// Copyright 2014 Google Inc. All Rights Reserved. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. // // Library for converting WOFF2 format font files to their TTF versions. #include "./woff2_dec.h" #include #include #include #include #include #include #include #include #include "./buffer.h" #include "./decode.h" #include "./round.h" #include "./store_bytes.h" #include "./table_tags.h" #include "./variable_length.h" #include "./woff2_common.h" namespace woff2 { namespace { using std::string; using std::vector; // simple glyph flags const int kGlyfOnCurve = 1 << 0; const int kGlyfXShort = 1 << 1; const int kGlyfYShort = 1 << 2; const int kGlyfRepeat = 1 << 3; const int kGlyfThisXIsSame = 1 << 4; const int kGlyfThisYIsSame = 1 << 5; // composite glyph flags // See CompositeGlyph.java in sfntly for full definitions const int FLAG_ARG_1_AND_2_ARE_WORDS = 1 << 0; const int FLAG_WE_HAVE_A_SCALE = 1 << 3; const int FLAG_MORE_COMPONENTS = 1 << 5; const int FLAG_WE_HAVE_AN_X_AND_Y_SCALE = 1 << 6; const int FLAG_WE_HAVE_A_TWO_BY_TWO = 1 << 7; const int FLAG_WE_HAVE_INSTRUCTIONS = 1 << 8; const size_t kCheckSumAdjustmentOffset = 8; const size_t kEndPtsOfContoursOffset = 10; const size_t kCompositeGlyphBegin = 10; // metadata for a TTC font entry struct TtcFont { uint32_t flavor; uint32_t dst_offset; std::vector table_indices; }; int WithSign(int flag, int baseval) { // Precondition: 0 <= baseval < 65536 (to avoid integer overflow) return (flag & 1) ? baseval : -baseval; } bool TripletDecode(const uint8_t* flags_in, const uint8_t* in, size_t in_size, unsigned int n_points, std::vector* result, size_t* in_bytes_consumed) { int x = 0; int y = 0; if (n_points > in_size) { return FONT_COMPRESSION_FAILURE(); } unsigned int triplet_index = 0; for (unsigned int i = 0; i < n_points; ++i) { uint8_t flag = flags_in[i]; bool on_curve = !(flag >> 7); flag &= 0x7f; unsigned int n_data_bytes; if (flag < 84) { n_data_bytes = 1; } else if (flag < 120) { n_data_bytes = 2; } else if (flag < 124) { n_data_bytes = 3; } else { n_data_bytes = 4; } if (triplet_index + n_data_bytes > in_size || triplet_index + n_data_bytes < triplet_index) { return FONT_COMPRESSION_FAILURE(); } int dx, dy; if (flag < 10) { dx = 0; dy = WithSign(flag, ((flag & 14) << 7) + in[triplet_index]); } else if (flag < 20) { dx = WithSign(flag, (((flag - 10) & 14) << 7) + in[triplet_index]); dy = 0; } else if (flag < 84) { int b0 = flag - 20; int b1 = in[triplet_index]; dx = WithSign(flag, 1 + (b0 & 0x30) + (b1 >> 4)); dy = WithSign(flag >> 1, 1 + ((b0 & 0x0c) << 2) + (b1 & 0x0f)); } else if (flag < 120) { int b0 = flag - 84; dx = WithSign(flag, 1 + ((b0 / 12) << 8) + in[triplet_index]); dy = WithSign(flag >> 1, 1 + (((b0 % 12) >> 2) << 8) + in[triplet_index + 1]); } else if (flag < 124) { int b2 = in[triplet_index + 1]; dx = WithSign(flag, (in[triplet_index] << 4) + (b2 >> 4)); dy = WithSign(flag >> 1, ((b2 & 0x0f) << 8) + in[triplet_index + 2]); } else { dx = WithSign(flag, (in[triplet_index] << 8) + in[triplet_index + 1]); dy = WithSign(flag >> 1, (in[triplet_index + 2] << 8) + in[triplet_index + 3]); } triplet_index += n_data_bytes; // Possible overflow but coordinate values are not security sensitive x += dx; y += dy; result->push_back(Point()); Point& back = result->back(); back.x = x; back.y = y; back.on_curve = on_curve; } *in_bytes_consumed = triplet_index; return true; } // This function stores just the point data. On entry, dst points to the // beginning of a simple glyph. Returns true on success. bool StorePoints(const std::vector& points, unsigned int n_contours, unsigned int instruction_length, uint8_t* dst, size_t dst_size, size_t* glyph_size) { // I believe that n_contours < 65536, in which case this is safe. However, a // comment and/or an assert would be good. unsigned int flag_offset = kEndPtsOfContoursOffset + 2 * n_contours + 2 + instruction_length; int last_flag = -1; int repeat_count = 0; int last_x = 0; int last_y = 0; unsigned int x_bytes = 0; unsigned