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authorQuincey Koziol <koziol@hdfgroup.org>2017-01-29 07:21:22 (GMT)
committerQuincey Koziol <koziol@hdfgroup.org>2017-01-29 07:21:22 (GMT)
commit3ad18072eba378ca1f598d33cc83587e8a76880f (patch)
tree63f600947a8d56c26a7b850ebb41fb8e688ecab9 /test
parent1949d5756d424be0b23fc127fc99140374a7dd13 (diff)
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Add missing files
Diffstat (limited to 'test')
-rw-r--r--test/cache_image.c6490
-rw-r--r--test/genall5.c3893
-rw-r--r--test/genall5.h53
3 files changed, 10436 insertions, 0 deletions
diff --git a/test/cache_image.c b/test/cache_image.c
new file mode 100644
index 0000000..c91914d
--- /dev/null
+++ b/test/cache_image.c
@@ -0,0 +1,6490 @@
+/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *
+ * Copyright by The HDF Group. *
+ * Copyright by the Board of Trustees of the University of Illinois. *
+ * 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. *
+ * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
+
+/* Programmer: John Mainzer
+ * 7/13/15
+ *
+ * This file contains tests specific to the cache image
+ * feature implemented in H5C.c
+ */
+#include "cache_common.h"
+#include "genall5.h"
+
+/* global variable declarations: */
+
+
+const char *FILENAMES[] = {
+ "cache_image_test",
+ NULL
+};
+
+/* local utility function declarations */
+static void create_datasets(hid_t file_id, int min_dset, int max_dset);
+static void delete_datasets(hid_t file_id, int min_dset, int max_dset);
+static void open_hdf5_file(hbool_t create_file, hbool_t mdci_sbem_expected,
+ hbool_t read_only, hbool_t set_mdci_fapl, hbool_t config_fsm,
+ const char *hdf_file_name, unsigned cache_image_flags,
+ hid_t *file_id_ptr, H5F_t **file_ptr_ptr, H5C_t **cache_ptr_ptr);
+static void attempt_swmr_open_hdf5_file(hbool_t create_file,
+ hbool_t set_mdci_fapl, const char *hdf_file_name);
+static void verify_datasets(hid_t file_id, int min_dset, int max_dset);
+
+/* local test function declarations */
+static unsigned check_cache_image_ctl_flow_1(void);
+static unsigned check_cache_image_ctl_flow_2(void);
+static unsigned check_cache_image_ctl_flow_3(void);
+static unsigned check_cache_image_ctl_flow_4(void);
+static unsigned check_cache_image_ctl_flow_5(void);
+static unsigned check_cache_image_ctl_flow_6(void);
+
+static unsigned cache_image_smoke_check_1(void);
+static unsigned cache_image_smoke_check_2(void);
+static unsigned cache_image_smoke_check_3(void);
+static unsigned cache_image_smoke_check_4(void);
+static unsigned cache_image_smoke_check_5(void);
+static unsigned cache_image_smoke_check_6(void);
+
+static unsigned cache_image_api_error_check_1(void);
+static unsigned cache_image_api_error_check_2(void);
+static unsigned cache_image_api_error_check_3(void);
+
+
+/****************************************************************************/
+/***************************** Utility Functions ****************************/
+/****************************************************************************/
+
+/*-------------------------------------------------------------------------
+ * Function: create_datasets()
+ *
+ * Purpose: If pass is TRUE on entry, create the specified datasets
+ * in the indicated file.
+ *
+ * Datasets and their contents must be well known, as we
+ * will verify that they contain the expected data later.
+ *
+ * On failure, set pass to FALSE, and set failure_mssg
+ * to point to an appropriate failure message.
+ *
+ * Do nothing if pass is FALSE on entry.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 7/15/15
+ *
+ *-------------------------------------------------------------------------
+ */
+
+#define CHUNK_SIZE 10
+#define DSET_SIZE (40 * CHUNK_SIZE)
+#define MAX_NUM_DSETS 256
+
+static void
+create_datasets(hid_t file_id, int min_dset, int max_dset)
+{
+ const char * fcn_name = "create_datasets()";
+ char dset_name[64];
+ hbool_t show_progress = FALSE;
+ hbool_t valid_chunk;
+ hbool_t verbose = FALSE;
+ int cp = 0;
+ int i, j, k, l, m;
+ int data_chunk[CHUNK_SIZE][CHUNK_SIZE];
+ herr_t status;
+ hid_t dataspace_id = -1;
+ hid_t filespace_ids[MAX_NUM_DSETS];
+ hid_t memspace_id = -1;
+ hid_t dataset_ids[MAX_NUM_DSETS];
+ hid_t properties = -1;
+ hsize_t dims[2];
+ hsize_t a_size[2];
+ hsize_t offset[2];
+ hsize_t chunk_size[2];
+
+ if ( show_progress ) HDfprintf(stdout, "%s: cp = %d.\n", fcn_name, cp++);
+
+ HDassert(0 <= min_dset);
+ HDassert(min_dset <= max_dset);
+ HDassert(max_dset < MAX_NUM_DSETS);
+
+ /* create the datasets */
+
+ if ( pass ) {
+
+ i = min_dset;
+
+ while ( ( pass ) && ( i <= max_dset ) )
+ {
+ /* create a dataspace for the chunked dataset */
+ dims[0] = DSET_SIZE;
+ dims[1] = DSET_SIZE;
+ dataspace_id = H5Screate_simple(2, dims, NULL);
+
+ if ( dataspace_id < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Screate_simple() failed.";
+ }
+
+ /* set the dataset creation plist to specify that the raw data is
+ * to be partioned into 10X10 element chunks.
+ */
+
+ if ( pass ) {
+
+ chunk_size[0] = CHUNK_SIZE;
+ chunk_size[1] = CHUNK_SIZE;
+ properties = H5Pcreate(H5P_DATASET_CREATE);
+
+ if ( properties < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Pcreate() failed.";
+ }
+ }
+
+ if ( pass ) {
+
+ if ( H5Pset_chunk(properties, 2, chunk_size) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Pset_chunk() failed.";
+ }
+ }
+
+ /* create the dataset */
+ if ( pass ) {
+
+ sprintf(dset_name, "/dset%03d", i);
+ dataset_ids[i] = H5Dcreate2(file_id, dset_name, H5T_STD_I32BE,
+ dataspace_id, H5P_DEFAULT,
+ properties, H5P_DEFAULT);
+
+ if ( dataset_ids[i] < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Dcreate() failed.";
+ }
+ }
+
+ /* get the file space ID */
+ if ( pass ) {
+
+ filespace_ids[i] = H5Dget_space(dataset_ids[i]);
+
+ if ( filespace_ids[i] < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Dget_space() failed.";
+ }
+ }
+
+ i++;
+ }
+ }
+
+ if ( show_progress ) HDfprintf(stdout, "%s: cp = %d.\n", fcn_name, cp++);
+
+ /* create the mem space to be used to read and write chunks */
+ if ( pass ) {
+
+ dims[0] = CHUNK_SIZE;
+ dims[1] = CHUNK_SIZE;
+ memspace_id = H5Screate_simple(2, dims, NULL);
+
+ if ( memspace_id < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Screate_simple() failed.";
+ }
+ }
+
+ if ( show_progress ) HDfprintf(stdout, "%s: cp = %d.\n", fcn_name, cp++);
+
+ /* select in memory hyperslab */
+ if ( pass ) {
+
+ offset[0] = 0; /*offset of hyperslab in memory*/
+ offset[1] = 0;
+ a_size[0] = CHUNK_SIZE; /*size of hyperslab*/
+ a_size[1] = CHUNK_SIZE;
+ status = H5Sselect_hyperslab(memspace_id, H5S_SELECT_SET, offset, NULL,
+ a_size, NULL);
+
+ if ( status < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Sselect_hyperslab() failed.";
+ }
+ }
+
+ if ( show_progress ) HDfprintf(stdout, "%s: cp = %d.\n", fcn_name, cp++);
+
+ /* initialize all datasets on a round robin basis */
+ i = 0;
+ while ( ( pass ) && ( i < DSET_SIZE ) )
+ {
+ j = 0;
+ while ( ( pass ) && ( j < DSET_SIZE ) )
+ {
+ m = min_dset;
+ while ( ( pass ) && ( m <= max_dset ) )
+ {
+ /* initialize the slab */
+ for ( k = 0; k < CHUNK_SIZE; k++ )
+ {
+ for ( l = 0; l < CHUNK_SIZE; l++ )
+ {
+ data_chunk[k][l] = (DSET_SIZE * DSET_SIZE * m) +
+ (DSET_SIZE * (i + k)) + j + l;
+ }
+ }
+
+ /* select on disk hyperslab */
+ offset[0] = (hsize_t)i; /*offset of hyperslab in file*/
+ offset[1] = (hsize_t)j;
+ a_size[0] = CHUNK_SIZE; /*size of hyperslab*/
+ a_size[1] = CHUNK_SIZE;
+ status = H5Sselect_hyperslab(filespace_ids[m], H5S_SELECT_SET,
+ offset, NULL, a_size, NULL);
+
+ if ( status < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "disk H5Sselect_hyperslab() failed.";
+ }
+
+ /* write the chunk to file */
+ status = H5Dwrite(dataset_ids[m], H5T_NATIVE_INT, memspace_id,
+ filespace_ids[m], H5P_DEFAULT, data_chunk);
+
+ if ( status < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Dwrite() failed.";
+ }
+ m++;
+ }
+ j += CHUNK_SIZE;
+ }
+
+ i += CHUNK_SIZE;
+ }
+
+ if ( show_progress ) HDfprintf(stdout, "%s: cp = %d.\n", fcn_name, cp++);
+
+ /* read data from datasets and validate it */
+ i = 0;
+ while ( ( pass ) && ( i < DSET_SIZE ) )
+ {
+ j = 0;
+ while ( ( pass ) && ( j < DSET_SIZE ) )
+ {
+ m = min_dset;
+ while ( ( pass ) && ( m <= max_dset ) )
+ {
+
+ /* select on disk hyperslab */
+ offset[0] = (hsize_t)i; /* offset of hyperslab in file */
+ offset[1] = (hsize_t)j;
+ a_size[0] = CHUNK_SIZE; /* size of hyperslab */
+ a_size[1] = CHUNK_SIZE;
+ status = H5Sselect_hyperslab(filespace_ids[m], H5S_SELECT_SET,
+ offset, NULL, a_size, NULL);
+
+ if ( status < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "disk hyperslab create failed.";
+ }
+
+ /* read the chunk from file */
+ if ( pass ) {
+
+ status = H5Dread(dataset_ids[m], H5T_NATIVE_INT,
+ memspace_id, filespace_ids[m],
+ H5P_DEFAULT, data_chunk);
+
+ if ( status < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "disk hyperslab create failed.";
+ }
+ }
+
+ /* validate the slab */
+ if ( pass ) {
+
+ valid_chunk = TRUE;
+ for ( k = 0; k < CHUNK_SIZE; k++ )
+ {
+ for ( l = 0; l < CHUNK_SIZE; l++ )
+ {
+ if ( data_chunk[k][l]
+ !=
+ ((DSET_SIZE * DSET_SIZE * m) +
+ (DSET_SIZE * (i + k)) + j + l) ) {
+
+ valid_chunk = FALSE;
+
+ if ( verbose ) {
+
+ HDfprintf(stdout,
+ "data_chunk[%0d][%0d] = %0d, expect %0d.\n",
+ k, l, data_chunk[k][l],
+ ((DSET_SIZE * DSET_SIZE * m) +
+ (DSET_SIZE * (i + k)) + j + l));
+ HDfprintf(stdout,
+ "m = %d, i = %d, j = %d, k = %d, l = %d\n",
+ m, i, j, k, l);
+ }
+ }
+ }
+ }
+
+ if ( ! valid_chunk ) {
+
+ pass = FALSE;
+ failure_mssg = "slab validation failed.";
+
+ if ( verbose ) {
+
+ fprintf(stdout,
+ "Chunk (%0d, %0d) in /dset%03d is invalid.\n",
+ i, j, m);
+ }
+ }
+ }
+ m++;
+ }
+ j += CHUNK_SIZE;
+ }
+ i += CHUNK_SIZE;
+ }
+
+ if ( show_progress ) HDfprintf(stdout, "%s: cp = %d.\n", fcn_name, cp++);
+
+ /* close the file spaces */
+ i = min_dset;
+ while ( ( pass ) && ( i <= max_dset ) )
+ {
+ if ( H5Sclose(filespace_ids[i]) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Sclose() failed.";
+ }
+ i++;
+ }
+
+
+ /* close the datasets */
+ i = min_dset;
+ while ( ( pass ) && ( i <= max_dset ) )
+ {
+ if ( H5Dclose(dataset_ids[i]) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Dclose() failed.";
+ }
+ i++;
+ }
+
+ /* close the mem space */
+ if ( pass ) {
+
+ if ( H5Sclose(memspace_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Sclose(memspace_id) failed.";
+ }
+ }
+
+ return;
+
+} /* create_datasets() */
+
+
+/*-------------------------------------------------------------------------
+ * Function: delete_datasets()
+ *
+ * Purpose: If pass is TRUE on entry, verify and then delete the
+ * dataset(s) indicated by min_dset and max_dset in the
+ * indicated file.
+ *
+ * Datasets and their contents must be well know, as we
+ * will verify that they contain the expected data later.
+ *
+ * On failure, set pass to FALSE, and set failure_mssg
+ * to point to an appropriate failure message.
+ *
+ * Do nothing if pass is FALSE on entry.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 10/31/16
+ *
+ *-------------------------------------------------------------------------
+ */
+
+static void
+delete_datasets(hid_t file_id, int min_dset, int max_dset)
+{
+ const char * fcn_name = "delete_datasets()";
+ char dset_name[64];
+ hbool_t show_progress = FALSE;
+ int cp = 0;
+ int i;
+
+ if ( show_progress ) HDfprintf(stdout, "%s: cp = %d.\n", fcn_name, cp++);
+
+ HDassert(0 <= min_dset);
+ HDassert(min_dset <= max_dset);
+ HDassert(max_dset < MAX_NUM_DSETS);
+
+ if ( show_progress ) HDfprintf(stdout, "%s: cp = %d.\n", fcn_name, cp++);
+
+ /* first, verify the contents of the target dataset(s) */
+ verify_datasets(file_id, min_dset, max_dset);
+
+ if ( show_progress ) HDfprintf(stdout, "%s: cp = %d.\n", fcn_name, cp++);
+
+ /* now delete the target datasets */
+ if ( pass ) {
+
+ i = min_dset;
+
+ while ( ( pass ) && ( i <= max_dset ) )
+ {
+ sprintf(dset_name, "/dset%03d", i);
+
+ if ( H5Ldelete(file_id, dset_name, H5P_DEFAULT) < 0) {
+
+ pass = FALSE;
+ failure_mssg = "H5Ldelete() failed.";
+ }
+
+ i++;
+ }
+ }
+
+ if ( show_progress ) HDfprintf(stdout, "%s: cp = %d.\n", fcn_name, cp++);
+
+ return;
+
+} /* delete_datasets() */
+
+
+/*-------------------------------------------------------------------------
+ * Function: open_hdf5_file()
+ *
+ * Purpose: If pass is true on entry, create or open the specified HDF5
+ * and test to see if it has a metadata cache image superblock
+ * extension message.
+ *
+ * Set pass to FALSE and issue a suitable failure
+ * message if either the file contains a metadata cache image
+ * superblock extension and mdci_sbem_expected is TRUE, or
+ * vise versa.
+ *
+ * If mdci_sbem_expected is TRUE, also verify that the metadata
+ * cache has been advised of this.
+ *
+ * If read_only is TRUE, open the file read only. Otherwise
+ * open the file read/write.
+ *
+ * If set_mdci_fapl is TRUE, set the metadata cache image
+ * FAPL entry when opening the file, and verify that the
+ * metadata cache is notified.
+ *
+ * If config_fsm is TRUE, setup the persistant free space
+ * manager. Note that this flag may only be set if
+ * create_file is also TRUE.
+ *
+ * Return pointers to the cache data structure and file data
+ * structures.
+ *
+ * On failure, set pass to FALSE, and set failure_mssg
+ * to point to an appropriate failure message.
+ *
+ * Do nothing if pass is FALSE on entry.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 7/14/15
+ *
+ *-------------------------------------------------------------------------
+ */
+
+static void
+open_hdf5_file(hbool_t create_file, hbool_t mdci_sbem_expected,
+ hbool_t read_only, hbool_t set_mdci_fapl, hbool_t config_fsm,
+ const char *hdf_file_name, unsigned cache_image_flags,
+ hid_t *file_id_ptr, H5F_t ** file_ptr_ptr, H5C_t ** cache_ptr_ptr)
+{
+ const char * fcn_name = "open_hdf5_file()";
+ hbool_t show_progress = FALSE;
+ hbool_t verbose = FALSE;
+ int cp = 0;
+ hid_t fapl_id = -1;
+ hid_t fcpl_id = -1;
+ hid_t file_id = -1;
+ herr_t result;
+ H5F_t * file_ptr = NULL;
+ H5C_t * cache_ptr = NULL;
+ H5C_cache_image_ctl_t image_ctl;
+ H5AC_cache_image_config_t cache_image_config = {
+ H5AC__CURR_CACHE_IMAGE_CONFIG_VERSION,
+ TRUE,
+ FALSE,
+ H5AC__CACHE_IMAGE__ENTRY_AGEOUT__NONE};
+
+ if ( pass )
+ {
+ /* opening the file both read only and with a cache image
+ * requested is a contradiction. We resolve it by ignoring
+ * the cache image request silently.
+ */
+ if ( ( create_file && mdci_sbem_expected ) ||
+ ( create_file && read_only ) ||
+ ( config_fsm && !create_file ) ||
+ ( hdf_file_name == NULL ) ||
+ ( ( set_mdci_fapl ) && ( cache_image_flags == 0 ) ) ||
+ ( ( set_mdci_fapl ) &&
+ ( (cache_image_flags & ~H5C_CI__ALL_FLAGS) != 0 ) ) ||
+ ( file_id_ptr == NULL ) ||
+ ( file_ptr_ptr == NULL ) ||
+ ( cache_ptr_ptr == NULL ) ) {
+
+ failure_mssg =
+ "Bad param(s) on entry to open_hdf5_file().\n";
+ pass = FALSE;
+ } else if ( verbose ) {
+
+ HDfprintf(stdout, "%s: HDF file name = \"%s\".\n",
+ fcn_name, hdf_file_name);
+ }
+ }
+
+ if ( show_progress ) HDfprintf(stdout, "%s: cp = %d.\n", fcn_name, cp++);
+
+ /* create a file access propertly list. */
+ if ( pass ) {
+
+ fapl_id = H5Pcreate(H5P_FILE_ACCESS);
+
+ if ( fapl_id < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Pcreate() failed.\n";
+ }
+ }
+
+ if ( show_progress ) HDfprintf(stdout, "%s: cp = %d.\n", fcn_name, cp++);
+
+ /* call H5Pset_libver_bounds() on the fapl_id */
+ if ( pass ) {
+
+ if ( H5Pset_libver_bounds(fapl_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Pset_libver_bounds() failed.\n";
+ }
+ }
+
+ if ( show_progress ) HDfprintf(stdout, "%s: cp = %d.\n", fcn_name, cp++);
+
+ /* get metadata cache image config -- verify that it is the default */
+ if ( pass ) {
+
+ result = H5Pget_mdc_image_config(fapl_id, &cache_image_config);
+
+ if ( result < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Pget_mdc_image_config() failed.\n";
+ }
+
+ if ( ( cache_image_config.version !=
+ H5AC__CURR_CACHE_IMAGE_CONFIG_VERSION ) ||
+ ( cache_image_config.generate_image != FALSE ) ||
+ ( cache_image_config.save_resize_status != FALSE ) ||
+ ( cache_image_config.entry_ageout !=
+ H5AC__CACHE_IMAGE__ENTRY_AGEOUT__NONE ) ) {
+
+ pass = FALSE;
+ failure_mssg = "Unexpected default cache image config.\n";
+ }
+ }
+
+ if ( show_progress ) HDfprintf(stdout, "%s: cp = %d.\n", fcn_name, cp++);
+
+ /* set metadata cache image fapl entry if indicated */
+ if ( ( pass ) && ( set_mdci_fapl ) ) {
+
+ /* set cache image config fields to taste */
+ cache_image_config.generate_image = TRUE;
+ cache_image_config.save_resize_status = FALSE;
+ cache_image_config.entry_ageout = H5AC__CACHE_IMAGE__ENTRY_AGEOUT__NONE;
+
+ result = H5Pset_mdc_image_config(fapl_id, &cache_image_config);
+
+ if ( result < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Pset_mdc_image_config() failed.\n";
+ }
+ }
+
+ if ( show_progress ) HDfprintf(stdout, "%s: cp = %d.\n", fcn_name, cp++);
+
+ /* setup the persistant free space manager if indicated */
+ if ( ( pass ) && ( config_fsm ) ) {
+
+ fcpl_id = H5Pcreate(H5P_FILE_CREATE);
+
+ if ( fcpl_id <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Pcreate(H5P_FILE_CREATE) failed.";
+ }
+ }
+
+ if ( ( pass ) && ( config_fsm ) ) {
+
+ if ( H5Pset_file_space(fcpl_id, H5F_FILE_SPACE_ALL_PERSIST, 1) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Pset_file_space() failed.";
+ }
+ }
+
+ if ( show_progress ) HDfprintf(stdout, "%s: cp = %d.\n", fcn_name, cp++);
+
+ /* open the file */
+ if ( pass ) {
+
+ if ( create_file ) {
+
+ if ( fcpl_id != -1 )
+
+ file_id = H5Fcreate(hdf_file_name, H5F_ACC_TRUNC, fcpl_id, fapl_id);
+ else
+
+ file_id = H5Fcreate(hdf_file_name, H5F_ACC_TRUNC, H5P_DEFAULT, fapl_id);
+
+ } else {
+
+ if ( read_only )
+
+ file_id = H5Fopen(hdf_file_name, H5F_ACC_RDONLY, fapl_id);
+
+ else
+
+ file_id = H5Fopen(hdf_file_name, H5F_ACC_RDWR, fapl_id);
+ }
+
+ if ( file_id < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fcreate() or H5Fopen() failed.\n";
+
+ } else {
+
+ file_ptr = (struct H5F_t *)H5I_object_verify(file_id, H5I_FILE);
+
+ if ( file_ptr == NULL ) {
+
+ pass = FALSE;
+ failure_mssg = "Can't get file_ptr.";
+
+ if ( verbose ) {
+ HDfprintf(stdout, "%s: Can't get file_ptr.\n", fcn_name);
+ }
+ }
+ }
+ }
+
+ if ( show_progress ) HDfprintf(stdout, "%s: cp = %d.\n", fcn_name, cp++);
+
+ /* get a pointer to the files internal data structure and then
+ * to the cache structure
+ */
+ if ( pass ) {
+
+ if ( file_ptr->shared->cache == NULL ) {
+
+ pass = FALSE;
+ failure_mssg = "can't get cache pointer(1).\n";
+
+ } else {
+
+ cache_ptr = file_ptr->shared->cache;
+ }
+ }
+
+ if ( show_progress ) HDfprintf(stdout, "%s: cp = %d.\n", fcn_name, cp++);
+
+ /* verify expected metadata cache status */
+
+ /* get the cache image control structure from the cache, and verify
+ * that it contains the expected values.
+ *
+ * Then set the flags in this structure to the specified value.
+ */
+ if ( pass ) {
+
+ if ( H5C_get_cache_image_config(cache_ptr, &image_ctl) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "error returned by H5C_get_cache_image_config().";
+ }
+ }
+
+ if ( show_progress ) HDfprintf(stdout, "%s: cp = %d.\n", fcn_name, cp++);
+
+ if ( pass ) {
+
+ if ( set_mdci_fapl ) {
+
+ if ( read_only ) {
+
+ if ( ( image_ctl.version !=
+ H5AC__CURR_CACHE_IMAGE_CONFIG_VERSION ) ||
+ ( image_ctl.generate_image != FALSE ) ||
+ ( image_ctl.save_resize_status != FALSE ) ||
+ ( image_ctl.entry_ageout !=
+ H5AC__CACHE_IMAGE__ENTRY_AGEOUT__NONE ) ||
+ ( image_ctl.flags != H5C_CI__ALL_FLAGS ) ) {
+
+ pass = FALSE;
+ failure_mssg = "Unexpected image_ctl values(1).\n";
+ }
+ } else {
+
+ if ( ( image_ctl.version !=
+ H5AC__CURR_CACHE_IMAGE_CONFIG_VERSION ) ||
+ ( image_ctl.generate_image != TRUE ) ||
+ ( image_ctl.save_resize_status != FALSE ) ||
+ ( image_ctl.entry_ageout !=
+ H5AC__CACHE_IMAGE__ENTRY_AGEOUT__NONE ) ||
+ ( image_ctl.flags != H5C_CI__ALL_FLAGS ) ) {
+
+ pass = FALSE;
+ failure_mssg = "Unexpected image_ctl values(2).\n";
+ }
+ }
+ } else {
+
+ if ( ( image_ctl.version !=
+ H5AC__CURR_CACHE_IMAGE_CONFIG_VERSION ) ||
+ ( image_ctl.generate_image != FALSE ) ||
+ ( image_ctl.save_resize_status != FALSE ) ||
+ ( image_ctl.entry_ageout !=
+ H5AC__CACHE_IMAGE__ENTRY_AGEOUT__NONE ) ||
+ ( image_ctl.flags != H5C_CI__ALL_FLAGS ) ) {
+
+ pass = FALSE;
+ failure_mssg = "Unexpected image_ctl values(3).\n";
+ }
+ }
+ }
+
+ if ( show_progress ) HDfprintf(stdout, "%s: cp = %d.\n", fcn_name, cp++);
+
+ if ( ( pass ) && ( set_mdci_fapl ) ) {
+
+ image_ctl.flags = cache_image_flags;
+
+ if ( H5C_set_cache_image_config(file_ptr, cache_ptr, &image_ctl) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "error returned by H5C_set_cache_image_config().";
+ }
+ }
+
+ if ( show_progress ) HDfprintf(stdout, "%s: cp = %d.\n", fcn_name, cp++);
+
+ if ( pass ) {
+
+ if ( cache_ptr->close_warning_received == TRUE ) {
+
+ pass = FALSE;
+ failure_mssg = "Unexpected value of close_warning_received.\n";
+ }
+
+ if ( mdci_sbem_expected ) {
+
+ if ( read_only ) {
+
+ if ( ( cache_ptr->load_image != TRUE ) ||
+ ( cache_ptr->delete_image != FALSE ) ) {
+
+ pass = FALSE;
+ failure_mssg = "mdci sb extension message not present?\n";
+ }
+ } else {
+
+ if ( ( cache_ptr->load_image != TRUE ) ||
+ ( cache_ptr->delete_image != TRUE ) ) {
+
+ pass = FALSE;
+ failure_mssg = "mdci sb extension message not present?\n";
+ }
+ }
+ } else {
+
+ if ( ( cache_ptr->load_image == TRUE ) ||
+ ( cache_ptr->delete_image == TRUE ) ) {
+
+ pass = FALSE;
+ failure_mssg = "mdci sb extension message present?\n";
+ }
+ }
+ }
+
+ if ( show_progress ) HDfprintf(stdout, "%s: cp = %d.\n", fcn_name, cp++);
+
+ if ( pass ) {
+
+ *file_id_ptr = file_id;
+ *file_ptr_ptr = file_ptr;
+ *cache_ptr_ptr = cache_ptr;
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d -- exiting.\n", fcn_name, cp++);
+
+ return;
+
+} /* open_hdf5_file() */
+
+
+/*-------------------------------------------------------------------------
+ * Function: attempt_swmr_open_hdf5_file()
+ *
+ * Purpose: If pass is true on entry, attempt to create or open the
+ * specified HDF5 file with SWMR, and also with cache image
+ * creation if requested.
