1ed646eaf7
Libcore's test infrastructure is complicated by the fact that many lang items are defined in the crate. The current approach (realcore/realstd imports) is hacky and hard to work with (tests inside of core::cmp haven't been run for months!). Moving tests to a separate crate does mean that they can only test the public API of libcore, but I don't feel that that is too much of an issue. The only tests that I had to get rid of were some checking the various numeric formatters, but those are also exercised through normal format! calls in other tests.
384 lines
12 KiB
Rust
384 lines
12 KiB
Rust
// Copyright 2012-2014 The Rust Project Developers. See the COPYRIGHT
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// file at the top-level directory of this distribution and at
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// http://rust-lang.org/COPYRIGHT.
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//
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// Licensed under the Apache License, Version 2.0 <LICENSE-APACHE or
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// http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
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// <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your
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// option. This file may not be copied, modified, or distributed
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// except according to those terms.
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//! Basic functions for dealing with memory
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//!
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//! This module contains functions for querying the size and alignment of
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//! types, initializing and manipulating memory.
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use intrinsics;
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use num::Int;
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use ptr;
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pub use intrinsics::transmute;
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/// Returns the size of a type in bytes.
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#[inline]
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#[stable]
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pub fn size_of<T>() -> uint {
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unsafe { intrinsics::size_of::<T>() }
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}
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/// Returns the size of the type that `_val` points to in bytes.
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#[inline]
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#[stable]
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pub fn size_of_val<T>(_val: &T) -> uint {
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size_of::<T>()
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}
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/// Deprecated, this function will be removed soon
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#[inline]
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#[deprecated = "this function will be removed soon"]
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pub fn nonzero_size_of<T>() -> uint {
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match size_of::<T>() {
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0 => 1,
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n => n,
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}
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}
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/// Deprecated, this function will be removed soon
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#[inline]
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#[deprecated = "this function will be removed soon"]
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pub fn nonzero_size_of_val<T>(val: &T) -> uint {
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match size_of_val::<T>(val) {
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0 => 1,
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n => n,
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}
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}
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/// Returns the ABI-required minimum alignment of a type
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///
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/// This is the alignment used for struct fields. It may be smaller
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/// than the preferred alignment.
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#[inline]
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#[stable]
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pub fn min_align_of<T>() -> uint {
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unsafe { intrinsics::min_align_of::<T>() }
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}
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/// Returns the ABI-required minimum alignment of the type of the value that
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/// `_val` points to
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#[inline]
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#[stable]
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pub fn min_align_of_val<T>(_val: &T) -> uint {
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min_align_of::<T>()
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}
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/// Returns the alignment in memory for a type.
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///
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/// This function will return the alignment, in bytes, of a type in memory. If
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/// the alignment returned is adhered to, then the type is guaranteed to
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/// function properly.
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#[inline]
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#[stable]
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pub fn align_of<T>() -> uint {
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// We use the preferred alignment as the default alignment for a type. This
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// appears to be what clang migrated towards as well:
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//
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// http://lists.cs.uiuc.edu/pipermail/cfe-commits/Week-of-Mon-20110725/044411.html
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unsafe { intrinsics::pref_align_of::<T>() }
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}
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/// Returns the alignment of the type of the value that `_val` points to.
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///
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/// This is similar to `align_of`, but function will properly handle types such
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/// as trait objects (in the future), returning the alignment for an arbitrary
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/// value at runtime.
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#[inline]
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#[stable]
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pub fn align_of_val<T>(_val: &T) -> uint {
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align_of::<T>()
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}
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/// Deprecated, this function has been renamed to align_of
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#[inline]
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#[deprecated = "use mem::align_of instead"]
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pub fn pref_align_of<T>() -> uint { align_of::<T>() }
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/// Deprecated, this function has been renamed to align_of_val
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#[inline]
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#[deprecated = "use mem::align_of_val instead"]
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pub fn pref_align_of_val<T>(val: &T) -> uint { align_of_val(val) }
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/// Create a value initialized to zero.
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///
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/// This function is similar to allocating space for a a local variable and
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/// zeroing it out (an unsafe operation).
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///
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/// Care must be taken when using this function, if the type `T` has a
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/// destructor and the value falls out of scope (due to unwinding or returning)
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/// before being initialized, then the destructor will run on zeroed
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/// data, likely leading to crashes.
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///
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/// This is useful for FFI functions sometimes, but should generally be avoided.
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#[inline]
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#[stable]
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pub unsafe fn zeroed<T>() -> T {
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intrinsics::init()
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}
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/// Deprecated, use zeroed() instead
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#[inline]
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#[deprecated = "this function has been renamed to zeroed()"]
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pub unsafe fn init<T>() -> T { zeroed() }
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/// Create an uninitialized value.
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///
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/// Care must be taken when using this function, if the type `T` has a
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/// destructor and the value falls out of scope (due to unwinding or returning)
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/// before being initialized, then the destructor will run on uninitialized
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/// data, likely leading to crashes.
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///
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/// This is useful for FFI functions sometimes, but should generally be avoided.
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#[inline]
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#[stable]
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pub unsafe fn uninitialized<T>() -> T {
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intrinsics::uninit()
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}
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/// Deprecated, use `uninitialized` instead.
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#[inline]
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#[deprecated = "this function has been renamed to `uninitialized`"]
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pub unsafe fn uninit<T>() -> T {
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intrinsics::uninit()
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}
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/// Unsafely overwrite a memory location with the given value without destroying
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/// the old value.
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///
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/// This operation is unsafe because it does not destroy the previous value
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/// contained at the location `dst`. This could leak allocations or resources,
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/// so care must be taken to previously deallocate the value at `dst`.
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#[inline]
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#[deprecated = "use ptr::write"]
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pub unsafe fn overwrite<T>(dst: *mut T, src: T) {
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intrinsics::move_val_init(&mut *dst, src)
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}
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/// Deprecated, use `overwrite` instead
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#[inline]
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#[deprecated = "use ptr::write"]
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pub unsafe fn move_val_init<T>(dst: &mut T, src: T) {
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ptr::write(dst, src)
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}
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/// Convert an u16 to little endian from the target's endianness.
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///
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/// On little endian, this is a no-op. On big endian, the bytes are swapped.
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#[inline]
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#[deprecated = "use `Int::to_le` instead"]
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pub fn to_le16(x: u16) -> u16 { x.to_le() }
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/// Convert an u32 to little endian from the target's endianness.
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///
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/// On little endian, this is a no-op. On big endian, the bytes are swapped.
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#[inline]
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#[deprecated = "use `Int::to_le` instead"]
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pub fn to_le32(x: u32) -> u32 { x.to_le() }
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/// Convert an u64 to little endian from the target's endianness.
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///
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/// On little endian, this is a no-op. On big endian, the bytes are swapped.
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#[inline]
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#[deprecated = "use `Int::to_le` instead"]
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pub fn to_le64(x: u64) -> u64 { x.to_le() }
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/// Convert an u16 to big endian from the target's endianness.
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///
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/// On big endian, this is a no-op. On little endian, the bytes are swapped.
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#[inline]
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#[deprecated = "use `Int::to_be` instead"]
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pub fn to_be16(x: u16) -> u16 { x.to_be() }
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/// Convert an u32 to big endian from the target's endianness.
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///
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/// On big endian, this is a no-op. On little endian, the bytes are swapped.
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#[inline]
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#[deprecated = "use `Int::to_be` instead"]
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pub fn to_be32(x: u32) -> u32 { x.to_be() }
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/// Convert an u64 to big endian from the target's endianness.
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///
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/// On big endian, this is a no-op. On little endian, the bytes are swapped.
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#[inline]
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#[deprecated = "use `Int::to_be` instead"]
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pub fn to_be64(x: u64) -> u64 { x.to_be() }
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/// Convert an u16 from little endian to the target's endianness.
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///
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/// On little endian, this is a no-op. On big endian, the bytes are swapped.
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#[inline]
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#[deprecated = "use `Int::from_le` instead"]
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pub fn from_le16(x: u16) -> u16 { Int::from_le(x) }
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/// Convert an u32 from little endian to the target's endianness.
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///
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/// On little endian, this is a no-op. On big endian, the bytes are swapped.
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#[inline]
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#[deprecated = "use `Int::from_le` instead"]
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pub fn from_le32(x: u32) -> u32 { Int::from_le(x) }
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/// Convert an u64 from little endian to the target's endianness.
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///
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/// On little endian, this is a no-op. On big endian, the bytes are swapped.
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#[inline]
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#[deprecated = "use `Int::from_le` instead"]
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pub fn from_le64(x: u64) -> u64 { Int::from_le(x) }
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/// Convert an u16 from big endian to the target's endianness.
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///
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/// On big endian, this is a no-op. On little endian, the bytes are swapped.
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#[inline]
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#[deprecated = "use `Int::from_be` instead"]
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pub fn from_be16(x: u16) -> u16 { Int::from_be(x) }
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/// Convert an u32 from big endian to the target's endianness.
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///
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/// On big endian, this is a no-op. On little endian, the bytes are swapped.
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#[inline]
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#[deprecated = "use `Int::from_be` instead"]
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pub fn from_be32(x: u32) -> u32 { Int::from_be(x) }
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/// Convert an u64 from big endian to the target's endianness.
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///
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/// On big endian, this is a no-op. On little endian, the bytes are swapped.
