xref: /DragonOS/kernel/src/driver/virtio/transport_pci.rs (revision 69715438f21c9a4da5198b92aee5c27aa8c44543) !
1 //! PCI transport for VirtIO.
2 
3 use crate::driver::base::device::DeviceId;
4 use crate::driver::pci::pci::{
5     BusDeviceFunction, PciDeviceStructure, PciDeviceStructureGeneralDevice, PciError,
6     PciStandardDeviceBar, PCI_CAP_ID_VNDR,
7 };
8 
9 use crate::driver::pci::root::pci_root_0;
10 
11 use crate::exception::IrqNumber;
12 
13 use crate::libs::volatile::{
14     volread, volwrite, ReadOnly, Volatile, VolatileReadable, VolatileWritable, WriteOnly,
15 };
16 use crate::mm::VirtAddr;
17 
18 use alloc::sync::Arc;
19 use core::{
20     fmt::{self, Display, Formatter},
21     mem::{align_of, size_of},
22     ptr::{self, addr_of_mut, NonNull},
23 };
24 use virtio_drivers::{
25     transport::{DeviceStatus, DeviceType, Transport},
26     Error, Hal, PhysAddr,
27 };
28 
29 use super::VIRTIO_VENDOR_ID;
30 
31 /// The offset to add to a VirtIO device ID to get the corresponding PCI device ID.
32 /// PCI Virtio设备的DEVICE_ID 的offset
33 const PCI_DEVICE_ID_OFFSET: u16 = 0x1040;
34 /// PCI Virtio 设备的DEVICE_ID及其对应的设备类型
35 const TRANSITIONAL_NETWORK: u16 = 0x1000;
36 const TRANSITIONAL_BLOCK: u16 = 0x1001;
37 const TRANSITIONAL_MEMORY_BALLOONING: u16 = 0x1002;
38 const TRANSITIONAL_CONSOLE: u16 = 0x1003;
39 const TRANSITIONAL_SCSI_HOST: u16 = 0x1004;
40 const TRANSITIONAL_ENTROPY_SOURCE: u16 = 0x1005;
41 const TRANSITIONAL_9P_TRANSPORT: u16 = 0x1009;
42 
43 /// The offset of the bar field within `virtio_pci_cap`.
44 const CAP_BAR_OFFSET: u8 = 4;
45 /// The offset of the offset field with `virtio_pci_cap`.
46 const CAP_BAR_OFFSET_OFFSET: u8 = 8;
47 /// The offset of the `length` field within `virtio_pci_cap`.
48 const CAP_LENGTH_OFFSET: u8 = 12;
49 /// The offset of the`notify_off_multiplier` field within `virtio_pci_notify_cap`.
50 const CAP_NOTIFY_OFF_MULTIPLIER_OFFSET: u8 = 16;
51 
52 /// Common configuration.
53 const VIRTIO_PCI_CAP_COMMON_CFG: u8 = 1;
54 /// Notifications.
55 const VIRTIO_PCI_CAP_NOTIFY_CFG: u8 = 2;
56 /// ISR Status.
57 const VIRTIO_PCI_CAP_ISR_CFG: u8 = 3;
58 /// Device specific configuration.
