/** * @file llfontgl.cpp * @brief Wrapper around FreeType * * $LicenseInfo:firstyear=2001&license=viewerlgpl$ * Second Life Viewer Source Code * Copyright (C) 2010, Linden Research, Inc. * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; * version 2.1 of the License only. * * This library 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 * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA * * Linden Research, Inc., 945 Battery Street, San Francisco, CA 94111 USA * $/LicenseInfo$ */ #include "linden_common.h" #include "llfontgl.h" // Linden library includes #include "llfasttimer.h" #include "llfontfreetype.h" #include "llfontbitmapcache.h" #include "llfontregistry.h" #include "llgl.h" #include "llimagegl.h" #include "llrender.h" #include "llstl.h" #include "v4color.h" #include "lltexture.h" #include "lldir.h" #include "llstring.h" // Third party library includes #include #if LL_WINDOWS #include #include #include #endif // LL_WINDOWS const S32 BOLD_OFFSET = 1; // static class members F32 LLFontGL::sVertDPI = 96.f; F32 LLFontGL::sHorizDPI = 96.f; F32 LLFontGL::sScaleX = 1.f; F32 LLFontGL::sScaleY = 1.f; bool LLFontGL::sDisplayFont = true ; std::string LLFontGL::sAppDir; LLColor4 LLFontGL::sShadowColor(0.f, 0.f, 0.f, 1.f); LLFontRegistry* LLFontGL::sFontRegistry = NULL; LLCoordGL LLFontGL::sCurOrigin; F32 LLFontGL::sCurDepth; std::vector > LLFontGL::sOriginStack; const F32 PAD_UVY = 0.5f; // half of vertical padding between glyphs in the glyph texture const F32 DROP_SHADOW_SOFT_STRENGTH = 0.3f; LLFontGL::LLFontGL() { } LLFontGL::~LLFontGL() { } void LLFontGL::reset() { mFontFreetype->reset(sVertDPI, sHorizDPI); } void LLFontGL::destroyGL() { mFontFreetype->destroyGL(); } bool LLFontGL::loadFace(const std::string& filename, F32 point_size, const F32 vert_dpi, const F32 horz_dpi, bool is_fallback, S32 face_n) { if(mFontFreetype == reinterpret_cast(NULL)) { mFontFreetype = new LLFontFreetype; } return mFontFreetype->loadFace(filename, point_size, vert_dpi, horz_dpi, is_fallback, face_n); } S32 LLFontGL::getNumFaces(const std::string& filename) { if (mFontFreetype == reinterpret_cast(NULL)) { mFontFreetype = new LLFontFreetype; } return mFontFreetype->getNumFaces(filename); } S32 LLFontGL::render(const LLWString &wstr, S32 begin_offset, const LLRect& rect, const LLColor4 &color, HAlign halign, VAlign valign, U8 style, ShadowType shadow, S32 max_chars, F32* right_x, bool use_ellipses, bool use_color) const { LLRectf rect_float((F32)rect.mLeft, (F32)rect.mTop, (F32)rect.mRight, (F32)rect.mBottom); return render(wstr, begin_offset, rect_float, color, halign, valign, style, shadow, max_chars, right_x, use_ellipses, use_color); } S32 LLFontGL::render(const LLWString &wstr, S32 begin_offset, const LLRectf& rect, const LLColor4 &color, HAlign halign, VAlign valign, U8 style, ShadowType shadow, S32 max_chars, F32* right_x, bool use_ellipses, bool use_color) const { F32 x = rect.mLeft; F32 y = 0.f; switch(valign) { case TOP: y = rect.mTop; break; case VCENTER: y = rect.getCenterY(); break; case BASELINE: case BOTTOM: y = rect.mBottom; break; default: y = rect.mBottom; break; } return render(wstr, begin_offset, x, y, color, halign, valign, style, shadow, max_chars, (S32)rect.getWidth(), right_x, use_ellipses, use_color); } S32 LLFontGL::render(const LLWString &wstr, S32 begin_offset, F32 x, F32 y, const LLColor4 &color, HAlign halign, VAlign valign, U8 style, ShadowType shadow, S32 max_chars, S32 max_pixels, F32* right_x, bool use_ellipses, bool use_color) const { LL_PROFILE_ZONE_SCOPED_CATEGORY_UI; if(!sDisplayFont) //do not display texts { return static_cast(wstr.length()); } if (wstr.empty()) { return 0; } gGL.getTexUnit(0)->enable(LLTexUnit::TT_TEXTURE); S32 scaled_max_pixels = max_pixels == S32_MAX ? S32_MAX : llceil((F32)max_pixels * sScaleX); // determine which style flags need to be added programmatically by stripping off the // style bits that are drawn by the underlying Freetype font U8 