rust/src/lib/ivec.rs

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// Interior vector utility functions.
import option::none;
import option::some;
import uint::next_power_of_two;
import ptr::addr_of;
type operator2[T,U,V] = fn(&T, &U) -> V;
native "rust-intrinsic" mod rusti {
fn ivec_len[T](&T[] v) -> uint;
}
native "rust" mod rustrt {
fn ivec_reserve_shared[T](&mutable T[mutable?] v, uint n);
fn ivec_on_heap[T](&T[] v) -> uint;
fn ivec_to_ptr[T](&T[] v) -> *T;
fn ivec_copy_from_buf_shared[T](&mutable T[mutable?] v,
*T ptr, uint count);
}
/// Reserves space for `n` elements in the given vector.
fn reserve[T](&mutable T[mutable?] v, uint n) {
rustrt::ivec_reserve_shared(v, n);
}
fn on_heap[T](&T[] v) -> bool {
ret rustrt::ivec_on_heap(v) != 0u;
}
fn to_ptr[T](&T[] v) -> *T {
ret rustrt::ivec_to_ptr(v);
}
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fn len[T](&T[mutable?] v) -> uint {
ret rusti::ivec_len(v);
}
type init_op[T] = fn(uint) -> T;
fn init_fn[T](&init_op[T] op, uint n_elts) -> T[] {
auto v = ~[];
reserve(v, n_elts);
let uint i = 0u;
while (i < n_elts) { v += ~[op(i)]; i += 1u; }
ret v;
}
// TODO: Remove me once we have slots.
fn init_fn_mut[T](&init_op[T] op, uint n_elts) -> T[mutable] {
auto v = ~[mutable];
reserve(v, n_elts);
let uint i = 0u;
while (i < n_elts) { v += ~[mutable op(i)]; i += 1u; }
ret v;
}
fn init_elt[T](&T t, uint n_elts) -> T[] {
auto v = ~[];
reserve(v, n_elts);
let uint i = 0u;
while (i < n_elts) { v += ~[t]; i += 1u; }
ret v;
}
// TODO: Remove me once we have slots.
fn init_elt_mut[T](&T t, uint n_elts) -> T[mutable] {
auto v = ~[mutable];
reserve(v, n_elts);
let uint i = 0u;
while (i < n_elts) { v += ~[mutable t]; i += 1u; }
ret v;
}
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fn to_mut[T](&T[] v) -> T[mutable] {
auto vres = ~[mutable];
for (T t in v) {
vres += ~[mutable t];
}
ret vres;
}
fn from_mut[T](&T[mutable] v) -> T[] {
auto vres = ~[];
for (T t in v) {
vres += ~[t];
}
ret vres;
}
// Predicates
pred is_empty[T](&T[mutable?] v) -> bool {
// FIXME: This would be easier if we could just call len
for (T t in v) {
ret false;
}
ret true;
}
pred is_not_empty[T](&T[mutable?] v) -> bool {
ret !is_empty(v);
}
// Accessors
/// Returns the first element of a vector
fn head[T](&T[mutable?] v) : is_not_empty(v) -> T {
ret v.(0);
}
/// Returns all but the first element of a vector
fn tail[T](&T[mutable?] v) : is_not_empty(v) -> T[mutable?] {
ret slice(v, 1u, len(v));
}
/// Returns the last element of `v`.
fn last[T](&T[mutable?] v) -> option::t[T] {
if (len(v) == 0u) { ret none; }
ret some(v.(len(v) - 1u));
}
/// Returns a copy of the elements from [`start`..`end`) from `v`.
fn slice[T](&T[mutable?] v, uint start, uint end) -> T[] {
assert (start <= end);
assert (end <= len(v));
auto result = ~[];
reserve(result, end - start);
auto i = start;
while (i < end) { result += ~[v.(i)]; i += 1u; }
ret result;
}
// TODO: Remove me once we have slots.
fn slice_mut[T](&T[mutable?] v, uint start, uint end) -> T[mutable] {
assert (start <= end);
assert (end <= len(v));
auto result = ~[mutable];
reserve(result, end - start);
auto i = start;
while (i < end) { result += ~[mutable v.(i)]; i += 1u; }
ret result;
}
// Mutators
// TODO: Write this, unsafely, in a way that's not O(n).
fn pop[T](&mutable T[mutable?] v) -> T {
auto ln = len(v);
assert (ln > 0u);
ln -= 1u;
auto e = v.(ln);
v = slice(v, 0u, ln);
ret e;
}
// TODO: More.
// Appending
/// Expands the given vector in-place by appending `n` copies of `initval`.
fn grow[T](&mutable T[] v, uint n, &T initval) {
reserve(v, next_power_of_two(len(v) + n));
let uint i = 0u;
while (i < n) {
v += ~[initval];
i += 1u;
}
}
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// TODO: Remove me once we have slots.
fn grow_mut[T](&mutable T[mutable] v, uint n, &T initval) {
reserve(v, next_power_of_two(len(v) + n));
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let uint i = 0u;
while (i < n) {
v += ~[mutable initval];
i += 1u;
}
}
/// Calls `f` `n` times and appends the results of these calls to the given
/// vector.
fn grow_fn[T](&mutable T[] v, uint n, fn(uint)->T init_fn) {
reserve(v, next_power_of_two(len(v) + n));
let uint i = 0u;
while (i < n) {
v += ~[init_fn(i)];
i += 1u;
}
}
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/// 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](&mutable T[mutable] v, uint index, &T initval, &T val) {
if (index >= len(v)) { grow_mut(v, index - len(v) + 1u, initval); }
v.(index) = val;
}
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// Functional utilities
fn map[T,U](fn(&T)->U f, &T[mutable?] v) -> U[] {
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auto result = ~[];
reserve(result, len(v));
for (T elem in v) {
auto elem2 = elem; // satisfies alias checker
result += ~[f(elem2)];
}
ret result;
}
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fn filter_map[T,U](fn(&T)->option::t[U] f, &T[mutable?] v) -> U[] {
auto result = ~[];
for (T elem in v) {
auto elem2 = elem; // satisfies alias checker
alt (f(elem2)) {
case (none) { /* no-op */ }
case (some(?result_elem)) { result += ~[result_elem]; }
}
}
ret result;
}
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fn foldl[T,U](fn(&U,&T)->U p, &U z, &T[mutable?] v) -> U {
auto sz = len(v);
if (sz == 0u) { ret z; }
auto first = v.(0);
auto rest = slice(v, 1u, sz);
ret p(foldl[T,U](p, z, rest), first);
}
fn any[T](fn(&T)->bool f, &T[] v) -> bool {
for (T elem in v) { if (f(elem)) { ret true; } }
ret false;
}
fn all[T](fn(&T)->bool f, &T[] v) -> bool {
for (T elem in v) { if (!f(elem)) { ret false; } }
ret true;
}
fn member[T](&T x, &T[] v) -> bool {
for (T elt in v) { if (x == elt) { ret true; } }
ret false;
}
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fn count[T](&T x, &T[mutable?] v) -> uint {
auto cnt = 0u;
for (T elt in v) { if (x == elt) { cnt += 1u; } }
ret cnt;
}
fn find[T](fn(&T) -> bool f, &T[] v) -> option::t[T] {
for (T elt in v) { if (f(elt)) { ret some[T](elt); } }
ret none[T];
}
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fn unzip[T, U](&rec(T _0, U _1)[] v) -> rec(T[] _0, U[] _1) {
auto sz = len(v);
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if (sz == 0u) {
ret rec(_0=~[], _1=~[]);
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} else {
auto rest = slice(v, 1u, sz);
auto tl = unzip(rest);
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auto a = ~[v.(0)._0];
auto b = ~[v.(0)._1];
ret rec(_0=a + tl._0, _1=b + tl._1);
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}
}
// FIXME make the lengths being equal a constraint
fn zip[T, U](&T[] v, &U[] u) -> rec(T _0, U _1)[] {
auto sz = len(v);
assert (sz == len(u));
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if (sz == 0u) {
ret ~[];
} else {
auto rest = zip(slice(v, 1u, sz), slice(u, 1u, sz));
ret ~[rec(_0=v.(0), _1=u.(0))] + rest;
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}
}
mod unsafe {
type ivec_repr = rec(mutable uint fill,
mutable uint alloc,
*mutable ivec_heap_part heap_part);
type ivec_heap_part = rec(mutable uint fill);
fn copy_from_buf[T](&mutable T[] v, *T ptr, uint count) {
ret rustrt::ivec_copy_from_buf_shared(v, ptr, count);
}
fn from_buf[T](*T ptr, uint bytes) -> T[] {
auto v = ~[];
copy_from_buf(v, ptr, bytes);
ret v;
}
fn set_len[T](&mutable T[] v, uint new_len) {
auto new_fill = new_len * sys::size_of[T]();
let *mutable ivec_repr stack_part =
::unsafe::reinterpret_cast(addr_of(v));
if ((*stack_part).fill == 0u) {
(*(*stack_part).heap_part).fill = new_fill; // On heap.
} else {
(*stack_part).fill = new_fill; // On stack.
}
}
}
// Local Variables:
// mode: rust;
// fill-column: 78;
// indent-tabs-mode: nil
// c-basic-offset: 4
// buffer-file-coding-system: utf-8-unix
// compile-command: "make -k -C .. 2>&1 | sed -e 's/\\/x\\//x:\\//g'";
// End: