src/hb-map.hh - third_party/harfbuzz - Git at Google

 /*
  * Copyright © 2018  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_MAP_HH
 #define HB_MAP_HH

 #include "hb.hh"

 #include "hb-set.hh"


 /*
  * hb_hashmap_t
  */

 extern HB_INTERNAL const hb_codepoint_t minus_1;

 template <typename K, typename V,
 	  bool minus_one = false>
 struct hb_hashmap_t
 {
   hb_hashmap_t ()  { init (); }
   ~hb_hashmap_t () { fini (); }

   hb_hashmap_t (const hb_hashmap_t& o) : hb_hashmap_t () { alloc (o.population); hb_copy (o, *this); }
   hb_hashmap_t (hb_hashmap_t&& o) : hb_hashmap_t () { hb_swap (*this, o); }
   hb_hashmap_t& operator= (const hb_hashmap_t& o)  { reset (); alloc (o.population); hb_copy (o, *this); return *this; }
   hb_hashmap_t& operator= (hb_hashmap_t&& o)  { hb_swap (*this, o); return *this; }

   hb_hashmap_t (std::initializer_list<hb_pair_t<K, V>> lst) : hb_hashmap_t ()
   {
     for (auto&& item : lst)
       set (item.first, item.second);
   }
   template <typename Iterable,
 	    hb_requires (hb_is_iterable (Iterable))>
   hb_hashmap_t (const Iterable &o) : hb_hashmap_t ()
   {
     auto iter = hb_iter (o);
     if (iter.is_random_access_iterator || iter.has_fast_len)
       alloc (hb_len (iter));
     hb_copy (iter, *this);
   }

   struct item_t
   {
     K key;
     uint32_t is_real_ : 1;
     uint32_t is_used_ : 1;
     uint32_t hash : 30;
     V value;

     item_t () : key (),
 		is_real_ (false), is_used_ (false),
 		hash (0),
 		value () {}

     // Needed for https://github.com/harfbuzz/harfbuzz/issues/4138
     K& get_key () { return key; }
     V& get_value () { return value; }

     bool is_used () const { return is_used_; }
     void set_used (bool is_used) { is_used_ = is_used; }
     void set_real (bool is_real) { is_real_ = is_real; }
     bool is_real () const { return is_real_; }

     template <bool v = minus_one,
 	      hb_enable_if (v == false)>
     static inline const V& default_value () { return Null(V); };
     template <bool v = minus_one,
 	      hb_enable_if (v == true)>
     static inline const V& default_value ()
     {
       static_assert (hb_is_same (V, hb_codepoint_t), "");
       return minus_1;
     };

     bool operator == (const K &o) const { return hb_deref (key) == hb_deref (o); }
     bool operator == (const item_t &o) const { return *this == o.key; }
     hb_pair_t<K, V> get_pair() const { return hb_pair_t<K, V> (key, value); }
     hb_pair_t<const K &, V &> get_pair_ref() { return hb_pair_t<const K &, V &> (key, value); }

     uint32_t total_hash () const
     { return (hash * 31) + hb_hash (value); }

     static constexpr bool is_trivial = std::is_trivially_constructible<K>::value &&
 				       std::is_trivially_destructible<K>::value &&
 				       std::is_trivially_constructible<V>::value &&
 				       std::is_trivially_destructible<V>::value;
   };

   hb_object_header_t header;
   unsigned int successful : 1; /* Allocations successful */
   unsigned int population : 31; /* Not including tombstones. */
   unsigned int occupancy; /* Including tombstones. */
   unsigned int mask;
   unsigned int prime;
   unsigned int max_chain_length;
   item_t *items;

   friend void swap (hb_hashmap_t& a, hb_hashmap_t& b)
   {
     if (unlikely (!a.successful || !b.successful))
       return;
     unsigned tmp = a.population;
     a.population = b.population;
     b.population = tmp;
     //hb_swap (a.population, b.population);
     hb_swap (a.occupancy, b.occupancy);
     hb_swap (a.mask, b.mask);
     hb_swap (a.prime, b.prime);
     hb_swap (a.max_chain_length, b.max_chain_length);
     hb_swap (a.items, b.items);
   }
   void init ()
   {
     hb_object_init (this);

