/* -*- Mode: C++; tab-width: 20; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* 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 "gfxFontEntry.h" #include "mozilla/DebugOnly.h" #include "mozilla/FontPropertyTypes.h" #include "mozilla/MathAlgorithms.h" #include "mozilla/Logging.h" #include "gfxTextRun.h" #include "gfxPlatform.h" #include "nsGkAtoms.h" #include "gfxTypes.h" #include "gfxContext.h" #include "gfxFontConstants.h" #include "gfxGraphiteShaper.h" #include "gfxHarfBuzzShaper.h" #include "gfxUserFontSet.h" #include "gfxPlatformFontList.h" #include "nsUnicodeProperties.h" #include "nsMathUtils.h" #include "nsBidiUtils.h" #include "nsStyleConsts.h" #include "mozilla/AppUnits.h" #include "mozilla/FloatingPoint.h" #ifdef MOZ_WASM_SANDBOXING_GRAPHITE # include "mozilla/ipc/LibrarySandboxPreload.h" #endif #include "mozilla/Likely.h" #include "mozilla/MemoryReporting.h" #include "mozilla/Preferences.h" #include "mozilla/ProfilerLabels.h" #include "mozilla/ScopeExit.h" #include "mozilla/Services.h" #include "mozilla/StaticPrefs_layout.h" #include "mozilla/Telemetry.h" #include "gfxSVGGlyphs.h" #include "gfx2DGlue.h" #include "harfbuzz/hb.h" #include "harfbuzz/hb-ot.h" #include "graphite2/Font.h" #include "ThebesRLBox.h" #include using namespace mozilla; using namespace mozilla::gfx; using namespace mozilla::unicode; nsrefcnt gfxCharacterMap::NotifyMaybeReleased() { auto* pfl = gfxPlatformFontList::PlatformFontList(); pfl->Lock(); // Something may have pulled our raw pointer out of gfxPlatformFontList before // we were able to complete the release. if (mRefCnt > 0) { pfl->Unlock(); return mRefCnt; } if (mShared) { pfl->RemoveCmap(this); } pfl->Unlock(); delete this; return 0; } gfxFontEntry::gfxFontEntry(const nsACString& aName, bool aIsStandardFace) : mName(aName), mLock("gfxFontEntry lock"), mFeatureInfoLock("gfxFontEntry featureInfo mutex"), mFixedPitch(false), mIsBadUnderlineFont(false), mIsUserFontContainer(false), mIsDataUserFont(false), mIsLocalUserFont(false), mStandardFace(aIsStandardFace), mIgnoreGDEF(false), mIgnoreGSUB(false), mSkipDefaultFeatureSpaceCheck(false), mSVGInitialized(false), mHasCmapTable(false), mGrFaceInitialized(false), mCheckedForColorGlyph(false), mCheckedForVariationAxes(false), mSpaceGlyphIsInvisible(LazyFlag::Uninitialized), mHasGraphiteTables(LazyFlag::Uninitialized), mHasGraphiteSpaceContextuals(LazyFlag::Uninitialized), mHasColorBitmapTable(LazyFlag::Uninitialized), mHasSpaceFeatures(SpaceFeatures::Uninitialized) { mTrakTable.exchange(kTrakTableUninitialized); memset(&mDefaultSubSpaceFeatures, 0, sizeof(mDefaultSubSpaceFeatures)); memset(&mNonDefaultSubSpaceFeatures, 0, sizeof(mNonDefaultSubSpaceFeatures)); } gfxFontEntry::~gfxFontEntry() { // Should not be dropped by stylo MOZ_ASSERT(!gfxFontUtils::IsInServoTraversal()); hb_blob_destroy(mCOLR.exchange(nullptr)); hb_blob_destroy(mCPAL.exchange(nullptr)); if (TrakTableInitialized()) { // Only if it was initialized, so that we don't try to call hb_blob_destroy // on the kTrakTableUninitialized flag value! hb_blob_destroy(mTrakTable.exchange(nullptr)); } // 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); } } delete mFontTableCache.exchange(nullptr); delete mSVGGlyphs.exchange(nullptr); delete[] mUVSData.exchange(nullptr); gfxCharacterMap* cmap = mCharacterMap.exchange(nullptr); NS_IF_RELEASE(cmap); // 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); } // Only used during initialization, before any other thread has a chance to see // the entry, so locking not required. void gfxFontEntry::InitializeFrom(fontlist::Face* aFace, const fontlist::Family* aFamily) { mStyleRange = aFace->mStyle; mWeightRange = aFace->mWeight; mStretchRange = aFace->mStretch; mFixedPitch = aFace->mFixedPitch; mIsBadUnderlineFont = aFamily->IsBadUnderlineFamily(); mShmemFace = aFace; auto* list = gfxPlatformFontList::PlatformFontList()->SharedFontList(); mFamilyName = aFamily->DisplayName().AsString(list); mHasCmapTable = TrySetShmemCharacterMap(); } bool gfxFontEntry::TrySetShmemCharacterMap() { MOZ_ASSERT(mShmemFace); auto list = gfxPlatformFontList::PlatformFontList()->SharedFontList(); const auto* shmemCmap = static_cast(mShmemFace->mCharacterMap.ToPtr(list)); mShmemCharacterMap.exchange(shmemCmap); return shmemCmap != nullptr; } bool gfxFontEntry::TestCharacterMap(uint32_t aCh) { if (!mCharacterMap && !mShmemCharacterMap) { ReadCMAP(); MOZ_ASSERT(mCharacterMap || mShmemCharacterMap, "failed to initialize character map"); } return mShmemCharacterMap ? GetShmemCharacterMap()->test(aCh) : GetCharacterMap()->test(aCh); } void gfxFontEntry::EnsureUVSMapInitialized() { // mUVSOffset will not be initialized // until cmap is initialized. if (!mCharacterMap && !mShmemCharacterMap) { ReadCMAP(); NS_ASSERTION(mCharacterMap || mShmemCharacterMap, "failed to initialize character map"); } if (!mUVSOffset) { return; } if (!mUVSData) { nsresult rv = NS_ERROR_NOT_AVAILABLE; const uint32_t kCmapTag = TRUETYPE_TAG('c', 'm', 'a', 'p'); AutoTable cmapTable(this, kCmapTag); if (cmapTable) { const uint8_t* uvsData = nullptr; unsigned int cmapLen; const char* cmapData = hb_blob_get_data(cmapTable, &cmapLen); rv = gfxFontUtils::ReadCMAPTableFormat14( (const uint8_t*)cmapData + mUVSOffset, cmapLen - mUVSOffset, uvsData); if (NS_SUCCEEDED(rv)) { if (!mUVSData.compareExchange(nullptr, uvsData)) { delete uvsData; } } } if (NS_FAILED(rv)) { mUVSOffset = 0; // don't try to read the table again } } } uint16_t gfxFontEntry::GetUVSGlyph(uint32_t aCh, uint32_t aVS) { EnsureUVSMapInitialized(); if (const auto* uvsData = GetUVSData()) { return gfxFontUtils::MapUVSToGlyphFormat14(uvsData, aCh, aVS); } return 0; } bool gfxFontEntry::SupportsScriptInGSUB(const hb_tag_t* aScriptTags, uint32_t aNumTags) { auto face(GetHBFace()); unsigned int index; hb_tag_t chosenScript; bool found = hb_ot_layout_table_select_script( face, TRUETYPE_TAG('G', 'S', 'U', 'B'), aNumTags, aScriptTags, &index, &chosenScript); return found && chosenScript != TRUETYPE_TAG('D', 'F', 'L', 'T'); } nsresult gfxFontEntry::ReadCMAP(FontInfoData* aFontInfoData) { MOZ_ASSERT(false, "using default no-op implementation of ReadCMAP"); RefPtr cmap = new gfxCharacterMap(); if (mCharacterMap.compareExchange(nullptr, cmap.get())) { Unused << cmap.forget(); // mCharacterMap now owns the reference } return NS_OK; } nsCString gfxFontEntry::RealFaceName() { AutoTable nameTable(this, TRUETYPE_TAG('n', 'a', 'm', 'e')); if (nameTable) { nsAutoCString name; nsresult rv = gfxFontUtils::GetFullNameFromTable(nameTable, name); if (NS_SUCCEEDED(rv)) { return std::move(name); } } return Name(); } already_AddRefed gfxFontEntry::FindOrMakeFont( const gfxFontStyle* aStyle, gfxCharacterMap* aUnicodeRangeMap) { RefPtr font = gfxFontCache::GetCache()->Lookup(this, aStyle, aUnicodeRangeMap); if (font) { return font.forget(); } font = CreateFontInstance(aStyle); if (!font || !font->Valid()) { return nullptr; } font->SetUnicodeRangeMap(aUnicodeRangeMap); return gfxFontCache::GetCache()->MaybeInsert(std::move(font)); } 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 GetSVGGlyphs()->HasSVGGlyph(aGlyphId); } bool gfxFontEntry::GetSVGGlyphExtents(DrawTarget* aDrawTarget, uint32_t aGlyphId, gfxFloat aSize, gfxRect* aResult) { MOZ_ASSERT(mSVGInitialized, "SVG data has not yet been loaded. TryGetSVGData() first."); MOZ_ASSERT(mUnitsPerEm >= kMinUPEM && mUnitsPerEm <= kMaxUPEM, "font has invalid unitsPerEm"); gfxMatrix svgToApp(aSize / mUnitsPerEm, 0, 0, aSize / mUnitsPerEm, 0, 0); return GetSVGGlyphs()->GetGlyphExtents(aGlyphId, svgToApp, aResult); } void gfxFontEntry::RenderSVGGlyph(gfxContext* aContext, uint32_t aGlyphId, SVGContextPaint* aContextPaint) { NS_ASSERTION(mSVGInitialized, "SVG data has not yet been loaded. TryGetSVGData() first."); GetSVGGlyphs()->RenderGlyph(aContext, aGlyphId, aContextPaint); } bool gfxFontEntry::TryGetSVGData(const gfxFont* aFont) { if (!gfxPlatform::GetPlatform()->OpenTypeSVGEnabled()) { return false; } // We don't support SVG-in-OT glyphs in offscreen-canvas worker threads. if (!NS_IsMainThread()) { return false; } if (!mSVGInitialized) { // If UnitsPerEm is not known/valid, we can't use SVG glyphs if (UnitsPerEm() == kInvalidUPEM) { mSVGInitialized = true; 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) { mSVGInitialized = true; return false; } // gfxSVGGlyphs will hb_blob_destroy() the table when it is finished // with it. auto* svgGlyphs = new gfxSVGGlyphs(svgTable, this); if (!mSVGGlyphs.compareExchange(nullptr, svgGlyphs)) { delete svgGlyphs; } mSVGInitialized = true; } if (GetSVGGlyphs()) { AutoWriteLock lock(mLock); if (!mFontsUsingSVGGlyphs.Contains(aFont)) { mFontsUsingSVGGlyphs.AppendElement(aFont); } } return !!GetSVGGlyphs(); } void gfxFontEntry::NotifyFontDestroyed(gfxFont* aFont) { AutoWriteLock lock(mLock); mFontsUsingSVGGlyphs.RemoveElement(aFont); } void gfxFontEntry::NotifyGlyphsChanged() { AutoReadLock lock(mLock); for (uint32_t i = 0, count = mFontsUsingSVGGlyphs.Length(); i < count; ++i) { const gfxFont* font = mFontsUsingSVGGlyphs[i]; font->NotifyGlyphsChanged(); } } bool gfxFontEntry::TryGetColorGlyphs() { if (mCheckedForColorGlyph) { return mCOLR && mCPAL; } auto* colr = GetFontTable(TRUETYPE_TAG('C', 'O', 'L', 'R')); auto* cpal = colr ? GetFontTable(TRUETYPE_TAG('C', 'P', 'A', 'L')) : nullptr; if (colr && cpal && gfx::COLRFonts::ValidateColorGlyphs(colr, cpal)) { if (!mCOLR.compareExchange(nullptr, colr)) { hb_blob_destroy(colr); } if (!mCPAL.compareExchange(nullptr, cpal)) { hb_blob_destroy(cpal); } } else { hb_blob_destroy(colr); hb_blob_destroy(cpal); } mCheckedForColorGlyph = true; return mCOLR && mCPAL; } /** * FontTableBlobData * * See FontTableHashEntry for the general strategy. */ class gfxFontEntry::FontTableBlobData { public: explicit FontTableBlobData(nsTArray&& aBuffer) : mTableData(std::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(std::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 { 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) { // Accessing the mFontTableCache pointer is atomic, so we don't need to take // a write lock even if we're initializing it here... MOZ_PUSH_IGNORE_THREAD_SAFETY if (MOZ_UNLIKELY(!mFontTableCache)) { // We do this here rather than on fontEntry construction // because not all shapers will access the table cache at all. // // We're not holding a write lock, so make sure to atomically update // the cache pointer. auto* newCache = new FontTableCache(8); if (MOZ_UNLIKELY(!mFontTableCache.compareExchange(nullptr, newCache))) { delete newCache; } } FontTableCache* cache = GetFontTableCache(); MOZ_POP_THREAD_SAFETY // ...but we do need a lock to read the actual hashtable contents. AutoReadLock lock(mLock); FontTableHashEntry* entry = cache->GetEntry(aTag); if (!entry) { return false; } *aBlob = entry->GetBlob(); return true; } hb_blob_t* gfxFontEntry::ShareFontTableAndGetBlob(uint32_t aTag, nsTArray* aBuffer) { MOZ_PUSH_IGNORE_THREAD_SAFETY if (MOZ_UNLIKELY(!mFontTableCache)) { auto* newCache = new FontTableCache(8); if (MOZ_UNLIKELY(!mFontTableCache.compareExchange(nullptr, newCache))) { delete newCache; } } FontTableCache* cache = GetFontTableCache(); MOZ_POP_THREAD_SAFETY AutoWriteLock lock(mLock); FontTableHashEntry* entry = cache->PutEntry(aTag); if (MOZ_UNLIKELY(!entry)) { // OOM return nullptr; } if (!aBuffer) { // ensure the entry is null entry->Clear(); return nullptr; } return entry->ShareTableAndGetBlob(std::move(*aBuffer), cache); } already_AddRefed gfxFontEntry::GetCMAPFromFontInfo( FontInfoData* aFontInfoData, uint32_t& aUVSOffset) { if (!aFontInfoData || !aFontInfoData->mLoadCmaps) { return nullptr; } return aFontInfoData->GetCMAP(mName, aUVSOffset); } 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 thread_local gfxFontEntry* tl_grGetFontTableCallbackData = nullptr; class gfxFontEntryCallbacks { public: static tainted_gr GrGetTable( rlbox_sandbox_gr& sandbox, tainted_gr /* aAppFaceHandle */, tainted_gr aName, tainted_gr aLen) { gfxFontEntry* fontEntry = tl_grGetFontTableCallbackData; *aLen = 0; tainted_gr ret = nullptr; if (fontEntry) { unsigned int fontTableKey = aName.unverified_safe_because( "This is only being used to index into a hashmap, which is robust " "for any value. No checks needed."); gfxFontUtils::AutoHBBlob blob(fontEntry->GetFontTable(fontTableKey)); if (blob) { unsigned int blobLength; const void* tableData = hb_blob_get_data(blob, &blobLength); // tableData is read-only data shared with the sandbox. // Making a copy in sandbox memory tainted_gr t_tableData = rlbox::sandbox_reinterpret_cast( sandbox.malloc_in_sandbox(blobLength)); if (t_tableData) { rlbox::memcpy(sandbox, t_tableData, tableData, blobLength); *aLen = blobLength; ret = rlbox::sandbox_const_cast(t_tableData); } } } return ret; } static void GrReleaseTable(rlbox_sandbox_gr& sandbox, tainted_gr /* aAppFaceHandle */, tainted_gr aTableBuffer) { sandbox.free_in_sandbox(aTableBuffer); } static tainted_gr GrGetAdvance(rlbox_sandbox_gr& sandbox, tainted_gr appFontHandle, tainted_gr glyphid) { tainted_opaque_gr ret = gfxGraphiteShaper::GrGetAdvance( sandbox, appFontHandle.to_opaque(), glyphid.to_opaque()); return rlbox::from_opaque(ret); } }; struct gfxFontEntry::GrSandboxData { rlbox_sandbox_gr sandbox; sandbox_callback_gr grGetTableCallback; sandbox_callback_gr grReleaseTableCallback; // Text Shapers register a callback to get glyph advances sandbox_callback_gr grGetGlyphAdvanceCallback; GrSandboxData() { sandbox.create_sandbox(); grGetTableCallback = sandbox.register_callback(gfxFontEntryCallbacks::GrGetTable); grReleaseTableCallback = sandbox.register_callback(gfxFontEntryCallbacks::GrReleaseTable); grGetGlyphAdvanceCallback = sandbox.register_callback(gfxFontEntryCallbacks::GrGetAdvance); } ~GrSandboxData() { grGetTableCallback.unregister(); grReleaseTableCallback.unregister(); grGetGlyphAdvanceCallback.unregister(); sandbox.destroy_sandbox(); } }; rlbox_sandbox_gr* gfxFontEntry::GetGrSandbox() { AutoReadLock lock(mLock); MOZ_ASSERT(mSandboxData != nullptr); return &mSandboxData->sandbox; } sandbox_callback_gr* gfxFontEntry::GetGrSandboxAdvanceCallbackHandle() { AutoReadLock lock(mLock); MOZ_ASSERT(mSandboxData != nullptr); return &mSandboxData->grGetGlyphAdvanceCallback; } tainted_opaque_gr gfxFontEntry::GetGrFace() { if (!mGrFaceInitialized) { // When possible, the below code will use WASM as a sandboxing mechanism. // At this time the wasm sandbox does not support threads. // If Thebes is updated to make callst to the sandbox on multiple threaads, // we need to make sure the underlying sandbox supports threading. MOZ_ASSERT(NS_IsMainThread()); mSandboxData = new GrSandboxData(); auto p_faceOps = mSandboxData->sandbox.malloc_in_sandbox(); if (!p_faceOps) { MOZ_CRASH("Graphite sandbox memory allocation failed"); } p_faceOps->size = sizeof(*p_faceOps); p_faceOps->get_table = mSandboxData->grGetTableCallback; p_faceOps->release_table = mSandboxData->grReleaseTableCallback; tl_grGetFontTableCallbackData = this; auto face = sandbox_invoke( mSandboxData->sandbox, gr_make_face_with_ops, // For security, we do not pass the callback data to this arg, and use // a TLS var instead. However, gr_make_face_with_ops expects this to // be a non null ptr. Therefore, we should pass some dummy non null // pointer which will be passed to callbacks, but never used. Let's just // pass p_faceOps again, as this is a non-null tainted pointer. p_faceOps /* appFaceHandle */, p_faceOps, gr_face_default); tl_grGetFontTableCallbackData = nullptr; mGrFace = face.to_opaque(); mGrFaceInitialized = true; mSandboxData->sandbox.free_in_sandbox(p_faceOps); } ++mGrFaceRefCnt; return mGrFace; } void gfxFontEntry::ReleaseGrFace(tainted_opaque_gr aFace) { MOZ_ASSERT( (rlbox::from_opaque(aFace) == rlbox::from_opaque(mGrFace)) .unverified_safe_because( "This is safe as the only thing we are doing is comparing " "addresses of two tainted pointers. Furthermore this is used " "merely as a debugging aid in the debug builds. This function is " "called only from the trusted Firefox code rather than the " "untrusted libGraphite.")); // sanity-check MOZ_ASSERT(mGrFaceRefCnt > 0); if (--mGrFaceRefCnt == 0) { auto t_mGrFace = rlbox::from_opaque(mGrFace); tl_grGetFontTableCallbackData = this; sandbox_invoke(mSandboxData->sandbox, gr_face_destroy, t_mGrFace); tl_grGetFontTableCallbackData = nullptr; t_mGrFace = nullptr; mGrFace = t_mGrFace.to_opaque(); delete mSandboxData; mSandboxData = nullptr; mGrFaceInitialized = false; } } 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; } tainted_boolean_hint gfxFontEntry::HasGraphiteSpaceContextuals() { LazyFlag flag = mHasGraphiteSpaceContextuals; if (flag == LazyFlag::Uninitialized) { auto face = GetGrFace(); auto t_face = rlbox::from_opaque(face); if (t_face) { tainted_gr faceInfo = sandbox_invoke(mSandboxData->sandbox, gr_face_info, t_face, 0); // Comparison with a value in sandboxed memory returns a // tainted_boolean_hint, i.e. a "hint", since the value could be changed // maliciously at any moment. tainted_boolean_hint is_not_none = faceInfo->space_contextuals != gr_faceinfo::gr_space_none; flag = is_not_none.unverified_safe_because( "Note ideally mHasGraphiteSpaceContextuals would be " "tainted_boolean_hint, but RLBox does not yet support " "bitfields, so it is not wrapped. However, its value is only " "ever accessed through this function which returns a " "tainted_boolean_hint, so unwrapping temporarily is safe. " "We remove the wrapper now and re-add it below.") ? LazyFlag::Yes : LazyFlag::No; } ReleaseGrFace(face); // always balance GetGrFace, even if face is null mHasGraphiteSpaceContextuals = flag; } return tainted_boolean_hint(flag == LazyFlag::Yes); } #define FEATURE_SCRIPT_MASK 0x000000ff // script index replaces low byte of tag static_assert(int(intl::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) { MutexAutoLock lock(mFeatureInfoLock); 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); return mSupportedFeatures->LookupOrInsertWith(scriptFeature, [&] { bool result = false; auto 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 unsigned int scriptCount = 4; hb_tag_t scriptTags[4]; hb_ot_tags_from_script_and_language(hbScript, HB_LANGUAGE_INVALID, &scriptCount, scriptTags, nullptr, nullptr); // Append DEFAULT to the returned tags, if room if (scriptCount < 4) { scriptTags[scriptCount++] = 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'); result = std::any_of(scriptTags, scriptTags + scriptCount, [&](const hb_tag_t& scriptTag) { unsigned int scriptIndex; return hb_ot_layout_table_find_script( face, kGSUB, scriptTag, &scriptIndex) && hb_ot_layout_language_find_feature( face, kGSUB, scriptIndex, HB_OT_LAYOUT_DEFAULT_LANGUAGE_INDEX, aFeatureTag, nullptr); }); } return result; }); } const hb_set_t* gfxFontEntry::InputsForOpenTypeFeature(Script aScript, uint32_t aFeatureTag) { MutexAutoLock lock(mFeatureInfoLock); if (!mFeatureInputs) { mFeatureInputs = MakeUnique>(); } NS_ASSERTION(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"); uint32_t scriptFeature = SCRIPT_FEATURE(aScript, aFeatureTag); hb_set_t* inputGlyphs; if (mFeatureInputs->Get(scriptFeature, &inputGlyphs)) { return inputGlyphs; } inputGlyphs = hb_set_create(); auto 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 unsigned int scriptCount = 4; hb_tag_t scriptTags[5]; // space for null terminator hb_ot_tags_from_script_and_language(hbScript, HB_LANGUAGE_INVALID, &scriptCount, scriptTags, nullptr, nullptr); // Append DEFAULT to the returned tags, if room if (scriptCount < 4) { scriptTags[scriptCount++] = HB_OT_TAG_DEFAULT_SCRIPT; } scriptTags[scriptCount++] = 0; 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); } mFeatureInputs->InsertOrUpdate(scriptFeature, inputGlyphs); return inputGlyphs; } bool gfxFontEntry::SupportsGraphiteFeature(uint32_t aFeatureTag) { MutexAutoLock lock(mFeatureInfoLock); 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; } auto face = GetGrFace(); auto t_face = rlbox::from_opaque(face); result = t_face ? sandbox_invoke(mSandboxData->sandbox, gr_face_find_fref, t_face, aFeatureTag) != nullptr : false; ReleaseGrFace(face); mSupportedFeatures->InsertOrUpdate(scriptFeature, result); return result; } void gfxFontEntry::GetFeatureInfo(nsTArray& aFeatureInfo) { // TODO: implement alternative code path for graphite fonts auto autoFace(GetHBFace()); // Expose the raw hb_face_t to be captured by the lambdas (not the // AutoHBFace wrapper). hb_face_t* face = autoFace; // Get the list of features for a specific pair and // append them to aFeatureInfo. auto collectForLang = [=, &aFeatureInfo]( hb_tag_t aTableTag, unsigned int aScript, hb_tag_t aScriptTag, unsigned int aLang, hb_tag_t aLangTag) { unsigned int featCount = hb_ot_layout_language_get_feature_tags( face, aTableTag, aScript, aLang, 0, nullptr, nullptr); AutoTArray featTags; featTags.SetLength(featCount); hb_ot_layout_language_get_feature_tags(face, aTableTag, aScript, aLang, 0, &featCount, featTags.Elements()); MOZ_ASSERT(featCount <= featTags.Length()); // Just in case HB didn't fill featTags (i.e. in case it returned fewer // tags than it promised), we truncate at the length it says it filled: featTags.SetLength(featCount); for (hb_tag_t t : featTags) { aFeatureInfo.AppendElement(gfxFontFeatureInfo{t, aScriptTag, aLangTag}); } }; // Iterate over the language systems supported by a given script, // and call collectForLang for each of them. auto collectForScript = [=](hb_tag_t aTableTag, unsigned int aScript, hb_tag_t aScriptTag) { collectForLang(aTableTag, aScript, aScriptTag, HB_OT_LAYOUT_DEFAULT_LANGUAGE_INDEX, HB_TAG('d', 'f', 'l', 't')); unsigned int langCount = hb_ot_layout_script_get_language_tags( face, aTableTag, aScript, 0, nullptr, nullptr); AutoTArray langTags; langTags.SetLength(langCount); hb_ot_layout_script_get_language_tags(face, aTableTag, aScript, 0, &langCount, langTags.Elements()); MOZ_ASSERT(langCount <= langTags.Length()); langTags.SetLength(langCount); for (unsigned int lang = 0; lang < langCount; ++lang) { collectForLang(aTableTag, aScript, aScriptTag, lang, langTags[lang]); } }; // Iterate over the scripts supported by a table (GSUB or GPOS), and call // collectForScript for each of them. auto collectForTable = [=](hb_tag_t aTableTag) { unsigned int scriptCount = hb_ot_layout_table_get_script_tags( face, aTableTag, 0, nullptr, nullptr); AutoTArray scriptTags; scriptTags.SetLength(scriptCount); hb_ot_layout_table_get_script_tags(face, aTableTag, 0, &scriptCount, scriptTags.Elements()); MOZ_ASSERT(scriptCount <= scriptTags.Length()); scriptTags.SetLength(scriptCount); for (unsigned int script = 0; script < scriptCount; ++script) { collectForScript(aTableTag, script, scriptTags[script]); } }; // Collect all OpenType Layout features, both substitution and positioning, // supported by the font resource. collectForTable(HB_TAG('G', 'S', 'U', 'B')); collectForTable(HB_TAG('G', 'P', 'O', 'S')); } typedef struct { AutoSwap_PRUint32 version; AutoSwap_PRUint16 format; AutoSwap_PRUint16 horizOffset; AutoSwap_PRUint16 vertOffset; AutoSwap_PRUint16 reserved; // TrackData horizData; // TrackData vertData; } TrakHeader; typedef struct { AutoSwap_PRUint16 nTracks; AutoSwap_PRUint16 nSizes; AutoSwap_PRUint32 sizeTableOffset; // trackTableEntry trackTable[]; // fixed32 sizeTable[]; } TrackData; typedef struct { AutoSwap_PRUint32 track; AutoSwap_PRUint16 nameIndex; AutoSwap_PRUint16 offset; } TrackTableEntry; bool gfxFontEntry::HasTrackingTable() { if (!TrakTableInitialized()) { hb_blob_t* trak = GetFontTable(TRUETYPE_TAG('t', 'r', 'a', 'k')); if (trak) { // mTrakTable itself is atomic, but we also want to set the auxiliary // pointers mTrakValues and mTrakSizeTable, so we take a lock here to // avoid racing with another thread also initializing the same values. AutoWriteLock lock(mLock); if (!mTrakTable.compareExchange(kTrakTableUninitialized, trak)) { hb_blob_destroy(trak); } else if (!ParseTrakTable()) { hb_blob_destroy(mTrakTable.exchange(nullptr)); } } else { mTrakTable.exchange(nullptr); } } return GetTrakTable() != nullptr; } bool gfxFontEntry::ParseTrakTable() { // Check table validity and set up the subtable pointers we need; // if 'trak' table is invalid, or doesn't contain a 'normal' track, // return false to tell the caller not to try using it. unsigned int len; const char* data = hb_blob_get_data(GetTrakTable(), &len); if (len < sizeof(TrakHeader)) { return false; } auto trak = reinterpret_cast(data); uint16_t horizOffset = trak->horizOffset; if (trak->version != 0x00010000 || uint16_t(trak->format) != 0 || horizOffset == 0 || uint16_t(trak->reserved) != 0) { return false; } // Find the horizontal trackData, and check it doesn't overrun the buffer. if (horizOffset > len - sizeof(TrackData)) { return false; } auto trackData = reinterpret_cast(data + horizOffset); uint16_t nTracks = trackData->nTracks; mNumTrakSizes = trackData->nSizes; if (nTracks == 0 || mNumTrakSizes < 2) { return false; } uint32_t sizeTableOffset = trackData->sizeTableOffset; // Find the trackTable, and check it doesn't overrun the buffer. if (horizOffset > len - (sizeof(TrackData) + nTracks * sizeof(TrackTableEntry))) { return false; } auto trackTable = reinterpret_cast( data + horizOffset + sizeof(TrackData)); // Look for 'normal' tracking, bail out if no such track is present. unsigned trackIndex; for (trackIndex = 0; trackIndex < nTracks; ++trackIndex) { if (trackTable[trackIndex].track == 0x00000000) { break; } } if (trackIndex == nTracks) { return false; } // Find list of tracking values, and check they won't overrun. uint16_t offset = trackTable[trackIndex].offset; if (offset > len - mNumTrakSizes * sizeof(uint16_t)) { return false; } mTrakValues = reinterpret_cast(data + offset); // Find the size subtable, and check it doesn't overrun the buffer. mTrakSizeTable = reinterpret_cast(data + sizeTableOffset); if (mTrakSizeTable + mNumTrakSizes > reinterpret_cast(data + len)) { return false; } return true; } float gfxFontEntry::TrackingForCSSPx(float aSize) const { // No locking because this does read-only access of fields that are inert // once initialized. MOZ_ASSERT(TrakTableInitialized() && mTrakTable && mTrakValues && mTrakSizeTable); // Find index of first sizeTable entry that is >= the requested size. int32_t fixedSize = int32_t(aSize * 65536.0); // float -> 16.16 fixed-point unsigned sizeIndex; for (sizeIndex = 0; sizeIndex < mNumTrakSizes; ++sizeIndex) { if (mTrakSizeTable[sizeIndex] >= fixedSize) { break; } } // Return the tracking value for the requested size, or an interpolated // value if the exact size isn't found. if (sizeIndex == mNumTrakSizes) { // Request is larger than last entry in the table, so just use that. // (We don't attempt to extrapolate more extreme tracking values than // the largest or smallest present in the table.) return int16_t(mTrakValues[mNumTrakSizes - 1]); } if (sizeIndex == 0 || mTrakSizeTable[sizeIndex] == fixedSize) { // Found an exact match, or size was smaller than the first entry. return int16_t(mTrakValues[sizeIndex]); } // Requested size falls between two entries: interpolate value. double s0 = mTrakSizeTable[sizeIndex - 1] / 65536.0; // 16.16 -> float double s1 = mTrakSizeTable[sizeIndex] / 65536.0; double t = (aSize - s0) / (s1 - s0); return (1.0 - t) * int16_t(mTrakValues[sizeIndex - 1]) + t * int16_t(mTrakValues[sizeIndex]); } void gfxFontEntry::SetupVariationRanges() { // No locking because this is done during initialization before any other // thread has access to the entry. if (!gfxPlatform::HasVariationFontSupport() || !StaticPrefs::layout_css_font_variations_enabled() || !HasVariations() || IsUserFont()) { return; } AutoTArray axes; GetVariationAxes(axes); for (const auto& axis : axes) { switch (axis.mTag) { case HB_TAG('w', 'g', 'h', 't'): // If the axis range looks like it doesn't fit the CSS font-weight // scale, we don't hook up the high-level property, and we mark // the face (in mRangeFlags) as having non-standard weight. This // means we won't map CSS font-weight to the axis. Setting 'wght' // with font-variation-settings will still work. // Strictly speaking, the min value should be checked against 1.0, // not 0.0, but we'll allow font makers that amount of leeway, as // in practice a number of fonts seem to use 0..1000. if (axis.mMinValue >= 0.0f && axis.mMaxValue <= 1000.0f && // If axis.mMaxValue is less than the default weight we already // set up, assume the axis has a non-standard range (like Skia) // and don't try to map it. Weight().Min() <= FontWeight::FromFloat(axis.mMaxValue)) { if (FontWeight::FromFloat(axis.mDefaultValue) != Weight().Min()) { mStandardFace = false; } mWeightRange = WeightRange(FontWeight::FromFloat(std::max(1.0f, axis.mMinValue)), FontWeight::FromFloat(axis.mMaxValue)); } else { mRangeFlags |= RangeFlags::eNonCSSWeight; } break; case HB_TAG('w', 'd', 't', 'h'): if (axis.mMinValue >= 0.0f && axis.mMaxValue <= 1000.0f && Stretch().Min() <= FontStretch::FromFloat(axis.mMaxValue)) { if (FontStretch::FromFloat(axis.mDefaultValue) != Stretch().Min()) { mStandardFace = false; } mStretchRange = StretchRange(FontStretch::FromFloat(axis.mMinValue), FontStretch::FromFloat(axis.mMaxValue)); } else { mRangeFlags |= RangeFlags::eNonCSSStretch; } break; case HB_TAG('s', 'l', 'n', 't'): if (axis.mMinValue >= -90.0f && axis.mMaxValue <= 90.0f) { if (FontSlantStyle::FromFloat(axis.mDefaultValue) != SlantStyle().Min()) { mStandardFace = false; } // OpenType and CSS measure angles in opposite directions, so we // have to flip signs and swap min/max when setting up the CSS // font-style range here. mStyleRange = SlantStyleRange(FontSlantStyle::FromFloat(-axis.mMaxValue), FontSlantStyle::FromFloat(-axis.mMinValue)); } break; case HB_TAG('i', 't', 'a', 'l'): if (axis.mMinValue <= 0.0f && axis.mMaxValue >= 1.0f) { if (axis.mDefaultValue != 0.0f) { mStandardFace = false; } mStyleRange = SlantStyleRange(FontSlantStyle::NORMAL, FontSlantStyle::ITALIC); } break; default: continue; } } } void gfxFontEntry::CheckForVariationAxes() { if (mCheckedForVariationAxes) { return; } mCheckedForVariationAxes = true; if (HasVariations()) { AutoTArray axes; GetVariationAxes(axes); for (const auto& axis : axes) { if (axis.mTag == HB_TAG('w', 'g', 'h', 't') && axis.mMaxValue >= 600.0f) { mRangeFlags |= RangeFlags::eBoldVariableWeight; } else if (axis.mTag == HB_TAG('i', 't', 'a', 'l') && axis.mMaxValue >= 1.0f) { mRangeFlags |= RangeFlags::eItalicVariation; } else if (axis.mTag == HB_TAG('o', 'p', 's', 'z')) { mRangeFlags |= RangeFlags::eOpticalSize; } } } } bool gfxFontEntry::HasBoldVariableWeight() { MOZ_ASSERT(!mIsUserFontContainer, "should not be called for user-font containers!"); CheckForVariationAxes(); return bool(mRangeFlags & RangeFlags::eBoldVariableWeight); } bool gfxFontEntry::HasItalicVariation() { MOZ_ASSERT(!mIsUserFontContainer, "should not be called for user-font containers!"); CheckForVariationAxes(); return bool(mRangeFlags & RangeFlags::eItalicVariation); } bool gfxFontEntry::HasOpticalSize() { MOZ_ASSERT(!mIsUserFontContainer, "should not be called for user-font containers!"); CheckForVariationAxes(); return bool(mRangeFlags & RangeFlags::eOpticalSize); } void gfxFontEntry::GetVariationsForStyle(nsTArray& aResult, const gfxFontStyle& aStyle) { if (!gfxPlatform::HasVariationFontSupport() || !StaticPrefs::layout_css_font_variations_enabled()) { return; } if (!HasVariations()) { return; } // Resolve high-level CSS properties from the requested style // (font-{style,weight,stretch}) to the appropriate variations. // The value used is clamped to the range available in the font face, // unless the face is a user font where no explicit descriptor was // given, indicated by the corresponding 'auto' range-flag. // We don't do these mappings if the font entry has weight and/or stretch // ranges that do not appear to use the CSS property scale. Some older // fonts created for QuickDrawGX/AAT may use "normalized" values where the // standard variation is 1.0 rather than 400.0 (weight) or 100.0 (stretch). if (!(mRangeFlags & RangeFlags::eNonCSSWeight)) { float weight = (IsUserFont() && (mRangeFlags & RangeFlags::eAutoWeight)) ? aStyle.weight.ToFloat() : Weight().Clamp(aStyle.weight).ToFloat(); aResult.AppendElement(gfxFontVariation{HB_TAG('w', 'g', 'h', 't'), weight}); } if (!(mRangeFlags & RangeFlags::eNonCSSStretch)) { float stretch = (IsUserFont() && (mRangeFlags & RangeFlags::eAutoStretch)) ? aStyle.stretch.ToFloat() : Stretch().Clamp(aStyle.stretch).ToFloat(); aResult.AppendElement( gfxFontVariation{HB_TAG('w', 'd', 't', 'h'), stretch}); } if (aStyle.style.IsItalic() && SupportsItalic()) { // The 'ital' axis is normally a binary toggle; intermediate values // can only be set using font-variation-settings. aResult.AppendElement(gfxFontVariation{HB_TAG('i', 't', 'a', 'l'), 1.0f}); } else if (SlantStyle().Min().IsOblique()) { // Figure out what slant angle we should try to match from the // requested style. float angle = aStyle.style.IsNormal() ? 0.0f : aStyle.style.IsItalic() ? FontSlantStyle::DEFAULT_OBLIQUE_DEGREES : aStyle.style.ObliqueAngle(); // Clamp to the available range, unless the face is a user font // with no explicit descriptor. if (!(IsUserFont() && (mRangeFlags & RangeFlags::eAutoSlantStyle))) { angle = SlantStyle().Clamp(FontSlantStyle::FromFloat(angle)).ObliqueAngle(); } // OpenType and CSS measure angles in opposite directions, so we have to // invert the sign of the CSS oblique value when setting OpenType 'slnt'. aResult.AppendElement(gfxFontVariation{HB_TAG('s', 'l', 'n', 't'), -angle}); } struct TagEquals { bool Equals(const gfxFontVariation& aIter, uint32_t aTag) const { return aIter.mTag == aTag; } }; auto replaceOrAppend = [&aResult](const gfxFontVariation& aSetting) { auto index = aResult.IndexOf(aSetting.mTag, 0, TagEquals()); if (index == aResult.NoIndex) { aResult.AppendElement(aSetting); } else { aResult[index].mValue = aSetting.mValue; } }; // The low-level font-variation-settings descriptor from @font-face, // if present, takes precedence over automatic variation settings // from high-level properties. for (const auto& v : mVariationSettings) { replaceOrAppend(v); } // And the low-level font-variation-settings property takes precedence // over the descriptor. for (const auto& v : aStyle.variationSettings) { replaceOrAppend(v); } // If there's no explicit opsz in the settings, apply 'auto' value. if (HasOpticalSize() && aStyle.autoOpticalSize >= 0.0f) { const uint32_t kOpszTag = HB_TAG('o', 'p', 's', 'z'); auto index = aResult.IndexOf(kOpszTag, 0, TagEquals()); if (index == aResult.NoIndex) { float value = aStyle.autoOpticalSize * mSizeAdjust; aResult.AppendElement(gfxFontVariation{kOpszTag, value}); } } } 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 && GetCharacterMap()->mBuildOnTheFly) { aSizes->mCharMapsSize += GetCharacterMap()->SizeOfIncludingThis(aMallocSizeOf); } { AutoReadLock lock(mLock); if (mFontTableCache) { aSizes->mFontTableCacheSize += GetFontTableCache()->SizeOfIncludingThis(aMallocSizeOf); } } // If the font has UVS data, we count that as part of the character map. if (mUVSData) { aSizes->mCharMapsSize += aMallocSizeOf(GetUVSData()); } // 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 += GetSVGGlyphs()->SizeOfIncludingThis(aMallocSizeOf); } { MutexAutoLock lock(mFeatureInfoLock); if (mSupportedFeatures) { aSizes->mFontTableCacheSize += mSupportedFeatures->ShallowSizeOfIncludingThis(aMallocSizeOf); } if (mFeatureInputs) { aSizes->mFontTableCacheSize += mFeatureInputs->ShallowSizeOfIncludingThis(aMallocSizeOf); // XXX Can't this simply be // aSizes->mFontTableCacheSize += 8192 * mFeatureInputs->Count(); 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() { MOZ_ASSERT(mLock.LockedForWritingByCurrentThread()); 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 aIgnoreSizeTolerance) { AutoTArray matched; FindAllFontsForStyle(aFontStyle, matched, aIgnoreSizeTolerance); if (!matched.IsEmpty()) { return matched[0]; } return nullptr; } static inline double WeightStyleStretchDistance( gfxFontEntry* aFontEntry, const gfxFontStyle& aTargetStyle) { double stretchDist = StretchDistance(aFontEntry->Stretch(), aTargetStyle.stretch); double styleDist = StyleDistance(aFontEntry->SlantStyle(), aTargetStyle.style); double weightDist = WeightDistance(aFontEntry->Weight(), aTargetStyle.weight); // Sanity-check that the distances are within the expected range // (update if implementation of the distance functions is changed). MOZ_ASSERT(stretchDist >= 0.0 && stretchDist <= 2000.0); MOZ_ASSERT(styleDist >= 0.0 && styleDist <= 500.0); MOZ_ASSERT(weightDist >= 0.0 && weightDist <= 1600.0); // weight/style/stretch priority: stretch >> style >> weight // so we multiply the stretch and style values to make them dominate // the result return stretchDist * kStretchFactor + styleDist * kStyleFactor + weightDist * kWeightFactor; } void gfxFontFamily::FindAllFontsForStyle( const gfxFontStyle& aFontStyle, nsTArray& aFontEntryList, bool aIgnoreSizeTolerance) { if (!mHasStyles) { FindStyleVariations(); // collect faces for the family, if not already // done } AutoReadLock lock(mLock); NS_ASSERTION(mAvailableFonts.Length() > 0, "font family with no faces!"); NS_ASSERTION(aFontEntryList.IsEmpty(), "non-empty fontlist passed in"); 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]; 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 wantBold = aFontStyle.weight >= FontWeight::FromInt(600); bool wantItalic = !aFontStyle.style.IsNormal(); uint8_t faceIndex = (wantItalic ? kItalicMask : 0) | (wantBold ? kBoldMask : 0); // if the desired style is available, return it directly fe = mAvailableFonts[faceIndex]; if (fe) { 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) { aFontEntryList.AppendElement(fe); return; } } // this can't happen unless we have totally broken the font-list manager! MOZ_ASSERT_UNREACHABLE("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. double minDistance = INFINITY; 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 double 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); } } void gfxFontFamily::CheckForSimpleFamily() { MOZ_ASSERT(mLock.LockedForWritingByCurrentThread()); // 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; } StretchRange firstStretch = mAvailableFonts[0]->Stretch(); if (!firstStretch.IsSingle()) { return; // family with variation fonts is not considered "simple" } 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; } if (!fe->Weight().IsSingle() || !fe->SlantStyle().IsSingle()) { return; // family with variation fonts is not considered "simple" } uint8_t faceIndex = (fe->IsItalic() ? kItalicMask : 0) | (fe->SupportsBold() ? 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) { AutoReadLock lock(mLock); 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(nsACString& aLocalizedName) { // just return the primary name; subclasses should override aLocalizedName = mName; } void gfxFontFamily::FindFontForChar(GlobalFontMatch* aMatchData) { gfxPlatformFontList::PlatformFontList()->mLock.AssertCurrentThreadIn(); { AutoReadLock lock(mLock); if (mFamilyCharacterMapInitialized && !TestCharacterMap(aMatchData->mCh)) { // none of the faces in the family support the required char, // so bail out immediately return; } } nsCString charAndName; if (profiler_thread_is_being_profiled( Combine(ThreadProfilingFeatures::Sampling, ThreadProfilingFeatures::Markers))) { charAndName = nsPrintfCString("\\u%x %s", aMatchData->mCh, mName.get()); } AUTO_PROFILER_LABEL_DYNAMIC_NSCSTRING("gfxFontFamily::FindFontForChar", LAYOUT, charAndName); AutoTArray entries; FindAllFontsForStyle(aMatchData->mStyle, entries, /*aIgnoreSizeTolerance*/ true); if (entries.IsEmpty()) { return; } gfxFontEntry* fe = nullptr; float distance = INFINITY; for (auto e : entries) { if (e->SkipDuringSystemFallback()) { continue; } aMatchData->mCmapsTested++; if (e->HasCharacter(aMatchData->mCh)) { aMatchData->mCount++; LogModule* log = gfxPlatform::GetLog(eGfxLog_textrun); if (MOZ_UNLIKELY(MOZ_LOG_TEST(log, LogLevel::Debug))) { intl::Script script = intl::UnicodeProperties::GetScriptCode(aMatchData->mCh); MOZ_LOG(log, LogLevel::Debug, ("(textrun-systemfallback-fonts) char: u+%6.6x " "script: %d match: [%s]\n", aMatchData->mCh, int(script), e->Name().get())); } fe = e; distance = WeightStyleStretchDistance(fe, aMatchData->mStyle); if (aMatchData->mPresentation != eFontPresentation::Any) { RefPtr font = fe->FindOrMakeFont(&aMatchData->mStyle); if (!font) { continue; } bool hasColorGlyph = font->HasColorGlyphFor(aMatchData->mCh, aMatchData->mNextCh); if (hasColorGlyph != PrefersColor(aMatchData->mPresentation)) { distance += kPresentationMismatch; } } break; } } if (!fe && !aMatchData->mStyle.IsNormalStyle()) { // If style/weight/stretch was not Normal, see if we can // fall back to a next-best face (e.g. Arial Black -> Bold, // or Arial Narrow -> Regular). GlobalFontMatch data(aMatchData->mCh, aMatchData->mNextCh, aMatchData->mStyle, aMatchData->mPresentation); SearchAllFontsForChar(&data); if (!data.mBestMatch) { return; } fe = data.mBestMatch; distance = data.mMatchDistance; } if (!fe) { return; } if (distance < aMatchData->mMatchDistance || (distance == aMatchData->mMatchDistance && Compare(fe->Name(), aMatchData->mBestMatch->Name()) > 0)) { aMatchData->mBestMatch = fe; aMatchData->mMatchedFamily = this; aMatchData->mMatchDistance = distance; } } void gfxFontFamily::SearchAllFontsForChar(GlobalFontMatch* aMatchData) { if (!mFamilyCharacterMapInitialized) { ReadAllCMAPs(); } AutoReadLock lock(mLock); if (!mFamilyCharacterMap.test(aMatchData->mCh)) { return; } uint32_t i, numFonts = mAvailableFonts.Length(); for (i = 0; i < numFonts; i++) { gfxFontEntry* fe = mAvailableFonts[i]; if (fe && fe->HasCharacter(aMatchData->mCh)) { float distance = WeightStyleStretchDistance(fe, aMatchData->mStyle); if (aMatchData->mPresentation != eFontPresentation::Any) { RefPtr font = fe->FindOrMakeFont(&aMatchData->mStyle); if (!font) { continue; } bool hasColorGlyph = font->HasColorGlyphFor(aMatchData->mCh, aMatchData->mNextCh); if (hasColorGlyph != PrefersColor(aMatchData->mPresentation)) { distance += kPresentationMismatch; } } if (distance < aMatchData->mMatchDistance || (distance == aMatchData->mMatchDistance && Compare(fe->Name(), aMatchData->mBestMatch->Name()) > 0)) { aMatchData->mBestMatch = fe; aMatchData->mMatchedFamily = this; aMatchData->mMatchDistance = distance; } } } } /*virtual*/ gfxFontFamily::~gfxFontFamily() { // Should not be dropped by stylo, but the InitFontList thread might use // a transient gfxFontFamily and that's OK. MOZ_ASSERT(!gfxFontUtils::IsInServoTraversal()); } // 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; gfxFontUtils::ReadOtherFamilyNamesForFace(mName, nameData, dataLength, otherFamilyNames, useFullName); if (!otherFamilyNames.IsEmpty()) { aPlatformFontList->AddOtherFamilyNames(this, otherFamilyNames); } return !otherFamilyNames.IsEmpty(); } void gfxFontFamily::ReadOtherFamilyNames( gfxPlatformFontList* aPlatformFontList) { AutoWriteLock lock(mLock); if (mOtherFamilyNamesInitialized) { return; } mOtherFamilyNamesInitialized = true; FindStyleVariationsLocked(); // 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); } } static bool LookForLegacyFamilyName(const nsACString& aCanonicalName, const char* aNameData, uint32_t aDataLength, nsACString& aLegacyName /* outparam */) { 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 false; } 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; if (stringsBase + nameOff + nameLen > aDataLength) { NS_WARNING("invalid font (name table strings)"); return false; } if (uint16_t(nameRecord->nameID) == gfxFontUtils::NAME_ID_FAMILY) { bool ok = gfxFontUtils::DecodeFontName( aNameData + stringsBase + nameOff, nameLen, uint32_t(nameRecord->platformID), uint32_t(nameRecord->encodingID), uint32_t(nameRecord->languageID), aLegacyName); // It's only a legacy name if it case-insensitively differs from the // canonical name (otherwise it would map to the same key). if (ok && !aLegacyName.Equals(aCanonicalName, nsCaseInsensitiveCStringComparator)) { return true; } } } return false; } bool gfxFontFamily::CheckForLegacyFamilyNames(gfxPlatformFontList* aFontList) { aFontList->mLock.AssertCurrentThreadIn(); if (mCheckedForLegacyFamilyNames) { // we already did this, so there's nothing more to add return false; } mCheckedForLegacyFamilyNames = true; bool added = false; const uint32_t kNAME = TRUETYPE_TAG('n', 'a', 'm', 'e'); AutoTArray, 16> faces; { // Take a local copy of the array of font entries, because it's possible // AddWithLegacyFamilyName will mutate it (and it needs to be able to take // an exclusive lock on the family to do so, so we release the read lock // here). AutoReadLock lock(mLock); faces.AppendElements(mAvailableFonts); } for (const auto& fe : faces) { if (!fe) { continue; } gfxFontEntry::AutoTable nameTable(fe, kNAME); if (!nameTable) { continue; } nsAutoCString legacyName; uint32_t dataLength; const char* nameData = hb_blob_get_data(nameTable, &dataLength); if (LookForLegacyFamilyName(Name(), nameData, dataLength, legacyName)) { if (aFontList->AddWithLegacyFamilyName(legacyName, fe, mVisibility)) { added = true; } } } return added; } void gfxFontFamily::ReadFaceNames(gfxPlatformFontList* aPlatformFontList, bool aNeedFullnamePostscriptNames, FontInfoData* aFontInfoData) { aPlatformFontList->mLock.AssertCurrentThreadIn(); // if all needed names have already been read, skip if (mOtherFamilyNamesInitialized && (mFaceNamesInitialized || !aNeedFullnamePostscriptNames)) { return; } AutoWriteLock lock(mLock); bool asyncFontLoaderDisabled = false; if (!mOtherFamilyNamesInitialized && aFontInfoData && aFontInfoData->mLoadOtherNames && !asyncFontLoaderDisabled) { const auto* otherFamilyNames = aFontInfoData->GetOtherFamilyNames(mName); if (otherFamilyNames && otherFamilyNames->Length()) { aPlatformFontList->AddOtherFamilyNames(this, *otherFamilyNames); } mOtherFamilyNamesInitialized = true; } // if all needed data has been initialized, return if (mOtherFamilyNamesInitialized && (mFaceNamesInitialized || !aNeedFullnamePostscriptNames)) { return; } FindStyleVariationsLocked(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; } nsAutoCString fullname, psname; bool foundFaceNames = false; if (!mFaceNamesInitialized && aNeedFullnamePostscriptNames && aFontInfoData && aFontInfoData->mLoadFaceNames) { aFontInfoData->GetFaceNames(fe->Name(), fullname, psname); if (!fullname.IsEmpty()) { aPlatformFontList->AddFullnameLocked(fe, fullname); } if (!psname.IsEmpty()) { aPlatformFontList->AddPostscriptNameLocked(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->AddFullnameLocked(fe, fullname); } if (gfxFontUtils::ReadCanonicalName( nameTable, gfxFontUtils::NAME_ID_POSTSCRIPT, psname) == NS_OK) { aPlatformFontList->AddPostscriptNameLocked(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 nsACString& aFontName, const nsCStringComparator& aCmp) const { // find the font using a simple linear search AutoReadLock lock(mLock); uint32_t numFonts = mAvailableFonts.Length(); for (uint32_t i = 0; i < numFonts; i++) { gfxFontEntry* fe = mAvailableFonts[i].get(); if (fe && fe->Name().Equals(aFontName, aCmp)) { return fe; } } return nullptr; } void gfxFontFamily::ReadAllCMAPs(FontInfoData* aFontInfoData) { AutoWriteLock lock(mLock); FindStyleVariationsLocked(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->GetCharacterMap())); } mFamilyCharacterMap.Compact(); mFamilyCharacterMapInitialized = true; } void gfxFontFamily::AddSizeOfExcludingThis(MallocSizeOf aMallocSizeOf, FontListSizes* aSizes) const { AutoReadLock lock(mLock); 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); }