##// END OF EJS Templates
push: add a way to allow concurrent pushes on unrelated heads...
push: add a way to allow concurrent pushes on unrelated heads Client has a mechanism for the server to check that nothing changed server side since the client prepared a push. That check is wide and any head changed on the server will lead to an aborted push. We introduce a way for the client to send a less strict checking. That logic will check that no heads impacted by the push have been affected. If other unrelated heads (including named branches heads) have been affected, the push will proceed. This is very helpful for repositories with high developers traffic on different heads, a common setup. That behavior is currently controlled by an experimental option. The config should live in the "server" section but bike-shedding of the name will happen in the next changesets. Servers advertise this capability through a new bundle2 capability 'checkeads', using the value 'related'. The 'test-push-race.t' is updated to check that new capabilities on the documented cases.

File last commit:

r31796:e0dc4053 default
r32709:16ada4cb default
Show More
zstd_cffi.py
1257 lines | 43.3 KiB | text/x-python | PythonLexer
# Copyright (c) 2016-present, Gregory Szorc
# All rights reserved.
#
# This software may be modified and distributed under the terms
# of the BSD license. See the LICENSE file for details.
"""Python interface to the Zstandard (zstd) compression library."""
from __future__ import absolute_import, unicode_literals
import os
import sys
from _zstd_cffi import (
ffi,
lib,
)
if sys.version_info[0] == 2:
bytes_type = str
int_type = long
else:
bytes_type = bytes
int_type = int
COMPRESSION_RECOMMENDED_INPUT_SIZE = lib.ZSTD_CStreamInSize()
COMPRESSION_RECOMMENDED_OUTPUT_SIZE = lib.ZSTD_CStreamOutSize()
DECOMPRESSION_RECOMMENDED_INPUT_SIZE = lib.ZSTD_DStreamInSize()
DECOMPRESSION_RECOMMENDED_OUTPUT_SIZE = lib.ZSTD_DStreamOutSize()
new_nonzero = ffi.new_allocator(should_clear_after_alloc=False)
MAX_COMPRESSION_LEVEL = lib.ZSTD_maxCLevel()
MAGIC_NUMBER = lib.ZSTD_MAGICNUMBER
FRAME_HEADER = b'\x28\xb5\x2f\xfd'
ZSTD_VERSION = (lib.ZSTD_VERSION_MAJOR, lib.ZSTD_VERSION_MINOR, lib.ZSTD_VERSION_RELEASE)
WINDOWLOG_MIN = lib.ZSTD_WINDOWLOG_MIN
WINDOWLOG_MAX = lib.ZSTD_WINDOWLOG_MAX
CHAINLOG_MIN = lib.ZSTD_CHAINLOG_MIN
CHAINLOG_MAX = lib.ZSTD_CHAINLOG_MAX
HASHLOG_MIN = lib.ZSTD_HASHLOG_MIN
HASHLOG_MAX = lib.ZSTD_HASHLOG_MAX
HASHLOG3_MAX = lib.ZSTD_HASHLOG3_MAX
SEARCHLOG_MIN = lib.ZSTD_SEARCHLOG_MIN
SEARCHLOG_MAX = lib.ZSTD_SEARCHLOG_MAX
SEARCHLENGTH_MIN = lib.ZSTD_SEARCHLENGTH_MIN
SEARCHLENGTH_MAX = lib.ZSTD_SEARCHLENGTH_MAX
TARGETLENGTH_MIN = lib.ZSTD_TARGETLENGTH_MIN
TARGETLENGTH_MAX = lib.ZSTD_TARGETLENGTH_MAX
STRATEGY_FAST = lib.ZSTD_fast
STRATEGY_DFAST = lib.ZSTD_dfast
STRATEGY_GREEDY = lib.ZSTD_greedy
STRATEGY_LAZY = lib.ZSTD_lazy
STRATEGY_LAZY2 = lib.ZSTD_lazy2
STRATEGY_BTLAZY2 = lib.ZSTD_btlazy2
STRATEGY_BTOPT = lib.ZSTD_btopt
COMPRESSOBJ_FLUSH_FINISH = 0
COMPRESSOBJ_FLUSH_BLOCK = 1
def _cpu_count():
# os.cpu_count() was introducd in Python 3.4.
try:
return os.cpu_count() or 0
except AttributeError:
pass
# Linux.
try:
if sys.version_info[0] == 2:
return os.sysconf(b'SC_NPROCESSORS_ONLN')
else:
return os.sysconf(u'SC_NPROCESSORS_ONLN')
except (AttributeError, ValueError):
