ComplexTextController::ComplexTextRun::ComplexTextRun(CTRunRef ctRun, const SimpleFontData* fontData, const UChar* characters, unsigned stringLocation, size_t stringLength, CFRange runRange)
: m_fontData(fontData)
, m_characters(characters)
, m_stringLocation(stringLocation)
, m_stringLength(stringLength)
, m_indexEnd(runRange.location + runRange.length)
, m_isMonotonic(true)
{
m_glyphCount = CTRunGetGlyphCount(ctRun);
m_coreTextIndices = CTRunGetStringIndicesPtr(ctRun);
if (!m_coreTextIndices) {
m_coreTextIndicesVector.grow(m_glyphCount);
CTRunGetStringIndices(ctRun, CFRangeMake(0, 0), m_coreTextIndicesVector.data());
m_coreTextIndices = m_coreTextIndicesVector.data();
}
m_glyphs = CTRunGetGlyphsPtr(ctRun);
if (!m_glyphs) {
m_glyphsVector.grow(m_glyphCount);
CTRunGetGlyphs(ctRun, CFRangeMake(0, 0), m_glyphsVector.data());
m_glyphs = m_glyphsVector.data();
}
m_advances = CTRunGetAdvancesPtr(ctRun);
if (!m_advances) {
m_advancesVector.grow(m_glyphCount);
CTRunGetAdvances(ctRun, CFRangeMake(0, 0), m_advancesVector.data());
m_advances = m_advancesVector.data();
}
}
static void
run_iterator_set_current_run (struct RunIterator *iter,
const int run_number)
{
CFIndex ct_glyph_count;
run_iterator_free_current_run (iter);
iter->current_run_number = run_number;
iter->current_run = CFArrayGetValueAtIndex (iter->runs, run_number);
iter->current_run_status = CTRunGetStatus (iter->current_run);
iter->current_cgglyphs = CTRunGetGlyphsPtr (iter->current_run);
ct_glyph_count = CTRunGetGlyphCount (iter->current_run);
iter->current_indices = malloc (sizeof (CFIndex *) * ct_glyph_count);
CTRunGetStringIndices (iter->current_run, CFRangeMake (0, ct_glyph_count),
iter->current_indices);
iter->ct_i = 0;
}
bool GlyphPage::fill(unsigned offset, unsigned length, UChar* buffer, unsigned bufferLength, const SimpleFontData* fontData)
{
bool haveGlyphs = false;
Vector<CGGlyph, 512> glyphs(bufferLength);
if (!shouldUseCoreText(buffer, bufferLength, fontData)) {
// We pass in either 256 or 512 UTF-16 characters: 256 for U+FFFF and less, 512 (double character surrogates)
// for U+10000 and above. It is indeed possible to get back 512 glyphs back from the API, so the glyph buffer
// we pass in must be 512. If we get back more than 256 glyphs though we'll ignore all the ones after 256,
// this should not happen as the only time we pass in 512 characters is when they are surrogates.
CGFontGetGlyphsForUnichars(fontData->platformData().cgFont(), buffer, glyphs.data(), bufferLength);
for (unsigned i = 0; i < length; ++i) {
if (!glyphs[i])
setGlyphDataForIndex(offset + i, 0, 0);
else {
setGlyphDataForIndex(offset + i, glyphs[i], fontData);
haveGlyphs = true;
}
}
} else if (!fontData->platformData().isCompositeFontReference() && ((fontData->platformData().widthVariant() == RegularWidth) ? wkGetVerticalGlyphsForCharacters(fontData->platformData().ctFont(), buffer, glyphs.data(), bufferLength)
: CTFontGetGlyphsForCharacters(fontData->platformData().ctFont(), buffer, glyphs.data(), bufferLength))) {
// When buffer consists of surrogate pairs, wkGetVerticalGlyphsForCharacters and CTFontGetGlyphsForCharacters
// place the glyphs at indices corresponding to the first character of each pair.
unsigned glyphStep = bufferLength / length;
for (unsigned i = 0; i < length; ++i) {
if (!glyphs[i * glyphStep])
setGlyphDataForIndex(offset + i, 0, 0);
else {
setGlyphDataForIndex(offset + i, glyphs[i * glyphStep], fontData);
haveGlyphs = true;
}
}
} else {
// We ask CoreText for possible vertical variant glyphs
RetainPtr<CFStringRef> string = adoptCF(CFStringCreateWithCharactersNoCopy(kCFAllocatorDefault, buffer, bufferLength, kCFAllocatorNull));
RetainPtr<CFAttributedStringRef> attributedString = adoptCF(CFAttributedStringCreate(kCFAllocatorDefault, string.get(), fontData->getCFStringAttributes(0, fontData->hasVerticalGlyphs() ? Vertical : Horizontal)));
RetainPtr<CTLineRef> line = adoptCF(CTLineCreateWithAttributedString(attributedString.get()));
CFArrayRef runArray = CTLineGetGlyphRuns(line.get());
CFIndex runCount = CFArrayGetCount(runArray);
// Initialize glyph entries
for (unsigned index = 0; index < length; ++index)
setGlyphDataForIndex(offset + index, 0, 0);
Vector<CGGlyph, 512> glyphVector;
Vector<CFIndex, 512> indexVector;
bool done = false;
// For the CGFont comparison in the loop, use the CGFont that Core Text assigns to the CTFont. This may
// be non-CFEqual to fontData->platformData().cgFont().
RetainPtr<CGFontRef> cgFont = adoptCF(CTFontCopyGraphicsFont(fontData->platformData().ctFont(), 0));
for (CFIndex r = 0; r < runCount && !done ; ++r) {
// CTLine could map characters over multiple fonts using its own font fallback list.
// We need to pick runs that use the exact font we need, i.e., fontData->platformData().ctFont().
CTRunRef ctRun = static_cast<CTRunRef>(CFArrayGetValueAtIndex(runArray, r));
ASSERT(CFGetTypeID(ctRun) == CTRunGetTypeID());
CFDictionaryRef attributes = CTRunGetAttributes(ctRun);
CTFontRef runFont = static_cast<CTFontRef>(CFDictionaryGetValue(attributes, kCTFontAttributeName));
RetainPtr<CGFontRef> runCGFont = adoptCF(CTFontCopyGraphicsFont(runFont, 0));
// Use CGFont here as CFEqual for CTFont counts all attributes for font.
bool gotBaseFont = CFEqual(cgFont.get(), runCGFont.get());
if (gotBaseFont || fontData->platformData().isCompositeFontReference()) {
// This run uses the font we want. Extract glyphs.
CFIndex glyphCount = CTRunGetGlyphCount(ctRun);
const CGGlyph* glyphs = CTRunGetGlyphsPtr(ctRun);
if (!glyphs) {
glyphVector.resize(glyphCount);
CTRunGetGlyphs(ctRun, CFRangeMake(0, 0), glyphVector.data());
glyphs = glyphVector.data();
}
const CFIndex* stringIndices = CTRunGetStringIndicesPtr(ctRun);
if (!stringIndices) {
indexVector.resize(glyphCount);
CTRunGetStringIndices(ctRun, CFRangeMake(0, 0), indexVector.data());
stringIndices = indexVector.data();
}
if (gotBaseFont) {
for (CFIndex i = 0; i < glyphCount; ++i) {
if (stringIndices[i] >= static_cast<CFIndex>(length)) {
done = true;
break;
}
if (glyphs[i]) {
setGlyphDataForIndex(offset + stringIndices[i], glyphs[i], fontData);
haveGlyphs = true;
}
}
#if !PLATFORM(IOS)
} else {
const SimpleFontData* runSimple = fontData->getCompositeFontReferenceFontData((NSFont *)runFont);
if (runSimple) {
for (CFIndex i = 0; i < glyphCount; ++i) {
if (stringIndices[i] >= static_cast<CFIndex>(length)) {
done = true;
break;
}
if (glyphs[i]) {
setGlyphDataForIndex(offset + stringIndices[i], glyphs[i], runSimple);
haveGlyphs = true;
}
}
}
#endif // !PLATFORM(IOS)
}
}
}
}
return haveGlyphs;
}
bool GlyphPage::fill(unsigned offset, unsigned length, UChar* buffer, unsigned bufferLength, const SimpleFontData* fontData)
{
bool haveGlyphs = false;
#ifndef BUILDING_ON_TIGER
if (fontData->orientation() == Horizontal || fontData->isBrokenIdeographFont()) {
Vector<CGGlyph, 512> glyphs(bufferLength);
wkGetGlyphsForCharacters(fontData->platformData().cgFont(), buffer, glyphs.data(), bufferLength);
for (unsigned i = 0; i < length; ++i) {
if (!glyphs[i])
setGlyphDataForIndex(offset + i, 0, 0);
else {
setGlyphDataForIndex(offset + i, glyphs[i], fontData);
haveGlyphs = true;
}
}
} else {
// We ask CoreText for possible vertical variant glyphs
RetainPtr<CFStringRef> string(AdoptCF, CFStringCreateWithCharactersNoCopy(kCFAllocatorDefault, buffer, bufferLength, kCFAllocatorNull));
RetainPtr<CFAttributedStringRef> attributedString(AdoptCF, CFAttributedStringCreate(kCFAllocatorDefault, string.get(), fontData->getCFStringAttributes(0)));
RetainPtr<CTLineRef> line(AdoptCF, CTLineCreateWithAttributedString(attributedString.get()));
CFArrayRef runArray = CTLineGetGlyphRuns(line.get());
CFIndex runCount = CFArrayGetCount(runArray);
// Initialize glyph entries
for (unsigned index = 0; index < length; ++index)
setGlyphDataForIndex(offset + index, 0, 0);
Vector<CGGlyph, 512> glyphVector;
Vector<CFIndex, 512> indexVector;
bool done = false;
for (CFIndex r = 0; r < runCount && !done ; ++r) {
// CTLine could map characters over multiple fonts using its own font fallback list.
// We need to pick runs that use the exact font we need, i.e., fontData->platformData().ctFont().
CTRunRef ctRun = static_cast<CTRunRef>(CFArrayGetValueAtIndex(runArray, r));
ASSERT(CFGetTypeID(ctRun) == CTRunGetTypeID());
CFDictionaryRef attributes = CTRunGetAttributes(ctRun);
CTFontRef runFont = static_cast<CTFontRef>(CFDictionaryGetValue(attributes, kCTFontAttributeName));
RetainPtr<CGFontRef> runCGFont(AdoptCF, CTFontCopyGraphicsFont(runFont, 0));
// Use CGFont here as CFEqual for CTFont counts all attributes for font.
if (CFEqual(fontData->platformData().cgFont(), runCGFont.get())) {
// This run uses the font we want. Extract glyphs.
CFIndex glyphCount = CTRunGetGlyphCount(ctRun);
const CGGlyph* glyphs = CTRunGetGlyphsPtr(ctRun);
if (!glyphs) {
glyphVector.resize(glyphCount);
CTRunGetGlyphs(ctRun, CFRangeMake(0, 0), glyphVector.data());
glyphs = glyphVector.data();
}
const CFIndex* stringIndices = CTRunGetStringIndicesPtr(ctRun);
if (!stringIndices) {
indexVector.resize(glyphCount);
CTRunGetStringIndices(ctRun, CFRangeMake(0, 0), indexVector.data());
stringIndices = indexVector.data();
}
for (CFIndex i = 0; i < glyphCount; ++i) {
if (stringIndices[i] >= static_cast<CFIndex>(length)) {
done = true;
break;
}
if (glyphs[i]) {
setGlyphDataForIndex(offset + stringIndices[i], glyphs[i], fontData);
haveGlyphs = true;
}
}
}
}
}
#else
// Use an array of long so we get good enough alignment.
long glyphVector[(GLYPH_VECTOR_SIZE + sizeof(long) - 1) / sizeof(long)];
OSStatus status = wkInitializeGlyphVector(GlyphPage::size, &glyphVector);
if (status != noErr)
// This should never happen, perhaps indicates a bad font! If it does the
// font substitution code will find an alternate font.
return false;
wkConvertCharToGlyphs(fontData->m_styleGroup, buffer, bufferLength, &glyphVector);
unsigned numGlyphs = wkGetGlyphVectorNumGlyphs(&glyphVector);
if (numGlyphs != length) {
// This should never happen, perhaps indicates a bad font?
// If it does happen, the font substitution code will find an alternate font.
wkClearGlyphVector(&glyphVector);
return false;
}
ATSLayoutRecord* glyphRecord = (ATSLayoutRecord*)wkGetGlyphVectorFirstRecord(glyphVector);
for (unsigned i = 0; i < length; i++) {
Glyph glyph = glyphRecord->glyphID;
if (!glyph)
setGlyphDataForIndex(offset + i, 0, 0);
else {
setGlyphDataForIndex(offset + i, glyph, fontData);
haveGlyphs = true;
}
glyphRecord = (ATSLayoutRecord *)((char *)glyphRecord + wkGetGlyphVectorRecordSize(glyphVector));
}
wkClearGlyphVector(&glyphVector);
#endif
return haveGlyphs;
}
bool GlyphPage::fill(unsigned offset, unsigned length, UChar* buffer, unsigned bufferLength, const SimpleFontData* fontData)
{
bool haveGlyphs = false;
if (!shouldUseCoreText(buffer, bufferLength, fontData)) {
Vector<CGGlyph, 512> glyphs(bufferLength);
CMFontGetGlyphsForUnichars(fontData->platformData().cgFont(), buffer, glyphs.data(), bufferLength);
// wkGetGlyphsForCharacters(fontData->platformData().cgFont(), buffer, glyphs.data(), bufferLength);
for (unsigned i = 0; i < length; ++i) {
if (!glyphs[i])
setGlyphDataForIndex(offset + i, 0, 0);
else {
setGlyphDataForIndex(offset + i, glyphs[i], fontData);
haveGlyphs = true;
}
}
} else {
// We ask CoreText for possible vertical variant glyphs
RetainPtr<CFStringRef> string(AdoptCF, CFStringCreateWithCharactersNoCopy(kCFAllocatorDefault, buffer, bufferLength, kCFAllocatorNull));
RetainPtr<CFAttributedStringRef> attributedString(AdoptCF, CFAttributedStringCreate(kCFAllocatorDefault, string.get(), fontData->getCFStringAttributes(0, fontData->hasVerticalGlyphs() ? Vertical : Horizontal)));
RetainPtr<CTLineRef> line(AdoptCF, CTLineCreateWithAttributedString(attributedString.get()));
CFArrayRef runArray = CTLineGetGlyphRuns(line.get());
CFIndex runCount = CFArrayGetCount(runArray);
// Initialize glyph entries
for (unsigned index = 0; index < length; ++index)
setGlyphDataForIndex(offset + index, 0, 0);
Vector<CGGlyph, 512> glyphVector;
Vector<CFIndex, 512> indexVector;
bool done = false;
// For the CGFont comparison in the loop, use the CGFont that Core Text assigns to the CTFont. This may
// be non-CFEqual to fontData->platformData().cgFont().
RetainPtr<CGFontRef> cgFont(AdoptCF, CTFontCopyGraphicsFont(fontData->platformData().ctFont(), 0));
for (CFIndex r = 0; r < runCount && !done ; ++r) {
// CTLine could map characters over multiple fonts using its own font fallback list.
// We need to pick runs that use the exact font we need, i.e., fontData->platformData().ctFont().
CTRunRef ctRun = static_cast<CTRunRef>(CFArrayGetValueAtIndex(runArray, r));
ASSERT(CFGetTypeID(ctRun) == CTRunGetTypeID());
CFDictionaryRef attributes = CTRunGetAttributes(ctRun);
CTFontRef runFont = static_cast<CTFontRef>(CFDictionaryGetValue(attributes, kCTFontAttributeName));
RetainPtr<CGFontRef> runCGFont(AdoptCF, CTFontCopyGraphicsFont(runFont, 0));
// Use CGFont here as CFEqual for CTFont counts all attributes for font.
if (CFEqual(cgFont.get(), runCGFont.get())) {
// This run uses the font we want. Extract glyphs.
