#ifndef HASHMAP_H #define HASHMAP_H #include #include "utils/Array.h" template class HashMap final { static constexpr int getCapacity() { int i = 1; while(i < N_MIN) { i <<= 1; } return i; } static constexpr int CAPACITY = getCapacity(); static constexpr int MASK = CAPACITY - 1; Array used; char keys[sizeof (K) * CAPACITY]; char values[sizeof (V) * CAPACITY]; const K& getKey(int index) const { return reinterpret_cast (keys)[index]; } V& getValue(int index) { return reinterpret_cast (values)[index]; } const V& getValue(int index) const { return reinterpret_cast (values)[index]; } enum SearchResult { FREE_INDEX_FOUND, KEY_FOUND, NOTHING_FOUND }; struct Search { int index; SearchResult result; Search(int index, SearchResult result) : index(index), result(result) { } }; Search searchIndex(const K& key) const { int base = hash(key); for(int i = 0; i < CAPACITY; i++) { int h = (base + i) & MASK; if(!used[h]) { return Search(h, FREE_INDEX_FOUND); } else if(getKey(h) == key) { return Search(h, KEY_FOUND); } } return Search(-1, NOTHING_FOUND); } void copy(const HashMap& other) { for(int i = 0; i < other.CAPACITY; i++) { if(other.used[i]) { used[i] = true; new (reinterpret_cast (keys) + i) K(other.getKey(i)); new (reinterpret_cast (values) + i) V(other.getValue(i)); } } } void move(HashMap& other) { for(int i = 0; i < other.CAPACITY; i++) { if(other.used[i]) { used[i] = true; new (reinterpret_cast (keys) + i) K(std::move(other.getKey(i))); new (reinterpret_cast (values) + i) V(std::move(other.getValue(i))); } } other.clear(); } public: HashMap() : used(false) { } ~HashMap() { clear(); } HashMap(const HashMap& other) : used(false) { copy(other); } HashMap& operator=(const HashMap& other) { clear(); copy(other); return *this; } HashMap(HashMap&& other) : used(false) { move(other); } HashMap& operator=(HashMap&& other) { clear(); move(other); return *this; } template bool tryEmplace(const K& key, Args&&... args) { Search s = searchIndex(key); if(s.result == FREE_INDEX_FOUND) { used[s.index] = true; new (reinterpret_cast (keys) + s.index) K(key); new (reinterpret_cast (values) + s.index) V(args...); return false; } return true; } void add(const K& key, const V& value) { Search s = searchIndex(key); if(s.result == KEY_FOUND) { getValue(s.index) = value; } else if(s.result == FREE_INDEX_FOUND) { used[s.index] = true; new (reinterpret_cast (keys) + s.index) K(key); new (reinterpret_cast (values) + s.index) V(value); } } void add(const K& key, const V&& value) { Search s = searchIndex(key); if(s.result == KEY_FOUND) { getValue(s.index) = std::move(value); } else if(s.result == FREE_INDEX_FOUND) { used[s.index] = true; new (reinterpret_cast (keys) + s.index) K(key); new (reinterpret_cast (values) + s.index) V(std::move(value)); } } const V& search(const K& key, const V& notFound) const { Search s = searchIndex(key); return s.result == KEY_FOUND ? getValue(s.index) : notFound; } V& search(const K& key, V& notFound) { Search s = searchIndex(key); return s.result == KEY_FOUND ? getValue(s.index) : notFound; } bool contains(const K& key) const { return searchIndex(key).result == KEY_FOUND; } void clear() { K* k = reinterpret_cast (keys); V* v = reinterpret_cast (values); for(int i = 0; i < CAPACITY; i++) { if(used[i]) { k[i].~K(); v[i].~V(); } } used.fill(false); } private: template static int hash(const H& key) { return key.hashCode(); } static int hash(int key) { return key; } }; #endif