// 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 © 2019 Intel Corporation // // SPDX-License-Identifier: Apache-2.0 AND BSD-3-Clause // use crate::config::{ ConsoleOutputMode, DeviceConfig, DiskConfig, FsConfig, NetConfig, PmemConfig, UserDeviceConfig, VdpaConfig, VhostMode, VmConfig, VsockConfig, }; use crate::cpu::{CpuManager, CPU_MANAGER_ACPI_SIZE}; use crate::device_tree::{DeviceNode, DeviceTree}; use crate::interrupt::LegacyUserspaceInterruptManager; use crate::interrupt::MsiInterruptManager; use crate::memory_manager::{Error as MemoryManagerError, MemoryManager, MEMORY_MANAGER_ACPI_SIZE}; use crate::pci_segment::PciSegment; use crate::seccomp_filters::{get_seccomp_filter, Thread}; use crate::serial_manager::{Error as SerialManagerError, SerialManager}; use crate::sigwinch_listener::start_sigwinch_listener; use crate::GuestRegionMmap; use crate::PciDeviceInfo; use crate::{device_node, DEVICE_MANAGER_SNAPSHOT_ID}; use acpi_tables::sdt::GenericAddress; use acpi_tables::{aml, Aml}; use anyhow::anyhow; use arch::layout; #[cfg(target_arch = "x86_64")] use arch::layout::{APIC_START, IOAPIC_SIZE, IOAPIC_START}; use arch::NumaNodes; #[cfg(target_arch = "aarch64")] use arch::{DeviceType, MmioDeviceInfo}; use block_util::{ async_io::DiskFile, block_io_uring_is_supported, detect_image_type, fixed_vhd_sync::FixedVhdDiskSync, qcow_sync::QcowDiskSync, raw_sync::RawFileDiskSync, vhdx_sync::VhdxDiskSync, ImageType, }; #[cfg(feature = "io_uring")] use block_util::{fixed_vhd_async::FixedVhdDiskAsync, raw_async::RawFileDisk}; #[cfg(target_arch = "aarch64")] use devices::gic; #[cfg(target_arch = "x86_64")] use devices::ioapic; #[cfg(target_arch = "aarch64")] use devices::legacy::Pl011; #[cfg(target_arch = "x86_64")] use devices::legacy::Serial; use devices::{ interrupt_controller, interrupt_controller::InterruptController, AcpiNotificationFlags, }; use hypervisor::{HypervisorType, IoEventAddress}; use libc::{ cfmakeraw, isatty, tcgetattr, tcsetattr, termios, MAP_NORESERVE, MAP_PRIVATE, MAP_SHARED, O_TMPFILE, PROT_READ, PROT_WRITE, TCSANOW, }; use pci::{ DeviceRelocation, PciBarRegionType, PciBdf, PciDevice, VfioPciDevice, VfioUserDmaMapping, VfioUserPciDevice, VfioUserPciDeviceError, }; use seccompiler::SeccompAction; use serde::{Deserialize, Serialize}; use std::collections::{BTreeSet, HashMap}; use std::fs::{read_link, File, OpenOptions}; use std::io::{self, stdout, Seek, SeekFrom}; use std::mem::zeroed; use std::num::Wrapping; use std::os::unix::fs::OpenOptionsExt; use std::os::unix::io::{AsRawFd, FromRawFd, RawFd}; use std::path::PathBuf; use std::result; use std::sync::{Arc, Mutex}; use std::time::Instant; use tracer::trace_scoped; use vfio_ioctls::{VfioContainer, VfioDevice, VfioDeviceFd}; use virtio_devices::transport::VirtioTransport; use virtio_devices::transport::{VirtioPciDevice, VirtioPciDeviceActivator}; use virtio_devices::vhost_user::VhostUserConfig; use virtio_devices::{ AccessPlatformMapping, ActivateError, VdpaDmaMapping, VirtioMemMappingSource, }; use virtio_devices::{Endpoint, IommuMapping}; use vm_allocator::{AddressAllocator, SystemAllocator}; use vm_device::dma_mapping::vfio::VfioDmaMapping; use vm_device::dma_mapping::ExternalDmaMapping; use vm_device::interrupt::{ InterruptIndex, InterruptManager, LegacyIrqGroupConfig, MsiIrqGroupConfig, }; use vm_device::{Bus, BusDevice, Resource}; use vm_memory::guest_memory::FileOffset; use vm_memory::GuestMemoryRegion; use vm_memory::{Address, GuestAddress, GuestUsize, MmapRegion}; #[cfg(target_arch = "x86_64")] use vm_memory::{GuestAddressSpace, GuestMemory}; use vm_migration::{ protocol::MemoryRangeTable, snapshot_from_id, versioned_state_from_id, Migratable, MigratableError, Pausable, Snapshot, SnapshotData, Snapshottable, Transportable, }; use vm_virtio::AccessPlatform; use vm_virtio::VirtioDeviceType; use vmm_sys_util::eventfd::EventFd; #[cfg(target_arch = "aarch64")] const MMIO_LEN: u64 = 0x1000; // Singleton devices / devices the user cannot name #[cfg(target_arch = "x86_64")] const IOAPIC_DEVICE_NAME: &str = "__ioapic"; const SERIAL_DEVICE_NAME: &str = "__serial"; #[cfg(target_arch = "aarch64")] const GPIO_DEVICE_NAME: &str = "__gpio"; const RNG_DEVICE_NAME: &str = "__rng"; const IOMMU_DEVICE_NAME: &str = "__iommu"; const BALLOON_DEVICE_NAME: &str = "__balloon"; const CONSOLE_DEVICE_NAME: &str = "__console"; const PVPANIC_DEVICE_NAME: &str = "__pvpanic"; // Devices that the user may name and for which we generate // identifiers if the user doesn't give one const DISK_DEVICE_NAME_PREFIX: &str = "_disk"; const FS_DEVICE_NAME_PREFIX: &str = "_fs"; const NET_DEVICE_NAME_PREFIX: &str = "_net"; const PMEM_DEVICE_NAME_PREFIX: &str = "_pmem"; const VDPA_DEVICE_NAME_PREFIX: &str = "_vdpa"; const VSOCK_DEVICE_NAME_PREFIX: &str = "_vsock"; const WATCHDOG_DEVICE_NAME: &str = "__watchdog"; const VFIO_DEVICE_NAME_PREFIX: &str = "_vfio"; const VFIO_USER_DEVICE_NAME_PREFIX: &str = "_vfio_user"; const VIRTIO_PCI_DEVICE_NAME_PREFIX: &str = "_virtio-pci"; /// Errors associated with device manager #[derive(Debug)] pub enum DeviceManagerError { /// Cannot create EventFd. EventFd(io::Error), /// Cannot open disk path Disk(io::Error), /// Cannot create vhost-user-net device CreateVhostUserNet(virtio_devices::vhost_user::Error), /// Cannot create virtio-blk device CreateVirtioBlock(io::Error), /// Cannot create virtio-net device CreateVirtioNet(virtio_devices::net::Error), /// Cannot create virtio-console device CreateVirtioConsole(io::Error), /// Cannot create virtio-rng device CreateVirtioRng(io::Error), /// Cannot create virtio-fs device CreateVirtioFs(virtio_devices::vhost_user::Error), /// Virtio-fs device was created without a socket. NoVirtioFsSock, /// Cannot create vhost-user-blk device CreateVhostUserBlk(virtio_devices::vhost_user::Error), /// Cannot create virtio-pmem device CreateVirtioPmem(io::Error), /// Cannot create vDPA device CreateVdpa(virtio_devices::vdpa::Error), /// Cannot create virtio-vsock device CreateVirtioVsock(io::Error), /// Cannot create tpm device CreateTpmDevice(anyhow::Error), /// Failed to convert Path to &str for the vDPA device. CreateVdpaConvertPath, /// Failed to convert Path to &str for the virtio-vsock device. CreateVsockConvertPath, /// Cannot create virtio-vsock backend CreateVsockBackend(virtio_devices::vsock::VsockUnixError), /// Cannot create virtio-iommu device CreateVirtioIommu(io::Error), /// Cannot create virtio-balloon device CreateVirtioBalloon(io::Error), /// Cannot create virtio-watchdog device CreateVirtioWatchdog(io::Error), /// Failed to parse disk image format DetectImageType(io::Error), /// Cannot open qcow disk path QcowDeviceCreate(qcow::Error), /// Cannot create serial manager CreateSerialManager(SerialManagerError), /// Cannot spawn the serial manager thread SpawnSerialManager(SerialManagerError), /// Cannot open tap interface OpenTap(net_util::TapError), /// Cannot allocate IRQ. AllocateIrq, /// Cannot configure the IRQ. Irq(vmm_sys_util::errno::Error), /// Cannot allocate PCI BARs AllocateBars(pci::PciDeviceError), /// Could not free the BARs associated with a PCI device. FreePciBars(pci::PciDeviceError), /// Cannot register ioevent. RegisterIoevent(anyhow::Error), /// Cannot unregister ioevent. UnRegisterIoevent(anyhow::Error), /// Cannot create virtio device VirtioDevice(virtio_devices::transport::VirtioPciDeviceError), /// Cannot add PCI device AddPciDevice(pci::PciRootError), /// Cannot open persistent memory file PmemFileOpen(io::Error), /// Cannot set persistent memory file size PmemFileSetLen(io::Error), /// Cannot find a memory range for persistent memory PmemRangeAllocation, /// Cannot find a memory range for virtio-fs FsRangeAllocation, /// Error creating serial output file SerialOutputFileOpen(io::Error), /// Error creating console output file ConsoleOutputFileOpen(io::Error), /// Error creating serial pty SerialPtyOpen(io::Error), /// Error creating console pty ConsolePtyOpen(io::Error), /// Error setting pty raw mode SetPtyRaw(vmm_sys_util::errno::Error), /// Error getting pty peer GetPtyPeer(vmm_sys_util::errno::Error), /// Cannot create a VFIO device VfioCreate(vfio_ioctls::VfioError), /// Cannot create a VFIO PCI device VfioPciCreate(pci::VfioPciError), /// Failed to map VFIO MMIO region. VfioMapRegion(pci::VfioPciError), /// Failed to DMA map VFIO device. VfioDmaMap(vfio_ioctls::VfioError), /// Failed to DMA unmap VFIO device. VfioDmaUnmap(pci::VfioPciError), /// Failed to create the passthrough device. CreatePassthroughDevice(anyhow::Error), /// Failed to memory map. Mmap(io::Error), /// Cannot add legacy device to Bus. BusError(vm_device::BusError), /// Failed to allocate IO port AllocateIoPort, /// Failed to allocate MMIO address AllocateMmioAddress, /// Failed to make hotplug notification HotPlugNotification(io::Error), /// Error from a memory manager operation MemoryManager(MemoryManagerError), /// Failed to create new interrupt source group. CreateInterruptGroup(io::Error), /// Failed to update interrupt source group. UpdateInterruptGroup(io::Error), /// Failed to create interrupt controller. CreateInterruptController(interrupt_controller::Error), /// Failed to create a new MmapRegion instance. NewMmapRegion(vm_memory::mmap::MmapRegionError), /// Failed to clone a File. CloneFile(io::Error), /// Failed to create socket file CreateSocketFile(io::Error), /// Failed to spawn the network backend SpawnNetBackend(io::Error), /// Failed to spawn the block backend SpawnBlockBackend(io::Error), /// Missing PCI bus. NoPciBus, /// Could not find an available device name. NoAvailableDeviceName, /// Missing PCI device. MissingPciDevice, /// Failed to remove a PCI device from the PCI bus. RemoveDeviceFromPciBus(pci::PciRootError), /// Failed to remove a bus device from the IO bus. RemoveDeviceFromIoBus(vm_device::BusError), /// Failed to remove a bus device from the MMIO bus. RemoveDeviceFromMmioBus(vm_device::BusError), /// Failed to find the device corresponding to a specific PCI b/d/f. UnknownPciBdf(u32), /// Not allowed to remove this type of device from the VM. RemovalNotAllowed(vm_virtio::VirtioDeviceType), /// Failed to find device corresponding to the given identifier. UnknownDeviceId(String), /// Failed to find an available PCI device ID. NextPciDeviceId(pci::PciRootError), /// Could not reserve the PCI device ID. GetPciDeviceId(pci::PciRootError), /// Could not give the PCI device ID back. PutPciDeviceId(pci::PciRootError), /// No disk path was specified when one was expected NoDiskPath, /// Failed to update guest memory for virtio device. UpdateMemoryForVirtioDevice(virtio_devices::Error), /// Cannot create virtio-mem device CreateVirtioMem(io::Error), /// Cannot find a memory range for virtio-mem memory VirtioMemRangeAllocation, /// Failed to update guest memory for VFIO PCI device. UpdateMemoryForVfioPciDevice(vfio_ioctls::VfioError), /// Trying to use a directory for pmem but no size specified PmemWithDirectorySizeMissing, /// Trying to use a size that is not multiple of 2MiB PmemSizeNotAligned, /// Could not find the node in the device tree. MissingNode, /// Resource was already found. ResourceAlreadyExists, /// Expected resources for virtio-pmem could not be found. MissingVirtioPmemResources, /// Missing PCI b/d/f from the DeviceNode. MissingDeviceNodePciBdf, /// No support for device passthrough NoDevicePassthroughSupport, /// Failed to resize virtio-balloon VirtioBalloonResize(virtio_devices::balloon::Error), /// Missing virtio-balloon, can't proceed as expected. MissingVirtioBalloon, /// Missing virtual IOMMU device MissingVirtualIommu, /// Failed to do power button notification PowerButtonNotification(io::Error), /// Failed to do AArch64 GPIO power button notification #[cfg(target_arch = "aarch64")] AArch64PowerButtonNotification(devices::legacy::GpioDeviceError), /// Failed to set O_DIRECT flag to file descriptor SetDirectIo, /// Failed to create FixedVhdDiskAsync CreateFixedVhdDiskAsync(io::Error), /// Failed to create FixedVhdDiskSync CreateFixedVhdDiskSync(io::Error), /// Failed to create QcowDiskSync CreateQcowDiskSync(qcow::Error), /// Failed to create FixedVhdxDiskSync CreateFixedVhdxDiskSync(vhdx::vhdx::VhdxError), /// Failed to add DMA mapping handler to virtio-mem device. AddDmaMappingHandlerVirtioMem(virtio_devices::mem::Error), /// Failed to remove DMA mapping handler from virtio-mem device. RemoveDmaMappingHandlerVirtioMem(virtio_devices::mem::Error), /// Failed to create vfio-user client VfioUserCreateClient(vfio_user::Error), /// Failed to create VFIO user device VfioUserCreate(VfioUserPciDeviceError), /// Failed to map region from VFIO user device into guest VfioUserMapRegion(VfioUserPciDeviceError), /// Failed to DMA map VFIO user device. VfioUserDmaMap(VfioUserPciDeviceError), /// Failed to DMA unmap VFIO user device. VfioUserDmaUnmap(VfioUserPciDeviceError), /// Failed to update memory mappings for VFIO user device UpdateMemoryForVfioUserPciDevice(VfioUserPciDeviceError), /// Cannot duplicate file descriptor DupFd(vmm_sys_util::errno::Error), /// Failed to DMA map virtio device. VirtioDmaMap(std::io::Error), /// Failed to DMA unmap virtio device. VirtioDmaUnmap(std::io::Error), /// Cannot hotplug device behind vIOMMU InvalidIommuHotplug, /// Invalid identifier as it is not unique. IdentifierNotUnique(String), /// Invalid identifier InvalidIdentifier(String), /// Error activating virtio device VirtioActivate(ActivateError), /// Failed retrieving device state from snapshot RestoreGetState(MigratableError), /// Cannot create a PvPanic device PvPanicCreate(devices::pvpanic::PvPanicError), } pub type DeviceManagerResult = result::Result; const DEVICE_MANAGER_ACPI_SIZE: usize = 0x10; const TIOCSPTLCK: libc::c_int = 0x4004_5431; const TIOCGTPEER: libc::c_int = 0x5441; pub fn create_pty() -> io::Result<(File, File, PathBuf)> { // Try to use /dev/pts/ptmx first then fall back to /dev/ptmx // This is done to try and use the devpts filesystem that // could be available for use in the process's namespace first. // Ideally these are all the same file though but different // kernels could have things setup differently. // See https://www.kernel.org/doc/Documentation/filesystems/devpts.txt // for further details. let custom_flags = libc::O_NONBLOCK; let main = match OpenOptions::new() .read(true) .write(true) .custom_flags(custom_flags) .open("/dev/pts/ptmx") { Ok(f) => f, _ => OpenOptions::new() .read(true) .write(true) .custom_flags(custom_flags) .open("/dev/ptmx")?, }; let mut unlock: libc::c_ulong = 0; // SAFETY: FFI call into libc, trivially safe unsafe { libc::ioctl(main.as_raw_fd(), TIOCSPTLCK as _, &mut unlock) }; // SAFETY: FFI call into libc, trivally safe let sub_fd = unsafe { libc::ioctl( main.as_raw_fd(), TIOCGTPEER as _, libc::O_NOCTTY | libc::O_RDWR, ) }; if sub_fd == -1 { return vmm_sys_util::errno::errno_result().map_err(|e| e.into()); } let proc_path = PathBuf::from(format!("/proc/self/fd/{sub_fd}")); let path = read_link(proc_path)?; // SAFETY: sub_fd is checked to be valid before being wrapped in File Ok((main, unsafe { File::from_raw_fd(sub_fd) }, path)) } #[derive(Default)] pub struct Console { console_resizer: Option>, } impl Console { pub fn need_resize(&self) -> bool { if let Some(_resizer) = self.console_resizer.as_ref() { return true; } false } pub fn update_console_size(&self) { if let Some(resizer) = self.console_resizer.as_ref() { resizer.update_console_size() } } } pub(crate) struct AddressManager { pub(crate) allocator: Arc>, #[cfg(target_arch = "x86_64")] pub(crate) io_bus: Arc, pub(crate) mmio_bus: Arc, pub(crate) vm: Arc, device_tree: Arc>, pci_mmio_allocators: Vec>>, } impl DeviceRelocation for AddressManager { fn move_bar( &self, old_base: u64, new_base: u64, len: u64, pci_dev: &mut dyn PciDevice, region_type: PciBarRegionType, ) -> std::result::Result<(), std::io::Error> { match region_type { PciBarRegionType::IoRegion => { #[cfg(target_arch = "x86_64")] { // Update system allocator self.allocator .lock() .unwrap() .free_io_addresses(GuestAddress(old_base), len as GuestUsize); self.allocator .lock() .unwrap() .allocate_io_addresses( Some(GuestAddress(new_base)), len as GuestUsize, None, ) .ok_or_else(|| { io::Error::new(io::ErrorKind::Other, "failed allocating new IO range") })?; // Update PIO bus self.io_bus .update_range(old_base, len, new_base, len) .map_err(|e| io::Error::new(io::ErrorKind::Other, e))?; } #[cfg(target_arch = "aarch64")] error!("I/O region is not supported"); } PciBarRegionType::Memory32BitRegion | PciBarRegionType::Memory64BitRegion => { // Update system allocator if region_type == PciBarRegionType::Memory32BitRegion { self.allocator .lock() .unwrap() .free_mmio_hole_addresses(GuestAddress(old_base), len as GuestUsize); self.allocator .lock() .unwrap() .allocate_mmio_hole_addresses( Some(GuestAddress(new_base)), len as GuestUsize, Some(len), ) .ok_or_else(|| { io::Error::new( io::ErrorKind::Other, "failed allocating new 32 bits MMIO range", ) })?; } else { // Find the specific allocator that this BAR was allocated from and use it for new one for allocator in &self.pci_mmio_allocators { let allocator_base = allocator.lock().unwrap().base(); let allocator_end = allocator.lock().unwrap().end(); if old_base >= allocator_base.0 && old_base <= allocator_end.0 { allocator .lock() .unwrap() .free(GuestAddress(old_base), len as GuestUsize); allocator .lock() .unwrap() .allocate( Some(GuestAddress(new_base)), len as GuestUsize, Some(len), ) .ok_or_else(|| { io::Error::new( io::ErrorKind::Other, "failed allocating new 64 bits MMIO range", ) })?; break; } } } // Update MMIO bus self.mmio_bus .update_range(old_base, len, new_base, len) .map_err(|e| io::Error::new(io::ErrorKind::Other, e))?; } } // Update the device_tree resources associated with the device if let Some(id) = pci_dev.id() { if let Some(node) = self.device_tree.lock().unwrap().get_mut(&id) { let mut resource_updated = false; for resource in node.resources.iter_mut() { if let Resource::PciBar { base, type_, .. } = resource { if PciBarRegionType::from(*type_) == region_type && *base == old_base { *base = new_base; resource_updated = true; break; } } } if !resource_updated { return Err(io::Error::new( io::ErrorKind::Other, format!( "Couldn't find a resource with base 0x{old_base:x} for device {id}" ), )); } } else { return Err(io::Error::new( io::ErrorKind::Other, format!("Couldn't find device {id} from device tree"), )); } } let any_dev = pci_dev.as_any(); if let Some(virtio_pci_dev) = any_dev.downcast_ref::() { let bar_addr = virtio_pci_dev.config_bar_addr(); if bar_addr == new_base { for (event, addr) in virtio_pci_dev.ioeventfds(old_base) { let io_addr = IoEventAddress::Mmio(addr); self.vm.unregister_ioevent(event, &io_addr).map_err(|e| { io::Error::new( io::ErrorKind::Other, format!("failed to unregister ioevent: {e:?}"), ) })?; } for (event, addr) in virtio_pci_dev.ioeventfds(new_base) { let io_addr = IoEventAddress::Mmio(addr); self.vm .register_ioevent(event, &io_addr, None) .map_err(|e| { io::Error::new( io::ErrorKind::Other, format!("failed to register ioevent: {e:?}"), ) })?; } } else { let virtio_dev = virtio_pci_dev.virtio_device(); let mut virtio_dev = virtio_dev.lock().unwrap(); if let Some(mut shm_regions) = virtio_dev.get_shm_regions() { if shm_regions.addr.raw_value() == old_base { let mem_region = self.vm.make_user_memory_region( shm_regions.mem_slot, old_base, shm_regions.len, shm_regions.host_addr, false, false, ); self.vm.remove_user_memory_region(mem_region).map_err(|e| { io::Error::new( io::ErrorKind::Other, format!("failed to remove user memory region: {e:?}"), ) })?; // Create new mapping by inserting new region to KVM. let mem_region = self.vm.make_user_memory_region( shm_regions.mem_slot, new_base, shm_regions.len, shm_regions.host_addr, false, false, ); self.vm.create_user_memory_region(mem_region).map_err(|e| { io::Error::new( io::ErrorKind::Other, format!("failed to create user memory regions: {e:?}"), ) })?; // Update shared memory regions to reflect the new mapping. shm_regions.addr = GuestAddress(new_base); virtio_dev.set_shm_regions(shm_regions).map_err(|e| { io::Error::new( io::ErrorKind::Other, format!("failed to update shared memory regions: {e:?}"), ) })?; } } } } pci_dev.move_bar(old_base, new_base) } } #[derive(Serialize, Deserialize)] struct DeviceManagerState { device_tree: DeviceTree, device_id_cnt: Wrapping, } #[derive(Debug)] pub struct PtyPair { pub main: File, pub path: PathBuf, } impl Clone for PtyPair { fn clone(&self) -> Self { PtyPair { main: self.main.try_clone().unwrap(), path: self.path.clone(), } } } #[derive(Clone)] pub enum PciDeviceHandle { Vfio(Arc>), Virtio(Arc>), VfioUser(Arc>), } #[derive(Clone)] struct MetaVirtioDevice { virtio_device: Arc>, iommu: bool, id: String, pci_segment: u16, dma_handler: Option>, } #[derive(Default)] pub struct AcpiPlatformAddresses { pub pm_timer_address: Option, pub reset_reg_address: Option, pub sleep_control_reg_address: Option, pub sleep_status_reg_address: Option, } pub struct DeviceManager { // The underlying hypervisor hypervisor_type: HypervisorType, // Manage address space related to devices address_manager: Arc, // Console abstraction console: Arc, // console PTY console_pty: Option>>, // serial PTY serial_pty: Option>>, // Serial Manager serial_manager: Option>, // pty foreground status, console_resize_pipe: Option>, // To restore on exit. original_termios_opt: Arc>>, // Interrupt controller #[cfg(target_arch = "x86_64")] interrupt_controller: Option>>, #[cfg(target_arch = "aarch64")] interrupt_controller: Option>>, // Things to be added to the commandline (e.g. aarch64 early console) #[cfg(target_arch = "aarch64")] cmdline_additions: Vec, // ACPI GED notification device ged_notification_device: Option>>, // VM configuration config: Arc>, // Memory Manager memory_manager: Arc>, // CPU Manager cpu_manager: Arc>, // The virtio devices on the system virtio_devices: Vec, // List of bus devices // Let the DeviceManager keep strong references to the BusDevice devices. // This allows the IO and MMIO buses to be provided with Weak references, // which prevents cyclic dependencies. bus_devices: Vec>>, // Counter to keep track of the consumed device IDs. device_id_cnt: Wrapping, pci_segments: Vec, #[cfg_attr(target_arch = "aarch64", allow(dead_code))] // MSI Interrupt Manager msi_interrupt_manager: Arc>, #[cfg_attr(feature = "mshv", allow(dead_code))] // Legacy Interrupt Manager legacy_interrupt_manager: Option>>, // Passthrough device handle passthrough_device: Option, // VFIO container // Only one container can be created, therefore it is stored as part of the // DeviceManager to be reused. vfio_container: Option>, // Paravirtualized IOMMU iommu_device: Option>>, iommu_mapping: Option>, // PCI information about devices attached to the paravirtualized IOMMU // It contains the virtual IOMMU PCI BDF along with the list of PCI BDF // representing the devices attached to the virtual IOMMU. This is useful // information for filling the ACPI VIOT table. iommu_attached_devices: Option<(PciBdf, Vec)>, // Tree of devices, representing the dependencies between devices. // Useful for introspection, snapshot and restore. device_tree: Arc>, // Exit event exit_evt: EventFd, reset_evt: EventFd, #[cfg(target_arch = "aarch64")] id_to_dev_info: HashMap<(DeviceType, String), MmioDeviceInfo>, // seccomp action seccomp_action: SeccompAction, // List of guest NUMA nodes. numa_nodes: NumaNodes, // Possible handle to the virtio-balloon device balloon: Option>>, // Virtio Device activation EventFd to allow the VMM thread to trigger device // activation and thus start the threads from the VMM thread activate_evt: EventFd, acpi_address: GuestAddress, selected_segment: usize, // Possible handle to the virtio-mem device virtio_mem_devices: Vec>>, #[cfg(target_arch = "aarch64")] // GPIO device for AArch64 gpio_device: Option>>, // pvpanic device pvpanic_device: Option>>, // Flag to force setting the iommu on virtio devices force_iommu: bool, // io_uring availability if detected io_uring_supported: Option, // List of unique identifiers provided at boot through the configuration. boot_id_list: BTreeSet, // Start time of the VM timestamp: Instant, // Pending activations pending_activations: Arc>>, // Addresses for ACPI platform devices e.g. ACPI PM timer, sleep/reset registers acpi_platform_addresses: AcpiPlatformAddresses, snapshot: Option, } impl DeviceManager { #[allow(clippy::too_many_arguments)] pub fn new( #[cfg(target_arch = "x86_64")] io_bus: Arc, mmio_bus: Arc, hypervisor_type: HypervisorType, vm: Arc, config: Arc>, memory_manager: Arc>, cpu_manager: Arc>, exit_evt: EventFd, reset_evt: EventFd, seccomp_action: SeccompAction, numa_nodes: NumaNodes, activate_evt: &EventFd, force_iommu: bool, boot_id_list: BTreeSet, timestamp: Instant, snapshot: Option, dynamic: bool, ) -> DeviceManagerResult>> { trace_scoped!("DeviceManager::new"); let (device_tree, device_id_cnt) = if let Some(snapshot) = snapshot.as_ref() { let state: DeviceManagerState = snapshot.to_state().unwrap(); ( Arc::new(Mutex::new(state.device_tree.clone())), state.device_id_cnt, ) } else { (Arc::new(Mutex::new(DeviceTree::new())), Wrapping(0)) }; let num_pci_segments = if let Some(platform_config) = config.lock().unwrap().platform.as_ref() { platform_config.num_pci_segments } else { 1 }; let start_of_device_area = memory_manager.lock().unwrap().start_of_device_area().0; let end_of_device_area = memory_manager.lock().unwrap().end_of_device_area().0; // Start each PCI segment range on a 4GiB boundary let pci_segment_size = (end_of_device_area - start_of_device_area + 1) / ((4 << 30) * num_pci_segments as u64) * (4 << 30); let mut pci_mmio_allocators = vec![]; for i in 0..num_pci_segments as u64 { let mmio_start = start_of_device_area + i * pci_segment_size; let allocator = Arc::new(Mutex::new( AddressAllocator::new(GuestAddress(mmio_start), pci_segment_size).unwrap(), )); pci_mmio_allocators.push(allocator) } let address_manager = Arc::new(AddressManager { allocator: memory_manager.lock().unwrap().allocator(), #[cfg(target_arch = "x86_64")] io_bus, mmio_bus, vm: vm.clone(), device_tree: Arc::clone(&device_tree), pci_mmio_allocators, }); // First we create the MSI interrupt manager, the legacy one is created // later, after the IOAPIC device creation. // The reason we create the MSI one first is because the IOAPIC needs it, // and then the legacy interrupt manager needs an IOAPIC. So we're // handling a linear dependency chain: // msi_interrupt_manager <- IOAPIC <- legacy_interrupt_manager. let msi_interrupt_manager: Arc> = Arc::new(MsiInterruptManager::new( Arc::clone(&address_manager.allocator), vm, )); let acpi_address = address_manager .allocator .lock() .unwrap() .allocate_platform_mmio_addresses(None, DEVICE_MANAGER_ACPI_SIZE as u64, None) .ok_or(DeviceManagerError::AllocateIoPort)?; let mut pci_irq_slots = [0; 32]; PciSegment::reserve_legacy_interrupts_for_pci_devices( &address_manager, &mut pci_irq_slots, )?; let mut pci_segments = vec![PciSegment::new_default_segment( &address_manager, Arc::clone(&address_manager.pci_mmio_allocators[0]), &pci_irq_slots, )?]; for i in 1..num_pci_segments as usize { pci_segments.push(PciSegment::new( i as u16, &address_manager, Arc::clone(&address_manager.pci_mmio_allocators[i]), &pci_irq_slots, )?); } if dynamic { let acpi_address = address_manager .allocator .lock() .unwrap() .allocate_platform_mmio_addresses(None, CPU_MANAGER_ACPI_SIZE as u64, None) .ok_or(DeviceManagerError::AllocateMmioAddress)?; address_manager .mmio_bus .insert( cpu_manager.clone(), acpi_address.0, CPU_MANAGER_ACPI_SIZE as u64, ) .map_err(DeviceManagerError::BusError)?; cpu_manager.lock().unwrap().set_acpi_address(acpi_address); } let device_manager = DeviceManager { hypervisor_type, address_manager: Arc::clone(&address_manager), console: Arc::new(Console::default()), interrupt_controller: None, #[cfg(target_arch = "aarch64")] cmdline_additions: Vec::new(), ged_notification_device: None, config, memory_manager, cpu_manager, virtio_devices: Vec::new(), bus_devices: Vec::new(), device_id_cnt, msi_interrupt_manager, legacy_interrupt_manager: None, passthrough_device: None, vfio_container: None, iommu_device: None, iommu_mapping: None, iommu_attached_devices: None, pci_segments, device_tree, exit_evt, reset_evt, #[cfg(target_arch = "aarch64")] id_to_dev_info: HashMap::new(), seccomp_action, numa_nodes, balloon: None, activate_evt: activate_evt .try_clone() .map_err(DeviceManagerError::EventFd)?, acpi_address, selected_segment: 0, serial_pty: None, serial_manager: None, console_pty: None, console_resize_pipe: None, original_termios_opt: Arc::new(Mutex::new(None)), virtio_mem_devices: Vec::new(), #[cfg(target_arch = "aarch64")] gpio_device: None, pvpanic_device: None, force_iommu, io_uring_supported: None, boot_id_list, timestamp, pending_activations: Arc::new(Mutex::new(Vec::default())), acpi_platform_addresses: AcpiPlatformAddresses::default(), snapshot, }; let device_manager = Arc::new(Mutex::new(device_manager)); address_manager .mmio_bus .insert( Arc::clone(&device_manager) as Arc>, acpi_address.0, DEVICE_MANAGER_ACPI_SIZE as u64, ) .map_err(DeviceManagerError::BusError)?; Ok(device_manager) } pub fn serial_pty(&self) -> Option { self.serial_pty .as_ref() .map(|pty| pty.lock().unwrap().clone()) } pub fn console_pty(&self) -> Option { self.console_pty .as_ref() .map(|pty| pty.lock().unwrap().clone()) } pub fn console_resize_pipe(&self) -> Option> { self.console_resize_pipe.as_ref().map(Arc::clone) } pub fn create_devices( &mut self, serial_pty: Option, console_pty: Option, console_resize_pipe: Option, original_termios_opt: Arc>>, ) -> DeviceManagerResult<()> { trace_scoped!("create_devices"); let mut virtio_devices: Vec = Vec::new(); let interrupt_controller = self.add_interrupt_controller()?; self.cpu_manager .lock() .unwrap() .set_interrupt_controller(interrupt_controller.clone()); // Now we can create the legacy interrupt manager, which needs the freshly // formed IOAPIC device. let legacy_interrupt_manager: Arc< dyn InterruptManager, > = Arc::new(LegacyUserspaceInterruptManager::new(Arc::clone( &interrupt_controller, ))); { if let Some(acpi_address) = self.memory_manager.lock().unwrap().acpi_address() { self.address_manager .mmio_bus .insert( Arc::clone(&self.memory_manager) as Arc>, acpi_address.0, MEMORY_MANAGER_ACPI_SIZE as u64, ) .map_err(DeviceManagerError::BusError)?; } } #[cfg(target_arch = "x86_64")] self.add_legacy_devices( self.reset_evt .try_clone() .map_err(DeviceManagerError::EventFd)?, )?; #[cfg(target_arch = "aarch64")] self.add_legacy_devices(&legacy_interrupt_manager)?; { self.ged_notification_device = self.add_acpi_devices( &legacy_interrupt_manager, self.reset_evt .try_clone() .map_err(DeviceManagerError::EventFd)?, self.exit_evt .try_clone() .map_err(DeviceManagerError::EventFd)?, )?; } self.original_termios_opt = original_termios_opt; self.console = self.add_console_device( &legacy_interrupt_manager, &mut virtio_devices, serial_pty, console_pty, console_resize_pipe, )?; if let Some(tpm) = self.config.clone().lock().unwrap().tpm.as_ref() { let tpm_dev = self.add_tpm_device(tpm.socket.clone())?; self.bus_devices .push(Arc::clone(&tpm_dev) as Arc>) } self.legacy_interrupt_manager = Some(legacy_interrupt_manager); virtio_devices.append(&mut self.make_virtio_devices()?); self.add_pci_devices(virtio_devices.clone())?; self.virtio_devices = virtio_devices; if self.config.clone().lock().unwrap().pvpanic { self.pvpanic_device = self.add_pvpanic_device()?; } Ok(()) } fn state(&self) -> DeviceManagerState { DeviceManagerState { device_tree: self.device_tree.lock().unwrap().clone(), device_id_cnt: self.device_id_cnt, } } fn get_msi_iova_space(&mut self) -> (u64, u64) { #[cfg(target_arch = "aarch64")] { let vcpus = self.config.lock().unwrap().cpus.boot_vcpus; let vgic_config = gic::Gic::create_default_config(vcpus.into()); ( vgic_config.msi_addr, vgic_config.msi_addr + vgic_config.msi_size - 1, ) } #[cfg(target_arch = "x86_64")] (0xfee0_0000, 0xfeef_ffff) } #[cfg(target_arch = "aarch64")] /// Gets the information of the devices registered up to some point in time. pub fn get_device_info(&self) -> &HashMap<(DeviceType, String), MmioDeviceInfo> { &self.id_to_dev_info } #[allow(unused_variables)] fn add_pci_devices( &mut self, virtio_devices: Vec, ) -> DeviceManagerResult<()> { let iommu_id = String::from(IOMMU_DEVICE_NAME); let iommu_device = if self.config.lock().unwrap().iommu { let (device, mapping) = virtio_devices::Iommu::new( iommu_id.clone(), self.seccomp_action.clone(), self.exit_evt .try_clone() .map_err(DeviceManagerError::EventFd)?, self.get_msi_iova_space(), versioned_state_from_id(self.snapshot.as_ref(), iommu_id.as_str()) .map_err(DeviceManagerError::RestoreGetState)?, ) .map_err(DeviceManagerError::CreateVirtioIommu)?; let device = Arc::new(Mutex::new(device)); self.iommu_device = Some(Arc::clone(&device)); self.iommu_mapping = Some(mapping); // Fill the device tree with a new node. In case of restore, we // know there is nothing to do, so we can simply override the // existing entry. self.device_tree .lock() .unwrap() .insert(iommu_id.clone(), device_node!(iommu_id, device)); Some(device) } else { None }; let mut iommu_attached_devices = Vec::new(); { for handle in virtio_devices { let mapping: Option> = if handle.iommu { self.iommu_mapping.clone() } else { None }; let dev_id = self.add_virtio_pci_device( handle.virtio_device, &mapping, handle.id, handle.pci_segment, handle.dma_handler, )?; if handle.iommu { iommu_attached_devices.push(dev_id); } } let mut vfio_iommu_device_ids = self.add_vfio_devices()?; iommu_attached_devices.append(&mut vfio_iommu_device_ids); let mut vfio_user_iommu_device_ids = self.add_user_devices()?; iommu_attached_devices.append(&mut vfio_user_iommu_device_ids); // Add all devices from forced iommu segments if let Some(platform_config) = self.config.lock().unwrap().platform.as_ref() { if let Some(iommu_segments) = platform_config.iommu_segments.as_ref() { for segment in iommu_segments { for device in 0..32 { let bdf = PciBdf::new(*segment, 0, device, 0); if !iommu_attached_devices.contains(&bdf) { iommu_attached_devices.push(bdf); } } } } } if let Some(iommu_device) = iommu_device { let dev_id = self.add_virtio_pci_device(iommu_device, &None, iommu_id, 0, None)?; self.iommu_attached_devices = Some((dev_id, iommu_attached_devices)); } } for segment in &self.pci_segments { #[cfg(target_arch = "x86_64")] if let Some(pci_config_io) = segment.pci_config_io.as_ref() { self.bus_devices .push(Arc::clone(pci_config_io) as Arc>); } self.bus_devices .push(Arc::clone(&segment.pci_config_mmio) as Arc>); } Ok(()) } #[cfg(target_arch = "aarch64")] fn add_interrupt_controller( &mut self, ) -> DeviceManagerResult>> { let interrupt_controller: Arc> = Arc::new(Mutex::new( gic::Gic::new( self.config.lock().unwrap().cpus.boot_vcpus, Arc::clone(&self.msi_interrupt_manager), self.address_manager.vm.clone(), ) .map_err(DeviceManagerError::CreateInterruptController)?, )); self.interrupt_controller = Some(interrupt_controller.clone()); // Restore the vGic if this is in the process of restoration let id = String::from(gic::GIC_SNAPSHOT_ID); if let Some(vgic_snapshot) = snapshot_from_id(self.snapshot.as_ref(), &id) { // PMU support is optional. Nothing should be impacted if the PMU initialization failed. if self .cpu_manager .lock() .unwrap() .init_pmu(arch::aarch64::fdt::AARCH64_PMU_IRQ + 16) .is_err() { info!("Failed to initialize PMU"); } let vgic_state = vgic_snapshot .to_state() .map_err(DeviceManagerError::RestoreGetState)?; let saved_vcpu_states = self.cpu_manager.lock().unwrap().get_saved_states(); interrupt_controller .lock() .unwrap() .restore_vgic(vgic_state, &saved_vcpu_states) .unwrap(); } self.device_tree .lock() .unwrap() .insert(id.clone(), device_node!(id, interrupt_controller)); Ok(interrupt_controller) } #[cfg(target_arch = "aarch64")] pub fn get_interrupt_controller(&mut self) -> Option<&Arc>> { self.interrupt_controller.as_ref() } #[cfg(target_arch = "x86_64")] fn add_interrupt_controller( &mut self, ) -> DeviceManagerResult>> { let id = String::from(IOAPIC_DEVICE_NAME); // Create IOAPIC let interrupt_controller = Arc::new(Mutex::new( ioapic::Ioapic::new( id.clone(), APIC_START, Arc::clone(&self.msi_interrupt_manager), versioned_state_from_id(self.snapshot.as_ref(), id.as_str()) .map_err(DeviceManagerError::RestoreGetState)?, ) .map_err(DeviceManagerError::CreateInterruptController)?, )); self.interrupt_controller = Some(interrupt_controller.clone()); self.address_manager .mmio_bus .insert(interrupt_controller.clone(), IOAPIC_START.0, IOAPIC_SIZE) .map_err(DeviceManagerError::BusError)?; self.bus_devices .push(Arc::clone(&interrupt_controller) as Arc>); // Fill the device tree with a new node. In case of restore, we // know there is nothing to do, so we can simply override the // existing entry. self.device_tree .lock() .unwrap() .insert(id.clone(), device_node!(id, interrupt_controller)); Ok(interrupt_controller) } fn add_acpi_devices( &mut self, interrupt_manager: &Arc>, reset_evt: EventFd, exit_evt: EventFd, ) -> DeviceManagerResult>>> { let shutdown_device = Arc::new(Mutex::new(devices::AcpiShutdownDevice::new( exit_evt, reset_evt, ))); self.bus_devices .push(Arc::clone(&shutdown_device) as Arc>); #[cfg(target_arch = "x86_64")] { let shutdown_pio_address: u16 = 0x600; self.address_manager .allocator .lock() .unwrap() .allocate_io_addresses(Some(GuestAddress(shutdown_pio_address.into())), 0x8, None) .ok_or(DeviceManagerError::AllocateIoPort)?; self.address_manager .io_bus .insert(shutdown_device, shutdown_pio_address.into(), 0x4) .map_err(DeviceManagerError::BusError)?; self.acpi_platform_addresses.sleep_control_reg_address = Some(GenericAddress::io_port_address::(shutdown_pio_address)); self.acpi_platform_addresses.sleep_status_reg_address = Some(GenericAddress::io_port_address::(shutdown_pio_address)); self.acpi_platform_addresses.reset_reg_address = Some(GenericAddress::io_port_address::(shutdown_pio_address)); } let ged_irq = self .address_manager .allocator .lock() .unwrap() .allocate_irq() .unwrap(); let interrupt_group = interrupt_manager .create_group(LegacyIrqGroupConfig { irq: ged_irq as InterruptIndex, }) .map_err(DeviceManagerError::CreateInterruptGroup)?; let ged_address = self .address_manager .allocator .lock() .unwrap() .allocate_platform_mmio_addresses( None, devices::acpi::GED_DEVICE_ACPI_SIZE as u64, None, ) .ok_or(DeviceManagerError::AllocateMmioAddress)?; let ged_device = Arc::new(Mutex::new(devices::AcpiGedDevice::new( interrupt_group, ged_irq, ged_address, ))); self.address_manager .mmio_bus .insert( ged_device.clone(), ged_address.0, devices::acpi::GED_DEVICE_ACPI_SIZE as u64, ) .map_err(DeviceManagerError::BusError)?; self.bus_devices .push(Arc::clone(&ged_device) as Arc>); let pm_timer_device = Arc::new(Mutex::new(devices::AcpiPmTimerDevice::new())); self.bus_devices .push(Arc::clone(&pm_timer_device) as Arc>); #[cfg(target_arch = "x86_64")] { let pm_timer_pio_address: u16 = 0x608; self.address_manager .allocator .lock() .unwrap() .allocate_io_addresses(Some(GuestAddress(pm_timer_pio_address.into())), 0x4, None) .ok_or(DeviceManagerError::AllocateIoPort)?; self.address_manager .io_bus .insert(pm_timer_device, pm_timer_pio_address.into(), 0x4) .map_err(DeviceManagerError::BusError)?; self.acpi_platform_addresses.pm_timer_address = Some(GenericAddress::io_port_address::(pm_timer_pio_address)); } Ok(Some(ged_device)) } #[cfg(target_arch = "x86_64")] fn add_legacy_devices(&mut self, reset_evt: EventFd) -> DeviceManagerResult<()> { // Add a shutdown device (i8042) let i8042 = Arc::new(Mutex::new(devices::legacy::I8042Device::new( reset_evt.try_clone().unwrap(), ))); self.bus_devices .push(Arc::clone(&i8042) as Arc>); self.address_manager .io_bus .insert(i8042, 0x61, 0x4) .map_err(DeviceManagerError::BusError)?; { // Add a CMOS emulated device let mem_size = self .memory_manager .lock() .unwrap() .guest_memory() .memory() .last_addr() .0 + 1; let mem_below_4g = std::cmp::min(arch::layout::MEM_32BIT_RESERVED_START.0, mem_size); let mem_above_4g = mem_size.saturating_sub(arch::layout::RAM_64BIT_START.0); let cmos = Arc::new(Mutex::new(devices::legacy::Cmos::new( mem_below_4g, mem_above_4g, reset_evt, ))); self.bus_devices .push(Arc::clone(&cmos) as Arc>); self.address_manager .io_bus .insert(cmos, 0x70, 0x2) .map_err(DeviceManagerError::BusError)?; let fwdebug = Arc::new(Mutex::new(devices::legacy::FwDebugDevice::new())); self.bus_devices .push(Arc::clone(&fwdebug) as Arc>); self.address_manager .io_bus .insert(fwdebug, 0x402, 0x1) .map_err(DeviceManagerError::BusError)?; } // 0x80 debug port let debug_port = Arc::new(Mutex::new(devices::legacy::DebugPort::new(self.timestamp))); self.bus_devices .push(Arc::clone(&debug_port) as Arc>); self.address_manager .io_bus .insert(debug_port, 0x80, 0x1) .map_err(DeviceManagerError::BusError)?; Ok(()) } #[cfg(target_arch = "aarch64")] fn add_legacy_devices( &mut self, interrupt_manager: &Arc>, ) -> DeviceManagerResult<()> { // Add a RTC device let rtc_irq = self .address_manager .allocator .lock() .unwrap() .allocate_irq() .unwrap(); let interrupt_group = interrupt_manager .create_group(LegacyIrqGroupConfig { irq: rtc_irq as InterruptIndex, }) .map_err(DeviceManagerError::CreateInterruptGroup)?; let rtc_device = Arc::new(Mutex::new(devices::legacy::Rtc::new(interrupt_group))); self.bus_devices .push(Arc::clone(&rtc_device) as Arc>); let addr = arch::layout::LEGACY_RTC_MAPPED_IO_START; self.address_manager .mmio_bus .insert(rtc_device, addr.0, MMIO_LEN) .map_err(DeviceManagerError::BusError)?; self.id_to_dev_info.insert( (DeviceType::Rtc, "rtc".to_string()), MmioDeviceInfo { addr: addr.0, len: MMIO_LEN, irq: rtc_irq, }, ); // Add a GPIO device let id = String::from(GPIO_DEVICE_NAME); let gpio_irq = self .address_manager .allocator .lock() .unwrap() .allocate_irq() .unwrap(); let interrupt_group = interrupt_manager .create_group(LegacyIrqGroupConfig { irq: gpio_irq as InterruptIndex, }) .map_err(DeviceManagerError::CreateInterruptGroup)?; let gpio_device = Arc::new(Mutex::new(devices::legacy::Gpio::new( id.clone(), interrupt_group, versioned_state_from_id(self.snapshot.as_ref(), id.as_str()) .map_err(DeviceManagerError::RestoreGetState)?, ))); self.bus_devices .push(Arc::clone(&gpio_device) as Arc>); let addr = arch::layout::LEGACY_GPIO_MAPPED_IO_START; self.address_manager .mmio_bus .insert(gpio_device.clone(), addr.0, MMIO_LEN) .map_err(DeviceManagerError::BusError)?; self.gpio_device = Some(gpio_device.clone()); self.id_to_dev_info.insert( (DeviceType::Gpio, "gpio".to_string()), MmioDeviceInfo { addr: addr.0, len: MMIO_LEN, irq: gpio_irq, }, ); self.device_tree .lock() .unwrap() .insert(id.clone(), device_node!(id, gpio_device)); Ok(()) } #[cfg(target_arch = "x86_64")] fn add_serial_device( &mut self, interrupt_manager: &Arc>, serial_writer: Option>, ) -> DeviceManagerResult>> { // Serial is tied to IRQ #4 let serial_irq = 4; let id = String::from(SERIAL_DEVICE_NAME); let interrupt_group = interrupt_manager .create_group(LegacyIrqGroupConfig { irq: serial_irq as InterruptIndex, }) .map_err(DeviceManagerError::CreateInterruptGroup)?; let serial = Arc::new(Mutex::new(Serial::new( id.clone(), interrupt_group, serial_writer, versioned_state_from_id(self.snapshot.as_ref(), id.as_str()) .map_err(DeviceManagerError::RestoreGetState)?, ))); self.bus_devices .push(Arc::clone(&serial) as Arc>); self.address_manager .allocator .lock() .unwrap() .allocate_io_addresses(Some(GuestAddress(0x3f8)), 0x8, None) .ok_or(DeviceManagerError::AllocateIoPort)?; self.address_manager .io_bus .insert(serial.clone(), 0x3f8, 0x8) .map_err(DeviceManagerError::BusError)?; // Fill the device tree with a new node. In case of restore, we // know there is nothing to do, so we can simply override the // existing entry. self.device_tree .lock() .unwrap() .insert(id.clone(), device_node!(id, serial)); Ok(serial) } #[cfg(target_arch = "aarch64")] fn add_serial_device( &mut self, interrupt_manager: &Arc>, serial_writer: Option>, ) -> DeviceManagerResult>> { let id = String::from(SERIAL_DEVICE_NAME); let serial_irq = self .address_manager .allocator .lock() .unwrap() .allocate_irq() .unwrap(); let interrupt_group = interrupt_manager .create_group(LegacyIrqGroupConfig { irq: serial_irq as InterruptIndex, }) .map_err(DeviceManagerError::CreateInterruptGroup)?; let serial = Arc::new(Mutex::new(devices::legacy::Pl011::new( id.clone(), interrupt_group, serial_writer, self.timestamp, versioned_state_from_id(self.snapshot.as_ref(), id.as_str()) .map_err(DeviceManagerError::RestoreGetState)?, ))); self.bus_devices .push(Arc::clone(&serial) as Arc>); let addr = arch::layout::LEGACY_SERIAL_MAPPED_IO_START; self.address_manager .mmio_bus .insert(serial.clone(), addr.0, MMIO_LEN) .map_err(DeviceManagerError::BusError)?; self.id_to_dev_info.insert( (DeviceType::Serial, DeviceType::Serial.to_string()), MmioDeviceInfo { addr: addr.0, len: MMIO_LEN, irq: serial_irq, }, ); self.cmdline_additions .push(format!("earlycon=pl011,mmio,0x{:08x}", addr.0)); // Fill the device tree with a new node. In case of restore, we // know there is nothing to do, so we can simply override the // existing entry. self.device_tree .lock() .unwrap() .insert(id.clone(), device_node!(id, serial)); Ok(serial) } fn modify_mode( &mut self, fd: RawFd, f: F, ) -> vmm_sys_util::errno::Result<()> { // SAFETY: safe because we check the return value of isatty. if unsafe { isatty(fd) } != 1 { return Ok(()); } // SAFETY: The following pair are safe because termios gets totally overwritten by tcgetattr // and we check the return result. let mut termios: termios = unsafe { zeroed() }; // SAFETY: see above let ret = unsafe { tcgetattr(fd, &mut termios as *mut _) }; if ret < 0 { return vmm_sys_util::errno::errno_result(); } let mut original_termios_opt = self.original_termios_opt.lock().unwrap(); if original_termios_opt.is_none() { *original_termios_opt = Some(termios); } f(&mut termios); // SAFETY: Safe because the syscall will only read the extent of termios and we check // the return result. let ret = unsafe { tcsetattr(fd, TCSANOW, &termios as *const _) }; if ret < 0 { return vmm_sys_util::errno::errno_result(); } Ok(()) } fn set_raw_mode(&mut self, f: &mut dyn AsRawFd) -> vmm_sys_util::errno::Result<()> { // SAFETY: FFI call. Variable t is guaranteed to be a valid termios from modify_mode. self.modify_mode(f.as_raw_fd(), |t| unsafe { cfmakeraw(t) }) } fn listen_for_sigwinch_on_tty(&mut self, pty_sub: File) -> std::io::Result<()> { let seccomp_filter = get_seccomp_filter( &self.seccomp_action, Thread::PtyForeground, self.hypervisor_type, ) .unwrap(); self.console_resize_pipe = Some(Arc::new(start_sigwinch_listener(seccomp_filter, pty_sub)?)); Ok(()) } fn add_virtio_console_device( &mut self, virtio_devices: &mut Vec, console_pty: Option, resize_pipe: Option, ) -> DeviceManagerResult>> { let console_config = self.config.lock().unwrap().console.clone(); let endpoint = match console_config.mode { ConsoleOutputMode::File => { let file = File::create(console_config.file.as_ref().unwrap()) .map_err(DeviceManagerError::ConsoleOutputFileOpen)?; Endpoint::File(file) } ConsoleOutputMode::Pty => { if let Some(pty) = console_pty { self.config.lock().unwrap().console.file = Some(pty.path.clone()); let file = pty.main.try_clone().unwrap(); self.console_pty = Some(Arc::new(Mutex::new(pty))); self.console_resize_pipe = resize_pipe.map(Arc::new); Endpoint::PtyPair(file.try_clone().unwrap(), file) } else { let (main, mut sub, path) = create_pty().map_err(DeviceManagerError::ConsolePtyOpen)?; self.set_raw_mode(&mut sub) .map_err(DeviceManagerError::SetPtyRaw)?; self.config.lock().unwrap().console.file = Some(path.clone()); let file = main.try_clone().unwrap(); assert!(resize_pipe.is_none()); self.listen_for_sigwinch_on_tty(sub).unwrap(); self.console_pty = Some(Arc::new(Mutex::new(PtyPair { main, path }))); Endpoint::PtyPair(file.try_clone().unwrap(), file) } } ConsoleOutputMode::Tty => { // Duplicating the file descriptors like this is needed as otherwise // they will be closed on a reboot and the numbers reused // SAFETY: FFI call to dup. Trivially safe. let stdout = unsafe { libc::dup(libc::STDOUT_FILENO) }; if stdout == -1 { return vmm_sys_util::errno::errno_result().map_err(DeviceManagerError::DupFd); } // SAFETY: stdout is valid and owned solely by us. let mut stdout = unsafe { File::from_raw_fd(stdout) }; // Make sure stdout is in raw mode, if it's a terminal. let _ = self.set_raw_mode(&mut stdout); // SAFETY: FFI call. Trivially safe. if unsafe { libc::isatty(libc::STDOUT_FILENO) } == 1 { self.listen_for_sigwinch_on_tty(stdout.try_clone().unwrap()) .unwrap(); } // If an interactive TTY then we can accept input // SAFETY: FFI call. Trivially safe. if unsafe { libc::isatty(libc::STDIN_FILENO) == 1 } { // SAFETY: FFI call to dup. Trivially safe. let stdin = unsafe { libc::dup(libc::STDIN_FILENO) }; if stdin == -1 { return vmm_sys_util::errno::errno_result() .map_err(DeviceManagerError::DupFd); } // SAFETY: stdin is valid and owned solely by us. let stdin = unsafe { File::from_raw_fd(stdin) }; Endpoint::FilePair(stdout, stdin) } else { Endpoint::File(stdout) } } ConsoleOutputMode::Null => Endpoint::Null, ConsoleOutputMode::Off => return Ok(None), }; let id = String::from(CONSOLE_DEVICE_NAME); let (virtio_console_device, console_resizer) = virtio_devices::Console::new( id.clone(), endpoint, self.console_resize_pipe .as_ref() .map(|p| p.try_clone().unwrap()), self.force_iommu | console_config.iommu, self.seccomp_action.clone(), self.exit_evt .try_clone() .map_err(DeviceManagerError::EventFd)?, versioned_state_from_id(self.snapshot.as_ref(), id.as_str()) .map_err(DeviceManagerError::RestoreGetState)?, ) .map_err(DeviceManagerError::CreateVirtioConsole)?; let virtio_console_device = Arc::new(Mutex::new(virtio_console_device)); virtio_devices.push(MetaVirtioDevice { virtio_device: Arc::clone(&virtio_console_device) as Arc>, iommu: console_config.iommu, id: id.clone(), pci_segment: 0, dma_handler: None, }); // Fill the device tree with a new node. In case of restore, we // know there is nothing to do, so we can simply override the // existing entry. self.device_tree .lock() .unwrap() .insert(id.clone(), device_node!(id, virtio_console_device)); // Only provide a resizer (for SIGWINCH handling) if the console is attached to the TTY Ok(if matches!(console_config.mode, ConsoleOutputMode::Tty) { Some(console_resizer) } else { None }) } fn add_console_device( &mut self, interrupt_manager: &Arc>, virtio_devices: &mut Vec, serial_pty: Option, console_pty: Option, console_resize_pipe: Option, ) -> DeviceManagerResult> { let serial_config = self.config.lock().unwrap().serial.clone(); let serial_writer: Option> = match serial_config.mode { ConsoleOutputMode::File => Some(Box::new( File::create(serial_config.file.as_ref().unwrap()) .map_err(DeviceManagerError::SerialOutputFileOpen)?, )), ConsoleOutputMode::Pty => { if let Some(pty) = serial_pty { self.config.lock().unwrap().serial.file = Some(pty.path.clone()); self.serial_pty = Some(Arc::new(Mutex::new(pty))); } else { let (main, mut sub, path) = create_pty().map_err(DeviceManagerError::SerialPtyOpen)?; self.set_raw_mode(&mut sub) .map_err(DeviceManagerError::SetPtyRaw)?; self.config.lock().unwrap().serial.file = Some(path.clone()); self.serial_pty = Some(Arc::new(Mutex::new(PtyPair { main, path }))); } None } ConsoleOutputMode::Tty => { let mut out = stdout(); let _ = self.set_raw_mode(&mut out); Some(Box::new(out)) } ConsoleOutputMode::Off | ConsoleOutputMode::Null => None, }; if serial_config.mode != ConsoleOutputMode::Off { let serial = self.add_serial_device(interrupt_manager, serial_writer)?; self.serial_manager = match serial_config.mode { ConsoleOutputMode::Pty | ConsoleOutputMode::Tty => { let serial_manager = SerialManager::new(serial, self.serial_pty.clone(), serial_config.mode) .map_err(DeviceManagerError::CreateSerialManager)?; if let Some(mut serial_manager) = serial_manager { serial_manager .start_thread( self.exit_evt .try_clone() .map_err(DeviceManagerError::EventFd)?, ) .map_err(DeviceManagerError::SpawnSerialManager)?; Some(Arc::new(serial_manager)) } else { None } } _ => None, }; } let console_resizer = self.add_virtio_console_device(virtio_devices, console_pty, console_resize_pipe)?; Ok(Arc::new(Console { console_resizer })) } fn add_tpm_device( &mut self, tpm_path: PathBuf, ) -> DeviceManagerResult>> { // Create TPM Device let tpm = devices::tpm::Tpm::new(tpm_path.to_str().unwrap().to_string()).map_err(|e| { DeviceManagerError::CreateTpmDevice(anyhow!("Failed to create TPM Device : {:?}", e)) })?; let tpm = Arc::new(Mutex::new(tpm)); // Add TPM Device to mmio self.address_manager .mmio_bus .insert( tpm.clone(), arch::layout::TPM_START.0, arch::layout::TPM_SIZE, ) .map_err(DeviceManagerError::BusError)?; Ok(tpm) } fn make_virtio_devices(&mut self) -> DeviceManagerResult> { let mut devices: Vec = Vec::new(); // Create "standard" virtio devices (net/block/rng) devices.append(&mut self.make_virtio_block_devices()?); devices.append(&mut self.make_virtio_net_devices()?); devices.append(&mut self.make_virtio_rng_devices()?); // Add virtio-fs if required devices.append(&mut self.make_virtio_fs_devices()?); // Add virtio-pmem if required devices.append(&mut self.make_virtio_pmem_devices()?); // Add virtio-vsock if required devices.append(&mut self.make_virtio_vsock_devices()?); devices.append(&mut self.make_virtio_mem_devices()?); // Add virtio-balloon if required devices.append(&mut self.make_virtio_balloon_devices()?); // Add virtio-watchdog device devices.append(&mut self.make_virtio_watchdog_devices()?); // Add vDPA devices if required devices.append(&mut self.make_vdpa_devices()?); Ok(devices) } // Cache whether io_uring is supported to avoid probing for very block device fn io_uring_is_supported(&mut self) -> bool { if let Some(supported) = self.io_uring_supported { return supported; } let supported = block_io_uring_is_supported(); self.io_uring_supported = Some(supported); supported } fn make_virtio_block_device( &mut self, disk_cfg: &mut DiskConfig, ) -> DeviceManagerResult { let id = if let Some(id) = &disk_cfg.id { id.clone() } else { let id = self.next_device_name(DISK_DEVICE_NAME_PREFIX)?; disk_cfg.id = Some(id.clone()); id }; info!("Creating virtio-block device: {:?}", disk_cfg); let snapshot = snapshot_from_id(self.snapshot.as_ref(), id.as_str()); let (virtio_device, migratable_device) = if disk_cfg.vhost_user { let socket = disk_cfg.vhost_socket.as_ref().unwrap().clone(); let vu_cfg = VhostUserConfig { socket, num_queues: disk_cfg.num_queues, queue_size: disk_cfg.queue_size, }; let vhost_user_block = Arc::new(Mutex::new( match virtio_devices::vhost_user::Blk::new( id.clone(), vu_cfg, self.seccomp_action.clone(), self.exit_evt .try_clone() .map_err(DeviceManagerError::EventFd)?, self.force_iommu, snapshot .map(|s| s.to_versioned_state()) .transpose() .map_err(DeviceManagerError::RestoreGetState)?, ) { Ok(vub_device) => vub_device, Err(e) => { return Err(DeviceManagerError::CreateVhostUserBlk(e)); } }, )); ( Arc::clone(&vhost_user_block) as Arc>, vhost_user_block as Arc>, ) } else { let mut options = OpenOptions::new(); options.read(true); options.write(!disk_cfg.readonly); if disk_cfg.direct { options.custom_flags(libc::O_DIRECT); } // Open block device path let mut file: File = options .open( disk_cfg .path .as_ref() .ok_or(DeviceManagerError::NoDiskPath)? .clone(), ) .map_err(DeviceManagerError::Disk)?; let image_type = detect_image_type(&mut file).map_err(DeviceManagerError::DetectImageType)?; let image = match image_type { ImageType::FixedVhd => { // Use asynchronous backend relying on io_uring if the // syscalls are supported. if cfg!(feature = "io_uring") && !disk_cfg.disable_io_uring && self.io_uring_is_supported() { info!("Using asynchronous fixed VHD disk file (io_uring)"); #[cfg(not(feature = "io_uring"))] unreachable!("Checked in if statement above"); #[cfg(feature = "io_uring")] { Box::new( FixedVhdDiskAsync::new(file) .map_err(DeviceManagerError::CreateFixedVhdDiskAsync)?, ) as Box } } else { info!("Using synchronous fixed VHD disk file"); Box::new( FixedVhdDiskSync::new(file) .map_err(DeviceManagerError::CreateFixedVhdDiskSync)?, ) as Box } } ImageType::Raw => { // Use asynchronous backend relying on io_uring if the // syscalls are supported. if cfg!(feature = "io_uring") && !disk_cfg.disable_io_uring && self.io_uring_is_supported() { info!("Using asynchronous RAW disk file (io_uring)"); #[cfg(not(feature = "io_uring"))] unreachable!("Checked in if statement above"); #[cfg(feature = "io_uring")] { Box::new(RawFileDisk::new(file)) as Box } } else { info!("Using synchronous RAW disk file"); Box::new(RawFileDiskSync::new(file)) as Box } } ImageType::Qcow2 => { info!("Using synchronous QCOW disk file"); Box::new( QcowDiskSync::new(file, disk_cfg.direct) .map_err(DeviceManagerError::CreateQcowDiskSync)?, ) as Box } ImageType::Vhdx => { info!("Using synchronous VHDX disk file"); Box::new( VhdxDiskSync::new(file) .map_err(DeviceManagerError::CreateFixedVhdxDiskSync)?, ) as Box } }; let virtio_block = Arc::new(Mutex::new( virtio_devices::Block::new( id.clone(), image, disk_cfg .path .as_ref() .ok_or(DeviceManagerError::NoDiskPath)? .clone(), disk_cfg.readonly, self.force_iommu | disk_cfg.iommu, disk_cfg.num_queues, disk_cfg.queue_size, self.seccomp_action.clone(), disk_cfg.rate_limiter_config, self.exit_evt .try_clone() .map_err(DeviceManagerError::EventFd)?, snapshot .map(|s| s.to_versioned_state()) .transpose() .map_err(DeviceManagerError::RestoreGetState)?, ) .map_err(DeviceManagerError::CreateVirtioBlock)?, )); ( Arc::clone(&virtio_block) as Arc>, virtio_block as Arc>, ) }; // Fill the device tree with a new node. In case of restore, we // know there is nothing to do, so we can simply override the // existing entry. self.device_tree .lock() .unwrap() .insert(id.clone(), device_node!(id, migratable_device)); Ok(MetaVirtioDevice { virtio_device, iommu: disk_cfg.iommu, id, pci_segment: disk_cfg.pci_segment, dma_handler: None, }) } fn make_virtio_block_devices(&mut self) -> DeviceManagerResult> { let mut devices = Vec::new(); let mut block_devices = self.config.lock().unwrap().disks.clone(); if let Some(disk_list_cfg) = &mut block_devices { for disk_cfg in disk_list_cfg.iter_mut() { devices.push(self.make_virtio_block_device(disk_cfg)?); } } self.config.lock().unwrap().disks = block_devices; Ok(devices) } fn make_virtio_net_device( &mut self, net_cfg: &mut NetConfig, ) -> DeviceManagerResult { let id = if let Some(id) = &net_cfg.id { id.clone() } else { let id = self.next_device_name(NET_DEVICE_NAME_PREFIX)?; net_cfg.id = Some(id.clone()); id }; info!("Creating virtio-net device: {:?