// -*- coding: utf-8 -*- // // disktest - Hard drive tester // // Copyright 2020-2022 Michael Buesch // // This program is free software; you can redistribute it and/or modify // it under the terms of the GNU General Public License as published by // the Free Software Foundation; either version 2 of the License, or // (at your option) any later version. // // This program is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // // You should have received a copy of the GNU General Public License along // with this program; if not, write to the Free Software Foundation, Inc., // 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. // use anyhow as ah; use crate::generator::NextRandom; use crate::util::fold; use rand::prelude::*; macro_rules! GeneratorChaCha { ( $Generator:ident, $ChaChaRng:ident, $testmodule:ident, $testresult0:literal, $testresult1:literal, $testresult2:literal, $testresult3:literal ) => { use rand_chacha::$ChaChaRng; pub struct $Generator { rng: $ChaChaRng, } impl $Generator { /// Size of the algorithm base output data. pub const BASE_SIZE: usize = 1024 * 1024 * 3; /// Chunk size. Multiple of the generator base size. pub const CHUNK_FACTOR: usize = 1; pub fn new(seed: &[u8]) -> $Generator { assert!(!seed.is_empty()); let mut folded_seed = [0u8; 32]; folded_seed.copy_from_slice(&fold(seed, 32)); let rng = $ChaChaRng::from_seed(folded_seed); $Generator { rng, } } } impl NextRandom for $Generator { fn get_base_size(&self) -> usize { $Generator::BASE_SIZE } fn next(&mut self, buf: &mut [u8], count: usize) { debug_assert!(buf.len() == $Generator::BASE_SIZE * count); self.rng.fill(buf); } fn seek(&mut self, byte_offset: u64) -> ah::Result<()> { if byte_offset % $Generator::BASE_SIZE as u64 != 0 { return Err(ah::format_err!("ChaCha seek: Byte offset is not a \ multiple of the base size ({} bytes).", $Generator::BASE_SIZE)); } if byte_offset % 4 != 0 { return Err(ah::format_err!("ChaCha seek: Byte offset is not a \ multiple of the word size (4 bytes).")); } let word_offset = byte_offset / 4; self.rng.set_word_pos(word_offset as u128); Ok(()) } } #[cfg(test)] mod $testmodule { use super::*; #[test] fn test_cmp_result() { let mut a = $Generator::new(&[1,2,3]); fn reduce(acc: u32, (i, x): (usize, &u8)) -> u32 { acc.rotate_left(i as u32) ^ (*x as u32) } let mut buf = vec![0u8; $Generator::BASE_SIZE * 3]; a.next(&mut buf[0..$Generator::BASE_SIZE], 1); assert_eq!(buf.iter().enumerate().fold(0, reduce), $testresult0); a.next(&mut buf[0..$Generator::BASE_SIZE], 1); assert_eq!(buf.iter().enumerate().fold(0, reduce), $testresult1); a.next(&mut buf[0..$Generator::BASE_SIZE*2], 2); assert_eq!(buf.iter().enumerate().fold(0, reduce), $testresult2); a.next(&mut buf[0..$Generator::BASE_SIZE*3], 3); assert_eq!(buf.iter().enumerate().fold(0, reduce), $testresult3); } #[test] fn test_seed_equal() { let mut a = $Generator::new(&[1,2,3]); let mut b = $Generator::new(&[1,2,3]); let mut res_a: Vec> = vec![]; let mut res_b: Vec> = vec![]; for _ in 0..2 { let mut buf = vec![0u8; $Generator::BASE_SIZE]; a.next(&mut buf, 1); res_a.push(buf); let mut buf = vec![0u8; $Generator::BASE_SIZE]; b.next(&mut buf, 1); res_b.push(buf); } assert_eq!(res_a[0], res_b[0]); assert_eq!(res_a[1], res_b[1]); assert_ne!(res_a[0], res_a[1]); assert_ne!(res_b[0], res_b[1]); } #[test] fn test_seed_diff() { let mut a = $Generator::new(&[1,2,3]); let mut b = $Generator::new(&[1,2,4]); let mut res_a: Vec> = vec![]; let mut res_b: Vec> = vec![]; for _ in 0..2 { let mut buf = vec![0u8; $Generator::BASE_SIZE]; a.next(&mut buf, 1); res_a.push(buf); let mut buf = vec![0u8; $Generator::BASE_SIZE]; b.next(&mut buf, 1); res_b.push(buf); } assert_ne!(res_a[0], res_b[0]); assert_ne!(res_a[1], res_b[1]); assert_ne!(res_a[0], res_a[1]); assert_ne!(res_b[0], res_b[1]); } #[test] fn test_concat_equal() { let mut a = $Generator::new(&[1,2,3]); let mut b = $Generator::new(&[1,2,3]); let mut buf_a = vec![0u8; $Generator::BASE_SIZE * 2]; a.next(&mut buf_a[0..$Generator::BASE_SIZE], 1); a.next(&mut buf_a[$Generator::BASE_SIZE..$Generator::BASE_SIZE*2], 1); let mut buf_b = vec![0u8; $Generator::BASE_SIZE * 2]; b.next(&mut buf_b, 2); assert_eq!(buf_a, buf_b); } #[test] fn test_seek() { let mut a = $Generator::new(&[1,2,3]); let mut b = $Generator::new(&[1,2,3]); b.seek($Generator::BASE_SIZE as u64 * 2).unwrap(); let mut bdata = vec![0u8; $Generator::BASE_SIZE]; b.next(&mut bdata, 1); let mut adata = vec![0u8; $Generator::BASE_SIZE]; a.next(&mut adata, 1); assert_ne!(adata, bdata); a.next(&mut adata, 1); assert_ne!(adata, bdata); a.next(&mut adata, 1); assert_eq!(adata, bdata); a.next(&mut adata, 1); assert_ne!(adata, bdata); } } }; } GeneratorChaCha!(GeneratorChaCha20, ChaCha20Rng, tests_chacha20, 331195744, 1401252284, 1567136089, 3153433807); GeneratorChaCha!(GeneratorChaCha12, ChaCha12Rng, tests_chacha12, 477482776, 774733417, 473700519, 3620480628); GeneratorChaCha!(GeneratorChaCha8, ChaCha8Rng, tests_chacha8, 3691419247, 1996469034, 1245532037, 1660157839); // vim: ts=4 sw=4 expandtab