int y_bytes = 0; for (unsigned int i = 0; i < points.size(); ++i) { const Point& point = points[i]; int flag = point.on_curve ? kGlyfOnCurve : 0; int dx = point.x - last_x; int dy = point.y - last_y; if (dx == 0) { flag |= kGlyfThisXIsSame; } else if (dx > -256 && dx < 256) { flag |= kGlyfXShort | (dx > 0 ? kGlyfThisXIsSame : 0); x_bytes += 1; } else { x_bytes += 2; } if (dy == 0) { flag |= kGlyfThisYIsSame; } else if (dy > -256 && dy < 256) { flag |= kGlyfYShort | (dy > 0 ? kGlyfThisYIsSame : 0); y_bytes += 1; } else { y_bytes += 2; } if (flag == last_flag && repeat_count != 255) { dst[flag_offset - 1] |= kGlyfRepeat; repeat_count++; } else { if (repeat_count != 0) { if (flag_offset >= dst_size) { return FONT_COMPRESSION_FAILURE(); } dst[flag_offset++] = repeat_count; } if (flag_offset >= dst_size) { return FONT_COMPRESSION_FAILURE(); } dst[flag_offset++] = flag; repeat_count = 0; } last_x = point.x; last_y = point.y; last_flag = flag; } if (repeat_count != 0) { if (flag_offset >= dst_size) { return FONT_COMPRESSION_FAILURE(); } dst[flag_offset++] = repeat_count; } unsigned int xy_bytes = x_bytes + y_bytes; if (xy_bytes < x_bytes || flag_offset + xy_bytes < flag_offset || flag_offset + xy_bytes > dst_size) { return FONT_COMPRESSION_FAILURE(); } int x_offset = flag_offset; int y_offset = flag_offset + x_bytes; last_x = 0; last_y = 0; for (unsigned int i = 0; i < points.size(); ++i) { int dx = points[i].x - last_x; if (dx == 0) { // pass } else if (dx > -256 && dx < 256) { dst[x_offset++] = std::abs(dx); } else { // will always fit for valid input, but overflow is harmless x_offset = Store16(dst, x_offset, dx); } last_x += dx; int dy = points[i].y - last_y; if (dy == 0) { // pass } else if (dy > -256 && dy < 256) { dst[y_offset++] = std::abs(dy); } else { y_offset = Store16(dst, y_offset, dy); } last_y += dy; } *glyph_size = y_offset; return true; } // Compute the bounding box of the coordinates, and store into a glyf buffer. // A precondition is that there are at least 10 bytes available. void ComputeBbox(const std::vector& points, uint8_t* dst) { int x_min = 0; int y_min = 0; int x_max = 0; int y_max = 0; for (unsigned int i = 0; i < points.size(); ++i) { int x = points[i].x; int y = points[i].y; if (i == 0 || x < x_min) x_min = x; if (i == 0 || x > x_max) x_max = x; if (i == 0 || y < y_min) y_min = y; if (i == 0 || y > y_max) y_max = y; } size_t offset = 2; offset = Store16(dst, offset, x_min); offset = Store16(dst, offset, y_min); offset = Store16(dst, offset, x_max); offset = Store16(dst, offset, y_max); } // Process entire bbox stream. This is done as a separate pass to allow for // composite bbox computations (an optional more aggressive transform). bool ProcessBboxStream(Buffer* bbox_stream, unsigned int n_glyphs, const std::vector& loca_values, uint8_t* glyf_buf, size_t glyf_buf_length) { const uint8_t* buf = bbox_stream->buffer(); if (n_glyphs >= 65536 || loca_values.size() != n_glyphs + 1) { return FONT_COMPRESSION_FAILURE(); } // Safe because n_glyphs is bounded unsigned int bitmap_length = ((n_glyphs + 31) >> 5) << 2; if (!bbox_stream->Skip(bitmap_length)) { return FONT_COMPRESSION_FAILURE(); } for (unsigned int i = 0; i < n_glyphs; ++i) { if (buf[i >> 3] & (0x80 >> (i & 7))) { uint32_t loca_offset = loca_values[i]; if (loca_values[i + 1] - loca_offset < kEndPtsOfContoursOffset) { return FONT_COMPRESSION_FAILURE(); } if (glyf_buf_length < 2 + 10 || loca_offset > glyf_buf_length - 2 - 10) { return FONT_COMPRESSION_FAILURE(); } if (!bbox_stream->Read(glyf_buf + loca_offset + 2, 8)) { return FONT_COMPRESSION_FAILURE(); } } } return true; } bool ProcessComposite(Buffer* composite_stream, uint8_t* dst, size_t dst_size, size_t* glyph_size, bool* have_instructions) { size_t start_offset = composite_stream->offset(); bool we_have_instructions = false; uint16_t flags = FLAG_MORE_COMPONENTS; while (flags & FLAG_MORE_COMPONENTS) { if (!composite_stream->ReadU16(&flags)) { return FONT_COMPRESSION_FAILURE(); } we_have_instructions |= (flags & FLAG_WE_HAVE_INSTRUCTIONS) != 0; size_t arg_size = 2; // glyph index if (flags & FLAG_ARG_1_AND_2_ARE_WORDS) { arg_size += 4; } else { arg_size += 2; } if (flags & FLAG_WE_HAVE_A_SCALE) { arg_size += 2; } else if (flags & FLAG_WE_HAVE_AN_X_AND_Y_SCALE) { arg_size += 4; } else if (flags & FLAG_WE_HAVE_A_TWO_BY_TWO) { arg_size += 8; } if (!composite_stream->Skip(arg_size)) { return FONT_COMPRESSION_FAILURE(); } } size_t composite_glyph_size = composite_stream->offset() - start_offset; if (composite_glyph_size + kCompositeGlyphBegin > dst_size) { return FONT_COMPRESSION_FAILURE(); } Store16(dst, 0, 0xffff); // nContours = -1 for composite glyph std::memcpy(dst + kCompositeGlyphBegin, composite_stream->buffer() + start_offset, composite_glyph_size); *glyph_size = kCompositeGlyphBegin + composite_glyph_size; *have_instructions = we_have_instructions; return true; } // Build TrueType loca table bool StoreLoca(const std::vector& loca_values, int index_format, uint8_t* dst, size_t dst_size) { const uint64_t loca_size = loca_values.size(); const uint64_t offset_size = index_format ? 4 : 2; if ((loca_size << 2) >> 2 != loca_size) { return FONT_COMPRESSION_FAILURE(); } if (offset_size * loca_size > dst_size) { return FONT_COMPRESSION_FAILURE(); } size_t offset = 0; for (size_t i = 0; i < loca_values.size(); ++i) { uint32_t value = loca_values[i]; if (index_format) { offset = StoreU32(dst, offset, value); } else { offset = Store16(dst, offset, value >> 1); } } return true; } // Reconstruct entire glyf table based on transformed original bool ReconstructGlyf(const uint8_t* data, size_t data_size, uint8_t* dst, size_t dst_size, uint8_t* loca_buf, size_t loca_size) { static const int kNumSubStreams = 7; Buffer file(data, data_size); uint32_t version; std::vector > substreams(kNumSubStreams); if (!file.ReadU32(&version)) { return FONT_COMPRESSION_FAILURE(); } uint16_t num_glyphs; uint16_t index_format; if (!file.ReadU16(&num_glyphs) || !file.ReadU16(&index_format)) { return FONT_COMPRESSION_FAILURE(); } unsigned int offset = (2 + kNumSubStreams) * 4; if (offset > data_size) { return FONT_COMPRESSION_FAILURE(); } // Invariant from here on: data_size >= offset for (int i = 0; i < kNumSubStreams; ++i) { uint32_t substream_size; if (!file.ReadU32(&substream_size)) { return FONT_COMPRESSION_FAILURE(); } if (substream_size > data_size - offset) { return FONT_COMPRESSION_FAILURE(); } substreams[i] = std::make_pair(data + offset, substream_size); offset += substream_size; } Buffer n_contour_stream(substreams[0].first, substreams[0].second); Buffer n_points_stream(substreams[1].first, substreams[1].second); Buffer flag_stream(substreams[2].first, substreams[2].second); Buffer glyph_stream(substreams[3].first, substreams[3].second); Buffer composite_stream(substreams[4].first, substreams[4].second); Buffer bbox_stream(substreams[5].first, substreams[5].second); Buffer instruction_stream(substreams[6].first, substreams[6].second); std::vector loca_values(num_glyphs + 1); std::vector n_points_vec; std::vector points; uint32_t loca_offset = 0; for (unsigned int i = 0; i < num_glyphs; ++i) { size_t glyph_size = 0; uint16_t n_contours = 0; if (!n_contour_stream.ReadU16(&n_contours)) { return FONT_COMPRESSION_FAILURE(); } uint8_t* glyf_dst = dst + loca_offset; size_t glyf_dst_size = dst_size - loca_offset; if (n_contours == 0xffff) { // composite glyph bool have_instructions = false; unsigned int instruction_size = 0; if (!ProcessComposite(&composite_stream, glyf_dst, glyf_dst_size, &glyph_size, &have_instructions)) { return FONT_COMPRESSION_FAILURE(); } if (have_instructions) { if (!Read255UShort(&glyph_stream, &instruction_size)) { return FONT_COMPRESSION_FAILURE(); } if (instruction_size + 2 > glyf_dst_size - glyph_size) { return FONT_COMPRESSION_FAILURE(); } Store16(glyf_dst, glyph_size, instruction_size); if (!instruction_stream.Read(glyf_dst + glyph_size + 2, instruction_size)) { return FONT_COMPRESSION_FAILURE(); } glyph_size += instruction_size + 2; } } else if (n_contours > 0) { // simple glyph n_points_vec.clear(); points.clear(); unsigned int total_n_points = 0; unsigned int n_points_contour; for (unsigned int j = 0; j < n_contours; ++j) { if (!Read255UShort(&n_points_stream, &n_points_contour)) { return FONT_COMPRESSION_FAILURE(); } n_points_vec.push_back(n_points_contour); if (total_n_points + n_points_contour < total_n_points) { return FONT_COMPRESSION_FAILURE(); } total_n_points += n_points_contour; } unsigned int flag_size = total_n_points; if (flag_size > flag_stream.length() - flag_stream.offset()) { return FONT_COMPRESSION_FAILURE(); } const uint8_t* flags_buf = flag_stream.buffer() + flag_stream.offset(); const uint8_t* triplet_buf = glyph_stream.buffer() + glyph_stream.offset(); size_t triplet_size = glyph_stream.length() - glyph_stream.offset(); size_t triplet_bytes_consumed = 0; if (!TripletDecode(flags_buf, triplet_buf, triplet_size, total_n_points, &points, &triplet_bytes_consumed)) { return FONT_COMPRESSION_FAILURE(); } const uint32_t header_and_endpts_contours_size = kEndPtsOfContoursOffset + 2 * n_contours; if (glyf_dst_size < header_and_endpts_contours_size) { return FONT_COMPRESSION_FAILURE(); } Store16(glyf_dst, 0, n_contours); ComputeBbox(points, glyf_dst); size_t offset = kEndPtsOfContoursOffset; int end_point = -1; for (unsigned int contour_ix = 0; contour_ix < n_contours; ++contour_ix) { end_point += n_points_vec[contour_ix]; if (end_point >= 65536) { return FONT_COMPRESSION_FAILURE(); } offset = Store16(glyf_dst, offset, end_point); } if (!flag_stream.Skip(flag_size)) { return FONT_COMPRESSION_FAILURE(); } if (!glyph_stream.Skip(triplet_bytes_consumed)) { return FONT_COMPRESSION_FAILURE(); } unsigned int instruction_size; if (!Read255UShort(&glyph_stream, &instruction_size)) { return FONT_COMPRESSION_FAILURE(); } if (glyf_dst_size - header_and_endpts_contours_size < instruction_size + 2) { return FONT_COMPRESSION_FAILURE(); } uint8_t* instruction_dst = glyf_dst + header_and_endpts_contours_size; Store16(instruction_dst, 0, instruction_size); if (!instruction_stream.Read(instruction_dst + 2, instruction_size)) { return FONT_COMPRESSION_FAILURE(); } if (!StorePoints(points, n_contours, instruction_size, glyf_dst, glyf_dst_size, &glyph_size)) { return FONT_COMPRESSION_FAILURE(); } } else { glyph_size = 0; } loca_values[i] = loca_offset; if (glyph_size + 3 < glyph_size) { return FONT_COMPRESSION_FAILURE(); } glyph_size = Round4(glyph_size); if (glyph_size > dst_size - loca_offset) { // This shouldn't happen, but this test defensively maintains the // invariant that loca_offset <= dst_size. return FONT_COMPRESSION_FAILURE(); } loca_offset += glyph_size; } loca_values[num_glyphs] = loca_offset; if (!ProcessBboxStream(&bbox_stream, num_glyphs, loca_values, dst, dst_size)) { return FONT_COMPRESSION_FAILURE(); } return StoreLoca(loca_values, index_format, loca_buf, loca_size); } // This is linear search, but could be changed to binary because we // do have a guarantee that the tables are sorted by tag. But the total // cpu time is expected to be very small in any case. const Table* FindTable(const std::vector& tables, uint32_t tag) { size_t n_tables = tables.size(); for (size_t i = 0; i < n_tables; ++i) { if (tables[i].tag == tag) { return &tables[i]; } } return NULL; } bool ReconstructTransformedGlyf(const uint8_t* transformed_buf, size_t transformed_size, const Table* glyf_table, const Table* loca_table, uint8_t* dst, size_t dst_length) { if (glyf_table == NULL || loca_table == NULL) { return FONT_COMPRESSION_FAILURE(); } if (static_cast(glyf_table->dst_offset + glyf_table->dst_length) > dst_length) { return FONT_COMPRESSION_FAILURE(); } if (static_cast(loca_table->dst_offset + loca_table->dst_length) > dst_length) { return FONT_COMPRESSION_FAILURE(); } return ReconstructGlyf(transformed_buf, transformed_size, dst + glyf_table->dst_offset, glyf_table->dst_length, dst + loca_table->dst_offset, loca_table->dst_length); } bool ReconstructTransformed(const std::vector

