hdf5/test/genall5.c
Sean McBride 4ac6ccc021
Snprintf2 (#1399)
* Replaced many uses of sprintf with safer snprintf

Many very straightforward, but in a few cases added a length parameter to some private functions, because buffer length was otherwise unknowable.

* Removed unnecessary use of static on small buffers

This improves thread safety.

* Committing clang-format changes

Co-authored-by: github-actions <41898282+github-actions[bot]@users.noreply.github.com>
2022-01-28 16:43:48 -06:00

3394 lines
96 KiB
C

/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *
* 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 COPYING file, which can be found at the root of the source code *
* distribution tree, or in https://www.hdfgroup.org/licenses. *
* 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 functionally reduce
* version of the test code first written by Quincey in a file
* of the same name.
*/
#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";
}
HDassert(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";
}
HDassert(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";
}
HDassert(gid > 0);
}
if (pass) {
ret = H5Pclose(gcpl);
if (ret < 0) {
pass = FALSE;
failure_mssg = "ns_grp_0: H5Pclose(gcpl) failed";
}
HDassert(ret >= 0);
}
if (pass) {
ret = H5Gclose(gid);
if (ret < 0) {
pass = FALSE;
failure_mssg = "ns_grp_0: H5Gclose(gid) failed";
}
HDassert(ret >= 0);
}
} /* 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) {
HDmemset(&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);
}
} /* 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];
HDsnprintf(linkname, sizeof(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);
}
} /* 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";
}
HDassert(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) {
HDmemset(&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_info2_t lnk_info;
char linkname[16];
htri_t link_exists;
HDsnprintf(linkname, sizeof(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);
HDmemset(&lnk_info, 0, sizeof(grp_info));
ret = H5Lget_info2(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 ((HDstrlen(group_name) + 1) != lnk_info.u.val_size) {
pass = FALSE;
failure_mssg = "vrfy_ns_grp_c: (HDstrlen(group_name) + 1) != lnk_info.u.val_size";
}
HDassert(H5L_TYPE_SOFT == lnk_info.type);
HDassert((HDstrlen(group_name) + 1) == lnk_info.u.val_size);
slinkval = (char *)HDmalloc(lnk_info.u.val_size);
if (!slinkval) {
pass = FALSE;
failure_mssg = "vrfy_ns_grp_c: HDmalloc 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 != HDstrcmp(slinkval, group_name)) {
pass = FALSE;
failure_mssg = "vrfy_ns_grp_c: 0 != HDstrcmp(slinkval, group_name)";
}
HDassert(ret >= 0);
HDassert(0 == HDstrcmp(slinkval, group_name));
HDfree(slinkval);
} /* end if */
else if (1 == (u % 3)) {
H5O_info2_t root_oinfo;
int token_cmp = 0;
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);
HDmemset(&root_oinfo, 0, sizeof(root_oinfo));
ret = H5Oget_info3(fid, &root_oinfo, H5O_INFO_BASIC);
if (ret < 0) {
pass = FALSE;
failure_mssg = "vrfy_ns_grp_c: H5Oget_info() failed.";
}
else {
if (H5Otoken_cmp(fid, &root_oinfo.token, &lnk_info.u.token, &token_cmp) < 0) {
pass = FALSE;
failure_mssg = "vrfy_ns_grp_c: H5Otoken_cmp() failed.";
}
if (token_cmp) {
pass = FALSE;
failure_mssg = "vrfy_ns_grp_c: root_oinfo.token != lnk_info.u.token";
