Sakurai/pdf.js
1
0
Fork 0
Code Issues Pull Requests Packages Projects Releases Wiki Activity
8943bcd3c3
pdf.js/src/core/cff_parser.js

1934 lines
60 KiB
JavaScript
Raw Blame History

/* Copyright 2016 Mozilla Foundation
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
import {
bytesToString,
FormatError,
info,
shadow,
stringToBytes,
Util,
warn,
} from "../shared/util.js";
import {
ExpertCharset,
ExpertSubsetCharset,
ISOAdobeCharset,
} from "./charsets.js";
import { ExpertEncoding, StandardEncoding } from "./encodings.js";
// Maximum subroutine call depth of type 2 chartrings. Matches OTS.
const MAX_SUBR_NESTING = 10;
/**
* The CFF class takes a Type1 file and wrap it into a
* 'Compact Font Format' which itself embed Type2 charstrings.
*/
// prettier-ignore
const CFFStandardStrings = [
".notdef", "space", "exclam", "quotedbl", "numbersign", "dollar", "percent",
"ampersand", "quoteright", "parenleft", "parenright", "asterisk", "plus",
"comma", "hyphen", "period", "slash", "zero", "one", "two", "three", "four",
"five", "six", "seven", "eight", "nine", "colon", "semicolon", "less",
"equal", "greater", "question", "at", "A", "B", "C", "D", "E", "F", "G", "H",
"I", "J", "K", "L", "M", "N", "O", "P", "Q", "R", "S", "T", "U", "V", "W",
"X", "Y", "Z", "bracketleft", "backslash", "bracketright", "asciicircum",
"underscore", "quoteleft", "a", "b", "c", "d", "e", "f", "g", "h", "i", "j",
"k", "l", "m", "n", "o", "p", "q", "r", "s", "t", "u", "v", "w", "x", "y",
"z", "braceleft", "bar", "braceright", "asciitilde", "exclamdown", "cent",
"sterling", "fraction", "yen", "florin", "section", "currency",
"quotesingle", "quotedblleft", "guillemotleft", "guilsinglleft",
"guilsinglright", "fi", "fl", "endash", "dagger", "daggerdbl",
"periodcentered", "paragraph", "bullet", "quotesinglbase", "quotedblbase",
"quotedblright", "guillemotright", "ellipsis", "perthousand", "questiondown",
"grave", "acute", "circumflex", "tilde", "macron", "breve", "dotaccent",
"dieresis", "ring", "cedilla", "hungarumlaut", "ogonek", "caron", "emdash",
"AE", "ordfeminine", "Lslash", "Oslash", "OE", "ordmasculine", "ae",
"dotlessi", "lslash", "oslash", "oe", "germandbls", "onesuperior",
"logicalnot", "mu", "trademark", "Eth", "onehalf", "plusminus", "Thorn",
"onequarter", "divide", "brokenbar", "degree", "thorn", "threequarters",
"twosuperior", "registered", "minus", "eth", "multiply", "threesuperior",
"copyright", "Aacute", "Acircumflex", "Adieresis", "Agrave", "Aring",
"Atilde", "Ccedilla", "Eacute", "Ecircumflex", "Edieresis", "Egrave",
"Iacute", "Icircumflex", "Idieresis", "Igrave", "Ntilde", "Oacute",
"Ocircumflex", "Odieresis", "Ograve", "Otilde", "Scaron", "Uacute",
"Ucircumflex", "Udieresis", "Ugrave", "Yacute", "Ydieresis", "Zcaron",
"aacute", "acircumflex", "adieresis", "agrave", "aring", "atilde",
"ccedilla", "eacute", "ecircumflex", "edieresis", "egrave", "iacute",
"icircumflex", "idieresis", "igrave", "ntilde", "oacute", "ocircumflex",
"odieresis", "ograve", "otilde", "scaron", "uacute", "ucircumflex",
"udieresis", "ugrave", "yacute", "ydieresis", "zcaron", "exclamsmall",
"Hungarumlautsmall", "dollaroldstyle", "dollarsuperior", "ampersandsmall",
"Acutesmall", "parenleftsuperior", "parenrightsuperior", "twodotenleader",
"onedotenleader", "zerooldstyle", "oneoldstyle", "twooldstyle",
"threeoldstyle", "fouroldstyle", "fiveoldstyle", "sixoldstyle",
"sevenoldstyle", "eightoldstyle", "nineoldstyle", "commasuperior",
"threequartersemdash", "periodsuperior", "questionsmall", "asuperior",
"bsuperior", "centsuperior", "dsuperior", "esuperior", "isuperior",
"lsuperior", "msuperior", "nsuperior", "osuperior", "rsuperior", "ssuperior",
"tsuperior", "ff", "ffi", "ffl", "parenleftinferior", "parenrightinferior",
"Circumflexsmall", "hyphensuperior", "Gravesmall", "Asmall", "Bsmall",
"Csmall", "Dsmall", "Esmall", "Fsmall", "Gsmall", "Hsmall", "Ismall",
"Jsmall", "Ksmall", "Lsmall", "Msmall", "Nsmall", "Osmall", "Psmall",
"Qsmall", "Rsmall", "Ssmall", "Tsmall", "Usmall", "Vsmall", "Wsmall",
"Xsmall", "Ysmall", "Zsmall", "colonmonetary", "onefitted", "rupiah",
"Tildesmall", "exclamdownsmall", "centoldstyle", "Lslashsmall",
"Scaronsmall", "Zcaronsmall", "Dieresissmall", "Brevesmall", "Caronsmall",
"Dotaccentsmall", "Macronsmall", "figuredash", "hypheninferior",
"Ogoneksmall", "Ringsmall", "Cedillasmall", "questiondownsmall", "oneeighth",
"threeeighths", "fiveeighths", "seveneighths", "onethird", "twothirds",
"zerosuperior", "foursuperior", "fivesuperior", "sixsuperior",
"sevensuperior", "eightsuperior", "ninesuperior", "zeroinferior",
"oneinferior", "twoinferior", "threeinferior", "fourinferior",
"fiveinferior", "sixinferior", "seveninferior", "eightinferior",
"nineinferior", "centinferior", "dollarinferior", "periodinferior",
"commainferior", "Agravesmall", "Aacutesmall", "Acircumflexsmall",
"Atildesmall", "Adieresissmall", "Aringsmall", "AEsmall", "Ccedillasmall",
"Egravesmall", "Eacutesmall", "Ecircumflexsmall", "Edieresissmall",
"Igravesmall", "Iacutesmall", "Icircumflexsmall", "Idieresissmall",
"Ethsmall", "Ntildesmall", "Ogravesmall", "Oacutesmall", "Ocircumflexsmall",
"Otildesmall", "Odieresissmall", "OEsmall", "Oslashsmall", "Ugravesmall",
"Uacutesmall", "Ucircumflexsmall", "Udieresissmall", "Yacutesmall",
"Thornsmall", "Ydieresissmall", "001.000", "001.001", "001.002", "001.003",
"Black", "Bold", "Book", "Light", "Medium", "Regular", "Roman", "Semibold"
];
const NUM_STANDARD_CFF_STRINGS = 391;
const CFFParser = (function CFFParserClosure() {
const CharstringValidationData = [
null,
{ id: "hstem", min: 2, stackClearing: true, stem: true },
null,
{ id: "vstem", min: 2, stackClearing: true, stem: true },
{ id: "vmoveto", min: 1, stackClearing: true },
