"""biplist -- a library for reading and writing binary property list files. Binary Property List (plist) files provide a faster and smaller serialization format for property lists on OS X. This is a library for generating binary plists which can be read by OS X, iOS, or other clients. The API models the plistlib API, and will call through to plistlib when XML serialization or deserialization is required. To generate plists with UID values, wrap the values with the Uid object. The value must be an int. To generate plists with NSData/CFData values, wrap the values with the Data object. The value must be a string. Date values can only be datetime.datetime objects. The exceptions InvalidPlistException and NotBinaryPlistException may be thrown to indicate that the data cannot be serialized or deserialized as a binary plist. Plist generation example: from biplist import * from datetime import datetime plist = {'aKey':'aValue', '0':1.322, 'now':datetime.now(), 'list':[1,2,3], 'tuple':('a','b','c') } try: writePlist(plist, "example.plist") except (InvalidPlistException, NotBinaryPlistException), e: print "Something bad happened:", e Plist parsing example: from biplist import * try: plist = readPlist("example.plist") print plist except (InvalidPlistException, NotBinaryPlistException), e: print "Not a plist:", e """ from collections import namedtuple import datetime import io import math import plistlib from struct import pack, unpack, unpack_from from struct import error as struct_error import sys import time try: unicode unicodeEmpty = r'' except NameError: unicode = str unicodeEmpty = '' try: long except NameError: long = int try: {}.iteritems iteritems = lambda x: x.iteritems() except AttributeError: iteritems = lambda x: x.items() __all__ = [ 'Uid', 'Data', 'readPlist', 'writePlist', 'readPlistFromString', 'writePlistToString', 'InvalidPlistException', 'NotBinaryPlistException' ] # Apple uses Jan 1, 2001 as a base for all plist date/times. apple_reference_date = datetime.datetime.utcfromtimestamp(978307200) class Uid(object): """Wrapper around integers for representing UID values. This is used in keyed archiving.""" integer = 0 def __init__(self, integer): self.integer = integer def __repr__(self): return "Uid(%d)" % self.integer def __eq__(self, other): if isinstance(self, Uid) and isinstance(other, Uid): return self.integer == other.integer return False def __cmp__(self, other): return self.integer - other.integer def __lt__(self, other): return self.integer < other.integer def __hash__(self): return self.integer def __int__(self): return int(self.integer) class Data(bytes): """Wrapper around bytes to distinguish Data values.""" class InvalidPlistException(Exception): """Raised when the plist is incorrectly formatted.""" class NotBinaryPlistException(Exception): """Raised when a binary plist was expected but not encountered.""" def readPlist(pathOrFile): """Raises NotBinaryPlistException, InvalidPlistException""" didOpen = False result = None if isinstance(pathOrFile, (bytes, unicode)): pathOrFile = open(pathOrFile, 'rb') didOpen = True try: reader = PlistReader(pathOrFile) result = reader.parse() except NotBinaryPlistException as e: try: pathOrFile.seek(0) result = None if hasattr(plistlib, 'loads'): contents = None if isinstance(pathOrFile, (bytes, unicode)): with open(pathOrFile, 'rb') as f: contents = f.read() else: contents = pathOrFile.read() result = plistlib.loads(contents) else: result = plistlib.readPlist(pathOrFile) result = wrapDataObject(result, for_binary=True) except Exception as e: raise InvalidPlistException(e) finally: if didOpen: pathOrFile.close() return result def wrapDataObject(o, for_binary=False): if isinstance(o, Data) and not for_binary: v = sys.version_info if not (v[0] >= 3 and v[1] >= 4): o = plistlib.Data(o) elif isinstance(o, (bytes, plistlib.Data)) and for_binary: if hasattr(o, 'data'): o = Data(o.data) elif isinstance(o, tuple): o = wrapDataObject(list(o), for_binary) o = tuple(o) elif isinstance(o, list): for i in range(len(o)): o[i] = wrapDataObject(o[i], for_binary) elif