rust/src/libcore/alloc.rs
Simon Sapin e9fd063edb Document memory allocation APIs
Add some docs where they were missing,
attempt to fix them where they were out of date.
2018-06-11 13:47:28 -07:00

1222 lines
48 KiB
Rust
Raw Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

// 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.
//! Memory allocation APIs
#![unstable(feature = "allocator_api",
reason = "the precise API and guarantees it provides may be tweaked \
slightly, especially to possibly take into account the \
types being stored to make room for a future \
tracing garbage collector",
issue = "32838")]
use cmp;
use fmt;
use mem;
use usize;
use ptr::{self, NonNull};
use num::NonZeroUsize;
#[cfg(stage0)]
pub type Opaque = u8;
/// Represents the combination of a starting address and
/// a total capacity of the returned block.
#[derive(Debug)]
pub struct Excess(pub NonNull<u8>, pub usize);
fn size_align<T>() -> (usize, usize) {
(mem::size_of::<T>(), mem::align_of::<T>())
}
/// Layout of a block of memory.
///
/// An instance of `Layout` describes a particular layout of memory.
/// You build a `Layout` up as an input to give to an allocator.
///
/// All layouts have an associated non-negative size and a
/// power-of-two alignment.
///
/// (Note however that layouts are *not* required to have positive
/// size, even though many allocators require that all memory
/// requests have positive size. A caller to the `Alloc::alloc`
/// method must either ensure that conditions like this are met, or
/// use specific allocators with looser requirements.)
#[derive(Copy, Clone, Debug, PartialEq, Eq)]
pub struct Layout {
// size of the requested block of memory, measured in bytes.
size_: usize,
// alignment of the requested block of memory, measured in bytes.
// we ensure that this is always a power-of-two, because API's
// like `posix_memalign` require it and it is a reasonable
// constraint to impose on Layout constructors.
//
// (However, we do not analogously require `align >= sizeof(void*)`,
// even though that is *also* a requirement of `posix_memalign`.)
align_: NonZeroUsize,
}
impl Layout {
/// Constructs a `Layout` from a given `size` and `align`,
/// or returns `LayoutErr` if either of the following conditions
/// are not met:
///
/// * `align` must be a power of two,
///
/// * `size`, when rounded up to the nearest multiple of `align`,
/// must not overflow (i.e. the rounded value must be less than
/// `usize::MAX`).
#[inline]
pub fn from_size_align(size: usize, align: usize) -> Result<Self, LayoutErr> {
if !align.is_power_of_two() {
return Err(LayoutErr { private: () });
}
// (power-of-two implies align != 0.)
// Rounded up size is:
// size_rounded_up = (size + align - 1) & !(align - 1);
//
// We know from above that align != 0. If adding (align - 1)
// does not overflow, then rounding up will be fine.
//
// Conversely, &-masking with !(align - 1) will subtract off
// only low-order-bits. Thus if overflow occurs with the sum,
// the &-mask cannot subtract enough to undo that overflow.
//
// Above implies that checking for summation overflow is both
// necessary and sufficient.
if size > usize::MAX - (align - 1) {
return Err(LayoutErr { private: () });
}
unsafe {
Ok(Layout::from_size_align_unchecked(size, align))
}
}
/// Creates a layout, bypassing all checks.
///
/// # Safety
///
/// This function is unsafe as it does not verify the preconditions from
/// [`Layout::from_size_align`](#method.from_size_align).
#[inline]
pub unsafe fn from_size_align_unchecked(size: usize, align: usize) -> Self {
Layout { size_: size, align_: NonZeroUsize::new_unchecked(align) }
}
/// The minimum size in bytes for a memory block of this layout.
#[inline]
pub fn size(&self) -> usize { self.size_ }
/// The minimum byte alignment for a memory block of this layout.
#[inline]
pub fn align(&self) -> usize { self.align_.get() }
/// Constructs a `Layout` suitable for holding a value of type `T`.
#[inline]
pub fn new<T>() -> Self {
let (size, align) = size_align::<T>();
// Note that the align is guaranteed by rustc to be a power of two and
// the size+align combo is guaranteed to fit in our address space. As a
// result use the unchecked constructor here to avoid inserting code
// that panics if it isn't optimized well enough.
debug_assert!(Layout::from_size_align(size, align).is_ok());
unsafe {
Layout::from_size_align_unchecked(size, align)
}
}
/// Produces layout describing a record that could be used to
/// allocate backing structure for `T` (which could be a trait
/// or other unsized type like a slice).
#[inline]
pub fn for_value<T: ?Sized>(t: &T) -> Self {
let (size, align) = (mem::size_of_val(t), mem::align_of_val(t));
// See rationale in `new` for why this us using an unsafe variant below
debug_assert!(Layout::from_size_align(size, align).is_ok());
unsafe {
Layout::from_size_align_unchecked(size, align)
}
}
/// Creates a layout describing the record that can hold a value
/// of the same layout as `self`, but that also is aligned to
/// alignment `align` (measured in bytes).
///
/// If `self` already meets the prescribed alignment, then returns
/// `self`.
///
/// Note that this method does not add any padding to the overall
/// size, regardless of whether the returned layout has a different
/// alignment. In other words, if `K` has size 16, `K.align_to(32)`
/// will *still* have size 16.
///
/// # Panics
///
/// Panics if the combination of `self.size()` and the given `align`
/// violates the conditions listed in
/// [`Layout::from_size_align`](#method.from_size_align).
#[inline]
pub fn align_to(&self, align: usize) -> Self {
Layout::from_size_align(self.size(), cmp::max(self.align(), align)).unwrap()
}
/// Returns the amount of padding we must insert after `self`
/// to ensure that the following address will satisfy `align`
/// (measured in bytes).
///
/// E.g. if `self.size()` is 9, then `self.padding_needed_for(4)`
/// returns 3, because that is the minimum number of bytes of
/// padding required to get a 4-aligned address (assuming that the
/// corresponding memory block starts at a 4-aligned address).
///
/// The return value of this function has no meaning if `align` is
/// not a power-of-two.
///
/// Note that the utility of the returned value requires `align`
/// to be less than or equal to the alignment of the starting
/// address for the whole allocated block of memory. One way to
/// satisfy this constraint is to ensure `align <= self.align()`.
#[inline]
pub fn padding_needed_for(&self, align: usize) -> usize {
let len = self.size();
// Rounded up value is:
// len_rounded_up = (len + align - 1) & !(align - 1);
// and then we return the padding difference: `len_rounded_up - len`.
//
// We use modular arithmetic throughout:
//
// 1. align is guaranteed to be > 0, so align - 1 is always
// valid.
//
// 2. `len + align - 1` can overflow by at most `align - 1`,
// so the &-mask wth `!(align - 1)` will ensure that in the
// case of overflow, `len_rounded_up` will itself be 0.
// Thus the returned padding, when added to `len`, yields 0,
// which trivially satisfies the alignment `align`.
//
// (Of course, attempts to allocate blocks of memory whose
// size and padding overflow in the above manner should cause
// the allocator to yield an error anyway.)
let len_rounded_up = len.wrapping_add(align).wrapping_sub(1)
& !align.wrapping_sub(1);
return len_rounded_up.wrapping_sub(len);
}
/// Creates a layout describing the record for `n` instances of
/// `self`, with a suitable amount of padding between each to
/// ensure that each instance is given its requested size and
/// alignment. On success, returns `(k, offs)` where `k` is the
/// layout of the array and `offs` is the distance between the start
/// of each element in the array.
///
/// On arithmetic overflow, returns `LayoutErr`.
#[inline]
pub fn repeat(&self, n: usize) -> Result<(Self, usize), LayoutErr> {
let padded_size = self.size().checked_add(self.padding_needed_for(self.align()))
.ok_or(LayoutErr { private: () })?;
let alloc_size = padded_size.checked_mul(n)
.ok_or(LayoutErr { private: () })?;
unsafe {
// self.align is already known to be valid and alloc_size has been
// padded already.
Ok((Layout::from_size_align_unchecked(alloc_size, self.align()), padded_size))
}
}
/// Creates a layout describing the record for `self` followed by
/// `next`, including any necessary padding to ensure that `next`
/// will be properly aligned. Note that the result layout will
/// satisfy the alignment properties of both `self` and `next`.
///
/// Returns `Some((k, offset))`, where `k` is layout of the concatenated
/// record and `offset` is the relative location, in bytes, of the
/// start of the `next` embedded within the concatenated record
/// (assuming that the record itself starts at offset 0).
///
/// On arithmetic overflow, returns `LayoutErr`.
#[inline]
pub fn extend(&self, next: Self) -> Result<(Self, usize), LayoutErr> {
let new_align = cmp::max(self.align(), next.align());
let pad = self.padding_needed_for(next.align());
let offset = self.size().checked_add(pad)
.ok_or(LayoutErr { private: () })?;
let new_size = offset.checked_add(next.size())
.ok_or(LayoutErr { private: () })?;
let layout = Layout::from_size_align(new_size, new_align)?;
Ok((layout, offset))
}
/// Creates a layout describing the record for `n` instances of
/// `self`, with no padding between each instance.
///
/// Note that, unlike `repeat`, `repeat_packed` does not guarantee
/// that the repeated instances of `self` will be properly
/// aligned, even if a given instance of `self` is properly
/// aligned. In other words, if the layout returned by
/// `repeat_packed` is used to allocate an array, it is not
/// guaranteed that all elements in the array will be properly
/// aligned.
///
/// On arithmetic overflow, returns `LayoutErr`.
#[inline]
pub fn repeat_packed(&self, n: usize) -> Result<Self, LayoutErr> {
let size = self.size().checked_mul(n).ok_or(LayoutErr { private: () })?;
Layout::from_size_align(size, self.align())
}
/// Creates a layout describing the record for `self` followed by
/// `next` with no additional padding between the two. Since no
/// padding is inserted, the alignment of `next` is irrelevant,
/// and is not incorporated *at all* into the resulting layout.
///
/// Returns `(k, offset)`, where `k` is layout of the concatenated
/// record and `offset` is the relative location, in bytes, of the
/// start of the `next` embedded within the concatenated record
/// (assuming that the record itself starts at offset 0).
///
/// (The `offset` is always the same as `self.size()`; we use this
/// signature out of convenience in matching the signature of
/// `extend`.)
///
/// On arithmetic overflow, returns `LayoutErr`.
#[inline]
pub fn extend_packed(&self, next: Self) -> Result<(Self, usize), LayoutErr> {
let new_size = self.size().checked_add(next.size())
.ok_or(LayoutErr { private: () })?;
let layout = Layout::from_size_align(new_size, self.align())?;
Ok((layout, self.size()))
}
/// Creates a layout describing the record for a `[T; n]`.
///
/// On arithmetic overflow, returns `LayoutErr`.
#[inline]
pub fn array<T>(n: usize) -> Result<Self, LayoutErr> {
Layout::new::<T>()
.repeat(n)
.map(|(k, offs)| {
debug_assert!(offs == mem::size_of::<T>());
k
})
}
}
/// The parameters given to `Layout::from_size_align`
/// or some other `Layout` constructor
/// do not satisfy its documented constraints.
#[derive(Clone, PartialEq, Eq, Debug)]
pub struct LayoutErr {
private: ()
}
// (we need this for downstream impl of trait Error)
impl fmt::Display for LayoutErr {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
f.write_str("invalid parameters to Layout::from_size_align")
}
}
/// The `AllocErr` error indicates an allocation failure
/// that may be due to resource exhaustion or to
/// something wrong when combining the given input arguments with this
/// allocator.
#[derive(Clone, PartialEq, Eq, Debug)]
pub struct AllocErr;
// (we need this for downstream impl of trait Error)
impl fmt::Display for AllocErr {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
f.write_str("memory allocation failed")
}
}
/// The `CannotReallocInPlace` error is used when `grow_in_place` or
/// `shrink_in_place` were unable to reuse the given memory block for
/// a requested layout.
// FIXME: should this be in libcore or liballoc?
#[derive(Clone, PartialEq, Eq, Debug)]
pub struct CannotReallocInPlace;
impl CannotReallocInPlace {
pub fn description(&self) -> &str {
"cannot reallocate allocator's memory in place"
}
}
// (we need this for downstream impl of trait Error)
impl fmt::Display for CannotReallocInPlace {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
write!(f, "{}", self.description())
}
}
/// Augments `AllocErr` with a CapacityOverflow variant.
// FIXME: should this be in libcore or liballoc?
#[derive(Clone, PartialEq, Eq, Debug)]
#[unstable(feature = "try_reserve", reason = "new API", issue="48043")]
pub enum CollectionAllocErr {
/// Error due to the computed capacity exceeding the collection's maximum
/// (usually `isize::MAX` bytes).
CapacityOverflow,
/// Error due to the allocator (see the `AllocErr` type's docs).
AllocErr,
}
#[unstable(feature = "try_reserve", reason = "new API", issue="48043")]
impl From<AllocErr> for CollectionAllocErr {
#[inline]
fn from(AllocErr: AllocErr) -> Self {
CollectionAllocErr::AllocErr
}
}
#[unstable(feature = "try_reserve", reason = "new API", issue="48043")]
impl From<LayoutErr> for CollectionAllocErr {
#[inline]
fn from(_: LayoutErr) -> Self {
CollectionAllocErr::CapacityOverflow
}
}
/// A memory allocator that can be registered as the standard librarys default
/// though the `#[global_allocator]` attributes.
///
/// Some of the methods require that a memory block be *currently
/// allocated* via an allocator. This means that:
///
/// * the starting address for that memory block was previously
/// returned by a previous call to an allocation method
/// such as `alloc`, and
///
/// * the memory block has not been subsequently deallocated, where
/// blocks are deallocated either by being passed to a deallocation
/// method such as `dealloc` or by being
/// passed to a reallocation method that returns a non-null pointer.
///
///
/// # Example
///
/// ```no_run
/// use std::alloc::{GlobalAlloc, Layout, alloc};
/// use std::ptr::null_mut;
///
/// struct MyAllocator;
///
/// unsafe impl GlobalAlloc for MyAllocator {
/// unsafe fn alloc(&self, _layout: Layout) -> *mut u8 { null_mut() }
/// unsafe fn dealloc(&self, _ptr: *mut u8, _layout: Layout) {}
/// }
///
/// #[global_allocator]
/// static A: MyAllocator = MyAllocator;
///
/// fn main() {
/// unsafe {
/// assert!(alloc(Layout::new::<u32>()).is_null())
/// }
/// }
/// ```
///
/// # Unsafety
///
/// The `GlobalAlloc` trait is an `unsafe` trait for a number of reasons, and
/// implementors must ensure that they adhere to these contracts:
///
/// * Pointers returned from allocation functions must point to valid memory and
/// retain their validity until at least the instance of `GlobalAlloc` is dropped
/// itself.
///
/// * It's undefined behavior if global allocators unwind. This restriction may
/// be lifted in the future, but currently a panic from any of these
/// functions may lead to memory unsafety.
///
/// * `Layout` queries and calculations in general must be correct. Callers of
/// this trait are allowed to rely on the contracts defined on each method,
/// and implementors must ensure such contracts remain true.
pub unsafe trait GlobalAlloc {
/// Allocate memory as described by the given `layout`.
///
/// Returns a pointer to newly-allocated memory,
/// or null to indicate allocation failure.
///
/// # Safety
///
/// This function is unsafe because undefined behavior can result
/// if the caller does not ensure that `layout` has non-zero size.
///
/// (Extension subtraits might provide more specific bounds on
/// behavior, e.g. guarantee a sentinel address or a null pointer
/// in response to a zero-size allocation request.)
///
/// The allocated block of memory may or may not be initialized.