{ id: "rlineto", min: 2, resetStack: true },
{ id: "hlineto", min: 1, resetStack: true },
{ id: "vlineto", min: 1, resetStack: true },
{ id: "rrcurveto", min: 6, resetStack: true },
null,
{ id: "callsubr", min: 1, undefStack: true },
{ id: "return", min: 0, undefStack: true },
null, // 12
null,
{ id: "endchar", min: 0, stackClearing: true },
null,
null,
null,
{ id: "hstemhm", min: 2, stackClearing: true, stem: true },
{ id: "hintmask", min: 0, stackClearing: true },
{ id: "cntrmask", min: 0, stackClearing: true },
{ id: "rmoveto", min: 2, stackClearing: true },
{ id: "hmoveto", min: 1, stackClearing: true },
{ id: "vstemhm", min: 2, stackClearing: true, stem: true },
{ id: "rcurveline", min: 8, resetStack: true },
{ id: "rlinecurve", min: 8, resetStack: true },
{ id: "vvcurveto", min: 4, resetStack: true },
{ id: "hhcurveto", min: 4, resetStack: true },
null, // shortint
{ id: "callgsubr", min: 1, undefStack: true },
{ id: "vhcurveto", min: 4, resetStack: true },
{ id: "hvcurveto", min: 4, resetStack: true },
];
const CharstringValidationData12 = [
null,
null,
null,
{ id: "and", min: 2, stackDelta: -1 },
{ id: "or", min: 2, stackDelta: -1 },
{ id: "not", min: 1, stackDelta: 0 },
null,
null,
null,
{ id: "abs", min: 1, stackDelta: 0 },
{
id: "add",
min: 2,
stackDelta: -1,
stackFn: function stack_div(stack, index) {
stack[index - 2] = stack[index - 2] + stack[index - 1];
},
},
{
id: "sub",
min: 2,
stackDelta: -1,
stackFn: function stack_div(stack, index) {
stack[index - 2] = stack[index - 2] - stack[index - 1];
},
},
{
id: "div",
min: 2,
stackDelta: -1,
stackFn: function stack_div(stack, index) {
stack[index - 2] = stack[index - 2] / stack[index - 1];
},
},
null,
{
id: "neg",
min: 1,
stackDelta: 0,
stackFn: function stack_div(stack, index) {
stack[index - 1] = -stack[index - 1];
},
},
{ id: "eq", min: 2, stackDelta: -1 },
null,
null,
{ id: "drop", min: 1, stackDelta: -1 },
null,
{ id: "put", min: 2, stackDelta: -2 },
{ id: "get", min: 1, stackDelta: 0 },
{ id: "ifelse", min: 4, stackDelta: -3 },
{ id: "random", min: 0, stackDelta: 1 },
{
id: "mul",
min: 2,
stackDelta: -1,
stackFn: function stack_div(stack, index) {
stack[index - 2] = stack[index - 2] * stack[index - 1];
},
},
null,
{ id: "sqrt", min: 1, stackDelta: 0 },
{ id: "dup", min: 1, stackDelta: 1 },
{ id: "exch", min: 2, stackDelta: 0 },
{ id: "index", min: 2, stackDelta: 0 },
{ id: "roll", min: 3, stackDelta: -2 },
null,
null,
null,
{ id: "hflex", min: 7, resetStack: true },
{ id: "flex", min: 13, resetStack: true },
{ id: "hflex1", min: 9, resetStack: true },
{ id: "flex1", min: 11, resetStack: true },
];
// eslint-disable-next-line no-shadow
class CFFParser {
constructor(file, properties, seacAnalysisEnabled) {
this.bytes = file.getBytes();
this.properties = properties;
this.seacAnalysisEnabled = !!seacAnalysisEnabled;
}
parse() {
const properties = this.properties;
const cff = new CFF();
this.cff = cff;
// The first five sections must be in order, all the others are reached
// via offsets contained in one of the below.
const header = this.parseHeader();
const nameIndex = this.parseIndex(header.endPos);
const topDictIndex = this.parseIndex(nameIndex.endPos);
const stringIndex = this.parseIndex(topDictIndex.endPos);
const globalSubrIndex = this.parseIndex(stringIndex.endPos);
const topDictParsed = this.parseDict(topDictIndex.obj.get(0));
const topDict = this.createDict(CFFTopDict, topDictParsed, cff.strings);
cff.header = header.obj;
cff.names = this.parseNameIndex(nameIndex.obj);
cff.strings = this.parseStringIndex(stringIndex.obj);
cff.topDict = topDict;
cff.globalSubrIndex = globalSubrIndex.obj;
this.parsePrivateDict(cff.topDict);
cff.isCIDFont = topDict.hasName("ROS");
const charStringOffset = topDict.getByName("CharStrings");
const charStringIndex = this.parseIndex(charStringOffset).obj;
const fontMatrix = topDict.getByName("FontMatrix");
if (fontMatrix) {
properties.fontMatrix = fontMatrix;
}
const fontBBox = topDict.getByName("FontBBox");
if (fontBBox) {
// adjusting ascent/descent
properties.ascent = Math.max(fontBBox[3], fontBBox[1]);
properties.descent = Math.min(fontBBox[1], fontBBox[3]);
properties.ascentScaled = true;
}
let charset, encoding;
if (cff.isCIDFont) {
const fdArrayIndex = this.parseIndex(topDict.getByName("FDArray")).obj;
for (let i = 0, ii = fdArrayIndex.count; i < ii; ++i) {
const dictRaw = fdArrayIndex.get(i);
const fontDict = this.createDict(
CFFTopDict,
this.parseDict(dictRaw),
cff.strings
);
this.parsePrivateDict(fontDict);
cff.fdArray.push(fontDict);
}
// cid fonts don't have an encoding
encoding = null;
charset = this.parseCharsets(
topDict.getByName("charset"),
charStringIndex.count,
cff.strings,
true
);
cff.fdSelect = this.parseFDSelect(
topDict.getByName("FDSelect"),
charStringIndex.count
);
} else {
charset = this.parseCharsets(
topDict.getByName("charset"),
charStringIndex.count,
cff.strings,
false
);
encoding = this.parseEncoding(
topDict.getByName("Encoding"),
properties,
cff.strings,
charset.charset
);
}
cff.charset = charset;
cff.encoding = encoding;
const charStringsAndSeacs = this.parseCharStrings({
charStrings: charStringIndex,
localSubrIndex: topDict.privateDict.subrsIndex,
globalSubrIndex: globalSubrIndex.obj,
fdSelect: cff.fdSelect,
fdArray: cff.fdArray,
privateDict: topDict.privateDict,
});
cff.charStrings = charStringsAndSeacs.charStrings;
cff.seacs = charStringsAndSeacs.seacs;
cff.widths = charStringsAndSeacs.widths;
return cff;
}
parseHeader() {
let bytes = this.bytes;
const bytesLength = bytes.length;
let offset = 0;
// Prevent an infinite loop, by checking that the offset is within the
// bounds of the bytes array. Necessary in empty, or invalid, font files.
while (offset < bytesLength && bytes[offset] !== 1) {
++offset;
}
if (offset >= bytesLength) {
throw new FormatError("Invalid CFF header");
}
if (offset !== 0) {
info("cff data is shifted");
bytes = bytes.subarray(offset);
this.bytes = bytes;
}
const major = bytes[0];
const minor = bytes[1];
const hdrSize = bytes[2];
const offSize = bytes[3];
const header = new CFFHeader(major, minor, hdrSize, offSize);
return { obj: header, endPos: hdrSize };
}
parseDict(dict) {
let pos = 0;
function parseOperand() {
let value = dict[pos++];
if (value === 30) {
return parseFloatOperand();
} else if (value === 28) {
value = dict[pos++];
value = ((value << 24) | (dict[pos++] << 16)) >> 16;
return value;
} else if (value === 29) {
value = dict[pos++];
value = (value << 8) | dict[pos++];
value = (value << 8) | dict[pos++];
value = (value << 8) | dict[pos++];
return value;
} else if (value >= 32 && value <= 246) {
return value - 139;
} else if (value >= 247 && value <= 250) {
return (value - 247) * 256 + dict[pos++] + 108;
} else if (value >= 251 && value <= 254) {
return -((value - 251) * 256) - dict[pos++] - 108;
}
warn('CFFParser_parseDict: "' + value + '" is a reserved command.');
return NaN;
}
function parseFloatOperand() {
let str = "";
const eof = 15;
// prettier-ignore
const lookup = ["0", "1", "2", "3", "4", "5", "6", "7", "8",
"9", ".", "E", "E-", null, "-"];
const length = dict.length;
while (pos < length) {
const b = dict[pos++];
const b1 = b >> 4;
const b2 = b & 15;
if (b1 === eof) {
break;
}
str += lookup[b1];
if (b2 === eof) {
break;
}
str += lookup[b2];
}
return parseFloat(str);
}
let operands = [];
const entries = [];
pos = 0;
const end = dict.length;
while (pos < end) {
let b = dict[pos];
if (b <= 21) {
if (b === 12) {
b = (b << 8) | dict[++pos];
}
entries.push([b, operands]);
operands = [];
++pos;
} else {
operands.push(parseOperand());
}
}
return entries;
}
parseIndex(pos) {
const cffIndex = new CFFIndex();
const bytes = this.bytes;
const count = (bytes[pos++] << 8) | bytes[pos++];
const offsets = [];
let end = pos;
let i, ii;
if (count !== 0) {
const offsetSize = bytes[pos++];
// add 1 for offset to determine size of last object
const startPos = pos + (count + 1) * offsetSize - 1;
for (i = 0, ii = count + 1; i < ii; ++i) {
let offset = 0;
for (let j = 0; j < offsetSize; ++j) {
offset <<= 8;
offset += bytes[pos++];
}
offsets.push(startPos + offset);
}
end = offsets[count];
}
for (i = 0, ii = offsets.length - 1; i < ii; ++i) {
const offsetStart = offsets[i];
const offsetEnd = offsets[i + 1];
cffIndex.add(bytes.subarray(offsetStart, offsetEnd));
}
return { obj: cffIndex, endPos: end };
}
parseNameIndex(index) {
const names = [];
for (let i = 0, ii = index.count; i < ii; ++i) {
const name = index.get(i);
names.push(bytesToString(name));
}
return names;
}
parseStringIndex(index) {
const strings = new CFFStrings();
for (let i = 0, ii = index.count; i < ii; ++i) {
const data = index.get(i);
strings.add(bytesToString(data));
}
return strings;
}
createDict(Type, dict, strings) {
const cffDict = new Type(strings);
for (let i = 0, ii = dict.length; i < ii; ++i) {
const pair = dict[i];
const key = pair[0];
const value = pair[1];
cffDict.setByKey(key, value);
}
return cffDict;
}
parseCharString(state, data, localSubrIndex, globalSubrIndex) {
if (!data || state.callDepth > MAX_SUBR_NESTING) {
return false;
}
let stackSize = state.stackSize;
const stack = state.stack;
const length = data.length;
for (let j = 0; j < length; ) {
const value = data[j++];
let validationCommand = null;
if (value === 12) {
const q = data[j++];
if (q === 0) {
// The CFF specification state that the 'dotsection' command
// (12, 0) is deprecated and treated as a no-op, but all Type2
// charstrings processors should support them. Unfortunately
// the font sanitizer don't. As a workaround the sequence (12, 0)
// is replaced by a useless (0, hmoveto).
data[j - 2] = 139;
data[j - 1] = 22;
stackSize = 0;
} else {
validationCommand = CharstringValidationData12[q];
}
} else if (value === 28) {
// number (16 bit)
stack[stackSize] = ((data[j] << 24) | (data[j + 1] << 16)) >> 16;
j += 2;
stackSize++;
} else if (value === 14) {
if (stackSize >= 4) {
stackSize -= 4;
if (this.seacAnalysisEnabled) {
state.seac = stack.slice(stackSize, stackSize + 4);
return false;
}
}
validationCommand = CharstringValidationData[value];
} else if (value >= 32 && value <= 246) {
// number
stack[stackSize] = value - 139;
stackSize++;
} else if (value >= 247 && value <= 254) {
// number (+1 bytes)
stack[stackSize] =
value < 251
? ((value - 247) << 8) + data[j] + 108
: -((value - 251) << 8) - data[j] - 108;
j++;
stackSize++;
} else if (value === 255) {
// number (32 bit)
stack[stackSize] =
((data[j] << 24) |
(data[j + 1] << 16) |
(data[j + 2] << 8) |
data[j + 3]) /
65536;
j += 4;
stackSize++;
} else if (value === 19 || value === 20) {
state.hints += stackSize >> 1;
// skipping right amount of hints flag data
j += (state.hints + 7) >> 3;
stackSize %= 2;
validationCommand = CharstringValidationData[value];
} else if (value === 10 || value === 29) {
let subrsIndex;
if (value === 10) {
subrsIndex = localSubrIndex;
} else {
subrsIndex = globalSubrIndex;
}
if (!subrsIndex) {
validationCommand = CharstringValidationData[value];
warn("Missing subrsIndex for " + validationCommand.id);
return false;
}
let bias = 32768;
if (subrsIndex.count < 1240) {
bias = 107;
} else if (subrsIndex.count < 33900) {
bias = 1131;
}
const subrNumber = stack[--stackSize] + bias;
if (
subrNumber < 0 ||
subrNumber >= subrsIndex.count ||
isNaN(subrNumber)
) {
validationCommand = CharstringValidationData[value];
warn("Out of bounds subrIndex for " + validationCommand.id);
return false;
}
state.stackSize = stackSize;
state.callDepth++;
const valid = this.parseCharString(
state,
subrsIndex.get(subrNumber),
localSubrIndex,
globalSubrIndex
);
if (!valid) {
return false;
}
state.callDepth--;
stackSize = state.stackSize;
continue;
} else if (value === 11) {
state.stackSize = stackSize;
return true;
} else {
validationCommand = CharstringValidationData[value];
}
if (validationCommand) {
if (validationCommand.stem) {
state.hints += stackSize >> 1;
if (value === 3 || value === 23) {
// vstem or vstemhm.
state.hasVStems = true;
} else if (state.hasVStems && (value === 1 || value === 18)) {
// Some browsers don't draw glyphs that specify vstems before
// hstems. As a workaround, replace hstem (1) and hstemhm (18)
// with a pointless vstem (3) or vstemhm (23).
