518dc52f85
This changes the indexing syntax from .() to [], the vector syntax from ~[] to [] and the extension syntax from #fmt() to #fmt[]
349 lines
8.8 KiB
Rust
349 lines
8.8 KiB
Rust
// Interior vector utility functions.
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import option::none;
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import option::some;
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import uint::next_power_of_two;
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import ptr::addr_of;
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native "rust-intrinsic" mod rusti {
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fn ivec_len<T>(v: &[T]) -> uint;
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}
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native "rust" mod rustrt {
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fn ivec_reserve_shared<T>(v: &mutable [mutable? T], n: uint);
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fn ivec_on_heap<T>(v: &[T]) -> uint;
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fn ivec_to_ptr<T>(v: &[T]) -> *T;
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fn ivec_copy_from_buf_shared<T>(v: &mutable [mutable? T], ptr: *T,
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count: uint);
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}
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/// Reserves space for `n` elements in the given vector.
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fn reserve<@T>(v: &mutable [mutable? T], n: uint) {
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rustrt::ivec_reserve_shared(v, n);
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}
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fn on_heap<T>(v: &[T]) -> bool { ret rustrt::ivec_on_heap(v) != 0u; }
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fn to_ptr<T>(v: &[T]) -> *T { ret rustrt::ivec_to_ptr(v); }
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fn len<T>(v: &[mutable? T]) -> uint { ret rusti::ivec_len(v); }
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type init_op<T> = fn(uint) -> T;
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fn init_fn<@T>(op: &init_op<T>, n_elts: uint) -> [T] {
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let v = [];
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reserve(v, n_elts);
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let i: uint = 0u;
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while i < n_elts { v += [op(i)]; i += 1u; }
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ret v;
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}
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// TODO: Remove me once we have slots.
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fn init_fn_mut<@T>(op: &init_op<T>, n_elts: uint) -> [mutable T] {
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let v = [mutable];
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reserve(v, n_elts);
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let i: uint = 0u;
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while i < n_elts { v += [mutable op(i)]; i += 1u; }
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ret v;
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}
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fn init_elt<@T>(t: &T, n_elts: uint) -> [T] {
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let v = [];
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reserve(v, n_elts);
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let i: uint = 0u;
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while i < n_elts { v += [t]; i += 1u; }
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ret v;
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}
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// TODO: Remove me once we have slots.
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fn init_elt_mut<@T>(t: &T, n_elts: uint) -> [mutable T] {
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let v = [mutable];
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reserve(v, n_elts);
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let i: uint = 0u;
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while i < n_elts { v += [mutable t]; i += 1u; }
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ret v;
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}
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fn to_mut<@T>(v: &[T]) -> [mutable T] {
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let vres = [mutable];
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for t: T in v { vres += [mutable t]; }
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ret vres;
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}
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fn from_mut<@T>(v: &[mutable T]) -> [T] {
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let vres = [];
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for t: T in v { vres += [t]; }
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ret vres;
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}
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// Predicates
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pred is_empty<T>(v: &[mutable? T]) -> bool {
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// FIXME: This would be easier if we could just call len
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for t: T in v { ret false; }
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ret true;
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}
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pred is_not_empty<T>(v: &[mutable? T]) -> bool { ret !is_empty(v); }
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// Accessors
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/// Returns the first element of a vector
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fn head<@T>(v: &[mutable? T]) : is_not_empty(v) -> T { ret v[0]; }
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/// Returns all but the first element of a vector
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fn tail<@T>(v: &[mutable? T]) : is_not_empty(v) -> [mutable? T] {
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ret slice(v, 1u, len(v));
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}
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/// Returns the last element of `v`.
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fn last<@T>(v: &[mutable? T]) -> option::t<T> {
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if len(v) == 0u { ret none; }
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ret some(v[len(v) - 1u]);
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}
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/// Returns a copy of the elements from [`start`..`end`) from `v`.
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fn slice<@T>(v: &[mutable? T], start: uint, end: uint) -> [T] {
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assert (start <= end);
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assert (end <= len(v));
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let result = [];
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reserve(result, end - start);
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let i = start;
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while i < end { result += [v[i]]; i += 1u; }
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ret result;
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}
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// TODO: Remove me once we have slots.
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fn slice_mut<@T>(v: &[mutable? T], start: uint, end: uint) -> [mutable T] {
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assert (start <= end);
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assert (end <= len(v));
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let result = [mutable];
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reserve(result, end - start);
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let i = start;
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while i < end { result += [mutable v[i]]; i += 1u; }
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ret result;
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}
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// Mutators
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fn shift<@T>(v: &mutable [mutable? T]) -> T {
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let ln = len::<T>(v);
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assert (ln > 0u);
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let e = v[0];
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v = slice::<T>(v, 1u, ln);
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ret e;
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}
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// TODO: Write this, unsafely, in a way that's not O(n).
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fn pop<@T>(v: &mutable [mutable? T]) -> T {
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let ln = len(v);
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assert (ln > 0u);
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ln -= 1u;
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let e = v[ln];
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v = slice(v, 0u, ln);
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ret e;
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}
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// TODO: More.
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// Appending
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/// Expands the given vector in-place by appending `n` copies of `initval`.
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fn grow<@T>(v: &mutable [T], n: uint, initval: &T) {
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reserve(v, next_power_of_two(len(v) + n));
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let i: uint = 0u;
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while i < n { v += [initval]; i += 1u; }
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}
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// TODO: Remove me once we have slots.
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fn grow_mut<@T>(v: &mutable [mutable T], n: uint, initval: &T) {
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reserve(v, next_power_of_two(len(v) + n));
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let i: uint = 0u;
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while i < n { v += [mutable initval]; i += 1u; }
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}
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/// Calls `f` `n` times and appends the results of these calls to the given
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/// vector.
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fn grow_fn<@T>(v: &mutable [T], n: uint, init_fn: fn(uint) -> T) {
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reserve(v, next_power_of_two(len(v) + n));
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let i: uint = 0u;
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while i < n { v += [init_fn(i)]; i += 1u; }
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}
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/// Sets the element at position `index` to `val`. If `index` is past the end
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/// of the vector, expands the vector by replicating `initval` to fill the
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/// intervening space.
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fn grow_set<@T>(v: &mutable [mutable T], index: uint, initval: &T, val: &T) {
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if index >= len(v) { grow_mut(v, index - len(v) + 1u, initval); }
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v[index] = val;
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}
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// Functional utilities
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fn map<@T, @U>(f: &block(&T) -> U, v: &[mutable? T]) -> [U] {
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let result = [];
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reserve(result, len(v));
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for elem: T in v {
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let elem2 = elem; // satisfies alias checker
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result += [f(elem2)];
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}
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ret result;
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}
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fn map2<@T, @U, @V>(f: &block(&T, &U) -> V, v0: &[T], v1: &[U]) -> [V] {
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let v0_len = len::<T>(v0);
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if v0_len != len::<U>(v1) { fail; }
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let u: [V] = [];
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let i = 0u;
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while i < v0_len { u += [f({ v0[i] }, { v1[i] })]; i += 1u; }
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ret u;
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}
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fn filter_map<@T, @U>(f: &block(&T) -> option::t<U>, v: &[mutable? T]) ->
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[U] {
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let result = [];
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for elem: T in v {
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let elem2 = elem; // satisfies alias checker
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alt f(elem2) {
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none. {/* no-op */ }
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some(result_elem) { result += [result_elem]; }
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}
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}
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ret result;
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}
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fn foldl<@T, @U>(p: &block(&U, &T) -> U, z: &U, v: &[mutable? T]) -> U {
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let sz = len(v);
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if sz == 0u { ret z; }
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let first = v[0];
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let rest = slice(v, 1u, sz);
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ret p(foldl(p, z, rest), first);
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}
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fn any<T>(f: &block(&T) -> bool, v: &[T]) -> bool {
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for elem: T in v { if f(elem) { ret true; } }
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ret false;
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}
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fn all<T>(f: &block(&T) -> bool, v: &[T]) -> bool {
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for elem: T in v { if !f(elem) { ret false; } }
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ret true;
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}
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fn member<T>(x: &T, v: &[T]) -> bool {
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for elt: T in v { if x == elt { ret true; } }
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ret false;
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}
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fn count<T>(x: &T, v: &[mutable? T]) -> uint {
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let cnt = 0u;
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for elt: T in v { if x == elt { cnt += 1u; } }
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ret cnt;
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}
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fn find<@T>(f: &block(&T) -> bool, v: &[T]) -> option::t<T> {
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for elt: T in v { if f(elt) { ret some(elt); } }
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ret none;
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}
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fn position<@T>(x: &T, v: &[T]) -> option::t<uint> {
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let i: uint = 0u;
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while i < len(v) { if x == v[i] { ret some::<uint>(i); } i += 1u; }
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ret none;
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}
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fn position_pred<T>(f: fn(&T) -> bool, v: &[T]) -> option::t<uint> {
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let i: uint = 0u;
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while i < len(v) { if f(v[i]) { ret some::<uint>(i); } i += 1u; }
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ret none;
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}
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fn unzip<@T, @U>(v: &[(T, U)]) -> ([T], [U]) {
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let as = [], bs = [];
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for (a, b) in v { as += [a]; bs += [b]; }
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ret (as, bs);
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}
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// FIXME make the lengths being equal a constraint
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fn zip<@T, @U>(v: &[T], u: &[U]) -> [(T, U)] {
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let zipped = [];
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let sz = len(v), i = 0u;
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assert (sz == len(u));
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while i < sz { zipped += [(v[i], u[i])]; i += 1u; }
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ret zipped;
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}
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// Swaps two elements in a vector
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fn swap<@T>(v: &[mutable T], a: uint, b: uint) {
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let t: T = v[a];
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v[a] = v[b];
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v[b] = t;
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}
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// In place vector reversal
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fn reverse<@T>(v: &[mutable T]) {
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let i: uint = 0u;
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let ln = len::<T>(v);
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while i < ln / 2u { swap(v, i, ln - i - 1u); i += 1u; }
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}
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// Functional vector reversal. Returns a reversed copy of v.
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fn reversed<@T>(v: &[T]) -> [T] {
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let rs: [T] = [];
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let i = len::<T>(v);
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if i == 0u { ret rs; } else { i -= 1u; }
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while i != 0u { rs += [v[i]]; i -= 1u; }
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rs += [v[0]];
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ret rs;
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}
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// Iterate over a list with with the indexes
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iter iter2<@T>(v: &[T]) -> (uint, T) {
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let i = 0u;
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for x in v {
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put (i, x);
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i += 1u;
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}
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}
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mod unsafe {
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type ivec_repr =
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{mutable fill: uint,
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mutable alloc: uint,
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heap_part: *mutable ivec_heap_part};
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type ivec_heap_part = {mutable fill: uint};
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fn copy_from_buf<T>(v: &mutable [T], ptr: *T, count: uint) {
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ret rustrt::ivec_copy_from_buf_shared(v, ptr, count);
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}
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fn from_buf<T>(ptr: *T, bytes: uint) -> [T] {
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let v = [];
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copy_from_buf(v, ptr, bytes);
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ret v;
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}
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fn set_len<T>(v: &mutable [T], new_len: uint) {
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let new_fill = new_len * sys::size_of::<T>();
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let stack_part: *mutable ivec_repr =
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::unsafe::reinterpret_cast(addr_of(v));
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if (*stack_part).fill == 0u {
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(*(*stack_part).heap_part).fill = new_fill; // On heap.
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} else {
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(*stack_part).fill = new_fill; // On stack.
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}
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}
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}
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// Local Variables:
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// mode: rust;
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// fill-column: 78;
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// indent-tabs-mode: nil
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// c-basic-offset: 4
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// buffer-file-coding-system: utf-8-unix
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// compile-command: "make -k -C $RBUILD 2>&1 | sed -e 's/\\/x\\//x:\\//g'";
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// End:
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