     successful = true;
     population = occupancy = 0;
     mask = 0;
     prime = 0;
     max_chain_length = 0;
     items = nullptr;
   }
   void fini ()
   {
     hb_object_fini (this);

     if (likely (items))
     {
       unsigned size = mask + 1;
       if (!item_t::is_trivial)
 	for (unsigned i = 0; i < size; i++)
 	  items[i].~item_t ();
       hb_free (items);
       items = nullptr;
     }
     population = occupancy = 0;
   }

   void reset ()
   {
     successful = true;
     clear ();
   }

   bool in_error () const { return !successful; }

   bool alloc (unsigned new_population = 0)
   {
     if (unlikely (!successful)) return false;

     if (new_population != 0 && (new_population + new_population / 2) < mask) return true;

     unsigned int power = hb_bit_storage (hb_max ((unsigned) population, new_population) * 2 + 8);
     unsigned int new_size = 1u << power;
     item_t *new_items = (item_t *) hb_malloc ((size_t) new_size * sizeof (item_t));
     if (unlikely (!new_items))
     {
       successful = false;
       return false;
     }
     if (!item_t::is_trivial)
       for (auto &_ : hb_iter (new_items, new_size))
 	new (&_) item_t ();
     else
       hb_memset (new_items, 0, (size_t) new_size * sizeof (item_t));

     unsigned int old_size = size ();
     item_t *old_items = items;

     /* Switch to new, empty, array. */
     population = occupancy = 0;
     mask = new_size - 1;
     prime = prime_for (power);
     max_chain_length = power * 2;
     items = new_items;

     /* Insert back old items. */
     for (unsigned int i = 0; i < old_size; i++)
     {
       if (old_items[i].is_real ())
       {
 	set_with_hash (std::move (old_items[i].key),
 		       old_items[i].hash,
 		       std::move (old_items[i].value));
       }
       if (!item_t::is_trivial)
 	old_items[i].~item_t ();
     }

     hb_free (old_items);

     return true;
   }

   template <typename KK, typename VV>
   bool set_with_hash (KK&& key, uint32_t hash, VV&& value, bool overwrite = true)
   {
     if (unlikely (!successful)) return false;
     if (unlikely ((occupancy + occupancy / 2) >= mask && !alloc ())) return false;

     hash &= 0x3FFFFFFF; // We only store lower 30bit of hash
     unsigned int tombstone = (unsigned int) -1;
     unsigned int i = hash % prime;
     unsigned length = 0;
     unsigned step = 0;
     while (items[i].is_used ())
     {
       if ((std::is_integral<K>::value || items[i].hash == hash) &&
 	  items[i] == key)
       {
         if (!overwrite)
 	  return false;
         else
 	  break;
       }
       if (!items[i].is_real () && tombstone == (unsigned) -1)
         tombstone = i;
       i = (i + ++step) & mask;
       length++;
     }

     item_t &item = items[tombstone == (unsigned) -1 ? i : tombstone];

     if (item.is_used ())
     {
       occupancy--;
       population -= item.is_real ();
     }

     item.key = std::forward<KK> (key);
     item.value = std::forward<VV> (value);
     item.hash = hash;
     item.set_used (true);
     item.set_real (true);

     occupancy++;
     population++;

     if (unlikely (length > max_chain_length) && occupancy * 8 > mask)
       alloc (mask - 8); // This ensures we jump to next larger size

     return true;
   }

   template <typename VV>
   bool set (const K &key, VV&& value, bool overwrite = true) { return set_with_hash (key, hb_hash (key), std::forward<VV> (value), overwrite); }
   template <typename VV>
   bool set (K &&key, VV&& value, bool overwrite = true)
   {
     uint32_t hash = hb_hash (key);
     return set_with_hash (std::move (key), hash, std::forward<VV> (value), overwrite);
   }
   bool add (const K &key)
   {
     uint32_t hash = hb_hash (key);
     return set_with_hash (key, hash, item_t::default_value ());
   }

   const V& get_with_hash (const K &key, uint32_t hash) const
   {
     if (!items) return item_t::default_value ();
     auto *item = fetch_item (key, hb_hash (key));
     if (item)
       return item->value;
     return item_t::default_value ();
   }
   const V& get (const K &key) const
   {
     if (!items) return item_t::default_value ();
     return get_with_hash (key, hb_hash (key));
   }

   void del (const K &key)
   {
     if (!items) return;
     auto *item = fetch_item (key, hb_hash (key));
     if (item)
     {
       item->set_real (false);
       population--;
     }
   }

   /* Has interface. */
   const V& operator [] (K k) const { return get (k); }
   template <typename VV=V>
   bool has (const K &key, VV **vp = nullptr) const
   {
     if (!items) return false;
     auto *item = fetch_item (key, hb_hash (key));
     if (item)
     {
       if (vp) *vp = std::addressof (item->value);
       return true;
     }
     return false;
   }
   item_t *fetch_item (const K &key, uint32_t hash) const
   {
     hash &= 0x3FFFFFFF; // We only store lower 30bit of hash
     unsigned int i = hash % prime;
     unsigned step = 0;
     while (items[i].is_used ())
     {
       if ((std::is_integral<K>::value || items[i].hash == hash) &&
 	  items[i] == key)
       {
 	if (items[i].is_real ())
 	  return &items[i];
 	else
 	  return nullptr;
       }
       i = (i + ++step) & mask;
     }
     return nullptr;
   }
   /* Projection. */
   const V& operator () (K k) const { return get (k); }

   unsigned size () const { return mask ? mask + 1 : 0; }

   void clear ()
   {
     if (unlikely (!successful)) return;

     for (auto &_ : hb_iter (items, size ()))
     {
       /* Reconstruct items. */
       _.~item_t ();
       new (&_) item_t ();
     }

     population = occupancy = 0;
   }

   bool is_empty () const { return population == 0; }
   explicit operator bool () const { return !is_empty (); }

   uint32_t hash () const
   {
     return
     + iter_items ()
     | hb_reduce ([] (uint32_t h, const item_t &_) { return h ^ _.total_hash (); }, (uint32_t) 0u)
     ;
   }

   bool is_equal (const hb_hashmap_t &other) const
   {
     if (population != other.population) return false;

     for (auto pair : iter ())
       if (other.get (pair.first) != pair.second)
         return false;

     return true;
   }
   bool operator == (const hb_hashmap_t &other) const { return is_equal (other); }
   bool operator != (const hb_hashmap_t &other) const { return !is_equal (other); }

   unsigned int get_population () const { return population; }

   void update (const hb_hashmap_t &other)
   {
     if (unlikely (!successful)) return;

     hb_copy (other, *this);
   }

   /*
    * Iterator
    */

   auto iter_items () const HB_AUTO_RETURN
   (
     + hb_iter (items, size ())
     | hb_filter (&item_t::is_real)
   )
   auto iter_ref () const HB_AUTO_RETURN
   (
     + iter_items ()
     | hb_map (&item_t::get_pair_ref)
   )
   auto iter () const HB_AUTO_RETURN
   (
     + iter_items ()
     | hb_map (&item_t::get_pair)
   )
   auto keys_ref () const HB_AUTO_RETURN
   (
     + iter_items ()
     | hb_map (&item_t::get_key)
   )
   auto keys () const HB_AUTO_RETURN
   (
     + keys_ref ()
     | hb_map (hb_ridentity)
   )
   auto values_ref () const HB_AUTO_RETURN
   (
     + iter_items ()
     | hb_map (&item_t::get_value)
   )
   auto values () const HB_AUTO_RETURN
   (
     + values_ref ()
     | hb_map (hb_ridentity)
   )

   /* C iterator. */
   bool next (int *idx,
 	     K *key,
 	     V *value) const
   {
     unsigned i = (unsigned) (*idx + 1);

     unsigned count = size ();
     while (i < count && !items[i].is_real ())
       i++;

     if (i >= count)
     {
       *idx = -1;
       return false;
     }

     *key = items[i].key;
     *value = items[i].value;

