// Copyright 2014 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include "ui/gfx/render_text_harfbuzz.h" #include #include #include "base/command_line.h" #include "base/containers/mru_cache.h" #include "base/feature_list.h" #include "base/hash.h" #include "base/i18n/base_i18n_switches.h" #include "base/i18n/bidi_line_iterator.h" #include "base/i18n/break_iterator.h" #include "base/i18n/char_iterator.h" #include "base/macros.h" #include "base/memory/ptr_util.h" #include "base/message_loop/message_loop_current.h" #include "base/no_destructor.h" #include "base/strings/string_number_conversions.h" #include "base/strings/string_util.h" #include "base/strings/utf_string_conversions.h" #include "base/trace_event/trace_event.h" #include "build/build_config.h" #include "third_party/icu/source/common/unicode/ubidi.h" #include "third_party/icu/source/common/unicode/utf16.h" #include "third_party/skia/include/core/SkColor.h" #include "third_party/skia/include/core/SkTypeface.h" #include "ui/gfx/canvas.h" #include "ui/gfx/decorated_text.h" #include "ui/gfx/font.h" #include "ui/gfx/font_fallback.h" #include "ui/gfx/font_render_params.h" #include "ui/gfx/geometry/safe_integer_conversions.h" #include "ui/gfx/harfbuzz_font_skia.h" #include "ui/gfx/range/range_f.h" #include "ui/gfx/skia_util.h" #include "ui/gfx/switches.h" #include "ui/gfx/text_utils.h" #include "ui/gfx/utf16_indexing.h" #if defined(OS_MACOSX) #include "base/mac/mac_util.h" #endif #include namespace gfx { namespace { // Text length limit. Longer strings are slow and not fully tested. const size_t kMaxTextLength = 10000; // The maximum number of scripts a Unicode character can belong to. This value // is arbitrarily chosen to be a good limit because it is unlikely for a single // character to belong to more scripts. const size_t kMaxScripts = 5; // Returns true if characters of |block_code| may trigger font fallback. bool IsUnusualBlockCode(UBlockCode block_code) { return block_code == UBLOCK_GEOMETRIC_SHAPES || block_code == UBLOCK_MISCELLANEOUS_SYMBOLS; } // Returns true if |character| is a bracket. This is used to avoid "matching" // brackets picking different font fallbacks, thereby appearing mismatched. bool IsBracket(UChar32 character) { // 0x300c and 0x300d are「foo」 style brackets. constexpr UChar32 kBrackets[] = {'(', ')', '{', '}', '<', '>', L'\u300c', L'\u300d'}; return base::ContainsValue(kBrackets, character); } // If the given scripts match, returns the one that isn't USCRIPT_INHERITED, // i.e. the more specific one. Otherwise returns USCRIPT_INVALID_CODE. This // function is used to split runs between characters of different script codes, // unless either character has USCRIPT_INHERITED property. See crbug.com/448909. UScriptCode ScriptIntersect(UScriptCode first, UScriptCode second) { if (first == second || second == USCRIPT_INHERITED) return first; if (first == USCRIPT_INHERITED) return second; return USCRIPT_INVALID_CODE; } // Writes the script and the script extensions of the character with the // Unicode |codepoint|. Returns the number of written scripts. int GetScriptExtensions(UChar32 codepoint, UScriptCode* scripts) { UErrorCode icu_error = U_ZERO_ERROR; // ICU documentation incorrectly states that the result of // |uscript_getScriptExtensions| will contain the regular script property. // Write the character's script property to the first element. scripts[0] = uscript_getScript(codepoint, &icu_error); if (U_FAILURE(icu_error)) return 0; // Fill the rest of |scripts| with the extensions. int count = uscript_getScriptExtensions(codepoint, scripts + 1, kMaxScripts - 1, &icu_error); if (U_FAILURE(icu_error)) count = 0; return count + 1; } // Intersects the script extensions set of |codepoint| with |result| and writes // to |result|, reading and updating |result_size|. void ScriptSetIntersect(UChar32 codepoint, UScriptCode* result, size_t* result_size) { UScriptCode scripts[kMaxScripts] = { USCRIPT_INVALID_CODE }; int count = GetScriptExtensions(codepoint, scripts); size_t out_size = 0; for (size_t i = 0; i < *result_size; ++i) { for (int j = 0; j < count; ++j) { UScriptCode intersection = ScriptIntersect(result[i], scripts[j]); if (intersection != USCRIPT_INVALID_CODE) { result[out_size++] = intersection; break; } } } *result_size = out_size; } // Returns true if |first_char| and |current_char| both have "COMMON" script // property but only one of them is an ASCII character. By doing this ASCII // characters will be put into a separate run and be rendered using its default // font. See crbug.com/530021 and crbug.com/533721 for more details. bool AsciiBreak(UChar32 first_char, UChar32 current_char) { if (isascii(first_char) == isascii(current_char)) return false; size_t scripts_size = 1; UScriptCode scripts[kMaxScripts] = { USCRIPT_COMMON }; ScriptSetIntersect(first_char, scripts, &scripts_size); if (scripts_size == 0) return false; ScriptSetIntersect(current_char, scripts, &scripts_size); return scripts_size != 0; } // When a string of "unusual" characters ends, the run usually breaks. However, // variation selectors should still attach to the run of unusual characters. // Detect this situation so that FindRunBreakingCharacter() can continue // tracking the unusual block. Otherwise, just returns |current|. UBlockCode MaybeCombineUnusualBlock(UBlockCode preceding, UBlockCode current) { return IsUnusualBlockCode(preceding) && current == UBLOCK_VARIATION_SELECTORS ? preceding : current; } // Returns the boundary between a special and a regular character. Special // characters are brackets or characters that satisfy |IsUnusualBlockCode|. size_t FindRunBreakingCharacter(const base::string16& text, size_t run_start, size_t run_break) { const int32_t run_length = static_cast(run_break - run_start); base::i18n::UTF16CharIterator iter(text.c_str() + run_start, run_length); const UChar32 first_char = iter.get(); // The newline character should form a single run so that the line breaker // can handle them easily. if (first_char == '\n') return run_start + 1; const UBlockCode first_block = ublock_getCode(first_char); const bool first_block_unusual = IsUnusualBlockCode(first_block); const bool first_bracket = IsBracket(first_char); while (iter.Advance() && iter.array_pos() < run_length) { const UChar32 current_char = iter.get(); const UBlockCode current_block = MaybeCombineUnusualBlock(first_block, ublock_getCode(current_char)); const bool block_break = current_block != first_block && (first_block_unusual || IsUnusualBlockCode(current_block)); if (block_break || current_char == '\n' || first_bracket != IsBracket(current_char) || AsciiBreak(first_char, current_char)) { return run_start + iter.array_pos(); } } return run_break; } // Find the longest sequence of characters from 0 and up to |length| that have // at least one common UScriptCode value. Writes the common script value to // |script| and returns the length of the sequence. Takes the characters' script // extensions into account. http://www.unicode.org/reports/tr24/#ScriptX // // Consider 3 characters with the script values {Kana}, {Hira, Kana}, {Kana}. // Without script extensions only the first script in each set would be taken // into account, resulting in 3 runs where 1 would be enough. int ScriptInterval(const base::string16& text, size_t start, size_t length, UScriptCode* script) { DCHECK_GT(length, 0U); UScriptCode scripts[kMaxScripts] = { USCRIPT_INVALID_CODE }; base::i18n::UTF16CharIterator char_iterator(text.c_str() + start, length); size_t scripts_size = GetScriptExtensions(char_iterator.get(), scripts); *script = scripts[0]; while (char_iterator.Advance()) { ScriptSetIntersect(char_iterator.get(), scripts, &scripts_size); if (scripts_size == 0U) return char_iterator.array_pos(); *script = scripts[0]; } return length; } // A port of hb_icu_script_to_script because harfbuzz on CrOS is built without // hb-icu. See http://crbug.com/356929 inline hb_script_t ICUScriptToHBScript(UScriptCode script) { if (script == USCRIPT_INVALID_CODE) return HB_SCRIPT_INVALID; return hb_script_from_string(uscript_getShortName(script), -1); } // Whether |segment| corresponds to the newline character. bool IsNewlineSegment(const base::string16& text, const internal::LineSegment& segment) { return text[segment.char_range.start()] == '\n'; } // Helper template function for |TextRunHarfBuzz::GetClusterAt()|. |Iterator| // can be a forward or reverse iterator type depending on the text direction. // Returns true on success, or false if an error is encountered. template bool GetClusterAtImpl(size_t pos, Range range, Iterator elements_begin, Iterator elements_end, bool reversed, Range* chars, Range* glyphs) { Iterator element = std::upper_bound(elements_begin, elements_end, pos); if (element == elements_begin) { *chars = range; *glyphs = Range(); return false; } chars->set_end(element == elements_end ? range.end() : *element); glyphs->set_end(reversed ? elements_end - element : element - elements_begin); while (--element != elements_begin && *element == *(element - 1)); chars->set_start(*element); glyphs->set_start( reversed ? elements_end - element : element - elements_begin); if (reversed) *glyphs = Range(glyphs->end(), glyphs->start()); DCHECK(!chars->is_reversed()); DCHECK(!chars->is_empty()); DCHECK(!glyphs->is_reversed()); DCHECK(!glyphs->is_empty()); return true; } // Returns the line segment index for the |line|, |text_x| pair. |text_x| is // relative to text in the given line. Returns -1 if |text_x| is to the left // of text in the line and |line|.segments.size() if it's to the right. // |offset_relative_segment| will contain the offset of |text_x| relative to // the start of the segment it is contained in. int GetLineSegmentContainingXCoord(const internal::Line& line, float line_x, float* offset_relative_segment) { DCHECK(offset_relative_segment); *offset_relative_segment = 0; if (line_x < 0) return -1; for (size_t i = 0; i < line.segments.size(); i++) { const internal::LineSegment& segment = line.segments[i]; // segment.x_range is not used because it is in text space. if (line_x < segment.width()) { *offset_relative_segment = line_x; return i; } line_x -= segment.width(); } return line.segments.size(); } // Internal class to generate Line structures. If |multiline| is true, the text // is broken into lines at |words| boundaries such that each line is no longer // than |max_width|. If |multiline| is false, only outputs a single Line from // the given runs. |min_baseline| and |min_height| are the minimum baseline and // height for each line. // TODO(ckocagil): Expose the interface of this class in the header and test // this class directly. class HarfBuzzLineBreaker { public: HarfBuzzLineBreaker(size_t max_width, int min_baseline, float min_height, WordWrapBehavior word_wrap_behavior, const base::string16& text, const BreakList* words, const internal::TextRunList& run_list) : max_width_((max_width == 0) ? SK_ScalarMax : SkIntToScalar(max_width)), min_baseline_(min_baseline), min_height_(min_height), word_wrap_behavior_(word_wrap_behavior), text_(text), words_(words), run_list_(run_list), max_descent_(0), max_ascent_(0), text_x_(0), available_width_(max_width_) { AdvanceLine(); } // Constructs a single line for |text_| using |run_list_|. void ConstructSingleLine() { for (size_t i = 0; i < run_list_.size(); i++) { const internal::TextRunHarfBuzz& run = *(run_list_.runs()[i]); internal::LineSegment segment; segment.run = i; segment.char_range = run.range; segment.x_range = RangeF(SkScalarToFloat(text_x_), SkScalarToFloat(text_x_) + run.shape.width); AddLineSegment(segment); } } // Constructs multiple lines for |text_| based on words iteration approach. void ConstructMultiLines() { DCHECK(words_); for (auto iter = words_->breaks().begin(); iter != words_->breaks().end(); iter++) { const Range word_range = words_->GetRange(iter); std::vector word_segments; SkScalar word_width = GetWordWidth(word_range, &word_segments); // If the last word is '\n', we should advance a new line after adding // the word to the current line. bool new_line = false; if (!word_segments.empty() && IsNewlineSegment(text_, word_segments.back())) { new_line = true; // Since the line should at least contain some information regarding the // text range it corresponds to, don't pop the newline segment, if it's // the only segment in the line. This ensures that every line has a non- // empty segments vector (except the last in some cases). This segment // won't be drawn though. if (word_segments.size() != 1u || available_width_ != max_width_) { word_width -= word_segments.back().width(); word_segments.pop_back(); } } // If the word is not the first word in the line and it can't fit into // the current line, advance a new line. if (word_width > available_width_ && available_width_ != max_width_) AdvanceLine(); if (!word_segments.empty()) AddWordToLine(word_segments); if (new_line) AdvanceLine(); } } // Finishes line breaking and outputs the results. Can be called at most once. void FinalizeLines(std::vector* lines, SizeF* size) { DCHECK(!lines_.empty()); // Add an empty line to finish the line size calculation and remove it. AdvanceLine(); lines_.pop_back(); *size = total_size_; lines->swap(lines_); } private: // A (line index, segment index) pair that specifies a segment in |lines_|. typedef std::pair SegmentHandle; internal::LineSegment* SegmentFromHandle(const SegmentHandle& handle) { return &lines_[handle.first].segments[handle.second]; } // Finishes the size calculations of the last Line in |lines_|. Adds a new // Line to the back of |lines_|. void AdvanceLine() { if (!lines_.empty()) { internal::Line* line = &lines_.back(); std::sort(line->segments.begin(), line->segments.end(), [this](const internal::LineSegment& s1, const internal::LineSegment& s2) -> bool { return run_list_.logical_to_visual(s1.run) < run_list_.logical_to_visual(s2.run); }); line->size.set_height(std::max(min_height_, max_descent_ + max_ascent_)); line->baseline = std::max(min_baseline_, SkScalarRoundToInt(max_ascent_)); line->preceding_heights = std::ceil(total_size_.height()); total_size_.set_height(total_size_.height() + line->size.height()); total_size_.set_width(std::max(total_size_.width(), line->size.width())); } max_descent_ = 0; max_ascent_ = 0; available_width_ = max_width_; lines_.push_back(internal::Line()); } // Adds word to the current line. A word may contain multiple segments. If the // word is the first word in line and its width exceeds |available_width_|, // ignore/truncate/wrap it according to |word_wrap_behavior_|. void AddWordToLine(const std::vector& word_segments) { DCHECK(!lines_.empty()); DCHECK(!word_segments.empty()); bool has_truncated = false; for (const internal::LineSegment& segment : word_segments) { if (has_truncated) break; if (segment.width() <= available_width_ || word_wrap_behavior_ == IGNORE_LONG_WORDS) { AddLineSegment(segment); } else { DCHECK(word_wrap_behavior_ == TRUNCATE_LONG_WORDS || word_wrap_behavior_ == WRAP_LONG_WORDS); has_truncated = (word_wrap_behavior_ == TRUNCATE_LONG_WORDS); const internal::TextRunHarfBuzz& run = *(run_list_.runs()[segment.run]); internal::LineSegment remaining_segment = segment; while (!remaining_segment.char_range.is_empty()) { size_t cutoff_pos = GetCutoffPos(remaining_segment); SkScalar width = run.GetGlyphWidthForCharRange( Range(remaining_segment.char_range.start(), cutoff_pos)); if (width > 0) { internal::LineSegment cut_segment; cut_segment.run = remaining_segment.run; cut_segment.char_range = Range(remaining_segment.char_range.start(), cutoff_pos); cut_segment.x_range = RangeF(SkScalarToFloat(text_x_), SkScalarToFloat(text_x_ + width)); AddLineSegment(cut_segment); // Updates old segment range. remaining_segment.char_range.set_start(cutoff_pos); remaining_segment.x_range.set_start(SkScalarToFloat(text_x_)); } if (has_truncated) break; if (!remaining_segment.char_range.is_empty()) AdvanceLine(); } } } } // Add a line segment to the current line. Note that, in order to keep the // visual order correct for ltr and rtl language, we need to merge segments // that belong to the same run. void AddLineSegment(const internal::LineSegment& segment) { DCHECK(!lines_.empty()); internal::Line* line = &lines_.back(); const internal::TextRunHarfBuzz& run = *(run_list_.runs()[segment.run]); if (!line->segments.empty()) { internal::LineSegment& last_segment = line->segments.back(); // Merge segments that belong to the same run. if (last_segment.run == segment.run) { DCHECK_EQ(last_segment.char_range.end(), segment.char_range.start()); // Check there is less than a pixel between one run and the next. DCHECK_LE( std::abs(last_segment.x_range.end() - segment.x_range.start()), 1.0f); last_segment.char_range.set_end(segment.char_range.end()); last_segment.x_range.set_end(SkScalarToFloat(text_x_) + segment.width()); if (run.font_params.is_rtl && last_segment.char_range.end() == run.range.end()) UpdateRTLSegmentRanges(); line->size.set_width(line->size.width() + segment.width()); text_x_ += segment.width(); available_width_ -= segment.width(); return; } } line->segments.push_back(segment); line->size.set_width(line->size.width() + segment.width()); SkPaint paint; paint.setTypeface(run.font_params.skia_face); paint.setTextSize(SkIntToScalar(run.font_params.font_size)); paint.setAntiAlias(run.font_params.render_params.antialiasing); SkPaint::FontMetrics metrics; paint.getFontMetrics(&metrics); // max_descent_ is y-down, fDescent is y-down, baseline_offset is y-down max_descent_ = std::max(max_descent_, metrics.fDescent + run.font_params.baseline_offset); // max_ascent_ is y-up, fAscent is y-down, baseline_offset is y-down max_ascent_ = std::max( max_ascent_, -(metrics.fAscent + run.font_params.baseline_offset)); if (run.font_params.is_rtl) { rtl_segments_.push_back( SegmentHandle(lines_.size() - 1, line->segments.size() - 1)); // If this is the last segment of an RTL run, reprocess the text-space x // ranges of all segments from the run. if (segment.char_range.end() == run.range.end()) UpdateRTLSegmentRanges(); } text_x_ += segment.width(); available_width_ -= segment.width(); } // Finds the end position |end_pos| in |segment| where the preceding width is // no larger than |available_width_|. size_t GetCutoffPos(const internal::LineSegment& segment) const { DCHECK(!segment.char_range.is_empty()); const internal::TextRunHarfBuzz& run = *(run_list_.runs()[segment.run]).get(); size_t end_pos = segment.char_range.start(); SkScalar width = 0; while (end_pos < segment.char_range.end()) { const SkScalar char_width = run.GetGlyphWidthForCharRange(Range(end_pos, end_pos + 1)); if (width + char_width > available_width_) break; width += char_width; end_pos++; } const size_t valid_end_pos = std::max( segment.char_range.start(), static_cast(FindValidBoundaryBefore(text_, end_pos))); if (end_pos != valid_end_pos) { end_pos = valid_end_pos; width = run.GetGlyphWidthForCharRange( Range(segment.char_range.start(), end_pos)); } // |max_width_| might be smaller than a single character. In this case we // need to put at least one character in the line. Note that, we should // not separate surrogate pair or combining characters. // See RenderTextHarfBuzzTest.Multiline_MinWidth for an example. if (width == 0 && available_width_ == max_width_) { end_pos = std::min( segment.char_range.end(), static_cast(FindValidBoundaryAfter(text_, end_pos + 1))); } return end_pos; } // Gets the glyph width for |word_range|, and splits the |word| into different // segments based on its runs. SkScalar GetWordWidth(const Range& word_range, std::vector* segments) const { DCHECK(words_); if (word_range.is_empty() || segments == nullptr) return 0; size_t run_start_index = run_list_.GetRunIndexAt(word_range.start()); size_t run_end_index = run_list_.GetRunIndexAt(word_range.end() - 1); SkScalar width = 0; for (size_t i = run_start_index; i <= run_end_index; i++) { const internal::TextRunHarfBuzz& run = *(run_list_.runs()[i]); const Range char_range = run.range.Intersect(word_range); DCHECK(!char_range.is_empty()); const SkScalar char_width = run.GetGlyphWidthForCharRange(char_range); width += char_width; internal::LineSegment segment; segment.run = i; segment.char_range = char_range; segment.x_range = RangeF(SkScalarToFloat(text_x_ + width - char_width), SkScalarToFloat(text_x_ + width)); segments->push_back(segment); } return width; } // RTL runs are broken in logical order but displayed in visual order. To find // the text-space coordinate (where it would fall in a single-line text) // |x_range| of RTL segments, segment widths are applied in reverse order. // e.g. {[5, 10], [10, 40]} will become {[35, 40], [5, 35]}. void UpdateRTLSegmentRanges() { if (rtl_segments_.empty()) return; float x = SegmentFromHandle(rtl_segments_[0])->x_range.start(); for (size_t i = rtl_segments_.size(); i > 0; --i) { internal::LineSegment* segment = SegmentFromHandle(rtl_segments_[i - 1]); const float segment_width = segment->width(); segment->x_range = RangeF(x, x + segment_width); x += segment_width; } rtl_segments_.clear(); } const SkScalar max_width_; const int min_baseline_; const float min_height_; const WordWrapBehavior word_wrap_behavior_; const base::string16& text_; const BreakList* const words_; const internal::TextRunList& run_list_; // Stores the resulting lines. std::vector lines_; float max_descent_; float max_ascent_; // Text space x coordinates of the next segment to be added. SkScalar text_x_; // Stores available width in the current line. SkScalar available_width_; // Size of the multiline text, not including the currently processed line. SizeF total_size_; // The current RTL run segments, to be applied by |UpdateRTLSegmentRanges()|. std::vector rtl_segments_; DISALLOW_COPY_AND_ASSIGN(HarfBuzzLineBreaker); }; // Function object for case insensitive string comparison. struct CaseInsensitiveCompare { bool operator() (const Font& a, const Font& b) const { return base::CompareCaseInsensitiveASCII(a.GetFontName(), b.GetFontName()) < 0; } }; // Applies a forced text rendering direction if specified by a command-line // switch. void ApplyForcedDirection(UBiDiLevel* level) { static bool has_switch = base::CommandLine::ForCurrentProcess()->HasSwitch( switches::kForceTextDirection); if (!has_switch) return; base::CommandLine* command_line = base::CommandLine::ForCurrentProcess(); if (command_line->HasSwitch(switches::kForceTextDirection)) { std::string force_flag = command_line->GetSwitchValueASCII(switches::kForceTextDirection); if (force_flag == switches::kForceDirectionRTL) *level = UBIDI_RTL; if (force_flag == switches::kForceDirectionLTR) *level = UBIDI_LTR; } } } // namespace namespace internal { #if !defined(OS_MACOSX) sk_sp CreateSkiaTypeface(const Font& font, bool italic, Font::Weight weight) { SkFontStyle skia_style( static_cast(weight), SkFontStyle::kNormal_Width, italic ? SkFontStyle::kItalic_Slant : SkFontStyle::kUpright_Slant); return sk_sp(SkTypeface::MakeFromName( font.GetFontName().c_str(), skia_style)); } #endif TextRunHarfBuzz::FontParams::FontParams(const Font& template_font) : font(template_font) {} TextRunHarfBuzz::FontParams::~FontParams() = default; TextRunHarfBuzz::FontParams::FontParams( const TextRunHarfBuzz::FontParams& other) = default; TextRunHarfBuzz::FontParams& TextRunHarfBuzz::FontParams::operator=( const TextRunHarfBuzz::FontParams& other) = default; bool TextRunHarfBuzz::FontParams::operator==(const FontParams& other) const { // Empirically, |script| and |weight| are the highest entropy members. return script == other.script && weight == other.weight && skia_face == other.skia_face && render_params == other.render_params && font_size == other.font_size && baseline_offset == other.baseline_offset && baseline_type == other.baseline_type && italic == other.italic && strike == other.strike && underline == other.underline && heavy_underline == other.heavy_underline && is_rtl == other.is_rtl && level == other.level; } void TextRunHarfBuzz::FontParams:: ComputeRenderParamsFontSizeAndBaselineOffset() { render_params = font.GetFontRenderParams(); if (font_size == 0) font_size = font.GetFontSize(); baseline_offset = 0; if (baseline_type != NORMAL_BASELINE) { // Calculate a slightly smaller font. The ratio here is somewhat arbitrary. // Proportions from 5/9 to 5/7 all look pretty good. const float ratio = 5.0f / 9.0f; font_size = ToRoundedInt(font.GetFontSize() * ratio); switch (baseline_type) { case SUPERSCRIPT: baseline_offset = font.GetCapHeight() - font.GetHeight(); break; case SUPERIOR: baseline_offset = ToRoundedInt(font.GetCapHeight() * ratio) - font.GetCapHeight(); break; case SUBSCRIPT: baseline_offset = font.GetHeight() - font.GetBaseline(); break; case INFERIOR: // Fall through. default: break; } } } size_t TextRunHarfBuzz::FontParams::Hash::operator()( const FontParams& key) const { // In practice, |font|, |skia_face|, |render_params|, and |baseline_offset| // have not yet been set when this is called. return static_cast(key.italic) << 0 ^ static_cast(key.strike) << 1 ^ static_cast(key.underline) << 2 ^ static_cast(key.heavy_underline) << 3 ^ static_cast(key.is_rtl) << 4 ^ static_cast(key.weight) << 8 ^ static_cast(key.font_size) << 12 ^ static_cast(key.baseline_type) << 16 ^ static_cast(key.level) << 20 ^ static_cast(key.script) << 24; } bool TextRunHarfBuzz::FontParams::SetFontAndRenderParams( const Font& new_font, const FontRenderParams& new_render_params) { sk_sp new_skia_face( internal::CreateSkiaTypeface(new_font, italic, weight)); if (!new_skia_face) return false; skia_face = new_skia_face; font = new_font; render_params = new_render_params; return true; } TextRunHarfBuzz::ShapeOutput::ShapeOutput() = default; TextRunHarfBuzz::ShapeOutput::~ShapeOutput() = default; TextRunHarfBuzz::ShapeOutput::ShapeOutput( const TextRunHarfBuzz::ShapeOutput& other) = default; TextRunHarfBuzz::ShapeOutput& TextRunHarfBuzz::ShapeOutput::operator=( const TextRunHarfBuzz::ShapeOutput& other) = default; TextRunHarfBuzz::ShapeOutput::ShapeOutput( TextRunHarfBuzz::ShapeOutput&& other) = default; TextRunHarfBuzz::ShapeOutput& TextRunHarfBuzz::ShapeOutput::operator=( TextRunHarfBuzz::ShapeOutput&& other) = default; TextRunHarfBuzz::TextRunHarfBuzz(const Font& template_font) : font_params(template_font) {} TextRunHarfBuzz::~TextRunHarfBuzz() {} Range TextRunHarfBuzz::CharRangeToGlyphRange(const Range& char_range) const { DCHECK(range.Contains(char_range)); DCHECK(!char_range.is_reversed()); DCHECK(!char_range.is_empty()); Range start_glyphs; Range end_glyphs; Range temp_range; GetClusterAt(char_range.start(), &temp_range, &start_glyphs); GetClusterAt(char_range.end() - 1, &temp_range, &end_glyphs); return font_params.is_rtl ? Range(end_glyphs.start(), start_glyphs.end()) : Range(start_glyphs.start(), end_glyphs.end()); } size_t TextRunHarfBuzz::CountMissingGlyphs() const { return shape.missing_glyph_count; } void TextRunHarfBuzz::GetClusterAt(size_t pos, Range* chars, Range* glyphs) const { DCHECK(chars); DCHECK(glyphs); bool success = true; if (shape.glyph_count == 0 || !range.Contains(Range(pos, pos + 1))) { *chars = range; *glyphs = Range(); success = false; } if (font_params.is_rtl) { success &= GetClusterAtImpl(pos, range, shape.glyph_to_char.rbegin(), shape.glyph_to_char.rend(), true, chars, glyphs); } else { success &= GetClusterAtImpl(pos, range, shape.glyph_to_char.begin(), shape.glyph_to_char.end(), false, chars, glyphs); } if (!success) { std::string glyph_to_char_string; for (size_t i = 0; i < shape.glyph_count && i < shape.glyph_to_char.size(); ++i) { glyph_to_char_string += base::NumberToString(i) + "->" + base::UintToString(shape.glyph_to_char[i]) + ", "; } LOG(ERROR) << " TextRunHarfBuzz error, please report at crbug.com/724880:" << " range: " << range.ToString() << ", rtl: " << font_params.is_rtl << "," << " level: '" << font_params.level << "', script: " << font_params.script << "," << " font: '" << font_params.font.GetActualFontNameForTesting() << "'," << " glyph_count: " << shape.glyph_count << ", pos: " << pos << "," << " glyph_to_char: " << glyph_to_char_string; } } RangeF TextRunHarfBuzz::GetGraphemeBounds(RenderTextHarfBuzz* render_text, size_t text_index) const { DCHECK_LT(text_index, range.end()); if (shape.glyph_count == 0) return RangeF(preceding_run_widths, preceding_run_widths + shape.width); Range chars; Range glyphs; GetClusterAt(text_index, &chars, &glyphs); const float cluster_begin_x = shape.positions[glyphs.start()].x(); const float cluster_end_x = glyphs.end() < shape.glyph_count ? shape.positions[glyphs.end()].x() : SkFloatToScalar(shape.width); DCHECK_LE(cluster_begin_x, cluster_end_x); // A cluster consists of a number of code points and corresponds to a number // of glyphs that should be drawn together. A cluster can contain multiple // graphemes. In order to place the cursor at a grapheme boundary inside the // cluster, we simply divide the cluster width by the number of graphemes. // Note: The first call to GetGraphemeIterator() can be expensive, so avoid // doing it unless it's actually needed (when |code_point_count| > 1). ptrdiff_t code_point_count = UTF16IndexToOffset(render_text->GetDisplayText(), chars.start(), chars.end()); if (code_point_count > 1 && render_text->GetGraphemeIterator()) { int before = 0; int total = 0; base::i18n::BreakIterator* grapheme_iterator = render_text->GetGraphemeIterator(); for (size_t i = chars.start(); i < chars.end(); ++i) { if (grapheme_iterator->IsGraphemeBoundary(i)) { if (i < text_index) ++before; ++total; } } DCHECK_GT(total, 0); // It's possible for |text_index| to point to a diacritical mark, at the end // of |chars|. In this case all the grapheme boundaries come before it. Just // provide the bounds of the last grapheme. if (before == total) --before; if (total > 1) { if (font_params.is_rtl) before = total - before - 1; DCHECK_GE(before, 0); DCHECK_LT(before, total); const float cluster_start = preceding_run_widths + cluster_begin_x; const float average_width = (cluster_end_x - cluster_begin_x) / total; return RangeF(cluster_start + average_width * before, cluster_start + average_width * (before + 1)); } } return RangeF(preceding_run_widths + cluster_begin_x, preceding_run_widths + cluster_end_x); } RangeF TextRunHarfBuzz::GetGraphemeSpanForCharRange( RenderTextHarfBuzz* render_text, const Range& char_range) const { if (char_range.is_empty()) return RangeF(); DCHECK(!char_range.is_reversed()); DCHECK(range.Contains(char_range)); size_t left_index = char_range.start(); size_t right_index = UTF16OffsetToIndex(render_text->GetDisplayText(), char_range.end(), -1); DCHECK_LE(left_index, right_index); if (font_params.is_rtl) std::swap(left_index, right_index); const RangeF left_span = GetGraphemeBounds(render_text, left_index); return left_index == right_index ? left_span : RangeF(left_span.start(), GetGraphemeBounds(render_text, right_index).end()); } SkScalar TextRunHarfBuzz::GetGlyphWidthForCharRange( const Range& char_range) const { if (char_range.is_empty()) return 0; DCHECK(range.Contains(char_range)); Range glyph_range = CharRangeToGlyphRange(char_range); // The |glyph_range| might be empty or invalid on Windows if a multi-character // grapheme is divided into different runs (e.g., there are two font sizes or // colors for a single glyph). In this case it might cause the browser crash, // see crbug.com/526234. if (glyph_range.start() >= glyph_range.end()) { NOTREACHED() << "The glyph range is empty or invalid! Its char range: [" << char_range.start() << ", " << char_range.end() << "], and its glyph range: [" << glyph_range.start() << ", " << glyph_range.end() << "]."; return 0; } return ((glyph_range.end() == shape.glyph_count) ? SkFloatToScalar(shape.width) : shape.positions[glyph_range.end()].x()) - shape.positions[glyph_range.start()].x(); } void TextRunHarfBuzz::UpdateFontParamsAndShape( const FontParams& new_font_params, const ShapeOutput& new_shape) { if (new_shape.missing_glyph_count < shape.missing_glyph_count) { font_params = new_font_params; shape = new_shape; // Note that |new_shape.glyph_to_char| is indexed from the beginning of // |range|, while |shape.glyph_to_char| is indexed from the beginning of // its embedding text. for (size_t i = 0; i < shape.glyph_to_char.size(); ++i) shape.glyph_to_char[i] += range.start(); } } TextRunList::TextRunList() : width_(0.0f) {} TextRunList::~TextRunList() {} void TextRunList::Reset() { runs_.clear(); width_ = 0.0f; } void TextRunList::InitIndexMap() { if (runs_.size() == 1) { visual_to_logical_ = logical_to_visual_ = std::vector(1, 0); return; } const size_t num_runs = runs_.size(); std::vector levels(num_runs); for (size_t i = 0; i < num_runs; ++i) levels[i] = runs_[i]->font_params.level; visual_to_logical_.resize(num_runs); ubidi_reorderVisual(&levels[0], num_runs, &visual_to_logical_[0]); logical_to_visual_.resize(num_runs); ubidi_reorderLogical(&levels[0], num_runs, &logical_to_visual_[0]); } void TextRunList::ComputePrecedingRunWidths() { // Precalculate run width information. width_ = 0.0f; for (size_t i = 0; i < runs_.size(); ++i) { const auto& run = runs_[visual_to_logical_[i]]; run->preceding_run_widths = width_; width_ += run->shape.width; } } size_t TextRunList::GetRunIndexAt(size_t position) const { for (size_t i = 0; i < runs_.size(); ++i) { if (runs_[i]->range.start() <= position && runs_[i]->range.end() > position) return i; } return runs_.size(); } namespace { // ShapeRunWithFont cache. Views makes repeated calls to ShapeRunWithFont // with the same arguments in several places, and typesetting is very expensive. // To compensate for this, encapsulate all of the input arguments to // ShapeRunWithFont in ShapeRunWithFontInput, all of the output arguments in // TextRunHarfBuzz::ShapeOutput, and add ShapeRunCache to map between the two. // This is analogous to the blink::ShapeCache. // https://crbug.com/826265 // Input for the stateless implementation of ShapeRunWithFont. struct ShapeRunWithFontInput { ShapeRunWithFontInput(const base::string16& full_text, const TextRunHarfBuzz::FontParams& font_params, Range full_range, bool obscured, float glyph_width_for_test, int glyph_spacing, bool subpixel_rendering_suppressed) : skia_face(font_params.skia_face), render_params(font_params.render_params), script(font_params.script), font_size(font_params.font_size), glyph_spacing(glyph_spacing), glyph_width_for_test(glyph_width_for_test), is_rtl(font_params.is_rtl), obscured(obscured), subpixel_rendering_suppressed(subpixel_rendering_suppressed) { // hb_buffer_add_utf16 will read the previous and next 5 unicode characters // (which can have a maximum length of 2 uint16_t) as "context" that is used // only for Arabic (which is RTL). Read the previous and next 10 uint16_ts // to ensure that we capture all of this context if we're using RTL. size_t kContextSize = is_rtl ? 