CFIndex glyphCount = CTRunGetGlyphCount(ctRun);
const CGGlyph* glyphs = CTRunGetGlyphsPtr(ctRun);
if (!glyphs) {
glyphVector.resize(glyphCount);
CTRunGetGlyphs(ctRun, CFRangeMake(0, 0), glyphVector.data());
glyphs = glyphVector.data();
}
const CFIndex* stringIndices = CTRunGetStringIndicesPtr(ctRun);
if (!stringIndices) {
indexVector.resize(glyphCount);
CTRunGetStringIndices(ctRun, CFRangeMake(0, 0), indexVector.data());
stringIndices = indexVector.data();
}
for (CFIndex i = 0; i < glyphCount; ++i) {
if (stringIndices[i] >= static_cast<CFIndex>(length)) {
done = true;
break;
}
if (glyphs[i]) {
setGlyphDataForIndex(offset + stringIndices[i], glyphs[i], fontData);
haveGlyphs = true;
}
}
}
}
}
return haveGlyphs;
}
bool SimpleFontData::fillGlyphPage(GlyphPage* pageToFill, unsigned offset, unsigned length, UChar* buffer, unsigned bufferLength) const
{
bool haveGlyphs = false;
Vector<CGGlyph, 512> glyphs(bufferLength);
if (!shouldUseCoreText(buffer, bufferLength, this)) {
CGFontGetGlyphsForUnichars(platformData().cgFont(), buffer, glyphs.data(), bufferLength);
for (unsigned i = 0; i < length; ++i) {
if (glyphs[i]) {
pageToFill->setGlyphDataForIndex(offset + i, glyphs[i], this);
haveGlyphs = true;
}
}
} else if (!platformData().isCompositeFontReference() && platformData().widthVariant() != RegularWidth
&& CTFontGetGlyphsForCharacters(platformData().ctFont(), buffer, glyphs.data(), bufferLength)) {
// When buffer consists of surrogate pairs, CTFontGetGlyphsForCharacters
// places the glyphs at indices corresponding to the first character of each pair.
unsigned glyphStep = bufferLength / length;
for (unsigned i = 0; i < length; ++i) {
if (glyphs[i * glyphStep]) {
pageToFill->setGlyphDataForIndex(offset + i, glyphs[i * glyphStep], this);
haveGlyphs = true;
}
}
} else {
// We ask CoreText for possible vertical variant glyphs
RetainPtr<CFStringRef> string(AdoptCF, CFStringCreateWithCharactersNoCopy(kCFAllocatorDefault, buffer, bufferLength, kCFAllocatorNull));
RetainPtr<CFAttributedStringRef> attributedString(AdoptCF, CFAttributedStringCreate(kCFAllocatorDefault, string.get(), getCFStringAttributes(0, hasVerticalGlyphs() ? Vertical : Horizontal)));
RetainPtr<CTLineRef> line(AdoptCF, CTLineCreateWithAttributedString(attributedString.get()));
CFArrayRef runArray = CTLineGetGlyphRuns(line.get());
CFIndex runCount = CFArrayGetCount(runArray);
Vector<CGGlyph, 512> glyphVector;
Vector<CFIndex, 512> indexVector;
bool done = false;
// For the CGFont comparison in the loop, use the CGFont that Core Text assigns to the CTFont. This may
// be non-CFEqual to platformData().cgFont().
RetainPtr<CGFontRef> cgFont(AdoptCF, CTFontCopyGraphicsFont(platformData().ctFont(), 0));
for (CFIndex r = 0; r < runCount && !done ; ++r) {
// CTLine could map characters over multiple fonts using its own font fallback list.
// We need to pick runs that use the exact font we need, i.e., platformData().ctFont().
