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Diffstat (limited to 'gfx/graphite2/src/TtfUtil.cpp')
-rw-r--r-- | gfx/graphite2/src/TtfUtil.cpp | 2048 |
1 files changed, 2048 insertions, 0 deletions
diff --git a/gfx/graphite2/src/TtfUtil.cpp b/gfx/graphite2/src/TtfUtil.cpp new file mode 100644 index 000000000..75e8da11c --- /dev/null +++ b/gfx/graphite2/src/TtfUtil.cpp @@ -0,0 +1,2048 @@ +/* GRAPHITE2 LICENSING + + Copyright 2010, SIL International + All rights reserved. + + This library is free software; you can redistribute it and/or modify + it under the terms of the GNU Lesser General Public License as published + by the Free Software Foundation; either version 2.1 of License, or + (at your option) any later version. + + This program is distributed in the hope that it will be useful, + but WITHOUT ANY WARRANTY; without even the implied warranty of + MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU + Lesser General Public License for more details. + + You should also have received a copy of the GNU Lesser General Public + License along with this library in the file named "LICENSE". + If not, write to the Free Software Foundation, 51 Franklin Street, + Suite 500, Boston, MA 02110-1335, USA or visit their web page on the + internet at http://www.fsf.org/licenses/lgpl.html. + +Alternatively, the contents of this file may be used under the terms of the +Mozilla Public License (http://mozilla.org/MPL) or the GNU General Public +License, as published by the Free Software Foundation, either version 2 +of the License or (at your option) any later version. +*/ +/*--------------------------------------------------------------------*//*:Ignore this sentence. + +File: TtfUtil.cpp +Responsibility: Alan Ward +Last reviewed: Not yet. + +Description + Implements the methods for TtfUtil class. This file should remain portable to any C++ + environment by only using standard C++ and the TTF structurs defined in Tt.h. +-------------------------------------------------------------------------------*//*:End Ignore*/ + + +/*********************************************************************************************** + Include files +***********************************************************************************************/ +// Language headers +//#include <algorithm> +#include <cassert> +#include <cstddef> +#include <cstring> +#include <climits> +#include <cwchar> +//#include <stdexcept> +// Platform headers +// Module headers +#include "inc/TtfUtil.h" +#include "inc/TtfTypes.h" +#include "inc/Endian.h" + +/*********************************************************************************************** + Forward declarations +***********************************************************************************************/ + +/*********************************************************************************************** + Local Constants and static variables +***********************************************************************************************/ +namespace +{ +#ifdef ALL_TTFUTILS + // max number of components allowed in composite glyphs + const int kMaxGlyphComponents = 8; +#endif + + template <int R, typename T> + inline float fixed_to_float(const T f) { + return float(f)/float(2^R); + } + +/*---------------------------------------------------------------------------------------------- + Table of standard Postscript glyph names. From Martin Hosken. Disagress with ttfdump.exe +---------------------------------------------------------------------------------------------*/ +#ifdef ALL_TTFUTILS + const int kcPostNames = 258; + + const char * rgPostName[kcPostNames] = { + ".notdef", ".null", "nonmarkingreturn", "space", "exclam", "quotedbl", "numbersign", + "dollar", "percent", "ampersand", "quotesingle", "parenleft", + "parenright", "asterisk", "plus", "comma", "hyphen", "period", "slash", + "zero", "one", "two", "three", "four", "five", "six", "seven", "eight", + "nine", "colon", "semicolon", "less", "equal", "greater", "question", + "at", "A", "B", "C", "D", "E", "F", "G", "H", "I", "J", "K", "L", "M", + "N", "O", "P", "Q", "R", "S", "T", "U", "V", "W", "X", "Y", "Z", + "bracketleft", "backslash", "bracketright", "asciicircum", + "underscore", "grave", "a", "b", "c", "d", "e", "f", "g", "h", "i", + "j", "k", "l", "m", "n", "o", "p", "q", "r", "s", "t", "u", "v", "w", + "x", "y", "z", "braceleft", "bar", "braceright", "asciitilde", + "Adieresis", "Aring", "Ccedilla", "Eacute", "Ntilde", "Odieresis", + "Udieresis", "aacute", "agrave", "acircumflex", "adieresis", "atilde", + "aring", "ccedilla", "eacute", "egrave", "ecircumflex", "edieresis", + "iacute", "igrave", "icircumflex", "idieresis", "ntilde", "oacute", + "ograve", "ocircumflex", "odieresis", "otilde", "uacute", "ugrave", + "ucircumflex", "udieresis", "dagger", "degree", "cent", "sterling", + "section", "bullet", "paragraph", "germandbls", "registered", + "copyright", "trademark", "acute", "dieresis", "notequal", "AE", + "Oslash", "infinity", "plusminus", "lessequal", "greaterequal", "yen", + "mu", "partialdiff", "summation", "product", "pi", "integral", + "ordfeminine", "ordmasculine", "Omega", "ae", "oslash", "questiondown", + "exclamdown", "logicalnot", "radical", "florin", "approxequal", + "Delta", "guillemotleft", "guillemotright", "ellipsis", "nonbreakingspace", + "Agrave", "Atilde", "Otilde", "OE", "oe", "endash", "emdash", + "quotedblleft", "quotedblright", "quoteleft", "quoteright", "divide", + "lozenge", "ydieresis", "Ydieresis", "fraction", "currency", + "guilsinglleft", "guilsinglright", "fi", "fl", "daggerdbl", "periodcentered", + "quotesinglbase", "quotedblbase", "perthousand", "Acircumflex", + "Ecircumflex", "Aacute", "Edieresis", "Egrave", "Iacute", + "Icircumflex", "Idieresis", "Igrave", "Oacute", "Ocircumflex", + "apple", "Ograve", "Uacute", "Ucircumflex", "Ugrave", "dotlessi", + "circumflex", "tilde", "macron", "breve", "dotaccent", "ring", + "cedilla", "hungarumlaut", "ogonek", "caron", "Lslash", "lslash", + "Scaron", "scaron", "Zcaron", "zcaron", "brokenbar", "Eth", "eth", + "Yacute", "yacute", "Thorn", "thorn", "minus", "multiply", + "onesuperior", "twosuperior", "threesuperior", "onehalf", "onequarter", + "threequarters", "franc", "Gbreve", "gbreve", "Idotaccent", "Scedilla", + "scedilla", "Cacute", "cacute", "Ccaron", "ccaron", + "dcroat" }; +#endif + +} // end of namespace + +/*********************************************************************************************** + Methods +***********************************************************************************************/ + +/* Note on error processing: The code guards against bad glyph ids being used to look up data +in open ended tables (loca, hmtx). If the glyph id comes from a cmap this shouldn't happen +but it seems prudent to check for user errors here. The code does assume that data obtained +from the TTF file is valid otherwise (though the CheckTable method seeks to check for +obvious problems that might accompany a change in table versions). For example an invalid +offset in the loca table which could exceed the size of the glyf table is NOT trapped. +Likewise if numberOf_LongHorMetrics in the hhea table is wrong, this will NOT be trapped, +which could cause a lookup in the hmtx table to exceed the table length. Of course, TTF tables +that are completely corrupt will cause unpredictable results. */ + +/* Note on composite glyphs: Glyphs that have components that are themselves composites +are not supported. IsDeepComposite can be used to test for this. False is returned from many +of the methods in this cases. It is unclear how to build composite glyphs in some cases, +so this code represents my best guess until test cases can be found. See notes on the high- +level GlyfPoints method. */ +namespace graphite2 +{ +namespace TtfUtil +{ + + +/*---------------------------------------------------------------------------------------------- + Get offset and size of the offset table needed to find table directory. + Return true if success, false otherwise. + lSize excludes any table directory entries. +----------------------------------------------------------------------------------------------*/ +bool GetHeaderInfo(size_t & lOffset, size_t & lSize) +{ + lOffset = 0; + lSize = offsetof(Sfnt::OffsetSubTable, table_directory); + assert(sizeof(uint32) + 4*sizeof (uint16) == lSize); + return true; +} + +/*---------------------------------------------------------------------------------------------- + Check the offset table for expected data. + Return true if success, false otherwise. +----------------------------------------------------------------------------------------------*/ +bool CheckHeader(const void * pHdr) +{ + const Sfnt::OffsetSubTable * pOffsetTable + = reinterpret_cast<const Sfnt::OffsetSubTable *>(pHdr); + + return pHdr && be::swap(pOffsetTable->scaler_type) == Sfnt::OffsetSubTable::TrueTypeWin; +} + +/*---------------------------------------------------------------------------------------------- + Get offset and size of the table directory. + Return true if successful, false otherwise. +----------------------------------------------------------------------------------------------*/ +bool GetTableDirInfo(const void * pHdr, size_t & lOffset, size_t & lSize) +{ + const Sfnt::OffsetSubTable * pOffsetTable + = reinterpret_cast<const Sfnt::OffsetSubTable *>(pHdr); + + lOffset = offsetof(Sfnt::OffsetSubTable, table_directory); + lSize = be::swap(pOffsetTable->num_tables) + * sizeof(Sfnt::OffsetSubTable::Entry); + + return true; +} + + +/*---------------------------------------------------------------------------------------------- + Get offset and size of the specified table. + Return true if successful, false otherwise. On false, offset and size will be 0. +----------------------------------------------------------------------------------------------*/ +bool GetTableInfo(const Tag TableTag, const void * pHdr, const void * pTableDir, + size_t & lOffset, size_t & lSize) +{ + const Sfnt::OffsetSubTable * pOffsetTable + = reinterpret_cast<const Sfnt::OffsetSubTable *>(pHdr); + const size_t num_tables = be::swap(pOffsetTable->num_tables); + const Sfnt::OffsetSubTable::Entry + * entry_itr = reinterpret_cast<const Sfnt::OffsetSubTable::Entry *>( + pTableDir), + * const dir_end = entry_itr + num_tables; + + if (num_tables > 40) + return false; + + for (;entry_itr != dir_end; ++entry_itr) // 40 - safe guard + { + if (be::swap(entry_itr->tag) == TableTag) + { + lOffset = be::swap(entry_itr->offset); + lSize = be::swap(entry_itr->length); + return true; + } + } + + return false; +} + +/*---------------------------------------------------------------------------------------------- + Check the specified table. Tests depend on the table type. + Return true if successful, false otherwise. +----------------------------------------------------------------------------------------------*/ +bool CheckTable(const Tag TableId, const void * pTable, size_t lTableSize) +{ + using namespace Sfnt; + + if (pTable == 0 || lTableSize < 4) return false; + + switch(TableId) + { + case Tag::cmap: // cmap + { + const Sfnt::CharacterCodeMap * const pCmap + = reinterpret_cast<const Sfnt::CharacterCodeMap *>(pTable); + if (lTableSize < sizeof(Sfnt::CharacterCodeMap)) + return false; + return be::swap(pCmap->version) == 0; + } + + case Tag::head: // head + { + const Sfnt::FontHeader * const pHead + = reinterpret_cast<const Sfnt::FontHeader *>(pTable); + if (lTableSize < sizeof(Sfnt::FontHeader)) + return false; + bool r = be::swap(pHead->version) == OneFix + && be::swap(pHead->magic_number) == FontHeader::MagicNumber + && be::swap(pHead->glyph_data_format) + == FontHeader::GlypDataFormat + && (be::swap(pHead->index_to_loc_format) + == FontHeader::ShortIndexLocFormat + || be::swap(pHead->index_to_loc_format) + == FontHeader::LongIndexLocFormat) + && sizeof(FontHeader) <= lTableSize; + return r; + } + + case Tag::post: // post + { + const Sfnt::PostScriptGlyphName * const pPost + = reinterpret_cast<const Sfnt::PostScriptGlyphName *>(pTable); + if (lTableSize < sizeof(Sfnt::PostScriptGlyphName)) + return false; + const fixed format = be::swap(pPost->format); + bool r = format == PostScriptGlyphName::Format1 + || format == PostScriptGlyphName::Format2 + || format == PostScriptGlyphName::Format3 + || format == PostScriptGlyphName::Format25; + return r; + } + + case Tag::hhea: // hhea + { + const Sfnt::HorizontalHeader * pHhea = + reinterpret_cast<const Sfnt::HorizontalHeader *>(pTable); + if (lTableSize < sizeof(Sfnt::HorizontalHeader)) + return false; + bool r = be::swap(pHhea->version) == OneFix + && be::swap(pHhea->metric_data_format) == 0 + && sizeof (Sfnt::HorizontalHeader) <= lTableSize; + return r; + } + + case Tag::maxp: // maxp + { + const Sfnt::MaximumProfile * pMaxp = + reinterpret_cast<const Sfnt::MaximumProfile *>(pTable); + if (lTableSize < sizeof(Sfnt::MaximumProfile)) + return false; + bool r = be::swap(pMaxp->version) == OneFix + && sizeof(Sfnt::MaximumProfile) <= lTableSize; + return r; + } + + case Tag::OS_2: // OS/2 + { + const Sfnt::Compatibility * pOs2 + = reinterpret_cast<const Sfnt::Compatibility *>(pTable); + if (be::swap(pOs2->version) == 0) + { // OS/2 table version 1 size +// if (sizeof(Sfnt::Compatibility) +// - sizeof(uint32)*2 - sizeof(int16)*2 +// - sizeof(uint16)*3 <= lTableSize) + if (sizeof(Sfnt::Compatibility0) <= lTableSize) + return true; + } + else if (be::swap(pOs2->version) == 1) + { // OS/2 table version 2 size +// if (sizeof(Sfnt::Compatibility) +// - sizeof(int16) *2 +// - sizeof(uint16)*3 <= lTableSize) + if (sizeof(Sfnt::Compatibility1) <= lTableSize) + return true; + } + else if (be::swap(pOs2->version) == 2) + { // OS/2 table version 3 size + if (sizeof(Sfnt::Compatibility2) <= lTableSize) + return true; + } + else if (be::swap(pOs2->version) == 3 || be::swap(pOs2->version) == 4) + { // OS/2 table version 4 size - version 4 changed the meaning of some fields which we don't use + if (sizeof(Sfnt::Compatibility3) <= lTableSize) + return true; + } + else + return false; + break; + } + + case Tag::name: + { + const Sfnt::FontNames * pName + = reinterpret_cast<const Sfnt::FontNames *>(pTable); + if (lTableSize < sizeof(Sfnt::FontNames)) + return false; + return be::swap(pName->format) == 0; + } + + default: + break; + } + + return true; +} + +/*---------------------------------------------------------------------------------------------- + Return the number of glyphs in the font. Should never be less than zero. + + Note: this method is not currently used by the Graphite engine. +----------------------------------------------------------------------------------------------*/ +size_t GlyphCount(const void * pMaxp) +{ + const Sfnt::MaximumProfile * pTable = + reinterpret_cast<const Sfnt::MaximumProfile *>(pMaxp); + return be::swap(pTable->num_glyphs); +} + +#ifdef ALL_TTFUTILS +/*---------------------------------------------------------------------------------------------- + Return the maximum number of components for any composite glyph in the font. + + Note: this method is not currently used by the Graphite engine. +----------------------------------------------------------------------------------------------*/ +size_t MaxCompositeComponentCount(const void * pMaxp) +{ + const Sfnt::MaximumProfile * pTable = + reinterpret_cast<const Sfnt::MaximumProfile *>(pMaxp); + return be::swap(pTable->max_component_elements); +} + +/*---------------------------------------------------------------------------------------------- + Composite glyphs can be composed of glyphs that are themselves composites. + This method returns the maximum number of levels like this for any glyph in the font. + A non-composite glyph has a level of 1. + + Note: this method is not currently used by the Graphite engine. +----------------------------------------------------------------------------------------------*/ +size_t MaxCompositeLevelCount(const void * pMaxp) +{ + const Sfnt::MaximumProfile * pTable = + reinterpret_cast<const Sfnt::MaximumProfile *>(pMaxp); + return be::swap(pTable->max_component_depth); +} + +/*---------------------------------------------------------------------------------------------- + Return the number of glyphs in the font according to a differt source. + Should never be less than zero. Return -1 on failure. + + Note: this method is not currently used by the Graphite engine. +----------------------------------------------------------------------------------------------*/ +size_t LocaGlyphCount(size_t lLocaSize, const void * pHead) //throw(std::domain_error) +{ + + const Sfnt::FontHeader * pTable + = reinterpret_cast<const Sfnt::FontHeader *>(pHead); + + if (be::swap(pTable->index_to_loc_format) + == Sfnt::FontHeader::ShortIndexLocFormat) + // loca entries are two bytes and have been divided by two + return (lLocaSize >> 1) - 1; + + if (be::swap(pTable->index_to_loc_format) + == Sfnt::FontHeader::LongIndexLocFormat) + // loca entries are four bytes + return (lLocaSize >> 2) - 1; + + return -1; + //throw std::domain_error("head table in inconsistent state. The font may be corrupted"); +} +#endif + +/*---------------------------------------------------------------------------------------------- + Return the design units the font is designed with +----------------------------------------------------------------------------------------------*/ +int DesignUnits(const void * pHead) +{ + const Sfnt::FontHeader * pTable = + reinterpret_cast<const Sfnt::FontHeader *>(pHead); + + return be::swap(pTable->units_per_em); +} + +#ifdef ALL_TTFUTILS +/*---------------------------------------------------------------------------------------------- + Return the checksum from the head table, which serves as a unique identifer for the font. +----------------------------------------------------------------------------------------------*/ +int HeadTableCheckSum(const void * pHead) +{ + const Sfnt::FontHeader * pTable = + reinterpret_cast<const Sfnt::FontHeader *>(pHead); + + return be::swap(pTable->check_sum_adjustment); +} + +/*---------------------------------------------------------------------------------------------- + Return the create time from the head table. This consists of a 64-bit integer, which + we return here as two 32-bit integers. + + Note: this method is not currently used by the Graphite engine. +----------------------------------------------------------------------------------------------*/ +void HeadTableCreateTime(const void * pHead, + unsigned int * pnDateBC, unsigned int * pnDateAD) +{ + const Sfnt::FontHeader * pTable = + reinterpret_cast<const Sfnt::FontHeader *>(pHead); + + *pnDateBC = be::swap(pTable->created[0]); + *pnDateAD = be::swap(pTable->created[1]); +} + +/*---------------------------------------------------------------------------------------------- + Return the modify time from the head table.This consists of a 64-bit integer, which + we return here as two 32-bit integers. + + Note: this method is not currently used by the Graphite engine. +----------------------------------------------------------------------------------------------*/ +void HeadTableModifyTime(const void * pHead, + unsigned int * pnDateBC, unsigned int *pnDateAD) +{ + const Sfnt::FontHeader * pTable = + reinterpret_cast<const Sfnt::FontHeader *>(pHead); + + *pnDateBC = be::swap(pTable->modified[0]); + *pnDateAD = be::swap(pTable->modified[1]); +} + +/*---------------------------------------------------------------------------------------------- + Return true if the font is