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#[inline]
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#[deprecated = "use `Int::from_be` instead"]
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pub fn from_be64(x: u64) -> u64 { Int::from_be(x) }
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/// Swap the values at two mutable locations of the same type, without
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/// deinitialising or copying either one.
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#[inline]
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#[stable]
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pub fn swap<T>(x: &mut T, y: &mut T) {
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unsafe {
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// Give ourselves some scratch space to work with
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let mut t: T = uninitialized();
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// Perform the swap, `&mut` pointers never alias
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ptr::copy_nonoverlapping_memory(&mut t, &*x, 1);
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ptr::copy_nonoverlapping_memory(x, &*y, 1);
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ptr::copy_nonoverlapping_memory(y, &t, 1);
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// y and t now point to the same thing, but we need to completely forget `t`
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// because it's no longer relevant.
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forget(t);
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}
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}
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/// Replace the value at a mutable location with a new one, returning the old
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/// value, without deinitialising or copying either one.
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///
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/// This is primarily used for transferring and swapping ownership of a value
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/// in a mutable location. For example, this function allows consumption of
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/// one field of a struct by replacing it with another value. The normal approach
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/// doesn't always work:
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///
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/// ```rust,ignore
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/// struct Buffer<T> { buf: Vec<T> }
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///
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/// impl<T> Buffer<T> {
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/// fn get_and_reset(&mut self) -> Vec<T> {
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/// // error: cannot move out of dereference of `&mut`-pointer
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/// let buf = self.buf;
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/// self.buf = Vec::new();
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/// buf
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/// }
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/// }
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/// ```
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///
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/// Note that `T` does not necessarily implement `Clone`, so it can't even
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/// clone and reset `self.buf`. But `replace` can be used to disassociate
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/// the original value of `self.buf` from `self`, allowing it to be returned:
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///
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/// ```rust
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/// # struct Buffer<T> { buf: Vec<T> }
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/// impl<T> Buffer<T> {
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/// fn get_and_reset(&mut self) -> Vec<T> {
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/// use std::mem::replace;
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/// replace(&mut self.buf, Vec::new())
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/// }
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/// }
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/// ```
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#[inline]
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#[stable]
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pub fn replace<T>(dest: &mut T, mut src: T) -> T {
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swap(dest, &mut src);
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src
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}
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/// Disposes of a value.
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///
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/// This function can be used to destroy any value by allowing `drop` to take
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/// ownership of its argument.
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///
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/// # Example
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///
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/// ```
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/// use std::cell::RefCell;
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///
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/// let x = RefCell::new(1i);
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///
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/// let mut mutable_borrow = x.borrow_mut();
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/// *mutable_borrow = 1;
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/// drop(mutable_borrow); // relinquish the mutable borrow on this slot
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///
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/// let borrow = x.borrow();
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/// println!("{}", *borrow);
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/// ```
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#[inline]
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#[stable]
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pub fn drop<T>(_x: T) { }
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/// Moves a thing into the void.
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///
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/// The forget function will take ownership of the provided value but neglect
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/// to run any required cleanup or memory management operations on it.
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///
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/// This function is the unsafe version of the `drop` function because it does
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/// not run any destructors.
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#[inline]
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#[stable]
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pub unsafe fn forget<T>(thing: T) { intrinsics::forget(thing) }
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/// Interprets `src` as `&U`, and then reads `src` without moving the contained
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/// value.
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///
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/// This function will unsafely assume the pointer `src` is valid for
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/// `sizeof(U)` bytes by transmuting `&T` to `&U` and then reading the `&U`. It
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/// will also unsafely create a copy of the contained value instead of moving
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/// out of `src`.
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///
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/// It is not a compile-time error if `T` and `U` have different sizes, but it
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/// is highly encouraged to only invoke this function where `T` and `U` have the
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/// same size. This function triggers undefined behavior if `U` is larger than
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/// `T`.
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#[inline]
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#[stable]
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pub unsafe fn transmute_copy<T, U>(src: &T) -> U {
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ptr::read(src as *const T as *const U)
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}
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/// Transforms lifetime of the second pointer to match the first.
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#[inline]
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#[unstable = "this function may be removed in the future due to its \
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questionable utility"]
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pub unsafe fn copy_lifetime<'a, S, T>(_ptr: &'a S, ptr: &T) -> &'a T {
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transmute(ptr)
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}
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/// Transforms lifetime of the second mutable pointer to match the first.
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#[inline]
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#[unstable = "this function may be removed in the future due to its \
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questionable utility"]
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pub unsafe fn copy_mut_lifetime<'a, S, T>(_ptr: &'a mut S,
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ptr: &mut T) -> &'a mut T {
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transmute(ptr)
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}
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