#ifndef NOMINMAX #define NOMINMAX 1 #endif #include "specter/FontCache.hpp" #include "logvisor/logvisor.hpp" #include #include #include #include FT_GZIP_H #include FT_SYSTEM_H #include FT_OUTLINE_H #include #include #include extern "C" const uint8_t DROIDSANS_PERMISSIVE[]; extern "C" size_t DROIDSANS_PERMISSIVE_SZ; extern "C" const uint8_t BMONOFONT[]; extern "C" size_t BMONOFONT_SZ; extern "C" const uint8_t SPECTERCURVES[]; extern "C" size_t SPECTERCURVES_SZ; extern "C" const FT_Driver_ClassRec tt_driver_class; namespace specter { static logvisor::Module Log("specter::FontCache"); const FCharFilter AllCharFilter = std::make_pair("all-glyphs", [](uint32_t)->bool {return true;}); const FCharFilter LatinCharFilter = std::make_pair("latin-glyphs", [](uint32_t c)->bool {return c <= 0xff || ((c - 0x2200) <= (0x23FF - 0x2200));}); const FCharFilter LatinAndJapaneseCharFilter = std::make_pair("latin-and-jp-glyphs", [](uint32_t c)->bool {return LatinCharFilter.second(c) || ((c - 0x2E00) <= (0x30FF - 0x2E00)) || ((c - 0x4E00) <= (0x9FFF - 0x4E00)) || ((c - 0xFF00) <= (0xFFEF - 0xFF00));}); FontTag::FontTag(const std::string& name, bool subpixel, float points, uint32_t dpi) { XXH64_state_t st; XXH64_reset(&st, 0); XXH64_update(&st, name.data(), name.size()); XXH64_update(&st, &subpixel, 1); XXH64_update(&st, &points, 4); XXH64_update(&st, &dpi, 4); m_hash = XXH64_digest(&st); } FreeTypeGZipMemFace::FreeTypeGZipMemFace(FT_Library lib, const uint8_t* data, size_t sz) : m_lib(lib) { m_comp.base = (unsigned char*)data; m_comp.size = sz; m_comp.memory = lib->memory; } void FreeTypeGZipMemFace::open() { if (m_face) return; if (FT_Stream_OpenGzip(&m_decomp, &m_comp)) Log.report(logvisor::Fatal, "unable to open FreeType gzip stream"); FT_Open_Args args = { FT_OPEN_STREAM, nullptr, 0, nullptr, &m_decomp }; if (FT_Open_Face(m_lib, &args, 0, &m_face)) Log.report(logvisor::Fatal, "unable to open FreeType gzip face"); } void FreeTypeGZipMemFace::close() { if (!m_face) return; FT_Done_Face(m_face); m_face = nullptr; } #define TEXMAP_DIM 1024 static unsigned RoundUpPow2(unsigned v) { v--; v |= v >> 1; v |= v >> 2; v |= v >> 4; v |= v >> 8; v |= v >> 16; v++; return v; } using GreyPixel = uint8_t; static void MemcpyRect(GreyPixel* img, const FT_Bitmap* bmp, unsigned slice, unsigned x, unsigned y) { unsigned sy = TEXMAP_DIM * slice + y; for (unsigned i=0 ; irows ; ++i) { const unsigned char* s = &bmp->buffer[bmp->pitch*i]; GreyPixel* t = &img[TEXMAP_DIM*(sy+i)+x]; memcpy(t, s, bmp->width); } } union RgbaPixel { uint8_t rgba[4]; uint32_t pixel; }; static void MemcpyRect(RgbaPixel* img, const FT_Bitmap* bmp, unsigned slice, unsigned x, unsigned y) { unsigned sy = TEXMAP_DIM * slice + y; for (unsigned i=0 ; irows ; ++i) { const unsigned char* s = &bmp->buffer[bmp->pitch*i]; RgbaPixel* t = &img[TEXMAP_DIM*(sy+i)+x]; for (unsigned j=0 ; jwidth/3 ; ++j) { t[j].rgba[0] = s[j*3]; t[j].rgba[1] = s[j*3+1]; t[j].rgba[2] = s[j*3+2]; t[j].rgba[3] = 0xff; } } } static inline void GridFitGlyph(FT_GlyphSlot slot, FT_UInt& width, FT_UInt& height) { width = slot->metrics.width >> 6; height = slot->metrics.height >> 6; } void FontAtlas::buildKernTable(FT_Face face) { if (face->driver->clazz == &tt_driver_class) { TT_Face ttface = reinterpret_cast(face); if (!ttface->kern_table) return; athena::io::MemoryReader r(ttface->kern_table, ttface->kern_table_size); auto it = m_kernAdjs.end(); atUint32 nSubs = r.readUint32Big(); for (atUint32 i=0 ; i> 8 != 0) { r.seek(kernHead.length - 6, athena::Current); continue; } TT_KernSubHead subHead; subHead.read(r); for (atUint16 p=0 ; pfirst != pair.left) if ((it = m_kernAdjs.find(pair.left)) == m_kernAdjs.end()) it = m_kernAdjs.insert(std::make_pair(pair.left, std::vector>())).first; it->second.emplace_back(pair.right, pair.value); } } } } #define NO_ZLIB 0 #define ZLIB_BUF_SZ 32768 static void WriteCompressed(athena::io::FileWriter& writer, const atUint8* data, size_t sz) { #if NO_ZLIB writer.writeUBytes(data, sz); return; #endif atUint8 compBuf[ZLIB_BUF_SZ]; z_stream z = {}; deflateInit(&z, Z_DEFAULT_COMPRESSION); z.next_in = (Bytef*)data; z.avail_in = sz; writer.writeUint32Big(sz); atUint64 adlerPos = writer.position(); writer.writeUint32Big(0); /* Space for adler32 */ while (z.avail_in) { z.next_out = compBuf; z.avail_out = ZLIB_BUF_SZ; deflate(&z, Z_NO_FLUSH); writer.writeUBytes(compBuf, ZLIB_BUF_SZ - z.avail_out); } int finishCycle = Z_OK; while (finishCycle != Z_STREAM_END) { z.next_out = compBuf; z.avail_out = ZLIB_BUF_SZ; finishCycle = deflate(&z, Z_FINISH); writer.writeUBytes(compBuf, ZLIB_BUF_SZ - z.avail_out); } writer.seek(adlerPos, athena::Begin); writer.writeUint32Big(z.adler); deflateEnd(&z); } static bool ReadDecompressed(athena::io::FileReader& reader, atUint8* data, size_t sz) { #if NO_ZLIB reader.readUBytesToBuf(data, sz); return true; #endif atUint8 compBuf[ZLIB_BUF_SZ]; z_stream z = {}; inflateInit(&z); z.next_out = data; atUint32 targetSz = reader.readUint32Big(); atUint32 adler32 = reader.readUint32Big(); z.avail_out = std::min(sz, size_t(targetSz)); size_t readSz; while ((readSz = reader.readUBytesToBuf(compBuf, ZLIB_BUF_SZ))) { z.next_in = compBuf; z.avail_in = readSz; if (inflate(&z, Z_NO_FLUSH) == Z_STREAM_END) break; } inflateEnd(&z); return adler32 == z.adler; } FontAtlas::FontAtlas(boo::IGraphicsDataFactory* gf, FT_Face face, uint32_t dpi, bool subpixel, FCharFilter& filter, athena::io::FileWriter& writer) : m_dpi(dpi), m_ftXscale(face->size->metrics.x_scale), m_ftXPpem(face->size->metrics.x_ppem), m_lineHeight(face->size->metrics.height), m_subpixel(subpixel) { FT_Int32 baseFlags = FT_LOAD_NO_BITMAP; if (subpixel) baseFlags |= FT_LOAD_TARGET_LCD; else baseFlags |= FT_LOAD_TARGET_NORMAL; /* First count glyphs exposed by unicode charmap and tally required area */ size_t glyphCount = 0; FT_UInt gindex; FT_ULong charcode = FT_Get_First_Char(face, &gindex); unsigned curLineWidth = 1; unsigned curLineHeight = 0; unsigned totalHeight = 1; unsigned fullTexmapLayers = 0; while (gindex != 0) { if (!filter.second(charcode)) { charcode = FT_Get_Next_Char(face, charcode, &gindex); continue; } ++glyphCount; FT_Load_Glyph(face, gindex, baseFlags); FT_UInt width, height; GridFitGlyph(face->glyph, width, height); if (curLineWidth + width + 1 > TEXMAP_DIM) { totalHeight += curLineHeight + 1; curLineHeight = 0; curLineWidth = 1; } curLineHeight = std::max(curLineHeight, height); if (totalHeight + curLineHeight + 1 > TEXMAP_DIM) { totalHeight = 1; ++fullTexmapLayers; //printf("StagedB: %u\n", gindex); curLineHeight = 0; curLineWidth = 1; } curLineWidth += width + 1; charcode = FT_Get_Next_Char(face, charcode, &gindex); } if (curLineHeight) totalHeight += curLineHeight + 1; m_glyphs.reserve(glyphCount); m_glyphLookup.reserve(glyphCount); totalHeight = RoundUpPow2(totalHeight); unsigned finalHeight = fullTexmapLayers ? TEXMAP_DIM : totalHeight; writer.writeUint32Big(fullTexmapLayers + 1); writer.writeUint32Big(TEXMAP_DIM); writer.writeUint32Big(finalHeight); if (subpixel) { /* Allocate texmap */ std::unique_ptr texmap; size_t bufSz; if (fullTexmapLayers) { //printf("ALLOC: %u\n", fullTexmapLayers + 1); size_t count = TEXMAP_DIM * TEXMAP_DIM * (fullTexmapLayers + 1); texmap.reset(new RgbaPixel[count]); bufSz = count * sizeof(RgbaPixel); memset(texmap.get(), 0, bufSz); } else { size_t count = TEXMAP_DIM * totalHeight; texmap.reset(new RgbaPixel[count]); bufSz = count * sizeof(RgbaPixel); memset(texmap.get(), 0, bufSz); } /* Assemble glyph texmaps and internal data structures */ charcode = FT_Get_First_Char(face, &gindex); curLineWidth = 1; curLineHeight = 0; totalHeight = 1; fullTexmapLayers = 0; while (gindex != 0) { if (!filter.second(charcode)) { charcode = FT_Get_Next_Char(face, charcode, &gindex); continue; } FT_Load_Glyph(face, gindex, FT_LOAD_RENDER | baseFlags); FT_UInt width, height; GridFitGlyph(face->glyph, width, height); m_glyphLookup[charcode] = m_glyphs.size(); m_glyphs.emplace_back(); Glyph& g = m_glyphs.back(); if (curLineWidth + width + 1 > TEXMAP_DIM) { totalHeight += curLineHeight + 1; curLineHeight = 0; curLineWidth = 1; } curLineHeight = std::max(curLineHeight, height); if (totalHeight + curLineHeight + 1 > TEXMAP_DIM) { totalHeight = 1; ++fullTexmapLayers; //printf("RealB: %u\n", gindex); curLineHeight = 0; curLineWidth = 1; } g.m_unicodePoint = charcode; g.m_glyphIdx = gindex; g.m_layerIdx = fullTexmapLayers; g.m_layerFloat = float(g.m_layerIdx); g.m_width = face->glyph->bitmap.width / 3; g.m_height = face->glyph->bitmap.rows; g.m_uv[0] = curLineWidth / float(TEXMAP_DIM); g.m_uv[1] = totalHeight / float(finalHeight); g.m_uv[2] = g.m_uv[0] + g.m_width / float(TEXMAP_DIM); g.m_uv[3] = g.m_uv[1] + g.m_height / float(finalHeight); g.m_leftPadding = face->glyph->metrics.horiBearingX >> 6; g.m_advance = face->glyph->advance.x >> 6; g.m_verticalOffset = (face->glyph->metrics.horiBearingY - face->glyph->metrics.height) >> 6; MemcpyRect(texmap.get(), &face->glyph->bitmap, fullTexmapLayers, curLineWidth, totalHeight); curLineWidth += width + 1; charcode = FT_Get_Next_Char(face, charcode, &gindex); } WriteCompressed(writer, (atUint8*)texmap.get(), bufSz); m_token = gf->commitTransaction([&](boo::IGraphicsDataFactory::Context& ctx) -> bool { m_tex = ctx.newStaticArrayTexture(TEXMAP_DIM, finalHeight, fullTexmapLayers + 1, boo::TextureFormat::RGBA8, texmap.get(), bufSz); return true; }); } else { /* Allocate texmap */ std::unique_ptr texmap; size_t bufSz; if (fullTexmapLayers) { //printf("ALLOC: %u\n", fullTexmapLayers + 1); size_t count = TEXMAP_DIM * TEXMAP_DIM * (fullTexmapLayers + 1); texmap.reset(new GreyPixel[count]); bufSz = count * sizeof(GreyPixel); memset(texmap.get(), 0, bufSz); } else { size_t count = TEXMAP_DIM * totalHeight; texmap.reset(new GreyPixel[count]); bufSz = count * sizeof(GreyPixel); memset(texmap.get(), 0, bufSz); } /* Assemble glyph texmaps and internal data structures */ charcode = FT_Get_First_Char(face, &gindex); curLineWidth = 1; curLineHeight = 0; totalHeight = 1; fullTexmapLayers = 0; while (gindex != 0) { if (!filter.second(charcode)) { charcode = FT_Get_Next_Char(face, charcode, &gindex); continue; } FT_Load_Glyph(face, gindex, FT_LOAD_RENDER | baseFlags); FT_UInt width, height; GridFitGlyph(face->glyph, width, height); m_glyphLookup[charcode] = m_glyphs.size(); m_glyphs.emplace_back(); Glyph& g = m_glyphs.back(); if (curLineWidth + width + 1 > TEXMAP_DIM) { totalHeight += curLineHeight + 1; curLineHeight = 0; curLineWidth = 1; } curLineHeight = std::max(curLineHeight, height); if (totalHeight + curLineHeight + 1 > TEXMAP_DIM) { totalHeight = 1; ++fullTexmapLayers; //printf("RealB: %u\n", gindex); curLineHeight = 0; curLineWidth = 1; } g.m_unicodePoint = charcode; g.m_glyphIdx = gindex; g.m_layerIdx = fullTexmapLayers; g.m_layerFloat = float(g.m_layerIdx); g.m_width = face->glyph->bitmap.width; g.m_height = face->glyph->bitmap.rows; g.m_uv[0] = curLineWidth / float(TEXMAP_DIM); g.m_uv[1] = totalHeight / float(finalHeight); g.m_uv[2] = g.m_uv[0] + g.m_width / float(TEXMAP_DIM); g.m_uv[3] = g.m_uv[1] + g.m_height / float(finalHeight); g.m_leftPadding = face->glyph->metrics.horiBearingX >> 6; g.m_advance = face->glyph->advance.x >> 6; g.m_verticalOffset = (face->glyph->metrics.horiBearingY - face->glyph->metrics.height) >> 6; MemcpyRect(texmap.get(), &face->glyph->bitmap, fullTexmapLayers, curLineWidth, totalHeight); curLineWidth += width + 1; charcode = FT_Get_Next_Char(face, charcode, &gindex); } WriteCompressed(writer, (atUint8*)texmap.get(), bufSz); m_token = gf->commitTransaction([&](boo::IGraphicsDataFactory::Context& ctx) -> bool { m_tex = ctx.newStaticArrayTexture(TEXMAP_DIM, finalHeight, fullTexmapLayers + 1, boo::TextureFormat::I8, texmap.get(), bufSz); return true; }); } buildKernTable(face); } FontAtlas::FontAtlas(boo::IGraphicsDataFactory* gf, FT_Face face, uint32_t dpi, bool subpixel, FCharFilter& filter, athena::io::FileReader& reader) : m_dpi(dpi), m_ftXscale(face->size->metrics.x_scale), m_ftXPpem(face->size->metrics.x_ppem), m_lineHeight(face->size->metrics.height), m_subpixel(subpixel) { FT_Int32 baseFlags = FT_LOAD_NO_BITMAP; if (subpixel) baseFlags |= FT_LOAD_TARGET_LCD; else baseFlags |= FT_LOAD_TARGET_NORMAL; /* First count glyphs exposed by unicode charmap */ size_t glyphCount = 0; FT_UInt gindex; FT_ULong charcode = FT_Get_First_Char(face, &gindex); while (gindex != 0) { if (!filter.second(charcode)) { charcode = FT_Get_Next_Char(face, charcode, &gindex); continue; } ++glyphCount; charcode = FT_Get_Next_Char(face, charcode, &gindex); } m_glyphs.reserve(glyphCount); m_glyphLookup.reserve(glyphCount); unsigned fullTexmapLayers = reader.readUint32Big() - 1; reader.readUint32Big(); unsigned finalHeight = reader.readUint32Big(); if (subpixel) { /* Allocate texmap */ std::unique_ptr texmap; size_t bufSz; if (fullTexmapLayers) { //printf("ALLOC: %u\n", fullTexmapLayers + 1); size_t count = TEXMAP_DIM * TEXMAP_DIM * (fullTexmapLayers + 1); texmap.reset(new RgbaPixel[count]); bufSz = count * sizeof(RgbaPixel); memset(texmap.get(), 0, bufSz); } else { size_t count = TEXMAP_DIM * finalHeight; texmap.reset(new RgbaPixel[TEXMAP_DIM * finalHeight]); bufSz = count * sizeof(RgbaPixel); memset(texmap.get(), 0, bufSz); } /* Assemble glyph texmaps and internal data structures */ charcode = FT_Get_First_Char(face, &gindex); unsigned curLineWidth = 1; unsigned curLineHeight = 0; unsigned totalHeight = 1; fullTexmapLayers = 0; while (gindex != 0) { if (!filter.second(charcode)) { charcode = FT_Get_Next_Char(face, charcode, &gindex); continue; } FT_Load_Glyph(face, gindex, baseFlags); FT_UInt width, height; GridFitGlyph(face->glyph, width, height); m_glyphLookup[charcode] = m_glyphs.size(); m_glyphs.emplace_back(); Glyph& g = m_glyphs.back(); if (curLineWidth + width + 1 > TEXMAP_DIM) { totalHeight += curLineHeight + 1; curLineHeight = 0; curLineWidth = 1; } curLineHeight = std::max(curLineHeight, height); if (totalHeight + curLineHeight + 1 > TEXMAP_DIM) { totalHeight = 1; ++fullTexmapLayers; //printf("RealB: %u\n", gindex); curLineHeight = 0; curLineWidth = 1; } g.m_unicodePoint = charcode; g.m_glyphIdx = gindex; g.m_layerIdx = fullTexmapLayers; g.m_layerFloat = float(g.m_layerIdx); g.m_width = width; g.m_height = height; g.m_uv[0] = curLineWidth / float(TEXMAP_DIM); g.m_uv[1] = totalHeight / float(finalHeight); g.m_uv[2] = g.m_uv[0] + g.m_width / float(TEXMAP_DIM); g.m_uv[3] = g.m_uv[1] + g.m_height / float(finalHeight); g.m_leftPadding = face->glyph->metrics.horiBearingX >> 6; g.m_advance = face->glyph->advance.x >> 6; g.m_verticalOffset = (face->glyph->metrics.horiBearingY - face->glyph->metrics.height) >> 6; curLineWidth += width + 1; charcode = FT_Get_Next_Char(face, charcode, &gindex); } if (!ReadDecompressed(reader, (atUint8*)texmap.get(), bufSz)) return; m_token = gf->commitTransaction([&](boo::IGraphicsDataFactory::Context& ctx) -> bool { m_tex = ctx.newStaticArrayTexture(TEXMAP_DIM, finalHeight, fullTexmapLayers + 1, boo::TextureFormat::RGBA8, texmap.get(), bufSz); return false; }); } else { /* Allocate texmap */ std::unique_ptr texmap; size_t bufSz; if (fullTexmapLayers) { //printf("ALLOC: %u\n", fullTexmapLayers + 1); size_t count = TEXMAP_DIM * TEXMAP_DIM * (fullTexmapLayers + 1); texmap.reset(new GreyPixel[count]); bufSz = count * sizeof(GreyPixel); memset(texmap.get(), 0, bufSz); } else { size_t count = TEXMAP_DIM * finalHeight; texmap.reset(new GreyPixel[TEXMAP_DIM * finalHeight]); bufSz = count * sizeof(GreyPixel); memset(texmap.get(), 0, bufSz); } /* Assemble glyph texmaps and internal data structures */ charcode = FT_Get_First_Char(face, &gindex); unsigned curLineWidth = 1; unsigned curLineHeight = 0; unsigned totalHeight = 1; fullTexmapLayers = 0; while (gindex != 0) { if (!filter.second(charcode)) { charcode = FT_Get_Next_Char(face, charcode, &gindex); continue; } FT_Load_Glyph(face, gindex, baseFlags); FT_UInt width, height; GridFitGlyph(face->glyph, width, height); m_glyphLookup[charcode] = m_glyphs.size(); m_glyphs.emplace_back(); Glyph& g = m_glyphs.back(); if (curLineWidth + width + 1 > TEXMAP_DIM) { totalHeight += curLineHeight + 1; curLineHeight = 0; curLineWidth = 1; } curLineHeight = std::max(curLineHeight, height); if (totalHeight + curLineHeight + 1 > TEXMAP_DIM) { totalHeight = 1; ++fullTexmapLayers; //printf("RealB: %u\n", gindex); curLineHeight = 0; curLineWidth = 1; } g.m_unicodePoint = charcode; g.m_glyphIdx = gindex; g.m_layerIdx = fullTexmapLayers; g.m_layerFloat = float(g.m_layerIdx); g.m_width = width; g.m_height = height; g.m_uv[0] = curLineWidth / float(TEXMAP_DIM); g.m_uv[1] = totalHeight / float(finalHeight); g.m_uv[2] = g.m_uv[0] + g.m_width / float(TEXMAP_DIM); g.m_uv[3] = g.m_uv[1] + g.m_height / float(finalHeight); g.m_leftPadding = face->glyph->metrics.horiBearingX >> 6; g.m_advance = face->glyph->advance.x >> 6; g.m_verticalOffset = (face->glyph->metrics.horiBearingY - face->glyph->metrics.height) >> 6; curLineWidth += width + 1; charcode = FT_Get_Next_Char(face, charcode, &gindex); } if (!ReadDecompressed(reader, (atUint8*)texmap.get(), bufSz)) return; m_token = gf->commitTransaction([&](boo::IGraphicsDataFactory::Context& ctx) -> bool { m_tex = ctx.newStaticArrayTexture(TEXMAP_DIM, finalHeight, fullTexmapLayers + 1, boo::TextureFormat::I8, texmap.get(), bufSz); return true; }); } buildKernTable(face); } FontCache::Library::Library() { FT_Error err = FT_Init_FreeType(&m_lib); if (err) Log.report(logvisor::Fatal, "unable to FT_Init_FreeType"); } FontCache::Library::~Library() { FT_Done_FreeType(m_lib); } FontCache::FontCache(const hecl::Runtime::FileStoreManager& fileMgr) : m_fileMgr(fileMgr), m_cacheRoot(m_fileMgr.getStoreRoot() + _S("/fontcache")), m_regFace(m_fontLib, DROIDSANS_PERMISSIVE, DROIDSANS_PERMISSIVE_SZ), m_monoFace(m_fontLib, BMONOFONT, BMONOFONT_SZ), m_curvesFace(m_fontLib, SPECTERCURVES, SPECTERCURVES_SZ) {hecl::MakeDir(m_cacheRoot.c_str());} FontTag FontCache::prepCustomFont(boo::IGraphicsDataFactory* gf, const std::string& name, FT_Face face, FCharFilter filter, bool subpixel, float points, uint32_t dpi) { /* Quick validation */ if (!face) Log.report(logvisor::Fatal, "invalid freetype face"); if (!face->charmap || face->charmap->encoding != FT_ENCODING_UNICODE) Log.report(logvisor::Fatal, "font does not contain a unicode char map"); /* Set size with FreeType */ FT_Set_Char_Size(face, 0, points * 64.0, 0, dpi); /* Make tag and search for cached version */ FontTag tag(name + '_' + filter.first, subpixel, points, dpi); auto search = m_cachedAtlases.find(tag); if (search != m_cachedAtlases.end()) return tag; /* Now check filesystem cache */ hecl::SystemString cachePath = m_cacheRoot + _S('/') + hecl::SysFormat(_S("%" PRIx64), tag.hash()); hecl::Sstat st; if (!hecl::Stat(cachePath.c_str(), &st) && S_ISREG(st.st_mode)) { athena::io::FileReader r(cachePath); if (!r.hasError()) { atUint32 magic = r.readUint32Big(); if (r.position() == 4 && magic == 'FONT') { std::unique_ptr fa = std::make_unique(gf, face, dpi, subpixel, filter, r); if (fa->m_tex) { m_cachedAtlases.emplace(tag, std::move(fa)); return tag; } } } } /* Nada, build and cache now */ athena::io::FileWriter w(cachePath); if (w.hasError()) Log.report(logvisor::Fatal, "unable to open '%s' for writing", cachePath.c_str()); w.writeUint32Big('FONT'); m_cachedAtlases.emplace(tag, std::make_unique(gf, face, dpi, subpixel, filter, w)); return tag; } const FontAtlas& FontCache::lookupAtlas(FontTag tag) const { auto search = m_cachedAtlases.find(tag); if (search == m_cachedAtlases.cend()) Log.report(logvisor::Fatal, "invalid font"); return *search->second.get(); } }