italic. +----------------------------------------------------------------------------------------------*/ +bool IsItalic(const void * pHead) +{ + const Sfnt::FontHeader * pTable = + reinterpret_cast<const Sfnt::FontHeader *>(pHead); + + return ((be::swap(pTable->mac_style) & 0x00000002) != 0); +} + +/*---------------------------------------------------------------------------------------------- + Return the ascent for the font +----------------------------------------------------------------------------------------------*/ +int FontAscent(const void * pOs2) +{ + const Sfnt::Compatibility * pTable = reinterpret_cast<const Sfnt::Compatibility *>(pOs2); + + return be::swap(pTable->win_ascent); +} + +/*---------------------------------------------------------------------------------------------- + Return the descent for the font +----------------------------------------------------------------------------------------------*/ +int FontDescent(const void * pOs2) +{ + const Sfnt::Compatibility * pTable = reinterpret_cast<const Sfnt::Compatibility *>(pOs2); + + return be::swap(pTable->win_descent); +} + +/*---------------------------------------------------------------------------------------------- + Get the bold and italic style bits. + Return true if successful. false otherwise. + In addition to checking the OS/2 table, one could also check + the head table's macStyle field (overridden by the OS/2 table on Win) + the sub-family name in the name table (though this can contain oblique, dark, etc too) +----------------------------------------------------------------------------------------------*/ +bool FontOs2Style(const void *pOs2, bool & fBold, bool & fItalic) +{ + const Sfnt::Compatibility * pTable = reinterpret_cast<const Sfnt::Compatibility *>(pOs2); + + fBold = (be::swap(pTable->fs_selection) & Sfnt::Compatibility::Bold) != 0; + fItalic = (be::swap(pTable->fs_selection) & Sfnt::Compatibility::Italic) != 0; + + return true; +} +#endif + +/*---------------------------------------------------------------------------------------------- + Method for searching name table. +----------------------------------------------------------------------------------------------*/ +bool GetNameInfo(const void * pName, int nPlatformId, int nEncodingId, + int nLangId, int nNameId, size_t & lOffset, size_t & lSize) +{ + lOffset = 0; + lSize = 0; + + const Sfnt::FontNames * pTable = reinterpret_cast<const Sfnt::FontNames *>(pName); + uint16 cRecord = be::swap(pTable->count); + uint16 nRecordOffset = be::swap(pTable->string_offset); + const Sfnt::NameRecord * pRecord = reinterpret_cast<const Sfnt::NameRecord *>(pTable + 1); + + for (int i = 0; i < cRecord; ++i) + { + if (be::swap(pRecord->platform_id) == nPlatformId && + be::swap(pRecord->platform_specific_id) == nEncodingId && + be::swap(pRecord->language_id) == nLangId && + be::swap(pRecord->name_id) == nNameId) + { + lOffset = be::swap(pRecord->offset) + nRecordOffset; + lSize = be::swap(pRecord->length); + return true; + } + pRecord++; + } + + return false; +} + +#ifdef ALL_TTFUTILS +/*---------------------------------------------------------------------------------------------- + Return all the lang-IDs that have data for the given name-IDs. Assume that there is room + in the return array (langIdList) for 128 items. The purpose of this method is to return + a list of all possible lang-IDs. +----------------------------------------------------------------------------------------------*/ +int GetLangsForNames(const void * pName, int nPlatformId, int nEncodingId, + int * nameIdList, int cNameIds, short * langIdList) +{ + const Sfnt::FontNames * pTable = reinterpret_cast<const Sfnt::FontNames *>(pName); + int cLangIds = 0; + uint16 cRecord = be::swap(pTable->count); + if (cRecord > 127) return cLangIds; + //uint16 nRecordOffset = swapw(pTable->stringOffset); + const Sfnt::NameRecord * pRecord = reinterpret_cast<const Sfnt::NameRecord *>(pTable + 1); + + for (int i = 0; i < cRecord; ++i) + { + if (be::swap(pRecord->platform_id) == nPlatformId && + be::swap(pRecord->platform_specific_id) == nEncodingId) + { + bool fNameFound = false; + int nLangId = be::swap(pRecord->language_id); + int nNameId = be::swap(pRecord->name_id); + for (int j = 0; j < cNameIds; j++) + { + if (nNameId == nameIdList[j]) + { + fNameFound = true; + break; + } + } + if (fNameFound) + { + // Add it if it's not there. + int ilang; + for (ilang = 0; ilang < cLangIds; ilang++) + if (langIdList[ilang] == nLangId) + break; + if (ilang >= cLangIds) + { + langIdList[cLangIds] = short(nLangId); + cLangIds++; + } + if (cLangIds == 128) + return cLangIds; + } + } + pRecord++; + } + + return cLangIds; +} + +/*---------------------------------------------------------------------------------------------- + Get the offset and size of the font family name in English for the MS Platform with Unicode + writing system. The offset is within the pName data. The string is double byte with MSB + first. +----------------------------------------------------------------------------------------------*/ +bool Get31EngFamilyInfo(const void * pName, size_t & lOffset, size_t & lSize) +{ + return GetNameInfo(pName, Sfnt::NameRecord::Microsoft, 1, 1033, + Sfnt::NameRecord::Family, lOffset, lSize); +} + +/*---------------------------------------------------------------------------------------------- + Get the offset and size of the full font name in English for the MS Platform with Unicode + writing system. The offset is within the pName data. The string is double byte with MSB + first. + + Note: this method is not currently used by the Graphite engine. +----------------------------------------------------------------------------------------------*/ +bool Get31EngFullFontInfo(const void * pName, size_t & lOffset, size_t & lSize) +{ + return GetNameInfo(pName, Sfnt::NameRecord::Microsoft, 1, 1033, + Sfnt::NameRecord::Fullname, lOffset, lSize); +} + +/*---------------------------------------------------------------------------------------------- + Get the offset and size of the font family name in English for the MS Platform with Symbol + writing system. The offset is within the pName data. The string is double byte with MSB + first. +----------------------------------------------------------------------------------------------*/ +bool Get30EngFamilyInfo(const void * pName, size_t & lOffset, size_t & lSize) +{ + return GetNameInfo(pName, Sfnt::NameRecord::Microsoft, 0, 1033, + Sfnt::NameRecord::Family, lOffset, lSize); +} + +/*---------------------------------------------------------------------------------------------- + Get the offset and size of the full font name in English for the MS Platform with Symbol + writing system. The offset is within the pName data. The string is double byte with MSB + first. + + Note: this method is not currently used by the Graphite engine. +----------------------------------------------------------------------------------------------*/ +bool Get30EngFullFontInfo(const void * pName, size_t & lOffset, size_t & lSize) +{ + return GetNameInfo(pName, Sfnt::NameRecord::Microsoft, 0, 1033, + Sfnt::NameRecord::Fullname, lOffset, lSize); +} + +/*---------------------------------------------------------------------------------------------- + Return the Glyph ID for a given Postscript name. This method finds the first glyph which + matches the requested Postscript name. Ideally every glyph should have a unique Postscript + name (except for special names such as .notdef), but this is not always true. + On failure return value less than zero. + -1 - table search failed + -2 - format 3 table (no Postscript glyph info) + -3 - other failures + + Note: this method is not currently used by the Graphite engine. +----------------------------------------------------------------------------------------------*/ +int PostLookup(const void * pPost, size_t lPostSize, const void * pMaxp, + const char * pPostName) +{ + using namespace Sfnt; + + const Sfnt::PostScriptGlyphName * pTable + = reinterpret_cast<const Sfnt::PostScriptGlyphName *>(pPost); + fixed format = be::swap(pTable->format); + + if (format == PostScriptGlyphName::Format3) + { // format 3 - no Postscript glyph info in font + return -2; + } + + // search for given Postscript name among the standard names + int iPostName = -1; // index in standard names + for (int i = 0; i < kcPostNames; i++) + { + if (!strcmp(pPostName, rgPostName[i])) + { + iPostName = i; + break; + } + } + + if (format == PostScriptGlyphName::Format1) + { // format 1 - use standard Postscript names + return iPostName; + } + + if (format == PostScriptGlyphName::Format25) + { + if (iPostName == -1) + return -1; + + const PostScriptGlyphName25 * pTable25 + = static_cast<const PostScriptGlyphName25 *>(pTable); + int cnGlyphs = GlyphCount(pMaxp); + for (gid16 nGlyphId = 0; nGlyphId < cnGlyphs && nGlyphId < kcPostNames; + nGlyphId++) + { // glyph_name_index25 contains bytes so no byte swapping needed + // search for first glyph id that uses the standard name + if (nGlyphId + pTable25->offset[nGlyphId] == iPostName) + return nGlyphId; + } + } + + if (format == PostScriptGlyphName::Format2) + { // format 2 + const PostScriptGlyphName2 * pTable2 + = static_cast<const PostScriptGlyphName2 *>(pTable); + + int cnGlyphs = be::swap(pTable2->number_of_glyphs); + + if (iPostName != -1) + { // did match a standard name, look for first glyph id mapped to that name + for (gid16 nGlyphId = 0; nGlyphId < cnGlyphs; nGlyphId++) + { + if (be::swap(pTable2->glyph_name_index[nGlyphId]) == iPostName) + return nGlyphId; + } + } + + { // did not match a standard name, search font specific names + size_t nStrSizeGoal = strlen(pPostName); + const char * pFirstGlyphName = reinterpret_cast<const char *>( + &pTable2->glyph_name_index[0] + cnGlyphs); + const char * pGlyphName = pFirstGlyphName; + int iInNames = 0; // index in font specific names + bool fFound = false; + const char * const endOfTable + = reinterpret_cast<const char *>(pTable2) + lPostSize; + while (pGlyphName < endOfTable && !fFound) + { // search Pascal strings for first matching name + size_t nStringSize = size_t(*pGlyphName); + if (nStrSizeGoal != nStringSize || + strncmp(pGlyphName + 1, pPostName, nStringSize)) + { // did not match + ++iInNames; + pGlyphName += nStringSize + 1; + } + else + { // did match + fFound = true; + } + } + if (!fFound) + return -1; // no font specific name matches request + + iInNames += kcPostNames; + for (gid16 nGlyphId = 0; nGlyphId < cnGlyphs; nGlyphId++) + { // search for first glyph id that maps to the found string index + if (be::swap(pTable2->glyph_name_index[nGlyphId]) == iInNames) + return nGlyphId; + } + return -1; // no glyph mapped to this index (very strange) + } + } + + return -3; +} + +/*---------------------------------------------------------------------------------------------- + Convert a Unicode character string from big endian (MSB first, Motorola) format to little + endian (LSB first, Intel) format. + nSize is the number of Unicode characters in the string. It should not include any + terminating null. If nSize is 0, it is assumed the string is null terminated. nSize + defaults to 0. + Return true if successful, false otherwise. +----------------------------------------------------------------------------------------------*/ +void SwapWString(void * pWStr, size_t nSize /* = 0 */) //throw (std::invalid_argument) +{ + if (pWStr == 0) + { +// throw std::invalid_argument("null pointer given"); + return; + } + + uint16 * pStr = reinterpret_cast<uint16 *>(pWStr); + uint16 * const pStrEnd = pStr + (nSize == 0 ? wcslen((const wchar_t*)pStr) : nSize); + + for (; pStr != pStrEnd; ++pStr) + *pStr = be::swap(*pStr); +// std::transform(pStr, pStrEnd, pStr, read<uint16>); + +// for (int i = 0; i < nSize; i++) +// { // swap the wide characters in the string +// pStr[i] = utf16(be::swap(uint16(pStr[i]))); +// } +} +#endif + +/*---------------------------------------------------------------------------------------------- + Get the left-side bearing and and advance width based on the given tables and Glyph ID + Return true if successful, false otherwise. On false, one or both value could be INT_MIN +----------------------------------------------------------------------------------------------*/ +bool HorMetrics(gid16 nGlyphId, const void * pHmtx, size_t lHmtxSize, const void * pHhea, + int & nLsb, unsigned int & nAdvWid) +{ + const Sfnt::HorizontalMetric * phmtx = + reinterpret_cast<const Sfnt::HorizontalMetric *>(pHmtx); + + const Sfnt::HorizontalHeader * phhea = + reinterpret_cast<const Sfnt::HorizontalHeader *>(pHhea); + + size_t cLongHorMetrics = be::swap(phhea->num_long_hor_metrics); + if (nGlyphId < cLongHorMetrics) + { // glyph id is acceptable + if ((nGlyphId + 1) * sizeof(Sfnt::HorizontalMetric) > lHmtxSize) return false; + nAdvWid = be::swap(phmtx[nGlyphId].advance_width); + nLsb = be::swap(phmtx[nGlyphId].left_side_bearing); + } + else + { + // guard against bad glyph id + size_t lLsbOffset = sizeof(Sfnt::HorizontalMetric) * cLongHorMetrics + + sizeof(int16) * (nGlyphId - cLongHorMetrics); // offset in bytes + // We test like this as LsbOffset is an offset not a length. + if (lLsbOffset >= lHmtxSize - sizeof(int16) || cLongHorMetrics == 0) + { + nLsb = 0; + return false; + } + nAdvWid = be::swap(phmtx[cLongHorMetrics - 1].advance_width); + nLsb = be::peek<int16>(reinterpret_cast<const byte *>(phmtx) + lLsbOffset); + } + + return true; +} + +/*---------------------------------------------------------------------------------------------- + Return a pointer to the requested cmap subtable. By default find the Microsoft Unicode + subtable. Pass nEncoding as -1 to find first table that matches only nPlatformId. + Return NULL if the subtable cannot be found. +----------------------------------------------------------------------------------------------*/ +const void * FindCmapSubtable(const void * pCmap, int nPlatformId, /* =3 */ int nEncodingId, /* = 1 */ size_t length) +{ + const Sfnt::CharacterCodeMap * pTable = reinterpret_cast<const Sfnt::CharacterCodeMap *>(pCmap); + uint16 csuPlatforms = be::swap(pTable->num_subtables); + if (length && (sizeof(Sfnt::CharacterCodeMap) + 8 * (csuPlatforms - 1) > length)) + return NULL; + for (int i = 0; i < csuPlatforms; i++) + { + if (be::swap(pTable->encoding[i].platform_id) == nPlatformId && + (nEncodingId == -1 || be::swap(pTable->encoding[i].platform_specific_id) == nEncodingId)) + { + uint32 offset = be::swap(pTable->encoding[i].offset); + const uint8 * pRtn = reinterpret_cast<const uint8 *>(pCmap) + offset; + if (length) + { + if (offset > length - 2) return NULL; + uint16 format = be::read<uint16>(pRtn); + if (format == 4) + { + if (offset > length - 4) return NULL; + uint16 subTableLength = be::peek<uint16>(pRtn); + if (i + 1 == csuPlatforms) + { + if (subTableLength > length - offset) + return NULL; + } + else if (subTableLength > be::swap(pTable->encoding[i+1].offset)) + return NULL; + } + if (format == 12) + { + if (offset > length - 6) return NULL; + uint32 subTableLength = be::peek<uint32>(pRtn); + if (i + 1 == csuPlatforms) + { + if (subTableLength > length - offset) + return NULL; + } + else if (subTableLength > be::swap(pTable->encoding[i+1].offset)) + return NULL; + } + } + return reinterpret_cast<const uint8 *>(pCmap) + offset; + } + } + + return 0; +} + +/*---------------------------------------------------------------------------------------------- + Check the Microsoft Unicode subtable for expected values +----------------------------------------------------------------------------------------------*/ +bool CheckCmapSubtable4(const void * pCmapSubtable4, const void * pCmapEnd /*, unsigned int maxgid*/) +{ + size_t table_len = (const byte *)pCmapEnd - (const byte *)pCmapSubtable4; + if (!pCmapSubtable4) return false; + const Sfnt::CmapSubTable * pTable = reinterpret_cast<const Sfnt::CmapSubTable *>(pCmapSubtable4); + // Bob H say some freeware TT fonts have version 1 (eg, CALIGULA.TTF) + // so don't check subtable version. 21 Mar 2002 spec changes version to language. + if (table_len < sizeof(*pTable) || be::swap(pTable->format) != 4) return false; + const Sfnt::CmapSubTableFormat4 * pTable4 = reinterpret_cast<const Sfnt::CmapSubTableFormat4 *>(pCmapSubtable4); + if (table_len < sizeof(*pTable4)) + return false; + uint16 length = be::swap(pTable4->length); + if (length > table_len) + return false; + if (length < sizeof(Sfnt::CmapSubTableFormat4)) + return false; + uint16 nRanges = be::swap(pTable4->seg_count_x2) >> 1; + if (!nRanges || length < sizeof(Sfnt::CmapSubTableFormat4) + 4 * nRanges * sizeof(uint16)) + return false; + // check last range is properly terminated + uint16 chEnd = be::peek<uint16>(pTable4->end_code + nRanges - 1); + if (chEnd != 0xFFFF) + return false; +#if 0 + int lastend = -1; + for (int i = 0; i < nRanges; ++i) + { + uint16 end = be::peek<uint16>(pTable4->end_code + i); + uint16 start = be::peek<uint16>(pTable4->end_code + nRanges + 1 + i); + int16 delta = be::peek<int16>(pTable4->end_code + 2*nRanges + 1 + i); + uint16 offset = be::peek<uint16>(pTable4->end_code + 3*nRanges + 1 + i); + if (lastend >= end || lastend >= start) + return false; + if (offset) + { + const uint16 *gstart = pTable4->end_code + 3*nRanges + 1 + i + (offset >> 1); + const uint16 *gend = gstart + end - start; + if ((char *)gend >= (char *)pCmapSubtable4 + length) + return false; + while (gstart <= gend) + { + uint16 g = be::peek<uint16>(gstart++); + if (g && ((g + delta) & 0xFFFF) > maxgid) + return false; + } + } + else if (((delta + end) & 0xFFFF) > maxgid) + return false; + lastend = end; + } +#endif + return true; +} + +/*---------------------------------------------------------------------------------------------- + Return the Glyph ID for the given Unicode ID in the Microsoft Unicode subtable. + (Actually this code only depends on subtable being format 4.) + Return 0 if the Unicode ID is not in the subtable. +----------------------------------------------------------------------------------------------*/ +gid16 CmapSubtable4Lookup(const void * pCmapSubtabel4, unsigned int nUnicodeId, int rangeKey) +{ + const Sfnt::CmapSubTableFormat4 * pTable = reinterpret_cast<const Sfnt::CmapSubTableFormat4 *>(pCmapSubtabel4); + + uint16 nSeg = be::swap(pTable->seg_count_x2) >> 1; + + uint16 n; + const uint16 * pLeft, * pMid; + uint16 cMid, chStart, chEnd; + + if (rangeKey) + { + pMid = &(pTable->end_code[rangeKey]); + chEnd = be::peek<uint16>(pMid); + } + else + { + // Binary search of the endCode[] array + pLeft = &(pTable->end_code[0]); + n = nSeg; + while (n > 0) + { + cMid = n >> 1; // Pick an element in the middle + pMid = pLeft + cMid; + chEnd = be::peek<uint16>(pMid); + if (nUnicodeId <= chEnd) + { + if (cMid == 0 || nUnicodeId > be::peek<uint16>(pMid -1)) + break; // Must be this seg or none! + n = cMid; // Continue on left side, omitting mid point + } + else + { + pLeft = pMid + 1; // Continue on right side, omitting mid point + n -= (cMid + 1); + } + } + + if (!n) + return 0; + } + + // Ok, we're down to one segment and pMid points to the endCode element + // Either this is it or none is. + + chStart = be::peek<uint16>(pMid += nSeg + 1); + if (chEnd >= nUnicodeId && nUnicodeId >= chStart) + { + // Found correct segment. Find Glyph Id + int16 idDelta = be::peek<uint16>(pMid += nSeg); + uint16 idRangeOffset = be::peek<uint16>(pMid += nSeg); + + if (idRangeOffset == 0) + return (uint16)(idDelta + nUnicodeId); // must use modulus 2^16 + + // Look up value in glyphIdArray + const ptrdiff_t offset = (nUnicodeId - chStart) + (idRangeOffset >> 1) + + (pMid - reinterpret_cast<const uint16 *>(pTable)); + if (offset * 2 + 1 >= be::swap<uint16>(pTable->length)) + return 0; + gid16 nGlyphId = be::peek<uint16>(reinterpret_cast<const uint16 *>(pTable)+offset); + // If this value is 0, return 0. Else add the idDelta + return nGlyphId ? nGlyphId + idDelta : 0; + } + + return 0; +} + +/*---------------------------------------------------------------------------------------------- + Return the next Unicode value in the cmap. Pass 0 to obtain the first item. + Returns 0xFFFF as the last item. + pRangeKey is an optional key that is used to optimize the search; its value is the range + in which the character is found. +----------------------------------------------------------------------------------------------*/ +unsigned int CmapSubtable4NextCodepoint(const void *pCmap31, unsigned int nUnicodeId, int * pRangeKey) +{ + const Sfnt::CmapSubTableFormat4 * pTable = reinterpret_cast<const Sfnt::CmapSubTableFormat4 *>(pCmap31); + + uint16 nRange = be::swap(pTable->seg_count_x2) >> 1; + + uint32 nUnicodePrev = (uint32)nUnicodeId; + + const uint16 * pStartCode = &(pTable->end_code[0]) + + nRange // length of end code array + + 1; // reserved word + + if (nUnicodePrev == 0) + { + // return the first codepoint. + if (pRangeKey) + *pRangeKey = 0; + return be::peek<uint16>(pStartCode); + } + else if (nUnicodePrev >= 0xFFFF) + { + if (pRangeKey) + *pRangeKey = nRange - 1; + return 0xFFFF; + } + + int iRange = (pRangeKey) ? *pRangeKey : 0; + // Just in case we have a bad key: + while (iRange > 0 && be::peek<uint16>(pStartCode + iRange) > nUnicodePrev) + iRange--; + while (iRange < nRange - 1 && be::peek<uint16>(pTable->end_code + iRange) < nUnicodePrev) + iRange++; + + // Now iRange is the range containing nUnicodePrev. + unsigned int nStartCode = be::peek<uint16>(pStartCode + iRange); + unsigned int nEndCode = be::peek<uint16>(pTable->end_code + iRange); + + if (nStartCode > nUnicodePrev) + // Oops, nUnicodePrev is not in the cmap! Adjust so we get a reasonable + // answer this time around. + nUnicodePrev = nStartCode - 1; + + if (nEndCode > nUnicodePrev) + { + // Next is in the same range; it is the next successive codepoint. + if (pRangeKey) + *pRangeKey = iRange; + return nUnicodePrev + 1; + } + + // Otherwise the next codepoint is the first one in the next range. + // There is guaranteed to be a next range because there must be one that + // ends with 0xFFFF. + if (pRangeKey) + *pRangeKey = iRange + 1; + return (iRange + 1 >= nRange) ? 0xFFFF : be::peek<uint16>(pStartCode + iRange + 1); +} + +/*---------------------------------------------------------------------------------------------- + Check the Microsoft UCS-4 subtable for expected values. +----------------------------------------------------------------------------------------------*/ +bool CheckCmapSubtable12(const void *pCmapSubtable12, const void *pCmapEnd /*, unsigned int maxgid*/) +{ + size_t table_len = (const byte *)pCmapEnd - (const byte *)pCmapSubtable12; + if (!pCmapSubtable12) return false; + const Sfnt::CmapSubTable * pTable = reinterpret_cast<const Sfnt::CmapSubTable *>(pCmapSubtable12); + if (table_len < sizeof(*pTable) || be::swap(pTable->format) != 12) + return false; + const Sfnt::CmapSubTableFormat12 * pTable12 = reinterpret_cast<const Sfnt::CmapSubTableFormat12 *>(pCmapSubtable12); + if (table_len < sizeof(*pTable12)) + return false; + uint32 length = be::swap(pTable12->length); + if (length > table_len) + return false; + if (length < sizeof(Sfnt::CmapSubTableFormat12)) + return false; + uint32 num_groups = be::swap(pTable12->num_groups); + if (num_groups > 0x10000000 || length != (sizeof(Sfnt::CmapSubTableFormat12) + (num_groups - 1) * sizeof(uint32) * 3)) + return false; +#if 0 + for (unsigned int i = 0; i < num_groups; ++i) + { + if (be::swap(pTable12->group[i].end_char_code) - be::swap(pTable12->group[i].start_char_code) + be::swap(pTable12->group[i].start_glyph_id) > maxgid) + return false; + if (i > 0 && be::swap(pTable12->group[i].start_char_code) <= be::swap(pTable12->group[i-1].end_char_code)) + return false; + } +#endif + return true; +} + +/*---------------------------------------------------------------------------------------------- + Return the Glyph ID for the given Unicode ID in the Microsoft UCS-4 subtable. + (Actually this code only depends on subtable being format 12.) + Return 0 if the Unicode ID is not in the subtable. +----------------------------------------------------------------------------------------------*/ +gid16 CmapSubtable12Lookup(const void * pCmap310, unsigned int uUnicodeId, int rangeKey) +{ + const Sfnt::CmapSubTableFormat12 * pTable = reinterpret_cast<const Sfnt::CmapSubTableFormat12 *>(pCmap310); + + //uint32 uLength = be::swap(pTable->length); //could use to test for premature end of table + uint32 ucGroups = be::swap(pTable->num_groups); + + for (unsigned int i = rangeKey; i < ucGroups; i++) + { + uint32 uStartCode = be::swap(pTable->group[i].start_char_code); + uint32 uEndCode = be::swap(pTable->group[i].end_char_code); + if (uUnicodeId >= uStartCode && uUnicodeId <= uEndCode) + { + uint32 uDiff = uUnicodeId - uStartCode; + uint32 uStartGid = be::swap(pTable->group[i].start_glyph_id); + return static_cast<gid16>(uStartGid + uDiff); + } + } + + return 0; +} + +/*---------------------------------------------------------------------------------------------- + Return the next Unicode value in the cmap. Pass 0 to obtain the first item. + Returns 0x10FFFF as the last item. + pRangeKey is an optional key that is used to optimize the search; its value is the range + in which the character is found. +----------------------------------------------------------------------------------------------*/ +unsigned int CmapSubtable12NextCodepoint(const void *pCmap310, unsigned int nUnicodeId, int * pRangeKey) +{ + const Sfnt::CmapSubTableFormat12 * pTable = reinterpret_cast<const Sfnt::CmapSubTableFormat12 *>(pCmap310); + + int nRange = be::swap(pTable->num_groups); + + uint32 nUnicodePrev = (uint32)nUnicodeId; + + if (nUnicodePrev == 0) + { + // return the first codepoint. + if (pRangeKey) + *pRangeKey = 0; + return be::swap(pTable->group[0].start_char_code); + } + else if (nUnicodePrev >= 0x10FFFF) + { + if (pRangeKey) + *pRangeKey = nRange; + return 0x10FFFF; + } + + int iRange = (pRangeKey) ? *pRangeKey : 0; + // Just in case we have a bad key: + while (iRange > 0 && be::swap(pTable->group[iRange].start_char_code) > nUnicodePrev) + iRange--; + while (iRange < nRange - 1 && be::swap(pTable->group[iRange].end_char_code) < nUnicodePrev) + iRange++; + + // Now iRange is the range containing nUnicodePrev. + + unsigned int nStartCode = be::swap(pTable->group[iRange].start_char_code); + unsigned int nEndCode = be::swap(pTable->group[iRange].end_char_code); + + if (nStartCode > nUnicodePrev) + // Oops, nUnicodePrev is not in the cmap! Adjust so we get a reasonable + // answer this time around. + nUnicodePrev = nStartCode - 1; + + if (nEndCode > nUnicodePrev) + { + // Next is in the same range; it is the next successive codepoint. + if (pRangeKey) + *pRangeKey = iRange; + return nUnicodePrev + 1; + } + + // Otherwise the next codepoint is the first one in the next range, or 10FFFF if we're done. + if (pRangeKey) + *pRangeKey = iRange + 1; + return (iRange + 1 >= nRange) ? 0x10FFFF : be::swap(pTable->group[iRange + 1].start_char_code); +} + +/*---------------------------------------------------------------------------------------------- + Return the offset stored in the loca table for the given Glyph ID. + (This offset is into the glyf table.) + Return -1 if the lookup failed. + Technically this method should return an unsigned long but it is unlikely the offset will + exceed 2^31. +----------------------------------------------------------------------------------------------*/ +size_t LocaLookup(gid16 nGlyphId, + const void * pLoca, size_t lLocaSize, + const void * pHead) // throw (std::out_of_range) +{ + const Sfnt::FontHeader * pTable = reinterpret_cast<const Sfnt::FontHeader *>(pHead); + size_t res = -2; + + // CheckTable verifies the index_to_loc_format is valid + if (be::swap(pTable->index_to_loc_format) == Sfnt::FontHeader::ShortIndexLocFormat) + { // loca entries are two bytes and have been divided by two + if (lLocaSize > 1 && nGlyphId + 1u < lLocaSize >> 1) // allow sentinel value to be accessed + { + const uint16 * pShortTable = reinterpret_cast<const uint16 *>(pLoca); + res = be::peek<uint16>(pShortTable + nGlyphId) << 1; + if (res == static_cast<size_t>(be::peek<uint16>(pShortTable + nGlyphId + 1) << 1)) + return -1; + } + } + else if (be::swap(pTable->index_to_loc_format) == Sfnt::FontHeader::LongIndexLocFormat) + { // loca entries are four bytes + if (lLocaSize > 3 && nGlyphId + 1u < lLocaSize >> 2) + { + const uint32 * pLongTable = reinterpret_cast<const uint32 *>(pLoca); + res = be::peek<uint32>(pLongTable + nGlyphId); + if (res == static_cast<size_t>(be::peek<uint32>(pLongTable + nGlyphId + 1))) + return -1; + } + } + + // only get here if glyph id was bad + return res; + //throw std::out_of_range("glyph id out of range for font"); +} + +/*---------------------------------------------------------------------------------------------- + Return a pointer into the glyf table based on the given offset (from LocaLookup). + Return NULL on error. +----------------------------------------------------------------------------------------------*/ +void * GlyfLookup(const void * pGlyf, size_t nGlyfOffset, size_t nTableLen) +{ + const uint8 * pByte = reinterpret_cast<const uint8 *>(pGlyf); + if (nGlyfOffset + pByte < pByte || nGlyfOffset + sizeof(Sfnt::Glyph) >= nTableLen) + return NULL; + return const_cast<uint8 *>(pByte + nGlyfOffset); +} + +/*---------------------------------------------------------------------------------------------- + Get the bounding box coordinates for a simple glyf entry (non-composite). + Return true if successful, false otherwise. +----------------------------------------------------------------------------------------------*/ +bool GlyfBox(const void * pSimpleGlyf, int & xMin, int & yMin, + int & xMax, int & yMax) +{ + const Sfnt::Glyph * pGlyph = reinterpret_cast<const Sfnt::Glyph *>(pSimpleGlyf); + + xMin = be::swap(pGlyph->x_min); + yMin = be::swap(pGlyph->y_min); + xMax = be::swap(pGlyph->x_max); + yMax = be::swap(pGlyph->y_max); + + return true; +} + +#ifdef ALL_TTFUTILS +/*---------------------------------------------------------------------------------------------- + Return the number of contours for a simple glyf entry (non-composite) + Returning -1 means this is a composite glyph +----------------------------------------------------------------------------------------------*/ +int GlyfContourCount(const void * pSimpleGlyf) +{ + const Sfnt::Glyph * pGlyph = reinterpret_cast<const Sfnt::Glyph *>(pSimpleGlyf); + return be::swap(pGlyph->number_of_contours); // -1 means composite glyph +} + +/*---------------------------------------------------------------------------------------------- + Get the point numbers for the end points of the glyph contours for a simple + glyf entry (non-composite). + cnPointsTotal - count of contours from GlyfContourCount(); (same as number of end points) + prgnContourEndPoints - should point to a buffer large enough to hold cnPoints integers + cnPoints - count of points placed in above range + Return true if successful, false otherwise. + False could indicate a multi-level composite glyphs. +----------------------------------------------------------------------------------------------*/ +bool GlyfContourEndPoints(const void * pSimpleGlyf, int * prgnContourEndPoint, + int cnPointsTotal, int & cnPoints) +{ + const Sfnt::SimpleGlyph * pGlyph = reinterpret_cast<const Sfnt::SimpleGlyph *>(pSimpleGlyf); + + int cContours = be::swap(pGlyph->number_of_contours); + if (cContours < 0) + return false; // this method isn't supposed handle composite glyphs + + for (int i = 0; i < cContours && i < cnPointsTotal; i++) + { + prgnContourEndPoint[i] = be::swap(pGlyph->end_pts_of_contours[i]); + } + + cnPoints = cContours; + return true; +} + +/*---------------------------------------------------------------------------------------------- + Get the points for a simple glyf entry (non-composite) + cnPointsTotal - count of points from largest end point obtained from GlyfContourEndPoints + prgnX & prgnY - should point to buffers large enough to hold cnPointsTotal integers + The ranges are parallel so that coordinates for point(n) are found at offset n in both + ranges. This is raw point data with relative coordinates. + prgbFlag - should point to a buffer a large enough to hold cnPointsTotal bytes + This range is parallel to the prgnX & prgnY + cnPoints - count of points placed in above ranges + Return true if successful, false otherwise. + False could indicate a composite glyph +----------------------------------------------------------------------------------------------*/ +bool GlyfPoints(const void * pSimpleGlyf, int * prgnX, int * prgnY, + char * prgbFlag, int cnPointsTotal, int & cnPoints) +{ + using namespace Sfnt; + + const Sfnt::SimpleGlyph * pGlyph = reinterpret_cast<const Sfnt::SimpleGlyph *>(pSimpleGlyf); + int cContours = be::swap(pGlyph->number_of_contours); + // return false for composite glyph + if (cContours <= 0) + return false; + int cPts = be::swap(pGlyph->end_pts_of_contours[cContours - 1]) + 1; + if (cPts > cnPointsTotal) + return false; + + // skip over bounding box data & point to byte count of instructions (hints) + const uint8 * pbGlyph = reinterpret_cast<const uint8 *> + (&pGlyph->end_pts_of_contours[cContours]); + + // skip over hints & point to first flag + int cbHints = be::swap(*(uint16 *)pbGlyph); + pbGlyph += sizeof(uint16); + pbGlyph += cbHints; + + // load flags & point to first x coordinate + int iFlag = 0; + while (iFlag < cPts) + { + if (!(*pbGlyph & SimpleGlyph::Repeat)) + { // flag isn't repeated + prgbFlag[iFlag] = (char)*pbGlyph; + pbGlyph++; + iFlag++; + } + else + { // flag is repeated; count specified by next byte + char chFlag = (char)*pbGlyph; + pbGlyph++; + int cFlags = (int)*pbGlyph; + pbGlyph++; + prgbFlag[iFlag] = chFlag; + iFlag++; + for (int i = 0; i < cFlags; i++) + { + prgbFlag[iFlag + i] = chFlag; + } + iFlag += cFlags; + } + } + if (iFlag != cPts) + return false; + + // load x coordinates + iFlag = 0; + while (iFlag < cPts) + { + if (prgbFlag[iFlag] & SimpleGlyph::XShort) + { + prgnX[iFlag] = *pbGlyph; + if (!(prgbFlag[iFlag] & SimpleGlyph::XIsPos)) + { + prgnX[iFlag] = -prgnX[iFlag]; + } + pbGlyph++; + } + else + { + if (prgbFlag[iFlag] & SimpleGlyph::XIsSame) + { + prgnX[iFlag] = 0; + // do NOT increment pbGlyph + } + else + { + prgnX[iFlag] = be::swap(*(int16 *)pbGlyph); + pbGlyph += sizeof(int16); + } + } + iFlag++; + } + + // load y coordinates + iFlag = 0; + while (iFlag < cPts) + { + if (prgbFlag[iFlag] & SimpleGlyph::YShort) + { + prgnY[iFlag] = *pbGlyph; + if (!(prgbFlag[iFlag] & SimpleGlyph::YIsPos)) + { + prgnY[iFlag] = -prgnY[iFlag]; + } + pbGlyph++; + } + else + { + if (prgbFlag[iFlag] & SimpleGlyph::YIsSame) + { + prgnY[iFlag] = 0; + // do NOT increment pbGlyph + } + else + { + prgnY[iFlag] = be::swap(*(int16 *)pbGlyph); + pbGlyph += sizeof(int16); + } + } + iFlag++; + } + + cnPoints = cPts; + return true; +} + +/*---------------------------------------------------------------------------------------------- + Fill prgnCompId with the component Glyph IDs from pSimpleGlyf. + Client must allocate space before calling. + pSimpleGlyf - assumed to point to a composite glyph + cCompIdTotal - the number of elements in prgnCompId + cCompId - the total number of Glyph IDs stored in prgnCompId + Return true if successful, false otherwise + False could indicate a non-composite glyph or the input array was not big enough +----------------------------------------------------------------------------------------------*/ +bool GetComponentGlyphIds(const void * pSimpleGlyf, int * prgnCompId, + size_t cnCompIdTotal, size_t & cnCompId) +{ + using namespace Sfnt; + + if (GlyfContourCount(pSimpleGlyf) >= 0) + return false; + + const Sfnt::SimpleGlyph * pGlyph = reinterpret_cast<const Sfnt::SimpleGlyph *>(pSimpleGlyf); + // for a composite glyph, the special data begins here + const uint8 * pbGlyph = reinterpret_cast<const uint8 *>(&pGlyph->end_pts_of_contours[0]); + + uint16 GlyphFlags; + size_t iCurrentComp = 0; + do + { + GlyphFlags = be::swap(*((uint16 *)pbGlyph)); + pbGlyph += sizeof(uint16); + prgnCompId[iCurrentComp++] = be::swap(*((uint16 *)pbGlyph)); + pbGlyph += sizeof(uint16); + if (iCurrentComp >= cnCompIdTotal) + return false; + int nOffset = 0; + nOffset += GlyphFlags & CompoundGlyph::Arg1Arg2Words ? 4 : 2; + nOffset += GlyphFlags & CompoundGlyph::HaveScale ? 2 : 0; + nOffset += GlyphFlags & CompoundGlyph::HaveXAndYScale ? 4 : 0; + nOffset += GlyphFlags & CompoundGlyph::HaveTwoByTwo ? 8 : 0; + pbGlyph += nOffset; + } while (GlyphFlags & CompoundGlyph::MoreComponents); + + cnCompId = iCurrentComp; + + return true; +} + +/*---------------------------------------------------------------------------------------------- + Return info on how a component glyph is to be placed + pSimpleGlyph - assumed to point to a composite glyph + nCompId - glyph id for component of interest + bOffset - if true, a & b are the x & y offsets for this component + if false, b is the point on this component that is attaching to point a on the + preceding glyph + Return true if successful, false otherwise + False could indicate a non-composite glyph or that component wasn't found +----------------------------------------------------------------------------------------------*/ +bool GetComponentPlacement(const void * pSimpleGlyf, int nCompId, + bool fOffset, int & a, int & b) +{ + using namespace Sfnt; + + if (GlyfContourCount(pSimpleGlyf) >= 0) + return false; + + const Sfnt::SimpleGlyph * pGlyph = reinterpret_cast<const Sfnt::SimpleGlyph *>(pSimpleGlyf); + // for a composite glyph, the special data begins here + const uint8 * pbGlyph = reinterpret_cast<const uint8 *>(&pGlyph->end_pts_of_contours[0]); + + uint16 GlyphFlags; + do + { + GlyphFlags = be::swap(*((uint16 *)pbGlyph)); + pbGlyph += sizeof(uint16); + if (be::swap(*((uint16 *)pbGlyph)) == nCompId) + { + pbGlyph += sizeof(uint16); // skip over glyph id of component + fOffset = (GlyphFlags & CompoundGlyph::ArgsAreXYValues) == CompoundGlyph::ArgsAreXYValues; + + if (GlyphFlags & CompoundGlyph::Arg1Arg2Words ) + { + a = be::swap(*(int16 *)pbGlyph); + pbGlyph += sizeof(int16); + b = be::swap(*(int16 *)pbGlyph); + pbGlyph += sizeof(int16); + } + else + { // args are signed bytes + a = *pbGlyph++; + b = *pbGlyph++; + } + return true; + } + pbGlyph += sizeof(uint16); // skip over glyph id of component + int nOffset = 0; + nOffset += GlyphFlags & CompoundGlyph::Arg1Arg2Words ? 4 : 2; + nOffset += GlyphFlags & CompoundGlyph::HaveScale ? 2 : 0; + nOffset += GlyphFlags & CompoundGlyph::HaveXAndYScale ? 4 : 0; + nOffset += GlyphFlags & CompoundGlyph::HaveTwoByTwo ? 8 : 0; + pbGlyph += nOffset; + } while (GlyphFlags & CompoundGlyph::MoreComponents); + + // didn't find requested component + fOffset = true; + a = 0; + b = 0; + return false; +} + +/*---------------------------------------------------------------------------------------------- + Return info on how a component glyph is to be transformed + pSimpleGlyph - assumed to point to a composite glyph + nCompId - glyph id for component of interest + flt11, flt11, flt11, flt11 - a 2x2 matrix giving the transform + bTransOffset - whether to transform the offset from above method + The spec is unclear about the meaning of this flag + Currently - initialize to true for MS rasterizer and false for Mac rasterizer, then + on return it will indicate whether transform should apply to offset (MSDN CD 10/99) + Return true if successful, false otherwise + False could indicate a non-composite glyph or that component wasn't found +----------------------------------------------------------------------------------------------*/ +bool GetComponentTransform(const void * pSimpleGlyf, int nCompId, + float & flt11, float & flt12, float & flt21, float & flt22, + bool & fTransOffset) +{ + using namespace Sfnt; + + if (GlyfContourCount(pSimpleGlyf) >= 0) + return false; + + const Sfnt::SimpleGlyph * pGlyph = reinterpret_cast<const Sfnt::SimpleGlyph *>(pSimpleGlyf); + // for a composite glyph, the special data begins here + const uint8 * pbGlyph = reinterpret_cast<const uint8 *>(&pGlyph->end_pts_of_contours[0]); + + uint16 GlyphFlags; + do + { + GlyphFlags = be::swap(*((uint16 *)pbGlyph)); + pbGlyph += sizeof(uint16); + if (be::swap(*((uint16 *)pbGlyph)) == nCompId) + { + pbGlyph += sizeof(uint16); // skip over glyph id of component + pbGlyph += GlyphFlags & CompoundGlyph::Arg1Arg2Words ? 4 : 2; // skip over placement data + + if (fTransOffset) // MS rasterizer + fTransOffset = !(GlyphFlags & CompoundGlyph::UnscaledOffset); + else // Apple rasterizer + fTransOffset = (GlyphFlags & CompoundGlyph::ScaledOffset) != 0; + + if (GlyphFlags & CompoundGlyph::HaveScale) + { + flt11 = fixed_to_float<14>(be::swap(*(uint16 *)pbGlyph)); + pbGlyph += sizeof(uint16); + flt12 = 0; + flt21 = 0; + flt22 = flt11; + } + else if (GlyphFlags & CompoundGlyph::HaveXAndYScale) + { + flt11 = fixed_to_float<14>(be::swap(*(uint16 *)pbGlyph)); + pbGlyph += sizeof(uint16); + flt12 = 0; + flt21 = 0; + flt22 = fixed_to_float<14>(be::swap(*(uint16 *)pbGlyph)); + pbGlyph += sizeof(uint16); + } + else if (GlyphFlags & CompoundGlyph::HaveTwoByTwo) + { + flt11 = fixed_to_float<14>(be::swap(*(uint16 *)pbGlyph)); + pbGlyph += sizeof(uint16); + flt12 = fixed_to_float<14>(be::swap(*(uint16 *)pbGlyph)); + pbGlyph += sizeof(uint16); + flt21 = fixed_to_float<14>(be::swap(*(uint16 *)pbGlyph)); + pbGlyph += sizeof(uint16); + flt22 = fixed_to_float<14>(be::swap(*(uint16 *)pbGlyph)); + pbGlyph += sizeof(uint16); + } + else + { // identity transform + flt11 = 1.0; + flt12 = 0.0; + flt21 = 0.0; + flt22 = 1.0; + } + return true; + } + pbGlyph += sizeof(uint16); // skip over glyph id of component + int nOffset = 0; + nOffset += GlyphFlags & CompoundGlyph::Arg1Arg2Words ? 4 : 2; + nOffset += GlyphFlags & CompoundGlyph::HaveScale ? 2 : 0; + nOffset += GlyphFlags & CompoundGlyph::HaveXAndYScale ? 4 : 0; + nOffset += GlyphFlags & CompoundGlyph::HaveTwoByTwo ? 8 : 0; + pbGlyph += nOffset; + } while (GlyphFlags & CompoundGlyph::MoreComponents); + + // didn't find requested component + fTransOffset = false; + flt11 = 1; + flt12 = 0; + flt21 = 0; + flt22 = 1; + return false; +} +#endif + +/*---------------------------------------------------------------------------------------------- + Return a pointer into the glyf table based on the given tables and Glyph ID + Since this method doesn't check for spaces, it is good to call IsSpace before using it. + Return NULL on error. +----------------------------------------------------------------------------------------------*/ +void * GlyfLookup(gid16 nGlyphId, const void * pGlyf, const void * pLoca, + size_t lGlyfSize, size_t lLocaSize, const void * pHead) +{ + // test for valid glyph id + // CheckTable verifies the index_to_loc_format is valid + + const Sfnt::FontHeader * pTable + = reinterpret_cast<const Sfnt::FontHeader *>(pHead); + + if (be::swap(pTable->index_to_loc_format) == Sfnt::FontHeader::ShortIndexLocFormat) + { // loca entries are two bytes (and have been divided by two) + if (nGlyphId >= (lLocaSize >> 1) - 1) // don't allow nGlyphId to access sentinel + { +// throw std::out_of_range("glyph id out of range for font"); + return NULL; + } + } + if (be::swap(pTable->index_to_loc_format) == Sfnt::FontHeader::LongIndexLocFormat) + { // loca entries are four bytes + if (nGlyphId >= (lLocaSize >> 2) - 1) + { +// throw std::out_of_range("glyph id out of range for font"); + return NULL; + } + } + + long lGlyfOffset = LocaLookup(nGlyphId, pLoca, lLocaSize, pHead); + void * pSimpleGlyf = GlyfLookup(pGlyf, lGlyfOffset, lGlyfSize); // invalid loca offset returns null + return pSimpleGlyf; +} + +#ifdef ALL_TTFUTILS +/*---------------------------------------------------------------------------------------------- + Determine if a particular Glyph ID has any data in the glyf table. If it is white space, + there will be no glyf data, though there will be metric data in hmtx, etc. +----------------------------------------------------------------------------------------------*/ +bool IsSpace(gid16 nGlyphId, const void * pLoca, size_t lLocaSize, const void * pHead) +{ + size_t lGlyfOffset = LocaLookup(nGlyphId, pLoca, lLocaSize, pHead); + + // the +1 should always work because there is a sentinel value at the end of the loca table + size_t lNextGlyfOffset = LocaLookup(nGlyphId + 1, pLoca, lLocaSize, pHead); + + return (lNextGlyfOffset - lGlyfOffset) == 0; +} + +/*---------------------------------------------------------------------------------------------- + Determine if a particular Glyph ID is a multi-level composite. +----------------------------------------------------------------------------------------------*/ +bool IsDeepComposite(gid16 nGlyphId, const void * pGlyf, const void * pLoca, + size_t lGlyfSize, long lLocaSize, const void * pHead) +{ + if (IsSpace(nGlyphId, pLoca, lLocaSize, pHead)) {return false;} + + void * pSimpleGlyf = GlyfLookup(nGlyphId, pGlyf, pLoca, lGlyfSize, lLocaSize, pHead); + if (pSimpleGlyf == NULL) + return false; // no way to really indicate an error occured here + + if (GlyfContourCount(pSimpleGlyf) >= 0) + return false; + + int rgnCompId[kMaxGlyphComponents]; // assumes only a limited number of glyph components + size_t cCompIdTotal = kMaxGlyphComponents; + size_t cCompId = 0; + + if (!GetComponentGlyphIds(pSimpleGlyf, rgnCompId, cCompIdTotal, cCompId)) + return false; + + for (size_t i = 0; i < cCompId; i++) + { + pSimpleGlyf = GlyfLookup(static_cast<gid16>(rgnCompId[i]), + pGlyf, pLoca, lGlyfSize, lLocaSize, pHead); + if (pSimpleGlyf == NULL) {return false;} + + if (GlyfContourCount(pSimpleGlyf) < 0) + return true; + } + + return false; +} + +/*---------------------------------------------------------------------------------------------- + Get the bounding box coordinates based on the given tables and Glyph ID + Handles both simple and composite glyphs. + Return true if successful, false otherwise. On false, all point values will be INT_MIN + False may indicate a white space glyph +----------------------------------------------------------------------------------------------*/ +bool GlyfBox(gid16 nGlyphId, const void * pGlyf, const void * pLoca, + size_t lGlyfSize, size_t lLocaSize, const void * pHead, int & xMin, int & yMin, int & xMax, int & yMax) +{ + xMin = yMin = xMax = yMax = INT_MIN; + + if (IsSpace(nGlyphId, pLoca, lLocaSize, pHead)) {return false;} + + void * pSimpleGlyf = GlyfLookup(nGlyphId, pGlyf, pLoca, lGlyfSize, lLocaSize, pHead); + if (pSimpleGlyf == NULL) {return false;} + + return GlyfBox(pSimpleGlyf, xMin, yMin, xMax, yMax); +} + +/*---------------------------------------------------------------------------------------------- + Get the number of contours based on the given tables and Glyph ID + Handles both simple and composite glyphs. + Return true if successful, false otherwise. On false, cnContours will be INT_MIN + False may indicate a white space glyph or a multi-level composite glyph. +----------------------------------------------------------------------------------------------*/ +bool GlyfContourCount(gid16 nGlyphId, const void * pGlyf, const void * pLoca, + size_t lGlyfSize, size_t lLocaSize, const void * pHead, size_t & cnContours) +{ + cnContours = static_cast<size_t>(INT_MIN); + + if (IsSpace(nGlyphId, pLoca, lLocaSize, pHead)) {return false;} + + void * pSimpleGlyf = GlyfLookup(nGlyphId, pGlyf, pLoca, lGlyfSize, lLocaSize, pHead); + if (pSimpleGlyf == NULL) {return false;} + + int cRtnContours = GlyfContourCount(pSimpleGlyf); + if (cRtnContours >= 0) + { + cnContours = size_t(cRtnContours); + return true; + } + + //handle composite glyphs + + int rgnCompId[kMaxGlyphComponents]; // assumes no glyph will be made of more than 8 components + size_t cCompIdTotal = kMaxGlyphComponents; + size_t cCompId = 0; + + if (!GetComponentGlyphIds(pSimpleGlyf, rgnCompId, cCompIdTotal, cCompId)) + return false; + + cRtnContours = 0; + int cTmp = 0; + for (size_t i = 0; i < cCompId; i++) + { + if (IsSpace(static_cast<gid16>(rgnCompId[i]), pLoca, lLocaSize, pHead)) {return false;} + pSimpleGlyf = GlyfLookup(static_cast<gid16>(rgnCompId[i]), + pGlyf, pLoca, lGlyfSize, lLocaSize, pHead); + if (pSimpleGlyf == 0) {return false;} + // return false on multi-level composite + if ((cTmp = GlyfContourCount(pSimpleGlyf)) < 0) + return false; + cRtnContours += cTmp; + } + + cnContours = size_t(cRtnContours); + return true; +} + +/*---------------------------------------------------------------------------------------------- + Get the point numbers for the end points of the glyph contours based on the given tables + and Glyph ID + Handles both simple and composite glyphs. + cnPoints - count of contours from GlyfContourCount (same as number of end points) + prgnContourEndPoints - should point to a buffer large enough to hold cnPoints integers + Return true if successful, false otherwise. On false, all end points are INT_MIN + False may indicate a white space glyph or a