HDF5 version 1.13.2 released on 2022-08-15
================================================================================


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 HDF5-1.13.1
- Platforms Tested
- Known Problems
- CMake vs. Autotools installations


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

    Configuration:
    -------------
    - Correct the usage of CMAKE_Fortran_MODULE_DIRECTORY and where to
      install Fortran mod files.

      The Fortran modules files, ending in .mod are files describing a
      Fortran 90 (and above) module API and ABI. These are not like C
      header files describing an API, they are compiler dependent and
      arch dependent, and not easily readable by a human being. They are
      nevertheless searched for in the includes directories by gfortran
      (in directories specified with -I).

      Autotools configure uses the -fmoddir option to specify the folder.
      CMake will use "mod" folder by default unless overridden by the CMake
      variable; HDF5_INSTALL_MODULE_DIR.

      (ADB - 2022/07/21)

    - HDF5 memory allocation sanity checking is now off by default for
      Autotools debug builds

      HDF5 can be configured to perform sanity checking on internal memory
      allocations by adding heap canaries to these allocations. However,
      enabling this option can cause issues with external filter plugins
      when working with (reallocating/freeing/allocating and passing back)
      buffers.

      Previously, this option was off by default for all CMake build types,
      but only off by default for non-debug Autotools builds. Since debug
      is the default build mode for HDF5 when built from source with
      Autotools, this can result in surprising segfaults that don't occur
      when an application is built against a release version of HDF5.
      Therefore, this option is now off by default for all build types
      across both CMake and Autotools.

      (JTH - 2022/03/01)


    Library:
    --------
    - Onion VFD

      The onion VFD allows creating "versioned" HDF5 files. File open/close
      operations after initial file creation will add changes to an external
      "onion" file (.onion extension by default) instead of the original file.
      Each written revision can be opened independently.

      To open a file with the onion VFD, use the H5Pset_fapl_onion() API call
      (does not need to be used for the initial creation of the file). The
      options for the H5FD_onion_fapl_info_t struct are described in H5FDonion.h.

      The H5FDonion_get_revision_count() API call can be used to query a file
      to find out how many revisions have been created.

      (DER - 2022/08/02)

    - Subfiling VFD

      The HDF5 Subfiling VFD is a new MPI-based file driver that allows an
      HDF5 application to distribute an HDF5 file across a collection of
      "sub-files" in equal-sized data segment "stripes". I/O to the logical
      HDF5 file is then directed to the appropriate "sub-file" according to
      the Subfiling configuration and a system of I/O concentrators, which
      are MPI ranks operating worker threads.

      By allowing a configurable stripe size, number of I/O concentrators and
      method for selecting MPI ranks as I/O concentrators, the Subfiling VFD
      aims to enable an HDF5 application to find a middle ground between the
      single shared file and file-per-process approaches to parallel file I/O
      for the particular machine the application is running on. In general, the
      goal is to avoid some of the complexity of the file-per-process approach
      while also minimizing the locking issues of the single shared file approach
      on a parallel file system.

      Also included with the Subfiling VFD is a new h5fuse.sh script which
      reads a Subfiling configuration file and then combines the various
      sub-files back into a single HDF5 file. By default, the h5fuse.sh script
      looks in the current directory for the Subfiling configuration file,
      but can also be pointed to the configuration file with a command-line
      option.

      The Subfiling VFD can be used by calling H5Pset_fapl_subfiling() on a
      File Access Property List and using that FAPL for file operations. Note
      that the Subfiling VFD currently has the following limitations:

      * Does not currently support HDF5 collective I/O, other than collective
        metadata writes and reads as set by H5Pset_coll_metadata_write() and
        H5Pset_all_coll_metadata_ops()

      * The Subfiling VFD should not currently be used with an HDF5 library
        that has been built with thread-safety enabled. This can cause deadlocks
        when failures occur due to interactions between the VFD's internal
        threads and HDF5's global lock. 

      (JTH - 2022/07/22)


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


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


    C++ Library:
    ------------
    - Added two new constructors to H5::H5File class

      Two new constructors were added to allow opening a file with non-default
      access property list.


    Java Library:
    -------------
    - Added version of H5Rget_name to return the name as a Java string.

      Other functions that get_name process the get_size then get the name
      within the JNI implementation. Now H5Rget_name has a H5Rget_name_string.

      (ADB - 2022/07/12)

    - Added reference support to H5A and H5D read write vlen JNI functions.

      Added the implementation to handle VL references as an Array of Lists
      of byte arrays.

      The JNI wrappers translate the Array of Lists to/from the hvl_t vlen
      structures. The wrappers use the specified datatype arguments for the
      List type translation, it is expected that the Java type is correct.

      (ADB - 2022/07/11, HDFFV-11318)

    - H5A and H5D read write vlen JNI functions were incorrect.

      Corrected the vlen function implementations for the basic primitive types.
      The VLStrings functions now correctly use the implementation that had been
      the VL functions. (VLStrings functions did not have an implementation.)
      The new VL functions implementation now expect an Array of Lists between
      Java and the JNI wrapper. 

      The JNI wrappers translate the Array of Lists to/from the hvl_t vlen
      structures. The wrappers use the specified datatype arguments for the
      List type translation, it is expected that the Java type is correct.

      (ADB - 2022/07/07, HDFFV-11310)

    - H5A and H5D read write JNI functions had flawed vlen datatype check.

      Adapted tools function for JNI utils file. This reduced multiple calls
      to a single check and variable. The variable can then be used to call 
      the H5Treclaim function. Adjusted existing test and added new test.

      (ADB - 2022/06/22)


    Tools:
    ------
    - Building h5perf/h5perf_serial in "standalone mode" has been removed

      Building h5perf separately from the library was added circa 2008
      in HDF5 1.6.8. It's unclear what purpose this serves and the current
      implementation is currently broken. The existing files require
      H5private.h and the symbols we use to determine how the copied
      platform-independence scheme should be used come from H5pubconf.h,
      which may not match the compiler being used to build standalone h5perf.

      Due to the maintenance overhead and lack of a clear use case, support
      for building h5perf and h5perf_serial separately from the HDF5 library
      has been removed.

      (DER - 2022/07/15)

    - The perf tool has been removed

      The small `perf` tool didn't really do anything special and the name
      conflicts with gnu's perf tool.

      (DER - 2022/07/15, GitHub #1787)

    - 1.10 References in containers were not displayed properly by h5dump.

      Ported 1.10 tools display function to provide ability to inspect and
      display 1.10 reference data. 

      (ADB - 2022/06/22)


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


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


    Internal header file:
    ---------------------
    - All the #defines named H5FD_CTL__* were renamed to H5FD_CTL_*, i.e. the double underscore was reduced to a single underscore.


    Documentation:
    --------------
    -


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


Bug Fixes since HDF5-1.13.1 release
===================================
    Library
    -------
    - The offset parameter in H5Dchunk_iter() is now scaled properly

      In earlier HDF5 1.13.x versions, the chunk offset was not scaled by the
      chunk dimensions. This offset parameter in the callback now matches
      that of H5Dget_chunk_info().

      (@mkitti - 2022/08/06, GitHub #1419)

    - Converted an assertion on (possibly corrupt) file contents to a normal
      error check

      Previously, the library contained an assertion check that a read superblock
      doesn't contain a superblock extension message when the superblock
      version < 2. When a corrupt HDF5 file is read, this assertion can be triggered
      in debug builds of HDF5. In production builds, this situation could cause
      either a library error or a crash, depending on the platform.

      (JTH - 2022/07/08, HDFFV-11316/HDFFV-11317)


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


    Configuration
    -------------
    -


    Tools
    -----
    -


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


    Fortran API
    -----------
    - h5open_f and h5close_f fixes
     * Fixed it so both h5open_f and h5close_f can be called multiple times.
     * Fixed an issue with open objects remaining after h5close_f was called.
     * Added additional tests.
       (MSB, 2022/04/19, HDFFV-11306)


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


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


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


    F90 APIs
    --------
    -


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


    Testing
    -------
    -


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

    Linux 5.16.14-200.fc35           GNU gcc (GCC) 11.2.1 20220127 (Red Hat 11.2.1-9)
    #1 SMP x86_64  GNU/Linux         GNU Fortran (GCC) 11.2.1 20220127 (Red Hat 11.2.1-9)
    Fedora35                         clang version 13.0.0 (Fedora 13.0.0-3.fc35)
                                     (cmake and autotools)

    Linux 5.11.0-34-generic          GNU gcc (GCC) 9.3.0-17ubuntu1
    #36-Ubuntu SMP x86_64 GNU/Linux  GNU Fortran (GCC) 9.3.0-17ubuntu1
    Ubuntu 20.04                     Ubuntu clang version 10.0.0-4
                                     (cmake and autotools)

    Linux 5.3.18-150300-cray_shasta_c cray-mpich/8.1.16
    #1 SMP x86_64 GNU/Linux              Cray clang 14.0.0
    (crusher)                            GCC 11.2.0
                                     (cmake)

    Linux 5.3.18-24-cray_shasta_c    cray-mpich/8.1.12
    #1 SMP x86_64 GNU/Linux              Cray clang 13.0.0   
    (spock)                              AMD clang 13.0.0
                                         GCC 8.2.0, 11.2.0
                                     (cmake)

    Linux 4.14.0-115.35.1.1chaos     openmpi 4.0.5
    #1 SMP aarch64 GNU/Linux             GCC 9.2.0 (ARM-build-5)
    (stria)                              GCC 7.2.0 (Spack GCC)
                                     (cmake)