CTRunRef ctRun = static_cast<CTRunRef>(CFArrayGetValueAtIndex(runArray, r));
ASSERT(CFGetTypeID(ctRun) == CTRunGetTypeID());
CFDictionaryRef attributes = CTRunGetAttributes(ctRun);
CTFontRef runFont = static_cast<CTFontRef>(CFDictionaryGetValue(attributes, kCTFontAttributeName));
RetainPtr<CGFontRef> runCGFont(AdoptCF, CTFontCopyGraphicsFont(runFont, 0));
// Use CGFont here as CFEqual for CTFont counts all attributes for font.
bool gotBaseFont = CFEqual(cgFont.get(), runCGFont.get());
if (gotBaseFont || platformData().isCompositeFontReference()) {
// This run uses the font we want. Extract glyphs.
CFIndex glyphCount = CTRunGetGlyphCount(ctRun);
const CGGlyph* glyphs = CTRunGetGlyphsPtr(ctRun);
if (!glyphs) {
glyphVector.resize(glyphCount);
CTRunGetGlyphs(ctRun, CFRangeMake(0, 0), glyphVector.data());
glyphs = glyphVector.data();
}
const CFIndex* stringIndices = CTRunGetStringIndicesPtr(ctRun);
if (!stringIndices) {
indexVector.resize(glyphCount);
CTRunGetStringIndices(ctRun, CFRangeMake(0, 0), indexVector.data());
stringIndices = indexVector.data();
}
if (gotBaseFont) {
for (CFIndex i = 0; i < glyphCount; ++i) {
if (stringIndices[i] >= static_cast<CFIndex>(length)) {
done = true;
break;
}
if (glyphs[i]) {
pageToFill->setGlyphDataForIndex(offset + stringIndices[i], glyphs[i], this);
haveGlyphs = true;
}
}
} else {
const SimpleFontData* runSimple = getCompositeFontReferenceFontData((NSFont *)runFont);
if (runSimple) {
for (CFIndex i = 0; i < glyphCount; ++i) {
if (stringIndices[i] >= static_cast<CFIndex>(length)) {
done = true;
break;
}
if (glyphs[i]) {
pageToFill->setGlyphDataForIndex(offset + stringIndices[i], glyphs[i], runSimple);
haveGlyphs = true;
}
}
}
}
}
}
}
return haveGlyphs;
}
void CoreTextController::adjustGlyphsAndAdvances()
{
size_t runCount = m_coreTextRuns.size();
for (size_t r = 0; r < runCount; ++r) {
const CoreTextRun& coreTextRun = m_coreTextRuns[r];
unsigned glyphCount = coreTextRun.glyphCount();
const SimpleFontData* fontData = coreTextRun.fontData();
Vector<CGGlyph, 256> glyphsVector;
const CGGlyph* glyphs;
Vector<CGSize, 256> advancesVector;
const CGSize* advances;
if (coreTextRun.ctRun()) {
glyphs = CTRunGetGlyphsPtr(coreTextRun.ctRun());
if (!glyphs) {
glyphsVector.grow(glyphCount);
CTRunGetGlyphs(coreTextRun.ctRun(), CFRangeMake(0, 0), glyphsVector.data());
glyphs = glyphsVector.data();
}
advances = CTRunGetAdvancesPtr(coreTextRun.ctRun());
if (!advances) {
advancesVector.grow(glyphCount);
CTRunGetAdvances(coreTextRun.ctRun(), CFRangeMake(0, 0), advancesVector.data());
advances = advancesVector.data();
}
} else {
// Synthesize a run of missing glyphs.