warn("CFF stem hints are in wrong order");
data[j - 1] = value === 1 ? 3 : 23;
}
}
if ("min" in validationCommand) {
if (!state.undefStack && stackSize < validationCommand.min) {
warn(
"Not enough parameters for " +
validationCommand.id +
"; actual: " +
stackSize +
", expected: " +
validationCommand.min
);
return false;
}
}
if (state.firstStackClearing && validationCommand.stackClearing) {
state.firstStackClearing = false;
// the optional character width can be found before the first
// stack-clearing command arguments
stackSize -= validationCommand.min;
if (stackSize >= 2 && validationCommand.stem) {
// there are even amount of arguments for stem commands
stackSize %= 2;
} else if (stackSize > 1) {
warn("Found too many parameters for stack-clearing command");
}
if (stackSize > 0 && stack[stackSize - 1] >= 0) {
state.width = stack[stackSize - 1];
}
}
if ("stackDelta" in validationCommand) {
if ("stackFn" in validationCommand) {
validationCommand.stackFn(stack, stackSize);
}
stackSize += validationCommand.stackDelta;
} else if (validationCommand.stackClearing) {
stackSize = 0;
} else if (validationCommand.resetStack) {
stackSize = 0;
state.undefStack = false;
} else if (validationCommand.undefStack) {
stackSize = 0;
state.undefStack = true;
state.firstStackClearing = false;
}
}
}
state.stackSize = stackSize;
return true;
}
parseCharStrings({
charStrings,
localSubrIndex,
globalSubrIndex,
fdSelect,
fdArray,
privateDict,
}) {
const seacs = [];
const widths = [];
const count = charStrings.count;
for (let i = 0; i < count; i++) {
const charstring = charStrings.get(i);
const state = {
callDepth: 0,
stackSize: 0,
stack: [],
undefStack: true,
hints: 0,
firstStackClearing: true,
seac: null,
width: null,
hasVStems: false,
};
let valid = true;
let localSubrToUse = null;
let privateDictToUse = privateDict;
if (fdSelect && fdArray.length) {
const fdIndex = fdSelect.getFDIndex(i);
if (fdIndex === -1) {
warn("Glyph index is not in fd select.");
valid = false;
}
if (fdIndex >= fdArray.length) {
warn("Invalid fd index for glyph index.");
valid = false;
}
if (valid) {
privateDictToUse = fdArray[fdIndex].privateDict;
localSubrToUse = privateDictToUse.subrsIndex;
}
} else if (localSubrIndex) {
localSubrToUse = localSubrIndex;
}
if (valid) {
valid = this.parseCharString(
state,
charstring,
localSubrToUse,
globalSubrIndex
);
}
if (state.width !== null) {
const nominalWidth = privateDictToUse.getByName("nominalWidthX");
widths[i] = nominalWidth + state.width;
} else {
const defaultWidth = privateDictToUse.getByName("defaultWidthX");
widths[i] = defaultWidth;
}
if (state.seac !== null) {
seacs[i] = state.seac;
}
if (!valid) {
// resetting invalid charstring to single 'endchar'
charStrings.set(i, new Uint8Array([14]));
}
}
return { charStrings, seacs, widths };
}
emptyPrivateDictionary(parentDict) {
const privateDict = this.createDict(
CFFPrivateDict,
[],
parentDict.strings
);
parentDict.setByKey(18, [0, 0]);
parentDict.privateDict = privateDict;
}
parsePrivateDict(parentDict) {
// no private dict, do nothing
if (!parentDict.hasName("Private")) {
this.emptyPrivateDictionary(parentDict);
return;
}
const privateOffset = parentDict.getByName("Private");
// make sure the params are formatted correctly
if (!Array.isArray(privateOffset) || privateOffset.length !== 2) {
parentDict.removeByName("Private");
return;
}
const size = privateOffset[0];
const offset = privateOffset[1];
// remove empty dicts or ones that refer to invalid location
if (size === 0 || offset >= this.bytes.length) {
this.emptyPrivateDictionary(parentDict);
return;
}
const privateDictEnd = offset + size;
const dictData = this.bytes.subarray(offset, privateDictEnd);
const dict = this.parseDict(dictData);
const privateDict = this.createDict(
CFFPrivateDict,
dict,
parentDict.strings
);
parentDict.privateDict = privateDict;
// Parse the Subrs index also since it's relative to the private dict.
if (!privateDict.getByName("Subrs")) {
return;
}
const subrsOffset = privateDict.getByName("Subrs");
const relativeOffset = offset + subrsOffset;
// Validate the offset.
if (subrsOffset === 0 || relativeOffset >= this.bytes.length) {
this.emptyPrivateDictionary(parentDict);
return;
}
const subrsIndex = this.parseIndex(relativeOffset);
privateDict.subrsIndex = subrsIndex.obj;
}
parseCharsets(pos, length, strings, cid) {
if (pos === 0) {
return new CFFCharset(
true,
CFFCharsetPredefinedTypes.ISO_ADOBE,
ISOAdobeCharset
);
} else if (pos === 1) {
return new CFFCharset(
true,
CFFCharsetPredefinedTypes.EXPERT,
ExpertCharset
);
} else if (pos === 2) {
return new CFFCharset(
true,
CFFCharsetPredefinedTypes.EXPERT_SUBSET,
ExpertSubsetCharset
);
}
const bytes = this.bytes;
const start = pos;
const format = bytes[pos++];
const charset = [cid ? 0 : ".notdef"];
let id, count, i;
// subtract 1 for the .notdef glyph
length -= 1;
switch (format) {
case 0:
for (i = 0; i < length; i++) {
id = (bytes[pos++] << 8) | bytes[pos++];
charset.push(cid ? id : strings.get(id));
}
break;
case 1:
while (charset.length <= length) {
id = (bytes[pos++] << 8) | bytes[pos++];
count = bytes[pos++];
for (i = 0; i <= count; i++) {
charset.push(cid ? id++ : strings.get(id++));
}
}
break;
case 2:
while (charset.length <= length) {
id = (bytes[pos++] << 8) | bytes[pos++];
count = (bytes[pos++] << 8) | bytes[pos++];
for (i = 0; i <= count; i++) {
charset.push(cid ? id++ : strings.get(id++));
}
}
break;
default:
throw new FormatError("Unknown charset format");
}
// Raw won't be needed if we actually compile the charset.
const end = pos;
const raw = bytes.subarray(start, end);
return new CFFCharset(false, format, charset, raw);
}
parseEncoding(pos, properties, strings, charset) {
const encoding = Object.create(null);
const bytes = this.bytes;
let predefined = false;
let format, i, ii;
let raw = null;
function readSupplement() {
const supplementsCount = bytes[pos++];
for (i = 0; i < supplementsCount; i++) {
const code = bytes[pos++];
const sid = (bytes[pos++] << 8) + (bytes[pos++] & 0xff);
encoding[code] = charset.indexOf(strings.get(sid));
}
}
if (pos === 0 || pos === 1) {
predefined = true;
format = pos;
const baseEncoding = pos ? ExpertEncoding : StandardEncoding;
for (i = 0, ii = charset.length; i < ii; i++) {
const index = baseEncoding.indexOf(charset[i]);
if (index !== -1) {
encoding[index] = i;
}
}
} else {
const dataStart = pos;
format = bytes[pos++];
switch (format & 0x7f) {
case 0:
const glyphsCount = bytes[pos++];
for (i = 1; i <= glyphsCount; i++) {
encoding[bytes[pos++]] = i;
}
break;
case 1:
const rangesCount = bytes[pos++];
let gid = 1;
for (i = 0; i < rangesCount; i++) {
const start = bytes[pos++];
const left = bytes[pos++];
for (let j = start; j <= start + left; j++) {
encoding[j] = gid++;
}
}
break;
default:
throw new FormatError(`Unknown encoding format: ${format} in CFF`);
}
const dataEnd = pos;
if (format & 0x80) {
// hasSupplement
// The font sanitizer does not support CFF encoding with a
// supplement, since the encoding is not really used to map
// between gid to glyph, let's overwrite what is declared in
// the top dictionary to let the sanitizer think the font use
// StandardEncoding, that's a lie but that's ok.
bytes[dataStart] &= 0x7f;
readSupplement();
}
raw = bytes.subarray(dataStart, dataEnd);
}
format = format & 0x7f;
return new CFFEncoding(predefined, format, encoding, raw);
}
parseFDSelect(pos, length) {
const bytes = this.bytes;
const format = bytes[pos++];
const fdSelect = [];
let i;
switch (format) {
case 0:
for (i = 0; i < length; ++i) {
const id = bytes[pos++];
fdSelect.push(id);
}
break;
case 3:
const rangesCount = (bytes[pos++] << 8) | bytes[pos++];
for (i = 0; i < rangesCount; ++i) {
let first = (bytes[pos++] << 8) | bytes[pos++];
if (i === 0 && first !== 0) {
warn(
"parseFDSelect: The first range must have a first GID of 0" +
" -- trying to recover."
);
first = 0;
}
const fdIndex = bytes[pos++];
const next = (bytes[pos] << 8) | bytes[pos + 1];
for (let j = first; j < next; ++j) {
fdSelect.push(fdIndex);
}
}
// Advance past the sentinel(next).
pos += 2;
break;
default:
throw new FormatError(`parseFDSelect: Unknown format "${format}".`);
}
if (fdSelect.length !== length) {
throw new FormatError("parseFDSelect: Invalid font data.");
}
return new CFFFDSelect(format, fdSelect);
}
}
return CFFParser;
})();
// Compact Font Format
class CFF {
constructor() {
this.header = null;
this.names = [];
this.topDict = null;
this.strings = new CFFStrings();
this.globalSubrIndex = null;
// The following could really be per font, but since we only have one font
// store them here.
this.encoding = null;
this.charset = null;
this.charStrings = null;
this.fdArray = [];
this.fdSelect = null;
this.isCIDFont = false;
}
duplicateFirstGlyph() {
// Browsers will not display a glyph at position 0. Typically glyph 0 is
// notdef, but a number of fonts put a valid glyph there so it must be
// duplicated and appended.
if (this.charStrings.count >= 65535) {
warn("Not enough space in charstrings to duplicate first glyph.");
return;
}
const glyphZero = this.charStrings.get(0);
this.charStrings.add(glyphZero);
if (this.isCIDFont) {
this.fdSelect.fdSelect.push(this.fdSelect.fdSelect[0]);
}
}
hasGlyphId(id) {
if (id < 0 || id >= this.charStrings.count) {
return false;
}
const glyph = this.charStrings.get(id);
return glyph.length > 0;
}
}
class CFFHeader {
constructor(major, minor, hdrSize, offSize) {
this.major = major;
this.minor = minor;
this.hdrSize = hdrSize;
this.offSize = offSize;
}
}
class CFFStrings {
constructor() {
this.strings = [];
}
get(index) {
if (index >= 0 && index <= NUM_STANDARD_CFF_STRINGS - 1) {
return CFFStandardStrings[index];
}
if (index - NUM_STANDARD_CFF_STRINGS <= this.strings.length) {
return this.strings[index - NUM_STANDARD_CFF_STRINGS];
}
return CFFStandardStrings[0];
}
getSID(str) {
let index = CFFStandardStrings.indexOf(str);
if (index !== -1) {
return index;
}
index = this.strings.indexOf(str);
if (index !== -1) {
return index + NUM_STANDARD_CFF_STRINGS;
}
return -1;
}
add(value) {
this.strings.push(value);
}
get count() {
return this.strings.length;
}
}
class CFFIndex {
constructor() {
this.objects = [];
this.length = 0;
}
add(data) {
this.length += data.length;
this.objects.push(data);
}
set(index, data) {
this.length += data.length - this.objects[index].length;
this.objects[index] = data;
}
get(index) {
return this.objects[index];
}
get count() {
return this.objects.length;
}
}
class CFFDict {
constructor(tables, strings) {
this.keyToNameMap = tables.keyToNameMap;
this.nameToKeyMap = tables.nameToKeyMap;
this.defaults = tables.defaults;
this.types = tables.types;
this.opcodes = tables.opcodes;
this.order = tables.order;
this.strings = strings;
this.values = Object.create(null);
}
// value should always be an array
setByKey(key, value) {
if (!(key in this.keyToNameMap)) {
return false;
}
const valueLength = value.length;
// ignore empty values
if (valueLength === 0) {
return true;
}
// Ignore invalid values (fixes bug1068432.pdf and bug1308536.pdf).
for (let i = 0; i < valueLength; i++) {
if (isNaN(value[i])) {
warn('Invalid CFFDict value: "' + value + '" for key "' + key + '".');
return true;
}
}
const type = this.types[key];
// remove the array wrapping these types of values
if (type === "num" || type === "sid" || type === "offset") {
value = value[0];
}
this.values[key] = value;
return true;
}
setByName(name, value) {
if (!(name in this.nameToKeyMap)) {
throw new FormatError(`Invalid dictionary name "${name}"`);
}
this.values[this.nameToKeyMap[name]] = value;
}
hasName(name) {
return this.nameToKeyMap[name] in this.values;
}
getByName(name) {
if (!(name in this.nameToKeyMap)) {
throw new FormatError(`Invalid dictionary name ${name}"`);
}
const key = this.nameToKeyMap[name];
if (!(key in this.values)) {
return this.defaults[key];
}
return this.values[key];
}
removeByName(name) {
delete this.values[this.nameToKeyMap[name]];
}
static createTables(layout) {
const tables = {
keyToNameMap: {},
nameToKeyMap: {},
defaults: {},
types: {},
opcodes: {},
order: [],
};
for (let i = 0, ii = layout.length; i < ii; ++i) {
const entry = layout[i];
const key = Array.isArray(entry[0])
? (entry[0][0] << 8) + entry[0][1]
: entry[0];
tables.keyToNameMap[key] = entry[1];
tables.nameToKeyMap[entry[1]] = key;
tables.types[key] = entry[2];
tables.defaults[key] = entry[3];
tables.opcodes[key] = Array.isArray(entry[0]) ? entry[0] : [entry[0]];
tables.order.push(key);
}
return tables;
}
}
const CFFTopDict = (function CFFTopDictClosure() {
const layout = [
[[12, 30], "ROS", ["sid", "sid", "num"], null],
[[12, 20], "SyntheticBase", "num", null],
[0, "version", "sid", null],
[1, "Notice", "sid", null],
[[12, 0], "Copyright", "sid", null],
[2, "FullName", "sid", null],
[3, "FamilyName", "sid", null],
[4, "Weight", "sid", null],
[[12, 1], "isFixedPitch", "num", 0],
[[12, 2], "ItalicAngle", "num", 0],
[[12, 3], "UnderlinePosition", "num", -100],
[[12, 4], "UnderlineThickness", "num", 50],
[[12, 5], "PaintType", "num", 0],
[[12, 6], "CharstringType", "num", 2],
// prettier-ignore
[[12, 7], "FontMatrix", ["num", "num", "num", "num", "num", "num"],
[0.001, 0, 0, 0.001, 0, 0]],
[13, "UniqueID", "num", null],
[5, "FontBBox", ["num", "num", "num", "num"], [0, 0, 0, 0]],
[[12, 8], "StrokeWidth", "num", 0],
[14, "XUID", "array", null],
[15, "charset", "offset", 0],
[16, "Encoding", "offset", 0],
[17, "CharStrings", "offset", 0],
[18, "Private", ["offset", "offset"], null],
[[12, 21], "PostScript", "sid", null],
[[12, 22], "BaseFontName", "sid", null],
[[12, 23], "BaseFontBlend", "delta", null],
[[12, 31], "CIDFontVersion", "num", 0],
[[12, 32], "CIDFontRevision", "num", 0],
[[12, 33], "CIDFontType", "num", 0],
[[12, 34], "CIDCount", "num", 8720],
[[12, 35], "UIDBase", "num", null],
// XXX: CID Fonts on DirectWrite 6.1 only seem to work if FDSelect comes
// before FDArray.