+ *
+ * In all cases, the attempted open or create should fail.
+ *
+ * Do nothing if pass is FALSE on entry.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 7/14/15
+ *
+ *-------------------------------------------------------------------------
+ */
+
+static void
+attempt_swmr_open_hdf5_file(const hbool_t create_file,
+ const hbool_t set_mdci_fapl,
+ const char * hdf_file_name)
+{
+ const char * fcn_name = "attempt_swmr_open_hdf5_file()";
+ hbool_t show_progress = FALSE;
+ int cp = 0;
+ hid_t fapl_id = -1;
+ hid_t file_id = -1;
+ herr_t result;
+ H5AC_cache_image_config_t cache_image_config = {
+ H5AC__CURR_CACHE_IMAGE_CONFIG_VERSION,
+ TRUE,
+ FALSE,
+ H5AC__CACHE_IMAGE__ENTRY_AGEOUT__NONE};
+
+ /* create a file access propertly list. */
+ if ( pass ) {
+
+ fapl_id = H5Pcreate(H5P_FILE_ACCESS);
+
+ if ( fapl_id < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Pcreate() failed.\n";
+ }
+ }
+
+ if ( show_progress ) HDfprintf(stdout, "%s: cp = %d.\n", fcn_name, cp++);
+
+ /* call H5Pset_libver_bounds() on the fapl_id */
+ if ( pass ) {
+
+ if ( H5Pset_libver_bounds(fapl_id, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST)
+ < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Pset_libver_bounds() failed.\n";
+ }
+ }
+
+ if ( show_progress ) HDfprintf(stdout, "%s: cp = %d.\n", fcn_name, cp++);
+
+ /* set metadata cache image fapl entry if indicated */
+ if ( ( pass ) && ( set_mdci_fapl ) ) {
+
+ /* set cache image config fields to taste */
+ cache_image_config.generate_image = TRUE;
+ cache_image_config.save_resize_status = FALSE;
+ cache_image_config.entry_ageout = H5AC__CACHE_IMAGE__ENTRY_AGEOUT__NONE;
+
+ result = H5Pset_mdc_image_config(fapl_id, &cache_image_config);
+
+ if ( result < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Pset_mdc_image_config() failed.\n";
+ }
+ }
+
+ if ( show_progress ) HDfprintf(stdout, "%s: cp = %d.\n", fcn_name, cp++);
+
+ /* open the file */
+ if ( pass ) {
+
+ if ( create_file ) {
+
+ H5E_BEGIN_TRY {
+ file_id = H5Fcreate(hdf_file_name, H5F_ACC_TRUNC | H5F_ACC_SWMR_WRITE,
+ H5P_DEFAULT, fapl_id);
+ } H5E_END_TRY;
+ } else {
+
+ H5E_BEGIN_TRY {
+ file_id = H5Fopen(hdf_file_name, H5F_ACC_RDWR | H5F_ACC_SWMR_WRITE, fapl_id);
+ } H5E_END_TRY;
+ }
+
+ if ( file_id >= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "SWMR H5Fcreate() or H5Fopen() succeeded.\n";
+
+ }
+ }
+
+ if ( show_progress ) HDfprintf(stdout, "%s: cp = %d.\n", fcn_name, cp++);
+
+ return;
+
+} /* attempt_swmr_open_hdf5_file() */
+
+
+/*-------------------------------------------------------------------------
+ * Function: verify_datasets()
+ *
+ * Purpose: If pass is TRUE on entry, verify that the datasets in the
+ * file exist and contain the expected data.
+ *
+ * Note that these datasets were created by
+ * create_datasets() above. Thus any changes in that
+ * function must be reflected in this function, and
+ * vise-versa.
+ *
+ * On failure, set pass to FALSE, and set failure_mssg
+ * to point to an appropriate failure message.
+ *
+ * Do nothing if pass is FALSE on entry.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 7/15/15
+ *
+ *-------------------------------------------------------------------------
+ */
+
+static void
+verify_datasets(hid_t file_id, int min_dset, int max_dset)
+{
+ const char * fcn_name = "verify_datasets()";
+ char dset_name[64];
+ hbool_t show_progress = FALSE;
+ hbool_t valid_chunk;
+ hbool_t verbose = FALSE;
+ int cp = 0;
+ int i, j, k, l, m;
+ int data_chunk[CHUNK_SIZE][CHUNK_SIZE];
+ herr_t status;
+ hid_t filespace_ids[MAX_NUM_DSETS];
+ hid_t memspace_id = -1;
+ hid_t dataset_ids[MAX_NUM_DSETS];
+ hsize_t dims[2];
+ hsize_t a_size[2];
+ hsize_t offset[2];
+
+ if ( show_progress ) HDfprintf(stdout, "%s: cp = %d.\n", fcn_name, cp++);
+
+ HDassert(0 <= min_dset);
+ HDassert(min_dset <= max_dset);
+ HDassert(max_dset < MAX_NUM_DSETS);
+
+ /* open the datasets */
+
+ if ( pass ) {
+
+ i = min_dset;
+
+ while ( ( pass ) && ( i <= max_dset ) )
+ {
+ /* open the dataset */
+ if ( pass ) {
+
+ sprintf(dset_name, "/dset%03d", i);
+ dataset_ids[i] = H5Dopen2(file_id, dset_name, H5P_DEFAULT);
+
+ if ( dataset_ids[i] < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Dopen2() failed.";
+ }
+ }
+
+ /* get the file space ID */
+ if ( pass ) {
+
+ filespace_ids[i] = H5Dget_space(dataset_ids[i]);
+
+ if ( filespace_ids[i] < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Dget_space() failed.";
+ }
+ }
+
+ i++;
+ }
+ }
+
+ if ( show_progress ) HDfprintf(stdout, "%s: cp = %d.\n", fcn_name, cp++);
+
+ /* create the mem space to be used to read and write chunks */
+ if ( pass ) {
+
+ dims[0] = CHUNK_SIZE;
+ dims[1] = CHUNK_SIZE;
+ memspace_id = H5Screate_simple(2, dims, NULL);
+
+ if ( memspace_id < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Screate_simple() failed.";
+ }
+ }
+
+ if ( show_progress ) HDfprintf(stdout, "%s: cp = %d.\n", fcn_name, cp++);
+
+ /* select in memory hyperslab */
+ if ( pass ) {
+
+ offset[0] = 0; /*offset of hyperslab in memory*/
+ offset[1] = 0;
+ a_size[0] = CHUNK_SIZE; /*size of hyperslab*/
+ a_size[1] = CHUNK_SIZE;
+ status = H5Sselect_hyperslab(memspace_id, H5S_SELECT_SET, offset, NULL,
+ a_size, NULL);
+
+ if ( status < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Sselect_hyperslab() failed.";
+ }
+ }
+
+ if ( show_progress ) HDfprintf(stdout, "%s: cp = %d.\n", fcn_name, cp++);
+
+
+ /* read data from datasets and validate it */
+ i = 0;
+ while ( ( pass ) && ( i < DSET_SIZE ) )
+ {
+ j = 0;
+ while ( ( pass ) && ( j < DSET_SIZE ) )
+ {
+ m = min_dset;
+ while ( ( pass ) && ( m <= max_dset ) )
+ {
+
+ /* select on disk hyperslab */
+ offset[0] = (hsize_t)i; /* offset of hyperslab in file */
+ offset[1] = (hsize_t)j;
+ a_size[0] = CHUNK_SIZE; /* size of hyperslab */
+ a_size[1] = CHUNK_SIZE;
+ status = H5Sselect_hyperslab(filespace_ids[m], H5S_SELECT_SET,
+ offset, NULL, a_size, NULL);
+
+ if ( status < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "disk hyperslab create failed.";
+ }
+
+ /* read the chunk from file */
+ if ( pass ) {
+
+ status = H5Dread(dataset_ids[m], H5T_NATIVE_INT,
+ memspace_id, filespace_ids[m],
+ H5P_DEFAULT, data_chunk);
+
+ if ( status < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "disk hyperslab create failed.";
+ }
+ }
+
+ /* validate the slab */
+ if ( pass ) {
+
+ valid_chunk = TRUE;
+ for ( k = 0; k < CHUNK_SIZE; k++ )
+ {
+ for ( l = 0; l < CHUNK_SIZE; l++ )
+ {
+ if ( data_chunk[k][l]
+ !=
+ ((DSET_SIZE * DSET_SIZE * m) +
+ (DSET_SIZE * (i + k)) + j + l) ) {
+
+ valid_chunk = FALSE;
+
+ if ( verbose ) {
+
+ HDfprintf(stdout,
+ "data_chunk[%0d][%0d] = %0d, expect %0d.\n",
+ k, l, data_chunk[k][l],
+ ((DSET_SIZE * DSET_SIZE * m) +
+ (DSET_SIZE * (i + k)) + j + l));
+ HDfprintf(stdout,
+ "m = %d, i = %d, j = %d, k = %d, l = %d\n",
+ m, i, j, k, l);
+ }
+ }
+ }
+ }
+
+ if ( ! valid_chunk ) {
+
+ pass = FALSE;
+ failure_mssg = "slab validation failed.";
+
+ if ( verbose ) {
+
+ fprintf(stdout,
+ "Chunk (%0d, %0d) in /dset%03d is invalid.\n",
+ i, j, m);
+ }
+ }
+ }
+ m++;
+ }
+ j += CHUNK_SIZE;
+ }
+ i += CHUNK_SIZE;
+ }
+
+ if ( show_progress ) HDfprintf(stdout, "%s: cp = %d.\n", fcn_name, cp++);
+
+ /* close the file spaces */
+ i = min_dset;
+ while ( ( pass ) && ( i <= max_dset ) )
+ {
+ if ( H5Sclose(filespace_ids[i]) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Sclose() failed.";
+ }
+ i++;
+ }
+
+
+ /* close the datasets */
+ i = min_dset;
+ while ( ( pass ) && ( i <= max_dset ) )
+ {
+ if ( H5Dclose(dataset_ids[i]) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Dclose() failed.";
+ }
+ i++;
+ }
+
+ /* close the mem space */
+ if ( pass ) {
+
+ if ( H5Sclose(memspace_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Sclose(memspace_id) failed.";
+ }
+ }
+
+ return;
+
+} /* verify_datasets() */
+
+
+/****************************************************************************/
+/******************************* Test Functions *****************************/
+/****************************************************************************/
+
+/*-------------------------------------------------------------------------
+ * Function: check_cache_image_ctl_flow_1()
+ *
+ * Purpose: This test is one of a sequence of control flow tests intended
+ * to verify that control flow for the cache image feature works
+ * as expected.
+ *
+ * This test is an initial smoke check, so the sequence of
+ * operations is relatively simple. In particular, we are
+ * testing:
+ *
+ * i) Creation of file with cache image FAPL entry set
+ * and insertion of metadata cache image superblock
+ * message on file close.
+ *
+ * ii) Open of file with metadata cache image superblock
+ * message, transmission of message to metadata cache,
+ * and deletion of superblock message prior to close.
+ *
+ * Note that in all cases we are performing operations on the
+ * file. While this is the typical case, we must repeat this
+ * test without operations on the file.
+ *
+ * 1) Create a HDF5 file with the cache image FAPL entry.
+ *
+ * Verify that the cache is informed of the cache image
+ * FAPL entry.
+ *
+ * Set flags forcing creation of metadata cache image
+ * super block extension message only.
+ *
+ * 2) Create some datasets in the file.
+ *
+ * 3) Close the file.
+ *
+ * 4) Open the file.
+ *
+ * Verify that the metadata cache is instructed
+ * to load the metadata cache image, and that the
+ * supplied address and length are HADDR_UNDEF and
+ * zero respectively. Note that these values indicate
+ * that the metadata image block doesn't exist.
+ *
+ * 5) Open a dataset.
+ *
+ * Verify that the metadata cache image superblock
+ * extension message has been deleted.
+ *
+ * 6) Close the file.
+ *
+ * 7) Open the file.
+ *
+ * Verify that the file doesn't contain a metadata cache
+ * image superblock extension message.
+ *
+ * 8) Close the file.
+ *
+ * 9) Delete the file.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 7/15/15
+ *
+ *-------------------------------------------------------------------------
+ */
+
+static unsigned
+check_cache_image_ctl_flow_1(void)
+{
+ const char * fcn_name = "check_cache_image_ctl_flow_1()";
+ char filename[512];
+ hbool_t show_progress = FALSE;
+ hid_t file_id = -1;
+ H5F_t *file_ptr = NULL;
+ H5C_t *cache_ptr = NULL;
+ int cp = 0;
+
+ TESTING("metadata cache image control flow test 1");
+
+ pass = TRUE;
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* setup the file name */
+ if ( pass ) {
+
+ if ( h5_fixname(FILENAMES[0], H5P_DEFAULT, filename, sizeof(filename))
+ == NULL ) {
+
+ pass = FALSE;
+ failure_mssg = "h5_fixname() failed.\n";
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 1) Create a HDF5 file with the cache image FAPL entry.
+ *
+ * Verify that the cache is informed of the cache image FAPL entry.
+ *
+ * Set flags forcing creation of metadata cache image super block
+ * extension message only.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ TRUE,
+ /* mdci_sbem_expected */ FALSE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ TRUE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ H5C_CI__GEN_MDCI_SBE_MESG,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 2) Create some datasets in the file. */
+
+ if ( pass ) {
+
+ create_datasets(file_id, 0, 5);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 3) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 4) Open the file.
+ *
+ * Verify that the metadata cache is instructed to load the
+ * metadata cache image, and that the supplied address and length
+ * are HADDR_UNDEF and zero respectively. Note that these values
+ * indicate that the metadata image block doesn't exist.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ TRUE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ FALSE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ 0,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 5) Open and close a dataset.
+ *
+ * Verify that the metadata cache image superblock
+ * extension message has been deleted.
+ */
+
+ if ( pass ) {
+
+ verify_datasets(file_id, 0, 5);
+ }
+
+ if ( pass ) {
+
+ /* think on how to verify that the superblock extension has been
+ * deleted, and if it is necessary to verify this directly.
+ */
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 6) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 7) Open the file.
+ *
+ * Verify that the file doesn't contain a metadata cache image
+ * superblock extension message.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ FALSE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ FALSE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ 0,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 8) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 9) Delete the file */
+
+ if ( pass ) {
+
+ if ( HDremove(filename) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "HDremove() failed.\n";
+ }
+ }
+
+ if ( pass ) { PASSED(); } else { H5_FAILED(); }
+
+ if ( ! pass )
+ HDfprintf(stdout, "%s: failure_mssg = \"%s\".\n",
+ FUNC, failure_mssg);
+
+ return !pass;
+
+} /* check_cache_image_ctl_flow_1() */
+
+
+/*-------------------------------------------------------------------------
+ * Function: check_cache_image_ctl_flow_2()
+ *
+ * Purpose: This test is one of a sequence of control flow tests intended
+ * to verify that control flow for the cache image feature works
+ * as expected.
+ *
+ * This test is an initial smoke check, so the sequence of
+ * operations is relatively simple. In particular, we are
+ * testing:
+ *
+ * i) Creation of file with cache image FAPL entry set
+ * and insertion of metadata cache image superblock
+ * message on file close.
+ *
+ * ii) Open of file with metadata cache image superblock
+ * message, transmission of message to metadata cache,
+ * and deletion of superblock message prior to close.
+ *
+ * Note that unlike the previous test, no operations are performed
+ * on the file. As a result of this, the metadata cache image
+ * message is not processed until the metadata cache receives
+ * the file close warning. (Under normal circumstances, it is
+ * processed as part of the first protect operation after the
+ * superblock is loaded.)
+ *
+ * In this particular test, we preform the following operations:
+ *
+ * 1) Create a HDF5 file with the cache image FAPL entry.
+ *
+ * Verify that the cache is informed of the cache image
+ * FAPL entry.
+ *
+ * Set flags forcing creation of metadata cache image
+ * super block extension message only.
+ *
+ * 2) Close the file.
+ *
+ * 3) Open the file.
+ *
+ * Verify that the metadata cache is instructed
+ * to load the metadata cache image, and that the
+ * supplied address and length are HADDR_UNDEF and
+ * zero respectively. Note that these values indicate
+ * that the metadata image block doesn't exist.
+ *
+ * 6) Close the file.
+ *
+ * 7) Open the file.
+ *
+ * Verify that the file doesn't contain a metadata cache
+ * image superblock extension message.
+ *
+ * 8) Close the file.
+ *
+ * 9) Delete the file.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 7/15/15
+ *
+ *-------------------------------------------------------------------------
+ */
+
+static unsigned
+check_cache_image_ctl_flow_2(void)
+{
+ const char * fcn_name = "check_cache_image_ctl_flow_2()";
+ char filename[512];
+ hbool_t show_progress = FALSE;
+ hid_t file_id = -1;
+ H5F_t *file_ptr = NULL;
+ H5C_t *cache_ptr = NULL;
+ int cp = 0;
+
+ TESTING("metadata cache image control flow test 2");
+
+ pass = TRUE;
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+ /* setup the file name */
+ if ( pass ) {
+
+ if ( h5_fixname(FILENAMES[0], H5P_DEFAULT, filename, sizeof(filename))
+ == NULL ) {
+
+ pass = FALSE;
+ failure_mssg = "h5_fixname() failed.\n";
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 1) Create a HDF5 file with the cache image FAPL entry.
+ *
+ * Verify that the cache is informed of the cache image FAPL entry.
+ *
+ * Set flags forcing creation of metadata cache image super block
+ * extension message only.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ TRUE,
+ /* mdci_sbem_expected */ FALSE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ TRUE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ H5C_CI__GEN_MDCI_SBE_MESG,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 2) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 3) Open the file.
+ *
+ * Verify that the metadata cache is instructed to load the
+ * metadata cache image, and that the supplied address and length
+ * are HADDR_UNDEF and zero respectively. Note that these values
+ * indicate that the metadata image block doesn't exist.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ TRUE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ FALSE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ 0,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 4) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 5) Open the file.
+ *
+ * Verify that the file doesn't contain a metadata cache image
+ * superblock extension message.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ FALSE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ FALSE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ 0,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 6) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 7) Delete the file */
+
+ if ( pass ) {
+
+ if ( HDremove(filename) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "HDremove() failed.\n";
+ }
+ }
+
+ if ( pass ) { PASSED(); } else { H5_FAILED(); }
+
+ if ( ! pass )
+ HDfprintf(stdout, "%s: failure_mssg = \"%s\".\n",
+ FUNC, failure_mssg);
+
+ return !pass;
+
+} /* check_cache_image_ctl_flow_2() */
+
+
+/*-------------------------------------------------------------------------
+ * Function: check_cache_image_ctl_flow_3()
+ *
+ * Purpose: This test is one of a sequence of control flow tests intended
+ * to verify that control flow for the cache image feature works
+ * as expected.
+ *
+ * The objectives of this test are to:
+ *
+ * i) Test operation of the metadata cache image FAPL
+ * entry set on open of an existing file. This
+ * should result in the insertion of a metadata
+ * cache image superblock message on file close.
+ *
+ * ii) Test operation of the metadata cache image super
+ * block extension message when it appears in a file
+ * that is opened READ ONLY.
+ *
+ * Note that in all cases we are performing operations on the
+ * file between file open and close. While this is the
+ * typical case, we must repeat this test without operations
+ * on the file.
+ *
+ * 1) Create a HDF5 file WITHOUT the cache image FAPL entry.
+ *
+ * Verify that the cache is NOT informed of the cache image
+ * FAPL entry.
+ *
+ * 2) Close the file.
+ *
+ * 3) Open the file WITH the cache image FAPL entry.
+ *
+ * Verify that the cache is informed of the cache image
+ * FAPL entry.
+ *
+ * Set flags forcing creation of metadata cache image
+ * super block extension message only.
+ *
+ * 4) Create some datasets.
+ *
+ * 5) Close the file.
+ *
+ * 6) Open the file READ ONLY.
+ *
+ * Verify that the metadata cache is instructed
+ * to load the metadata cache image, and that the
+ * supplied address and length are HADDR_UNDEF and
+ * zero respectively. Note that these values indicate
+ * that the metadata image block doesn't exist.
+ *
+ * 7) Verify the contents of the datasets.
+ *
+ * 8) Close the file.
+ *
+ * 9) Open the file READ/WRITE.
+ *
+ * Verify that the metadata cache is instructed
+ * to load the metadata cache image, and that the
+ * supplied address and length are HADDR_UNDEF and
+ * zero respectively. Note that these values indicate
+ * that the metadata image block doesn't exist.
+ *
+ * 10) Verify the contents of the datasets.
+ *
+ * 11) Close the file.
+ *
+ * 12) Open the file
+ *
+ * Verify that the file doesn't contain a metadata cache
+ * image superblock extension message.
+ *
+ * 13) Close the file.
+ *
+ * 14) Delete the file.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 7/16/15
+ *
+ *-------------------------------------------------------------------------
+ */
+
+static unsigned
+check_cache_image_ctl_flow_3(void)
+{
+ const char * fcn_name = "check_cache_image_ctl_flow_3()";
+ char filename[512];
+ hbool_t show_progress = FALSE;
+ hid_t file_id = -1;
+ H5F_t *file_ptr = NULL;
+ H5C_t *cache_ptr = NULL;
+ int cp = 0;
+
+ TESTING("metadata cache image control flow test 3");
+
+ pass = TRUE;
+
+ if ( show_progress ) /* 0 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+ /* setup the file name */
+ if ( pass ) {
+
+ if ( h5_fixname(FILENAMES[0], H5P_DEFAULT, filename, sizeof(filename))
+ == NULL ) {
+
+ pass = FALSE;
+ failure_mssg = "h5_fixname() failed.\n";
+ }
+ }
+
+ if ( show_progress ) /* 1 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+ /* 1) Create a HDF5 file WITHOUT the cache image FAPL entry.
+ *
+ * Verify that the cache is NOT informed of the cache image
+ * FAPL entry.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ TRUE,
+ /* mdci_sbem_expected */ FALSE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ FALSE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ 0,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress ) /* 2 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 2) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+ if ( show_progress ) /* 3 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 3) Open the file WITH the cache image FAPL entry.
+ *
+ * Verify that the cache is informed of the cache image FAPL entry.
+ *
+ * Set flags forcing creation of metadata cache image super block
+ * extension message only.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ FALSE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ TRUE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ H5C_CI__GEN_MDCI_SBE_MESG,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress ) /* 4 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 4) Create some datasets. */
+
+ if ( pass ) {
+
+ create_datasets(file_id, 0, 5);
+ }
+
+ if ( show_progress ) /* 5 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 5) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+ if ( show_progress ) /* 6 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 6) Open the file READ ONLY.
+ *
+ * Verify that the metadata cache is instructed
+ * to load the metadata cache image, and that the
+ * supplied address and length are HADDR_UNDEF and
+ * zero respectively. Note that these values indicate
+ * that the metadata image block doesn't exist.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ TRUE,
+ /* read_only */ TRUE,
+ /* set_mdci_fapl */ FALSE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ 0,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress ) /* 7 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 7) Verify the contents of the datasets. */
+
+ if ( pass ) {
+
+ verify_datasets(file_id, 0, 5);
+ }
+
+ if ( show_progress ) /* 8 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 8) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+ if ( show_progress ) /* 9 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 9) Open the file READ/WRITE.
+ *
+ * Verify that the metadata cache is instructed
+ * to load the metadata cache image, and that the
+ * supplied address and length are HADDR_UNDEF and
+ * zero respectively. Note that these values indicate
+ * that the metadata image block doesn't exist.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ TRUE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ FALSE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ 0,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress ) /* 10 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 10) Verify the contents of the datasets. */
+
+ if ( pass ) {
+
+ verify_datasets(file_id, 0, 5);
+ }
+
+ if ( show_progress ) /* 11 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 11) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+ if ( show_progress ) /* 12 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 12) Open the file
+ *
+ * Verify that the file doesn't contain a metadata cache
+ * image superblock extension message.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ FALSE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ FALSE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ 0,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress ) /* 13 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 13) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+ if ( show_progress ) /* 14 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 14) Delete the file. */
+
+ if ( pass ) {
+
+ if ( HDremove(filename) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "HDremove() failed.\n";
+ }
+ }
+
+
+ if ( pass ) { PASSED(); } else { H5_FAILED(); }
+
+ if ( ! pass )
+ HDfprintf(stdout, "%s: failure_mssg = \"%s\".\n",
+ FUNC, failure_mssg);
+
+ return !pass;
+
+} /* check_cache_image_ctl_flow_3() */
+
+
+/*-------------------------------------------------------------------------
+ * Function: check_cache_image_ctl_flow_4()
+ *
+ * Purpose: This test is one of a sequence of control flow tests intended
+ * to verify that control flow for the cache image feature works
+ * as expected.
+ *
+ * The objectives of this test are to:
+ *
+ * i) Test operation of the metadata cache image FAPL
+ * entry set on open of an existing file. This
+ * should result in the insertion of a metadata
+ * cache image superblock message on file close.
+ *
+ * ii) Test operation of the metadata cache image super
+ * block extension message when it appears in a file
+ * that is opened READ ONLY.
+ *
+ * In this test we avoid all file access beyond file open
+ * and close.
+ *
+ * 1) Create a HDF5 file WITHOUT the cache image FAPL entry.
+ *
+ * Verify that the cache is NOT informed of the cache image
+ * FAPL entry.
+ *
+ * 2) Close the file.
+ *
+ * 3) Open the file WITH the cache image FAPL entry.
+ *
+ * Verify that the cache is informed of the cache image
+ * FAPL entry.
+ *
+ * Set flags forcing creation of metadata cache image
+ * super block extension message only.
+ *
+ * 4) Close the file.
+ *
+ * 5) Open the file READ ONLY.
+ *
+ * Verify that the metadata cache is instructed
+ * to load the metadata cache image, and that the
+ * supplied address and length are HADDR_UNDEF and
+ * zero respectively. Note that these values indicate
+ * that the metadata image block doesn't exist.
+ *
+ * 6) Close the file.
+ *
+ * 7) Open the file READ/WRITE.
+ *
+ * Verify that the metadata cache is instructed
+ * to load the metadata cache image, and that the
+ * supplied address and length are HADDR_UNDEF and
+ * zero respectively. Note that these values indicate
+ * that the metadata image block doesn't exist.
+ *
+ * 8) Close the file.
+ *
+ * 9) Open the file
+ *
+ * Verify that the file doesn't contain a metadata cache
+ * image superblock extension message.
+ *
+ * 10) Close the file.
+ *
+ * 11) Delete the file.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 7/16/15
+ *
+ *-------------------------------------------------------------------------
+ */
+
+static unsigned
+check_cache_image_ctl_flow_4(void)
+{
+ const char * fcn_name = "check_cache_image_ctl_flow_4()";
+ char filename[512];
+ hbool_t show_progress = FALSE;
+ hid_t file_id = -1;
+ H5F_t *file_ptr = NULL;
+ H5C_t *cache_ptr = NULL;
+ int cp = 0;
+
+ TESTING("metadata cache image control flow test 4");
+
+ pass = TRUE;
+
+ if ( show_progress ) /* 0 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+ /* setup the file name */
+ if ( pass ) {
+
+ if ( h5_fixname(FILENAMES[0], H5P_DEFAULT, filename, sizeof(filename))
+ == NULL ) {
+
+ pass = FALSE;
+ failure_mssg = "h5_fixname() failed.\n";
+ }
+ }
+
+ if ( show_progress ) /* 1 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+ /* 1) Create a HDF5 file WITHOUT the cache image FAPL entry.
+ *
+ * Verify that the cache is NOT informed of the cache image
+ * FAPL entry.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ TRUE,
+ /* mdci_sbem_expected */ FALSE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ FALSE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ 0,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress ) /* 2 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 2) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+ if ( show_progress ) /* 3 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 3) Open the file WITH the cache image FAPL entry.
+ *
+ * Verify that the cache is informed of the cache image FAPL entry.
+ *
+ * Set flags forcing creation of metadata cache image super block
+ * extension message only.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ FALSE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ TRUE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ H5C_CI__GEN_MDCI_SBE_MESG,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress ) /* 4 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 4) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+ if ( show_progress ) /* 5 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 5) Open the file READ ONLY.
+ *
+ * Verify that the metadata cache is instructed
+ * to load the metadata cache image, and that the
+ * supplied address and length are HADDR_UNDEF and
+ * zero respectively. Note that these values indicate
+ * that the metadata image block doesn't exist.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ TRUE,
+ /* read_only */ TRUE,
+ /* set_mdci_fapl */ FALSE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ 0,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress ) /* 6 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 6) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+ if ( show_progress ) /* 7 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 7) Open the file READ/WRITE.
+ *
+ * Verify that the metadata cache is instructed
+ * to load the metadata cache image, and that the
+ * supplied address and length are HADDR_UNDEF and
+ * zero respectively. Note that these values indicate
+ * that the metadata image block doesn't exist.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ TRUE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ FALSE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ 0,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress ) /* 8 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 8) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+ if ( show_progress ) /* 9 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 9) Open the file
+ *
+ * Verify that the file doesn't contain a metadata cache
+ * image superblock extension message.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ FALSE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ FALSE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ 0,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress ) /* 10 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 10) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+ if ( show_progress ) /* 11 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 11) Delete the file. */
+
+ if ( pass ) {
+
+ if ( HDremove(filename) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "HDremove() failed.\n";
+ }
+ }
+
+
+ if ( pass ) { PASSED(); } else { H5_FAILED(); }
+
+ if ( ! pass )
+ HDfprintf(stdout, "%s: failure_mssg = \"%s\".\n",
+ FUNC, failure_mssg);
+
+ return !pass;
+
+} /* check_cache_image_ctl_flow_4() */
+
+
+/*-------------------------------------------------------------------------
+ * Function: check_cache_image_ctl_flow_5()
+ *
+ * Purpose: This test is one of a sequence of control flow tests intended
+ * to verify that control flow for the cache image feature works
+ * as expected.
+ *
+ * The objective of this test is verify correct control flow
+ * when a file with a metadata cache image superblock extension
+ * message is opened with the metadata cache image FAPL entry.
+ *
+ * Note that in all cases we are performing operations on the
+ * file between file open and close. While this is the
+ * typical case, we must repeat this test without operations
+ * on the file.
+ *
+ * 1) Create a HDF5 file with the cache image FAPL entry.
+ *
+ * Verify that the cache is informed of the cache image
+ * FAPL entry.
+ *
+ * Set flags forcing creation of metadata cache image
+ * super block extension message only.
+ *
+ * 2) Create some datasets.
+ *
+ * 3) Close the file.
+ *
+ * 4) Open the file WITH the cache image FAPL entry.
+ *
+ * Verify that the metadata cache is instructed
+ * to load the metadata cache image, and that the
+ * supplied address and length are HADDR_UNDEF and
+ * zero respectively. Note that these values indicate
+ * that the metadata image block doesn't exist.
+ *
+ * Verify that the cache is informed of the cache image
+ * FAPL entry.
+ *
+ * Set flags forcing creation of metadata cache image
+ * super block extension message only.
+ *
+ * 5) Verify the contents of the datasets.
+ *
+ * 6) Close the file.
+ *
+ * 7) Open the file.
+ *
+ * Verify that the metadata cache is instructed
+ * to load the metadata cache image, and that the
+ * supplied address and length are HADDR_UNDEF and
+ * zero respectively. Note that these values indicate
+ * that the metadata image block doesn't exist.
+ *
+ * 8) Verify the contents of the datasets.
+ *
+ * 9) Close the file.
+ *
+ * 10) Delete the file.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 7/17/15
+ *
+ *-------------------------------------------------------------------------
+ */
+
+static unsigned
+check_cache_image_ctl_flow_5(void)
+{
+ const char * fcn_name = "check_cache_image_ctl_flow_5()";
+ char filename[512];
+ hbool_t show_progress = FALSE;
+ hid_t file_id = -1;
+ H5F_t *file_ptr = NULL;
+ H5C_t *cache_ptr = NULL;
+ int cp = 0;
+
+ TESTING("metadata cache image control flow test 5");
+
+ pass = TRUE;
+
+ if ( show_progress ) /* 0 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+ /* setup the file name */
+ if ( pass ) {
+
+ if ( h5_fixname(FILENAMES[0], H5P_DEFAULT, filename, sizeof(filename))
+ == NULL ) {
+
+ pass = FALSE;
+ failure_mssg = "h5_fixname() failed.\n";
+ }
+ }
+
+ if ( show_progress ) /* 1 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 1) Create a HDF5 file with the cache image FAPL entry.
+ *
+ * Verify that the cache is informed of the cache image FAPL entry.
+ *
+ * Set flags forcing creation of metadata cache image
+ * super block extension message only.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ TRUE,
+ /* mdci_sbem_expected */ FALSE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ TRUE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ H5C_CI__GEN_MDCI_SBE_MESG,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress ) /* 2 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 2) Create some datasets. */
+
+ if ( pass ) {
+
+ create_datasets(file_id, 0, 5);
+ }
+
+ if ( show_progress ) /* 3 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 3) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+ if ( show_progress ) /* 4 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 4) Open the file WITH the cache image FAPL entry.
+ *
+ * Verify that the metadata cache is instructed
+ * to load the metadata cache image, and that the
+ * supplied address and length are HADDR_UNDEF and
+ * zero respectively. Note that these values indicate
+ * that the metadata image block doesn't exist.
+ *
+ * Verify that the cache is informed of the cache image
+ * FAPL entry.
+ *
+ * Set flags forcing creation of metadata cache image
+ * super block extension message only.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ TRUE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ TRUE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ H5C_CI__GEN_MDCI_SBE_MESG,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress ) /* 5 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+ /* 5) Verify the contents of the datasets. */
+
+ if ( pass ) {
+
+ verify_datasets(file_id, 0, 5);
+ }
+
+ if ( show_progress ) /* 6 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 6) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+ if ( show_progress ) /* 7 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 7) Open the file.
+ *
+ * Verify that the metadata cache is instructed
+ * to load the metadata cache image, and that the
+ * supplied address and length are HADDR_UNDEF and
+ * zero respectively. Note that these values indicate
+ * that the metadata image block doesn't exist.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ TRUE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ FALSE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ 0,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress ) /* 8 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+ /* 8) Verify the contents of the datasets. */
+
+ if ( pass ) {
+
+ verify_datasets(file_id, 0, 5);
+ }
+
+ if ( show_progress ) /* 9 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 9) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+ if ( show_progress ) /* 10 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 10) Delete the file. */
+
+ if ( pass ) {
+
+ if ( HDremove(filename) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "HDremove() failed.\n";
+ }
+ }
+
+
+ if ( pass ) { PASSED(); } else { H5_FAILED(); }
+
+ if ( ! pass )
+ HDfprintf(stdout, "%s: failure_mssg = \"%s\".\n",
+ FUNC, failure_mssg);
+
+ return !pass;
+
+} /* check_cache_image_ctl_flow_5() */
+
+
+/*-------------------------------------------------------------------------
+ * Function: check_cache_image_ctl_flow_6()
+ *
+ * Purpose: This test is one of a sequence of control flow tests intended
+ * to verify that control flow for the cache image feature works
+ * as expected.
+ *
+ * The objective of this test is verify correct control flow
+ * when a file with a metadata cache image superblock extension
+ * message is opened with the metadata cache image FAPL entry.
+ *
+ * In this test we avoid all file activity other than open
+ * and close.
+ *
+ * 1) Create a HDF5 file with the cache image FAPL entry.
+ *
+ * Verify that the cache is informed of the cache image
+ * FAPL entry.
+ *
+ * Set flags forcing creation of metadata cache image
+ * super block extension message only.
+ *
+ * 2) Close the file.
+ *
+ * 3) Open the file WITH the cache image FAPL entry.
+ *
+ * Verify that the metadata cache is instructed
+ * to load the metadata cache image, and that the
+ * supplied address and length are HADDR_UNDEF and
+ * zero respectively. Note that these values indicate
+ * that the metadata image block doesn't exist.
+ *
+ * Verify that the cache is informed of the cache image
+ * FAPL entry.
+ *
+ * Set flags forcing creation of metadata cache image
+ * super block extension message only.
+ *
+ * 4) Close the file.
+ *
+ * 5) Open the file.
+ *
+ * Verify that the metadata cache is instructed
+ * to load the metadata cache image, and that the
+ * supplied address and length are HADDR_UNDEF and
+ * zero respectively. Note that these values indicate
+ * that the metadata image block doesn't exist.
+ *
+ * 6) Close the file.
+ *
+ * 7) Delete the file.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 7/17/15
+ *
+ *-------------------------------------------------------------------------
+ */
+
+static unsigned
+check_cache_image_ctl_flow_6(void)
+{
+ const char * fcn_name = "check_cache_image_ctl_flow_6()";
+ char filename[512];
+ hbool_t show_progress = FALSE;
+ hid_t file_id = -1;
+ H5F_t *file_ptr = NULL;
+ H5C_t *cache_ptr = NULL;
+ int cp = 0;
+
+ TESTING("metadata cache image control flow test 6");
+
+ pass = TRUE;
+
+ if ( show_progress ) /* 0 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+ /* setup the file name */
+ if ( pass ) {
+
+ if ( h5_fixname(FILENAMES[0], H5P_DEFAULT, filename, sizeof(filename))
+ == NULL ) {
+
+ pass = FALSE;
+ failure_mssg = "h5_fixname() failed.\n";
+ }
+ }
+
+ if ( show_progress ) /* 1 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 1) Create a HDF5 file with the cache image FAPL entry.
+ *
+ * Verify that the cache is informed of the cache image FAPL entry.
+ *
+ * Set flags forcing creation of metadata cache image
+ * super block extension message only.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ TRUE,
+ /* mdci_sbem_expected */ FALSE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ TRUE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ H5C_CI__GEN_MDCI_SBE_MESG,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress ) /* 2 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 2) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+ if ( show_progress ) /* 3 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 4) Open the file WITH the cache image FAPL entry.
+ *
+ * Verify that the metadata cache is instructed
+ * to load the metadata cache image, and that the
+ * supplied address and length are HADDR_UNDEF and
+ * zero respectively. Note that these values indicate
+ * that the metadata image block doesn't exist.
+ *
+ * Verify that the cache is informed of the cache image
+ * FAPL entry.
+ *
+ * Set flags forcing creation of metadata cache image
+ * super block extension message only.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ TRUE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ TRUE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ H5C_CI__GEN_MDCI_SBE_MESG,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress ) /* 4 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 5) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+ if ( show_progress ) /* 5 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 5) Open the file.
+ *
+ * Verify that the metadata cache is instructed
+ * to load the metadata cache image, and that the
+ * supplied address and length are HADDR_UNDEF and
+ * zero respectively. Note that these values indicate
+ * that the metadata image block doesn't exist.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ TRUE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ FALSE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ 0,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress ) /* 6 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 6) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+ if ( show_progress ) /* 7 */
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 7) Delete the file. */
+
+ if ( pass ) {
+
+ if ( HDremove(filename) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "HDremove() failed.\n";
+ }
+ }
+
+
+ if ( pass ) { PASSED(); } else { H5_FAILED(); }
+
+ if ( ! pass )
+ HDfprintf(stdout, "%s: failure_mssg = \"%s\".\n",
+ FUNC, failure_mssg);
+
+ return !pass;
+
+} /* check_cache_image_ctl_flow_6() */
+
+
+/*-------------------------------------------------------------------------
+ * Function: cache_image_smoke_check_1()
+ *
+ * Purpose: This test is one of a sequence of tests intended
+ * to exercise the cache image feature verifying that it
+ * works more or less correctly in common cases.
+ *
+ * This test is an initial smoke check, so the sequence of
+ * operations is relatively simple. In particular, we are
+ * testing:
+ *
+ * i) Creation of file with metadata cache image
+ * superblock extension message and cache image
+ * block.
+ *
+ * ii) Open of file with metadata cache image superblock
+ * extension message and cache image block.
+ * Deserialization and removal of both, insertion
+ * of prefetched cache entries, and deserialization
+ * of prefetched cache entries as they are protected.
+ *
+ * iii) Subsequent write of file without metadata cache
+ * image.
+ *
+ * iv) Open and close of file with metadata cache image
+ * image requested, but with no operations on the
+ * file.
+ *
+ * To do this:
+ *
+ * 1) Create a HDF5 file with the cache image FAPL entry.
+ *
+ * Verify that the cache is informed of the cache image
+ * FAPL entry.
+ *
+ * Set all cache image flags, forcing full functionality.
+ *
+ * 2) Create some datasets in the file.
+ *
+ * 3) Close the file.
+ *
+ * 4) Open the file.
+ *
+ * Verify that the metadata cache is instructed
+ * to load the metadata cache image.
+ *
+ * 5) Open a dataset.
+ *
+ * Verify that it contains the expected data
+ *
+ * 6) Close the file.
+ *
+ * 7) Open the file.
+ *
+ * Verify that the file doesn't contain a metadata cache
+ * image superblock extension message.
+ *
+ * 8) Open a dataset.
+ *
+ * Verify that it contains the expected data.
+ *
+ * 9) Close the file.
+ *
+ * 10) Open the file with the cache image FAPL entry.
+ *
+ * Verify that the cache is informed of the cache image
+ * FAPL entry.
+ *
+ * Set all cache image flags, forcing full functionality.
+ *
+ * 11) Close the file. Since there has been no access to
+ * any entries that would be included in the cache image,
+ * there should be no cache image.
+ *
+ * 12) Open the file.
+ *
+ * Verify that the file doesn't contain a metadata cache
+ * image superblock extension message.
+ *
+ * 13) Open a dataset.
+ *
+ * Verify that it contains the expected data.
+ *
+ * 14) Close the file.
+ *
+ * 15) Delete the file.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 8/17/15
+ *
+ *-------------------------------------------------------------------------
+ */
+
+static unsigned
+cache_image_smoke_check_1(void)
+{
+ const char * fcn_name = "cache_image_smoke_check_1()";
+ char filename[512];
+ hbool_t show_progress = FALSE;
+ hid_t file_id = -1;
+ H5F_t *file_ptr = NULL;
+ H5C_t *cache_ptr = NULL;
+ int cp = 0;
+
+ TESTING("metadata cache image smoke check 1");
+
+ pass = TRUE;
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* setup the file name */
+ if ( pass ) {
+
+ if ( h5_fixname(FILENAMES[0], H5P_DEFAULT, filename, sizeof(filename))
+ == NULL ) {
+
+ pass = FALSE;
+ failure_mssg = "h5_fixname() failed.\n";
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 1) Create a HDF5 file with the cache image FAPL entry.
+ *
+ * Verify that the cache is informed of the cache image FAPL entry.
+ *
+ * Set flags forcing full function of the cache image feature.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ TRUE,
+ /* mdci_sbem_expected */ FALSE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ TRUE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ H5C_CI__ALL_FLAGS,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 2) Create some datasets in the file. */
+
+ if ( pass ) {
+
+ create_datasets(file_id, 0, 5);
+ }
+
+#if H5C_COLLECT_CACHE_STATS
+ if ( pass ) {
+
+ if ( cache_ptr->images_loaded != 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "metadata cache image block loaded(1).";
+ }
+ }
+#endif /* H5C_COLLECT_CACHE_STATS */
+
+
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 3) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 4) Open the file.
+ *
+ * Verify that the metadata cache is instructed to load the
+ * metadata cache image, and that the supplied address and length
+ * are HADDR_UNDEF and zero respectively. Note that these values
+ * indicate that the metadata image block doesn't exist.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ TRUE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ FALSE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ 0,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 5) Open and close a dataset.
+ *
+ * Verify that the metadata cache image superblock
+ * extension message has been deleted.
+ */
+
+ if ( pass ) {
+
+ verify_datasets(file_id, 0, 5);
+ }
+
+#if H5C_COLLECT_CACHE_STATS
+ if ( pass ) {
+
+ if ( cache_ptr->images_loaded != 1 ) {
+
+ pass = FALSE;
+ failure_mssg = "metadata cache image block not loaded(1).";
+ }
+ }
+#endif /* H5C_COLLECT_CACHE_STATS */
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 6) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 7) Open the file.
+ *
+ * Verify that the file doesn't contain a metadata cache image
+ * superblock extension message.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ FALSE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ FALSE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ 0,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 8) Open and close a dataset.
+ *
+ * Verify that the metadata cache image superblock
+ * extension message has been deleted.
+ */
+
+ if ( pass ) {
+
+ verify_datasets(file_id, 0, 5);
+ }
+
+#if H5C_COLLECT_CACHE_STATS
+ if ( pass ) {
+
+ if ( cache_ptr->images_loaded != 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "metadata cache image block loaded(2).";
+ }
+ }
+#endif /* H5C_COLLECT_CACHE_STATS */
+
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 9) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 10) Open the file with the cache image FAPL entry.
+ *
+ * Verify that the cache is informed of the cache image
+ * FAPL entry.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ FALSE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ TRUE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ H5C_CI__ALL_FLAGS,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 11) Close the file. Since there has been no access to
+ * any entries that would be included in the cache image,
+ * there should be no cache image.
+ */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 12) Open the file.
+ *
+ * Verify that the file doesn't contain a metadata cache
+ * image superblock extension message.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ FALSE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ FALSE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ 0,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 13) Open a dataset.
+ *
+ * Verify that it contains the expected data.
+ */
+
+ if ( pass ) {
+
+ verify_datasets(file_id, 0, 5);
+ }
+
+#if H5C_COLLECT_CACHE_STATS
+ if ( pass ) {
+
+ if ( cache_ptr->images_loaded != 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "metadata cache image block loaded(3).";
+ }
+ }
+#endif /* H5C_COLLECT_CACHE_STATS */
+
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 14) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 15) Delete the file */
+
+ if ( pass ) {
+
+ if ( HDremove(filename) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "HDremove() failed.\n";
+ }
+ }
+
+ if ( pass ) { PASSED(); } else { H5_FAILED(); }
+
+ if ( ! pass )
+ HDfprintf(stdout, "%s: failure_mssg = \"%s\".\n",
+ FUNC, failure_mssg);
+
+ return !pass;
+
+} /* cache_image_smoke_check_1() */
+
+
+/*-------------------------------------------------------------------------
+ * Function: cache_image_smoke_check_2()
+ *
+ * Purpose: This test is one of a sequence of tests intended
+ * to exercise the cache image feature verifying that it
+ * works more or less correctly in common cases.
+ *
+ * This test is an initial smoke check, so the sequence of
+ * operations is relatively simple. In particular, we are
+ * testing:
+ *
+ * i) Creation of file with metadata cache image
+ * superblock extension message and cache image
+ * block.
+ *
+ * ii) Open of file with metadata cache image superblock
+ * extension message and cache image block. Write
+ * of prefetched entries to file on file close.
+ *
+ * To do this:
+ *
+ * 1) Create a HDF5 file with the cache image FAPL entry.
+ *
+ * Verify that the cache is informed of the cache image
+ * FAPL entry.
+ *
+ * Set all cache image flags, forcing full functionality.
+ *
+ * 2) Create some datasets in the file.
+ *
+ * 3) Close the file.
+ *
+ * 4) Open the file.
+ *
+ * 5) Close the file.
+ *
+ * 6) Open the file.
+ *
+ * Verify that the file doesn't contain a metadata cache
+ * image superblock extension message.
+ *
+ * 7) Open a dataset.
+ *
+ * Verify that it contains the expected data.
+ *
+ * 8) Close the file.
+ *
+ * 9) Delete the file.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 8/18/15
+ *
+ *-------------------------------------------------------------------------
+ */
+
+static unsigned
+cache_image_smoke_check_2(void)
+{
+ const char * fcn_name = "cache_image_smoke_check_2()";
+ char filename[512];
+ hbool_t show_progress = FALSE;
+ hid_t file_id = -1;
+ H5F_t *file_ptr = NULL;
+ H5C_t *cache_ptr = NULL;
+ int cp = 0;
+
+ TESTING("metadata cache image smoke check 2");
+
+ pass = TRUE;
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* setup the file name */
+ if ( pass ) {
+
+ if ( h5_fixname(FILENAMES[0], H5P_DEFAULT, filename, sizeof(filename))
+ == NULL ) {
+
+ pass = FALSE;
+ failure_mssg = "h5_fixname() failed.\n";
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 1) Create a HDF5 file with the cache image FAPL entry.
+ *
+ * Verify that the cache is informed of the cache image FAPL entry.
+ *
+ * Set flags forcing full function of the cache image feature.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ TRUE,
+ /* mdci_sbem_expected */ FALSE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ TRUE,
+ /* config_fsm */ TRUE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ H5C_CI__ALL_FLAGS,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 2) Create some datasets in the file. */
+
+ if ( pass ) {
+
+ create_datasets(file_id, 0, 5);
+ }
+
+#if H5C_COLLECT_CACHE_STATS
+ if ( pass ) {
+
+ if ( cache_ptr->images_loaded != 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "metadata cache image block loaded(1).";
+ }
+ }
+#endif /* H5C_COLLECT_CACHE_STATS */
+
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 3) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 4) Open the file.
+ *
+ * Verify that the metadata cache is instructed to load the
+ * metadata cache image.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ TRUE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ FALSE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ 0,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ /* can't verify that metadata cache image has been loaded directly,
+ * as in this cache, the load will not happen until close, and thus
+ * the images_created stat will not be readily available as it is
+ * incremented just before the cache is shut down.
+ */
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 5) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 6) Open the file.
+ *
+ * Verify that the file doesn't contain a metadata cache image
+ * superblock extension message.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ FALSE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ FALSE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ 0,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 7) Open and close a dataset.
+ *
+ * Verify that the metadata cache image superblock
+ * extension message has been deleted.
+ */
+
+ if ( pass ) {
+
+ verify_datasets(file_id, 0, 5);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 8) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 9) Delete the file */
+
+ if ( pass ) {
+
+ if ( HDremove(filename) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "HDremove() failed.\n";
+ }
+ }
+
+ if ( pass ) { PASSED(); } else { H5_FAILED(); }
+
+ if ( ! pass )
+ HDfprintf(stdout, "%s: failure_mssg = \"%s\".\n",
+ FUNC, failure_mssg);
+
+ return !pass;
+
+} /* cache_image_smoke_check_2() */
+
+
+/*-------------------------------------------------------------------------
+ * Function: cache_image_smoke_check_3()
+ *
+ * Purpose: This test is one of a sequence of tests intended
+ * to exercise the cache image feature verifying that it
+ * works more or less correctly in common cases.
+ *
+ * This test is an initial smoke check, so the sequence of
+ * operations is relatively simple. In particular, we are
+ * testing:
+ *
+ * i) Creation of file with metadata cache image
+ * superblock extension message and cache image
+ * block.
+ *
+ * ii) Read only open and close of file with metadata
+ * cache image superblock extension message and
+ * cache image block.
+ *
+ * iii) Subsequent R/W open and close of file with metadata
+ * cache image superblock extension message and
+ * cache image block.
+ *
+ * To do this:
+ *
+ * 1) Create a HDF5 file with the cache image FAPL entry.
+ *
+ * Verify that the cache is informed of the cache image
+ * FAPL entry.
+ *
+ * Set all cache image flags, forcing full functionality.
+ *
+ * 2) Create some datasets in the file.
+ *
+ * 3) Close the file.
+ *
+ * 4) Open the file read only.
+ *
+ * Verify that the file contains a metadata cache
+ * image superblock extension message.
+ *
+ * 5 Open a dataset.
+ *
+ * Verify that it contains the expected data.
+ *
+ * 6) Close the file.
+ *
+ * 7) Open the file.
+ *
+ * Verify that the file contains a metadata cache
+ * image superblock extension message.
+ *
+ * 8 Open a dataset.
+ *
+ * Verify that it contains the expected data.
+ *
+ * 9) Close the file.
+ *
+ * 10) Open the file.
+ *
+ * Verify that the file doesn't contain a metadata cache
+ * image superblock extension message.
+ *
+ * 11) Open a dataset.
+ *
+ * Verify that it contains the expected data.
+ *
+ * 12) Close the file.
+ *
+ * 13) Delete the file.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 8/18/15
+ *
+ *-------------------------------------------------------------------------
+ */
+
+static unsigned
+cache_image_smoke_check_3(void)
+{
+ const char * fcn_name = "cache_image_smoke_check_3()";
+ char filename[512];
+ hbool_t show_progress = FALSE;
+ hid_t file_id = -1;
+ H5F_t *file_ptr = NULL;
+ H5C_t *cache_ptr = NULL;
+ int cp = 0;
+
+ TESTING("metadata cache image smoke check 3");
+
+ pass = TRUE;
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* setup the file name */
+ if ( pass ) {
+
+ if ( h5_fixname(FILENAMES[0], H5P_DEFAULT, filename, sizeof(filename))
+ == NULL ) {
+
+ pass = FALSE;
+ failure_mssg = "h5_fixname() failed.\n";
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 1) Create a HDF5 file with the cache image FAPL entry.
+ *
+ * Verify that the cache is informed of the cache image FAPL entry.
+ *
+ * Set flags forcing full function of the cache image feature.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ TRUE,
+ /* mdci_sbem_expected */ FALSE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ TRUE,
+ /* config_fsm */ TRUE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ H5C_CI__ALL_FLAGS,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 2) Create some datasets in the file. */
+
+ if ( pass ) {
+
+ create_datasets(file_id, 0, 5);
+ }
+
+#if H5C_COLLECT_CACHE_STATS
+ if ( pass ) {
+
+ if ( cache_ptr->images_loaded != 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "metadata cache image block loaded(1).";
+ }
+ }
+#endif /* H5C_COLLECT_CACHE_STATS */
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 3) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 4) Open the file read only.
+ *
+ * Verify that the metadata cache is instructed to load the
+ * metadata cache image.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ TRUE,
+ /* read_only */ TRUE,
+ /* set_mdci_fapl */ FALSE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ 0,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 5) Open and close a dataset.
+ *
+ * Verify that the metadata cache image superblock
+ * extension message has been deleted.
+ */
+
+ if ( pass ) {
+
+ verify_datasets(file_id, 0, 5);
+ }
+
+#if H5C_COLLECT_CACHE_STATS
+ if ( pass ) {
+
+ if ( cache_ptr->images_loaded == 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "metadata cache image block not loaded(1).";
+ }
+ }
+#endif /* H5C_COLLECT_CACHE_STATS */
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 6) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 7) Open the file.
+ *
+ * Verify that the file contains a metadata cache image
+ * superblock extension message.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ TRUE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ FALSE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ 0,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 8) Open and close a dataset.
+ *
+ * Verify that the metadata cache image superblock
+ * extension message has been deleted.
+ */
+
+ if ( pass ) {
+
+ verify_datasets(file_id, 0, 5);
+ }
+
+#if H5C_COLLECT_CACHE_STATS
+ if ( pass ) {
+
+ if ( cache_ptr->images_loaded == 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "metadata cache image block not loaded(2).";
+ }
+ }
+#endif /* H5C_COLLECT_CACHE_STATS */
+
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 9) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+
+ /* 10) Open the file.
+ *
+ * Verify that the file doesn't contain a metadata cache image
+ * superblock extension message.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ FALSE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ FALSE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ 0,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 11) Open and close a dataset.
+ *
+ * Verify that the metadata cache image superblock
+ * extension message has been deleted.
+ */
+
+ if ( pass ) {
+
+ verify_datasets(file_id, 0, 5);
+ }
+
+#if H5C_COLLECT_CACHE_STATS
+ if ( pass ) {
+
+ if ( cache_ptr->images_loaded != 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "metadata cache image block loaded(2).";
+ }
+ }
+#endif /* H5C_COLLECT_CACHE_STATS */
+
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 12) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 13) Delete the file */
+
+ if ( pass ) {
+
+ if ( HDremove(filename) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "HDremove() failed.\n";
+ }
+ }
+
+ if ( pass ) { PASSED(); } else { H5_FAILED(); }
+
+ if ( ! pass )
+ HDfprintf(stdout, "%s: failure_mssg = \"%s\".\n",
+ FUNC, failure_mssg);
+
+ return !pass;
+
+} /* cache_image_smoke_check_3() */
+
+
+/*-------------------------------------------------------------------------
+ * Function: cache_image_smoke_check_4()
+ *
+ * Purpose: This test attempts to mimic the typical "poor man's
+ * parallel use case in which the file is passed between
+ * processes, each of which open the file, write some data,
+ * close the file, and then pass control on to the next
+ * process.
+ *
+ * In this case, we only write one dataset per process.
+ *
+ * Cycle of operation
+ *
+ * 1) Create a HDF5 file with the cache image FAPL entry.
+ *
+ * Verify that the cache is informed of the cache image
+ * FAPL entry.
+ *
+ * Set all cache image flags, forcing full functionality.
+ *
+ * 2) Create and write a dataset in the file.
+ *
+ * 3) Close the file.
+ *
+ * 4) Open the file with the cache image FAPL entry.
+ *
+ * Verify that the file contains a metadata cache
+ * image superblock extension message.
+ *
+ * 5 Create and write a new dataset
+ *
+ * 6) Close the file.
+ *
+ * If sufficient datasets have been created, continue to
+ * 7). Otherwise goto 4)
+ *
+ * 7) Open the file.
+ *
+ * Verify that the file contains a metadata cache
+ * image superblock extension message.
+ *
+ * 8) Open all datasets that have been created, and
+ * verify that they contain the expected data.
+ *
+ * 9) Close the file.
+ *
+ * 10) Open the file.
+ *
+ * Verify that the file doesn't contain a metadata cache
+ * image superblock extension message.
+ *
+ * 11) Open all datasets that have been created, and
+ * verify that they contain the expected data.
+ *
+ * Verify that it contains the expected data.
+ *
+ * 12) Close the file.
+ *
+ * 13) Delete the file.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 8/18/15
+ *
+ *-------------------------------------------------------------------------
+ */
+
+static unsigned
+cache_image_smoke_check_4(void)
+{
+ const char * fcn_name = "cache_image_smoke_check_4()";
+ char filename[512];
+ hbool_t show_progress = FALSE;
+ hid_t file_id = -1;
+ H5F_t *file_ptr = NULL;
+ H5C_t *cache_ptr = NULL;
+ int cp = 0;
+ int min_dset = 0;
+ int max_dset = 0;
+
+ TESTING("metadata cache image smoke check 4");
+
+ pass = TRUE;
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* setup the file name */
+ if ( pass ) {
+
+ if ( h5_fixname(FILENAMES[0], H5P_DEFAULT, filename, sizeof(filename))
+ == NULL ) {
+
+ pass = FALSE;
+ failure_mssg = "h5_fixname() failed.\n";
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 1) Create a HDF5 file with the cache image FAPL entry.
+ *
+ * Verify that the cache is informed of the cache image FAPL entry.
+ *
+ * Set flags forcing full function of the cache image feature.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ TRUE,
+ /* mdci_sbem_expected */ FALSE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ TRUE,
+ /* config_fsm */ TRUE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ H5C_CI__ALL_FLAGS,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 2) Create a dataset in the file. */
+
+ if ( pass ) {
+
+ create_datasets(file_id, min_dset++, max_dset++);
+ }
+
+#if H5C_COLLECT_CACHE_STATS
+ if ( pass ) {
+
+ if ( cache_ptr->images_loaded != 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "metadata cache image block loaded(1).";
+ }
+ }
+#endif /* H5C_COLLECT_CACHE_STATS */
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 3) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+ while ( ( pass ) && ( max_dset < MAX_NUM_DSETS ) )
+ {
+
+ /* 4) Open the file.
+ *
+ * Verify that the metadata cache is instructed to load the
+ * metadata cache image.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ TRUE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ TRUE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ H5C_CI__ALL_FLAGS,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s:L1 cp = %d, max_dset = %d, pass = %d.\n",
+ fcn_name, cp, max_dset, pass);
+
+
+ /* 5) Create a dataset in the file. */
+
+ if ( pass ) {
+
+ create_datasets(file_id, min_dset++, max_dset++);
+ }
+
+#if H5C_COLLECT_CACHE_STATS
+ if ( pass ) {
+
+ if ( cache_ptr->images_loaded == 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "metadata cache image block not loaded(1).";
+ }
+ }
+#endif /* H5C_COLLECT_CACHE_STATS */
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s:L2 cp = %d, max_dset = %d, pass = %d.\n",
+ fcn_name, cp + 1, max_dset, pass);
+
+
+ /* 6) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s:L3 cp = %d, max_dset = %d, pass = %d.\n",
+ fcn_name, cp + 2, max_dset, pass);
+ } /* end while */
+ cp += 3;
+
+
+ /* 7) Open the file.
+ *
+ * Verify that the file contains a metadata cache image
+ * superblock extension message.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ TRUE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ FALSE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ 0,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 8) Open and close all datasets.
+ *
+ * Verify that the metadata cache image superblock
+ * extension message has been deleted.
+ */
+
+ if ( pass ) {
+
+ verify_datasets(file_id, 0, max_dset - 1);
+ }
+
+#if H5C_COLLECT_CACHE_STATS
+ if ( pass ) {
+
+ if ( cache_ptr->images_loaded == 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "metadata cache image block not loaded(2).";
+ }
+ }
+#endif /* H5C_COLLECT_CACHE_STATS */
+
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 9) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+
+ /* 10) Open the file.
+ *
+ * Verify that the file doesn't contain a metadata cache image
+ * superblock extension message.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ FALSE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ FALSE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ 0,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 11) Open and close all datasets.
+ *
+ * Verify that the metadata cache image superblock
+ * extension message has been deleted.
+ */
+
+ if ( pass ) {
+
+ verify_datasets(file_id, 0, max_dset - 1);
+ }
+
+#if H5C_COLLECT_CACHE_STATS
+ if ( pass ) {
+
+ if ( cache_ptr->images_loaded != 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "metadata cache image block loaded(2).";
+ }
+ }
+#endif /* H5C_COLLECT_CACHE_STATS */
+
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 12) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 13) Delete the file */
+
+ if ( pass ) {
+
+ if ( HDremove(filename) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "HDremove() failed.\n";
+ }
+ }
+
+ if ( pass ) { PASSED(); } else { H5_FAILED(); }
+
+ if ( ! pass )
+ HDfprintf(stdout, "%s: failure_mssg = \"%s\".\n",
+ FUNC, failure_mssg);
+
+ return !pass;
+
+} /* cache_image_smoke_check_4() */
+
+
+/*-------------------------------------------------------------------------
+ * Function: cache_image_smoke_check_5()
+ *
+ * Purpose: This test attempts to mimic the typical "poor man's
+ * parallel use case in which the file is passed between
+ * processes, each of which open the file, write some data,
+ * close the file, and then pass control on to the next
+ * process.
+ *
+ * In this case, we create one group for each process, and
+ * populate it with a "zoo" of HDF5 objects selected to
+ * (ideally) exercise all HDF5 on disk data structures.
+ *
+ * Cycle of operation
+ *
+ * 1) Create a HDF5 file with the cache image FAPL entry.
+ *
+ * Verify that the cache is informed of the cache image
+ * FAPL entry.
+ *
+ * Set all cache image flags, forcing full functionality.
+ *
+ * 2) Create a process specific group.
+ *
+ * 3) Construct a "zoo" in the above group, and validate it.
+ *
+ * 4) Close the file.
+ *
+ * 5) Open the file with the cache image FAPL entry.
+ *
+ * Verify that the file contains a metadata cache
+ * image superblock extension message.
+ *
+ * 6) Validate the "zoo" created in the previous file open.
+ *
+ * 7) Create a process specific group for this file open
+ *
+ * 8) Construct a "zoo" in the above group, and validate it.
+ *
+ * 9) Close the file.
+ *
+ * If sufficient zoos have been created, continue to
+ * 10). Otherwise goto 5)
+ *
+ * 10) Open the file.
+ *
+ * Verify that the file contains a metadata cache
+ * image superblock extension message.
+ *
+ * 11) Validate all the zoos.
+ *
+ * 12) Close the file.
+ *
+ * 13) Open the file.
+ *
+ * Verify that the file doesn't contain a metadata cache
+ * image superblock extension message.
+ *
+ * 14) Validate all the zoos.
+ *
+ * 15) Close the file.
+ *
+ * 16) Delete the file.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 9/15/15
+ *
+ *-------------------------------------------------------------------------
+ */
+
+#define MAX_NUM_GROUPS 128
+
+static unsigned
+cache_image_smoke_check_5(void)
+{
+ const char * fcn_name = "cache_image_smoke_check_5()";
+ char filename[512];
+ char process_group_name[512];
+ hbool_t show_progress = FALSE;
+ hid_t file_id = -1;
+ hid_t proc_gid = -1;
+ H5F_t *file_ptr = NULL;
+ H5C_t *cache_ptr = NULL;
+ int cp = 0;
+ int i;
+ int min_group = 0;
+ int max_group = 0;
+
+ TESTING("metadata cache image smoke check 5");
+
+ pass = TRUE;
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* setup the file name */
+ if ( pass ) {
+
+ if ( h5_fixname(FILENAMES[0], H5P_DEFAULT, filename, sizeof(filename))
+ == NULL ) {
+
+ pass = FALSE;
+ failure_mssg = "h5_fixname() failed.\n";
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 1) Create a HDF5 file with the cache image FAPL entry.
+ *
+ * Verify that the cache is informed of the cache image FAPL entry.
+ *
+ * Set flags forcing full function of the cache image feature.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ TRUE,
+ /* mdci_sbem_expected */ FALSE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ TRUE,
+ /* config_fsm */ TRUE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ H5C_CI__ALL_FLAGS,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 2) Create a process specific group. */
+ if ( pass ) {
+
+ sprintf(process_group_name, "/process_%d", min_group);
+
+ proc_gid = H5Gcreate2(file_id, process_group_name, H5P_DEFAULT,
+ H5P_DEFAULT, H5P_DEFAULT);
+
+ if ( proc_gid < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Gcreate2() failed (1).\n";
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 3) Construct a "zoo" in the above group, and validate it. */
+ if ( pass )
+ create_zoo(file_id, process_group_name, min_group);
+
+#if H5C_COLLECT_CACHE_STATS
+ if ( pass ) {
+
+ if ( cache_ptr->images_loaded != 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "metadata cache image block loaded(1).";
+ }
+ }
+#endif /* H5C_COLLECT_CACHE_STATS */
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 4) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Gclose(proc_gid) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Gclose(proc_gid) failed. (1)";
+ }
+ }
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+ while ( ( pass ) && ( max_group < MAX_NUM_GROUPS ) )
+ {
+
+ /* 5) Open the file.
+ *
+ * Verify that the metadata cache is instructed to load the
+ * metadata cache image.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ TRUE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ TRUE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ H5C_CI__ALL_FLAGS,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s:L1 cp = %d, max_group = %d, pass = %d.\n",
+ fcn_name, cp, max_group, pass);
+
+
+ /* 6) Validate the "zoo" created in the previous file open. */
+ if ( pass )
+ validate_zoo(file_id, process_group_name, max_group);
+
+#if H5C_COLLECT_CACHE_STATS
+ if ( pass ) {
+
+ if ( cache_ptr->images_loaded == 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "metadata cache image block not loaded(1).";
+ }
+ }
+#endif /* H5C_COLLECT_CACHE_STATS */
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s:L2 cp = %d, max_group = %d, pass = %d.\n",
+ fcn_name, cp + 1, max_group, pass);
+
+
+ /* 7) Create a process specific group for this file open */
+ if ( pass ) {
+
+ max_group++;
+ sprintf(process_group_name, "/process_%d", max_group);
+
+ proc_gid = H5Gcreate2(file_id, process_group_name, H5P_DEFAULT,
+ H5P_DEFAULT, H5P_DEFAULT);
+
+ if ( proc_gid < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Gcreate2() failed (2).\n";
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s:L3 cp = %d, max_group = %d, pass = %d.\n",
+ fcn_name, cp + 2, max_group, pass);
+
+
+ /* 8) Construct a "zoo" in the above group, and validate it. */
+ if ( pass )
+ create_zoo(file_id, process_group_name, max_group);
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s:L4 cp = %d, max_group = %d, pass = %d.\n",
+ fcn_name, cp + 3, max_group, pass);
+
+
+ /* 9) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Gclose(proc_gid) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Gclose(process_gid) failed. (2)";
+ }
+ }
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s:L5 cp = %d, max_group = %d, pass = %d.\n",
+ fcn_name, cp + 4, max_group, pass);
+ } /* end while */
+ cp += 5;
+
+
+
+ /* 10) Open the file.
+ *
+ * Verify that the file contains a metadata cache image
+ * superblock extension message.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ TRUE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ FALSE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ 0,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 11) Validate all the zoos. */
+ i = min_group;
+ while ( ( pass ) && ( i <= max_group ) ) {
+
+ sprintf(process_group_name, "/process_%d", i);
+ validate_zoo(file_id, process_group_name, i++);
+ }
+
+#if H5C_COLLECT_CACHE_STATS
+ if ( pass ) {
+
+ if ( cache_ptr->images_loaded == 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "metadata cache image block not loaded(2).";
+ }
+ }
+#endif /* H5C_COLLECT_CACHE_STATS */
+
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 12) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+
+ /* 13) Open the file.
+ *
+ * Verify that the file doesn't contain a metadata cache image
+ * superblock extension message.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ FALSE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ FALSE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ 0,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 14) Validate all the zoos.
+ *
+ * Verify that the metadata cache image superblock
+ * extension message has been deleted.
+ */
+ i = min_group;
+ while ( ( pass ) && ( i <= max_group ) ) {
+
+ sprintf(process_group_name, "/process_%d", i);
+ validate_zoo(file_id, process_group_name, i++);
+ }
+
+#if H5C_COLLECT_CACHE_STATS
+ if ( pass ) {
+
+ if ( cache_ptr->images_loaded != 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "metadata cache image block loaded(2).";
+ }
+ }
+#endif /* H5C_COLLECT_CACHE_STATS */
+
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 15) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 16) Delete the file */
+
+ if ( pass ) {
+
+ if ( HDremove(filename) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "HDremove() failed.\n";
+ }
+ }
+
+
+ if ( pass ) { PASSED(); } else { H5_FAILED(); }
+
+ if ( ! pass )
+ HDfprintf(stdout, "%s: failure_mssg = \"%s\".\n",
+ FUNC, failure_mssg);
+
+ return !pass;
+
+} /* cache_image_smoke_check_5() */
+
+
+/*-------------------------------------------------------------------------
+ * Function: cache_image_smoke_check_6()
+ *
+ * Purpose: As the free space manager metadata is now included in the
+ * cache image, a smoke check to verify generally correct
+ * behaviour of the persistent free space managers seems
+ * prudent.
+ *
+ * The basic idea of this test is to construct a long
+ * sequence of dataset creations and deletions, all separated
+ * by file open/close cycles with cache image enabled. If the
+ * perisistant free space managers are performing as expected,
+ * the size of the file should stabilize.
+ *
+ * To implement this, proceed as outlined in the cycle of
+ * operation below:
+ *
+ * Cycle of operation
+ *
+ * 1) Create a HDF5 file with the cache image FAPL entry.
+ *
+ * Verify that the cache is informed of the cache image
+ * FAPL entry.
+ *
+ * Set all cache image flags, forcing full functionality.
+ *
+ * 2) Create and write a dataset in the file.
+ *
+ * 3) Close the file.
+ *
+ * 4) Open the file with the cache image FAPL entry.
+ *
+ * Verify that the file contains a metadata cache
+ * image superblock extension message.
+ *
+ * 5) Create and write a new dataset.
+ *
+ * 6) Verify and delete the old dataset.
+ *
+ * 7) Close the file.
+ *
+ * If sufficient datasets have been created, and then
+ * deleteded continue to 8). Otherwise goto 4)
+ *
+ * 8) Open the file.
+ *
+ * Verify that the file contains a metadata cache
+ * image superblock extension message.
+ *
+ * 9) Verify the last dataset created.
+ *
+ * 10) Close the file.
+ *
+ * 11) Open the file.
+ *
+ * 12) Verify and delete the last dataset.
+ *
+ * Verify that a metadata cache image is not loaded.
+ *
+ * 13) Close the file.
+ *
+ * 14) Get the size of the file. Verify that it is less
+ * than 1 KB. Without deletions and persistant free
+ * space managers, size size is about 167 MB, so this
+ * is sufficient to verify that the persistant free
+ * space managers are more or less doing their job.
+ *
+ * 15) Delete the file.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 10/31/16
+ *
+ *-------------------------------------------------------------------------
+ */
+
+static unsigned
+cache_image_smoke_check_6(void)
+{
+ const char * fcn_name = "cache_image_smoke_check_6()";
+ char filename[512];
+ hbool_t show_progress = FALSE;
+ hid_t file_id = -1;
+ H5F_t *file_ptr = NULL;
+ H5C_t *cache_ptr = NULL;
+ h5_stat_size_t file_size;
+ int cp = 0;
+ int min_dset = 0;
+ int max_dset = 0;
+
+ TESTING("metadata cache image smoke check 6");
+
+ pass = TRUE;
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* setup the file name */
+ if ( pass ) {
+
+ if ( h5_fixname(FILENAMES[0], H5P_DEFAULT, filename, sizeof(filename))
+ == NULL ) {
+
+ pass = FALSE;
+ failure_mssg = "h5_fixname() failed.\n";
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 1) Create a HDF5 file with the cache image FAPL entry.
+ *
+ * Verify that the cache is informed of the cache image FAPL entry.
+ *
+ * Set flags forcing full function of the cache image feature.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ TRUE,
+ /* mdci_sbem_expected */ FALSE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ TRUE,
+ /* config_fsm */ TRUE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ H5C_CI__ALL_FLAGS,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 2) Create a dataset in the file. */
+
+ if ( pass ) {
+
+ create_datasets(file_id, min_dset++, max_dset++);
+ }
+
+#if H5C_COLLECT_CACHE_STATS
+ if ( pass ) {
+
+ if ( cache_ptr->images_loaded != 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "metadata cache image block loaded(1).";
+ }
+ }
+#endif /* H5C_COLLECT_CACHE_STATS */
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 3) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+ while ( ( pass ) && ( max_dset < MAX_NUM_DSETS ) )
+ {
+
+ /* 4) Open the file.
+ *
+ * Verify that the metadata cache is instructed to load the
+ * metadata cache image.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ TRUE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ TRUE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ H5C_CI__ALL_FLAGS,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s:L1 cp = %d, max_dset = %d, pass = %d.\n",
+ fcn_name, cp, max_dset, pass);
+
+
+ /* 5) Create a dataset in the file. */
+
+ if ( pass ) {
+
+ create_datasets(file_id, min_dset++, max_dset++);
+ }
+
+#if H5C_COLLECT_CACHE_STATS
+ if ( pass ) {
+
+ if ( cache_ptr->images_loaded == 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "metadata cache image block not loaded(1).";
+ }
+ }
+#endif /* H5C_COLLECT_CACHE_STATS */
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s:L2 cp = %d, max_dset = %d, pass = %d.\n",
+ fcn_name, cp + 1, max_dset, pass);
+
+
+ /* 6) Verify and delete the old dataset. */
+ if ( pass ) {
+
+ delete_datasets(file_id, min_dset - 2, max_dset - 2);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s:L3 cp = %d, max_dset = %d, pass = %d.\n",
+ fcn_name, cp + 2, max_dset, pass);
+
+
+ /* 7) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s:L4 cp = %d, max_dset = %d, pass = %d.\n",
+ fcn_name, cp + 3, max_dset, pass);
+ } /* end while */
+ cp += 4;
+
+
+ /* 8) Open the file.
+ *
+ * Verify that the file contains a metadata cache image
+ * superblock extension message.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ TRUE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ FALSE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ 0,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 9) Verify the last dataset created. */
+
+ if ( pass ) {
+
+ verify_datasets(file_id, min_dset - 1, max_dset - 1);
+ }
+
+#if H5C_COLLECT_CACHE_STATS
+ if ( pass ) {
+
+ if ( cache_ptr->images_loaded == 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "metadata cache image block not loaded(2).";
+ }
+ }
+#endif /* H5C_COLLECT_CACHE_STATS */
+
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 10) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+
+ /* 11) Open the file.
+ *
+ * Verify that the file doesn't contain a metadata cache image
+ * superblock extension message.
+ */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ FALSE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ FALSE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ 0,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 12) Verify and delete the last dataset.
+ *
+ * Verify that a metadata cache image is not loaded.
+ */
+
+ if ( pass ) {
+
+ delete_datasets(file_id, min_dset - 1, max_dset - 1);
+ }
+
+#if H5C_COLLECT_CACHE_STATS
+ if ( pass ) {
+
+ if ( cache_ptr->images_loaded != 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "metadata cache image block loaded(2).";
+ }
+ }
+#endif /* H5C_COLLECT_CACHE_STATS */
+
+
+
+ /* 13) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 14) Get the size of the file. Verify that it is less
+ * than 1 KB. Without deletions and persistant free
+ * space managers, size size is about 167 MB, so this
+ * is sufficient to verify that the persistant free
+ * space managers are more or less doing their job.
+ */
+ if((file_size = h5_get_file_size(filename, H5P_DEFAULT)) < 0) {
+
+ pass = FALSE;
+ failure_mssg = "h5_get_file_size() failed.\n";
+
+ } else if ( file_size > 1024 ) {
+
+ pass = FALSE;
+ failure_mssg = "unexpectedly large file size.\n";
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 15) Delete the file */
+ if ( pass ) {
+
+ if ( HDremove(filename) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "HDremove() failed.\n";
+ }
+ }
+
+
+ if ( pass ) { PASSED(); } else { H5_FAILED(); }
+
+ if ( ! pass )
+ HDfprintf(stdout, "%s: failure_mssg = \"%s\".\n",
+ FUNC, failure_mssg);
+
+ return !pass;
+
+} /* cache_image_smoke_check_6() */
+
+
+/*-------------------------------------------------------------------------
+ * Function: cache_image_api_error_check_1()
+ *
+ * Purpose: This test is one of a sequence of tests intended
+ * to verify correct management of API errors.
+ *
+ * The object of this test is to verify that a file without
+ * a pre-existing cache image that is opened both read only
+ * and with a cache image requested is handle correctly
+ * (the cache image request should be ignored silently).
+ *
+ * The test is set up as follows:
+ *
+ * 1) Create a HDF5 file.
+ *
+ * 2) Create some datasets in the file.
+ *
+ * 3) Close the file.
+ *
+ * 4) Open the file read only with a cache image FAPL entry
+ * requested.
+ *
+ * 5) Open a dataset.
+ *
+ * Verify that it contains the expected data
+ *
+ * Verify that the cache image was not loaded.
+ *
+ * 6) Close the file.
+ *
+ * 7) Open the file read only.
+ *
+ * 8) Open a dataset.
+ *
+ * Verify that it contains the expected data.
+ *
+ * Verify that the cache image was not loaded.
+ *
+ * 9) Close the file.
+ *
+ * 10) Open the file read write.
+ *
+ * 11) Open a dataset.
+ *
+ * Verify that it contains the expected data.
+ *
+ * 12) Close the file.
+ *
+ * 13) Delete the file.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 9/25/15
+ *
+ *-------------------------------------------------------------------------
+ */
+
+static unsigned
+cache_image_api_error_check_1(void)
+{
+ const char * fcn_name = "cache_image_api_error_check_1()";
+ char filename[512];
+ hbool_t show_progress = FALSE;
+ hid_t file_id = -1;
+ H5F_t *file_ptr = NULL;
+ H5C_t *cache_ptr = NULL;
+ int cp = 0;
+
+ TESTING("metadata cache image api error check 1");
+
+ pass = TRUE;
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* setup the file name */
+ if ( pass ) {
+
+ if ( h5_fixname(FILENAMES[0], H5P_DEFAULT, filename, sizeof(filename))
+ == NULL ) {
+
+ pass = FALSE;
+ failure_mssg = "h5_fixname() failed.\n";
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 1) Create a HDF5 file. */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ TRUE,
+ /* mdci_sbem_expected */ FALSE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ FALSE,
+ /* config_fsm */ TRUE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ 0,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 2) Create some datasets in the file. */
+
+ if ( pass ) {
+
+ create_datasets(file_id, 0, 5);
+ }
+
+#if H5C_COLLECT_CACHE_STATS
+ if ( pass ) {
+
+ if ( cache_ptr->images_loaded != 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "metadata cache image block loaded(1).";
+ }
+ }
+#endif /* H5C_COLLECT_CACHE_STATS */
+
+
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 3) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 4) Open the file read only with a cache image FAPL entry requested. */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ FALSE,
+ /* read_only */ TRUE,
+ /* set_mdci_fapl */ TRUE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ H5C_CI__ALL_FLAGS,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 5) Open and close a dataset.
+ *
+ * Verify that it contains the expected data.
+ *
+ * Verify that the cache image was not loaded.
+ */
+
+ if ( pass ) {
+
+ verify_datasets(file_id, 0, 5);
+ }
+
+#if H5C_COLLECT_CACHE_STATS
+ if ( pass ) {
+
+ if ( cache_ptr->images_loaded != 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "metadata cache image block loaded(2).";
+ }
+ }
+#endif /* H5C_COLLECT_CACHE_STATS */
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 6) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 7) Open the file read only. */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ FALSE,
+ /* read_only */ TRUE,
+ /* set_mdci_fapl */ FALSE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ 0,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 8) Open and close a dataset.
+ *
+ * Verify that it contains the expected data.
+ *
+ * Verify that the cache image was not loaded.
+ */
+
+ if ( pass ) {
+
+ verify_datasets(file_id, 0, 5);
+ }
+
+#if H5C_COLLECT_CACHE_STATS
+ if ( pass ) {
+
+ if ( cache_ptr->images_loaded != 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "metadata cache image block loaded(3).";
+ }
+ }
+#endif /* H5C_COLLECT_CACHE_STATS */
+
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 9) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 10) Open the file read / write. */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ FALSE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ FALSE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ H5C_CI__ALL_FLAGS,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+ /* 11) Open and close a dataset.
+ *
+ * Verify that it contains the expected data.
+ *
+ * Verify that the cache image was not loaded.
+ */
+
+ if ( pass ) {
+
+ verify_datasets(file_id, 0, 5);
+ }
+
+#if H5C_COLLECT_CACHE_STATS
+ if ( pass ) {
+
+ if ( cache_ptr->images_loaded != 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "metadata cache image block loaded(4).";
+ }
+ }
+#endif /* H5C_COLLECT_CACHE_STATS */
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 12) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 13) Delete the file */
+
+ if ( pass ) {
+
+ if ( HDremove(filename) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "HDremove() failed.\n";
+ }
+ }
+
+ if ( pass ) { PASSED(); } else { H5_FAILED(); }
+
+ if ( ! pass )
+ HDfprintf(stdout, "%s: failure_mssg = \"%s\".\n",
+ FUNC, failure_mssg);
+
+ return !pass;
+
+} /* cache_image_api_error_check_1() */
+
+
+/*-------------------------------------------------------------------------
+ * Function: cache_image_api_error_check_2()
+ *
+ * Purpose: This test is one of a sequence of tests intended
+ * to verify correct management of API errors.
+ *
+ * The object of this test is to verify that a file with
+ * a pre-existing cache image that is opened both read only
+ * and with a cache image requested is handled correctly
+ * (the cache image request should be ignored silently).
+ *
+ * The test is set up as follows:
+ *
+ * 1) Create a HDF5 file with a cache image requested..
+ *
+ * 2) Create some datasets in the file.
+ *
+ * 3) Close the file.
+ *
+ * 4) Open the file read only with a cache image FAPL entry
+ * requested.
+ *
+ * 5) Open a dataset.
+ *
+ * Verify that it contains the expected data
+ *
+ * Verify that the cache image was loaded.
+ *
+ * 6) Close the file.
+ *
+ * 7) Open the file read only.
+ *
+ * 8) Open a dataset.
+ *
+ * Verify that it contains the expected data.
+ *
+ * Verify that the cache image was loaded.
+ *
+ * 9) Close the file.
+ *
+ * 10) Open the file read write.
+ *
+ * 11) Open a dataset.
+ *
+ * Verify that it contains the expected data.
+ *
+ * Verify that the cache image was loaded.
+ *
+ * 12) Close the file.
+ *
+ * 13) Open the file read write.
+ *
+ * 14) Open a dataset.
+ *
+ * Verify that it contains the expected data.
+ *
+ * Verify that the cache image was NOT loaded.
+ *
+ * 15) Close the file.
+ *
+ * 16) Delete the file.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 9/25/15
+ *
+ *-------------------------------------------------------------------------
+ */
+
+static unsigned
+cache_image_api_error_check_2(void)
+{
+ const char * fcn_name = "cache_image_api_error_check_2()";
+ char filename[512];
+ hbool_t show_progress = FALSE;
+ hid_t file_id = -1;
+ H5F_t *file_ptr = NULL;
+ H5C_t *cache_ptr = NULL;
+ int cp = 0;
+
+ TESTING("metadata cache image api error check 2");
+
+ pass = TRUE;
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* setup the file name */
+ if ( pass ) {
+
+ if ( h5_fixname(FILENAMES[0], H5P_DEFAULT, filename, sizeof(filename))
+ == NULL ) {
+
+ pass = FALSE;
+ failure_mssg = "h5_fixname() failed.\n";
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 1) Create a HDF5 file with a cache image requested. */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ TRUE,
+ /* mdci_sbem_expected */ FALSE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ TRUE,
+ /* config_fsm */ TRUE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ H5C_CI__ALL_FLAGS,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 2) Create some datasets in the file. */
+
+ if ( pass ) {
+
+ create_datasets(file_id, 0, 5);
+ }
+
+#if H5C_COLLECT_CACHE_STATS
+ if ( pass ) {
+
+ if ( cache_ptr->images_loaded != 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "metadata cache image block loaded(1).";
+ }
+ }
+#endif /* H5C_COLLECT_CACHE_STATS */
+
+
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 3) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 4) Open the file read only with a cache image FAPL entry requested. */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ TRUE,
+ /* read_only */ TRUE,
+ /* set_mdci_fapl */ TRUE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ H5C_CI__ALL_FLAGS,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 5) Open and close a dataset.
+ *
+ * Verify that it contains the expected data.
+ *
+ * Verify that the cache image was loaded.
+ */
+
+ if ( pass ) {
+
+ verify_datasets(file_id, 0, 5);
+ }
+
+#if H5C_COLLECT_CACHE_STATS
+ if ( pass ) {
+
+ if ( cache_ptr->images_loaded != 1 ) {
+
+ pass = FALSE;
+ failure_mssg = "metadata cache image block was not loaded(1).";
+ }
+ }
+#endif /* H5C_COLLECT_CACHE_STATS */
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 6) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 7) Open the file read only. */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ TRUE,
+ /* read_only */ TRUE,
+ /* set_mdci_fapl */ FALSE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ 0,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 8) Open and close a dataset.
+ *
+ * Verify that it contains the expected data.
+ *
+ * Verify that the cache image was loaded.
+ */
+
+ if ( pass ) {
+
+ verify_datasets(file_id, 0, 5);
+ }
+
+#if H5C_COLLECT_CACHE_STATS
+ if ( pass ) {
+
+ if ( cache_ptr->images_loaded != 1 ) {
+
+ pass = FALSE;
+ failure_mssg = "metadata cache image block was not loaded(2).";
+ }
+ }
+#endif /* H5C_COLLECT_CACHE_STATS */
+
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 9) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 10) Open the file read / write. */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ TRUE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ FALSE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ H5C_CI__ALL_FLAGS,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+ /* 11) Open and close a dataset.
+ *
+ * Verify that it contains the expected data.
+ *
+ * Verify that the cache image was loaded.
+ */
+
+ if ( pass ) {
+
+ verify_datasets(file_id, 0, 5);
+ }
+
+#if H5C_COLLECT_CACHE_STATS
+ if ( pass ) {
+
+ if ( cache_ptr->images_loaded != 1 ) {
+
+ pass = FALSE;
+ failure_mssg = "metadata cache image block was not loaded(3).";
+ }
+ }
+#endif /* H5C_COLLECT_CACHE_STATS */
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 12) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 13) Open the file read / write. */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ FALSE,
+ /* mdci_sbem_expected */ FALSE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ FALSE,
+ /* config_fsm */ FALSE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ H5C_CI__ALL_FLAGS,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+ /* 14) Open and close a dataset.
+ *
+ * Verify that it contains the expected data.
+ *
+ * Verify that the cache image was not loaded.
+ */
+
+ if ( pass ) {
+
+ verify_datasets(file_id, 0, 5);
+ }
+
+#if H5C_COLLECT_CACHE_STATS
+ if ( pass ) {
+
+ if ( cache_ptr->images_loaded != 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "metadata cache image block was loaded(2).";
+ }
+ }
+#endif /* H5C_COLLECT_CACHE_STATS */
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 15) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 13) Delete the file */
+
+ if ( pass ) {
+
+ if ( HDremove(filename) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "HDremove() failed.\n";
+ }
+ }
+
+ if ( pass ) { PASSED(); } else { H5_FAILED(); }
+
+ if ( ! pass )
+ HDfprintf(stdout, "%s: failure_mssg = \"%s\".\n",
+ FUNC, failure_mssg);
+
+ return !pass;
+
+} /* cache_image_api_error_check_2() */
+
+
+/*-------------------------------------------------------------------------
+ * Function: cache_image_api_error_check_3()
+ *
+ * Purpose: This test is one of a sequence of tests intended
+ * to verify correct management of API errors.
+ *
+ * At present, SWMR and cache image may not be active
+ * at the same time. The purpose of this test is to
+ * verify that attempts to run SWMR and cache image
+ * at the same time will fail.
+ *
+ * The test is set up as follows:
+ *
+ * 1) Create a HDF5 file with a cache image requested..
+ *
+ * 2) Try to start SWMR write -- should fail.
+ *
+ * 3) Discard the file if necessary
+ *
+ * 4) Attempt to create a HDF5 file with SWMR write
+ * access and cache image requested -- should fail.
+ *
+ * 5) Discard the file if necessary
+ *
+ * 6) Create a HDF5 file with a cache image requested.
+ *
+ * 7) Create some datasets in the file.
+ *
+ * 8) Close the file.
+ *
+ * 9) Attempt to open the file with SWMR write access --
+ * should fail.
+ *
+ * 10) Discard the file if necessary.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 12/29/16
+ *
+ *-------------------------------------------------------------------------
+ */
+
+static unsigned
+cache_image_api_error_check_3(void)
+{
+ const char * fcn_name = "cache_image_api_error_check_3()";
+ char filename[512];
+ hbool_t show_progress = FALSE;
+ hid_t file_id = -1;
+ H5F_t *file_ptr = NULL;
+ H5C_t *cache_ptr = NULL;
+ int cp = 0;
+
+ TESTING("metadata cache image api error check 3");
+
+ pass = TRUE;
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* setup the file name */
+ if ( pass ) {
+
+ if ( h5_fixname(FILENAMES[0], H5P_DEFAULT, filename, sizeof(filename))
+ == NULL ) {
+
+ pass = FALSE;
+ failure_mssg = "h5_fixname() failed.\n";
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 1) Create a HDF5 file with a cache image requested. */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ TRUE,
+ /* mdci_sbem_expected */ FALSE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ TRUE,
+ /* config_fsm */ TRUE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ H5C_CI__ALL_FLAGS,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 2) Try to start SWMR write -- should fail. */
+
+ if ( pass ) {
+
+ H5E_BEGIN_TRY {
+ if ( H5Fstart_swmr_write(file_id) == SUCCEED ) {
+
+ pass = FALSE;
+ failure_mssg = "metadata cache image block loaded(1).";
+ }
+ } H5E_END_TRY;
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 3) Discard the file if necessary */
+
+ if ( pass ) {
+
+ if ( HDremove(filename) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "HDremove() failed.\n";
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 4) Attempt to create a HDF5 file with SWMR write
+ * access and cache image requested -- should fail.
+ */
+
+ attempt_swmr_open_hdf5_file(/* create_file */ TRUE,
+ /* set_mdci_fapl */ TRUE,
+ /* hdf_file_name */ filename);
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 5) Discard the file if necessary */
+
+ if ( pass ) {
+
+ /* file probably doesn't exist, so don't
+ * error check the remove call.
+ */
+ HDremove(filename);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 6) Create a HDF5 file with a cache image requested. */
+
+ if ( pass ) {
+
+ open_hdf5_file(/* create_file */ TRUE,
+ /* mdci_sbem_expected */ FALSE,
+ /* read_only */ FALSE,
+ /* set_mdci_fapl */ TRUE,
+ /* config_fsm */ TRUE,
+ /* hdf_file_name */ filename,
+ /* cache_image_flags */ H5C_CI__ALL_FLAGS,
+ /* file_id_ptr */ &file_id,
+ /* file_ptr_ptr */ &file_ptr,
+ /* cache_ptr_ptr */ &cache_ptr);
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 7) Create some datasets in the file. */
+
+ if ( pass ) {
+
+ create_datasets(file_id, 0, 5);
+ }
+
+#if H5C_COLLECT_CACHE_STATS
+ if ( pass ) {
+
+ if ( cache_ptr->images_loaded != 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "metadata cache image block loaded(1).";
+ }
+ }
+#endif /* H5C_COLLECT_CACHE_STATS */
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 8) Close the file. */
+
+ if ( pass ) {
+
+ if ( H5Fclose(file_id) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "H5Fclose() failed.\n";
+
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 9) Attempt to open the file with SWMR write access -- should fail. */
+
+ attempt_swmr_open_hdf5_file(/* create_file */ FALSE,
+ /* set_mdci_fapl */ TRUE,
+ /* hdf_file_name */ filename);
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ /* 10) Discard the file if necessary. */
+
+ if ( pass ) {
+
+ if ( HDremove(filename) < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "HDremove() failed.\n";
+ }
+ }
+
+ if ( show_progress )
+ HDfprintf(stdout, "%s: cp = %d, pass = %d.\n", fcn_name, cp++, pass);
+
+
+ if ( pass ) { PASSED(); } else { H5_FAILED(); }
+
+ if ( ! pass )
+ HDfprintf(stdout, "%s: failure_mssg = \"%s\".\n",
+ FUNC, failure_mssg);
+
+ return !pass;
+
+} /* cache_image_api_error_check_3() */
+
+
+/*-------------------------------------------------------------------------
+ * Function: main
+ *
+ * Purpose: Run tests on the cache code contained in H5C.c
+ *
+ * Return: Success:
+ *
+ * Failure:
+ *
+ * Programmer: John Mainzer
+ * 6/24/04
+ *
+ *-------------------------------------------------------------------------
+ */
+int
+main(void)
+{
+ unsigned nerrs = 0;
+ int express_test;
+
+ H5open();
+
+ express_test = GetTestExpress();
+
+ printf("=========================================\n");
+ printf("Cache image tests\n");
+ printf(" express_test = %d\n", express_test);
+ printf("=========================================\n");
+
+ nerrs += check_cache_image_ctl_flow_1();
+ nerrs += check_cache_image_ctl_flow_2();
+ nerrs += check_cache_image_ctl_flow_3();
+ nerrs += check_cache_image_ctl_flow_4();
+ nerrs += check_cache_image_ctl_flow_5();
+ nerrs += check_cache_image_ctl_flow_6();
+
+ nerrs += cache_image_smoke_check_1();
+ nerrs += cache_image_smoke_check_2();
+ nerrs += cache_image_smoke_check_3();
+ nerrs += cache_image_smoke_check_4();
+ nerrs += cache_image_smoke_check_5();
+ nerrs += cache_image_smoke_check_6();
+
+ nerrs += cache_image_api_error_check_1();
+ nerrs += cache_image_api_error_check_2();
+ nerrs += cache_image_api_error_check_3();
+
+ return(nerrs > 0);
+
+} /* main() */
+
+
diff --git a/test/genall5.c b/test/genall5.c
new file mode 100644
index 0000000..1d92e96
--- /dev/null
+++ b/test/genall5.c
@@ -0,0 +1,3893 @@
+/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *
+ * Copyright by The HDF Group. *
+ * Copyright by the Board of Trustees of the University of Illinois. *
+ * 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. *
+ * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
+
+/* Programmer: John Mainzer
+ * 9/23/15
+ *
+ * This file contains a heavily edited and functionaly reduce
+ * version of the test code first written by Quincey in a file
+ * of the same name.
+ */
+
+#include <assert.h>
+#include <stdbool.h>
+#include <stdlib.h>
+#include <string.h>
+#include "hdf5.h"
+#include "cache_common.h"
+#include "genall5.h"
+
+#define DSET_DIMS (1024 * 1024)
+#define DSET_SMALL_DIMS (64 * 1024)
+#define DSET_CHUNK_DIMS 1024
+#define DSET_COMPACT_DIMS 4096
+
+
+/*-------------------------------------------------------------------------
+ * Function: ns_grp_0
+ *
+ * Purpose: Create an empty "new style" group at the specified location
+ * in the specified file.
+ *
+ * If pass is false on entry, do nothing.
+ *
+ * If an error is detected, set pass to FALSE, and set
+ * failure_mssg to point to an appropriate error message.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 9/14/15
+ *
+ *-------------------------------------------------------------------------
+ */
+
+void
+ns_grp_0(hid_t fid, const char *group_name)
+{
+ hid_t gid = -1;
+ hid_t gcpl = -1;
+ herr_t ret;
+
+ if ( pass ) {
+
+ gcpl = H5Pcreate(H5P_GROUP_CREATE);
+
+ if ( gcpl <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ns_grp_0: H5Pcreate() failed";
+ }
+ assert(gcpl > 0);
+ }
+
+ if ( pass ) {
+
+ ret = H5Pset_link_creation_order(gcpl, H5P_CRT_ORDER_TRACKED);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ns_grp_0: H5Pset_link_creation_order() failed";
+ }
+ assert(ret >= 0);
+ }
+
+ if ( pass ) {
+
+ gid = H5Gcreate2(fid, group_name, H5P_DEFAULT, gcpl, H5P_DEFAULT);
+
+ if ( gid <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ns_grp_0: H5Gcreate2() failed";
+ }
+ assert(gid > 0);
+ }
+
+ if ( pass ) {
+
+ ret = H5Pclose(gcpl);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ns_grp_0: H5Pclose(gcpl) failed";
+ }
+ assert(ret >= 0);
+ }
+
+ if ( pass ) {
+
+ ret = H5Gclose(gid);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ns_grp_0: H5Gclose(gid) failed";
+ }
+ assert(ret >= 0);
+ }
+
+ return;
+
+} /* ns_grp_0 */
+
+
+/*-------------------------------------------------------------------------
+ * Function: vrfy_ns_grp_0
+ *
+ * Purpose: verify an empty "new style" group at the specified location
+ * in the specified file.
+ *
+ * If pass is false on entry, do nothing.
+ *
+ * If an error is detected, set pass to FALSE, and set
+ * failure_mssg to point to an appropriate error message.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 9/14/15
+ *
+ *-------------------------------------------------------------------------
+ */
+
+void vrfy_ns_grp_0(hid_t fid, const char *group_name)
+{
+ hid_t gid = -1;
+ hid_t gcpl = -1;
+ H5G_info_t grp_info;
+ unsigned crt_order_flags = 0;
+ herr_t ret;
+
+ if ( pass ) {
+
+ gid = H5Gopen2(fid, group_name, H5P_DEFAULT);
+
+ if ( gid <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_0: H5Gopen2() failed";
+ }
+ HDassert(gid > 0);
+ }
+
+ if ( pass ) {
+
+ gcpl = H5Gget_create_plist(gid);
+
+ if ( gcpl <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_0: H5Gget_create_plist() failed";
+ }
+ HDassert(gcpl > 0);
+ }
+
+ if ( pass ) {
+
+ ret = H5Pget_link_creation_order(gcpl, &crt_order_flags);
+
+ if ( gcpl <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_0: H5Pget_link_creation_order() failed";
+ }
+ else if ( H5P_CRT_ORDER_TRACKED != crt_order_flags ) {
+
+ pass = FALSE;
+ failure_mssg =
+ "vrfy_ns_grp_0: H5P_CRT_ORDER_TRACKED != crt_order_flags";
+ }
+ HDassert(ret >= 0);
+ HDassert(H5P_CRT_ORDER_TRACKED == crt_order_flags);
+ }
+
+ if ( pass ) {
+
+ ret = H5Pclose(gcpl);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_0: H5Pclose() failed";
+ }
+ HDassert(ret >= 0);
+ }
+
+ if ( pass ) {
+
+ memset(&grp_info, 0, sizeof(grp_info));
+ ret = H5Gget_info(gid, &grp_info);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_0: H5Gget_info() failed";
+ }
+ else if ( H5G_STORAGE_TYPE_COMPACT != grp_info.storage_type ) {
+
+ pass = FALSE;
+ failure_mssg =
+ "vrfy_ns_grp_0: H5G_STORAGE_TYPE_COMPACT != grp_info.storage_type";
+ }
+ else if ( 0 != grp_info.nlinks ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_0: 0 != grp_info.nlinks";
+ }
+ else if ( 0 != grp_info.max_corder ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_0: 0 != grp_info.max_corder";
+ }
+ else if ( FALSE != grp_info.mounted ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_0: FALSE != grp_info.mounted";
+ }
+
+ HDassert(ret >= 0);
+ HDassert(H5G_STORAGE_TYPE_COMPACT == grp_info.storage_type);
+ HDassert(0 == grp_info.nlinks);
+ HDassert(0 == grp_info.max_corder);
+ HDassert(false == grp_info.mounted);
+ }
+
+ if ( pass ) {
+
+ ret = H5Gclose(gid);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_0: H5Gclose() failed";
+ }
+ HDassert(ret >= 0);
+ }
+
+ return;
+
+} /* vrfy_ns_grp_0() */
+
+
+/*-------------------------------------------------------------------------
+ * Function: ns_grp_c
+ *
+ * Purpose: Create a compact "new style" group, with 'nlinks'
+ * soft/hard/external links in it in the specified file.
+ *
+ * If pass is false on entry, do nothing.
+ *
+ * If an error is detected, set pass to FALSE, and set
+ * failure_mssg to point to an appropriate error message.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 9/14/15
+ *
+ *-------------------------------------------------------------------------
+ */
+
+void
+ns_grp_c(hid_t fid, const char *group_name, unsigned nlinks)
+{
+ hid_t gid = -1;
+ hid_t gcpl = -1;
+ unsigned max_compact;
+ unsigned u;
+ herr_t ret;
+
+ if ( pass ) {
+
+ gcpl = H5Pcreate(H5P_GROUP_CREATE);
+
+ if ( gcpl <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ns_grp_c: H5Pcreate(H5P_GROUP_CREATE) failed";
+ }
+ HDassert(gcpl > 0);
+ }
+
+ if ( pass ) {
+
+ ret = H5Pset_link_creation_order(gcpl, H5P_CRT_ORDER_TRACKED);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ns_grp_c: H5Pset_link_creation_order() failed";
+ }
+ HDassert(ret >= 0);
+ }
+
+ if ( pass ) {
+
+ gid = H5Gcreate2(fid, group_name, H5P_DEFAULT, gcpl, H5P_DEFAULT);
+
+ if ( gid <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ns_grp_c: H5Gcreate2() failed";
+ }
+ HDassert(gid > 0);
+ }
+
+ if ( pass ) {
+
+ max_compact = 0;
+ ret = H5Pget_link_phase_change(gcpl, &max_compact, NULL);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ns_grp_c: H5Pget_link_phase_change() failed";
+ }
+ else if ( nlinks <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ns_grp_c: nlinks <= 0";
+ }
+ else if ( nlinks >= max_compact ) {
+
+ pass = FALSE;
+ failure_mssg = "ns_grp_c: nlinks >= max_compact";
+ }
+
+ HDassert(ret >= 0);
+ HDassert(nlinks > 0);
+ HDassert(nlinks < max_compact);
+ }
+
+ u = 0;
+ while ( ( pass ) && ( u < nlinks ) ) {
+
+ char linkname[16];
+
+ sprintf(linkname, "%u", u);
+
+ if(0 == (u % 3)) {
+
+ ret = H5Lcreate_soft(group_name, gid, linkname, H5P_DEFAULT,
+ H5P_DEFAULT);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ns_grp_c: H5Lcreate_soft() failed";
+ }
+ HDassert(ret >= 0);
+ } /* end if */
+ else if(1 == (u % 3)) {
+
+ ret = H5Lcreate_hard(fid, "/", gid, linkname, H5P_DEFAULT,
+ H5P_DEFAULT);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ns_grp_c: H5Lcreate_hard() failed";
+ }
+ HDassert(ret >= 0);
+ } /* end else-if */
+ else {
+
+ HDassert(2 == (u % 3));
+ ret = H5Lcreate_external("external.h5", "/ext", gid, linkname,
+ H5P_DEFAULT, H5P_DEFAULT);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ns_grp_c: H5Lcreate_external() failed";
+ }
+ HDassert(ret >= 0);
+ } /* end else */
+
+ u++;
+
+ } /* end while() */
+
+ if ( pass ) {
+
+ ret = H5Pclose(gcpl);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ns_grp_c: H5Pclose(gcpl) failed";
+ }
+ HDassert(ret >= 0);
+ }
+
+ if ( pass ) {
+
+ ret = H5Gclose(gid);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ns_grp_c: H5Gclose(gid) failed";
+ }
+ HDassert(ret >= 0);
+ }
+
+ return;
+
+} /* ns_grp_c() */
+
+
+/*-------------------------------------------------------------------------
+ * Function: vrfy_ns_grp_c
+ *
+ * Purpose: Verify a compact "new style" group, with 'nlinks'
+ * soft/hard/external links in it in the specified file.
+ *
+ * If pass is false on entry, do nothing.
+ *
+ * If an error is detected, set pass to FALSE, and set
+ * failure_mssg to point to an appropriate error message.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 9/14/15
+ *
+ *-------------------------------------------------------------------------
+ */
+
+void
+vrfy_ns_grp_c(hid_t fid, const char *group_name, unsigned nlinks)
+{
+ hid_t gid = -1;
+ hid_t gcpl = -1;
+ H5G_info_t grp_info;
+ unsigned crt_order_flags = 0;
+ unsigned u;
+ herr_t ret;
+
+ if ( pass ) {
+
+ gid = H5Gopen2(fid, group_name, H5P_DEFAULT);
+
+ if ( gid <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_c: H5Gopen2() failed";
+ }
+ HDassert(gid > 0);
+ }
+
+ if ( pass ) {
+
+ gcpl = H5Gget_create_plist(gid);
+
+ if ( gcpl <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_c: H5Gget_create_plist(gid) failed";
+ }
+ assert(gcpl > 0);
+ }
+
+ if ( pass ) {
+
+ ret = H5Pget_link_creation_order(gcpl, &crt_order_flags);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_c: H5Pget_link_creation_order() failed";
+ }
+ else if ( H5P_CRT_ORDER_TRACKED != crt_order_flags ) {
+
+ pass = FALSE;
+ failure_mssg =
+ "vrfy_ns_grp_c: H5P_CRT_ORDER_TRACKED != crt_order_flags";
+ }
+ HDassert(ret >= 0);
+ HDassert(H5P_CRT_ORDER_TRACKED == crt_order_flags);
+ }
+
+ if ( pass ) {
+
+ ret = H5Pclose(gcpl);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_c: H5Pclose() failed";
+ }
+ HDassert(ret >= 0);
+ }
+
+ if ( pass ) {
+
+ memset(&grp_info, 0, sizeof(grp_info));
+ ret = H5Gget_info(gid, &grp_info);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_c: H5Gget_info() failed";
+ }
+ else if ( H5G_STORAGE_TYPE_COMPACT != grp_info.storage_type ) {
+
+ pass = FALSE;
+ failure_mssg =
+ "vrfy_ns_grp_c: H5G_STORAGE_TYPE_COMPACT != grp_info.storage_type";
+ }
+ else if ( nlinks != grp_info.nlinks ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_c: nlinks != grp_info.nlinks";
+ }
+ else if ( nlinks != grp_info.max_corder ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_c: nlinks != grp_info.max_corder";
+ }
+ else if ( FALSE != grp_info.mounted ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_c: FALSE != grp_info.mounted";
+ }
+
+ HDassert(ret >= 0);
+ HDassert(H5G_STORAGE_TYPE_COMPACT == grp_info.storage_type);
+ HDassert(nlinks == grp_info.nlinks);
+ HDassert(nlinks == grp_info.max_corder);
+ HDassert(false == grp_info.mounted);
+ }
+
+ u = 0;
+ while ( ( pass ) && ( u < nlinks ) ) {
+
+ H5L_info_t lnk_info;
+ char linkname[16];
+ htri_t link_exists;
+
+ sprintf(linkname, "%u", u);
+ link_exists = H5Lexists(gid, linkname, H5P_DEFAULT);
+
+ if ( link_exists < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_c: H5Lexists() failed";
+ }
+ HDassert(link_exists >= 0);
+
+ memset(&lnk_info, 0, sizeof(grp_info));
+ ret = H5Lget_info(gid, linkname, &lnk_info, H5P_DEFAULT);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_c: H5Lget_info() failed";
+ }
+ else if ( TRUE != lnk_info.corder_valid ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_c: TRUE != lnk_info.corder_valid";
+ }
+ else if ( u != lnk_info.corder ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_c: u != lnk_info.corder";
+ }
+ else if ( H5T_CSET_ASCII != lnk_info.cset ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_c: H5T_CSET_ASCII != lnk_info.cset";
+ }
+ HDassert(ret >= 0);
+ HDassert(true == lnk_info.corder_valid);
+ HDassert(u == lnk_info.corder);
+ HDassert(H5T_CSET_ASCII == lnk_info.cset);
+
+ if ( 0 == (u % 3) ) {
+
+ char *slinkval;
+
+ if ( H5L_TYPE_SOFT != lnk_info.type ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_c: H5L_TYPE_SOFT != lnk_info.type";
+ }
+ else if ( (strlen(group_name) + 1) != lnk_info.u.val_size ) {
+
+ pass = FALSE;
+ failure_mssg =
+ "vrfy_ns_grp_c: (strlen(group_name) + 1) != lnk_info.u.val_size";
+ }
+ HDassert(H5L_TYPE_SOFT == lnk_info.type);
+ HDassert((strlen(group_name) + 1) == lnk_info.u.val_size);
+
+ slinkval = (char *)malloc(lnk_info.u.val_size);
+
+ if ( ! slinkval ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_c: malloc of slinkval failed";
+ }
+ HDassert(slinkval);
+
+ ret = H5Lget_val(gid, linkname, slinkval, lnk_info.u.val_size,
+ H5P_DEFAULT);
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_c: H5Lget_val() failed";
+ }
+ else if ( 0 != strcmp(slinkval, group_name) ) {
+
+ pass = FALSE;
+ failure_mssg =
+ "vrfy_ns_grp_c: 0 != strcmp(slinkval, group_name)";
+ }
+ HDassert(ret >= 0);
+ HDassert(0 == strcmp(slinkval, group_name));
+
+ free(slinkval);
+ } /* end if */
+ else if(1 == (u % 3)) {
+
+ H5O_info_t root_oinfo;
+
+ if ( H5L_TYPE_HARD != lnk_info.type ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_c: H5L_TYPE_HARD != lnk_info.type";
+ }
+ HDassert(H5L_TYPE_HARD == lnk_info.type);
+
+ memset(&root_oinfo, 0, sizeof(root_oinfo));
+ ret = H5Oget_info(fid, &root_oinfo);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_c: H5Oget_info() failed.";
+ }
+ else if ( root_oinfo.addr != lnk_info.u.address ) {
+
+ pass = FALSE;
+ failure_mssg =
+ "vrfy_ns_grp_c: root_oinfo.addr != lnk_info.u.address";
+ }
+ HDassert(ret >= 0);
+ HDassert(root_oinfo.addr == lnk_info.u.address);
+ } /* end else-if */
+ else {
+ void *elinkval;
+ const char *file = NULL;
+ const char *path = NULL;
+
+ HDassert(2 == (u % 3));
+
+ if ( H5L_TYPE_EXTERNAL != lnk_info.type ) {
+
+ pass = FALSE;
+ failure_mssg =
+ "vrfy_ns_grp_c: H5L_TYPE_EXTERNAL != lnk_info.type";
+ }
+ HDassert(H5L_TYPE_EXTERNAL == lnk_info.type);
+
+ elinkval = malloc(lnk_info.u.val_size);
+
+ if ( ! elinkval ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_c: malloc of elinkval failed.";
+ }
+ HDassert(elinkval);
+
+ ret = H5Lget_val(gid, linkname, elinkval, lnk_info.u.val_size,
+ H5P_DEFAULT);
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_c: H5Lget_val() failed.";
+ }
+ HDassert(ret >= 0);
+
+ ret = H5Lunpack_elink_val(elinkval, lnk_info.u.val_size,
+ NULL, &file, &path);
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_c: H5Lunpack_elink_val() failed.";
+ }
+ else if ( 0 != strcmp(file, "external.h5") ) {
+
+ pass = FALSE;
+ failure_mssg =
+ "vrfy_ns_grp_c: 0 != strcmp(file, \"external.h5\")";
+ }
+ else if ( 0 != strcmp(path, "/ext") ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_c: 0 != strcmp(path, \"/ext\")";
+ }
+ HDassert(ret >= 0);
+ HDassert(0 == strcmp(file, "external.h5"));
+ HDassert(0 == strcmp(path, "/ext"));
+
+ free(elinkval);
+ } /* end else */
+
+ u++;
+
+ } /* end while */
+
+ if ( pass ) {
+
+ ret = H5Gclose(gid);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_c: H5Gclose() failed.";
+ }
+ assert(ret >= 0);
+ }
+
+ return;
+
+} /* vrfy_ns_grp_c() */
+
+
+/*-------------------------------------------------------------------------
+ * Function: ns_grp_d
+ *
+ * Purpose: Create a dense "new style" group, with 'nlinks'
+ * (soft/hard/external) links in it in the specified file.
+ *
+ * If pass is false on entry, do nothing.
+ *
+ * If an error is detected, set pass to FALSE, and set
+ * failure_mssg to point to an appropriate error message.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 9/14/15
+ *
+ *-------------------------------------------------------------------------
+ */
+
+void
+ns_grp_d(hid_t fid, const char *group_name, unsigned nlinks)
+{
+ hid_t gid = -1;
+ hid_t gcpl = -1;
+ unsigned max_compact;
+ unsigned u;
+ herr_t ret;
+
+ if ( pass ) {
+
+ gcpl = H5Pcreate(H5P_GROUP_CREATE);
+
+ if ( gcpl <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ns_grp_d: H5Pcreate() failed.";
+ }
+ HDassert(gcpl > 0);
+ }
+
+ if ( pass ) {
+
+ ret = H5Pset_link_creation_order(gcpl, H5P_CRT_ORDER_TRACKED);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ns_grp_d: H5Pset_link_creation_order() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ if ( pass ) {
+
+ gid = H5Gcreate2(fid, group_name, H5P_DEFAULT, gcpl, H5P_DEFAULT);
+
+ if ( gid <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ns_grp_d: H5Gcreate2() failed.";
+ }
+ HDassert(gid > 0);
+ }
+
+ if ( pass ) {
+
+ max_compact = 0;
+ ret = H5Pget_link_phase_change(gcpl, &max_compact, NULL);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ns_grp_d: H5Pget_link_phase_change() failed.";
+ }
+ else if ( nlinks <= max_compact ) {
+
+ pass = FALSE;
+ failure_mssg = "ns_grp_d: nlinks <= max_compact";
+ }
+ HDassert(ret >= 0);
+ HDassert(nlinks > max_compact);
+ }
+
+ u = 0;
+ while ( ( pass ) && ( u < nlinks ) ) {
+
+ char linkname[16];
+
+ sprintf(linkname, "%u", u);
+
+ if(0 == (u % 3)) {
+
+ ret = H5Lcreate_soft(group_name, gid, linkname,
+ H5P_DEFAULT, H5P_DEFAULT);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ns_grp_d: H5Lcreate_soft() failed.";
+ }
+ HDassert(ret >= 0);
+ } /* end if */
+ else if(1 == (u % 3)) {
+
+ ret = H5Lcreate_hard(fid, "/", gid, linkname,
+ H5P_DEFAULT, H5P_DEFAULT);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ns_grp_d: H5Lcreate_hard() failed.";
+ }
+ HDassert(ret >= 0);
+ } /* end else-if */
+ else {
+
+ HDassert(2 == (u % 3));
+
+ ret = H5Lcreate_external("external.h5", "/ext", gid, linkname,
+ H5P_DEFAULT, H5P_DEFAULT);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ns_grp_d: H5Lcreate_external() failed.";
+ }
+ HDassert(ret >= 0);
+ } /* end else */
+
+ u++;
+
+ } /* end while */
+
+ if ( pass ) {
+
+ ret = H5Pclose(gcpl);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ns_grp_d: H5Pclose() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ if ( pass ) {
+
+ ret = H5Gclose(gid);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ns_grp_d: H5Gclose() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ return;
+
+} /* ns_grp_d() */
+
+
+/*-------------------------------------------------------------------------
+ * Function: vrfy_ns_grp_d
+ *
+ * Purpose: Verify a dense "new style" group, with 'nlinks'
+ * soft/hard/external links in it in the specified file.
+ *
+ * If pass is false on entry, do nothing.
+ *
+ * If an error is detected, set pass to FALSE, and set
+ * failure_mssg to point to an appropriate error message.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 9/14/15
+ *
+ *-------------------------------------------------------------------------
+ */
+
+
+void
+vrfy_ns_grp_d(hid_t fid, const char *group_name, unsigned nlinks)
+{
+ hid_t gid = -1;
+ hid_t gcpl = -1;
+ H5G_info_t grp_info;
+ unsigned crt_order_flags = 0;
+ unsigned u;
+ herr_t ret;
+
+ if ( pass ) {
+
+ gid = H5Gopen2(fid, group_name, H5P_DEFAULT);
+
+ if ( gid <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_d: H5Gopen2() failed.";
+ }
+ HDassert(gid > 0);
+ }
+
+ if ( pass ) {
+
+ gcpl = H5Gget_create_plist(gid);
+
+ if ( gcpl <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_d: H5Gget_create_plist() failed.";
+ }
+ assert(gcpl > 0);
+ }
+
+ if ( pass ) {
+
+ ret = H5Pget_link_creation_order(gcpl, &crt_order_flags);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg =
+ "vrfy_ns_grp_d: H5Pget_link_creation_order() failed.";
+ }
+ else if ( H5P_CRT_ORDER_TRACKED != crt_order_flags ) {
+
+ pass = FALSE;
+ failure_mssg =
+ "vrfy_ns_grp_d: H5P_CRT_ORDER_TRACKED != crt_order_flags";
+ }
+ HDassert(ret >= 0);
+ HDassert(H5P_CRT_ORDER_TRACKED == crt_order_flags);
+ }
+
+ if ( pass ) {
+
+ ret = H5Pclose(gcpl);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_d: H5Pclose() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ if ( pass ) {
+
+ memset(&grp_info, 0, sizeof(grp_info));
+ ret = H5Gget_info(gid, &grp_info);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_d: H5Gget_info() failed.";
+ }
+ else if ( H5G_STORAGE_TYPE_DENSE != grp_info.storage_type ) {
+
+ pass = FALSE;
+ failure_mssg =
+ "vrfy_ns_grp_d: H5G_STORAGE_TYPE_DENSE != grp_info.storage_type";
+ }
+ else if ( nlinks != grp_info.nlinks ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_d: nlinks != grp_info.nlinks";
+ }
+ else if ( nlinks != grp_info.max_corder ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_d: nlinks != grp_info.max_corder";
+ }
+ else if ( FALSE != grp_info.mounted ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_d: FALSE != grp_info.mounted";
+ }
+ HDassert(ret >= 0);
+ HDassert(H5G_STORAGE_TYPE_DENSE == grp_info.storage_type);
+ HDassert(nlinks == grp_info.nlinks);
+ HDassert(nlinks == grp_info.max_corder);
+ HDassert(false == grp_info.mounted);
+ }
+
+ u = 0;
+ while ( ( pass ) && ( u < nlinks ) ) {
+
+ H5L_info_t lnk_info;
+ char linkname[16];
+ htri_t link_exists;
+
+ sprintf(linkname, "%u", u);
+ link_exists = H5Lexists(gid, linkname, H5P_DEFAULT);
+
+ if ( link_exists < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_d: H5Lexists() failed.";
+ }
+ HDassert(link_exists >= 0);
+
+ memset(&lnk_info, 0, sizeof(grp_info));
+ ret = H5Lget_info(gid, linkname, &lnk_info, H5P_DEFAULT);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_d: H5Lget_info() failed.";
+ }
+ else if ( TRUE != lnk_info.corder_valid ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_d: TRUE != lnk_info.corder_valid";
+ }
+ else if ( u != lnk_info.corder ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_d: u != lnk_info.corder";
+ }
+ else if ( H5T_CSET_ASCII != lnk_info.cset ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_d: H5T_CSET_ASCII != lnk_info.cset";
+ }
+ HDassert(ret >= 0);
+ HDassert(true == lnk_info.corder_valid);
+ HDassert(u == lnk_info.corder);
+ HDassert(H5T_CSET_ASCII == lnk_info.cset);
+
+ if(0 == (u % 3)) {
+ char *slinkval;
+
+ if ( H5L_TYPE_SOFT != lnk_info.type ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_d: H5L_TYPE_SOFT != lnk_info.type";
+ }
+ else if ( (strlen(group_name) + 1) != lnk_info.u.val_size ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_d: H5L_TYPE_SOFT != lnk_info.type";
+ }
+ HDassert(H5L_TYPE_SOFT == lnk_info.type);
+ HDassert((strlen(group_name) + 1) == lnk_info.u.val_size);
+
+ slinkval = (char *)malloc(lnk_info.u.val_size);
+
+ if ( ! slinkval ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_d: malloc of slinkval failed";
+ }
+ HDassert(slinkval);
+
+ ret = H5Lget_val(gid, linkname, slinkval, lnk_info.u.val_size,
+ H5P_DEFAULT);
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_d: H5Lget_val() failed";
+ }
+ else if ( 0 != strcmp(slinkval, group_name) ) {
+
+ pass = FALSE;
+ failure_mssg =
+ "vrfy_ns_grp_d: 0 != strcmp(slinkval, group_name)";
+ }
+ HDassert(ret >= 0);
+ HDassert(0 == strcmp(slinkval, group_name));
+
+ free(slinkval);
+ } /* end if */
+ else if(1 == (u % 3)) {
+ H5O_info_t root_oinfo;
+
+ if ( H5L_TYPE_HARD != lnk_info.type ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_d: H5L_TYPE_HARD != lnk_info.type";
+ }
+ HDassert(H5L_TYPE_HARD == lnk_info.type);
+
+ memset(&root_oinfo, 0, sizeof(root_oinfo));
+ ret = H5Oget_info(fid, &root_oinfo);
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_d: H5Oget_info() failed.";
+ }
+ else if ( root_oinfo.addr != lnk_info.u.address ) {
+
+ pass = FALSE;
+ failure_mssg =
+ "vrfy_ns_grp_d: root_oinfo.addr != lnk_info.u.address";
+ }
+ HDassert(ret >= 0);
+ HDassert(root_oinfo.addr == lnk_info.u.address);
+ } /* end else-if */
+ else {
+ void *elinkval;
+ const char *file = NULL;
+ const char *path = NULL;
+
+ HDassert(2 == (u % 3));
+
+ if ( H5L_TYPE_EXTERNAL != lnk_info.type ) {
+
+ pass = FALSE;
+ failure_mssg =
+ "vrfy_ns_grp_d: H5L_TYPE_EXTERNAL != lnk_info.type";
+ }
+ HDassert(H5L_TYPE_EXTERNAL == lnk_info.type);
+
+ elinkval = malloc(lnk_info.u.val_size);
+
+ if ( ! elinkval ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_d: malloc of elinkval failed.";
+ }
+ HDassert(elinkval);
+
+ ret = H5Lget_val(gid, linkname, elinkval, lnk_info.u.val_size,
+ H5P_DEFAULT);
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_d: H5Lget_val failed.";
+ }
+ HDassert(ret >= 0);
+
+ ret = H5Lunpack_elink_val(elinkval, lnk_info.u.val_size, NULL,
+ &file, &path);
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_d: H5Lunpack_elink_val failed.";
+ }
+ else if ( 0 != strcmp(file, "external.h5") ) {
+
+ pass = FALSE;
+ failure_mssg =
+ "vrfy_ns_grp_d: 0 != strcmp(file, \"external.h5\").";
+ }
+ else if ( 0 != strcmp(path, "/ext") ) {
+
+ pass = FALSE;
+ failure_mssg =
+ "vrfy_ns_grp_d: 0 != strcmp(path, \"/ext\")";
+ }
+ HDassert(ret >= 0);
+ HDassert(0 == strcmp(file, "external.h5"));
+ HDassert(0 == strcmp(path, "/ext"));
+
+ free(elinkval);
+
+ } /* end else */
+
+ u++;
+
+ } /* end while() */
+
+ if ( pass ) {
+
+ ret = H5Gclose(gid);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ns_grp_d: H5Gclose() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ return;
+
+} /* vrfy_ns_grp_d() */
+
+
+/*-------------------------------------------------------------------------
+ * Function: os_grp_0
+ *
+ * Purpose: Create an empty "old style" group.
+ *
+ * If pass is false on entry, do nothing.
+ *
+ * If an error is detected, set pass to FALSE, and set
+ * failure_mssg to point to an appropriate error message.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 9/14/15
+ *
+ *-------------------------------------------------------------------------
+ */
+
+void
+os_grp_0(hid_t fid, const char *group_name)
+{
+ hid_t gid = -1;
+ herr_t ret;
+
+ if ( pass ) { /* turn file format latest off */
+
+ ret = H5Fset_latest_format(fid, FALSE);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "os_grp_0: H5Fset_latest_format() failed(1).";
+ }
+ HDassert(ret >= 0);
+ }
+
+ if ( pass ) {
+
+ gid = H5Gcreate2(fid, group_name, H5P_DEFAULT, H5P_DEFAULT,
+ H5P_DEFAULT);
+ if ( gid <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "os_grp_0: H5Gcreate2() failed.";
+ }
+ HDassert(gid > 0);
+ }
+
+ if ( pass ) {
+
+ ret = H5Gclose(gid);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "os_grp_0: H5Gclose() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ if ( pass ) { /* turn file format latest on */
+
+ ret = H5Fset_latest_format(fid, TRUE);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "os_grp_0: H5Fset_latest_format() failed(2).";
+ }
+ HDassert(ret >= 0);
+ }
+
+ return;
+
+} /* os_grp_0() */
+
+
+/*-------------------------------------------------------------------------
+ * Function: vrfy_os_grp_0
+ *
+ * Purpose: Validate an empty "old style" group.
+ *
+ * If pass is false on entry, do nothing.
+ *
+ * If an error is detected, set pass to FALSE, and set
+ * failure_mssg to point to an appropriate error message.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 9/14/15
+ *
+ *-------------------------------------------------------------------------
+ */
+
+void
+vrfy_os_grp_0(hid_t fid, const char *group_name)
+{
+ hid_t gid = -1;
+ hid_t gcpl = -1;
+ H5G_info_t grp_info;
+ unsigned crt_order_flags = 0;
+ herr_t ret;
+
+ if ( pass ) {
+
+ gid = H5Gopen2(fid, group_name, H5P_DEFAULT);
+
+ if ( gid <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_os_grp_0: H5Gopen2() failed.";
+ }
+ HDassert(gid > 0);
+ }
+
+ if ( pass ) {
+
+ gcpl = H5Gget_create_plist(gid);
+
+ if ( gcpl <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_os_grp_0: H5Gget_create_plist() failed.";
+ }
+ HDassert(gcpl > 0);
+ }
+
+ if ( pass ) {
+
+ ret = H5Pget_link_creation_order(gcpl, &crt_order_flags);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_os_grp_0: H5Pget_link_creation_order() failed";
+ }
+ else if ( 0 != crt_order_flags ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_os_grp_0: 0 != crt_order_flags";
+ }
+ HDassert(ret >= 0);
+ HDassert(0 == crt_order_flags);
+ }
+
+ if ( pass ) {
+
+ ret = H5Pclose(gcpl);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_os_grp_0: H5Pclose() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ if ( pass ) {
+
+ memset(&grp_info, 0, sizeof(grp_info));
+ ret = H5Gget_info(gid, &grp_info);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_os_grp_0: H5Gget_info() failed.";
+ }
+ else if ( H5G_STORAGE_TYPE_SYMBOL_TABLE != grp_info.storage_type ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_os_grp_0: H5G_STORAGE_TYPE_SYMBOL_TABLE != grp_info.storage_type";
+ }
+ else if ( 0 != grp_info.nlinks ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_os_grp_0: 0 != grp_info.nlinks";
+ }
+ else if ( 0 != grp_info.max_corder ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_os_grp_0: 0 != grp_info.max_corder";
+ }
+ else if ( FALSE != grp_info.mounted ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_os_grp_0: FALSE != grp_info.mounted";
+ }
+ HDassert(ret >= 0);
+ HDassert(H5G_STORAGE_TYPE_SYMBOL_TABLE == grp_info.storage_type);
+ HDassert(0 == grp_info.nlinks);
+ HDassert(0 == grp_info.max_corder);
+ HDassert(false == grp_info.mounted);
+ }
+
+ if ( pass ) {
+
+ ret = H5Gclose(gid);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_os_grp_0: H5Gclose() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ return;
+
+} /* vrfy_os_grp_0() */
+
+
+/*-------------------------------------------------------------------------
+ * Function: os_grp_n
+ *
+ * Purpose: Create an "old style" group, with 'nlinks' soft/hard
+ * links in it.
+ *
+ * If pass is false on entry, do nothing.
+ *
+ * If an error is detected, set pass to FALSE, and set
+ * failure_mssg to point to an appropriate error message.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 9/14/15
+ *
+ *-------------------------------------------------------------------------
+ */
+
+void
+os_grp_n(hid_t fid, const char *group_name, int proc_num, unsigned nlinks)
+{
+ hid_t gid = -1;
+ unsigned u;
+ herr_t ret;
+
+ if ( pass ) { /* turn file format latest off */
+
+ ret = H5Fset_latest_format(fid, FALSE);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "os_grp_n: H5Fset_latest_format() failed(1).";
+ }
+ HDassert(ret >= 0);
+ }
+
+ if ( pass ) {
+
+ gid = H5Gcreate2(fid, group_name, H5P_DEFAULT, H5P_DEFAULT,
+ H5P_DEFAULT);
+ if ( gid <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "os_grp_n: H5Gcreate2() failed.";
+ }
+ HDassert(gid > 0);
+ }
+
+ HDassert(nlinks > 0);
+
+ u = 0;
+ while ( ( pass ) && ( u < nlinks ) ) {
+
+ char linkname[32];
+
+ sprintf(linkname, "ln%d_%u", proc_num, u);
+
+ if(0 == (u % 2)) {
+
+ ret = H5Lcreate_soft(group_name, gid, linkname, H5P_DEFAULT,
+ H5P_DEFAULT);
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "os_grp_n: H5Lcreate_soft() failed.";
+ }
+ HDassert(ret >= 0);
+ } /* end if */
+ else {
+
+ HDassert(1 == (u % 2));
+
+ ret = H5Lcreate_hard(fid, "/", gid, linkname, H5P_DEFAULT,
+ H5P_DEFAULT);
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "os_grp_n: H5Lcreate_hard() failed.";
+ }
+ HDassert(ret >= 0);
+ } /* end else */
+
+ u++;
+
+ } /* end while */
+
+ if ( pass ) {
+
+ ret = H5Gclose(gid);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "os_grp_n: H5Gclose() failed.";
+ }
+ assert(ret >= 0);
+ }
+
+ if ( pass ) { /* turn file format latest on */
+
+ ret = H5Fset_latest_format(fid, TRUE);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "os_grp_n: H5Fset_latest_format() failed(2).";
+ }
+ HDassert(ret >= 0);
+ }
+
+ return;
+} /* os_grp_n() */
+
+
+/*-------------------------------------------------------------------------
+ * Function: vrfy_os_grp_n
+ *
+ * Purpose: Validate an "old style" group with 'nlinks' soft/hard
+ * links in it.
+ *
+ * If pass is false on entry, do nothing.