pass
# TODO implement on other platforms.
return 0
class ZstdError(Exception):
pass
class CompressionParameters(object):
def __init__(self, window_log, chain_log, hash_log, search_log,
search_length, target_length, strategy):
if window_log < WINDOWLOG_MIN or window_log > WINDOWLOG_MAX:
raise ValueError('invalid window log value')
if chain_log < CHAINLOG_MIN or chain_log > CHAINLOG_MAX:
raise ValueError('invalid chain log value')
if hash_log < HASHLOG_MIN or hash_log > HASHLOG_MAX:
raise ValueError('invalid hash log value')
if search_log < SEARCHLOG_MIN or search_log > SEARCHLOG_MAX:
raise ValueError('invalid search log value')
if search_length < SEARCHLENGTH_MIN or search_length > SEARCHLENGTH_MAX:
raise ValueError('invalid search length value')
if target_length < TARGETLENGTH_MIN or target_length > TARGETLENGTH_MAX:
raise ValueError('invalid target length value')
if strategy < STRATEGY_FAST or strategy > STRATEGY_BTOPT:
raise ValueError('invalid strategy value')
self.window_log = window_log
self.chain_log = chain_log
self.hash_log = hash_log
self.search_log = search_log
self.search_length = search_length
self.target_length = target_length
self.strategy = strategy
zresult = lib.ZSTD_checkCParams(self.as_compression_parameters())
if lib.ZSTD_isError(zresult):
raise ValueError('invalid compression parameters: %s',
ffi.string(lib.ZSTD_getErrorName(zresult)))
def estimated_compression_context_size(self):
return lib.ZSTD_estimateCCtxSize(self.as_compression_parameters())
def as_compression_parameters(self):
p = ffi.new('ZSTD_compressionParameters *')[0]
p.windowLog = self.window_log
p.chainLog = self.chain_log
p.hashLog = self.hash_log
p.searchLog = self.search_log
p.searchLength = self.search_length
p.targetLength = self.target_length
p.strategy = self.strategy
return p
def get_compression_parameters(level, source_size=0, dict_size=0):
params = lib.ZSTD_getCParams(level, source_size, dict_size)
return CompressionParameters(window_log=params.windowLog,
chain_log=params.chainLog,
hash_log=params.hashLog,
search_log=params.searchLog,
search_length=params.searchLength,
target_length=params.targetLength,
strategy=params.strategy)
def estimate_compression_context_size(params):
if not isinstance(params, CompressionParameters):
raise ValueError('argument must be a CompressionParameters')
cparams = params.as_compression_parameters()
return lib.ZSTD_estimateCCtxSize(cparams)
def estimate_decompression_context_size():
return lib.ZSTD_estimateDCtxSize()
class ZstdCompressionWriter(object):
def __init__(self, compressor, writer, source_size, write_size):
self._compressor = compressor
self._writer = writer
self._source_size = source_size
self._write_size = write_size
self._entered = False
self._mtcctx = compressor._cctx if compressor._multithreaded else None
def __enter__(self):
if self._entered:
raise ZstdError('cannot __enter__ multiple times')
if self._mtcctx:
self._compressor._init_mtcstream(self._source_size)
else:
self._compressor._ensure_cstream(self._source_size)
self._entered = True
return self
def __exit__(self, exc_type, exc_value, exc_tb):
self._entered = False
if not exc_type and not exc_value and not exc_tb:
out_buffer = ffi.new('ZSTD_outBuffer *')
dst_buffer = ffi.new('char[]', self._write_size)
out_buffer.dst = dst_buffer
out_buffer.size = self._write_size
out_buffer.pos = 0
while True:
if self._mtcctx:
zresult = lib.ZSTDMT_endStream(self._mtcctx, out_buffer)
else:
zresult = lib.ZSTD_endStream(self._compressor._cstream, out_buffer)
if lib.ZSTD_isError(zresult):
raise ZstdError('error ending compression stream: %s' %
ffi.string(lib.ZSTD_getErrorName(zresult)))
if out_buffer.pos:
self._writer.write(ffi.buffer(out_buffer.dst, out_buffer.pos)[:])
out_buffer.pos = 0
if zresult == 0:
break
self._compressor = None
return False
def memory_size(self):
if not self._entered:
raise ZstdError('cannot determine size of an inactive compressor; '
'call when a context manager is active')
return lib.ZSTD_sizeof_CStream(self._compressor._cstream)
def write(self, data):
if not self._entered:
raise ZstdError('write() must be called from an active context '
'manager')
total_write = 0
data_buffer = ffi.from_buffer(data)
in_buffer = ffi.new('ZSTD_inBuffer *')
in_buffer.src = data_buffer
in_buffer.size = len(data_buffer)
in_buffer.pos = 0
out_buffer = ffi.new('ZSTD_outBuffer *')
dst_buffer = ffi.new('char[]', self._write_size)
out_buffer.dst = dst_buffer
out_buffer.size = self._write_size
out_buffer.pos = 0
while in_buffer.pos < in_buffer.size:
if self._mtcctx:
zresult = lib.ZSTDMT_compressStream(self._mtcctx, out_buffer,
in_buffer)
else:
