/* * * (C) Copyright IBM Corp. 1998-2013 - All Rights Reserved * */ #include "LETypes.h" #include "LEFontInstance.h" #include "OpenTypeTables.h" #include "GlyphPositioningTables.h" #include "PairPositioningSubtables.h" #include "ValueRecords.h" #include "GlyphIterator.h" #include "OpenTypeUtilities.h" #include "LESwaps.h" U_NAMESPACE_BEGIN le_uint32 PairPositioningSubtable::process(const LEReferenceTo &base, GlyphIterator *glyphIterator, const LEFontInstance *fontInstance, LEErrorCode &success) const { switch(SWAPW(subtableFormat)) { case 0: return 0; case 1: { const LEReferenceTo subtable(base, success, (const PairPositioningFormat1Subtable *) this); if(LE_SUCCESS(success)) return subtable->process(subtable, glyphIterator, fontInstance, success); else return 0; } case 2: { const LEReferenceTo subtable(base, success, (const PairPositioningFormat2Subtable *) this); if(LE_SUCCESS(success)) return subtable->process(subtable, glyphIterator, fontInstance, success); else return 0; } default: return 0; } } le_uint32 PairPositioningFormat1Subtable::process(const LEReferenceTo &base, GlyphIterator *glyphIterator, const LEFontInstance *fontInstance, LEErrorCode &success) const { LEGlyphID firstGlyph = glyphIterator->getCurrGlyphID(); le_int32 coverageIndex = getGlyphCoverage(base, firstGlyph, success); GlyphIterator tempIterator(*glyphIterator); if (coverageIndex >= 0 && glyphIterator->next()) { Offset pairSetTableOffset = SWAPW(pairSetTableOffsetArray[coverageIndex]); PairSetTable *pairSetTable = (PairSetTable *) ((char *) this + pairSetTableOffset); le_uint16 pairValueCount = SWAPW(pairSetTable->pairValueCount); le_int16 valueRecord1Size = ValueRecord::getSize(SWAPW(valueFormat1)); le_int16 valueRecord2Size = ValueRecord::getSize(SWAPW(valueFormat2)); le_int16 recordSize = sizeof(PairValueRecord) - sizeof(ValueRecord) + valueRecord1Size + valueRecord2Size; LEGlyphID secondGlyph = glyphIterator->getCurrGlyphID(); const PairValueRecord *pairValueRecord = NULL; if (pairValueCount != 0) { pairValueRecord = findPairValueRecord((TTGlyphID) LE_GET_GLYPH(secondGlyph), pairSetTable->pairValueRecordArray, pairValueCount, recordSize); } if (pairValueRecord == NULL) { return 0; } if (valueFormat1 != 0) { pairValueRecord->valueRecord1.adjustPosition(SWAPW(valueFormat1), (char *) this, tempIterator, fontInstance); } if (valueFormat2 != 0) { const ValueRecord *valueRecord2 = (const ValueRecord *) ((char *) &pairValueRecord->valueRecord1 + valueRecord1Size); valueRecord2->adjustPosition(SWAPW(valueFormat2), (char *) this, *glyphIterator, fontInstance); } // back up glyphIterator so second glyph can be // first glyph in the next pair glyphIterator->prev(); return 1; } return 0; } le_uint32 PairPositioningFormat2Subtable::process(const LEReferenceTo &base, GlyphIterator *glyphIterator, const LEFontInstance *fontInstance, LEErrorCode &success) const { LEGlyphID firstGlyph = glyphIterator->getCurrGlyphID(); le_int32 coverageIndex = getGlyphCoverage(base, firstGlyph, success); GlyphIterator tempIterator(*glyphIterator); if (coverageIndex >= 0 && glyphIterator->next()) { LEGlyphID secondGlyph = glyphIterator->getCurrGlyphID(); const ClassDefinitionTable *classDef1 = (const ClassDefinitionTable *) ((char *) this + SWAPW(classDef1Offset)); const ClassDefinitionTable *classDef2 = (const ClassDefinitionTable *) ((char *) this + SWAPW(classDef2Offset)); le_int32 class1 = classDef1->getGlyphClass(firstGlyph); le_int32 class2 = classDef2->getGlyphClass(secondGlyph); le_int16 valueRecord1Size = ValueRecord::getSize(SWAPW(valueFormat1)); le_int16 valueRecord2Size = ValueRecord::getSize(SWAPW(valueFormat2)); le_int16 class2RecordSize = valueRecord1Size + valueRecord2Size; le_int16 class1RecordSize = class2RecordSize * SWAPW(class2Count); const Class1Record *class1Record = (const Class1Record *) ((char *) class1RecordArray + (class1RecordSize * class1)); const Class2Record *class2Record = (const Class2Record *) ((char *) class1Record->class2RecordArray + (class2RecordSize * class2)); if (valueFormat1 != 0) { class2Record->valueRecord1.adjustPosition(SWAPW(valueFormat1), (char *) this, tempIterator, fontInstance); } if (valueFormat2 != 0) { const ValueRecord *valueRecord2 = (const ValueRecord *) ((char *) &class2Record->valueRecord1 + valueRecord1Size); valueRecord2->adjustPosition(SWAPW(valueFormat2), (const char *) this, *glyphIterator, fontInstance); } // back up glyphIterator so second glyph can be // first glyph in the next pair glyphIterator->prev(); return 1; } return 0; } const PairValueRecord *PairPositioningFormat1Subtable::findPairValueRecord(TTGlyphID glyphID, const PairValueRecord *records, le_uint16 recordCount, le_uint16 recordSize) const { #if 1 // The OpenType spec. says that the ValueRecord table is // sorted by secondGlyph. Unfortunately, there are fonts // around that have an unsorted ValueRecord table. const PairValueRecord *record = records; for(le_int32 r = 0; r < recordCount; r += 1) { if (SWAPW(record->secondGlyph) == glyphID) { return record; } record = (const PairValueRecord *) ((char *) record + recordSize); } #else le_uint8 bit = OpenTypeUtilities::highBit(recordCount); le_uint16 power = 1 << bit; le_uint16 extra = (recordCount - power) * recordSize; le_uint16 probe = power * recordSize; const PairValueRecord *record = records; const PairValueRecord *trial = (const PairValueRecord *) ((char *) record + extra); if (SWAPW(trial->secondGlyph) <= glyphID) { record = trial; } while (probe > recordSize) { probe >>= 1; trial = (const PairValueRecord *) ((char *) record + probe); if (SWAPW(trial->secondGlyph) <= glyphID) { record = trial; } } if (SWAPW(record->secondGlyph) == glyphID) { return record; } #endif return NULL; } U_NAMESPACE_END