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hashmap.rs
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// 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 <LICENSE-APACHE or
// http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
// <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your
// option. This file may not be copied, modified, or distributed
// except according to those terms.
//! An unordered map and set type implemented as hash tables
//!
//! The tables use a keyed hash with new random keys generated for each container, so the ordering
//! of a set of keys in a hash table is randomized.
use container::{Container, Mutable, Map, Set};
use cmp::{Eq, Equiv};
use hash::Hash;
use to_bytes::IterBytes;
use iter::BaseIter;
use hash::Hash;
use iter;
use option::{None, Option, Some};
use rand::RngUtil;
use rand;
use uint;
use vec;
use util::unreachable;
static INITIAL_CAPACITY: uint = 32u; // 2^5
struct Bucket<K,V> {
hash: uint,
key: K,
value: V,
}
pub struct HashMap<K,V> {
priv k0: u64,
priv k1: u64,
priv resize_at: uint,
priv size: uint,
priv buckets: ~[Option<Bucket<K, V>>],
}
// We could rewrite FoundEntry to have type Option<&Bucket<K, V>>
// which would be nifty
enum SearchResult {
FoundEntry(uint), FoundHole(uint), TableFull
}
#[inline(always)]
fn resize_at(capacity: uint) -> uint {
((capacity as float) * 3. / 4.) as uint
}
pub fn linear_map_with_capacity<K:Eq + Hash,V>(
initial_capacity: uint) -> HashMap<K, V> {
let r = rand::task_rng();
linear_map_with_capacity_and_keys(r.gen_u64(), r.gen_u64(),
initial_capacity)
}
fn linear_map_with_capacity_and_keys<K:Eq + Hash,V>(
k0: u64, k1: u64,
initial_capacity: uint) -> HashMap<K, V> {
HashMap {
k0: k0, k1: k1,
resize_at: resize_at(initial_capacity),
size: 0,
buckets: vec::from_fn(initial_capacity, |_| None)
}
}
priv impl<K:Hash + IterBytes + Eq,V> HashMap<K, V> {
#[inline(always)]
fn to_bucket(&self, h: uint) -> uint {
// A good hash function with entropy spread over all of the
// bits is assumed. SipHash is more than good enough.
h % self.buckets.len()
}
#[inline(always)]
fn next_bucket(&self, idx: uint, len_buckets: uint) -> uint {
let n = (idx + 1) % len_buckets;
debug!("next_bucket(%?, %?) = %?", idx, len_buckets, n);
n
}
#[inline(always)]
fn bucket_sequence(&self, hash: uint,
op: &fn(uint) -> bool) -> uint {
let start_idx = self.to_bucket(hash);
let len_buckets = self.buckets.len();
let mut idx = start_idx;
loop {
if !op(idx) {
return idx;
}
idx = self.next_bucket(idx, len_buckets);
if idx == start_idx {
return start_idx;
}
}
}
#[inline(always)]
fn bucket_for_key(&self, k: &K) -> SearchResult {
let hash = k.hash_keyed(self.k0, self.k1) as uint;
self.bucket_for_key_with_hash(hash, k)
}
#[inline(always)]
fn bucket_for_key_equiv<Q:Hash + IterBytes + Equiv<K>>(&self,
k: &Q)
-> SearchResult {
let hash = k.hash_keyed(self.k0, self.k1) as uint;
self.bucket_for_key_with_hash_equiv(hash, k)
}
#[inline(always)]
fn bucket_for_key_with_hash(&self,
hash: uint,
k: &K)
-> SearchResult {
let _ = for self.bucket_sequence(hash) |i| {
match self.buckets[i] {
Some(ref bkt) => if bkt.hash == hash && *k == bkt.key {
return FoundEntry(i);
},
None => return FoundHole(i)
}
};
TableFull
}
#[inline(always)]
fn bucket_for_key_with_hash_equiv<Q:Equiv<K>>(&self,
hash: uint,
k: &Q)
-> SearchResult {
let _ = for self.bucket_sequence(hash) |i| {
match self.buckets[i] {
Some(ref bkt) => {
if bkt.hash == hash && k.equiv(&bkt.key) {
return FoundEntry(i);
}
},
None => return FoundHole(i)
}
};
TableFull
}
/// Expand the capacity of the array to the next power of two
/// and re-insert each of the existing buckets.