zresult = lib.ZSTD_compressStream(self._compressor._cstream, out_buffer,
in_buffer)
if lib.ZSTD_isError(zresult):
raise ZstdError('zstd compress error: %s' %
ffi.string(lib.ZSTD_getErrorName(zresult)))
if out_buffer.pos:
self._writer.write(ffi.buffer(out_buffer.dst, out_buffer.pos)[:])
total_write += out_buffer.pos
out_buffer.pos = 0
return total_write
def flush(self):
if not self._entered:
raise ZstdError('flush must be called from an active context manager')
total_write = 0
out_buffer = ffi.new('ZSTD_outBuffer *')
dst_buffer = ffi.new('char[]', self._write_size)
out_buffer.dst = dst_buffer
out_buffer.size = self._write_size
out_buffer.pos = 0
while True:
if self._mtcctx:
zresult = lib.ZSTDMT_flushStream(self._mtcctx, out_buffer)
else:
zresult = lib.ZSTD_flushStream(self._compressor._cstream, out_buffer)
if lib.ZSTD_isError(zresult):
raise ZstdError('zstd compress error: %s' %
ffi.string(lib.ZSTD_getErrorName(zresult)))
if not out_buffer.pos:
break
self._writer.write(ffi.buffer(out_buffer.dst, out_buffer.pos)[:])
total_write += out_buffer.pos
out_buffer.pos = 0
return total_write
class ZstdCompressionObj(object):
def compress(self, data):
if self._finished:
raise ZstdError('cannot call compress() after compressor finished')
data_buffer = ffi.from_buffer(data)
source = ffi.new('ZSTD_inBuffer *')
source.src = data_buffer
source.size = len(data_buffer)
source.pos = 0
chunks = []
while source.pos < len(data):
if self._mtcctx:
zresult = lib.ZSTDMT_compressStream(self._mtcctx,
self._out, source)
else:
zresult = lib.ZSTD_compressStream(self._compressor._cstream, self._out,
source)
if lib.ZSTD_isError(zresult):
raise ZstdError('zstd compress error: %s' %
ffi.string(lib.ZSTD_getErrorName(zresult)))
if self._out.pos:
chunks.append(ffi.buffer(self._out.dst, self._out.pos)[:])
self._out.pos = 0
return b''.join(chunks)
def flush(self, flush_mode=COMPRESSOBJ_FLUSH_FINISH):
if flush_mode not in (COMPRESSOBJ_FLUSH_FINISH, COMPRESSOBJ_FLUSH_BLOCK):
raise ValueError('flush mode not recognized')
if self._finished:
raise ZstdError('compressor object already finished')
assert self._out.pos == 0
if flush_mode == COMPRESSOBJ_FLUSH_BLOCK:
if self._mtcctx:
zresult = lib.ZSTDMT_flushStream(self._mtcctx, self._out)
else:
zresult = lib.ZSTD_flushStream(self._compressor._cstream, self._out)
if lib.ZSTD_isError(zresult):
raise ZstdError('zstd compress error: %s' %
ffi.string(lib.ZSTD_getErrorName(zresult)))
# Output buffer is guaranteed to hold full block.
assert zresult == 0
if self._out.pos:
result = ffi.buffer(self._out.dst, self._out.pos)[:]
self._out.pos = 0
return result
else:
return b''
assert flush_mode == COMPRESSOBJ_FLUSH_FINISH
self._finished = True
chunks = []
while True:
if self._mtcctx:
zresult = lib.ZSTDMT_endStream(self._mtcctx, self._out)
else:
zresult = lib.ZSTD_endStream(self._compressor._cstream, self._out)
if lib.ZSTD_isError(zresult):
raise ZstdError('error ending compression stream: %s' %
ffi.string(lib.ZSTD_getErroName(zresult)))
if self._out.pos:
chunks.append(ffi.buffer(self._out.dst, self._out.pos)[:])
self._out.pos = 0
if not zresult:
break
return b''.join(chunks)
class ZstdCompressor(object):
def __init__(self, level=3, dict_data=None, compression_params=None,
write_checksum=False, write_content_size=False,
write_dict_id=True, threads=0):
if level < 1:
raise ValueError('level must be greater than 0')
elif level > lib.ZSTD_maxCLevel():
raise ValueError('level must be less than %d' % lib.ZSTD_maxCLevel())
if threads < 0:
threads = _cpu_count()
self._compression_level = level
self._dict_data = dict_data
self._cparams = compression_params
self._fparams = ffi.new('ZSTD_frameParameters *')[0]
self._fparams.checksumFlag = write_checksum
self._fparams.contentSizeFlag = write_content_size
self._fparams.noDictIDFlag = not write_dict_id
if threads:
cctx = lib.ZSTDMT_createCCtx(threads)
if cctx == ffi.NULL:
raise MemoryError()
self._cctx = ffi.gc(cctx, lib.ZSTDMT_freeCCtx)
self._multithreaded = True
else:
cctx = lib.ZSTD_createCCtx()
if cctx == ffi.NULL:
raise MemoryError()
self._cctx = ffi.gc(cctx, lib.ZSTD_freeCCtx)
self._multithreaded = False
self._cstream = None
def compress(self, data, allow_empty=False):
if len(data) == 0 and self._fparams.contentSizeFlag and not allow_empty:
raise ValueError('cannot write empty inputs when writing content sizes')
if self._multithreaded and self._dict_data:
raise ZstdError('compress() cannot be used with both dictionaries and multi-threaded compression')
if self._multithreaded and self._cparams:
raise ZstdError('compress() cannot be used with both compression parameters and multi-threaded compression')
# TODO use a CDict for performance.
dict_data = ffi.NULL
dict_size = 0
if self._dict_data:
dict_data = self._dict_data.as_bytes()
dict_size = len(self._dict_data)
params = ffi.new('ZSTD_parameters *')[0]
if self._cparams:
params.cParams = self._cparams.as_compression_parameters()
else:
params.cParams = lib.ZSTD_getCParams(self._compression_level, len(data),
dict_size)
params.fParams = self._fparams
dest_size = lib.ZSTD_compressBound(len(data))
out = new_nonzero('char[]', dest_size)
if self._multithreaded:
zresult = lib.ZSTDMT_compressCCtx(self._cctx,
ffi.addressof(out), dest_size,
data, len(data),
self._compression_level)
else:
zresult = lib.ZSTD_compress_advanced(self._cctx,
ffi.addressof(out), dest_size,
data, len(data),
dict_data, dict_size,
params)
if lib.ZSTD_isError(zresult):
raise ZstdError('cannot compress: %s' %
ffi.string(lib.ZSTD_getErrorName(zresult)))
return ffi.buffer(out, zresult)[:]
def compressobj(self, size=0):
if self._multithreaded:
self._init_mtcstream(size)
else:
self._ensure_cstream(size)
cobj = ZstdCompressionObj()
cobj._out = ffi.new('ZSTD_outBuffer *')
cobj._dst_buffer = ffi.new('char[]', COMPRESSION_RECOMMENDED_OUTPUT_SIZE)
cobj._out.dst = cobj._dst_buffer
cobj._out.size = COMPRESSION_RECOMMENDED_OUTPUT_SIZE
cobj._out.pos = 0
cobj._compressor = self
cobj._finished = False
if self._multithreaded:
cobj._mtcctx = self._cctx
else:
cobj._mtcctx = None
return cobj
def copy_stream(self, ifh, ofh, size=0,
read_size=COMPRESSION_RECOMMENDED_INPUT_SIZE,
write_size=COMPRESSION_RECOMMENDED_OUTPUT_SIZE):
if not hasattr(ifh, 'read'):
raise ValueError('first argument must have a read() method')
if not hasattr(ofh, 'write'):
raise ValueError('second argument must have a write() method')
mt = self._multithreaded
if mt:
self._init_mtcstream(size)
else:
self._ensure_cstream(size)
in_buffer = ffi.new('ZSTD_inBuffer *')
out_buffer = ffi.new('ZSTD_outBuffer *')
dst_buffer = ffi.new('char[]', write_size)
out_buffer.dst = dst_buffer
out_buffer.size = write_size
out_buffer.pos = 0
total_read, total_write = 0, 0
while True:
data = ifh.read(read_size)
if not data:
break
data_buffer = ffi.from_buffer(data)
total_read += len(data_buffer)
in_buffer.src = data_buffer
in_buffer.size = len(data_buffer)
in_buffer.pos = 0
while in_buffer.pos < in_buffer.size:
if mt:
zresult = lib.ZSTDMT_compressStream(self._cctx, out_buffer, in_buffer)
else:
zresult = lib.ZSTD_compressStream(self._cstream,
out_buffer, in_buffer)
if lib.ZSTD_isError(zresult):
raise ZstdError('zstd compress error: %s' %
ffi.string(lib.ZSTD_getErrorName(zresult)))
if out_buffer.pos:
ofh.write(ffi.buffer(out_buffer.dst, out_buffer.pos))
total_write += out_buffer.pos
out_buffer.pos = 0
# We've finished reading. Flush the compressor.
while True:
if mt:
zresult = lib.ZSTDMT_endStream(self._cctx, out_buffer)
else:
zresult = lib.ZSTD_endStream(self._cstream, out_buffer)
if lib.ZSTD_isError(zresult):
raise ZstdError('error ending compression stream: %s' %
ffi.string(lib.ZSTD_getErrorName(zresult)))
if out_buffer.pos:
ofh.write(ffi.buffer(out_buffer.dst, out_buffer.pos))
total_write += out_buffer.pos
out_buffer.pos = 0
if zresult == 0:
break
return total_read, total_write
def write_to(self, writer, size=0,
write_size=COMPRESSION_RECOMMENDED_OUTPUT_SIZE):
if not hasattr(writer, 'write'):
raise ValueError('must pass an object with a write() method')
return ZstdCompressionWriter(self, writer, size, write_size)
def read_from(self, reader, size=0,
read_size=COMPRESSION_RECOMMENDED_INPUT_SIZE,
write_size=COMPRESSION_RECOMMENDED_OUTPUT_SIZE):
if hasattr(reader, 'read'):
have_read = True
elif hasattr(reader, '__getitem__'):
have_read = False
buffer_offset = 0
size = len(reader)
else:
raise ValueError('must pass an object with a read() method or '
'conforms to buffer protocol')
if self._multithreaded:
self._init_mtcstream(size)
else:
self._ensure_cstream(size)
in_buffer = ffi.new('ZSTD_inBuffer *')
out_buffer = ffi.new('ZSTD_outBuffer *')
in_buffer.src = ffi.NULL
in_buffer.size = 0
in_buffer.pos = 0
dst_buffer = ffi.new('char[]', write_size)
out_buffer.dst = dst_buffer
out_buffer.size = write_size
out_buffer.pos = 0
while True:
# We should never have output data sitting around after a previous
# iteration.
assert out_buffer.pos == 0
# Collect input data.
if have_read:
read_result = reader.read(read_size)
else:
remaining = len(reader) - buffer_offset
slice_size = min(remaining, read_size)
read_result = reader[buffer_offset:buffer_offset + slice_size]
buffer_offset += slice_size
# No new input data. Break out of the read loop.
if not read_result:
break
# Feed all read data into the compressor and emit output until
# exhausted.
read_buffer = ffi.from_buffer(read_result)
in_buffer.src = read_buffer
in_buffer.size = len(read_buffer)
in_buffer.pos = 0
while in_buffer.pos < in_buffer.size:
if self._multithreaded:
zresult = lib.ZSTDMT_compressStream(self._cctx, out_buffer, in_buffer)
else:
zresult = lib.ZSTD_compressStream(self._cstream, out_buffer, in_buffer)
if lib.ZSTD_isError(zresult):
raise ZstdError('zstd compress error: %s' %
ffi.string(lib.ZSTD_getErrorName(zresult)))
if out_buffer.pos:
data = ffi.buffer(out_buffer.dst, out_buffer.pos)[:]
out_buffer.pos = 0
yield data
assert out_buffer.pos == 0
# And repeat the loop to collect more data.
continue
# If we get here, input is exhausted. End the stream and emit what
# remains.
while True:
assert out_buffer.pos == 0
if self._multithreaded:
zresult = lib.ZSTDMT_endStream(self._cctx, out_buffer)
else:
zresult = lib.ZSTD_endStream(self._cstream, out_buffer)
if lib.ZSTD_isError(zresult):
raise ZstdError('error ending compression stream: %s' %
ffi.string(lib.ZSTD_getErrorName(zresult)))
if out_buffer.pos:
data = ffi.buffer(out_buffer.dst, out_buffer.pos)[:]
out_buffer.pos = 0
yield data
if zresult == 0:
break
def _ensure_cstream(self, size):
if self._cstream:
zresult = lib.ZSTD_resetCStream(self._cstream, size)
if lib.ZSTD_isError(zresult):
raise ZstdError('could not reset CStream: %s' %
ffi.string(lib.ZSTD_getErrorName(zresult)))
return
cstream = lib.ZSTD_createCStream()
if cstream == ffi.NULL:
raise MemoryError()
cstream = ffi.gc(cstream, lib.ZSTD_freeCStream)
dict_data = ffi.NULL
dict_size = 0
if self._dict_data:
dict_data = self._dict_data.as_bytes()
dict_size = len(self._dict_data)
zparams = ffi.new('ZSTD_parameters *')[0]
if self._cparams:
zparams.cParams = self._cparams.as_compression_parameters()
else:
zparams.cParams = lib.ZSTD_getCParams(self._compression_level,
size, dict_size)
zparams.fParams = self._fparams
zresult = lib.ZSTD_initCStream_advanced(cstream, dict_data, dict_size,
zparams, size)
if lib.ZSTD_isError(zresult):
raise Exception('cannot init CStream: %s' %
ffi.string(lib.ZSTD_getErrorName(zresult)))
self._cstream = cstream
def _init_mtcstream(self, size):
assert self._multithreaded
dict_data = ffi.NULL
dict_size = 0
if self._dict_data:
dict_data = self._dict_data.as_bytes()
dict_size = len(self._dict_data)
zparams = ffi.new('ZSTD_parameters *')[0]
if self._cparams:
zparams.cParams = self._cparams.as_compression_parameters()
else:
zparams.cParams = lib.ZSTD_getCParams(self._compression_level,
size, dict_size)
zparams.fParams = self._fparams
zresult = lib.ZSTDMT_initCStream_advanced(self._cctx, dict_data, dict_size,
zparams, size)
if lib.ZSTD_isError(zresult):
raise ZstdError('cannot init CStream: %s' %
ffi.string(lib.ZSTD_getErrorName(zresult)))
class FrameParameters(object):
def __init__(self, fparams):
self.content_size = fparams.frameContentSize
self.window_size = fparams.windowSize
self.dict_id = fparams.dictID
self.has_checksum = bool(fparams.checksumFlag)
def get_frame_parameters(data):
if not isinstance(data, bytes_type):
raise TypeError('argument must be bytes')
params = ffi.new('ZSTD_frameParams *')
zresult = lib.ZSTD_getFrameParams(params, data, len(data))
if lib.ZSTD_isError(zresult):
raise ZstdError('cannot get frame parameters: %s' %
ffi.string(lib.ZSTD_getErrorName(zresult)))
if zresult:
raise ZstdError('not enough data for frame parameters; need %d bytes' %
zresult)
return FrameParameters(params[0])
class ZstdCompressionDict(object):
def __init__(self, data, k=0, d=0):
assert isinstance(data, bytes_type)
self._data = data
self.k = k
self.d = d
def __len__(self):
return len(self._data)
def dict_id(self):
return int_type(lib.ZDICT_getDictID(self._data, len(self._data)))
def as_bytes(self):
return self._data
def train_dictionary(dict_size, samples, selectivity=0, level=0,
notifications=0, dict_id=0):
if not isinstance(samples, list):
raise TypeError('samples must be a list')
total_size = sum(map(len, samples))
samples_buffer = new_nonzero('char[]', total_size)
sample_sizes = new_nonzero('size_t[]', len(samples))
offset = 0
for i, sample in enumerate(samples):
if not isinstance(sample, bytes_type):
raise ValueError('samples must be bytes')
l = len(sample)
ffi.memmove(samples_buffer + offset, sample, l)
offset += l
sample_sizes[i] = l
dict_data = new_nonzero('char[]', dict_size)
dparams = ffi.new('ZDICT_params_t *')[0]
dparams.selectivityLevel = selectivity
dparams.compressionLevel = level
dparams.notificationLevel = notifications
dparams.dictID = dict_id
zresult = lib.ZDICT_trainFromBuffer_advanced(
ffi.addressof(dict_data), dict_size,
ffi.addressof(samples_buffer),
ffi.addressof(sample_sizes, 0), len(samples),
dparams)
if lib.ZDICT_isError(zresult):
raise ZstdError('Cannot train dict: %s' %
ffi.string(lib.ZDICT_getErrorName(zresult)))
return ZstdCompressionDict(ffi.buffer(dict_data, zresult)[:])
def train_cover_dictionary(dict_size, samples, k=0, d=0,
notifications=0, dict_id=0, level=0, optimize=False,
steps=0, threads=0):
if not isinstance(samples, list):
raise TypeError('samples must be a list')
if threads < 0:
threads = _cpu_count()
total_size = sum(map(len, samples))
samples_buffer = new_nonzero('char[]', total_size)
sample_sizes = new_nonzero('size_t[]', len(samples))
offset = 0
for i, sample in enumerate(samples):
if not isinstance(sample, bytes_type):
raise ValueError('samples must be bytes')
l = len(sample)
ffi.memmove(samples_buffer + offset, sample, l)
offset += l
sample_sizes[i] = l
dict_data = new_nonzero('char[]', dict_size)
dparams = ffi.new('COVER_params_t *')[0]
dparams.k = k
dparams.d = d
dparams.steps = steps
dparams.nbThreads = threads
dparams.notificationLevel = notifications
dparams.dictID = dict_id
dparams.compressionLevel = level
if optimize:
zresult = lib.COVER_optimizeTrainFromBuffer(
ffi.addressof(dict_data), dict_size,
ffi.addressof(samples_buffer),
ffi.addressof(sample_sizes, 0), len(samples),
ffi.addressof(dparams))
else:
zresult = lib.COVER_trainFromBuffer(
ffi.addressof(dict_data), dict_size,
ffi.addressof(samples_buffer),
ffi.addressof(sample_sizes, 0), len(samples),
dparams)
if lib.ZDICT_isError(zresult):
raise ZstdError('cannot train dict: %s' %
ffi.string(lib.ZDICT_getErrorName(zresult)))
return ZstdCompressionDict(ffi.buffer(dict_data, zresult)[:],
k=dparams.k, d=dparams.d)
class ZstdDecompressionObj(object):
def __init__(self, decompressor):
self._decompressor = decompressor
self._finished = False
def decompress(self, data):
if self._finished:
raise ZstdError('cannot use a decompressobj multiple times')
assert(self._decompressor._dstream)
in_buffer = ffi.new('ZSTD_inBuffer *')
out_buffer = ffi.new('ZSTD_outBuffer *')
data_buffer = ffi.from_buffer(data)
in_buffer.src = data_buffer
in_buffer.size = len(data_buffer)
in_buffer.pos = 0
dst_buffer = ffi.new('char[]', DECOMPRESSION_RECOMMENDED_OUTPUT_SIZE)
out_buffer.dst = dst_buffer
out_buffer.size = len(dst_buffer)
out_buffer.pos = 0
chunks = []
while in_buffer.pos < in_buffer.size:
zresult = lib.ZSTD_decompressStream(self._decompressor._dstream,
out_buffer, in_buffer)
if lib.ZSTD_isError(zresult):
raise ZstdError('zstd decompressor error: %s' %
ffi.string(lib.ZSTD_getErrorName(zresult)))
if zresult == 0:
self._finished = True
self._decompressor = None
if out_buffer.pos:
chunks.append(ffi.buffer(out_buffer.dst, out_buffer.pos)[:])
out_buffer.pos = 0
return b''.join(chunks)
class ZstdDecompressionWriter(object):
def __init__(self, decompressor, writer, write_size):
self._decompressor = decompressor
self._writer = writer
self._write_size = write_size
self._entered = False
def __enter__(self):
if self._entered:
raise ZstdError('cannot __enter__ multiple times')
self._decompressor._ensure_dstream()
self._entered = True
return self
def __exit__(self, exc_type, exc_value, exc_tb):
self._entered = False
def memory_size(self):
if not self._decompressor._dstream:
raise ZstdError('cannot determine size of inactive decompressor '
'call when context manager is active')
return lib.ZSTD_sizeof_DStream(self._decompressor._dstream)
def write(self, data):
if not self._entered:
raise ZstdError('write must be called from an active context manager')
total_write = 0
in_buffer = ffi.new('ZSTD_inBuffer *')
out_buffer = ffi.new('ZSTD_outBuffer *')
