Updating trunk VERSION from 2139.0 to 2140.0
[chromium-blink-merge.git] / ui / gfx / render_text_win.cc
blobe76e6db39e8a55af31a8b1a0a1e0ad349bd86953
1 // Copyright (c) 2012 The Chromium Authors. All rights reserved.
2 // Use of this source code is governed by a BSD-style license that can be
3 // found in the LICENSE file.
5 #include "ui/gfx/render_text_win.h"
7 #include <algorithm>
9 #include "base/i18n/break_iterator.h"
10 #include "base/i18n/char_iterator.h"
11 #include "base/i18n/rtl.h"
12 #include "base/logging.h"
13 #include "base/strings/string_util.h"
14 #include "base/strings/utf_string_conversions.h"
15 #include "base/win/windows_version.h"
16 #include "third_party/icu/source/common/unicode/uchar.h"
17 #include "ui/gfx/canvas.h"
18 #include "ui/gfx/font_fallback_win.h"
19 #include "ui/gfx/font_render_params.h"
20 #include "ui/gfx/geometry/size_conversions.h"
21 #include "ui/gfx/platform_font_win.h"
22 #include "ui/gfx/utf16_indexing.h"
24 namespace gfx {
26 namespace {
28 // The maximum length of text supported for Uniscribe layout and display.
29 // This empirically chosen value should prevent major performance degradations.
30 // TODO(msw): Support longer text, partial layout/painting, etc.
31 const size_t kMaxUniscribeTextLength = 10000;
33 // The initial guess and maximum supported number of runs; arbitrary values.
34 // TODO(msw): Support more runs, determine a better initial guess, etc.
35 const int kGuessRuns = 100;
36 const size_t kMaxRuns = 10000;
38 // The maximum number of glyphs per run; ScriptShape fails on larger values.
39 const size_t kMaxGlyphs = 65535;
41 // Changes |font| to have the specified |font_size| (or |font_height| on Windows
42 // XP) and |font_style| if it is not the case already. Only considers bold and
43 // italic styles, since the underlined style has no effect on glyph shaping.
44 void DeriveFontIfNecessary(int font_size,
45 int font_height,
46 int font_style,
47 Font* font) {
48 const int kStyleMask = (Font::BOLD | Font::ITALIC);
49 const int target_style = (font_style & kStyleMask);
51 // On Windows XP, the font must be resized using |font_height| instead of
52 // |font_size| to match GDI behavior.
53 if (base::win::GetVersion() < base::win::VERSION_VISTA) {
54 PlatformFontWin* platform_font =
55 static_cast<PlatformFontWin*>(font->platform_font());
56 *font = platform_font->DeriveFontWithHeight(font_height, target_style);
57 return;
60 const int current_style = (font->GetStyle() & kStyleMask);
61 const int current_size = font->GetFontSize();
62 if (current_style != target_style || current_size != font_size)
63 *font = font->Derive(font_size - current_size, target_style);
66 // Returns true if |c| is a Unicode BiDi control character.
67 bool IsUnicodeBidiControlCharacter(base::char16 c) {
68 return c == base::i18n::kRightToLeftMark ||
69 c == base::i18n::kLeftToRightMark ||
70 c == base::i18n::kLeftToRightEmbeddingMark ||
71 c == base::i18n::kRightToLeftEmbeddingMark ||
72 c == base::i18n::kPopDirectionalFormatting ||
73 c == base::i18n::kLeftToRightOverride ||
74 c == base::i18n::kRightToLeftOverride;
77 // Returns the corresponding glyph range of the given character range.
78 // |range| is in text-space (0 corresponds to |GetLayoutText()[0]|).
79 // Returned value is in run-space (0 corresponds to the first glyph in the run).
80 Range CharRangeToGlyphRange(const internal::TextRun& run,
81 const Range& range) {
82 DCHECK(run.range.Contains(range));
83 DCHECK(!range.is_reversed());
84 DCHECK(!range.is_empty());
85 const Range run_range(range.start() - run.range.start(),
86 range.end() - run.range.start());
87 Range result;
88 if (run.script_analysis.fRTL) {
89 result = Range(run.logical_clusters[run_range.end() - 1],
90 run_range.start() > 0 ? run.logical_clusters[run_range.start() - 1]
91 : run.glyph_count);
92 } else {
93 result = Range(run.logical_clusters[run_range.start()],
94 run_range.end() < run.range.length() ?
95 run.logical_clusters[run_range.end()] : run.glyph_count);
97 DCHECK(!result.is_reversed());
98 DCHECK(Range(0, run.glyph_count).Contains(result));
99 return result;
102 // Starting from |start_char|, finds a suitable line break position at or before
103 // |available_width| using word break info from |breaks|. If |empty_line| is
104 // true, this function will not roll back to |start_char| and |*next_char| will
105 // be greater than |start_char| (to avoid constructing empty lines). Returns
106 // whether to skip the line before |*next_char|.
107 // TODO(ckocagil): Do not break ligatures and diacritics.
108 // TextRun::logical_clusters might help.
109 // TODO(ckocagil): We might have to reshape after breaking at ligatures.
110 // See whether resolving the TODO above resolves this too.
111 // TODO(ckocagil): Do not reserve width for whitespace at the end of lines.
112 bool BreakRunAtWidth(const wchar_t* text,
113 const internal::TextRun& run,
114 const BreakList<size_t>& breaks,
115 size_t start_char,
116 int available_width,
117 bool empty_line,
118 int* width,
119 size_t* next_char) {
120 DCHECK(run.range.Contains(Range(start_char, start_char + 1)));
121 BreakList<size_t>::const_iterator word = breaks.GetBreak(start_char);
122 BreakList<size_t>::const_iterator next_word = word + 1;
123 // Width from |std::max(word->first, start_char)| to the current character.
124 int word_width = 0;
125 *width = 0;
127 for (size_t i = start_char; i < run.range.end(); ++i) {
128 if (U16_IS_SINGLE(text[i]) && text[i] == L'\n') {
129 *next_char = i + 1;
130 return true;
133 // |word| holds the word boundary at or before |i|, and |next_word| holds
134 // the word boundary right after |i|. Advance both |word| and |next_word|
135 // when |i| reaches |next_word|.
