Crates.io | turborand |
lib.rs | turborand |
version | 0.10.1 |
source | src |
created_at | 2022-06-10 19:06:43.183088 |
updated_at | 2024-02-24 14:45:20.378777 |
description | Fast random number generators |
homepage | |
repository | https://github.com/Bluefinger/turborand |
max_upload_size | |
id | 603727 |
size | 279,113 |
Fast random number generators.
turborand
's internal implementations use Wyrand, a simple and fast
generator but not cryptographically secure, and also ChaCha8, a cryptographically
secure generator tuned to 8 rounds of the ChaCha algorithm in order to increase throughput considerably without sacrificing
too much security, as per the recommendations set out in the Too Much Crypto paper.
use turborand::prelude::*;
let rand = Rng::new();
if rand.bool() {
println!("Success! :D");
} else {
println!("Failure... :(");
}
Sample a value from a list:
use turborand::prelude::*;
let rand = Rng::new();
let values = [1, 2, 3, 4, 5];
let value = rand.sample(&values);
Generate a vector with random values:
use turborand::prelude::*;
use std::iter::repeat_with;
let rand = Rng::new();
let values: Vec<_> = repeat_with(|| rand.f32()).take(10).collect();
no-std
Compatibilityturborand
can be exposed to no-std
environments, however only with reduced capability and feature sets. There'll be no Default
implementations, and no new()
constructors, so Rng
/ChaChaRng
seeds must be provided by the user from whatever source available on the platform. Some TurboRand
methods will also not be available unless the alloc
feature is enabled, which necessitates having a global allocator.
For suppporting WASM builds, you'll need to add the following to your Cargo.toml
:
[target.'cfg(target_arch = "wasm32")'.dependencies]
instant = { version = "0.1", features = ["wasm-bindgen"] }
instant
needs either the wasm-bindgen
or stdweb
feature active on WASM in order to compile. stdweb
however is unmaintained, but to support future alternatives and features, toggling on WASM support is left to the user of this crate.
Wyrand
is a pretty fast PRNG, and is a good choice when speed is needed while still having decent statistical properties. Currently, the turborand
implementation benches extremely well against similar rand
algorithms. Below is a chart of the fill_bytes
method performance, tested on Windows 10 x64 on an AMD Ryzen 1700 clocked at 3.7Ghz with 32GB RAM at 3066Mhz.
For filling 2048 byte array buffers, turborand
's Rng
is able to do so in around 170-180ns, whereas SmallRng
does it between 260-268ns, and Pcg64Mcg
(the fastest PCG impl on 64bit systems) does it in 305-312ns.
For generating unbound u64
values, turborand
and fastrand
are equal in performance, which is expected given they both implement the Wyrand
algorithm, consistently performing around 820-830ps for generating a u64
value. SmallRng
performs around 1.16ns, while Pcg64Mcg
is at 1.35ns.
Check out MIGRATION.md to get all the notes needed to migrate between major versions of turborand
.
Licensed under either of
at your option.