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/*
* Copyright (C) 2005, 2008, 2010, 2015 Apple Inc. All rights reserved.
* Copyright (C) 2006 Alexey Proskuryakov
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
*
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* 3. Neither the name of Apple Inc. ("Apple") nor the names of
* its contributors may be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY APPLE AND ITS CONTRIBUTORS "AS IS" AND ANY
* EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL APPLE OR ITS CONTRIBUTORS BE LIABLE FOR ANY
* DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
* THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include "config.h"
#include "Font.h"
#if PLATFORM(COCOA)
#include <pal/spi/cocoa/CoreTextSPI.h>
#endif
#include "CharacterProperties.h"
#include "FontCache.h"
#include "FontCascade.h"
#include "OpenTypeMathData.h"
#include <wtf/MathExtras.h>
#include <wtf/NeverDestroyed.h>
#include <wtf/text/AtomStringHash.h>
#if ENABLE(OPENTYPE_VERTICAL)
#include "OpenTypeVerticalData.h"
#endif
namespace WebCore {
unsigned GlyphPage::s_count = 0;
const float smallCapsFontSizeMultiplier = 0.7f;
const float emphasisMarkFontSizeMultiplier = 0.5f;
Font::Font(const FontPlatformData& platformData, Origin origin, Interstitial interstitial, Visibility visibility, OrientationFallback orientationFallback)
: m_platformData(platformData)
, m_origin(origin)
, m_visibility(visibility)
, m_treatAsFixedPitch(false)
, m_isInterstitial(interstitial == Interstitial::Yes)
, m_isTextOrientationFallback(orientationFallback == OrientationFallback::Yes)
, m_isBrokenIdeographFallback(false)
, m_hasVerticalGlyphs(false)
, m_isUsedInSystemFallbackCache(false)
#if PLATFORM(IOS_FAMILY)
, m_shouldNotBeUsedForArabic(false)
#endif
{
platformInit();
platformGlyphInit();
platformCharWidthInit();
#if ENABLE(OPENTYPE_VERTICAL)
if (platformData.orientation() == FontOrientation::Vertical && orientationFallback == OrientationFallback::No) {
m_verticalData = FontCache::singleton().verticalData(platformData);
m_hasVerticalGlyphs = m_verticalData.get() && m_verticalData->hasVerticalMetrics();
}
#endif
}
// Estimates of avgCharWidth and maxCharWidth for platforms that don't support accessing these values from the font.
void Font::initCharWidths()
{
auto* glyphPageZero = glyphPage(GlyphPage::pageNumberForCodePoint('0'));
// Treat the width of a '0' as the avgCharWidth.
if (m_avgCharWidth <= 0.f && glyphPageZero) {
Glyph digitZeroGlyph = glyphPageZero->glyphDataForCharacter('0').glyph;
if (digitZeroGlyph)
m_avgCharWidth = widthForGlyph(digitZeroGlyph);
}
// If we can't retrieve the width of a '0', fall back to the x height.
if (m_avgCharWidth <= 0.f)
m_avgCharWidth = m_fontMetrics.xHeight();
if (m_maxCharWidth <= 0.f)
m_maxCharWidth = std::max(m_avgCharWidth, m_fontMetrics.floatAscent());
}
void Font::platformGlyphInit()
{
#if USE(FREETYPE)
auto* glyphPageZeroWidthSpace = glyphPage(GlyphPage::pageNumberForCodePoint(zeroWidthSpace));
UChar32 zeroWidthSpaceCharacter = zeroWidthSpace;
#else
// Ask for the glyph for 0 to avoid paging in ZERO WIDTH SPACE. Control characters, including 0,
// are mapped to the ZERO WIDTH SPACE glyph for non FreeType based ports.
auto* glyphPageZeroWidthSpace = glyphPage(0);
UChar32 zeroWidthSpaceCharacter = 0;
#endif
auto* glyphPageCharacterZero = glyphPage(GlyphPage::pageNumberForCodePoint('0'));
auto* glyphPageSpace = glyphPage(GlyphPage::pageNumberForCodePoint(space));
if (glyphPageZeroWidthSpace)
m_zeroWidthSpaceGlyph = glyphPageZeroWidthSpace->glyphDataForCharacter(zeroWidthSpaceCharacter).glyph;
// Nasty hack to determine if we should round or ceil space widths.
// If the font is monospace or fake monospace we ceil to ensure that
// every character and the space are the same width. Otherwise we round.
if (glyphPageSpace)
m_spaceGlyph = glyphPageSpace->glyphDataForCharacter(space).glyph;
float width = widthForGlyph(m_spaceGlyph);
m_spaceWidth = width;
if (glyphPageCharacterZero)
m_zeroGlyph = glyphPageCharacterZero->glyphDataForCharacter('0').glyph;
m_fontMetrics.setZeroWidth(widthForGlyph(m_zeroGlyph));
determinePitch();
m_adjustedSpaceWidth = m_treatAsFixedPitch ? ceilf(width) : roundf(width);
// Force the glyph for ZERO WIDTH SPACE to have zero width, unless it is shared with SPACE.
// Helvetica is an example of a non-zero width ZERO WIDTH SPACE glyph.
// See <http://bugs.webkit.org/show_bug.cgi?id=13178> and Font::isZeroWidthSpaceGlyph()
if (m_zeroWidthSpaceGlyph == m_spaceGlyph)
m_zeroWidthSpaceGlyph = 0;
}
Font::~Font()
{
removeFromSystemFallbackCache();
}
static bool fillGlyphPage(GlyphPage& pageToFill, UChar* buffer, unsigned bufferLength, const Font& font)
{
bool hasGlyphs = pageToFill.fill(buffer, bufferLength);
#if ENABLE(OPENTYPE_VERTICAL)
if (hasGlyphs && font.verticalData())
font.verticalData()->substituteWithVerticalGlyphs(&font, &pageToFill);
#else
UNUSED_PARAM(font);
#endif
return hasGlyphs;
}
static Optional<size_t> codePointSupportIndex(UChar32 codePoint)
{
// FIXME: Consider reordering these so the most common ones are at the front.
// Doing this could cause the BitVector to fit inside inline storage and therefore
// be both a performance and a memory progression.
if (codePoint < 0x20)
return codePoint;
if (codePoint >= 0x7F && codePoint < 0xA0)
return codePoint - 0x7F + 0x20;
Optional<size_t> result;
switch (codePoint) {
case softHyphen:
result = 0x41;
break;
case newlineCharacter:
result = 0x42;
break;
case tabCharacter:
result = 0x43;
break;
case noBreakSpace:
result = 0x44;
break;
case narrowNoBreakSpace:
result = 0x45;
break;
case leftToRightMark:
result = 0x46;
break;
case rightToLeftMark:
result = 0x47;
break;
case leftToRightEmbed:
result = 0x48;
break;
case rightToLeftEmbed:
result = 0x49;
break;
case leftToRightOverride:
result = 0x4A;
break;
case rightToLeftOverride:
result = 0x4B;
break;
case leftToRightIsolate:
result = 0x4C;
break;
case rightToLeftIsolate:
result = 0x4D;
break;
case zeroWidthNonJoiner:
result = 0x4E;
break;
case zeroWidthJoiner:
result = 0x4F;
break;
case popDirectionalFormatting:
result = 0x50;
break;
case popDirectionalIsolate:
result = 0x51;
break;
case firstStrongIsolate:
result = 0x52;
break;
case objectReplacementCharacter:
result = 0x53;
break;
case zeroWidthNoBreakSpace:
result = 0x54;
break;
default:
result = WTF::nullopt;
}
#ifndef NDEBUG
UChar32 codePointOrder[] = {
0x00, 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07, 0x08, 0x09, 0x0A, 0x0B, 0x0C, 0x0D, 0x0E, 0x0F,
0x10, 0x11, 0x12, 0x13, 0x14, 0x15, 0x16, 0x17, 0x18, 0x19, 0x1A, 0x1B, 0x1C, 0x1D, 0x1E, 0x1F,
0x7F,
0x80, 0x81, 0x82, 0x83, 0x84, 0x85, 0x86, 0x87, 0x88, 0x89, 0x8A, 0x8B, 0x8C, 0x8D, 0x8E, 0x8F,
0x90, 0x91, 0x92, 0x93, 0x94, 0x95, 0x96, 0x97, 0x98, 0x99, 0x9A, 0x9B, 0x9C, 0x9D, 0x9E, 0x9F,
softHyphen,
newlineCharacter,
tabCharacter,
noBreakSpace,
narrowNoBreakSpace,
leftToRightMark,
rightToLeftMark,
leftToRightEmbed,
rightToLeftEmbed,
leftToRightOverride,
rightToLeftOverride,
leftToRightIsolate,
rightToLeftIsolate,
zeroWidthNonJoiner,
zeroWidthJoiner,
popDirectionalFormatting,
popDirectionalIsolate,
firstStrongIsolate,
objectReplacementCharacter,
zeroWidthNoBreakSpace
};
bool found = false;
for (size_t i = 0; i < WTF_ARRAY_LENGTH(codePointOrder); ++i) {
if (codePointOrder[i] == codePoint) {
ASSERT(i == result);
found = true;
}
}
ASSERT(found == static_cast<bool>(result));
#endif
return result;
}
#if !USE(FREETYPE)
static void overrideControlCharacters(Vector<UChar>& buffer, unsigned start, unsigned end)
{
auto overwriteCodePoints = [&](unsigned minimum, unsigned maximum, UChar newCodePoint) {
unsigned begin = std::max(start, minimum);
unsigned complete = std::min(end, maximum);
for (unsigned i = begin; i < complete; ++i) {
ASSERT(codePointSupportIndex(i));
buffer[i - start] = newCodePoint;
}
};
auto overwriteCodePoint = [&](UChar codePoint, UChar newCodePoint) {
ASSERT(codePointSupportIndex(codePoint));
if (codePoint >= start && codePoint < end)
buffer[codePoint - start] = newCodePoint;
};
// Code points 0x0 - 0x20 and 0x7F - 0xA0 are control character and shouldn't render. Map them to ZERO WIDTH SPACE.
overwriteCodePoints(0x0, 0x20, zeroWidthSpace);
overwriteCodePoints(0x7F, 0xA0, zeroWidthSpace);
overwriteCodePoint(softHyphen, zeroWidthSpace);
overwriteCodePoint('\n', space);
overwriteCodePoint('\t', space);
overwriteCodePoint(noBreakSpace, space);
overwriteCodePoint(narrowNoBreakSpace, zeroWidthSpace);
overwriteCodePoint(leftToRightMark, zeroWidthSpace);
overwriteCodePoint(rightToLeftMark, zeroWidthSpace);
overwriteCodePoint(leftToRightEmbed, zeroWidthSpace);
overwriteCodePoint(rightToLeftEmbed, zeroWidthSpace);
overwriteCodePoint(leftToRightOverride, zeroWidthSpace);
overwriteCodePoint(rightToLeftOverride, zeroWidthSpace);
overwriteCodePoint(leftToRightIsolate, zeroWidthSpace);
overwriteCodePoint(rightToLeftIsolate, zeroWidthSpace);
overwriteCodePoint(zeroWidthNonJoiner, zeroWidthSpace);
overwriteCodePoint(zeroWidthJoiner, zeroWidthSpace);
overwriteCodePoint(popDirectionalFormatting, zeroWidthSpace);
overwriteCodePoint(popDirectionalIsolate, zeroWidthSpace);
overwriteCodePoint(firstStrongIsolate, zeroWidthSpace);
overwriteCodePoint(objectReplacementCharacter, zeroWidthSpace);
overwriteCodePoint(zeroWidthNoBreakSpace, zeroWidthSpace);
}
#endif
static RefPtr<GlyphPage> createAndFillGlyphPage(unsigned pageNumber, const Font& font)
{
#if PLATFORM(IOS_FAMILY)
// FIXME: Times New Roman contains Arabic glyphs, but Core Text doesn't know how to shape them. See <rdar://problem/9823975>.
// Once we have the fix for <rdar://problem/9823975> then remove this code together with Font::shouldNotBeUsedForArabic()
// in <rdar://problem/12096835>.
if (GlyphPage::pageNumberIsUsedForArabic(pageNumber) && font.shouldNotBeUsedForArabic())
return nullptr;
#endif
unsigned glyphPageSize = GlyphPage::sizeForPageNumber(pageNumber);
unsigned start = GlyphPage::startingCodePointInPageNumber(pageNumber);
Vector<UChar> buffer(glyphPageSize * 2 + 2);
unsigned bufferLength;
// Fill in a buffer with the entire "page" of characters that we want to look up glyphs for.
if (U_IS_BMP(start)) {
bufferLength = glyphPageSize;
for (unsigned i = 0; i < bufferLength; i++)
buffer[i] = start + i;
#if !USE(FREETYPE)
overrideControlCharacters(buffer, start, start + glyphPageSize);
#endif
} else {
bufferLength = glyphPageSize * 2;
for (unsigned i = 0; i < glyphPageSize; i++) {
int c = i + start;
buffer[i * 2] = U16_LEAD(c);
buffer[i * 2 + 1] = U16_TRAIL(c);
}
}
// Now that we have a buffer full of characters, we want to get back an array
// of glyph indices. This part involves calling into the platform-specific
// routine of our glyph map for actually filling in the page with the glyphs.
// Success is not guaranteed. For example, Times fails to fill page 260, giving glyph data
// for only 128 out of 256 characters.
Ref<GlyphPage> glyphPage = GlyphPage::create(font);
bool haveGlyphs = fillGlyphPage(glyphPage, buffer.data(), bufferLength, font);
if (!haveGlyphs)
return nullptr;
return glyphPage;
}
const GlyphPage* Font::glyphPage(unsigned pageNumber) const
{
if (!pageNumber) {
if (!m_glyphPageZero)
m_glyphPageZero = createAndFillGlyphPage(0, *this);
return m_glyphPageZero.get();
}
auto addResult = m_glyphPages.add(pageNumber, nullptr);
if (addResult.isNewEntry)
addResult.iterator->value = createAndFillGlyphPage(pageNumber, *this);
return addResult.iterator->value.get();
}
Glyph Font::glyphForCharacter(UChar32 character) const
{
auto* page = glyphPage(GlyphPage::pageNumberForCodePoint(character));
if (!page)
return 0;
return page->glyphForCharacter(character);
}
GlyphData Font::glyphDataForCharacter(UChar32 character) const
{
auto* page = glyphPage(GlyphPage::pageNumberForCodePoint(character));
if (!page)
return GlyphData();
return page->glyphDataForCharacter(character);
}
auto Font::ensureDerivedFontData() const -> DerivedFonts&
{
if (!m_derivedFontData)
m_derivedFontData = makeUnique<DerivedFonts>();
return *m_derivedFontData;
}
const Font& Font::verticalRightOrientationFont() const
{
DerivedFonts& derivedFontData = ensureDerivedFontData();
if (!derivedFontData.verticalRightOrientationFont) {
auto verticalRightPlatformData = FontPlatformData::cloneWithOrientation(m_platformData, FontOrientation::Horizontal);
derivedFontData.verticalRightOrientationFont = create(verticalRightPlatformData, origin(), Interstitial::No, Visibility::Visible, OrientationFallback::Yes);
}
ASSERT(derivedFontData.verticalRightOrientationFont != this);
return *derivedFontData.verticalRightOrientationFont;
}
const Font& Font::uprightOrientationFont() const
{
DerivedFonts& derivedFontData = ensureDerivedFontData();
if (!derivedFontData.uprightOrientationFont)
derivedFontData.uprightOrientationFont = create(m_platformData, origin(), Interstitial::No, Visibility::Visible, OrientationFallback::Yes);
ASSERT(derivedFontData.uprightOrientationFont != this);
return *derivedFontData.uprightOrientationFont;
}
const Font& Font::invisibleFont() const
{
DerivedFonts& derivedFontData = ensureDerivedFontData();
if (!derivedFontData.invisibleFont)
derivedFontData.invisibleFont = create(m_platformData, origin(), Interstitial::Yes, Visibility::Invisible);
ASSERT(derivedFontData.invisibleFont != this);
return *derivedFontData.invisibleFont;
}
const Font* Font::smallCapsFont(const FontDescription& fontDescription) const
{
DerivedFonts& derivedFontData = ensureDerivedFontData();
if (!derivedFontData.smallCapsFont)
derivedFontData.smallCapsFont = createScaledFont(fontDescription, smallCapsFontSizeMultiplier);
ASSERT(derivedFontData.smallCapsFont != this);
return derivedFontData.smallCapsFont.get();
}
const Font& Font::noSynthesizableFeaturesFont() const
{
#if PLATFORM(COCOA)
DerivedFonts& derivedFontData = ensureDerivedFontData();
if (!derivedFontData.noSynthesizableFeaturesFont)
derivedFontData.noSynthesizableFeaturesFont = createFontWithoutSynthesizableFeatures();
ASSERT(derivedFontData.noSynthesizableFeaturesFont != this);
return *derivedFontData.noSynthesizableFeaturesFont;
#else
return *this;
#endif
}
const Font* Font::emphasisMarkFont(const FontDescription& fontDescription) const
{
DerivedFonts& derivedFontData = ensureDerivedFontData();
if (!derivedFontData.emphasisMarkFont)
derivedFontData.emphasisMarkFont = createScaledFont(fontDescription, emphasisMarkFontSizeMultiplier);
ASSERT(derivedFontData.emphasisMarkFont != this);
return derivedFontData.emphasisMarkFont.get();
}
const Font& Font::brokenIdeographFont() const
{
DerivedFonts& derivedFontData = ensureDerivedFontData();
if (!derivedFontData.brokenIdeographFont) {
derivedFontData.brokenIdeographFont = create(m_platformData, origin(), Interstitial::No);
derivedFontData.brokenIdeographFont->m_isBrokenIdeographFallback = true;
}
ASSERT(derivedFontData.brokenIdeographFont != this);
return *derivedFontData.brokenIdeographFont;
}
#if !LOG_DISABLED
String Font::description() const
{
if (origin() == Origin::Remote)
return "[custom font]";
return platformData().description();
}
#endif
const OpenTypeMathData* Font::mathData() const
{
if (isInterstitial())
return nullptr;
if (!m_mathData) {
m_mathData = OpenTypeMathData::create(m_platformData);
if (!m_mathData->hasMathData())
m_mathData = nullptr;
}
return m_mathData.get();
}
RefPtr<Font> Font::createScaledFont(const FontDescription& fontDescription, float scaleFactor) const
{
return platformCreateScaledFont(fontDescription, scaleFactor);
}
bool Font::applyTransforms(GlyphBufferGlyph* glyphs, GlyphBufferAdvance* advances, size_t glyphCount, bool enableKerning, bool requiresShaping) const
{
#if PLATFORM(COCOA)
CTFontTransformOptions options = (enableKerning ? kCTFontTransformApplyPositioning : 0) | (requiresShaping ? kCTFontTransformApplyShaping : 0);
return CTFontTransformGlyphs(m_platformData.ctFont(), glyphs, reinterpret_cast<CGSize*>(advances), glyphCount, options);
#else
UNUSED_PARAM(glyphs);
UNUSED_PARAM(advances);
UNUSED_PARAM(glyphCount);
UNUSED_PARAM(enableKerning);
UNUSED_PARAM(requiresShaping);
return false;
#endif
}
class CharacterFallbackMapKey {
public:
CharacterFallbackMapKey()
{
}
CharacterFallbackMapKey(const AtomString& locale, UChar32 character, IsForPlatformFont isForPlatformFont)
: locale(locale)
, character(character)
, isForPlatformFont(isForPlatformFont == IsForPlatformFont::Yes)
{
}
CharacterFallbackMapKey(WTF::HashTableDeletedValueType)
: character(-1)
{
}
bool isHashTableDeletedValue() const { return character == -1; }
bool operator==(const CharacterFallbackMapKey& other) const
{
return locale == other.locale && character == other.character && isForPlatformFont == other.isForPlatformFont;
}
static const bool emptyValueIsZero = true;
private:
friend struct CharacterFallbackMapKeyHash;
AtomString locale;
UChar32 character { 0 };
bool isForPlatformFont { false };
};
struct CharacterFallbackMapKeyHash {
static unsigned hash(const CharacterFallbackMapKey& key)
{
IntegerHasher hasher;
hasher.add(key.character);
hasher.add(key.isForPlatformFont);
hasher.add(key.locale.existingHash());
return hasher.hash();
}
static bool equal(const CharacterFallbackMapKey& a, const CharacterFallbackMapKey& b)
{
return a == b;
}
static const bool safeToCompareToEmptyOrDeleted = true;
};
// Fonts are not ref'd to avoid cycles.
// FIXME: Shouldn't these be WeakPtrs?
typedef HashMap<CharacterFallbackMapKey, Font*, CharacterFallbackMapKeyHash, WTF::SimpleClassHashTraits<CharacterFallbackMapKey>> CharacterFallbackMap;
typedef HashMap<const Font*, CharacterFallbackMap> SystemFallbackCache;
static SystemFallbackCache& systemFallbackCache()
{
static NeverDestroyed<SystemFallbackCache> map;
return map.get();
}
RefPtr<Font> Font::systemFallbackFontForCharacter(UChar32 character, const FontDescription& description, IsForPlatformFont isForPlatformFont) const
{
auto fontAddResult = systemFallbackCache().add(this, CharacterFallbackMap());
if (!character) {
UChar codeUnit = 0;
return FontCache::singleton().systemFallbackForCharacters(description, this, isForPlatformFont, FontCache::PreferColoredFont::No, &codeUnit, 1);
}
auto key = CharacterFallbackMapKey(description.locale(), character, isForPlatformFont);
auto characterAddResult = fontAddResult.iterator->value.add(WTFMove(key), nullptr);
Font*& fallbackFont = characterAddResult.iterator->value;
if (!fallbackFont) {
UChar codeUnits[2];
unsigned codeUnitsLength;
if (U_IS_BMP(character)) {
codeUnits[0] = FontCascade::normalizeSpaces(character);
codeUnitsLength = 1;
} else {
codeUnits[0] = U16_LEAD(character);
codeUnits[1] = U16_TRAIL(character);
codeUnitsLength = 2;
}
fallbackFont = FontCache::singleton().systemFallbackForCharacters(description, this, isForPlatformFont, FontCache::PreferColoredFont::No, codeUnits, codeUnitsLength).get();
if (fallbackFont)
fallbackFont->m_isUsedInSystemFallbackCache = true;
}
return fallbackFont;
}
void Font::removeFromSystemFallbackCache()
{
systemFallbackCache().remove(this);
if (!m_isUsedInSystemFallbackCache)
return;
for (auto& characterMap : systemFallbackCache().values()) {
Vector<CharacterFallbackMapKey, 512> toRemove;
for (auto& entry : characterMap) {
if (entry.value == this)
toRemove.append(entry.key);
}
for (auto& key : toRemove)
characterMap.remove(key);
}
}
#if !PLATFORM(COCOA) && !USE(FREETYPE)
bool Font::variantCapsSupportsCharacterForSynthesis(FontVariantCaps fontVariantCaps, UChar32) const
{
switch (fontVariantCaps) {
case FontVariantCaps::Small:
case FontVariantCaps::Petite:
case FontVariantCaps::AllSmall:
case FontVariantCaps::AllPetite:
return false;
default:
// Synthesis only supports the variant-caps values listed above.
return true;
}
}
bool Font::platformSupportsCodePoint(UChar32 character, Optional<UChar32> variation) const
{
return variation ? false : glyphForCharacter(character);
}
#endif
bool Font::supportsCodePoint(UChar32 character) const
{
// This is very similar to static_cast<bool>(glyphForCharacter(character))
// except that glyphForCharacter() maps certain code points to ZWS (because they
// shouldn't be visible). This function doesn't do that mapping, and instead is
// as honest as possible about what code points the font supports. This is so
// that we can accurately determine which characters are supported by this font
// so we know which boundaries to break strings when we send them to the complex
// text codepath. The complex text codepath is totally separate from this ZWS
// replacement logic (because CoreText handles those characters instead of WebKit).
if (auto index = codePointSupportIndex(character)) {
m_codePointSupport.ensureSize(2 * (*index + 1));
bool hasBeenSet = m_codePointSupport.quickSet(2 * *index);
if (!hasBeenSet && platformSupportsCodePoint(character))
m_codePointSupport.quickSet(2 * *index + 1);
return m_codePointSupport.quickGet(2 * *index + 1);
}
return glyphForCharacter(character);
}
bool Font::canRenderCombiningCharacterSequence(const UChar* characters, size_t length) const
{
ASSERT(isMainThread());
auto codePoints = StringView(characters, length).codePoints();
auto it = codePoints.begin();
auto end = codePoints.end();
while (it != end) {
auto codePoint = *it;
++it;
if (it != end && isVariationSelector(*it)) {
if (!platformSupportsCodePoint(codePoint, *it)) {
// Try the characters individually.
if (!supportsCodePoint(codePoint) || !supportsCodePoint(*it))
return false;
}
++it;
continue;
}
if (!supportsCodePoint(codePoint))
return false;
}
return true;
}
// Don't store the result of this! The hash map is free to rehash at any point, leaving this reference dangling.
const Path& Font::pathForGlyph(Glyph glyph) const
{
if (const auto& path = m_glyphPathMap.existingMetricsForGlyph(glyph))
return *path;
auto path = platformPathForGlyph(glyph);
m_glyphPathMap.setMetricsForGlyph(glyph, path);
return *m_glyphPathMap.existingMetricsForGlyph(glyph);
}
} // namespace WebCore