136 if (next_word != breaks.breaks().end() && i >= next_word->first) {
137 word = next_word++;
138 word_width = 0;
141 Range glyph_range = CharRangeToGlyphRange(run, Range(i, i + 1));
142 int char_width = 0;
143 for (size_t j = glyph_range.start(); j < glyph_range.end(); ++j)
144 char_width += run.advance_widths[j];
146 *width += char_width;
147 word_width += char_width;
149 if (*width > available_width) {
150 if (!empty_line || word_width < *width) {
151 // Roll back one word.
152 *width -= word_width;
153 *next_char = std::max(word->first, start_char);
154 } else if (char_width < *width) {
155 // Roll back one character.
156 *width -= char_width;
157 *next_char = i;
158 } else {
159 // Continue from the next character.
160 *next_char = i + 1;
163 return true;
167 *next_char = run.range.end();
168 return false;
171 // For segments in the same run, checks the continuity and order of |x_range|
172 // and |char_range| fields.
173 void CheckLineIntegrity(const std::vector<internal::Line>& lines,
174 const ScopedVector<internal::TextRun>& runs) {
175 size_t previous_segment_line = 0;
176 const internal::LineSegment* previous_segment = NULL;
178 for (size_t i = 0; i < lines.size(); ++i) {
179 for (size_t j = 0; j < lines[i].segments.size(); ++j) {
180 const internal::LineSegment* segment = &lines[i].segments[j];
181 internal::TextRun* run = runs[segment->run];
183 if (!previous_segment) {
184 previous_segment = segment;
185 } else if (runs[previous_segment->run] != run) {
186 previous_segment = NULL;
187 } else {
188 DCHECK_EQ(previous_segment->char_range.end(),
189 segment->char_range.start());
190 if (!run->script_analysis.fRTL) {
191 DCHECK_EQ(previous_segment->x_range.end(), segment->x_range.start());
192 } else {
193 DCHECK_EQ(segment->x_range.end(), previous_segment->x_range.start());
196 previous_segment = segment;
197 previous_segment_line = i;
203 // Returns true if characters of |block_code| may trigger font fallback.
204 bool IsUnusualBlockCode(const UBlockCode block_code) {
205 return block_code == UBLOCK_GEOMETRIC_SHAPES ||
206 block_code == UBLOCK_MISCELLANEOUS_SYMBOLS;
209 // Returns the index of the first unusual character after a usual character or
210 // vice versa. Unusual characters are defined by |IsUnusualBlockCode|.
211 size_t FindUnusualCharacter(const base::string16& text,
212 size_t run_start,
213 size_t run_break) {
214 const int32 run_length = static_cast<int32>(run_break - run_start);
215 base::i18n::UTF16CharIterator iter(text.c_str() + run_start,
216 run_length);
217 const UBlockCode first_block_code = ublock_getCode(iter.get());
218 const bool first_block_unusual = IsUnusualBlockCode(first_block_code);
219 while (iter.Advance() && iter.array_pos() < run_length) {
220 const UBlockCode current_block_code = ublock_getCode(iter.get());
221 if (current_block_code != first_block_code &&
222 (first_block_unusual || IsUnusualBlockCode(current_block_code))) {
223 return run_start + iter.array_pos();
226 return run_break;
229 } // namespace
231 namespace internal {
233 TextRun::TextRun()
234 : font_style(0),
235 strike(false),
236 diagonal_strike(false),
237 underline(false),
238 width(0),
239 preceding_run_widths(0),
240 glyph_count(0),
241 script_cache(NULL) {
242 memset(&script_analysis, 0, sizeof(script_analysis));
243 memset(&abc_widths, 0, sizeof(abc_widths));
246 TextRun::~TextRun() {
247 ScriptFreeCache(&script_cache);
250 // Returns the X coordinate of the leading or |trailing| edge of the glyph
251 // starting at |index|, relative to the left of the text (not the view).
252 int GetGlyphXBoundary(const internal::TextRun* run,
253 size_t index,
254 bool trailing) {
255 DCHECK_GE(index, run->range.start());
256 DCHECK_LT(index, run->range.end() + (trailing ? 0 : 1));
257 int x = 0;
258 HRESULT hr = ScriptCPtoX(
259 index - run->range.start(),
260 trailing,
261 run->range.length(),
262 run->glyph_count,
263 run->logical_clusters.get(),
264 run->visible_attributes.get(),
265 run->advance_widths.get(),
266 &run->script_analysis,
267 &x);
268 DCHECK(SUCCEEDED(hr));
269 return run->preceding_run_widths + x;
272 // Internal class to generate Line structures. If |multiline| is true, the text
273 // is broken into lines at |words| boundaries such that each line is no longer
274 // than |max_width|. If |multiline| is false, only outputs a single Line from
275 // the given runs. |min_baseline| and |min_height| are the minimum baseline and
276 // height for each line.
277 // TODO(ckocagil): Expose the interface of this class in the header and test
278 // this class directly.
279 class LineBreaker {
280 public:
281 LineBreaker(int max_width,
282 int min_baseline,
283 int min_height,
284 bool multiline,
285 const wchar_t* text,
286 const BreakList<size_t>* words,
287 const ScopedVector<TextRun>& runs)
288 : max_width_(max_width),
289 min_baseline_(min_baseline),
290 min_height_(min_height),
291 multiline_(multiline),
292 text_(text),
293 words_(words),
294 runs_(runs),
295 text_x_(0),
296 line_x_(0),
297 line_ascent_(0),
298 line_descent_(0) {
299 AdvanceLine();
302 // Breaks the run at given |run_index| into Line structs.
303 void AddRun(int run_index) {
304 const TextRun* run = runs_[run_index];
305 bool run_fits = !multiline_;
306 if (multiline_ && line_x_ + run->width <= max_width_) {
307 DCHECK(!run->range.is_empty());
308 const wchar_t first_char = text_[run->range.start()];
309 // Uniscribe always puts newline characters in their own runs.
310 if (!U16_IS_SINGLE(first_char) || first_char != L'\n')
311 run_fits = true;
314 if (!run_fits)
315 BreakRun(run_index);
316 else
317 AddSegment(run_index, run->range, run->width);
320 // Finishes line breaking and outputs the results. Can be called at most once.
321 void Finalize(std::vector<Line>* lines, Size* size) {
322 DCHECK(!lines_.empty());
323 // Add an empty line to finish the line size calculation and remove it.
324 AdvanceLine();
325 lines_.pop_back();
326 *size = total_size_;
327 lines->swap(lines_);
330 private:
331 // A (line index, segment index) pair that specifies a segment in |lines_|.
332 typedef std::pair<size_t, size_t> SegmentHandle;
334 LineSegment* SegmentFromHandle(const SegmentHandle& handle) {
335 return &lines_[handle.first].segments[handle.second];
338 // Breaks a run into segments that fit in the last line in |lines_| and adds
339 // them. Adds a new Line to the back of |lines_| whenever a new segment can't
340 // be added without the Line's width exceeding |max_width_|.
341 void BreakRun(int run_index) {
342 DCHECK(words_);
343 const TextRun* const run = runs_[run_index];
344 int width = 0;
345 size_t next_char = run->range.start();
347 // Break the run until it fits the current line.
348 while (next_char < run->range.end()) {
349 const size_t current_char = next_char;
350 const bool skip_line = BreakRunAtWidth(text_, *run, *words_, current_char,
351 max_width_ - line_x_, line_x_ == 0, &width, &next_char);
352 AddSegment(run_index, Range(current_char, next_char), width);
353 if (skip_line)
354 AdvanceLine();
358 // RTL runs are broken in logical order but displayed in visual order. To find
359 // the text-space coordinate (where it would fall in a single-line text)
360 // |x_range| of RTL segments, segment widths are applied in reverse order.
361 // e.g. {[5, 10], [10, 40]} will become {[35, 40], [5, 35]}.
362 void UpdateRTLSegmentRanges() {
363 if (rtl_segments_.empty())
364 return;
365 int x = SegmentFromHandle(rtl_segments_[0])->x_range.start();
366 for (size_t i = rtl_segments_.size(); i > 0; --i) {
367 LineSegment* segment = SegmentFromHandle(rtl_segments_[i - 1]);
368 const size_t segment_width = segment->x_range.length();
369 segment->x_range = Range(x, x + segment_width);
370 x += segment_width;
372 rtl_segments_.clear();
375 // Finishes the size calculations of the last Line in |lines_|. Adds a new
376 // Line to the back of |lines_|.
377 void AdvanceLine() {
378 if (!lines_.empty()) {
379 Line* line = &lines_.back();
380 // TODO(ckocagil): Determine optimal multiline height behavior.
381 if (line_ascent_ + line_descent_ == 0) {
382 line_ascent_ = min_baseline_;
383 line_descent_ = min_height_ - min_baseline_;
385 // Set the single-line mode Line's metrics to be at least
386 // |RenderText::font_list()| to not break the current single-line code.
387 line_ascent_ = std::max(line_ascent_, min_baseline_);
388 line_descent_ = std::max(line_descent_, min_height_ - min_baseline_);
390 line->baseline = line_ascent_;
391 line->size.set_height(line_ascent_ + line_descent_);
392 line->preceding_heights = total_size_.height();
393 const Size line_size(ToCeiledSize(line->size));
394 total_size_.set_height(total_size_.height() + line_size.height());
395 total_size_.set_width(std::max(total_size_.width(), line_size.width()));
397 line_x_ = 0;
398 line_ascent_ = 0;
399 line_descent_ = 0;
400 lines_.push_back(Line());
403 // Adds a new segment with the given properties to |lines_.back()|.
404 void AddSegment(int run_index, Range char_range, int width) {
405 if (char_range.is_empty()) {
406 DCHECK_EQ(width, 0);
407 return;
409 const TextRun* run = runs_[run_index];
410 line_ascent_ = std::max(line_ascent_, run->font.GetBaseline());
411 line_descent_ = std::max(line_descent_,
412 run->font.GetHeight() - run->font.GetBaseline());
414 LineSegment segment;
415 segment.run = run_index;
416 segment.char_range = char_range;
417 segment.x_range = Range(text_x_, text_x_ + width);
419 Line* line = &lines_.back();
420 line->segments.push_back(segment);
421 line->size.set_width(line->size.width() + segment.x_range.length());
422 if (run->script_analysis.fRTL) {
423 rtl_segments_.push_back(SegmentHandle(lines_.size() - 1,
424 line->segments.size() - 1));
425 // If this is the last segment of an RTL run, reprocess the text-space x
426 // ranges of all segments from the run.
427 if (char_range.end() == run->range.end())
428 UpdateRTLSegmentRanges();
430 text_x_ += width;
431 line_x_ += width;
434 const int max_width_;
435 const int min_baseline_;
436 const int min_height_;
437 const bool multiline_;
438 const wchar_t* text_;
439 const BreakList<size_t>* const words_;
440 const ScopedVector<TextRun>& runs_;
442 // Stores the resulting lines.
443 std::vector<Line> lines_;
445 // Text space and line space x coordinates of the next segment to be added.
446 int text_x_;
447 int line_x_;
449 // Size of the multiline text, not including the currently processed line.
450 Size total_size_;
452 // Ascent and descent values of the current line, |lines_.back()|.
453 int line_ascent_;
454 int line_descent_;
456 // The current RTL run segments, to be applied by |UpdateRTLSegmentRanges()|.
457 std::vector<SegmentHandle> rtl_segments_;
459 DISALLOW_COPY_AND_ASSIGN(LineBreaker);
462 } // namespace internal
464 // static
465 HDC RenderTextWin::cached_hdc_ = NULL;
467 // static
468 std::map<std::string, Font> RenderTextWin::successful_substitute_fonts_;
470 RenderTextWin::RenderTextWin() : RenderText(), needs_layout_(false) {
471 set_truncate_length(kMaxUniscribeTextLength);
472 memset(&script_control_, 0, sizeof(script_control_));
473 memset(&script_state_, 0, sizeof(script_state_));
474 MoveCursorTo(EdgeSelectionModel(CURSOR_LEFT));
477 RenderTextWin::~RenderTextWin() {}
479 Size RenderTextWin::GetStringSize() {
480 EnsureLayout();
481 return multiline_string_size_;
484 SelectionModel RenderTextWin::FindCursorPosition(const Point& point) {
485 if (text().empty())
486 return SelectionModel();
488 EnsureLayout();
489 // Find the run that contains the point and adjust the argument location.
490 int x = ToTextPoint(point).x();
491 size_t run_index = GetRunContainingXCoord(x);
492 if (run_index >= runs_.size())
493 return EdgeSelectionModel((x < 0) ? CURSOR_LEFT : CURSOR_RIGHT);
494 internal::TextRun* run = runs_[run_index];
496 int position = 0, trailing = 0;
497 HRESULT hr = ScriptXtoCP(x - run->preceding_run_widths,
498 run->range.length(),
499 run->glyph_count,
500 run->logical_clusters.get(),
501 run->visible_attributes.get(),
502 run->advance_widths.get(),
503 &(run->script_analysis),
504 &position,
505 &trailing);
506 DCHECK(SUCCEEDED(hr));
507 DCHECK_GE(trailing, 0);
508 position += run->range.start();
509 const size_t cursor = LayoutIndexToTextIndex(position + trailing);
510 DCHECK_LE(cursor, text().length());
511 return SelectionModel(cursor, trailing ? CURSOR_BACKWARD : CURSOR_FORWARD);
514 std::vector<RenderText::FontSpan> RenderTextWin::GetFontSpansForTesting() {
515 EnsureLayout();
517 std::vector<RenderText::FontSpan> spans;
518 for (size_t i = 0; i < runs_.size(); ++i) {
519 spans.push_back(RenderText::FontSpan(runs_[i]->font,
520 Range(LayoutIndexToTextIndex(runs_[i]->range.start()),
521 LayoutIndexToTextIndex(runs_[i]->range.end()))));
524 return spans;
527 int RenderTextWin::GetLayoutTextBaseline() {
528 EnsureLayout();
529 return lines()[0].baseline;
532 SelectionModel RenderTextWin::AdjacentCharSelectionModel(
533 const SelectionModel& selection,
534 VisualCursorDirection direction) {
535 DCHECK(!needs_layout_);
536 internal::TextRun* run;
537 size_t run_index = GetRunContainingCaret(selection);
538 if (run_index >= runs_.size()) {
539 // The cursor is not in any run: we're at the visual and logical edge.
540 SelectionModel edge = EdgeSelectionModel(direction);
541 if (edge.caret_pos() == selection.caret_pos())
542 return edge;
543 int visual_index = (direction == CURSOR_RIGHT) ? 0 : runs_.size() - 1;
544 run = runs_[visual_to_logical_[visual_index]];
545 } else {
546 // If the cursor is moving within the current run, just move it by one
547 // grapheme in the appropriate direction.
548 run = runs_[run_index];
549 size_t caret = selection.caret_pos();
550 bool forward_motion =
551 run->script_analysis.fRTL == (direction == CURSOR_LEFT);
552 if (forward_motion) {
553 if (caret < LayoutIndexToTextIndex(run->range.end())) {
554 caret = IndexOfAdjacentGrapheme(caret, CURSOR_FORWARD);
555 return SelectionModel(caret, CURSOR_BACKWARD);
557 } else {
558 if (caret > LayoutIndexToTextIndex(run->range.start())) {
559 caret = IndexOfAdjacentGrapheme(caret, CURSOR_BACKWARD);
560 return SelectionModel(caret, CURSOR_FORWARD);
563 // The cursor is at the edge of a run; move to the visually adjacent run.
564 int visual_index = logical_to_visual_[run_index];
565 visual_index += (direction == CURSOR_LEFT) ? -1 : 1;
566 if (visual_index < 0 || visual_index >= static_cast<int>(runs_.size()))
567 return EdgeSelectionModel(direction);
568 run = runs_[visual_to_logical_[visual_index]];
570 bool forward_motion = run->script_analysis.fRTL == (direction == CURSOR_LEFT);
571 return forward_motion ? FirstSelectionModelInsideRun(run) :
572 LastSelectionModelInsideRun(run);
575 // TODO(msw): Implement word breaking for Windows.
576 SelectionModel RenderTextWin::AdjacentWordSelectionModel(
577 const SelectionModel& selection,
578 VisualCursorDirection direction) {
579 if (obscured())
580 return EdgeSelectionModel(direction);
582 base::i18n::BreakIterator iter(text(), base::i18n::BreakIterator::BREAK_WORD);
583 bool success = iter.Init();
584 DCHECK(success);
585 if (!success)
586 return selection;
588 size_t pos;
589 if (direction == CURSOR_RIGHT) {
590 pos = std::min(selection.caret_pos() + 1, text().length());
591 while (iter.Advance()) {
592 pos = iter.pos();
593 if (iter.IsWord() && pos > selection.caret_pos())
594 break;
596 } else { // direction == CURSOR_LEFT
597 // Notes: We always iterate words from the beginning.
598 // This is probably fast enough for our usage, but we may
599 // want to modify WordIterator so that it can start from the
600 // middle of string and advance backwards.
601 pos = std::max<int>(selection.caret_pos() - 1, 0);
602 while (iter.Advance()) {
603 if (iter.IsWord()) {
604 size_t begin = iter.pos() - iter.GetString().length();
605 if (begin == selection.caret_pos()) {
606 // The cursor is at the beginning of a word.
607 // Move to previous word.
608 break;
609 } else if (iter.pos() >= selection.caret_pos()) {
610 // The cursor is in the middle or at the end of a word.
611 // Move to the top of current word.
612 pos = begin;
613 break;
614 } else {
615 pos = iter.pos() - iter.GetString().length();
620 return SelectionModel(pos, CURSOR_FORWARD);
623 Range RenderTextWin::GetGlyphBounds(size_t index) {
624 EnsureLayout();
625 const size_t run_index =
626 GetRunContainingCaret(SelectionModel(index, CURSOR_FORWARD));
627 // Return edge bounds if the index is invalid or beyond the layout text size.
628 if (run_index >= runs_.size())
629 return Range(string_width_);
630 internal::TextRun* run = runs_[run_index];
631 const size_t layout_index = TextIndexToLayoutIndex(index);
632 return Range(GetGlyphXBoundary(run, layout_index, false),
633 GetGlyphXBoundary(run, layout_index, true));
636 std::vector<Rect> RenderTextWin::GetSubstringBounds(const Range& range) {
637 DCHECK(!needs_layout_);
638 DCHECK(Range(0, text().length()).Contains(range));
639 Range layout_range(TextIndexToLayoutIndex(range.start()),
640 TextIndexToLayoutIndex(range.end()));
641 DCHECK(Range(0, GetLayoutText().length()).Contains(layout_range));
643 std::vector<Rect> rects;
644 if (layout_range.is_empty())
645 return rects;
646 std::vector<Range> bounds;
648 // Add a Range for each run/selection intersection.
649 // TODO(msw): The bounds should probably not always be leading the range ends.
