// 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. //! An ordered map and set for integer keys implemented as a radix trie use prelude::*; use iterator::IteratorUtil; use uint; use util::{swap, replace}; // FIXME: #5244: need to manually update the TrieNode constructor static SHIFT: uint = 4; static SIZE: uint = 1 << SHIFT; static MASK: uint = SIZE - 1; enum Child { Internal(~TrieNode), External(uint, T), Nothing } #[allow(missing_doc)] pub struct TrieMap { priv root: TrieNode, priv length: uint } impl Container for TrieMap { /// Return the number of elements in the map #[inline] fn len(&self) -> uint { self.length } /// Return true if the map contains no elements #[inline] fn is_empty(&self) -> bool { self.len() == 0 } } impl Mutable for TrieMap { /// Clear the map, removing all values. #[inline] fn clear(&mut self) { self.root = TrieNode::new(); self.length = 0; } } impl Map for TrieMap { /// Return true if the map contains a value for the specified key #[inline] fn contains_key(&self, key: &uint) -> bool { self.find(key).is_some() } /// Return a reference to the value corresponding to the key #[inline] fn find<'a>(&'a self, key: &uint) -> Option<&'a T> { let mut node: &'a TrieNode = &self.root; let mut idx = 0; loop { match node.children[chunk(*key, idx)] { Internal(ref x) => node = &**x, External(stored, ref value) => { if stored == *key { return Some(value) } else { return None } } Nothing => return None } idx += 1; } } /// Return a mutable reference to the value corresponding to the key #[inline] fn find_mut<'a>(&'a mut self, key: &uint) -> Option<&'a mut T> { find_mut(&mut self.root.children[chunk(*key, 0)], *key, 1) } /// Insert a key-value pair into the map. An existing value for a /// key is replaced by the new value. Return true if the key did /// not already exist in the map. #[inline] fn insert(&mut self, key: uint, value: T) -> bool { self.swap(key, value).is_none() } /// Remove a key-value pair from the map. Return true if the key /// was present in the map, otherwise false. #[inline] fn remove(&mut self, key: &uint) -> bool { self.pop(key).is_some() } /// Insert a key-value pair from the map. If the key already had a value /// present in the map, that value is returned. Otherwise None is returned. fn swap(&mut self, key: uint, value: T) -> Option { let ret = insert(&mut self.root.count, &mut self.root.children[chunk(key, 0)], key, value, 1); if ret.is_none() { self.length += 1 } ret } /// Removes a key from the map, returning the value at the key if the key /// was previously in the map. fn pop(&mut self, key: &uint) -> Option { let ret = remove(&mut self.root.count, &mut self.root.children[chunk(*key, 0)], *key, 1); if ret.is_some() { self.length -= 1 } ret } } impl TrieMap { /// Create an empty TrieMap #[inline] pub fn new() -> TrieMap { TrieMap{root: TrieNode::new(), length: 0} } /// Visit all key-value pairs in reverse order #[inline] pub fn each_reverse<'a>(&'a self, f: &fn(&uint, &'a T) -> bool) -> bool { self.root.each_reverse(f) } /// Visit all key-value pairs in order #[inline] pub fn each<'a>(&'a self, f: &fn(&uint, &'a T) -> bool) -> bool { self.root.each(f) } /// Visit all keys in order #[inline] pub fn each_key(&self, f: &fn(&uint) -> bool) -> bool { self.each(|k, _| f(k)) } /// Visit all values in order #[inline] pub fn each_value<'a>(&'a self, f: &fn(&'a T) -> bool) -> bool { self.each(|_, v| f(v)) } /// Iterate over the map and mutate the contained values #[inline] pub fn mutate_values(&mut self, f: &fn(&uint, &mut T) -> bool) -> bool { self.root.mutate_values(f) } /// Visit all keys in reverse order #[inline] pub fn each_key_reverse(&self, f: &fn(&uint) -> bool) -> bool { self.each_reverse(|k, _| f(k)) } /// Visit all values in reverse order #[inline] pub fn each_value_reverse(&self, f: &fn(&T) -> bool) -> bool { self.each_reverse(|_, v| f(v)) } } #[allow(missing_doc)] pub struct TrieSet { priv map: TrieMap<()> } impl Container for TrieSet { /// Return the number of elements in the set #[inline] fn len(&self) -> uint { self.map.len() } /// Return true if the set contains no elements #[inline] fn is_empty(&self) -> bool { self.map.is_empty() } } impl Mutable for TrieSet { /// Clear the set, removing all values. #[inline] fn clear(&mut self) { self.map.clear() } } impl TrieSet { /// Create an empty TrieSet #[inline] pub fn new() -> TrieSet { TrieSet{map: TrieMap::new()} } /// Return true if the set contains a value #[inline] pub fn contains(&self, value: &uint) -> bool { self.map.contains_key(value) } /// Add a value to the set. Return true if the value was not already /// present in the set. #[inline] pub fn insert(&mut self, value: uint) -> bool { self.map.insert(value, ()) } /// Remove a value from the set. Return true if the value was /// present in the set. #[inline] pub fn remove(&mut self, value: &uint) -> bool { self.map.remove(value) } /// Visit all values in order #[inline] pub fn each(&self, f: &fn(&uint) -> bool) -> bool { self.map.each_key(f) } /// Visit all values in reverse order #[inline] pub fn each_reverse(&self, f: &fn(&uint) -> bool) -> bool { self.map.each_key_reverse(f) } } struct TrieNode { count: uint, children: [Child, ..SIZE] } impl TrieNode { #[inline] fn new() -> TrieNode { // FIXME: #5244: [Nothing, ..SIZE] should be possible without Copy TrieNode{count: 0, children: [Nothing, Nothing, Nothing, Nothing, Nothing, Nothing, Nothing, Nothing, Nothing, Nothing, Nothing, Nothing, Nothing, Nothing, Nothing, Nothing]} } } impl TrieNode { fn each<'a>(&'a self, f: &fn(&uint, &'a T) -> bool) -> bool { for uint::range(0, self.children.len()) |idx| { match self.children[idx] { Internal(ref x) => if !x.each(|i,t| f(i,t)) { return false }, External(k, ref v) => if !f(&k, v) { return false }, Nothing => () } } true } fn each_reverse<'a>(&'a self, f: &fn(&uint, &'a T) -> bool) -> bool { for uint::range_rev(self.children.len(), 0) |idx| { match self.children[idx - 1] { Internal(ref x) => if !x.each_reverse(|i,t| f(i,t)) { return false }, External(k, ref v) => if !f(&k, v) { return false }, Nothing => () } } true } fn mutate_values<'a>(&'a mut self, f: &fn(&uint, &mut T) -> bool) -> bool { for self.children.mut_iter().advance |child| { match *child { Internal(ref mut x) => if !x.mutate_values(|i,t| f(i,t)) { return false }, External(k, ref mut v) => if !f(&k, v) { return false }, Nothing => () } } true } } // if this was done via a trait, the key could be generic #[inline] fn chunk(n: uint, idx: uint) -> uint { let sh = uint::bits - (SHIFT * (idx + 1)); (n >> sh) & MASK } fn find_mut<'r, T>(child: &'r mut Child, key: uint, idx: uint) -> Option<&'r mut T> { match *child { External(_, ref mut value) => Some(value), Internal(ref mut x) => find_mut(&mut x.children[chunk(key, idx)], key, idx + 1), Nothing => None } } fn insert(count: &mut uint, child: &mut Child, key: uint, value: T, idx: uint) -> Option { let mut tmp = Nothing; let ret; swap(&mut tmp, child); *child = match tmp { External(stored_key, stored_value) => { if stored_key == key { ret = Some(stored_value); External(stored_key, value) } else { // conflict - split the node let mut new = ~TrieNode::new(); insert(&mut new.count, &mut new.children[chunk(stored_key, idx)], stored_key, stored_value, idx + 1); ret = insert(&mut new.count, &mut new.children[chunk(key, idx)], key, value, idx + 1); Internal(new) } } Internal(x) => { let mut x = x; ret = insert(&mut x.count, &mut x.children[chunk(key, idx)], key, value, idx + 1); Internal(x) } Nothing => { *count += 1; ret = None; External(key, value) } }; return ret; } fn remove(count: &mut uint, child: &mut Child, key: uint, idx: uint) -> Option { let (ret, this) = match *child { External(stored, _) if stored == key => { match replace(child, Nothing) { External(_, value) => (Some(value), true), _ => fail!() } } External(*) => (None, false), Internal(ref mut x) => { let ret = remove(&mut x.count, &mut x.children[chunk(key, idx)], key, idx + 1); (ret, x.count == 0) } Nothing => (None, false) }; if this { *child = Nothing; *count -= 1; } return ret; } #[cfg(test)] pub fn check_integrity(trie: &TrieNode) { assert!(trie.count != 0); let mut sum = 0; for trie.children.iter().advance |x| { match *x { Nothing => (), Internal(ref y) => { check_integrity(&**y); sum += 1 } External(_, _) => { sum += 1 } } } assert_eq!(sum, trie.count); } #[cfg(test)] mod tests { use super::*; use core::option::{Some, None}; use uint; #[test] fn test_find_mut() { let mut m = TrieMap::new(); assert!(m.insert(1, 12)); assert!(m.insert(2, 8)); assert!(m.insert(5, 14)); let new = 100; match m.find_mut(&5) { None => fail!(), Some(x) => *x = new } assert_eq!(m.find(&5), Some(&new)); } #[test] fn test_step() { let mut trie = TrieMap::new(); let n = 300; for uint::range_step(1, n, 2) |x| { assert!(trie.insert(x, x + 1)); assert!(trie.contains_key(&x)); check_integrity(&trie.root); } for uint::range_step(0, n, 2) |x| { assert!(!trie.contains_key(&x)); assert!(trie.insert(x, x + 1)); check_integrity(&trie.root); } for uint::range(0, n) |x| { assert!(trie.contains_key(&x)); assert!(!trie.insert(x, x + 1)); check_integrity(&trie.root); } for uint::range_step(1, n, 2) |x| { assert!(trie.remove(&x)); assert!(!trie.contains_key(&x)); check_integrity(&trie.root); } for uint::range_step(0, n, 2) |x| { assert!(trie.contains_key(&x)); assert!(!trie.insert(x, x + 1)); check_integrity(&trie.root); } } #[test] fn test_each() { let mut m = TrieMap::new(); assert!(m.insert(3, 6)); assert!(m.insert(0, 0)); assert!(m.insert(4, 8)); assert!(m.insert(2, 4)); assert!(m.insert(1, 2)); let mut n = 0; for m.each |k, v| { assert_eq!(*k, n); assert_eq!(*v, n * 2); n += 1; } } #[test] fn test_each_break() { let mut m = TrieMap::new(); for uint::range_rev(uint::max_value, uint::max_value - 10000) |x| { m.insert(x, x / 2); } let mut n = uint::max_value - 9999; for m.each |k, v| { if n == uint::max_value - 5000 { break } assert!(n < uint::max_value - 5000); assert_eq!(*k, n); assert_eq!(*v, n / 2); n += 1; } } #[test] fn test_each_reverse() { let mut m = TrieMap::new(); assert!(m.insert(3, 6)); assert!(m.insert(0, 0)); assert!(m.insert(4, 8)); assert!(m.insert(2, 4)); assert!(m.insert(1, 2)); let mut n = 4; for m.each_reverse |k, v| { assert_eq!(*k, n); assert_eq!(*v, n * 2); n -= 1; } } #[test] fn test_each_reverse_break() { let mut m = TrieMap::new(); for uint::range_rev(uint::max_value, uint::max_value - 10000) |x| { m.insert(x, x / 2); } let mut n = uint::max_value; for m.each_reverse |k, v| { if n == uint::max_value - 5000 { break } assert!(n > uint::max_value - 5000); assert_eq!(*k, n); assert_eq!(*v, n / 2); n -= 1; } } #[test] fn test_sane_chunk() { let x = 1; let y = 1 << (uint::bits - 1); let mut trie = TrieSet::new(); assert!(trie.insert(x)); assert!(trie.insert(y)); assert_eq!(trie.len(), 2); let expected = [x, y]; let mut i = 0; for trie.each |x| { assert_eq!(expected[i], *x); i += 1; } } #[test] fn test_swap() { let mut m = TrieMap::new(); assert_eq!(m.swap(1, 2), None); assert_eq!(m.swap(1, 3), Some(2)); assert_eq!(m.swap(1, 4), Some(3)); } #[test] fn test_pop() { let mut m = TrieMap::new(); m.insert(1, 2); assert_eq!(m.pop(&1), Some(2)); assert_eq!(m.pop(&1), None); } }