// Copyright 2014-2016 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. //! A collection of numeric types and traits for Rust. //! //! This includes new types for big integers, rationals, and complex numbers, //! new traits for generic programming on numeric properties like `Integer`, //! and generic range iterators. //! //! ## Example //! //! This example uses the BigRational type and [Newton's method][newt] to //! approximate a square root to arbitrary precision: //! //! ``` //! extern crate num; //! # #[cfg(all(feature = "bigint", feature="rational"))] //! # mod test { //! //! use num::FromPrimitive; //! use num::bigint::BigInt; //! use num::rational::{Ratio, BigRational}; //! //! # pub //! fn approx_sqrt(number: u64, iterations: usize) -> BigRational { //! let start: Ratio = Ratio::from_integer(FromPrimitive::from_u64(number).unwrap()); //! let mut approx = start.clone(); //! //! for _ in 0..iterations { //! approx = (&approx + (&start / &approx)) / //! Ratio::from_integer(FromPrimitive::from_u64(2).unwrap()); //! } //! //! approx //! } //! # } //! # #[cfg(not(all(feature = "bigint", feature="rational")))] //! # mod test { pub fn approx_sqrt(n: u64, _: usize) -> u64 { n } } //! # use test::approx_sqrt; //! //! fn main() { //! println!("{}", approx_sqrt(10, 4)); // prints 4057691201/1283082416 //! } //! //! ``` //! //! [newt]: https://en.wikipedia.org/wiki/Methods_of_computing_square_roots#Babylonian_method #![doc(html_logo_url = "http://rust-num.github.io/num/rust-logo-128x128-blk-v2.png", html_favicon_url = "http://rust-num.github.io/num/favicon.ico", html_root_url = "http://rust-num.github.io/num/", html_playground_url = "http://play.rust-lang.org/")] pub extern crate num_traits; pub extern crate num_integer; pub extern crate num_iter; #[cfg(feature = "num-complex")] pub extern crate num_complex; #[cfg(feature = "num-bigint")] pub extern crate num_bigint; #[cfg(feature = "num-rational")] pub extern crate num_rational; #[cfg(feature = "rustc-serialize")] extern crate rustc_serialize; // Some of the tests of non-RNG-based functionality are randomized using the // RNG-based functionality, so the RNG-based functionality needs to be enabled // for tests. #[cfg(any(feature = "rand", all(feature = "bigint", test)))] extern crate rand; #[cfg(feature = "serde")] extern crate serde; #[cfg(feature = "num-bigint")] pub use bigint::{BigInt, BigUint}; #[cfg(feature = "num-rational")] pub use rational::Rational; #[cfg(all(feature = "num-rational", feature="num-bigint"))] pub use rational::BigRational; #[cfg(feature = "num-complex")] pub use complex::Complex; pub use integer::Integer; pub use iter::{range, range_inclusive, range_step, range_step_inclusive}; pub use traits::{Num, Zero, One, Signed, Unsigned, Bounded, Saturating, CheckedAdd, CheckedSub, CheckedMul, CheckedDiv, PrimInt, Float, ToPrimitive, FromPrimitive, NumCast, cast}; #[cfg(test)] use std::hash; use std::ops::{Mul}; #[cfg(feature = "num-bigint")] pub use num_bigint as bigint; pub use num_complex as complex; pub use num_integer as integer; pub use num_iter as iter; pub use num_traits as traits; #[cfg(feature = "num-rational")] pub use num_rational as rational; /// Returns the additive identity, `0`. #[inline(always)] pub fn zero() -> T { Zero::zero() } /// Returns the multiplicative identity, `1`. #[inline(always)] pub fn one() -> T { One::one() } /// Computes the absolute value. /// /// For `f32` and `f64`, `NaN` will be returned if the number is `NaN` /// /// For signed integers, `::MIN` will be returned if the number is `::MIN`. #[inline(always)] pub fn abs(value: T) -> T { value.abs() } /// The positive difference of two numbers. /// /// Returns zero if `x` is less than or equal to `y`, otherwise the difference /// between `x` and `y` is returned. #[inline(always)] pub fn abs_sub(x: T, y: T) -> T { x.abs_sub(&y) } /// Returns the sign of the number. /// /// For `f32` and `f64`: /// /// * `1.0` if the number is positive, `+0.0` or `INFINITY` /// * `-1.0` if the number is negative, `-0.0` or `NEG_INFINITY` /// * `NaN` if the number is `NaN` /// /// For signed integers: /// /// * `0` if the number is zero /// * `1` if the number is positive /// * `-1` if the number is negative #[inline(always)] pub fn signum(value: T) -> T { value.signum() } /// Raises a value to the power of exp, using exponentiation by squaring. /// /// # Example /// /// ```rust /// use num; /// /// assert_eq!(num::pow(2i8, 4), 16); /// assert_eq!(num::pow(6u8, 3), 216); /// ``` #[inline] pub fn pow>(mut base: T, mut exp: usize) -> T { if exp == 0 { return T::one() } while exp & 1 == 0 { base = base.clone() * base; exp >>= 1; } if exp == 1 { return base } let mut acc = base.clone(); while exp > 1 { exp >>= 1; base = base.clone() * base; if exp & 1 == 1 { acc = acc * base.clone(); } } acc } /// Raises a value to the power of exp, returning `None` if an overflow occurred. /// /// Otherwise same as the `pow` function. /// /// # Example /// /// ```rust /// use num; /// /// assert_eq!(num::checked_pow(2i8, 4), Some(16)); /// assert_eq!(num::checked_pow(7i8, 8), None); /// assert_eq!(num::checked_pow(7u32, 8), Some(5_764_801)); /// ``` #[inline] pub fn checked_pow(mut base: T, mut exp: usize) -> Option { if exp == 0 { return Some(T::one()) } macro_rules! optry { ( $ expr : expr ) => { if let Some(val) = $expr { val } else { return None } } } while exp & 1 == 0 { base = optry!(base.checked_mul(&base)); exp >>= 1; } if exp == 1 { return Some(base) } let mut acc = base.clone(); while exp > 1 { exp >>= 1; base = optry!(base.checked_mul(&base)); if exp & 1 == 1 { acc = optry!(acc.checked_mul(&base)); } } Some(acc) }