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raw_vec.rs
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raw_vec.rs
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// Copyright 2015 The Rust Project Developers. See the COPYRIGHT
// file at the top-level directory of this distribution and at
// http://rust-lang.org/COPYRIGHT.
//
// Licensed under the Apache License, Version 2.0 <LICENSE-APACHE or
// http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
// <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your
// option. This file may not be copied, modified, or distributed
// except according to those terms.
use core::cmp;
use core::mem;
use core::ops::Drop;
use core::ptr::{self, Unique};
use core::slice;
use heap::{Alloc, Layout, Heap};
use super::boxed::Box;
/// A low-level utility for more ergonomically allocating, reallocating, and deallocating
/// a buffer of memory on the heap without having to worry about all the corner cases
/// involved. This type is excellent for building your own data structures like Vec and VecDeque.
/// In particular:
///
/// * Produces Unique::empty() on zero-sized types
/// * Produces Unique::empty() on zero-length allocations
/// * Catches all overflows in capacity computations (promotes them to "capacity overflow" panics)
/// * Guards against 32-bit systems allocating more than isize::MAX bytes
/// * Guards against overflowing your length
/// * Aborts on OOM
/// * Avoids freeing Unique::empty()
/// * Contains a ptr::Unique and thus endows the user with all related benefits
///
/// This type does not in anyway inspect the memory that it manages. When dropped it *will*
/// free its memory, but it *won't* try to Drop its contents. It is up to the user of RawVec
/// to handle the actual things *stored* inside of a RawVec.
///
/// Note that a RawVec always forces its capacity to be usize::MAX for zero-sized types.
/// This enables you to use capacity growing logic catch the overflows in your length
/// that might occur with zero-sized types.
///
/// However this means that you need to be careful when roundtripping this type
/// with a `Box<[T]>`: `cap()` won't yield the len. However `with_capacity`,
/// `shrink_to_fit`, and `from_box` will actually set RawVec's private capacity
/// field. This allows zero-sized types to not be special-cased by consumers of
/// this type.
#[allow(missing_debug_implementations)]
pub struct RawVec<T, A: Alloc = Heap> {
ptr: Unique<T>,
cap: usize,
a: A,
}
impl<T, A: Alloc> RawVec<T, A> {
/// Like `new` but parameterized over the choice of allocator for
/// the returned RawVec.
pub fn new_in(a: A) -> Self {
// !0 is usize::MAX. This branch should be stripped at compile time.
let cap = if mem::size_of::<T>() == 0 { !0 } else { 0 };
// Unique::empty() doubles as "unallocated" and "zero-sized allocation"
RawVec {
ptr: Unique::empty(),
cap,
a,
}
}
/// Like `with_capacity` but parameterized over the choice of
/// allocator for the returned RawVec.
#[inline]
pub fn with_capacity_in(cap: usize, a: A) -> Self {
RawVec::allocate_in(cap, false, a)
}
/// Like `with_capacity_zeroed` but parameterized over the choice
/// of allocator for the returned RawVec.
#[inline]
pub fn with_capacity_zeroed_in(cap: usize, a: A) -> Self {
RawVec::allocate_in(cap, true, a)
}
fn allocate_in(cap: usize, zeroed: bool, mut a: A) -> Self {
unsafe {
let elem_size = mem::size_of::<T>();
let alloc_size = cap.checked_mul(elem_size).expect("capacity overflow");
alloc_guard(alloc_size);
// handles ZSTs and `cap = 0` alike
let ptr = if alloc_size == 0 {
mem::align_of::<T>() as *mut u8
} else {
let align = mem::align_of::<T>();
let result = if zeroed {
a.alloc_zeroed(Layout::from_size_align(alloc_size, align).unwrap())
} else {
a.alloc(Layout::from_size_align(alloc_size, align).unwrap())
};
match result {
Ok(ptr) => ptr,
Err(err) => a.oom(err),
}
};
RawVec {
ptr: Unique::new_unchecked(ptr as *mut _),
cap,
a,
}
}
}
}
impl<T> RawVec<T, Heap> {
/// Creates the biggest possible RawVec (on the system heap)
/// without allocating. If T has positive size, then this makes a
/// RawVec with capacity 0. If T has 0 size, then it makes a
/// RawVec with capacity `usize::MAX`. Useful for implementing
/// delayed allocation.