}
}
HDassert(ret >= 0);
HDassert(!token_cmp);
} /* 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 = HDmalloc(lnk_info.u.val_size);
if (!elinkval) {
pass = FALSE;
failure_mssg = "vrfy_ns_grp_c: HDmalloc 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 != HDstrcmp(file, "external.h5")) {
pass = FALSE;
failure_mssg = "vrfy_ns_grp_c: 0 != HDstrcmp(file, \"external.h5\")";
}
else if (0 != HDstrcmp(path, "/ext")) {
pass = FALSE;
failure_mssg = "vrfy_ns_grp_c: 0 != HDstrcmp(path, \"/ext\")";
}
HDassert(ret >= 0);
HDassert(0 == HDstrcmp(file, "external.h5"));
HDassert(0 == HDstrcmp(path, "/ext"));
HDfree(elinkval);
} /* end else */
u++;
} /* end while */
if (pass) {
ret = H5Gclose(gid);
if (ret < 0) {
pass = FALSE;
failure_mssg = "vrfy_ns_grp_c: H5Gclose() failed.";
}
HDassert(ret >= 0);
}
} /* 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];
HDsnprintf(linkname, sizeof(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);
}
} /* 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.";
}
HDassert(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) {
HDmemset(&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_info2_t lnk_info;
char linkname[16];
htri_t link_exists;
HDsnprintf(linkname, sizeof(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);
HDmemset(&lnk_info, 0, sizeof(grp_info));
ret = H5Lget_info2(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 ((HDstrlen(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((HDstrlen(group_name) + 1) == lnk_info.u.val_size);
slinkval = (char *)HDmalloc(lnk_info.u.val_size);
if (!slinkval) {
pass = FALSE;
failure_mssg = "vrfy_ns_grp_d: HDmalloc 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 != HDstrcmp(slinkval, group_name)) {
pass = FALSE;
failure_mssg = "vrfy_ns_grp_d: 0 != HDstrcmp(slinkval, group_name)";
}
HDassert(ret >= 0);
HDassert(0 == HDstrcmp(slinkval, group_name));
HDfree(slinkval);
} /* end if */
else if (1 == (u % 3)) {
H5O_info2_t root_oinfo;
int token_cmp = 0;
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);
HDmemset(&root_oinfo, 0, sizeof(root_oinfo));
ret = H5Oget_info3(fid, &root_oinfo, H5O_INFO_BASIC);
if (ret < 0) {
pass = FALSE;
failure_mssg = "vrfy_ns_grp_d: H5Oget_info() failed.";
}
else {
if (H5Otoken_cmp(fid, &root_oinfo.token, &lnk_info.u.token, &token_cmp) < 0) {
pass = FALSE;
failure_mssg = "vrfy_ns_grp_d: H5Otoken_cmp() failed.";
}
if (token_cmp) {
pass = FALSE;
failure_mssg = "vrfy_ns_grp_d: root_oinfo.token != lnk_info.u.token";
}
}
HDassert(ret >= 0);
HDassert(!token_cmp);
} /* 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 = HDmalloc(lnk_info.u.val_size);
if (!elinkval) {
pass = FALSE;
failure_mssg = "vrfy_ns_grp_d: HDmalloc 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 != HDstrcmp(file, "external.h5")) {
pass = FALSE;
failure_mssg = "vrfy_ns_grp_d: 0 != HDstrcmp(file, \"external.h5\").";
}
else if (0 != HDstrcmp(path, "/ext")) {
pass = FALSE;
failure_mssg = "vrfy_ns_grp_d: 0 != HDstrcmp(path, \"/ext\")";
}
HDassert(ret >= 0);
HDassert(0 == HDstrcmp(file, "external.h5"));
HDassert(0 == HDstrcmp(path, "/ext"));
HDfree(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);
}
} /* 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;
hid_t fapl = -1;
H5F_libver_t low, high;
herr_t ret;
if (pass) { /* get the file's file access property list */
