/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*- */ /* * This file is part of the LibreOffice project. * * This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. * * This file incorporates work covered by the following license notice: * * Licensed to the Apache Software Foundation (ASF) under one or more * contributor license agreements. See the NOTICE file distributed * with this work for additional information regarding copyright * ownership. The ASF licenses this file to you under the Apache * License, Version 2.0 (the "License"); you may not use this file * except in compliance with the License. You may obtain a copy of * the License at http://www.apache.org/licenses/LICENSE-2.0 . */ /* * Sun Font Tools * * Author: Alexander Gelfenbain * */ #include #include #include #include #ifdef UNX #include #include #endif #include #include "ttcr.hxx" #include "xlat.hxx" #include #include #include #include #include #include namespace vcl { /*- module identification */ static const char * const modname = "SunTypeTools-TT"; static const char * const modver = "1.0"; static const char * const modextra = "gelf"; /*- private functions, constants and data types */ enum PathSegmentType { PS_NOOP = 0, PS_MOVETO = 1, PS_LINETO = 2, PS_CURVETO = 3, PS_CLOSEPATH = 4 }; struct PSPathElement { PathSegmentType type; int x1, y1; int x2, y2; int x3, y3; explicit PSPathElement( PathSegmentType i_eType ) : type( i_eType ), x1( 0 ), y1( 0 ), x2( 0 ), y2( 0 ), x3( 0 ), y3( 0 ) { } }; /*- In horizontal writing mode right sidebearing is calculated using this formula *- rsb = aw - (lsb + xMax - xMin) -*/ struct TTGlyphMetrics { sal_Int16 xMin; sal_Int16 yMin; sal_Int16 xMax; sal_Int16 yMax; sal_uInt16 aw; /*- Advance Width (horizontal writing mode) */ sal_Int16 lsb; /*- Left sidebearing (horizontal writing mode) */ sal_uInt16 ah; /*- advance height (vertical writing mode) */ }; #define HFORMAT_LINELEN 64 struct HexFmt { FILE *o; char buffer[HFORMAT_LINELEN]; size_t bufpos; int total; }; struct GlyphOffsets { sal_uInt32 nGlyphs; /* number of glyphs in the font + 1 */ sal_uInt32 *offs; /* array of nGlyphs offsets */ }; static const sal_uInt32 T_true = 0x74727565; /* 'true' */ static const sal_uInt32 T_ttcf = 0x74746366; /* 'ttcf' */ static const sal_uInt32 T_otto = 0x4f54544f; /* 'OTTO' */ /* standard TrueType table tags */ #define T_maxp 0x6D617870 #define T_glyf 0x676C7966 #define T_head 0x68656164 #define T_loca 0x6C6F6361 #define T_name 0x6E616D65 #define T_hhea 0x68686561 #define T_hmtx 0x686D7478 #define T_cmap 0x636D6170 #define T_vhea 0x76686561 #define T_vmtx 0x766D7478 #define T_OS2 0x4F532F32 #define T_post 0x706F7374 #define T_cvt 0x63767420 #define T_prep 0x70726570 #define T_fpgm 0x6670676D #define T_gsub 0x47535542 #define T_CFF 0x43464620 static void *smalloc(size_t size) { void *res = malloc(size); assert(res != nullptr); return res; } static void *scalloc(size_t n, size_t size) { void *res = calloc(n, size); assert(res != nullptr); return res; } /*- Data access methods for data stored in big-endian format */ static sal_Int16 GetInt16(const sal_uInt8 *ptr, size_t offset) { sal_Int16 t; assert(ptr != nullptr); t = (ptr+offset)[0] << 8 | (ptr+offset)[1]; return t; } static sal_uInt16 GetUInt16(const sal_uInt8 *ptr, size_t offset) { sal_uInt16 t; assert(ptr != nullptr); t = (ptr+offset)[0] << 8 | (ptr+offset)[1]; return t; } static sal_Int32 GetInt32(const sal_uInt8 *ptr, size_t offset) { sal_Int32 t; assert(ptr != nullptr); t = (ptr+offset)[0] << 24 | (ptr+offset)[1] << 16 | (ptr+offset)[2] << 8 | (ptr+offset)[3]; return t; } static sal_uInt32 GetUInt32(const sal_uInt8 *ptr, size_t offset) { sal_uInt32 t; assert(ptr != nullptr); t = (ptr+offset)[0] << 24 | (ptr+offset)[1] << 16 | (ptr+offset)[2] << 8 | (ptr+offset)[3]; return t; } #if defined(OSL_BIGENDIAN) #define Int16FromMOTA(a) (a) #define Int32FromMOTA(a) (a) #else static sal_uInt16 Int16FromMOTA(sal_uInt16 a) { return static_cast(static_cast(a >> 8) | (static_cast(a) << 8)); } static sal_uInt32 Int32FromMOTA(sal_uInt32 a) { return ((a>>24)&0xFF) | (((a>>8)&0xFF00) | ((a&0xFF00)<<8) | ((a&0xFF)<<24)); } #endif static F16Dot16 fixedMul(F16Dot16 a, F16Dot16 b) { unsigned int a1, b1; unsigned int a2, b2; F16Dot16 res; int sign; sign = (a & 0x80000000) ^ (b & 0x80000000); if (a < 0) a = -a; if (b < 0) b = -b; a1 = a >> 16; b1 = a & 0xFFFF; a2 = b >> 16; b2 = b & 0xFFFF; res = a1 * a2; /* if (res > 0x7FFF) assert(!"fixedMul: F16Dot16 overflow"); */ res <<= 16; res += a1 * b2 + b1 * a2 + ((b1 * b2) >> 16); return sign ? -res : res; } static F16Dot16 fixedDiv(F16Dot16 a, F16Dot16 b) { unsigned int f, r; F16Dot16 res; int sign; sign = (a & 0x80000000) ^ (b & 0x80000000); if (a < 0) a = -a; if (b < 0) b = -b; f = a / b; r = a % b; /* if (f > 0x7FFFF) assert(!"fixedDiv: F16Dot16 overflow"); */ while (r > 0xFFFF) { r >>= 1; b >>= 1; } res = (f << 16) + (r << 16) / b; return sign ? -res : res; } /*- returns a * b / c -*/ /* XXX provide a real implementation that preserves accuracy */ static F16Dot16 fixedMulDiv(F16Dot16 a, F16Dot16 b, F16Dot16 c) { F16Dot16 res; res = fixedMul(a, b); return fixedDiv(res, c); } /*- Translate units from TT to PS (standard 1/1000) -*/ static int XUnits(int unitsPerEm, int n) { return (n * 1000) / unitsPerEm; } static const sal_uInt8* getTable( TrueTypeFont const *ttf, sal_uInt32 ord) { return ttf->tables[ord]; } static sal_uInt32 getTableSize(TrueTypeFont const *ttf, sal_uInt32 ord) { return ttf->tlens[ord]; } /* Hex Formatter functions */ static const char HexChars[] = "0123456789ABCDEF"; static HexFmt *HexFmtNew(FILE *outf) { HexFmt* res = static_cast(smalloc(sizeof(HexFmt))); res->bufpos = res->total = 0; res->o = outf; return res; } static bool HexFmtFlush(HexFmt *_this) { bool bRet = true; if (_this->bufpos) { size_t nWritten = fwrite(_this->buffer, 1, _this->bufpos, _this->o); bRet = nWritten == _this->bufpos; _this->bufpos = 0; } return bRet; } static void HexFmtOpenString(HexFmt *_this) { fputs("<\n", _this->o); } static void HexFmtCloseString(HexFmt *_this) { HexFmtFlush(_this); fputs("00\n>\n", _this->o); } static void HexFmtDispose(HexFmt *_this) { HexFmtFlush(_this); free(_this); } static void HexFmtBlockWrite(HexFmt *_this, const void *ptr, sal_uInt32 size) { sal_uInt8 Ch; sal_uInt32 i; if (_this->total + size > 65534) { HexFmtFlush(_this); HexFmtCloseString(_this); _this->total = 0; HexFmtOpenString(_this); } for (i=0; i(ptr)[i]; _this->buffer[_this->bufpos++] = HexChars[Ch >> 4]; _this->buffer[_this->bufpos++] = HexChars[Ch & 0xF]; if (_this->bufpos == HFORMAT_LINELEN) { HexFmtFlush(_this); fputc('\n', _this->o); } } _this->total += size; } /* Outline Extraction functions */ /* fills the aw and lsb entries of the TTGlyphMetrics structure from hmtx table -*/ static void GetMetrics(TrueTypeFont const *ttf, sal_uInt32 glyphID, TTGlyphMetrics *metrics) { const sal_uInt8* table = getTable( ttf, O_hmtx ); metrics->aw = metrics->lsb = metrics->ah = 0; if (!table || !ttf->numberOfHMetrics) return; if (glyphID < ttf->numberOfHMetrics) { metrics->aw = GetUInt16(table, 4 * glyphID); metrics->lsb = GetInt16(table, 4 * glyphID + 2); } else { metrics->aw = GetUInt16(table, 4 * (ttf->numberOfHMetrics - 1)); metrics->lsb = GetInt16(table + ttf->numberOfHMetrics * 4, (glyphID - ttf->numberOfHMetrics) * 2); } table = getTable(ttf, O_vmtx); if( !table || !ttf->numOfLongVerMetrics ) return; if (glyphID < ttf->numOfLongVerMetrics) { metrics->ah = GetUInt16(table, 4 * glyphID); } else { metrics->ah = GetUInt16(table, 4 * (ttf->numOfLongVerMetrics - 1)); } } static int GetTTGlyphOutline(TrueTypeFont *, sal_uInt32 , ControlPoint **, TTGlyphMetrics *, std::vector< sal_uInt32 >* ); /* returns the number of control points, allocates the pointArray */ static int GetSimpleTTOutline(TrueTypeFont const *ttf, sal_uInt32 glyphID, ControlPoint **pointArray, TTGlyphMetrics *metrics) { const sal_uInt8* table = getTable(ttf, O_glyf); const sal_uInt32 nTableSize = getTableSize(ttf, O_glyf); sal_uInt8 flag, n; int i, j, z; *pointArray = nullptr; /* printf("GetSimpleTTOutline(%d)\n", glyphID); */ if( glyphID >= ttf->nglyphs ) /*- glyph is not present in the font */ return 0; const sal_uInt8* ptr = table + ttf->goffsets[glyphID]; const sal_Int16 numberOfContours = GetInt16(ptr, 0); if( numberOfContours <= 0 ) /*- glyph is not simple */ return 0; if (metrics) { /*- GetCompoundTTOutline() calls this function with NULL metrics -*/ metrics->xMin = GetInt16(ptr, 2); metrics->yMin = GetInt16(ptr, 4); metrics->xMax = GetInt16(ptr, 6); metrics->yMax = GetInt16(ptr, 8); GetMetrics(ttf, glyphID, metrics); } /* determine the last point and be extra safe about it. But probably this code is not needed */ sal_uInt16 lastPoint=0; const sal_Int32 nMaxContours = (nTableSize - 10)/2; if (numberOfContours > nMaxContours) return 0; for (i=0; i lastPoint) lastPoint = t; } sal_uInt16 instLen = GetUInt16(ptr, 10 + numberOfContours*2); sal_uInt32 nOffset = 10 + 2 * numberOfContours + 2 + instLen; if (nOffset > nTableSize) return 0; const sal_uInt8* p = ptr + nOffset; const sal_uInt32 nBytesRemaining = nTableSize - nOffset; const sal_uInt16 palen = lastPoint+1; //at a minimum its one byte per entry if (palen > nBytesRemaining || lastPoint > nBytesRemaining-1) { SAL_WARN("vcl.fonts", "Font " << OUString::createFromAscii(ttf->fname) << "claimed a palen of " << palen << " but max bytes remaining is " << nBytesRemaining); return 0; } ControlPoint* pa = static_cast(calloc(palen, sizeof(ControlPoint))); i = 0; while (i <= lastPoint) { flag = *p++; pa[i++].flags = static_cast(flag); if (flag & 8) { /*- repeat flag */ n = *p++; for (j=0; j lastPoint) { /*- if the font is really broken */ free(pa); return 0; } pa[i++].flags = flag; } } } /*- Process the X coordinate */ z = 0; for (i = 0; i <= lastPoint; i++) { if (pa[i].flags & 0x02) { if (pa[i].flags & 0x10) { z += static_cast(*p++); } else { z -= static_cast(*p++); } } else if ( !(pa[i].flags & 0x10)) { z += GetInt16(p, 0); p += 2; } pa[i].x = static_cast(z); } /*- Process the Y coordinate */ z = 0; for (i = 0; i <= lastPoint; i++) { if (pa[i].flags & 0x04) { if (pa[i].flags & 0x20) { z += *p++; } else { z -= *p++; } } else if ( !(pa[i].flags & 0x20)) { z += GetInt16(p, 0); p += 2; } pa[i].y = static_cast(z); } for (i=0; i= palen, "vcl.fonts", "Font " << OUString::createFromAscii(ttf->fname) << " contour " << i << " claimed an illegal offset of " << offset << " but max offset is " << palen-1); if (offset >= palen) continue; pa[offset].flags |= 0x00008000; /*- set the end contour flag */ } *pointArray = pa; return lastPoint + 1; } static int GetCompoundTTOutline(TrueTypeFont *ttf, sal_uInt32 glyphID, ControlPoint **pointArray, TTGlyphMetrics *metrics, std::vector< sal_uInt32 >& glyphlist) { sal_uInt16 flags, index; sal_Int16 e, f; const sal_uInt8* table = getTable( ttf, O_glyf ); std::vector myPoints; ControlPoint *nextComponent, *pa; int i, np; F16Dot16 a = 0x10000, b = 0, c = 0, d = 0x10000, m, n, abs1, abs2, abs3; *pointArray = nullptr; /* printf("GetCompoundTTOutline(%d)\n", glyphID); */ if (glyphID >= ttf->nglyphs) /*- incorrect glyphID */ return 0; const sal_uInt8* ptr = table + ttf->goffsets[glyphID]; if (GetInt16(ptr, 0) != -1) /* number of contours - glyph is not compound */ return 0; if (metrics) { metrics->xMin = GetInt16(ptr, 2); metrics->yMin = GetInt16(ptr, 4); metrics->xMax = GetInt16(ptr, 6); metrics->yMax = GetInt16(ptr, 8); GetMetrics(ttf, glyphID, metrics); } ptr += 10; do { flags = GetUInt16(ptr, 0); /* printf("flags: 0x%X\n", flags); */ index = GetUInt16(ptr, 2); ptr += 4; if( std::find( glyphlist.begin(), glyphlist.end(), index ) != glyphlist.end() ) { #if OSL_DEBUG_LEVEL > 1 fprintf(stderr, "Endless loop found in a compound glyph.\n"); fprintf(stderr, "%d -> ", index); fprintf(stderr," ["); for( const auto& rGlyph : glyphlist ) { fprintf( stderr,"%d ", (int) rGlyph ); } fprintf(stderr,"]\n"); /**/ #endif } glyphlist.push_back( index ); if ((np = GetTTGlyphOutline(ttf, index, &nextComponent, nullptr, &glyphlist)) == 0) { /* XXX that probably indicates a corrupted font */ #if OSL_DEBUG_LEVEL > 1 fprintf(stderr, "An empty compound!\n"); /* assert(!"An empty compound"); */ #endif } if( ! glyphlist.empty() ) glyphlist.pop_back(); if ((flags & USE_MY_METRICS) && metrics) GetMetrics(ttf, index, metrics); if (flags & ARG_1_AND_2_ARE_WORDS) { e = GetInt16(ptr, 0); f = GetInt16(ptr, 2); /* printf("ARG_1_AND_2_ARE_WORDS: %d %d\n", e & 0xFFFF, f & 0xFFFF); */ ptr += 4; } else { if (flags & ARGS_ARE_XY_VALUES) { /* args are signed */ e = static_cast(*ptr++); f = static_cast(*ptr++); /* printf("ARGS_ARE_XY_VALUES: %d %d\n", e & 0xFF, f & 0xFF); */ } else { /* args are unsigned */ /* printf("!ARGS_ARE_XY_VALUES\n"); */ e = *ptr++; f = *ptr++; } } a = d = 0x10000; b = c = 0; if (flags & WE_HAVE_A_SCALE) { a = GetInt16(ptr, 0) << 2; d = a; ptr += 2; } else if (flags & WE_HAVE_AN_X_AND_Y_SCALE) { a = GetInt16(ptr, 0) << 2; d = GetInt16(ptr, 2) << 2; ptr += 4; } else if (flags & WE_HAVE_A_TWO_BY_TWO) { a = GetInt16(ptr, 0) << 2; b = GetInt16(ptr, 2) << 2; c = GetInt16(ptr, 4) << 2; d = GetInt16(ptr, 6) << 2; ptr += 8; } abs1 = (a < 0) ? -a : a; abs2 = (b < 0) ? -b : b; m = std::max(abs1, abs2); abs3 = abs1 - abs2; if (abs3 < 0) abs3 = -abs3; if (abs3 <= 33) m *= 2; abs1 = (c < 0) ? -c : c; abs2 = (d < 0) ? -d : d; n = std::max(abs1, abs2); abs3 = abs1 - abs2; if (abs3 < 0) abs3 = -abs3; if (abs3 <= 33) n *= 2; SAL_WARN_IF(np && !m, "vcl.fonts", "Parsing error in " << OUString::createFromAscii(ttf->fname) << ": divide by zero"); if (m != 0) { for (i=0; i(fixedMul(t, m) >> 16); t = fixedMulDiv(b, x << 16, n) + fixedMulDiv(d, y << 16, n) + sal_Int32(sal_uInt16(f) << 16); cp.y = static_cast(fixedMul(t, n) >> 16); myPoints.push_back( cp ); } } free(nextComponent); } while (flags & MORE_COMPONENTS); // #i123417# some fonts like IFAOGrec have no outline points in some compound glyphs // so this unlikely but possible scenario should be handled gracefully if( myPoints.empty() ) return 0; np = myPoints.size(); if (np > 0) { pa = static_cast(calloc(np, sizeof(ControlPoint))); assert(pa != nullptr); memcpy(pa, &myPoints[0], np * sizeof(ControlPoint)); *pointArray = pa; } return np; } /* NOTE: GetTTGlyphOutline() returns -1 if the glyphID is incorrect, * but Get{Simple|Compound}GlyphOutline returns 0 in such a case. * * NOTE: glyphlist is the stack of glyphs traversed while constructing * a composite glyph. This is a safeguard against endless recursion * in corrupted fonts. */ static int GetTTGlyphOutline(TrueTypeFont *ttf, sal_uInt32 glyphID, ControlPoint **pointArray, TTGlyphMetrics *metrics, std::vector< sal_uInt32 >* glyphlist) { const sal_uInt8 *table = getTable( ttf, O_glyf ); sal_Int16 numberOfContours; int res; *pointArray = nullptr; if (metrics) { memset(metrics, 0, sizeof(TTGlyphMetrics)); /*- metrics is initialized to all zeroes */ } if (glyphID >= ttf->nglyphs) return -1; /**/ const sal_uInt8* ptr = table + ttf->goffsets[glyphID]; int length = ttf->goffsets[glyphID+1] - ttf->goffsets[glyphID]; if (length == 0) { /*- empty glyphs still have hmtx and vmtx metrics values */ if (metrics) GetMetrics(ttf, glyphID, metrics); return 0; } numberOfContours = GetInt16(ptr, 0); if (numberOfContours >= 0) { res=GetSimpleTTOutline(ttf, glyphID, pointArray, metrics); } else { std::vector< sal_uInt32 > aPrivList; aPrivList.push_back( glyphID ); res = GetCompoundTTOutline(ttf, glyphID, pointArray, metrics, glyphlist ? *glyphlist : aPrivList ); } return res; } /*- returns the number of items in the path -*/ static int BSplineToPSPath(ControlPoint const *srcA, int srcCount, PSPathElement **path) { std::vector< PSPathElement > aPathList; int nPathCount = 0; PSPathElement p( PS_NOOP ); int x0 = 0, y0 = 0, x1 = 0, y1 = 0, x2, y2, curx, cury; bool lastOff = false; /*- last point was off-contour */ int scflag = 1; /*- start contour flag */ bool ecflag = false; /*- end contour flag */ int cp = 0; /*- current point */ int StartContour = 0, EndContour = 1; *path = nullptr; /* if (srcCount > 0) for(;;) */ while (srcCount > 0) { /*- srcCount does not get changed inside the loop. */ if (scflag) { int l = cp; StartContour = cp; while (!(srcA[l].flags & 0x8000)) l++; EndContour = l; if (StartContour == EndContour) { if (cp + 1 < srcCount) { cp++; continue; } else { break; } } p = PSPathElement(PS_MOVETO); if (!(srcA[cp].flags & 1)) { if (!(srcA[EndContour].flags & 1)) { p.x1 = x0 = (srcA[cp].x + srcA[EndContour].x + 1) / 2; p.y1 = y0 = (srcA[cp].y + srcA[EndContour].y + 1) / 2; } else { p.x1 = x0 = srcA[EndContour].x; p.y1 = y0 = srcA[EndContour].y; } } else { p.x1 = x0 = srcA[cp].x; p.y1 = y0 = srcA[cp].y; cp++; } aPathList.push_back( p ); lastOff = false; scflag = 0; } curx = srcA[cp].x; cury = srcA[cp].y; if (srcA[cp].flags & 1) { if (lastOff) { p = PSPathElement(PS_CURVETO); p.x1 = x0 + (2 * (x1 - x0) + 1) / 3; p.y1 = y0 + (2 * (y1 - y0) + 1) / 3; p.x2 = x1 + (curx - x1 + 1) / 3; p.y2 = y1 + (cury - y1 + 1) / 3; p.x3 = curx; p.y3 = cury; aPathList.push_back( p ); } else { if (!(x0 == curx && y0 == cury)) { /* eliminate empty lines */ p = PSPathElement(PS_LINETO); p.x1 = curx; p.y1 = cury; aPathList.push_back( p ); } } x0 = curx; y0 = cury; lastOff = false; } else { if (lastOff) { x2 = (x1 + curx + 1) / 2; y2 = (y1 + cury + 1) / 2; p = PSPathElement(PS_CURVETO); p.x1 = x0 + (2 * (x1 - x0) + 1) / 3; p.y1 = y0 + (2 * (y1 - y0) + 1) / 3; p.x2 = x1 + (x2 - x1 + 1) / 3; p.y2 = y1 + (y2 - y1 + 1) / 3; p.x3 = x2; p.y3 = y2; aPathList.push_back( p ); x0 = x2; y0 = y2; x1 = curx; y1 = cury; } else { x1 = curx; y1 = cury; } lastOff = true; } if (ecflag) { aPathList.emplace_back(PS_CLOSEPATH ); scflag = 1; ecflag = false; cp = EndContour + 1; if (cp >= srcCount) break; continue; } if (cp == EndContour) { cp = StartContour; ecflag = true; } else { cp++; } } if( (nPathCount = static_cast(aPathList.size())) > 0) { *path = static_cast(calloc(nPathCount, sizeof(PSPathElement))); assert(*path != nullptr); memcpy( *path, &aPathList[0], nPathCount * sizeof(PSPathElement) ); } return nPathCount; } /*- Extracts a string from the name table and allocates memory for it -*/ static char *nameExtract( const sal_uInt8* name, int nTableSize, int n, int dbFlag, sal_Unicode** ucs2result ) { char *res; const sal_uInt8* ptr = name + GetUInt16(name, 4) + GetUInt16(name + 6, 12 * n + 10); int len = GetUInt16(name+6, 12 * n + 8); // sanity check const sal_uInt8* end_table = name+nTableSize; const int available_space = ptr > end_table ? 0 : (end_table - ptr); if( (len <= 0) || len > available_space) { if( ucs2result ) *ucs2result = nullptr; return nullptr; } if( ucs2result ) *ucs2result = nullptr; if (dbFlag) { res = static_cast(malloc(1 + len/2)); assert(res != nullptr); for (int i = 0; i < len/2; i++) res[i] = *(ptr + i * 2 + 1); res[len/2] = 0; if( ucs2result ) { *ucs2result = static_cast(malloc( len+2 )); for (int i = 0; i < len/2; i++ ) (*ucs2result)[i] = GetUInt16( ptr, 2*i ); (*ucs2result)[len/2] = 0; } } else { res = static_cast(malloc(1 + len)); assert(res != nullptr); memcpy(res, ptr, len); res[len] = 0; } return res; } static int findname( const sal_uInt8 *name, sal_uInt16 n, sal_uInt16 platformID, sal_uInt16 encodingID, sal_uInt16 languageID, sal_uInt16 nameID ) { if (n == 0) return -1; int l = 0, r = n-1; sal_uInt32 t1, t2; sal_uInt32 m1, m2; m1 = (platformID << 16) | encodingID; m2 = (languageID << 16) | nameID; do { const int i = (l + r) >> 1; t1 = GetUInt32(name + 6, i * 12 + 0); t2 = GetUInt32(name + 6, i * 12 + 4); if (! ((m1 < t1) || ((m1 == t1) && (m2 < t2)))) l = i + 1; if (! ((m1 > t1) || ((m1 == t1) && (m2 > t2)))) r = i - 1; } while (l <= r); if (l - r == 2) { return l - 1; } return -1; } /* XXX marlett.ttf uses (3, 0, 1033) instead of (3, 1, 1033) and does not have any Apple tables. * Fix: if (3, 1, 1033) is not found - need to check for (3, 0, 1033) * * /d/fonts/ttzh_tw/Big5/Hanyi/ma6b5p uses (1, 0, 19) for English strings, instead of (1, 0, 0) * and does not have (3, 1, 1033) * Fix: if (1, 0, 0) and (3, 1, 1033) are not found need to look for (1, 0, *) - that will * require a change in algorithm * * /d/fonts/fdltest/Korean/h2drrm has unsorted names and a an unknown (to me) Mac LanguageID, * but (1, 0, 1042) strings usable * Fix: change algorithm, and use (1, 0, *) if both standard Mac and MS strings are not found */ static void GetNames(TrueTypeFont *t) { const sal_uInt8* table = getTable( t, O_name ); const sal_uInt32 nTableSize = getTableSize(t, O_name); if (nTableSize < 6) { #if OSL_DEBUG_LEVEL > 1 fprintf(stderr, "O_name table too small\n"); #endif return; } sal_uInt16 n = GetUInt16(table, 2); /* simple sanity check for name table entry count */ const size_t nMinRecordSize = 12; const size_t nSpaceAvailable = nTableSize - 6; const size_t nMaxRecords = nSpaceAvailable/nMinRecordSize; if (n >= nMaxRecords) n = 0; int i, r; bool bPSNameOK = true; /* PostScript name: preferred Microsoft */ t->psname = nullptr; if ((r = findname(table, n, 3, 1, 0x0409, 6)) != -1) t->psname = nameExtract(table, nTableSize, r, 1, nullptr); if ( ! t->psname && (r = findname(table, n, 1, 0, 0, 6)) != -1) t->psname = nameExtract(table, nTableSize, r, 0, nullptr); if ( ! t->psname && (r = findname(table, n, 3, 0, 0x0409, 6)) != -1) { // some symbol fonts like Marlett have a 3,0 name! t->psname = nameExtract(table, nTableSize, r, 1, nullptr); } // for embedded font in Ghostscript PDFs if ( ! t->psname && (r = findname(table, n, 2, 2, 0, 6)) != -1) { t->psname = nameExtract(table, nTableSize, r, 0, nullptr); } if ( ! t->psname ) { if ( t->fname ) { char* pReverse = t->fname + strlen(t->fname); /* take only last token of filename */ while(pReverse != t->fname && *pReverse != '/') pReverse--; if(*pReverse == '/') pReverse++; t->psname = strdup(pReverse); assert(t->psname != nullptr); for (i=strlen(t->psname) - 1; i > 0; i--) { /*- Remove the suffix -*/ if (t->psname[i] == '.' ) { t->psname[i] = 0; break; } } } else t->psname = strdup( "Unknown" ); } /* Font family and subfamily names: preferred Apple */ t->family = nullptr; if ((r = findname(table, n, 0, 0, 0, 1)) != -1) t->family = nameExtract(table, nTableSize, r, 1, &t->ufamily); if ( ! t->family && (r = findname(table, n, 3, 1, 0x0409, 1)) != -1) t->family = nameExtract(table, nTableSize, r, 1, &t->ufamily); if ( ! t->family && (r = findname(table, n, 1, 0, 0, 1)) != -1) t->family = nameExtract(table, nTableSize, r, 0, nullptr); if ( ! t->family && (r = findname(table, n, 3, 1, 0x0411, 1)) != -1) t->family = nameExtract(table, nTableSize, r, 1, &t->ufamily); if ( ! t->family && (r = findname(table, n, 3, 0, 0x0409, 1)) != -1) t->family = nameExtract(table, nTableSize, r, 1, &t->ufamily); if ( ! t->family ) { t->family = strdup(t->psname); assert(t->family != nullptr); } t->subfamily = nullptr; t->usubfamily = nullptr; if ((r = findname(table, n, 1, 0, 0, 2)) != -1) t->subfamily = nameExtract(table, nTableSize, r, 0, &t->usubfamily); if ( ! t->subfamily && (r = findname(table, n, 3, 1, 0x0409, 2)) != -1) t->subfamily = nameExtract(table, nTableSize, r, 1, &t->usubfamily); if ( ! t->subfamily ) { t->subfamily = strdup(""); } /* #i60349# sanity check psname * psname pratically has to be 7bit ascii and should not contains spaces * there is a class of broken fonts which do not fulfill that at all, so let's try * if the family name is 7bit ascii and take it instead if so */ /* check psname */ for( i = 0; t->psname[i] != 0 && bPSNameOK; i++ ) if( t->psname[ i ] < 33 || (t->psname[ i ] & 0x80) ) bPSNameOK = false; if( !bPSNameOK ) { /* check if family is a suitable replacement */ if( t->ufamily && t->family ) { bool bReplace = true; for( i = 0; t->ufamily[ i ] != 0 && bReplace; i++ ) if( t->ufamily[ i ] < 33 || t->ufamily[ i ] > 127 ) bReplace = false; if( bReplace ) { free( t->psname ); t->psname = strdup( t->family ); } } } } enum cmapType { CMAP_NOT_USABLE = -1, CMAP_MS_Symbol = 10, CMAP_MS_Unicode = 11, CMAP_MS_ShiftJIS = 12, CMAP_MS_Big5 = 13, CMAP_MS_PRC = 14, CMAP_MS_Wansung = 15, CMAP_MS_Johab = 16 }; #define MISSING_GLYPH_INDEX 0 static sal_uInt32 getGlyph0(const sal_uInt8* cmap, sal_uInt32, sal_uInt32 c) { if (c <= 255) { return *(cmap + 6 + c); } else { return MISSING_GLYPH_INDEX; } } struct subHeader2 { sal_uInt16 const firstCode; sal_uInt16 const entryCount; sal_uInt16 const idDelta; sal_uInt16 idRangeOffset; }; static sal_uInt32 getGlyph2(const sal_uInt8 *cmap, const sal_uInt32 nMaxCmapSize, sal_uInt32 c) { sal_uInt16 const *CMAP2 = reinterpret_cast(cmap); sal_uInt8 theHighByte; sal_uInt8 theLowByte; subHeader2 const * subHeader2s; sal_uInt16 const * subHeader2Keys; sal_uInt16 firstCode; int k = -1; sal_uInt32 ToReturn; theHighByte = static_cast((c >> 8) & 0x00ff); theLowByte = static_cast(c & 0x00ff); subHeader2Keys = CMAP2 + 3; subHeader2s = reinterpret_cast(subHeader2Keys + 256); if(reinterpret_cast(&subHeader2Keys[theHighByte]) - cmap < int(nMaxCmapSize - 2)) { k = Int16FromMOTA(subHeader2Keys[theHighByte]) / 8; // check if the subheader record fits into available space if(reinterpret_cast(&subHeader2s[k]) - cmap >= int(nMaxCmapSize - sizeof(subHeader2))) k = -1; } if(k == 0) { firstCode = Int16FromMOTA(subHeader2s[0].firstCode); if(theLowByte >= firstCode && theLowByte < (firstCode + Int16FromMOTA(subHeader2s[k].entryCount))) { sal_uInt16 const * pGlyph = (&(subHeader2s[0].idRangeOffset)) + (Int16FromMOTA(subHeader2s[0].idRangeOffset)/2) /* + offset */ + theLowByte /* + to_look */ - firstCode ; if (reinterpret_cast(pGlyph) - cmap < int(nMaxCmapSize) - 4) return *pGlyph; else return MISSING_GLYPH_INDEX; } else { return MISSING_GLYPH_INDEX; } } else if (k > 0) { firstCode = Int16FromMOTA(subHeader2s[k].firstCode); if(theLowByte >= firstCode && theLowByte < (firstCode + Int16FromMOTA(subHeader2s[k].entryCount))) { ToReturn = *((&(subHeader2s[k].idRangeOffset)) + (Int16FromMOTA(subHeader2s[k].idRangeOffset)/2) + theLowByte - firstCode); if(ToReturn == 0) { return MISSING_GLYPH_INDEX; } else { ToReturn += Int16FromMOTA(subHeader2s[k].idDelta); return (ToReturn & 0xFFFF); } } else { return MISSING_GLYPH_INDEX; } } else { return MISSING_GLYPH_INDEX; } } static sal_uInt32 getGlyph6(const sal_uInt8 *cmap, sal_uInt32, sal_uInt32 c) { sal_uInt16 firstCode, lastCode, count; sal_uInt16 const *CMAP6 = reinterpret_cast(cmap); firstCode = Int16FromMOTA(*(CMAP6 + 3)); count = Int16FromMOTA(*(CMAP6 + 4)); lastCode = firstCode + count - 1; if (c < firstCode || c > lastCode) { return MISSING_GLYPH_INDEX; } else { return *((CMAP6 + 5)/*glyphIdArray*/ + (c - firstCode)); } } static sal_uInt16 GEbinsearch(sal_uInt16 const *ar, sal_uInt16 length, sal_uInt16 toSearch) { signed int low, high, lastfound = 0xffff; sal_uInt16 res; if(length == sal_uInt16(0) || length == sal_uInt16(0xFFFF)) { return sal_uInt16(0xFFFF); } low = 0; high = length - 1; while(high >= low) { int mid = (high + low)/2; res = Int16FromMOTA(*(ar+mid)); if(res >= toSearch) { lastfound = mid; high = --mid; } else { low = ++mid; } } return static_cast(lastfound); } static sal_uInt32 getGlyph4(const sal_uInt8 *cmap, const sal_uInt32 nMaxCmapSize, sal_uInt32 c) { sal_uInt16 i; int ToReturn; sal_uInt16 segCount; sal_uInt16 const * startCode; sal_uInt16 const * endCode; sal_uInt16 const * idDelta; /* sal_uInt16 * glyphIdArray; */ sal_uInt16 const * idRangeOffset; /*sal_uInt16 * glyphIndexArray;*/ sal_uInt16 const *CMAP4 = reinterpret_cast(cmap); /* sal_uInt16 GEbinsearch(sal_uInt16 *ar, sal_uInt16 length, sal_uInt16 toSearch); */ segCount = Int16FromMOTA(*(CMAP4 + 3))/2; endCode = CMAP4 + 7; i = GEbinsearch(endCode, segCount, static_cast(c)); if (i == sal_uInt16(0xFFFF)) { return MISSING_GLYPH_INDEX; } startCode = endCode + segCount + 1; if((reinterpret_cast(&startCode[i]) - cmap >= int(nMaxCmapSize - 2)) || Int16FromMOTA(startCode[i]) > c) { return MISSING_GLYPH_INDEX; } idDelta = startCode + segCount; idRangeOffset = idDelta + segCount; /*glyphIndexArray = idRangeOffset + segCount;*/ if((reinterpret_cast(&idRangeOffset[i]) - cmap < int(nMaxCmapSize - 2)) && Int16FromMOTA(idRangeOffset[i]) != 0) { sal_uInt16 const * pGlyphOffset = &(idRangeOffset[i]) + (Int16FromMOTA(idRangeOffset[i])/2 + (c - Int16FromMOTA(startCode[i]))); if(reinterpret_cast(pGlyphOffset) - cmap >= int(nMaxCmapSize - 2)) return MISSING_GLYPH_INDEX; c = Int16FromMOTA(*pGlyphOffset); } ToReturn = (Int16FromMOTA(idDelta[i]) + c) & 0xFFFF; return ToReturn; } static sal_uInt32 getGlyph12(const sal_uInt8 *pCmap, sal_uInt32, sal_uInt32 cChar) { const sal_uInt32* pCMAP12 = reinterpret_cast(pCmap); int nLength = Int32FromMOTA( pCMAP12[1] ); int nGroups = Int32FromMOTA( pCMAP12[3] ); int nLower = 0; int nUpper = nGroups; if( nUpper > (nLength-16)/12 ) nUpper = (nLength-16)/12; /* binary search in "segmented coverage" subtable */ while( nLower < nUpper ) { int nIndex = (nLower + nUpper) / 2; const sal_uInt32* pEntry = &pCMAP12[ 4 + 3*nIndex ]; sal_uInt32 cStart = Int32FromMOTA( pEntry[0] ); sal_uInt32 cLast = Int32FromMOTA( pEntry[1] ); if( cChar < cStart ) nUpper = nIndex; else if( cChar > cLast ) nLower = nIndex + 1; else { /* found matching entry! */ sal_uInt32 nGlyph = Int32FromMOTA( pEntry[2] ); nGlyph += cChar - cStart; return nGlyph; } } return MISSING_GLYPH_INDEX; } static void FindCmap(TrueTypeFont *ttf) { const sal_uInt8* table = getTable(ttf, O_cmap); sal_uInt32 table_size = getTableSize(ttf, O_cmap); if (table_size < 4) { SAL_WARN("vcl.fonts", "Parsing error in " << OUString::createFromAscii(ttf->fname) << "cmap table size too short"); return; } sal_uInt16 ncmaps = GetUInt16(table, 2); sal_uInt32 AppleUni = 0; // Apple Unicode sal_uInt32 ThreeZero = 0; /* MS Symbol */ sal_uInt32 ThreeOne = 0; /* MS UCS-2 */ sal_uInt32 ThreeTwo = 0; /* MS ShiftJIS */ sal_uInt32 ThreeThree = 0; /* MS Big5 */ sal_uInt32 ThreeFour = 0; /* MS PRC */ sal_uInt32 ThreeFive = 0; /* MS Wansung */ sal_uInt32 ThreeSix = 0; /* MS Johab */ const sal_uInt32 remaining_table_size = table_size-4; const sal_uInt32 nMinRecordSize = 8; const sal_uInt32 nMaxRecords = remaining_table_size / nMinRecordSize; if (ncmaps > nMaxRecords) { SAL_WARN("vcl.fonts", "Parsing error in " << OUString::createFromAscii(ttf->fname) << ": " << nMaxRecords << " max possible entries, but " << ncmaps << " claimed, truncating"); ncmaps = nMaxRecords; } for (unsigned int i = 0; i < ncmaps; i++) { /* sanity check, cmap entry must lie within table */ sal_uInt32 nLargestFixedOffsetPos = 8 + i * 8; sal_uInt32 nMinSize = nLargestFixedOffsetPos + sizeof(sal_uInt32); if (nMinSize > table_size) { SAL_WARN( "vcl.fonts", "Font " << OUString::createFromAscii(ttf->fname) << " claimed to have " << ncmaps << " cmaps, but only space for " << i); break; } sal_uInt16 pID = GetUInt16(table, 4 + i * 8); sal_uInt16 eID = GetUInt16(table, 6 + i * 8); sal_uInt32 offset = GetUInt32(table, nLargestFixedOffsetPos); /* sanity check, cmap must lie within file */ if( (table - ttf->ptr) + offset > static_cast(ttf->fsize) ) continue; /* Unicode tables in Apple fonts */ if (pID == 0) { AppleUni = offset; } if (pID == 3) { switch (eID) { case 0: ThreeZero = offset; break; case 10: // UCS-4 case 1: ThreeOne = offset; break; case 2: ThreeTwo = offset; break; case 3: ThreeThree = offset; break; case 4: ThreeFour = offset; break; case 5: ThreeFive = offset; break; case 6: ThreeSix = offset; break; } } } // fall back to AppleUnicode if there are no ThreeOne/Threezero tables if( AppleUni && !ThreeZero && !ThreeOne) ThreeOne = AppleUni; if (ThreeOne) { ttf->cmapType = CMAP_MS_Unicode; ttf->cmap = table + ThreeOne; } else if (ThreeTwo) { ttf->cmapType = CMAP_MS_ShiftJIS; ttf->cmap = table + ThreeTwo; } else if (ThreeThree) { ttf->cmapType = CMAP_MS_Big5; ttf->cmap = table + ThreeThree; } else if (ThreeFour) { ttf->cmapType = CMAP_MS_PRC; ttf->cmap = table + ThreeFour; } else if (ThreeFive) { ttf->cmapType = CMAP_MS_Wansung; ttf->cmap = table + ThreeFive; } else if (ThreeSix) { ttf->cmapType = CMAP_MS_Johab; ttf->cmap = table + ThreeSix; } else if (ThreeZero) { ttf->cmapType = CMAP_MS_Symbol; ttf->cmap = table + ThreeZero; } else { ttf->cmapType = CMAP_NOT_USABLE; ttf->cmap = nullptr; } if (ttf->cmapType != CMAP_NOT_USABLE) { if( (ttf->cmap - ttf->ptr + 2U) > static_cast(ttf->fsize) ) { ttf->cmapType = CMAP_NOT_USABLE; ttf->cmap = nullptr; } } if (ttf->cmapType != CMAP_NOT_USABLE) { switch (GetUInt16(ttf->cmap, 0)) { case 0: ttf->mapper = getGlyph0; break; case 2: ttf->mapper = getGlyph2; break; case 4: ttf->mapper = getGlyph4; break; case 6: ttf->mapper = getGlyph6; break; case 12: ttf->mapper= getGlyph12; break; default: #if OSL_DEBUG_LEVEL > 1 /*- if the cmap table is really broken */ printf("%s: %d is not a recognized cmap format.\n", ttf->fname, GetUInt16(ttf->cmap, 0)); #endif ttf->cmapType = CMAP_NOT_USABLE; ttf->cmap = nullptr; ttf->mapper = nullptr; } } } /*- Public functions */ int CountTTCFonts(const char* fname) { int nFonts = 0; sal_uInt8 buffer[12]; FILE* fd = fopen(fname, "rb"); if( fd ) { if (fread(buffer, 1, 12, fd) == 12) { if(GetUInt32(buffer, 0) == T_ttcf ) nFonts = GetUInt32(buffer, 8); } fclose(fd); } return nFonts; } static void allocTrueTypeFont( TrueTypeFont** ttf ) { *ttf = static_cast(calloc(1,sizeof(TrueTypeFont))); if( *ttf != nullptr ) { (*ttf)->fname = nullptr; (*ttf)->fsize = -1; (*ttf)->ptr = nullptr; (*ttf)->nglyphs = 0xFFFFFFFF; } } /* forward declaration for the two entry points to use*/ static SFErrCodes doOpenTTFont( sal_uInt32 facenum, TrueTypeFont* t ); #if !defined(_WIN32) SFErrCodes OpenTTFontFile( const char* fname, sal_uInt32 facenum, TrueTypeFont** ttf ) { SFErrCodes ret; int fd = -1; struct stat st; if (!fname || !