HDF5 version 1.13.0 currently under development ================================================================================ INTRODUCTION This document describes the differences between this release and the previous HDF5 release. It contains information on the platforms tested and known problems in this release. For more details check the HISTORY*.txt files in the HDF5 source. Note that documentation in the links below will be updated at the time of each final release. Links to HDF5 documentation can be found on The HDF5 web page: https://portal.hdfgroup.org/display/HDF5/HDF5 The official HDF5 releases can be obtained from: https://www.hdfgroup.org/downloads/hdf5/ Changes from Release to Release and New Features in the HDF5-1.13.x release series can be found at: https://portal.hdfgroup.org/display/HDF5/HDF5+Application+Developer%27s+Guide If you have any questions or comments, please send them to the HDF Help Desk: help@hdfgroup.org CONTENTS - New Features - Support for new platforms and languages - Bug Fixes since HDF5-1.12.0 - Supported Platforms - Tested Configuration Features Summary - More Tested Platforms - Known Problems - CMake vs. Autotools installations New Features ============ Configuration: ------------- - CMake option to build the HDF filter plugins project as an external project The HDF filter plugins project is a collection of registered compression filters that can be dynamically loaded when needed to access data stored in a hdf5 file. This CMake-only option allows the plugins to be built and distributed with the hdf5 library and tools. Like the options for szip and zlib, either a tgz file or a git repository can be specified for the source. The option was refactored to use the CMake FetchContent process. This allows more control over the filter targets, but required external project command options to be moved to a CMake include file, HDF5PluginCache.cmake. Also enabled the filter examples to be used as tests for operation of the filter plugins. (ADB - 2020/12/10, OESS-98) - FreeBSD Autotools configuration now defaults to 'cc' and 'c++' compilers On FreeBSD, the autotools defaulted to 'gcc' as the C compiler and did not process C++ options. Since FreeBSD 10, the default compiler has been clang (via 'cc'). The default compilers have been set to 'cc' for C and 'c++' for C++, which will pick up clang and clang++ respectively on FreeBSD 10+. Additionally, clang options are now set correctly for both C and C++ and g++ options will now be set if that compiler is being used (an omission from the former functionality). (DER - 2020/11/28, HDFFV-11193) - Fixed POSIX problems when building w/ gcc on Solaris When building on Solaris using gcc, the POSIX symbols were not being set correctly, which could lead to issues like clock_gettime() not being found. The standard is now set to gnu99 when building with gcc on Solaris, which allows POSIX things to be #defined and linked correctly. This differs slightly from the gcc norm, where we set the standard to c99 and manually set POSIX #define symbols. (DER - 2020/11/25, HDFFV-11191) - Added a configure-time option to consider certain compiler warnings as errors A new configure-time option was added that converts some compiler warnings to errors. This is mainly intended for library developers and currently only works for gcc and clang. The warnings that are considered errors will appear in the generated libhdf5.settings file. These warnings apply to C and C++ code and will appear in "H5 C Flags" and H5 C++ Flags", respectively. They will NOT be exported to h5cc, etc. The default is OFF. Building with this option may fail when compiling on operating systems and with compiler versions not commonly used by the library developers. Compilation may also fail when headers not under the control of the library developers (e.g., mpi.h, hdfs.h) raise warnings. Autotools: --enable-warnings-as-errors CMake: HDF5_ENABLE_WARNINGS_AS_ERRORS (DER - 2020/11/23, HDFFV-11189) - Autotools and CMake target added to produce doxygen generated documentation The default is OFF or disabled. Autoconf option is '--enable-doxygen' autotools make target is 'doxygen' and will build all doxygen targets CMake configure option is 'HDF5_BUILD_DOC'. CMake target is 'doxygen' for all available doxygen targets CMake target is 'hdf5lib_doc' for the src subdirectory (ADB - 2020/11/03) - CMake option