pub fn new() -> Self {
Self::new_in(Heap)
}
/// Creates a RawVec (on the system heap) with exactly the
/// capacity and alignment requirements for a `[T; cap]`. This is
/// equivalent to calling RawVec::new when `cap` is 0 or T is
/// zero-sized. Note that if `T` is zero-sized this means you will
/// *not* get a RawVec with the requested capacity!
///
/// # Panics
///
/// * Panics if the requested capacity exceeds `usize::MAX` bytes.
/// * Panics on 32-bit platforms if the requested capacity exceeds
/// `isize::MAX` bytes.
///
/// # Aborts
///
/// Aborts on OOM
#[inline]
pub fn with_capacity(cap: usize) -> Self {
RawVec::allocate_in(cap, false, Heap)
}
/// Like `with_capacity` but guarantees the buffer is zeroed.
#[inline]
pub fn with_capacity_zeroed(cap: usize) -> Self {
RawVec::allocate_in(cap, true, Heap)
}
}
impl<T, A: Alloc> RawVec<T, A> {
/// Reconstitutes a RawVec from a pointer, capacity, and allocator.
///
/// # Undefined Behavior
///
/// The ptr must be allocated (via the given allocator `a`), and with the given capacity. The
/// capacity cannot exceed `isize::MAX` (only a concern on 32-bit systems).
/// If the ptr and capacity come from a RawVec created via `a`, then this is guaranteed.
pub unsafe fn from_raw_parts_in(ptr: *mut T, cap: usize, a: A) -> Self {
RawVec {
ptr: Unique::new_unchecked(ptr),
cap,
a,
}
}
}
impl<T> RawVec<T, Heap> {
/// Reconstitutes a RawVec from a pointer, capacity.
///
/// # Undefined Behavior
///
/// The ptr must be allocated (on the system heap), and with the given capacity. The
/// capacity cannot exceed `isize::MAX` (only a concern on 32-bit systems).
/// If the ptr and capacity come from a RawVec, then this is guaranteed.
pub unsafe fn from_raw_parts(ptr: *mut T, cap: usize) -> Self {
RawVec {
ptr: Unique::new_unchecked(ptr),
cap,
a: Heap,
}
}
/// Converts a `Box<[T]>` into a `RawVec<T>`.
pub fn from_box(mut slice: Box<[T]>) -> Self {
unsafe {
let result = RawVec::from_raw_parts(slice.as_mut_ptr(), slice.len());
mem::forget(slice);
result
}
}
}
impl<T, A: Alloc> RawVec<T, A> {
/// Gets a raw pointer to the start of the allocation. Note that this is
/// Unique::empty() if `cap = 0` or T is zero-sized. In the former case, you must
/// be careful.
pub fn ptr(&self) -> *mut T {
self.ptr.as_ptr()
}
/// Gets the capacity of the allocation.
///
/// This will always be `usize::MAX` if `T` is zero-sized.
#[inline(always)]
pub fn cap(&self) -> usize {
if mem::size_of::<T>() == 0 {
!0
} else {
self.cap
}
}
/// Returns a shared reference to the allocator backing this RawVec.
pub fn alloc(&self) -> &A {
&self.a
}
/// Returns a mutable reference to the allocator backing this RawVec.
pub fn alloc_mut(&mut self) -> &mut A {
&mut self.a
}
fn current_layout(&self) -> Option<Layout> {
if self.cap == 0 {
None
} else {
// We have an allocated chunk of memory, so we can bypass runtime
// checks to get our current layout.
unsafe {
let align = mem::align_of::<T>();
let size = mem::size_of::<T>() * self.cap;
Some(Layout::from_size_align_unchecked(size, align))
}
}
}
/// Doubles the size of the type's backing allocation. This is common enough
/// to want to do that it's easiest to just have a dedicated method. Slightly
/// more efficient logic can be provided for this than the general case.
///
/// This function is ideal for when pushing elements one-at-a-time because
/// you don't need to incur the costs of the more general computations
/// reserve needs to do to guard against overflow. You do however need to
/// manually check if your `len == cap`.
///
/// # Panics
///
/// * Panics if T is zero-sized on the assumption that you managed to exhaust
/// all `usize::MAX` slots in your imaginary buffer.
/// * Panics on 32-bit platforms if the requested capacity exceeds
/// `isize::MAX` bytes.
///
/// # Aborts
///
/// Aborts on OOM
///
/// # Examples
///
/// ```
/// # #![feature(alloc)]
/// # extern crate alloc;
/// # use std::ptr;
/// # use alloc::raw_vec::RawVec;
/// struct MyVec<T> {
/// buf: RawVec<T>,
/// len: usize,
/// }
///
/// impl<T> MyVec<T> {
/// pub fn push(&mut self, elem: T) {
/// if self.len == self.buf.cap() { self.buf.double(); }
/// // double would have aborted or panicked if the len exceeded
/// // `isize::MAX` so this is safe to do unchecked now.
/// unsafe {
/// ptr::write(self.buf.ptr().offset(self.len as isize), elem);
/// }
/// self.len += 1;
/// }
/// }
/// # fn main() {
/// # let mut vec = MyVec { buf: RawVec::new(), len: 0 };
/// # vec.push(1);
/// # }
/// ```
#[inline(never)]
#[cold]
pub fn double(&mut self) {
unsafe {
let elem_size = mem::size_of::<T>();
// since we set the capacity to usize::MAX when elem_size is
// 0, getting to here necessarily means the RawVec is overfull.
assert!(elem_size != 0, "capacity overflow");
let (new_cap, uniq) = match self.current_layout() {
Some(cur) => {
// Since we guarantee that we never allocate more than
// isize::MAX bytes, `elem_size * self.cap <= isize::MAX` as
// a precondition, so this can't overflow. Additionally the
// alignment will never be too large as to "not be
// satisfiable", so `Layout::from_size_align` will always
// return `Some`.
//
// tl;dr; we bypass runtime checks due to dynamic assertions
// in this module, allowing us to use
// `from_size_align_unchecked`.
let new_cap = 2 * self.cap;
let new_size = new_cap * elem_size;
let new_layout = Layout::from_size_align_unchecked(new_size, cur.align());
alloc_guard(new_size);
let ptr_res = self.a.realloc(self.ptr.as_ptr() as *mut u8,
cur,
new_layout);
match ptr_res {
Ok(ptr) => (new_cap, Unique::new_unchecked(ptr as *mut T)),
Err(e) => self.a.oom(e),
}
}
None => {
// skip to 4 because tiny Vec's are dumb; but not if that
// would cause overflow
let new_cap = if elem_size > (!0) / 8 { 1 } else { 4 };
match self.a.alloc_array::<T>(new_cap) {
Ok(ptr) => (new_cap, ptr.into()),
Err(e) => self.a.oom(e),
}
}
};
self.ptr = uniq;
self.cap = new_cap;
}
}
/// Attempts to double the size of the type's backing allocation in place. This is common
/// enough to want to do that it's easiest to just have a dedicated method. Slightly
/// more efficient logic can be provided for this than the general case.
///
/// Returns true if the reallocation attempt has succeeded, or false otherwise.
///
/// # Panics
///
/// * Panics if T is zero-sized on the assumption that you managed to exhaust
/// all `usize::MAX` slots in your imaginary buffer.
/// * Panics on 32-bit platforms if the requested capacity exceeds
/// `isize::MAX` bytes.
#[inline(never)]
#[cold]
pub fn double_in_place(&mut self) -> bool {
unsafe {
let elem_size = mem::size_of::<T>();
let old_layout = match self.current_layout() {
Some(layout) => layout,
None => return false, // nothing to double
};
// since we set the capacity to usize::MAX when elem_size is
// 0, getting to here necessarily means the RawVec is overfull.
assert!(elem_size != 0, "capacity overflow");
// Since we guarantee that we never allocate more than isize::MAX
// bytes, `elem_size * self.cap <= isize::MAX` as a precondition, so
// this can't overflow.
//
// Similarly like with `double` above we can go straight to
// `Layout::from_size_align_unchecked` as we know this won't
// overflow and the alignment is sufficiently small.
let new_cap = 2 * self.cap;
let new_size = new_cap * elem_size;
alloc_guard(new_size);
let ptr = self.ptr() as *mut _;
let new_layout = Layout::from_size_align_unchecked(new_size, old_layout.align());
match self.a.grow_in_place(ptr, old_layout, new_layout) {
Ok(_) => {
// We can't directly divide `size`.
self.cap = new_cap;
true
}
Err(_) => {
false
}
}
}
}
/// Ensures that the buffer contains at least enough space to hold
/// `used_cap + needed_extra_cap` elements. If it doesn't already,
/// will reallocate the minimum possible amount of memory necessary.
/// Generally this will be exactly the amount of memory necessary,
/// but in principle the allocator is free to give back more than
/// we asked for.
///
/// If `used_cap` exceeds `self.cap()`, this may fail to actually allocate
/// the requested space. This is not really unsafe, but the unsafe
/// code *you* write that relies on the behavior of this function may break.
///
/// # Panics
///
/// * Panics if the requested capacity exceeds `usize::MAX` bytes.
/// * Panics on 32-bit platforms if the requested capacity exceeds
/// `isize::MAX` bytes.
///
/// # Aborts
///
/// Aborts on OOM
pub fn reserve_exact(&mut self, used_cap: usize, needed_extra_cap: usize) {
unsafe {
// NOTE: we don't early branch on ZSTs here because we want this
// to actually catch "asking for more than usize::MAX" in that case.
// If we make it past the first branch then we are guaranteed to
// panic.
// Don't actually need any more capacity.
// Wrapping in case they gave a bad `used_cap`.
if self.cap().wrapping_sub(used_cap) >= needed_extra_cap {
return;
}
// Nothing we can really do about these checks :(
let new_cap = used_cap.checked_add(needed_extra_cap).expect("capacity overflow");
let new_layout = match Layout::array::<T>(new_cap) {
Some(layout) => layout,
None => panic!("capacity overflow"),
};
alloc_guard(new_layout.size());
let res = match self.current_layout() {
Some(layout) => {
let old_ptr = self.ptr.as_ptr() as *mut u8;
self.a.realloc(old_ptr, layout, new_layout)
}
None => self.a.alloc(new_layout),
};
let uniq = match res {
Ok(ptr) => Unique::new_unchecked(ptr as *mut T),
Err(e) => self.a.oom(e),
};
self.ptr = uniq;
self.cap = new_cap;
}
}
/// Calculates the buffer's new size given that it'll hold `used_cap +
/// needed_extra_cap` elements. This logic is used in amortized reserve methods.
