/* Copyright 2012 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 { assert, bytesToString, FONT_IDENTITY_MATRIX, FontType, FormatError, info, isNum, shadow, string32, warn, } from "../shared/util.js"; import { CFFCompiler, CFFParser } from "./cff_parser.js"; import { FontFlags, getFontType, MacStandardGlyphOrdering, normalizeFontName, recoverGlyphName, SEAC_ANALYSIS_ENABLED, } from "./fonts_utils.js"; import { getDingbatsGlyphsUnicode, getGlyphsUnicode } from "./glyphlist.js"; import { getEncoding, MacRomanEncoding, StandardEncoding, SymbolSetEncoding, ZapfDingbatsEncoding, } from "./encodings.js"; import { getGlyphMapForStandardFonts, getNonStdFontMap, getStdFontMap, getSupplementalGlyphMapForArialBlack, getSupplementalGlyphMapForCalibri, } from "./standard_fonts.js"; import { getUnicodeForGlyph, getUnicodeRangeFor, mapSpecialUnicodeValues, } from "./unicode.js"; import { IdentityToUnicodeMap, ToUnicodeMap } from "./to_unicode_map.js"; import { CFFFont } from "./cff_font.js"; import { FontRendererFactory } from "./font_renderer.js"; import { GlyfTable } from "./glyf.js"; import { IdentityCMap } from "./cmap.js"; import { OpenTypeFileBuilder } from "./opentype_file_builder.js"; import { readUint32 } from "./core_utils.js"; import { Stream } from "./stream.js"; import { Type1Font } from "./type1_font.js"; // Unicode Private Use Areas: const PRIVATE_USE_AREAS = [ [0xe000, 0xf8ff], // BMP (0) [0x100000, 0x10fffd], // PUP (16) ]; // PDF Glyph Space Units are one Thousandth of a TextSpace Unit // except for Type 3 fonts const PDF_GLYPH_SPACE_UNITS = 1000; const EXPORT_DATA_PROPERTIES = [ "ascent", "bbox", "black", "bold", "charProcOperatorList", "composite", "cssFontInfo", "data", "defaultVMetrics", "defaultWidth", "descent", "fallbackName", "fontMatrix", "fontType", "isMonospace", "isSerifFont", "isType3Font", "italic", "loadedName", "mimetype", "missingFile", "name", "remeasure", "subtype", "type", "vertical", ]; const EXPORT_DATA_EXTRA_PROPERTIES = [ "cMap", "defaultEncoding", "differences", "isSymbolicFont", "seacMap", "toFontChar", "toUnicode", "vmetrics", "widths", ]; function adjustWidths(properties) { if (!properties.fontMatrix) { return; } if (properties.fontMatrix[0] === FONT_IDENTITY_MATRIX[0]) { return; } // adjusting width to fontMatrix scale const scale = 0.001 / properties.fontMatrix[0]; const glyphsWidths = properties.widths; for (const glyph in glyphsWidths) { glyphsWidths[glyph] *= scale; } properties.defaultWidth *= scale; } function adjustToUnicode(properties, builtInEncoding) { if (properties.isInternalFont) { return; } if (properties.hasIncludedToUnicodeMap) { return; // The font dictionary has a `ToUnicode` entry. } if (builtInEncoding === properties.defaultEncoding) { return; // No point in trying to adjust `toUnicode` if the encodings match. } if (properties.toUnicode instanceof IdentityToUnicodeMap) { return; } const toUnicode = [], glyphsUnicodeMap = getGlyphsUnicode(); for (const charCode in builtInEncoding) { if ( properties.hasEncoding && properties.differences[charCode] !== undefined ) { continue; // The font dictionary has an `Encoding`/`Differences` entry. } const glyphName = builtInEncoding[charCode]; const unicode = getUnicodeForGlyph(glyphName, glyphsUnicodeMap); if (unicode !== -1) { toUnicode[charCode] = String.fromCharCode(unicode); } } properties.toUnicode.amend(toUnicode); } class Glyph { constructor( originalCharCode, fontChar, unicode, accent, width, vmetric, operatorListId, isSpace, isInFont ) { this.originalCharCode = originalCharCode; this.fontChar = fontChar; this.unicode = unicode; this.accent = accent; this.width = width; this.vmetric = vmetric; this.operatorListId = operatorListId; this.isSpace = isSpace; this.isInFont = isInFont; } matchesForCache( originalCharCode, fontChar, unicode, accent, width, vmetric, operatorListId, isSpace, isInFont ) { return ( this.originalCharCode === originalCharCode && this.fontChar === fontChar && this.unicode === unicode && this.accent === accent && this.width === width && this.vmetric === vmetric && this.operatorListId === operatorListId && this.isSpace === isSpace && this.isInFont === isInFont ); } } function int16(b0, b1) { return (b0 << 8) + b1; } function writeSignedInt16(bytes, index, value) { bytes[index + 1] = value; bytes[index] = value >>> 8; } function signedInt16(b0, b1) { const value = (b0 << 8) + b1; return value & (1 << 15) ? value - 0x10000 : value; } function int32(b0, b1, b2, b3) { return (b0 << 24) + (b1 << 16) + (b2 << 8) + b3; } function string16(value) { return String.fromCharCode((value >> 8) & 0xff, value & 0xff); } function safeString16(value) { // clamp value to the 16-bit int range if (value > 0x7fff) { value = 0x7fff; } else if (value < -0x8000) { value = -0x8000; } return String.fromCharCode((value >> 8) & 0xff, value & 0xff); } function isTrueTypeFile(file) { const header = file.peekBytes(4); return ( readUint32(header, 0) === 0x00010000 || bytesToString(header) === "true" ); } function isTrueTypeCollectionFile(file) { const header = file.peekBytes(4); return bytesToString(header) === "ttcf"; } function isOpenTypeFile(file) { const header = file.peekBytes(4); return bytesToString(header) === "OTTO"; } function isType1File(file) { const header = file.peekBytes(2); // All Type1 font programs must begin with the comment '%!' (0x25 + 0x21). if (header[0] === 0x25 && header[1] === 0x21) { return true; } // ... obviously some fonts violate that part of the specification, // please refer to the comment in |Type1Font| below (pfb file header). if (header[0] === 0x80 && header[1] === 0x01) { return true; } return false; } /** * Compared to other font formats, the header in CFF files is not constant * but contains version numbers. To reduce the possibility of misclassifying * font files as CFF, it's recommended to check for other font formats first. */ function isCFFFile(file) { const header = file.peekBytes(4); if ( /* major version, [1, 255] */ header[0] >= 1 && /* minor version, [0, 255]; header[1] */ /* header size, [0, 255]; header[2] */ /* offset(0) size, [1, 4] */ header[3] >= 1 && header[3] <= 4 ) { return true; } return false; } function getFontFileType(file, { type, subtype, composite }) { let fileType, fileSubtype; if (isTrueTypeFile(file) || isTrueTypeCollectionFile(file)) { if (composite) { fileType = "CIDFontType2"; } else { fileType = "TrueType"; } } else if (isOpenTypeFile(file)) { if (composite) { fileType = "CIDFontType2"; } else { fileType = "OpenType"; } } else if (isType1File(file)) { if (composite) { fileType = "CIDFontType0"; } else { fileType = type === "MMType1" ? "MMType1" : "Type1"; } } else if (isCFFFile(file)) { if (composite) { fileType = "CIDFontType0"; fileSubtype = "CIDFontType0C"; } else { fileType = type === "MMType1" ? "MMType1" : "Type1"; fileSubtype = "Type1C"; } } else { warn("getFontFileType: Unable to detect correct font file Type/Subtype."); fileType = type; fileSubtype = subtype; } return [fileType, fileSubtype]; } function buildToFontChar(encoding, glyphsUnicodeMap, differences) { const toFontChar = []; let unicode; for (let i = 0, ii = encoding.length; i < ii; i++) { unicode = getUnicodeForGlyph(encoding[i], glyphsUnicodeMap); if (unicode !== -1) { toFontChar[i] = unicode; } } for (const charCode in differences) { unicode = getUnicodeForGlyph(differences[charCode], glyphsUnicodeMap); if (unicode !== -1) { toFontChar[+charCode] = unicode; } } return toFontChar; } /** * Rebuilds the char code to glyph ID map by moving all char codes to the * private use area. This is done to avoid issues with various problematic * unicode areas where either a glyph won't be drawn or is deformed by a * shaper. * @returns {Object} Two properties: * 'toFontChar' - maps original char codes(the value that will be read * from commands such as show text) to the char codes that will be used in the * font that we build * 'charCodeToGlyphId' - maps the new font char codes to glyph ids */ function adjustMapping(charCodeToGlyphId, hasGlyph, newGlyphZeroId) { const newMap = Object.create(null); const toFontChar = []; let privateUseAreaIndex = 0; let nextAvailableFontCharCode = PRIVATE_USE_AREAS[privateUseAreaIndex][0]; let privateUseOffetEnd = PRIVATE_USE_AREAS[privateUseAreaIndex][1]; for (let originalCharCode in charCodeToGlyphId) { originalCharCode |= 0; let glyphId = charCodeToGlyphId[originalCharCode]; // For missing glyphs don't create the mappings so the glyph isn't // drawn. if (!hasGlyph(glyphId)) { continue; } if (nextAvailableFontCharCode > privateUseOffetEnd) { privateUseAreaIndex++; if (privateUseAreaIndex >= PRIVATE_USE_AREAS.length) { warn("Ran out of space in font private use area."); break; } nextAvailableFontCharCode = PRIVATE_USE_AREAS[privateUseAreaIndex][0]; privateUseOffetEnd = PRIVATE_USE_AREAS[privateUseAreaIndex][1]; } const fontCharCode = nextAvailableFontCharCode++; if (glyphId === 0) { glyphId = newGlyphZeroId; } newMap[fontCharCode] = glyphId; toFontChar[originalCharCode] = fontCharCode; } return { toFontChar, charCodeToGlyphId: newMap, nextAvailableFontCharCode, }; } function getRanges(glyphs, numGlyphs) { // Array.sort() sorts by characters, not numerically, so convert to an // array of characters. const codes = []; for (const charCode in glyphs) { // Remove an invalid glyph ID mappings to make OTS happy. if (glyphs[charCode] >= numGlyphs) { continue; } codes.push({ fontCharCode: charCode | 0, glyphId: glyphs[charCode] }); } // Some fonts have zero glyphs and are used only for text selection, but // there needs to be at least one to build a valid cmap table. if (codes.length === 0) { codes.push({ fontCharCode: 0, glyphId: 0 }); } codes.sort(function fontGetRangesSort(a, b) { return a.fontCharCode - b.fontCharCode; }); // Split the sorted codes into ranges. const ranges = []; const length = codes.length; for (let n = 0; n < length; ) { const start = codes[n].fontCharCode; const codeIndices = [codes[n].glyphId]; ++n; let end = start; while (n < length && end + 1 === codes[n].fontCharCode) { codeIndices.push(codes[n].glyphId); ++end; ++n; if (end === 0xffff) { break; } } ranges.push([start, end, codeIndices]); } return ranges; } function createCmapTable(glyphs, numGlyphs) { const ranges = getRanges(glyphs, numGlyphs); const numTables = ranges[ranges.length - 1][1] > 0xffff ? 2 : 1; let cmap = "\x00\x00" + // version string16(numTables) + // numTables "\x00\x03" + // platformID "\x00\x01" + // encodingID string32(4 + numTables * 8); // start of the table record let i, ii, j, jj; for (i = ranges.length - 1; i >= 0; --i) { if (ranges[i][0] <= 0xffff) { break; } } const bmpLength = i + 1; if (ranges[i][0] < 0xffff && ranges[i][1] === 0xffff) { ranges[i][1] = 0xfffe; } const trailingRangesCount = ranges[i][1] < 0xffff ? 1 : 0; const segCount = bmpLength + trailingRangesCount; const searchParams = OpenTypeFileBuilder.getSearchParams(segCount, 2); // Fill up the 4 parallel arrays describing the segments. let startCount = ""; let endCount = ""; let idDeltas = ""; let idRangeOffsets = ""; let glyphsIds = ""; let bias = 0; let range, start, end, codes; for (i = 0, ii = bmpLength; i < ii; i++) { range = ranges[i]; start = range[0]; end = range[1]; startCount += string16(start); endCount += string16(end); codes = range[2]; let contiguous = true; for (j = 1, jj = codes.length; j < jj; ++j) { if (codes[j] !== codes[j - 1] + 1) { contiguous = false; break; } } if (!contiguous) { const offset = (segCount - i) * 2 + bias * 2; bias += end - start + 1; idDeltas += string16(0); idRangeOffsets += string16(offset); for (j = 0, jj = codes.length; j < jj; ++j) { glyphsIds += string16(codes[j]); } } else { const startCode = codes[0]; idDeltas += string16((startCode - start) & 0xffff); idRangeOffsets += string16(0); } } if (trailingRangesCount > 0) { endCount += "\xFF\xFF"; startCount += "\xFF\xFF"; idDeltas += "\x00\x01"; idRangeOffsets += "\x00\x00"; } const format314 = "\x00\x00" + // language string16(2 * segCount) + string16(searchParams.range) + string16(searchParams.entry) + string16(searchParams.rangeShift) + endCount + "\x00\x00" + startCount + idDeltas + idRangeOffsets + glyphsIds; let format31012 = ""; let header31012 = ""; if (numTables > 1) { cmap += "\x00\x03" + // platformID "\x00\x0A" + // encodingID string32(4 + numTables * 8 + 4 + format314.length); // start of the table record format31012 = ""; for (i = 0, ii = ranges.length; i < ii; i++) { range = ranges[i]; start = range[0]; codes = range[2]; let code = codes[0]; for (j = 1, jj = codes.length; j < jj; ++j) { if (codes[j] !== codes[j - 1] + 1) { end = range[0] + j - 1; format31012 += string32(start) + // startCharCode string32(end) + // endCharCode string32(code); // startGlyphID start = end + 1; code = codes[j]; } } format31012 += string32(start) + // startCharCode string32(range[1]) + // endCharCode string32(code); // startGlyphID } header31012 = "\x00\x0C" + // format "\x00\x00" + // reserved string32(format31012.length + 16) + // length "\x00\x00\x00\x00" + // language string32(format31012.length / 12); // nGroups } return ( cmap + "\x00\x04" + // format string16(format314.length + 4) + // length format314 + header31012 + format31012 ); } function validateOS2Table(os2, file) { file.pos = (file.start || 0) + os2.offset; const version = file.getUint16(); // TODO verify all OS/2 tables fields, but currently we validate only those // that give us issues file.skip(60); // skipping type, misc sizes, panose, unicode ranges const selection = file.getUint16(); if (version < 4 && selection & 0x0300) { return false; } const firstChar = file.getUint16(); const lastChar = file.getUint16(); if (firstChar > lastChar) { return false; } file.skip(6); // skipping sTypoAscender/Descender/LineGap const usWinAscent = file.getUint16(); if (usWinAscent === 0) { // makes font unreadable by windows return false; } // OS/2 appears to be valid, resetting some fields os2.data[8] = os2.data[9] = 0; // IE rejects fonts if fsType != 0 return true; } function createOS2Table(properties, charstrings, override) { override = override || { unitsPerEm: 0, yMax: 0, yMin: 0, ascent: 0, descent: 0, }; let ulUnicodeRange1 = 0; let ulUnicodeRange2 = 0; let ulUnicodeRange3 = 0; let ulUnicodeRange4 = 0; let firstCharIndex = null; let lastCharIndex = 0; if (charstrings) { for (let code in charstrings) { code |= 0; if (firstCharIndex > code || !firstCharIndex) { firstCharIndex = code; } if (lastCharIndex < code) { lastCharIndex = code; } const position = getUnicodeRangeFor(code); if (position < 32) { ulUnicodeRange1 |= 1 << position; } else if (position < 64) { ulUnicodeRange2 |= 1 << (position - 32); } else if (position < 96) { ulUnicodeRange3 |= 1 << (position - 64); } else if (position < 123) { ulUnicodeRange4 |= 1 << (position - 96); } else { throw new FormatError( "Unicode ranges Bits > 123 are reserved for internal usage" ); } } if (lastCharIndex > 0xffff) { // OS2 only supports a 16 bit int. The spec says if supplementary // characters are used the field should just be set to 0xFFFF. lastCharIndex = 0xffff; } } else { // TODO firstCharIndex = 0; lastCharIndex = 255; } const bbox = properties.bbox || [0, 0, 0, 0]; const unitsPerEm = override.unitsPerEm || 1 / (properties.fontMatrix || FONT_IDENTITY_MATRIX)[0]; // if the font units differ to the PDF glyph space units // then scale up the values const scale = properties.ascentScaled ? 1.0 : unitsPerEm / PDF_GLYPH_SPACE_UNITS; const typoAscent = override.ascent || Math.round(scale * (properties.ascent || bbox[3])); let typoDescent = override.descent || Math.round(scale * (properties.descent || bbox[1])); if (typoDescent > 0 && properties.descent > 0 && bbox[1] < 0) { typoDescent = -typoDescent; // fixing incorrect descent } const winAscent = override.yMax || typoAscent; const winDescent = -override.yMin || -typoDescent; return ( "\x00\x03" + // version "\x02\x24" + // xAvgCharWidth "\x01\xF4" + // usWeightClass "\x00\x05" + // usWidthClass "\x00\x00" + // fstype (0 to let the font loads via font-face on IE) "\x02\x8A" + // ySubscriptXSize "\x02\xBB" + // ySubscriptYSize "\x00\x00" + // ySubscriptXOffset "\x00\x8C" + // ySubscriptYOffset "\x02\x8A" + // ySuperScriptXSize "\x02\xBB" + // ySuperScriptYSize "\x00\x00" + // ySuperScriptXOffset "\x01\xDF" + // ySuperScriptYOffset "\x00\x31" + // yStrikeOutSize "\x01\x02" + // yStrikeOutPosition "\x00\x00" + // sFamilyClass "\x00\x00\x06" + String.fromCharCode(properties.fixedPitch ? 0x09 : 0x00) + "\x00\x00\x00\x00\x00\x00" + // Panose string32(ulUnicodeRange1) + // ulUnicodeRange1 (Bits 0-31) string32(ulUnicodeRange2) + // ulUnicodeRange2 (Bits 32-63) string32(ulUnicodeRange3) + // ulUnicodeRange3 (Bits 64-95) string32(ulUnicodeRange4) + // ulUnicodeRange4 (Bits 96-127) "\x2A\x32\x31\x2A" + // achVendID string16(properties.italicAngle ? 1 : 0) + // fsSelection string16(firstCharIndex || properties.firstChar) + // usFirstCharIndex string16(lastCharIndex || properties.lastChar) + // usLastCharIndex string16(typoAscent) + // sTypoAscender string16(typoDescent) + // sTypoDescender "\x00\x64" + // sTypoLineGap (7%-10% of the unitsPerEM value) string16(winAscent) + // usWinAscent string16(winDescent) + // usWinDescent "\x00\x00\x00\x00" + // ulCodePageRange1 (Bits 0-31) "\x00\x00\x00\x00" + // ulCodePageRange2 (Bits 32-63) string16(properties.xHeight) + // sxHeight string16(properties.capHeight) + // sCapHeight string16(0) + // usDefaultChar string16(firstCharIndex || properties.firstChar) + // usBreakChar "\x00\x03" ); // usMaxContext } function createPostTable(properties) { const angle = Math.floor(properties.italicAngle * 2 ** 16); return ( "\x00\x03\x00\x00" + // Version number string32(angle) + // italicAngle "\x00\x00" + // underlinePosition "\x00\x00" + // underlineThickness string32(properties.fixedPitch) + // isFixedPitch "\x00\x00\x00\x00" + // minMemType42 "\x00\x00\x00\x00" + // maxMemType42 "\x00\x00\x00\x00" + // minMemType1 "\x00\x00\x00\x00" ); // maxMemType1 } function createPostscriptName(name) { // See https://docs.microsoft.com/en-us/typography/opentype/spec/recom#name. return name.replace(/[^\x21-\x7E]|[[\](){}<>/%]/g, "").slice(0, 63); } function createNameTable(name, proto) { if (!proto) { proto = [[], []]; // no strings and unicode strings } const strings = [ proto[0][0] || "Original licence", // 0.Copyright proto[0][1] || name, // 1.Font family proto[0][2] || "Unknown", // 2.Font subfamily (font weight) proto[0][3] || "uniqueID", // 3.Unique ID proto[0][4] || name, // 4.Full font name proto[0][5] || "Version 0.11", // 5.Version proto[0][6] || createPostscriptName(name), // 6.Postscript name proto[0][7] || "Unknown", // 7.Trademark proto[0][8] || "Unknown", // 8.Manufacturer proto[0][9] || "Unknown", // 9.Designer ]; // Mac want 1-byte per character strings while Windows want // 2-bytes per character, so duplicate the names table const stringsUnicode = []; let i, ii, j, jj, str; for (i = 0, ii = strings.length; i < ii; i++) { str = proto[1][i] || strings[i]; const strBufUnicode = []; for (j = 0, jj = str.length; j < jj; j++) { strBufUnicode.push(string16(str.charCodeAt(j))); } stringsUnicode.push(strBufUnicode.join("")); } const names = [strings, stringsUnicode]; const platforms = ["\x00\x01", "\x00\x03"]; const encodings = ["\x00\x00", "\x00\x01"]; const languages = ["\x00\x00", "\x04\x09"]; const namesRecordCount = strings.length * platforms.length; let nameTable = "\x00\x00" + // format string16(namesRecordCount) + // Number of names Record string16(namesRecordCount * 12 + 6); // Storage // Build the name records field let strOffset = 0; for (i = 0, ii = platforms.length; i < ii; i++) { const strs = names[i]; for (j = 0, jj = strs.length; j < jj; j++) { str = strs[j]; const nameRecord = platforms[i] + // platform ID encodings[i] + // encoding ID languages[i] + // language ID string16(j) + // name ID string16(str.length) + string16(strOffset); nameTable += nameRecord; strOffset += str.length; } } nameTable += strings.join("") + stringsUnicode.join(""); return nameTable; } /** * 'Font' is the class the outside world should use, it encapsulate all the font * decoding logics whatever type it is (assuming the font type is supported). */ class Font { constructor(name, file, properties) { this.name = name; this.mimetype = null; this.disableFontFace = false; this.loadedName = properties.loadedName; this.isType3Font = properties.isType3Font; this.missingFile = false; this.cssFontInfo = properties.cssFontInfo; this._charsCache = Object.create(null); this._glyphCache = Object.create(null); this.isSerifFont = !!(properties.flags & FontFlags.Serif); this.isSymbolicFont = !!(properties.flags & FontFlags.Symbolic); this.isMonospace = !!(properties.flags & FontFlags.FixedPitch); let type = properties.type; let subtype = properties.subtype; this.type = type; this.subtype = subtype; let fallbackName = "sans-serif"; if (this.isMonospace) { fallbackName = "monospace"; } else if (this.isSerifFont) { fallbackName = "serif"; } this.fallbackName = fallbackName; this.differences = properties.differences; this.widths = properties.widths; this.defaultWidth = properties.defaultWidth; this.composite = properties.composite; this.cMap = properties.cMap; this.capHeight = properties.capHeight / PDF_GLYPH_SPACE_UNITS; this.ascent = properties.ascent / PDF_GLYPH_SPACE_UNITS; this.descent = properties.descent / PDF_GLYPH_SPACE_UNITS; this.fontMatrix = properties.fontMatrix; this.bbox = properties.bbox; this.defaultEncoding = properties.defaultEncoding; this.toUnicode = properties.toUnicode; this.fallbackToUnicode = properties.fallbackToUnicode || new ToUnicodeMap(); this.toFontChar = []; if (properties.type === "Type3") { for (let charCode = 0; charCode < 256; charCode++) { this.toFontChar[charCode] = this.differences[charCode] || properties.defaultEncoding[charCode]; } this.fontType = FontType.TYPE3; return; } this.cidEncoding = properties.cidEncoding; this.vertical = !!properties.vertical; if (this.vertical) { this.vmetrics = properties.vmetrics; this.defaultVMetrics = properties.defaultVMetrics; } if (!file || file.isEmpty) { if (file) { // Some bad PDF generators will include empty font files, // attempting to recover by assuming that no file exists. warn('Font file is empty in "' + name + '" (' + this.loadedName + ")"); } this.fallbackToSystemFont(properties); return; } // Parse the font file to determine the correct type/subtype, rather than // relying on the (often incorrect) data in the font dictionary; (see e.g. // issue6782.pdf, issue7598.pdf, and issue9949.pdf). [type, subtype] = getFontFileType(file, properties); if (type !== this.type || subtype !== this.subtype) { info( "Inconsistent font file Type/SubType, expected: " + `${this.type}/${this.subtype} but found: ${type}/${subtype}.` ); } let data; try { switch (type) { case "MMType1": info("MMType1 font (" + name + "), falling back to Type1."); /* falls through */ case "Type1": case "CIDFontType0": this.mimetype = "font/opentype"; const cff = subtype === "Type1C" || subtype === "CIDFontType0C" ? new CFFFont(file, properties) : new Type1Font(name, file, properties); adjustWidths(properties); // Wrap the CFF data inside an OTF font file data = this.convert(name, cff, properties); break; case "OpenType": case "TrueType": case "CIDFontType2": this.mimetype = "font/opentype"; // Repair the TrueType file. It is can be damaged in the point of // view of the sanitizer data = this.checkAndRepair(name, file, properties); if (this.isOpenType) { adjustWidths(properties); type = "OpenType"; } break; default: throw new FormatError(`Font ${type} is not supported`); } } catch (e) { warn(e); this.fallbackToSystemFont(properties); return; } this.data = data; this.fontType = getFontType(type, subtype, properties.isStandardFont); // Transfer some properties again that could change during font conversion this.fontMatrix = properties.fontMatrix; this.widths = properties.widths; this.defaultWidth = properties.defaultWidth; this.toUnicode = properties.toUnicode; this.seacMap = properties.seacMap; } get renderer() { const renderer = FontRendererFactory.create(this, SEAC_ANALYSIS_ENABLED); return shadow(this, "renderer", renderer); } exportData(extraProperties = false) { const exportDataProperties = extraProperties ? [...EXPORT_DATA_PROPERTIES, ...EXPORT_DATA_EXTRA_PROPERTIES] : EXPORT_DATA_PROPERTIES; const data = Object.create(null); let property, value; for (property of exportDataProperties) { value = this[property]; // Ignore properties that haven't been explicitly set. if (value !== undefined) { data[property] = value; } } return data; } fallbackToSystemFont(properties) { this.missingFile = true; // The file data is not specified. Trying to fix the font name // to be used with the canvas.font. const name = this.name; const type = this.type; const subtype = this.subtype; let fontName = normalizeFontName(name); const stdFontMap = getStdFontMap(), nonStdFontMap = getNonStdFontMap(); const isStandardFont = !!stdFontMap[fontName]; const isMappedToStandardFont = !!( nonStdFontMap[fontName] && stdFontMap[nonStdFontMap[fontName]] ); fontName = stdFontMap[fontName] || nonStdFontMap[fontName] || fontName; this.bold = fontName.search(/bold/gi) !== -1; this.italic = fontName.search(/oblique/gi) !== -1 || fontName.search(/italic/gi) !== -1; // Use 'name' instead of 'fontName' here because the original // name ArialBlack for example will be replaced by Helvetica. this.black = name.search(/Black/g) !== -1; // Use 'name' instead of 'fontName' here because the original // name ArialNarrow for example will be replaced by Helvetica. const isNarrow = name.search(/Narrow/g) !== -1; // if at least one width is present, remeasure all chars when exists this.remeasure = (!isStandardFont || isNarrow) && Object.keys(this.widths).length > 0; if ( (isStandardFont || isMappedToStandardFont) && type === "CIDFontType2" && this.cidEncoding.startsWith("Identity-") ) { const GlyphMapForStandardFonts = getGlyphMapForStandardFonts(), cidToGidMap = properties.cidToGidMap; // Standard fonts might be embedded as CID font without glyph mapping. // Building one based on GlyphMapForStandardFonts. const map = []; for (const charCode in GlyphMapForStandardFonts) { map[+charCode] = GlyphMapForStandardFonts[charCode]; } if (/Arial-?Black/i.test(name)) { const SupplementalGlyphMapForArialBlack = getSupplementalGlyphMapForArialBlack(); for (const charCode in SupplementalGlyphMapForArialBlack) { map[+charCode] = SupplementalGlyphMapForArialBlack[charCode]; } } else if (/Calibri/i.test(name)) { const SupplementalGlyphMapForCalibri = getSupplementalGlyphMapForCalibri(); for (const charCode in SupplementalGlyphMapForCalibri) { map[+charCode] = SupplementalGlyphMapForCalibri[charCode]; } } // Always update the glyph mapping with the `cidToGidMap` when it exists // (fixes issue12418_reduced.pdf). if (cidToGidMap) { for (const charCode in map) { const cid = map[charCode]; if (cidToGidMap[cid] !== undefined) { map[+charCode] = cidToGidMap[cid]; } } } const isIdentityUnicode = this.toUnicode instanceof IdentityToUnicodeMap; if (!isIdentityUnicode) { this.toUnicode.forEach(function (charCode, unicodeCharCode) { map[+charCode] = unicodeCharCode; }); } this.toFontChar = map; this.toUnicode = new ToUnicodeMap(map); } else if (/Symbol/i.test(fontName)) { this.toFontChar = buildToFontChar( SymbolSetEncoding, getGlyphsUnicode(), this.differences ); } else if (/Dingbats/i.test(fontName)) { if (/Wingdings/i.test(name)) { warn("Non-embedded Wingdings font, falling back to ZapfDingbats."); } this.toFontChar = buildToFontChar( ZapfDingbatsEncoding, getDingbatsGlyphsUnicode(), this.differences ); } else if (isStandardFont) { this.toFontChar = buildToFontChar( this.defaultEncoding, getGlyphsUnicode(), this.differences ); } else { const glyphsUnicodeMap = getGlyphsUnicode(); const map = []; this.toUnicode.forEach((charCode, unicodeCharCode) => { if (!this.composite) { const glyphName = this.differences[charCode] || this.defaultEncoding[charCode]; const unicode = getUnicodeForGlyph(glyphName, glyphsUnicodeMap); if (unicode !== -1) { unicodeCharCode = unicode; } } map[+charCode] = unicodeCharCode; }); // Attempt to improve the glyph mapping for (some) composite fonts that // appear to lack meaningful ToUnicode data. if (this.composite && this.toUnicode instanceof IdentityToUnicodeMap) { if (/Verdana/i.test(name)) { // Fixes issue11242_reduced.pdf const GlyphMapForStandardFonts = getGlyphMapForStandardFonts(); for (const charCode in GlyphMapForStandardFonts) { map[+charCode] = GlyphMapForStandardFonts[charCode]; } } } this.toFontChar = map; } this.loadedName = fontName.split("-")[0]; this.fontType = getFontType(type, subtype, properties.isStandardFont); } checkAndRepair(name, font, properties) { const VALID_TABLES = [ "OS/2", "cmap", "head", "hhea", "hmtx", "maxp", "name", "post", "loca", "glyf", "fpgm", "prep", "cvt ", "CFF ", ]; function readTables(file, numTables) { const tables = Object.create(null); tables["OS/2"] = null; tables.cmap = null; tables.head = null; tables.hhea = null; tables.hmtx = null; tables.maxp = null; tables.name = null; tables.post = null; for (let i = 0; i < numTables; i++) { const table = readTableEntry(file); if (!VALID_TABLES.includes(table.tag)) { continue; // skipping table if it's not a required or optional table } if (table.length === 0) { continue; // skipping empty tables } tables[table.tag] = table; } return tables; } function readTableEntry(file) { const tag = file.getString(4); const checksum = file.getInt32() >>> 0; const offset = file.getInt32() >>> 0; const length = file.getInt32() >>> 0; // Read the table associated data const previousPosition = file.pos; file.pos = file.start ? file.start : 0; file.skip(offset); const data = file.getBytes(length); file.pos = previousPosition; if (tag === "head") { // clearing checksum adjustment data[8] = data[9] = data[10] = data[11] = 0; data[17] |= 0x20; // Set font optimized for cleartype flag. } return { tag, checksum, length, offset, data, }; } function readOpenTypeHeader(ttf) { return { version: ttf.getString(4), numTables: ttf.getUint16(), searchRange: ttf.getUint16(), entrySelector: ttf.getUint16(), rangeShift: ttf.getUint16(), }; } function readTrueTypeCollectionHeader(ttc) { const ttcTag = ttc.getString(4); assert(ttcTag === "ttcf", "Must be a TrueType Collection font."); const majorVersion = ttc.getUint16(); const minorVersion = ttc.getUint16(); const numFonts = ttc.getInt32() >>> 0; const offsetTable = []; for (let i = 0; i < numFonts; i++) { offsetTable.push(ttc.getInt32() >>> 0); } const header = { ttcTag, majorVersion, minorVersion, numFonts, offsetTable, }; switch (majorVersion) { case 1: return header; case 2: header.dsigTag = ttc.getInt32() >>> 0; header.dsigLength = ttc.getInt32() >>> 0; header.dsigOffset = ttc.getInt32() >>> 0; return header; } throw new FormatError( `Invalid TrueType Collection majorVersion: ${majorVersion}.