1 #![allow(dead_code)] 2 // 目前仅支持单主桥单Segment 3 4 use super::pci_irq::{IrqType, PciIrqError}; 5 use super::root::{pci_root_0, PciRoot}; 6 use crate::arch::{PciArch, TraitPciArch}; 7 use crate::exception::IrqNumber; 8 use crate::libs::rwlock::{RwLock, RwLockReadGuard, RwLockWriteGuard}; 9 10 use crate::mm::mmio_buddy::{mmio_pool, MMIOSpaceGuard}; 11 12 use crate::mm::VirtAddr; 13 use crate::{kdebug, kerror, kinfo, kwarn}; 14 use alloc::sync::Arc; 15 use alloc::vec::Vec; 16 use alloc::{boxed::Box, collections::LinkedList}; 17 use bitflags::bitflags; 18 19 use core::{ 20 convert::TryFrom, 21 fmt::{self, Debug, Display, Formatter}, 22 }; 23 // PCI_DEVICE_LINKEDLIST 添加了读写锁的全局链表,里面存储了检索到的PCI设备结构体 24 lazy_static! { 25 pub static ref PCI_DEVICE_LINKEDLIST: PciDeviceLinkedList = PciDeviceLinkedList::new(); 26 } 27 28 /// PCI域地址 29 #[derive(Clone, Copy, Eq, Ord, PartialEq, PartialOrd)] 30 #[repr(transparent)] 31 pub struct PciAddr(usize); 32 33 impl PciAddr { 34 #[inline(always)] 35 pub const fn new(address: usize) -> Self { 36 Self(address) 37 } 38 39 /// @brief 获取PCI域地址的值 40 #[inline(always)] 41 pub fn data(&self) -> usize { 42 self.0 43 } 44 45 /// @brief 将PCI域地址加上一个偏移量 46 #[inline(always)] 47 pub fn add(self, offset: usize) -> Self { 48 Self(self.0 + offset) 49 } 50 51 /// @brief 判断PCI域地址是否按照指定要求对齐 52 #[inline(always)] 53 pub fn check_aligned(&self, align: usize) -> bool { 54 return self.0 & (align - 1) == 0; 55 } 56 } 57 impl Debug for PciAddr { 58 fn fmt(&self, f: &mut core::fmt::Formatter<'_>) -> core::fmt::Result { 59 write!(f, "PciAddr({:#x})", self.0) 60 } 61 } 62 63 /// 添加了读写锁的链表,存储PCI设备结构体 64 pub struct PciDeviceLinkedList { 65 list: RwLock<LinkedList<Box<dyn PciDeviceStructure>>>, 66 } 67 68 impl PciDeviceLinkedList { 69 /// @brief 初始化结构体 70 fn new() -> Self { 71 PciDeviceLinkedList { 72 list: RwLock::new(LinkedList::new()), 73 } 74 } 75 /// @brief 获取可读的linkedlist(读锁守卫) 76 /// @return RwLockReadGuard<LinkedList<Box<dyn PciDeviceStructure>>> 读锁守卫 77 pub fn read(&self) -> RwLockReadGuard<LinkedList<Box<dyn PciDeviceStructure>>> { 78 self.list.read() 79 } 80 /// @brief 获取可写的linkedlist(写锁守卫) 81 /// @return RwLockWriteGuard<LinkedList<Box<dyn PciDeviceStructure>>> 写锁守卫 82 pub fn write(&self) -> RwLockWriteGuard<LinkedList<Box<dyn PciDeviceStructure>>> { 83 self.list.write() 84 } 85 /// @brief 获取链表中PCI结构体数目 86 /// @return usize 链表中PCI结构体数目 87 pub fn num(&self) -> usize { 88 let list = self.list.read(); 89 list.len() 90 } 91 /// @brief 添加Pci设备结构体到链表中 92 pub fn add(&self, device: Box<dyn PciDeviceStructure>) { 93 let mut list = self.list.write(); 94 list.push_back(device); 95 } 96 } 97 98 /// # 获取具有特定供应商ID的PCI设备结构的引用 99 /// 100 /// 这个函数通过供应商ID搜索PCI设备结构列表,并返回匹配该ID的所有设备结构的引用。 101 /// 102 /// ## 参数 103 /// 104 /// - list: 一个可变的PCI设备结构链表,类型为`&'a mut RwLockWriteGuard<'_, LinkedList<Box<dyn PciDeviceStructure>>>`。 105 /// - vendor_id: 要查找的PCI供应商ID,类型为`u16`。 106 /// 107 /// ## 返回值 108 /// 109 /// - 返回匹配的供应商ID的PCI设备结构的引用。 110 pub fn get_pci_device_structures_mut_by_vendor_id<'a>( 111 list: &'a mut RwLockWriteGuard<'_, LinkedList<Box<dyn PciDeviceStructure>>>, 112 vendor_id: u16, 113 ) -> Vec<&'a mut Box<(dyn PciDeviceStructure)>> { 114 let mut result = Vec::new(); 115 for box_pci_device_structure in list.iter_mut() { 116 let common_header = (*box_pci_device_structure).common_header(); 117 if common_header.vendor_id == vendor_id { 118 result.push(box_pci_device_structure); 119 } 120 } 121 result 122 } 123 124 /// # get_pci_device_structure_mut - 在链表中寻找满足条件的PCI设备结构体并返回其可变引用 125 /// 126 /// 该函数遍历给定的PCI设备链表,寻找其common_header中class_code和subclass字段与给定值匹配的设备结构体。 127 /// 对于每一个匹配的设备结构体,函数返回一个可变引用。 128 /// 129 /// ## 参数 130 /// 131 /// - list: &'a mut RwLockWriteGuard<'_, LinkedList<Box<dyn PciDeviceStructure>>> — 链表的写锁守卫,用于访问和遍历PCI设备链表。 132 /// - class_code: u8 — PCI设备class code寄存器值,用于分类设备的功能。 133 /// - subclass: u8 — PCI设备subclass寄存器值,与class_code一起确定设备的子类型。 134 /// 135 /// ## 返回值 136 /// - 包含链表中所有满足条件的PCI结构体的可变引用的容器。 137 pub fn get_pci_device_structure_mut<'a>( 138 list: &'a mut RwLockWriteGuard<'_, LinkedList<Box<dyn PciDeviceStructure>>>, 139 class_code: u8, 140 subclass: u8, 141 ) -> Vec<&'a mut Box<(dyn PciDeviceStructure)>> { 142 let mut result = Vec::new(); 143 for box_pci_device_structure in list.iter_mut() { 144 let common_header = (*box_pci_device_structure).common_header(); 145 if (common_header.class_code == class_code) && (common_header.subclass == subclass) { 146 result.push(box_pci_device_structure); 147 } 148 } 149 result 150 } 151 152 /// # get_pci_device_structure - 在链表中寻找满足条件的PCI设备结构体并返回其不可变引用 153 /// 154 /// 该函数遍历给定的PCI设备链表,寻找其common_header中class_code和subclass字段与给定值匹配的设备结构体。 155 /// 对于每一个匹配的设备结构体,函数返回一个可变引用。 156 /// 157 /// ## 参数 158 /// 159 /// - list: &'a mut RwLockWriteGuard<'_, LinkedList<Box<dyn PciDeviceStructure>>> — 链表的写锁守卫,用于访问和遍历PCI设备链表。 160 /// - class_code: u8 — PCI设备class code寄存器值,用于分类设备的功能。 161 /// - subclass: u8 — PCI设备subclass寄存器值,与class_code一起确定设备的子类型。 162 /// 163 /// ## 返回值 164 /// - 包含链表中所有满足条件的PCI结构体的不可变引用的容器。 165 #[allow(clippy::borrowed_box)] 166 pub fn get_pci_device_structure<'a>( 167 list: &'a mut RwLockReadGuard<'_, LinkedList<Box<dyn PciDeviceStructure>>>, 168 class_code: u8, 169 subclass: u8, 170 ) -> Vec<&'a Box<(dyn PciDeviceStructure)>> { 171 let mut result = Vec::new(); 172 for box_pci_device_structure in list.iter() { 173 let common_header = (*box_pci_device_structure).common_header(); 174 if (common_header.class_code == class_code) && (common_header.subclass == subclass) { 175 result.push(box_pci_device_structure); 176 } 177 } 178 result 179 } 180 181 //Bar0寄存器的offset 182 const BAR0_OFFSET: u8 = 0x10; 183 //Status、Command寄存器的offset 184 const STATUS_COMMAND_OFFSET: u8 = 0x04; 185 /// ID for vendor-specific PCI capabilities.(Virtio Capabilities) 186 pub const PCI_CAP_ID_VNDR: u8 = 0x09; 187 pub const PCI_CAP_ID_MSI: u8 = 0x05; 188 pub const PCI_CAP_ID_MSIX: u8 = 0x11; 189 pub const PORT_PCI_CONFIG_ADDRESS: u16 = 0xcf8; 190 pub const PORT_PCI_CONFIG_DATA: u16 = 0xcfc; 191 // pci设备分组的id 192 pub type SegmentGroupNumber = u16; //理论上最多支持65535个Segment_Group 193 194 bitflags! { 195 /// The status register in PCI configuration space. 196 pub struct Status: u16 { 197 // Bits 0-2 are reserved. 198 /// The state of the device's INTx# signal. 