//! Managed vectors // NB: transitionary, de-mode-ing. #[forbid(deprecated_mode)]; #[forbid(deprecated_pattern)]; use cast::transmute; use ptr::addr_of; /// Code for dealing with @-vectors. This is pretty incomplete, and /// contains a bunch of duplication from the code for ~-vectors. #[abi = "cdecl"] extern mod rustrt { #[legacy_exports]; fn vec_reserve_shared_actual(++t: *sys::TypeDesc, ++v: **vec::raw::VecRepr, ++n: libc::size_t); } #[abi = "rust-intrinsic"] extern mod rusti { #[legacy_exports]; fn move_val_init(dst: &mut T, -src: T); } /// Returns the number of elements the vector can hold without reallocating #[inline(always)] pub pure fn capacity(v: @[const T]) -> uint { unsafe { let repr: **raw::VecRepr = ::cast::reinterpret_cast(&addr_of(&v)); (**repr).unboxed.alloc / sys::size_of::() } } /** * Builds a vector by calling a provided function with an argument * function that pushes an element to the back of a vector. * This version takes an initial size for the vector. * * # Arguments * * * size - An initial size of the vector to reserve * * builder - A function that will construct the vector. It recieves * as an argument a function that will push an element * onto the vector being constructed. */ #[inline(always)] pub pure fn build_sized(size: uint, builder: &fn(push: pure fn(v: A))) -> @[A] { let mut vec: @[const A] = @[]; unsafe { raw::reserve(&mut vec, size); } builder(|+x| unsafe { raw::push(&mut vec, move x) }); return unsafe { transmute(vec) }; } /** * Builds a vector by calling a provided function with an argument * function that pushes an element to the back of a vector. * * # Arguments * * * builder - A function that will construct the vector. It recieves * as an argument a function that will push an element * onto the vector being constructed. */ #[inline(always)] pub pure fn build(builder: &fn(push: pure fn(v: A))) -> @[A] { build_sized(4, builder) } /** * Builds a vector by calling a provided function with an argument * function that pushes an element to the back of a vector. * This version takes an initial size for the vector. * * # Arguments * * * size - An option, maybe containing initial size of the vector to reserve * * builder - A function that will construct the vector. It recieves * as an argument a function that will push an element * onto the vector being constructed. */ #[inline(always)] pub pure fn build_sized_opt(size: Option, builder: &fn(push: pure fn(v: A))) -> @[A] { build_sized(size.get_default(4), builder) } // Appending #[inline(always)] pub pure fn append(lhs: @[T], rhs: &[const T]) -> @[T] { do build_sized(lhs.len() + rhs.len()) |push| { for vec::each(lhs) |x| { push(*x); } for uint::range(0, rhs.len()) |i| { push(rhs[i]); } } } /// Apply a function to each element of a vector and return the results pub pure fn map(v: &[T], f: &fn(x: &T) -> U) -> @[U] { do build_sized(v.len()) |push| { for vec::each(v) |elem| { push(f(elem)); } } } /** * 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`. */ pub pure fn from_fn(n_elts: uint, op: iter::InitOp) -> @[T] { do build_sized(n_elts) |push| { let mut i: uint = 0u; while i < n_elts { push(op(i)); i += 1u; } } } /** * Creates and initializes an immutable vector. * * Creates an immutable vector of size `n_elts` and initializes the elements * to the value `t`. */ pub pure fn from_elem(n_elts: uint, t: T) -> @[T] { do build_sized(n_elts) |push| { let mut i: uint = 0u; while i < n_elts { push(copy t); i += 1u; } } } #[cfg(notest)] pub mod traits { #[legacy_exports]; pub impl @[T] : Add<&[const T],@[T]> { #[inline(always)] pure fn add(rhs: & &[const T]) -> @[T] { append(self, (*rhs)) } } } #[cfg(test)] pub mod traits { #[legacy_exports];} pub mod raw { pub type VecRepr = vec::raw::VecRepr; pub type SliceRepr = vec::raw::SliceRepr; /** * Sets the length of a vector * * This will 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)] pub unsafe fn set_len(v: @[const T], new_len: uint) { let repr: **VecRepr = ::cast::reinterpret_cast(&addr_of(&v)); (**repr).unboxed.fill = new_len * sys::size_of::(); } #[inline(always)] pub unsafe fn push(v: &mut @[const T], initval: T) { let repr: **VecRepr = ::cast::reinterpret_cast(&v); let fill = (**repr).unboxed.fill; if (**repr).unboxed.alloc > fill { push_fast(v, move initval); } else { push_slow(v, move initval); } } #[inline(always)] // really pretty please pub unsafe fn push_fast(v: &mut @[const T], initval: T) { let repr: **VecRepr = ::cast::reinterpret_cast(&v); let fill = (**repr).unboxed.fill; (**repr).unboxed.fill += sys::size_of::(); let p = addr_of(&((**repr).unboxed.data)); let p = ptr::offset(p, fill) as *mut T; rusti::move_val_init(&mut(*p), move initval); } pub unsafe fn push_slow(v: &mut @[const T], initval: T) { reserve_at_least(v, v.len() + 1u); push_fast(v, move initval); } /** * Reserves capacity for exactly `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. * * # Arguments * * * v - A vector * * n - The number of elements to reserve space for */ pub unsafe fn reserve(v: &mut @[const T], n: uint) { // Only make the (slow) call into the runtime if we have to if capacity(*v) < n { let ptr: **VecRepr = transmute(copy v); rustrt::vec_reserve_shared_actual(sys::get_type_desc::(), ptr, n as libc::size_t); } } /** * Reserves capacity for at least `n` elements in the given vector. * * This function will over-allocate in order to amortize the * allocation costs in scenarios where the caller may need to * repeatedly reserve additional space. * * If the capacity for `v` is already equal to or greater than the * requested capacity, then no action is taken. * * # Arguments * * * v - A vector * * n - The number of elements to reserve space for */ pub unsafe fn reserve_at_least(v: &mut @[const T], n: uint) { reserve(v, uint::next_power_of_two(n)); } } #[test] pub fn test() { // Some code that could use that, then: fn seq_range(lo: uint, hi: uint) -> @[uint] { do build |push| { for uint::range(lo, hi) |i| { push(i); } } } assert seq_range(10, 15) == @[10, 11, 12, 13, 14]; assert from_fn(5, |x| x+1) == @[1, 2, 3, 4, 5]; assert from_elem(5, 3.14) == @[3.14, 3.14, 3.14, 3.14, 3.14]; } #[test] pub fn append_test() { assert @[1,2,3] + @[4,5,6] == @[1,2,3,4,5,6]; }