freebsd-nq/sys/contrib/zstd/programs
Conrad Meyer 37f1f2684f Update to Zstandard 1.4.5
As usual, the full release notes are found on Github:

  https://github.com/facebook/zstd/releases/tag/v1.4.5

Notable changes include:

* Improved decompress performance on amd64 and arm (5-10%
  and 15-50%, respectively).
* '--patch-from' zstd(1) CLI option, which provides something like a very fast
  version of bspatch(1) with slightly worse compression.  See release notes.

In this update, I dropped the 3-year old -O0 workaround for an LLVM ARM bug;
the bug was fixed in LLVM SVN in 2017, but we didn't remove this workaround
from our tree until now.

MFC after:	I won't, but feel free
Relnotes:	yes
2020-05-23 21:23:46 +00:00
..
benchfn.c
benchfn.h
benchzstd.c
benchzstd.h
BUCK
datagen.c
datagen.h
dibio.c
dibio.h
fileio.c
fileio.h
Makefile
platform.h
README.md
timefn.c
timefn.h
util.c
util.h
zstd.1
zstd.1.md
zstdcli.c
zstdgrep
zstdgrep.1
zstdgrep.1.md
zstdless
zstdless.1
zstdless.1.md

Command Line Interface for Zstandard library

Command Line Interface (CLI) can be created using the make command without any additional parameters. There are however other Makefile targets that create different variations of CLI:

  • zstd : default CLI supporting gzip-like arguments; includes dictionary builder, benchmark, and support for decompression of legacy zstd formats
  • zstd_nolegacy : Same as zstd but without support for legacy zstd formats
  • zstd-small : CLI optimized for minimal size; no dictionary builder, no benchmark, and no support for legacy zstd formats
  • zstd-compress : version of CLI which can only compress into zstd format
  • zstd-decompress : version of CLI which can only decompress zstd format

Compilation variables

zstd scope can be altered by modifying the following make variables :

  • HAVE_THREAD : multithreading is automatically enabled when pthread is detected. It's possible to disable multithread support, by setting HAVE_THREAD=0. Example : make zstd HAVE_THREAD=0 It's also possible to force multithread support, using HAVE_THREAD=1. In which case, linking stage will fail if neither pthread nor windows.h library can be found. This is useful to ensure this feature is not silently disabled.

  • ZSTD_LEGACY_SUPPORT : zstd can decompress files compressed by older versions of zstd. Starting v0.8.0, all versions of zstd produce frames compliant with the specification, and are therefore compatible. But older versions (< v0.8.0) produced different, incompatible, frames. By default, zstd supports decoding legacy formats >= v0.4.0 (ZSTD_LEGACY_SUPPORT=4). This can be altered by modifying this compilation variable. ZSTD_LEGACY_SUPPORT=1 means "support all formats >= v0.1.0". ZSTD_LEGACY_SUPPORT=2 means "support all formats >= v0.2.0", and so on. ZSTD_LEGACY_SUPPORT=0 means DO NOT support any legacy format. if ZSTD_LEGACY_SUPPORT >= 8, it's the same as 0, since there is no legacy format after 7. Note : zstd only supports decoding older formats, and cannot generate any legacy format.

  • HAVE_ZLIB : zstd can compress and decompress files in .gz format. This is ordered through command --format=gzip. Alternatively, symlinks named gzip or gunzip will mimic intended behavior. .gz support is automatically enabled when zlib library is detected at build time. It's possible to disable .gz support, by setting HAVE_ZLIB=0. Example : make zstd HAVE_ZLIB=0 It's also possible to force compilation with zlib support, using HAVE_ZLIB=1. In which case, linking stage will fail if zlib library cannot be found. This is useful to prevent silent feature disabling.

  • HAVE_LZMA : zstd can compress and decompress files in .xz and .lzma formats. This is ordered through commands --format=xz and --format=lzma respectively. Alternatively, symlinks named xz, unxz, lzma, or unlzma will mimic intended behavior. .xz and .lzma support is automatically enabled when lzma library is detected at build time. It's possible to disable .xz and .lzma support, by setting HAVE_LZMA=0. Example : make zstd HAVE_LZMA=0 It's also possible to force compilation with lzma support, using HAVE_LZMA=1. In which case, linking stage will fail if lzma library cannot be found. This is useful to prevent silent feature disabling.

  • HAVE_LZ4 : zstd can compress and decompress files in .lz4 formats. This is ordered through commands --format=lz4. Alternatively, symlinks named lz4, or unlz4 will mimic intended behavior. .lz4 support is automatically enabled when lz4 library is detected at build time. It's possible to disable .lz4 support, by setting HAVE_LZ4=0 . Example : make zstd HAVE_LZ4=0 It's also possible to force compilation with lz4 support, using HAVE_LZ4=1. In which case, linking stage will fail if lz4 library cannot be found. This is useful to prevent silent feature disabling.

  • ZSTD_NOBENCH : zstd cli will be compiled without its integrated benchmark module. This can be useful to produce smaller binaries. In this case, the corresponding unit can also be excluded from compilation target.