///
/// # Errors
///
/// Returning a null pointer indicates that either memory is exhausted
/// or `layout` does not meet allocator's size or alignment constraints.
///
/// Implementations are encouraged to return null on memory
/// exhaustion rather than aborting, but this is not
/// a strict requirement. (Specifically: it is *legal* to
/// implement this trait atop an underlying native allocation
/// library that aborts on memory exhaustion.)
///
/// Clients wishing to abort computation in response to an
/// allocation error are encouraged to call the [`oom`] function,
/// rather than directly invoking `panic!` or similar.
unsafe fn alloc(&self, layout: Layout) -> *mut u8;
/// Deallocate the block of memory at the given `ptr` pointer with the given `layout`.
///
/// # Safety
///
/// This function is unsafe because undefined behavior can result
/// if the caller does not ensure all of the following:
///
/// * `ptr` must denote a block of memory currently allocated via
/// this allocator,
///
/// * `layout` must be the same layout that was used
/// to allocated that block of memory,
unsafe fn dealloc(&self, ptr: *mut u8, layout: Layout);
/// Behaves like `alloc`, but also ensures that the contents
/// are set to zero before being returned.
///
/// # Safety
///
/// This function is unsafe for the same reasons that `alloc` is.
/// However the allocated block of memory is guaranteed to be initialized.
///
/// # Errors
///
/// Returning a null pointer indicates that either memory is exhausted
/// or `layout` does not meet allocator's size or alignment constraints,
/// just as in `alloc`.
///
/// Clients wishing to abort computation in response to an
/// allocation error are encouraged to call the [`oom`] function,
/// rather than directly invoking `panic!` or similar.
unsafe fn alloc_zeroed(&self, layout: Layout) -> *mut u8 {
let size = layout.size();
let ptr = self.alloc(layout);
if !ptr.is_null() {
ptr::write_bytes(ptr, 0, size);
}
ptr
}
/// Shink or grow a block of memory to the given `new_size`.
/// The block is described by the given `ptr` pointer and `layout`.
///
/// If this returns a non-null pointer, then ownership of the memory block
/// referenced by `ptr` has been transferred to this alloctor.
/// The memory may or may not have been deallocated,
/// and should be considered unusable (unless of course it was
/// transferred back to the caller again via the return value of
/// this method).
///
/// If this method returns null, then ownership of the memory
/// block has not been transferred to this allocator, and the
/// contents of the memory block are unaltered.
///
/// # Safety
///
/// This function is unsafe because undefined behavior can result
/// if the caller does not ensure all of the following:
///
/// * `ptr` must be currently allocated via this allocator,
///
/// * `layout` must be the same layout that was used
/// to allocated that block of memory,
///
/// * `new_size` must be greater than zero.
///
/// * `new_size`, when rounded up to the nearest multiple of `layout.align()`,
/// must not overflow (i.e. the rounded value must be less than `usize::MAX`).
///
/// (Extension subtraits might provide more specific bounds on
/// behavior, e.g. guarantee a sentinel address or a null pointer
/// in response to a zero-size allocation request.)
///
/// # Errors
///
/// Returns null if the new layout does not meet the size
/// and alignment constraints of the allocator, or if reallocation
/// otherwise fails.
///
/// Implementations are encouraged to return null on memory
/// exhaustion rather than panicking or aborting, but this is not
/// a strict requirement. (Specifically: it is *legal* to
/// implement this trait atop an underlying native allocation
/// library that aborts on memory exhaustion.)
///
/// Clients wishing to abort computation in response to a
/// reallocation error are encouraged to call the [`oom`] function,
/// rather than directly invoking `panic!` or similar.
unsafe fn realloc(&self, ptr: *mut u8, layout: Layout, new_size: usize) -> *mut u8 {
let new_layout = Layout::from_size_align_unchecked(new_size, layout.align());
let new_ptr = self.alloc(new_layout);
if !new_ptr.is_null() {
ptr::copy_nonoverlapping(
ptr,
new_ptr,
cmp::min(layout.size(), new_size),
);
self.dealloc(ptr, layout);
}
new_ptr
}
}
/// An implementation of `Alloc` can allocate, reallocate, and
/// deallocate arbitrary blocks of data described via `Layout`.
///
/// Some of the methods require that a memory block be *currently
/// allocated* via an allocator. This means that:
///
/// * the starting address for that memory block was previously
/// returned by a previous call to an allocation method (`alloc`,
/// `alloc_zeroed`, `alloc_excess`, `alloc_one`, `alloc_array`) or
/// reallocation method (`realloc`, `realloc_excess`, or
/// `realloc_array`), and
///
/// * the memory block has not been subsequently deallocated, where
/// blocks are deallocated either by being passed to a deallocation
/// method (`dealloc`, `dealloc_one`, `dealloc_array`) or by being
/// passed to a reallocation method (see above) that returns `Ok`.
///
/// A note regarding zero-sized types and zero-sized layouts: many
/// methods in the `Alloc` trait state that allocation requests
/// must be non-zero size, or else undefined behavior can result.
///
/// * However, some higher-level allocation methods (`alloc_one`,
/// `alloc_array`) are well-defined on zero-sized types and can
/// optionally support them: it is left up to the implementor
/// whether to return `Err`, or to return `Ok` with some pointer.
///
/// * If an `Alloc` implementation chooses to return `Ok` in this
/// case (i.e. the pointer denotes a zero-sized inaccessible block)
/// then that returned pointer must be considered "currently
/// allocated". On such an allocator, *all* methods that take
/// currently-allocated pointers as inputs must accept these
/// zero-sized pointers, *without* causing undefined behavior.
///
/// * In other words, if a zero-sized pointer can flow out of an
/// allocator, then that allocator must likewise accept that pointer
/// flowing back into its deallocation and reallocation methods.
///
/// Some of the methods require that a layout *fit* a memory block.
/// What it means for a layout to "fit" a memory block means (or
/// equivalently, for a memory block to "fit" a layout) is that the
/// following two conditions must hold:
///
/// 1. The block's starting address must be aligned to `layout.align()`.
///
/// 2. The block's size must fall in the range `[use_min, use_max]`, where:
///
/// * `use_min` is `self.usable_size(layout).0`, and
///
/// * `use_max` is the capacity that was (or would have been)
/// returned when (if) the block was allocated via a call to
/// `alloc_excess` or `realloc_excess`.
///
/// Note that:
///
/// * the size of the layout most recently used to allocate the block
/// is guaranteed to be in the range `[use_min, use_max]`, and
///
/// * a lower-bound on `use_max` can be safely approximated by a call to
/// `usable_size`.
///
/// * if a layout `k` fits a memory block (denoted by `ptr`)
/// currently allocated via an allocator `a`, then it is legal to
/// use that layout to deallocate it, i.e. `a.dealloc(ptr, k);`.
///
/// # Unsafety
///
/// The `Alloc` trait is an `unsafe` trait for a number of reasons, and
/// implementors must ensure that they adhere to these contracts:
///
/// * Pointers returned from allocation functions must point to valid memory and
/// retain their validity until at least the instance of `Alloc` is dropped
/// itself.
///
/// * `Layout` queries and calculations in general must be correct. Callers of
/// this trait are allowed to rely on the contracts defined on each method,
/// and implementors must ensure such contracts remain true.
///
/// Note that this list may get tweaked over time as clarifications are made in
/// the future.
pub unsafe trait Alloc {
// (Note: some existing allocators have unspecified but well-defined
// behavior in response to a zero size allocation request ;
// e.g. in C, `malloc` of 0 will either return a null pointer or a
// unique pointer, but will not have arbitrary undefined
// behavior.
// However in jemalloc for example,
// `mallocx(0)` is documented as undefined behavior.)
/// Returns a pointer meeting the size and alignment guarantees of
/// `layout`.
///
/// If this method returns an `Ok(addr)`, then the `addr` returned
/// will be non-null address pointing to a block of storage
/// suitable for holding an instance of `layout`.
///
/// The returned block of storage may or may not have its contents
/// initialized. (Extension subtraits might restrict this
/// behavior, e.g. to ensure initialization to particular sets of
/// bit patterns.)
///
/// # Safety
///
/// This function is unsafe because undefined behavior can result
/// if the caller does not ensure that `layout` has non-zero size.
///
/// (Extension subtraits might provide more specific bounds on
/// behavior, e.g. guarantee a sentinel address or a null pointer
/// in response to a zero-size allocation request.)
///
/// # Errors
///
/// Returning `Err` indicates that either memory is exhausted or
/// `layout` does not meet allocator's size or alignment
/// constraints.
///
/// Implementations are encouraged to return `Err` on memory
/// exhaustion rather than panicking or aborting, but this is not
/// a strict requirement. (Specifically: it is *legal* to
/// implement this trait atop an underlying native allocation
/// library that aborts on memory exhaustion.)
///
/// Clients wishing to abort computation in response to an
/// allocation error are encouraged to call the `oom` function,
/// rather than directly invoking `panic!` or similar.
unsafe fn alloc(&mut self, layout: Layout) -> Result<NonNull<u8>, AllocErr>;
/// Deallocate the memory referenced by `ptr`.
///
/// # Safety
///
/// This function is unsafe because undefined behavior can result
/// if the caller does not ensure all of the following:
///
/// * `ptr` must denote a block of memory currently allocated via
/// this allocator,
///
/// * `layout` must *fit* that block of memory,
///
/// * In addition to fitting the block of memory `layout`, the
/// alignment of the `layout` must match the alignment used
/// to allocate that block of memory.
unsafe fn dealloc(&mut self, ptr: NonNull<u8>, layout: Layout);
// == ALLOCATOR-SPECIFIC QUANTITIES AND LIMITS ==
// usable_size
/// Returns bounds on the guaranteed usable size of a successful
/// allocation created with the specified `layout`.
///
/// In particular, if one has a memory block allocated via a given
/// allocator `a` and layout `k` where `a.usable_size(k)` returns
/// `(l, u)`, then one can pass that block to `a.dealloc()` with a
/// layout in the size range [l, u].
///
/// (All implementors of `usable_size` must ensure that
/// `l <= k.size() <= u`)
///
/// Both the lower- and upper-bounds (`l` and `u` respectively)
/// are provided, because an allocator based on size classes could
/// misbehave if one attempts to deallocate a block without
/// providing a correct value for its size (i.e., one within the
/// range `[l, u]`).
///
/// Clients who wish to make use of excess capacity are encouraged
/// to use the `alloc_excess` and `realloc_excess` instead, as
/// this method is constrained to report conservative values that
/// serve as valid bounds for *all possible* allocation method
/// calls.
///
/// However, for clients that do not wish to track the capacity
/// returned by `alloc_excess` locally, this method is likely to
/// produce useful results.
#[inline]
fn usable_size(&self, layout: &Layout) -> (usize, usize) {
(layout.size(), layout.size())
}
// == METHODS FOR MEMORY REUSE ==
// realloc. alloc_excess, realloc_excess
/// Returns a pointer suitable for holding data described by
/// a new layout with `layout`s alginment and a size given
/// by `new_size`. To
/// accomplish this, this may extend or shrink the allocation
/// referenced by `ptr` to fit the new layout.
///
/// If this returns `Ok`, then ownership of the memory block
/// referenced by `ptr` has been transferred to this
/// allocator. The memory may or may not have been freed, and
/// should be considered unusable (unless of course it was
/// transferred back to the caller again via the return value of
/// this method).
///
/// If this method returns `Err`, then ownership of the memory
/// block has not been transferred to this allocator, and the
/// contents of the memory block are unaltered.
///
/// # Safety
///
/// This function is unsafe because undefined behavior can result
/// if the caller does not ensure all of the following:
///
/// * `ptr` must be currently allocated via this allocator,
///
/// * `layout` must *fit* the `ptr` (see above). (The `new_size`
/// argument need not fit it.)
///
/// * `new_size` must be greater than zero.
///
/// * `new_size`, when rounded up to the nearest multiple of `layout.align()`,
/// must not overflow (i.e. the rounded value must be less than `usize::MAX`).
///
/// (Extension subtraits might provide more specific bounds on
/// behavior, e.g. guarantee a sentinel address or a null pointer
/// in response to a zero-size allocation request.)
///
/// # Errors
///
/// Returns `Err` only if the new layout
/// does not meet the allocator's size
/// and alignment constraints of the allocator, or if reallocation
/// otherwise fails.
///
/// Implementations are encouraged to return `Err` on memory
/// exhaustion rather than panicking or aborting, but this is not
/// a strict requirement. (Specifically: it is *legal* to
/// implement this trait atop an underlying native allocation
/// library that aborts on memory exhaustion.)
///
/// Clients wishing to abort computation in response to a
/// reallocation error are encouraged to call the [`oom`] function,
/// rather than directly invoking `panic!` or similar.
unsafe fn realloc(&mut self,
ptr: NonNull<u8>,
layout: Layout,
new_size: usize) -> Result<NonNull<u8>, AllocErr> {
let old_size = layout.size();
if new_size >= old_size {
if let Ok(()) = self.grow_in_place(ptr, layout.clone(), new_size) {
return Ok(ptr);
}
} else if new_size < old_size {
if let Ok(()) = self.shrink_in_place(ptr, layout.clone(), new_size) {
return Ok(ptr);
}
}
// otherwise, fall back on alloc + copy + dealloc.
let new_layout = Layout::from_size_align_unchecked(new_size, layout.align());
let result = self.alloc(new_layout);
if let Ok(new_ptr) = result {
ptr::copy_nonoverlapping(ptr.as_ptr(),
new_ptr.as_ptr(),
cmp::min(old_size, new_size));
self.dealloc(ptr, layout);
}
result
}
/// Behaves like `alloc`, but also ensures that the contents
/// are set to zero before being returned.
///
/// # Safety
///
/// This function is unsafe for the same reasons that `alloc` is.
///
/// # Errors
///
/// Returning `Err` indicates that either memory is exhausted or
/// `layout` does not meet allocator's size or alignment
/// constraints, just as in `alloc`.
///
/// Clients wishing to abort computation in response to an
/// allocation error are encouraged to call the [`oom`] function,
/// rather than directly invoking `panic!` or similar.
unsafe fn alloc_zeroed(&mut self, layout: Layout) -> Result<NonNull<u8>, AllocErr> {
let size = layout.size();
let p = self.alloc(layout);
if let Ok(p) = p {
ptr::write_bytes(p.as_ptr(), 0, size);
}
p
}
/// Behaves like `alloc`, but also returns the whole size of
/// the returned block. For some `layout` inputs, like arrays, this
/// may include extra storage usable for additional data.
///
/// # Safety
///
/// This function is unsafe for the same reasons that `alloc` is.
///
/// # Errors
///
/// Returning `Err` indicates that either memory is exhausted or
/// `layout` does not meet allocator's size or alignment
/// constraints, just as in `alloc`.
///
/// Clients wishing to abort computation in response to an
/// allocation error are encouraged to call the [`oom`] function,
/// rather than directly invoking `panic!` or similar.
unsafe fn alloc_excess(&mut self, layout: Layout) -> Result<Excess, AllocErr> {
let usable_size = self.usable_size(&layout);
self.alloc(layout).map(|p| Excess(p, usable_size.1))
}
/// Behaves like `realloc`, but also returns the whole size of
/// the returned block. For some `layout` inputs, like arrays, this
/// may include extra storage usable for additional data.
///
/// # Safety
///
/// This function is unsafe for the same reasons that `realloc` is.
///
/// # Errors
///
/// Returning `Err` indicates that either memory is exhausted or
/// `layout` does not meet allocator's size or alignment
/// constraints, just as in `realloc`.
