// Copyright (c) 2014 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. // We use an underscore to avoid confusion with the standard math.h library. #include "math_.h" #include #include #include "layout.h" #include "maxp.h" // MATH - The MATH Table // The specification is not yet public but has been submitted to the MPEG group // in response to the 'Call for Proposals for ISO/IEC 14496-22 "Open Font // Format" Color Font Technology and MATH layout support'. Meanwhile, you can // contact Microsoft's engineer Murray Sargent to obtain a copy. #define TABLE_NAME "MATH" namespace { // The size of MATH header. // Version // MathConstants // MathGlyphInfo // MathVariants const unsigned kMathHeaderSize = 4 + 3 * 2; // The size of the MathGlyphInfo header. // MathItalicsCorrectionInfo // MathTopAccentAttachment // ExtendedShapeCoverage // MathKernInfo const unsigned kMathGlyphInfoHeaderSize = 4 * 2; // The size of the MathValueRecord. // Value // DeviceTable const unsigned kMathValueRecordSize = 2 * 2; // The size of the GlyphPartRecord. // glyph // StartConnectorLength // EndConnectorLength // FullAdvance // PartFlags const unsigned kGlyphPartRecordSize = 5 * 2; // Shared Table: MathValueRecord bool ParseMathValueRecord(const ots::Font *font, ots::Buffer* subtable, const uint8_t *data, const size_t length) { // Check the Value field. if (!subtable->Skip(2)) { return OTS_FAILURE(); } // Check the offset to device table. uint16_t offset = 0; if (!subtable->ReadU16(&offset)) { return OTS_FAILURE(); } if (offset) { if (offset >= length) { return OTS_FAILURE(); } if (!ots::ParseDeviceTable(font, data + offset, length - offset)) { return OTS_FAILURE(); } } return true; } bool ParseMathConstantsTable(const ots::Font *font, const uint8_t *data, size_t length) { ots::Buffer subtable(data, length); // Part 1: int16 or uint16 constants. // ScriptPercentScaleDown // ScriptScriptPercentScaleDown // DelimitedSubFormulaMinHeight // DisplayOperatorMinHeight if (!subtable.Skip(4 * 2)) { return OTS_FAILURE(); } // Part 2: MathValueRecord constants. // MathLeading // AxisHeight // AccentBaseHeight // FlattenedAccentBaseHeight // SubscriptShiftDown // SubscriptTopMax // SubscriptBaselineDropMin // SuperscriptShiftUp // SuperscriptShiftUpCramped // SuperscriptBottomMin // // SuperscriptBaselineDropMax // SubSuperscriptGapMin // SuperscriptBottomMaxWithSubscript // SpaceAfterScript // UpperLimitGapMin // UpperLimitBaselineRiseMin // LowerLimitGapMin // LowerLimitBaselineDropMin // StackTopShiftUp // StackTopDisplayStyleShiftUp // // StackBottomShiftDown // StackBottomDisplayStyleShiftDown // StackGapMin // StackDisplayStyleGapMin // StretchStackTopShiftUp // StretchStackBottomShiftDown // StretchStackGapAboveMin // StretchStackGapBelowMin // FractionNumeratorShiftUp // FractionNumeratorDisplayStyleShiftUp // // FractionDenominatorShiftDown // FractionDenominatorDisplayStyleShiftDown // FractionNumeratorGapMin // FractionNumDisplayStyleGapMin // FractionRuleThickness // FractionDenominatorGapMin // FractionDenomDisplayStyleGapMin // SkewedFractionHorizontalGap // SkewedFractionVerticalGap // OverbarVerticalGap // // OverbarRuleThickness // OverbarExtraAscender // UnderbarVerticalGap // UnderbarRuleThickness // UnderbarExtraDescender // RadicalVerticalGap // RadicalDisplayStyleVerticalGap // RadicalRuleThickness // RadicalExtraAscender // RadicalKernBeforeDegree // // RadicalKernAfterDegree for (unsigned i = 0; i < static_cast(51); ++i) { if (!ParseMathValueRecord(font, &subtable, data, length)) { return OTS_FAILURE(); } } // Part 3: uint16 constant // RadicalDegreeBottomRaisePercent if (!subtable.Skip(2)) { return OTS_FAILURE(); } return true; } bool ParseMathValueRecordSequenceForGlyphs(const ots::Font *font, ots::Buffer* subtable, const uint8_t *data, const size_t length, const uint16_t num_glyphs) { // Check the header. uint16_t offset_coverage = 0; uint16_t sequence_count = 0; if (!subtable->ReadU16(&offset_coverage) || !subtable->ReadU16(&sequence_count)) { return OTS_FAILURE(); } const unsigned sequence_end = static_cast(2 * 2) + sequence_count * kMathValueRecordSize; if (sequence_end > std::numeric_limits::max()) { return OTS_FAILURE(); } // Check coverage table. if (offset_coverage < sequence_end || offset_coverage >= length) { return OTS_FAILURE(); } if (!ots::ParseCoverageTable(font, data + offset_coverage, length - offset_coverage, num_glyphs, sequence_count)) { return OTS_FAILURE(); } // Check sequence. for (unsigned i = 0; i < sequence_count; ++i) { if (!ParseMathValueRecord(font, subtable, data, length)) { return OTS_FAILURE(); } } return true; } bool ParseMathItalicsCorrectionInfoTable(const ots::Font *font, const uint8_t *data, size_t length, const uint16_t num_glyphs) { ots::Buffer subtable(data, length); return ParseMathValueRecordSequenceForGlyphs(font, &subtable, data, length, num_glyphs); } bool ParseMathTopAccentAttachmentTable(const ots::Font *font, const uint8_t *data, size_t length, const uint16_t num_glyphs) { ots::Buffer subtable(data, length); return ParseMathValueRecordSequenceForGlyphs(font, &subtable, data, length, num_glyphs); } bool ParseMathKernTable(const ots::Font *font, const uint8_t *data, size_t length) { ots::Buffer subtable(data, length); // Check the Height count. uint16_t height_count = 0; if (!subtable.ReadU16(&height_count)) { return OTS_FAILURE(); } // Check the Correction Heights. for (unsigned i = 0; i < height_count; ++i) { if (!ParseMathValueRecord(font, &subtable, data, length)) { return OTS_FAILURE(); } } // Check the Kern Values. for (unsigned i = 0; i <= height_count; ++i) { if (!ParseMathValueRecord(font, &subtable, data, length)) { return OTS_FAILURE(); } } return true; } bool ParseMathKernInfoTable(const ots::Font *font, const uint8_t *data, size_t length, const uint16_t num_glyphs) { ots::Buffer subtable(data, length); // Check the header. uint16_t offset_coverage = 0; uint16_t sequence_count = 0; if (!subtable.ReadU16(&offset_coverage) || !subtable.ReadU16(&sequence_count)) { return OTS_FAILURE(); } const unsigned sequence_end = static_cast(2 * 2) + sequence_count * 4 * 2; if (sequence_end > std::numeric_limits::max()) { return OTS_FAILURE(); } // Check coverage table. if (offset_coverage < sequence_end || offset_coverage >= length) { return OTS_FAILURE(); } if (!ots::ParseCoverageTable(font, data + offset_coverage, length - offset_coverage, num_glyphs, sequence_count)) { return OTS_FAILURE(); } // Check sequence of MathKernInfoRecord for (unsigned i = 0; i < sequence_count; ++i) { // Check TopRight, TopLeft, BottomRight and BottomLeft Math Kern. for (unsigned j = 0; j < 4; ++j) { uint16_t offset_math_kern = 0; if (!subtable.ReadU16(&offset_math_kern)) { return OTS_FAILURE(); } if (offset_math_kern) { if (offset_math_kern < sequence_end || offset_math_kern >= length || !ParseMathKernTable(font, data + offset_math_kern, length - offset_math_kern)) { return OTS_FAILURE(); } } } } return true; } bool ParseMathGlyphInfoTable(const ots::Font *font, const uint8_t *data, size_t length, const uint16_t num_glyphs) { ots::Buffer subtable(data, length); // Check Header. uint16_t offset_math_italics_correction_info = 0; uint16_t offset_math_top_accent_attachment = 0; uint16_t offset_extended_shaped_coverage = 0; uint16_t offset_math_kern_info = 0; if (!subtable.ReadU16(&offset_math_italics_correction_info) || !subtable.ReadU16(&offset_math_top_accent_attachment) || !subtable.ReadU16(&offset_extended_shaped_coverage) || !subtable.ReadU16(&offset_math_kern_info)) { return OTS_FAILURE(); } // Check subtables. // The specification does not say whether the offsets for // MathItalicsCorrectionInfo, MathTopAccentAttachment and MathKernInfo may // be