style_to_add = (style | mFontDescriptor.getStyle()) & ~mFontFreetype->getStyle(); F32 drop_shadow_strength = 0.f; if (shadow != NO_SHADOW) { F32 luminance; color.calcHSL(NULL, NULL, &luminance); drop_shadow_strength = clamp_rescale(luminance, 0.35f, 0.6f, 0.f, 1.f); if (luminance < 0.35f) { shadow = NO_SHADOW; } } gGL.pushUIMatrix(); gGL.loadUIIdentity(); LLVector2 origin(floorf(sCurOrigin.mX*sScaleX), floorf(sCurOrigin.mY*sScaleY)); // Depth translation, so that floating text appears 'in-world' // and is correctly occluded. gGL.translatef(0.f,0.f,sCurDepth); S32 chars_drawn = 0; S32 i; S32 length; if (-1 == max_chars) { max_chars = length = (S32)wstr.length() - begin_offset; } else { length = llmin((S32)wstr.length() - begin_offset, max_chars ); } F32 cur_x, cur_y, cur_render_x, cur_render_y; // Not guaranteed to be set correctly gGL.setSceneBlendType(LLRender::BT_ALPHA); cur_x = ((F32)x * sScaleX) + origin.mV[VX]; cur_y = ((F32)y * sScaleY) + origin.mV[VY]; // Offset y by vertical alignment. // use unscaled font metrics here switch (valign) { case TOP: cur_y -= llceil(mFontFreetype->getAscenderHeight()); break; case BOTTOM: cur_y += llceil(mFontFreetype->getDescenderHeight()); break; case VCENTER: cur_y -= llceil((llceil(mFontFreetype->getAscenderHeight()) - llceil(mFontFreetype->getDescenderHeight())) / 2.f); break; case BASELINE: // Baseline, do nothing. break; default: break; } switch (halign) { case LEFT: break; case RIGHT: cur_x -= llmin(scaled_max_pixels, ll_round(getWidthF32(wstr.c_str(), begin_offset, length) * sScaleX)); break; case HCENTER: cur_x -= llmin(scaled_max_pixels, ll_round(getWidthF32(wstr.c_str(), begin_offset, length) * sScaleX)) / 2; break; default: break; } cur_render_y = cur_y; cur_render_x = cur_x; F32 start_x = (F32)ll_round(cur_x); const LLFontBitmapCache* font_bitmap_cache = mFontFreetype->getFontBitmapCache(); F32 inv_width = 1.f / font_bitmap_cache->getBitmapWidth(); F32 inv_height = 1.f / font_bitmap_cache->getBitmapHeight(); const S32 LAST_CHARACTER = LLFontFreetype::LAST_CHAR_FULL; bool draw_ellipses = false; if (use_ellipses) { // check for too long of a string S32 string_width = ll_round(getWidthF32(wstr.c_str(), begin_offset, max_chars) * sScaleX); if (string_width > scaled_max_pixels) { // use four dots for ellipsis width to generate padding const LLWString dots(utf8str_to_wstring(std::string("...."))); scaled_max_pixels = llmax(0, scaled_max_pixels - ll_round(getWidthF32(dots.c_str()))); draw_ellipses = true; } } const LLFontGlyphInfo* next_glyph = NULL; static constexpr U32 GLYPH_BATCH_SIZE = 30; static thread_local LLVector4a vertices[GLYPH_BATCH_SIZE * 6]; static thread_local LLVector2 uvs[GLYPH_BATCH_SIZE * 6]; static thread_local LLColor4U colors[GLYPH_BATCH_SIZE * 6]; LLColor4U text_color(color); // Preserve the transparency to render fading emojis in fading text (e.g. // for the chat console)... HB LLColor4U emoji_color(255, 255, 255, text_color.mV[VALPHA]); std::pair bitmap_entry = std::make_pair(EFontGlyphType::Grayscale, -1); U32 glyph_count = 0; for (i = begin_offset; i < begin_offset + length; i++) { llwchar wch = wstr[i]; const LLFontGlyphInfo* fgi = next_glyph; next_glyph = NULL; if(!fgi) { fgi = mFontFreetype->getGlyphInfo(wch, (!use_color) ? EFontGlyphType::Grayscale : EFontGlyphType::Color); } if (!fgi) { LL_ERRS() << "Missing Glyph Info" << LL_ENDL; break; } // Per-glyph bitmap texture. std::pair next_bitmap_entry = fgi->mBitmapEntry; if (next_bitmap_entry != bitmap_entry) { // Actually draw the queued glyphs before switching their texture; // otherwise the queued glyphs will be taken from wrong textures. if (glyph_count > 0) { gGL.begin(LLRender::TRIANGLES); { gGL.vertexBatchPreTransformed(vertices, uvs, colors, glyph_count * 6); } gGL.end(); glyph_count = 0; } bitmap_entry = next_bitmap_entry; LLImageGL* font_image = font_bitmap_cache->getImageGL(bitmap_entry.first, bitmap_entry.second); gGL.getTexUnit(0)->bind(font_image); } if ((start_x + scaled_max_pixels) < (cur_x + fgi->mXBearing + fgi->mWidth)) { // Not enough room for this character. break; } // Draw the text at the appropriate location //Specify vertices and texture coordinates LLRectf uv_rect((fgi->mXBitmapOffset) * inv_width, (fgi->mYBitmapOffset + fgi->mHeight + PAD_UVY) * inv_height, (fgi->mXBitmapOffset + fgi->mWidth) * inv_width, (fgi->mYBitmapOffset - PAD_UVY) * inv_height); // snap glyph origin to whole screen pixel LLRectf screen_rect((F32)ll_round(cur_render_x + (F32)fgi->mXBearing), (F32)ll_round(cur_render_y + (F32)fgi->mYBearing), (F32)ll_round(cur_render_x + (F32)fgi->mXBearing) + (F32)fgi->mWidth, (F32)ll_round(cur_render_y + (F32)fgi->mYBearing) - (F32)fgi->mHeight); if (glyph_count >= GLYPH_BATCH_SIZE) { gGL.begin(LLRender::TRIANGLES); { gGL.vertexBatchPreTransformed(vertices, uvs, colors, glyph_count * 6); } gGL.end(); glyph_count = 0; } const LLColor4U& col = bitmap_entry.first == EFontGlyphType::Grayscale ? text_color : emoji_color; drawGlyph(glyph_count, vertices, uvs, colors, screen_rect, uv_rect, col, style_to_add, shadow, drop_shadow_strength); chars_drawn++; cur_x += fgi->mXAdvance; cur_y += fgi->mYAdvance; llwchar next_char = wstr[i+1]; if (next_char && (next_char < LAST_CHARACTER)) { // Kern this puppy. next_glyph = mFontFreetype->getGlyphInfo(next_char, (!use_color) ? EFontGlyphType::Grayscale : EFontGlyphType::Color); cur_x += mFontFreetype->getXKerning(fgi, next_glyph); } // Round after kerning. // Must do this to cur_x, not just to cur_render_x, otherwise you // will squish sub-pixel kerned characters too close together. // For example, "CCCCC" looks bad. cur_x = (F32)ll_round(cur_x); //cur_y = (F32)ll_round(cur_y); cur_render_x = cur_x; cur_render_y = cur_y; } gGL.begin(LLRender::TRIANGLES); { gGL.vertexBatchPreTransformed(vertices, uvs, colors, glyph_count * 6); } gGL.end(); if (right_x) { *right_x = (cur_x - origin.mV[VX]) / sScaleX; } //FIXME: add underline as glyph? if (style_to_add & UNDERLINE) { F32 descender = (F32)llfloor(mFontFreetype->getDescenderHeight()); gGL.getTexUnit(0)->unbind(LLTexUnit::TT_TEXTURE); gGL.begin(LLRender::LINES); gGL.vertex2f(start_x, cur_y - descender); gGL.vertex2f(cur_x, cur_y - descender); gGL.end(); } if (draw_ellipses) { // recursively render ellipses at end of string // we've already reserved enough room static LLWString elipses_wstr(utf8string_to_wstring(std::string("..."))); render(elipses_wstr, 0, (cur_x - origin.mV[VX]) / sScaleX, (F32)y, color, LEFT, valign, style_to_add, shadow, S32_MAX, max_pixels, right_x, false, use_color); } gGL.popUIMatrix(); return chars_drawn; } S32 LLFontGL::render(const LLWString &text, S32 begin_offset, F32 x, F32 y, const LLColor4 &color) const { return render(text, begin_offset, x, y, color, LEFT, BASELINE, NORMAL, NO_SHADOW); } S32 LLFontGL::renderUTF8(const std::string &text, S32 begin_offset, F32 x, F32 y, const LLColor4 &color, HAlign halign, VAlign valign, U8 style, ShadowType shadow, S32 max_chars, S32 max_pixels, F32* right_x, bool use_ellipses, bool use_color) const { return render(utf8str_to_wstring(text), begin_offset, x, y, color, halign, valign, style, shadow, max_chars, max_pixels, right_x, use_ellipses, use_color); } S32 LLFontGL::renderUTF8(const std::string &text, S32 begin_offset, S32 x, S32 y, const LLColor4 &color) const { return renderUTF8(text, begin_offset, (F32)x, (F32)y, color, LEFT, BASELINE, NORMAL, NO_SHADOW); } S32 LLFontGL::renderUTF8(const std::string &text, S32 begin_offset, S32 x, S32 y, const LLColor4 &color, HAlign halign, VAlign valign, U8 style, ShadowType shadow) const { return renderUTF8(text, begin_offset, (F32)x, (F32)y, color, halign, valign, style, shadow); } // font metrics - override for LLFontFreetype that returns units of virtual pixels F32 LLFontGL::getAscenderHeight() const { return mFontFreetype->getAscenderHeight() / sScaleY; } F32 LLFontGL::getDescenderHeight() const { return mFontFreetype->getDescenderHeight() / sScaleY; } S32 