fapl = H5Fget_access_plist(fid);
if (fapl <= 0) {
pass = FALSE;
failure_mssg = "os_grp_0: H5Fget_access_plist() failed.";
}
HDassert(fapl > 0);
}
if (pass) { /* get low and high bounds from fapl */
ret = H5Pget_libver_bounds(fapl, &low, &high);
if (ret < 0) {
pass = FALSE;
failure_mssg = "os_grp_0: H5Pget_libver_bounds() failed(1).";
}
HDassert(ret >= 0);
}
if (pass) { /* turn file format latest off */
if (low >= H5F_LIBVER_V18) {
ret = H5Fset_libver_bounds(fid, H5F_LIBVER_EARLIEST, high);
if (ret < 0) {
pass = FALSE;
failure_mssg = "os_grp_0: H5Fset_libver_bounds() 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) { /* restore low and high bounds */
if (low >= H5F_LIBVER_V18) {
ret = H5Fset_libver_bounds(fid, low, high);
if (ret < 0) {
pass = FALSE;
failure_mssg = "os_grp_0: H5Fset_libver_bounds() failed(1).";
}
HDassert(ret >= 0);
}
}
} /* 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) {
HDmemset(&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);
}
} /* 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;
hid_t fapl = -1;
H5F_libver_t low, high;
herr_t ret;
if (pass) { /* get the file's file access property list */
fapl = H5Fget_access_plist(fid);
if (fapl <= 0) {
pass = FALSE;
failure_mssg = "os_grp_n: H5Fget_access_plist() failed.";
}
HDassert(fapl > 0);
}
if (pass) { /* get low and high bounds from fapl */
ret = H5Pget_libver_bounds(fapl, &low, &high);
if (ret < 0) {
pass = FALSE;
failure_mssg = "os_grp_0: H5Pget_libver_bounds() failed(1).";
}
HDassert(ret >= 0);
}
if (pass) { /* turn file format latest off */
if (low >= H5F_LIBVER_V18) {
ret = H5Fset_libver_bounds(fid, H5F_LIBVER_EARLIEST, high);
if (ret < 0) {
pass = FALSE;
failure_mssg = "os_grp_0: H5Fset_libver_bounds() 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];
HDsnprintf(linkname, sizeof(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.";
}
HDassert(ret >= 0);
}
if (pass) { /* restore low and high bounds */
if (low >= H5F_LIBVER_V18) {
ret = H5Fset_libver_bounds(fid, low, high);
if (ret < 0) {
pass = FALSE;
failure_mssg = "os_grp_n: H5Fset_libver_bounds() failed(2).";
}
HDassert(ret >= 0);
}
}
} /* 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) {
HDmemset(&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_info2_t lnk_info;
char linkname[32];
htri_t link_exists;
HDsnprintf(linkname, sizeof(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);
HDmemset(&lnk_info, 0, sizeof(grp_info));
ret = H5Lget_info2(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 ((HDstrlen(group_name) + 1) != lnk_info.u.val_size) {
pass = FALSE;
failure_mssg = "vrfy_os_grp_n: (HDstrlen(group_name) + 1) != lnk_info.u.val_size";
}
HDassert(H5L_TYPE_SOFT == lnk_info.type);
HDassert((HDstrlen(group_name) + 1) == lnk_info.u.val_size);
slinkval = (char *)HDmalloc(lnk_info.u.val_size);
if (!slinkval) {
pass = FALSE;
failure_mssg = "vrfy_os_grp_n: HDmalloc 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 != HDstrcmp(slinkval, group_name)) {
pass = FALSE;
failure_mssg = "vrfy_os_grp_n: 0 != HDstrcmp(slinkval, group_name)";
}
HDassert(ret >= 0);
HDassert(0 == HDstrcmp(slinkval, group_name));
HDfree(slinkval);
} /* end if */
else {
H5O_info2_t root_oinfo;
int token_cmp = 0;
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);
HDmemset(&root_oinfo, 0, sizeof(root_oinfo));
