cloud-hypervisor/pci/src/bus.rs

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// Copyright 2018 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.
use crate::configuration::{
PciBarRegionType, PciBridgeSubclass, PciClassCode, PciConfiguration, PciHeaderType,
};
use crate::device::{DeviceRelocation, Error as PciDeviceError, PciDevice};
use byteorder::{ByteOrder, LittleEndian};
use devices::BusDevice;
use std;
use std::any::Any;
use std::collections::HashMap;
use std::ops::DerefMut;
use std::sync::{Arc, Mutex};
use vm_memory::{Address, GuestAddress, GuestUsize};
const VENDOR_ID_INTEL: u16 = 0x8086;
const DEVICE_ID_INTEL_VIRT_PCIE_HOST: u16 = 0x0d57;
const NUM_DEVICE_IDS: usize = 32;
/// Errors for device manager.
#[derive(Debug)]
pub enum PciRootError {
/// Could not allocate device address space for the device.
AllocateDeviceAddrs(PciDeviceError),
/// Could not allocate an IRQ number.
AllocateIrq,
/// Could not add a device to the port io bus.
PioInsert(devices::BusError),
/// Could not add a device to the mmio bus.
MmioInsert(devices::BusError),
/// Could not find an available device slot on the PCI bus.
NoPciDeviceSlotAvailable,
/// Invalid PCI device identifier provided.
InvalidPciDeviceSlot(usize),
}
pub type Result<T> = std::result::Result<T, PciRootError>;
/// Emulates the PCI Root bridge device.
pub struct PciRoot {
/// Configuration space.
config: PciConfiguration,
}
impl PciRoot {
/// Create an empty PCI root bridge.
pub fn new(config: Option<PciConfiguration>) -> Self {
if let Some(config) = config {
PciRoot { config }
} else {
PciRoot {
config: PciConfiguration::new(
VENDOR_ID_INTEL,
DEVICE_ID_INTEL_VIRT_PCIE_HOST,
PciClassCode::BridgeDevice,
&PciBridgeSubclass::HostBridge,
None,
PciHeaderType::Device,
0,
0,
None,
),
}
}
}
}
impl BusDevice for PciRoot {}
impl PciDevice for PciRoot {
fn write_config_register(&mut self, reg_idx: usize, offset: u64, data: &[u8]) {
self.config.write_config_register(reg_idx, offset, data);
}
fn read_config_register(&mut self, reg_idx: usize) -> u32 {
self.config.read_reg(reg_idx)
}
fn as_any(&mut self) -> &mut dyn Any {
self
}
}
pub struct PciBus {
/// Devices attached to this bus.
/// Device 0 is host bridge.
devices: HashMap<u32, Arc<Mutex<dyn PciDevice>>>,
device_reloc: Arc<dyn DeviceRelocation>,
device_ids: Vec<bool>,
}
impl PciBus {
pub fn new(pci_root: PciRoot, device_reloc: Arc<dyn DeviceRelocation>) -> Self {
let mut devices: HashMap<u32, Arc<Mutex<dyn PciDevice>>> = HashMap::new();
let mut device_ids: Vec<bool> = vec![false; NUM_DEVICE_IDS];
devices.insert(0, Arc::new(Mutex::new(pci_root)));
device_ids[0] = true;
PciBus {
devices,
device_reloc,
device_ids,
}
}
pub fn register_mapping(
&self,
dev: Arc<Mutex<dyn BusDevice>>,
io_bus: &devices::Bus,
mmio_bus: &devices::Bus,
bars: Vec<(GuestAddress, GuestUsize, PciBarRegionType)>,
) -> Result<()> {
for (address, size, type_) in bars {
match type_ {
PciBarRegionType::IORegion => {
io_bus
.insert(dev.clone(), address.raw_value(), size)
.map_err(PciRootError::PioInsert)?;
}
PciBarRegionType::Memory32BitRegion | PciBarRegionType::Memory64BitRegion => {
mmio_bus
.insert(dev.clone(), address.raw_value(), size)
.map_err(PciRootError::MmioInsert)?;
}
}
}
Ok(())
}
pub fn add_device(
&mut self,
pci_device_bdf: u32,
device: Arc<Mutex<dyn PciDevice>>,
) -> Result<()> {
self.devices.insert(pci_device_bdf >> 3, device);
Ok(())
}
pub fn remove_by_device(&mut self, device: &Arc<Mutex<dyn PciDevice>>) -> Result<()> {
self.devices.retain(|_, dev| !Arc::ptr_eq(dev, device));
Ok(())
}
pub fn next_device_id(&mut self) -> Result<u32> {
for (idx, device_id) in self.device_ids.iter_mut().enumerate() {
if !(*device_id) {
*device_id = true;
return Ok(idx as u32);
}
}
Err(PciRootError::NoPciDeviceSlotAvailable)
}
pub fn put_device_id(&mut self, id: usize) -> Result<()> {
if id < NUM_DEVICE_IDS {
self.device_ids[id] = false;
Ok(())
} else {
Err(PciRootError::InvalidPciDeviceSlot(id))
}
}
}
pub struct PciConfigIo {
/// Config space register.