}", net_cfg); let snapshot = snapshot_from_id(self.snapshot.as_ref(), id.as_str()); let (virtio_device, migratable_device) = if net_cfg.vhost_user { let socket = net_cfg.vhost_socket.as_ref().unwrap().clone(); let vu_cfg = VhostUserConfig { socket, num_queues: net_cfg.num_queues, queue_size: net_cfg.queue_size, }; let server = match net_cfg.vhost_mode { VhostMode::Client => false, VhostMode::Server => true, }; let vhost_user_net = Arc::new(Mutex::new( match virtio_devices::vhost_user::Net::new( id.clone(), net_cfg.mac, net_cfg.mtu, vu_cfg, server, self.seccomp_action.clone(), self.exit_evt .try_clone() .map_err(DeviceManagerError::EventFd)?, self.force_iommu, snapshot .map(|s| s.to_versioned_state()) .transpose() .map_err(DeviceManagerError::RestoreGetState)?, net_cfg.offload_tso, net_cfg.offload_ufo, net_cfg.offload_csum, ) { Ok(vun_device) => vun_device, Err(e) => { return Err(DeviceManagerError::CreateVhostUserNet(e)); } }, )); ( Arc::clone(&vhost_user_net) as Arc>, vhost_user_net as Arc>, ) } else { let state = snapshot .map(|s| s.to_versioned_state()) .transpose() .map_err(DeviceManagerError::RestoreGetState)?; let virtio_net = if let Some(ref tap_if_name) = net_cfg.tap { Arc::new(Mutex::new( virtio_devices::Net::new( id.clone(), Some(tap_if_name), None, None, Some(net_cfg.mac), &mut net_cfg.host_mac, net_cfg.mtu, self.force_iommu | net_cfg.iommu, net_cfg.num_queues, net_cfg.queue_size, self.seccomp_action.clone(), net_cfg.rate_limiter_config, self.exit_evt .try_clone() .map_err(DeviceManagerError::EventFd)?, state, net_cfg.offload_tso, net_cfg.offload_ufo, net_cfg.offload_csum, ) .map_err(DeviceManagerError::CreateVirtioNet)?, )) } else if let Some(fds) = &net_cfg.fds { let net = virtio_devices::Net::from_tap_fds( id.clone(), fds, Some(net_cfg.mac), net_cfg.mtu, self.force_iommu | net_cfg.iommu, net_cfg.queue_size, self.seccomp_action.clone(), net_cfg.rate_limiter_config, self.exit_evt .try_clone() .map_err(DeviceManagerError::EventFd)?, state, net_cfg.offload_tso, net_cfg.offload_ufo, net_cfg.offload_csum, ) .map_err(DeviceManagerError::CreateVirtioNet)?; // SAFETY: 'fds' are valid because TAP devices are created successfully unsafe { self.config.lock().unwrap().add_preserved_fds(fds.clone()); } Arc::new(Mutex::new(net)) } else { Arc::new(Mutex::new( virtio_devices::Net::new( id.clone(), None, Some(net_cfg.ip), Some(net_cfg.mask), Some(net_cfg.mac), &mut net_cfg.host_mac, net_cfg.mtu, self.force_iommu | net_cfg.iommu, net_cfg.num_queues, net_cfg.queue_size, self.seccomp_action.clone(), net_cfg.rate_limiter_config, self.exit_evt .try_clone() .map_err(DeviceManagerError::EventFd)?, state, net_cfg.offload_tso, net_cfg.offload_ufo, net_cfg.offload_csum, ) .map_err(DeviceManagerError::CreateVirtioNet)?, )) }; ( Arc::clone(&virtio_net) as Arc>, virtio_net as Arc>, ) }; // Fill the device tree with a new node. In case of restore, we // know there is nothing to do, so we can simply override the // existing entry. self.device_tree .lock() .unwrap() .insert(id.clone(), device_node!(id, migratable_device)); Ok(MetaVirtioDevice { virtio_device, iommu: net_cfg.iommu, id, pci_segment: net_cfg.pci_segment, dma_handler: None, }) } /// Add virto-net and vhost-user-net devices fn make_virtio_net_devices(&mut self) -> DeviceManagerResult> { let mut devices = Vec::new(); let mut net_devices = self.config.lock().unwrap().net.clone(); if let Some(net_list_cfg) = &mut net_devices { for net_cfg in net_list_cfg.iter_mut() { devices.push(self.make_virtio_net_device(net_cfg)?); } } self.config.lock().unwrap().net = net_devices; Ok(devices) } fn make_virtio_rng_devices(&mut self) -> DeviceManagerResult> { let mut devices = Vec::new(); // Add virtio-rng if required let rng_config = self.config.lock().unwrap().rng.clone(); if let Some(rng_path) = rng_config.src.to_str() { info!("Creating virtio-rng device: {:?}", rng_config); let id = String::from(RNG_DEVICE_NAME); let virtio_rng_device = Arc::new(Mutex::new( virtio_devices::Rng::new( id.clone(), rng_path, self.force_iommu | rng_config.iommu, self.seccomp_action.clone(), self.exit_evt .try_clone() .map_err(DeviceManagerError::EventFd)?, versioned_state_from_id(self.snapshot.as_ref(), id.as_str()) .map_err(DeviceManagerError::RestoreGetState)?, ) .map_err(DeviceManagerError::CreateVirtioRng)?, )); devices.push(MetaVirtioDevice { virtio_device: Arc::clone(&virtio_rng_device) as Arc>, iommu: rng_config.iommu, id: id.clone(), pci_segment: 0, dma_handler: None, }); // Fill the device tree with a new node. In case of restore, we // know there is nothing to do, so we can simply override the // existing entry. self.device_tree .lock() .unwrap() .insert(id.clone(), device_node!(id, virtio_rng_device)); } Ok(devices) } fn make_virtio_fs_device( &mut self, fs_cfg: &mut FsConfig, ) -> DeviceManagerResult { let id = if let Some(id) = &fs_cfg.id { id.clone() } else { let id = self.next_device_name(FS_DEVICE_NAME_PREFIX)?; fs_cfg.id = Some(id.clone()); id }; info!("Creating virtio-fs device: {:?}", fs_cfg); let mut node = device_node!(id); if let Some(fs_socket) = fs_cfg.socket.to_str() { let virtio_fs_device = Arc::new(Mutex::new( virtio_devices::vhost_user::Fs::new( id.clone(), fs_socket, &fs_cfg.tag, fs_cfg.num_queues, fs_cfg.queue_size, None, self.seccomp_action.clone(), self.exit_evt .try_clone() .map_err(DeviceManagerError::EventFd)?, self.force_iommu, versioned_state_from_id(self.snapshot.as_ref(), id.as_str()) .map_err(DeviceManagerError::RestoreGetState)?, ) .map_err(DeviceManagerError::CreateVirtioFs)?, )); // Update the device tree with the migratable device. node.migratable = Some(Arc::clone(&virtio_fs_device) as Arc>); self.device_tree.lock().unwrap().insert(id.clone(), node); Ok(MetaVirtioDevice { virtio_device: Arc::clone(&virtio_fs_device) as Arc>, iommu: false, id, pci_segment: fs_cfg.pci_segment, dma_handler: None, }) } else { Err(DeviceManagerError::NoVirtioFsSock) } } fn make_virtio_fs_devices(&mut self) -> DeviceManagerResult> { let mut devices = Vec::new(); let mut fs_devices = self.config.lock().unwrap().fs.clone(); if let Some(fs_list_cfg) = &mut fs_devices { for fs_cfg in fs_list_cfg.iter_mut() { devices.push(self.make_virtio_fs_device(fs_cfg)?); } } self.config.lock().unwrap().fs = fs_devices; Ok(devices) } fn make_virtio_pmem_device( &mut self, pmem_cfg: &mut PmemConfig, ) -> DeviceManagerResult { let id = if let Some(id) = &pmem_cfg.id { id.clone() } else { let id = self.next_device_name(PMEM_DEVICE_NAME_PREFIX)?; pmem_cfg.id = Some(id.clone()); id }; info!("Creating virtio-pmem device: {:?}", pmem_cfg); let mut node = device_node!(id); // Look for the id in the device tree. If it can be found, that means // the device is being restored, otherwise it's created from scratch. let region_range = if let Some(node) = self.device_tree.lock().unwrap().get(&id) { info!("Restoring virtio-pmem {} resources", id); let mut region_range: Option<(u64, u64)> = None; for resource in node.resources.iter() { match resource { Resource::MmioAddressRange { base, size } => { if region_range.is_some() { return Err(DeviceManagerError::ResourceAlreadyExists); } region_range = Some((*base, *size)); } _ => { error!("Unexpected resource {:?} for {}", resource, id); } } } if region_range.is_none() { return Err(DeviceManagerError::MissingVirtioPmemResources); } region_range } else { None }; let (custom_flags, set_len) = if pmem_cfg.file.is_dir() { if pmem_cfg.size.is_none() { return Err(DeviceManagerError::PmemWithDirectorySizeMissing); } (O_TMPFILE, true) } else { (0, false) }; let mut file = OpenOptions::new() .read(true) .write(!pmem_cfg.discard_writes) .custom_flags(custom_flags) .open(&pmem_cfg.file) .map_err(DeviceManagerError::PmemFileOpen)?; let size = if let Some(size) = pmem_cfg.size { if set_len { file.set_len(size) .map_err(DeviceManagerError::PmemFileSetLen)?; } size } else { file.seek(SeekFrom::End(0)) .map_err(DeviceManagerError::PmemFileSetLen)? }; if size % 0x20_0000 != 0 { return Err(DeviceManagerError::PmemSizeNotAligned); } let (region_base, region_size) = if let Some((base, size)) = region_range { // The memory needs to be 2MiB aligned in order to support // hugepages. self.pci_segments[pmem_cfg.pci_segment as usize] .allocator .lock() .unwrap() .allocate( Some(GuestAddress(base)), size as GuestUsize, Some(0x0020_0000), ) .ok_or(DeviceManagerError::PmemRangeAllocation)?; (base, size) } else { // The memory needs to be 2MiB aligned in order to support // hugepages. let base = self.pci_segments[pmem_cfg.pci_segment as usize] .allocator .lock() .unwrap() .allocate(None, size as GuestUsize, Some(0x0020_0000)) .ok_or(DeviceManagerError::PmemRangeAllocation)?; (base.raw_value(), size) }; let cloned_file = file.try_clone().map_err(DeviceManagerError::CloneFile)?; let mmap_region = MmapRegion::build( Some(FileOffset::new(cloned_file, 0)), region_size as usize, PROT_READ | PROT_WRITE, MAP_NORESERVE | if pmem_cfg.discard_writes { MAP_PRIVATE } else { MAP_SHARED }, ) .map_err(DeviceManagerError::NewMmapRegion)?; let host_addr: u64 = mmap_region.as_ptr() as u64; let mem_slot = self .memory_manager .lock() .unwrap() .create_userspace_mapping(region_base, region_size, host_addr, false, false, false) .map_err(DeviceManagerError::MemoryManager)?; let mapping = virtio_devices::UserspaceMapping { host_addr, mem_slot, addr: GuestAddress(region_base), len: region_size, mergeable: false, }; let virtio_pmem_device = Arc::new(Mutex::new( virtio_devices::Pmem::new( id.clone(), file, GuestAddress(region_base), mapping, mmap_region, self.force_iommu | pmem_cfg.iommu, self.seccomp_action.clone(), self.exit_evt .try_clone() .map_err(DeviceManagerError::EventFd)?, versioned_state_from_id(self.snapshot.as_ref(), id.as_str()) .map_err(DeviceManagerError::RestoreGetState)?, ) .map_err(DeviceManagerError::CreateVirtioPmem)?, )); // Update the device tree with correct resource information and with // the migratable device. node.resources.push(Resource::MmioAddressRange { base: region_base, size: region_size, }); node.migratable = Some(Arc::clone(&virtio_pmem_device) as Arc>); self.device_tree.lock().unwrap().insert(id.clone(), node); Ok(MetaVirtioDevice { virtio_device: Arc::clone(&virtio_pmem_device) as Arc>, iommu: pmem_cfg.iommu, id, pci_segment: pmem_cfg.pci_segment, dma_handler: None, }) } fn make_virtio_pmem_devices(&mut self) -> DeviceManagerResult> { let mut devices = Vec::new(); // Add virtio-pmem if required let mut pmem_devices = self.config.lock().unwrap().pmem.clone(); if let Some(pmem_list_cfg) = &mut pmem_devices { for pmem_cfg in pmem_list_cfg.iter_mut() { devices.push(self.make_virtio_pmem_device(pmem_cfg)?); } } self.config.lock().unwrap().pmem = pmem_devices; Ok(devices) } fn make_virtio_vsock_device( &mut self, vsock_cfg: &mut VsockConfig, ) -> DeviceManagerResult { let id = if let Some(id) = &vsock_cfg.id { id.clone() } else { let id = self.next_device_name(VSOCK_DEVICE_NAME_PREFIX)?; vsock_cfg.id = Some(id.clone()); id }; info!("Creating virtio-vsock device: {:?}", vsock_cfg); let socket_path = vsock_cfg .socket .to_str() .ok_or(DeviceManagerError::CreateVsockConvertPath)?; let backend = virtio_devices::vsock::VsockUnixBackend::new(vsock_cfg.cid, socket_path.to_string()) .map_err(DeviceManagerError::CreateVsockBackend)?; let vsock_device = Arc::new(Mutex::new( virtio_devices::Vsock::new( id.clone(), vsock_cfg.cid, vsock_cfg.socket.clone(), backend, self.force_iommu | vsock_cfg.iommu, self.seccomp_action.clone(), self.exit_evt .try_clone() .map_err(DeviceManagerError::EventFd)?, versioned_state_from_id(self.snapshot.as_ref(), id.as_str()) .map_err(DeviceManagerError::RestoreGetState)?, ) .map_err(DeviceManagerError::CreateVirtioVsock)?, )); // Fill the device tree with a new node. In case of restore, we // know there is nothing to do, so we can simply override the // existing entry. self.device_tree .lock() .unwrap() .insert(id.clone(), device_node!(id, vsock_device)); Ok(MetaVirtioDevice { virtio_device: Arc::clone(&vsock_device) as Arc>, iommu: vsock_cfg.iommu, id, pci_segment: vsock_cfg.pci_segment, dma_handler: None, }) } fn make_virtio_vsock_devices(&mut self) -> DeviceManagerResult> { let mut devices = Vec::new(); let mut vsock = self.config.lock().unwrap().vsock.clone(); if let Some(ref mut vsock_cfg) = &mut vsock { devices.push(self.make_virtio_vsock_device(vsock_cfg)?); } self.config.lock().unwrap().vsock = vsock; Ok(devices) } fn make_virtio_mem_devices(&mut self) -> DeviceManagerResult> { let mut devices = Vec::new(); let mm = self.memory_manager.clone(); let mut mm = mm.lock().unwrap(); for (memory_zone_id, memory_zone) in mm.memory_zones_mut().iter_mut() { if let Some(virtio_mem_zone) = memory_zone.virtio_mem_zone_mut() { info!("Creating virtio-mem device: id = {}", memory_zone_id); let node_id = numa_node_id_from_memory_zone_id(&self.numa_nodes, memory_zone_id) .map(|i| i as u16); let virtio_mem_device = Arc::new(Mutex::new( virtio_devices::Mem::new( memory_zone_id.clone(), virtio_mem_zone.region(), self.seccomp_action.clone(), node_id, virtio_mem_zone.hotplugged_size(), virtio_mem_zone.hugepages(), self.exit_evt .try_clone() .map_err(DeviceManagerError::EventFd)?, virtio_mem_zone.blocks_state().clone(), versioned_state_from_id(self.snapshot.as_ref(), memory_zone_id.as_str()) .map_err(DeviceManagerError::RestoreGetState)?, ) .map_err(DeviceManagerError::CreateVirtioMem)?, )); // Update the virtio-mem zone so that it has a handle onto the // virtio-mem device, which will be used for triggering a resize // if needed. virtio_mem_zone.set_virtio_device(Arc::clone(&virtio_mem_device)); self.virtio_mem_devices.push(Arc::clone(&virtio_mem_device)); devices.push(MetaVirtioDevice { virtio_device: Arc::clone(&virtio_mem_device) as Arc>, iommu: false, id: memory_zone_id.clone(), pci_segment: 0, dma_handler: None, }); // Fill the device tree with a new node. In case of restore, we // know there is nothing to do, so we can simply override the // existing entry. self.device_tree.lock().unwrap().insert( memory_zone_id.clone(), device_node!(memory_zone_id, virtio_mem_device), ); } } Ok(devices) } fn make_virtio_balloon_devices(&mut self) -> DeviceManagerResult> { let mut devices = Vec::new(); if let Some(balloon_config) = &self.config.lock().unwrap().balloon { let id = String::from(BALLOON_DEVICE_NAME); info!("Creating virtio-balloon device: id = {}", id); let virtio_balloon_device = Arc::new(Mutex::new( virtio_devices::Balloon::new( id.clone(), balloon_config.size, balloon_config.deflate_on_oom, balloon_config.free_page_reporting, self.seccomp_action.clone(), self.exit_evt .try_clone() .map_err(DeviceManagerError::EventFd)?, versioned_state_from_id(self.snapshot.as_ref(), id.as_str()) .map_err(DeviceManagerError::RestoreGetState)?, ) .map_err(DeviceManagerError::CreateVirtioBalloon)?, )); self.balloon = Some(virtio_balloon_device.clone()); devices.push(MetaVirtioDevice { virtio_device: Arc::clone(&virtio_balloon_device) as Arc>, iommu: false, id: id.clone(), pci_segment: 0, dma_handler: None, }); self.device_tree .lock() .unwrap() .insert(id.clone(), device_node!