ret = H5Oget_info3(fid, &root_oinfo, H5O_INFO_BASIC);
if (ret < 0) {
pass = FALSE;
failure_mssg = "vrfy_os_grp_n: H5Oget_info() failed.";
}
else {
if (H5Otoken_cmp(fid, &root_oinfo.token, &lnk_info.u.token, &token_cmp) < 0) {
pass = FALSE;
failure_mssg = "vrfy_os_grp_n: H5Otoken_cmp() failed.";
}
if (token_cmp) {
pass = FALSE;
failure_mssg = "vrfy_os_grp_n: root_oinfo.token != lnk_info.u.token";
}
}
HDassert(ret >= 0);
HDassert(!token_cmp);
} /* 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);
}
} /* 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 *)HDmalloc(sizeof(int) * DSET_DIMS);
if (!wdata) {
pass = FALSE;
failure_mssg = "ds_ctg_i: HDmalloc 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);
}
HDfree(wdata);
if (pass) {
ret = H5Dclose(dsid);
if (ret < 0) {
pass = FALSE;
failure_mssg = "ds_ctg_i: H5Dclose() failed";
}
HDassert(ret >= 0);
}
} /* 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.";
}
HDassert(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 *)HDmalloc(sizeof(int) * DSET_DIMS);
if (!rdata) {
pass = FALSE;
failure_mssg = "vrfy_ds_ctg_i: HDmalloc 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]);
}
} /* end if */
HDfree(rdata);
if (pass) {
ret = H5Dclose(dsid);
if (ret < 0) {
pass = FALSE;
failure_mssg = "vrfy_ds_ctg_i: H5Dclose() failed";
}
HDassert(ret >= 0);
}
} /* 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 *)HDmalloc(sizeof(int) * DSET_DIMS);
if (!wdata) {
pass = FALSE;
failure_mssg = "ds_chk_i: HDmalloc 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);
HDfree(wdata);
} /* end if */
if (pass) {
ret = H5Dclose(dsid);
if (ret < 0) {
pass = FALSE;
failure_mssg = "ds_chk_i: H5Dclose() failed.";
}
HDassert(ret >= 0);
}
} /* 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 *)HDmalloc(sizeof(int) * DSET_DIMS);
if (!rdata) {
pass = FALSE;
failure_mssg = "vrfy_ds_chk_i: HDmalloc 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]);
}
} /* end if */
HDfree(rdata);
if (pass) {
ret = H5Dclose(dsid);
if (ret < 0) {
pass = FALSE;
failure_mssg = "vrfy_ds_chk_i: H5Dclose() failed.";
}
HDassert(ret >= 0);
}
} /* 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 *)HDmalloc(sizeof(int) * DSET_COMPACT_DIMS);
if (!wdata) {
pass = FALSE;
failure_mssg = "ds_cpt_i: HDmalloc 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);
HDfree(wdata);
} /* end if */
if (pass) {
ret = H5Dclose(dsid);
if (ret < 0) {
pass = FALSE;
failure_mssg = "ds_cpt_i: H5Dclose() failed.";
}
HDassert(ret >= 0);
}
} /* 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 *)HDmalloc(sizeof(int) * DSET_COMPACT_DIMS);
if (!rdata) {
pass = FALSE;
failure_mssg = "vrfy_ds_cpt_i: HDmalloc 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]);
}
} /* end if */
HDfree(rdata);
if (pass) {
ret = H5Dclose(dsid);
if (ret < 0) {
pass = FALSE;
failure_mssg = "vrfy_ds_cpt_i: H5Dclose() failed.";
}
HDassert(ret >= 0);
}
} /* 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 *)HDmalloc(sizeof(hvl_t) * DSET_SMALL_DIMS);
if (!wdata) {
pass = FALSE;
failure_mssg = "ds_ctg_v: HDmalloc 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 *)HDmalloc(sizeof(int) * len);
if (!tdata) {
pass = FALSE;
failure_mssg = "ds_ctg_v: HDmalloc 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 = H5Treclaim(tid, sid, H5P_DEFAULT, wdata);
if (ret < 0) {
pass = FALSE;
failure_mssg = "ds_ctg_v: H5Treclaim() failed.";
