// SPDX-License-Identifier: MIT OR MPL-2.0 OR LGPL-2.1-or-later OR GPL-2.0-or-later // Copyright 2012, SIL International, All rights reserved. #include "graphite2/Font.h" #include "inc/Main.h" #include "inc/Face.h" //for the tags #include "inc/GlyphCache.h" #include "inc/GlyphFace.h" #include "inc/Endian.h" #include "inc/bits.h" using namespace graphite2; namespace { // Iterator over version 1 or 2 glat entries which consist of a series of // +-+-+-+-+-+-+-+-+-+-+ +-+-+-+-+-+-+-+-+-+-+-+-+ // v1 |k|n|v1 |v2 |...|vN | or v2 | k | n |v1 |v2 |...|vN | // +-+-+-+-+-+-+-+-+-+-+ +-+-+-+-+-+-+-+-+-+-+-+-+ // variable length structures. template class _glat_iterator { unsigned short key() const { return uint16(be::peek(_e) + _n); } unsigned int run() const { return be::peek(_e+sizeof(W)); } void advance_entry() { _n = 0; _e = _v; be::skip(_v,2); } public: using iterator_category = std::input_iterator_tag; using value_type = std::pair; using difference_type = ptrdiff_t; using pointer = value_type *; using reference = value_type &; _glat_iterator(const void * glat=0) : _e(reinterpret_cast(glat)), _v(_e+2*sizeof(W)), _n(0) {} _glat_iterator & operator ++ () { ++_n; be::skip(_v); if (_n == run()) advance_entry(); return *this; } _glat_iterator operator ++ (int) { _glat_iterator tmp(*this); operator++(); return tmp; } // This is strictly a >= operator. A true == operator could be // implemented that test for overlap but it would be more expensive a // test. bool operator == (const _glat_iterator & rhs) { return _v >= rhs._e - 1; } bool operator != (const _glat_iterator & rhs) { return !operator==(rhs); } value_type operator * () const { return value_type(key(), be::peek(_v)); } protected: const byte * _e, * _v; size_t _n; }; typedef _glat_iterator glat_iterator; typedef _glat_iterator glat2_iterator; } const SlantBox SlantBox::empty = {0,0,0,0}; class GlyphCache::Loader { public: Loader(const Face & face); //return result indicates success. Do not use if failed. operator bool () const throw(); unsigned short int units_per_em() const throw(); unsigned short int num_glyphs() const throw(); unsigned short int num_attrs() const throw(); bool has_boxes() const throw(); const GlyphFace * read_glyph(unsigned short gid, GlyphFace &, int *numsubs) const throw(); GlyphBox * read_box(uint16 gid, GlyphBox *curr, const GlyphFace & face) const throw(); CLASS_NEW_DELETE; private: Face::Table _head, _hhea, _hmtx, _glyf, _loca, m_pGlat, m_pGloc; bool _long_fmt; bool _has_boxes; unsigned short _num_glyphs_graphics, //i.e. boundary box and advance _num_glyphs_attributes, _num_attrs; // number of glyph attributes per glyph }; GlyphCache::GlyphCache(const Face & face, const uint32 face_options) : _glyph_loader(new Loader(face)), _glyphs(_glyph_loader && *_glyph_loader && _glyph_loader->num_glyphs() ? grzeroalloc(_glyph_loader->num_glyphs()) : 0), _boxes(_glyph_loader && _glyph_loader->has_boxes() && _glyph_loader->num_glyphs() ? grzeroalloc(_glyph_loader->num_glyphs()) : 0), _num_glyphs(_glyphs ? _glyph_loader->num_glyphs() : 0), _num_attrs(_glyphs ? _glyph_loader->num_attrs() : 0), _upem(_glyphs ? _glyph_loader->units_per_em() : 0) { if ((face_options & gr_face_preloadGlyphs) && _glyph_loader && _glyphs) { int numsubs = 0; GlyphFace * const glyphs = new GlyphFace [_num_glyphs]; if (!glyphs) return; // The 0 glyph is definately required. _glyphs[0] = _glyph_loader->read_glyph(0, glyphs[0], &numsubs); // glyphs[0] has the same address as the glyphs array just allocated, // thus assigning the &glyphs[0] to _glyphs[0] means _glyphs[0] points // to the entire array. const GlyphFace * loaded = _glyphs[0]; for (uint16 gid = 1; loaded && gid != _num_glyphs; ++gid) _glyphs[gid] = loaded = _glyph_loader->read_glyph(gid, glyphs[gid], &numsubs); if (!loaded) { _glyphs[0] = 0; delete [] glyphs; } else if (numsubs > 0 && _boxes) { GlyphBox * boxes = (GlyphBox *)gralloc(_num_glyphs * sizeof(GlyphBox) + numsubs * 8 * sizeof(float)); GlyphBox * currbox = boxes; for (uint16 gid = 0; currbox && gid != _num_glyphs; ++gid) { _boxes[gid] = currbox; currbox = _glyph_loader->read_box(gid, currbox, *_glyphs[gid]); } if (!currbox) { free(boxes); _boxes[0] = 0; } } delete _glyph_loader; _glyph_loader = 0; // coverity[leaked_storage : FALSE] - calling read_glyph on index 0 saved // glyphs as _glyphs[0]. Setting _glyph_loader to nullptr here flags that // the dtor needs to call delete[] on _glyphs[0] to release what was allocated // as glyphs } if (_glyphs && glyph(0) == 0) { free(_glyphs); _glyphs = 0; if (_boxes) { free(_boxes); _boxes = 0; } _num_glyphs = _num_attrs = _upem = 0; } } GlyphCache::~GlyphCache() { if (_glyphs) { if (_glyph_loader) { const GlyphFace * * g = _glyphs; for(unsigned short n = _num_glyphs; n; --n, ++g) delete *g; } else delete [] _glyphs[0]; free(_glyphs); } if (_boxes) { if (_glyph_loader) { GlyphBox * * g = _boxes; for (uint16 n = _num_glyphs; n; --n, ++g) free(*g); } else free(_boxes[0]); free(_boxes); } delete _glyph_loader; } const GlyphFace *GlyphCache::glyph(unsigned short glyphid) const //result may be changed by subsequent call with a different glyphid { if (glyphid >= numGlyphs()) return _glyphs[0]; const GlyphFace * & p = _glyphs[glyphid]; if (p == 0 && _glyph_loader) { int numsubs = 0; GlyphFace * g = new GlyphFace(); if (g) p = _glyph_loader->read_glyph(glyphid, *g, &numsubs); if (!p) { delete g; return *_glyphs; } if (_boxes) { _boxes[glyphid] = (GlyphBox *)gralloc(sizeof(GlyphBox) + 8 * numsubs * sizeof(float)); if (!_glyph_loader->read_box(glyphid, _boxes[glyphid], *_glyphs[glyphid])) { free(_boxes[glyphid]); _boxes[glyphid] = 0; } } } return p; } GlyphCache::Loader::Loader(const Face & face) : _head(face, Tag::head), _hhea(face, Tag::hhea), _hmtx(face, Tag::hmtx), _glyf(face, Tag::glyf), _loca(face, Tag::loca), _long_fmt(false), _has_boxes(false), _num_glyphs_graphics(0), _num_glyphs_attributes(0), _num_attrs(0) { if (!operator bool()) return; const Face::Table maxp = Face::Table(face, Tag::maxp); if (!maxp) { _head = Face::Table(); return; } _num_glyphs_graphics = static_cast(TtfUtil::GlyphCount(maxp)); // This will fail if the number of glyphs is wildly out of range. if (_glyf && TtfUtil::LocaLookup(_num_glyphs_graphics-1, _loca, _loca.size(), _head) == size_t(-2)) { _head = Face::Table(); return; } if ((m_pGlat = Face::Table(face, Tag::Glat, 0x00030000)) == NULL || (m_pGloc = Face::Table(face, Tag::Gloc)) == NULL || m_pGloc.size() < 8) { _head = Face::Table(); return; } const byte * p = m_pGloc; int version = be::read(p); const uint16 flags = be::read(p); _num_attrs = be::read(p); // We can accurately calculate the number of attributed glyphs by // subtracting the length of the attribids array (numAttribs long if present) // and dividing by either 2 or 4 depending on shor or lonf format _long_fmt = flags & 1; ptrdiff_t tmpnumgattrs = (m_pGloc.size() - (p - m_pGloc) - sizeof(uint16)*(flags & 0x2 ? _num_attrs : 0)) / (_long_fmt ? sizeof(uint32) : sizeof(uint16)) - 1; if (version >= 0x00020000 || tmpnumgattrs < 0 || tmpnumgattrs > 65535 || _num_attrs == 0 || _num_attrs > 0x3000 // is this hard limit appropriate? || _num_glyphs_graphics > tmpnumgattrs || m_pGlat.size() < 4) { _head = Face::Table(); return; } _num_glyphs_attributes = static_cast(tmpnumgattrs); p = m_pGlat; version = be::read(p); if (version >= 0x00040000 || (version >= 0x00030000 && m_pGlat.size() < 8)) // reject Glat tables that are too new { _head = Face::Table(); return; } else if (version >= 0x00030000) { unsigned int glatflags = be::read(p); _has_boxes = glatflags & 1; // delete this once the compiler is fixed _has_boxes = true; } } inline GlyphCache::Loader::operator bool () const throw() { return _head && _hhea && _hmtx && !(bool(_glyf) != bool(_loca)); } inline unsigned short int GlyphCache::Loader::units_per_em() const throw() { return _head ? TtfUtil::DesignUnits(_head) : 0; } inline unsigned short int GlyphCache::Loader::num_glyphs() const throw() { return max(_num_glyphs_graphics, _num_glyphs_attributes); } inline unsigned short int GlyphCache::Loader::num_attrs() const throw() { return _num_attrs; } inline bool GlyphCache::Loader::has_boxes () const throw() { return _has_boxes; } const GlyphFace * GlyphCache::Loader::read_glyph(unsigned short glyphid, GlyphFace & glyph, int *numsubs) const throw() { Rect bbox; Position advance; if (glyphid < _num_glyphs_graphics) { int nLsb; unsigned int nAdvWid; if (_glyf) { int xMin, yMin, xMax, yMax; size_t locidx = TtfUtil::LocaLookup(glyphid, _loca, _loca.size(), _head); void *pGlyph = TtfUtil::GlyfLookup(_glyf, locidx, _glyf.size()); if (pGlyph && TtfUtil::GlyfBox(pGlyph, xMin, yMin, xMax, yMax)) { if ((xMin > xMax) || (yMin > yMax)) return 0; bbox = Rect(Position(static_cast(xMin), static_cast(yMin)), Position(static_cast(xMax), static_cast(yMax))); } } if (TtfUtil::HorMetrics(glyphid, _hmtx, _hmtx.size(), _hhea, nLsb, nAdvWid)) advance = Position(static_cast(nAdvWid), 0); } if (glyphid < _num_glyphs_attributes) { const byte * gloc = m_pGloc; size_t glocs = 0, gloce = 0; be::skip(gloc); be::skip(gloc,2); if (_long_fmt) { if (8 + glyphid * sizeof(uint32) > m_pGloc.size()) return 0; be::skip(gloc, glyphid); glocs = be::read(gloc); gloce = be::peek(gloc); } else { if (8 + glyphid * sizeof(uint16) > m_pGloc.size()) return 0; be::skip(gloc, glyphid); glocs = be::read(gloc); gloce = be::peek(gloc); } if (glocs >= m_pGlat.size() - 1 || gloce > m_pGlat.size()) return 0; const uint32 glat_version = be::peek(m_pGlat); if (glat_version >= 0x00030000) { if (glocs >= gloce) return 0; const byte * p = m_pGlat + glocs; uint16 bmap = be::read(p); int num = bit_set_count((uint32)bmap); if (numsubs) *numsubs += num; glocs += 6 + 8 * num; if (glocs > gloce) return 0; } if (glat_version < 0x00020000) { if (gloce - glocs < 2*sizeof(byte)+sizeof(uint16) || gloce - glocs > _num_attrs*(2*sizeof(byte)+sizeof(uint16))) return 0; new (&glyph) GlyphFace(bbox, advance, glat_iterator(m_pGlat + glocs), glat_iterator(m_pGlat + gloce)); } else { if (gloce - glocs < 3*sizeof(uint16) // can a glyph have no attributes? why not? || gloce - glocs > _num_attrs*3*sizeof(uint16) || glocs > m_pGlat.size() - 2*sizeof(uint16)) return 0; new (&glyph) GlyphFace(bbox, advance, glat2_iterator(m_pGlat + glocs), glat2_iterator(m_pGlat + gloce)); } if (!glyph.attrs() || glyph.attrs().capacity() > _num_attrs) return 0; } return &glyph; } inline float scale_to(uint8 t, float zmin, float zmax) { return (zmin + t * (zmax - zmin) / 255); } Rect readbox(Rect &b, uint8 zxmin, uint8 zymin, uint8 zxmax, uint8 zymax) { return Rect(Position(scale_to(zxmin, b.bl.x, b.tr.x), scale_to(zymin, b.bl.y, b.tr.y)), Position(scale_to(zxmax, b.bl.x, b.tr.x), scale_to(zymax, b.bl.y, b.tr.y))); } GlyphBox * GlyphCache::Loader::read_box(uint16 gid, GlyphBox *curr, const GlyphFace & glyph) const throw() { if (gid >= _num_glyphs_attributes) return 0; const byte * gloc = m_pGloc; size_t glocs = 0, gloce = 0; be::skip(gloc); be::skip(gloc,2); if (_long_fmt) { be::skip(gloc, gid); glocs = be::read(gloc); gloce = be::peek(gloc); } else { be::skip(gloc, gid); glocs = be::read(gloc); gloce = be::peek(gloc); } if (gloce > m_pGlat.size() || glocs + 6 >= gloce) return 0; const byte * p = m_pGlat + glocs; uint16 bmap = be::read(p); int num = bit_set_count((uint32)bmap); Rect bbox = glyph.theBBox(); Rect diamax(Position(bbox.bl.x + bbox.bl.y, bbox.bl.x - bbox.tr.y), Position(bbox.tr.x + bbox.tr.y, bbox.tr.x - bbox.bl.y)); Rect diabound = readbox(diamax, p[0], p[2], p[1], p[3]); ::new (curr) GlyphBox(num, bmap, &diabound); be::skip(p, 4); if (glocs + 6 + num * 8 >= gloce) return 0; for (int i = 0; i < num * 2; ++i) { Rect box = readbox((i & 1) ? diamax : bbox, p[0], p[2], p[1], p[3]); curr->addSubBox(i >> 1, i & 1, &box); be::skip(p, 4); } return (GlyphBox *)((char *)(curr) + sizeof(GlyphBox) + 2 * num * sizeof(Rect)); }