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

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• Hash : a4b7033d
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  Date : 2023-02-19T17:48:02
  

  [cff2-subset] Blend Private values when instancing
  

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• src/hb-serialize.hh

• /*
   * Copyright © 2007,2008,2009,2010  Red Hat, Inc.
   * Copyright © 2012,2018  Google, Inc.
   * Copyright © 2019  Facebook, 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.
   *
   * Red Hat Author(s): Behdad Esfahbod
   * Google Author(s): Behdad Esfahbod
   * Facebook Author(s): Behdad Esfahbod
   */
  
  #ifndef HB_SERIALIZE_HH
  #define HB_SERIALIZE_HH
  
  #include "hb.hh"
  #include "hb-blob.hh"
  #include "hb-map.hh"
  #include "hb-pool.hh"
  
  #ifdef HB_EXPERIMENTAL_API
  #include "hb-subset-repacker.h"
  #endif
  
  /*
   * Serialize
   */
  
  enum hb_serialize_error_t {
    HB_SERIALIZE_ERROR_NONE =            0x00000000u,
    HB_SERIALIZE_ERROR_OTHER =           0x00000001u,
    HB_SERIALIZE_ERROR_OFFSET_OVERFLOW = 0x00000002u,
    HB_SERIALIZE_ERROR_OUT_OF_ROOM =     0x00000004u,
    HB_SERIALIZE_ERROR_INT_OVERFLOW =    0x00000008u,
    HB_SERIALIZE_ERROR_ARRAY_OVERFLOW =  0x00000010u
  };
  HB_MARK_AS_FLAG_T (hb_serialize_error_t);
  
  struct hb_serialize_context_t
  {
    typedef unsigned objidx_t;
  
    enum whence_t {
       Head,	/* Relative to the current object head (default). */
       Tail,	/* Relative to the current object tail after packed. */
       Absolute	/* Absolute: from the start of the serialize buffer. */
     };
  
  
  
    struct object_t
    {
      void fini () {
        real_links.fini ();
        virtual_links.fini ();
      }
  
      object_t () = default;
  
  #ifdef HB_EXPERIMENTAL_API
      object_t (const hb_object_t &o)
      {
        head = o.head;
        tail = o.tail;
        next = nullptr;
        real_links.alloc (o.num_real_links, true);
        for (unsigned i = 0 ; i < o.num_real_links; i++)
          real_links.push (o.real_links[i]);
  
        virtual_links.alloc (o.num_virtual_links, true);
        for (unsigned i = 0; i < o.num_virtual_links; i++)
          virtual_links.push (o.virtual_links[i]);
      }
  #endif
  
      friend void swap (object_t& a, object_t& b)
      {
        hb_swap (a.head, b.head);
        hb_swap (a.tail, b.tail);
        hb_swap (a.next, b.next);
        hb_swap (a.real_links, b.real_links);
        hb_swap (a.virtual_links, b.virtual_links);
      }
  
      bool operator == (const object_t &o) const
      {
        // Virtual links aren't considered for equality since they don't affect the functionality
        // of the object.
        return (tail - head == o.tail - o.head)
  	  && (real_links.length == o.real_links.length)
  	  && 0 == hb_memcmp (head, o.head, tail - head)
  	  && real_links.as_bytes () == o.real_links.as_bytes ();
      }
      uint32_t hash () const
      {
        // Virtual links aren't considered for equality since they don't affect the functionality
        // of the object.
        return hb_bytes_t (head, tail - head).hash () ^
            real_links.as_bytes ().hash ();
      }
  
      struct link_t
      {
        unsigned width: 3;
        unsigned is_signed: 1;
        unsigned whence: 2;
        unsigned bias : 26;
        unsigned position;
        objidx_t objidx;
  
        link_t () = default;
  
  #ifdef HB_EXPERIMENTAL_API
        link_t (const hb_link_t &o)
        {
          width = o.width;
          is_signed = 0;
          whence = 0;
          position = o.position;
          bias = 0;
          objidx = o.objidx;
        }
  #endif
  
        HB_INTERNAL static int cmp (const void* a, const void* b)
        {
          int cmp = ((const link_t*)a)->position - ((const link_t*)b)->position;
          if (cmp) return cmp;
  
          return ((const link_t*)a)->objidx - ((const link_t*)b)->objidx;
        }
      };
  
      char *head;
      char *tail;
      hb_vector_t<link_t> real_links;
      hb_vector_t<link_t> virtual_links;
      object_t *next;
  
      auto all_links () const HB_AUTO_RETURN
          (( hb_concat (this->real_links, this->virtual_links) ));
      auto all_links_writer () HB_AUTO_RETURN
          (( hb_concat (this->real_links.writer (), this->virtual_links.writer ()) ));
    };
  
    struct snapshot_t
    {
      char *head;
      char *tail;
      object_t *current; // Just for sanity check
      unsigned num_real_links;
      unsigned num_virtual_links;
      hb_serialize_error_t errors;
    };
  
    snapshot_t snapshot ()
    { return snapshot_t {
        head, tail, current, current->real_links.length, current->virtual_links.length, errors }; }
  
    hb_serialize_context_t (void *start_, unsigned int size) :
      start ((char *) start_),
      end (start + size),
      current (nullptr)
    { reset (); }
    ~hb_serialize_context_t () { fini (); }
  
    void fini ()
    {
      for (object_t *_ : ++hb_iter (packed)) _->fini ();
      packed.fini ();
      this->packed_map.fini ();
  
      while (current)
      {
        auto *_ = current;
        current = current->next;
        _->fini ();
      }
    }
  
    bool in_error () const { return bool (errors); }
  
    bool successful () const { return !bool (errors); }
  
    HB_NODISCARD bool ran_out_of_room () const { return errors & HB_SERIALIZE_ERROR_OUT_OF_ROOM; }
    HB_NODISCARD bool offset_overflow () const { return errors & HB_SERIALIZE_ERROR_OFFSET_OVERFLOW; }
    HB_NODISCARD bool only_offset_overflow () const { return errors == HB_SERIALIZE_ERROR_OFFSET_OVERFLOW; }
    HB_NODISCARD bool only_overflow () const
    {
      return errors == HB_SERIALIZE_ERROR_OFFSET_OVERFLOW
          || errors == HB_SERIALIZE_ERROR_INT_OVERFLOW
          || errors == HB_SERIALIZE_ERROR_ARRAY_OVERFLOW;
    }
  
    void reset (void *start_, unsigned int size)
    {
      start = (char*) start_;
      end = start + size;
      reset ();
      current = nullptr;
    }
  
    void reset ()
    {
      this->errors = HB_SERIALIZE_ERROR_NONE;
      this->head = this->start;
      this->tail = this->end;
      this->zerocopy = nullptr;
      this->debug_depth = 0;
  
      fini ();
      this->packed.push (nullptr);
      this->packed_map.init ();
    }
  
    bool check_success (bool success,
                        hb_serialize_error_t err_type = HB_SERIALIZE_ERROR_OTHER)
    {
      return successful ()
          && (success || err (err_type));
    }
  
    template <typename T1, typename T2>
    bool check_equal (T1 &&v1, T2 &&v2, hb_serialize_error_t err_type)
    {
      if ((long long) v1 != (long long) v2)
      {
        return err (err_type);
      }
      return true;
    }
  
    template <typename T1, typename T2>
    bool check_assign (T1 &v1, T2 &&v2, hb_serialize_error_t err_type)
    { return check_equal (v1 = v2, v2, err_type); }
  
    template <typename T> bool propagate_error (T &&obj)
    { return check_success (!hb_deref (obj).in_error ()); }
  
    template <typename T1, typename... Ts> bool propagate_error (T1 &&o1, Ts&&... os)
    { return propagate_error (std::forward<T1> (o1)) &&
  	   propagate_error (std::forward<Ts> (os)...); }
  
