//======================================================================== // // GfxFont.cc // // Copyright 1996-2003 Glyph & Cog, LLC // //======================================================================== //======================================================================== // // Modified under the Poppler project - http://poppler.freedesktop.org // // All changes made under the Poppler project to this file are licensed // under GPL version 2 or later // // Copyright (C) 2005, 2006, 2008-2010, 2012, 2014, 2015, 2017-2020 Albert Astals Cid // Copyright (C) 2005, 2006 Kristian Høgsberg // Copyright (C) 2006 Takashi Iwai // Copyright (C) 2007 Julien Rebetez // Copyright (C) 2007 Jeff Muizelaar // Copyright (C) 2007 Koji Otani // Copyright (C) 2007 Ed Catmur // Copyright (C) 2008 Jonathan Kew // Copyright (C) 2008 Ed Avis // Copyright (C) 2008, 2010 Hib Eris // Copyright (C) 2009 Peter Kerzum // Copyright (C) 2009, 2010 David Benjamin // Copyright (C) 2011 Axel Strübing // Copyright (C) 2011, 2012, 2014 Adrian Johnson // Copyright (C) 2012 Yi Yang // Copyright (C) 2012 Suzuki Toshiya // Copyright (C) 2012, 2017 Thomas Freitag // Copyright (C) 2013-2016, 2018 Jason Crain // Copyright (C) 2014 Olly Betts // Copyright (C) 2018 Klarälvdalens Datakonsult AB, a KDAB Group company, . Work sponsored by the LiMux project of the city of Munich // Copyright (C) 2018 Adam Reichold // Copyright (C) 2019 LE GARREC Vincent // // To see a description of the changes please see the Changelog file that // came with your tarball or type make ChangeLog if you are building from git // //======================================================================== #include #include #include #include #include #include #include #include #include "goo/gmem.h" #include "Error.h" #include "Object.h" #include "Dict.h" #include "GlobalParams.h" #include "CMap.h" #include "CharCodeToUnicode.h" #include "FontEncodingTables.h" #include "BuiltinFont.h" #include "UnicodeTypeTable.h" #include #include #include #include #include "GfxFont.h" #include "PSOutputDev.h" //------------------------------------------------------------------------ struct Base14FontMapEntry { const char *altName; const char *base14Name; }; static const Base14FontMapEntry base14FontMap[] = { { "Arial", "Helvetica" }, { "Arial,Bold", "Helvetica-Bold" }, { "Arial,BoldItalic", "Helvetica-BoldOblique" }, { "Arial,Italic", "Helvetica-Oblique" }, { "Arial-Bold", "Helvetica-Bold" }, { "Arial-BoldItalic", "Helvetica-BoldOblique" }, { "Arial-BoldItalicMT", "Helvetica-BoldOblique" }, { "Arial-BoldMT", "Helvetica-Bold" }, { "Arial-Italic", "Helvetica-Oblique" }, { "Arial-ItalicMT", "Helvetica-Oblique" }, { "ArialMT", "Helvetica" }, { "Courier", "Courier" }, { "Courier,Bold", "Courier-Bold" }, { "Courier,BoldItalic", "Courier-BoldOblique" }, { "Courier,Italic", "Courier-Oblique" }, { "Courier-Bold", "Courier-Bold" }, { "Courier-BoldOblique", "Courier-BoldOblique" }, { "Courier-Oblique", "Courier-Oblique" }, { "CourierNew", "Courier" }, { "CourierNew,Bold", "Courier-Bold" }, { "CourierNew,BoldItalic", "Courier-BoldOblique" }, { "CourierNew,Italic", "Courier-Oblique" }, { "CourierNew-Bold", "Courier-Bold" }, { "CourierNew-BoldItalic", "Courier-BoldOblique" }, { "CourierNew-Italic", "Courier-Oblique" }, { "CourierNewPS-BoldItalicMT", "Courier-BoldOblique" }, { "CourierNewPS-BoldMT", "Courier-Bold" }, { "CourierNewPS-ItalicMT", "Courier-Oblique" }, { "CourierNewPSMT", "Courier" }, { "Helvetica", "Helvetica" }, { "Helvetica,Bold", "Helvetica-Bold" }, { "Helvetica,BoldItalic", "Helvetica-BoldOblique" }, { "Helvetica,Italic", "Helvetica-Oblique" }, { "Helvetica-Bold", "Helvetica-Bold" }, { "Helvetica-BoldItalic", "Helvetica-BoldOblique" }, { "Helvetica-BoldOblique", "Helvetica-BoldOblique" }, { "Helvetica-Italic", "Helvetica-Oblique" }, { "Helvetica-Oblique", "Helvetica-Oblique" }, { "Symbol", "Symbol" }, { "Symbol,Bold", "Symbol" }, { "Symbol,BoldItalic", "Symbol" }, { "Symbol,Italic", "Symbol" }, { "SymbolMT", "Symbol" }, { "SymbolMT,Bold", "Symbol" }, { "SymbolMT,BoldItalic", "Symbol" }, { "SymbolMT,Italic", "Symbol" }, { "Times-Bold", "Times-Bold" }, { "Times-BoldItalic", "Times-BoldItalic" }, { "Times-Italic", "Times-Italic" }, { "Times-Roman", "Times-Roman" }, { "TimesNewRoman", "Times-Roman" }, { "TimesNewRoman,Bold", "Times-Bold" }, { "TimesNewRoman,BoldItalic", "Times-BoldItalic" }, { "TimesNewRoman,Italic", "Times-Italic" }, { "TimesNewRoman-Bold", "Times-Bold" }, { "TimesNewRoman-BoldItalic", "Times-BoldItalic" }, { "TimesNewRoman-Italic", "Times-Italic" }, { "TimesNewRomanPS", "Times-Roman" }, { "TimesNewRomanPS-Bold", "Times-Bold" }, { "TimesNewRomanPS-BoldItalic", "Times-BoldItalic" }, { "TimesNewRomanPS-BoldItalicMT", "Times-BoldItalic" }, { "TimesNewRomanPS-BoldMT", "Times-Bold" }, { "TimesNewRomanPS-Italic", "Times-Italic" }, { "TimesNewRomanPS-ItalicMT", "Times-Italic" }, { "TimesNewRomanPSMT", "Times-Roman" }, { "TimesNewRomanPSMT,Bold", "Times-Bold" }, { "TimesNewRomanPSMT,BoldItalic", "Times-BoldItalic" }, { "TimesNewRomanPSMT,Italic", "Times-Italic" }, { "ZapfDingbats", "ZapfDingbats" } }; //------------------------------------------------------------------------ // index: {fixed:0, sans-serif:4, serif:8} + bold*2 + italic // NB: must be in same order as psSubstFonts in PSOutputDev.cc static const char *base14SubstFonts[14] = { "Courier", "Courier-Oblique", "Courier-Bold", "Courier-BoldOblique", "Helvetica", "Helvetica-Oblique", "Helvetica-Bold", "Helvetica-BoldOblique", "Times-Roman", "Times-Italic", "Times-Bold", "Times-BoldItalic", // the last two are never used for substitution "Symbol", "ZapfDingbats" }; //------------------------------------------------------------------------ static int parseCharName(char *charName, Unicode *uBuf, int uLen, bool names, bool ligatures, bool numeric, bool hex, bool variants); //------------------------------------------------------------------------ static int readFromStream(void *data) { return ((Stream *)data)->getChar(); } //------------------------------------------------------------------------ // GfxFontLoc //------------------------------------------------------------------------ GfxFontLoc::GfxFontLoc() { path = nullptr; fontNum = 0; encoding = nullptr; substIdx = -1; } GfxFontLoc::~GfxFontLoc() { if (path) { delete path; } if (encoding) { delete encoding; } } //------------------------------------------------------------------------ // GfxFont //------------------------------------------------------------------------ GfxFont *GfxFont::makeFont(XRef *xref, const char *tagA, Ref idA, Dict *fontDict) { GooString *nameA; Ref embFontIDA; GfxFontType typeA; GfxFont *font; // get base font name nameA = nullptr; Object obj1 = fontDict->lookup("BaseFont"); if (obj1.isName()) { nameA = new GooString(obj1.getName()); } // get embedded font ID and font type typeA = getFontType(xref, fontDict, &embFontIDA); // create the font object font = nullptr; if (typeA < fontCIDType0) { font = new Gfx8BitFont(xref, tagA, idA, nameA, typeA, embFontIDA, fontDict); } else { font = new GfxCIDFont(xref, tagA, idA, nameA, typeA, embFontIDA, fontDict); } return font; } GfxFont::GfxFont(const char *tagA, Ref idA, const GooString *nameA, GfxFontType typeA, Ref embFontIDA) { ok = false; tag = new GooString(tagA); id = idA; name = nameA; type = typeA; embFontID = embFontIDA; embFontName = nullptr; family = nullptr; stretch = StretchNotDefined; weight = WeightNotDefined; refCnt = 1; encodingName = new GooString(""); hasToUnicode = false; } GfxFont::~GfxFont() { delete tag; delete family; if (name) { delete name; } if (embFontName) { delete embFontName; } if (encodingName) { delete encodingName; } } void GfxFont::incRefCnt() { refCnt++; } void GfxFont::decRefCnt() { if (--refCnt == 0) delete this; } bool GfxFont::isSubset() const { if (name) { int i; for (i = 0; i < name->getLength(); ++i) { if (name->getChar(i) < 'A' || name->getChar(i) > 'Z') { break; } } return i == 6 && name->getLength() > 7 && name->getChar(6) == '+'; } return false; } std::string GfxFont::getNameWithoutSubsetTag() const { if (!name) { return {}; } if (!isSubset()) { return name->toStr(); } return name->toStr().substr(7); } // This function extracts three pieces of information: // 1. the "expected" font type, i.e., the font type implied by // Font.Subtype, DescendantFont.Subtype, and // FontDescriptor.FontFile3.Subtype // 2. the embedded font object ID // 3. the actual font type - determined by examining the embedded font // if there is one, otherwise equal to the expected font type // If the expected and actual font types don't match, a warning // message is printed. The expected font type is not used for // anything else. GfxFontType GfxFont::getFontType(XRef *xref, Dict *fontDict, Ref *embID) { GfxFontType t, expectedType; FoFiIdentifierType fft; Dict *fontDict2; bool isType0, err; t = fontUnknownType; *embID = Ref::INVALID(); err = false; Object subtype = fontDict->lookup("Subtype"); expectedType = fontUnknownType; isType0 = false; if (subtype.isName("Type1") || subtype.isName("MMType1")) { expectedType = fontType1; } else if (subtype.isName("Type1C")) { expectedType = fontType1C; } else if (subtype.isName("Type3")) { expectedType = fontType3; } else if (subtype.isName("TrueType")) { expectedType = fontTrueType; } else if (subtype.isName("Type0")) { isType0 = true; } else { error(errSyntaxWarning, -1, "Unknown font type: '{0:s}'", subtype.isName() ? subtype.getName() : "???"); } fontDict2 = fontDict; Object obj1 = fontDict->lookup("DescendantFonts"); Object obj2; // Do not move to inside the if // we need it around so that fontDict2 remains valid if (obj1.isArray()) { if (obj1.arrayGetLength() == 0) { error(errSyntaxWarning, -1, "Empty DescendantFonts array in font"); } else { obj2 = obj1.arrayGet(0); if (obj2.isDict()) { if (!isType0) { error(errSyntaxWarning, -1, "Non-CID font with DescendantFonts array"); } fontDict2 = obj2.getDict(); subtype = fontDict2->lookup("Subtype"); if (subtype.isName("CIDFontType0")) { if (isType0) { expectedType = fontCIDType0; } } else if (subtype.isName("CIDFontType2")) { if (isType0) { expectedType = fontCIDType2; } } } } } Object fontDesc = fontDict2->lookup("FontDescriptor"); if (fontDesc.isDict()) { Object obj3 = fontDesc.dictLookupNF("FontFile").copy(); if (obj3.isRef()) { *embID = obj3.getRef(); if (expectedType != fontType1) { err = true; } } if (*embID == Ref::INVALID() && (obj3 = fontDesc.dictLookupNF("FontFile2").copy(), obj3.isRef())) { *embID = obj3.getRef(); if (isType0) { expectedType = fontCIDType2; } else if (expectedType != fontTrueType) { err = true; } } if (*embID == Ref::INVALID() && (obj3 = fontDesc.dictLookupNF("FontFile3").copy(), obj3.isRef())) { *embID = obj3.getRef(); Object obj4 = obj3.fetch(xref); if (obj4.isStream()) { subtype = obj4.streamGetDict()->lookup("Subtype"); if (subtype.isName("Type1")) { if (expectedType != fontType1) { err = true; expectedType = isType0 ? fontCIDType0 : fontType1; } } else if (subtype.isName("Type1C")) { if (expectedType == fontType1) { expectedType = fontType1C; } else if (expectedType != fontType1C) { err = true; expectedType = isType0 ? fontCIDType0C : fontType1C; } } else if (subtype.isName("TrueType")) { if (expectedType != fontTrueType) { err = true; expectedType = isType0 ? fontCIDType2 : fontTrueType; } } else if (subtype.isName("CIDFontType0C")) { if (expectedType == fontCIDType0) { expectedType = fontCIDType0C; } else { err = true; expectedType = isType0 ? fontCIDType0C : fontType1C; } } else if (subtype.isName("OpenType")) { if (expectedType == fontTrueType) { expectedType = fontTrueTypeOT; } else if (expectedType == fontType1) { expectedType = fontType1COT; } else if (expectedType == fontCIDType0) { expectedType = fontCIDType0COT; } else if (expectedType == fontCIDType2) { expectedType = fontCIDType2OT; } else { err = true; } } else { error(errSyntaxError, -1, "Unknown font type '{0:s}'", subtype.isName() ? subtype.getName() : "???"); } } } } t = fontUnknownType; if (*embID != Ref::INVALID()) { Object obj3(*embID); Object obj4 = obj3.fetch(xref); if (obj4.isStream()) { obj4.streamReset(); fft = FoFiIdentifier::identifyStream(&readFromStream, obj4.getStream()); obj4.streamClose(); switch (fft) { case fofiIdType1PFA: case fofiIdType1PFB: t = fontType1; break; case fofiIdCFF8Bit: t = isType0 ? fontCIDType0C : fontType1C; break; case fofiIdCFFCID: t = fontCIDType0C; break; case fofiIdTrueType: case fofiIdTrueTypeCollection: t = isType0 ? fontCIDType2 : fontTrueType; break; case fofiIdOpenTypeCFF8Bit: t = isType0 ? fontCIDType0COT : fontType1COT; break; case fofiIdOpenTypeCFFCID: t = fontCIDType0COT; break; default: error(errSyntaxError, -1, "Embedded font file may be invalid"); break; } } } if (t == fontUnknownType) { t = expectedType; } if (t != expectedType) { err = true; } if (err) { error(errSyntaxWarning, -1, "Mismatch between font type and embedded font file"); } return t; } void GfxFont::readFontDescriptor(XRef *xref, Dict *fontDict) { double t; // assume Times-Roman by default (for substitution purposes) flags = fontSerif; missingWidth = 0; Object obj1 = fontDict->lookup("FontDescriptor"); if (obj1.isDict()) { // get flags Object obj2 = obj1.dictLookup("Flags"); if (obj2.isInt()) { flags = obj2.getInt(); } // get name obj2 = obj1.dictLookup("FontName"); if (obj2.isName()) { embFontName = new GooString(obj2.getName()); } if (embFontName == nullptr) { // get name with typo obj2 = obj1.dictLookup("Fontname"); if (obj2.isName()) { embFontName = new GooString(obj2.getName()); error(errSyntaxWarning, -1, "The file uses Fontname instead of FontName please notify the creator that the file is broken"); } } // get family obj2 = obj1.dictLookup("FontFamily"); if (obj2.isString()) family = new GooString(obj2.getString()); // get stretch obj2 = obj1.dictLookup("FontStretch"); if (obj2.isName()) { if (strcmp(obj2.getName(), "UltraCondensed") == 0) stretch = UltraCondensed; else if (strcmp(obj2.getName(), "ExtraCondensed") == 0) stretch = ExtraCondensed; else if (strcmp(obj2.getName(), "Condensed") == 0) stretch = Condensed; else if (strcmp(obj2.getName(), "SemiCondensed") == 0) stretch = SemiCondensed; else if (strcmp(obj2.getName(), "Normal") == 0) stretch = Normal; else if (strcmp(obj2.getName(), "SemiExpanded") == 0) stretch = SemiExpanded; else if (strcmp(obj2.getName(), "Expanded") == 0) stretch = Expanded; else if (strcmp(obj2.getName(), "ExtraExpanded") == 0) stretch = ExtraExpanded; else if (strcmp(obj2.getName(), "UltraExpanded") == 0) stretch = UltraExpanded; else error(errSyntaxWarning, -1, "Invalid Font Stretch"); } // get weight obj2 = obj1.dictLookup("FontWeight"); if (obj2.isNum()) { if (obj2.getNum() == 100) weight = W100; else if (obj2.getNum() == 200) weight = W200; else if (obj2.getNum() == 300) weight = W300; else if (obj2.getNum() == 400) weight = W400; else if (obj2.getNum() == 500) weight = W500; else if (obj2.getNum() == 600) weight = W600; else if (obj2.getNum() == 700) weight = W700; else if (obj2.getNum() == 800) weight = W800; else if (obj2.getNum() == 900) weight = W900; else error(errSyntaxWarning, -1, "Invalid Font Weight"); } // look for MissingWidth obj2 = obj1.dictLookup("MissingWidth"); if (obj2.isNum()) { missingWidth = obj2.getNum(); } // get Ascent and Descent obj2 = obj1.dictLookup("Ascent"); if (obj2.isNum()) { t = 0.001 * obj2.getNum(); // some broken font descriptors specify a negative ascent if (t < 0) { t = -t; } // some broken font descriptors set ascent and descent to 0; // others set it to ridiculous values (e.g., 32768) if (t != 0 && t < 3) { ascent = t; } } obj2 = obj1.dictLookup("Descent"); if (obj2.isNum()) { t = 0.001 * obj2.getNum(); // some broken font descriptors specify a positive descent if (t > 0) { t = -t; } // some broken font descriptors set ascent and descent to 0 if (t != 0 && t > -3) { descent = t; } } // font FontBBox obj2 = obj1.dictLookup("FontBBox"); if (obj2.isArray()) { for (int i = 0; i < 4 && i < obj2.arrayGetLength(); ++i) { Object obj3 = obj2.arrayGet(i); if (obj3.isNum()) { fontBBox[i] = 0.001 * obj3.getNum(); } } } } } CharCodeToUnicode *GfxFont::readToUnicodeCMap(Dict *fontDict, int nBits, CharCodeToUnicode *ctu) { GooString *buf; Object obj1 = fontDict->lookup("ToUnicode"); if (!obj1.isStream()) { return nullptr; } buf = new GooString(); obj1.getStream()->fillGooString(buf); obj1.streamClose(); if (ctu) { ctu->mergeCMap(buf, nBits); } else { ctu = CharCodeToUnicode::parseCMap(buf, nBits); } hasToUnicode = true; delete buf; return ctu; } GfxFontLoc *GfxFont::locateFont(XRef *xref, PSOutputDev *ps) { GfxFontLoc *fontLoc; SysFontType sysFontType; GooString *path, *base14Name, *substName; int substIdx, fontNum; bool embed; if (type == fontType3) { return nullptr; } //----- embedded font if (embFontID != Ref::INVALID()) { embed = true; Object refObj(embFontID); Object embFontObj = refObj.fetch(xref); if (!embFontObj.isStream()) { error(errSyntaxError, -1, "Embedded font object is wrong type"); embed = false; } if (embed) { if (ps) { switch (type) { case fontType1: case fontType1C: case fontType1COT: embed = ps->getEmbedType1(); break; case fontTrueType: case fontTrueTypeOT: embed = ps->getEmbedTrueType(); break; case fontCIDType0C: case fontCIDType0COT: embed = ps->getEmbedCIDPostScript(); break; case fontCIDType2: case fontCIDType2OT: embed = ps->getEmbedCIDTrueType(); break; default: break; } } if (embed) { fontLoc = new GfxFontLoc(); fontLoc->locType = gfxFontLocEmbedded; fontLoc->fontType = type; fontLoc->embFontID = embFontID; return fontLoc; } } } //----- PS passthrough if (ps && !isCIDFont() && ps->getFontPassthrough()) { fontLoc = new GfxFontLoc(); fontLoc->locType = gfxFontLocResident; fontLoc->fontType = fontType1; fontLoc->path = name->copy(); return fontLoc; } //----- PS resident Base-14 font if (ps && !isCIDFont() && ((Gfx8BitFont *)this)->base14) { fontLoc = new GfxFontLoc(); fontLoc->locType = gfxFontLocResident; fontLoc->fontType = fontType1; fontLoc->path = new GooString(((Gfx8BitFont *)this)->base14->base14Name); return fontLoc; } //----- external font file (fontFile, fontDir) if (name && (path = globalParams->findFontFile(name))) { if ((fontLoc = getExternalFont(path, isCIDFont()))) { return fontLoc; } } //----- external font file for Base-14 font if (!ps && !isCIDFont() && ((Gfx8BitFont *)this)->base14) { base14Name = new GooString(((Gfx8BitFont *)this)->base14->base14Name); if ((path = globalParams->findBase14FontFile(base14Name, this))) { if ((fontLoc = getExternalFont(path, false))) { delete base14Name; return fontLoc; } } delete base14Name; } //----- system font if ((path = globalParams->findSystemFontFile(this, &sysFontType, &fontNum))) { if (isCIDFont()) { if (sysFontType == sysFontTTF || sysFontType == sysFontTTC) { fontLoc = new GfxFontLoc(); fontLoc->locType = gfxFontLocExternal; fontLoc->fontType = fontCIDType2; fontLoc->path = path; fontLoc->fontNum = fontNum; return fontLoc; } } else { if (sysFontType == sysFontTTF || sysFontType == sysFontTTC) { fontLoc = new GfxFontLoc(); fontLoc->locType = gfxFontLocExternal; fontLoc->fontType = fontTrueType; fontLoc->path = path; return fontLoc; } else if (sysFontType == sysFontPFA || sysFontType == sysFontPFB) { fontLoc = new GfxFontLoc(); fontLoc->locType = gfxFontLocExternal; fontLoc->fontType = fontType1; fontLoc->path = path; fontLoc->fontNum = fontNum; return fontLoc; } } delete path; } if (!isCIDFont()) { //----- 8-bit font substitution if (flags & fontFixedWidth) { substIdx = 0; } else if (flags & fontSerif) { substIdx = 8; } else { substIdx = 4; } if (isBold()) { substIdx += 2; } if (isItalic()) { substIdx += 1; } substName = new GooString(base14SubstFonts[substIdx]); if (ps) { error(errSyntaxWarning, -1, "Substituting font '{0:s}' for '{1:s}'", base14SubstFonts[substIdx], name ? name->c_str() : "null"); fontLoc = new GfxFontLoc(); fontLoc->locType = gfxFontLocResident; fontLoc->fontType = fontType1; fontLoc->path = substName; fontLoc->substIdx = substIdx; return fontLoc; } else { path = globalParams->findFontFile(substName); delete substName; if (path) { if ((fontLoc = getExternalFont(path, false))) { error(errSyntaxWarning, -1, "Substituting font '{0:s}' for '{1:s}'", base14SubstFonts[substIdx], name ? name->c_str() : ""); name = new GooString(base14SubstFonts[substIdx]); fontLoc->substIdx = substIdx; return fontLoc; } } } // failed to find a substitute font return nullptr; } // failed to find a substitute font return nullptr; } GfxFontLoc *GfxFont::locateBase14Font(const GooString *base14Name) { GooString *path; path = globalParams->findFontFile(base14Name); if (!path) { return nullptr; } return getExternalFont(path, false); } GfxFontLoc *GfxFont::getExternalFont(GooString *path, bool cid) { FoFiIdentifierType fft; GfxFontType fontType; GfxFontLoc *fontLoc; fft = FoFiIdentifier::identifyFile(path->c_str()); switch (fft) { case fofiIdType1PFA: case fofiIdType1PFB: fontType = fontType1; break; case fofiIdCFF8Bit: fontType = fontType1C; break; case fofiIdCFFCID: fontType = fontCIDType0C; break; case fofiIdTrueType: case fofiIdTrueTypeCollection: fontType = cid ? fontCIDType2 : fontTrueType; break; case fofiIdOpenTypeCFF8Bit: fontType = fontType1COT; break; case fofiIdOpenTypeCFFCID: fontType = fontCIDType0COT; break; case fofiIdUnknown: case fofiIdError: default: fontType = fontUnknownType; break; } if (fontType == fontUnknownType || (cid ? (fontType < fontCIDType0) : (fontType >= fontCIDType0))) { delete path; return nullptr; } fontLoc = new GfxFontLoc(); fontLoc->locType = gfxFontLocExternal; fontLoc->fontType = fontType; fontLoc->path = path; return fontLoc; } char *GfxFont::readEmbFontFile(XRef *xref, int *len) { char *buf; Stream *str; Object obj1(embFontID); Object obj2 = obj1.fetch(xref); if (!obj2.isStream()) { error(errSyntaxError, -1, "Embedded font file is not a stream"); embFontID = Ref::INVALID(); *len = 0; return nullptr; } str = obj2.getStream(); buf = (char *)str->toUnsignedChars(len); str->close(); return buf; } struct AlternateNameMap { const char *name; const char *alt; }; static const AlternateNameMap alternateNameMap[] = { { "fi", "f_i" }, { "fl", "f_l" }, { "ff", "f_f" }, { "ffi", "f_f_i" }, { "ffl", "f_f_l" }, { nullptr, nullptr } }; const char *GfxFont::getAlternateName(const char *name) { const AlternateNameMap *map = alternateNameMap; while (map->name) { if (strcmp(name, map->name) == 0) { return map->alt; } map++; } return nullptr; } //------------------------------------------------------------------------ // Gfx8BitFont //------------------------------------------------------------------------ // Parse character names of the form 'Axx', 'xx', 'Ann', 'ABnn', or // 'nn', where 'A' and 'B' are any letters, 'xx' is two hex digits, // and 'nn' is decimal digits. static bool parseNumericName(const char *s, bool hex, unsigned int *u) { char *endptr; // Strip leading alpha characters. if (hex) { int n = 0; // Get string length while ignoring junk at end. while (isalnum(s[n])) ++n; // Only 2 hex characters with optional leading alpha is allowed. if (n == 3 && isalpha(*s)) { ++s; } else if (n != 2) { return false; } } else { // Strip up to two alpha characters. for (int i = 0; i < 2 && isalpha(*s); ++i) ++s; } int v = strtol(s, &endptr, hex ? 