#[inline(always)]
fn expand(&mut self) {
let new_capacity = self.buckets.len() * 2;
self.resize(new_capacity);
}
/// Expands the capacity of the array and re-insert each of the
/// existing buckets.
fn resize(&mut self, new_capacity: uint) {
let old_capacity = self.buckets.len();
self.resize_at = resize_at(new_capacity);
let mut old_buckets = vec::from_fn(new_capacity, |_| None);
self.buckets <-> old_buckets;
self.size = 0;
for uint::range(0, old_capacity) |i| {
let mut bucket = None;
bucket <-> old_buckets[i];
self.insert_opt_bucket(bucket);
}
}
fn insert_opt_bucket(&mut self, bucket: Option<Bucket<K, V>>) {
match bucket {
Some(Bucket{hash: hash, key: key, value: value}) => {
self.insert_internal(hash, key, value);
}
None => {}
}
}
#[inline(always)]
fn value_for_bucket(&self, idx: uint) -> &'self V {
match self.buckets[idx] {
Some(ref bkt) => &bkt.value,
None => fail!(~"HashMap::find: internal logic error"),
}
}
#[inline(always)]
fn mut_value_for_bucket(&mut self, idx: uint) -> &'self mut V {
match self.buckets[idx] {
Some(ref mut bkt) => &mut bkt.value,
None => unreachable()
}
}
/// Inserts the key value pair into the buckets.
/// Assumes that there will be a bucket.
/// True if there was no previous entry with that key
fn insert_internal(&mut self, hash: uint, k: K, v: V) -> bool {
match self.bucket_for_key_with_hash(hash, &k) {
TableFull => { fail!(~"Internal logic error"); }
FoundHole(idx) => {
debug!("insert fresh (%?->%?) at idx %?, hash %?",
k, v, idx, hash);
self.buckets[idx] = Some(Bucket{hash: hash, key: k,
value: v});
self.size += 1;
true
}
FoundEntry(idx) => {
debug!("insert overwrite (%?->%?) at idx %?, hash %?",
k, v, idx, hash);
self.buckets[idx] = Some(Bucket{hash: hash, key: k,
value: v});
false
}
}
}
fn pop_internal(&mut self, hash: uint, k: &K) -> Option<V> {
// Removing from an open-addressed hashtable
// is, well, painful. The problem is that
// the entry may lie on the probe path for other
// entries, so removing it would make you think that
// those probe paths are empty.
//
// To address this we basically have to keep walking,
// re-inserting entries we find until we reach an empty
// bucket. We know we will eventually reach one because
// we insert one ourselves at the beginning (the removed
// entry).
//
// I found this explanation elucidating:
// http://www.maths.lse.ac.uk/Courses/MA407/del-hash.pdf
let mut idx = match self.bucket_for_key_with_hash(hash, k) {
TableFull | FoundHole(_) => return None,
FoundEntry(idx) => idx
};
let len_buckets = self.buckets.len();
let mut bucket = None;
self.buckets[idx] <-> bucket;
let value = match bucket {
None => None,
Some(bucket) => {
let Bucket{value: value, _} = bucket;
Some(value)
},
};
/* re-inserting buckets may cause changes in size, so remember
what our new size is ahead of time before we start insertions */
let size = self.size - 1;
idx = self.next_bucket(idx, len_buckets);
while self.buckets[idx].is_some() {
let mut bucket = None;
bucket <-> self.buckets[idx];
self.insert_opt_bucket(bucket);
idx = self.next_bucket(idx, len_buckets);
}
self.size = size;
value
}
fn search(&self, hash: uint,
op: &fn(x: &Option<Bucket<K, V>>) -> bool) {
let _ = self.bucket_sequence(hash, |i| op(&self.buckets[i]));
}
}
impl<'self,K:Hash + IterBytes + Eq,V>
BaseIter<(&'self K, &'self V)> for HashMap<K, V> {
/// Visit all key-value pairs
fn each(&self, blk: &fn(&(&'self K, &'self V)) -> bool) {
for uint::range(0, self.buckets.len()) |i| {
let mut broke = false;
do self.buckets[i].map |bucket| {
if !blk(&(&bucket.key, &bucket.value)) {
broke = true; // FIXME(#3064) just write "break;"
}
};
if broke { break; }
}
}
fn size_hint(&self) -> Option<uint> { Some(self.len()) }
}
impl<K:Hash + IterBytes + Eq,V> Container for HashMap<K, V> {
/// Return the number of elements in the map
fn len(&const self) -> uint { self.size }
/// Return true if the map contains no elements
fn is_empty(&const self) -> bool { self.len() == 0 }
}
impl<K:Hash + IterBytes + Eq,V> Mutable for HashMap<K, V> {
/// Clear the map, removing all key-value pairs.
fn clear(&mut self) {
for uint::range(0, self.buckets.len()) |idx| {
self.buckets[idx] = None;
}
self.size = 0;
}
}
impl<'self,K:Hash + IterBytes + Eq,V> Map<'self, K, V> for HashMap<K, V> {
/// Return true if the map contains a value for the specified key
fn contains_key(&self, k: &K) -> bool {
match self.bucket_for_key(k) {
FoundEntry(_) => {true}
TableFull | FoundHole(_) => {false}
}
}
/// Visit all keys
fn each_key(&self, blk: &fn(k: &'self K) -> bool) {
self.each(|&(k, _)| blk(k))
}
/// Visit all values
fn each_value(&self, blk: &fn(v: &'self V) -> bool) {
self.each(|&(_, v)| blk(v))
}
/// Iterate over the map and mutate the contained values
fn mutate_values(&mut self, blk: &fn(&'self K,
&'self mut V) -> bool) {
for uint::range(0, self.buckets.len()) |i| {
match self.buckets[i] {
Some(Bucket{key: ref key, value: ref mut value, _}) => {
if !blk(key, value) { return }
}
None => ()
}
}
}
/// Return a reference to the value corresponding to the key
fn find(&self, k: &K) -> Option<&'self V> {
match self.bucket_for_key(k) {
FoundEntry(idx) => Some(self.value_for_bucket(idx)),
TableFull | FoundHole(_) => None,
}
}
/// Return a mutable reference to the value corresponding to the key
fn find_mut(&mut self, k: &K) -> Option<&'self mut V> {
let idx = match self.bucket_for_key(k) {
FoundEntry(idx) => idx,
TableFull | FoundHole(_) => return None
};
unsafe { // FIXME(#4903)---requires flow-sensitive borrow checker
Some(::cast::transmute_mut_region(self.mut_value_for_bucket(idx)))
}
}
/// 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, k: K, v: V) -> bool {
if self.size >= self.resize_at {
// n.b.: We could also do this after searching, so
// that we do not resize if this call to insert is
// simply going to update a key in place. My sense
// though is that it's worse to have to search through
// buckets to find the right spot twice than to just
// resize in this corner case.
self.expand();
}
let hash = k.hash_keyed(self.k0, self.k1) as uint;
self.insert_internal(hash, k, v)
}
/// Remove a key-value pair from the map. Return true if the key
/// was present in the map, otherwise false.
fn remove(&mut self, k: &K) -> bool {
self.pop(k).is_some()
}
}
pub impl<K: Hash + IterBytes + Eq, V> HashMap<K, V> {
/// Create an empty HashMap
fn new() -> HashMap<K, V> {
HashMap::with_capacity(INITIAL_CAPACITY)
}
/// Create an empty HashMap with space for at least `n` elements in
/// the hash table.
fn with_capacity(capacity: uint) -> HashMap<K, V> {
linear_map_with_capacity(capacity)
}
/// Reserve space for at least `n` elements in the hash table.
fn reserve_at_least(&mut self, n: uint) {
if n > self.buckets.len() {
let buckets = n * 4 / 3 + 1;
self.resize(uint::next_power_of_two(buckets));
}
}
fn pop(&mut self, k: &K) -> Option<V> {
let hash = k.hash_keyed(self.k0, self.k1) as uint;
self.pop_internal(hash, k)
}
fn swap(&mut self, k: K, v: V) -> Option<V> {
// this could be faster.
let hash = k.hash_keyed(self.k0, self.k1) as uint;
let old_value = self.pop_internal(hash, &k);
if self.size >= self.resize_at {
// n.b.: We could also do this after searching, so
// that we do not resize if this call to insert is
// simply going to update a key in place. My sense
// though is that it's worse to have to search through
// buckets to find the right spot twice than to just
// resize in this corner case.
self.expand();
}
self.insert_internal(hash, k, v);
old_value
}
/// Return the value corresponding to the key in the map, or insert
/// and return the value if it doesn't exist.
fn find_or_insert(&mut self, k: K, v: V) -> &'self V {
if self.size >= self.resize_at {
// n.b.: We could also do this after searching, so
// that we do not resize if this call to insert is
// simply going to update a key in place. My sense
// though is that it's worse to have to search through
// buckets to find the right spot twice than to just
// resize in this corner case.
