/* * Copyright (C) 2005, 2006, 2010, 2011 Apple Inc. All rights reserved. * Copyright (C) 2006 Alexey Proskuryakov * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY APPLE INC. AND ITS CONTRIBUTORS ``AS IS'' * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, * THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL APPLE INC. OR ITS CONTRIBUTORS * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF * THE POSSIBILITY OF SUCH DAMAGE. */ #import "config.h" #import "Font.h" #import "BlockExceptions.h" #import "Color.h" #import "CoreGraphicsSPI.h" #import "CoreTextSPI.h" #import "FloatRect.h" #import "FontCache.h" #import "FontCascade.h" #import "FontDescription.h" #import "SharedBuffer.h" #import "WebCoreSystemInterface.h" #import <float.h> #import <unicode/uchar.h> #import <wtf/Assertions.h> #import <wtf/NeverDestroyed.h> #import <wtf/RetainPtr.h> #import <wtf/StdLibExtras.h> #if USE(APPKIT) #import <AppKit/AppKit.h> #import <ApplicationServices/ApplicationServices.h> #else #import "FontServicesIOS.h" #import <CoreText/CoreText.h> #endif #if USE(APPKIT) @interface NSFont (WebAppKitSecretAPI) - (BOOL)_isFakeFixedPitch; @end #endif namespace WebCore { static bool fontHasVerticalGlyphs(CTFontRef ctFont) { // The check doesn't look neat but this is what AppKit does for vertical writing... RetainPtr<CFArrayRef> tableTags = adoptCF(CTFontCopyAvailableTables(ctFont, kCTFontTableOptionNoOptions)); CFIndex numTables = CFArrayGetCount(tableTags.get()); for (CFIndex index = 0; index < numTables; ++index) { CTFontTableTag tag = (CTFontTableTag)(uintptr_t)CFArrayGetValueAtIndex(tableTags.get(), index); if (tag == kCTFontTableVhea || tag == kCTFontTableVORG) return true; } return false; } #if USE(APPKIT) static NSString *webFallbackFontFamily(void) { static NSString *webFallbackFontFamily = [[[NSFont systemFontOfSize:16.0f] familyName] retain]; return webFallbackFontFamily; } #else bool fontFamilyShouldNotBeUsedForArabic(CFStringRef fontFamilyName) { if (!fontFamilyName) return false; // Times New Roman and Arial are not performant enough to use. <rdar://problem/21333326> // FIXME <rdar://problem/12096835> remove this function once the above bug is fixed. return (CFStringCompare(CFSTR("Times New Roman"), fontFamilyName, 0) == kCFCompareEqualTo) || (CFStringCompare(CFSTR("Arial"), fontFamilyName, 0) == kCFCompareEqualTo); } #endif void Font::platformInit() { // FIXME: Unify these two codepaths #if USE(APPKIT) m_syntheticBoldOffset = m_platformData.m_syntheticBold ? 1.0f : 0.f; bool failedSetup = false; if (!platformData().cgFont()) { // Ack! Something very bad happened, like a corrupt font. // Try looking for an alternate 'base' font for this renderer. // Special case hack to use "Times New Roman" in place of "Times". // "Times RO" is a common font whose family name is "Times". // It overrides the normal "Times" family font. // It also appears to have a corrupt regular variant. NSString *fallbackFontFamily; if ([[m_platformData.nsFont() familyName] isEqual:@"Times"]) fallbackFontFamily = @"Times New Roman"; else fallbackFontFamily = webFallbackFontFamily(); // Try setting up the alternate font. // This is a last ditch effort to use a substitute font when something has gone wrong. #if !ERROR_DISABLED RetainPtr<NSFont> initialFont = m_platformData.nsFont(); #endif if (m_platformData.font()) m_platformData.setNSFont([[NSFontManager sharedFontManager] convertFont:m_platformData.nsFont() toFamily:fallbackFontFamily]); else m_platformData.setNSFont([NSFont fontWithName:fallbackFontFamily size:m_platformData.size()]); if (!platformData().cgFont()) { if ([fallbackFontFamily isEqual:@"Times New Roman"]) { // OK, couldn't setup Times New Roman as an alternate to Times, fallback // on the system font. If this fails we have no alternative left. m_platformData.setNSFont([[NSFontManager sharedFontManager] convertFont:m_platformData.nsFont() toFamily:webFallbackFontFamily()]); if (!platformData().cgFont()) { // We tried, Times, Times New Roman, and the system font. No joy. We have to give up. LOG_ERROR("unable to initialize with font %@", initialFont.get()); failedSetup = true; } } else { // We tried the requested font and the