src/libcore/raw.rs - third_party/rust - Git at Google

 #![allow(missing_docs)]
 #![unstable(feature = "raw", issue = "27751")]

 //! Contains struct definitions for the layout of compiler built-in types.
 //!
 //! They can be used as targets of transmutes in unsafe code for manipulating
 //! the raw representations directly.
 //!
 //! Their definition should always match the ABI defined in `rustc::back::abi`.

 /// The representation of a trait object like `&SomeTrait`.
 ///
 /// This struct has the same layout as types like `&SomeTrait` and
 /// `Box<dyn AnotherTrait>`.
 ///
 /// `TraitObject` is guaranteed to match layouts, but it is not the
 /// type of trait objects (e.g., the fields are not directly accessible
 /// on a `&SomeTrait`) nor does it control that layout (changing the
 /// definition will not change the layout of a `&SomeTrait`). It is
 /// only designed to be used by unsafe code that needs to manipulate
 /// the low-level details.
 ///
 /// There is no way to refer to all trait objects generically, so the only
 /// way to create values of this type is with functions like
 /// [`std::mem::transmute`][transmute]. Similarly, the only way to create a true
 /// trait object from a `TraitObject` value is with `transmute`.
 ///
 /// [transmute]: ../intrinsics/fn.transmute.html
 ///
 /// Synthesizing a trait object with mismatched types—one where the
 /// vtable does not correspond to the type of the value to which the
 /// data pointer points—is highly likely to lead to undefined
 /// behavior.
 ///
 /// # Examples
 ///
 /// ```
 /// #![feature(raw)]
 ///
 /// use std::{mem, raw};
 ///
 /// // an example trait
 /// trait Foo {
 ///     fn bar(&self) -> i32;
 /// }
 ///
 /// impl Foo for i32 {
 ///     fn bar(&self) -> i32 {
 ///          *self + 1
 ///     }
 /// }
 ///
 /// let value: i32 = 123;
 ///
 /// // let the compiler make a trait object
 /// let object: &dyn Foo = &value;
 ///
 /// // look at the raw representation
 /// let raw_object: raw::TraitObject = unsafe { mem::transmute(object) };
 ///
 /// // the data pointer is the address of `value`
 /// assert_eq!(raw_object.data as *const i32, &value as *const _);
 ///
 /// let other_value: i32 = 456;
 ///
 /// // construct a new object, pointing to a different `i32`, being
 /// // careful to use the `i32` vtable from `object`
 /// let synthesized: &dyn Foo = unsafe {
 ///      mem::transmute(raw::TraitObject {
 ///          data: &other_value as *const _ as *mut (),
 ///          vtable: raw_object.vtable,
 ///      })
 /// };
 ///
 /// // it should work just as if we had constructed a trait object out of
 /// // `other_value` directly
 /// assert_eq!(synthesized.bar(), 457);
 /// ```
 #[repr(C)]
 #[derive(Copy, Clone)]
 #[allow(missing_debug_implementations)]
 pub struct TraitObject {
     pub data: *mut (),
     pub vtable: *mut (),
 }
	#![allow(missing_docs)]
	#![unstable(feature = "raw", issue = "27751")]

	//! Contains struct definitions for the layout of compiler built-in types.
	//!
	//! They can be used as targets of transmutes in unsafe code for manipulating
	//! the raw representations directly.
	//!
	//! Their definition should always match the ABI defined in `rustc::back::abi`.

	/// The representation of a trait object like `&SomeTrait`.
	///
	/// This struct has the same layout as types like `&SomeTrait` and
	/// `Box<dyn AnotherTrait>`.
	///
	/// `TraitObject` is guaranteed to match layouts, but it is not the
	/// type of trait objects (e.g., the fields are not directly accessible
	/// on a `&SomeTrait`) nor does it control that layout (changing the
	/// definition will not change the layout of a `&SomeTrait`). It is
	/// only designed to be used by unsafe code that needs to manipulate
	/// the low-level details.
	///
	/// There is no way to refer to all trait objects generically, so the only
	/// way to create values of this type is with functions like
	/// [`std::mem::transmute`][transmute]. Similarly, the only way to create a true
	/// trait object from a `TraitObject` value is with `transmute`.
	///
	/// [transmute]: ../intrinsics/fn.transmute.html
	///
	/// Synthesizing a trait object with mismatched types—one where the
	/// vtable does not correspond to the type of the value to which the
	/// data pointer points—is highly likely to lead to undefined
	/// behavior.
	///
	/// # Examples
	///
	/// ```
	/// #![feature(raw)]
	///
	/// use std::{mem, raw};
	///
	/// // an example trait
	/// trait Foo {
	/// fn bar(&self) -> i32;
	/// }
	///
	/// impl Foo for i32 {
	/// fn bar(&self) -> i32 {
	/// *self + 1
	/// }
	/// }
	///
	/// let value: i32 = 123;
	///
	/// // let the compiler make a trait object
	/// let object: &dyn Foo = &value;
	///
	/// // look at the raw representation
	/// let raw_object: raw::TraitObject = unsafe { mem::transmute(object) };
	///
	/// // the data pointer is the address of `value`
	/// assert_eq!(raw_object.data as const i32, &value as const _);
	///
	/// let other_value: i32 = 456;
	///
	/// // construct a new object, pointing to a different `i32`, being
	/// // careful to use the `i32` vtable from `object`
	/// let synthesized: &dyn Foo = unsafe {
	/// mem::transmute(raw::TraitObject {
	/// data: &other_value as const _ as mut (),
	/// vtable: raw_object.vtable,
	/// })
	/// };
	///
	/// // it should work just as if we had constructed a trait object out of
	/// // `other_value` directly
	/// assert_eq!(synthesized.bar(), 457);
	/// ```
	#[repr(C)]
	#[derive(Copy, Clone)]
	#[allow(missing_debug_implementations)]
	pub struct TraitObject {
	pub data: *mut (),
	pub vtable: *mut (),
	}