// -*- 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 crate::bufcache::{BufCache, BufCacheCons}; use crate::generator::{ GeneratorChaCha12, GeneratorChaCha20, GeneratorChaCha8, GeneratorCrc, NextRandom, }; use crate::kdf::kdf; use anyhow as ah; use std::cell::RefCell; use std::rc::Rc; use std::sync::atomic::{AtomicBool, AtomicIsize, Ordering}; use std::sync::mpsc::{channel, Receiver, Sender}; use std::sync::{Arc, Condvar, Mutex}; use std::thread; /// Stream algorithm type. #[derive(Copy, Clone, Debug, PartialEq, Eq)] pub enum DtStreamType { ChaCha8, ChaCha12, ChaCha20, Crc, } /// Data chunk that contains the computed PRNG data. pub struct DtStreamChunk { pub data: Option>, pub index: u8, } /// Thread worker function, that computes the chunks. #[allow(clippy::too_many_arguments)] fn thread_worker( stype: DtStreamType, chunk_factor: usize, seed: Vec, thread_id: u32, mut cache_cons: BufCacheCons, byte_offset: u64, invert_pattern: bool, abort: Arc, error: Arc, level: Arc, sleep: Arc<(Mutex, Condvar)>, tx: Sender, ) { // Calculate the per-thread-seed from the global seed. let thread_seed = kdf(&seed, thread_id); drop(seed); // Construct the generator algorithm. let mut generator: Box = match stype { DtStreamType::ChaCha8 => Box::new(GeneratorChaCha8::new(&thread_seed)), DtStreamType::ChaCha12 => Box::new(GeneratorChaCha12::new(&thread_seed)), DtStreamType::ChaCha20 => Box::new(GeneratorChaCha20::new(&thread_seed)), DtStreamType::Crc => Box::new(GeneratorCrc::new(&thread_seed)), }; // Seek the generator to the specified byte offset. if let Err(e) = generator.seek(byte_offset) { eprintln!("ERROR in generator thread {}: {}", thread_id, e); error.store(true, Ordering::Relaxed); return; } // Run the generator work loop. let mut index = 0; let mut cur_level = level.load(Ordering::Relaxed); while !abort.load(Ordering::SeqCst) { if cur_level < DtStream::MAX_THRES { // Get the next chunk from the generator. let size = generator.get_base_size() * chunk_factor; let mut data = cache_cons.pull(size); generator.next(&mut data, chunk_factor); debug_assert_eq!(data.len(), size); // Invert the bit pattern, if requested. if invert_pattern { for x in &mut data { *x ^= 0xFFu8; } }; let chunk = DtStreamChunk { data: Some(data), index, }; index = index.wrapping_add(1); // Send the chunk to the main thread. tx.send(chunk).expect("Worker thread: Send failed."); cur_level = level.fetch_add(1, Ordering::Relaxed) + 1; } else { // The chunk buffer is full. Wait... let mut sleeping = sleep.0.lock().expect("Thread Condvar lock poison"); *sleeping = true; while *sleeping { sleeping = sleep.1.wait(sleeping).expect("Thread Condvar wait poison"); } cur_level = level.load(Ordering::Relaxed); } } } /// PRNG stream. pub struct DtStream { stype: DtStreamType, seed: Vec, invert_pattern: bool, thread_id: u32, rx: Option>, cache: Rc>, is_active: bool, thread_join: Option>, abort: Arc, error: Arc, level: Arc, sleep: Arc<(Mutex, Condvar)>, } impl DtStream { /// Maximum number of chunks that the thread will compute in advance. const MAX_THRES: isize = 10; /// Low watermark for thread wakeup. const LO_THRES: isize = 6; pub fn new( stype: DtStreamType, seed: Vec, invert_pattern: bool, thread_id: u32, cache: Rc>, ) -> DtStream { let abort = Arc::new(AtomicBool::new(false)); let error = Arc::new(AtomicBool::new(false)); let level = Arc::new(AtomicIsize::new(0)); let sleep = Arc::new((Mutex::new(false), Condvar::new())); DtStream { stype, seed, invert_pattern, thread_id, rx: None, cache, is_active: false, thread_join: None, abort, error, level, sleep, } } /// Wake