system font. No joy. We have to give up. LOG_ERROR("unable to initialize with font %@", initialFont.get()); failedSetup = true; } } // Report the problem. LOG_ERROR("Corrupt font detected, using %@ in place of %@.", [m_platformData.nsFont() familyName], [initialFont.get() familyName]); } // If all else fails, try to set up using the system font. // This is probably because Times and Times New Roman are both unavailable. if (failedSetup) { m_platformData.setNSFont([NSFont systemFontOfSize:[m_platformData.nsFont() pointSize]]); LOG_ERROR("failed to set up font, using system font %s", m_platformData.font()); } m_isSystemFont = CTFontDescriptorIsSystemUIFont(adoptCF(CTFontCopyFontDescriptor(m_platformData.font())).get()); // Work around <rdar://problem/19433490> CGGlyph dummyGlyphs[] = {0, 0}; CGSize dummySize[] = { CGSizeMake(0, 0), CGSizeMake(0, 0) }; CTFontTransformGlyphs(m_platformData.ctFont(), dummyGlyphs, dummySize, 2, kCTFontTransformApplyPositioning | kCTFontTransformApplyShaping); int iAscent; int iDescent; int iCapHeight; int iLineGap; unsigned unitsPerEm; iAscent = CGFontGetAscent(m_platformData.cgFont()); // Some fonts erroneously specify a positive descender value. We follow Core Text in assuming that // such fonts meant the same distance, but in the reverse direction. iDescent = -abs(CGFontGetDescent(m_platformData.cgFont())); iCapHeight = CGFontGetCapHeight(m_platformData.cgFont()); iLineGap = CGFontGetLeading(m_platformData.cgFont()); unitsPerEm = CGFontGetUnitsPerEm(m_platformData.cgFont()); float pointSize = m_platformData.m_size; float ascent = scaleEmToUnits(iAscent, unitsPerEm) * pointSize; float descent = -scaleEmToUnits(iDescent, unitsPerEm) * pointSize; float capHeight = scaleEmToUnits(iCapHeight, unitsPerEm) * pointSize; float lineGap = scaleEmToUnits(iLineGap, unitsPerEm) * pointSize; // We need to adjust Times, Helvetica, and Courier to closely match the // vertical metrics of their Microsoft counterparts that are the de facto // web standard. The AppKit adjustment of 20% is too big and is // incorrectly added to line spacing, so we use a 15% adjustment instead // and add it to the ascent. NSString *familyName = [m_platformData.nsFont() familyName]; if ([familyName isEqualToString:@"Times"] || [familyName isEqualToString:@"Helvetica"] || [familyName isEqualToString:@"Courier"]) ascent += floorf(((ascent + descent) * 0.15f) + 0.5f); // Compute and store line spacing, before the line metrics hacks are applied. m_fontMetrics.setLineSpacing(lroundf(ascent) + lroundf(descent) + lroundf(lineGap)); // Hack Hiragino line metrics to allow room for marked text underlines. // <rdar://problem/5386183> if (descent < 3 && lineGap >= 3 && [familyName hasPrefix:@"Hiragino"]) { lineGap -= 3 - descent; descent = 3; } if (platformData().orientation() == Vertical && !isTextOrientationFallback()) m_hasVerticalGlyphs = fontHasVerticalGlyphs(m_platformData.ctFont()); float xHeight; if (platformData().orientation() == Horizontal) { // Measure the actual character "x", since it's possible for it to extend below the baseline, and we need the // reported x-height to only include the portion of the glyph that is above the baseline. NSGlyph xGlyph = glyphForCharacter('x'); if (xGlyph) xHeight = -CGRectGetMinY(platformBoundsForGlyph(xGlyph)); else xHeight = scaleEmToUnits(CGFontGetXHeight(m_platformData.cgFont()), unitsPerEm) * pointSize; } else xHeight = verticalRightOrientationFont()->fontMetrics().xHeight(); m_fontMetrics.setUnitsPerEm(unitsPerEm); m_fontMetrics.setAscent(ascent); m_fontMetrics.setDescent(descent); m_fontMetrics.setCapHeight(capHeight); m_fontMetrics.setLineGap(lineGap); m_fontMetrics.setXHeight(xHeight); #else m_isSystemFont = CTFontDescriptorIsSystemUIFont(adoptCF(CTFontCopyFontDescriptor(m_platformData.font())).get()); m_syntheticBoldOffset = m_platformData.m_syntheticBold ? ceilf(m_platformData.size() / 24.0f) : 0.f; m_spaceGlyph = 0; m_spaceWidth = 0; unsigned unitsPerEm; float ascent; float descent; float capHeight; float lineGap; float lineSpacing; float xHeight; RetainPtr<CFStringRef> familyName; if (CTFontRef ctFont = m_platformData.font()) { FontServicesIOS fontService(ctFont); ascent = ceilf(fontService.ascent()); descent = ceilf(fontService.descent()); lineSpacing = fontService.lineSpacing(); lineGap = fontService.lineGap(); xHeight = fontService.xHeight(); capHeight = fontService.capHeight(); unitsPerEm = fontService.unitsPerEm(); familyName = adoptCF(CTFontCopyFamilyName(ctFont)); } else { // FIXME: This else block is dead code. Remove it. CGFontRef cgFont = m_platformData.cgFont(); unitsPerEm = CGFontGetUnitsPerEm(cgFont); float pointSize = m_platformData.size(); ascent = lroundf(scaleEmToUnits(CGFontGetAscent(cgFont), unitsPerEm) * pointSize); descent = lroundf(-scaleEmToUnits(-abs(CGFontGetDescent(cgFont)), unitsPerEm) * pointSize); lineGap = lroundf(scaleEmToUnits(CGFontGetLeading(cgFont), unitsPerEm) * pointSize); xHeight = scaleEmToUnits(CGFontGetXHeight(cgFont), unitsPerEm) * pointSize; capHeight = scaleEmToUnits(CGFontGetCapHeight(cgFont), unitsPerEm) * pointSize; lineSpacing = ascent + descent + lineGap; familyName = adoptCF(CGFontCopyFamilyName(cgFont)); } m_fontMetrics.setUnitsPerEm(unitsPerEm); m_fontMetrics.setAscent(ascent); m_fontMetrics.setDescent(descent); m_fontMetrics.setLineGap(lineGap); m_fontMetrics.setLineSpacing(lineSpacing); m_fontMetrics.setXHeight(xHeight); m_fontMetrics.setCapHeight(capHeight); m_shouldNotBeUsedForArabic = fontFamilyShouldNotBeUsedForArabic(familyName.get()); if (platformData().orientation() == Vertical && !isTextOrientationFallback()) m_hasVerticalGlyphs = fontHasVerticalGlyphs(m_platformData.ctFont()); if (m_platformData.isEmoji()) { int thirdOfSize = m_platformData.size() / 3; m_fontMetrics.setAscent(thirdOfSize); m_fontMetrics.setDescent(thirdOfSize); m_fontMetrics.setLineGap(thirdOfSize); } #endif } void Font::platformCharWidthInit() { m_avgCharWidth = 0; m_maxCharWidth = 0; #if PLATFORM(MAC) RetainPtr<CFDataRef> os2Table = adoptCF(CGFontCopyTableForTag(m_platformData.cgFont(), 'OS/2')); if (os2Table && CFDataGetLength(os2Table.get()) >= 4) { const UInt8* os2 = CFDataGetBytePtr(os2Table.get()); SInt16 os2AvgCharWidth = os2[2] * 256 + os2[3]; m_avgCharWidth = scaleEmToUnits(os2AvgCharWidth, m_fontMetrics.unitsPerEm()) * m_platformData.m_size; } RetainPtr<CFDataRef> headTable = adoptCF(CGFontCopyTableForTag(m_platformData.cgFont(), 'head')); if (headTable && CFDataGetLength(headTable.get()) >= 42) { const UInt8* head = CFDataGetBytePtr(headTable.get()); ushort uxMin = head[36] * 256 + head[37]; ushort uxMax = head[40] * 256 + head[41]; SInt16 xMin = static_cast<SInt16>(uxMin); SInt16 xMax = static_cast<SInt16>(uxMax); float diff = static_cast<float>(xMax - xMin); m_maxCharWidth = scaleEmToUnits(diff, m_fontMetrics.unitsPerEm()) * m_platformData.m_size; } #endif // Fallback to a cross-platform estimate, which will populate these values if they are non-positive. initCharWidths(); } void Font::platformDestroy() { } bool Font::variantCapsSupportsCharacterForSynthesis(FontVariantCaps fontVariantCaps, UChar32 character) const { #if (PLATFORM(IOS) && TARGET_OS_IOS && __IPHONE_OS_VERSION_MIN_REQUIRED >= 90300) || (PLATFORM(MAC) && __MAC_OS_X_VERSION_MIN_REQUIRED >= 101100 && __MAC_OS_X_VERSION_MAX_ALLOWED >= 101104) Glyph glyph = glyphForCharacter(character); if (!glyph) return false; switch (fontVariantCaps) { case FontVariantCaps::Small: { auto& supported = glyphsSupportedBySmallCaps(); return supported.size() > glyph && supported.get(glyph); } case FontVariantCaps::Petite: { auto& supported = glyphsSupportedByPetiteCaps(); return supported.size() > glyph && supported.get(glyph); } case FontVariantCaps::AllSmall: { auto& supported = glyphsSupportedByAllSmallCaps(); return supported.size() > glyph && supported.get(glyph); } case FontVariantCaps::AllPetite: { auto& supported = glyphsSupportedByAllPetiteCaps(); return supported.size() > glyph && supported.get(glyph); } default: // Synthesis only supports the variant-caps values listed above. return true; } #else UNUSED_PARAM(character); switch (fontVariantCaps) { case FontVariantCaps::Small: case FontVariantCaps::Petite: case FontVariantCaps::AllSmall: case FontVariantCaps::AllPetite: return false; default: // Synthesis only supports the variant-caps values listed above. return true; } #endif } #if (PLATFORM(IOS) && TARGET_OS_IOS && __IPHONE_OS_VERSION_MIN_REQUIRED >= 90300) || (PLATFORM(MAC) && __MAC_OS_X_VERSION_MIN_REQUIRED >= 101100 && __MAC_OS_X_VERSION_MAX_ALLOWED >= 101104) static RetainPtr<CFDictionaryRef> smallCapsOpenTypeDictionary(CFStringRef key, int rawValue) { RetainPtr<CFNumberRef> value = adoptCF(CFNumberCreate(kCFAllocatorDefault, kCFNumberIntType, &rawValue)); CFTypeRef keys[] = { kCTFontOpenTypeFeatureTag, kCTFontOpenTypeFeatureValue }; CFTypeRef values[] = { key, value.get() }; return adoptCF(CFDictionaryCreate(kCFAllocatorDefault, keys, values, WTF_ARRAY_LENGTH(keys), &kCFTypeDictionaryKeyCallBacks, &kCFTypeDictionaryValueCallBacks)); } static RetainPtr<CFDictionaryRef> smallCapsTrueTypeDictionary(int rawKey, int rawValue) { RetainPtr<CFNumberRef> key = adoptCF(CFNumberCreate(kCFAllocatorDefault, kCFNumberIntType, &rawKey)); RetainPtr<CFNumberRef> value = adoptCF(CFNumberCreate(kCFAllocatorDefault, kCFNumberIntType, &rawValue)); CFTypeRef keys[] = { kCTFontFeatureTypeIdentifierKey, kCTFontFeatureSelectorIdentifierKey }; CFTypeRef values[] = { key.get(), value.get() }; return adoptCF(CFDictionaryCreate(kCFAllocatorDefault, keys, values, WTF_ARRAY_LENGTH(keys), &kCFTypeDictionaryKeyCallBacks, &kCFTypeDictionaryValueCallBacks)); } static void unionBitVectors(BitVector& result, CFBitVectorRef source) { CFIndex length = CFBitVectorGetCount(source); result.ensureSize(length); CFIndex min = 0; while (min < length) { CFIndex nextIndex = CFBitVectorGetFirstIndexOfBit(source, CFRangeMake(min, length - min), 1); if (nextIndex == kCFNotFound) break; result.set(nextIndex, true); min = nextIndex + 1; } } static void injectOpenTypeCoverage(CFStringRef feature, CTFontRef font, BitVector& result) { RetainPtr<CFBitVectorRef> source = adoptCF(CTFontCopyGlyphCoverageForFeature(font, smallCapsOpenTypeDictionary(feature, 1).get())); unionBitVectors(result, source.get()); } static void injectTrueTypeCoverage(int type, int selector, CTFontRef font, BitVector& result) { RetainPtr<CFBitVectorRef> source = adoptCF(CTFontCopyGlyphCoverageForFeature(font, smallCapsTrueTypeDictionary(type, selector).get())); unionBitVectors(result, source.get()); } const BitVector& Font::glyphsSupportedBySmallCaps() const { if (!m_glyphsSupportedBySmallCaps) { m_glyphsSupportedBySmallCaps = BitVector(); injectOpenTypeCoverage(CFSTR("smcp"), platformData().font(), m_glyphsSupportedBySmallCaps.value()); injectTrueTypeCoverage(kLowerCaseType, kLowerCaseSmallCapsSelector, platformData().font(), m_glyphsSupportedBySmallCaps.value()); } return m_glyphsSupportedBySmallCaps.value(); } const BitVector& Font::glyphsSupportedByAllSmallCaps() const { if (!m_glyphsSupportedByAllSmallCaps) { m_glyphsSupportedByAllSmallCaps = BitVector(); injectOpenTypeCoverage(CFSTR("smcp"), platformData().font(), m_glyphsSupportedByAllSmallCaps.value()); injectOpenTypeCoverage(CFSTR("c2sc"), platformData().font(), m_glyphsSupportedByAllSmallCaps.value()); injectTrueTypeCoverage(kLowerCaseType, kLowerCaseSmallCapsSelector, platformData().font(), m_glyphsSupportedByAllSmallCaps.value()); injectTrueTypeCoverage(kUpperCaseType, kUpperCaseSmallCapsSelector, platformData().font(), m_glyphsSupportedByAllSmallCaps.value()); } return m_glyphsSupportedByAllSmallCaps.value(); } const BitVector& Font::glyphsSupportedByPetiteCaps() const { if (!m_glyphsSupportedByPetiteCaps) { m_glyphsSupportedByPetiteCaps = BitVector(); injectOpenTypeCoverage(CFSTR("pcap"), platformData().font(), m_glyphsSupportedByPetiteCaps.value()); injectTrueTypeCoverage(kLowerCaseType, kLowerCasePetiteCapsSelector, platformData().font(), m_glyphsSupportedByPetiteCaps.value()); } return m_glyphsSupportedByPetiteCaps.value(); } const BitVector& Font::glyphsSupportedByAllPetiteCaps() const { if (!m_glyphsSupportedByAllPetiteCaps) { m_glyphsSupportedByAllPetiteCaps = BitVector(); injectOpenTypeCoverage(CFSTR("pcap"), platformData().font(), m_glyphsSupportedByAllPetiteCaps.value()); injectOpenTypeCoverage(CFSTR("c2pc"), platformData().font(), m_glyphsSupportedByAllPetiteCaps.value()); injectTrueTypeCoverage(kLowerCaseType, kLowerCasePetiteCapsSelector, platformData().font(), m_glyphsSupportedByAllPetiteCaps.value()); injectTrueTypeCoverage(kUpperCaseType, kUpperCasePetiteCapsSelector, platformData().font(), m_glyphsSupportedByAllPetiteCaps.value()); } return m_glyphsSupportedByAllPetiteCaps.value(); } #endif static RefPtr<Font> createDerivativeFont(CTFontRef font, float size, FontOrientation orientation, CTFontSymbolicTraits fontTraits, bool syntheticBold, bool syntheticItalic) { if (!font) return nullptr; FontPlatformData scaledFontData(font, size, false, false, orientation); if (syntheticBold) fontTraits |= kCTFontBoldTrait; if (syntheticItalic) fontTraits |= kCTFontItalicTrait; CTFontSymbolicTraits scaledFontTraits = CTFontGetSymbolicTraits(scaledFontData.font()); scaledFontData.m_syntheticBold = (fontTraits & kCTFontBoldTrait) && !(scaledFontTraits & kCTFontTraitBold); scaledFontData.m_syntheticOblique = (fontTraits & kCTFontItalicTrait) && !(scaledFontTraits & kCTFontTraitItalic); return Font::create(scaledFontData); } static inline bool isOpenTypeFeature(CFDictionaryRef feature) { return CFDictionaryContainsKey(feature, kCTFontOpenTypeFeatureTag) && CFDictionaryContainsKey(feature, kCTFontOpenTypeFeatureValue); } static inline bool isTrueTypeFeature(CFDictionaryRef feature) { return CFDictionaryContainsKey(feature, kCTFontFeatureTypeIdentifierKey) && CFDictionaryContainsKey(feature, kCTFontFeatureSelectorIdentifierKey); } static inline Optional<CFStringRef> openTypeFeature(CFDictionaryRef feature) { ASSERT(isOpenTypeFeature(feature)); CFStringRef tag = static_cast<CFStringRef>(CFDictionaryGetValue(feature, kCTFontOpenTypeFeatureTag)); int rawValue; CFNumberRef value = static_cast<CFNumberRef>(CFDictionaryGetValue(feature, kCTFontOpenTypeFeatureValue)); auto success = CFNumberGetValue(value, kCFNumberIntType, &rawValue); ASSERT_UNUSED(success, success); return rawValue ? Optional<CFStringRef>(tag) : Nullopt; } static inline std::pair<int, int> trueTypeFeature(CFDictionaryRef feature) { ASSERT(isTrueTypeFeature(feature)); int rawType; CFNumberRef type = static_cast<CFNumberRef>(CFDictionaryGetValue(feature, kCTFontFeatureTypeIdentifierKey)); auto success = CFNumberGetValue(type, kCFNumberIntType, &rawType); ASSERT_UNUSED(success, success); int rawSelector; CFNumberRef selector = static_cast<CFNumberRef>(CFDictionaryGetValue(feature, kCTFontFeatureSelectorIdentifierKey)); success = CFNumberGetValue(selector, kCFNumberIntType, &rawSelector); ASSERT_UNUSED(success, success); return std::make_pair(rawType, rawSelector); } static inline CFNumberRef defaultSelectorForTrueTypeFeature(int key, CTFontRef font) { RetainPtr<CFArrayRef> features = adoptCF(CTFontCopyFeatures(font)); CFIndex featureCount = CFArrayGetCount(features.get()); for (CFIndex i = 0; i < featureCount; ++i) { CFDictionaryRef featureType = static_cast<CFDictionaryRef>(CFArrayGetValueAtIndex(features.get(), i)); CFNumberRef featureKey = static_cast<CFNumberRef>(CFDictionaryGetValue(featureType, kCTFontFeatureTypeIdentifierKey)); if (!featureKey) continue; int rawFeatureKey; CFNumberGetValue(featureKey, kCFNumberIntType, &rawFeatureKey); if (rawFeatureKey != key) continue; CFArrayRef featureSelectors = static_cast<CFArrayRef>(CFDictionaryGetValue(featureType, kCTFontFeatureTypeSelectorsKey)); if (!featureSelectors) continue; CFIndex selectorsCount = CFArrayGetCount(featureSelectors); for (CFIndex j = 0; j < selectorsCount; ++j) { CFDictionaryRef featureSelector = static_cast<CFDictionaryRef>(CFArrayGetValueAtIndex(featureSelectors, j)); CFNumberRef isDefault = static_cast<CFNumberRef>(CFDictionaryGetValue(featureSelector, kCTFontFeatureSelectorDefaultKey)); if (!isDefault) continue; int rawIsDefault; CFNumberGetValue(isDefault, kCFNumberIntType, &rawIsDefault); if (!rawIsDefault) continue; return static_cast<CFNumberRef>(CFDictionaryGetValue(featureSelector, kCTFontFeatureSelectorIdentifierKey)); } } return nullptr; } static inline RetainPtr<CFDictionaryRef> removedFeature(CFDictionaryRef feature, CTFontRef font) { bool isOpenType = isOpenTypeFeature(feature); bool isTrueType = isTrueTypeFeature(feature); if (!isOpenType && !isTrueType) return feature; // We don't understand this font format. RetainPtr<CFMutableDictionaryRef> result = adoptCF(CFDictionaryCreateMutable(kCFAllocatorDefault, 0, &kCFTypeDictionaryKeyCallBacks, &kCFTypeDictionaryValueCallBacks)); if (isOpenType) { auto featureTag = openTypeFeature(feature); if (featureTag && (CFEqual(featureTag.value(), CFSTR("smcp")) || CFEqual(featureTag.value(), CFSTR("c2sc")) || CFEqual(featureTag.value(), CFSTR("pcap")) || CFEqual(featureTag.value(), CFSTR("c2pc")))) { int rawZero = 0; RetainPtr<CFNumberRef> zero = adoptCF(CFNumberCreate(kCFAllocatorDefault, kCFNumberIntType, &rawZero)); CFDictionaryAddValue(result.get(), kCTFontOpenTypeFeatureTag, featureTag.value()); CFDictionaryAddValue(result.get(), kCTFontOpenTypeFeatureValue, zero.get()); } else { CFDictionaryAddValue(result.get(), kCTFontOpenTypeFeatureTag, CFDictionaryGetValue(feature, kCTFontOpenTypeFeatureTag)); CFDictionaryAddValue(result.get(), kCTFontOpenTypeFeatureValue, CFDictionaryGetValue(feature, kCTFontOpenTypeFeatureValue)); } } if (isTrueType) { auto trueTypeFeaturePair = trueTypeFeature(feature); if (trueTypeFeaturePair.first == kLowerCaseType && (trueTypeFeaturePair.second == kLowerCaseSmallCapsSelector || trueTypeFeaturePair.second == kLowerCasePetiteCapsSelector)) { CFDictionaryAddValue(result.get(), kCTFontFeatureTypeIdentifierKey, CFDictionaryGetValue(feature, kCTFontFeatureTypeIdentifierKey)); if (CFNumberRef defaultSelector = defaultSelectorForTrueTypeFeature(kLowerCaseType, font)) CFDictionaryAddValue(result.get(), kCTFontFeatureSelectorIdentifierKey, defaultSelector); else CFDictionaryAddValue(result.get(), kCTFontFeatureSelectorIdentifierKey, CFDictionaryGetValue(feature, kCTFontFeatureSelectorIdentifierKey)); } else if (trueTypeFeaturePair.first == kUpperCaseType && (trueTypeFeaturePair.second == kUpperCaseSmallCapsSelector || trueTypeFeaturePair.second == kUpperCasePetiteCapsSelector)) { CFDictionaryAddValue(result.get(), kCTFontFeatureTypeIdentifierKey, CFDictionaryGetValue(feature, kCTFontFeatureTypeIdentifierKey)); if (CFNumberRef defaultSelector = defaultSelectorForTrueTypeFeature(kUpperCaseType, font)) CFDictionaryAddValue(result.get(), kCTFontFeatureSelectorIdentifierKey, defaultSelector); else CFDictionaryAddValue(result.get(), kCTFontFeatureSelectorIdentifierKey, CFDictionaryGetValue(feature, kCTFontFeatureSelectorIdentifierKey)); } else { CFDictionaryAddValue(result.get(), kCTFontFeatureTypeIdentifierKey, CFDictionaryGetValue(feature, kCTFontFeatureTypeIdentifierKey)); CFDictionaryAddValue(result.get(), kCTFontFeatureSelectorIdentifierKey, CFDictionaryGetValue(feature, kCTFontFeatureSelectorIdentifierKey)); } } return result; } static RetainPtr<CTFontRef> createCTFontWithoutSynthesizableFeatures(CTFontRef font) { RetainPtr<CFArrayRef> features = adoptCF(static_cast<CFArrayRef>(CTFontCopyAttribute(font, kCTFontFeatureSettingsAttribute))); if (!features) return font; CFIndex featureCount = CFArrayGetCount(features.get()); RetainPtr<CFMutableArrayRef> newFeatures = adoptCF(CFArrayCreateMutable(kCFAllocatorDefault, featureCount, &kCFTypeArrayCallBacks)); for (CFIndex i = 0; i < featureCount; ++i) { CFDictionaryRef feature = static_cast<CFDictionaryRef>(CFArrayGetValueAtIndex(features.get(), i)); CFArrayAppendValue(newFeatures.get(), removedFeature(feature, font).get()); } CFTypeRef keys[] = { kCTFontFeatureSettingsAttribute }; CFTypeRef values[] = { newFeatures.get() }; RetainPtr<CFDictionaryRef> attributes = adoptCF(CFDictionaryCreate(kCFAllocatorDefault, keys, values, WTF_ARRAY_LENGTH(keys), &kCFTypeDictionaryKeyCallBacks, &kCFTypeDictionaryValueCallBacks)); RetainPtr<CTFontDescriptorRef> newDescriptor = adoptCF(CTFontDescriptorCreateWithAttributes(attributes.get())); return adoptCF(CTFontCreateCopyWithAttributes(font, CTFontGetSize(font), nullptr, newDescriptor.get())); } RefPtr<Font> Font::createFontWithoutSynthesizableFeatures() const { float size = m_platformData.size(); CTFontSymbolicTraits fontTraits = CTFontGetSymbolicTraits(m_platformData.font()); RetainPtr<CTFontRef> ctFont = createCTFontWithoutSynthesizableFeatures(m_platformData.font()); return createDerivativeFont(ctFont.get(), size, m_platformData.orientation(), fontTraits, m_platformData.m_syntheticBold, m_platformData.m_syntheticOblique); } PassRefPtr<Font> Font::platformCreateScaledFont(const