16 : 10); if (endptr == s) return false; // Skip trailing junk characters. while (*endptr != '\0' && !isalnum(*endptr)) ++endptr; if (*endptr == '\0') { if (u) *u = v; return true; } return false; } // Returns true if the font has character names like xx or Axx which // should be parsed for hex or decimal values. static bool testForNumericNames(Dict *fontDict, bool hex) { bool numeric = true; Object enc = fontDict->lookup("Encoding"); if (!enc.isDict()) { return false; } Object diff = enc.dictLookup("Differences"); if (!diff.isArray()) { return false; } for (int i = 0; i < diff.arrayGetLength() && numeric; ++i) { Object obj = diff.arrayGet(i); if (obj.isInt()) { // All sequences must start between character codes 0 and 5. if (obj.getInt() > 5) numeric = false; } else if (obj.isName()) { // All character names must successfully parse. if (!parseNumericName(obj.getName(), hex, nullptr)) numeric = false; } else { numeric = false; } } return numeric; } Gfx8BitFont::Gfx8BitFont(XRef *xref, const char *tagA, Ref idA, GooString *nameA, GfxFontType typeA, Ref embFontIDA, Dict *fontDict) : GfxFont(tagA, idA, nameA, typeA, embFontIDA) { GooString *name2; const BuiltinFont *builtinFont; const char **baseEnc; bool baseEncFromFontFile; char *buf; int len; FoFiType1 *ffT1; FoFiType1C *ffT1C; char *charName; bool missing, hex; bool numeric; Unicode toUnicode[256]; Unicode uBuf[8]; double mul; int firstChar, lastChar; unsigned short w; Object obj1; int n, i, a, b, m; refCnt = 1; ctu = nullptr; // do font name substitution for various aliases of the Base 14 font // names base14 = nullptr; if (name) { name2 = name->copy(); i = 0; while (i < name2->getLength()) { if (name2->getChar(i) == ' ') { name2->del(i); } else { ++i; } } a = 0; b = sizeof(base14FontMap) / sizeof(Base14FontMapEntry); // invariant: base14FontMap[a].altName <= name2 < base14FontMap[b].altName while (b - a > 1) { m = (a + b) / 2; if (name2->cmp(base14FontMap[m].altName) >= 0) { a = m; } else { b = m; } } if (!name2->cmp(base14FontMap[a].altName)) { base14 = &base14FontMap[a]; } delete name2; } // is it a built-in font? builtinFont = nullptr; if (base14) { for (const BuiltinFont &bf : builtinFonts) { if (!strcmp(base14->base14Name, bf.name)) { builtinFont = &bf; break; } } } // default ascent/descent values if (builtinFont) { ascent = 0.001 * builtinFont->ascent; descent = 0.001 * builtinFont->descent; fontBBox[0] = 0.001 * builtinFont->bbox[0]; fontBBox[1] = 0.001 * builtinFont->bbox[1]; fontBBox[2] = 0.001 * builtinFont->bbox[2]; fontBBox[3] = 0.001 * builtinFont->bbox[3]; } else { ascent = 0.95; descent = -0.35; fontBBox[0] = fontBBox[1] = fontBBox[2] = fontBBox[3] = 0; } // get info from font descriptor readFontDescriptor(xref, fontDict); // for non-embedded fonts, don't trust the ascent/descent/bbox // values from the font descriptor if (builtinFont && embFontID == Ref::INVALID()) { ascent = 0.001 * builtinFont->ascent; descent = 0.001 * builtinFont->descent; fontBBox[0] = 0.001 * builtinFont->bbox[0]; fontBBox[1] = 0.001 * builtinFont->bbox[1]; fontBBox[2] = 0.001 * builtinFont->bbox[2]; fontBBox[3] = 0.001 * builtinFont->bbox[3]; } // get font matrix fontMat[0] = fontMat[3] = 1; fontMat[1] = fontMat[2] = fontMat[4] = fontMat[5] = 0; obj1 = fontDict->lookup("FontMatrix"); if (obj1.isArray()) { for (i = 0; i < 6 && i < obj1.arrayGetLength(); ++i) { Object obj2 = obj1.arrayGet(i); if (obj2.isNum()) { fontMat[i] = obj2.getNum(); } } } // get Type 3 bounding box, font definition, and resources if (type == fontType3) { obj1 = fontDict->lookup("FontBBox"); if (obj1.isArray()) { for (i = 0; i < 4 && i < obj1.arrayGetLength(); ++i) { Object obj2 = obj1.arrayGet(i); if (obj2.isNum()) { fontBBox[i] = obj2.getNum(); } } } charProcs = fontDict->lookup("CharProcs"); if (!charProcs.isDict()) { error(errSyntaxError, -1, "Missing or invalid CharProcs dictionary in Type 3 font"); charProcs.setToNull(); } resources = fontDict->lookup("Resources"); if (!resources.isDict()) { resources.setToNull(); } } //----- build the font encoding ----- // Encodings start with a base encoding, which can come from // (in order of priority): // 1. FontDict.Encoding or FontDict.Encoding.BaseEncoding // - MacRoman / MacExpert / WinAnsi / Standard // 2. embedded or external font file // 3. default: // - builtin --> builtin encoding // - TrueType --> WinAnsiEncoding // - others --> StandardEncoding // and then add a list of differences (if any) from // FontDict.Encoding.Differences. // check FontDict for base encoding hasEncoding = false; usesMacRomanEnc = false; baseEnc = nullptr; baseEncFromFontFile = false; obj1 = fontDict->lookup("Encoding"); if (obj1.isDict()) { Object obj2 = obj1.dictLookup("BaseEncoding"); if (obj2.isName("MacRomanEncoding")) { hasEncoding = true; usesMacRomanEnc = true; baseEnc = macRomanEncoding; } else if (obj2.isName("MacExpertEncoding")) { hasEncoding = true; baseEnc = macExpertEncoding; } else if (obj2.isName("WinAnsiEncoding")) { hasEncoding = true; baseEnc = winAnsiEncoding; } } else if (obj1.isName("MacRomanEncoding")) { hasEncoding = true; usesMacRomanEnc = true; baseEnc = macRomanEncoding; } else if (obj1.isName("MacExpertEncoding")) { hasEncoding = true; baseEnc = macExpertEncoding; } else if (obj1.isName("WinAnsiEncoding")) { hasEncoding = true; baseEnc = winAnsiEncoding; } // check embedded font file for base encoding // (only for Type 1 fonts - trying to get an encoding out of a // TrueType font is a losing proposition) ffT1 = nullptr; ffT1C = nullptr; buf = nullptr; if (type == fontType1 && embFontID != Ref::INVALID()) { if ((buf = readEmbFontFile(xref, &len))) { if ((ffT1 = FoFiType1::make(buf, len))) { if (ffT1->getName()) { if (embFontName) { delete embFontName; } embFontName = new GooString(ffT1->getName()); } if (!baseEnc) { baseEnc = (const char **)ffT1->getEncoding(); baseEncFromFontFile = true; } } gfree(buf); } } else if (type == fontType1C && embFontID != Ref::INVALID()) { if ((buf = readEmbFontFile(xref, &len))) { if ((ffT1C = FoFiType1C::make(buf, len))) { if (ffT1C->getName()) { if (embFontName) { delete embFontName; } embFontName = new GooString(ffT1C->getName()); } if (!baseEnc) { baseEnc = (const char **)ffT1C->getEncoding(); baseEncFromFontFile = true; } } gfree(buf); } } // get default base encoding if (!baseEnc) { if (builtinFont && embFontID == Ref::INVALID()) { baseEnc = builtinFont->defaultBaseEnc; hasEncoding = true; } else if (type == fontTrueType) { baseEnc = winAnsiEncoding; } else { baseEnc = standardEncoding; } } if (baseEncFromFontFile) { encodingName->Set("Builtin"); } else if (baseEnc == winAnsiEncoding) { encodingName->Set("WinAnsi"); } else if (baseEnc == macRomanEncoding) { encodingName->Set("MacRoman"); } else if (baseEnc == macExpertEncoding) { encodingName->Set("MacExpert"); } else if (baseEnc == symbolEncoding) { encodingName->Set("Symbol"); } else if (baseEnc == zapfDingbatsEncoding) { encodingName->Set("ZapfDingbats"); } else { encodingName->Set("Standard"); } // copy the base encoding for (i = 0; i < 256; ++i) { enc[i] = (char *)baseEnc[i]; if ((encFree[i] = baseEncFromFontFile) && enc[i]) { enc[i] = copyString(baseEnc[i]); } } // some Type 1C font files have empty encodings, which can break the // T1C->T1 conversion (since the 'seac' operator depends on having // the accents in the encoding), so we fill in any gaps from // StandardEncoding if (type == fontType1C && embFontID != Ref::INVALID() && baseEncFromFontFile) { for (i = 0; i < 256; ++i) { if (!enc[i] && standardEncoding[i]) { enc[i] = (char *)standardEncoding[i]; encFree[i] = false; } } } // merge differences into encoding if (obj1.isDict()) { Object obj2 = obj1.dictLookup("Differences"); if (obj2.isArray()) { encodingName->Set("Custom"); hasEncoding = true; int code = 0; for (i = 0; i < obj2.arrayGetLength(); ++i) { Object obj3 = obj2.arrayGet(i); if (obj3.isInt()) { code = obj3.getInt(); } else if (obj3.isName()) { if (code >= 0 && code < 256) { if (encFree[code]) { gfree(enc[code]); } enc[code] = copyString(obj3.getName()); encFree[code] = true; ++code; } } else { error(errSyntaxError, -1, "Wrong type in font encoding resource differences ({0:s})", obj3.getTypeName()); } } } } delete ffT1; delete ffT1C; //----- build the mapping to Unicode ----- // pass 1: use the name-to-Unicode mapping table missing = hex = false; bool isZapfDingbats = name && name->endsWith("ZapfDingbats"); for (int code = 0; code < 256; ++code) { if ((charName = enc[code])) { if (isZapfDingbats) { // include ZapfDingbats names toUnicode[code] = globalParams->mapNameToUnicodeAll(charName); } else { toUnicode[code] = globalParams->mapNameToUnicodeText(charName); } if (!toUnicode[code] && strcmp(charName, ".notdef")) { // if it wasn't in the name-to-Unicode table, check for a // name that looks like 'Axx' or 'xx', where 'A' is any letter // and 'xx' is two hex digits if ((strlen(charName) == 3 && isalpha(charName[0]) && isxdigit(charName[1]) && isxdigit(charName[2]) && ((charName[1] >= 'a' && charName[1] <= 'f') || (charName[1] >= 'A' && charName[1] <= 'F') || (charName[2] >= 'a' && charName[2] <= 'f') || (charName[2] >= 'A' && charName[2] <= 'F'))) || (strlen(charName) == 2 && isxdigit(charName[0]) && isxdigit(charName[1]) && // Only check idx 1 to avoid misidentifying a decimal // number like a0 ((charName[1] >= 'a' && charName[1] <= 'f') || (charName[1] >= 'A' && charName[1] <= 'F')))) { hex = true; } missing = true; } } else { toUnicode[code] = 0; } } numeric = testForNumericNames(fontDict, hex); // construct the char code -> Unicode mapping object ctu = CharCodeToUnicode::make8BitToUnicode(toUnicode); // pass 1a: Expand ligatures in the Alphabetic Presentation Form // block (eg "fi", "ffi") to normal form for (int code = 0; code < 256; ++code) { if (unicodeIsAlphabeticPresentationForm(toUnicode[code])) { Unicode *normalized = unicodeNormalizeNFKC(&toUnicode[code], 1, &len, nullptr); if (len > 1) ctu->setMapping((CharCode)code, normalized, len); gfree(normalized); } } // pass 2: try to fill in the missing chars, looking for ligatures, numeric // references and variants if (missing) { for (int code = 0; code < 256; ++code) { if (!toUnicode[code]) { if ((charName = enc[code]) && strcmp(charName, ".notdef") && (n = parseCharName(charName, uBuf, sizeof(uBuf) / sizeof(*uBuf), false, // don't check simple names (pass 1) true, // do check ligatures numeric, hex, true))) { // do check variants ctu->setMapping((CharCode)code, uBuf, n); continue; } // do a simple pass-through // mapping for unknown character names uBuf[0] = code; ctu->setMapping((CharCode)code, uBuf, 1); } } } // merge in a ToUnicode CMap, if there is one -- this overwrites // existing entries in ctu, i.e., the ToUnicode CMap takes // precedence, but the other encoding info is allowed to fill in any // holes readToUnicodeCMap(fontDict, 16, ctu); //----- get the character widths ----- // initialize all widths for (double &width : widths) { width = missingWidth * 0.001; } // use widths from font dict, if present obj1 = fontDict->lookup("FirstChar"); firstChar = obj1.isInt() ? obj1.getInt() : 0; if (firstChar < 0 || firstChar > 255) { firstChar = 0; } obj1 = fontDict->lookup("LastChar"); lastChar = obj1.isInt() ? obj1.getInt() : 255; if (lastChar < 0 || lastChar > 255) { lastChar = 255; } mul = (type == fontType3) ? fontMat[0] : 0.001; obj1 = fontDict->lookup("Widths"); if (obj1.isArray()) { flags |= fontFixedWidth; if (obj1.arrayGetLength() < lastChar - firstChar + 1) { lastChar = firstChar + obj1.arrayGetLength() - 1; } for (int code = firstChar; code <= lastChar; ++code) { Object obj2 = obj1.arrayGet(code - firstChar); if (obj2.isNum()) { widths[code] = obj2.getNum() * mul; if (fabs(widths[code] - widths[firstChar]) > 0.00001) { flags &= ~fontFixedWidth; } } } // use widths from built-in font } else if (builtinFont) { // this is a kludge for broken PDF files that encode char 32 // as .notdef if (builtinFont->getWidth("space", &w)) { widths[32] = 0.001 * w; } for (int code = 0; code < 256; ++code) { if (enc[code] && builtinFont->getWidth(enc[code], &w)) { widths[code] = 0.001 * w; } } // couldn't find widths -- use defaults } else { // this is technically an error -- the Widths entry is required // for all but the Base-14 fonts -- but certain PDF generators // apparently don't include widths for Arial and TimesNewRoman if (isFixedWidth()) { i = 0; } else if (isSerif()) { i = 8; } else { i = 4; } if (isBold()) { i += 2; } if (isItalic()) { i += 1; } builtinFont = builtinFontSubst[i]; // this is a kludge for broken PDF files that encode char 32 // as .notdef if (builtinFont->getWidth("space", &w)) { widths[32] = 0.001 * w; } for (int code = 0; code < 256; ++code) { if (enc[code] && builtinFont->getWidth(enc[code], &w)) { widths[code] = 0.001 * w; } } } ok = true; } Gfx8BitFont::~Gfx8BitFont() { int i; for (i = 0; i < 256; ++i) { if (encFree[i] && enc[i]) { gfree(enc[i]); } } ctu->decRefCnt(); } // This function is in part a derived work of the Adobe Glyph Mapping // Convention: http://www.adobe.com/devnet/opentype/archives/glyph.html // Algorithmic comments are excerpted from that document to aid // maintainability. static int parseCharName(char *charName, Unicode *uBuf, int uLen, bool names, bool ligatures, bool numeric, bool hex, bool variants) { if (uLen <= 0) { error(errInternal, -1, "Zero-length output buffer (recursion overflow?) in " "parseCharName, component \"{0:s}\"", charName); return 0; } // Step 1: drop all the characters from the glyph name starting with the // first occurrence of a period (U+002E FULL STOP), if any. if (variants) { char *var_part = strchr(charName, '.'); if (var_part == charName) { return 0; // .notdef or similar } else if (var_part != nullptr) { // parse names of the form 7.oldstyle, P.swash, s.sc, etc. char *main_part = copyString(charName, var_part - charName); bool namesRecurse = true, variantsRecurse = false; int n = parseCharName(main_part, uBuf, uLen, namesRecurse, ligatures, numeric, hex, variantsRecurse); gfree(main_part); return n; } } // Step 2: split the remaining string into a sequence of components, using // underscore (U+005F LOW LINE) as the delimiter. if (ligatures && strchr(charName, '_')) { // parse names of the form A_a (e.g. f_i, T_h, l_quotesingle) char *lig_part, *lig_end, *lig_copy; int n = 0, m; lig_part = lig_copy = copyString(charName); do { if ((lig_end = strchr(lig_part, '_'))) *lig_end = '\0'; if (lig_part[0] != '\0') { bool namesRecurse = true, ligaturesRecurse = false; if ((m = parseCharName(lig_part, uBuf + n, uLen - n, namesRecurse, ligaturesRecurse, numeric, hex, variants))) n += m; else error(errSyntaxWarning, -1, "Could not parse ligature component \"{0:s}\" of \"{1:s}\" in " "parseCharName", lig_part, charName); } if (lig_end) { lig_part = lig_end + 1; } } while (lig_end && n < uLen); gfree(lig_copy); return n; } // Step 3: map each component to a character string according to the // procedure below, and concatenate those strings; the result is the // character string to which the glyph name is mapped. // 3.1. if the font is Zapf Dingbats (PostScript FontName ZapfDingbats), and // the component is in the ZapfDingbats list, then map it to the // corresponding character in that list. // 3.2. otherwise, if the component is in the Adobe Glyph List, then map it // to the corresponding character in that list. if (names && (uBuf[0] = globalParams->mapNameToUnicodeText(charName))) { return 1; } unsigned int n = strlen(charName); // 3.3. otherwise, if the component is of the form "uni" (U+0075 U+006E // U+0069) followed by a sequence of uppercase hexadecimal digits (0 .. 9, // A .. F, i.e. U+0030 .. U+0039, U+0041 .. U+0046), the length of that // sequence is a multiple of four, and each group of four digits represents // a number in the set {0x0000 .. 0xD7FF, 0xE000 .. 0xFFFF}, then interpret // each such number as a Unicode scalar value and map the component to the // string made of those scalar values. Note that the range and digit length // restrictions mean that the "uni" prefix can be used only with Unicode // values from the Basic Multilingual Plane (BMP). if (n >= 7 && (n % 4) == 3 && !strncmp(charName, "uni", 3)) { int i; unsigned int m; for (i = 0, m = 3; i < uLen && m < n; m += 4) { if (isxdigit(charName[m]) && isxdigit(charName[m + 1]) && isxdigit(charName[m + 2]) && isxdigit(charName[m + 3])) { unsigned int u; sscanf(charName + m, "%4x", &u); if (u <= 0xD7FF || (0xE000 <= u && u <= 0xFFFF)) { uBuf[i++] = u; } } } return i; } // 3.4. otherwise, if the component is of the form "u" (U+0075) followed by // a sequence of four to six uppercase hexadecimal digits {0 .. 9, A .. F} // (U+0030 .. U+0039, U+0041 .. U+0046), and those digits represent a // number in {0x0000 .. 0xD7FF, 0xE000 .. 