up the worker thread, if it is currently sleeping. fn wake_thread(&self) { let mut sleeping = self.sleep.0.lock().expect("Wake Condvar lock poison"); if *sleeping { *sleeping = false; self.sleep.1.notify_one(); } } /// Stop the worker thread. /// Does nothing, if the thread is not running. fn stop(&mut self) { self.is_active = false; self.abort.store(true, Ordering::SeqCst); self.wake_thread(); if let Some(thread_join) = self.thread_join.take() { thread_join.join().expect("Thread join failed"); } self.abort.store(false, Ordering::SeqCst); } /// Spawn the worker thread. /// Panics, if the thread is already running. fn start(&mut self, byte_offset: u64, chunk_factor: usize) { assert!(!self.is_active); assert!(self.thread_join.is_none()); // Initialize thread communication self.abort.store(false, Ordering::SeqCst); self.error.store(false, Ordering::SeqCst); self.level.store(0, Ordering::SeqCst); let (tx, rx) = channel(); self.rx = Some(rx); // Spawn the worker thread. let thread_stype = self.stype; let thread_chunk_factor = chunk_factor; let thread_seed = self.seed.to_vec(); let thread_id = self.thread_id; let thread_cache_cons = self.cache.borrow_mut().new_consumer(self.thread_id); let thread_byte_offset = byte_offset; let thread_invert_pattern = self.invert_pattern; let thread_abort = Arc::clone(&self.abort); let thread_error = Arc::clone(&self.error); let thread_level = Arc::clone(&self.level); let thread_sleep = Arc::clone(&self.sleep); self.thread_join = Some(thread::spawn(move || { thread_worker( thread_stype, thread_chunk_factor, thread_seed, thread_id, thread_cache_cons, thread_byte_offset, thread_invert_pattern, thread_abort, thread_error, thread_level, thread_sleep, tx, ); })); self.is_active = true; } /// Check if the thread exited due to an error. #[inline] fn is_thread_error(&self) -> bool { self.error.load(Ordering::Relaxed) } /// Activate the worker thread. pub fn activate(&mut self, byte_offset: u64, chunk_factor: usize) -> ah::Result<()> { self.stop(); self.start(byte_offset, chunk_factor); Ok(()) } /// Check if the worker thread is currently running. #[inline] pub fn is_active(&self) -> bool { self.is_active } /// Get the chunk base size. pub fn get_chunk_size(&self) -> usize { match self.stype { DtStreamType::ChaCha8 => GeneratorChaCha8::BASE_SIZE, DtStreamType::ChaCha12 => GeneratorChaCha12::BASE_SIZE, DtStreamType::ChaCha20 => GeneratorChaCha20::BASE_SIZE, DtStreamType::Crc => GeneratorCrc::BASE_SIZE, } } /// Get the default chunk factor of the selected generator. pub fn get_default_chunk_factor(&self) -> usize { match self.stype { DtStreamType::ChaCha8 => GeneratorChaCha8::DEFAULT_CHUNK_FACTOR, DtStreamType::ChaCha12 => GeneratorChaCha12::DEFAULT_CHUNK_FACTOR, DtStreamType::ChaCha20 => GeneratorChaCha20::DEFAULT_CHUNK_FACTOR, DtStreamType::Crc => GeneratorCrc::DEFAULT_CHUNK_FACTOR, } } /// Get the next chunk from the thread. /// Returns None, if no chunk is available, yet. #[inline] pub fn get_chunk(&mut self) -> ah::Result> { if !self.is_active() { return Err(ah::format_err!("Generator stream is not active.")); } if self.is_thread_error() { return Err(ah::format_err!( "Generator stream thread aborted with an error." )); } let Some(rx) = &self.rx else { return Err(ah::format_err!