59 const VIRTIO_PCI_CAP_DEVICE_CFG: u8 = 4;
60 
61 /// Virtio设备接收中断的设备号
62 const VIRTIO_RECV_VECTOR: IrqNumber = IrqNumber::new(56);
63 /// Virtio设备接收中断的设备号的表项号
64 const VIRTIO_RECV_VECTOR_INDEX: u16 = 0;
65 // 接收的queue号
66 const QUEUE_RECEIVE: u16 = 0;
67 ///@brief device id 转换为设备类型
68 ///@param pci_device_id,device_id
69 ///@return DeviceType 对应的设备类型
device_type(pci_device_id: u16) -> DeviceType70 fn device_type(pci_device_id: u16) -> DeviceType {
71     match pci_device_id {
72         TRANSITIONAL_NETWORK => DeviceType::Network,
73         TRANSITIONAL_BLOCK => DeviceType::Block,
74         TRANSITIONAL_MEMORY_BALLOONING => DeviceType::MemoryBalloon,
75         TRANSITIONAL_CONSOLE => DeviceType::Console,
76         TRANSITIONAL_SCSI_HOST => DeviceType::ScsiHost,
77         TRANSITIONAL_ENTROPY_SOURCE => DeviceType::EntropySource,
78         TRANSITIONAL_9P_TRANSPORT => DeviceType::_9P,
79         id if id >= PCI_DEVICE_ID_OFFSET => DeviceType::from(id - PCI_DEVICE_ID_OFFSET),
80         _ => DeviceType::Invalid,
81     }
82 }
83 
84 /// PCI transport for VirtIO.
85 ///
86 /// Ref: 4.1 Virtio Over PCI Bus
87 #[allow(dead_code)]
88 #[derive(Debug, Clone)]
89 pub struct PciTransport {
90     device_type: DeviceType,
91     /// The bus, device and function identifier for the VirtIO device.
92     _bus_device_function: BusDeviceFunction,
93     /// The common configuration structure within some BAR.
94     common_cfg: NonNull<CommonCfg>,
95     /// The start of the queue notification region within some BAR.
96     notify_region: NonNull<[WriteOnly<u16>]>,
97     notify_off_multiplier: u32,
98     /// The ISR status register within some BAR.
99     isr_status: NonNull<Volatile<u8>>,
100     /// The VirtIO device-specific configuration within some BAR.
101     config_space: Option<NonNull<[u32]>>,
102     irq: IrqNumber,
103     dev_id: Arc<DeviceId>,
104     device: Arc<PciDeviceStructureGeneralDevice>,
105 }
106 
107 impl PciTransport {
108     /// Construct a new PCI VirtIO device driver for the given device function on the given PCI
109     /// root controller.
110     ///
111     /// ## 参数
112     ///
113     /// - `device` - The PCI device structure for the VirtIO device.
114     /// - `irq_handler` - An optional handler for the device's interrupt. If `None`, a default
115     ///     handler `DefaultVirtioIrqHandler` will be used.
116     /// - `irq_number_offset` - Currently, this parameter is just simple make a offset to the irq number, cause it's not be allowed to have the same irq number within different device
117     #[allow(clippy::extra_unused_type_parameters)]
new<H: Hal>( device: Arc<PciDeviceStructureGeneralDevice>, dev_id: Arc<DeviceId>, ) -> Result<Self, VirtioPciError>118     pub fn new<H: Hal>(
119         device: Arc<PciDeviceStructureGeneralDevice>,
120         dev_id: Arc<DeviceId>,
121     ) -> Result<Self, VirtioPciError> {
122         let irq = VIRTIO_RECV_VECTOR;
123         let header = &device.common_header;
124         let bus_device_function = header.bus_device_function;
125         if header.vendor_id != VIRTIO_VENDOR_ID {
126             return Err(VirtioPciError::InvalidVendorId(header.vendor_id));
127         }
128         let device_type = device_type(header.device_id);
129         // Find the PCI capabilities we need.
130         let mut common_cfg: Option<VirtioCapabilityInfo> = None;
131         let mut notify_cfg: Option<VirtioCapabilityInfo> = None;
132         let mut notify_off_multiplier = 0;
133         let mut isr_cfg = None;
134         let mut device_cfg = None;
135         device.bar_ioremap().unwrap()?;
136         device.enable_master();
137         let standard_device = device.as_standard_device().unwrap();
138         // 目前缺少对PCI设备中断号的统一管理,所以这里需要指定一个中断号。不能与其他中断重复
139         let irq_vector = standard_device.irq_vector_mut().unwrap();
140         irq_vector.write().push(irq);
141 
142         // panic!();
143         //device_capability为迭代器,遍历其相当于遍历所有的cap空间
144         for capability in device.capabilities().unwrap() {
145             if capability.id != PCI_CAP_ID_VNDR {
146                 continue;
147             }
148             let cap_len = capability.private_header as u8;
149             let cfg_type = (capability.private_header >> 8) as u8;
150             if cap_len < 16 {
151                 continue;
152             }
153             let struct_info = VirtioCapabilityInfo {
154                 bar: pci_root_0().read_config(
155                     bus_device_function,
156                     (capability.offset + CAP_BAR_OFFSET).into(),
157                 ) as u8,
158                 offset: pci_root_0().read_config(
159                     bus_device_function,
160                     (capability.offset + CAP_BAR_OFFSET_OFFSET).into(),
161                 ),
162                 length: pci_root_0().read_config(
163                     bus_device_function,
164                     (capability.offset + CAP_LENGTH_OFFSET).into(),
165                 ),
166             };
167 
168             match cfg_type {
169                 VIRTIO_PCI_CAP_COMMON_CFG if common_cfg.is_none() => {
170                     common_cfg = Some(struct_info);
171                 }
172                 VIRTIO_PCI_CAP_NOTIFY_CFG if cap_len >= 20 && notify_cfg.is_none() => {
173                     notify_cfg = Some(struct_info);
174                     notify_off_multiplier = pci_root_0().read_config(
175                         bus_device_function,
176                         (capability.offset + CAP_NOTIFY_OFF_MULTIPLIER_OFFSET).into(),
177                     );
178                 }
179                 VIRTIO_PCI_CAP_ISR_CFG if isr_cfg.is_none() => {
180                     isr_cfg = Some(struct_info);
181                 }
182                 VIRTIO_PCI_CAP_DEVICE_CFG if device_cfg.is_none() => {
183                     device_cfg = Some(struct_info);
184                 }
185                 _ => {}
186             }
187         }
188 
189         let common_cfg = get_bar_region::<_>(
190             &device.standard_device_bar.read(),
191             &common_cfg.ok_or(VirtioPciError::MissingCommonConfig)?,
192         )?;
193 
194         let notify_cfg = notify_cfg.ok_or(VirtioPciError::MissingNotifyConfig)?;
195         if notify_off_multiplier % 2 != 0 {
196             return Err(VirtioPciError::InvalidNotifyOffMultiplier(
197                 notify_off_multiplier,
198             ));
199         }
200         //debug!("notify.offset={},notify.length={}",notify_cfg.offset,notify_cfg.length);
201         let notify_region =
202             get_bar_region_slice::<_>(&device.standard_device_bar.read(), &notify_cfg)?;
203         let isr_status = get_bar_region::<_>(
204             &device.standard_device_bar.read(),
205             &isr_cfg.ok_or(VirtioPciError::MissingIsrConfig)?,
206         )?;
207         let config_space = if let Some(device_cfg) = device_cfg {
208             Some(get_bar_region_slice::<_>(
209                 &device.standard_device_bar.read(),
210                 &device_cfg,
211             )?)
212         } else {
213             None
214         };
215         Ok(Self {
216             device_type,
217             _bus_device_function: bus_device_function,
218             common_cfg,
219             notify_region,
220             notify_off_multiplier,
221             isr_status,
222             config_space,
223             irq,
224             dev_id,
225             device,
226         })
227     }
228 
pci_device(&self) -> Arc<PciDeviceStructureGeneralDevice>229     pub fn pci_device(&self) -> Arc<PciDeviceStructureGeneralDevice> {
230         self.device.clone()
231     }
232 
irq(&self) -> IrqNumber233     pub fn irq(&self) -> IrqNumber {
234         self.irq
235     }
236 }
237 
238 impl Transport for PciTransport {
device_type(&self) -> DeviceType239     fn device_type(&self) -> DeviceType {
240         self.device_type
241     }
242 
read_device_features(&mut self) -> u64243     fn read_device_features(&mut self) -> u64 {
244         // Safe because the common config pointer is valid and we checked in get_bar_region that it
245         // was aligned.
