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@ r27283:895ef9174a75
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Location: cpp/openttd-patchpack/source/src/os/windows/string_uniscribe.cpp
r27283:895ef9174a75
21.7 KiB
text/x-c
Change: include fmt.h C++ headers in stdafx.h
This to prevent compilation issues between runs with and without precompiled
headers. Also remove the headers from the rest of the code base as they are
not needed there anymore, although they do relatively little harm.
This to prevent compilation issues between runs with and without precompiled
headers. Also remove the headers from the rest of the code base as they are
not needed there anymore, although they do relatively little harm.
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* This file is part of OpenTTD.
* OpenTTD is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, version 2.
* OpenTTD is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
* See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with OpenTTD. If not, see <http://www.gnu.org/licenses/>.
*/
/** @file string_uniscribe.cpp Functions related to laying out text on Win32. */
#include "../../stdafx.h"
#include "../../debug.h"
#include "string_uniscribe.h"
#include "../../language.h"
#include "../../strings_func.h"
#include "../../string_func.h"
#include "../../table/control_codes.h"
#include "../../zoom_func.h"
#include "win32.h"
#include <windows.h>
#include <usp10.h>
#include "../../safeguards.h"
#ifdef _MSC_VER
# pragma comment(lib, "usp10")
#endif
/** Uniscribe cache for internal font information, cleared when OTTD changes fonts. */
static SCRIPT_CACHE _script_cache[FS_END];
/**
* Contains all information about a run of characters. A run are consecutive
* characters that share a single font and language.
*/
struct UniscribeRun {
int pos;
int len;
Font *font;
std::vector<GlyphID> ft_glyphs;
SCRIPT_ANALYSIS sa;
std::vector<WORD> char_to_glyph;
std::vector<SCRIPT_VISATTR> vis_attribs;
std::vector<WORD> glyphs;
std::vector<int> advances;
std::vector<GOFFSET> offsets;
int total_advance;
UniscribeRun(int pos, int len, Font *font, SCRIPT_ANALYSIS &sa) : pos(pos), len(len), font(font), sa(sa) {}
};
/** Break a string into language formatting ranges. */
static std::vector<SCRIPT_ITEM> UniscribeItemizeString(UniscribeParagraphLayoutFactory::CharType *buff, int32 length);
/** Generate and place glyphs for a run of characters. */
static bool UniscribeShapeRun(const UniscribeParagraphLayoutFactory::CharType *buff, UniscribeRun &range);
/**
* Wrapper for doing layouts with Uniscribe.
*/
class UniscribeParagraphLayout : public ParagraphLayouter {
private:
const UniscribeParagraphLayoutFactory::CharType *text_buffer;
std::vector<UniscribeRun> ranges; ///< All runs of the text.
std::vector<UniscribeRun>::iterator cur_range; ///< The next run to be output.
int cur_range_offset = 0; ///< Offset from the start of the current run from where to output.
public:
/** Visual run contains data about the bit of text with the same font. */
class UniscribeVisualRun : public ParagraphLayouter::VisualRun {
private:
std::vector<GlyphID> glyphs;
std::vector<float> positions;
std::vector<WORD> char_to_glyph;
int start_pos;
int total_advance;
int num_glyphs;
Font *font;
mutable int *glyph_to_char = nullptr;
public:
UniscribeVisualRun(const UniscribeRun &range, int x);
UniscribeVisualRun(UniscribeVisualRun &&other) noexcept;
~UniscribeVisualRun() override
{
free(this->glyph_to_char);
}
const GlyphID *GetGlyphs() const override { return &this->glyphs[0]; }
const float *GetPositions() const override { return &this->positions[0]; }
const int *GetGlyphToCharMap() const override;
const Font *GetFont() const override { return this->font; }
int GetLeading() const override { return this->font->fc->GetHeight(); }
int GetGlyphCount() const override { return this->num_glyphs; }
int GetAdvance() const { return this->total_advance; }
};
/** A single line worth of VisualRuns. */
class UniscribeLine : public std::vector<UniscribeVisualRun>, public ParagraphLayouter::Line {
public:
int GetLeading() const override;
int GetWidth() const override;
int CountRuns() const override { return (uint)this->size(); }
const VisualRun &GetVisualRun(int run) const override { return this->at(run); }
int GetInternalCharLength(WChar c) const override
{
/* Uniscribe uses UTF-16 internally which means we need to account for surrogate pairs. */
return c >= 0x010000U ? 2 : 1;
}
};
UniscribeParagraphLayout(std::vector<UniscribeRun> &ranges, const UniscribeParagraphLayoutFactory::CharType *buffer) : text_buffer(buffer), ranges(ranges)
{
this->Reflow();
}
~UniscribeParagraphLayout() override {}
void Reflow() override
{
this->cur_range = this->ranges.begin();
this->cur_range_offset = 0;
}
std::unique_ptr<const Line> NextLine(int max_width) override;
};
void UniscribeResetScriptCache(FontSize size)
{
if (_script_cache[size] != nullptr) {
ScriptFreeCache(&_script_cache[size]);
_script_cache[size] = nullptr;
}
}
/** Load the matching native Windows font. */
static HFONT HFontFromFont(Font *font)
{
if (font->fc->GetOSHandle() != nullptr) return CreateFontIndirect(reinterpret_cast<PLOGFONT>(const_cast<void *>(font->fc->GetOSHandle())));
LOGFONT logfont;
ZeroMemory(&logfont, sizeof(LOGFONT));
logfont.lfHeight = font->fc->GetHeight();
logfont.lfWeight = FW_NORMAL;
logfont.lfCharSet = DEFAULT_CHARSET;
convert_to_fs(font->fc->GetFontName(), logfont.lfFaceName, lengthof(logfont.lfFaceName));
return CreateFontIndirect(&logfont);
}
/** Determine the glyph positions for a run. */
static bool UniscribeShapeRun(const UniscribeParagraphLayoutFactory::CharType *buff, UniscribeRun &range)
{
/* Initial size guess for the number of glyphs recommended by Uniscribe. */
range.glyphs.resize(range.len * 3 / 2 + 16);
range.vis_attribs.resize(range.glyphs.size());
/* The char-to-glyph array is the same size as the input. */
range.char_to_glyph.resize(range.len);
HDC temp_dc = nullptr;
HFONT old_font = nullptr;
HFONT cur_font = nullptr;
while (true) {
/* Shape the text run by determining the glyphs needed for display. */
int glyphs_used = 0;
HRESULT hr = ScriptShape(temp_dc, &_script_cache[range.font->fc->GetSize()], buff + range.pos, range.len, (int)range.glyphs.size(), &range.sa, &range.glyphs[0], &range.char_to_glyph[0], &range.vis_attribs[0], &glyphs_used);
if (SUCCEEDED(hr)) {
range.glyphs.resize(glyphs_used);
range.vis_attribs.resize(glyphs_used);
/* Calculate the glyph positions. */
ABC abc;
range.advances.resize(range.glyphs.size());
range.offsets.resize(range.glyphs.size());
hr = ScriptPlace(temp_dc, &_script_cache[range.font->fc->GetSize()], &range.glyphs[0], (int)range.glyphs.size(), &range.vis_attribs[0], &range.sa, &range.advances[0], &range.offsets[0], &abc);
if (SUCCEEDED(hr)) {
/* We map our special sprite chars to values that don't fit into a WORD. Copy the glyphs
* into a new vector and query the real glyph to use for these special chars. */
range.ft_glyphs.resize(range.glyphs.size());
for (size_t g_id = 0; g_id < range.glyphs.size(); g_id++) {
range.ft_glyphs[g_id] = range.glyphs[g_id];
}
for (int i = 0; i < range.len; i++) {
if (buff[range.pos + i] >= SCC_SPRITE_START && buff[range.pos + i] <= SCC_SPRITE_END) {
auto pos = range.char_to_glyph[i];
range.ft_glyphs[pos] = range.font->fc->MapCharToGlyph(buff[range.pos + i]);
range.offsets[pos].dv = (range.font->fc->GetHeight() - ScaleSpriteTrad(FontCache::GetDefaultFontHeight(range.font->fc->GetSize()))) / 2; // Align sprite font to centre
range.advances[pos] = range.font->fc->GetGlyphWidth(range.ft_glyphs[pos]);
}
}
range.total_advance = 0;
for (size_t i = 0; i < range.advances.size(); i++) {
#ifdef WITH_FREETYPE
/* FreeType and GDI/Uniscribe seems to occasionally disagree over the width of a glyph. */
if (range.advances[i] > 0 && range.ft_glyphs[i] != 0xFFFF) range.advances[i] = range.font->fc->GetGlyphWidth(range.ft_glyphs[i]);
#endif
range.total_advance += range.advances[i];
}
break;
}
}
if (hr == E_OUTOFMEMORY) {
/* The glyph buffer needs to be larger. Just double it every time. */
range.glyphs.resize(range.glyphs.size() * 2);
range.vis_attribs.resize(range.vis_attribs.size() * 2);
} else if (hr == E_PENDING) {
/* Glyph data is not in cache, load native font. */
cur_font = HFontFromFont(range.font);
if (cur_font == nullptr) return false; // Sorry, no dice.
temp_dc = CreateCompatibleDC(nullptr);
SetMapMode(temp_dc, MM_TEXT);
old_font = (HFONT)SelectObject(temp_dc, cur_font);
} else if (hr == USP_E_SCRIPT_NOT_IN_FONT && range.sa.eScript != SCRIPT_UNDEFINED) {
/* Try again with the generic shaping engine. */
range.sa.eScript = SCRIPT_UNDEFINED;
} else {
/* Some unknown other error. */
if (temp_dc != nullptr) {
SelectObject(temp_dc, old_font);
DeleteObject(cur_font);
ReleaseDC(nullptr, temp_dc);
}
return false;
}
}
if (temp_dc != nullptr) {
SelectObject(temp_dc, old_font);
DeleteObject(cur_font);
ReleaseDC(nullptr, temp_dc);
}
return true;
}
static std::vector<SCRIPT_ITEM> UniscribeItemizeString(UniscribeParagraphLayoutFactory::CharType *buff, int32 length)
{
/* Itemize text. */
SCRIPT_CONTROL control;
ZeroMemory(&control, sizeof(SCRIPT_CONTROL));
control.uDefaultLanguage = _current_language->winlangid;
SCRIPT_STATE state;
ZeroMemory(&state, sizeof(SCRIPT_STATE));
state.uBidiLevel = _current_text_dir == TD_RTL ? 1 : 0;
std::vector<SCRIPT_ITEM> items(16);
while (true) {
/* We subtract one from max_items to work around a buffer overflow on some older versions of Windows. */
int generated = 0;
HRESULT hr = ScriptItemize(buff, length, (int)items.size() - 1, &control, &state, &items[0], &generated);
if (SUCCEEDED(hr)) {
/* Resize the item buffer. Note that Uniscribe will always add an additional end sentinel item. */
items.resize(generated + 1);
break;
}
/* Some kind of error except item buffer too small. */
if (hr != E_OUTOFMEMORY) return std::vector<SCRIPT_ITEM>();
items.resize(items.size() * 2);
}
return items;
}
/* static */ ParagraphLayouter *UniscribeParagraphLayoutFactory::GetParagraphLayout(CharType *buff, CharType *buff_end, FontMap &fontMapping)
{
int32 length = buff_end - buff;
/* Can't layout an empty string. */
if (length == 0) return nullptr;
/* Can't layout our in-built sprite fonts. */
for (auto const &pair : fontMapping) {
if (pair.second->fc->IsBuiltInFont()) return nullptr;
}
/* Itemize text. */
std::vector<SCRIPT_ITEM> items = UniscribeItemizeString(buff, length);
if (items.size() == 0) return nullptr;
/* Build ranges from the items and the font map. A range is a run of text
* that is part of a single item and formatted using a single font style. */
std::vector<UniscribeRun> ranges;
int cur_pos = 0;
std::vector<SCRIPT_ITEM>::iterator cur_item = items.begin();
for (auto const &i : fontMapping) {
while (cur_pos < i.first && cur_item != items.end() - 1) {
/* Add a range that spans the intersection of the remaining item and font run. */
int stop_pos = std::min(i.first, (cur_item + 1)->iCharPos);
assert(stop_pos - cur_pos > 0);
ranges.push_back(UniscribeRun(cur_pos, stop_pos - cur_pos, i.second, cur_item->a));
/* Shape the range. */
if (!UniscribeShapeRun(buff, ranges.back())) {
return nullptr;
}
/* If we are at the end of the current item, advance to the next item. */
if (stop_pos == (cur_item + 1)->iCharPos) cur_item++;
cur_pos = stop_pos;
}
}
return new UniscribeParagraphLayout(ranges, buff);
}
/* virtual */ std::unique_ptr<const ParagraphLayouter::Line> UniscribeParagraphLayout::NextLine(int max_width)
{
std::vector<UniscribeRun>::iterator start_run = this->cur_range;
std::vector<UniscribeRun>::iterator last_run = this->cur_range;
if (start_run == this->ranges.end()) return nullptr;
/* Add remaining width of the first run if it is a broken run. */
int cur_width = 0;
if (this->cur_range_offset != 0) {
std::vector<int> dx(start_run->len);
ScriptGetLogicalWidths(&start_run->sa, start_run->len, (int)start_run->glyphs.size(), &start_run->advances[0], &start_run->char_to_glyph[0], &start_run->vis_attribs[0], &dx[0]);
for (std::vector<int>::const_iterator c = dx.begin() + this->cur_range_offset; c != dx.end(); c++) {
cur_width += *c;
}
++last_run;
}
/* Gather runs until the line is full. */
while (last_run != this->ranges.end() && cur_width <= max_width) {
cur_width += last_run->total_advance;
++last_run;
}
/* If the text does not fit into the available width, find a suitable breaking point. */
int remaining_offset = (last_run - 1)->len + 1;
int whitespace_count = 0;
if (cur_width > max_width) {
std::vector<SCRIPT_LOGATTR> log_attribs;
/* Get word break information. */
int width_avail = max_width;
int num_chars = this->cur_range_offset;
int start_offs = this->cur_range_offset;
int last_cluster = this->cur_range_offset + 1;
for (std::vector<UniscribeRun>::iterator r = start_run; r != last_run; r++) {
log_attribs.resize(r->pos - start_run->pos + r->len);
if (FAILED(ScriptBreak(this->text_buffer + r->pos + start_offs, r->len - start_offs, &r->sa, &log_attribs[r->pos - start_run->pos + start_offs]))) return nullptr;
std::vector<int> dx(r->len);
ScriptGetLogicalWidths(&r->sa, r->len, (int)r->glyphs.size(), &r->advances[0], &r->char_to_glyph[0], &r->vis_attribs[0], &dx[0]);
/* Count absolute max character count on the line. */
for (int c = start_offs; c < r->len && width_avail > 0; c++, num_chars++) {
if (c > start_offs && log_attribs[num_chars].fCharStop) last_cluster = num_chars;
width_avail -= dx[c];
}
start_offs = 0;
}
/* Walk backwards to find the last suitable breaking point. */
while (--num_chars > this->cur_range_offset && !log_attribs[num_chars].fSoftBreak && !log_attribs[num_chars].fWhiteSpace) {}
if (num_chars == this->cur_range_offset) {
/* Didn't find any suitable word break point, just break on the last cluster boundary. */
num_chars = last_cluster;
}
/* Eat any whitespace characters before the breaking point. */
while (num_chars - 1 > this->cur_range_offset && log_attribs[num_chars - 1].fWhiteSpace) num_chars--;
/* Count whitespace after the breaking point. */
while (num_chars + whitespace_count < (int)log_attribs.size() && log_attribs[num_chars + whitespace_count].fWhiteSpace) whitespace_count++;
/* Get last run that corresponds to the number of characters to show. */
for (std::vector<UniscribeRun>::iterator run = start_run; run != last_run; run++) {
num_chars -= run->len;
if (num_chars <= 0) {
remaining_offset = num_chars + run->len + 1;
last_run = run + 1;
assert(remaining_offset - 1 > 0);
break;
}
}
}
/* Build display order from the runs. */
std::vector<BYTE> bidi_level;
for (std::vector<UniscribeRun>::iterator r = start_run; r != last_run; r++) {
bidi_level.push_back(r->sa.s.uBidiLevel);
}
std::vector<INT> vis_to_log(bidi_level.size());
if (FAILED(ScriptLayout((int)bidi_level.size(), &bidi_level[0], &vis_to_log[0], nullptr))) return nullptr;
/* Create line. */
std::unique_ptr<UniscribeLine> line(new UniscribeLine());
int cur_pos = 0;
for (std::vector<INT>::iterator l = vis_to_log.begin(); l != vis_to_log.end(); l++) {
std::vector<UniscribeRun>::iterator i_run = start_run + *l;
UniscribeRun run = *i_run;
/* Partial run after line break (either start or end)? Reshape run to get the first/last glyphs right. */
if (i_run == last_run - 1 && remaining_offset < (last_run - 1)->len) {
run.len = remaining_offset - 1;