}
HDassert(ret >= 0);
HDfree(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);
}
} /* 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 *)HDmalloc(sizeof(hvl_t) * DSET_SMALL_DIMS);
if (!rdata) {
pass = FALSE;
failure_mssg = "vrfy_ds_ctg_v: HDmalloc 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 = H5Treclaim(tid, sid, H5P_DEFAULT, rdata);
if (ret < 0) {
pass = FALSE;
failure_mssg = "vrfy_ds_ctg_v: H5Treclaim() failed.";
}
HDassert(ret >= 0);
} /* end if */
HDfree(rdata);
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);
}
} /* 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) {
HDsnprintf(full_path, sizeof(full_path), "%s/A", base_path);
HDassert(HDstrlen(full_path) < 1024);
ns_grp_0(fid, full_path);
}
if (pass) {
HDsnprintf(full_path, sizeof(full_path), "%s/A", base_path);
HDassert(HDstrlen(full_path) < 1024);
vrfy_ns_grp_0(fid, full_path);
}
/* Add & verify a compact "new style" group (3 link messages) */
if (pass) {
HDsnprintf(full_path, sizeof(full_path), "%s/B", base_path);
HDassert(HDstrlen(full_path) < 1024);
ns_grp_c(fid, full_path, 3);
}
if (pass) {
HDsnprintf(full_path, sizeof(full_path), "%s/B", base_path);
HDassert(HDstrlen(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) {
HDsnprintf(full_path, sizeof(full_path), "%s/C", base_path);
HDassert(HDstrlen(full_path) < 1024);
ns_grp_d(fid, full_path, 300);
}
if (pass) {
HDsnprintf(full_path, sizeof(full_path), "%s/C", base_path);
HDassert(HDstrlen(full_path) < 1024);
vrfy_ns_grp_d(fid, full_path, 300);
}
/* Add & verify an empty "old style" group to file */
if (pass) {
HDsnprintf(full_path, sizeof(full_path), "%s/D", base_path);
HDassert(HDstrlen(full_path) < 1024);
os_grp_0(fid, full_path);
}
if (pass) {
HDsnprintf(full_path, sizeof(full_path), "%s/D", base_path);
HDassert(HDstrlen(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) {
HDsnprintf(full_path, sizeof(full_path), "%s/E", base_path);
HDassert(HDstrlen(full_path) < 1024);
os_grp_n(fid, full_path, proc_num, 300);
}
if (pass) {
HDsnprintf(full_path, sizeof(full_path), "%s/E", base_path);
HDassert(HDstrlen(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) {
HDsnprintf(full_path, sizeof(full_path), "%s/F", base_path);
HDassert(HDstrlen(full_path) < 1024);
ds_ctg_i(fid, full_path, FALSE);
}
if (pass) {
HDsnprintf(full_path, sizeof(full_path), "%s/F", base_path);
HDassert(HDstrlen(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) {
HDsnprintf(full_path, sizeof(full_path), "%s/G", base_path);
HDassert(HDstrlen(full_path) < 1024);
ds_ctg_i(fid, full_path, TRUE);
}
if (pass) {
HDsnprintf(full_path, sizeof(full_path), "%s/G", base_path);
HDassert(HDstrlen(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) {
HDsnprintf(full_path, sizeof(full_path), "%s/H", base_path);
HDassert(HDstrlen(full_path) < 1024);
ds_chk_i(fid, full_path, FALSE);
}
if (pass) {
HDsnprintf(full_path, sizeof(full_path), "%s/H", base_path);
HDassert(HDstrlen(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) {
HDsnprintf(full_path, sizeof(full_path), "%s/I", base_path);
HDassert(HDstrlen(full_path) < 1024);
ds_chk_i(fid, full_path, TRUE);
}
if (pass) {
HDsnprintf(full_path, sizeof(full_path), "%s/I", base_path);
HDassert(HDstrlen(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) {
HDsnprintf(full_path, sizeof(full_path), "%s/J", base_path);