///
/// Clients wishing to abort computation in response to a
/// reallocation error are encouraged to call the [`oom`] function,
/// rather than directly invoking `panic!` or similar.
unsafe fn realloc_excess(&mut self,
ptr: NonNull<u8>,
layout: Layout,
new_size: usize) -> Result<Excess, AllocErr> {
let new_layout = Layout::from_size_align_unchecked(new_size, layout.align());
let usable_size = self.usable_size(&new_layout);
self.realloc(ptr, layout, new_size)
.map(|p| Excess(p, usable_size.1))
}
/// Attempts to extend the allocation referenced by `ptr` to fit `new_size`.
///
/// If this returns `Ok`, then the allocator has asserted that the
/// memory block referenced by `ptr` now fits `new_size`, and thus can
/// be used to carry data of a layout of that size and same alignment as
/// `layout`. (The allocator is allowed to
/// expend effort to accomplish this, such as extending the memory block to
/// include successor blocks, or virtual memory tricks.)
///
/// Regardless of what this method returns, ownership of the
/// memory block referenced by `ptr` has not been transferred, and
/// the contents of the memory block are unaltered.
///
/// # Safety
///
/// This function is unsafe because undefined behavior can result
/// if the caller does not ensure all of the following:
///
/// * `ptr` must be currently allocated via this allocator,
///
/// * `layout` must *fit* the `ptr` (see above); note the
/// `new_size` argument need not fit it,
///
/// * `new_size` must not be less than `layout.size()`,
///
/// # Errors
///
/// Returns `Err(CannotReallocInPlace)` when the allocator is
/// unable to assert that the memory block referenced by `ptr`
/// could fit `layout`.
///
/// Note that one cannot pass `CannotReallocInPlace` to the `oom`
/// function; clients are expected either to be able to recover from
/// `grow_in_place` failures without aborting, or to fall back on
/// another reallocation method before resorting to an abort.
unsafe fn grow_in_place(&mut self,
ptr: NonNull<u8>,
layout: Layout,
new_size: usize) -> Result<(), CannotReallocInPlace> {
let _ = ptr; // this default implementation doesn't care about the actual address.
debug_assert!(new_size >= layout.size());
let (_l, u) = self.usable_size(&layout);
// _l <= layout.size() [guaranteed by usable_size()]
// layout.size() <= new_layout.size() [required by this method]
if new_size <= u {
return Ok(());
} else {
return Err(CannotReallocInPlace);
}
}
/// Attempts to shrink the allocation referenced by `ptr` to fit `new_size`.
///
/// If this returns `Ok`, then the allocator has asserted that the
/// memory block referenced by `ptr` now fits `new_size`, and
/// thus can only be used to carry data of that smaller
/// layout. (The allocator is allowed to take advantage of this,
/// carving off portions of the block for reuse elsewhere.) The
/// truncated contents of the block within the smaller layout are
/// unaltered, and ownership of block has not been transferred.
///
/// If this returns `Err`, then the memory block is considered to
/// still represent the original (larger) `layout`. None of the
/// block has been carved off for reuse elsewhere, ownership of
/// the memory block has not been transferred, and the contents of
/// the memory block are unaltered.
///
/// # Safety
///
/// This function is unsafe because undefined behavior can result
/// if the caller does not ensure all of the following:
///
/// * `ptr` must be currently allocated via this allocator,
///
/// * `layout` must *fit* the `ptr` (see above); note the
/// `new_size` argument need not fit it,
///
/// * `new_size` must not be greater than `layout.size()`
/// (and must be greater than zero),
///
/// # Errors
///
/// Returns `Err(CannotReallocInPlace)` when the allocator is
/// unable to assert that the memory block referenced by `ptr`
/// could fit `layout`.
///
/// Note that one cannot pass `CannotReallocInPlace` to the `oom`
/// function; clients are expected either to be able to recover from
/// `shrink_in_place` failures without aborting, or to fall back
/// on another reallocation method before resorting to an abort.
unsafe fn shrink_in_place(&mut self,
ptr: NonNull<u8>,
layout: Layout,
new_size: usize) -> Result<(), CannotReallocInPlace> {
let _ = ptr; // this default implementation doesn't care about the actual address.
debug_assert!(new_size <= layout.size());
let (l, _u) = self.usable_size(&layout);
// layout.size() <= _u [guaranteed by usable_size()]
// new_layout.size() <= layout.size() [required by this method]
if l <= new_size {
return Ok(());
} else {
return Err(CannotReallocInPlace);
}
}
// == COMMON USAGE PATTERNS ==
// alloc_one, dealloc_one, alloc_array, realloc_array. dealloc_array
/// Allocates a block suitable for holding an instance of `T`.
///
/// Captures a common usage pattern for allocators.
///
/// The returned block is suitable for passing to the
/// `alloc`/`realloc` methods of this allocator.
///
/// Note to implementors: If this returns `Ok(ptr)`, then `ptr`
/// must be considered "currently allocated" and must be
/// acceptable input to methods such as `realloc` or `dealloc`,
/// *even if* `T` is a zero-sized type. In other words, if your
/// `Alloc` implementation overrides this method in a manner
/// that can return a zero-sized `ptr`, then all reallocation and
/// deallocation methods need to be similarly overridden to accept
/// such values as input.
///
/// # Errors
///
/// Returning `Err` indicates that either memory is exhausted or
/// `T` does not meet allocator's size or alignment constraints.
///
/// For zero-sized `T`, may return either of `Ok` or `Err`, but
/// will *not* yield undefined behavior.
///
/// Clients wishing to abort computation in response to an
/// allocation error are encouraged to call the [`oom`] function,
/// rather than directly invoking `panic!` or similar.
fn alloc_one<T>(&mut self) -> Result<NonNull<T>, AllocErr>
where Self: Sized
{
let k = Layout::new::<T>();
if k.size() > 0 {
unsafe { self.alloc(k).map(|p| p.cast()) }
} else {
Err(AllocErr)
}
}
/// Deallocates a block suitable for holding an instance of `T`.
///
/// The given block must have been produced by this allocator,
/// and must be suitable for storing a `T` (in terms of alignment
/// as well as minimum and maximum size); otherwise yields
/// undefined behavior.
///
/// Captures a common usage pattern for allocators.
///
/// # Safety
///
/// This function is unsafe because undefined behavior can result
/// if the caller does not ensure both:
///
/// * `ptr` must denote a block of memory currently allocated via this allocator
///
/// * the layout of `T` must *fit* that block of memory.
unsafe fn dealloc_one<T>(&mut self, ptr: NonNull<T>)
where Self: Sized
{
let k = Layout::new::<T>();
if k.size() > 0 {
self.dealloc(ptr.cast(), k);
}
}
/// Allocates a block suitable for holding `n` instances of `T`.
///
/// Captures a common usage pattern for allocators.
///
/// The returned block is suitable for passing to the
/// `alloc`/`realloc` methods of this allocator.
///
/// Note to implementors: If this returns `Ok(ptr)`, then `ptr`
/// must be considered "currently allocated" and must be
/// acceptable input to methods such as `realloc` or `dealloc`,
/// *even if* `T` is a zero-sized type. In other words, if your
/// `Alloc` implementation overrides this method in a manner
/// that can return a zero-sized `ptr`, then all reallocation and
/// deallocation methods need to be similarly overridden to accept
/// such values as input.
///
/// # Errors
///
/// Returning `Err` indicates that either memory is exhausted or
/// `[T; n]` does not meet allocator's size or alignment
/// constraints.
///
/// For zero-sized `T` or `n == 0`, may return either of `Ok` or
/// `Err`, but will *not* yield undefined behavior.
///
/// Always returns `Err` on arithmetic overflow.
///
/// Clients wishing to abort computation in response to an
/// allocation error are encouraged to call the [`oom`] function,
/// rather than directly invoking `panic!` or similar.
fn alloc_array<T>(&mut self, n: usize) -> Result<NonNull<T>, AllocErr>
where Self: Sized
{
match Layout::array::<T>(n) {
Ok(ref layout) if layout.size() > 0 => {
unsafe {
self.alloc(layout.clone()).map(|p| p.cast())
}
}
_ => Err(AllocErr),
}
}
/// Reallocates a block previously suitable for holding `n_old`
/// instances of `T`, returning a block suitable for holding
/// `n_new` instances of `T`.
///
/// Captures a common usage pattern for allocators.
///
/// The returned block is suitable for passing to the
/// `alloc`/`realloc` methods of this allocator.
///
/// # Safety
///
/// This function is unsafe because undefined behavior can result
/// if the caller does not ensure all of the following:
///
/// * `ptr` must be currently allocated via this allocator,
///
/// * the layout of `[T; n_old]` must *fit* that block of memory.
///
/// # Errors
///
/// Returning `Err` indicates that either memory is exhausted or
/// `[T; n_new]` does not meet allocator's size or alignment
/// constraints.
///
/// For zero-sized `T` or `n_new == 0`, may return either of `Ok` or
/// `Err`, but will *not* yield undefined behavior.
///
/// Always returns `Err` on arithmetic overflow.
///
/// Clients wishing to abort computation in response to a
/// reallocation error are encouraged to call the [`oom`] function,
/// rather than directly invoking `panic!` or similar.
unsafe fn realloc_array<T>(&mut self,
ptr: NonNull<T>,
n_old: usize,
n_new: usize) -> Result<NonNull<T>, AllocErr>
where Self: Sized
{
match (Layout::array::<T>(n_old), Layout::array::<T>(n_new)) {
(Ok(ref k_old), Ok(ref k_new)) if k_old.size() > 0 && k_new.size() > 0 => {
debug_assert!(k_old.align() == k_new.align());
self.realloc(ptr.cast(), k_old.clone(), k_new.size()).map(NonNull::cast)
}
_ => {
Err(AllocErr)
}
}
}
/// Deallocates a block suitable for holding `n` instances of `T`.
///
/// Captures a common usage pattern for allocators.
///
/// # Safety
///
/// This function is unsafe because undefined behavior can result
/// if the caller does not ensure both:
///
/// * `ptr` must denote a block of memory currently allocated via this allocator
///
/// * the layout of `[T; n]` must *fit* that block of memory.
///
/// # Errors
///
/// Returning `Err` indicates that either `[T; n]` or the given
/// memory block does not meet allocator's size or alignment
/// constraints.
///
/// Always returns `Err` on arithmetic overflow.
unsafe fn dealloc_array<T>(&mut self, ptr: NonNull<T>, n: usize) -> Result<(), AllocErr>
where Self: Sized
{
match Layout::array::<T>(n) {
Ok(ref k) if k.size() > 0 => {
Ok(self.dealloc(ptr.cast(), k.clone()))
}
_ => {
Err(AllocErr)
}
}
}
}