// Copyright 2018 Amazon.com, Inc. or its affiliates. All Rights Reserved. // // Portions Copyright 2017 The Chromium OS Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE-BSD-3-Clause file. // // Copyright © 2020 Intel Corporation // // SPDX-License-Identifier: Apache-2.0 AND BSD-3-Clause use super::Error as DeviceError; use super::{ ActivateError, ActivateResult, EpollHelper, EpollHelperError, EpollHelperHandler, Queue, VirtioDevice, VirtioDeviceType, VirtioInterruptType, EPOLL_HELPER_EVENT_LAST, }; use crate::VirtioInterrupt; use anyhow::anyhow; use block_util::{build_disk_image_id, Request, RequestType, VirtioBlockConfig}; use io_uring::IoUring; use libc::EFD_NONBLOCK; use std::collections::HashMap; use std::fs::File; use std::io::{self, Seek, SeekFrom}; use std::num::Wrapping; use std::os::unix::io::{AsRawFd, RawFd}; use std::path::PathBuf; use std::result; use std::sync::atomic::{AtomicBool, AtomicU64, Ordering}; use std::sync::Arc; use std::thread; use virtio_bindings::bindings::virtio_blk::*; use vm_memory::{ ByteValued, Bytes, GuestAddress, GuestAddressSpace, GuestMemoryAtomic, GuestMemoryError, GuestMemoryMmap, }; use vm_migration::{ Migratable, MigratableError, Pausable, Snapshot, SnapshotDataSection, Snapshottable, Transportable, }; use vmm_sys_util::eventfd::EventFd; const SECTOR_SHIFT: u8 = 9; pub const SECTOR_SIZE: u64 = (0x01 as u64) << SECTOR_SHIFT; // New descriptors are pending on the virtio queue. const QUEUE_AVAIL_EVENT: u16 = EPOLL_HELPER_EVENT_LAST + 1; // New completed tasks are pending on the completion ring. const IO_URING_EVENT: u16 = EPOLL_HELPER_EVENT_LAST + 2; #[derive(Debug)] pub enum Error { /// Guest gave us bad memory addresses. GuestMemory(GuestMemoryError), /// Guest gave us offsets that would have overflowed a usize. CheckedOffset(GuestAddress, usize), /// Guest gave us a write only descriptor that protocol says to read from. UnexpectedWriteOnlyDescriptor, /// Guest gave us a read only descriptor that protocol says to write to. UnexpectedReadOnlyDescriptor, /// Guest gave us too few descriptors in a descriptor chain. DescriptorChainTooShort, /// Guest gave us a descriptor that was too short to use. DescriptorLengthTooSmall, /// Getting a block's metadata fails for any reason. GetFileMetadata, /// The requested operation would cause a seek beyond disk end. InvalidOffset, /// Unsupported operation on the disk. Unsupported(u32), /// Failed to parse the request. RequestParsing(block_util::Error), /// Failed to execute the request. RequestExecuting(block_util::ExecuteError), /// Missing the expected entry in the list of requests. MissingEntryRequestList, /// The asynchronous request returned with failure. AsyncRequestFailure, } pub type Result = result::Result; #[derive(Default, Clone)] pub struct BlockCounters { read_bytes: Arc, read_ops: Arc, write_bytes: Arc, write_ops: Arc, } struct BlockIoUringEpollHandler { queue: Queue, mem: GuestMemoryAtomic, disk_image_fd: RawFd, disk_nsectors: u64, interrupt_cb: Arc, disk_image_id: Vec, kill_evt: EventFd, pause_evt: EventFd, writeback: Arc, counters: BlockCounters, queue_evt: EventFd, io_uring: IoUring, io_uring_evt: EventFd, request_list: HashMap, } impl BlockIoUringEpollHandler { fn process_queue_submit(&mut self) -> Result { let queue = &mut self.queue; let mem = self.mem.memory(); let mut used_desc_heads = Vec::new(); let mut used_count = 0; for avail_desc in queue.iter(&mem) { let mut request = Request::parse(&avail_desc, &mem).map_err(Error::RequestParsing)?; request.set_writeback(self.writeback.load(Ordering::SeqCst)); if request .execute_io_uring( &mem, &mut self.io_uring, self.disk_nsectors, self.disk_image_fd, &self.disk_image_id, avail_desc.index as u64, ) .map_err(Error::RequestExecuting)? { self.request_list.insert(avail_desc.index, request); } else { // We use unwrap because the request parsing process already // checked that the status_addr was valid. mem.write_obj(VIRTIO_BLK_S_OK, request.status_addr).unwrap(); // If no asynchronous operation has been submitted, we can // simply return the used descriptor. used_desc_heads.push((avail_desc.index, 0)); used_count += 1; } } for &(desc_index, len) in used_desc_heads.iter() { queue.add_used(&mem, desc_index, len); } Ok(used_count > 0) } fn process_queue_complete(&mut self) -> Result { let queue = &mut self.queue; let mut used_desc_heads = Vec::new(); let mut used_count = 0; let mem = self.mem.memory(); let mut read_bytes = Wrapping(0); let mut write_bytes = Wrapping(0); let mut read_ops = Wrapping(0); let mut write_ops = Wrapping(0); let cq = self.io_uring.completion(); for cq_entry in cq.available() { let result = cq_entry.result(); let desc_index = cq_entry.user_data() as u16; let request = self .request_list .remove(&desc_index) .ok_or(Error::MissingEntryRequestList)?; let (status, len) = if result >= 0 { match request.request_type { RequestType::In => { read_bytes += Wrapping(request.data_len as u64); read_ops += Wrapping(1); } RequestType::Out => { if !request.writeback { unsafe { libc::fsync(self.disk_image_fd) }; } write_bytes += Wrapping(request.data_len as u64); write_ops += Wrapping(1); } _ => {} } (VIRTIO_BLK_S_OK, result as u32) } else { error!( "Request failed: {:?}", io::Error::from_raw_os_error(-result) ); return Err(Error::AsyncRequestFailure); }; // We use unwrap because the request parsing process already // checked that the status_addr was valid. mem.write_obj(status, request.status_addr).unwrap(); used_desc_heads.push((desc_index, len)); used_count += 1; } for &(desc_index, len) in used_desc_heads.iter() { queue.add_used(&mem, desc_index, len); } self.counters .write_bytes .fetch_add(write_bytes.0, Ordering::AcqRel); self.counters .write_ops .fetch_add(write_ops.0, Ordering::AcqRel); self.counters .read_bytes .fetch_add(read_bytes.0, Ordering::AcqRel); self.counters .read_ops .fetch_add(read_ops.0, Ordering::AcqRel); Ok(used_count > 0) } fn signal_used_queue(&self) -> result::Result<(), DeviceError> { self.interrupt_cb .trigger(&VirtioInterruptType::Queue, Some(&self.queue)) .map_err(|e| { error!("Failed to signal used queue: {:?}", e); DeviceError::FailedSignalingUsedQueue(e) }) } fn run(&mut self, paused: Arc) -> result::Result<(), EpollHelperError> { let mut helper = EpollHelper::new(&self.kill_evt, &self.pause_evt)?; helper.add_event(self.queue_evt.as_raw_fd(), QUEUE_AVAIL_EVENT)?; helper.add_event(self.io_uring_evt.as_raw_fd(), IO_URING_EVENT)?; helper.run(paused, self)?; Ok(()) } } impl EpollHelperHandler for BlockIoUringEpollHandler { fn handle_event(&mut self, _helper: &mut EpollHelper, event: &epoll::Event) -> bool { let ev_type = event.data as u16; match ev_type { QUEUE_AVAIL_EVENT => { if let Err(e) = self.queue_evt.read() { error!("Failed to get queue event: {:?}", e); return true; } match self.process_queue_submit() { Ok(needs_notification) => { if needs_notification { if let Err(e) = self.signal_used_queue() { error!("Failed to signal used queue: {:?}", e); return true; } } } Err(e) => { error!("Failed to process queue (submit): {:?}", e); return true; } } } IO_URING_EVENT => { if let Err(e) = self.io_uring_evt.read() { error!("Failed to get queue event: {:?}", e); return true; } match self.process_queue_complete() { Ok(needs_notification) => { if needs_notification { if let Err(e) = self.signal_used_queue() { error!("Failed to signal used queue: {:?}", e); return true; } } } Err(e) => { error!("Failed to process queue (complete): {:?}", e); return true; } } } _ => { error!("Unexpected event: {}", ev_type); return true; } } false } } /// Virtio device for exposing block level read/write operations on a host file. pub struct BlockIoUring { id: String, kill_evt: Option, disk_image: File, disk_path: PathBuf, disk_nsectors: u64, avail_features: u64, acked_features: u64, config: VirtioBlockConfig, queue_evts: Option>, interrupt_cb: Option>, epoll_threads: Option>>>, pause_evt: Option, paused: Arc, queue_size: Vec, writeback: Arc, counters: BlockCounters, } #[derive(Serialize, Deserialize)] pub struct BlockState { pub disk_path: PathBuf, pub disk_nsectors: u64, pub avail_features: u64, pub acked_features: u64, pub config: VirtioBlockConfig, } impl BlockIoUring { /// Create a new virtio block device that operates on the given file. pub fn new( id: String, mut disk_image: File, disk_path: PathBuf, is_disk_read_only: bool, iommu: bool, num_queues: usize, queue_size: u16, ) -> io::Result { let disk_size = disk_image.seek(SeekFrom::End(0))? as u64; if disk_size % SECTOR_SIZE != 0 { warn!( "Disk size {} is not a multiple of sector size {}; \ the remainder will not be visible to the guest.", disk_size, SECTOR_SIZE ); } let mut avail_features = (1u64 << VIRTIO_F_VERSION_1) | (1u64 << VIRTIO_BLK_F_FLUSH) | (1u64 << VIRTIO_BLK_F_CONFIG_WCE); if iommu { avail_features |= 1u64 << VIRTIO_F_IOMMU_PLATFORM; } if is_disk_read_only { avail_features |= 1u64 << VIRTIO_BLK_F_RO; } let disk_nsectors = disk_size / SECTOR_SIZE; let mut config = VirtioBlockConfig { capacity: disk_nsectors, writeback: 1, ..Default::default() }; if num_queues > 1 { avail_features |= 1u64 << VIRTIO_BLK_F_MQ; config.num_queues = num_queues as u16; } Ok(BlockIoUring { id, kill_evt: None, disk_image, disk_path, disk_nsectors, avail_features, acked_features: 0u64, config, queue_evts: None, interrupt_cb: None, epoll_threads: None, pause_evt: None, paused: Arc::new(AtomicBool::new(false)), queue_size: vec![queue_size; num_queues], writeback: Arc::new(AtomicBool::new(true)), counters: BlockCounters::default(), }) } fn state(&self) -> BlockState { BlockState { disk_path: self.disk_path.clone(), disk_nsectors: self.disk_nsectors, avail_features: self.avail_features, acked_features: self.acked_features, config: self.config, } } fn set_state(&mut self, state: &BlockState) -> io::Result<()> { self.disk_path = state.disk_path.clone(); self.disk_nsectors = state.disk_nsectors; self.avail_features = state.avail_features; self.acked_features = state.acked_features; self.config = state.config; Ok(()) } fn update_writeback(&mut self) { // Use writeback from config if VIRTIO_BLK_F_CONFIG_WCE let writeback = if self.acked_features & 1 << VIRTIO_BLK_F_CONFIG_WCE == 1 << VIRTIO_BLK_F_CONFIG_WCE { self.config.writeback == 1 } else { // Else check if VIRTIO_BLK_F_FLUSH negotiated self.acked_features & 1 << VIRTIO_BLK_F_FLUSH == 1 << VIRTIO_BLK_F_FLUSH }; info!