650 for (size_t i = 0; i < runs_.size(); ++i) {
651 const internal::TextRun* run = runs_[visual_to_logical_[i]];
652 Range intersection = run->range.Intersect(layout_range);
653 if (intersection.IsValid()) {
654 DCHECK(!intersection.is_reversed());
655 Range range_x(GetGlyphXBoundary(run, intersection.start(), false),
656 GetGlyphXBoundary(run, intersection.end(), false));
657 if (range_x.is_empty())
658 continue;
659 range_x = Range(range_x.GetMin(), range_x.GetMax());
660 // Union this with the last range if they're adjacent.
661 DCHECK(bounds.empty() || bounds.back().GetMax() <= range_x.GetMin());
662 if (!bounds.empty() && bounds.back().GetMax() == range_x.GetMin()) {
663 range_x = Range(bounds.back().GetMin(), range_x.GetMax());
664 bounds.pop_back();
666 bounds.push_back(range_x);
669 for (size_t i = 0; i < bounds.size(); ++i) {
670 std::vector<Rect> current_rects = TextBoundsToViewBounds(bounds[i]);
671 rects.insert(rects.end(), current_rects.begin(), current_rects.end());
673 return rects;
676 size_t RenderTextWin::TextIndexToLayoutIndex(size_t index) const {
677 DCHECK_LE(index, text().length());
678 ptrdiff_t i = obscured() ? UTF16IndexToOffset(text(), 0, index) : index;
679 CHECK_GE(i, 0);
680 // Clamp layout indices to the length of the text actually used for layout.
681 return std::min<size_t>(GetLayoutText().length(), i);
684 size_t RenderTextWin::LayoutIndexToTextIndex(size_t index) const {
685 if (!obscured())
686 return index;
688 DCHECK_LE(index, GetLayoutText().length());
689 const size_t text_index = UTF16OffsetToIndex(text(), 0, index);
690 DCHECK_LE(text_index, text().length());
691 return text_index;
694 bool RenderTextWin::IsValidCursorIndex(size_t index) {
695 if (index == 0 || index == text().length())
696 return true;
697 if (!IsValidLogicalIndex(index))
698 return false;
699 EnsureLayout();
700 // Disallow indices amid multi-character graphemes by checking glyph bounds.
701 // These characters are not surrogate-pairs, but may yield a single glyph:
702 // \x0915\x093f - (ki) - one of many Devanagari biconsonantal conjuncts.
703 // \x0e08\x0e33 - (cho chan + sara am) - a Thai consonant and vowel pair.
704 return GetGlyphBounds(index) != GetGlyphBounds(index - 1);
707 void RenderTextWin::ResetLayout() {
708 // Layout is performed lazily as needed for drawing/metrics.
709 needs_layout_ = true;
712 void RenderTextWin::EnsureLayout() {
713 if (needs_layout_) {
714 // TODO(msw): Skip complex processing if ScriptIsComplex returns false.
715 ItemizeLogicalText();
716 if (!runs_.empty())
717 LayoutVisualText();
718 needs_layout_ = false;
719 std::vector<internal::Line> lines;
720 set_lines(&lines);
723 // Compute lines if they're not valid. This is separate from the layout steps
724 // above to avoid text layout and shaping when we resize |display_rect_|.
725 if (lines().empty()) {
726 DCHECK(!needs_layout_);
727 std::vector<internal::Line> lines;
728 internal::LineBreaker line_breaker(display_rect().width() - 1,
729 font_list().GetBaseline(),
730 font_list().GetHeight(), multiline(),
731 GetLayoutText().c_str(),
732 multiline() ? &GetLineBreaks() : NULL,
733 runs_);
734 for (size_t i = 0; i < runs_.size(); ++i)
735 line_breaker.AddRun(visual_to_logical_[i]);
736 line_breaker.Finalize(&lines, &multiline_string_size_);
737 DCHECK(!lines.empty());
738 #ifndef NDEBUG
739 CheckLineIntegrity(lines, runs_);
740 #endif
741 set_lines(&lines);
745 void RenderTextWin::DrawVisualText(Canvas* canvas) {
746 DCHECK(!needs_layout_);
747 DCHECK(!lines().empty());
749 std::vector<SkPoint> pos;
751 internal::SkiaTextRenderer renderer(canvas);
752 ApplyFadeEffects(&renderer);
753 ApplyTextShadows(&renderer);
755 renderer.SetFontRenderParams(
756 font_list().GetPrimaryFont().GetFontRenderParams(),
757 background_is_transparent());
759 ApplyCompositionAndSelectionStyles();
761 for (size_t i = 0; i < lines().size(); ++i) {
762 const internal::Line& line = lines()[i];
763 const Vector2d line_offset = GetLineOffset(i);
765 // Skip painting empty lines or lines outside the display rect area.
766 if (!display_rect().Intersects(Rect(PointAtOffsetFromOrigin(line_offset),
767 ToCeiledSize(line.size))))
768 continue;
770 const Vector2d text_offset = line_offset + Vector2d(0, line.baseline);
771 int preceding_segment_widths = 0;
773 for (size_t j = 0; j < line.segments.size(); ++j) {
774 const internal::LineSegment* segment = &line.segments[j];
775 const int segment_width = segment->x_range.length();
776 const internal::TextRun* run = runs_[segment->run];
777 DCHECK(!segment->char_range.is_empty());
778 DCHECK(run->range.Contains(segment->char_range));
779 Range glyph_range = CharRangeToGlyphRange(*run, segment->char_range);
780 DCHECK(!glyph_range.is_empty());
781 // Skip painting segments outside the display rect area.
782 if (!multiline()) {
783 const Rect segment_bounds(PointAtOffsetFromOrigin(line_offset) +
784 Vector2d(preceding_segment_widths, 0),
785 Size(segment_width, line.size.height()));
786 if (!display_rect().Intersects(segment_bounds)) {
787 preceding_segment_widths += segment_width;
788 continue;
792 // |pos| contains the positions of glyphs. An extra terminal |pos| entry
793 // is added to simplify width calculations.