("Generator stream RX channel not present.")); }; let Ok(chunk) = rx.try_recv() else { // Queue is empty. Wake thread. self.wake_thread(); return Ok(None); }; if self.level.fetch_sub(1, Ordering::Relaxed) - 1 <= DtStream::LO_THRES { // Queue fill level is low. Wake thread. self.wake_thread(); } // We got a chunk. Ok(Some(chunk)) } } impl Drop for DtStream { fn drop(&mut self) { self.stop(); } } #[cfg(test)] mod tests { use super::*; use crate::disktest::DisktestQuiet; use std::time::Duration; impl DtStream { pub fn wait_chunk(&mut self) -> DtStreamChunk { loop { if let Some(chunk) = self.get_chunk().unwrap() { break chunk; } thread::sleep(Duration::from_millis(1)); } } } fn run_base_test(algorithm: DtStreamType) { println!("stream base test"); let cache = Rc::new(RefCell::new(BufCache::new(DisktestQuiet::Normal))); let mut s = DtStream::new(algorithm, vec![1, 2, 3], false, 0, cache); s.activate(0, s.get_default_chunk_factor()).unwrap(); assert!(s.is_active()); assert!(s.get_chunk_size() > 0); assert!(s.get_default_chunk_factor() > 0); let mut results_first = vec![]; for count in 0..5 { let chunk = s.wait_chunk(); println!( "{}: index={} data[0]={} (current level = {})", count, chunk.index, chunk.data.as_ref().unwrap()[0], s.level.load(Ordering::Relaxed) ); results_first.push(chunk.data.as_ref().unwrap()[0]); assert_eq!(chunk.index, count); } match algorithm { DtStreamType::ChaCha8 => { assert_eq!(results_first, vec![66, 209, 254, 224, 203]); } DtStreamType::ChaCha12 => { assert_eq!(results_first, vec![200, 202, 12, 60, 234]); } DtStreamType::ChaCha20 => { assert_eq!(results_first, vec![206, 236, 87, 55, 170]); } DtStreamType::Crc => { assert_eq!(results_first, vec![108, 99, 114, 196, 213]); } } } fn run_offset_test(algorithm: DtStreamType) { println!("stream offset test"); // a: start at chunk offset 0 let cache = Rc::new(RefCell::new(BufCache::new(DisktestQuiet::Normal))); let mut a = DtStream::new(algorithm, vec![1, 2, 3], false, 0, cache); a.activate(0, a.get_default_chunk_factor()).unwrap(); // b: start at chunk offset 1 let cache = Rc::new(RefCell::new(BufCache::new(DisktestQuiet::Normal))); let mut b = DtStream::new(algorithm, vec![1, 2, 3], false, 0, cache); b.activate( a.get_chunk_size() as u64 * a.get_default_chunk_factor() as u64, a.get_default_chunk_factor(), ) .unwrap(); let achunk = a.wait_chunk(); let bchunk = b.wait_chunk(); assert!(achunk.data.as_ref().unwrap() != bchunk.data.as_ref().unwrap()); let achunk = a.wait_chunk(); assert!(achunk.data.as_ref().unwrap() == bchunk.data.as_ref().unwrap()); } fn run_invert_test(algorithm: DtStreamType) { println!("stream invert test"); let cache = Rc::new(RefCell::new(BufCache::new(DisktestQuiet::Normal))); let mut a = DtStream::new(algorithm, vec![1, 2, 3], false, 0, cache); a.activate(0, a.get_default_chunk_factor()).unwrap(); let cache = Rc::new(RefCell::new(BufCache::new(DisktestQuiet::Normal))); let mut b = DtStream::new(algorithm, vec![1, 2, 3], true, 0, cache); b.activate(0, a.get_default_chunk_factor()).unwrap(); let achunk = a.wait_chunk(); let bchunk = b.wait_chunk(); let inv_bchunk: Vec = bchunk .data .as_ref() .unwrap() .iter() .map(|x| x ^ 0xFF) .collect(); assert!(achunk.data.as_ref().unwrap() != bchunk.data.as_ref().unwrap()); assert!(achunk.data.as_ref().unwrap() == &inv_bchunk); } #[test] fn test_chacha8() { let alg = DtStreamType::ChaCha8; run_base_test(alg); run_offset_test(alg); run_invert_test(alg); } #[test] fn test_chacha12() { let alg = DtStreamType::ChaCha12; run_base_test(alg); run_offset_test(alg); run_invert_test(alg); } #[test] fn test_chacha20() { let alg = DtStreamType::ChaCha20; run_base_test(alg); run_offset_test(alg); run_invert_test(alg); } #[test] fn test_crc() { let alg = DtStreamType::Crc; run_base_test(alg); run_offset_test(alg); run_invert_test(alg); } } // vim: ts=4 sw=4 expandtab