rust/src/libcore/vec.rs

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/*
Module: vec
*/
import option::{some, none};
import uint::next_power_of_two;
import ptr::addr_of;
#[abi = "rust-intrinsic"]
native mod rusti {
fn vec_len<T>(&&v: [const T]) -> ctypes::size_t;
}
#[abi = "cdecl"]
native mod rustrt {
fn vec_reserve_shared<T>(t: *sys::type_desc,
&v: [const T],
n: ctypes::size_t);
fn vec_from_buf_shared<T>(t: *sys::type_desc,
ptr: *T,
count: ctypes::size_t) -> [T];
}
/*
Type: init_op
A function used to initialize the elements of a vector.
*/
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type init_op<T> = fn(uint) -> T;
/*
Predicate: is_empty
Returns true if a vector contains no elements.
*/
pure fn is_empty<T>(v: [const T]) -> bool {
// FIXME: This would be easier if we could just call len
for t: T in v { ret false; }
ret true;
}
/*
Predicate: is_not_empty
Returns true if a vector contains some elements.
*/
pure fn is_not_empty<T>(v: [const T]) -> bool { ret !is_empty(v); }
/*
Predicate: same_length
Returns true if two vectors have the same length
*/
pure fn same_length<T, U>(xs: [const T], ys: [const U]) -> bool {
vec::len(xs) == vec::len(ys)
}
/*
Function: reserve
Reserves capacity for `n` elements in the given vector.
If the capacity for `v` is already equal to or greater than the requested
capacity, then no action is taken.
Parameters:
v - A vector
n - The number of elements to reserve space for
*/
fn reserve<T>(&v: [const T], n: uint) {
rustrt::vec_reserve_shared(sys::get_type_desc::<T>(), v, n);
}
/*
Function: len
Returns the length of a vector
*/
#[inline(always)]
pure fn len<T>(v: [const T]) -> uint { unchecked { rusti::vec_len(v) } }
/*
Function: init_fn
Creates and initializes an immutable vector.
Creates an immutable vector of size `n_elts` and initializes the elements
to the value returned by the function `op`.
*/
fn init_fn<T>(n_elts: uint, op: init_op<T>) -> [T] {
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let mut v = [];
reserve(v, n_elts);
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let mut i: uint = 0u;
while i < n_elts { v += [op(i)]; i += 1u; }
ret v;
}
/*
Function: init_elt
Creates and initializes an immutable vector.
Creates an immutable vector of size `n_elts` and initializes the elements
to the value `t`.
*/
fn init_elt<T: copy>(n_elts: uint, t: T) -> [T] {
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let mut v = [];
reserve(v, n_elts);
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let mut i: uint = 0u;
while i < n_elts { v += [t]; i += 1u; }
ret v;
}
// FIXME: Possible typestate postcondition:
// len(result) == len(v) (needs issue #586)
/*
Produces a mutable vector from an immutable vector.
*/
fn to_mut<T>(+v: [T]) -> [mutable T] unsafe {
let r = ::unsafe::reinterpret_cast(v);
::unsafe::leak(v);
r
}
/*
Function: from_mut
Produces an immutable vector from a mutable vector.
*/
fn from_mut<T>(+v: [mutable T]) -> [T] unsafe {
let r = ::unsafe::reinterpret_cast(v);
::unsafe::leak(v);
r
}
// Accessors
/*
Function: head
Returns the first element of a vector
Predicates:
<is_not_empty> (v)
*/
pure fn head<T: copy>(v: [const T]) -> T { v[0] }
/*
Function: tail
Returns all but the first element of a vector
*/
fn tail<T: copy>(v: [const T]) -> [T] {
ret slice(v, 1u, len(v));
}
/*
Function tail_n
Returns all but the first N elements of a vector
*/
fn tail_n<T: copy>(v: [const T], n: uint) -> [T] {
slice(v, n, len(v))
}
// FIXME: This name is sort of confusing next to init_fn, etc
// but this is the name haskell uses for this function,
// along with head/tail/last.
/*
Function: init
Returns all but the last elemnt of a vector
Preconditions:
`v` is not empty
*/
fn init<T: copy>(v: [const T]) -> [T] {
assert len(v) != 0u;
slice(v, 0u, len(v) - 1u)
}
/*
Function: last
Returns the last element of a `v`, failing if the vector is empty.
*/
pure fn last<T: copy>(v: [const T]) -> T {
if len(v) == 0u { fail "last_unsafe: empty vector" }
v[len(v) - 1u]
}
/*
Function: last_opt
Returns some(x) where `x` is the last element of a vector `v`,
or none if the vector is empty.
*/
pure fn last_opt<T: copy>(v: [const T]) -> option<T> {
if len(v) == 0u { ret none; }
some(v[len(v) - 1u])
}
/*
Function: slice
Returns a copy of the elements from [`start`..`end`) from `v`.
*/
fn slice<T: copy>(v: [const T], start: uint, end: uint) -> [T] {
assert (start <= end);
assert (end <= len(v));
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let mut result = [];
reserve(result, end - start);
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let mut i = start;
while i < end { result += [v[i]]; i += 1u; }
ret result;
}
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/*
Function: split
Split the vector `v` by applying each element against the predicate `f`.
*/
fn split<T: copy>(v: [const T], f: fn(T) -> bool) -> [[T]] {
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let ln = len(v);
if (ln == 0u) { ret [] }
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let mut start = 0u;
let mut result = [];
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while start < ln {
alt position_from(v, start, ln, f) {
none { break }
some(i) {
push(result, slice(v, start, i));
start = i + 1u;
}
}
}
push(result, slice(v, start, ln));
result
}
/*
Function: splitn
Split the vector `v` by applying each element against the predicate `f` up
to `n` times.
*/
fn splitn<T: copy>(v: [const T], n: uint, f: fn(T) -> bool) -> [[T]] {
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let ln = len(v);
if (ln == 0u) { ret [] }
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let mut start = 0u;
let mut count = n;
let mut result = [];
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while start < ln && count > 0u {
alt position_from(v, start, ln, f) {
none { break }
some(i) {
push(result, slice(v, start, i));
// Make sure to skip the separator.
start = i + 1u;
count -= 1u;
}
}
}
push(result, slice(v, start, ln));
result
}
/*
Function: rsplit
Reverse split the vector `v` by applying each element against the predicate
`f`.
