// Copyright 2012 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 or the MIT license // , at your // option. This file may not be copied, modified, or distributed // except according to those terms. // So we don't have to document the actual methods on the traits. #[allow(missing_doc)]; /*! * * Traits representing built-in operators, useful for overloading * * Implementing these traits allows you to get an effect similar to * overloading operators. * * The values for the right hand side of an operator are automatically * borrowed, so `a + b` is sugar for `a.add(&b)`. * * All of these traits are imported by the prelude, so they are available in * every Rust program. * * # Example * * This example creates a `Point` struct that implements `Add` and `Sub`, and then * demonstrates adding and subtracting two `Point`s. * * ```rust * struct Point { * x: int, * y: int * } * * impl Add for Point { * fn add(&self, other: &Point) -> Point { * Point {x: self.x + other.x, y: self.y + other.y} * } * } * * impl Sub for Point { * fn sub(&self, other: &Point) -> Point { * Point {x: self.x - other.x, y: self.y - other.y} * } * } * fn main() { * println!("{:?}", Point {x: 1, y: 0} + Point {x: 2, y: 3}); * println!("{:?}", Point {x: 1, y: 0} - Point {x: 2, y: 3}); * } * ``` * * See the documentation for each trait for a minimum implementation that prints * something to the screen. * */ /** * * The `Drop` trait is used to run some code when a value goes out of scope. This * is sometimes called a 'destructor'. * * # Example * * A trivial implementation of `Drop`. The `drop` method is called when `_x` goes * out of scope, and therefore `main` prints `Dropping!`. * * ```rust * struct HasDrop; * * impl Drop for HasDrop { * fn drop(&mut self) { * println!("Dropping!"); * } * } * * fn main() { * let _x = HasDrop; * } * ``` */ #[lang="drop"] pub trait Drop { fn drop(&mut self); } /** * * The `Add` trait is used to specify the functionality of `+`. * * # Example * * A trivial implementation of `Add`. When `Foo + Foo` happens, it ends up * calling `add`, and therefore, `main` prints `Adding!`. * * ```rust * struct Foo; * * impl Add for Foo { * fn add(&self, _rhs: &Foo) -> Foo { * println!("Adding!"); * *self * } * } * * fn main() { * Foo + Foo; * } * ``` */ #[lang="add"] pub trait Add { fn add(&self, rhs: &RHS) -> Result; } /** * * The `Sub` trait is used to specify the functionality of `-`. * * # Example * * A trivial implementation of `Sub`. When `Foo - Foo` happens, it ends up * calling `sub`, and therefore, `main` prints `Subtracting!`. * * ```rust * struct Foo; * * impl Sub for Foo { * fn sub(&self, _rhs: &Foo) -> Foo { * println!("Subtracting!"); * *self * } * } * * fn main() { * Foo - Foo; * } * ``` */ #[lang="sub"] pub trait Sub { fn sub(&self, rhs: &RHS) -> Result; } /** * * The `Mul` trait is used to specify the functionality of `*`. * * # Example * * A trivial implementation of `Mul`. When `Foo * Foo` happens, it ends up * calling `mul`, and therefore, `main` prints `Multiplying!`. * * ```rust * struct Foo; * * impl Mul for Foo { * fn mul(&self, _rhs: &Foo) -> Foo { * println!("Multiplying!"); * *self * } * } * * fn main() { * Foo * Foo; * } * ``` */ #[lang="mul"] pub trait Mul { fn mul(&self, rhs: &RHS) -> Result; } /** * * The `Div` trait is used to specify the functionality of `/`. * * # Example * * A trivial implementation of `Div`. When `Foo / Foo` happens, it ends up * calling `div`, and therefore, `main` prints `Dividing!`. * * ``` * struct Foo; * * impl Div for Foo { * fn div(&self, _rhs: &Foo) -> Foo { * println!("Dividing!"); * *self * } * } * * fn main() { * Foo / Foo; * } * ``` */ #[lang="div"] pub trait Div { fn div(&self, rhs: &RHS) -> Result; } /** * * The `Rem` trait is used to specify the functionality of `%`. * * # Example * * A trivial implementation of `Rem`. When `Foo % Foo` happens, it ends up * calling `rem`, and therefore, `main` prints `Remainder-ing!`. * * ``` * struct Foo; * * impl Rem for Foo { * fn rem(&self, _rhs: &Foo) -> Foo { * println!("Remainder-ing!"); * *self * } * } * * fn main() { * Foo % Foo; * } * ``` */ #[lang="rem"] pub trait Rem { fn rem(&self, rhs: &RHS) -> Result; } /** * * The `Neg` trait is used to specify the functionality of unary `-`. * * # Example * * A trivial implementation of `Neg`. When `-Foo` happens, it ends up calling * `neg`, and therefore, `main` prints `Negating!`. * * ``` * struct Foo; * * impl Neg for Foo { * fn neg(&self) -> Foo { * println!("Negating!"); * *self * } * } * * fn main() { * -Foo; * } * ``` */ #[lang="neg"] pub trait Neg { fn neg(&self) -> Result; } /** * * The `Not` trait is used to specify the functionality of unary `!`. * * # Example * * A trivial implementation of `Not`. When `!Foo` happens, it ends up calling * `not`, and therefore, `main` prints `Not-ing!`. * * ``` * struct Foo; * * impl Not for Foo { * fn not(&self) -> Foo { * println!("Not-ing!"); * *self * } * } * * fn main() { * !Foo; * } * ``` */ #[lang="not"] pub trait Not { fn not(&self) -> Result; } /** * * The `BitAnd` trait is used to specify the functionality of `&`. * * # Example * * A trivial implementation of `BitAnd`. When `Foo & Foo` happens, it ends up * calling `bitand`, and therefore, `main` prints `Bitwise And-ing!`. * * ``` * struct Foo; * * impl BitAnd for Foo { * fn bitand(&self, _rhs: &Foo) -> Foo { * println!("Bitwise And-ing!"); * *self * } * } * * fn main() { * Foo & Foo; * } * ``` */ #[lang="bitand"] pub trait BitAnd { fn bitand(&self, rhs: &RHS) -> Result; } /** * * The `BitOr` trait is used to specify the functionality of `|`. * * # Example * * A trivial implementation of `BitOr`. When `Foo | Foo` happens, it ends up * calling `bitor`, and therefore, `main` prints `Bitwise Or-ing!`. * * ``` * struct Foo; * * impl BitOr for Foo { * fn bitor(&self, _rhs: &Foo) -> Foo { * println!("Bitwise Or-ing!"); * *self * } * } * * fn main() { * Foo | Foo; * } * ``` */ #[lang="bitor"] pub trait BitOr { fn bitor(&self, rhs: &RHS) -> Result; } /** * * The `BitXor` trait is used to specify the functionality of `^`. * * # Example * * A trivial implementation of `BitXor`. When `Foo ^ Foo` happens, it ends up * calling `bitxor`, and therefore, `main` prints `Bitwise Xor-ing!`. * * ``` * struct Foo; * * impl BitXor for Foo { * fn bitxor(&self, _rhs: &Foo) -> Foo { * println!("Bitwise Xor-ing!"); * *self * } * } * * fn main() { * Foo ^ Foo; * } * ``` */ #[lang="bitxor"] pub trait BitXor { fn bitxor(&self, rhs: &RHS) -> Result; } /** * * The `Shl` trait is used to specify the functionality of `<<`. * * # Example * * A trivial implementation of `Shl`. When `Foo << Foo` happens, it ends up * calling `shl`, and therefore, `main` prints `Shifting left!`. * * ``` * struct Foo; * * impl Shl for Foo { * fn shl(&self, _rhs: &Foo) -> Foo { * println!("Shifting left!"); * *self * } * } * * fn main() { * Foo << Foo; * } * ``` */ #[lang="shl"] pub trait Shl { fn shl(&self, rhs: &RHS) -> Result; } /** * * The `Shr` trait is used to specify the functionality of `>>`. * * # Example * * A trivial implementation of `Shr`. When `Foo >> Foo` happens, it ends up * calling `shr`, and therefore, `main` prints `Shifting right!`. * * ``` * struct Foo; * * impl Shr for Foo { * fn shr(&self, _rhs: &Foo) -> Foo { * println!("Shifting right!"); * *self * } * } * * fn main() { * Foo >> Foo; * } * ``` */ #[lang="shr"] pub trait Shr { fn shr(&self, rhs: &RHS) -> Result; } /** * * The `Index` trait is used to specify the functionality of indexing operations * like `arr[idx]`. * * # Example * * A trivial implementation of `Index`. When `Foo[Foo]` happens, it ends up * calling `index`, and therefore, `main` prints `Indexing!`. * * ``` * struct Foo; * * impl Index for Foo { * fn index(&self, _rhs: &Foo) -> Foo { * println!("Indexing!"); * *self * } * } * * fn main() { * Foo[Foo]; * } * ``` */ #[lang="index"] pub trait Index { fn index(&self, index: &Index) -> Result; } #[cfg(test)] mod bench { extern crate test; use self::test::BenchHarness; use ops::Drop; // Overhead of dtors struct HasDtor { x: int } impl Drop for HasDtor { fn drop(&mut self) { } } #[bench] fn alloc_obj_with_dtor(bh: &mut BenchHarness) { bh.iter(|| { HasDtor { x : 10 }; }) } }