246         unsafe {
247             volwrite!(self.common_cfg, device_feature_select, 0);
248             let mut device_features_bits = volread!(self.common_cfg, device_feature) as u64;
249             volwrite!(self.common_cfg, device_feature_select, 1);
250             device_features_bits |= (volread!(self.common_cfg, device_feature) as u64) << 32;
251             device_features_bits
252         }
253     }
254 
write_driver_features(&mut self, driver_features: u64)255     fn write_driver_features(&mut self, driver_features: u64) {
256         // Safe because the common config pointer is valid and we checked in get_bar_region that it
257         // was aligned.
258         unsafe {
259             volwrite!(self.common_cfg, driver_feature_select, 0);
260             volwrite!(self.common_cfg, driver_feature, driver_features as u32);
261             volwrite!(self.common_cfg, driver_feature_select, 1);
262             volwrite!(
263                 self.common_cfg,
264                 driver_feature,
265                 (driver_features >> 32) as u32
266             );
267         }
268     }
269 
max_queue_size(&mut self, queue: u16) -> u32270     fn max_queue_size(&mut self, queue: u16) -> u32 {
271         unsafe {
272             volwrite!(self.common_cfg, queue_select, queue);
273             volread!(self.common_cfg, queue_size).into()
274         }
275     }
276 
notify(&mut self, queue: u16)277     fn notify(&mut self, queue: u16) {
278         // Safe because the common config and notify region pointers are valid and we checked in
279         // get_bar_region that they were aligned.
280         unsafe {
281             volwrite!(self.common_cfg, queue_select, queue);
282             // TODO: Consider caching this somewhere (per queue).
283             let queue_notify_off = volread!(self.common_cfg, queue_notify_off);
284 
285             let offset_bytes = usize::from(queue_notify_off) * self.notify_off_multiplier as usize;
286             let index = offset_bytes / size_of::<u16>();
287             addr_of_mut!((*self.notify_region.as_ptr())[index]).vwrite(queue);
288         }
289     }
290 
set_status(&mut self, status: DeviceStatus)291     fn set_status(&mut self, status: DeviceStatus) {
292         // Safe because the common config pointer is valid and we checked in get_bar_region that it
293         // was aligned.
294         unsafe {
295             volwrite!(self.common_cfg, device_status, status.bits() as u8);
296         }
297     }
298 
get_status(&self) -> DeviceStatus299     fn get_status(&self) -> DeviceStatus {
300         // Safe because the common config pointer is valid and we checked in get_bar_region that it
301         // was aligned.
302         unsafe { DeviceStatus::from_bits_truncate(volread!(self.common_cfg, device_status).into()) }
303     }
304 
set_guest_page_size(&mut self, _guest_page_size: u32)305     fn set_guest_page_size(&mut self, _guest_page_size: u32) {
306         // No-op, the PCI transport doesn't care.
307     }
requires_legacy_layout(&self) -> bool308     fn requires_legacy_layout(&self) -> bool {
309         false
310     }
queue_set( &mut self, queue: u16, size: u32, descriptors: PhysAddr, driver_area: PhysAddr, device_area: PhysAddr, )311     fn queue_set(
312         &mut self,
313         queue: u16,
314         size: u32,
315         descriptors: PhysAddr,
316         driver_area: PhysAddr,
317         device_area: PhysAddr,
318     ) {
319         // Safe because the common config pointer is valid and we checked in get_bar_region that it
320         // was aligned.
321         unsafe {
322             volwrite!(self.common_cfg, queue_select, queue);
323             volwrite!(self.common_cfg, queue_size, size as u16);
324             volwrite!(self.common_cfg, queue_desc, descriptors as u64);
325             volwrite!(self.common_cfg, queue_driver, driver_area as u64);
326             volwrite!(self.common_cfg, queue_device, device_area as u64);
327             // 这里设置队列中断对应的中断项
328             if queue == QUEUE_RECEIVE {
329                 volwrite!(self.common_cfg, queue_msix_vector, VIRTIO_RECV_VECTOR_INDEX);
330                 let vector = volread!(self.common_cfg, queue_msix_vector);
331                 if vector != VIRTIO_RECV_VECTOR_INDEX {
332                     panic!("Vector set failed");
333                 }
334             }
335             volwrite!(self.common_cfg, queue_enable, 1);
336         }
337     }
338 
queue_unset(&mut self, queue: u16)339     fn queue_unset(&mut self, queue: u16) {
340         // Safe because the common config pointer is valid and we checked in get_bar_region that it
341         // was aligned.
342         unsafe {
343             volwrite!(self.common_cfg, queue_select, queue);
344             volwrite!(self.common_cfg, queue_size, 0);
345             volwrite!(self.common_cfg, queue_desc, 0);
346             volwrite!(self.common_cfg, queue_driver, 0);
347             volwrite!(self.common_cfg, queue_device, 0);
348         }
349     }
350 
queue_used(&mut self, queue: u16) -> bool351     fn queue_used(&mut self, queue: u16) -> bool {
352         // Safe because the common config pointer is valid and we checked in get_bar_region that it
353         // was aligned.
354         unsafe {
355             volwrite!(self.common_cfg, queue_select, queue);
356             volread!(self.common_cfg, queue_enable) == 1
357         }
358     }
359 
ack_interrupt(&mut self) -> bool360     fn ack_interrupt(&mut self) -> bool {
361         // Safe because the common config pointer is valid and we checked in get_bar_region that it
362         // was aligned.
363         // Reading the ISR status resets it to 0 and causes the device to de-assert the interrupt.
364         let isr_status = unsafe { self.isr_status.as_ptr().vread() };
365         // TODO: Distinguish between queue interrupt and device configuration interrupt.
366         isr_status & 0x3 != 0
367     }
368 
config_space<T>(&self) -> Result<NonNull<T>, Error>369     fn config_space<T>(&self) -> Result<NonNull<T>, Error> {
370         if let Some(config_space) = self.config_space {
371             if size_of::<T>() > config_space.len() * size_of::<u32>() {
372                 Err(Error::ConfigSpaceTooSmall)
373             } else if align_of::<T>() > 4 {
374                 // Panic as this should only happen if the driver is written incorrectly.
375                 panic!(
376                     "Driver expected config space alignment of {} bytes, but VirtIO only guarantees 4 byte alignment.",
377                     align_of::<T>()
378                 );
379             } else {
380                 // TODO: Use NonNull::as_non_null_ptr once it is stable.
381                 let config_space_ptr = NonNull::new(config_space.as_ptr() as *mut u32).unwrap();
382                 Ok(config_space_ptr.cast())
383             }
384         } else {
385             Err(Error::ConfigSpaceMissing)
386         }
387     }
388 }
389 
390 impl Drop for PciTransport {
drop(&mut self)391     fn drop(&mut self) {
392         // Reset the device when the transport is dropped.
393         self.set_status(DeviceStatus::empty());
394 
395         // todo: 调用pci的中断释放函数,并且在virtio_irq_manager里面删除对应的设备的中断
396     }
397 }
398 
399 #[repr(C)]
400 struct CommonCfg {
401     device_feature_select: Volatile<u32>,
402     device_feature: ReadOnly<u32>,
403     driver_feature_select: Volatile<u32>,
404     driver_feature: Volatile<u32>,
405     msix_config: Volatile<u16>,
406     num_queues: ReadOnly<u16>,
407     device_status: Volatile<u8>,
408     config_generation: ReadOnly<u8>,
409     queue_select: Volatile<u16>,
410     queue_size: Volatile<u16>,
411     queue_msix_vector: Volatile<u16>,
412     queue_enable: Volatile<u16>,
413     queue_notify_off: Volatile<u16>,
414     queue_desc: Volatile<u64>,
415     queue_driver: Volatile<u64>,
416     queue_device: Volatile<u64>,
417 }
418 
419 /// Information about a VirtIO structure within some BAR, as provided by a `virtio_pci_cap`.
420 /// cfg空间在哪个bar的多少偏移处,长度多少
421 #[derive(Clone, Debug, Eq, PartialEq)]
422 struct VirtioCapabilityInfo {
423     /// The bar in which the structure can be found.
424     bar: u8,
425     /// The offset within the bar.
426     offset: u32,
427     /// The length in bytes of the structure within the bar.
428     length: u32,
429 }
430 
431 /// An error encountered initialising a VirtIO PCI transport.
432 /// VirtIO PCI transport 初始化时的错误
433 #[derive(Clone, Debug, Eq, PartialEq)]
434 pub enum VirtioPciError {
435     /// PCI device vender ID was not the VirtIO vendor ID.
436     InvalidVendorId(u16),
437     /// No valid `VIRTIO_PCI_CAP_COMMON_CFG` capability was found.
438     MissingCommonConfig,
439     /// No valid `VIRTIO_PCI_CAP_NOTIFY_CFG` capability was found.
440     MissingNotifyConfig,
441     /// `VIRTIO_PCI_CAP_NOTIFY_CFG` capability has a `notify_off_multiplier` that is not a multiple
442     /// of 2.
443     InvalidNotifyOffMultiplier(u32),
444     /// No valid `VIRTIO_PCI_CAP_ISR_CFG` capability was found.
445     MissingIsrConfig,
446     /// An IO BAR was provided rather than a memory BAR.
447     UnexpectedBarType,
448     /// A BAR which we need was not allocated an address.
449     BarNotAllocated(u8),
450     /// The offset for some capability was greater than the length of the BAR.
451     BarOffsetOutOfRange,
452     /// The virtual address was not aligned as expected.
453     Misaligned {
454         /// The virtual address in question.
455         vaddr: VirtAddr,
456         /// The expected alignment in bytes.
457         alignment: usize,
458     },
459     ///获取虚拟地址失败
460     BarGetVaddrFailed,
461     /// A generic PCI error,
462     Pci(PciError),
463 }
464 
465 impl Display for VirtioPciError {
fmt(&self, f: &mut Formatter) -> fmt::Result466     fn fmt(&self, f: &mut Formatter) -> fmt::Result {
467         match self {
468             Self::InvalidVendorId(vendor_id) => write!(
469                 f,
470                 "PCI device vender ID {:#06x} was not the VirtIO vendor ID {:#06x}.",
471                 vendor_id, VIRTIO_VENDOR_ID
472             ),
473             Self::MissingCommonConfig => write!(
474                 f,
475                 "No valid `VIRTIO_PCI_CAP_COMMON_CFG` capability was found."
476             ),
477             Self::MissingNotifyConfig => write!(
478                 f,
479                 "No valid `VIRTIO_PCI_CAP_NOTIFY_CFG` capability was found."
480             ),
481             Self::InvalidNotifyOffMultiplier(notify_off_multiplier) => {
482                 write!(
483                     f,
484                     "`VIRTIO_PCI_CAP_NOTIFY_CFG` capability has a `notify_off_multiplier` that is not a multiple of 2: {}",
485                     notify_off_multiplier
486                 )
487             }
488             Self::MissingIsrConfig => {
489                 write!(f, "No valid `VIRTIO_PCI_CAP_ISR_CFG` capability was found.")
490             }
491             Self::UnexpectedBarType => write!(f, "Unexpected BAR (expected memory BAR)."),
492             Self::BarNotAllocated(bar_index) => write!(f, "Bar {} not allocated.", bar_index),
493             Self::BarOffsetOutOfRange => write!(f, "Capability offset greater than BAR length."),
494             Self::Misaligned { vaddr, alignment } => write!(
495                 f,
496                 "Virtual address {:?} was not aligned to a {} byte boundary as expected.",
497                 vaddr, alignment
498             ),
499             Self::BarGetVaddrFailed => write!(f, "Get bar virtaddress failed"),
500             Self::Pci(pci_error) => pci_error.fmt(f),
501         }
502     }
503 }
504 
505 /// PCI error到VirtioPciError的转换,层层上报
506 impl From<PciError> for VirtioPciError {
from(error: PciError) -> Self507     fn from(error: PciError) -> Self {
508         Self::Pci(error)
509     }
510 }
511 
512 /// @brief 获取虚拟地址并将其转化为对应类型的指针
513 /// @param device_bar 存储bar信息的结构体 struct_info 存储cfg空间的位置信息
514 /// @return Result<NonNull<T>, VirtioPciError> 成功则返回对应类型的指针,失败则返回Error
get_bar_region<T>( device_bar: &PciStandardDeviceBar, struct_info: &VirtioCapabilityInfo, ) -> Result<NonNull<T>, VirtioPciError>515 fn get_bar_region<T>(
516     device_bar: &PciStandardDeviceBar,
517     struct_info: &VirtioCapabilityInfo,
518 ) -> Result<NonNull<T>, VirtioPciError> {
519     let bar_info = device_bar.get_bar(struct_info.bar)?;
520     let (bar_address, bar_size) = bar_info
521         .memory_address_size()
522         .ok_or(VirtioPciError::UnexpectedBarType)?;
523     if bar_address == 0 {
524         return Err(VirtioPciError::BarNotAllocated(struct_info.bar));
525     }
526     if struct_info.offset + struct_info.length > bar_size
527         || size_of::<T>() > struct_info.length as usize
528     {
529         return Err(VirtioPciError::BarOffsetOutOfRange);
530     }
531     //debug!("Chossed bar ={},used={}",struct_info.bar,struct_info.offset + struct_info.length);
532     let vaddr = (bar_info
533         .virtual_address()
534         .ok_or(VirtioPciError::BarGetVaddrFailed)?)
535         + struct_info.offset as usize;
536     if vaddr.data() % align_of::<T>() != 0 {
537         return Err(VirtioPciError::Misaligned {
538             vaddr,
539             alignment: align_of::<T>(),
540         });
541     }
542     let vaddr = NonNull::new(vaddr.data() as *mut u8).unwrap();
543     Ok(vaddr.cast())
544 }
545 
546 /// @brief 获取虚拟地址并将其转化为对应类型的切片的指针
547 /// @param device_bar 存储bar信息的结构体 struct_info 存储cfg空间的位置信息切片的指针
548 /// @return Result<NonNull<[T]>, VirtioPciError> 成功则返回对应类型的指针切片,失败则返回Error
get_bar_region_slice<T>( device_bar: &PciStandardDeviceBar, struct_info: &VirtioCapabilityInfo, ) -> Result<NonNull<[T]>, VirtioPciError>549 fn get_bar_region_slice<T>(
550     device_bar: &PciStandardDeviceBar,
551     struct_info: &VirtioCapabilityInfo,
552 ) -> Result<NonNull<[T]>, VirtioPciError> {
553     let ptr = get_bar_region::<T>(device_bar, struct_info)?;
554     // let raw_slice =
555     //     ptr::slice_from_raw_parts_mut(ptr.as_ptr(), struct_info.length as usize / size_of::<T>());
556     Ok(nonnull_slice_from_raw_parts(
557         ptr,
558         struct_info.length as usize / size_of::<T>(),
559     ))
560 }
561 
nonnull_slice_from_raw_parts<T>(data: NonNull<T>, len: usize) -> NonNull<[T]>562 fn nonnull_slice_from_raw_parts<T>(data: NonNull<T>, len: usize) -> NonNull<[T]> {
563     NonNull::new(ptr::slice_from_raw_parts_mut(data.as_ptr(), len)).unwrap()
564 }
565