(id, virtio_balloon_device)); } Ok(devices) } fn make_virtio_watchdog_devices(&mut self) -> DeviceManagerResult> { let mut devices = Vec::new(); if !self.config.lock().unwrap().watchdog { return Ok(devices); } let id = String::from(WATCHDOG_DEVICE_NAME); info!("Creating virtio-watchdog device: id = {}", id); let virtio_watchdog_device = Arc::new(Mutex::new( virtio_devices::Watchdog::new( id.clone(), self.reset_evt.try_clone().unwrap(), self.seccomp_action.clone(), self.exit_evt .try_clone() .map_err(DeviceManagerError::EventFd)?, versioned_state_from_id(self.snapshot.as_ref(), id.as_str()) .map_err(DeviceManagerError::RestoreGetState)?, ) .map_err(DeviceManagerError::CreateVirtioWatchdog)?, )); devices.push(MetaVirtioDevice { virtio_device: Arc::clone(&virtio_watchdog_device) as Arc>, iommu: false, id: id.clone(), pci_segment: 0, dma_handler: None, }); self.device_tree .lock() .unwrap() .insert(id.clone(), device_node!(id, virtio_watchdog_device)); Ok(devices) } fn make_vdpa_device( &mut self, vdpa_cfg: &mut VdpaConfig, ) -> DeviceManagerResult { let id = if let Some(id) = &vdpa_cfg.id { id.clone() } else { let id = self.next_device_name(VDPA_DEVICE_NAME_PREFIX)?; vdpa_cfg.id = Some(id.clone()); id }; info!("Creating vDPA device: {:?}", vdpa_cfg); let device_path = vdpa_cfg .path .to_str() .ok_or(DeviceManagerError::CreateVdpaConvertPath)?; let vdpa_device = Arc::new(Mutex::new( virtio_devices::Vdpa::new( id.clone(), device_path, self.memory_manager.lock().unwrap().guest_memory(), vdpa_cfg.num_queues as u16, versioned_state_from_id(self.snapshot.as_ref(), id.as_str()) .map_err(DeviceManagerError::RestoreGetState)?, ) .map_err(DeviceManagerError::CreateVdpa)?, )); // Create the DMA handler that is required by the vDPA device let vdpa_mapping = Arc::new(VdpaDmaMapping::new( Arc::clone(&vdpa_device), Arc::new(self.memory_manager.lock().unwrap().guest_memory()), )); self.device_tree .lock() .unwrap() .insert(id.clone(), device_node!(id, vdpa_device)); Ok(MetaVirtioDevice { virtio_device: vdpa_device as Arc>, iommu: vdpa_cfg.iommu, id, pci_segment: vdpa_cfg.pci_segment, dma_handler: Some(vdpa_mapping), }) } fn make_vdpa_devices(&mut self) -> DeviceManagerResult> { let mut devices = Vec::new(); // Add vdpa if required let mut vdpa_devices = self.config.lock().unwrap().vdpa.clone(); if let Some(vdpa_list_cfg) = &mut vdpa_devices { for vdpa_cfg in vdpa_list_cfg.iter_mut() { devices.push(self.make_vdpa_device(vdpa_cfg)?); } } self.config.lock().unwrap().vdpa = vdpa_devices; Ok(devices) } fn next_device_name(&mut self, prefix: &str) -> DeviceManagerResult { let start_id = self.device_id_cnt; loop { // Generate the temporary name. let name = format!("{}{}", prefix, self.device_id_cnt); // Increment the counter. self.device_id_cnt += Wrapping(1); // Check if the name is already in use. if !self.boot_id_list.contains(&name) && !self.device_tree.lock().unwrap().contains_key(&name) { return Ok(name); } if self.device_id_cnt == start_id { // We went through a full loop and there's nothing else we can // do. break; } } Err(DeviceManagerError::NoAvailableDeviceName) } fn add_passthrough_device( &mut self, device_cfg: &mut DeviceConfig, ) -> DeviceManagerResult<(PciBdf, String)> { // If the passthrough device has not been created yet, it is created // here and stored in the DeviceManager structure for future needs. if self.passthrough_device.is_none() { self.passthrough_device = Some( self.address_manager .vm .create_passthrough_device() .map_err(|e| DeviceManagerError::CreatePassthroughDevice(e.into()))?, ); } self.add_vfio_device(device_cfg) } fn create_vfio_container(&self) -> DeviceManagerResult> { let passthrough_device = self .passthrough_device .as_ref() .ok_or(DeviceManagerError::NoDevicePassthroughSupport)?; let dup = passthrough_device .try_clone() .map_err(DeviceManagerError::VfioCreate)?; Ok(Arc::new( VfioContainer::new(Some(Arc::new(dup))).map_err(DeviceManagerError::VfioCreate)?, )) } fn add_vfio_device( &mut self, device_cfg: &mut DeviceConfig, ) -> DeviceManagerResult<(PciBdf, String)> { let vfio_name = if let Some(id) = &device_cfg.id { id.clone() } else { let id = self.next_device_name(VFIO_DEVICE_NAME_PREFIX)?; device_cfg.id = Some(id.clone()); id }; let (pci_segment_id, pci_device_bdf, resources) = self.pci_resources(&vfio_name, device_cfg.pci_segment)?; let mut needs_dma_mapping = false; // Here we create a new VFIO container for two reasons. Either this is // the first VFIO device, meaning we need a new VFIO container, which // will be shared with other VFIO devices. Or the new VFIO device is // attached to a vIOMMU, meaning we must create a dedicated VFIO // container. In the vIOMMU use case, we can't let all devices under // the same VFIO container since we couldn't map/unmap memory for each // device. That's simply because the map/unmap operations happen at the // VFIO container level. let vfio_container = if device_cfg.iommu { let vfio_container = self.create_vfio_container()?; let vfio_mapping = Arc::new(VfioDmaMapping::new( Arc::clone(&vfio_container), Arc::new(self.memory_manager.lock().unwrap().guest_memory()), )); if let Some(iommu) = &self.iommu_device { iommu .lock() .unwrap() .add_external_mapping(pci_device_bdf.into(), vfio_mapping); } else { return Err(DeviceManagerError::MissingVirtualIommu); } vfio_container } else if let Some(vfio_container) = &self.vfio_container { Arc::clone(vfio_container) } else { let vfio_container = self.create_vfio_container()?; needs_dma_mapping = true; self.vfio_container = Some(Arc::clone(&vfio_container)); vfio_container }; let vfio_device = VfioDevice::new(&device_cfg.path, Arc::clone(&vfio_container)) .map_err(DeviceManagerError::VfioCreate)?; if needs_dma_mapping { // Register DMA mapping in IOMMU. // Do not register virtio-mem regions, as they are handled directly by // virtio-mem device itself. for (_, zone) in self.memory_manager.lock().unwrap().memory_zones().iter() { for region in zone.regions() { vfio_container .vfio_dma_map( region.start_addr().raw_value(), region.len(), region.as_ptr() as u64, ) .map_err(DeviceManagerError::VfioDmaMap)?; } } let vfio_mapping = Arc::new(VfioDmaMapping::new( Arc::clone(&vfio_container), Arc::new(self.memory_manager.lock().unwrap().guest_memory()), )); for virtio_mem_device in self.virtio_mem_devices.iter() { virtio_mem_device .lock() .unwrap() .add_dma_mapping_handler( VirtioMemMappingSource::Container, vfio_mapping.clone(), ) .map_err(DeviceManagerError::AddDmaMappingHandlerVirtioMem)?; } } let legacy_interrupt_group = if let Some(legacy_interrupt_manager) = &self.legacy_interrupt_manager { Some( legacy_interrupt_manager .create_group(LegacyIrqGroupConfig { irq: self.pci_segments[pci_segment_id as usize].pci_irq_slots [pci_device_bdf.device() as usize] as InterruptIndex, }) .map_err(DeviceManagerError::CreateInterruptGroup)?, ) } else { None }; let memory_manager = self.memory_manager.clone(); let vfio_pci_device = VfioPciDevice::new( vfio_name.clone(), &self.address_manager.vm, vfio_device, vfio_container, self.msi_interrupt_manager.clone(), legacy_interrupt_group, device_cfg.iommu, pci_device_bdf, Arc::new(move || memory_manager.lock().unwrap().allocate_memory_slot()), vm_migration::snapshot_from_id(self.snapshot.as_ref(), vfio_name.as_str()), ) .map_err(DeviceManagerError::VfioPciCreate)?; let vfio_pci_device = Arc::new(Mutex::new(vfio_pci_device)); let new_resources = self.add_pci_device( vfio_pci_device.clone(), vfio_pci_device.clone(), pci_segment_id, pci_device_bdf, resources, )?; vfio_pci_device .lock() .unwrap() .map_mmio_regions() .map_err(DeviceManagerError::VfioMapRegion)?; let mut node = device_node!(vfio_name, vfio_pci_device); // Update the device tree with correct resource information. node.resources = new_resources; node.pci_bdf = Some(pci_device_bdf); node.pci_device_handle = Some(PciDeviceHandle::Vfio(vfio_pci_device)); self.device_tree .lock() .unwrap() .insert(vfio_name.clone(), node); Ok((pci_device_bdf, vfio_name)) } fn add_pci_device( &mut self, bus_device: Arc>, pci_device: Arc>, segment_id: u16, bdf: PciBdf, resources: Option>, ) -> DeviceManagerResult> { let bars = pci_device .lock() .unwrap() .allocate_bars( &self.address_manager.allocator, &mut self.pci_segments[segment_id as usize] .allocator .lock() .unwrap(), resources, ) .map_err(DeviceManagerError::AllocateBars)?; let mut pci_bus = self.pci_segments[segment_id as usize] .pci_bus .lock() .unwrap(); pci_bus .add_device(bdf.device() as u32, pci_device) .map_err(DeviceManagerError::AddPciDevice)?; self.bus_devices.push(Arc::clone(&bus_device)); pci_bus .register_mapping( bus_device, #[cfg(target_arch = "x86_64")] self.address_manager.io_bus.as_ref(), self.address_manager.mmio_bus.as_ref(), bars.clone(), ) .map_err(DeviceManagerError::AddPciDevice)?; let mut new_resources = Vec::new(); for bar in bars { new_resources.push(Resource::PciBar { index: bar.idx(), base: bar.addr(), size: bar.size(), type_: bar.region_type().into(), prefetchable: bar.prefetchable().into(), }); } Ok(new_resources) } fn add_vfio_devices(&mut self) -> DeviceManagerResult> { let mut iommu_attached_device_ids = Vec::new(); let mut devices = self.config.lock().unwrap().devices.clone(); if let Some(device_list_cfg) = &mut devices { for device_cfg in device_list_cfg.iter_mut() { let (device_id, _) = self.add_passthrough_device(device_cfg)?; if device_cfg.iommu && self.iommu_device.is_some() { iommu_attached_device_ids.push(device_id); } } } // Update the list of devices self.config.lock().unwrap().devices = devices; Ok(iommu_attached_device_ids) } fn add_vfio_user_device( &mut self, device_cfg: &mut UserDeviceConfig, ) -> DeviceManagerResult<(PciBdf, String)> { let vfio_user_name = if let Some(id) = &device_cfg.id { id.clone() } else { let id = self.next_device_name(VFIO_USER_DEVICE_NAME_PREFIX)?; device_cfg.id = Some(id.clone()); id }; let (pci_segment_id, pci_device_bdf, resources) = self.pci_resources(&vfio_user_name, device_cfg.pci_segment)?; let legacy_interrupt_group = if let Some(legacy_interrupt_manager) = &self.legacy_interrupt_manager { Some( legacy_interrupt_manager .create_group(LegacyIrqGroupConfig { irq: self.pci_segments[pci_segment_id as usize].pci_irq_slots [pci_device_bdf.device() as usize] as InterruptIndex, }) .map_err(DeviceManagerError::CreateInterruptGroup)?, ) } else { None }; let client = Arc::new(Mutex::new( vfio_user::Client::new(&device_cfg.socket) .map_err(DeviceManagerError::VfioUserCreateClient)?, )); let memory_manager = self.memory_manager.clone(); let mut vfio_user_pci_device = VfioUserPciDevice::new( vfio_user_name.clone(), &self.address_manager.vm, client.clone(), self.msi_interrupt_manager.clone(), legacy_interrupt_group, pci_device_bdf, Arc::new(move || memory_manager.lock().unwrap().allocate_memory_slot()), vm_migration::snapshot_from_id(self.snapshot.as_ref(), vfio_user_name.as_str()), ) .map_err(DeviceManagerError::VfioUserCreate)?; let memory = self.memory_manager.lock().unwrap().guest_memory(); let vfio_user_mapping = Arc::new(VfioUserDmaMapping::new(client, Arc::new(memory))); for virtio_mem_device in self.virtio_mem_devices.iter() { virtio_mem_device .lock() .unwrap() .add_dma_mapping_handler( VirtioMemMappingSource::Device(pci_device_bdf.into()), vfio_user_mapping.clone(), ) .map_err(DeviceManagerError::AddDmaMappingHandlerVirtioMem)?; } for (_, zone) in self.memory_manager.lock().unwrap().memory_zones().iter() { for region in zone.regions() { vfio_user_pci_device .dma_map(region) .map_err(DeviceManagerError::VfioUserDmaMap)?; } } let vfio_user_pci_device = Arc::new(Mutex::new(vfio_user_pci_device)); let new_resources = self.add_pci_device( vfio_user_pci_device.clone(), vfio_user_pci_device.clone(), pci_segment_id, pci_device_bdf, resources, )?; // Note it is required to call 'add_pci_device()' in advance to have the list of // mmio regions provisioned correctly vfio_user_pci_device .lock() .unwrap() .map_mmio_regions() .map_err(DeviceManagerError::VfioUserMapRegion)?; let mut node = device_node!(vfio_user_name, vfio_user_pci_device); // Update the device tree with correct resource information. node.resources = new_resources; node.pci_bdf = Some(pci_device_bdf); node.pci_device_handle = Some(PciDeviceHandle::VfioUser(vfio_user_pci_device)); self.device_tree .lock() .unwrap() .insert(vfio_user_name.clone(), node); Ok((pci_device_bdf, vfio_user_name)) } fn add_user_devices(&mut self) -> DeviceManagerResult> { let mut user_devices = self.config.lock().unwrap().user_devices.clone(); if let Some(device_list_cfg) = &mut user_devices { for device_cfg in device_list_cfg.iter_mut() { let (_device_id, _id) = self.add_vfio_user_device(device_cfg)?; } } // Update the list of devices self.config.lock().unwrap().user_devices = user_devices; Ok(vec![]) } fn add_virtio_pci_device( &mut self, virtio_device: Arc>, iommu_mapping: &Option>, virtio_device_id: String, pci_segment_id: u16, dma_handler: Option>, ) -> DeviceManagerResult { let id = format!("{VIRTIO_PCI_DEVICE_NAME_PREFIX}-{virtio_device_id}"); // Add the new virtio-pci node to the device tree. let mut node = device_node!