` ); } function readTrueTypeCollectionData(ttc, fontName) { const { numFonts, offsetTable } = readTrueTypeCollectionHeader(ttc); const fontNameParts = fontName.split("+"); let fallbackData; for (let i = 0; i < numFonts; i++) { ttc.pos = (ttc.start || 0) + offsetTable[i]; const potentialHeader = readOpenTypeHeader(ttc); const potentialTables = readTables(ttc, potentialHeader.numTables); if (!potentialTables.name) { throw new FormatError( 'TrueType Collection font must contain a "name" table.' ); } const nameTable = readNameTable(potentialTables.name); for (let j = 0, jj = nameTable.length; j < jj; j++) { for (let k = 0, kk = nameTable[j].length; k < kk; k++) { const nameEntry = nameTable[j][k] && nameTable[j][k].replace(/\s/g, ""); if (!nameEntry) { continue; } if (nameEntry === fontName) { return { header: potentialHeader, tables: potentialTables, }; } if (fontNameParts.length < 2) { continue; } for (const part of fontNameParts) { if (nameEntry === part) { fallbackData = { name: part, header: potentialHeader, tables: potentialTables, }; } } } } } if (fallbackData) { warn( `TrueType Collection does not contain "${fontName}" font, ` + `falling back to "${fallbackData.name}" font instead.` ); return { header: fallbackData.header, tables: fallbackData.tables, }; } throw new FormatError( `TrueType Collection does not contain "${fontName}" font.` ); } /** * Read the appropriate subtable from the cmap according to 9.6.6.4 from * PDF spec */ function readCmapTable(cmap, file, isSymbolicFont, hasEncoding) { if (!cmap) { warn("No cmap table available."); return { platformId: -1, encodingId: -1, mappings: [], hasShortCmap: false, }; } let segment; let start = (file.start ? file.start : 0) + cmap.offset; file.pos = start; file.skip(2); // version const numTables = file.getUint16(); let potentialTable; let canBreak = false; // There's an order of preference in terms of which cmap subtable to // use: // - non-symbolic fonts the preference is a 3,1 table then a 1,0 table // - symbolic fonts the preference is a 3,0 table then a 1,0 table // The following takes advantage of the fact that the tables are sorted // to work. for (let i = 0; i < numTables; i++) { const platformId = file.getUint16(); const encodingId = file.getUint16(); const offset = file.getInt32() >>> 0; let useTable = false; // Sometimes there are multiple of the same type of table. Default // to choosing the first table and skip the rest. if ( potentialTable && potentialTable.platformId === platformId && potentialTable.encodingId === encodingId ) { continue; } if ( platformId === 0 && (encodingId === /* Unicode Default */ 0 || encodingId === /* Unicode 1.1 */ 1 || encodingId === /* Unicode BMP */ 3) ) { useTable = true; // Continue the loop since there still may be a higher priority // table. } else if (platformId === 1 && encodingId === 0) { useTable = true; // Continue the loop since there still may be a higher priority // table. } else if ( platformId === 3 && encodingId === 1 && (hasEncoding || !potentialTable) ) { useTable = true; if (!isSymbolicFont) { canBreak = true; } } else if (isSymbolicFont && platformId === 3 && encodingId === 0) { useTable = true; canBreak = true; } if (useTable) { potentialTable = { platformId, encodingId, offset, }; } if (canBreak) { break; } } if (potentialTable) { file.pos = start + potentialTable.offset; } if (!potentialTable || file.peekByte() === -1) { warn("Could not find a preferred cmap table."); return { platformId: -1, encodingId: -1, mappings: [], hasShortCmap: false, }; } const format = file.getUint16(); file.skip(2 + 2); // length + language let hasShortCmap = false; const mappings = []; let j, glyphId; // TODO(mack): refactor this cmap subtable reading logic out if (format === 0) { for (j = 0; j < 256; j++) { const index = file.getByte(); if (!index) { continue; } mappings.push({ charCode: j, glyphId: index, }); } hasShortCmap = true; } else if (format === 4) { // re-creating the table in format 4 since the encoding // might be changed const segCount = file.getUint16() >> 1; file.skip(6); // skipping range fields const segments = []; let segIndex; for (segIndex = 0; segIndex < segCount; segIndex++) { segments.push({ end: file.getUint16() }); } file.skip(2); for (segIndex = 0; segIndex < segCount; segIndex++) { segments[segIndex].start = file.getUint16(); } for (segIndex = 0; segIndex < segCount; segIndex++) { segments[segIndex].delta = file.getUint16(); } let offsetsCount = 0, offsetIndex; for (segIndex = 0; segIndex < segCount; segIndex++) { segment = segments[segIndex]; const rangeOffset = file.getUint16(); if (!rangeOffset) { segment.offsetIndex = -1; continue; } offsetIndex = (rangeOffset >> 1) - (segCount - segIndex); segment.offsetIndex = offsetIndex; offsetsCount = Math.max( offsetsCount, offsetIndex + segment.end - segment.start + 1 ); } const offsets = []; for (j = 0; j < offsetsCount; j++) { offsets.push(file.getUint16()); } for (segIndex = 0; segIndex < segCount; segIndex++) { segment = segments[segIndex]; start = segment.start; const end = segment.end; const delta = segment.delta; offsetIndex = segment.offsetIndex; for (j = start; j <= end; j++) { if (j === 0xffff) { continue; } glyphId = offsetIndex < 0 ? j : offsets[offsetIndex + j - start]; glyphId = (glyphId + delta) & 0xffff; mappings.push({ charCode: j, glyphId, }); } } } else if (format === 6) { // Format 6 is a 2-bytes dense mapping, which means the font data // lives glue together even if they are pretty far in the unicode // table. (This looks weird, so I can have missed something), this // works on Linux but seems to fails on Mac so let's rewrite the // cmap table to a 3-1-4 style const firstCode = file.getUint16(); const entryCount = file.getUint16(); for (j = 0; j < entryCount; j++) { glyphId = file.getUint16(); const charCode = firstCode + j; mappings.push({ charCode, glyphId, }); } } else { warn("cmap table has unsupported format: " + format); return { platformId: -1, encodingId: -1, mappings: [], hasShortCmap: false, }; } // removing duplicate entries mappings.sort(function (a, b) { return a.charCode - b.charCode; }); for (let i = 1; i < mappings.length; i++) { if (mappings[i - 1].charCode === mappings[i].charCode) { mappings.splice(i, 1); i--; } } return { platformId: potentialTable.platformId, encodingId: potentialTable.encodingId, mappings, hasShortCmap, }; } function sanitizeMetrics(file, header, metrics, numGlyphs, dupFirstEntry) { if (!header) { if (metrics) { metrics.data = null; } return; } file.pos = (file.start ? file.start : 0) + header.offset; file.pos += 4; // version file.pos += 2; // ascent file.pos += 2; // descent file.pos += 2; // linegap file.pos += 2; // adv_width_max file.pos += 2; // min_sb1 file.pos += 2; // min_sb2 file.pos += 2; // max_extent file.pos += 2; // caret_slope_rise file.pos += 2; // caret_slope_run file.pos += 2; // caret_offset file.pos += 8; // reserved file.pos += 2; // format let numOfMetrics = file.getUint16(); if (numOfMetrics > numGlyphs) { info( "The numOfMetrics (" + numOfMetrics + ") should not be " + "greater than the numGlyphs (" + numGlyphs + ")" ); // Reduce numOfMetrics if it is greater than numGlyphs numOfMetrics = numGlyphs; header.data[34] = (numOfMetrics & 0xff00) >> 8; header.data[35] = numOfMetrics & 0x00ff; } const numOfSidebearings = numGlyphs - numOfMetrics; const numMissing = numOfSidebearings - ((metrics.length - numOfMetrics * 4) >> 1); if (numMissing > 0) { // For each missing glyph, we set both the width and lsb to 0 (zero). // Since we need to add two properties for each glyph, this explains // the use of |numMissing * 2| when initializing the typed array. const entries = new Uint8Array(metrics.length + numMissing * 2); entries.set(metrics.data); if (dupFirstEntry) { // Set the sidebearing value of the duplicated glyph. entries[metrics.length] = metrics.data[2]; entries[metrics.length + 1] = metrics.data[3]; } metrics.data = entries; } } function sanitizeGlyph( source, sourceStart, sourceEnd, dest, destStart, hintsValid ) { const glyphProfile = { length: 0, sizeOfInstructions: 0, }; if (sourceEnd - sourceStart <= 12) { // glyph with data less than 12 is invalid one return glyphProfile; } const glyf = source.subarray(sourceStart, sourceEnd); let contoursCount = signedInt16(glyf[0], glyf[1]); if (contoursCount < 0) { // OTS doesn't like contour count to be less than -1. contoursCount = -1; writeSignedInt16(glyf, 0, contoursCount); // complex glyph, writing as is dest.set(glyf, destStart); glyphProfile.length = glyf.length; return glyphProfile; } let i, j = 10, flagsCount = 0; for (i = 0; i < contoursCount; i++) { const endPoint = (glyf[j] << 8) | glyf[j + 1]; flagsCount = endPoint + 1; j += 2; } // skipping instructions const instructionsStart = j; const instructionsLength = (glyf[j] << 8) | glyf[j + 1]; glyphProfile.sizeOfInstructions = instructionsLength; j += 2 + instructionsLength; const instructionsEnd = j; // validating flags let coordinatesLength = 0; for (i = 0; i < flagsCount; i++) { const flag = glyf[j++]; if (flag & 0xc0) { // reserved flags must be zero, cleaning up glyf[j - 1] = flag & 0x3f; } let xLength = 2; if (flag & 2) { xLength = 1; } else if (flag & 16) { xLength = 0; } let yLength = 2; if (flag & 4) { yLength = 1; } else if (flag & 32) { yLength = 0; } const xyLength = xLength + yLength; coordinatesLength += xyLength; if (flag & 8) { const repeat = glyf[j++]; i += repeat; coordinatesLength += repeat * xyLength; } } // glyph without coordinates will be rejected if (coordinatesLength === 0) { return glyphProfile; } let glyphDataLength = j + coordinatesLength; if (glyphDataLength > glyf.length) { // not enough data for coordinates return glyphProfile; } if (!hintsValid && instructionsLength > 0) { dest.set(glyf.subarray(0, instructionsStart), destStart); dest.set([0, 0], destStart + instructionsStart); dest.set( glyf.subarray(instructionsEnd, glyphDataLength), destStart + instructionsStart + 2 ); glyphDataLength -= instructionsLength; if (glyf.length - glyphDataLength > 3) { glyphDataLength = (glyphDataLength + 3) & ~3; } glyphProfile.length = glyphDataLength; return glyphProfile; } if (glyf.length - glyphDataLength > 3) { // truncating and aligning to 4 bytes the long glyph data glyphDataLength = (glyphDataLength + 3) & ~3; dest.set(glyf.subarray(0, glyphDataLength), destStart); glyphProfile.length = glyphDataLength; return glyphProfile; } // glyph data is fine dest.set(glyf, destStart); glyphProfile.length = glyf.length; return glyphProfile; } function sanitizeHead(head, numGlyphs, locaLength) { const data = head.data; // Validate version: // Should always be 0x00010000 const version = int32(data[0], data[1], data[2], data[3]); if (version >> 16 !== 1) { info("Attempting to fix invalid version in head table: " + version); data[0] = 0; data[1] = 1; data[2] = 0; data[3] = 0; } const indexToLocFormat = int16(data[50], data[51]); if (indexToLocFormat < 0 || indexToLocFormat > 1) { info( "Attempting to fix invalid indexToLocFormat in head table: " + indexToLocFormat ); // The value of indexToLocFormat should be 0 if the loca table // consists of short offsets, and should be 1 if the loca table // consists of long offsets. // // The number of entries in the loca table should be numGlyphs + 1. // // Using this information, we can work backwards to deduce if the // size of each offset in the loca table, and thus figure out the // appropriate value for indexToLocFormat. const numGlyphsPlusOne = numGlyphs + 1; if (locaLength === numGlyphsPlusOne << 1) { // 0x0000 indicates the loca table consists of short offsets data[50] = 0; data[51] = 0; } else if (locaLength === numGlyphsPlusOne << 2) { // 0x0001 indicates the loca table consists of long offsets data[50] = 0; data[51] = 1; } else { throw new FormatError( "Could not fix indexToLocFormat: " + indexToLocFormat ); } } } function sanitizeGlyphLocations( loca, glyf, numGlyphs, isGlyphLocationsLong, hintsValid, dupFirstEntry, maxSizeOfInstructions ) { let itemSize, itemDecode, itemEncode; if (isGlyphLocationsLong) { itemSize = 4; itemDecode = function fontItemDecodeLong(data, offset) { return ( (data[offset] << 24) | (data[offset + 1] << 16) | (data[offset + 2] << 8) | data[offset + 3] ); }; itemEncode = function fontItemEncodeLong(data, offset, value) { data[offset] = (value >>> 24) & 0xff; data[offset + 1] = (value >> 16) & 0xff; data[offset + 2] = (value >> 8) & 0xff; data[offset + 3] = value & 0xff; }; } else { itemSize = 2; itemDecode = function fontItemDecode(data, offset) { return (data[offset] << 9) | (data[offset + 1] << 1); }; itemEncode = function fontItemEncode(data, offset, value) { data[offset] = (value >> 9) & 0xff; data[offset + 1] = (value >> 1) & 0xff; }; } // The first glyph is duplicated. const numGlyphsOut = dupFirstEntry ? numGlyphs + 1 : numGlyphs; const locaDataSize = itemSize * (1 + numGlyphsOut); // Resize loca table to account for duplicated glyph. const locaData = new Uint8Array(locaDataSize); locaData.set(loca.data.subarray(0, locaDataSize)); loca.data = locaData; // removing the invalid glyphs const oldGlyfData = glyf.data; const oldGlyfDataLength = oldGlyfData.length; const newGlyfData = new Uint8Array(oldGlyfDataLength); // The spec says the offsets should be in ascending order, however // this is not true for some fonts or they use the offset of 0 to mark a // glyph as missing. OTS requires the offsets to be in order and not to // be zero, so we must sort and rebuild the loca table and potentially // re-arrange the glyf data. let i, j; const locaEntries = []; // There are numGlyphs + 1 loca table entries. for (i = 0, j = 0; i < numGlyphs + 1; i++, j += itemSize) { let offset = itemDecode(locaData, j); if (offset > oldGlyfDataLength) { offset = oldGlyfDataLength; } locaEntries.push({ index: i, offset, endOffset: 0, }); } locaEntries.sort((a, b) => { return a.offset - b.offset; }); // Now the offsets are sorted, calculate the end offset of each glyph. // The last loca entry's endOffset is not calculated since it's the end // of the data and will be stored on the previous entry's endOffset. for (i = 0; i < numGlyphs; i++) { locaEntries[i].endOffset = locaEntries[i + 1].offset; } // Re-sort so glyphs aren't out of order. locaEntries.sort((a, b) => { return a.index - b.index; }); const missingGlyphs = Object.create(null); let writeOffset = 0; itemEncode(locaData, 0, writeOffset); for (i = 0, j = itemSize; i < numGlyphs; i++, j += itemSize) { const glyphProfile = sanitizeGlyph( oldGlyfData, locaEntries[i].offset, locaEntries[i].endOffset, newGlyfData, writeOffset, hintsValid ); const newLength = glyphProfile.length; if (newLength === 0) { missingGlyphs[i] = true; } if (glyphProfile.sizeOfInstructions > maxSizeOfInstructions) { maxSizeOfInstructions = glyphProfile.sizeOfInstructions; } writeOffset += newLength; itemEncode(locaData, j, writeOffset); } if (writeOffset === 0) { // glyf table cannot be empty -- redoing the glyf and loca tables // to have single glyph with one point const simpleGlyph = new Uint8Array([ 0, 1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 49, 0, ]); for (i = 0, j = itemSize; i < numGlyphsOut; i++, j += itemSize) { itemEncode(locaData, j, simpleGlyph.length); } glyf.data = simpleGlyph; } else if (dupFirstEntry) { // 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. const firstEntryLength = itemDecode(locaData, itemSize); if (newGlyfData.length > firstEntryLength + writeOffset) { glyf.data = newGlyfData.subarray(0, firstEntryLength + writeOffset); } else { glyf.data = new Uint8Array(firstEntryLength + writeOffset); glyf.data.set(newGlyfData.subarray(0, writeOffset)); } glyf.data.set(newGlyfData.subarray(0, firstEntryLength), writeOffset); itemEncode( loca.data, locaData.length - itemSize, writeOffset + firstEntryLength ); } else { glyf.data = newGlyfData.subarray(0, writeOffset); } return { missingGlyphs, maxSizeOfInstructions, }; } function readPostScriptTable(post, propertiesObj, maxpNumGlyphs) { const start = (font.start ? font.start : 0) + post.offset; font.pos = start; const length = post.length, end = start + length; const version = font.getInt32(); // skip rest to the tables font.skip(28); let glyphNames; let valid = true; let i; switch (version) { case 0x00010000: glyphNames = MacStandardGlyphOrdering; break; case 0x00020000: const numGlyphs = font.getUint16(); if (numGlyphs !== maxpNumGlyphs) { valid = false; break; } const glyphNameIndexes = []; for (i = 0; i < numGlyphs; ++i) { const index = font.getUint16(); if (index >= 32768) { valid = false; break; } glyphNameIndexes.push(index); } if (!valid) { break; } const customNames = [], strBuf = []; while (font.pos < end) { const stringLength = font.getByte(); strBuf.length = stringLength; for (i = 0; i < stringLength; ++i) { strBuf[i] = String.fromCharCode(font.getByte()); } customNames.push(strBuf.join("")); } glyphNames = []; for (i = 0; i < numGlyphs; ++i) { const j = glyphNameIndexes[i]; if (j < 258) { glyphNames.push(MacStandardGlyphOrdering[j]); continue; } glyphNames.push(customNames[j - 258]); } break; case 0x00030000: break; default: warn("Unknown/unsupported post table version " + version); valid = false; if (propertiesObj.defaultEncoding) { glyphNames = propertiesObj.defaultEncoding; } break; } propertiesObj.glyphNames = glyphNames; return valid; } function readNameTable(nameTable) { const start = (font.start ? font.start : 0) + nameTable.offset; font.pos = start; const names = [[], []]; const length = nameTable.length, end = start + length; const format = font.getUint16(); const FORMAT_0_HEADER_LENGTH = 6; if (format !== 0 || length < FORMAT_0_HEADER_LENGTH) { // unsupported name table format or table "too" small return names; } const numRecords = font.getUint16(); const stringsStart = font.getUint16(); const records = []; const NAME_RECORD_LENGTH = 12; let i, ii; for (i = 0; i < numRecords && font.pos + NAME_RECORD_LENGTH <= end; i++) { const r = { platform: font.getUint16(), encoding: font.getUint16(), language: font.getUint16(), name: font.getUint16(), length: font.getUint16(), offset: font.getUint16(), }; // using only Macintosh and Windows platform/encoding names if ( (r.platform === 1 && r.encoding === 0 && r.language === 0) || (r.platform === 3 && r.encoding === 1 && r.language === 0x409) ) { records.push(r); } } for (i = 0, ii = records.length; i < ii; i++) { const record = records[i]; if (record.length <= 0) { continue; // Nothing to process, ignoring. } const pos = start + stringsStart + record.offset; if (pos + record.length > end) { continue; // outside of name table, ignoring } font.pos = pos; const nameIndex = record.name; if (record.encoding) { // unicode let str = ""; for (let j = 0, jj = record.length; j < jj; j += 2) { str += String.fromCharCode(font.getUint16()); } names[1][nameIndex] = str; } else { names[0][nameIndex] = font.getString(record.length); } } return names; } // prettier-ignore const TTOpsStackDeltas = [ 0, 0, 0, 0, 0, 0, 0, 0, -2, -2, -2, -2, 0, 0, -2, -5, -1, -1, -1, -1, -1, -1, -1, -1, 0, 0, -1, 0, -1, -1, -1, -1, 1, -1, -999, 0, 1, 0, -1, -2, 0, -1, -2, -1, -1, 0, -1, -1, 0, 0, -999, -999, -1, -1, -1, -1, -2, -999, -2, -2, -999, 0, -2, -2, 0, 0, -2, 0, -2, 0, 0, 0, -2, -1, -1, 1, 1, 0, 