/// Returns `(new_capacity, new_alloc_size)`.
fn amortized_new_size(&self, used_cap: usize, needed_extra_cap: usize) -> usize {
// Nothing we can really do about these checks :(
let required_cap = used_cap.checked_add(needed_extra_cap)
.expect("capacity overflow");
// Cannot overflow, because `cap <= isize::MAX`, and type of `cap` is `usize`.
let double_cap = self.cap * 2;
// `double_cap` guarantees exponential growth.
cmp::max(double_cap, required_cap)
}
/// Ensures that the buffer contains at least enough space to hold
/// `used_cap + needed_extra_cap` elements. If it doesn't already have
/// enough capacity, will reallocate enough space plus comfortable slack
/// space to get amortized `O(1)` behavior. Will limit this behavior
/// if it would needlessly cause itself to panic.
///
/// If `used_cap` exceeds `self.cap()`, this may fail to actually allocate
/// the requested space. This is not really unsafe, but the unsafe
/// code *you* write that relies on the behavior of this function may break.
///
/// This is ideal for implementing a bulk-push operation like `extend`.
///
/// # Panics
///
/// * Panics if the requested capacity exceeds `usize::MAX` bytes.
/// * Panics on 32-bit platforms if the requested capacity exceeds
/// `isize::MAX` bytes.
///
/// # Aborts
///
/// Aborts on OOM
///
/// # Examples
///
/// ```
/// # #![feature(alloc)]
/// # extern crate alloc;
/// # use std::ptr;
/// # use alloc::raw_vec::RawVec;
/// struct MyVec<T> {
/// buf: RawVec<T>,
/// len: usize,
/// }
///
/// impl<T: Clone> MyVec<T> {
/// pub fn push_all(&mut self, elems: &[T]) {
/// self.buf.reserve(self.len, elems.len());
/// // reserve would have aborted or panicked if the len exceeded
/// // `isize::MAX` so this is safe to do unchecked now.
/// for x in elems {
/// unsafe {
/// ptr::write(self.buf.ptr().offset(self.len as isize), x.clone());
/// }
/// self.len += 1;
/// }
/// }
/// }
/// # fn main() {
/// # let mut vector = MyVec { buf: RawVec::new(), len: 0 };
/// # vector.push_all(&[1, 3, 5, 7, 9]);
/// # }
/// ```
pub fn reserve(&mut self, used_cap: usize, needed_extra_cap: usize) {
unsafe {
// NOTE: we don't early branch on ZSTs here because we want this
// to actually catch "asking for more than usize::MAX" in that case.
// If we make it past the first branch then we are guaranteed to
// panic.
// Don't actually need any more capacity.
// Wrapping in case they give a bad `used_cap`
if self.cap().wrapping_sub(used_cap) >= needed_extra_cap {
return;
}
let new_cap = self.amortized_new_size(used_cap, needed_extra_cap);
let new_layout = match Layout::array::<T>(new_cap) {
Some(layout) => layout,
None => panic!("capacity overflow"),
};
// FIXME: may crash and burn on over-reserve
alloc_guard(new_layout.size());
let res = match self.current_layout() {
Some(layout) => {
let old_ptr = self.ptr.as_ptr() as *mut u8;
self.a.realloc(old_ptr, layout, new_layout)
}
None => self.a.alloc(new_layout),
};
let uniq = match res {
Ok(ptr) => Unique::new_unchecked(ptr as *mut T),
Err(e) => self.a.oom(e),
};
self.ptr = uniq;
self.cap = new_cap;
}
}
/// Attempts to ensure that the buffer contains at least enough space to hold
/// `used_cap + needed_extra_cap` elements. If it doesn't already have
/// enough capacity, will reallocate in place enough space plus comfortable slack
/// space to get amortized `O(1)` behavior. Will limit this behaviour
/// if it would needlessly cause itself to panic.
///
/// If `used_cap` exceeds `self.cap()`, this may fail to actually allocate
/// the requested space. This is not really unsafe, but the unsafe
/// code *you* write that relies on the behavior of this function may break.
///
/// Returns true if the reallocation attempt has succeeded, or false otherwise.
///
/// # Panics
///
/// * Panics if the requested capacity exceeds `usize::MAX` bytes.
