// Copyright 2013 The Rust Project Developers. See the COPYRIGHT // file at the top-level directory of this distribution and at // http://rust-lang.org/COPYRIGHT. // // Licensed under the Apache License, Version 2.0 or the MIT license // , at your // option. This file may not be copied, modified, or distributed // except according to those terms. //! A cache that holds a limited number of key-value pairs. When the //! capacity of the cache is exceeded, the least-recently-used //! (where "used" means a look-up or putting the pair into the cache) //! pair is automatically removed. //! //! # Example //! //! ```rust //! use std::collections::LruCache; //! //! let mut cache: LruCache = LruCache::new(2); //! cache.put(1, 10); //! cache.put(2, 20); //! cache.put(3, 30); //! assert!(cache.get(&1).is_none()); //! assert_eq!(*cache.get(&2).unwrap(), 20); //! assert_eq!(*cache.get(&3).unwrap(), 30); //! //! cache.put(2, 22); //! assert_eq!(*cache.get(&2).unwrap(), 22); //! //! cache.put(6, 60); //! assert!(cache.get(&3).is_none()); //! //! cache.change_capacity(1); //! assert!(cache.get(&2).is_none()); //! ``` use cmp::{PartialEq, Eq}; use collections::{HashMap, Collection, Mutable, MutableMap}; use fmt; use hash::Hash; use iter::{range, Iterator}; use mem; use ops::Drop; use option::{Some, None, Option}; use owned::Box; use ptr; use result::{Ok, Err}; struct KeyRef { k: *const K } struct LruEntry { next: *mut LruEntry, prev: *mut LruEntry, key: K, value: V, } /// An LRU Cache. pub struct LruCache { map: HashMap, Box>>, max_size: uint, head: *mut LruEntry, } impl> Hash for KeyRef { fn hash(&self, state: &mut S) { unsafe { (*self.k).hash(state) } } } impl PartialEq for KeyRef { fn eq(&self, other: &KeyRef) -> bool { unsafe{ (*self.k).eq(&*other.k) } } } impl Eq for KeyRef {} impl LruEntry { fn new(k: K, v: V) -> LruEntry { LruEntry { key: k, value: v, next: ptr::mut_null(), prev: ptr::mut_null(), } } } impl LruCache { /// Create an LRU Cache that holds at most `capacity` items. pub fn new(capacity: uint) -> LruCache { let cache = LruCache { map: HashMap::new(), max_size: capacity, head: unsafe{ mem::transmute(box mem::uninitialized::>()) }, }; unsafe { (*cache.head).next = cache.head; (*cache.head).prev = cache.head; } return cache; } /// Put a key-value pair into cache. pub fn put(&mut self, k: K, v: V) { let (node_ptr, node_opt) = match self.map.find_mut(&KeyRef{k: &k}) { Some(node) => { node.value = v; let node_ptr: *mut LruEntry = &mut **node; (node_ptr, None) } None => { let mut node = box LruEntry::new(k, v); let node_ptr: *mut LruEntry = &mut *node; (node_ptr, Some(node)) } }; match node_opt { None => { // Existing node, just update LRU position self.detach(node_ptr); self.attach(node_ptr); } Some(node) => { let keyref = unsafe { &(*node_ptr).key }; self.map.swap(KeyRef{k: keyref}, node); self.attach(node_ptr); if self.len() > self.capacity() { self.remove_lru(); } } } } /// Return a value corresponding to the key in the cache. pub fn get<'a>(&'a mut self, k: &K) -> Option<&'a V> { let (value, node_ptr_opt) = match self.map.find_mut(&KeyRef{k: k}) { None => (None, None), Some(node) => { let node_ptr: *mut LruEntry = &mut **node; (Some(unsafe { &(*node_ptr).value }), Some(node_ptr)) } }; match node_ptr_opt { None => (), Some(node_ptr) => { self.detach(node_ptr); self.attach(node_ptr); } } return value; } /// Remove and return a value corresponding to the key from the cache. pub fn pop(&mut self, k: &K) -> Option { match self.map.pop(&KeyRef{k: k}) { None => None, Some(lru_entry) => Some(lru_entry.value) } } /// Return the maximum number of key-value pairs the cache can hold. pub fn capacity(&self) -> uint { self.max_size } /// Change the number of key-value pairs the cache can hold. Remove /// least-recently-used key-value pairs if necessary. pub fn change_capacity(&mut self, capacity: uint) { for _ in range(capacity, self.len()) { self.remove_lru(); } self.max_size = capacity; } #[inline] fn remove_lru(&mut self) { if self.len() > 0 { let lru = unsafe { (*self.head).prev }; self.detach(lru); self.map.pop(&KeyRef{k: unsafe { &(*lru).key }}); } } #[inline] fn detach(&mut self, node: *mut LruEntry) { unsafe { (*(*node).prev).next = (*node).next; (*(*node).next).prev = (*node).prev; } } #[inline] fn attach(&mut self, node: *mut LruEntry) { unsafe { (*node).next = (*self.head).next; (*node).prev = self.head; (*self.head).next = node; (*(*node).next).prev = node; } } } impl fmt::Show for LruCache { /// Return a string that lists the key-value pairs from most-recently /// used to least-recently used. fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { try!(write!(f, "{{")); let mut cur = self.head; for i in range(0, self.len()) { if i > 0 { try!(write!(f, ", ")) } unsafe { cur = (*cur).next; try!(write!(f, "{}", (*cur).key)); } try!(write!(f, ": ")); unsafe { try!(write!(f, "{}", (*cur).value)); } } write!(f, r"}}") } } impl Collection for LruCache { /// Return the number of key-value pairs in the cache. fn len(&self) -> uint { self.map.len() } } impl Mutable for LruCache { /// Clear the cache of all key-value pairs. fn clear(&mut self) { self.map.clear(); } } #[unsafe_destructor] impl Drop for LruCache { fn drop(&mut self) { unsafe { let node: Box> = mem::transmute(self.head); // Prevent compiler from trying to drop the un-initialized field in the sigil node. let box LruEntry { key: k, value: v, .. } = node; mem::forget(k); mem::forget(v); } } } #[cfg(test)] mod tests { use prelude::*; use super::LruCache; fn assert_opt_eq(opt: Option<&V>, v: V) { assert!(opt.is_some()); assert!(opt.unwrap() == &v); } #[test] fn test_put_and_get() { let mut cache: LruCache = LruCache::new(2); cache.put(1, 10); cache.put(2, 20); assert_opt_eq(cache.get(&1), 10); assert_opt_eq(cache.get(&2), 20); assert_eq!(cache.len(), 2); } #[test] fn test_put_update() { let mut cache: LruCache> = LruCache::new(1); cache.put("1".to_string(), vec![10, 10]); cache.put("1".to_string(), vec![10, 19]); assert_opt_eq(cache.get(&"1".to_string()), vec![10, 19]); assert_eq!(cache.len(), 1); } #[test] fn test_expire_lru() { let mut cache: LruCache = LruCache::new(2); cache.put("foo1".to_string(), "bar1".to_string()); cache.put("foo2".to_string(), "bar2".to_string()); cache.put("foo3".to_string(), "bar3".to_string()); assert!(cache.get(&"foo1".to_string()).is_none()); cache.put("foo2".to_string(), "bar2update".to_string()); cache.put("foo4".to_string(), "bar4".to_string()); assert!(cache.get(&"foo3".to_string()).is_none()); } #[test] fn test_pop() { let mut cache: LruCache = LruCache::new(2); cache.put(1, 10); cache.put(2, 20); assert_eq!(cache.len(), 2); let opt1 = cache.pop(&1); assert!(opt1.is_some()); assert_eq!(opt1.unwrap(), 10); assert!(cache.get(&1).is_none()); assert_eq!(cache.len(), 1); } #[test] fn test_change_capacity() { let mut cache: LruCache = LruCache::new(2); assert_eq!(cache.capacity(), 2); cache.put(1, 10); cache.put(2, 20); cache.change_capacity(1); assert!(cache.get(&1).is_none()); assert_eq!(cache.capacity(), 1); } #[test] fn test_to_string() { let mut cache: LruCache = LruCache::new(3); cache.put(1, 10); cache.put(2, 20); cache.put(3, 30); assert_eq!(cache.to_string(), "{3: 30, 2: 20, 1: 10}".to_string()); cache.put(2, 22); assert_eq!(cache.to_string(), "{2: 22, 3: 30, 1: 10}".to_string()); cache.put(6, 60); assert_eq!(cache.to_string(), "{6: 60, 2: 22, 3: 30}".to_string()); cache.get(&3); assert_eq!(cache.to_string(), "{3: 30, 6: 60, 2: 22}".to_string()); cache.change_capacity(2); assert_eq!(cache.to_string(), "{3: 30, 6: 60}".to_string()); } #[test] fn test_clear() { let mut cache: LruCache = LruCache::new(2); cache.put(1, 10); cache.put(2, 20); cache.clear(); assert!(cache.get(&1).is_none()); assert!(cache.get(&2).is_none()); assert_eq!(cache.to_string(), "{}".to_string()); } }