0x10FFFF}, then interpret this // number as a Unicode scalar value and map the component to the string // made of this scalar value. if (n >= 5 && n <= 7 && charName[0] == 'u' && isxdigit(charName[1]) && isxdigit(charName[2]) && isxdigit(charName[3]) && isxdigit(charName[4]) && (n <= 5 || isxdigit(charName[5])) && (n <= 6 || isxdigit(charName[6]))) { unsigned int u; sscanf(charName + 1, "%x", &u); if (u <= 0xD7FF || (0xE000 <= u && u <= 0x10FFFF)) { uBuf[0] = u; return 1; } } // Not in Adobe Glyph Mapping convention: look for names like xx // or Axx and parse for hex or decimal values. if (numeric && parseNumericName(charName, hex, uBuf)) return 1; // 3.5. otherwise, map the component to the empty string return 0; } int Gfx8BitFont::getNextChar(const char *s, int len, CharCode *code, Unicode const **u, int *uLen, double *dx, double *dy, double *ox, double *oy) const { CharCode c; *code = c = (CharCode)(*s & 0xff); *uLen = ctu->mapToUnicode(c, u); *dx = widths[c]; *dy = *ox = *oy = 0; return 1; } const CharCodeToUnicode *Gfx8BitFont::getToUnicode() const { return ctu; } int *Gfx8BitFont::getCodeToGIDMap(FoFiTrueType *ff) { int *map; int cmapPlatform, cmapEncoding; int unicodeCmap, macRomanCmap, msSymbolCmap, cmap; bool useMacRoman, useUnicode; char *charName; Unicode u; int code, i, n; map = (int *)gmallocn(256, sizeof(int)); for (i = 0; i < 256; ++i) { map[i] = 0; } // To match up with the Adobe-defined behaviour, we choose a cmap // like this: // 1. If the PDF font has an encoding: // 1a. If the TrueType font has a Microsoft Unicode // cmap or a non-Microsoft Unicode cmap, use it, and use the // Unicode indexes, not the char codes. // 1b. If the PDF font specified MacRomanEncoding and the // TrueType font has a Macintosh Roman cmap, use it, and // reverse map the char names through MacRomanEncoding to // get char codes. // 1c. If the PDF font is symbolic and the TrueType font has a // Microsoft Symbol cmap, use it, and use char codes // directly (possibly with an offset of 0xf000). // 1d. If the TrueType font has a Macintosh Roman cmap, use it, // as in case 1a. // 2. If the PDF font does not have an encoding or the PDF font is // symbolic: // 2a. If the TrueType font has a Macintosh Roman cmap, use it, // and use char codes directly (possibly with an offset of // 0xf000). // 2b. If the TrueType font has a Microsoft Symbol cmap, use it, // and use char codes directly (possible with an offset of // 0xf000). // 3. If none of these rules apply, use the first cmap and hope for // the best (this shouldn't happen). unicodeCmap = macRomanCmap = msSymbolCmap = -1; for (i = 0; i < ff->getNumCmaps(); ++i) { cmapPlatform = ff->getCmapPlatform(i); cmapEncoding = ff->getCmapEncoding(i); if ((cmapPlatform == 3 && cmapEncoding == 1) || cmapPlatform == 0) { unicodeCmap = i; } else if (cmapPlatform == 1 && cmapEncoding == 0) { macRomanCmap = i; } else if (cmapPlatform == 3 && cmapEncoding == 0) { msSymbolCmap = i; } } cmap = 0; useMacRoman = false; useUnicode = false; if (hasEncoding || type == fontType1) { if (unicodeCmap >= 0) { cmap = unicodeCmap; useUnicode = true; } else if (usesMacRomanEnc && macRomanCmap >= 0) { cmap = macRomanCmap; useMacRoman = true; } else if ((flags & fontSymbolic) && msSymbolCmap >= 0) { cmap = msSymbolCmap; } else if ((flags & fontSymbolic) && macRomanCmap >= 0) { cmap = macRomanCmap; } else if (macRomanCmap >= 0) { cmap = macRomanCmap; useMacRoman = true; } } else { if (msSymbolCmap >= 0) { cmap = msSymbolCmap; } else if (macRomanCmap >= 0) { cmap = macRomanCmap; } } // reverse map the char names through MacRomanEncoding, then map the // char codes through the cmap if (useMacRoman) { for (i = 0; i < 256; ++i) { if ((charName = enc[i])) { if ((code = globalParams->getMacRomanCharCode(charName))) { map[i] = ff->mapCodeToGID(cmap, code); } } else { map[i] = -1; } } // map Unicode through the cmap } else if (useUnicode) { const Unicode *uAux; for (i = 0; i < 256; ++i) { if (((charName = enc[i]) && (u = globalParams->mapNameToUnicodeAll(charName)))) map[i] = ff->mapCodeToGID(cmap, u); else { n = ctu->mapToUnicode((CharCode)i, &uAux); if (n > 0) map[i] = ff->mapCodeToGID(cmap, uAux[0]); else map[i] = -1; } } // map the char codes through the cmap, possibly with an offset of // 0xf000 } else { for (i = 0; i < 256; ++i) { if (!(map[i] = ff->mapCodeToGID(cmap, i))) { map[i] = ff->mapCodeToGID(cmap, 0xf000 + i); } } } // try the TrueType 'post' table to handle any unmapped characters for (i = 0; i < 256; ++i) { if (map[i] <= 0 && (charName = enc[i])) { map[i] = ff->mapNameToGID(charName); } } return map; } Dict *Gfx8BitFont::getCharProcs() { return charProcs.isDict() ? charProcs.getDict() : nullptr; } Object Gfx8BitFont::getCharProc(int code) { if (enc[code] && charProcs.isDict()) { return charProcs.dictLookup(enc[code]); } else { return Object(objNull); } } Object Gfx8BitFont::getCharProcNF(int code) { if (enc[code] && charProcs.isDict()) { return charProcs.dictLookupNF(enc[code]).copy(); } else { return Object(objNull); } } Dict *Gfx8BitFont::getResources() { return resources.isDict() ? resources.getDict() : nullptr; } //------------------------------------------------------------------------ // GfxCIDFont //------------------------------------------------------------------------ struct cmpWidthExcepFunctor { bool operator()(const GfxFontCIDWidthExcep w1, const GfxFontCIDWidthExcep w2) { return w1.first < w2.first; } }; struct cmpWidthExcepVFunctor { bool operator()(const GfxFontCIDWidthExcepV &w1, const GfxFontCIDWidthExcepV &w2) { return w1.first < w2.first; } }; GfxCIDFont::GfxCIDFont(XRef *xref, const char *tagA, Ref idA, GooString *nameA, GfxFontType typeA, Ref embFontIDA, Dict *fontDict) : GfxFont(tagA, idA, nameA, typeA, embFontIDA) { Dict *desFontDict; Object desFontDictObj; Object obj1, obj2, obj3, obj4, obj5, obj6; int c1, c2; int excepsSize, j, k; refCnt = 1; ascent = 0.95; descent = -0.35; fontBBox[0] = fontBBox[1] = fontBBox[2] = fontBBox[3] = 0; collection = nullptr; cMap = nullptr; ctu = nullptr; ctuUsesCharCode = true; widths.defWidth = 1.0; widths.defHeight = -1.0; widths.defVY = 0.880; widths.exceps = nullptr; widths.nExceps = 0; widths.excepsV = nullptr; widths.nExcepsV = 0; cidToGID = nullptr; cidToGIDLen = 0; // get the descendant font obj1 = fontDict->lookup("DescendantFonts"); if (!obj1.isArray() || obj1.arrayGetLength() == 0) { error(errSyntaxError, -1, "Missing or empty DescendantFonts entry in Type 0 font"); return; } desFontDictObj = obj1.arrayGet(0); if (!desFontDictObj.isDict()) { error(errSyntaxError, -1, "Bad descendant font in Type 0 font"); return; } desFontDict = desFontDictObj.getDict(); // get info from font descriptor readFontDescriptor(xref, desFontDict); //----- encoding info ----- // char collection obj1 = desFontDict->lookup("CIDSystemInfo"); if (!obj1.isDict()) { error(errSyntaxError, -1, "Missing CIDSystemInfo dictionary in Type 0 descendant font"); return; } obj2 = obj1.dictLookup("Registry"); obj3 = obj1.dictLookup("Ordering"); if (!obj2.isString() || !obj3.isString()) { error(errSyntaxError, -1, "Invalid CIDSystemInfo dictionary in Type 0 descendant font"); return; } collection = obj2.getString()->copy()->append('-')->append(obj3.getString()); // look for a ToUnicode CMap if (!(ctu = readToUnicodeCMap(fontDict, 16, nullptr))) { ctuUsesCharCode = false; // use an identity mapping for the "Adobe-Identity" and // "Adobe-UCS" collections if (!collection->cmp("Adobe-Identity") || !collection->cmp("Adobe-UCS")) { ctu = CharCodeToUnicode::makeIdentityMapping(); } else { // look for a user-supplied .cidToUnicode file if (!(ctu = globalParams->getCIDToUnicode(collection))) { // I'm not completely sure that this is the best thing to do // but it seems to produce better results when the .cidToUnicode // files from the poppler-data package are missing. At least // we know that assuming the Identity mapping is definitely wrong. // -- jrmuizel static const char *knownCollections[] = { "Adobe-CNS1", "Adobe-GB1", "Adobe-Japan1", "Adobe-Japan2", "Adobe-Korea1", }; for (const char *knownCollection : knownCollections) { if (collection->cmp(knownCollection) == 0) { error(errSyntaxError, -1, "Missing language pack for '{0:t}' mapping", collection); return; } } error(errSyntaxError, -1, "Unknown character collection '{0:t}'", collection); // fall-through, assuming the Identity mapping -- this appears // to match Adobe's behavior } } } // encoding (i.e., CMap) obj1 = fontDict->lookup("Encoding"); if (obj1.isNull()) { error(errSyntaxError, -1, "Missing Encoding entry in Type 0 font"); return; } if (!