// 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::{PciBridgeSubclass, PciClassCode, PciConfiguration, PciHeaderType}; use crate::device::{Error as PciDeviceError, PciDevice}; use byteorder::{ByteOrder, LittleEndian}; use devices::BusDevice; use std; use std::sync::Arc; use std::sync::Mutex; use vm_memory::{Address, GuestAddress, GuestUsize}; const VENDOR_ID_INTEL: u16 = 0x8086; const DEVICE_ID_INTEL_VIRT_PCIE_HOST: u16 = 0x0d57; /// 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 mmio bus. MmioInsert(devices::BusError), } pub type Result = std::result::Result; /// Emulates the PCI Root bridge. pub struct PciRoot { /// Bus configuration for the root device. configuration: PciConfiguration, /// Devices attached to this bridge. devices: Vec>>, } impl PciRoot { /// Create an empty PCI root bus. pub fn new(configuration: Option) -> Self { if let Some(config) = configuration { PciRoot { configuration: config, devices: Vec::new(), } } else { PciRoot { configuration: PciConfiguration::new( VENDOR_ID_INTEL, DEVICE_ID_INTEL_VIRT_PCIE_HOST, PciClassCode::BridgeDevice, &PciBridgeSubclass::HostBridge, None, PciHeaderType::Bridge, 0, 0, None, ), devices: Vec::new(), } } } /// Add a `device` to this root PCI bus. pub fn add_device(&mut self, pci_device: Arc>) -> Result<()> { self.devices.push(pci_device); Ok(()) } /// Register Guest Address mapping of a `device` to IO bus. pub fn register_mapping( &self, device: Arc>, bus: &mut devices::Bus, bars: Vec<(GuestAddress, GuestUsize)>, ) -> Result<()> { for (address, size) in bars { bus.insert(device.clone(), address.raw_value(), size) .map_err(PciRootError::MmioInsert)?; } Ok(()) } pub fn config_space_read( &self, bus: usize, device: usize, _function: usize, register: usize, ) -> u32 { // Only support one bus. if bus != 0 { return 0xffff_ffff; } match device { 0 => { // If bus and device are both zero, then read from the root config. self.configuration.read_config_register(register) } dev_num => self.devices.get(dev_num - 1).map_or(0xffff_ffff, |d| { d.lock().unwrap().read_config_register(register) }), } } pub fn config_space_write( &mut self, bus: usize, device: usize, _function: usize, register: usize, offset: u64, data: &[u8], ) { if offset as usize + data.len() > 4 { return; } // Only support one bus. if bus != 0 { return; } match device { 0 => { // If bus and device are both zero, then read from the root config. self.configuration .write_config_register(register, offset, data); } dev_num => { if let Some(d) = self.devices.get(dev_num - 1) { d.lock() .unwrap() .write_config_register(register, offset, data); } } } } } /// Emulates PCI configuration access mechanism #1 (I/O ports 0xcf8 and 0xcfc). pub struct PciConfigIo { /// PCI root bridge. pci_root: PciRoot, /// Current address to read/write from (0xcf8 register, litte endian). config_address: u32, } impl PciConfigIo { pub fn new(pci_root: PciRoot) -> Self { PciConfigIo { pci_root, config_address: 0, } } 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_config_address(self.config_address & !0x8000_0000); self.pci_root .config_space_read(bus, device, function, register) } fn config_space_write(&mut self, offset: u64, data: &[u8]) { let enabled = (self.config_address & 0x8000_0000) != 0; if !enabled { return; } let (bus, device, function, register) = parse_config_address(self.config_address & !0x8000_0000); self.pci_root .config_space_write(bus, device, function, 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, 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, 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 root bridge. pci_root: PciRoot, } impl PciConfigMmio { pub fn new(pci_root: PciRoot) -> Self { PciConfigMmio { pci_root } } fn config_space_read(&self, config_address: u32) -> u32 { let (bus, device, function, register) = parse_config_address(config_address); self.pci_root .config_space_read(bus, device, function, register) } fn config_space_write(&mut self, config_address: u32, offset: u64, data: &[u8]) { let (bus, device, function, register) = parse_config_address(config_address); self.pci_root .config_space_write(bus, device, function, register, offset, data) } } impl BusDevice for PciConfigMmio { fn read(&mut self, 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, offset: u64, data: &[u8]) { if offset > u64::from(u32::max_value()) { return; } self.config_space_write(offset as u32, offset % 4, data) } } // Parse the CONFIG_ADDRESS register to a (bus, device, function, register) tuple. fn parse_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; let bus_number = ((config_address >> BUS_NUMBER_OFFSET) & BUS_NUMBER_MASK) as usize; let device_number = ((config_address >> DEVICE_NUMBER_OFFSET) & DEVICE_NUMBER_MASK) as usize; let function_number = ((config_address >> FUNCTION_NUMBER_OFFSET) & FUNCTION_NUMBER_MASK) as usize; let register_number = ((config_address >> REGISTER_NUMBER_OFFSET) & REGISTER_NUMBER_MASK) as usize; (bus_number, device_number, function_number, register_number) }