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Diffstat (limited to 'testpar/t_shapesame.c')
-rw-r--r-- | testpar/t_shapesame.c | 4940 |
1 files changed, 4940 insertions, 0 deletions
diff --git a/testpar/t_shapesame.c b/testpar/t_shapesame.c new file mode 100644 index 0000000..3f8006f --- /dev/null +++ b/testpar/t_shapesame.c @@ -0,0 +1,4940 @@ +/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * + * Copyright by The HDF Group. * + * All rights reserved. * + * * + * This file is part of HDF5. The full HDF5 copyright notice, including * + * terms governing use, modification, and redistribution, is contained in * + * the files COPYING and Copyright.html. COPYING can be found at the root * + * of the source code distribution tree; Copyright.html can be found at the * + * root level of an installed copy of the electronic HDF5 document set and * + * is linked from the top-level documents page. It can also be found at * + * http://hdfgroup.org/HDF5/doc/Copyright.html. If you do not have * + * access to either file, you may request a copy from help@hdfgroup.org. * + * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */ + +/* + This program will test independant and collective reads and writes between + selections of different rank that non-the-less are deemed as having the + same shape by H5Sselect_shape_same(). + */ + +#define H5S_PACKAGE /*suppress error about including H5Spkg */ + +/* Define this macro to indicate that the testing APIs should be available */ +#define H5S_TESTING + + +#include "hdf5.h" +#include "H5private.h" +#include "testphdf5.h" +#include "H5Spkg.h" /* Dataspaces */ + +/* The following macros are used in the detection of tests that run overlong -- + * so that tests can be ommitted if necessary to get the overall set of tests + * to complete. + * + * Observe that we can't do this if we don't have gettimeofday(), so in that + * case, the macros resolve to the empty string. + */ + +#ifdef H5_HAVE_GETTIMEOFDAY + +#define START_TIMER(time_tests, start_time, vrfy_msg) \ + { \ + int result; \ + if ( time_tests ) { \ + result = HDgettimeofday(&(start_time), NULL); \ + VRFY( (result == 0), (vrfy_msg)); \ + } \ + } + +#define STOP_TIMER_AND_UPDATE(time_tests, end_time, vrfy_msg, times) \ + { \ + int result; \ + long long delta_usecs; \ + if ( time_tests ) { \ + result = HDgettimeofday(&(end_time), NULL); \ + VRFY( (result == 0), (vrfy_msg)); \ + delta_usecs = \ + (1000000 * (timeval_b.tv_sec - timeval_a.tv_sec)) + \ + (timeval_b.tv_usec - timeval_a.tv_usec); \ + HDassert( delta_usecs >= 0L ); \ + (times) += delta_usecs; \ + } \ + } + +#else /* H5_HAVE_GETTIMEOFDAY */ + +#define START_TIMER(time_tests, start_time, vrfy_msg) + +#define STOP_TIMER_AND_UPDATE(time_tests, end_time, vrfy_msg, times) + +#endif /* H5_HAVE_GETTIMEOFDAY */ + +/* On Lustre (and perhaps other parallel file systems?), we have severe + * slow downs if two or more processes attempt to access the same file system + * block. To minimize this problem, we set alignment in the shape same tests + * to the default Lustre block size -- which greatly reduces contention in + * the chunked dataset case. + */ + +#define SHAPE_SAME_TEST_ALIGNMENT ((hsize_t)(4 * 1024 * 1024)) + + +/*------------------------------------------------------------------------- + * Function: contig_hyperslab_dr_pio_test__run_test() + * + * Purpose: Test I/O to/from hyperslab selections of different rank in + * the parallel. + * + * Return: void + * + * Programmer: JRM -- 9/18/09 + * + * Modifications: + * + * JRM -- 9/16/10 + * Added express_test parameter. Use it to control whether + * we set up the chunks so that no chunk is shared between + * processes, and also whether we set an alignment when we + * create the test file. + * + *------------------------------------------------------------------------- + */ + +#define PAR_SS_DR_MAX_RANK 5 +#define CONTIG_HYPERSLAB_DR_PIO_TEST__RUN_TEST__DEBUG 0 + +static void +contig_hyperslab_dr_pio_test__run_test(const int test_num, + const int edge_size, + const int chunk_edge_size, + const int small_rank, + const int large_rank, + const hbool_t use_collective_io, + const hid_t dset_type, + const int express_test) +{ +#if CONTIG_HYPERSLAB_DR_PIO_TEST__RUN_TEST__DEBUG + const char *fcnName = "contig_hyperslab_dr_pio_test__run_test()"; +#endif /* CONTIG_HYPERSLAB_DR_PIO_TEST__RUN_TEST__DEBUG */ + const char *filename; + hbool_t use_gpfs = FALSE; /* Use GPFS hints */ + hbool_t mis_match = FALSE; + int i, j, k, l, n; + int mrc; + int mpi_size = -1; + int mpi_rank = -1; + int start_index; + int stop_index; + const int test_max_rank = 5; /* must update code if this changes */ + uint32_t expected_value; + uint32_t * small_ds_buf_0 = NULL; + uint32_t * small_ds_buf_1 = NULL; + uint32_t * small_ds_buf_2 = NULL; + uint32_t * small_ds_slice_buf = NULL; + uint32_t * large_ds_buf_0 = NULL; + uint32_t * large_ds_buf_1 = NULL; + uint32_t * large_ds_buf_2 = NULL; + uint32_t * large_ds_slice_buf = NULL; + uint32_t * ptr_0; + uint32_t * ptr_1; + uint32_t * ptr_2; + MPI_Comm mpi_comm = MPI_COMM_NULL; + MPI_Info mpi_info = MPI_INFO_NULL; + hid_t fid; /* HDF5 file ID */ + hid_t acc_tpl; /* File access templates */ + hid_t xfer_plist = H5P_DEFAULT; + hid_t full_mem_small_ds_sid; + hid_t full_file_small_ds_sid; + hid_t mem_small_ds_sid; + hid_t file_small_ds_sid; + hid_t small_ds_slice_sid; + hid_t full_mem_large_ds_sid; + hid_t full_file_large_ds_sid; + hid_t mem_large_ds_sid; + hid_t file_large_ds_sid; + hid_t file_large_ds_process_slice_sid; + hid_t mem_large_ds_process_slice_sid; + hid_t large_ds_slice_sid; + hid_t small_ds_dcpl_id = H5P_DEFAULT; + hid_t large_ds_dcpl_id = H5P_DEFAULT; + hid_t small_dataset; /* Dataset ID */ + hid_t large_dataset; /* Dataset ID */ + size_t small_ds_size = 1; + size_t small_ds_slice_size = 1; + size_t large_ds_size = 1; + size_t large_ds_slice_size = 1; + hsize_t dims[PAR_SS_DR_MAX_RANK]; + hsize_t chunk_dims[PAR_SS_DR_MAX_RANK]; + hsize_t start[PAR_SS_DR_MAX_RANK]; + hsize_t stride[PAR_SS_DR_MAX_RANK]; + hsize_t count[PAR_SS_DR_MAX_RANK]; + hsize_t block[PAR_SS_DR_MAX_RANK]; + hsize_t * start_ptr = NULL; + hsize_t * stride_ptr = NULL; + hsize_t * count_ptr = NULL; + hsize_t * block_ptr = NULL; + htri_t check; /* Shape comparison return value */ + herr_t ret; /* Generic return value */ + + HDassert( edge_size >= 6 ); + HDassert( edge_size >= chunk_edge_size ); + HDassert( ( chunk_edge_size == 0 ) || ( chunk_edge_size >= 3 ) ); + HDassert( 1 < small_rank ); + HDassert( small_rank < large_rank ); + HDassert( large_rank <= test_max_rank ); + HDassert( test_max_rank <= PAR_SS_DR_MAX_RANK ); + + MPI_Comm_size(MPI_COMM_WORLD, &mpi_size); + MPI_Comm_rank(MPI_COMM_WORLD, &mpi_rank); + + HDassert( mpi_size >= 1 ); + + mpi_comm = MPI_COMM_WORLD; + mpi_info = MPI_INFO_NULL; + + for ( i = 0; i < small_rank - 1; i++ ) + { + small_ds_size *= (size_t)edge_size; + small_ds_slice_size *= (size_t)edge_size; + } + small_ds_size *= (size_t)(mpi_size + 1); + + + for ( i = 0; i < large_rank - 1; i++ ) { + + large_ds_size *= (size_t)edge_size; + large_ds_slice_size *= (size_t)edge_size; + } + large_ds_size *= (size_t)(mpi_size + 1); + + + /* set up the start, stride, count, and block pointers */ + start_ptr = &(start[PAR_SS_DR_MAX_RANK - large_rank]); + stride_ptr = &(stride[PAR_SS_DR_MAX_RANK - large_rank]); + count_ptr = &(count[PAR_SS_DR_MAX_RANK - large_rank]); + block_ptr = &(block[PAR_SS_DR_MAX_RANK - large_rank]); + + + /* Allocate buffers */ + small_ds_buf_0 = (uint32_t *)HDmalloc(sizeof(uint32_t) * small_ds_size); + VRFY((small_ds_buf_0 != NULL), "malloc of small_ds_buf_0 succeeded"); + + small_ds_buf_1 = (uint32_t *)HDmalloc(sizeof(uint32_t) * small_ds_size); + VRFY((small_ds_buf_1 != NULL), "malloc of small_ds_buf_1 succeeded"); + + small_ds_buf_2 = (uint32_t *)HDmalloc(sizeof(uint32_t) * small_ds_size); + VRFY((small_ds_buf_2 != NULL), "malloc of small_ds_buf_2 succeeded"); + + small_ds_slice_buf = + (uint32_t *)HDmalloc(sizeof(uint32_t) * small_ds_slice_size); + VRFY((small_ds_slice_buf != NULL), "malloc of small_ds_slice_buf succeeded"); + + large_ds_buf_0 = (uint32_t *)HDmalloc(sizeof(uint32_t) * large_ds_size); + VRFY((large_ds_buf_0 != NULL), "malloc of large_ds_buf_0 succeeded"); + + large_ds_buf_1 = (uint32_t *)HDmalloc(sizeof(uint32_t) * large_ds_size); + VRFY((large_ds_buf_1 != NULL), "malloc of large_ds_buf_1 succeeded"); + + large_ds_buf_2 = (uint32_t *)HDmalloc(sizeof(uint32_t) * large_ds_size); + VRFY((large_ds_buf_2 != NULL), "malloc of large_ds_buf_2 succeeded"); + + large_ds_slice_buf = + (uint32_t *)HDmalloc(sizeof(uint32_t) * large_ds_slice_size); + VRFY((large_ds_slice_buf != NULL), "malloc of large_ds_slice_buf succeeded"); + + /* initialize the buffers */ + + ptr_0 = small_ds_buf_0; + for(i = 0; i < (int)small_ds_size; i++) + *ptr_0++ = (uint32_t)i; + HDmemset(small_ds_buf_1, 0, sizeof(uint32_t) * small_ds_size); + HDmemset(small_ds_buf_2, 0, sizeof(uint32_t) * small_ds_size); + + HDmemset(small_ds_slice_buf, 0, sizeof(uint32_t) * small_ds_slice_size); + + ptr_0 = large_ds_buf_0; + for(i = 0; i < (int)large_ds_size; i++) + *ptr_0++ = (uint32_t)i; + HDmemset(large_ds_buf_1, 0, sizeof(uint32_t) * large_ds_size); + HDmemset(large_ds_buf_2, 0, sizeof(uint32_t) * large_ds_size); + + HDmemset(large_ds_slice_buf, 0, sizeof(uint32_t) * large_ds_slice_size); + + filename = (const char *)GetTestParameters(); + HDassert( filename != NULL ); +#if CONTIG_HYPERSLAB_DR_PIO_TEST__RUN_TEST__DEBUG + if ( MAINPROCESS ) { + + HDfprintf(stdout, "%d: test num = %d.\n", mpi_rank, test_num); + HDfprintf(stdout, "%d: mpi_size = %d.\n", mpi_rank, mpi_size); + HDfprintf(stdout, + "%d: small/large rank = %d/%d, use_collective_io = %d.\n", + mpi_rank, small_rank, large_rank, (int)use_collective_io); + HDfprintf(stdout, "%d: edge_size = %d, chunk_edge_size = %d.\n", + mpi_rank, edge_size, chunk_edge_size); + HDfprintf(stdout, "%d: small_ds_size = %d, large_ds_size = %d.\n", + mpi_rank, (int)small_ds_size, (int)large_ds_size); + HDfprintf(stdout, "%d: filename = %s.\n", mpi_rank, filename); + } +#endif + /* ---------------------------------------- + * CREATE AN HDF5 FILE WITH PARALLEL ACCESS + * ---------------------------------------*/ + /* setup file access template */ + acc_tpl = create_faccess_plist(mpi_comm, mpi_info, facc_type, use_gpfs); + VRFY((acc_tpl >= 0), "create_faccess_plist() succeeded"); + + /* set the alignment -- need it large so that we aren't always hitting the + * the same file system block. Do this only if express_test is greater + * than zero. + */ + if ( express_test > 0 ) { + + ret = H5Pset_alignment(acc_tpl, (hsize_t)0, SHAPE_SAME_TEST_ALIGNMENT); + VRFY((ret != FAIL), "H5Pset_alignment() succeeded"); + } + + /* create the file collectively */ + fid = H5Fcreate(filename, H5F_ACC_TRUNC, H5P_DEFAULT, acc_tpl); + VRFY((fid >= 0), "H5Fcreate succeeded"); + + MESG("File opened."); + + /* Release file-access template */ + ret = H5Pclose(acc_tpl); + VRFY((ret >= 0), "H5Pclose(acc_tpl) succeeded"); + + + /* setup dims: */ + dims[0] = (int)(mpi_size + 1); + dims[1] = dims[2] = dims[3] = dims[4] = edge_size; + + + /* Create small ds dataspaces */ + full_mem_small_ds_sid = H5Screate_simple(small_rank, dims, NULL); + VRFY((full_mem_small_ds_sid != 0), + "H5Screate_simple() full_mem_small_ds_sid succeeded"); + + full_file_small_ds_sid = H5Screate_simple(small_rank, dims, NULL); + VRFY((full_file_small_ds_sid != 0), + "H5Screate_simple() full_file_small_ds_sid succeeded"); + + mem_small_ds_sid = H5Screate_simple(small_rank, dims, NULL); + VRFY((mem_small_ds_sid != 0), + "H5Screate_simple() mem_small_ds_sid succeeded"); + + file_small_ds_sid = H5Screate_simple(small_rank, dims, NULL); + VRFY((file_small_ds_sid != 0), + "H5Screate_simple() file_small_ds_sid succeeded"); + + small_ds_slice_sid = H5Screate_simple(small_rank - 1, &(dims[1]), NULL); + VRFY((small_ds_slice_sid != 0), + "H5Screate_simple() small_ds_slice_sid succeeded"); + + + /* Create large ds dataspaces */ + full_mem_large_ds_sid = H5Screate_simple(large_rank, dims, NULL); + VRFY((full_mem_large_ds_sid != 0), + "H5Screate_simple() full_mem_large_ds_sid succeeded"); + + full_file_large_ds_sid = H5Screate_simple(large_rank, dims, NULL); + VRFY((full_file_large_ds_sid != FAIL), + "H5Screate_simple() full_file_large_ds_sid succeeded"); + + mem_large_ds_sid = H5Screate_simple(large_rank, dims, NULL); + VRFY((mem_large_ds_sid != FAIL), + "H5Screate_simple() mem_large_ds_sid succeeded"); + + file_large_ds_sid = H5Screate_simple(large_rank, dims, NULL); + VRFY((file_large_ds_sid != FAIL), + "H5Screate_simple() file_large_ds_sid succeeded"); + + mem_large_ds_process_slice_sid = H5Screate_simple(large_rank, dims, NULL); + VRFY((mem_large_ds_process_slice_sid != FAIL), + "H5Screate_simple() mem_large_ds_process_slice_sid succeeded"); + + file_large_ds_process_slice_sid = H5Screate_simple(large_rank, dims, NULL); + VRFY((file_large_ds_process_slice_sid != FAIL), + "H5Screate_simple() file_large_ds_process_slice_sid succeeded"); + + + large_ds_slice_sid = H5Screate_simple(large_rank - 1, &(dims[1]), NULL); + VRFY((large_ds_slice_sid != 0), + "H5Screate_simple() large_ds_slice_sid succeeded"); + + + /* if chunk edge size is greater than zero, set up the small and + * large data set creation property lists to specify chunked + * datasets. + */ + if ( chunk_edge_size > 0 ) { + + /* Under Lustre (and perhaps other parallel file systems?) we get + * locking delays when two or more processes attempt to access the + * same file system block. + * + * To minimize this problem, I have changed chunk_dims[0] + * from (mpi_size + 1) to just when any sort of express test is + * selected. Given the structure of the test, and assuming we + * set the alignment large enough, this avoids the contention + * issue by seeing to it that each chunk is only accessed by one + * process. + * + * One can argue as to whether this is a good thing to do in our + * tests, but for now it is necessary if we want the test to complete + * in a reasonable amount of time. + * + * JRM -- 9/16/10 + */ + if ( express_test == 0 ) { + + chunk_dims[0] = 1; + + } else { + + chunk_dims[0] = 1; + } + chunk_dims[1] = chunk_dims[2] = + chunk_dims[3] = chunk_dims[4] = chunk_edge_size; + + small_ds_dcpl_id = H5Pcreate(H5P_DATASET_CREATE); + VRFY((ret != FAIL), "H5Pcreate() small_ds_dcpl_id succeeded"); + + ret = H5Pset_layout(small_ds_dcpl_id, H5D_CHUNKED); + VRFY((ret != FAIL), "H5Pset_layout() small_ds_dcpl_id succeeded"); + + ret = H5Pset_chunk(small_ds_dcpl_id, small_rank, chunk_dims); + VRFY((ret != FAIL), "H5Pset_chunk() small_ds_dcpl_id succeeded"); + + + large_ds_dcpl_id = H5Pcreate(H5P_DATASET_CREATE); + VRFY((ret != FAIL), "H5Pcreate() large_ds_dcpl_id succeeded"); + + ret = H5Pset_layout(large_ds_dcpl_id, H5D_CHUNKED); + VRFY((ret != FAIL), "H5Pset_layout() large_ds_dcpl_id succeeded"); + + ret = H5Pset_chunk(large_ds_dcpl_id, large_rank, chunk_dims); + VRFY((ret != FAIL), "H5Pset_chunk() large_ds_dcpl_id succeeded"); + } + + /* create the small dataset */ + small_dataset = H5Dcreate2(fid, "small_dataset", dset_type, + file_small_ds_sid, H5P_DEFAULT, + small_ds_dcpl_id, H5P_DEFAULT); + VRFY((ret != FAIL), "H5Dcreate2() small_dataset succeeded"); + + /* create the large dataset */ + large_dataset = H5Dcreate2(fid, "large_dataset", dset_type, + file_large_ds_sid, H5P_DEFAULT, + large_ds_dcpl_id, H5P_DEFAULT); + VRFY((ret != FAIL), "H5Dcreate2() large_dataset succeeded"); + + + + /* setup xfer property list */ + xfer_plist = H5Pcreate(H5P_DATASET_XFER); + VRFY((xfer_plist >= 0), "H5Pcreate(H5P_DATASET_XFER) succeeded"); + + if(use_collective_io) { + ret = H5Pset_dxpl_mpio(xfer_plist, H5FD_MPIO_COLLECTIVE); + VRFY((ret >= 0), "H5Pset_dxpl_mpio succeeded"); + } + + /* setup selection to write initial data to the small and large data sets */ + start[0] = mpi_rank; + stride[0] = 2 * (mpi_size + 1); + count[0] = 1; + block[0] = 1; + + for ( i = 1; i < large_rank; i++ ) { + + start[i] = 0; + stride[i] = 2 * edge_size; + count[i] = 1; + block[i] = edge_size; + } + + /* setup selections for writing initial data to the small data set */ + ret = H5Sselect_hyperslab(mem_small_ds_sid, + H5S_SELECT_SET, + start, + stride, + count, + block); + VRFY((ret >= 0), "H5Sselect_hyperslab(mem_small_ds_sid, set) suceeded"); + + ret = H5Sselect_hyperslab(file_small_ds_sid, + H5S_SELECT_SET, + start, + stride, + count, + block); + VRFY((ret >= 0), "H5Sselect_hyperslab(file_small_ds_sid, set) suceeded"); + + if ( MAINPROCESS ) { /* add an additional slice to the selections */ + + start[0] = mpi_size; + + ret = H5Sselect_hyperslab(mem_small_ds_sid, + H5S_SELECT_OR, + start, + stride, + count, + block); + VRFY((ret>= 0), "H5Sselect_hyperslab(mem_small_ds_sid, or) suceeded"); + + ret = H5Sselect_hyperslab(file_small_ds_sid, + H5S_SELECT_OR, + start, + stride, + count, + block); + VRFY((ret>= 0), "H5Sselect_hyperslab(file_small_ds_sid, or) suceeded"); + } + + + /* write the initial value of the small data set to file */ + ret = H5Dwrite(small_dataset, dset_type, mem_small_ds_sid, file_small_ds_sid, + xfer_plist, small_ds_buf_0); + + VRFY((ret >= 0), "H5Dwrite() small_dataset initial write succeeded"); + + + /* sync with the other processes before checking data */ + if ( ! use_collective_io ) { + + mrc = MPI_Barrier(MPI_COMM_WORLD); + VRFY((mrc==MPI_SUCCESS), "Sync after small dataset writes"); + } + + /* read the small data set back to verify that it contains the + * expected data. Note that each process reads in the entire + * data set. + */ + ret = H5Dread(small_dataset, + H5T_NATIVE_UINT32, + full_mem_small_ds_sid, + full_file_small_ds_sid, + xfer_plist, + small_ds_buf_1); + VRFY((ret >= 0), "H5Dread() small_dataset initial read succeeded"); + + + /* verify that the correct data was written to the small data set */ + expected_value = 0; + mis_match = FALSE; + ptr_1 = small_ds_buf_1; + + i = 0; + for ( i = 0; i < (int)small_ds_size; i++ ) { + + if ( *ptr_1 != expected_value ) { + + mis_match = TRUE; + } + ptr_1++; + expected_value++; + } + VRFY( (mis_match == FALSE), "small ds init data good."); + + + + /* setup selections for writing initial data to the large data set */ + + start[0] = mpi_rank; + + ret = H5Sselect_hyperslab(mem_large_ds_sid, + H5S_SELECT_SET, + start, + stride, + count, + block); + VRFY((ret >= 0), "H5Sselect_hyperslab(mem_large_ds_sid, set) suceeded"); + + ret = H5Sselect_hyperslab(file_large_ds_sid, + H5S_SELECT_SET, + start, + stride, + count, + block); + VRFY((ret >= 0), "H5Sselect_hyperslab(file_large_ds_sid, set) suceeded"); + + /* In passing, setup the process slice data spaces as well */ + + ret = H5Sselect_hyperslab(mem_large_ds_process_slice_sid, + H5S_SELECT_SET, + start, + stride, + count, + block); + VRFY((ret >= 0), + "H5Sselect_hyperslab(mem_large_ds_process_slice_sid, set) suceeded"); + + ret = H5Sselect_hyperslab(file_large_ds_process_slice_sid, + H5S_SELECT_SET, + start, + stride, + count, + block); + VRFY((ret >= 0), + "H5Sselect_hyperslab(file_large_ds_process_slice_sid, set) suceeded"); + + if ( MAINPROCESS ) { /* add an additional slice to the selections */ + + start[0] = mpi_size; + + ret = H5Sselect_hyperslab(mem_large_ds_sid, + H5S_SELECT_OR, + start, + stride, + count, + block); + VRFY((ret>= 0), "H5Sselect_hyperslab(mem_large_ds_sid, or) suceeded"); + + ret = H5Sselect_hyperslab(file_large_ds_sid, + H5S_SELECT_OR, + start, + stride, + count, + block); + VRFY((ret>= 0), "H5Sselect_hyperslab(file_large_ds_sid, or) suceeded"); + } + + + /* write the initial value of the large data set to file */ + ret = H5Dwrite(large_dataset, dset_type, mem_large_ds_sid, file_large_ds_sid, + xfer_plist, large_ds_buf_0); + if ( ret < 0 ) H5Eprint2(H5E_DEFAULT, stderr); + VRFY((ret >= 0), "H5Dwrite() large_dataset initial write succeeded"); + + + /* sync with the other processes before checking data */ + if ( ! use_collective_io ) { + + mrc = MPI_Barrier(MPI_COMM_WORLD); + VRFY((mrc==MPI_SUCCESS), "Sync after large dataset writes"); + } + + + /* read the small data set back to verify that it contains the + * expected data. Note that each process reads in the entire + * data set. + */ + ret = H5Dread(large_dataset, + H5T_NATIVE_UINT32, + full_mem_large_ds_sid, + full_file_large_ds_sid, + xfer_plist, + large_ds_buf_1); + VRFY((ret >= 0), "H5Dread() large_dataset initial read succeeded"); + + + /* verify that the correct data was written to the large data set */ + expected_value = 0; + mis_match = FALSE; + ptr_1 = large_ds_buf_1; + + i = 0; + for ( i = 0; i < (int)large_ds_size; i++ ) { + + if ( *ptr_1 != expected_value ) { + + mis_match = TRUE; + } + ptr_1++; + expected_value++; + } + VRFY( (mis_match == FALSE), "large ds init data good."); + + + /* sync with the other processes before changing data */ + + if ( ! use_collective_io ) { + + mrc = MPI_Barrier(MPI_COMM_WORLD); + VRFY((mrc==MPI_SUCCESS), "Sync initial values check"); + } + + + /* first, verify that we can read from disk correctly using selections + * of different rank that H5S_select_shape_same() views as being of the + * same shape. + * + * Start by reading small_rank-D - 1 slice from the on disk large cube, + * and verifying that the data read is correct. Verify that + * H5S_select_shape_same() returns true on the memory and file selections. + */ + + /* We have already done a H5Sselect_all() on the data space + * small_ds_slice_sid, so no need to call H5Sselect_all() again. + */ + + /* set up start, stride, count, and block -- note that we will + * change start[] so as to read slices of the large cube. + */ + for ( i = 0; i < PAR_SS_DR_MAX_RANK; i++ ) { + + start[i] = 0; + stride[i] = 2 * edge_size; + count[i] = 1; + if ( (PAR_SS_DR_MAX_RANK - i) > (small_rank - 1) ) { + + block[i] = 1; + + } else { + + block[i] = edge_size; + } + } + + /* zero out the buffer we will be reading into */ + HDmemset(small_ds_slice_buf, 0, sizeof(uint32_t) * small_ds_slice_size); + +#if CONTIG_HYPERSLAB_DR_PIO_TEST__RUN_TEST__DEBUG + HDfprintf(stdout, + "%s reading slices from big cube on disk into small cube slice.\n", + fcnName); +#endif + /* in serial versions of this test, we loop through all the dimensions + * of the large data set. However, in the parallel version, each + * process only works with that slice of the large cube indicated + * by its rank -- hence we set the most slowly changing index to + * mpi_rank, and don't itterate over it. + */ + + if ( PAR_SS_DR_MAX_RANK - large_rank == 0 ) { + + i = mpi_rank; + + } else { + + i = 0; + } + + /* since large_rank is at most PAR_SS_DR_MAX_RANK, no need to + * loop over it -- either we are setting i to mpi_rank, or + * we are setting it to zero. It will not change during the + * test. + */ + + if ( PAR_SS_DR_MAX_RANK - large_rank == 1 ) { + + j = mpi_rank; + + } else { + + j = 0; + } + + do { + if ( PAR_SS_DR_MAX_RANK - large_rank == 2 ) { + + k = mpi_rank; + + } else { + + k = 0; + } + + do { + /* since small rank >= 2 and large_rank > small_rank, we + * have large_rank >= 3. Since PAR_SS_DR_MAX_RANK == 5 + * (baring major re-orgaization), this gives us: + * + * (PAR_SS_DR_MAX_RANK - large_rank) <= 2 + * + * so no need to repeat the test in the outer loops -- + * just set l = 0. + */ + + l = 0; + do { + /* we know that small_rank - 1 >= 1 and that + * large_rank > small_rank by the assertions at the head + * of this function. Thus no need for another inner loop. + */ + start[0] = i; + start[1] = j; + start[2] = k; + start[3] = l; + start[4] = 0; + + ret = H5Sselect_hyperslab(file_large_ds_sid, + H5S_SELECT_SET, + start_ptr, + stride_ptr, + count_ptr, + block_ptr); + VRFY((ret != FAIL), + "H5Sselect_hyperslab(file_large_cube_sid) succeeded"); + + + /* verify that H5S_select_shape_same() reports the two + * selections as having the same shape. + */ + check = H5S_select_shape_same_test(small_ds_slice_sid, + file_large_ds_sid); + VRFY((check == TRUE), "H5S_select_shape_same_test passed"); + + + /* Read selection from disk */ +#if CONTIG_HYPERSLAB_DR_PIO_TEST__RUN_TEST__DEBUG + HDfprintf(stdout, "%s:%d: start = %d %d %d %d %d.\n", + fcnName, (int)mpi_rank, + (int)start[0], (int)start[1], (int)start[2], + (int)start[3], (int)start[4]); + HDfprintf(stdout, "%s slice/file extent dims = %d/%d.\n", + fcnName, + H5Sget_simple_extent_ndims(small_ds_slice_sid), + H5Sget_simple_extent_ndims(file_large_ds_sid)); +#endif + ret = H5Dread(large_dataset, + H5T_NATIVE_UINT32, + small_ds_slice_sid, + file_large_ds_sid, + xfer_plist, + small_ds_slice_buf); + VRFY((ret >= 0), "H5Sread() slice from large ds succeeded."); + + + /* verify that expected data is retrieved */ + + mis_match = FALSE; + ptr_1 = small_ds_slice_buf; + expected_value = + (i * edge_size * edge_size * edge_size * edge_size) + + (j * edge_size * edge_size * edge_size) + + (k * edge_size * edge_size) + + (l * edge_size); + + for ( n = 0; n < (int)small_ds_slice_size; n++ ) { + + if ( *ptr_1 != expected_value ) { + + mis_match = TRUE; + } + + *ptr_1 = 0; /* zero data for next use */ + + ptr_1++; + expected_value++; + } + + VRFY((mis_match == FALSE), + "small slice read from large ds data good."); + l++; + + } while ( ( large_rank > 2 ) && + ( (small_rank - 1) <= 1 ) && + ( l < edge_size ) ); + k++; + } while ( ( large_rank > 3 ) && + ( (small_rank - 1) <= 2 ) && + ( k < edge_size ) ); + j++; + } while ( ( large_rank > 4 ) && + ( (small_rank - 1) <= 3 ) && + ( j < edge_size ) ); + + + /* similarly, read slices of the on disk small data set into slices + * through the in memory large data set, and verify that the correct + * data (and only the correct data) is read. + */ + + start[0] = mpi_rank; + stride[0] = 2 * (mpi_size + 1); + count[0] = 1; + block[0] = 1; + + for ( i = 1; i < large_rank; i++ ) { + + start[i] = 0; + stride[i] = 2 * edge_size; + count[i] = 1; + block[i] = edge_size; + } + + ret = H5Sselect_hyperslab(file_small_ds_sid, + H5S_SELECT_SET, + start, + stride, + count, + block); + VRFY((ret >= 0), "H5Sselect_hyperslab(file_small_ds_sid, set) suceeded"); + + +#if CONTIG_HYPERSLAB_DR_PIO_TEST__RUN_TEST__DEBUG + HDfprintf(stdout, + "%s reading slices of on disk small data set into slices of big data set.\n", + fcnName); +#endif + + /* zero out the in memory large ds */ + HDmemset(large_ds_buf_1, 0, sizeof(uint32_t) * large_ds_size); + + /* set up start, stride, count, and block -- note that we will + * change start[] so as to read slices of the large cube. + */ + for ( i = 0; i < PAR_SS_DR_MAX_RANK; i++ ) { + + start[i] = 0; + stride[i] = 2 * edge_size; + count[i] = 1; + if ( (PAR_SS_DR_MAX_RANK - i) > (small_rank - 1) ) { + + block[i] = 1; + + } else { + + block[i] = edge_size; + } + } + + + /* in serial versions of this test, we loop through all the dimensions + * of the large data set that don't appear in the small data set. + * + * However, in the parallel version, each process only works with that + * slice of the large (and small) data set indicated by its rank -- hence + * we set the most slowly changing index to mpi_rank, and don't itterate + * over it. + */ + + + if ( PAR_SS_DR_MAX_RANK - large_rank == 0 ) { + + i = mpi_rank; + + } else { + + i = 0; + } + + /* since large_rank is at most PAR_SS_DR_MAX_RANK, no need to + * loop over it -- either we are setting i to mpi_rank, or + * we are setting it to zero. It will not change during the + * test. + */ + + if ( PAR_SS_DR_MAX_RANK - large_rank == 1 ) { + + j = mpi_rank; + + } else { + + j = 0; + } + + do { + if ( PAR_SS_DR_MAX_RANK - large_rank == 2 ) { + + k = mpi_rank; + + } else { + + k = 0; + } + + do { + /* since small rank >= 2 and large_rank > small_rank, we + * have large_rank >= 3. Since PAR_SS_DR_MAX_RANK == 5 + * (baring major re-orgaization), this gives us: + * + * (PAR_SS_DR_MAX_RANK - large_rank) <= 2 + * + * so no need to repeat the test in the outer loops -- + * just set l = 0. + */ + + l = 0; + do { + /* we know that small_rank >= 1 and that large_rank > small_rank + * by the assertions at the head of this function. Thus no + * need for another inner loop. + */ + start[0] = i; + start[1] = j; + start[2] = k; + start[3] = l; + start[4] = 0; + + ret = H5Sselect_hyperslab(mem_large_ds_sid, + H5S_SELECT_SET, + start_ptr, + stride_ptr, + count_ptr, + block_ptr); + VRFY((ret != FAIL), + "H5Sselect_hyperslab(mem_large_ds_sid) succeeded"); + + + /* verify that H5S_select_shape_same() reports the two + * selections as having the same shape. + */ + check = H5S_select_shape_same_test(file_small_ds_sid, + mem_large_ds_sid); + VRFY((check == TRUE), "H5S_select_shape_same_test passed"); + + + /* Read selection from disk */ +#if CONTIG_HYPERSLAB_DR_PIO_TEST__RUN_TEST__DEBUG + HDfprintf(stdout, "%s:%d: start = %d %d %d %d %d.\n", + fcnName, (int)mpi_rank, + (int)start[0], (int)start[1], (int)start[2], + (int)start[3], (int)start[4]); + HDfprintf(stdout, "%s:%d: mem/file extent dims = %d/%d.\n", + fcnName, mpi_rank, + H5Sget_simple_extent_ndims(mem_large_ds_sid), + H5Sget_simple_extent_ndims(file_small_ds_sid)); +#endif + ret = H5Dread(small_dataset, + H5T_NATIVE_UINT32, + mem_large_ds_sid, + file_small_ds_sid, + xfer_plist, + large_ds_buf_1); + VRFY((ret >= 0), "H5Sread() slice from small ds succeeded."); + + /* verify that the expected data and only the + * expected data was read. + */ + ptr_1 = large_ds_buf_1; + expected_value = mpi_rank * small_ds_slice_size; + start_index = + (i * edge_size * edge_size * edge_size * edge_size) + + (j * edge_size * edge_size * edge_size) + + (k * edge_size * edge_size) + + (l * edge_size); + stop_index = start_index + (int)small_ds_slice_size - 1; + + HDassert( 0 <= start_index ); + HDassert( start_index < stop_index ); + HDassert( stop_index <= (int)large_ds_size ); + + for ( n = 0; n < (int)large_ds_size; n++ ) { + + if ( ( n >= start_index ) && ( n <= stop_index ) ) { + + if ( *ptr_1 != expected_value ) { + + mis_match = TRUE; + } + expected_value++; + + } else { + + if ( *ptr_1 != 0 ) { + + mis_match = TRUE; + } + } + /* zero out the value for the next pass */ + *ptr_1 = 0; + + ptr_1++; + } + + VRFY((mis_match == FALSE), + "small slice read from large ds data good."); + + l++; + + } while ( ( large_rank > 2 ) && + ( (small_rank - 1) <= 1 ) && + ( l < edge_size ) ); + k++; + } while ( ( large_rank > 3 ) && + ( (small_rank - 1) <= 2 ) && + ( k < edge_size ) ); + j++; + } while ( ( large_rank > 4 ) && + ( (small_rank - 1) <= 3 ) && + ( j < edge_size ) ); + + + /* now we go in the opposite direction, verifying that we can write + * from memory to file using selections of different rank that + * H5S_select_shape_same() views as being of the same shape. + * + * Start by writing small_rank - 1 D slices from the in memory large data + * set to the on disk small cube dataset. After each write, read the + * slice of the small dataset back from disk, and verify that it contains + * the expected data. Verify that H5S_select_shape_same() returns true on + * the memory and file selections. + */ + + start[0] = mpi_rank; + stride[0] = 2 * (mpi_size + 1); + count[0] = 1; + block[0] = 1; + + for ( i = 1; i < large_rank; i++ ) { + + start[i] = 0; + stride[i] = 2 * edge_size; + count[i] = 1; + block[i] = edge_size; + } + + ret = H5Sselect_hyperslab(file_small_ds_sid, + H5S_SELECT_SET, + start, + stride, + count, + block); + VRFY((ret >= 0), "H5Sselect_hyperslab(file_small_ds_sid, set) suceeded"); + + ret = H5Sselect_hyperslab(mem_small_ds_sid, + H5S_SELECT_SET, + start, + stride, + count, + block); + VRFY((ret >= 0), "H5Sselect_hyperslab(mem_small_ds_sid, set) suceeded"); + + + /* set up start, stride, count, and block -- note that we will + * change start[] so as to read slices of the large cube. + */ + for ( i = 0; i < PAR_SS_DR_MAX_RANK; i++ ) { + + start[i] = 0; + stride[i] = 2 * edge_size; + count[i] = 1; + if ( (PAR_SS_DR_MAX_RANK - i) > (small_rank - 1) ) { + + block[i] = 1; + + } else { + + block[i] = edge_size; + } + } + + /* zero out the in memory small ds */ + HDmemset(small_ds_buf_1, 0, sizeof(uint32_t) * small_ds_size); + + +#if CONTIG_HYPERSLAB_DR_PIO_TEST__RUN_TEST__DEBUG + HDfprintf(stdout, + "%s writing slices from big ds to slices of small ds on disk.