[[12, 37], "FDSelect", "offset", null],
[[12, 36], "FDArray", "offset", null],
[[12, 38], "FontName", "sid", null],
];
let tables = null;
// eslint-disable-next-line no-shadow
class CFFTopDict extends CFFDict {
constructor(strings) {
if (tables === null) {
tables = CFFDict.createTables(layout);
}
super(tables, strings);
this.privateDict = null;
}
}
return CFFTopDict;
})();
const CFFPrivateDict = (function CFFPrivateDictClosure() {
const layout = [
[6, "BlueValues", "delta", null],
[7, "OtherBlues", "delta", null],
[8, "FamilyBlues", "delta", null],
[9, "FamilyOtherBlues", "delta", null],
[[12, 9], "BlueScale", "num", 0.039625],
[[12, 10], "BlueShift", "num", 7],
[[12, 11], "BlueFuzz", "num", 1],
[10, "StdHW", "num", null],
[11, "StdVW", "num", null],
[[12, 12], "StemSnapH", "delta", null],
[[12, 13], "StemSnapV", "delta", null],
[[12, 14], "ForceBold", "num", 0],
[[12, 17], "LanguageGroup", "num", 0],
[[12, 18], "ExpansionFactor", "num", 0.06],
[[12, 19], "initialRandomSeed", "num", 0],
[20, "defaultWidthX", "num", 0],
[21, "nominalWidthX", "num", 0],
[19, "Subrs", "offset", null],
];
let tables = null;
// eslint-disable-next-line no-shadow
class CFFPrivateDict extends CFFDict {
constructor(strings) {
if (tables === null) {
tables = CFFDict.createTables(layout);
}
super(tables, strings);
this.subrsIndex = null;
}
}
return CFFPrivateDict;
})();
const CFFCharsetPredefinedTypes = {
ISO_ADOBE: 0,
EXPERT: 1,
EXPERT_SUBSET: 2,
};
class CFFCharset {
constructor(predefined, format, charset, raw) {
this.predefined = predefined;
this.format = format;
this.charset = charset;
this.raw = raw;
}
}
class CFFEncoding {
constructor(predefined, format, encoding, raw) {
this.predefined = predefined;
this.format = format;
this.encoding = encoding;
this.raw = raw;
}
}
class CFFFDSelect {
constructor(format, fdSelect) {
this.format = format;
this.fdSelect = fdSelect;
}
getFDIndex(glyphIndex) {
if (glyphIndex < 0 || glyphIndex >= this.fdSelect.length) {
return -1;
}
return this.fdSelect[glyphIndex];
}
}
// Helper class to keep track of where an offset is within the data and helps
// filling in that offset once it's known.
class CFFOffsetTracker {
constructor() {
this.offsets = Object.create(null);
}
isTracking(key) {
return key in this.offsets;
}
track(key, location) {
if (key in this.offsets) {
throw new FormatError(`Already tracking location of ${key}`);
}
this.offsets[key] = location;
}
offset(value) {
for (const key in this.offsets) {
this.offsets[key] += value;
}
}
setEntryLocation(key, values, output) {
if (!(key in this.offsets)) {
throw new FormatError(`Not tracking location of ${key}`);
}
const data = output.data;
const dataOffset = this.offsets[key];
const size = 5;
for (let i = 0, ii = values.length; i < ii; ++i) {
const offset0 = i * size + dataOffset;
const offset1 = offset0 + 1;
const offset2 = offset0 + 2;
const offset3 = offset0 + 3;
const offset4 = offset0 + 4;
// It's easy to screw up offsets so perform this sanity check.
if (
data[offset0] !== 0x1d ||
data[offset1] !== 0 ||
data[offset2] !== 0 ||
data[offset3] !== 0 ||
data[offset4] !== 0
) {
throw new FormatError("writing to an offset that is not empty");
}
const value = values[i];
data[offset0] = 0x1d;
data[offset1] = (value >> 24) & 0xff;
data[offset2] = (value >> 16) & 0xff;
data[offset3] = (value >> 8) & 0xff;
data[offset4] = value & 0xff;
}
}
}
// Takes a CFF and converts it to the binary representation.
class CFFCompiler {
constructor(cff) {
this.cff = cff;
}
compile() {
const cff = this.cff;
const output = {
data: [],
length: 0,
add: function CFFCompiler_add(data) {
this.data = this.data.concat(data);
this.length = this.data.length;
},
};
// Compile the five entries that must be in order.
const header = this.compileHeader(cff.header);
output.add(header);
const nameIndex = this.compileNameIndex(cff.names);
output.add(nameIndex);
if (cff.isCIDFont) {
// The spec is unclear on how font matrices should relate to each other
// when there is one in the main top dict and the sub top dicts.
// Windows handles this differently than linux and osx so we have to
// normalize to work on all.
// Rules based off of some mailing list discussions:
// - If main font has a matrix and subfont doesn't, use the main matrix.
// - If no main font matrix and there is a subfont matrix, use the
// subfont matrix.
// - If both have matrices, concat together.
// - If neither have matrices, use default.
// To make this work on all platforms we move the top matrix into each
// sub top dict and concat if necessary.
if (cff.topDict.hasName("FontMatrix")) {
const base = cff.topDict.getByName("FontMatrix");
cff.topDict.removeByName("FontMatrix");
for (let i = 0, ii = cff.fdArray.length; i < ii; i++) {
const subDict = cff.fdArray[i];
let matrix = base.slice(0);
if (subDict.hasName("FontMatrix")) {
matrix = Util.transform(matrix, subDict.getByName("FontMatrix"));
}
subDict.setByName("FontMatrix", matrix);
}
}
}
const xuid = cff.topDict.getByName("XUID");
if (xuid && xuid.length > 16) {
// Length of XUID array must not be greater than 16 (issue #12399).
cff.topDict.removeByName("XUID");
}
cff.topDict.setByName("charset", 0);
let compiled = this.compileTopDicts(
[cff.topDict],
output.length,
cff.isCIDFont
);
output.add(compiled.output);
const topDictTracker = compiled.trackers[0];
const stringIndex = this.compileStringIndex(cff.strings.strings);
output.add(stringIndex);
const globalSubrIndex = this.compileIndex(cff.globalSubrIndex);
output.add(globalSubrIndex);
// Now start on the other entries that have no specific order.
if (cff.encoding && cff.topDict.hasName("Encoding")) {
if (cff.encoding.predefined) {
topDictTracker.setEntryLocation(
"Encoding",
[cff.encoding.format],
output
);
} else {
const encoding = this.compileEncoding(cff.encoding);
topDictTracker.setEntryLocation("Encoding", [output.length], output);
output.add(encoding);
}
}
const charset = this.compileCharset(
cff.charset,
cff.charStrings.count,
cff.strings,
cff.isCIDFont
);
topDictTracker.setEntryLocation("charset", [output.length], output);
output.add(charset);
const charStrings = this.compileCharStrings(cff.charStrings);
topDictTracker.setEntryLocation("CharStrings", [output.length], output);
output.add(charStrings);
if (cff.isCIDFont) {
// For some reason FDSelect must be in front of FDArray on windows. OSX
// and linux don't seem to care.
topDictTracker.setEntryLocation("FDSelect", [output.length], output);
const fdSelect = this.compileFDSelect(cff.fdSelect);
output.add(fdSelect);
// It is unclear if the sub font dictionary can have CID related
// dictionary keys, but the sanitizer doesn't like them so remove them.
compiled = this.compileTopDicts(cff.fdArray, output.length, true);
topDictTracker.setEntryLocation("FDArray", [output.length], output);
output.add(compiled.output);
const fontDictTrackers = compiled.trackers;
this.compilePrivateDicts(cff.fdArray, fontDictTrackers, output);
}
this.compilePrivateDicts([cff.topDict], [topDictTracker], output);
// If the font data ends with INDEX whose object data is zero-length,
// the sanitizer will bail out. Add a dummy byte to avoid that.
output.add([0]);
return output.data;
}
encodeNumber(value) {
if (Number.isInteger(value)) {
return this.encodeInteger(value);
}
return this.encodeFloat(value);
}
static get EncodeFloatRegExp() {
return shadow(
this,
"EncodeFloatRegExp",
/\.(\d*?)(?:9{5,20}|0{5,20})\d{0,2}(?:e(.+)|$)/
);
}
encodeFloat(num) {
let value = num.toString();
// Rounding inaccurate doubles.
const m = CFFCompiler.EncodeFloatRegExp.exec(value);
if (m) {
const epsilon = parseFloat("1e" + ((m[2] ? +m[2] : 0) + m[1].length));
value = (Math.round(num * epsilon) / epsilon).toString();
}
let nibbles = "";
let i, ii;
for (i = 0, ii = value.length; i < ii; ++i) {
const a = value[i];
if (a === "e") {
nibbles += value[++i] === "-" ? "c" : "b";
} else if (a === ".") {
nibbles += "a";
} else if (a === "-") {
nibbles += "e";
} else {
nibbles += a;
}
}
nibbles += nibbles.length & 1 ? "f" : "ff";
const out = [30];
for (i = 0, ii = nibbles.length; i < ii; i += 2) {
out.push(parseInt(nibbles.substring(i, i + 2), 16));
}
return out;
}
encodeInteger(value) {
let code;
if (value >= -107 && value <= 107) {
code = [value + 139];
} else if (value >= 108 && value <= 1131) {
value = value - 108;
code = [(value >> 8) + 247, value & 0xff];
} else if (value >= -1131 && value <= -108) {
value = -value - 108;
code = [(value >> 8) + 251, value & 0xff];
} else if (value >= -32768 && value <= 32767) {
code = [0x1c, (value >> 8) & 0xff, value & 0xff];
} else {
code = [
0x1d,
(value >> 24) & 0xff,
(value >> 16) & 0xff,
(value >> 8) & 0xff,
value & 0xff,
];
}
return code;
}
compileHeader(header) {
// `header.hdrSize` can be any value but we only write 4 values
// so header size is 4 (prevents OTS from rejecting the font).
return [header.major, header.minor, 4, header.offSize];
}
compileNameIndex(names) {
const nameIndex = new CFFIndex();
for (let i = 0, ii = names.length; i < ii; ++i) {
const name = names[i];
// OTS doesn't allow names to be over 127 characters.
const length = Math.min(name.length, 127);
let sanitizedName = new Array(length);
for (let j = 0; j < length; j++) {
// OTS requires chars to be between a range and not certain other
// chars.
let char = name[j];
if (
char < "!" ||
char > "~" ||
char === "[" ||
char === "]" ||
char === "(" ||
char === ")" ||
char === "{" ||
char === "}" ||
char === "<" ||
char === ">" ||
char === "/" ||
char === "%"
) {
char = "_";
}
sanitizedName[j] = char;
}
sanitizedName = sanitizedName.join("");
if (sanitizedName === "") {
sanitizedName = "Bad_Font_Name";
}
nameIndex.add(stringToBytes(sanitizedName));
}
return this.compileIndex(nameIndex);
}
compileTopDicts(dicts, length, removeCidKeys) {
const fontDictTrackers = [];
let fdArrayIndex = new CFFIndex();
for (let i = 0, ii = dicts.length; i < ii; ++i) {
const fontDict = dicts[i];
if (removeCidKeys) {
fontDict.removeByName("CIDFontVersion");
fontDict.removeByName("CIDFontRevision");
fontDict.removeByName("CIDFontType");
fontDict.removeByName("CIDCount");
fontDict.removeByName("UIDBase");
}
const fontDictTracker = new CFFOffsetTracker();
const fontDictData = this.compileDict(fontDict, fontDictTracker);
fontDictTrackers.push(fontDictTracker);
fdArrayIndex.add(fontDictData);
fontDictTracker.offset(length);
}
fdArrayIndex = this.compileIndex(fdArrayIndex, fontDictTrackers);
return {
trackers: fontDictTrackers,
output: fdArrayIndex,
};
}
compilePrivateDicts(dicts, trackers, output) {
for (let i = 0, ii = dicts.length; i < ii; ++i) {
const fontDict = dicts[i];
const privateDict = fontDict.privateDict;
if (!privateDict || !fontDict.hasName("Private")) {
throw new FormatError("There must be a private dictionary.");
}
const privateDictTracker = new CFFOffsetTracker();
const privateDictData = this.compileDict(privateDict, privateDictTracker);
let outputLength = output.length;
privateDictTracker.offset(outputLength);
if (!privateDictData.length) {
// The private dictionary was empty, set the output length to zero to
// ensure the offset length isn't out of bounds in the eyes of the
// sanitizer.
outputLength = 0;
}
trackers[i].setEntryLocation(
"Private",
[privateDictData.length, outputLength],
output
);
output.add(privateDictData);
if (privateDict.subrsIndex && privateDict.hasName("Subrs")) {
const subrs = this.compileIndex(privateDict.subrsIndex);
privateDictTracker.setEntryLocation(
"Subrs",
[privateDictData.length],
output
);
output.add(subrs);
}
}
}
compileDict(dict, offsetTracker) {
let out = [];
// The dictionary keys must be in a certain order.