LLFontGL::getLineHeight() const { return llceil(mFontFreetype->getAscenderHeight() / sScaleY) + llceil(mFontFreetype->getDescenderHeight() / sScaleY); } S32 LLFontGL::getWidth(const std::string& utf8text) const { LLWString wtext = utf8str_to_wstring(utf8text); return getWidth(wtext.c_str(), 0, S32_MAX); } S32 LLFontGL::getWidth(const llwchar* wchars) const { return getWidth(wchars, 0, S32_MAX); } S32 LLFontGL::getWidth(const std::string& utf8text, S32 begin_offset, S32 max_chars) const { LLWString wtext = utf8str_to_wstring(utf8text); return getWidth(wtext.c_str(), begin_offset, max_chars); } S32 LLFontGL::getWidth(const llwchar* wchars, S32 begin_offset, S32 max_chars) const { F32 width = getWidthF32(wchars, begin_offset, max_chars); return ll_round(width); } F32 LLFontGL::getWidthF32(const std::string& utf8text) const { LLWString wtext = utf8str_to_wstring(utf8text); return getWidthF32(wtext.c_str(), 0, S32_MAX); } F32 LLFontGL::getWidthF32(const llwchar* wchars) const { return getWidthF32(wchars, 0, S32_MAX); } F32 LLFontGL::getWidthF32(const std::string& utf8text, S32 begin_offset, S32 max_chars) const { LLWString wtext = utf8str_to_wstring(utf8text); return getWidthF32(wtext.c_str(), begin_offset, max_chars); } F32 LLFontGL::getWidthF32(const llwchar* wchars, S32 begin_offset, S32 max_chars, bool no_padding) const { LL_PROFILE_ZONE_SCOPED_CATEGORY_UI; const S32 LAST_CHARACTER = LLFontFreetype::LAST_CHAR_FULL; F32 cur_x = 0; const S32 max_index = begin_offset + max_chars; const LLFontGlyphInfo* next_glyph = NULL; F32 width_padding = 0.f; for (S32 i = begin_offset; i < max_index && wchars[i] != 0; i++) { llwchar wch = wchars[i]; const LLFontGlyphInfo* fgi = next_glyph; next_glyph = NULL; if(!fgi) { fgi = mFontFreetype->getGlyphInfo(wch, EFontGlyphType::Unspecified); } F32 advance = mFontFreetype->getXAdvance(fgi); if (!no_padding) { // for the last character we want to measure the greater of its width and xadvance values // so keep track of the difference between these values for the each character we measure // so we can fix things up at the end width_padding = llmax(0.f, // always use positive padding amount width_padding - advance, // previous padding left over after advance of current character (F32)(fgi->mWidth + fgi->mXBearing) - advance); // difference between width of this character and advance to next character } cur_x += advance; llwchar next_char = wchars[i+1]; if (((i + 1) < begin_offset + max_chars) && next_char && (next_char < LAST_CHARACTER)) { // Kern this puppy. next_glyph = mFontFreetype->getGlyphInfo(next_char, EFontGlyphType::Unspecified); cur_x += mFontFreetype->getXKerning(fgi, next_glyph); } // Round after kerning. cur_x = (F32)ll_round(cur_x); } if (!no_padding) { // add in extra pixels for last character's width past its xadvance cur_x += width_padding; } return cur_x / sScaleX; } void LLFontGL::generateASCIIglyphs() { LL_PROFILE_ZONE_SCOPED_CATEGORY_UI; for (U32 i = 32; (i < 127); i++) { mFontFreetype->getGlyphInfo(i, EFontGlyphType::Grayscale); } } // Returns the max number of complete characters from text (up to max_chars) that can be drawn in max_pixels S32 LLFontGL::maxDrawableChars(const llwchar* wchars, F32 max_pixels, S32 max_chars, EWordWrapStyle end_on_word_boundary) const { LL_PROFILE_ZONE_SCOPED_CATEGORY_UI; if (!wchars || !wchars[0] || max_chars == 0) { return 0; } llassert(max_pixels >= 0.f); llassert(max_chars >= 0); bool clip = false; F32 cur_x = 0; S32 start_of_last_word = 0; bool in_word = false; // avoid S32 overflow when max_pixels == S32_MAX by staying in floating point F32 scaled_max_pixels = max_pixels * sScaleX; F32 width_padding = 0.f; LLFontGlyphInfo* next_glyph = NULL; S32 i; for (i=0; (i < max_chars); i++) { llwchar wch = wchars[i]; if(wch == 0) { // Null terminator. We're done. break; } if (in_word) { if (iswspace(wch)) { if(wch !=(0x00A0)) { in_word = false; } } if (iswindividual(wch)) { if (iswpunct(wchars[i+1])) { in_word=true; } else { in_word=false; start_of_last_word = i; } } } else { start_of_last_word = i; if (!iswspace(wch)||!iswindividual(wch)) { in_word = true; } } LLFontGlyphInfo* fgi = next_glyph; next_glyph = NULL; if(!fgi) { fgi = mFontFreetype->getGlyphInfo(wch, EFontGlyphType::Unspecified); if (NULL == fgi) { return 0; } } // account for glyphs that run beyond the starting point for the next glyphs width_padding = llmax( 0.f, // always use positive padding amount width_padding - fgi->mXAdvance, // previous padding left over after advance of current character (F32)(fgi->mWidth + fgi->mXBearing) - fgi->mXAdvance); // difference between width of this character and advance to next character cur_x += fgi->mXAdvance; // clip if current character runs past scaled_max_pixels (using width_padding) if (scaled_max_pixels < cur_x + width_padding) { clip = true; break; } if (((i+1) < max_chars) && wchars[i+1]) { // Kern this puppy. next_glyph = mFontFreetype->getGlyphInfo(wchars[i+1], EFontGlyphType::Unspecified); cur_x += mFontFreetype->getXKerning(fgi, next_glyph); } // Round after kerning. cur_x = (F32)ll_round(cur_x); } if( clip ) { switch (end_on_word_boundary) { case ONLY_WORD_BOUNDARIES: i = start_of_last_word; break; case WORD_BOUNDARY_IF_POSSIBLE: if (start_of_last_word != 0) { i = start_of_last_word; } break; default: case ANYWHERE: // do nothing break; } } return i; } S32 LLFontGL::firstDrawableChar(const llwchar* wchars, F32 max_pixels, S32 text_len, S32 start_pos, S32 max_chars) const { if (!wchars || !wchars[0] || max_chars == 0) { return 0; } F32 total_width = 0.0; S32 drawable_chars = 0; F32 scaled_max_pixels = max_pixels * sScaleX; S32 start = llmin(start_pos, text_len - 1); for (S32 i = start; i >= 0; i--) { llwchar wch = wchars[i]; const LLFontGlyphInfo* fgi= mFontFreetype->getGlyphInfo(wch, EFontGlyphType::Unspecified); // last character uses character width, since the whole character needs to be visible // other characters just use advance F32 width = (i == start) ? (F32)(fgi->mWidth + fgi->mXBearing) // use actual width for last character : fgi->mXAdvance; // use advance for all other characters if( scaled_max_pixels < (total_width + width) ) { break; } total_width += width; drawable_chars++; if( max_chars >= 0 && drawable_chars >= max_chars ) { break; } if ( i > 0 ) { // kerning total_width += mFontFreetype->getXKerning(wchars[i-1], wch); } // Round after kerning. total_width = (F32)ll_round(total_width); } if (drawable_chars == 0) { return start_pos; // just draw last character } else { // if only 1 character is drawable, we want to return start_pos as the first character to draw // if 2 are drawable, return start_pos and character before start_pos, etc. return start_pos + 1 - drawable_chars; } } S32 LLFontGL::charFromPixelOffset(const llwchar* wchars, S32 begin_offset, F32 target_x, F32 max_pixels, S32 max_chars, bool round) const { if (!wchars || !wchars[0] || max_chars == 0) { return 0; } F32 cur_x = 0; target_x *= sScaleX; // max_chars is S32_MAX by default, so make sure we don't get overflow const S32 max_index = begin_offset + llmin(S32_MAX - begin_offset, max_chars - 1); F32 scaled_max_pixels = max_pixels * sScaleX; const LLFontGlyphInfo* next_glyph = NULL; S32 pos; for (pos = begin_offset; pos < max_index; pos++) { llwchar wch = wchars[pos]; if (!wch) { break; // done } const LLFontGlyphInfo* glyph = next_glyph; next_glyph = NULL; if(!glyph) { glyph = mFontFreetype->getGlyphInfo(wch, EFontGlyphType::Unspecified); } F32 char_width = mFontFreetype->getXAdvance(glyph); if (round) { // Note: if the mouse is on the left half of the character, the pick is to the character's left // If it's on the right half, the pick is to the right. if (target_x < cur_x + char_width*0.5f) { break; } } else if (target_x < cur_x + char_width) { break; } if (scaled_max_pixels < cur_x + char_width) { break; } cur_x += char_width; if (((pos + 1) < max_index) && (wchars[(pos + 1)])) { // Kern this puppy. next_glyph = mFontFreetype->getGlyphInfo(wchars[pos + 1], EFontGlyphType::Unspecified); cur_x += mFontFreetype->getXKerning(glyph, next_glyph); } // Round after kerning. cur_x = (F32)ll_round(cur_x); } return llmin(max_chars, pos - begin_offset); } const LLFontDescriptor& LLFontGL::getFontDesc() const { return mFontDescriptor; } // static void LLFontGL::initClass(F32 screen_dpi, F32 x_scale, F32 y_scale, const std::string& app_dir, bool create_gl_textures) { sVertDPI = (F32)llfloor(screen_dpi * y_scale); sHorizDPI = (F32)llfloor(screen_dpi * x_scale); sScaleX = x_scale; sScaleY = y_scale; sAppDir = app_dir; // Font registry init if (!sFontRegistry) { sFontRegistry = new LLFontRegistry(create_gl_textures); sFontRegistry->parseFontInfo("fonts.xml"); } else { sFontRegistry->reset(); } LLFontGL::loadDefaultFonts(); } void LLFontGL::dumpTextures() { if (mFontFreetype.notNull()) { mFontFreetype->dumpFontBitmaps(); } } // static void LLFontGL::dumpFonts() { sFontRegistry->dump(); } // static void LLFontGL::dumpFontTextures() { sFontRegistry->dumpTextures(); } // Force standard fonts to get generated up front. // This is primarily for error detection purposes. // Don't do this during initClass because it can be slow and we want to get // the viewer window on screen first. JC // static bool LLFontGL::loadDefaultFonts() { LL_PROFILE_ZONE_SCOPED_CATEGORY_UI; bool succ = true; succ &= (NULL != getFontSansSerifSmall()); succ &= (NULL != getFontSansSerif()); succ &= (NULL != getFontSansSerifBig()); succ &= (NULL != getFontSansSerifHuge()); succ &= (NULL != getFontSansSerifBold()); succ &= (NULL != getFontMonospace()); return succ; } void LLFontGL::loadCommonFonts() { LL_PROFILE_ZONE_SCOPED_CATEGORY_UI; getFont(LLFontDescriptor("SansSerif", "Small", BOLD)); getFont(LLFontDescriptor("SansSerif", "Large", BOLD)); getFont(LLFontDescriptor("SansSerif", "Huge", BOLD)); getFont(LLFontDescriptor("Monospace", "Medium", 0)); } // static void LLFontGL::destroyDefaultFonts() { // Remove the actual fonts. delete sFontRegistry; sFontRegistry = NULL; } //static void LLFontGL::destroyAllGL() { if (sFontRegistry) { sFontRegistry->destroyGL(); } } // static U8 LLFontGL::getStyleFromString(const std::string &style) { S32 ret = 0; if (style.find("BOLD") != style.npos) { ret |= BOLD; } if (style.find("ITALIC") != style.npos) { ret |= ITALIC; } if (style.find("UNDERLINE") != style.npos) { ret |= UNDERLINE; } return ret; } // static std::string LLFontGL::getStringFromStyle(U8 style) { std::string style_string; if (style == NORMAL) { style_string += "|NORMAL"; } if (style & BOLD) { style_string += "|BOLD"; } if (style & ITALIC) { style_string += "|ITALIC"; } if (style & UNDERLINE) { style_string += "|UNDERLINE"; } return style_string; } // static std::string LLFontGL::nameFromFont(const LLFontGL* fontp) { return fontp->mFontDescriptor.getName(); } // static std::string LLFontGL::sizeFromFont(const LLFontGL* fontp) { return fontp->mFontDescriptor.getSize(); } // static std::string LLFontGL::nameFromHAlign(LLFontGL::HAlign align) { if (align == LEFT) return std::string("left"); else if (align == RIGHT) return std::string("right"); else if (align == HCENTER) return std::string("center"); else return std::string(); } // static LLFontGL::HAlign LLFontGL::hAlignFromName(const std::string& name) { LLFontGL::HAlign gl_hfont_align = LLFontGL::LEFT; if (name == "left") { gl_hfont_align = LLFontGL::LEFT; } else if (name == "right") { gl_hfont_align = LLFontGL::RIGHT; } else if (name == "center") { gl_hfont_align = LLFontGL::HCENTER; } //else leave left return gl_hfont_align; } // static std::string LLFontGL::nameFromVAlign(LLFontGL::VAlign align) { if (align == TOP) return std::string("top"); else if (align == VCENTER) return std::string("center"); else if (align == BASELINE) return std::string("baseline"); else if (align == BOTTOM) return std::string("bottom"); else return std::string(); } // static LLFontGL::VAlign LLFontGL::vAlignFromName(const std::string& name) { LLFontGL::VAlign gl_vfont_align = LLFontGL::BASELINE; if (name == "top") { gl_vfont_align = LLFontGL::TOP; } else if (name == "center") { gl_vfont_align = LLFontGL::VCENTER; } else if (name == "baseline") { gl_vfont_align = LLFontGL::BASELINE; } else if (name == "bottom") { gl_vfont_align = LLFontGL::BOTTOM; } //else leave baseline return gl_vfont_align; } //static LLFontGL* LLFontGL::getFontEmojiSmall() { static LLFontGL* fontp = getFont(LLFontDescriptor("Emoji", "Small", 0)); return fontp;; } //static LLFontGL* LLFontGL::getFontEmojiMedium() { static LLFontGL* fontp = getFont(LLFontDescriptor("Emoji", "Medium", 0)); return fontp;; } //static LLFontGL* LLFontGL::getFontEmojiLarge() { static LLFontGL* fontp = getFont(LLFontDescriptor("Emoji", "Large", 0)); return fontp;; } //static LLFontGL* LLFontGL::getFontEmojiHuge() { static LLFontGL* fontp = getFont(LLFontDescriptor("Emoji", "Huge", 0)); return fontp;; } //static LLFontGL* LLFontGL::getFontMonospace() { static LLFontGL* fontp = getFont(LLFontDescriptor("Monospace","Monospace",0)); return fontp; } //static LLFontGL* LLFontGL::getFontSansSerifSmall() { static LLFontGL* fontp = getFont(LLFontDescriptor("SansSerif","Small",0)); return fontp; } //static LLFontGL* LLFontGL::getFontSansSerifSmallBold() { static LLFontGL* fontp = getFont(LLFontDescriptor("SansSerif","Small",BOLD)); return fontp; } //static LLFontGL* LLFontGL::getFontSansSerifSmallItalic() { static LLFontGL* fontp = getFont(LLFontDescriptor("SansSerif","Small",ITALIC)); return fontp; } //static LLFontGL* LLFontGL::getFontSansSerif() { static LLFontGL* fontp = getFont(LLFontDescriptor("SansSerif","Medium",0)); return fontp; } //static LLFontGL* LLFontGL::getFontSansSerifBig() { static LLFontGL* fontp = getFont(LLFontDescriptor("SansSerif","Large",0)); return fontp; } //static LLFontGL* LLFontGL::getFontSansSerifHuge() { static LLFontGL* fontp = getFont(LLFontDescriptor("SansSerif","Huge",0)); return fontp; } //static LLFontGL* LLFontGL::getFontSansSerifBold() { static LLFontGL* fontp = getFont(LLFontDescriptor("SansSerif","Medium",BOLD)); return fontp; } //static LLFontGL* LLFontGL::getFont(const LLFontDescriptor& desc) { return sFontRegistry->getFont(desc); } //static LLFontGL* LLFontGL::getFontByName(const std::string& name) { // check for most common fonts first if (name == "SANSSERIF") { return getFontSansSerif(); } else if (name == "SANSSERIF_SMALL") { return getFontSansSerifSmall(); } else if (name == "SANSSERIF_BIG") { return getFontSansSerifBig(); } else if (name == "SMALL" || name == "OCRA") { // *BUG: Should this be "MONOSPACE"? Do we use "OCRA" anymore? // Does "SMALL" mean "SERIF"? return getFontMonospace(); } else { return NULL; } } //static LLFontGL* LLFontGL::getFontDefault() { return getFontSansSerif(); // Fallback to sans serif as default font } // static std::string LLFontGL::getFontPathSystem() { #if LL_DARWIN // HACK for macOS return "/System/Library/Fonts/"; #elif LL_WINDOWS auto system_root = LLStringUtil::getenv("SystemRoot"); if (! system_root.empty()) { std::string fontpath(gDirUtilp->add(system_root, "fonts") + gDirUtilp->getDirDelimiter()); LL_INFOS() << "from SystemRoot: " << fontpath << LL_ENDL; return fontpath; } wchar_t *pwstr = NULL; HRESULT okay = SHGetKnownFolderPath(FOLDERID_Fonts, 0, NULL, &pwstr); if (SUCCEEDED(okay) && pwstr) { std::string fontpath(ll_convert_wide_to_string(pwstr)); // SHGetKnownFolderPath() contract requires us to free pwstr CoTaskMemFree(pwstr); LL_INFOS() << "from SHGetKnownFolderPath(): " << fontpath << LL_ENDL; return fontpath; } #endif LL_WARNS() << "Could not determine system fonts path" << LL_ENDL; return {}; } // static std::string LLFontGL::getFontPathLocal() { std::string local_path; // Backup files if we can't load from system fonts directory. // We could store this in an end-user writable directory to allow // end users to switch fonts. if (LLFontGL::sAppDir.length()) { // use specified application dir to look for fonts local_path = LLFontGL::sAppDir + "/fonts/"; } else { // assume working directory is executable directory local_path = "./fonts/"; } return local_path; } LLFontGL::LLFontGL(const LLFontGL &source) { LL_ERRS() << "Not implemented!" << LL_ENDL; } LLFontGL &LLFontGL::operator=(const LLFontGL &source) { LL_ERRS() << "Not implemented" << LL_ENDL; return *this; } void LLFontGL::renderTriangle(LLVector4a* vertex_out, LLVector2* uv_out, LLColor4U* colors_out, const LLRectf& screen_rect, const LLRectf& uv_rect, const LLColor4U& color, F32 slant_amt) const { S32 index = 0; vertex_out[index].set(screen_rect.mRight, screen_rect.mTop, 0.f); uv_out[index].set(uv_rect.mRight, uv_rect.mTop); colors_out[index] = color; index++; vertex_out[index].set(screen_rect.mLeft, screen_rect.mTop, 0.f); uv_out[index].set(uv_rect.mLeft, uv_rect.mTop); colors_out[index] = color; index++; vertex_out[index].set(screen_rect.mLeft, screen_rect.mBottom, 0.f); uv_out[index].set(uv_rect.mLeft, uv_rect.mBottom); colors_out[index] = color; index++; vertex_out[index].set(screen_rect.mRight, screen_rect.mTop, 0.f); uv_out[index].set(uv_rect.mRight, uv_rect.mTop); colors_out[index] = color; index++; vertex_out[index].set(screen_rect.mLeft, screen_rect.mBottom, 0.f); uv_out[index].set(uv_rect.mLeft, uv_rect.mBottom); colors_out[index] = color; index++; vertex_out[index].set(screen_rect.mRight, screen_rect.mBottom, 0.f); uv_out[index].set(uv_rect.mRight, uv_rect.mBottom); colors_out[index] = color; } void LLFontGL::drawGlyph(U32& glyph_count, LLVector4a* vertex_out, LLVector2* uv_out, LLColor4U* colors_out, const LLRectf& screen_rect, const LLRectf& uv_rect, const LLColor4U& color, U8 style, ShadowType shadow, F32 drop_shadow_strength) const { F32 slant_offset; slant_offset = ((style & ITALIC) ? ( -mFontFreetype->getAscenderHeight() * 0.2f) : 0.f); //FIXME: bold and drop shadow are mutually exclusive only for convenience //Allow both when we need them. if (style & BOLD) { for (S32 pass = 0; pass < 2; pass++) { LLRectf screen_rect_offset = screen_rect; screen_rect_offset.translate((F32)(pass * BOLD_OFFSET), 0.f); renderTriangle(&vertex_out[glyph_count * 6], &uv_out[glyph_count * 6], &colors_out[glyph_count * 6], screen_rect_offset, uv_rect, color, slant_offset); glyph_count++; } } else if (shadow == DROP_SHADOW_SOFT) { LLColor4U shadow_color = LLFontGL::sShadowColor; shadow_color.mV[VALPHA] = U8(color.mV[VALPHA] * drop_shadow_strength * DROP_SHADOW_SOFT_STRENGTH); for (S32 pass = 0; pass < 5; pass++) { LLRectf screen_rect_offset = screen_rect; switch(pass) { case 0: screen_rect_offset.translate(-1.f, -1.f); break; case 1: screen_rect_offset.translate(1.f, -1.f); break; case 2: screen_rect_offset.translate(1.f, 1.f); break; case 3: screen_rect_offset.translate(-1.f, 1.f); break; case 4: screen_rect_offset.translate(0, -2.f); break; } renderTriangle(&vertex_out[glyph_count * 6], &uv_out[glyph_count * 6], &colors_out[glyph_count * 6], screen_rect_offset, uv_rect, shadow_color, slant_offset); glyph_count++; } renderTriangle(&vertex_out[glyph_count * 6], &uv_out[glyph_count * 6], &colors_out[glyph_count * 6], screen_rect, uv_rect, color, slant_offset); glyph_count++; } else if (shadow == DROP_SHADOW) { LLColor4U shadow_color = LLFontGL::sShadowColor; shadow_color.mV[VALPHA] = U8(color.mV[VALPHA] * drop_shadow_strength); LLRectf screen_rect_shadow = screen_rect; screen_rect_shadow.translate(1.f, -1.f); renderTriangle(&vertex_out[glyph_count * 6], &uv_out[glyph_count * 6], &colors_out[glyph_count * 6], screen_rect_shadow, uv_rect, shadow_color, slant_offset); glyph_count++; renderTriangle(&vertex_out[glyph_count * 6], &uv_out[glyph_count * 6], &colors_out[glyph_count * 6], screen_rect, uv_rect, color, slant_offset); glyph_count++; } else // normal rendering { renderTriangle(&vertex_out[glyph_count * 6], &uv_out[glyph_count * 6], &colors_out[glyph_count * 6], screen_rect, uv_rect, color, slant_offset); glyph_count++; } }