*fname) return SFErrCodes::BadFile; allocTrueTypeFont( ttf ); if( ! *ttf ) return SFErrCodes::Memory; (*ttf)->fname = strdup(fname); if( ! (*ttf)->fname ) { ret = SFErrCodes::Memory; goto cleanup; } fd = open(fname, O_RDONLY); if (fd == -1) { ret = SFErrCodes::BadFile; goto cleanup; } if (fstat(fd, &st) == -1) { ret = SFErrCodes::FileIo; goto cleanup; } (*ttf)->fsize = st.st_size; /* On Mac OS, most likely will happen if a Mac user renames a font file * to be .ttf when its really a Mac resource-based font. * Size will be 0, but fonts smaller than 4 bytes would be broken anyway. */ if ((*ttf)->fsize == 0) { ret = SFErrCodes::BadFile; goto cleanup; } if (((*ttf)->ptr = static_cast(mmap(nullptr, (*ttf)->fsize, PROT_READ, MAP_SHARED, fd, 0))) == MAP_FAILED) { ret = SFErrCodes::Memory; goto cleanup; } close(fd); return doOpenTTFont( facenum, *ttf ); cleanup: if (fd != -1) close(fd); /*- t and t->fname have been allocated! */ free((*ttf)->fname); free(*ttf); *ttf = nullptr; return ret; } #endif SFErrCodes OpenTTFontBuffer(const void* pBuffer, sal_uInt32 nLen, sal_uInt32 facenum, TrueTypeFont** ttf) { allocTrueTypeFont( ttf ); if( *ttf == nullptr ) return SFErrCodes::Memory; (*ttf)->fname = nullptr; (*ttf)->fsize = nLen; (*ttf)->ptr = const_cast(static_cast(pBuffer)); return doOpenTTFont( facenum, *ttf ); } namespace { bool withinBounds(sal_uInt32 tdoffset, sal_uInt32 moreoffset, sal_uInt32 len, sal_uInt32 available) { sal_uInt32 result; if (o3tl::checked_add(tdoffset, moreoffset, result)) return false; if (o3tl::checked_add(result, len, result)) return false; return result <= available; } class TTFontCloser { TrueTypeFont* m_font; public: TTFontCloser(TrueTypeFont* t) : m_font(t) { } void clear() { m_font = nullptr; } ~TTFontCloser() { if (m_font) CloseTTFont(m_font); } }; } static SFErrCodes doOpenTTFont( sal_uInt32 facenum, TrueTypeFont* t ) { TTFontCloser aCloseGuard(t); if (t->fsize < 4) { return SFErrCodes::TtFormat; } int i; sal_uInt32 length, tag; sal_uInt32 tdoffset = 0; /* offset to TableDirectory in a TTC file. For TTF files is 0 */ sal_uInt32 TTCTag = GetInt32(t->ptr, 0); if ((TTCTag == 0x00010000) || (TTCTag == T_true)) { tdoffset = 0; } else if (TTCTag == T_otto) { /* PS-OpenType font */ tdoffset = 0; } else if (TTCTag == T_ttcf) { /* TrueType collection */ if (!withinBounds(12, 4 * facenum, sizeof(sal_uInt32), t->fsize)) { return SFErrCodes::FontNo; } sal_uInt32 Version = GetUInt32(t->ptr, 4); if (Version != 0x00010000 && Version != 0x00020000) { return SFErrCodes::TtFormat; } if (facenum >= GetUInt32(t->ptr, 8)) { return SFErrCodes::FontNo; } tdoffset = GetUInt32(t->ptr, 12 + 4 * facenum); } else { return SFErrCodes::TtFormat; } if (withinBounds(tdoffset, 0, 4 + sizeof(sal_uInt16), t->fsize)) { t->ntables = GetUInt16(t->ptr + tdoffset, 4); } if (t->ntables >= 128 || t->ntables == 0) { return SFErrCodes::TtFormat; } t->tables = static_cast(calloc(NUM_TAGS, sizeof(sal_uInt8 *))); assert(t->tables != nullptr); t->tlens = static_cast(calloc(NUM_TAGS, sizeof(sal_uInt32))); assert(t->tlens != nullptr); /* parse the tables */ for (i=0; i(t->ntables); i++) { int nIndex; const sal_uInt32 nStart = tdoffset + 12; const sal_uInt32 nOffset = 16 * i; if (withinBounds(nStart, nOffset, sizeof(sal_uInt32), t->fsize)) tag = GetUInt32(t->ptr + nStart, nOffset); else tag = static_cast(-1); switch( tag ) { case T_maxp: nIndex = O_maxp; break; case T_glyf: nIndex = O_glyf; break; case T_head: nIndex = O_head; break; case T_loca: nIndex = O_loca; break; case T_name: nIndex = O_name; break; case T_hhea: nIndex = O_hhea; break; case T_hmtx: nIndex = O_hmtx; break; case T_cmap: nIndex = O_cmap; break; case T_vhea: nIndex = O_vhea; break; case T_vmtx: nIndex = O_vmtx; break; case T_OS2 : nIndex = O_OS2; break; case T_post: nIndex = O_post; break; case T_cvt : nIndex = O_cvt; break; case T_prep: nIndex = O_prep; break; case T_fpgm: nIndex = O_fpgm; break; case T_gsub: nIndex = O_gsub; break; case T_CFF: nIndex = O_CFF; break; default: nIndex = -1; break; } if ((nIndex >= 0) && withinBounds(nStart, nOffset, 12 + sizeof(sal_uInt32), t->fsize)) { sal_uInt32 nTableOffset = GetUInt32(t->ptr + nStart, nOffset + 8); length = GetUInt32(t->ptr + nStart, nOffset + 12); t->tables[nIndex] = t->ptr + nTableOffset; t->tlens[nIndex] = length; } } /* Fixup offsets when only a TTC extract was provided */ if( facenum == sal_uInt32(~0) ) { sal_uInt8* pHead = const_cast(t->tables[O_head]); if (!pHead) { return SFErrCodes::TtFormat; } /* limit Head candidate to TTC extract's limits */ if( pHead > t->ptr + (t->fsize - 54) ) pHead = t->ptr + (t->fsize - 54); /* TODO: find better method than searching head table's magic */ sal_uInt8* p = nullptr; for( p = pHead + 12; p > t->ptr; --p ) { if( p[0]==0x5F && p[1]==0x0F && p[2]==0x3C && p[3]==0xF5 ) { int nDelta = (pHead + 12) - p; if( nDelta ) for( int j = 0; j < NUM_TAGS; ++j ) if( t->tables[j] ) *reinterpret_cast(&t->tables[j]) -= nDelta; break; } } if (p <= t->ptr) { return SFErrCodes::TtFormat; } } /* Check the table offsets after TTC correction */ for (i=0; itables[i] < t->ptr ) { #if OSL_DEBUG_LEVEL > 1 if( t->tables[i] ) fprintf( stderr, "font file %s has bad table offset %" SAL_PRI_PTRDIFFT "d (tagnum=%d)\n", t->fname, (sal_uInt8*)t->tables[i]-t->ptr, i ); #endif t->tlens[i] = 0; t->tables[i] = nullptr; } else if( const_cast(t->tables[i]) + t->tlens[i] > t->ptr + t->fsize ) { sal_PtrDiff nMaxLen = (t->ptr + t->fsize) - t->tables[i]; if( nMaxLen < 0 ) nMaxLen = 0; t->tlens[i] = nMaxLen; #if OSL_DEBUG_LEVEL > 1 fprintf( stderr, "font file %s has too big table (tagnum=%d)\n", t->fname, i ); #endif } } /* At this point TrueTypeFont is constructed, now need to verify the font format and read the basic font properties */ /* The following tables are absolutely required: * maxp, head, name, cmap */ if( !(getTable(t, O_maxp) && getTable(t, O_head) && getTable(t, O_name) && getTable(t, O_cmap)) ) { return SFErrCodes::TtFormat; } const sal_uInt8* table = getTable(t, O_maxp); sal_uInt32 table_size = getTableSize(t, O_maxp); t->nglyphs = table_size >= 6 ? GetUInt16(table, 4) : 0; table = getTable(t, O_head); table_size = getTableSize(t, O_head); if (table_size < 52) { return SFErrCodes::TtFormat; } t->unitsPerEm = GetUInt16(table, 18); int indexfmt = GetInt16(table, 50); if( ((indexfmt != 0) && (indexfmt != 1)) || (t->unitsPerEm <= 0) ) { return SFErrCodes::TtFormat; } if( getTable(t, O_glyf) && getTable(t, O_loca) ) /* TTF or TTF-OpenType */ { int k = (getTableSize(t, O_loca) / (indexfmt ? 4 : 2)) - 1; if( k < static_cast(t->nglyphs) ) /* Hack for broken Chinese fonts */ t->nglyphs = k; table = getTable(t, O_loca); t->goffsets = static_cast(calloc(1+t->nglyphs, sizeof(sal_uInt32))); assert(t->goffsets != nullptr); for( i = 0; i <= static_cast(t->nglyphs); ++i ) t->goffsets[i] = indexfmt ? GetUInt32(table, i << 2) : static_cast(GetUInt16(table, i << 1)) << 1; } else if( getTable(t, O_CFF) ) { /* PS-OpenType */ int k = (getTableSize(t, O_CFF) / 2) - 1; /* set a limit here, presumably much lower than the table size, but establishes some sort of physical bound */ if( k < static_cast(t->nglyphs) ) t->nglyphs = k; t->goffsets = static_cast(calloc(1+t->nglyphs, sizeof(sal_uInt32))); /* TODO: implement to get subsetting */ assert(t->goffsets != nullptr); } else { return SFErrCodes::TtFormat; } table = getTable(t, O_hhea); table_size = getTableSize(t, O_hhea); t->numberOfHMetrics = (table && table_size >= 36) ? GetUInt16(table, 34) : 0; table = getTable(t, O_vhea); table_size = getTableSize(t, O_vhea); t->numOfLongVerMetrics = (table && table_size >= 36) ? GetUInt16(table, 34) : 0; GetNames(t); FindCmap(t); aCloseGuard.clear(); return SFErrCodes::Ok; } void CloseTTFont(TrueTypeFont *ttf) { #if !defined(_WIN32) if( ttf->fname ) munmap(ttf->ptr, ttf->fsize); #endif free(ttf->fname); free(ttf->goffsets); free(ttf->psname); free(ttf->family); if( ttf->ufamily ) free( ttf->ufamily ); free(ttf->subfamily); if( ttf->usubfamily ) free( ttf->usubfamily ); free(ttf->tables); free(ttf->tlens); free(ttf); } int GetTTGlyphPoints(TrueTypeFont *ttf, sal_uInt32 glyphID, ControlPoint **pointArray) { return GetTTGlyphOutline(ttf, glyphID, pointArray, nullptr, nullptr); } int GetTTGlyphComponents(TrueTypeFont *ttf, sal_uInt32 glyphID, std::vector< sal_uInt32 >& glyphlist) { int n = 1; if( glyphID >= ttf->nglyphs ) return 0; const sal_uInt8* glyf = getTable(ttf, O_glyf); const sal_uInt8* ptr = glyf + ttf->goffsets[glyphID]; const sal_uInt8* nptr = glyf + ttf->goffsets[glyphID+1]; if (nptr <= ptr) return 0; glyphlist.push_back( glyphID ); if (GetInt16(ptr, 0) == -1) { sal_uInt16 flags, index; ptr += 10; do { flags = GetUInt16(ptr, 0); index = GetUInt16(ptr, 2); ptr += 4; n += GetTTGlyphComponents(ttf, index, glyphlist); if (flags & ARG_1_AND_2_ARE_WORDS) { ptr += 4; } else { ptr += 2; } if (flags & WE_HAVE_A_SCALE) { ptr += 2; } else if (flags & WE_HAVE_AN_X_AND_Y_SCALE) { ptr += 4; } else if (flags & WE_HAVE_A_TWO_BY_TWO) { ptr += 8; } } while (flags & MORE_COMPONENTS); } return n; } SFErrCodes CreateT3FromTTGlyphs(TrueTypeFont *ttf, FILE *outf, const char *fname, sal_uInt16 const *glyphArray, sal_uInt8 *encoding, int nGlyphs, int wmode) { ControlPoint *pa; PSPathElement *path; int i, j, n; const sal_uInt8* table = getTable(ttf, O_head); TTGlyphMetrics metrics; int UPEm = ttf->unitsPerEm; const char * const h01 = "%%!PS-AdobeFont-%d.%d-%d.%d\n"; const char * const h02 = "%% Creator: %s %s %s\n"; const char * const h09 = "%% Original font name: %s\n"; const char * const h10 = "30 dict begin\n" "/PaintType 0 def\n" "/FontType 3 def\n" "/StrokeWidth 0 def\n"; const char * const h11 = "/FontName (%s) cvn def\n"; /* const char *h12 = "%/UniqueID %d def\n"; */ const char * const h13 = "/FontMatrix [.001 0 0 .001 0 0] def\n"; const char * const h14 = "/FontBBox [%d %d %d %d] def\n"; const char * const h15= "/Encoding 256 array def\n" " 0 1 255 {Encoding exch /.notdef put} for\n"; const char * const h16 = " Encoding %d /glyph%d put\n"; const char * const h17 = "/XUID [103 0 0 16#%08" SAL_PRIXUINT32 " %d 16#%08" SAL_PRIXUINT32 " 16#%08" SAL_PRIXUINT32 "] def\n"; const char * const h30 = "/CharProcs %d dict def\n"; const char * const h31 = " CharProcs begin\n"; const char * const h32 = " /.notdef {} def\n"; const char * const h33 = " /glyph%d {\n"; const char * const h34 = " } bind def\n"; const char * const h35 = " end\n"; const char * const h40 = "/BuildGlyph {\n" " exch /CharProcs get exch\n" " 2 copy known not\n" " {pop /.notdef} if\n" " get exec\n" "} bind def\n" "/BuildChar {\n" " 1 index /Encoding get exch get\n" " 1 index /BuildGlyph get exec\n" "} bind def\n" "currentdict end\n"; const char * const h41 = "(%s) cvn exch definefont pop\n"; if (!((nGlyphs > 0) && (nGlyphs <= 256))) return SFErrCodes::GlyphNum; if (!glyphArray) return SFErrCodes::BadArg; if (!fname) fname = ttf->psname; fprintf(outf, h01, GetInt16(table, 0), GetUInt16(table, 2), GetInt16(table, 4), GetUInt16(table, 6)); fprintf(outf, h02, modname, modver, modextra); fprintf(outf, h09, ttf->psname); fprintf(outf, "%s", h10); fprintf(outf, h11, fname); /* fprintf(outf, h12, 4000000); */ /* XUID generation: * 103 0 0 C1 C2 C3 C4 * C1 - CRC-32 of the entire source TrueType font * C2 - number of glyphs in the subset * C3 - CRC-32 of the glyph array * C4 - CRC-32 of the encoding array * * All CRC-32 numbers are presented as hexadecimal numbers */ fprintf(outf, h17, rtl_crc32(0, ttf->ptr, ttf->fsize), nGlyphs, rtl_crc32(0, glyphArray, nGlyphs * 2), rtl_crc32(0, encoding, nGlyphs)); fprintf(outf, "%s", h13); fprintf(outf, h14, XUnits(UPEm, GetInt16(table, 36)), XUnits(UPEm, GetInt16(table, 38)), XUnits(UPEm, GetInt16(table, 40)), XUnits(UPEm, GetInt16(table, 42))); fprintf(outf, "%s", h15); for (i = 0; i < nGlyphs; i++) { fprintf(outf, h16, encoding[i], i); } fprintf(outf, h30, nGlyphs+1); fprintf(outf, "%s", h31); fprintf(outf, "%s", h32); for (i = 0; i < nGlyphs; i++) { fprintf(outf, h33, i); int r = GetTTGlyphOutline(ttf, glyphArray[i] < ttf->nglyphs ? glyphArray[i] : 0, &pa, &metrics, nullptr); if (r > 0) { n = BSplineToPSPath(pa, r, &path); } else { n = 0; /* glyph might have zero contours but valid metrics ??? */ path = nullptr; if (r < 0) { /* glyph is not present in the font - pa array was not allocated, so no need to free it */ continue; } } fprintf(outf, "\t%d %d %d %d %d %d setcachedevice\n", wmode == 0 ? XUnits(UPEm, metrics.aw) : 0, wmode == 0 ? 0 : -XUnits(UPEm, metrics.ah), XUnits(UPEm, metrics.xMin), XUnits(UPEm, metrics.yMin), XUnits(UPEm, metrics.xMax), XUnits(UPEm, metrics.yMax)); for (j = 0; j < n; j++) { switch (path[j].type) { case PS_MOVETO: fprintf(outf, "\t%d %d moveto\n", XUnits(UPEm, path[j].x1), XUnits(UPEm, path[j].y1)); break; case PS_LINETO: fprintf(outf, "\t%d %d lineto\n", XUnits(UPEm, path[j].x1), XUnits(UPEm, path[j].y1)); break; case PS_CURVETO: fprintf(outf, "\t%d %d %d %d %d %d curveto\n", XUnits(UPEm, path[j].x1), XUnits(UPEm, path[j].y1), XUnits(UPEm, path[j].x2), XUnits(UPEm, path[j].y2), XUnits(UPEm, path[j].x3), XUnits(UPEm, path[j].y3)); break; case PS_CLOSEPATH: fprintf(outf, "\tclosepath\n"); break; case PS_NOOP: break; } } if (n > 0) fprintf(outf, "\tfill\n"); /* if glyph is not a whitespace character */ fprintf(outf, "%s", h34); free(pa); free(path); } fprintf(outf, "%s", h35); fprintf(outf, "%s", h40); fprintf(outf, h41, fname); return SFErrCodes::Ok; } SFErrCodes CreateTTFromTTGlyphs(TrueTypeFont *ttf, const char *fname, sal_uInt16 const *glyphArray, sal_uInt8 const *encoding, int nGlyphs) { TrueTypeCreator *ttcr; TrueTypeTable *head=nullptr, *hhea=nullptr, *maxp=nullptr, *cvt=nullptr, *prep=nullptr, *glyf=nullptr, *fpgm=nullptr, *cmap=nullptr, *name=nullptr, *post = nullptr, *os2 = nullptr; int i; SFErrCodes res; TrueTypeCreatorNewEmpty(T_true, &ttcr); /** name **/ NameRecord *names; int n = GetTTNameRecords(ttf, &names); name = TrueTypeTableNew_name(n, names); DisposeNameRecords(names, n); /** maxp **/ maxp = TrueTypeTableNew_maxp(getTable(ttf, O_maxp), getTableSize(ttf, O_maxp)); /** hhea **/ const sal_uInt8* p = getTable(ttf, O_hhea); if (p) { hhea = TrueTypeTableNew_hhea(GetUInt16(p, 4), GetUInt16(p, 6), GetUInt16(p, 8), GetUInt16(p, 18), GetUInt16(p, 20)); } else { hhea = TrueTypeTableNew_hhea(0, 0, 0, 0, 0); } /** head **/ p = getTable(ttf, O_head); assert(p != nullptr); head = TrueTypeTableNew_head(GetUInt32(p, 4), GetUInt16(p, 16), GetUInt16(p, 18), p+20, GetUInt16(p, 44), GetUInt16(p, 46), GetInt16(p, 48)); /** glyf **/ glyf = TrueTypeTableNew_glyf(); sal_uInt32* gID = static_cast(scalloc(nGlyphs, sizeof(sal_uInt32))); for (i = 0; i < nGlyphs; i++) { gID[i] = glyfAdd(glyf, GetTTRawGlyphData(ttf, glyphArray[i]), ttf); } /** cmap **/ cmap = TrueTypeTableNew_cmap(); for (i=0; i < nGlyphs; i++) { cmapAdd(cmap, 0x010000, encoding[i], gID[i]); } /** cvt **/ if ((p = getTable(ttf, O_cvt)) != nullptr) { cvt = TrueTypeTableNew(T_cvt, getTableSize(ttf, O_cvt), p); } /** prep **/ if ((p = getTable(ttf, O_prep)) != nullptr) { prep = TrueTypeTableNew(T_prep, getTableSize(ttf, O_prep), p); } /** fpgm **/ if ((p = getTable(ttf, O_fpgm)) != nullptr) { fpgm = TrueTypeTableNew(T_fpgm, getTableSize(ttf, O_fpgm), p); } /** post **/ if ((p = getTable(ttf, O_post)) != nullptr) { post = TrueTypeTableNew_post(0x00030000, GetUInt32(p, 4), GetUInt16(p, 8), GetUInt16(p, 10), GetUInt16(p, 12)); } else { post = TrueTypeTableNew_post(0x00030000, 0, 0, 0, 0); } AddTable(ttcr, name); AddTable(ttcr, maxp); AddTable(ttcr, hhea); AddTable(ttcr, head); AddTable(ttcr, glyf); AddTable(ttcr, cmap); AddTable(ttcr, cvt ); AddTable(ttcr, prep); AddTable(ttcr, fpgm); AddTable(ttcr, post); AddTable(ttcr, os2); if ((res = StreamToFile(ttcr, fname)) != SFErrCodes::Ok) { #if OSL_DEBUG_LEVEL > 1 fprintf(stderr, "StreamToFile: error code: %d.\n", int(res)); #endif } TrueTypeCreatorDispose(ttcr); free(gID); return res; } static GlyphOffsets *GlyphOffsetsNew(sal_uInt8 *sfntP, sal_uInt32 sfntLen) { GlyphOffsets* res = static_cast(smalloc(sizeof(GlyphOffsets))); sal_uInt8 *loca = nullptr; sal_uInt16 numTables = GetUInt16(sfntP, 4); sal_uInt32 locaLen = 0; sal_Int16 indexToLocFormat = 0; sal_uInt32 nMaxPossibleTables = sfntLen / (3*sizeof(sal_uInt32)); /*the three GetUInt32 calls*/ if (numTables > nMaxPossibleTables) { SAL_WARN( "vcl.fonts", "GlyphOffsetsNew claimed to have " << numTables << " tables, but that's impossibly large"); numTables = nMaxPossibleTables; } for (sal_uInt16 i = 0; i < numTables; i++) { sal_uInt32 nLargestFixedOffsetPos = 12 + 16 * i + 12; sal_uInt32 nMinSize = nLargestFixedOffsetPos + sizeof(sal_uInt32); if (nMinSize > sfntLen) { SAL_WARN( "vcl.fonts", "GlyphOffsetsNew claimed to have " << numTables << " tables, but only space for " << i); break; } sal_uInt32 tag = GetUInt32(sfntP, 12 + 16 * i); sal_uInt32 off = GetUInt32(sfntP, 12 + 16 * i + 8); sal_uInt32 len = GetUInt32(sfntP, nLargestFixedOffsetPos); if (tag == T_loca) { loca = sfntP + off; locaLen = len; } else if (tag == T_head) { indexToLocFormat = GetInt16(sfntP + off, 50); } } res->nGlyphs = locaLen / ((indexToLocFormat == 1) ? 4 : 2); assert(res->nGlyphs != 0); res->offs = static_cast(scalloc(res->nGlyphs, sizeof(sal_uInt32))); for (sal_uInt32 i = 0; i < res->nGlyphs; i++) { if (indexToLocFormat == 1) { res->offs[i] = GetUInt32(loca, i * 4); } else { res->offs[i] = GetUInt16(loca, i * 2) << 1; } } return res; } static void GlyphOffsetsDispose(GlyphOffsets *_this) { if (_this) { free(_this->offs); free(_this); } } static void DumpSfnts(FILE *outf, sal_uInt8 *sfntP, sal_uInt32 sfntLen) { if (sfntLen < 12) { SAL_WARN( "vcl.fonts", "DumpSfnts sfntLen is too short: " << sfntLen << " legal min is: " << 12); return; } const sal_uInt32 nSpaceForTables = sfntLen - 12; const sal_uInt32 nTableSize = 16; const sal_uInt32 nMaxPossibleTables = nSpaceForTables/nTableSize; HexFmt *h = HexFmtNew(outf); sal_uInt16 i, numTables = GetUInt16(sfntP, 4); GlyphOffsets *go = GlyphOffsetsNew(sfntP, sfntLen); sal_uInt8 const pad[] = {0,0,0,0}; /* zeroes */ if (numTables > nMaxPossibleTables) { SAL_WARN( "vcl.fonts", "DumpSfnts claimed to have " << numTables << " tables, but only space for " << nMaxPossibleTables); numTables = nMaxPossibleTables; } assert(numTables <= 9); /* Type42 has 9 required tables */ sal_uInt32* offs = static_cast(scalloc(numTables, sizeof(sal_uInt32))); fputs("/sfnts [", outf); HexFmtOpenString(h); HexFmtBlockWrite(h, sfntP, 12); /* stream out the Offset Table */ HexFmtBlockWrite(h, sfntP+12, 16 * numTables); /* stream out the Table Directory */ for (i=0; i sfntLen) { SAL_WARN( "vcl.fonts", "DumpSfnts claimed to have " << numTables << " tables, but only space for " << i); break; } sal_uInt32 tag = GetUInt32(sfntP, 12 + 16 * i); sal_uInt32 off = GetUInt32(sfntP, 12 + 16 * i + 8); if (off > sfntLen) { SAL_WARN( "vcl.fonts", "DumpSfnts claims offset of " << off << " but max possible is " << sfntLen); break; } sal_uInt8 *pRecordStart = sfntP + off; sal_uInt32 len = GetUInt32(sfntP, nLargestFixedOffsetPos); sal_uInt32 nMaxLenPossible = sfntLen - off; if (len > nMaxLenPossible) { SAL_WARN( "vcl.fonts", "DumpSfnts claims len of " << len << " but only space for " << nMaxLenPossible); break; } if (tag != T_glyf) { HexFmtBlockWrite(h, pRecordStart, len); } else { sal_uInt8 *glyf = pRecordStart; for (sal_uInt32 j = 0; j < go->nGlyphs - 1; j++) { sal_uInt32 o = go->offs[j]; sal_uInt32 l = go->offs[j + 1] - o; HexFmtBlockWrite(h, glyf + o, l); } } HexFmtBlockWrite(h, pad, (4 - (len & 3)) & 3); } HexFmtCloseString(h); fputs("] def\n", outf); GlyphOffsetsDispose(go); HexFmtDispose(h); free(offs); } SFErrCodes CreateT42FromTTGlyphs(TrueTypeFont *ttf, FILE *outf, const char *psname, sal_uInt16 const *glyphArray, sal_uInt8 *encoding, int nGlyphs) { TrueTypeCreator *ttcr; TrueTypeTable *head=nullptr, *hhea=nullptr, *maxp=nullptr, *cvt=nullptr, *prep=nullptr, *glyf=nullptr, *fpgm=nullptr; int i; SFErrCodes res; sal_uInt32 ver, rev; sal_uInt8 *sfntP; sal_uInt32 sfntLen; int UPEm = ttf->unitsPerEm; if (nGlyphs >= 256) return SFErrCodes::GlyphNum; assert(psname != nullptr); TrueTypeCreatorNewEmpty(T_true, &ttcr); /* head */ const sal_uInt8* p = getTable(ttf, O_head); const sal_uInt8* headP = p; assert(p != nullptr); head = TrueTypeTableNew_head(GetUInt32(p, 4), GetUInt16(p, 16), GetUInt16(p, 18), p+20, GetUInt16(p, 44), GetUInt16(p, 46), GetInt16(p, 48)); ver = GetUInt32(p, 0); rev = GetUInt32(p, 4); /** hhea **/ p = getTable(ttf, O_hhea); if (p) { hhea = TrueTypeTableNew_hhea(GetUInt16(p, 4), GetUInt16(p, 6), GetUInt16(p, 8), GetUInt16(p, 18), GetUInt16(p, 20)); } else { hhea = TrueTypeTableNew_hhea(0, 0, 0, 0, 0); } /** maxp **/ maxp = TrueTypeTableNew_maxp(getTable(ttf, O_maxp), getTableSize(ttf, O_maxp)); /** cvt **/ if ((p = getTable(ttf, O_cvt)) != nullptr) { cvt = TrueTypeTableNew(T_cvt, getTableSize(ttf, O_cvt), p); } /** prep **/ if ((p = getTable(ttf, O_prep)) != nullptr) { prep = TrueTypeTableNew(T_prep, getTableSize(ttf, O_prep), p); } /** fpgm **/ if ((p = getTable(ttf, O_fpgm)) != nullptr) { fpgm = TrueTypeTableNew(T_fpgm, getTableSize(ttf, O_fpgm), p); } /** glyf **/ glyf = TrueTypeTableNew_glyf(); sal_uInt16* gID = static_cast(scalloc(nGlyphs, sizeof(sal_uInt32))); for (i = 0; i < nGlyphs; i++) { gID[i] = static_cast(glyfAdd(glyf, GetTTRawGlyphData(ttf, glyphArray[i]), ttf)); } AddTable(ttcr, head); AddTable(ttcr, hhea); AddTable(ttcr, maxp); AddTable(ttcr, cvt); AddTable(ttcr, prep); AddTable(ttcr, glyf); AddTable(ttcr, fpgm); if ((res = StreamToMemory(ttcr, &sfntP, &sfntLen)) != SFErrCodes::Ok) { TrueTypeCreatorDispose(ttcr); free(gID); return res; } fprintf(outf, "%%!PS-TrueTypeFont-%d.%d-%d.%d\n", static_cast(ver>>16), static_cast(ver & 0xFFFF), static_cast(rev>>16), static_cast(rev & 0xFFFF)); fprintf(outf, "%%%%Creator: %s %s %s\n", modname, modver, modextra); fprintf(outf, "%%- Font subset generated from a source font file: '%s'\n", ttf->fname); fprintf(outf, "%%- Original font name: %s\n", ttf->psname); fprintf(outf, "%%- Original font family: %s\n", ttf->family); fprintf(outf, "%%- Original font sub-family: %s\n", ttf->subfamily); fprintf(outf, "11 dict begin\n"); fprintf(outf, "/FontName (%s) cvn def\n", psname); fprintf(outf, "/PaintType 0 def\n"); fprintf(outf, "/FontMatrix [1 0 0 1 0 0] def\n"); fprintf(outf, "/FontBBox [%d %d %d %d] def\n", XUnits(UPEm, GetInt16(headP, 36)), XUnits(UPEm, GetInt16(headP, 38)), XUnits(UPEm, GetInt16(headP, 40)), XUnits(UPEm, GetInt16(headP, 42))); fprintf(outf, "/FontType 42 def\n"); fprintf(outf, "/Encoding 256 array def\n"); fprintf(outf, " 0 1 255 {Encoding exch /.notdef put} for\n"); for (i = 1; i(rtl_crc32(0, ttf->ptr, ttf->fsize)), static_cast(nGlyphs), static_cast(rtl_crc32(0, glyphArray, nGlyphs * 2)), static_cast(rtl_crc32(0, encoding, nGlyphs))); DumpSfnts(outf, sfntP, sfntLen); /* dump charstrings */ fprintf(outf, "/CharStrings %d dict dup begin\n", nGlyphs); fprintf(outf, "/.notdef 0 def\n"); for (i = 1; i < static_cast(glyfCount(glyf)); i++) { fprintf(outf,"/glyph%d %d def\n", i, i); } fprintf(outf, "end readonly def\n"); fprintf(outf, "FontName currentdict end definefont pop\n"); TrueTypeCreatorDispose(ttcr); free(gID); free(sfntP); return SFErrCodes::Ok; } #if defined(_WIN32) || defined(MACOSX) || defined(IOS) sal_uInt16 MapChar(TrueTypeFont const *ttf, sal_uInt16 ch) { switch (ttf->cmapType) { case CMAP_MS_Symbol: { const sal_uInt32 nMaxCmapSize = ttf->ptr + ttf->fsize - ttf->cmap; if( ttf->mapper == getGlyph0 && ( ch & 0xf000 ) == 0xf000 ) ch &= 0x00ff; return static_cast(ttf->mapper(ttf->cmap, nMaxCmapSize, ch )); } case CMAP_MS_Unicode: break; case CMAP_MS_ShiftJIS: ch = TranslateChar12(ch); break; case CMAP_MS_Big5: ch = TranslateChar13(ch); break; case CMAP_MS_PRC: ch = TranslateChar14(ch); break; case CMAP_MS_Wansung: ch = TranslateChar15(ch); break; case CMAP_MS_Johab: ch = TranslateChar16(ch); break; default: return 0; } const sal_uInt32 nMaxCmapSize = ttf->ptr + ttf->fsize - ttf->cmap; ch = static_cast(ttf->mapper(ttf->cmap, nMaxCmapSize, ch)); return ch; } #endif int GetTTGlyphCount( TrueTypeFont const * ttf ) { return ttf->nglyphs; } bool GetSfntTable( TrueTypeFont const * ttf, int nSubtableIndex, const sal_uInt8** ppRawBytes, int* pRawLength ) { if( (nSubtableIndex < 0) || (nSubtableIndex >= NUM_TAGS) ) return false; *pRawLength = ttf->tlens[ nSubtableIndex ]; *ppRawBytes = ttf->tables[ nSubtableIndex ]; bool bOk = (*pRawLength > 0) && (*ppRawBytes != nullptr); return bOk; } std::unique_ptr GetTTSimpleGlyphMetrics(TrueTypeFont const *ttf, const sal_uInt16 *glyphArray, int nGlyphs, bool vertical) { const sal_uInt8* pTable; sal_uInt32 n; int nTableSize; if (!vertical) { n = ttf->numberOfHMetrics; pTable = getTable( ttf, O_hmtx ); nTableSize = getTableSize( ttf, O_hmtx ); } else { n = ttf->numOfLongVerMetrics; pTable = getTable( ttf, O_vmtx ); nTableSize = getTableSize( ttf, O_vmtx ); } if (!nGlyphs || !glyphArray) return nullptr; /* invalid parameters */ if (!n || !pTable) return nullptr; /* the font does not contain the requested