     *idx = (signed) i;
     return true;
   }

   /* Sink interface. */
   hb_hashmap_t& operator << (const hb_pair_t<K, V>& v)
   { set (v.first, v.second); return *this; }
   hb_hashmap_t& operator << (const hb_pair_t<K, V&&>& v)
   { set (v.first, std::move (v.second)); return *this; }
   hb_hashmap_t& operator << (const hb_pair_t<K&&, V>& v)
   { set (std::move (v.first), v.second); return *this; }
   hb_hashmap_t& operator << (const hb_pair_t<K&&, V&&>& v)
   { set (std::move (v.first), std::move (v.second)); return *this; }

   static unsigned int prime_for (unsigned int shift)
   {
     /* Following comment and table copied from glib. */
     /* Each table size has an associated prime modulo (the first prime
      * lower than the table size) used to find the initial bucket. Probing
      * then works modulo 2^n. The prime modulo is necessary to get a
      * good distribution with poor hash functions.
      */
     /* Not declaring static to make all kinds of compilers happy... */
     /*static*/ const unsigned int prime_mod [32] =
     {
       1,          /* For 1 << 0 */
       2,
       3,
       7,
       13,
       31,
       61,
       127,
       251,
       509,
       1021,
       2039,
       4093,
       8191,
       16381,
       32749,
       65521,      /* For 1 << 16 */
       131071,
       262139,
       524287,
       1048573,
       2097143,
       4194301,
       8388593,
       16777213,
       33554393,
       67108859,
       134217689,
       268435399,
       536870909,
       1073741789,
       2147483647  /* For 1 << 31 */
     };

     if (unlikely (shift >= ARRAY_LENGTH (prime_mod)))
       return prime_mod[ARRAY_LENGTH (prime_mod) - 1];

     return prime_mod[shift];
   }
 };

 /*
  * hb_map_t
  */

 struct hb_map_t : hb_hashmap_t<hb_codepoint_t,
 			       hb_codepoint_t,
 			       true>
 {
   using hashmap = hb_hashmap_t<hb_codepoint_t,
 			       hb_codepoint_t,
 			       true>;

   ~hb_map_t () = default;
   hb_map_t () : hashmap () {}
   hb_map_t (const hb_map_t &o) : hashmap ((hashmap &) o) {}
   hb_map_t (hb_map_t &&o) : hashmap (std::move ((hashmap &) o)) {}
   hb_map_t& operator= (const hb_map_t&) = default;
   hb_map_t& operator= (hb_map_t&&) = default;
   hb_map_t (std::initializer_list<hb_codepoint_pair_t> lst) : hashmap (lst) {}
   template <typename Iterable,
 	    hb_requires (hb_is_iterable (Iterable))>
   hb_map_t (const Iterable &o) : hashmap (o) {}
 };


 #endif /* HB_MAP_HH */
	/*
	* Copyright © 2018 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_MAP_HH
	#define HB_MAP_HH

	#include "hb.hh"

	#include "hb-set.hh"


	/*
	* hb_hashmap_t
	*/

	extern HB_INTERNAL const hb_codepoint_t minus_1;

	template <typename K, typename V,
	bool minus_one = false>
	struct hb_hashmap_t
	{
	hb_hashmap_t () { init (); }
	~hb_hashmap_t () { fini (); }

	hb_hashmap_t (const hb_hashmap_t& o) : hb_hashmap_t () { alloc (o.population); hb_copy (o, *this); }
	hb_hashmap_t (hb_hashmap_t&& o) : hb_hashmap_t () { hb_swap (*this, o); }
	hb_hashmap_t& operator= (const hb_hashmap_t& o) { reset (); alloc (o.population); hb_copy (o, this); return this; }
	hb_hashmap_t& operator= (hb_hashmap_t&& o) { hb_swap (this, o); return this; }

	hb_hashmap_t (std::initializer_list<hb_pair_t<K, V>> lst) : hb_hashmap_t ()
	{
	for (auto&& item : lst)
	set (item.first, item.second);
	}
	template <typename Iterable,
	hb_requires (hb_is_iterable (Iterable))>
	hb_hashmap_t (const Iterable &o) : hb_hashmap_t ()
	{
	auto iter = hb_iter (o);
	if (iter.is_random_access_iterator \|\| iter.has_fast_len)
	alloc (hb_len (iter));
	hb_copy (iter, *this);
	}

	struct item_t
	{
	K key;
	uint32_t is_real_ : 1;
	uint32_t is_used_ : 1;
	uint32_t hash : 30;
	V value;

	item_t () : key (),
	is_real_ (false), is_used_ (false),
	hash (0),
	value () {}

	// Needed for https://github.com/harfbuzz/harfbuzz/issues/4138
	K& get_key () { return key; }
	V& get_value () { return value; }

	bool is_used () const { return is_used_; }
	void set_used (bool is_used) { is_used_ = is_used; }
	void set_real (bool is_real) { is_real_ = is_real; }
	bool is_real () const { return is_real_; }

	template <bool v = minus_one,
	hb_enable_if (v == false)>
	static inline const V& default_value () { return Null(V); };
	template <bool v = minus_one,
	hb_enable_if (v == true)>
	static inline const V& default_value ()
	{
	static_assert (hb_is_same (V, hb_codepoint_t), "");
	return minus_1;
	};

	bool operator == (const K &o) const { return hb_deref (key) == hb_deref (o); }
	bool operator == (const item_t &o) const { return *this == o.key; }
	hb_pair_t<K, V> get_pair() const { return hb_pair_t<K, V> (key, value); }
	hb_pair_t<const K &, V &> get_pair_ref() { return hb_pair_t<const K &, V &> (key, value); }

	uint32_t total_hash () const
	{ return (hash * 31) + hb_hash (value); }

	static constexpr bool is_trivial = std::is_trivially_constructible<K>::value &&
	std::is_trivially_destructible<K>::value &&
	std::is_trivially_constructible<V>::value &&
	std::is_trivially_destructible<V>::value;
	};

	hb_object_header_t header;
	unsigned int successful : 1; /* Allocations successful */
	unsigned int population : 31; /* Not including tombstones. */
	unsigned int occupancy; /* Including tombstones. */
	unsigned int mask;
	unsigned int prime;
	unsigned int max_chain_length;
	item_t *items;

	friend void swap (hb_hashmap_t& a, hb_hashmap_t& b)
	{
	if (unlikely (!a.successful \|\| !b.successful))
	return;
	unsigned tmp = a.population;
	a.population = b.population;
	b.population = tmp;
	//hb_swap (a.population, b.population);
	hb_swap (a.occupancy, b.occupancy);
	hb_swap (a.mask, b.mask);
	hb_swap (a.prime, b.prime);
	hb_swap (a.max_chain_length, b.max_chain_length);
	hb_swap (a.items, b.items);
	}
	void init ()
	{
	hb_object_init (this);

	successful = true;
	population = occupancy = 0;
	mask = 0;
	prime = 0;
	max_chain_length = 0;
	items = nullptr;
	}
	void fini ()
	{
	hb_object_fini (this);

	if (likely (items))
	{
	unsigned size = mask + 1;
	if (!item_t::is_trivial)
	for (unsigned i = 0; i < size; i++)
	items[i].~item_t ();
	hb_free (items);
	items = nullptr;
	}
	population = occupancy = 0;
	}

	void reset ()
	{
	successful = true;
	clear ();
	}

	bool in_error () const { return !successful; }

	bool alloc (unsigned new_population = 0)
	{
	if (unlikely (!successful)) return false;

	if (new_population != 0 && (new_population + new_population / 2) < mask) return true;

	unsigned int power = hb_bit_storage (hb_max ((unsigned) population, new_population) * 2 + 8);
	unsigned int new_size = 1u << power;
	item_t new_items = (item_t ) hb_malloc ((size_t) new_size * sizeof (item_t));
	if (unlikely (!new_items))
	{
	successful = false;
	return false;
	}
	if (!item_t::is_trivial)
	for (auto &_ : hb_iter (new_items, new_size))
	new (&_) item_t ();
	else
	hb_memset (new_items, 0, (size_t) new_size * sizeof (item_t));

	unsigned int old_size = size ();
	item_t *old_items = items;

	/* Switch to new, empty, array. */
	population = occupancy = 0;
	mask = new_size - 1;
	prime = prime_for (power);
	max_chain_length = power * 2;
	items = new_items;

	/* Insert back old items. */
	for (unsigned int i = 0; i < old_size; i++)
	{
	if (old_items[i].is_real ())
	{
	set_with_hash (std::move (old_items[i].key),
	old_items[i].hash,
	std::move (old_items[i].value));
	}
	if (!item_t::is_trivial)
	old_items[i].~item_t ();
	}

	hb_free (old_items);

	return true;
	}

	template <typename KK, typename VV>
	bool set_with_hash (KK&& key, uint32_t hash, VV&& value, bool overwrite = true)
	{
	if (unlikely (!successful)) return false;
	if (unlikely ((occupancy + occupancy / 2) >= mask && !alloc ())) return false;

	hash &= 0x3FFFFFFF; // We only store lower 30bit of hash
	unsigned int tombstone = (unsigned int) -1;
	unsigned int i = hash % prime;
	unsigned length = 0;
	unsigned step = 0;
	while (items[i].is_used ())
	{
	if ((std::is_integral<K>::value \|\| items[i].hash == hash) &&
	items[i] == key)
	{
	if (!overwrite)
	return false;
	else
	break;
	}
	if (!items[i].is_real () && tombstone == (unsigned) -1)
	tombstone = i;
	i = (i + ++step) & mask;
	length++;
	}

	item_t &item = items[tombstone == (unsigned) -1 ? i : tombstone];

	if (item.is_used ())
	{
	occupancy--;
	population -= item.is_real ();
	}

	item.key = std::forward<KK> (key);
	item.value = std::forward<VV> (value);
	item.hash = hash;
	item.set_used (true);
	item.set_real (true);

	occupancy++;
	population++;

	if (unlikely (length > max_chain_length) && occupancy * 8 > mask)
	alloc (mask - 8); // This ensures we jump to next larger size

	return true;
	}

	template <typename VV>
	bool set (const K &key, VV&& value, bool overwrite = true) { return set_with_hash (key, hb_hash (key), std::forward<VV> (value), overwrite); }
	template <typename VV>
	bool set (K &&key, VV&& value, bool overwrite = true)
	{
	uint32_t hash = hb_hash (key);
	return set_with_hash (std::move (key), hash, std::forward<VV> (value), overwrite);
	}
	bool add (const K &key)
	{
	uint32_t hash = hb_hash (key);
	return set_with_hash (key, hash, item_t::default_value ());
	}

	const V& get_with_hash (const K &key, uint32_t hash) const
	{
	if (!items) return item_t::default_value ();
	auto *item = fetch_item (key, hb_hash (key));
	if (item)
	return item->value;
	return item_t::default_value ();
	}
	const V& get (const K &key) const
	{
	if (!items) return item_t::default_value ();
	return get_with_hash (key, hb_hash (key));
	}

	void del (const K &key)
	{
	if (!items) return;
	auto *item = fetch_item (key, hb_hash (key));
	if (item)
	{
	item->set_real (false);
	population--;
	}
	}

	/* Has interface. */
	const V& operator [] (K k) const { return get (k); }
	template <typename VV=V>
	bool has (const K &key, VV **vp = nullptr) const
	{
	if (!items) return false;
	auto *item = fetch_item (key, hb_hash (key));
	if (item)
	{
	if (vp) *vp = std::addressof (item->value);
	return true;
	}
	return false;
	}
	item_t *fetch_item (const K &key, uint32_t hash) const
	{
	hash &= 0x3FFFFFFF; // We only store lower 30bit of hash
	unsigned int i = hash % prime;
	unsigned step = 0;
	while (items[i].is_used ())
	{
	if ((std::is_integral<K>::value \|\| items[i].hash == hash) &&
	items[i] == key)
	{
	if (items[i].is_real ())
	return &items[i];
	else
	return nullptr;
	}
	i = (i + ++step) & mask;
	}
	return nullptr;
	}
	/* Projection. */
	const V& operator () (K k) const { return get (k); }

	unsigned size () const { return mask ? mask + 1 : 0; }

	void clear ()
	{
	if (unlikely (!successful)) return;

	for (auto &_ : hb_iter (items, size ()))
	{
	/* Reconstruct items. */
	_.~item_t ();
	new (&_) item_t ();
	}

	population = occupancy = 0;
	}

	bool is_empty () const { return population == 0; }
	explicit operator bool () const { return !is_empty (); }

	uint32_t hash () const
	{
	return
	+ iter_items ()
	\| hb_reduce ([] (uint32_t h, const item_t &_) { return h ^ _.total_hash (); }, (uint32_t) 0u)
	;
	}

	bool is_equal (const hb_hashmap_t &other) const
	{
	if (population != other.population) return false;

	for (auto pair : iter ())
	if (other.get (pair.first) != pair.second)
	return false;

	return true;
	}
	bool operator == (const hb_hashmap_t &other) const { return is_equal (other); }
	bool operator != (const hb_hashmap_t &other) const { return !is_equal (other); }

	unsigned int get_population () const { return population; }

	void update (const hb_hashmap_t &other)
	{
	if (unlikely (!successful)) return;

	hb_copy (other, *this);
	}

	/*
	* Iterator
	*/

	auto iter_items () const HB_AUTO_RETURN
	(
	+ hb_iter (items, size ())
	\| hb_filter (&item_t::is_real)
	)
	auto iter_ref () const HB_AUTO_RETURN
	(
	+ iter_items ()
	\| hb_map (&item_t::get_pair_ref)
	)
	auto iter () const HB_AUTO_RETURN
	(
	+ iter_items ()
	\| hb_map (&item_t::get_pair)
	)
	auto keys_ref () const HB_AUTO_RETURN
	(
	+ iter_items ()
	\| hb_map (&item_t::get_key)
	)
	auto keys () const HB_AUTO_RETURN
	(
	+ keys_ref ()
	\| hb_map (hb_ridentity)
	)
	auto values_ref () const HB_AUTO_RETURN
	(
	+ iter_items ()
	\| hb_map (&item_t::get_value)
	)
	auto values () const HB_AUTO_RETURN
	(
	+ values_ref ()
	\| hb_map (hb_ridentity)
	)

	/* C iterator. */
	bool next (int *idx,
	K *key,
	V *value) const
	{
	unsigned i = (unsigned) (*idx + 1);

	unsigned count = size ();
	while (i < count && !items[i].is_real ())
	i++;

	if (i >= count)
	{
	*idx = -1;
	return false;
	}

	*key = items[i].key;
	*value = items[i].value;

	*idx = (signed) i;
	return true;
	}

	/* Sink interface. */
	hb_hashmap_t& operator << (const hb_pair_t<K, V>& v)
	{ set (v.first, v.second); return *this; }
	hb_hashmap_t& operator << (const hb_pair_t<K, V&&>& v)
	{ set (v.first, std::move (v.second)); return *this; }
	hb_hashmap_t& operator << (const hb_pair_t<K&&, V>& v)
	{ set (std::move (v.first), v.second); return *this; }
	hb_hashmap_t& operator << (const hb_pair_t<K&&, V&&>& v)
	{ set (std::move (v.first), std::move (v.second)); return *this; }

	static unsigned int prime_for (unsigned int shift)
	{
	/* Following comment and table copied from glib. */
	/* Each table size has an associated prime modulo (the first prime
	* lower than the table size) used to find the initial bucket. Probing
	* then works modulo 2^n. The prime modulo is necessary to get a
	* good distribution with poor hash functions.
	*/
	/* Not declaring static to make all kinds of compilers happy... */
	/static/ const unsigned int prime_mod [32] =
	{
	1, /* For 1 << 0 */
	2,
	3,
	7,
	13,
	31,
	61,
	127,
	251,
	509,
	1021,
	2039,
	4093,
	8191,
	16381,
	32749,
	65521, /* For 1 << 16 */
	131071,
	262139,
	524287,
	1048573,
	2097143,
	4194301,
	8388593,
	16777213,
	33554393,
	67108859,
	134217689,
	268435399,
	536870909,
	1073741789,
	2147483647 /* For 1 << 31 */
	};

	if (unlikely (shift >= ARRAY_LENGTH (prime_mod)))
	return prime_mod[ARRAY_LENGTH (prime_mod) - 1];

	return prime_mod[shift];
	}
	};

	/*
	* hb_map_t
	*/

	struct hb_map_t : hb_hashmap_t<hb_codepoint_t,
	hb_codepoint_t,
	true>
	{
	using hashmap = hb_hashmap_t<hb_codepoint_t,
	hb_codepoint_t,
	true>;

	~hb_map_t () = default;
	hb_map_t () : hashmap () {}
	hb_map_t (const hb_map_t &o) : hashmap ((hashmap &) o) {}
	hb_map_t (hb_map_t &&o) : hashmap (std::move ((hashmap &) o)) {}
	hb_map_t& operator= (const hb_map_t&) = default;
	hb_map_t& operator= (hb_map_t&&) = default;
	hb_map_t (std::initializer_list<hb_codepoint_pair_t> lst) : hashmap (lst) {}
	template <typename Iterable,
	hb_requires (hb_is_iterable (Iterable))>
	hb_map_t (const Iterable &o) : hashmap (o) {}
	};


	#endif /* HB_MAP_HH */