config_address: u32,
pci_bus: Arc<Mutex<PciBus>>,
}
impl PciConfigIo {
pub fn new(pci_bus: Arc<Mutex<PciBus>>) -> Self {
PciConfigIo {
pci_bus,
config_address: 0,
}
}
pub fn config_space_read(&self) -> u32 {
let enabled = (self.config_address & 0x8000_0000) != 0;
if !enabled {
return 0xffff_ffff;
}
let (bus, device, function, register) =
parse_io_config_address(self.config_address & !0x8000_0000);
// Only support one bus.
if bus != 0 {
return 0xffff_ffff;
}
// Don't support multi-function devices.
if function > 0 {
return 0xffff_ffff;
}
self.pci_bus
.lock()
.unwrap()
.devices
.get(&(device as u32))
.map_or(0xffff_ffff, |d| {
d.lock().unwrap().read_config_register(register)
})
}
pub fn config_space_write(&mut self, offset: u64, data: &[u8]) {
if offset as usize + data.len() > 4 {
return;
}
let enabled = (self.config_address & 0x8000_0000) != 0;
if !enabled {
return;
}
let (bus, device, _function, register) =
parse_io_config_address(self.config_address & !0x8000_0000);
// Only support one bus.
if bus != 0 {
return;
}
let pci_bus = self.pci_bus.lock().unwrap();
if let Some(d) = pci_bus.devices.get(&(device as u32)) {
let mut device = d.lock().unwrap();
// Find out if one of the device's BAR is being reprogrammed, and
// reprogram it if needed.
if let Some(params) = device.detect_bar_reprogramming(register, data) {
if let Err(e) = pci_bus.device_reloc.move_bar(
params.old_base,
params.new_base,
params.len,
device.deref_mut(),
params.region_type,
) {
error!("Failed moving device BAR: {}", e);
}
}
// Update the register value
device.write_config_register(register, offset, data);
}
}
fn set_config_address(&mut self, offset: u64, data: &[u8]) {
if offset as usize + data.len() > 4 {
return;
}
let (mask, value): (u32, u32) = match data.len() {
1 => (
0x0000_00ff << (offset * 8),
u32::from(data[0]) << (offset * 8),
),
2 => (
0x0000_ffff << (offset * 16),
(u32::from(data[1]) << 8 | u32::from(data[0])) << (offset * 16),
),
4 => (0xffff_ffff, LittleEndian::read_u32(data)),
_ => return,
};
self.config_address = (self.config_address & !mask) | value;
}
}
impl BusDevice for PciConfigIo {
fn read(&mut self, _base: u64, offset: u64, data: &mut [u8]) {
// `offset` is relative to 0xcf8
let value = match offset {
0..=3 => self.config_address,
4..=7 => self.config_space_read(),
_ => 0xffff_ffff,
};
// Only allow reads to the register boundary.
let start = offset as usize % 4;
let end = start + data.len();
if end <= 4 {
for i in start..end {
data[i - start] = (value >> (i * 8)) as u8;
}
} else {
for d in data {
*d = 0xff;
}
}
}
fn write(&mut self, _base: u64, offset: u64, data: &[u8]) {
// `offset` is relative to 0xcf8
match offset {
o @ 0..=3 => self.set_config_address(o, data),
o @ 4..=7 => self.config_space_write(o - 4, data),
_ => (),
};
}
}
/// Emulates PCI memory-mapped configuration access mechanism.
pub struct PciConfigMmio {
pci_bus: Arc<Mutex<PciBus>>,
}
impl PciConfigMmio {
pub fn new(pci_bus: Arc<Mutex<PciBus>>) -> Self {
PciConfigMmio { pci_bus }
}
fn config_space_read(&self, config_address: u32) -> u32 {
let (bus, device, _function, register) = parse_mmio_config_address(config_address);
// Only support one bus.
if bus != 0 {
return 0xffff_ffff;
}
self.pci_bus
.lock()
.unwrap()
.devices
.get(&(device as u32))
.map_or(0xffff_ffff, |d| {
d.lock().unwrap().read_config_register(register)
})
}
fn config_space_write(&mut self, config_address: u32, offset: u64, data: &[u8]) {
if offset as usize + data.len() > 4 {
return;
}
let (bus, device, _function, register) = parse_mmio_config_address(config_address);
// Only support one bus.
if bus != 0 {
return;
}
let pci_bus = self.pci_bus.lock().unwrap();
if let Some(d) = pci_bus.devices.get(&(device as u32)) {
let mut device = d.lock().unwrap();
// Find out if one of the device's BAR is being reprogrammed, and
// reprogram it if needed.
if let Some(params) = device.detect_bar_reprogramming(register, data) {
if let Err(e) = pci_bus.device_reloc.move_bar(
params.old_base,
params.new_base,
params.len,
device.deref_mut(),
params.region_type,
) {
error!("Failed moving device BAR: {}", e);
}
}
// Update the register value
device.write_config_register(register, offset, data);
}
}
}
impl BusDevice for PciConfigMmio {
fn read(&mut self, _base: u64, offset: u64, data: &mut [u8]) {
// Only allow reads to the register boundary.
let start = offset as usize % 4;
let end = start + data.len();
if end > 4 || offset > u64::from(u32::max_value()) {
for d in data {
*d = 0xff;
}
return;
}
let value = self.config_space_read(offset as u32);
for i in start..end {
data[i - start] = (value >> (i * 8)) as u8;
}
}
fn write(&mut self, _base: u64, offset: u64, data: &[u8]) {
if offset > u64::from(u32::max_value()) {
return;
}
self.config_space_write(offset as u32, offset % 4, data)
}
}
fn shift_and_mask(value: u32, offset: usize, mask: u32) -> usize {
((value >> offset) & mask) as usize
}
// Parse the MMIO address offset to a (bus, device, function, register) tuple.
// See section 7.2.2 PCI Express Enhanced Configuration Access Mechanism (ECAM)
// from the Pci Express Base Specification Revision 5.0 Version 1.0.
fn parse_mmio_config_address(config_address: u32) -> (usize, usize, usize, usize) {
const BUS_NUMBER_OFFSET: usize = 20;
const BUS_NUMBER_MASK: u32 = 0x00ff;
const DEVICE_NUMBER_OFFSET: usize = 15;
const DEVICE_NUMBER_MASK: u32 = 0x1f;
const FUNCTION_NUMBER_OFFSET: usize = 12;
const FUNCTION_NUMBER_MASK: u32 = 0x07;
const REGISTER_NUMBER_OFFSET: usize = 2;
const REGISTER_NUMBER_MASK: u32 = 0x3ff;
(
shift_and_mask(config_address, BUS_NUMBER_OFFSET, BUS_NUMBER_MASK),
shift_and_mask(config_address, DEVICE_NUMBER_OFFSET, DEVICE_NUMBER_MASK),
shift_and_mask(config_address, FUNCTION_NUMBER_OFFSET, FUNCTION_NUMBER_MASK),
shift_and_mask(config_address, REGISTER_NUMBER_OFFSET, REGISTER_NUMBER_MASK),
)
}
// Parse the CONFIG_ADDRESS register to a (bus, device, function, register) tuple.
fn parse_io_config_address(config_address: u32) -> (usize, usize, usize, usize) {
const BUS_NUMBER_OFFSET: usize = 16;
const BUS_NUMBER_MASK: u32 = 0x00ff;
const DEVICE_NUMBER_OFFSET: usize = 11;
const DEVICE_NUMBER_MASK: u32 = 0x1f;
const FUNCTION_NUMBER_OFFSET: usize = 8;
const FUNCTION_NUMBER_MASK: u32 = 0x07;
const REGISTER_NUMBER_OFFSET: usize = 2;
const REGISTER_NUMBER_MASK: u32 = 0x3f;
(
shift_and_mask(config_address, BUS_NUMBER_OFFSET, BUS_NUMBER_MASK),
shift_and_mask(config_address, DEVICE_NUMBER_OFFSET, DEVICE_NUMBER_MASK),
shift_and_mask(config_address, FUNCTION_NUMBER_OFFSET, FUNCTION_NUMBER_MASK),
shift_and_mask(config_address, REGISTER_NUMBER_OFFSET, REGISTER_NUMBER_MASK),
)
}