to use MSVC naming conventions with MinGW HDF5_MSVC_NAMING_CONVENTION option enable to use MSVC naming conventions when using a MinGW toolchain (xan - 2020/10/30) - CMake option to statically link gcc libs with MinGW HDF5_MINGW_STATIC_GCC_LIBS allows to statically link libg/libstdc++ with the MinGW toolchain (xan - 2020/10/30) - CMake option to build the HDF filter plugins project as an external project The HDF filter plugins project is a collection of registered compression filters that can be dynamically loaded when needed to access data stored in a hdf5 file. This CMake-only option allows the plugins to be built and distributed with the hdf5 library and tools. Like the options for szip and zlib, either a tgz file or a git repository can be specified for the source. The necessary options are (see the INSTALL_CMake.txt file): HDF5_ENABLE_PLUGIN_SUPPORT PLUGIN_TGZ_NAME or PLUGIN_GIT_URL There are more options necessary for various filters and the plugin project documents should be referenced. (ADB - 2020/09/27, OESS-98) - Added CMake option to format source files HDF5_ENABLE_FORMATTERS option will enable creation of targets using the pattern - HDF5_*_SRC_FORMAT - where * corresponds to the source folder or tool folder. All sources can be formatted by executing the format target; make format (ADB - 2020/08/24) - Add file locking configure and CMake options HDF5 1.10.0 introduced a file locking scheme, primarily to help enforce SWMR setup. Formerly, the only user-level control of the scheme was via the HDF5_USE_FILE_LOCKING environment variable. This change introduces configure-time options that control whether or not file locking will be used and whether or not the library ignores errors when locking has been disabled on the file system (useful on some HPC Lustre installations). In both the Autotools and CMake, the settings have the effect of changing the default property list settings (see the H5Pset/get_file_locking() entry, below). The yes/no/best-effort file locking configure setting has also been added to the libhdf5.settings file. Autotools: An --enable-file-locking=(yes|no|best-effort) option has been added. yes: Use file locking. no: Do not use file locking. best-effort: Use file locking and ignore "disabled" errors. CMake: Two self-explanatory options have been added: HDF5_USE_FILE_LOCKING HDF5_IGNORE_DISABLED_FILE_LOCKS Setting both of these to ON is the equivalent to the Autotools' best-effort setting. NOTE: The precedence order of the various file locking control mechanisms is: 1) HDF5_USE_FILE_LOCKING environment variable (highest) 2) H5Pset_file_locking() 3) configure/CMake options (which set the property list defaults) 4) library defaults (currently best-effort) (DER - 2020/07/30, HDFFV-11092) - CMake option to link the generated Fortran MOD files into the include directory. The Fortran generation of MOD files by a Fortran compile can produce different binary files between SHARED and STATIC compiles with different compilers and/or different platforms. Note that it has been found that different versions of Fortran compilers will produce incompatible MOD files. Currently, CMake will locate these MOD files in subfolders of the include directory and add that path to the Fortran library target in the CMake config file, which can be used by the CMake find library process. For other build systems using the binary from a CMake install, a new CMake configuration can be used to copy the pre-chosen version of the Fortran MOD files into the install include directory. The default will depend on the configuration of BUILD_STATIC_LIBS and BUILD_SHARED_LIBS: YES YES Default to SHARED YES NO Default to STATIC NO YES Default to SHARED NO NO Default to SHARED The defaults can be overriden by setting the config option HDF5_INSTALL_MOD_FORTRAN to one of NO, SHARED, or STATIC (ADB - 2020/07/09, HDFFV-11116) - CMake option to use AEC (open source SZip) library instead of SZip The open source AEC library is a replacement library for SZip. In order to use it for hdf5 the libaec CMake source was changed to add "-fPIC" and exclude test files. Autotools does not build the compression libraries within hdf5 builds. New option USE_LIBAEC is required to compensate for the different files produced by AEC build. (ADB - 2020/04/22, OESS-65) - CMake ConfigureChecks.cmake file now uses CHECK_STRUCT_HAS_MEMBER Some handcrafted tests in HDFTests.c has been removed and the CMake CHECK_STRUCT_HAS_MEMBER module has been used. (ADB - 2020/03/24, TRILAB-24) - Both build systems use same set of warnings flags GNU C, C++ and gfortran warnings flags were moved to files in a config sub-folder named gnu-warnings. Flags that only are available for a specific version of the compiler are in files named with that version. Clang C warnings flags were moved to files in a config sub-folder named clang-warnings. Intel C, Fortran warnings flags were moved to files in a config sub-folder named intel-warnings. There are flags in named "error-xxx" files with warnings that may be promoted to errors. Some source files may still need fixes. There are also pairs of files named "developer-xxx" and "no-developer-xxx" that are chosen by the CMake option:HDF5_ENABLE_DEV_WARNINGS or the configure option:--enable-developer-warnings. In addition, CMake no longer applies these warnings for examples. (ADB - 2020/03/24, TRILAB-192) - Added test script for file size compare If CMake minimum version is at least 3.14, the fileCompareTest.cmake script will compare file sizes. (ADB - 2020/02/24, HDFFV-11036) - Update CMake minimum version to 3.12 Updated CMake minimum version to 3.12 and added version checks for Windows features. (ADB - 2020/02/05, TRILABS-142) - Fixed CMake include properties for Fortran libraries Corrected the library properties for Fortran to use the correct path for the Fortran module files. (ADB - 2020/02/04, HDFFV-11012) - Added common warnings files for gnu and intel Added warnings files to use one common set of flags during configure for both autotools and CMake build systems. The initial implementation only affects a general set of flags for gnu and intel compilers. (ADB - 2020/01/17) - Added new options to CMake for control of testing Added CMake options (default ON); HDF5_TEST_SERIAL AND/OR HDF5_TEST_PARALLEL combined with: HDF5_TEST_TOOLS HDF5_TEST_EXAMPLES HDF5_TEST_SWMR HDF5_TEST_FORTRAN HDF5_TEST_CPP HDF5_TEST_JAVA (ADB - 2020/01/15, HDFFV-11001) - Added Clang sanitizers to CMake for analyzer support if compiler is clang. Added CMake code and files to execute the Clang sanitizers if HDF5_ENABLE_SANITIZERS is enabled and the USE_SANITIZER option is set to one of the following: Address Memory MemoryWithOrigins Undefined Thread Leak 'Address;Undefined' (ADB - 2019/12/12, TRILAB-135) - Update CMake for VS2019 support CMake added support for VS2019 in version 3.15. Changes to the CMake generator setting required changes to scripts. Also updated version references in CMake files as necessary. (ADB - 2019/11/18, HDFFV-10962) - Update CMake options to match new autotools options Add configure options (autotools - CMake): enable-asserts HDF5_ENABLE_ASSERTS enable-symbols HDF5_ENABLE_SYMBOLS enable-profiling HDF5_ENABLE_PROFILING enable-optimization HDF5_ENABLE_OPTIMIZATION In addition NDEBUG is no longer forced defined and relies on the CMake process. (ADB - 2019/10/07, HDFFV-100901, HDFFV-10637, TRILAB-97) Library: -------- - Replaced H5E_ATOM with H5E_ID in H5Epubgen.h The term "atom" is archaic and not in line with current HDF5 library terminology, which uses "ID" instead. "Atom" has mostly been purged from the library internals and this change removes H5E_ATOM from the H5Epubgen.h (exposed via H5Epublic.h) and replaces it with H5E_ID. (DER - 2020/11/24, HDFFV-11190) - Add new public function H5Ssel_iter_reset This function resets a dataspace selection iterator back to an initial state so that it may be used for iteration once more. This can be useful when needing to iterate over a selection multiple times without having to repeatedly create/destroy a selection iterator for that dataspace selection. (JTH - 2020/09/18) - Remove HDFS VFD stubs The original implementation of the HDFS VFD included non-functional versions of the following public API calls when the HDFS VFD is not built as a part of the HDF5 library: * H5FD_hdfs_init() * H5Pget_fapl_hdfs() * H5Pset_fapl_hdfs() They will remain present in HDF5 1.10 and HDF5 1.12 releases for binary compatibility purposes but have been removed as of 1.14.0. Note that this has nothing to do with the real HDFS VFD API calls that are fully functional when the HDFS VFD is configured and built. We simply changed: #ifdef LIBHDFS #else #endif to: #ifdef LIBHDFS #endif Which is how the other optional VFDs are handled. (DER - 2020/08/27) - Add Mirror VFD Use TCP/IP sockets to perform write-only (W/O) file I/O on a remote machine. Must be used in conjunction with the Splitter VFD. (JOS - 2020/03/13, TBD) - Add Splitter VFD Maintain separate R/W and W/O channels for "concurrent" file writes to two files using a single HDF5 file handle. (JOS - 2020/03/13, TBD) - Refactored public exposure of haddr_t type in favor of "object tokens" To better accommodate HDF5 VOL connectors where "object addresses in a file" may not make much sense, the following changes were made to the library: * Introduced new H5O_token_t "object token" type, which represents a unique and permanent identifier for referencing an HDF5 object within a container; these "object tokens" are meant to replace object addresses. Along with the new type, a new H5Oopen_by_token API call was introduced to open an object by a token, similar to how object addresses were previously used with H5Oopen_by_addr. * Introduced new H5Lget_info2, H5Lget_info_by_idx2, H5Literate2, H5Literate_by_name2, H5Lvisit2 and H5Lvisit_by_name2 API calls, along with their associated H5L_info2_t struct and H5L_iterate2_t callback function, which work with the newly-introduced object tokens, instead of object addresses. The original functions have been renamed to version 1 functions and are deprecated in favor of the new version 2 functions. The H5L_info_t and H5L_iterate_t types have been renamed to version 1 types and are now deprecated in favor of their version 2 counterparts. For each of the functions and types, compatibility macros take place of the original symbols. * Introduced new H5Oget_info3, H5Oget_info_by_name3, H5Oget_info_by_idx3, H5Ovisit3 and H5Ovisit_by_name3 API calls, along with their associated H5O_info2_t struct and H5O_iterate2_t callback function, which work with the newly-introduced object tokens, instead of object addresses. The version 2 functions are now deprecated in favor of the version 3 functions. The H5O_info_t and H5O_iterate_t types have been renamed to version 1 types and are now deprecated in favor of their version 2 counterparts. For each, compatibility macros take place of the original symbols. * Introduced new H5Oget_native_info, H5Oget_native_info_by_name and H5Oget_native_info_by_idx API calls, along with their associated H5O_native_info_t struct, which are used to retrieve the native HDF5 file format-specific information about an object. This information (such as object header info and B-tree/heap info) has been removed from the new H5O_info2_t struct so that the more generic H5Oget_info(_by_name/_by_idx)3 routines will not try to retrieve it for non-native VOL connectors. * Added new H5Otoken_cmp, H5Otoken_to_str and H5Otoken_from_str routines to compare two object tokens, convert an object token into a nicely-readable string format and to convert an object token string back into a real object token, respectively. (DER, QAK, JTH - 2020/01/16) - Add new public function H5Sselect_adjust. This function shifts a dataspace selection by a specified logical offset within the dataspace extent. This can be useful for VOL developers to implement chunked datasets. (NAF - 2019/11/18) - Add new public function H5Sselect_project_intersection. This function computes the intersection between two dataspace selections and projects that intersection into a third selection. This can be useful for VOL developers to implement chunked or virtual datasets. (NAF - 2019/11/13, ID-148) - Add new public function H5VLget_file_type. This function returns a datatype equivalent to the supplied datatype but with the location set to be in the file. This datatype can then be used with H5Tconvert to convert data between file and in-memory representation. This funcition is intended for use only by VOL connector developers. (NAF - 2019/11/08, ID-127) Parallel Library: ----------------- - Fortran Library: ---------------- - Add wrappers for H5Pset/get_file_locking() API calls h5pget_file_locking_f() h5pset_file_locking_f() See the configure option discussion for HDFFV-11092 (above) for more information on the file locking feature and how it's controlled. (DER - 2020/07/30, HDFFV-11092) C++ Library: ------------ - Add wrappers for H5Pset/get_file_locking() API calls FileAccPropList::setFileLocking() FileAccPropList::getFileLocking() See the configure option discussion for HDFFV-11092 (above) for more