(id); node.children = vec![virtio_device_id.clone()]; let (pci_segment_id, pci_device_bdf, resources) = self.pci_resources(&id, pci_segment_id)?; // Update the existing virtio node by setting the parent. if let Some(node) = self.device_tree.lock().unwrap().get_mut(&virtio_device_id) { node.parent = Some(id.clone()); } else { return Err(DeviceManagerError::MissingNode); } // Allows support for one MSI-X vector per queue. It also adds 1 // as we need to take into account the dedicated vector to notify // about a virtio config change. let msix_num = (virtio_device.lock().unwrap().queue_max_sizes().len() + 1) as u16; // Create the AccessPlatform trait from the implementation IommuMapping. // This will provide address translation for any virtio device sitting // behind a vIOMMU. let access_platform: Option> = if let Some(mapping) = iommu_mapping { Some(Arc::new(AccessPlatformMapping::new( pci_device_bdf.into(), mapping.clone(), ))) } else { None }; let memory = self.memory_manager.lock().unwrap().guest_memory(); // Map DMA ranges if a DMA handler is available and if the device is // not attached to a virtual IOMMU. if let Some(dma_handler) = &dma_handler { if iommu_mapping.is_some() { if let Some(iommu) = &self.iommu_device { iommu .lock() .unwrap() .add_external_mapping(pci_device_bdf.into(), dma_handler.clone()); } else { return Err(DeviceManagerError::MissingVirtualIommu); } } else { // Let every virtio-mem device handle the DMA map/unmap through the // DMA handler provided. for virtio_mem_device in self.virtio_mem_devices.iter() { virtio_mem_device .lock() .unwrap() .add_dma_mapping_handler( VirtioMemMappingSource::Device(pci_device_bdf.into()), dma_handler.clone(), ) .map_err(DeviceManagerError::AddDmaMappingHandlerVirtioMem)?; } // Do not register virtio-mem regions, as they are handled directly by // virtio-mem devices. for (_, zone) in self.memory_manager.lock().unwrap().memory_zones().iter() { for region in zone.regions() { let gpa = region.start_addr().0; let size = region.len(); dma_handler .map(gpa, gpa, size) .map_err(DeviceManagerError::VirtioDmaMap)?; } } } } let device_type = virtio_device.lock().unwrap().device_type(); let virtio_pci_device = Arc::new(Mutex::new( VirtioPciDevice::new( id.clone(), memory, virtio_device, msix_num, access_platform, &self.msi_interrupt_manager, pci_device_bdf.into(), self.activate_evt .try_clone() .map_err(DeviceManagerError::EventFd)?, // All device types *except* virtio block devices should be allocated a 64-bit bar // The block devices should be given a 32-bit BAR so that they are easily accessible // to firmware without requiring excessive identity mapping. // The exception being if not on the default PCI segment. pci_segment_id > 0 || device_type != VirtioDeviceType::Block as u32, dma_handler, self.pending_activations.clone(), vm_migration::snapshot_from_id(self.snapshot.as_ref(), id.as_str()), ) .map_err(DeviceManagerError::VirtioDevice)?, )); let new_resources = self.add_pci_device( virtio_pci_device.clone(), virtio_pci_device.clone(), pci_segment_id, pci_device_bdf, resources, )?; let bar_addr = virtio_pci_device.lock().unwrap().config_bar_addr(); for (event, addr) in virtio_pci_device.lock().unwrap().ioeventfds(bar_addr) { let io_addr = IoEventAddress::Mmio(addr); self.address_manager .vm .register_ioevent(event, &io_addr, None) .map_err(|e| DeviceManagerError::RegisterIoevent(e.into()))?; } // Update the device tree with correct resource information. node.resources = new_resources; node.migratable = Some(Arc::clone(&virtio_pci_device) as Arc>); node.pci_bdf = Some(pci_device_bdf); node.pci_device_handle = Some(PciDeviceHandle::Virtio(virtio_pci_device)); self.device_tree.lock().unwrap().insert(id, node); Ok(pci_device_bdf) } fn add_pvpanic_device( &mut self, ) -> DeviceManagerResult>>> { let id = String::from(PVPANIC_DEVICE_NAME); let pci_segment_id = 0x0_u16; info!("Creating pvpanic device {}", id); let (pci_segment_id, pci_device_bdf, resources) = self.pci_resources(&id, pci_segment_id)?; let snapshot = snapshot_from_id(self.snapshot.as_ref(), id.as_str()); let pvpanic_device = devices::PvPanicDevice::new(id.clone(), snapshot) .map_err(DeviceManagerError::PvPanicCreate)?; let pvpanic_device = Arc::new(Mutex::new(pvpanic_device)); let new_resources = self.add_pci_device( pvpanic_device.clone(), pvpanic_device.clone(), pci_segment_id, pci_device_bdf, resources, )?; let mut node = device_node!(id, pvpanic_device); node.resources = new_resources; node.pci_bdf = Some(pci_device_bdf); node.pci_device_handle = None; self.device_tree.lock().unwrap().insert(id, node); Ok(Some(pvpanic_device)) } fn pci_resources( &self, id: &str, pci_segment_id: u16, ) -> DeviceManagerResult<(u16, PciBdf, Option>)> { // Look for the id in the device tree. If it can be found, that means // the device is being restored, otherwise it's created from scratch. Ok( if let Some(node) = self.device_tree.lock().unwrap().get(id) { info!("Restoring virtio-pci {} resources", id); let pci_device_bdf: PciBdf = node .pci_bdf .ok_or(DeviceManagerError::MissingDeviceNodePciBdf)?; let pci_segment_id = pci_device_bdf.segment(); self.pci_segments[pci_segment_id as usize] .pci_bus .lock() .unwrap() .get_device_id(pci_device_bdf.device() as usize) .map_err(DeviceManagerError::GetPciDeviceId)?; (pci_segment_id, pci_device_bdf, Some(node.resources.clone())) } else { let pci_device_bdf = self.pci_segments[pci_segment_id as usize].next_device_bdf()?; (pci_segment_id, pci_device_bdf, None) }, ) } #[cfg(target_arch = "x86_64")] pub fn io_bus(&self) -> &Arc { &self.address_manager.io_bus } pub fn mmio_bus(&self) -> &Arc { &self.address_manager.mmio_bus } pub fn allocator(&self) -> &Arc> { &self.address_manager.allocator } pub fn interrupt_controller(&self) -> Option>> { self.interrupt_controller .as_ref() .map(|ic| ic.clone() as Arc>) } pub(crate) fn pci_segments(&self) -> &Vec { &self.pci_segments } pub fn console(&self) -> &Arc { &self.console } #[cfg(target_arch = "aarch64")] pub fn cmdline_additions(&self) -> &[String] { self.cmdline_additions.as_slice() } pub fn update_memory(&self, new_region: &Arc) -> DeviceManagerResult<()> { for handle in self.virtio_devices.iter() { handle .virtio_device .lock() .unwrap() .add_memory_region(new_region) .map_err(DeviceManagerError::UpdateMemoryForVirtioDevice)?; if let Some(dma_handler) = &handle.dma_handler { if !handle.iommu { let gpa = new_region.start_addr().0; let size = new_region.len(); dma_handler .map(gpa, gpa, size) .map_err(DeviceManagerError::VirtioDmaMap)?; } } } // Take care of updating the memory for VFIO PCI devices. if let Some(vfio_container) = &self.vfio_container { vfio_container .vfio_dma_map( new_region.start_addr().raw_value(), new_region.len(), new_region.as_ptr() as u64, ) .map_err(DeviceManagerError::UpdateMemoryForVfioPciDevice)?; } // Take care of updating the memory for vfio-user devices. { let device_tree = self.device_tree.lock().unwrap(); for pci_device_node in device_tree.pci_devices() { if let PciDeviceHandle::VfioUser(vfio_user_pci_device) = pci_device_node .pci_device_handle .as_ref() .ok_or(DeviceManagerError::MissingPciDevice)? { vfio_user_pci_device .lock() .unwrap() .dma_map(new_region) .map_err(DeviceManagerError::UpdateMemoryForVfioUserPciDevice)?; } } } Ok(()) } pub fn activate_virtio_devices(&self) -> DeviceManagerResult<()> { for mut activator in self.pending_activations.lock().unwrap().drain(..) { activator .activate() .map_err(DeviceManagerError::VirtioActivate)?; } Ok(()) } pub fn notify_hotplug( &self, _notification_type: AcpiNotificationFlags, ) -> DeviceManagerResult<()> { return self .ged_notification_device .as_ref() .unwrap() .lock() .unwrap() .notify(_notification_type) .map_err(DeviceManagerError::HotPlugNotification); } pub fn add_device( &mut self, device_cfg: &mut DeviceConfig, ) -> DeviceManagerResult { self.validate_identifier(&device_cfg.id)?; if device_cfg.iommu && !self.is_iommu_segment(device_cfg.pci_segment) { return Err(DeviceManagerError::InvalidIommuHotplug); } let (bdf, device_name) = self.add_passthrough_device(device_cfg)?; // Update the PCIU bitmap self.pci_segments[device_cfg.pci_segment as usize].pci_devices_up |= 1 << bdf.device(); Ok(PciDeviceInfo { id: device_name, bdf, }) } pub fn add_user_device( &mut self, device_cfg: &mut UserDeviceConfig, ) -> DeviceManagerResult { self.validate_identifier(&device_cfg.id)?; let (bdf, device_name) = self.add_vfio_user_device(device_cfg)?; // Update the PCIU bitmap self.pci_segments[device_cfg.pci_segment as usize].pci_devices_up |= 1 << bdf.device(); Ok(PciDeviceInfo { id: device_name, bdf, }) } pub fn remove_device(&mut self, id: String) -> DeviceManagerResult<()> { // The node can be directly a PCI node in case the 'id' refers to a // VFIO device or a virtio-pci one. // In case the 'id' refers to a virtio device, we must find the PCI // node by looking at the parent. let device_tree = self.device_tree.lock().unwrap(); let node = device_tree .get(&id) .ok_or(DeviceManagerError::UnknownDeviceId(id))?; let pci_device_node = if node.pci_bdf.is_some() && node.pci_device_handle.is_some() { node } else { let parent = node .parent .as_ref() .ok_or(DeviceManagerError::MissingNode)?; device_tree .get(parent) .ok_or(DeviceManagerError::MissingNode)? }; let pci_device_bdf: PciBdf = pci_device_node .pci_bdf .ok_or(DeviceManagerError::MissingDeviceNodePciBdf)?; let pci_segment_id = pci_device_bdf.segment(); let pci_device_handle = pci_device_node .pci_device_handle .as_ref() .ok_or(DeviceManagerError::MissingPciDevice)?; #[allow(irrefutable_let_patterns)] if let PciDeviceHandle::Virtio(virtio_pci_device) = pci_device_handle { let device_type = VirtioDeviceType::from( virtio_pci_device .lock() .unwrap() .virtio_device() .lock() .unwrap() .device_type(), ); match device_type { VirtioDeviceType::Net | VirtioDeviceType::Block | VirtioDeviceType::Pmem | VirtioDeviceType::Fs | VirtioDeviceType::Vsock => {} _ => return Err(DeviceManagerError::RemovalNotAllowed(device_type)), } } // Update the PCID bitmap self.pci_segments[pci_segment_id as usize].pci_devices_down |= 1 << pci_device_bdf.device(); Ok(()) } pub fn eject_device(&mut self, pci_segment_id: u16, device_id: u8) -> DeviceManagerResult<()> { info!( "Ejecting device_id = {} on segment_id={}", device_id, pci_segment_id ); // Convert the device ID into the corresponding b/d/f. let pci_device_bdf = PciBdf::new(pci_segment_id, 0, device_id, 0); // Give the PCI device ID back to the PCI bus. self.pci_segments[pci_segment_id as usize] .pci_bus .lock() .unwrap() .put_device_id(device_id as usize) .map_err(DeviceManagerError::PutPciDeviceId)?; // Remove the device from the device tree along with its children. let mut device_tree = self.device_tree.lock().unwrap(); let pci_device_node = device_tree .remove_node_by_pci_bdf(pci_device_bdf) .ok_or(DeviceManagerError::MissingPciDevice)?; // For VFIO and vfio-user the PCI device id is the id. // For virtio we overwrite it later as we want the id of the // underlying device. let mut id = pci_device_node.id; let pci_device_handle = pci_device_node .pci_device_handle .ok_or(DeviceManagerError::MissingPciDevice)?; if matches!(pci_device_handle, PciDeviceHandle::Virtio(_)) { // The virtio-pci device has a single child if !pci_device_node.children.is_empty() { assert_eq!(pci_device_node.children.len(), 1); let child_id = &pci_device_node.children[0]; id = child_id.clone(); } } for child in pci_device_node.children.iter() { device_tree.remove(child); } let mut iommu_attached = false; if let Some((_, iommu_attached_devices)) = &self.iommu_attached_devices { if iommu_attached_devices.contains(&pci_device_bdf) { iommu_attached = true; } } let (pci_device, bus_device, virtio_device, remove_dma_handler) = match pci_device_handle { // No need to remove any virtio-mem mapping here as the container outlives all devices PciDeviceHandle::Vfio(vfio_pci_device) => ( Arc::clone(&vfio_pci_device) as Arc>, Arc::clone(&vfio_pci_device) as Arc>, None as Option>>, false, ), PciDeviceHandle::Virtio(virtio_pci_device) => { let dev = virtio_pci_device.lock().unwrap(); let bar_addr = dev.config_bar_addr(); for (event, addr) in dev.ioeventfds(bar_addr) { let io_addr = IoEventAddress::Mmio(addr); self.address_manager .vm .unregister_ioevent(event, &io_addr) .map_err(|e| DeviceManagerError::UnRegisterIoevent(e.into()))?; } if let Some(dma_handler) = dev.dma_handler() { if !iommu_attached { for (_, zone) in self.memory_manager.lock().unwrap().memory_zones().iter() { for region in zone.regions() { let iova = region.start_addr().0; let size = region.len(); dma_handler .unmap(iova, size) .map_err(DeviceManagerError::VirtioDmaUnmap)?; } } } } ( Arc::clone(&virtio_pci_device) as Arc>, Arc::clone(&virtio_pci_device) as Arc>, Some(dev.virtio_device()), dev.dma_handler().is_some() && !iommu_attached, ) } PciDeviceHandle::VfioUser(vfio_user_pci_device) => { let mut dev = vfio_user_pci_device.lock().unwrap(); for (_, zone) in self.memory_manager.lock().unwrap().memory_zones().iter() { for region in zone.regions() { dev.dma_unmap(region) .map_err(DeviceManagerError::VfioUserDmaUnmap)?; } } ( Arc::clone(&vfio_user_pci_device) as Arc>, Arc::clone(&vfio_user_pci_device) as Arc>, None as Option>>, true, ) } }; if remove_dma_handler { for virtio_mem_device in self.virtio_mem_devices.iter() { virtio_mem_device .lock() .unwrap() .remove_dma_mapping_handler(VirtioMemMappingSource::Device( pci_device_bdf.into(), )) .map_err(DeviceManagerError::RemoveDmaMappingHandlerVirtioMem)?; } } // Free the allocated BARs pci_device .lock() .unwrap() .free_bars( &mut self.address_manager.allocator.lock().unwrap(), &mut self.pci_segments[pci_segment_id as usize] .allocator .lock() .unwrap(), ) .map_err(DeviceManagerError::FreePciBars)?; // Remove the device from the PCI bus self.pci_segments[pci_segment_id as usize] .pci_bus .lock() .unwrap() .remove_by_device(&pci_device) .map_err(DeviceManagerError::RemoveDeviceFromPciBus)?; #[cfg(target_arch = "x86_64")] // Remove the device from the IO bus self.io_bus() .remove_by_device(&bus_device) .map_err(DeviceManagerError::RemoveDeviceFromIoBus)?; // Remove the device from the MMIO bus self.mmio_bus() .remove_by_device(&bus_device) .map_err(DeviceManagerError::RemoveDeviceFromMmioBus)?; // Remove the device from the list of BusDevice held by the // DeviceManager. self.bus_devices .retain(|dev| !Arc::ptr_eq(dev, &bus_device)); // Shutdown and remove the underlying virtio-device if present if let Some(virtio_device) = virtio_device { for mapping in virtio_device.lock().unwrap().userspace_mappings() { self.memory_manager .lock() .unwrap() .remove_userspace_mapping( mapping.addr.raw_value(), mapping.len, mapping.host_addr, mapping.mergeable, mapping.mem_slot, ) .map_err(DeviceManagerError::MemoryManager)?; } virtio_device.lock().unwrap().shutdown(); self.virtio_devices .retain(|handler| !Arc::ptr_eq(&handler.virtio_device, &virtio_device)); } event!