from __future__ import print_function, division, absolute_import from fontTools.misc.py23 import * from fontTools.misc.textTools import safeEval, readHex from fontTools.misc.encodingTools import getEncoding from fontTools.ttLib import getSearchRange from fontTools.unicode import Unicode from . import DefaultTable import sys import struct import array import logging log = logging.getLogger(__name__) def _make_map(font, chars, gids): assert len(chars) == len(gids) cmap = {} glyphOrder = font.getGlyphOrder() for char,gid in zip(chars,gids): if gid is 0: continue try: name = glyphOrder[gid] except IndexError: name = font.getGlyphName(gid) cmap[char] = name return cmap class table__c_m_a_p(DefaultTable.DefaultTable): def getcmap(self, platformID, platEncID): for subtable in self.tables: if (subtable.platformID == platformID and subtable.platEncID == platEncID): return subtable return None # not found def getBestCmap(self, cmapPreferences=((3, 10), (0, 6), (0, 4), (3, 1), (0, 3), (0, 2), (0, 1), (0, 0))): """Return the 'best' unicode cmap dictionary available in the font, or None, if no unicode cmap subtable is available. By default it will search for the following (platformID, platEncID) pairs: (3, 10), (0, 6), (0, 4), (3, 1), (0, 3), (0, 2), (0, 1), (0, 0) This can be customized via the cmapPreferences argument. """ for platformID, platEncID in cmapPreferences: cmapSubtable = self.getcmap(platformID, platEncID) if cmapSubtable is not None: return cmapSubtable.cmap return None # None of the requested cmap subtables were found def buildReversed(self): """Returns a reverse cmap such as {'one':{0x31}, 'A':{0x41,0x391}}. The values are sets of Unicode codepoints because some fonts map different codepoints to the same glyph. For example, U+0041 LATIN CAPITAL LETTER A and U+0391 GREEK CAPITAL LETTER ALPHA are sometimes the same glyph. """ result = {} for subtable in self.tables: if subtable.isUnicode(): for codepoint, name in subtable.cmap.items(): result.setdefault(name, set()).add(codepoint) return result def decompile(self, data, ttFont): tableVersion, numSubTables = struct.unpack(">HH", data[:4]) self.tableVersion = int(tableVersion) self.tables = tables = [] seenOffsets = {} for i in range(numSubTables): platformID, platEncID, offset = struct.unpack( ">HHl", data[4+i*8:4+(i+1)*8]) platformID, platEncID = int(platformID), int(platEncID) format, length = struct.unpack(">HH", data[offset:offset+4]) if format in [8,10,12,13]: format, reserved, length = struct.unpack(">HHL", data[offset:offset+8]) elif format in [14]: format, length = struct.unpack(">HL", data[offset:offset+6]) if not length: log.error( "cmap subtable is reported as having zero length: platformID %s, " "platEncID %s, format %s offset %s. Skipping table.", platformID, platEncID, format, offset) continue table = CmapSubtable.newSubtable(format) table.platformID = platformID table.platEncID = platEncID # Note that by default we decompile only the subtable header info; # any other data gets decompiled only when an attribute of the # subtable is referenced. table.decompileHeader(data[offset:offset+int(length)], ttFont) if offset in seenOffsets: table.data = None # Mark as decompiled table.cmap = tables[seenOffsets[offset]].cmap else: seenOffsets[offset] = i tables.append(table) def compile(self, ttFont): self.tables.sort() # sort according to the spec; see CmapSubtable.__lt__() numSubTables = len(self.tables) totalOffset = 4 + 8 * numSubTables data = struct.pack(">HH", self.tableVersion, numSubTables) tableData = b"" seen = {} # Some tables are the same object reference. Don't compile them twice. done = {} # Some tables are different objects, but compile to the same data chunk for table in self.tables: try: offset = seen[id(table.cmap)] except KeyError: chunk = table.compile(ttFont) if chunk in done: offset = done[chunk] else: offset = seen[id(table.cmap)] = done[chunk] = totalOffset + len(tableData) tableData = tableData + chunk data = data + struct.pack(">HHl", table.platformID, table.platEncID, offset) return data + tableData def toXML(self, writer, ttFont): writer.simpletag("tableVersion", version=self.tableVersion) writer.newline() for table in self.tables: table.toXML(writer, ttFont) def fromXML(self, name, attrs, content, ttFont): if name == "tableVersion": self.tableVersion = safeEval(attrs["version"]) return if name[:12] != "cmap_format_": return if not hasattr(self, "tables"): self.tables = [] format = safeEval(name[12:]) table = CmapSubtable.newSubtable(format) table.platformID = safeEval(attrs["platformID"]) table.platEncID = safeEval(attrs["platEncID"]) table.fromXML(name, attrs, content, ttFont) self.tables.append(table) class CmapSubtable(object): @staticmethod def getSubtableClass(format): """Return the subtable class for a format.""" return cmap_classes.get(format, cmap_format_unknown) @staticmethod def newSubtable(format): """Return a new instance of a subtable for format.""" subtableClass = CmapSubtable.getSubtableClass(format) return subtableClass(format) def __init__(self, format): self.format = format self.data = None self.ttFont = None def __getattr__(self, attr): # allow lazy decompilation of subtables. if attr[:2] == '__': # don't handle requests for member functions like '__lt__' raise AttributeError(attr) if self.data is None: raise AttributeError(attr) self.decompile(None, None) # use saved data. self.data = None # Once this table has been decompiled, make sure we don't # just return the original data. Also avoids recursion when # called with an attribute that the cmap subtable doesn't have. return getattr(self, attr) def decompileHeader(self, data, ttFont): format, length, language = struct.unpack(">HHH", data[:6]) assert len(data) == length, "corrupt cmap table format %d (data length: %d, header length: %d)" % (format, len(data), length) self.format = int(format) self.length = int(length) self.language = int(language) self.data = data[6:] self.ttFont = ttFont def toXML(self, writer, ttFont): writer.begintag(self.__class__.__name__, [ ("platformID", self.platformID), ("platEncID", self.platEncID), ("language", self.language), ]) writer.newline() codes = sorted(self.cmap.items()) self._writeCodes(codes, writer) writer.endtag(self.__class__.__name__) writer.newline() def getEncoding(self, default=None): """Returns the Python encoding name for this cmap subtable based on its platformID, platEncID, and language. If encoding for these values is not known, by default None is returned. That can be overriden by passing a value to the default argument. Note that if you want to choose a "preferred" cmap subtable, most of the time self.isUnicode() is what you want as that one only returns true for the modern, commonly used, Unicode-compatible triplets, not the legacy ones. """ return getEncoding(self.platformID, self.platEncID, self.language, default) def isUnicode(self): return (self.platformID == 0 or (self.platformID == 3 and self.platEncID in [0, 1, 10])) def isSymbol(self): return self.platformID == 3 and self.platEncID == 0 def _writeCodes(self, codes, writer): isUnicode = self.isUnicode() for code, name in codes: writer.simpletag("map", code=hex(code), name=name) if isUnicode: writer.comment(Unicode[code]) writer.newline() def __lt__(self, other): if not isinstance(other, CmapSubtable): return NotImplemented # implemented so that list.sort() sorts according to the spec. selfTuple = ( getattr(self, "platformID", None), getattr(self, "platEncID", None), getattr(self, "language", None), self.__dict__) otherTuple = ( getattr(other, "platformID", None), getattr(other, "platEncID", None), getattr(other, "language", None), other.__dict__) return selfTuple < otherTuple class cmap_format_0(CmapSubtable): def decompile(self, data, ttFont): # we usually get here indirectly from the subtable __getattr__ function, in which case both args must be None. # If not, someone is calling the subtable decompile() directly, and must provide both args. if data is not None and ttFont is not None: self.decompileHeader(data, ttFont) else: assert (data is None and ttFont is None), "Need both data and ttFont arguments" data = self.data # decompileHeader assigns the data after the header to self.data assert 262 == self.length, "Format 0 cmap subtable not 262 bytes" gids = array.array("B") gids.fromstring(self.data) charCodes = list(range(len(gids))) self.cmap = _make_map(self.ttFont, charCodes, gids) def compile(self, ttFont): if self.data: return struct.pack(">HHH", 0, 262, self.language) + self.data cmap = self.cmap assert set(cmap.keys()).issubset(range(256)) getGlyphID = ttFont.getGlyphID valueList = [getGlyphID(cmap[i]) if i in cmap else 0 for i in range(256)] gids = array.array("B", valueList) data = struct.pack(">HHH", 0, 262, self.language) + gids.tostring() assert len(data) == 262 return data def fromXML(self, name, attrs, content, ttFont): self.language = safeEval(attrs["language"]) if not hasattr(self, "cmap"): self.cmap = {} cmap = self.cmap for element in content: if not isinstance(element, tuple): continue name, attrs, content = element if name != "map": continue cmap[safeEval(attrs["code"])] = attrs["name"] subHeaderFormat = ">HHhH" class SubHeader(object): def __init__(self): self.firstCode = None self.entryCount = None self.idDelta = None self.idRangeOffset = None self.glyphIndexArray = [] class cmap_format_2(CmapSubtable): def setIDDelta(self, subHeader): subHeader.idDelta = 0 # find the minGI which is not zero. minGI = subHeader.glyphIndexArray[0] for gid in subHeader.glyphIndexArray: if (gid != 0) and (gid < minGI): minGI = gid # The lowest gid in glyphIndexArray, after subtracting idDelta, must be 1. # idDelta is a short, and must be between -32K and 32K. minGI can be between 1 and 64K. # We would like to pick an idDelta such that the first glyphArray GID is 1, # so that we are more likely to be able to combine glypharray GID subranges. # This means that we have a problem when minGI is > 32K # Since the final gi is reconstructed from the glyphArray GID by: # (short)finalGID = (gid + idDelta) % 0x10000), # we can get from a glypharray GID of 1 to a final GID of 65K by subtracting 2, and casting the # negative number to an unsigned short. if (minGI > 1): if minGI > 0x7FFF: subHeader.idDelta = -(0x10000 - minGI) -1 else: subHeader.idDelta = minGI -1 idDelta = subHeader.idDelta for i in range(subHeader.entryCount): gid = subHeader.glyphIndexArray[i] if gid > 0: subHeader.glyphIndexArray[i] = gid - idDelta def decompile(self, data, ttFont): # we usually get here indirectly from the subtable __getattr__ function, in which case both args must be None. # If not, someone is calling the subtable decompile() directly, and must provide both args. if data is not None and ttFont is not None: self.decompileHeader(data, ttFont) else: assert (data is None and ttFont is None), "Need both data and ttFont arguments" data = self.data # decompileHeader assigns the data after the header to self.data subHeaderKeys = [] maxSubHeaderindex = 0 # get the key array, and determine the number of subHeaders. allKeys = array.array("H") allKeys.fromstring(data[:512]) data = data[512:] if sys.byteorder != "big": allKeys.byteswap() subHeaderKeys = [ key//8 for key in allKeys] maxSubHeaderindex = max(subHeaderKeys) #Load subHeaders subHeaderList = [] pos = 0 for i in range(maxSubHeaderindex + 1): subHeader = SubHeader() (subHeader.firstCode, subHeader.entryCount, subHeader.idDelta, \ subHeader.idRangeOffset) = struct.unpack(subHeaderFormat, data[pos:pos + 8]) pos += 8 giDataPos = pos + subHeader.idRangeOffset-2 giList = array.array("H") giList.fromstring(data[giDataPos:giDataPos + subHeader.entryCount*2]) if sys.byteorder != "big": giList.byteswap() subHeader.glyphIndexArray = giList subHeaderList.append(subHeader) # How this gets processed. # Charcodes may be one or two bytes. # The first byte of a charcode is mapped through the subHeaderKeys, to select # a subHeader. For any subheader but 0, the next byte is then mapped through the # selected subheader. If subheader Index 0 is selected, then the byte itself is # mapped through the subheader, and there is no second byte. # Then assume that the subsequent byte is the first byte of the next charcode,and repeat. # # Each subheader references a range in the glyphIndexArray whose length is entryCount. # The range in glyphIndexArray referenced by a sunheader may overlap with the range in glyphIndexArray # referenced by another subheader. # The only subheader that will be referenced by more than one first-byte value is the subheader # that maps the entire range of glyphID values to glyphIndex 0, e.g notdef: # {firstChar 0, EntryCount 0,idDelta 0,idRangeOffset xx} # A byte being mapped though a subheader is treated as in index into a mapping of array index to font glyphIndex. # A subheader specifies a subrange within (0...256) by the # firstChar and EntryCount values. If the byte value is outside the subrange, then the glyphIndex is zero # (e.g. glyph not in font). # If the byte index is in the subrange, then an offset index is calculated as (byteIndex - firstChar). # The index to glyphIndex mapping is a subrange of the glyphIndexArray. You find the start of the subrange by # counting idRangeOffset bytes from the idRangeOffset word. The first value in this subrange is the # glyphIndex for the index firstChar. The offset index should then be used in this array to get the glyphIndex. # Example for Logocut-Medium # first byte of charcode = 129; selects subheader 1. # subheader 1 = {firstChar 64, EntryCount 108,idDelta 42,idRangeOffset 0252} # second byte of charCode = 66 # the index offset = 66-64 = 2. # The subrange of the glyphIndexArray starting at 0x0252 bytes from the idRangeOffset word is: # [glyphIndexArray index], [subrange array index] = glyphIndex # [256], [0]=1 from charcode [129, 64] # [257], [1]=2 from charcode [129, 65] # [258], [2]=3 from charcode [129, 66] # [259], [3]=4 from charcode [129, 67] # So, the glyphIndex = 3 from the array. Then if idDelta is not zero and the glyph ID is not zero, # add it to the glyphID to get the final glyphIndex # value. In this case the final glyph index = 3+ 42 -> 45 for the final glyphIndex. Whew! self.data = b"" cmap = {} notdefGI = 0 for firstByte in range(256): subHeadindex = subHeaderKeys[firstByte] subHeader = subHeaderList[subHeadindex] if subHeadindex == 0: if (firstByte < subHeader.firstCode) or (firstByte >= subHeader.firstCode + subHeader.entryCount): continue # gi is notdef. else: charCode = firstByte offsetIndex = firstByte - subHeader.firstCode gi = subHeader.glyphIndexArray[offsetIndex] if gi != 0: gi = (gi + subHeader.idDelta) % 0x10000 else: continue # gi is notdef. cmap[charCode] = gi else: if subHeader.entryCount: charCodeOffset = firstByte * 256 + subHeader.firstCode for offsetIndex in range(subHeader.entryCount): charCode = charCodeOffset + offsetIndex gi = subHeader.glyphIndexArray[offsetIndex] if gi != 0: gi = (gi + subHeader.idDelta) % 0x10000 else: continue cmap[charCode] = gi # If not subHeader.entryCount, then all char codes with this first byte are # mapped to .notdef. We can skip this subtable, and leave the glyphs un-encoded, which is the # same as mapping it to .notdef. gids = list(cmap.values()) charCodes = list(cmap.keys()) self.cmap = _make_map(self.ttFont, charCodes, gids) def compile(self, ttFont): if self.data: return struct.pack(">HHH", self.format, self.length, self.language) + self.data kEmptyTwoCharCodeRange = -1 notdefGI = 0 items = sorted(self.cmap.items()) charCodes = [item[0] for item in items] names = [item[1] for item in items] nameMap = ttFont.getReverseGlyphMap() try: gids = [nameMap[name] for name in names] except KeyError: nameMap = ttFont.getReverseGlyphMap(rebuild=True) try: gids = [nameMap[name] for name in names] except KeyError: # allow virtual GIDs in format 2 tables gids = [] for name in names: try: gid = nameMap[name] except KeyError: try: if (name[:3] == 'gid'): gid = int(name[3:]) else: gid = ttFont.getGlyphID(name) except: raise KeyError(name) gids.append(gid) # Process the (char code to gid) item list in char code order. # By definition, all one byte char codes map to subheader 0. # For all the two byte char codes, we assume that the first byte maps maps to the empty subhead (with an entry count of 0, # which defines all char codes in its range to map to notdef) unless proven otherwise. # Note that since the char code items are processed in char code order, all the char codes with the # same first byte are in sequential order. subHeaderKeys = [kEmptyTwoCharCodeRange for x in range(256)] # list of indices into subHeaderList. subHeaderList = [] # We force this subheader entry 0 to exist in the subHeaderList in the case where some one comes up # with a cmap where all the one byte char codes map to notdef, # with the result that the subhead 0 would not get created just by processing the item list. charCode = charCodes[0] if charCode > 255: subHeader = SubHeader() subHeader.firstCode = 0 subHeader.entryCount = 0 subHeader.idDelta = 0 subHeader.idRangeOffset = 0 subHeaderList.append(subHeader) lastFirstByte = -1 items = zip(charCodes, gids) for charCode, gid in items: if gid == 0: continue firstbyte = charCode >> 8 secondByte = charCode & 0x00FF if firstbyte != lastFirstByte: # Need to update the current subhead, and start a new one. if lastFirstByte > -1: # fix GI's and iDelta of current subheader. self.setIDDelta(subHeader) # If it was sunheader 0 for one-byte charCodes, then we need to set the subHeaderKeys value to zero # for the indices matching the char codes. if lastFirstByte == 0: for index in range(subHeader.entryCount): charCode = subHeader.firstCode + index subHeaderKeys[charCode] = 0 assert (subHeader.entryCount == len(subHeader.glyphIndexArray)), "Error - subhead entry count does not match len of glyphID subrange." # init new subheader subHeader = SubHeader() subHeader.firstCode = secondByte subHeader.entryCount = 1 subHeader.glyphIndexArray.append(gid) subHeaderList.append(subHeader) subHeaderKeys[firstbyte] = len(subHeaderList) -1 lastFirstByte = firstbyte else: # need to fill in with notdefs all the code points between the last charCode and the current charCode. codeDiff = secondByte - (subHeader.firstCode + subHeader.entryCount) for i in range(codeDiff): subHeader.glyphIndexArray.append(notdefGI) subHeader.glyphIndexArray.append(gid) subHeader.entryCount = subHeader.entryCount + codeDiff + 1 # fix GI's and iDelta of last subheader that we we added to the subheader array. self.setIDDelta(subHeader) # Now we add a final subheader for the subHeaderKeys which maps to empty two byte charcode ranges. subHeader = SubHeader() subHeader.firstCode = 0 subHeader.entryCount = 0 subHeader.idDelta = 0 subHeader.idRangeOffset = 2 subHeaderList.append(subHeader) emptySubheadIndex = len(subHeaderList) - 1 for index in range(256): if subHeaderKeys[index] == kEmptyTwoCharCodeRange: subHeaderKeys[index] = emptySubheadIndex # Since this is the last subheader, the GlyphIndex Array starts two bytes after the start of the # idRangeOffset word of this subHeader. We can safely point to the first entry in the GlyphIndexArray, # since the first subrange of the GlyphIndexArray is for subHeader 0, which always starts with # charcode 0 and GID 0. idRangeOffset = (len(subHeaderList)-1)*8 + 2 # offset to beginning of glyphIDArray from first subheader idRangeOffset. subheadRangeLen = len(subHeaderList) -1 # skip last special empty-set subheader; we've already hardocodes its idRangeOffset to 2. for index in range(subheadRangeLen): subHeader = subHeaderList[index] subHeader.idRangeOffset = 0 for j in range(index): prevSubhead = subHeaderList[j] if prevSubhead.glyphIndexArray == subHeader.glyphIndexArray: # use the glyphIndexArray subarray subHeader.idRangeOffset = prevSubhead.idRangeOffset - (index-j)*8 subHeader.glyphIndexArray = [] break if subHeader.idRangeOffset == 0: # didn't find one. subHeader.idRangeOffset = idRangeOffset idRangeOffset = (idRangeOffset - 8) + subHeader.entryCount*2 # one less subheader, one more subArray. else: idRangeOffset = idRangeOffset - 8 # one less subheader # Now we can write out the data! length = 6 + 512 + 8*len(subHeaderList) # header, 256 subHeaderKeys, and subheader array. for subhead in subHeaderList[:-1]: length = length + len(subhead.glyphIndexArray)*2 # We can't use subhead.entryCount, as some of the subhead may share subArrays. dataList = [struct.pack(">HHH", 2, length, self.language)] for index in subHeaderKeys: dataList.append(struct.pack(">H", index*8)) for subhead in subHeaderList: dataList.append(struct.pack(subHeaderFormat, subhead.firstCode, subhead.entryCount, subhead.idDelta, subhead.idRangeOffset)) for subhead in subHeaderList[:-1]: for gi in subhead.glyphIndexArray: dataList.append(struct.pack(">H", gi)) data = bytesjoin(dataList) assert (len(data) == length), "Error: cmap format 2 is not same length as calculated! actual: " + str(len(data))+ " calc : " + str(length) return data def fromXML(self, name, attrs, content, ttFont): self.language = safeEval(attrs["language"]) if not hasattr(self, "cmap"): self.cmap = {} cmap = self.cmap for element in content: if not isinstance(element, tuple): continue name, attrs, content = element if name != "map": continue cmap[safeEval(attrs["code"])] = attrs["name"] cmap_format_4_format = ">7H" #uint16 endCode[segCount] # Ending character code for each segment, last = 0xFFFF. #uint16 reservedPad # This value should be zero #uint16 startCode[segCount] # Starting character code for each segment #uint16 idDelta[segCount] # Delta for all character codes in segment #uint16 idRangeOffset[segCount] # Offset in bytes to glyph indexArray, or 0 #uint16 glyphIndexArray[variable] # Glyph index array def splitRange(startCode, endCode, cmap): # Try to split a range of character codes into subranges with consecutive # glyph IDs in such a way that the cmap4 subtable can be stored "most" # efficiently. I can't prove I've got the optimal solution, but it seems # to do well with the fonts I tested: none became bigger, many became smaller. if startCode == endCode: return [], [endCode] lastID = cmap[startCode] lastCode = startCode inOrder = None orderedBegin = None subRanges = [] # Gather subranges in which the glyph IDs are consecutive. for code in range(startCode + 1, endCode + 1): glyphID = cmap[code] if glyphID - 1 == lastID: if inOrder is None or not inOrder: inOrder = 1 orderedBegin = lastCode else: if inOrder: inOrder = 0 subRanges.append((orderedBegin, lastCode)) orderedBegin = None lastID = glyphID lastCode = code if inOrder: subRanges.append((orderedBegin, lastCode)) assert lastCode == endCode # Now filter out those new subranges that would only make the data bigger. # A new segment cost 8 bytes, not using a new segment costs 2 bytes per # character. newRanges = [] for b, e in subRanges: if b == startCode and e == endCode: break # the whole range, we're fine if b == startCode or e == endCode: threshold = 4 # split costs one more segment else: threshold = 8 # split costs two more segments if (e - b + 1) > threshold: newRanges.append((b, e)) subRanges = newRanges if not subRanges: return [], [endCode] if subRanges[0][0] != startCode: subRanges.insert(0, (startCode, subRanges[0][0] - 1)) if subRanges[-1][1] != endCode: subRanges.append((subRanges[-1][1] + 1, endCode)) # Fill the "holes" in the segments list -- those are the segments in which # the glyph IDs are _not_ consecutive. i = 1 while i < len(subRanges): if subRanges[i-1][1] + 1 != subRanges[i][0]: subRanges.insert(i, (subRanges[i-1][1] + 1, subRanges[i][0] - 1)) i = i + 1 i = i + 1 # Transform the ranges into startCode/endCode lists. start = [] end = [] for b, e in subRanges: start.append(b) end.append(e) start.pop(0) assert len(start) + 1 == len(end) return start, end class cmap_format_4(CmapSubtable): def decompile(self, data, ttFont): # we usually get here indirectly from the subtable __getattr__ function, in which case both args must be None. # If not, someone is calling the subtable decompile() directly, and must provide both args. if data is not None and ttFont is not None: self.decompileHeader(data, ttFont) else: assert (data is None and ttFont is None), "Need both data and ttFont arguments" data = self.data # decompileHeader assigns the data after the header to self.data (segCountX2, searchRange, entrySelector, rangeShift) = \ struct.unpack(">4H", data[:8]) data = data[8:] segCount = segCountX2 // 2 allCodes = array.array("H") allCodes.fromstring(data) self.data = data = None if sys.byteorder != "big": allCodes.byteswap() # divide the data endCode = allCodes[:segCount] allCodes = allCodes[segCount+1:] # the +1 is skipping the reservedPad field startCode = allCodes[:segCount] allCodes = allCodes[segCount:] idDelta = allCodes[:segCount] allCodes = allCodes[segCount:] idRangeOffset = allCodes[:segCount] glyphIndexArray = allCodes[segCount:] lenGIArray = len(glyphIndexArray) # build 2-byte character mapping charCodes = [] gids = [] for i in range(len(startCode) - 1): # don't do 0xffff! start = startCode[i] delta = idDelta[i] rangeOffset = idRangeOffset[i] # *someone* needs to get killed. partial = rangeOffset // 2 - start + i - len(idRangeOffset) rangeCharCodes = list(range(startCode[i], endCode[i] + 1)) charCodes.extend(rangeCharCodes) if rangeOffset == 0: gids.extend([(charCode + delta) & 0xFFFF for charCode in rangeCharCodes]) else: for charCode in rangeCharCodes: index = charCode + partial assert (index < lenGIArray), "In format 4 cmap, range (%d), the calculated index (%d) into the glyph index array is not less than the length of the array (%d) !" % (i, index, lenGIArray) if glyphIndexArray[index] != 0: # if not missing glyph glyphID = glyphIndexArray[index] + delta else: glyphID = 0 # missing glyph gids.append(glyphID & 0xFFFF) self.cmap = _make_map(self.ttFont, charCodes, gids) def compile(self, ttFont): if self.data: return struct.pack(">HHH", self.format, self.length, self.language) + self.data charCodes = list(self.cmap.keys()) if not charCodes: startCode = [0xffff] endCode = [0xffff] else: charCodes.sort() names = [self.cmap[code] for code in charCodes] nameMap = ttFont.getReverseGlyphMap() try: gids = [nameMap[name] for name in names] except KeyError: nameMap = ttFont.getReverseGlyphMap(rebuild=True) try: gids = [nameMap[name] for name in names] except KeyError: # allow virtual GIDs in format 4 tables gids = [] for name in names: try: gid = nameMap[name] except KeyError: try: if (name[:3] == 'gid'): gid = int(name[3:]) else: gid = ttFont.getGlyphID(name) except: raise KeyError(name) gids.append(gid) cmap = {} # code:glyphID mapping for code, gid in zip(charCodes, gids): cmap[code] = gid # Build startCode and endCode lists. # Split the char codes in ranges of consecutive char codes, then split # each range in more ranges of consecutive/not consecutive glyph IDs. # See splitRange(). lastCode = charCodes[0] endCode = [] startCode = [lastCode] for charCode in charCodes[1:]: # skip the first code, it's the first start code if charCode == lastCode + 1: lastCode = charCode continue start, end = splitRange(startCode[-1], lastCode, cmap) startCode.extend(start) endCode.extend(end) startCode.append(charCode) lastCode = charCode start, end = splitRange(startCode[-1], lastCode, cmap) startCode.extend(start) endCode.extend(end) startCode.append(0xffff) endCode.append(0xffff) # build up rest of cruft idDelta = [] idRangeOffset = [] glyphIndexArray = [] for i in range(len(endCode)-1): # skip the closing codes (0xffff) indices = [] for charCode in range(startCode[i], endCode[i] + 1): indices.append(cmap[charCode]) if (indices == list(range(indices[0], indices[0] + len(indices)))): idDelta.append((indices[0] - startCode[i]) % 0x10000) idRangeOffset.append(0) else: # someone *definitely* needs to get killed. idDelta.append(0) idRangeOffset.append(2 * (len(endCode) + len(glyphIndexArray) - i)) glyphIndexArray.extend(indices) idDelta.append(1) # 0xffff + 1 == (tadaa!) 0. So this end code maps to .notdef idRangeOffset.append(0) # Insane. segCount = len(endCode) segCountX2 = segCount * 2 searchRange, entrySelector, rangeShift = getSearchRange(segCount, 2) charCodeArray = array.array("H", endCode + [0] + startCode) idDeltaArray = array.array("H", idDelta) restArray = array.array("H", idRangeOffset + glyphIndexArray) if sys.byteorder != "big": charCodeArray.byteswap() if sys.byteorder != "big": idDeltaArray.byteswap() if sys.byteorder != "big": restArray.byteswap() data = charCodeArray.tostring() + idDeltaArray.tostring() + restArray.tostring() length = struct.calcsize(cmap_format_4_format) + len(data) header = struct.pack(cmap_format_4_format, self.format, length, self.language, segCountX2, searchRange, entrySelector, rangeShift) return header + data def fromXML(self, name, attrs, content, ttFont): self.language = safeEval(attrs["language"]) if not hasattr(self, "cmap"): self.cmap = {} cmap = self.cmap for element in content: if not isinstance(element, tuple): continue nameMap, attrsMap, dummyContent = element if nameMap != "map": assert 0, "Unrecognized keyword in cmap subtable" cmap[safeEval(attrsMap["code"])] = attrsMap["name"] class cmap_format_6(CmapSubtable): def decompile(self, data, ttFont): # we usually get here indirectly from the subtable __getattr__ function, in which case both args must be None. # If not, someone is calling the subtable decompile() directly, and must provide both args. if data is not None and ttFont is not None: self.decompileHeader(data, ttFont) else: assert (data is None and ttFont is None), "Need both data and ttFont arguments" data = self.data # decompileHeader assigns the data after the header to self.data firstCode, entryCount = struct.unpack(">HH", data[:4]) firstCode = int(firstCode) data = data[4:] #assert len(data) == 2 * entryCount # XXX not true in Apple's Helvetica!!! gids = array.array("H") gids.fromstring(data[:2 * int(entryCount)]) if sys.byteorder != "big": gids.byteswap() self.data = data = None charCodes = list(range(firstCode, firstCode + len(gids))) self.cmap = _make_map(self.ttFont, charCodes, gids) def compile(self, ttFont): if self.data: return struct.pack(">HHH", self.format, self.length, self.language) + self.data cmap = self.cmap codes = sorted(cmap.keys()) if codes: # yes, there are empty cmap tables. codes = list(range(codes[0], codes[-1] + 1)) firstCode = codes[0] valueList = [ ttFont.getGlyphID(cmap[code]) if code in cmap else 0 for code in codes ] gids = array.array("H", valueList) if sys.byteorder != "big": gids.byteswap() data = gids.tostring() else: data = b"" firstCode = 0 header = struct.pack(">HHHHH", 6, len(data) + 10, self.language, firstCode, len(codes)) return header + data def fromXML(self, name, attrs, content, ttFont): self.language = safeEval(attrs["language"]) if not hasattr(self, "cmap"): self.cmap = {} cmap = self.cmap for element in content: if not isinstance(element, tuple): continue name, attrs, content = element if name != "map": continue cmap[safeEval(attrs["code"])] = attrs["name"] class cmap_format_12_or_13(CmapSubtable): def __init__(self, format): self.format = format self.reserved = 0 self.data = None self.ttFont = None def decompileHeader(self, data, ttFont): format, reserved, length, language, nGroups = struct.unpack(">HHLLL", data[:16]) assert len(data) == (16 + nGroups*12) == (length), "corrupt cmap table format %d (data length: %d, header length: %d)" % (self.format, len(data), length) self.format = format self.reserved = reserved self.length = length self.language = language self.nGroups = nGroups self.data = data[16:] self.ttFont = ttFont def decompile(self, data, ttFont): # we usually get here indirectly from the subtable __getattr__ function, in which case both args must be None. # If not, someone is calling the subtable decompile() directly, and must provide both args. if data is not None and ttFont is not None: self.decompileHeader(data, ttFont) else: assert (data is None and ttFont is None), "Need both data and ttFont arguments" data = self.data # decompileHeader assigns the data after the header to self.data charCodes = [] gids = [] pos = 0 for i in range(self.nGroups): startCharCode, endCharCode, glyphID = struct.unpack(">LLL",data[pos:pos+12] ) pos += 12 lenGroup = 1 + endCharCode - startCharCode charCodes.extend(list(range(startCharCode, endCharCode +1))) gids.extend(self._computeGIDs(glyphID, lenGroup)) self.data = data = None self.cmap = _make_map(self.ttFont, charCodes, gids) def compile(self, ttFont): if self.data: return struct.pack(">HHLLL", self.format, self.reserved, self.length, self.language, self.nGroups) + self.data charCodes = list(self.cmap.keys()) names = list(self.cmap.values()) nameMap = ttFont.getReverseGlyphMap() try: gids = [nameMap[name] for name in names] except KeyError: nameMap = ttFont.getReverseGlyphMap(rebuild=True) try: gids = [nameMap[name] for name in names] except KeyError: # allow virtual GIDs in format 12 tables gids = [] for name in names: try: gid = nameMap[name] except KeyError: try: if (name[:3] == 'gid'): gid = int(name[3:]) else: gid = ttFont.getGlyphID(name) except: raise KeyError(name) gids.append(gid) cmap = {} # code:glyphID mapping for code, gid in zip(charCodes, gids): cmap[code] = gid charCodes.sort() index = 0 startCharCode = charCodes[0] startGlyphID = cmap[startCharCode] lastGlyphID = startGlyphID - self._format_step lastCharCode = startCharCode - 1 nGroups = 0 dataList = [] maxIndex = len(charCodes) for index in range(maxIndex): charCode = charCodes[index] glyphID = cmap[charCode] if not self._IsInSameRun(glyphID, lastGlyphID, charCode, lastCharCode): dataList.append(struct.pack(">LLL", startCharCode, lastCharCode, startGlyphID)) startCharCode = charCode startGlyphID = glyphID nGroups = nGroups + 1 lastGlyphID = glyphID lastCharCode = charCode dataList.append(struct.pack(">LLL", startCharCode, lastCharCode, startGlyphID)) nGroups = nGroups + 1 data = bytesjoin(dataList) lengthSubtable = len(data) +16 assert len(data) == (nGroups*12) == (lengthSubtable-16) return struct.pack(">HHLLL", self.format, self.reserved, lengthSubtable, self.language, nGroups) + data def toXML(self, writer, ttFont): writer.begintag(self.__class__.__name__, [ ("platformID", self.platformID), ("platEncID", self.platEncID), ("format", self.format), ("reserved", self.reserved), ("length", self.length), ("language", self.language), ("nGroups", self.nGroups), ]) writer.newline() codes = sorted(self.cmap.items()) self._writeCodes(codes, writer) writer.endtag(self.__class__.__name__) writer.newline() def fromXML(self, name, attrs, content, ttFont): self.format = safeEval(attrs["format"]) self.reserved = safeEval(attrs["reserved"]) self.length = safeEval(attrs["length"]) self.language = safeEval(attrs["language"]) self.nGroups = safeEval(attrs["nGroups"]) if not hasattr(self, "cmap"): self.cmap = {} cmap = self.cmap for element in content: if not isinstance(element, tuple): continue name, attrs, content = element if name != "map": continue cmap[safeEval(attrs["code"])] = attrs["name"] class cmap_format_12(cmap_format_12_or_13): _format_step = 1 def __init__(self, format=12): cmap_format_12_or_13.__init__(self, format) def _computeGIDs(self, startingGlyph, numberOfGlyphs): return list(range(startingGlyph, startingGlyph + numberOfGlyphs)) def _IsInSameRun(self, glyphID, lastGlyphID, charCode, lastCharCode): return (glyphID == 1 + lastGlyphID) and (charCode == 1 + lastCharCode) class cmap_format_13(cmap_format_12_or_13): _format_step = 0 def __init__(self, format=13): cmap_format_12_or_13.__init__(self, format) def _computeGIDs(self, startingGlyph, numberOfGlyphs): return [startingGlyph] * numberOfGlyphs def _IsInSameRun(self, glyphID, lastGlyphID, charCode, lastCharCode): return (glyphID == lastGlyphID) and (charCode == 1 + lastCharCode) def cvtToUVS(threeByteString): data = b"\0" + threeByteString val, = struct.unpack(">L", data) return val def cvtFromUVS(val): assert 0 <= val < 0x1000000 fourByteString = struct.pack(">L", val) return fourByteString[1:] class cmap_format_14(CmapSubtable): def decompileHeader(self, data, ttFont): format, length, numVarSelectorRecords = struct.unpack(">HLL", data[:10]) self.data = data[10:] self.length = length self.numVarSelectorRecords = numVarSelectorRecords self.ttFont = ttFont self.language = 0xFF # has no language. def decompile(self, data, ttFont): if data is not None and ttFont is not None: self.decompileHeader(data, ttFont) else: assert (data is None and ttFont is None), "Need both data and ttFont arguments" data = self.data self.cmap = {} # so that clients that expect this to exist in a cmap table won't fail. uvsDict = {} recOffset = 0 for n in range(self.numVarSelectorRecords): uvs, defOVSOffset, nonDefUVSOffset = struct.unpack(">3sLL", data[recOffset:recOffset +11]) recOffset += 11 varUVS = cvtToUVS(uvs) if defOVSOffset: startOffset = defOVSOffset - 10 numValues, = struct.unpack(">L", data[startOffset:startOffset+4]) startOffset +=4 for r in range(numValues): uv, addtlCnt = struct.unpack(">3sB", data[startOffset:startOffset+4]) startOffset += 4 firstBaseUV = cvtToUVS(uv) cnt = addtlCnt+1 baseUVList = list(range(firstBaseUV, firstBaseUV+cnt)) glyphList = [None]*cnt localUVList = zip(baseUVList, glyphList) try: uvsDict[varUVS].extend(localUVList) except KeyError: uvsDict[varUVS] = list(localUVList) if nonDefUVSOffset: startOffset = nonDefUVSOffset - 10 numRecs, = struct.unpack(">L", data[startOffset:startOffset+4]) startOffset +=4 localUVList = [] for r in range(numRecs): uv, gid = struct.unpack(">3sH", data[startOffset:startOffset+5]) startOffset += 5 uv = cvtToUVS(uv) glyphName = self.ttFont.getGlyphName(gid) localUVList.append((uv, glyphName)) try: uvsDict[varUVS].extend(localUVList) except KeyError: uvsDict[varUVS] = localUVList self.uvsDict = uvsDict def toXML(self, writer, ttFont): writer.begintag(self.__class__.__name__, [ ("platformID", self.platformID), ("platEncID", self.platEncID), ]) writer.newline() uvsDict = self.uvsDict uvsList = sorted(uvsDict.keys()) for uvs in uvsList: uvList = uvsDict[uvs] uvList.sort(key=lambda item: (item[1] is not None, item[0], item[1])) for uv, gname in uvList: attrs = [("uv", hex(uv)), ("uvs", hex(uvs))] if gname is not None: attrs.append(("name", gname)) writer.simpletag("map", attrs) writer.newline() writer.endtag(self.__class__.__name__) writer.newline() def fromXML(self, name, attrs, content, ttFont): self.language = 0xFF # provide a value so that CmapSubtable.__lt__() won't fail if not hasattr(self, "cmap"): self.cmap = {} # so that clients that expect this to exist in a cmap table won't fail. if not hasattr(self, "uvsDict"): self.uvsDict = {} uvsDict = self.uvsDict # For backwards compatibility reasons we accept "None" as an indicator # for "default mapping", unless the font actually has a glyph named # "None". _hasGlyphNamedNone = None for element in content: if not isinstance(element, tuple): continue name, attrs, content = element if name != "map": continue uvs = safeEval(attrs["uvs"]) uv = safeEval(attrs["uv"]) gname = attrs.get("name") if gname == "None": if _hasGlyphNamedNone is None: _hasGlyphNamedNone = "None" in ttFont.getGlyphOrder() if not _hasGlyphNamedNone: gname = None try: uvsDict[uvs].append((uv, gname)) except KeyError: uvsDict[uvs] = [(uv, gname)] def compile(self, ttFont): if self.data: return struct.pack(">HLL", self.format, self.length, self.numVarSelectorRecords) + self.data uvsDict = self.uvsDict uvsList = sorted(uvsDict.keys()) self.numVarSelectorRecords = len(uvsList) offset = 10 + self.numVarSelectorRecords*11 # current value is end of VarSelectorRecords block. data = [] varSelectorRecords =[] for uvs in uvsList: entryList = uvsDict[uvs] defList = [entry for entry in entryList if entry[1] is None] if defList: defList = [entry[0] for entry in defList] defOVSOffset = offset defList.sort() lastUV = defList[0] cnt = -1 defRecs = [] for defEntry in defList: cnt +=1 if (lastUV+cnt) != defEntry: rec = struct.pack(">3sB", cvtFromUVS(lastUV), cnt-1) lastUV = defEntry defRecs.append(rec) cnt = 0 rec = struct.pack(">3sB", cvtFromUVS(lastUV), cnt) defRecs.append(rec) numDefRecs = len(defRecs) data.append(struct.pack(">L", numDefRecs)) data.extend(defRecs) offset += 4 + numDefRecs*4 else: defOVSOffset = 0 ndefList = [entry for entry in entryList if entry[1] is not None] if ndefList: nonDefUVSOffset = offset ndefList.sort() numNonDefRecs = len(ndefList) data.append(struct.pack(">L", numNonDefRecs)) offset += 4 + numNonDefRecs*5 for uv, gname in ndefList: gid = ttFont.getGlyphID(gname) ndrec = struct.pack(">3sH", cvtFromUVS(uv), gid) data.append(ndrec) else: nonDefUVSOffset = 0 vrec = struct.pack(">3sLL", cvtFromUVS(uvs), defOVSOffset, nonDefUVSOffset) varSelectorRecords.append(vrec) data = bytesjoin(varSelectorRecords) + bytesjoin(data) self.length = 10 + len(data) headerdata = struct.pack(">HLL", self.format, self.length, self.numVarSelectorRecords) return headerdata + data class cmap_format_unknown(CmapSubtable): def toXML(self, writer, ttFont): cmapName = self.__class__.__name__[:12] + str(self.format) writer.begintag(cmapName, [ ("platformID", self.platformID), ("platEncID", self.platEncID), ]) writer.newline() writer.dumphex(self.data) writer.endtag(cmapName) writer.newline() def fromXML(self, name, attrs, content, ttFont): self.data = readHex(content) self.cmap = {} def decompileHeader(self, data, ttFont): self.language = 0 # dummy value self.data = data def decompile(self, data, ttFont): # we usually get here indirectly from the subtable __getattr__ function, in which case both args must be None. # If not, someone is calling the subtable decompile() directly, and must provide both args. if data is not None and ttFont is not None: self.decompileHeader(data, ttFont) else: assert (data is None and ttFont is None), "Need both data and ttFont arguments" def compile(self, ttFont): if self.data: return self.data else: return None cmap_classes = { 0: cmap_format_0, 2: cmap_format_2, 4: cmap_format_4, 6: cmap_format_6, 12: cmap_format_12, 13: cmap_format_13, 14: cmap_format_14, }