& tables, uint32_t tag, const uint8_t* transformed_buf, size_t transformed_size, uint8_t* dst, size_t dst_length) { if (tag == kGlyfTableTag) { const Table* glyf_table = FindTable(tables, tag); const Table* loca_table = FindTable(tables, kLocaTableTag); return ReconstructTransformedGlyf(transformed_buf, transformed_size, glyf_table, loca_table, dst, dst_length); } else if (tag == kLocaTableTag) { // processing was already done by glyf table, but validate if (!FindTable(tables, kGlyfTableTag)) { return FONT_COMPRESSION_FAILURE(); } } else { // transform for the tag is not known return FONT_COMPRESSION_FAILURE(); } return true; } uint32_t ComputeChecksum(const Table* table, const uint8_t* dst) { return ComputeULongSum(dst + table->dst_offset, table->dst_length); } const Table* FindTable(TtcFont ttc_font, const std::vector

& tables, uint32_t tag) { for (const auto i : ttc_font.table_indices) { if (tables[i].tag == tag) return &tables[i]; } return NULL; } bool FixCollectionChecksums(size_t header_version, const std::vector

& tables, const std::vector& ttc_fonts, uint8_t* dst) { size_t offset = CollectionHeaderSize(header_version, ttc_fonts.size()); for (const auto& ttc_font : ttc_fonts) { offset += 12; // move to start of Offset Table const std::vector& table_indices = ttc_font.table_indices; const Table* head_table = FindTable(ttc_font, tables, kHeadTableTag); if (head_table == NULL || head_table->dst_length < kCheckSumAdjustmentOffset + 4) { return FONT_COMPRESSION_FAILURE(); } size_t first_table_offset = std::numeric_limits::max(); for (const auto index : table_indices) { const auto& table = tables[index]; if (table.dst_offset < first_table_offset) { first_table_offset = table.dst_offset; } } size_t adjustment_offset = head_table->dst_offset + kCheckSumAdjustmentOffset; StoreU32(dst, adjustment_offset, 0); uint32_t file_checksum = 0; // compute each tables checksum for (auto i = 0; i < table_indices.size(); i++) { const Table& table = tables[table_indices[i]]; uint32_t table_checksum = ComputeChecksum(&table, dst); size_t checksum_offset = offset + 4; // skip past tag to checkSum // write the checksum for the Table Record StoreU32(dst, checksum_offset, table_checksum); file_checksum += table_checksum; // next Table Record offset += 16; } size_t header_size = kSfntHeaderSize + kSfntEntrySize * table_indices.size(); uint32_t header_checksum = ComputeULongSum(dst + ttc_font.dst_offset, header_size); file_checksum += header_checksum; uint32_t checksum_adjustment = 0xb1b0afba - file_checksum; StoreU32(dst, adjustment_offset, checksum_adjustment); } return true; } bool FixChecksums(const std::vector

& tables, uint8_t* dst) { const Table* head_table = FindTable(tables, kHeadTableTag); if (head_table == NULL || head_table->dst_length < kCheckSumAdjustmentOffset + 4) { return FONT_COMPRESSION_FAILURE(); } size_t adjustment_offset = head_table->dst_offset + kCheckSumAdjustmentOffset; StoreU32(dst, adjustment_offset, 0); size_t n_tables = tables.size(); uint32_t file_checksum = 0; for (size_t i = 0; i < n_tables; ++i) { uint32_t checksum = ComputeChecksum(&tables[i], dst); StoreU32(dst, kSfntHeaderSize + i * kSfntEntrySize + 4, checksum); file_checksum += checksum; } file_checksum += ComputeULongSum(dst, kSfntHeaderSize + kSfntEntrySize * n_tables); uint32_t checksum_adjustment = 0xb1b0afba - file_checksum; StoreU32(dst, adjustment_offset, checksum_adjustment); return true; } bool Woff2Uncompress(uint8_t* dst_buf, size_t dst_size, const uint8_t* src_buf, size_t src_size) { size_t uncompressed_size = dst_size; int ok = BrotliDecompressBuffer(src_size, src_buf, &uncompressed_size, dst_buf); if (!ok || uncompressed_size != dst_size) { return FONT_COMPRESSION_FAILURE(); } return true; } bool ReadTableDirectory(Buffer* file, std::vector

