1 //! PCI transport for VirtIO. 2 use crate::arch::{PciArch, TraitPciArch}; 3 use crate::driver::pci::pci::{ 4 BusDeviceFunction, PciDeviceStructure, PciDeviceStructureGeneralDevice, PciError, 5 PciStandardDeviceBar, PCI_CAP_ID_VNDR, 6 }; 7 8 use crate::libs::volatile::{ 9 volread, volwrite, ReadOnly, Volatile, VolatileReadable, VolatileWritable, WriteOnly, 10 }; 11 use core::{ 12 fmt::{self, Display, Formatter}, 13 mem::{align_of, size_of}, 14 ptr::{self, addr_of_mut, NonNull}, 15 }; 16 use virtio_drivers::{ 17 transport::{DeviceStatus, DeviceType, Transport}, 18 Error, Hal, PhysAddr, 19 }; 20 21 type VirtAddr = usize; 22 /// The PCI vendor ID for VirtIO devices. 23 /// PCI Virtio设备的vendor ID 24 const VIRTIO_VENDOR_ID: u16 = 0x1af4; 25 26 /// The offset to add to a VirtIO device ID to get the corresponding PCI device ID. 27 /// PCI Virtio设备的DEVICE_ID 的offset 28 const PCI_DEVICE_ID_OFFSET: u16 = 0x1040; 29 /// PCI Virtio 设备的DEVICE_ID及其对应的设备类型 30 const TRANSITIONAL_NETWORK: u16 = 0x1000; 31 const TRANSITIONAL_BLOCK: u16 = 0x1001; 32 const TRANSITIONAL_MEMORY_BALLOONING: u16 = 0x1002; 33 const TRANSITIONAL_CONSOLE: u16 = 0x1003; 34 const TRANSITIONAL_SCSI_HOST: u16 = 0x1004; 35 const TRANSITIONAL_ENTROPY_SOURCE: u16 = 0x1005; 36 const TRANSITIONAL_9P_TRANSPORT: u16 = 0x1009; 37 38 /// The offset of the bar field within `virtio_pci_cap`. 39 const CAP_BAR_OFFSET: u8 = 4; 40 /// The offset of the offset field with `virtio_pci_cap`. 41 const CAP_BAR_OFFSET_OFFSET: u8 = 8; 42 /// The offset of the `length` field within `virtio_pci_cap`. 43 const CAP_LENGTH_OFFSET: u8 = 12; 44 /// The offset of the`notify_off_multiplier` field within `virtio_pci_notify_cap`. 45 const CAP_NOTIFY_OFF_MULTIPLIER_OFFSET: u8 = 16; 46 47 /// Common configuration. 48 const VIRTIO_PCI_CAP_COMMON_CFG: u8 = 1; 49 /// Notifications. 50 const VIRTIO_PCI_CAP_NOTIFY_CFG: u8 = 2; 51 /// ISR Status. 52 const VIRTIO_PCI_CAP_ISR_CFG: u8 = 3; 53 /// Device specific configuration. 54 const VIRTIO_PCI_CAP_DEVICE_CFG: u8 = 4; 55 56 ///@brief device id 转换为设备类型 57 ///@param pci_device_id,device_id 58 ///@return DeviceType 对应的设备类型 59 fn device_type(pci_device_id: u16) -> DeviceType { 60 match pci_device_id { 61 TRANSITIONAL_NETWORK => DeviceType::Network, 62 TRANSITIONAL_BLOCK => DeviceType::Block, 63 TRANSITIONAL_MEMORY_BALLOONING => DeviceType::MemoryBalloon, 64 TRANSITIONAL_CONSOLE => DeviceType::Console, 65 TRANSITIONAL_SCSI_HOST => DeviceType::ScsiHost, 66 TRANSITIONAL_ENTROPY_SOURCE => DeviceType::EntropySource, 67 TRANSITIONAL_9P_TRANSPORT => DeviceType::_9P, 68 id if id >= PCI_DEVICE_ID_OFFSET => DeviceType::from(id - PCI_DEVICE_ID_OFFSET), 69 _ => DeviceType::Invalid, 70 } 71 } 72 73 /// PCI transport for VirtIO. 74 /// 75 /// Ref: 4.1 Virtio Over PCI Bus 76 #[derive(Debug, Clone)] 77 pub struct PciTransport { 78 device_type: DeviceType, 79 /// The bus, device and function identifier for the VirtIO device. 80 bus_device_function: BusDeviceFunction, 81 /// The common configuration structure within some BAR. 82 common_cfg: NonNull<CommonCfg>, 83 /// The start of the queue notification region within some BAR. 84 notify_region: NonNull<[WriteOnly<u16>]>, 85 notify_off_multiplier: u32, 86 /// The ISR status register within some BAR. 87 isr_status: NonNull<Volatile<u8>>, 88 /// The VirtIO device-specific configuration within some BAR. 89 config_space: Option<NonNull<[u32]>>, 90 } 91 92 impl PciTransport { 93 /// Construct a new PCI VirtIO device driver for the given device function on the given PCI 94 /// root controller. 95 /// 96 /// 97 pub fn new<H: Hal>( 98 device: &mut PciDeviceStructureGeneralDevice, 99 ) -> Result<Self, VirtioPciError> { 100 let header = &device.common_header; 101 let bus_device_function = header.bus_device_function; 102 if header.vendor_id != VIRTIO_VENDOR_ID { 103 return Err(VirtioPciError::InvalidVendorId(header.vendor_id)); 104 } 105 let device_type = device_type(header.device_id); 106 // Find the PCI capabilities we need. 107 let mut common_cfg: Option<VirtioCapabilityInfo> = None; 108 let mut notify_cfg: Option<VirtioCapabilityInfo> = None; 109 let mut notify_off_multiplier = 0; 110 let mut isr_cfg = None; 111 let mut device_cfg = None; 112 device.bar_ioremap().unwrap()?; 113 device.enable_master(); 114 //device_capability为迭代器,遍历其相当于遍历所有的cap空间 115 for capability in device.capabilities().unwrap() { 116 if capability.id != PCI_CAP_ID_VNDR { 117 continue; 118 } 119 let cap_len = capability.private_header as u8; 120 let cfg_type = (capability.private_header >> 8) as u8; 121 if cap_len < 16 { 122 continue; 123 } 124 let struct_info = VirtioCapabilityInfo { 125 bar: PciArch::read_config(&bus_device_function, capability.offset + CAP_BAR_OFFSET) 126 as u8, 127 offset: PciArch::read_config( 128 &bus_device_function, 129 capability.offset + CAP_BAR_OFFSET_OFFSET, 130 ), 131 length: PciArch::read_config( 132 &bus_device_function, 133 capability.offset + CAP_LENGTH_OFFSET, 134 ), 135 }; 136 137 match cfg_type { 138 VIRTIO_PCI_CAP_COMMON_CFG if common_cfg.is_none() => { 139 common_cfg = Some(struct_info); 140 } 141 VIRTIO_PCI_CAP_NOTIFY_CFG if cap_len >= 20 && notify_cfg.is_none() => { 142 notify_cfg = Some(struct_info); 143 notify_off_multiplier = PciArch::read_config( 144 &bus_device_function, 145 capability.offset + CAP_NOTIFY_OFF_MULTIPLIER_OFFSET, 146 ); 147 } 148 VIRTIO_PCI_CAP_ISR_CFG if isr_cfg.is_none() => { 149 isr_cfg = Some(struct_info); 150 } 151 VIRTIO_PCI_CAP_DEVICE_CFG if device_cfg.is_none() => { 152 device_cfg = Some(struct_info); 153 } 154 _ => {} 155 } 156 } 157 158 let common_cfg = get_bar_region::<_>( 159 &device.standard_device_bar, 160 &common_cfg.ok_or(VirtioPciError::MissingCommonConfig)?, 161 )?; 162 163 let notify_cfg = notify_cfg.ok_or(VirtioPciError::MissingNotifyConfig)?; 164 if notify_off_multiplier % 2 != 0 { 165 return Err(VirtioPciError::InvalidNotifyOffMultiplier( 166 notify_off_multiplier, 167 )); 168 } 169 //kdebug!("notify.offset={},notify.length={}",notify_cfg.offset,notify_cfg.length); 170 let notify_region = get_bar_region_slice::<_>(&device.standard_device_bar, ¬ify_cfg)?; 171 let isr_status = get_bar_region::<_>( 172 &device.standard_device_bar, 173 &isr_cfg.ok_or(VirtioPciError::MissingIsrConfig)?, 174 )?; 175 let config_space = if let Some(device_cfg) = device_cfg { 176 Some(get_bar_region_slice::<_>( 177 &device.standard_device_bar, 178 &device_cfg, 179 )?) 180 } else { 181 None 182 }; 183 Ok(Self { 184 device_type, 185 bus_device_function, 186 common_cfg, 187 notify_region, 188 notify_off_multiplier, 189 isr_status, 190 config_space, 191 }) 192 } 193 } 194 195 impl Transport for PciTransport { 196 fn device_type(&self) -> DeviceType { 197 self.device_type 198 } 199 200 fn read_device_features(&mut self) -> u64 { 201 // Safe because the common config pointer is valid and we checked in get_bar_region that it 202 // was aligned. 203 unsafe { 204 volwrite!(self.common_cfg, device_feature_select, 0); 205 let mut device_features_bits = volread!(self.common_cfg, device_feature) as u64; 206 volwrite!(self.common_cfg, device_feature_select, 1); 207 device_features_bits |= (volread!(self.common_cfg, device_feature) as u64) << 32; 208 device_features_bits 209 } 210 } 211 212 fn write_driver_features(&mut self, driver_features: u64) { 213 // Safe because the common config pointer is valid and we checked in get_bar_region that it 214 // was aligned. 215 unsafe { 216 volwrite!(self.common_cfg, driver_feature_select, 0); 217 volwrite!(self.common_cfg, driver_feature, driver_features as u32); 218 volwrite!(self.common_cfg, driver_feature_select, 1); 219 volwrite!( 220 self.common_cfg, 221 driver_feature, 222 (driver_features >> 32) as u32 223 ); 224 } 225 } 226 227 fn max_queue_size(&self) -> u32 { 228 // Safe because the common config pointer is valid and we checked in get_bar_region that it 229 // was aligned. 230 unsafe { volread!(self.common_cfg, queue_size) }.into() 231 } 232 233 fn notify(&mut self, queue: u16) { 234 // Safe because the common config and notify region pointers are valid and we checked in 235 // get_bar_region that they were aligned. 236 unsafe { 237 volwrite!(self.common_cfg, queue_select, queue); 238 // TODO: Consider caching this somewhere (per queue). 239 let queue_notify_off = volread!(self.common_cfg, queue_notify_off); 240 241 let offset_bytes = usize::from(queue_notify_off) * self.notify_off_multiplier as usize; 242 let index = offset_bytes / size_of::<u16>(); 243 addr_of_mut!((*self.notify_region.as_ptr())[index]).vwrite(queue); 244 } 245 } 246 247 fn set_status(&mut self, status: DeviceStatus) { 248 // Safe because the common config pointer is valid and we checked in get_bar_region that it 249 // was aligned. 250 unsafe { 251 volwrite!(self.common_cfg, device_status, status.bits() as u8); 252 } 253 } 254 255 fn set_guest_page_size(&mut self, _guest_page_size: u32) { 256 // No-op, the PCI transport doesn't care. 257 } 258 fn requires_legacy_layout(&self) -> bool { 259 false 260 } 261 fn queue_set( 262 &mut self, 263 queue: u16, 264 size: u32, 265 descriptors: PhysAddr, 266 driver_area: PhysAddr, 267 device_area: PhysAddr, 268 ) { 269 // Safe because the common config pointer is valid and we checked in get_bar_region that it 270 // was aligned. 271 // kdebug!("queue_select={}",queue); 272 // kdebug!("queue_size={}",size as u16); 273 // kdebug!("queue_desc={:#x}",descriptors as u64); 274 // kdebug!("driver_area={:#x}",driver_area); 275 unsafe { 276 volwrite!(self.common_cfg, queue_select, queue); 277 volwrite!(self.common_cfg, queue_size, size as u16); 278 volwrite!(self.common_cfg, queue_desc, descriptors as u64); 279 volwrite!(self.common_cfg, queue_driver, driver_area as u64); 280 volwrite!(self.common_cfg, queue_device, device_area as u64); 281 volwrite!(self.common_cfg, queue_enable, 1); 282 } 283 } 284 285 fn queue_unset(&mut self, queue: u16) { 286 // Safe because the common config pointer is valid and we checked in get_bar_region that it 287 // was aligned. 288 unsafe { 289 volwrite!(self.common_cfg, queue_select, queue); 290 volwrite!(self.common_cfg, queue_size, 0); 291 volwrite!(self.common_cfg, queue_desc, 0); 292 volwrite!(self.common_cfg, queue_driver, 0); 293 volwrite!(self.common_cfg, queue_device, 0); 294 } 295 } 296 297 fn queue_used(&mut self, queue: u16) -> bool { 298 // Safe because the common config pointer is valid and we checked in get_bar_region that it 299 // was aligned. 300 unsafe { 301 volwrite!(self.common_cfg, queue_select, queue); 302 volread!(self.common_cfg, queue_enable) == 1 303 } 304 } 305 306 fn ack_interrupt(&mut self) -> bool { 307 // Safe because the common config pointer is valid and we checked in get_bar_region that it 308 // was aligned. 309 // Reading the ISR status resets it to 0 and causes the device to de-assert the interrupt. 310 let isr_status = unsafe { self.isr_status.as_ptr().vread() }; 311 // TODO: Distinguish between queue interrupt and device configuration interrupt. 312 isr_status & 0x3 != 0 313 } 314 315 fn config_space<T>(&self) -> Result<NonNull<T>, Error> { 316 if let Some(config_space) = self.config_space { 317 if size_of::<T>() > config_space.len() * size_of::<u32>() { 318 Err(Error::ConfigSpaceTooSmall) 319 } else if align_of::<T>() > 4 { 320 // Panic as this should only happen if the driver is written incorrectly. 321 panic!( 322 "Driver expected config space alignment of {} bytes, but VirtIO only guarantees 4 byte alignment.", 323 align_of::<T>() 324 ); 325 } else { 326 // TODO: Use NonNull::as_non_null_ptr once it is stable. 327 let config_space_ptr = NonNull::new(config_space.as_ptr() as *mut u32).unwrap(); 328 Ok(config_space_ptr.cast()) 329 } 330 } else { 331 Err(Error::ConfigSpaceMissing) 332 } 333 } 334 } 335 336 impl Drop for PciTransport { 337 fn drop(&mut self) { 338 // Reset the device when the transport is dropped. 339 self.set_status(DeviceStatus::empty()) 340 } 341 } 342 343 #[repr(C)] 344 struct CommonCfg { 345 device_feature_select: Volatile<u32>, 346 device_feature: ReadOnly<u32>, 347 driver_feature_select: Volatile<u32>, 348 driver_feature: Volatile<u32>, 349 msix_config: Volatile<u16>, 350 num_queues: ReadOnly<u16>, 351 device_status: Volatile<u8>, 352 config_generation: ReadOnly<u8>, 353 queue_select: Volatile<u16>, 354 queue_size: Volatile<u16>, 355 queue_msix_vector: Volatile<u16>, 356 queue_enable: Volatile<u16>, 357 queue_notify_off: Volatile<u16>, 358 queue_desc: Volatile<u64>, 359 queue_driver: Volatile<u64>, 360 queue_device: Volatile<u64>, 361 } 362 363 /// Information about a VirtIO structure within some BAR, as provided by a `virtio_pci_cap`. 364 /// cfg空间在哪个bar的多少偏移处,长度多少 365 #[derive(Clone, Debug, Eq, PartialEq)] 366 struct VirtioCapabilityInfo { 367 /// The bar in which the structure can be found. 368 bar: u8, 369 /// The offset within the bar. 370 offset: u32, 371 /// The length in bytes of the structure within the bar. 372 length: u32, 373 } 374 375 /// An error encountered initialising a VirtIO PCI transport. 376 /// VirtIO PCI transport 初始化时的错误 377 #[derive(Clone, Debug, Eq, PartialEq)] 378 pub enum VirtioPciError { 379 /// PCI device vender ID was not the VirtIO vendor ID. 380 InvalidVendorId(u16), 381 /// No valid `VIRTIO_PCI_CAP_COMMON_CFG` capability was found. 382 MissingCommonConfig, 383 /// No valid `VIRTIO_PCI_CAP_NOTIFY_CFG` capability was found. 384 MissingNotifyConfig, 385 /// `VIRTIO_PCI_CAP_NOTIFY_CFG` capability has a `notify_off_multiplier` that is not a multiple 386 /// of 2. 387 InvalidNotifyOffMultiplier(u32), 388 /// No valid `VIRTIO_PCI_CAP_ISR_CFG` capability was found. 389 MissingIsrConfig, 390 /// An IO BAR was provided rather than a memory BAR. 391 UnexpectedBarType, 392 /// A BAR which we need was not allocated an address. 393 BarNotAllocated(u8), 394 /// The offset for some capability was greater than the length of the BAR. 395 BarOffsetOutOfRange, 396 /// The virtual address was not aligned as expected. 397 Misaligned { 398 /// The virtual address in question. 399 vaddr: VirtAddr, 400 /// The expected alignment in bytes. 401 alignment: usize, 402 }, 403 ///获取虚拟地址失败 404 BarGetVaddrFailed, 405 /// A generic PCI error, 406 Pci(PciError), 407 } 408 409 impl Display for VirtioPciError { 410 fn fmt(&self, f: &mut Formatter) -> fmt::Result { 411 match self { 412 Self::InvalidVendorId(vendor_id) => write!( 413 f, 414 "PCI device vender ID {:#06x} was not the VirtIO vendor ID {:#06x}.", 415 vendor_id, VIRTIO_VENDOR_ID 416 ), 417 Self::MissingCommonConfig => write!( 418 f, 419 "No valid `VIRTIO_PCI_CAP_COMMON_CFG` capability was found." 420 ), 421 Self::MissingNotifyConfig => write!( 422 f, 423 "No valid `VIRTIO_PCI_CAP_NOTIFY_CFG` capability was found." 424 ), 425 Self::InvalidNotifyOffMultiplier(notify_off_multiplier) => { 426 write!( 427 f, 428 "`VIRTIO_PCI_CAP_NOTIFY_CFG` capability has a `notify_off_multiplier` that is not a multiple of 2: {}", 429 notify_off_multiplier 430 ) 431 } 432 Self::MissingIsrConfig => { 433 write!(f, "No valid `VIRTIO_PCI_CAP_ISR_CFG` capability was found.") 434 } 435 Self::UnexpectedBarType => write!(f, "Unexpected BAR (expected memory BAR)."), 436 Self::BarNotAllocated(bar_index) => write!(f, "Bar {} not allocated.", bar_index), 437 Self::BarOffsetOutOfRange => write!(f, "Capability offset greater than BAR length."), 438 Self::Misaligned { vaddr, alignment } => write!( 439 f, 440 "Virtual address {:#018x} was not aligned to a {} byte boundary as expected.", 441 vaddr, alignment 442 ), 443 Self::BarGetVaddrFailed => write!(f, "Get bar virtaddress failed"), 444 Self::Pci(pci_error) => pci_error.fmt(f), 445 } 446 } 447 } 448 449 /// PCI error到VirtioPciError的转换,层层上报 450 impl From<PciError> for VirtioPciError { 451 fn from(error: PciError) -> Self { 452 Self::Pci(error) 453 } 454 } 455 456 /// @brief 获取虚拟地址并将其转化为对应类型的指针 457 /// @param device_bar 存储bar信息的结构体 struct_info 存储cfg空间的位置信息 458 /// @return Result<NonNull<T>, VirtioPciError> 成功则返回对应类型的指针,失败则返回Error 459 fn get_bar_region<T>( 460 device_bar: &PciStandardDeviceBar, 461 struct_info: &VirtioCapabilityInfo, 462 ) -> Result<NonNull<T>, VirtioPciError> { 463 let bar_info = device_bar.get_bar(struct_info.bar)?; 464 let (bar_address, bar_size) = bar_info 465 .memory_address_size() 466 .ok_or(VirtioPciError::UnexpectedBarType)?; 467 if bar_address == 0 { 468 return Err(VirtioPciError::BarNotAllocated(struct_info.bar)); 469 } 470 if struct_info.offset + struct_info.length > bar_size 471 || size_of::<T>() > struct_info.length as usize 472 { 473 return Err(VirtioPciError::BarOffsetOutOfRange); 474 } 475 //kdebug!("Chossed bar ={},used={}",struct_info.bar,struct_info.offset + struct_info.length); 476 let vaddr = (bar_info 477 .virtual_address() 478 .ok_or(VirtioPciError::BarGetVaddrFailed)?) as usize 479 + struct_info.offset as usize; 480 if vaddr % align_of::<T>() != 0 { 481 return Err(VirtioPciError::Misaligned { 482 vaddr, 483 alignment: align_of::<T>(), 484 }); 485 } 486 let vaddr = NonNull::new(vaddr as *mut u8).unwrap(); 487 Ok(vaddr.cast()) 488 } 489 490 /// @brief 获取虚拟地址并将其转化为对应类型的切片的指针 491 /// @param device_bar 存储bar信息的结构体 struct_info 存储cfg空间的位置信息切片的指针 492 /// @return Result<NonNull<[T]>, VirtioPciError> 成功则返回对应类型的指针切片,失败则返回Error 493 fn get_bar_region_slice<T>( 494 device_bar: &PciStandardDeviceBar, 495 struct_info: &VirtioCapabilityInfo, 496 ) -> Result<NonNull<[T]>, VirtioPciError> { 497 let ptr = get_bar_region::<T>(device_bar, struct_info)?; 498 // let raw_slice = 499 // ptr::slice_from_raw_parts_mut(ptr.as_ptr(), struct_info.length as usize / size_of::<T>()); 500 Ok(nonnull_slice_from_raw_parts( 501 ptr, 502 struct_info.length as usize / size_of::<T>(), 503 )) 504 } 505 506 fn nonnull_slice_from_raw_parts<T>(data: NonNull<T>, len: usize) -> NonNull<[T]> { 507 NonNull::new(ptr::slice_from_raw_parts_mut(data.as_ptr(), len)).unwrap() 508 } 509