( "Changing cache mode to {}", if writeback { "writeback" } else { "writethrough" } ); self.writeback.store(writeback, Ordering::SeqCst); } } impl Drop for BlockIoUring { fn drop(&mut self) { if let Some(kill_evt) = self.kill_evt.take() { // Ignore the result because there is nothing we can do about it. let _ = kill_evt.write(1); } } } impl VirtioDevice for BlockIoUring { fn device_type(&self) -> u32 { VirtioDeviceType::TYPE_BLOCK as u32 } fn queue_max_sizes(&self) -> &[u16] { self.queue_size.as_slice() } fn features(&self) -> u64 { self.avail_features } fn ack_features(&mut self, value: u64) { let mut v = value; // Check if the guest is ACK'ing a feature that we didn't claim to have. let unrequested_features = v & !self.avail_features; if unrequested_features != 0 { warn!("Received acknowledge request for unknown feature."); // Don't count these features as acked. v &= !unrequested_features; } self.acked_features |= v; } fn read_config(&self, offset: u64, data: &mut [u8]) { self.read_config_from_slice(self.config.as_slice(), offset, data); } fn write_config(&mut self, offset: u64, data: &[u8]) { // The "writeback" field is the only mutable field let writeback_offset = (&self.config.writeback as *const _ as u64) - (&self.config as *const _ as u64); if offset != writeback_offset || data.len() != std::mem::size_of_val(&self.config.writeback) { error!( "Attempt to write to read-only field: offset {:x} length {}", offset, data.len() ); return; } self.config.writeback = data[0]; self.update_writeback(); } fn activate( &mut self, mem: GuestMemoryAtomic, interrupt_cb: Arc, mut queues: Vec, mut queue_evts: Vec, ) -> ActivateResult { if queues.len() != self.queue_size.len() || queue_evts.len() != self.queue_size.len() { error!( "Cannot perform activate. Expected {} queue(s), got {}", self.queue_size.len(), queues.len() ); return Err(ActivateError::BadActivate); } let (self_kill_evt, kill_evt) = EventFd::new(EFD_NONBLOCK) .and_then(|e| Ok((e.try_clone()?, e))) .map_err(|e| { error!("failed creating kill EventFd pair: {}", e); ActivateError::BadActivate })?; self.kill_evt = Some(self_kill_evt); let (self_pause_evt, pause_evt) = EventFd::new(EFD_NONBLOCK) .and_then(|e| Ok((e.try_clone()?, e))) .map_err(|e| { error!("failed creating pause EventFd pair: {}", e); ActivateError::BadActivate })?; self.pause_evt = Some(self_pause_evt); let disk_image_id = build_disk_image_id(&self.disk_path); let mut tmp_queue_evts: Vec = Vec::new(); for queue_evt in queue_evts.iter() { // Save the queue EventFD as we need to return it on reset // but clone it to pass into the thread. tmp_queue_evts.push(queue_evt.try_clone().map_err(|e| { error!("failed to clone queue EventFd: {}", e); ActivateError::BadActivate })?); } self.queue_evts = Some(tmp_queue_evts); let mut tmp_queue_evts: Vec = Vec::new(); for queue_evt in queue_evts.iter() { // Save the queue EventFD as we need to return it on reset // but clone it to pass into the thread. tmp_queue_evts.push(queue_evt.try_clone().map_err(|e| { error!("failed to clone queue EventFd: {}", e); ActivateError::BadActivate })?); } self.queue_evts = Some(tmp_queue_evts); self.update_writeback(); let mut epoll_threads = Vec::new(); for i in 0..self.queue_size.len() { let queue_size = self.queue_size[i] as usize; let queue_evt = queue_evts.remove(0); let io_uring = IoUring::new(queue_size as u32).map_err(|e| { error!("failed to create io_uring instance: {}", e); ActivateError::BadActivate })?; let mut handler = BlockIoUringEpollHandler { queue: queues.remove(0), mem: mem.clone(), disk_image_fd: self.disk_image.as_raw_fd(), disk_nsectors: self.disk_nsectors, interrupt_cb: interrupt_cb.clone(), disk_image_id: disk_image_id.clone(), kill_evt: kill_evt.try_clone().map_err(|e| { error!("failed to clone kill_evt eventfd: {}", e); ActivateError::BadActivate })?, pause_evt: pause_evt.try_clone().map_err(|e| { error!("failed to clone pause_evt eventfd: {}", e); ActivateError::BadActivate })?, writeback: self.writeback.clone(), counters: self.counters.clone(), queue_evt, io_uring, io_uring_evt: EventFd::new(EFD_NONBLOCK).map_err(|e| { error!("failed to create io_uring eventfd: {}", e); ActivateError::BadActivate })?, request_list: HashMap::with_capacity(queue_size), }; let paused = self.paused.clone(); // Register the io_uring eventfd that will notify the epoll loop // when something in the completion queue is ready. handler .io_uring .submitter() .register_eventfd(handler.io_uring_evt.as_raw_fd()) .map_err(|e| { error!("failed to register eventfd for io_uring: {}", e); ActivateError::BadActivate })?; thread::Builder::new() .name("virtio_blk".to_string()) .spawn(move || handler.run(paused)) .map(|thread| epoll_threads.push(thread)) .map_err(|e| { error!("failed to clone the virtio-blk epoll thread: {}", e); ActivateError::BadActivate })?; } // Save the interrupt EventFD as we need to return it on reset // but clone it to pass into the thread. self.interrupt_cb = Some(interrupt_cb); self.epoll_threads = Some(epoll_threads); Ok(()) } fn reset(&mut self) -> Option<(Arc, Vec)> { // We first must resume the virtio thread if it was paused. if self.pause_evt.take().is_some() { self.resume().ok()?; } if let Some(kill_evt) = self.kill_evt.take() { // Ignore the result because there is nothing we can do about it. let _ = kill_evt.write(1); } // Return the interrupt and queue EventFDs Some(( self.interrupt_cb.take().unwrap(), self.queue_evts.take().unwrap(), )) } fn counters(&self) -> Option>> { let mut counters = HashMap::new(); counters.insert( "read_bytes", Wrapping(self.counters.read_bytes.load(Ordering::Acquire)), ); counters.insert( "write_bytes", Wrapping(self.counters.write_bytes.load(Ordering::Acquire)), ); counters.insert( "read_ops", Wrapping(self.counters.read_ops.load(Ordering::Acquire)), ); counters.insert( "write_ops", Wrapping(self.counters.write_ops.load(Ordering::Acquire)), ); Some(counters) } } virtio_pausable!(BlockIoUring); impl Snapshottable for BlockIoUring { fn id(&self) -> String { self.id.clone() } fn snapshot(&self) -> std::result::Result { let snapshot = serde_json::to_vec(&self.state()).map_err(|e| MigratableError::Snapshot(e.into()))?; let mut block_snapshot = Snapshot::new(self.id.as_str()); block_snapshot.add_data_section(SnapshotDataSection { id: format!("{}-section", self.id), snapshot, }); Ok(block_snapshot) } fn restore(&mut self, snapshot: Snapshot) -> std::result::Result<(), MigratableError> { if let Some(block_section) = snapshot.snapshot_data.get(&format!("{}-section", self.id)) { let block_state = match serde_json::from_slice(&block_section.snapshot) { Ok(state) => state, Err(error) => { return Err(MigratableError::Restore(anyhow!( "Could not deserialize BLOCK {}", error ))) } }; return self.set_state(&block_state).map_err(|e| { MigratableError::Restore(anyhow!("Could not restore BLOCK state {:?}", e)) }); } Err(MigratableError::Restore(anyhow!( "Could not find BLOCK snapshot section" ))) } } impl Transportable for BlockIoUring {} impl Migratable for BlockIoUring {}