199 const INTERRUPT_STATUS = 1 << 3; 200 /// The device has a linked list of capabilities. 201 const CAPABILITIES_LIST = 1 << 4; 202 /// The device is capabile of running at 66 MHz rather than 33 MHz. 203 const MHZ_66_CAPABLE = 1 << 5; 204 // Bit 6 is reserved. 205 /// The device can accept fast back-to-back transactions not from the same agent. 206 const FAST_BACK_TO_BACK_CAPABLE = 1 << 7; 207 /// The bus agent observed a parity error (if parity error handling is enabled). 208 const MASTER_DATA_PARITY_ERROR = 1 << 8; 209 // Bits 9-10 are DEVSEL timing. 210 /// A target device terminated a transaction with target-abort. 211 const SIGNALED_TARGET_ABORT = 1 << 11; 212 /// A master device transaction was terminated with target-abort. 213 const RECEIVED_TARGET_ABORT = 1 << 12; 214 /// A master device transaction was terminated with master-abort. 215 const RECEIVED_MASTER_ABORT = 1 << 13; 216 /// A device asserts SERR#. 217 const SIGNALED_SYSTEM_ERROR = 1 << 14; 218 /// The device detects a parity error, even if parity error handling is disabled. 219 const DETECTED_PARITY_ERROR = 1 << 15; 220 } 221 } 222 223 bitflags! { 224 /// The command register in PCI configuration space. 225 pub struct Command: u16 { 226 /// The device can respond to I/O Space accesses. 227 const IO_SPACE = 1 << 0; 228 /// The device can respond to Memory Space accesses. 229 const MEMORY_SPACE = 1 << 1; 230 /// The device can behave as a bus master. 231 const BUS_MASTER = 1 << 2; 232 /// The device can monitor Special Cycle operations. 233 const SPECIAL_CYCLES = 1 << 3; 234 /// The device can generate the Memory Write and Invalidate command. 235 const MEMORY_WRITE_AND_INVALIDATE_ENABLE = 1 << 4; 236 /// The device will snoop palette register data. 237 const VGA_PALETTE_SNOOP = 1 << 5; 238 /// The device should take its normal action when a parity error is detected. 239 const PARITY_ERROR_RESPONSE = 1 << 6; 240 // Bit 7 is reserved. 241 /// The SERR# driver is enabled. 242 const SERR_ENABLE = 1 << 8; 243 /// The device is allowed to generate fast back-to-back transactions. 244 const FAST_BACK_TO_BACK_ENABLE = 1 << 9; 245 /// Assertion of the device's INTx# signal is disabled. 246 const INTERRUPT_DISABLE = 1 << 10; 247 } 248 } 249 250 /// The type of a PCI device function header. 251 /// 标头类型/设备类型 252 #[derive(Copy, Clone, Debug, Eq, PartialEq)] 253 pub enum HeaderType { 254 /// A normal PCI device. 255 Standard, 256 /// A PCI to PCI bridge. 257 PciPciBridge, 258 /// A PCI to CardBus bridge. 259 PciCardbusBridge, 260 /// Unrecognised header type. 261 Unrecognised(u8), 262 } 263 /// u8到HeaderType的转换 264 impl From<u8> for HeaderType { 265 fn from(value: u8) -> Self { 266 match value { 267 0x00 => Self::Standard, 268 0x01 => Self::PciPciBridge, 269 0x02 => Self::PciCardbusBridge, 270 _ => Self::Unrecognised(value), 271 } 272 } 273 } 274 /// Pci可能触发的各种错误 275 #[derive(Copy, Clone, Debug, Eq, PartialEq)] 276 pub enum PciError { 277 /// The device reported an invalid BAR type. 278 InvalidBarType, 279 CreateMmioError, 280 InvalidBusDeviceFunction, 281 SegmentNotFound, 282 McfgTableNotFound, 283 GetWrongHeader, 284 UnrecognisedHeaderType, 285 PciDeviceStructureTransformError, 286 PciIrqError(PciIrqError), 287 } 288 ///实现PciError的Display trait,使其可以直接输出 289 impl Display for PciError { 290 fn fmt(&self, f: &mut Formatter) -> fmt::Result { 291 match self { 292 Self::InvalidBarType => write!(f, "Invalid PCI BAR type."), 293 Self::CreateMmioError => write!(f, "Error occurred while creating mmio."), 294 Self::InvalidBusDeviceFunction => write!(f, "Found invalid BusDeviceFunction."), 295 Self::SegmentNotFound => write!(f, "Target segment not found"), 296 Self::McfgTableNotFound => write!(f, "ACPI MCFG Table not found"), 297 Self::GetWrongHeader => write!(f, "GetWrongHeader with vendor id 0xffff"), 298 Self::UnrecognisedHeaderType => write!(f, "Found device with unrecognised header type"), 299 Self::PciDeviceStructureTransformError => { 300 write!(f, "Found None When transform Pci device structure") 301 } 302 Self::PciIrqError(err) => write!(f, "Error occurred while setting irq :{:?}.", err), 303 } 304 } 305 } 306 307 /// trait类型Pci_Device_Structure表示pci设备,动态绑定三种具体设备类型:Pci_Device_Structure_General_Device、Pci_Device_Structure_Pci_to_Pci_Bridge、Pci_Device_Structure_Pci_to_Cardbus_Bridge 308 pub trait PciDeviceStructure: Send + Sync { 309 /// @brief 获取设备类型 310 /// @return HeaderType 设备类型 311 fn header_type(&self) -> HeaderType; 312 /// @brief 当其为standard设备时返回&Pci_Device_Structure_General_Device,其余情况返回None 313 #[inline(always)] 314 fn as_standard_device(&self) -> Option<&PciDeviceStructureGeneralDevice> { 315 None 316 } 317 /// @brief 当其为pci to pci bridge设备时返回&Pci_Device_Structure_Pci_to_Pci_Bridge,其余情况返回None 318 #[inline(always)] 319 fn as_pci_to_pci_bridge_device(&self) -> Option<&PciDeviceStructurePciToPciBridge> { 320 None 321 } 322 /// @brief 当其为pci to cardbus bridge设备时返回&Pci_Device_Structure_Pci_to_Cardbus_Bridge,其余情况返回None 323 #[inline(always)] 324 fn as_pci_to_carbus_bridge_device(&self) -> Option<&PciDeviceStructurePciToCardbusBridge> { 325 None 326 } 327 /// @brief 获取Pci设备共有的common_header 328 /// @return 返回其不可变引用 329 fn common_header(&self) -> &PciDeviceStructureHeader; 330 /// @brief 当其为standard设备时返回&mut Pci_Device_Structure_General_Device,其余情况返回None 331 #[inline(always)] 332 fn as_standard_device_mut(&mut self) -> Option<&mut PciDeviceStructureGeneralDevice> { 333 None 334 } 335 /// @brief 当其为pci to pci bridge设备时返回&mut Pci_Device_Structure_Pci_to_Pci_Bridge,其余情况返回None 336 #[inline(always)] 337 fn as_pci_to_pci_bridge_device_mut(&mut self) -> Option<&mut PciDeviceStructurePciToPciBridge> { 338 None 339 } 340 /// @brief 当其为pci to cardbus bridge设备时返回&mut Pci_Device_Structure_Pci_to_Cardbus_Bridge,其余情况返回None 341 #[inline(always)] 342 fn as_pci_to_carbus_bridge_device_mut( 343 &mut self, 344 ) -> Option<&mut PciDeviceStructurePciToCardbusBridge> { 345 None 346 } 347 /// @brief 返回迭代器,遍历capabilities 348 fn capabilities(&self) -> Option<CapabilityIterator> { 349 None 350 } 351 /// @brief 获取Status、Command寄存器的值 352 fn status_command(&self) -> (Status, Command) { 353 let common_header = self.common_header(); 354 let status = Status::from_bits_truncate(common_header.status); 355 let command = Command::from_bits_truncate(common_header.command); 356 (status, command) 357 } 358 /// @brief 设置Command寄存器的值 359 fn set_command(&mut self, command: Command) { 360 let common_header = self.common_header_mut(); 361 let command = command.bits(); 362 common_header.command = command; 363 pci_root_0().write_config( 364 common_header.bus_device_function, 365 STATUS_COMMAND_OFFSET.into(), 366 command as u32, 367 ); 368 } 369 /// @brief 获取Pci设备共有的common_header 370 /// @return 返回其可变引用 371 fn common_header_mut(&mut self) -> &mut PciDeviceStructureHeader; 372 373 /// @brief 读取standard设备的bar寄存器,映射后将结果加入结构体的standard_device_bar变量 374 /// @return 只有standard设备才返回成功或者错误,其余返回None 375 #[inline(always)] 376 fn bar_ioremap(&mut self) -> Option<Result<u8, PciError>> { 377 None 378 } 379 /// @brief 获取PCI设备的bar寄存器的引用 380 /// @return 381 #[inline(always)] 382 fn bar(&mut self) -> Option<&PciStandardDeviceBar> { 383 None 384 } 385 /// @brief 通过设置该pci设备的command 386 fn enable_master(&mut self) { 387 self.set_command(Command::IO_SPACE | Command::MEMORY_SPACE | Command::BUS_MASTER); 388 } 389 /// @brief 寻找设备的msix空间的offset 390 fn msix_capability_offset(&self) -> Option<u8> { 391 for capability in self.capabilities()? { 392 if capability.id == PCI_CAP_ID_MSIX { 393 return Some(capability.offset); 394 } 395 } 396 None 397 } 398 /// @brief 寻找设备的msi空间的offset 399 fn msi_capability_offset(&self) -> Option<u8> { 400 for capability in self.capabilities()? { 401 if capability.id == PCI_CAP_ID_MSI { 402 return Some(capability.offset); 403 } 404 } 405 None 406 } 407 /// @brief 返回结构体中的irq_type的可变引用 408 fn irq_type_mut(&mut self) -> Option<&mut IrqType>; 409 /// @brief 返回结构体中的irq_vector的可变引用 410 fn irq_vector_mut(&mut self) -> Option<&mut Vec<IrqNumber>>; 411 } 412 413 /// Pci_Device_Structure_Header PCI设备结构体共有的头部 414 #[derive(Clone, Debug)] 415 pub struct PciDeviceStructureHeader { 416 // ==== busdevicefunction变量表示该结构体所处的位置 417 pub bus_device_function: BusDeviceFunction, 418 pub vendor_id: u16, // 供应商ID 0xffff是一个无效值,在读取访问不存在的设备的配置空间寄存器时返回 419 pub device_id: u16, // 设备ID,标志特定设备 420 pub command: u16, // 提供对设备生成和响应pci周期的能力的控制 向该寄存器写入0时,设备与pci总线断开除配置空间访问以外的所有连接 421 pub status: u16, // 用于记录pci总线相关时间的状态信息寄存器 422 pub revision_id: u8, // 修订ID,指定特定设备的修订标志符 423 pub prog_if: u8, // 编程接口字节,一个只读寄存器,指定设备具有的寄存器级别的编程接口(如果有的话) 424 pub subclass: u8, // 子类。指定设备执行的特定功能的只读寄存器 425 pub class_code: u8, // 类代码,一个只读寄存器,指定设备执行的功能类型 426 pub cache_line_size: u8, // 缓存线大小:以 32 位为单位指定系统缓存线大小。设备可以限制它可以支持的缓存线大小的数量,如果不支持的值写入该字段,设备将表现得好像写入了 0 值 427 pub latency_timer: u8, // 延迟计时器:以 PCI 总线时钟为单位指定延迟计时器。 428 pub header_type: u8, // 标头类型 a value of 0x0 specifies a general device, a value of 0x1 specifies a PCI-to-PCI bridge, and a value of 0x2 specifies a CardBus bridge. If bit 7 of this register is set, the device has multiple functions; otherwise, it is a single function device. 429 pub bist: u8, // Represents that status and allows control of a devices BIST (built-in self test). 430 // Here is the layout of the BIST register: 431 // | bit7 | bit6 | Bits 5-4 | Bits 3-0 | 432 // | BIST Capable | Start BIST | Reserved | Completion Code | 433 // for more details, please visit https://wiki.osdev.org/PCI 434 } 435 436 /// Pci_Device_Structure_General_Device PCI标准设备结构体 437 #[derive(Clone, Debug)] 438 pub struct PciDeviceStructureGeneralDevice { 439 pub common_header: PciDeviceStructureHeader, 440 // 中断结构体,包括legacy,msi,msix三种情况 441 pub irq_type: IrqType, 442 // 使用的中断号的vec集合 443 pub irq_vector: Vec<IrqNumber>, 444 pub standard_device_bar: PciStandardDeviceBar, 445 pub cardbus_cis_pointer: u32, // 指向卡信息结构,供在 CardBus 和 PCI 之间共享芯片的设备使用。 446 pub subsystem_vendor_id: u16, 447 pub subsystem_id: u16, 448 pub expansion_rom_base_address: u32, 449 pub capabilities_pointer: u8, 450 pub reserved0: u8, 451 pub reserved1: u16, 452 pub reserved2: u32, 453 pub interrupt_line: u8, // 指定设备的中断引脚连接到系统中断控制器的哪个输入,并由任何使用中断引脚的设备实现。对于 x86 架构,此寄存器对应于 PIC IRQ 编号 0-15(而不是 I/O APIC IRQ 编号),并且值0xFF定义为无连接。 454 pub interrupt_pin: u8, // 指定设备使用的中断引脚。其中值为0x1INTA#、0x2INTB#、0x3INTC#、0x4INTD#,0x0表示设备不使用中断引脚。 455 pub min_grant: u8, // 一个只读寄存器,用于指定设备所需的突发周期长度(以 1/4 微秒为单位)(假设时钟速率为 33 MHz) 456 pub max_latency: u8, // 一个只读寄存器,指定设备需要多长时间访问一次 PCI 总线(以 1/4 微秒为单位)。 457 } 458 impl PciDeviceStructure for PciDeviceStructureGeneralDevice { 459 #[inline(always)] 460 fn header_type(&self) -> HeaderType { 461 HeaderType::Standard 462 } 463 #[inline(always)] 464 fn as_standard_device(&self) -> Option<&PciDeviceStructureGeneralDevice> { 465 Some(self) 466 } 467 #[inline(always)] 468 fn as_standard_device_mut(&mut self) -> Option<&mut PciDeviceStructureGeneralDevice> { 469 Some(self) 470 } 471 #[inline(always)] 472 fn common_header(&self) -> &PciDeviceStructureHeader { 473 &self.common_header 474 } 475 #[inline(always)] 476 fn common_header_mut(&mut self) -> &mut PciDeviceStructureHeader { 477 &mut self.common_header 478 } 479 fn capabilities(&self) -> Option<CapabilityIterator> { 480 Some(CapabilityIterator { 481 bus_device_function: self.common_header.bus_device_function, 482 next_capability_offset: Some(self.capabilities_pointer), 483 }) 484 } 485 fn bar_ioremap(&mut self) -> Option<Result<u8, PciError>> { 486 let common_header = &self.common_header; 487 match pci_bar_init(common_header.bus_device_function) { 488 Ok(bar) => { 489 self.standard_device_bar = bar; 490 Some(Ok(0)) 491 } 492 Err(e) => Some(Err(e)), 493 } 494 } 495 fn bar(&mut self) -> Option<&PciStandardDeviceBar> { 496 Some(&self.standard_device_bar) 497 } 498 #[inline(always)] 499 fn irq_type_mut(&mut self) -> Option<&mut IrqType> { 500 Some(&mut self.irq_type) 501 } 502 #[inline(always)] 503 fn irq_vector_mut(&mut self) -> Option<&mut Vec<IrqNumber>> { 504 Some(&mut self.irq_vector) 505 } 506 } 507 508 /// Pci_Device_Structure_Pci_to_Pci_Bridge pci-to-pci桥设备结构体 509 #[derive(Clone, Debug)] 510 pub struct PciDeviceStructurePciToPciBridge { 511 pub common_header: PciDeviceStructureHeader, 512 // 中断结构体,包括legacy,msi,msix三种情况 513 pub irq_type: IrqType, 514 // 使用的中断号的vec集合 515 pub irq_vector: Vec<IrqNumber>, 516 pub bar0: u32, 517 pub bar1: u32, 518 pub primary_bus_number: u8, 519 pub secondary_bus_number: u8, 520 pub subordinate_bus_number: u8, 521 pub secondary_latency_timer: u8, 522 pub io_base: u8, 523 pub io_limit: u8, 524 pub secondary_status: u16, 525 pub memory_base: u16, 526 pub memory_limit: u16, 527 pub prefetchable_memory_base: u16, 528 pub prefetchable_memory_limit: u16, 529 pub prefetchable_base_upper_32_bits: u32, 530 pub prefetchable_limit_upper_32_bits: u32, 531 pub io_base_upper_16_bits: u16, 532 pub io_limit_upper_16_bits: u16, 533 pub capability_pointer: u8, 534 pub reserved0: u8, 535 pub reserved1: u16, 536 pub expansion_rom_base_address: u32, 537 pub interrupt_line: u8, 538 pub interrupt_pin: u8, 539 pub bridge_control: u16, 540 } 541 impl PciDeviceStructure for PciDeviceStructurePciToPciBridge { 542 #[inline(always)] 543 fn header_type(&self) -> HeaderType { 544 HeaderType::PciPciBridge 545 } 546 #[inline(always)] 547 fn as_pci_to_pci_bridge_device(&self) -> Option<&PciDeviceStructurePciToPciBridge> { 548 Some(self) 549 } 550 #[inline(always)] 551 fn as_pci_to_pci_bridge_device_mut(&mut self) -> Option<&mut PciDeviceStructurePciToPciBridge> { 552 Some(self) 553 } 554 #[inline(always)] 555 fn common_header(&self) -> &PciDeviceStructureHeader { 556 &self.common_header 557 } 558 #[inline(always)] 559 fn common_header_mut(&mut self) -> &mut PciDeviceStructureHeader { 560 &mut self.common_header 561 } 562 #[inline(always)] 563 fn irq_type_mut(&mut self) -> Option<&mut IrqType> { 564 Some(&mut self.irq_type) 565 } 566 #[inline(always)] 567 fn irq_vector_mut(&mut self) -> Option<&mut Vec<IrqNumber>> { 568 Some(&mut self.irq_vector) 569 } 570 } 571 /// Pci_Device_Structure_Pci_to_Cardbus_Bridge Pci_to_Cardbus桥设备结构体 572 #[derive(Clone, Debug)] 573 pub struct PciDeviceStructurePciToCardbusBridge { 574 pub common_header: PciDeviceStructureHeader, 575 pub cardbus_socket_ex_ca_base_address: u32, 576 pub offset_of_capabilities_list: u8, 577 pub reserved: u8, 578 pub secondary_status: u16, 579 pub pci_bus_number: u8, 580 pub card_bus_bus_number: u8, 581 pub subordinate_bus_number: u8, 582 pub card_bus_latency_timer: u8, 583 pub memory_base_address0: u32, 584 pub memory_limit0: u32, 585 pub memory_base_address1: u32, 586 pub memory_limit1: u32, 587 pub io_base_address0: u32, 588 pub io_limit0: u32, 589 pub io_base_address1: u32, 590 pub io_limit1: u32, 591 pub interrupt_line: u8, 592 pub interrupt_pin: u8, 593 pub bridge_control: u16, 594 pub subsystem_device_id: u16, 595 pub subsystem_vendor_id: u16, 596 pub pc_card_legacy_mode_base_address_16_bit: u32, 597 } 598 impl PciDeviceStructure for PciDeviceStructurePciToCardbusBridge { 599 #[inline(always)] 600 fn header_type(&self) -> HeaderType { 601 HeaderType::PciCardbusBridge 602 } 603 #[inline(always)] 604 fn as_pci_to_carbus_bridge_device(&self) -> Option<&PciDeviceStructurePciToCardbusBridge> { 605 Some(self) 606 } 607 #[inline(always)] 608 fn as_pci_to_carbus_bridge_device_mut( 609 &mut self, 610 ) -> Option<&mut PciDeviceStructurePciToCardbusBridge> { 611 Some(self) 612 } 613 #[inline(always)] 614 fn common_header(&self) -> &PciDeviceStructureHeader { 615 &self.common_header 616 } 617 #[inline(always)] 618 fn common_header_mut(&mut self) -> &mut PciDeviceStructureHeader { 619 &mut self.common_header 620 } 621 #[inline(always)] 622 fn irq_type_mut(&mut self) -> Option<&mut IrqType> { 623 None 624 } 625 #[inline(always)] 626 fn irq_vector_mut(&mut self) -> Option<&mut Vec<IrqNumber>> { 627 None 628 } 629 } 630 631 /// PCI配置空间访问机制 632 /// 633 /// 用于访问PCI设备的功能配置空间的一组机制。 634 #[derive(Copy, Clone, Debug, Eq, PartialEq)] 635 pub enum PciCam { 636 /// PCI内存映射配置访问机制 637 /// 638 /// 为每个设备功能提供256字节的配置空间访问。 639 MmioCam, 640 /// PCIe内存映射增强配置访问机制 641 /// 642 /// 为每个设备功能提供4千字节(4096字节)的配置空间访问。 643 Ecam, 644 } 645 646 impl PciCam { 647 /// Returns the total size in bytes of the memory-mapped region. 648 pub const fn size(self) -> u32 { 649 match self { 650 Self::MmioCam => 0x1000000, 651 Self::Ecam => 0x10000000, 652 } 653 } 654 } 655 656 /// Gets the capabilities 'pointer' for the device function, if any. 657 /// @brief 获取第一个capability 的offset 658 /// @param bus_device_function PCI设备的唯一标识 659 /// @return Option<u8> offset 660 pub fn capabilities_offset(bus_device_function: BusDeviceFunction) -> Option<u8> { 661 let result = pci_root_0().read_config(bus_device_function, STATUS_COMMAND_OFFSET.into()); 662 let status: Status = Status::from_bits_truncate((result >> 16) as u16); 663 if status.contains(Status::CAPABILITIES_LIST) { 664 let cap_pointer = pci_root_0().read_config(bus_device_function, 0x34) as u8 & 0xFC; 665 Some(cap_pointer) 666 } else { 667 None 668 } 669 } 670 671 /// @brief 读取pci设备头部 672 /// @param bus_device_function PCI设备的唯一标识 673 /// @param add_to_list 是否添加到链表 674 /// @return 返回的header(trait 类型) 675 fn pci_read_header( 676 bus_device_function: BusDeviceFunction, 677 add_to_list: bool, 678 ) -> Result<Box<dyn PciDeviceStructure>, PciError> { 679 // 先读取公共header 680 let result = pci_root_0().read_config(bus_device_function, 0x00); 681 let vendor_id = result as u16; 682 let device_id = (result >> 16) as u16; 683 684 let result = pci_root_0().read_config(bus_device_function, 0x04); 685 let command = result as u16; 686 let status = (result >> 16) as u16; 687 688 let result = pci_root_0().read_config(bus_device_function, 0x08); 689 let revision_id = result as u8; 690 let prog_if = (result >> 8) as u8; 691 let subclass = (result >> 16) as u8; 692 let class_code = (result >> 24) as u8; 693 694 let result = pci_root_0().read_config(bus_device_function, 0x0c); 695 let cache_line_size = result as u8; 696 let latency_timer = (result >> 8) as u8; 697 let header_type = (result >> 16) as u8; 698 let bist = (result >> 24) as u8; 699 if vendor_id == 0xffff { 700 return Err(PciError::GetWrongHeader); 701 } 702 let header = PciDeviceStructureHeader { 703 bus_device_function, 704 vendor_id, 705 device_id, 706 command, 707 status, 708 revision_id, 709 prog_if, 710 subclass, 711 class_code, 712 cache_line_size, 713 latency_timer, 714 header_type, 715 bist, 716 }; 717 match HeaderType::from(header_type & 0x7f) { 718 HeaderType::Standard => { 719 let general_device = pci_read_general_device_header(header, &bus_device_function); 720 let box_general_device = Box::new(general_device); 721 let box_general_device_clone = box_general_device.clone(); 722 if add_to_list { 723 PCI_DEVICE_LINKEDLIST.add(box_general_device); 724 } 725 Ok(box_general_device_clone) 726 } 727 HeaderType::PciPciBridge => { 728 let pci_to_pci_bridge = pci_read_pci_to_pci_bridge_header(header, &bus_device_function); 729 let box_pci_to_pci_bridge = Box::new(pci_to_pci_bridge); 730 let box_pci_to_pci_bridge_clone = box_pci_to_pci_bridge.clone(); 731 if add_to_list { 732 PCI_DEVICE_LINKEDLIST.add(box_pci_to_pci_bridge); 733 } 734 Ok(box_pci_to_pci_bridge_clone) 735 } 736 HeaderType::PciCardbusBridge => { 737 let pci_cardbus_bridge = 738 pci_read_pci_to_cardbus_bridge_header(header, &bus_device_function); 739 let box_pci_cardbus_bridge = Box::new(pci_cardbus_bridge); 740 let box_pci_cardbus_bridge_clone = box_pci_cardbus_bridge.clone(); 741 if add_to_list { 742 PCI_DEVICE_LINKEDLIST.add(box_pci_cardbus_bridge); 743 } 744 Ok(box_pci_cardbus_bridge_clone) 745 } 746 HeaderType::Unrecognised(_) => Err(PciError::UnrecognisedHeaderType), 747 } 748 } 749 750 /// @brief 读取type为0x0的pci设备的header 751 /// 本函数只应被 pci_read_header()调用 752 /// @param common_header 共有头部 753 /// @param bus_device_function PCI设备的唯一标识 754 /// @return Pci_Device_Structure_General_Device 标准设备头部 755 fn pci_read_general_device_header( 756 common_header: PciDeviceStructureHeader, 757 bus_device_function: &BusDeviceFunction, 758 ) -> PciDeviceStructureGeneralDevice { 759 let standard_device_bar = PciStandardDeviceBar::default(); 760 let cardbus_cis_pointer = pci_root_0().read_config(*bus_device_function, 0x28); 761 762 let result = pci_root_0().read_config(*bus_device_function, 0x2c); 763 let subsystem_vendor_id = result as u16; 764 let subsystem_id = (result >> 16) as u16; 765 766 let expansion_rom_base_address = pci_root_0().read_config(*bus_device_function, 0x30); 767 768 let result = pci_root_0().read_config(*bus_device_function, 0x34); 769 let capabilities_pointer = result as u8; 770 let reserved0 = (result >> 8) as u8; 771 let reserved1 = (result >> 16) as u16; 772 773 let reserved2 = pci_root_0().read_config(*bus_device_function, 0x38); 774 775 let result = pci_root_0().read_config(*bus_device_function, 0x3c); 776 let interrupt_line = result as u8; 777 let interrupt_pin = (result >> 8) as u8; 778 let min_grant = (result >> 16) as u8; 779 let max_latency = (result >> 24) as u8; 780 PciDeviceStructureGeneralDevice { 781 common_header, 782 irq_type: IrqType::Unused, 783 irq_vector: Vec::new(), 784 standard_device_bar, 785 cardbus_cis_pointer, 786 subsystem_vendor_id, 787 subsystem_id, 788 expansion_rom_base_address, 789 capabilities_pointer, 790 reserved0, 791 reserved1, 792 reserved2, 793 interrupt_line, 794 interrupt_pin, 795 min_grant, 796 max_latency, 797 } 798 } 799 800 /// @brief 读取type为0x1的pci设备的header 801 /// 本函数只应被 pci_read_header()调用 802 /// @param common_header 共有头部 803 /// @param bus_device_function PCI设备的唯一标识 804 /// @return Pci_Device_Structure_Pci_to_Pci_Bridge pci-to-pci 桥设备头部 805 fn pci_read_pci_to_pci_bridge_header( 806 common_header: PciDeviceStructureHeader, 807 bus_device_function: &BusDeviceFunction, 808 ) -> PciDeviceStructurePciToPciBridge { 809 let bar0 = pci_root_0().read_config(*bus_device_function, 0x10); 810 let bar1 = pci_root_0().read_config(*bus_device_function, 0x14); 811 812 let result = pci_root_0().read_config(*bus_device_function, 0x18); 813 814 let primary_bus_number = result as u8; 815 let secondary_bus_number = (result >> 8) as u8; 816 let subordinate_bus_number = (result >> 16) as u8; 817 let secondary_latency_timer = (result >> 24) as u8; 818 819 let result = pci_root_0().read_config(*bus_device_function, 0x1c); 820 let io_base = result as u8; 821 let io_limit = (result >> 8) as u8; 822 let secondary_status = (result >> 16) as u16; 823 824 let result = pci_root_0().read_config(*bus_device_function, 0x20); 825 let memory_base = result as u16; 826 let memory_limit = (result >> 16) as u16; 827 828 let result = pci_root_0().read_config(*bus_device_function, 0x24); 829 let prefetchable_memory_base = result as u16; 830 let prefetchable_memory_limit = (result >> 16) as u16; 831 832 let prefetchable_base_upper_32_bits = pci_root_0().read_config(*bus_device_function, 0x28); 833 let prefetchable_limit_upper_32_bits = pci_root_0().read_config(*bus_device_function, 0x2c); 834 835 let result = pci_root_0().read_config(*bus_device_function, 0x30); 836 let io_base_upper_16_bits = result as u16; 837 let io_limit_upper_16_bits = (result >> 16) as u16; 838 839 let result = pci_root_0().read_config(*bus_device_function, 0x34); 840 let capability_pointer = result as u8; 841 let reserved0 = (result >> 8) as u8; 842 let reserved1 = (result >> 16) as u16; 843 844 let expansion_rom_base_address = pci_root_0().read_config(*bus_device_function, 0x38); 845 846 let result = pci_root_0().read_config(*bus_device_function, 0x3c); 847 let interrupt_line = result as u8; 848 let interrupt_pin = (result >> 8) as u8; 849 let bridge_control = (result >> 16) as u16; 850 PciDeviceStructurePciToPciBridge { 851 common_header, 852 irq_type: IrqType::Unused, 853 irq_vector: Vec::new(), 854 bar0, 855 bar1, 856 primary_bus_number, 857 secondary_bus_number, 858 subordinate_bus_number, 859 secondary_latency_timer, 860 io_base, 861 io_limit, 862 secondary_status, 863 memory_base, 864 memory_limit, 865 prefetchable_memory_base, 866 prefetchable_memory_limit, 867 prefetchable_base_upper_32_bits, 868 prefetchable_limit_upper_32_bits, 869 io_base_upper_16_bits, 870 io_limit_upper_16_bits, 871 capability_pointer, 872 reserved0, 873 reserved1, 874 expansion_rom_base_address, 875 interrupt_line, 876 interrupt_pin, 877 bridge_control, 878 } 879 } 880 881 /// @brief 读取type为0x2的pci设备的header 882 /// 本函数只应被 pci_read_header()调用 883 /// @param common_header 共有头部 884 /// @param bus_device_function PCI设备的唯一标识 885 /// @return Pci_Device_Structure_Pci_to_Cardbus_Bridge pci-to-cardbus 桥设备头部 886 fn pci_read_pci_to_cardbus_bridge_header( 887 common_header: PciDeviceStructureHeader, 888 busdevicefunction: &BusDeviceFunction, 889 ) -> PciDeviceStructurePciToCardbusBridge { 890 let cardbus_socket_ex_ca_base_address = pci_root_0().read_config(*busdevicefunction, 0x10); 891 892 let result = pci_root_0().read_config(*busdevicefunction, 0x14); 893 let offset_of_capabilities_list = result as u8; 894 let reserved = (result >> 8) as u8; 895 let secondary_status = (result >> 16) as u16; 896 897 let result = pci_root_0().read_config(*busdevicefunction, 0x18); 898 let pci_bus_number = result as u8; 899 let card_bus_bus_number = (result >> 8) as u8; 900 let subordinate_bus_number = (result >> 16) as u8; 901 let card_bus_latency_timer = (result >> 24) as u8; 902 903 let memory_base_address0 = pci_root_0().read_config(*busdevicefunction, 0x1c); 904 let memory_limit0 = pci_root_0().read_config(*busdevicefunction, 0x20); 905 let memory_base_address1 = pci_root_0().read_config(*busdevicefunction, 0x24); 906 let memory_limit1 = pci_root_0().read_config(*busdevicefunction, 0x28); 907 908 let io_base_address0 = pci_root_0().read_config(*busdevicefunction, 0x2c); 909 let io_limit0 = pci_root_0().read_config(*busdevicefunction, 0x30); 910 let io_base_address1 = pci_root_0().read_config(*busdevicefunction, 0x34); 911 let io_limit1 = pci_root_0().read_config(*busdevicefunction, 0x38); 912 let result = pci_root_0().read_config(*busdevicefunction, 0x3c); 913 let interrupt_line = result as u8; 914 let interrupt_pin = (result >> 8) as u8; 915 let bridge_control = (result >> 16) as u16; 916 917 let result = pci_root_0().read_config(*busdevicefunction, 0x40); 918 let subsystem_device_id = result as u16; 919 let subsystem_vendor_id = (result >> 16) as u16; 920 921 let pc_card_legacy_mode_base_address_16_bit = 922 pci_root_0().read_config(*busdevicefunction, 0x44); 923 PciDeviceStructurePciToCardbusBridge { 924 common_header, 925 cardbus_socket_ex_ca_base_address, 926 offset_of_capabilities_list, 927 reserved, 928 secondary_status, 929 pci_bus_number, 930 card_bus_bus_number, 931 subordinate_bus_number, 932 card_bus_latency_timer, 933 memory_base_address0, 934 memory_limit0, 935 memory_base_address1, 936 memory_limit1, 937 io_base_address0, 938 io_limit0, 939 io_base_address1, 940 io_limit1, 941 interrupt_line, 942 interrupt_pin, 943 bridge_control, 944 subsystem_device_id, 945 subsystem_vendor_id, 946 pc_card_legacy_mode_base_address_16_bit, 947 } 948 } 949 950 /// @brief 检查所有bus上的设备并将其加入链表 951 /// @return 成功返回ok(),失败返回失败原因 952 fn pci_check_all_buses() -> Result<u8, PciError> { 953 kinfo!("Checking all devices in PCI bus..."); 954 let busdevicefunction = BusDeviceFunction { 955 bus: 0, 956 device: 0, 957 function: 0, 958 }; 959 let header = pci_read_header(busdevicefunction, false)?; 960 let common_header = header.common_header(); 961 pci_check_bus(0)?; 962 if common_header.header_type & 0x80 != 0 { 963 for function in 1..8 { 964 pci_check_bus(function)?; 965 } 966 } 967 Ok(0) 968 } 969 /// @brief 检查特定设备并将其加入链表 970 /// @return 成功返回ok(),失败返回失败原因 971 fn pci_check_function(busdevicefunction: BusDeviceFunction) -> Result<u8, PciError> { 972 //kdebug!("PCI check function {}", busdevicefunction.function); 973 let header = match pci_read_header(busdevicefunction, true) { 974 Ok(header) => header, 975 Err(PciError::GetWrongHeader) => { 976 return Ok(255); 977 } 978 Err(e) => { 979 return Err(e); 980 } 981 }; 982 let common_header = header.common_header(); 983 if (common_header.class_code == 0x06) 984 && (common_header.subclass == 0x04 || common_header.subclass == 0x09) 985 { 986 let pci_to_pci_bridge = header 987 .as_pci_to_pci_bridge_device() 988 .ok_or(PciError::PciDeviceStructureTransformError)?; 989 let secondary_bus = pci_to_pci_bridge.secondary_bus_number; 990 pci_check_bus(secondary_bus)?; 991 } 992 Ok(0) 993 } 994 995 /// @brief 检查device上的设备并将其加入链表 996 /// @return 成功返回ok(),失败返回失败原因 997 fn pci_check_device(bus: u8, device: u8) -> Result<u8, PciError> { 998 //kdebug!("PCI check device {}", device); 999 let busdevicefunction = BusDeviceFunction { 1000 bus, 1001 device, 1002 function: 0, 1003 }; 1004 let header = match pci_read_header(busdevicefunction, false) { 1005 Ok(header) => header, 1006 Err(PciError::GetWrongHeader) => { 1007 //设备不存在,直接返回即可,不用终止遍历 1008 return Ok(255); 1009 } 1010 Err(e) => { 1011 return Err(e); 1012 } 1013 }; 1014 pci_check_function(busdevicefunction)?; 1015 let common_header = header.common_header(); 1016 if common_header.header_type & 0x80 != 0 { 1017 kdebug!( 1018 "Detected multi func device in bus{},device{}", 1019 busdevicefunction.bus, 1020 busdevicefunction.device 1021 ); 1022 // 这是一个多function的设备,因此查询剩余的function 1023 for function in 1..8 { 1024 let busdevicefunction = BusDeviceFunction { 1025 bus, 1026 device, 1027 function, 1028 }; 1029 pci_check_function(busdevicefunction)?; 1030 } 1031 } 1032 Ok(0) 1033 } 1034 /// @brief 检查该bus上的设备并将其加入链表 1035 /// @return 成功返回ok(),失败返回失败原因 1036 fn pci_check_bus(bus: u8) -> Result<u8, PciError> { 1037 //kdebug!("PCI check bus {}", bus); 1038 for device in 0..32 { 1039 pci_check_device(bus, device)?; 1040 } 1041 Ok(0) 1042 } 1043 1044 /// pci初始化函数 1045 #[inline(never)] 1046 pub fn pci_init() { 1047 kinfo!("Initializing PCI bus..."); 1048 if let Err(e) = pci_check_all_buses() { 1049 kerror!("pci init failed when checking bus because of error: {}", e); 1050 return; 1051 } 1052 kinfo!( 1053 "Total pci device and function num = {}", 1054 PCI_DEVICE_LINKEDLIST.num() 1055 ); 1056 let list = PCI_DEVICE_LINKEDLIST.read(); 1057 for box_pci_device in list.iter() { 1058 let common_header = box_pci_device.common_header(); 1059 match box_pci_device.header_type() { 1060 HeaderType::Standard if common_header.status & 0x10 != 0 => { 1061 kinfo!("Found pci standard device with class code ={} subclass={} status={:#x} cap_pointer={:#x} vendor={:#x}, device id={:#x},bdf={}", common_header.class_code, common_header.subclass, common_header.status, box_pci_device.as_standard_device().unwrap().capabilities_pointer,common_header.vendor_id, common_header.device_id,common_header.bus_device_function); 1062 } 1063 HeaderType::Standard => { 1064 kinfo!( 1065 "Found pci standard device with class code ={} subclass={} status={:#x} ", 1066 common_header.class_code, 1067 common_header.subclass, 1068 common_header.status 1069 ); 1070 } 1071 HeaderType::PciPciBridge if common_header.status & 0x10 != 0 => { 1072 kinfo!("Found pci-to-pci bridge device with class code ={} subclass={} status={:#x} cap_pointer={:#x}", common_header.class_code, common_header.subclass, common_header.status, box_pci_device.as_pci_to_pci_bridge_device().unwrap().capability_pointer); 1073 } 1074 HeaderType::PciPciBridge => { 1075 kinfo!( 1076 "Found pci-to-pci bridge device with class code ={} subclass={} status={:#x} ", 1077 common_header.class_code, 1078 common_header.subclass, 1079 common_header.status 1080 ); 1081 } 1082 HeaderType::PciCardbusBridge => { 1083 kinfo!( 1084 "Found pcicardbus bridge device with class code ={} subclass={} status={:#x} ", 1085 common_header.class_code, 1086 common_header.subclass, 1087 common_header.status 1088 ); 1089 } 1090 HeaderType::Unrecognised(_) => {} 1091 } 1092 } 1093 kinfo!("PCI bus initialized."); 1094 } 1095 1096 /// An identifier for a PCI bus, device and function. 1097 /// PCI设备的唯一标识 1098 #[derive(Copy, Clone, Debug, Eq, PartialEq)] 1099 pub struct BusDeviceFunction { 1100 /// The PCI bus number, between 0 and 255. 1101 pub bus: u8, 1102 /// The device number on the bus, between 0 and 31. 1103 pub device: u8, 1104 /// The function number of the device, between 0 and 7. 1105 pub function: u8, 1106 } 1107 impl BusDeviceFunction { 1108 /// Returns whether the device and function numbers are valid, i.e. the device is between 0 and 1109 ///@brief 检测BusDeviceFunction实例是否有效 1110 ///@param self 1111 ///@return bool 是否有效 1112 #[allow(dead_code)] 1113 pub fn valid(&self) -> bool { 1114 self.device < 32 && self.function < 8 1115 } 1116 } 1117 ///实现BusDeviceFunction的Display trait,使其可以直接输出 1118 impl Display for BusDeviceFunction { 1119 fn fmt(&self, f: &mut Formatter) -> fmt::Result { 1120 write!( 1121 f, 1122 "bus {} device {} function{}", 1123 self.bus, self.device, self.function 1124 ) 1125 } 1126 } 1127 /// The location allowed for a memory BAR. 1128 /// memory BAR的三种情况 1129 #[derive(Copy, Clone, Debug, Eq, PartialEq)] 1130 pub enum MemoryBarType { 1131 /// The BAR has a 32-bit address and can be mapped anywhere in 32-bit address space. 1132 Width32, 1133 /// The BAR must be mapped below 1MiB. 1134 Below1MiB, 1135 /// The BAR has a 64-bit address and can be mapped anywhere in 64-bit address space. 1136 Width64, 1137 } 1138 ///实现MemoryBarType与u8的类型转换 1139 impl From<MemoryBarType> for u8 { 1140 fn from(bar_type: MemoryBarType) -> Self { 1141 match bar_type { 1142 MemoryBarType::Width32 => 0, 1143 MemoryBarType::Below1MiB => 1, 1144 MemoryBarType::Width64 => 2, 1145 } 1146 } 1147 } 1148 ///实现MemoryBarType与u8的类型转换 1149 impl TryFrom<u8> for MemoryBarType { 1150 type Error = PciError; 1151 fn try_from(value: u8) -> Result<Self, Self::Error> { 1152 match value { 1153 0 => Ok(Self::Width32), 1154 1 => Ok(Self::Below1MiB), 1155 2 => Ok(Self::Width64), 1156 _ => Err(PciError::InvalidBarType), 1157 } 1158 } 1159 } 1160 1161 /// Information about a PCI Base Address Register. 1162 /// BAR的三种类型 Memory/IO/Unused 1163 #[derive(Clone, Debug)] 1164 pub enum BarInfo { 1165 /// The BAR is for a memory region. 1166 Memory { 1167 /// The size of the BAR address and where it can be located. 1168 address_type: MemoryBarType, 1169 /// If true, then reading from the region doesn't have side effects. The CPU may cache reads 1170 /// and merge repeated stores. 1171 prefetchable: bool, 1172 /// The memory address, always 16-byte aligned. 1173 address: u64, 1174 /// The size of the BAR in bytes. 1175 size: u32, 1176 /// The virtaddress for a memory bar(mapped). 1177 mmio_guard: Arc<MMIOSpaceGuard>, 1178 }, 1179 /// The BAR is for an I/O region. 1180 IO { 1181 /// The I/O address, always 4-byte aligned. 1182 address: u32, 1183 /// The size of the BAR in bytes. 1184 size: u32, 1185 }, 1186 Unused, 1187 } 1188 1189 impl BarInfo { 1190 /// Returns the address and size of this BAR if it is a memory bar, or `None` if it is an IO 1191 /// BAR. 1192 ///@brief 得到某个bar的memory_address与size(前提是他的类型为Memory Bar) 1193 ///@param self 1194 ///@return Option<(u64, u32) 是Memory Bar返回内存地址与大小,不是则返回None 1195 pub fn memory_address_size(&self) -> Option<(u64, u32)> { 1196 if let Self::Memory { address, size, .. } = self { 1197 Some((*address, *size)) 1198 } else { 1199 None 1200 } 1201 } 1202 ///@brief 得到某个bar的virtaddress(前提是他的类型为Memory Bar) 1203 ///@param self 1204 ///@return Option<(u64) 是Memory Bar返回映射的虚拟地址,不是则返回None 1205 pub fn virtual_address(&self) -> Option<VirtAddr> { 1206 if let Self::Memory { mmio_guard, .. } = self { 1207 Some(mmio_guard.vaddr()) 1208 } else { 1209 None 1210 } 1211 } 1212 } 1213 ///实现BarInfo的Display trait,自定义输出 1214 impl Display for BarInfo { 1215 fn fmt(&self, f: &mut Formatter<'_>) -> fmt::Result { 1216 match self { 1217 Self::Memory { 1218 address_type, 1219 prefetchable, 1220 address, 1221 size, 1222 mmio_guard, 1223 } => write!( 1224 f, 1225 "Memory space at {:#010x}, size {}, type {:?}, prefetchable {}, mmio_guard: {:?}", 1226 address, size, address_type, prefetchable, mmio_guard 1227 ), 1228 Self::IO { address, size } => { 1229 write!(f, "I/O space at {:#010x}, size {}", address, size) 1230 } 1231 Self::Unused => { 1232 write!(f, "Unused bar") 1233 } 1234 } 1235 } 1236 } 1237 // todo 增加对桥的bar的支持 1238 pub trait PciDeviceBar {} 1239 1240 ///一个普通PCI设备(非桥)有6个BAR寄存器,PciStandardDeviceBar存储其全部信息 1241 #[derive(Clone, Debug)] 1242 pub struct PciStandardDeviceBar { 1243 bar0: BarInfo, 1244 bar1: BarInfo, 1245 bar2: BarInfo, 1246 bar3: BarInfo, 1247 bar4: BarInfo, 1248 bar5: BarInfo, 1249 } 1250 1251 impl PciStandardDeviceBar { 1252 ///@brief 得到某个bar的barinfo 1253 ///@param self ,bar_index(0-5) 1254 ///@return Result<&BarInfo, PciError> bar_index在0-5则返回对应的bar_info结构体,超出范围则返回错误 1255 pub fn get_bar(&self, bar_index: u8) -> Result<&BarInfo, PciError> { 1256 match bar_index { 1257 0 => Ok(&self.bar0), 1258 1 => Ok(&self.bar1), 1259 2 => Ok(&self.bar2), 1260 3 => Ok(&self.bar3), 1261 4 => Ok(&self.bar4), 1262 5 => Ok(&self.bar5), 1263 _ => Err(PciError::InvalidBarType), 1264 } 1265 } 1266 } 1267 ///实现PciStandardDeviceBar的Display trait,使其可以直接输出 1268 impl Display for PciStandardDeviceBar { 1269 fn fmt(&self, f: &mut Formatter<'_>) -> fmt::Result { 1270 write!( 1271 f, 1272 "\r\nBar0:{}\r\nBar1:{}\r\nBar2:{}\r\nBar3:{}\r\nBar4:{}\r\nBar5:{}", 1273 self.bar0, self.bar1, self.bar2, self.bar3, self.bar4, self.bar5 1274 ) 1275 } 1276 } 1277 ///实现PciStandardDeviceBar的Default trait,使其可以简单初始化 1278 impl Default for PciStandardDeviceBar { 1279 fn default() -> Self { 1280 PciStandardDeviceBar { 1281 bar0: BarInfo::Unused, 1282 bar1: BarInfo::Unused, 1283 bar2: BarInfo::Unused, 1284 bar3: BarInfo::Unused, 1285 bar4: BarInfo::Unused, 1286 bar5: BarInfo::Unused, 1287 } 1288 } 1289 } 1290 1291 ///@brief 将某个pci设备的bar寄存器读取值后映射到虚拟地址 1292 ///@param self ,bus_device_function PCI设备的唯一标识符 1293 ///@return Result<PciStandardDeviceBar, PciError> 成功则返回对应的PciStandardDeviceBar结构体,失败则返回错误类型 1294 pub fn pci_bar_init( 1295 bus_device_function: BusDeviceFunction, 1296 ) -> Result<PciStandardDeviceBar, PciError> { 1297 let mut device_bar: PciStandardDeviceBar = PciStandardDeviceBar::default(); 1298 let mut bar_index_ignore: u8 = 255; 1299 for bar_index in 0..6 { 1300 if bar_index == bar_index_ignore { 1301 continue; 1302 } 1303 let bar_info; 1304 let bar_orig = 1305 pci_root_0().read_config(bus_device_function, (BAR0_OFFSET + 4 * bar_index).into()); 1306 pci_root_0().write_config( 1307 bus_device_function, 1308 (BAR0_OFFSET + 4 * bar_index).into(), 1309 0xffffffff, 1310 ); 1311 let size_mask = 1312 pci_root_0().read_config(bus_device_function, (BAR0_OFFSET + 4 * bar_index).into()); 1313 // A wrapping add is necessary to correctly handle the case of unused BARs, which read back 1314 // as 0, and should be treated as size 0. 1315 let size = (!(size_mask & 0xfffffff0)).wrapping_add(1); 1316 //kdebug!("bar_orig:{:#x},size: {:#x}", bar_orig,size); 1317 // Restore the original value. 1318 pci_root_0().write_config( 1319 bus_device_function, 1320 (BAR0_OFFSET + 4 * bar_index).into(), 1321 bar_orig, 1322 ); 1323 if size == 0 { 1324 continue; 1325 } 1326 if bar_orig & 0x00000001 == 0x00000001 { 1327 // I/O space 1328 let address = bar_orig & 0xfffffffc; 1329 bar_info = BarInfo::IO { address, size }; 1330 } else { 1331 // Memory space 1332 let mut address = u64::from(bar_orig & 0xfffffff0); 1333 let prefetchable = bar_orig & 0x00000008 != 0; 1334 let address_type = MemoryBarType::try_from(((bar_orig & 0x00000006) >> 1) as u8)?; 1335 if address_type == MemoryBarType::Width64 { 1336 if bar_index >= 5 { 1337 return Err(PciError::InvalidBarType); 1338 } 1339 let address_top = pci_root_0().read_config( 1340 bus_device_function, 1341 (BAR0_OFFSET + 4 * (bar_index + 1)).into(), 1342 ); 1343 address |= u64::from(address_top) << 32; 1344 bar_index_ignore = bar_index + 1; //下个bar跳过,因为64位的memory bar覆盖了两个bar 1345 } 1346 let pci_address = PciAddr::new(address as usize); 1347 let paddr = PciArch::address_pci_to_physical(pci_address); //PCI总线域物理地址转换为存储器域物理地址 1348 1349 let space_guard: Arc<MMIOSpaceGuard>; 1350 unsafe { 1351 let size_want = size as usize; 1352 let tmp = mmio_pool() 1353 .create_mmio(size_want) 1354 .map_err(|_| PciError::CreateMmioError)?; 1355 space_guard = Arc::new(tmp); 1356 //kdebug!("Pci bar init: mmio space: {space_guard:?}, paddr={paddr:?}, size_want={size_want}"); 1357 assert!( 1358 space_guard.map_phys(paddr, size_want).is_ok(), 1359 "pci_bar_init: map_phys failed" 1360 ); 1361 } 1362 bar_info = BarInfo::Memory { 1363 address_type, 1364 prefetchable, 1365 address, 1366 size, 1367 mmio_guard: space_guard, 1368 }; 1369 } 1370 match bar_index { 1371 0 => { 1372 device_bar.bar0 = bar_info; 1373 } 1374 1 => { 1375 device_bar.bar1 = bar_info; 1376 } 1377 2 => { 1378 device_bar.bar2 = bar_info; 1379 } 1380 3 => { 1381 device_bar.bar3 = bar_info; 1382 } 1383 4 => { 1384 device_bar.bar4 = bar_info; 1385 } 1386 5 => { 1387 device_bar.bar5 = bar_info; 1388 } 1389 _ => {} 1390 } 1391 } 1392 //kdebug!("pci_device_bar:{}", device_bar); 1393 return Ok(device_bar); 1394 } 1395 1396 /// Information about a PCI device capability. 1397 /// PCI设备的capability的信息 1398 #[derive(Debug, Copy, Clone, Eq, PartialEq)] 1399 pub struct CapabilityInfo { 1400 /// The offset of the capability in the PCI configuration space of the device function. 1401 pub offset: u8, 1402 /// The ID of the capability. 1403 pub id: u8, 1404 /// The third and fourth bytes of the capability, to save reading them again. 1405 pub private_header: u16, 1406 } 1407 1408 /// Iterator over capabilities for a device. 1409 /// 创建迭代器以遍历PCI设备的capability 1410 #[derive(Debug)] 1411 pub struct CapabilityIterator { 1412 pub bus_device_function: BusDeviceFunction, 1413 pub next_capability_offset: Option<u8>, 1414 } 1415 1416 impl Iterator for CapabilityIterator { 1417 type Item = CapabilityInfo; 1418 fn next(&mut self) -> Option<Self::Item> { 1419 let offset = self.next_capability_offset?; 1420 1421 // Read the first 4 bytes of the capability. 1422 let capability_header = pci_root_0().read_config(self.bus_device_function, offset.into()); 1423 let id = capability_header as u8; 1424 let next_offset = (capability_header >> 8) as u8; 1425 let private_header = (capability_header >> 16) as u16; 1426 1427 self.next_capability_offset = if next_offset == 0 { 1428 None 1429 } else if next_offset < 64 || next_offset & 0x3 != 0 { 1430 kwarn!("Invalid next capability offset {:#04x}", next_offset); 1431 None 1432 } else { 1433 Some(next_offset) 1434 }; 1435 1436 Some(CapabilityInfo { 1437 offset, 1438 id, 1439 private_header, 1440 }) 1441 } 1442 } 1443 1444 /// Information about a PCIe device capability. 1445 /// PCIe设备的external capability的信息 1446 #[derive(Debug, Copy, Clone, Eq, PartialEq)] 1447 pub struct ExternalCapabilityInfo { 1448 /// The offset of the capability in the PCI configuration space of the device function. 1449 pub offset: u16, 1450 /// The ID of the capability. 1451 pub id: u16, 1452 /// The third and fourth bytes of the capability, to save reading them again. 1453 pub capability_version: u8, 1454 } 1455 1456 /// Iterator over capabilities for a device. 1457 /// 创建迭代器以遍历PCIe设备的external capability 1458 #[derive(Debug)] 1459 pub struct ExternalCapabilityIterator<'a> { 1460 pub root: &'a PciRoot, 1461 pub bus_device_function: BusDeviceFunction, 1462 pub next_capability_offset: Option<u16>, 1463 } 1464 impl<'a> Iterator for ExternalCapabilityIterator<'a> { 1465 type Item = ExternalCapabilityInfo; 1466 fn next(&mut self) -> Option<Self::Item> { 1467 let offset = self.next_capability_offset?; 1468 1469 // Read the first 4 bytes of the capability. 1470 let capability_header = self.root.read_config(self.bus_device_function, offset); 1471 let id = capability_header as u16; 1472 let next_offset = (capability_header >> 20) as u16; 1473 let capability_version = ((capability_header >> 16) & 0xf) as u8; 1474 1475 self.next_capability_offset = if next_offset == 0 { 1476 None 1477 } else if next_offset < 0x100 || next_offset & 0x3 != 0 { 1478 kwarn!("Invalid next capability offset {:#04x}", next_offset); 1479 None 1480 } else { 1481 Some(next_offset) 1482 }; 1483 1484 Some(ExternalCapabilityInfo { 1485 offset, 1486 id, 1487 capability_version, 1488 }) 1489 } 1490 } 1491