xref: /DragonOS/kernel/src/exception/manage.rs (revision 52dc4c3ee87b31fee4f567f776fd8ad58fbfd9a5)
1 use core::ops::{BitXor, Deref, DerefMut};
2 
3 use alloc::{string::String, sync::Arc};
4 
5 use log::{debug, error, warn};
6 use system_error::SystemError;
7 
8 use crate::{
9     driver::base::device::DeviceId,
10     exception::{
11         irqchip::IrqChipSetMaskResult,
12         irqdesc::{irq_desc_manager, InnerIrqDesc, IrqAction},
13     },
14     libs::{cpumask::CpuMask, spinlock::SpinLockGuard},
15     process::{kthread::KernelThreadMechanism, ProcessManager},
16     smp::cpu::ProcessorId,
17 };
18 
19 use super::{
20     dummychip::no_irq_chip,
21     irqchip::IrqChipFlags,
22     irqdata::{IrqData, IrqHandlerData, IrqLineStatus, IrqStatus},
23     irqdesc::{InnerIrqAction, IrqDesc, IrqDescState, IrqHandleFlags, IrqHandler, IrqReturn},
24     irqdomain::irq_domain_manager,
25     IrqNumber,
26 };
27 
28 lazy_static! {
29     /// 默认的中断亲和性
30     static ref IRQ_DEFAULT_AFFINITY: CpuMask = {
31         let mut mask = CpuMask::new();
32         // 默认情况下,中断处理程序将在第一个处理器上运行
33         mask.set(ProcessorId::new(0), true);
34         mask
35     };
36 }
37 
38 pub fn irq_manager() -> &'static IrqManager {
39     &IrqManager
40 }
41 
42 /// 中断管理器
43 pub struct IrqManager;
44 
45 impl IrqManager {
46     pub const IRQ_RESEND: bool = true;
47     #[allow(dead_code)]
48     pub const IRQ_NORESEND: bool = false;
49     #[allow(dead_code)]
50     pub const IRQ_START_FORCE: bool = true;
51     pub const IRQ_START_COND: bool = false;
52 
53     /// 在中断线上添加一个处理函数
54     ///
55     /// ## 参数
56     ///
57     /// - irq: 虚拟中断号(中断线号)
58     /// - name: 生成该中断的设备名称
59     /// - handler: 中断处理函数
60     /// - flags: 中断处理标志
61     /// - dev_id: 一个用于标识设备的cookie
62     pub fn request_irq(
63         &self,
64         irq: IrqNumber,
65         name: String,
66         handler: &'static dyn IrqHandler,
67         flags: IrqHandleFlags,
68         dev_id: Option<Arc<DeviceId>>,
69     ) -> Result<(), SystemError> {
70         return self.request_threaded_irq(irq, Some(handler), None, flags, name, dev_id);
71     }
72 
73     /// 在中断线上添加一个处理函数(可以是线程化的中断)
74     ///
75     /// ## 参数
76     ///
77     /// - irq: 虚拟中断号
78     /// - handler: 当中断发生时将被调用的函数,是
79     ///     线程化中断的初级处理程序。如果handler为`None`并且thread_fn不为`None`,
80     ///    将安装默认的初级处理程序
81     /// - thread_fn: 在中断处理程序线程中调用的函数. 如果为`None`,则不会创建irq线程
82     /// - flags: 中断处理标志
83     ///     - IRQF_SHARED: 中断是共享的
84     ///     - IRQF_TRIGGER*: 指定中断触发方式
85     ///     - IRQF_ONESHOT: 在thread_fn中运行时,中断线被遮蔽
86     /// - dev_name: 生成该中断的设备名称
87     /// - dev_id: 一个用于标识设备的cookie
88     ///
89     /// ## 说明
90     ///
91     /// 此调用分配中断资源并启用中断线和IRQ处理。
92     /// 从这一点开始,您的处理程序函数可能会被调用。
93     /// 因此,您必须确保首先初始化您的硬件,
94     /// 并确保以正确的顺序设置中断处理程序。
95     ///
96     /// 如果您想为您的设备设置线程化中断处理程序
97     /// 则需要提供@handler和@thread_fn。@handler仍然
98     /// 在硬中断上下文中调用,并且必须检查
99     /// 中断是否来自设备。如果是,它需要禁用设备上的中断
100     /// 并返回IRQ_WAKE_THREAD,这将唤醒处理程序线程并运行
101     /// @thread_fn。这种拆分处理程序设计是为了支持
102     /// 共享中断。
103     ///
104     /// dev_id必须是全局唯一的。通常使用设备数据结构的地址或者uuid
105     /// 作为cookie。由于处理程序接收这个值,因此使用它是有意义的。
106     ///
107     /// 如果您的中断是共享的,您必须传递一个非NULL的dev_id
108     /// 因为当释放中断时需要它。
109     pub fn request_threaded_irq(
110         &self,
111         irq: IrqNumber,
112         mut handler: Option<&'static dyn IrqHandler>,
113         thread_fn: Option<&'static dyn IrqHandler>,
114         flags: IrqHandleFlags,
115         dev_name: String,
116         dev_id: Option<Arc<DeviceId>>,
117     ) -> Result<(), SystemError> {
118         if irq == IrqNumber::IRQ_NOTCONNECTED {
119             return Err(SystemError::ENOTCONN);
120         }
121 
122         // 逻辑检查:共享中断必须传入一个真正的设备ID,
123         // 否则后来我们将难以确定哪个中断是哪个(会搞乱中断释放逻辑等)。
124         // 此外,共享中断与禁用自动使能不相符。 共享中断可能在仍然禁用时请求它,然后永远等待中断。
125         // 另外,IRQF_COND_SUSPEND 仅适用于共享中断,并且它不能与 IRQF_NO_SUSPEND 同时设置。
126 
127         if ((flags.contains(IrqHandleFlags::IRQF_SHARED)) && dev_id.is_none())
128             || ((flags.contains(IrqHandleFlags::IRQF_SHARED))
129                 && (flags.contains(IrqHandleFlags::IRQF_NO_AUTOEN)))
130             || (!(flags.contains(IrqHandleFlags::IRQF_SHARED))
131                 && (flags.contains(IrqHandleFlags::IRQF_COND_SUSPEND)))
132             || ((flags.contains(IrqHandleFlags::IRQF_NO_SUSPEND))
133                 && (flags.contains(IrqHandleFlags::IRQF_COND_SUSPEND)))
134         {
135             return Err(SystemError::EINVAL);
136         }
137         let desc = irq_desc_manager().lookup(irq).ok_or(SystemError::EINVAL)?;
138         if !desc.can_request() {
139             warn!("desc {} can not request", desc.irq().data());
140             return Err(SystemError::EINVAL);
141         }
142 
143         if handler.is_none() {
144             if thread_fn.is_none() {
145                 // 不允许中断处理函数和线程处理函数都为空
146                 return Err(SystemError::EINVAL);
147             }
148 
149             // 如果中断处理函数为空,线程处理函数不为空,则使用默认的中断处理函数
150             handler = Some(&DefaultPrimaryIrqHandler);
151         }
152 
153         let irqaction = IrqAction::new(irq, dev_name, handler, thread_fn);
154 
155         let mut action_guard = irqaction.inner();
156         *action_guard.flags_mut() = flags;
157         *action_guard.dev_id_mut() = dev_id;
158         drop(action_guard);
159         debug!("to inner_setup_irq: {irq:?}");
160         return self.inner_setup_irq(irq, irqaction, desc);
161     }
162 
163     /// 参考 https://code.dragonos.org.cn/xref/linux-6.1.9/kernel/irq/manage.c?r=&mo=59252&fi=2138#1497
164     #[inline(never)]
165     fn inner_setup_irq(
166         &self,
167         irq: IrqNumber,
168         action: Arc<IrqAction>,
169         desc: Arc<IrqDesc>,
170     ) -> Result<(), SystemError> {
171         // ==== 定义错误处理函数 ====
172         let err_out_thread =
173             |e: SystemError, mut action_guard: SpinLockGuard<'_, InnerIrqAction>| -> SystemError {
174                 if let Some(thread_pcb) = action_guard.thread() {
175                     action_guard.set_thread(None);
176                     KernelThreadMechanism::stop(&thread_pcb).ok();
177                 }
178 
179                 if let Some(secondary) = action_guard.secondary() {
180                     let mut secondary_guard = secondary.inner();
181                     if let Some(thread_pcb) = secondary_guard.thread() {
182                         secondary_guard.set_thread(None);
183                         KernelThreadMechanism::stop(&thread_pcb).ok();
184                     }
185                 }
186                 return e;
187             };
188 
189         let err_out_bus_unlock = |e: SystemError,
190                                   desc: Arc<IrqDesc>,
191                                   req_mutex_guard: crate::libs::mutex::MutexGuard<'_, ()>,
192                                   action_guard: SpinLockGuard<'_, InnerIrqAction>|
193          -> SystemError {
194             desc.chip_bus_sync_unlock();
195             drop(req_mutex_guard);
196             return err_out_thread(e, action_guard);
197         };
198 
199         let err_out_unlock = |e: SystemError,
200                               desc_guard: SpinLockGuard<'_, InnerIrqDesc>,
201                               desc: Arc<IrqDesc>,
202                               req_mutex_guard: crate::libs::mutex::MutexGuard<'_, ()>,
203                               action_guard: SpinLockGuard<'_, InnerIrqAction>|
204          -> SystemError {
205             drop(desc_guard);
206             return err_out_bus_unlock(e, desc, req_mutex_guard, action_guard);
207         };
208 
209         let err_out_mismatch = |old_action_guard: SpinLockGuard<'_, InnerIrqAction>,
210                                 desc_guard: SpinLockGuard<'_, InnerIrqDesc>,
211                                 action_guard: SpinLockGuard<'_, InnerIrqAction>,
212                                 desc: Arc<IrqDesc>,
213                                 req_mutex_guard: crate::libs::mutex::MutexGuard<'_, ()>|
214          -> SystemError {
215             if !action_guard
216                 .flags()
217                 .contains(IrqHandleFlags::IRQF_PROBE_SHARED)
218             {
219                 error!("Flags mismatch for irq {} (name: {}, flags: {:?}). old action name: {}, old flags: {:?}", irq.data(), action_guard.name(), action_guard.flags(), old_action_guard.name(), old_action_guard.flags());
220             }
221             return err_out_unlock(
222                 SystemError::EBUSY,
223                 desc_guard,
224                 desc,
225                 req_mutex_guard,
226                 action_guard,
227             );
228         };
229 
230         // ===== 代码开始 =====
231 
232         if Arc::ptr_eq(
233             &desc.irq_data().chip_info_read_irqsave().chip(),
234             &no_irq_chip(),
235         ) {
236             return Err(SystemError::ENOSYS);
237         }
238 
239         let mut action_guard = action.inner();
240         if !action_guard.flags().trigger_type_specified() {
241             // 如果没有指定触发类型,则使用默认的触发类型
242             action_guard
243                 .flags_mut()
244                 .insert_trigger_type(desc.irq_data().common_data().trigger_type())
245         }
246 
247         let nested = desc.nested_thread();
248 
249         if nested {
250             if action_guard.thread_fn().is_none() {
251                 return Err(SystemError::EINVAL);
252             }
253 
254             action_guard.set_handler(Some(&IrqNestedPrimaryHandler));
255         } else if desc.can_thread() {
256             self.setup_forced_threading(action_guard.deref_mut())?;
257         }
258 
259         // 如果具有中断线程处理程序,并且中断不是嵌套的,则设置中断线程
260         if action_guard.thread_fn().is_some() && !nested {
261             self.setup_irq_thread(irq, action_guard.deref(), false)?;
262 
263             if let Some(secondary) = action_guard.secondary() {
264                 let secondary_guard = secondary.inner();
265                 if let Err(e) = self.setup_irq_thread(irq, secondary_guard.deref(), true) {
266                     return Err(err_out_thread(e, action_guard));
267                 }
268             }
269         }
270 
271         // Drivers are often written to work w/o knowledge about the
272         // underlying irq chip implementation, so a request for a
273         // threaded irq without a primary hard irq context handler
274         // requires the ONESHOT flag to be set. Some irq chips like
275         // MSI based interrupts are per se one shot safe. Check the
276         // chip flags, so we can avoid the unmask dance at the end of
277         // the threaded handler for those.
278 
279         if desc
280             .irq_data()
281             .chip_info_read_irqsave()
282             .chip()
283             .flags()
284             .contains(IrqChipFlags::IRQCHIP_ONESHOT_SAFE)
285         {
286             *action_guard.flags_mut() &= !IrqHandleFlags::IRQF_ONESHOT;
287         }
288 
289         // Protects against a concurrent __free_irq() call which might wait
290         // for synchronize_hardirq() to complete without holding the optional
291         // chip bus lock and desc->lock. Also protects against handing out
292         // a recycled oneshot thread_mask bit while it's still in use by
293         // its previous owner.
294         let req_mutex_guard = desc.request_mutex_lock();
295 
296         // Acquire bus lock as the irq_request_resources() callback below
297         // might rely on the serialization or the magic power management
298         // functions which are abusing the irq_bus_lock() callback,
299         desc.chip_bus_lock();
300 
301         // 如果当前中断线上还没有irqaction, 则先为中断线申请资源
302         if desc.actions().is_empty() {
303             if let Err(e) = self.irq_request_resources(desc.clone()) {
304                 error!(
305                     "Failed to request resources for {} (irq {}) on irqchip {}, error {:?}",
306                     action_guard.name(),
307                     irq.data(),
308                     desc.irq_data().chip_info_read_irqsave().chip().name(),
309                     e
310                 );
311                 return Err(err_out_bus_unlock(
312                     e,
313                     desc.clone(),
314                     req_mutex_guard,
315                     action_guard,
316                 ));
317             }
318         }
319 
320         let mut desc_inner_guard: SpinLockGuard<'_, InnerIrqDesc> = desc.inner();
321 
322         // 标记当前irq是否是共享的
323         let mut irq_shared = false;
324         if !desc_inner_guard.actions().is_empty() {
325             // 除非双方都同意并且是相同类型(级别、边沿、极性),否则不能共享中断。
326             // 因此,两个标志字段都必须设置IRQF_SHARED,并且设置触发类型的位必须匹配。
327             // 另外,所有各方都必须就ONESHOT达成一致。
328             // NMI用途的中断线不能共享。
329             if desc_inner_guard
330                 .internal_state()
331                 .contains(IrqDescState::IRQS_NMI)
332             {
333                 error!(
334                     "Invalid attempt to share NMI for {} (irq {}) on irqchip {}",
335                     action_guard.name(),
336                     irq.data(),
337                     desc_inner_guard
338                         .irq_data()
339                         .chip_info_read_irqsave()
340                         .chip()
341                         .name()
342                 );
343                 return Err(err_out_unlock(
344                     SystemError::EINVAL,
345                     desc_inner_guard,
346                     desc.clone(),
347                     req_mutex_guard,
348                     action_guard,
349                 ));
350             }
351 
352             let irq_data = desc_inner_guard.irq_data();
353 
354             let old_trigger_type: super::irqdata::IrqLineStatus;
355             let status = irq_data.common_data().status();
356             if status.trigger_type_was_set() {
357                 old_trigger_type = status.trigger_type();
358             } else {
359                 old_trigger_type = action_guard.flags().trigger_type();
360                 irq_data.common_data().set_trigger_type(old_trigger_type);
361             }
362 
363             let old = &desc_inner_guard.actions()[0].clone();
364             let old_guard = old.inner();
365 
366             if (!(old_guard
367                 .flags()
368                 .intersection(*action_guard.flags())
369                 .contains(IrqHandleFlags::IRQF_SHARED)))
370                 || (old_trigger_type != (action_guard.flags().trigger_type()))
371                 || ((old_guard.flags().bitxor(*action_guard.flags()))
372                     .contains(IrqHandleFlags::IRQF_ONESHOT))
373             {
374                 debug!(
375                     "Flags mismatch for irq {} (name: {}, flags: {:?}). old action name: {}, old flags: {:?}",
376                     irq.data(),
377                     action_guard.name(),
378                     action_guard.flags(),
379                     old_guard.name(),
380                     old_guard.flags()
381                 );
382 
383                 return Err(err_out_mismatch(
384                     old_guard,
385                     desc_inner_guard,
386                     action_guard,
387                     desc.clone(),
388                     req_mutex_guard,
389                 ));
390             }
391 
392             // all handlers must agree on per-cpuness
393             if *old_guard.flags() & IrqHandleFlags::IRQF_PERCPU
394                 != *action_guard.flags() & IrqHandleFlags::IRQF_PERCPU
395             {
396                 debug!(
397                     "Per-cpu mismatch for irq {} (name: {}, flags: {:?})",
398                     irq.data(),
399                     action_guard.name(),
400                     action_guard.flags()
401                 );
402                 return Err(err_out_mismatch(
403                     old_guard,
404                     desc_inner_guard,
405                     action_guard,
406                     desc.clone(),
407                     req_mutex_guard,
408                 ));
409             }
410 
411             irq_shared = true;
412         }
413 
414         if action_guard.flags().contains(IrqHandleFlags::IRQF_ONESHOT) {
415             // todo: oneshot
416         } else if action_guard.handler().is_some_and(|h| {
417             h.type_id() == (&DefaultPrimaryIrqHandler as &dyn IrqHandler).type_id()
418         }) && !desc_inner_guard
419             .irq_data()
420             .chip_info_read_irqsave()
421             .chip()
422             .flags()
423             .contains(IrqChipFlags::IRQCHIP_ONESHOT_SAFE)
424         {
425             // 请求中断时 hander = NULL,因此我们为其使用默认的主处理程序。
426             // 但它没有设置ONESHOT标志。与电平触发中断结合时,
427             // 这是致命的,因为默认的主处理程序只是唤醒线程,然后重新启用 irq 线路,
428             // 但设备仍然保持电平中断生效。周而复始....
429             // 虽然这对于边缘类型中断来说可行,但我们为了安全起见,不加条件地拒绝,
430             // 因为我们不能确定这个中断实际上具有什么类型。
431             // 由于底层芯片实现可能会覆盖它们,所以类型标志并不可靠.
432 
433             error!(
434                 "Requesting irq {} without a handler, and ONESHOT flags not set for irqaction: {}",
435                 irq.data(),
436                 action_guard.name()
437             );
438             return Err(err_out_unlock(
439                 SystemError::EINVAL,
440                 desc_inner_guard,
441                 desc.clone(),
442                 req_mutex_guard,
443                 action_guard,
444             ));
445         }
446 
447         // 第一次在当前irqdesc上注册中断处理函数
448         if !irq_shared {
449             // 设置中断触发方式
450             if action_guard.flags().trigger_type_specified() {
451                 let trigger_type = action_guard.flags().trigger_type();
452                 if let Err(e) =
453                     self.do_set_irq_trigger(desc.clone(), &mut desc_inner_guard, trigger_type)
454                 {
455                     debug!(
456                         "Failed to set trigger type for irq {} (name: {}, flags: {:?}), error {:?}",
457                         irq.data(),
458                         action_guard.name(),
459                         action_guard.flags(),
460                         e
461                     );
462                     return Err(err_out_unlock(
463                         e,
464                         desc_inner_guard,
465                         desc.clone(),
466                         req_mutex_guard,
467                         action_guard,
468                     ));
469                 }
470             }
471             debug!("to irq_activate");
472             // 激活中断。这种激活必须独立于IRQ_NOAUTOEN进行*desc_inner_guard.internal_state_mut() |= IrqDescState::IRQS_NOREQUEST;uest.
