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Quelle hb-aat-layout-morx-table.hh Sprache: C |
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/* * Copyright © 2017 Google, Inc. * * This is part of HarfBuzz, a text shaping library. * * Permission is hereby granted, without written agreement and without * license or royalty fees, to use, copy, modify, and distribute this * software and its documentation for any purpose, provided that the * above copyright notice and the following two paragraphs appear in * all copies of this software. * * IN NO EVENT SHALL THE COPYRIGHT HOLDER BE LIABLE TO ANY PARTY FOR * DIRECT, INDIRECT, SPECIAL, INCIDENTAL, OR CONSEQUENTIAL DAMAGES * ARISING OUT OF THE USE OF THIS SOFTWARE AND ITS DOCUMENTATION, EVEN * IF THE COPYRIGHT HOLDER HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH * DAMAGE. * * THE COPYRIGHT HOLDER SPECIFICALLY DISCLAIMS ANY WARRANTIES, INCLUDING, * BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND * FITNESS FOR A PARTICULAR PURPOSE. THE SOFTWARE PROVIDED HEREUNDER IS * ON AN "AS IS" BASIS, AND THE COPYRIGHT HOLDER HAS NO OBLIGATION TO * PROVIDE MAINTENANCE, SUPPORT, UPDATES, ENHANCEMENTS, OR MODIFICATIONS. * * Google Author(s): Behdad Esfahbod */ #ifndef HB_AAT_LAYOUT_MORX_TABLE_HH #define HB_AAT_LAYOUT_MORX_TABLE_HH #include "hb-open-type.hh" #include "hb-aat-layout-common.hh" #include "hb-ot-layout-common.hh" #include "hb-ot-layout-gdef-table.hh" #include "hb-aat-map.hh" /* * morx -- Extended Glyph Metamorphosis * https://developer.apple.com/fonts/TrueType-Reference-Manual/RM06/Chap6morx.html * https://developer.apple.com/fonts/TrueType-Reference-Manual/RM06/Chap6mort.html */ #define HB_AAT_TAG_morx HB_TAG('m','o','r','x') #define HB_AAT_TAG_mort HB_TAG('m','o','r','t') namespace AAT { using namespace OT; template <typename Types> struct RearrangementSubtable { typedef typename Types::HBUINT HBUINT; typedef void EntryData; struct driver_context_t { static constexpr bool in_place = true; enum Flags { MarkFirst = 0x8000, /* If set, make the current glyph the first * glyph to be rearranged. */ DontAdvance = 0x4000, /* If set, don't advance to the next glyph * before going to the new state. This means * that the glyph index doesn't change, even * if the glyph at that index has changed. */ MarkLast = 0x2000, /* If set, make the current glyph the last * glyph to be rearranged. */ Reserved = 0x1FF0, /* These bits are reserved and should be set to 0. */ Verb = 0x000F, /* The type of rearrangement specified. */ }; driver_context_t (const RearrangementSubtable *table HB_UNUSED) : ret (false), start (0), end (0) {} bool is_actionable (hb_buffer_t *buffer HB_UNUSED, StateTableDriver<Types, EntryData> *driver HB_UNUSED, const Entry<EntryData> &entry) const { return (entry.flags & Verb) && start < end; } void transition (hb_buffer_t *buffer, StateTableDriver<Types, EntryData> *driver, const Entry<EntryData> &entry) { unsigned int flags = entry.flags; if (flags & MarkFirst) start = buffer->idx; if (flags & MarkLast) end = hb_min (buffer->idx + 1, buffer->len); if ((flags & Verb) && start < end) { /* The following map has two nibbles, for start-side * and end-side. Values of 0,1,2 mean move that many * to the other side. Value of 3 means move 2 and * flip them. */ const unsigned char map[16] = { 0x00, /* 0 no change */ 0x10, /* 1 Ax => xA */ 0x01, /* 2 xD => Dx */ 0x11, /* 3 AxD => DxA */ 0x20, /* 4 ABx => xAB */ 0x30, /* 5 ABx => xBA */ 0x02, /* 6 xCD => CDx */ 0x03, /* 7 xCD => DCx */ 0x12, /* 8 AxCD => CDxA */ 0x13, /* 9 AxCD => DCxA */ 0x21, /* 10 ABxD => DxAB */ 0x31, /* 11 ABxD => DxBA */ 0x22, /* 12 ABxCD => CDxAB */ 0x32, /* 13 ABxCD => CDxBA */ 0x23, /* 14 ABxCD => DCxAB */ 0x33, /* 15 ABxCD => DCxBA */ }; unsigned int m = map[flags & Verb]; unsigned int l = hb_min (2u, m >> 4); unsigned int r = hb_min (2u, m & 0x0F); bool reverse_l = 3 == (m >> 4); bool reverse_r = 3 == (m & 0x0F); if (end - start >= l + r && end-start <= HB_MAX_CONTEXT_LENGTH) { buffer->merge_clusters (start, hb_min (buffer->idx + 1, buffer->len)); buffer->merge_clusters (start, end); hb_glyph_info_t *info = buffer->info; hb_glyph_info_t buf[4]; hb_memcpy (buf, info + start, l * sizeof (buf[0])); hb_memcpy (buf + 2, info + end - r, r * sizeof (buf[0])); if (l != r) memmove (info + start + r, info + start + l, (end - start - l - r) * sizeof (buf[0])); hb_memcpy (info + start, buf + 2, r * sizeof (buf[0])); hb_memcpy (info + end - l, buf, l * sizeof (buf[0])); if (reverse_l) { buf[0] = info[end - 1]; info[end - 1] = info[end - 2]; info[end - 2] = buf[0]; } if (reverse_r) { buf[0] = info[start]; info[start] = info[start + 1]; info[start + 1] = buf[0]; } } } } public: bool ret; private: unsigned int start; unsigned int end; }; bool apply (hb_aat_apply_context_t *c) const { TRACE_APPLY (this); driver_context_t dc (this); StateTableDriver<Types, EntryData> driver (machine, c->face); if (driver.is_idempotent_on_all_out_of_bounds (&dc, c) && !c->buffer_digest.may_have (c->machine_glyph_set)) return_trace (false); driver.drive (&dc, c); return_trace (dc.ret); } bool sanitize (hb_sanitize_context_t *c) const { TRACE_SANITIZE (this); return_trace (machine.sanitize (c)); } public: StateTable<Types, EntryData> machine; public: DEFINE_SIZE_STATIC ((StateTable<Types, EntryData>::static_size)); }; template <typename Types> struct ContextualSubtable { typedef typename Types::HBUINT HBUINT; struct EntryData { HBUINT16 markIndex; /* Index of the substitution table for the * marked glyph (use 0xFFFF for none). */ HBUINT16 currentIndex; /* Index of the substitution table for the * current glyph (use 0xFFFF for none). */ public: DEFINE_SIZE_STATIC (4); }; struct driver_context_t { static constexpr bool in_place = true; enum Flags { SetMark = 0x8000, /* If set, make the current glyph the marked glyph. */ DontAdvance = 0x4000, /* If set, don't advance to the next glyph before * going to the new state. */ Reserved = 0x3FFF, /* These bits are reserved and should be set to 0. */ }; driver_context_t (const ContextualSubtable *table_, hb_aat_apply_context_t *c_) : ret (false), c (c_), gdef (*c->gdef_table), mark_set (false), has_glyph_classes (gdef.has_glyph_classes ()), mark (0), table (table_), subs (table+table->substitutionTables) {} bool is_actionable (hb_buffer_t *buffer, StateTableDriver<Types, EntryData> *driver, const Entry<EntryData> &entry) const { if (buffer->idx == buffer->len && !mark_set) return false; return entry.data.markIndex != 0xFFFF || entry.data.currentIndex != 0xFFFF; } void transition (hb_buffer_t *buffer, StateTableDriver<Types, EntryData> *driver, const Entry<EntryData> &entry) { /* Looks like CoreText applies neither mark nor current substitution for * end-of-text if mark was not explicitly set. */ if (buffer->idx == buffer->len && !mark_set) return; const HBGlyphID16 *replacement; replacement = nullptr; if (Types::extended) { if (entry.data.markIndex != 0xFFFF) { const Lookup<HBGlyphID16> &lookup = subs[entry.data.markIndex]; replacement = lookup.get_value (buffer->info[mark].codepoint, driver->num_glyphs); } } else { unsigned int offset = entry.data.markIndex + buffer->info[mark].codepoint; const UnsizedArrayOf<HBGlyphID16> &subs_old = (const UnsizedArrayOf<HBGlyphID16> &) subs; replacement = &subs_old[Types::wordOffsetToIndex (offset, table, subs_old.arrayZ)]; if (!(replacement->sanitize (&c->sanitizer) && hb_barrier () && *replacement)) replacement = nullptr; } if (replacement) { buffer->unsafe_to_break (mark, hb_min (buffer->idx + 1, buffer->len)); buffer->info[mark].codepoint = *replacement; c->buffer_digest.add (*replacement); if (has_glyph_classes) _hb_glyph_info_set_glyph_props (&buffer->info[mark], gdef.get_glyph_props (*replacement)); ret = true; } replacement = nullptr; unsigned int idx = hb_min (buffer->idx, buffer->len - 1); if (Types::extended) { if (entry.data.currentIndex != 0xFFFF) { const Lookup<HBGlyphID16> &lookup = subs[entry.data.currentIndex]; replacement = lookup.get_value (buffer->info[idx].codepoint, driver->num_glyphs); } } else { unsigned int offset = entry.data.currentIndex + buffer->info[idx].codepoint; const UnsizedArrayOf<HBGlyphID16> &subs_old = (const UnsizedArrayOf<HBGlyphID16> &) subs; replacement = &subs_old[Types::wordOffsetToIndex (offset, table, subs_old.arrayZ)]; if (!(replacement->sanitize (&c->sanitizer) && hb_barrier () && *replacement)) replacement = nullptr; } if (replacement) { buffer->info[idx].codepoint = *replacement; c->buffer_digest.add (*replacement); if (has_glyph_classes) _hb_glyph_info_set_glyph_props (&buffer->info[idx], gdef.get_glyph_props (*replacement)); ret = true; } if (entry.flags & SetMark) { mark_set = true; mark = buffer->idx; } } public: bool ret; private: hb_aat_apply_context_t *c; const OT::GDEF &gdef; bool mark_set; bool has_glyph_classes; unsigned int mark; const ContextualSubtable *table; const UnsizedListOfOffset16To<Lookup<HBGlyphID16>, HBUINT, void, false> &subs; }; bool apply (hb_aat_apply_context_t *c) const { TRACE_APPLY (this); driver_context_t dc (this, c); StateTableDriver<Types, EntryData> driver (machine, c->face); if (driver.is_idempotent_on_all_out_of_bounds (&dc, c) && !c->buffer_digest.may_have (c->machine_glyph_set)) return_trace (false); driver.drive (&dc, c); return_trace (dc.ret); } bool sanitize (hb_sanitize_context_t *c) const { TRACE_SANITIZE (this); unsigned int num_entries = 0; if (unlikely (!machine.sanitize (c, &num_entries))) return_trace (false); hb_barrier (); if (!Types::extended) return_trace (substitutionTables.sanitize (c, this, 0)); unsigned int num_lookups = 0; const Entry<EntryData> *entries = machine.get_entries (); for (unsigned int i = 0; i < num_entries; i++) { const EntryData &data = entries[i].data; if (data.markIndex != 0xFFFF) num_lookups = hb_max (num_lookups, 1u + data.markIndex); if (data.currentIndex != 0xFFFF) num_lookups = hb_max (num_lookups, 1u + data.currentIndex); } return_trace (substitutionTables.sanitize (c, this, num_lookups)); } public: StateTable<Types, EntryData> machine; protected: NNOffsetTo<UnsizedListOfOffset16To<Lookup<HBGlyphID16>, HBUINT, void, false>, HBUINT> substitutionTables; public: DEFINE_SIZE_STATIC ((StateTable<Types, EntryData>::static_size + HBUINT::static_size)) }; template <bool extended> struct LigatureEntry; template <> struct LigatureEntry<true> { enum Flags { SetComponent = 0x8000, /* Push this glyph onto the component stack for * eventual processing. */ DontAdvance = 0x4000, /* Leave the glyph pointer at this glyph for the next iteration. */ PerformAction = 0x2000, /* Use the ligActionIndex to process a ligature * group. */ Reserved = 0x1FFF, /* These bits are reserved and should be set to 0. */ }; struct EntryData { HBUINT16 ligActionIndex; /* Index to the first ligActionTable entry * for processing this group, if indicated * by the flags. */ public: DEFINE_SIZE_STATIC (2); }; static bool performAction (const Entry<EntryData> &entry) { return entry.flags & PerformAction; } static unsigned int ligActionIndex (const Entry<EntryData> &entry) { return entry.data.ligActionIndex; } }; template <> struct LigatureEntry<false> { enum Flags { SetComponent = 0x8000, /* Push this glyph onto the component stack for * eventual processing. */ DontAdvance = 0x4000, /* Leave the glyph pointer at this glyph for the next iteration. */ Offset = 0x3FFF, /* Byte offset from beginning of subtable to the * ligature action list. This value must be a * multiple of 4. */ }; typedef void EntryData; static bool performAction (const Entry<EntryData> &entry) { return entry.flags & Offset; } static unsigned int ligActionIndex (const Entry<EntryData> &entry) { return entry.flags & Offset; } }; template <typename Types> struct LigatureSubtable { typedef typename Types::HBUINT HBUINT; typedef LigatureEntry<Types::extended> LigatureEntryT; typedef typename LigatureEntryT::EntryData EntryData; struct driver_context_t { static constexpr bool in_place = false; enum { DontAdvance = LigatureEntryT::DontAdvance, }; enum LigActionFlags { LigActionLast = 0x80000000, /* This is the last action in the list. This also * implies storage. */ LigActionStore = 0x40000000, /* Store the ligature at the current cumulated index * in the ligature table in place of the marked * (i.e. currently-popped) glyph. */ LigActionOffset = 0x3FFFFFFF, /* A 30-bit value which is sign-extended to 32-bits * and added to the glyph ID, resulting in an index * into the component table. */ }; driver_context_t (const LigatureSubtable *table_, hb_aat_apply_context_t *c_) : ret (false), c (c_), table (table_), ligAction (table+table->ligAction), component (table+table->component), ligature (table+table->ligature), match_length (0) {} bool is_actionable (hb_buffer_t *buffer HB_UNUSED, StateTableDriver<Types, EntryData> *driver HB_UNUSED, const Entry<EntryData> &entry) const { return LigatureEntryT::performAction (entry); } void transition (hb_buffer_t *buffer, StateTableDriver<Types, EntryData> *driver, const Entry<EntryData> &entry) { DEBUG_MSG (APPLY, nullptr, "Ligature transition at %u", buffer->idx); if (entry.flags & LigatureEntryT::SetComponent) { /* Never mark same index twice, in case DontAdvance was used... */ if (match_length && match_positions[(match_length - 1u) % ARRAY_LENGTH (match_positions)] = match_length--; match_positions[match_length++ % ARRAY_LENGTH (match_positions)] = buffer->out_len; DEBUG_MSG (APPLY, nullptr, "Set component at %u", buffer->out_len); } if (LigatureEntryT::performAction (entry)) { DEBUG_MSG (APPLY, nullptr, "Perform action with %u", match_length); unsigned int end = buffer->out_len; if (unlikely (!match_length)) return; if (buffer->idx >= buffer->len) return; /* TODO Work on previous instead? */ unsigned int cursor = match_length; unsigned int action_idx = LigatureEntryT::ligActionIndex (entry); action_idx = Types::offsetToIndex (action_idx, table, ligAction.arrayZ); const HBUINT32 *actionData = &ligAction[action_idx]; unsigned int ligature_idx = 0; unsigned int action; do { if (unlikely (!cursor)) { /* Stack underflow. Clear the stack. */ DEBUG_MSG (APPLY, nullptr, "Stack underflow"); match_length = 0; break; } DEBUG_MSG (APPLY, nullptr, "Moving to stack position %u", cursor - 1); if (unlikely (!buffer->move_to (match_positions[--cursor % ARRAY_LENGTH (match_position if (unlikely (!actionData->sanitize (&c->sanitizer))) break; hb_barrier (); action = *actionData; uint32_t uoffset = action & LigActionOffset; if (uoffset & 0x20000000) uoffset |= 0xC0000000; /* Sign-extend. */ int32_t offset = (int32_t) uoffset; unsigned int component_idx = buffer->cur().codepoint + offset; component_idx = Types::wordOffsetToIndex (component_idx, table, component.arrayZ); const HBUINT16 &componentData = component[component_idx]; if (unlikely (!componentData.sanitize (&c->sanitizer))) break; hb_barrier (); ligature_idx += componentData; DEBUG_MSG (APPLY, nullptr, "Action store %d last %d", bool (action & LigActionStore), bool (action & LigActionLast)); if (action & (LigActionStore | LigActionLast)) { ligature_idx = Types::offsetToIndex (ligature_idx, table, ligature.arrayZ); const HBGlyphID16 &ligatureData = ligature[ligature_idx]; if (unlikely (!ligatureData.sanitize (&c->sanitizer))) break; hb_barrier (); hb_codepoint_t lig = ligatureData; DEBUG_MSG (APPLY, nullptr, "Produced ligature %u", lig); if (unlikely (!buffer->replace_glyph (lig))) return; unsigned int lig_end = match_positions[(match_length - 1u) % ARRAY_LENGTH (match_position /* Now go and delete all subsequent components. */ while (match_length - 1u > cursor) { DEBUG_MSG (APPLY, nullptr, "Skipping ligature component"); if (unlikely (!buffer->move_to (match_positions[--match_length % ARRAY_LENGTH (match_po buffer->cur().unicode_props() |= UPROPS_MASK_IGNORABLE; if (unlikely (!buffer->replace_glyph (DELETED_GLYPH))) return; } if (unlikely (!buffer->move_to (lig_end))) return; buffer->merge_out_clusters (match_positions[cursor % ARRAY_LENGTH (match_positions)], } actionData++; } while (!(action & LigActionLast)); if (unlikely (!buffer->move_to (end))) return; } } public: bool ret; private: hb_aat_apply_context_t *c; const LigatureSubtable *table; const UnsizedArrayOf<HBUINT32> &ligAction; const UnsizedArrayOf<HBUINT16> &component; const UnsizedArrayOf<HBGlyphID16> &ligature; unsigned int match_length; unsigned int match_positions[HB_MAX_CONTEXT_LENGTH]; }; bool apply (hb_aat_apply_context_t *c) const { TRACE_APPLY (this); driver_context_t dc (this, c); StateTableDriver<Types, EntryData> driver (machine, c->face); if (driver.is_idempotent_on_all_out_of_bounds (&dc, c) && !c->buffer_digest.may_have (c->machine_glyph_set)) return_trace (false); driver.drive (&dc, c); return_trace (dc.ret); } bool sanitize (hb_sanitize_context_t *c) const { TRACE_SANITIZE (this); /* The rest of array sanitizations are done at run-time. */ return_trace (c->check_struct (this) && machine.sanitize (c) && hb_barrier () && ligAction && component && ligature); } public: StateTable<Types, EntryData> machine; protected: NNOffsetTo<UnsizedArrayOf<HBUINT32>, HBUINT> ligAction; /* Offset to the ligature action table. */ NNOffsetTo<UnsizedArrayOf<HBUINT16>, HBUINT> component; /* Offset to the component table. */ NNOffsetTo<UnsizedArrayOf<HBGlyphID16>, HBUINT> ligature; /* Offset to the actual ligature lists. */ public: DEFINE_SIZE_STATIC ((StateTable<Types, EntryData>::static_size + 3 * HBUINT::static_size }; template <typename Types> struct NoncontextualSubtable { bool apply (hb_aat_apply_context_t *c) const { TRACE_APPLY (this); const OT::GDEF &gdef (*c->gdef_table); bool has_glyph_classes = gdef.has_glyph_classes (); bool ret = false; unsigned int num_glyphs = c->face->get_num_glyphs (); hb_glyph_info_t *info = c->buffer->info; unsigned int count = c->buffer->len; // If there's only one range, we already checked the flag. auto *last_range = c->range_flags && (c->range_flags->length > 1) ? &(*c->range_flags)[0] : nullptr; for (unsigned int i = 0; i < count; i++) { /* This block copied from StateTableDriver::drive. Keep in sync. */ if (last_range) { auto *range = last_range; { unsigned cluster = info[i].cluster; while (cluster < range->cluster_first) range--; while (cluster > range->cluster_last) range++; last_range = range; } if (!(range->flags & c->subtable_flags)) continue; } const HBGlyphID16 *replacement = substitute.get_value (info[i].codepoint, num_glyphs); if (replacement) { info[i].codepoint = *replacement; c->buffer_digest.add (*replacement); if (has_glyph_classes) _hb_glyph_info_set_glyph_props (&info[i], gdef.get_glyph_props (*replacement)); ret = true; } } return_trace (ret); } bool sanitize (hb_sanitize_context_t *c) const { TRACE_SANITIZE (this); return_trace (substitute.sanitize (c)); } protected: Lookup<HBGlyphID16> substitute; public: DEFINE_SIZE_MIN (2); }; template <typename Types> struct InsertionSubtable { typedef typename Types::HBUINT HBUINT; struct EntryData { HBUINT16 currentInsertIndex; /* Zero-based index into the insertion glyph table. * The number of glyphs to be inserted is contained * in the currentInsertCount field in the flags. * A value of 0xFFFF indicates no insertion is to * be done. */ HBUINT16 markedInsertIndex; /* Zero-based index into the insertion glyph table. * The number of glyphs to be inserted is contained * in the markedInsertCount field in the flags. * A value of 0xFFFF indicates no insertion is to * be done. */ public: DEFINE_SIZE_STATIC (4); }; struct driver_context_t { static constexpr bool in_place = false; enum Flags { SetMark = 0x8000, /* If set, mark the current glyph. */ DontAdvance = 0x4000, /* If set, don't advance to the next glyph before * going to the new state. This does not mean * that the glyph pointed to is the same one as * before. If you've made insertions immediately * downstream of the current glyph, the next glyph * processed would in fact be the first one * inserted. */ CurrentIsKashidaLike= 0x2000, /* If set, and the currentInsertList is nonzero, * then the specified glyph list will be inserted * as a kashida-like insertion, either before or * after the current glyph (depending on the state * of the currentInsertBefore flag). If clear, and * the currentInsertList is nonzero, then the * specified glyph list will be inserted as a * split-vowel-like insertion, either before or * after the current glyph (depending on the state * of the currentInsertBefore flag). */ MarkedIsKashidaLike= 0x1000, /* If set, and the markedInsertList is nonzero, * then the specified glyph list will be inserted * as a kashida-like insertion, either before or * after the marked glyph (depending on the state * of the markedInsertBefore flag). If clear, and * the markedInsertList is nonzero, then the * specified glyph list will be inserted as a * split-vowel-like insertion, either before or * after the marked glyph (depending on the state * of the markedInsertBefore flag). */ CurrentInsertBefore= 0x0800, /* If set, specifies that insertions are to be made * to the left of the current glyph. If clear, * they're made to the right of the current glyph. */ MarkedInsertBefore= 0x0400, /* If set, specifies that insertions are to be * made to the left of the marked glyph. If clear, * they're made to the right of the marked glyph. */ CurrentInsertCount= 0x3E0, /* This 5-bit field is treated as a count of the * number of glyphs to insert at the current * position. Since zero means no insertions, the * largest number of insertions at any given * current location is 31 glyphs. */ MarkedInsertCount= 0x001F, /* This 5-bit field is treated as a count of the * number of glyphs to insert at the marked * position. Since zero means no insertions, the * largest number of insertions at any given * marked location is 31 glyphs. */ }; driver_context_t (const InsertionSubtable *table, hb_aat_apply_context_t *c_) : ret (false), c (c_), mark (0), insertionAction (table+table->insertionAction) {} bool is_actionable (hb_buffer_t *buffer HB_UNUSED, StateTableDriver<Types, EntryData> *driver HB_UNUSED, const Entry<EntryData> &entry) const { return (entry.flags & (CurrentInsertCount | MarkedInsertCount)) && (entry.data.currentInsertIndex != 0xFFFF ||entry.data.markedInsertIndex != 0xFFFF); } void transition (hb_buffer_t *buffer, StateTableDriver<Types, EntryData> *driver, const Entry<EntryData> &entry) { unsigned int flags = entry.flags; unsigned mark_loc = buffer->out_len; if (entry.data.markedInsertIndex != 0xFFFF) { unsigned int count = (flags & MarkedInsertCount); if (unlikely ((buffer->max_ops -= count) <= 0)) return; unsigned int start = entry.data.markedInsertIndex; const HBGlyphID16 *glyphs = &insertionAction[start]; if (unlikely (!c->sanitizer.check_array (glyphs, count))) count = 0; hb_barrier (); bool before = flags & MarkedInsertBefore; unsigned int end = buffer->out_len; if (unlikely (!buffer->move_to (mark))) return; if (buffer->idx < buffer->len && !before) if (unlikely (!buffer->copy_glyph ())) return; /* TODO We ignore KashidaLike setting. */ if (unlikely (!buffer->replace_glyphs (0, count, glyphs))) return; for (unsigned int i = 0; i < count; i++) c->buffer_digest.add (glyphs[i]); ret = true; if (buffer->idx < buffer->len && !before) buffer->skip_glyph (); if (unlikely (!buffer->move_to (end + count))) return; buffer->unsafe_to_break_from_outbuffer (mark, hb_min (buffer->idx + 1, buffer->len)); } if (flags & SetMark) mark = mark_loc; if (entry.data.currentInsertIndex != 0xFFFF) { unsigned int count = (flags & CurrentInsertCount) >> 5; if (unlikely ((buffer->max_ops -= count) <= 0)) return; unsigned int start = entry.data.currentInsertIndex; const HBGlyphID16 *glyphs = &insertionAction[start]; if (unlikely (!c->sanitizer.check_array (glyphs, count))) count = 0; hb_barrier (); bool before = flags & CurrentInsertBefore; unsigned int end = buffer->out_len; if (buffer->idx < buffer->len && !before) if (unlikely (!buffer->copy_glyph ())) return; /* TODO We ignore KashidaLike setting. */ if (unlikely (!buffer->replace_glyphs (0, count, glyphs))) return; if (buffer->idx < buffer->len && !before) buffer->skip_glyph (); /* Humm. Not sure where to move to. There's this wording under * DontAdvance flag: * * "If set, don't update the glyph index before going to the new state. * This does not mean that the glyph pointed to is the same one as * before. If you've made insertions immediately downstream of the * current glyph, the next glyph processed would in fact be the first * one inserted." * * This suggests that if DontAdvance is NOT set, we should move to * end+count. If it *was*, then move to end, such that newly inserted * glyphs are now visible. * * https://github.com/harfbuzz/harfbuzz/issues/1224#issuecomment-427691417 */ if (unlikely (!buffer->move_to ((flags & DontAdvance) ? end : end + count))) return; } } public: bool ret; private: hb_aat_apply_context_t *c; unsigned int mark; const UnsizedArrayOf<HBGlyphID16> &insertionAction; }; bool apply (hb_aat_apply_context_t *c) const { TRACE_APPLY (this); driver_context_t dc (this, c); StateTableDriver<Types, EntryData> driver (machine, c->face); if (driver.is_idempotent_on_all_out_of_bounds (&dc, c) && !c->buffer_digest.may_have (c->machine_glyph_set)) return_trace (false); driver.drive (&dc, c); return_trace (dc.ret); } bool sanitize (hb_sanitize_context_t *c) const { TRACE_SANITIZE (this); /* The rest of array sanitizations are done at run-time. */ return_trace (c->check_struct (this) && machine.sanitize (c) && hb_barrier () && insertionAction); } public: StateTable<Types, EntryData> machine; protected: NNOffsetTo<UnsizedArrayOf<HBGlyphID16>, HBUINT> insertionAction; /* Byte offset from stateHeader to the start of * the insertion glyph table. */ public: DEFINE_SIZE_STATIC ((StateTable<Types, EntryData>::static_size + HBUINT::static_size)) }; struct Feature { bool sanitize (hb_sanitize_context_t *c) const { TRACE_SANITIZE (this); return_trace (c->check_struct (this)); } public: HBUINT16 featureType; /* The type of feature. */ HBUINT16 featureSetting; /* The feature's setting (aka selector). */ HBUINT32 enableFlags; /* Flags for the settings that this feature * and setting enables. */ HBUINT32 disableFlags; /* Complement of flags for the settings that this * feature and setting disable. */ public: DEFINE_SIZE_STATIC (12); }; struct hb_accelerate_subtables_context_t : hb_dispatch_context_t<hb_accelerate_subtables_context_t> { struct hb_applicable_t { friend struct hb_accelerate_subtables_context_t; friend struct hb_aat_layout_lookup_accelerator_t; public: hb_set_digest_t digest; template <typename T> auto init_ (const T &obj_, unsigned num_glyphs, hb_priority<1>) HB_AUTO_RETURN ( obj_.machine.collect_glyphs (this->digest, num_glyphs) ) template <typename T> void init_ (const T &obj_, unsigned num_glyphs, hb_priority<0>) { digest = digest.full (); } template <typename T> void init (const T &obj_, unsigned num_glyphs) { init_ (obj_, num_glyphs, hb_prioritize); } }; /* Dispatch interface. */ template <typename T> return_t dispatch (const T &obj) { hb_applicable_t *entry = &array[i++]; entry->init (obj, num_glyphs); return hb_empty_t (); } static return_t default_return_value () { return hb_empty_t (); } bool stop_sublookup_iteration (return_t r) const { return false; } hb_accelerate_subtables_context_t (hb_applicable_t *array_, unsigned num_glyphs_) : hb_dispatch_context_t<hb_accelerate_subtables_context_t> (), array (array_), num_glyphs (num_glyphs_) {} hb_applicable_t *array; unsigned num_glyphs; unsigned i = 0; }; struct hb_aat_layout_chain_accelerator_t { template <typename TChain> static hb_aat_layout_chain_accelerator_t *create (const TChain &chain, unsigned num_glyph { unsigned count = chain.get_subtable_count (); unsigned size = sizeof (hb_aat_layout_chain_accelerator_t) - HB_VAR_ARRAY * sizeof (hb_accelerate_subtables_context_t::hb_applicable_t) + count * sizeof (hb_accelerate_subtables_context_t::hb_applicable_t); /* The following is a calloc because when we are collecting subtables, * some of them might be invalid and hence not collect; as a result, * we might not fill in all the count entries of the subtables array. * Zeroing it allows the set digest to gatekeep it without having to * initialize it further. */ auto *thiz = (hb_aat_layout_chain_accelerator_t *) hb_calloc (1, size); if (unlikely (!thiz)) return nullptr; hb_accelerate_subtables_context_t c_accelerate_subtables (thiz->subtables, num_glyph chain.dispatch (&c_accelerate_subtables); return thiz; } hb_accelerate_subtables_context_t::hb_applicable_t subtables[HB_VAR_ARRAY]; }; template <typename Types> struct ChainSubtable { typedef typename Types::HBUINT HBUINT; template <typename T> friend struct Chain; unsigned int get_size () const { return length; } unsigned int get_type () const { return coverage & 0xFF; } unsigned int get_coverage () const { return coverage >> (sizeof (HBUINT) * 8 - 8); } enum Coverage { Vertical = 0x80, /* If set, this subtable will only be applied * to vertical text. If clear, this subtable * will only be applied to horizontal text. */ Backwards = 0x40, /* If set, this subtable will process glyphs * in descending order. If clear, it will * process the glyphs in ascending order. */ AllDirections = 0x20, /* If set, this subtable will be applied to * both horizontal and vertical text (i.e. * the state of bit 0x80000000 is ignored). */ Logical = 0x10, /* If set, this subtable will process glyphs * in logical order (or reverse logical order, * depending on the value of bit 0x80000000). */ }; enum Type { Rearrangement = 0, Contextual = 1, Ligature = 2, Noncontextual = 4, Insertion = 5 }; template <typename context_t, typename ...Ts> typename context_t::return_t dispatch (context_t *c, Ts&&... ds) const { unsigned int subtable_type = get_type (); TRACE_DISPATCH (this, subtable_type); switch (subtable_type) { case Rearrangement: return_trace (c->dispatch (u.rearrangement, std::forward<Ts> (ds)...) case Contextual: return_trace (c->dispatch (u.contextual, std::forward<Ts> (ds)...)); case Ligature: return_trace (c->dispatch (u.ligature, std::forward<Ts> (ds)...)); case Noncontextual: return_trace (c->dispatch (u.noncontextual, std::forward<Ts> (ds)...) case Insertion: return_trace (c->dispatch (u.insertion, std::forward<Ts> (ds)...)); default: return_trace (c->default_return_value ()); } } bool apply (hb_aat_apply_context_t *c) const { TRACE_APPLY (this); // Disabled for https://github.com/harfbuzz/harfbuzz/issues/4873 //hb_sanitize_with_object_t with (&c->sanitizer, this); return_trace (dispatch (c)); } bool sanitize (hb_sanitize_context_t *c) const { TRACE_SANITIZE (this); if (!(length.sanitize (c) && hb_barrier () && length >= min_size && c->check_range (this, length))) return_trace (false); // Disabled for https://github.com/harfbuzz/harfbuzz/issues/4873 //hb_sanitize_with_object_t with (c, this); return_trace (dispatch (c)); } protected: HBUINT length; /* Total subtable length, including this header. */ HBUINT coverage; /* Coverage flags and subtable type. */ HBUINT32 subFeatureFlags;/* The 32-bit mask identifying which subtable this is. */ union { RearrangementSubtable<Types> rearrangement; ContextualSubtable<Types> contextual; LigatureSubtable<Types> ligature; NoncontextualSubtable<Types> noncontextual; InsertionSubtable<Types> insertion; } u; public: DEFINE_SIZE_MIN (2 * sizeof (HBUINT) + 4); }; template <typename Types> struct Chain { typedef typename Types::HBUINT HBUINT; unsigned get_subtable_count () const { return subtableCount; } hb_mask_t compile_flags (const hb_aat_map_builder_t *map) const { hb_mask_t flags = defaultFlags; { unsigned int count = featureCount; for (unsigned i = 0; i < count; i++) { const Feature &feature = featureZ[i]; hb_aat_layout_feature_type_t type = (hb_aat_layout_feature_type_t) (unsigned int) feat hb_aat_layout_feature_selector_t setting = (hb_aat_layout_feature_selector_t) (unsig retry: // Check whether this type/setting pair was requested in the map, and if so, apply its flags. // (The search here only looks at the type and setting fields of feature_info_t.) hb_aat_map_builder_t::feature_info_t info = { type, setting, false, 0 }; if (map->current_features.bsearch (info)) { flags &= feature.disableFlags; flags |= feature.enableFlags; } else if (type == HB_AAT_LAYOUT_FEATURE_TYPE_LETTER_CASE && setting == HB_AAT_LAYOUT_FEATUR { /* Deprecated. https://github.com/harfbuzz/harfbuzz/issues/1342 */ type = HB_AAT_LAYOUT_FEATURE_TYPE_LOWER_CASE; setting = HB_AAT_LAYOUT_FEATURE_SELECTOR_LOWER_CASE_SMALL_CAPS; goto retry; } #ifndef HB_NO_AAT else if (type == HB_AAT_LAYOUT_FEATURE_TYPE_LANGUAGE_TAG_TYPE && setting && /* TODO: Rudimentary language matching. */ hb_language_matches (map->face->table.ltag->get_language (setting - 1), map->props.langua { flags &= feature.disableFlags; flags |= feature.enableFlags; } #endif } } return flags; } void apply (hb_aat_apply_context_t *c, const hb_aat_layout_chain_accelerator_t *accel) const { const ChainSubtable<Types> *subtable = &StructAfter<ChainSubtable<Types>> (featureZ.as_array (feature unsigned int count = subtableCount; for (unsigned int i = 0; i < count; i++) { bool reverse; if (hb_none (hb_iter (c->range_flags) | hb_map ([&subtable] (const hb_aat_map_t::range_flags_t _) -> bool { return subtable->subFeatureF goto skip; c->subtable_flags = subtable->subFeatureFlags; c->machine_glyph_set = accel ? accel->subtables[i].digest : hb_set_digest_t::full (); if (!(subtable->get_coverage() & ChainSubtable<Types>::AllDirections) && HB_DIRECTION_IS_VERTICAL (c->buffer->props.direction) != bool (subtable->get_coverage() & ChainSubtable<Types>::Vertical)) goto skip; /* Buffer contents is always in logical direction. Determine if * we need to reverse before applying this subtable. We reverse * back after if we did reverse indeed. * * Quoting the spac: * """ * Bits 28 and 30 of the coverage field control the order in which * glyphs are processed when the subtable is run by the layout engine. * Bit 28 is used to indicate if the glyph processing direction is * the same as logical order or layout order. Bit 30 is used to * indicate whether glyphs are processed forwards or backwards within * that order. Bit 30 Bit 28 Interpretation for Horizontal Text 0 0 The subtable is processed in layout order (the same order as the glyphs, which is always left-to-right). 1 0 The subtable is processed in reverse layout order (the order opposite that of the glyphs, which is always right-to-left). 0 1 The subtable is processed in logical order (the same order as the characters, which may be left-to-right or right-to-left). 1 1 The subtable is processed in reverse logical order (the order opposite that of the characters, which may be right-to-left or left-to-right). */ reverse = subtable->get_coverage () & ChainSubtable<Types>::Logical ? bool (subtable->get_coverage () & ChainSubtable<Types>::Backwards) : bool (subtable->get_coverage () & ChainSubtable<Types>::Backwards) != HB_DIRECTION_IS_BACKWARD (c->buffer->props.direction); if (!c->buffer->message (c->font, "start chainsubtable %u", c->lookup_index)) goto skip; if (reverse) c->buffer->reverse (); subtable->apply (c); if (reverse) c->buffer->reverse (); (void) c->buffer->message (c->font, "end chainsubtable %u", c->lookup_index); if (unlikely (!c->buffer->successful)) return; skip: subtable = &StructAfter<ChainSubtable<Types>> (*subtable); c->set_lookup_index (c->lookup_index + 1); } } unsigned int get_size () const { return length; } template <typename context_t, typename ...Ts> typename context_t::return_t dispatch (context_t *c, Ts&&... ds) const { const ChainSubtable<Types> *subtable = &StructAfter<ChainSubtable<Types>> (featureZ.as_array (feature unsigned int count = subtableCount; for (unsigned int i = 0; i < count; i++) { typename context_t::return_t ret = subtable->dispatch (c, std::forward<Ts> (ds)...); if (c->stop_sublookup_iteration (ret)) return ret; subtable = &StructAfter<ChainSubtable<Types>> (*subtable); } return c->default_return_value (); } bool sanitize (hb_sanitize_context_t *c, unsigned int version) const { TRACE_SANITIZE (this); if (!(length.sanitize (c) && hb_barrier () && length >= min_size && c->check_range (this, length))) return_trace (false); if (!c->check_array (featureZ.arrayZ, featureCount)) return_trace (false); const ChainSubtable<Types> *subtable = &StructAfter<ChainSubtable<Types>> (featureZ.as_array (feature unsigned int count = subtableCount; for (unsigned int i = 0; i < count; i++) { if (!subtable->sanitize (c)) return_trace (false); hb_barrier (); subtable = &StructAfter<ChainSubtable<Types>> (*subtable); } if (version >= 3) { const SubtableGlyphCoverage *coverage = (const SubtableGlyphCoverage *) subtable; if (!coverage->sanitize (c, count)) return_trace (false); } return_trace (true); } protected: HBUINT32 defaultFlags; /* The default specification for subtables. */ HBUINT32 length; /* Total byte count, including this header. */ HBUINT featureCount; /* Number of feature subtable entries. */ HBUINT subtableCount; /* The number of subtables in the chain. */ UnsizedArrayOf<Feature> featureZ; /* Features. */ /*ChainSubtable firstSubtable;*//* Subtables. */ /*SubtableGlyphCoverage coverages*//* Only if version >= 3. */ public: DEFINE_SIZE_MIN (8 + 2 * sizeof (HBUINT)); }; /* * The 'mort'/'morx' Table */ template <typename T, typename Types, hb_tag_t TAG> struct mortmorx { static constexpr hb_tag_t tableTag = TAG; bool has_data () const { return version != 0; } struct accelerator_t { accelerator_t (hb_face_t *face) { hb_sanitize_context_t sc; this->table = sc.reference_table<T> (face); this->chain_count = table->get_chain_count (); this->accels = (hb_atomic_ptr_t<hb_aat_layout_chain_accelerator_t> *) hb_calloc (this->ch if (unlikely (!this->accels)) { this->chain_count = 0; this->table.destroy (); this->table = hb_blob_get_empty (); } } ~accelerator_t () { for (unsigned int i = 0; i < this->chain_count; i++) hb_free (this->accels[i]); hb_free (this->accels); this->table.destroy (); } hb_blob_t *get_blob () const { return table.get_blob (); } template <typename Chain> hb_aat_layout_chain_accelerator_t *get_accel (unsigned chain_index, const Chain &chain, u { if (unlikely (chain_index >= chain_count)) return nullptr; retry: auto *accel = accels[chain_index].get_acquire (); if (unlikely (!accel)) { accel = hb_aat_layout_chain_accelerator_t::create (chain, num_glyphs); if (unlikely (!accel)) return nullptr; if (unlikely (!accels[chain_index].cmpexch (nullptr, accel))) { hb_free (accel); goto retry; } } return accel; } hb_blob_ptr_t<T> table; unsigned int chain_count; hb_atomic_ptr_t<hb_aat_layout_chain_accelerator_t> *accels; }; void compile_flags (const hb_aat_map_builder_t *mapper, hb_aat_map_t *map) const { const Chain<Types> *chain = &firstChain; unsigned int count = chainCount; if (unlikely (!map->chain_flags.resize (count))) return; for (unsigned int i = 0; i < count; i++) { map->chain_flags[i].push (hb_aat_map_t::range_flags_t {chain->compile_flags (mapper), mapper->range_first, mapper->range_last}); chain = &StructAfter<Chain<Types>> (*chain); } } unsigned get_chain_count () const { return chainCount; } void apply (hb_aat_apply_context_t *c, const hb_aat_map_t &map, const accelerator_t &accel) const { if (unlikely (!c->buffer->successful)) return; c->buffer->unsafe_to_concat (); if (c->buffer->len < HB_AAT_BUFFER_DIGEST_THRESHOLD) c->buffer_digest = c->buffer->digest (); else c->buffer_digest = hb_set_digest_t::full (); c->set_lookup_index (0); const Chain<Types> *chain = &firstChain; unsigned int count = chainCount; for (unsigned int i = 0; i < count; i++) { auto *chain_accel = accel.get_accel (i, *chain, c->face->get_num_glyphs ()); c->range_flags = &map.chain_flags[i]; chain->apply (c, chain_accel); if (unlikely (!c->buffer->successful)) return; chain = &StructAfter<Chain<Types>> (*chain); } } bool sanitize (hb_sanitize_context_t *c) const { TRACE_SANITIZE (this); if (!(version.sanitize (c) && hb_barrier () && version && chainCount.sanitize (c))) return_trace (false); const Chain<Types> *chain = &firstChain; unsigned int count = chainCount; for (unsigned int i = 0; i < count; i++) { if (!chain->sanitize (c, version)) return_trace (false); hb_barrier (); chain = &StructAfter<Chain<Types>> (*chain); } return_trace (true); } protected: HBUINT16 version; /* Version number of the glyph metamorphosis table. * 1, 2, or 3. */ HBUINT16 unused; /* Set to 0. */ HBUINT32 chainCount; /* Number of metamorphosis chains contained in this * table. */ Chain<Types> firstChain; /* Chains. */ public: DEFINE_SIZE_MIN (8); }; struct morx : mortmorx<morx, ExtendedTypes, HB_AAT_TAG_morx> {}; struct mort : mortmorx<mort, ObsoleteTypes, HB_AAT_TAG_mort> {}; struct morx_accelerator_t : morx::accelerator_t { morx_accelerator_t (hb_face_t *face) : morx::accelerator_t (face) {} }; struct mort_accelerator_t : mort::accelerator_t { mort_accelerator_t (hb_face_t *face) : mort::accelerator_t (face) {} }; } /* namespace AAT */ #endif /* HB_AAT_LAYOUT_MORX_TABLE_HH */
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2026-04-02