/* -*- 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 "gfxFT2FontBase.h" #include "gfxFT2Utils.h" #include "harfbuzz/hb.h" #include "mozilla/Likely.h" #include "mozilla/StaticPrefs_gfx.h" #include "gfxFontConstants.h" #include "gfxFontUtils.h" #include #include #include FT_TRUETYPE_TAGS_H #include FT_TRUETYPE_TABLES_H #include FT_ADVANCES_H #include FT_MULTIPLE_MASTERS_H #ifndef FT_LOAD_COLOR # define FT_LOAD_COLOR (1L << 20) #endif #ifndef FT_FACE_FLAG_COLOR # define FT_FACE_FLAG_COLOR (1L << 14) #endif using namespace mozilla; using namespace mozilla::gfx; gfxFT2FontBase::gfxFT2FontBase( const RefPtr& aUnscaledFont, RefPtr&& aFTFace, gfxFontEntry* aFontEntry, const gfxFontStyle* aFontStyle, int aLoadFlags, bool aEmbolden) : gfxFont(aUnscaledFont, aFontEntry, aFontStyle, kAntialiasDefault), mFTFace(std::move(aFTFace)), mFTLoadFlags(aLoadFlags | FT_LOAD_IGNORE_GLOBAL_ADVANCE_WIDTH | FT_LOAD_COLOR), mEmbolden(aEmbolden), mFTSize(1.0) {} gfxFT2FontBase::~gfxFT2FontBase() { mFTFace->ForgetLockOwner(this); } FT_Face gfxFT2FontBase::LockFTFace() { if (!mFTFace->Lock(this)) { FT_Set_Transform(mFTFace->GetFace(), nullptr, nullptr); FT_F26Dot6 charSize = NS_lround(mFTSize * 64.0); FT_Set_Char_Size(mFTFace->GetFace(), charSize, charSize, 0, 0); } return mFTFace->GetFace(); } void gfxFT2FontBase::UnlockFTFace() { mFTFace->Unlock(); } gfxFT2FontEntryBase::CmapCacheSlot* gfxFT2FontEntryBase::GetCmapCacheSlot( uint32_t aCharCode) { // This cache algorithm and size is based on what is done in // cairo_scaled_font_text_to_glyphs and pango_fc_font_real_get_glyph. I // think the concept is that adjacent characters probably come mostly from // one Unicode block. This assumption is probably not so valid with // scripts with large character sets as used for East Asian languages. if (!mCmapCache) { mCmapCache = mozilla::MakeUnique(kNumCmapCacheSlots); // Invalidate slot 0 by setting its char code to something that would // never end up in slot 0. All other slots are already invalid // because they have mCharCode = 0 and a glyph for char code 0 will // always be in the slot 0. mCmapCache[0].mCharCode = 1; } return &mCmapCache[aCharCode % kNumCmapCacheSlots]; } uint32_t gfxFT2FontBase::GetGlyph(uint32_t aCharCode) { // FcFreeTypeCharIndex needs to lock the FT_Face and can end up searching // through all the postscript glyph names in the font. Therefore use a // lightweight cache, which is stored on the font entry. auto* slot = static_cast(mFontEntry.get()) ->GetCmapCacheSlot(aCharCode); if (slot->mCharCode != aCharCode) { slot->mCharCode = aCharCode; slot->mGlyphIndex = gfxFT2LockedFace(this).GetGlyph(aCharCode); } return slot->mGlyphIndex; } // aScale is intended for a 16.16 x/y_scale of an FT_Size_Metrics static inline FT_Long ScaleRoundDesignUnits(FT_Short aDesignMetric, FT_Fixed aScale) { FT_Long fixed26dot6 = FT_MulFix(aDesignMetric, aScale); return ROUND_26_6_TO_INT(fixed26dot6); } // Snap a line to pixels while keeping the center and size of the line as // close to the original position as possible. // // Pango does similar snapping for underline and strikethrough when fonts are // hinted, but nsCSSRendering::GetTextDecorationRectInternal always snaps the // top and size of lines. Optimizing the distance between the line and // baseline is probably good for the gap between text and underline, but // optimizing the center of the line is better for positioning strikethough. static void SnapLineToPixels(gfxFloat& aOffset, gfxFloat& aSize) { gfxFloat snappedSize = std::max(floor(aSize + 0.5), 1.0); // Correct offset for change in size gfxFloat offset = aOffset - 0.5 * (aSize - snappedSize); // Snap offset aOffset = floor(offset + 0.5); aSize = snappedSize; } static inline gfxRect ScaleGlyphBounds(const IntRect& aBounds, gfxFloat aScale) { return gfxRect(FLOAT_FROM_26_6(aBounds.x) * aScale, FLOAT_FROM_26_6(aBounds.y) * aScale, FLOAT_FROM_26_6(aBounds.width) * aScale, FLOAT_FROM_26_6(aBounds.height) * aScale); } /** * Get extents for a simple character representable by a single glyph. * The return value is the glyph id of that glyph or zero if no such glyph * exists. aWidth/aBounds is only set when this returns a non-zero glyph id. * This is just for use during initialization, and doesn't use the width cache. */ uint32_t gfxFT2FontBase::GetCharExtents(char aChar, gfxFloat* aWidth, gfxRect* aBounds) { FT_UInt gid = GetGlyph(aChar); int32_t width; IntRect bounds; if (gid && GetFTGlyphExtents(gid, aWidth ? &width : nullptr, aBounds ? &bounds : nullptr)) { if (aWidth) { *aWidth = FLOAT_FROM_16_16(width); } if (aBounds) { *aBounds = ScaleGlyphBounds(bounds, GetAdjustedSize() / mFTSize); } return gid; } else { return 0; } } /** * Find the closest available fixed strike size, if applicable, to the * desired font size. */ static double FindClosestSize(FT_Face aFace, double aSize) { // FT size selection does not actually support sizes smaller than 1 and will // clamp this internally, regardless of what is requested. Do the clamp here // instead so that glyph extents/font matrix scaling will compensate it, as // Cairo normally would. if (aSize < 1.0) { aSize = 1.0; } if (FT_IS_SCALABLE(aFace)) { return aSize; } double bestDist = DBL_MAX; FT_Int bestSize = -1; for (FT_Int i = 0; i < aFace->num_fixed_sizes; i++) { double dist = aFace->available_sizes[i].y_ppem / 64.0 - aSize; // If the previous best is smaller than the desired size, prefer // a bigger size. Otherwise, just choose whatever size is closest. if (bestDist < 0 ? dist >= bestDist : fabs(dist) <= bestDist) { bestDist = dist; bestSize = i; } } if (bestSize < 0) { return aSize; } return aFace->available_sizes[bestSize].y_ppem / 64.0; } void gfxFT2FontBase::InitMetrics() { mFUnitsConvFactor = 0.0; if (MOZ_UNLIKELY(GetStyle()->size <= 0.0) || MOZ_UNLIKELY(GetStyle()->sizeAdjust == 0.0)) { memset(&mMetrics, 0, sizeof(mMetrics)); // zero initialize mSpaceGlyph = GetGlyph(' '); return; } // Cairo metrics are normalized to em-space, so that whatever fixed size // might actually be chosen is factored out. They are then later scaled by // the font matrix to the target adjusted size. Stash the chosen closest // size here for later scaling of the metrics. mFTSize = FindClosestSize(mFTFace->GetFace(), GetAdjustedSize()); // Explicitly lock the face so we can release it early before calling // back into Cairo below. FT_Face face = LockFTFace(); if (MOZ_UNLIKELY(!face)) { // No face. This unfortunate situation might happen if the font // file is (re)moved at the wrong time. const gfxFloat emHeight = GetAdjustedSize(); mMetrics.emHeight = emHeight; mMetrics.maxAscent = mMetrics.emAscent = 0.8 * emHeight; mMetrics.maxDescent = mMetrics.emDescent = 0.2 * emHeight; mMetrics.maxHeight = emHeight; mMetrics.internalLeading = 0.0; mMetrics.externalLeading = 0.2 * emHeight; const gfxFloat spaceWidth = 0.5 * emHeight; mMetrics.spaceWidth = spaceWidth; mMetrics.maxAdvance = spaceWidth; mMetrics.aveCharWidth = spaceWidth; mMetrics.zeroWidth = spaceWidth; const gfxFloat xHeight = 0.5 * emHeight; mMetrics.xHeight = xHeight; mMetrics.capHeight = mMetrics.maxAscent; const gfxFloat underlineSize = emHeight / 14.0; mMetrics.underlineSize = underlineSize; mMetrics.underlineOffset = -underlineSize; mMetrics.strikeoutOffset = 0.25 * emHeight; mMetrics.strikeoutSize = underlineSize; SanitizeMetrics(&mMetrics, false); return; } const FT_Size_Metrics& ftMetrics = face->size->metrics; mMetrics.maxAscent = FLOAT_FROM_26_6(ftMetrics.ascender); mMetrics.maxDescent = -FLOAT_FROM_26_6(ftMetrics.descender); mMetrics.maxAdvance = FLOAT_FROM_26_6(ftMetrics.max_advance); gfxFloat lineHeight = FLOAT_FROM_26_6(ftMetrics.height); gfxFloat emHeight; // Scale for vertical design metric conversion: pixels per design unit. // If this remains at 0.0, we can't use metrics from OS/2 etc. gfxFloat yScale = 0.0; if (FT_IS_SCALABLE(face)) { // Prefer FT_Size_Metrics::x_scale to x_ppem as x_ppem does not // have subpixel accuracy. // // FT_Size_Metrics::y_scale is in 16.16 fixed point format. Its // (fractional) value is a factor that converts vertical metrics from // design units to units of 1/64 pixels, so that the result may be // interpreted as pixels in 26.6 fixed point format. mFUnitsConvFactor = FLOAT_FROM_26_6(FLOAT_FROM_16_16(ftMetrics.x_scale)); yScale = FLOAT_FROM_26_6(FLOAT_FROM_16_16(ftMetrics.y_scale)); emHeight = face->units_per_EM * yScale; } else { // Not scalable. emHeight = ftMetrics.y_ppem; // FT_Face doc says units_per_EM and a bunch of following fields // are "only relevant to scalable outlines". If it's an sfnt, // we can get units_per_EM from the 'head' table instead; otherwise, // we don't have a unitsPerEm value so we can't compute/use yScale or // mFUnitsConvFactor (x scale). const TT_Header* head = static_cast(FT_Get_Sfnt_Table(face, ft_sfnt_head)); if (head) { // Bug 1267909 - Even if the font is not explicitly scalable, // if the face has color bitmaps, it should be treated as scalable // and scaled to the desired size. Metrics based on y_ppem need // to be rescaled for the adjusted size. This makes metrics agree // with the scales we pass to Cairo for Fontconfig fonts. if (face->face_flags & FT_FACE_FLAG_COLOR) { emHeight = GetAdjustedSize(); gfxFloat adjustScale = emHeight / ftMetrics.y_ppem; mMetrics.maxAscent *= adjustScale; mMetrics.maxDescent *= adjustScale; mMetrics.maxAdvance *= adjustScale; lineHeight *= adjustScale; } gfxFloat emUnit = head->Units_Per_EM; mFUnitsConvFactor = ftMetrics.x_ppem / emUnit; yScale = emHeight / emUnit; } } TT_OS2* os2 = static_cast(FT_Get_Sfnt_Table(face, ft_sfnt_os2)); if (os2 && os2->sTypoAscender && yScale > 0.0) { mMetrics.emAscent = os2->sTypoAscender * yScale; mMetrics.emDescent = -os2->sTypoDescender * yScale; FT_Short typoHeight = os2->sTypoAscender - os2->sTypoDescender + os2->sTypoLineGap; lineHeight = typoHeight * yScale; // If the OS/2 fsSelection USE_TYPO_METRICS bit is set, // set maxAscent/Descent from the sTypo* fields instead of hhea. const uint16_t kUseTypoMetricsMask = 1 << 7; if ((os2->fsSelection & kUseTypoMetricsMask) || // maxAscent/maxDescent get used for frame heights, and some fonts // don't have the HHEA table ascent/descent set (bug 279032). (mMetrics.maxAscent == 0.0 && mMetrics.maxDescent == 0.0)) { // We use NS_round here to parallel the pixel-rounded values that // freetype gives us for ftMetrics.ascender/descender. mMetrics.maxAscent = NS_round(mMetrics.emAscent); mMetrics.maxDescent = NS_round(mMetrics.emDescent); } } else { mMetrics.emAscent = mMetrics.maxAscent; mMetrics.emDescent = mMetrics.maxDescent; } // gfxFont::Metrics::underlineOffset is the position of the top of the // underline. // // FT_FaceRec documentation describes underline_position as "the // center of the underlining stem". This was the original definition // of the PostScript metric, but in the PostScript table of OpenType // fonts the metric is "the top of the underline" // (http://www.microsoft.com/typography/otspec/post.htm), and FreeType // (up to version 2.3.7) doesn't make any adjustment. // // Therefore get the underline position directly from the table // ourselves when this table exists. Use FreeType's metrics for // other (including older PostScript) fonts. if (face->underline_position && face->underline_thickness && yScale > 0.0) { mMetrics.underlineSize = face->underline_thickness * yScale; TT_Postscript* post = static_cast(FT_Get_Sfnt_Table(face, ft_sfnt_post)); if (post && post->underlinePosition) { mMetrics.underlineOffset = post->underlinePosition * yScale; } else { mMetrics.underlineOffset = face->underline_position * yScale + 0.5 * mMetrics.underlineSize; } } else { // No underline info. // Imitate Pango. mMetrics.underlineSize = emHeight / 14.0; mMetrics.underlineOffset = -mMetrics.underlineSize; } if (os2 && os2->yStrikeoutSize && os2->yStrikeoutPosition && yScale > 0.0) { mMetrics.strikeoutSize = os2->yStrikeoutSize * yScale; mMetrics.strikeoutOffset = os2->yStrikeoutPosition * yScale; } else { // No strikeout info. mMetrics.strikeoutSize = mMetrics.underlineSize; // Use OpenType spec's suggested position for Roman font. mMetrics.strikeoutOffset = emHeight * 409.0 / 2048.0 + 0.5 * mMetrics.strikeoutSize; } SnapLineToPixels(mMetrics.strikeoutOffset, mMetrics.strikeoutSize); if (os2 && os2->sxHeight && yScale > 0.0) { mMetrics.xHeight = os2->sxHeight * yScale; } else { // CSS 2.1, section 4.3.2 Lengths: "In the cases where it is // impossible or impractical to determine the x-height, a value of // 0.5em should be used." mMetrics.xHeight = 0.5 * emHeight; } // aveCharWidth is used for the width of text input elements so be // liberal rather than conservative in the estimate. if (os2 && os2->xAvgCharWidth) { // Round to pixels as this is compared with maxAdvance to guess // whether this is a fixed width font. mMetrics.aveCharWidth = ScaleRoundDesignUnits(os2->xAvgCharWidth, ftMetrics.x_scale); } else { mMetrics.aveCharWidth = 0.0; // updated below } if (os2 && os2->sCapHeight && yScale > 0.0) { mMetrics.capHeight = os2->sCapHeight * yScale; } else { mMetrics.capHeight = mMetrics.maxAscent; } // Release the face lock to safely load glyphs with GetCharExtents if // necessary without recursively locking. UnlockFTFace(); gfxFloat width; mSpaceGlyph = GetCharExtents(' ', &width); if (mSpaceGlyph) { mMetrics.spaceWidth = width; } else { mMetrics.spaceWidth = mMetrics.maxAdvance; // guess } if (GetCharExtents('0', &width)) { mMetrics.zeroWidth = width; } else { mMetrics.zeroWidth = -1.0; // indicates not found } // Prefering a measured x over sxHeight because sxHeight doesn't consider // hinting, but maybe the x extents are not quite right in some fancy // script fonts. CSS 2.1 suggests possibly using the height of an "o", // which would have a more consistent glyph across fonts. gfxFloat xWidth; gfxRect xBounds; if (GetCharExtents('x', &xWidth, &xBounds) && xBounds.y < 0.0) { mMetrics.xHeight = -xBounds.y; mMetrics.aveCharWidth = std::max(mMetrics.aveCharWidth, xWidth); } if (GetCharExtents('H', nullptr, &xBounds) && xBounds.y < 0.0) { mMetrics.capHeight = -xBounds.y; } mMetrics.aveCharWidth = std::max(mMetrics.aveCharWidth, mMetrics.zeroWidth); if (mMetrics.aveCharWidth == 0.0) { mMetrics.aveCharWidth = mMetrics.spaceWidth; } // Apparently hinting can mean that max_advance is not always accurate. mMetrics.maxAdvance = std::max(mMetrics.maxAdvance, mMetrics.aveCharWidth); mMetrics.maxHeight = mMetrics.maxAscent + mMetrics.maxDescent; // Make the line height an integer number of pixels so that lines will be // equally spaced (rather than just being snapped to pixels, some up and // some down). Layout calculates line height from the emHeight + // internalLeading + externalLeading, but first each of these is rounded // to layout units. To ensure that the result is an integer number of // pixels, round each of the components to pixels. mMetrics.emHeight = floor(emHeight + 0.5); // maxHeight will normally be an integer, but round anyway in case // FreeType is configured differently. mMetrics.internalLeading = floor(mMetrics.maxHeight - mMetrics.emHeight + 0.5); // Text input boxes currently don't work well with lineHeight // significantly less than maxHeight (with Verdana, for example). lineHeight = floor(std::max(lineHeight, mMetrics.maxHeight) + 0.5); mMetrics.externalLeading = lineHeight - mMetrics.internalLeading - mMetrics.emHeight; // Ensure emAscent + emDescent == emHeight gfxFloat sum = mMetrics.emAscent + mMetrics.emDescent; mMetrics.emAscent = sum > 0.0 ? mMetrics.emAscent * mMetrics.emHeight / sum : 0.0; mMetrics.emDescent = mMetrics.emHeight - mMetrics.emAscent; SanitizeMetrics(&mMetrics, false); #if 0 // printf("font name: %s %f\n", NS_ConvertUTF16toUTF8(GetName()).get(), GetStyle()->size); // printf ("pango font %s\n", pango_font_description_to_string (pango_font_describe (font))); fprintf (stderr, "Font: %s\n", NS_ConvertUTF16toUTF8(GetName()).get()); fprintf (stderr, " emHeight: %f emAscent: %f emDescent: %f\n", mMetrics.emHeight, mMetrics.emAscent, mMetrics.emDescent); fprintf (stderr, " maxAscent: %f maxDescent: %f\n", mMetrics.maxAscent, mMetrics.maxDescent); fprintf (stderr, " internalLeading: %f externalLeading: %f\n", mMetrics.externalLeading, mMetrics.internalLeading); fprintf (stderr, " spaceWidth: %f aveCharWidth: %f xHeight: %f\n", mMetrics.spaceWidth, mMetrics.aveCharWidth, mMetrics.xHeight); fprintf (stderr, " uOff: %f uSize: %f stOff: %f stSize: %f\n", mMetrics.underlineOffset, mMetrics.underlineSize, mMetrics.strikeoutOffset, mMetrics.strikeoutSize); #endif } const gfxFont::Metrics& gfxFT2FontBase::GetHorizontalMetrics() { return mMetrics; } uint32_t gfxFT2FontBase::GetGlyph(uint32_t unicode, uint32_t variation_selector) { if (variation_selector) { uint32_t id = gfxFT2LockedFace(this).GetUVSGlyph(unicode, variation_selector); if (id) { return id; } unicode = gfxFontUtils::GetUVSFallback(unicode, variation_selector); if (unicode) { return GetGlyph(unicode); } return 0; } return GetGlyph(unicode); } bool gfxFT2FontBase::ShouldRoundXOffset(cairo_t* aCairo) const { // Force rounding if outputting to a Cairo context or if requested by pref to // disable subpixel positioning. Otherwise, allow subpixel positioning (no // rounding) if rendering a scalable outline font with anti-aliasing. // Monochrome rendering or some bitmap fonts can become too distorted with // subpixel positioning, so force rounding in those cases. Also be careful not // to use subpixel positioning if the user requests full hinting via // Fontconfig, which we detect by checking that neither hinting was disabled // nor light hinting was requested. Allow pref to force subpixel positioning // on even if full hinting was requested. return MOZ_UNLIKELY( StaticPrefs:: gfx_text_subpixel_position_force_disabled_AtStartup()) || aCairo != nullptr || !mFTFace || !FT_IS_SCALABLE(mFTFace->GetFace()) || (mFTLoadFlags & FT_LOAD_MONOCHROME) || !((mFTLoadFlags & FT_LOAD_NO_HINTING) || FT_LOAD_TARGET_MODE(mFTLoadFlags) == FT_RENDER_MODE_LIGHT || MOZ_UNLIKELY( StaticPrefs:: gfx_text_subpixel_position_force_enabled_AtStartup())); } FT_Vector gfxFT2FontBase::GetEmboldenStrength(FT_Face aFace) { FT_Vector strength = {0, 0}; if (!mEmbolden) { return strength; } // If it's an outline glyph, we'll be using mozilla_glyphslot_embolden_less // (see gfx/wr/webrender/src/platform/unix/font.rs), so we need to match its // emboldening strength here. if (aFace->glyph->format == FT_GLYPH_FORMAT_OUTLINE) { strength.x = FT_MulFix(aFace->units_per_EM, aFace->size->metrics.y_scale) / 48; strength.y = strength.x; return strength; } // This is the embolden "strength" used by FT_GlyphSlot_Embolden. strength.x = FT_MulFix(aFace->units_per_EM, aFace->size->metrics.y_scale) / 24; strength.y = strength.x; if (aFace->glyph->format == FT_GLYPH_FORMAT_BITMAP) { strength.x &= -64; if (!strength.x) { strength.x = 64; } strength.y &= -64; } return strength; } bool gfxFT2FontBase::GetFTGlyphExtents(uint16_t aGID, int32_t* aAdvance, IntRect* aBounds) { gfxFT2LockedFace face(this); MOZ_ASSERT(face.get()); if (!face.get()) { // Failed to get the FT_Face? Give up already. NS_WARNING("failed to get FT_Face!"); return false; } FT_Int32 flags = mFTLoadFlags; if (!aBounds) { flags |= FT_LOAD_ADVANCE_ONLY; } if (Factory::LoadFTGlyph(face.get(), aGID, flags) != FT_Err_Ok) { // FT_Face was somehow broken/invalid? Don't try to access glyph slot. // This probably shouldn't happen, but does: see bug 1440938. NS_WARNING("failed to load glyph!"); return false; } bool hintMetrics = ShouldHintMetrics(); // Normalize out the loaded FT glyph size and then scale to the actually // desired size, in case these two sizes differ. gfxFloat extentsScale = GetAdjustedSize() / mFTSize; FT_Vector bold = GetEmboldenStrength(face.get()); // Due to freetype bug 52683 we MUST use the linearHoriAdvance field when // dealing with a variation font; also use it for scalable fonts when not // applying hinting. Otherwise, prefer hinted width from glyph->advance.x. if (aAdvance) { FT_Fixed advance; if (!ShouldRoundXOffset(nullptr) || FT_HAS_MULTIPLE_MASTERS(face.get())) { advance = face.get()->glyph->linearHoriAdvance; } else { advance = face.get()->glyph->advance.x << 10; // convert 26.6 to 16.16 } if (advance) { advance += bold.x << 10; // convert 26.6 to 16.16 } // Hinting was requested, but FT did not apply any hinting to the metrics. // Round the advance here to approximate hinting as Cairo does. This must // happen BEFORE we apply the glyph extents scale, just like FT hinting // would. if (hintMetrics && (mFTLoadFlags & FT_LOAD_NO_HINTING)) { advance = (advance + 0x8000) & 0xffff0000u; } *aAdvance = NS_lround(advance * extentsScale); } if (aBounds) { const FT_Glyph_Metrics& metrics = face.get()->glyph->metrics; FT_F26Dot6 x = metrics.horiBearingX; FT_F26Dot6 y = -metrics.horiBearingY; FT_F26Dot6 x2 = x + metrics.width; FT_F26Dot6 y2 = y + metrics.height; // Synthetic bold moves the glyph top and right boundaries. y -= bold.y; x2 += bold.x; if (hintMetrics && (mFTLoadFlags & FT_LOAD_NO_HINTING)) { x &= -64; y &= -64; x2 = (x2 + 63) & -64; y2 = (y2 + 63) & -64; } *aBounds = IntRect(x, y, x2 - x, y2 - y); } return true; } /** * Get the cached glyph metrics for the glyph id if available. Otherwise, query * FreeType for the glyph extents and initialize the glyph metrics. */ const gfxFT2FontBase::GlyphMetrics& gfxFT2FontBase::GetCachedGlyphMetrics( uint16_t aGID, IntRect* aBounds) { if (!mGlyphMetrics) { mGlyphMetrics = mozilla::MakeUnique>( 128); } if (const GlyphMetrics* metrics = mGlyphMetrics->GetValue(aGID)) { return *metrics; } GlyphMetrics& metrics = mGlyphMetrics->GetOrInsert(aGID); IntRect bounds; if (GetFTGlyphExtents(aGID, &metrics.mAdvance, &bounds)) { metrics.SetBounds(bounds); if (aBounds) { *aBounds = bounds; } } return metrics; } int32_t gfxFT2FontBase::GetGlyphWidth(uint16_t aGID) { return GetCachedGlyphMetrics(aGID).mAdvance; } bool gfxFT2FontBase::GetGlyphBounds(uint16_t aGID, gfxRect* aBounds, bool aTight) { IntRect bounds; const GlyphMetrics& metrics = GetCachedGlyphMetrics(aGID, &bounds); if (!metrics.HasValidBounds()) { return false; } // Check if there are cached bounds and use those if available. Otherwise, // fall back to directly querying the glyph extents. if (metrics.HasCachedBounds()) { bounds = metrics.GetBounds(); } else if (bounds.IsEmpty() && !GetFTGlyphExtents(aGID, nullptr, &bounds)) { return false; } // The bounds are stored unscaled, so must be scaled to the adjusted size. *aBounds = ScaleGlyphBounds(bounds, GetAdjustedSize() / mFTSize); return true; } // For variation fonts, figure out the variation coordinates to be applied // for each axis, in freetype's order (which may not match the order of // axes in mStyle.variationSettings, so we need to search by axis tag). /*static*/ void gfxFT2FontBase::SetupVarCoords( FT_MM_Var* aMMVar, const nsTArray& aVariations, FT_Face aFTFace) { if (!aMMVar) { return; } nsTArray coords; for (unsigned i = 0; i < aMMVar->num_axis; ++i) { coords.AppendElement(aMMVar->axis[i].def); for (const auto& v : aVariations) { if (aMMVar->axis[i].tag == v.mTag) { FT_Fixed val = v.mValue * 0x10000; val = std::min(val, aMMVar->axis[i].maximum); val = std::max(val, aMMVar->axis[i].minimum); coords[i] = val; break; } } } if (!coords.IsEmpty()) { #if MOZ_TREE_FREETYPE FT_Set_Var_Design_Coordinates(aFTFace, coords.Length(), coords.Elements()); #else typedef FT_Error (*SetCoordsFunc)(FT_Face, FT_UInt, FT_Fixed*); static SetCoordsFunc setCoords; static bool firstTime = true; if (firstTime) { firstTime = false; setCoords = (SetCoordsFunc)dlsym(RTLD_DEFAULT, "FT_Set_Var_Design_Coordinates"); } if (setCoords) { (*setCoords)(aFTFace, coords.Length(), coords.Elements()); } #endif } } already_AddRefed FTUserFontData::CloneFace(int aFaceIndex) { RefPtr face = Factory::NewSharedFTFaceFromData( nullptr, mFontData, mLength, aFaceIndex, this); if (!face || (FT_Select_Charmap(face->GetFace(), FT_ENCODING_UNICODE) != FT_Err_Ok && FT_Select_Charmap(face->GetFace(), FT_ENCODING_MS_SYMBOL) != FT_Err_Ok)) { return nullptr; } return face.forget(); }