rust/src/libcore/dvec.rs
2012-09-26 18:02:07 -07:00

362 lines
9.8 KiB
Rust

/*!
Dynamic vector
A growable vector that makes use of unique pointers so that the
result can be sent between tasks and so forth.
Note that recursive use is not permitted.
*/
// NB: transitionary, de-mode-ing.
#[forbid(deprecated_mode)];
#[forbid(deprecated_pattern)];
use cast::reinterpret_cast;
use ptr::null;
/**
* A growable, modifiable vector type that accumulates elements into a
* unique vector.
*
* # Limitations on recursive use
*
* This class works by swapping the unique vector out of the data
* structure whenever it is to be used. Therefore, recursive use is not
* permitted. That is, while iterating through a vector, you cannot
* access the vector in any other way or else the program will fail. If
* you wish, you can use the `swap()` method to gain access to the raw
* vector and transform it or use it any way you like. Eventually, we
* may permit read-only access during iteration or other use.
*
* # WARNING
*
* For maximum performance, this type is implemented using some rather
* unsafe code. In particular, this innocent looking `~[mut A]` pointer
* *may be null!* Therefore, it is important you not reach into the
* data structure manually but instead use the provided extensions.
*
* The reason that I did not use an unsafe pointer in the structure
* itself is that I wanted to ensure that the vector would be freed when
* the dvec is dropped. The reason that I did not use an `Option<T>`
* instead of a nullable pointer is that I found experimentally that it
* becomes approximately 50% slower. This can probably be improved
* through optimization. You can run your own experiments using
* `src/test/bench/vec-append.rs`. My own tests found that using null
* pointers achieved about 103 million pushes/second. Using an option
* type could only produce 47 million pushes/second.
*/
type DVec_<A> = {
mut data: ~[A]
};
pub enum DVec<A> {
DVec_(DVec_<A>)
}
/// Creates a new, empty dvec
pub fn DVec<A>() -> DVec<A> {
DVec_({mut data: ~[]})
}
/// Creates a new dvec with a single element
pub fn from_elem<A>(+e: A) -> DVec<A> {
DVec_({mut data: ~[move e]})
}
/// Creates a new dvec with the contents of a vector
pub fn from_vec<A>(+v: ~[A]) -> DVec<A> {
DVec_({mut data: move v})
}
/// Consumes the vector and returns its contents
pub fn unwrap<A>(+d: DVec<A>) -> ~[A] {
let DVec_({data: v}) <- d;
move v
}
priv impl<A> DVec<A> {
pure fn check_not_borrowed() {
unsafe {
let data: *() = cast::reinterpret_cast(&self.data);
if data.is_null() {
fail ~"Recursive use of dvec";
}
}
}
#[inline(always)]
fn check_out<B>(f: &fn(+v: ~[A]) -> B) -> B {
unsafe {
let mut data = cast::reinterpret_cast(&null::<()>());
data <-> self.data;
let data_ptr: *() = cast::reinterpret_cast(&data);
if data_ptr.is_null() { fail ~"Recursive use of dvec"; }
return f(move data);
}
}
#[inline(always)]
fn give_back(+data: ~[A]) {
unsafe {
self.data = move data;
}
}
}
// In theory, most everything should work with any A, but in practice
// almost nothing works without the copy bound due to limitations
// around closures.
impl<A> DVec<A> {
/// Reserves space for N elements
fn reserve(count: uint) {
vec::reserve(&mut self.data, count)
}
/**
* Swaps out the current vector and hands it off to a user-provided
* function `f`. The function should transform it however is desired
* and return a new vector to replace it with.
*/
#[inline(always)]
fn swap(f: &fn(+v: ~[A]) -> ~[A]) {
self.check_out(|v| self.give_back(f(move v)))
}
/**
* Swaps out the current vector and hands it off to a user-provided
* function `f`. The function should transform it however is desired
* and return a new vector to replace it with.
*/
#[inline(always)]
fn swap_mut(f: &fn(-v: ~[mut A]) -> ~[mut A]) {
do self.swap |v| {
vec::from_mut(f(vec::to_mut(move v)))
}
}
/// Returns the number of elements currently in the dvec
pure fn len() -> uint {
unsafe {
do self.check_out |v| {
let l = v.len();
self.give_back(move v);
l
}
}
}
/// Overwrite the current contents
fn set(+w: ~[A]) {
self.check_not_borrowed();
self.data <- w;
}
/// Remove and return the last element
fn pop() -> A {
do self.check_out |v| {
let mut v <- v;
let result = vec::pop(v);
self.give_back(move v);
move result
}
}
/// Insert a single item at the front of the list
fn unshift(+t: A) {
unsafe {
let mut data = cast::reinterpret_cast(&null::<()>());
data <-> self.data;
let data_ptr: *() = cast::reinterpret_cast(&data);
if data_ptr.is_null() { fail ~"Recursive use of dvec"; }
log(error, ~"a");
self.data <- ~[move t];
self.data.push_all_move(move data);
log(error, ~"b");
}
}
/// Append a single item to the end of the list
fn push(+t: A) {
self.check_not_borrowed();
self.data.push(move t);
}
/// Remove and return the first element
fn shift() -> A {
do self.check_out |v| {
let mut v = move v;
let result = vec::shift(v);
self.give_back(move v);
move result
}
}
/// Reverse the elements in the list, in place
fn reverse() {
do self.check_out |v| {
let mut v = move v;
vec::reverse(v);
self.give_back(move v);
}
}
/// Gives access to the vector as a slice with immutable contents
fn borrow<R>(op: fn(x: &[A]) -> R) -> R {
do self.check_out |v| {
let result = op(v);
self.give_back(move v);
move result
}
}
/// Gives access to the vector as a slice with mutable contents
fn borrow_mut<R>(op: fn(x: &[mut A]) -> R) -> R {
do self.check_out |v| {
let mut v = move v;
let result = op(v);
self.give_back(move v);
move result
}
}
}
impl<A: Copy> DVec<A> {
/**
* Append all elements of a vector to the end of the list
*
* Equivalent to `append_iter()` but potentially more efficient.
*/
fn push_all(ts: &[const A]) {
self.push_slice(ts, 0u, vec::len(ts));
}
/// Appends elements from `from_idx` to `to_idx` (exclusive)
fn push_slice(ts: &[const A], from_idx: uint, to_idx: uint) {
do self.swap |v| {
let mut v <- v;
let new_len = vec::len(v) + to_idx - from_idx;
vec::reserve(&mut v, new_len);
let mut i = from_idx;
while i < to_idx {
v.push(ts[i]);
i += 1u;
}
move v
}
}
/**
* Append all elements of an iterable.
*
* Failure will occur if the iterable's `each()` method
* attempts to access this vector.
*/
/*
fn append_iter<A, I:iter::base_iter<A>>(ts: I) {
do self.swap |v| {
let mut v = match ts.size_hint() {
none { v }
Some(h) {
let len = v.len() + h;
let mut v <- v;
vec::reserve(v, len);
v
}
};
for ts.each |t| { v.push(*t) };
v
}
}
*/
/**
* Gets a copy of the current contents.
*
* See `unwrap()` if you do not wish to copy the contents.
*/
pure fn get() -> ~[A] {
unsafe {
do self.check_out |v| {
let w = copy v;
self.give_back(move v);
move w
}
}
}
/// Copy out an individual element
#[inline(always)]
pure fn get_elt(idx: uint) -> A {
self.check_not_borrowed();
return self.data[idx];
}
/// Overwrites the contents of the element at `idx` with `a`
fn set_elt(idx: uint, +a: A) {
self.check_not_borrowed();
self.data[idx] = a;
}
/**
* Overwrites the contents of the element at `idx` with `a`,
* growing the vector if necessary. New elements will be initialized
* with `initval`
*/
fn grow_set_elt(idx: uint, initval: A, +val: A) {
do self.swap |v| {
let mut v = move v;
vec::grow_set(v, idx, initval, val);
move v
}
}
/// Returns the last element, failing if the vector is empty
#[inline(always)]
pure fn last() -> A {
self.check_not_borrowed();
let length = self.len();
if length == 0 {
fail ~"attempt to retrieve the last element of an empty vector";
}
return self.data[length - 1];
}
/// Iterates over the elements in reverse order
#[inline(always)]
fn rev_each(f: fn(v: &A) -> bool) {
do self.swap |v| {
// FIXME(#2263)---we should be able to write
// `vec::rev_each(v, f);` but we cannot write now
for vec::rev_each(v) |e| {
if !f(e) { break; }
}
move v
}
}
/// Iterates over the elements and indices in reverse order
#[inline(always)]
fn rev_eachi(f: fn(uint, v: &A) -> bool) {
do self.swap |v| {
// FIXME(#2263)---we should be able to write
// `vec::rev_eachi(v, f);` but we cannot write now
for vec::rev_eachi(v) |i, e| {
if !f(i, e) { break; }
}
move v
}
}
}
impl<A:Copy> DVec<A>: Index<uint,A> {
pure fn index(+idx: uint) -> A {
self.get_elt(idx)
}
}