glyphsVector.fill(0, glyphCount);
glyphs = glyphsVector.data();
advancesVector.fill(CGSizeMake(fontData->widthForGlyph(0), 0), glyphCount);
advances = advancesVector.data();
}
bool lastRun = r + 1 == runCount;
const UChar* cp = coreTextRun.characters();
CGFloat roundedSpaceWidth = roundCGFloat(fontData->m_spaceWidth);
bool roundsAdvances = !m_font.isPrinterFont() && fontData->platformData().roundsGlyphAdvances();
bool hasExtraSpacing = (m_font.letterSpacing() || m_font.wordSpacing() || m_padding) && !m_run.spacingDisabled();
for (unsigned i = 0; i < glyphCount; i++) {
CFIndex characterIndex = coreTextRun.indexAt(i);
UChar ch = *(cp + characterIndex);
bool lastGlyph = lastRun && i + 1 == glyphCount;
UChar nextCh;
if (lastGlyph)
nextCh = ' ';
else if (i + 1 < glyphCount)
nextCh = *(cp + coreTextRun.indexAt(i + 1));
else
nextCh = *(m_coreTextRuns[r + 1].characters() + m_coreTextRuns[r + 1].indexAt(0));
bool treatAsSpace = Font::treatAsSpace(ch);
CGGlyph glyph = treatAsSpace ? fontData->m_spaceGlyph : glyphs[i];
CGSize advance = treatAsSpace ? CGSizeMake(fontData->m_spaceWidth, advances[i].height) : advances[i];
if (ch == '\t' && m_run.allowTabs()) {
float tabWidth = m_font.tabWidth();
advance.width = tabWidth - fmodf(m_run.xPos() + m_totalWidth, tabWidth);
} else if (ch == zeroWidthSpace || Font::treatAsZeroWidthSpace(ch) && !treatAsSpace) {
advance.width = 0;
glyph = fontData->m_spaceGlyph;
}
float roundedAdvanceWidth = roundf(advance.width);
if (roundsAdvances)
advance.width = roundedAdvanceWidth;
advance.width += fontData->m_syntheticBoldOffset;
// We special case spaces in two ways when applying word rounding.
// First, we round spaces to an adjusted width in all fonts.
// Second, in fixed-pitch fonts we ensure that all glyphs that
// match the width of the space glyph have the same width as the space glyph.
if (roundedAdvanceWidth == roundedSpaceWidth && (fontData->m_treatAsFixedPitch || glyph == fontData->m_spaceGlyph) && m_run.applyWordRounding())
advance.width = fontData->m_adjustedSpaceWidth;
if (hasExtraSpacing) {
// If we're a glyph with an advance, go ahead and add in letter-spacing.
// That way we weed out zero width lurkers. This behavior matches the fast text code path.
if (advance.width && m_font.letterSpacing())
advance.width += m_font.letterSpacing();
// Handle justification and word-spacing.
if (glyph == fontData->m_spaceGlyph) {
// Account for padding. WebCore uses space padding to justify text.
// We distribute the specified padding over the available spaces in the run.
if (m_padding) {
// Use leftover padding if not evenly divisible by number of spaces.
if (m_padding < m_padPerSpace) {
advance.width += m_padding;
m_padding = 0;
} else {
advance.width += m_padPerSpace;
m_padding -= m_padPerSpace;
}
}
// Account for word-spacing.
if (treatAsSpace && characterIndex > 0 && !Font::treatAsSpace(*m_run.data(characterIndex - 1)) && m_font.wordSpacing())
advance.width += m_font.wordSpacing();
}
}
// Deal with the float/integer impedance mismatch between CG and WebCore. "Words" (characters
// followed by a character defined by isRoundingHackCharacter()) are always an integer width.
// We adjust the width of the last character of a "word" to ensure an integer width.
// Force characters that are used to determine word boundaries for the rounding hack
// to be integer width, so the following words will start on an integer boundary.
if (m_run.applyWordRounding() && Font::isRoundingHackCharacter(ch))
advance.width = ceilCGFloat(advance.width);
// Check to see if the next character is a "rounding hack character", if so, adjust the
// width so that the total run width will be on an integer boundary.
if (m_run.applyWordRounding() && !lastGlyph && Font::isRoundingHackCharacter(nextCh) || m_run.applyRunRounding() && lastGlyph) {
CGFloat totalWidth = m_totalWidth + advance.width;
CGFloat extraWidth = ceilCGFloat(totalWidth) - totalWidth;
if (m_run.ltr())
advance.width += extraWidth;
else {
m_totalWidth += extraWidth;
if (m_lastRoundingGlyph)
m_adjustedAdvances[m_lastRoundingGlyph - 1].width += extraWidth;
else
m_finalRoundingWidth = extraWidth;
m_lastRoundingGlyph = m_adjustedAdvances.size() + 1;
}
}
m_totalWidth += advance.width;
advance.height *= -1;
m_adjustedAdvances.append(advance);
m_adjustedGlyphs.append(glyph);
}
}
}
static void
basic_engine_shape (PangoEngineShape *engine,
PangoFont *font,
const char *text,
gint length,
const PangoAnalysis *analysis,
PangoGlyphString *glyphs)
{
const char *p;
char *copy;
CTLineRef line;
CFStringRef cstr;
CFDictionaryRef attributes;
CFAttributedStringRef attstr;
PangoCoreTextFont *cfont = PANGO_CORE_TEXT_FONT (font);
PangoCoverage *coverage;
CFArrayRef runs;
CTRunRef run;
CTRunStatus run_status;
CFIndex i, glyph_count;
const CGGlyph *cgglyphs;
CFTypeRef keys[] = {
(CFTypeRef) kCTFontAttributeName
};
CFTypeRef values[] = {
pango_core_text_font_get_ctfont (cfont)
};
attributes = CFDictionaryCreate (kCFAllocatorDefault,
(const void **)keys,
(const void **)values,
1,
&kCFCopyStringDictionaryKeyCallBacks,
&kCFTypeDictionaryValueCallBacks);
copy = g_strndup (text, length + 1);
copy[length] = 0;
cstr = CFStringCreateWithCString (kCFAllocatorDefault, copy,
kCFStringEncodingUTF8);
g_free (copy);
attstr = CFAttributedStringCreate (kCFAllocatorDefault,
cstr,
attributes);
line = CTLineCreateWithAttributedString (attstr);
runs = CTLineGetGlyphRuns (line);
/* Since Pango divides things into runs already, we assume there is
* only a single run in this line.
*/
run = CFArrayGetValueAtIndex (runs, 0);
run_status = CTRunGetStatus (run);
glyph_count = CTRunGetGlyphCount (run);
cgglyphs = CTRunGetGlyphsPtr (run);
p = text;
pango_glyph_string_set_size (glyphs, glyph_count);
coverage = pango_font_get_coverage (PANGO_FONT (cfont),
analysis->language);
for (i = 0; i < glyph_count; i++)
{
CFIndex real_i, prev_i;
gunichar wc;
gunichar mirrored_ch;
wc = g_utf8_get_char (p);
if (analysis->level % 2)
if (pango_get_mirror_char (wc, &mirrored_ch))
wc = mirrored_ch;
if (run_status & kCTRunStatusRightToLeft)
{
real_i = glyph_count - i - 1;
prev_i = real_i + 1;
}
else
{
real_i = i;
prev_i = real_i - 1;
}
if (wc == 0xa0) /* non-break-space */
wc = 0x20;
if (pango_is_zero_width (wc))
{
set_glyph (font, glyphs, real_i, p - text, PANGO_GLYPH_EMPTY);
}
else
{
PangoCoverageLevel result;
result = pango_coverage_get (coverage, wc);
if (result != PANGO_COVERAGE_NONE)
{
set_glyph (font, glyphs, real_i, p - text, cgglyphs[real_i]);
if (g_unichar_type (wc) == G_UNICODE_NON_SPACING_MARK)
{
if (i > 0)
{
PangoRectangle logical_rect, ink_rect;
glyphs->glyphs[real_i].geometry.width = MAX (glyphs->glyphs[prev_i].geometry.width,
glyphs->glyphs[prev_i].geometry.width);
glyphs->glyphs[prev_i].geometry.width = 0;
glyphs->log_clusters[real_i] = glyphs->log_clusters[prev_i];
/* Some heuristics to try to guess how overstrike glyphs are
* done and compensate
*/
pango_font_get_glyph_extents (font, glyphs->glyphs[real_i].glyph, &ink_rect, &logical_rect);
if (logical_rect.width == 0 && ink_rect.x == 0)
glyphs->glyphs[real_i].geometry.x_offset = (glyphs->glyphs[real_i].geometry.width - ink_rect.width) / 2;
}
}
}
else
{
set_glyph (font, glyphs, real_i, p - text,
PANGO_GET_UNKNOWN_GLYPH (wc));
}
}
p = g_utf8_next_char (p);
}
CFRelease (line);
CFRelease (attstr);
CFRelease (cstr);
CFRelease (attributes);
pango_coverage_unref (coverage);
}