    Linux 4.14.0-115.35.1.3chaos     spectrum-mpi/rolling-release
    #1 SMP ppc64le GNU/Linux             clang 12.0.1
    (vortex)                             GCC 8.3.1
                                         XL 16.1.1
                                     (cmake)

    Linux-4.14.0-115.21.2            spectrum-mpi/rolling-release
    #1 SMP ppc64le GNU/Linux             clang 8.0.1, 11.0.1
    (lassen)                             GCC 7.3.1
                                         XL 16.1.1.2
                                     (cmake)

    Linux-4.12.14-150.75-default     cray-mpich/7.7.10
    #1 SMP x86_64 GNU/Linux              GCC 7.3.0, 8.2.0
    (cori)                               Intel (R) Version 19.0.3.199
                                     (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 3.10.0-1160.24.1.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 5.3.0, Version 6.3.0,
                                         Version 7.2.0, Version 8.3.0, Version 9.1.0
                                     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 6.1(Tozai)
                                     Intel(R) C (icc) and C++ (icpc) 17.0.0.098 compilers
                                         with NAG Fortran Compiler Release 6.1(Tozai)
                                     MPICH 3.1.4 compiled with GCC 4.9.3
                                     MPICH 3.3 compiled with GCC 7.2.0
                                     OpenMPI 2.1.6 compiled with icc 18.0.1
                                     OpenMPI 3.1.3 and 4.0.0 compiled with GCC 7.2.0
                                     PGI C, Fortran, C++ for 64-bit target on
                                     x86_64;
                                         Version 19.10-0
                                     (autotools and cmake)

    Linux-3.10.0-1160.71.1.1chaos    openmpi-4.0.0
    #1 SMP x86_64 GNU/Linux              clang 6.0.0, 11.0.1
    (quartz)                             GCC 7.3.0, 8.1.0
                                         Intel 16.0.4, 18.0.2, 19.0.4
                                     (cmake)

    Linux-3.10.0-1160.71.1.1chaos    openmpi/4.1
    #1 SMP x86_64 GNU/Linux              GCC 7.2.0
    (skybridge)                          Intel/19.1
                                     (cmake)

    Linux-3.10.0-1160.66.1.1chaos    openmpi/4.1
    #1 SMP x86_64 GNU/Linux              GCC 7.2.0
    (attaway)                            Intel/19.1
                                     (cmake)

    Linux-3.10.0-1160.59.1.1chaos    openmpi/4.1
    #1 SMP x86_64 GNU/Linux              Intel/19.1
    (chama)                          (cmake)

    macOS Apple M1 11.6              Apple clang version 12.0.5 (clang-1205.0.22.11)
    Darwin 20.6.0 arm64              gfortran GNU Fortran (Homebrew GCC 11.2.0) 11.1.0
    (macmini-m1)                     Intel icc/icpc/ifort version 2021.3.0 202106092021.3.0 20210609

    macOS Big Sur 11.3.1             Apple clang version 12.0.5 (clang-1205.0.22.9)
    Darwin 20.4.0 x86_64             gfortran GNU Fortran (Homebrew GCC 10.2.0_3) 10.2.0
    (bigsur-1)                       Intel icc/icpc/ifort version 2021.2.0 20210228

    macOS High Sierra 10.13.6        Apple LLVM version 10.0.0 (clang-1000.10.44.4)
    64-bit                           gfortran GNU Fortran (GCC) 6.3.0
    (bear)                           Intel icc/icpc/ifort version 19.0.4.233 20190416

    macOS Sierra 10.12.6             Apple LLVM version 9.0.0 (clang-900.39.2)
    64-bit                           gfortran GNU Fortran (GCC) 7.4.0
    (kite)                           Intel icc/icpc/ifort version 17.0.2

    Mac OS X El Capitan 10.11.6      Apple clang version 7.3.0 from Xcode 7.3
    64-bit                           gfortran GNU Fortran (GCC) 5.2.0
    (osx1011test)                    Intel icc/icpc/ifort version 16.0.2


    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 2015 w/ Intel C/C++/Fortran 18 (cmake)
                                    Visual Studio 2017 w/ Intel C/C++/Fortran 19 (cmake)
                                    Visual Studio 2019 w/ clang 12.0.0
                                        with MSVC-like command-line (C/C++ only - cmake)
                                    Visual Studio 2019 w/ Intel C/C++/Fortran oneAPI 2021 (cmake)
                                    Visual Studio 2019 w/ MSMPI 10.1 (C only - cmake)


Known Problems
==============
    Setting a variable-length dataset fill value will leak the memory allocated
    for the p field of the hvl_t struct. A fix is in progress for this.
    HDFFV-10840

    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.

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

    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.

    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.

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 can be avoided by not building
the gif tool. Disable building the High-Level tools with these options:
    autotools:   --disable-hltools
    cmake:       HDF5_BUILD_HL_TOOLS=OFF