+ *
+ * If an error is detected, set pass to FALSE, and set
+ * failure_mssg to point to an appropriate error message.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 9/14/15
+ *
+ *-------------------------------------------------------------------------
+ */
+void
+vrfy_os_grp_n(hid_t fid, const char *group_name, int proc_num, unsigned nlinks)
+{
+ hid_t gid = -1;
+ hid_t gcpl = -1;
+ H5G_info_t grp_info;
+ unsigned crt_order_flags = 0;
+ unsigned u;
+ herr_t ret;
+
+ if ( pass ) {
+
+ gid = H5Gopen2(fid, group_name, H5P_DEFAULT);
+
+ if ( gid <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_os_grp_n: H5Gopen2() failed";
+ }
+ HDassert(gid > 0);
+ }
+
+ if ( pass ) {
+
+ gcpl = H5Gget_create_plist(gid);
+
+ if ( gcpl <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_os_grp_n: H5Gget_create_plist() failed";
+ }
+ HDassert(gcpl > 0);
+ }
+
+ if ( pass ) {
+
+ ret = H5Pget_link_creation_order(gcpl, &crt_order_flags);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_os_grp_n: H5Pget_link_creation_order";
+ }
+ else if ( 0 != crt_order_flags ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_os_grp_n: 0 != crt_order_flags";
+ }
+ HDassert(ret >= 0);
+ HDassert(0 == crt_order_flags);
+ }
+
+ if ( pass ) {
+
+ ret = H5Pclose(gcpl);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_os_grp_n: H5Pclose() failed";
+ }
+ HDassert(ret >= 0);
+ }
+
+ if ( pass ) {
+
+ memset(&grp_info, 0, sizeof(grp_info));
+
+ ret = H5Gget_info(gid, &grp_info);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_os_grp_n: H5Gget_info() failed";
+ }
+ else if ( H5G_STORAGE_TYPE_SYMBOL_TABLE != grp_info.storage_type ) {
+
+ pass = FALSE;
+ failure_mssg =
+ "vrfy_os_grp_n: H5G_STORAGE_TYPE_SYMBOL_TABLE != grp_info.storage_type";
+ }
+ else if ( nlinks != grp_info.nlinks ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_os_grp_n: nlinks != grp_info.nlinks";
+ }
+ else if ( 0 != grp_info.max_corder ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_os_grp_n: 0 != grp_info.max_corder";
+ }
+ else if ( FALSE != grp_info.mounted ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_os_grp_n: FALSE != grp_info.mounted";
+ }
+ HDassert(ret >= 0);
+ HDassert(H5G_STORAGE_TYPE_SYMBOL_TABLE == grp_info.storage_type);
+ HDassert(nlinks == grp_info.nlinks);
+ HDassert(0 == grp_info.max_corder);
+ HDassert(false == grp_info.mounted);
+ }
+
+ u = 0;
+ while ( ( pass ) && ( u < nlinks ) ) {
+
+ H5L_info_t lnk_info;
+ char linkname[32];
+ htri_t link_exists;
+
+ sprintf(linkname, "ln%d_%u", proc_num, u);
+ link_exists = H5Lexists(gid, linkname, H5P_DEFAULT);
+
+ if ( link_exists < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_os_grp_n: H5Lexists() failed";
+ }
+ HDassert(link_exists >= 0);
+
+ memset(&lnk_info, 0, sizeof(grp_info));
+ ret = H5Lget_info(gid, linkname, &lnk_info, H5P_DEFAULT);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_os_grp_n: H5Lget_info() failed";
+ }
+ else if ( FALSE != lnk_info.corder_valid ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_os_grp_n: FALSE != lnk_info.corder_valid";
+ }
+ else if ( H5T_CSET_ASCII != lnk_info.cset ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_os_grp_n: H5T_CSET_ASCII != lnk_info.cset";
+ }
+ HDassert(ret >= 0);
+ HDassert(false == lnk_info.corder_valid);
+ HDassert(H5T_CSET_ASCII == lnk_info.cset);
+
+ if(0 == (u % 2)) {
+ char *slinkval;
+
+ if ( H5L_TYPE_SOFT != lnk_info.type ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_os_grp_n: H5L_TYPE_SOFT != lnk_info.type";
+ }
+ else if ( (strlen(group_name) + 1) != lnk_info.u.val_size ) {
+
+ pass = FALSE;
+ failure_mssg =
+ "vrfy_os_grp_n: (strlen(group_name) + 1) != lnk_info.u.val_size";
+ }
+ HDassert(H5L_TYPE_SOFT == lnk_info.type);
+ HDassert((strlen(group_name) + 1) == lnk_info.u.val_size);
+
+ slinkval = (char *)malloc(lnk_info.u.val_size);
+
+ if ( ! slinkval ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_os_grp_n: malloc of slinkval failed";
+ }
+ HDassert(slinkval);
+
+ ret = H5Lget_val(gid, linkname, slinkval, lnk_info.u.val_size,
+ H5P_DEFAULT);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_os_grp_n: H5Lget_val() failed";
+ }
+ else if ( 0 != strcmp(slinkval, group_name) ) {
+
+ pass = FALSE;
+ failure_mssg =
+ "vrfy_os_grp_n: 0 != strcmp(slinkval, group_name)";
+ }
+ HDassert(ret >= 0);
+ HDassert(0 == strcmp(slinkval, group_name));
+
+ free(slinkval);
+ } /* end if */
+ else {
+ H5O_info_t root_oinfo;
+
+ HDassert(1 == (u % 2));
+
+ if ( H5L_TYPE_HARD != lnk_info.type ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_os_grp_n: H5L_TYPE_HARD != lnk_info.type";
+ }
+ HDassert(H5L_TYPE_HARD == lnk_info.type);
+
+ memset(&root_oinfo, 0, sizeof(root_oinfo));
+ ret = H5Oget_info(fid, &root_oinfo);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_os_grp_n: H5Oget_info() failed.";
+ }
+ else if ( root_oinfo.addr != lnk_info.u.address ) {
+
+ pass = FALSE;
+ failure_mssg =
+ "vrfy_os_grp_n: root_oinfo.addr != lnk_info.u.address";
+ }
+ HDassert(ret >= 0);
+ HDassert(root_oinfo.addr == lnk_info.u.address);
+ } /* end else */
+
+ u++;
+
+ } /* end while */
+
+ if ( pass ) {
+
+ ret = H5Gclose(gid);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_os_grp_n: H5Gclose() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ return;
+
+} /* vrfy_os_grp_n() */
+
+
+/*-------------------------------------------------------------------------
+ * Function: ds_ctg_i
+ *
+ * Purpose: Create a contiguous dataset w/int datatype. Write data
+ * to the data set or not as indicated by the write_data
+ * parameter.
+ *
+ * If pass is false on entry, do nothing.
+ *
+ * If an error is detected, set pass to FALSE, and set
+ * failure_mssg to point to an appropriate error message.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 9/14/15
+ *
+ *-------------------------------------------------------------------------
+ */
+void
+ds_ctg_i(hid_t fid, const char *dset_name, hbool_t write_data)
+{
+ int *wdata = NULL;
+ unsigned u;
+ hid_t dsid = -1;
+ hid_t sid = -1;
+ hsize_t dims[1] = {DSET_DIMS};
+ herr_t ret;
+
+ if ( pass ) {
+
+ sid = H5Screate_simple(1, dims, NULL);
+
+ if ( sid <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ds_ctg_i: H5Screate_simple() failed";
+ }
+ HDassert(sid > 0);
+ }
+
+ if ( pass ) {
+
+ dsid = H5Dcreate2(fid, dset_name, H5T_NATIVE_INT, sid, H5P_DEFAULT,
+ H5P_DEFAULT, H5P_DEFAULT);
+
+ if ( dsid <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ds_ctg_i: H5Dcreate2() failed";
+ }
+ HDassert(dsid > 0);
+ }
+
+ if ( pass ) {
+
+ ret = H5Sclose(sid);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ds_ctg_i: H5Sclose() failed";
+ }
+ HDassert(ret >= 0);
+ }
+
+ if ( ( pass ) && ( write_data ) ) {
+
+ wdata = (int *)malloc(sizeof(int) * DSET_DIMS);
+
+ if ( ! wdata ) {
+
+ pass = FALSE;
+ failure_mssg = "ds_ctg_i: malloc of wdata failed.";
+ }
+ HDassert(wdata);
+ }
+
+ if ( ( pass ) && ( write_data ) ) {
+
+ for(u = 0; u < DSET_DIMS; u++)
+
+ wdata[u] = (int)u;
+
+ ret = H5Dwrite(dsid, H5T_NATIVE_INT, H5S_ALL, H5S_ALL,
+ H5P_DEFAULT, wdata);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ds_ctg_i: H5Dwrite() failed.";
+ }
+ HDassert(ret >= 0);
+
+ free(wdata);
+ }
+
+ if ( pass ) {
+
+ ret = H5Dclose(dsid);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ds_ctg_i: H5Dclose() failed";
+ }
+ HDassert(ret >= 0);
+ }
+
+ return;
+
+} /* ds_ctg_i */
+
+
+/*-------------------------------------------------------------------------
+ * Function: vrfy_ds_ctg_i
+ *
+ * Purpose: Validate a contiguous datasets w/int datatypes. Validate
+ * data if indicated via the write_data parameter.
+ *
+ * If pass is false on entry, do nothing.
+ *
+ * If an error is detected, set pass to FALSE, and set
+ * failure_mssg to point to an appropriate error message.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 9/14/15
+ *
+ *-------------------------------------------------------------------------
+ */
+void
+vrfy_ds_ctg_i(hid_t fid, const char *dset_name, hbool_t write_data)
+{
+ int *rdata = NULL;
+ unsigned u;
+ hid_t dsid = -1;
+ hid_t sid = -1;
+ hid_t tid = -1;
+ hid_t dcpl = -1;
+ H5D_space_status_t allocation;
+ H5D_layout_t layout;
+ int ndims;
+ hsize_t dims[1], max_dims[1];
+ htri_t type_equal;
+ herr_t ret;
+
+ if ( pass ) {
+
+ dsid = H5Dopen2(fid, dset_name, H5P_DEFAULT);
+
+ if ( dsid <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_i: H5Dopen2() failed.";
+ }
+ HDassert(dsid > 0);
+ }
+
+ if ( pass ) {
+
+ sid = H5Dget_space(dsid);
+
+ if ( sid <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_i: H5Dget_space() failed.";
+ }
+ HDassert(sid > 0);
+ }
+
+ if ( pass ) {
+
+ ndims = H5Sget_simple_extent_ndims(sid);
+
+ if ( 1 != ndims ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_i: 1 != ndims";
+ }
+ HDassert(1 == ndims);
+ }
+
+ if ( pass ) {
+
+ ret = H5Sget_simple_extent_dims(sid, dims, max_dims);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_i: H5Sget_simple_extent_dims() failed";
+ }
+ else if ( DSET_DIMS != dims[0] ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_i: DSET_DIMS != dims[0]";
+ }
+ else if ( DSET_DIMS != max_dims[0] ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_i: DSET_DIMS != max_dims[0]";
+ }
+ HDassert(ret >= 0);
+ HDassert(DSET_DIMS == dims[0]);
+ HDassert(DSET_DIMS == max_dims[0]);
+ }
+
+ if ( pass ) {
+
+ ret = H5Sclose(sid);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_i: H5Sclose() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ if ( pass ) {
+
+ tid = H5Dget_type(dsid);
+
+ if ( tid <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_i: H5Dget_type() failed.";
+ }
+ HDassert(tid > 0);
+ }
+
+ if ( pass ) {
+
+ type_equal = H5Tequal(tid, H5T_NATIVE_INT);
+
+ if ( 1 != type_equal ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_i: type not H5T_NATIVE_INT";
+ }
+ HDassert(1 == type_equal);
+ }
+
+ if ( pass ) {
+
+ ret = H5Tclose(tid);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_i: H5Tclose() failed.";
+ }
+ assert(ret >= 0);
+ }
+
+ if ( pass ) {
+
+ ret = H5Dget_space_status(dsid, &allocation);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_i: H5Dget_space_status() failed.";
+ }
+ else if ( write_data && ( allocation != H5D_SPACE_STATUS_ALLOCATED ) ) {
+
+ pass = FALSE;
+ failure_mssg =
+ "vrfy_ds_ctg_i: write_data && allocation != H5D_SPACE_STATUS_ALLOCATED";
+ }
+ else if ( !write_data &&
+ ( allocation != H5D_SPACE_STATUS_NOT_ALLOCATED ) ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_i: !write_data && allocation != H5D_SPACE_STATUS_NOT_ALLOCATED";
+ }
+ HDassert(ret >= 0);
+ HDassert((write_data && allocation == H5D_SPACE_STATUS_ALLOCATED) ||
+ (!write_data && allocation == H5D_SPACE_STATUS_NOT_ALLOCATED));
+ }
+
+ if ( pass ) {
+
+ dcpl = H5Dget_create_plist(dsid);
+
+ if ( dcpl <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_i: H5Dget_create_plist() failed.";
+ }
+ HDassert(dcpl > 0);
+ }
+
+ if ( pass ) {
+
+ layout = H5Pget_layout(dcpl);
+
+ if ( H5D_CONTIGUOUS != layout ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_i: H5D_CONTIGUOUS != layout";
+ }
+ HDassert(H5D_CONTIGUOUS == layout);
+ }
+
+ if ( pass ) {
+
+ ret = H5Pclose(dcpl);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_i: H5Pclose() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ if ( ( pass ) && ( write_data ) ) {
+
+ rdata = (int *)malloc(sizeof(int) * DSET_DIMS);
+
+ if ( ! rdata ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_i: malloc of rdata failed.";
+ }
+ HDassert(rdata);
+ }
+
+ if ( ( pass ) && ( write_data ) ) {
+
+ ret = H5Dread(dsid, H5T_NATIVE_INT, H5S_ALL, H5S_ALL,
+ H5P_DEFAULT, rdata);
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_i: H5Dread() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ if ( ( pass ) && ( write_data ) ) {
+
+ for(u = 0; u < DSET_DIMS; u++) {
+
+ if ( (int)u != rdata[u] ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_i: u != rdata[u].";
+ break;
+ }
+ HDassert((int)u == rdata[u]);
+ }
+
+ free(rdata);
+ } /* end if */
+
+ if ( pass ) {
+
+ ret = H5Dclose(dsid);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_i: H5Dclose() failed";
+ }
+ HDassert(ret >= 0);
+ }
+
+ return;
+
+} /* vrfy_ds_ctg_i() */
+
+
+/*-------------------------------------------------------------------------
+ * Function: ds_chk_i
+ *
+ * Purpose: Create a chunked dataset w/int datatype. Write data
+ * to the data set or not as indicated by the write_data
+ * parameter.
+ *
+ * If pass is false on entry, do nothing.
+ *
+ * If an error is detected, set pass to FALSE, and set
+ * failure_mssg to point to an appropriate error message.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 9/14/15
+ *
+ *-------------------------------------------------------------------------
+ */
+void
+ds_chk_i(hid_t fid, const char *dset_name, hbool_t write_data)
+{
+ int *wdata = NULL;
+ unsigned u;
+ hid_t dsid = -1;
+ hid_t dcpl = -1;
+ hid_t sid = -1;
+ hsize_t dims[1] = {DSET_DIMS};
+ hsize_t chunk_dims[1] = {DSET_CHUNK_DIMS};
+ herr_t ret;
+
+ if ( pass ) {
+
+ sid = H5Screate_simple(1, dims, NULL);
+
+ if ( sid <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ds_chk_i: H5Screate_simple() failed.";
+ }
+ HDassert(sid > 0);
+ }
+
+ if ( pass ) {
+
+ dcpl = H5Pcreate(H5P_DATASET_CREATE);
+
+ if ( dcpl <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ds_chk_i: H5Pcreate() failed.";
+ }
+ HDassert(dcpl > 0);
+ }
+
+ if ( pass ) {
+
+ ret = H5Pset_chunk(dcpl, 1, chunk_dims);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ds_chk_i: H5Pset_chunk() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ if ( pass ) {
+
+ dsid = H5Dcreate2(fid, dset_name, H5T_NATIVE_INT, sid,
+ H5P_DEFAULT, dcpl, H5P_DEFAULT);
+
+ if ( dsid <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ds_chk_i: H5Dcreate2() failed";
+ }
+ HDassert(dsid > 0);
+ }
+
+ if ( pass ) {
+
+ ret = H5Pclose(dcpl);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ds_chk_i: H5Pclose() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ if ( pass ) {
+
+ ret = H5Sclose(sid);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ds_chk_i: H5Sclose() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ if ( ( pass ) && ( write_data ) ) {
+
+ wdata = (int *)malloc(sizeof(int) * DSET_DIMS);
+
+ if ( ! wdata ) {
+
+ pass = FALSE;
+ failure_mssg = "ds_chk_i: malloc of wdata failed.";
+ }
+ HDassert(wdata);
+ }
+
+ if ( ( pass ) && ( write_data ) ) {
+
+ for(u = 0; u < DSET_DIMS; u++)
+ wdata[u] = (int)u;
+
+ ret = H5Dwrite(dsid, H5T_NATIVE_INT, H5S_ALL, H5S_ALL,
+ H5P_DEFAULT, wdata);
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ds_chk_i: H5Dwrite() failed.";
+ }
+ HDassert(ret >= 0);
+
+ free(wdata);
+ } /* end if */
+
+ if ( pass ) {
+
+ ret = H5Dclose(dsid);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ds_chk_i: H5Dclose() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ return;
+
+} /* ds_chk_i */
+
+
+/*-------------------------------------------------------------------------
+ * Function: vrfy_ds_chk_i
+ *
+ * Purpose: Validate a chunked datasets w/int datatypes. Validate
+ * data if indicated via the write_data parameter.
+ *
+ * If pass is false on entry, do nothing.
+ *
+ * If an error is detected, set pass to FALSE, and set
+ * failure_mssg to point to an appropriate error message.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 9/14/15
+ *
+ *-------------------------------------------------------------------------
+ */
+void
+vrfy_ds_chk_i(hid_t fid, const char *dset_name, hbool_t write_data)
+{
+ int *rdata = NULL;
+ unsigned u;
+ hid_t dsid = -1;
+ hid_t sid = -1;
+ hid_t tid = -1;
+ hid_t dcpl = -1;
+ H5D_space_status_t allocation;
+ H5D_layout_t layout;
+ int ndims;
+ hsize_t dims[1], max_dims[1], chunk_dims[1];
+ htri_t type_equal;
+ herr_t ret;
+
+ if ( pass ) {
+
+ dsid = H5Dopen2(fid, dset_name, H5P_DEFAULT);
+
+ if ( dsid <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_chk_i: H5Dopen2() failed.";
+ }
+ HDassert(dsid > 0);
+ }
+
+ if ( pass ) {
+
+ sid = H5Dget_space(dsid);
+
+ if ( sid <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_chk_i: H5Dget_space() failed.";
+ }
+ HDassert(sid > 0);
+ }
+
+ if ( pass ) {
+
+ ndims = H5Sget_simple_extent_ndims(sid);
+
+ if ( 1 != ndims ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_chk_i: 1 != ndims";
+ }
+ HDassert(1 == ndims);
+ }
+
+ if ( pass ) {
+
+ ret = H5Sget_simple_extent_dims(sid, dims, max_dims);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_chk_i: H5Sget_simple_extent_dims() failed";
+ }
+ else if ( DSET_DIMS != dims[0] ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_chk_i: DSET_DIMS != dims[0]";
+ }
+ else if ( DSET_DIMS != max_dims[0] ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_chk_i: DSET_DIMS != max_dims[0]";
+ }
+ HDassert(ret >= 0);
+ HDassert(DSET_DIMS == dims[0]);
+ HDassert(DSET_DIMS == max_dims[0]);
+ }
+
+ if ( pass ) {
+
+ ret = H5Sclose(sid);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_chk_i: H5Sclose() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ if ( pass ) {
+
+ tid = H5Dget_type(dsid);
+
+ if ( tid <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_chk_i: H5Dget_type() failed.";
+ }
+ HDassert(tid > 0);
+ }
+
+ if ( pass ) {
+
+ type_equal = H5Tequal(tid, H5T_NATIVE_INT);
+
+ if ( 1 != type_equal ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_chk_i: tid != H5T_NATIVE_INT";
+ }
+ HDassert(1 == type_equal);
+ }
+
+ if ( pass ) {
+
+ ret = H5Tclose(tid);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_chk_i: H5Tclose() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ if ( pass ) {
+
+ ret = H5Dget_space_status(dsid, &allocation);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_chk_i: H5Dget_space_status() failed.";
+ }
+ else if ( write_data && ( allocation != H5D_SPACE_STATUS_ALLOCATED ) ) {
+
+ pass = FALSE;
+ failure_mssg =
+ "vrfy_ds_chk_i: write_data && allocation != H5D_SPACE_STATUS_ALLOCATED";
+ }
+ else if ( !write_data &&
+ ( allocation != H5D_SPACE_STATUS_NOT_ALLOCATED ) ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_chk_i: !write_data && allocation != H5D_SPACE_STATUS_NOT_ALLOCATED";
+ }
+ HDassert(ret >= 0);
+ HDassert((write_data && allocation == H5D_SPACE_STATUS_ALLOCATED) ||
+ (!write_data && allocation == H5D_SPACE_STATUS_NOT_ALLOCATED));
+ }
+
+ if ( pass ) {
+
+ dcpl = H5Dget_create_plist(dsid);
+
+ if ( dcpl <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_chk_i: H5Dget_create_plist() failed.";
+ }
+ HDassert(dcpl > 0);
+ }
+
+ if ( pass ) {
+
+ layout = H5Pget_layout(dcpl);
+
+ if ( H5D_CHUNKED != layout ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_chk_i: H5D_CHUNKED != layout";
+ }
+ HDassert(H5D_CHUNKED == layout);
+ }
+
+ if ( pass ) {
+
+ ret = H5Pget_chunk(dcpl, 1, chunk_dims);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_chk_i: H5Pget_chunk";
+ }
+ else if ( DSET_CHUNK_DIMS != chunk_dims[0] ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_chk_i: ";
+ }
+ HDassert(ret >= 0);
+ HDassert(DSET_CHUNK_DIMS == chunk_dims[0]);
+ }
+
+ if ( pass ) {
+
+ ret = H5Pclose(dcpl);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_chk_i: H5Pclose() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ if ( ( pass ) && ( write_data ) ) {
+
+ rdata = (int *)malloc(sizeof(int) * DSET_DIMS);
+
+ if ( ! rdata ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_chk_i: malloc of rdata failed.";
+ }
+ HDassert(rdata);
+ }
+
+ if ( ( pass ) && ( write_data ) ) {
+
+ ret = H5Dread(dsid, H5T_NATIVE_INT, H5S_ALL, H5S_ALL, H5P_DEFAULT,
+ rdata);
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_chk_i: H5Dread() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ if ( ( pass ) && ( write_data ) ) {
+
+ for(u = 0; u < DSET_DIMS; u++) {
+
+ if ( (int)u != rdata[u] ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_chk_i: u != rdata[u]";
+ break;
+ }
+ HDassert((int)u == rdata[u]);
+ }
+
+ free(rdata);
+ } /* end if */
+
+
+ if ( pass ) {
+
+ ret = H5Dclose(dsid);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_chk_i: H5Dclose() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ return;
+
+} /* vrfy_ds_chk_i() */
+
+
+/*-------------------------------------------------------------------------
+ * Function: ds_cpt_i
+ *
+ * Purpose: Create a compact dataset w/int datatype. Write data
+ * to the data set or not as indicated by the write_data
+ * parameter.
+ *
+ * If pass is false on entry, do nothing.
+ *
+ * If an error is detected, set pass to FALSE, and set
+ * failure_mssg to point to an appropriate error message.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 9/14/15
+ *
+ *-------------------------------------------------------------------------
+ */
+void
+ds_cpt_i(hid_t fid, const char *dset_name, hbool_t write_data)
+{
+ int *wdata = NULL;
+ unsigned u;
+ hid_t dsid = -1;
+ hid_t dcpl = -1;
+ hid_t sid = -1;
+ hsize_t dims[1] = {DSET_COMPACT_DIMS};
+ herr_t ret;
+
+ if ( pass ) {
+
+ sid = H5Screate_simple(1, dims, NULL);
+
+ if ( sid <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ds_cpt_i: H5Screate_simple() failed.";
+ }
+ HDassert(sid > 0);
+ }
+
+ if ( pass ) {
+
+ dcpl = H5Pcreate(H5P_DATASET_CREATE);
+
+ if ( dcpl <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ds_cpt_i: H5Pcreate() failed.";
+ }
+ HDassert(dcpl > 0);
+ }
+
+ if ( pass ) {
+
+ ret = H5Pset_layout(dcpl, H5D_COMPACT);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ds_cpt_i: H5Pset_layout() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ if ( pass ) {
+
+ dsid = H5Dcreate2(fid, dset_name, H5T_NATIVE_INT, sid,
+ H5P_DEFAULT, dcpl, H5P_DEFAULT);
+
+ if ( dsid <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ds_cpt_i: H5Dcreate2() failed.";
+ }
+ HDassert(dsid > 0);
+ }
+
+ if ( pass ) {
+
+ ret = H5Pclose(dcpl);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ds_cpt_i: H5Pclose() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ if ( pass ) {
+
+ ret = H5Sclose(sid);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ds_cpt_i: H5Sclose() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ if ( ( pass ) && ( write_data ) ) {
+
+ wdata = (int *)malloc(sizeof(int) * DSET_COMPACT_DIMS);
+
+ if ( ! wdata ) {
+
+ pass = FALSE;
+ failure_mssg = "ds_cpt_i: malloc of wdata failed.";
+ }
+ HDassert(wdata);
+ }
+
+ if ( ( pass ) && ( write_data ) ) {
+
+ for(u = 0; u < DSET_COMPACT_DIMS; u++)
+ wdata[u] = (int)u;
+
+ ret = H5Dwrite(dsid, H5T_NATIVE_INT, H5S_ALL, H5S_ALL,
+ H5P_DEFAULT, wdata);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ds_cpt_i: H5Dwrite() failed.";
+ }
+ HDassert(ret >= 0);
+
+ free(wdata);
+ } /* end if */
+
+ if ( pass ) {
+
+ ret = H5Dclose(dsid);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ds_cpt_i: H5Dclose() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ return;
+
+} /* ds_cpt_i() */
+
+
+/*-------------------------------------------------------------------------
+ * Function: vrfy_ds_cpt_i
+ *
+ * Purpose: Validate a compact datasets w/int datatypes. Validate
+ * data if indicated via the write_data parameter.
+ *
+ * If pass is false on entry, do nothing.
+ *
+ * If an error is detected, set pass to FALSE, and set
+ * failure_mssg to point to an appropriate error message.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 9/14/15
+ *
+ *-------------------------------------------------------------------------
+ */
+void
+vrfy_ds_cpt_i(hid_t fid, const char *dset_name, hbool_t write_data)
+{
+ int *rdata = NULL;
+ unsigned u;
+ hid_t dsid = -1;
+ hid_t sid = -1;
+ hid_t tid = -1;
+ hid_t dcpl = -1;
+ H5D_space_status_t allocation;
+ H5D_layout_t layout;
+ int ndims;
+ hsize_t dims[1], max_dims[1];
+ htri_t type_equal;
+ herr_t ret;
+
+ if ( pass ) {
+
+ dsid = H5Dopen2(fid, dset_name, H5P_DEFAULT);
+
+ if ( dsid <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_cpt_i: H5Dopen2() failed.";
+ }
+ HDassert(dsid > 0);
+ }
+
+ if ( pass ) {
+
+ sid = H5Dget_space(dsid);
+
+ if ( sid <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_cpt_i: H5Dget_space() failed.";
+ }
+ HDassert(sid > 0);
+ }
+
+ if ( pass ) {
+
+ ndims = H5Sget_simple_extent_ndims(sid);
+
+ if ( 1 != ndims ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_cpt_i: 1 != ndims";
+ }
+ HDassert(1 == ndims);
+ }
+
+ if ( pass ) {
+
+ ret = H5Sget_simple_extent_dims(sid, dims, max_dims);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_cpt_i: H5Sget_simple_extent_dims() failed";
+ }
+ else if ( DSET_COMPACT_DIMS != dims[0] ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_cpt_i: DSET_COMPACT_DIMS != dims[0]";
+ }
+ else if ( DSET_COMPACT_DIMS != max_dims[0] ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_cpt_i: DSET_COMPACT_DIMS != max_dims[0]";
+ }
+ HDassert(ret >= 0);
+ HDassert(DSET_COMPACT_DIMS == dims[0]);
+ HDassert(DSET_COMPACT_DIMS == max_dims[0]);
+ }
+
+ if ( pass ) {
+
+ ret = H5Sclose(sid);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_cpt_i: H5Sclose() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ if ( pass ) {
+
+ tid = H5Dget_type(dsid);
+
+ if ( tid <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_cpt_i: H5Dget_type() failed.";
+ }
+ HDassert(tid > 0);
+ }
+
+ if ( pass ) {
+
+ type_equal = H5Tequal(tid, H5T_NATIVE_INT);
+
+ if ( 1 != type_equal ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_cpt_i: type != H5T_NATIVE_INT";
+ }
+ HDassert(1 == type_equal);
+ }
+
+ if ( pass ) {
+
+ ret = H5Tclose(tid);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_cpt_i: H5Tclose() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ if ( pass ) {
+
+ ret = H5Dget_space_status(dsid, &allocation);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_cpt_i: H5Dget_space_status() failed.";
+ }
+ else if ( H5D_SPACE_STATUS_ALLOCATED != allocation ) {
+
+ pass = FALSE;
+ failure_mssg =
+ "vrfy_ds_cpt_i: H5D_SPACE_STATUS_ALLOCATED != allocation";
+ }
+ HDassert(ret >= 0);
+ HDassert(H5D_SPACE_STATUS_ALLOCATED == allocation);
+ }
+
+ if ( pass ) {
+
+ dcpl = H5Dget_create_plist(dsid);
+
+ if ( dcpl <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_cpt_i: H5Dget_create_plist() failed.";
+ }
+ HDassert(dcpl > 0);
+ }
+
+ if ( pass ) {
+
+ layout = H5Pget_layout(dcpl);
+
+ if ( H5D_COMPACT != layout ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_cpt_i: H5D_COMPACT != layout";
+ }
+ HDassert(H5D_COMPACT == layout);
+ }
+
+ if ( pass ) {
+
+ ret = H5Pclose(dcpl);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_cpt_i: H5Pclose() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ if ( ( pass ) && ( write_data ) ) {
+
+ rdata = (int *)malloc(sizeof(int) * DSET_COMPACT_DIMS);
+
+ if ( ! rdata ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_cpt_i: malloc of rdata failed.";
+ }
+ HDassert(rdata);
+ }
+
+ if ( ( pass ) && ( write_data ) ) {
+
+ ret = H5Dread(dsid, H5T_NATIVE_INT, H5S_ALL, H5S_ALL,
+ H5P_DEFAULT, rdata);
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_cpt_i: H5Dread() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ if ( ( pass ) && ( write_data ) ) {
+
+ for(u = 0; u < DSET_COMPACT_DIMS; u++) {
+
+ if ( (int)u != rdata[u] ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_cpt_i: (int)u != rdata[u]";
+ break;
+ }
+ HDassert((int)u == rdata[u]);
+ }
+
+ free(rdata);
+ } /* end if */
+
+ if ( pass ) {
+
+ ret = H5Dclose(dsid);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_cpt_i: H5Dclose() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ return;
+
+} /* vrfy_ds_cpt_i() */
+
+
+/*-------------------------------------------------------------------------
+ * Function: ds_ctg_v
+ *
+ * Purpose: Create a contiguous dataset w/variable-length datatype.
