Mercurial > hg
view hgext/fsmonitor/pywatchman/pybser.py @ 42783:c8d3af9c7e65
perf: handle NameError for `pycompat.foo` when pycompat wasn't imported
On old Mercurial versions, we won't have a pycompat variable defined,
and then `pycompat.foo` will raise a NameError.
Differential Revision: https://phab.mercurial-scm.org/D6743
author | Martin von Zweigbergk <martinvonz@google.com> |
---|---|
date | Mon, 19 Aug 2019 10:38:38 -0700 |
parents | 876494fd967d |
children | 6469c23a40a2 |
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# Copyright 2015 Facebook, Inc. # All rights reserved. # # Redistribution and use in source and binary forms, with or without # modification, are permitted provided that the following conditions are met: # # * Redistributions of source code must retain the above copyright notice, # this list of conditions and the following disclaimer. # # * Redistributions in binary form must reproduce the above copyright notice, # this list of conditions and the following disclaimer in the documentation # and/or other materials provided with the distribution. # # * Neither the name Facebook nor the names of its contributors may be used to # endorse or promote products derived from this software without specific # prior written permission. # # THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" # AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE # IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE # DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE # FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL # DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR # SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER # CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, # OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE # OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. from __future__ import absolute_import from __future__ import division from __future__ import print_function # no unicode literals import binascii import collections import ctypes import struct import sys from . import ( compat, ) BSER_ARRAY = b'\x00' BSER_OBJECT = b'\x01' BSER_BYTESTRING = b'\x02' BSER_INT8 = b'\x03' BSER_INT16 = b'\x04' BSER_INT32 = b'\x05' BSER_INT64 = b'\x06' BSER_REAL = b'\x07' BSER_TRUE = b'\x08' BSER_FALSE = b'\x09' BSER_NULL = b'\x0a' BSER_TEMPLATE = b'\x0b' BSER_SKIP = b'\x0c' BSER_UTF8STRING = b'\x0d' if compat.PYTHON3: STRING_TYPES = (str, bytes) unicode = str def tobytes(i): return str(i).encode('ascii') long = int else: STRING_TYPES = (unicode, str) tobytes = bytes # Leave room for the serialization header, which includes # our overall length. To make things simpler, we'll use an # int32 for the header EMPTY_HEADER = b"\x00\x01\x05\x00\x00\x00\x00" EMPTY_HEADER_V2 = b"\x00\x02\x00\x00\x00\x00\x05\x00\x00\x00\x00" def _int_size(x): """Return the smallest size int that can store the value""" if -0x80 <= x <= 0x7F: return 1 elif -0x8000 <= x <= 0x7FFF: return 2 elif -0x80000000 <= x <= 0x7FFFFFFF: return 4 elif long(-0x8000000000000000) <= x <= long(0x7FFFFFFFFFFFFFFF): return 8 else: raise RuntimeError('Cannot represent value: ' + str(x)) def _buf_pos(buf, pos): ret = buf[pos] # In Python 2, buf is a str array so buf[pos] is a string. In Python 3, buf # is a bytes array and buf[pos] is an integer. if compat.PYTHON3: ret = bytes((ret,)) return ret class _bser_buffer(object): def __init__(self, version): self.bser_version = version self.buf = ctypes.create_string_buffer(8192) if self.bser_version == 1: struct.pack_into(tobytes(len(EMPTY_HEADER)) + b's', self.buf, 0, EMPTY_HEADER) self.wpos = len(EMPTY_HEADER) else: assert self.bser_version == 2 struct.pack_into(tobytes(len(EMPTY_HEADER_V2)) + b's', self.buf, 0, EMPTY_HEADER_V2) self.wpos = len(EMPTY_HEADER_V2) def ensure_size(self, size): while ctypes.sizeof(self.buf) - self.wpos < size: ctypes.resize(self.buf, ctypes.sizeof(self.buf) * 2) def append_long(self, val): size = _int_size(val) to_write = size + 1 self.ensure_size(to_write) if size == 1: struct.pack_into(b'=cb', self.buf, self.wpos, BSER_INT8, val) elif size == 2: struct.pack_into(b'=ch', self.buf, self.wpos, BSER_INT16, val) elif size == 4: struct.pack_into(b'=ci', self.buf, self.wpos, BSER_INT32, val) elif size == 8: struct.pack_into(b'=cq', self.buf, self.wpos, BSER_INT64, val) else: raise RuntimeError('Cannot represent this long value') self.wpos += to_write def append_string(self, s): if isinstance(s, unicode): s = s.encode('utf-8') s_len = len(s) size = _int_size(s_len) to_write = 2 + size + s_len self.ensure_size(to_write) if size == 1: struct.pack_into(b'=ccb' + tobytes(s_len) + b's', self.buf, self.wpos, BSER_BYTESTRING, BSER_INT8, s_len, s) elif size == 2: struct.pack_into(b'=cch' + tobytes(s_len) + b's', self.buf, self.wpos, BSER_BYTESTRING, BSER_INT16, s_len, s) elif size == 4: struct.pack_into(b'=cci' + tobytes(s_len) + b's', self.buf, self.wpos, BSER_BYTESTRING, BSER_INT32, s_len, s) elif size == 8: struct.pack_into(b'=ccq' + tobytes(s_len) + b's', self.buf, self.wpos, BSER_BYTESTRING, BSER_INT64, s_len, s) else: raise RuntimeError('Cannot represent this string value') self.wpos += to_write def append_recursive(self, val): if isinstance(val, bool): needed = 1 self.ensure_size(needed) if val: to_encode = BSER_TRUE else: to_encode = BSER_FALSE struct.pack_into(b'=c', self.buf, self.wpos, to_encode) self.wpos += needed elif val is None: needed = 1 self.ensure_size(needed) struct.pack_into(b'=c', self.buf, self.wpos, BSER_NULL) self.wpos += needed elif isinstance(val, (int, long)): self.append_long(val) elif isinstance(val, STRING_TYPES): self.append_string(val) elif isinstance(val, float): needed = 9 self.ensure_size(needed) struct.pack_into(b'=cd', self.buf, self.wpos, BSER_REAL, val) self.wpos += needed elif isinstance(val, collections.Mapping) and \ isinstance(val, collections.Sized): val_len = len(val) size = _int_size(val_len) needed = 2 + size self.ensure_size(needed) if size == 1: struct.pack_into(b'=ccb', self.buf, self.wpos, BSER_OBJECT, BSER_INT8, val_len) elif size == 2: struct.pack_into(b'=cch', self.buf, self.wpos, BSER_OBJECT, BSER_INT16, val_len) elif size == 4: struct.pack_into(b'=cci', self.buf, self.wpos, BSER_OBJECT, BSER_INT32, val_len) elif size == 8: struct.pack_into(b'=ccq', self.buf, self.wpos, BSER_OBJECT, BSER_INT64, val_len) else: raise RuntimeError('Cannot represent this mapping value') self.wpos += needed if compat.PYTHON3: iteritems = val.items() else: iteritems = val.iteritems() for k, v in iteritems: self.append_string(k) self.append_recursive(v) elif isinstance(val, collections.Iterable) and \ isinstance(val, collections.Sized): val_len = len(val) size = _int_size(val_len) needed = 2 + size self.ensure_size(needed) if size == 1: struct.pack_into(b'=ccb', self.buf, self.wpos, BSER_ARRAY, BSER_INT8, val_len) elif size == 2: struct.pack_into(b'=cch', self.buf, self.wpos, BSER_ARRAY, BSER_INT16, val_len) elif size == 4: struct.pack_into(b'=cci', self.buf, self.wpos, BSER_ARRAY, BSER_INT32, val_len) elif size == 8: struct.pack_into(b'=ccq', self.buf, self.wpos, BSER_ARRAY, BSER_INT64, val_len) else: raise RuntimeError('Cannot represent this sequence value') self.wpos += needed for v in val: self.append_recursive(v) else: raise RuntimeError('Cannot represent unknown value type') def dumps(obj, version=1, capabilities=0): bser_buf = _bser_buffer(version=version) bser_buf.append_recursive(obj) # Now fill in the overall length if version == 1: obj_len = bser_buf.wpos - len(EMPTY_HEADER) struct.pack_into(b'=i', bser_buf.buf, 3, obj_len) else: obj_len = bser_buf.wpos - len(EMPTY_HEADER_V2) struct.pack_into(b'=i', bser_buf.buf, 2, capabilities) struct.pack_into(b'=i', bser_buf.buf, 7, obj_len) return bser_buf.buf.raw[:bser_buf.wpos] # This is a quack-alike with the bserObjectType in bser.c # It provides by getattr accessors and getitem for both index # and name. class _BunserDict(object): __slots__ = ('_keys', '_values') def __init__(self, keys, values): self._keys = keys self._values = values def __getattr__(self, name): return self.__getitem__(name) def __getitem__(self, key): if isinstance(key, (int, long)): return self._values[key] elif key.startswith('st_'): # hack^Wfeature to allow mercurial to use "st_size" to # reference "size" key = key[3:] try: return self._values[self._keys.index(key)] except ValueError: raise KeyError('_BunserDict has no key %s' % key) def __len__(self): return len(self._keys) class Bunser(object): def __init__(self, mutable=True, value_encoding=None, value_errors=None): self.mutable = mutable self.value_encoding = value_encoding if value_encoding is None: self.value_errors = None elif value_errors is None: self.value_errors = 'strict' else: self.value_errors = value_errors @staticmethod def unser_int(buf, pos): try: int_type = _buf_pos(buf, pos) except IndexError: raise ValueError('Invalid bser int encoding, pos out of range') if int_type == BSER_INT8: needed = 2 fmt = b'=b' elif int_type == BSER_INT16: needed = 3 fmt = b'=h' elif int_type == BSER_INT32: needed = 5 fmt = b'=i' elif int_type == BSER_INT64: needed = 9 fmt = b'=q' else: raise