information on the file locking feature and how it's controlled. (DER - 2020/07/30, HDFFV-11092) Java Library: ---------------- - Replaced HDF5AtomException with HDF5IdException Since H5E_ATOM changed to H5E_ID in the C library, the Java exception that wraps the error category was also renamed. Its functionality remains unchanged aside from the name. (See also the HDFFV-11190 note in the C library section) (DER - 2020/11/24, HDFFV-11190) - Added new H5S functions. H5Sselect_copy, H5Sselect_shape_same, H5Sselect_adjust, H5Sselect_intersect_block, H5Sselect_project_intersection, H5Scombine_hyperslab, H5Smodify_select, H5Scombine_select wrapper functions added. (ADB - 2020/10/27, HDFFV-10868) - Add wrappers for H5Pset/get_file_locking() API calls H5Pset_file_locking() H5Pget_use_file_locking() H5Pget_ignore_disabled_file_locking() Unlike the C++ and Fortran wrappers, there are separate getters for the two file locking settings, each of which returns a boolean value. See the configure option discussion for HDFFV-11092 (above) for more information on the file locking feature and how it's controlled. (DER - 2020/07/30, HDFFV-11092) - Added ability to test java library with VOLs. Created new CMake script that combines the java and vol test scripts. (ADB - 2020/02/03, HDFFV-10996) - Tests fail for non-English locale. In the JUnit tests with a non-English locale, only the part before the decimal comma is replaced by XXXX and this leads to a comparison error. Changed the regex for the Time substitution. (ADB - 2020/01/09, HDFFV-10995) Tools: ------ - Added h5delete tool Deleting HDF5 storage when using the VOL can be tricky when the VOL does not create files. The h5delete tool is a simple wrapper around the H5Fdelete() API call that uses the VOL specified in the HDF5_VOL_CONNECTOR environment variable to delete a "file". If the call to H5Fdelete() fails, the tool will attempt to use the POSIX remove(3) call to remove the file. Note that the HDF5 library does currently have support for H5Fdelete() in the native VOL connector. (DER - 2020/12/16) - h5repack added options to control how external links are handled. Currently h5repack preserves external links and cannot copy and merge data from the external files. Two options, merge and prune, were added to control how to merge data from an external link into the resulting file. --merge Follow external soft link recursively and merge data. --prune Do not follow external soft links and remove link. --merge --prune Follow external link, merge data and remove dangling link. (ADB - 2020/08/05, HDFFV-9984) - h5repack was fixed to repack the reference attributes properly. The code line that checks if the update of reference inside a compound datatype is misplaced outside the code block loop that carries out the check. In consequence, the next attribute that is not the reference type was repacked again as the reference type and caused the failure of repacking. The fix is to move the corresponding code line to the correct code block. (KY -2020/02/07, HDFFV-11014) - h5diff was updated to use the new reference APIs. h5diff uses the new reference APIs to compare references. Attribute references can also be compared. (ADB - 2019/12/19, HDFFV-10980) - h5dump and h5ls were updated to use the new reference APIs. The tools library now use the new reference APIs to inspect a file. Also the DDL spec was updated to reflect the format changes produced with the new APIs. The export API and support functions in the JNI were updated to match. (ADB - 2019/12/06, HDFFV-10876 and HDFFV-10877) High-Level APIs: --------------- - C Packet Table API ------------------ - Internal header file -------------------- - Documentation ------------- - Support for new platforms, languages and compilers. ======================================= - Bug Fixes since HDF5-1.12.0 release ================================== Library ------- - Creation of dataset with optional filter When the combination of type, space, etc doesn't work for filter and the filter is optional, it was supposed to be skipped but it was not skipped and the creation failed. Allowed the creation of the dataset in such situation. (BMR - 2020/08/13, HDFFV-10933) - Explicitly declared dlopen to use RTLD_LOCAL dlopen documentation states that if neither RTLD_GLOBAL nor RTLD_LOCAL are specified, then the default behavior is unspecified. The default on linux is usually RTLD_LOCAL while macos will default to RTLD_GLOBAL. (ADB - 2020/08/12, HDFFV-11127) - H5Sset_extent_none() sets the dataspace class to H5S_NO_CLASS which causes asserts/errors when passed to other dataspace API calls. H5S_NO_CLASS is an internal class value that should not have been exposed via a public API call. In debug builds of the library, this can cause asserts to trip. In non-debug builds, it will produce normal library errors. The new library behavior is for H5Sset_extent_none() to convert the dataspace into one of type H5S_NULL, which is better handled by the library and easier for developers to reason about. (DER - 2020/07/27, HDFFV-11027) - Fixed issues CVE-2018-13870 and CVE-2018-13869 When a buffer overflow occurred because a name length was corrupted and became very large, h5dump crashed on memory access violation. A check for reading pass the end of the buffer was added to multiple locations to prevent the crashes and h5dump now simply fails with an error message when this error condition occurs. (BMR - 2020/07/22, HDFFV-11120 and HDFFV-11121) - Fixed the segmentation fault when reading attributes with multiple threads It was reported that the reading of attributes with variable length string datatype will crash with segmentation fault particularly when the number of threads is high (>16 threads). The problem was due to the file pointer that was set in the variable length string datatype for the attribute. That file pointer was already closed when the attribute was accessed. The problem was fixed by setting the file pointer to the current opened file pointer when the attribute was accessed. Similar patch up was done before when reading dataset with variable length string datatype. (VC - 2020/07/13, HDFFV-11080) - Fixed CVE-2020-10810 The tool h5clear produced a segfault during an error recovery in the superblock decoding. An internal pointer was reset to prevent further accessing when it is not assigned with a value. (BMR - 2020/06/29, HDFFV-11053) - Fixed CVE-2018-17435 The tool h52gif produced a segfault when the size of an attribute message was corrupted and caused a buffer overflow. The problem was fixed by verifying the attribute message's size against the buffer size before accessing the buffer. h52gif was also fixed to display the failure instead of silently exiting after the segfault was eliminated. (BMR - 2020/06/19, HDFFV-10591) Java Library: ---------------- - The H5FArray.java class, in which virtually the entire execution time is spent using the HDFNativeData method that converts from an array of bytes to an array of the destination Java type. 1. Convert the entire byte array into a 1-d array of the desired type, rather than performing 1 conversion per row; 2. Use the Java Arrays method copyOfRange to grab the section of the array from (1) that is desired to be inserted into the destination array. (PGT,ADB - 2020/12/13, HDFFV-10865) - Added ability to test java library with VOLs. Created new CMake script that combines the java and vol test scripts. (ADB - 2020/02/03, HDFFV-10996) - Tests fail for non-English locale. In the JUnit tests with a non-English locale, only the part before the decimal comma is replaced by XXXX and this leads to a comparison error. Changed the regex for the Time substitution. (ADB - 2020/01/09, HDFFV-10995) Configuration ------------- - Performance ------------- - Fortran -------- - Corrected INTERFACE INTENT(IN) to INTENT(OUT) for buf_size in h5fget_file_image_f. (MSB - 2020/02/18, HDFFV-11029) Tools ----- - The tools library was updated by standardizing the error stack process. General sequence is: h5tools_setprogname(PROGRAMNAME); h5tools_setstatus(EXIT_SUCCESS); h5tools_init(); ... process the command-line (check for error-stack enable) ... h5tools_error_report(); ... (do work) ... h5diff_exit(ret); (ADB - 2020/07/20, HDFFV-11066) - h5diff fixed a command line parsing error. h5diff would ignore the argument to -d (delta) if it is smaller than DBL_EPSILON. The macro H5_DBL_ABS_EQUAL was removed and a direct value comparision was used. (ADB - 2020/07/20, HDFFV-10897) - h5diff added a command line option to ignore attributes. h5diff would ignore all objects with a supplied path if the exclude-path argument is used. Adding the exclude-attribute argument will only eclude attributes, with the supplied path, from comparision. (ADB - 2020/07/20, HDFFV-5935) - h5diff added another level to the verbose argument to print filenames. Added verbose level 3 that is level 2 plus the filenames. The levels are: 0 : Identical to '-v' or '--verbose' 1 : All level 0 information plus one-line attribute status summary 2 : All level 1 information plus extended attribute status report 3 : All level 2 information plus file names (ADB - 2020/07/20, HDFFV-10005) - h5repack was fixed to repack the reference attributes properly. The code line that checks if the update of reference inside a compound datatype is misplaced outside the code block loop that carries out the check. In consequence, the next attribute that is not the reference type was repacked again as the reference type and caused the failure of repacking. The fix is to move the corresponding code line to the correct code block. (KY -2020/02/10, HDFFV-11014) - h5diff was updated to use the new reference APIs. h5diff uses the new reference APIs to compare references. Attribute references can also be compared. (ADB - 2019/12/19, HDFFV-10980) - h5dump and h5ls were updated to use the new reference APIs. The tools library now use the new reference APIs to inspect a file. Also the DDL spec was updated to reflect the format changes produced with the new APIs. The export API and support functions in the JNI were updated to match. (ADB - 2019/12/06, HDFFV-10876 and HDFFV-10877) High-Level APIs: ------ - Fortran High-Level APIs: ------ - Documentation ------------- - F90 APIs -------- - C++ APIs -------- - Testing ------- - Stopped java/test/junit.sh.in installing libs for testing under ${prefix} Lib files needed are now copied to a subdirectory in the java/test directory, and on Macs the loader path for libhdf5.xxxs.so is changed in the temporary copy of libhdf5_java.dylib. (LRK, 2020/07/02, HDFFV-11063) Supported Platforms =================== Linux 2.6.32-696.16.1.el6.ppc64 gcc (GCC) 4.4.7 20120313 (Red Hat 4.4.7-18) #1 SMP ppc64 GNU/Linux g++ (GCC) 4.4.7 20120313 (Red Hat 4.4.7-18) (ostrich) GNU Fortran (GCC) 4.4.7 20120313 (Red Hat 4.4.7-18) IBM XL C/C++ V13.1 IBM XL Fortran V15.1 Linux 3.10.0-327.10.1.el7 GNU C (gcc), Fortran (gfortran), C++ (g++) #1 SMP x86_64 GNU/Linux compilers: (kituo/moohan) Version 4.8.5 20150623 (Red Hat 4.8.5-4) Version 4.9.3, Version 5.2.0, Intel(R) C (icc), C++ (icpc), Fortran (icc) compilers: Version 17.0.0.098 Build 20160721 MPICH 3.1.4 compiled with GCC 4.9.3 SunOS 5.11 32- and 64-bit Sun C 5.12 SunOS_sparc (emu) Sun Fortran 95 8.6 SunOS_sparc Sun C++ 5.12 SunOS_sparc Windows 10 x64 Visual Studio 2015 w/ Intel Fortran 18 (cmake) Visual Studio 2017 w/ Intel Fortran 19 (cmake) Visual Studio 2019 w/ Intel Fortran 19 (cmake) Visual Studio 2019 w/ MSMPI 10.1 (cmake) Mac OS X Yosemite 10.10.5 Apple clang/clang++ version 6.1 from Xcode 7.0 64-bit gfortran GNU Fortran (GCC) 4.9.2 (osx1010dev/osx1010test) Intel icc/icpc/ifort version 15.0.3 Mac OS X El Capitan 10.11.6 Apple clang/clang++ version 7.3.0 from Xcode 7.3 64-bit gfortran GNU Fortran (GCC) 5.2.0 (osx1011dev/osx1011test) Intel icc/icpc/ifort version 16.0.2 Mac OS Sierra 10.12.6 Apple LLVM version 8.1.0 (clang/clang++-802.0.42) 64-bit gfortran GNU Fortran (GCC) 7.1.0 (swallow/kite) Intel icc/icpc/ifort version 17.0.2 Tested Configuration Features Summary ===================================== In the tables below y = tested n = not tested in this release C = Cluster W = Workstation x = not working in this release dna = does not apply ( ) = footnote appears below second table = testing incomplete on this feature or platform Platform C F90/ F90 C++ zlib SZIP parallel F2003 parallel Solaris2.11 32-bit n y/y n y y y Solaris2.11 64-bit n y/n n y y y Windows 10 y y/y n y y y Windows 10 x64 y y/y n y y y Mac OS X Mountain Lion 10.8.5 64-bit n y/y n y y y Mac OS X Mavericks 10.9.5 64-bit n y/y n y y ? Mac OS X Yosemite 10.10.5 64-bit n y/y n y y ? Mac OS X El Capitan 10.11.6 64-bit n y/y n y y ? CentOS 6.7 Linux 2.6.18 x86_64 GNU n y/y n y y y CentOS 6.7 Linux 2.6.18 x86_64 Intel n y/y n y y y CentOS 6.7 Linux 2.6.32 x86_64 PGI n y/y n y y y CentOS 7.2 Linux 2.6.32 x86_64 GNU y y/y y y y y CentOS 7.2 Linux 2.6.32 x86_64 Intel n y/y n y y y Linux 2.6.32-573.18.1.el6.ppc64 n y/n n y y y Platform Shared Shared Shared Thread- C libs F90 libs C++ libs safe Solaris2.11 32-bit y y y y Solaris2.11 64-bit y y y y Windows 10 y y y y Windows 10 x64 y y y y Mac OS X Mountain Lion 10.8.5 64-bit y n y y Mac OS X Mavericks 10.9.5 64-bit y n y y Mac OS X Yosemite 10.10.5 64-bit y n y y Mac OS X El Capitan 10.11.6 64-bit y n y y CentOS 6.7 Linux 2.6.18 x86_64 GNU y y y y CentOS 6.7 Linux 2.6.18 x86_64 Intel y y y n CentOS 6.7 Linux 2.6.32 x86_64 PGI y y y n CentOS 7.2 Linux 2.6.32 x86_64 GNU y y y n CentOS 7.2 Linux 2.6.32 x86_64 Intel y y y n Linux 2.6.32-573.18.1.el6.ppc64 y y y n Compiler versions for each platform are listed in the preceding "Supported Platforms" table. More Tested Platforms ===================== The following platforms are not supported but have been tested for this release. Linux 2.6.32-573.22.1.el6 GNU C (gcc), Fortran (gfortran), C++ (g++) #1 SMP x86_64 GNU/Linux compilers: (mayll/platypus) Version 4.4.7 20120313 Version 4.9.3, 5.3.0, 6.2.0 PGI C, Fortran, C++ for 64-bit target on x86-64; Version 17.10-0 Intel(R) C (icc), C++ (icpc), Fortran (icc) compilers: Version 17.0.4.196 Build 20170411 MPICH 3.1.4 compiled with GCC 4.9.3 Linux 3.10.0-327.18.2.el7 GNU C (gcc) and C++ (g++) compilers #1 SMP x86_64 GNU/Linux Version 4.8.5 20150623 (Red Hat 4.8.5-4) (jelly) with NAG Fortran Compiler Release 6.1(Tozai) GCC Version 7.1.0 OpenMPI 3.0.0-GCC-7.2.0-2.29 Intel(R) C (icc) and C++ (icpc) compilers Version 17.0.0.098 Build 20160721 with NAG Fortran Compiler Release 6.1(Tozai) Linux 3.10.0-327.10.1.el7 MPICH 3.2 compiled with GCC 5.3.0 #1 SMP x86_64 GNU/Linux (moohan) Linux 2.6.32-573.18.1.el6.ppc64 MPICH mpich 3.1.4 compiled with #1 SMP ppc64 GNU/Linux IBM XL C/C++ for Linux, V13.1 (ostrich) and IBM XL Fortran for Linux, V15.1 Fedora32 5.8.18-200.fc32.x86_64 #1 SMP x86_64 GNU/Linux GNU gcc (GCC) 10.2.1 20201016 (Red Hat 10.2.1-6) GNU Fortran (GCC) 10.2.1 20201016 (Red Hat 10.2.1-6) clang version 10.0.1 (Fedora 10.0.1-3.fc32) (cmake and autotools) Ubuntu20.10 -5.8.0-29-generic-x86_64 #31-Ubuntu SMP x86_64 GNU/Linux GNU gcc (GCC) 10.2.0-13ubuntu1 GNU Fortran (GCC) 10.2.0-13ubuntu1 (cmake and autotools) Known Problems ============== CMake files do not behave correctly with paths containing spaces. Do not use spaces in paths because the required escaping for handling spaces results in very complex and fragile build files. ADB - 2019/05/07 At present, metadata cache images may not be generated by parallel applications. Parallel applications can read files with metadata cache images, but since this is a collective operation, a deadlock is possible if one or more processes do not participate. CPP ptable test fails on both VS2017 and VS2019 with Intel compiler, JIRA issue: HDFFV-10628. This test will pass with VS2015 with Intel compiler. Known problems in previous releases can be found in the HISTORY*.txt files in the HDF5 source. Please report any new problems found to help@hdfgroup.org. CMake vs. Autotools installations ================================= While both build systems produce similar results, there are differences. Each system produces the same set of folders on linux (only CMake works on standard Windows); bin, include, lib and share. Autotools places the COPYING and RELEASE.txt file in the root folder, CMake places them in the share folder. The bin folder contains the tools and the build scripts. Additionally, CMake creates dynamic versions of the tools with the suffix "-shared". Autotools installs one set of tools depending on the "--enable-shared" configuration option. build scripts ------------- Autotools: h5c++, h5cc, h5fc CMake: h5c++, h5cc, h5hlc++, h5hlcc The include folder holds the header files and the fortran mod files. CMake places the fortran mod files into separate shared and static subfolders, while Autotools places one set of mod files into the include folder. Because CMake produces a tools library, the header files for tools will appear in the include folder. The lib folder contains the library files, and CMake adds the pkgconfig subfolder with the hdf5*.pc files used by the bin/build scripts created by the CMake build. CMake separates the C interface code from the fortran code by creating C-stub libraries for each Fortran library. In addition, only CMake installs the tools library. The names of the szip libraries are different between the build systems. The share folder will have the most differences because CMake builds include a number of CMake specific files for support of CMake's find_package and support for the HDF5 Examples CMake project.