( "vm", "device-removed", "id", &id, "bdf", pci_device_bdf.to_string() ); // At this point, the device has been removed from all the list and // buses where it was stored. At the end of this function, after // any_device, bus_device and pci_device are released, the actual // device will be dropped. Ok(()) } fn hotplug_virtio_pci_device( &mut self, handle: MetaVirtioDevice, ) -> DeviceManagerResult { // Add the virtio device to the device manager list. This is important // as the list is used to notify virtio devices about memory updates // for instance. self.virtio_devices.push(handle.clone()); let mapping: Option> = if handle.iommu { self.iommu_mapping.clone() } else { None }; let bdf = self.add_virtio_pci_device( handle.virtio_device, &mapping, handle.id.clone(), handle.pci_segment, handle.dma_handler, )?; // Update the PCIU bitmap self.pci_segments[handle.pci_segment as usize].pci_devices_up |= 1 << bdf.device(); Ok(PciDeviceInfo { id: handle.id, bdf }) } fn is_iommu_segment(&self, pci_segment_id: u16) -> bool { self.config .lock() .as_ref() .unwrap() .platform .as_ref() .map(|pc| { pc.iommu_segments .as_ref() .map(|v| v.contains(&pci_segment_id)) .unwrap_or_default() }) .unwrap_or_default() } pub fn add_disk(&mut self, disk_cfg: &mut DiskConfig) -> DeviceManagerResult { self.validate_identifier(&disk_cfg.id)?; if disk_cfg.iommu && !self.is_iommu_segment(disk_cfg.pci_segment) { return Err(DeviceManagerError::InvalidIommuHotplug); } let device = self.make_virtio_block_device(disk_cfg)?; self.hotplug_virtio_pci_device(device) } pub fn add_fs(&mut self, fs_cfg: &mut FsConfig) -> DeviceManagerResult { self.validate_identifier(&fs_cfg.id)?; let device = self.make_virtio_fs_device(fs_cfg)?; self.hotplug_virtio_pci_device(device) } pub fn add_pmem(&mut self, pmem_cfg: &mut PmemConfig) -> DeviceManagerResult { self.validate_identifier(&pmem_cfg.id)?; if pmem_cfg.iommu && !self.is_iommu_segment(pmem_cfg.pci_segment) { return Err(DeviceManagerError::InvalidIommuHotplug); } let device = self.make_virtio_pmem_device(pmem_cfg)?; self.hotplug_virtio_pci_device(device) } pub fn add_net(&mut self, net_cfg: &mut NetConfig) -> DeviceManagerResult { self.validate_identifier(&net_cfg.id)?; if net_cfg.iommu && !self.is_iommu_segment(net_cfg.pci_segment) { return Err(DeviceManagerError::InvalidIommuHotplug); } let device = self.make_virtio_net_device(net_cfg)?; self.hotplug_virtio_pci_device(device) } pub fn add_vdpa(&mut self, vdpa_cfg: &mut VdpaConfig) -> DeviceManagerResult { self.validate_identifier(&vdpa_cfg.id)?; if vdpa_cfg.iommu && !self.is_iommu_segment(vdpa_cfg.pci_segment) { return Err(DeviceManagerError::InvalidIommuHotplug); } let device = self.make_vdpa_device(vdpa_cfg)?; self.hotplug_virtio_pci_device(device) } pub fn add_vsock(&mut self, vsock_cfg: &mut VsockConfig) -> DeviceManagerResult { self.validate_identifier(&vsock_cfg.id)?; if vsock_cfg.iommu && !self.is_iommu_segment(vsock_cfg.pci_segment) { return Err(DeviceManagerError::InvalidIommuHotplug); } let device = self.make_virtio_vsock_device(vsock_cfg)?; self.hotplug_virtio_pci_device(device) } pub fn counters(&self) -> HashMap>> { let mut counters = HashMap::new(); for handle in &self.virtio_devices { let virtio_device = handle.virtio_device.lock().unwrap(); if let Some(device_counters) = virtio_device.counters() { counters.insert(handle.id.clone(), device_counters.clone()); } } counters } pub fn resize_balloon(&mut self, size: u64) -> DeviceManagerResult<()> { if let Some(balloon) = &self.balloon { return balloon .lock() .unwrap() .resize(size) .map_err(DeviceManagerError::VirtioBalloonResize); } warn!("No balloon setup: Can't resize the balloon"); Err(DeviceManagerError::MissingVirtioBalloon) } pub fn balloon_size(&self) -> u64 { if let Some(balloon) = &self.balloon { return balloon.lock().unwrap().get_actual(); } 0 } pub fn device_tree(&self) -> Arc> { self.device_tree.clone() } #[cfg(target_arch = "x86_64")] pub fn notify_power_button(&self) -> DeviceManagerResult<()> { self.ged_notification_device .as_ref() .unwrap() .lock() .unwrap() .notify(AcpiNotificationFlags::POWER_BUTTON_CHANGED) .map_err(DeviceManagerError::PowerButtonNotification) } #[cfg(target_arch = "aarch64")] pub fn notify_power_button(&self) -> DeviceManagerResult<()> { // There are two use cases: // 1. Users will use direct kernel boot with device tree. // 2. Users will use ACPI+UEFI boot. // Trigger a GPIO pin 3 event to satisify use case 1. self.gpio_device .as_ref() .unwrap() .lock() .unwrap() .trigger_key(3) .map_err(DeviceManagerError::AArch64PowerButtonNotification)?; // Trigger a GED power button event to satisify use case 2. return self .ged_notification_device .as_ref() .unwrap() .lock() .unwrap() .notify(AcpiNotificationFlags::POWER_BUTTON_CHANGED) .map_err(DeviceManagerError::PowerButtonNotification); } pub fn iommu_attached_devices(&self) -> &Option<(PciBdf, Vec)> { &self.iommu_attached_devices } fn validate_identifier(&self, id: &Option) -> DeviceManagerResult<()> { if let Some(id) = id { if id.starts_with("__") { return Err(DeviceManagerError::InvalidIdentifier(id.clone())); } if self.device_tree.lock().unwrap().contains_key(id) { return Err(DeviceManagerError::IdentifierNotUnique(id.clone())); } } Ok(()) } pub(crate) fn acpi_platform_addresses(&self) -> &AcpiPlatformAddresses { &self.acpi_platform_addresses } } fn numa_node_id_from_memory_zone_id(numa_nodes: &NumaNodes, memory_zone_id: &str) -> Option { for (numa_node_id, numa_node) in numa_nodes.iter() { if numa_node.memory_zones.contains(&memory_zone_id.to_owned()) { return Some(*numa_node_id); } } None } struct TpmDevice {} impl Aml for TpmDevice { fn to_aml_bytes(&self, sink: &mut dyn acpi_tables::AmlSink) { aml::Device::new( "TPM2".into(), vec![ &aml::Name::new("_HID".into(), &"MSFT0101"), &aml::Name::new("_STA".into(), &(0xF_usize)), &aml::Name::new( "_CRS".into(), &aml::ResourceTemplate::new(vec![&aml::Memory32Fixed::new( true, layout::TPM_START.0 as u32, layout::TPM_SIZE as u32, )]), ), ], ) .to_aml_bytes(sink) } } impl Aml for DeviceManager { fn to_aml_bytes(&self, sink: &mut dyn acpi_tables::AmlSink) { #[cfg(target_arch = "aarch64")] use arch::aarch64::DeviceInfoForFdt; let mut pci_scan_methods = Vec::new(); for i in 0..self.pci_segments.len() { pci_scan_methods.push(aml::MethodCall::new( format!("\\_SB_.PC{i:02X}.PCNT").as_str().into(), vec![], )); } let mut pci_scan_inner: Vec<&dyn Aml> = Vec::new(); for method in &pci_scan_methods { pci_scan_inner.push(method) } // PCI hotplug controller aml::Device::new( "_SB_.PHPR".into(), vec![ &aml::Name::new("_HID".into(), &aml::EISAName::new("PNP0A06")), &aml::Name::new("_STA".into(), &0x0bu8), &aml::Name::new("_UID".into(), &"PCI Hotplug Controller"), &aml::Mutex::new("BLCK".into(), 0), &aml::Name::new( "_CRS".into(), &aml::ResourceTemplate::new(vec![&aml::AddressSpace::new_memory( aml::AddressSpaceCachable::NotCacheable, true, self.acpi_address.0, self.acpi_address.0 + DEVICE_MANAGER_ACPI_SIZE as u64 - 1, None, )]), ), // OpRegion and Fields map MMIO range into individual field values &aml::OpRegion::new( "PCST".into(), aml::OpRegionSpace::SystemMemory, &(self.acpi_address.0 as usize), &DEVICE_MANAGER_ACPI_SIZE, ), &aml::Field::new( "PCST".into(), aml::FieldAccessType::DWord, aml::FieldLockRule::NoLock, aml::FieldUpdateRule::WriteAsZeroes, vec![ aml::FieldEntry::Named(*b"PCIU", 32), aml::FieldEntry::Named(*b"PCID", 32), aml::FieldEntry::Named(*b"B0EJ", 32), aml::FieldEntry::Named(*b"PSEG", 32), ], ), &aml::Method::new( "PCEJ".into(), 2, true, vec![ // Take lock defined above &aml::Acquire::new("BLCK".into(), 0xffff), // Choose the current segment &aml::Store::new(&aml::Path::new("PSEG"), &aml::Arg(1)), // Write PCI bus number (in first argument) to I/O port via field &aml::ShiftLeft::new(&aml::Path::new("B0EJ"), &aml::ONE, &aml::Arg(0)), // Release lock &aml::Release::new("BLCK".into()), // Return 0 &aml::Return::new(&aml::ZERO), ], ), &aml::Method::new("PSCN".into(), 0, true, pci_scan_inner), ], ) .to_aml_bytes(sink); for segment in &self.pci_segments { segment.to_aml_bytes(sink); } let mut mbrd_memory = Vec::new(); for segment in &self.pci_segments { mbrd_memory.push(aml::Memory32Fixed::new( true, segment.mmio_config_address as u32, layout::PCI_MMIO_CONFIG_SIZE_PER_SEGMENT as u32, )) } let mut mbrd_memory_refs = Vec::new(); for mbrd_memory_ref in &mbrd_memory { mbrd_memory_refs.push(mbrd_memory_ref as &dyn Aml); } aml::Device::new( "_SB_.MBRD".into(), vec![ &aml::Name::new("_HID".into(), &aml::EISAName::new("PNP0C02")), &aml::Name::new("_UID".into(), &aml::ZERO), &aml::Name::new("_CRS".into(), &aml::ResourceTemplate::new(mbrd_memory_refs)), ], ) .to_aml_bytes(sink); // Serial device #[cfg(target_arch = "x86_64")] let serial_irq = 4; #[cfg(target_arch = "aarch64")] let serial_irq = if self.config.lock().unwrap().serial.clone().mode != ConsoleOutputMode::Off { self.get_device_info() .clone() .get(&(DeviceType::Serial, DeviceType::Serial.to_string())) .unwrap() .irq() } else { // If serial is turned off, add a fake device with invalid irq. 31 }; if self.config.lock().unwrap().serial.mode != ConsoleOutputMode::Off { aml::Device::new( "_SB_.COM1".into(), vec![ &aml::Name::new( "_HID".into(), #[cfg(target_arch = "x86_64")] &aml::EISAName::new("PNP0501"), #[cfg(target_arch = "aarch64")] &"ARMH0011", ), &aml::Name::new("_UID".into(), &aml::ZERO), &aml::Name::new("_DDN".into(), &"COM1"), &aml::Name::new( "_CRS".into(), &aml::ResourceTemplate::new(vec![ &aml::Interrupt::new(true, true, false, false, serial_irq), #[cfg(target_arch = "x86_64")] &aml::IO::new(0x3f8, 0x3f8, 0, 0x8), #[cfg(target_arch = "aarch64")] &aml::Memory32Fixed::new( true, arch::layout::LEGACY_SERIAL_MAPPED_IO_START.raw_value() as u32, MMIO_LEN as u32, ), ]), ), ], ) .to_aml_bytes(sink); } aml::Name::new("_S5_".into(), &aml::Package::new(vec![&5u8])).to_aml_bytes(sink); aml::Device::new( "_SB_.PWRB".into(), vec![ &aml::Name::new("_HID".into(), &aml::EISAName::new("PNP0C0C")), &aml::Name::new("_UID".into(), &aml::ZERO), ], ) .to_aml_bytes(sink); if self.config.lock().unwrap().tpm.is_some() { // Add tpm device TpmDevice {}.to_aml_bytes(sink); } self.ged_notification_device .as_ref() .unwrap() .lock() .unwrap() .to_aml_bytes(sink) } } impl Pausable for DeviceManager { fn pause(&mut self) -> result::Result<(), MigratableError> { for (_, device_node) in self.device_tree.lock().unwrap().iter() { if let Some(migratable) = &device_node.migratable { migratable.lock().unwrap().pause()?; } } // On AArch64, the pause of device manager needs to trigger // a "pause" of GIC, which will flush the GIC pending tables // and ITS tables to guest RAM. #[cfg(target_arch = "aarch64")] { self.get_interrupt_controller() .unwrap() .lock() .unwrap() .pause()?; }; Ok(()) } fn resume(&mut self) -> result::Result<(), MigratableError> { for (_, device_node) in self.device_tree.lock().unwrap().iter() { if let Some(migratable) = &device_node.migratable { migratable.lock().unwrap().resume()?; } } Ok(()) } } impl Snapshottable for DeviceManager { fn id(&self) -> String { DEVICE_MANAGER_SNAPSHOT_ID.to_string() } fn snapshot(&mut self) -> std::result::Result { let mut snapshot = Snapshot::from_data(SnapshotData::new_from_state(&self.state())?); // We aggregate all devices snapshots. for (_, device_node) in self.device_tree.lock().unwrap().iter() { if let Some(migratable) = &device_node.migratable { let mut migratable = migratable.lock().unwrap(); snapshot.add_snapshot(migratable.id(), migratable.snapshot()?); } } Ok(snapshot) } } impl Transportable for DeviceManager {} impl Migratable for DeviceManager { fn start_dirty_log(&mut self) -> std::result::Result<(), MigratableError> { for (_, device_node) in self.device_tree.lock().unwrap().iter() { if let Some(migratable) = &device_node.migratable { migratable.lock().unwrap().start_dirty_log()?; } } Ok(()) } fn stop_dirty_log(&mut self) -> std::result::Result<(), MigratableError> { for (_, device_node) in self.device_tree.lock().unwrap().iter() { if let Some(migratable) = &device_node.migratable { migratable.lock().unwrap().stop_dirty_log()?; } } Ok(()) } fn dirty_log(&mut self) -> std::result::Result { let mut tables = Vec::new(); for (_, device_node) in self.device_tree.lock().unwrap().iter() { if let Some(migratable) = &device_node.migratable { tables.push(migratable.lock().unwrap().dirty_log()?); } } Ok(MemoryRangeTable::new_from_tables(tables)) } fn start_migration(&mut self) -> std::result::Result<(), MigratableError> { for (_, device_node) in self.device_tree.lock().unwrap().iter() { if let Some(migratable) = &device_node.migratable { migratable.lock().unwrap().start_migration()?; } } Ok(()) } fn complete_migration(&mut self) -> std::result::Result<(), MigratableError> { for (_, device_node) in self.device_tree.lock().unwrap().iter() { if let Some(migratable) = &device_node.migratable { migratable.lock().unwrap().complete_migration()?; } } Ok(()) } } const PCIU_FIELD_OFFSET: u64 = 0; const PCID_FIELD_OFFSET: u64 = 4; const B0EJ_FIELD_OFFSET: u64 = 8; const PSEG_FIELD_OFFSET: u64 = 12; const PCIU_FIELD_SIZE: usize = 4; const PCID_FIELD_SIZE: usize = 4; const B0EJ_FIELD_SIZE: usize = 4; const PSEG_FIELD_SIZE: usize = 4; impl BusDevice for DeviceManager { fn read(&mut self, base: u64, offset: u64, data: &mut [u8]) { match offset { PCIU_FIELD_OFFSET => { assert!(data.len() == PCIU_FIELD_SIZE); data.copy_from_slice( &self.pci_segments[self.selected_segment] .pci_devices_up .to_le_bytes(), ); // Clear the PCIU bitmap self.pci_segments[self.selected_segment].pci_devices_up = 0; } PCID_FIELD_OFFSET => { assert!(data.len() == PCID_FIELD_SIZE); data.copy_from_slice( &self.pci_segments[self.selected_segment] .pci_devices_down .to_le_bytes(), ); // Clear the PCID bitmap self.pci_segments[self.selected_segment].pci_devices_down = 0; } B0EJ_FIELD_OFFSET => { assert!(data.len() == B0EJ_FIELD_SIZE); // Always return an empty bitmap since the eject is always // taken care of right away during a write access. data.fill(0); } PSEG_FIELD_OFFSET => { assert_eq!(data.len(), PSEG_FIELD_SIZE); data.copy_from_slice(&(self.selected_segment as u32).to_le_bytes()); } _ => error!( "Accessing unknown location at base 0x{:x}, offset 0x{:x}", base, offset ), } debug!( "PCI_HP_REG_R: base 0x{:x}, offset 0x{:x}, data {:?}", base, offset, data ) } fn write(&mut self, base: u64, offset: u64, data: &[u8]) -> Option> { match offset { B0EJ_FIELD_OFFSET => { assert!(data.len() == B0EJ_FIELD_SIZE); let mut data_array: [u8; 4] = [0, 0, 0, 0]; data_array.copy_from_slice(data); let mut slot_bitmap = u32::from_le_bytes(data_array); while slot_bitmap > 0 { let slot_id = slot_bitmap.trailing_zeros(); if let Err(e) = self.eject_device(self.selected_segment as u16, slot_id as u8) { error!("Failed ejecting device {}: {:?}", slot_id, e); } slot_bitmap &= !(1 << slot_id); } } PSEG_FIELD_OFFSET => { assert_eq!(data.len(), PSEG_FIELD_SIZE); let mut data_array: [u8; 4] = [0, 0, 0, 0]; data_array.copy_from_slice(data); let selected_segment = u32::from_le_bytes(data_array) as usize; if selected_segment >= self.pci_segments.len() { error!( "Segment selection out of range: {} >= {}", selected_segment, self.pci_segments.len() ); return None; } self.selected_segment = selected_segment; } _ => error!( "Accessing unknown location at base 0x{:x}, offset 0x{:x}", base, offset ), } debug!( "PCI_HP_REG_W: base 0x{:x}, offset 0x{:x}, data {:?}", base, offset, data ); None } } impl Drop for DeviceManager { fn drop(&mut self) { for handle in self.virtio_devices.drain(..) { handle.virtio_device.lock().unwrap().shutdown(); } if let Some(termios) = *self.original_termios_opt.lock().unwrap() { // SAFETY: FFI call let _ = unsafe { tcsetattr(stdout().lock().as_raw_fd(), TCSANOW, &termios) }; } } }