\n", + fcnName); +#endif + + /* in serial versions of this test, we loop through all the dimensions + * of the large data set that don't appear in the small data set. + * + * However, in the parallel version, each process only works with that + * slice of the large (and small) data set indicated by its rank -- hence + * we set the most slowly changing index to mpi_rank, and don't itterate + * over it. + */ + + + if ( PAR_SS_DR_MAX_RANK - large_rank == 0 ) { + + i = mpi_rank; + + } else { + + i = 0; + } + + /* since large_rank is at most PAR_SS_DR_MAX_RANK, no need to + * loop over it -- either we are setting i to mpi_rank, or + * we are setting it to zero. It will not change during the + * test. + */ + + if ( PAR_SS_DR_MAX_RANK - large_rank == 1 ) { + + j = mpi_rank; + + } else { + + j = 0; + } + + j = 0; + do { + if ( PAR_SS_DR_MAX_RANK - large_rank == 2 ) { + + k = mpi_rank; + + } else { + + k = 0; + } + + do { + /* since small rank >= 2 and large_rank > small_rank, we + * have large_rank >= 3. Since PAR_SS_DR_MAX_RANK == 5 + * (baring major re-orgaization), this gives us: + * + * (PAR_SS_DR_MAX_RANK - large_rank) <= 2 + * + * so no need to repeat the test in the outer loops -- + * just set l = 0. + */ + + l = 0; + do { + /* we know that small_rank >= 1 and that large_rank > small_rank + * by the assertions at the head of this function. Thus no + * need for another inner loop. + */ + + /* zero out this rank's slice of the on disk small data set */ + ret = H5Dwrite(small_dataset, + H5T_NATIVE_UINT32, + mem_small_ds_sid, + file_small_ds_sid, + xfer_plist, + small_ds_buf_2); + VRFY((ret >= 0), "H5Dwrite() zero slice to small ds succeeded."); + + /* select the portion of the in memory large cube from which we + * are going to write data. + */ + start[0] = i; + start[1] = j; + start[2] = k; + start[3] = l; + start[4] = 0; + + ret = H5Sselect_hyperslab(mem_large_ds_sid, + H5S_SELECT_SET, + start_ptr, + stride_ptr, + count_ptr, + block_ptr); + VRFY((ret >= 0), + "H5Sselect_hyperslab() mem_large_ds_sid succeeded."); + + + /* verify that H5S_select_shape_same() reports the in + * memory slice through the cube selection and the + * on disk full square selections as having the same shape. + */ + check = H5S_select_shape_same_test(file_small_ds_sid, + mem_large_ds_sid); + VRFY((check == TRUE), "H5S_select_shape_same_test passed."); + + + /* write the slice from the in memory large data set to the + * slice of the on disk small dataset. */ +#if CONTIG_HYPERSLAB_DR_PIO_TEST__RUN_TEST__DEBUG + HDfprintf(stdout, "%s:%d: start = %d %d %d %d %d.\n", + fcnName, (int)mpi_rank, + (int)start[0], (int)start[1], (int)start[2], + (int)start[3], (int)start[4]); + HDfprintf(stdout, "%s:%d: mem/file extent dims = %d/%d.\n", + fcnName, mpi_rank, + H5Sget_simple_extent_ndims(mem_large_ds_sid), + H5Sget_simple_extent_ndims(file_small_ds_sid)); +#endif + ret = H5Dwrite(small_dataset, + H5T_NATIVE_UINT32, + mem_large_ds_sid, + file_small_ds_sid, + xfer_plist, + large_ds_buf_0); + VRFY((ret >= 0), "H5Dwrite() slice to large ds succeeded."); + + + /* read the on disk square into memory */ + ret = H5Dread(small_dataset, + H5T_NATIVE_UINT32, + mem_small_ds_sid, + file_small_ds_sid, + xfer_plist, + small_ds_buf_1); + VRFY((ret >= 0), "H5Dread() slice from small ds succeeded."); + + + /* verify that expected data is retrieved */ + + mis_match = FALSE; + ptr_1 = small_ds_buf_1; + + expected_value = + (i * edge_size * edge_size * edge_size * edge_size) + + (j * edge_size * edge_size * edge_size) + + (k * edge_size * edge_size) + + (l * edge_size); + + start_index = mpi_rank * small_ds_slice_size; + stop_index = start_index + small_ds_slice_size - 1; + + HDassert( 0 <= start_index ); + HDassert( start_index < stop_index ); + HDassert( stop_index <= (int)small_ds_size ); + + for ( n = 0; n < (int)small_ds_size; n++ ) { + + if ( ( n >= start_index ) && ( n <= stop_index ) ) { + + if ( *ptr_1 != expected_value ) { + + mis_match = TRUE; + } + expected_value++; + + } else { + + if ( *ptr_1 != 0 ) { + + mis_match = TRUE; + } + } + /* zero out the value for the next pass */ + *ptr_1 = 0; + + ptr_1++; + } + + VRFY((mis_match == FALSE), + "small slice write from large ds data good."); + + l++; + + } while ( ( large_rank > 2 ) && + ( (small_rank - 1) <= 1 ) && + ( l < edge_size ) ); + k++; + } while ( ( large_rank > 3 ) && + ( (small_rank - 1) <= 2 ) && + ( k < edge_size ) ); + j++; + } while ( ( large_rank > 4 ) && + ( (small_rank - 1) <= 3 ) && + ( j < edge_size ) ); + + + /* Now write the contents of the process's slice of the in memory + * small data set to slices of the on disk large data set. After + * each write, read the process's slice of the large data set back + * into memory, and verify that it contains the expected data. + * Verify that H5S_select_shape_same() returns true on the memory + * and file selections. + */ + + /* select the slice of the in memory small data set associated with + * the process's mpi rank. + */ + start[0] = mpi_rank; + stride[0] = 2 * (mpi_size + 1); + count[0] = 1; + block[0] = 1; + + for ( i = 1; i < large_rank; i++ ) { + + start[i] = 0; + stride[i] = 2 * edge_size; + count[i] = 1; + block[i] = edge_size; + } + + ret = H5Sselect_hyperslab(mem_small_ds_sid, + H5S_SELECT_SET, + start, + stride, + count, + block); + VRFY((ret >= 0), "H5Sselect_hyperslab(mem_small_ds_sid, set) suceeded"); + + + /* set up start, stride, count, and block -- note that we will + * change start[] so as to write slices of the small data set to + * slices of the large data set. + */ + for ( i = 0; i < PAR_SS_DR_MAX_RANK; i++ ) { + + start[i] = 0; + stride[i] = 2 * edge_size; + count[i] = 1; + if ( (PAR_SS_DR_MAX_RANK - i) > (small_rank - 1) ) { + + block[i] = 1; + + } else { + + block[i] = edge_size; + } + } + + /* zero out the in memory large ds */ + HDmemset(large_ds_buf_1, 0, sizeof(uint32_t) * large_ds_size); + +#if CONTIG_HYPERSLAB_DR_PIO_TEST__RUN_TEST__DEBUG + HDfprintf(stdout, + "%s writing process slices of small ds to slices of large ds on disk.\n", + fcnName); +#endif + + if ( PAR_SS_DR_MAX_RANK - large_rank == 0 ) { + + i = mpi_rank; + + } else { + + i = 0; + } + + /* since large_rank is at most PAR_SS_DR_MAX_RANK, no need to + * loop over it -- either we are setting i to mpi_rank, or + * we are setting it to zero. It will not change during the + * test. + */ + + if ( PAR_SS_DR_MAX_RANK - large_rank == 1 ) { + + j = mpi_rank; + + } else { + + j = 0; + } + + do { + if ( PAR_SS_DR_MAX_RANK - large_rank == 2 ) { + + k = mpi_rank; + + } else { + + k = 0; + } + + do { + /* since small rank >= 2 and large_rank > small_rank, we + * have large_rank >= 3. Since PAR_SS_DR_MAX_RANK == 5 + * (baring major re-orgaization), this gives us: + * + * (PAR_SS_DR_MAX_RANK - large_rank) <= 2 + * + * so no need to repeat the test in the outer loops -- + * just set l = 0. + */ + + l = 0; + do { + /* we know that small_rank >= 1 and that large_rank > small_rank + * by the assertions at the head of this function. Thus no + * need for another inner loop. + */ + + /* Zero out this processes slice of the on disk large data set. + * Note that this will leave one slice with its original data + * as there is one more slice than processes. + */ + ret = H5Dwrite(large_dataset, + H5T_NATIVE_UINT32, + large_ds_slice_sid, + file_large_ds_process_slice_sid, + xfer_plist, + large_ds_buf_2); + VRFY((ret != FAIL), "H5Dwrite() to zero large ds suceeded"); + + + /* select the portion of the in memory large cube to which we + * are going to write data. + */ + start[0] = i; + start[1] = j; + start[2] = k; + start[3] = l; + start[4] = 0; + + ret = H5Sselect_hyperslab(file_large_ds_sid, + H5S_SELECT_SET, + start_ptr, + stride_ptr, + count_ptr, + block_ptr); + VRFY((ret != FAIL), + "H5Sselect_hyperslab() target large ds slice succeeded"); + + + /* verify that H5S_select_shape_same() reports the in + * memory small data set slice selection and the + * on disk slice through the large data set selection + * as having the same shape. + */ + check = H5S_select_shape_same_test(mem_small_ds_sid, + file_large_ds_sid); + VRFY((check == TRUE), "H5S_select_shape_same_test passed"); + + + /* write the small data set slice from memory to the + * target slice of the disk data set + */ +#if CONTIG_HYPERSLAB_DR_PIO_TEST__RUN_TEST__DEBUG + HDfprintf(stdout, "%s:%d: start = %d %d %d %d %d.\n", + fcnName, (int)mpi_rank, + (int)start[0], (int)start[1], (int)start[2], + (int)start[3], (int)start[4]); + HDfprintf(stdout, "%s:%d: mem/file extent dims = %d/%d.\n", + fcnName, mpi_rank, + H5Sget_simple_extent_ndims(mem_small_ds_sid), + H5Sget_simple_extent_ndims(file_large_ds_sid)); +#endif + ret = H5Dwrite(large_dataset, + H5T_NATIVE_UINT32, + mem_small_ds_sid, + file_large_ds_sid, + xfer_plist, + small_ds_buf_0); + VRFY((ret != FAIL), + "H5Dwrite of small ds slice to large ds succeeded"); + + + /* read this processes slice on the on disk large + * data set into memory. + */ + + ret = H5Dread(large_dataset, + H5T_NATIVE_UINT32, + mem_large_ds_process_slice_sid, + file_large_ds_process_slice_sid, + xfer_plist, + large_ds_buf_1); + VRFY((ret != FAIL), + "H5Dread() of process slice of large ds succeeded"); + + + /* verify that the expected data and only the + * expected data was read. + */ + ptr_1 = large_ds_buf_1; + expected_value = (uint32_t)(mpi_rank) * small_ds_slice_size; + + + start_index = (i * edge_size * edge_size * edge_size * edge_size) + + (j * edge_size * edge_size * edge_size) + + (k * edge_size * edge_size) + + (l * edge_size); + stop_index = start_index + (int)small_ds_slice_size - 1; + + HDassert( 0 <= start_index ); + HDassert( start_index < stop_index ); + HDassert( stop_index < (int)large_ds_size ); + + for ( n = 0; n < (int)large_ds_size; n++ ) { + + if ( ( n >= start_index ) && ( n <= stop_index ) ) { + + if ( *ptr_1 != expected_value ) { + + mis_match = TRUE; + } + + expected_value++; + + } else { + + if ( *ptr_1 != 0 ) { + + mis_match = TRUE; + } + } + /* zero out buffer for next test */ + *ptr_1 = 0; + ptr_1++; + } + + VRFY((mis_match == FALSE), + "small ds slice write to large ds slice data good."); + + l++; + + } while ( ( large_rank > 2 ) && + ( (small_rank - 1) <= 1 ) && + ( l < edge_size ) ); + k++; + } while ( ( large_rank > 3 ) && + ( (small_rank - 1) <= 2 ) && + ( k < edge_size ) ); + j++; + } while ( ( large_rank > 4 ) && + ( (small_rank - 1) <= 3 ) && + ( j < edge_size ) ); + + + /* Close dataspaces */ + ret = H5Sclose(full_mem_small_ds_sid); + VRFY((ret != FAIL), "H5Sclose(full_mem_small_ds_sid) succeeded"); + + ret = H5Sclose(full_file_small_ds_sid); + VRFY((ret != FAIL), "H5Sclose(full_file_small_ds_sid) succeeded"); + + ret = H5Sclose(mem_small_ds_sid); + VRFY((ret != FAIL), "H5Sclose(mem_small_ds_sid) succeeded"); + + ret = H5Sclose(file_small_ds_sid); + VRFY((ret != FAIL), "H5Sclose(file_small_ds_sid) succeeded"); + + ret = H5Sclose(small_ds_slice_sid); + VRFY((ret != FAIL), "H5Sclose(small_ds_slice_sid) succeeded"); + + ret = H5Sclose(full_mem_large_ds_sid); + VRFY((ret != FAIL), "H5Sclose(full_mem_large_ds_sid) succeeded"); + + ret = H5Sclose(full_file_large_ds_sid); + VRFY((ret != FAIL), "H5Sclose(full_file_large_ds_sid) succeeded"); + + ret = H5Sclose(mem_large_ds_sid); + VRFY((ret != FAIL), "H5Sclose(mem_large_ds_sid) succeeded"); + + ret = H5Sclose(file_large_ds_sid); + VRFY((ret != FAIL), "H5Sclose(mem_large_ds_sid) succeeded"); + + ret = H5Sclose(mem_large_ds_process_slice_sid); + VRFY((ret != FAIL), "H5Sclose(mem_large_ds_process_slice_sid) succeeded"); + + ret = H5Sclose(file_large_ds_process_slice_sid); + VRFY((ret != FAIL), "H5Sclose(file_large_ds_process_slice_sid) succeeded"); + + ret = H5Sclose(large_ds_slice_sid); + VRFY((ret != FAIL), "H5Sclose(large_ds_slice_sid) succeeded"); + + + /* Close Datasets */ + ret = H5Dclose(small_dataset); + VRFY((ret != FAIL), "H5Dclose(small_dataset) succeeded"); + + ret = H5Dclose(large_dataset); + VRFY((ret != FAIL), "H5Dclose(large_dataset) succeeded"); + + + /* close the file collectively */ + MESG("about to close file."); + ret = H5Fclose(fid); + VRFY((ret != FAIL), "file close succeeded"); + + /* Free memory buffers */ + + if ( small_ds_buf_0 != NULL ) HDfree(small_ds_buf_0); + if ( small_ds_buf_1 != NULL ) HDfree(small_ds_buf_1); + if ( small_ds_buf_2 != NULL ) HDfree(small_ds_buf_2); + if ( small_ds_slice_buf != NULL ) HDfree(small_ds_slice_buf); + + if ( large_ds_buf_0 != NULL ) HDfree(large_ds_buf_0); + if ( large_ds_buf_1 != NULL ) HDfree(large_ds_buf_1); + if ( large_ds_buf_2 != NULL ) HDfree(large_ds_buf_2); + if ( large_ds_slice_buf != NULL ) HDfree(large_ds_slice_buf); + + return; + +} /* contig_hyperslab_dr_pio_test__run_test() */ + + +/*------------------------------------------------------------------------- + * Function: contig_hyperslab_dr_pio_test(ShapeSameTestMethods sstest_type) + * + * Purpose: Test I/O to/from hyperslab selections of different rank in + * the parallel case. + * + * Return: void + * + * Programmer: JRM -- 9/18/09 + * + * Modifications: + * + * Modified function to take a sample of the run times + * of the different tests, and skip some of them if + * run times are too long. + * + * We need to do this because Lustre runns very slowly + * if two or more processes are banging on the same + * block of memory. + * JRM -- 9/10/10 + * Break this one big test into 4 smaller tests according + * to {independent,collective}x{contigous,chunked} datasets. + * AKC -- 2010/01/14 + * + *------------------------------------------------------------------------- + */ + +void +contig_hyperslab_dr_pio_test(ShapeSameTestMethods sstest_type) +{ + int test_num = 0; + int edge_size = 10; + int chunk_edge_size = 0; + int small_rank; + int large_rank; + int skips[4] = {0, 0, 0, 0}; + int skip_counters[4] = {0, 0, 0, 0}; + int tests_skiped[4] = {0, 0, 0, 0}; + int mpi_result; + hid_t dset_type = H5T_NATIVE_UINT; +#ifdef H5_HAVE_GETTIMEOFDAY + hbool_t time_tests = TRUE; + hbool_t display_skips = FALSE; + int local_express_test; + int express_test; + int i; + int samples = 0; + int sample_size = 1; + int mpi_size = -1; + int mpi_rank = -1; + int local_skips[4]; + const int ind_contig_idx = 0; + const int col_contig_idx = 1; + const int ind_chunked_idx = 2; + const int col_chunked_idx = 3; + const int test_types = 4; + long long max_test_time = 3000000; /* for one test */ + long long sample_times[4] = {0, 0, 0, 0}; + struct timeval timeval_a; + struct timeval timeval_b; +#endif /* H5_HAVE_GETTIMEOFDAY */ + + HDcompile_assert(sizeof(uint32_t) == sizeof(unsigned)); + + local_express_test = GetTestExpress(); + + mpi_result = MPI_Allreduce((void *)&local_express_test, + (void *)&express_test, + 1, + MPI_INT, + MPI_MAX, + MPI_COMM_WORLD); + + VRFY((mpi_result == MPI_SUCCESS ), "MPI_Allreduce(0) succeeded"); + + for ( large_rank = 3; large_rank <= PAR_SS_DR_MAX_RANK; large_rank++ ) { + + for ( small_rank = 2; small_rank < large_rank; small_rank++ ) { + switch(sstest_type){ + case IND_CONTIG: + /* contiguous data set, independent I/O */ + chunk_edge_size = 0; + if ( skip_counters[ind_contig_idx] < skips[ind_contig_idx] ) { + + skip_counters[ind_contig_idx]++; + tests_skiped[ind_contig_idx]++; + printf("Test skipped\n"); + } else { + skip_counters[ind_contig_idx] = 0; + START_TIMER(time_tests, timeval_a, "HDgettimeofday(0) succeeds."); + contig_hyperslab_dr_pio_test__run_test(test_num, + edge_size, + chunk_edge_size, + small_rank, + large_rank, + FALSE, + dset_type, + express_test); + STOP_TIMER_AND_UPDATE(time_tests, timeval_b, \ + "HDgettimeofday(1) succeeds.", \ + sample_times[col_contig_idx]); + } + test_num++; + break; + /* end of case IND_CONTIG */ + + case COL_CONTIG: + /* contiguous data set, collective I/O */ + chunk_edge_size = 0; + if ( skip_counters[col_contig_idx] < skips[col_contig_idx] ) { + + skip_counters[col_contig_idx]++; + tests_skiped[col_contig_idx]++; + printf("Test skipped\n"); + } else { + skip_counters[col_contig_idx] = 0; + START_TIMER(time_tests, timeval_a, "HDgettimeofday(2) succeeds."); + contig_hyperslab_dr_pio_test__run_test(test_num, + edge_size, + chunk_edge_size, + small_rank, + large_rank, + TRUE, + dset_type, + express_test); + STOP_TIMER_AND_UPDATE(time_tests, timeval_b, \ + "HDgettimeofday(3) succeeds.", \ + sample_times[ind_contig_idx]); + } + test_num++; + break; + /* end of case COL_CONTIG */ + + case IND_CHUNKED: + /* chunked data set, independent I/O */ + chunk_edge_size = 5; + if ( skip_counters[ind_chunked_idx] < skips[ind_chunked_idx] ) { + + skip_counters[ind_chunked_idx]++; + tests_skiped[ind_chunked_idx]++; + printf("Test skipped\n"); + } else { + skip_counters[ind_chunked_idx] = 0; + START_TIMER(time_tests, timeval_a, "HDgettimeofday(4) succeeds."); + contig_hyperslab_dr_pio_test__run_test(test_num, + edge_size, + chunk_edge_size, + small_rank, + large_rank, + FALSE, + dset_type, + express_test); + STOP_TIMER_AND_UPDATE(time_tests, timeval_b, \ + "HDgettimeofday(5) succeeds.", \ + sample_times[col_chunked_idx]); + } + test_num++; + break; + /* end of case IND_CHUNKED */ + + case COL_CHUNKED: + /* chunked data set, collective I/O */ + chunk_edge_size = 5; + if ( skip_counters[col_chunked_idx] < skips[col_chunked_idx] ) { + + skip_counters[col_chunked_idx]++; + tests_skiped[col_chunked_idx]++; + printf("Test skipped\n"); + } else { + skip_counters[col_chunked_idx] = 0; + START_TIMER(time_tests, timeval_a, "HDgettimeofday(6) succeeds."); + contig_hyperslab_dr_pio_test__run_test(test_num, + edge_size, + chunk_edge_size, + small_rank, + large_rank, + TRUE, + dset_type, + express_test); + STOP_TIMER_AND_UPDATE(time_tests, timeval_b, \ + "HDgettimeofday(7) succeeds.", \ + sample_times[ind_chunked_idx]); + } + test_num++; + break; + /* end of case COL_CHUNKED */ + } /* end of switch(sstest_type) */ + +#ifdef H5_HAVE_GETTIMEOFDAY + if ( time_tests ) { + + samples++; + + if ( samples >= sample_size ) { + + int result; + + time_tests = FALSE; + + max_test_time = ((long long)sample_size) * max_test_time; + + for ( i = 0; i < test_types; i++ ) { + + if ( ( express_test == 0 ) || + ( sample_times[i] <= max_test_time ) ) { + + local_skips[i] = 0; + + } else { + + local_skips[i] = (int)(sample_times[i] / max_test_time); + } + } + + /* do an MPI_Allreduce() with the skips vector to ensure that + * all processes agree on its contents. + */ + result = MPI_Allreduce((void *)local_skips, + (void *)skips, + test_types, + MPI_INT, + MPI_MAX, + MPI_COMM_WORLD); + VRFY((result == MPI_SUCCESS ), \ + "MPI_Allreduce(1) succeeded"); + } + } +#endif /* H5_HAVE_GETTIMEOFDAY */ + + } + } + +#ifdef H5_HAVE_GETTIMEOFDAY + if ( ( MAINPROCESS ) && ( display_skips ) ) { + + HDfprintf(stdout, "***********************************\n"); + HDfprintf(stdout, "express_test = %d.\n", express_test); + HDfprintf(stdout, "sample_size = %d, max_test_time = %lld.\n", + sample_size, max_test_time); + HDfprintf(stdout, "sample_times[] = %lld, %lld, %lld, %lld.\n", + sample_times[ind_contig_idx], + sample_times[col_contig_idx], + sample_times[ind_chunked_idx], + sample_times[col_chunked_idx]); + HDfprintf(stdout, "skips[] = %d, %d, %d, %d.\n", + skips[ind_contig_idx], + skips[col_contig_idx], + skips[ind_chunked_idx], + skips[col_chunked_idx]); + HDfprintf(stdout, "tests_skiped[] = %d, %d, %d, %d.\n", + tests_skiped[ind_contig_idx], + tests_skiped[col_contig_idx], + tests_skiped[ind_chunked_idx], + tests_skiped[col_chunked_idx]); + HDfprintf(stdout, "test_num = %d.\n", test_num); + HDfprintf(stdout, "***********************************\n"); + } +#endif /* H5_HAVE_GETTIMEOFDAY */ + + return; + +} /* contig_hyperslab_dr_pio_test() */ + + +/**************************************************************** +** +** checker_board_hyperslab_dr_pio_test__select_checker_board(): +** Given a data space of tgt_rank, and dimensions: +** +** (mpi_size + 1), edge_size, ... , edge_size +** +** edge_size, and a checker_edge_size, select a checker +** board selection of a sel_rank (sel_rank < tgt_rank) +** dimensional slice through the data space parallel to the +** sel_rank fastest changing indicies, with origin (in the +** higher indicies) as indicated by the start array. +** +** Note that this function, like all its relatives, is +** hard coded to presume a maximum data space rank of 5. +** While this maximum is declared as a constant, increasing +** it will require extensive coding in addition to changing +** the value of the constant. +** +** JRM -- 10/8/09 +** +****************************************************************/ + +#define CHECKER_BOARD_HYPERSLAB_DR_PIO_TEST__SELECT_CHECKER_BOARD__DEBUG 0 + +static void +checker_board_hyperslab_dr_pio_test__select_checker_board( + const int mpi_rank, + const hid_t tgt_sid, + const int tgt_rank, + const int edge_size, + const int checker_edge_size, + const int sel_rank, + hsize_t sel_start[]) +{ +#if CHECKER_BOARD_HYPERSLAB_DR_PIO_TEST__SELECT_CHECKER_BOARD__DEBUG + const char * fcnName = + "checker_board_hyperslab_dr_pio_test__select_checker_board():"; +#endif + hbool_t first_selection = TRUE; + int i, j, k, l, m; + int n_cube_offset; + int sel_offset; + const int test_max_rank = PAR_SS_DR_MAX_RANK; /* must update code if */ + /* this changes */ + hsize_t base_count; + hsize_t offset_count; + hsize_t start[PAR_SS_DR_MAX_RANK]; + hsize_t stride[PAR_SS_DR_MAX_RANK]; + hsize_t count[PAR_SS_DR_MAX_RANK]; + hsize_t block[PAR_SS_DR_MAX_RANK]; + herr_t ret; /* Generic return value */ + + HDassert( edge_size >= 6 ); + HDassert( 0 < checker_edge_size ); + HDassert( checker_edge_size <= edge_size ); + HDassert( 0 < sel_rank ); + HDassert( sel_rank <= tgt_rank ); + HDassert( tgt_rank <= test_max_rank ); + HDassert( test_max_rank <= PAR_SS_DR_MAX_RANK ); + + sel_offset = test_max_rank - sel_rank; + HDassert( sel_offset >= 0 ); + + n_cube_offset = test_max_rank - tgt_rank; + HDassert( n_cube_offset >= 0 ); + HDassert( n_cube_offset <= sel_offset ); + +#if CHECKER_BOARD_HYPERSLAB_DR_PIO_TEST__SELECT_CHECKER_BOARD__DEBUG + HDfprintf(stdout, "%s:%d: edge_size/checker_edge_size = %d/%d\n", + fcnName, mpi_rank, edge_size, checker_edge_size); + HDfprintf(stdout, "%s:%d: sel_rank/sel_offset = %d/%d.\n", + fcnName, mpi_rank, sel_rank, sel_offset); + HDfprintf(stdout, "%s:%d: tgt_rank/n_cube_offset = %d/%d.\n", + fcnName, mpi_rank, tgt_rank, n_cube_offset); +#endif /* CHECKER_BOARD_HYPERSLAB_DR_PIO_TEST__SELECT_CHECKER_BOARD__DEBUG */ + + /* First, compute the base count (which assumes start == 0 + * for the associated offset) and offset_count (which + * assumes start == checker_edge_size for the associated + * offset). + * + * Note that the following computation depends on the C99 + * requirement that integer division discard any fraction + * (truncation towards zero) to function correctly. As we + * now require C99, this shouldn't be a problem, but noting + * it may save us some pain if we are ever obliged to support + * pre-C99 compilers again. + */ + + base_count = edge_size / (checker_edge_size * 2); + + if ( (edge_size % (checker_edge_size * 2)) > 0 ) { + + base_count++; + } + + offset_count = (edge_size - checker_edge_size) / (checker_edge_size * 2); + + if ( ((edge_size - checker_edge_size) % (checker_edge_size * 2)) > 0 ) { + + offset_count++; + } + + /* Now set up the stride and block arrays, and portions of the start + * and count arrays that will not be altered during the selection of + * the checker board. + */ + i = 0; + while ( i < n_cube_offset ) { + + /* these values should never be used */ + start[i] = 0; + stride[i] = 0; + count[i] = 0; + block[i] = 0; + + i++; + } + + while ( i < sel_offset ) { + + start[i] = sel_start[i]; + stride[i] = 2 * edge_size; + count[i] = 1; + block[i] = 1; + + i++; + } + + while ( i < test_max_rank ) { + + stride[i] = 2 * checker_edge_size; + block[i] = checker_edge_size; + + i++; + } + + i = 0; + do { + if ( 0 >= sel_offset ) { + + if ( i == 0 ) { + + start[0] = 0; + count[0] = base_count; + + } else { + + start[0] = checker_edge_size; + count[0] = offset_count; + + } + } + + j = 0; + do { + if ( 1 >= sel_offset ) { + + if ( j == 0 ) { + + start[1] = 0; + count[1] = base_count; + + } else { + + start[1] = checker_edge_size; + count[1] = offset_count; + + } + } + + k = 0; + do { + if ( 2 >= sel_offset ) { + + if ( k == 0 ) { + + start[2] = 0; + count[2] = base_count; + + } else { + + start[2] = checker_edge_size; + count[2] = offset_count; + + } + } + + l = 0; + do { + if ( 3 >= sel_offset ) { + + if ( l == 0 ) { + + start[3] = 0; + count[3] = base_count; + + } else { + + start[3] = checker_edge_size; + count[3] = offset_count; + + } + } + + m = 0; + do { + if ( 4 >= sel_offset ) { + + if ( m == 0 ) { + + start[4] = 0; + count[4] = base_count; + + } else { + + start[4] = checker_edge_size; + count[4] = offset_count; + + } + } + + if ( ((i + j + k + l + m) % 2) == 0 ) { + +#if CHECKER_BOARD_HYPERSLAB_DR_PIO_TEST__SELECT_CHECKER_BOARD__DEBUG + HDfprintf(stdout, "%s%d: *** first_selection = %d ***\n", + fcnName, mpi_rank, (int)first_selection); + HDfprintf(stdout, "%s:%d: i/j/k/l/m = %d/%d/%d/%d/%d\n", + fcnName, mpi_rank, i, j, k, l, m); + HDfprintf(stdout, + "%s:%d: start = %d %d %d %d %d.\n", + fcnName, mpi_rank, (int)start[0], (int)start[1], + (int)start[2], (int)start[3], (int)start[4]); + HDfprintf(stdout, + "%s:%d: stride = %d %d %d %d %d.\n", + fcnName, mpi_rank, (int)stride[0], (int)stride[1], + (int)stride[2], (int)stride[3], (int)stride[4]); + HDfprintf(stdout, + "%s:%d: count = %d %d %d %d %d.\n", + fcnName, mpi_rank, (int)count[0], (int)count[1], + (int)count[2], (int)count[3], (int)count[4]); + HDfprintf(stdout, + "%s:%d: block = %d %d %d %d %d.\n", + fcnName, mpi_rank, (int)block[0], (int)block[1], + (int)block[2], (int)block[3], (int)block[4]); + HDfprintf(stdout, "%s:%d: n-cube extent dims = %d.\n", + fcnName, mpi_rank, + H5Sget_simple_extent_ndims(tgt_sid)); + HDfprintf(stdout, "%s:%d: selection rank = %d.\n", + fcnName, mpi_rank, sel_rank); +#endif + + if ( first_selection ) { + + first_selection = FALSE; + + ret = H5Sselect_hyperslab + ( + tgt_sid, + H5S_SELECT_SET, + &(start[n_cube_offset]), + &(stride[n_cube_offset]), + &(count[n_cube_offset]), + &(block[n_cube_offset]) + ); + + VRFY((ret != FAIL), "H5Sselect_hyperslab(SET) succeeded"); + + } else { + + ret = H5Sselect_hyperslab + ( + tgt_sid, + H5S_SELECT_OR, + &(start[n_cube_offset]), + &(stride[n_cube_offset]), + &(count[n_cube_offset]), + &(block[n_cube_offset]) + ); + + VRFY((ret != FAIL), "H5Sselect_hyperslab(OR) succeeded"); + + } + } + + m++; + + } while ( ( m <= 1 ) && + ( 4 >= sel_offset ) ); + + l++; + + } while ( ( l <= 1 ) && + ( 3 >= sel_offset ) ); + + k++; + + } while ( ( k <= 1 ) && + ( 2 >= sel_offset ) ); + + j++; + + } while ( ( j <= 1 ) && + ( 1 >= sel_offset ) ); + + + i++; + + } while ( ( i <= 1 ) && + ( 0 >= sel_offset ) ); + +#if CHECKER_BOARD_HYPERSLAB_DR_PIO_TEST__SELECT_CHECKER_BOARD__DEBUG + HDfprintf(stdout, "%s%d: H5Sget_select_npoints(tgt_sid) = %d.\n", + fcnName, mpi_rank, (int)H5Sget_select_npoints(tgt_sid)); +#endif /* CHECKER_BOARD_HYPERSLAB_DR_PIO_TEST__SELECT_CHECKER_BOARD__DEBUG */ + + /* Clip the selection back to the data space proper. */ + + for ( i = 0; i < test_max_rank; i++ ) { + + start[i] = 0; + stride[i] = edge_size; + count[i] = 1; + block[i] = edge_size; + } + + ret = H5Sselect_hyperslab(tgt_sid, H5S_SELECT_AND, + start, stride, count, block); + + VRFY((ret != FAIL), "H5Sselect_hyperslab(AND) succeeded"); + +#if CHECKER_BOARD_HYPERSLAB_DR_PIO_TEST__SELECT_CHECKER_BOARD__DEBUG + HDfprintf(stdout, "%s%d: H5Sget_select_npoints(tgt_sid) = %d.\n", + fcnName, mpi_rank, (int)H5Sget_select_npoints(tgt_sid)); + HDfprintf(stdout, "%s%d: done.\n", fcnName, mpi_rank); +#endif /* CHECKER_BOARD_HYPERSLAB_DR_PIO_TEST__SELECT_CHECKER_BOARD__DEBUG */ + + return; + +} /* checker_board_hyperslab_dr_pio_test__select_checker_board() */ + + +/**************************************************************** +** +** checker_board_hyperslab_dr_pio_test__verify_data(): +** +** Examine the supplied buffer to see if it contains the +** expected data. Return TRUE if it does, and FALSE +** otherwise. +** +** The supplied buffer is presumed to this process's slice +** of the target data set. Each such slice will be an +** n-cube of rank (rank -1) and the supplied edge_size with +** origin (mpi_rank, 0, ... , 0) in the target data set. +** +** Further, the buffer is presumed to be the result of reading +** or writing a checker board selection of an m (1 <= m < +** rank) dimensional slice through this processes slice +** of the target data set. Also, this slice must be parallel +** to the fastest changing indicies. +** +** It is further presumed that the buffer was zeroed before +** the read/write, and that the full target data set (i.e. +** the buffer/data set for all processes) was initialized +** with the natural numbers listed in order from the origin +** along the fastest changing axis. +** +** Thus for a 20x10x10 dataset, the value stored in location +** (x, y, z) (assuming that z is the fastest changing index +** and x the slowest) is assumed to be: +** +** (10 * 10 * x) + (10 * y) + z +** +** Further, supposing that this is process 10, this process's +** slice of the dataset would be a 10 x 10 2-cube with origin +** (10, 0, 0) in the data set, and would be initialize (prior +** to the checkerboard selection) as follows: +** +** 1000, 1001, 1002, ... 1008, 1009 +** 1010, 1011, 1012, ... 1018, 1019 +** . . . . . +** . . . . . +** . . . . . +** 1090, 1091, 1092, ... 1098, 1099 +** +** In the case of a read from the processors slice of another +** data set of different rank, the values expected will have +** to be adjusted accordingly. This is done via the +** first_expected_val parameter. +** +** Finally, the function presumes that the first element +** of the buffer resides either at the origin of either +** a selected or an unselected checker. (Translation: +** if partial checkers appear in the buffer, they will +** intersect the edges of the n-cube oposite the origin.) +** +****************************************************************/ + +#define CHECKER_BOARD_HYPERSLAB_DR_PIO_TEST__VERIFY_DATA__DEBUG 0 + +static hbool_t +checker_board_hyperslab_dr_pio_test__verify_data(uint32_t * buf_ptr, + const int rank, + const int edge_size, + const int checker_edge_size, + uint32_t first_expected_val, + hbool_t buf_starts_in_checker) +{ +#if CHECKER_BOARD_HYPERSLAB_DR_PIO_TEST__VERIFY_DATA__DEBUG + const char * fcnName = + "checker_board_hyperslab_dr_pio_test__verify_data():"; +#endif + hbool_t good_data = TRUE; + hbool_t in_checker; + hbool_t start_in_checker[5]; + uint32_t expected_value; + uint32_t * val_ptr; + int i, j, k, l, m; /* to track position in n-cube */ + int v, w, x, y, z; /* to track position in checker */ + const int test_max_rank = 5; /* code changes needed if this is increased */ + + HDassert( buf_ptr != NULL ); + HDassert( 0 < rank ); + HDassert( rank <= test_max_rank ); + HDassert( edge_size >= 6 ); + HDassert( 0 < checker_edge_size ); + HDassert( checker_edge_size <= edge_size ); + HDassert( test_max_rank <= PAR_SS_DR_MAX_RANK ); + +#if CHECKER_BOARD_HYPERSLAB_DR_PIO_TEST__VERIFY_DATA__DEBUG + + int mpi_rank; + + MPI_Comm_rank(MPI_COMM_WORLD, &mpi_rank); + HDfprintf(stdout, "%s mpi_rank = %d.\n", fcnName, mpi_rank); + HDfprintf(stdout, "%s rank = %d.\n", fcnName, rank); + HDfprintf(stdout, "%s edge_size = %d.\n", fcnName, edge_size); + HDfprintf(stdout, "%s checker_edge_size = %d.\n", fcnName, checker_edge_size); + HDfprintf(stdout, "%s first_expected_val = %d.\n", fcnName, (int)first_expected_val); + HDfprintf(stdout, "%s starts_in_checker = %d.\n", fcnName, (int)buf_starts_in_checker); +} +#endif + + val_ptr = buf_ptr; + expected_value = first_expected_val; + + i = 0; + v = 0; + start_in_checker[0] = buf_starts_in_checker; + do + { + if ( v >= checker_edge_size ) { + + start_in_checker[0] = ! start_in_checker[0]; + v = 0; + } + + j = 0; + w = 0; + start_in_checker[1] = start_in_checker[0]; + do + { + if ( w >= checker_edge_size ) { + + start_in_checker[1] = ! start_in_checker[1]; + w = 0; + } + + k = 0; + x = 0; + start_in_checker[2] = start_in_checker[1]; + do + { + if ( x >= checker_edge_size ) { + + start_in_checker[2] = ! start_in_checker[2]; + x = 0; + } + + l = 0; + y = 0; + start_in_checker[3] = start_in_checker[2]; + do + { + if ( y >= checker_edge_size ) { + + start_in_checker[3] = ! start_in_checker[3]; + y = 0; + } + + m = 0; + z = 0; +#if CHECKER_BOARD_HYPERSLAB_DR_PIO_TEST__VERIFY_DATA__DEBUG + HDfprintf(stdout, "%d, %d, %d, %d, %d:", i, j, k, l, m); +#endif + in_checker = start_in_checker[3]; + do + { +#if CHECKER_BOARD_HYPERSLAB_DR_PIO_TEST__VERIFY_DATA__DEBUG + HDfprintf(stdout, " %d", (int)(*val_ptr)); +#endif + if ( z >= checker_edge_size ) { + + in_checker = ! in_checker; + z = 0; + } + + if ( in_checker ) { + + if ( *val_ptr != expected_value ) { + + good_data = FALSE; + } + + /* zero out buffer for re-use */ + *val_ptr = 0; + + } else if ( *val_ptr != 0 ) { + + good_data = FALSE; + + /* zero out buffer for re-use */ + *val_ptr = 0; + + } + + val_ptr++; + expected_value++; + m++; + z++; + + } while ( ( rank >= (test_max_rank - 4) ) && + ( m < edge_size ) ); +#if CHECKER_BOARD_HYPERSLAB_DR_PIO_TEST__VERIFY_DATA__DEBUG + HDfprintf(stdout, "\n"); +#endif + l++; + y++; + } while ( ( rank >= (test_max_rank - 3) ) && + ( l < edge_size ) ); + k++; + x++; + } while ( ( rank >= (test_max_rank - 2) ) && + ( k < edge_size ) ); + j++; + w++; + } while ( ( rank >= (test_max_rank - 1) ) && + ( j < edge_size ) ); + i++; + v++; + } while ( ( rank >= test_max_rank ) && + ( i < edge_size ) ); + + return(good_data); + +} /* checker_board_hyperslab_dr_pio_test__verify_data() */ + + +/*------------------------------------------------------------------------- + * Function: checker_board_hyperslab_dr_pio_test__run_test() + * + * Purpose: Test I/O to/from checkerboard selections of hyperslabs of + * different rank in the parallel. + * + * Return: void + * + * Programmer: JRM -- 10/10/09 + * + * Modifications: + * + * JRM -- 9/16/10 + * Added the express_test parameter. Use it to control + * whether we set an alignment, and whether we allocate + * chunks such that no two processes will normally touch + * the same chunk. + * + *------------------------------------------------------------------------- + */ + +#define PAR_SS_DR_MAX_RANK 5 +#define CHECKER_BOARD_HYPERSLAB_DR_PIO_TEST__RUN_TEST__DEBUG 0 + +static void +checker_board_hyperslab_dr_pio_test__run_test(const int test_num, + const int edge_size, + const int checker_edge_size, + const int chunk_edge_size, + const int small_rank, + const int large_rank, + const hbool_t use_collective_io, + const hid_t dset_type, + const int express_test) +{ +#if CHECKER_BOARD_HYPERSLAB_DR_PIO_TEST__RUN_TEST__DEBUG + const char *fcnName = "checker_board_hyperslab_dr_pio_test__run_test()"; +#endif /* CHECKER_BOARD_HYPERSLAB_DR_PIO_TEST__RUN_TEST__DEBUG */ + const char *filename; + hbool_t use_gpfs = FALSE; /* Use GPFS hints */ + hbool_t data_ok = FALSE; + hbool_t mis_match = FALSE; + int i, j, k, l, n; + int mrc; + int start_index; + int stop_index; + int small_ds_offset; + int large_ds_offset; + const int test_max_rank = 5; /* must update code if this changes */ + uint32_t expected_value; + uint32_t * small_ds_buf_0 = NULL; + uint32_t * small_ds_buf_1 = NULL; + uint32_t * small_ds_buf_2 = NULL; + uint32_t * small_ds_slice_buf = NULL; + uint32_t * large_ds_buf_0 = NULL; + uint32_t * large_ds_buf_1 = NULL; + uint32_t * large_ds_buf_2 = NULL; + uint32_t * large_ds_slice_buf = NULL; + uint32_t * ptr_0; + uint32_t * ptr_1; + uint32_t * ptr_2; + int mpi_rank; + int mpi_size; + MPI_Comm mpi_comm = MPI_COMM_NULL; + MPI_Info mpi_info = MPI_INFO_NULL; + hid_t fid; /* HDF5 file ID */ + hid_t acc_tpl; /* File access templates */ + hid_t xfer_plist = H5P_DEFAULT; + hid_t full_mem_small_ds_sid; + hid_t full_file_small_ds_sid; + hid_t mem_small_ds_sid; + hid_t file_small_ds_sid_0; + hid_t file_small_ds_sid_1; + hid_t small_ds_slice_sid; + hid_t full_mem_large_ds_sid; + hid_t full_file_large_ds_sid; + hid_t mem_large_ds_sid; + hid_t file_large_ds_sid_0; + hid_t file_large_ds_sid_1; + hid_t file_large_ds_process_slice_sid; + hid_t mem_large_ds_process_slice_sid; + hid_t large_ds_slice_sid; + hid_t small_ds_dcpl_id = H5P_DEFAULT; + hid_t large_ds_dcpl_id = H5P_DEFAULT; + hid_t small_dataset; /* Dataset ID */ + hid_t large_dataset; /* Dataset ID */ + size_t small_ds_size = 1; + size_t small_ds_slice_size = 1; + size_t large_ds_size = 1; + size_t large_ds_slice_size = 1; + hsize_t dims[PAR_SS_DR_MAX_RANK]; + hsize_t chunk_dims[PAR_SS_DR_MAX_RANK]; + hsize_t start[PAR_SS_DR_MAX_RANK]; + hsize_t stride[PAR_SS_DR_MAX_RANK]; + hsize_t count[PAR_SS_DR_MAX_RANK]; + hsize_t block[PAR_SS_DR_MAX_RANK]; + hsize_t sel_start[PAR_SS_DR_MAX_RANK]; + htri_t check; /* Shape comparison return value */ + herr_t ret; /* Generic return value */ + + HDassert( edge_size >= 6 ); + HDassert( edge_size >= chunk_edge_size ); + HDassert( ( chunk_edge_size == 0 ) || ( chunk_edge_size >= 3 ) ); + HDassert( 1 < small_rank ); + HDassert( small_rank < large_rank ); + HDassert( large_rank <= test_max_rank ); + HDassert( test_max_rank <= PAR_SS_DR_MAX_RANK ); + + MPI_Comm_size(MPI_COMM_WORLD, &mpi_size); + MPI_Comm_rank(MPI_COMM_WORLD, &mpi_rank); + + HDassert( mpi_size >= 1 ); + + mpi_comm = MPI_COMM_WORLD; + mpi_info = MPI_INFO_NULL; + + for ( i = 0; i < small_rank - 1; i++ ) + { + small_ds_size *= (size_t)edge_size; + small_ds_slice_size *= (size_t)edge_size; + } + small_ds_size *= (size_t)(mpi_size + 1); + + small_ds_offset = PAR_SS_DR_MAX_RANK - small_rank; + + HDassert( 0 < small_ds_offset ); + HDassert( small_ds_offset < PAR_SS_DR_MAX_RANK ); + + + for ( i = 0; i < large_rank - 1; i++ ) { + + large_ds_size *= (size_t)edge_size; + large_ds_slice_size *= (size_t)edge_size; + } + large_ds_size *= (size_t)(mpi_size + 1); + + large_ds_offset = PAR_SS_DR_MAX_RANK - large_rank; + + HDassert( 0 <= large_ds_offset ); + HDassert( large_ds_offset < PAR_SS_DR_MAX_RANK ); + + + /* Allocate buffers */ + small_ds_buf_0 = (uint32_t *)HDmalloc(sizeof(uint32_t) * small_ds_size); + VRFY((small_ds_buf_0 != NULL), "malloc of small_ds_buf_0 succeeded"); + + small_ds_buf_1 = (uint32_t *)HDmalloc(sizeof(uint32_t) * small_ds_size); + VRFY((small_ds_buf_1 != NULL), "malloc of small_ds_buf_1 succeeded"); + + small_ds_buf_2 = (uint32_t *)HDmalloc(sizeof(uint32_t) * small_ds_size); + VRFY((small_ds_buf_2 != NULL), "malloc of small_ds_buf_2 succeeded"); + + small_ds_slice_buf = + (uint32_t *)HDmalloc(sizeof(uint32_t) * small_ds_slice_size); + VRFY((small_ds_slice_buf != NULL), "malloc of small_ds_slice_buf succeeded"); + + large_ds_buf_0 = (uint32_t *)HDmalloc(sizeof(uint32_t) * large_ds_size); + VRFY((large_ds_buf_0 != NULL), "malloc of large_ds_buf_0 succeeded"); + + large_ds_buf_1 = (uint32_t *)HDmalloc(sizeof(uint32_t) * large_ds_size); + VRFY((large_ds_buf_1 != NULL), "malloc of large_ds_buf_1 succeeded"); + + large_ds_buf_2 = (uint32_t *)HDmalloc(sizeof(uint32_t) * large_ds_size); + VRFY((large_ds_buf_2 != NULL), "malloc of large_ds_buf_2 succeeded"); + + large_ds_slice_buf = + (uint32_t *)HDmalloc(sizeof(uint32_t) * large_ds_slice_size); + VRFY((large_ds_slice_buf != NULL), "malloc of large_ds_slice_buf succeeded"); + + /* initialize the buffers */ + + ptr_0 = small_ds_buf_0; + for(i = 0; i < (int)small_ds_size; i++) + *ptr_0++ = (uint32_t)i; + HDmemset(small_ds_buf_1, 0, sizeof(uint32_t) * small_ds_size); + HDmemset(small_ds_buf_2, 0, sizeof(uint32_t) * small_ds_size); + + HDmemset(small_ds_slice_buf, 0, sizeof(uint32_t) * small_ds_slice_size); + + ptr_0 = large_ds_buf_0; + for(i = 0; i < (int)large_ds_size; i++) + *ptr_0++ = (uint32_t)i; + HDmemset(large_ds_buf_1, 0, sizeof(uint32_t) * large_ds_size); + HDmemset(large_ds_buf_2, 0, sizeof(uint32_t) * large_ds_size); + + HDmemset(large_ds_slice_buf, 0, sizeof(uint32_t) * large_ds_slice_size); + + filename = (const char *)GetTestParameters(); + HDassert( filename != NULL ); + +#if CHECKER_BOARD_HYPERSLAB_DR_PIO_TEST__RUN_TEST__DEBUG + if ( MAINPROCESS ) { + + HDfprintf(stdout, "%s:%d: test num = %d.\n", fcnName, mpi_rank, test_num); + HDfprintf(stdout, "%s:%d: mpi_size = %d.\n", fcnName, mpi_rank, mpi_size); + HDfprintf(stdout, + "%s:%d: small/large rank = %d/%d, use_collective_io = %d.\n", + fcnName, mpi_rank, small_rank, large_rank, (int)use_collective_io); + HDfprintf(stdout, "%s:%d: edge_size = %d, chunk_edge_size = %d.\n", + fcnName, mpi_rank, edge_size, chunk_edge_size); + HDfprintf(stdout, "%s:%d: checker_edge_size = %d.\n", + fcnName, mpi_rank, checker_edge_size); + HDfprintf(stdout, "%s:%d: small_ds_size = %d, large_ds_size = %d.\n", + fcnName, mpi_rank, (int)small_ds_size, (int)large_ds_size); + HDfprintf(stdout, "%s:%d: filename = %s.\n", fcnName, mpi_rank, filename); + } +#endif /* CHECKER_BOARD_HYPERSLAB_DR_PIO_TEST__RUN_TEST__DEBUG */ + + /* ---------------------------------------- + * CREATE AN HDF5 FILE WITH PARALLEL ACCESS + * ---------------------------------------*/ + /* setup file access template */ + acc_tpl = create_faccess_plist(mpi_comm, mpi_info, facc_type, use_gpfs); + VRFY((acc_tpl >= 0), "create_faccess_plist() succeeded"); + + /* set the alignment -- need it large so that we aren't always hitting the + * the same file system block. Do this only if express_test is greater + * than zero. + */ + if ( express_test > 0 ) { + + ret = H5Pset_alignment(acc_tpl, (hsize_t)0, SHAPE_SAME_TEST_ALIGNMENT); + VRFY((ret != FAIL), "H5Pset_alignment() succeeded"); + } + + /* create the file collectively */ + fid = H5Fcreate(filename, H5F_ACC_TRUNC, H5P_DEFAULT, acc_tpl); + VRFY((fid >= 0), "H5Fcreate succeeded"); + + MESG("File opened."); + + /* Release file-access template */ + ret = H5Pclose(acc_tpl); + VRFY((ret >= 0), "H5Pclose(acc_tpl) succeeded"); + + + /* setup dims: */ + dims[0] = (int)(mpi_size + 1); + dims[1] = dims[2] = dims[3] = dims[4] = edge_size; + + + /* Create small ds dataspaces */ + full_mem_small_ds_sid = H5Screate_simple(small_rank, dims, NULL); + VRFY((full_mem_small_ds_sid != 0), + "H5Screate_simple() full_mem_small_ds_sid succeeded"); + + full_file_small_ds_sid = H5Screate_simple(small_rank, dims, NULL); + VRFY((full_file_small_ds_sid != 0), + "H5Screate_simple() full_file_small_ds_sid succeeded"); + + mem_small_ds_sid = H5Screate_simple(small_rank, dims, NULL); + VRFY((mem_small_ds_sid != 0), + "H5Screate_simple() mem_small_ds_sid succeeded"); + + file_small_ds_sid_0 = H5Screate_simple(small_rank, dims, NULL); + VRFY((file_small_ds_sid_0 != 0), + "H5Screate_simple() file_small_ds_sid_0 succeeded"); + + file_small_ds_sid_1 = H5Screate_simple(small_rank, dims, NULL); + VRFY((file_small_ds_sid_1 != 0), + "H5Screate_simple() file_small_ds_sid_1 succeeded"); + + small_ds_slice_sid = H5Screate_simple(small_rank - 1, &(dims[1]), NULL); + VRFY((small_ds_slice_sid != 0), + "H5Screate_simple() small_ds_slice_sid succeeded"); + + + /* Create large ds dataspaces */ + full_mem_large_ds_sid = H5Screate_simple(large_rank, dims, NULL); + VRFY((full_mem_large_ds_sid != 0), + "H5Screate_simple() full_mem_large_ds_sid succeeded"); + + full_file_large_ds_sid = H5Screate_simple(large_rank, dims, NULL); + VRFY((full_file_large_ds_sid != FAIL), + "H5Screate_simple() full_file_large_ds_sid succeeded"); + + mem_large_ds_sid = H5Screate_simple(large_rank, dims, NULL); + VRFY((mem_large_ds_sid != FAIL), + "H5Screate_simple() mem_large_ds_sid succeeded"); + + file_large_ds_sid_0 = H5Screate_simple(large_rank, dims, NULL); + VRFY((file_large_ds_sid_0 != FAIL), + "H5Screate_simple() file_large_ds_sid_0 succeeded"); + + file_large_ds_sid_1 = H5Screate_simple(large_rank, dims, NULL); + VRFY((file_large_ds_sid_1 != FAIL), + "H5Screate_simple() file_large_ds_sid_1 succeeded"); + + mem_large_ds_process_slice_sid = H5Screate_simple(large_rank, dims, NULL); + VRFY((mem_large_ds_process_slice_sid != FAIL), + "H5Screate_simple() mem_large_ds_process_slice_sid succeeded"); + + file_large_ds_process_slice_sid = H5Screate_simple(large_rank, dims, NULL); + VRFY((file_large_ds_process_slice_sid != FAIL), + "H5Screate_simple() file_large_ds_process_slice_sid succeeded"); + + + large_ds_slice_sid = H5Screate_simple(large_rank - 1, &(dims[1]), NULL); + VRFY((large_ds_slice_sid != 0), + "H5Screate_simple() large_ds_slice_sid succeeded"); + + + /* if chunk edge size is greater than zero, set up the small and + * large data set creation property lists to specify chunked + * datasets. + */ + if ( chunk_edge_size > 0 ) { + + /* Under Lustre (and perhaps other parallel file systems?) we get + * locking delays when two or more processes attempt to access the + * same file system block. + * + * To minimize this problem, I have changed chunk_dims[0] + * from (mpi_size + 1) to just when any sort of express test is + * selected. Given the structure of the test, and assuming we + * set the alignment large enough, this avoids the contention + * issue by seeing to it that each chunk is only accessed by one + * process. + * + * One can argue as to whether this is a good thing to do in our + * tests, but for now it is necessary if we want the test to complete + * in a reasonable amount of time. + * + * JRM -- 9/16/10 + */ + if ( express_test == 0 ) { + + chunk_dims[0] = 1; + + } else { + + chunk_dims[0] = 1; + } + + chunk_dims[1] = chunk_dims[2] = + chunk_dims[3] = chunk_dims[4] = chunk_edge_size; + + small_ds_dcpl_id = H5Pcreate(H5P_DATASET_CREATE); + VRFY((ret != FAIL), "H5Pcreate() small_ds_dcpl_id succeeded"); + + ret = H5Pset_layout(small_ds_dcpl_id, H5D_CHUNKED); + VRFY((ret != FAIL), "H5Pset_layout() small_ds_dcpl_id succeeded"); + + ret = H5Pset_chunk(small_ds_dcpl_id, small_rank, chunk_dims); + VRFY((ret != FAIL), "H5Pset_chunk() small_ds_dcpl_id succeeded"); + + + large_ds_dcpl_id = H5Pcreate(H5P_DATASET_CREATE); + VRFY((ret != FAIL), "H5Pcreate() large_ds_dcpl_id succeeded"); + + ret = H5Pset_layout(large_ds_dcpl_id, H5D_CHUNKED); + VRFY((ret != FAIL), "H5Pset_layout() large_ds_dcpl_id succeeded"); + + ret = H5Pset_chunk(large_ds_dcpl_id, large_rank, chunk_dims); + VRFY((ret != FAIL), "H5Pset_chunk() large_ds_dcpl_id succeeded"); + } + + /* create the small dataset */ + small_dataset = H5Dcreate2(fid, "small_dataset", dset_type, + file_small_ds_sid_0, H5P_DEFAULT, + small_ds_dcpl_id, H5P_DEFAULT); + VRFY((ret != FAIL), "H5Dcreate2() small_dataset succeeded"); + + /* create the large dataset */ + large_dataset = H5Dcreate2(fid, "large_dataset", dset_type, + file_large_ds_sid_0, H5P_DEFAULT, + large_ds_dcpl_id, H5P_DEFAULT); + VRFY((ret != FAIL), "H5Dcreate2() large_dataset succeeded"); + + + /* setup xfer property list */ + xfer_plist = H5Pcreate(H5P_DATASET_XFER); + VRFY((xfer_plist >= 0), "H5Pcreate(H5P_DATASET_XFER) succeeded"); + + if(use_collective_io) { + ret = H5Pset_dxpl_mpio(xfer_plist, H5FD_MPIO_COLLECTIVE); + VRFY((ret >= 0), "H5Pset_dxpl_mpio succeeded"); + } + + + /* setup selection to write initial data to the small and large data sets */ + start[0] = mpi_rank; + stride[0] = 2 * (mpi_size + 1); + count[0] = 1; + block[0] = 1; + + for ( i = 1; i < large_rank; i++ ) { + + start[i] = 0; + stride[i] = 2 * edge_size; + count[i] = 1; + block[i] = edge_size; + } + + /* setup selections for writing initial data to the small data set */ + ret = H5Sselect_hyperslab(mem_small_ds_sid, + H5S_SELECT_SET, + start, + stride, + count, + block); + VRFY((ret >= 0), "H5Sselect_hyperslab(mem_small_ds_sid, set) suceeded"); + + ret = H5Sselect_hyperslab(file_small_ds_sid_0, + H5S_SELECT_SET, + start, + stride, + count, + block); + VRFY((ret >= 0), "H5Sselect_hyperslab(file_small_ds_sid_0, set) suceeded"); + + if ( MAINPROCESS ) { /* add an additional slice to the selections */ + + start[0] = mpi_size; + + ret = H5Sselect_hyperslab(mem_small_ds_sid, + H5S_SELECT_OR, + start, + stride, + count, + block); + VRFY((ret>= 0), "H5Sselect_hyperslab(mem_small_ds_sid, or) suceeded"); + + ret = H5Sselect_hyperslab(file_small_ds_sid_0, + H5S_SELECT_OR, + start, + stride, + count, + block); + VRFY((ret>= 0), "H5Sselect_hyperslab(file_small_ds_sid_0, or) suceeded"); + } + + + /* write the initial value of the small data set to file */ + ret = H5Dwrite(small_dataset, dset_type, mem_small_ds_sid, file_small_ds_sid_0, + xfer_plist, small_ds_buf_0); + VRFY((ret >= 0), "H5Dwrite() small_dataset initial write succeeded"); + + + /* sync with the other processes before checking data */ + if ( ! use_collective_io ) { + + mrc = MPI_Barrier(MPI_COMM_WORLD); + VRFY((mrc==MPI_SUCCESS), "Sync after small dataset writes"); + } + + /* read the small data set back to verify that it contains the + * expected data. Note that each process reads in the entire + * data set and verifies it. + */ + ret = H5Dread(small_dataset, + H5T_NATIVE_UINT32, + full_mem_small_ds_sid, + full_file_small_ds_sid, + xfer_plist, + small_ds_buf_1); + VRFY((ret >= 0), "H5Dread() small_dataset initial read succeeded"); + + + /* verify that the correct data was written to the small data set */ + expected_value = 0; + mis_match = FALSE; + ptr_1 = small_ds_buf_1; + + i = 0; + for ( i = 0; i < (int)small_ds_size; i++ ) { + + if ( *ptr_1 != expected_value ) { + + mis_match = TRUE; + } + ptr_1++; + expected_value++; + } + VRFY( (mis_match == FALSE), "small ds init data good."); + + + + /* setup selections for writing initial data to the large data set */ + + start[0] = mpi_rank; + + ret = H5Sselect_hyperslab(mem_large_ds_sid, + H5S_SELECT_SET, + start, + stride, + count, + block); + VRFY((ret >= 0), "H5Sselect_hyperslab(mem_large_ds_sid, set) suceeded"); + + ret = H5Sselect_hyperslab(file_large_ds_sid_0, + H5S_SELECT_SET, + start, + stride, + count, + block); + VRFY((ret >= 0), "H5Sselect_hyperslab(file_large_ds_sid_0, set) suceeded"); + + /* In passing, setup the process slice data spaces as well */ + + ret = H5Sselect_hyperslab(mem_large_ds_process_slice_sid, + H5S_SELECT_SET, + start, + stride, + count, + block); + VRFY((ret >= 0), + "H5Sselect_hyperslab(mem_large_ds_process_slice_sid, set) suceeded"); + + ret = H5Sselect_hyperslab(file_large_ds_process_slice_sid, + H5S_SELECT_SET, + start, + stride, + count, + block); + VRFY((ret >= 0), + "H5Sselect_hyperslab(file_large_ds_process_slice_sid, set) suceeded"); + + if ( MAINPROCESS ) { /* add an additional slice to the selections */ + + start[0] = mpi_size; + + ret = H5Sselect_hyperslab(mem_large_ds_sid, + H5S_SELECT_OR, + start, + stride, + count, + block); + VRFY((ret>= 0), "H5Sselect_hyperslab(mem_large_ds_sid, or) suceeded"); + + ret = H5Sselect_hyperslab(file_large_ds_sid_0, + H5S_SELECT_OR, + start, + stride, + count, + block); + VRFY((ret>= 0), "H5Sselect_hyperslab(file_large_ds_sid_0, or) suceeded"); + } + + + /* write the initial value of the large data set to file */ + ret = H5Dwrite(large_dataset, dset_type, mem_large_ds_sid, file_large_ds_sid_0, + xfer_plist, large_ds_buf_0); + if ( ret < 0 ) H5Eprint2(H5E_DEFAULT, stderr); + VRFY((ret >= 0), "H5Dwrite() large_dataset initial write succeeded"); + + + /* sync with the other processes before checking data */ + if ( ! use_collective_io ) { + + mrc = MPI_Barrier(MPI_COMM_WORLD); + VRFY((mrc==MPI_SUCCESS), "Sync after large dataset writes"); + } + + + /* read the small data set back to verify that it contains the + * expected data. Note that each process reads in the entire + * data set. + */ + ret = H5Dread(large_dataset, + H5T_NATIVE_UINT32, + full_mem_large_ds_sid, + full_file_large_ds_sid, + xfer_plist, + large_ds_buf_1); + VRFY((ret >= 0), "H5Dread() large_dataset initial read succeeded"); + + + /* verify that the correct data was written to the small data set */ + expected_value = 0; + mis_match = FALSE; + ptr_1 = large_ds_buf_1; + + i = 0; + for ( i = 0; i < (int)large_ds_size; i++ ) { + + if ( *ptr_1 != expected_value ) { + + mis_match = TRUE; + } + ptr_1++; + expected_value++; + } + VRFY( (mis_match == FALSE), "large ds init data good."); + + /* sync with the other processes before changing data */ + + if ( ! use_collective_io ) { + + mrc = MPI_Barrier(MPI_COMM_WORLD); + VRFY((mrc==MPI_SUCCESS), "Sync after initial values check"); + } + + + /***********************************/ + /***** INITIALIZATION COMPLETE *****/ + /***********************************/ + + /* first, verify that we can read from disk correctly using selections + * of different rank that H5S_select_shape_same() views as being of the + * same shape. + * + * Start by reading a (small_rank - 1)-D slice from this processes slice + * of the on disk large data set, and verifying that the data read is + * correct. Verify that H5S_select_shape_same() returns true on the + * memory and file selections. + * + * The first step is to set up the needed checker board selection in the + * in memory small small cube + */ + + sel_start[0] = sel_start[1] = sel_start[2] = sel_start[3] = sel_start[4] = 0; + sel_start[small_ds_offset] = mpi_rank; + + checker_board_hyperslab_dr_pio_test__select_checker_board(mpi_rank, + small_ds_slice_sid, + small_rank - 1, + edge_size, + checker_edge_size, + small_rank - 1, + sel_start); + + /* zero out the buffer we will be reading into */ + HDmemset(small_ds_slice_buf, 0, sizeof(uint32_t) * small_ds_slice_size); + +#if CHECKER_BOARD_HYPERSLAB_DR_PIO_TEST__RUN_TEST__DEBUG + HDfprintf(stdout, "%s:%d: initial small_ds_slice_buf = ", + fcnName, mpi_rank); + ptr_0 = small_ds_slice_buf; + for ( i = 0; i < (int)small_ds_slice_size; i++ ) { + HDfprintf(stdout, "%d ", (int)(*ptr_0)); + ptr_0++; + } + HDfprintf(stdout, "\n"); +#endif /* CHECKER_BOARD_HYPERSLAB_DR_PIO_TEST__RUN_TEST__DEBUG */ + + /* set up start, stride, count, and block -- note that we will + * change start[] so as to read slices of the large cube. + */ + for ( i = 0; i < PAR_SS_DR_MAX_RANK; i++ ) { + + start[i] = 0; + stride[i] = 2 * edge_size; + count[i] = 1; + if ( (PAR_SS_DR_MAX_RANK - i) > (small_rank - 1) ) { + + block[i] = 1; + + } else { + + block[i] = edge_size; + } + } + +#if CHECKER_BOARD_HYPERSLAB_DR_PIO_TEST__RUN_TEST__DEBUG + HDfprintf(stdout, + "%s:%d: reading slice from big ds on disk into small ds slice.\n", + fcnName, mpi_rank); +#endif /* CHECKER_BOARD_HYPERSLAB_DR_PIO_TEST__RUN_TEST__DEBUG */ + /* in serial versions of this test, we loop through all the dimensions + * of the large data set. However, in the parallel version, each + * process only works with that slice of the large cube indicated + * by its rank -- hence we set the most slowly changing index to + * mpi_rank, and don't itterate over it. + */ + + if ( PAR_SS_DR_MAX_RANK - large_rank == 0 ) { + + i = mpi_rank; + + } else { + + i = 0; + } + + /* since large_rank is at most PAR_SS_DR_MAX_RANK, no need to + * loop over it -- either we are setting i to mpi_rank, or + * we are setting it to zero. It will not change during the + * test. + */ + + if ( PAR_SS_DR_MAX_RANK - large_rank == 1 ) { + + j = mpi_rank; + + } else { + + j = 0; + } + + do { + if ( PAR_SS_DR_MAX_RANK - large_rank == 2 ) { + + k = mpi_rank; + + } else { + + k = 0; + } + + do { + /* since small rank >= 2 and large_rank > small_rank, we + * have large_rank >= 3. Since PAR_SS_DR_MAX_RANK == 5 + * (baring major re-orgaization), this gives us: + * + * (PAR_SS_DR_MAX_RANK - large_rank) <= 2 + * + * so no need to repeat the test in the outer loops -- + * just set l = 0. + */ + + l = 0; + do { + /* we know that small_rank - 1 >= 1 and that + * large_rank > small_rank by the assertions at the head + * of this function. Thus no need for another inner loop. + */ + start[0] = i; + start[1] = j; + start[2] = k; + start[3] = l; + start[4] = 0; + + HDassert( ( start[0] == 0 ) || ( 0 < small_ds_offset + 1 ) ); + HDassert( ( start[1] == 0 ) || ( 1 < small_ds_offset + 1 ) ); + HDassert( ( start[2] == 0 ) || ( 2 < small_ds_offset + 1 ) ); + HDassert( ( start[3] == 0 ) || ( 3 < small_ds_offset + 1 ) ); + HDassert( ( start[4] == 0 ) || ( 4 < small_ds_offset + 1 ) ); + + checker_board_hyperslab_dr_pio_test__select_checker_board + ( + mpi_rank, + file_large_ds_sid_0, + large_rank, + edge_size, + checker_edge_size, + small_rank - 1, + start + ); + + /* verify that H5S_select_shape_same() reports the two + * selections as having the same shape. + */ + check = H5S_select_shape_same_test(small_ds_slice_sid, + file_large_ds_sid_0); + VRFY((check == TRUE), "H5S_select_shape_same_test passed"); + + + /* Read selection from disk */ +#if CHECKER_BOARD_HYPERSLAB_DR_PIO_TEST__RUN_TEST__DEBUG + HDfprintf(stdout, "%s:%d: start = %d %d %d %d %d.\n", fcnName, + mpi_rank, start[0], start[1], start[2], start[3], + start[4]); + HDfprintf(stdout, "%s slice/file extent dims = %d/%d.\n", + fcnName, + H5Sget_simple_extent_ndims(small_ds_slice_sid), + H5Sget_simple_extent_ndims(file_large_ds_sid_0)); +#endif /* CHECKER_BOARD_HYPERSLAB_DR_PIO_TEST__RUN_TEST__DEBUG */ + + ret = H5Dread(large_dataset, + H5T_NATIVE_UINT32, + small_ds_slice_sid, + file_large_ds_sid_0, + xfer_plist, + small_ds_slice_buf); + VRFY((ret >= 0), "H5Sread() slice from large ds succeeded."); + +#if CHECKER_BOARD_HYPERSLAB_DR_PIO_TEST__RUN_TEST__DEBUG + HDfprintf(stdout, "%s:%d: H5Dread() returns.\n", + fcnName, mpi_rank); +#endif + + /* verify that expected data is retrieved */ + + expected_value = (uint32_t) + ((i * edge_size * edge_size * edge_size * edge_size) + + (j * edge_size * edge_size * edge_size) + + (k * edge_size * edge_size) + + (l * edge_size)); + + data_ok = checker_board_hyperslab_dr_pio_test__verify_data + ( + small_ds_slice_buf, + small_rank - 1, + edge_size, + checker_edge_size, + expected_value, + (hbool_t)TRUE + ); + + VRFY((data_ok == TRUE), + "small slice read from large ds data good."); + l++; + + } while ( ( large_rank > 2 ) && + ( (small_rank - 1) <= 1 ) && + ( l < edge_size ) ); + k++; + } while ( ( large_rank > 3 ) && + ( (small_rank - 1) <= 2 ) && + ( k < edge_size ) ); + j++; + } while ( ( large_rank > 4 ) && + ( (small_rank - 1) <= 3 ) && + ( j < edge_size ) ); + + + /* similarly, read slices of the on disk small data set into slices + * through the in memory large data set, and verify that the correct + * data (and only the correct data) is read. + */ + + sel_start[0] = sel_start[1] = sel_start[2] = sel_start[3] = sel_start[4] = 0; + sel_start[small_ds_offset] = mpi_rank; + + checker_board_hyperslab_dr_pio_test__select_checker_board(mpi_rank, + file_small_ds_sid_0, + small_rank, + edge_size, + checker_edge_size, + small_rank - 1, + sel_start); + +#if CHECKER_BOARD_HYPERSLAB_DR_PIO_TEST__RUN_TEST__DEBUG + HDfprintf(stdout, + "%s reading slices of on disk small data set into slices of big data set.\n", + fcnName); +#endif + + /* zero out the buffer we will be reading into */ + HDmemset(large_ds_buf_1, 0, sizeof(uint32_t) * large_ds_size); + + /* set up start, stride, count, and block -- note that we will + * change start[] so as to read the slice of the small data set + * into different slices of the process slice of the large data + * set. + */ + for ( i = 0; i < PAR_SS_DR_MAX_RANK; i++ ) { + + start[i] = 0; + stride[i] = 2 * edge_size; + count[i] = 1; + if ( (PAR_SS_DR_MAX_RANK - i) > (small_rank - 1) ) { + + block[i] = 1; + + } else { + + block[i] = edge_size; + } + } + + + /* in serial versions of this test, we loop through all the dimensions + * of the large data set that don't appear in the small data set. + * + * However, in the parallel version, each process only works with that + * slice of the large (and small) data set indicated by its rank -- hence + * we set the most slowly changing index to mpi_rank, and don't itterate + * over it. + */ + + + if ( PAR_SS_DR_MAX_RANK - large_rank == 0 ) { + + i = mpi_rank; + + } else { + + i = 0; + } + + /* since large_rank is at most PAR_SS_DR_MAX_RANK, no need to + * loop over it -- either we are setting i to mpi_rank, or + * we are setting it to zero. It will not change during the + * test. + */ + + if ( PAR_SS_DR_MAX_RANK - large_rank == 1 ) { + + j = mpi_rank; + + } else { + + j = 0; + } + + do { + if ( PAR_SS_DR_MAX_RANK - large_rank == 2 ) { + + k = mpi_rank; + + } else { + + k = 0; + } + + do { + /* since small rank >= 2 and large_rank > small_rank, we + * have large_rank >= 3. Since PAR_SS_DR_MAX_RANK == 5 + * (baring major re-orgaization), this gives us: + * + * (PAR_SS_DR_MAX_RANK - large_rank) <= 2 + * + * so no need to repeat the test in the outer loops -- + * just set l = 0. + */ + + l = 0; + do { + /* we know that small_rank >= 1 and that large_rank > small_rank + * by the assertions at the head of this function. Thus no + * need for another inner loop. + */ + start[0] = i; + start[1] = j; + start[2] = k; + start[3] = l; + start[4] = 0; + + HDassert( ( start[0] == 0 ) || ( 0 < small_ds_offset + 1 ) ); + HDassert( ( start[1] == 0 ) || ( 1 < small_ds_offset + 1 ) ); + HDassert( ( start[2] == 0 ) || ( 2 < small_ds_offset + 1 ) ); + HDassert( ( start[3] == 0 ) || ( 3 < small_ds_offset + 1 ) ); + HDassert( ( start[4] == 0 ) || ( 4 < small_ds_offset + 1 ) ); + + checker_board_hyperslab_dr_pio_test__select_checker_board + ( + mpi_rank, + mem_large_ds_sid, + large_rank, + edge_size, + checker_edge_size, + small_rank - 1, + start + ); + + + /* verify that H5S_select_shape_same() reports the two + * selections as having the same shape. + */ + check = H5S_select_shape_same_test(file_small_ds_sid_0, + mem_large_ds_sid); + VRFY((check == TRUE), "H5S_select_shape_same_test passed"); + + + /* Read selection from disk */ +#if CHECKER_BOARD_HYPERSLAB_DR_PIO_TEST__RUN_TEST__DEBUG + HDfprintf(stdout, "%s:%d: start = %d %d %d %d %d.\n", + fcnName, mpi_rank, + start[0], start[1], start[2], start[3], start[4]); + HDfprintf(stdout, "%s:%d: mem/file extent dims = %d/%d.\n", + fcnName, mpi_rank, + H5Sget_simple_extent_ndims(large_ds_slice_sid), + H5Sget_simple_extent_ndims(file_small_ds_sid_0)); +#endif + ret = H5Dread(small_dataset, + H5T_NATIVE_UINT32, + mem_large_ds_sid, + file_small_ds_sid_0, + xfer_plist, + large_ds_buf_1); + VRFY((ret >= 0), "H5Sread() slice from small ds succeeded."); + + /* verify that the expected data and only the + * expected data was read. + */ + data_ok = TRUE; + ptr_1 = large_ds_buf_1; + expected_value = mpi_rank * small_ds_slice_size; + start_index = + (i * edge_size * edge_size * edge_size * edge_size) + + (j * edge_size * edge_size * edge_size) + + (k * edge_size * edge_size) + + (l * edge_size); + stop_index = start_index + (int)small_ds_slice_size - 1; + +#if CHECKER_BOARD_HYPERSLAB_DR_PIO_TEST__RUN_TEST__DEBUG +{ +int m; + HDfprintf(stdout, "%s:%d: expected_value = %d.\n", + fcnName, mpi_rank, expected_value); + HDfprintf(stdout, "%s:%d: start/stop index = %d/%d.\n", + fcnName, mpi_rank, start_index, stop_index); + n = 0; + for ( m = 0; m < large_ds_size; m ++ ) { + HDfprintf(stdout, "%d ", (int)(*ptr_1)); + ptr_1++; + n++; + if ( n >= edge_size ) { + HDfprintf(stdout, "\n"); + n = 0; + } + } + HDfprintf(stdout, "\n"); + fsync(stdout); + ptr_1 = large_ds_buf_1; +} +#endif + + HDassert( 0 <= start_index ); + HDassert( start_index < stop_index ); + HDassert( stop_index <= (int)large_ds_size ); + + for ( n = 0; n < (int)start_index; n++ ) { + + if ( *ptr_1 != 0 ) { + + data_ok = FALSE; + } + + /* zero out the value for the next pass */ + *ptr_1 = 0; + + ptr_1++; + } + + VRFY((data_ok == TRUE), + "slice read from small to large ds data good(1)."); + + data_ok = checker_board_hyperslab_dr_pio_test__verify_data + ( + ptr_1, + small_rank - 1, + edge_size, + checker_edge_size, + expected_value, + (hbool_t)TRUE + ); + + VRFY((data_ok == TRUE), + "slice read from small to large ds data good(2)."); + + + ptr_1 = large_ds_buf_1 + stop_index + 1; + + for ( n = stop_index + 1; n < large_ds_size; n++ ) { + + if ( *ptr_1 != 0 ) { + + data_ok = FALSE; + } + + /* zero out the value for the next pass */ + *ptr_1 = 0; + + *ptr_1++; + } + + VRFY((data_ok == TRUE), + "slice read from small to large ds data good(3)."); + + l++; + + } while ( ( large_rank > 2 ) && + ( (small_rank - 1) <= 1 ) && + ( l < edge_size ) ); + k++; + } while ( ( large_rank > 3 ) && + ( (small_rank - 1) <= 2 ) && + ( k < edge_size ) ); + j++; + } while ( ( large_rank > 4 ) && + ( (small_rank - 1) <= 3 ) && + ( j < edge_size ) ); + + + /* now we go in the opposite direction, verifying that we can write + * from memory to file using selections of different rank that + * H5S_select_shape_same() views as being of the same shape. + * + * Start by writing small_rank - 1 D slices from the in memory large data + * set to the on disk small dataset. After each write, read the slice of + * the small dataset back from disk, and verify that it contains the + * expected data. Verify that H5S_select_shape_same() returns true on + * the memory and file selections. + */ + + start[0] = mpi_rank; + stride[0] = 2 * (mpi_size + 1); + count[0] = 1; + block[0] = 1; + + for ( i = 1; i < large_rank; i++ ) { + + start[i] = 0; + stride[i] = 2 * edge_size; + count[i] = 1; + block[i] = edge_size; + } + + ret = H5Sselect_hyperslab(file_small_ds_sid_0, + H5S_SELECT_SET, + start, + stride, + count, + block); + VRFY((ret >= 0), "H5Sselect_hyperslab(file_small_ds_sid_0, set) suceeded"); + + ret = H5Sselect_hyperslab(mem_small_ds_sid, + H5S_SELECT_SET, + start, + stride, + count, + block); + VRFY((ret >= 0), "H5Sselect_hyperslab(mem_small_ds_sid, set) suceeded"); + + + sel_start[0] = sel_start[1] = sel_start[2] = sel_start[3] = sel_start[4] = 0; + sel_start[small_ds_offset] = mpi_rank; + + checker_board_hyperslab_dr_pio_test__select_checker_board(mpi_rank, + file_small_ds_sid_1, + small_rank, + edge_size, + checker_edge_size, + small_rank - 1, + sel_start); + + + /* set up start, stride, count, and block -- note that we will + * change start[] so as to read slices of the large cube. + */ + for ( i = 0; i < PAR_SS_DR_MAX_RANK; i++ ) { + + start[i] = 0; + stride[i] = 2 * edge_size; + count[i] = 1; + if ( (PAR_SS_DR_MAX_RANK - i) > (small_rank - 1) ) { + + block[i] = 1; + + } else { + + block[i] = edge_size; + } + } + + /* zero out the in memory small ds */ + HDmemset(small_ds_buf_1, 0, sizeof(uint32_t) * small_ds_size); + + +#if CHECKER_BOARD_HYPERSLAB_DR_PIO_TEST__RUN_TEST__DEBUG + HDfprintf(stdout, + "%s writing checker boards selections of slices from big ds to slices of small ds on disk.\n", + fcnName); +#endif + + /* in serial versions of this test, we loop through all the dimensions + * of the large data set that don't appear in the small data set. + * + * However, in the parallel version, each process only works with that + * slice of the large (and small) data set indicated by its rank -- hence + * we set the most slowly changing index to mpi_rank, and don't itterate + * over it. + */ + + + if ( PAR_SS_DR_MAX_RANK - large_rank == 0 ) { + + i = mpi_rank; + + } else { + + i = 0; + } + + /* since large_rank is at most PAR_SS_DR_MAX_RANK, no need to + * loop over it -- either we are setting i to mpi_rank, or + * we are setting it to zero. It will not change during the + * test. + */ + + if ( PAR_SS_DR_MAX_RANK - large_rank == 1 ) { + + j = mpi_rank; + + } else { + + j = 0; + } + + j = 0; + do { + if ( PAR_SS_DR_MAX_RANK - large_rank == 2 ) { + + k = mpi_rank; + + } else { + + k = 0; + } + + do { + /* since small rank >= 2 and large_rank > small_rank, we + * have large_rank >= 3. Since PAR_SS_DR_MAX_RANK == 5 + * (baring major re-orgaization), this gives us: + * + * (PAR_SS_DR_MAX_RANK - large_rank) <= 2 + * + * so no need to repeat the test in the outer loops -- + * just set l = 0. + */ + + l = 0; + do { + /* we know that small_rank >= 1 and that large_rank > small_rank + * by the assertions at the head of this function. Thus no + * need for another inner loop. + */ + + /* zero out this rank's slice of the on disk small data set */ + ret = H5Dwrite(small_dataset, + H5T_NATIVE_UINT32, + mem_small_ds_sid, + file_small_ds_sid_0, + xfer_plist, + small_ds_buf_2); + VRFY((ret >= 0), "H5Dwrite() zero slice to small ds succeeded."); + + /* select the portion of the in memory large cube from which we + * are going to write data. + */ + start[0] = i; + start[1] = j; + start[2] = k; + start[3] = l; + start[4] = 0; + + HDassert( ( start[0] == 0 ) || ( 0 < small_ds_offset + 1 ) ); + HDassert( ( start[1] == 0 ) || ( 1 < small_ds_offset + 1 ) ); + HDassert( ( start[2] == 0 ) || ( 2 < small_ds_offset + 1 ) ); + HDassert( ( start[3] == 0 ) || ( 3 < small_ds_offset + 1 ) ); + HDassert( ( start[4] == 0 ) || ( 4 < small_ds_offset + 1 ) ); + + checker_board_hyperslab_dr_pio_test__select_checker_board + ( + mpi_rank, + mem_large_ds_sid, + large_rank, + edge_size, + checker_edge_size, + small_rank - 1, + start + ); + + + /* verify that H5S_select_shape_same() reports the in + * memory checkerboard selection of the slice through the + * large dataset and the checkerboard selection of the process + * slice of the small data set as having the same shape. + */ + check = H5S_select_shape_same_test(file_small_ds_sid_1, + mem_large_ds_sid); + VRFY((check == TRUE), "H5S_select_shape_same_test passed."); + + + /* write the checker board selection of the slice from the in + * memory large data set to the slice of the on disk small + * dataset. + */ +#if CHECKER_BOARD_HYPERSLAB_DR_PIO_TEST__RUN_TEST__DEBUG + HDfprintf(stdout, "%s:%d: start = %d %d %d %d %d.\n", + fcnName, mpi_rank, + start[0], start[1], start[2], start[3], start[4]); + HDfprintf(stdout, "%s:%d: mem/file extent dims = %d/%d.\n", + fcnName, mpi_rank, + H5Sget_simple_extent_ndims(mem_large_ds_sid), + H5Sget_simple_extent_ndims(file_small_ds_sid_1)); +#endif + ret = H5Dwrite(small_dataset, + H5T_NATIVE_UINT32, + mem_large_ds_sid, + file_small_ds_sid_1, + xfer_plist, + large_ds_buf_0); + VRFY((ret >= 0), "H5Dwrite() slice to large ds succeeded."); + + + /* read the on disk process slice of the small dataset into memory */ + ret = H5Dread(small_dataset, + H5T_NATIVE_UINT32, + mem_small_ds_sid, + file_small_ds_sid_0, + xfer_plist, + small_ds_buf_1); + VRFY((ret >= 0), "H5Dread() slice from small ds succeeded."); + + + /* verify that expected data is retrieved */ + + mis_match = FALSE; + ptr_1 = small_ds_buf_1; + + expected_value = + (i * edge_size * edge_size * edge_size * edge_size) + + (j * edge_size * edge_size * edge_size) + + (k * edge_size * edge_size) + + (l * edge_size); + + start_index = mpi_rank * small_ds_slice_size; + stop_index = start_index + small_ds_slice_size - 1; + + HDassert( 0 <= start_index ); + HDassert( start_index < stop_index ); + HDassert( stop_index <= (int)small_ds_size ); + + data_ok = TRUE; + + for ( n = 0; n < start_index; n++ ) { + + if ( *(ptr_1 + n) != 0 ) { + + data_ok = FALSE; + *(ptr_1 + n) = 0; + } + } + + data_ok &= checker_board_hyperslab_dr_pio_test__verify_data + ( + ptr_1 + start_index, + small_rank - 1, + edge_size, + checker_edge_size, + expected_value, + (hbool_t)TRUE + ); + + + for ( n = stop_index; n < small_ds_size; n++ ) { + + if ( *(ptr_1 + n) != 0 ) { + + data_ok = FALSE; + *(ptr_1 + n) = 0; + } + } + + VRFY((data_ok == TRUE), + "large slice write slice to small slice data good."); + + l++; + + } while ( ( large_rank > 2 ) && + ( (small_rank - 1) <= 1 ) && + ( l < edge_size ) ); + k++; + } while ( ( large_rank > 3 ) && + ( (small_rank - 1) <= 2 ) && + ( k < edge_size ) ); + j++; + } while ( ( large_rank > 4 ) && + ( (small_rank - 1) <= 3 ) && + ( j < edge_size ) ); + + + /* Now write the contents of the process's slice of the in memory + * small data set to slices of the on disk large data set. After + * each write, read the process's slice of the large data set back + * into memory, and verify that it contains the expected data. + * Verify that H5S_select_shape_same() returns true on the memory + * and file selections. + */ + + start[0] = mpi_rank; + stride[0] = 2 * (mpi_size + 1); + count[0] = 1; + block[0] = 1; + + for ( i = 1; i < large_rank; i++ ) { + + start[i] = 0; + stride[i] = 2 * edge_size; + count[i] = 1; + block[i] = edge_size; + } + + ret = H5Sselect_hyperslab(file_large_ds_sid_0, + H5S_SELECT_SET, + start, + stride, + count, + block); + VRFY((ret >= 0), "H5Sselect_hyperslab(file_large_ds_sid_0, set) suceeded"); + + ret = H5Sselect_hyperslab(mem_large_ds_sid, + H5S_SELECT_SET, + start, + stride, + count, + block); + VRFY((ret >= 0), "H5Sselect_hyperslab(mem_small_ds_sid, set) suceeded"); + + /* setup a checkerboard selection of the slice of the in memory small + * data set associated with the process's mpi rank. + */ + + sel_start[0] = sel_start[1] = sel_start[2] = sel_start[3] = sel_start[4] = 0; + sel_start[small_ds_offset] = mpi_rank; + + checker_board_hyperslab_dr_pio_test__select_checker_board(mpi_rank, + mem_small_ds_sid, + small_rank, + edge_size, + checker_edge_size, + small_rank - 1, + sel_start); + + /* set up start, stride, count, and block -- note that we will + * change start[] so as to write checkerboard selections of slices + * of the small data set to slices of the large data set. + */ + for ( i = 0; i < PAR_SS_DR_MAX_RANK; i++ ) { + + start[i] = 0; + stride[i] = 2 * edge_size; + count[i] = 1; + if ( (PAR_SS_DR_MAX_RANK - i) > (small_rank - 1) ) { + + block[i] = 1; + + } else { + + block[i] = edge_size; + } + } + + /* zero out the in memory large ds */ + HDmemset(large_ds_buf_1, 0, sizeof(uint32_t) * large_ds_size); + +#if CONTIG_HYPERSLAB_DR_PIO_TEST__RUN_TEST__DEBUG + HDfprintf(stdout, + "%s writing process checkerboard selections of slices of small ds to process slices of large ds on disk.\n", + fcnName); +#endif + + if ( PAR_SS_DR_MAX_RANK - large_rank == 0 ) { + + i = mpi_rank; + + } else { + + i = 0; + } + + /* since large_rank is at most PAR_SS_DR_MAX_RANK, no need to + * loop over it -- either we are setting i to mpi_rank, or + * we are setting it to zero. It will not change during the + * test. + */ + + if ( PAR_SS_DR_MAX_RANK - large_rank == 1 ) { + + j = mpi_rank; + + } else { + + j = 0; + } + + do { + if ( PAR_SS_DR_MAX_RANK - large_rank == 2 ) { + + k = mpi_rank; + + } else { + + k = 0; + } + + do { + /* since small rank >= 2 and large_rank > small_rank, we + * have large_rank >= 3. Since PAR_SS_DR_MAX_RANK == 5 + * (baring major re-orgaization), this gives us: + * + * (PAR_SS_DR_MAX_RANK - large_rank) <= 2 + * + * so no need to repeat the test in the outer loops -- + * just set l = 0. + */ + + l = 0; + do { + /* we know that small_rank >= 1 and that large_rank > small_rank + * by the assertions at the head of this function. Thus no + * need for another inner loop. + */ + + /* Zero out this processes slice of the on disk large data set. + * Note that this will leave one slice with its original data + * as there is one more slice than processes. + */ + ret = H5Dwrite(large_dataset, + H5T_NATIVE_UINT32, + mem_large_ds_sid, + file_large_ds_sid_0, + xfer_plist, + large_ds_buf_2); + VRFY((ret != FAIL), "H5Dwrite() to zero large ds suceeded"); + + + /* select the portion of the in memory large cube to which we + * are going to write data. + */ + start[0] = i; + start[1] = j; + start[2] = k; + start[3] = l; + start[4] = 0; + + HDassert( ( start[0] == 0 ) || ( 0 < small_ds_offset + 1 ) ); + HDassert( ( start[1] == 0 ) || ( 1 < small_ds_offset + 1 ) ); + HDassert( ( start[2] == 0 ) || ( 2 < small_ds_offset + 1 ) ); + HDassert( ( start[3] == 0 ) || ( 3 < small_ds_offset + 1 ) ); + HDassert( ( start[4] == 0 ) || ( 4 < small_ds_offset + 1 ) ); + + checker_board_hyperslab_dr_pio_test__select_checker_board + ( + mpi_rank, + file_large_ds_sid_1, + large_rank, + edge_size, + checker_edge_size, + small_rank - 1, + start + ); + + + /* verify that H5S_select_shape_same() reports the in + * memory small data set slice selection and the + * on disk slice through the large data set selection + * as having the same shape. + */ + check = H5S_select_shape_same_test(mem_small_ds_sid, + file_large_ds_sid_1); + VRFY((check == TRUE), "H5S_select_shape_same_test passed"); + + + /* write the small data set slice from memory to the + * target slice of the disk data set + */ +#if CHECKER_BOARD_HYPERSLAB_DR_PIO_TEST__RUN_TEST__DEBUG + HDfprintf(stdout, "%s:%d: start = %d %d %d %d %d.\n", + fcnName, mpi_rank, + start[0], start[1], start[2], start[3], start[4]); + HDfprintf(stdout, "%s:%d: mem/file extent dims = %d/%d.\n", + fcnName, mpi_rank, + H5Sget_simple_extent_ndims(mem_small_ds_sid), + H5Sget_simple_extent_ndims(file_large_ds_sid_1)); +#endif + ret = H5Dwrite(large_dataset, + H5T_NATIVE_UINT32, + mem_small_ds_sid, + file_large_ds_sid_1, + xfer_plist, + small_ds_buf_0); + VRFY((ret != FAIL), + "H5Dwrite of small ds slice to large ds succeeded"); + + + /* read this processes slice on the on disk large + * data set into memory. + */ + + ret = H5Dread(large_dataset, + H5T_NATIVE_UINT32, + mem_large_ds_sid, + file_large_ds_sid_0, + xfer_plist, + large_ds_buf_1); + VRFY((ret != FAIL), + "H5Dread() of process slice of large ds succeeded"); + + + /* verify that the expected data and only the + * expected data was read. + */ + ptr_1 = large_ds_buf_1; + expected_value = (uint32_t)(mpi_rank) * small_ds_slice_size; + + + start_index = (i * edge_size * edge_size * edge_size * edge_size) + + (j * edge_size * edge_size * edge_size) + + (k * edge_size * edge_size) + + (l * edge_size); + stop_index = start_index + (int)small_ds_slice_size - 1; + + HDassert( 0 <= start_index ); + HDassert( start_index < stop_index ); + HDassert( stop_index < (int)large_ds_size ); + + + mis_match = FALSE; + + data_ok = TRUE; + + for ( n = 0; n < start_index; n++ ) { + + if ( *(ptr_1 + n) != 0 ) { + + data_ok = FALSE; + *(ptr_1 + n) = 0; + } + } + + data_ok &= checker_board_hyperslab_dr_pio_test__verify_data + ( + ptr_1 + start_index, + small_rank - 1, + edge_size, + checker_edge_size, + expected_value, + (hbool_t)TRUE + ); + + + for ( n = stop_index; n < small_ds_size; n++ ) { + + if ( *(ptr_1 + n) != 0 ) { + + data_ok = FALSE; + *(ptr_1 + n) = 0; + } + } + + VRFY((data_ok == TRUE), + "small ds cb slice write to large ds slice data good."); + + l++; + + } while ( ( large_rank > 2 ) && + ( (small_rank - 1) <= 1 ) && + ( l < edge_size ) ); + k++; + } while ( ( large_rank > 3 ) && + ( (small_rank - 1) <= 2 ) && + ( k < edge_size ) ); + j++; + } while ( ( large_rank > 4 ) && + ( (small_rank - 1) <= 3 ) && + ( j < edge_size ) ); + + + /* Close dataspaces */ + ret = H5Sclose(full_mem_small_ds_sid); + VRFY((ret != FAIL), "H5Sclose(full_mem_small_ds_sid) succeeded"); + + ret = H5Sclose(full_file_small_ds_sid); + VRFY((ret != FAIL), "H5Sclose(full_file_small_ds_sid) succeeded"); + + ret = H5Sclose(mem_small_ds_sid); + VRFY((ret != FAIL), "H5Sclose(mem_small_ds_sid) succeeded"); + + ret = H5Sclose(file_small_ds_sid_0); + VRFY((ret != FAIL), "H5Sclose(file_small_ds_sid_0) succeeded"); + + ret = H5Sclose(file_small_ds_sid_1); + VRFY((ret != FAIL), "H5Sclose(file_small_ds_sid_1) succeeded"); + + ret = H5Sclose(small_ds_slice_sid); + VRFY((ret != FAIL), "H5Sclose(small_ds_slice_sid) succeeded"); + + ret = H5Sclose(full_mem_large_ds_sid); + VRFY((ret != FAIL), "H5Sclose(full_mem_large_ds_sid) succeeded"); + + ret = H5Sclose(full_file_large_ds_sid); + VRFY((ret != FAIL), "H5Sclose(full_file_large_ds_sid) succeeded"); + + ret = H5Sclose(mem_large_ds_sid); + VRFY((ret != FAIL), "H5Sclose(mem_large_ds_sid) succeeded"); + + ret = H5Sclose(file_large_ds_sid_0); + VRFY((ret != FAIL), "H5Sclose(mem_large_ds_sid) succeeded"); + + ret = H5Sclose(file_large_ds_sid_1); + VRFY((ret != FAIL), "H5Sclose(mem_large_ds_sid) succeeded"); + + ret = H5Sclose(mem_large_ds_process_slice_sid); + VRFY((ret != FAIL), "H5Sclose(mem_large_ds_process_slice_sid) succeeded"); + + ret = H5Sclose(file_large_ds_process_slice_sid); + VRFY((ret != FAIL), "H5Sclose(file_large_ds_process_slice_sid) succeeded"); + + ret = H5Sclose(large_ds_slice_sid); + VRFY((ret != FAIL), "H5Sclose(large_ds_slice_sid) succeeded"); + + + /* Close Datasets */ + ret = H5Dclose(small_dataset); + VRFY((ret != FAIL), "H5Dclose(small_dataset) succeeded"); + + ret = H5Dclose(large_dataset); + VRFY((ret != FAIL), "H5Dclose(large_dataset) succeeded"); + + + /* close the file collectively */ + MESG("about to close file."); + ret = H5Fclose(fid); + VRFY((ret != FAIL), "file close succeeded"); + + /* Free memory buffers */ + if ( small_ds_buf_0 != NULL ) HDfree(small_ds_buf_0); + if ( small_ds_buf_1 != NULL ) HDfree(small_ds_buf_1); + if ( small_ds_buf_2 != NULL ) HDfree(small_ds_buf_2); + if ( small_ds_slice_buf != NULL ) HDfree(small_ds_slice_buf); + + if ( large_ds_buf_0 != NULL ) HDfree(large_ds_buf_0); + if ( large_ds_buf_1 != NULL ) HDfree(large_ds_buf_1); + if ( large_ds_buf_2 != NULL ) HDfree(large_ds_buf_2); + if ( large_ds_slice_buf != NULL ) HDfree(large_ds_slice_buf); + + return; + +} /* checker_board_hyperslab_dr_pio_test__run_test() */ + + +/*------------------------------------------------------------------------- + * Function: checker_board_hyperslab_dr_pio_test() + * + * Purpose: Test I/O to/from hyperslab selections of different rank in + * the parallel case. + * + * Return: void + * + * Programmer: JRM -- 9/18/09 + * + * Modifications: + * + * Modified function to take a sample of the run times + * of the different tests, and skip some of them if + * run times are too long. + * + * We need to do this because Lustre runns very slowly + * if two or more processes are banging on the same + * block of memory. + * JRM -- 9/10/10 + * Break this one big test into 4 smaller tests according + * to {independent,collective}x{contigous,chunked} datasets. + * AKC -- 2010/01/17 + * + *------------------------------------------------------------------------- + */ + +void +checker_board_hyperslab_dr_pio_test(ShapeSameTestMethods sstest_type) +{ + int test_num = 0; + int edge_size = 10; + int checker_edge_size = 3; + int chunk_edge_size = 0; + int small_rank = 3; + int large_rank = 4; + int skips[4] = {0, 0, 0, 0}; + int skip_counters[4] = {0, 0, 0, 0}; + int tests_skiped[4] = {0, 0, 0, 0}; + int mpi_result; + hid_t dset_type = H5T_NATIVE_UINT; +#ifdef H5_HAVE_GETTIMEOFDAY + hbool_t time_tests = TRUE; + hbool_t display_skips = FALSE; + int local_express_test; + int express_test; + int i; + int samples = 0; + int sample_size = 1; + int mpi_size = -1; + int mpi_rank = -1; + int local_skips[4]; + const int ind_contig_idx = 0; + const int col_contig_idx = 1; + const int ind_chunked_idx = 2; + const int col_chunked_idx = 3; + const int test_types = 4; + long long max_test_time = 3000000; /* for one test */ + long long sample_times[4] = {0, 0, 0, 0}; + struct timeval timeval_a; + struct timeval timeval_b; + + MPI_Comm_size(MPI_COMM_WORLD, &mpi_size); + MPI_Comm_rank(MPI_COMM_WORLD, &mpi_rank); +#endif /* H5_HAVE_GETTIMEOFDAY */ + + local_express_test = GetTestExpress(); + + HDcompile_assert(sizeof(uint32_t) == sizeof(unsigned)); + + mpi_result = MPI_Allreduce((void *)&local_express_test, + (void *)&express_test, + 1, + MPI_INT, + MPI_MAX, + MPI_COMM_WORLD); + + VRFY((mpi_result == MPI_SUCCESS ), "MPI_Allreduce(0) succeeded"); + +#if 0 + { + int DebugWait = 1; + + while (DebugWait) ; + } +#endif + + for ( large_rank = 3; large_rank <= PAR_SS_DR_MAX_RANK; large_rank++ ) { + + for ( small_rank = 2; small_rank < large_rank; small_rank++ ) { + switch(sstest_type){ + case IND_CONTIG: + /* contiguous data set, independent I/O */ + chunk_edge_size = 0; + if ( skip_counters[ind_contig_idx] < skips[ind_contig_idx] ) { + + skip_counters[ind_contig_idx]++; + tests_skiped[ind_contig_idx]++; + printf("Test skipped\n"); + } else { + skip_counters[ind_contig_idx] = 0; + START_TIMER(time_tests, timeval_a, "HDgettimeofday(0) succeeds."); + + checker_board_hyperslab_dr_pio_test__run_test(test_num, + edge_size, + checker_edge_size, + chunk_edge_size, + small_rank, + large_rank, + FALSE, + dset_type, + express_test); + STOP_TIMER_AND_UPDATE(time_tests, timeval_b, \ + "HDgettimeofday(1) succeeds.", \ + sample_times[ind_contig_idx]); + + } + test_num++; + break; + /* end of case IND_CONTIG */ + + case COL_CONTIG: + /* contiguous data set, collective I/O */ + chunk_edge_size = 0; + if ( skip_counters[col_contig_idx] < skips[col_contig_idx] ) { + + skip_counters[col_contig_idx]++; + tests_skiped[col_contig_idx]++; + printf("Test skipped\n"); + } else { + skip_counters[col_contig_idx] = 0; + START_TIMER(time_tests, timeval_a, "HDgettimeofday(2) succeeds."); + + checker_board_hyperslab_dr_pio_test__run_test(test_num, + edge_size, + checker_edge_size, + chunk_edge_size, + small_rank, + large_rank, + TRUE, + dset_type, + express_test); + STOP_TIMER_AND_UPDATE(time_tests, timeval_b, \ + "HDgettimeofday(3) succeeds.", \ + sample_times[col_contig_idx]); + + } + test_num++; + break; + /* end of case COL_CONTIG */ + + case IND_CHUNKED: + /* chunked data set, independent I/O */ + chunk_edge_size = 5; + if ( skip_counters[ind_chunked_idx] < skips[ind_chunked_idx] ) { + + skip_counters[ind_chunked_idx]++; + tests_skiped[ind_chunked_idx]++; + printf("Test skipped\n"); + } else { + skip_counters[ind_chunked_idx] = 0; + START_TIMER(time_tests, timeval_a, "HDgettimeofday(4) succeeds."); + + checker_board_hyperslab_dr_pio_test__run_test(test_num, + edge_size, + checker_edge_size, + chunk_edge_size, + small_rank, + large_rank, + FALSE, + dset_type, + express_test); + STOP_TIMER_AND_UPDATE(time_tests, timeval_b, \ + "HDgettimeofday(5) succeeds.", \ + sample_times[ind_chunked_idx]); + + } + test_num++; + break; + /* end of case IND_CHUNKED */ + + case COL_CHUNKED: + /* chunked data set, collective I/O */ + chunk_edge_size = 5; + if ( skip_counters[col_chunked_idx] < skips[col_chunked_idx] ) { + + skip_counters[col_chunked_idx]++; + tests_skiped[col_chunked_idx]++; + printf("Test skipped\n"); + } else { + skip_counters[col_chunked_idx] = 0; + START_TIMER(time_tests, timeval_a, "HDgettimeofday(6) succeeds."); + + checker_board_hyperslab_dr_pio_test__run_test(test_num, + edge_size, + checker_edge_size, + chunk_edge_size, + small_rank, + large_rank, + TRUE, + dset_type, + express_test); + STOP_TIMER_AND_UPDATE(time_tests, timeval_b, \ + "HDgettimeofday(7) succeeds.", \ + sample_times[col_chunked_idx]); + + } + test_num++; + break; + /* end of case COL_CHUNKED */ + } /* end of switch(sstest_type) */ + +#ifdef H5_HAVE_GETTIMEOFDAY + if ( time_tests ) { + + samples++; + + if ( samples >= sample_size ) { + + int result; + + time_tests = FALSE; + + max_test_time = ((long long)sample_size) * max_test_time; + + for ( i = 0; i < test_types; i++ ) { + + if ( ( express_test == 0 ) || + ( sample_times[i] <= max_test_time ) ) { + + local_skips[i] = 0; + + } else { + + local_skips[i] = (int)(sample_times[i] / max_test_time); + } + } + + /* do an MPI_Allreduce() with the skips vector to ensure that + * all processes agree on its contents. + */ + result = MPI_Allreduce((void *)local_skips, + (void *)skips, + test_types, + MPI_INT, + MPI_MAX, + MPI_COMM_WORLD); + VRFY((result == MPI_SUCCESS ), "MPI_Allreduce() succeeded"); + } + } +#endif /* H5_HAVE_GETTIMEOFDAY */ + + } + } + +#ifdef H5_HAVE_GETTIMEOFDAY + if ( ( MAINPROCESS ) && ( display_skips ) ) { + + HDfprintf(stdout, "***********************************\n"); + HDfprintf(stdout, "express test = %d.\n", express_test); + HDfprintf(stdout, "sample_size = %d, max_test_time = %lld.\n", + sample_size, max_test_time); + HDfprintf(stdout, "sample_times[] = %lld, %lld, %lld, %lld.\n", + sample_times[ind_contig_idx], + sample_times[col_contig_idx], + sample_times[ind_chunked_idx], + sample_times[col_chunked_idx]); + HDfprintf(stdout, "skips[] = %d, %d, %d, %d.\n", + skips[ind_contig_idx], + skips[col_contig_idx], + skips[ind_chunked_idx], + skips[col_chunked_idx]); + HDfprintf(stdout, "tests_skiped[] = %d, %d, %d, %d.\n", + tests_skiped[ind_contig_idx], + tests_skiped[col_contig_idx], + tests_skiped[ind_chunked_idx], + tests_skiped[col_chunked_idx]); + HDfprintf(stdout, "test_num = %d.\n", test_num); + HDfprintf(stdout, "***********************************\n"); + } +#endif /* H5_HAVE_GETTIMEOFDAY */ + + return; + +} /* checker_board_hyperslab_dr_pio_test() */ + +/* Main Body. Here for now, may have to move them to a separated file later. */ + +/* + * Main driver of the Parallel HDF5 tests + */ + +#include "testphdf5.h" + +#ifndef PATH_MAX +#define PATH_MAX 512 +#endif /* !PATH_MAX */ + +/* global variables */ +int dim0; +int dim1; +int chunkdim0; +int chunkdim1; +int nerrors = 0; /* errors count */ +int ndatasets = 300; /* number of datasets to create*/ +int ngroups = 512; /* number of groups to create in root + * group. */ +int facc_type = FACC_MPIO; /*Test file access type */ +int dxfer_coll_type = DXFER_COLLECTIVE_IO; + +H5E_auto2_t old_func; /* previous error handler */ +void *old_client_data; /* previous error handler arg.*/ + +/* other option flags */ + +/* FILENAME and filenames must have the same number of names. + * Use PARATESTFILE in general and use a separated filename only if the file + * created in one test is accessed by a different test. + * filenames[0] is reserved as the file name for PARATESTFILE. + */ +#define NFILENAME 2 +#define PARATESTFILE filenames[0] +const char *FILENAME[NFILENAME]={ + "ShapeSameTest", + NULL}; +char filenames[NFILENAME][PATH_MAX]; +hid_t fapl; /* file access property list */ + +#ifdef USE_PAUSE +/* pause the process for a moment to allow debugger to attach if desired. */ +/* Will pause more if greenlight file is not persent but will eventually */ +/* continue. */ +#include <sys/types.h> +#include <sys/stat.h> + +void pause_proc(void) +{ + + int pid; + h5_stat_t statbuf; + char greenlight[] = "go"; + int maxloop = 10; + int loops = 0; + int time_int = 10; + + /* mpi variables */ + int mpi_size, mpi_rank; + int mpi_namelen; + char mpi_name[MPI_MAX_PROCESSOR_NAME]; + + pid = getpid(); + MPI_Comm_size(MPI_COMM_WORLD, &mpi_size); + MPI_Comm_rank(MPI_COMM_WORLD, &mpi_rank); + MPI_Get_processor_name(mpi_name, &mpi_namelen); + + if (MAINPROCESS) + while ((stat(greenlight, &statbuf) == -1) && loops < maxloop){ + if (!loops++){ + printf("Proc %d (%*s, %d): to debug, attach %d\n", + mpi_rank, mpi_namelen, mpi_name, pid, pid); + } + printf("waiting(%ds) for file %s ...\n", time_int, greenlight); + fflush(stdout); + sleep(time_int); + } + MPI_Barrier(MPI_COMM_WORLD); +} + +/* Use the Profile feature of MPI to call the pause_proc() */ +int MPI_Init(int *argc, char ***argv) +{ + int ret_code; + ret_code=PMPI_Init(argc, argv); + pause_proc(); + return (ret_code); +} +#endif /* USE_PAUSE */ + + +/* + * Show command usage + */ +static void +usage(void) +{ + printf(" [-r] [-w] [-m<n_datasets>] [-n<n_groups>] " + "[-o] [-f <prefix>] [-d <dim0> <dim1>]\n"); + printf("\t-m<n_datasets>" + "\tset number of datasets for the multiple dataset test\n"); + printf("\t-n<n_groups>" + "\tset number of groups for the multiple group test\n"); + printf("\t-f <prefix>\tfilename prefix\n"); + printf("\t-2\t\tuse Split-file together with MPIO\n"); + printf("\t-p\t\tuse combo MPI-POSIX driver\n"); + printf("\t-d <factor0> <factor1>\tdataset dimensions factors. Defaults (%d,%d)\n", + ROW_FACTOR, COL_FACTOR); + printf("\t-c <dim0> <dim1>\tdataset chunk dimensions. Defaults (dim0/10,dim1/10)\n"); + printf("\n"); +} + + +/* + * parse the command line options + */ +static int +parse_options(int argc, char **argv) +{ + int mpi_size, mpi_rank; /* mpi variables */ + + MPI_Comm_size(MPI_COMM_WORLD, &mpi_size); + MPI_Comm_rank(MPI_COMM_WORLD, &mpi_rank); + + /* setup default chunk-size. Make sure sizes are > 0 */ + + chunkdim0 = (dim0+9)/10; + chunkdim1 = (dim1+9)/10; + + while (--argc){ + if (**(++argv) != '-'){ + break; + }else{ + switch(*(*argv+1)){ + case 'm': ndatasets = atoi((*argv+1)+1); + if (ndatasets < 0){ + nerrors++; + return(1); + } + break; + case 'n': ngroups = atoi((*argv+1)+1); + if (ngroups < 0){ + nerrors++; + return(1); + } + break; + case 'f': if (--argc < 1) { + nerrors++; + return(1); + } + if (**(++argv) == '-') { + nerrors++; + return(1); + } + paraprefix = *argv; + break; + case 'p': /* Use the MPI-POSIX driver access */ + facc_type = FACC_MPIPOSIX; + break; + case 'i': /* Collective MPI-IO access with independent IO */ + dxfer_coll_type = DXFER_INDEPENDENT_IO; + break; + case '2': /* Use the split-file driver with MPIO access */ + /* Can use $HDF5_METAPREFIX to define the */ + /* meta-file-prefix. */ + facc_type = FACC_MPIO | FACC_SPLIT; + break; + case 'd': /* dimensizes */ + if (--argc < 2){ + nerrors++; + return(1); + } + dim0 = atoi(*(++argv))*mpi_size; + argc--; + dim1 = atoi(*(++argv))*mpi_size; + /* set default chunkdim sizes too */ + chunkdim0 = (dim0+9)/10; + chunkdim1 = (dim1+9)/10; + break; + case 'c': /* chunk dimensions */ + if (--argc < 2){ + nerrors++; + return(1); + } + chunkdim0 = atoi(*(++argv)); + argc--; + chunkdim1 = atoi(*(++argv)); + break; + case 'h': /* print help message--return with nerrors set */ + return(1); + default: printf("Illegal option(%s)\n", *argv); + nerrors++; + return(1); + } + } + } /*while*/ + + /* check validity of dimension and chunk sizes */ + if (dim0 <= 0 || dim1 <= 0){ + printf("Illegal dim sizes (%d, %d)\n", dim0, dim1); + nerrors++; + return(1); + } + if (chunkdim0 <= 0 || chunkdim1 <= 0){ + printf("Illegal chunkdim sizes (%d, %d)\n", chunkdim0, chunkdim1); + nerrors++; + return(1); + } + + /* Make sure datasets can be divided into equal portions by the processes */ + if ((dim0 % mpi_size) || (dim1 % mpi_size)){ + if (MAINPROCESS) + printf("dim0(%d) and dim1(%d) must be multiples of processes(%d)\n", + dim0, dim1, mpi_size); + nerrors++; + return(1); + } + + /* compose the test filenames */ + { + int i, n; + + n = sizeof(FILENAME)/sizeof(FILENAME[0]) - 1; /* exclude the NULL */ + + for (i=0; i < n; i++) + if (h5_fixname(FILENAME[i],fapl,filenames[i],sizeof(filenames[i])) + == NULL){ + printf("h5_fixname failed\n"); + nerrors++; + return(1); + } + printf("Test filenames are:\n"); + for (i=0; i < n; i++) + printf(" %s\n", filenames[i]); + } + + return(0); +} + + +/* + * Create the appropriate File access property list + */ +hid_t +create_faccess_plist(MPI_Comm comm, MPI_Info info, int l_facc_type, + hbool_t use_gpfs) +{ + hid_t ret_pl = -1; + herr_t ret; /* generic return value */ + int mpi_rank; /* mpi variables */ + + /* need the rank for error checking macros */ + MPI_Comm_rank(MPI_COMM_WORLD, &mpi_rank); + + ret_pl = H5Pcreate (H5P_FILE_ACCESS); + VRFY((ret_pl >= 0), "H5P_FILE_ACCESS"); + + if (l_facc_type == FACC_DEFAULT) + return (ret_pl); + + if (l_facc_type == FACC_MPIO){ + /* set Parallel access with communicator */ + ret = H5Pset_fapl_mpio(ret_pl, comm, info); + VRFY((ret >= 0), ""); + return(ret_pl); + } + + if (l_facc_type == (FACC_MPIO | FACC_SPLIT)){ + hid_t mpio_pl; + + mpio_pl = H5Pcreate (H5P_FILE_ACCESS); + VRFY((mpio_pl >= 0), ""); + /* set Parallel access with communicator */ + ret = H5Pset_fapl_mpio(mpio_pl, comm, info); + VRFY((ret >= 0), ""); + + /* setup file access template */ + ret_pl = H5Pcreate (H5P_FILE_ACCESS); + VRFY((ret_pl >= 0), ""); + /* set Parallel access with communicator */ + ret = H5Pset_fapl_split(ret_pl, ".meta", mpio_pl, ".raw", mpio_pl); + VRFY((ret >= 0), "H5Pset_fapl_split succeeded"); + H5Pclose(mpio_pl); + return(ret_pl); + } + + if (l_facc_type == FACC_MPIPOSIX) { + /* set Parallel access with communicator */ + ret = H5Pset_fapl_mpiposix(ret_pl, comm, use_gpfs); + VRFY((ret >= 0), "H5Pset_fapl_mpiposix succeeded"); + return(ret_pl); + } + + /* unknown file access types */ + return (ret_pl); +} + + +/* Shape Same test using contigous hyperslab using independent IO on contigous datasets */ +static void +sscontig1(void) +{ + contig_hyperslab_dr_pio_test(IND_CONTIG); +} + +/* Shape Same test using contigous hyperslab using collective IO on contigous datasets */ +static void +sscontig2(void) +{ + contig_hyperslab_dr_pio_test(COL_CONTIG); +} + +/* Shape Same test using contigous hyperslab using independent IO on chunked datasets */ +static void +sscontig3(void) +{ + contig_hyperslab_dr_pio_test(IND_CHUNKED); +} + +/* Shape Same test using contigous hyperslab using collective IO on chunked datasets */ +static void +sscontig4(void) +{ + contig_hyperslab_dr_pio_test(COL_CHUNKED); +} + + +/* Shape Same test using checker hyperslab using independent IO on contigous datasets */ +static void +sschecker1(void) +{ + checker_board_hyperslab_dr_pio_test(IND_CONTIG); +} + +/* Shape Same test using checker hyperslab using collective IO on contigous datasets */ +static void +sschecker2(void) +{ + checker_board_hyperslab_dr_pio_test(COL_CONTIG); +} + +/* Shape Same test using checker hyperslab using independent IO on chunked datasets */ +static void +sschecker3(void) +{ + checker_board_hyperslab_dr_pio_test(IND_CHUNKED); +} + +/* Shape Same test using checker hyperslab using collective IO on chunked datasets */ +static void +sschecker4(void) +{ + checker_board_hyperslab_dr_pio_test(COL_CHUNKED); +} + + +int main(int argc, char **argv) +{ + int mpi_size, mpi_rank; /* mpi variables */ + H5Ptest_param_t ndsets_params, ngroups_params; + H5Ptest_param_t collngroups_params; + H5Ptest_param_t io_mode_confusion_params; + H5Ptest_param_t rr_obj_flush_confusion_params; + + /* Un-buffer the stdout and stderr */ + setbuf(stderr, NULL); + setbuf(stdout, NULL); + + MPI_Init(&argc, &argv); + MPI_Comm_size(MPI_COMM_WORLD, &mpi_size); + MPI_Comm_rank(MPI_COMM_WORLD, &mpi_rank); + + dim0 = ROW_FACTOR*mpi_size; + dim1 = COL_FACTOR*mpi_size; + + if (MAINPROCESS){ + printf("===================================\n"); + printf("Shape Same Tests Start\n"); + printf("===================================\n"); + } + + /* Attempt to turn off atexit post processing so that in case errors + * happen during the test and the process is aborted, it will not get + * hang in the atexit post processing in which it may try to make MPI + * calls. By then, MPI calls may not work. + */ + if (H5dont_atexit() < 0){ + printf("Failed to turn off atexit processing. Continue.\n", mpi_rank); + }; + H5open(); + h5_show_hostname(); + + /* Initialize testing framework */ + TestInit(argv[0], usage, parse_options); + + /* Shape Same tests using contigous hyperslab */ + AddTest("sscontig1", sscontig1, NULL, + "Shape Same, contigous hyperslab, ind IO, contig datasets", PARATESTFILE); + AddTest("sscontig2", sscontig2, NULL, + "Shape Same, contigous hyperslab, col IO, contig datasets", PARATESTFILE); + AddTest("sscontig3", sscontig3, NULL, + "Shape Same, contigous hyperslab, ind IO, chunked datasets", PARATESTFILE); + AddTest("sscontig4", sscontig4, NULL, + "Shape Same, contigous hyperslab, col IO, chunked datasets", PARATESTFILE); + + /* Shape Same tests using checker board hyperslab */ + AddTest("sschecker1", sschecker1, NULL, + "Shape Same, checker hyperslab, ind IO, contig datasets", PARATESTFILE); + AddTest("sschecker2", sschecker2, NULL, + "Shape Same, checker hyperslab, col IO, contig datasets", PARATESTFILE); + AddTest("sschecker3", sschecker3, NULL, + "Shape Same, checker hyperslab, ind IO, chunked datasets", PARATESTFILE); + AddTest("sschecker4", sschecker4, NULL, + "Shape Same, checker hyperslab, col IO, chunked datasets", PARATESTFILE); + + /* Display testing information */ + TestInfo(argv[0]); + + /* setup file access property list */ + fapl = H5Pcreate (H5P_FILE_ACCESS); + H5Pset_fapl_mpio(fapl, MPI_COMM_WORLD, MPI_INFO_NULL); + + /* Parse command line arguments */ + TestParseCmdLine(argc, argv); + + if (facc_type == FACC_MPIPOSIX && MAINPROCESS){ + printf("===================================\n" + " Using MPIPOSIX driver\n" + "===================================\n"); + } + + if (dxfer_coll_type == DXFER_INDEPENDENT_IO && MAINPROCESS){ + printf("===================================\n" + " Using Independent I/O with file set view to replace collective I/O \n" + "===================================\n"); + } + + + /* Perform requested testing */ + PerformTests(); + + /* make sure all processes are finished before final report, cleanup + * and exit. + */ + MPI_Barrier(MPI_COMM_WORLD); + + /* Display test summary, if requested */ + if (MAINPROCESS && GetTestSummary()) + TestSummary(); + + /* Clean up test files */ + h5_cleanup(FILENAME, fapl); + + nerrors += GetTestNumErrs(); + + /* Gather errors from all processes */ + { + int temp; + MPI_Allreduce(&nerrors, &temp, 1, MPI_INT, MPI_MAX, MPI_COMM_WORLD); + nerrors=temp; + } + + if (MAINPROCESS){ /* only process 0 reports */ + printf("===================================\n"); + if (nerrors) + printf("***PHDF5 tests detected %d errors***\n", nerrors); + else + printf("PHDF5 tests finished with no errors\n"); + printf("===================================\n"); + } + /* close HDF5 library */ + H5close(); + + /* MPI_Finalize must be called AFTER H5close which may use MPI calls */ + MPI_Finalize(); + + /* cannot just return (nerrors) because exit code is limited to 1byte */ + return(nerrors!=0); +} |