HDassert(HDstrlen(full_path) < 1024);
ds_cpt_i(fid, full_path, FALSE);
}
if (pass) {
HDsnprintf(full_path, sizeof(full_path), "%s/J", base_path);
HDassert(HDstrlen(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) {
HDsnprintf(full_path, sizeof(full_path), "%s/K", base_path);
HDassert(HDstrlen(full_path) < 1024);
ds_cpt_i(fid, full_path, TRUE);
}
if (pass) {
HDsnprintf(full_path, sizeof(full_path), "%s/K", base_path);
HDassert(HDstrlen(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) {
HDsnprintf(full_path, sizeof(full_path), "%s/L", base_path);
HDassert(HDstrlen(full_path) < 1024);
ds_ctg_v(fid, full_path, FALSE);
}
if (pass) {
HDsnprintf(full_path, sizeof(full_path), "%s/L", base_path);
HDassert(HDstrlen(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) {
HDsnprintf(full_path, sizeof(full_path), "%s/M", base_path);
HDassert(HDstrlen(full_path) < 1024);
ds_ctg_v(fid, full_path, TRUE);
}
if (pass) {
HDsnprintf(full_path, sizeof(full_path), "%s/M", base_path);
HDassert(HDstrlen(full_path) < 1024);
vrfy_ds_ctg_v(fid, full_path, TRUE);
}
} /* 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) {
HDsnprintf(full_path, sizeof(full_path), "%s/A", base_path);
HDassert(HDstrlen(full_path) < 1024);
vrfy_ns_grp_0(fid, full_path);
}
/* validate a compact "new style" group (3 link messages) */
if (pass) {
HDsnprintf(full_path, sizeof(full_path), "%s/B", base_path);
HDassert(HDstrlen(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) {
HDsnprintf(full_path, sizeof(full_path), "%s/C", base_path);
HDassert(HDstrlen(full_path) < 1024);
vrfy_ns_grp_d(fid, full_path, 300);
}
/* validate an empty "old style" group in file */
if (pass) {
HDsnprintf(full_path, sizeof(full_path), "%s/D", base_path);
HDassert(HDstrlen(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) {
HDsnprintf(full_path, sizeof(full_path), "%s/E", base_path);
HDassert(HDstrlen(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) {
HDsnprintf(full_path, sizeof(full_path), "%s/F", base_path);
HDassert(HDstrlen(full_path) < 1024);
vrfy_ds_ctg_i(fid, full_path, FALSE);
}
/* validate a contiguous dataset w/integer datatype (with data)
* in file.
*/
if (pass) {
HDsnprintf(full_path, sizeof(full_path), "%s/G", base_path);
HDassert(HDstrlen(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) {
HDsnprintf(full_path, sizeof(full_path), "%s/H", base_path);
HDassert(HDstrlen(full_path) < 1024);
vrfy_ds_chk_i(fid, full_path, FALSE);
}
/* validate a chunked dataset w/integer datatype (and data)
* in file
*/
if (pass) {
HDsnprintf(full_path, sizeof(full_path), "%s/I", base_path);
HDassert(HDstrlen(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) {
HDsnprintf(full_path, sizeof(full_path), "%s/J", base_path);
HDassert(HDstrlen(full_path) < 1024);
vrfy_ds_cpt_i(fid, full_path, FALSE);
}
/* validate a compact dataset w/integer datatype (and data)
* in file
*/
if (pass) {
HDsnprintf(full_path, sizeof(full_path), "%s/K", base_path);
HDassert(HDstrlen(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) {
HDsnprintf(full_path, sizeof(full_path), "%s/L", base_path);
HDassert(HDstrlen(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) {
HDsnprintf(full_path, sizeof(full_path), "%s/M", base_path);
HDassert(HDstrlen(full_path) < 1024);
vrfy_ds_ctg_v(fid, full_path, TRUE);
}
} /* validate_zoo() */