10 : 0; size_t context_start = full_range.start() < kContextSize ? 0 : full_range.start() - kContextSize; size_t context_end = std::min(full_text.length(), full_range.end() + kContextSize); range = Range(full_range.start() - context_start, full_range.end() - context_start); text = full_text.substr(context_start, context_end - context_start); // Pre-compute the hash to avoid having to re-hash text at every comparison. // Attempt to minimize collisions by including the font and text in the // hash. hash = (uintptr_t)skia_face.get() ^ base::Hash(text); } bool operator==(const ShapeRunWithFontInput& other) const { return text == other.text && skia_face == other.skia_face && render_params == other.render_params && font_size == other.font_size && range == other.range && script == other.script && is_rtl == other.is_rtl && obscured == other.obscured && glyph_width_for_test == other.glyph_width_for_test && glyph_spacing == other.glyph_spacing && subpixel_rendering_suppressed == other.subpixel_rendering_suppressed; } struct Hash { size_t operator()(const ShapeRunWithFontInput& key) const { return key.hash; } }; sk_sp skia_face; FontRenderParams render_params; UScriptCode script; int font_size; int glyph_spacing; float glyph_width_for_test; bool is_rtl; bool obscured; bool subpixel_rendering_suppressed; // The parts of the input text that may be read by hb_buffer_add_utf16. base::string16 text; // The conversion of the input range to a range within |text|. Range range; // The hash is cached to avoid repeated calls. size_t hash = 0; }; // An MRU cache of the results from calling ShapeRunWithFont. Use the same // maximum cache size as is used in blink::ShapeCache. constexpr int kShapeRunCacheSize = 10000; using ShapeRunCacheBase = base::HashingMRUCache; class ShapeRunCache : public ShapeRunCacheBase { public: ShapeRunCache() : ShapeRunCacheBase(kShapeRunCacheSize) {} }; void ShapeRunWithFont(const ShapeRunWithFontInput& in, TextRunHarfBuzz::ShapeOutput* out) { TRACE_EVENT0("ui", "RenderTextHarfBuzz::ShapeRunWithFontInternal"); hb_font_t* harfbuzz_font = CreateHarfBuzzFont(in.skia_face, SkIntToScalar(in.font_size), in.render_params, in.subpixel_rendering_suppressed); // Create a HarfBuzz buffer and add the string to be shaped. The HarfBuzz // buffer holds our text, run information to be used by the shaping engine, // and the resulting glyph data. hb_buffer_t* buffer = hb_buffer_create(); // Note that the value of the |item_offset| argument (here specified as // |in.range.start()|) does affect the result, so we will have to adjust // the computed offsets. hb_buffer_add_utf16(buffer, reinterpret_cast(in.text.c_str()), in.text.length(), in.range.start(), in.range.length()); hb_buffer_set_script(buffer, ICUScriptToHBScript(in.script)); hb_buffer_set_direction(buffer, in.is_rtl ? HB_DIRECTION_RTL : HB_DIRECTION_LTR); // TODO(ckocagil): Should we determine the actual language? hb_buffer_set_language(buffer, hb_language_get_default()); // Shape the text. hb_shape(harfbuzz_font, buffer, NULL, 0); // Populate the run fields with the resulting glyph data in the buffer. unsigned int glyph_count = 0; hb_glyph_info_t* infos = hb_buffer_get_glyph_infos(buffer, &glyph_count); out->glyph_count = glyph_count; hb_glyph_position_t* hb_positions = hb_buffer_get_glyph_positions(buffer, NULL); out->glyphs.resize(out->glyph_count); out->glyph_to_char.resize(out->glyph_count); out->positions.resize(out->glyph_count); out->width = 0.0f; #if defined(OS_MACOSX) // Mac 10.9 and 10.10 give a quirky offset for whitespace glyphs in RTL, // which requires tests relying on the behavior of |glyph_width_for_test_| // to also be given a zero x_offset, otherwise expectations get thrown off. const bool force_zero_offset = in.glyph_width_for_test > 0 && base::mac::IsAtMostOS10_10(); #else constexpr bool force_zero_offset = false; #endif constexpr uint16_t kMissingGlyphId = 0; DCHECK(in.obscured || in.glyph_spacing == 0); out->missing_glyph_count = 0; for (size_t i = 0; i < out->glyph_count; ++i) { DCHECK_LE(infos[i].codepoint, std::numeric_limits::max()); uint16_t glyph = static_cast(infos[i].codepoint); out->glyphs[i] = glyph; if (glyph == kMissingGlyphId) out->missing_glyph_count += 1; DCHECK_GE(infos[i].cluster, in.range.start()); out->glyph_to_char[i] = infos[i].cluster - in.range.start(); const SkScalar x_offset = force_zero_offset ? 0 : HarfBuzzUnitsToSkiaScalar(hb_positions[i].x_offset); const SkScalar y_offset = HarfBuzzUnitsToSkiaScalar(hb_positions[i].y_offset); out->positions[i].set(out->width + x_offset, -y_offset); out->width += (in.glyph_width_for_test > 0) ? in.glyph_width_for_test : HarfBuzzUnitsToFloat(hb_positions[i].x_advance) + in.glyph_spacing; // Round run widths if subpixel positioning is off to match native behavior. if (!in.render_params.subpixel_positioning) out->width = std::round(out->width); } hb_buffer_destroy(buffer); hb_font_destroy(harfbuzz_font); } } // namespace } // namespace internal RenderTextHarfBuzz::RenderTextHarfBuzz() : RenderText(), update_layout_run_list_(false), update_display_run_list_(false), update_grapheme_iterator_(false), update_display_text_(false), glyph_width_for_test_(0u) { set_truncate_length(kMaxTextLength); } RenderTextHarfBuzz::~RenderTextHarfBuzz() {} std::unique_ptr RenderTextHarfBuzz::CreateInstanceOfSameType() const { return base::WrapUnique(new RenderTextHarfBuzz); } bool RenderTextHarfBuzz::MultilineSupported() const { return true; } const base::string16& RenderTextHarfBuzz::GetDisplayText() { // TODO(krb): Consider other elision modes for multiline. if ((multiline() && (max_lines() == 0 || elide_behavior() != ELIDE_TAIL)) || elide_behavior() == NO_ELIDE || elide_behavior() == FADE_TAIL) { // Call UpdateDisplayText to clear |display_text_| and |text_elided_| // on the RenderText class. UpdateDisplayText(0); update_display_text_ = false; display_run_list_.reset(); return layout_text(); } EnsureLayoutRunList(); DCHECK(!update_display_text_); return text_elided() ? display_text() : layout_text(); } Size RenderTextHarfBuzz::GetStringSize() { const SizeF size_f = GetStringSizeF(); return Size(std::ceil(size_f.width()), size_f.height()); } SizeF RenderTextHarfBuzz::GetStringSizeF() { EnsureLayout(); return total_size_; } SelectionModel RenderTextHarfBuzz::FindCursorPosition(const Point& view_point) { EnsureLayout(); DCHECK(!lines().empty()); int line_index = GetLineContainingYCoord((view_point - GetLineOffset(0)).y()); // Handle kDragToEndIfOutsideVerticalBounds above or below the text in a // single-line by extending towards the mouse cursor. if (RenderText::kDragToEndIfOutsideVerticalBounds && !multiline() && (line_index < 0 || line_index >= static_cast(lines().size()))) { SelectionModel selection_start = GetSelectionModelForSelectionStart(); bool left = view_point.x() < GetCursorBounds(selection_start, true).x(); return EdgeSelectionModel(left ? CURSOR_LEFT : CURSOR_RIGHT); } // Otherwise, clamp |line_index| to a valid value or drag to logical ends. if (line_index < 0) { if (RenderText::kDragToEndIfOutsideVerticalBounds) return EdgeSelectionModel(GetVisualDirectionOfLogicalBeginning()); line_index = 0; } if (line_index >= static_cast(lines().size())) { if (RenderText::kDragToEndIfOutsideVerticalBounds) return EdgeSelectionModel(GetVisualDirectionOfLogicalEnd()); line_index = lines().size() - 1; } const internal::Line& line = lines()[line_index]; float point_offset_relative_segment = 0; const int segment_index = GetLineSegmentContainingXCoord( line, (view_point - GetLineOffset(line_index)).x(), &point_offset_relative_segment); if (segment_index < 0) return LineSelectionModel(line_index, CURSOR_LEFT); if (segment_index >= static_cast(line.segments.size())) return LineSelectionModel(line_index, CURSOR_RIGHT); const internal::LineSegment& segment = line.segments[segment_index]; const internal::TextRunHarfBuzz& run = *GetRunList()->runs()[segment.run]; const size_t segment_min_glyph_index = run.CharRangeToGlyphRange(segment.char_range).GetMin(); const float segment_offset_relative_run = segment_min_glyph_index != 0 ? SkScalarToFloat(run.shape.positions[segment_min_glyph_index].x()) : 0; const float point_offset_relative_run = point_offset_relative_segment + segment_offset_relative_run; // TODO(crbug.com/676287): Use offset within the glyph to return the correct // grapheme position within a multi-grapheme glyph. for (size_t i = 0; i < run.shape.glyph_count; ++i) { const float end = i + 1 == run.shape.glyph_count ? run.shape.width : SkScalarToFloat(run.shape.positions[i + 1].x()); const float middle = (end + SkScalarToFloat(run.shape.positions[i].x())) / 2; const size_t index = DisplayIndexToTextIndex(run.shape.glyph_to_char[i]); if (point_offset_relative_run < middle) { return run.font_params.is_rtl ? SelectionModel(IndexOfAdjacentGrapheme( index, CURSOR_FORWARD), CURSOR_BACKWARD) : SelectionModel(index, CURSOR_FORWARD); } if (point_offset_relative_run < end) { return run.font_params.is_rtl ? SelectionModel(index, CURSOR_FORWARD) : SelectionModel(IndexOfAdjacentGrapheme( index, CURSOR_FORWARD), CURSOR_BACKWARD); } } return LineSelectionModel(line_index, CURSOR_RIGHT); } bool RenderTextHarfBuzz::IsSelectionSupported() const { return true; } std::vector RenderTextHarfBuzz::GetFontSpansForTesting() { EnsureLayout(); internal::TextRunList* run_list = GetRunList(); std::vector spans; for (const auto& run : run_list->runs()) { spans.push_back( RenderText::FontSpan(run->font_params.font, Range(DisplayIndexToTextIndex(run->range.start()), DisplayIndexToTextIndex(run->range.end())))); } return spans; } Range RenderTextHarfBuzz::GetCursorSpan(const Range& text_range) { DCHECK(!text_range.is_reversed()); EnsureLayout(); const size_t index = text_range.start(); const size_t run_index = GetRunContainingCaret(SelectionModel(index, CURSOR_FORWARD)); internal::TextRunList* run_list = GetRunList(); // Return edge bounds if the index is invalid or beyond the layout text size. if (run_index >= run_list->size()) return Range(GetStringSize().width()); internal::TextRunHarfBuzz* run = run_list->runs()[run_index].get(); Range display_range(TextIndexToDisplayIndex(text_range.start()), TextIndexToDisplayIndex(text_range.end())); // Although highly likely, there's no guarantee that a single text run is used // for the entire cursor span. For example, Unicode Variation Selectors are // incorrectly placed in the next run; see crbug.com/775404. (For these, the // variation selector has zero width, so it's safe to ignore the second run). // TODO(tapted): Change this to a DCHECK when crbug.com/775404 is fixed. display_range = display_range.Intersect(run->range); RangeF bounds = run->GetGraphemeSpanForCharRange(this, display_range); // If cursor is enabled, extend the last glyph up to the rightmost cursor // position since clients expect them to be contiguous. if (cursor_enabled() && run_index == run_list->size() - 1 && index == (run->font_params.is_rtl ? run->range.start() : run->range.end() - 1)) bounds.set_end(std::ceil(bounds.end())); return run->font_params.is_rtl ? RangeF(bounds.end(), bounds.start()).Round() : bounds.Round(); } base::i18n::BreakIterator* RenderTextHarfBuzz::GetGraphemeIterator() { if (update_grapheme_iterator_) { update_grapheme_iterator_ = false; grapheme_iterator_.reset(new base::i18n::BreakIterator( GetDisplayText(), base::i18n::BreakIterator::BREAK_CHARACTER)); if (!grapheme_iterator_->Init()) grapheme_iterator_.reset(); } return grapheme_iterator_.get(); } int RenderTextHarfBuzz::GetDisplayTextBaseline() { EnsureLayout(); return lines()[0].baseline; } SelectionModel RenderTextHarfBuzz::AdjacentCharSelectionModel( const SelectionModel& selection, VisualCursorDirection direction) { DCHECK(!update_display_run_list_); internal::TextRunList* run_list = GetRunList(); internal::TextRunHarfBuzz* run; size_t run_index = GetRunContainingCaret(selection); if (run_index >= run_list->size()) { // The cursor is not in any run: we're at the visual and logical edge. SelectionModel edge = EdgeSelectionModel(direction); if (edge.caret_pos() == selection.caret_pos()) return edge; int visual_index = (direction == CURSOR_RIGHT) ? 0 : run_list->size() - 1; run = run_list->runs()[run_list->visual_to_logical(visual_index)].get(); } else { // If the cursor is moving within the current run, just move it by one // grapheme in the appropriate direction. run = run_list->runs()[run_index].get(); size_t caret = selection.caret_pos(); bool forward_motion = run->font_params.is_rtl == (direction == CURSOR_LEFT); if (forward_motion) { if (caret < DisplayIndexToTextIndex(run->range.end())) { caret = IndexOfAdjacentGrapheme(caret, CURSOR_FORWARD); return SelectionModel(caret, CURSOR_BACKWARD); } } else { if (caret > DisplayIndexToTextIndex(run->range.start())) { caret = IndexOfAdjacentGrapheme(caret, CURSOR_BACKWARD); return SelectionModel(caret, CURSOR_FORWARD); } } // The cursor is at the edge of a run; move to the visually adjacent run. int visual_index = run_list->logical_to_visual(run_index); visual_index += (direction == CURSOR_LEFT) ? -1 : 1; if (visual_index < 0 || visual_index >= static_cast(run_list->size())) return EdgeSelectionModel(direction); run = run_list->runs()[run_list->visual_to_logical(visual_index)].get(); } bool forward_motion = run->font_params.is_rtl == (direction == CURSOR_LEFT); return forward_motion ? FirstSelectionModelInsideRun(run) : LastSelectionModelInsideRun(run); } SelectionModel RenderTextHarfBuzz::AdjacentWordSelectionModel( const SelectionModel& selection, VisualCursorDirection direction) { if (obscured()) return EdgeSelectionModel(direction); base::i18n::BreakIterator iter(text(), base::i18n::BreakIterator::BREAK_WORD); bool success = iter.Init(); DCHECK(success); if (!success) return selection; internal::TextRunList* run_list = GetRunList(); SelectionModel current(selection); for (;;) { current = AdjacentCharSelectionModel(current, direction); size_t run = GetRunContainingCaret(current); if (run == run_list->size()) break; size_t cursor = current.caret_pos(); #if defined(OS_WIN) // Windows generally advances to the start of a word in either direction. // TODO: Break on the end of a word when the neighboring text is puctuation. if (iter.IsStartOfWord(cursor)) break; #else const bool is_forward = run_list->runs()[run]->font_params.is_rtl == (direction == CURSOR_LEFT); if (is_forward ? iter.IsEndOfWord(cursor) : iter.IsStartOfWord(cursor)) break; #endif // defined(OS_WIN) } return current; } std::vector RenderTextHarfBuzz::GetSubstringBounds(const Range& range) { DCHECK(!update_display_run_list_); DCHECK(Range(0, text().length()).Contains(range)); const size_t start = IsValidCursorIndex(range.GetMin()) ? range.GetMin() : IndexOfAdjacentGrapheme(range.GetMin(), CURSOR_BACKWARD); const size_t end = IsValidCursorIndex(range.GetMax()) ? range.GetMax() : IndexOfAdjacentGrapheme(range.GetMax(), CURSOR_FORWARD); const Range display_range(TextIndexToDisplayIndex(start), TextIndexToDisplayIndex(end)); DCHECK(Range(0, GetDisplayText().length()).Contains(display_range)); std::vector rects; if (display_range.is_empty()) return rects; internal::TextRunList* run_list = GetRunList(); for (size_t line_index = 0; line_index < lines().size(); ++line_index) { const internal::Line& line = lines()[line_index]; // Only the last line can be empty. DCHECK(!line.segments.empty() || (line_index == lines().size() - 1)); const float line_start_x = line.segments.empty() ? 0 : run_list->runs()[line.segments[0].run]->preceding_run_widths; for (const internal::LineSegment& segment : line.segments) { const Range intersection = segment.char_range.Intersect(display_range); DCHECK(!intersection.is_reversed()); if (!intersection.is_empty()) { const internal::TextRunHarfBuzz& run = *run_list->runs()[segment.run]; RangeF selected_span = run.GetGraphemeSpanForCharRange(this, intersection); int start_x = std::ceil(selected_span.start() - line_start_x); int end_x = std::ceil(selected_span.end() - line_start_x); Rect rect(start_x, 0, end_x - start_x, std::ceil(line.size.height())); rects.push_back(rect + GetLineOffset(line_index)); } } } return rects; } size_t RenderTextHarfBuzz::TextIndexToDisplayIndex(size_t index) { return TextIndexToGivenTextIndex(GetDisplayText(), index); } size_t RenderTextHarfBuzz::DisplayIndexToTextIndex(size_t index) { if (!obscured()) return index; const size_t text_index = UTF16OffsetToIndex(text(), 0, index); DCHECK_LE(text_index, text().length()); return text_index; } bool RenderTextHarfBuzz::IsValidCursorIndex(size_t index) { if (index == 0 || index == text().length()) return true; if (!IsValidLogicalIndex(index)) return false; base::i18n::BreakIterator* grapheme_iterator = GetGraphemeIterator(); return !grapheme_iterator || grapheme_iterator->IsGraphemeBoundary(index); } void RenderTextHarfBuzz::OnLayoutTextAttributeChanged(bool text_changed) { update_layout_run_list_ = true; OnDisplayTextAttributeChanged(); } void RenderTextHarfBuzz::OnDisplayTextAttributeChanged() { update_display_text_ = true; update_grapheme_iterator_ = true; } void RenderTextHarfBuzz::EnsureLayout() { EnsureLayoutRunList(); if (update_display_run_list_) { DCHECK(text_elided()); const base::string16& display_text = GetDisplayText(); display_run_list_.reset(new internal::TextRunList); if (!display_text.empty()) ItemizeAndShapeText(display_text, display_run_list_.get()); update_display_run_list_ = false; std::vector empty_lines; set_lines(&empty_lines); } if (lines().empty()) { internal::TextRunList* run_list = GetRunList(); const int height = std::max(font_list().GetHeight(), min_line_height()); HarfBuzzLineBreaker line_breaker( display_rect().width(), DetermineBaselineCenteringText(height, font_list()), height, word_wrap_behavior(), GetDisplayText(), multiline() ? &GetLineBreaks() : nullptr, *run_list); if (multiline()) line_breaker.ConstructMultiLines(); else line_breaker.ConstructSingleLine(); std::vector lines; line_breaker.FinalizeLines(&lines, &total_size_); set_lines(&lines); } } void RenderTextHarfBuzz::DrawVisualText(internal::SkiaTextRenderer* renderer) { DCHECK(!update_layout_run_list_); DCHECK(!update_display_run_list_); DCHECK(!update_display_text_); if (lines().empty()) return; ApplyFadeEffects(renderer); ApplyTextShadows(renderer); ApplyCompositionAndSelectionStyles(); internal::TextRunList* run_list = GetRunList(); for (size_t i = 0; i < lines().size(); ++i) { const internal::Line& line = lines()[i]; const Vector2d origin = GetLineOffset(i) + Vector2d(0, line.baseline); SkScalar preceding_segment_widths = 0; for (const internal::LineSegment& segment : line.segments) { // Don't draw the newline glyph (crbug.com/680430). if (IsNewlineSegment(GetDisplayText(), segment)) continue; const internal::TextRunHarfBuzz& run = *run_list->runs()[segment.run]; renderer->SetTypeface(run.font_params.skia_face); renderer->SetTextSize(SkIntToScalar(run.font_params.font_size)); renderer->SetFontRenderParams(run.font_params.render_params, subpixel_rendering_suppressed()); Range glyphs_range = run.CharRangeToGlyphRange(segment.char_range); std::vector positions(glyphs_range.length()); SkScalar offset_x = preceding_segment_widths - ((glyphs_range.GetMin() != 0) ? run.shape.positions[glyphs_range.GetMin()].x() : 0); for (size_t j = 0; j < glyphs_range.length(); ++j) { positions[j] = run.shape.positions[(glyphs_range.is_reversed()) ? (glyphs_range.start() - j) : (glyphs_range.start() + j)]; positions[j].offset( SkIntToScalar(origin.x()) + offset_x, SkIntToScalar(origin.y() + run.font_params.baseline_offset)); } for (BreakList::const_iterator it = colors().GetBreak(segment.char_range.start()); it != colors().breaks().end() && it->first < segment.char_range.end(); ++it) { const Range intersection = colors().GetRange(it).Intersect(segment.char_range); const Range colored_glyphs = run.CharRangeToGlyphRange(intersection); // The range may be empty if a portion of a multi-character grapheme is // selected, yielding two colors for a single glyph. For now, this just // paints the glyph with a single style, but it should paint it twice, // clipped according to selection bounds. See http://crbug.com/366786 if (colored_glyphs.is_empty()) continue; renderer->SetForegroundColor(it->second); renderer->DrawPosText( &positions[colored_glyphs.start() - glyphs_range.start()], &run.shape.glyphs[colored_glyphs.start()], colored_glyphs.length()); int start_x = SkScalarRoundToInt( positions[colored_glyphs.start() - glyphs_range.start()].x()); int end_x = SkScalarRoundToInt( (colored_glyphs.end() == glyphs_range.end()) ? (SkFloatToScalar(segment.width()) + preceding_segment_widths + SkIntToScalar(origin.x())) : positions[colored_glyphs.end() - glyphs_range.start()].x()); if (run.font_params.heavy_underline) renderer->DrawUnderline(start_x, origin.y(), end_x - start_x, 2.0); else if (run.font_params.underline) renderer->DrawUnderline(start_x, origin.y(), end_x - start_x); if (run.font_params.strike) renderer->DrawStrike(start_x, origin.y(), end_x - start_x, strike_thickness_factor()); } preceding_segment_widths += SkFloatToScalar(segment.width()); } } UndoCompositionAndSelectionStyles(); } size_t RenderTextHarfBuzz::GetRunContainingCaret( const SelectionModel& caret) { DCHECK(!update_display_run_list_); size_t layout_position = TextIndexToDisplayIndex(caret.caret_pos()); LogicalCursorDirection affinity = caret.caret_affinity(); internal::TextRunList* run_list = GetRunList(); for (size_t i = 0; i < run_list->size(); ++i) { internal::TextRunHarfBuzz* run = run_list->runs()[i].get(); if (RangeContainsCaret(run->range, layout_position, affinity)) return i; } return run_list->size(); } SelectionModel RenderTextHarfBuzz::FirstSelectionModelInsideRun( const internal::TextRunHarfBuzz* run) { size_t position = DisplayIndexToTextIndex(run->range.start()); position = IndexOfAdjacentGrapheme(position, CURSOR_FORWARD); return SelectionModel(position, CURSOR_BACKWARD); } SelectionModel RenderTextHarfBuzz::LastSelectionModelInsideRun( const internal::TextRunHarfBuzz* run) { size_t position = DisplayIndexToTextIndex(run->range.end()); position = IndexOfAdjacentGrapheme(position, CURSOR_BACKWARD); return SelectionModel(position, CURSOR_FORWARD); } void RenderTextHarfBuzz::ItemizeAndShapeText(const base::string16& text, internal::TextRunList* run_list) { CommonizedRunsMap commonized_run_map; ItemizeTextToRuns(text, run_list, &commonized_run_map); for (auto iter = commonized_run_map.begin(); iter != commonized_run_map.end(); ++iter) { internal::TextRunHarfBuzz::FontParams font_params = iter->first; font_params.ComputeRenderParamsFontSizeAndBaselineOffset(); ShapeRuns(text, font_params, std::move(iter->second)); } run_list->InitIndexMap(); run_list->ComputePrecedingRunWidths(); } void RenderTextHarfBuzz::ItemizeTextToRuns( const base::string16& text, internal::TextRunList* out_run_list, CommonizedRunsMap* out_commonized_run_map) { TRACE_EVENT1("ui", "RenderTextHarfBuzz::ItemizeTextToRuns", "text_length", text.length()); DCHECK_NE(0U, text.length()); const Font& primary_font = font_list().GetPrimaryFont(); // If ICU fails to itemize the text, we create a run that spans the entire // text. This is needed because leaving the runs set empty causes some clients // to misbehave since they expect non-zero text metrics from a non-empty text. base::i18n::BiDiLineIterator bidi_iterator; base::i18n::BiDiLineIterator::CustomBehavior behavior = base::i18n::BiDiLineIterator::CustomBehavior::NONE; // If the feature flag is enabled, use the special URL behaviour on the Bidi // algorithm, if this is a URL. if (base::FeatureList::IsEnabled(features::kLeftToRightUrls) && directionality_mode() == DIRECTIONALITY_AS_URL) { behavior = base::i18n::BiDiLineIterator::CustomBehavior::AS_URL; } if (!bidi_iterator.Open(text, GetTextDirection(text), behavior)) { auto run = std::make_unique( font_list().GetPrimaryFont()); run->range = Range(0, text.length()); internal::TextRunHarfBuzz::FontParams font_params(primary_font); (*out_commonized_run_map)[font_params].push_back(run.get()); out_run_list->Add(std::move(run)); return; } // Temporarily apply composition underlines and selection colors. ApplyCompositionAndSelectionStyles(); // Build the run list from the script items and ranged styles and baselines. // Use an empty color BreakList to avoid breaking runs at color boundaries. BreakList empty_colors; empty_colors.SetMax(colors().max()); DCHECK_LE(text.size(), baselines().max()); for (const BreakList& style : styles()) DCHECK_LE(text.size(), style.max()); internal::StyleIterator style(empty_colors, baselines(), font_size_overrides(), weights(), styles()); for (size_t run_break = 0; run_break < text.length();) { Range run_range; internal::TextRunHarfBuzz::FontParams font_params(primary_font); run_range.set_start(run_break); font_params.italic = style.style(ITALIC); font_params.baseline_type = style.baseline(); font_params.font_size = style.font_size_override(); font_params.strike = style.style(STRIKE); font_params.underline = style.style(UNDERLINE); font_params.heavy_underline = style.style(HEAVY_UNDERLINE); font_params.weight = style.weight(); int32_t script_item_break = 