FontDescription&, float scaleFactor) const { float size = m_platformData.size() * scaleFactor; CTFontSymbolicTraits fontTraits = CTFontGetSymbolicTraits(m_platformData.font()); RetainPtr<CTFontDescriptorRef> fontDescriptor = adoptCF(CTFontCopyFontDescriptor(m_platformData.font())); RetainPtr<CTFontRef> scaledFont = adoptCF(CTFontCreateWithFontDescriptor(fontDescriptor.get(), size, nullptr)); return createDerivativeFont(scaledFont.get(), size, m_platformData.orientation(), fontTraits, m_platformData.m_syntheticBold, m_platformData.m_syntheticOblique); } void Font::determinePitch() { #if USE(APPKIT) NSFont* f = m_platformData.nsFont(); // Special case Osaka-Mono. // According to <rdar://problem/3999467>, we should treat Osaka-Mono as fixed pitch. // Note that the AppKit does not report Osaka-Mono as fixed pitch. // Special case MS-PGothic. // According to <rdar://problem/4032938>, we should not treat MS-PGothic as fixed pitch. // Note that AppKit does report MS-PGothic as fixed pitch. // Special case MonotypeCorsiva // According to <rdar://problem/5454704>, we should not treat MonotypeCorsiva as fixed pitch. // Note that AppKit does report MonotypeCorsiva as fixed pitch. NSString *name = [f fontName]; m_treatAsFixedPitch = ([f isFixedPitch] || [f _isFakeFixedPitch] || [name caseInsensitiveCompare:@"Osaka-Mono"] == NSOrderedSame) && [name caseInsensitiveCompare:@"MS-PGothic"] != NSOrderedSame && [name caseInsensitiveCompare:@"MonotypeCorsiva"] != NSOrderedSame; #else CTFontRef ctFont = m_platformData.font(); m_treatAsFixedPitch = false; if (!ctFont) return; // CTFont is null in the case of SVG fonts for example. RetainPtr<CFStringRef> fullName = adoptCF(CTFontCopyFullName(ctFont)); RetainPtr<CFStringRef> familyName = adoptCF(CTFontCopyFamilyName(ctFont)); m_treatAsFixedPitch = CGFontIsFixedPitch(m_platformData.cgFont()) || (fullName && (CFStringCompare(fullName.get(), CFSTR("Osaka-Mono"), kCFCompareCaseInsensitive) == kCFCompareEqualTo || CFStringCompare(fullName.get(), CFSTR("MS-PGothic"), kCFCompareCaseInsensitive) == kCFCompareEqualTo)); if (familyName && CFStringCompare(familyName.get(), CFSTR("Courier New"), kCFCompareCaseInsensitive) == kCFCompareEqualTo) { // Special case Courier New to not be treated as fixed pitch, as this will make use of a hacked space width which is undesireable for iPhone (see rdar://6269783). m_treatAsFixedPitch = false; } #endif } FloatRect Font::platformBoundsForGlyph(Glyph glyph) const { FloatRect boundingBox; boundingBox = CTFontGetBoundingRectsForGlyphs(m_platformData.ctFont(), platformData().orientation() == Vertical ? kCTFontOrientationVertical : kCTFontOrientationHorizontal, &glyph, 0, 1); boundingBox.setY(-boundingBox.maxY()); if (m_syntheticBoldOffset) boundingBox.setWidth(boundingBox.width() + m_syntheticBoldOffset); return boundingBox; } static inline CGFontRenderingStyle renderingStyle(const FontPlatformData& platformData) { #if USE(APPKIT) CGFontRenderingStyle style = kCGFontRenderingStyleAntialiasing | kCGFontRenderingStyleSubpixelPositioning | kCGFontRenderingStyleSubpixelQuantization; NSFont *font = platformData.nsFont(); if (font) { switch ([font renderingMode]) { case NSFontIntegerAdvancementsRenderingMode: style = 0; break; case NSFontAntialiasedIntegerAdvancementsRenderingMode: style = kCGFontRenderingStyleAntialiasing; break; default: break; } } return style; #else UNUSED_PARAM(platformData); return kCGFontRenderingStyleAntialiasing | kCGFontRenderingStyleSubpixelPositioning | kCGFontRenderingStyleSubpixelQuantization | kCGFontAntialiasingStyleUnfiltered; #endif } static inline bool advanceForColorBitmapFont(const FontPlatformData& platformData, Glyph glyph, CGSize& advance) { #if PLATFORM(MAC) NSFont *font = platformData.nsFont(); if (!font || !platformData.isColorBitmapFont()) return false; advance = NSSizeToCGSize([font advancementForGlyph:glyph]); return true; #else UNUSED_PARAM(platformData); UNUSED_PARAM(glyph); UNUSED_PARAM(advance); return false; #endif } static inline bool canUseFastGlyphAdvanceGetter(const Font& font, Glyph glyph, CGSize& advance, bool& populatedAdvance) { const