*/
fn rsplit<T: copy>(v: [const T], f: fn(T) -> bool) -> [[T]] {
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let ln = len(v);
if (ln == 0u) { ret [] }
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let mut end = ln;
let mut result = [];
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while end > 0u {
alt rposition_from(v, 0u, end, f) {
none { break }
some(i) {
push(result, slice(v, i + 1u, end));
end = i;
}
}
}
push(result, slice(v, 0u, end));
reversed(result)
}
/*
Function: rsplitn
Reverse split the vector `v` by applying each element against the predicate
`f` up to `n times.
*/
fn rsplitn<T: copy>(v: [const T], n: uint, f: fn(T) -> bool) -> [[T]] {
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let ln = len(v);
if (ln == 0u) { ret [] }
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let mut end = ln;
let mut count = n;
let mut result = [];
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while end > 0u && count > 0u {
alt rposition_from(v, 0u, end, f) {
none { break }
some(i) {
push(result, slice(v, i + 1u, end));
// Make sure to skip the separator.
end = i;
count -= 1u;
}
}
}
push(result, slice(v, 0u, end));
reversed(result)
}
// Mutators
/*
Function: shift
Removes the first element from a vector and return it
*/
fn shift<T: copy>(&v: [const T]) -> T {
let ln = len::<T>(v);
assert (ln > 0u);
let e = v[0];
v = slice::<T>(v, 1u, ln);
ret e;
}
/*
Function: pop
Remove the last element from a vector and return it
*/
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fn pop<T>(&v: [const T]) -> T unsafe {
let ln = len(v);
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assert ln > 0u;
let valptr = ptr::mut_addr_of(v[ln - 1u]);
let val <- *valptr;
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unsafe::set_len(v, ln - 1u);
val
}
/*
Function: push
Append an element to a vector
*/
fn push<T: copy>(&v: [const T], initval: T) {
v += [initval];
}
// TODO: More.
// Appending
/*
Function: grow
Expands a vector in place, initializing the new elements to a given value
Parameters:
v - The vector to grow
n - The number of elements to add
initval - The value for the new elements
*/
fn grow<T: copy>(&v: [const T], n: uint, initval: T) {
reserve(v, next_power_of_two(len(v) + n));
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let mut i: uint = 0u;
while i < n { v += [initval]; i += 1u; }
}
/*
Function: grow_fn
Expands a vector in place, initializing the new elements to the result of a
function
Function `init_op` is called `n` times with the values [0..`n`)
Parameters:
v - The vector to grow
n - The number of elements to add
init_op - A function to call to retreive each appended element's value
*/
fn grow_fn<T>(&v: [const T], n: uint, op: init_op<T>) {
reserve(v, next_power_of_two(len(v) + n));
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let mut i: uint = 0u;
while i < n { v += [op(i)]; i += 1u; }
}
/*
Function: grow_set
Sets the value of a vector element at a given index, growing the vector as
needed
Sets the element at position `index` to `val`. If `index` is past the end
of the vector, expands the vector by replicating `initval` to fill the
intervening space.
*/
fn grow_set<T: copy>(&v: [mutable T], index: uint, initval: T, val: T) {
if index >= len(v) { grow(v, index - len(v) + 1u, initval); }
v[index] = val;
}
// Functional utilities
/*
Function: map
Apply a function to each element of a vector and return the results
*/
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fn map<T, U>(v: [T], f: fn(T) -> U) -> [U] {
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let mut result = [];
reserve(result, len(v));
for elem: T in v { result += [f(elem)]; }
ret result;
}
/*
Function: map2
Apply a function to each pair of elements and return the results
*/
fn map2<T: copy, U: copy, V>(v0: [const T], v1: [const U],
f: fn(T, U) -> V) -> [V] {
let v0_len = len(v0);
if v0_len != len(v1) { fail; }
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let mut u: [V] = [];
let mut i = 0u;
while i < v0_len { u += [f(copy v0[i], copy v1[i])]; i += 1u; }
ret u;
}
/*
Function: filter_map
Apply a function to each element of a vector and return the results
If function `f` returns `none` then that element is excluded from
the resulting vector.
*/
fn filter_map<T: copy, U: copy>(v: [const T], f: fn(T) -> option<U>)
-> [U] {
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let mut result = [];
for elem: T in v {
alt f(copy elem) {
none {/* no-op */ }
some(result_elem) { result += [result_elem]; }
}
}
ret result;
}
/*
Function: filter
Construct a new vector from the elements of a vector for which some predicate
holds.
Apply function `f` to each element of `v` and return a vector containing
only those elements for which `f` returned true.
*/
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fn filter<T: copy>(v: [T], f: fn(T) -> bool) -> [T] {
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let mut result = [];
for elem: T in v {
if f(elem) { result += [elem]; }
}
ret result;
}
/*
Function: concat
Concatenate a vector of vectors. Flattens a vector of vectors of T into
a single vector of T.
*/
fn concat<T: copy>(v: [const [const T]]) -> [T] {
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let mut new: [T] = [];
for inner: [T] in v { new += inner; }
ret new;
}
/*
Function: connect
Concatenate a vector of vectors, placing a given separator between each
*/
fn connect<T: copy>(v: [const [const T]], sep: T) -> [T] {
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let mut new: [T] = [];
let mut first = true;
for inner: [T] in v {
if first { first = false; } else { push(new, sep); }
new += inner;
}
ret new;
}
/*
Function: foldl
Reduce a vector from left to right
*/
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fn foldl<T: copy, U>(z: T, v: [const U], p: fn(T, U) -> T) -> T {
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let mut accum = z;
iter(v) { |elt|
accum = p(accum, elt);
}
ret accum;
}
/*
Function: foldr
Reduce a vector from right to left
*/
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fn foldr<T, U: copy>(v: [const T], z: U, p: fn(T, U) -> U) -> U {
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let mut accum = z;
riter(v) { |elt|
accum = p(elt, accum);
}
ret accum;
}
/*
Function: any
Return true if a predicate matches any elements
If the vector contains no elements then false is returned.
*/
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fn any<T>(v: [T], f: fn(T) -> bool) -> bool {
for elem: T in v { if f(elem) { ret true; } }
ret false;
}
/*
Function: any2
Return true if a predicate matches any elements in both vectors.
If the vectors contains no elements then false is returned.
