Module ndarray_rand::rand::distributions::uniform [−][src]
A distribution uniformly sampling numbers within a given range.
Uniform
is the standard distribution to sample uniformly from a range;
e.g. Uniform::new_inclusive(1, 6)
can sample integers from 1 to 6, like a
standard die. Rng::gen_range
supports any type supported by
Uniform
.
This distribution is provided with support for several primitive types
(all integer and floating-point types) as well as std::time::Duration
,
and supports extension to user-defined types via a type-specific back-end
implementation.
The types UniformInt
, UniformFloat
and UniformDuration
are the
back-ends supporting sampling from primitive integer and floating-point
ranges as well as from std::time::Duration
; these types do not normally
need to be used directly (unless implementing a derived back-end).
Example usage
use rand::{Rng, thread_rng}; use rand::distributions::Uniform; let mut rng = thread_rng(); let side = Uniform::new(-10.0, 10.0); // sample between 1 and 10 points for _ in 0..rng.gen_range(1..=10) { // sample a point from the square with sides -10 - 10 in two dimensions let (x, y) = (rng.sample(side), rng.sample(side)); println!("Point: {}, {}", x, y); }
Extending Uniform
to support a custom type
To extend Uniform
to support your own types, write a back-end which
implements the UniformSampler
trait, then implement the SampleUniform
helper trait to “register” your back-end. See the MyF32
example below.
At a minimum, the back-end needs to store any parameters needed for sampling
(e.g. the target range) and implement new
, new_inclusive
and sample
.
Those methods should include an assert to check the range is valid (i.e.
low < high
). The example below merely wraps another back-end.
The new
, new_inclusive
and sample_single
functions use arguments of
type SampleBorrowSampleBorrow::borrow
, or you can choose
to copy or clone the value, whatever is appropriate for your type.
use rand::prelude::*; use rand::distributions::uniform::{Uniform, SampleUniform, UniformSampler, UniformFloat, SampleBorrow}; struct MyF32(f32); #[derive(Clone, Copy, Debug)] struct UniformMyF32(UniformFloat<f32>); impl UniformSampler for UniformMyF32 { type X = MyF32; fn new<B1, B2>(low: B1, high: B2) -> Self where B1: SampleBorrow<Self::X> + Sized, B2: SampleBorrow<Self::X> + Sized { UniformMyF32(UniformFloat::<f32>::new(low.borrow().0, high.borrow().0)) } fn new_inclusive<B1, B2>(low: B1, high: B2) -> Self where B1: SampleBorrow<Self::X> + Sized, B2: SampleBorrow<Self::X> + Sized { UniformSampler::new(low, high) } fn sample<R: Rng + ?Sized>(&self, rng: &mut R) -> Self::X { MyF32(self.0.sample(rng)) } } impl SampleUniform for MyF32 { type Sampler = UniformMyF32; } let (low, high) = (MyF32(17.0f32), MyF32(22.0f32)); let uniform = Uniform::new(low, high); let x = uniform.sample(&mut thread_rng());
Structs
Uniform | Sample values uniformly between two bounds. |
UniformChar | The back-end implementing |
UniformDuration | The back-end implementing |
UniformFloat | The back-end implementing |
UniformInt | The back-end implementing |
Traits
SampleBorrow | Helper trait similar to |
SampleRange | Range that supports generating a single sample efficiently. |
SampleUniform | Helper trait for creating objects using the correct implementation of
|
UniformSampler | Helper trait handling actual uniform sampling. |