// 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 implemented as self-balancing binary search //! trees. The only requirement for the types is that the key implements //! `TotalOrd`. use std::uint; use std::util::{swap, replace}; // This is implemented as an AA tree, which is a simplified variation of // a red-black tree where red (horizontal) nodes can only be added // as a right child. The time complexity is the same, and re-balancing // operations are more frequent but also cheaper. // Future improvements: // range search - O(log n) retrieval of an iterator from some key // (possibly) implement the overloads Python does for sets: // * intersection: & // * difference: - // * symmetric difference: ^ // * union: | // These would be convenient since the methods work like `each` #[allow(missing_doc)] pub struct TreeMap { priv root: Option<~TreeNode>, priv length: uint } impl Eq for TreeMap { fn eq(&self, other: &TreeMap) -> bool { if self.len() != other.len() { false } else { let mut x = self.iter(); let mut y = other.iter(); for self.len().times { if x.next().unwrap() != y.next().unwrap() { return false } } true } } fn ne(&self, other: &TreeMap) -> bool { !self.eq(other) } } // Lexicographical comparison fn lt(a: &TreeMap, b: &TreeMap) -> bool { let mut x = a.iter(); let mut y = b.iter(); let (a_len, b_len) = (a.len(), b.len()); for uint::min(a_len, b_len).times { let (key_a, value_a) = x.next().unwrap(); let (key_b, value_b) = y.next().unwrap(); if *key_a < *key_b { return true; } if *key_a > *key_b { return false; } if *value_a < *value_b { return true; } if *value_a > *value_b { return false; } } a_len < b_len } impl Ord for TreeMap { #[inline] fn lt(&self, other: &TreeMap) -> bool { lt(self, other) } #[inline] fn le(&self, other: &TreeMap) -> bool { !lt(other, self) } #[inline] fn ge(&self, other: &TreeMap) -> bool { !lt(self, other) } #[inline] fn gt(&self, other: &TreeMap) -> bool { lt(other, self) } } impl Container for TreeMap { /// Return the number of elements in the map fn len(&self) -> uint { self.length } /// Return true if the map contains no elements fn is_empty(&self) -> bool { self.root.is_none() } } impl Mutable for TreeMap { /// Clear the map, removing all key-value pairs. fn clear(&mut self) { self.root = None; self.length = 0 } } impl Map for TreeMap { /// Return true if the map contains a value for the specified key fn contains_key(&self, key: &K) -> bool { self.find(key).is_some() } /// Return a reference to the value corresponding to the key fn find<'a>(&'a self, key: &K) -> Option<&'a V> { let mut current: &'a Option<~TreeNode> = &self.root; loop { match *current { Some(ref r) => { match key.cmp(&r.key) { Less => current = &r.left, Greater => current = &r.right, Equal => return Some(&r.value) } } None => return None } } } /// Return a mutable reference to the value corresponding to the key #[inline] fn find_mut<'a>(&'a mut self, key: &K) -> Option<&'a mut V> { find_mut(&mut self.root, key) } /// 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. fn insert(&mut self, key: K, value: V) -> 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. fn remove(&mut self, key: &K) -> 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: K, value: V) -> Option { let ret = insert(&mut self.root, key, value); 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: &K) -> Option { let ret = remove(&mut self.root, key); if ret.is_some() { self.length -= 1 } ret } } impl TreeMap { /// Create an empty TreeMap pub fn new() -> TreeMap { TreeMap{root: None, length: 0} } /// Visit all keys in order pub fn each_key(&self, f: &fn(&K) -> bool) -> bool { self.iter().advance(|(k, _)| f(k)) } /// Visit all values in order pub fn each_value<'a>(&'a self, f: &fn(&'a V) -> bool) -> bool { self.iter().advance(|(_, v)| f(v)) } /// Iterate over the map and mutate the contained values pub fn mutate_values(&mut self, f: &fn(&K, &mut V) -> bool) -> bool { mutate_values(&mut self.root, f) } /// Visit all key-value pairs in reverse order pub fn each_reverse<'a>(&'a self, f: &fn(&'a K, &'a V) -> bool) -> bool { each_reverse(&self.root, f) } /// Visit all keys in reverse order pub fn each_key_reverse(&self, f: &fn(&K) -> bool) -> bool { self.each_reverse(|k, _| f(k)) } /// Visit all values in reverse order pub fn each_value_reverse(&self, f: &fn(&V) -> bool) -> bool { self.each_reverse(|_, v| f(v)) } /// Get a lazy iterator over the key-value pairs in the map. /// Requires that it be frozen (immutable). pub fn iter<'a>(&'a self) -> TreeMapIterator<'a, K, V> { TreeMapIterator{stack: ~[], node: &self.root, remaining: self.length} } } /// Lazy forward iterator over a map pub struct TreeMapIterator<'self, K, V> { priv stack: ~[&'self ~TreeNode], priv node: &'self Option<~TreeNode>, priv remaining: uint } impl<'self, K, V> Iterator<(&'self K, &'self V)> for TreeMapIterator<'self, K, V> { /// Advance the iterator to the next node (in order) and return a /// tuple with a reference to the key and value. If there are no /// more nodes, return `None`. fn next(&mut self) -> Option<(&'self K, &'self V)> { while !self.stack.is_empty() || self.node.is_some() { match *self.node { Some(ref x) => { self.stack.push(x); self.node = &x.left; } None => { let res = self.stack.pop(); self.node = &res.right; self.remaining -= 1; return Some((&res.key, &res.value)); } } } None } #[inline] fn size_hint(&self) -> (uint, Option) { (self.remaining, Some(self.remaining)) } } impl<'self, T> Iterator<&'self T> for TreeSetIterator<'self, T> { /// Advance the iterator to the next node (in order). If there are no more nodes, return `None`. #[inline] fn next(&mut self) -> Option<&'self T> { do self.iter.next().map |&(value, _)| { value } } } /// A implementation of the `Set` trait on top of the `TreeMap` container. The /// only requirement is that the type of the elements contained ascribes to the /// `TotalOrd` trait. pub struct TreeSet { priv map: TreeMap } impl Eq for TreeSet { #[inline] fn eq(&self, other: &TreeSet) -> bool { self.map == other.map } #[inline] fn ne(&self, other: &TreeSet) -> bool { self.map != other.map } } impl Ord for TreeSet { #[inline] fn lt(&self, other: &TreeSet) -> bool { self.map < other.map } #[inline] fn le(&self, other: &TreeSet) -> bool { self.map <= other.map } #[inline] fn ge(&self, other: &TreeSet) -> bool { self.map >= other.map } #[inline] fn gt(&self, other: &TreeSet) -> bool { self.map > other.map } } impl Container for TreeSet { /// 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 TreeSet { /// Clear the set, removing all values. #[inline] fn clear(&mut self) { self.map.clear() } } impl Set for TreeSet { /// Return true if the set contains a value #[inline] fn contains(&self, value: &T) -> 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] fn insert(&mut self, value: T) -> bool { self.map.insert(value, ()) } /// Remove a value from the set. Return true if the value was /// present in the set. #[inline] fn remove(&mut self, value: &T) -> bool { self.map.remove(value) } /// Return true if the set has no elements in common with `other`. /// This is equivalent to checking for an empty intersection. fn is_disjoint(&self, other: &TreeSet) -> bool { let mut x = self.iter(); let mut y = other.iter(); let mut a = x.next(); let mut b = y.next(); while a.is_some() && b.is_some() { let a1 = a.unwrap(); let b1 = b.unwrap(); match a1.cmp(b1) { Less => a = x.next(), Greater => b = y.next(), Equal => return false } } true } /// Return true if the set is a subset of another #[inline] fn is_subset(&self, other: &TreeSet) -> bool { other.is_superset(self) } /// Return true if the set is a superset of another fn is_superset(&self, other: &TreeSet) -> bool { let mut x = self.iter(); let mut y = other.iter(); let mut a = x.next(); let mut b = y.next(); while b.is_some() { if a.is_none() { return false } let a1 = a.unwrap(); let b1 = b.unwrap(); match a1.cmp(b1) { Less => (), Greater => return false, Equal => b = y.next(), } a = x.next(); } true } /// Visit the values (in-order) representing the difference fn difference(&self, other: &TreeSet, f: &fn(&T) -> bool) -> bool { let mut x = self.iter(); let mut y = other.iter(); let mut a = x.next(); let mut b = y.next(); while a.is_some() { if b.is_none() { return f(a.unwrap()) && x.advance(f); } let a1 = a.unwrap(); let b1 = b.unwrap(); let cmp = a1.cmp(b1); if cmp == Less { if !f(a1) { return false; } a = x.next(); } else { if cmp == Equal { a = x.next() } b = y.next(); } } return true; } /// Visit the values (in-order) representing the symmetric difference fn symmetric_difference(&self, other: &TreeSet, f: &fn(&T) -> bool) -> bool { let mut x = self.iter(); let mut y = other.iter(); let mut a = x.next(); let mut b = y.next(); while a.is_some() { if b.is_none() { return f(a.unwrap()) && x.advance(f); } let a1 = a.unwrap(); let b1 = b.unwrap(); let cmp = a1.cmp(b1); if cmp == Less { if !f(a1) { return false; } a = x.next(); } else { if cmp == Greater { if !f(b1) { return false; } } else { a = x.next(); } b = y.next(); } } b.iter().advance(|&x| f(x)) && y.advance(f) } /// Visit the values (in-order) representing the intersection fn intersection(&self, other: &TreeSet, f: &fn(&T) -> bool) -> bool { let mut x = self.iter(); let mut y = other.iter(); let mut a = x.next(); let mut b = y.next(); while a.is_some() && b.is_some() { let a1 = a.unwrap(); let b1 = b.unwrap(); let cmp = a1.cmp(b1); if cmp == Less { a = x.next(); } else { if cmp == Equal { if !f(a1) { return false } } b = y.next(); } } return true; } /// Visit the values (in-order) representing the union fn union(&self, other: &TreeSet, f: &fn(&T) -> bool) -> bool { let mut x = self.iter(); let mut y = other.iter(); let mut a = x.next(); let mut b = y.next(); while a.is_some() { if b.is_none() { return f(a.unwrap()) && x.advance(f); } let a1 = a.unwrap(); let b1 = b.unwrap(); let cmp = a1.cmp(b1); if cmp == Greater { if !f(b1) { return false; } b = y.next(); } else { if !f(a1) { return false; } if cmp == Equal { b = y.next(); } a = x.next(); } } b.iter().advance(|&x| f(x)) && y.advance(f) } } impl TreeSet { /// Create an empty TreeSet #[inline] pub fn new() -> TreeSet { TreeSet{map: TreeMap::new()} } /// Get a lazy iterator over the values in the set. /// Requires that it be frozen (immutable). #[inline] pub fn iter<'a>(&'a self) -> TreeSetIterator<'a, T> { TreeSetIterator{iter: self.map.iter()} } /// Visit all values in reverse order #[inline] pub fn each_reverse(&self, f: &fn(&T) -> bool) -> bool { self.map.each_key_reverse(f) } } /// Lazy forward iterator over a set pub struct TreeSetIterator<'self, T> { priv iter: TreeMapIterator<'self, T, ()> } // Nodes keep track of their level in the tree, starting at 1 in the // leaves and with a red child sharing the level of the parent. struct TreeNode { key: K, value: V, left: Option<~TreeNode>, right: Option<~TreeNode>, level: uint } impl TreeNode { /// Creates a new tree node. #[inline] pub fn new(key: K, value: V) -> TreeNode { TreeNode{key: key, value: value, left: None, right: None, level: 1} } } fn each<'r, K: TotalOrd, V>(node: &'r Option<~TreeNode>, f: &fn(&'r K, &'r V) -> bool) -> bool { node.iter().advance(|x| each(&x.left, |k,v| f(k,v)) && f(&x.key, &x.value) && each(&x.right, |k,v| f(k,v))) } fn each_reverse<'r, K: TotalOrd, V>(node: &'r Option<~TreeNode>, f: &fn(&'r K, &'r V) -> bool) -> bool { node.iter().advance(|x| each_reverse(&x.right, |k,v| f(k,v)) && f(&x.key, &x.value) && each_reverse(&x.left, |k,v| f(k,v))) } fn mutate_values<'r, K: TotalOrd, V>(node: &'r mut Option<~TreeNode>, f: &fn(&'r K, &'r mut V) -> bool) -> bool { match *node { Some(~TreeNode{key: ref key, value: ref mut value, left: ref mut left, right: ref mut right, _}) => { if !mutate_values(left, |k,v| f(k,v)) { return false } if !f(key, value) { return false } if !mutate_values(right, |k,v| f(k,v)) { return false } } None => return false } true } // Remove left horizontal link by rotating right fn skew(node: &mut ~TreeNode) { if node.left.map_default(false, |x| x.level == node.level) { let mut save = node.left.swap_unwrap(); swap(&mut node.left, &mut save.right); // save.right now None swap(node, &mut save); node.right = Some(save); } } // Remove dual horizontal link by rotating left and increasing level of // the parent fn split(node: &mut ~TreeNode) { if node.right.map_default(false, |x| x.right.map_default(false, |y| y.level == node.level)) { let mut save = node.right.swap_unwrap(); swap(&mut node.right, &mut save.left); // save.left now None save.level += 1; swap(node, &mut save); node.left = Some(save); } } fn find_mut<'r, K: TotalOrd, V>(node: &'r mut Option<~TreeNode>, key: &K) -> Option<&'r mut V> { match *node { Some(ref mut x) => { match key.cmp(&x.key) { Less => find_mut(&mut x.left, key), Greater => find_mut(&mut x.right, key), Equal => Some(&mut x.value), } } None => None } } fn insert(node: &mut Option<~TreeNode>, key: K, value: V) -> Option { match *node { Some(ref mut save) => { match key.cmp(&save.key) { Less => { let inserted = insert(&mut save.left, key, value); skew(save); split(save); inserted } Greater => { let inserted = insert(&mut save.right, key, value); skew(save); split(save); inserted } Equal => { save.key = key; Some(replace(&mut save.value, value)) } } } None => { *node = Some(~TreeNode::new(key, value)); None } } } fn remove(node: &mut Option<~TreeNode>, key: &K) -> Option { fn heir_swap(node: &mut ~TreeNode, child: &mut Option<~TreeNode>) { // *could* be done without recursion, but it won't borrow check for child.mut_iter().advance |x| { if x.right.is_some() { heir_swap(node, &mut x.right); } else { swap(&mut node.key, &mut x.key); swap(&mut node.value, &mut x.value); } } } match *node { None => { return None; // bottom of tree } Some(ref mut save) => { let (ret, rebalance) = match key.cmp(&save.key) { Less => (remove(&mut save.left, key), true), Greater => (remove(&mut save.right, key), true), Equal => { if save.left.is_some() { if save.right.is_some() { let mut left = save.left.swap_unwrap(); if left.right.is_some() { heir_swap(save, &mut left.right); } else { swap(&mut save.key, &mut left.key); swap(&mut save.value, &mut left.value); } save.left = Some(left); (remove(&mut save.left, key), true) } else { let new = save.left.swap_unwrap(); let ~TreeNode{value, _} = replace(save, new); *save = save.left.swap_unwrap(); (Some(value), true) } } else if save.right.is_some() { let new = save.right.swap_unwrap(); let ~TreeNode{value, _} = replace(save, new); (Some(value), true) } else { (None, false) } } }; if rebalance { let left_level = save.left.map_default(0, |x| x.level); let right_level = save.right.map_default(0, |x| x.level); // re-balance, if necessary if left_level < save.level - 1 || right_level < save.level - 1 { save.level -= 1; if right_level > save.level { for save.right.mut_iter().advance |x| { x.level = save.level } } skew(save); for save.right.mut_iter().advance |right| { skew(right); for right.right.mut_iter().advance |x| { skew(x) } } split(save); for save.right.mut_iter().advance |x| { split(x) } } return ret; } } } return match replace(node, None) { Some(~TreeNode{value, _}) => Some(value), None => fail!() }; } #[cfg(test)] mod test_treemap { use super::*; use std::rand::RngUtil; use std::rand; #[test] fn find_empty() { let m = TreeMap::new::(); assert!(m.find(&5) == None); } #[test] fn find_not_found() { let mut m = TreeMap::new(); assert!(m.insert(1, 2)); assert!(m.insert(5, 3)); assert!(m.insert(9, 3)); assert_eq!(m.find(&2), None); } #[test] fn test_find_mut() { let mut m = TreeMap::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 insert_replace() { let mut m = TreeMap::new(); assert!(m.insert(5, 2)); assert!(m.insert(2, 9)); assert!(!m.insert(2, 11)); assert_eq!(m.find(&2).unwrap(), &11); } #[test] fn test_clear() { let mut m = TreeMap::new(); m.clear(); assert!(m.insert(5, 11)); assert!(m.insert(12, -3)); assert!(m.insert(19, 2)); m.clear(); assert!(m.find(&5).is_none()); assert!(m.find(&12).is_none()); assert!(m.find(&19).is_none()); assert!(m.is_empty()); } #[test] fn u8_map() { let mut m = TreeMap::new(); let k1 = "foo".as_bytes(); let k2 = "bar".as_bytes(); let v1 = "baz".as_bytes(); let v2 = "foobar".as_bytes(); m.insert(copy k1, copy v1); m.insert(copy k2, copy v2); assert_eq!(m.find(&k2), Some(&v2)); assert_eq!(m.find(&k1), Some(&v1)); } fn check_equal(ctrl: &[(K, V)], map: &TreeMap) { assert_eq!(ctrl.is_empty(), map.is_empty()); for ctrl.iter().advance |x| { let &(k, v) = x; assert!(map.find(&k).unwrap() == &v) } for map.iter().advance |(map_k, map_v)| { let mut found = false; for ctrl.iter().advance |x| { let &(ctrl_k, ctrl_v) = x; if *map_k == ctrl_k { assert!(*map_v == ctrl_v); found = true; break; } } assert!(found); } } fn check_left(node: &Option<~TreeNode>, parent: &~TreeNode) { match *node { Some(ref r) => { assert_eq!(r.key.cmp(&parent.key), Less); assert!(r.level == parent.level - 1); // left is black check_left(&r.left, r); check_right(&r.right, r, false); } None => assert!(parent.level == 1) // parent is leaf } } fn check_right(node: &Option<~TreeNode>, parent: &~TreeNode, parent_red: bool) { match *node { Some(ref r) => { assert_eq!(r.key.cmp(&parent.key), Greater); let red = r.level == parent.level; if parent_red { assert!(!red) } // no dual horizontal links // Right red or black assert!(red || r.level == parent.level - 1); check_left(&r.left, r); check_right(&r.right, r, red); } None => assert!(parent.level == 1) // parent is leaf } } fn check_structure(map: &TreeMap) { match map.root { Some(ref r) => { check_left(&r.left, r); check_right(&r.right, r, false); } None => () } } #[test] fn test_rand_int() { let mut map = TreeMap::new::(); let mut ctrl = ~[]; check_equal(ctrl, &map); assert!(map.find(&5).is_none()); let mut rng = rand::IsaacRng::new_seeded(&[42]); for 3.times { for 90.times { let k = rng.gen(); let v = rng.gen(); if !ctrl.iter().any(|x| x == &(k, v)) { assert!(map.insert(k, v)); ctrl.push((k, v)); check_structure(&map); check_equal(ctrl, &map); } } for 30.times { let r = rng.gen_uint_range(0, ctrl.len()); let (key, _) = ctrl.remove(r); assert!(map.remove(&key)); check_structure(&map); check_equal(ctrl, &map); } } } #[test] fn test_len() { let mut m = TreeMap::new(); assert!(m.insert(3, 6)); assert_eq!(m.len(), 1); assert!(m.insert(0, 0)); assert_eq!(m.len(), 2); assert!(m.insert(4, 8)); assert_eq!(m.len(), 3); assert!(m.remove(&3)); assert_eq!(m.len(), 2); assert!(!m.remove(&5)); assert_eq!(m.len(), 2); assert!(m.insert(2, 4)); assert_eq!(m.len(), 3); assert!(m.insert(1, 2)); assert_eq!(m.len(), 4); } #[test] fn test_iterator() { let mut m = TreeMap::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.iter().advance |(k, v)| { assert_eq!(*k, n); assert_eq!(*v, n * 2); n += 1; } } #[test] fn test_each_reverse() { let mut m = TreeMap::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_eq() { let mut a = TreeMap::new(); let mut b = TreeMap::new(); assert!(a == b); assert!(a.insert(0, 5)); assert!(a != b); assert!(b.insert(0, 4)); assert!(a != b); assert!(a.insert(5, 19)); assert!(a != b); assert!(!b.insert(0, 5)); assert!(a != b); assert!(b.insert(5, 19)); assert!(a == b); } #[test] fn test_lt() { let mut a = TreeMap::new(); let mut b = TreeMap::new(); assert!(!(a < b) && !(b < a)); assert!(b.insert(0, 5)); assert!(a < b); assert!(a.insert(0, 7)); assert!(!(a < b) && b < a); assert!(b.insert(-2, 0)); assert!(b < a); assert!(a.insert(-5, 2)); assert!(a < b); assert!(a.insert(6, 2)); assert!(a < b && !(b < a)); } #[test] fn test_ord() { let mut a = TreeMap::new(); let mut b = TreeMap::new(); assert!(a <= b && a >= b); assert!(a.insert(1, 1)); assert!(a > b && a >= b); assert!(b < a && b <= a); assert!(b.insert(2, 2)); assert!(b > a && b >= a); assert!(a < b && a <= b); } #[test] fn test_lazy_iterator() { let mut m = TreeMap::new(); let (x1, y1) = (2, 5); let (x2, y2) = (9, 12); let (x3, y3) = (20, -3); let (x4, y4) = (29, 5); let (x5, y5) = (103, 3); assert!(m.insert(x1, y1)); assert!(m.insert(x2, y2)); assert!(m.insert(x3, y3)); assert!(m.insert(x4, y4)); assert!(m.insert(x5, y5)); let m = m; let mut a = m.iter(); assert_eq!(a.next().unwrap(), (&x1, &y1)); assert_eq!(a.next().unwrap(), (&x2, &y2)); assert_eq!(a.next().unwrap(), (&x3, &y3)); assert_eq!(a.next().unwrap(), (&x4, &y4)); assert_eq!(a.next().unwrap(), (&x5, &y5)); assert!(a.next().is_none()); let mut b = m.iter(); let expected = [(&x1, &y1), (&x2, &y2), (&x3, &y3), (&x4, &y4), (&x5, &y5)]; let mut i = 0; for b.advance |x| { assert_eq!(expected[i], x); i += 1; if i == 2 { break } } for b.advance |x| { assert_eq!(expected[i], x); i += 1; } } } #[cfg(test)] mod test_set { use super::*; #[test] fn test_clear() { let mut s = TreeSet::new(); s.clear(); assert!(s.insert(5)); assert!(s.insert(12)); assert!(s.insert(19)); s.clear(); assert!(!s.contains(&5)); assert!(!s.contains(&12)); assert!(!s.contains(&19)); assert!(s.is_empty()); } #[test] fn test_disjoint() { let mut xs = TreeSet::new(); let mut ys = TreeSet::new(); assert!(xs.is_disjoint(&ys)); assert!(ys.is_disjoint(&xs)); assert!(xs.insert(5)); assert!(ys.insert(11)); assert!(xs.is_disjoint(&ys)); assert!(ys.is_disjoint(&xs)); assert!(xs.insert(7)); assert!(xs.insert(19)); assert!(xs.insert(4)); assert!(ys.insert(2)); assert!(ys.insert(-11)); assert!(xs.is_disjoint(&ys)); assert!(ys.is_disjoint(&xs)); assert!(ys.insert(7)); assert!(!xs.is_disjoint(&ys)); assert!(!ys.is_disjoint(&xs)); } #[test] fn test_subset_and_superset() { let mut a = TreeSet::new(); assert!(a.insert(0)); assert!(a.insert(5)); assert!(a.insert(11)); assert!(a.insert(7)); let mut b = TreeSet::new(); assert!(b.insert(0)); assert!(b.insert(7)); assert!(b.insert(19)); assert!(b.insert(250)); assert!(b.insert(11)); assert!(b.insert(200)); assert!(!a.is_subset(&b)); assert!(!a.is_superset(&b)); assert!(!b.is_subset(&a)); assert!(!b.is_superset(&a)); assert!(b.insert(5)); assert!(a.is_subset(&b)); assert!(!a.is_superset(&b)); assert!(!b.is_subset(&a)); assert!(b.is_superset(&a)); } #[test] fn test_iterator() { let mut m = TreeSet::new(); assert!(m.insert(3)); assert!(m.insert(0)); assert!(m.insert(4)); assert!(m.insert(2)); assert!(m.insert(1)); let mut n = 0; for m.iter().advance |x| { println(fmt!("%?", x)); assert_eq!(*x, n); n += 1 } } #[test] fn test_each_reverse() { let mut m = TreeSet::new(); assert!(m.insert(3)); assert!(m.insert(0)); assert!(m.insert(4)); assert!(m.insert(2)); assert!(m.insert(1)); let mut n = 4; for m.each_reverse |x| { assert_eq!(*x, n); n -= 1 } } fn check(a: &[int], b: &[int], expected: &[int], f: &fn(&TreeSet, &TreeSet, f: &fn(&int) -> bool) -> bool) { let mut set_a = TreeSet::new(); let mut set_b = TreeSet::new(); for a.iter().advance |x| { assert!(set_a.insert(*x)) } for b.iter().advance |y| { assert!(set_b.insert(*y)) } let mut i = 0; for f(&set_a, &set_b) |x| { assert_eq!(*x, expected[i]); i += 1; } assert_eq!(i, expected.len()); } #[test] fn test_intersection() { fn check_intersection(a: &[int], b: &[int], expected: &[int]) { check(a, b, expected, |x, y, z| x.intersection(y, z)) } check_intersection([], [], []); check_intersection([1, 2, 3], [], []); check_intersection([], [1, 2, 3], []); check_intersection([2], [1, 2, 3], [2]); check_intersection([1, 2, 3], [2], [2]); check_intersection([11, 1, 3, 77, 103, 5, -5], [2, 11, 77, -9, -42, 5, 3], [3, 5, 11, 77]); } #[test] fn test_difference() { fn check_difference(a: &[int], b: &[int], expected: &[int]) { check(a, b, expected, |x, y, z| x.difference(y, z)) } check_difference([], [], []); check_difference([1, 12], [], [1, 12]); check_difference([], [1, 2, 3, 9], []); check_difference([1, 3, 5, 9, 11], [3, 9], [1, 5, 11]); check_difference([-5, 11, 22, 33, 40, 42], [-12, -5, 14, 23, 34, 38, 39, 50], [11, 22, 33, 40, 42]); } #[test] fn test_symmetric_difference() { fn check_symmetric_difference(a: &[int], b: &[int], expected: &[int]) { check(a, b, expected, |x, y, z| x.symmetric_difference(y, z)) } check_symmetric_difference([], [], []); check_symmetric_difference([1, 2, 3], [2], [1, 3]); check_symmetric_difference([2], [1, 2, 3], [1, 3]); check_symmetric_difference([1, 3, 5, 9, 11], [-2, 3, 9, 14, 22], [-2, 1, 5, 11, 14, 22]); } #[test] fn test_union() { fn check_union(a: &[int], b: &[int], expected: &[int]) { check(a, b, expected, |x, y, z| x.union(y, z)) } check_union([], [], []); check_union([1, 2, 3], [2], [1, 2, 3]); check_union([2], [1, 2, 3], [1, 2, 3]); check_union([1, 3, 5, 9, 11, 16, 19, 24], [-2, 1, 5, 9, 13, 19], [-2, 1, 3, 5, 9, 11, 13, 16, 19, 24]); } #[test] fn test_zip() { let mut x = TreeSet::new(); x.insert(5u); x.insert(12u); x.insert(11u); let mut y = TreeSet::new(); y.insert("foo"); y.insert("bar"); let x = x; let y = y; let mut z = x.iter().zip(y.iter()); // FIXME: #5801: this needs a type hint to compile... let result: Option<(&uint, & &'static str)> = z.next(); assert_eq!(result.unwrap(), (&5u, & &"bar")); let result: Option<(&uint, & &'static str)> = z.next(); assert_eq!(result.unwrap(), (&11u, & &"foo")); let result: Option<(&uint, & &'static str)> = z.next(); assert!(result.is_none()); } #[test] fn test_swap() { let mut m = TreeMap::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 = TreeMap::new(); m.insert(1, 2); assert_eq!(m.pop(&1), Some(2)); assert_eq!(m.pop(&1), None); } }