794 int segment_x = preceding_segment_widths;
795 pos.resize(glyph_range.length() + 1);
796 for (size_t k = glyph_range.start(); k < glyph_range.end(); ++k) {
797 pos[k - glyph_range.start()].set(
798 SkIntToScalar(text_offset.x() + run->offsets[k].du + segment_x),
799 SkIntToScalar(text_offset.y() - run->offsets[k].dv));
800 segment_x += run->advance_widths[k];
802 pos.back().set(SkIntToScalar(text_offset.x() + segment_x),
803 SkIntToScalar(text_offset.y()));
805 renderer.SetTextSize(run->font.GetFontSize());
806 renderer.SetFontFamilyWithStyle(run->font.GetFontName(), run->font_style);
808 for (BreakList<SkColor>::const_iterator it =
809 colors().GetBreak(segment->char_range.start());
810 it != colors().breaks().end() &&
811 it->first < segment->char_range.end();
812 ++it) {
813 const Range intersection =
814 colors().GetRange(it).Intersect(segment->char_range);
815 const Range colored_glyphs = CharRangeToGlyphRange(*run, intersection);
816 // The range may be empty if a portion of a multi-character grapheme is
817 // selected, yielding two colors for a single glyph. For now, this just
818 // paints the glyph with a single style, but it should paint it twice,
819 // clipped according to selection bounds. See http://crbug.com/366786
820 if (colored_glyphs.is_empty())
821 continue;
822 DCHECK(glyph_range.Contains(colored_glyphs));
823 const SkPoint& start_pos =
824 pos[colored_glyphs.start() - glyph_range.start()];
825 const SkPoint& end_pos =
826 pos[colored_glyphs.end() - glyph_range.start()];
828 renderer.SetForegroundColor(it->second);
829 renderer.DrawPosText(&start_pos, &run->glyphs[colored_glyphs.start()],
830 colored_glyphs.length());
831 renderer.DrawDecorations(start_pos.x(), text_offset.y(),
832 SkScalarCeilToInt(end_pos.x() - start_pos.x()),
833 run->underline, run->strike,
834 run->diagonal_strike);
837 preceding_segment_widths += segment_width;
840 renderer.EndDiagonalStrike();
843 UndoCompositionAndSelectionStyles();
846 void RenderTextWin::ItemizeLogicalText() {
847 runs_.clear();
848 string_width_ = 0;
849 multiline_string_size_ = Size();
851 // Set Uniscribe's base text direction.
852 script_state_.uBidiLevel =
853 (GetTextDirection() == base::i18n::RIGHT_TO_LEFT) ? 1 : 0;
855 const base::string16& layout_text = GetLayoutText();
856 if (layout_text.empty())
857 return;
859 HRESULT hr = E_OUTOFMEMORY;
860 int script_items_count = 0;
861 std::vector<SCRIPT_ITEM> script_items;
862 const size_t layout_text_length = layout_text.length();
863 // Ensure that |kMaxRuns| is attempted and the loop terminates afterward.
864 for (size_t runs = kGuessRuns; hr == E_OUTOFMEMORY && runs <= kMaxRuns;
865 runs = std::max(runs + 1, std::min(runs * 2, kMaxRuns))) {
866 // Derive the array of Uniscribe script items from the logical text.
867 // ScriptItemize always adds a terminal array item so that the length of
868 // the last item can be derived from the terminal SCRIPT_ITEM::iCharPos.
869 script_items.resize(runs);
870 hr = ScriptItemize(layout_text.c_str(), layout_text_length, runs - 1,
871 &script_control_, &script_state_, &script_items[0],
872 &script_items_count);
874 DCHECK(SUCCEEDED(hr));
875 if (!SUCCEEDED(hr) || script_items_count <= 0)
876 return;
878 // Temporarily apply composition underlines and selection colors.
879 ApplyCompositionAndSelectionStyles();
881 // Build the list of runs from the script items and ranged styles. Use an
882 // empty color BreakList to avoid breaking runs at color boundaries.
883 BreakList<SkColor> empty_colors;
884 empty_colors.SetMax(layout_text_length);
885 internal::StyleIterator style(empty_colors, styles());
886 SCRIPT_ITEM* script_item = &script_items[0];
887 const size_t max_run_length = kMaxGlyphs / 2;
888 for (size_t run_break = 0; run_break < layout_text_length;) {
889 internal::TextRun* run = new internal::TextRun();
890 run->range.set_start(run_break);
891 run->font = font_list().GetPrimaryFont();
892 run->font_style = (style.style(BOLD) ? Font::BOLD : 0) |
893 (style.style(ITALIC) ? Font::ITALIC : 0);
894 DeriveFontIfNecessary(run->font.GetFontSize(), run->font.GetHeight(),
895 run->font_style, &run->font);
896 run->strike = style.style(STRIKE);
897 run->diagonal_strike = style.style(DIAGONAL_STRIKE);
898 run->underline = style.style(UNDERLINE);
899 run->script_analysis = script_item->a;
901 // Find the next break and advance the iterators as needed.
902 const size_t script_item_break = (script_item + 1)->iCharPos;
903 run_break = std::min(script_item_break,
904 TextIndexToLayoutIndex(style.GetRange().end()));
906 // Clamp run lengths to avoid exceeding the maximum supported glyph count.
907 if ((run_break - run->range.start()) > max_run_length) {
908 run_break = run->range.start() + max_run_length;
909 if (!IsValidCodePointIndex(layout_text, run_break))
910 --run_break;
913 // Break runs adjacent to character substrings in certain code blocks.
914 // This avoids using their fallback fonts for more characters than needed,
915 // in cases like "\x25B6 Media Title", etc. http://crbug.com/278913
916 if (run_break > run->range.start()) {
917 run_break =
918 FindUnusualCharacter(layout_text, run->range.start(), run_break);
921 DCHECK(IsValidCodePointIndex(layout_text, run_break));
923 style.UpdatePosition(LayoutIndexToTextIndex(run_break));
924 if (script_item_break == run_break)
925 script_item++;
926 run->range.set_end(run_break);
927 runs_.push_back(run);
930 // Undo the temporarily applied composition underlines and selection colors.
931 UndoCompositionAndSelectionStyles();
934 void RenderTextWin::LayoutVisualText() {
935 DCHECK(!runs_.empty());
937 if (!cached_hdc_)
938 cached_hdc_ = CreateCompatibleDC(NULL);
940 HRESULT hr = E_FAIL;
941 // Ensure ascent and descent are not smaller than ones of the font list.
942 // Keep them tall enough to draw often-used characters.
943 // For example, if a text field contains a Japanese character, which is
944 // smaller than Latin ones, and then later a Latin one is inserted, this
945 // ensures that the text baseline does not shift.
