xref: /DragonOS/kernel/src/driver/pci/pci.rs (revision c635d8a9cfe25bc11779f323ef0c7d7a0f597d4a)
1 #![allow(dead_code)]
2 // 目前仅支持单主桥单Segment
3 
4 use super::device::pci_device_manager;
5 use super::pci_irq::{IrqType, PciIrqError};
6 use super::raw_device::PciGeneralDevice;
7 use super::root::{pci_root_0, PciRoot};
8 
9 use crate::arch::{PciArch, TraitPciArch};
10 use crate::driver::pci::subsys::pci_bus_subsys_init;
11 use crate::exception::IrqNumber;
12 use crate::libs::rwlock::{RwLock, RwLockReadGuard, RwLockWriteGuard};
13 
14 use crate::mm::mmio_buddy::{mmio_pool, MMIOSpaceGuard};
15 
16 use crate::mm::VirtAddr;
17 
18 use alloc::string::String;
19 use alloc::sync::Arc;
20 use alloc::vec::Vec;
21 use alloc::{boxed::Box, collections::LinkedList};
22 use bitflags::bitflags;
23 use log::{debug, error, info, warn};
24 
25 use core::{
26     convert::TryFrom,
27     fmt::{self, Debug, Display, Formatter},
28 };
29 // 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
30 lazy_static! {
31     pub static ref PCI_DEVICE_LINKEDLIST: PciDeviceLinkedList = PciDeviceLinkedList::new();
32 }
33 
34 /// PCI域地址
35 #[derive(Clone, Copy, Eq, Ord, PartialEq, PartialOrd)]
36 #[repr(transparent)]
37 pub struct PciAddr(usize);
38 
39 impl PciAddr {
40     #[inline(always)]
41     pub const fn new(address: usize) -> Self {
42         Self(address)
43     }
44 
45     /// @brief 获取PCI域地址的值
46     #[inline(always)]
47     pub fn data(&self) -> usize {
48         self.0
49     }
50 
51     /// @brief 将PCI域地址加上一个偏移量
52     #[inline(always)]
53     pub fn add(self, offset: usize) -> Self {
54         Self(self.0 + offset)
55     }
56 
57     /// @brief 判断PCI域地址是否按照指定要求对齐
58     #[inline(always)]
59     pub fn check_aligned(&self, align: usize) -> bool {
60         return self.0 & (align - 1) == 0;
61     }
62 }
63 impl Debug for PciAddr {
64     fn fmt(&self, f: &mut core::fmt::Formatter<'_>) -> core::fmt::Result {
65         write!(f, "PciAddr({:#x})", self.0)
66     }
67 }
68 
69 /// 添加了读写锁的链表,存储PCI设备结构体
70 pub struct PciDeviceLinkedList {
71     list: RwLock<LinkedList<Box<dyn PciDeviceStructure>>>,
72 }
73 
74 impl PciDeviceLinkedList {
75     /// @brief 初始化结构体
76     fn new() -> Self {
77         PciDeviceLinkedList {
78             list: RwLock::new(LinkedList::new()),
79         }
80     }
81     /// @brief 获取可读的linkedlist(读锁守卫)
82     /// @return RwLockReadGuard<LinkedList<Box<dyn PciDeviceStructure>>>  读锁守卫
83     pub fn read(&self) -> RwLockReadGuard<LinkedList<Box<dyn PciDeviceStructure>>> {
84         self.list.read()
85     }
86     /// @brief 获取可写的linkedlist(写锁守卫)
87     /// @return RwLockWriteGuard<LinkedList<Box<dyn PciDeviceStructure>>>  写锁守卫
88     pub fn write(&self) -> RwLockWriteGuard<LinkedList<Box<dyn PciDeviceStructure>>> {
89         self.list.write()
90     }
91     /// @brief 获取链表中PCI结构体数目
92     /// @return usize 链表中PCI结构体数目
93     pub fn num(&self) -> usize {
94         let list = self.list.read();
95         list.len()
96     }
97     /// @brief 添加Pci设备结构体到链表中
98     pub fn add(&self, device: Box<dyn PciDeviceStructure>) {
99         let mut list = self.list.write();
100         list.push_back(device);
101     }
102 }
103 
104 /// # 获取具有特定供应商ID的PCI设备结构的引用
105 ///
106 /// 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。
107 ///
108 /// ## 参数
109 ///
110 /// - list: 一个可变的PCI设备结构链表,类型为`&'a mut RwLockWriteGuard<'_, LinkedList<Box<dyn PciDeviceStructure>>>`。
111 /// - vendor_id: 要查找的PCI供应商ID,类型为`u16`。
112 ///
113 /// ## 返回值
114 ///
115 /// - 返回匹配的供应商ID的PCI设备结构的引用。
116 pub fn get_pci_device_structures_mut_by_vendor_id<'a>(
117     list: &'a mut RwLockWriteGuard<'_, LinkedList<Box<dyn PciDeviceStructure>>>,
118     vendor_id: u16,
119 ) -> Vec<&'a mut Box<(dyn PciDeviceStructure)>> {
120     let mut result = Vec::new();
121     for box_pci_device_structure in list.iter_mut() {
122         let common_header = (*box_pci_device_structure).common_header();
123         if common_header.vendor_id == vendor_id {
124             result.push(box_pci_device_structure);
125         }
126     }
127     result
128 }
129 
130 /// # 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
131 ///
132 /// 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。
133 /// 对于每一个匹配的设备结构体,函数返回一个可变引用。
134 ///
135 /// ## 参数
136 ///
137 /// - 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。
138 /// - class_code: u8 — PCI设备class code寄存器值,用于分类设备的功能。
139 /// - subclass: u8 — PCI设备subclass寄存器值,与class_code一起确定设备的子类型。
140 ///
141 /// ## 返回值
142 /// - 包含链表中所有满足条件的PCI结构体的可变引用的容器。
143 pub fn get_pci_device_structure_mut<'a>(
144     list: &'a mut RwLockWriteGuard<'_, LinkedList<Box<dyn PciDeviceStructure>>>,
145     class_code: u8,
146     subclass: u8,
147 ) -> Vec<&'a mut Box<(dyn PciDeviceStructure)>> {
148     let mut result = Vec::new();
149     for box_pci_device_structure in list.iter_mut() {
150         let common_header = (*box_pci_device_structure).common_header();
151         if (common_header.class_code == class_code) && (common_header.subclass == subclass) {
152             result.push(box_pci_device_structure);
153         }
154     }
155     result
156 }
157 
158 /// # 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
159 ///
160 /// 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。
161 /// 对于每一个匹配的设备结构体,函数返回一个可变引用。
162 ///
163 /// ## 参数
164 ///
165 /// - 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。
166 /// - class_code: u8 — PCI设备class code寄存器值,用于分类设备的功能。
167 /// - subclass: u8 — PCI设备subclass寄存器值,与class_code一起确定设备的子类型。
168 ///
169 /// ## 返回值
170 /// - 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。
171 #[allow(clippy::borrowed_box)]
172 pub fn get_pci_device_structure<'a>(
173     list: &'a mut RwLockReadGuard<'_, LinkedList<Box<dyn PciDeviceStructure>>>,
174     class_code: u8,
175     subclass: u8,
176 ) -> Vec<&'a Box<(dyn PciDeviceStructure)>> {
177     let mut result = Vec::new();
178     for box_pci_device_structure in list.iter() {
179         let common_header = (*box_pci_device_structure).common_header();
180         if (common_header.class_code == class_code) && (common_header.subclass == subclass) {
181             result.push(box_pci_device_structure);
182         }
183     }
184     result
185 }
186 
187 //Bar0寄存器的offset
188 const BAR0_OFFSET: u8 = 0x10;
189 //Status、Command寄存器的offset
190 const STATUS_COMMAND_OFFSET: u8 = 0x04;
191 /// ID for vendor-specific PCI capabilities.(Virtio Capabilities)
192 pub const PCI_CAP_ID_VNDR: u8 = 0x09;
193 pub const PCI_CAP_ID_MSI: u8 = 0x05;
194 pub const PCI_CAP_ID_MSIX: u8 = 0x11;
195 pub const PORT_PCI_CONFIG_ADDRESS: u16 = 0xcf8;
196 pub const PORT_PCI_CONFIG_DATA: u16 = 0xcfc;
197 // pci设备分组的id
198 pub type SegmentGroupNumber = u16; //理论上最多支持65535个Segment_Group
199 
200 bitflags! {
201     /// The status register in PCI configuration space.
202     pub struct Status: u16 {
203         // Bits 0-2 are reserved.
204         /// The state of the device's INTx# signal.
205         const INTERRUPT_STATUS = 1 << 3;
206         /// The device has a linked list of capabilities.
207         const CAPABILITIES_LIST = 1 << 4;
208         /// The device is capabile of running at 66 MHz rather than 33 MHz.
209         const MHZ_66_CAPABLE = 1 << 5;
210         // Bit 6 is reserved.
211         /// The device can accept fast back-to-back transactions not from the same agent.
212         const FAST_BACK_TO_BACK_CAPABLE = 1 << 7;
213         /// The bus agent observed a parity error (if parity error handling is enabled).
214         const MASTER_DATA_PARITY_ERROR = 1 << 8;
215         // Bits 9-10 are DEVSEL timing.
216         /// A target device terminated a transaction with target-abort.
217         const SIGNALED_TARGET_ABORT = 1 << 11;
218         /// A master device transaction was terminated with target-abort.
219         const RECEIVED_TARGET_ABORT = 1 << 12;
220         /// A master device transaction was terminated with master-abort.
221         const RECEIVED_MASTER_ABORT = 1 << 13;
222         /// A device asserts SERR#.
223         const SIGNALED_SYSTEM_ERROR = 1 << 14;
224         /// The device detects a parity error, even if parity error handling is disabled.
225         const DETECTED_PARITY_ERROR = 1 << 15;
226     }
227 }
228 
229 bitflags! {
230     /// The command register in PCI configuration space.
231     pub struct Command: u16 {
232         /// The device can respond to I/O Space accesses.
233         const IO_SPACE = 1 << 0;
234         /// The device can respond to Memory Space accesses.
235         const MEMORY_SPACE = 1 << 1;
236         /// The device can behave as a bus master.
237         const BUS_MASTER = 1 << 2;
238         /// The device can monitor Special Cycle operations.
239         const SPECIAL_CYCLES = 1 << 3;
240         /// The device can generate the Memory Write and Invalidate command.
241         const MEMORY_WRITE_AND_INVALIDATE_ENABLE = 1 << 4;
242         /// The device will snoop palette register data.
243         const VGA_PALETTE_SNOOP = 1 << 5;
244         /// The device should take its normal action when a parity error is detected.
245         const PARITY_ERROR_RESPONSE = 1 << 6;
246         // Bit 7 is reserved.
247         /// The SERR# driver is enabled.
248         const SERR_ENABLE = 1 << 8;
249         /// The device is allowed to generate fast back-to-back transactions.
250         const FAST_BACK_TO_BACK_ENABLE = 1 << 9;
251         /// Assertion of the device's INTx# signal is disabled.
252         const INTERRUPT_DISABLE = 1 << 10;
253     }
254 }
255 
256 /// The type of a PCI device function header.
257 /// 标头类型/设备类型
258 #[derive(Copy, Clone, Debug, Eq, PartialEq)]
259 pub enum HeaderType {
260     /// A normal PCI device.
261     Standard,
262     /// A PCI to PCI bridge.
263     PciPciBridge,
264     /// A PCI to CardBus bridge.
265     PciCardbusBridge,
266     /// Unrecognised header type.
267     Unrecognised(u8),
268 }
269 /// u8到HeaderType的转换
270 impl From<u8> for HeaderType {
271     fn from(value: u8) -> Self {
272         match value {
273             0x00 => Self::Standard,
274             0x01 => Self::PciPciBridge,
275             0x02 => Self::PciCardbusBridge,
276             _ => Self::Unrecognised(value),
277         }
278     }
279 }
280 /// Pci可能触发的各种错误
281 #[derive(Copy, Clone, Debug, Eq, PartialEq)]
282 pub enum PciError {
283     /// The device reported an invalid BAR type.
284     InvalidBarType,
285     CreateMmioError,
286     InvalidBusDeviceFunction,
287     SegmentNotFound,
288     McfgTableNotFound,
289     GetWrongHeader,
290     UnrecognisedHeaderType,
291     PciDeviceStructureTransformError,
292     PciIrqError(PciIrqError),
293 }
294 ///实现PciError的Display trait,使其可以直接输出
295 impl Display for PciError {
296     fn fmt(&self, f: &mut Formatter) -> fmt::Result {
297         match self {
298             Self::InvalidBarType => write!(f, "Invalid PCI BAR type."),
299             Self::CreateMmioError => write!(f, "Error occurred while creating mmio."),
300             Self::InvalidBusDeviceFunction => write!(f, "Found invalid BusDeviceFunction."),
301             Self::SegmentNotFound => write!(f, "Target segment not found"),
302             Self::McfgTableNotFound => write!(f, "ACPI MCFG Table not found"),
303             Self::GetWrongHeader => write!(f, "GetWrongHeader with vendor id 0xffff"),
304             Self::UnrecognisedHeaderType => write!(f, "Found device with unrecognised header type"),
305             Self::PciDeviceStructureTransformError => {
306                 write!(f, "Found None When transform Pci device structure")
307             }
308             Self::PciIrqError(err) => write!(f, "Error occurred while setting irq :{:?}.", err),
309         }
310     }
311 }
312 
313 /// 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
314 pub trait PciDeviceStructure: Send + Sync {
315     /// @brief 获取设备类型
316     /// @return HeaderType 设备类型
317     fn header_type(&self) -> HeaderType;
318     /// @brief 当其为standard设备时返回&Pci_Device_Structure_General_Device,其余情况返回None
319     #[inline(always)]
320     fn as_standard_device(&self) -> Option<&PciDeviceStructureGeneralDevice> {
321         None
322     }
323     /// @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
324     #[inline(always)]
325     fn as_pci_to_pci_bridge_device(&self) -> Option<&PciDeviceStructurePciToPciBridge> {
326         None
327     }
328     /// @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
329     #[inline(always)]
330     fn as_pci_to_carbus_bridge_device(&self) -> Option<&PciDeviceStructurePciToCardbusBridge> {
331         None
332     }
333     /// @brief 获取Pci设备共有的common_header
334     /// @return 返回其不可变引用
335     fn common_header(&self) -> &PciDeviceStructureHeader;
336     /// @brief 当其为standard设备时返回&mut Pci_Device_Structure_General_Device,其余情况返回None
337     #[inline(always)]
338     fn as_standard_device_mut(&mut self) -> Option<&mut PciDeviceStructureGeneralDevice> {
339         None
340     }
341     /// @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
342     #[inline(always)]
343     fn as_pci_to_pci_bridge_device_mut(&mut self) -> Option<&mut PciDeviceStructurePciToPciBridge> {
344         None
345     }
346     /// @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
347     #[inline(always)]
348     fn as_pci_to_carbus_bridge_device_mut(
349         &mut self,
350     ) -> Option<&mut PciDeviceStructurePciToCardbusBridge> {
351         None
352     }
353     /// @brief 返回迭代器,遍历capabilities
354     fn capabilities(&self) -> Option<CapabilityIterator> {
355         None
356     }
357     /// @brief 获取Status、Command寄存器的值
358     fn status_command(&self) -> (Status, Command) {
359         let common_header = self.common_header();
360         let status = Status::from_bits_truncate(common_header.status);
361         let command = Command::from_bits_truncate(common_header.command);
362         (status, command)
363     }
364     /// @brief 设置Command寄存器的值
365     fn set_command(&mut self, command: Command) {
366         let common_header = self.common_header_mut();
367         let command = command.bits();