FontPlatformData& platformData = font.platformData(); // Fast getter doesn't take custom tracking into account if (font.hasCustomTracking()) return false; // Fast getter doesn't work for emoji if (platformData.isEmoji()) return false; // ... or for any bitmap fonts in general if (advanceForColorBitmapFont(platformData, glyph, advance)) { populatedAdvance = true; return false; } return true; } float Font::platformWidthForGlyph(Glyph glyph) const { CGSize advance = CGSizeZero; bool horizontal = platformData().orientation() == Horizontal; bool populatedAdvance = false; if ((horizontal || m_isBrokenIdeographFallback) && canUseFastGlyphAdvanceGetter(*this, glyph, advance, populatedAdvance)) { float pointSize = platformData().m_size; CGAffineTransform m = CGAffineTransformMakeScale(pointSize, pointSize); if (!CGFontGetGlyphAdvancesForStyle(platformData().cgFont(), &m, renderingStyle(platformData()), &glyph, 1, &advance)) { RetainPtr<CFStringRef> fullName = adoptCF(CGFontCopyFullName(platformData().cgFont())); LOG_ERROR("Unable to cache glyph widths for %@ %f", fullName.get(), pointSize); advance.width = 0; } } else if (!populatedAdvance) CTFontGetAdvancesForGlyphs(m_platformData.ctFont(), horizontal ? kCTFontOrientationHorizontal : kCTFontOrientationVertical, &glyph, &advance, 1); return advance.width + m_syntheticBoldOffset; } struct ProviderInfo { const UChar* characters; size_t length; CFDictionaryRef attributes; }; static const UniChar* provideStringAndAttributes(CFIndex stringIndex, CFIndex* count, CFDictionaryRef* attributes, void* context) { ProviderInfo* info = static_cast<struct ProviderInfo*>(context); if (stringIndex < 0 || static_cast<size_t>(stringIndex) >= info->length) return 0; *count = info->length - stringIndex; *attributes = info->attributes; return info->characters + stringIndex; } bool Font::canRenderCombiningCharacterSequence(const UChar* characters, size_t length) const { ASSERT(isMainThread()); if (!m_combiningCharacterSequenceSupport) m_combiningCharacterSequenceSupport = std::make_unique<HashMap<String, bool>>(); WTF::HashMap<String, bool>::AddResult addResult = m_combiningCharacterSequenceSupport->add(String(characters, length), false); if (!addResult.isNewEntry) return addResult.iterator->value; RetainPtr<CFTypeRef> fontEqualityObject = platformData().objectForEqualityCheck(); ProviderInfo info = { characters, length, getCFStringAttributes(false, platformData().orientation()) }; RetainPtr<CTLineRef> line = adoptCF(CTLineCreateWithUniCharProvider(&provideStringAndAttributes, 0, &info)); CFArrayRef runArray = CTLineGetGlyphRuns(line.get()); CFIndex runCount = CFArrayGetCount(runArray); for (CFIndex r = 0; r < runCount; r++) { CTRunRef ctRun = static_cast<CTRunRef>(CFArrayGetValueAtIndex(runArray, r)); ASSERT(CFGetTypeID(ctRun) == CTRunGetTypeID()); CFDictionaryRef runAttributes = CTRunGetAttributes(ctRun); CTFontRef runFont = static_cast<CTFontRef>(CFDictionaryGetValue(runAttributes, kCTFontAttributeName)); if (!CFEqual(fontEqualityObject.get(), FontPlatformData::objectForEqualityCheck(runFont).get())) return false; } addResult.iterator->value = true; return true; } #if USE(APPKIT) const Font* Font::compositeFontReferenceFont(NSFont *key) const { if (!key || CFEqual(adoptCF(CTFontCopyPostScriptName(CTFontRef(key))).get(), CFSTR("LastResort"))) return nullptr; if (!m_derivedFontData) m_derivedFontData = std::make_unique<DerivedFontData>(isCustomFont()); auto addResult = m_derivedFontData->compositeFontReferences.add(key, nullptr); if (addResult.isNewEntry) { NSFont *substituteFont = [key printerFont]; CTFontSymbolicTraits traits = CTFontGetSymbolicTraits((CTFontRef)substituteFont); bool syntheticBold = platformData().syntheticBold() && !(traits & kCTFontBoldTrait); bool syntheticOblique = platformData().syntheticOblique() && !(traits & kCTFontItalicTrait); FontPlatformData substitutePlatform(reinterpret_cast<CTFontRef>(substituteFont), platformData().size(), syntheticBold, syntheticOblique, platformData().orientation(), platformData().widthVariant()); addResult.iterator->value = Font::create(substitutePlatform, isCustomFont()); } return addResult.iterator->value.get(); } #endif } // namespace WebCore