src/OT/Layout/GPOS/MarkLigPosFormat1.hh - third_party/harfbuzz - Git at Google

 #ifndef OT_LAYOUT_GPOS_MARKLIGPOSFORMAT1_HH
 #define OT_LAYOUT_GPOS_MARKLIGPOSFORMAT1_HH

 #include "LigatureArray.hh"

 namespace OT {
 namespace Layout {
 namespace GPOS_impl {


 template <typename Types>
 struct MarkLigPosFormat1_2
 {
   protected:
   HBUINT16      format;                 /* Format identifier--format = 1 */
   typename Types::template OffsetTo<Coverage>
                 markCoverage;           /* Offset to Mark Coverage table--from
                                          * beginning of MarkLigPos subtable */
   typename Types::template OffsetTo<Coverage>
                 ligatureCoverage;       /* Offset to Ligature Coverage
                                          * table--from beginning of MarkLigPos
                                          * subtable */
   HBUINT16      classCount;             /* Number of defined mark classes */
   typename Types::template OffsetTo<MarkArray>
                 markArray;              /* Offset to MarkArray table--from
                                          * beginning of MarkLigPos subtable */
   typename Types::template OffsetTo<LigatureArray>
                 ligatureArray;          /* Offset to LigatureArray table--from
                                          * beginning of MarkLigPos subtable */
   public:
   DEFINE_SIZE_STATIC (4 + 4 * Types::size);

   bool sanitize (hb_sanitize_context_t *c) const
   {
     TRACE_SANITIZE (this);
     return_trace (c->check_struct (this) &&
                   markCoverage.sanitize (c, this) &&
                   ligatureCoverage.sanitize (c, this) &&
                   markArray.sanitize (c, this) &&
                   ligatureArray.sanitize (c, this, (unsigned int) classCount));
   }

   bool intersects (const hb_set_t *glyphs) const
   {
     return (this+markCoverage).intersects (glyphs) &&
            (this+ligatureCoverage).intersects (glyphs);
   }

   void closure_lookups (hb_closure_lookups_context_t *c) const {}

   void collect_variation_indices (hb_collect_variation_indices_context_t *c) const
   {
     + hb_zip (this+markCoverage, this+markArray)
     | hb_filter (c->glyph_set, hb_first)
     | hb_map (hb_second)
     | hb_apply ([&] (const MarkRecord& record) { record.collect_variation_indices (c, &(this+markArray)); })
     ;

     hb_map_t klass_mapping;
     Markclass_closure_and_remap_indexes (this+markCoverage, this+markArray, *c->glyph_set, &klass_mapping);

     unsigned ligcount = (this+ligatureArray).len;
     auto lig_iter =
     + hb_zip (this+ligatureCoverage, hb_range (ligcount))
     | hb_filter (c->glyph_set, hb_first)
     | hb_map (hb_second)
     ;

     const LigatureArray& lig_array = this+ligatureArray;
     for (const unsigned i : lig_iter)
     {
       hb_sorted_vector_t<unsigned> lig_indexes;
       unsigned row_count = lig_array[i].rows;
       for (unsigned row : + hb_range (row_count))
       {
         + hb_range ((unsigned) classCount)
         | hb_filter (klass_mapping)
         | hb_map ([&] (const unsigned col) { return row * (unsigned) classCount + col; })
         | hb_sink (lig_indexes)
         ;
       }

       lig_array[i].collect_variation_indices (c, lig_indexes.iter ());
     }
   }

   void collect_glyphs (hb_collect_glyphs_context_t *c) const
   {
     if (unlikely (!(this+markCoverage).collect_coverage (c->input))) return;
     if (unlikely (!(this+ligatureCoverage).collect_coverage (c->input))) return;
   }

   const Coverage &get_coverage () const { return this+markCoverage; }

   bool apply (hb_ot_apply_context_t *c) const
   {
     TRACE_APPLY (this);
     hb_buffer_t *buffer = c->buffer;
     unsigned int mark_index = (this+markCoverage).get_coverage  (buffer->cur().codepoint);
     if (likely (mark_index == NOT_COVERED)) return_trace (false);

     /* Now we search backwards for a non-mark glyph */

     hb_ot_apply_context_t::skipping_iterator_t &skippy_iter = c->iter_input;
     skippy_iter.set_lookup_props (LookupFlag::IgnoreMarks);

     if (c->last_base_until > buffer->idx)
     {
       c->last_base_until = 0;
       c->last_base = -1;
     }
     unsigned j;
     for (j = buffer->idx; j > c->last_base_until; j--)
     {
       auto match = skippy_iter.match (buffer->info[j - 1]);
       if (match == skippy_iter.MATCH)
       {
 	c->last_base = (signed) j - 1;
 	break;
       }
     }
     c->last_base_until = buffer->idx;
     if (c->last_base == -1)
     {
       buffer->unsafe_to_concat_from_outbuffer (0, buffer->idx + 1);
       return_trace (false);
     }

     unsigned idx = (unsigned) c->last_base;

     /* Checking that matched glyph is actually a ligature by GDEF is too strong; disabled */
     //if (!_hb_glyph_info_is_ligature (&buffer->info[idx])) { return_trace (false); }

     unsigned int lig_index = (this+ligatureCoverage).get_coverage  (buffer->info[idx].codepoint);
     if (lig_index == NOT_COVERED)
     {
       buffer->unsafe_to_concat_from_outbuffer (idx, buffer->idx + 1);
       return_trace (false);
     }

     const LigatureArray& lig_array = this+ligatureArray;
     const LigatureAttach& lig_attach = lig_array[lig_index];

     /* Find component to attach to */
     unsigned int comp_count = lig_attach.rows;
     if (unlikely (!comp_count))
     {
       buffer->unsafe_to_concat_from_outbuffer (idx, buffer->idx + 1);
       return_trace (false);
     }

     /* We must now check whether the ligature ID of the current mark glyph
      * is identical to the ligature ID of the found ligature.  If yes, we
      * can directly use the component index.  If not, we attach the mark
      * glyph to the last component of the ligature. */
     unsigned int comp_index;
     unsigned int lig_id = _hb_glyph_info_get_lig_id (&buffer->info[idx]);
     unsigned int mark_id = _hb_glyph_info_get_lig_id (&buffer->cur());
     unsigned int mark_comp = _hb_glyph_info_get_lig_comp (&buffer->cur());
     if (lig_id && lig_id == mark_id && mark_comp > 0)
       comp_index = hb_min (comp_count, _hb_glyph_info_get_lig_comp (&buffer->cur())) - 1;
     else
       comp_index = comp_count - 1;

     return_trace ((this+markArray).apply (c, mark_index, comp_index, lig_attach, classCount, 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;

     hb_map_t klass_mapping;
     Markclass_closure_and_remap_indexes (this+markCoverage, this+markArray, glyphset, &klass_mapping);

     if (!klass_mapping.get_population ()) return_trace (false);
     out->classCount = klass_mapping.get_population ();

     auto mark_iter =
     + hb_zip (this+markCoverage, this+markArray)
     | hb_filter (glyphset, hb_first)
     ;

     auto new_mark_coverage =
     + mark_iter
     | hb_map_retains_sorting (hb_first)
     | hb_map_retains_sorting (glyph_map)
     ;

     if (!out->markCoverage.serialize_serialize (c->serializer, new_mark_coverage))
       return_trace (false);

     if (unlikely (!out->markArray.serialize_subset (c, markArray, this,
 						    (this+markCoverage).iter (),
 						    &klass_mapping)))
       return_trace (false);

     auto new_ligature_coverage =
     + hb_iter (this + ligatureCoverage)
     | hb_filter (glyphset)
     | hb_map_retains_sorting (glyph_map)
     ;

     if (!out->ligatureCoverage.serialize_serialize (c->serializer, new_ligature_coverage))
       return_trace (false);

     return_trace (out->ligatureArray.serialize_subset (c, ligatureArray, this,
 						       hb_iter (this+ligatureCoverage),
 						       classCount, &klass_mapping));
   }

 };

 }
 }
 }

 #endif /* OT_LAYOUT_GPOS_MARKLIGPOSFORMAT1_HH */
	#ifndef OT_LAYOUT_GPOS_MARKLIGPOSFORMAT1_HH
	#define OT_LAYOUT_GPOS_MARKLIGPOSFORMAT1_HH

	#include "LigatureArray.hh"

	namespace OT {
	namespace Layout {
	namespace GPOS_impl {


	template <typename Types>
	struct MarkLigPosFormat1_2
	{
	protected:
	HBUINT16 format; /* Format identifier--format = 1 */
	typename Types::template OffsetTo<Coverage>
	markCoverage; /* Offset to Mark Coverage table--from
	* beginning of MarkLigPos subtable */
	typename Types::template OffsetTo<Coverage>
	ligatureCoverage; /* Offset to Ligature Coverage
	* table--from beginning of MarkLigPos
	* subtable */
	HBUINT16 classCount; /* Number of defined mark classes */
	typename Types::template OffsetTo<MarkArray>
	markArray; /* Offset to MarkArray table--from
	* beginning of MarkLigPos subtable */
	typename Types::template OffsetTo<LigatureArray>
	ligatureArray; /* Offset to LigatureArray table--from
	* beginning of MarkLigPos subtable */
	public:
	DEFINE_SIZE_STATIC (4 + 4 * Types::size);

	bool sanitize (hb_sanitize_context_t *c) const
	{
	TRACE_SANITIZE (this);
	return_trace (c->check_struct (this) &&
	markCoverage.sanitize (c, this) &&
	ligatureCoverage.sanitize (c, this) &&
	markArray.sanitize (c, this) &&
	ligatureArray.sanitize (c, this, (unsigned int) classCount));
	}

	bool intersects (const hb_set_t *glyphs) const
	{
	return (this+markCoverage).intersects (glyphs) &&
	(this+ligatureCoverage).intersects (glyphs);
	}

	void closure_lookups (hb_closure_lookups_context_t *c) const {}

	void collect_variation_indices (hb_collect_variation_indices_context_t *c) const
	{
	+ hb_zip (this+markCoverage, this+markArray)
	\| hb_filter (c->glyph_set, hb_first)
	\| hb_map (hb_second)
	\| hb_apply ([&] (const MarkRecord& record) { record.collect_variation_indices (c, &(this+markArray)); })
	;

	hb_map_t klass_mapping;
	Markclass_closure_and_remap_indexes (this+markCoverage, this+markArray, *c->glyph_set, &klass_mapping);

	unsigned ligcount = (this+ligatureArray).len;
	auto lig_iter =
	+ hb_zip (this+ligatureCoverage, hb_range (ligcount))
	\| hb_filter (c->glyph_set, hb_first)
	\| hb_map (hb_second)
	;

	const LigatureArray& lig_array = this+ligatureArray;
	for (const unsigned i : lig_iter)
	{
	hb_sorted_vector_t<unsigned> lig_indexes;
	unsigned row_count = lig_array[i].rows;
	for (unsigned row : + hb_range (row_count))
	{
	+ hb_range ((unsigned) classCount)
	\| hb_filter (klass_mapping)
	\| hb_map ([&] (const unsigned col) { return row * (unsigned) classCount + col; })
	\| hb_sink (lig_indexes)
	;
	}

	lig_array[i].collect_variation_indices (c, lig_indexes.iter ());
	}
	}

	void collect_glyphs (hb_collect_glyphs_context_t *c) const
	{
	if (unlikely (!(this+markCoverage).collect_coverage (c->input))) return;
	if (unlikely (!(this+ligatureCoverage).collect_coverage (c->input))) return;
	}

	const Coverage &get_coverage () const { return this+markCoverage; }

	bool apply (hb_ot_apply_context_t *c) const
	{
	TRACE_APPLY (this);
	hb_buffer_t *buffer = c->buffer;
	unsigned int mark_index = (this+markCoverage).get_coverage (buffer->cur().codepoint);
	if (likely (mark_index == NOT_COVERED)) return_trace (false);

	/* Now we search backwards for a non-mark glyph */

	hb_ot_apply_context_t::skipping_iterator_t &skippy_iter = c->iter_input;
	skippy_iter.set_lookup_props (LookupFlag::IgnoreMarks);

	if (c->last_base_until > buffer->idx)
	{
	c->last_base_until = 0;
	c->last_base = -1;
	}
	unsigned j;
	for (j = buffer->idx; j > c->last_base_until; j--)
	{
	auto match = skippy_iter.match (buffer->info[j - 1]);
	if (match == skippy_iter.MATCH)
	{
	c->last_base = (signed) j - 1;
	break;
	}
	}
	c->last_base_until = buffer->idx;
	if (c->last_base == -1)
	{
	buffer->unsafe_to_concat_from_outbuffer (0, buffer->idx + 1);
	return_trace (false);
	}

	unsigned idx = (unsigned) c->last_base;

	/* Checking that matched glyph is actually a ligature by GDEF is too strong; disabled */
	//if (!_hb_glyph_info_is_ligature (&buffer->info[idx])) { return_trace (false); }

	unsigned int lig_index = (this+ligatureCoverage).get_coverage (buffer->info[idx].codepoint);
	if (lig_index == NOT_COVERED)
	{
	buffer->unsafe_to_concat_from_outbuffer (idx, buffer->idx + 1);
	return_trace (false);
	}

	const LigatureArray& lig_array = this+ligatureArray;
	const LigatureAttach& lig_attach = lig_array[lig_index];

	/* Find component to attach to */
	unsigned int comp_count = lig_attach.rows;
	if (unlikely (!comp_count))
	{
	buffer->unsafe_to_concat_from_outbuffer (idx, buffer->idx + 1);
	return_trace (false);
	}

	/* We must now check whether the ligature ID of the current mark glyph
	* is identical to the ligature ID of the found ligature. If yes, we
	* can directly use the component index. If not, we attach the mark
	* glyph to the last component of the ligature. */
	unsigned int comp_index;
	unsigned int lig_id = _hb_glyph_info_get_lig_id (&buffer->info[idx]);
	unsigned int mark_id = _hb_glyph_info_get_lig_id (&buffer->cur());
	unsigned int mark_comp = _hb_glyph_info_get_lig_comp (&buffer->cur());
	if (lig_id && lig_id == mark_id && mark_comp > 0)
	comp_index = hb_min (comp_count, _hb_glyph_info_get_lig_comp (&buffer->cur())) - 1;
	else
	comp_index = comp_count - 1;

	return_trace ((this+markArray).apply (c, mark_index, comp_index, lig_attach, classCount, 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;

	hb_map_t klass_mapping;
	Markclass_closure_and_remap_indexes (this+markCoverage, this+markArray, glyphset, &klass_mapping);

	if (!klass_mapping.get_population ()) return_trace (false);
	out->classCount = klass_mapping.get_population ();

	auto mark_iter =
	+ hb_zip (this+markCoverage, this+markArray)
	\| hb_filter (glyphset, hb_first)
	;

	auto new_mark_coverage =
	+ mark_iter
	\| hb_map_retains_sorting (hb_first)
	\| hb_map_retains_sorting (glyph_map)
	;

	if (!out->markCoverage.serialize_serialize (c->serializer, new_mark_coverage))
	return_trace (false);

	if (unlikely (!out->markArray.serialize_subset (c, markArray, this,
	(this+markCoverage).iter (),
	&klass_mapping)))
	return_trace (false);

	auto new_ligature_coverage =
	+ hb_iter (this + ligatureCoverage)
	\| hb_filter (glyphset)
	\| hb_map_retains_sorting (glyph_map)
	;

	if (!out->ligatureCoverage.serialize_serialize (c->serializer, new_ligature_coverage))
	return_trace (false);

	return_trace (out->ligatureArray.serialize_subset (c, ligatureArray, this,
	hb_iter (this+ligatureCoverage),
	classCount, &klass_mapping));
	}

	};

	}
	}
	}

	#endif /* OT_LAYOUT_GPOS_MARKLIGPOSFORMAT1_HH */