data_buffer = ffi.from_buffer(data)
in_buffer.src = data_buffer
in_buffer.size = len(data_buffer)
in_buffer.pos = 0
dst_buffer = ffi.new('char[]', self._write_size)
out_buffer.dst = dst_buffer
out_buffer.size = len(dst_buffer)
out_buffer.pos = 0
dstream = self._decompressor._dstream
while in_buffer.pos < in_buffer.size:
zresult = lib.ZSTD_decompressStream(dstream, out_buffer, in_buffer)
if lib.ZSTD_isError(zresult):
raise ZstdError('zstd decompress error: %s' %
ffi.string(lib.ZSTD_getErrorName(zresult)))
if out_buffer.pos:
self._writer.write(ffi.buffer(out_buffer.dst, out_buffer.pos)[:])
total_write += out_buffer.pos
out_buffer.pos = 0
return total_write
class ZstdDecompressor(object):
def __init__(self, dict_data=None):
self._dict_data = dict_data
dctx = lib.ZSTD_createDCtx()
if dctx == ffi.NULL:
raise MemoryError()
self._refdctx = ffi.gc(dctx, lib.ZSTD_freeDCtx)
self._dstream = None
@property
def _ddict(self):
if self._dict_data:
dict_data = self._dict_data.as_bytes()
dict_size = len(self._dict_data)
ddict = lib.ZSTD_createDDict(dict_data, dict_size)
if ddict == ffi.NULL:
raise ZstdError('could not create decompression dict')
else:
ddict = None
self.__dict__['_ddict'] = ddict
return ddict
def decompress(self, data, max_output_size=0):
data_buffer = ffi.from_buffer(data)
orig_dctx = new_nonzero('char[]', lib.ZSTD_sizeof_DCtx(self._refdctx))
dctx = ffi.cast('ZSTD_DCtx *', orig_dctx)
lib.ZSTD_copyDCtx(dctx, self._refdctx)
ddict = self._ddict
output_size = lib.ZSTD_getDecompressedSize(data_buffer, len(data_buffer))
if output_size:
result_buffer = ffi.new('char[]', output_size)
result_size = output_size
else:
if not max_output_size:
raise ZstdError('input data invalid or missing content size '
'in frame header')
result_buffer = ffi.new('char[]', max_output_size)
result_size = max_output_size
if ddict:
zresult = lib.ZSTD_decompress_usingDDict(dctx,
result_buffer, result_size,
data_buffer, len(data_buffer),
ddict)
else:
zresult = lib.ZSTD_decompressDCtx(dctx,
result_buffer, result_size,
data_buffer, len(data_buffer))
if lib.ZSTD_isError(zresult):
raise ZstdError('decompression error: %s' %
ffi.string(lib.ZSTD_getErrorName(zresult)))
elif output_size and zresult != output_size:
raise ZstdError('decompression error: decompressed %d bytes; expected %d' %
(zresult, output_size))
return ffi.buffer(result_buffer, zresult)[:]
def decompressobj(self):
self._ensure_dstream()
return ZstdDecompressionObj(self)
def read_from(self, reader, read_size=DECOMPRESSION_RECOMMENDED_INPUT_SIZE,
write_size=DECOMPRESSION_RECOMMENDED_OUTPUT_SIZE,
skip_bytes=0):
if skip_bytes >= read_size:
raise ValueError('skip_bytes must be smaller than read_size')
if hasattr(reader, 'read'):
have_read = True
elif hasattr(reader, '__getitem__'):
have_read = False
buffer_offset = 0
size = len(reader)
else:
raise ValueError('must pass an object with a read() method or '
'conforms to buffer protocol')
if skip_bytes:
if have_read:
reader.read(skip_bytes)
else:
if skip_bytes > size:
raise ValueError('skip_bytes larger than first input chunk')
buffer_offset = skip_bytes
self._ensure_dstream()
in_buffer = ffi.new('ZSTD_inBuffer *')
out_buffer = ffi.new('ZSTD_outBuffer *')
dst_buffer = ffi.new('char[]', write_size)
out_buffer.dst = dst_buffer
out_buffer.size = len(dst_buffer)
out_buffer.pos = 0
while True:
assert out_buffer.pos == 0
if have_read:
read_result = reader.read(read_size)
else:
remaining = size - buffer_offset
slice_size = min(remaining, read_size)
read_result = reader[buffer_offset:buffer_offset + slice_size]
buffer_offset += slice_size
# No new input. Break out of read loop.
if not read_result:
break
# Feed all read data into decompressor and emit output until
# exhausted.
read_buffer = ffi.from_buffer(read_result)
in_buffer.src = read_buffer
in_buffer.size = len(read_buffer)
in_buffer.pos = 0
while in_buffer.pos < in_buffer.size:
assert out_buffer.pos == 0
zresult = lib.ZSTD_decompressStream(self._dstream, out_buffer, in_buffer)
if lib.ZSTD_isError(zresult):
raise ZstdError('zstd decompress error: %s' %
ffi.string(lib.ZSTD_getErrorName(zresult)))
if out_buffer.pos:
data = ffi.buffer(out_buffer.dst, out_buffer.pos)[:]
out_buffer.pos = 0
yield data
if zresult == 0:
return
# Repeat loop to collect more input data.
continue
# If we get here, input is exhausted.
def write_to(self, writer, write_size=DECOMPRESSION_RECOMMENDED_OUTPUT_SIZE):
if not hasattr(writer, 'write'):
raise ValueError('must pass an object with a write() method')
return ZstdDecompressionWriter(self, writer, write_size)
def copy_stream(self, ifh, ofh,
read_size=DECOMPRESSION_RECOMMENDED_INPUT_SIZE,
write_size=DECOMPRESSION_RECOMMENDED_OUTPUT_SIZE):
if not hasattr(ifh, 'read'):
raise ValueError('first argument must have a read() method')
if not hasattr(ofh, 'write'):
raise ValueError('second argument must have a write() method')
self._ensure_dstream()
in_buffer = ffi.new('ZSTD_inBuffer *')
out_buffer = ffi.new('ZSTD_outBuffer *')
dst_buffer = ffi.new('char[]', write_size)
out_buffer.dst = dst_buffer
out_buffer.size = write_size
out_buffer.pos = 0
total_read, total_write = 0, 0
# Read all available input.
while True:
data = ifh.read(read_size)
if not data:
break
data_buffer = ffi.from_buffer(data)
total_read += len(data_buffer)
in_buffer.src = data_buffer
in_buffer.size = len(data_buffer)
in_buffer.pos = 0
# Flush all read data to output.
while in_buffer.pos < in_buffer.size:
zresult = lib.ZSTD_decompressStream(self._dstream, out_buffer, in_buffer)
if lib.ZSTD_isError(zresult):
raise ZstdError('zstd decompressor error: %s' %
ffi.string(lib.ZSTD_getErrorName(zresult)))
if out_buffer.pos:
ofh.write(ffi.buffer(out_buffer.dst, out_buffer.pos))
total_write += out_buffer.pos
out_buffer.pos = 0
# Continue loop to keep reading.
return total_read, total_write
def decompress_content_dict_chain(self, frames):
if not isinstance(frames, list):
raise TypeError('argument must be a list')
if not frames:
raise ValueError('empty input chain')
# First chunk should not be using a dictionary. We handle it specially.
chunk = frames[0]
if not isinstance(chunk, bytes_type):
raise ValueError('chunk 0 must be bytes')
# All chunks should be zstd frames and should have content size set.
chunk_buffer = ffi.from_buffer(chunk)
params = ffi.new('ZSTD_frameParams *')
zresult = lib.ZSTD_getFrameParams(params, chunk_buffer, len(chunk_buffer))
if lib.ZSTD_isError(zresult):
raise ValueError('chunk 0 is not a valid zstd frame')
elif zresult:
raise ValueError('chunk 0 is too small to contain a zstd frame')
if not params.frameContentSize:
raise ValueError('chunk 0 missing content size in frame')
dctx = lib.ZSTD_createDCtx()
if dctx == ffi.NULL:
raise MemoryError()
dctx = ffi.gc(dctx, lib.ZSTD_freeDCtx)
last_buffer = ffi.new('char[]', params.frameContentSize)
zresult = lib.ZSTD_decompressDCtx(dctx, last_buffer, len(last_buffer),
chunk_buffer, len(chunk_buffer))
if lib.ZSTD_isError(zresult):
raise ZstdError('could not decompress chunk 0: %s' %
ffi.string(lib.ZSTD_getErrorName(zresult)))
# Special case of chain length of 1
if len(frames) == 1:
return ffi.buffer(last_buffer, len(last_buffer))[:]
i = 1
while i < len(frames):
chunk = frames[i]
if not isinstance(chunk, bytes_type):
raise ValueError('chunk %d must be bytes' % i)
chunk_buffer = ffi.from_buffer(chunk)
zresult = lib.ZSTD_getFrameParams(params, chunk_buffer, len(chunk_buffer))
if lib.ZSTD_isError(zresult):
raise ValueError('chunk %d is not a valid zstd frame' % i)
elif zresult:
raise ValueError('chunk %d is too small to contain a zstd frame' % i)
if not params.frameContentSize:
raise ValueError('chunk %d missing content size in frame' % i)
dest_buffer = ffi.new('char[]', params.frameContentSize)
zresult = lib.ZSTD_decompress_usingDict(dctx, dest_buffer, len(dest_buffer),
chunk_buffer, len(chunk_buffer),
last_buffer, len(last_buffer))
if lib.ZSTD_isError(zresult):
raise ZstdError('could not decompress chunk %d' % i)
last_buffer = dest_buffer
i += 1
return ffi.buffer(last_buffer, len(last_buffer))[:]
def _ensure_dstream(self):
if self._dstream:
zresult = lib.ZSTD_resetDStream(self._dstream)
if lib.ZSTD_isError(zresult):
raise ZstdError('could not reset DStream: %s' %
ffi.string(lib.ZSTD_getErrorName(zresult)))
return
self._dstream = lib.ZSTD_createDStream()
if self._dstream == ffi.NULL:
raise MemoryError()
self._dstream = ffi.gc(self._dstream, lib.ZSTD_freeDStream)
if self._dict_data:
zresult = lib.ZSTD_initDStream_usingDict(self._dstream,
self._dict_data.as_bytes(),
len(self._dict_data))
else:
zresult = lib.ZSTD_initDStream(self._dstream)
if lib.ZSTD_isError(zresult):
self._dstream = None
raise ZstdError('could not initialize DStream: %s' %
ffi.string(lib.ZSTD_getErrorName(zresult)))