368         common_header.command = command;
369         pci_root_0().write_config(
370             common_header.bus_device_function,
371             STATUS_COMMAND_OFFSET.into(),
372             command as u32,
373         );
374     }
375     /// @brief 获取Pci设备共有的common_header
376     /// @return 返回其可变引用
377     fn common_header_mut(&mut self) -> &mut PciDeviceStructureHeader;
378 
379     /// @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
380     /// @return 只有standard设备才返回成功或者错误,其余返回None
381     #[inline(always)]
382     fn bar_ioremap(&mut self) -> Option<Result<u8, PciError>> {
383         None
384     }
385     /// @brief 获取PCI设备的bar寄存器的引用
386     /// @return
387     #[inline(always)]
388     fn bar(&mut self) -> Option<&PciStandardDeviceBar> {
389         None
390     }
391     /// @brief 通过设置该pci设备的command
392     fn enable_master(&mut self) {
393         self.set_command(Command::IO_SPACE | Command::MEMORY_SPACE | Command::BUS_MASTER);
394     }
395     /// @brief 寻找设备的msix空间的offset
396     fn msix_capability_offset(&self) -> Option<u8> {
397         for capability in self.capabilities()? {
398             if capability.id == PCI_CAP_ID_MSIX {
399                 return Some(capability.offset);
400             }
401         }
402         None
403     }
404     /// @brief 寻找设备的msi空间的offset
405     fn msi_capability_offset(&self) -> Option<u8> {
406         for capability in self.capabilities()? {
407             if capability.id == PCI_CAP_ID_MSI {
408                 return Some(capability.offset);
409             }
410         }
411         None
412     }
413     /// @brief 返回结构体中的irq_type的可变引用
414     fn irq_type_mut(&mut self) -> Option<&mut IrqType>;
415     /// @brief 返回结构体中的irq_vector的可变引用
416     fn irq_vector_mut(&mut self) -> Option<&mut Vec<IrqNumber>>;
417 }
418 
419 /// Pci_Device_Structure_Header PCI设备结构体共有的头部
420 #[derive(Clone, Debug)]
421 pub struct PciDeviceStructureHeader {
422     // ==== busdevicefunction变量表示该结构体所处的位置
423     pub bus_device_function: BusDeviceFunction,
424     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
425     pub device_id: u16, // 设备ID,标志特定设备
426     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
427     pub status: u16,  // 用于记录pci总线相关时间的状态信息寄存器
428     pub revision_id: u8, // 修订ID,指定特定设备的修订标志符
429     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)
430     pub subclass: u8, // 子类。指定设备执行的特定功能的只读寄存器
431     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
432     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
433     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。
434     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.
435     pub bist: u8, // Represents that status and allows control of a devices BIST (built-in self test).
436                   // Here is the layout of the BIST register:
437                   // |     bit7     |    bit6    | Bits 5-4 |     Bits 3-0    |
438                   // | BIST Capable | Start BIST | Reserved | Completion Code |
439                   // for more details, please visit https://wiki.osdev.org/PCI
440 }
441 
442 /// Pci_Device_Structure_General_Device PCI标准设备结构体
443 #[derive(Clone, Debug)]
444 pub struct PciDeviceStructureGeneralDevice {
445     pub common_header: PciDeviceStructureHeader,
446     // 中断结构体,包括legacy,msi,msix三种情况
447     pub irq_type: IrqType,
448     // 使用的中断号的vec集合
449     pub irq_vector: Vec<IrqNumber>,
450     pub standard_device_bar: PciStandardDeviceBar,
451     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。
452     pub subsystem_vendor_id: u16,
453     pub subsystem_id: u16,
454     pub expansion_rom_base_address: u32,
455     pub capabilities_pointer: u8,
456     pub reserved0: u8,
457     pub reserved1: u16,
458     pub reserved2: u32,
459     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。
460     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。
461     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)
462     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)。
463 }
464 impl PciDeviceStructure for PciDeviceStructureGeneralDevice {
465     #[inline(always)]
466     fn header_type(&self) -> HeaderType {
467         HeaderType::Standard
468     }
469     #[inline(always)]
470     fn as_standard_device(&self) -> Option<&PciDeviceStructureGeneralDevice> {
471         Some(self)
472     }
473     #[inline(always)]
474     fn as_standard_device_mut(&mut self) -> Option<&mut PciDeviceStructureGeneralDevice> {
475         Some(self)
476     }
477     #[inline(always)]
478     fn common_header(&self) -> &PciDeviceStructureHeader {
479         &self.common_header
480     }
481     #[inline(always)]
482     fn common_header_mut(&mut self) -> &mut PciDeviceStructureHeader {
483         &mut self.common_header
484     }
485     fn capabilities(&self) -> Option<CapabilityIterator> {
486         Some(CapabilityIterator {
487             bus_device_function: self.common_header.bus_device_function,
488             next_capability_offset: Some(self.capabilities_pointer),
489         })
490     }
491     fn bar_ioremap(&mut self) -> Option<Result<u8, PciError>> {
492         let common_header = &self.common_header;
493         match pci_bar_init(common_header.bus_device_function) {
494             Ok(bar) => {
495                 self.standard_device_bar = bar;
496                 Some(Ok(0))
497             }
498             Err(e) => Some(Err(e)),
499         }
500     }
501     fn bar(&mut self) -> Option<&PciStandardDeviceBar> {
502         Some(&self.standard_device_bar)
503     }
504     #[inline(always)]
505     fn irq_type_mut(&mut self) -> Option<&mut IrqType> {
506         Some(&mut self.irq_type)
507     }
508     #[inline(always)]
509     fn irq_vector_mut(&mut self) -> Option<&mut Vec<IrqNumber>> {
510         Some(&mut self.irq_vector)
511     }
512 }
513 
514 /// Pci_Device_Structure_Pci_to_Pci_Bridge pci-to-pci桥设备结构体
515 #[derive(Clone, Debug)]
516 pub struct PciDeviceStructurePciToPciBridge {
517     pub common_header: PciDeviceStructureHeader,
518     // 中断结构体,包括legacy,msi,msix三种情况
519     pub irq_type: IrqType,
520     // 使用的中断号的vec集合
521     pub irq_vector: Vec<IrqNumber>,
522     pub bar0: u32,
523     pub bar1: u32,
524     pub primary_bus_number: u8,
525     pub secondary_bus_number: u8,
526     pub subordinate_bus_number: u8,
527     pub secondary_latency_timer: u8,
528     pub io_base: u8,
529     pub io_limit: u8,
530     pub secondary_status: u16,
531     pub memory_base: u16,
532     pub memory_limit: u16,
533     pub prefetchable_memory_base: u16,
534     pub prefetchable_memory_limit: u16,
535     pub prefetchable_base_upper_32_bits: u32,
536     pub prefetchable_limit_upper_32_bits: u32,
537     pub io_base_upper_16_bits: u16,
538     pub io_limit_upper_16_bits: u16,
539     pub capability_pointer: u8,
540     pub reserved0: u8,
541     pub reserved1: u16,
542     pub expansion_rom_base_address: u32,
543     pub interrupt_line: u8,
544     pub interrupt_pin: u8,
545     pub bridge_control: u16,
546 }
547 impl PciDeviceStructure for PciDeviceStructurePciToPciBridge {
548     #[inline(always)]
549     fn header_type(&self) -> HeaderType {
550         HeaderType::PciPciBridge
551     }
552     #[inline(always)]
553     fn as_pci_to_pci_bridge_device(&self) -> Option<&PciDeviceStructurePciToPciBridge> {
554         Some(self)
555     }
556     #[inline(always)]
557     fn as_pci_to_pci_bridge_device_mut(&mut self) -> Option<&mut PciDeviceStructurePciToPciBridge> {
558         Some(self)
559     }
560     #[inline(always)]
561     fn common_header(&self) -> &PciDeviceStructureHeader {
562         &self.common_header
563     }
564     #[inline(always)]
565     fn common_header_mut(&mut self) -> &mut PciDeviceStructureHeader {
566         &mut self.common_header
567     }
568     #[inline(always)]
569     fn irq_type_mut(&mut self) -> Option<&mut IrqType> {
570         Some(&mut self.irq_type)
571     }
572     #[inline(always)]
573     fn irq_vector_mut(&mut self) -> Option<&mut Vec<IrqNumber>> {
574         Some(&mut self.irq_vector)
575     }
576 }
577 /// Pci_Device_Structure_Pci_to_Cardbus_Bridge Pci_to_Cardbus桥设备结构体
578 #[derive(Clone, Debug)]
579 pub struct PciDeviceStructurePciToCardbusBridge {
580     pub common_header: PciDeviceStructureHeader,
581     pub cardbus_socket_ex_ca_base_address: u32,
582     pub offset_of_capabilities_list: u8,
583     pub reserved: u8,
584     pub secondary_status: u16,
585     pub pci_bus_number: u8,
586     pub card_bus_bus_number: u8,
587     pub subordinate_bus_number: u8,
588     pub card_bus_latency_timer: u8,
589     pub memory_base_address0: u32,
590     pub memory_limit0: u32,
591     pub memory_base_address1: u32,
592     pub memory_limit1: u32,
593     pub io_base_address0: u32,
594     pub io_limit0: u32,
595     pub io_base_address1: u32,
596     pub io_limit1: u32,
597     pub interrupt_line: u8,
598     pub interrupt_pin: u8,
599     pub bridge_control: u16,
600     pub subsystem_device_id: u16,
601     pub subsystem_vendor_id: u16,
602     pub pc_card_legacy_mode_base_address_16_bit: u32,
603 }
604 impl PciDeviceStructure for PciDeviceStructurePciToCardbusBridge {
605     #[inline(always)]
606     fn header_type(&self) -> HeaderType {
607         HeaderType::PciCardbusBridge
608     }
609     #[inline(always)]
610     fn as_pci_to_carbus_bridge_device(&self) -> Option<&PciDeviceStructurePciToCardbusBridge> {
611         Some(self)
612     }
613     #[inline(always)]
614     fn as_pci_to_carbus_bridge_device_mut(
615         &mut self,
616     ) -> Option<&mut PciDeviceStructurePciToCardbusBridge> {
617         Some(self)
618     }
619     #[inline(always)]
620     fn common_header(&self) -> &PciDeviceStructureHeader {
621         &self.common_header
622     }
623     #[inline(always)]
624     fn common_header_mut(&mut self) -> &mut PciDeviceStructureHeader {
625         &mut self.common_header
626     }
627     #[inline(always)]
628     fn irq_type_mut(&mut self) -> Option<&mut IrqType> {
629         None
630     }
631     #[inline(always)]
632     fn irq_vector_mut(&mut self) -> Option<&mut Vec<IrqNumber>> {
633         None
634     }
635 }
636 
637 /// PCI配置空间访问机制
638 ///
639 /// 用于访问PCI设备的功能配置空间的一组机制。
640 #[derive(Copy, Clone, Debug, Eq, PartialEq)]
641 pub enum PciCam {
642     /// PortIO配置访问机制
643     Portiocam,
644     /// PCI内存映射配置访问机制
645     ///
646     /// 为每个设备功能提供256字节的配置空间访问。
647     MmioCam,
648     /// PCIe内存映射增强配置访问机制
649     ///
650     /// 为每个设备功能提供4千字节(4096字节)的配置空间访问。
651     Ecam,
652 }
653 
654 impl PciCam {
655     /// Returns the total size in bytes of the memory-mapped region.
656     pub const fn size(self) -> u32 {
657         match self {
658             Self::Portiocam => 0x100000,
659             Self::MmioCam => 0x1000000,
660             Self::Ecam => 0x10000000,
661         }
662     }
663 }
664 
665 /// Gets the capabilities 'pointer' for the device function, if any.
666 /// @brief 获取第一个capability 的offset
667 /// @param bus_device_function PCI设备的唯一标识
668 /// @return Option<u8> offset
669 pub fn capabilities_offset(bus_device_function: BusDeviceFunction) -> Option<u8> {
670     let result = pci_root_0().read_config(bus_device_function, STATUS_COMMAND_OFFSET.into());
671     let status: Status = Status::from_bits_truncate((result >> 16) as u16);
672     if status.contains(Status::CAPABILITIES_LIST) {
673         let cap_pointer = pci_root_0().read_config(bus_device_function, 0x34) as u8 & 0xFC;
674         Some(cap_pointer)
675     } else {
676         None
677     }
678 }
679 
680 /// @brief 读取pci设备头部
681 /// @param bus_device_function PCI设备的唯一标识
682 /// @param add_to_list 是否添加到链表
683 /// @return 返回的header(trait 类型)
684 fn pci_read_header(
685     bus_device_function: BusDeviceFunction,
686     add_to_list: bool,
687 ) -> Result<Box<dyn PciDeviceStructure>, PciError> {
688     // 先读取公共header
689     let result = pci_root_0().read_config(bus_device_function, 0x00);
690     let vendor_id = result as u16;
691     let device_id = (result >> 16) as u16;
692 
693     let result = pci_root_0().read_config(bus_device_function, 0x04);
694     let command = result as u16;
695     let status = (result >> 16) as u16;
696 
697     let result = pci_root_0().read_config(bus_device_function, 0x08);
698     let revision_id = result as u8;
699     let prog_if = (result >> 8) as u8;
700     let subclass = (result >> 16) as u8;
701     let class_code = (result >> 24) as u8;
702 
703     let result = pci_root_0().read_config(bus_device_function, 0x0c);
704     let cache_line_size = result as u8;
705     let latency_timer = (result >> 8) as u8;
706     let header_type = (result >> 16) as u8;
707     let bist = (result >> 24) as u8;
708     if vendor_id == 0xffff {
709         return Err(PciError::GetWrongHeader);
710     }
711     let header = PciDeviceStructureHeader {
712         bus_device_function,
713         vendor_id,
714         device_id,
715         command,
716         status,
717         revision_id,
718         prog_if,
719         subclass,
720         class_code,
721         cache_line_size,
722         latency_timer,
723         header_type,
724         bist,
725     };
726     match HeaderType::from(header_type & 0x7f) {
727         HeaderType::Standard => {
728             let general_device: PciDeviceStructureGeneralDevice =
729                 pci_read_general_device_header(header, &bus_device_function);
730             let box_general_device = Box::new(general_device.clone());
731             let box_general_device_clone = box_general_device.clone();
732             if add_to_list {
733                 PCI_DEVICE_LINKEDLIST.add(box_general_device);
734                 //这里实际上不应该使用clone,因为raw是用于sysfs的结构,但是实际上pci设备是在PCI_DEVICE_LINKEDLIST链表上的,
735                 //这就导致sysfs呈现的对pci设备的操控接口实际上操控的是pci设备描述符是一个副本
736                 //但是无奈这里没有使用Arc
737                 //todo:修改pci设备描述符在静态链表中存在的方式,并修改这里的clone操作
738                 let raw = PciGeneralDevice::from(&general_device);
739                 let _ = pci_device_manager().device_add(Arc::new(raw));
740             }
741             Ok(box_general_device_clone)
742         }
743         HeaderType::PciPciBridge => {
744             let pci_to_pci_bridge = pci_read_pci_to_pci_bridge_header(header, &bus_device_function);
745             let box_pci_to_pci_bridge = Box::new(pci_to_pci_bridge);
746             let box_pci_to_pci_bridge_clone = box_pci_to_pci_bridge.clone();
747             if add_to_list {
748                 PCI_DEVICE_LINKEDLIST.add(box_pci_to_pci_bridge);
749             }
750             Ok(box_pci_to_pci_bridge_clone)
751         }