0, -1, -1, -1, -1, -1, -1, -1, 0, 0, -1, 0, -1, -1, 0, -999, -1, -1, -1, -1, -1, -1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, -2, -999, -999, -999, -999, -999, -1, -1, -2, -2, 0, 0, 0, 0, -1, -1, -999, -2, -2, 0, 0, -1, -2, -2, 0, 0, 0, -1, -1, -1, -2]; // 0xC0-DF == -1 and 0xE0-FF == -2 function sanitizeTTProgram(table, ttContext) { let data = table.data; let i = 0, j, n, b, funcId, pc, lastEndf = 0, lastDeff = 0; const stack = []; const callstack = []; const functionsCalled = []; let tooComplexToFollowFunctions = ttContext.tooComplexToFollowFunctions; let inFDEF = false, ifLevel = 0, inELSE = 0; for (let ii = data.length; i < ii; ) { const op = data[i++]; // The TrueType instruction set docs can be found at // https://developer.apple.com/fonts/TTRefMan/RM05/Chap5.html if (op === 0x40) { // NPUSHB - pushes n bytes n = data[i++]; if (inFDEF || inELSE) { i += n; } else { for (j = 0; j < n; j++) { stack.push(data[i++]); } } } else if (op === 0x41) { // NPUSHW - pushes n words n = data[i++]; if (inFDEF || inELSE) { i += n * 2; } else { for (j = 0; j < n; j++) { b = data[i++]; stack.push((b << 8) | data[i++]); } } } else if ((op & 0xf8) === 0xb0) { // PUSHB - pushes bytes n = op - 0xb0 + 1; if (inFDEF || inELSE) { i += n; } else { for (j = 0; j < n; j++) { stack.push(data[i++]); } } } else if ((op & 0xf8) === 0xb8) { // PUSHW - pushes words n = op - 0xb8 + 1; if (inFDEF || inELSE) { i += n * 2; } else { for (j = 0; j < n; j++) { b = data[i++]; stack.push((b << 8) | data[i++]); } } } else if (op === 0x2b && !tooComplexToFollowFunctions) { // CALL if (!inFDEF && !inELSE) { // collecting information about which functions are used funcId = stack[stack.length - 1]; if (isNaN(funcId)) { info("TT: CALL empty stack (or invalid entry)."); } else { ttContext.functionsUsed[funcId] = true; if (funcId in ttContext.functionsStackDeltas) { const newStackLength = stack.length + ttContext.functionsStackDeltas[funcId]; if (newStackLength < 0) { warn("TT: CALL invalid functions stack delta."); ttContext.hintsValid = false; return; } stack.length = newStackLength; } else if ( funcId in ttContext.functionsDefined && !functionsCalled.includes(funcId) ) { callstack.push({ data, i, stackTop: stack.length - 1 }); functionsCalled.push(funcId); pc = ttContext.functionsDefined[funcId]; if (!pc) { warn("TT: CALL non-existent function"); ttContext.hintsValid = false; return; } data = pc.data; i = pc.i; } } } } else if (op === 0x2c && !tooComplexToFollowFunctions) { // FDEF if (inFDEF || inELSE) { warn("TT: nested FDEFs not allowed"); tooComplexToFollowFunctions = true; } inFDEF = true; // collecting information about which functions are defined lastDeff = i; funcId = stack.pop(); ttContext.functionsDefined[funcId] = { data, i }; } else if (op === 0x2d) { // ENDF - end of function if (inFDEF) { inFDEF = false; lastEndf = i; } else { pc = callstack.pop(); if (!pc) { warn("TT: ENDF bad stack"); ttContext.hintsValid = false; return; } funcId = functionsCalled.pop(); data = pc.data; i = pc.i; ttContext.functionsStackDeltas[funcId] = stack.length - pc.stackTop; } } else if (op === 0x89) { // IDEF - instruction definition if (inFDEF || inELSE) { warn("TT: nested IDEFs not allowed"); tooComplexToFollowFunctions = true; } inFDEF = true; // recording it as a function to track ENDF lastDeff = i; } else if (op === 0x58) { // IF ++ifLevel; } else if (op === 0x1b) { // ELSE inELSE = ifLevel; } else if (op === 0x59) { // EIF if (inELSE === ifLevel) { inELSE = 0; } --ifLevel; } else if (op === 0x1c) { // JMPR if (!inFDEF && !inELSE) { const offset = stack[stack.length - 1]; // only jumping forward to prevent infinite loop if (offset > 0) { i += offset - 1; } } } // Adjusting stack not extactly, but just enough to get function id if (!inFDEF && !inELSE) { let stackDelta = 0; if (op <= 0x8e) { stackDelta = TTOpsStackDeltas[op]; } else if (op >= 0xc0 && op <= 0xdf) { stackDelta = -1; } else if (op >= 0xe0) { stackDelta = -2; } if (op >= 0x71 && op <= 0x75) { n = stack.pop(); if (!isNaN(n)) { stackDelta = -n * 2; } } while (stackDelta < 0 && stack.length > 0) { stack.pop(); stackDelta++; } while (stackDelta > 0) { stack.push(NaN); // pushing any number into stack stackDelta--; } } } ttContext.tooComplexToFollowFunctions = tooComplexToFollowFunctions; const content = [data]; if (i > data.length) { content.push(new Uint8Array(i - data.length)); } if (lastDeff > lastEndf) { warn("TT: complementing a missing function tail"); // new function definition started, but not finished // complete function by [CLEAR, ENDF] content.push(new Uint8Array([0x22, 0x2d])); } foldTTTable(table, content); } function checkInvalidFunctions(ttContext, maxFunctionDefs) { if (ttContext.tooComplexToFollowFunctions) { return; } if (ttContext.functionsDefined.length > maxFunctionDefs) { warn("TT: more functions defined than expected"); ttContext.hintsValid = false; return; } for (let j = 0, jj = ttContext.functionsUsed.length; j < jj; j++) { if (j > maxFunctionDefs) { warn("TT: invalid function id: " + j); ttContext.hintsValid = false; return; } if (ttContext.functionsUsed[j] && !ttContext.functionsDefined[j]) { warn("TT: undefined function: " + j); ttContext.hintsValid = false; return; } } } function foldTTTable(table, content) { if (content.length > 1) { // concatenating the content items let newLength = 0; let j, jj; for (j = 0, jj = content.length; j < jj; j++) { newLength += content[j].length; } newLength = (newLength + 3) & ~3; const result = new Uint8Array(newLength); let pos = 0; for (j = 0, jj = content.length; j < jj; j++) { result.set(content[j], pos); pos += content[j].length; } table.data = result; table.length = newLength; } } function sanitizeTTPrograms(fpgm, prep, cvt, maxFunctionDefs) { const ttContext = { functionsDefined: [], functionsUsed: [], functionsStackDeltas: [], tooComplexToFollowFunctions: false, hintsValid: true, }; if (fpgm) { sanitizeTTProgram(fpgm, ttContext); } if (prep) { sanitizeTTProgram(prep, ttContext); } if (fpgm) { checkInvalidFunctions(ttContext, maxFunctionDefs); } if (cvt && cvt.length & 1) { const cvtData = new Uint8Array(cvt.length + 1); cvtData.set(cvt.data); cvt.data = cvtData; } return ttContext.hintsValid; } // The following steps modify the original font data, making copy font = new Stream(new Uint8Array(font.getBytes())); let header, tables; if (isTrueTypeCollectionFile(font)) { const ttcData = readTrueTypeCollectionData(font, this.name); header = ttcData.header; tables = ttcData.tables; } else { header = readOpenTypeHeader(font); tables = readTables(font, header.numTables); } let cff, cffFile; const isTrueType = !tables["CFF "]; if (!isTrueType) { const isComposite = properties.composite && ((properties.cidToGidMap || []).length > 0 || !(properties.cMap instanceof IdentityCMap)); // OpenType font (skip composite fonts with non-default glyph mapping). if ( (header.version === "OTTO" && !isComposite) || !tables.head || !tables.hhea || !tables.maxp || !tables.post ) { // No major tables: throwing everything at `CFFFont`. cffFile = new Stream(tables["CFF "].data); cff = new CFFFont(cffFile, properties); adjustWidths(properties); return this.convert(name, cff, properties); } delete tables.glyf; delete tables.loca; delete tables.fpgm; delete tables.prep; delete tables["cvt "]; this.isOpenType = true; } else { if (!tables.loca) { throw new FormatError('Required "loca" table is not found'); } if (!tables.glyf) { warn('Required "glyf" table is not found -- trying to recover.'); // Note: We use `sanitizeGlyphLocations` to add dummy glyf data below. tables.glyf = { tag: "glyf", data: new Uint8Array(0), }; } this.isOpenType = false; } if (!tables.maxp) { throw new FormatError('Required "maxp" table is not found'); } font.pos = (font.start || 0) + tables.maxp.offset; const version = font.getInt32(); const numGlyphs = font.getUint16(); if ( properties.scaleFactors && properties.scaleFactors.length === numGlyphs && isTrueType ) { const { scaleFactors } = properties; const isGlyphLocationsLong = int16( tables.head.data[50], tables.head.data[51] ); const glyphs = new GlyfTable({ glyfTable: tables.glyf.data, isGlyphLocationsLong, locaTable: tables.loca.data, numGlyphs, }); glyphs.scale(scaleFactors); const { glyf, loca, isLocationLong } = glyphs.write(); tables.glyf.data = glyf; tables.loca.data = loca; if (isLocationLong !== !!isGlyphLocationsLong) { tables.head.data[50] = 0; tables.head.data[51] = isLocationLong ? 1 : 0; } const metrics = tables.hmtx.data; for (let i = 0; i < numGlyphs; i++) { const j = 4 * i; const advanceWidth = Math.round( scaleFactors[i] * int16(metrics[j], metrics[j + 1]) ); metrics[j] = (advanceWidth >> 8) & 0xff; metrics[j + 1] = advanceWidth & 0xff; const lsb = Math.round( scaleFactors[i] * signedInt16(metrics[j + 2], metrics[j + 3]) ); writeSignedInt16(metrics, j + 2, lsb); } } // Glyph 0 is duplicated and appended. let numGlyphsOut = numGlyphs + 1; let dupFirstEntry = true; if (numGlyphsOut > 0xffff) { dupFirstEntry = false; numGlyphsOut = numGlyphs; warn("Not enough space in glyfs to duplicate first glyph."); } let maxFunctionDefs = 0; let maxSizeOfInstructions = 0; if (version >= 0x00010000 && tables.maxp.length >= 22) { // maxZones can be invalid font.pos += 8; const maxZones = font.getUint16(); if (maxZones > 2) { // reset to 2 if font has invalid maxZones tables.maxp.data[14] = 0; tables.maxp.data[15] = 2; } font.pos += 4; maxFunctionDefs = font.getUint16(); font.pos += 4; maxSizeOfInstructions = font.getUint16(); } tables.maxp.data[4] = numGlyphsOut >> 8; tables.maxp.data[5] = numGlyphsOut & 255; const hintsValid = sanitizeTTPrograms( tables.fpgm, tables.prep, tables["cvt "], maxFunctionDefs ); if (!hintsValid) { delete tables.fpgm; delete tables.prep; delete tables["cvt "]; } // Ensure the hmtx table contains the advance width and // sidebearings information for numGlyphs in the maxp table sanitizeMetrics( font, tables.hhea, tables.hmtx, numGlyphsOut, dupFirstEntry ); if (!tables.head) { throw new FormatError('Required "head" table is not found'); } sanitizeHead(tables.head, numGlyphs, isTrueType ? tables.loca.length : 0); let missingGlyphs = Object.create(null); if (isTrueType) { const isGlyphLocationsLong = int16( tables.head.data[50], tables.head.data[51] ); const glyphsInfo = sanitizeGlyphLocations( tables.loca, tables.glyf, numGlyphs, isGlyphLocationsLong, hintsValid, dupFirstEntry, maxSizeOfInstructions ); missingGlyphs = glyphsInfo.missingGlyphs; // Some fonts have incorrect maxSizeOfInstructions values, so we use // the computed value instead. if (version >= 0x00010000 && tables.maxp.length >= 22) { tables.maxp.data[26] = glyphsInfo.maxSizeOfInstructions >> 8; tables.maxp.data[27] = glyphsInfo.maxSizeOfInstructions & 255; } } if (!tables.hhea) { throw new FormatError('Required "hhea" table is not found'); } // Sanitizer reduces the glyph advanceWidth to the maxAdvanceWidth // Sometimes it's 0. That needs to be fixed if (tables.hhea.data[10] === 0 && tables.hhea.data[11] === 0) { tables.hhea.data[10] = 0xff; tables.hhea.data[11] = 0xff; } // Extract some more font properties from the OpenType head and // hhea tables; yMin and descent value are always negative. const metricsOverride = { unitsPerEm: int16(tables.head.data[18], tables.head.data[19]), yMax: int16(tables.head.data[42], tables.head.data[43]), yMin: signedInt16(tables.head.data[38], tables.head.data[39]), ascent: int16(tables.hhea.data[4], tables.hhea.data[5]), descent: signedInt16(tables.hhea.data[6], tables.hhea.data[7]), }; // PDF FontDescriptor metrics lie -- using data from actual font. this.ascent = metricsOverride.ascent / metricsOverride.unitsPerEm; this.descent = metricsOverride.descent / metricsOverride.unitsPerEm; // The 'post' table has glyphs names. if (tables.post) { readPostScriptTable(tables.post, properties, numGlyphs); } // The original 'post' table is not needed, replace it. tables.post = { tag: "post", data: createPostTable(properties), }; const charCodeToGlyphId = []; // Helper function to try to skip mapping of empty glyphs. function hasGlyph(glyphId) { return !missingGlyphs[glyphId]; } if (properties.composite) { const cidToGidMap = properties.cidToGidMap || []; const isCidToGidMapEmpty = cidToGidMap.length === 0; properties.cMap.forEach(function (charCode, cid) { if (cid > 0xffff) { throw new FormatError("Max size of CID is 65,535"); } let glyphId = -1; if (isCidToGidMapEmpty) { glyphId = cid; } else if (cidToGidMap[cid] !== undefined) { glyphId = cidToGidMap[cid]; } if (glyphId >= 0 && glyphId < numGlyphs && hasGlyph(glyphId)) { charCodeToGlyphId[charCode] = glyphId; } }); } else { // Most of the following logic in this code branch is based on the // 9.6.6.4 of the PDF spec. const cmapTable = readCmapTable( tables.cmap, font, this.isSymbolicFont, properties.hasEncoding ); const cmapPlatformId = cmapTable.platformId; const cmapEncodingId = cmapTable.encodingId; const cmapMappings = cmapTable.mappings; const cmapMappingsLength = cmapMappings.length; let baseEncoding = []; if ( properties.hasEncoding && (properties.baseEncodingName === "MacRomanEncoding" || properties.baseEncodingName === "WinAnsiEncoding") ) { baseEncoding = getEncoding(properties.baseEncodingName); } // If the font has an encoding and is not symbolic then follow the // rules in section 9.6.6.4 of the spec on how to map 3,1 and 1,0 // cmaps. if ( properties.hasEncoding && !this.isSymbolicFont && ((cmapPlatformId === 3 && cmapEncodingId === 1) || (cmapPlatformId === 1 && cmapEncodingId === 0)) ) { const glyphsUnicodeMap = getGlyphsUnicode(); for (let charCode = 0; charCode < 256; charCode++) { let glyphName; if (this.differences && charCode in this.differences) { glyphName = this.differences[charCode]; } else if ( charCode in baseEncoding && baseEncoding[charCode] !== "" ) { glyphName = baseEncoding[charCode]; } else { glyphName = StandardEncoding[charCode]; } if (!glyphName) { continue; } // Ensure that non-standard glyph names are resolved to valid ones. const standardGlyphName = recoverGlyphName( glyphName, glyphsUnicodeMap ); let unicodeOrCharCode; if (cmapPlatformId === 3 && cmapEncodingId === 1) { unicodeOrCharCode = glyphsUnicodeMap[standardGlyphName]; } else if (cmapPlatformId === 1 && cmapEncodingId === 0) { // TODO: the encoding needs to be updated with mac os table. unicodeOrCharCode = MacRomanEncoding.indexOf(standardGlyphName); } for (let i = 0; i < cmapMappingsLength; ++i) { if (cmapMappings[i].charCode !== unicodeOrCharCode) { continue; } charCodeToGlyphId[charCode] = cmapMappings[i].glyphId; break; } } } else if (cmapPlatformId === 0) { // Default Unicode semantics, use the charcodes as is. for (let i = 0; i < cmapMappingsLength; ++i) { charCodeToGlyphId[cmapMappings[i].charCode] = cmapMappings[i].glyphId; } } else { // When there is only a (1, 0) cmap table, the char code is a single // byte and it is used directly as the char code. // When a (3, 0) cmap table is present, it is used instead but the // spec has special rules for char codes in the range of 0xF000 to // 0xF0FF and it says the (3, 0) table should map the values from // the (1, 0) table by prepending 0xF0 to the char codes. To reverse // this, the upper bits of the char code are cleared, but only for the // special range since some PDFs have char codes outside of this range // (e.g. 0x2013) which when masked would overwrite other values in the // cmap. for (let i = 0; i < cmapMappingsLength; ++i) { let charCode = cmapMappings[i].charCode; if ( cmapPlatformId === 3 && charCode >= 0xf000 && charCode <= 0xf0ff ) { charCode &= 0xff; } charCodeToGlyphId[charCode] = cmapMappings[i].glyphId; } } // Last, try to map any missing charcodes using the post table. if ( properties.glyphNames && (baseEncoding.length || this.differences.length) ) { for (let i = 0; i < 256; ++i) { if (charCodeToGlyphId[i] !== undefined) { continue; } const glyphName = this.differences[i] || baseEncoding[i]; if (!glyphName) { continue; } const glyphId = properties.glyphNames.indexOf(glyphName); if (glyphId > 0 && hasGlyph(glyphId)) { charCodeToGlyphId[i] = glyphId; } } } } if (charCodeToGlyphId.length === 0) { // defines at least one glyph charCodeToGlyphId[0] = 0; } // Typically glyph 0 is duplicated and the mapping must be updated, but if // there isn't enough room to duplicate, the glyph id is left the same. In // this case, glyph 0 may not work correctly, but that is better than // having the whole font fail. let glyphZeroId = numGlyphsOut - 1; if (!dupFirstEntry) { glyphZeroId = 0; } // When `cssFontInfo` is set, the font is used to render text in the HTML // view (e.g. with Xfa) so nothing must be moved in the private use area. if (!properties.cssFontInfo) { // Converting glyphs and ids into font's cmap table const newMapping = adjustMapping( charCodeToGlyphId, hasGlyph, glyphZeroId ); this.toFontChar = newMapping.toFontChar; tables.cmap = { tag: "cmap", data: createCmapTable(newMapping.charCodeToGlyphId, numGlyphsOut), }; if (!tables["OS/2"] || !validateOS2Table(tables["OS/2"], font)) { tables["OS/2"] = { tag: "OS/2", data: createOS2Table( properties, newMapping.charCodeToGlyphId, metricsOverride ), }; } } if (!isTrueType) { try { // Trying to repair CFF file cffFile = new Stream(tables["CFF "].data); const parser = new CFFParser( cffFile, properties, SEAC_ANALYSIS_ENABLED ); cff = parser.parse(); cff.duplicateFirstGlyph(); const compiler = new CFFCompiler(cff); tables["CFF "].data = compiler.compile(); } catch (e) { warn("Failed to compile font " + properties.loadedName); } } // Re-creating 'name' table if (!tables.name) { tables.name = { tag: "name", data: createNameTable(this.name), }; } else { // ... using existing 'name' table as prototype const namePrototype = readNameTable(tables.name); tables.name.data = createNameTable(name, namePrototype); } const builder = new OpenTypeFileBuilder(header.version); for (const tableTag in tables) { builder.addTable(tableTag, tables[tableTag].data); } return builder.toArray(); } convert(fontName, font, properties) { // TODO: Check the charstring widths to determine this. properties.fixedPitch = false; if (properties.builtInEncoding) { // For Type1 fonts that do not include either `ToUnicode` or `Encoding` // data, attempt to use the `builtInEncoding` to improve text selection. adjustToUnicode(properties, properties.builtInEncoding); } // Type 1 fonts have a notdef inserted at the beginning, so glyph 0 // becomes glyph 1. In a CFF font glyph 0 is appended to the end of the // char strings. let glyphZeroId = 1; if (font instanceof CFFFont) { glyphZeroId = font.numGlyphs - 1; } const mapping = font.getGlyphMapping(properties); let newMapping = null; let newCharCodeToGlyphId = mapping; // When `cssFontInfo` is set, the font is used to render text in the HTML // view (e.g. with Xfa) so nothing must be moved in the private use area. if (!properties.cssFontInfo) { newMapping = adjustMapping( mapping, font.hasGlyphId.bind(font), glyphZeroId ); this.toFontChar = newMapping.toFontChar; newCharCodeToGlyphId = newMapping.charCodeToGlyphId; } const numGlyphs = font.numGlyphs; function getCharCodes(charCodeToGlyphId, glyphId) { let charCodes = null; for (const charCode in charCodeToGlyphId) { if (glyphId === charCodeToGlyphId[charCode]) { if (!charCodes) { charCodes = []; } charCodes.push(charCode | 0); } } return charCodes; } function createCharCode(charCodeToGlyphId, glyphId) { for (const charCode in charCodeToGlyphId) { if (glyphId === charCodeToGlyphId[charCode]) { return charCode | 0; } } newMapping.charCodeToGlyphId[newMapping.nextAvailableFontCharCode] = glyphId; return newMapping.nextAvailableFontCharCode++; } const seacs = font.seacs; if (newMapping && SEAC_ANALYSIS_ENABLED && seacs && seacs.length) { const matrix = properties.fontMatrix || FONT_IDENTITY_MATRIX; const charset = font.getCharset(); const seacMap = Object.create(null); for (let glyphId in seacs) { glyphId |= 0; const seac = seacs[glyphId]; const baseGlyphName = StandardEncoding[seac[2]]; const accentGlyphName = StandardEncoding[seac[3]]; const baseGlyphId = charset.indexOf(baseGlyphName); const accentGlyphId = charset.indexOf(accentGlyphName); if (baseGlyphId < 0 || accentGlyphId < 0) { continue; } const accentOffset = { x: seac[0] * matrix[0] + seac[1] * matrix[2] + matrix[4], y: seac[0] * matrix[1] + seac[1] * matrix[3] + matrix[5], }; const charCodes = getCharCodes(mapping, glyphId); if (!charCodes) { // There's no point in mapping it if the char code was never mapped // to begin with. continue; } for (let i = 0, ii = charCodes.length; i < ii; i++) { const charCode = charCodes[i]; // Find a fontCharCode that maps to the base and accent glyphs. // If one doesn't exists, create it. const charCodeToGlyphId = newMapping.charCodeToGlyphId; const baseFontCharCode = createCharCode( charCodeToGlyphId, baseGlyphId ); const accentFontCharCode = createCharCode( charCodeToGlyphId, accentGlyphId ); seacMap[charCode] = { baseFontCharCode, accentFontCharCode, accentOffset, }; } } properties.seacMap = seacMap; } const unitsPerEm = 1 / (properties.fontMatrix || FONT_IDENTITY_MATRIX)[0]; const builder = new OpenTypeFileBuilder("\x4F\x54\x54\x4F"); // PostScript Font Program builder.addTable("CFF ", font.data); // OS/2 and Windows Specific metrics builder.addTable("OS/2", createOS2Table(properties, newCharCodeToGlyphId)); // Character to glyphs mapping builder.addTable("cmap", createCmapTable(newCharCodeToGlyphId, numGlyphs)); // Font header builder.addTable( "head", "\x00\x01\x00\x00" + // Version number "\x00\x00\x10\x00" + // fontRevision "\x00\x00\x00\x00" + // checksumAdjustement "\x5F\x0F\x3C\xF5" + // magicNumber "\x00\x00" + // Flags safeString16(unitsPerEm) + // unitsPerEM "\x00\x00\x00\x00\x9e\x0b\x7e\x27" + // creation date "\x00\x00\x00\x00\x9e\x0b\x7e\x27" + // modifification date "\x00\x00" + // xMin safeString16(properties.descent) + // yMin "\x0F\xFF" + // xMax safeString16(properties.ascent) + // yMax string16(properties.italicAngle ? 2 : 0) + // macStyle "\x00\x11" + // lowestRecPPEM "\x00\x00" + // fontDirectionHint "\x00\x00" + // indexToLocFormat "\x00\x00" ); // glyphDataFormat // Horizontal header builder.addTable( "hhea", "\x00\x01\x00\x00" + // Version number safeString16(properties.ascent) + // Typographic Ascent safeString16(properties.descent) + // Typographic Descent "\x00\x00" + // Line Gap "\xFF\xFF" + // advanceWidthMax "\x00\x00" + // minLeftSidebearing "\x00\x00" + // minRightSidebearing "\x00\x00" + // xMaxExtent safeString16(properties.capHeight) + // caretSlopeRise safeString16(Math.tan(properties.italicAngle) * properties.xHeight) + // caretSlopeRun "\x00\x00" + // caretOffset "\x00\x00" + // -reserved- "\x00\x00" + // -reserved- "\x00\x00" + // -reserved- "\x00\x00" + // -reserved- "\x00\x00" + // metricDataFormat string16(numGlyphs) ); // Number of HMetrics // Horizontal metrics builder.addTable( "hmtx", (function fontFieldsHmtx() { const charstrings = font.charstrings; const cffWidths = font.cff ? font.cff.widths : null; let hmtx = "\x00\x00\x00\x00"; // Fake .notdef for (let i = 1, ii = numGlyphs; i < ii; i++) { let width = 0; if (charstrings) { const charstring = charstrings[i - 1]; width = "width" in charstring ? charstring.width : 0; } else if (cffWidths) { width = Math.ceil(cffWidths[i] || 0); } hmtx += string16(width) + string16(0); } return hmtx; })() ); // Maximum profile builder.addTable( "maxp", "\x00\x00\x50\x00" + string16(numGlyphs) // Version number ); // Num of glyphs // Naming tables builder.addTable("name", createNameTable(fontName)); // PostScript information builder.addTable("post", createPostTable(properties)); return builder.toArray(); } get spaceWidth() { // trying to estimate space character width const possibleSpaceReplacements = ["space", "minus", "one", "i", "I"]; let width; for (let i = 0, ii = possibleSpaceReplacements.length; i < ii; i++) { const glyphName = possibleSpaceReplacements[i]; // if possible, getting width by glyph name if (glyphName in this.widths) { width = this.widths[glyphName]; break; } const glyphsUnicodeMap = getGlyphsUnicode(); const glyphUnicode = glyphsUnicodeMap[glyphName]; // finding the charcode via unicodeToCID map let charcode = 0; if (this.composite && this.cMap.contains(glyphUnicode)) { charcode = this.cMap.lookup(glyphUnicode); } // ... via toUnicode map if (!charcode && this.toUnicode) { charcode = this.toUnicode.charCodeOf(glyphUnicode); } // setting it to unicode if negative or undefined if (charcode <= 0) { charcode = glyphUnicode; } // trying to get width via charcode width = this.widths[charcode]; if (width) { break; // the non-zero width found } } width = width || this.defaultWidth; return shadow(this, "spaceWidth", width); } /** * @private */ _charToGlyph(charcode, isSpace = false) { let fontCharCode, width, operatorListId; let widthCode = charcode; if (this.cMap && this.cMap.contains(charcode)) { widthCode = this.cMap.lookup(charcode); } width = this.widths[widthCode]; width = isNum(width) ? width : this.defaultWidth; const vmetric = this.vmetrics && this.vmetrics[widthCode]; let unicode = this.toUnicode.get(charcode) || this.fallbackToUnicode.get(charcode) || charcode; if (typeof unicode === "number") { unicode = String.fromCharCode(unicode); } let isInFont = charcode in this.toFontChar; // First try the toFontChar map, if it's not there then try falling // back to the char code. fontCharCode = this.toFontChar[charcode] || charcode; if (this.missingFile) { const glyphName = this.differences[charcode] || this.defaultEncoding[charcode]; if ( (glyphName === ".notdef" || glyphName === "") && this.type === "Type1" ) { // .notdef glyphs should be invisible in non-embedded Type1 fonts, so // replace them with spaces. fontCharCode = 0x20; } fontCharCode = mapSpecialUnicodeValues(fontCharCode); } if (this.isType3Font) { // Font char code in this case is actually a glyph name. operatorListId = fontCharCode; } let accent = null; if (this.seacMap && this.seacMap[charcode]) { isInFont = true; const seac = this.seacMap[charcode]; fontCharCode = seac.baseFontCharCode; accent = { fontChar: String.fromCodePoint(seac.accentFontCharCode), offset: seac.accentOffset, }; } let fontChar = ""; if (typeof fontCharCode === "number") { if (fontCharCode <= 0x10ffff) { fontChar = String.fromCodePoint(fontCharCode); } else { warn(`charToGlyph - invalid fontCharCode: ${fontCharCode}`); } } let glyph = this._glyphCache[charcode]; if ( !glyph || !glyph.matchesForCache( charcode, fontChar, unicode, accent, width, vmetric, operatorListId, isSpace, isInFont ) ) { glyph = new Glyph( charcode, fontChar, unicode, accent, width, vmetric, operatorListId, isSpace, isInFont ); this._glyphCache[charcode] = glyph; } return glyph; } charsToGlyphs(chars) { // If we translated this string before, just grab it from the cache. let glyphs = this._charsCache[chars]; if (glyphs) { return glyphs; } glyphs = []; if (this.cMap) { // Composite fonts have multi-byte strings, convert the string from // single-byte to multi-byte. const c = Object.create(null), ii = chars.length; let i = 0; while (i < ii) { this.cMap.readCharCode(chars, i, c); const { charcode, length } = c; i += length; // Space is char with code 0x20 and length 1 in multiple-byte codes. const glyph = this._charToGlyph( charcode, length === 1 && chars.charCodeAt(i - 1) === 0x20 ); glyphs.push(glyph); } } else { for (let i = 0, ii = chars.length; i < ii; ++i) { const charcode = chars.charCodeAt(i); const glyph = this._charToGlyph(charcode, charcode === 0x20); glyphs.push(glyph); } } // Enter the translated string into the cache. return (this._charsCache[chars] = glyphs); } /** * Chars can have different sizes (depends on the encoding). * @param {String} a string encoded with font encoding. * @returns {Array>} the positions of each char in the string. */ getCharPositions(chars) { // This function doesn't use a cache because // it's called only when saving or printing. const positions = []; if (this.cMap) { const c = Object.create(null); let i = 0; while (i < chars.length) { this.cMap.readCharCode(chars, i, c); const length = c.length; positions.push([i, i + length]); i += length; } } else { for (let i = 0, ii = chars.length; i < ii; ++i) { positions.push([i, i + 1]); } } return positions; } get glyphCacheValues() { return Object.values(this._glyphCache); } /** * Encode a js string using font encoding. * The resulting array contains an encoded string at even positions * (can be empty) and a non-encoded one at odd positions. * @param {String} a js string. * @returns {Array} an array of encoded strings or non-encoded ones. */ encodeString(str) { const buffers = []; const currentBuf = []; // buffers will contain: encoded, non-encoded, encoded, ... // currentBuf is pushed in buffers each time there is a change. // So when buffers.length is odd then the last string is an encoded one // and currentBuf contains non-encoded chars. const hasCurrentBufErrors = () => buffers.length % 2 === 1; for (let i = 0, ii = str.length; i < ii; i++) { const unicode = str.codePointAt(i); if (unicode > 0xd7ff && (unicode < 0xe000 || unicode > 0xfffd)) { // unicode is represented by two uint16 i++; } if (this.toUnicode) { const char = String.fromCodePoint(unicode); const charCode = this.toUnicode.charCodeOf(char); if (charCode !== -1) { if (hasCurrentBufErrors()) { buffers.push(currentBuf.join("")); currentBuf.length = 0; } const charCodeLength = this.cMap ? this.cMap.getCharCodeLength(charCode) : 1; for (let j = charCodeLength - 1; j >= 0; j--) { currentBuf.push(String.fromCharCode((charCode >> (8 * j)) & 0xff)); } continue; } } // unicode can't be encoded if (!hasCurrentBufErrors()) { buffers.push(currentBuf.join("")); currentBuf.length = 0; } currentBuf.push(String.fromCodePoint(unicode)); } buffers.push(currentBuf.join("")); return buffers; } } class ErrorFont { constructor(error) { this.error = error; this.loadedName = "g_font_error"; this.missingFile = true; } charsToGlyphs() { return []; } encodeString(chars) { return [chars]; } exportData(extraProperties = false) { return { error: this.error }; } } export { ErrorFont, Font };