metrics */ std::unique_ptr res(new sal_uInt16[nGlyphs]); const int UPEm = ttf->unitsPerEm; for( int i = 0; i < nGlyphs; ++i) { int nAdvOffset; sal_uInt16 glyphID = glyphArray[i]; if (glyphID < n) { nAdvOffset = 4 * glyphID; } else { nAdvOffset = 4 * (n - 1); } if( nAdvOffset >= nTableSize) res[i] = 0; /* better than a crash for buggy fonts */ else res[i] = static_cast( XUnits( UPEm, GetUInt16( pTable, nAdvOffset) ) ); } return res; } // TODO, clean up table parsing and re-use it elsewhere in this file. void GetTTFontMetrics(const std::vector& hhea, const std::vector& os2, TTGlobalFontInfo *info) { /* There are 3 different versions of OS/2 table: original (68 bytes long), * Microsoft old (78 bytes long) and Microsoft new (86 bytes long,) * Apple's documentation recommends looking at the table length. * * FIXME: horribly outdated comment and horrible code that uses hard-coded * offsets to read the table. */ if (os2.size() >= 76 + 2) { info->fsSelection = GetUInt16(os2.data(), 62); info->typoAscender = GetInt16(os2.data(), 68); info->typoDescender = GetInt16(os2.data(), 70); info->typoLineGap = GetInt16(os2.data(), 72); info->winAscent = GetUInt16(os2.data(), 74); info->winDescent = GetUInt16(os2.data(), 76); } if (hhea.size() >= 8 + 2) { info->ascender = GetInt16(hhea.data(), 4); info->descender = GetInt16(hhea.data(), 6); info->linegap = GetInt16(hhea.data(), 8); } } void GetTTGlobalFontInfo(TrueTypeFont *ttf, TTGlobalFontInfo *info) { int UPEm = ttf->unitsPerEm; memset(info, 0, sizeof(TTGlobalFontInfo)); info->family = ttf->family; info->ufamily = ttf->ufamily; info->subfamily = ttf->subfamily; info->usubfamily = ttf->usubfamily; info->psname = ttf->psname; info->symbolEncoded = (ttf->cmapType == CMAP_MS_Symbol); const sal_uInt8* table = getTable(ttf, O_OS2); sal_uInt32 table_size = getTableSize(ttf, O_OS2); if (table && table_size >= 42) { info->weight = GetUInt16(table, 4); info->width = GetUInt16(table, 6); /* There are 3 different versions of OS/2 table: original (68 bytes long), * Microsoft old (78 bytes long) and Microsoft new (86 bytes long,) * Apple's documentation recommends looking at the table length. */ if (table_size >= 78) { info->typoAscender = XUnits(UPEm,GetInt16(table, 68)); info->typoDescender = XUnits(UPEm, GetInt16(table, 70)); info->typoLineGap = XUnits(UPEm, GetInt16(table, 72)); info->winAscent = XUnits(UPEm, GetUInt16(table, 74)); info->winDescent = XUnits(UPEm, GetUInt16(table, 76)); /* sanity check; some fonts treat winDescent as signed * violating the standard */ if( info->winDescent > 5*UPEm ) info->winDescent = XUnits(UPEm, GetInt16(table, 76)); } memcpy(info->panose, table + 32, 10); info->typeFlags = GetUInt16( table, 8 ); } table = getTable(ttf, O_post); if (table && getTableSize(ttf, O_post) >= 12+sizeof(sal_uInt32)) { info->pitch = GetUInt32(table, 12); info->italicAngle = GetInt32(table, 4); } table = getTable(ttf, O_head); /* 'head' tables is always there */ table_size = getTableSize(ttf, O_head); if (table_size >= 46) { info->xMin = XUnits(UPEm, GetInt16(table, 36)); info->yMin = XUnits(UPEm, GetInt16(table, 38)); info->xMax = XUnits(UPEm, GetInt16(table, 40)); info->yMax = XUnits(UPEm, GetInt16(table, 42)); info->macStyle = GetInt16(table, 44); } table = getTable(ttf, O_hhea); table_size = getTableSize(ttf, O_hhea); if (table && table_size >= 10) { info->ascender = XUnits(UPEm, GetInt16(table, 4)); info->descender = XUnits(UPEm, GetInt16(table, 6)); info->linegap = XUnits(UPEm, GetInt16(table, 8)); } table = getTable(ttf, O_vhea); } GlyphData *GetTTRawGlyphData(TrueTypeFont *ttf, sal_uInt32 glyphID) { const sal_uInt8* glyf = getTable(ttf, O_glyf); const sal_uInt8* hmtx = getTable(ttf, O_hmtx); int n; if( glyphID >= ttf->nglyphs ) return nullptr; /* #127161# check the glyph offsets */ sal_uInt32 length = getTableSize( ttf, O_glyf ); if( length < ttf->goffsets[ glyphID+1 ] ) return nullptr; length = ttf->goffsets[glyphID+1] - ttf->goffsets[glyphID]; GlyphData* d = static_cast(malloc(sizeof(GlyphData))); assert(d != nullptr); if (length > 0) { const sal_uInt8* srcptr = glyf + ttf->goffsets[glyphID]; const size_t nChunkLen = ((length + 1) & ~1); d->ptr = static_cast(malloc(nChunkLen)); assert(d->ptr != nullptr); memcpy(d->ptr, srcptr, length); memset(d->ptr + length, 0, nChunkLen - length); d->compflag = (GetInt16( srcptr, 0 ) < 0); } else { d->ptr = nullptr; d->compflag = false; } d->glyphID = glyphID; d->nbytes = static_cast((length + 1) & ~1); /* now calculate npoints and ncontours */ ControlPoint *cp; n = GetTTGlyphPoints(ttf, glyphID, &cp); if (n > 0) { int m = 0; for (int i = 0; i < n; i++) { if (cp[i].flags & 0x8000) m++; } d->npoints = static_cast(n); d->ncontours = static_cast(m); free(cp); } else { d->npoints = 0; d->ncontours = 0; } /* get advance width and left sidebearing */ if (glyphID < ttf->numberOfHMetrics) { d->aw = GetUInt16(hmtx, 4 * glyphID); d->lsb = GetInt16(hmtx, 4 * glyphID + 2); } else { d->aw = GetUInt16(hmtx, 4 * (ttf->numberOfHMetrics - 1)); d->lsb = GetInt16(hmtx + ttf->numberOfHMetrics * 4, (glyphID - ttf->numberOfHMetrics) * 2); } return d; } int GetTTNameRecords(TrueTypeFont const *ttf, NameRecord **nr) { const sal_uInt8* table = getTable(ttf, O_name); int nTableSize = getTableSize(ttf, O_name ); if (nTableSize < 6) { #if OSL_DEBUG_LEVEL > 1 fprintf(stderr, "O_name table too small\n"); #endif return 0; } sal_uInt16 n = GetUInt16(table, 2); int nStrBase = GetUInt16(table, 4); int i; *nr = nullptr; if (n == 0) return 0; const sal_uInt32 remaining_table_size = nTableSize-6; const sal_uInt32 nMinRecordSize = 12; const sal_uInt32 nMaxRecords = remaining_table_size / nMinRecordSize; if (n > nMaxRecords) { SAL_WARN("vcl.fonts", "Parsing error in " << OUString::createFromAscii(ttf->fname) << ": " << nMaxRecords << " max possible entries, but " << n << " claimed, truncating"); n = nMaxRecords; } NameRecord* rec = static_cast(calloc(n, sizeof(NameRecord))); assert(rec); for (i = 0; i < n; i++) { int nLargestFixedOffsetPos = 6 + 10 + 12 * i; int nMinSize = nLargestFixedOffsetPos + sizeof(sal_uInt16); if (nMinSize > nTableSize) { SAL_WARN( "vcl.fonts", "Font " << OUString::createFromAscii(ttf->fname) << " claimed to have " << n << " name records, but only space for " << i); n = i; break; } rec[i].platformID = GetUInt16(table, 6 + 0 + 12 * i); rec[i].encodingID = GetUInt16(table, 6 + 2 + 12 * i); rec[i].languageID = LanguageType(GetUInt16(table, 6 + 4 + 12 * i)); rec[i].nameID = GetUInt16(table, 6 + 6 + 12 * i); rec[i].slen = GetUInt16(table, 6 + 8 + 12 * i); int nStrOffset = GetUInt16(table, nLargestFixedOffsetPos); if (rec[i].slen) { if( nStrBase+nStrOffset+rec[i].slen >= nTableSize ) { rec[i].sptr = nullptr; rec[i].slen = 0; continue; } const sal_uInt8* rec_string = table + nStrBase + nStrOffset; // sanity check const sal_uInt8* end_table = ttf->ptr + ttf->fsize; const size_t available_space = rec_string > end_table ? 0 : (end_table - rec_string); if (rec[i].slen <= available_space) { rec[i].sptr = static_cast(malloc(rec[i].slen)); assert(rec[i].sptr != nullptr); memcpy(rec[i].sptr, rec_string, rec[i].slen); } else { rec[i].sptr = nullptr; rec[i].slen = 0; } } else { rec[i].sptr = nullptr; } // some fonts have 3.0 names => fix them to 3.1 if( (rec[i].platformID == 3) && (rec[i].encodingID == 0) ) rec[i].encodingID = 1; } *nr = rec; return n; } void DisposeNameRecords(NameRecord* nr, int n) { int i; for (i = 0; i < n; i++) { if (nr[i].sptr) free(nr[i].sptr); } free(nr); } template static void append(std::bitset & rSet, size_t const nOffset, sal_uInt32 const nValue) { for (size_t i = 0; i < 32; ++i) { rSet.set(nOffset + i, (nValue & (1 << i)) != 0); } } bool getTTCoverage( boost::optional> &rUnicodeRange, boost::optional> &rCodePageRange, const unsigned char* pTable, size_t nLength) { bool bRet = false; // parse OS/2 header if (nLength >= 58) { rUnicodeRange = std::bitset(); append(rUnicodeRange.get(), 0, GetUInt32(pTable, 42)); append(rUnicodeRange.get(), 32, GetUInt32(pTable, 46)); append(rUnicodeRange.get(), 64, GetUInt32(pTable, 50)); append(rUnicodeRange.get(), 96, GetUInt32(pTable, 54)); bRet = true; if (nLength >= 86) { rCodePageRange = std::bitset(); append(rCodePageRange.get(), 0, GetUInt32(pTable, 78)); append(rCodePageRange.get(), 32, GetUInt32(pTable, 82)); } } return bRet; } } // namespace vcl /* vim:set shiftwidth=4 softtabstop=4 expandtab: */