NULL, but that's the case in some fonts (e.g STIX) so we accept that. if (offset_math_italics_correction_info) { if (offset_math_italics_correction_info >= length || offset_math_italics_correction_info < kMathGlyphInfoHeaderSize || !ParseMathItalicsCorrectionInfoTable( font, data + offset_math_italics_correction_info, length - offset_math_italics_correction_info, num_glyphs)) { return OTS_FAILURE(); } } if (offset_math_top_accent_attachment) { if (offset_math_top_accent_attachment >= length || offset_math_top_accent_attachment < kMathGlyphInfoHeaderSize || !ParseMathTopAccentAttachmentTable(font, data + offset_math_top_accent_attachment, length - offset_math_top_accent_attachment, num_glyphs)) { return OTS_FAILURE(); } } if (offset_extended_shaped_coverage) { if (offset_extended_shaped_coverage >= length || offset_extended_shaped_coverage < kMathGlyphInfoHeaderSize || !ots::ParseCoverageTable(font, data + offset_extended_shaped_coverage, length - offset_extended_shaped_coverage, num_glyphs)) { return OTS_FAILURE(); } } if (offset_math_kern_info) { if (offset_math_kern_info >= length || offset_math_kern_info < kMathGlyphInfoHeaderSize || !ParseMathKernInfoTable(font, data + offset_math_kern_info, length - offset_math_kern_info, num_glyphs)) { return OTS_FAILURE(); } } return true; } bool ParseGlyphAssemblyTable(const ots::Font *font, const uint8_t *data, size_t length, const uint16_t num_glyphs) { ots::Buffer subtable(data, length); // Check the header. uint16_t part_count = 0; if (!ParseMathValueRecord(font, &subtable, data, length) || !subtable.ReadU16(&part_count)) { return OTS_FAILURE(); } const unsigned sequence_end = kMathValueRecordSize + static_cast(2) + part_count * kGlyphPartRecordSize; if (sequence_end > std::numeric_limits::max()) { return OTS_FAILURE(); } // Check the sequence of GlyphPartRecord. for (unsigned i = 0; i < part_count; ++i) { uint16_t glyph = 0; uint16_t part_flags = 0; if (!subtable.ReadU16(&glyph) || !subtable.Skip(2 * 3) || !subtable.ReadU16(&part_flags)) { return OTS_FAILURE(); } if (glyph >= num_glyphs) { return OTS_FAILURE_MSG("bad glyph ID: %u", glyph); } if (part_flags & ~0x00000001) { return OTS_FAILURE_MSG("unknown part flag: %u", part_flags); } } return true; } bool ParseMathGlyphConstructionTable(const ots::Font *font, const uint8_t *data, size_t length, const uint16_t num_glyphs) { ots::Buffer subtable(data, length); // Check the header. uint16_t offset_glyph_assembly = 0; uint16_t variant_count = 0; if (!subtable.ReadU16(&offset_glyph_assembly) || !subtable.ReadU16(&variant_count)) { return OTS_FAILURE(); } const unsigned sequence_end = static_cast(2 * 2) + variant_count * 2 * 2; if (sequence_end > std::numeric_limits::max()) { return OTS_FAILURE(); } // Check the GlyphAssembly offset. if (offset_glyph_assembly) { if (offset_glyph_assembly >= length || offset_glyph_assembly < sequence_end) { return OTS_FAILURE(); } if (!ParseGlyphAssemblyTable(font, data + offset_glyph_assembly, length - offset_glyph_assembly, num_glyphs)) { return OTS_FAILURE(); } } // Check the sequence of MathGlyphVariantRecord. for (unsigned i = 0; i < variant_count; ++i) { uint16_t glyph = 0; if (!subtable.ReadU16(&glyph) || !subtable.Skip(2)) { return OTS_FAILURE(); } if (glyph >= num_glyphs) { return OTS_FAILURE_MSG("bad glyph ID: %u", glyph); } } return true; } bool ParseMathGlyphConstructionSequence(const ots::Font *font, ots::Buffer* subtable, const uint8_t *data, size_t length, const uint16_t num_glyphs, uint16_t offset_coverage, uint16_t glyph_count, const unsigned sequence_end) { // Zero glyph count, nothing to parse. if (!glyph_count) { return true; } // Check coverage table. if (offset_coverage < sequence_end || offset_coverage >= length) { return OTS_FAILURE(); } if (!ots::ParseCoverageTable(font, data + offset_coverage, length - offset_coverage, num_glyphs, glyph_count)) { return