/* A type-safe hash map. Copyright (C) 2014-2019 Free Software Foundation, Inc. This file is part of GCC. GCC is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3, or (at your option) any later version. GCC is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with GCC; see the file COPYING3. If not see . */ #ifndef hash_map_h #define hash_map_h /* Class hash_map is a hash-value based container mapping objects of KeyId type to those of the Value type. Both KeyId and Value may be non-trivial (non-POD) types provided a suitabe Traits class. A few default Traits specializations are provided for basic types such as integers, pointers, and std::pair. Inserted elements are value-initialized either to zero for POD types or by invoking their default ctor. Removed elements are destroyed by invoking their dtor. On hash_map destruction all elements are removed. Objects of hash_map type are copy-constructible but not assignable. */ const size_t default_hash_map_size = 13; template, Value> */> class GTY((user)) hash_map { typedef typename Traits::key_type Key; struct hash_entry { Key m_key; Value m_value; typedef hash_entry value_type; typedef Key compare_type; static hashval_t hash (const hash_entry &e) { return Traits::hash (e.m_key); } static bool equal (const hash_entry &a, const Key &b) { return Traits::equal_keys (a.m_key, b); } static void remove (hash_entry &e) { Traits::remove (e); } static void mark_deleted (hash_entry &e) { Traits::mark_deleted (e); } static bool is_deleted (const hash_entry &e) { return Traits::is_deleted (e); } static void mark_empty (hash_entry &e) { Traits::mark_empty (e); } static bool is_empty (const hash_entry &e) { return Traits::is_empty (e); } static void ggc_mx (hash_entry &e) { gt_ggc_mx (e.m_key); gt_ggc_mx (e.m_value); } static void ggc_maybe_mx (hash_entry &e) { if (Traits::maybe_mx) ggc_mx (e); } static void pch_nx (hash_entry &e) { gt_pch_nx (e.m_key); gt_pch_nx (e.m_value); } static void pch_nx (hash_entry &e, gt_pointer_operator op, void *c) { pch_nx_helper (e.m_key, op, c); pch_nx_helper (e.m_value, op, c); } static int keep_cache_entry (hash_entry &e) { return ggc_marked_p (e.m_key); } private: template static void pch_nx_helper (T &x, gt_pointer_operator op, void *cookie) { gt_pch_nx (&x, op, cookie); } static void pch_nx_helper (int, gt_pointer_operator, void *) { } static void pch_nx_helper (unsigned int, gt_pointer_operator, void *) { } static void pch_nx_helper (bool, gt_pointer_operator, void *) { } template static void pch_nx_helper (T *&x, gt_pointer_operator op, void *cookie) { op (&x, cookie); } }; public: explicit hash_map (size_t n = default_hash_map_size, bool ggc = false, bool sanitize_eq_and_hash = true, bool gather_mem_stats = GATHER_STATISTICS CXX_MEM_STAT_INFO) : m_table (n, ggc, sanitize_eq_and_hash, gather_mem_stats, HASH_MAP_ORIGIN PASS_MEM_STAT) { } explicit hash_map (const hash_map &h, bool ggc = false, bool sanitize_eq_and_hash = true, bool gather_mem_stats = GATHER_STATISTICS CXX_MEM_STAT_INFO) : m_table (h.m_table, ggc, sanitize_eq_and_hash, gather_mem_stats, HASH_MAP_ORIGIN PASS_MEM_STAT) {} /* Create a hash_map in ggc memory. */ static hash_map *create_ggc (size_t size = default_hash_map_size, bool gather_mem_stats = GATHER_STATISTICS CXX_MEM_STAT_INFO) { hash_map *map = ggc_alloc (); new (map) hash_map (size, true, true, gather_mem_stats PASS_MEM_STAT); return map; } /* If key k isn't already in the map add key k with value v to the map, and return false. Otherwise set the value of the entry for key k to be v and return true. */ bool put (const Key &k, const Value &v) { hash_entry *e = m_table.find_slot_with_hash (k, Traits::hash (k), INSERT); bool ins = hash_entry::is_empty (*e); if (ins) { e->m_key = k; new ((void *) &e->m_value) Value (v); } else e->m_value = v; return !ins; } /* if the passed in key is in the map return its value otherwise NULL. */ Value *get (const Key &k) { hash_entry &e = m_table.find_with_hash (k, Traits::hash (k)); return Traits::is_empty (e) ? NULL : &e.m_value; } /* Return a reference to the value for the passed in key, creating the entry if it doesn't already exist. If existed is not NULL then it is set to false if the key was not previously in the map, and true otherwise. */ Value &get_or_insert (const Key &k, bool *existed = NULL) { hash_entry *e = m_table.find_slot_with_hash (k, Traits::hash (k), INSERT); bool ins = Traits::is_empty (*e); if (ins) { e->m_key = k; new ((void *)&e->m_value) Value (); } if (existed != NULL) *existed = !ins; return e->m_value; } void remove (const Key &k) { m_table.remove_elt_with_hash (k, Traits::hash (k)); } /* Call the call back on each pair of key and value with the passed in arg. */ template void traverse (Arg a) const { for (typename hash_table::iterator iter = m_table.begin (); iter != m_table.end (); ++iter) f ((*iter).m_key, (*iter).m_value, a); } template void traverse (Arg a) const { for (typename hash_table::iterator iter = m_table.begin (); iter != m_table.end (); ++iter) if (!f ((*iter).m_key, &(*iter).m_value, a)) break; } size_t elements () const { return m_table.elements (); } void empty () { m_table.empty(); } /* Return true when there are no elements in this hash map. */ bool is_empty () const { return m_table.is_empty (); } class iterator { public: explicit iterator (const typename hash_table::iterator &iter) : m_iter (iter) {} iterator &operator++ () { ++m_iter; return *this; } /* Can't use std::pair here, because GCC before 4.3 don't handle std::pair where template parameters are references well. See PR86739. */ class reference_pair { public: const Key &first; Value &second; reference_pair (const Key &key, Value &value) : first (key), second (value) {} template operator std::pair () const { return std::pair (first, second); } }; reference_pair operator* () { hash_entry &e = *m_iter; return reference_pair (e.m_key, e.m_value); } bool operator != (const iterator &other) const { return m_iter != other.m_iter; } private: typename hash_table::iterator m_iter; }; /* Standard iterator retrieval methods. */ iterator begin () const { return iterator (m_table.begin ()); } iterator end () const { return iterator (m_table.end ()); } private: template friend void gt_ggc_mx (hash_map *); template friend void gt_pch_nx (hash_map *); template friend void gt_pch_nx (hash_map *, gt_pointer_operator, void *); template friend void gt_cleare_cache (hash_map *); hash_table m_table; }; /* ggc marking routines. */ template static inline void gt_ggc_mx (hash_map *h) { gt_ggc_mx (&h->m_table); } template static inline void gt_pch_nx (hash_map *h) { gt_pch_nx (&h->m_table); } template static inline void gt_cleare_cache (hash_map *h) { if (h) gt_cleare_cache (&h->m_table); } template static inline void gt_pch_nx (hash_map *h, gt_pointer_operator op, void *cookie) { op (&h->m_table.m_entries, cookie); } enum hm_alloc { hm_heap = false, hm_ggc = true }; template inline hash_map * hash_map_maybe_create (hash_map *&h, size_t size = default_hash_map_size) { if (!h) { if (ggc) h = hash_map::create_ggc (size); else h = new hash_map (size); } return h; } /* Like h->get, but handles null h. */ template inline V* hash_map_safe_get (hash_map *h, const K& k) { return h ? h->get (k) : NULL; } /* Like h->get, but handles null h. */ template inline V& hash_map_safe_get_or_insert (hash_map *&h, const K& k, bool *e = NULL, size_t size = default_hash_map_size) { return hash_map_maybe_create (h, size)->get_or_insert (k, e); } /* Like h->put, but handles null h. */ template inline bool hash_map_safe_put (hash_map *&h, const K& k, const V& v, size_t size = default_hash_map_size) { return hash_map_maybe_create (h, size)->put (k, v); } #endif