package maps import ( "fmt" "reflect" "codeberg.org/gruf/go-byteutil" "codeberg.org/gruf/go-kv" ) // ordered provides a common ordered hashmap base, storing order in a doubly-linked list. type ordered[K comparable, V any] struct { hmap map[K]*elem[K, V] list list[K, V] pool []*elem[K, V] rnly bool } // write_check panics if map is not in a safe-state to write to. func (m ordered[K, V]) write_check() { if m.rnly { panic("map write during read loop") } } // Has returns whether key exists in map. func (m *ordered[K, V]) Has(key K) bool { _, ok := m.hmap[key] return ok } // Delete will delete given key from map, returns false if not found. func (m *ordered[K, V]) Delete(key K) bool { // Ensure safe m.write_check() // Look for existing elem elem, ok := m.hmap[key] if !ok { return false } // Drop from list m.list.Unlink(elem) // Delete from map delete(m.hmap, key) // Return to pool m.free(elem) return true } // Range passes given function over the requested range of the map. func (m *ordered[K, V]) Range(start, length int, fn func(int, K, V)) { // Disallow writes m.rnly = true defer func() { m.rnly = false }() // Nil check _ = fn switch end := start + length; { // No loop to iterate case length == 0: if start < 0 || (m.list.len > 0 && start >= m.list.len) { panic("index out of bounds") } // Step backwards case length < 0: // Check loop indices are within map bounds if end < -1 || start >= m.list.len || m.list.len == 0 { panic("index out of bounds") } // Get starting index elem elem := m.list.Index(start) for i := start; i > end; i-- { fn(i, elem.K, elem.V) elem = elem.prev } // Step forwards case length > 0: // Check loop indices are within map bounds if start < 0 || end > m.list.len || m.list.len == 0 { panic("index out of bounds") } // Get starting index elem elem := m.list.Index(start) for i := start; i < end; i++ { fn(i, elem.K, elem.V) elem = elem.next } } } // RangeIf passes given function over the requested range of the map. Returns early on 'fn' -> false. func (m *ordered[K, V]) RangeIf(start, length int, fn func(int, K, V) bool) { // Disallow writes m.rnly = true defer func() { m.rnly = false }() // Nil check _ = fn switch end := start + length; { // No loop to iterate case length == 0: if start < 0 || (m.list.len > 0 && start >= m.list.len) { panic("index out of bounds") } // Step backwards case length < 0: // Check loop indices are within map bounds if end < -1 || start >= m.list.len || m.list.len == 0 { panic("index out of bounds") } // Get starting index elem elem := m.list.Index(start) for i := start; i > end; i-- { if !fn(i, elem.K, elem.V) { return } elem = elem.prev } // Step forwards case length > 0: // Check loop indices are within map bounds if start < 0 || end > m.list.len || m.list.len == 0 { panic("index out of bounds") } // Get starting index elem elem := m.list.Index(start) for i := start; i < end; i++ { if !fn(i, elem.K, elem.V) { return } elem = elem.next } } } // Truncate will truncate the map from the back by given amount, passing dropped elements to given function. func (m *ordered[K, V]) Truncate(sz int, fn func(K, V)) { // Check size withing bounds if sz > m.list.len { panic("index out of bounds") } if fn == nil { // move nil check out of loop fn = func(K, V) {} } // Disallow writes m.rnly = true defer func() { m.rnly = false }() for i := 0; i < sz; i++ { // Pop current tail elem := m.list.tail m.list.Unlink(elem) // Delete from map delete(m.hmap, elem.K) // Pass dropped to func fn(elem.K, elem.V) // Release to pool m.free(elem) } } // Len returns the current length of the map. func (m *ordered[K, V]) Len() int { return m.list.len } // format implements fmt.Formatter, allowing performant string formatting of map. func (m *ordered[K, V]) format(rtype reflect.Type, state fmt.State, verb rune) { var ( kvbuf byteutil.Buffer field kv.Field vbose bool ) switch { // Only handle 'v' verb case verb != 'v': panic("invalid verb '" + string(verb) + "' for map") // Prefix with type when verbose case state.Flag('#'): state.Write([]byte(rtype.String())) } // Disallow writes m.rnly = true defer func() { m.rnly = false }() // Write map opening brace state.Write([]byte{'{'}) if m.list.len > 0 { // Preallocate buffer kvbuf.Guarantee(64) // Start at index 0 elem := m.list.head for i := 0; i < m.list.len-1; i++ { // Append formatted key-val pair to state field.K = fmt.Sprint(elem.K) field.V = elem.V field.AppendFormat(&kvbuf, vbose) _, _ = state.Write(kvbuf.B) kvbuf.Reset() // Prepare buffer with comma separator kvbuf.B = append(kvbuf.B, `, `...) // Jump to next in list elem = elem.next } // Append formatted key-val pair to state field.K = fmt.Sprint(elem.K) field.V = elem.V field.AppendFormat(&kvbuf, vbose) _, _ = state.Write(kvbuf.B) } // Write map closing brace state.Write([]byte{'}'}) } // Std returns a clone of map's data in the standard library equivalent map type. func (m *ordered[K, V]) Std() map[K]V { std := make(map[K]V, m.list.len) for _, elem := range m.hmap { std[elem.K] = elem.V } return std } // alloc will acquire list element from pool, or allocate new. func (m *ordered[K, V]) alloc() *elem[K, V] { if len(m.pool) == 0 { return &elem[K, V]{} } idx := len(m.pool) - 1 elem := m.pool[idx] m.pool = m.pool[:idx] return elem } // free will reset elem fields and place back in pool. func (m *ordered[K, V]) free(elem *elem[K, V]) { var ( zk K zv V ) elem.K = zk elem.V = zv elem.next = nil elem.prev = nil m.pool = append(m.pool, elem) }