946 int ascent = font_list().GetBaseline();
947 int descent = font_list().GetHeight() - font_list().GetBaseline();
948 for (size_t i = 0; i < runs_.size(); ++i) {
949 internal::TextRun* run = runs_[i];
950 LayoutTextRun(run);
952 ascent = std::max(ascent, run->font.GetBaseline());
953 descent = std::max(descent,
954 run->font.GetHeight() - run->font.GetBaseline());
956 if (run->glyph_count > 0) {
957 run->advance_widths.reset(new int[run->glyph_count]);
958 run->offsets.reset(new GOFFSET[run->glyph_count]);
959 hr = ScriptPlace(cached_hdc_,
960 &run->script_cache,
961 run->glyphs.get(),
962 run->glyph_count,
963 run->visible_attributes.get(),
964 &(run->script_analysis),
965 run->advance_widths.get(),
966 run->offsets.get(),
967 &(run->abc_widths));
968 DCHECK(SUCCEEDED(hr));
972 // Build the array of bidirectional embedding levels.
973 scoped_ptr<BYTE[]> levels(new BYTE[runs_.size()]);
974 for (size_t i = 0; i < runs_.size(); ++i)
975 levels[i] = runs_[i]->script_analysis.s.uBidiLevel;
977 // Get the maps between visual and logical run indices.
978 visual_to_logical_.reset(new int[runs_.size()]);
979 logical_to_visual_.reset(new int[runs_.size()]);
980 hr = ScriptLayout(runs_.size(),
981 levels.get(),
982 visual_to_logical_.get(),
983 logical_to_visual_.get());
984 DCHECK(SUCCEEDED(hr));
986 // Precalculate run width information.
987 size_t preceding_run_widths = 0;
988 for (size_t i = 0; i < runs_.size(); ++i) {
989 internal::TextRun* run = runs_[visual_to_logical_[i]];
990 run->preceding_run_widths = preceding_run_widths;
991 const ABC& abc = run->abc_widths;
992 run->width = abc.abcA + abc.abcB + abc.abcC;
993 preceding_run_widths += run->width;
995 string_width_ = preceding_run_widths;
998 void RenderTextWin::LayoutTextRun(internal::TextRun* run) {
999 const size_t run_length = run->range.length();
1000 const wchar_t* run_text = &(GetLayoutText()[run->range.start()]);
1001 Font original_font = run->font;
1003 run->logical_clusters.reset(new WORD[run_length]);
1005 // Try shaping with |original_font|.
1006 Font current_font = original_font;
1007 int missing_count = CountCharsWithMissingGlyphs(run,
1008 ShapeTextRunWithFont(run, current_font));
1009 if (missing_count == 0)
1010 return;
1012 // Keep track of the font that is able to display the greatest number of
1013 // characters for which ScriptShape() returned S_OK. This font will be used
1014 // in the case where no font is able to display the entire run.
1015 int best_partial_font_missing_char_count = missing_count;
1016 Font best_partial_font = current_font;
1018 // Try to shape with the cached font from previous runs, if any.
1019 std::map<std::string, Font>::const_iterator it =
1020 successful_substitute_fonts_.find(original_font.GetFontName());
1021 if (it != successful_substitute_fonts_.end()) {
1022 current_font = it->second;
1023 missing_count = CountCharsWithMissingGlyphs(run,
1024 ShapeTextRunWithFont(run, current_font));
1025 if (missing_count == 0)
1026 return;
1027 if (missing_count < best_partial_font_missing_char_count) {
1028 best_partial_font_missing_char_count = missing_count;
1029 best_partial_font = current_font;
1033 // Try finding a fallback font using a meta file.
1034 // TODO(msw|asvitkine): Support RenderText's font_list()?
1035 if (GetUniscribeFallbackFont(original_font, run_text, run_length,
1036 &current_font)) {
1037 missing_count = CountCharsWithMissingGlyphs(run,
1038 ShapeTextRunWithFont(run, current_font));
1039 if (missing_count == 0) {
1040 successful_substitute_fonts_[original_font.GetFontName()] = current_font;
1041 return;
1043 if (missing_count < best_partial_font_missing_char_count) {
1044 best_partial_font_missing_char_count = missing_count;
1045 best_partial_font = current_font;
1049 // Try fonts in the fallback list except the first, which is |original_font|.
1050 std::vector<std::string> fonts =
1051 GetFallbackFontFamilies(original_font.GetFontName());
1052 for (size_t i = 1; i < fonts.size(); ++i) {
1053 missing_count = CountCharsWithMissingGlyphs(run,
1054 ShapeTextRunWithFont(run, Font(fonts[i], original_font.GetFontSize())));
1055 if (missing_count == 0) {
1056 successful_substitute_fonts_[original_font.GetFontName()] = current_font;
1057 return;
1059 if (missing_count < best_partial_font_missing_char_count) {
1060 best_partial_font_missing_char_count = missing_count;
1061 best_partial_font = current_font;
1065 // If a font was able to partially display the run, use that now.
1066 if (best_partial_font_missing_char_count < static_cast<int>(run_length)) {
1067 // Re-shape the run only if |best_partial_font| differs from the last font.
1068 if (best_partial_font.GetNativeFont() != run->font.GetNativeFont())
1069 ShapeTextRunWithFont(run, best_partial_font);
1070 return;
1073 // If no font was able to partially display the run, replace all glyphs
1074 // with |wgDefault| from the original font to ensure to they don't hold
1075 // garbage values.
1076 // First, clear the cache and select the original font on the HDC.
1077 ScriptFreeCache(&run->script_cache);
1078 run->font = original_font;
1079 SelectObject(cached_hdc_, run->font.GetNativeFont());
1081 // Now, get the font's properties.
1082 SCRIPT_FONTPROPERTIES properties;
1083 memset(&properties, 0, sizeof(properties));
1084 properties.cBytes = sizeof(properties);
1085 HRESULT hr = ScriptGetFontProperties(cached_hdc_, &run->script_cache,
1086 &properties);
1088 // The initial values for the "missing" glyph and the space glyph are taken
1089 // from the recommendations section of the OpenType spec:
1090 // https://www.microsoft.com/typography/otspec/recom.htm
1091 WORD missing_glyph = 0;
1092 WORD space_glyph = 3;
1093 if (hr == S_OK) {
1094 missing_glyph = properties.wgDefault;
1095 space_glyph = properties.wgBlank;
1098 // Finally, initialize |glyph_count|, |glyphs|, |visible_attributes| and
1099 // |logical_clusters| on the run (since they may not have been set yet).
1100 run->glyph_count = run_length;
1101 memset(run->visible_attributes.get(), 0,
1102 run->glyph_count * sizeof(SCRIPT_VISATTR));
1103 for (int i = 0; i < run->glyph_count; ++i)
1104 run->glyphs[i] = IsWhitespace(run_text[i]) ? space_glyph : missing_glyph;
1105 for (size_t i = 0; i < run_length; ++i) {
1106 run->logical_clusters[i] = run->script_analysis.fRTL ?
1107 run_length - 1 - i : i;
1110 // TODO(msw): Don't use SCRIPT_UNDEFINED. Apparently Uniscribe can
1111 // crash on certain surrogate pairs with SCRIPT_UNDEFINED.
1112 // See https://bugzilla.mozilla.org/show_bug.cgi?id=341500
1113 // And http://maxradi.us/documents/uniscribe/
1114 run->script_analysis.eScript = SCRIPT_UNDEFINED;
1117 HRESULT RenderTextWin::ShapeTextRunWithFont(internal::TextRun* run,
1118 const Font& font) {
1119 // Update the run's font only if necessary. If the two fonts wrap the same
1120 // PlatformFontWin object, their native fonts will have the same value.
1121 if (run->font.GetNativeFont() != font.GetNativeFont()) {
1122 const int font_size = run->font.GetFontSize();
1123 const int font_height = run->font.GetHeight();
1124 run->font = font;
1125 DeriveFontIfNecessary(font_size, font_height, run->font_style, &run->font);
1126 ScriptFreeCache(&run->script_cache);
1129 // Select the font desired for glyph generation.
1130 SelectObject(cached_hdc_, run->font.GetNativeFont());
1132 HRESULT hr = E_OUTOFMEMORY;
1133 const size_t run_length = run->range.length();
1134 const wchar_t* run_text = &(GetLayoutText()[run->range.start()]);
1135 // Guess the expected number of glyphs from the length of the run.
1136 // MSDN suggests this at http://msdn.microsoft.com/en-us/library/dd368564.aspx
1137 size_t max_glyphs = static_cast<size_t>(1.5 * run_length + 16);
1138 while (hr == E_OUTOFMEMORY && max_glyphs <= kMaxGlyphs) {
1139 run->glyph_count = 0;
1140 run->glyphs.reset(new WORD[max_glyphs]);
1141 run->visible_attributes.reset(new SCRIPT_VISATTR[max_glyphs]);
1142 hr = ScriptShape(cached_hdc_, &run->script_cache, run_text, run_length,
1143 max_glyphs, &run->script_analysis, run->glyphs.get(),
1144 run->logical_clusters.get(), run->visible_attributes.get(),
1145 &run->glyph_count);
1146 // Ensure that |kMaxGlyphs| is attempted and the loop terminates afterward.
1147 max_glyphs = std::max(max_glyphs + 1, std::min(max_glyphs * 2, kMaxGlyphs));
1149 return hr;
1152 int RenderTextWin::CountCharsWithMissingGlyphs(internal::TextRun* run,
1153 HRESULT shaping_result) const {
1154 if (shaping_result != S_OK) {
1155 DCHECK_EQ(shaping_result, USP_E_SCRIPT_NOT_IN_FONT);
1156 return INT_MAX;
1159 // If |hr| is S_OK, there could still be missing glyphs in the output.
1160 // http://msdn.microsoft.com/en-us/library/windows/desktop/dd368564.aspx
1161 int chars_not_missing_glyphs = 0;
1162 SCRIPT_FONTPROPERTIES properties;
1163 memset(&properties, 0, sizeof(properties));
1164 properties.cBytes = sizeof(properties);
1165 ScriptGetFontProperties(cached_hdc_, &run->script_cache, &properties);
1167 const wchar_t* run_text = &(GetLayoutText()[run->range.start()]);
1168 for (size_t char_index = 0; char_index < run->range.length(); ++char_index) {
1169 const int glyph_index = run->logical_clusters[char_index];
1170 DCHECK_GE(glyph_index, 0);
1171 DCHECK_LT(glyph_index, run->glyph_count);
1173 if (run->glyphs[glyph_index] == properties.wgDefault)
1174 continue;
1176 // Windows Vista sometimes returns glyphs equal to wgBlank (instead of
1177 // wgDefault), with fZeroWidth set. Treat such cases as having missing
1178 // glyphs if the corresponding character is not whitespace.
1179 // See: http://crbug.com/125629
1180 if (run->glyphs[glyph_index] == properties.wgBlank &&
1181 run->visible_attributes[glyph_index].fZeroWidth &&
1182 !IsWhitespace(run_text[char_index]) &&
1183 !IsUnicodeBidiControlCharacter(run_text[char_index])) {
1184 continue;
1187 ++chars_not_missing_glyphs;
1190 DCHECK_LE(chars_not_missing_glyphs, static_cast<int>(run->range.length()));
1191 return run->range.length() - chars_not_missing_glyphs;
1194 size_t RenderTextWin::GetRunContainingCaret(const SelectionModel& caret) const {
1195 DCHECK(!needs_layout_);
1196 size_t layout_position = TextIndexToLayoutIndex(caret.caret_pos());
1197 LogicalCursorDirection affinity = caret.caret_affinity();
1198 for (size_t run = 0; run < runs_.size(); ++run)
1199 if (RangeContainsCaret(runs_[run]->range, layout_position, affinity))
1200 return run;
1201 return runs_.size();
1204 size_t RenderTextWin::GetRunContainingXCoord(int x) const {
1205 DCHECK(!needs_layout_);
1206 // Find the text run containing the argument point (assumed already offset).
1207 for (size_t run = 0; run < runs_.size(); ++run) {
1208 if ((runs_[run]->preceding_run_widths <= x) &&
1209 ((runs_[run]->preceding_run_widths + runs_[run]->width) > x))
1210 return run;
1212 return runs_.size();
1215 SelectionModel RenderTextWin::FirstSelectionModelInsideRun(
1216 const internal::TextRun* run) {
1217 size_t position = LayoutIndexToTextIndex(run->range.start());
1218 position = IndexOfAdjacentGrapheme(position, CURSOR_FORWARD);
1219 return SelectionModel(position, CURSOR_BACKWARD);
1222 SelectionModel RenderTextWin::LastSelectionModelInsideRun(
1223 const internal::TextRun* run) {
1224 size_t position = LayoutIndexToTextIndex(run->range.end());
1225 position = IndexOfAdjacentGrapheme(position, CURSOR_BACKWARD);
1226 return SelectionModel(position, CURSOR_FORWARD);
1229 RenderText* RenderText::CreateNativeInstance() {
1230 return new RenderTextWin;
1233 } // namespace gfx