#ifndef hash_map_hh_INCLUDED #define hash_map_hh_INCLUDED #include "hash.hh" #include "memory.hh" #include "vector.hh" namespace Kakoune { template struct HashIndex { struct Entry { size_t hash; int index; }; void resize(size_t new_size) { kak_assert(new_size > m_entries.size()); Vector old_entries = std::move(m_entries); m_entries.resize(new_size, {0,-1}); for (auto& entry : old_entries) { if (entry.index >= 0) add(entry.hash, entry.index); } } void reserve(size_t count) { constexpr float max_fill_rate = 0.5f; const size_t min_size = (size_t)(count / max_fill_rate) + 1; size_t new_size = m_entries.empty() ? 4 : m_entries.size(); while (new_size < min_size) new_size *= 2; if (new_size > m_entries.size()) resize(new_size); } void add(size_t hash, int index) { Entry entry{hash, index}; while (true) { auto target_slot = compute_slot(entry.hash); for (auto slot = target_slot; slot < m_entries.size(); ++slot) { if (m_entries[slot].index == -1) { m_entries[slot] = entry; return; } // Robin hood hashing auto candidate_slot = compute_slot(m_entries[slot].hash); if (target_slot < candidate_slot) { std::swap(m_entries[slot], entry); target_slot = candidate_slot; } } // no free entries found, resize, try again resize(m_entries.size() * 2); } } void remove(size_t hash, int index) { for (auto slot = compute_slot(hash); slot < m_entries.size(); ++slot) { kak_assert(m_entries[slot].index >= 0); if (m_entries[slot].index == index) { m_entries[slot].index = -1; // Recompact following entries for (auto next = slot+1; next < m_entries.size(); ++next) { if (m_entries[next].index == -1 or compute_slot(m_entries[next].hash) == next) break; kak_assert(compute_slot(m_entries[next].hash) < next); std::swap(m_entries[next-1], m_entries[next]); } break; } } } void ordered_fix_entries(int index) { for (auto& entry : m_entries) { if (entry.index >= index) --entry.index; } } void unordered_fix_entries(size_t hash, int old_index, int new_index) { for (auto slot = compute_slot(hash); slot < m_entries.size(); ++slot) { if (m_entries[slot].index == old_index) { m_entries[slot].index = new_index; return; } } kak_assert(false); // entry not found ?! } const Entry& operator[](size_t index) const { return m_entries[index]; } size_t size() const { return m_entries.size(); } size_t compute_slot(size_t hash) const { // We assume entries.size() is power of 2 return hash & (m_entries.size()-1); } void clear() { m_entries.clear(); } private: Vector m_entries; }; template struct HashItem { Key key; Value value; }; template struct HashMap { using Item = HashItem; HashMap() = default; HashMap(std::initializer_list val) : m_items{val} { m_index.reserve(val.size()); for (int i = 0; i < m_items.size(); ++i) m_index.add(hash_value(m_items[i].key), i); } Value& insert(Item item) { m_index.reserve(m_items.size()+1); m_index.add(hash_value(item.key), (int)m_items.size()); m_items.push_back(std::move(item)); return m_items.back().value; } template using EnableIfHashCompatible = typename std::enable_if< HashCompatible::type>::value >::type; template> int find_index(const KeyType& key, size_t hash) const { for (auto slot = m_index.compute_slot(hash); slot < m_index.size(); ++slot) { auto& entry = m_index[slot]; if (entry.index == -1) return -1; if (entry.hash == hash and m_items[entry.index].key == key) return entry.index; } return -1; } template> int find_index(const KeyType& key) const { return find_index(key, hash_value(key)); } template> bool contains(const KeyType& key) const { return find_index(key) >= 0; } template> Value& operator[](KeyType&& key) { const auto hash = hash_value(key); auto index = find_index(key, hash); if (index >= 0) return m_items[index].value; m_index.reserve(m_items.size()+1); m_index.add(hash, (int)m_items.size()); m_items.push_back({Key{std::forward(key)}, {}}); return m_items.back().value; } template> void remove(const KeyType& key) { const auto hash = hash_value(key); int index = find_index(key, hash); if (index >= 0) { m_items.erase(m_items.begin() + index); m_index.remove(hash, index); m_index.ordered_fix_entries(index); } } template> void unordered_remove(const KeyType& key) { const auto hash = hash_value(key); int index = find_index(key, hash); if (index >= 0) { std::swap(m_items[index], m_items.back()); m_items.pop_back(); m_index.remove(hash, index); if (index != m_items.size()) m_index.unordered_fix_entries(hash_value(m_items[index].key), m_items.size(), index); } } void erase(const Key& key) { unordered_remove(key); } template> void remove_all(const KeyType& key) { const auto hash = hash_value(key); for (int index = find_index(key, hash); index >= 0; index = find_index(key, hash)) { m_items.erase(m_items.begin() + index); m_index.remove(hash, index); m_index.ordered_fix_entries(index); } } using iterator = typename Vector::iterator; iterator begin() { return m_items.begin(); } iterator end() { return m_items.end(); } using const_iterator = typename Vector::const_iterator; const_iterator begin() const { return m_items.begin(); } const_iterator end() const { return m_items.end(); } template> iterator find(const KeyType& key) { auto index = find_index(key); return index >= 0 ? begin() + index : end(); } template> const_iterator find(const KeyType& key) const { return const_cast(this)->find(key); } void clear() { m_items.clear(); m_index.clear(); } size_t size() const { return m_items.size(); } bool empty() const { return m_items.empty(); } void reserve(size_t size) { m_items.reserve(size); m_index.reserve(size); } // Equality is taking the order of insertion into account template bool operator==(const HashMap& other) const { return size() == other.size() and std::equal(begin(), end(), other.begin(), [](const Item& lhs, const Item& rhs) { return lhs.key == rhs.key and lhs.value == rhs.value; }); } template bool operator!=(const HashMap& other) const { return not (*this == other); } private: Vector m_items; HashIndex m_index; }; void profile_hash_maps(); } #endif // hash_map_hh_INCLUDED