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packaging: add make target for linux wheels Having linux wheels is going to helps system without compiler or python-dev plus speed up the installation for everyone. I followed the manylinux example repository https://github.com/pypa/python-manylinux-demo to add a make target (build-linux-wheels) using official docker image to build python 2 linux wheels for mercurial. It generates Python 2.6 and Python 2.7 for both 32 and 64 bits architectures. I had to blacklist several test cases for various reasons: * test-convert-git.t and test-subrepo-git.t because of the git version * test-patchbomb-tls.t because of warning using tls 1.0 It's likely because the docker image is based on centos 5.0 and openssl is outdated.

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python-zstandard

This project provides Python bindings for interfacing with the Zstandard compression library. A C extension and CFFI interface are provided.

The primary goal of the project is to provide a rich interface to the underlying C API through a Pythonic interface while not sacrificing performance. This means exposing most of the features and flexibility of the C API while not sacrificing usability or safety that Python provides.

The canonical home for this project is https://github.com/indygreg/python-zstandard.

ci-status Windows build status

State of Project

The project is officially in beta state. The author is reasonably satisfied that functionality works as advertised. There will be some backwards incompatible changes before 1.0, probably in the 0.9 release. This may involve renaming the main module from zstd to zstandard and renaming various types and methods. Pin the package version to prevent unwanted breakage when this change occurs!

This project is vendored and distributed with Mercurial 4.1, where it is used in a production capacity.

There is continuous integration for Python versions 2.6, 2.7, and 3.3+ on Linux x86_x64 and Windows x86 and x86_64. The author is reasonably confident the extension is stable and works as advertised on these platforms.

The CFFI bindings are mostly feature complete. Where a feature is implemented in CFFI, unit tests run against both C extension and CFFI implementation to ensure behavior parity.

Expected Changes

The author is reasonably confident in the current state of what's implemented on the ZstdCompressor and ZstdDecompressor types. Those APIs likely won't change significantly. Some low-level behavior (such as naming and types expected by arguments) may change.

There will likely be arguments added to control the input and output buffer sizes (currently, certain operations read and write in chunk sizes using zstd's preferred defaults).

There should be an API that accepts an object that conforms to the buffer interface and returns an iterator over compressed or decompressed output.

There should be an API that exposes an io.RawIOBase interface to compressor and decompressor streams, like how gzip.GzipFile from the standard library works (issue 13).

The author is on the fence as to whether to support the extremely low level compression and decompression APIs. It could be useful to support compression without the framing headers. But the author doesn't believe it a high priority at this time.

There will likely be a refactoring of the module names. Currently, zstd is a C extension and zstd_cffi is the CFFI interface. This means that all code for the C extension must be implemented in C. zstd may be converted to a Python module so code can be reused between CFFI and C and so not all code in the C extension has to be C.

Requirements

This extension is designed to run with Python 2.6, 2.7, 3.3, 3.4, 3.5, and 3.6 on common platforms (Linux, Windows, and OS X). Only x86_64 is currently well-tested as an architecture.

Installing

This package is uploaded to PyPI at https://pypi.python.org/pypi/zstandard. So, to install this package:

$ pip install zstandard

Binary wheels are made available for some platforms. If you need to install from a source distribution, all you should need is a working C compiler and the Python development headers/libraries. On many Linux distributions, you can install a python-dev or python-devel package to provide these dependencies.

Packages are also uploaded to Anaconda Cloud at https://anaconda.org/indygreg/zstandard. See that URL for how to install this package with conda.

Performance

Very crude and non-scientific benchmarking (most benchmarks fall in this category because proper benchmarking is hard) show that the Python bindings perform within 10% of the native C implementation.

The following table compares the performance of compressing and decompressing a 1.1 GB tar file comprised of the files in a Firefox source checkout. Values obtained with the zstd program are on the left. The remaining columns detail performance of various compression APIs in the Python bindings.

Level Native Comp / Decomp Simple Comp / Decomp Stream In Comp / Decomp Stream Out Comp
1 490 / 1338 MB/s 458 / 1266 MB/s 407 / 1156 MB/s 405 MB/s
2 412 / 1288 MB/s 381 / 1203 MB/s 345 / 1128 MB/s 349 MB/s
3 342 / 1312 MB/s 319 / 1182 MB/s 285 / 1165 MB/s 287 MB/s
11 64 / 1506 MB/s 66 / 1436 MB/s 56 / 1342 MB/s 57 MB/s

Again, these are very unscientific. But it shows that Python is capable of compressing at several hundred MB/s and decompressing at over 1 GB/s.

Comparison to Other Python Bindings

https://pypi.python.org/pypi/zstd is an alternate Python binding to Zstandard. At the time this was written, the latest release of that package (1.1.2) only exposed the simple APIs for compression and decompression. This package exposes much more of the zstd API, including streaming and dictionary compression. This package also has CFFI support.

Bundling of Zstandard Source Code

The source repository for this project contains a vendored copy of the Zstandard source code. This is done for a few reasons.

First, Zstandard is relatively new and not yet widely available as a system package. Providing a copy of the source code enables the Python C extension to be compiled without requiring the user to obtain the Zstandard source code separately.

Second, Zstandard has both a stable public API and an experimental API. The experimental API is actually quite useful (contains functionality for training dictionaries for example), so it is something we wish to expose to Python. However, the experimental API is only available via static linking. Furthermore, the experimental API can change at any time. So, control over the exact version of the Zstandard library linked against is important to ensure known behavior.

Instructions for Building and Testing

Once you have the source code, the extension can be built via setup.py:

$ python setup.py build_ext

We recommend testing with nose:

$ nosetests

A Tox configuration is present to test against multiple Python versions:

$ tox

Tests use the hypothesis Python package to perform fuzzing. If you don't have it, those tests won't run. Since the fuzzing tests take longer to execute than normal tests, you'll need to opt in to running them by setting the ZSTD_SLOW_TESTS environment variable. This is set automatically when using tox.

The cffi Python package needs to be installed in order to build the CFFI bindings. If it isn't present, the CFFI bindings won't be built.

To create a virtualenv with all development dependencies, do something like the following:

# Python 2
$ virtualenv venv

# Python 3
$ python3 -m venv venv

$ source venv/bin/activate
$ pip install cffi hypothesis nose tox

API

The compiled C extension provides a zstd Python module. The CFFI bindings provide a zstd_cffi module. Both provide an identical API interface. The types, functions, and attributes exposed by these modules are documented in the sections below.

Note

The documentation in this section makes references to various zstd concepts and functionality. The Concepts section below explains these concepts in more detail.

ZstdCompressor

The ZstdCompressor class provides an interface for performing compression operations.

Each instance is associated with parameters that control compression behavior. These come from the following named arguments (all optional):

level
Integer compression level. Valid values are between 1 and 22.
dict_data

Compression dictionary to use.

Note: When using dictionary data and compress() is called multiple times, the CompressionParameters derived from an integer compression level and the first compressed data's size will be reused for all subsequent operations. This may not be desirable if source data size varies significantly.

compression_params
A CompressionParameters instance (overrides the level value).
write_checksum
Whether a 4 byte checksum should be written with the compressed data. Defaults to False. If True, the decompressor can verify that decompressed data matches the original input data.
write_content_size
Whether the size of the uncompressed data will be written into the header of compressed data. Defaults to False. The data will only be written if the compressor knows the size of the input data. This is likely not true for streaming compression.
write_dict_id
Whether to write the dictionary ID into the compressed data. Defaults to True. The dictionary ID is only written if a dictionary is being used.
threads
Enables and sets the number of threads to use for multi-threaded compression operations. Defaults to 0, which means to use single-threaded compression. Negative values will resolve to the number of logical CPUs in the system. Read below for more info on multi-threaded compression. This argument only controls thread count for operations that operate on individual pieces of data. APIs that spawn multiple threads for working on multiple pieces of data have their own threads argument.

Unless specified otherwise, assume that no two methods of ZstdCompressor instances can be called from multiple Python threads simultaneously. In other words, assume instances are not thread safe unless stated otherwise.

Simple API

compress(data) compresses and returns data as a one-shot operation.:

cctx = zstd.ZstdCompressor()
compressed = cctx.compress(b'data to compress')

The data argument can be any object that implements the buffer protocol.

Unless compression_params or dict_data are passed to the ZstdCompressor, each invocation of compress() will calculate the optimal compression parameters for the configured compression level and input data size (some parameters are fine-tuned for small input sizes).

If a compression dictionary is being used, the compression parameters determined from the first input's size will be reused for subsequent operations.

There is currently a deficiency in zstd's C APIs that makes it difficult to round trip empty inputs when write_content_size=True. Attempting this will raise a ValueError unless allow_empty=True is passed to compress().

Streaming Input API

write_to(fh) (which behaves as a context manager) allows you to stream data into a compressor.:

cctx = zstd.ZstdCompressor(level=10)
with cctx.write_to(fh) as compressor:
    compressor.write(b'chunk 0')
    compressor.write(b'chunk 1')
    ...

The argument to write_to() must have a write(data) method. As compressed data is available, write() will be called with the compressed data as its argument. Many common Python types implement write(), including open file handles and io.BytesIO.

write_to() returns an object representing a streaming compressor instance. It must be used as a context manager. That object's write(data) method is used to feed data into the compressor.

A flush() method can be called to evict whatever data remains within the compressor's internal state into the output object. This may result in 0 or more write() calls to the output object.

Both write() and flush() return the number of bytes written to the object's write(). In many cases, small inputs do not accumulate enough data to cause a write and write() will return 0.

If the size of the data being fed to this streaming compressor is known, you can declare it before compression begins:

cctx = zstd.ZstdCompressor()
with cctx.write_to(fh, size=data_len) as compressor:
    compressor.write(chunk0)
    compressor.write(chunk1)
    ...

Declaring the size of the source data allows compression parameters to be tuned. And if write_content_size is used, it also results in the content size being written into the frame header of the output data.

The size of chunks being write() to the destination can be specified:

cctx = zstd.ZstdCompressor()
with cctx.write_to(fh, write_size=32768) as compressor:
    ...

To see how much memory is being used by the streaming compressor:

cctx = zstd.ZstdCompressor()
with cctx.write_to(fh) as compressor:
    ...
    byte_size = compressor.memory_size()

Streaming Output API

read_from(reader) provides a mechanism to stream data out of a compressor as an iterator of data chunks.:

cctx = zstd.ZstdCompressor()
for chunk in cctx.read_from(fh):
     # Do something with emitted data.

read_from() accepts an object that has a read(size) method or conforms to the buffer protocol. (bytes and memoryview are 2 common types that provide the buffer protocol.)

Uncompressed data is fetched from the source either by calling read(size) or by fetching a slice of data from the object directly (in the case where the buffer protocol is being used). The returned iterator consists of chunks of compressed data.

If reading from the source via read(), read() will be called until it raises or returns an empty bytes (b''). It is perfectly valid for the source to deliver fewer bytes than were what requested by read(size).

Like write_to(), read_from() also accepts a size argument declaring the size of the input stream:

cctx = zstd.ZstdCompressor()
for chunk in cctx.read_from(fh, size=some_int):
    pass

You can also control the size that data is read() from the source and the ideal size of output chunks:

cctx = zstd.ZstdCompressor()
for chunk in cctx.read_from(fh, read_size=16384, write_size=8192):
    pass

Unlike write_to(), read_from() does not give direct control over the sizes of chunks fed into the compressor. Instead, chunk sizes will be whatever the object being read from delivers. These will often be of a uniform size.

Stream Copying API

copy_stream(ifh, ofh) can be used to copy data between 2 streams while compressing it.:

cctx = zstd.ZstdCompressor()
cctx.copy_stream(ifh, ofh)

For example, say you wish to compress a file:

cctx = zstd.ZstdCompressor()
with open(input_path, 'rb') as ifh, open(output_path, 'wb') as ofh:
    cctx.copy_stream(ifh, ofh)

It is also possible to declare the size of the source stream:

cctx = zstd.ZstdCompressor()
cctx.copy_stream(ifh, ofh, size=len_of_input)

You can also specify how large the chunks that are read() and write() from and to the streams:

cctx = zstd.ZstdCompressor()
cctx.copy_stream(ifh, ofh, read_size=32768, write_size=16384)

The stream copier returns a 2-tuple of bytes read and written:

cctx = zstd.ZstdCompressor()
read_count, write_count = cctx.copy_stream(ifh, ofh)

Compressor API

compressobj() returns an object that exposes compress(data) and flush() methods. Each returns compressed data or an empty bytes.

The purpose of compressobj() is to provide an API-compatible interface with zlib.compressobj and bz2.BZ2Compressor. This allows callers to swap in different compressor objects while using the same API.

flush() accepts an optional argument indicating how to end the stream. zstd.COMPRESSOBJ_FLUSH_FINISH (the default) ends the compression stream. Once this type of flush is performed, compress() and flush() can no longer be called. This type of flush must be called to end the compression context. If not called, returned data may be incomplete.

A zstd.COMPRESSOBJ_FLUSH_BLOCK argument to flush() will flush a zstd block. Flushes of this type can be performed multiple times. The next call to compress() will begin a new zstd block.

Here is how this API should be used:

cctx = zstd.ZstdCompressor()
cobj = cctx.compressobj()
data = cobj.compress(b'raw input 0')
data = cobj.compress(b'raw input 1')
data = cobj.flush()

Or to flush blocks:

cctx.zstd.ZstdCompressor()
cobj = cctx.compressobj()
data = cobj.compress(b'chunk in first block')
data = cobj.flush(zstd.COMPRESSOBJ_FLUSH_BLOCK)
data = cobj.compress(b'chunk in second block')
data = cobj.flush()

For best performance results, keep input chunks under 256KB. This avoids extra allocations for a large output object.

It is possible to declare the input size of the data that will be fed into the compressor:

cctx = zstd.ZstdCompressor()
cobj = cctx.compressobj(size=6)
data = cobj.compress(b'foobar')
data = cobj.flush()

Batch Compression API

(Experimental. Not yet supported in CFFI bindings.)

multi_compress_to_buffer(data, [threads=0]) performs compression of multiple inputs as a single operation.

Data to be compressed can be passed as a BufferWithSegmentsCollection, a BufferWithSegments, or a list containing byte like objects. Each element of the container will be compressed individually using the configured parameters on the ZstdCompressor instance.

The threads argument controls how many threads to use for compression. The default is 0 which means to use a single thread. Negative values use the number of logical CPUs in the machine.

The function returns a BufferWithSegmentsCollection. This type represents N discrete memory allocations, eaching holding 1 or more compressed frames.

Output data is written to shared memory buffers. This means that unlike regular Python objects, a reference to any object within the collection keeps the shared buffer and therefore memory backing it alive. This can have undesirable effects on process memory usage.

The API and behavior of this function is experimental and will likely change. Known deficiencies include:

  • If asked to use multiple threads, it will always spawn that many threads, even if the input is too small to use them. It should automatically lower the thread count when the extra threads would just add overhead.
  • The buffer allocation strategy is fixed. There is room to make it dynamic, perhaps even to allow one output buffer per input, facilitating a variation of the API to return a list without the adverse effects of shared memory buffers.

ZstdDecompressor

The ZstdDecompressor class provides an interface for performing decompression.

Each instance is associated with parameters that control decompression. These come from the following named arguments (all optional):

dict_data
Compression dictionary to use.

The interface of this class is very similar to ZstdCompressor (by design).

Unless specified otherwise, assume that no two methods of ZstdDecompressor instances can be called from multiple Python threads simultaneously. In other words, assume instances are not thread safe unless stated otherwise.

Simple API

decompress(data) can be used to decompress an entire compressed zstd frame in a single operation.:

dctx = zstd.ZstdDecompressor()
decompressed = dctx.decompress(data)

By default, decompress(data) will only work on data written with the content size encoded in its header. This can be achieved by creating a ZstdCompressor with write_content_size=True. If compressed data without an embedded content size is seen, zstd.ZstdError will be raised.

If the compressed data doesn't have its content size embedded within it, decompression can be attempted by specifying the max_output_size argument.:

dctx = zstd.ZstdDecompressor()
uncompressed = dctx.decompress(data, max_output_size=1048576)

Ideally, max_output_size will be identical to the decompressed output size.

If max_output_size is too small to hold the decompressed data, zstd.ZstdError will be raised.

If max_output_size is larger than the decompressed data, the allocated output buffer will be resized to only use the space required.

Please note that an allocation of the requested max_output_size will be performed every time the method is called. Setting to a very large value could result in a lot of work for the memory allocator and may result in MemoryError being raised if the allocation fails.

If the exact size of decompressed data is unknown, it is strongly recommended to use a streaming API.

Streaming Input API

write_to(fh) can be used to incrementally send compressed data to a decompressor.:

dctx = zstd.ZstdDecompressor()
with dctx.write_to(fh) as decompressor:
    decompressor.write(compressed_data)

This behaves similarly to zstd.ZstdCompressor: compressed data is written to the decompressor by calling write(data) and decompressed output is written to the output object by calling its write(data) method.

Calls to write() will return the number of bytes written to the output object. Not all inputs will result in bytes being written, so return values of 0 are possible.

The size of chunks being write() to the destination can be specified:

dctx = zstd.ZstdDecompressor()
with dctx.write_to(fh, write_size=16384) as decompressor:
    pass

You can see how much memory is being used by the decompressor:

dctx = zstd.ZstdDecompressor()
with dctx.write_to(fh) as decompressor:
    byte_size = decompressor.memory_size()

Streaming Output API

read_from(fh) provides a mechanism to stream decompressed data out of a compressed source as an iterator of data chunks.:

dctx = zstd.ZstdDecompressor()
for chunk in dctx.read_from(fh):
    # Do something with original data.

read_from() accepts a) an object with a read(size) method that will return compressed bytes b) an object conforming to the buffer protocol that can expose its data as a contiguous range of bytes. The bytes and memoryview types expose this buffer protocol.

read_from() returns an iterator whose elements are chunks of the decompressed data.

The size of requested read() from the source can be specified:

dctx = zstd.ZstdDecompressor()
for chunk in dctx.read_from(fh, read_size=16384):
    pass

It is also possible to skip leading bytes in the input data:

dctx = zstd.ZstdDecompressor()
for chunk in dctx.read_from(fh, skip_bytes=1):
    pass

Skipping leading bytes is useful if the source data contains extra header data but you want to avoid the overhead of making a buffer copy or allocating a new memoryview object in order to decompress the data.

Similarly to ZstdCompressor.read_from(), the consumer of the iterator controls when data is decompressed. If the iterator isn't consumed, decompression is put on hold.

When read_from() is passed an object conforming to the buffer protocol, the behavior may seem similar to what occurs when the simple decompression API is used. However, this API works when the decompressed size is unknown. Furthermore, if feeding large inputs, the decompressor will work in chunks instead of performing a single operation.

Stream Copying API

copy_stream(ifh, ofh) can be used to copy data across 2 streams while performing decompression.:

dctx = zstd.ZstdDecompressor()
dctx.copy_stream(ifh, ofh)

e.g. to decompress a file to another file:

dctx = zstd.ZstdDecompressor()
with open(input_path, 'rb') as ifh, open(output_path, 'wb') as ofh:
    dctx.copy_stream(ifh, ofh)

The size of chunks being read() and write() from and to the streams can be specified:

dctx = zstd.ZstdDecompressor()
dctx.copy_stream(ifh, ofh, read_size=8192, write_size=16384)

Decompressor API

decompressobj() returns an object that exposes a decompress(data) methods. Compressed data chunks are fed into decompress(data) and uncompressed output (or an empty bytes) is returned. Output from subsequent calls needs to be concatenated to reassemble the full decompressed byte sequence.

The purpose of decompressobj() is to provide an API-compatible interface with zlib.decompressobj and bz2.BZ2Decompressor. This allows callers to swap in different decompressor objects while using the same API.

Each object is single use: once an input frame is decoded, decompress() can no longer be called.

Here is how this API should be used:

dctx = zstd.ZstdDeompressor()
dobj = cctx.decompressobj()
data = dobj.decompress(compressed_chunk_0)
data = dobj.decompress(compressed_chunk_1)

Batch Decompression API

(Experimental. Not yet supported in CFFI bindings.)

multi_decompress_to_buffer() performs decompression of multiple frames as a single operation and returns a BufferWithSegmentsCollection containing decompressed data for all inputs.

Compressed frames can be passed to the function as a BufferWithSegments, a BufferWithSegmentsCollection, or as a list containing objects that conform to the buffer protocol. For best performance, pass a BufferWithSegmentsCollection or a BufferWithSegments, as minimal input validation will be done for that type. If calling from Python (as opposed to C), constructing one of these instances may add overhead cancelling out the performance overhead of validation for list inputs.

The decompressed size of each frame must be discoverable. It can either be embedded within the zstd frame (write_content_size=True argument to ZstdCompressor) or passed in via the decompressed_sizes argument.

The decompressed_sizes argument is an object conforming to the buffer protocol which holds an array of 64-bit unsigned integers in the machine's native format defining the decompressed sizes of each frame. If this argument is passed, it avoids having to scan each frame for its decompressed size. This frame scanning can add noticeable overhead in some scenarios.

The threads argument controls the number of threads to use to perform decompression operations. The default (0) or the value 1 means to use a single thread. Negative values use the number of logical CPUs in the machine.

Note

It is possible to pass a mmap.mmap() instance into this function by wrapping it with a BufferWithSegments instance (which will define the offsets of frames within the memory mapped region).

This function is logically equivalent to performing dctx.decompress() on each input frame and returning the result.

This function exists to perform decompression on multiple frames as fast as possible by having as little overhead as possible. Since decompression is performed as a single operation and since the decompressed output is stored in a single buffer, extra memory allocations, Python objects, and Python function calls are avoided. This is ideal for scenarios where callers need to access decompressed data for multiple frames.

Currently, the implementation always spawns multiple threads when requested, even if the amount of work to do is small. In the future, it will be smarter about avoiding threads and their associated overhead when the amount of work to do is small.

Content-Only Dictionary Chain Decompression

decompress_content_dict_chain(frames) performs decompression of a list of zstd frames produced using chained content-only dictionary compression. Such a list of frames is produced by compressing discrete inputs where each non-initial input is compressed with a content-only dictionary consisting of the content of the previous input.

For example, say you have the following inputs:

inputs = [b'input 1', b'input 2', b'input 3']

The zstd frame chain consists of:

  1. b'input 1' compressed in standalone/discrete mode
  2. b'input 2' compressed using b'input 1' as a content-only dictionary
  3. b'input 3' compressed using b'input 2' as a content-only dictionary

Each zstd frame must have the content size written.

The following Python code can be used to produce a content-only dictionary chain:

def make_chain(inputs):
    frames = []

    # First frame is compressed in standalone/discrete mode.
    zctx = zstd.ZstdCompressor(write_content_size=True)
    frames.append(zctx.compress(inputs[0]))

    # Subsequent frames use the previous fulltext as a content-only dictionary
    for i, raw in enumerate(inputs[1:]):
        dict_data = zstd.ZstdCompressionDict(inputs[i])
        zctx = zstd.ZstdCompressor(write_content_size=True, dict_data=dict_data)
        frames.append(zctx.compress(raw))

    return frames

decompress_content_dict_chain() returns the uncompressed data of the last element in the input chain.

It is possible to implement content-only dictionary chain decompression on top of other Python APIs. However, this function will likely be significantly faster, especially for long input chains, as it avoids the overhead of instantiating and passing around intermediate objects between C and Python.

Multi-Threaded Compression

ZstdCompressor accepts a threads argument that controls the number of threads to use for compression. The way this works is that input is split into segments and each segment is fed into a worker pool for compression. Once a segment is compressed, it is flushed/appended to the output.

The segment size for multi-threaded compression is chosen from the window size of the compressor. This is derived from the window_log attribute of a CompressionParameters instance. By default, segment sizes are in the 1+MB range.

If multi-threaded compression is requested and the input is smaller than the configured segment size, only a single compression thread will be used. If the input is smaller than the segment size multiplied by the thread pool size or if data cannot be delivered to the compressor fast enough, not all requested compressor threads may be active simultaneously.

Compared to non-multi-threaded compression, multi-threaded compression has higher per-operation overhead. This includes extra memory operations, thread creation, lock acquisition, etc.

Due to the nature of multi-threaded compression using N compression states, the output from multi-threaded compression will likely be larger than non-multi-threaded compression. The difference is usually small. But there is a CPU/wall time versus size trade off that may warrant investigation.

Output from multi-threaded compression does not require any special handling on the decompression side. In other words, any zstd decompressor should be able to consume data produced with multi-threaded compression.

Dictionary Creation and Management

Compression dictionaries are represented as the ZstdCompressionDict type.

Instances can be constructed from bytes:

dict_data = zstd.ZstdCompressionDict(data)

It is possible to construct a dictionary from any data. Unless the data begins with a magic header, the dictionary will be treated as content-only. Content-only dictionaries allow compression operations that follow to reference raw data within the content. For one use of content-only dictionaries, see ZstdDecompressor.decompress_content_dict_chain().

More interestingly, instances can be created by training on sample data:

dict_data = zstd.train_dictionary(size, samples)

This takes a list of bytes instances and creates and returns a ZstdCompressionDict.

You can see how many bytes are in the dictionary by calling len():

dict_data = zstd.train_dictionary(size, samples)
dict_size = len(dict_data)  # will not be larger than ``size``

Once you have a dictionary, you can pass it to the objects performing compression and decompression:

dict_data = zstd.train_dictionary(16384, samples)

cctx = zstd.ZstdCompressor(dict_data=dict_data)
for source_data in input_data:
    compressed = cctx.compress(source_data)
    # Do something with compressed data.

dctx = zstd.ZstdDecompressor(dict_data=dict_data)
for compressed_data in input_data:
    buffer = io.BytesIO()
    with dctx.write_to(buffer) as decompressor:
        decompressor.write(compressed_data)
    # Do something with raw data in ``buffer``.

Dictionaries have unique integer IDs. You can retrieve this ID via:

dict_id = zstd.dictionary_id(dict_data)

You can obtain the raw data in the dict (useful for persisting and constructing a ZstdCompressionDict later) via as_bytes():

dict_data = zstd.train_dictionary(size, samples)
raw_data = dict_data.as_bytes()

The following named arguments to train_dictionary can also be used to further control dictionary generation.

selectivity
Integer selectivity level. Default is 9. Larger values yield more data in dictionary.
level
Integer compression level. Default is 6.
dict_id
Integer dictionary ID for the produced dictionary. Default is 0, which means to use a random value.
notifications
Controls writing of informational messages to stderr. 0 (the default) means to write nothing. 1 writes errors. 2 writes progression info. 3 writes more details. And 4 writes all info.

Cover Dictionaries

An alternate dictionary training mechanism named cover is also available. More details about this training mechanism are available in the paper Effective Construction of Relative Lempel-Ziv Dictionaries (authors: Liao, Petri, Moffat, Wirth).

To use this mechanism, use zstd.train_cover_dictionary() instead of zstd.train_dictionary(). The function behaves nearly the same except its arguments are different and the returned dictionary will contain k and d attributes reflecting the parameters to the cover algorithm.

Note

The k and d attributes are only populated on dictionary instances created by this function. If a ZstdCompressionDict is constructed from raw bytes data, the k and d attributes will be 0.

The segment and dmer size parameters to the cover algorithm can either be specified manually or you can ask train_cover_dictionary() to try multiple values and pick the best one, where best means the smallest compressed data size.

In manual mode, the k and d arguments must be specified or a ZstdError will be raised.

In automatic mode (triggered by specifying optimize=True), k and d are optional. If a value isn't specified, then default values for both are tested. The steps argument can control the number of steps through k values. The level argument defines the compression level that will be used when testing the compressed size. And threads can specify the number of threads to use for concurrent operation.

This function takes the following arguments:

dict_size
Target size in bytes of the dictionary to generate.
samples
A list of bytes holding samples the dictionary will be trained from.
k
Parameter to cover algorithm defining the segment size. A reasonable range is [16, 2048+].
d
Parameter to cover algorithm defining the dmer size. A reasonable range is [6, 16]. d must be less than or equal to k.
dict_id
Integer dictionary ID for the produced dictionary. Default is 0, which uses a random value.
optimize
When true, test dictionary generation with multiple parameters.
level
Integer target compression level when testing compression with optimize=True. Default is 1.
steps
Number of steps through k values to perform when optimize=True. Default is 32.
threads
Number of threads to use when optimize=True. Default is 0, which means to use a single thread. A negative value can be specified to use as many threads as there are detected logical CPUs.
notifications
Controls writing of informational messages to stderr. See the documentation for train_dictionary() for more.

Explicit Compression Parameters

Zstandard's integer compression levels along with the input size and dictionary size are converted into a data structure defining multiple parameters to tune behavior of the compression algorithm. It is possible to use define this data structure explicitly to have lower-level control over compression behavior.

The zstd.CompressionParameters type represents this data structure. You can see how Zstandard converts compression levels to this data structure by calling zstd.get_compression_parameters(). e.g.:

params = zstd.get_compression_parameters(5)

This function also accepts the uncompressed data size and dictionary size to adjust parameters:

params = zstd.get_compression_parameters(3, source_size=len(data), dict_size=len(dict_data))

You can also construct compression parameters from their low-level components:

params = zstd.CompressionParameters(20, 6, 12, 5, 4, 10, zstd.STRATEGY_FAST)

You can then configure a compressor to use the custom parameters:

cctx = zstd.ZstdCompressor(compression_params=params)

The members/attributes of CompressionParameters instances are as follows:

* window_log
* chain_log
* hash_log
* search_log
* search_length
* target_length
* strategy

This is the order the arguments are passed to the constructor if not using named arguments.

You'll need to read the Zstandard documentation for what these parameters do.

Frame Inspection

Data emitted from zstd compression is encapsulated in a frame. This frame begins with a 4 byte magic number header followed by 2 to 14 bytes describing the frame in more detail. For more info, see https://github.com/facebook/zstd/blob/master/doc/zstd_compression_format.md.

zstd.get_frame_parameters(data) parses a zstd frame header from a bytes instance and return a FrameParameters object describing the frame.

Depending on which fields are present in the frame and their values, the length of the frame parameters varies. If insufficient bytes are passed in to fully parse the frame parameters, ZstdError is raised. To ensure frame parameters can be parsed, pass in at least 18 bytes.

FrameParameters instances have the following attributes:

content_size
Integer size of original, uncompressed content. This will be 0 if the original content size isn't written to the frame (controlled with the write_content_size argument to ZstdCompressor) or if the input content size was 0.
window_size
Integer size of maximum back-reference distance in compressed data.
dict_id
Integer of dictionary ID used for compression. 0 if no dictionary ID was used or if the dictionary ID was 0.
has_checksum
Bool indicating whether a 4 byte content checksum is stored at the end of the frame.

Misc Functionality

estimate_compression_context_size(CompressionParameters)

Given a CompressionParameters struct, estimate the memory size required to perform compression.

estimate_decompression_context_size()

Estimate the memory size requirements for a decompressor instance.

Constants

The following module constants/attributes are exposed:

ZSTD_VERSION
This module attribute exposes a 3-tuple of the Zstandard version. e.g. (1, 0, 0)
MAX_COMPRESSION_LEVEL
Integer max compression level accepted by compression functions
COMPRESSION_RECOMMENDED_INPUT_SIZE
Recommended chunk size to feed to compressor functions
COMPRESSION_RECOMMENDED_OUTPUT_SIZE
Recommended chunk size for compression output
DECOMPRESSION_RECOMMENDED_INPUT_SIZE
Recommended chunk size to feed into decompresor functions
DECOMPRESSION_RECOMMENDED_OUTPUT_SIZE
Recommended chunk size for decompression output
FRAME_HEADER
bytes containing header of the Zstandard frame
MAGIC_NUMBER
Frame header as an integer
WINDOWLOG_MIN
Minimum value for compression parameter
WINDOWLOG_MAX
Maximum value for compression parameter
CHAINLOG_MIN
Minimum value for compression parameter
CHAINLOG_MAX
Maximum value for compression parameter
HASHLOG_MIN
Minimum value for compression parameter
HASHLOG_MAX
Maximum value for compression parameter
SEARCHLOG_MIN
Minimum value for compression parameter
SEARCHLOG_MAX
Maximum value for compression parameter
SEARCHLENGTH_MIN
Minimum value for compression parameter
SEARCHLENGTH_MAX
Maximum value for compression parameter
TARGETLENGTH_MIN
Minimum value for compression parameter
TARGETLENGTH_MAX
Maximum value for compression parameter
STRATEGY_FAST
Compression strategy
STRATEGY_DFAST
Compression strategy
STRATEGY_GREEDY
Compression strategy
STRATEGY_LAZY
Compression strategy
STRATEGY_LAZY2
Compression strategy
STRATEGY_BTLAZY2
Compression strategy
STRATEGY_BTOPT
Compression strategy

Performance Considerations

The ZstdCompressor and ZstdDecompressor types maintain state to a persistent compression or decompression context. Reusing a ZstdCompressor or ZstdDecompressor instance for multiple operations is faster than instantiating a new ZstdCompressor or ZstdDecompressor for each operation. The differences are magnified as the size of data decreases. For example, the difference between context reuse and non-reuse for 100,000 100 byte inputs will be significant (possiby over 10x faster to reuse contexts) whereas 10 1,000,000 byte inputs will be more similar in speed (because the time spent doing compression dwarfs time spent creating new contexts).

Buffer Types

The API exposes a handful of custom types for interfacing with memory buffers. The primary goal of these types is to facilitate efficient multi-object operations.

The essential idea is to have a single memory allocation provide backing storage for multiple logical objects. This has 2 main advantages: fewer allocations and optimal memory access patterns. This avoids having to allocate a Python object for each logical object and furthermore ensures that access of data for objects can be sequential (read: fast) in memory.

BufferWithSegments

The BufferWithSegments type represents a memory buffer containing N discrete items of known lengths (segments). It is essentially a fixed size memory address and an array of 2-tuples of (offset, length) 64-bit unsigned native endian integers defining the byte offset and length of each segment within the buffer.

Instances behave like containers.

len() returns the number of segments within the instance.

o[index] or __getitem__ obtains a BufferSegment representing an individual segment within the backing buffer. That returned object references (not copies) memory. This means that iterating all objects doesn't copy data within the buffer.

The .size attribute contains the total size in bytes of the backing buffer.

Instances conform to the buffer protocol. So a reference to the backing bytes can be obtained via memoryview(o). A copy of the backing bytes can also be obtained via .tobytes().

The .segments attribute exposes the array of (offset, length) for segments within the buffer. It is a BufferSegments type.

BufferSegment

The BufferSegment type represents a segment within a BufferWithSegments. It is essentially a reference to N bytes within a BufferWithSegments.

len() returns the length of the segment in bytes.

.offset contains the byte offset of this segment within its parent BufferWithSegments instance.

The object conforms to the buffer protocol. .tobytes() can be called to obtain a bytes instance with a copy of the backing bytes.

BufferSegments

This type represents an array of (offset, length) integers defining segments within a BufferWithSegments.

The array members are 64-bit unsigned integers using host/native bit order.

Instances conform to the buffer protocol.

BufferWithSegmentsCollection

The BufferWithSegmentsCollection type represents a virtual spanning view of multiple BufferWithSegments instances.

Instances are constructed from 1 or more BufferWithSegments instances. The resulting object behaves like an ordered sequence whose members are the segments within each BufferWithSegments.

len() returns the number of segments within all BufferWithSegments instances.

o[index] and __getitem__(index) return the BufferSegment at that offset as if all BufferWithSegments instances were a single entity.

If the object is composed of 2 BufferWithSegments instances with the first having 2 segments and the second have 3 segments, then b[0] and b[1] access segments in the first object and b[2], b[3], and b[4] access segments from the second.

Choosing an API

There are multiple APIs for performing compression and decompression. This is because different applications have different needs and the library wants to facilitate optimal use in as many use cases as possible.

From a high-level, APIs are divided into one-shot and streaming. See the Concepts section for a description of how these are different at the C layer.

The one-shot APIs are useful for small data, where the input or output size is known. (The size can come from a buffer length, file size, or stored in the zstd frame header.) A limitation of the one-shot APIs is that input and output must fit in memory simultaneously. For say a 4 GB input, this is often not feasible.

The one-shot APIs also perform all work as a single operation. So, if you feed it large input, it could take a long time for the function to return.

The streaming APIs do not have the limitations of the simple API. But the price you pay for this flexibility is that they are more complex than a single function call.

The streaming APIs put the caller in control of compression and decompression behavior by allowing them to directly control either the input or output side of the operation.

With the streaming input, compressor, and decompressor APIs, the caller has full control over the input to the compression or decompression stream. They can directly choose when new data is operated on.

With the streaming ouput APIs, the caller has full control over the output of the compression or decompression stream. It can choose when to receive new data.

When using the streaming APIs that operate on file-like or stream objects, it is important to consider what happens in that object when I/O is requested. There is potential for long pauses as data is read or written from the underlying stream (say from interacting with a filesystem or network). This could add considerable overhead.

Concepts

It is important to have a basic understanding of how Zstandard works in order to optimally use this library. In addition, there are some low-level Python concepts that are worth explaining to aid understanding. This section aims to provide that knowledge.

Zstandard Frames and Compression Format

Compressed zstandard data almost always exists within a container called a frame. (For the technically curious, see the `specification <https://github.com/facebook/zstd/blob/3bee41a70eaf343fbcae3637b3f6edbe52f35ed8/doc/zstd_compression_format.md>_.)

The frame contains a header and optional trailer. The header contains a magic number to self-identify as a zstd frame and a description of the compressed data that follows.

Among other things, the frame optionally contains the size of the decompressed data the frame represents, a 32-bit checksum of the decompressed data (to facilitate verification during decompression), and the ID of the dictionary used to compress the data.

Storing the original content size in the frame (write_content_size=True to ZstdCompressor) is important for performance in some scenarios. Having the decompressed size stored there (or storing it elsewhere) allows decompression to perform a single memory allocation that is exactly sized to the output. This is faster than continuously growing a memory buffer to hold output.

Compression and Decompression Contexts

In order to perform a compression or decompression operation with the zstd C API, you need what's called a context. A context essentially holds configuration and state for a compression or decompression operation. For example, a compression context holds the configured compression level.

Contexts can be reused for multiple operations. Since creating and destroying contexts is not free, there are performance advantages to reusing contexts.

The ZstdCompressor and ZstdDecompressor types are essentially wrappers around these contexts in the zstd C API.

One-shot And Streaming Operations

A compression or decompression operation can either be performed as a single one-shot operation or as a continuous streaming operation.

In one-shot mode (the simple APIs provided by the Python interface), all input is handed to the compressor or decompressor as a single buffer and all output is returned as a single buffer.

In streaming mode, input is delivered to the compressor or decompressor as a series of chunks via multiple function calls. Likewise, output is obtained in chunks as well.

Streaming operations require an additional stream object to be created to track the operation. These are logical extensions of context instances.

There are advantages and disadvantages to each mode of operation. There are scenarios where certain modes can't be used. See the Choosing an API section for more.

Dictionaries

A compression dictionary is essentially data used to seed the compressor state so it can achieve better compression. The idea is that if you are compressing a lot of similar pieces of data (e.g. JSON documents or anything sharing similar structure), then you can find common patterns across multiple objects then leverage those common patterns during compression and decompression operations to achieve better compression ratios.

Dictionary compression is generally only useful for small inputs - data no larger than a few kilobytes. The upper bound on this range is highly dependent on the input data and the dictionary.

Python Buffer Protocol

Many functions in the library operate on objects that implement Python's buffer protocol.

The buffer protocol is an internal implementation detail of a Python type that allows instances of that type (objects) to be exposed as a raw pointer (or buffer) in the C API. In other words, it allows objects to be exposed as an array of bytes.

From the perspective of the C API, objects implementing the buffer protocol all look the same: they are just a pointer to a memory address of a defined length. This allows the C API to be largely type agnostic when accessing their data. This allows custom types to be passed in without first converting them to a specific type.

Many Python types implement the buffer protocol. These include bytes (str on Python 2), bytearray, array.array, io.BytesIO, mmap.mmap, and memoryview.

python-zstandard APIs that accept objects conforming to the buffer protocol require that the buffer is C contiguous and has a single dimension (ndim==1). This is usually the case. An example of where it is not is a Numpy matrix type.

Requiring Output Sizes for Non-Streaming Decompression APIs

Non-streaming decompression APIs require that either the output size is explicitly defined (either in the zstd frame header or passed into the function) or that a max output size is specified. This restriction is for your safety.

The one-shot decompression APIs store the decompressed result in a single buffer. This means that a buffer needs to be pre-allocated to hold the result. If the decompressed size is not known, then there is no universal good default size to use. Any default will fail or will be highly sub-optimal in some scenarios (it will either be too small or will put stress on the memory allocator to allocate a too large block).

A helpful API may retry decompression with buffers of increasing size. While useful, there are obvious performance disadvantages, namely redoing decompression N times until it works. In addition, there is a security concern. Say the input came from highly compressible data, like 1 GB of the same byte value. The output size could be several magnitudes larger than the input size. An input of <100KB could decompress to >1GB. Without a bounds restriction on the decompressed size, certain inputs could exhaust all system memory. That's not good and is why the maximum output size is limited.

Note on Zstandard's Experimental API

Many of the Zstandard APIs used by this module are marked as experimental within the Zstandard project. This includes a large number of useful features, such as compression and frame parameters and parts of dictionary compression.

It is unclear how Zstandard's C API will evolve over time, especially with regards to this experimental functionality. We will try to maintain backwards compatibility at the Python API level. However, we cannot guarantee this for things not under our control.

Since a copy of the Zstandard source code is distributed with this module and since we compile against it, the behavior of a specific version of this module should be constant for all of time. So if you pin the version of this module used in your projects (which is a Python best practice), you should be buffered from unwanted future changes.