/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* vim: set ts=8 sts=2 et sw=2 tw=80: */ /* 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/. */ #include "ScaledFontMac.h" #include "UnscaledFontMac.h" #include "mozilla/webrender/WebRenderTypes.h" #ifdef USE_SKIA # include "PathSkia.h" # include "skia/include/core/SkPaint.h" # include "skia/include/core/SkPath.h" # include "skia/include/ports/SkTypeface_mac.h" #endif #include #include #ifdef MOZ_WIDGET_UIKIT # include #endif #include "nsCocoaFeatures.h" #include "mozilla/gfx/Logging.h" #ifdef MOZ_WIDGET_COCOA // prototype for private API extern "C" { CGPathRef CGFontGetGlyphPath(CGFontRef fontRef, CGAffineTransform* textTransform, int unknown, CGGlyph glyph); }; #endif #ifdef USE_CAIRO_SCALED_FONT # include "cairo-quartz.h" #endif namespace mozilla { namespace gfx { // Simple helper class to automatically release a CFObject when it goes out // of scope. template class AutoRelease final { public: explicit AutoRelease(T aObject) : mObject(aObject) {} ~AutoRelease() { if (mObject) { CFRelease(mObject); } } void operator=(T aObject) { if (mObject) { CFRelease(mObject); } mObject = aObject; } operator T() { return mObject; } T forget() { T obj = mObject; mObject = nullptr; return obj; } private: T mObject; }; // Helper to create a CTFont from a CGFont, copying any variations that were // set on the original CGFont. static CTFontRef CreateCTFontFromCGFontWithVariations(CGFontRef aCGFont, CGFloat aSize, bool aInstalledFont) { // Avoid calling potentially buggy variation APIs on pre-Sierra macOS // versions (see bug 1331683). // // And on HighSierra, CTFontCreateWithGraphicsFont properly carries over // variation settings from the CGFont to CTFont, so we don't need to do // the extra work here -- and this seems to avoid Core Text crashiness // seen in bug 1454094. // // However, for installed fonts it seems we DO need to copy the variations // explicitly even on 10.13, otherwise fonts fail to render (as in bug // 1455494) when non-default values are used. Fortunately, the crash // mentioned above occurs with data fonts, not (AFAICT) with system- // installed fonts. // // So we only need to do this "the hard way" on Sierra, and for installed // fonts on HighSierra+; otherwise, just let the standard CTFont function // do its thing. // // NOTE in case this ever needs further adjustment: there is similar logic // in four places in the tree (sadly): // CreateCTFontFromCGFontWithVariations in gfxMacFont.cpp // CreateCTFontFromCGFontWithVariations in ScaledFontMac.cpp // CreateCTFontFromCGFontWithVariations in cairo-quartz-font.c // ctfont_create_exact_copy in SkFontHost_mac.cpp CTFontRef ctFont; if (nsCocoaFeatures::OnSierraExactly() || (aInstalledFont && nsCocoaFeatures::OnHighSierraOrLater())) { CFDictionaryRef vars = CGFontCopyVariations(aCGFont); if (vars) { CFDictionaryRef varAttr = CFDictionaryCreate( nullptr, (const void**)&kCTFontVariationAttribute, (const void**)&vars, 1, &kCFTypeDictionaryKeyCallBacks, &kCFTypeDictionaryValueCallBacks); CFRelease(vars); CTFontDescriptorRef varDesc = CTFontDescriptorCreateWithAttributes(varAttr); CFRelease(varAttr); ctFont = CTFontCreateWithGraphicsFont(aCGFont, aSize, nullptr, varDesc); CFRelease(varDesc); } else { ctFont = CTFontCreateWithGraphicsFont(aCGFont, aSize, nullptr, nullptr); } } else { ctFont = CTFontCreateWithGraphicsFont(aCGFont, aSize, nullptr, nullptr); } return ctFont; } ScaledFontMac::ScaledFontMac(CGFontRef aFont, const RefPtr& aUnscaledFont, Float aSize, bool aOwnsFont, const DeviceColor& aFontSmoothingBackgroundColor, bool aUseFontSmoothing, bool aApplySyntheticBold) : ScaledFontBase(aUnscaledFont, aSize), mFont(aFont), mFontSmoothingBackgroundColor(aFontSmoothingBackgroundColor), mUseFontSmoothing(aUseFontSmoothing), mApplySyntheticBold(aApplySyntheticBold) { if (!aOwnsFont) { // XXX: should we be taking a reference CGFontRetain(aFont); } auto unscaledMac = static_cast(aUnscaledFont.get()); bool dataFont = unscaledMac->IsDataFont(); mCTFont = CreateCTFontFromCGFontWithVariations(aFont, aSize, !dataFont); } ScaledFontMac::ScaledFontMac(CTFontRef aFont, const RefPtr& aUnscaledFont, const DeviceColor& aFontSmoothingBackgroundColor, bool aUseFontSmoothing, bool aApplySyntheticBold) : ScaledFontBase(aUnscaledFont, CTFontGetSize(aFont)), mCTFont(aFont), mFontSmoothingBackgroundColor(aFontSmoothingBackgroundColor), mUseFontSmoothing(aUseFontSmoothing), mApplySyntheticBold(aApplySyntheticBold) { mFont = CTFontCopyGraphicsFont(aFont, nullptr); CFRetain(mCTFont); } ScaledFontMac::~ScaledFontMac() { CFRelease(mCTFont); CGFontRelease(mFont); } #ifdef USE_SKIA SkTypeface* ScaledFontMac::CreateSkTypeface() { return SkCreateTypefaceFromCTFont(mCTFont); } void ScaledFontMac::SetupSkFontDrawOptions(SkFont& aFont) { aFont.setSubpixel(true); // Normally, Skia enables LCD FontSmoothing which creates thicker fonts // and also enables subpixel AA. CoreGraphics without font smoothing // explicitly creates thinner fonts and grayscale AA. // CoreGraphics doesn't support a configuration that produces thicker // fonts with grayscale AA as LCD Font Smoothing enables or disables // both. However, Skia supports it by enabling font smoothing (producing // subpixel AA) and converts it to grayscale AA. Since Skia doesn't // support subpixel AA on transparent backgrounds, we still want font // smoothing for the thicker fonts, even if it is grayscale AA. // // With explicit Grayscale AA (from -moz-osx-font-smoothing:grayscale), // we want to have grayscale AA with no smoothing at all. This means // disabling the LCD font smoothing behaviour. // To accomplish this we have to explicitly disable hinting, // and disable LCDRenderText. if (aFont.getEdging() == SkFont::Edging::kAntiAlias && !mUseFontSmoothing) { aFont.setHinting(SkFontHinting::kNone); } } #endif // private API here are the public options on OS X // CTFontCreatePathForGlyph // ATSUGlyphGetCubicPaths // we've used this in cairo sucessfully for some time. // Note: cairo dlsyms it. We could do that but maybe it's // safe just to use? already_AddRefed ScaledFontMac::GetPathForGlyphs( const GlyphBuffer& aBuffer, const DrawTarget* aTarget) { return ScaledFontBase::GetPathForGlyphs(aBuffer, aTarget); } static uint32_t CalcTableChecksum(const uint32_t* tableStart, uint32_t length, bool skipChecksumAdjust = false) { uint32_t sum = 0L; const uint32_t* table = tableStart; const uint32_t* end = table + length / sizeof(uint32_t); while (table < end) { if (skipChecksumAdjust && (table - tableStart) == 2) { table++; } else { sum += CFSwapInt32BigToHost(*table++); } } // The length is not 4-byte aligned, but we still must process the remaining // bytes. if (length & 3) { // Pad with zero before adding to the checksum. uint32_t last = 0; memcpy(&last, end, length & 3); sum += CFSwapInt32BigToHost(last); } return sum; } struct TableRecord { uint32_t tag; uint32_t checkSum; uint32_t offset; uint32_t length; CFDataRef data; }; static int maxPow2LessThanEqual(int a) { int x = 1; int shift = 0; while ((x << (shift + 1)) <= a) { shift++; } return shift; } struct writeBuf final { explicit writeBuf(int size) { this->data = new unsigned char[size]; this->offset = 0; } ~writeBuf() { delete[] this->data; } template void writeElement(T a) { *reinterpret_cast(&this->data[this->offset]) = a; this->offset += sizeof(T); } void writeMem(const void* data, unsigned long length) { memcpy(&this->data[this->offset], data, length); this->offset += length; } void align() { while (this->offset & 3) { this->data[this->offset] = 0; this->offset++; } } unsigned char* data; int offset; }; bool UnscaledFontMac::GetFontFileData(FontFileDataOutput aDataCallback, void* aBaton) { // We'll reconstruct a TTF font from the tables we can get from the CGFont CFArrayRef tags = CGFontCopyTableTags(mFont); CFIndex count = CFArrayGetCount(tags); TableRecord* records = new TableRecord[count]; uint32_t offset = 0; offset += sizeof(uint32_t) * 3; offset += sizeof(uint32_t) * 4 * count; bool CFF = false; for (CFIndex i = 0; i < count; i++) { uint32_t tag = (uint32_t)(uintptr_t)CFArrayGetValueAtIndex(tags, i); if (tag == 0x43464620) { // 'CFF ' CFF = true; } CFDataRef data = CGFontCopyTableForTag(mFont, tag); // Bug 1602391 suggests CGFontCopyTableForTag can fail, even though we just // got the tag from the font via CGFontCopyTableTags above. If we can catch // this (e.g. in fuzz-testing) it'd be good to understand when it happens, // but in any case we'll handle it safely below by treating the table as // zero-length. MOZ_ASSERT(data, "failed to get font table data"); records[i].tag = tag; records[i].offset = offset; records[i].data = data; if (data) { records[i].length = CFDataGetLength(data); bool skipChecksumAdjust = (tag == 0x68656164); // 'head' records[i].checkSum = CalcTableChecksum( reinterpret_cast(CFDataGetBytePtr(data)), records[i].length, skipChecksumAdjust); offset += records[i].length; // 32 bit align the tables offset = (offset + 3) & ~3; } else { records[i].length = 0; records[i].checkSum = 0; } } CFRelease(tags); struct writeBuf buf(offset); // write header/offset table if (CFF) { buf.writeElement(CFSwapInt32HostToBig(0x4f54544f)); } else { buf.writeElement(CFSwapInt32HostToBig(0x00010000)); } buf.writeElement(CFSwapInt16HostToBig(count)); int maxPow2Count = maxPow2LessThanEqual(count); buf.writeElement(CFSwapInt16HostToBig((1 << maxPow2Count) * 16)); buf.writeElement(CFSwapInt16HostToBig(maxPow2Count)); buf.writeElement(CFSwapInt16HostToBig((count - (1 << maxPow2Count)) * 16)); // write table record entries for (CFIndex i = 0; i < count; i++) { buf.writeElement(CFSwapInt32HostToBig(records[i].tag)); buf.writeElement(CFSwapInt32HostToBig(records[i].checkSum)); buf.writeElement(CFSwapInt32HostToBig(records[i].offset)); buf.writeElement(CFSwapInt32HostToBig(records[i].length)); } // write tables int checkSumAdjustmentOffset = 0; for (CFIndex i = 0; i < count; i++) { if (records[i].tag == 0x68656164) { checkSumAdjustmentOffset = buf.offset + 2 * 4; } if (records[i].data) { buf.writeMem(CFDataGetBytePtr(records[i].data), records[i].length); buf.align(); CFRelease(records[i].data); } } delete[] records; // clear the checksumAdjust field before checksumming the whole font memset(&buf.data[checkSumAdjustmentOffset], 0, sizeof(uint32_t)); uint32_t fontChecksum = CFSwapInt32HostToBig( 0xb1b0afba - CalcTableChecksum(reinterpret_cast(buf.data), offset)); // set checkSumAdjust to the computed checksum memcpy(&buf.data[checkSumAdjustmentOffset], &fontChecksum, sizeof(fontChecksum)); // we always use an index of 0 aDataCallback(buf.data, buf.offset, 0, aBaton); return true; } bool UnscaledFontMac::GetFontDescriptor(FontDescriptorOutput aCb, void* aBaton) { if (mIsDataFont) { return false; } AutoRelease psname(CGFontCopyPostScriptName(mFont)); if (!psname) { return false; } char buf[256]; const char* cstr = CFStringGetCStringPtr(psname, kCFStringEncodingUTF8); if (!cstr) { if (!CFStringGetCString(psname, buf, sizeof(buf), kCFStringEncodingUTF8)) { return false; } cstr = buf; } aCb(reinterpret_cast(cstr), strlen(cstr), 0, aBaton); return true; } static void CollectVariationsFromDictionary(const void* aKey, const void* aValue, void* aContext) { auto keyPtr = static_cast(aKey); auto valuePtr = static_cast(aValue); auto outVariations = static_cast*>(aContext); if (CFGetTypeID(keyPtr) == CFNumberGetTypeID() && CFGetTypeID(valuePtr) == CFNumberGetTypeID()) { uint64_t t; double v; if (CFNumberGetValue(static_cast(keyPtr), kCFNumberSInt64Type, &t) && CFNumberGetValue(static_cast(valuePtr), kCFNumberDoubleType, &v)) { outVariations->push_back(FontVariation{uint32_t(t), float(v)}); } } } static bool GetVariationsForCTFont(CTFontRef aCTFont, std::vector* aOutVariations) { if (!aCTFont) { return true; } AutoRelease dict(CTFontCopyVariation(aCTFont)); CFIndex count = dict ? CFDictionaryGetCount(dict) : 0; if (count > 0) { aOutVariations->reserve(count); CFDictionaryApplyFunction(dict, CollectVariationsFromDictionary, aOutVariations); } return true; } bool ScaledFontMac::GetFontInstanceData(FontInstanceDataOutput aCb, void* aBaton) { // Collect any variation settings that were incorporated into the CTFont. std::vector variations; if (!GetVariationsForCTFont(mCTFont, &variations)) { return false; } InstanceData instance(this); aCb(reinterpret_cast(&instance), sizeof(instance), variations.data(), variations.size(), aBaton); return true; } bool ScaledFontMac::GetWRFontInstanceOptions( Maybe* aOutOptions, Maybe* aOutPlatformOptions, std::vector* aOutVariations) { GetVariationsForCTFont(mCTFont, aOutVariations); wr::FontInstanceOptions options; options.render_mode = wr::FontRenderMode::Subpixel; options.flags = wr::FontInstanceFlags::SUBPIXEL_POSITION; if (mUseFontSmoothing) { options.flags |= wr::FontInstanceFlags::FONT_SMOOTHING; } if (mApplySyntheticBold) { options.flags |= wr::FontInstanceFlags::SYNTHETIC_BOLD; } options.bg_color = wr::ToColorU(mFontSmoothingBackgroundColor); options.synthetic_italics = wr::DegreesToSyntheticItalics(GetSyntheticObliqueAngle()); *aOutOptions = Some(options); return true; } ScaledFontMac::InstanceData::InstanceData( const wr::FontInstanceOptions* aOptions, const wr::FontInstancePlatformOptions* aPlatformOptions) : mUseFontSmoothing(true), mApplySyntheticBold(false) { if (aOptions) { if (!(aOptions->flags & wr::FontInstanceFlags::FONT_SMOOTHING)) { mUseFontSmoothing = false; } if (aOptions->flags & wr::FontInstanceFlags::SYNTHETIC_BOLD) { mApplySyntheticBold = true; } if (aOptions->bg_color.a != 0) { mFontSmoothingBackgroundColor = DeviceColor::FromU8(aOptions->bg_color.r, aOptions->bg_color.g, aOptions->bg_color.b, aOptions->bg_color.a); } } } static CFDictionaryRef CreateVariationDictionaryOrNull( CGFontRef aCGFont, CFArrayRef& aAxesCache, uint32_t aVariationCount, const FontVariation* aVariations) { if (!aAxesCache) { AutoRelease ctFont( CTFontCreateWithGraphicsFont(aCGFont, 0, nullptr, nullptr)); aAxesCache = CTFontCopyVariationAxes(ctFont); if (!aAxesCache) { return nullptr; } } CFIndex axisCount = CFArrayGetCount(aAxesCache); AutoRelease dict(CFDictionaryCreateMutable( kCFAllocatorDefault, axisCount, &kCFTypeDictionaryKeyCallBacks, &kCFTypeDictionaryValueCallBacks)); // Number of variation settings passed in the aVariations parameter. // This will typically be a very low value, so we just linear-search them. bool allDefaultValues = true; for (CFIndex i = 0; i < axisCount; ++i) { // We sanity-check the axis info found in the CTFont, and bail out // (returning null) if it doesn't have the expected types. CFTypeRef axisInfo = CFArrayGetValueAtIndex(aAxesCache, i); if (CFDictionaryGetTypeID() != CFGetTypeID(axisInfo)) { return nullptr; } CFDictionaryRef axis = static_cast(axisInfo); CFTypeRef axisTag = CFDictionaryGetValue(axis, kCTFontVariationAxisIdentifierKey); if (!axisTag || CFGetTypeID(axisTag) != CFNumberGetTypeID()) { return nullptr; } int64_t tagLong; if (!CFNumberGetValue(static_cast(axisTag), kCFNumberSInt64Type, &tagLong)) { return nullptr; } CFTypeRef axisName = CFDictionaryGetValue(axis, kCTFontVariationAxisNameKey); if (!axisName || CFGetTypeID(axisName) != CFStringGetTypeID()) { return nullptr; } // Clamp axis values to the supported range. CFTypeRef min = CFDictionaryGetValue(axis, kCTFontVariationAxisMinimumValueKey); CFTypeRef max = CFDictionaryGetValue(axis, kCTFontVariationAxisMaximumValueKey); CFTypeRef def = CFDictionaryGetValue(axis, kCTFontVariationAxisDefaultValueKey); if (!min || CFGetTypeID(min) != CFNumberGetTypeID() || !max || CFGetTypeID(max) != CFNumberGetTypeID() || !def || CFGetTypeID(def) != CFNumberGetTypeID()) { return nullptr; } double minDouble; double maxDouble; double defDouble; if (!CFNumberGetValue(static_cast(min), kCFNumberDoubleType, &minDouble) || !CFNumberGetValue(static_cast(max), kCFNumberDoubleType, &maxDouble) || !CFNumberGetValue(static_cast(def), kCFNumberDoubleType, &defDouble)) { return nullptr; } double value = defDouble; for (uint32_t j = 0; j < aVariationCount; ++j) { if (aVariations[j].mTag == tagLong) { value = std::min(std::max(aVariations[j].mValue, minDouble), maxDouble); if (value != defDouble) { allDefaultValues = false; } break; } } AutoRelease valueNumber( CFNumberCreate(kCFAllocatorDefault, kCFNumberDoubleType, &value)); CFDictionaryAddValue(dict, axisName, valueNumber); } if (allDefaultValues) { // We didn't actually set any non-default values, so throw away the // variations dictionary and just use the default rendering. return nullptr; } return dict.forget(); } static CFDictionaryRef CreateVariationTagDictionaryOrNull( CTFontRef aCTFont, uint32_t aVariationCount, const FontVariation* aVariations) { AutoRelease axes(CTFontCopyVariationAxes(aCTFont)); CFIndex axisCount = CFArrayGetCount(axes); AutoRelease dict(CFDictionaryCreateMutable( kCFAllocatorDefault, axisCount, &kCFTypeDictionaryKeyCallBacks, &kCFTypeDictionaryValueCallBacks)); // Number of variation settings passed in the aVariations parameter. // This will typically be a very low value, so we just linear-search them. bool allDefaultValues = true; for (CFIndex i = 0; i < axisCount; ++i) { // We sanity-check the axis info found in the CTFont, and bail out // (returning null) if it doesn't have the expected types. CFTypeRef axisInfo = CFArrayGetValueAtIndex(axes, i); if (CFDictionaryGetTypeID() != CFGetTypeID(axisInfo)) { return nullptr; } CFDictionaryRef axis = static_cast(axisInfo); CFTypeRef axisTag = CFDictionaryGetValue(axis, kCTFontVariationAxisIdentifierKey); if (!axisTag || CFGetTypeID(axisTag) != CFNumberGetTypeID()) { return nullptr; } int64_t tagLong; if (!CFNumberGetValue(static_cast(axisTag), kCFNumberSInt64Type, &tagLong)) { return nullptr; } // Clamp axis values to the supported range. CFTypeRef min = CFDictionaryGetValue(axis, kCTFontVariationAxisMinimumValueKey); CFTypeRef max = CFDictionaryGetValue(axis, kCTFontVariationAxisMaximumValueKey); CFTypeRef def = CFDictionaryGetValue(axis, kCTFontVariationAxisDefaultValueKey); if (!min || CFGetTypeID(min) != CFNumberGetTypeID() || !max || CFGetTypeID(max) != CFNumberGetTypeID() || !def || CFGetTypeID(def) != CFNumberGetTypeID()) { return nullptr; } double minDouble; double maxDouble; double defDouble; if (!CFNumberGetValue(static_cast(min), kCFNumberDoubleType, &minDouble) || !CFNumberGetValue(static_cast(max), kCFNumberDoubleType, &maxDouble) || !CFNumberGetValue(static_cast(def), kCFNumberDoubleType, &defDouble)) { return nullptr; } double value = defDouble; for (uint32_t j = 0; j < aVariationCount; ++j) { if (aVariations[j].mTag == tagLong) { value = std::min(std::max(aVariations[j].mValue, minDouble), maxDouble); if (value != defDouble) { allDefaultValues = false; } break; } } AutoRelease valueNumber( CFNumberCreate(kCFAllocatorDefault, kCFNumberDoubleType, &value)); CFDictionaryAddValue(dict, axisTag, valueNumber); } if (allDefaultValues) { // We didn't actually set any non-default values, so throw away the // variations dictionary and just use the default rendering. return nullptr; } return dict.forget(); } /* static */ CGFontRef UnscaledFontMac::CreateCGFontWithVariations( CGFontRef aFont, CFArrayRef& aAxesCache, uint32_t aVariationCount, const FontVariation* aVariations) { MOZ_ASSERT(aVariationCount > 0); MOZ_ASSERT(aVariations); AutoRelease varDict(CreateVariationDictionaryOrNull( aFont, aAxesCache, aVariationCount, aVariations)); if (!varDict) { return nullptr; } return CGFontCreateCopyWithVariations(aFont, varDict); } already_AddRefed UnscaledFontMac::CreateScaledFont( Float aGlyphSize, const uint8_t* aInstanceData, uint32_t aInstanceDataLength, const FontVariation* aVariations, uint32_t aNumVariations) { if (aInstanceDataLength < sizeof(ScaledFontMac::InstanceData)) { gfxWarning() << "Mac scaled font instance data is truncated."; return nullptr; } const ScaledFontMac::InstanceData& instanceData = *reinterpret_cast(aInstanceData); RefPtr scaledFont; if (mFontDesc) { AutoRelease font( CTFontCreateWithFontDescriptor(mFontDesc, aGlyphSize, nullptr)); if (aNumVariations > 0) { AutoRelease varDict(CreateVariationTagDictionaryOrNull( font, aNumVariations, aVariations)); CFDictionaryRef varAttr = CFDictionaryCreate( nullptr, (const void**)&kCTFontVariationAttribute, (const void**)&varDict, 1, &kCFTypeDictionaryKeyCallBacks, &kCFTypeDictionaryValueCallBacks); AutoRelease fontDesc( CTFontDescriptorCreateCopyWithAttributes(mFontDesc, varAttr)); if (!fontDesc) { return nullptr; } font = CTFontCreateWithFontDescriptor(fontDesc, aGlyphSize, nullptr); } scaledFont = new ScaledFontMac( font, this, instanceData.mFontSmoothingBackgroundColor, instanceData.mUseFontSmoothing, instanceData.mApplySyntheticBold); } else { CGFontRef fontRef = mFont; if (aNumVariations > 0) { CGFontRef varFont = CreateCGFontWithVariations( mFont, mAxesCache, aNumVariations, aVariations); if (varFont) { fontRef = varFont; } } scaledFont = new ScaledFontMac(fontRef, this, aGlyphSize, fontRef != mFont, instanceData.mFontSmoothingBackgroundColor, instanceData.mUseFontSmoothing, instanceData.mApplySyntheticBold); } return scaledFont.forget(); } already_AddRefed UnscaledFontMac::CreateScaledFontFromWRFont( Float aGlyphSize, const wr::FontInstanceOptions* aOptions, const wr::FontInstancePlatformOptions* aPlatformOptions, const FontVariation* aVariations, uint32_t aNumVariations) { ScaledFontMac::InstanceData instanceData(aOptions, aPlatformOptions); return CreateScaledFont(aGlyphSize, reinterpret_cast(&instanceData), sizeof(instanceData), aVariations, aNumVariations); } #ifdef USE_CAIRO_SCALED_FONT cairo_font_face_t* ScaledFontMac::CreateCairoFontFace( cairo_font_options_t* aFontOptions) { MOZ_ASSERT(mFont); return cairo_quartz_font_face_create_for_cgfont(mFont); } #endif already_AddRefed UnscaledFontMac::CreateFromFontDescriptor( const uint8_t* aData, uint32_t aDataLength, uint32_t aIndex) { if (aDataLength == 0) { gfxWarning() << "Mac font descriptor is truncated."; return nullptr; } CFStringRef name = CFStringCreateWithBytes(kCFAllocatorDefault, (const UInt8*)aData, aDataLength, kCFStringEncodingUTF8, false); if (!name) { return nullptr; } CGFontRef font = CGFontCreateWithFontName(name); CFRelease(name); if (!font) { return nullptr; } RefPtr unscaledFont = new UnscaledFontMac(font); CFRelease(font); return unscaledFont.forget(); } } // namespace gfx } // namespace mozilla