* tables, size_t num_tables) { for (size_t i = 0; i < num_tables; ++i) { Table* table = &(*tables)[i]; uint8_t flag_byte; if (!file->ReadU8(&flag_byte)) { return FONT_COMPRESSION_FAILURE(); } uint32_t tag; if ((flag_byte & 0x3f) == 0x3f) { if (!file->ReadU32(&tag)) { return FONT_COMPRESSION_FAILURE(); } } else { tag = kKnownTags[flag_byte & 0x3f]; } // Bits 6 and 7 are reserved and must be 0. if ((flag_byte & 0xC0) != 0) { return FONT_COMPRESSION_FAILURE(); } uint32_t flags = 0; if (i > 0) { flags |= kWoff2FlagsContinueStream; } // Always transform the glyf and loca tables if (tag == kGlyfTableTag || tag == kLocaTableTag) { flags |= kWoff2FlagsTransform; } uint32_t dst_length; if (!ReadBase128(file, &dst_length)) { return FONT_COMPRESSION_FAILURE(); } uint32_t transform_length = dst_length; if ((flags & kWoff2FlagsTransform) != 0) { if (!ReadBase128(file, &transform_length)) { return FONT_COMPRESSION_FAILURE(); } if (tag == kLocaTableTag && transform_length) { return FONT_COMPRESSION_FAILURE(); } } table->tag = tag; table->flags = flags; table->transform_length = transform_length; table->dst_length = dst_length; } return true; } } // namespace size_t ComputeWOFF2FinalSize(const uint8_t* data, size_t length) { Buffer file(data, length); uint32_t total_length; if (!file.Skip(16) || !file.ReadU32(&total_length)) { return 0; } return total_length; } // Writes a single Offset Table entry size_t StoreOffsetTable(uint8_t* result, size_t offset, uint32_t flavor, uint16_t num_tables) { offset = StoreU32(result, offset, flavor); // sfnt version offset = Store16(result, offset, num_tables); // num_tables unsigned max_pow2 = 0; while (1u << (max_pow2 + 1) <= num_tables) { max_pow2++; } const uint16_t output_search_range = (1u << max_pow2) << 4; offset = Store16(result, offset, output_search_range); // searchRange offset = Store16(result, offset, max_pow2); // entrySelector // rangeShift offset = Store16(result, offset, (num_tables << 4) - output_search_range); return offset; } size_t StoreTableEntry(uint8_t* result, const Table& table, size_t offset) { offset = StoreU32(result, offset, table.tag); offset = StoreU32(result, offset, 0); // checksum, to fill in later offset = StoreU32(result, offset, table.dst_offset); offset = StoreU32(result, offset, table.dst_length); return offset; } // First table goes after all the headers, table directory, etc uint64_t ComputeOffsetToFirstTable(const uint32_t header_version, const uint16_t num_tables, const std::vector& ttc_fonts) { uint64_t offset = kSfntHeaderSize + kSfntEntrySize * static_cast(num_tables); if (header_version) { offset = CollectionHeaderSize(header_version, ttc_fonts.size()) + kSfntHeaderSize * ttc_fonts.size(); for (const auto& ttc_font : ttc_fonts) { offset += kSfntEntrySize * ttc_font.table_indices.size(); } } return offset; } bool ConvertWOFF2ToTTF(uint8_t* result, size_t result_length, const uint8_t* data, size_t length) { Buffer file(data, length); uint32_t signature; uint32_t flavor; if (!file.ReadU32(&signature) || signature != kWoff2Signature || !file.ReadU32(&flavor)) { return FONT_COMPRESSION_FAILURE(); } // TODO(user): Should call IsValidVersionTag() here. uint32_t reported_length; if (!file.ReadU32(&reported_length) || length != reported_length) { return FONT_COMPRESSION_FAILURE(); } uint16_t num_tables; if (!file.ReadU16(&num_tables) || !num_tables) { return FONT_COMPRESSION_FAILURE(); } // We don't care about these fields of the header: // uint16_t reserved // uint32_t total_sfnt_size, the caller already passes it as result_length if (!file.Skip(6)) { return FONT_COMPRESSION_FAILURE(); } uint32_t compressed_length; if (!file.ReadU32(&compressed_length)) { return FONT_COMPRESSION_FAILURE(); } // We don't care about these fields of the header: // uint16_t major_version, minor_version if (!file.Skip(2 * 2)) { return FONT_COMPRESSION_FAILURE(); } uint32_t meta_offset; uint32_t meta_length; uint32_t meta_length_orig; if (!file.ReadU32(&meta_offset) || !file.ReadU32(&meta_length) || !file.ReadU32(&meta_length_orig)) { return FONT_COMPRESSION_FAILURE(); } if (meta_offset) { if (meta_offset >= length || length - meta_offset < meta_length) { return FONT_COMPRESSION_FAILURE(); } } uint32_t priv_offset; uint32_t priv_length; if (!file.ReadU32(&priv_offset) || !file.ReadU32(&priv_length)) { return FONT_COMPRESSION_FAILURE(); } if (priv_offset) { if (priv_offset >= length || length - priv_offset < priv_length) { return FONT_COMPRESSION_FAILURE(); } } std::vector