multi-level composite glyph. +----------------------------------------------------------------------------------------------*/ +bool GlyfContourEndPoints(gid16 nGlyphId, const void * pGlyf, const void * pLoca, + size_t lGlyfSize, size_t lLocaSize, const void * pHead, + int * prgnContourEndPoint, size_t cnPoints) +{ + memset(prgnContourEndPoint, 0xFF, cnPoints * sizeof(int)); + // std::fill_n(prgnContourEndPoint, cnPoints, INT_MIN); + + if (IsSpace(nGlyphId, pLoca, lLocaSize, pHead)) {return false;} + + void * pSimpleGlyf = GlyfLookup(nGlyphId, pGlyf, pLoca, lGlyfSize, lLocaSize, pHead); + if (pSimpleGlyf == NULL) {return false;} + + int cContours = GlyfContourCount(pSimpleGlyf); + int cActualPts = 0; + if (cContours > 0) + return GlyfContourEndPoints(pSimpleGlyf, prgnContourEndPoint, cnPoints, cActualPts); + + // handle composite glyphs + + int rgnCompId[kMaxGlyphComponents]; // assumes no glyph will be made of more than 8 components + size_t cCompIdTotal = kMaxGlyphComponents; + size_t cCompId = 0; + + if (!GetComponentGlyphIds(pSimpleGlyf, rgnCompId, cCompIdTotal, cCompId)) + return false; + + int * prgnCurrentEndPoint = prgnContourEndPoint; + int cCurrentPoints = cnPoints; + int nPrevPt = 0; + for (size_t i = 0; i < cCompId; i++) + { + if (IsSpace(static_cast<gid16>(rgnCompId[i]), pLoca, lLocaSize, pHead)) {return false;} + pSimpleGlyf = GlyfLookup(static_cast<gid16>(rgnCompId[i]), pGlyf, pLoca, lGlyfSize, lLocaSize, pHead); + if (pSimpleGlyf == NULL) {return false;} + // returns false on multi-level composite + if (!GlyfContourEndPoints(pSimpleGlyf, prgnCurrentEndPoint, cCurrentPoints, cActualPts)) + return false; + // points in composite are numbered sequentially as components are added + // must adjust end point numbers for new point numbers + for (int j = 0; j < cActualPts; j++) + prgnCurrentEndPoint[j] += nPrevPt; + nPrevPt = prgnCurrentEndPoint[cActualPts - 1] + 1; + + prgnCurrentEndPoint += cActualPts; + cCurrentPoints -= cActualPts; + } + + return true; +} + +/*---------------------------------------------------------------------------------------------- + Get the points for a glyph based on the given tables and Glyph ID + Handles both simple and composite glyphs. + cnPoints - count of points from largest end point obtained from GlyfContourEndPoints + prgnX & prgnY - should point to buffers large enough to hold cnPoints integers + The ranges are parallel so that coordinates for point(n) are found at offset n in + both ranges. These points are in absolute coordinates. + prgfOnCurve - should point to a buffer a large enough to hold cnPoints bytes (bool) + This range is parallel to the prgnX & prgnY + Return true if successful, false otherwise. On false, all points may be INT_MIN + False may indicate a white space glyph, a multi-level composite, or a corrupt font + It's not clear from the TTF spec when the transforms should be applied. Should the + transform be done before or after attachment point calcs? (current code - before) + Should the transform be applied to other offsets? (currently - no; however commented + out code is in place so that if CompoundGlyph::UnscaledOffset on the MS rasterizer is + clear (typical) then yes, and if CompoundGlyph::ScaledOffset on the Apple rasterizer is + clear (typical?) then no). See GetComponentTransform. + It's also unclear where point numbering with attachment poinst starts + (currently - first point number is relative to whole glyph, second point number is + relative to current glyph). +----------------------------------------------------------------------------------------------*/ +bool GlyfPoints(gid16 nGlyphId, const void * pGlyf, + const void * pLoca, size_t lGlyfSize, size_t lLocaSize, const void * pHead, + const int * /*prgnContourEndPoint*/, size_t /*cnEndPoints*/, + int * prgnX, int * prgnY, bool * prgfOnCurve, size_t cnPoints) +{ + memset(prgnX, 0x7F, cnPoints * sizeof(int)); + memset(prgnY, 0x7F, cnPoints * sizeof(int)); + + if (IsSpace(nGlyphId, pLoca, lLocaSize, pHead)) + return false; + + void * pSimpleGlyf = GlyfLookup(nGlyphId, pGlyf, pLoca, lGlyfSize, lLocaSize, pHead); + if (pSimpleGlyf == NULL) + return false; + + int cContours = GlyfContourCount(pSimpleGlyf); + int cActualPts; + if (cContours > 0) + { + if (!GlyfPoints(pSimpleGlyf, prgnX, prgnY, (char *)prgfOnCurve, cnPoints, cActualPts)) + return false; + CalcAbsolutePoints(prgnX, prgnY, cnPoints); + SimplifyFlags((char *)prgfOnCurve, cnPoints); + return true; + } + + // handle composite glyphs + int rgnCompId[kMaxGlyphComponents]; // assumes no glyph will be made of more than 8 components + size_t cCompIdTotal = kMaxGlyphComponents; + size_t cCompId = 0; + + // this will fail if there are more components than there is room for + if (!GetComponentGlyphIds(pSimpleGlyf, rgnCompId, cCompIdTotal, cCompId)) + return false; + + int * prgnCurrentX = prgnX; + int * prgnCurrentY = prgnY; + char * prgbCurrentFlag = (char *)prgfOnCurve; // converting bool to char should be safe + int cCurrentPoints = cnPoints; + bool fOffset = true, fTransOff = true; + int a, b; + float flt11, flt12, flt21, flt22; + // int * prgnPrevX = prgnX; // in case first att pt number relative to preceding glyph + // int * prgnPrevY = prgnY; + for (size_t i = 0; i < cCompId; i++) + { + if (IsSpace(static_cast<gid16>(rgnCompId[i]), pLoca, lLocaSize, pHead)) {return false;} + void * pCompGlyf = GlyfLookup(static_cast<gid16>(rgnCompId[i]), pGlyf, pLoca, lGlyfSize, lLocaSize, pHead); + if (pCompGlyf == NULL) {return false;} + // returns false on multi-level composite + if (!GlyfPoints(pCompGlyf, prgnCurrentX, prgnCurrentY, prgbCurrentFlag, + cCurrentPoints, cActualPts)) + return false; + if (!GetComponentPlacement(pSimpleGlyf, rgnCompId[i], fOffset, a, b)) + return false; + if (!GetComponentTransform(pSimpleGlyf, rgnCompId[i], + flt11, flt12, flt21, flt22, fTransOff)) + return false; + bool fIdTrans = flt11 == 1.0 && flt12 == 0.0 && flt21 == 0.0 && flt22 == 1.0; + + // convert points to absolute coordinates + // do before transform and attachment point placement are applied + CalcAbsolutePoints(prgnCurrentX, prgnCurrentY, cActualPts); + + // apply transform - see main method note above + // do before attachment point calcs + if (!fIdTrans) + for (int j = 0; j < cActualPts; j++) + { + int x = prgnCurrentX[j]; // store before transform applied + int y = prgnCurrentY[j]; + prgnCurrentX[j] = (int)(x * flt11 + y * flt12); + prgnCurrentY[j] = (int)(x * flt21 + y * flt22); + } + + // apply placement - see main method note above + int nXOff, nYOff; + if (fOffset) // explicit x & y offsets + { + /* ignore fTransOff for now + if (fTransOff && !fIdTrans) + { // transform x & y offsets + nXOff = (int)(a * flt11 + b * flt12); + nYOff = (int)(a * flt21 + b * flt22); + } + else */ + { // don't transform offset + nXOff = a; + nYOff = b; + } + } + else // attachment points + { // in case first point is relative to preceding glyph and second relative to current + // nXOff = prgnPrevX[a] - prgnCurrentX[b]; + // nYOff = prgnPrevY[a] - prgnCurrentY[b]; + // first point number relative to whole composite, second relative to current glyph + nXOff = prgnX[a] - prgnCurrentX[b]; + nYOff = prgnY[a] - prgnCurrentY[b]; + } + for (int j = 0; j < cActualPts; j++) + { + prgnCurrentX[j] += nXOff; + prgnCurrentY[j] += nYOff; + } + + // prgnPrevX = prgnCurrentX; + // prgnPrevY = prgnCurrentY; + prgnCurrentX += cActualPts; + prgnCurrentY += cActualPts; + prgbCurrentFlag += cActualPts; + cCurrentPoints -= cActualPts; + } + + SimplifyFlags((char *)prgfOnCurve, cnPoints); + + return true; +} + +/*---------------------------------------------------------------------------------------------- + Simplify the meaning of flags to just indicate whether point is on-curve or off-curve. +---------------------------------------------------------------------------------------------*/ +bool SimplifyFlags(char * prgbFlags, int cnPoints) +{ + for (int i = 0; i < cnPoints; i++) + prgbFlags[i] = static_cast<char>(prgbFlags[i] & Sfnt::SimpleGlyph::OnCurve); + return true; +} + +/*---------------------------------------------------------------------------------------------- + Convert relative point coordinates to absolute coordinates + Points are stored in the font such that they are offsets from one another except for the + first point of a glyph. +---------------------------------------------------------------------------------------------*/ +bool CalcAbsolutePoints(int * prgnX, int * prgnY, int cnPoints) +{ + int nX = prgnX[0]; + int nY = prgnY[0]; + for (int i = 1; i < cnPoints; i++) + { + prgnX[i] += nX; + nX = prgnX[i]; + prgnY[i] += nY; + nY = prgnY[i]; + } + + return true; +} +#endif + +/*---------------------------------------------------------------------------------------------- + Return the length of the 'name' table in bytes. + Currently used. +---------------------------------------------------------------------------------------------*/ +#if 0 +size_t NameTableLength(const byte * pTable) +{ + byte * pb = (const_cast<byte *>(pTable)) + 2; // skip format + size_t cRecords = *pb++ << 8; cRecords += *pb++; + int dbStringOffset0 = (*pb++) << 8; dbStringOffset0 += *pb++; + int dbMaxStringOffset = 0; + for (size_t irec = 0; irec < cRecords; irec++) + { + int nPlatform = (*pb++) << 8; nPlatform += *pb++; + int nEncoding = (*pb++) << 8; nEncoding += *pb++; + int nLanguage = (*pb++) << 8; nLanguage += *pb++; + int nName = (*pb++) << 8; nName += *pb++; + int cbStringLen = (*pb++) << 8; cbStringLen += *pb++; + int dbStringOffset = (*pb++) << 8; dbStringOffset += *pb++; + if (dbMaxStringOffset < dbStringOffset + cbStringLen) + dbMaxStringOffset = dbStringOffset + cbStringLen; + } + return dbStringOffset0 + dbMaxStringOffset; +} +#endif + +} // end of namespace TtfUtil +} // end of namespace graphite |