source/test/letest/cmaps.cpp - external/github.com/unicode-org/icu - Git at Google

 /***************************************************************************
 *
 *   Copyright (C) 1998-2003, International Business Machines
 *   Corporation and others.  All Rights Reserved.
 *
 ************************************************************************/

 #include "LETypes.h"
 #include "LESwaps.h"

 #include "sfnt.h"
 #include "cmaps.h"

 #define SWAPU16(code) ((LEUnicode16) SWAPW(code))
 #define SWAPU32(code) ((LEUnicode32) SWAPL(code))

 //
 // Finds the high bit by binary searching
 // through the bits in value.
 //
 le_int8 highBit(le_uint32 value)
 {
     le_uint8 bit = 0;

     if (value >= 1 << 16) {
         value >>= 16;
         bit += 16;
     }

     if (value >= 1 << 8) {
         value >>= 8;
         bit += 8;
     }

     if (value >= 1 << 4) {
         value >>= 4;
         bit += 4;
     }

     if (value >= 1 << 2) {
         value >>= 2;
         bit += 2;
     }

     if (value >= 1 << 1) {
         value >>= 1;
         bit += 1;
     }

     return bit;
 }

 CMAPMapper *CMAPMapper::createUnicodeMapper(const CMAPTable *cmap)
 {
     le_uint16 i;
     le_uint16 nSubtables = SWAPW(cmap->numberSubtables);
     const CMAPEncodingSubtable *subtable = NULL;
     le_uint32 offset1 = 0, offset10 = 0;

     for (i = 0; i < nSubtables; i += 1) {
         const CMAPEncodingSubtableHeader *esh = &cmap->encodingSubtableHeaders[i];

         if (SWAPW(esh->platformID) == 3) {
             switch (SWAPW(esh->platformSpecificID)) {
             case 1:
                 offset1 = SWAPL(esh->encodingOffset);
                 break;

             case 10:
                 offset10 = SWAPL(esh->encodingOffset);
                 break;
             }
         }
     }


     if (offset10 != 0)
     {
         subtable = (const CMAPEncodingSubtable *) ((const char *) cmap + offset10);
     } else if (offset1 != 0) {
         subtable = (const CMAPEncodingSubtable *) ((const char *) cmap + offset1);
     } else {
         return NULL;
     }

     switch (SWAPW(subtable->format)) {
     case 4:
         return new CMAPFormat4Mapper(cmap, (const CMAPFormat4Encoding *) subtable);

     case 12:
     {
         const CMAPFormat12Encoding *encoding = (const CMAPFormat12Encoding *) subtable;

         return new CMAPGroupMapper(cmap, encoding->groups, SWAPL(encoding->nGroups));
     }

     default:
         break;
     }

     return NULL;
 }

 CMAPFormat4Mapper::CMAPFormat4Mapper(const CMAPTable *cmap, const CMAPFormat4Encoding *header)
     : CMAPMapper(cmap)
 {
     le_uint16 segCount = SWAPW(header->segCountX2) / 2;

     fEntrySelector = SWAPW(header->entrySelector);
     fRangeShift = SWAPW(header->rangeShift) / 2;
     fEndCodes = &header->endCodes[0];
     fStartCodes = &header->endCodes[segCount + 1]; // + 1 for reservedPad...
     fIdDelta = &fStartCodes[segCount];
     fIdRangeOffset = &fIdDelta[segCount];
 }

 LEGlyphID CMAPFormat4Mapper::unicodeToGlyph(LEUnicode32 unicode32) const
 {
     if (unicode32 >= 0x10000) {
         return 0;
     }

     LEUnicode16 unicode = (LEUnicode16) unicode32;
     le_uint16 index = 0;
     le_uint16 probe = 1 << fEntrySelector;
     TTGlyphID result = 0;

     if (SWAPU16(fStartCodes[fRangeShift]) <= unicode) {
         index = fRangeShift;
     }

     while (probe > (1 << 0)) {
         probe >>= 1;

         if (SWAPU16(fStartCodes[index + probe]) <= unicode) {
             index += probe;
         }
     }

     if (unicode >= SWAPU16(fStartCodes[index]) && unicode <= SWAPU16(fEndCodes[index])) {
         if (fIdRangeOffset[index] == 0) {
             result = (TTGlyphID) unicode;
         } else {
             le_uint16 offset = unicode - SWAPU16(fStartCodes[index]);
             le_uint16 rangeOffset = SWAPW(fIdRangeOffset[index]);
             le_uint16 *glyphIndexTable = (le_uint16 *) ((char *) &fIdRangeOffset[index] + rangeOffset);

             result = SWAPW(glyphIndexTable[offset]);
         }

         result += SWAPW(fIdDelta[index]);
     } else {
         result = 0;
     }

     return LE_SET_GLYPH(0, result);
 }

 CMAPFormat4Mapper::~CMAPFormat4Mapper()
 {
     // parent destructor does it all
 }

 CMAPGroupMapper::CMAPGroupMapper(const CMAPTable *cmap, const CMAPGroup *groups, le_uint32 nGroups)
     : CMAPMapper(cmap), fGroups(groups)
 {
     le_uint8 bit = highBit(nGroups);
     fPower = 1 << bit;
     fRangeOffset = nGroups - fPower;
 }

 LEGlyphID CMAPGroupMapper::unicodeToGlyph(LEUnicode32 unicode32) const
 {
     le_int32 probe = fPower;
     le_int32 range = 0;

     if (SWAPU32(fGroups[fRangeOffset].startCharCode) <= unicode32) {
         range = fRangeOffset;
     }

     while (probe > (1 << 0)) {
         probe >>= 1;

         if (SWAPU32(fGroups[range + probe].startCharCode) <= unicode32) {
             range += probe;
         }
     }

     if (SWAPU32(fGroups[range].startCharCode) <= unicode32 && SWAPU32(fGroups[range].endCharCode) >= unicode32) {
         return (LEGlyphID) (SWAPU32(fGroups[range].startGlyphCode) + unicode32 - SWAPU32(fGroups[range].startCharCode));
     }

     return 0;
 }

 CMAPGroupMapper::~CMAPGroupMapper()
 {
     // parent destructor does it all
 }
	/***************************************************************************
	*
	* Copyright (C) 1998-2003, International Business Machines
	* Corporation and others. All Rights Reserved.
	*
	************************************************************************/

	#include "LETypes.h"
	#include "LESwaps.h"

	#include "sfnt.h"
	#include "cmaps.h"

	#define SWAPU16(code) ((LEUnicode16) SWAPW(code))
	#define SWAPU32(code) ((LEUnicode32) SWAPL(code))

	//
	// Finds the high bit by binary searching
	// through the bits in value.
	//
	le_int8 highBit(le_uint32 value)
	{
	le_uint8 bit = 0;

	if (value >= 1 << 16) {
	value >>= 16;
	bit += 16;
	}

	if (value >= 1 << 8) {
	value >>= 8;
	bit += 8;
	}

	if (value >= 1 << 4) {
	value >>= 4;
	bit += 4;
	}

	if (value >= 1 << 2) {
	value >>= 2;
	bit += 2;
	}

	if (value >= 1 << 1) {
	value >>= 1;
	bit += 1;
	}

	return bit;
	}

	CMAPMapper CMAPMapper::createUnicodeMapper(const CMAPTable cmap)
	{
	le_uint16 i;
	le_uint16 nSubtables = SWAPW(cmap->numberSubtables);
	const CMAPEncodingSubtable *subtable = NULL;
	le_uint32 offset1 = 0, offset10 = 0;

	for (i = 0; i < nSubtables; i += 1) {
	const CMAPEncodingSubtableHeader *esh = &cmap->encodingSubtableHeaders[i];

	if (SWAPW(esh->platformID) == 3) {
	switch (SWAPW(esh->platformSpecificID)) {
	case 1:
	offset1 = SWAPL(esh->encodingOffset);
	break;

	case 10:
	offset10 = SWAPL(esh->encodingOffset);
	break;
	}
	}
	}


	if (offset10 != 0)
	{
	subtable = (const CMAPEncodingSubtable ) ((const char ) cmap + offset10);
	} else if (offset1 != 0) {
	subtable = (const CMAPEncodingSubtable ) ((const char ) cmap + offset1);
	} else {
	return NULL;
	}

	switch (SWAPW(subtable->format)) {
	case 4:
	return new CMAPFormat4Mapper(cmap, (const CMAPFormat4Encoding *) subtable);

	case 12:
	{
	const CMAPFormat12Encoding encoding = (const CMAPFormat12Encoding ) subtable;

	return new CMAPGroupMapper(cmap, encoding->groups, SWAPL(encoding->nGroups));
	}

	default:
	break;
	}

	return NULL;
	}

	CMAPFormat4Mapper::CMAPFormat4Mapper(const CMAPTable cmap, const CMAPFormat4Encoding header)
	: CMAPMapper(cmap)
	{
	le_uint16 segCount = SWAPW(header->segCountX2) / 2;

	fEntrySelector = SWAPW(header->entrySelector);
	fRangeShift = SWAPW(header->rangeShift) / 2;
	fEndCodes = &header->endCodes[0];
	fStartCodes = &header->endCodes[segCount + 1]; // + 1 for reservedPad...
	fIdDelta = &fStartCodes[segCount];
	fIdRangeOffset = &fIdDelta[segCount];
	}

	LEGlyphID CMAPFormat4Mapper::unicodeToGlyph(LEUnicode32 unicode32) const
	{
	if (unicode32 >= 0x10000) {
	return 0;
	}

	LEUnicode16 unicode = (LEUnicode16) unicode32;
	le_uint16 index = 0;
	le_uint16 probe = 1 << fEntrySelector;
	TTGlyphID result = 0;

	if (SWAPU16(fStartCodes[fRangeShift]) <= unicode) {
	index = fRangeShift;
	}

	while (probe > (1 << 0)) {
	probe >>= 1;

	if (SWAPU16(fStartCodes[index + probe]) <= unicode) {
	index += probe;
	}
	}

	if (unicode >= SWAPU16(fStartCodes[index]) && unicode <= SWAPU16(fEndCodes[index])) {
	if (fIdRangeOffset[index] == 0) {
	result = (TTGlyphID) unicode;
	} else {
	le_uint16 offset = unicode - SWAPU16(fStartCodes[index]);
	le_uint16 rangeOffset = SWAPW(fIdRangeOffset[index]);
	le_uint16 glyphIndexTable = (le_uint16 ) ((char *) &fIdRangeOffset[index] + rangeOffset);

	result = SWAPW(glyphIndexTable[offset]);
	}

	result += SWAPW(fIdDelta[index]);
	} else {
	result = 0;
	}

	return LE_SET_GLYPH(0, result);
	}

	CMAPFormat4Mapper::~CMAPFormat4Mapper()
	{
	// parent destructor does it all
	}

	CMAPGroupMapper::CMAPGroupMapper(const CMAPTable cmap, const CMAPGroup groups, le_uint32 nGroups)
	: CMAPMapper(cmap), fGroups(groups)
	{
	le_uint8 bit = highBit(nGroups);
	fPower = 1 << bit;
	fRangeOffset = nGroups - fPower;
	}

	LEGlyphID CMAPGroupMapper::unicodeToGlyph(LEUnicode32 unicode32) const
	{
	le_int32 probe = fPower;
	le_int32 range = 0;

	if (SWAPU32(fGroups[fRangeOffset].startCharCode) <= unicode32) {
	range = fRangeOffset;
	}

	while (probe > (1 << 0)) {
	probe >>= 1;

	if (SWAPU32(fGroups[range + probe].startCharCode) <= unicode32) {
	range += probe;
	}
	}

	if (SWAPU32(fGroups[range].startCharCode) <= unicode32 && SWAPU32(fGroups[range].endCharCode) >= unicode32) {
	return (LEGlyphID) (SWAPU32(fGroups[range].startGlyphCode) + unicode32 - SWAPU32(fGroups[range].startCharCode));
	}

	return 0;
	}

	CMAPGroupMapper::~CMAPGroupMapper()
	{
	// parent destructor does it all
	}