tables(num_tables); if (!ReadTableDirectory(&file, &tables, num_tables)) { return FONT_COMPRESSION_FAILURE(); } uint32_t header_version = 0; // for each font in a ttc, metadata to use when rebuilding std::vector ttc_fonts; std::map loca_by_glyf; if (flavor == kTtcFontFlavor) { if (!file.ReadU32(&header_version)) { return FONT_COMPRESSION_FAILURE(); } uint32_t num_fonts; if (!Read255UShort(&file, &num_fonts) || !num_fonts) { return FONT_COMPRESSION_FAILURE(); } ttc_fonts.resize(num_fonts); for (auto i = 0; i < num_fonts; i++) { TtcFont& ttc_font = ttc_fonts[i]; uint32_t num_tables; if (!Read255UShort(&file, &num_tables) || !num_tables) { return FONT_COMPRESSION_FAILURE(); } if (!file.ReadU32(&ttc_font.flavor)) { return FONT_COMPRESSION_FAILURE(); } ttc_font.table_indices.resize(num_tables); const Table* glyf_table = NULL; const Table* loca_table = NULL; uint16_t glyf_idx; uint16_t loca_idx; for (auto j = 0; j < num_tables; j++) { unsigned int table_idx; if (!Read255UShort(&file, &table_idx)) { return FONT_COMPRESSION_FAILURE(); } ttc_font.table_indices[j] = table_idx; const Table& table = tables[table_idx]; if (table.tag == kLocaTableTag) { loca_table = &table; loca_idx = table_idx; } if (table.tag == kGlyfTableTag) { glyf_table = &table; glyf_idx = table_idx; } } if ((glyf_table == NULL) != (loca_table == NULL)) { fprintf(stderr, "Cannot have just one of glyf/loca\n"); return FONT_COMPRESSION_FAILURE(); } if (glyf_table != NULL && loca_table != NULL) { loca_by_glyf[glyf_table] = loca_table; } } } const uint64_t first_table_offset = ComputeOffsetToFirstTable(header_version, num_tables, ttc_fonts); if (first_table_offset > result_length) { return FONT_COMPRESSION_FAILURE(); } uint64_t src_offset = file.offset(); uint64_t dst_offset = first_table_offset; uint64_t uncompressed_sum = 0; for (uint16_t i = 0; i < num_tables; ++i) { Table* table = &tables[i]; table->src_offset = src_offset; table->src_length = (i == 0 ? compressed_length : 0); src_offset += table->src_length; if (src_offset > std::numeric_limits::max()) { return FONT_COMPRESSION_FAILURE(); } src_offset = Round4(src_offset); table->dst_offset = dst_offset; dst_offset += table->dst_length; if (dst_offset > std::numeric_limits::max()) { return FONT_COMPRESSION_FAILURE(); } dst_offset = Round4(dst_offset); uncompressed_sum += table->src_length; if (uncompressed_sum > std::numeric_limits::max()) { return FONT_COMPRESSION_FAILURE(); } } // Enforce same 30M limit on uncompressed tables as OTS if (uncompressed_sum > 30 * 1024 * 1024) { return FONT_COMPRESSION_FAILURE(); } if (src_offset > length || dst_offset != result_length) { fprintf(stderr, "offset fail; src_offset %lu length %lu " "dst_offset %lu result_length %lu\n", src_offset, length, dst_offset, result_length); return FONT_COMPRESSION_FAILURE(); } // Re-order tables in output (OTSpec) order if (header_version) { // collection; we have to sort the table offset vector in each font for (auto& ttc_font : ttc_fonts) { std::map sorted_index_by_tag; for (auto table_index : ttc_font.table_indices) { sorted_index_by_tag[tables[table_index].tag] = table_index; } uint16_t index = 0; for (auto& i : sorted_index_by_tag) { ttc_font.table_indices[index++] = i.second; } } } else { // non-collection; we can just sort the tables std::sort(tables.begin(), tables.end()); } if (meta_offset) { if (src_offset != meta_offset) { return FONT_COMPRESSION_FAILURE(); } src_offset = Round4(meta_offset + meta_length); if (src_offset > std::numeric_limits::max()) { return FONT_COMPRESSION_FAILURE(); } } if (priv_offset) { if (src_offset != priv_offset) { return FONT_COMPRESSION_FAILURE(); } src_offset = Round4(priv_offset + priv_length); if (src_offset > std::numeric_limits::max()) { return FONT_COMPRESSION_FAILURE(); } } if (src_offset != Round4(length)) { return FONT_COMPRESSION_FAILURE(); } // Start building the font size_t offset = 0; size_t offset_table = 0; if (header_version) { // TTC header offset = StoreU32(result, offset, flavor); // TAG TTCTag offset = StoreU32(result, offset, header_version); // FIXED Version offset = StoreU32(result, offset, ttc_fonts.size()); // ULONG numFonts // Space for ULONG OffsetTable[numFonts] (zeroed initially) offset_table = offset; // keep start of offset table for later for (int i = 0; i < ttc_fonts.size(); i++) { offset = StoreU32(result, offset, 0); // will fill real values in later } // space for DSIG fields for header v2 if (header_version == 0x00020000) { offset = StoreU32(result, offset, 0); // ULONG ulDsigTag offset = StoreU32(result, offset, 0); // ULONG ulDsigLength offset = StoreU32(result, offset, 0); // ULONG ulDsigOffset } // write Offset Tables and store the location of each in TTC Header for (auto& ttc_font : ttc_fonts) { // write Offset Table location into TTC Header offset_table = StoreU32(result, offset_table, offset); // write the actual offset table so our header doesn't lie ttc_font.dst_offset = offset; offset = StoreOffsetTable(result, offset, ttc_font.flavor, ttc_font.table_indices.size()); // write table entries for (const auto table_index : ttc_font.table_indices) { offset = StoreTableEntry(result, tables[table_index], offset); } } } else { offset = StoreOffsetTable(result, offset, flavor, num_tables); for (uint16_t i = 0; i < num_tables; ++i) { offset = StoreTableEntry(result, tables[i], offset); } } std::vector uncompressed_buf; bool continue_valid = false; const uint8_t* transform_buf = NULL; for (uint16_t i = 0; i < num_tables; ++i) { const Table* table = &tables[i]; uint32_t flags = table->flags; const uint8_t* src_buf = data + table->src_offset; size_t transform_length = table->transform_length; if ((flags & kWoff2FlagsContinueStream) != 0) { if (!continue_valid) { return FONT_COMPRESSION_FAILURE(); } } else if ((flags & kWoff2FlagsContinueStream) == 0) { uint64_t total_size = transform_length; for (uint16_t j = i + 1; j < num_tables; ++j) { if ((tables[j].flags & kWoff2FlagsContinueStream) == 0) { break; } total_size += tables[j].transform_length; if (total_size > std::numeric_limits::max()) { return FONT_COMPRESSION_FAILURE(); } } uncompressed_buf.resize(total_size); if (!Woff2Uncompress(&uncompressed_buf[0], total_size, src_buf, compressed_length)) { return FONT_COMPRESSION_FAILURE(); } transform_buf = &uncompressed_buf[0]; continue_valid = true; } else { return FONT_COMPRESSION_FAILURE(); } if ((flags & kWoff2FlagsTransform) == 0) { if (transform_length != table->dst_length) { return FONT_COMPRESSION_FAILURE(); } if (static_cast(table->dst_offset + transform_length) > result_length) { return FONT_COMPRESSION_FAILURE(); } std::memcpy(result + table->dst_offset, transform_buf, transform_length); } else { if (header_version) { if (table->tag == kGlyfTableTag) { const Table* loca_table = loca_by_glyf[table]; if (!ReconstructTransformedGlyf(transform_buf, transform_length, table, loca_table, result, result_length)) { return FONT_COMPRESSION_FAILURE(); } } else if (table->tag != kLocaTableTag) { // transform for this tag not known return FONT_COMPRESSION_FAILURE(); } } else { if (!ReconstructTransformed(tables, table->tag, transform_buf, transform_length, result, result_length)) { return FONT_COMPRESSION_FAILURE(); } } } if (continue_valid) { transform_buf += transform_length; if (transform_buf > &uncompressed_buf[0] + uncompressed_buf.size()) { return FONT_COMPRESSION_FAILURE(); } } } if (header_version) { if (!FixCollectionChecksums(header_version, tables, ttc_fonts, result)) { return FONT_COMPRESSION_FAILURE(); } } else { if (!FixChecksums(tables, result)) { return FONT_COMPRESSION_FAILURE(); } } return true; } } // namespace woff2