  • ZSTD_NODICT : zstd cli will be compiled without support for the integrated dictionary builder. This can be useful to produce smaller binaries. In this case, the corresponding unit can also be excluded from compilation target.

  • ZSTD_NOCOMPRESS : zstd cli will be compiled without support for compression. The resulting binary will only be able to decompress files. This can be useful to produce smaller binaries. A corresponding Makefile target using this ability is zstd-decompress.

  • ZSTD_NODECOMPRESS : zstd cli will be compiled without support for decompression. The resulting binary will only be able to compress files. This can be useful to produce smaller binaries. A corresponding Makefile target using this ability is zstd-compress.

  • BACKTRACE : zstd can display a stack backtrace when execution generates a runtime exception. By default, this feature may be degraded/disabled on some platforms unless additional compiler directives are applied. When triaging a runtime issue, enabling this feature can provide more context to determine the location of the fault. Example : make zstd BACKTRACE=1

Aggregation of parameters

CLI supports aggregation of parameters i.e. -b1, -e18, and -i1 can be joined into -b1e18i1.

It's possible to invoke zstd through a symlink. When the name of the symlink has a specific value, it triggers an associated behavior.

  • zstdmt : compress using all cores available on local system.
  • zcat : will decompress and output target file using any of the supported formats. gzcat and zstdcat are also equivalent.
  • gzip : if zlib support is enabled, will mimic gzip by compressing file using .gz format, removing source file by default (use --keep to preserve). If zlib is not supported, triggers an error.
  • xz : if lzma support is enabled, will mimic xz by compressing file using .xz format, removing source file by default (use --keep to preserve). If xz is not supported, triggers an error.
  • lzma : if lzma support is enabled, will mimic lzma by compressing file using .lzma format, removing source file by default (use --keep to preserve). If lzma is not supported, triggers an error.
  • lz4 : if lz4 support is enabled, will mimic lz4 by compressing file using .lz4 format. If lz4 is not supported, triggers an error.
  • unzstd and unlz4 will decompress any of the supported format.
  • ungz, unxz and unlzma will do the same, and will also remove source file by default (use --keep to preserve).

Dictionary builder in Command Line Interface

Zstd offers a training mode, which can be used to tune the algorithm for a selected type of data, by providing it with a few samples. The result of the training is stored in a file selected with the -o option (default name is dictionary), which can be loaded before compression and decompression.

Using a dictionary, the compression ratio achievable on small data improves dramatically. These compression gains are achieved while simultaneously providing faster compression and decompression speeds. Dictionary work if there is some correlation in a family of small data (there is no universal dictionary). Hence, deploying one dictionary per type of data will provide the greater benefits. Dictionary gains are mostly effective in the first few KB. Then, the compression algorithm will rely more and more on previously decoded content to compress the rest of the file.

Usage of the dictionary builder and created dictionaries with CLI:

  1. Create the dictionary : zstd --train PathToTrainingSet/* -o dictionaryName
  2. Compress with the dictionary: zstd FILE -D dictionaryName
  3. Decompress with the dictionary: zstd --decompress FILE.zst -D dictionaryName

Benchmark in Command Line Interface

CLI includes in-memory compression benchmark module for zstd. The benchmark is conducted using given filenames. The files are read into memory and joined together. It makes benchmark more precise as it eliminates I/O overhead. Multiple filenames can be supplied, as multiple parameters, with wildcards, or names of directories can be used as parameters with -r option.

The benchmark measures ratio, compressed size, compression and decompression speed. One can select compression levels starting from -b and ending with -e. The -i parameter selects minimal time used for each of tested levels.

Usage of Command Line Interface

The full list of options can be obtained with -h or -H parameter:

Usage :
      zstd [args] [FILE(s)] [-o file]

FILE    : a filename
          with no FILE, or when FILE is - , read standard input
Arguments :
 -#     : # compression level (1-19, default: 3)
 -d     : decompression
 -D file: use `file` as Dictionary
 -o file: result stored into `file` (only if 1 input file)
 -f     : overwrite output without prompting and (de)compress links
--rm    : remove source file(s) after successful de/compression
 -k     : preserve source file(s) (default)
 -h/-H  : display help/long help and exit

Advanced arguments :
 -V     : display Version number and exit
 -v     : verbose mode; specify multiple times to increase verbosity
 -q     : suppress warnings; specify twice to suppress errors too
 -c     : force write to standard output, even if it is the console
 -l     : print information about zstd compressed files
--exclude-compressed:  only compress files that are not previously compressed
--ultra : enable levels beyond 19, up to 22 (requires more memory)
--long[=#]: enable long distance matching with given window log (default: 27)
--fast[=#]: switch to very fast compression levels (default: 1)
--adapt : dynamically adapt compression level to I/O conditions
--stream-size=# : optimize compression parameters for streaming input of given number of bytes
--size-hint=# optimize compression parameters for streaming input of approximately this size
--target-compressed-block-size=# : make compressed block near targeted size
 -T#    : spawns # compression threads (default: 1, 0==# cores)
 -B#    : select size of each job (default: 0==automatic)
--rsyncable : compress using a rsync-friendly method (-B sets block size)
--no-dictID : don't write dictID into header (dictionary compression)
--[no-]check : integrity check (default: enabled)
--[no-]compress-literals : force (un)compressed literals
 -r     : operate recursively on directories
--output-dir-flat[=directory]: all resulting files stored into `directory`.
--format=zstd : compress files to the .zst format (default)
--format=gzip : compress files to the .gz format
--test  : test compressed file integrity
--[no-]sparse : sparse mode (default: disabled)
 -M#    : Set a memory usage limit for decompression
--no-progress : do not display the progress bar
--      : All arguments after "--" are treated as files

Dictionary builder :
--train ## : create a dictionary from a training set of files
--train-cover[=k=#,d=#,steps=#,split=#,shrink[=#]] : use the cover algorithm with optional args
--train-fastcover[=k=#,d=#,f=#,steps=#,split=#,accel=#,shrink[=#]] : use the fast cover algorithm with optional args
--train-legacy[=s=#] : use the legacy algorithm with selectivity (default: 9)
 -o file : `file` is dictionary name (default: dictionary)
--maxdict=# : limit dictionary to specified size (default: 112640)
--dictID=# : force dictionary ID to specified value (default: random)

Benchmark arguments :
 -b#    : benchmark file(s), using # compression level (default: 3)
 -e#    : test all compression levels from -bX to # (default: 1)
 -i#    : minimum evaluation time in seconds (default: 3s)
 -B#    : cut file into independent blocks of size # (default: no block)
--priority=rt : set process priority to real-time

Passing parameters through Environment Variables

ZSTD_CLEVEL can be used to modify the default compression level of zstd (usually set to 3) to another value between 1 and 19 (the "normal" range). This can be useful when zstd CLI is invoked in a way that doesn't allow passing arguments. One such scenario is tar --zstd. As ZSTD_CLEVEL only replaces the default compression level, it can then be overridden by corresponding command line arguments.

There is no "generic" way to pass "any kind of parameter" to zstd in a pass-through manner. Using environment variables for this purpose has security implications. Therefore, this avenue is intentionally restricted and only supports ZSTD_CLEVEL.

Long distance matching mode

The long distance matching mode, enabled with --long, is designed to improve the compression ratio for files with long matches at a large distance (up to the maximum window size, 128 MiB) while still maintaining compression speed.

Enabling this mode sets the window size to 128 MiB and thus increases the memory usage for both the compressor and decompressor. Performance in terms of speed is dependent on long matches being found. Compression speed may degrade if few long matches are found. Decompression speed usually improves when there are many long distance matches.

Below are graphs comparing the compression speed, compression ratio, and decompression speed with and without long distance matching on an ideal use case: a tar of four versions of clang (versions 3.4.1, 3.4.2, 3.5.0, 3.5.1) with a total size of 244889600 B. This is an ideal use case as there are many long distance matches within the maximum window size of 128 MiB (each version is less than 128 MiB).

Compression Speed vs Ratio Decompression Speed
Compression Speed vs Ratio Decompression Speed
Method Compression ratio Compression speed Decompression speed
zstd -1 5.065 284.8 MB/s 759.3 MB/s
zstd -5 5.826 124.9 MB/s 674.0 MB/s
zstd -10 6.504 29.5 MB/s 771.3 MB/s
zstd -1 --long 17.426 220.6 MB/s 1638.4 MB/s
zstd -5 --long 19.661 165.5 MB/s 1530.6 MB/s
zstd -10 --long 21.949 75.6 MB/s 1632.6 MB/s

On this file, the compression ratio improves significantly with minimal impact on compression speed, and the decompression speed doubles.

On the other extreme, compressing a file with few long distance matches (such as the Silesia compression corpus) will likely lead to a deterioration in compression speed (for lower levels) with minimal change in compression ratio.

The below table illustrates this on the Silesia compression corpus.

Method Compression ratio Compression speed Decompression speed
zstd -1 2.878 231.7 MB/s 594.4 MB/s
zstd -1 --long 2.929 106.5 MB/s 517.9 MB/s
zstd -5 3.274 77.1 MB/s 464.2 MB/s
zstd -5 --long 3.319 51.7 MB/s 371.9 MB/s
zstd -10 3.523 16.4 MB/s 489.2 MB/s
zstd -10 --long 3.566 16.2 MB/s 415.7 MB/s

zstdgrep

zstdgrep is a utility which makes it possible to grep directly a .zst compressed file. It's used the same way as normal grep, for example : zstdgrep pattern file.zst

zstdgrep is not compatible with dictionary compression.

To search into a file compressed with a dictionary, it's necessary to decompress it using zstd or zstdcat, and then pipe the result to grep. For example : zstdcat -D dictionary -qc -- file.zst | grep pattern