(cMap = CMap::parse(nullptr, collection, &obj1))) { return; } if (cMap->getCMapName()) { encodingName->Set(cMap->getCMapName()->c_str()); } else { encodingName->Set("Custom"); } // CIDToGIDMap (for embedded TrueType fonts) obj1 = desFontDict->lookup("CIDToGIDMap"); if (obj1.isStream()) { cidToGIDLen = 0; int i = 64; cidToGID = (int *)gmallocn(i, sizeof(int)); obj1.streamReset(); while ((c1 = obj1.streamGetChar()) != EOF && (c2 = obj1.streamGetChar()) != EOF) { if (cidToGIDLen == i) { i *= 2; cidToGID = (int *)greallocn(cidToGID, i, sizeof(int)); } cidToGID[cidToGIDLen++] = (c1 << 8) + c2; } } else if (!obj1.isName("Identity") && !obj1.isNull()) { error(errSyntaxError, -1, "Invalid CIDToGIDMap entry in CID font"); } //----- character metrics ----- // default char width obj1 = desFontDict->lookup("DW"); if (obj1.isInt()) { widths.defWidth = obj1.getInt() * 0.001; } // char width exceptions obj1 = desFontDict->lookup("W"); if (obj1.isArray()) { excepsSize = 0; int i = 0; while (i + 1 < obj1.arrayGetLength()) { obj2 = obj1.arrayGet(i); obj3 = obj1.arrayGet(i + 1); if (obj2.isInt() && obj3.isInt() && i + 2 < obj1.arrayGetLength()) { obj4 = obj1.arrayGet(i + 2); if (obj4.isNum()) { if (widths.nExceps == excepsSize) { excepsSize += 16; widths.exceps = (GfxFontCIDWidthExcep *)greallocn(widths.exceps, excepsSize, sizeof(GfxFontCIDWidthExcep)); } widths.exceps[widths.nExceps].first = obj2.getInt(); widths.exceps[widths.nExceps].last = obj3.getInt(); widths.exceps[widths.nExceps].width = obj4.getNum() * 0.001; ++widths.nExceps; } else { error(errSyntaxError, -1, "Bad widths array in Type 0 font"); } i += 3; } else if (obj2.isInt() && obj3.isArray()) { if (widths.nExceps + obj3.arrayGetLength() > excepsSize) { excepsSize = (widths.nExceps + obj3.arrayGetLength() + 15) & ~15; widths.exceps = (GfxFontCIDWidthExcep *)greallocn(widths.exceps, excepsSize, sizeof(GfxFontCIDWidthExcep)); } j = obj2.getInt(); for (k = 0; k < obj3.arrayGetLength(); ++k) { obj4 = obj3.arrayGet(k); if (obj4.isNum()) { widths.exceps[widths.nExceps].first = j; widths.exceps[widths.nExceps].last = j; widths.exceps[widths.nExceps].width = obj4.getNum() * 0.001; ++j; ++widths.nExceps; } else { error(errSyntaxError, -1, "Bad widths array in Type 0 font"); } } i += 2; } else { error(errSyntaxError, -1, "Bad widths array in Type 0 font"); ++i; } } std::sort(widths.exceps, widths.exceps + widths.nExceps, cmpWidthExcepFunctor()); } // default metrics for vertical font obj1 = desFontDict->lookup("DW2"); if (obj1.isArray() && obj1.arrayGetLength() == 2) { obj2 = obj1.arrayGet(0); if (obj2.isNum()) { widths.defVY = obj2.getNum() * 0.001; } obj2 = obj1.arrayGet(1); if (obj2.isNum()) { widths.defHeight = obj2.getNum() * 0.001; } } // char metric exceptions for vertical font obj1 = desFontDict->lookup("W2"); if (obj1.isArray()) { excepsSize = 0; int i = 0; while (i + 1 < obj1.arrayGetLength()) { obj2 = obj1.arrayGet(i); obj3 = obj1.arrayGet(i + 1); if (obj2.isInt() && obj3.isInt() && i + 4 < obj1.arrayGetLength()) { if ((obj4 = obj1.arrayGet(i + 2), obj4.isNum()) && (obj5 = obj1.arrayGet(i + 3), obj5.isNum()) && (obj6 = obj1.arrayGet(i + 4), obj6.isNum())) { if (widths.nExcepsV == excepsSize) { excepsSize += 16; widths.excepsV = (GfxFontCIDWidthExcepV *)greallocn(widths.excepsV, excepsSize, sizeof(GfxFontCIDWidthExcepV)); } widths.excepsV[widths.nExcepsV].first = obj2.getInt(); widths.excepsV[widths.nExcepsV].last = obj3.getInt(); widths.excepsV[widths.nExcepsV].height = obj4.getNum() * 0.001; widths.excepsV[widths.nExcepsV].vx = obj5.getNum() * 0.001; widths.excepsV[widths.nExcepsV].vy = obj6.getNum() * 0.001; ++widths.nExcepsV; } else { error(errSyntaxError, -1, "Bad widths (W2) array in Type 0 font"); } i += 5; } else if (obj2.isInt() && obj3.isArray()) { if (widths.nExcepsV + obj3.arrayGetLength() / 3 > excepsSize) { excepsSize = (widths.nExcepsV + obj3.arrayGetLength() / 3 + 15) & ~15; widths.excepsV = (GfxFontCIDWidthExcepV *)greallocn(widths.excepsV, excepsSize, sizeof(GfxFontCIDWidthExcepV)); } j = obj2.getInt(); for (k = 0; k < obj3.arrayGetLength(); k += 3) { if ((obj4 = obj3.arrayGet(k), obj4.isNum()) && (obj5 = obj3.arrayGet(k + 1), obj5.isNum()) && (obj6 = obj3.arrayGet(k + 2), obj6.isNum())) { widths.excepsV[widths.nExcepsV].first = j; widths.excepsV[widths.nExcepsV].last = j; widths.excepsV[widths.nExcepsV].height = obj4.getNum() * 0.001; widths.excepsV[widths.nExcepsV].vx = obj5.getNum() * 0.001; widths.excepsV[widths.nExcepsV].vy = obj6.getNum() * 0.001; ++j; ++widths.nExcepsV; } else { error(errSyntaxError, -1, "Bad widths (W2) array in Type 0 font"); } } i += 2; } else { error(errSyntaxError, -1, "Bad widths (W2) array in Type 0 font"); ++i; } } std::sort(widths.excepsV, widths.excepsV + widths.nExcepsV, cmpWidthExcepVFunctor()); } ok = true; } GfxCIDFont::~GfxCIDFont() { if (collection) { delete collection; } if (cMap) { cMap->decRefCnt(); } if (ctu) { ctu->decRefCnt(); } gfree(widths.exceps); gfree(widths.excepsV); if (cidToGID) { gfree(cidToGID); } } int GfxCIDFont::getNextChar(const char *s, int len, CharCode *code, Unicode const **u, int *uLen, double *dx, double *dy, double *ox, double *oy) const { CID cid; CharCode dummy; double w, h, vx, vy; int n, a, b, m; if (!cMap) { *code = 0; *uLen = 0; *dx = *dy = 0; return 1; } *code = (CharCode)(cid = cMap->getCID(s, len, &dummy, &n)); if (ctu) { if (hasToUnicode) { int i = 0, c = 0; while (i < n) { c = (c << 8) + (s[i] & 0xff); ++i; } *uLen = ctu->mapToUnicode(c, u); } else { *uLen = ctu->mapToUnicode(cid, u); } } else { *uLen = 0; } // horizontal if (cMap->getWMode() == 0) { w = getWidth(cid); h = vx = vy = 0; // vertical } else { w = 0; h = widths.defHeight; vx = getWidth(cid) / 2; vy = widths.defVY; if (widths.nExcepsV > 0 && cid >= widths.excepsV[0].first) { a = 0; b = widths.nExcepsV; // invariant: widths.excepsV[a].first <= cid < widths.excepsV[b].first while (b - a > 1) { m = (a + b) / 2; if (widths.excepsV[m].last <= cid) { a = m; } else { b = m; } } if (cid <= widths.excepsV[a].last) { h = widths.excepsV[a].height; vx = widths.excepsV[a].vx; vy = widths.excepsV[a].vy; } } } *dx = w; *dy = h; *ox = vx; *oy = vy; return n; } int GfxCIDFont::getWMode() { return cMap ? cMap->getWMode() : 0; } const CharCodeToUnicode *GfxCIDFont::getToUnicode() const { return ctu; } const GooString *GfxCIDFont::getCollection() const { return cMap ? cMap->getCollection() : nullptr; } int GfxCIDFont::mapCodeToGID(FoFiTrueType *ff, int cmapi, Unicode unicode, bool wmode) { unsigned short gid = ff->mapCodeToGID(cmapi, unicode); if (wmode) { unsigned short vgid = ff->mapToVertGID(gid); if (vgid != 0) gid = vgid; } return gid; } int *GfxCIDFont::getCodeToGIDMap(FoFiTrueType *ff, int *codeToGIDLen) { #define N_UCS_CANDIDATES 2 /* space characters */ static const unsigned long spaces[] = { 0x2000, 0x2001, 0x2002, 0x2003, 0x2004, 0x2005, 0x2006, 0x2007, 0x2008, 0x2009, 0x200A, 0x00A0, 0x200B, 0x2060, 0x3000, 0xFEFF, 0 }; static const char *adobe_cns1_cmaps[] = { "UniCNS-UTF32-V", "UniCNS-UCS2-V", "UniCNS-UTF32-H", "UniCNS-UCS2-H", nullptr }; static const char *adobe_gb1_cmaps[] = { "UniGB-UTF32-V", "UniGB-UCS2-V", "UniGB-UTF32-H", "UniGB-UCS2-H", nullptr }; static const char *adobe_japan1_cmaps[] = { "UniJIS-UTF32-V", "UniJIS-UCS2-V", "UniJIS-UTF32-H", "UniJIS-UCS2-H", nullptr }; static const char *adobe_japan2_cmaps[] = { "UniHojo-UTF32-V", "UniHojo-UCS2-V", "UniHojo-UTF32-H", "UniHojo-UCS2-H", nullptr }; static const char *adobe_korea1_cmaps[] = { "UniKS-UTF32-V", "UniKS-UCS2-V", "UniKS-UTF32-H", "UniKS-UCS2-H", nullptr }; static struct CMapListEntry { const char *collection; const char *scriptTag; const char *languageTag; const char *toUnicodeMap; const char **CMaps; } CMapList[] = { { "Adobe-CNS1", "hani", "CHN ", "Adobe-CNS1-UCS2", adobe_cns1_cmaps, }, { "Adobe-GB1", "hani", "CHN ", "Adobe-GB1-UCS2", adobe_gb1_cmaps, }, { "Adobe-Japan1", "kana", "JAN ", "Adobe-Japan1-UCS2", adobe_japan1_cmaps, }, { "Adobe-Japan2", "kana", "JAN ", "Adobe-Japan2-UCS2", adobe_japan2_cmaps, }, { "Adobe-Korea1", "hang", "KOR ", "Adobe-Korea1-UCS2", adobe_korea1_cmaps, }, { nullptr, nullptr, nullptr, nullptr, nullptr } }; Unicode *humap = nullptr; Unicode *vumap = nullptr; Unicode *tumap = nullptr; int *codeToGID = nullptr; int i; unsigned long code; int wmode; const char **cmapName; CMapListEntry *lp; int cmap; int cmapPlatform, cmapEncoding; Ref embID; *codeToGIDLen = 0; if (!ctu || !getCollection()) return nullptr; if (getCollection()->cmp("Adobe-Identity") == 0) return nullptr; if (getEmbeddedFontID(&embID)) { /* if this font is embedded font, * CIDToGIDMap should be embedded in PDF file * and already set. So return it. */ *codeToGIDLen = getCIDToGIDLen(); return getCIDToGID(); } /* we use only unicode cmap */ cmap = -1; for (i = 0; i < ff->getNumCmaps(); ++i) { cmapPlatform = ff->getCmapPlatform(i); cmapEncoding = ff->getCmapEncoding(i); if (cmapPlatform == 3 && cmapEncoding == 10) { /* UCS-4 */ cmap = i; /* use UCS-4 cmap */ break; } else if (cmapPlatform == 3 && cmapEncoding == 1) { /* Unicode */ cmap = i; } else if (cmapPlatform == 0 && cmap < 0) { cmap = i; } } if (cmap < 0) return nullptr; wmode = getWMode(); for (lp = CMapList; lp->collection != nullptr; lp++) { if (strcmp(lp->collection, getCollection()->c_str()) == 0) { break; } } const unsigned int n = 65536; tumap = new Unicode[n]; humap = new Unicode[n * N_UCS_CANDIDATES]; memset(humap, 0, sizeof(Unicode) * n * N_UCS_CANDIDATES); if (lp->collection != nullptr) { CharCodeToUnicode *tctu; GooString tname(lp->toUnicodeMap); if ((tctu = CharCodeToUnicode::parseCMapFromFile(&tname, 16)) != nullptr) { CharCode cid; for (cid = 0; cid < n; cid++) { int len; const Unicode *ucodes; len = tctu->mapToUnicode(cid, &ucodes); if (len == 1) { tumap[cid] = ucodes[0]; } else { /* if not single character, ignore it */ tumap[cid] = 0; } } delete tctu; } vumap = new Unicode[n]; memset(vumap, 0, sizeof(Unicode) * n); for (cmapName = lp->CMaps; *cmapName != nullptr; cmapName++) { GooString cname(*cmapName); CMap *cnameCMap; if ((cnameCMap = globalParams->getCMap(getCollection(), &cname)) != nullptr) { if (cnameCMap->getWMode()) { cnameCMap->setReverseMap(vumap, n, 1); } else { cnameCMap->setReverseMap(humap, n, N_UCS_CANDIDATES); } cnameCMap->decRefCnt(); } } ff->setupGSUB(lp->scriptTag, lp->languageTag); } else { error(errSyntaxError, -1, "Unknown character collection {0:t}\n", getCollection()); if (ctu) { CharCode cid; for (cid = 0; cid < n; cid++) { const Unicode *ucode; if (ctu->mapToUnicode(cid, &ucode)) humap[cid * N_UCS_CANDIDATES] = ucode[0]; else humap[cid * N_UCS_CANDIDATES] = 0; for (i = 1; i < N_UCS_CANDIDATES; i++) { humap[cid * N_UCS_CANDIDATES + i] = 0; } } } } // map CID -> Unicode -> GID codeToGID = (int *)gmallocn(n, sizeof(int)); for (code = 0; code < n; ++code) { Unicode unicode; unsigned long gid; unicode = 0; gid = 0; if (humap != nullptr) { for (i = 0; i < N_UCS_CANDIDATES && gid == 0 && (unicode = humap[code * N_UCS_CANDIDATES + i]) != 0; i++) { gid = mapCodeToGID(ff, cmap, unicode, false); } } if (gid == 0 && vumap != nullptr) { unicode = vumap[code]; if (unicode != 0) { gid = mapCodeToGID(ff, cmap, unicode, true); if (gid == 0 && tumap != nullptr) { if ((unicode = tumap[code]) != 0) { gid = mapCodeToGID(ff, cmap, unicode, true); } } } } if (gid == 0 && tumap != nullptr) { if ((unicode = tumap[code]) != 0) { gid = mapCodeToGID(ff, cmap, unicode, false); } } if (gid == 0) { /* special handling space characters */ const unsigned long *p; if (humap != nullptr) unicode = humap[code]; if (unicode != 0) { /* check if code is space character , so map code to 0x0020 */ for (p = spaces; *p != 0; p++) { if (*p == unicode) { unicode = 0x20; gid = mapCodeToGID(ff, cmap, unicode, wmode); break; } } } } codeToGID[code] = gid; } *codeToGIDLen = n; if (humap != nullptr) delete[] humap; if (tumap != nullptr) delete[] tumap; if (vumap != nullptr) delete[] vumap; return codeToGID; } double GfxCIDFont::getWidth(CID cid) const { double w; int a, b, m; w = widths.defWidth; if (widths.nExceps > 0 && cid >= widths.exceps[0].first) { a = 0; b = widths.nExceps; // invariant: widths.exceps[a].first <= cid < widths.exceps[b].first while (b - a > 1) { m = (a + b) / 2; if (widths.exceps[m].first <= cid) { a = m; } else { b = m; } } if (cid <= widths.exceps[a].last) { w = widths.exceps[a].width; } } return w; } double GfxCIDFont::getWidth(char *s, int len) const { int nUsed; CharCode c; CID cid = cMap->getCID(s, len, &c, &nUsed); return getWidth(cid); } //------------------------------------------------------------------------ // GfxFontDict //------------------------------------------------------------------------ GfxFontDict::GfxFontDict(XRef *xref, Ref *fontDictRef, Dict *fontDict) { int i; Ref r; numFonts = fontDict->getLength(); fonts = (GfxFont **)gmallocn(numFonts, sizeof(GfxFont *)); for (i = 0; i < numFonts; ++i) { const Object &obj1 = fontDict->getValNF(i); Object obj2 = obj1.fetch(xref); if (obj2.isDict()) { if (obj1.isRef()) { r = obj1.getRef(); } else if (fontDictRef) { // legal generation numbers are five digits, so we use a // 6-digit number here r.gen = 100000 + fontDictRef->num; r.num = i; } else { // no indirect reference for this font, or for the containing // font dict, so hash the font and use that r.gen = 100000; r.num = hashFontObject(&obj2); } fonts[i] = GfxFont::makeFont(xref, fontDict->getKey(i), r, obj2.getDict()); if (fonts[i] && !fonts[i]->isOk()) { // XXX: it may be meaningful to distinguish between // NULL and !isOk() so that when we do lookups // we can tell the difference between a missing font // and a font that is just !isOk() fonts[i]->decRefCnt(); fonts[i] = nullptr; } } else { error(errSyntaxError, -1, "font resource is not a dictionary"); fonts[i] = nullptr; } } } GfxFontDict::~GfxFontDict() { int i; for (i = 0; i < numFonts; ++i) { if (fonts[i]) { fonts[i]->decRefCnt(); } } gfree(fonts); } GfxFont *GfxFontDict::lookup(const char *tag) { int i; for (i = 0; i < numFonts; ++i) { if (fonts[i] && fonts[i]->matches(tag)) { return fonts[i]; } } return nullptr; } // FNV-1a hash class FNVHash { public: FNVHash() { h = 2166136261U; } void hash(char c) { h ^= c & 0xff; h *= 16777619; } void hash(const char *p, int n) { int i; for (i = 0; i < n; ++i) { hash(p[i]); } } int get31() { return (h ^ (h >> 31)) & 0x7fffffff; } private: unsigned int h; }; int GfxFontDict::hashFontObject(Object *obj) { FNVHash h; hashFontObject1(obj, &h); return h.get31(); } void GfxFontDict::hashFontObject1(const Object *obj, FNVHash *h) { const GooString *s; const char *p; double r; int n, i; switch (obj->getType()) { case objBool: h->hash('b'); h->hash(obj->getBool() ? 1 : 0); break; case objInt: h->hash('i'); n = obj->getInt(); h->hash((char *)&n, sizeof(int)); break; case objReal: h->hash('r'); r = obj->getReal(); h->hash((char *)&r, sizeof(double)); break; case objString: h->hash('s'); s = obj->getString(); h->hash(s->c_str(), s->getLength()); break; case objName: h->hash('n'); p = obj->getName(); h->hash(p, (int)strlen(p)); break; case objNull: h->hash('z'); break; case objArray: h->hash('a'); n = obj->arrayGetLength(); h->hash((char *)&n, sizeof(int)); for (i = 0; i < n; ++i) { const Object &obj2 = obj->arrayGetNF(i); hashFontObject1(&obj2, h); } break; case objDict: h->hash('d'); n = obj->dictGetLength(); h->hash((char *)&n, sizeof(int)); for (i = 0; i < n; ++i) { p = obj->dictGetKey(i); h->hash(p, (int)strlen(p)); const Object &obj2 = obj->dictGetValNF(i); hashFontObject1(&obj2, h); } break; case objStream: // this should never happen - streams must be indirect refs break; case objRef: h->hash('f'); n = obj->getRefNum(); h->hash((char *)&n, sizeof(int)); n = obj->getRefGen(); h->hash((char *)&n, sizeof(int)); break; default: h->hash('u'); break; } }