    /* To be called around main operation. */
    template <typename Type>
    Type *start_serialize ()
    {
      DEBUG_MSG_LEVEL (SERIALIZE, this->start, 0, +1,
  		     "start [%p..%p] (%lu bytes)",
  		     this->start, this->end,
  		     (unsigned long) (this->end - this->start));
  
      assert (!current);
      return push<Type> ();
    }
    void end_serialize ()
    {
      DEBUG_MSG_LEVEL (SERIALIZE, this->start, 0, -1,
  		     "end [%p..%p] serialized %u bytes; %s",
  		     this->start, this->end,
  		     (unsigned) (this->head - this->start),
  		     successful () ? "successful" : "UNSUCCESSFUL");
  
      propagate_error (packed, packed_map);
  
      if (unlikely (!current)) return;
      if (unlikely (in_error()))
      {
        // Offset overflows that occur before link resolution cannot be handled
        // by repacking, so set a more general error.
        if (offset_overflow ()) err (HB_SERIALIZE_ERROR_OTHER);
        return;
      }
  
      assert (!current->next);
  
      /* Only "pack" if there exist other objects... Otherwise, don't bother.
       * Saves a move. */
      if (packed.length <= 1)
        return;
  
      pop_pack (false);
  
      resolve_links ();
    }
  
    template <typename Type = void>
    Type *push ()
    {
      if (unlikely (in_error ())) return start_embed<Type> ();
  
      object_t *obj = object_pool.alloc ();
      if (unlikely (!obj))
        check_success (false);
      else
      {
        obj->head = head;
        obj->tail = tail;
        obj->next = current;
        current = obj;
      }
      return start_embed<Type> ();
    }
    void pop_discard ()
    {
      object_t *obj = current;
      if (unlikely (!obj)) return;
      if (unlikely (in_error() && !only_overflow ())) return;
  
      current = current->next;
      revert (zerocopy ? zerocopy : obj->head, obj->tail);
      zerocopy = nullptr;
      obj->fini ();
      object_pool.release (obj);
    }
  
    /* Set share to false when an object is unlikely shareable with others
     * so not worth an attempt, or a contiguous table is serialized as
     * multiple consecutive objects in the reverse order so can't be shared.
     */
    objidx_t pop_pack (bool share=true)
    {
      object_t *obj = current;
      if (unlikely (!obj)) return 0;
      if (unlikely (in_error())) return 0;
  
      current = current->next;
      obj->tail = head;
      obj->next = nullptr;
      assert (obj->head <= obj->tail);
      unsigned len = obj->tail - obj->head;
      head = zerocopy ? zerocopy : obj->head; /* Rewind head. */
      bool was_zerocopy = zerocopy;
      zerocopy = nullptr;
  
      if (!len)
      {
        assert (!obj->real_links.length);
        assert (!obj->virtual_links.length);
        return 0;
      }
  
      objidx_t objidx;
      uint32_t hash = 0;
      if (share)
      {
        hash = hb_hash (obj);
        objidx = packed_map.get_with_hash (obj, hash);
        if (objidx)
        {
          merge_virtual_links (obj, objidx);
  	obj->fini ();
  	return objidx;
        }
      }
  
      tail -= len;
      if (was_zerocopy)
        assert (tail == obj->head);
      else
        memmove (tail, obj->head, len);
  
      obj->head = tail;
      obj->tail = tail + len;
  
      packed.push (obj);
  
      if (unlikely (!propagate_error (packed)))
      {
        /* Obj wasn't successfully added to packed, so clean it up otherwise its
         * links will be leaked. When we use constructor/destructors properly, we
         * can remove these. */
        obj->fini ();
        return 0;
      }
  
      objidx = packed.length - 1;
  
      if (share) packed_map.set_with_hash (obj, hash, objidx);
      propagate_error (packed_map);
  
      return objidx;
    }
  
    void revert (snapshot_t snap)
    {
      // Overflows that happened after the snapshot will be erased by the revert.
      if (unlikely (in_error () && !only_overflow ())) return;
      assert (snap.current == current);
      current->real_links.shrink (snap.num_real_links);
      current->virtual_links.shrink (snap.num_virtual_links);
      errors = snap.errors;
      revert (snap.head, snap.tail);
    }
  
    void revert (char *snap_head,
  	       char *snap_tail)
    {
      if (unlikely (in_error ())) return;
      assert (snap_head <= head);
      assert (tail <= snap_tail);
      head = snap_head;
      tail = snap_tail;
      discard_stale_objects ();
    }
  
    void discard_stale_objects ()
    {
      if (unlikely (in_error ())) return;
      while (packed.length > 1 &&
  	   packed.tail ()->head < tail)
      {
        packed_map.del (packed.tail ());
        assert (!packed.tail ()->next);
        packed.tail ()->fini ();
        packed.pop ();
      }
      if (packed.length > 1)
        assert (packed.tail ()->head == tail);
    }
  
    // Adds a virtual link from the current object to objidx. A virtual link is not associated with
    // an actual offset field. They are solely used to enforce ordering constraints between objects.
    // Adding a virtual link from object a to object b will ensure that object b is always packed after
    // object a in the final serialized order.
    //
    // This is useful in certain situations where there needs to be a specific ordering in the
    // final serialization. Such as when platform bugs require certain orderings, or to provide
    //  guidance to the repacker for better offset overflow resolution.
    void add_virtual_link (objidx_t objidx)
    {
      if (unlikely (in_error ())) return;
  
      if (!objidx)
        return;
  
      assert (current);
  
      auto& link = *current->virtual_links.push ();
      if (current->virtual_links.in_error ())
        err (HB_SERIALIZE_ERROR_OTHER);
  
      link.width = 0;
      link.objidx = objidx;
      link.is_signed = 0;
      link.whence = 0;
      link.position = 0;
      link.bias = 0;
    }
  
    template <typename T>
    void add_link (T &ofs, objidx_t objidx,
  		 whence_t whence = Head,
  		 unsigned bias = 0)
    {
      if (unlikely (in_error ())) return;
  
      if (!objidx)
        return;
  
      assert (current);
      assert (current->head <= (const char *) &ofs);
  
      auto& link = *current->real_links.push ();
      if (current->real_links.in_error ())
        err (HB_SERIALIZE_ERROR_OTHER);
  
      link.width = sizeof (T);
      link.objidx = objidx;
      if (unlikely (!sizeof (T)))
      {
        // This link is not associated with an actual offset and exists merely to enforce
        // an ordering constraint.
        link.is_signed = 0;
        link.whence = 0;
        link.position = 0;
        link.bias = 0;
        return;
      }
  
      link.is_signed = std::is_signed<hb_unwrap_type (T)>::value;
      link.whence = (unsigned) whence;
      link.position = (const char *) &ofs - current->head;
      link.bias = bias;
    }
  
    unsigned to_bias (const void *base) const
    {
      if (unlikely (in_error ())) return 0;
      if (!base) return 0;
      assert (current);
      assert (current->head <= (const char *) base);
      return (const char *) base - current->head;
    }
  
    void resolve_links ()
    {
      if (unlikely (in_error ())) return;
  
      assert (!current);
      assert (packed.length > 1);
  
      for (const object_t* parent : ++hb_iter (packed))
        for (const object_t::link_t &link : parent->real_links)
        {
  	const object_t* child = packed[link.objidx];
  	if (unlikely (!child)) { err (HB_SERIALIZE_ERROR_OTHER); return; }
  	unsigned offset = 0;
  	switch ((whence_t) link.whence) {
  	case Head:     offset = child->head - parent->head; break;
  	case Tail:     offset = child->head - parent->tail; break;
  	case Absolute: offset = (head - start) + (child->head - tail); break;
  	}
  
  	assert (offset >= link.bias);
  	offset -= link.bias;
  	if (link.is_signed)
  	{
  	  assert (link.width == 2 || link.width == 4);
  	  if (link.width == 4)
  	    assign_offset<int32_t> (parent, link, offset);
  	  else
  	    assign_offset<int16_t> (parent, link, offset);
  	}
  	else
  	{
  	  assert (link.width == 2 || link.width == 3 || link.width == 4);
  	  if (link.width == 4)
  	    assign_offset<uint32_t> (parent, link, offset);
  	  else if (link.width == 3)
  	    assign_offset<uint32_t, 3> (parent, link, offset);
  	  else
  	    assign_offset<uint16_t> (parent, link, offset);
  	}
        }
    }
  
    unsigned int length () const
    {
      if (unlikely (!current)) return 0;
      return this->head - current->head;
    }
  
    void align (unsigned int alignment)
    {
      unsigned int l = length () % alignment;
      if (l)
        allocate_size<void> (alignment - l);
    }
  
    template <typename Type = void>
    Type *start_embed (const Type *obj HB_UNUSED = nullptr) const
    { return reinterpret_cast<Type *> (this->head); }
    template <typename Type>
    Type *start_embed (const Type &obj) const
    { return start_embed (std::addressof (obj)); }
  
    bool err (hb_serialize_error_t err_type)
    {
      return !bool ((errors = (errors | err_type)));
    }
  
    bool start_zerocopy (size_t size)
    {
      if (unlikely (in_error ())) return false;
  
      if (unlikely (size > INT_MAX || this->tail - this->head < ptrdiff_t (size)))
      {
        err (HB_SERIALIZE_ERROR_OUT_OF_ROOM);
        return false;
      }
  
      assert (!this->zerocopy);
      this->zerocopy = this->head;
  
      assert (this->current->head == this->head);
      this->current->head = this->current->tail = this->head = this->tail - size;
      return true;
    }
  
    template <typename Type>
    Type *allocate_size (size_t size, bool clear = true)
    {
      if (unlikely (in_error ())) return nullptr;
  
      if (unlikely (size > INT_MAX || this->tail - this->head < ptrdiff_t (size)))
      {
        err (HB_SERIALIZE_ERROR_OUT_OF_ROOM);
        return nullptr;
      }
      if (clear)
        hb_memset (this->head, 0, size);
      char *ret = this->head;
      this->head += size;
      return reinterpret_cast<Type *> (ret);
    }
  
    template <typename Type>
    Type *allocate_min ()
    { return this->allocate_size<Type> (Type::min_size); }
  
    template <typename Type>
    Type *embed (const Type *obj)
    {
      unsigned int size = obj->get_size ();
      Type *ret = this->allocate_size<Type> (size, false);
      if (unlikely (!ret)) return nullptr;
      hb_memcpy (ret, obj, size);
      return ret;
    }
    template <typename Type>
    Type *embed (const Type &obj)
    { return embed (std::addressof (obj)); }
    char *embed (const char *obj, unsigned size)
    {
      char *ret = this->allocate_size<char> (size, false);
      if (unlikely (!ret)) return nullptr;
      hb_memcpy (ret, obj, size);
      return ret;
    }
  
    template <typename Type, typename ...Ts> auto
    _copy (const Type &src, hb_priority<1>, Ts&&... ds) HB_RETURN
    (Type *, src.copy (this, std::forward<Ts> (ds)...))
  
    template <typename Type> auto
    _copy (const Type &src, hb_priority<0>) -> decltype (&(hb_declval<Type> () = src))
    {
      Type *ret = this->allocate_size<Type> (sizeof (Type));
      if (unlikely (!ret)) return nullptr;
      *ret = src;
      return ret;
    }
  
    /* Like embed, but active: calls obj.operator=() or obj.copy() to transfer data
     * instead of hb_memcpy(). */
    template <typename Type, typename ...Ts>
    Type *copy (const Type &src, Ts&&... ds)
    { return _copy (src, hb_prioritize, std::forward<Ts> (ds)...); }
    template <typename Type, typename ...Ts>
    Type *copy (const Type *src, Ts&&... ds)
    { return copy (*src, std::forward<Ts> (ds)...); }
  
    template<typename Iterator,
  	   hb_requires (hb_is_iterator (Iterator)),
  	   typename ...Ts>
    void copy_all (Iterator it, Ts&&... ds)
    { for (decltype (*it) _ : it) copy (_, std::forward<Ts> (ds)...); }
  
    template <typename Type>
    hb_serialize_context_t& operator << (const Type &obj) & { embed (obj); return *this; }
  
    template <typename Type>
    Type *extend_size (Type *obj, size_t size, bool clear = true)
    {
      if (unlikely (in_error ())) return nullptr;
  
      assert (this->start <= (char *) obj);
      assert ((char *) obj <= this->head);
      assert ((size_t) (this->head - (char *) obj) <= size);
      if (unlikely (((char *) obj + size < (char *) obj) ||
  		  !this->allocate_size<Type> (((char *) obj) + size - this->head, clear))) return nullptr;
      return reinterpret_cast<Type *> (obj);
    }
    template <typename Type>
    Type *extend_size (Type &obj, size_t size, bool clear = true)
    { return extend_size (std::addressof (obj), size, clear); }
  
    template <typename Type>
    Type *extend_min (Type *obj) { return extend_size (obj, obj->min_size); }
    template <typename Type>
    Type *extend_min (Type &obj) { return extend_min (std::addressof (obj)); }
  
    template <typename Type, typename ...Ts>
    Type *extend (Type *obj, Ts&&... ds)
    { return extend_size (obj, obj->get_size (std::forward<Ts> (ds)...)); }
    template <typename Type, typename ...Ts>
    Type *extend (Type &obj, Ts&&... ds)
    { return extend (std::addressof (obj), std::forward<Ts> (ds)...); }
  
    /* Output routines. */
    hb_bytes_t copy_bytes () const
    {
      assert (successful ());
      /* Copy both items from head side and tail side... */
      unsigned int len = (this->head - this->start)
  		     + (this->end  - this->tail);
  
      // If len is zero don't hb_malloc as the memory won't get properly
      // cleaned up later.
      if (!len) return hb_bytes_t ();
  
      char *p = (char *) hb_malloc (len);
      if (unlikely (!p)) return hb_bytes_t ();
  
      hb_memcpy (p, this->start, this->head - this->start);
      hb_memcpy (p + (this->head - this->start), this->tail, this->end - this->tail);
      return hb_bytes_t (p, len);
    }
    template <typename Type>
    Type *copy () const
    { return reinterpret_cast<Type *> ((char *) copy_bytes ().arrayZ); }
    hb_blob_t *copy_blob () const
    {
      hb_bytes_t b = copy_bytes ();
      return hb_blob_create (b.arrayZ, b.length,
  			   HB_MEMORY_MODE_WRITABLE,
  			   (char *) b.arrayZ, hb_free);
    }
  
    const hb_vector_t<object_t *>& object_graph() const
    { return packed; }
  
    private:
    template <typename T, unsigned Size = sizeof (T)>
    void assign_offset (const object_t* parent, const object_t::link_t &link, unsigned offset)
    {
      auto &off = * ((BEInt<T, Size> *) (parent->head + link.position));
      assert (0 == off);
      check_assign (off, offset, HB_SERIALIZE_ERROR_OFFSET_OVERFLOW);
    }
  
    public:
    char *start, *head, *tail, *end, *zerocopy;
    unsigned int debug_depth;
    hb_serialize_error_t errors;
  
    private:
  
    void merge_virtual_links (const object_t* from, objidx_t to_idx) {
      object_t* to = packed[to_idx];
      for (const auto& l : from->virtual_links) {
        to->virtual_links.push (l);
      }
    }
  
    /* Object memory pool. */
    hb_pool_t<object_t> object_pool;
  
    /* Stack of currently under construction objects. */
    object_t *current;
  
    /* Stack of packed objects.  Object 0 is always nil object. */
    hb_vector_t<object_t *> packed;
  
    /* Map view of packed objects. */
    hb_hashmap_t<const object_t *, objidx_t> packed_map;
  };
  
  #endif /* HB_SERIALIZE_HH */
  

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