752         HeaderType::PciCardbusBridge => {
753             let pci_cardbus_bridge =
754                 pci_read_pci_to_cardbus_bridge_header(header, &bus_device_function);
755             let box_pci_cardbus_bridge = Box::new(pci_cardbus_bridge);
756             let box_pci_cardbus_bridge_clone = box_pci_cardbus_bridge.clone();
757             if add_to_list {
758                 PCI_DEVICE_LINKEDLIST.add(box_pci_cardbus_bridge);
759             }
760             Ok(box_pci_cardbus_bridge_clone)
761         }
762         HeaderType::Unrecognised(_) => Err(PciError::UnrecognisedHeaderType),
763     }
764 }
765 
766 /// @brief 读取type为0x0的pci设备的header
767 /// 本函数只应被 pci_read_header()调用
768 /// @param common_header 共有头部
769 /// @param bus_device_function PCI设备的唯一标识
770 /// @return Pci_Device_Structure_General_Device 标准设备头部
771 fn pci_read_general_device_header(
772     common_header: PciDeviceStructureHeader,
773     bus_device_function: &BusDeviceFunction,
774 ) -> PciDeviceStructureGeneralDevice {
775     let standard_device_bar = PciStandardDeviceBar::default();
776     let cardbus_cis_pointer = pci_root_0().read_config(*bus_device_function, 0x28);
777 
778     let result = pci_root_0().read_config(*bus_device_function, 0x2c);
779     let subsystem_vendor_id = result as u16;
780     let subsystem_id = (result >> 16) as u16;
781 
782     let expansion_rom_base_address = pci_root_0().read_config(*bus_device_function, 0x30);
783 
784     let result = pci_root_0().read_config(*bus_device_function, 0x34);
785     let capabilities_pointer = result as u8;
786     let reserved0 = (result >> 8) as u8;
787     let reserved1 = (result >> 16) as u16;
788 
789     let reserved2 = pci_root_0().read_config(*bus_device_function, 0x38);
790 
791     let result = pci_root_0().read_config(*bus_device_function, 0x3c);
792     let interrupt_line = result as u8;
793     let interrupt_pin = (result >> 8) as u8;
794     let min_grant = (result >> 16) as u8;
795     let max_latency = (result >> 24) as u8;
796     PciDeviceStructureGeneralDevice {
797         common_header,
798         irq_type: IrqType::Unused,
799         irq_vector: Vec::new(),
800         standard_device_bar,
801         cardbus_cis_pointer,
802         subsystem_vendor_id,
803         subsystem_id,
804         expansion_rom_base_address,
805         capabilities_pointer,
806         reserved0,
807         reserved1,
808         reserved2,
809         interrupt_line,
810         interrupt_pin,
811         min_grant,
812         max_latency,
813     }
814 }
815 
816 /// @brief 读取type为0x1的pci设备的header
817 /// 本函数只应被 pci_read_header()调用
818 /// @param common_header 共有头部
819 /// @param bus_device_function PCI设备的唯一标识
820 /// @return Pci_Device_Structure_Pci_to_Pci_Bridge pci-to-pci 桥设备头部
821 fn pci_read_pci_to_pci_bridge_header(
822     common_header: PciDeviceStructureHeader,
823     bus_device_function: &BusDeviceFunction,
824 ) -> PciDeviceStructurePciToPciBridge {
825     let bar0 = pci_root_0().read_config(*bus_device_function, 0x10);
826     let bar1 = pci_root_0().read_config(*bus_device_function, 0x14);
827 
828     let result = pci_root_0().read_config(*bus_device_function, 0x18);
829 
830     let primary_bus_number = result as u8;
831     let secondary_bus_number = (result >> 8) as u8;
832     let subordinate_bus_number = (result >> 16) as u8;
833     let secondary_latency_timer = (result >> 24) as u8;
834 
835     let result = pci_root_0().read_config(*bus_device_function, 0x1c);
836     let io_base = result as u8;
837     let io_limit = (result >> 8) as u8;
838     let secondary_status = (result >> 16) as u16;
839 
840     let result = pci_root_0().read_config(*bus_device_function, 0x20);
841     let memory_base = result as u16;
842     let memory_limit = (result >> 16) as u16;
843 
844     let result = pci_root_0().read_config(*bus_device_function, 0x24);
845     let prefetchable_memory_base = result as u16;
846     let prefetchable_memory_limit = (result >> 16) as u16;
847 
848     let prefetchable_base_upper_32_bits = pci_root_0().read_config(*bus_device_function, 0x28);
849     let prefetchable_limit_upper_32_bits = pci_root_0().read_config(*bus_device_function, 0x2c);
850 
851     let result = pci_root_0().read_config(*bus_device_function, 0x30);
852     let io_base_upper_16_bits = result as u16;
853     let io_limit_upper_16_bits = (result >> 16) as u16;
854 
855     let result = pci_root_0().read_config(*bus_device_function, 0x34);
856     let capability_pointer = result as u8;
857     let reserved0 = (result >> 8) as u8;
858     let reserved1 = (result >> 16) as u16;
859 
860     let expansion_rom_base_address = pci_root_0().read_config(*bus_device_function, 0x38);
861 
862     let result = pci_root_0().read_config(*bus_device_function, 0x3c);
863     let interrupt_line = result as u8;
864     let interrupt_pin = (result >> 8) as u8;
865     let bridge_control = (result >> 16) as u16;
866     PciDeviceStructurePciToPciBridge {
867         common_header,
868         irq_type: IrqType::Unused,
869         irq_vector: Vec::new(),
870         bar0,
871         bar1,
872         primary_bus_number,
873         secondary_bus_number,
874         subordinate_bus_number,
875         secondary_latency_timer,
876         io_base,
877         io_limit,
878         secondary_status,
879         memory_base,
880         memory_limit,
881         prefetchable_memory_base,
882         prefetchable_memory_limit,
883         prefetchable_base_upper_32_bits,
884         prefetchable_limit_upper_32_bits,
885         io_base_upper_16_bits,
886         io_limit_upper_16_bits,
887         capability_pointer,
888         reserved0,
889         reserved1,
890         expansion_rom_base_address,
891         interrupt_line,
892         interrupt_pin,
893         bridge_control,
894     }
895 }
896 
897 /// @brief 读取type为0x2的pci设备的header
898 /// 本函数只应被 pci_read_header()调用
899 /// @param common_header 共有头部
900 /// @param bus_device_function PCI设备的唯一标识
901 /// @return   Pci_Device_Structure_Pci_to_Cardbus_Bridge  pci-to-cardbus 桥设备头部
902 fn pci_read_pci_to_cardbus_bridge_header(
903     common_header: PciDeviceStructureHeader,
904     busdevicefunction: &BusDeviceFunction,
905 ) -> PciDeviceStructurePciToCardbusBridge {
906     let cardbus_socket_ex_ca_base_address = pci_root_0().read_config(*busdevicefunction, 0x10);
907 
908     let result = pci_root_0().read_config(*busdevicefunction, 0x14);
909     let offset_of_capabilities_list = result as u8;
910     let reserved = (result >> 8) as u8;
911     let secondary_status = (result >> 16) as u16;
912 
913     let result = pci_root_0().read_config(*busdevicefunction, 0x18);
914     let pci_bus_number = result as u8;
915     let card_bus_bus_number = (result >> 8) as u8;
916     let subordinate_bus_number = (result >> 16) as u8;
917     let card_bus_latency_timer = (result >> 24) as u8;
918 
919     let memory_base_address0 = pci_root_0().read_config(*busdevicefunction, 0x1c);
920     let memory_limit0 = pci_root_0().read_config(*busdevicefunction, 0x20);
921     let memory_base_address1 = pci_root_0().read_config(*busdevicefunction, 0x24);
922     let memory_limit1 = pci_root_0().read_config(*busdevicefunction, 0x28);
923 
924     let io_base_address0 = pci_root_0().read_config(*busdevicefunction, 0x2c);
925     let io_limit0 = pci_root_0().read_config(*busdevicefunction, 0x30);
926     let io_base_address1 = pci_root_0().read_config(*busdevicefunction, 0x34);
927     let io_limit1 = pci_root_0().read_config(*busdevicefunction, 0x38);
928     let result = pci_root_0().read_config(*busdevicefunction, 0x3c);
929     let interrupt_line = result as u8;
930     let interrupt_pin = (result >> 8) as u8;
931     let bridge_control = (result >> 16) as u16;
932 
933     let result = pci_root_0().read_config(*busdevicefunction, 0x40);
934     let subsystem_device_id = result as u16;
935     let subsystem_vendor_id = (result >> 16) as u16;
936 
937     let pc_card_legacy_mode_base_address_16_bit =
938         pci_root_0().read_config(*busdevicefunction, 0x44);
939     PciDeviceStructurePciToCardbusBridge {
940         common_header,
941         cardbus_socket_ex_ca_base_address,
942         offset_of_capabilities_list,
943         reserved,
944         secondary_status,
945         pci_bus_number,
946         card_bus_bus_number,
947         subordinate_bus_number,
948         card_bus_latency_timer,
949         memory_base_address0,
950         memory_limit0,
951         memory_base_address1,
952         memory_limit1,
953         io_base_address0,
954         io_limit0,
955         io_base_address1,
956         io_limit1,
957         interrupt_line,
958         interrupt_pin,
959         bridge_control,
960         subsystem_device_id,
961         subsystem_vendor_id,
962         pc_card_legacy_mode_base_address_16_bit,
963     }
964 }
965 
966 /// @brief 检查所有bus上的设备并将其加入链表
967 /// @return 成功返回ok(),失败返回失败原因
968 fn pci_check_all_buses() -> Result<u8, PciError> {
969     info!("Checking all devices in PCI bus...");
970     let busdevicefunction = BusDeviceFunction {
971         bus: 0,
972         device: 0,
973         function: 0,
974     };
975     let header = pci_read_header(busdevicefunction, false)?;
976     let common_header = header.common_header();
977     pci_check_bus(0)?;
978     if common_header.header_type & 0x80 != 0 {
979         for function in 1..8 {
980             pci_check_bus(function)?;
981         }
982     }
983     Ok(0)
984 }
985 /// @brief 检查特定设备并将其加入链表
986 /// @return 成功返回ok(),失败返回失败原因
987 fn pci_check_function(busdevicefunction: BusDeviceFunction) -> Result<u8, PciError> {
988     //debug!("PCI check function {}", busdevicefunction.function);
989     let header = match pci_read_header(busdevicefunction, true) {
990         Ok(header) => header,
991         Err(PciError::GetWrongHeader) => {
992             return Ok(255);
993         }
994         Err(e) => {
995             return Err(e);
996         }
997     };
998     let common_header = header.common_header();
999     if (common_header.class_code == 0x06)
1000         && (common_header.subclass == 0x04 || common_header.subclass == 0x09)
1001     {
1002         let pci_to_pci_bridge = header
1003             .as_pci_to_pci_bridge_device()
1004             .ok_or(PciError::PciDeviceStructureTransformError)?;
1005         let secondary_bus = pci_to_pci_bridge.secondary_bus_number;
1006         pci_check_bus(secondary_bus)?;
1007     }
1008     Ok(0)
1009 }
1010 
1011 /// @brief 检查device上的设备并将其加入链表
1012 /// @return 成功返回ok(),失败返回失败原因
1013 fn pci_check_device(bus: u8, device: u8) -> Result<u8, PciError> {
1014     //debug!("PCI check device {}", device);
1015     let busdevicefunction = BusDeviceFunction {
1016         bus,
1017         device,
1018         function: 0,
1019     };
1020     let header = match pci_read_header(busdevicefunction, false) {
1021         Ok(header) => header,
1022         Err(PciError::GetWrongHeader) => {
1023             //设备不存在,直接返回即可,不用终止遍历
1024             return Ok(255);
1025         }
1026         Err(e) => {
1027             return Err(e);
1028         }
1029     };
1030     pci_check_function(busdevicefunction)?;
1031     let common_header = header.common_header();
1032     if common_header.header_type & 0x80 != 0 {
1033         debug!(
1034             "Detected multi func device in bus{},device{}",
1035             busdevicefunction.bus, busdevicefunction.device
1036         );
1037         // 这是一个多function的设备,因此查询剩余的function
1038         for function in 1..8 {
1039             let busdevicefunction = BusDeviceFunction {
1040                 bus,
1041                 device,
1042                 function,
1043             };
1044             pci_check_function(busdevicefunction)?;
1045         }
1046     }
1047     Ok(0)
1048 }
1049 /// @brief 检查该bus上的设备并将其加入链表
1050 /// @return 成功返回ok(),失败返回失败原因
1051 fn pci_check_bus(bus: u8) -> Result<u8, PciError> {
1052     //debug!("PCI check bus {}", bus);
1053     for device in 0..32 {
1054         pci_check_device(bus, device)?;
1055     }
1056     Ok(0)
1057 }
1058 
1059 /// pci初始化函数
1060 #[inline(never)]
1061 pub fn pci_init() {
1062     info!("Initializing PCI bus...");
1063     pci_bus_subsys_init().expect("Failed to init pci bus subsystem");
1064     if let Err(e) = pci_check_all_buses() {
1065         error!("pci init failed when checking bus because of error: {}", e);
1066         return;
1067     }
1068     info!(
1069         "Total pci device and function num = {}",
1070         PCI_DEVICE_LINKEDLIST.num()
1071     );
1072     let list = PCI_DEVICE_LINKEDLIST.read();
1073     for box_pci_device in list.iter() {
1074         let common_header = box_pci_device.common_header();
1075         match box_pci_device.header_type() {
1076             HeaderType::Standard if common_header.status & 0x10 != 0 => {
1077                 info!("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);
1078             }
1079             HeaderType::Standard => {
1080                 info!(
1081                     "Found pci standard device with class code ={} subclass={} status={:#x} ",
1082                     common_header.class_code, common_header.subclass, common_header.status
1083                 );
1084             }
1085             HeaderType::PciPciBridge if common_header.status & 0x10 != 0 => {
1086                 info!("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);
1087             }
1088             HeaderType::PciPciBridge => {
1089                 info!(
1090                     "Found pci-to-pci bridge device with class code ={} subclass={} status={:#x} ",
1091                     common_header.class_code, common_header.subclass, common_header.status
1092                 );
1093             }
1094             HeaderType::PciCardbusBridge => {
1095                 info!(
1096                     "Found pcicardbus bridge device with class code ={} subclass={} status={:#x} ",
1097                     common_header.class_code, common_header.subclass, common_header.status
1098                 );
1099             }
1100             HeaderType::Unrecognised(_) => {}
1101         }
1102     }
1103 
1104     info!("PCI bus initialized.");
1105 }
1106 
1107 /// An identifier for a PCI bus, device and function.
1108 /// PCI设备的唯一标识
1109 #[derive(Copy, Clone, Debug, Eq, PartialEq)]
1110 pub struct BusDeviceFunction {
1111     /// The PCI bus number, between 0 and 255.
1112     pub bus: u8,
1113     /// The device number on the bus, between 0 and 31.
1114     pub device: u8,
1115     /// The function number of the device, between 0 and 7.
1116     pub function: u8,
1117 }
1118 impl BusDeviceFunction {
1119     /// Returns whether the device and function numbers are valid, i.e. the device is between 0 and
1120     ///@brief 检测BusDeviceFunction实例是否有效
1121     ///@param self
1122     ///@return bool 是否有效
1123     #[allow(dead_code)]
1124     pub fn valid(&self) -> bool {
1125         self.device < 32 && self.function < 8
1126     }
1127 }
1128 
1129 impl From<BusDeviceFunction> for String {
1130     /// # 函数的功能
1131     /// 这里提供一个由BusDeviceFunction到dddd:bb:vv.f字符串的转换函数,主要用于转换成设备的名称(pci设备的名称一般是诸如0000:00:00.1这种)
1132     fn from(value: BusDeviceFunction) -> Self {
1133         //需要注意,这里的0000应该是所谓的“域号”(Domain ID),但是尚不知道是如何获得的,故硬编码在这里
1134         //todo:实现域号的获取
1135         format!(
1136             "0000:{:02x}:{:02x}.{}",
1137             value.bus, value.device, value.function
1138         )
1139     }
1140 }
1141 ///实现BusDeviceFunction的Display trait,使其可以直接输出
1142 impl Display for BusDeviceFunction {
1143     fn fmt(&self, f: &mut Formatter) -> fmt::Result {
1144         write!(
1145             f,
1146             "bus {} device {} function{}",
1147             self.bus, self.device, self.function
1148         )
1149     }
1150 }
1151 /// The location allowed for a memory BAR.
1152 /// memory BAR的三种情况
1153 #[derive(Copy, Clone, Debug, Eq, PartialEq)]
1154 pub enum MemoryBarType {
1155     /// The BAR has a 32-bit address and can be mapped anywhere in 32-bit address space.
1156     Width32,
1157     /// The BAR must be mapped below 1MiB.
1158     Below1MiB,
1159     /// The BAR has a 64-bit address and can be mapped anywhere in 64-bit address space.
1160     Width64,
1161 }
1162 ///实现MemoryBarType与u8的类型转换
1163 impl From<MemoryBarType> for u8 {
1164     fn from(bar_type: MemoryBarType) -> Self {
1165         match bar_type {
1166             MemoryBarType::Width32 => 0,
1167             MemoryBarType::Below1MiB => 1,
1168             MemoryBarType::Width64 => 2,
1169         }
1170     }
1171 }
1172 ///实现MemoryBarType与u8的类型转换
1173 impl TryFrom<u8> for MemoryBarType {
1174     type Error = PciError;
1175     fn try_from(value: u8) -> Result<Self, Self::Error> {
1176         match value {
1177             0 => Ok(Self::Width32),
1178             1 => Ok(Self::Below1MiB),
1179             2 => Ok(Self::Width64),
1180             _ => Err(PciError::InvalidBarType),
1181         }
1182     }
1183 }
1184 
1185 /// Information about a PCI Base Address Register.
1186 /// BAR的三种类型 Memory/IO/Unused
1187 #[derive(Clone, Debug)]
1188 pub enum BarInfo {
1189     /// The BAR is for a memory region.
1190     Memory {
1191         /// The size of the BAR address and where it can be located.
1192         address_type: MemoryBarType,
1193         /// If true, then reading from the region doesn't have side effects. The CPU may cache reads
1194         /// and merge repeated stores.
1195         prefetchable: bool,
1196         /// The memory address, always 16-byte aligned.
1197         address: u64,
1198         /// The size of the BAR in bytes.
1199         size: u32,
1200         /// The virtaddress for a memory bar(mapped).
1201         mmio_guard: Arc<MMIOSpaceGuard>,
1202     },
1203     /// The BAR is for an I/O region.
1204     IO {
1205         /// The I/O address, always 4-byte aligned.
1206         address: u32,
1207         /// The size of the BAR in bytes.
1208         size: u32,
1209     },
1210     Unused,
1211 }
1212 
1213 impl BarInfo {
1214     /// Returns the address and size of this BAR if it is a memory bar, or `None` if it is an IO
1215     /// BAR.
1216     ///@brief 得到某个bar的memory_address与size(前提是他的类型为Memory Bar)
1217     ///@param self
1218     ///@return Option<(u64, u32) 是Memory Bar返回内存地址与大小,不是则返回None
1219     pub fn memory_address_size(&self) -> Option<(u64, u32)> {
1220         if let Self::Memory { address, size, .. } = self {
1221             Some((*address, *size))
1222         } else {
1223             None
1224         }
1225     }
1226     ///@brief 得到某个bar的virtaddress(前提是他的类型为Memory Bar)
1227     ///@param self
1228     ///@return Option<(u64) 是Memory Bar返回映射的虚拟地址,不是则返回None
1229     pub fn virtual_address(&self) -> Option<VirtAddr> {
1230         if let Self::Memory { mmio_guard, .. } = self {
1231             Some(mmio_guard.vaddr())
1232         } else {
1233             None
1234         }
1235     }
1236 }
1237 ///实现BarInfo的Display trait,自定义输出
1238 impl Display for BarInfo {
1239     fn fmt(&self, f: &mut Formatter<'_>) -> fmt::Result {
1240         match self {
1241             Self::Memory {
1242                 address_type,
1243                 prefetchable,
1244                 address,
1245                 size,
1246                 mmio_guard,
1247             } => write!(
1248                 f,
1249                 "Memory space at {:#010x}, size {}, type {:?}, prefetchable {}, mmio_guard: {:?}",
1250                 address, size, address_type, prefetchable, mmio_guard
1251             ),
1252             Self::IO { address, size } => {
1253                 write!(f, "I/O space at {:#010x}, size {}", address, size)
1254             }
1255             Self::Unused => {
1256                 write!(f, "Unused bar")
1257             }
1258         }
1259     }
1260 }
1261 // todo 增加对桥的bar的支持
1262 pub trait PciDeviceBar {}
1263 
1264 ///一个普通PCI设备(非桥)有6个BAR寄存器,PciStandardDeviceBar存储其全部信息
1265 #[derive(Clone, Debug)]
1266 pub struct PciStandardDeviceBar {
1267     bar0: BarInfo,
1268     bar1: BarInfo,
1269     bar2: BarInfo,
1270     bar3: BarInfo,
1271     bar4: BarInfo,
1272     bar5: BarInfo,
1273 }
1274 
1275 impl PciStandardDeviceBar {
1276     ///@brief 得到某个bar的barinfo
1277     ///@param self ,bar_index(0-5)
1278     ///@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
1279     pub fn get_bar(&self, bar_index: u8) -> Result<&BarInfo, PciError> {
1280         match bar_index {
1281             0 => Ok(&self.bar0),
1282             1 => Ok(&self.bar1),
1283             2 => Ok(&self.bar2),
1284             3 => Ok(&self.bar3),
1285             4 => Ok(&self.bar4),
1286             5 => Ok(&self.bar5),
1287             _ => Err(PciError::InvalidBarType),
1288         }
1289     }
1290 }
1291 ///实现PciStandardDeviceBar的Display trait,使其可以直接输出
1292 impl Display for PciStandardDeviceBar {
1293     fn fmt(&self, f: &mut Formatter<'_>) -> fmt::Result {
1294         write!(
1295             f,
1296             "\r\nBar0:{}\r\nBar1:{}\r\nBar2:{}\r\nBar3:{}\r\nBar4:{}\r\nBar5:{}",
1297             self.bar0, self.bar1, self.bar2, self.bar3, self.bar4, self.bar5
1298         )
1299     }
1300 }
1301 ///实现PciStandardDeviceBar的Default trait,使其可以简单初始化
1302 impl Default for PciStandardDeviceBar {
1303     fn default() -> Self {
1304         PciStandardDeviceBar {
1305             bar0: BarInfo::Unused,
1306             bar1: BarInfo::Unused,
1307             bar2: BarInfo::Unused,
1308             bar3: BarInfo::Unused,
1309             bar4: BarInfo::Unused,
1310             bar5: BarInfo::Unused,
1311         }
1312     }
1313 }
1314 
1315 ///@brief 将某个pci设备的bar寄存器读取值后映射到虚拟地址
1316 ///@param self ,bus_device_function PCI设备的唯一标识符
1317 ///@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
1318 pub fn pci_bar_init(
1319     bus_device_function: BusDeviceFunction,
1320 ) -> Result<PciStandardDeviceBar, PciError> {
1321     let mut device_bar: PciStandardDeviceBar = PciStandardDeviceBar::default();
1322     let mut bar_index_ignore: u8 = 255;
1323     for bar_index in 0..6 {
1324         if bar_index == bar_index_ignore {
1325             continue;
1326         }
1327         let bar_info;
1328         let bar_orig =
1329             pci_root_0().read_config(bus_device_function, (BAR0_OFFSET + 4 * bar_index).into());
1330         pci_root_0().write_config(
1331             bus_device_function,
1332             (BAR0_OFFSET + 4 * bar_index).into(),
1333             0xffffffff,
1334         );
1335         let size_mask =
1336             pci_root_0().read_config(bus_device_function, (BAR0_OFFSET + 4 * bar_index).into());
1337         // A wrapping add is necessary to correctly handle the case of unused BARs, which read back
1338         // as 0, and should be treated as size 0.
1339         let size = (!(size_mask & 0xfffffff0)).wrapping_add(1);
1340         //debug!("bar_orig:{:#x},size: {:#x}", bar_orig,size);
1341         // Restore the original value.
1342         pci_root_0().write_config(
1343             bus_device_function,
1344             (BAR0_OFFSET + 4 * bar_index).into(),
1345             bar_orig,
1346         );
1347         if size == 0 {
1348             continue;
1349         }
1350         if bar_orig & 0x00000001 == 0x00000001 {
1351             // I/O space
1352             let address = bar_orig & 0xfffffffc;
1353             bar_info = BarInfo::IO { address, size };
1354         } else {
1355             // Memory space
1356             let mut address = u64::from(bar_orig & 0xfffffff0);
1357             let prefetchable = bar_orig & 0x00000008 != 0;
1358             let address_type = MemoryBarType::try_from(((bar_orig & 0x00000006) >> 1) as u8)?;
1359             if address_type == MemoryBarType::Width64 {
1360                 if bar_index >= 5 {
1361                     return Err(PciError::InvalidBarType);
1362                 }
1363                 let address_top = pci_root_0().read_config(
1364                     bus_device_function,
1365                     (BAR0_OFFSET + 4 * (bar_index + 1)).into(),
1366                 );
1367                 address |= u64::from(address_top) << 32;
1368                 bar_index_ignore = bar_index + 1; //下个bar跳过,因为64位的memory bar覆盖了两个bar
1369             }
1370             let pci_address = PciAddr::new(address as usize);
1371             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
1372 
1373             let space_guard: Arc<MMIOSpaceGuard>;
1374             unsafe {
1375                 let size_want = size as usize;
1376                 let tmp = mmio_pool()
1377                     .create_mmio(size_want)
1378                     .map_err(|_| PciError::CreateMmioError)?;
1379                 space_guard = Arc::new(tmp);
1380                 //debug!("Pci bar init: mmio space: {space_guard:?}, paddr={paddr:?}, size_want={size_want}");
1381                 assert!(
1382                     space_guard.map_phys(paddr, size_want).is_ok(),
1383                     "pci_bar_init: map_phys failed"
1384                 );
1385             }
1386             bar_info = BarInfo::Memory {
1387                 address_type,
1388                 prefetchable,
1389                 address,
1390                 size,
1391                 mmio_guard: space_guard,
1392             };
1393         }
1394         match bar_index {
1395             0 => {
1396                 device_bar.bar0 = bar_info;
1397             }
1398             1 => {
1399                 device_bar.bar1 = bar_info;
1400             }
1401             2 => {
1402                 device_bar.bar2 = bar_info;
1403             }
1404             3 => {
1405                 device_bar.bar3 = bar_info;
1406             }
1407             4 => {
1408                 device_bar.bar4 = bar_info;
1409             }
1410             5 => {
1411                 device_bar.bar5 = bar_info;
1412             }
1413             _ => {}
1414         }
1415     }
1416     //debug!("pci_device_bar:{}", device_bar);
1417     return Ok(device_bar);
1418 }
1419 
1420 /// Information about a PCI device capability.
1421 /// PCI设备的capability的信息
1422 #[derive(Debug, Copy, Clone, Eq, PartialEq)]
1423 pub struct CapabilityInfo {
1424     /// The offset of the capability in the PCI configuration space of the device function.
1425     pub offset: u8,
1426     /// The ID of the capability.
1427     pub id: u8,
1428     /// The third and fourth bytes of the capability, to save reading them again.
1429     pub private_header: u16,
1430 }
1431 
1432 /// Iterator over capabilities for a device.
1433 /// 创建迭代器以遍历PCI设备的capability
1434 #[derive(Debug)]
1435 pub struct CapabilityIterator {
1436     pub bus_device_function: BusDeviceFunction,
1437     pub next_capability_offset: Option<u8>,
1438 }
1439 
1440 impl Iterator for CapabilityIterator {
1441     type Item = CapabilityInfo;
1442     fn next(&mut self) -> Option<Self::Item> {
1443         let offset = self.next_capability_offset?;
1444 
1445         // Read the first 4 bytes of the capability.
1446         let capability_header = pci_root_0().read_config(self.bus_device_function, offset.into());
1447         let id = capability_header as u8;
1448         let next_offset = (capability_header >> 8) as u8;
1449         let private_header = (capability_header >> 16) as u16;
1450 
1451         self.next_capability_offset = if next_offset == 0 {
1452             None
1453         } else if next_offset < 64 || next_offset & 0x3 != 0 {
1454             warn!("Invalid next capability offset {:#04x}", next_offset);
1455             None
1456         } else {
1457             Some(next_offset)
1458         };
1459 
1460         Some(CapabilityInfo {
1461             offset,
1462             id,
1463             private_header,
1464         })
1465     }
1466 }
1467 
1468 /// Information about a PCIe device capability.
1469 /// PCIe设备的external capability的信息
1470 #[derive(Debug, Copy, Clone, Eq, PartialEq)]
1471 pub struct ExternalCapabilityInfo {
1472     /// The offset of the capability in the PCI configuration space of the device function.
1473     pub offset: u16,
1474     /// The ID of the capability.
1475     pub id: u16,
1476     /// The third and fourth bytes of the capability, to save reading them again.
1477     pub capability_version: u8,
1478 }
1479 
1480 /// Iterator over capabilities for a device.
1481 /// 创建迭代器以遍历PCIe设备的external capability
1482 #[derive(Debug)]
1483 pub struct ExternalCapabilityIterator<'a> {
1484     pub root: &'a PciRoot,
1485     pub bus_device_function: BusDeviceFunction,
1486     pub next_capability_offset: Option<u16>,
1487 }
1488 impl<'a> Iterator for ExternalCapabilityIterator<'a> {
1489     type Item = ExternalCapabilityInfo;
1490     fn next(&mut self) -> Option<Self::Item> {
1491         let offset = self.next_capability_offset?;
1492 
1493         // Read the first 4 bytes of the capability.
1494         let capability_header = self.root.read_config(self.bus_device_function, offset);
1495         let id = capability_header as u16;
1496         let next_offset = (capability_header >> 20) as u16;
1497         let capability_version = ((capability_header >> 16) & 0xf) as u8;
1498 
1499         self.next_capability_offset = if next_offset == 0 {
1500             None
1501         } else if next_offset < 0x100 || next_offset & 0x3 != 0 {
1502             warn!("Invalid next capability offset {:#04x}", next_offset);
1503             None
1504         } else {
1505             Some(next_offset)
1506         };
1507 
1508         Some(ExternalCapabilityInfo {
1509             offset,
1510             id,
1511             capability_version,
1512         })
1513     }
1514 }
1515