const order = dict.order;
for (let i = 0; i < order.length; ++i) {
const key = order[i];
if (!(key in dict.values)) {
continue;
}
let values = dict.values[key];
let types = dict.types[key];
if (!Array.isArray(types)) {
types = [types];
}
if (!Array.isArray(values)) {
values = [values];
}
// Remove any empty dict values.
if (values.length === 0) {
continue;
}
for (let j = 0, jj = types.length; j < jj; ++j) {
const type = types[j];
const value = values[j];
switch (type) {
case "num":
case "sid":
out = out.concat(this.encodeNumber(value));
break;
case "offset":
// For offsets we just insert a 32bit integer so we don't have to
// deal with figuring out the length of the offset when it gets
// replaced later on by the compiler.
const name = dict.keyToNameMap[key];
// Some offsets have the offset and the length, so just record the
// position of the first one.
if (!offsetTracker.isTracking(name)) {
offsetTracker.track(name, out.length);
}
out = out.concat([0x1d, 0, 0, 0, 0]);
break;
case "array":
case "delta":
out = out.concat(this.encodeNumber(value));
for (let k = 1, kk = values.length; k < kk; ++k) {
out = out.concat(this.encodeNumber(values[k]));
}
break;
default:
throw new FormatError(`Unknown data type of ${type}`);
}
}
out = out.concat(dict.opcodes[key]);
}
return out;
}
compileStringIndex(strings) {
const stringIndex = new CFFIndex();
for (let i = 0, ii = strings.length; i < ii; ++i) {
stringIndex.add(stringToBytes(strings[i]));
}
return this.compileIndex(stringIndex);
}
compileGlobalSubrIndex() {
const globalSubrIndex = this.cff.globalSubrIndex;
this.out.writeByteArray(this.compileIndex(globalSubrIndex));
}
compileCharStrings(charStrings) {
const charStringsIndex = new CFFIndex();
for (let i = 0; i < charStrings.count; i++) {
const glyph = charStrings.get(i);
// If the CharString outline is empty, replace it with .notdef to
// prevent OTS from rejecting the font (fixes bug1252420.pdf).
if (glyph.length === 0) {
charStringsIndex.add(new Uint8Array([0x8b, 0x0e]));
continue;
}
charStringsIndex.add(glyph);
}
return this.compileIndex(charStringsIndex);
}
compileCharset(charset, numGlyphs, strings, isCIDFont) {
// Freetype requires the number of charset strings be correct and MacOS
// requires a valid mapping for printing.
let out;
const numGlyphsLessNotDef = numGlyphs - 1;
if (isCIDFont) {
// In a CID font, the charset is a mapping of CIDs not SIDs so just
// create an identity mapping.
out = new Uint8Array([
2, // format
0, // first CID upper byte
0, // first CID lower byte
(numGlyphsLessNotDef >> 8) & 0xff,
numGlyphsLessNotDef & 0xff,
]);
} else {
const length = 1 + numGlyphsLessNotDef * 2;
out = new Uint8Array(length);
out[0] = 0; // format 0
let charsetIndex = 0;
const numCharsets = charset.charset.length;
let warned = false;
for (let i = 1; i < out.length; i += 2) {
let sid = 0;
if (charsetIndex < numCharsets) {
const name = charset.charset[charsetIndex++];
sid = strings.getSID(name);
if (sid === -1) {
sid = 0;
if (!warned) {
warned = true;
warn(`Couldn't find ${name} in CFF strings`);
}
}
}
out[i] = (sid >> 8) & 0xff;
out[i + 1] = sid & 0xff;
}
}
return this.compileTypedArray(out);
}
compileEncoding(encoding) {
return this.compileTypedArray(encoding.raw);
}
compileFDSelect(fdSelect) {
const format = fdSelect.format;
let out, i;
switch (format) {
case 0:
out = new Uint8Array(1 + fdSelect.fdSelect.length);
out[0] = format;
for (i = 0; i < fdSelect.fdSelect.length; i++) {
out[i + 1] = fdSelect.fdSelect[i];
}
break;
case 3:
const start = 0;
let lastFD = fdSelect.fdSelect[0];
const ranges = [
format,
0, // nRanges place holder
0, // nRanges place holder
(start >> 8) & 0xff,
start & 0xff,
lastFD,
];
for (i = 1; i < fdSelect.fdSelect.length; i++) {
const currentFD = fdSelect.fdSelect[i];
if (currentFD !== lastFD) {
ranges.push((i >> 8) & 0xff, i & 0xff, currentFD);
lastFD = currentFD;
}
}
// 3 bytes are pushed for every range and there are 3 header bytes.
const numRanges = (ranges.length - 3) / 3;
ranges[1] = (numRanges >> 8) & 0xff;
ranges[2] = numRanges & 0xff;
// sentinel
ranges.push((i >> 8) & 0xff, i & 0xff);
out = new Uint8Array(ranges);
break;
}
return this.compileTypedArray(out);
}
compileTypedArray(data) {
const out = [];
for (let i = 0, ii = data.length; i < ii; ++i) {
out[i] = data[i];
}
return out;
}
compileIndex(index, trackers = []) {
const objects = index.objects;
// First 2 bytes contains the number of objects contained into this index
const count = objects.length;
// If there is no object, just create an index. This technically
// should just be [0, 0] but OTS has an issue with that.
if (count === 0) {
return [0, 0, 0];
}
const data = [(count >> 8) & 0xff, count & 0xff];
let lastOffset = 1,
i;
for (i = 0; i < count; ++i) {
lastOffset += objects[i].length;
}
let offsetSize;
if (lastOffset < 0x100) {
offsetSize = 1;
} else if (lastOffset < 0x10000) {
offsetSize = 2;
} else if (lastOffset < 0x1000000) {
offsetSize = 3;
} else {
offsetSize = 4;
}
// Next byte contains the offset size use to reference object in the file
data.push(offsetSize);
// Add another offset after this one because we need a new offset
let relativeOffset = 1;
for (i = 0; i < count + 1; i++) {
if (offsetSize === 1) {
data.push(relativeOffset & 0xff);
} else if (offsetSize === 2) {
data.push((relativeOffset >> 8) & 0xff, relativeOffset & 0xff);
} else if (offsetSize === 3) {
data.push(
(relativeOffset >> 16) & 0xff,
(relativeOffset >> 8) & 0xff,
relativeOffset & 0xff
);
} else {
data.push(
(relativeOffset >>> 24) & 0xff,
(relativeOffset >> 16) & 0xff,
(relativeOffset >> 8) & 0xff,
relativeOffset & 0xff
);
}
if (objects[i]) {
relativeOffset += objects[i].length;
}
}
for (i = 0; i < count; i++) {
// Notify the tracker where the object will be offset in the data.
if (trackers[i]) {
trackers[i].offset(data.length);
}
for (let j = 0, jj = objects[i].length; j < jj; j++) {
data.push(objects[i][j]);
}
}
return data;
}
}
export {
CFF,
CFFCharset,
CFFCompiler,
CFFFDSelect,
CFFHeader,
CFFIndex,
CFFParser,
CFFPrivateDict,
CFFStandardStrings,
CFFStrings,
CFFTopDict,
};
Reference in New Issue View Git Blame Copy Permalink