release_docs/RELEASE.txt

HDF5 version 2.0.0 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:

     https://support.hdfgroup.org/releases/hdf5/latest-docs.html

The official HDF5 releases can be obtained from:

     https://support.hdfgroup.org/downloads/index.html

Changes from Release to Release and New Features in the HDF5-2.x.y release series
can be found at:

     https://support.hdfgroup.org/releases/hdf5/documentation/release_specific_info.md

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 HDF5-2.0.0
- Platforms Tested
- Known Problems
- CMake vs. Autotools installations


New Features
============

    Configuration:
    -------------
    - Renamed the option: HDF5_ENABLE_Z_LIB_SUPPORT

      The option has been renamed to HDF5_ENABLE_ZLIB_SUPPORT to be consistent
      with the naming of other options.

    - Added support for MinGW + MSYS2 when building with CMake

      We previously added support for this to the Autotools and the appropriate
      configure-time checks have been added to CMake.

      CMake + MinGW + MSYS2 is now tested with the following environments:

        * mingw32
        * mingw64
        * ucrt64
        * clang64

    - Added CMake build mode flags to the libhdf5.settings file

      Flags from the CMake build mode (e.g., optimization) are not a part of
      CMAKE_<language>_FLAGS and were not exported to the libhdf5.settings file. This
      has been fixed and the C, Fortran, and C++ build mode flags are now exported to
      the file.

      This also affects the text output of H5check_version() and the libhdf5.settings
      string stored in the library (for those who use strings(1), etc. to get
      build info from the binary).

    - CMake: Split compiler specific flags into separate files

      The compiler specific flags have been split into separate files to make
      it easier to maintain and add new compiler flags. The flags for NVHPC,
      Intel, GNU and Clang compilers are now in separate files included from
      the current compiler flags files; HDFCompiler<language>Flags.cmake.

    - Added a configuration option for internal threading/concurrency support:

          CMake:      HDF5_ENABLE_THREADS (ON/OFF) (Default: ON)
          Autotools:  --enable-threads    (yes/no) (Default: yes)

      This option enables support for threading and concurrency algorithms
      within the HDF5 library.  It is required for, but separate from, the
      'threadsafe' configure option, which makes the HDF5 API safe to call from
      multiple threads.  It is possible to enable the 'threads' option and
      disable the 'threadsafe' option, but not vice versa.  The 'threads' option
      must be on to enable the subfiling VFD.

    - Added support for native zlib-ng compression.

      Changed the zlib-ng CMake logic to prefer the native zlib-ng library. Added
      #ifdef around the compression function calls. Added including the correct
      header file with the same #ifdef.

    - Renamed remaining HDF5 library CMake options except for CMake BUILD* variables

      DEFAULT_API_VERSION to HDF5_DEFAULT_API_VERSION
      DISABLE_PDB_FILES to HDF5_DISABLE_PDB_FILES
      ONLY_SHARED_LIBS to HDF5_ONLY_SHARED_LIBS
      ALLOW_UNSUPPORTED to HDF5_ALLOW_UNSUPPORTED
      TEST_SHELL_SCRIPTS to HDF5_TEST_SHELL_SCRIPTS

      All other HDF5 library CMake options are prefixed with HDF5_

    - bin/cmakehdf5 has been removed

      This was an unsupported build script that made building HDF5 via CMake
      work like building HDF5 via the Autotools. It has been unmaintained
      for a long time, has been marked deprecated, and is being removed.

    - Generated files in src are now checked into version control

      These files are infrequently updated and generating them adds a
      dependency on Perl. The listed files are now checked in and do
      not need to be recreated when checking out development branches.

        * H5Edefin.h
        * H5Einit.h
        * H5Emajdef.h
        * H5Emindef.h
        * H5Epubgen.h
        * H5Eterm.h
        * H5overflow.h
        * H5version.h

    - Dropped some old Solaris Studio work-arounds

      Solaris Studio no longer seems to be maintained and the last version
      (12.4, circa 2015) doesn't seem to fully support C11. We've removed
      some hacks that work around things like __attribute__() support.