self.expand();
}
let hash = k.hash_keyed(self.k0, self.k1) as uint;
let idx = match self.bucket_for_key_with_hash(hash, &k) {
TableFull => fail!(~"Internal logic error"),
FoundEntry(idx) => idx,
FoundHole(idx) => {
self.buckets[idx] = Some(Bucket{hash: hash, key: k,
value: v});
self.size += 1;
idx
},
};
unsafe { // FIXME(#4903)---requires flow-sensitive borrow checker
::cast::transmute_region(self.value_for_bucket(idx))
}
}
/// Return the value corresponding to the key in the map, or create,
/// insert, and return a new value if it doesn't exist.
fn find_or_insert_with(&mut self, k: K, f: &fn(&K) -> V) -> &'self V {
if self.size >= self.resize_at {
// n.b.: We could also do this after searching, so
// that we do not resize if this call to insert is
// simply going to update a key in place. My sense
// though is that it's worse to have to search through
// buckets to find the right spot twice than to just
// resize in this corner case.
self.expand();
}
let hash = k.hash_keyed(self.k0, self.k1) as uint;
let idx = match self.bucket_for_key_with_hash(hash, &k) {
TableFull => fail!(~"Internal logic error"),
FoundEntry(idx) => idx,
FoundHole(idx) => {
let v = f(&k);
self.buckets[idx] = Some(Bucket{hash: hash, key: k,
value: v});
self.size += 1;
idx
},
};
unsafe { // FIXME(#4903)---requires flow-sensitive borrow checker
::cast::transmute_region(self.value_for_bucket(idx))
}
}
fn consume(&mut self, f: &fn(K, V)) {
let mut buckets = ~[];
self.buckets <-> buckets;
self.size = 0;
do vec::consume(buckets) |_, bucket| {
match bucket {
None => {},
Some(bucket) => {
let Bucket{key: key, value: value, _} = bucket;
f(key, value)
}
}
}
}
fn get(&self, k: &K) -> &'self V {
match self.find(k) {
Some(v) => v,
None => fail!(fmt!("No entry found for key: %?", k)),
}
}
/// Return true if the map contains a value for the specified key,
/// using equivalence
fn contains_key_equiv<Q:Hash + IterBytes + Equiv<K>>(&self, key: &Q)
-> bool {
match self.bucket_for_key_equiv(key) {
FoundEntry(_) => {true}
TableFull | FoundHole(_) => {false}
}
}
/// Return the value corresponding to the key in the map, using
/// equivalence
fn find_equiv<Q:Hash + IterBytes + Equiv<K>>(&self, k: &Q)
-> Option<&'self V> {
match self.bucket_for_key_equiv(k) {
FoundEntry(idx) => Some(self.value_for_bucket(idx)),
TableFull | FoundHole(_) => None,
}
}
}
impl<K:Hash + IterBytes + Eq,V:Eq> Eq for HashMap<K, V> {
fn eq(&self, other: &HashMap<K, V>) -> bool {
if self.len() != other.len() { return false; }
for self.each |&(key, value)| {
match other.find(key) {
None => return false,
Some(v) => if value != v { return false },
}
}
true
}
fn ne(&self, other: &HashMap<K, V>) -> bool { !self.eq(other) }
}
pub struct HashSet<T> {
priv map: HashMap<T, ()>
}
impl<T:Hash + IterBytes + Eq> BaseIter<T> for HashSet<T> {
/// Visit all values in order
fn each(&self, f: &fn(&'self T) -> bool) { self.map.each_key(f) }
fn size_hint(&self) -> Option<uint> { Some(self.len()) }
}
impl<T:Hash + IterBytes + Eq> Eq for HashSet<T> {
fn eq(&self, other: &HashSet<T>) -> bool { self.map == other.map }
fn ne(&self, other: &HashSet<T>) -> bool { self.map != other.map }
}
impl<T:Hash + IterBytes + Eq> Container for HashSet<T> {
/// Return the number of elements in the set
fn len(&const self) -> uint { self.map.len() }
/// Return true if the set contains no elements
fn is_empty(&const self) -> bool { self.map.is_empty() }
}
impl<T:Hash + IterBytes + Eq> Mutable for HashSet<T> {
/// Clear the set, removing all values.
fn clear(&mut self) { self.map.clear() }
}
impl<T:Hash + IterBytes + Eq> Set<T> for HashSet<T> {
/// Return true if the set contains a value
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.
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.
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: &HashSet<T>) -> bool {
iter::all(self, |v| !other.contains(v))
}
/// Return true if the set is a subset of another
fn is_subset(&self, other: &HashSet<T>) -> bool {
iter::all(self, |v| other.contains(v))
}
/// Return true if the set is a superset of another
fn is_superset(&self, other: &HashSet<T>) -> bool {
other.is_subset(self)
}
/// Visit the values representing the difference
fn difference(&self, other: &HashSet<T>, f: &fn(&T) -> bool) {
for self.each |v| {
if !other.contains(v) {
if !f(v) { return }
}
}
}
/// Visit the values representing the symmetric difference
fn symmetric_difference(&self,
other: &HashSet<T>,
f: &fn(&T) -> bool) {
self.difference(other, f);
other.difference(self, f);
}
/// Visit the values representing the intersection
fn intersection(&self, other: &HashSet<T>, f: &fn(&T) -> bool) {
for self.each |v| {
if other.contains(v) {
if !f(v) { return }
}
}
}
/// Visit the values representing the union
fn union(&self, other: &HashSet<T>, f: &fn(&T) -> bool) {
for self.each |v| {
if !f(v) { return }
}
for other.each |v| {
if !self.contains(v) {
if !f(v) { return }
}
}
}
}
pub impl <T:Hash + IterBytes + Eq> HashSet<T> {
/// Create an empty HashSet
fn new() -> HashSet<T> {
HashSet::with_capacity(INITIAL_CAPACITY)
}
/// Create an empty HashSet with space for at least `n` elements in
/// the hash table.
fn with_capacity(capacity: uint) -> HashSet<T> {
HashSet { map: HashMap::with_capacity(capacity) }
}
/// Reserve space for at least `n` elements in the hash table.
fn reserve_at_least(&mut self, n: uint) {
self.map.reserve_at_least(n)
}
/// Consumes all of the elements in the set, emptying it out
fn consume(&mut self, f: &fn(T)) {
self.map.consume(|k, _| f(k))
}
}
#[test]
mod test_map {
use container::{Container, Map, Set};
use option::{None, Some};
use super::*;
use uint;
#[test]
pub fn test_insert() {
let mut m = HashMap::new();
assert!(m.insert(1, 2));
assert!(m.insert(2, 4));
assert!(*m.get(&1) == 2);
assert!(*m.get(&2) == 4);
}
#[test]
fn test_find_mut() {
let mut m = HashMap::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]
pub fn test_insert_overwrite() {
let mut m = HashMap::new();
assert!(m.insert(1, 2));
assert!(*m.get(&1) == 2);
assert!(!m.insert(1, 3));
assert!(*m.get(&1) == 3);
}
#[test]
pub fn test_insert_conflicts() {
let mut m = linear_map_with_capacity(4);
assert!(m.insert(1, 2));
assert!(m.insert(5, 3));
assert!(m.insert(9, 4));
assert!(*m.get(&9) == 4);
assert!(*m.get(&5) == 3);
assert!(*m.get(&1) == 2);
}
#[test]
pub fn test_conflict_remove() {
let mut m = linear_map_with_capacity(4);
assert!(m.insert(1, 2));
assert!(m.insert(5, 3));
assert!(m.insert(9, 4));
assert!(m.remove(&1));
assert!(*m.get(&9) == 4);
assert!(*m.get(&5) == 3);
}
#[test]
pub fn test_is_empty() {
let mut m = linear_map_with_capacity(4);
assert!(m.insert(1, 2));
assert!(!m.is_empty());
assert!(m.remove(&1));
assert!(m.is_empty());
}
#[test]
pub fn test_pop() {
let mut m = HashMap::new();
m.insert(1, 2);
assert!(m.pop(&1) == Some(2));
assert!(m.pop(&1) == None);
}
#[test]
pub fn test_swap() {
let mut m = HashMap::new();
assert!(m.swap(1, 2) == None);
assert!(m.swap(1, 3) == Some(2));
assert!(m.swap(1, 4) == Some(3));
}
#[test]
pub fn test_find_or_insert() {
let mut m = HashMap::new::<int, int>();
assert!(m.find_or_insert(1, 2) == &2);
assert!(m.find_or_insert(1, 3) == &2);
}
#[test]
pub fn test_find_or_insert_with() {
let mut m = HashMap::new::<int, int>();
assert!(m.find_or_insert_with(1, |_| 2) == &2);
assert!(m.find_or_insert_with(1, |_| 3) == &2);
}
#[test]
pub fn test_consume() {
let mut m = HashMap::new();
assert!(m.insert(1, 2));
assert!(m.insert(2, 3));
let mut m2 = HashMap::new();
do m.consume |k, v| {
m2.insert(k, v);
}
assert!(m.len() == 0);
assert!(m2.len() == 2);
assert!(m2.get(&1) == &2);
assert!(m2.get(&2) == &3);
}
#[test]
pub fn test_iterate() {
let mut m = linear_map_with_capacity(4);
for uint::range(0, 32) |i| {
assert!(m.insert(i, i*2));
}
let mut observed = 0;
for m.each |&(k, v)| {
assert!(*v == *k * 2);
observed |= (1 << *k);
}
assert!(observed == 0xFFFF_FFFF);
}
#[test]
pub fn test_find() {
let mut m = HashMap::new();
assert!(m.find(&1).is_none());
m.insert(1, 2);
match m.find(&1) {
None => fail!(),
Some(v) => assert!(*v == 2)
}
}
#[test]
pub fn test_eq() {
let mut m1 = HashMap::new();
m1.insert(1, 2);
m1.insert(2, 3);
m1.insert(3, 4);
let mut m2 = HashMap::new();
m2.insert(1, 2);
m2.insert(2, 3);
assert!(m1 != m2);
m2.insert(3, 4);
assert!(m1 == m2);
}
#[test]
pub fn test_expand() {
let mut m = HashMap::new();
assert!(m.len() == 0);
assert!(m.is_empty());
let mut i = 0u;
let old_resize_at = m.resize_at;
while old_resize_at == m.resize_at {
m.insert(i, i);
i += 1;
}
assert!(m.len() == i);
assert!(!m.is_empty());
}
}
#[test]
mod test_set {
use super::*;
use container::{Container, Map, Set};
use vec;
#[test]
fn test_disjoint() {
let mut xs = HashSet::new();
let mut ys = HashSet::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 = HashSet::new();
assert!(a.insert(0));
assert!(a.insert(5));
assert!(a.insert(11));
assert!(a.insert(7));
let mut b = HashSet::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_intersection() {
let mut a = HashSet::new();
let mut b = HashSet::new();
assert!(a.insert(11));
assert!(a.insert(1));
assert!(a.insert(3));
assert!(a.insert(77));
assert!(a.insert(103));
assert!(a.insert(5));
assert!(a.insert(-5));
assert!(b.insert(2));
assert!(b.insert(11));
assert!(b.insert(77));
assert!(b.insert(-9));
assert!(b.insert(-42));
assert!(b.insert(5));
assert!(b.insert(3));
let mut i = 0;
let expected = [3, 5, 11, 77];
for a.intersection(&b) |x| {
assert!(vec::contains(expected, x));
i += 1
}
assert!(i == expected.len());
}
#[test]
fn test_difference() {
let mut a = HashSet::new();
let mut b = HashSet::new();
assert!(a.insert(1));
assert!(a.insert(3));
assert!(a.insert(5));
assert!(a.insert(9));
assert!(a.insert(11));
assert!(b.insert(3));
assert!(b.insert(9));
let mut i = 0;
let expected = [1, 5, 11];
for a.difference(&b) |x| {
assert!(vec::contains(expected, x));
i += 1
}
assert!(i == expected.len());
}
#[test]
fn test_symmetric_difference() {
let mut a = HashSet::new();
let mut b = HashSet::new();
assert!(a.insert(1));
assert!(a.insert(3));
assert!(a.insert(5));
assert!(a.insert(9));
assert!(a.insert(11));
assert!(b.insert(-2));
assert!(b.insert(3));
assert!(b.insert(9));
assert!(b.insert(14));
assert!(b.insert(22));
let mut i = 0;
let expected = [-2, 1, 5, 11, 14, 22];
for a.symmetric_difference(&b) |x| {
assert!(vec::contains(expected, x));
i += 1
}
assert!(i == expected.len());
}
#[test]
fn test_union() {
let mut a = HashSet::new();
let mut b = HashSet::new();
assert!(a.insert(1));
assert!(a.insert(3));
assert!(a.insert(5));
assert!(a.insert(9));