OTS_FAILURE(); } // Check sequence of MathGlyphConstruction. for (unsigned i = 0; i < glyph_count; ++i) { uint16_t offset_glyph_construction = 0; if (!subtable->ReadU16(&offset_glyph_construction)) { return OTS_FAILURE(); } if (offset_glyph_construction < sequence_end || offset_glyph_construction >= length || !ParseMathGlyphConstructionTable(font, data + offset_glyph_construction, length - offset_glyph_construction, num_glyphs)) { return OTS_FAILURE(); } } return true; } bool ParseMathVariantsTable(const ots::Font *font, const uint8_t *data, size_t length, const uint16_t num_glyphs) { ots::Buffer subtable(data, length); // Check the header. uint16_t offset_vert_glyph_coverage = 0; uint16_t offset_horiz_glyph_coverage = 0; uint16_t vert_glyph_count = 0; uint16_t horiz_glyph_count = 0; if (!subtable.Skip(2) || // MinConnectorOverlap !subtable.ReadU16(&offset_vert_glyph_coverage) || !subtable.ReadU16(&offset_horiz_glyph_coverage) || !subtable.ReadU16(&vert_glyph_count) || !subtable.ReadU16(&horiz_glyph_count)) { return OTS_FAILURE(); } const unsigned sequence_end = 5 * 2 + vert_glyph_count * 2 + horiz_glyph_count * 2; if (sequence_end > std::numeric_limits::max()) { return OTS_FAILURE(); } if (!ParseMathGlyphConstructionSequence(font, &subtable, data, length, num_glyphs, offset_vert_glyph_coverage, vert_glyph_count, sequence_end) || !ParseMathGlyphConstructionSequence(font, &subtable, data, length, num_glyphs, offset_horiz_glyph_coverage, horiz_glyph_count, sequence_end)) { return OTS_FAILURE(); } return true; } } // namespace #define DROP_THIS_TABLE(msg_) \ do { \ OTS_FAILURE_MSG(msg_ ", table discarded"); \ font->math->data = 0; \ font->math->length = 0; \ } while (0) namespace ots { bool ots_math_parse(Font *font, const uint8_t *data, size_t length) { // Grab the number of glyphs in the font from the maxp table to check // GlyphIDs in MATH table. if (!font->maxp) { return OTS_FAILURE(); } const uint16_t num_glyphs = font->maxp->num_glyphs; Buffer table(data, length); OpenTypeMATH* math = new OpenTypeMATH; font->math = math; uint32_t version = 0; if (!table.ReadU32(&version)) { return OTS_FAILURE(); } if (version != 0x00010000) { DROP_THIS_TABLE("bad MATH version"); return true; } uint16_t offset_math_constants = 0; uint16_t offset_math_glyph_info = 0; uint16_t offset_math_variants = 0; if (!table.ReadU16(&offset_math_constants) || !table.ReadU16(&offset_math_glyph_info) || !table.ReadU16(&offset_math_variants)) { return OTS_FAILURE(); } if (offset_math_constants >= length || offset_math_constants < kMathHeaderSize || offset_math_glyph_info >= length || offset_math_glyph_info < kMathHeaderSize || offset_math_variants >= length || offset_math_variants < kMathHeaderSize) { DROP_THIS_TABLE("bad offset in MATH header"); return true; } if (!ParseMathConstantsTable(font, data + offset_math_constants, length - offset_math_constants)) { DROP_THIS_TABLE("failed to parse MathConstants table"); return true; } if (!ParseMathGlyphInfoTable(font, data + offset_math_glyph_info, length - offset_math_glyph_info, num_glyphs)) { DROP_THIS_TABLE("failed to parse MathGlyphInfo table"); return true; } if (!ParseMathVariantsTable(font, data + offset_math_variants, length - offset_math_variants, num_glyphs)) { DROP_THIS_TABLE("failed to parse MathVariants table"); return true; } math->data = data; math->length = length; return true; } bool ots_math_should_serialise(Font *font) { return font->math != NULL && font->math->data != NULL; } bool ots_math_serialise(OTSStream *out, Font *font) { if (!out->Write(font->math->data, font->math->length)) { return OTS_FAILURE(); } return true; } void ots_math_reuse(Font *font, Font *other) { font->math = other->math; font->math_reused = true; } void ots_math_free(Font *font) { delete font->math; } } // namespace ots #undef TABLE_NAME #undef DROP_THIS_TABLE