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impls.rs
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impls.rs
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// Copyright 2018 Developers of the Rand project.
//
// Licensed under the Apache License, Version 2.0 <LICENSE-APACHE or
// https://www.apache.org/licenses/LICENSE-2.0> or the MIT license
// <LICENSE-MIT or https://opensource.org/licenses/MIT>, at your
// option. This file may not be copied, modified, or distributed
// except according to those terms.
//! Helper functions for implementing `RngCore` functions.
//!
//! For cross-platform reproducibility, these functions all use Little Endian:
//! least-significant part first. For example, `next_u64_via_u32` takes `u32`
//! values `x, y`, then outputs `(y << 32) | x`. To implement `next_u32`
//! from `next_u64` in little-endian order, one should use `next_u64() as u32`.
//!
//! Byte-swapping (like the std `to_le` functions) is only needed to convert
//! to/from byte sequences, and since its purpose is reproducibility,
//! non-reproducible sources (e.g. `OsRng`) need not bother with it.
use crate::RngCore;
use core::cmp::min;
/// Implement `next_u64` via `next_u32`, little-endian order.
pub fn next_u64_via_u32<R: RngCore + ?Sized>(rng: &mut R) -> u64 {
// Use LE; we explicitly generate one value before the next.
let x = u64::from(rng.next_u32());
let y = u64::from(rng.next_u32());
(y << 32) | x
}
/// Implement `fill_bytes` via `next_u64` and `next_u32`, little-endian order.
///
/// The fastest way to fill a slice is usually to work as long as possible with
/// integers. That is why this method mostly uses `next_u64`, and only when
/// there are 4 or less bytes remaining at the end of the slice it uses
/// `next_u32` once.
pub fn fill_bytes_via_next<R: RngCore + ?Sized>(rng: &mut R, dest: &mut [u8]) {
let mut left = dest;
while left.len() >= 8 {
let (l, r) = { left }.split_at_mut(8);
left = r;
let chunk: [u8; 8] = rng.next_u64().to_le_bytes();
l.copy_from_slice(&chunk);
}
let n = left.len();
if n > 4 {
let chunk: [u8; 8] = rng.next_u64().to_le_bytes();
left.copy_from_slice(&chunk[..n]);
} else if n > 0 {
let chunk: [u8; 4] = rng.next_u32().to_le_bytes();
left.copy_from_slice(&chunk[..n]);
}
}
macro_rules! fill_via_chunks {
($src:expr, $dst:expr, $ty:ty) => {{
const SIZE: usize = core::mem::size_of::<$ty>();
let chunk_size_u8 = min($src.len() * SIZE, $dst.len());
let chunk_size = (chunk_size_u8 + SIZE - 1) / SIZE;
// The following can be replaced with safe code, but unfortunately it's
// ca. 8% slower.
if cfg!(target_endian = "little") {
unsafe {
core::ptr::copy_nonoverlapping(
$src.as_ptr() as *const u8,
$dst.as_mut_ptr(),
chunk_size_u8);
}
} else {
for (&n, chunk) in $src.iter().zip($dst.chunks_mut(SIZE)) {
let tmp = n.to_le();
let src_ptr = &tmp as *const $ty as *const u8;
unsafe {
core::ptr::copy_nonoverlapping(
src_ptr,
chunk.as_mut_ptr(),
chunk.len());
}
}
}
(chunk_size, chunk_size_u8)
}};
}
/// Implement `fill_bytes` by reading chunks from the output buffer of a block
/// based RNG.
///
/// The return values are `(consumed_u32, filled_u8)`.
///
/// `filled_u8` is the number of filled bytes in `dest`, which may be less than
/// the length of `dest`.
/// `consumed_u32` is the number of words consumed from `src`, which is the same
/// as `filled_u8 / 4` rounded up.
///
/// # Example
/// (from `IsaacRng`)
///
/// ```ignore
/// fn fill_bytes(&mut self, dest: &mut [u8]) {
/// let mut read_len = 0;
/// while read_len < dest.len() {
/// if self.index >= self.rsl.len() {
/// self.isaac();
/// }
///
/// let (consumed_u32, filled_u8) =
/// impls::fill_via_u32_chunks(&mut self.rsl[self.index..],
/// &mut dest[read_len..]);
///
/// self.index += consumed_u32;
/// read_len += filled_u8;
/// }
/// }
/// ```
pub fn fill_via_u32_chunks(src: &[u32], dest: &mut [u8]) -> (usize, usize) {
fill_via_chunks!(src, dest, u32)
}
/// Implement `fill_bytes` by reading chunks from the output buffer of a block
/// based RNG.
///
/// The return values are `(consumed_u64, filled_u8)`.
/// `filled_u8` is the number of filled bytes in `dest`, which may be less than
/// the length of `dest`.
/// `consumed_u64` is the number of words consumed from `src`, which is the same
/// as `filled_u8 / 8` rounded up.
///
/// See `fill_via_u32_chunks` for an example.
pub fn fill_via_u64_chunks(src: &[u64], dest: &mut [u8]) -> (usize, usize) {
fill_via_chunks!(src, dest, u64)
}
/// Implement `next_u32` via `fill_bytes`, little-endian order.
pub fn next_u32_via_fill<R: RngCore + ?Sized>(rng: &mut R) -> u32 {
let mut buf = [0; 4];
rng.fill_bytes(&mut buf);
u32::from_le_bytes(buf)
}
/// Implement `next_u64` via `fill_bytes`, little-endian order.
pub fn next_u64_via_fill<R: RngCore + ?Sized>(rng: &mut R) -> u64 {
let mut buf = [0; 8];
rng.fill_bytes(&mut buf);
u64::from_le_bytes(buf)
}
#[cfg(test)]
mod test {
use super::*;
#[test]
fn test_fill_via_u32_chunks() {
let src = [1, 2, 3];
let mut dst = [0u8; 11];
assert_eq!(fill_via_u32_chunks(&src, &mut dst), (3, 11));
assert_eq!(dst, [1, 0, 0, 0, 2, 0, 0, 0, 3, 0, 0]);
let mut dst = [0u8; 13];
assert_eq!(fill_via_u32_chunks(&src, &mut dst), (3, 12));
assert_eq!(dst, [1, 0, 0, 0, 2, 0, 0, 0, 3, 0, 0, 0, 0]);
let mut dst = [0u8; 5];
assert_eq!(fill_via_u32_chunks(&src, &mut dst), (2, 5));
assert_eq!(dst, [1, 0, 0, 0, 2]);
}
#[test]
fn test_fill_via_u64_chunks() {
let src = [1, 2];
let mut dst = [0u8; 11];
assert_eq!(fill_via_u64_chunks(&src, &mut dst), (2, 11));
assert_eq!(dst, [1, 0, 0, 0, 0, 0, 0, 0, 2, 0, 0]);
let mut dst = [0u8; 17];
assert_eq!(fill_via_u64_chunks(&src, &mut dst), (2, 16));
assert_eq!(dst, [1, 0, 0, 0, 0, 0, 0, 0, 2, 0, 0, 0, 0, 0, 0, 0, 0]);
let mut dst = [0u8; 5];
assert_eq!(fill_via_u64_chunks(&src, &mut dst), (1, 5));
assert_eq!(dst, [1, 0, 0, 0, 0]);
}
}