pager: do not start pager if `ui` has been `pushbuffer`-ed
The `pushbuffer`, `popbuffer` APIs are intended to capture internal output.
They will prevent `ui.write` from writing to the actual `ui.fout`. So a
pager won't receive the output and do the right thing. In general, it does
not make sense to start a pager if ui is in the "pushbuffer" mode.
Differential Revision: https://phab.mercurial-scm.org/D574
# 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)))