+ * Write data to the data set or not as indicated by the
+ * write_data parameter.
+ *
+ * If pass is false on entry, do nothing.
+ *
+ * If an error is detected, set pass to FALSE, and set
+ * failure_mssg to point to an appropriate error message.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 9/14/15
+ *
+ *-------------------------------------------------------------------------
+ */
+void
+ds_ctg_v(hid_t fid, const char *dset_name, hbool_t write_data)
+{
+ hid_t dsid = -1;
+ hid_t sid = -1;
+ hid_t tid = -1;
+ hsize_t dims[1] = {DSET_SMALL_DIMS};
+ herr_t ret;
+ hvl_t *wdata = NULL;
+ unsigned u;
+
+ if ( pass ) {
+
+ sid = H5Screate_simple(1, dims, NULL);
+
+ if ( sid <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ds_ctg_v: H5Screate_simple";
+ }
+ HDassert(sid > 0);
+ }
+
+ if ( pass ) {
+
+ tid = H5Tvlen_create(H5T_NATIVE_INT);
+
+ if ( tid <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ds_ctg_v: H5Tvlen_create() failed.";
+ }
+ HDassert(tid > 0);
+ }
+
+ if ( pass ) {
+
+ dsid = H5Dcreate2(fid, dset_name, tid, sid, H5P_DEFAULT,
+ H5P_DEFAULT, H5P_DEFAULT);
+
+ if ( dsid <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ds_ctg_v: H5Dcreate2() failed.";
+ }
+ HDassert(dsid > 0);
+ }
+
+ if ( ( pass ) && ( write_data ) ) {
+
+ wdata = (hvl_t *)malloc(sizeof(hvl_t) * DSET_SMALL_DIMS);
+
+ if ( ! wdata ) {
+
+ pass = FALSE;
+ failure_mssg = "ds_ctg_v: malloc of wdata failed.";
+ }
+ HDassert(wdata);
+ }
+
+ if ( ( pass ) && ( write_data ) ) {
+
+ for(u = 0; u < DSET_SMALL_DIMS; u++) {
+
+ int *tdata;
+ unsigned len;
+ unsigned v;
+
+ len = (u % 10) + 1;
+ tdata = (int *)malloc(sizeof(int) * len);
+
+ if ( !tdata ) {
+
+ pass = FALSE;
+ failure_mssg = "ds_ctg_v: malloc of tdata failed.";
+ break;
+ }
+ HDassert(tdata);
+
+ for(v = 0; v < len; v++)
+ tdata[v] = (int)(u + v);
+
+ wdata[u].len = len;
+ wdata[u].p = tdata;
+ } /* end for */
+ }
+
+ if ( ( pass ) && ( write_data ) ) {
+
+ ret = H5Dwrite(dsid, tid, H5S_ALL, H5S_ALL, H5P_DEFAULT, wdata);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ds_ctg_v: H5Dwrite() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ if ( ( pass ) && ( write_data ) ) {
+
+ ret = H5Dvlen_reclaim(tid, sid, H5P_DEFAULT, wdata);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ds_ctg_v: H5Dvlen_reclaim() failed.";
+ }
+ HDassert(ret >= 0);
+
+ free(wdata);
+
+ } /* end if */
+
+ if ( pass ) {
+
+ ret = H5Sclose(sid);
+
+ if ( sid < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ds_ctg_v: H5Sclose() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ if ( pass ) {
+
+ ret = H5Tclose(tid);
+
+ if ( tid < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ds_ctg_v: H5Tclose() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ if ( pass ) {
+
+ ret = H5Dclose(dsid);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "ds_ctg_v: H5Dclose() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ return;
+
+} /* ds_ctg_v() */
+
+
+/*-------------------------------------------------------------------------
+ * Function: vrfy_ds_ctg_v
+ *
+ * Purpose: Validate a contiguous datasets w/variable-length datatypes.
+ * Validate data if indicated via the write_data parameter.
+ *
+ * If pass is false on entry, do nothing.
+ *
+ * If an error is detected, set pass to FALSE, and set
+ * failure_mssg to point to an appropriate error message.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 9/14/15
+ *
+ *-------------------------------------------------------------------------
+ */
+void
+vrfy_ds_ctg_v(hid_t fid, const char *dset_name, hbool_t write_data)
+{
+ hid_t dsid = -1;
+ hid_t sid = -1;
+ hid_t tid = -1;
+ hid_t tmp_tid = -1;
+ hid_t dcpl = -1;
+ H5D_space_status_t allocation;
+ H5D_layout_t layout;
+ int ndims;
+ hsize_t dims[1], max_dims[1];
+ htri_t type_equal;
+ hvl_t *rdata = NULL;
+ unsigned u;
+ herr_t ret;
+
+ if ( pass ) {
+
+ dsid = H5Dopen2(fid, dset_name, H5P_DEFAULT);
+
+ if ( dsid <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_v: H5Dopen2() failed.";
+ }
+ HDassert(dsid > 0);
+ }
+
+ if ( pass ) {
+
+ sid = H5Dget_space(dsid);
+
+ if ( sid <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_v: H5Dget_space() failed";
+ }
+ HDassert(sid > 0);
+ }
+
+ if ( pass ) {
+
+ ndims = H5Sget_simple_extent_ndims(sid);
+
+ if ( 1 != ndims ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_v: 1 != ndims";
+ }
+ HDassert(1 == ndims);
+ }
+
+ if ( pass ) {
+
+ ret = H5Sget_simple_extent_dims(sid, dims, max_dims);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_v: H5Sget_simple_extent_dims() failed.";
+ }
+ else if ( DSET_SMALL_DIMS != dims[0] ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_v: DSET_SMALL_DIMS != dims[0]";
+ }
+ else if ( DSET_SMALL_DIMS != max_dims[0] ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_v: DSET_SMALL_DIMS != max_dims[0]";
+ }
+ HDassert(ret >= 0);
+ HDassert(DSET_SMALL_DIMS == dims[0]);
+ HDassert(DSET_SMALL_DIMS == max_dims[0]);
+ }
+
+ if ( pass ) {
+
+ tid = H5Dget_type(dsid);
+
+ if ( tid <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_v: H5Dget_type() failed.";
+ }
+ HDassert(tid > 0);
+ }
+
+ if ( pass ) {
+
+ tmp_tid = H5Tvlen_create(H5T_NATIVE_INT);
+
+ if ( tmp_tid <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_v: H5Tvlen_create() failed.";
+ }
+ HDassert(tmp_tid > 0);
+ }
+
+ if ( pass ) {
+
+ type_equal = H5Tequal(tid, tmp_tid);
+
+ if ( 1 != type_equal ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_v: type != vlen H5T_NATIVE_INT";
+ }
+ HDassert(1 == type_equal);
+ }
+
+ if ( pass ) {
+
+ ret = H5Tclose(tmp_tid);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_v: H5Tclose() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ if ( pass ) {
+
+ ret = H5Dget_space_status(dsid, &allocation);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_v: H5Dget_space_status() failed";
+ }
+ else if ( write_data && (allocation != H5D_SPACE_STATUS_ALLOCATED) ) {
+
+ pass = FALSE;
+ failure_mssg =
+ "vrfy_ds_ctg_v: write_data && allocation != H5D_SPACE_STATUS_ALLOCATED";
+ }
+ else if ( !write_data &&
+ ( allocation != H5D_SPACE_STATUS_NOT_ALLOCATED ) ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_v: !write_data && allocation != H5D_SPACE_STATUS_NOT_ALLOCATED";
+ }
+ HDassert(ret >= 0);
+ HDassert((write_data && allocation == H5D_SPACE_STATUS_ALLOCATED) ||
+ (!write_data && allocation == H5D_SPACE_STATUS_NOT_ALLOCATED));
+ }
+
+ if ( pass ) {
+
+ dcpl = H5Dget_create_plist(dsid);
+
+ if ( dcpl <= 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_v: H5Dget_create_plist() failed.";
+ }
+ HDassert(dcpl > 0);
+ }
+
+ if ( pass ) {
+
+ layout = H5Pget_layout(dcpl);
+
+ if ( H5D_CONTIGUOUS != layout ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_v: H5D_CONTIGUOUS != layout";
+ }
+ HDassert(H5D_CONTIGUOUS == layout);
+ }
+
+ if ( pass ) {
+
+ ret = H5Pclose(dcpl);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_v: H5Pclose() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ if ( ( pass ) && ( write_data ) ) {
+
+ rdata = (hvl_t *)malloc(sizeof(hvl_t) * DSET_SMALL_DIMS);
+
+ if ( !rdata ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_v: malloc of rdata failed.";
+ }
+ HDassert(rdata);
+ }
+
+ if ( ( pass ) && ( write_data ) ) {
+
+ ret = H5Dread(dsid, tid, H5S_ALL, H5S_ALL, H5P_DEFAULT, rdata);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_v: H5Dread() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ if ( ( pass ) && ( write_data ) ) {
+
+ for(u = 0; u < DSET_SMALL_DIMS; u++) {
+ unsigned len;
+ unsigned v;
+
+ len = (unsigned)rdata[u].len;
+ for(v = 0; v < len; v++) {
+ int *tdata = (int *)rdata[u].p;
+
+ if ( !tdata ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_v: !tdata";
+ break;
+ }
+ else if ( (int)(u + v) != tdata[v] ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_v: (int)(u + v) != tdata[v]";
+ break;
+ }
+ HDassert(tdata);
+ HDassert((int)(u + v) == tdata[v]);
+ } /* end for */
+ } /* end for */
+ }
+
+ if ( ( pass ) && ( write_data ) ) {
+
+ ret = H5Dvlen_reclaim(tid, sid, H5P_DEFAULT, rdata);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_v: H5Dvlen_reclaim() failed.";
+ }
+ HDassert(ret >= 0);
+
+ free(rdata);
+ } /* end if */
+
+ if ( pass ) {
+
+ ret = H5Sclose(sid);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_v: H5Sclose() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ if ( pass ) {
+
+ ret = H5Tclose(tid);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_v: H5Tclose() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ if ( pass ) {
+
+ ret = H5Dclose(dsid);
+
+ if ( ret < 0 ) {
+
+ pass = FALSE;
+ failure_mssg = "vrfy_ds_ctg_v: H5Dclose() failed.";
+ }
+ HDassert(ret >= 0);
+ }
+
+ return;
+
+} /* vrfy_ds_ctg_v() */
+
+
+/*-------------------------------------------------------------------------
+ * Function: create_zoo
+ *
+ * Purpose: Given the path to a group, construct a variety of HDF5
+ * data sets, groups, and other objects selected so as to
+ * include instances of all on disk data structures used
+ * in the HDF5 library.
+ *
+ * If pass is false on entry, do nothing.
+ *
+ * If an error is detected, set pass to FALSE, and set
+ * failure_mssg to point to an appropriate error message.
+ *
+ * This function was initially created to assist in testing
+ * the cache image feature of the metadata cache. Thus, it
+ * only concerns itself with the version 2 superblock, and
+ * on disk structures that can occur with this version of
+ * the superblock.
+ *
+ * Note the associated validate_zoo() function.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 9/14/15
+ *
+ *-------------------------------------------------------------------------
+ */
+
+void
+create_zoo(hid_t fid, const char *base_path, int proc_num)
+{
+ char full_path[1024];
+
+ HDassert(base_path);
+
+ /* Add & verify an empty "new style" group */
+ if ( pass ) {
+ sprintf(full_path, "%s/A", base_path);
+ HDassert(strlen(full_path) < 1024);
+ ns_grp_0(fid, full_path);
+ }
+
+ if ( pass ) {
+ sprintf(full_path, "%s/A", base_path);
+ HDassert(strlen(full_path) < 1024);
+ vrfy_ns_grp_0(fid, full_path);
+ }
+
+ /* Add & verify a compact "new style" group (3 link messages) */
+ if ( pass ) {
+ sprintf(full_path, "%s/B", base_path);
+ HDassert(strlen(full_path) < 1024);
+ ns_grp_c(fid, full_path, 3);
+ }
+
+ if ( pass ) {
+ sprintf(full_path, "%s/B", base_path);
+ HDassert(strlen(full_path) < 1024);
+ vrfy_ns_grp_c(fid, full_path, 3);
+ }
+
+ /* Add & verify a dense "new style" group (w/300 links, in v2 B-tree &
+ * fractal heap)
+ */
+ if ( pass ) {
+ sprintf(full_path, "%s/C", base_path);
+ HDassert(strlen(full_path) < 1024);
+ ns_grp_d(fid, full_path, 300);
+ }
+
+ if ( pass ) {
+ sprintf(full_path, "%s/C", base_path);
+ HDassert(strlen(full_path) < 1024);
+ vrfy_ns_grp_d(fid, full_path, 300);
+ }
+
+ /* Add & verify an empty "old style" group to file */
+ if ( pass ) {
+ sprintf(full_path, "%s/D", base_path);
+ HDassert(strlen(full_path) < 1024);
+ os_grp_0(fid, full_path);
+ }
+
+ if ( pass ) {
+ sprintf(full_path, "%s/D", base_path);
+ HDassert(strlen(full_path) < 1024);
+ vrfy_os_grp_0(fid, full_path);
+ }
+
+ /* Add & verify an "old style" group (w/300 links, in v1 B-tree &
+ * local heap) to file
+ */
+ if ( pass ) {
+ sprintf(full_path, "%s/E", base_path);
+ HDassert(strlen(full_path) < 1024);
+ os_grp_n(fid, full_path, proc_num, 300);
+ }
+
+ if ( pass ) {
+ sprintf(full_path, "%s/E", base_path);
+ HDassert(strlen(full_path) < 1024);
+ vrfy_os_grp_n(fid, full_path, proc_num, 300);
+ }
+
+ /* Add & verify a contiguous dataset w/integer datatype (but no data)
+ * to file
+ */
+ if ( pass ) {
+ sprintf(full_path, "%s/F", base_path);
+ HDassert(strlen(full_path) < 1024);
+ ds_ctg_i(fid, full_path, FALSE);
+ }
+
+ if ( pass ) {
+ sprintf(full_path, "%s/F", base_path);
+ HDassert(strlen(full_path) < 1024);
+ vrfy_ds_ctg_i(fid, full_path, FALSE);
+ }
+
+ /* Add & verify a contiguous dataset w/integer datatype (with data)
+ * to file
+ */
+ if ( pass ) {
+ sprintf(full_path, "%s/G", base_path);
+ HDassert(strlen(full_path) < 1024);
+ ds_ctg_i(fid, full_path, TRUE);
+ }
+
+ if ( pass ) {
+ sprintf(full_path, "%s/G", base_path);
+ HDassert(strlen(full_path) < 1024);
+ vrfy_ds_ctg_i(fid, full_path, TRUE);
+ }
+
+ /* Add & verify a chunked dataset w/integer datatype (but no data)
+ * to file
+ */
+ if ( pass ) {
+ sprintf(full_path, "%s/H", base_path);
+ HDassert(strlen(full_path) < 1024);
+ ds_chk_i(fid, full_path, FALSE);
+ }
+
+ if ( pass ) {
+ sprintf(full_path, "%s/H", base_path);
+ HDassert(strlen(full_path) < 1024);
+ vrfy_ds_chk_i(fid, full_path, FALSE);
+ }
+
+ /* Add & verify a chunked dataset w/integer datatype (and data)
+ * to file
+ */
+ if ( pass ) {
+ sprintf(full_path, "%s/I", base_path);
+ HDassert(strlen(full_path) < 1024);
+ ds_chk_i(fid, full_path, TRUE);
+ }
+
+ if ( pass ) {
+ sprintf(full_path, "%s/I", base_path);
+ HDassert(strlen(full_path) < 1024);
+ vrfy_ds_chk_i(fid, full_path, TRUE);
+ }
+
+ /* Add & verify a compact dataset w/integer datatype (but no data)
+ * to file
+ */
+ if ( pass ) {
+ sprintf(full_path, "%s/J", base_path);
+ HDassert(strlen(full_path) < 1024);
+ ds_cpt_i(fid, full_path, FALSE);
+ }
+
+ if ( pass ) {
+ sprintf(full_path, "%s/J", base_path);
+ HDassert(strlen(full_path) < 1024);
+ vrfy_ds_cpt_i(fid, full_path, FALSE);
+ }
+
+ /* Add & verify a compact dataset w/integer datatype (and data)
+ * to file
+ */
+ if ( pass ) {
+ sprintf(full_path, "%s/K", base_path);
+ HDassert(strlen(full_path) < 1024);
+ ds_cpt_i(fid, full_path, TRUE);
+ }
+
+ if ( pass ) {
+ sprintf(full_path, "%s/K", base_path);
+ HDassert(strlen(full_path) < 1024);
+ vrfy_ds_cpt_i(fid, full_path, TRUE);
+ }
+
+ /* Add & verify a contiguous dataset w/variable-length datatype
+ * (but no data) to file
+ */
+ if ( pass ) {
+ sprintf(full_path, "%s/L", base_path);
+ HDassert(strlen(full_path) < 1024);
+ ds_ctg_v(fid, full_path, FALSE);
+ }
+
+ if ( pass ) {
+ sprintf(full_path, "%s/L", base_path);
+ HDassert(strlen(full_path) < 1024);
+ vrfy_ds_ctg_v(fid, full_path, FALSE);
+ }
+
+ /* Add & verify a contiguous dataset w/variable-length datatype
+ * (and data) to file
+ */
+ if ( pass ) {
+ sprintf(full_path, "%s/M", base_path);
+ HDassert(strlen(full_path) < 1024);
+ ds_ctg_v(fid, full_path, TRUE);
+ }
+
+ if ( pass ) {
+ sprintf(full_path, "%s/M", base_path);
+ HDassert(strlen(full_path) < 1024);
+ vrfy_ds_ctg_v(fid, full_path, TRUE);
+ }
+
+ return;
+
+} /* create_zoo() */
+
+
+/*-------------------------------------------------------------------------
+ * Function: validate_zoo
+ *
+ * Purpose: Given the path to a group in which a "zoo" has been
+ * constructed, validate the objects in the "zoo".
+ *
+ * If pass is false on entry, do nothing.
+ *
+ * If an error is detected, set pass to FALSE, and set
+ * failure_mssg to point to an appropriate error message.
+ *
+ * This function was initially created to assist in testing
+ * the cache image feature of the metadata cache. Thus, it
+ * only concerns itself with the version 2 superblock, and
+ * on disk structures that can occur with this version of
+ * the superblock.
+ *
+ * Note the associated validate_zoo() function.
+ *
+ * Return: void
+ *
+ * Programmer: John Mainzer
+ * 9/14/15
+ *
+ *-------------------------------------------------------------------------
+ */
+
+void
+validate_zoo(hid_t fid, const char *base_path, int proc_num)
+{
+ char full_path[1024];
+
+ HDassert(base_path);
+
+ /* validate an empty "new style" group */
+ if ( pass ) {
+ sprintf(full_path, "%s/A", base_path);
+ HDassert(strlen(full_path) < 1024);
+ vrfy_ns_grp_0(fid, full_path);
+ }
+
+ /* validate a compact "new style" group (3 link messages) */
+ if ( pass ) {
+ sprintf(full_path, "%s/B", base_path);
+ HDassert(strlen(full_path) < 1024);
+ vrfy_ns_grp_c(fid, full_path, 3);
+ }
+
+ /* validate a dense "new style" group (w/300 links, in v2 B-tree &
+ * fractal heap)
+ */
+ if ( pass ) {
+ sprintf(full_path, "%s/C", base_path);
+ HDassert(strlen(full_path) < 1024);
+ vrfy_ns_grp_d(fid, full_path, 300);
+ }
+
+ /* validate an empty "old style" group in file */
+ if ( pass ) {
+ sprintf(full_path, "%s/D", base_path);
+ HDassert(strlen(full_path) < 1024);
+ vrfy_os_grp_0(fid, full_path);
+ }
+
+ /* validate an "old style" group (w/300 links, in v1 B-tree &
+ * local heap)
+ */
+ if ( pass ) {
+ sprintf(full_path, "%s/E", base_path);
+ HDassert(strlen(full_path) < 1024);
+ vrfy_os_grp_n(fid, full_path, proc_num, 300);
+ }
+
+ /* validate a contiguous dataset w/integer datatype (but no data)
+ * in file.
+ */
+ if ( pass ) {
+ sprintf(full_path, "%s/F", base_path);
+ HDassert(strlen(full_path) < 1024);
+ vrfy_ds_ctg_i(fid, full_path, FALSE);
+ }
+
+ /* validate a contiguous dataset w/integer datatype (with data)
+ * in file.
+ */
+ if ( pass ) {
+ sprintf(full_path, "%s/G", base_path);
+ HDassert(strlen(full_path) < 1024);
+ vrfy_ds_ctg_i(fid, full_path, TRUE);
+ }
+
+ /* validate a chunked dataset w/integer datatype (but no data)
+ * in file
+ */
+ if ( pass ) {
+ sprintf(full_path, "%s/H", base_path);
+ HDassert(strlen(full_path) < 1024);
+ vrfy_ds_chk_i(fid, full_path, FALSE);
+ }
+
+ /* validate a chunked dataset w/integer datatype (and data)
+ * in file
+ */
+ if ( pass ) {
+ sprintf(full_path, "%s/I", base_path);
+ HDassert(strlen(full_path) < 1024);
+ vrfy_ds_chk_i(fid, full_path, TRUE);
+ }
+
+ /* Validate a compact dataset w/integer datatype (but no data)
+ * in file
+ */
+ if ( pass ) {
+ sprintf(full_path, "%s/J", base_path);
+ HDassert(strlen(full_path) < 1024);
+ vrfy_ds_cpt_i(fid, full_path, FALSE);
+ }
+
+ /* validate a compact dataset w/integer datatype (and data)
+ * in file
+ */
+ if ( pass ) {
+ sprintf(full_path, "%s/K", base_path);
+ HDassert(strlen(full_path) < 1024);
+ vrfy_ds_cpt_i(fid, full_path, TRUE);
+ }
+
+ /* validate a contiguous dataset w/variable-length datatype
+ * (but no data) to file
+ */
+ if ( pass ) {
+ sprintf(full_path, "%s/L", base_path);
+ HDassert(strlen(full_path) < 1024);
+ vrfy_ds_ctg_v(fid, full_path, FALSE);
+ }
+
+ /* validate a contiguous dataset w/variable-length datatype
+ * (and data) to file
+ */
+ if ( pass ) {
+ sprintf(full_path, "%s/M", base_path);
+ HDassert(strlen(full_path) < 1024);
+ vrfy_ds_ctg_v(fid, full_path, TRUE);
+ }
+
+ return;
+
+} /* validate_zoo() */
+
diff --git a/test/genall5.h b/test/genall5.h
new file mode 100644
index 0000000..70b5a6f
--- /dev/null
+++ b/test/genall5.h
@@ -0,0 +1,53 @@
+/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *
+ * Copyright by The HDF Group. *
+ * Copyright by the Board of Trustees of the University of Illinois. *
+ * 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. *
+ * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
+
+/* Programmer: John Mainzer
+ * 9/4/15
+ *
+ * This file contains declarations of all functions defined
+ * in genall5.c
+ */
+
+void create_zoo(hid_t fid, const char *base_path, int proc_num);
+void validate_zoo(hid_t fid, const char *base_path, int proc_num);
+
+void ns_grp_0(hid_t fid, const char *group_name);
+void vrfy_ns_grp_0(hid_t fid, const char *group_name);
+
+void ns_grp_c(hid_t fid, const char *group_name, unsigned nlinks);
+void vrfy_ns_grp_c(hid_t fid, const char *group_name, unsigned nlinks);
+
+void ns_grp_d(hid_t fid, const char *group_name, unsigned nlinks);
+void vrfy_ns_grp_d(hid_t fid, const char *group_name, unsigned nlinks);
+
+void os_grp_0(hid_t fid, const char *group_name);
+void vrfy_os_grp_0(hid_t fid, const char *group_name);
+
+void os_grp_n(hid_t fid, const char *group_name, int proc_num, unsigned nlinks);
+void vrfy_os_grp_n(hid_t fid, const char *group_name, int proc_num,
+ unsigned nlinks);
+
+void ds_ctg_i(hid_t fid, const char *dset_name, hbool_t write_data);
+void vrfy_ds_ctg_i(hid_t fid, const char *dset_name, hbool_t write_data);
+
+void ds_chk_i(hid_t fid, const char *dset_name, hbool_t write_data);
+void vrfy_ds_chk_i(hid_t fid, const char *dset_name, hbool_t write_data);
+
+void ds_cpt_i(hid_t fid, const char *dset_name, hbool_t write_data);
+void vrfy_ds_cpt_i(hid_t fid, const char *dset_name, hbool_t write_data);
+
+void ds_ctg_v(hid_t fid, const char *dset_name, hbool_t write_data);
+void vrfy_ds_ctg_v(hid_t fid, const char *dset_name, hbool_t write_data);
+
generated by cgit v0.12 at 2024-07-19 06:12:59 (GMT)