*/
fn any2<T, U>(v0: [const T], v1: [U], f: fn(T, U) -> bool) -> bool {
let v0_len = len(v0);
let v1_len = len(v1);
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let mut i = 0u;
while i < v0_len && i < v1_len {
if f(v0[i], v1[i]) { ret true; };
i += 1u;
}
ret false;
}
/*
Function: all
Return true if a predicate matches all elements
If the vector contains no elements then true is returned.
*/
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fn all<T>(v: [T], f: fn(T) -> bool) -> bool {
for elem: T in v { if !f(elem) { ret false; } }
ret true;
}
/*
Function: all2
Return true if a predicate matches all elements in both vectors.
If the vectors are not the same size then false is returned.
*/
fn all2<T, U>(v0: [const T], v1: [const U], f: fn(T, U) -> bool) -> bool {
let v0_len = len(v0);
if v0_len != len(v1) { ret false; }
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let mut i = 0u;
while i < v0_len { if !f(v0[i], v1[i]) { ret false; }; i += 1u; }
ret true;
}
/*
Function: contains
Return true if a vector contains an element with the given value
*/
fn contains<T>(v: [const T], x: T) -> bool {
for elt: T in v { if x == elt { ret true; } }
ret false;
}
/*
Function: count
Returns the number of elements that are equal to a given value
*/
fn count<T>(v: [const T], x: T) -> uint {
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let mut cnt = 0u;
for elt: T in v { if x == elt { cnt += 1u; } }
ret cnt;
}
/*
Function: find
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Search for the first element that matches a given predicate
Apply function `f` to each element of `v`, starting from the first.
When function `f` returns true then an option containing the element
is returned. If `f` matches no elements then none is returned.
*/
fn find<T: copy>(v: [const T], f: fn(T) -> bool) -> option<T> {
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find_from(v, 0u, len(v), f)
}
/*
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Function: find_from
Search for the first element that matches a given predicate within a range
Apply function `f` to each element of `v` within the range [`start`, `end`).
When function `f` returns true then an option containing the element
is returned. If `f` matches no elements then none is returned.
*/
fn find_from<T: copy>(v: [const T], start: uint, end: uint,
f: fn(T) -> bool) -> option<T> {
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option::map(position_from(v, start, end, f)) { |i| v[i] }
}
/*
Function: rfind
Search for the last element that matches a given predicate
Apply function `f` to each element of `v` in reverse order. When function `f`
returns true then an option containing the element is returned. If `f`
matches no elements then none is returned.
*/
fn rfind<T: copy>(v: [const T], f: fn(T) -> bool) -> option<T> {
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rfind_from(v, 0u, len(v), f)
}
/*
Function: rfind_from
Search for the last element that matches a given predicate within a range
Apply function `f` to each element of `v` in reverse order within the range
[`start`, `end`). When function `f` returns true then an option containing
the element is returned. If `f` matches no elements then none is returned.
*/
fn rfind_from<T: copy>(v: [const T], start: uint, end: uint,
f: fn(T) -> bool) -> option<T> {
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option::map(rposition_from(v, start, end, f)) { |i| v[i] }
}
/*
Function: position_elt
Find the first index containing a matching value
Returns:
option::some(uint) - The first index containing a matching value
option::none - No elements matched
*/
fn position_elt<T>(v: [const T], x: T) -> option<uint> {
position(v) { |y| x == y }
}
/*
Function: position
Find the first index matching some predicate
Apply function `f` to each element of `v`. When function `f` returns true
then an option containing the index is returned. If `f` matches no elements
then none is returned.
*/
fn position<T>(v: [const T], f: fn(T) -> bool) -> option<uint> {
position_from(v, 0u, len(v), f)
}
/*
Function: position_from
Find the first index matching some predicate within a range
Apply function `f` to each element of `v` between the range [`start`, `end`).
When function `f` returns true then an option containing the index is
returned. If `f` matches no elements then none is returned.
*/
fn position_from<T>(v: [const T], start: uint, end: uint,
f: fn(T) -> bool) -> option<uint> {
assert start <= end;
assert end <= len(v);
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let mut i = start;
while i < end { if f(v[i]) { ret some::<uint>(i); } i += 1u; }
ret none;
}
/*
Function: rposition_elt
Find the last index containing a matching value
Returns:
option::some(uint) - The last index containing a matching value
option::none - No elements matched
*/
fn rposition_elt<T>(v: [const T], x: T) -> option<uint> {
rposition(v) { |y| x == y }
}
/*
Function: rposition
Find the last index matching some predicate
Apply function `f` to each element of `v` in reverse order. When function
`f` returns true then an option containing the index is returned. If `f`
matches no elements then none is returned.
*/
fn rposition<T>(v: [const T], f: fn(T) -> bool) -> option<uint> {
rposition_from(v, 0u, len(v), f)
}
/*
Function: rposition_from
Find the last index matching some predicate within a range
Apply function `f` to each element of `v` in reverse order between the range
[`start`, `end`). When function `f` returns true then an option containing
the index is returned. If `f` matches no elements then none is returned.
*/
fn rposition_from<T>(v: [const T], start: uint, end: uint,
f: fn(T) -> bool) -> option<uint> {
assert start <= end;
assert end <= len(v);
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let mut i = end;
while i > start {
if f(v[i - 1u]) { ret some::<uint>(i - 1u); }
i -= 1u;
}
ret none;
}
// FIXME: if issue #586 gets implemented, could have a postcondition
// saying the two result lists have the same length -- or, could
// return a nominal record with a constraint saying that, instead of
// returning a tuple (contingent on issue #869)
/*
Function: unzip
Convert a vector of pairs into a pair of vectors
Returns a tuple containing two vectors where the i-th element of the first
vector contains the first element of the i-th tuple of the input vector,
and the i-th element of the second vector contains the second element
of the i-th tuple of the input vector.
*/
fn unzip<T: copy, U: copy>(v: [const (T, U)]) -> ([T], [U]) {
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let mut as = [], bs = [];
for (a, b) in v { as += [a]; bs += [b]; }
ret (as, bs);
}
/*
Function: zip
Convert two vectors to a vector of pairs
Returns a vector of tuples, where the i-th tuple contains contains the
i-th elements from each of the input vectors.
Preconditions:
<same_length> (v, u)
*/
fn zip<T: copy, U: copy>(v: [const T], u: [const U]) -> [(T, U)] {
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let mut zipped = [];
let sz = len(v);
let mut i = 0u;
assert sz == len(u);
while i < sz { zipped += [(v[i], u[i])]; i += 1u; }
ret zipped;
}
/*
Function: swap
Swaps two elements in a vector
Parameters:
v - The input vector
a - The index of the first element
b - The index of the second element
*/
fn swap<T>(v: [mutable T], a: uint, b: uint) {
v[a] <-> v[b];
}
/*
Function: reverse
Reverse the order of elements in a vector, in place
*/
fn reverse<T>(v: [mutable T]) {
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let mut i: uint = 0u;
let ln = len::<T>(v);
while i < ln / 2u { v[i] <-> v[ln - i - 1u]; i += 1u; }
}
/*
Function: reversed
Returns a vector with the order of elements reversed
*/
fn reversed<T: copy>(v: [const T]) -> [T] {
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let mut rs: [T] = [];
let mut i = len::<T>(v);
if i == 0u { ret rs; } else { i -= 1u; }
while i != 0u { rs += [v[i]]; i -= 1u; }
rs += [v[0]];
ret rs;
}
// FIXME: Seems like this should take char params. Maybe belongs in char
/*
Function: enum_chars
Returns a vector containing a range of chars
*/
fn enum_chars(start: u8, end: u8) -> [char] {
assert start < end;
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let mut i = start;
let mut r = [];
while i <= end { r += [i as char]; i += 1u as u8; }
ret r;
}
// FIXME: Probably belongs in uint. Compare to uint::range
/*
Function: enum_uints
Returns a vector containing a range of uints
*/
fn enum_uints(start: uint, end: uint) -> [uint] {
assert start < end;
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let mut i = start;
let mut r = [];
while i <= end { r += [i]; i += 1u; }
ret r;
}
/*
Function: iter
Iterates over a vector
Iterates over vector `v` and, for each element, calls function `f` with the
element's value.
*/
#[inline(always)]
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fn iter<T>(v: [const T], f: fn(T)) {
unsafe {
let mut n = vec::len(v);
let mut p = unsafe::to_ptr(v);
while n > 0u {
f(*p);
p = ptr::offset(p, 1u);
n -= 1u;
}
}
}
/*
Function: iter2
Iterates over two vectors in parallel
*/
#[inline]
fn iter2<U, T>(v: [ U], v2: [const T], f: fn(U, T)) {
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let mut i = 0;
for elt in v { f(elt, v2[i]); i += 1; }
}
/*
Function: iteri
Iterates over a vector's elements and indexes
Iterates over vector `v` and, for each element, calls function `f` with the
element's value and index.
*/
#[inline(always)]
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fn iteri<T>(v: [const T], f: fn(uint, T)) {
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let mut i = 0u;
let l = len(v);
while i < l { f(i, v[i]); i += 1u; }
}
/*
Function: riter
Iterates over a vector in reverse
Iterates over vector `v` and, for each element, calls function `f` with the
element's value.
*/
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fn riter<T>(v: [const T], f: fn(T)) {
riteri(v) { |_i, v| f(v) }
}
/*
Function: riteri
Iterates over a vector's elements and indexes in reverse
Iterates over vector `v` and, for each element, calls function `f` with the
element's value and index.
*/
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fn riteri<T>(v: [const T], f: fn(uint, T)) {
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let mut i = len(v);
while 0u < i {
i -= 1u;
f(i, v[i]);
};
}
/*
Function: permute
Iterate over all permutations of vector `v`. Permutations are produced in
lexicographic order with respect to the order of elements in `v` (so if `v`
is sorted then the permutations are lexicographically sorted).
The total number of permutations produced is `len(v)!`. If `v` contains
repeated elements, then some permutations are repeated.
*/
fn permute<T: copy>(v: [T], put: fn([T])) {
let ln = len(v);
if ln == 0u {
put([]);
} else {
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let mut i = 0u;
while i < ln {
let elt = v[i];
let rest = slice(v, 0u, i) + slice(v, i+1u, ln);
permute(rest) {|permutation| put([elt] + permutation)}
i += 1u;
}
}
}
fn windowed <TT: copy> (nn: uint, xx: [const TT]) -> [[TT]] {
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let mut ww = [];
assert 1u <= nn;
vec::iteri (xx, {|ii, _x|
let len = vec::len(xx);
if ii+nn <= len {
let w = vec::slice ( xx, ii, ii+nn );
vec::push (ww, w);
}
});
ret ww;
}
/*
Function: as_buf
Work with the buffer of a vector. Allows for unsafe manipulation
of vector contents, which is useful for native interop.
*/
fn as_buf<E,T>(v: [const E], f: fn(*E) -> T) -> T unsafe {
let buf = unsafe::to_ptr(v); f(buf)
}
fn as_mut_buf<E,T>(v: [mutable E], f: fn(*mutable E) -> T) -> T unsafe {
let buf = unsafe::to_ptr(v) as *mutable E; f(buf)
}
impl vec_len<T> for [T] {
#[inline(always)]
fn len() -> uint { len(self) }
}
/*
Module: unsafe
*/
mod unsafe {
type vec_repr = {mutable fill: uint, mutable alloc: uint, data: u8};
/*
Function: from_buf
Constructs a vector from an unsafe pointer to a buffer
Parameters:
ptr - An unsafe pointer to a buffer of `T`
elts - The number of elements in the buffer
*/
#[inline(always)]
unsafe fn from_buf<T>(ptr: *T, elts: uint) -> [T] {
ret rustrt::vec_from_buf_shared(sys::get_type_desc::<T>(),
ptr, elts);
}
/*
Function: set_len
Sets the length of a vector
This well explicitly set the size of the vector, without actually
modifing its buffers, so it is up to the caller to ensure that
the vector is actually the specified size.
*/
#[inline(always)]
unsafe fn set_len<T>(&v: [const T], new_len: uint) {
let repr: **vec_repr = ::unsafe::reinterpret_cast(addr_of(v));
(**repr).fill = new_len * sys::size_of::<T>();
}
/*
Function: to_ptr
Returns an unsafe pointer to the vector's buffer
The caller must ensure that the vector outlives the pointer this
function returns, or else it will end up pointing to garbage.
Modifying the vector may cause its buffer to be reallocated, which
would also make any pointers to it invalid.
*/
#[inline(always)]
unsafe fn to_ptr<T>(v: [const T]) -> *T {
let repr: **vec_repr = ::unsafe::reinterpret_cast(addr_of(v));
ret ::unsafe::reinterpret_cast(addr_of((**repr).data));
}
}
/*
Module: u8
*/
mod u8 {
export cmp;
export lt, le, eq, ne, ge, gt;
export hash;
/*
Function cmp
Bytewise string comparison
*/
pure fn cmp(&&a: [u8], &&b: [u8]) -> int unsafe {
let a_len = len(a);
let b_len = len(b);
let n = math::min(a_len, b_len) as ctypes::size_t;
let r = libc::memcmp(unsafe::to_ptr(a) as *libc::c_void,
unsafe::to_ptr(b) as *libc::c_void, n) as int;
if r != 0 { r } else {
if a_len == b_len {
0
} else if a_len < b_len {
-1
} else {
1
}
}
}
/*
Function: lt
Bytewise less than or equal
*/
pure fn lt(&&a: [u8], &&b: [u8]) -> bool { cmp(a, b) < 0 }
/*
Function: le
Bytewise less than or equal
*/
pure fn le(&&a: [u8], &&b: [u8]) -> bool { cmp(a, b) <= 0 }
/*
Function: eq
Bytewise equality
*/
pure fn eq(&&a: [u8], &&b: [u8]) -> bool unsafe { cmp(a, b) == 0 }
/*
Function: ne
Bytewise inequality
*/
pure fn ne(&&a: [u8], &&b: [u8]) -> bool unsafe { cmp(a, b) != 0 }
/*
Function: ge
Bytewise greater than or equal
*/
pure fn ge(&&a: [u8], &&b: [u8]) -> bool { cmp(a, b) >= 0 }
/*
Function: gt
Bytewise greater than
*/
pure fn gt(&&a: [u8], &&b: [u8]) -> bool { cmp(a, b) > 0 }
/*
Function: hash
String hash function
*/
fn hash(&&s: [u8]) -> uint {
// djb hash.
// FIXME: replace with murmur.
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let mut u: uint = 5381u;
vec::iter(s, { |c| u *= 33u; u += c as uint; });
ret u;
}
}
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#[cfg(test)]
mod tests {
fn square(n: uint) -> uint { ret n * n; }
fn square_ref(&&n: uint) -> uint { ret n * n; }
pure fn is_three(&&n: uint) -> bool { ret n == 3u; }
pure fn is_odd(&&n: uint) -> bool { ret n % 2u == 1u; }
pure fn is_equal(&&x: uint, &&y:uint) -> bool { ret x == y; }
fn square_if_odd(&&n: uint) -> option<uint> {
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ret if n % 2u == 1u { some(n * n) } else { none };
}
fn add(&&x: uint, &&y: uint) -> uint { ret x + y; }
#[test]
fn test_unsafe_ptrs() unsafe {
// Test on-stack copy-from-buf.
let a = [1, 2, 3];
let ptr = unsafe::to_ptr(a);
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let b = unsafe::from_buf(ptr, 3u);
assert (len(b) == 3u);
assert (b[0] == 1);
assert (b[1] == 2);
assert (b[2] == 3);
// Test on-heap copy-from-buf.
let c = [1, 2, 3, 4, 5];
ptr = unsafe::to_ptr(c);
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let d = unsafe::from_buf(ptr, 5u);
assert (len(d) == 5u);
assert (d[0] == 1);
assert (d[1] == 2);
assert (d[2] == 3);
assert (d[3] == 4);
assert (d[4] == 5);
}
#[test]
fn test_init_fn() {
// Test on-stack init_fn.
let v = init_fn(3u, square);
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assert (len(v) == 3u);
assert (v[0] == 0u);
assert (v[1] == 1u);
assert (v[2] == 4u);
// Test on-heap init_fn.
v = init_fn(5u, square);
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assert (len(v) == 5u);
assert (v[0] == 0u);
assert (v[1] == 1u);
assert (v[2] == 4u);
assert (v[3] == 9u);
assert (v[4] == 16u);
}
#[test]
fn test_init_elt() {
// Test on-stack init_elt.
let v = init_elt(2u, 10u);
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assert (len(v) == 2u);
assert (v[0] == 10u);
assert (v[1] == 10u);
// Test on-heap init_elt.
v = init_elt(6u, 20u);
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assert (v[0] == 20u);
assert (v[1] == 20u);
assert (v[2] == 20u);
assert (v[3] == 20u);
assert (v[4] == 20u);
assert (v[5] == 20u);
}
#[test]
fn test_is_empty() {
assert (is_empty::<int>([]));
assert (!is_empty([0]));
}
#[test]
fn test_is_not_empty() {
assert (is_not_empty([0]));
assert (!is_not_empty::<int>([]));
}
#[test]
fn test_head() {
let a = [11, 12];
assert (head(a) == 11);
}
#[test]
fn test_tail() {
let a = [11];
assert (tail(a) == []);
a = [11, 12];
assert (tail(a) == [12]);
}
#[test]
fn test_last() {
let n = last_opt([]);
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assert (n == none);
n = last_opt([1, 2, 3]);
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assert (n == some(3));
n = last_opt([1, 2, 3, 4, 5]);
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assert (n == some(5));
}
#[test]
fn test_slice() {
// Test on-stack -> on-stack slice.
let v = slice([1, 2, 3], 1u, 3u);
assert (len(v) == 2u);
assert (v[0] == 2);
assert (v[1] == 3);
// Test on-heap -> on-stack slice.
v = slice([1, 2, 3, 4, 5], 0u, 3u);
assert (len(v) == 3u);
assert (v[0] == 1);
assert (v[1] == 2);
assert (v[2] == 3);
// Test on-heap -> on-heap slice.
v = slice([1, 2, 3, 4, 5, 6], 1u, 6u);
assert (len(v) == 5u);
assert (v[0] == 2);
assert (v[1] == 3);
assert (v[2] == 4);
assert (v[3] == 5);
assert (v[4] == 6);
}
#[test]
fn test_pop() {
// Test on-stack pop.
let v = [1, 2, 3];
let e = pop(v);
assert (len(v) == 2u);
assert (v[0] == 1);
assert (v[1] == 2);
assert (e == 3);
// Test on-heap pop.
v = [1, 2, 3, 4, 5];
e = pop(v);
assert (len(v) == 4u);
assert (v[0] == 1);
assert (v[1] == 2);
assert (v[2] == 3);
assert (v[3] == 4);
assert (e == 5);
}
#[test]
fn test_push() {
// Test on-stack push().