/// * Panics on 32-bit platforms if the requested capacity exceeds
/// `isize::MAX` bytes.
pub fn reserve_in_place(&mut self, used_cap: usize, needed_extra_cap: usize) -> bool {
unsafe {
// NOTE: we don't early branch on ZSTs here because we want this
// to actually catch "asking for more than usize::MAX" in that case.
// If we make it past the first branch then we are guaranteed to
// panic.
// Don't actually need any more capacity. If the current `cap` is 0, we can't
// reallocate in place.
// Wrapping in case they give a bad `used_cap`
let old_layout = match self.current_layout() {
Some(layout) => layout,
None => return false,
};
if self.cap().wrapping_sub(used_cap) >= needed_extra_cap {
return false;
}
let new_cap = self.amortized_new_size(used_cap, needed_extra_cap);
// Here, `cap < used_cap + needed_extra_cap <= new_cap`
// (regardless of whether `self.cap - used_cap` wrapped).
// Therefore we can safely call grow_in_place.
let ptr = self.ptr() as *mut _;
let new_layout = Layout::new::<T>().repeat(new_cap).unwrap().0;
// FIXME: may crash and burn on over-reserve
alloc_guard(new_layout.size());
match self.a.grow_in_place(ptr, old_layout, new_layout) {
Ok(_) => {
self.cap = new_cap;
true
}
Err(_) => {
false
}
}
}
}
/// Shrinks the allocation down to the specified amount. If the given amount
/// is 0, actually completely deallocates.
///
/// # Panics
///
/// Panics if the given amount is *larger* than the current capacity.
///
/// # Aborts
///
/// Aborts on OOM.
pub fn shrink_to_fit(&mut self, amount: usize) {
let elem_size = mem::size_of::<T>();
// Set the `cap` because they might be about to promote to a `Box<[T]>`
if elem_size == 0 {
self.cap = amount;
return;
}
// This check is my waterloo; it's the only thing Vec wouldn't have to do.
assert!(self.cap >= amount, "Tried to shrink to a larger capacity");
if amount == 0 {
// We want to create a new zero-length vector within the
// same allocator. We use ptr::write to avoid an
// erroneous attempt to drop the contents, and we use
// ptr::read to sidestep condition against destructuring
// types that implement Drop.
unsafe {
let a = ptr::read(&self.a as *const A);
self.dealloc_buffer();
ptr::write(self, RawVec::new_in(a));
}
} else if self.cap != amount {
unsafe {
// We know here that our `amount` is greater than zero. This
// implies, via the assert above, that capacity is also greater
// than zero, which means that we've got a current layout that
// "fits"
//
// We also know that `self.cap` is greater than `amount`, and
// consequently we don't need runtime checks for creating either
// layout
let old_size = elem_size * self.cap;
let new_size = elem_size * amount;
let align = mem::align_of::<T>();
let old_layout = Layout::from_size_align_unchecked(old_size, align);
let new_layout = Layout::from_size_align_unchecked(new_size, align);
match self.a.realloc(self.ptr.as_ptr() as *mut u8,
old_layout,
new_layout) {
Ok(p) => self.ptr = Unique::new_unchecked(p as *mut T),
Err(err) => self.a.oom(err),
}
}
self.cap = amount;
}
}
}
impl<T> RawVec<T, Heap> {
/// Converts the entire buffer into `Box<[T]>`.
///
/// While it is not *strictly* Undefined Behavior to call
/// this procedure while some of the RawVec is uninitialized,
/// it certainly makes it trivial to trigger it.
///
/// Note that this will correctly reconstitute any `cap` changes
/// that may have been performed. (see description of type for details)
pub unsafe fn into_box(self) -> Box<[T]> {
// NOTE: not calling `cap()` here, actually using the real `cap` field!
let slice = slice::from_raw_parts_mut(self.ptr(), self.cap);
let output: Box<[T]> = Box::from_raw(slice);
mem::forget(self);
output
}
}
impl<T, A: Alloc> RawVec<T, A> {
/// Frees the memory owned by the RawVec *without* trying to Drop its contents.
pub unsafe fn dealloc_buffer(&mut self) {
let elem_size = mem::size_of::<T>();
if elem_size != 0 {
if let Some(layout) = self.current_layout() {
let ptr = self.ptr() as *mut u8;
self.a.dealloc(ptr, layout);
}
}
}
}
unsafe impl<#[may_dangle] T, A: Alloc> Drop for RawVec<T, A> {
/// Frees the memory owned by the RawVec *without* trying to Drop its contents.
fn drop(&mut self) {
unsafe { self.dealloc_buffer(); }
}
}
// We need to guarantee the following:
// * We don't ever allocate `> isize::MAX` byte-size objects
// * We don't overflow `usize::MAX` and actually allocate too little
//
// On 64-bit we just need to check for overflow since trying to allocate
// `> isize::MAX` bytes will surely fail. On 32-bit and 16-bit we need to add
// an extra guard for this in case we're running on a platform which can use
// all 4GB in user-space. e.g. PAE or x32
#[inline]
fn alloc_guard(alloc_size: usize) {
if mem::size_of::<usize>() < 8 {
assert!(alloc_size <= ::core::isize::MAX as usize,
"capacity overflow");
}
}
#[cfg(test)]
mod tests {
use super::*;
#[test]
fn allocator_param() {
use allocator::{Alloc, AllocErr};
// Writing a test of integration between third-party
// allocators and RawVec is a little tricky because the RawVec
// API does not expose fallible allocation methods, so we
// cannot check what happens when allocator is exhausted
// (beyond detecting a panic).
//
// Instead, this just checks that the RawVec methods do at
// least go through the Allocator API when it reserves
// storage.
// A dumb allocator that consumes a fixed amount of fuel
// before allocation attempts start failing.
struct BoundedAlloc { fuel: usize }
unsafe impl Alloc for BoundedAlloc {
unsafe fn alloc(&mut self, layout: Layout) -> Result<*mut u8, AllocErr> {
let size = layout.size();
if size > self.fuel {
return Err(AllocErr::Unsupported { details: "fuel exhausted" });
}
match Heap.alloc(layout) {
ok @ Ok(_) => { self.fuel -= size; ok }
err @ Err(_) => err,
}
}
unsafe fn dealloc(&mut self, ptr: *mut u8, layout: Layout) {
Heap.dealloc(ptr, layout)
}
}
let a = BoundedAlloc { fuel: 500 };
let mut v: RawVec<u8, _> = RawVec::with_capacity_in(50, a);
assert_eq!(v.a.fuel, 450);
v.reserve(50, 150); // (causes a realloc, thus using 50 + 150 = 200 units of fuel)
assert_eq!(v.a.fuel, 250);
}
#[test]
fn reserve_does_not_overallocate() {
{
let mut v: RawVec<u32> = RawVec::new();
// First `reserve` allocates like `reserve_exact`
v.reserve(0, 9);
assert_eq!(9, v.cap());
}
{
let mut v: RawVec<u32> = RawVec::new();
v.reserve(0, 7);
assert_eq!(7, v.cap());
// 97 if more than double of 7, so `reserve` should work
// like `reserve_exact`.
v.reserve(7, 90);
assert_eq!(97, v.cap());
}
{
let mut v: RawVec<u32> = RawVec::new();
v.reserve(0, 12);
assert_eq!(12, v.cap());
v.reserve(12, 3);
// 3 is less than half of 12, so `reserve` must grow
// exponentially. At the time of writing this test grow
// factor is 2, so new capacity is 24, however, grow factor
// of 1.5 is OK too. Hence `>= 18` in assert.
assert!(v.cap() >= 12 + 12 / 2);
}
}
}