rust/src/libstd/map.rs
2012-01-06 07:47:14 -08:00

417 lines
9.9 KiB
Rust

/*
Module: map
A hashmap
*/
/* Section: Types */
/*
Type: hashfn
A function that returns a hash of a value.
The hash should concentrate entropy in the
lower bits.
*/
type hashfn<K> = fn(K) -> uint;
/*
Type: eqfn
Equality
*/
type eqfn<K> = fn(K, K) -> bool;
/*
Type: hashset
A convenience type to treat a hashmap as a set
*/
type hashset<K> = hashmap<K, ()>;
/*
Obj: hashmap
*/
type hashmap<K, V> = obj {
/*
Method: size
Return the number of elements in the map
*/
fn size() -> uint;
/*
Method: insert
Add a value to the map. If the map already contains a value for
the specified key then the original value is replaced.
Returns:
True if the key did not already exist in the map
*/
fn insert(K, V) -> bool;
/*
Method: contains_key
Returns true if the map contains a value for the specified key
*/
fn contains_key(K) -> bool;
/*
Method: get
Get the value for the specified key
Failure:
If the key does not exist in the map
*/
fn get(K) -> V;
/*
Method: find
Get the value for the specified key. If the key does not exist
in the map then returns none.
*/
fn find(K) -> core::option::t<V>;
/*
Method: remove
Remove and return a value from the map. If the key does not exist
in the map then returns none.
*/
fn remove(K) -> core::option::t<V>;
/*
Method: rehash
Force map growth and rehashing
*/
fn rehash();
/*
Method: items
Iterate over all the key/value pairs in the map
*/
fn items(block(K, V));
/*
Method: keys
Iterate over all the keys in the map
*/
fn keys(block(K));
/*
Iterate over all the values in the map
*/
fn values(block(V));
};
/* Section: Operations */
mod chained {
type entry<K: copy, V: copy> = {
hash: uint,
key: K,
mutable value: V,
mutable next: chain<K, V>
};
tag chain<K: copy, V: copy> {
present(@entry<K, V>);
absent;
}
type t<K: copy, V: copy> = {
mutable size: uint,
mutable chains: [mutable chain<K,V>],
hasher: hashfn<K>,
eqer: eqfn<K>
};
tag search_result<K: copy, V: copy> {
not_found;
found_first(uint, @entry<K,V>);
found_after(@entry<K,V>, @entry<K,V>);
}
fn search_rem<K: copy, V: copy>(tbl: t<K,V>,
k: K,
h: uint,
idx: uint,
e_root: @entry<K,V>) -> search_result<K,V> {
let e0 = e_root;
let comp = 1u; // for logging
while true {
alt e0.next {
absent. {
#debug("search_tbl: absent, comp %u, hash %u, idx %u",
comp, h, idx);
ret not_found;
}
present(e1) {
comp += 1u;
let e1_key = e1.key; // Satisfy alias checker.
if e1.hash == h && tbl.eqer(e1_key, k) {
#debug("search_tbl: present, comp %u, hash %u, idx %u",
comp, h, idx);
ret found_after(e0, e1);
} else {
e0 = e1;
}
}
}
}
util::unreachable();
}
fn search_tbl<K: copy, V: copy>(
tbl: t<K,V>, k: K, h: uint) -> search_result<K,V> {
let idx = h % vec::len(tbl.chains);
alt tbl.chains[idx] {
absent. {
#debug("search_tbl: absent, comp %u, hash %u, idx %u",
0u, h, idx);
ret not_found;
}
present(e) {
let e_key = e.key; // Satisfy alias checker.
if e.hash == h && tbl.eqer(e_key, k) {
#debug("search_tbl: present, comp %u, hash %u, idx %u",
1u, h, idx);
ret found_first(idx, e);
} else {
ret search_rem(tbl, k, h, idx, e);
}
}
}
}
fn insert<K: copy, V: copy>(tbl: t<K,V>, k: K, v: V) -> bool {
let hash = tbl.hasher(k);
alt search_tbl(tbl, k, hash) {
not_found. {
tbl.size += 1u;
let idx = hash % vec::len(tbl.chains);
let old_chain = tbl.chains[idx];
tbl.chains[idx] = present(@{
hash: hash,
key: k,
mutable value: v,
mutable next: old_chain});
ret true;
}
found_first(_, entry) {
entry.value = v;
ret false;
}
found_after(_, entry) {
entry.value = v;
ret false
}
}
}
fn get<K: copy, V: copy>(tbl: t<K,V>, k: K) -> core::option::t<V> {
alt search_tbl(tbl, k, tbl.hasher(k)) {
not_found. {
ret core::option::none;
}
found_first(_, entry) {
ret core::option::some(entry.value);
}
found_after(_, entry) {
ret core::option::some(entry.value);
}
}
}
fn remove<K: copy, V: copy>(tbl: t<K,V>, k: K) -> core::option::t<V> {
alt search_tbl(tbl, k, tbl.hasher(k)) {
not_found. {
ret core::option::none;
}
found_first(idx, entry) {
tbl.size -= 1u;
tbl.chains[idx] = entry.next;
ret core::option::some(entry.value);
}
found_after(eprev, entry) {
tbl.size -= 1u;
eprev.next = entry.next;
ret core::option::some(entry.value);
}
}
}
fn chains<K: copy, V: copy>(nchains: uint) -> [mutable chain<K,V>] {
ret vec::init_elt_mut(absent, nchains);
}
fn foreach_entry<K: copy, V: copy>(chain0: chain<K,V>,
blk: block(@entry<K,V>)) {
let chain = chain0;
while true {
alt chain {
absent. { ret; }
present(entry) {
let next = entry.next;
blk(entry); // may modify entry.next!
chain = next;
}
}
}
}
fn foreach_chain<K: copy, V: copy>(chains: [const chain<K,V>],
blk: block(@entry<K,V>)) {
let i = 0u, n = vec::len(chains);
while i < n {
foreach_entry(chains[i], blk);
i += 1u;
}
}
fn rehash<K: copy, V: copy>(tbl: t<K,V>) {
let old_chains = tbl.chains;
let n_old_chains = vec::len(old_chains);
let n_new_chains: uint = uint::next_power_of_two(n_old_chains + 1u);
tbl.chains = chains(n_new_chains);
foreach_chain(old_chains) { |entry|
let idx = entry.hash % n_new_chains;
entry.next = tbl.chains[idx];
tbl.chains[idx] = present(entry);
}
}
fn items<K: copy, V: copy>(tbl: t<K,V>, blk: block(K,V)) {
let tbl_chains = tbl.chains; // Satisfy alias checker.
foreach_chain(tbl_chains) { |entry|
let key = entry.key;
let value = entry.value;
blk(key, value);
}
}
obj o<K: copy, V: copy>(tbl: @t<K,V>,
lf: util::rational) {
fn size() -> uint {
ret tbl.size;
}
fn insert(k: K, v: V) -> bool {
let nchains = vec::len(tbl.chains);
let load = {num:tbl.size + 1u as int, den:nchains as int};
if !util::rational_leq(load, lf) {
rehash(*tbl);
}
ret insert(*tbl, k, v);
}
fn contains_key(k: K) -> bool {
ret core::option::is_some(get(*tbl, k));
}
fn get(k: K) -> V {
ret core::option::get(get(*tbl, k));
}
fn find(k: K) -> core::option::t<V> {
ret get(*tbl, k);
}
fn remove(k: K) -> core::option::t<V> {
ret remove(*tbl, k);
}
fn rehash() {
rehash(*tbl);
}
fn items(blk: block(K, V)) {
items(*tbl, blk);
}
fn keys(blk: block(K)) {
items(*tbl) { |k, _v| blk(k) }
}
fn values(blk: block(V)) {
items(*tbl) { |_k, v| blk(v) }
}
}
fn mk<K: copy, V: copy>(hasher: hashfn<K>, eqer: eqfn<K>)
-> hashmap<K,V> {
let initial_capacity: uint = 32u; // 2^5
let t = @{mutable size: 0u,
mutable chains: chains(initial_capacity),
hasher: hasher,
eqer: eqer};
ret o(t, {num:3, den:4});
}
}
/*
Function: mk_hashmap
Construct a hashmap.
Parameters:
hasher - The hash function for key type K
eqer - The equality function for key type K
*/
fn mk_hashmap<K: copy, V: copy>(hasher: hashfn<K>, eqer: eqfn<K>)
-> hashmap<K, V> {
ret chained::mk(hasher, eqer);
}
/*
Function: new_str_hash
Construct a hashmap for string keys
*/
fn new_str_hash<V: copy>() -> hashmap<str, V> {
ret mk_hashmap(str::hash, str::eq);
}
/*
Function: new_int_hash
Construct a hashmap for int keys
*/
fn new_int_hash<V: copy>() -> hashmap<int, V> {
fn hash_int(&&x: int) -> uint { int::hash(x) }
fn eq_int(&&a: int, &&b: int) -> bool { ret a == b; }
ret mk_hashmap(hash_int, eq_int);
}
/*
Function: new_uint_hash
Construct a hashmap for uint keys
*/
fn new_uint_hash<V: copy>() -> hashmap<uint, V> {
fn hash_uint(&&x: uint) -> uint { uint::hash(x) }
fn eq_uint(&&a: uint, &&b: uint) -> bool { ret a == b; }
ret mk_hashmap(hash_uint, eq_uint);
}
/*
Function: set_add
Convenience function for adding keys to a hashmap with nil type keys
*/
fn set_add<K>(set: hashset<K>, key: K) -> bool { ret set.insert(key, ()); }
// Local Variables:
// mode: rust;
// fill-column: 78;
// indent-tabs-mode: nil
// c-basic-offset: 4
// buffer-file-coding-system: utf-8-unix
// End: