to the chunk data buffer */ + void *tmp_gath_buf = NULL; /* Temporary gather buffer to gather into from application buffer + before scattering out to the chunk data buffer (when writing data), + or vice versa (when reading data) */ int mpi_code; herr_t ret_value = SUCCEED; @@ -3073,9 +3098,6 @@ H5D__filtered_collective_chunk_entry_io(H5D_filtered_collective_io_info_t *chunk HGOTO_ERROR(H5E_DATASET, H5E_CANTINIT, FAIL, "unable to initialize memory selection information") mem_iter_init = TRUE; - if ((iter_nelmts = H5S_GET_SELECT_NPOINTS(chunk_info->mspace)) < 0) - HGOTO_ERROR(H5E_DATASET, H5E_CANTCOUNT, FAIL, "dataspace is invalid") - /* If this is a read operation, scatter the read chunk data to the user's buffer. * * If this is a write operation, update the chunk data buffer with the modifications @@ -3084,16 +3106,39 @@ H5D__filtered_collective_chunk_entry_io(H5D_filtered_collective_io_info_t *chunk */ switch (io_info->op_type) { case H5D_IO_OP_READ: - if (H5D__scatter_mem(chunk_entry->buf, chunk_info->mspace, mem_iter, (size_t)iter_nelmts, io_info->u.rbuf) < 0) - HGOTO_ERROR(H5E_DATASET, H5E_READERROR, FAIL, "couldn't scatter to read buffer") + if (NULL == (file_iter = (H5S_sel_iter_t *) H5MM_malloc(sizeof(H5S_sel_iter_t)))) + HGOTO_ERROR(H5E_DATASET, H5E_CANTALLOC, FAIL, "couldn't allocate file iterator") + + if (H5S_select_iter_init(file_iter, chunk_info->fspace, type_info->src_type_size) < 0) + HGOTO_ERROR(H5E_DATASET, H5E_CANTINIT, FAIL, "unable to initialize memory selection information") + file_iter_init = TRUE; + + if ((iter_nelmts = H5S_GET_SELECT_NPOINTS(chunk_info->fspace)) < 0) + HGOTO_ERROR(H5E_DATASET, H5E_CANTCOUNT, FAIL, "dataspace is invalid") + + if (NULL == (tmp_gath_buf = H5MM_malloc((hsize_t) iter_nelmts * type_info->src_type_size))) + HGOTO_ERROR(H5E_DATASET, H5E_CANTALLOC, FAIL, "couldn't allocate temporary gather buffer") + + if (!H5D__gather_mem(chunk_entry->buf, chunk_info->fspace, file_iter, (size_t) iter_nelmts, tmp_gath_buf)) + HGOTO_ERROR(H5E_IO, H5E_READERROR, FAIL, "couldn't gather from chunk buffer") + + if ((iter_nelmts = H5S_GET_SELECT_NPOINTS(chunk_info->mspace)) < 0) + HGOTO_ERROR(H5E_DATASET, H5E_CANTCOUNT, FAIL, "dataspace is invalid") + + if (H5D__scatter_mem(tmp_gath_buf, chunk_info->mspace, mem_iter, (size_t) iter_nelmts, io_info->u.rbuf) < 0) + HGOTO_ERROR(H5E_DATASET, H5E_READERROR, FAIL, "couldn't scatter to read buffer") + break; case H5D_IO_OP_WRITE: + if ((iter_nelmts = H5S_GET_SELECT_NPOINTS(chunk_info->mspace)) < 0) + HGOTO_ERROR(H5E_DATASET, H5E_CANTCOUNT, FAIL, "dataspace is invalid") + if (NULL == (tmp_gath_buf = H5MM_malloc((hsize_t) iter_nelmts * type_info->src_type_size))) HGOTO_ERROR(H5E_DATASET, H5E_CANTALLOC, FAIL, "couldn't allocate temporary gather buffer") /* Gather modification data from the application write buffer into a temporary buffer */ - if(!H5D__gather_mem(io_info->u.wbuf, chunk_info->mspace, mem_iter, (size_t)iter_nelmts, tmp_gath_buf)) + if(!H5D__gather_mem(io_info->u.wbuf, chunk_info->mspace, mem_iter, (size_t) iter_nelmts, tmp_gath_buf)) HGOTO_ERROR(H5E_IO, H5E_WRITEERROR, FAIL, "couldn't gather from write buffer") if (H5S_SELECT_ITER_RELEASE(mem_iter) < 0) @@ -3111,7 +3156,7 @@ H5D__filtered_collective_chunk_entry_io(H5D_filtered_collective_io_info_t *chunk /* Scatter the owner's modification data into the chunk data buffer according to * the file space. */ - if(H5D__scatter_mem(tmp_gath_buf, chunk_info->fspace, mem_iter, (size_t)iter_nelmts, chunk_entry->buf) < 0) + if(H5D__scatter_mem(tmp_gath_buf, chunk_info->fspace, mem_iter, (size_t) iter_nelmts, chunk_entry->buf) < 0) HGOTO_ERROR(H5E_DATASET, H5E_READERROR, FAIL, "couldn't scatter to chunk data buffer") if (H5S_SELECT_ITER_RELEASE(mem_iter) < 0) @@ -3177,10 +3222,12 @@ done: H5MM_free(chunk_entry->async_info.receive_buffer_array); if (chunk_entry->async_info.receive_requests_array) H5MM_free(chunk_entry->async_info.receive_requests_array); - if (mod_data) - H5MM_free(mod_data); if (tmp_gath_buf) H5MM_free(tmp_gath_buf); + if (file_iter_init && H5S_SELECT_ITER_RELEASE(file_iter) < 0) + HDONE_ERROR(H5E_DATASET, H5E_CANTFREE, FAIL, "couldn't release selection iterator") + if (file_iter) + H5MM_free(file_iter); if (mem_iter_init && H5S_SELECT_ITER_RELEASE(mem_iter) < 0) HDONE_ERROR(H5E_DATASET, H5E_CANTFREE, FAIL, "couldn't release selection iterator") if (mem_iter) diff --git a/testpar/t_filters_parallel.c b/testpar/t_filters_parallel.c index 21a5ce0..3647732 100644 --- a/testpar/t_filters_parallel.c +++ b/testpar/t_filters_parallel.c @@ -31,22 +31,56 @@ char filenames[1][256]; int nerrors = 0; +size_t cur_filter_idx = 0; + #define ARRAY_SIZE(a) sizeof(a) / sizeof(a[0]) -static void test_one_chunk_filtered_dataset(void); -static void test_filtered_dataset_no_overlap(void); -static void test_filtered_dataset_overlap(void); -static void test_filtered_dataset_single_no_selection(void); -static void test_filtered_dataset_all_no_selection(void); -static void test_filtered_dataset_point_selection(void); -static void test_filtered_dataset_interleaved_write(void); -static void test_3d_filtered_dataset_no_overlap_separate_pages(void); -static void test_3d_filtered_dataset_no_overlap_same_pages(void); -static void test_3d_filtered_dataset_overlap(void); -static void test_cmpd_filtered_dataset_no_conversion_unshared(void); -static void test_cmpd_filtered_dataset_no_conversion_shared(void); -static void test_cmpd_filtered_dataset_type_conversion_unshared(void); -static void test_cmpd_filtered_dataset_type_conversion_shared(void); +static herr_t set_dcpl_filter(hid_t dcpl); + +/* Tests for writing data in parallel */ +static void test_write_one_chunk_filtered_dataset(void); +static void test_write_filtered_dataset_no_overlap(void); +static void test_write_filtered_dataset_overlap(void); +static void test_write_filtered_dataset_single_no_selection(void); +static void test_write_filtered_dataset_all_no_selection(void); +static void test_write_filtered_dataset_point_selection(void); +static void test_write_filtered_dataset_interleaved_write(void); +static void test_write_3d_filtered_dataset_no_overlap_separate_pages(void); +static void test_write_3d_filtered_dataset_no_overlap_same_pages(void); +static void test_write_3d_filtered_dataset_overlap(void); +static void test_write_cmpd_filtered_dataset_no_conversion_unshared(void); +static void test_write_cmpd_filtered_dataset_no_conversion_shared(void); +static void test_write_cmpd_filtered_dataset_type_conversion_unshared(void); +static void test_write_cmpd_filtered_dataset_type_conversion_shared(void); + +/* Tests for reading data in parallel */ +static void test_read_one_chunk_filtered_dataset(void); +static void test_read_filtered_dataset_no_overlap(void); +static void test_read_filtered_dataset_overlap(void); +static void test_read_filtered_dataset_single_no_selection(void); +static void test_read_filtered_dataset_all_no_selection(void); +static void test_read_filtered_dataset_point_selection(void); +static void test_read_filtered_dataset_interleaved_read(void); +static void test_read_3d_filtered_dataset_no_overlap_separate_pages(void); +static void test_read_3d_filtered_dataset_no_overlap_same_pages(void); +static void test_read_3d_filtered_dataset_overlap(void); +static void test_read_cmpd_filtered_dataset_no_conversion_unshared(void); +static void test_read_cmpd_filtered_dataset_no_conversion_shared(void); +static void test_read_cmpd_filtered_dataset_type_conversion_unshared(void); +static void test_read_cmpd_filtered_dataset_type_conversion_shared(void); + +/* Other miscellaneous tests */ +static void test_shrinking_growing_chunks(void); + +/* + * Tests for attempting to round-trip the data going from + * + * written serially -> read in parallel + * + * and + * + * written in parallel -> read serially + */ static void test_write_serial_read_parallel(void); static void test_write_parallel_read_serial(void); @@ -56,25 +90,60 @@ static int mpi_rank; static int mpi_size; static void (*tests[])(void) = { - test_one_chunk_filtered_dataset, - test_filtered_dataset_no_overlap, - test_filtered_dataset_overlap, - test_filtered_dataset_single_no_selection, - test_filtered_dataset_all_no_selection, - test_filtered_dataset_point_selection, - test_filtered_dataset_interleaved_write, - test_3d_filtered_dataset_no_overlap_separate_pages, - test_3d_filtered_dataset_no_overlap_same_pages, - test_3d_filtered_dataset_overlap, - test_cmpd_filtered_dataset_no_conversion_unshared, - test_cmpd_filtered_dataset_no_conversion_shared, - test_cmpd_filtered_dataset_type_conversion_unshared, - test_cmpd_filtered_dataset_type_conversion_shared, - test_write_serial_read_parallel, - test_write_parallel_read_serial, + test_write_one_chunk_filtered_dataset, + test_write_filtered_dataset_no_overlap, + test_write_filtered_dataset_overlap, + test_write_filtered_dataset_single_no_selection, + test_write_filtered_dataset_all_no_selection, + test_write_filtered_dataset_point_selection, + test_write_filtered_dataset_interleaved_write, + test_write_3d_filtered_dataset_no_overlap_separate_pages, + test_write_3d_filtered_dataset_no_overlap_same_pages, + test_write_3d_filtered_dataset_overlap, + test_write_cmpd_filtered_dataset_no_conversion_unshared, + test_write_cmpd_filtered_dataset_no_conversion_shared, + test_write_cmpd_filtered_dataset_type_conversion_unshared, + test_write_cmpd_filtered_dataset_type_conversion_shared, + test_read_one_chunk_filtered_dataset, + test_read_filtered_dataset_no_overlap, + test_read_filtered_dataset_overlap, + test_read_filtered_dataset_single_no_selection, + test_read_filtered_dataset_all_no_selection, + test_read_filtered_dataset_point_selection, + test_read_filtered_dataset_interleaved_read, + test_read_3d_filtered_dataset_no_overlap_separate_pages, + test_read_3d_filtered_dataset_no_overlap_same_pages, + test_read_3d_filtered_dataset_overlap, + test_read_cmpd_filtered_dataset_no_conversion_unshared, + test_read_cmpd_filtered_dataset_no_conversion_shared, + test_read_cmpd_filtered_dataset_type_conversion_unshared, + test_read_cmpd_filtered_dataset_type_conversion_shared, + test_write_serial_read_parallel, + test_write_parallel_read_serial, + test_shrinking_growing_chunks, }; /* + * Function to call the appropriate HDF5 filter-setting function + * depending on the currently set index. Used to re-run the tests + * with different filters to check that the data still comes back + * correctly under a variety of circumstances, such as the + * Fletcher32 checksum filter increasing the size of the chunk. + */ +static herr_t +set_dcpl_filter(hid_t dcpl) +{ + switch (cur_filter_idx) { + case 0: + return H5Pset_deflate(dcpl, DEFAULT_DEFLATE_LEVEL); + case 1: + return H5Pset_fletcher32(dcpl); + default: + return H5Pset_deflate(dcpl, DEFAULT_DEFLATE_LEVEL); + } +} + +/* * Tests parallel write of filtered data in the special * case where a dataset is composed of a single chunk. * @@ -82,31 +151,32 @@ static void (*tests[])(void) = { * 02/01/2017 */ static void -test_one_chunk_filtered_dataset(void) +test_write_one_chunk_filtered_dataset(void) { C_DATATYPE *data = NULL; C_DATATYPE *read_buf = NULL; C_DATATYPE *correct_buf = NULL; - hsize_t dataset_dims[ONE_CHUNK_FILTERED_DATASET_DIMS]; - hsize_t chunk_dims[ONE_CHUNK_FILTERED_DATASET_DIMS]; - hsize_t sel_dims[ONE_CHUNK_FILTERED_DATASET_DIMS]; - hsize_t count[ONE_CHUNK_FILTERED_DATASET_DIMS]; - hsize_t stride[ONE_CHUNK_FILTERED_DATASET_DIMS]; - hsize_t block[ONE_CHUNK_FILTERED_DATASET_DIMS]; - hsize_t offset[ONE_CHUNK_FILTERED_DATASET_DIMS]; + hsize_t dataset_dims[WRITE_ONE_CHUNK_FILTERED_DATASET_DIMS]; + hsize_t chunk_dims[WRITE_ONE_CHUNK_FILTERED_DATASET_DIMS]; + hsize_t sel_dims[WRITE_ONE_CHUNK_FILTERED_DATASET_DIMS]; + hsize_t start[WRITE_ONE_CHUNK_FILTERED_DATASET_DIMS]; + hsize_t stride[WRITE_ONE_CHUNK_FILTERED_DATASET_DIMS]; + hsize_t count[WRITE_ONE_CHUNK_FILTERED_DATASET_DIMS]; + hsize_t block[WRITE_ONE_CHUNK_FILTERED_DATASET_DIMS]; size_t i, data_size, correct_buf_size; hid_t file_id = -1, dset_id = -1, plist_id = -1; hid_t filespace = -1, memspace = -1; - if (MAINPROCESS) puts("Testing one-chunk filtered dataset"); + if (MAINPROCESS) puts("Testing write to one-chunk filtered dataset"); /* Set up file access property list with parallel I/O access */ plist_id = H5Pcreate(H5P_FILE_ACCESS); VRFY((plist_id >= 0), "FAPL creation succeeded"); - VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), "Set FAPL MPIO succeeded"); - - VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), "Set libver bounds succeeded"); + VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), + "Set FAPL MPIO succeeded"); + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); file_id = H5Fopen(filenames[0], H5F_ACC_RDWR, plist_id); VRFY((file_id >= 0), "Test file open succeeded"); @@ -114,29 +184,30 @@ test_one_chunk_filtered_dataset(void) VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); /* Create the dataspace for the dataset */ - dataset_dims[0] = (hsize_t) ONE_CHUNK_FILTERED_DATASET_NROWS; - dataset_dims[1] = (hsize_t) ONE_CHUNK_FILTERED_DATASET_NCOLS; - chunk_dims[0] = (hsize_t) ONE_CHUNK_FILTERED_DATASET_CH_NROWS; - chunk_dims[1] = (hsize_t) ONE_CHUNK_FILTERED_DATASET_CH_NCOLS; - sel_dims[0] = (hsize_t) ONE_CHUNK_FILTERED_DATASET_NROWS / (hsize_t) mpi_size; - sel_dims[1] = (hsize_t) ONE_CHUNK_FILTERED_DATASET_NCOLS; - - filespace = H5Screate_simple(ONE_CHUNK_FILTERED_DATASET_DIMS, dataset_dims, NULL); + dataset_dims[0] = (hsize_t) WRITE_ONE_CHUNK_FILTERED_DATASET_NROWS; + dataset_dims[1] = (hsize_t) WRITE_ONE_CHUNK_FILTERED_DATASET_NCOLS; + chunk_dims[0] = (hsize_t) WRITE_ONE_CHUNK_FILTERED_DATASET_CH_NROWS; + chunk_dims[1] = (hsize_t) WRITE_ONE_CHUNK_FILTERED_DATASET_CH_NCOLS; + sel_dims[0] = (hsize_t) WRITE_ONE_CHUNK_FILTERED_DATASET_NROWS / (hsize_t) mpi_size; + sel_dims[1] = (hsize_t) WRITE_ONE_CHUNK_FILTERED_DATASET_NCOLS; + + filespace = H5Screate_simple(WRITE_ONE_CHUNK_FILTERED_DATASET_DIMS, dataset_dims, NULL); VRFY((filespace >= 0), "File dataspace creation succeeded"); - memspace = H5Screate_simple(ONE_CHUNK_FILTERED_DATASET_DIMS, sel_dims, NULL); + memspace = H5Screate_simple(WRITE_ONE_CHUNK_FILTERED_DATASET_DIMS, sel_dims, NULL); VRFY((memspace >= 0), "Memory dataspace creation succeeded"); /* Create chunked dataset */ plist_id = H5Pcreate(H5P_DATASET_CREATE); VRFY((plist_id >= 0), "DCPL creation succeeded"); - VRFY((H5Pset_chunk(plist_id, ONE_CHUNK_FILTERED_DATASET_DIMS, chunk_dims) >= 0), "Chunk size set"); + VRFY((H5Pset_chunk(plist_id, WRITE_ONE_CHUNK_FILTERED_DATASET_DIMS, chunk_dims) >= 0), + "Chunk size set"); /* Add test filter to the pipeline */ - VRFY((SET_FILTER(plist_id) >= 0), "Filter set"); + VRFY((set_dcpl_filter(plist_id) >= 0), "Filter set"); - dset_id = H5Dcreate2(file_id, ONE_CHUNK_FILTERED_DATASET_NAME, HDF5_DATATYPE_NAME, filespace, + dset_id = H5Dcreate2(file_id, WRITE_ONE_CHUNK_FILTERED_DATASET_NAME, HDF5_DATATYPE_NAME, filespace, H5P_DEFAULT, plist_id, H5P_DEFAULT); VRFY((dset_id >= 0), "Dataset creation succeeded"); @@ -148,66 +219,73 @@ test_one_chunk_filtered_dataset(void) */ count[0] = 1; count[1] = 1; - stride[0] = (hsize_t) ONE_CHUNK_FILTERED_DATASET_CH_NROWS; - stride[1] = (hsize_t) ONE_CHUNK_FILTERED_DATASET_CH_NCOLS; + stride[0] = (hsize_t) WRITE_ONE_CHUNK_FILTERED_DATASET_CH_NROWS; + stride[1] = (hsize_t) WRITE_ONE_CHUNK_FILTERED_DATASET_CH_NCOLS; block[0] = sel_dims[0]; block[1] = sel_dims[1]; - offset[0] = ((hsize_t) mpi_rank * sel_dims[0]); - offset[1] = 0; + start[0] = ((hsize_t) mpi_rank * sel_dims[0]); + start[1] = 0; - if (VERBOSE_MED) - printf("Process %d: count[ %llu, %llu ], stride[ %llu, %llu ], offset[ %llu, %llu ], block size[ %llu, %llu ]\n", - mpi_rank, count[0], count[1], stride[0], stride[1], offset[0], offset[1], block[0], block[1]); + if (VERBOSE_MED) { + printf("Process %d is writing with count[ %llu, %llu ], stride[ %llu, %llu ], start[ %llu, %llu ], block size[ %llu, %llu ]\n", + mpi_rank, count[0], count[1], stride[0], stride[1], start[0], start[1], block[0], block[1]); + fflush(stdout); + } /* Select hyperslab in the file */ filespace = H5Dget_space(dset_id); VRFY((filespace >= 0), "File dataspace retrieval succeeded"); - VRFY((H5Sselect_hyperslab(filespace, H5S_SELECT_SET, offset, stride, count, block) >= 0), + VRFY((H5Sselect_hyperslab(filespace, H5S_SELECT_SET, start, stride, count, block) >= 0), "Hyperslab selection succeeded"); /* Fill data buffer */ - data_size = (hsize_t) ONE_CHUNK_FILTERED_DATASET_CH_NROWS * (hsize_t) ONE_CHUNK_FILTERED_DATASET_NCOLS * sizeof(*data); + data_size = (hsize_t) WRITE_ONE_CHUNK_FILTERED_DATASET_CH_NROWS + * (hsize_t) WRITE_ONE_CHUNK_FILTERED_DATASET_NCOLS * sizeof(*data); correct_buf_size = dataset_dims[0] * dataset_dims[1] * sizeof(*correct_buf); - data = (C_DATATYPE *) calloc(1, data_size); - VRFY((NULL != data), "calloc succeeded"); + data = (C_DATATYPE *) HDcalloc(1, data_size); + VRFY((NULL != data), "HDcalloc succeeded"); - correct_buf = (C_DATATYPE *) calloc(1, correct_buf_size); - VRFY((NULL != correct_buf), "calloc succeeded"); + correct_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != correct_buf), "HDcalloc succeeded"); for (i = 0; i < data_size / sizeof(*data); i++) data[i] = (C_DATATYPE) GEN_DATA(i); for (i = 0; i < correct_buf_size / sizeof(*correct_buf); i++) - correct_buf[i] = ((C_DATATYPE) i % (ONE_CHUNK_FILTERED_DATASET_CH_NROWS / mpi_size * ONE_CHUNK_FILTERED_DATASET_CH_NCOLS)) - + ((C_DATATYPE) i / (ONE_CHUNK_FILTERED_DATASET_CH_NROWS / mpi_size * ONE_CHUNK_FILTERED_DATASET_CH_NCOLS)); + correct_buf[i] = ((C_DATATYPE) i % (WRITE_ONE_CHUNK_FILTERED_DATASET_CH_NROWS / mpi_size * WRITE_ONE_CHUNK_FILTERED_DATASET_CH_NCOLS)) + + ((C_DATATYPE) i / (WRITE_ONE_CHUNK_FILTERED_DATASET_CH_NROWS / mpi_size * WRITE_ONE_CHUNK_FILTERED_DATASET_CH_NCOLS)); /* Create property list for collective dataset write */ plist_id = H5Pcreate(H5P_DATASET_XFER); VRFY((plist_id >= 0), "DXPL creation succeeded"); - VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), "Set DXPL MPIO succeeded"); + VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), + "Set DXPL MPIO succeeded"); - VRFY((H5Dwrite(dset_id, HDF5_DATATYPE_NAME, memspace, filespace, plist_id, data) >= 0), "Dataset write succeeded"); + VRFY((H5Dwrite(dset_id, HDF5_DATATYPE_NAME, memspace, filespace, plist_id, data) >= 0), + "Dataset write succeeded"); - if (data) free(data); + if (data) HDfree(data); VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); /* Verify the correct data was written */ - read_buf = (C_DATATYPE *) calloc(1, correct_buf_size); - VRFY((NULL != read_buf), "calloc succeeded"); + read_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != read_buf), "HDcalloc succeeded"); - dset_id = H5Dopen2(file_id, "/" ONE_CHUNK_FILTERED_DATASET_NAME, H5P_DEFAULT); + dset_id = H5Dopen2(file_id, "/" WRITE_ONE_CHUNK_FILTERED_DATASET_NAME, H5P_DEFAULT); VRFY((dset_id >= 0), "Dataset open succeeded"); - VRFY((H5Dread(dset_id, HDF5_DATATYPE_NAME, H5S_ALL, H5S_ALL, plist_id, read_buf) >= 0), "Dataset read succeeded"); + VRFY((H5Dread(dset_id, HDF5_DATATYPE_NAME, H5S_ALL, H5S_ALL, plist_id, read_buf) >= 0), + "Dataset read succeeded"); - VRFY((0 == memcmp(read_buf, correct_buf, correct_buf_size)), "Data verification succeeded"); + VRFY((0 == memcmp(read_buf, correct_buf, correct_buf_size)), + "Data verification succeeded"); - if (correct_buf) free(correct_buf); - if (read_buf) free(read_buf); + if (correct_buf) HDfree(correct_buf); + if (read_buf) HDfree(read_buf); VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); @@ -228,18 +306,18 @@ test_one_chunk_filtered_dataset(void) * 02/01/2017 */ static void -test_filtered_dataset_no_overlap(void) +test_write_filtered_dataset_no_overlap(void) { C_DATATYPE *data = NULL; C_DATATYPE *read_buf = NULL; C_DATATYPE *correct_buf = NULL; - hsize_t dataset_dims[UNSHARED_FILTERED_CHUNKS_DATASET_DIMS]; - hsize_t chunk_dims[UNSHARED_FILTERED_CHUNKS_DATASET_DIMS]; - hsize_t sel_dims[UNSHARED_FILTERED_CHUNKS_DATASET_DIMS]; - hsize_t count[UNSHARED_FILTERED_CHUNKS_DATASET_DIMS]; - hsize_t stride[UNSHARED_FILTERED_CHUNKS_DATASET_DIMS]; - hsize_t block[UNSHARED_FILTERED_CHUNKS_DATASET_DIMS]; - hsize_t offset[UNSHARED_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t dataset_dims[WRITE_UNSHARED_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t chunk_dims[WRITE_UNSHARED_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t sel_dims[WRITE_UNSHARED_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t start[WRITE_UNSHARED_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t stride[WRITE_UNSHARED_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t count[WRITE_UNSHARED_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t block[WRITE_UNSHARED_FILTERED_CHUNKS_DATASET_DIMS]; size_t i, data_size, correct_buf_size; hid_t file_id = -1, dset_id = -1, plist_id = -1; hid_t filespace = -1, memspace = -1; @@ -250,9 +328,11 @@ test_filtered_dataset_no_overlap(void) plist_id = H5Pcreate(H5P_FILE_ACCESS); VRFY((plist_id >= 0), "FAPL creation succeeded"); - VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), "Set FAPL MPIO succeeded"); + VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), + "Set FAPL MPIO succeeded"); - VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), "Set libver bounds succeeded"); + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); file_id = H5Fopen(filenames[0], H5F_ACC_RDWR, plist_id); VRFY((file_id >= 0), "Test file open succeeded"); @@ -260,29 +340,30 @@ test_filtered_dataset_no_overlap(void) VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); /* Create the dataspace for the dataset */ - dataset_dims[0] = (hsize_t) UNSHARED_FILTERED_CHUNKS_NROWS; - dataset_dims[1] = (hsize_t) UNSHARED_FILTERED_CHUNKS_NCOLS; - chunk_dims[0] = (hsize_t) UNSHARED_FILTERED_CHUNKS_CH_NROWS; - chunk_dims[1] = (hsize_t) UNSHARED_FILTERED_CHUNKS_CH_NCOLS; - sel_dims[0] = (hsize_t) UNSHARED_FILTERED_CHUNKS_CH_NROWS; - sel_dims[1] = (hsize_t) UNSHARED_FILTERED_CHUNKS_NCOLS; - - filespace = H5Screate_simple(UNSHARED_FILTERED_CHUNKS_DATASET_DIMS, dataset_dims, NULL); + dataset_dims[0] = (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_NROWS; + dataset_dims[1] = (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_NCOLS; + chunk_dims[0] = (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_CH_NROWS; + chunk_dims[1] = (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_CH_NCOLS; + sel_dims[0] = (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_CH_NROWS; + sel_dims[1] = (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_NCOLS; + + filespace = H5Screate_simple(WRITE_UNSHARED_FILTERED_CHUNKS_DATASET_DIMS, dataset_dims, NULL); VRFY((filespace >= 0), "File dataspace creation succeeded"); - memspace = H5Screate_simple(UNSHARED_FILTERED_CHUNKS_DATASET_DIMS, sel_dims, NULL); + memspace = H5Screate_simple(WRITE_UNSHARED_FILTERED_CHUNKS_DATASET_DIMS, sel_dims, NULL); VRFY((memspace >= 0), "Memory dataspace creation succeeded"); /* Create chunked dataset */ plist_id = H5Pcreate(H5P_DATASET_CREATE); VRFY((plist_id >= 0), "DCPL creation succeeded"); - VRFY((H5Pset_chunk(plist_id, UNSHARED_FILTERED_CHUNKS_DATASET_DIMS, chunk_dims) >= 0), "Chunk size set"); + VRFY((H5Pset_chunk(plist_id, WRITE_UNSHARED_FILTERED_CHUNKS_DATASET_DIMS, chunk_dims) >= 0), + "Chunk size set"); /* Add test filter to the pipeline */ - VRFY((SET_FILTER(plist_id) >= 0), "Filter set"); + VRFY((set_dcpl_filter(plist_id) >= 0), "Filter set"); - dset_id = H5Dcreate2(file_id, UNSHARED_FILTERED_CHUNKS_DATASET_NAME, HDF5_DATATYPE_NAME, filespace, + dset_id = H5Dcreate2(file_id, WRITE_UNSHARED_FILTERED_CHUNKS_DATASET_NAME, HDF5_DATATYPE_NAME, filespace, H5P_DEFAULT, plist_id, H5P_DEFAULT); VRFY((dset_id >= 0), "Dataset creation succeeded"); @@ -293,66 +374,76 @@ test_filtered_dataset_no_overlap(void) * it to the hyperslab in the file */ count[0] = 1; - count[1] = (hsize_t) UNSHARED_FILTERED_CHUNKS_NCOLS / (hsize_t) UNSHARED_FILTERED_CHUNKS_CH_NCOLS; - stride[0] = (hsize_t) UNSHARED_FILTERED_CHUNKS_CH_NROWS; - stride[1] = (hsize_t) UNSHARED_FILTERED_CHUNKS_CH_NCOLS; - block[0] = (hsize_t) UNSHARED_FILTERED_CHUNKS_CH_NROWS; - block[1] = (hsize_t) UNSHARED_FILTERED_CHUNKS_CH_NCOLS; - offset[0] = ((hsize_t) mpi_rank * (hsize_t) UNSHARED_FILTERED_CHUNKS_CH_NROWS * count[0]); - offset[1] = 0; - - if (VERBOSE_MED) - printf("Process %d: count[ %llu, %llu ], stride[ %llu, %llu ], offset[ %llu, %llu ], block size[ %llu, %llu ]\n", - mpi_rank, count[0], count[1], stride[0], stride[1], offset[0], offset[1], block[0], block[1]); + count[1] = (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_NCOLS / (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_CH_NCOLS; + stride[0] = (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_CH_NROWS; + stride[1] = (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_CH_NCOLS; + block[0] = (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_CH_NROWS; + block[1] = (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_CH_NCOLS; + start[0] = ((hsize_t) mpi_rank * (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_CH_NROWS * count[0]); + start[1] = 0; + + if (VERBOSE_MED) { + printf("Process %d is writing with count[ %llu, %llu ], stride[ %llu, %llu ], start[ %llu, %llu ], block size[ %llu, %llu ]\n", + mpi_rank, count[0], count[1], stride[0], stride[1], start[0], start[1], block[0], block[1]); + fflush(stdout); + } /* Select hyperslab in the file */ filespace = H5Dget_space(dset_id); VRFY((dset_id >= 0), "File dataspace retrieval succeeded"); - VRFY((H5Sselect_hyperslab(filespace, H5S_SELECT_SET, offset, stride, count, block) >= 0), "Hyperslab selection succeeded"); + VRFY((H5Sselect_hyperslab(filespace, H5S_SELECT_SET, start, stride, count, block) >= 0), + "Hyperslab selection succeeded"); /* Fill data buffer */ data_size = sel_dims[0] * sel_dims[1] * sizeof(*data); correct_buf_size = dataset_dims[0] * dataset_dims[1] * sizeof(*correct_buf); - data = (C_DATATYPE *) calloc(1, data_size); - VRFY((NULL != data), "calloc succeeded"); + data = (C_DATATYPE *) HDcalloc(1, data_size); + VRFY((NULL != data), "HDcalloc succeeded"); - correct_buf = (C_DATATYPE *) calloc(1, correct_buf_size); - VRFY((NULL != correct_buf), "calloc succeeded"); + correct_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != correct_buf), "HDcalloc succeeded"); for (i = 0; i < data_size / sizeof(*data); i++) data[i] = (C_DATATYPE) GEN_DATA(i); for (i = 0; i < correct_buf_size / sizeof(*correct_buf); i++) - correct_buf[i] = (C_DATATYPE) ( (i % (dataset_dims[0] / (hsize_t) mpi_size * dataset_dims[1])) - + (i / (dataset_dims[0] / (hsize_t) mpi_size * dataset_dims[1]))); + correct_buf[i] = + (C_DATATYPE) ( + (i % (dataset_dims[0] / (hsize_t) mpi_size * dataset_dims[1])) + + (i / (dataset_dims[0] / (hsize_t) mpi_size * dataset_dims[1])) + ); /* Create property list for collective dataset write */ plist_id = H5Pcreate(H5P_DATASET_XFER); VRFY((plist_id >= 0), "DXPL creation succeeded"); - VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), "Set DXPL MPIO succeeded"); + VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), + "Set DXPL MPIO succeeded"); - VRFY((H5Dwrite(dset_id, HDF5_DATATYPE_NAME, memspace, filespace, plist_id, data) >= 0), "Dataset write succeeded"); + VRFY((H5Dwrite(dset_id, HDF5_DATATYPE_NAME, memspace, filespace, plist_id, data) >= 0), + "Dataset write succeeded"); - if (data) free(data); + if (data) HDfree(data); VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); /* Verify the correct data was written */ - read_buf = (C_DATATYPE *) calloc(1, correct_buf_size); - VRFY((NULL != read_buf), "calloc succeeded"); + read_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != read_buf), "HDcalloc succeeded"); - dset_id = H5Dopen2(file_id, "/" UNSHARED_FILTERED_CHUNKS_DATASET_NAME, H5P_DEFAULT); + dset_id = H5Dopen2(file_id, "/" WRITE_UNSHARED_FILTERED_CHUNKS_DATASET_NAME, H5P_DEFAULT); VRFY((dset_id >= 0), "Dataset open succeeded"); - VRFY((H5Dread(dset_id, HDF5_DATATYPE_NAME, H5S_ALL, H5S_ALL, plist_id, read_buf) >= 0), "Dataset read succeeded"); + VRFY((H5Dread(dset_id, HDF5_DATATYPE_NAME, H5S_ALL, H5S_ALL, plist_id, read_buf) >= 0), + "Dataset read succeeded"); - VRFY((0 == memcmp(read_buf, correct_buf, correct_buf_size)), "Data verification succeeded"); + VRFY((0 == memcmp(read_buf, correct_buf, correct_buf_size)), + "Data verification succeeded"); - if (correct_buf) free(correct_buf); - if (read_buf) free(read_buf); + if (correct_buf) HDfree(correct_buf); + if (read_buf) HDfree(read_buf); VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); @@ -374,18 +465,18 @@ test_filtered_dataset_no_overlap(void) * 02/01/2017 */ static void -test_filtered_dataset_overlap(void) +test_write_filtered_dataset_overlap(void) { C_DATATYPE *data = NULL; C_DATATYPE *read_buf = NULL; C_DATATYPE *correct_buf = NULL; - hsize_t dataset_dims[SHARED_FILTERED_CHUNKS_DATASET_DIMS]; - hsize_t chunk_dims[SHARED_FILTERED_CHUNKS_DATASET_DIMS]; - hsize_t sel_dims[SHARED_FILTERED_CHUNKS_DATASET_DIMS]; - hsize_t count[SHARED_FILTERED_CHUNKS_DATASET_DIMS]; - hsize_t stride[SHARED_FILTERED_CHUNKS_DATASET_DIMS]; - hsize_t block[SHARED_FILTERED_CHUNKS_DATASET_DIMS]; - hsize_t offset[SHARED_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t dataset_dims[WRITE_SHARED_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t chunk_dims[WRITE_SHARED_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t sel_dims[WRITE_SHARED_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t start[WRITE_SHARED_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t stride[WRITE_SHARED_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t count[WRITE_SHARED_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t block[WRITE_SHARED_FILTERED_CHUNKS_DATASET_DIMS]; size_t i, data_size, correct_buf_size; hid_t file_id = -1, dset_id = -1, plist_id = -1; hid_t filespace = -1, memspace = -1; @@ -396,9 +487,11 @@ test_filtered_dataset_overlap(void) plist_id = H5Pcreate(H5P_FILE_ACCESS); VRFY((plist_id >= 0), "FAPL creation succeeded"); - VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), "Set FAPL MPIO succeeded"); + VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), + "Set FAPL MPIO succeeded"); - VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), "Set libver bounds succeeded"); + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); file_id = H5Fopen(filenames[0], H5F_ACC_RDWR, plist_id); VRFY((file_id >= 0), "Test file open succeeded"); @@ -406,29 +499,30 @@ test_filtered_dataset_overlap(void) VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); /* Create the dataspace for the dataset */ - dataset_dims[0] = (hsize_t) SHARED_FILTERED_CHUNKS_NROWS; - dataset_dims[1] = (hsize_t) SHARED_FILTERED_CHUNKS_NCOLS; - chunk_dims[0] = (hsize_t) SHARED_FILTERED_CHUNKS_CH_NROWS; - chunk_dims[1] = (hsize_t) SHARED_FILTERED_CHUNKS_CH_NCOLS; + dataset_dims[0] = (hsize_t) WRITE_SHARED_FILTERED_CHUNKS_NROWS; + dataset_dims[1] = (hsize_t) WRITE_SHARED_FILTERED_CHUNKS_NCOLS; + chunk_dims[0] = (hsize_t) WRITE_SHARED_FILTERED_CHUNKS_CH_NROWS; + chunk_dims[1] = (hsize_t) WRITE_SHARED_FILTERED_CHUNKS_CH_NCOLS; sel_dims[0] = (hsize_t) DIM0_SCALE_FACTOR; - sel_dims[1] = (hsize_t) SHARED_FILTERED_CHUNKS_CH_NCOLS * (hsize_t) DIM1_SCALE_FACTOR; + sel_dims[1] = (hsize_t) WRITE_SHARED_FILTERED_CHUNKS_CH_NCOLS * (hsize_t) DIM1_SCALE_FACTOR; - filespace = H5Screate_simple(SHARED_FILTERED_CHUNKS_DATASET_DIMS, dataset_dims, NULL); + filespace = H5Screate_simple(WRITE_SHARED_FILTERED_CHUNKS_DATASET_DIMS, dataset_dims, NULL); VRFY((filespace >= 0), "File dataspace creation succeeded"); - memspace = H5Screate_simple(SHARED_FILTERED_CHUNKS_DATASET_DIMS, sel_dims, NULL); + memspace = H5Screate_simple(WRITE_SHARED_FILTERED_CHUNKS_DATASET_DIMS, sel_dims, NULL); VRFY((memspace >= 0), "Memory dataspace creation succeeded"); /* Create chunked dataset */ plist_id = H5Pcreate(H5P_DATASET_CREATE); VRFY((plist_id >= 0), "DCPL creation succeeded"); - VRFY((H5Pset_chunk(plist_id, SHARED_FILTERED_CHUNKS_DATASET_DIMS, chunk_dims) >= 0), "Chunk size set"); + VRFY((H5Pset_chunk(plist_id, WRITE_SHARED_FILTERED_CHUNKS_DATASET_DIMS, chunk_dims) >= 0), + "Chunk size set"); /* Add test filter to the pipeline */ - VRFY((SET_FILTER(plist_id) >= 0), "Filter set"); + VRFY((set_dcpl_filter(plist_id) >= 0), "Filter set"); - dset_id = H5Dcreate2(file_id, SHARED_FILTERED_CHUNKS_DATASET_NAME, HDF5_DATATYPE_NAME, filespace, + dset_id = H5Dcreate2(file_id, WRITE_SHARED_FILTERED_CHUNKS_DATASET_NAME, HDF5_DATATYPE_NAME, filespace, H5P_DEFAULT, plist_id, H5P_DEFAULT); VRFY((dset_id >= 0), "Dataset creation succeeded"); @@ -438,68 +532,77 @@ test_filtered_dataset_overlap(void) /* Each process defines the dataset selection in memory and writes * it to the hyperslab in the file */ - count[0] = (hsize_t) SHARED_FILTERED_CHUNKS_NROWS / (hsize_t) SHARED_FILTERED_CHUNKS_CH_NROWS; - count[1] = (hsize_t) SHARED_FILTERED_CHUNKS_NCOLS / (hsize_t) SHARED_FILTERED_CHUNKS_CH_NCOLS; - stride[0] = (hsize_t) SHARED_FILTERED_CHUNKS_CH_NROWS; - stride[1] = (hsize_t) SHARED_FILTERED_CHUNKS_CH_NCOLS; - block[0] = (hsize_t) SHARED_FILTERED_CHUNKS_CH_NROWS / (hsize_t) mpi_size; - block[1] = (hsize_t) SHARED_FILTERED_CHUNKS_CH_NCOLS; - offset[0] = (hsize_t) mpi_rank * block[0]; - offset[1] = 0; - - if (VERBOSE_MED) - printf("Process %d is writing with count[ %llu, %llu ], stride[ %llu, %llu ], offset[ %llu, %llu ], block size[ %llu, %llu ]\n", - mpi_rank, count[0], count[1], stride[0], stride[1], offset[0], offset[1], block[0], block[1]); + count[0] = (hsize_t) WRITE_SHARED_FILTERED_CHUNKS_NROWS / (hsize_t) WRITE_SHARED_FILTERED_CHUNKS_CH_NROWS; + count[1] = (hsize_t) WRITE_SHARED_FILTERED_CHUNKS_NCOLS / (hsize_t) WRITE_SHARED_FILTERED_CHUNKS_CH_NCOLS; + stride[0] = (hsize_t) WRITE_SHARED_FILTERED_CHUNKS_CH_NROWS; + stride[1] = (hsize_t) WRITE_SHARED_FILTERED_CHUNKS_CH_NCOLS; + block[0] = (hsize_t) WRITE_SHARED_FILTERED_CHUNKS_CH_NROWS / (hsize_t) mpi_size; + block[1] = (hsize_t) WRITE_SHARED_FILTERED_CHUNKS_CH_NCOLS; + start[0] = (hsize_t) mpi_rank * block[0]; + start[1] = 0; + + if (VERBOSE_MED) { + printf("Process %d is writing with count[ %llu, %llu ], stride[ %llu, %llu ], start[ %llu, %llu ], block size[ %llu, %llu ]\n", + mpi_rank, count[0], count[1], stride[0], stride[1], start[0], start[1], block[0], block[1]); + fflush(stdout); + } /* Select hyperslab in the file */ filespace = H5Dget_space(dset_id); VRFY((filespace >= 0), "File dataspace retrieval succeeded"); - VRFY((H5Sselect_hyperslab(filespace, H5S_SELECT_SET, offset, stride, count, block) >= 0), "Hyperslab selection succeeded"); + VRFY((H5Sselect_hyperslab(filespace, H5S_SELECT_SET, start, stride, count, block) >= 0), + "Hyperslab selection succeeded"); /* Fill data buffer */ data_size = sel_dims[0] * sel_dims[1] * sizeof(*data); correct_buf_size = dataset_dims[0] * dataset_dims[1] * sizeof(*correct_buf); - data = (C_DATATYPE *) calloc(1, data_size); - VRFY((NULL != data), "calloc succeeded"); + data = (C_DATATYPE *) HDcalloc(1, data_size); + VRFY((NULL != data), "HDcalloc succeeded"); - correct_buf = (C_DATATYPE *) calloc(1, correct_buf_size); - VRFY((NULL != correct_buf), "calloc succeeded"); + correct_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != correct_buf), "HDcalloc succeeded"); for (i = 0; i < data_size / sizeof(*data); i++) data[i] = (C_DATATYPE) GEN_DATA(i); for (i = 0; i < correct_buf_size / sizeof(*correct_buf); i++) - correct_buf[i] = (C_DATATYPE) ((dataset_dims[1] * (i / ((hsize_t) mpi_size * dataset_dims[1]))) - + (i % dataset_dims[1]) - + (((i % ((hsize_t) mpi_size * dataset_dims[1])) / dataset_dims[1]) % dataset_dims[1])); + correct_buf[i] = (C_DATATYPE) ( + (dataset_dims[1] * (i / ((hsize_t) mpi_size * dataset_dims[1]))) + + (i % dataset_dims[1]) + + (((i % ((hsize_t) mpi_size * dataset_dims[1])) / dataset_dims[1]) % dataset_dims[1]) + ); /* Create property list for collective dataset write */ plist_id = H5Pcreate(H5P_DATASET_XFER); VRFY((plist_id >= 0), "DXPL creation succeeded"); - VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), "Set DXPL MPIO succeeded"); + VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), + "Set DXPL MPIO succeeded"); - VRFY((H5Dwrite(dset_id, HDF5_DATATYPE_NAME, memspace, filespace, plist_id, data) >= 0), "Dataset write succeeded"); + VRFY((H5Dwrite(dset_id, HDF5_DATATYPE_NAME, memspace, filespace, plist_id, data) >= 0), + "Dataset write succeeded"); - if (data) free(data); + if (data) HDfree(data); VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); /* Verify correct data was written */ - read_buf = (C_DATATYPE *) calloc(1, correct_buf_size); - VRFY((NULL != read_buf), "calloc succeeded"); + read_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != read_buf), "HDcalloc succeeded"); - dset_id = H5Dopen2(file_id, "/" SHARED_FILTERED_CHUNKS_DATASET_NAME, H5P_DEFAULT); + dset_id = H5Dopen2(file_id, "/" WRITE_SHARED_FILTERED_CHUNKS_DATASET_NAME, H5P_DEFAULT); VRFY((dset_id >= 0), "Dataset open succeeded"); - VRFY((H5Dread(dset_id, HDF5_DATATYPE_NAME, H5S_ALL, H5S_ALL, plist_id, read_buf) >= 0), "Dataset read succeeded"); + VRFY((H5Dread(dset_id, HDF5_DATATYPE_NAME, H5S_ALL, H5S_ALL, plist_id, read_buf) >= 0), + "Dataset read succeeded"); - VRFY((0 == memcmp(read_buf, correct_buf, correct_buf_size)), "Data verification succeeded"); + VRFY((0 == memcmp(read_buf, correct_buf, correct_buf_size)), + "Data verification succeeded"); - if (correct_buf) free(correct_buf); - if (read_buf) free(read_buf); + if (correct_buf) HDfree(correct_buf); + if (read_buf) HDfree(read_buf); VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); @@ -523,18 +626,18 @@ test_filtered_dataset_overlap(void) * 02/01/2017 */ static void -test_filtered_dataset_single_no_selection(void) +test_write_filtered_dataset_single_no_selection(void) { C_DATATYPE *data = NULL; C_DATATYPE *read_buf = NULL; C_DATATYPE *correct_buf = NULL; - hsize_t dataset_dims[SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS]; - hsize_t chunk_dims[SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS]; - hsize_t sel_dims[SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS]; - hsize_t count[SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS]; - hsize_t stride[SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS]; - hsize_t block[SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS]; - hsize_t offset[SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t dataset_dims[WRITE_SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t chunk_dims[WRITE_SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t sel_dims[WRITE_SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t start[WRITE_SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t stride[WRITE_SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t count[WRITE_SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t block[WRITE_SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS]; size_t i, data_size, correct_buf_size; size_t segment_length; hid_t file_id = -1, dset_id = -1, plist_id = -1; @@ -546,9 +649,11 @@ test_filtered_dataset_single_no_selection(void) plist_id = H5Pcreate(H5P_FILE_ACCESS); VRFY((plist_id >= 0), "FAPL creation succeeded"); - VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), "Set FAPL MPIO succeeded"); + VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), + "Set FAPL MPIO succeeded"); - VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), "Set libver bounds succeeded"); + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); file_id = H5Fopen(filenames[0], H5F_ACC_RDWR, plist_id); VRFY((file_id >= 0), "Test file open succeeded"); @@ -556,32 +661,33 @@ test_filtered_dataset_single_no_selection(void) VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); /* Create the dataspace for the dataset */ - dataset_dims[0] = (hsize_t) SINGLE_NO_SELECTION_FILTERED_CHUNKS_NROWS; - dataset_dims[1] = (hsize_t) SINGLE_NO_SELECTION_FILTERED_CHUNKS_NCOLS; - chunk_dims[0] = (hsize_t) SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NROWS; - chunk_dims[1] = (hsize_t) SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NCOLS; - sel_dims[0] = (hsize_t) SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NROWS; - sel_dims[1] = (hsize_t) SINGLE_NO_SELECTION_FILTERED_CHUNKS_NCOLS; - - if (mpi_rank == SINGLE_NO_SELECTION_FILTERED_CHUNKS_NO_SELECT_PROC) + dataset_dims[0] = (hsize_t) WRITE_SINGLE_NO_SELECTION_FILTERED_CHUNKS_NROWS; + dataset_dims[1] = (hsize_t) WRITE_SINGLE_NO_SELECTION_FILTERED_CHUNKS_NCOLS; + chunk_dims[0] = (hsize_t) WRITE_SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NROWS; + chunk_dims[1] = (hsize_t) WRITE_SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NCOLS; + sel_dims[0] = (hsize_t) WRITE_SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NROWS; + sel_dims[1] = (hsize_t) WRITE_SINGLE_NO_SELECTION_FILTERED_CHUNKS_NCOLS; + + if (mpi_rank == WRITE_SINGLE_NO_SELECTION_FILTERED_CHUNKS_NO_SELECT_PROC) sel_dims[0] = sel_dims[1] = 0; - filespace = H5Screate_simple(SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS, dataset_dims, NULL); + filespace = H5Screate_simple(WRITE_SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS, dataset_dims, NULL); VRFY((filespace >= 0), "File dataspace creation succeeded"); - memspace = H5Screate_simple(SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS, sel_dims, NULL); + memspace = H5Screate_simple(WRITE_SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS, sel_dims, NULL); VRFY((memspace >= 0), "Memory dataspace creation succeeded"); /* Create chunked dataset */ plist_id = H5Pcreate(H5P_DATASET_CREATE); VRFY((plist_id >= 0), "DCPL creation succeeded"); - VRFY((H5Pset_chunk(plist_id, SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS, chunk_dims) >= 0), "Chunk size set"); + VRFY((H5Pset_chunk(plist_id, WRITE_SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS, chunk_dims) >= 0), + "Chunk size set"); /* Add test filter to the pipeline */ - VRFY((SET_FILTER(plist_id) >= 0), "Filter set"); + VRFY((set_dcpl_filter(plist_id) >= 0), "Filter set"); - dset_id = H5Dcreate2(file_id, SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_NAME, HDF5_DATATYPE_NAME, filespace, + dset_id = H5Dcreate2(file_id, WRITE_SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_NAME, HDF5_DATATYPE_NAME, filespace, H5P_DEFAULT, plist_id, H5P_DEFAULT); VRFY((dset_id >= 0), "Dataset creation succeeded"); @@ -592,73 +698,84 @@ test_filtered_dataset_single_no_selection(void) * it to the hyperslab in the file */ count[0] = 1; - count[1] = (hsize_t) SINGLE_NO_SELECTION_FILTERED_CHUNKS_NCOLS / (hsize_t) SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NCOLS; - stride[0] = (hsize_t) SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NROWS; - stride[1] = (hsize_t) SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NCOLS; - block[0] = (hsize_t) SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NROWS; - block[1] = (hsize_t) SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NCOLS; - offset[0] = (hsize_t) mpi_rank * (hsize_t) SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NROWS * count[0]; - offset[1] = 0; - - if (VERBOSE_MED) - printf("Process %d is writing with count[ %llu, %llu ], stride[ %llu, %llu ], offset[ %llu, %llu ], block size[ %llu, %llu ]\n", - mpi_rank, count[0], count[1], stride[0], stride[1], offset[0], offset[1], block[0], block[1]); + count[1] = (hsize_t) WRITE_SINGLE_NO_SELECTION_FILTERED_CHUNKS_NCOLS / (hsize_t) WRITE_SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NCOLS; + stride[0] = (hsize_t) WRITE_SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NROWS; + stride[1] = (hsize_t) WRITE_SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NCOLS; + block[0] = (hsize_t) WRITE_SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NROWS; + block[1] = (hsize_t) WRITE_SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NCOLS; + start[0] = (hsize_t) mpi_rank * (hsize_t) WRITE_SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NROWS * count[0]; + start[1] = 0; + + if (VERBOSE_MED) { + printf("Process %d is writing with count[ %llu, %llu ], stride[ %llu, %llu ], start[ %llu, %llu ], block size[ %llu, %llu ]\n", + mpi_rank, count[0], count[1], stride[0], stride[1], start[0], start[1], block[0], block[1]); + fflush(stdout); + } /* Select hyperslab in the file */ filespace = H5Dget_space(dset_id); VRFY((filespace >= 0), "File dataspace retrieval succeeded"); - if (mpi_rank == SINGLE_NO_SELECTION_FILTERED_CHUNKS_NO_SELECT_PROC) + if (mpi_rank == WRITE_SINGLE_NO_SELECTION_FILTERED_CHUNKS_NO_SELECT_PROC) VRFY((H5Sselect_none(filespace) >= 0), "Select none succeeded"); else - VRFY((H5Sselect_hyperslab(filespace, H5S_SELECT_SET, offset, stride, count, block) >= 0), "Hyperslab selection succeeded"); + VRFY((H5Sselect_hyperslab(filespace, H5S_SELECT_SET, start, stride, count, block) >= 0), + "Hyperslab selection succeeded"); /* Fill data buffer */ data_size = sel_dims[0] * sel_dims[1] * sizeof(*data); correct_buf_size = dataset_dims[0] * dataset_dims[1] * sizeof(*correct_buf); - data = (C_DATATYPE *) calloc(1, data_size); - VRFY((NULL != data), "calloc succeeded"); + data = (C_DATATYPE *) HDcalloc(1, data_size); + VRFY((NULL != data), "HDcalloc succeeded"); - correct_buf = (C_DATATYPE *) calloc(1, correct_buf_size); - VRFY((NULL != correct_buf), "calloc succeeded"); + correct_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != correct_buf), "HDcalloc succeeded"); for (i = 0; i < data_size / sizeof(*data); i++) data[i] = (C_DATATYPE) GEN_DATA(i); for (i = 0; i < correct_buf_size / sizeof(*correct_buf); i++) - correct_buf[i] = (C_DATATYPE) ( (i % (dataset_dims[0] / (hsize_t) mpi_size * dataset_dims[1])) - + (i / (dataset_dims[0] / (hsize_t) mpi_size * dataset_dims[1]))); + correct_buf[i] = + (C_DATATYPE) ( + (i % (dataset_dims[0] / (hsize_t) mpi_size * dataset_dims[1])) + + (i / (dataset_dims[0] / (hsize_t) mpi_size * dataset_dims[1])) + ); /* Compute the correct offset into the buffer for the process having no selection and clear it */ segment_length = dataset_dims[0] * dataset_dims[1] / (hsize_t) mpi_size; - HDmemset(correct_buf + ((size_t) SINGLE_NO_SELECTION_FILTERED_CHUNKS_NO_SELECT_PROC * segment_length), 0, segment_length * sizeof(*data)); + HDmemset(correct_buf + ((size_t) WRITE_SINGLE_NO_SELECTION_FILTERED_CHUNKS_NO_SELECT_PROC * segment_length), + 0, segment_length * sizeof(*data)); /* Create property list for collective dataset write */ plist_id = H5Pcreate(H5P_DATASET_XFER); VRFY((plist_id >= 0), "DXPL creation succeeded"); - VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), "Set DXPL MPIO succeeded"); + VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), + "Set DXPL MPIO succeeded"); - VRFY((H5Dwrite(dset_id, HDF5_DATATYPE_NAME, memspace, filespace, plist_id, data) >= 0), "Dataset write succeeded"); + VRFY((H5Dwrite(dset_id, HDF5_DATATYPE_NAME, memspace, filespace, plist_id, data) >= 0), + "Dataset write succeeded"); - if (data) free(data); + if (data) HDfree(data); VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); /* Verify the correct data was written */ - read_buf = (C_DATATYPE *) calloc(1, correct_buf_size); - VRFY((NULL != read_buf), "calloc succeeded"); + read_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != read_buf), "HDcalloc succeeded"); - dset_id = H5Dopen2(file_id, "/" SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_NAME, H5P_DEFAULT); + dset_id = H5Dopen2(file_id, "/" WRITE_SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_NAME, H5P_DEFAULT); VRFY((dset_id >= 0), "Dataset open succeeded"); - VRFY((H5Dread(dset_id, HDF5_DATATYPE_NAME, H5S_ALL, H5S_ALL, plist_id, read_buf) >= 0), "Dataset read succeeded"); + VRFY((H5Dread(dset_id, HDF5_DATATYPE_NAME, H5S_ALL, H5S_ALL, plist_id, read_buf) >= 0), + "Dataset read succeeded"); - VRFY((0 == memcmp(read_buf, correct_buf, correct_buf_size)), "Data verification succeeded"); + VRFY((0 == memcmp(read_buf, correct_buf, correct_buf_size)), + "Data verification succeeded"); - if (correct_buf) free(correct_buf); - if (read_buf) free(read_buf); + if (correct_buf) HDfree(correct_buf); + if (read_buf) HDfree(read_buf); VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); @@ -683,14 +800,14 @@ test_filtered_dataset_single_no_selection(void) * 02/02/2017 */ static void -test_filtered_dataset_all_no_selection(void) +test_write_filtered_dataset_all_no_selection(void) { C_DATATYPE *data = NULL; C_DATATYPE *read_buf = NULL; C_DATATYPE *correct_buf = NULL; - hsize_t dataset_dims[ALL_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS]; - hsize_t chunk_dims[ALL_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS]; - hsize_t sel_dims[ALL_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t dataset_dims[WRITE_ALL_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t chunk_dims[WRITE_ALL_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t sel_dims[WRITE_ALL_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS]; size_t i, data_size, correct_buf_size; hid_t file_id = -1, dset_id = -1, plist_id = -1; hid_t filespace = -1, memspace = -1; @@ -701,9 +818,11 @@ test_filtered_dataset_all_no_selection(void) plist_id = H5Pcreate(H5P_FILE_ACCESS); VRFY((plist_id >= 0), "FAPL creation succeeded"); - VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), "Set FAPL MPIO succeeded"); + VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), + "Set FAPL MPIO succeeded"); - VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), "Set libver bounds succeeded"); + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); file_id = H5Fopen(filenames[0], H5F_ACC_RDWR, plist_id); VRFY((file_id >= 0), "Test file open succeeded"); @@ -711,28 +830,29 @@ test_filtered_dataset_all_no_selection(void) VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); /* Create the dataspace for the dataset */ - dataset_dims[0] = (hsize_t) ALL_NO_SELECTION_FILTERED_CHUNKS_NROWS; - dataset_dims[1] = (hsize_t) ALL_NO_SELECTION_FILTERED_CHUNKS_NCOLS; - chunk_dims[0] = (hsize_t) ALL_NO_SELECTION_FILTERED_CHUNKS_CH_NROWS; - chunk_dims[1] = (hsize_t) ALL_NO_SELECTION_FILTERED_CHUNKS_CH_NCOLS; + dataset_dims[0] = (hsize_t) WRITE_ALL_NO_SELECTION_FILTERED_CHUNKS_NROWS; + dataset_dims[1] = (hsize_t) WRITE_ALL_NO_SELECTION_FILTERED_CHUNKS_NCOLS; + chunk_dims[0] = (hsize_t) WRITE_ALL_NO_SELECTION_FILTERED_CHUNKS_CH_NROWS; + chunk_dims[1] = (hsize_t) WRITE_ALL_NO_SELECTION_FILTERED_CHUNKS_CH_NCOLS; sel_dims[0] = sel_dims[1] = 0; - filespace = H5Screate_simple(ALL_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS, dataset_dims, NULL); + filespace = H5Screate_simple(WRITE_ALL_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS, dataset_dims, NULL); VRFY((filespace >= 0), "File dataspace creation succeeded"); - memspace = H5Screate_simple(ALL_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS, sel_dims, NULL); + memspace = H5Screate_simple(WRITE_ALL_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS, sel_dims, NULL); VRFY((memspace >= 0), "Memory dataspace creation succeeded"); /* Create chunked dataset */ plist_id = H5Pcreate(H5P_DATASET_CREATE); VRFY((plist_id >= 0), "DCPL creation succeeded"); - VRFY((H5Pset_chunk(plist_id, ALL_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS, chunk_dims) >= 0), "Chunk size set"); + VRFY((H5Pset_chunk(plist_id, WRITE_ALL_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS, chunk_dims) >= 0), + "Chunk size set"); /* Add test filter to the pipeline */ - VRFY((SET_FILTER(plist_id) >= 0), "Filter set"); + VRFY((set_dcpl_filter(plist_id) >= 0), "Filter set"); - dset_id = H5Dcreate2(file_id, ALL_NO_SELECTION_FILTERED_CHUNKS_DATASET_NAME, HDF5_DATATYPE_NAME, filespace, + dset_id = H5Dcreate2(file_id, WRITE_ALL_NO_SELECTION_FILTERED_CHUNKS_DATASET_NAME, HDF5_DATATYPE_NAME, filespace, H5P_DEFAULT, plist_id, H5P_DEFAULT); VRFY((dset_id >= 0), "Dataset creation succeeded"); @@ -748,11 +868,11 @@ test_filtered_dataset_all_no_selection(void) data_size = sel_dims[0] * sel_dims[1] * sizeof(*data); correct_buf_size = dataset_dims[0] * dataset_dims[1] * sizeof(*correct_buf); - data = (C_DATATYPE *) calloc(1, data_size); - VRFY((NULL != data), "calloc succeeded"); + data = (C_DATATYPE *) HDcalloc(1, data_size); + VRFY((NULL != data), "HDcalloc succeeded"); - correct_buf = (C_DATATYPE *) calloc(1, correct_buf_size); - VRFY((NULL != correct_buf), "calloc succeeded"); + correct_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != correct_buf), "HDcalloc succeeded"); for (i = 0; i < data_size / sizeof(*data); i++) data[i] = (C_DATATYPE) GEN_DATA(i); @@ -761,27 +881,31 @@ test_filtered_dataset_all_no_selection(void) plist_id = H5Pcreate(H5P_DATASET_XFER); VRFY((plist_id >= 0), "DXPL creation succeeded"); - VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), "Set DXPL MPIO succeeded"); + VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), + "Set DXPL MPIO succeeded"); - VRFY((H5Dwrite(dset_id, HDF5_DATATYPE_NAME, memspace, filespace, plist_id, data) >= 0), "Dataset write succeeded"); + VRFY((H5Dwrite(dset_id, HDF5_DATATYPE_NAME, memspace, filespace, plist_id, data) >= 0), + "Dataset write succeeded"); - if (data) free(data); + if (data) HDfree(data); VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); /* Verify the correct data was written */ - read_buf = (C_DATATYPE *) calloc(1, correct_buf_size); - VRFY((NULL != read_buf), "calloc succeeded"); + read_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != read_buf), "HDcalloc succeeded"); - dset_id = H5Dopen2(file_id, "/" ALL_NO_SELECTION_FILTERED_CHUNKS_DATASET_NAME, H5P_DEFAULT); + dset_id = H5Dopen2(file_id, "/" WRITE_ALL_NO_SELECTION_FILTERED_CHUNKS_DATASET_NAME, H5P_DEFAULT); VRFY((dset_id >= 0), "Dataset open succeeded"); - VRFY((H5Dread(dset_id, HDF5_DATATYPE_NAME, H5S_ALL, H5S_ALL, plist_id, read_buf) >= 0), "Dataset read succeeded"); + VRFY((H5Dread(dset_id, HDF5_DATATYPE_NAME, H5S_ALL, H5S_ALL, plist_id, read_buf) >= 0), + "Dataset read succeeded"); - VRFY((0 == memcmp(read_buf, correct_buf, correct_buf_size)), "Data verification succeeded"); + VRFY((0 == memcmp(read_buf, correct_buf, correct_buf_size)), + "Data verification succeeded"); - if (correct_buf) free(correct_buf); - if (read_buf) free(read_buf); + if (correct_buf) HDfree(correct_buf); + if (read_buf) HDfree(read_buf); VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); @@ -800,15 +924,15 @@ test_filtered_dataset_all_no_selection(void) * 02/02/2017 */ static void -test_filtered_dataset_point_selection(void) +test_write_filtered_dataset_point_selection(void) { C_DATATYPE *data = NULL; C_DATATYPE *correct_buf = NULL; C_DATATYPE *read_buf = NULL; hsize_t *coords = NULL; - hsize_t dataset_dims[POINT_SELECTION_FILTERED_CHUNKS_DATASET_DIMS]; - hsize_t chunk_dims[POINT_SELECTION_FILTERED_CHUNKS_DATASET_DIMS]; - hsize_t sel_dims[POINT_SELECTION_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t dataset_dims[WRITE_POINT_SELECTION_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t chunk_dims[WRITE_POINT_SELECTION_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t sel_dims[WRITE_POINT_SELECTION_FILTERED_CHUNKS_DATASET_DIMS]; size_t i, j, data_size, correct_buf_size; size_t num_points; hid_t file_id = -1, dset_id = -1, plist_id = -1; @@ -820,9 +944,11 @@ test_filtered_dataset_point_selection(void) plist_id = H5Pcreate(H5P_FILE_ACCESS); VRFY((plist_id >= 0), "FAPL creation succeeded"); - VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), "Set FAPL MPIO succeeded"); + VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), + "Set FAPL MPIO succeeded"); - VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), "Set libver bounds succeeded"); + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); file_id = H5Fopen(filenames[0], H5F_ACC_RDWR, plist_id); VRFY((file_id >= 0), "Test file open succeeded"); @@ -830,29 +956,30 @@ test_filtered_dataset_point_selection(void) VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); /* Create the dataspace for the dataset */ - dataset_dims[0] = (hsize_t) POINT_SELECTION_FILTERED_CHUNKS_NROWS; - dataset_dims[1] = (hsize_t) POINT_SELECTION_FILTERED_CHUNKS_NCOLS; - chunk_dims[0] = (hsize_t) POINT_SELECTION_FILTERED_CHUNKS_CH_NROWS; - chunk_dims[1] = (hsize_t) POINT_SELECTION_FILTERED_CHUNKS_CH_NCOLS; - sel_dims[0] = (hsize_t) POINT_SELECTION_FILTERED_CHUNKS_NROWS / (hsize_t) mpi_size; - sel_dims[1] = (hsize_t) POINT_SELECTION_FILTERED_CHUNKS_NCOLS; - - filespace = H5Screate_simple(POINT_SELECTION_FILTERED_CHUNKS_DATASET_DIMS, dataset_dims, NULL); + dataset_dims[0] = (hsize_t) WRITE_POINT_SELECTION_FILTERED_CHUNKS_NROWS; + dataset_dims[1] = (hsize_t) WRITE_POINT_SELECTION_FILTERED_CHUNKS_NCOLS; + chunk_dims[0] = (hsize_t) WRITE_POINT_SELECTION_FILTERED_CHUNKS_CH_NROWS; + chunk_dims[1] = (hsize_t) WRITE_POINT_SELECTION_FILTERED_CHUNKS_CH_NCOLS; + sel_dims[0] = (hsize_t) WRITE_POINT_SELECTION_FILTERED_CHUNKS_NROWS / (hsize_t) mpi_size; + sel_dims[1] = (hsize_t) WRITE_POINT_SELECTION_FILTERED_CHUNKS_NCOLS; + + filespace = H5Screate_simple(WRITE_POINT_SELECTION_FILTERED_CHUNKS_DATASET_DIMS, dataset_dims,NULL); VRFY((filespace >= 0), "File dataspace creation succeeded"); - memspace = H5Screate_simple(POINT_SELECTION_FILTERED_CHUNKS_DATASET_DIMS, sel_dims, NULL); + memspace = H5Screate_simple(WRITE_POINT_SELECTION_FILTERED_CHUNKS_DATASET_DIMS, sel_dims, NULL); VRFY((memspace >= 0), "Memory dataspace creation succeeded"); /* Create chunked dataset */ plist_id = H5Pcreate(H5P_DATASET_CREATE); VRFY((plist_id >= 0), "DCPL creation succeeded"); - VRFY((H5Pset_chunk(plist_id, POINT_SELECTION_FILTERED_CHUNKS_DATASET_DIMS, chunk_dims) >= 0), "Chunk size set"); + VRFY((H5Pset_chunk(plist_id, WRITE_POINT_SELECTION_FILTERED_CHUNKS_DATASET_DIMS, chunk_dims) >= 0), + "Chunk size set"); /* Add test filter to the pipeline */ - VRFY((SET_FILTER(plist_id) >= 0), "Filter set"); + VRFY((set_dcpl_filter(plist_id) >= 0), "Filter set"); - dset_id = H5Dcreate2(file_id, POINT_SELECTION_FILTERED_CHUNKS_DATASET_NAME, HDF5_DATATYPE_NAME, filespace, + dset_id = H5Dcreate2(file_id, WRITE_POINT_SELECTION_FILTERED_CHUNKS_DATASET_NAME, HDF5_DATATYPE_NAME, filespace, H5P_DEFAULT, plist_id, H5P_DEFAULT); VRFY((dset_id >= 0), "Dataset creation succeeded"); @@ -863,62 +990,69 @@ test_filtered_dataset_point_selection(void) filespace = H5Dget_space(dset_id); VRFY((filespace >= 0), "File dataspace retrieval succeeded"); - num_points = (hsize_t) POINT_SELECTION_FILTERED_CHUNKS_NROWS * (hsize_t) POINT_SELECTION_FILTERED_CHUNKS_NCOLS / (hsize_t) mpi_size; - coords = (hsize_t *) calloc(1, 2 * num_points * sizeof(*coords)); - VRFY((NULL != coords), "Coords calloc succeeded"); + num_points = (hsize_t) WRITE_POINT_SELECTION_FILTERED_CHUNKS_NROWS * (hsize_t) WRITE_POINT_SELECTION_FILTERED_CHUNKS_NCOLS / (hsize_t) mpi_size; + coords = (hsize_t *) HDcalloc(1, 2 * num_points * sizeof(*coords)); + VRFY((NULL != coords), "Coords HDcalloc succeeded"); for (i = 0; i < num_points; i++) - for (j = 0; j < POINT_SELECTION_FILTERED_CHUNKS_DATASET_DIMS; j++) - coords[(i * POINT_SELECTION_FILTERED_CHUNKS_DATASET_DIMS) + j] = (j > 0) ? (i % (hsize_t) POINT_SELECTION_FILTERED_CHUNKS_NCOLS) - : ((hsize_t) mpi_rank + ((hsize_t) mpi_size * (i / (hsize_t) POINT_SELECTION_FILTERED_CHUNKS_NCOLS))); + for (j = 0; j < WRITE_POINT_SELECTION_FILTERED_CHUNKS_DATASET_DIMS; j++) + coords[(i * WRITE_POINT_SELECTION_FILTERED_CHUNKS_DATASET_DIMS) + j] = + (j > 0) ? (i % (hsize_t) WRITE_POINT_SELECTION_FILTERED_CHUNKS_NCOLS) + : ((hsize_t) mpi_rank + ((hsize_t) mpi_size * (i / (hsize_t) WRITE_POINT_SELECTION_FILTERED_CHUNKS_NCOLS))); - VRFY((H5Sselect_elements(filespace, H5S_SELECT_SET, (hsize_t) num_points, (const hsize_t *) coords) >= 0), + VRFY((H5Sselect_elements(filespace, H5S_SELECT_SET, (hsize_t ) num_points, (const hsize_t * ) coords) >= 0), "Point selection succeeded"); /* Fill data buffer */ data_size = sel_dims[0] * sel_dims[1] * sizeof(*data); correct_buf_size = dataset_dims[0] * dataset_dims[1] * sizeof(*correct_buf); - data = (C_DATATYPE *) calloc(1, data_size); - VRFY((NULL != data), "calloc succeeded"); + data = (C_DATATYPE *) HDcalloc(1, data_size); + VRFY((NULL != data), "HDcalloc succeeded"); - correct_buf = (C_DATATYPE *) calloc(1, correct_buf_size); - VRFY((NULL != correct_buf), "calloc succeeded"); + correct_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != correct_buf), "HDcalloc succeeded"); for (i = 0; i < data_size / sizeof(*data); i++) data[i] = (C_DATATYPE) GEN_DATA(i); for (i = 0; i < correct_buf_size / sizeof(*correct_buf); i++) - correct_buf[i] = (C_DATATYPE) ((dataset_dims[1] * (i / ((hsize_t) mpi_size * dataset_dims[1]))) - + (i % dataset_dims[1]) - + (((i % ((hsize_t) mpi_size * dataset_dims[1])) / dataset_dims[1]) % dataset_dims[1])); + correct_buf[i] = (C_DATATYPE) ( + (dataset_dims[1] * (i / ((hsize_t) mpi_size * dataset_dims[1]))) + + (i % dataset_dims[1]) + + (((i % ((hsize_t) mpi_size * dataset_dims[1])) / dataset_dims[1]) % dataset_dims[1]) + ); /* Create property list for collective dataset write */ plist_id = H5Pcreate(H5P_DATASET_XFER); VRFY((plist_id >= 0), "DXPL creation succeeded"); - VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), "Set DXPL MPIO succeeded"); + VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), + "Set DXPL MPIO succeeded"); - VRFY((H5Dwrite(dset_id, HDF5_DATATYPE_NAME, memspace, filespace, plist_id, data) >= 0), "Dataset write succeeded"); + VRFY((H5Dwrite(dset_id, HDF5_DATATYPE_NAME, memspace, filespace, plist_id, data) >= 0), + "Dataset write succeeded"); - if (data) free(data); + if (data) HDfree(data); VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); /* Verify the correct data was written */ - read_buf = (C_DATATYPE *) calloc(1, correct_buf_size); - VRFY((NULL != read_buf), "calloc succeeded"); + read_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != read_buf), "HDcalloc succeeded"); - dset_id = H5Dopen2(file_id, "/" POINT_SELECTION_FILTERED_CHUNKS_DATASET_NAME, H5P_DEFAULT); + dset_id = H5Dopen2(file_id, "/" WRITE_POINT_SELECTION_FILTERED_CHUNKS_DATASET_NAME, H5P_DEFAULT); VRFY((dset_id >= 0), "Dataset open succeeded"); - VRFY((H5Dread(dset_id, HDF5_DATATYPE_NAME, H5S_ALL, H5S_ALL, plist_id, read_buf) >= 0), "Dataset read succeeded"); + VRFY((H5Dread(dset_id, HDF5_DATATYPE_NAME, H5S_ALL, H5S_ALL, plist_id, read_buf) >= 0), + "Dataset read succeeded"); - VRFY((0 == memcmp(read_buf, correct_buf, correct_buf_size)), "Data verification succeeded"); + VRFY((0 == memcmp(read_buf, correct_buf, correct_buf_size)), + "Data verification succeeded"); - if (coords) free(coords); - if (correct_buf) free(correct_buf); - if (read_buf) free(read_buf); + if (coords) HDfree(coords); + if (correct_buf) HDfree(correct_buf); + if (read_buf) HDfree(read_buf); VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); @@ -941,7 +1075,7 @@ test_filtered_dataset_point_selection(void) * 02/02/2017 */ static void -test_filtered_dataset_interleaved_write(void) +test_write_filtered_dataset_interleaved_write(void) { C_DATATYPE *data = NULL; C_DATATYPE *read_buf = NULL; @@ -949,10 +1083,10 @@ test_filtered_dataset_interleaved_write(void) hsize_t dataset_dims[INTERLEAVED_WRITE_FILTERED_DATASET_DIMS]; hsize_t chunk_dims[INTERLEAVED_WRITE_FILTERED_DATASET_DIMS]; hsize_t sel_dims[INTERLEAVED_WRITE_FILTERED_DATASET_DIMS]; - hsize_t count[INTERLEAVED_WRITE_FILTERED_DATASET_DIMS]; + hsize_t start[INTERLEAVED_WRITE_FILTERED_DATASET_DIMS]; hsize_t stride[INTERLEAVED_WRITE_FILTERED_DATASET_DIMS]; + hsize_t count[INTERLEAVED_WRITE_FILTERED_DATASET_DIMS]; hsize_t block[INTERLEAVED_WRITE_FILTERED_DATASET_DIMS]; - hsize_t offset[INTERLEAVED_WRITE_FILTERED_DATASET_DIMS]; size_t i, data_size, correct_buf_size; hid_t file_id = -1, dset_id = -1, plist_id = -1; hid_t filespace = -1, memspace = -1; @@ -963,9 +1097,11 @@ test_filtered_dataset_interleaved_write(void) plist_id = H5Pcreate(H5P_FILE_ACCESS); VRFY((plist_id >= 0), "FAPL creation succeeded"); - VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), "Set FAPL MPIO succeeded"); + VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), + "Set FAPL MPIO succeeded"); - VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), "Set libver bounds succeeded"); + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); file_id = H5Fopen(filenames[0], H5F_ACC_RDWR, plist_id); VRFY((file_id >= 0), "Test file open succeeded"); @@ -990,10 +1126,11 @@ test_filtered_dataset_interleaved_write(void) plist_id = H5Pcreate(H5P_DATASET_CREATE); VRFY((plist_id >= 0), "DCPL creation succeeded"); - VRFY((H5Pset_chunk(plist_id, INTERLEAVED_WRITE_FILTERED_DATASET_DIMS, chunk_dims) >= 0), "Chunk size set"); + VRFY((H5Pset_chunk(plist_id, INTERLEAVED_WRITE_FILTERED_DATASET_DIMS, chunk_dims) >= 0), + "Chunk size set"); /* Add test filter to the pipeline */ - VRFY((SET_FILTER(plist_id) >= 0), "Filter set"); + VRFY((set_dcpl_filter(plist_id) >= 0), "Filter set"); dset_id = H5Dcreate2(file_id, INTERLEAVED_WRITE_FILTERED_DATASET_NAME, HDF5_DATATYPE_NAME, filespace, H5P_DEFAULT, plist_id, H5P_DEFAULT); @@ -1011,67 +1148,77 @@ test_filtered_dataset_interleaved_write(void) stride[1] = (hsize_t) INTERLEAVED_WRITE_FILTERED_DATASET_CH_NCOLS; block[0] = 1; block[1] = (hsize_t) INTERLEAVED_WRITE_FILTERED_DATASET_CH_NCOLS; - offset[0] = (hsize_t) mpi_rank; - offset[1] = 0; + start[0] = (hsize_t) mpi_rank; + start[1] = 0; - if (VERBOSE_MED) - printf("Process %d is writing with count[ %llu, %llu ], stride[ %llu, %llu ], offset[ %llu, %llu ], block size[ %llu, %llu ]\n", - mpi_rank, count[0], count[1], stride[0], stride[1], offset[0], offset[1], block[0], block[1]); + if (VERBOSE_MED) { + printf("Process %d is writing with count[ %llu, %llu ], stride[ %llu, %llu ], start[ %llu, %llu ], block size[ %llu, %llu ]\n", + mpi_rank, count[0], count[1], stride[0], stride[1], start[0], start[1], block[0], block[1]); + fflush(stdout); + } /* Select hyperslab in the file */ filespace = H5Dget_space(dset_id); VRFY((filespace >= 0), "File dataspace retrieval succeeded"); - VRFY((H5Sselect_hyperslab(filespace, H5S_SELECT_SET, offset, stride, count, block) >= 0), "Hyperslab selection succeeded"); + VRFY((H5Sselect_hyperslab(filespace, H5S_SELECT_SET, start, stride, count, block) >= 0), + "Hyperslab selection succeeded"); /* Fill data buffer */ data_size = sel_dims[0] * sel_dims[1] * sizeof(*data); correct_buf_size = dataset_dims[0] * dataset_dims[1] * sizeof(*correct_buf); - data = (C_DATATYPE *) calloc(1, data_size); - VRFY((NULL != data), "calloc succeeded"); + data = (C_DATATYPE *) HDcalloc(1, data_size); + VRFY((NULL != data), "HDcalloc succeeded"); - correct_buf = (C_DATATYPE *) calloc(1, correct_buf_size); - VRFY((NULL != correct_buf), "calloc succeeded"); + correct_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != correct_buf), "HDcalloc succeeded"); for (i = 0; i < data_size / sizeof(*data); i++) data[i] = (C_DATATYPE) GEN_DATA(i); for (i = 0; i < correct_buf_size / sizeof(*correct_buf); i++) - /* Add Column Index */ - correct_buf[i] = (C_DATATYPE) ( (i % (hsize_t) INTERLEAVED_WRITE_FILTERED_DATASET_NCOLS) + /* Add Column Index */ + correct_buf[i] = + (C_DATATYPE) ( + (i % (hsize_t) INTERLEAVED_WRITE_FILTERED_DATASET_NCOLS) - /* Add the Row Index */ - + ((i % (hsize_t) (mpi_size * INTERLEAVED_WRITE_FILTERED_DATASET_NCOLS)) / (hsize_t) INTERLEAVED_WRITE_FILTERED_DATASET_NCOLS) + /* Add the Row Index */ + + ((i % (hsize_t) (mpi_size * INTERLEAVED_WRITE_FILTERED_DATASET_NCOLS)) / (hsize_t) INTERLEAVED_WRITE_FILTERED_DATASET_NCOLS) - /* Add the amount that gets added when a rank moves down to its next section vertically in the dataset */ - + ((hsize_t) INTERLEAVED_WRITE_FILTERED_DATASET_NCOLS * (i / (hsize_t) (mpi_size * INTERLEAVED_WRITE_FILTERED_DATASET_NCOLS)))); + /* Add the amount that gets added when a rank moves down to its next section vertically in the dataset */ + + ((hsize_t) INTERLEAVED_WRITE_FILTERED_DATASET_NCOLS * (i / (hsize_t) (mpi_size * INTERLEAVED_WRITE_FILTERED_DATASET_NCOLS))) + ); /* Create property list for collective dataset write */ plist_id = H5Pcreate(H5P_DATASET_XFER); VRFY((plist_id >= 0), "DXPL creation succeeded"); - VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), "Set DXPL MPIO succeeded"); + VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), + "Set DXPL MPIO succeeded"); - VRFY((H5Dwrite(dset_id, HDF5_DATATYPE_NAME, memspace, filespace, plist_id, data) >= 0), "Dataset write succeeded"); + VRFY((H5Dwrite(dset_id, HDF5_DATATYPE_NAME, memspace, filespace, plist_id, data) >= 0), + "Dataset write succeeded"); - if (data) free(data); + if (data) HDfree(data); VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); /* Verify the correct data was written */ - read_buf = (C_DATATYPE *) calloc(1, correct_buf_size); - VRFY((NULL != read_buf), "calloc succeeded"); + read_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != read_buf), "HDcalloc succeeded"); dset_id = H5Dopen2(file_id, "/" INTERLEAVED_WRITE_FILTERED_DATASET_NAME, H5P_DEFAULT); VRFY((dset_id >= 0), "Dataset open succeeded"); - VRFY((H5Dread(dset_id, HDF5_DATATYPE_NAME, H5S_ALL, H5S_ALL, plist_id, read_buf) >= 0), "Dataset read succeeded"); + VRFY((H5Dread(dset_id, HDF5_DATATYPE_NAME, H5S_ALL, H5S_ALL, plist_id, read_buf) >= 0), + "Dataset read succeeded"); - VRFY((0 == memcmp(read_buf, correct_buf, correct_buf_size)), "Data verification succeeded"); + VRFY((0 == memcmp(read_buf, correct_buf, correct_buf_size)), + "Data verification succeeded"); - if (correct_buf) free(correct_buf); - if (read_buf) free(read_buf); + if (correct_buf) HDfree(correct_buf); + if (read_buf) HDfree(read_buf); VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); @@ -1091,18 +1238,18 @@ test_filtered_dataset_interleaved_write(void) * 02/06/2017 */ static void -test_3d_filtered_dataset_no_overlap_separate_pages(void) +test_write_3d_filtered_dataset_no_overlap_separate_pages(void) { C_DATATYPE *data = NULL; C_DATATYPE *read_buf = NULL; C_DATATYPE *correct_buf = NULL; - hsize_t dataset_dims[UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_DIMS]; - hsize_t chunk_dims[UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_DIMS]; - hsize_t sel_dims[UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_DIMS]; - hsize_t count[UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_DIMS]; - hsize_t stride[UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_DIMS]; - hsize_t block[UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_DIMS]; - hsize_t offset[UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_DIMS]; + hsize_t dataset_dims[WRITE_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_DIMS]; + hsize_t chunk_dims[WRITE_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_DIMS]; + hsize_t sel_dims[WRITE_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_DIMS]; + hsize_t start[WRITE_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_DIMS]; + hsize_t stride[WRITE_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_DIMS]; + hsize_t count[WRITE_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_DIMS]; + hsize_t block[WRITE_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_DIMS]; size_t i, data_size, correct_buf_size; hid_t file_id = -1, dset_id = -1, plist_id = -1; hid_t filespace = -1, memspace = -1; @@ -1113,9 +1260,11 @@ test_3d_filtered_dataset_no_overlap_separate_pages(void) plist_id = H5Pcreate(H5P_FILE_ACCESS); VRFY((plist_id >= 0), "FAPL creation succeeded"); - VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), "Set FAPL MPIO succeeded"); + VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), + "Set FAPL MPIO succeeded"); - VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), "Set libver bounds succeeded"); + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); file_id = H5Fopen(filenames[0], H5F_ACC_RDWR, plist_id); VRFY((file_id >= 0), "Test file open succeeded"); @@ -1123,32 +1272,33 @@ test_3d_filtered_dataset_no_overlap_separate_pages(void) VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); /* Create the dataspace for the dataset */ - dataset_dims[0] = (hsize_t) UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_NROWS; - dataset_dims[1] = (hsize_t) UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_NCOLS; - dataset_dims[2] = (hsize_t) UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DEPTH; - chunk_dims[0] = (hsize_t) UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_CH_NROWS; - chunk_dims[1] = (hsize_t) UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_CH_NCOLS; + dataset_dims[0] = (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_NROWS; + dataset_dims[1] = (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_NCOLS; + dataset_dims[2] = (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DEPTH; + chunk_dims[0] = (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_CH_NROWS; + chunk_dims[1] = (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_CH_NCOLS; chunk_dims[2] = 1; - sel_dims[0] = (hsize_t) UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_NROWS; - sel_dims[1] = (hsize_t) UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_NCOLS; + sel_dims[0] = (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_NROWS; + sel_dims[1] = (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_NCOLS; sel_dims[2] = 1; - filespace = H5Screate_simple(UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_DIMS, dataset_dims, NULL); + filespace = H5Screate_simple( WRITE_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_DIMS, dataset_dims, NULL); VRFY((filespace >= 0), "File dataspace creation succeeded"); - memspace = H5Screate_simple(UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_DIMS, sel_dims, NULL); + memspace = H5Screate_simple( WRITE_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_DIMS, sel_dims, NULL); VRFY((memspace >= 0), "Memory dataspace creation succeeded"); /* Create chunked dataset */ plist_id = H5Pcreate(H5P_DATASET_CREATE); VRFY((plist_id >= 0), "DCPL creation succeeded"); - VRFY((H5Pset_chunk(plist_id, UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_DIMS, chunk_dims) >= 0), "Chunk size set"); + VRFY((H5Pset_chunk(plist_id, WRITE_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_DIMS, chunk_dims) >= 0), + "Chunk size set"); /* Add test filter to the pipeline */ - VRFY((SET_FILTER(plist_id) >= 0), "Filter set"); + VRFY((set_dcpl_filter(plist_id) >= 0), "Filter set"); - dset_id = H5Dcreate2(file_id, UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_NAME, HDF5_DATATYPE_NAME, filespace, + dset_id = H5Dcreate2(file_id, WRITE_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_NAME, HDF5_DATATYPE_NAME, filespace, H5P_DEFAULT, plist_id, H5P_DEFAULT); VRFY((dset_id >= 0), "Dataset creation succeeded"); @@ -1158,38 +1308,41 @@ test_3d_filtered_dataset_no_overlap_separate_pages(void) /* Each process defines the dataset selection in memory and writes * it to the hyperslab in the file */ - count[0] = (hsize_t) UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_NROWS / (hsize_t) UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_CH_NROWS; - count[1] = (hsize_t) UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_NCOLS / (hsize_t) UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_CH_NCOLS; + count[0] = (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_NROWS / (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_CH_NROWS; + count[1] = (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_NCOLS / (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_CH_NCOLS; count[2] = 1; - stride[0] = (hsize_t) UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_CH_NROWS; - stride[1] = (hsize_t) UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_CH_NCOLS; + stride[0] = (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_CH_NROWS; + stride[1] = (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_CH_NCOLS; stride[2] = 1; - block[0] = (hsize_t) UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_CH_NROWS; - block[1] = (hsize_t) UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_CH_NCOLS; + block[0] = (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_CH_NROWS; + block[1] = (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_CH_NCOLS; block[2] = 1; - offset[0] = 0; - offset[1] = 0; - offset[2] = (hsize_t) mpi_rank; - - if (VERBOSE_MED) - printf("Process %d is writing with count[ %llu, %llu, %llu ], stride[ %llu, %llu, %llu ], offset[ %llu, %llu, %llu ], block size[ %llu, %llu, %llu ]\n", - mpi_rank, count[0], count[1], count[2], stride[0], stride[1], stride[2], offset[0], offset[1], offset[2], block[0], block[1], block[2]); + start[0] = 0; + start[1] = 0; + start[2] = (hsize_t) mpi_rank; + + if (VERBOSE_MED) { + printf("Process %d is writing with count[ %llu, %llu, %llu ], stride[ %llu, %llu, %llu ], start[ %llu, %llu, %llu ], block size[ %llu, %llu, %llu ]\n", + mpi_rank, count[0], count[1], count[2], stride[0], stride[1], stride[2], start[0], start[1], start[2], block[0], block[1], block[2]); + fflush(stdout); + } /* Select hyperslab in the file */ filespace = H5Dget_space(dset_id); VRFY((filespace >= 0), "File dataspace retrieval succeeded"); - VRFY((H5Sselect_hyperslab(filespace, H5S_SELECT_SET, offset, stride, count, block) >= 0), "Hyperslab selection succeeded"); + VRFY((H5Sselect_hyperslab(filespace, H5S_SELECT_SET, start, stride, count, block) >= 0), + "Hyperslab selection succeeded"); /* Fill data buffer */ data_size = sel_dims[0] * sel_dims[1] * sel_dims[2] * sizeof(*data); correct_buf_size = dataset_dims[0] * dataset_dims[1] * dataset_dims[2] * sizeof(*correct_buf); - data = (C_DATATYPE *) calloc(1, data_size); - VRFY((NULL != data), "calloc succeeded"); + data = (C_DATATYPE *) HDcalloc(1, data_size); + VRFY((NULL != data), "HDcalloc succeeded"); - correct_buf = (C_DATATYPE *) calloc(1, correct_buf_size); - VRFY((NULL != correct_buf), "calloc succeeded"); + correct_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != correct_buf), "HDcalloc succeeded"); for (i = 0; i < data_size / sizeof(*data); i++) data[i] = (C_DATATYPE) GEN_DATA(i); @@ -1201,27 +1354,31 @@ test_3d_filtered_dataset_no_overlap_separate_pages(void) plist_id = H5Pcreate(H5P_DATASET_XFER); VRFY((plist_id >= 0), "DXPL creation succeeded"); - VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), "Set DXPL MPIO succeeded"); + VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), + "Set DXPL MPIO succeeded"); - VRFY((H5Dwrite(dset_id, HDF5_DATATYPE_NAME, memspace, filespace, plist_id, data) >= 0), "Dataset write succeeded"); + VRFY((H5Dwrite(dset_id, HDF5_DATATYPE_NAME, memspace, filespace, plist_id, data) >= 0), + "Dataset write succeeded"); - if (data) free(data); + if (data) HDfree(data); VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); /* Verify the correct data was written */ - read_buf = (C_DATATYPE *) calloc(1, correct_buf_size); - VRFY((NULL != read_buf), "calloc succeeded"); + read_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != read_buf), "HDcalloc succeeded"); - dset_id = H5Dopen2(file_id, "/" UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_NAME, H5P_DEFAULT); + dset_id = H5Dopen2(file_id, "/" WRITE_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_NAME, H5P_DEFAULT); VRFY((dset_id >= 0), "Dataset open succeeded"); - VRFY((H5Dread(dset_id, HDF5_DATATYPE_NAME, H5S_ALL, H5S_ALL, plist_id, read_buf) >= 0), "Dataset read succeeded"); + VRFY((H5Dread(dset_id, HDF5_DATATYPE_NAME, H5S_ALL, H5S_ALL, plist_id, read_buf) >= 0), + "Dataset read succeeded"); - VRFY((0 == memcmp(read_buf, correct_buf, correct_buf_size)), "Data verification succeeded"); + VRFY((0 == memcmp(read_buf, correct_buf, correct_buf_size)), + "Data verification succeeded"); - if (correct_buf) free(correct_buf); - if (read_buf) free(read_buf); + if (correct_buf) HDfree(correct_buf); + if (read_buf) HDfree(read_buf); VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); @@ -1242,18 +1399,18 @@ test_3d_filtered_dataset_no_overlap_separate_pages(void) * 02/06/2017 */ static void -test_3d_filtered_dataset_no_overlap_same_pages(void) +test_write_3d_filtered_dataset_no_overlap_same_pages(void) { C_DATATYPE *data = NULL; C_DATATYPE *read_buf = NULL; C_DATATYPE *correct_buf = NULL; - hsize_t dataset_dims[UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_DIMS]; - hsize_t chunk_dims[UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_DIMS]; - hsize_t sel_dims[UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_DIMS]; - hsize_t count[UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_DIMS]; - hsize_t stride[UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_DIMS]; - hsize_t block[UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_DIMS]; - hsize_t offset[UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_DIMS]; + hsize_t dataset_dims[WRITE_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_DIMS]; + hsize_t chunk_dims[WRITE_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_DIMS]; + hsize_t sel_dims[WRITE_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_DIMS]; + hsize_t start[WRITE_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_DIMS]; + hsize_t stride[WRITE_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_DIMS]; + hsize_t count[WRITE_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_DIMS]; + hsize_t block[WRITE_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_DIMS]; size_t i, data_size, correct_buf_size; hid_t file_id, dset_id, plist_id; hid_t filespace, memspace; @@ -1264,9 +1421,11 @@ test_3d_filtered_dataset_no_overlap_same_pages(void) plist_id = H5Pcreate(H5P_FILE_ACCESS); VRFY((plist_id >= 0), "FAPL creation succeeded"); - VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), "Set FAPL MPIO succeeded"); + VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), + "Set FAPL MPIO succeeded"); - VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), "Set libver bounds succeeded"); + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); file_id = H5Fopen(filenames[0], H5F_ACC_RDWR, plist_id); VRFY((file_id >= 0), "Test file open succeeded"); @@ -1274,32 +1433,33 @@ test_3d_filtered_dataset_no_overlap_same_pages(void) VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); /* Create the dataspace for the dataset */ - dataset_dims[0] = (hsize_t) UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_NROWS; - dataset_dims[1] = (hsize_t) UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_NCOLS; - dataset_dims[2] = (hsize_t) UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DEPTH; - chunk_dims[0] = (hsize_t) UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_CH_NROWS; - chunk_dims[1] = (hsize_t) UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_CH_NCOLS; + dataset_dims[0] = (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_NROWS; + dataset_dims[1] = (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_NCOLS; + dataset_dims[2] = (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DEPTH; + chunk_dims[0] = (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_CH_NROWS; + chunk_dims[1] = (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_CH_NCOLS; chunk_dims[2] = 1; - sel_dims[0] = (hsize_t) UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_CH_NROWS; - sel_dims[1] = (hsize_t) UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_NCOLS; - sel_dims[2] = (hsize_t) UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DEPTH; + sel_dims[0] = (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_CH_NROWS; + sel_dims[1] = (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_NCOLS; + sel_dims[2] = (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DEPTH; - filespace = H5Screate_simple(UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_DIMS, dataset_dims, NULL); + filespace = H5Screate_simple(WRITE_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_DIMS, dataset_dims, NULL); VRFY((filespace >= 0), "File dataspace creation succeeded"); - memspace = H5Screate_simple(UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_DIMS, sel_dims, NULL); + memspace = H5Screate_simple(WRITE_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_DIMS, sel_dims, NULL); VRFY((memspace >= 0), "Memory dataspace creation succeeded"); /* Create chunked dataset */ plist_id = H5Pcreate(H5P_DATASET_CREATE); VRFY((plist_id >= 0), "DCPL creation succeeded"); - VRFY((H5Pset_chunk(plist_id, UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_DIMS, chunk_dims) >= 0), "Chunk size set"); + VRFY((H5Pset_chunk(plist_id, WRITE_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_DIMS, chunk_dims) >= 0), + "Chunk size set"); /* Add test filter to the pipeline */ - VRFY((SET_FILTER(plist_id) >= 0), "Filter set"); + VRFY((set_dcpl_filter(plist_id) >= 0), "Filter set"); - dset_id = H5Dcreate2(file_id, UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_NAME, HDF5_DATATYPE_NAME, filespace, + dset_id = H5Dcreate2(file_id, WRITE_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_NAME, HDF5_DATATYPE_NAME, filespace, H5P_DEFAULT, plist_id, H5P_DEFAULT); VRFY((dset_id >= 0), "Dataset creation succeeded"); @@ -1310,69 +1470,79 @@ test_3d_filtered_dataset_no_overlap_same_pages(void) * it to the hyperslab in the file */ count[0] = 1; - count[1] = (hsize_t) UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_NCOLS / (hsize_t) UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_CH_NCOLS; + count[1] = (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_NCOLS / (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_CH_NCOLS; count[2] = (hsize_t) mpi_size; - stride[0] = (hsize_t) UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_CH_NROWS; - stride[1] = (hsize_t) UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_CH_NCOLS; + stride[0] = (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_CH_NROWS; + stride[1] = (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_CH_NCOLS; stride[2] = 1; - block[0] = (hsize_t) UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_CH_NROWS; - block[1] = (hsize_t) UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_CH_NCOLS; + block[0] = (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_CH_NROWS; + block[1] = (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_CH_NCOLS; block[2] = 1; - offset[0] = ((hsize_t) mpi_rank * (hsize_t) UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_CH_NROWS * count[0]); - offset[1] = 0; - offset[2] = 0; - - if (VERBOSE_MED) - printf("Process %d is writing with count[ %llu, %llu, %llu ], stride[ %llu, %llu, %llu ], offset[ %llu, %llu, %llu ], block size[ %llu, %llu, %llu ]\n", - mpi_rank, count[0], count[1], count[2], stride[0], stride[1], stride[2], offset[0], offset[1], offset[2], block[0], block[1], block[2]); + start[0] = ((hsize_t) mpi_rank * (hsize_t) WRITE_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_CH_NROWS * count[0]); + start[1] = 0; + start[2] = 0; + + if (VERBOSE_MED) { + printf("Process %d is writing with count[ %llu, %llu, %llu ], stride[ %llu, %llu, %llu ], start[ %llu, %llu, %llu ], block size[ %llu, %llu, %llu ]\n", + mpi_rank, count[0], count[1], count[2], stride[0], stride[1], stride[2], start[0], start[1], start[2], block[0], block[1], block[2]); + fflush(stdout); + } /* Select hyperslab in the file */ filespace = H5Dget_space(dset_id); VRFY((filespace >= 0), "File dataspace retrieval succeeded"); - VRFY((H5Sselect_hyperslab(filespace, H5S_SELECT_SET, offset, stride, count, block) >= 0), "Hyperslab selection succeeded"); + VRFY((H5Sselect_hyperslab(filespace, H5S_SELECT_SET, start, stride, count, block) >= 0), + "Hyperslab selection succeeded"); /* Fill data buffer */ data_size = sel_dims[0] * sel_dims[1] * sel_dims[2] * sizeof(*data); correct_buf_size = dataset_dims[0] * dataset_dims[1] * dataset_dims[2] * sizeof(*correct_buf); - data = (C_DATATYPE *) calloc(1, data_size); - VRFY((NULL != data), "calloc succeeded"); + data = (C_DATATYPE *) HDcalloc(1, data_size); + VRFY((NULL != data), "HDcalloc succeeded"); - correct_buf = (C_DATATYPE *) calloc(1, correct_buf_size); - VRFY((NULL != correct_buf), "calloc succeeded"); + correct_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != correct_buf), "HDcalloc succeeded"); for (i = 0; i < data_size / sizeof(*data); i++) data[i] = (C_DATATYPE) GEN_DATA(i); for (i = 0; i < correct_buf_size / sizeof(*correct_buf); i++) - correct_buf[i] = (C_DATATYPE) ((i % (dataset_dims[0] * dataset_dims[1])) + (i / (dataset_dims[0] * dataset_dims[1]))); + correct_buf[i] = (C_DATATYPE) ( + (i % (dataset_dims[0] * dataset_dims[1])) + + (i / (dataset_dims[0] * dataset_dims[1])) + ); /* Create property list for collective dataset write */ plist_id = H5Pcreate(H5P_DATASET_XFER); VRFY((plist_id >= 0), "DXPL creation succeeded"); - VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), "Set DXPL MPIO succeeded"); + VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), + "Set DXPL MPIO succeeded"); - VRFY((H5Dwrite(dset_id, HDF5_DATATYPE_NAME, memspace, filespace, plist_id, data) >= 0), "Dataset write succeeded"); + VRFY((H5Dwrite(dset_id, HDF5_DATATYPE_NAME, memspace, filespace, plist_id, data) >= 0), + "Dataset write succeeded"); - if (data) free(data); + if (data) HDfree(data); VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); /* Verify the correct data was written */ - read_buf = (C_DATATYPE *) calloc(1, correct_buf_size); - VRFY((NULL != read_buf), "calloc succeeded"); + read_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != read_buf), "HDcalloc succeeded"); - dset_id = H5Dopen2(file_id, "/" UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_NAME, H5P_DEFAULT); + dset_id = H5Dopen2(file_id, "/" WRITE_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_NAME, H5P_DEFAULT); VRFY((dset_id >= 0), "Dataset open succeeded"); - VRFY((H5Dread(dset_id, HDF5_DATATYPE_NAME, H5S_ALL, H5S_ALL, plist_id, read_buf) >= 0), "Dataset read succeeded"); + VRFY((H5Dread(dset_id, HDF5_DATATYPE_NAME, H5S_ALL, H5S_ALL, plist_id, read_buf) >= 0), + "Dataset read succeeded"); - VRFY((0 == memcmp(read_buf, correct_buf, correct_buf_size)), "Data verification succeeded"); + VRFY((0 == memcmp(read_buf, correct_buf, correct_buf_size)), + "Data verification succeeded"); - if (correct_buf) free(correct_buf); - if (read_buf) free(read_buf); + if (correct_buf) HDfree(correct_buf); + if (read_buf) HDfree(read_buf); VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); @@ -1393,18 +1563,18 @@ test_3d_filtered_dataset_no_overlap_same_pages(void) * 02/06/2017 */ static void -test_3d_filtered_dataset_overlap(void) +test_write_3d_filtered_dataset_overlap(void) { C_DATATYPE *data = NULL; C_DATATYPE *read_buf = NULL; C_DATATYPE *correct_buf = NULL; - hsize_t dataset_dims[SHARED_FILTERED_CHUNKS_3D_DATASET_DIMS]; - hsize_t chunk_dims[SHARED_FILTERED_CHUNKS_3D_DATASET_DIMS]; - hsize_t sel_dims[SHARED_FILTERED_CHUNKS_3D_DATASET_DIMS]; - hsize_t count[SHARED_FILTERED_CHUNKS_3D_DATASET_DIMS]; - hsize_t stride[SHARED_FILTERED_CHUNKS_3D_DATASET_DIMS]; - hsize_t block[SHARED_FILTERED_CHUNKS_3D_DATASET_DIMS]; - hsize_t offset[SHARED_FILTERED_CHUNKS_3D_DATASET_DIMS]; + hsize_t dataset_dims[WRITE_SHARED_FILTERED_CHUNKS_3D_DATASET_DIMS]; + hsize_t chunk_dims[WRITE_SHARED_FILTERED_CHUNKS_3D_DATASET_DIMS]; + hsize_t sel_dims[WRITE_SHARED_FILTERED_CHUNKS_3D_DATASET_DIMS]; + hsize_t start[WRITE_SHARED_FILTERED_CHUNKS_3D_DATASET_DIMS]; + hsize_t stride[WRITE_SHARED_FILTERED_CHUNKS_3D_DATASET_DIMS]; + hsize_t count[WRITE_SHARED_FILTERED_CHUNKS_3D_DATASET_DIMS]; + hsize_t block[WRITE_SHARED_FILTERED_CHUNKS_3D_DATASET_DIMS]; size_t i, data_size, correct_buf_size; hid_t file_id = -1, dset_id = -1, plist_id = -1; hid_t filespace = -1, memspace = -1; @@ -1415,9 +1585,11 @@ test_3d_filtered_dataset_overlap(void) plist_id = H5Pcreate(H5P_FILE_ACCESS); VRFY((plist_id >= 0), "FAPL creation succeeded"); - VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), "Set FAPL MPIO succeeded"); + VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), + "Set FAPL MPIO succeeded"); - VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), "Set libver bounds succeeded"); + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); file_id = H5Fopen(filenames[0], H5F_ACC_RDWR, plist_id); VRFY((file_id >= 0), "Test file open succeeded"); @@ -1425,32 +1597,33 @@ test_3d_filtered_dataset_overlap(void) VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); /* Create the dataspace for the dataset */ - dataset_dims[0] = (hsize_t) SHARED_FILTERED_CHUNKS_3D_NROWS; - dataset_dims[1] = (hsize_t) SHARED_FILTERED_CHUNKS_3D_NCOLS; - dataset_dims[2] = (hsize_t) SHARED_FILTERED_CHUNKS_3D_DEPTH; - chunk_dims[0] = (hsize_t) SHARED_FILTERED_CHUNKS_3D_CH_NROWS; - chunk_dims[1] = (hsize_t) SHARED_FILTERED_CHUNKS_3D_CH_NCOLS; + dataset_dims[0] = (hsize_t) WRITE_SHARED_FILTERED_CHUNKS_3D_NROWS; + dataset_dims[1] = (hsize_t) WRITE_SHARED_FILTERED_CHUNKS_3D_NCOLS; + dataset_dims[2] = (hsize_t) WRITE_SHARED_FILTERED_CHUNKS_3D_DEPTH; + chunk_dims[0] = (hsize_t) WRITE_SHARED_FILTERED_CHUNKS_3D_CH_NROWS; + chunk_dims[1] = (hsize_t) WRITE_SHARED_FILTERED_CHUNKS_3D_CH_NCOLS; chunk_dims[2] = 1; - sel_dims[0] = (hsize_t) (SHARED_FILTERED_CHUNKS_3D_NROWS / mpi_size); - sel_dims[1] = (hsize_t) SHARED_FILTERED_CHUNKS_3D_NCOLS; - sel_dims[2] = (hsize_t) SHARED_FILTERED_CHUNKS_3D_DEPTH; + sel_dims[0] = (hsize_t) (WRITE_SHARED_FILTERED_CHUNKS_3D_NROWS / mpi_size); + sel_dims[1] = (hsize_t) WRITE_SHARED_FILTERED_CHUNKS_3D_NCOLS; + sel_dims[2] = (hsize_t) WRITE_SHARED_FILTERED_CHUNKS_3D_DEPTH; - filespace = H5Screate_simple(SHARED_FILTERED_CHUNKS_3D_DATASET_DIMS, dataset_dims, NULL); + filespace = H5Screate_simple(WRITE_SHARED_FILTERED_CHUNKS_3D_DATASET_DIMS, dataset_dims, NULL); VRFY((filespace >= 0), "File dataspace creation succeeded"); - memspace = H5Screate_simple(SHARED_FILTERED_CHUNKS_3D_DATASET_DIMS, sel_dims, NULL); + memspace = H5Screate_simple(WRITE_SHARED_FILTERED_CHUNKS_3D_DATASET_DIMS, sel_dims, NULL); VRFY((memspace >= 0), "Memory dataspace creation succeeded"); /* Create chunked dataset */ plist_id = H5Pcreate(H5P_DATASET_CREATE); VRFY((plist_id >= 0), "DCPL creation succeeded"); - VRFY((H5Pset_chunk(plist_id, SHARED_FILTERED_CHUNKS_3D_DATASET_DIMS, chunk_dims) >= 0), "Chunk size set"); + VRFY((H5Pset_chunk(plist_id, WRITE_SHARED_FILTERED_CHUNKS_3D_DATASET_DIMS, chunk_dims) >= 0), + "Chunk size set"); /* Add test filter to the pipeline */ - VRFY((SET_FILTER(plist_id) >= 0), "Filter set"); + VRFY((set_dcpl_filter(plist_id) >= 0), "Filter set"); - dset_id = H5Dcreate2(file_id, SHARED_FILTERED_CHUNKS_3D_DATASET_NAME, HDF5_DATATYPE_NAME, filespace, + dset_id = H5Dcreate2(file_id, WRITE_SHARED_FILTERED_CHUNKS_3D_DATASET_NAME, HDF5_DATATYPE_NAME, filespace, H5P_DEFAULT, plist_id, H5P_DEFAULT); VRFY((dset_id >= 0), "Dataset creation succeeded"); @@ -1460,77 +1633,89 @@ test_3d_filtered_dataset_overlap(void) /* Each process defines the dataset selection in memory and writes * it to the hyperslab in the file */ - count[0] = (hsize_t) (SHARED_FILTERED_CHUNKS_3D_NROWS / SHARED_FILTERED_CHUNKS_3D_CH_NROWS); - count[1] = (hsize_t) (SHARED_FILTERED_CHUNKS_3D_NCOLS / SHARED_FILTERED_CHUNKS_3D_CH_NCOLS); - count[2] = (hsize_t) SHARED_FILTERED_CHUNKS_3D_DEPTH; - stride[0] = (hsize_t) SHARED_FILTERED_CHUNKS_3D_CH_NROWS; - stride[1] = (hsize_t) SHARED_FILTERED_CHUNKS_3D_CH_NCOLS; + count[0] = (hsize_t) (WRITE_SHARED_FILTERED_CHUNKS_3D_NROWS / WRITE_SHARED_FILTERED_CHUNKS_3D_CH_NROWS); + count[1] = (hsize_t) (WRITE_SHARED_FILTERED_CHUNKS_3D_NCOLS / WRITE_SHARED_FILTERED_CHUNKS_3D_CH_NCOLS); + count[2] = (hsize_t) WRITE_SHARED_FILTERED_CHUNKS_3D_DEPTH; + stride[0] = (hsize_t) WRITE_SHARED_FILTERED_CHUNKS_3D_CH_NROWS; + stride[1] = (hsize_t) WRITE_SHARED_FILTERED_CHUNKS_3D_CH_NCOLS; stride[2] = 1; block[0] = 1; - block[1] = (hsize_t) SHARED_FILTERED_CHUNKS_3D_CH_NCOLS; + block[1] = (hsize_t) WRITE_SHARED_FILTERED_CHUNKS_3D_CH_NCOLS; block[2] = 1; - offset[0] = (hsize_t) mpi_rank; - offset[1] = 0; - offset[2] = 0; - - if (VERBOSE_MED) - printf("Process %d is writing with count[ %llu, %llu, %llu ], stride[ %llu, %llu, %llu ], offset[ %llu, %llu, %llu ], block size[ %llu, %llu, %llu ]\n", - mpi_rank, count[0], count[1], count[2], stride[0], stride[1], stride[2], offset[0], offset[1], offset[2], block[0], block[1], block[2]); + start[0] = (hsize_t) mpi_rank; + start[1] = 0; + start[2] = 0; + + if (VERBOSE_MED) { + printf("Process %d is writing with count[ %llu, %llu, %llu ], stride[ %llu, %llu, %llu ], start[ %llu, %llu, %llu ], block size[ %llu, %llu, %llu ]\n", + mpi_rank, count[0], count[1], count[2], stride[0], stride[1], stride[2], start[0], start[1], start[2], block[0], block[1], block[2]); + fflush(stdout); + } /* Select hyperslab in the file */ filespace = H5Dget_space(dset_id); VRFY((filespace >= 0), "File dataspace retrieval succeeded"); - VRFY((H5Sselect_hyperslab(filespace, H5S_SELECT_SET, offset, stride, count, block) >= 0), "Hyperslab selection succeeded"); + VRFY((H5Sselect_hyperslab(filespace, H5S_SELECT_SET, start, stride, + count, block) >= 0), "Hyperslab selection succeeded"); /* Fill data buffer */ data_size = sel_dims[0] * sel_dims[1] * sel_dims[2] * sizeof(*data); correct_buf_size = dataset_dims[0] * dataset_dims[1] * dataset_dims[2] * sizeof(*correct_buf); - data = (C_DATATYPE *) calloc(1, data_size); - VRFY((NULL != data), "calloc succeeded"); + data = (C_DATATYPE *) HDcalloc(1, data_size); + VRFY((NULL != data), "HDcalloc succeeded"); - correct_buf = (C_DATATYPE *) calloc(1, correct_buf_size); - VRFY((NULL != correct_buf), "calloc succeeded"); + correct_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != correct_buf), "HDcalloc succeeded"); for (i = 0; i < data_size / sizeof(*data); i++) data[i] = (C_DATATYPE) GEN_DATA(i); for (i = 0; i < correct_buf_size / sizeof(*correct_buf); i++) - /* Add the Column Index */ - correct_buf[i] = (C_DATATYPE) ( (i % (hsize_t) (SHARED_FILTERED_CHUNKS_3D_DEPTH * SHARED_FILTERED_CHUNKS_3D_NCOLS)) + /* Add the Column Index */ + correct_buf[i] = + (C_DATATYPE) ( + (i % (hsize_t) (WRITE_SHARED_FILTERED_CHUNKS_3D_DEPTH * WRITE_SHARED_FILTERED_CHUNKS_3D_NCOLS)) - /* Add the Row Index */ - + ((i % (hsize_t) (mpi_size * SHARED_FILTERED_CHUNKS_3D_DEPTH * SHARED_FILTERED_CHUNKS_3D_NCOLS)) / (hsize_t) (SHARED_FILTERED_CHUNKS_3D_DEPTH * SHARED_FILTERED_CHUNKS_3D_NCOLS)) + /* Add the Row Index */ + + ((i % (hsize_t) (mpi_size * WRITE_SHARED_FILTERED_CHUNKS_3D_DEPTH * WRITE_SHARED_FILTERED_CHUNKS_3D_NCOLS)) + / (hsize_t) (WRITE_SHARED_FILTERED_CHUNKS_3D_DEPTH * WRITE_SHARED_FILTERED_CHUNKS_3D_NCOLS)) - /* Add the amount that gets added when a rank moves down to its next section vertically in the dataset */ - + ((hsize_t) (SHARED_FILTERED_CHUNKS_3D_DEPTH * SHARED_FILTERED_CHUNKS_3D_NCOLS) * (i / (hsize_t) (mpi_size * SHARED_FILTERED_CHUNKS_3D_DEPTH * SHARED_FILTERED_CHUNKS_3D_NCOLS)))); + /* Add the amount that gets added when a rank moves down to its next section vertically in the dataset */ + + ((hsize_t) (WRITE_SHARED_FILTERED_CHUNKS_3D_DEPTH * WRITE_SHARED_FILTERED_CHUNKS_3D_NCOLS) + * (i / (hsize_t) (mpi_size * WRITE_SHARED_FILTERED_CHUNKS_3D_DEPTH * WRITE_SHARED_FILTERED_CHUNKS_3D_NCOLS))) + ); /* Create property list for collective dataset write */ plist_id = H5Pcreate(H5P_DATASET_XFER); VRFY((plist_id >= 0), "DXPL creation succeeded"); - VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), "Set DXPL MPIO succeeded"); + VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), + "Set DXPL MPIO succeeded"); - VRFY((H5Dwrite(dset_id, HDF5_DATATYPE_NAME, memspace, filespace, plist_id, data) >= 0), "Dataset write succeeded"); + VRFY((H5Dwrite(dset_id, HDF5_DATATYPE_NAME, memspace, filespace, plist_id, data) >= 0), + "Dataset write succeeded"); - if (data) free(data); + if (data) HDfree(data); VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); /* Verify the correct data was written */ - read_buf = (C_DATATYPE *) calloc(1, correct_buf_size); - VRFY((NULL != read_buf), "calloc succeeded"); + read_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != read_buf), "HDcalloc succeeded"); - dset_id = H5Dopen2(file_id, "/" SHARED_FILTERED_CHUNKS_3D_DATASET_NAME, H5P_DEFAULT); + dset_id = H5Dopen2(file_id, "/" WRITE_SHARED_FILTERED_CHUNKS_3D_DATASET_NAME, H5P_DEFAULT); VRFY((dset_id >= 0), "Dataset open succeeded"); - VRFY((H5Dread(dset_id, HDF5_DATATYPE_NAME, H5S_ALL, H5S_ALL, plist_id, read_buf) >= 0), "Dataset read succeeded"); + VRFY((H5Dread(dset_id, HDF5_DATATYPE_NAME, H5S_ALL, H5S_ALL, plist_id, read_buf) >= 0), + "Dataset read succeeded"); - VRFY((0 == memcmp(read_buf, correct_buf, correct_buf_size)), "Data verification succeeded"); + VRFY((0 == memcmp(read_buf, correct_buf, correct_buf_size)), + "Data verification succeeded"); - if (correct_buf) free(correct_buf); - if (read_buf) free(read_buf); + if (correct_buf) HDfree(correct_buf); + if (read_buf) HDfree(read_buf); VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); @@ -1549,21 +1734,22 @@ test_3d_filtered_dataset_overlap(void) * Programmer: Jordan Henderson * 02/10/2017 */ -/* JTH: This test currently cannot be data-verified due to the floating-point data involved */ static void -test_cmpd_filtered_dataset_no_conversion_unshared(void) +test_write_cmpd_filtered_dataset_no_conversion_unshared(void) { - cmpd_filtered_t *data = NULL; - hsize_t dataset_dims[COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_DIMS]; - hsize_t chunk_dims[COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_DIMS]; - hsize_t sel_dims[COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_DIMS]; - hsize_t count[COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_DIMS]; - hsize_t stride[COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_DIMS]; - hsize_t block[COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_DIMS]; - hsize_t offset[COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_DIMS]; - size_t i; - hid_t file_id = -1, dset_id = -1, plist_id = -1, memtype = -1; - hid_t filespace = -1, memspace = -1; + COMPOUND_C_DATATYPE *data = NULL; + COMPOUND_C_DATATYPE *read_buf = NULL; + COMPOUND_C_DATATYPE *correct_buf = NULL; + hsize_t dataset_dims[WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_DIMS]; + hsize_t chunk_dims[WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_DIMS]; + hsize_t sel_dims[WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_DIMS]; + hsize_t start[WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_DIMS]; + hsize_t stride[WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_DIMS]; + hsize_t count[WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_DIMS]; + hsize_t block[WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_DIMS]; + size_t i, correct_buf_size; + hid_t file_id = -1, dset_id = -1, plist_id = -1, memtype = -1; + hid_t filespace = -1, memspace = -1; if (MAINPROCESS) puts("Testing write to unshared filtered chunks in Compound Datatype dataset without Datatype conversion"); @@ -1571,9 +1757,11 @@ test_cmpd_filtered_dataset_no_conversion_unshared(void) plist_id = H5Pcreate(H5P_FILE_ACCESS); VRFY((plist_id >= 0), "FAPL creation succeeded"); - VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), "Set FAPL MPIO succeeded"); + VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), + "Set FAPL MPIO succeeded"); - VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), "Set libver bounds succeeded"); + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); file_id = H5Fopen(filenames[0], H5F_ACC_RDWR, plist_id); VRFY((file_id >= 0), "Test file open succeeded"); @@ -1581,38 +1769,41 @@ test_cmpd_filtered_dataset_no_conversion_unshared(void) VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); /* Create the dataspace for the dataset */ - dataset_dims[0] = COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_NROWS; - dataset_dims[1] = (hsize_t) COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_NCOLS; - chunk_dims[0] = COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_CH_NROWS; - chunk_dims[1] = COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_CH_NCOLS; - sel_dims[0] = COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_CH_NROWS; - sel_dims[1] = (hsize_t) COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_ENTRIES_PER_PROC; - - filespace = H5Screate_simple(COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_DIMS, dataset_dims, NULL); + dataset_dims[0] = WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_NROWS; + dataset_dims[1] = (hsize_t) WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_NCOLS; + chunk_dims[0] = WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_CH_NROWS; + chunk_dims[1] = WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_CH_NCOLS; + sel_dims[0] = WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_CH_NROWS; + sel_dims[1] = (hsize_t) WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_ENTRIES_PER_PROC; + + filespace = H5Screate_simple(WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_DIMS, dataset_dims, NULL); VRFY((filespace >= 0), "File dataspace creation succeeded"); - memspace = H5Screate_simple(COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_DIMS, sel_dims, NULL); + memspace = H5Screate_simple(WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_DIMS, sel_dims, NULL); VRFY((memspace >= 0), "Memory dataspace creation succeeded"); /* Create chunked dataset */ plist_id = H5Pcreate(H5P_DATASET_CREATE); VRFY((plist_id >= 0), "DCPL creation succeeded"); - VRFY((H5Pset_chunk(plist_id, COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_DIMS, chunk_dims) >= 0), "Chunk size set"); + VRFY((H5Pset_chunk(plist_id, WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_DIMS, chunk_dims) >= 0), + "Chunk size set"); /* Add test filter to the pipeline */ - VRFY((SET_FILTER(plist_id) >= 0), "Filter set"); + VRFY((set_dcpl_filter(plist_id) >= 0), "Filter set"); /* Create the compound type for memory. */ - memtype = H5Tcreate(H5T_COMPOUND, sizeof(cmpd_filtered_t)); + memtype = H5Tcreate(H5T_COMPOUND, sizeof(COMPOUND_C_DATATYPE)); VRFY((memtype >= 0), "Datatype creation succeeded"); - VRFY((H5Tinsert(memtype, "ShortData", HOFFSET(cmpd_filtered_t, field1), H5T_NATIVE_SHORT) >= 0), "Datatype insertion succeeded"); - VRFY((H5Tinsert(memtype, "IntData", HOFFSET(cmpd_filtered_t, field2), H5T_NATIVE_INT) >= 0), "Datatype insertion succeeded"); - VRFY((H5Tinsert(memtype, "LongData", HOFFSET(cmpd_filtered_t, field3), H5T_NATIVE_LONG) >= 0), "Datatype insertion succeeded"); - VRFY((H5Tinsert(memtype, "DoubleData", HOFFSET(cmpd_filtered_t, field4), H5T_NATIVE_DOUBLE) >= 0), "Datatype insertion succeeded"); + VRFY((H5Tinsert(memtype, "ShortData", HOFFSET(COMPOUND_C_DATATYPE, field1), H5T_NATIVE_SHORT) >= 0), + "Datatype insertion succeeded"); + VRFY((H5Tinsert(memtype, "IntData", HOFFSET(COMPOUND_C_DATATYPE, field2), H5T_NATIVE_INT) >= 0), + "Datatype insertion succeeded"); + VRFY((H5Tinsert(memtype, "LongData", HOFFSET(COMPOUND_C_DATATYPE, field3), H5T_NATIVE_LONG) >= 0), + "Datatype insertion succeeded"); - dset_id = H5Dcreate2(file_id, COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_NAME, memtype, filespace, + dset_id = H5Dcreate2(file_id, WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_NAME, memtype, filespace, H5P_DEFAULT, plist_id, H5P_DEFAULT); VRFY((dset_id >= 0), "Dataset creation succeeded"); @@ -1623,45 +1814,88 @@ test_cmpd_filtered_dataset_no_conversion_unshared(void) * it to the hyperslab in the file */ count[0] = 1; - count[1] = (hsize_t) COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_ENTRIES_PER_PROC; - stride[0] = COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_CH_NROWS; - stride[1] = COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_CH_NCOLS; - block[0] = COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_CH_NROWS; - block[1] = COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_CH_NCOLS; - offset[0] = 0; - offset[1] = ((hsize_t) mpi_rank * COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_CH_NCOLS); - - if (VERBOSE_MED) - printf("Process %d is writing with count[ %llu, %llu ], stride[ %llu, %llu ], offset[ %llu, %llu ], block size[ %llu, %llu ]\n", - mpi_rank, count[0], count[1], stride[0], stride[1], offset[0], offset[1], block[0], block[1]); + count[1] = (hsize_t) WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_ENTRIES_PER_PROC; + stride[0] = WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_CH_NROWS; + stride[1] = WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_CH_NCOLS; + block[0] = WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_CH_NROWS; + block[1] = WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_CH_NCOLS; + start[0] = 0; + start[1] = ((hsize_t) mpi_rank * WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_CH_NCOLS); + + if (VERBOSE_MED) { + printf("Process %d is writing with count[ %llu, %llu ], stride[ %llu, %llu ], start[ %llu, %llu ], block size[ %llu, %llu ]\n", + mpi_rank, count[0], count[1], stride[0], stride[1], start[0], start[1], block[0], block[1]); + fflush(stdout); + } /* Select hyperslab in the file */ filespace = H5Dget_space(dset_id); VRFY((filespace >= 0), "File dataspace retrieval succeeded"); - VRFY((H5Sselect_hyperslab(filespace, H5S_SELECT_SET, offset, stride, count, block) >= 0), "Hyperslab selection succeeded"); + VRFY((H5Sselect_hyperslab(filespace, H5S_SELECT_SET, start, stride, count, block) >= 0), + "Hyperslab selection succeeded"); + + data = (COMPOUND_C_DATATYPE *) HDcalloc(1, (hsize_t) WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_ENTRIES_PER_PROC * sizeof(*data)); + VRFY((NULL != data), "HDcalloc succeeded"); + + correct_buf_size = dataset_dims[0] * dataset_dims[1] * sizeof(COMPOUND_C_DATATYPE); - data = (COMPOUND_C_DATATYPE *) calloc(1, (hsize_t) COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_ENTRIES_PER_PROC * sizeof(*data)); - VRFY((NULL != data), "calloc succeeded"); + correct_buf = (COMPOUND_C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != correct_buf), "HDcalloc succeeded"); /* Fill data buffer */ - memset(data, 0, sizeof(cmpd_filtered_t) * (size_t) COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_ENTRIES_PER_PROC); - for (i = 0; i < (hsize_t) COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_ENTRIES_PER_PROC; i++) { + for (i = 0; i < (hsize_t) WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_ENTRIES_PER_PROC; i++) { data[i].field1 = (short) GEN_DATA(i); data[i].field2 = (int) GEN_DATA(i); data[i].field3 = (long) GEN_DATA(i); - data[i].field4 = (double) GEN_DATA(i); + } + + for (i = 0; i < correct_buf_size / sizeof(*correct_buf); i++) { + correct_buf[i].field1 = (short) ( + (i % dataset_dims[1]) + + (i / dataset_dims[1]) + ); + + correct_buf[i].field2 = (int) ( + (i % dataset_dims[1]) + + (i / dataset_dims[1]) + ); + + correct_buf[i].field3 = (long) ( + (i % dataset_dims[1]) + + (i / dataset_dims[1]) + ); } /* Create property list for collective dataset write */ plist_id = H5Pcreate(H5P_DATASET_XFER); VRFY((plist_id >= 0), "DXPL creation succeeded"); - VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), "Set DXPL MPIO succeeded"); + VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), + "Set DXPL MPIO succeeded"); - VRFY((H5Dwrite(dset_id, memtype, memspace, filespace, plist_id, data) >= 0), "Dataset write succeeded"); + VRFY((H5Dwrite(dset_id, memtype, memspace, filespace, plist_id, data) >= 0), + "Dataset write succeeded"); - if (data) free(data); + if (data) HDfree(data); + + VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); + + /* Verify the correct data was written */ + read_buf = (COMPOUND_C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != read_buf), "HDcalloc succeeded"); + + dset_id = H5Dopen2(file_id, "/" WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_NAME, H5P_DEFAULT); + VRFY((dset_id >= 0), "Dataset open succeeded"); + + VRFY((H5Dread(dset_id, memtype, H5S_ALL, H5S_ALL, plist_id, read_buf) >= 0), + "Dataset read succeeded"); + + VRFY((0 == memcmp(read_buf, correct_buf, correct_buf_size)), + "Data verification succeeded"); + + if (correct_buf) HDfree(correct_buf); + if (read_buf) HDfree(read_buf); VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); @@ -1681,31 +1915,34 @@ test_cmpd_filtered_dataset_no_conversion_unshared(void) * Programmer: Jordan Henderson * 02/10/2017 */ -/* JTH: This test currently cannot be data-verified due to the floating-point data involved */ static void -test_cmpd_filtered_dataset_no_conversion_shared(void) +test_write_cmpd_filtered_dataset_no_conversion_shared(void) { - cmpd_filtered_t *data = NULL; - hsize_t dataset_dims[COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_DIMS]; - hsize_t chunk_dims[COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_DIMS]; - hsize_t sel_dims[COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_DIMS]; - hsize_t count[COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_DIMS]; - hsize_t stride[COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_DIMS]; - hsize_t block[COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_DIMS]; - hsize_t offset[COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_DIMS]; - size_t i; - hid_t file_id, dset_id, plist_id, memtype; - hid_t filespace, memspace; + COMPOUND_C_DATATYPE *data = NULL; + COMPOUND_C_DATATYPE *read_buf = NULL; + COMPOUND_C_DATATYPE *correct_buf = NULL; + hsize_t dataset_dims[WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_DIMS]; + hsize_t chunk_dims[WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_DIMS]; + hsize_t sel_dims[WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_DIMS]; + hsize_t start[WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_DIMS]; + hsize_t stride[WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_DIMS]; + hsize_t count[WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_DIMS]; + hsize_t block[WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_DIMS]; + size_t i, correct_buf_size; + hid_t file_id, dset_id, plist_id, memtype; + hid_t filespace, memspace; if (MAINPROCESS) puts("Testing write to shared filtered chunks in Compound Datatype dataset without Datatype conversion"); /* Set up file access property list with parallel I/O access */ plist_id = H5Pcreate(H5P_FILE_ACCESS); - VRFY((plist_id>= 0), "FAPL creation succeeded"); + VRFY((plist_id >= 0), "FAPL creation succeeded"); - VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), "Set FAPL MPIO succeeded"); + VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), + "Set FAPL MPIO succeeded"); - VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), "Set libver bounds succeeded"); + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); file_id = H5Fopen(filenames[0], H5F_ACC_RDWR, plist_id); VRFY((file_id >= 0), "Test file open succeeded"); @@ -1713,38 +1950,41 @@ test_cmpd_filtered_dataset_no_conversion_shared(void) VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); /* Create the dataspace for the dataset */ - dataset_dims[0] = (hsize_t) COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_NROWS; - dataset_dims[1] = (hsize_t) COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_NCOLS; - chunk_dims[0] = (hsize_t) COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_CH_NROWS; - chunk_dims[1] = COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_CH_NCOLS; - sel_dims[0] = (hsize_t) COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_CH_NROWS / (hsize_t) mpi_size; - sel_dims[1] = (hsize_t) COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_ENTRIES_PER_PROC; - - filespace = H5Screate_simple(COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_DIMS, dataset_dims, NULL); + dataset_dims[0] = (hsize_t) WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_NROWS; + dataset_dims[1] = (hsize_t) WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_NCOLS; + chunk_dims[0] = (hsize_t) WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_CH_NROWS; + chunk_dims[1] = WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_CH_NCOLS; + sel_dims[0] = (hsize_t) WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_CH_NROWS / (hsize_t) mpi_size; + sel_dims[1] = (hsize_t) WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_ENTRIES_PER_PROC; + + filespace = H5Screate_simple(WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_DIMS, dataset_dims, NULL); VRFY((filespace >= 0), "File dataspace creation succeeded"); - memspace = H5Screate_simple(COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_DIMS, sel_dims, NULL); + memspace = H5Screate_simple(WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_DIMS, sel_dims, NULL); VRFY((memspace >= 0), "Memory dataspace creation succeeded"); /* Create chunked dataset */ plist_id = H5Pcreate(H5P_DATASET_CREATE); VRFY((plist_id >= 0), "DCPL creation succeeded"); - VRFY((H5Pset_chunk(plist_id, COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_DIMS, chunk_dims) >= 0), "Chunk size set"); + VRFY((H5Pset_chunk(plist_id, WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_DIMS, chunk_dims) >= 0), + "Chunk size set"); /* Add test filter to the pipeline */ - VRFY((SET_FILTER(plist_id) >= 0), "Filter set"); + VRFY((set_dcpl_filter(plist_id) >= 0), "Filter set"); /* Create the compound type for memory. */ - memtype = H5Tcreate(H5T_COMPOUND, sizeof(cmpd_filtered_t)); + memtype = H5Tcreate(H5T_COMPOUND, sizeof(COMPOUND_C_DATATYPE)); VRFY((memtype >= 0), "Datatype creation succeeded"); - VRFY((H5Tinsert(memtype, "ShortData", HOFFSET(cmpd_filtered_t, field1), H5T_NATIVE_SHORT) >= 0), "Datatype insertion succeeded"); - VRFY((H5Tinsert(memtype, "IntData", HOFFSET(cmpd_filtered_t, field2), H5T_NATIVE_INT) >= 0), "Datatype insertion succeeded"); - VRFY((H5Tinsert(memtype, "LongData", HOFFSET(cmpd_filtered_t, field3), H5T_NATIVE_LONG) >= 0), "Datatype insertion succeeded"); - VRFY((H5Tinsert(memtype, "DoubleData", HOFFSET(cmpd_filtered_t, field4), H5T_NATIVE_DOUBLE) >= 0), "Datatype insertion succeeded"); + VRFY((H5Tinsert(memtype, "ShortData", HOFFSET(COMPOUND_C_DATATYPE, field1), H5T_NATIVE_SHORT) >= 0), + "Datatype insertion succeeded"); + VRFY((H5Tinsert(memtype, "IntData", HOFFSET(COMPOUND_C_DATATYPE, field2), H5T_NATIVE_INT) >= 0), + "Datatype insertion succeeded"); + VRFY((H5Tinsert(memtype, "LongData", HOFFSET(COMPOUND_C_DATATYPE, field3), H5T_NATIVE_LONG) >= 0), + "Datatype insertion succeeded"); - dset_id = H5Dcreate2(file_id, COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_NAME, memtype, filespace, + dset_id = H5Dcreate2(file_id, WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_NAME, memtype, filespace, H5P_DEFAULT, plist_id, H5P_DEFAULT); VRFY((dset_id >= 0), "Dataset creation succeeded"); @@ -1755,45 +1995,91 @@ test_cmpd_filtered_dataset_no_conversion_shared(void) * it to the hyperslab in the file */ count[0] = 1; - count[1] = (hsize_t) COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_ENTRIES_PER_PROC; - stride[0] = (hsize_t) COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_CH_NROWS; - stride[1] = COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_CH_NCOLS; - block[0] = (hsize_t) COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_CH_NROWS / (hsize_t) mpi_size; - block[1] = COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_CH_NCOLS; - offset[0] = (hsize_t) mpi_rank; - offset[1] = 0; - - if (VERBOSE_MED) - printf("Process %d is writing with count[ %llu, %llu ], stride[ %llu, %llu ], offset[ %llu, %llu ], block size[ %llu, %llu ]\n", - mpi_rank, count[0], count[1], stride[0], stride[1], offset[0], offset[1], block[0], block[1]); + count[1] = (hsize_t) WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_ENTRIES_PER_PROC; + stride[0] = (hsize_t) WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_CH_NROWS; + stride[1] = WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_CH_NCOLS; + block[0] = (hsize_t) WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_CH_NROWS / (hsize_t) mpi_size; + block[1] = WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_CH_NCOLS; + start[0] = (hsize_t) mpi_rank; + start[1] = 0; + + if (VERBOSE_MED) { + printf("Process %d is writing with count[ %llu, %llu ], stride[ %llu, %llu ], start[ %llu, %llu ], block size[ %llu, %llu ]\n", + mpi_rank, count[0], count[1], stride[0], stride[1], start[0], start[1], block[0], block[1]); + fflush(stdout); + } /* Select hyperslab in the file */ filespace = H5Dget_space(dset_id); VRFY((filespace >= 0), "File dataspace retrieval succeeded"); - VRFY((H5Sselect_hyperslab(filespace, H5S_SELECT_SET, offset, stride, count, block) >= 0), "Hyperslab selection succeeded"); + VRFY((H5Sselect_hyperslab(filespace, H5S_SELECT_SET, start, stride, count, block) >= 0), + "Hyperslab selection succeeded"); + + data = (COMPOUND_C_DATATYPE *) HDcalloc(1, (hsize_t) WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_ENTRIES_PER_PROC * sizeof(*data)); + VRFY((NULL != data), "HDcalloc succeeded"); + + correct_buf_size = dataset_dims[0] * dataset_dims[1] * sizeof(COMPOUND_C_DATATYPE); - data = (COMPOUND_C_DATATYPE *) calloc(1, (hsize_t) COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_ENTRIES_PER_PROC * sizeof(*data)); - VRFY((NULL != data), "calloc succeeded"); + correct_buf = (COMPOUND_C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != correct_buf), "HDcalloc succeeded"); /* Fill data buffer */ - memset(data, 0, sizeof(cmpd_filtered_t) * (size_t) COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_ENTRIES_PER_PROC); - for (i = 0; i < (hsize_t) COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_ENTRIES_PER_PROC; i++) { + for (i = 0; i < (hsize_t) WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_ENTRIES_PER_PROC; i++) { data[i].field1 = (short) GEN_DATA(i); data[i].field2 = (int) GEN_DATA(i); data[i].field3 = (long) GEN_DATA(i); - data[i].field4 = (double) GEN_DATA(i); + } + + for (i = 0; i < correct_buf_size / sizeof(*correct_buf); i++) { + correct_buf[i].field1 = (short) ( + (dataset_dims[1] * (i / ((hsize_t) mpi_size * dataset_dims[1]))) + + (i % dataset_dims[1]) + + (((i % ((hsize_t) mpi_size * dataset_dims[1])) / dataset_dims[1]) % dataset_dims[1]) + ); + + correct_buf[i].field2 = (int) ( + (dataset_dims[1] * (i / ((hsize_t) mpi_size * dataset_dims[1]))) + + (i % dataset_dims[1]) + + (((i % ((hsize_t) mpi_size * dataset_dims[1])) / dataset_dims[1]) % dataset_dims[1]) + ); + + correct_buf[i].field3 = (long) ( + (dataset_dims[1] * (i / ((hsize_t) mpi_size * dataset_dims[1]))) + + (i % dataset_dims[1]) + + (((i % ((hsize_t) mpi_size * dataset_dims[1])) / dataset_dims[1]) % dataset_dims[1]) + ); } /* Create property list for collective dataset write */ plist_id = H5Pcreate(H5P_DATASET_XFER); VRFY((plist_id >= 0), "DXPL creation succeeded"); - VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), "Set DXPL MPIO succeeded"); + VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), + "Set DXPL MPIO succeeded"); + + VRFY((H5Dwrite(dset_id, memtype, memspace, filespace, plist_id, data) >= 0), + "Dataset write succeeded"); + + if (data) HDfree(data); + + VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); + + /* Verify the correct data was written */ + read_buf = (COMPOUND_C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != read_buf), "HDcalloc succeeded"); + + dset_id = H5Dopen2(file_id, "/" WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_NAME, H5P_DEFAULT); + VRFY((dset_id >= 0), "Dataset open succeeded"); + + VRFY((H5Dread(dset_id, memtype, H5S_ALL, H5S_ALL, plist_id, read_buf) >= 0), + "Dataset read succeeded"); - VRFY((H5Dwrite(dset_id, memtype, memspace, filespace, plist_id, data) >= 0), "Dataset write succeeded"); + VRFY((0 == memcmp(read_buf, correct_buf, correct_buf_size)), + "Data verification succeeded"); - if (data) free(data); + if (correct_buf) HDfree(correct_buf); + if (read_buf) HDfree(read_buf); VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); @@ -1810,29 +2096,30 @@ test_cmpd_filtered_dataset_no_conversion_shared(void) * chunks using a compound datatype which requires a * datatype conversion. * - * This test currently should fail because the datatype - * conversion causes the parallel library to break - * to independent I/O and this isn't allowed when + * NOTE: This test currently should fail because the + * datatype conversion causes the parallel library to + * break to independent I/O and this isn't allowed when * there are filters in the pipeline. * * Programmer: Jordan Henderson * 02/07/2017 */ -/* JTH: This test currently cannot be data-verified due to the floating-point data involved */ static void -test_cmpd_filtered_dataset_type_conversion_unshared(void) +test_write_cmpd_filtered_dataset_type_conversion_unshared(void) { - cmpd_filtered_t *data = NULL; - hsize_t dataset_dims[COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_DIMS]; - hsize_t chunk_dims[COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_DIMS]; - hsize_t sel_dims[COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_DIMS]; - hsize_t count[COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_DIMS]; - hsize_t stride[COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_DIMS]; - hsize_t block[COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_DIMS]; - hsize_t offset[COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_DIMS]; - size_t i; - hid_t file_id = -1, dset_id = -1, plist_id = -1, filetype = -1, memtype = -1; - hid_t filespace = -1, memspace = -1; + COMPOUND_C_DATATYPE *data = NULL; + COMPOUND_C_DATATYPE *read_buf = NULL; + COMPOUND_C_DATATYPE *correct_buf = NULL; + hsize_t dataset_dims[WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_DIMS]; + hsize_t chunk_dims[WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_DIMS]; + hsize_t sel_dims[WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_DIMS]; + hsize_t start[WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_DIMS]; + hsize_t stride[WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_DIMS]; + hsize_t count[WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_DIMS]; + hsize_t block[WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_DIMS]; + size_t i, correct_buf_size; + hid_t file_id = -1, dset_id = -1, plist_id = -1, filetype = -1, memtype = -1; + hid_t filespace = -1, memspace = -1; if (MAINPROCESS) puts("Testing write to unshared filtered chunks in Compound Datatype dataset with Datatype conversion"); @@ -1840,9 +2127,11 @@ test_cmpd_filtered_dataset_type_conversion_unshared(void) plist_id = H5Pcreate(H5P_FILE_ACCESS); VRFY((plist_id >= 0), "FAPL creation succeeded"); - VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), "Set FAPL MPIO succeeded"); + VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), + "Set FAPL MPIO succeeded"); - VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), "Set libver bounds succeeded"); + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); file_id = H5Fopen(filenames[0], H5F_ACC_RDWR, plist_id); VRFY((file_id >= 0), "Test file open succeeded"); @@ -1850,48 +2139,53 @@ test_cmpd_filtered_dataset_type_conversion_unshared(void) VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); /* Create the dataspace for the dataset */ - dataset_dims[0] = COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_NROWS; - dataset_dims[1] = (hsize_t) COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_NCOLS; - chunk_dims[0] = COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_CH_NROWS; - chunk_dims[1] = COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_CH_NCOLS; - sel_dims[0] = COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_CH_NROWS; - sel_dims[1] = (hsize_t) COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_ENTRIES_PER_PROC; - - filespace = H5Screate_simple(COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_DIMS, dataset_dims, NULL); + dataset_dims[0] = WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_NROWS; + dataset_dims[1] = (hsize_t) WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_NCOLS; + chunk_dims[0] = WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_CH_NROWS; + chunk_dims[1] = WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_CH_NCOLS; + sel_dims[0] = WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_CH_NROWS; + sel_dims[1] = (hsize_t) WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_ENTRIES_PER_PROC; + + filespace = H5Screate_simple(WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_DIMS, dataset_dims, NULL); VRFY((filespace >= 0), "File dataspace creation succeeded"); - memspace = H5Screate_simple(COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_DIMS, sel_dims, NULL); + memspace = H5Screate_simple(WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_DIMS, sel_dims, NULL); VRFY((memspace >= 0), "Memory dataspace creation succeeded"); /* Create chunked dataset */ plist_id = H5Pcreate(H5P_DATASET_CREATE); VRFY((plist_id >= 0), "DCPL creation succeeded"); - VRFY((H5Pset_chunk(plist_id, COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_DIMS, chunk_dims) >= 0), "Chunk size set"); + VRFY((H5Pset_chunk(plist_id, WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_DIMS, chunk_dims) >= 0), + "Chunk size set"); /* Add test filter to the pipeline */ - VRFY((SET_FILTER(plist_id) >= 0), "Filter set"); + VRFY((set_dcpl_filter(plist_id) >= 0), "Filter set"); /* Create the compound type for memory. */ - memtype = H5Tcreate(H5T_COMPOUND, sizeof(cmpd_filtered_t)); + memtype = H5Tcreate(H5T_COMPOUND, sizeof(COMPOUND_C_DATATYPE)); VRFY((memtype >= 0), "Datatype creation succeeded"); - VRFY((H5Tinsert(memtype, "ShortData", HOFFSET(cmpd_filtered_t, field1), H5T_NATIVE_SHORT) >= 0), "Datatype insertion succeeded"); - VRFY((H5Tinsert(memtype, "IntData", HOFFSET(cmpd_filtered_t, field2), H5T_NATIVE_INT) >= 0), "Datatype insertion succeeded"); - VRFY((H5Tinsert(memtype, "LongData", HOFFSET(cmpd_filtered_t, field3), H5T_NATIVE_LONG) >= 0), "Datatype insertion succeeded"); - VRFY((H5Tinsert(memtype, "DoubleData", HOFFSET(cmpd_filtered_t, field4), H5T_NATIVE_DOUBLE) >= 0), "Datatype insertion succeeded"); + VRFY((H5Tinsert(memtype, "ShortData", HOFFSET(COMPOUND_C_DATATYPE, field1), H5T_NATIVE_SHORT) >= 0), + "Datatype insertion succeeded"); + VRFY((H5Tinsert(memtype, "IntData", HOFFSET(COMPOUND_C_DATATYPE, field2), H5T_NATIVE_INT) >= 0), + "Datatype insertion succeeded"); + VRFY((H5Tinsert(memtype, "LongData", HOFFSET(COMPOUND_C_DATATYPE, field3), H5T_NATIVE_LONG) >= 0), + "Datatype insertion succeeded"); /* Create the compound type for file. */ filetype = H5Tcreate(H5T_COMPOUND, 32); VRFY((filetype >= 0), "Datatype creation succeeded"); - VRFY((H5Tinsert(filetype, "ShortData", 0, H5T_STD_I64BE) >= 0), "Datatype insertion succeeded"); - VRFY((H5Tinsert(filetype, "IntData", 8, H5T_STD_I64BE) >= 0), "Datatype insertion succeeded"); - VRFY((H5Tinsert(filetype, "LongData", 16, H5T_STD_I64BE) >= 0), "Datatype insertion succeeded"); - VRFY((H5Tinsert(filetype, "DoubleData", 24, H5T_IEEE_F64BE) >= 0), "Datatype insertion succeeded"); + VRFY((H5Tinsert(filetype, "ShortData", 0, H5T_STD_I64BE) >= 0), + "Datatype insertion succeeded"); + VRFY((H5Tinsert(filetype, "IntData", 8, H5T_STD_I64BE) >= 0), + "Datatype insertion succeeded"); + VRFY((H5Tinsert(filetype, "LongData", 16, H5T_STD_I64BE) >= 0), + "Datatype insertion succeeded"); - dset_id = H5Dcreate2(file_id, COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_NAME, filetype, filespace, - H5P_DEFAULT, plist_id, H5P_DEFAULT); + dset_id = H5Dcreate2(file_id, WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_NAME, filetype, filespace, + H5P_DEFAULT, plist_id, H5P_DEFAULT); VRFY((dset_id >= 0), "Dataset creation succeeded"); VRFY((H5Pclose(plist_id) >= 0), "DCPL close succeeded"); @@ -1901,48 +2195,74 @@ test_cmpd_filtered_dataset_type_conversion_unshared(void) * it to the hyperslab in the file */ count[0] = 1; - count[1] = (hsize_t) COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_ENTRIES_PER_PROC; - stride[0] = COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_CH_NROWS; - stride[1] = COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_CH_NCOLS; - block[0] = COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_CH_NROWS; - block[1] = COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_CH_NCOLS; - offset[0] = 0; - offset[1] = ((hsize_t) mpi_rank * COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_CH_NCOLS); - - if (VERBOSE_MED) - printf("Process %d is writing with count[ %llu, %llu ], stride[ %llu, %llu ], offset[ %llu, %llu ], block size[ %llu, %llu ]\n", - mpi_rank, count[0], count[1], stride[0], stride[1], offset[0], offset[1], block[0], block[1]); + count[1] = (hsize_t) WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_ENTRIES_PER_PROC; + stride[0] = WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_CH_NROWS; + stride[1] = WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_CH_NCOLS; + block[0] = WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_CH_NROWS; + block[1] = WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_CH_NCOLS; + start[0] = 0; + start[1] = ((hsize_t) mpi_rank * WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_CH_NCOLS); + + if (VERBOSE_MED) { + printf("Process %d is writing with count[ %llu, %llu ], stride[ %llu, %llu ], start[ %llu, %llu ], block size[ %llu, %llu ]\n", + mpi_rank, count[0], count[1], stride[0], stride[1], start[0], start[1], block[0], block[1]); + fflush(stdout); + } /* Select hyperslab in the file */ filespace = H5Dget_space(dset_id); VRFY((filespace >= 0), "File dataspace retrieval succeeded"); - VRFY((H5Sselect_hyperslab(filespace, H5S_SELECT_SET, offset, stride, count, block) >= 0), "Hyperslab selection succeeded"); + VRFY((H5Sselect_hyperslab(filespace, H5S_SELECT_SET, start, stride, count, block) >= 0), + "Hyperslab selection succeeded"); + + data = (COMPOUND_C_DATATYPE *) HDcalloc(1, (hsize_t) WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_ENTRIES_PER_PROC * sizeof(*data)); + VRFY((NULL != data), "HDcalloc succeeded"); + + correct_buf_size = dataset_dims[0] * dataset_dims[1] * sizeof(COMPOUND_C_DATATYPE); - data = (COMPOUND_C_DATATYPE *) calloc(1, (hsize_t) COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_ENTRIES_PER_PROC * sizeof(*data)); - VRFY((NULL != data), "calloc succeeded"); + correct_buf = (COMPOUND_C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != correct_buf), "HDcalloc succeeded"); /* Fill data buffer */ - memset(data, 0, sizeof(cmpd_filtered_t) * (hsize_t) COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_ENTRIES_PER_PROC); - for (i = 0; i < (hsize_t) COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_ENTRIES_PER_PROC; i++) { + for (i = 0; i < (hsize_t) WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_ENTRIES_PER_PROC; i++) { data[i].field1 = (short) GEN_DATA(i); data[i].field2 = (int) GEN_DATA(i); data[i].field3 = (long) GEN_DATA(i); - data[i].field4 = (double) GEN_DATA(i); } /* Create property list for collective dataset write */ plist_id = H5Pcreate(H5P_DATASET_XFER); VRFY((plist_id >= 0), "DXPL creation succeeded"); - VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), "Set DXPL MPIO succeeded"); + VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), + "Set DXPL MPIO succeeded"); /* Ensure that this test currently fails since type conversions break collective mode */ H5E_BEGIN_TRY { - VRFY((H5Dwrite(dset_id, memtype, memspace, filespace, plist_id, data) < 0), "Dataset write succeeded"); + VRFY((H5Dwrite(dset_id, memtype, memspace, filespace, plist_id, data) < 0), + "Dataset write succeeded"); } H5E_END_TRY; - if (data) free(data); + if (data) HDfree(data); + + /* Verify that no data was written */ + VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); + + read_buf = (COMPOUND_C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != read_buf), "HDcalloc succeeded"); + + dset_id = H5Dopen2(file_id, "/" WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_NAME, H5P_DEFAULT); + VRFY((dset_id >= 0), "Dataset open succeeded"); + + VRFY((H5Dread(dset_id, memtype, H5S_ALL, H5S_ALL, plist_id, read_buf) >= 0), + "Dataset read succeeded"); + + VRFY((0 == memcmp(read_buf, correct_buf, correct_buf_size)), + "Data verification succeeded"); + + if (correct_buf) HDfree(correct_buf); + if (read_buf) HDfree(read_buf); VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); @@ -1960,29 +2280,30 @@ test_cmpd_filtered_dataset_type_conversion_unshared(void) * chunks using a compound datatype which requires * a datatype conversion. * - * This test currently should fail because the datatype - * conversion causes the parallel library to break - * to independent I/O and this isn't allowed when + * NOTE: This test currently should fail because the + * datatype conversion causes the parallel library to + * break to independent I/O and this isn't allowed when * there are filters in the pipeline. * * Programmer: Jordan Henderson * 02/10/2017 */ -/* JTH: This test currently cannot be data-verified due to the floating-point data involved */ static void -test_cmpd_filtered_dataset_type_conversion_shared(void) +test_write_cmpd_filtered_dataset_type_conversion_shared(void) { - cmpd_filtered_t *data = NULL; - hsize_t dataset_dims[COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_DIMS]; - hsize_t chunk_dims[COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_DIMS]; - hsize_t sel_dims[COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_DIMS]; - hsize_t count[COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_DIMS]; - hsize_t stride[COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_DIMS]; - hsize_t block[COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_DIMS]; - hsize_t offset[COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_DIMS]; - size_t i; - hid_t file_id, dset_id, plist_id, filetype, memtype; - hid_t filespace, memspace; + COMPOUND_C_DATATYPE *data = NULL; + COMPOUND_C_DATATYPE *read_buf = NULL; + COMPOUND_C_DATATYPE *correct_buf = NULL; + hsize_t dataset_dims[WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_DIMS]; + hsize_t chunk_dims[WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_DIMS]; + hsize_t sel_dims[WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_DIMS]; + hsize_t start[WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_DIMS]; + hsize_t stride[WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_DIMS]; + hsize_t count[WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_DIMS]; + hsize_t block[WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_DIMS]; + size_t i, correct_buf_size; + hid_t file_id, dset_id, plist_id, filetype, memtype; + hid_t filespace, memspace; if (MAINPROCESS) puts("Testing write to shared filtered chunks in Compound Datatype dataset with Datatype conversion"); @@ -1990,9 +2311,11 @@ test_cmpd_filtered_dataset_type_conversion_shared(void) plist_id = H5Pcreate(H5P_FILE_ACCESS); VRFY((plist_id >= 0), "FAPL creation succeeded"); - VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), "Set FAPL MPIO succeeded"); + VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), + "Set FAPL MPIO succeeded"); - VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), "Set libver bounds succeeded"); + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); file_id = H5Fopen(filenames[0], H5F_ACC_RDWR, plist_id); VRFY((file_id >= 0), "Test file open succeeded"); @@ -2000,47 +2323,52 @@ test_cmpd_filtered_dataset_type_conversion_shared(void) VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); /* Create the dataspace for the dataset */ - dataset_dims[0] = (hsize_t) COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_NROWS; - dataset_dims[1] = (hsize_t) COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_NCOLS; - chunk_dims[0] = (hsize_t) COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_CH_NROWS; - chunk_dims[1] = COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_CH_NCOLS; - sel_dims[0] = (hsize_t) COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_CH_NROWS / (hsize_t) mpi_size; - sel_dims[1] = (hsize_t) COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_ENTRIES_PER_PROC; - - filespace = H5Screate_simple(COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_DIMS, dataset_dims, NULL); + dataset_dims[0] = (hsize_t) WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_NROWS; + dataset_dims[1] = (hsize_t) WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_NCOLS; + chunk_dims[0] = (hsize_t) WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_CH_NROWS; + chunk_dims[1] = WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_CH_NCOLS; + sel_dims[0] = (hsize_t) WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_CH_NROWS / (hsize_t) mpi_size; + sel_dims[1] = (hsize_t) WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_ENTRIES_PER_PROC; + + filespace = H5Screate_simple(WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_DIMS, dataset_dims, NULL); VRFY((filespace >= 0), "File dataspace creation succeeded"); - memspace = H5Screate_simple(COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_DIMS, sel_dims, NULL); + memspace = H5Screate_simple(WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_DIMS, sel_dims, NULL); VRFY((memspace >= 0), "Memory dataspace creation succeeded"); /* Create chunked dataset */ plist_id = H5Pcreate(H5P_DATASET_CREATE); VRFY((plist_id >= 0), "DCPL creation succeeded"); - VRFY((H5Pset_chunk(plist_id, COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_DIMS, chunk_dims) >= 0), "Chunk size set"); + VRFY((H5Pset_chunk(plist_id, WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_DIMS, chunk_dims) >= 0), + "Chunk size set"); /* Add test filter to the pipeline */ - VRFY((SET_FILTER(plist_id) >= 0), "Filter set"); + VRFY((set_dcpl_filter(plist_id) >= 0), "Filter set"); /* Create the compound type for memory. */ - memtype = H5Tcreate(H5T_COMPOUND, sizeof(cmpd_filtered_t)); + memtype = H5Tcreate(H5T_COMPOUND, sizeof(COMPOUND_C_DATATYPE)); VRFY((memtype >= 0), "Datatype creation succeeded"); - VRFY((H5Tinsert(memtype, "ShortData", HOFFSET(cmpd_filtered_t, field1), H5T_NATIVE_SHORT) >= 0), "Datatype insertion succeeded"); - VRFY((H5Tinsert(memtype, "IntData", HOFFSET(cmpd_filtered_t, field2), H5T_NATIVE_INT) >= 0), "Datatype insertion succeeded"); - VRFY((H5Tinsert(memtype, "LongData", HOFFSET(cmpd_filtered_t, field3), H5T_NATIVE_LONG) >= 0), "Datatype insertion succeeded"); - VRFY((H5Tinsert(memtype, "DoubleData", HOFFSET(cmpd_filtered_t, field4), H5T_NATIVE_DOUBLE) >= 0), "Datatype insertion succeeded"); + VRFY((H5Tinsert(memtype, "ShortData", HOFFSET(COMPOUND_C_DATATYPE, field1), H5T_NATIVE_SHORT) >= 0), + "Datatype insertion succeeded"); + VRFY((H5Tinsert(memtype, "IntData", HOFFSET(COMPOUND_C_DATATYPE, field2), H5T_NATIVE_INT) >= 0), + "Datatype insertion succeeded"); + VRFY((H5Tinsert(memtype, "LongData", HOFFSET(COMPOUND_C_DATATYPE, field3), H5T_NATIVE_LONG) >= 0), + "Datatype insertion succeeded"); /* Create the compound type for file. */ filetype = H5Tcreate(H5T_COMPOUND, 32); VRFY((filetype >= 0), "Datatype creation succeeded"); - VRFY((H5Tinsert(filetype, "ShortData", 0, H5T_STD_I64BE) >= 0), "Datatype insertion succeeded"); - VRFY((H5Tinsert(filetype, "IntData", 8, H5T_STD_I64BE) >= 0), "Datatype insertion succeeded"); - VRFY((H5Tinsert(filetype, "LongData", 16, H5T_STD_I64BE) >= 0), "Datatype insertion succeeded"); - VRFY((H5Tinsert(filetype, "DoubleData", 24, H5T_IEEE_F64BE) >= 0), "Datatype insertion succeeded"); + VRFY((H5Tinsert(filetype, "ShortData", 0, H5T_STD_I64BE) >= 0), + "Datatype insertion succeeded"); + VRFY((H5Tinsert(filetype, "IntData", 8, H5T_STD_I64BE) >= 0), + "Datatype insertion succeeded"); + VRFY((H5Tinsert(filetype, "LongData", 16, H5T_STD_I64BE) >= 0), + "Datatype insertion succeeded"); - dset_id = H5Dcreate2(file_id, COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_NAME, filetype, filespace, + dset_id = H5Dcreate2(file_id, WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_NAME, filetype, filespace, H5P_DEFAULT, plist_id, H5P_DEFAULT); VRFY((dset_id >= 0), "Dataset creation succeeded"); @@ -2051,48 +2379,74 @@ test_cmpd_filtered_dataset_type_conversion_shared(void) * it to the hyperslab in the file */ count[0] = 1; - count[1] = (hsize_t) COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_ENTRIES_PER_PROC; - stride[0] = (hsize_t) COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_CH_NROWS; - stride[1] = COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_CH_NCOLS; - block[0] = (hsize_t) COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_CH_NROWS / (hsize_t) mpi_size; - block[1] = COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_CH_NCOLS; - offset[0] = (hsize_t) mpi_rank; - offset[1] = 0; - - if (VERBOSE_MED) - printf("Process %d is writing with count[ %llu, %llu ], stride[ %llu, %llu ], offset[ %llu, %llu ], block size[ %llu, %llu ]\n", - mpi_rank, count[0], count[1], stride[0], stride[1], offset[0], offset[1], block[0], block[1]); + count[1] = (hsize_t) WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_ENTRIES_PER_PROC; + stride[0] = (hsize_t) WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_CH_NROWS; + stride[1] = WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_CH_NCOLS; + block[0] = (hsize_t) WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_CH_NROWS / (hsize_t) mpi_size; + block[1] = WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_CH_NCOLS; + start[0] = (hsize_t) mpi_rank; + start[1] = 0; + + if (VERBOSE_MED) { + printf("Process %d is writing with count[ %llu, %llu ], stride[ %llu, %llu ], start[ %llu, %llu ], block size[ %llu, %llu ]\n", + mpi_rank, count[0], count[1], stride[0], stride[1], start[0], start[1], block[0], block[1]); + fflush(stdout); + } /* Select hyperslab in the file */ filespace = H5Dget_space(dset_id); VRFY((filespace >= 0), "File dataspace retrieval succeeded"); - VRFY((H5Sselect_hyperslab(filespace, H5S_SELECT_SET, offset, stride, count, block) >= 0), "Hyperslab selection succeeded"); + VRFY((H5Sselect_hyperslab(filespace, H5S_SELECT_SET, start, stride, count, block) >= 0), + "Hyperslab selection succeeded"); + + data = (COMPOUND_C_DATATYPE *) HDcalloc(1, (hsize_t) WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_ENTRIES_PER_PROC * sizeof(*data)); + VRFY((NULL != data), "HDcalloc succeeded"); - data = (COMPOUND_C_DATATYPE *) calloc(1, (hsize_t) COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_ENTRIES_PER_PROC * sizeof(*data)); - VRFY((NULL != data), "calloc succeeded"); + correct_buf_size = dataset_dims[0] * dataset_dims[1] * sizeof(COMPOUND_C_DATATYPE); + + correct_buf = (COMPOUND_C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != correct_buf), "HDcalloc succeeded"); /* Fill data buffer */ - memset(data, 0, sizeof(cmpd_filtered_t) * (size_t) COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_ENTRIES_PER_PROC); - for (i = 0; i < (hsize_t) COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_ENTRIES_PER_PROC; i++) { + for (i = 0; i < (hsize_t) WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_ENTRIES_PER_PROC; i++) { data[i].field1 = (short) GEN_DATA(i); data[i].field2 = (int) GEN_DATA(i); data[i].field3 = (long) GEN_DATA(i); - data[i].field4 = (double) GEN_DATA(i); } /* Create property list for collective dataset write */ plist_id = H5Pcreate(H5P_DATASET_XFER); VRFY((plist_id >= 0), "DXPL creation succeeded"); - VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), "Set DXPL MPIO succeeded"); + VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), + "Set DXPL MPIO succeeded"); /* Ensure that this test currently fails since type conversions break collective mode */ H5E_BEGIN_TRY { - VRFY((H5Dwrite(dset_id, memtype, memspace, filespace, plist_id, data) < 0), "Dataset write succeeded"); + VRFY((H5Dwrite(dset_id, memtype, memspace, filespace, plist_id, data) < 0), + "Dataset write succeeded"); } H5E_END_TRY; - if (data) free(data); + if (data) HDfree(data); + + /* Verify that no data was written */ + VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); + + read_buf = (COMPOUND_C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != read_buf), "HDcalloc succeeded"); + + dset_id = H5Dopen2(file_id, "/" WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_NAME, H5P_DEFAULT); + VRFY((dset_id >= 0), "Dataset open succeeded"); + + VRFY((H5Dread(dset_id, memtype, H5S_ALL, H5S_ALL, plist_id, read_buf) >= 0), + "Dataset read succeeded"); + + VRFY((0 == memcmp(read_buf, correct_buf, correct_buf_size)), + "Data verification succeeded"); + + if (correct_buf) HDfree(correct_buf); + if (read_buf) HDfree(read_buf); VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); @@ -2106,6 +2460,2940 @@ test_cmpd_filtered_dataset_type_conversion_shared(void) } /* + * Tests parallel read of filtered data in the special + * case where a dataset is composed of a single chunk. + * + * The MAINPROCESS rank will first write out all of the + * data to the dataset. Then, each rank reads a part of + * the singular chunk and contributes its piece to a + * global buffer that is checked for consistency. + * + * Programmer: Jordan Henderson + * 05/14/2018 + */ +static void +test_read_one_chunk_filtered_dataset(void) +{ + C_DATATYPE *read_buf = NULL; + C_DATATYPE *correct_buf = NULL; + C_DATATYPE *global_buf = NULL; + hsize_t dataset_dims[READ_ONE_CHUNK_FILTERED_DATASET_DIMS]; + hsize_t chunk_dims[READ_ONE_CHUNK_FILTERED_DATASET_DIMS]; + hsize_t sel_dims[READ_ONE_CHUNK_FILTERED_DATASET_DIMS]; + hsize_t start[READ_ONE_CHUNK_FILTERED_DATASET_DIMS]; + hsize_t stride[READ_ONE_CHUNK_FILTERED_DATASET_DIMS]; + hsize_t count[READ_ONE_CHUNK_FILTERED_DATASET_DIMS]; + hsize_t block[READ_ONE_CHUNK_FILTERED_DATASET_DIMS]; + hsize_t flat_dims[1]; + size_t i, read_buf_size, correct_buf_size; + hid_t file_id = -1, dset_id = -1, plist_id = -1; + hid_t filespace = -1, memspace = -1; + int *recvcounts = NULL; + int *displs = NULL; + + dataset_dims[0] = (hsize_t) READ_ONE_CHUNK_FILTERED_DATASET_NROWS; + dataset_dims[1] = (hsize_t) READ_ONE_CHUNK_FILTERED_DATASET_NCOLS; + + /* Setup the buffer for writing and for comparison */ + correct_buf_size = dataset_dims[0] * dataset_dims[1] * sizeof(*correct_buf); + + correct_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != correct_buf), "HDcalloc succeeded"); + + for (i = 0; i < correct_buf_size / sizeof(*correct_buf); i++) + correct_buf[i] = ((C_DATATYPE) i % (READ_ONE_CHUNK_FILTERED_DATASET_CH_NROWS / mpi_size * READ_ONE_CHUNK_FILTERED_DATASET_CH_NCOLS)) + + ((C_DATATYPE) i / (READ_ONE_CHUNK_FILTERED_DATASET_CH_NROWS / mpi_size * READ_ONE_CHUNK_FILTERED_DATASET_CH_NCOLS)); + + if (MAINPROCESS) { + puts("Testing read from one-chunk filtered dataset"); + + plist_id = H5Pcreate(H5P_FILE_ACCESS); + VRFY((plist_id >= 0), "FAPL creation succeeded"); + + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); + + file_id = H5Fopen(filenames[0], H5F_ACC_RDWR, plist_id); + VRFY((file_id >= 0), "Test file open succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); + + /* Create the dataspace for the dataset */ + filespace = H5Screate_simple(READ_ONE_CHUNK_FILTERED_DATASET_DIMS, dataset_dims, NULL); + VRFY((filespace >= 0), "File dataspace creation succeeded"); + + /* Create chunked dataset */ + chunk_dims[0] = (hsize_t) READ_ONE_CHUNK_FILTERED_DATASET_CH_NROWS; + chunk_dims[1] = (hsize_t) READ_ONE_CHUNK_FILTERED_DATASET_CH_NCOLS; + + plist_id = H5Pcreate(H5P_DATASET_CREATE); + VRFY((plist_id >= 0), "DCPL creation succeeded"); + + VRFY((H5Pset_chunk(plist_id, READ_ONE_CHUNK_FILTERED_DATASET_DIMS, chunk_dims) >= 0), + "Chunk size set"); + + /* Add test filter to the pipeline */ + VRFY((set_dcpl_filter(plist_id) >= 0), "Filter set"); + + dset_id = H5Dcreate2(file_id, READ_ONE_CHUNK_FILTERED_DATASET_NAME, HDF5_DATATYPE_NAME, filespace, + H5P_DEFAULT, plist_id, H5P_DEFAULT); + VRFY((dset_id >= 0), "Dataset creation succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "DCPL close succeeded"); + VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); + + VRFY((H5Dwrite(dset_id, HDF5_DATATYPE_NAME, H5S_ALL, H5S_ALL, H5P_DEFAULT, correct_buf) >= 0), + "Dataset write succeeded"); + + VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); + VRFY((H5Fclose(file_id) >= 0), "File close succeeded"); + } + + /* Set up file access property list with parallel I/O access */ + plist_id = H5Pcreate(H5P_FILE_ACCESS); + VRFY((plist_id >= 0), "FAPL creation succeeded"); + + VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), + "Set FAPL MPIO succeeded"); + + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); + + file_id = H5Fopen(filenames[0], H5F_ACC_RDONLY, plist_id); + VRFY((file_id >= 0), "Test file open succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); + + dset_id = H5Dopen2(file_id, "/" READ_ONE_CHUNK_FILTERED_DATASET_NAME, H5P_DEFAULT); + VRFY((dset_id >= 0), "Dataset open succeeded"); + + sel_dims[0] = (hsize_t) READ_ONE_CHUNK_FILTERED_DATASET_NROWS / (hsize_t) mpi_size; + sel_dims[1] = (hsize_t) READ_ONE_CHUNK_FILTERED_DATASET_NCOLS; + + /* Setup one-dimensional memory dataspace for reading the dataset data into a contiguous buffer */ + flat_dims[0] = sel_dims[0] * sel_dims[1]; + + memspace = H5Screate_simple(1, flat_dims, NULL); + VRFY((memspace >= 0), "Memory dataspace creation succeeded"); + + /* Select hyperslab in the file */ + filespace = H5Dget_space(dset_id); + VRFY((filespace >= 0), "File dataspace retrieval succeeded"); + + /* + * Each process defines the dataset selection in the file and + * reads it to the selection in memory + */ + count[0] = 1; + count[1] = 1; + stride[0] = (hsize_t) READ_ONE_CHUNK_FILTERED_DATASET_CH_NROWS; + stride[1] = (hsize_t) READ_ONE_CHUNK_FILTERED_DATASET_CH_NCOLS; + block[0] = sel_dims[0]; + block[1] = sel_dims[1]; + start[0] = ((hsize_t) mpi_rank * sel_dims[0]); + start[1] = 0; + + if (VERBOSE_MED) { + printf("Process %d is reading with count[ %llu, %llu ], stride[ %llu, %llu ], start[ %llu, %llu ], block size[ %llu, %llu ]\n", + mpi_rank, count[0], count[1], stride[0], stride[1], start[0], start[1], block[0], block[1]); + fflush(stdout); + } + + VRFY((H5Sselect_hyperslab(filespace, H5S_SELECT_SET, start, stride, count, block) >= 0), + "Hyperslab selection succeeded"); + + /* Create property list for collective dataset read */ + plist_id = H5Pcreate(H5P_DATASET_XFER); + VRFY((plist_id >= 0), "DXPL creation succeeded"); + + VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), + "Set DXPL MPIO succeeded"); + + read_buf_size = flat_dims[0] * sizeof(*read_buf); + + read_buf = (C_DATATYPE *) HDcalloc(1, read_buf_size); + VRFY((NULL != read_buf), "HDcalloc succeeded"); + + VRFY((H5Dread(dset_id, HDF5_DATATYPE_NAME, memspace, filespace, plist_id, read_buf) >= 0), + "Dataset read succeeded"); + + global_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != global_buf), "HDcalloc succeeded"); + + /* Collect each piece of data from all ranks into a global buffer on all ranks */ + recvcounts = (int *) HDcalloc(1, (size_t) mpi_size * sizeof(*recvcounts)); + VRFY((NULL != recvcounts), "HDcalloc succeeded"); + + for (i = 0; i < (size_t) mpi_size; i++) + recvcounts[i] = (int) flat_dims[0]; + + displs = (int *) HDcalloc(1, (size_t) mpi_size * sizeof(*displs)); + VRFY((NULL != displs), "HDcalloc succeeded"); + + for (i = 0; i < (size_t) mpi_size; i++) + displs[i] = (int) (i * flat_dims[0]); + + VRFY((MPI_SUCCESS == MPI_Allgatherv(read_buf, (int) flat_dims[0], C_DATATYPE_MPI, global_buf, recvcounts, displs, C_DATATYPE_MPI, comm)), + "MPI_Allgatherv succeeded"); + + VRFY((0 == memcmp(global_buf, correct_buf, correct_buf_size)), + "Data verification succeeded"); + + if (displs) HDfree(displs); + if (recvcounts) HDfree(recvcounts); + if (global_buf) HDfree(global_buf); + if (read_buf) HDfree(read_buf); + if (correct_buf) HDfree(correct_buf); + + VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); + VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); + VRFY((H5Sclose(memspace) >= 0), "Memory dataspace close succeeded"); + VRFY((H5Pclose(plist_id) >= 0), "DXPL close succeeded"); + VRFY((H5Fclose(file_id) >= 0), "File close succeeded"); + + return; +} + +/* + * Tests parallel read of filtered data in the case where only + * one process is reading from a particular chunk in the operation. + * + * The MAINPROCESS rank will first write out all of the + * data to the dataset. Then, each rank reads a part of + * the dataset and contributes its piece to a global buffer + * that is checked for consistency. + * + * Programmer: Jordan Henderson + * 05/15/2018 + */ +static void +test_read_filtered_dataset_no_overlap(void) +{ + C_DATATYPE *read_buf = NULL; + C_DATATYPE *correct_buf = NULL; + C_DATATYPE *global_buf = NULL; + hsize_t dataset_dims[READ_UNSHARED_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t chunk_dims[READ_UNSHARED_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t sel_dims[READ_UNSHARED_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t start[READ_UNSHARED_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t stride[READ_UNSHARED_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t count[READ_UNSHARED_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t block[READ_UNSHARED_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t flat_dims[1]; + size_t i, read_buf_size, correct_buf_size; + hid_t file_id = -1, dset_id = -1, plist_id = -1; + hid_t filespace = -1, memspace = -1; + int *recvcounts = NULL; + int *displs = NULL; + + dataset_dims[0] = (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_NROWS; + dataset_dims[1] = (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_NCOLS; + + /* Setup the buffer for writing and for comparison */ + correct_buf_size = (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_NROWS * (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_NCOLS * sizeof(*correct_buf); + + correct_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != correct_buf), "HDcalloc succeeded"); + + for (i = 0; i < correct_buf_size / sizeof(*correct_buf); i++) + correct_buf[i] = (C_DATATYPE) ( + (i % (dataset_dims[0] / (hsize_t) mpi_size * dataset_dims[1])) + + (i / (dataset_dims[0] / (hsize_t) mpi_size * dataset_dims[1])) + ); + + if (MAINPROCESS) { + puts("Testing read from unshared filtered chunks"); + + plist_id = H5Pcreate(H5P_FILE_ACCESS); + VRFY((plist_id >= 0), "FAPL creation succeeded"); + + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); + + file_id = H5Fopen(filenames[0], H5F_ACC_RDWR, plist_id); + VRFY((file_id >= 0), "Test file open succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); + + /* Create the dataspace for the dataset */ + filespace = H5Screate_simple(READ_UNSHARED_FILTERED_CHUNKS_DATASET_DIMS, dataset_dims, NULL); + VRFY((filespace >= 0), "File dataspace creation succeeded"); + + /* Create chunked dataset */ + chunk_dims[0] = (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_CH_NROWS; + chunk_dims[1] = (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_CH_NCOLS; + + plist_id = H5Pcreate(H5P_DATASET_CREATE); + VRFY((plist_id >= 0), "DCPL creation succeeded"); + + VRFY((H5Pset_chunk(plist_id, READ_UNSHARED_FILTERED_CHUNKS_DATASET_DIMS, chunk_dims) >= 0), + "Chunk size set"); + + /* Add test filter to the pipeline */ + VRFY((set_dcpl_filter(plist_id) >= 0), "Filter set"); + + dset_id = H5Dcreate2(file_id, READ_UNSHARED_FILTERED_CHUNKS_DATASET_NAME, HDF5_DATATYPE_NAME, filespace, + H5P_DEFAULT, plist_id, H5P_DEFAULT); + VRFY((dset_id >= 0), "Dataset creation succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "DCPL close succeeded"); + VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); + + VRFY((H5Dwrite(dset_id, HDF5_DATATYPE_NAME, H5S_ALL, H5S_ALL, H5P_DEFAULT, correct_buf) >= 0), + "Dataset write succeeded"); + + VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); + VRFY((H5Fclose(file_id) >= 0), "File close succeeded"); + } + + /* Set up file access property list with parallel I/O access */ + plist_id = H5Pcreate(H5P_FILE_ACCESS); + VRFY((plist_id >= 0), "FAPL creation succeeded"); + + VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), + "Set FAPL MPIO succeeded"); + + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); + + file_id = H5Fopen(filenames[0], H5F_ACC_RDONLY, plist_id); + VRFY((file_id >= 0), "Test file open succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); + + dset_id = H5Dopen2(file_id, "/" READ_UNSHARED_FILTERED_CHUNKS_DATASET_NAME, H5P_DEFAULT); + VRFY((dset_id >= 0), "Dataset open succeeded"); + + sel_dims[0] = (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_CH_NROWS; + sel_dims[1] = (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_NCOLS; + + /* Setup one-dimensional memory dataspace for reading the dataset data into a contiguous buffer */ + flat_dims[0] = sel_dims[0] * sel_dims[1]; + + memspace = H5Screate_simple(1, flat_dims, NULL); + VRFY((memspace >= 0), "Memory dataspace creation succeeded"); + + /* Select hyperslab in the file */ + filespace = H5Dget_space(dset_id); + VRFY((filespace >= 0), "File dataspace retrieval succeeded"); + + /* + * Each process defines the dataset selection in the file and reads + * it to the selection in memory + */ + count[0] = 1; + count[1] = (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_NCOLS / (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_CH_NCOLS; + stride[0] = (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_CH_NROWS; + stride[1] = (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_CH_NCOLS; + block[0] = (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_CH_NROWS; + block[1] = (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_CH_NCOLS; + start[0] = ((hsize_t) mpi_rank * (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_CH_NROWS * count[0]); + start[1] = 0; + + if (VERBOSE_MED) { + printf("Process %d is reading with count[ %llu, %llu ], stride[ %llu, %llu ], start[ %llu, %llu ], block size[ %llu, %llu ]\n", + mpi_rank, count[0], count[1], stride[0], stride[1], start[0], start[1], block[0], block[1]); + fflush(stdout); + } + + VRFY((H5Sselect_hyperslab(filespace, H5S_SELECT_SET, start, stride, count, block) >= 0), + "Hyperslab selection succeeded"); + + /* Create property list for collective dataset read */ + plist_id = H5Pcreate(H5P_DATASET_XFER); + VRFY((plist_id >= 0), "DXPL creation succeeded"); + + VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), + "Set DXPL MPIO succeeded"); + + read_buf_size = flat_dims[0] * sizeof(*read_buf); + + read_buf = (C_DATATYPE *) HDcalloc(1, read_buf_size); + VRFY((NULL != read_buf), "HDcalloc succeeded"); + + VRFY((H5Dread(dset_id, HDF5_DATATYPE_NAME, memspace, filespace, plist_id, read_buf) >= 0), + "Dataset read succeeded"); + + global_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != global_buf), "HDcalloc succeeded"); + + /* Collect each piece of data from all ranks into a global buffer on all ranks */ + recvcounts = (int *) HDcalloc(1, (size_t) mpi_size * sizeof(*recvcounts)); + VRFY((NULL != recvcounts), "HDcalloc succeeded"); + + for (i = 0; i < (size_t) mpi_size; i++) + recvcounts[i] = (int) flat_dims[0]; + + displs = (int *) HDcalloc(1, (size_t) mpi_size * sizeof(*displs)); + VRFY((NULL != displs), "HDcalloc succeeded"); + + for (i = 0; i < (size_t) mpi_size; i++) + displs[i] = (int) (i * flat_dims[0]); + + VRFY((MPI_SUCCESS == MPI_Allgatherv(read_buf, (int) flat_dims[0], C_DATATYPE_MPI, global_buf, recvcounts, displs, C_DATATYPE_MPI, comm)), + "MPI_Allgatherv succeeded"); + + VRFY((0 == memcmp(global_buf, correct_buf, correct_buf_size)), + "Data verification succeeded"); + + if (displs) HDfree(displs); + if (recvcounts) HDfree(recvcounts); + if (global_buf) HDfree(global_buf); + if (read_buf) HDfree(read_buf); + if (correct_buf) HDfree(correct_buf); + + VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); + VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); + VRFY((H5Sclose(memspace) >= 0), "Memory dataspace close succeeded"); + VRFY((H5Pclose(plist_id) >= 0), "DXPL close succeeded"); + VRFY((H5Fclose(file_id) >= 0), "File close succeeded"); + + return; +} + +/* + * Tests parallel read of filtered data in the case where + * more than one process is reading from a particular chunk + * in the operation. + * + * The MAINPROCESS rank will first write out all of the + * data to the dataset. Then, each rank reads a part of + * each chunk of the dataset and contributes its pieces + * to a global buffer that is checked for consistency. + * + * Programmer: Jordan Henderson + * 05/15/2018 + */ +static void +test_read_filtered_dataset_overlap(void) +{ + C_DATATYPE *read_buf = NULL; + C_DATATYPE *correct_buf = NULL; + C_DATATYPE *global_buf = NULL; + hsize_t dataset_dims[READ_SHARED_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t chunk_dims[READ_SHARED_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t sel_dims[READ_SHARED_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t start[READ_SHARED_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t stride[READ_SHARED_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t count[READ_SHARED_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t block[READ_SHARED_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t flat_dims[1]; + size_t i, read_buf_size, correct_buf_size; + hid_t file_id = -1, dset_id = -1, plist_id = -1; + hid_t filespace = -1, memspace = -1; + int *recvcounts = NULL; + int *displs = NULL; + + dataset_dims[0] = (hsize_t) READ_SHARED_FILTERED_CHUNKS_NROWS; + dataset_dims[1] = (hsize_t) READ_SHARED_FILTERED_CHUNKS_NCOLS; + + /* Setup the buffer for writing and for comparison */ + correct_buf_size = dataset_dims[0] * dataset_dims[1] * sizeof(*correct_buf); + + correct_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != correct_buf), "HDcalloc succeeded"); + + for (i = 0; i < correct_buf_size / sizeof(*correct_buf); i++) + correct_buf[i] = (C_DATATYPE) ( + (dataset_dims[1] * (i / ((hsize_t) mpi_size * dataset_dims[1]))) + + (i % dataset_dims[1]) + + (((i % ((hsize_t) mpi_size * dataset_dims[1])) / dataset_dims[1]) % dataset_dims[1]) + ); + + if (MAINPROCESS) { + puts("Testing read from shared filtered chunks"); + + plist_id = H5Pcreate(H5P_FILE_ACCESS); + VRFY((plist_id >= 0), "FAPL creation succeeded"); + + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); + + file_id = H5Fopen(filenames[0], H5F_ACC_RDWR, plist_id); + VRFY((file_id >= 0), "Test file open succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); + + /* Create the dataspace for the dataset */ + filespace = H5Screate_simple(READ_SHARED_FILTERED_CHUNKS_DATASET_DIMS, dataset_dims, NULL); + VRFY((filespace >= 0), "File dataspace creation succeeded"); + + /* Create chunked dataset */ + chunk_dims[0] = (hsize_t) READ_SHARED_FILTERED_CHUNKS_CH_NROWS; + chunk_dims[1] = (hsize_t) READ_SHARED_FILTERED_CHUNKS_CH_NCOLS; + + plist_id = H5Pcreate(H5P_DATASET_CREATE); + VRFY((plist_id >= 0), "DCPL creation succeeded"); + + VRFY((H5Pset_chunk(plist_id, READ_SHARED_FILTERED_CHUNKS_DATASET_DIMS, chunk_dims) >= 0), + "Chunk size set"); + + /* Add test filter to the pipeline */ + VRFY((set_dcpl_filter(plist_id) >= 0), "Filter set"); + + dset_id = H5Dcreate2(file_id, READ_SHARED_FILTERED_CHUNKS_DATASET_NAME, HDF5_DATATYPE_NAME, filespace, + H5P_DEFAULT, plist_id, H5P_DEFAULT); + VRFY((dset_id >= 0), "Dataset creation succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "DCPL close succeeded"); + VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); + + VRFY((H5Dwrite(dset_id, HDF5_DATATYPE_NAME, H5S_ALL, H5S_ALL, H5P_DEFAULT, correct_buf) >= 0), + "Dataset write succeeded"); + + VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); + VRFY((H5Fclose(file_id) >= 0), "File close succeeded"); + } + + /* Set up file access property list with parallel I/O access */ + plist_id = H5Pcreate(H5P_FILE_ACCESS); + VRFY((plist_id >= 0), "FAPL creation succeeded"); + + VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), + "Set FAPL MPIO succeeded"); + + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); + + file_id = H5Fopen(filenames[0], H5F_ACC_RDONLY, plist_id); + VRFY((file_id >= 0), "Test file open succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); + + dset_id = H5Dopen2(file_id, "/" READ_SHARED_FILTERED_CHUNKS_DATASET_NAME, H5P_DEFAULT); + VRFY((dset_id >= 0), "Dataset open succeeded"); + + sel_dims[0] = (hsize_t) DIM0_SCALE_FACTOR; + sel_dims[1] = (hsize_t) READ_SHARED_FILTERED_CHUNKS_CH_NCOLS * (hsize_t) DIM1_SCALE_FACTOR; + + /* Setup one-dimensional memory dataspace for reading the dataset data into a contiguous buffer */ + flat_dims[0] = sel_dims[0] * sel_dims[1]; + + memspace = H5Screate_simple(1, flat_dims, NULL); + VRFY((memspace >= 0), "Memory dataspace creation succeeded"); + + /* Select hyperslab in the file */ + filespace = H5Dget_space(dset_id); + VRFY((filespace >= 0), "File dataspace retrieval succeeded"); + + /* + * Each process defines the dataset selection in the file and + * reads it to the selection in memory + */ + count[0] = (hsize_t) READ_SHARED_FILTERED_CHUNKS_NROWS / (hsize_t) READ_SHARED_FILTERED_CHUNKS_CH_NROWS; + count[1] = (hsize_t) READ_SHARED_FILTERED_CHUNKS_NCOLS / (hsize_t) READ_SHARED_FILTERED_CHUNKS_CH_NCOLS; + stride[0] = (hsize_t) READ_SHARED_FILTERED_CHUNKS_CH_NROWS; + stride[1] = (hsize_t) READ_SHARED_FILTERED_CHUNKS_CH_NCOLS; + block[0] = (hsize_t) READ_SHARED_FILTERED_CHUNKS_CH_NROWS / (hsize_t) mpi_size; + block[1] = (hsize_t) READ_SHARED_FILTERED_CHUNKS_CH_NCOLS; + start[0] = (hsize_t) mpi_rank * block[0]; + start[1] = 0; + + if (VERBOSE_MED) { + printf("Process %d is reading with count[ %llu, %llu ], stride[ %llu, %llu ], start[ %llu, %llu ], block size[ %llu, %llu ]\n", + mpi_rank, count[0], count[1], stride[0], stride[1], start[0], start[1], block[0], block[1]); + fflush(stdout); + } + + VRFY((H5Sselect_hyperslab(filespace, H5S_SELECT_SET, start, stride, count, block) >= 0), + "Hyperslab selection succeeded"); + + /* Create property list for collective dataset read */ + plist_id = H5Pcreate(H5P_DATASET_XFER); + VRFY((plist_id >= 0), "DXPL creation succeeded"); + + VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), + "Set DXPL MPIO succeeded"); + + read_buf_size = flat_dims[0] * sizeof(*read_buf); + + read_buf = (C_DATATYPE *) HDcalloc(1, read_buf_size); + VRFY((NULL != read_buf), "HDcalloc succeeded"); + + VRFY((H5Dread(dset_id, HDF5_DATATYPE_NAME, memspace, filespace, plist_id, read_buf) >= 0), + "Dataset read succeeded"); + + global_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != global_buf), "HDcalloc succeeded"); + + /* + * Since these chunks are shared, run multiple rounds of MPI_Allgatherv + * to collect all of the pieces into their appropriate locations. The + * number of times MPI_Allgatherv is run should be equal to the number + * of chunks in the first dimension of the dataset. + */ + { + size_t loop_count = count[0]; + size_t total_recvcounts = 0; + + recvcounts = (int *) HDcalloc(1, (size_t) mpi_size * sizeof(*recvcounts)); + VRFY((NULL != recvcounts), "HDcalloc succeeded"); + + displs = (int *) HDcalloc(1, (size_t) mpi_size * sizeof(*displs)); + VRFY((NULL != displs), "HDcalloc succeeded"); + + for (i = 0; i < (size_t) mpi_size; i++) { + recvcounts[i] = (int) dataset_dims[1]; + total_recvcounts += (size_t) recvcounts[i]; + } + + for (i = 0; i < (size_t) mpi_size; i++) + displs[i] = (int) (i * dataset_dims[1]); + + for (; loop_count; loop_count--) { + VRFY((MPI_SUCCESS == MPI_Allgatherv(&read_buf[(count[0] - loop_count) * dataset_dims[1]], recvcounts[mpi_rank], C_DATATYPE_MPI, + &global_buf[(count[0] - loop_count) * total_recvcounts], recvcounts, displs, C_DATATYPE_MPI, comm)), + "MPI_Allgatherv succeeded"); + } + } + + VRFY((0 == memcmp(global_buf, correct_buf, correct_buf_size)), + "Data verification succeeded"); + + if (displs) HDfree(displs); + if (recvcounts) HDfree(recvcounts); + if (global_buf) HDfree(global_buf); + if (read_buf) HDfree(read_buf); + if (correct_buf) HDfree(correct_buf); + + VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); + VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); + VRFY((H5Sclose(memspace) >= 0), "Memory dataspace close succeeded"); + VRFY((H5Pclose(plist_id) >= 0), "DXPL close succeeded"); + VRFY((H5Fclose(file_id) >= 0), "File close succeeded"); + + return; +} + +/* + * Tests parallel read of filtered data in the case where + * a single process in the read operation has no selection + * in the dataset's dataspace. + * + * The MAINPROCESS rank will first write out all of the + * data to the dataset. Then, each rank (except for one) + * reads a part of the dataset and contributes its piece + * to a global buffer that is checked for consistency. + * + * Programmer: Jordan Henderson + * 05/15/2018 + */ +static void +test_read_filtered_dataset_single_no_selection(void) +{ + C_DATATYPE *read_buf = NULL; + C_DATATYPE *correct_buf = NULL; + C_DATATYPE *global_buf = NULL; + hsize_t dataset_dims[READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t chunk_dims[READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t sel_dims[READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t start[READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t stride[READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t count[READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t block[READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t flat_dims[1]; + size_t i, read_buf_size, correct_buf_size; + size_t segment_length; + hid_t file_id = -1, dset_id = -1, plist_id = -1; + hid_t filespace = -1, memspace = -1; + int *recvcounts = NULL; + int *displs = NULL; + + dataset_dims[0] = (hsize_t) READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_NROWS; + dataset_dims[1] = (hsize_t) READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_NCOLS; + + /* Setup the buffer for writing and for comparison */ + correct_buf_size = dataset_dims[0] * dataset_dims[1] * sizeof(*correct_buf); + + correct_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != correct_buf), "HDcalloc succeeded"); + + for (i = 0; i < correct_buf_size / sizeof(*correct_buf); i++) + correct_buf[i] = + (C_DATATYPE) ( + (i % (dataset_dims[0] / (hsize_t) mpi_size * dataset_dims[1])) + + (i / (dataset_dims[0] / (hsize_t) mpi_size * dataset_dims[1])) + ); + + /* Compute the correct offset into the buffer for the process having no selection and clear it */ + segment_length = dataset_dims[0] * dataset_dims[1] / (hsize_t) mpi_size; + HDmemset(correct_buf + ((size_t) READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_NO_SELECT_PROC * segment_length), + 0, segment_length * sizeof(*correct_buf)); + + if (MAINPROCESS) { + puts("Testing read from filtered chunks with a single process having no selection"); + + plist_id = H5Pcreate(H5P_FILE_ACCESS); + VRFY((plist_id >= 0), "FAPL creation succeeded"); + + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); + + file_id = H5Fopen(filenames[0], H5F_ACC_RDWR, plist_id); + VRFY((file_id >= 0), "Test file open succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); + + /* Create the dataspace for the dataset */ + filespace = H5Screate_simple(READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS, dataset_dims, NULL); + VRFY((filespace >= 0), "File dataspace creation succeeded"); + + /* Create chunked dataset */ + chunk_dims[0] = (hsize_t) READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NROWS; + chunk_dims[1] = (hsize_t) READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NCOLS; + + plist_id = H5Pcreate(H5P_DATASET_CREATE); + VRFY((plist_id >= 0), "DCPL creation succeeded"); + + VRFY((H5Pset_chunk(plist_id, READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS, chunk_dims) >= 0), + "Chunk size set"); + + /* Add test filter to the pipeline */ + VRFY((set_dcpl_filter(plist_id) >= 0), "Filter set"); + + dset_id = H5Dcreate2(file_id, READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_NAME, HDF5_DATATYPE_NAME, filespace, + H5P_DEFAULT, plist_id, H5P_DEFAULT); + VRFY((dset_id >= 0), "Dataset creation succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "DCPL close succeeded"); + VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); + + VRFY((H5Dwrite(dset_id, HDF5_DATATYPE_NAME, H5S_ALL, H5S_ALL, H5P_DEFAULT, correct_buf) >= 0), + "Dataset write succeeded"); + + VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); + VRFY((H5Fclose(file_id) >= 0), "File close succeeded"); + } + + /* Set up file access property list with parallel I/O access */ + plist_id = H5Pcreate(H5P_FILE_ACCESS); + VRFY((plist_id >= 0), "FAPL creation succeeded"); + + VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), + "Set FAPL MPIO succeeded"); + + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); + + file_id = H5Fopen(filenames[0], H5F_ACC_RDONLY, plist_id); + VRFY((file_id >= 0), "Test file open succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); + + dset_id = H5Dopen2(file_id, "/" READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_NAME, H5P_DEFAULT); + VRFY((dset_id >= 0), "Dataset open succeeded"); + + sel_dims[0] = (hsize_t) READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NROWS; + sel_dims[1] = (hsize_t) READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_NCOLS; + + if (mpi_rank == READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_NO_SELECT_PROC) + sel_dims[0] = sel_dims[1] = 0; + + /* Setup one-dimensional memory dataspace for reading the dataset data into a contiguous buffer */ + flat_dims[0] = sel_dims[0] * sel_dims[1]; + + memspace = H5Screate_simple(1, flat_dims, NULL); + VRFY((memspace >= 0), "Memory dataspace creation succeeded"); + + /* Select hyperslab in the file */ + filespace = H5Dget_space(dset_id); + VRFY((filespace >= 0), "File dataspace retrieval succeeded"); + + /* + * Each process defines the dataset selection in the file and + * reads it to the selection in memory + */ + count[0] = 1; + count[1] = (hsize_t) READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_NCOLS / (hsize_t) READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NCOLS; + stride[0] = (hsize_t) READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NROWS; + stride[1] = (hsize_t) READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NCOLS; + block[0] = (hsize_t) READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NROWS; + block[1] = (hsize_t) READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NCOLS; + start[0] = (hsize_t) mpi_rank * (hsize_t) READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NROWS * count[0]; + start[1] = 0; + + if (VERBOSE_MED) { + printf("Process %d is reading with count[ %llu, %llu ], stride[ %llu, %llu ], start[ %llu, %llu ], block size[ %llu, %llu ]\n", + mpi_rank, count[0], count[1], stride[0], stride[1], start[0], start[1], block[0], block[1]); + fflush(stdout); + } + + if (mpi_rank == READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_NO_SELECT_PROC) + VRFY((H5Sselect_none(filespace) >= 0), "Select none succeeded"); + else + VRFY((H5Sselect_hyperslab(filespace, H5S_SELECT_SET, start, stride, count, block) >= 0), + "Hyperslab selection succeeded"); + + /* Create property list for collective dataset read */ + plist_id = H5Pcreate(H5P_DATASET_XFER); + VRFY((plist_id >= 0), "DXPL creation succeeded"); + + VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), + "Set DXPL MPIO succeeded"); + + read_buf_size = flat_dims[0] * sizeof(*read_buf); + + read_buf = (C_DATATYPE *) HDcalloc(1, read_buf_size); + VRFY((NULL != read_buf), "HDcalloc succeeded"); + + VRFY((H5Dread(dset_id, HDF5_DATATYPE_NAME, memspace, filespace, plist_id, read_buf) >= 0), + "Dataset read succeeded"); + + global_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != global_buf), "HDcalloc succeeded"); + + /* Collect each piece of data from all ranks into a global buffer on all ranks */ + recvcounts = (int *) HDcalloc(1, (size_t) mpi_size * sizeof(*recvcounts)); + VRFY((NULL != recvcounts), "HDcalloc succeeded"); + + for (i = 0; i < (size_t) mpi_size; i++) + recvcounts[i] = (int) (READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NROWS * READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_NCOLS); + recvcounts[READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_NO_SELECT_PROC] = 0; + + displs = (int *) HDcalloc(1, (size_t) mpi_size * sizeof(*displs)); + VRFY((NULL != displs), "HDcalloc succeeded"); + + for (i = 0; i < (size_t) mpi_size; i++) + displs[i] = (int) (i * (size_t) (READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NROWS * READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_NCOLS)); + + if (mpi_rank == READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_NO_SELECT_PROC) + VRFY((MPI_SUCCESS == MPI_Allgatherv(read_buf, 0, C_DATATYPE_MPI, global_buf, recvcounts, displs, C_DATATYPE_MPI, comm)), + "MPI_Allgatherv succeeded"); + else + VRFY((MPI_SUCCESS == MPI_Allgatherv(read_buf, (int) flat_dims[0], C_DATATYPE_MPI, global_buf, recvcounts, displs, C_DATATYPE_MPI, comm)), + "MPI_Allgatherv succeeded"); + + VRFY((0 == memcmp(global_buf, correct_buf, correct_buf_size)), + "Data verification succeeded"); + + if (displs) HDfree(displs); + if (recvcounts) HDfree(recvcounts); + if (global_buf) HDfree(global_buf); + if (read_buf) HDfree(read_buf); + if (correct_buf) HDfree(correct_buf); + + VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); + VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); + VRFY((H5Sclose(memspace) >= 0), "Memory dataspace close succeeded"); + VRFY((H5Pclose(plist_id) >= 0), "DXPL close succeeded"); + VRFY((H5Fclose(file_id) >= 0), "File close succeeded"); + + return; +} + +/* + * Tests parallel read of filtered data in the case where + * no process in the read operation has a selection in the + * dataset's dataspace. This test is to ensure that there + * are no assertion failures or similar issues due to size + * 0 allocations and the like. + * + * The MAINPROCESS rank will first write out all of the + * data to the dataset. Then, each rank will simply issue + * a no-op read. + * + * Programmer: Jordan Henderson + * 05/15/2018 + */ +static void +test_read_filtered_dataset_all_no_selection(void) +{ + C_DATATYPE *read_buf = NULL; + C_DATATYPE *correct_buf = NULL; + hsize_t dataset_dims[READ_ALL_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t chunk_dims[READ_ALL_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t sel_dims[READ_ALL_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS]; + size_t read_buf_size, correct_buf_size; + hid_t file_id = -1, dset_id = -1, plist_id = -1; + hid_t filespace = -1, memspace = -1; + + dataset_dims[0] = (hsize_t) READ_ALL_NO_SELECTION_FILTERED_CHUNKS_NROWS; + dataset_dims[1] = (hsize_t) READ_ALL_NO_SELECTION_FILTERED_CHUNKS_NCOLS; + + /* Setup the buffer for writing and for comparison */ + correct_buf_size = dataset_dims[0] * dataset_dims[1] * sizeof(*correct_buf); + + correct_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != correct_buf), "HDcalloc succeeded"); + + if (MAINPROCESS) { + puts("Testing read from filtered chunks with all processes having no selection"); + + plist_id = H5Pcreate(H5P_FILE_ACCESS); + VRFY((plist_id >= 0), "FAPL creation succeeded"); + + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); + + file_id = H5Fopen(filenames[0], H5F_ACC_RDWR, plist_id); + VRFY((file_id >= 0), "Test file open succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); + + /* Create the dataspace for the dataset */ + filespace = H5Screate_simple(READ_ALL_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS, dataset_dims, NULL); + VRFY((filespace >= 0), "File dataspace creation succeeded"); + + /* Create chunked dataset */ + chunk_dims[0] = (hsize_t) READ_ALL_NO_SELECTION_FILTERED_CHUNKS_CH_NROWS; + chunk_dims[1] = (hsize_t) READ_ALL_NO_SELECTION_FILTERED_CHUNKS_CH_NCOLS; + + plist_id = H5Pcreate(H5P_DATASET_CREATE); + VRFY((plist_id >= 0), "DCPL creation succeeded"); + + VRFY((H5Pset_chunk(plist_id, READ_ALL_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS, chunk_dims) >= 0), + "Chunk size set"); + + /* Add test filter to the pipeline */ + VRFY((set_dcpl_filter(plist_id) >= 0), "Filter set"); + + dset_id = H5Dcreate2(file_id, READ_ALL_NO_SELECTION_FILTERED_CHUNKS_DATASET_NAME, HDF5_DATATYPE_NAME, filespace, + H5P_DEFAULT, plist_id, H5P_DEFAULT); + VRFY((dset_id >= 0), "Dataset creation succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "DCPL close succeeded"); + VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); + + VRFY((H5Dwrite(dset_id, HDF5_DATATYPE_NAME, H5S_ALL, H5S_ALL, H5P_DEFAULT, correct_buf) >= 0), + "Dataset write succeeded"); + + VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); + VRFY((H5Fclose(file_id) >= 0), "File close succeeded"); + } + + /* Set up file access property list with parallel I/O access */ + plist_id = H5Pcreate(H5P_FILE_ACCESS); + VRFY((plist_id >= 0), "FAPL creation succeeded"); + + VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), + "Set FAPL MPIO succeeded"); + + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); + + file_id = H5Fopen(filenames[0], H5F_ACC_RDONLY, plist_id); + VRFY((file_id >= 0), "Test file open succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); + + dset_id = H5Dopen2(file_id, "/" READ_ALL_NO_SELECTION_FILTERED_CHUNKS_DATASET_NAME, H5P_DEFAULT); + VRFY((dset_id >= 0), "Dataset open succeeded"); + + sel_dims[0] = sel_dims[1] = 0; + + memspace = H5Screate_simple(READ_ALL_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS, sel_dims, NULL); + VRFY((memspace >= 0), "Memory dataspace creation succeeded"); + + /* Select hyperslab in the file */ + filespace = H5Dget_space(dset_id); + VRFY((filespace >= 0), "File dataspace retrieval succeeded"); + + VRFY((H5Sselect_none(filespace) >= 0), "Select none succeeded"); + + /* Create property list for collective dataset read */ + plist_id = H5Pcreate(H5P_DATASET_XFER); + VRFY((plist_id >= 0), "DXPL creation succeeded"); + + VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), + "Set DXPL MPIO succeeded"); + + read_buf_size = dataset_dims[0] * dataset_dims[1] * sizeof(*read_buf); + + read_buf = (C_DATATYPE *) HDcalloc(1, read_buf_size); + VRFY((NULL != read_buf), "HDcalloc succeeded"); + + VRFY((H5Dread(dset_id, HDF5_DATATYPE_NAME, memspace, filespace, plist_id, read_buf) >= 0), + "Dataset read succeeded"); + + if (read_buf) HDfree(read_buf); + if (correct_buf) HDfree(correct_buf); + + VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); + VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); + VRFY((H5Sclose(memspace) >= 0), "Memory dataspace close succeeded"); + VRFY((H5Pclose(plist_id) >= 0), "DXPL close succeeded"); + VRFY((H5Fclose(file_id) >= 0), "File close succeeded"); + + return; +} + +/* + * Tests parallel read of filtered data by using point + * selections instead of hyperslab selections. + * + * The MAINPROCESS rank will first write out all of the + * data to the dataset. Then, each rank will read part + * of the dataset using a point selection and will + * contribute its piece to a global buffer that is + * checked for consistency. + * + * Programmer: Jordan Henderson + * 05/15/2018 + */ +static void +test_read_filtered_dataset_point_selection(void) +{ + C_DATATYPE *correct_buf = NULL; + C_DATATYPE *read_buf = NULL; + C_DATATYPE *global_buf = NULL; + hsize_t *coords = NULL; + hsize_t dataset_dims[READ_POINT_SELECTION_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t chunk_dims[READ_POINT_SELECTION_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t sel_dims[READ_POINT_SELECTION_FILTERED_CHUNKS_DATASET_DIMS]; + hsize_t flat_dims[1]; + size_t i, j, read_buf_size, correct_buf_size; + size_t num_points; + hid_t file_id = -1, dset_id = -1, plist_id = -1; + hid_t filespace = -1, memspace = -1; + int *recvcounts = NULL; + int *displs = NULL; + + dataset_dims[0] = (hsize_t) READ_POINT_SELECTION_FILTERED_CHUNKS_NROWS; + dataset_dims[1] = (hsize_t) READ_POINT_SELECTION_FILTERED_CHUNKS_NCOLS; + + /* Setup the buffer for writing and for comparison */ + correct_buf_size = dataset_dims[0] * dataset_dims[1] * sizeof(*correct_buf); + + correct_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != correct_buf), "HDcalloc succeeded"); + + for (i = 0; i < correct_buf_size / sizeof(*correct_buf); i++) + correct_buf[i] = (C_DATATYPE) ( + (dataset_dims[1] * (i / ((hsize_t) mpi_size * dataset_dims[1]))) + + (i % dataset_dims[1]) + + (((i % ((hsize_t) mpi_size * dataset_dims[1])) / dataset_dims[1]) % dataset_dims[1]) + ); + + if (MAINPROCESS) { + puts("Testing read from filtered chunks with point selection"); + + plist_id = H5Pcreate(H5P_FILE_ACCESS); + VRFY((plist_id >= 0), "FAPL creation succeeded"); + + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); + + file_id = H5Fopen(filenames[0], H5F_ACC_RDWR, plist_id); + VRFY((file_id >= 0), "Test file open succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); + + /* Create the dataspace for the dataset */ + filespace = H5Screate_simple(READ_POINT_SELECTION_FILTERED_CHUNKS_DATASET_DIMS, dataset_dims, NULL); + VRFY((filespace >= 0), "File dataspace creation succeeded"); + + /* Create chunked dataset */ + chunk_dims[0] = (hsize_t) READ_POINT_SELECTION_FILTERED_CHUNKS_CH_NROWS; + chunk_dims[1] = (hsize_t) READ_POINT_SELECTION_FILTERED_CHUNKS_CH_NCOLS; + + plist_id = H5Pcreate(H5P_DATASET_CREATE); + VRFY((plist_id >= 0), "DCPL creation succeeded"); + + VRFY((H5Pset_chunk(plist_id, READ_POINT_SELECTION_FILTERED_CHUNKS_DATASET_DIMS, chunk_dims) >= 0), + "Chunk size set"); + + /* Add test filter to the pipeline */ + VRFY((set_dcpl_filter(plist_id) >= 0), "Filter set"); + + dset_id = H5Dcreate2(file_id, READ_POINT_SELECTION_FILTERED_CHUNKS_DATASET_NAME, HDF5_DATATYPE_NAME, filespace, + H5P_DEFAULT, plist_id, H5P_DEFAULT); + VRFY((dset_id >= 0), "Dataset creation succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "DCPL close succeeded"); + VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); + + VRFY((H5Dwrite(dset_id, HDF5_DATATYPE_NAME, H5S_ALL, H5S_ALL, H5P_DEFAULT, correct_buf) >= 0), + "Dataset write succeeded"); + + VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); + VRFY((H5Fclose(file_id) >= 0), "File close succeeded"); + } + + /* Set up file access property list with parallel I/O access */ + plist_id = H5Pcreate(H5P_FILE_ACCESS); + VRFY((plist_id >= 0), "FAPL creation succeeded"); + + VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), + "Set FAPL MPIO succeeded"); + + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); + + file_id = H5Fopen(filenames[0], H5F_ACC_RDONLY, plist_id); + VRFY((file_id >= 0), "Test file open succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); + + dset_id = H5Dopen2(file_id, "/" READ_POINT_SELECTION_FILTERED_CHUNKS_DATASET_NAME, H5P_DEFAULT); + VRFY((dset_id >= 0), "Dataset open succeeded"); + + sel_dims[0] = (hsize_t) READ_POINT_SELECTION_FILTERED_CHUNKS_NROWS / (hsize_t) mpi_size; + sel_dims[1] = (hsize_t) READ_POINT_SELECTION_FILTERED_CHUNKS_NCOLS; + + /* Setup one-dimensional memory dataspace for reading the dataset data into a contiguous buffer */ + flat_dims[0] = sel_dims[0] * sel_dims[1]; + + memspace = H5Screate_simple(1, flat_dims, NULL); + VRFY((memspace >= 0), "Memory dataspace creation succeeded"); + + /* Set up point selection */ + filespace = H5Dget_space(dset_id); + VRFY((filespace >= 0), "File dataspace retrieval succeeded"); + + num_points = (hsize_t) READ_POINT_SELECTION_FILTERED_CHUNKS_NROWS * (hsize_t) READ_POINT_SELECTION_FILTERED_CHUNKS_NCOLS / (hsize_t) mpi_size; + coords = (hsize_t *) HDcalloc(1, 2 * num_points * sizeof(*coords)); + VRFY((NULL != coords), "Coords HDcalloc succeeded"); + + for (i = 0; i < num_points; i++) + for (j = 0; j < READ_POINT_SELECTION_FILTERED_CHUNKS_DATASET_DIMS; j++) + coords[(i * READ_POINT_SELECTION_FILTERED_CHUNKS_DATASET_DIMS) + j] = + (j > 0) ? (i % (hsize_t) READ_POINT_SELECTION_FILTERED_CHUNKS_NCOLS) + : ((hsize_t) mpi_rank + ((hsize_t) mpi_size * (i / (hsize_t) READ_POINT_SELECTION_FILTERED_CHUNKS_NCOLS))); + + VRFY((H5Sselect_elements(filespace, H5S_SELECT_SET, (hsize_t ) num_points, (const hsize_t * ) coords) >= 0), + "Point selection succeeded"); + + /* Create property list for collective dataset read */ + plist_id = H5Pcreate(H5P_DATASET_XFER); + VRFY((plist_id >= 0), "DXPL creation succeeded"); + + VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), + "Set DXPL MPIO succeeded"); + + read_buf_size = flat_dims[0] * sizeof(*read_buf); + + read_buf = (C_DATATYPE *) HDcalloc(1, read_buf_size); + VRFY((NULL != read_buf), "HDcalloc succeeded"); + + VRFY((H5Dread(dset_id, HDF5_DATATYPE_NAME, memspace, filespace, plist_id, read_buf) >= 0), + "Dataset read succeeded"); + + global_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != global_buf), "HDcalloc succeeded"); + + /* + * Since these chunks are shared, run multiple rounds of MPI_Allgatherv + * to collect all of the pieces into their appropriate locations. The + * number of times MPI_Allgatherv is run should be equal to the number + * of chunks in the first dimension of the dataset. + */ + { + size_t original_loop_count = dataset_dims[0] / (hsize_t) mpi_size; + size_t cur_loop_count = original_loop_count; + size_t total_recvcounts = 0; + + recvcounts = (int *) HDcalloc(1, (size_t) mpi_size * sizeof(*recvcounts)); + VRFY((NULL != recvcounts), "HDcalloc succeeded"); + + displs = (int *) HDcalloc(1, (size_t) mpi_size * sizeof(*displs)); + VRFY((NULL != displs), "HDcalloc succeeded"); + + for (i = 0; i < (size_t) mpi_size; i++) { + recvcounts[i] = (int) dataset_dims[1]; + total_recvcounts += (size_t) recvcounts[i]; + } + + for (i = 0; i < (size_t) mpi_size; i++) + displs[i] = (int) (i * dataset_dims[1]); + + for (; cur_loop_count; cur_loop_count--) { + VRFY((MPI_SUCCESS == MPI_Allgatherv(&read_buf[(original_loop_count - cur_loop_count) * dataset_dims[1]], recvcounts[mpi_rank], C_DATATYPE_MPI, + &global_buf[(original_loop_count - cur_loop_count) * total_recvcounts], recvcounts, displs, C_DATATYPE_MPI, comm)), + "MPI_Allgatherv succeeded"); + } + } + + VRFY((0 == memcmp(global_buf, correct_buf, correct_buf_size)), + "Data verification succeeded"); + + if (displs) HDfree(displs); + if (recvcounts) HDfree(recvcounts); + if (global_buf) HDfree(global_buf); + if (read_buf) HDfree(read_buf); + if (correct_buf) HDfree(correct_buf); + + VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); + VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); + VRFY((H5Sclose(memspace) >= 0), "Memory dataspace close succeeded"); + VRFY((H5Pclose(plist_id) >= 0), "DXPL close succeeded"); + VRFY((H5Fclose(file_id) >= 0), "File close succeeded"); + + return; +} + +/* + * Tests parallel read of filtered data in the case where + * each process reads an equal amount of data from each + * chunk in the dataset. Each chunk is distributed among the + * processes in round-robin fashion by blocks of size 1 until + * the whole chunk is selected, leading to an interleaved + * read pattern. + * + * The MAINPROCESS rank will first write out all of the + * data to the dataset. Then, each rank will read part + * of each chunk of the dataset and will contribute its + * pieces to a global buffer that is checked for consistency. + * + * Programmer: Jordan Henderson + * 05/15/2018 + */ +static void +test_read_filtered_dataset_interleaved_read(void) +{ + C_DATATYPE *read_buf = NULL; + C_DATATYPE *correct_buf = NULL; + C_DATATYPE *global_buf = NULL; + hsize_t dataset_dims[INTERLEAVED_READ_FILTERED_DATASET_DIMS]; + hsize_t chunk_dims[INTERLEAVED_READ_FILTERED_DATASET_DIMS]; + hsize_t sel_dims[INTERLEAVED_READ_FILTERED_DATASET_DIMS]; + hsize_t start[INTERLEAVED_READ_FILTERED_DATASET_DIMS]; + hsize_t stride[INTERLEAVED_READ_FILTERED_DATASET_DIMS]; + hsize_t count[INTERLEAVED_READ_FILTERED_DATASET_DIMS]; + hsize_t block[INTERLEAVED_READ_FILTERED_DATASET_DIMS]; + hsize_t flat_dims[1]; + size_t i, read_buf_size, correct_buf_size; + hid_t file_id = -1, dset_id = -1, plist_id = -1; + hid_t filespace = -1, memspace = -1; + int *recvcounts = NULL; + int *displs = NULL; + + dataset_dims[0] = (hsize_t) INTERLEAVED_READ_FILTERED_DATASET_NROWS; + dataset_dims[1] = (hsize_t) INTERLEAVED_READ_FILTERED_DATASET_NCOLS; + + /* Setup the buffer for writing and for comparison */ + correct_buf_size = dataset_dims[0] * dataset_dims[1] * sizeof(*correct_buf); + + correct_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != correct_buf), "HDcalloc succeeded"); + + for (i = 0; i < correct_buf_size / sizeof(*correct_buf); i++) + /* Add Column Index */ + correct_buf[i] = + (C_DATATYPE) ( + (i % (hsize_t) INTERLEAVED_READ_FILTERED_DATASET_NCOLS) + + /* Add the Row Index */ + + ((i % (hsize_t) (mpi_size * INTERLEAVED_READ_FILTERED_DATASET_NCOLS)) / (hsize_t) INTERLEAVED_READ_FILTERED_DATASET_NCOLS) + + /* Add the amount that gets added when a rank moves down to its next section vertically in the dataset */ + + ((hsize_t) INTERLEAVED_READ_FILTERED_DATASET_NCOLS * (i / (hsize_t) (mpi_size * INTERLEAVED_READ_FILTERED_DATASET_NCOLS))) + ); + + if (MAINPROCESS) { + puts("Testing interleaved read from filtered chunks"); + + plist_id = H5Pcreate(H5P_FILE_ACCESS); + VRFY((plist_id >= 0), "FAPL creation succeeded"); + + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); + + file_id = H5Fopen(filenames[0], H5F_ACC_RDWR, plist_id); + VRFY((file_id >= 0), "Test file open succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); + + /* Create the dataspace for the dataset */ + filespace = H5Screate_simple(INTERLEAVED_READ_FILTERED_DATASET_DIMS, dataset_dims, NULL); + VRFY((filespace >= 0), "File dataspace creation succeeded"); + + /* Create chunked dataset */ + chunk_dims[0] = (hsize_t) INTERLEAVED_READ_FILTERED_DATASET_CH_NROWS; + chunk_dims[1] = (hsize_t) INTERLEAVED_READ_FILTERED_DATASET_CH_NCOLS; + + plist_id = H5Pcreate(H5P_DATASET_CREATE); + VRFY((plist_id >= 0), "DCPL creation succeeded"); + + VRFY((H5Pset_chunk(plist_id, INTERLEAVED_READ_FILTERED_DATASET_DIMS, chunk_dims) >= 0), + "Chunk size set"); + + /* Add test filter to the pipeline */ + VRFY((set_dcpl_filter(plist_id) >= 0), "Filter set"); + + dset_id = H5Dcreate2(file_id, INTERLEAVED_READ_FILTERED_DATASET_NAME, HDF5_DATATYPE_NAME, filespace, + H5P_DEFAULT, plist_id, H5P_DEFAULT); + VRFY((dset_id >= 0), "Dataset creation succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "DCPL close succeeded"); + VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); + + VRFY((H5Dwrite(dset_id, HDF5_DATATYPE_NAME, H5S_ALL, H5S_ALL, H5P_DEFAULT, correct_buf) >= 0), + "Dataset write succeeded"); + + VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); + VRFY((H5Fclose(file_id) >= 0), "File close succeeded"); + } + + /* Set up file access property list with parallel I/O access */ + plist_id = H5Pcreate(H5P_FILE_ACCESS); + VRFY((plist_id >= 0), "FAPL creation succeeded"); + + VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), + "Set FAPL MPIO succeeded"); + + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); + + file_id = H5Fopen(filenames[0], H5F_ACC_RDONLY, plist_id); + VRFY((file_id >= 0), "Test file open succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); + + dset_id = H5Dopen2(file_id, "/" INTERLEAVED_READ_FILTERED_DATASET_NAME, H5P_DEFAULT); + VRFY((dset_id >= 0), "Dataset open succeeded"); + + sel_dims[0] = (hsize_t) (INTERLEAVED_READ_FILTERED_DATASET_NROWS / mpi_size); + sel_dims[1] = (hsize_t) INTERLEAVED_READ_FILTERED_DATASET_NCOLS; + + /* Setup one-dimensional memory dataspace for reading the dataset data into a contiguous buffer */ + flat_dims[0] = sel_dims[0] * sel_dims[1]; + + memspace = H5Screate_simple(1, flat_dims, NULL); + VRFY((memspace >= 0), "Memory dataspace creation succeeded"); + + /* Select hyperslab in the file */ + filespace = H5Dget_space(dset_id); + VRFY((filespace >= 0), "File dataspace retrieval succeeded"); + + /* + * Each process defines the dataset selection in the file and + * reads it to the selection in memory + */ + count[0] = (hsize_t) (INTERLEAVED_READ_FILTERED_DATASET_NROWS / INTERLEAVED_READ_FILTERED_DATASET_CH_NROWS); + count[1] = (hsize_t) (INTERLEAVED_READ_FILTERED_DATASET_NCOLS / INTERLEAVED_READ_FILTERED_DATASET_CH_NCOLS); + stride[0] = (hsize_t) INTERLEAVED_READ_FILTERED_DATASET_CH_NROWS; + stride[1] = (hsize_t) INTERLEAVED_READ_FILTERED_DATASET_CH_NCOLS; + block[0] = 1; + block[1] = (hsize_t) INTERLEAVED_READ_FILTERED_DATASET_CH_NCOLS; + start[0] = (hsize_t) mpi_rank; + start[1] = 0; + + if (VERBOSE_MED) { + printf("Process %d is reading with count[ %llu, %llu ], stride[ %llu, %llu ], start[ %llu, %llu ], block size[ %llu, %llu ]\n", + mpi_rank, count[0], count[1], stride[0], stride[1], start[0], start[1], block[0], block[1]); + fflush(stdout); + } + + VRFY((H5Sselect_hyperslab(filespace, H5S_SELECT_SET, start, stride, count, block) >= 0), + "Hyperslab selection succeeded"); + + /* Create property list for collective dataset read */ + plist_id = H5Pcreate(H5P_DATASET_XFER); + VRFY((plist_id >= 0), "DXPL creation succeeded"); + + VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), + "Set DXPL MPIO succeeded"); + + read_buf_size = flat_dims[0] * sizeof(*read_buf); + + read_buf = (C_DATATYPE *) HDcalloc(1, read_buf_size); + VRFY((NULL != read_buf), "HDcalloc succeeded"); + + VRFY((H5Dread(dset_id, HDF5_DATATYPE_NAME, memspace, filespace, plist_id, read_buf) >= 0), + "Dataset read succeeded"); + + global_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != global_buf), "HDcalloc succeeded"); + + /* + * Since these chunks are shared, run multiple rounds of MPI_Allgatherv + * to collect all of the pieces into their appropriate locations. The + * number of times MPI_Allgatherv is run should be equal to the number + * of chunks in the first dimension of the dataset. + */ + { + size_t loop_count = count[0]; + size_t total_recvcounts = 0; + + recvcounts = (int *) HDcalloc(1, (size_t) mpi_size * sizeof(*recvcounts)); + VRFY((NULL != recvcounts), "HDcalloc succeeded"); + + displs = (int *) HDcalloc(1, (size_t) mpi_size * sizeof(*displs)); + VRFY((NULL != displs), "HDcalloc succeeded"); + + for (i = 0; i < (size_t) mpi_size; i++) { + recvcounts[i] = (int) dataset_dims[1]; + total_recvcounts += (size_t) recvcounts[i]; + } + + for (i = 0; i < (size_t) mpi_size; i++) + displs[i] = (int) (i * dataset_dims[1]); + + for (; loop_count; loop_count--) { + VRFY((MPI_SUCCESS == MPI_Allgatherv(&read_buf[(count[0] - loop_count) * dataset_dims[1]], recvcounts[mpi_rank], C_DATATYPE_MPI, + &global_buf[(count[0] - loop_count) * total_recvcounts], recvcounts, displs, C_DATATYPE_MPI, comm)), + "MPI_Allgatherv succeeded"); + } + } + + VRFY((0 == memcmp(global_buf, correct_buf, correct_buf_size)), + "Data verification succeeded"); + + if (displs) HDfree(displs); + if (recvcounts) HDfree(recvcounts); + if (global_buf) HDfree(global_buf); + if (read_buf) HDfree(read_buf); + if (correct_buf) HDfree(correct_buf); + + VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); + VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); + VRFY((H5Sclose(memspace) >= 0), "Memory dataspace close succeeded"); + VRFY((H5Pclose(plist_id) >= 0), "DXPL close succeeded"); + VRFY((H5Fclose(file_id) >= 0), "File close succeeded"); + + return; +} + +/* + * Tests parallel read of filtered data in the case where + * the dataset has 3 dimensions and each process reads from + * its own "page" in the 3rd dimension. + * + * The MAINPROCESS rank will first write out all of the + * data to the dataset. Then, each rank reads its own "page" + * of the dataset and contributes its piece to a global buffer + * that is checked for consistency. + * + * Programmer: Jordan Henderson + * 05/16/2018 + */ +static void +test_read_3d_filtered_dataset_no_overlap_separate_pages(void) +{ + MPI_Datatype vector_type; + MPI_Datatype resized_vector_type; + C_DATATYPE *read_buf = NULL; + C_DATATYPE *correct_buf = NULL; + C_DATATYPE *global_buf = NULL; + hsize_t dataset_dims[READ_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_DIMS]; + hsize_t chunk_dims[READ_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_DIMS]; + hsize_t sel_dims[READ_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_DIMS]; + hsize_t start[READ_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_DIMS]; + hsize_t stride[READ_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_DIMS]; + hsize_t count[READ_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_DIMS]; + hsize_t block[READ_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_DIMS]; + hsize_t flat_dims[1]; + size_t i, read_buf_size, correct_buf_size; + hid_t file_id = -1, dset_id = -1, plist_id = -1; + hid_t filespace = -1, memspace = -1; + + dataset_dims[0] = (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_NROWS; + dataset_dims[1] = (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_NCOLS; + dataset_dims[2] = (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DEPTH; + + /* Setup the buffer for writing and for comparison */ + correct_buf_size = dataset_dims[0] * dataset_dims[1] * dataset_dims[2] * sizeof(*correct_buf); + + correct_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != correct_buf), "HDcalloc succeeded"); + + for (i = 0; i < correct_buf_size / sizeof(*correct_buf); i++) + correct_buf[i] = (C_DATATYPE) ((i % (hsize_t) mpi_size) + (i / (hsize_t) mpi_size)); + + if (MAINPROCESS) { + puts("Testing read from unshared filtered chunks on separate pages in 3D dataset"); + + plist_id = H5Pcreate(H5P_FILE_ACCESS); + VRFY((plist_id >= 0), "FAPL creation succeeded"); + + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); + + file_id = H5Fopen(filenames[0], H5F_ACC_RDWR, plist_id); + VRFY((file_id >= 0), "Test file open succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); + + /* Create the dataspace for the dataset */ + filespace = H5Screate_simple(READ_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_DIMS, dataset_dims, NULL); + VRFY((filespace >= 0), "File dataspace creation succeeded"); + + /* Create chunked dataset */ + chunk_dims[0] = (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_CH_NROWS; + chunk_dims[1] = (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_CH_NCOLS; + chunk_dims[2] = 1; + + plist_id = H5Pcreate(H5P_DATASET_CREATE); + VRFY((plist_id >= 0), "DCPL creation succeeded"); + + VRFY((H5Pset_chunk(plist_id, READ_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_DIMS, chunk_dims) >= 0), + "Chunk size set"); + + /* Add test filter to the pipeline */ + VRFY((set_dcpl_filter(plist_id) >= 0), "Filter set"); + + dset_id = H5Dcreate2(file_id, READ_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_NAME, HDF5_DATATYPE_NAME, filespace, + H5P_DEFAULT, plist_id, H5P_DEFAULT); + VRFY((dset_id >= 0), "Dataset creation succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "DCPL close succeeded"); + VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); + + VRFY((H5Dwrite(dset_id, HDF5_DATATYPE_NAME, H5S_ALL, H5S_ALL, H5P_DEFAULT, correct_buf) >= 0), + "Dataset write succeeded"); + + VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); + VRFY((H5Fclose(file_id) >= 0), "File close succeeded"); + } + + /* Set up file access property list with parallel I/O access */ + plist_id = H5Pcreate(H5P_FILE_ACCESS); + VRFY((plist_id >= 0), "FAPL creation succeeded"); + + VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), + "Set FAPL MPIO succeeded"); + + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); + + file_id = H5Fopen(filenames[0], H5F_ACC_RDONLY, plist_id); + VRFY((file_id >= 0), "Test file open succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); + + dset_id = H5Dopen2(file_id, "/" READ_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_NAME, H5P_DEFAULT); + VRFY((dset_id >= 0), "Dataset open succeeded"); + + sel_dims[0] = (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_NROWS; + sel_dims[1] = (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_NCOLS; + sel_dims[2] = 1; + + /* Setup one-dimensional memory dataspace for reading the dataset data into a contiguous buffer */ + flat_dims[0] = sel_dims[0] * sel_dims[1] * sel_dims[2]; + + memspace = H5Screate_simple(1, flat_dims, NULL); + VRFY((memspace >= 0), "Memory dataspace creation succeeded"); + + /* Select hyperslab in the file */ + filespace = H5Dget_space(dset_id); + VRFY((filespace >= 0), "File dataspace retrieval succeeded"); + + /* + * Each process defines the dataset selection in the file and + * reads it to the selection in memory + */ + count[0] = (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_NROWS / (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_CH_NROWS; + count[1] = (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_NCOLS / (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_CH_NCOLS; + count[2] = 1; + stride[0] = (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_CH_NROWS; + stride[1] = (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_CH_NCOLS; + stride[2] = 1; + block[0] = (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_CH_NROWS; + block[1] = (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_CH_NCOLS; + block[2] = 1; + start[0] = 0; + start[1] = 0; + start[2] = (hsize_t) mpi_rank; + + if (VERBOSE_MED) { + printf("Process %d is reading with count[ %llu, %llu ], stride[ %llu, %llu ], start[ %llu, %llu ], block size[ %llu, %llu ]\n", + mpi_rank, count[0], count[1], stride[0], stride[1], start[0], start[1], block[0], block[1]); + fflush(stdout); + } + + VRFY((H5Sselect_hyperslab(filespace, H5S_SELECT_SET, start, stride, count, block) >= 0), + "Hyperslab selection succeeded"); + + /* Create property list for collective dataset read */ + plist_id = H5Pcreate(H5P_DATASET_XFER); + VRFY((plist_id >= 0), "DXPL creation succeeded"); + + VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), + "Set DXPL MPIO succeeded"); + + read_buf_size = flat_dims[0] * sizeof(*read_buf); + + read_buf = (C_DATATYPE *) HDcalloc(1, read_buf_size); + VRFY((NULL != read_buf), "HDcalloc succeeded"); + + VRFY((H5Dread(dset_id, HDF5_DATATYPE_NAME, memspace, filespace, plist_id, read_buf) >= 0), + "Dataset read succeeded"); + + global_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != global_buf), "HDcalloc succeeded"); + + /* + * Due to the nature of 3-dimensional reading, create an MPI vector type that allows each + * rank to write to the nth position of the global data buffer, where n is the rank number. + */ + VRFY((MPI_SUCCESS == MPI_Type_vector((int) flat_dims[0], 1, mpi_size, C_DATATYPE_MPI, &vector_type)), + "MPI_Type_vector succeeded"); + VRFY((MPI_SUCCESS == MPI_Type_commit(&vector_type)), "MPI_Type_commit succeeded"); + + /* + * Resize the type to allow interleaving, + * so make it only one MPI_LONG wide + */ + VRFY((MPI_SUCCESS == MPI_Type_create_resized(vector_type, 0, sizeof(long), &resized_vector_type)), + "MPI_Type_create_resized"); + VRFY((MPI_SUCCESS == MPI_Type_commit(&resized_vector_type)), "MPI_Type_commit succeeded"); + + VRFY((MPI_SUCCESS == MPI_Allgather(read_buf, (int) flat_dims[0], C_DATATYPE_MPI, global_buf, 1, resized_vector_type, comm)), + "MPI_Allgather succeeded"); + + VRFY((0 == memcmp(global_buf, correct_buf, correct_buf_size)), + "Data verification succeeded"); + + VRFY((MPI_SUCCESS == MPI_Type_free(&vector_type)), "MPI_Type_free succeeded"); + VRFY((MPI_SUCCESS == MPI_Type_free(&resized_vector_type)), "MPI_Type_free succeeded"); + + if (global_buf) HDfree(global_buf); + if (read_buf) HDfree(read_buf); + if (correct_buf) HDfree(correct_buf); + + VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); + VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); + VRFY((H5Sclose(memspace) >= 0), "Memory dataspace close succeeded"); + VRFY((H5Pclose(plist_id) >= 0), "DXPL close succeeded"); + VRFY((H5Fclose(file_id) >= 0), "File close succeeded"); + + return; +} + +/* + * Tests parallel read of filtered data in the case where + * the dataset has 3 dimensions and each process reads from + * each "page" in the 3rd dimension. However, no chunk on a + * given "page" is read from by more than one process. + * + * The MAINPROCESS rank will first write out all of the + * data to the dataset. Then, each rank reads a part of + * each "page" of the dataset and contributes its piece to a + * global buffer that is checked for consistency. + * + * Programmer: Jordan Henderson + * 05/16/2018 + */ +static void +test_read_3d_filtered_dataset_no_overlap_same_pages(void) +{ + C_DATATYPE *read_buf = NULL; + C_DATATYPE *correct_buf = NULL; + C_DATATYPE *global_buf = NULL; + hsize_t dataset_dims[READ_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_DIMS]; + hsize_t chunk_dims[READ_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_DIMS]; + hsize_t sel_dims[READ_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_DIMS]; + hsize_t start[READ_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_DIMS]; + hsize_t stride[READ_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_DIMS]; + hsize_t count[READ_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_DIMS]; + hsize_t block[READ_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_DIMS]; + hsize_t flat_dims[1]; + size_t i, read_buf_size, correct_buf_size; + hid_t file_id, dset_id, plist_id; + hid_t filespace, memspace; + int *recvcounts = NULL; + int *displs = NULL; + + dataset_dims[0] = (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_NROWS; + dataset_dims[1] = (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_NCOLS; + dataset_dims[2] = (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DEPTH; + + /* Setup the buffer for writing and for comparison */ + correct_buf_size = dataset_dims[0] * dataset_dims[1] * dataset_dims[2] * sizeof(*correct_buf); + + correct_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != correct_buf), "HDcalloc succeeded"); + + for (i = 0; i < correct_buf_size / sizeof(*correct_buf); i++) + correct_buf[i] = (C_DATATYPE) ( + (i % (dataset_dims[0] * dataset_dims[1])) + + (i / (dataset_dims[0] * dataset_dims[1])) + ); + + if (MAINPROCESS) { + puts("Testing read from unshared filtered chunks on the same pages in 3D dataset"); + + plist_id = H5Pcreate(H5P_FILE_ACCESS); + VRFY((plist_id >= 0), "FAPL creation succeeded"); + + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); + + file_id = H5Fopen(filenames[0], H5F_ACC_RDWR, plist_id); + VRFY((file_id >= 0), "Test file open succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); + + /* Create the dataspace for the dataset */ + filespace = H5Screate_simple(READ_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_DIMS, dataset_dims, NULL); + VRFY((filespace >= 0), "File dataspace creation succeeded"); + + /* Create chunked dataset */ + chunk_dims[0] = (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_CH_NROWS; + chunk_dims[1] = (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_CH_NCOLS; + chunk_dims[2] = 1; + + plist_id = H5Pcreate(H5P_DATASET_CREATE); + VRFY((plist_id >= 0), "DCPL creation succeeded"); + + VRFY((H5Pset_chunk(plist_id, READ_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_DIMS, chunk_dims) >= 0), + "Chunk size set"); + + /* Add test filter to the pipeline */ + VRFY((set_dcpl_filter(plist_id) >= 0), "Filter set"); + + dset_id = H5Dcreate2(file_id, READ_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_NAME, HDF5_DATATYPE_NAME, filespace, + H5P_DEFAULT, plist_id, H5P_DEFAULT); + VRFY((dset_id >= 0), "Dataset creation succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "DCPL close succeeded"); + VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); + + VRFY((H5Dwrite(dset_id, HDF5_DATATYPE_NAME, H5S_ALL, H5S_ALL, H5P_DEFAULT, correct_buf) >= 0), + "Dataset write succeeded"); + + VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); + VRFY((H5Fclose(file_id) >= 0), "File close succeeded"); + } + + /* Set up file access property list with parallel I/O access */ + plist_id = H5Pcreate(H5P_FILE_ACCESS); + VRFY((plist_id >= 0), "FAPL creation succeeded"); + + VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), + "Set FAPL MPIO succeeded"); + + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); + + file_id = H5Fopen(filenames[0], H5F_ACC_RDONLY, plist_id); + VRFY((file_id >= 0), "Test file open succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); + + dset_id = H5Dopen2(file_id, "/" READ_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_NAME, H5P_DEFAULT); + VRFY((dset_id >= 0), "Dataset open succeeded"); + + sel_dims[0] = (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_CH_NROWS; + sel_dims[1] = (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_NCOLS; + sel_dims[2] = (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DEPTH; + + /* Setup one-dimensional memory dataspace for reading the dataset data into a contiguous buffer */ + flat_dims[0] = sel_dims[0] * sel_dims[1] * sel_dims[2]; + + memspace = H5Screate_simple(1, flat_dims, NULL); + VRFY((memspace >= 0), "Memory dataspace creation succeeded"); + + /* Select hyperslab in the file */ + filespace = H5Dget_space(dset_id); + VRFY((filespace >= 0), "File dataspace retrieval succeeded"); + + /* + * Each process defines the dataset selection in the file and + * reads it to the selection in memory + */ + count[0] = 1; + count[1] = (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_NCOLS / (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_CH_NCOLS; + count[2] = (hsize_t) mpi_size; + stride[0] = (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_CH_NROWS; + stride[1] = (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_CH_NCOLS; + stride[2] = 1; + block[0] = (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_CH_NROWS; + block[1] = (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_CH_NCOLS; + block[2] = 1; + start[0] = ((hsize_t) mpi_rank * (hsize_t) READ_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_CH_NROWS * count[0]); + start[1] = 0; + start[2] = 0; + + if (VERBOSE_MED) { + printf("Process %d is reading with count[ %llu, %llu ], stride[ %llu, %llu ], start[ %llu, %llu ], block size[ %llu, %llu ]\n", + mpi_rank, count[0], count[1], stride[0], stride[1], start[0], start[1], block[0], block[1]); + fflush(stdout); + } + + VRFY((H5Sselect_hyperslab(filespace, H5S_SELECT_SET, start, stride, count, block) >= 0), + "Hyperslab selection succeeded"); + + /* Create property list for collective dataset read */ + plist_id = H5Pcreate(H5P_DATASET_XFER); + VRFY((plist_id >= 0), "DXPL creation succeeded"); + + VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), + "Set DXPL MPIO succeeded"); + + read_buf_size = flat_dims[0] * sizeof(*read_buf); + + read_buf = (C_DATATYPE *) HDcalloc(1, read_buf_size); + VRFY((NULL != read_buf), "HDcalloc succeeded"); + + VRFY((H5Dread(dset_id, HDF5_DATATYPE_NAME, memspace, filespace, plist_id, read_buf) >= 0), + "Dataset read succeeded"); + + global_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != global_buf), "HDcalloc succeeded"); + + /* Collect each piece of data from all ranks into a global buffer on all ranks */ + recvcounts = (int *) HDcalloc(1, (size_t) mpi_size * sizeof(*recvcounts)); + VRFY((NULL != recvcounts), "HDcalloc succeeded"); + + for (i = 0; i < (size_t) mpi_size; i++) + recvcounts[i] = (int) flat_dims[0]; + + displs = (int *) HDcalloc(1, (size_t) mpi_size * sizeof(*displs)); + VRFY((NULL != displs), "HDcalloc succeeded"); + + for (i = 0; i < (size_t) mpi_size; i++) + displs[i] = (int) (i * flat_dims[0]); + + VRFY((MPI_SUCCESS == MPI_Allgatherv(read_buf, (int) flat_dims[0], C_DATATYPE_MPI, global_buf, recvcounts, displs, C_DATATYPE_MPI, comm)), + "MPI_Allgatherv succeeded"); + + VRFY((0 == memcmp(global_buf, correct_buf, correct_buf_size)), + "Data verification succeeded"); + + if (displs) HDfree(displs); + if (recvcounts) HDfree(recvcounts); + if (global_buf) HDfree(global_buf); + if (read_buf) HDfree(read_buf); + if (correct_buf) HDfree(correct_buf); + + VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); + VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); + VRFY((H5Sclose(memspace) >= 0), "Memory dataspace close succeeded"); + VRFY((H5Pclose(plist_id) >= 0), "DXPL close succeeded"); + VRFY((H5Fclose(file_id) >= 0), "File close succeeded"); + + return; +} + +/* + * Tests parallel read of filtered data in the case where + * the dataset has 3 dimensions and each process reads from + * each "page" in the 3rd dimension. Further, each chunk in + * each "page" is read from equally by all processes. + * + * The MAINPROCESS rank will first write out all of the + * data to the dataset. Then, each rank reads part of each + * chunk of each "page" and contributes its pieces to a + * global buffer that is checked for consistency. + * + * Programmer: Jordan Henderson + * 05/16/2018 + */ +static void +test_read_3d_filtered_dataset_overlap(void) +{ + MPI_Datatype vector_type; + MPI_Datatype resized_vector_type; + C_DATATYPE *read_buf = NULL; + C_DATATYPE *correct_buf = NULL; + C_DATATYPE *global_buf = NULL; + hsize_t dataset_dims[READ_SHARED_FILTERED_CHUNKS_3D_DATASET_DIMS]; + hsize_t chunk_dims[READ_SHARED_FILTERED_CHUNKS_3D_DATASET_DIMS]; + hsize_t sel_dims[READ_SHARED_FILTERED_CHUNKS_3D_DATASET_DIMS]; + hsize_t start[READ_SHARED_FILTERED_CHUNKS_3D_DATASET_DIMS]; + hsize_t stride[READ_SHARED_FILTERED_CHUNKS_3D_DATASET_DIMS]; + hsize_t count[READ_SHARED_FILTERED_CHUNKS_3D_DATASET_DIMS]; + hsize_t block[READ_SHARED_FILTERED_CHUNKS_3D_DATASET_DIMS]; + hsize_t flat_dims[1]; + size_t i, read_buf_size, correct_buf_size; + hid_t file_id = -1, dset_id = -1, plist_id = -1; + hid_t filespace = -1, memspace = -1; + + dataset_dims[0] = (hsize_t) READ_SHARED_FILTERED_CHUNKS_3D_NROWS; + dataset_dims[1] = (hsize_t) READ_SHARED_FILTERED_CHUNKS_3D_NCOLS; + dataset_dims[2] = (hsize_t) READ_SHARED_FILTERED_CHUNKS_3D_DEPTH; + + /* Setup the buffer for writing and for comparison */ + correct_buf_size = dataset_dims[0] * dataset_dims[1] * dataset_dims[2] * sizeof(*correct_buf); + + correct_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != correct_buf), "HDcalloc succeeded"); + + for (i = 0; i < correct_buf_size / sizeof(*correct_buf); i++) + /* Add the Column Index */ + correct_buf[i] = + (C_DATATYPE) ( + (i % (hsize_t) (READ_SHARED_FILTERED_CHUNKS_3D_DEPTH * READ_SHARED_FILTERED_CHUNKS_3D_NCOLS)) + + /* Add the Row Index */ + + ((i % (hsize_t) (mpi_size * READ_SHARED_FILTERED_CHUNKS_3D_DEPTH * READ_SHARED_FILTERED_CHUNKS_3D_NCOLS)) + / (hsize_t) (READ_SHARED_FILTERED_CHUNKS_3D_DEPTH * READ_SHARED_FILTERED_CHUNKS_3D_NCOLS)) + + /* Add the amount that gets added when a rank moves down to its next section vertically in the dataset */ + + ((hsize_t) (READ_SHARED_FILTERED_CHUNKS_3D_DEPTH * READ_SHARED_FILTERED_CHUNKS_3D_NCOLS) + * (i / (hsize_t) (mpi_size * READ_SHARED_FILTERED_CHUNKS_3D_DEPTH * READ_SHARED_FILTERED_CHUNKS_3D_NCOLS))) + ); + + if (MAINPROCESS) { + puts("Testing read from shared filtered chunks in 3D dataset"); + + plist_id = H5Pcreate(H5P_FILE_ACCESS); + VRFY((plist_id >= 0), "FAPL creation succeeded"); + + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); + + file_id = H5Fopen(filenames[0], H5F_ACC_RDWR, plist_id); + VRFY((file_id >= 0), "Test file open succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); + + /* Create the dataspace for the dataset */ + filespace = H5Screate_simple(READ_SHARED_FILTERED_CHUNKS_3D_DATASET_DIMS, dataset_dims, NULL); + VRFY((filespace >= 0), "File dataspace creation succeeded"); + + /* Create chunked dataset */ + chunk_dims[0] = (hsize_t) READ_SHARED_FILTERED_CHUNKS_3D_CH_NROWS; + chunk_dims[1] = (hsize_t) READ_SHARED_FILTERED_CHUNKS_3D_CH_NCOLS; + chunk_dims[2] = 1; + + plist_id = H5Pcreate(H5P_DATASET_CREATE); + VRFY((plist_id >= 0), "DCPL creation succeeded"); + + VRFY((H5Pset_chunk(plist_id, READ_SHARED_FILTERED_CHUNKS_3D_DATASET_DIMS, chunk_dims) >= 0), + "Chunk size set"); + + /* Add test filter to the pipeline */ + VRFY((set_dcpl_filter(plist_id) >= 0), "Filter set"); + + dset_id = H5Dcreate2(file_id, READ_SHARED_FILTERED_CHUNKS_3D_DATASET_NAME, HDF5_DATATYPE_NAME, filespace, + H5P_DEFAULT, plist_id, H5P_DEFAULT); + VRFY((dset_id >= 0), "Dataset creation succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "DCPL close succeeded"); + VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); + + VRFY((H5Dwrite(dset_id, HDF5_DATATYPE_NAME, H5S_ALL, H5S_ALL, H5P_DEFAULT, correct_buf) >= 0), + "Dataset write succeeded"); + + VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); + VRFY((H5Fclose(file_id) >= 0), "File close succeeded"); + } + + /* Set up file access property list with parallel I/O access */ + plist_id = H5Pcreate(H5P_FILE_ACCESS); + VRFY((plist_id >= 0), "FAPL creation succeeded"); + + VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), + "Set FAPL MPIO succeeded"); + + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); + + file_id = H5Fopen(filenames[0], H5F_ACC_RDONLY, plist_id); + VRFY((file_id >= 0), "Test file open succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); + + dset_id = H5Dopen2(file_id, "/" READ_SHARED_FILTERED_CHUNKS_3D_DATASET_NAME, H5P_DEFAULT); + VRFY((dset_id >= 0), "Dataset open succeeded"); + + sel_dims[0] = (hsize_t) (READ_SHARED_FILTERED_CHUNKS_3D_NROWS / mpi_size); + sel_dims[1] = (hsize_t) READ_SHARED_FILTERED_CHUNKS_3D_NCOLS; + sel_dims[2] = (hsize_t) READ_SHARED_FILTERED_CHUNKS_3D_DEPTH; + + /* Setup one-dimensional memory dataspace for reading the dataset data into a contiguous buffer */ + flat_dims[0] = sel_dims[0] * sel_dims[1] * sel_dims[2]; + + memspace = H5Screate_simple(1, flat_dims, NULL); + VRFY((memspace >= 0), "Memory dataspace creation succeeded"); + + /* Select hyperslab in the file */ + filespace = H5Dget_space(dset_id); + VRFY((filespace >= 0), "File dataspace retrieval succeeded"); + + /* + * Each process defines the dataset selection in the file and + * reads it to the selection in memory + */ + count[0] = (hsize_t) (READ_SHARED_FILTERED_CHUNKS_3D_NROWS / READ_SHARED_FILTERED_CHUNKS_3D_CH_NROWS); + count[1] = (hsize_t) (READ_SHARED_FILTERED_CHUNKS_3D_NCOLS / READ_SHARED_FILTERED_CHUNKS_3D_CH_NCOLS); + count[2] = (hsize_t) READ_SHARED_FILTERED_CHUNKS_3D_DEPTH; + stride[0] = (hsize_t) READ_SHARED_FILTERED_CHUNKS_3D_CH_NROWS; + stride[1] = (hsize_t) READ_SHARED_FILTERED_CHUNKS_3D_CH_NCOLS; + stride[2] = 1; + block[0] = 1; + block[1] = (hsize_t) READ_SHARED_FILTERED_CHUNKS_3D_CH_NCOLS; + block[2] = 1; + start[0] = (hsize_t) mpi_rank; + start[1] = 0; + start[2] = 0; + + if (VERBOSE_MED) { + printf("Process %d is reading with count[ %llu, %llu ], stride[ %llu, %llu ], start[ %llu, %llu ], block size[ %llu, %llu ]\n", + mpi_rank, count[0], count[1], stride[0], stride[1], start[0], start[1], block[0], block[1]); + fflush(stdout); + } + + VRFY((H5Sselect_hyperslab(filespace, H5S_SELECT_SET, start, stride, count, block) >= 0), + "Hyperslab selection succeeded"); + + /* Create property list for collective dataset read */ + plist_id = H5Pcreate(H5P_DATASET_XFER); + VRFY((plist_id >= 0), "DXPL creation succeeded"); + + VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), + "Set DXPL MPIO succeeded"); + + read_buf_size = flat_dims[0] * sizeof(*read_buf); + + read_buf = (C_DATATYPE *) HDcalloc(1, read_buf_size); + VRFY((NULL != read_buf), "HDcalloc succeeded"); + + VRFY((H5Dread(dset_id, HDF5_DATATYPE_NAME, memspace, filespace, plist_id, read_buf) >= 0), + "Dataset read succeeded"); + + global_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != global_buf), "HDcalloc succeeded"); + + { + size_t run_length = (size_t) (READ_SHARED_FILTERED_CHUNKS_3D_NCOLS * READ_SHARED_FILTERED_CHUNKS_3D_DEPTH); + size_t num_blocks = (size_t) (READ_SHARED_FILTERED_CHUNKS_3D_NROWS / mpi_size); + + /* + * Due to the nature of 3-dimensional reading, create an MPI vector type that allows each + * rank to write to the nth position of the global data buffer, where n is the rank number. + */ + VRFY((MPI_SUCCESS == MPI_Type_vector((int) num_blocks, (int) run_length, (int) (mpi_size * (int) run_length), C_DATATYPE_MPI, &vector_type)), + "MPI_Type_vector succeeded"); + VRFY((MPI_SUCCESS == MPI_Type_commit(&vector_type)), "MPI_Type_commit succeeded"); + + /* + * Resize the type to allow interleaving, + * so make it "run_length" MPI_LONGs wide + */ + VRFY((MPI_SUCCESS == MPI_Type_create_resized(vector_type, 0, (MPI_Aint) (run_length * sizeof(long)), &resized_vector_type)), + "MPI_Type_create_resized"); + VRFY((MPI_SUCCESS == MPI_Type_commit(&resized_vector_type)), "MPI_Type_commit succeeded"); + } + + VRFY((MPI_SUCCESS == MPI_Allgather(read_buf, (int) flat_dims[0], C_DATATYPE_MPI, global_buf, 1, resized_vector_type, comm)), + "MPI_Allgatherv succeeded"); + + VRFY((0 == memcmp(global_buf, correct_buf, correct_buf_size)), + "Data verification succeeded"); + + VRFY((MPI_SUCCESS == MPI_Type_free(&vector_type)), "MPI_Type_free succeeded"); + VRFY((MPI_SUCCESS == MPI_Type_free(&resized_vector_type)), "MPI_Type_free succeeded"); + + if (global_buf) HDfree(global_buf); + if (read_buf) HDfree(read_buf); + if (correct_buf) HDfree(correct_buf); + + VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); + VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); + VRFY((H5Sclose(memspace) >= 0), "Memory dataspace close succeeded"); + VRFY((H5Pclose(plist_id) >= 0), "DXPL close succeeded"); + VRFY((H5Fclose(file_id) >= 0), "File close succeeded"); + + return; +} + +/* + * Tests parallel read of filtered data to unshared + * chunks using a compound datatype which doesn't + * require a datatype conversion. + * + * The MAINPROCESS rank will first write out all of the + * data to the dataset. Then, each rank reads a part of + * the dataset and contributes its piece to a global + * buffer that is checked for consistency. + * + * Programmer: Jordan Henderson + * 05/17/2018 + */ +static void +test_read_cmpd_filtered_dataset_no_conversion_unshared(void) +{ + COMPOUND_C_DATATYPE *read_buf = NULL; + COMPOUND_C_DATATYPE *correct_buf = NULL; + COMPOUND_C_DATATYPE *global_buf = NULL; + hsize_t dataset_dims[READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_DIMS]; + hsize_t chunk_dims[READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_DIMS]; + hsize_t sel_dims[READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_DIMS]; + hsize_t start[READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_DIMS]; + hsize_t stride[READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_DIMS]; + hsize_t count[READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_DIMS]; + hsize_t block[READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_DIMS]; + hsize_t flat_dims[1]; + size_t i, read_buf_size, correct_buf_size; + hid_t file_id = -1, dset_id = -1, plist_id = -1, memtype = -1; + hid_t filespace = -1, memspace = -1; + int *recvcounts = NULL; + int *displs = NULL; + + dataset_dims[0] = (hsize_t) READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_NROWS; + dataset_dims[1] = (hsize_t) READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_NCOLS; + + /* Setup the buffer for writing and for comparison */ + correct_buf_size = dataset_dims[0] * dataset_dims[1] * sizeof(*correct_buf); + + correct_buf = (COMPOUND_C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != correct_buf), "HDcalloc succeeded"); + + for (i = 0; i < correct_buf_size / sizeof(*correct_buf); i++) { + correct_buf[i].field1 = (short) ( + (i % dataset_dims[1]) + + (i / dataset_dims[1]) + ); + + correct_buf[i].field2 = (int) ( + (i % dataset_dims[1]) + + (i / dataset_dims[1]) + ); + + correct_buf[i].field3 = (long) ( + (i % dataset_dims[1]) + + (i / dataset_dims[1]) + ); + } + + /* Create the compound type for memory. */ + memtype = H5Tcreate(H5T_COMPOUND, sizeof(COMPOUND_C_DATATYPE)); + VRFY((memtype >= 0), "Datatype creation succeeded"); + + VRFY((H5Tinsert(memtype, "ShortData", HOFFSET(COMPOUND_C_DATATYPE, field1), H5T_NATIVE_SHORT) >= 0), + "Datatype insertion succeeded"); + VRFY((H5Tinsert(memtype, "IntData", HOFFSET(COMPOUND_C_DATATYPE, field2), H5T_NATIVE_INT) >= 0), + "Datatype insertion succeeded"); + VRFY((H5Tinsert(memtype, "LongData", HOFFSET(COMPOUND_C_DATATYPE, field3), H5T_NATIVE_LONG) >= 0), + "Datatype insertion succeeded"); + + if (MAINPROCESS) { + puts("Testing read from unshared filtered chunks in Compound Datatype dataset without Datatype conversion"); + + plist_id = H5Pcreate(H5P_FILE_ACCESS); + VRFY((plist_id >= 0), "FAPL creation succeeded"); + + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); + + file_id = H5Fopen(filenames[0], H5F_ACC_RDWR, plist_id); + VRFY((file_id >= 0), "Test file open succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); + + /* Create the dataspace for the dataset */ + filespace = H5Screate_simple(READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_DIMS, dataset_dims, NULL); + VRFY((filespace >= 0), "File dataspace creation succeeded"); + + /* Create chunked dataset */ + chunk_dims[0] = READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_CH_NROWS; + chunk_dims[1] = READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_CH_NCOLS; + + plist_id = H5Pcreate(H5P_DATASET_CREATE); + VRFY((plist_id >= 0), "DCPL creation succeeded"); + + VRFY((H5Pset_chunk(plist_id, READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_DIMS, chunk_dims) >= 0), + "Chunk size set"); + + /* Add test filter to the pipeline */ + VRFY((set_dcpl_filter(plist_id) >= 0), "Filter set"); + + dset_id = H5Dcreate2(file_id, READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_NAME, memtype, filespace, + H5P_DEFAULT, plist_id, H5P_DEFAULT); + VRFY((dset_id >= 0), "Dataset creation succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "DCPL close succeeded"); + VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); + + VRFY((H5Dwrite(dset_id, memtype, H5S_ALL, H5S_ALL, H5P_DEFAULT, correct_buf) >= 0), + "Dataset write succeeded"); + + VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); + VRFY((H5Fclose(file_id) >= 0), "File close succeeded"); + } + + /* Set up file access property list with parallel I/O access */ + plist_id = H5Pcreate(H5P_FILE_ACCESS); + VRFY((plist_id >= 0), "FAPL creation succeeded"); + + VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), + "Set FAPL MPIO succeeded"); + + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); + + file_id = H5Fopen(filenames[0], H5F_ACC_RDONLY, plist_id); + VRFY((file_id >= 0), "Test file open succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); + + dset_id = H5Dopen2(file_id, "/" READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_NAME, H5P_DEFAULT); + VRFY((dset_id >= 0), "Dataset open succeeded"); + + sel_dims[0] = (hsize_t) READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_CH_NROWS; + sel_dims[1] = (hsize_t) READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_ENTRIES_PER_PROC; + + /* Setup one-dimensional memory dataspace for reading the dataset data into a contiguous buffer */ + flat_dims[0] = sel_dims[0] * sel_dims[1]; + + memspace = H5Screate_simple(1, flat_dims, NULL); + VRFY((memspace >= 0), "Memory dataspace creation succeeded"); + + /* Select hyperslab in the file */ + filespace = H5Dget_space(dset_id); + VRFY((filespace >= 0), "File dataspace retrieval succeeded"); + + /* + * Each process defines the dataset selection in the file and + * reads it to the selection in memory + */ + count[0] = 1; + count[1] = (hsize_t) READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_ENTRIES_PER_PROC; + stride[0] = READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_CH_NROWS; + stride[1] = READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_CH_NCOLS; + block[0] = READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_CH_NROWS; + block[1] = READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_CH_NCOLS; + start[0] = 0; + start[1] = ((hsize_t) mpi_rank * READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_CH_NCOLS); + + if (VERBOSE_MED) { + printf("Process %d is reading with count[ %llu, %llu ], stride[ %llu, %llu ], start[ %llu, %llu ], block size[ %llu, %llu ]\n", + mpi_rank, count[0], count[1], stride[0], stride[1], start[0], start[1], block[0], block[1]); + fflush(stdout); + } + + VRFY((H5Sselect_hyperslab(filespace, H5S_SELECT_SET, start, stride, count, block) >= 0), + "Hyperslab selection succeeded"); + + /* Create property list for collective dataset read */ + plist_id = H5Pcreate(H5P_DATASET_XFER); + VRFY((plist_id >= 0), "DXPL creation succeeded"); + + VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), + "Set DXPL MPIO succeeded"); + + read_buf_size = flat_dims[0] * sizeof(*read_buf); + + read_buf = (COMPOUND_C_DATATYPE *) HDcalloc(1, read_buf_size); + VRFY((NULL != read_buf), "HDcalloc succeeded"); + + VRFY((H5Dread(dset_id, memtype, memspace, filespace, plist_id, read_buf) >= 0), + "Dataset read succeeded"); + + global_buf = (COMPOUND_C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != global_buf), "HDcalloc succeeded"); + + /* Collect each piece of data from all ranks into a global buffer on all ranks */ + recvcounts = (int *) HDcalloc(1, (size_t) mpi_size * sizeof(*recvcounts)); + VRFY((NULL != recvcounts), "HDcalloc succeeded"); + + for (i = 0; i < (size_t) mpi_size; i++) + recvcounts[i] = (int) (flat_dims[0] * sizeof(*read_buf)); + + displs = (int *) HDcalloc(1, (size_t) mpi_size * sizeof(*displs)); + VRFY((NULL != displs), "HDcalloc succeeded"); + + for (i = 0; i < (size_t) mpi_size; i++) + displs[i] = (int) (i * flat_dims[0] * sizeof(*read_buf)); + + VRFY((MPI_SUCCESS == MPI_Allgatherv(read_buf, (int) (flat_dims[0] * sizeof(COMPOUND_C_DATATYPE)), MPI_BYTE, global_buf, recvcounts, displs, MPI_BYTE, comm)), + "MPI_Allgatherv succeeded"); + + VRFY((0 == memcmp(global_buf, correct_buf, correct_buf_size)), + "Data verification succeeded"); + + if (displs) HDfree(displs); + if (recvcounts) HDfree(recvcounts); + if (global_buf) HDfree(global_buf); + if (read_buf) HDfree(read_buf); + if (correct_buf) HDfree(correct_buf); + + VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); + VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); + VRFY((H5Sclose(memspace) >= 0), "Memory dataspace close succeeded"); + VRFY((H5Tclose(memtype) >= 0), "Memory datatype close succeeded"); + VRFY((H5Pclose(plist_id) >= 0), "DXPL close succeeded"); + VRFY((H5Fclose(file_id) >= 0), "File close succeeded"); + + return; +} + +/* + * Tests parallel read of filtered data from shared + * chunks using a compound datatype which doesn't + * require a datatype conversion. + * + * The MAINPROCESS rank will first write out all of the + * data to the dataset. Then, each rank reads a part of + * each chunk of the dataset and contributes its piece + * to a global buffer that is checked for consistency. + * + * Programmer: Jordan Henderson + * 05/17/2018 + */ +static void +test_read_cmpd_filtered_dataset_no_conversion_shared(void) +{ + COMPOUND_C_DATATYPE *read_buf = NULL; + COMPOUND_C_DATATYPE *correct_buf = NULL; + COMPOUND_C_DATATYPE *global_buf = NULL; + hsize_t dataset_dims[READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_DIMS]; + hsize_t chunk_dims[READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_DIMS]; + hsize_t sel_dims[READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_DIMS]; + hsize_t start[READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_DIMS]; + hsize_t stride[READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_DIMS]; + hsize_t count[READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_DIMS]; + hsize_t block[READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_DIMS]; + hsize_t flat_dims[1]; + size_t i, read_buf_size, correct_buf_size; + hid_t file_id, dset_id, plist_id, memtype; + hid_t filespace, memspace; + int *recvcounts = NULL; + int *displs = NULL; + + dataset_dims[0] = (hsize_t) READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_NROWS; + dataset_dims[1] = (hsize_t) READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_NCOLS; + + /* Setup the buffer for writing and for comparison */ + correct_buf_size = dataset_dims[0] * dataset_dims[1] * sizeof(*correct_buf); + + correct_buf = (COMPOUND_C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != correct_buf), "HDcalloc succeeded"); + + for (i = 0; i < correct_buf_size / sizeof(*correct_buf); i++) { + correct_buf[i].field1 = (short) ( + (dataset_dims[1] * (i / ((hsize_t) mpi_size * dataset_dims[1]))) + + (i % dataset_dims[1]) + + (((i % ((hsize_t) mpi_size * dataset_dims[1])) / dataset_dims[1]) % dataset_dims[1]) + ); + + correct_buf[i].field2 = (int) ( + (dataset_dims[1] * (i / ((hsize_t) mpi_size * dataset_dims[1]))) + + (i % dataset_dims[1]) + + (((i % ((hsize_t) mpi_size * dataset_dims[1])) / dataset_dims[1]) % dataset_dims[1]) + ); + + correct_buf[i].field3 = (long) ( + (dataset_dims[1] * (i / ((hsize_t) mpi_size * dataset_dims[1]))) + + (i % dataset_dims[1]) + + (((i % ((hsize_t) mpi_size * dataset_dims[1])) / dataset_dims[1]) % dataset_dims[1]) + ); + } + + /* Create the compound type for memory. */ + memtype = H5Tcreate(H5T_COMPOUND, sizeof(COMPOUND_C_DATATYPE)); + VRFY((memtype >= 0), "Datatype creation succeeded"); + + VRFY((H5Tinsert(memtype, "ShortData", HOFFSET(COMPOUND_C_DATATYPE, field1), H5T_NATIVE_SHORT) >= 0), + "Datatype insertion succeeded"); + VRFY((H5Tinsert(memtype, "IntData", HOFFSET(COMPOUND_C_DATATYPE, field2), H5T_NATIVE_INT) >= 0), + "Datatype insertion succeeded"); + VRFY((H5Tinsert(memtype, "LongData", HOFFSET(COMPOUND_C_DATATYPE, field3), H5T_NATIVE_LONG) >= 0), + "Datatype insertion succeeded"); + + if (MAINPROCESS) { + puts("Testing read from shared filtered chunks in Compound Datatype dataset without Datatype conversion"); + + plist_id = H5Pcreate(H5P_FILE_ACCESS); + VRFY((plist_id >= 0), "FAPL creation succeeded"); + + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); + + file_id = H5Fopen(filenames[0], H5F_ACC_RDWR, plist_id); + VRFY((file_id >= 0), "Test file open succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); + + /* Create the dataspace for the dataset */ + filespace = H5Screate_simple(READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_DIMS, dataset_dims, NULL); + VRFY((filespace >= 0), "File dataspace creation succeeded"); + + /* Create chunked dataset */ + chunk_dims[0] = (hsize_t) READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_CH_NROWS; + chunk_dims[1] = (hsize_t) READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_CH_NCOLS; + + plist_id = H5Pcreate(H5P_DATASET_CREATE); + VRFY((plist_id >= 0), "DCPL creation succeeded"); + + VRFY((H5Pset_chunk(plist_id, READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_DIMS, chunk_dims) >= 0), + "Chunk size set"); + + /* Add test filter to the pipeline */ + VRFY((set_dcpl_filter(plist_id) >= 0), "Filter set"); + + dset_id = H5Dcreate2(file_id, READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_NAME, memtype, filespace, + H5P_DEFAULT, plist_id, H5P_DEFAULT); + VRFY((dset_id >= 0), "Dataset creation succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "DCPL close succeeded"); + VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); + + VRFY((H5Dwrite(dset_id, memtype, H5S_ALL, H5S_ALL, H5P_DEFAULT, correct_buf) >= 0), + "Dataset write succeeded"); + + VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); + VRFY((H5Fclose(file_id) >= 0), "File close succeeded"); + } + + /* Set up file access property list with parallel I/O access */ + plist_id = H5Pcreate(H5P_FILE_ACCESS); + VRFY((plist_id >= 0), "FAPL creation succeeded"); + + VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), + "Set FAPL MPIO succeeded"); + + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); + + file_id = H5Fopen(filenames[0], H5F_ACC_RDONLY, plist_id); + VRFY((file_id >= 0), "Test file open succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); + + dset_id = H5Dopen2(file_id, "/" READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_NAME, H5P_DEFAULT); + VRFY((dset_id >= 0), "Dataset open succeeded"); + + sel_dims[0] = (hsize_t) READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_CH_NROWS / (hsize_t) mpi_size; + sel_dims[1] = (hsize_t) READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_ENTRIES_PER_PROC; + + /* Setup one-dimensional memory dataspace for reading the dataset data into a contiguous buffer */ + flat_dims[0] = sel_dims[0] * sel_dims[1]; + + memspace = H5Screate_simple(1, flat_dims, NULL); + VRFY((memspace >= 0), "Memory dataspace creation succeeded"); + + /* Select hyperslab in the file */ + filespace = H5Dget_space(dset_id); + VRFY((filespace >= 0), "File dataspace retrieval succeeded"); + + /* + * Each process defines the dataset selection in the file and + * reads it to the selection in memory + */ + count[0] = 1; + count[1] = (hsize_t) READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_ENTRIES_PER_PROC; + stride[0] = (hsize_t) READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_CH_NROWS; + stride[1] = READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_CH_NCOLS; + block[0] = (hsize_t) READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_CH_NROWS / (hsize_t) mpi_size; + block[1] = READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_CH_NCOLS; + start[0] = (hsize_t) mpi_rank; + start[1] = 0; + + if (VERBOSE_MED) { + printf("Process %d is reading with count[ %llu, %llu ], stride[ %llu, %llu ], start[ %llu, %llu ], block size[ %llu, %llu ]\n", + mpi_rank, count[0], count[1], stride[0], stride[1], start[0], start[1], block[0], block[1]); + fflush(stdout); + } + + VRFY((H5Sselect_hyperslab(filespace, H5S_SELECT_SET, start, stride, count, block) >= 0), + "Hyperslab selection succeeded"); + + /* Create property list for collective dataset read */ + plist_id = H5Pcreate(H5P_DATASET_XFER); + VRFY((plist_id >= 0), "DXPL creation succeeded"); + + VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), + "Set DXPL MPIO succeeded"); + + read_buf_size = flat_dims[0] * sizeof(*read_buf); + + read_buf = (COMPOUND_C_DATATYPE *) HDcalloc(1, read_buf_size); + VRFY((NULL != read_buf), "HDcalloc succeeded"); + + VRFY((H5Dread(dset_id, memtype, memspace, filespace, plist_id, read_buf) >= 0), + "Dataset read succeeded"); + + global_buf = (COMPOUND_C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != global_buf), "HDcalloc succeeded"); + + /* Collect each piece of data from all ranks into a global buffer on all ranks */ + recvcounts = (int *) HDcalloc(1, (size_t) mpi_size * sizeof(*recvcounts)); + VRFY((NULL != recvcounts), "HDcalloc succeeded"); + + for (i = 0; i < (size_t) mpi_size; i++) + recvcounts[i] = (int) (flat_dims[0] * sizeof(*read_buf)); + + displs = (int *) HDcalloc(1, (size_t) mpi_size * sizeof(*displs)); + VRFY((NULL != displs), "HDcalloc succeeded"); + + for (i = 0; i < (size_t) mpi_size; i++) + displs[i] = (int) (i * flat_dims[0] * sizeof(*read_buf)); + + VRFY((MPI_SUCCESS == MPI_Allgatherv(read_buf, (int) (flat_dims[0] * sizeof(COMPOUND_C_DATATYPE)), MPI_BYTE, global_buf, recvcounts, displs, MPI_BYTE, comm)), + "MPI_Allgatherv succeeded"); + + VRFY((0 == memcmp(global_buf, correct_buf, correct_buf_size)), + "Data verification succeeded"); + + if (displs) HDfree(displs); + if (recvcounts) HDfree(recvcounts); + if (global_buf) HDfree(global_buf); + if (read_buf) HDfree(read_buf); + if (correct_buf) HDfree(correct_buf); + + VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); + VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); + VRFY((H5Sclose(memspace) >= 0), "Memory dataspace close succeeded"); + VRFY((H5Tclose(memtype) >= 0), "Memory datatype close succeeded"); + VRFY((H5Pclose(plist_id) >= 0), "DXPL close succeeded"); + VRFY((H5Fclose(file_id) >= 0), "File close succeeded"); + + return; +} + +/* + * Tests parallel read of filtered data from unshared + * chunks using a compound datatype which requires a + * datatype conversion. + * + * The MAINPROCESS rank will first write out all of the + * data to the dataset. Then, each rank reads a part of + * the dataset and contributes its piece to a global + * buffer that is checked for consistency. + * + * Programmer: Jordan Henderson + * 05/17/2018 + */ +static void +test_read_cmpd_filtered_dataset_type_conversion_unshared(void) +{ + COMPOUND_C_DATATYPE *read_buf = NULL; + COMPOUND_C_DATATYPE *correct_buf = NULL; + COMPOUND_C_DATATYPE *global_buf = NULL; + hsize_t dataset_dims[READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_DIMS]; + hsize_t chunk_dims[READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_DIMS]; + hsize_t sel_dims[READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_DIMS]; + hsize_t start[READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_DIMS]; + hsize_t stride[READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_DIMS]; + hsize_t count[READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_DIMS]; + hsize_t block[READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_DIMS]; + hsize_t flat_dims[1]; + size_t i, read_buf_size, correct_buf_size; + hid_t file_id = -1, dset_id = -1, plist_id = -1, filetype = -1, memtype = -1; + hid_t filespace = -1, memspace = -1; + int *recvcounts = NULL; + int *displs = NULL; + + dataset_dims[0] = (hsize_t) READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_NROWS; + dataset_dims[1] = (hsize_t) READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_NCOLS; + + /* Setup the buffer for writing and for comparison */ + correct_buf_size = dataset_dims[0] * dataset_dims[1] * sizeof(*correct_buf); + + correct_buf = (COMPOUND_C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != correct_buf), "HDcalloc succeeded"); + + for (i = 0; i < correct_buf_size / sizeof(*correct_buf); i++) { + correct_buf[i].field1 = (short) ( + (i % dataset_dims[1]) + + (i / dataset_dims[1]) + ); + + correct_buf[i].field2 = (int) ( + (i % dataset_dims[1]) + + (i / dataset_dims[1]) + ); + + correct_buf[i].field3 = (long) ( + (i % dataset_dims[1]) + + (i / dataset_dims[1]) + ); + } + + /* Create the compound type for memory. */ + memtype = H5Tcreate(H5T_COMPOUND, sizeof(COMPOUND_C_DATATYPE)); + VRFY((memtype >= 0), "Datatype creation succeeded"); + + VRFY((H5Tinsert(memtype, "ShortData", HOFFSET(COMPOUND_C_DATATYPE, field1), H5T_NATIVE_SHORT) >= 0), + "Datatype insertion succeeded"); + VRFY((H5Tinsert(memtype, "IntData", HOFFSET(COMPOUND_C_DATATYPE, field2), H5T_NATIVE_INT) >= 0), + "Datatype insertion succeeded"); + VRFY((H5Tinsert(memtype, "LongData", HOFFSET(COMPOUND_C_DATATYPE, field3), H5T_NATIVE_LONG) >= 0), + "Datatype insertion succeeded"); + + /* Create the compound type for file. */ + filetype = H5Tcreate(H5T_COMPOUND, 32); + VRFY((filetype >= 0), "Datatype creation succeeded"); + + VRFY((H5Tinsert(filetype, "ShortData", 0, H5T_STD_I64BE) >= 0), + "Datatype insertion succeeded"); + VRFY((H5Tinsert(filetype, "IntData", 8, H5T_STD_I64BE) >= 0), + "Datatype insertion succeeded"); + VRFY((H5Tinsert(filetype, "LongData", 16, H5T_STD_I64BE) >= 0), + "Datatype insertion succeeded"); + + if (MAINPROCESS) { + puts("Testing read from unshared filtered chunks in Compound Datatype dataset with Datatype conversion"); + + plist_id = H5Pcreate(H5P_FILE_ACCESS); + VRFY((plist_id >= 0), "FAPL creation succeeded"); + + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); + + file_id = H5Fopen(filenames[0], H5F_ACC_RDWR, plist_id); + VRFY((file_id >= 0), "Test file open succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); + + /* Create the dataspace for the dataset */ + filespace = H5Screate_simple(READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_DIMS, dataset_dims, NULL); + VRFY((filespace >= 0), "File dataspace creation succeeded"); + + /* Create chunked dataset */ + chunk_dims[0] = READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_CH_NROWS; + chunk_dims[1] = READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_CH_NCOLS; + + plist_id = H5Pcreate(H5P_DATASET_CREATE); + VRFY((plist_id >= 0), "DCPL creation succeeded"); + + VRFY((H5Pset_chunk(plist_id, READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_DIMS, chunk_dims) >= 0), + "Chunk size set"); + + /* Add test filter to the pipeline */ + VRFY((set_dcpl_filter(plist_id) >= 0), "Filter set"); + + dset_id = H5Dcreate2(file_id, READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_NAME, filetype, filespace, + H5P_DEFAULT, plist_id, H5P_DEFAULT); + VRFY((dset_id >= 0), "Dataset creation succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "DCPL close succeeded"); + VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); + + VRFY((H5Dwrite(dset_id, memtype, H5S_ALL, H5S_ALL, H5P_DEFAULT, correct_buf) >= 0), + "Dataset write succeeded"); + + VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); + VRFY((H5Fclose(file_id) >= 0), "File close succeeded"); + } + + /* Set up file access property list with parallel I/O access */ + plist_id = H5Pcreate(H5P_FILE_ACCESS); + VRFY((plist_id >= 0), "FAPL creation succeeded"); + + VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), + "Set FAPL MPIO succeeded"); + + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); + + file_id = H5Fopen(filenames[0], H5F_ACC_RDONLY, plist_id); + VRFY((file_id >= 0), "Test file open succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); + + dset_id = H5Dopen2(file_id, "/" READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_NAME, H5P_DEFAULT); + VRFY((dset_id >= 0), "Dataset open succeeded"); + + sel_dims[0] = (hsize_t) READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_CH_NROWS; + sel_dims[1] = (hsize_t) READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_ENTRIES_PER_PROC; + + /* Setup one-dimensional memory dataspace for reading the dataset data into a contiguous buffer */ + flat_dims[0] = sel_dims[0] * sel_dims[1]; + + memspace = H5Screate_simple(1, flat_dims, NULL); + VRFY((memspace >= 0), "Memory dataspace creation succeeded"); + + /* Select hyperslab in the file */ + filespace = H5Dget_space(dset_id); + VRFY((filespace >= 0), "File dataspace retrieval succeeded"); + + /* + * Each process defines the dataset selection in the file and + * reads it to the selection in memory + */ + count[0] = 1; + count[1] = (hsize_t) READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_ENTRIES_PER_PROC; + stride[0] = READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_CH_NROWS; + stride[1] = READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_CH_NCOLS; + block[0] = READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_CH_NROWS; + block[1] = READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_CH_NCOLS; + start[0] = 0; + start[1] = ((hsize_t) mpi_rank * READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_CH_NCOLS); + + if (VERBOSE_MED) { + printf("Process %d is reading with count[ %llu, %llu ], stride[ %llu, %llu ], start[ %llu, %llu ], block size[ %llu, %llu ]\n", + mpi_rank, count[0], count[1], stride[0], stride[1], start[0], start[1], block[0], block[1]); + fflush(stdout); + } + + VRFY((H5Sselect_hyperslab(filespace, H5S_SELECT_SET, start, stride, count, block) >= 0), + "Hyperslab selection succeeded"); + + /* Create property list for collective dataset read */ + plist_id = H5Pcreate(H5P_DATASET_XFER); + VRFY((plist_id >= 0), "DXPL creation succeeded"); + + VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), + "Set DXPL MPIO succeeded"); + + read_buf_size = flat_dims[0] * sizeof(*read_buf); + + read_buf = (COMPOUND_C_DATATYPE *) HDcalloc(1, read_buf_size); + VRFY((NULL != read_buf), "HDcalloc succeeded"); + + VRFY((H5Dread(dset_id, memtype, memspace, filespace, plist_id, read_buf) >= 0), + "Dataset read succeeded"); + + global_buf = (COMPOUND_C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != global_buf), "HDcalloc succeeded"); + + /* Collect each piece of data from all ranks into a global buffer on all ranks */ + recvcounts = (int *) HDcalloc(1, (size_t) mpi_size * sizeof(*recvcounts)); + VRFY((NULL != recvcounts), "HDcalloc succeeded"); + + for (i = 0; i < (size_t) mpi_size; i++) + recvcounts[i] = (int) (flat_dims[0] * sizeof(*read_buf)); + + displs = (int *) HDcalloc(1, (size_t) mpi_size * sizeof(*displs)); + VRFY((NULL != displs), "HDcalloc succeeded"); + + for (i = 0; i < (size_t) mpi_size; i++) + displs[i] = (int) (i * flat_dims[0] * sizeof(*read_buf)); + + VRFY((MPI_SUCCESS == MPI_Allgatherv(read_buf, (int) (flat_dims[0] * sizeof(COMPOUND_C_DATATYPE)), MPI_BYTE, global_buf, recvcounts, displs, MPI_BYTE, comm)), + "MPI_Allgatherv succeeded"); + + VRFY((0 == memcmp(global_buf, correct_buf, correct_buf_size)), + "Data verification succeeded"); + + if (displs) HDfree(displs); + if (recvcounts) HDfree(recvcounts); + if (global_buf) HDfree(global_buf); + if (read_buf) HDfree(read_buf); + if (correct_buf) HDfree(correct_buf); + + VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); + VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); + VRFY((H5Sclose(memspace) >= 0), "Memory dataspace close succeeded"); + VRFY((H5Tclose(filetype) >= 0), "File datatype close succeeded"); + VRFY((H5Tclose(memtype) >= 0), "Memory datatype close succeeded"); + VRFY((H5Pclose(plist_id) >= 0), "DXPL close succeeded"); + VRFY((H5Fclose(file_id) >= 0), "File close succeeded"); + + return; +} + +/* + * Tests parallel read of filtered data from shared + * chunks using a compound datatype which requires + * a datatype conversion. + * + * The MAINPROCESS rank will first write out all of the + * data to the dataset. Then, each rank reads a part of + * each chunk of the dataset and contributes its pieces + * to a global buffer that is checked for consistency. + * + * Programmer: Jordan Henderson + * 05/17/2018 + */ +static void +test_read_cmpd_filtered_dataset_type_conversion_shared(void) +{ + COMPOUND_C_DATATYPE *read_buf = NULL; + COMPOUND_C_DATATYPE *correct_buf = NULL; + COMPOUND_C_DATATYPE *global_buf = NULL; + hsize_t dataset_dims[READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_DIMS]; + hsize_t chunk_dims[READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_DIMS]; + hsize_t sel_dims[READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_DIMS]; + hsize_t start[READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_DIMS]; + hsize_t stride[READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_DIMS]; + hsize_t count[READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_DIMS]; + hsize_t block[READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_DIMS]; + hsize_t flat_dims[1]; + size_t i, read_buf_size, correct_buf_size; + hid_t file_id, dset_id, plist_id, filetype, memtype; + hid_t filespace, memspace; + int *recvcounts = NULL; + int *displs = NULL; + + dataset_dims[0] = (hsize_t) READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_NROWS; + dataset_dims[1] = (hsize_t) READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_NCOLS; + + /* Setup the buffer for writing and for comparison */ + correct_buf_size = dataset_dims[0] * dataset_dims[1] * sizeof(*correct_buf); + + correct_buf = (COMPOUND_C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != correct_buf), "HDcalloc succeeded"); + + for (i = 0; i < correct_buf_size / sizeof(*correct_buf); i++) { + correct_buf[i].field1 = (short) ( + (dataset_dims[1] * (i / ((hsize_t) mpi_size * dataset_dims[1]))) + + (i % dataset_dims[1]) + + (((i % ((hsize_t) mpi_size * dataset_dims[1])) / dataset_dims[1]) % dataset_dims[1]) + ); + + correct_buf[i].field2 = (int) ( + (dataset_dims[1] * (i / ((hsize_t) mpi_size * dataset_dims[1]))) + + (i % dataset_dims[1]) + + (((i % ((hsize_t) mpi_size * dataset_dims[1])) / dataset_dims[1]) % dataset_dims[1]) + ); + + correct_buf[i].field3 = (long) ( + (dataset_dims[1] * (i / ((hsize_t) mpi_size * dataset_dims[1]))) + + (i % dataset_dims[1]) + + (((i % ((hsize_t) mpi_size * dataset_dims[1])) / dataset_dims[1]) % dataset_dims[1]) + ); + } + + /* Create the compound type for memory. */ + memtype = H5Tcreate(H5T_COMPOUND, sizeof(COMPOUND_C_DATATYPE)); + VRFY((memtype >= 0), "Datatype creation succeeded"); + + VRFY((H5Tinsert(memtype, "ShortData", HOFFSET(COMPOUND_C_DATATYPE, field1), H5T_NATIVE_SHORT) >= 0), + "Datatype insertion succeeded"); + VRFY((H5Tinsert(memtype, "IntData", HOFFSET(COMPOUND_C_DATATYPE, field2), H5T_NATIVE_INT) >= 0), + "Datatype insertion succeeded"); + VRFY((H5Tinsert(memtype, "LongData", HOFFSET(COMPOUND_C_DATATYPE, field3), H5T_NATIVE_LONG) >= 0), + "Datatype insertion succeeded"); + + /* Create the compound type for file. */ + filetype = H5Tcreate(H5T_COMPOUND, 32); + VRFY((filetype >= 0), "Datatype creation succeeded"); + + VRFY((H5Tinsert(filetype, "ShortData", 0, H5T_STD_I64BE) >= 0), + "Datatype insertion succeeded"); + VRFY((H5Tinsert(filetype, "IntData", 8, H5T_STD_I64BE) >= 0), + "Datatype insertion succeeded"); + VRFY((H5Tinsert(filetype, "LongData", 16, H5T_STD_I64BE) >= 0), + "Datatype insertion succeeded"); + + if (MAINPROCESS) { + puts("Testing read from shared filtered chunks in Compound Datatype dataset with Datatype conversion"); + + plist_id = H5Pcreate(H5P_FILE_ACCESS); + VRFY((plist_id >= 0), "FAPL creation succeeded"); + + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); + + file_id = H5Fopen(filenames[0], H5F_ACC_RDWR, plist_id); + VRFY((file_id >= 0), "Test file open succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); + + /* Create the dataspace for the dataset */ + filespace = H5Screate_simple(READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_DIMS, dataset_dims, NULL); + VRFY((filespace >= 0), "File dataspace creation succeeded"); + + /* Create chunked dataset */ + chunk_dims[0] = (hsize_t) READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_CH_NROWS; + chunk_dims[1] = (hsize_t) READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_CH_NCOLS; + + plist_id = H5Pcreate(H5P_DATASET_CREATE); + VRFY((plist_id >= 0), "DCPL creation succeeded"); + + VRFY((H5Pset_chunk(plist_id, READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_DIMS, chunk_dims) >= 0), + "Chunk size set"); + + /* Add test filter to the pipeline */ + VRFY((set_dcpl_filter(plist_id) >= 0), "Filter set"); + + dset_id = H5Dcreate2(file_id, READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_NAME, filetype, filespace, + H5P_DEFAULT, plist_id, H5P_DEFAULT); + VRFY((dset_id >= 0), "Dataset creation succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "DCPL close succeeded"); + VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); + + VRFY((H5Dwrite(dset_id, memtype, H5S_ALL, H5S_ALL, H5P_DEFAULT, correct_buf) >= 0), + "Dataset write succeeded"); + + VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); + VRFY((H5Fclose(file_id) >= 0), "File close succeeded"); + } + + /* Set up file access property list with parallel I/O access */ + plist_id = H5Pcreate(H5P_FILE_ACCESS); + VRFY((plist_id >= 0), "FAPL creation succeeded"); + + VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), + "Set FAPL MPIO succeeded"); + + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); + + file_id = H5Fopen(filenames[0], H5F_ACC_RDONLY, plist_id); + VRFY((file_id >= 0), "Test file open succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); + + dset_id = H5Dopen2(file_id, "/" READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_NAME, H5P_DEFAULT); + VRFY((dset_id >= 0), "Dataset open succeeded"); + + sel_dims[0] = (hsize_t) READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_CH_NROWS / (hsize_t) mpi_size; + sel_dims[1] = (hsize_t) READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_ENTRIES_PER_PROC; + + /* Setup one-dimensional memory dataspace for reading the dataset data into a contiguous buffer */ + flat_dims[0] = sel_dims[0] * sel_dims[1]; + + memspace = H5Screate_simple(1, flat_dims, NULL); + VRFY((memspace >= 0), "Memory dataspace creation succeeded"); + + /* Select hyperslab in the file */ + filespace = H5Dget_space(dset_id); + VRFY((filespace >= 0), "File dataspace retrieval succeeded"); + + /* + * Each process defines the dataset selection in the file and + * reads it to the selection in memory + */ + count[0] = 1; + count[1] = (hsize_t) READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_ENTRIES_PER_PROC; + stride[0] = (hsize_t) READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_CH_NROWS; + stride[1] = READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_CH_NCOLS; + block[0] = (hsize_t) READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_CH_NROWS / (hsize_t) mpi_size; + block[1] = READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_CH_NCOLS; + start[0] = (hsize_t) mpi_rank; + start[1] = 0; + + if (VERBOSE_MED) { + printf("Process %d is reading with count[ %llu, %llu ], stride[ %llu, %llu ], start[ %llu, %llu ], block size[ %llu, %llu ]\n", + mpi_rank, count[0], count[1], stride[0], stride[1], start[0], start[1], block[0], block[1]); + fflush(stdout); + } + + VRFY((H5Sselect_hyperslab(filespace, H5S_SELECT_SET, start, stride, count, block) >= 0), + "Hyperslab selection succeeded"); + + /* Create property list for collective dataset read */ + plist_id = H5Pcreate(H5P_DATASET_XFER); + VRFY((plist_id >= 0), "DXPL creation succeeded"); + + VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), + "Set DXPL MPIO succeeded"); + + read_buf_size = flat_dims[0] * sizeof(*read_buf); + + read_buf = (COMPOUND_C_DATATYPE *) HDcalloc(1, read_buf_size); + VRFY((NULL != read_buf), "HDcalloc succeeded"); + + VRFY((H5Dread(dset_id, memtype, memspace, filespace, plist_id, read_buf) >= 0), + "Dataset read succeeded"); + + global_buf = (COMPOUND_C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != global_buf), "HDcalloc succeeded"); + + /* Collect each piece of data from all ranks into a global buffer on all ranks */ + recvcounts = (int *) HDcalloc(1, (size_t) mpi_size * sizeof(*recvcounts)); + VRFY((NULL != recvcounts), "HDcalloc succeeded"); + + for (i = 0; i < (size_t) mpi_size; i++) + recvcounts[i] = (int) (flat_dims[0] * sizeof(*read_buf)); + + displs = (int *) HDcalloc(1, (size_t) mpi_size * sizeof(*displs)); + VRFY((NULL != displs), "HDcalloc succeeded"); + + for (i = 0; i < (size_t) mpi_size; i++) + displs[i] = (int) (i * flat_dims[0] * sizeof(*read_buf)); + + VRFY((MPI_SUCCESS == MPI_Allgatherv(read_buf, (int) (flat_dims[0] * sizeof(COMPOUND_C_DATATYPE)), MPI_BYTE, global_buf, recvcounts, displs, MPI_BYTE, comm)), + "MPI_Allgatherv succeeded"); + + VRFY((0 == memcmp(global_buf, correct_buf, correct_buf_size)), + "Data verification succeeded"); + + if (displs) HDfree(displs); + if (recvcounts) HDfree(recvcounts); + if (global_buf) HDfree(global_buf); + if (read_buf) HDfree(read_buf); + if (correct_buf) HDfree(correct_buf); + + VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); + VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); + VRFY((H5Sclose(memspace) >= 0), "Memory dataspace close succeeded"); + VRFY((H5Tclose(memtype) >= 0), "Memory datatype close succeeded"); + VRFY((H5Pclose(plist_id) >= 0), "DXPL close succeeded"); + VRFY((H5Fclose(file_id) >= 0), "File close succeeded"); + + return; +} + +/* * Tests write of filtered data to a dataset * by a single process. After the write has * succeeded, the dataset is closed and then @@ -2139,7 +5427,8 @@ test_write_serial_read_parallel(void) plist_id = H5Pcreate(H5P_FILE_ACCESS); VRFY((plist_id >= 0), "FAPL creation succeeded"); - VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), "Set libver bounds succeeded"); + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); file_id = H5Fopen(filenames[0], H5F_ACC_RDWR, plist_id); VRFY((file_id >= 0), "Test file open succeeded"); @@ -2158,10 +5447,11 @@ test_write_serial_read_parallel(void) plist_id = H5Pcreate(H5P_DATASET_CREATE); VRFY((plist_id >= 0), "DCPL creation succeeded"); - VRFY((H5Pset_chunk(plist_id, WRITE_SERIAL_READ_PARALLEL_DATASET_DIMS, chunk_dims) >= 0), "Chunk size set"); + VRFY((H5Pset_chunk(plist_id, WRITE_SERIAL_READ_PARALLEL_DATASET_DIMS, chunk_dims) >= 0), + "Chunk size set"); /* Add test filter to the pipeline */ - VRFY((SET_FILTER(plist_id) >= 0), "Filter set"); + VRFY((set_dcpl_filter(plist_id) >= 0), "Filter set"); dset_id = H5Dcreate2(file_id, WRITE_SERIAL_READ_PARALLEL_DATASET_NAME, HDF5_DATATYPE_NAME, filespace, H5P_DEFAULT, plist_id, H5P_DEFAULT); @@ -2172,15 +5462,16 @@ test_write_serial_read_parallel(void) data_size = dataset_dims[0] * dataset_dims[1] * dataset_dims[2] * sizeof(*data); - data = (C_DATATYPE *) calloc(1, data_size); - VRFY((NULL != data), "calloc succeeded"); + data = (C_DATATYPE *) HDcalloc(1, data_size); + VRFY((NULL != data), "HDcalloc succeeded"); for (i = 0; i < data_size / sizeof(*data); i++) data[i] = (C_DATATYPE) GEN_DATA(i); - VRFY((H5Dwrite(dset_id, HDF5_DATATYPE_NAME, H5S_ALL, H5S_ALL, H5P_DEFAULT, data) >= 0), "Dataset write succeeded"); + VRFY((H5Dwrite(dset_id, HDF5_DATATYPE_NAME, H5S_ALL, H5S_ALL, H5P_DEFAULT, data) >= 0), + "Dataset write succeeded"); - if (data) free(data); + if (data) HDfree(data); VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); VRFY((H5Fclose(file_id) >= 0), "File close succeeded"); @@ -2188,11 +5479,11 @@ test_write_serial_read_parallel(void) correct_buf_size = dataset_dims[0] * dataset_dims[1] * dataset_dims[2] * sizeof(*correct_buf); - correct_buf = (C_DATATYPE *) calloc(1, correct_buf_size); - VRFY((NULL != correct_buf), "calloc succeeded"); + correct_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != correct_buf), "HDcalloc succeeded"); - read_buf = (C_DATATYPE *) calloc(1, correct_buf_size); - VRFY((NULL != read_buf), "calloc succeeded"); + read_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != read_buf), "HDcalloc succeeded"); for (i = 0; i < correct_buf_size / sizeof(*correct_buf); i++) correct_buf[i] = (long) i; @@ -2201,9 +5492,11 @@ test_write_serial_read_parallel(void) plist_id = H5Pcreate(H5P_FILE_ACCESS); VRFY((plist_id >= 0), "FAPL creation succeeded"); - VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), "Set FAPL MPIO succeeded"); + VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), + "Set FAPL MPIO succeeded"); - VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), "Set libver bounds succeeded"); + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); file_id = H5Fopen(filenames[0], H5F_ACC_RDWR, plist_id); VRFY((file_id >= 0), "Test file open succeeded"); @@ -2216,14 +5509,17 @@ test_write_serial_read_parallel(void) plist_id = H5Pcreate(H5P_DATASET_XFER); VRFY((plist_id >= 0), "DXPL creation succeeded"); - VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), "Set DXPL MPIO succeeded"); + VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), + "Set DXPL MPIO succeeded"); - VRFY((H5Dread(dset_id, HDF5_DATATYPE_NAME, H5S_ALL, H5S_ALL, plist_id, read_buf) >= 0), "Dataset read succeeded"); + VRFY((H5Dread(dset_id, HDF5_DATATYPE_NAME, H5S_ALL, H5S_ALL, plist_id, read_buf) >= 0), + "Dataset read succeeded"); - VRFY((0 == memcmp(read_buf, correct_buf, correct_buf_size)), "Data verification succeeded"); + VRFY((0 == memcmp(read_buf, correct_buf, correct_buf_size)), + "Data verification succeeded"); - if (correct_buf) free(correct_buf); - if (read_buf) free(read_buf); + if (correct_buf) HDfree(correct_buf); + if (read_buf) HDfree(read_buf); VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); VRFY((H5Pclose(plist_id) >= 0), "DXPL close succeeded"); @@ -2265,9 +5561,11 @@ test_write_parallel_read_serial(void) plist_id = H5Pcreate(H5P_FILE_ACCESS); VRFY((plist_id >= 0), "FAPL creation succeeded"); - VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), "Set FAPL MPIO succeeded"); + VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), + "Set FAPL MPIO succeeded"); - VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), "Set libver bounds succeeded"); + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); file_id = H5Fopen(filenames[0], H5F_ACC_RDWR, plist_id); VRFY((file_id >= 0), "Test file open succeeded"); @@ -2278,12 +5576,12 @@ test_write_parallel_read_serial(void) dataset_dims[0] = (hsize_t) WRITE_PARALLEL_READ_SERIAL_NROWS; dataset_dims[1] = (hsize_t) WRITE_PARALLEL_READ_SERIAL_NCOLS; dataset_dims[2] = (hsize_t) WRITE_PARALLEL_READ_SERIAL_DEPTH; - chunk_dims[0] = (hsize_t) WRITE_PARALLEL_READ_SERIAL_CH_NROWS; - chunk_dims[1] = (hsize_t) WRITE_PARALLEL_READ_SERIAL_CH_NCOLS; - chunk_dims[2] = 1; - sel_dims[0] = (hsize_t) WRITE_PARALLEL_READ_SERIAL_CH_NROWS; - sel_dims[1] = (hsize_t) WRITE_PARALLEL_READ_SERIAL_NCOLS; - sel_dims[2] = (hsize_t) WRITE_PARALLEL_READ_SERIAL_DEPTH; + chunk_dims[0] = (hsize_t) WRITE_PARALLEL_READ_SERIAL_CH_NROWS; + chunk_dims[1] = (hsize_t) WRITE_PARALLEL_READ_SERIAL_CH_NCOLS; + chunk_dims[2] = 1; + sel_dims[0] = (hsize_t) WRITE_PARALLEL_READ_SERIAL_CH_NROWS; + sel_dims[1] = (hsize_t) WRITE_PARALLEL_READ_SERIAL_NCOLS; + sel_dims[2] = (hsize_t) WRITE_PARALLEL_READ_SERIAL_DEPTH; filespace = H5Screate_simple(WRITE_PARALLEL_READ_SERIAL_DATASET_DIMS, dataset_dims, NULL); VRFY((filespace >= 0), "File dataspace creation succeeded"); @@ -2295,10 +5593,11 @@ test_write_parallel_read_serial(void) plist_id = H5Pcreate(H5P_DATASET_CREATE); VRFY((plist_id >= 0), "DCPL creation succeeded"); - VRFY((H5Pset_chunk(plist_id, WRITE_PARALLEL_READ_SERIAL_DATASET_DIMS, chunk_dims) >= 0), "Chunk size set"); + VRFY((H5Pset_chunk(plist_id, WRITE_PARALLEL_READ_SERIAL_DATASET_DIMS, chunk_dims) >= 0), + "Chunk size set"); /* Add test filter to the pipeline */ - VRFY((SET_FILTER(plist_id) >= 0), "Filter set"); + VRFY((set_dcpl_filter(plist_id) >= 0), "Filter set"); dset_id = H5Dcreate2(file_id, WRITE_PARALLEL_READ_SERIAL_DATASET_NAME, HDF5_DATATYPE_NAME, filespace, H5P_DEFAULT, plist_id, H5P_DEFAULT); @@ -2310,34 +5609,37 @@ test_write_parallel_read_serial(void) /* Each process defines the dataset selection in memory and writes * it to the hyperslab in the file */ - count[0] = 1; - count[1] = (hsize_t) WRITE_PARALLEL_READ_SERIAL_NCOLS / (hsize_t) WRITE_PARALLEL_READ_SERIAL_CH_NCOLS; - count[2] = (hsize_t) mpi_size; + count[0] = 1; + count[1] = (hsize_t) WRITE_PARALLEL_READ_SERIAL_NCOLS / (hsize_t) WRITE_PARALLEL_READ_SERIAL_CH_NCOLS; + count[2] = (hsize_t) mpi_size; stride[0] = (hsize_t) WRITE_PARALLEL_READ_SERIAL_CH_NROWS; stride[1] = (hsize_t) WRITE_PARALLEL_READ_SERIAL_CH_NCOLS; stride[2] = 1; - block[0] = (hsize_t) WRITE_PARALLEL_READ_SERIAL_CH_NROWS; - block[1] = (hsize_t) WRITE_PARALLEL_READ_SERIAL_CH_NCOLS; - block[2] = 1; + block[0] = (hsize_t) WRITE_PARALLEL_READ_SERIAL_CH_NROWS; + block[1] = (hsize_t) WRITE_PARALLEL_READ_SERIAL_CH_NCOLS; + block[2] = 1; offset[0] = ((hsize_t) mpi_rank * (hsize_t) WRITE_PARALLEL_READ_SERIAL_CH_NROWS * count[0]); offset[1] = 0; offset[2] = 0; - if (VERBOSE_MED) + if (VERBOSE_MED) { printf("Process %d is writing with count[ %llu, %llu, %llu ], stride[ %llu, %llu, %llu ], offset[ %llu, %llu, %llu ], block size[ %llu, %llu, %llu ]\n", - mpi_rank, count[0], count[1], count[2], stride[0], stride[1], stride[2], offset[0], offset[1], offset[2], block[0], block[1], block[2]); + mpi_rank, count[0], count[1], count[2], stride[0], stride[1], stride[2], offset[0], offset[1], offset[2], block[0], block[1], block[2]); + fflush(stdout); + } /* Select hyperslab in the file */ filespace = H5Dget_space(dset_id); VRFY((filespace >= 0), "File dataspace retrieval succeeded"); - VRFY((H5Sselect_hyperslab(filespace, H5S_SELECT_SET, offset, stride, count, block) >= 0), "Hyperslab selection succeeded"); + VRFY((H5Sselect_hyperslab(filespace, H5S_SELECT_SET, offset, stride, + count, block) >= 0), "Hyperslab selection succeeded"); /* Fill data buffer */ data_size = sel_dims[0] * sel_dims[1] * sel_dims[2] * sizeof(*data); - data = (C_DATATYPE *) calloc(1, data_size); - VRFY((NULL != data), "calloc succeeded"); + data = (C_DATATYPE *) HDcalloc(1, data_size); + VRFY((NULL != data), "HDcalloc succeeded"); for (i = 0; i < data_size / sizeof(*data); i++) data[i] = (C_DATATYPE) GEN_DATA(i); @@ -2346,11 +5648,13 @@ test_write_parallel_read_serial(void) plist_id = H5Pcreate(H5P_DATASET_XFER); VRFY((plist_id >= 0), "DXPL creation succeeded"); - VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), "Set DXPL MPIO succeeded"); + VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), + "Set DXPL MPIO succeeded"); - VRFY((H5Dwrite(dset_id, HDF5_DATATYPE_NAME, memspace, filespace, plist_id, data) >= 0), "Dataset write succeeded"); + VRFY((H5Dwrite(dset_id, HDF5_DATATYPE_NAME, memspace, filespace, plist_id, data) >= 0), + "Dataset write succeeded"); - if (data) free(data); + if (data) HDfree(data); VRFY((H5Pclose(plist_id) >= 0), "DXPL close succeeded"); VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); @@ -2362,7 +5666,8 @@ test_write_parallel_read_serial(void) plist_id = H5Pcreate(H5P_FILE_ACCESS); VRFY((plist_id >= 0), "FAPL creation succeeded"); - VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), "Set libver bounds succeeded"); + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); file_id = H5Fopen(filenames[0], H5F_ACC_RDWR, plist_id); VRFY((file_id >= 0), "Test file open succeeded"); @@ -2374,18 +5679,23 @@ test_write_parallel_read_serial(void) correct_buf_size = dataset_dims[0] * dataset_dims[1] * dataset_dims[2] * sizeof(*correct_buf); - correct_buf = (C_DATATYPE *) calloc(1, correct_buf_size); - VRFY((NULL != correct_buf), "calloc succeeded"); + correct_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != correct_buf), "HDcalloc succeeded"); - read_buf = (C_DATATYPE *) calloc(1, correct_buf_size); - VRFY((NULL != read_buf), "calloc succeeded"); + read_buf = (C_DATATYPE *) HDcalloc(1, correct_buf_size); + VRFY((NULL != read_buf), "HDcalloc succeeded"); for (i = 0; i < correct_buf_size / sizeof(*correct_buf); i++) - correct_buf[i] = (C_DATATYPE) ((i % (dataset_dims[0] * dataset_dims[1])) + (i / (dataset_dims[0] * dataset_dims[1])));; + correct_buf[i] = (C_DATATYPE) ( + (i % (dataset_dims[0] * dataset_dims[1])) + + (i / (dataset_dims[0] * dataset_dims[1])) + ); - VRFY((H5Dread(dset_id, HDF5_DATATYPE_NAME, H5S_ALL, H5S_ALL, H5P_DEFAULT, read_buf) >= 0), "Dataset read succeeded"); + VRFY((H5Dread(dset_id, HDF5_DATATYPE_NAME, H5S_ALL, H5S_ALL, H5P_DEFAULT, read_buf) >= 0), + "Dataset read succeeded"); - VRFY((0 == memcmp(read_buf, correct_buf, correct_buf_size)), "Data verification succeeded"); + VRFY((0 == memcmp(read_buf, correct_buf, correct_buf_size)), + "Data verification succeeded"); VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); VRFY((H5Fclose(file_id) >= 0), "File close succeeded"); @@ -2394,6 +5704,142 @@ test_write_parallel_read_serial(void) return; } +/* + * Tests that causing chunks to continually grow and shrink + * by writing random data followed by zeroed-out data (and + * thus controlling the compression ratio) does not cause + * problems. + * + * Programmer: Jordan Henderson + * 06/04/2018 + */ +static void +test_shrinking_growing_chunks(void) +{ + float *data = NULL; + hsize_t dataset_dims[SHRINKING_GROWING_CHUNKS_DATASET_DIMS]; + hsize_t chunk_dims[SHRINKING_GROWING_CHUNKS_DATASET_DIMS]; + hsize_t sel_dims[SHRINKING_GROWING_CHUNKS_DATASET_DIMS]; + hsize_t start[SHRINKING_GROWING_CHUNKS_DATASET_DIMS]; + hsize_t stride[SHRINKING_GROWING_CHUNKS_DATASET_DIMS]; + hsize_t count[SHRINKING_GROWING_CHUNKS_DATASET_DIMS]; + hsize_t block[SHRINKING_GROWING_CHUNKS_DATASET_DIMS]; + size_t i, data_size; + hid_t file_id = -1, dset_id = -1, plist_id = -1; + hid_t filespace = -1, memspace = -1; + + if (MAINPROCESS) puts("Testing continually shrinking/growing chunks"); + + /* Set up file access property list with parallel I/O access */ + plist_id = H5Pcreate(H5P_FILE_ACCESS); + VRFY((plist_id >= 0), "FAPL creation succeeded"); + + VRFY((H5Pset_fapl_mpio(plist_id, comm, info) >= 0), + "Set FAPL MPIO succeeded"); + + VRFY((H5Pset_libver_bounds(plist_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); + + file_id = H5Fopen(filenames[0], H5F_ACC_RDWR, plist_id); + VRFY((file_id >= 0), "Test file open succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "FAPL close succeeded"); + + /* Create the dataspace for the dataset */ + dataset_dims[0] = (hsize_t) SHRINKING_GROWING_CHUNKS_NROWS; + dataset_dims[1] = (hsize_t) SHRINKING_GROWING_CHUNKS_NCOLS; + chunk_dims[0] = (hsize_t) SHRINKING_GROWING_CHUNKS_CH_NROWS; + chunk_dims[1] = (hsize_t) SHRINKING_GROWING_CHUNKS_CH_NCOLS; + sel_dims[0] = (hsize_t) SHRINKING_GROWING_CHUNKS_CH_NROWS; + sel_dims[1] = (hsize_t) SHRINKING_GROWING_CHUNKS_NCOLS; + + filespace = H5Screate_simple(SHRINKING_GROWING_CHUNKS_DATASET_DIMS, dataset_dims, NULL); + VRFY((filespace >= 0), "File dataspace creation succeeded"); + + memspace = H5Screate_simple(SHRINKING_GROWING_CHUNKS_DATASET_DIMS, sel_dims, NULL); + VRFY((memspace >= 0), "Memory dataspace creation succeeded"); + + /* Create chunked dataset */ + plist_id = H5Pcreate(H5P_DATASET_CREATE); + VRFY((plist_id >= 0), "DCPL creation succeeded"); + + VRFY((H5Pset_chunk(plist_id, SHRINKING_GROWING_CHUNKS_DATASET_DIMS, chunk_dims) >= 0), + "Chunk size set"); + + /* Add test filter to the pipeline */ + VRFY((set_dcpl_filter(plist_id) >= 0), "Filter set"); + + dset_id = H5Dcreate2(file_id, SHRINKING_GROWING_CHUNKS_DATASET_NAME, H5T_NATIVE_DOUBLE, filespace, + H5P_DEFAULT, plist_id, H5P_DEFAULT); + VRFY((dset_id >= 0), "Dataset creation succeeded"); + + VRFY((H5Pclose(plist_id) >= 0), "DCPL close succeeded"); + VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); + + /* + * Each process defines the dataset selection in memory and writes + * it to the hyperslab in the file + */ + count[0] = 1; + count[1] = (hsize_t) SHRINKING_GROWING_CHUNKS_NCOLS / (hsize_t) SHRINKING_GROWING_CHUNKS_CH_NCOLS; + stride[0] = (hsize_t) SHRINKING_GROWING_CHUNKS_CH_NROWS; + stride[1] = (hsize_t) SHRINKING_GROWING_CHUNKS_CH_NCOLS; + block[0] = (hsize_t) SHRINKING_GROWING_CHUNKS_CH_NROWS; + block[1] = (hsize_t) SHRINKING_GROWING_CHUNKS_CH_NCOLS; + start[0] = ((hsize_t) mpi_rank * (hsize_t) SHRINKING_GROWING_CHUNKS_CH_NROWS * count[0]); + start[1] = 0; + + if (VERBOSE_MED) { + printf("Process %d is writing with count[ %llu, %llu ], stride[ %llu, %llu ], start[ %llu, %llu ], block size[ %llu, %llu ]\n", + mpi_rank, count[0], count[1], stride[0], stride[1], start[0], start[1], block[0], block[1]); + fflush(stdout); + } + + /* Select hyperslab in the file */ + filespace = H5Dget_space(dset_id); + VRFY((dset_id >= 0), "File dataspace retrieval succeeded"); + + VRFY((H5Sselect_hyperslab(filespace, H5S_SELECT_SET, start, stride, count, block) >= 0), + "Hyperslab selection succeeded"); + + /* Create property list for collective dataset write */ + plist_id = H5Pcreate(H5P_DATASET_XFER); + VRFY((plist_id >= 0), "DXPL creation succeeded"); + + VRFY((H5Pset_dxpl_mpio(plist_id, H5FD_MPIO_COLLECTIVE) >= 0), + "Set DXPL MPIO succeeded"); + + data_size = sel_dims[0] * sel_dims[1] * sizeof(*data); + + data = (float *) HDcalloc(1, data_size); + VRFY((NULL != data), "HDcalloc succeeded"); + + for (i = 0; i < SHRINKING_GROWING_CHUNKS_NLOOPS; i++) { + /* Continually write random float data, followed by zeroed-out data */ + if ((i % 2)) + HDmemset(data, 0, data_size); + else { + size_t j; + for (j = 0; j < data_size / sizeof(*data); j++) { + data[j] = (float) ( rand() / (double) (RAND_MAX / (double) 1.0L) ); + } + } + + VRFY((H5Dwrite(dset_id, H5T_NATIVE_DOUBLE, memspace, filespace, plist_id, data) >= 0), + "Dataset write succeeded"); + } + + if (data) HDfree(data); + + VRFY((H5Dclose(dset_id) >= 0), "Dataset close succeeded"); + VRFY((H5Sclose(filespace) >= 0), "File dataspace close succeeded"); + VRFY((H5Sclose(memspace) >= 0), "Memory dataspace close succeeded"); + VRFY((H5Pclose(plist_id) >= 0), "DXPL close succeeded"); + VRFY((H5Fclose(file_id) >= 0), "File close succeeded"); + + return; +} + int main(int argc, char** argv) { @@ -2416,7 +5862,9 @@ main(int argc, char** argv) } if (H5dont_atexit() < 0) { - printf("Failed to turn off atexit processing. Continue.\n"); + if (MAINPROCESS) { + printf("Failed to turn off atexit processing. Continue.\n"); + } } H5open(); @@ -2437,19 +5885,59 @@ main(int argc, char** argv) VRFY((H5Pset_fapl_mpio(fapl, comm, info) >= 0), "Set FAPL MPIO succeeded"); - VRFY((H5Pset_libver_bounds(fapl, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), "Set libver bounds succeeded"); + VRFY((H5Pset_libver_bounds(fapl, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); + + VRFY((h5_fixname(FILENAME[0], fapl, filenames[0], sizeof(filenames[0])) != NULL), + "Test file name created"); + + file_id = H5Fcreate(filenames[0], H5F_ACC_TRUNC, H5P_DEFAULT, fapl); + VRFY((file_id >= 0), "Test file creation succeeded"); + + VRFY((H5Fclose(file_id) >= 0), "File close succeeded"); + + for (i = 0; i < ARRAY_SIZE(tests); i++) { + if (MPI_SUCCESS == (mpi_code = MPI_Barrier(comm))) { + (*tests[i])(); + } + else { + if (MAINPROCESS) MESG("MPI_Barrier failed"); + nerrors++; + } + } - VRFY((h5_fixname(FILENAME[0], fapl, filenames[0], sizeof(filenames[0])) != NULL), "Test file name created"); + /* + * Increment the filter index to switch to the checksum filter + * and re-run the tests. + */ + cur_filter_idx++; + + h5_clean_files(FILENAME, fapl); + + fapl = H5Pcreate(H5P_FILE_ACCESS); + VRFY((fapl >= 0), "FAPL creation succeeded"); + + VRFY((H5Pset_fapl_mpio(fapl, comm, info) >= 0), "Set FAPL MPIO succeeded"); + + VRFY((H5Pset_libver_bounds(fapl, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) >= 0), + "Set libver bounds succeeded"); file_id = H5Fcreate(filenames[0], H5F_ACC_TRUNC, H5P_DEFAULT, fapl); VRFY((file_id >= 0), "Test file creation succeeded"); VRFY((H5Fclose(file_id) >= 0), "File close succeeded"); + if (MAINPROCESS) { + printf("\n=================================================================\n"); + printf("Re-running Parallel Filters tests with Fletcher32 checksum filter\n"); + printf("=================================================================\n\n"); + } + for (i = 0; i < ARRAY_SIZE(tests); i++) { if (MPI_SUCCESS == (mpi_code = MPI_Barrier(comm))) { (*tests[i])(); - } else { + } + else { if (MAINPROCESS) MESG("MPI_Barrier failed"); nerrors++; } @@ -2461,7 +5949,9 @@ main(int argc, char** argv) exit: if (nerrors) - if (MAINPROCESS) printf("*** %d TEST ERROR%s OCCURRED ***\n", nerrors, nerrors > 1 ? "S" : ""); + if (MAINPROCESS) + printf("*** %d TEST ERROR%s OCCURRED ***\n", nerrors, + nerrors > 1 ? "S" : ""); ALARM_OFF; diff --git a/testpar/t_filters_parallel.h b/testpar/t_filters_parallel.h index cb9a1ab..9543508 100644 --- a/testpar/t_filters_parallel.h +++ b/testpar/t_filters_parallel.h @@ -43,77 +43,83 @@ size_t cd_nelmts = FILTER_NUM_CDVALUES; /* Common defines for all tests */ #define C_DATATYPE long +#define C_DATATYPE_MPI MPI_LONG #define COMPOUND_C_DATATYPE cmpd_filtered_t #define C_DATATYPE_STR(type) STRINGIFY(type) #define HDF5_DATATYPE_NAME H5T_NATIVE_LONG +/* Macro used to generate data for datasets for later verification */ #define GEN_DATA(i) INCREMENTAL_DATA(i) -#define INCREMENTAL_DATA(i) ((size_t) mpi_rank + i) /* Generates incremental test data */ /* For experimental purposes only, will cause tests to fail data verification phase - JTH */ /* #define GEN_DATA(i) RANK_DATA(i) */ /* Given an index value i, generates test data based upon selected mode */ -#define RANK_DATA(i) (mpi_rank) /* Generates test data to visibly show which rank wrote to which parts of the dataset */ -#ifdef DYNAMIC_FILTER -#define SET_FILTER(dcpl) H5Pset_filter(dcpl, filter_id, flags, FILTER_NUM_CDVALUES, cd_values) /* Test other filter in parallel */ -#else -#define SET_FILTER(dcpl) H5Pset_deflate(dcpl, 6) /* Test GZIP filter in parallel */ -#endif +#define INCREMENTAL_DATA(i) ((size_t) mpi_rank + i) /* Generates incremental test data */ +#define RANK_DATA(i) (mpi_rank) /* Generates test data to visibly show which rank wrote to which parts of the dataset */ + +#define DEFAULT_DEFLATE_LEVEL 6 #define DIM0_SCALE_FACTOR 4 #define DIM1_SCALE_FACTOR 2 -/* Defines for the one-chunk filtered dataset test */ -#define ONE_CHUNK_FILTERED_DATASET_NAME "one_chunk_filtered_dataset" -#define ONE_CHUNK_FILTERED_DATASET_DIMS 2 -#define ONE_CHUNK_FILTERED_DATASET_NROWS (mpi_size * DIM0_SCALE_FACTOR) /* Must be an even multiple of the number of ranks to avoid issues */ -#define ONE_CHUNK_FILTERED_DATASET_NCOLS (mpi_size * DIM1_SCALE_FACTOR) /* Must be an even multiple of the number of ranks to avoid issues */ -#define ONE_CHUNK_FILTERED_DATASET_CH_NROWS ONE_CHUNK_FILTERED_DATASET_NROWS -#define ONE_CHUNK_FILTERED_DATASET_CH_NCOLS ONE_CHUNK_FILTERED_DATASET_NCOLS +/* Struct type for the compound datatype filtered dataset tests */ +typedef struct { + short field1; + int field2; + long field3; +} COMPOUND_C_DATATYPE; + +/* Defines for the one-chunk filtered dataset write test */ +#define WRITE_ONE_CHUNK_FILTERED_DATASET_NAME "one_chunk_filtered_dataset_write" +#define WRITE_ONE_CHUNK_FILTERED_DATASET_DIMS 2 +#define WRITE_ONE_CHUNK_FILTERED_DATASET_NROWS (mpi_size * DIM0_SCALE_FACTOR) /* Must be an even multiple of the number of ranks to avoid issues */ +#define WRITE_ONE_CHUNK_FILTERED_DATASET_NCOLS (mpi_size * DIM1_SCALE_FACTOR) /* Must be an even multiple of the number of ranks to avoid issues */ +#define WRITE_ONE_CHUNK_FILTERED_DATASET_CH_NROWS WRITE_ONE_CHUNK_FILTERED_DATASET_NROWS +#define WRITE_ONE_CHUNK_FILTERED_DATASET_CH_NCOLS WRITE_ONE_CHUNK_FILTERED_DATASET_NCOLS /* Defines for the unshared filtered chunks write test */ -#define UNSHARED_FILTERED_CHUNKS_DATASET_NAME "unshared_filtered_chunks" -#define UNSHARED_FILTERED_CHUNKS_DATASET_DIMS 2 -#define UNSHARED_FILTERED_CHUNKS_NROWS (mpi_size * DIM0_SCALE_FACTOR) -#define UNSHARED_FILTERED_CHUNKS_NCOLS (mpi_size * DIM1_SCALE_FACTOR) -#define UNSHARED_FILTERED_CHUNKS_CH_NROWS (UNSHARED_FILTERED_CHUNKS_NROWS / mpi_size) -#define UNSHARED_FILTERED_CHUNKS_CH_NCOLS (UNSHARED_FILTERED_CHUNKS_NCOLS / mpi_size) +#define WRITE_UNSHARED_FILTERED_CHUNKS_DATASET_NAME "unshared_filtered_chunks_write" +#define WRITE_UNSHARED_FILTERED_CHUNKS_DATASET_DIMS 2 +#define WRITE_UNSHARED_FILTERED_CHUNKS_NROWS (mpi_size * DIM0_SCALE_FACTOR) +#define WRITE_UNSHARED_FILTERED_CHUNKS_NCOLS (mpi_size * DIM1_SCALE_FACTOR) +#define WRITE_UNSHARED_FILTERED_CHUNKS_CH_NROWS (WRITE_UNSHARED_FILTERED_CHUNKS_NROWS / mpi_size) +#define WRITE_UNSHARED_FILTERED_CHUNKS_CH_NCOLS (WRITE_UNSHARED_FILTERED_CHUNKS_NCOLS / mpi_size) /* Defines for the shared filtered chunks write test */ -#define SHARED_FILTERED_CHUNKS_DATASET_NAME "shared_filtered_chunks" -#define SHARED_FILTERED_CHUNKS_DATASET_DIMS 2 -#define SHARED_FILTERED_CHUNKS_CH_NROWS (mpi_size) -#define SHARED_FILTERED_CHUNKS_CH_NCOLS (mpi_size) -#define SHARED_FILTERED_CHUNKS_NROWS (SHARED_FILTERED_CHUNKS_CH_NROWS * DIM0_SCALE_FACTOR) -#define SHARED_FILTERED_CHUNKS_NCOLS (SHARED_FILTERED_CHUNKS_CH_NCOLS * DIM1_SCALE_FACTOR) +#define WRITE_SHARED_FILTERED_CHUNKS_DATASET_NAME "shared_filtered_chunks_write" +#define WRITE_SHARED_FILTERED_CHUNKS_DATASET_DIMS 2 +#define WRITE_SHARED_FILTERED_CHUNKS_CH_NROWS (mpi_size) +#define WRITE_SHARED_FILTERED_CHUNKS_CH_NCOLS (mpi_size) +#define WRITE_SHARED_FILTERED_CHUNKS_NROWS (WRITE_SHARED_FILTERED_CHUNKS_CH_NROWS * DIM0_SCALE_FACTOR) +#define WRITE_SHARED_FILTERED_CHUNKS_NCOLS (WRITE_SHARED_FILTERED_CHUNKS_CH_NCOLS * DIM1_SCALE_FACTOR) /* Defines for the filtered chunks write test where a process has no selection */ -#define SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_NAME "single_no_selection_filtered_chunks" -#define SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS 2 -#define SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NROWS (DIM0_SCALE_FACTOR) -#define SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NCOLS (DIM1_SCALE_FACTOR) -#define SINGLE_NO_SELECTION_FILTERED_CHUNKS_NROWS (SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NROWS * mpi_size) -#define SINGLE_NO_SELECTION_FILTERED_CHUNKS_NCOLS (SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NCOLS * mpi_size) -#define SINGLE_NO_SELECTION_FILTERED_CHUNKS_NO_SELECT_PROC (mpi_size - 1) +#define WRITE_SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_NAME "single_no_selection_filtered_chunks_write" +#define WRITE_SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS 2 +#define WRITE_SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NROWS (DIM0_SCALE_FACTOR) +#define WRITE_SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NCOLS (DIM1_SCALE_FACTOR) +#define WRITE_SINGLE_NO_SELECTION_FILTERED_CHUNKS_NROWS (WRITE_SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NROWS * mpi_size) +#define WRITE_SINGLE_NO_SELECTION_FILTERED_CHUNKS_NCOLS (WRITE_SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NCOLS * mpi_size) +#define WRITE_SINGLE_NO_SELECTION_FILTERED_CHUNKS_NO_SELECT_PROC (mpi_size - 1) /* Defines for the filtered chunks write test where no process has a selection */ -#define ALL_NO_SELECTION_FILTERED_CHUNKS_DATASET_NAME "all_no_selection_filtered_chunks" -#define ALL_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS 2 -#define ALL_NO_SELECTION_FILTERED_CHUNKS_CH_NROWS (DIM0_SCALE_FACTOR) -#define ALL_NO_SELECTION_FILTERED_CHUNKS_CH_NCOLS (DIM1_SCALE_FACTOR) -#define ALL_NO_SELECTION_FILTERED_CHUNKS_NROWS (ALL_NO_SELECTION_FILTERED_CHUNKS_CH_NROWS * mpi_size) -#define ALL_NO_SELECTION_FILTERED_CHUNKS_NCOLS (ALL_NO_SELECTION_FILTERED_CHUNKS_CH_NCOLS * mpi_size) +#define WRITE_ALL_NO_SELECTION_FILTERED_CHUNKS_DATASET_NAME "all_no_selection_filtered_chunks_write" +#define WRITE_ALL_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS 2 +#define WRITE_ALL_NO_SELECTION_FILTERED_CHUNKS_CH_NROWS (DIM0_SCALE_FACTOR) +#define WRITE_ALL_NO_SELECTION_FILTERED_CHUNKS_CH_NCOLS (DIM1_SCALE_FACTOR) +#define WRITE_ALL_NO_SELECTION_FILTERED_CHUNKS_NROWS (WRITE_ALL_NO_SELECTION_FILTERED_CHUNKS_CH_NROWS * mpi_size) +#define WRITE_ALL_NO_SELECTION_FILTERED_CHUNKS_NCOLS (WRITE_ALL_NO_SELECTION_FILTERED_CHUNKS_CH_NCOLS * mpi_size) /* Defines for the filtered chunks write test with a point selection */ -#define POINT_SELECTION_FILTERED_CHUNKS_DATASET_NAME "point_selection_filtered_chunks" -#define POINT_SELECTION_FILTERED_CHUNKS_DATASET_DIMS 2 -#define POINT_SELECTION_FILTERED_CHUNKS_CH_NROWS (DIM0_SCALE_FACTOR) -#define POINT_SELECTION_FILTERED_CHUNKS_CH_NCOLS (DIM1_SCALE_FACTOR) -#define POINT_SELECTION_FILTERED_CHUNKS_NROWS (POINT_SELECTION_FILTERED_CHUNKS_CH_NROWS * mpi_size) -#define POINT_SELECTION_FILTERED_CHUNKS_NCOLS (POINT_SELECTION_FILTERED_CHUNKS_CH_NCOLS * mpi_size) +#define WRITE_POINT_SELECTION_FILTERED_CHUNKS_DATASET_NAME "point_selection_filtered_chunks_write" +#define WRITE_POINT_SELECTION_FILTERED_CHUNKS_DATASET_DIMS 2 +#define WRITE_POINT_SELECTION_FILTERED_CHUNKS_CH_NROWS (DIM0_SCALE_FACTOR) +#define WRITE_POINT_SELECTION_FILTERED_CHUNKS_CH_NCOLS (DIM1_SCALE_FACTOR) +#define WRITE_POINT_SELECTION_FILTERED_CHUNKS_NROWS (WRITE_POINT_SELECTION_FILTERED_CHUNKS_CH_NROWS * mpi_size) +#define WRITE_POINT_SELECTION_FILTERED_CHUNKS_NCOLS (WRITE_POINT_SELECTION_FILTERED_CHUNKS_CH_NCOLS * mpi_size) /* Defines for the filtered dataset interleaved write test */ -#define INTERLEAVED_WRITE_FILTERED_DATASET_NAME "interleaved_write_filtered_dataset" +#define INTERLEAVED_WRITE_FILTERED_DATASET_NAME "filtered_dataset_interleaved_write" #define INTERLEAVED_WRITE_FILTERED_DATASET_DIMS 2 #define INTERLEAVED_WRITE_FILTERED_DATASET_CH_NROWS (mpi_size) #define INTERLEAVED_WRITE_FILTERED_DATASET_CH_NCOLS (DIM1_SCALE_FACTOR) @@ -121,75 +127,187 @@ size_t cd_nelmts = FILTER_NUM_CDVALUES; #define INTERLEAVED_WRITE_FILTERED_DATASET_NCOLS (INTERLEAVED_WRITE_FILTERED_DATASET_CH_NCOLS * DIM1_SCALE_FACTOR) /* Defines for the 3D unshared filtered dataset separate page write test */ -#define UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_NAME "3D_unshared_filtered_chunks_separate_pages" -#define UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_DIMS 3 -#define UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_NROWS (mpi_size * DIM0_SCALE_FACTOR) -#define UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_NCOLS (mpi_size * DIM1_SCALE_FACTOR) -#define UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DEPTH (mpi_size) -#define UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_CH_NROWS (UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_NROWS / mpi_size) -#define UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_CH_NCOLS (UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_NCOLS / mpi_size) +#define WRITE_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_NAME "3D_unshared_filtered_chunks_separate_pages_write" +#define WRITE_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_DIMS 3 +#define WRITE_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_NROWS (mpi_size * DIM0_SCALE_FACTOR) +#define WRITE_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_NCOLS (mpi_size * DIM1_SCALE_FACTOR) +#define WRITE_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DEPTH (mpi_size) +#define WRITE_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_CH_NROWS (WRITE_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_NROWS / mpi_size) +#define WRITE_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_CH_NCOLS (WRITE_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_NCOLS / mpi_size) /* Defines for the 3D unshared filtered dataset same page write test */ -#define UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_NAME "3D_unshared_filtered_chunks_same_pages" -#define UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_DIMS 3 -#define UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_NROWS (mpi_size * DIM0_SCALE_FACTOR) -#define UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_NCOLS (mpi_size * DIM1_SCALE_FACTOR) -#define UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DEPTH (mpi_size) -#define UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_CH_NROWS (UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_NROWS / mpi_size) -#define UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_CH_NCOLS (UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_NCOLS / mpi_size) +#define WRITE_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_NAME "3D_unshared_filtered_chunks_same_pages_write" +#define WRITE_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_DIMS 3 +#define WRITE_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_NROWS (mpi_size * DIM0_SCALE_FACTOR) +#define WRITE_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_NCOLS (mpi_size * DIM1_SCALE_FACTOR) +#define WRITE_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DEPTH (mpi_size) +#define WRITE_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_CH_NROWS (WRITE_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_NROWS / mpi_size) +#define WRITE_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_CH_NCOLS (WRITE_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_NCOLS / mpi_size) /* Defines for the 3d shared filtered dataset write test */ -#define SHARED_FILTERED_CHUNKS_3D_DATASET_NAME "3D_shared_filtered_chunks" -#define SHARED_FILTERED_CHUNKS_3D_DATASET_DIMS 3 -#define SHARED_FILTERED_CHUNKS_3D_CH_NROWS (mpi_size) -#define SHARED_FILTERED_CHUNKS_3D_CH_NCOLS (DIM1_SCALE_FACTOR) -#define SHARED_FILTERED_CHUNKS_3D_NROWS (SHARED_FILTERED_CHUNKS_3D_CH_NROWS * DIM0_SCALE_FACTOR) -#define SHARED_FILTERED_CHUNKS_3D_NCOLS (SHARED_FILTERED_CHUNKS_3D_CH_NCOLS * DIM1_SCALE_FACTOR) -#define SHARED_FILTERED_CHUNKS_3D_DEPTH (mpi_size) - -/* Struct type for the compound datatype filtered dataset tests */ -typedef struct { - short field1; - int field2; - long field3; - double field4; -} COMPOUND_C_DATATYPE; +#define WRITE_SHARED_FILTERED_CHUNKS_3D_DATASET_NAME "3D_shared_filtered_chunks_write" +#define WRITE_SHARED_FILTERED_CHUNKS_3D_DATASET_DIMS 3 +#define WRITE_SHARED_FILTERED_CHUNKS_3D_CH_NROWS (mpi_size) +#define WRITE_SHARED_FILTERED_CHUNKS_3D_CH_NCOLS (DIM1_SCALE_FACTOR) +#define WRITE_SHARED_FILTERED_CHUNKS_3D_NROWS (WRITE_SHARED_FILTERED_CHUNKS_3D_CH_NROWS * DIM0_SCALE_FACTOR) +#define WRITE_SHARED_FILTERED_CHUNKS_3D_NCOLS (WRITE_SHARED_FILTERED_CHUNKS_3D_CH_NCOLS * DIM1_SCALE_FACTOR) +#define WRITE_SHARED_FILTERED_CHUNKS_3D_DEPTH (mpi_size) /* Defines for the compound datatype filtered dataset no conversion write test with unshared chunks */ -#define COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_NAME "compound_unshared_filtered_chunks_no_conversion" -#define COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_DIMS 2 -#define COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_NROWS 1 -#define COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_NCOLS mpi_size -#define COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_CH_NROWS 1 -#define COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_CH_NCOLS 1 -#define COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_ENTRIES_PER_PROC (COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_NCOLS / mpi_size) +#define WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_NAME "compound_unshared_filtered_chunks_no_conversion_write" +#define WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_DIMS 2 +#define WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_NROWS 1 +#define WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_NCOLS mpi_size +#define WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_CH_NROWS 1 +#define WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_CH_NCOLS 1 +#define WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_ENTRIES_PER_PROC (WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_NCOLS / mpi_size) /* Defines for the compound datatype filtered dataset no conversion write test with shared chunks */ -#define COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_NAME "compound_shared_filtered_chunks_no_conversion" -#define COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_DIMS 2 -#define COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_NROWS mpi_size -#define COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_NCOLS mpi_size -#define COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_CH_NROWS mpi_size -#define COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_CH_NCOLS 1 -#define COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_ENTRIES_PER_PROC COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_NCOLS +#define WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_NAME "compound_shared_filtered_chunks_no_conversion_write" +#define WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_DIMS 2 +#define WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_NROWS mpi_size +#define WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_NCOLS mpi_size +#define WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_CH_NROWS mpi_size +#define WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_CH_NCOLS 1 +#define WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_ENTRIES_PER_PROC WRITE_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_NCOLS /* Defines for the compound datatype filtered dataset type conversion write test with unshared chunks */ -#define COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_NAME "compound_unshared_filtered_chunks_type_conversion" -#define COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_DIMS 2 -#define COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_NROWS 1 -#define COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_NCOLS mpi_size -#define COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_CH_NROWS 1 -#define COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_CH_NCOLS 1 -#define COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_ENTRIES_PER_PROC (COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_NCOLS / mpi_size) +#define WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_NAME "compound_unshared_filtered_chunks_type_conversion_write" +#define WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_DIMS 2 +#define WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_NROWS 1 +#define WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_NCOLS mpi_size +#define WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_CH_NROWS 1 +#define WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_CH_NCOLS 1 +#define WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_ENTRIES_PER_PROC (WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_NCOLS / mpi_size) /* Defines for the compound datatype filtered dataset type conversion write test with shared chunks */ -#define COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_NAME "compound_shared_filtered_chunks_type_conversion" -#define COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_DIMS 2 -#define COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_NROWS mpi_size -#define COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_NCOLS mpi_size -#define COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_CH_NROWS mpi_size -#define COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_CH_NCOLS 1 -#define COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_ENTRIES_PER_PROC COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_NCOLS +#define WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_NAME "compound_shared_filtered_chunks_type_conversion_write" +#define WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_DIMS 2 +#define WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_NROWS mpi_size +#define WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_NCOLS mpi_size +#define WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_CH_NROWS mpi_size +#define WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_CH_NCOLS 1 +#define WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_ENTRIES_PER_PROC WRITE_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_NCOLS + +/* Defines for the one-chunk filtered dataset read test */ +#define READ_ONE_CHUNK_FILTERED_DATASET_NAME "one_chunk_filtered_dataset_read" +#define READ_ONE_CHUNK_FILTERED_DATASET_DIMS 2 +#define READ_ONE_CHUNK_FILTERED_DATASET_NROWS (mpi_size * DIM0_SCALE_FACTOR) /* Must be an even multiple of the number of ranks to avoid issues */ +#define READ_ONE_CHUNK_FILTERED_DATASET_NCOLS (mpi_size * DIM1_SCALE_FACTOR) /* Must be an even multiple of the number of ranks to avoid issues */ +#define READ_ONE_CHUNK_FILTERED_DATASET_CH_NROWS READ_ONE_CHUNK_FILTERED_DATASET_NROWS +#define READ_ONE_CHUNK_FILTERED_DATASET_CH_NCOLS READ_ONE_CHUNK_FILTERED_DATASET_NCOLS + +/* Defines for the unshared filtered chunks read test */ +#define READ_UNSHARED_FILTERED_CHUNKS_DATASET_NAME "unshared_filtered_chunks_read" +#define READ_UNSHARED_FILTERED_CHUNKS_DATASET_DIMS 2 +#define READ_UNSHARED_FILTERED_CHUNKS_NROWS (mpi_size * DIM0_SCALE_FACTOR) +#define READ_UNSHARED_FILTERED_CHUNKS_NCOLS (mpi_size * DIM1_SCALE_FACTOR) +#define READ_UNSHARED_FILTERED_CHUNKS_CH_NROWS (READ_UNSHARED_FILTERED_CHUNKS_NROWS / mpi_size) +#define READ_UNSHARED_FILTERED_CHUNKS_CH_NCOLS (READ_UNSHARED_FILTERED_CHUNKS_NCOLS / mpi_size) + +/* Defines for the shared filtered chunks read test */ +#define READ_SHARED_FILTERED_CHUNKS_DATASET_NAME "shared_filtered_chunks_read" +#define READ_SHARED_FILTERED_CHUNKS_DATASET_DIMS 2 +#define READ_SHARED_FILTERED_CHUNKS_CH_NROWS (mpi_size) +#define READ_SHARED_FILTERED_CHUNKS_CH_NCOLS (mpi_size) +#define READ_SHARED_FILTERED_CHUNKS_NROWS (READ_SHARED_FILTERED_CHUNKS_CH_NROWS * DIM0_SCALE_FACTOR) +#define READ_SHARED_FILTERED_CHUNKS_NCOLS (READ_SHARED_FILTERED_CHUNKS_CH_NCOLS * DIM1_SCALE_FACTOR) + +/* Defines for the filtered chunks read test where a process has no selection */ +#define READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_NAME "single_no_selection_filtered_chunks_read" +#define READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS 2 +#define READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NROWS (DIM0_SCALE_FACTOR) +#define READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NCOLS (DIM1_SCALE_FACTOR) +#define READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_NROWS (READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NROWS * mpi_size) +#define READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_NCOLS (READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_CH_NCOLS * mpi_size) +#define READ_SINGLE_NO_SELECTION_FILTERED_CHUNKS_NO_SELECT_PROC (mpi_size - 1) + +/* Defines for the filtered chunks read test where no process has a selection */ +#define READ_ALL_NO_SELECTION_FILTERED_CHUNKS_DATASET_NAME "all_no_selection_filtered_chunks_read" +#define READ_ALL_NO_SELECTION_FILTERED_CHUNKS_DATASET_DIMS 2 +#define READ_ALL_NO_SELECTION_FILTERED_CHUNKS_CH_NROWS (DIM0_SCALE_FACTOR) +#define READ_ALL_NO_SELECTION_FILTERED_CHUNKS_CH_NCOLS (DIM1_SCALE_FACTOR) +#define READ_ALL_NO_SELECTION_FILTERED_CHUNKS_NROWS (READ_ALL_NO_SELECTION_FILTERED_CHUNKS_CH_NROWS * mpi_size) +#define READ_ALL_NO_SELECTION_FILTERED_CHUNKS_NCOLS (READ_ALL_NO_SELECTION_FILTERED_CHUNKS_CH_NCOLS * mpi_size) + +/* Defines for the filtered chunks read test with a point selection */ +#define READ_POINT_SELECTION_FILTERED_CHUNKS_DATASET_NAME "point_selection_filtered_chunks_read" +#define READ_POINT_SELECTION_FILTERED_CHUNKS_DATASET_DIMS 2 +#define READ_POINT_SELECTION_FILTERED_CHUNKS_CH_NROWS (DIM0_SCALE_FACTOR) +#define READ_POINT_SELECTION_FILTERED_CHUNKS_CH_NCOLS (DIM1_SCALE_FACTOR) +#define READ_POINT_SELECTION_FILTERED_CHUNKS_NROWS (READ_POINT_SELECTION_FILTERED_CHUNKS_CH_NROWS * mpi_size) +#define READ_POINT_SELECTION_FILTERED_CHUNKS_NCOLS (READ_POINT_SELECTION_FILTERED_CHUNKS_CH_NCOLS * mpi_size) + +/* Defines for the filtered dataset interleaved read test */ +#define INTERLEAVED_READ_FILTERED_DATASET_NAME "filtered_dataset_interleaved_read" +#define INTERLEAVED_READ_FILTERED_DATASET_DIMS 2 +#define INTERLEAVED_READ_FILTERED_DATASET_CH_NROWS (mpi_size) +#define INTERLEAVED_READ_FILTERED_DATASET_CH_NCOLS (DIM1_SCALE_FACTOR) +#define INTERLEAVED_READ_FILTERED_DATASET_NROWS (INTERLEAVED_READ_FILTERED_DATASET_CH_NROWS * DIM0_SCALE_FACTOR) +#define INTERLEAVED_READ_FILTERED_DATASET_NCOLS (INTERLEAVED_READ_FILTERED_DATASET_CH_NCOLS * DIM1_SCALE_FACTOR) + +/* Defines for the 3D unshared filtered dataset separate page read test */ +#define READ_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_NAME "3D_unshared_filtered_chunks_separate_pages_read" +#define READ_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DATASET_DIMS 3 +#define READ_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_NROWS (mpi_size * DIM0_SCALE_FACTOR) +#define READ_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_NCOLS (mpi_size * DIM1_SCALE_FACTOR) +#define READ_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_DEPTH (mpi_size) +#define READ_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_CH_NROWS (READ_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_NROWS / mpi_size) +#define READ_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_CH_NCOLS (READ_UNSHARED_FILTERED_CHUNKS_3D_SEP_PAGE_NCOLS / mpi_size) + +/* Defines for the 3D unshared filtered dataset same page read test */ +#define READ_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_NAME "3D_unshared_filtered_chunks_same_pages_read" +#define READ_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DATASET_DIMS 3 +#define READ_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_NROWS (mpi_size * DIM0_SCALE_FACTOR) +#define READ_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_NCOLS (mpi_size * DIM1_SCALE_FACTOR) +#define READ_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_DEPTH (mpi_size) +#define READ_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_CH_NROWS (READ_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_NROWS / mpi_size) +#define READ_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_CH_NCOLS (READ_UNSHARED_FILTERED_CHUNKS_3D_SAME_PAGE_NCOLS / mpi_size) + +/* Defines for the 3d shared filtered dataset read test */ +#define READ_SHARED_FILTERED_CHUNKS_3D_DATASET_NAME "3D_shared_filtered_chunks_read" +#define READ_SHARED_FILTERED_CHUNKS_3D_DATASET_DIMS 3 +#define READ_SHARED_FILTERED_CHUNKS_3D_CH_NROWS (mpi_size) +#define READ_SHARED_FILTERED_CHUNKS_3D_CH_NCOLS (DIM1_SCALE_FACTOR) +#define READ_SHARED_FILTERED_CHUNKS_3D_NROWS (READ_SHARED_FILTERED_CHUNKS_3D_CH_NROWS * DIM0_SCALE_FACTOR) +#define READ_SHARED_FILTERED_CHUNKS_3D_NCOLS (READ_SHARED_FILTERED_CHUNKS_3D_CH_NCOLS * DIM1_SCALE_FACTOR) +#define READ_SHARED_FILTERED_CHUNKS_3D_DEPTH (mpi_size) + +/* Defines for the compound datatype filtered dataset no conversion read test with unshared chunks */ +#define READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_NAME "compound_unshared_filtered_chunks_no_conversion_read" +#define READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_DATASET_DIMS 2 +#define READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_NROWS 1 +#define READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_NCOLS mpi_size +#define READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_CH_NROWS 1 +#define READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_CH_NCOLS 1 +#define READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_ENTRIES_PER_PROC (READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_UNSHARED_NCOLS / mpi_size) + +/* Defines for the compound datatype filtered dataset no conversion read test with shared chunks */ +#define READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_NAME "compound_shared_filtered_chunks_no_conversion_read" +#define READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_DATASET_DIMS 2 +#define READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_NROWS mpi_size +#define READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_NCOLS mpi_size +#define READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_CH_NROWS mpi_size +#define READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_CH_NCOLS 1 +#define READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_ENTRIES_PER_PROC READ_COMPOUND_FILTERED_CHUNKS_NO_CONVERSION_SHARED_NCOLS + +/* Defines for the compound datatype filtered dataset type conversion read test with unshared chunks */ +#define READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_NAME "compound_unshared_filtered_chunks_type_conversion_read" +#define READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_DATASET_DIMS 2 +#define READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_NROWS 1 +#define READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_NCOLS mpi_size +#define READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_CH_NROWS 1 +#define READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_CH_NCOLS 1 +#define READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_ENTRIES_PER_PROC (READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_UNSHARED_NCOLS / mpi_size) + +/* Defines for the compound datatype filtered dataset type conversion read test with shared chunks */ +#define READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_NAME "compound_shared_filtered_chunks_type_conversion_read" +#define READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_DATASET_DIMS 2 +#define READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_NROWS mpi_size +#define READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_NCOLS mpi_size +#define READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_CH_NROWS mpi_size +#define READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_CH_NCOLS 1 +#define READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_ENTRIES_PER_PROC READ_COMPOUND_FILTERED_CHUNKS_TYPE_CONVERSION_SHARED_NCOLS /* Defines for the write file serially/read in parallel test */ #define WRITE_SERIAL_READ_PARALLEL_DATASET_NAME "write_serial_read_parallel" @@ -209,4 +327,13 @@ typedef struct { #define WRITE_PARALLEL_READ_SERIAL_CH_NROWS (WRITE_PARALLEL_READ_SERIAL_NROWS / mpi_size) #define WRITE_PARALLEL_READ_SERIAL_CH_NCOLS (WRITE_PARALLEL_READ_SERIAL_NCOLS / mpi_size) +/* Defines for the shrinking/growing chunks test */ +#define SHRINKING_GROWING_CHUNKS_DATASET_NAME "shrink_grow_chunks_test" +#define SHRINKING_GROWING_CHUNKS_DATASET_DIMS 2 +#define SHRINKING_GROWING_CHUNKS_NROWS (mpi_size * DIM0_SCALE_FACTOR) +#define SHRINKING_GROWING_CHUNKS_NCOLS (mpi_size * DIM1_SCALE_FACTOR) +#define SHRINKING_GROWING_CHUNKS_CH_NROWS (SHRINKING_GROWING_CHUNKS_NROWS / mpi_size) +#define SHRINKING_GROWING_CHUNKS_CH_NCOLS (SHRINKING_GROWING_CHUNKS_NCOLS / mpi_size) +#define SHRINKING_GROWING_CHUNKS_NLOOPS 20 + #endif /* TEST_PARALLEL_FILTERS_H_ */ |