let v = [];
push(v, 1);
assert (len(v) == 1u);
assert (v[0] == 1);
// Test on-heap push().
push(v, 2);
assert (len(v) == 2u);
assert (v[0] == 1);
assert (v[1] == 2);
}
#[test]
fn test_grow() {
// Test on-stack grow().
let v = [];
grow(v, 2u, 1);
assert (len(v) == 2u);
assert (v[0] == 1);
assert (v[1] == 1);
// Test on-heap grow().
grow(v, 3u, 2);
assert (len(v) == 5u);
assert (v[0] == 1);
assert (v[1] == 1);
assert (v[2] == 2);
assert (v[3] == 2);
assert (v[4] == 2);
}
#[test]
fn test_grow_fn() {
let v = [];
grow_fn(v, 3u, square);
assert (len(v) == 3u);
assert (v[0] == 0u);
assert (v[1] == 1u);
assert (v[2] == 4u);
}
#[test]
fn test_grow_set() {
let v = [mutable 1, 2, 3];
grow_set(v, 4u, 4, 5);
assert (len(v) == 5u);
assert (v[0] == 1);
assert (v[1] == 2);
assert (v[2] == 3);
assert (v[3] == 4);
assert (v[4] == 5);
}
#[test]
fn test_map() {
// Test on-stack map.
let v = [1u, 2u, 3u];
let w = map(v, square_ref);
assert (len(w) == 3u);
assert (w[0] == 1u);
assert (w[1] == 4u);
assert (w[2] == 9u);
// Test on-heap map.
v = [1u, 2u, 3u, 4u, 5u];
w = map(v, square_ref);
assert (len(w) == 5u);
assert (w[0] == 1u);
assert (w[1] == 4u);
assert (w[2] == 9u);
assert (w[3] == 16u);
assert (w[4] == 25u);
}
#[test]
fn test_map2() {
fn times(&&x: int, &&y: int) -> int { ret x * y; }
let f = times;
let v0 = [1, 2, 3, 4, 5];
let v1 = [5, 4, 3, 2, 1];
let u = map2::<int, int, int>(v0, v1, f);
let i = 0;
while i < 5 { assert (v0[i] * v1[i] == u[i]); i += 1; }
}
#[test]
fn test_filter_map() {
// Test on-stack filter-map.
let v = [1u, 2u, 3u];
let w = filter_map(v, square_if_odd);
assert (len(w) == 2u);
assert (w[0] == 1u);
assert (w[1] == 9u);
// Test on-heap filter-map.
v = [1u, 2u, 3u, 4u, 5u];
w = filter_map(v, square_if_odd);
assert (len(w) == 3u);
assert (w[0] == 1u);
assert (w[1] == 9u);
assert (w[2] == 25u);
fn halve(&&i: int) -> option<int> {
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if i % 2 == 0 {
ret option::some::<int>(i / 2);
} else { ret option::none::<int>; }
}
fn halve_for_sure(&&i: int) -> int { ret i / 2; }
let all_even: [int] = [0, 2, 8, 6];
let all_odd1: [int] = [1, 7, 3];
let all_odd2: [int] = [];
let mix: [int] = [9, 2, 6, 7, 1, 0, 0, 3];
let mix_dest: [int] = [1, 3, 0, 0];
assert (filter_map(all_even, halve) == map(all_even, halve_for_sure));
assert (filter_map(all_odd1, halve) == []);
assert (filter_map(all_odd2, halve) == []);
assert (filter_map(mix, halve) == mix_dest);
}
#[test]
fn test_filter() {
assert filter([1u, 2u, 3u], is_odd) == [1u, 3u];
assert filter([1u, 2u, 4u, 8u, 16u], is_three) == [];
}
#[test]
fn test_foldl() {
// Test on-stack fold.
let v = [1u, 2u, 3u];
let sum = foldl(0u, v, add);
assert (sum == 6u);
// Test on-heap fold.
v = [1u, 2u, 3u, 4u, 5u];
sum = foldl(0u, v, add);
assert (sum == 15u);
}
#[test]
fn test_foldl2() {
fn sub(&&a: int, &&b: int) -> int {
a - b
}
let v = [1, 2, 3, 4];
let sum = foldl(0, v, sub);
assert sum == -10;
}
#[test]
fn test_foldr() {
fn sub(&&a: int, &&b: int) -> int {
a - b
}
let v = [1, 2, 3, 4];
let sum = foldr(v, 0, sub);
assert sum == -2;
}
#[test]
fn test_iter_empty() {
let i = 0;
iter::<int>([], { |_v| i += 1 });
assert i == 0;
}
#[test]
fn test_iter_nonempty() {
let i = 0;
iter([1, 2, 3], { |v| i += v });
assert i == 6;
}
#[test]
fn test_iteri() {
let i = 0;
iteri([1, 2, 3], { |j, v|
if i == 0 { assert v == 1; }
assert j + 1u == v as uint;
i += v;
});
assert i == 6;
}
#[test]
fn test_riter_empty() {
let i = 0;
riter::<int>([], { |_v| i += 1 });
assert i == 0;
}
#[test]
fn test_riter_nonempty() {
let i = 0;
riter([1, 2, 3], { |v|
if i == 0 { assert v == 3; }
i += v
});
assert i == 6;
}
#[test]
fn test_riteri() {
let i = 0;
riteri([0, 1, 2], { |j, v|
if i == 0 { assert v == 2; }
assert j == v as uint;
i += v;
});
assert i == 3;
}
#[test]
fn test_permute() {
let results: [[int]];
results = [];
permute([]) {|v| results += [v]; }
assert results == [[]];
results = [];
permute([7]) {|v| results += [v]; }
assert results == [[7]];
results = [];
permute([1,1]) {|v| results += [v]; }
assert results == [[1,1],[1,1]];
results = [];
permute([5,2,0]) {|v| results += [v]; }
assert results == [[5,2,0],[5,0,2],[2,5,0],[2,0,5],[0,5,2],[0,2,5]];
}
#[test]
fn test_any_and_all() {
assert (any([1u, 2u, 3u], is_three));
assert (!any([0u, 1u, 2u], is_three));
assert (any([1u, 2u, 3u, 4u, 5u], is_three));
assert (!any([1u, 2u, 4u, 5u, 6u], is_three));
assert (all([3u, 3u, 3u], is_three));
assert (!all([3u, 3u, 2u], is_three));
assert (all([3u, 3u, 3u, 3u, 3u], is_three));
assert (!all([3u, 3u, 0u, 1u, 2u], is_three));
}
#[test]
fn test_any2_and_all2() {
assert (any2([2u, 4u, 6u], [2u, 4u, 6u], is_equal));
assert (any2([1u, 2u, 3u], [4u, 5u, 3u], is_equal));
assert (!any2([1u, 2u, 3u], [4u, 5u, 6u], is_equal));
assert (any2([2u, 4u, 6u], [2u, 4u], is_equal));
assert (all2([2u, 4u, 6u], [2u, 4u, 6u], is_equal));
assert (!all2([1u, 2u, 3u], [4u, 5u, 3u], is_equal));
assert (!all2([1u, 2u, 3u], [4u, 5u, 6u], is_equal));
assert (!all2([2u, 4u, 6u], [2u, 4u], is_equal));
}
#[test]
fn test_zip_unzip() {
let v1 = [1, 2, 3];
let v2 = [4, 5, 6];
let z1 = zip(v1, v2);
assert ((1, 4) == z1[0]);
assert ((2, 5) == z1[1]);
assert ((3, 6) == z1[2]);
let (left, right) = unzip(z1);
assert ((1, 4) == (left[0], right[0]));
assert ((2, 5) == (left[1], right[1]));
assert ((3, 6) == (left[2], right[2]));
}
#[test]
fn test_position_elt() {
assert position_elt([], 1) == none;
let v1 = [1, 2, 3, 3, 2, 5];
assert position_elt(v1, 1) == some(0u);
assert position_elt(v1, 2) == some(1u);
assert position_elt(v1, 5) == some(5u);
assert position_elt(v1, 4) == none;
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}
#[test]
fn test_position() {
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fn less_than_three(&&i: int) -> bool { ret i < 3; }
fn is_eighteen(&&i: int) -> bool { ret i == 18; }
assert position([], less_than_three) == none;
let v1 = [5, 4, 3, 2, 1];
assert position(v1, less_than_three) == some(3u);
assert position(v1, is_eighteen) == none;
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}
#[test]
fn test_position_from() {
assert position_from([], 0u, 0u, f) == none;
fn f(xy: (int, char)) -> bool { let (_x, y) = xy; y == 'b' }
let v = [(0, 'a'), (1, 'b'), (2, 'c'), (3, 'b')];
assert position_from(v, 0u, 0u, f) == none;
assert position_from(v, 0u, 1u, f) == none;
assert position_from(v, 0u, 2u, f) == some(1u);
assert position_from(v, 0u, 3u, f) == some(1u);
assert position_from(v, 0u, 4u, f) == some(1u);
assert position_from(v, 1u, 1u, f) == none;
assert position_from(v, 1u, 2u, f) == some(1u);
assert position_from(v, 1u, 3u, f) == some(1u);
assert position_from(v, 1u, 4u, f) == some(1u);
assert position_from(v, 2u, 2u, f) == none;
assert position_from(v, 2u, 3u, f) == none;
assert position_from(v, 2u, 4u, f) == some(3u);
assert position_from(v, 3u, 3u, f) == none;
assert position_from(v, 3u, 4u, f) == some(3u);
assert position_from(v, 4u, 4u, f) == none;
}
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#[test]
fn test_find() {
assert find([], f) == none;
fn f(xy: (int, char)) -> bool { let (_x, y) = xy; y == 'b' }
fn g(xy: (int, char)) -> bool { let (_x, y) = xy; y == 'd' }
let v = [(0, 'a'), (1, 'b'), (2, 'c'), (3, 'b')];
assert find(v, f) == some((1, 'b'));
assert find(v, g) == none;
}
#[test]
fn test_find_from() {
assert find_from([], 0u, 0u, f) == none;
fn f(xy: (int, char)) -> bool { let (_x, y) = xy; y == 'b' }
let v = [(0, 'a'), (1, 'b'), (2, 'c'), (3, 'b')];
assert find_from(v, 0u, 0u, f) == none;
assert find_from(v, 0u, 1u, f) == none;
assert find_from(v, 0u, 2u, f) == some((1, 'b'));
assert find_from(v, 0u, 3u, f) == some((1, 'b'));
assert find_from(v, 0u, 4u, f) == some((1, 'b'));
assert find_from(v, 1u, 1u, f) == none;
assert find_from(v, 1u, 2u, f) == some((1, 'b'));
assert find_from(v, 1u, 3u, f) == some((1, 'b'));
assert find_from(v, 1u, 4u, f) == some((1, 'b'));
assert find_from(v, 2u, 2u, f) == none;
assert find_from(v, 2u, 3u, f) == none;
assert find_from(v, 2u, 4u, f) == some((3, 'b'));
assert find_from(v, 3u, 3u, f) == none;
assert find_from(v, 3u, 4u, f) == some((3, 'b'));
assert find_from(v, 4u, 4u, f) == none;
}
#[test]
fn test_rposition() {
assert find([], f) == none;
fn f(xy: (int, char)) -> bool { let (_x, y) = xy; y == 'b' }
fn g(xy: (int, char)) -> bool { let (_x, y) = xy; y == 'd' }
let v = [(0, 'a'), (1, 'b'), (2, 'c'), (3, 'b')];
assert position(v, f) == some(1u);
assert position(v, g) == none;
}
#[test]
fn test_rposition_from() {
assert rposition_from([], 0u, 0u, f) == none;
fn f(xy: (int, char)) -> bool { let (_x, y) = xy; y == 'b' }
let v = [(0, 'a'), (1, 'b'), (2, 'c'), (3, 'b')];
assert rposition_from(v, 0u, 0u, f) == none;
assert rposition_from(v, 0u, 1u, f) == none;
assert rposition_from(v, 0u, 2u, f) == some(1u);
assert rposition_from(v, 0u, 3u, f) == some(1u);
assert rposition_from(v, 0u, 4u, f) == some(3u);
assert rposition_from(v, 1u, 1u, f) == none;
assert rposition_from(v, 1u, 2u, f) == some(1u);
assert rposition_from(v, 1u, 3u, f) == some(1u);
assert rposition_from(v, 1u, 4u, f) == some(3u);
assert rposition_from(v, 2u, 2u, f) == none;
assert rposition_from(v, 2u, 3u, f) == none;
assert rposition_from(v, 2u, 4u, f) == some(3u);
assert rposition_from(v, 3u, 3u, f) == none;
assert rposition_from(v, 3u, 4u, f) == some(3u);