    - Dropped support for the traditional MSVC preprocessor

      Visual Studio has recently started using a standards-compliant
      preprocessor (In VS2019+) and this is the default in C11.

      https://learn.microsoft.com/en-us/cpp/preprocessor/preprocessor-experimental-overview?view=msvc-170

      Because of this, we've dropped support for the traditional
      MSVC preprocessor.

    - The standard for building the library is now C11

      We have updated the build files to set the C standard to C11, though
      some platforms use gnu11 to get some GNU things to work.


    Library:
    --------
    - Added support for complex number datatypes

      Support for the C99 "float _Complex", "double _Complex" and "long double _Complex"
      (with MSVC, "_Fcomplex", "_Dcomplex" and "_Lcomplex") types has been added for
      platforms/compilers that support them. These types have been implemented with a
      new datatype class, H5T_COMPLEX. Note that any datatypes of class H5T_COMPLEX
      will not be readable with previous versions of HDF5. If a file is accessed with
      a library version bounds "high" setting less than H5F_LIBVER_V200, an error will
      occur if the application tries to create an object with a complex number datatype.
      If compatibility with previous versions of HDF5 is desired, applications should
      instead consider adopting one of the existing conventions at
      https://nc-complex.readthedocs.io/en/latest/#conventions-used-in-applications.

      The following new macros have been added:

        - H5_HAVE_COMPLEX_NUMBERS

        This macro is defined in H5pubconf.h and will have the value 1 if native
        support for complex numbers is available. It will not be defined otherwise.

        - H5_HAVE_C99_COMPLEX_NUMBERS

        This macro is defined in H5pubconf.h and will have the value 1 if native
        support for C99 complex numbers is available. It will not be defined otherwise.
        If this macro is not defined but H5_HAVE_COMPLEX_NUMBERS is defined, the
        complex number types supported are the MSVC types.

        - H5_SIZEOF_FLOAT_COMPLEX

        This macro is defined in H5pubconf.h and will have a value corresponding
        to the size of the native float complex datatype, as computed by sizeof().
        If C99 complex number support is available, this will be the size of the
        "float _Complex" type. Otherwise, it will be the size of the "_Fcomplex"
        type. It will have the value 0 if support for a native float complex datatype
        is not available.

        - H5_SIZEOF_DOUBLE_COMPLEX

        This macro is defined in H5pubconf.h and will have a value corresponding
        to the size of the native double complex datatype, as computed by sizeof().
        If C99 complex number support is available, this will be the size of the
        "double _Complex" type. Otherwise, it will be the size of the "_Dcomplex"
        type. It will have the value 0 if support for a native double complex datatype
        is not available.

        - H5_SIZEOF_LONG_DOUBLE_COMPLEX

        This macro is defined in H5pubconf.h and will have a value corresponding
        to the size of the native long double complex datatype, as computed by sizeof().
        If C99 complex number support is available, this will be the size of the
        "long double _Complex" type. Otherwise, it will be the size of the "_Lcomplex"
        type. It will have the value 0 if support for a native long double complex
        datatype is not available.

        - H5T_NATIVE_FLOAT_COMPLEX

        This macro maps to the ID of an HDF5 datatype representing the native C
        float complex datatype (either "float _Complex" or "_Fcomplex") for the
        platform. If support for a native float complex datatype is not available
        (H5_HAVE_COMPLEX_NUMBERS is not defined), the macro will map to
        H5I_INVALID_HID and should not be used.

        - H5T_NATIVE_DOUBLE_COMPLEX

        This macro maps to the ID of an HDF5 datatype representing the native C
        double complex datatype (either "double _Complex" or "_Dcomplex") for the
        platform. If support for a native double complex datatype is not available
        (H5_HAVE_COMPLEX_NUMBERS is not defined), the macro will map to
        H5I_INVALID_HID and should not be used.

        - H5T_NATIVE_LDOUBLE_COMPLEX

        This macro maps to the ID of an HDF5 datatype representing the native C
        long double complex datatype (either "long double _Complex" or "_Lcomplex")
        for the platform. If support for a native long double complex datatype is
        not available (H5_HAVE_COMPLEX_NUMBERS is not defined), the macro will map
        to H5I_INVALID_HID and should not be used.

        - H5T_COMPLEX_IEEE_F16LE / H5T_COMPLEX_IEEE_F16BE

        These macros map to IDs of HDF5 datatypes representing a complex number of
        two parts, each of which is an IEEE 754 16-bit floating-point datatype in
        little- or big-endian order. These datatypes are available regardless of
        whether complex number support is available or not.

        - H5T_COMPLEX_IEEE_F32LE / H5T_COMPLEX_IEEE_F32BE

        These macros map to IDs of HDF5 datatypes representing a complex number of
        two parts, each of which is an IEEE 754 32-bit floating-point datatype in
        little- or big-endian order. These datatypes are available regardless of
        whether complex number support is available or not.

        - H5T_COMPLEX_IEEE_F64LE / H5T_COMPLEX_IEEE_F64BE

        These macros map to IDs of HDF5 datatypes representing a complex number of
        two parts, each of which is an IEEE 754 64-bit floating-point datatype in
        little- or big-endian order. These datatypes are available regardless of
        whether complex number support is available or not.

      The following new API function has been added:

        hid_t H5Tcomplex_create(hid_t base_type_id);

        Creates a new complex number datatype from the base datatype specified
        by the given HDF5 ID `base_type_id`. The base datatype must be a
        floating-point datatype.

      The following new hard datatype conversion paths have been added, but
      will only be used when complex number support is available:

        H5T_NATIVE_SCHAR   <-> H5T_NATIVE_FLOAT_COMPLEX | H5T_NATIVE_UCHAR   <-> H5T_NATIVE_FLOAT_COMPLEX
        H5T_NATIVE_SHORT   <-> H5T_NATIVE_FLOAT_COMPLEX | H5T_NATIVE_USHORT  <-> H5T_NATIVE_FLOAT_COMPLEX
        H5T_NATIVE_INT     <-> H5T_NATIVE_FLOAT_COMPLEX | H5T_NATIVE_UINT    <-> H5T_NATIVE_FLOAT_COMPLEX
        H5T_NATIVE_LONG    <-> H5T_NATIVE_FLOAT_COMPLEX | H5T_NATIVE_ULONG   <-> H5T_NATIVE_FLOAT_COMPLEX
        H5T_NATIVE_LLONG   <-> H5T_NATIVE_FLOAT_COMPLEX | H5T_NATIVE_ULLONG  <-> H5T_NATIVE_FLOAT_COMPLEX
        H5T_NATIVE_FLOAT16 <-> H5T_NATIVE_FLOAT_COMPLEX | H5T_NATIVE_FLOAT   <-> H5T_NATIVE_FLOAT_COMPLEX 
        H5T_NATIVE_DOUBLE  <-> H5T_NATIVE_FLOAT_COMPLEX | H5T_NATIVE_LDOUBLE <-> H5T_NATIVE_FLOAT_COMPLEX

        H5T_NATIVE_SCHAR   <-> H5T_NATIVE_DOUBLE_COMPLEX | H5T_NATIVE_UCHAR   <-> H5T_NATIVE_DOUBLE_COMPLEX
        H5T_NATIVE_SHORT   <-> H5T_NATIVE_DOUBLE_COMPLEX | H5T_NATIVE_USHORT  <-> H5T_NATIVE_DOUBLE_COMPLEX
        H5T_NATIVE_INT     <-> H5T_NATIVE_DOUBLE_COMPLEX | H5T_NATIVE_UINT    <-> H5T_NATIVE_DOUBLE_COMPLEX
        H5T_NATIVE_LONG    <-> H5T_NATIVE_DOUBLE_COMPLEX | H5T_NATIVE_ULONG   <-> H5T_NATIVE_DOUBLE_COMPLEX
        H5T_NATIVE_LLONG   <-> H5T_NATIVE_DOUBLE_COMPLEX | H5T_NATIVE_ULLONG  <-> H5T_NATIVE_DOUBLE_COMPLEX
        H5T_NATIVE_FLOAT16 <-> H5T_NATIVE_DOUBLE_COMPLEX | H5T_NATIVE_FLOAT   <-> H5T_NATIVE_DOUBLE_COMPLEX 
        H5T_NATIVE_DOUBLE  <-> H5T_NATIVE_DOUBLE_COMPLEX | H5T_NATIVE_LDOUBLE <-> H5T_NATIVE_DOUBLE_COMPLEX

        H5T_NATIVE_SCHAR   <-> H5T_NATIVE_LDOUBLE_COMPLEX | H5T_NATIVE_UCHAR   <-> H5T_NATIVE_LDOUBLE_COMPLEX
        H5T_NATIVE_SHORT   <-> H5T_NATIVE_LDOUBLE_COMPLEX | H5T_NATIVE_USHORT  <-> H5T_NATIVE_LDOUBLE_COMPLEX
        H5T_NATIVE_INT     <-> H5T_NATIVE_LDOUBLE_COMPLEX | H5T_NATIVE_UINT    <-> H5T_NATIVE_LDOUBLE_COMPLEX
        H5T_NATIVE_LONG    <-> H5T_NATIVE_LDOUBLE_COMPLEX | H5T_NATIVE_ULONG   <-> H5T_NATIVE_LDOUBLE_COMPLEX
        H5T_NATIVE_LLONG   <-> H5T_NATIVE_LDOUBLE_COMPLEX | H5T_NATIVE_ULLONG  <-> H5T_NATIVE_LDOUBLE_COMPLEX
        H5T_NATIVE_FLOAT16 <-> H5T_NATIVE_LDOUBLE_COMPLEX | H5T_NATIVE_FLOAT   <-> H5T_NATIVE_LDOUBLE_COMPLEX 
        H5T_NATIVE_DOUBLE  <-> H5T_NATIVE_LDOUBLE_COMPLEX | H5T_NATIVE_LDOUBLE <-> H5T_NATIVE_LDOUBLE_COMPLEX

        H5T_NATIVE_FLOAT_COMPLEX  <-> H5T_NATIVE_DOUBLE_COMPLEX
        H5T_NATIVE_FLOAT_COMPLEX  <-> H5T_NATIVE_LDOUBLE_COMPLEX
        H5T_NATIVE_DOUBLE_COMPLEX <-> H5T_NATIVE_LDOUBLE_COMPLEX

      Alternative software implementation conversion paths have been added for all of
      the above for use when native complex number support is not available. All of these
      conversion paths follow the behavior outlined in the C standard for conversions of
      complex number values.

      Additionally, a special datatype conversion path has been added between complex number
      datatypes and array or compound datatypes where the in-memory layout of data is the
      same between the datatypes and data can be directly converted. This conversion path
      is subject to the following rules:

        - An array datatype must consist of exactly two elements where each element is of
          the same floating-point datatype as the complex number datatype's base floating-point
          datatype.

        - A compound datatype must consist of exactly two fields where each field is of the
          same floating-point datatype as the complex number datatype's base floating-point
          datatype. The compound datatype must not have any leading or trailing structure
          padding or any padding between its two fields. The fields must also have compatible
          names, must have compatible offsets within the datatype and must be in the order
          of "real" part -> "imaginary" part, such that the compound datatype matches the
          following representation:

          H5T_COMPOUND {
              <float_type> "r(e)(a)(l)";                OFFSET 0
              <float_type> "i(m)(a)(g)(i)(n)(a)(r)(y)"; OFFSET SIZEOF("r(e)(a)(l)")
          }

          where "r(e)(a)(l)" means the field may be named any substring of "real", such as
          "r", or "re" and "i(m)(a)(g)(i)(n)(a)(r)(y)" means the field may be named any
          substring of "imaginary", such as "im" or "imag".

      Support for complex numbers has been added to the h5dump, h5ls and h5diff/ph5diff
      tools. The h5dump command-line option '-m' can be used to change the floating-point
      printing format for the float complex and double complex datatypes, as well as
      the long double complex datatype if it has the same size as a double complex
      datatype.

      Support for the predefined complex number datatypes and the H5Tcomplex_create
      function has been added to the Java wrappers. However, Java does not have
      official types for complex numbers, so an application must be sure that
      data is in an appropriate format in-memory when using these datatypes.

      Support for the Fortran wrappers has not yet been added.

      Support for the predefined complex number datatypes and the H5Tcomplex_create
      function has been added to the high level library, allowing them to work
      with the H5LTtext_to_dtype and H5LTdtype_to_text functions.

      Simple example programs showing how to use complex number datatypes have
      been added in the following files:

        - HDF5Examples/C/H5T/200/h5ex_t_complex.c        (Uses C99 complex number types)
        - HDF5Examples/C/H5T/200/h5ex_t_complex_msvc.c   (Uses MSVC complex number types)
        - HDF5Examples/C/H5T/200/h5ex_t_complex_custom.c (Uses H5Tcomplex_create to create
                                                          a custom complex number type)

    - FOR VOL DEVELOPERS: Renamed H5VLstart_lib_state and H5VLfinish_lib_state

      The APIs H5VLstart_lib_state and H5VLfinish_lib_state have been renamed to
      H5VLopen_lib_context and H5VLclose_lib_context, respectively, with the addition
      of a "context" argument.

    - Removed H5FDperform_init API routine.  Virtual File Driver (VFD)
      developers who wish to provide an ID for their driver should create
      a routine specific to their individual implementation.

    - H5Pset_external() now uses HDoff_t, which is always a 64-bit type

      The H5Pset_external() call took an off_t parameter in HDF5 1.14.x and
      earlier. On POSIX systems, off_t is specified as a 64-bit type via
      POSIX large-file support (LFS). On Windows, however, off_t is defined
      as a 32-bit type, even on 64-bit Windows.

      HDoff_t has been added to H5public.h and is defined to be int64_t on
      Windows and the library has been updated to use HDoff_t in place of
      off_t throughout. The H5Pset_external() offset parameter has also been
      updated to be HDoff_t.

      There is no API compatibility wrapper for this change.

      Fixes GitHub issue #3506


    Parallel Library:
    -----------------
    -


    Fortran Library:
    ----------------
    -


    C++ Library:
    ------------
    -


    Java Library:
    -------------
    -


    Tools:
    ------
    - Added h5dump command option to set the floating point format for long double

      The new option is --lformat, which allows the user to set the
      floating point format for long double. The default format is %Lg.
      There is already an option --format to set the floating point format
      for double and float. The default format is %g.

    - Remove the high-level GIF tools

      The high-level GIF tools, h52gif and gif2h5, have unfixed CVE issues
      (with no proof-of-concept files). They are not critical tools, are not
      well maintained, and are an odd fit for building with the library.
      Because of this, they have been removed. We may move them to a separate
      repository in the future.

      This also removes the following configure options:

        Autotools:  --(dis|en)able-hlgiftools

        CMake:      HDF5_BUILD_HL_GIF_TOOLS

    High-Level APIs:
    ----------------
    -


    C Packet Table API:
    -------------------
    -


    Internal header file:
    ---------------------
    -


    Documentation:
    --------------
    - The COPYING file has been renamed to LICENSE

      This is where most people will expect to find license information. The
      COPYING_LBNL_HDF5 file has also been renamed to LICENSE_LBNL_HDF5.
      The licenses are unchanged.


Support for new platforms, languages and compilers
==================================================
    -

Bug Fixes since HDF5-2.0.0 release
===================================
    Library
    -------
    - Fixed a bug in the H5Oexists and H5Oexists_by_name API routines that
      would cause those routines to return FAIL instead of FALSE when checking
      the existence of a non-existent object with a file ID instead of a
      group ID.
      
    - Fixed a segfault in h5dump when a B-tree node level is corrupted

      h5dump produced a segfault on a mal-formed file because a B-tree node
      level was corrupted.

      An internal function was modified to help detecting when a decoded B-tree
      node level has an unexpected value and an error will be produced.

      Fixes GitHub issue #4432

    - Fixed H5Ovisit2 to recursively visit all objects

      H5Ovisit2 visited only the root group and not all the nested groups.

      This behavior occurred when the fields are not H5O_INFO_BASIC or
      H5O_INFO_ALL because an internal function did not obtain the basic
      information needed by its caller.  This problem is now fixed.

      Fixes GitHub issue #4941

    - Only clear FE_INVALID when that symbol is present on the system

      When we initialize the floating-point types at library startup, it's
      possible to raise floating-point exceptions when we check which things
      are supported. Normally, we clear these floating-point exceptions via
      feclearexcept(FE_INVALID), but FE_INVALID may not be present on all
      systems. Specifically, this was reported as being a problem when using
      Emscripten 3.1.68 to compile HDF5 1.14.5 to WebAssembly.

      We've added an #ifdef FE_INVALID block around the exception clearing
      code to correct this.

      Fixes GitHub issue #4952


    Java Library
    ------------
    -


    Configuration
    -------------
    - Changed name of libhdf5hl_fortran installed by autotools to libhdf5_hl_fortran.  The 
      new name is consistent with the name of the lib when installed by CMake and with the 
      other hl libs.  

      Fixes GitHub issue #4811


    Tools
    -----
    -


    Performance
    -------------
    -


    Fortran API
    -----------
    -


    High-Level Library
    ------------------
    -


    Fortran High-Level APIs
    -----------------------
    -


    Documentation
    -------------
    -


    F90 APIs
    --------
    -


    C++ APIs
    --------
    - 


    Testing
    -------


Platforms Tested
===================

    - HDF5 is tested with the two latest macOS versions that are available
      on github runners. As new major macOS versions become available, HDF5
      will discontinue support for the older version and add the new latest
      version to its list of compatible systems, along with the previous
      version.

    Linux 6.8.0-1010-aws             GNU gcc, gfortran, g++
    #10-Ubuntu SMP 2024 x86_64       (Ubuntu 13.2.0-23ubuntu4) 13.2.0
    GNU/Linux Ubuntu 24.04           Ubuntu clang version 18.1.3 (1ubuntu1)
                                     Intel(R) oneAPI DPC++/C++ Compiler 2024.2.0
                                     ifx (IFX) 2024.2.0 20240602
                                     (cmake and autotools)

    Linux 6.5.0-1018-aws             GNU gcc, gfortran, g++
    #18-Ubuntu SMP x86_64 GNU/Linux  (Ubuntu 11.4.0-1ubuntu1~22.04) 11.4.0
    Ubuntu 22.04                     Ubuntu clang version 14.0.0-1ubuntu1
                                     Intel(R) oneAPI DPC++/C++ Compiler 2024.0.2
                                     ifx (IFX) 2024.0.2 20231213
                                     (cmake and autotools)

    Linux 5.14.21-cray_shasta_c      cray-mpich/8.1.28
    #1 SMP x86_64 GNU/Linux              cce/15.0.0
    (frontier)                           gcc/13.2
                                     (cmake)

    Linux 5.14.0-427.24.1.el9_4      GNU gcc, gfortran, g++ (Red Hat 11.4.1-3)
    #1 SMP x86_64 GNU/Linux          clang version 17.0.6
    Rocky 9                          Intel(R) oneAPI DPC++/C++ Compiler 2024.2.0
                                     ifx (IFX) 2024.2.0 
                                     (cmake and autotools)

    Linux-4.18.0-553.16.1.1toss.t4   openmpi/4.1.2
    #1 SMP x86_64 GNU/Linux              clang 14.0.6
    (corona, dane)                       GCC 12.1.1
                                         Intel(R) oneAPI DPC++/C++ Compiler 2023.2.1
                                         ifx (IFX) 2023.2.1

    Linux-4.18.0-553.5.1.1toss.t4    openmpi/4.1/4.1.6
    #1 SMP x86_64 GNU/Linux              clang 16.0.6
    (eclipse)                            GCC 12.3.0
                                         Intel(R) oneAPI DPC++/C++ Compiler 2024.0.2
                                         ifx (IFX) 2024.0.2
                                     (cmake)

    Linux 4.14.0-115.35.1.3chaos     spectrum-mpi/rolling-release
    #1 SMP ppc64le GNU/Linux             clang 17.0.6
    (vortex)                             GCC 12.2.1
                                         nvhpc 24.1
                                         XL 2023.06.28
                                     (cmake)

    Linux-4.14.0-115.35.1            spectrum-mpi/rolling-release
    #1 SMP ppc64le GNU/Linux             clang 14.0.5, 15.0.6
    (lassen)                             GCC 8.3.1
                                         XL 2021.09.22, 2022.08.05
                                     (cmake)

    Linux 3.10.0-1160.36.2.el7.ppc64 gcc (GCC) 4.8.5 20150623 (Red Hat 4.8.5-39)
    #1 SMP ppc64be GNU/Linux         g++ (GCC) 4.8.5 20150623 (Red Hat 4.8.5-39)
    Power8 (echidna)                 GNU Fortran (GCC) 4.8.5 20150623 (Red Hat 4.8.5-39)

    Linux 3.10.0-1160.80.1.el7       GNU C (gcc), Fortran (gfortran), C++ (g++)
    #1 SMP x86_64 GNU/Linux          compilers:
    Centos7                              Version 4.8.5 20150623 (Red Hat 4.8.5-4)
    (jelly/kituo/moohan)                 Version 4.9.3, Version 7.2.0, Version 8.3.0,
                                         Version 9.1.0, Version 10.2.0
                                     Intel(R) C (icc), C++ (icpc), Fortran (icc)
                                     compilers:
                                         Version 17.0.0.098 Build 20160721
                                     GNU C (gcc) and C++ (g++) 4.8.5 compilers
                                         with NAG Fortran Compiler Release 7.1(Hanzomon)
                                     Intel(R) C (icc) and C++ (icpc) 17.0.0.098 compilers
                                         with NAG Fortran Compiler Release 7.1(Hanzomon)
                                     MPICH 3.1.4 compiled with GCC 4.9.3
                                     MPICH 3.3 compiled with GCC 7.2.0
                                     OpenMPI 3.1.3 compiled with GCC 7.2.0 and 4.1.2
                                         compiled with GCC 9.1.0
                                     PGI C, Fortran, C++ for 64-bit target on
                                     x86_64;
                                         Versions 18.4.0 and 19.10-0
                                     NVIDIA nvc, nvfortran and nvc++ version 22.5-0
                                     (autotools and cmake)


    Linux-3.10.0-1160.119.1.1chaos   openmpi/4.1.4
    #1 SMP x86_64 GNU/Linux              clang 16.0.6
    (skybridge)                          Intel(R) oneAPI DPC++/C++ Compiler 2023.2.0
                                         ifx (IFX) 2023.2.0
                                     (cmake)

    Linux-3.10.0-1160.90.1.1chaos    openmpi/4.1
    #1 SMP x86_64 GNU/Linux              clang 16.0.6
    (attaway)                            GCC 12.1.0
                                         Intel(R) oneAPI DPC++/C++ Compiler 2024.0.2
                                         ifx (IFX) 2024.0.2
                                     (cmake)

    Linux 2.6.32-573.22.1.el6        GNU C (gcc), Fortran (gfortran), C++ (g++)
    #1 SMP x86_64 GNU/Linux          compilers:
    Centos6                              Version 4.4.7 20120313
    (platypus)                           Version 4.9.3, 5.3.0, 6.2.0
                                     MPICH 3.1.4 compiled with GCC 4.9.3
                                     PGI C, Fortran, C++ for 64-bit target on
                                     x86_64;
                                         Version 19.10-0

    Windows 10 x64                  Visual Studio 2019 w/ clang 12.0.0
                                        with MSVC-like command-line (C/C++ only - cmake)
                                    Visual Studio 2019 w/ Intel (C/C++ only - cmake)
                                    Visual Studio 2022 w/ clang 17.0.3
                                        with MSVC-like command-line (C/C++ only - cmake)
                                    Visual Studio 2022 w/ Intel C/C++ oneAPI 2023 (cmake)
                                    Visual Studio 2019 w/ MSMPI 10.1 (C only - cmake)


Known Problems
==============

 -  When building with the NAG Fortran compiler using the Autotools and libtool
    2.4.2 or earlier, the -shared flag will be missing '-Wl,', which will cause
    compilation to fail. This is due to a bug in libtool that was fixed in 2012
    and released in 2.4.4 in 2014.

 -  When the library detects and builds in support for the _Float16 datatype, an
    issue has been observed on at least one MacOS 14 system where the library
    fails to initialize due to not being able to detect the byte order of the
    _Float16 type (https://github.com/HDFGroup/hdf5/issues/4310):

        #5: H5Tinit_float.c line 308 in H5T__fix_order(): failed to detect byte order
        major: Datatype
        minor: Unable to initialize object

    If this issue is encountered, support for the _Float16 type can be disabled
    with a configuration option:

        CMake:      HDF5_ENABLE_NONSTANDARD_FEATURE_FLOAT16=OFF
        Autotools:  --disable-nonstandard-feature-float16

 -  When HDF5 is compiled with NVHPC versions 23.5 - 23.9 (additional versions may
    also be applicable) and with -O2 (or higher) and -DNDEBUG, test failures occur
    in the following tests:

        H5PLUGIN-filter_plugin
        H5TEST-flush2
        H5TEST-testhdf5-base
        MPI_TEST_t_filters_parallel

    Sporadic failures (even with lower -O levels):
        Java JUnit-TestH5Pfapl
        Java JUnit-TestH5D

    Also, NVHPC will fail to compile the test/tselect.c test file with a compiler
    error of 'use of undefined value' when the optimization level is -O2 or higher.

    This is confirmed to be a bug in the nvc compiler that has been fixed as of
    23.11. If you are using an affected version of the NVidia compiler, the
    work-around is to set the optimization level to -O1.

    https://forums.developer.nvidia.com/t/hdf5-no-longer-compiles-with-nv-23-9/269045

 -  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.

 -  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.

 -  The subsetting option in ph5diff currently will fail and should be avoided.
    The subsetting option works correctly in serial h5diff.

 -  Flang Fortran compilation will fail (last check version 17) due to not yet
    implemented: (1) derived type argument passed by value (H5VLff.F90),
    and (2) support for REAL with KIND = 2 in intrinsic SPACING used in testing.

 -  Fortran tests HDF5_1_8.F90 and HDF5_F03.F90 will fail with Cray compilers
    greater than version 16.0 due to a compiler bug. The latest version verified
    as failing was version 17.0.

 -  Several tests currently fail on certain platforms:
        MPI_TEST-t_bigio fails with spectrum-mpi on ppc64le platforms.

        MPI_TEST-t_subfiling_vfd and MPI_TEST_EXAMPLES-ph5_subfiling fail with
        cray-mpich on theta and with XL compilers on ppc64le platforms.

        MPI_TEST_testphdf5_tldsc fails with cray-mpich 7.7 on cori and theta.

 -  File space may not be released when overwriting or deleting certain nested
    variable length or reference types.

 -  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
LICENSE 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.

The issues with the gif tool are:
    HDFFV-10592 CVE-2018-17433
    HDFFV-10593 CVE-2018-17436
    HDFFV-11048 CVE-2020-10809
These CVE issues have not yet been addressed and are avoided by not building
the gif tool by default. Enable building the High-Level tools with these options:
    autotools:   --enable-hlgiftools
    cmake:       HDF5_BUILD_HL_GIF_TOOLS=ON