kc3-lang/harfbuzz/src/hb-repacker.hh

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• Hash : 8e5fffc4
  Author :
  Date : 2022-07-27T20:00:00
  

  [repack] add helper to create new nodes.
  
  Switch to malloc'ing each node individually rather than trying to guess up front the total buffer space needed.
  

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• src/hb-repacker.hh

• /*
   * Copyright © 2020  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): Garret Rieger
   */
  
  #ifndef HB_REPACKER_HH
  #define HB_REPACKER_HH
  
  #include "hb-open-type.hh"
  #include "hb-map.hh"
  #include "hb-vector.hh"
  #include "graph/graph.hh"
  #include "graph/gsubgpos-graph.hh"
  #include "graph/serialize.hh"
  
  using graph::graph_t;
  
  /*
   * For a detailed writeup on the overflow resolution algorithm see:
   * docs/repacker.md
   */
  
  struct lookup_size_t
  {
    unsigned lookup_index;
    size_t size;
    unsigned num_subtables;
  
    static int cmp (const void* a, const void* b)
    {
      return cmp ((const lookup_size_t*) a,
                  (const lookup_size_t*) b);
    }
  
    static int cmp (const lookup_size_t* a, const lookup_size_t* b)
    {
      double subtables_per_byte_a = (double) a->num_subtables / (double) a->size;
      double subtables_per_byte_b = (double) b->num_subtables / (double) b->size;
      if (subtables_per_byte_a == subtables_per_byte_b) {
        return b->lookup_index - a->lookup_index;
      }
  
      double cmp = subtables_per_byte_b - subtables_per_byte_a;
      if (cmp < 0) return -1;
      if (cmp > 0) return 1;
      return 0;
    }
  };
  
  static inline
  bool _presplit_subtables_if_needed (graph::gsubgpos_graph_context_t& ext_context)
  {
    // For each lookup this will check the size of subtables and split them as needed
    // so that no subtable is at risk of overflowing. (where we support splitting for
    // that subtable type).
    //
    // TODO(grieger): de-dup newly added nodes as necessary. Probably just want a full de-dup
    //                pass after this processing is done. Not super necessary as splits are
    //                only done where overflow is likely, so de-dup probably will get undone
    //                later anyways.
    for (unsigned lookup_index : ext_context.lookups.keys ())
    {
      graph::Lookup* lookup = ext_context.lookups.get(lookup_index);
      if (!lookup->split_subtables_if_needed (ext_context, lookup_index))
        return false;
    }
  
    return true;
  }
  
  /*
   * Analyze the lookups in a GSUB/GPOS table and decide if any should be promoted
   * to extension lookups.
   */
  static inline
  bool _promote_extensions_if_needed (graph::gsubgpos_graph_context_t& ext_context)
  {
    // Simple Algorithm (v1, current):
    // 1. Calculate how many bytes each non-extension lookup consumes.
    // 2. Select up to 64k of those to remain as non-extension (greedy, highest subtables per byte first)
    // 3. Promote the rest.
    //
    // Advanced Algorithm (v2, not implemented):
    // 1. Perform connected component analysis using lookups as roots.
    // 2. Compute size of each connected component.
    // 3. Select up to 64k worth of connected components to remain as non-extensions.
    //    (greedy, highest subtables per byte first)
    // 4. Promote the rest.
  
    // TODO(garretrieger): support extension demotion, then consider all lookups. Requires advanced algo.
    // TODO(garretrieger): also support extension promotion during iterative resolution phase, then
    //                     we can use a less conservative threshold here.
    // TODO(grieger): skip this for the 24 bit case.
    if (!ext_context.lookups) return true;
  
    hb_vector_t<lookup_size_t> lookup_sizes;
    lookup_sizes.alloc (ext_context.lookups.get_population ());
  
    for (unsigned lookup_index : ext_context.lookups.keys ())
    {
      const graph::Lookup* lookup = ext_context.lookups.get(lookup_index);
      hb_set_t visited;
      lookup_sizes.push (lookup_size_t {
          lookup_index,
          ext_context.graph.find_subgraph_size (lookup_index, visited),
          lookup->number_of_subtables (),
        });
    }
  
    lookup_sizes.qsort ();
  
    size_t lookup_list_size = ext_context.graph.vertices_[ext_context.lookup_list_index].table_size ();
    size_t l2_l3_size = lookup_list_size; // Lookup List + Lookups
    size_t l3_l4_size = 0; // Lookups + SubTables
    size_t l4_plus_size = 0; // SubTables + their descendants
  
    // Start by assuming all lookups are using extension subtables, this size will be removed later
    // if it's decided to not make a lookup extension.
    for (auto p : lookup_sizes)
    {
      unsigned subtables_size = p.num_subtables * 8;
      l3_l4_size += subtables_size;
      l4_plus_size += subtables_size;
    }
  
    bool layers_full = false;
    for (auto p : lookup_sizes)
    {
      const graph::Lookup* lookup = ext_context.lookups.get(p.lookup_index);
      if (lookup->is_extension (ext_context.table_tag))
        // already an extension so size is counted by the loop above.
        continue;
  
      if (!layers_full)
      {
        size_t lookup_size = ext_context.graph.vertices_[p.lookup_index].table_size ();
        hb_set_t visited;
        size_t subtables_size = ext_context.graph.find_subgraph_size (p.lookup_index, visited, 1) - lookup_size;
        size_t remaining_size = p.size - subtables_size - lookup_size;
  
        l2_l3_size   += lookup_size;
        l3_l4_size   += lookup_size + subtables_size;
        l3_l4_size   -= p.num_subtables * 8;
        l4_plus_size += subtables_size + remaining_size;
  
        if (l2_l3_size < (1 << 16)
            && l3_l4_size < (1 << 16)
            && l4_plus_size < (1 << 16)) continue; // this lookup fits within all layers groups
  
        layers_full = true;
      }
  
      if (!ext_context.lookups.get(p.lookup_index)->make_extension (ext_context, p.lookup_index))
        return false;
    }
  
    return true;
  }
  
  static inline
  bool _try_isolating_subgraphs (const hb_vector_t<graph::overflow_record_t>& overflows,
                                 graph_t& sorted_graph)
  {
    unsigned space = 0;
    hb_set_t roots_to_isolate;
  
    for (int i = overflows.length - 1; i >= 0; i--)
    {
      const graph::overflow_record_t& r = overflows[i];
  
      unsigned root;
      unsigned overflow_space = sorted_graph.space_for (r.parent, &root);
      if (!overflow_space) continue;
      if (sorted_graph.num_roots_for_space (overflow_space) <= 1) continue;
  
      if (!space) {
        space = overflow_space;
      }
  
      if (space == overflow_space)
        roots_to_isolate.add(root);
    }
  
    if (!roots_to_isolate) return false;
  
    unsigned maximum_to_move = hb_max ((sorted_graph.num_roots_for_space (space) / 2u), 1u);
    if (roots_to_isolate.get_population () > maximum_to_move) {
      // Only move at most half of the roots in a space at a time.
      unsigned extra = roots_to_isolate.get_population () - maximum_to_move;
      while (extra--) {
        unsigned root = HB_SET_VALUE_INVALID;
        roots_to_isolate.previous (&root);
        roots_to_isolate.del (root);
      }
    }
  
    DEBUG_MSG (SUBSET_REPACK, nullptr,
               "Overflow in space %d (%d roots). Moving %d roots to space %d.",
               space,
               sorted_graph.num_roots_for_space (space),
               roots_to_isolate.get_population (),
               sorted_graph.next_space ());
  
    sorted_graph.isolate_subgraph (roots_to_isolate);
    sorted_graph.move_to_new_space (roots_to_isolate);
  
    return true;
  }
  
  static inline
  bool _process_overflows (const hb_vector_t<graph::overflow_record_t>& overflows,
                           hb_set_t& priority_bumped_parents,
                           graph_t& sorted_graph)
  {
    bool resolution_attempted = false;
  
    // Try resolving the furthest overflows first.
    for (int i = overflows.length - 1; i >= 0; i--)
    {
      const graph::overflow_record_t& r = overflows[i];
      const auto& child = sorted_graph.vertices_[r.child];
      if (child.is_shared ())
      {
        // The child object is shared, we may be able to eliminate the overflow
        // by duplicating it.
        if (!sorted_graph.duplicate (r.parent, r.child)) continue;
        return true;
      }
  
      if (child.is_leaf () && !priority_bumped_parents.has (r.parent))
      {
        // This object is too far from it's parent, attempt to move it closer.
        //
        // TODO(garretrieger): initially limiting this to leaf's since they can be
        //                     moved closer with fewer consequences. However, this can
        //                     likely can be used for non-leafs as well.
        // TODO(garretrieger): also try lowering priority of the parent. Make it
        //                     get placed further up in the ordering, closer to it's children.
        //                     this is probably preferable if the total size of the parent object
        //                     is < then the total size of the children (and the parent can be moved).
        //                     Since in that case moving the parent will cause a smaller increase in
        //                     the length of other offsets.
        if (sorted_graph.raise_childrens_priority (r.parent)) {
          priority_bumped_parents.add (r.parent);
          resolution_attempted = true;
        }
        continue;
      }
  
      // TODO(garretrieger): add additional offset resolution strategies
      // - Promotion to extension lookups.
      // - Table splitting.
    }
  
    return resolution_attempted;
  }
  
  /*
   * Attempts to modify the topological sorting of the provided object graph to
   * eliminate offset overflows in the links between objects of the graph. If a
   * non-overflowing ordering is found the updated graph is serialized it into the
   * provided serialization context.
   *
   * If necessary the structure of the graph may be modified in ways that do not
   * affect the functionality of the graph. For example shared objects may be
   * duplicated.
   *
   * For a detailed writeup describing how the algorithm operates see:
   * docs/repacker.md
   */
  template<typename T>
  inline hb_blob_t*
  hb_resolve_overflows (const T& packed,
                        hb_tag_t table_tag,
                        unsigned max_rounds = 20,
                        bool recalculate_extensions = false) {
    graph_t sorted_graph (packed);
    sorted_graph.sort_shortest_distance ();
  
    bool will_overflow = graph::will_overflow (sorted_graph);
    if (!will_overflow)
    {
      return graph::serialize (sorted_graph);
    }
  
    graph::gsubgpos_graph_context_t ext_context (table_tag, sorted_graph);
    if ((table_tag == HB_OT_TAG_GPOS
         ||  table_tag == HB_OT_TAG_GSUB)
        && will_overflow)
    {
      if (recalculate_extensions)
      {
        DEBUG_MSG (SUBSET_REPACK, nullptr, "Splitting subtables if needed.");
        if (!_presplit_subtables_if_needed (ext_context)) {
          DEBUG_MSG (SUBSET_REPACK, nullptr, "Subtable splitting failed.");
          return nullptr;
        }
  
        DEBUG_MSG (SUBSET_REPACK, nullptr, "Promoting lookups to extensions if needed.");
        if (!_promote_extensions_if_needed (ext_context)) {
          DEBUG_MSG (SUBSET_REPACK, nullptr, "Extensions promotion failed.");
          return nullptr;
        }
      }
  
      DEBUG_MSG (SUBSET_REPACK, nullptr, "Assigning spaces to 32 bit subgraphs.");
      if (sorted_graph.assign_spaces ())
        sorted_graph.sort_shortest_distance ();
      else
        sorted_graph.sort_shortest_distance_if_needed ();
    }
  
    unsigned round = 0;
    hb_vector_t<graph::overflow_record_t> overflows;
    // TODO(garretrieger): select a good limit for max rounds.
    while (!sorted_graph.in_error ()
           && graph::will_overflow (sorted_graph, &overflows)
           && round < max_rounds) {
      DEBUG_MSG (SUBSET_REPACK, nullptr, "=== Overflow resolution round %d ===", round);
      print_overflows (sorted_graph, overflows);
  
      hb_set_t priority_bumped_parents;
  
      if (!_try_isolating_subgraphs (overflows, sorted_graph))
      {
        // Don't count space isolation towards round limit. Only increment
        // round counter if space isolation made no changes.
        round++;
        if (!_process_overflows (overflows, priority_bumped_parents, sorted_graph))
        {
          DEBUG_MSG (SUBSET_REPACK, nullptr, "No resolution available :(");
          break;
        }
      }
  
      sorted_graph.sort_shortest_distance ();
    }
  
    if (sorted_graph.in_error ())
    {
      DEBUG_MSG (SUBSET_REPACK, nullptr, "Sorted graph in error state.");
      return nullptr;
    }
  
    if (graph::will_overflow (sorted_graph))
    {
      DEBUG_MSG (SUBSET_REPACK, nullptr, "Offset overflow resolution failed.");
      return nullptr;
    }
  
    return graph::serialize (sorted_graph);
  }
  
  #endif /* HB_REPACKER_HH */
  

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