assert rposition_from(v, 4u, 4u, f) == none;
}
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#[test]
fn test_rfind() {
assert rfind([], f) == none;
fn f(xy: (int, char)) -> bool { let (_x, y) = xy; y == 'b' }
fn g(xy: (int, char)) -> bool { let (_x, y) = xy; y == 'd' }
let v = [(0, 'a'), (1, 'b'), (2, 'c'), (3, 'b')];
assert rfind(v, f) == some((3, 'b'));
assert rfind(v, g) == none;
}
#[test]
fn test_rfind_from() {
assert rfind_from([], 0u, 0u, f) == none;
fn f(xy: (int, char)) -> bool { let (_x, y) = xy; y == 'b' }
let v = [(0, 'a'), (1, 'b'), (2, 'c'), (3, 'b')];
assert rfind_from(v, 0u, 0u, f) == none;
assert rfind_from(v, 0u, 1u, f) == none;
assert rfind_from(v, 0u, 2u, f) == some((1, 'b'));
assert rfind_from(v, 0u, 3u, f) == some((1, 'b'));
assert rfind_from(v, 0u, 4u, f) == some((3, 'b'));
assert rfind_from(v, 1u, 1u, f) == none;
assert rfind_from(v, 1u, 2u, f) == some((1, 'b'));
assert rfind_from(v, 1u, 3u, f) == some((1, 'b'));
assert rfind_from(v, 1u, 4u, f) == some((3, 'b'));
assert rfind_from(v, 2u, 2u, f) == none;
assert rfind_from(v, 2u, 3u, f) == none;
assert rfind_from(v, 2u, 4u, f) == some((3, 'b'));
assert rfind_from(v, 3u, 3u, f) == none;
assert rfind_from(v, 3u, 4u, f) == some((3, 'b'));
assert rfind_from(v, 4u, 4u, f) == none;
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}
#[test]
fn reverse_and_reversed() {
let v: [mutable int] = [mutable 10, 20];
assert (v[0] == 10);
assert (v[1] == 20);
reverse(v);
assert (v[0] == 20);
assert (v[1] == 10);
let v2 = reversed::<int>([10, 20]);
assert (v2[0] == 20);
assert (v2[1] == 10);
v[0] = 30;
assert (v2[0] == 20);
// Make sure they work with 0-length vectors too.
let v4 = reversed::<int>([]);
assert (v4 == []);
let v3: [mutable int] = [mutable];
reverse::<int>(v3);
}
#[test]
fn reversed_mut() {
let v2 = reversed::<int>([mutable 10, 20]);
assert (v2[0] == 20);
assert (v2[1] == 10);
}
#[test]
fn test_init() {
let v = init([1, 2, 3]);
assert v == [1, 2];
}
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#[test]
fn test_split() {
fn f(&&x: int) -> bool { x == 3 }
assert split([], f) == [];
assert split([1, 2], f) == [[1, 2]];
assert split([3, 1, 2], f) == [[], [1, 2]];
assert split([1, 2, 3], f) == [[1, 2], []];
assert split([1, 2, 3, 4, 3, 5], f) == [[1, 2], [4], [5]];
}
#[test]
fn test_splitn() {
fn f(&&x: int) -> bool { x == 3 }
assert splitn([], 1u, f) == [];
assert splitn([1, 2], 1u, f) == [[1, 2]];
assert splitn([3, 1, 2], 1u, f) == [[], [1, 2]];
assert splitn([1, 2, 3], 1u, f) == [[1, 2], []];
assert splitn([1, 2, 3, 4, 3, 5], 1u, f) == [[1, 2], [4, 3, 5]];
}
#[test]
fn test_rsplit() {
fn f(&&x: int) -> bool { x == 3 }
assert rsplit([], f) == [];
assert rsplit([1, 2], f) == [[1, 2]];
assert rsplit([1, 2, 3], f) == [[1, 2], []];
assert rsplit([1, 2, 3, 4, 3, 5], f) == [[1, 2], [4], [5]];
}
#[test]
fn test_rsplitn() {
fn f(&&x: int) -> bool { x == 3 }
assert rsplitn([], 1u, f) == [];
assert rsplitn([1, 2], 1u, f) == [[1, 2]];
assert rsplitn([1, 2, 3], 1u, f) == [[1, 2], []];
assert rsplitn([1, 2, 3, 4, 3, 5], 1u, f) == [[1, 2, 3, 4], [5]];
}
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#[test]
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#[should_fail]
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#[ignore(cfg(target_os = "win32"))]
fn test_init_empty() {
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init::<int>([]);
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}
#[test]
fn test_concat() {
assert concat([[1], [2,3]]) == [1, 2, 3];
}
#[test]
fn test_connect() {
assert connect([], 0) == [];
assert connect([[1], [2, 3]], 0) == [1, 0, 2, 3];
assert connect([[1], [2], [3]], 0) == [1, 0, 2, 0, 3];
}
#[test]
fn test_windowed () {
assert [[1u,2u,3u],[2u,3u,4u],[3u,4u,5u],[4u,5u,6u]]
== windowed (3u, [1u,2u,3u,4u,5u,6u]);
assert [[1u,2u,3u,4u],[2u,3u,4u,5u],[3u,4u,5u,6u]]
== windowed (4u, [1u,2u,3u,4u,5u,6u]);
assert [] == windowed (7u, [1u,2u,3u,4u,5u,6u]);
}
#[test]
#[should_fail]
#[ignore(cfg(target_os = "win32"))]
fn test_windowed_() {
let _x = windowed (0u, [1u,2u,3u,4u,5u,6u]);
}
#[test]
fn to_mut_no_copy() unsafe {
let x = [1, 2, 3];
let addr = unsafe::to_ptr(x);
let x_mut = to_mut(x);
let addr_mut = unsafe::to_ptr(x_mut);
assert addr == addr_mut;
}
#[test]
fn from_mut_no_copy() unsafe {
let x = [mut 1, 2, 3];
let addr = unsafe::to_ptr(x);
let x_imm = from_mut(x);
let addr_imm = unsafe::to_ptr(x_imm);
assert addr == addr_imm;
}
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}
// Local Variables:
// mode: rust;
// fill-column: 78;
// indent-tabs-mode: nil
// c-basic-offset: 4
// buffer-file-coding-system: utf-8-unix
// End: