#ifndef OT_LAYOUT_GPOS_PAIRPOSFORMAT1_HH #define OT_LAYOUT_GPOS_PAIRPOSFORMAT1_HH #include "PairSet.hh" namespace OT { namespace Layout { namespace GPOS_impl { template struct PairPosFormat1_3 { using PairSet = GPOS_impl::PairSet; using PairValueRecord = GPOS_impl::PairValueRecord; protected: HBUINT16 format; /* Format identifier--format = 1 */ typename Types::template OffsetTo coverage; /* Offset to Coverage table--from * beginning of subtable */ ValueFormat valueFormat[2]; /* [0] Defines the types of data in * ValueRecord1--for the first glyph * in the pair--may be zero (0) */ /* [1] Defines the types of data in * ValueRecord2--for the second glyph * in the pair--may be zero (0) */ Array16Of> pairSet; /* Array of PairSet tables * ordered by Coverage Index */ public: DEFINE_SIZE_ARRAY (8 + Types::size, pairSet); bool sanitize (hb_sanitize_context_t *c) const { TRACE_SANITIZE (this); if (!c->check_struct (this)) return_trace (false); unsigned int len1 = valueFormat[0].get_len (); unsigned int len2 = valueFormat[1].get_len (); typename PairSet::sanitize_closure_t closure = { valueFormat, len1, Types::HBGlyphID::static_size + HBUINT16::static_size * (len1 + len2) }; return_trace (coverage.sanitize (c, this) && pairSet.sanitize (c, this, &closure)); } bool intersects (const hb_set_t *glyphs) const { auto &cov = this+coverage; if (pairSet.len > glyphs->get_population () * hb_bit_storage ((unsigned) pairSet.len) / 4) { for (hb_codepoint_t g = HB_SET_VALUE_INVALID; glyphs->next (&g);) { unsigned i = cov.get_coverage (g); if ((this+pairSet[i]).intersects (glyphs, valueFormat)) return true; } return false; } return + hb_zip (cov, pairSet) | hb_filter (*glyphs, hb_first) | hb_map (hb_second) | hb_map ([glyphs, this] (const typename Types::template OffsetTo &_) { return (this+_).intersects (glyphs, valueFormat); }) | hb_any ; } void closure_lookups (hb_closure_lookups_context_t *c) const {} void collect_variation_indices (hb_collect_variation_indices_context_t *c) const { if ((!valueFormat[0].has_device ()) && (!valueFormat[1].has_device ())) return; auto it = + hb_zip (this+coverage, pairSet) | hb_filter (c->glyph_set, hb_first) | hb_map (hb_second) ; if (!it) return; + it | hb_map (hb_add (this)) | hb_apply ([&] (const PairSet& _) { _.collect_variation_indices (c, valueFormat); }) ; } void collect_glyphs (hb_collect_glyphs_context_t *c) const { if (unlikely (!(this+coverage).collect_coverage (c->input))) return; unsigned int count = pairSet.len; for (unsigned int i = 0; i < count; i++) (this+pairSet[i]).collect_glyphs (c, valueFormat); } const Coverage &get_coverage () const { return this+coverage; } bool apply (hb_ot_apply_context_t *c) const { TRACE_APPLY (this); hb_buffer_t *buffer = c->buffer; unsigned int index = (this+coverage).get_coverage (buffer->cur().codepoint); if (likely (index == NOT_COVERED)) return_trace (false); hb_ot_apply_context_t::skipping_iterator_t &skippy_iter = c->iter_input; skippy_iter.reset (buffer->idx, 1); unsigned unsafe_to; if (!skippy_iter.next (&unsafe_to)) { buffer->unsafe_to_concat (buffer->idx, unsafe_to); return_trace (false); } return_trace ((this+pairSet[index]).apply (c, valueFormat, skippy_iter.idx)); } bool subset (hb_subset_context_t *c) const { TRACE_SUBSET (this); const hb_set_t &glyphset = *c->plan->glyphset_gsub (); const hb_map_t &glyph_map = *c->plan->glyph_map; auto *out = c->serializer->start_embed (*this); if (unlikely (!c->serializer->extend_min (out))) return_trace (false); out->format = format; out->valueFormat[0] = valueFormat[0]; out->valueFormat[1] = valueFormat[1]; if (c->plan->flags & HB_SUBSET_FLAGS_NO_HINTING) { hb_pair_t newFormats = compute_effective_value_formats (glyphset); out->valueFormat[0] = newFormats.first; out->valueFormat[1] = newFormats.second; } if (c->plan->all_axes_pinned) { out->valueFormat[0] = out->valueFormat[0].drop_device_table_flags (); out->valueFormat[1] = out->valueFormat[1].drop_device_table_flags (); } hb_sorted_vector_t new_coverage; + hb_zip (this+coverage, pairSet) | hb_filter (glyphset, hb_first) | hb_filter ([this, c, out] (const typename Types::template OffsetTo& _) { auto snap = c->serializer->snapshot (); auto *o = out->pairSet.serialize_append (c->serializer); if (unlikely (!o)) return false; bool ret = o->serialize_subset (c, _, this, valueFormat, out->valueFormat); if (!ret) { out->pairSet.pop (); c->serializer->revert (snap); } return ret; }, hb_second) | hb_map (hb_first) | hb_map (glyph_map) | hb_sink (new_coverage) ; out->coverage.serialize_serialize (c->serializer, new_coverage.iter ()); return_trace (bool (new_coverage)); } hb_pair_t compute_effective_value_formats (const hb_set_t& glyphset) const { unsigned record_size = PairSet::get_size (valueFormat); unsigned format1 = 0; unsigned format2 = 0; for (const auto & _ : + hb_zip (this+coverage, pairSet) | hb_filter (glyphset, hb_first) | hb_map (hb_second) ) { const PairSet& set = (this + _); const PairValueRecord *record = &set.firstPairValueRecord; unsigned count = set.len; for (unsigned i = 0; i < count; i++) { if (record->intersects (glyphset)) { format1 = format1 | valueFormat[0].get_effective_format (record->get_values_1 ()); format2 = format2 | valueFormat[1].get_effective_format (record->get_values_2 (valueFormat[0])); } record = &StructAtOffset (record, record_size); } if (format1 == valueFormat[0] && format2 == valueFormat[1]) break; } return hb_pair (format1, format2); } }; } } } #endif // OT_LAYOUT_GPOS_PAIRPOSFORMAT1_HH