ValueError('Invalid bser int encoding 0x%s' % binascii.hexlify(int_type).decode('ascii')) int_val = struct.unpack_from(fmt, buf, pos + 1)[0] return (int_val, pos + needed) def unser_utf8_string(self, buf, pos): str_len, pos = self.unser_int(buf, pos + 1) str_val = struct.unpack_from(tobytes(str_len) + b's', buf, pos)[0] return (str_val.decode('utf-8'), pos + str_len) def unser_bytestring(self, buf, pos): str_len, pos = self.unser_int(buf, pos + 1) str_val = struct.unpack_from(tobytes(str_len) + b's', buf, pos)[0] if self.value_encoding is not None: str_val = str_val.decode(self.value_encoding, self.value_errors) # str_len stays the same because that's the length in bytes return (str_val, pos + str_len) def unser_array(self, buf, pos): arr_len, pos = self.unser_int(buf, pos + 1) arr = [] for i in range(arr_len): arr_item, pos = self.loads_recursive(buf, pos) arr.append(arr_item) if not self.mutable: arr = tuple(arr) return arr, pos def unser_object(self, buf, pos): obj_len, pos = self.unser_int(buf, pos + 1) if self.mutable: obj = {} else: keys = [] vals = [] for i in range(obj_len): key, pos = self.unser_utf8_string(buf, pos) val, pos = self.loads_recursive(buf, pos) if self.mutable: obj[key] = val else: keys.append(key) vals.append(val) if not self.mutable: obj = _BunserDict(keys, vals) return obj, pos def unser_template(self, buf, pos): val_type = _buf_pos(buf, pos + 1) if val_type != BSER_ARRAY: raise RuntimeError('Expect ARRAY to follow TEMPLATE') # force UTF-8 on keys keys_bunser = Bunser(mutable=self.mutable, value_encoding='utf-8') keys, pos = keys_bunser.unser_array(buf, pos + 1) nitems, pos = self.unser_int(buf, pos) arr = [] for i in range(nitems): if self.mutable: obj = {} else: vals = [] for keyidx in range(len(keys)): if _buf_pos(buf, pos) == BSER_SKIP: pos += 1 ele = None else: ele, pos = self.loads_recursive(buf, pos) if self.mutable: key = keys[keyidx] obj[key] = ele else: vals.append(ele) if not self.mutable: obj = _BunserDict(keys, vals) arr.append(obj) return arr, pos def loads_recursive(self, buf, pos): val_type = _buf_pos(buf, pos) if (val_type == BSER_INT8 or val_type == BSER_INT16 or val_type == BSER_INT32 or val_type == BSER_INT64): return self.unser_int(buf, pos) elif val_type == BSER_REAL: val = struct.unpack_from(b'=d', buf, pos + 1)[0] return (val, pos + 9) elif val_type == BSER_TRUE: return (True, pos + 1) elif val_type == BSER_FALSE: return (False, pos + 1) elif val_type == BSER_NULL: return (None, pos + 1) elif val_type == BSER_BYTESTRING: return self.unser_bytestring(buf, pos) elif val_type == BSER_UTF8STRING: return self.unser_utf8_string(buf, pos) elif val_type == BSER_ARRAY: return self.unser_array(buf, pos) elif val_type == BSER_OBJECT: return self.unser_object(buf, pos) elif val_type == BSER_TEMPLATE: return self.unser_template(buf, pos) else: raise ValueError('unhandled bser opcode 0x%s' % binascii.hexlify(val_type).decode('ascii')) def _pdu_info_helper(buf): if buf[0:2] == EMPTY_HEADER[0:2]: bser_version = 1 bser_capabilities = 0 expected_len, pos2 = Bunser.unser_int(buf, 2) elif buf[0:2] == EMPTY_HEADER_V2[0:2]: if len(buf) < 8: raise ValueError('Invalid BSER header') bser_version = 2 bser_capabilities = struct.unpack_from("I", buf, 2)[0] expected_len, pos2 = Bunser.unser_int(buf, 6) else: raise ValueError('Invalid BSER header') return bser_version, bser_capabilities, expected_len, pos2 def pdu_info(buf): info = _pdu_info_helper(buf) return info[0], info[1], info[2] + info[3] def pdu_len(buf): info = _pdu_info_helper(buf) return info[2] + info[3] def loads(buf, mutable=True, value_encoding=None, value_errors=None): """Deserialize a BSER-encoded blob. @param buf: The buffer to deserialize. @type buf: bytes @param mutable: Whether to return mutable results. @type mutable: bool @param value_encoding: Optional codec to use to decode values. If unspecified or None, return values as bytestrings. @type value_encoding: str @param value_errors: Optional error handler for codec. 'strict' by default. The other most common argument is 'surrogateescape' on Python 3. If value_encoding is None, this is ignored. @type value_errors: str """ info = _pdu_info_helper(buf) expected_len = info[2] pos = info[3] if len(buf) != expected_len + pos: raise ValueError('bser data len != header len') bunser = Bunser(mutable=mutable, value_encoding=value_encoding, value_errors=value_errors) return bunser.loads_recursive(buf, pos)[0] def load(fp, mutable=True, value_encoding=None, value_errors=None): from . import load return load.load(fp, mutable, value_encoding, value_errors)