isinstance(o, dict): for k in o: o[k] = wrapDataObject(o[k], for_binary) return o def writePlist(rootObject, pathOrFile, binary=True): if not binary: rootObject = wrapDataObject(rootObject, binary) if hasattr(plistlib, "dump"): if isinstance(pathOrFile, (bytes, unicode)): with open(pathOrFile, 'wb') as f: return plistlib.dump(rootObject, f) else: return plistlib.dump(rootObject, pathOrFile) else: return plistlib.writePlist(rootObject, pathOrFile) else: didOpen = False if isinstance(pathOrFile, (bytes, unicode)): pathOrFile = open(pathOrFile, 'wb') didOpen = True writer = PlistWriter(pathOrFile) result = writer.writeRoot(rootObject) if didOpen: pathOrFile.close() return result def readPlistFromString(data): return readPlist(io.BytesIO(data)) def writePlistToString(rootObject, binary=True): if not binary: rootObject = wrapDataObject(rootObject, binary) if hasattr(plistlib, "dumps"): return plistlib.dumps(rootObject) elif hasattr(plistlib, "writePlistToBytes"): return plistlib.writePlistToBytes(rootObject) else: return plistlib.writePlistToString(rootObject) else: ioObject = io.BytesIO() writer = PlistWriter(ioObject) writer.writeRoot(rootObject) return ioObject.getvalue() def is_stream_binary_plist(stream): stream.seek(0) header = stream.read(7) if header == b'bplist0': return True else: return False PlistTrailer = namedtuple('PlistTrailer', 'offsetSize, objectRefSize, offsetCount, topLevelObjectNumber, offsetTableOffset') PlistByteCounts = namedtuple('PlistByteCounts', 'nullBytes, boolBytes, intBytes, realBytes, dateBytes, dataBytes, stringBytes, uidBytes, arrayBytes, setBytes, dictBytes') class PlistReader(object): file = None contents = '' offsets = None trailer = None currentOffset = 0 # Used to detect recursive object references. offsetsStack = [] def __init__(self, fileOrStream): """Raises NotBinaryPlistException.""" self.reset() self.file = fileOrStream def parse(self): return self.readRoot() def reset(self): self.trailer = None self.contents = '' self.offsets = [] self.currentOffset = 0 self.offsetsStack = [] def readRoot(self): result = None self.reset() # Get the header, make sure it's a valid file. if not is_stream_binary_plist(self.file): raise NotBinaryPlistException() self.file.seek(0) self.contents = self.file.read() if len(self.contents) < 32: raise InvalidPlistException("File is too short.") trailerContents = self.contents[-32:] try: self.trailer = PlistTrailer._make(unpack("!xxxxxxBBQQQ", trailerContents)) if pow(2, self.trailer.offsetSize*8) < self.trailer.offsetTableOffset: raise InvalidPlistException("Offset size insufficient to reference all objects.") if pow(2, self.trailer.objectRefSize*8) < self.trailer.offsetCount: raise InvalidPlistException("Too many offsets to represent in size of object reference representation.") offset_size = self.trailer.offsetSize * self.trailer.offsetCount offset = self.trailer.offsetTableOffset if offset + offset_size > pow(2, 64): raise InvalidPlistException("Offset table is excessively long.") if self.trailer.offsetSize > 16: raise InvalidPlistException("Offset size is greater than maximum integer size.") if self.trailer.objectRefSize == 0: raise InvalidPlistException("Object reference size is zero.") if offset >= len(self.contents) - 32: raise InvalidPlistException("Offset table offset is too large.") if offset < len("bplist00x"): raise InvalidPlistException("Offset table offset is too small.") if self.trailer.topLevelObjectNumber >= self.trailer.offsetCount: raise InvalidPlistException("Top level object number is larger than the number of objects.") offset_contents = self.contents[offset:offset+offset_size] offset_i = 0 offset_table_length = len(offset_contents) while offset_i < self.trailer.offsetCount: begin = self.trailer.offsetSize*offset_i end = begin+self.trailer.offsetSize if end > offset_table_length: raise InvalidPlistException("End of object is at invalid offset %d in offset table of length %d" % (end, offset_table_length)) tmp_contents = offset_contents[begin:end] tmp_sized = self.getSizedInteger(tmp_contents, self.trailer.offsetSize) self.offsets.append(tmp_sized) offset_i += 1 self.setCurrentOffsetToObjectNumber(self.trailer.topLevelObjectNumber) result = self.readObject() except TypeError as e: raise InvalidPlistException(e) return result def setCurrentOffsetToObjectNumber(self, objectNumber): if objectNumber > len(self.offsets) - 1: raise InvalidPlistException("Invalid offset number: %d" % objectNumber) self.currentOffset = self.offsets[objectNumber] if self.currentOffset in self.offsetsStack: raise InvalidPlistException("Recursive data structure detected in object: %d" % objectNumber) def beginOffsetProtection(self): self.offsetsStack.append(self.currentOffset) return self.currentOffset def endOffsetProtection(self, offset): try: index = self.offsetsStack.index(offset) self.offsetsStack = self.offsetsStack[:index] except ValueError as e: pass def readObject(self): protection = self.beginOffsetProtection() result = None tmp_byte = self.contents[self.currentOffset:self.currentOffset+1] if len(tmp_byte) != 1: raise InvalidPlistException("No object found at offset: %d" % self.currentOffset) marker_byte = unpack("!B", tmp_byte)[0] format = (marker_byte >> 4) & 0x0f extra = marker_byte & 0x0f self.currentOffset += 1 def proc_extra(extra): if extra == 0b1111: extra = self.readObject() return extra # bool, null, or fill byte if format == 0b0000: if extra == 0b0000: result = None elif extra == 0b1000: result = False elif extra == 0b1001: result = True elif extra == 0b1111: pass # fill byte else: raise InvalidPlistException("Invalid object found at offset: %d" % (self.currentOffset - 1)) # int elif format == 0b0001: result = self.readInteger(pow(2, extra)) # real elif format == 0b0010: result = self.readReal(extra) # date elif format == 0b0011 and extra == 0b0011: result = self.readDate() # data elif format == 0b0100: extra = proc_extra(extra) result = self.readData(extra) # ascii string elif format == 0b0101: extra = proc_extra(extra) result = self.readAsciiString(extra) # Unicode string elif format == 0b0110: extra = proc_extra(extra) result = self.readUnicode(extra) # uid elif format == 0b1000: result = self.readUid(extra) # array elif format == 0b1010: extra = proc_extra(extra) result = self.readArray(extra) # set elif format == 0b1100: extra = proc_extra(extra) result = set(self.readArray(extra)) # dict elif format == 0b1101: extra = proc_extra(extra) result = self.readDict(extra) else: raise InvalidPlistException("Invalid object found: {format: %s, extra: %s}" % (bin(format), bin(extra))) self.endOffsetProtection(protection) return result def readContents(self, length, description="Object contents"): end = self.currentOffset + length if end >= len(self.contents) - 32: raise InvalidPlistException("%s extends into trailer" % description) elif length < 0: raise InvalidPlistException("%s length is less than zero" % length) data = self.contents[self.currentOffset:end] return data def readInteger(self, byteSize): data = self.readContents(byteSize, "Integer") self.currentOffset = self.currentOffset + byteSize return self.getSizedInteger(data, byteSize, as_number=True) def readReal(self, length): to_read = pow(2, length) data = self.readContents(to_read, "Real") if length == 2: # 4 bytes result = unpack('>f', data)[0] elif length == 3: # 8 bytes result = unpack('>d', data)[0] else: raise InvalidPlistException("Unknown Real of length %d bytes" % to_read) return result def readRefs(self, count): refs = [] i = 0 while i < count: fragment = self.readContents(self.trailer.objectRefSize, "Object reference") ref = self.getSizedInteger(fragment, len(fragment)) refs.append(ref) self.currentOffset += self.trailer.objectRefSize i += 1 return refs def readArray(self, count): if not isinstance(count, (int, long)): raise InvalidPlistException("Count of entries in dict isn't of integer type.") result = [] values = self.readRefs(count) i = 0 while i < len(values): self.setCurrentOffsetToObjectNumber(values[i]) value = self.readObject() result.append(value) i += 1 return result def readDict(self, count): if not isinstance(count, (int, long)): raise InvalidPlistException("Count of keys/values in dict isn't of integer type.") result = {} keys = self.readRefs(count) values = self.readRefs(count) i = 0 while i < len(keys): self.setCurrentOffsetToObjectNumber(keys[i]) key = self.readObject() self.setCurrentOffsetToObjectNumber(values[i]) value = self.readObject() result[key] = value i += 1 return result def readAsciiString(self, length): if not isinstance(length, (int, long)): raise InvalidPlistException("Length of ASCII string isn't of integer type.") data = self.readContents(length, "ASCII string") result = unpack("!%ds" % length, data)[0] self.currentOffset += length return str(result.decode('ascii')) def readUnicode(self, length): if not isinstance(length, (int, long)): raise InvalidPlistException("Length of Unicode string isn't of integer type.") actual_length = length*2 data = self.readContents(actual_length, "Unicode string") self.currentOffset += actual_length return data.decode('utf_16_be') def readDate(self): data = self.readContents(8, "Date") x = unpack(">d", data)[0] if math.isnan(x): raise InvalidPlistException("Date is NaN") # Use timedelta to workaround time_t size limitation on 32-bit python. try: result = datetime.timedelta(seconds=x) + apple_reference_date except OverflowError: if x > 0: result = datetime.datetime.max else: result = datetime.datetime.min self.currentOffset += 8 return result def readData(self, length): if not isinstance(length, (int, long)): raise InvalidPlistException("Length of data isn't of integer type.") result = self.readContents(length, "Data") self.currentOffset += length return Data(result) def readUid(self, length): if not isinstance(length, (int, long)): raise InvalidPlistException("Uid length isn't of integer type.") return Uid(self.readInteger(length+1)) def getSizedInteger(self, data, byteSize, as_number=False): """Numbers of 8 bytes are signed integers when they refer to numbers, but unsigned otherwise.""" result = 0 if byteSize == 0: raise InvalidPlistException("Encountered integer with byte size of 0.") # 1, 2, and 4 byte integers are unsigned elif byteSize == 1: result = unpack('>B', data)[0] elif byteSize == 2: result = unpack('>H', data)[0] elif byteSize == 4: result = unpack('>L', data)[0] elif byteSize == 8: if as_number: result = unpack('>q', data)[0] else: result = unpack('>Q', data)[0] elif byteSize <= 16: # Handle odd-sized or integers larger than 8 bytes # Don't naively go over 16 bytes, in order to prevent infinite loops. result = 0 if hasattr(int, 'from_bytes'): result = int.from_bytes(data, 'big') else: for byte in data: if not isinstance(byte, int): # Python3.0-3.1.x return ints, 2.x return str byte = unpack_from('>B', byte)[0] result = (result << 8) | byte else: raise InvalidPlistException("Encountered integer longer than 16 bytes.") return result class HashableWrapper(object): def __init__(self, value): self.value = value def __repr__(self): return "" % [self.value] class BoolWrapper(object): def __init__(self, value): self.value = value def __repr__(self): return "" % self.value class FloatWrapper(object): _instances = {} def __new__(klass, value): # Ensure FloatWrapper(x) for a given float x is always the same object wrapper = klass._instances.get(value) if wrapper is None: wrapper = object.__new__(klass) wrapper.value = value klass._instances[value] = wrapper return wrapper def __repr__(self): return "" % self.value class StringWrapper(object): __instances = {} encodedValue = None encoding = None def __new__(cls, value): '''Ensure we only have a only one instance for any string, and that we encode ascii as 1-byte-per character when possible''' encodedValue = None for encoding in ('ascii', 'utf_16_be'): try: encodedValue = value.encode(encoding) except: pass if encodedValue is not None: if encodedValue not in cls.__instances: cls.__instances[encodedValue] = super(StringWrapper, cls).__new__(cls) cls.__instances[encodedValue].encodedValue = encodedValue cls.__instances[encodedValue].encoding = encoding return cls.__instances[encodedValue] raise ValueError('Unable to get ascii or utf_16_be encoding for %s' % repr(value)) def __len__(self): '''Return roughly the number of characters in this string (half the byte length)''' if self.encoding == 'ascii': return len(self.encodedValue) else: return len(self.encodedValue)//2 def __lt__(self, other): return self.encodedValue < other.encodedValue @property def encodingMarker(self): if self.encoding == 'ascii': return 0b0101 else: return 0b0110 def __repr__(self): return '' % (self.encoding, self.encodedValue) class PlistWriter(object): header = b'bplist00bybiplist1.0' file = None byteCounts = None trailer = None computedUniques = None writtenReferences = None referencePositions = None wrappedTrue = None wrappedFalse = None # Used to detect recursive object references. objectsStack = [] def __init__(self, file): self.reset() self.file = file self.wrappedTrue = BoolWrapper(True) self.wrappedFalse = BoolWrapper(False) def reset(self): self.byteCounts = PlistByteCounts(0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0) self.trailer = PlistTrailer(0, 0, 0, 0, 0) # A set of all the uniques which have been computed. self.computedUniques = set() # A list of all the uniques which have been written. self.writtenReferences = {} # A dict of the positions of the written uniques. self.referencePositions = {} self.objectsStack = [] def positionOfObjectReference(self, obj): """If the given object has been written already, return its position in the offset table. Otherwise, return None.""" return self.writtenReferences.get(obj) def writeRoot(self, root): """ Strategy is: - write header - wrap root object so everything is hashable - compute size of objects which will be written - need to do this in order to know how large the object refs will be in the list/dict/set reference lists - write objects - keep objects in writtenReferences - keep positions of object references in referencePositions - write object references with the length computed previously - computer object reference length - write object reference positions - write trailer """ output = self.header wrapped_root = self.wrapRoot(root) self.computeOffsets(wrapped_root, asReference=True, isRoot=True) self.trailer = self.trailer._replace(**{'objectRefSize':self.intSize(len(self.computedUniques))}) self.writeObjectReference(wrapped_root, output) output = self.writeObject(wrapped_root, output, setReferencePosition=True) # output size at this point is an upper bound on how big the # object reference offsets need to be. self.trailer = self.trailer._replace(**{ 'offsetSize':self.intSize(len(output)), 'offsetCount':len(self.computedUniques), 'offsetTableOffset':len(output), 'topLevelObjectNumber':0 }) output = self.writeOffsetTable(output) output += pack('!xxxxxxBBQQQ', *self.trailer) self.file.write(output) def beginRecursionProtection(self, obj): if not isinstance(obj, (set, dict, list, tuple)): return if id(obj) in self.objectsStack: raise InvalidPlistException("Recursive containers are not allowed in plists.") self.objectsStack.append(id(obj)) def endRecursionProtection(self, obj): if not isinstance(obj, (set, dict, list, tuple)): return try: index = self.objectsStack.index(id(obj)) self.objectsStack = self.objectsStack[:index] except ValueError as e: pass def wrapRoot(self, root): result = None self.beginRecursionProtection(root) if isinstance(root, bool): if root is True: result = self.wrappedTrue else: result = self.wrappedFalse elif isinstance(root, float): result = FloatWrapper(root) elif isinstance(root, set): n = set() for value in root: n.add(self.wrapRoot(value)) result = HashableWrapper(n) elif isinstance(root, dict): n = {} for key, value in iteritems(root): n[self.wrapRoot(key)] = self.wrapRoot(value) result = HashableWrapper(n) elif isinstance(root, list): n = [] for value in root: n.append(self.wrapRoot(value)) result = HashableWrapper(n) elif isinstance(root, tuple): n = tuple([self.wrapRoot(value) for value in root]) result = HashableWrapper(n) elif isinstance(root, (str, unicode)) and not isinstance(root, Data): result = StringWrapper(root) elif isinstance(root, bytes): result = Data(root) else: result = root self.endRecursionProtection(root) return result def incrementByteCount(self, field, incr=1): self.byteCounts = self.byteCounts._replace(**{field:self.byteCounts.__getattribute__(field) + incr}) def computeOffsets(self, obj, asReference=False, isRoot=False): def check_key(key): if key is None: raise InvalidPlistException('Dictionary keys cannot be null in plists.') elif isinstance(key, Data): raise InvalidPlistException('Data cannot be dictionary keys in plists.') elif not isinstance(key, StringWrapper): raise InvalidPlistException('Keys must be strings.') def proc_size(size): if size > 0b1110: size += self.intSize(size) return size # If this should be a reference, then we keep a record of it in the # uniques table. if asReference: if obj in self.computedUniques: return else: self.computedUniques.add(obj) if obj is None: self.incrementByteCount('nullBytes') elif isinstance(obj, BoolWrapper): self.incrementByteCount('boolBytes') elif isinstance(obj, Uid): size = self.intSize(obj.integer) self.incrementByteCount('uidBytes', incr=1+size) elif isinstance(obj, (int, long)): size = self.intSize(obj) self.incrementByteCount('intBytes', incr=1+size) elif isinstance(obj, FloatWrapper): size = self.realSize(obj) self.incrementByteCount('realBytes', incr=1+size) elif isinstance(obj, datetime.datetime): self.incrementByteCount('dateBytes', incr=2) elif isinstance(obj, Data): size = proc_size(len(obj)) self.incrementByteCount('dataBytes', incr=1+size) elif isinstance(obj, StringWrapper): size = proc_size(len(obj)) self.incrementByteCount('stringBytes', incr=1+size) elif isinstance(obj, HashableWrapper): obj = obj.value if isinstance(obj, set): size = proc_size(len(obj)) self.incrementByteCount('setBytes', incr=1+size) for value in obj: self.computeOffsets(value, asReference=True) elif isinstance(obj, (list, tuple)): size = proc_size(len(obj)) self.incrementByteCount('arrayBytes', incr=1+size) for value in obj: asRef = True self.computeOffsets(value, asReference=True) elif isinstance(obj, dict): size = proc_size(len(obj)) self.incrementByteCount('dictBytes', incr=1+size) for key, value in iteritems(obj): check_key(key) self.computeOffsets(key, asReference=True) self.computeOffsets(value, asReference=True) else: raise InvalidPlistException("Unknown object type: %s (%s)" % (type(obj).__name__, repr(obj))) def writeObjectReference(self, obj, output): """Tries to write an object reference, adding it to the references table. Does not write the actual object bytes or set the reference position. Returns a tuple of whether the object was a new reference (True if it was, False if it already was in the reference table) and the new output. """ position = self.positionOfObjectReference(obj) if position is None: self.writtenReferences[obj] = len(self.writtenReferences) output += self.binaryInt(len(self.writtenReferences) - 1, byteSize=self.trailer.objectRefSize) return (True, output) else: output += self.binaryInt(position, byteSize=self.trailer.objectRefSize) return (False, output) def writeObject(self, obj, output, setReferencePosition=False): """Serializes the given object to the output. Returns output. If setReferencePosition is True, will set the position the object was written. """ def proc_variable_length(format, length): result = b'' if length > 0b1110: result += pack('!B', (format << 4) | 0b1111) result = self.writeObject(length, result) else: result += pack('!B', (format << 4) | length) return result def timedelta_total_seconds(td): # Shim for Python 2.6 compatibility, which doesn't have total_seconds. # Make one argument a float to ensure the right calculation. return (td.microseconds + (td.seconds + td.days * 24 * 3600) * 10.0**6) / 10.0**6 if setReferencePosition: self.referencePositions[obj] = len(output) if obj is None: output += pack('!B', 0b00000000) elif isinstance(obj, BoolWrapper): if obj.value is False: output += pack('!B', 0b00001000) else: output += pack('!B', 0b00001001) elif isinstance(obj, Uid): size = self.intSize(obj.integer) output += pack('!B', (0b1000 << 4) | size - 1) output += self.binaryInt(obj.integer) elif isinstance(obj, (int, long)): byteSize = self.intSize(obj) root = math.log(byteSize, 2) output += pack('!B', (0b0001 << 4) | int(root)) output += self.binaryInt(obj, as_number=True) elif isinstance(obj, FloatWrapper): # just use doubles output += pack('!B', (0b0010 << 4) | 3) output += self.binaryReal(obj) elif isinstance(obj, datetime.datetime): try: timestamp = (obj - apple_reference_date).total_seconds() except AttributeError: timestamp = timedelta_total_seconds(obj - apple_reference_date) output += pack('!B', 0b00110011) output += pack('!d', float(timestamp)) elif isinstance(obj, Data): output += proc_variable_length(0b0100, len(obj)) output += obj elif isinstance(obj, StringWrapper): output += proc_variable_length(obj.encodingMarker, len(obj)) output += obj.encodedValue elif isinstance(obj, bytes): output += proc_variable_length(0b0101, len(obj)) output += obj elif isinstance(obj, HashableWrapper): obj = obj.value if isinstance(obj, (set, list, tuple)): if isinstance(obj, set): output += proc_variable_length(0b1100, len(obj)) else: output += proc_variable_length(0b1010, len(obj)) objectsToWrite = [] for objRef in sorted(obj) if isinstance(obj, set) else obj: (isNew, output) = self.writeObjectReference(objRef, output) if isNew: objectsToWrite.append(objRef) for objRef in objectsToWrite: output = self.writeObject(objRef, output, setReferencePosition=True) elif isinstance(obj, dict): output += proc_variable_length(0b1101, len(obj)) keys = [] values = [] objectsToWrite = [] for key, value in sorted(iteritems(obj)): keys.append(key) values.append(value) for key in keys: (isNew, output) = self.writeObjectReference(key, output) if isNew: objectsToWrite.append(key) for value in values: (isNew, output) = self.writeObjectReference(value, output) if isNew: objectsToWrite.append(value) for objRef in objectsToWrite: output = self.writeObject(objRef, output, setReferencePosition=True) return output def writeOffsetTable(self, output): """Writes all of the object reference offsets.""" all_positions = [] writtenReferences = list(self.writtenReferences.items()) writtenReferences.sort(key=lambda x: x[1]) for obj,order in writtenReferences: # Porting note: Elsewhere we deliberately replace empty unicdoe strings # with empty binary strings, but the empty unicode string # goes into writtenReferences. This isn't an issue in Py2 # because u'' and b'' have the same hash; but it is in # Py3, where they don't. if bytes != str and obj == unicodeEmpty: obj = b'' position = self.referencePositions.get(obj) if position is None: raise InvalidPlistException("Error while writing offsets table. Object not found. %s" % obj) output += self.binaryInt(position, self.trailer.offsetSize) all_positions.append(position) return output def binaryReal(self, obj): # just use doubles result = pack('>d', obj.value) return result def binaryInt(self, obj, byteSize=None, as_number=False): result = b'' if byteSize is None: byteSize = self.intSize(obj) if byteSize == 1: result += pack('>B', obj) elif byteSize == 2: result += pack('>H', obj) elif byteSize == 4: result += pack('>L', obj) elif byteSize == 8: if as_number: result += pack('>q', obj) else: result += pack('>Q', obj) elif byteSize <= 16: try: result = pack('>Q', 0) + pack('>Q', obj) except struct_error as e: raise InvalidPlistException("Unable to pack integer %d: %s" % (obj, e)) else: raise InvalidPlistException("Core Foundation can't handle integers with size greater than 16 bytes.") return result def intSize(self, obj): """Returns the number of bytes necessary to store the given integer.""" # SIGNED if obj < 0: # Signed integer, always 8 bytes return 8 # UNSIGNED elif obj <= 0xFF: # 1 byte return 1 elif obj <= 0xFFFF: # 2 bytes return 2 elif obj <= 0xFFFFFFFF: # 4 bytes return 4 # SIGNED # 0x7FFFFFFFFFFFFFFF is the max. elif obj <= 0x7FFFFFFFFFFFFFFF: # 8 bytes signed return 8 elif obj <= 0xffffffffffffffff: # 8 bytes unsigned return 16 else: raise InvalidPlistException("Core Foundation can't handle integers with size greater than 8 bytes.") def realSize(self, obj): return 8