if (!UniscribeShapeRun(this->text_buffer, run)) return nullptr;
}
if (i_run == start_run && this->cur_range_offset > 0) {
assert(run.len - this->cur_range_offset > 0);
run.pos += this->cur_range_offset;
run.len -= this->cur_range_offset;
if (!UniscribeShapeRun(this->text_buffer, run)) return nullptr;
}
line->emplace_back(run, cur_pos);
cur_pos += run.total_advance;
}
if (remaining_offset + whitespace_count - 1 < (last_run - 1)->len) {
/* We didn't use up all of the last run, store remainder for the next line. */
this->cur_range_offset = remaining_offset + whitespace_count - 1;
this->cur_range = last_run - 1;
assert(this->cur_range->len > this->cur_range_offset);
} else {
this->cur_range_offset = 0;
this->cur_range = last_run;
}
return line;
}
/**
* Get the height of the line.
* @return The maximum height of the line.
*/
int UniscribeParagraphLayout::UniscribeLine::GetLeading() const
{
int leading = 0;
for (const auto &run : *this) {
leading = std::max(leading, run.GetLeading());
}
return leading;
}
/**
* Get the width of this line.
* @return The width of the line.
*/
int UniscribeParagraphLayout::UniscribeLine::GetWidth() const
{
int length = 0;
for (const auto &run : *this) {
length += run.GetAdvance();
}
return length;
}
UniscribeParagraphLayout::UniscribeVisualRun::UniscribeVisualRun(const UniscribeRun &range, int x) : glyphs(range.ft_glyphs), char_to_glyph(range.char_to_glyph), start_pos(range.pos), total_advance(range.total_advance), font(range.font)
{
this->num_glyphs = (int)glyphs.size();
this->positions.resize(this->num_glyphs * 2 + 2);
int advance = 0;
for (int i = 0; i < this->num_glyphs; i++) {
this->positions[i * 2 + 0] = range.offsets[i].du + advance + x;
this->positions[i * 2 + 1] = range.offsets[i].dv;
advance += range.advances[i];
}
this->positions[this->num_glyphs * 2] = advance + x;
}
UniscribeParagraphLayout::UniscribeVisualRun::UniscribeVisualRun(UniscribeVisualRun&& other) noexcept
: glyphs(std::move(other.glyphs)), positions(std::move(other.positions)), char_to_glyph(std::move(other.char_to_glyph)),
start_pos(other.start_pos), total_advance(other.total_advance), num_glyphs(other.num_glyphs), font(other.font)
{
this->glyph_to_char = other.glyph_to_char;
other.glyph_to_char = nullptr;
}
const int *UniscribeParagraphLayout::UniscribeVisualRun::GetGlyphToCharMap() const
{
if (this->glyph_to_char == nullptr) {
this->glyph_to_char = CallocT<int>(this->GetGlyphCount());
/* The char to glyph array contains the first glyph index of the cluster that is associated
* with each character. It is possible for a cluster to be formed of several chars. */
for (int c = 0; c < (int)this->char_to_glyph.size(); c++) {
/* If multiple chars map to one glyph, only refer back to the first character. */
if (this->glyph_to_char[this->char_to_glyph[c]] == 0) this->glyph_to_char[this->char_to_glyph[c]] = c + this->start_pos;
}
/* We only marked the first glyph of each cluster in the loop above. Fill the gaps. */
int last_char = this->glyph_to_char[0];
for (int g = 0; g < this->GetGlyphCount(); g++) {
if (this->glyph_to_char[g] != 0) last_char = this->glyph_to_char[g];
this->glyph_to_char[g] = last_char;
}
}
return this->glyph_to_char;
}
/* virtual */ void UniscribeStringIterator::SetString(const char *s)
{
const char *string_base = s;
this->utf16_to_utf8.clear();
this->str_info.clear();
this->cur_pos = 0;
/* Uniscribe operates on UTF-16, thus we have to convert the input string.
* To be able to return proper offsets, we have to create a mapping at the same time. */
std::vector<wchar_t> utf16_str; ///< UTF-16 copy of the string.
while (*s != '\0') {
size_t idx = s - string_base;
WChar c = Utf8Consume(&s);
if (c < 0x10000) {
utf16_str.push_back((wchar_t)c);
} else {
/* Make a surrogate pair. */
utf16_str.push_back((wchar_t)(0xD800 + ((c - 0x10000) >> 10)));
utf16_str.push_back((wchar_t)(0xDC00 + ((c - 0x10000) & 0x3FF)));
this->utf16_to_utf8.push_back(idx);
}
this->utf16_to_utf8.push_back(idx);
}
this->utf16_to_utf8.push_back(s - string_base);
/* Query Uniscribe for word and cluster break information. */
this->str_info.resize(utf16_to_utf8.size());
if (utf16_str.size() > 0) {
/* Itemize string into language runs. */
std::vector<SCRIPT_ITEM> runs = UniscribeItemizeString(&utf16_str[0], (int32)utf16_str.size());
for (std::vector<SCRIPT_ITEM>::const_iterator run = runs.begin(); runs.size() > 0 && run != runs.end() - 1; run++) {
/* Get information on valid word and character break.s */
int len = (run + 1)->iCharPos - run->iCharPos;
std::vector<SCRIPT_LOGATTR> attr(len);
ScriptBreak(&utf16_str[run->iCharPos], len, &run->a, &attr[0]);
/* Extract the information we're interested in. */
for (size_t c = 0; c < attr.size(); c++) {
/* First character of a run is always a valid word break. */
this->str_info[c + run->iCharPos].word_stop = attr[c].fWordStop || c == 0;
this->str_info[c + run->iCharPos].char_stop = attr[c].fCharStop;
}
}
}
/* End-of-string is always a valid stopping point. */
this->str_info.back().char_stop = true;
this->str_info.back().word_stop = true;
}
/* virtual */ size_t UniscribeStringIterator::SetCurPosition(size_t pos)
{
/* Convert incoming position to an UTF-16 string index. */
size_t utf16_pos = 0;
for (size_t i = 0; i < this->utf16_to_utf8.size(); i++) {
if (this->utf16_to_utf8[i] == pos) {
utf16_pos = i;
break;
}
}
/* Sanitize in case we get a position inside a grapheme cluster. */
while (utf16_pos > 0 && !this->str_info[utf16_pos].char_stop) utf16_pos--;
this->cur_pos = utf16_pos;
return this->utf16_to_utf8[this->cur_pos];
}
/* virtual */ size_t UniscribeStringIterator::Next(IterType what)
{
assert(this->cur_pos <= this->utf16_to_utf8.size());
assert(what == StringIterator::ITER_CHARACTER || what == StringIterator::ITER_WORD);
if (this->cur_pos == this->utf16_to_utf8.size()) return END;
do {
this->cur_pos++;
} while (this->cur_pos < this->utf16_to_utf8.size() && (what == ITER_WORD ? !this->str_info[this->cur_pos].word_stop : !this->str_info[this->cur_pos].char_stop));
return this->cur_pos == this->utf16_to_utf8.size() ? END : this->utf16_to_utf8[this->cur_pos];
}
/*virtual */ size_t UniscribeStringIterator::Prev(IterType what)
{
assert(this->cur_pos <= this->utf16_to_utf8.size());
assert(what == StringIterator::ITER_CHARACTER || what == StringIterator::ITER_WORD);
if (this->cur_pos == 0) return END;
do {
this->cur_pos--;
} while (this->cur_pos > 0 && (what == ITER_WORD ? !this->str_info[this->cur_pos].word_stop : !this->str_info[this->cur_pos].char_stop));
return this->utf16_to_utf8[this->cur_pos];
}
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