/* -*- Mode: C++; tab-width: 20; indent-tabs-mode: nil; c-basic-offset: 4 -*- */ /* 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 "mozilla/DebugOnly.h" #include "mozilla/MathAlgorithms.h" #include "mozilla/Logging.h" #include "nsServiceManagerUtils.h" #include "nsILanguageAtomService.h" #include "gfxFontEntry.h" #include "gfxTextRun.h" #include "gfxPlatform.h" #include "nsGkAtoms.h" #include "gfxTypes.h" #include "gfxContext.h" #include "gfxFontConstants.h" #include "gfxHarfBuzzShaper.h" #include "gfxUserFontSet.h" #include "gfxPlatformFontList.h" #include "nsUnicodeProperties.h" #include "nsMathUtils.h" #include "nsBidiUtils.h" #include "nsUnicodeRange.h" #include "nsStyleConsts.h" #include "mozilla/AppUnits.h" #include "mozilla/FloatingPoint.h" #include "mozilla/Likely.h" #include "mozilla/MemoryReporting.h" #include "mozilla/Preferences.h" #include "mozilla/Services.h" #include "mozilla/Telemetry.h" #include "gfxSVGGlyphs.h" #include "gfx2DGlue.h" #include "cairo.h" #include "harfbuzz/hb.h" #include "harfbuzz/hb-ot.h" #include "graphite2/Font.h" #include using namespace mozilla; using namespace mozilla::gfx; using namespace mozilla::unicode; using mozilla::services::GetObserverService; void gfxCharacterMap::NotifyReleased() { gfxPlatformFontList *fontlist = gfxPlatformFontList::PlatformFontList(); if (mShared) { fontlist->RemoveCmap(this); } delete this; } gfxFontEntry::gfxFontEntry() : mStyle(NS_FONT_STYLE_NORMAL), mFixedPitch(false), mIsValid(true), mIsBadUnderlineFont(false), mIsUserFontContainer(false), mIsDataUserFont(false), mIsLocalUserFont(false), mStandardFace(false), mSymbolFont(false), mIgnoreGDEF(false), mIgnoreGSUB(false), mSVGInitialized(false), mHasSpaceFeaturesInitialized(false), mHasSpaceFeatures(false), mHasSpaceFeaturesKerning(false), mHasSpaceFeaturesNonKerning(false), mSkipDefaultFeatureSpaceCheck(false), mGraphiteSpaceContextualsInitialized(false), mHasGraphiteSpaceContextuals(false), mSpaceGlyphIsInvisible(false), mSpaceGlyphIsInvisibleInitialized(false), mCheckedForGraphiteTables(false), mHasCmapTable(false), mGrFaceInitialized(false), mCheckedForColorGlyph(false), mWeight(500), mStretch(NS_FONT_STRETCH_NORMAL), mUVSOffset(0), mUVSData(nullptr), mLanguageOverride(NO_FONT_LANGUAGE_OVERRIDE), mCOLR(nullptr), mCPAL(nullptr), mUnitsPerEm(0), mHBFace(nullptr), mGrFace(nullptr), mGrFaceRefCnt(0), mComputedSizeOfUserFont(0) { memset(&mDefaultSubSpaceFeatures, 0, sizeof(mDefaultSubSpaceFeatures)); memset(&mNonDefaultSubSpaceFeatures, 0, sizeof(mNonDefaultSubSpaceFeatures)); } gfxFontEntry::gfxFontEntry(const nsAString& aName, bool aIsStandardFace) : mName(aName), mStyle(NS_FONT_STYLE_NORMAL), mFixedPitch(false), mIsValid(true), mIsBadUnderlineFont(false), mIsUserFontContainer(false), mIsDataUserFont(false), mIsLocalUserFont(false), mStandardFace(aIsStandardFace), mSymbolFont(false), mIgnoreGDEF(false), mIgnoreGSUB(false), mSVGInitialized(false), mHasSpaceFeaturesInitialized(false), mHasSpaceFeatures(false), mHasSpaceFeaturesKerning(false), mHasSpaceFeaturesNonKerning(false), mSkipDefaultFeatureSpaceCheck(false), mGraphiteSpaceContextualsInitialized(false), mHasGraphiteSpaceContextuals(false), mSpaceGlyphIsInvisible(false), mSpaceGlyphIsInvisibleInitialized(false), mCheckedForGraphiteTables(false), mHasCmapTable(false), mGrFaceInitialized(false), mCheckedForColorGlyph(false), mWeight(500), mStretch(NS_FONT_STRETCH_NORMAL), mUVSOffset(0), mUVSData(nullptr), mLanguageOverride(NO_FONT_LANGUAGE_OVERRIDE), mCOLR(nullptr), mCPAL(nullptr), mUnitsPerEm(0), mHBFace(nullptr), mGrFace(nullptr), mGrFaceRefCnt(0), mComputedSizeOfUserFont(0) { memset(&mDefaultSubSpaceFeatures, 0, sizeof(mDefaultSubSpaceFeatures)); memset(&mNonDefaultSubSpaceFeatures, 0, sizeof(mNonDefaultSubSpaceFeatures)); } gfxFontEntry::~gfxFontEntry() { // Should not be dropped by stylo MOZ_ASSERT(NS_IsMainThread()); if (mCOLR) { hb_blob_destroy(mCOLR); } if (mCPAL) { hb_blob_destroy(mCPAL); } // For downloaded fonts, we need to tell the user font cache that this // entry is being deleted. if (mIsDataUserFont) { gfxUserFontSet::UserFontCache::ForgetFont(this); } if (mFeatureInputs) { for (auto iter = mFeatureInputs->Iter(); !iter.Done(); iter.Next()) { hb_set_t*& set = iter.Data(); hb_set_destroy(set); } } // By the time the entry is destroyed, all font instances that were // using it should already have been deleted, and so the HB and/or Gr // face objects should have been released. MOZ_ASSERT(!mHBFace); MOZ_ASSERT(!mGrFaceInitialized); } bool gfxFontEntry::IsSymbolFont() { return mSymbolFont; } bool gfxFontEntry::TestCharacterMap(uint32_t aCh) { if (!mCharacterMap) { ReadCMAP(); NS_ASSERTION(mCharacterMap, "failed to initialize character map"); } return mCharacterMap->test(aCh); } nsresult gfxFontEntry::InitializeUVSMap() { // mUVSOffset will not be initialized // until cmap is initialized. if (!mCharacterMap) { ReadCMAP(); NS_ASSERTION(mCharacterMap, "failed to initialize character map"); } if (!mUVSOffset) { return NS_ERROR_FAILURE; } if (!mUVSData) { const uint32_t kCmapTag = TRUETYPE_TAG('c','m','a','p'); AutoTable cmapTable(this, kCmapTag); if (!cmapTable) { mUVSOffset = 0; // don't bother to read the table again return NS_ERROR_FAILURE; } UniquePtr uvsData; unsigned int cmapLen; const char* cmapData = hb_blob_get_data(cmapTable, &cmapLen); nsresult rv = gfxFontUtils::ReadCMAPTableFormat14( (const uint8_t*)cmapData + mUVSOffset, cmapLen - mUVSOffset, uvsData); if (NS_FAILED(rv)) { mUVSOffset = 0; // don't bother to read the table again return rv; } mUVSData = Move(uvsData); } return NS_OK; } uint16_t gfxFontEntry::GetUVSGlyph(uint32_t aCh, uint32_t aVS) { InitializeUVSMap(); if (mUVSData) { return gfxFontUtils::MapUVSToGlyphFormat14(mUVSData.get(), aCh, aVS); } return 0; } bool gfxFontEntry::SupportsScriptInGSUB(const hb_tag_t* aScriptTags) { hb_face_t *face = GetHBFace(); if (!face) { return false; } unsigned int index; hb_tag_t chosenScript; bool found = hb_ot_layout_table_choose_script(face, TRUETYPE_TAG('G','S','U','B'), aScriptTags, &index, &chosenScript); hb_face_destroy(face); return found && chosenScript != TRUETYPE_TAG('D','F','L','T'); } nsresult gfxFontEntry::ReadCMAP(FontInfoData *aFontInfoData) { NS_ASSERTION(false, "using default no-op implementation of ReadCMAP"); mCharacterMap = new gfxCharacterMap(); return NS_OK; } nsString gfxFontEntry::RealFaceName() { AutoTable nameTable(this, TRUETYPE_TAG('n','a','m','e')); if (nameTable) { nsAutoString name; nsresult rv = gfxFontUtils::GetFullNameFromTable(nameTable, name); if (NS_SUCCEEDED(rv)) { return name; } } return Name(); } already_AddRefed gfxFontEntry::FindOrMakeFont(const gfxFontStyle *aStyle, bool aNeedsBold, gfxCharacterMap* aUnicodeRangeMap) { // the font entry name is the psname, not the family name RefPtr font = gfxFontCache::GetCache()->Lookup(this, aStyle, aUnicodeRangeMap); if (!font) { gfxFont *newFont = CreateFontInstance(aStyle, aNeedsBold); if (!newFont) return nullptr; if (!newFont->Valid()) { delete newFont; return nullptr; } font = newFont; font->SetUnicodeRangeMap(aUnicodeRangeMap); gfxFontCache::GetCache()->AddNew(font); } return font.forget(); } uint16_t gfxFontEntry::UnitsPerEm() { if (!mUnitsPerEm) { AutoTable headTable(this, TRUETYPE_TAG('h','e','a','d')); if (headTable) { uint32_t len; const HeadTable* head = reinterpret_cast(hb_blob_get_data(headTable, &len)); if (len >= sizeof(HeadTable)) { mUnitsPerEm = head->unitsPerEm; } } // if we didn't find a usable 'head' table, or if the value was // outside the valid range, record it as invalid if (mUnitsPerEm < kMinUPEM || mUnitsPerEm > kMaxUPEM) { mUnitsPerEm = kInvalidUPEM; } } return mUnitsPerEm; } bool gfxFontEntry::HasSVGGlyph(uint32_t aGlyphId) { NS_ASSERTION(mSVGInitialized, "SVG data has not yet been loaded. TryGetSVGData() first."); return mSVGGlyphs->HasSVGGlyph(aGlyphId); } bool gfxFontEntry::GetSVGGlyphExtents(DrawTarget* aDrawTarget, uint32_t aGlyphId, gfxRect *aResult) { MOZ_ASSERT(mSVGInitialized, "SVG data has not yet been loaded. TryGetSVGData() first."); MOZ_ASSERT(mUnitsPerEm >= kMinUPEM && mUnitsPerEm <= kMaxUPEM, "font has invalid unitsPerEm"); cairo_matrix_t fontMatrix; cairo_get_font_matrix(gfxFont::RefCairo(aDrawTarget), &fontMatrix); gfxMatrix svgToAppSpace(fontMatrix.xx, fontMatrix.yx, fontMatrix.xy, fontMatrix.yy, fontMatrix.x0, fontMatrix.y0); svgToAppSpace.Scale(1.0f / mUnitsPerEm, 1.0f / mUnitsPerEm); return mSVGGlyphs->GetGlyphExtents(aGlyphId, svgToAppSpace, aResult); } bool gfxFontEntry::RenderSVGGlyph(gfxContext *aContext, uint32_t aGlyphId, SVGContextPaint* aContextPaint) { NS_ASSERTION(mSVGInitialized, "SVG data has not yet been loaded. TryGetSVGData() first."); return mSVGGlyphs->RenderGlyph(aContext, aGlyphId, aContextPaint); } bool gfxFontEntry::TryGetSVGData(gfxFont* aFont) { if (!gfxPlatform::GetPlatform()->OpenTypeSVGEnabled()) { return false; } if (!mSVGInitialized) { mSVGInitialized = true; // If UnitsPerEm is not known/valid, we can't use SVG glyphs if (UnitsPerEm() == kInvalidUPEM) { return false; } // We don't use AutoTable here because we'll pass ownership of this // blob to the gfxSVGGlyphs, once we've confirmed the table exists hb_blob_t *svgTable = GetFontTable(TRUETYPE_TAG('S','V','G',' ')); if (!svgTable) { return false; } // gfxSVGGlyphs will hb_blob_destroy() the table when it is finished // with it. mSVGGlyphs = MakeUnique(svgTable, this); } if (mSVGGlyphs && !mFontsUsingSVGGlyphs.Contains(aFont)) { mFontsUsingSVGGlyphs.AppendElement(aFont); } return !!mSVGGlyphs; } void gfxFontEntry::NotifyFontDestroyed(gfxFont* aFont) { mFontsUsingSVGGlyphs.RemoveElement(aFont); } void gfxFontEntry::NotifyGlyphsChanged() { for (uint32_t i = 0, count = mFontsUsingSVGGlyphs.Length(); i < count; ++i) { gfxFont* font = mFontsUsingSVGGlyphs[i]; font->NotifyGlyphsChanged(); } } bool gfxFontEntry::TryGetColorGlyphs() { if (mCheckedForColorGlyph) { return (mCOLR && mCPAL); } mCheckedForColorGlyph = true; mCOLR = GetFontTable(TRUETYPE_TAG('C', 'O', 'L', 'R')); if (!mCOLR) { return false; } mCPAL = GetFontTable(TRUETYPE_TAG('C', 'P', 'A', 'L')); if (!mCPAL) { hb_blob_destroy(mCOLR); mCOLR = nullptr; return false; } // validation COLR and CPAL table if (gfxFontUtils::ValidateColorGlyphs(mCOLR, mCPAL)) { return true; } hb_blob_destroy(mCOLR); hb_blob_destroy(mCPAL); mCOLR = nullptr; mCPAL = nullptr; return false; } /** * FontTableBlobData * * See FontTableHashEntry for the general strategy. */ class gfxFontEntry::FontTableBlobData { public: explicit FontTableBlobData(nsTArray&& aBuffer) : mTableData(Move(aBuffer)) , mHashtable(nullptr) , mHashKey(0) { MOZ_COUNT_CTOR(FontTableBlobData); } ~FontTableBlobData() { MOZ_COUNT_DTOR(FontTableBlobData); if (mHashtable && mHashKey) { mHashtable->RemoveEntry(mHashKey); } } // Useful for creating blobs const char *GetTable() const { return reinterpret_cast(mTableData.Elements()); } uint32_t GetTableLength() const { return mTableData.Length(); } // Tell this FontTableBlobData to remove the HashEntry when this is // destroyed. void ManageHashEntry(nsTHashtable *aHashtable, uint32_t aHashKey) { mHashtable = aHashtable; mHashKey = aHashKey; } // Disconnect from the HashEntry (because the blob has already been // removed from the hashtable). void ForgetHashEntry() { mHashtable = nullptr; mHashKey = 0; } size_t SizeOfExcludingThis(MallocSizeOf aMallocSizeOf) const { return mTableData.ShallowSizeOfExcludingThis(aMallocSizeOf); } size_t SizeOfIncludingThis(MallocSizeOf aMallocSizeOf) const { return aMallocSizeOf(this) + SizeOfExcludingThis(aMallocSizeOf); } private: // The font table data block nsTArray mTableData; // The blob destroy function needs to know the owning hashtable // and the hashtable key, so that it can remove the entry. nsTHashtable *mHashtable; uint32_t mHashKey; // not implemented FontTableBlobData(const FontTableBlobData&); }; hb_blob_t * gfxFontEntry::FontTableHashEntry:: ShareTableAndGetBlob(nsTArray&& aTable, nsTHashtable *aHashtable) { Clear(); // adopts elements of aTable mSharedBlobData = new FontTableBlobData(Move(aTable)); mBlob = hb_blob_create(mSharedBlobData->GetTable(), mSharedBlobData->GetTableLength(), HB_MEMORY_MODE_READONLY, mSharedBlobData, DeleteFontTableBlobData); if (mBlob == hb_blob_get_empty() ) { // The FontTableBlobData was destroyed during hb_blob_create(). // The (empty) blob is still be held in the hashtable with a strong // reference. return hb_blob_reference(mBlob); } // Tell the FontTableBlobData to remove this hash entry when destroyed. // The hashtable does not keep a strong reference. mSharedBlobData->ManageHashEntry(aHashtable, GetKey()); return mBlob; } void gfxFontEntry::FontTableHashEntry::Clear() { // If the FontTableBlobData is managing the hash entry, then the blob is // not owned by this HashEntry; otherwise there is strong reference to the // blob that must be removed. if (mSharedBlobData) { mSharedBlobData->ForgetHashEntry(); mSharedBlobData = nullptr; } else if (mBlob) { hb_blob_destroy(mBlob); } mBlob = nullptr; } // a hb_destroy_func for hb_blob_create /* static */ void gfxFontEntry::FontTableHashEntry::DeleteFontTableBlobData(void *aBlobData) { delete static_cast(aBlobData); } hb_blob_t * gfxFontEntry::FontTableHashEntry::GetBlob() const { return hb_blob_reference(mBlob); } bool gfxFontEntry::GetExistingFontTable(uint32_t aTag, hb_blob_t **aBlob) { if (!mFontTableCache) { // we do this here rather than on fontEntry construction // because not all shapers will access the table cache at all mFontTableCache = MakeUnique>(8); } FontTableHashEntry *entry = mFontTableCache->GetEntry(aTag); if (!entry) { return false; } *aBlob = entry->GetBlob(); return true; } hb_blob_t * gfxFontEntry::ShareFontTableAndGetBlob(uint32_t aTag, nsTArray* aBuffer) { if (MOZ_UNLIKELY(!mFontTableCache)) { // we do this here rather than on fontEntry construction // because not all shapers will access the table cache at all mFontTableCache = MakeUnique>(8); } FontTableHashEntry *entry = mFontTableCache->PutEntry(aTag); if (MOZ_UNLIKELY(!entry)) { // OOM return nullptr; } if (!aBuffer) { // ensure the entry is null entry->Clear(); return nullptr; } return entry->ShareTableAndGetBlob(Move(*aBuffer), mFontTableCache.get()); } already_AddRefed gfxFontEntry::GetCMAPFromFontInfo(FontInfoData *aFontInfoData, uint32_t& aUVSOffset, bool& aSymbolFont) { if (!aFontInfoData || !aFontInfoData->mLoadCmaps) { return nullptr; } return aFontInfoData->GetCMAP(mName, aUVSOffset, aSymbolFont); } hb_blob_t * gfxFontEntry::GetFontTable(uint32_t aTag) { hb_blob_t *blob; if (GetExistingFontTable(aTag, &blob)) { return blob; } nsTArray buffer; bool haveTable = NS_SUCCEEDED(CopyFontTable(aTag, buffer)); return ShareFontTableAndGetBlob(aTag, haveTable ? &buffer : nullptr); } // callback for HarfBuzz to get a font table (in hb_blob_t form) // from the font entry (passed as aUserData) /*static*/ hb_blob_t * gfxFontEntry::HBGetTable(hb_face_t *face, uint32_t aTag, void *aUserData) { gfxFontEntry *fontEntry = static_cast(aUserData); // bug 589682 - ignore the GDEF table in buggy fonts (applies to // Italic and BoldItalic faces of Times New Roman) if (aTag == TRUETYPE_TAG('G','D','E','F') && fontEntry->IgnoreGDEF()) { return nullptr; } // bug 721719 - ignore the GSUB table in buggy fonts (applies to Roboto, // at least on some Android ICS devices; set in gfxFT2FontList.cpp) if (aTag == TRUETYPE_TAG('G','S','U','B') && fontEntry->IgnoreGSUB()) { return nullptr; } return fontEntry->GetFontTable(aTag); } /*static*/ void gfxFontEntry::HBFaceDeletedCallback(void *aUserData) { gfxFontEntry *fe = static_cast(aUserData); fe->ForgetHBFace(); } void gfxFontEntry::ForgetHBFace() { mHBFace = nullptr; } hb_face_t* gfxFontEntry::GetHBFace() { if (!mHBFace) { mHBFace = hb_face_create_for_tables(HBGetTable, this, HBFaceDeletedCallback); return mHBFace; } return hb_face_reference(mHBFace); } /*static*/ const void* gfxFontEntry::GrGetTable(const void *aAppFaceHandle, unsigned int aName, size_t *aLen) { gfxFontEntry *fontEntry = static_cast(const_cast(aAppFaceHandle)); hb_blob_t *blob = fontEntry->GetFontTable(aName); if (blob) { unsigned int blobLength; const void *tableData = hb_blob_get_data(blob, &blobLength); fontEntry->mGrTableMap->Put(tableData, blob); *aLen = blobLength; return tableData; } *aLen = 0; return nullptr; } /*static*/ void gfxFontEntry::GrReleaseTable(const void *aAppFaceHandle, const void *aTableBuffer) { gfxFontEntry *fontEntry = static_cast(const_cast(aAppFaceHandle)); void *data; if (fontEntry->mGrTableMap->Get(aTableBuffer, &data)) { fontEntry->mGrTableMap->Remove(aTableBuffer); hb_blob_destroy(static_cast(data)); } } gr_face* gfxFontEntry::GetGrFace() { if (!mGrFaceInitialized) { gr_face_ops faceOps = { sizeof(gr_face_ops), GrGetTable, GrReleaseTable }; mGrTableMap = new nsDataHashtable,void*>; mGrFace = gr_make_face_with_ops(this, &faceOps, gr_face_default); mGrFaceInitialized = true; } ++mGrFaceRefCnt; return mGrFace; } void gfxFontEntry::ReleaseGrFace(gr_face *aFace) { MOZ_ASSERT(aFace == mGrFace); // sanity-check MOZ_ASSERT(mGrFaceRefCnt > 0); if (--mGrFaceRefCnt == 0) { gr_face_destroy(mGrFace); mGrFace = nullptr; mGrFaceInitialized = false; delete mGrTableMap; mGrTableMap = nullptr; } } void gfxFontEntry::DisconnectSVG() { if (mSVGInitialized && mSVGGlyphs) { mSVGGlyphs = nullptr; mSVGInitialized = false; } } bool gfxFontEntry::HasFontTable(uint32_t aTableTag) { AutoTable table(this, aTableTag); return table && hb_blob_get_length(table) > 0; } void gfxFontEntry::CheckForGraphiteTables() { mHasGraphiteTables = HasFontTable(TRUETYPE_TAG('S','i','l','f')); } bool gfxFontEntry::HasGraphiteSpaceContextuals() { if (!mGraphiteSpaceContextualsInitialized) { gr_face* face = GetGrFace(); if (face) { const gr_faceinfo* faceInfo = gr_face_info(face, 0); mHasGraphiteSpaceContextuals = faceInfo->space_contextuals != gr_faceinfo::gr_space_none; } ReleaseGrFace(face); // always balance GetGrFace, even if face is null mGraphiteSpaceContextualsInitialized = true; } return mHasGraphiteSpaceContextuals; } #define FEATURE_SCRIPT_MASK 0x000000ff // script index replaces low byte of tag static_assert(int(Script::NUM_SCRIPT_CODES) <= FEATURE_SCRIPT_MASK, "Too many script codes"); // high-order three bytes of tag with script in low-order byte #define SCRIPT_FEATURE(s,tag) (((~FEATURE_SCRIPT_MASK) & (tag)) | \ ((FEATURE_SCRIPT_MASK) & static_cast(s))) bool gfxFontEntry::SupportsOpenTypeFeature(Script aScript, uint32_t aFeatureTag) { if (!mSupportedFeatures) { mSupportedFeatures = MakeUnique>(); } // note: high-order three bytes *must* be unique for each feature // listed below (see SCRIPT_FEATURE macro def'n) NS_ASSERTION(aFeatureTag == HB_TAG('s','m','c','p') || aFeatureTag == HB_TAG('c','2','s','c') || aFeatureTag == HB_TAG('p','c','a','p') || aFeatureTag == HB_TAG('c','2','p','c') || aFeatureTag == HB_TAG('s','u','p','s') || aFeatureTag == HB_TAG('s','u','b','s') || aFeatureTag == HB_TAG('v','e','r','t'), "use of unknown feature tag"); // note: graphite feature support uses the last script index NS_ASSERTION(int(aScript) < FEATURE_SCRIPT_MASK - 1, "need to bump the size of the feature shift"); uint32_t scriptFeature = SCRIPT_FEATURE(aScript, aFeatureTag); bool result; if (mSupportedFeatures->Get(scriptFeature, &result)) { return result; } result = false; hb_face_t *face = GetHBFace(); if (hb_ot_layout_has_substitution(face)) { hb_script_t hbScript = gfxHarfBuzzShaper::GetHBScriptUsedForShaping(aScript); // Get the OpenType tag(s) that match this script code hb_tag_t scriptTags[4] = { HB_TAG_NONE, HB_TAG_NONE, HB_TAG_NONE, HB_TAG_NONE }; hb_ot_tags_from_script(hbScript, &scriptTags[0], &scriptTags[1]); // Replace the first remaining NONE with DEFAULT hb_tag_t* scriptTag = &scriptTags[0]; while (*scriptTag != HB_TAG_NONE) { ++scriptTag; } *scriptTag = HB_OT_TAG_DEFAULT_SCRIPT; // Now check for 'smcp' under the first of those scripts that is present const hb_tag_t kGSUB = HB_TAG('G','S','U','B'); scriptTag = &scriptTags[0]; while (*scriptTag != HB_TAG_NONE) { unsigned int scriptIndex; if (hb_ot_layout_table_find_script(face, kGSUB, *scriptTag, &scriptIndex)) { if (hb_ot_layout_language_find_feature(face, kGSUB, scriptIndex, HB_OT_LAYOUT_DEFAULT_LANGUAGE_INDEX, aFeatureTag, nullptr)) { result = true; } break; } ++scriptTag; } } hb_face_destroy(face); mSupportedFeatures->Put(scriptFeature, result); return result; } const hb_set_t* gfxFontEntry::InputsForOpenTypeFeature(Script aScript, uint32_t aFeatureTag) { if (!mFeatureInputs) { mFeatureInputs = MakeUnique>(); } NS_ASSERTION(aFeatureTag == HB_TAG('s','u','p','s') || aFeatureTag == HB_TAG('s','u','b','s'), "use of unknown feature tag"); uint32_t scriptFeature = SCRIPT_FEATURE(aScript, aFeatureTag); hb_set_t *inputGlyphs; if (mFeatureInputs->Get(scriptFeature, &inputGlyphs)) { return inputGlyphs; } inputGlyphs = hb_set_create(); hb_face_t *face = GetHBFace(); if (hb_ot_layout_has_substitution(face)) { hb_script_t hbScript = gfxHarfBuzzShaper::GetHBScriptUsedForShaping(aScript); // Get the OpenType tag(s) that match this script code hb_tag_t scriptTags[4] = { HB_TAG_NONE, HB_TAG_NONE, HB_TAG_NONE, HB_TAG_NONE }; hb_ot_tags_from_script(hbScript, &scriptTags[0], &scriptTags[1]); // Replace the first remaining NONE with DEFAULT hb_tag_t* scriptTag = &scriptTags[0]; while (*scriptTag != HB_TAG_NONE) { ++scriptTag; } *scriptTag = HB_OT_TAG_DEFAULT_SCRIPT; const hb_tag_t kGSUB = HB_TAG('G','S','U','B'); hb_tag_t features[2] = { aFeatureTag, HB_TAG_NONE }; hb_set_t *featurelookups = hb_set_create(); hb_ot_layout_collect_lookups(face, kGSUB, scriptTags, nullptr, features, featurelookups); hb_codepoint_t index = -1; while (hb_set_next(featurelookups, &index)) { hb_ot_layout_lookup_collect_glyphs(face, kGSUB, index, nullptr, inputGlyphs, nullptr, nullptr); } hb_set_destroy(featurelookups); } hb_face_destroy(face); mFeatureInputs->Put(scriptFeature, inputGlyphs); return inputGlyphs; } bool gfxFontEntry::SupportsGraphiteFeature(uint32_t aFeatureTag) { if (!mSupportedFeatures) { mSupportedFeatures = MakeUnique>(); } // note: high-order three bytes *must* be unique for each feature // listed below (see SCRIPT_FEATURE macro def'n) NS_ASSERTION(aFeatureTag == HB_TAG('s','m','c','p') || aFeatureTag == HB_TAG('c','2','s','c') || aFeatureTag == HB_TAG('p','c','a','p') || aFeatureTag == HB_TAG('c','2','p','c') || aFeatureTag == HB_TAG('s','u','p','s') || aFeatureTag == HB_TAG('s','u','b','s'), "use of unknown feature tag"); // graphite feature check uses the last script slot uint32_t scriptFeature = SCRIPT_FEATURE(FEATURE_SCRIPT_MASK, aFeatureTag); bool result; if (mSupportedFeatures->Get(scriptFeature, &result)) { return result; } gr_face* face = GetGrFace(); result = face ? gr_face_find_fref(face, aFeatureTag) != nullptr : false; ReleaseGrFace(face); mSupportedFeatures->Put(scriptFeature, result); return result; } bool gfxFontEntry::GetColorLayersInfo(uint32_t aGlyphId, const mozilla::gfx::Color& aDefaultColor, nsTArray& aLayerGlyphs, nsTArray& aLayerColors) { return gfxFontUtils::GetColorGlyphLayers(mCOLR, mCPAL, aGlyphId, aDefaultColor, aLayerGlyphs, aLayerColors); } size_t gfxFontEntry::FontTableHashEntry::SizeOfExcludingThis(mozilla::MallocSizeOf aMallocSizeOf) const { size_t n = 0; if (mBlob) { n += aMallocSizeOf(mBlob); } if (mSharedBlobData) { n += mSharedBlobData->SizeOfIncludingThis(aMallocSizeOf); } return n; } void gfxFontEntry::AddSizeOfExcludingThis(MallocSizeOf aMallocSizeOf, FontListSizes* aSizes) const { aSizes->mFontListSize += mName.SizeOfExcludingThisIfUnshared(aMallocSizeOf); // cmaps are shared so only non-shared cmaps are included here if (mCharacterMap && mCharacterMap->mBuildOnTheFly) { aSizes->mCharMapsSize += mCharacterMap->SizeOfIncludingThis(aMallocSizeOf); } if (mFontTableCache) { aSizes->mFontTableCacheSize += mFontTableCache->SizeOfIncludingThis(aMallocSizeOf); } // If the font has UVS data, we count that as part of the character map. if (mUVSData) { aSizes->mCharMapsSize += aMallocSizeOf(mUVSData.get()); } // The following, if present, are essentially cached forms of font table // data, so we'll accumulate them together with the basic table cache. if (mUserFontData) { aSizes->mFontTableCacheSize += mUserFontData->SizeOfIncludingThis(aMallocSizeOf); } if (mSVGGlyphs) { aSizes->mFontTableCacheSize += mSVGGlyphs->SizeOfIncludingThis(aMallocSizeOf); } if (mSupportedFeatures) { aSizes->mFontTableCacheSize += mSupportedFeatures->ShallowSizeOfIncludingThis(aMallocSizeOf); } if (mFeatureInputs) { aSizes->mFontTableCacheSize += mFeatureInputs->ShallowSizeOfIncludingThis(aMallocSizeOf); for (auto iter = mFeatureInputs->ConstIter(); !iter.Done(); iter.Next()) { // There's no API to get the real size of an hb_set, so we'll use // an approximation based on knowledge of the implementation. aSizes->mFontTableCacheSize += 8192; // vector of 64K bits } } // We don't include the size of mCOLR/mCPAL here, because (depending on the // font backend implementation) they will either wrap blocks of data owned // by the system (and potentially shared), or tables that are in our font // table cache and therefore already counted. } void gfxFontEntry::AddSizeOfIncludingThis(MallocSizeOf aMallocSizeOf, FontListSizes* aSizes) const { aSizes->mFontListSize += aMallocSizeOf(this); AddSizeOfExcludingThis(aMallocSizeOf, aSizes); } // This is used to report the size of an individual downloaded font in the // user font cache. (Fonts that are part of the platform font list accumulate // their sizes to the font list's reporter using the AddSizeOf... methods // above.) size_t gfxFontEntry::ComputedSizeOfExcludingThis(MallocSizeOf aMallocSizeOf) const { FontListSizes s = { 0 }; AddSizeOfExcludingThis(aMallocSizeOf, &s); // When reporting memory used for the main platform font list, // where we're typically summing the totals for a few hundred font faces, // we report the fields of FontListSizes separately. // But for downloaded user fonts, the actual resource data (added below) // will dominate, and the minor overhead of these pieces isn't worth // splitting out for an individual font. size_t result = s.mFontListSize + s.mFontTableCacheSize + s.mCharMapsSize; if (mIsDataUserFont) { MOZ_ASSERT(mComputedSizeOfUserFont > 0, "user font with no data?"); result += mComputedSizeOfUserFont; } return result; } ////////////////////////////////////////////////////////////////////////////// // // class gfxFontFamily // ////////////////////////////////////////////////////////////////////////////// // we consider faces with mStandardFace == true to be "less than" those with false, // because during style matching, earlier entries are tried first class FontEntryStandardFaceComparator { public: bool Equals(const RefPtr& a, const RefPtr& b) const { return a->mStandardFace == b->mStandardFace; } bool LessThan(const RefPtr& a, const RefPtr& b) const { return (a->mStandardFace == true && b->mStandardFace == false); } }; void gfxFontFamily::SortAvailableFonts() { mAvailableFonts.Sort(FontEntryStandardFaceComparator()); } bool gfxFontFamily::HasOtherFamilyNames() { // need to read in other family names to determine this if (!mOtherFamilyNamesInitialized) { ReadOtherFamilyNames(gfxPlatformFontList::PlatformFontList()); // sets mHasOtherFamilyNames } return mHasOtherFamilyNames; } gfxFontEntry* gfxFontFamily::FindFontForStyle(const gfxFontStyle& aFontStyle, bool& aNeedsSyntheticBold) { AutoTArray matched; FindAllFontsForStyle(aFontStyle, matched, aNeedsSyntheticBold); if (!matched.IsEmpty()) { return matched[0]; } return nullptr; } #define STYLE_SHIFT 2 // number of bits to contain style distance // style distance ==> [0,2] static inline uint32_t StyleDistance(uint32_t aFontStyle, uint32_t aTargetStyle) { if (aFontStyle == aTargetStyle) { return 0; // styles match exactly ==> 0 } if (aFontStyle == NS_FONT_STYLE_NORMAL || aTargetStyle == NS_FONT_STYLE_NORMAL) { return 2; // one is normal (but not the other) ==> 2 } return 1; // neither is normal; must be italic vs oblique ==> 1 } #define REVERSE_STRETCH_DISTANCE 5 // stretch distance ==> [0,13] static inline uint32_t StretchDistance(int16_t aFontStretch, int16_t aTargetStretch) { int32_t distance = 0; if (aTargetStretch != aFontStretch) { // stretch values are in the range -4 .. +4 // if aTargetStretch is positive, we prefer more-positive values; // if zero or negative, prefer more-negative if (aTargetStretch > 0) { distance = (aFontStretch - aTargetStretch); } else { distance = (aTargetStretch - aFontStretch); } // if the computed "distance" here is negative, it means that // aFontEntry lies in the "non-preferred" direction from aTargetStretch, // so we treat that as larger than any preferred-direction distance // (max possible is 4) by adding an extra 5 to the absolute value if (distance < 0) { distance = -distance + REVERSE_STRETCH_DISTANCE; } } return uint32_t(distance); } // CSS currently limits font weights to multiples of 100 but the weight // matching code below does not assume this. // // Calculate weight distance with values in the range (0..1000). In general, // heavier weights match towards even heavier weights while lighter weights // match towards even lighter weights. Target weight values in the range // [400..500] are special, since they will first match up to 500, then down // towards 0, then up again towards 999. // // Example: with target 600 and font weight 800, distance will be 200. With // target 300 and font weight 600, distance will be 900, since heavier // weights are farther away than lighter weights. If the target is 5 and the // font weight 995, the distance would be 1590 for the same reason. #define REVERSE_WEIGHT_DISTANCE 600 #define WEIGHT_SHIFT 11 // number of bits to contain weight distance // weight distance ==> [0,1598] static inline uint32_t WeightDistance(uint32_t aFontWeight, uint32_t aTargetWeight) { // Compute a measure of the "distance" between the requested // weight and the given fontEntry int32_t distance = 0, addedDistance = 0; if (aTargetWeight != aFontWeight) { if (aTargetWeight > 500) { distance = aFontWeight - aTargetWeight; } else if (aTargetWeight < 400) { distance = aTargetWeight - aFontWeight; } else { // special case - target is between 400 and 500 // font weights between 400 and 500 are close if (aFontWeight >= 400 && aFontWeight <= 500) { if (aFontWeight < aTargetWeight) { distance = 500 - aFontWeight; } else { distance = aFontWeight - aTargetWeight; } } else { // font weights outside use rule for target weights < 400 with // added distance to separate from font weights in // the [400..500] range distance = aTargetWeight - aFontWeight; addedDistance = 100; } } if (distance < 0) { distance = -distance + REVERSE_WEIGHT_DISTANCE; } distance += addedDistance; } return uint32_t(distance); } #define MAX_DISTANCE 0xffffffff static inline uint32_t WeightStyleStretchDistance(gfxFontEntry* aFontEntry, const gfxFontStyle& aTargetStyle) { // weight/style/stretch priority: stretch >> style >> weight uint32_t stretchDist = StretchDistance(aFontEntry->mStretch, aTargetStyle.stretch); uint32_t styleDist = StyleDistance(aFontEntry->mStyle, aTargetStyle.style); uint32_t weightDist = WeightDistance(aFontEntry->Weight(), aTargetStyle.weight); NS_ASSERTION(weightDist < (1 << WEIGHT_SHIFT), "weight value out of bounds"); NS_ASSERTION(styleDist < (1 << STYLE_SHIFT), "slope value out of bounds"); return (stretchDist << (STYLE_SHIFT + WEIGHT_SHIFT)) | (styleDist << WEIGHT_SHIFT) | weightDist; } void gfxFontFamily::FindAllFontsForStyle(const gfxFontStyle& aFontStyle, nsTArray& aFontEntryList, bool& aNeedsSyntheticBold) { if (!mHasStyles) { FindStyleVariations(); // collect faces for the family, if not already done } NS_ASSERTION(mAvailableFonts.Length() > 0, "font family with no faces!"); NS_ASSERTION(aFontEntryList.IsEmpty(), "non-empty fontlist passed in"); aNeedsSyntheticBold = false; int8_t baseWeight = aFontStyle.ComputeWeight(); bool wantBold = baseWeight >= 6; gfxFontEntry *fe = nullptr; // If the family has only one face, we simply return it; no further // checking needed uint32_t count = mAvailableFonts.Length(); if (count == 1) { fe = mAvailableFonts[0]; aNeedsSyntheticBold = wantBold && !fe->IsBold() && aFontStyle.allowSyntheticWeight; aFontEntryList.AppendElement(fe); return; } // Most families are "simple", having just Regular/Bold/Italic/BoldItalic, // or some subset of these. In this case, we have exactly 4 entries in mAvailableFonts, // stored in the above order; note that some of the entries may be nullptr. // We can then pick the required entry based on whether the request is for // bold or non-bold, italic or non-italic, without running the more complex // matching algorithm used for larger families with many weights and/or widths. if (mIsSimpleFamily) { // Family has no more than the "standard" 4 faces, at fixed indexes; // calculate which one we want. // Note that we cannot simply return it as not all 4 faces are necessarily present. bool wantItalic = (aFontStyle.style != NS_FONT_STYLE_NORMAL); uint8_t faceIndex = (wantItalic ? kItalicMask : 0) | (wantBold ? kBoldMask : 0); // if the desired style is available, return it directly fe = mAvailableFonts[faceIndex]; if (fe) { // no need to set aNeedsSyntheticBold here as we matched the boldness request aFontEntryList.AppendElement(fe); return; } // order to check fallback faces in a simple family, depending on requested style static const uint8_t simpleFallbacks[4][3] = { { kBoldFaceIndex, kItalicFaceIndex, kBoldItalicFaceIndex }, // fallbacks for Regular { kRegularFaceIndex, kBoldItalicFaceIndex, kItalicFaceIndex },// Bold { kBoldItalicFaceIndex, kRegularFaceIndex, kBoldFaceIndex }, // Italic { kItalicFaceIndex, kBoldFaceIndex, kRegularFaceIndex } // BoldItalic }; const uint8_t *order = simpleFallbacks[faceIndex]; for (uint8_t trial = 0; trial < 3; ++trial) { // check remaining faces in order of preference to find the first that actually exists fe = mAvailableFonts[order[trial]]; if (fe) { aNeedsSyntheticBold = wantBold && !fe->IsBold() && aFontStyle.allowSyntheticWeight; aFontEntryList.AppendElement(fe); return; } } // this can't happen unless we have totally broken the font-list manager! NS_NOTREACHED("no face found in simple font family!"); } // Pick the font(s) that are closest to the desired weight, style, and // stretch. Iterate over all fonts, measuring the weight/style distance. // Because of unicode-range values, there may be more than one font for a // given but the 99% use case is only a single font entry per // weight/style/stretch distance value. To optimize this, only add entries // to the matched font array when another entry already has the same // weight/style/stretch distance and add the last matched font entry. For // normal platform fonts with a single font entry for each // weight/style/stretch combination, only the last matched font entry will // be added. uint32_t minDistance = MAX_DISTANCE; gfxFontEntry* matched = nullptr; // iterate in forward order so that faces like 'Bold' are matched before // matching style distance faces such as 'Bold Outline' (see bug 1185812) for (uint32_t i = 0; i < count; i++) { fe = mAvailableFonts[i]; // weight/style/stretch priority: stretch >> style >> weight uint32_t distance = WeightStyleStretchDistance(fe, aFontStyle); if (distance < minDistance) { matched = fe; if (!aFontEntryList.IsEmpty()) { aFontEntryList.Clear(); } minDistance = distance; } else if (distance == minDistance) { if (matched) { aFontEntryList.AppendElement(matched); } matched = fe; } } NS_ASSERTION(matched, "didn't match a font within a family"); if (matched) { aFontEntryList.AppendElement(matched); if (!matched->IsBold() && aFontStyle.weight >= 600 && aFontStyle.allowSyntheticWeight) { aNeedsSyntheticBold = true; } } } void gfxFontFamily::CheckForSimpleFamily() { // already checked this family if (mIsSimpleFamily) { return; } uint32_t count = mAvailableFonts.Length(); if (count > 4 || count == 0) { return; // can't be "simple" if there are >4 faces; // if none then the family is unusable anyway } if (count == 1) { mIsSimpleFamily = true; return; } int16_t firstStretch = mAvailableFonts[0]->Stretch(); gfxFontEntry *faces[4] = { 0 }; for (uint8_t i = 0; i < count; ++i) { gfxFontEntry *fe = mAvailableFonts[i]; if (fe->Stretch() != firstStretch || fe->IsOblique()) { // simple families don't have varying font-stretch or oblique return; } uint8_t faceIndex = (fe->IsItalic() ? kItalicMask : 0) | (fe->Weight() >= 600 ? kBoldMask : 0); if (faces[faceIndex]) { return; // two faces resolve to the same slot; family isn't "simple" } faces[faceIndex] = fe; } // we have successfully slotted the available faces into the standard // 4-face framework mAvailableFonts.SetLength(4); for (uint8_t i = 0; i < 4; ++i) { if (mAvailableFonts[i].get() != faces[i]) { mAvailableFonts[i].swap(faces[i]); } } mIsSimpleFamily = true; } #ifdef DEBUG bool gfxFontFamily::ContainsFace(gfxFontEntry* aFontEntry) { uint32_t i, numFonts = mAvailableFonts.Length(); for (i = 0; i < numFonts; i++) { if (mAvailableFonts[i] == aFontEntry) { return true; } // userfonts contain the actual real font entry if (mAvailableFonts[i] && mAvailableFonts[i]->mIsUserFontContainer) { gfxUserFontEntry* ufe = static_cast(mAvailableFonts[i].get()); if (ufe->GetPlatformFontEntry() == aFontEntry) { return true; } } } return false; } #endif void gfxFontFamily::LocalizedName(nsAString& aLocalizedName) { // just return the primary name; subclasses should override aLocalizedName = mName; } // metric for how close a given font matches a style static int32_t CalcStyleMatch(gfxFontEntry *aFontEntry, const gfxFontStyle *aStyle) { int32_t rank = 0; if (aStyle) { // italics bool wantUpright = (aStyle->style == NS_FONT_STYLE_NORMAL); if (aFontEntry->IsUpright() == wantUpright) { rank += 10; } // measure of closeness of weight to the desired value rank += 9 - DeprecatedAbs(aFontEntry->Weight() / 100 - aStyle->ComputeWeight()); } else { // if no font to match, prefer non-bold, non-italic fonts if (aFontEntry->IsUpright()) { rank += 3; } if (!aFontEntry->IsBold()) { rank += 2; } } return rank; } #define RANK_MATCHED_CMAP 20 void gfxFontFamily::FindFontForChar(GlobalFontMatch *aMatchData) { if (mFamilyCharacterMapInitialized && !TestCharacterMap(aMatchData->mCh)) { // none of the faces in the family support the required char, // so bail out immediately return; } bool needsBold; gfxFontEntry *fe = FindFontForStyle(aMatchData->mStyle ? *aMatchData->mStyle : gfxFontStyle(), needsBold); if (fe && !fe->SkipDuringSystemFallback()) { int32_t rank = 0; if (fe->HasCharacter(aMatchData->mCh)) { rank += RANK_MATCHED_CMAP; aMatchData->mCount++; LogModule* log = gfxPlatform::GetLog(eGfxLog_textrun); if (MOZ_UNLIKELY(MOZ_LOG_TEST(log, LogLevel::Debug))) { uint32_t unicodeRange = FindCharUnicodeRange(aMatchData->mCh); Script script = GetScriptCode(aMatchData->mCh); MOZ_LOG(log, LogLevel::Debug,\ ("(textrun-systemfallback-fonts) char: u+%6.6x " "unicode-range: %d script: %d match: [%s]\n", aMatchData->mCh, unicodeRange, int(script), NS_ConvertUTF16toUTF8(fe->Name()).get())); } } aMatchData->mCmapsTested++; if (rank == 0) { return; } // omitting from original windows code -- family name, lang group, pitch // not available in current FontEntry implementation rank += CalcStyleMatch(fe, aMatchData->mStyle); // xxx - add whether AAT font with morphing info for specific lang groups if (rank > aMatchData->mMatchRank || (rank == aMatchData->mMatchRank && Compare(fe->Name(), aMatchData->mBestMatch->Name()) > 0)) { aMatchData->mBestMatch = fe; aMatchData->mMatchedFamily = this; aMatchData->mMatchRank = rank; } } } void gfxFontFamily::SearchAllFontsForChar(GlobalFontMatch *aMatchData) { uint32_t i, numFonts = mAvailableFonts.Length(); for (i = 0; i < numFonts; i++) { gfxFontEntry *fe = mAvailableFonts[i]; if (fe && fe->HasCharacter(aMatchData->mCh)) { int32_t rank = RANK_MATCHED_CMAP; rank += CalcStyleMatch(fe, aMatchData->mStyle); if (rank > aMatchData->mMatchRank || (rank == aMatchData->mMatchRank && Compare(fe->Name(), aMatchData->mBestMatch->Name()) > 0)) { aMatchData->mBestMatch = fe; aMatchData->mMatchedFamily = this; aMatchData->mMatchRank = rank; } } } } /*virtual*/ gfxFontFamily::~gfxFontFamily() { // Should not be dropped by stylo MOZ_ASSERT(NS_IsMainThread()); } /*static*/ void gfxFontFamily::ReadOtherFamilyNamesForFace(const nsAString& aFamilyName, const char *aNameData, uint32_t aDataLength, nsTArray& aOtherFamilyNames, bool useFullName) { const gfxFontUtils::NameHeader *nameHeader = reinterpret_cast(aNameData); uint32_t nameCount = nameHeader->count; if (nameCount * sizeof(gfxFontUtils::NameRecord) > aDataLength) { NS_WARNING("invalid font (name records)"); return; } const gfxFontUtils::NameRecord *nameRecord = reinterpret_cast(aNameData + sizeof(gfxFontUtils::NameHeader)); uint32_t stringsBase = uint32_t(nameHeader->stringOffset); for (uint32_t i = 0; i < nameCount; i++, nameRecord++) { uint32_t nameLen = nameRecord->length; uint32_t nameOff = nameRecord->offset; // offset from base of string storage if (stringsBase + nameOff + nameLen > aDataLength) { NS_WARNING("invalid font (name table strings)"); return; } uint16_t nameID = nameRecord->nameID; if ((useFullName && nameID == gfxFontUtils::NAME_ID_FULL) || (!useFullName && (nameID == gfxFontUtils::NAME_ID_FAMILY || nameID == gfxFontUtils::NAME_ID_PREFERRED_FAMILY))) { nsAutoString otherFamilyName; bool ok = gfxFontUtils::DecodeFontName(aNameData + stringsBase + nameOff, nameLen, uint32_t(nameRecord->platformID), uint32_t(nameRecord->encodingID), uint32_t(nameRecord->languageID), otherFamilyName); // add if not same as canonical family name if (ok && otherFamilyName != aFamilyName) { aOtherFamilyNames.AppendElement(otherFamilyName); } } } } // returns true if other names were found, false otherwise bool gfxFontFamily::ReadOtherFamilyNamesForFace(gfxPlatformFontList *aPlatformFontList, hb_blob_t *aNameTable, bool useFullName) { uint32_t dataLength; const char *nameData = hb_blob_get_data(aNameTable, &dataLength); AutoTArray otherFamilyNames; ReadOtherFamilyNamesForFace(mName, nameData, dataLength, otherFamilyNames, useFullName); uint32_t n = otherFamilyNames.Length(); for (uint32_t i = 0; i < n; i++) { aPlatformFontList->AddOtherFamilyName(this, otherFamilyNames[i]); } return n != 0; } void gfxFontFamily::ReadOtherFamilyNames(gfxPlatformFontList *aPlatformFontList) { if (mOtherFamilyNamesInitialized) return; mOtherFamilyNamesInitialized = true; FindStyleVariations(); // read in other family names for the first face in the list uint32_t i, numFonts = mAvailableFonts.Length(); const uint32_t kNAME = TRUETYPE_TAG('n','a','m','e'); for (i = 0; i < numFonts; ++i) { gfxFontEntry *fe = mAvailableFonts[i]; if (!fe) { continue; } gfxFontEntry::AutoTable nameTable(fe, kNAME); if (!nameTable) { continue; } mHasOtherFamilyNames = ReadOtherFamilyNamesForFace(aPlatformFontList, nameTable); break; } // read in other names for the first face in the list with the assumption // that if extra names don't exist in that face then they don't exist in // other faces for the same font if (!mHasOtherFamilyNames) return; // read in names for all faces, needed to catch cases where fonts have // family names for individual weights (e.g. Hiragino Kaku Gothic Pro W6) for ( ; i < numFonts; i++) { gfxFontEntry *fe = mAvailableFonts[i]; if (!fe) { continue; } gfxFontEntry::AutoTable nameTable(fe, kNAME); if (!nameTable) { continue; } ReadOtherFamilyNamesForFace(aPlatformFontList, nameTable); } } void gfxFontFamily::ReadFaceNames(gfxPlatformFontList *aPlatformFontList, bool aNeedFullnamePostscriptNames, FontInfoData *aFontInfoData) { // if all needed names have already been read, skip if (mOtherFamilyNamesInitialized && (mFaceNamesInitialized || !aNeedFullnamePostscriptNames)) return; bool asyncFontLoaderDisabled = false; if (!mOtherFamilyNamesInitialized && aFontInfoData && aFontInfoData->mLoadOtherNames && !asyncFontLoaderDisabled) { AutoTArray otherFamilyNames; bool foundOtherNames = aFontInfoData->GetOtherFamilyNames(mName, otherFamilyNames); if (foundOtherNames) { uint32_t i, n = otherFamilyNames.Length(); for (i = 0; i < n; i++) { aPlatformFontList->AddOtherFamilyName(this, otherFamilyNames[i]); } } mOtherFamilyNamesInitialized = true; } // if all needed data has been initialized, return if (mOtherFamilyNamesInitialized && (mFaceNamesInitialized || !aNeedFullnamePostscriptNames)) { return; } FindStyleVariations(aFontInfoData); // check again, as style enumeration code may have loaded names if (mOtherFamilyNamesInitialized && (mFaceNamesInitialized || !aNeedFullnamePostscriptNames)) { return; } uint32_t i, numFonts = mAvailableFonts.Length(); const uint32_t kNAME = TRUETYPE_TAG('n','a','m','e'); bool firstTime = true, readAllFaces = false; for (i = 0; i < numFonts; ++i) { gfxFontEntry *fe = mAvailableFonts[i]; if (!fe) { continue; } nsAutoString fullname, psname; bool foundFaceNames = false; if (!mFaceNamesInitialized && aNeedFullnamePostscriptNames && aFontInfoData && aFontInfoData->mLoadFaceNames) { aFontInfoData->GetFaceNames(fe->Name(), fullname, psname); if (!fullname.IsEmpty()) { aPlatformFontList->AddFullname(fe, fullname); } if (!psname.IsEmpty()) { aPlatformFontList->AddPostscriptName(fe, psname); } foundFaceNames = true; // found everything needed? skip to next font if (mOtherFamilyNamesInitialized) { continue; } } // load directly from the name table gfxFontEntry::AutoTable nameTable(fe, kNAME); if (!nameTable) { continue; } if (aNeedFullnamePostscriptNames && !foundFaceNames) { if (gfxFontUtils::ReadCanonicalName( nameTable, gfxFontUtils::NAME_ID_FULL, fullname) == NS_OK) { aPlatformFontList->AddFullname(fe, fullname); } if (gfxFontUtils::ReadCanonicalName( nameTable, gfxFontUtils::NAME_ID_POSTSCRIPT, psname) == NS_OK) { aPlatformFontList->AddPostscriptName(fe, psname); } } if (!mOtherFamilyNamesInitialized && (firstTime || readAllFaces)) { bool foundOtherName = ReadOtherFamilyNamesForFace(aPlatformFontList, nameTable); // if the first face has a different name, scan all faces, otherwise // assume the family doesn't have other names if (firstTime && foundOtherName) { mHasOtherFamilyNames = true; readAllFaces = true; } firstTime = false; } // if not reading in any more names, skip other faces if (!readAllFaces && !aNeedFullnamePostscriptNames) { break; } } mFaceNamesInitialized = true; mOtherFamilyNamesInitialized = true; } gfxFontEntry* gfxFontFamily::FindFont(const nsAString& aPostscriptName) { // find the font using a simple linear search uint32_t numFonts = mAvailableFonts.Length(); for (uint32_t i = 0; i < numFonts; i++) { gfxFontEntry *fe = mAvailableFonts[i].get(); if (fe && fe->Name() == aPostscriptName) return fe; } return nullptr; } void gfxFontFamily::ReadAllCMAPs(FontInfoData *aFontInfoData) { FindStyleVariations(aFontInfoData); uint32_t i, numFonts = mAvailableFonts.Length(); for (i = 0; i < numFonts; i++) { gfxFontEntry *fe = mAvailableFonts[i]; // don't try to load cmaps for downloadable fonts not yet loaded if (!fe || fe->mIsUserFontContainer) { continue; } fe->ReadCMAP(aFontInfoData); mFamilyCharacterMap.Union(*(fe->mCharacterMap)); } mFamilyCharacterMap.Compact(); mFamilyCharacterMapInitialized = true; } void gfxFontFamily::AddSizeOfExcludingThis(MallocSizeOf aMallocSizeOf, FontListSizes* aSizes) const { aSizes->mFontListSize += mName.SizeOfExcludingThisIfUnshared(aMallocSizeOf); aSizes->mCharMapsSize += mFamilyCharacterMap.SizeOfExcludingThis(aMallocSizeOf); aSizes->mFontListSize += mAvailableFonts.ShallowSizeOfExcludingThis(aMallocSizeOf); for (uint32_t i = 0; i < mAvailableFonts.Length(); ++i) { gfxFontEntry *fe = mAvailableFonts[i]; if (fe) { fe->AddSizeOfIncludingThis(aMallocSizeOf, aSizes); } } } void gfxFontFamily::AddSizeOfIncludingThis(MallocSizeOf aMallocSizeOf, FontListSizes* aSizes) const { aSizes->mFontListSize += aMallocSizeOf(this); AddSizeOfExcludingThis(aMallocSizeOf, aSizes); }