0; bidi_iterator.GetLogicalRun(run_break, &script_item_break, &font_params.level); CHECK_GT(static_cast(script_item_break), run_break); ApplyForcedDirection(&font_params.level); // Odd BiDi embedding levels correspond to RTL runs. font_params.is_rtl = (font_params.level % 2) == 1; // Find the length and script of this script run. script_item_break = ScriptInterval(text, run_break, script_item_break - run_break, &font_params.script) + run_break; // Find the next break and advance the iterators as needed. const size_t new_run_break = std::min( static_cast(script_item_break), TextIndexToGivenTextIndex(text, style.GetRange().end())); CHECK_GT(new_run_break, run_break) << "It must proceed! " << text << " " << run_break; run_break = new_run_break; // Break runs at certain characters that need to be rendered separately to // prevent either an unusual character from forcing a fallback font on the // entire run, or brackets from being affected by a fallback font. // http://crbug.com/278913, http://crbug.com/396776 if (run_break > run_range.start()) run_break = FindRunBreakingCharacter(text, run_range.start(), run_break); DCHECK(IsValidCodePointIndex(text, run_break)); style.UpdatePosition(DisplayIndexToTextIndex(run_break)); run_range.set_end(run_break); auto run = std::make_unique( font_list().GetPrimaryFont()); (*out_commonized_run_map)[font_params].push_back(run.get()); run->range = run_range; out_run_list->Add(std::move(run)); } // Undo the temporarily applied composition underlines and selection colors. UndoCompositionAndSelectionStyles(); } void RenderTextHarfBuzz::ShapeRuns( const base::string16& text, const internal::TextRunHarfBuzz::FontParams& font_params, std::vector runs) { TRACE_EVENT1("ui", "RenderTextHarfBuzz::ShapeRuns", "run_count", runs.size()); const Font& primary_font = font_list().GetPrimaryFont(); Font best_font(primary_font); for (const Font& font : font_list().GetFonts()) { internal::TextRunHarfBuzz::FontParams test_font_params = font_params; if (test_font_params.SetFontAndRenderParams(font, font.GetFontRenderParams())) { ShapeRunsWithFont(text, test_font_params, &runs); } if (runs.empty()) return; } std::string preferred_fallback_family; #if defined(OS_WIN) || defined(OS_MACOSX) Font fallback_font(primary_font); const base::char16* run_text = &(text[runs.front()->range.start()]); if (GetFallbackFont(primary_font, run_text, runs.front()->range.length(), &fallback_font)) { preferred_fallback_family = fallback_font.GetFontName(); internal::TextRunHarfBuzz::FontParams test_font_params = font_params; if (test_font_params.SetFontAndRenderParams( fallback_font, fallback_font.GetFontRenderParams())) { ShapeRunsWithFont(text, test_font_params, &runs); } if (runs.empty()) return; } #endif std::vector fallback_font_list = GetFallbackFonts(primary_font); #if defined(OS_WIN) // Append fonts in the fallback list of the preferred fallback font. // TODO(tapted): Investigate whether there's a case that benefits from this on // Mac. if (!preferred_fallback_family.empty()) { std::vector fallback_fonts = GetFallbackFonts(fallback_font); fallback_font_list.insert(fallback_font_list.end(), fallback_fonts.begin(), fallback_fonts.end()); } // Add Segoe UI and its associated linked fonts to the fallback font list to // ensure that the fallback list covers the basic cases. // http://crbug.com/467459. On some Windows configurations the default font // could be a raster font like System, which would not give us a reasonable // fallback font list. if (!base::LowerCaseEqualsASCII(primary_font.GetFontName(), "segoe ui") && !base::LowerCaseEqualsASCII(preferred_fallback_family, "segoe ui")) { std::vector default_fallback_families = GetFallbackFonts(Font("Segoe UI", 13)); fallback_font_list.insert(fallback_font_list.end(), default_fallback_families.begin(), default_fallback_families.end()); } #endif // Use a set to track the fallback fonts and avoid duplicate entries. std::set fallback_fonts; // Try shaping with the fallback fonts. for (const auto& font : fallback_font_list) { std::string font_name = font.GetFontName(); if (font_name == primary_font.GetFontName() || font_name == preferred_fallback_family || fallback_fonts.count(font)) { continue; } fallback_fonts.insert(font); FontRenderParamsQuery query; query.families.push_back(font_name); query.pixel_size = font_params.font_size; query.style = font_params.italic ? Font::ITALIC : 0; FontRenderParams fallback_render_params = GetFontRenderParams(query, NULL); internal::TextRunHarfBuzz::FontParams test_font_params = font_params; if (test_font_params.SetFontAndRenderParams(font, fallback_render_params)) { ShapeRunsWithFont(text, test_font_params, &runs); } if (runs.empty()) return; } for (internal::TextRunHarfBuzz*& run : runs) { if (run->shape.missing_glyph_count == std::numeric_limits::max()) { run->shape.glyph_count = 0; run->shape.width = 0.0f; } } } void RenderTextHarfBuzz::ShapeRunsWithFont( const base::string16& text, const internal::TextRunHarfBuzz::FontParams& font_params, std::vector* in_out_runs) { // ShapeRunWithFont can be extremely slow, so use cached results if possible. // Only do this on the UI thread, to avoid synchronization overhead (and // because almost all calls are on the UI thread. Also avoid caching long // strings, to avoid blowing up the cache size. constexpr size_t kMaxRunLengthToCache = 25; static base::NoDestructor cache; std::vector runs_with_missing_glyphs; for (internal::TextRunHarfBuzz*& run : *in_out_runs) { // First do a cache lookup. bool can_use_cache = base::MessageLoopCurrentForUI::IsSet() && run->range.length() <= kMaxRunLengthToCache; bool found_in_cache = false; const internal::ShapeRunWithFontInput cache_key( text, font_params, run->range, obscured(), glyph_width_for_test_, glyph_spacing(), subpixel_rendering_suppressed()); if (can_use_cache) { auto found = cache.get()->Get(cache_key); if (found != cache.get()->end()) { run->UpdateFontParamsAndShape(font_params, found->second); found_in_cache = true; } } // If that fails, compute the shape of the run, and add the result to the // cache. // TODO(ccameron): Coalesce calls to ShapeRunsWithFont when possible. if (!found_in_cache) { internal::TextRunHarfBuzz::ShapeOutput output; ShapeRunWithFont(cache_key, &output); run->UpdateFontParamsAndShape(font_params, output); if (can_use_cache) cache.get()->Put(cache_key, output); } // Check to see if we still have missing glyphs. if (run->shape.missing_glyph_count) runs_with_missing_glyphs.push_back(run); } in_out_runs->swap(runs_with_missing_glyphs); } void RenderTextHarfBuzz::EnsureLayoutRunList() { if (update_layout_run_list_) { layout_run_list_.Reset(); const base::string16& text = layout_text(); if (!text.empty()) ItemizeAndShapeText(text, &layout_run_list_); display_run_list_.reset(); update_display_text_ = true; update_layout_run_list_ = false; } if (update_display_text_) { std::vector empty_lines; set_lines(&empty_lines); UpdateDisplayText(multiline() ? 0 : layout_run_list_.width()); update_display_text_ = false; update_display_run_list_ = text_elided(); } } // Returns the current run list, |display_run_list_| if the text is elided, or // |layout_run_list_| otherwise. internal::TextRunList* RenderTextHarfBuzz::GetRunList() { DCHECK(!update_layout_run_list_); DCHECK(!update_display_run_list_); return text_elided() ? display_run_list_.get() : &layout_run_list_; } const internal::TextRunList* RenderTextHarfBuzz::GetRunList() const { return const_cast(this)->GetRunList(); } bool RenderTextHarfBuzz::GetDecoratedTextForRange( const Range& range, DecoratedText* decorated_text) { if (obscured()) return false; EnsureLayout(); decorated_text->attributes.clear(); decorated_text->text = GetTextFromRange(range); const internal::TextRunList* run_list = GetRunList(); for (size_t i = 0; i < run_list->size(); i++) { const internal::TextRunHarfBuzz& run = *run_list->runs()[i]; const Range intersection = range.Intersect(run.range); DCHECK(!intersection.is_reversed()); if (!intersection.is_empty()) { int style = Font::NORMAL; if (run.font_params.italic) style |= Font::ITALIC; if (run.font_params.underline || run.font_params.heavy_underline) style |= Font::UNDERLINE; // Get range relative to the decorated text. DecoratedText::RangedAttribute attribute( Range(intersection.start() - range.GetMin(), intersection.end() - range.GetMin()), run.font_params.font.Derive(0, style, run.font_params.weight)); attribute.strike = run.font_params.strike; decorated_text->attributes.push_back(attribute); } } return true; } void RenderTextHarfBuzz::SetGlyphWidthForTest(float test_width) { glyph_width_for_test_ = test_width; } } // namespace gfx