473             if let Err(e) = self.irq_activate(&desc, &mut desc_inner_guard) {
474                 debug!(
475                     "Failed to activate irq {} (name: {}, flags: {:?}), error {:?}",
476                     irq.data(),
477                     action_guard.name(),
478                     action_guard.flags(),
479                     e
480                 );
481                 return Err(err_out_unlock(
482                     e,
483                     desc_inner_guard,
484                     desc.clone(),
485                     req_mutex_guard,
486                     action_guard,
487                 ));
488             }
489 
490             *desc_inner_guard.internal_state_mut() &= !(IrqDescState::IRQS_AUTODETECT
491                 | IrqDescState::IRQS_SPURIOUS_DISABLED
492                 | IrqDescState::IRQS_ONESHOT
493                 | IrqDescState::IRQS_WAITING);
494             desc_inner_guard
495                 .common_data()
496                 .clear_status(IrqStatus::IRQD_IRQ_INPROGRESS);
497 
498             if action_guard.flags().contains(IrqHandleFlags::IRQF_PERCPU) {
499                 desc_inner_guard
500                     .common_data()
501                     .insert_status(IrqStatus::IRQD_PER_CPU);
502                 desc_inner_guard.line_status_set_per_cpu();
503 
504                 if action_guard.flags().contains(IrqHandleFlags::IRQF_NO_DEBUG) {
505                     desc_inner_guard.line_status_set_no_debug();
506                 }
507             }
508 
509             if action_guard.flags().contains(IrqHandleFlags::IRQF_ONESHOT) {
510                 *desc_inner_guard.internal_state_mut() |= IrqDescState::IRQS_ONESHOT;
511             }
512 
513             // 如果有要求的话,则忽略IRQ的均衡。
514             if action_guard
515                 .flags()
516                 .contains(IrqHandleFlags::IRQF_NOBALANCING)
517             {
518                 todo!("IRQF_NO_BALANCING");
519             }
520 
521             if !action_guard
522                 .flags()
523                 .contains(IrqHandleFlags::IRQF_NO_AUTOEN)
524                 && desc_inner_guard.can_autoenable()
525             {
526                 // 如果没有设置IRQF_NOAUTOEN,则自动使能中断
527                 self.irq_startup(
528                     &desc,
529                     &mut desc_inner_guard,
530                     Self::IRQ_RESEND,
531                     Self::IRQ_START_COND,
532                 )
533                 .ok();
534             } else {
535                 // 共享中断与禁用自动使能不太兼容。
536                 // 共享中断可能在它仍然被禁用时请求它,然后永远等待中断。
537 
538                 static mut WARNED: bool = false;
539                 if action_guard.flags().contains(IrqHandleFlags::IRQF_SHARED) && unsafe { !WARNED }
540                 {
541                     warn!(
542                         "Shared interrupt {} for {} requested but not auto enabled",
543                         irq.data(),
544                         action_guard.name()
545                     );
546                     unsafe { WARNED = true };
547                 }
548 
549                 desc_inner_guard.set_depth(1);
550             }
551         } else if action_guard.flags().trigger_type_specified() {
552             let new_trigger_type = action_guard.flags().trigger_type();
553             let old_trigger_type = desc_inner_guard.common_data().trigger_type();
554             if new_trigger_type != old_trigger_type {
555                 warn!("Irq {} uses trigger type: {old_trigger_type:?}, but requested trigger type: {new_trigger_type:?}.", irq.data());
556             }
557         }
558 
559         // 在队列末尾添加新的irqaction
560         desc_inner_guard.add_action(action.clone());
561 
562         // 检查我们是否曾经通过虚构的中断处理程序禁用过irq。重新启用它并再给它一次机会。
563         if irq_shared
564             && desc_inner_guard
565                 .internal_state()
566                 .contains(IrqDescState::IRQS_SPURIOUS_DISABLED)
567         {
568             desc_inner_guard
569                 .internal_state_mut()
570                 .remove(IrqDescState::IRQS_SPURIOUS_DISABLED);
571             self.do_enable_irq(desc.clone(), &mut desc_inner_guard).ok();
572         }
573 
574         drop(desc_inner_guard);
575         desc.chip_bus_sync_unlock();
576         drop(req_mutex_guard);
577 
578         drop(action_guard);
579         self.wake_up_and_wait_for_irq_thread_ready(&desc, Some(action.clone()));
580         self.wake_up_and_wait_for_irq_thread_ready(&desc, action.inner().secondary());
581         return Ok(());
582     }
583 
584     /// 唤醒中断线程并等待中断线程准备好
585     ///
586     /// ## 参数
587     ///
588     /// - desc: 中断描述符
589     /// - action: 要唤醒的中断处理函数
590     ///
591     /// ## 锁
592     ///
593     /// 进入当前函数时,`action`的锁需要被释放
594     fn wake_up_and_wait_for_irq_thread_ready(
595         &self,
596         desc: &Arc<IrqDesc>,
597         action: Option<Arc<IrqAction>>,
598     ) {
599         if action.is_none() {
600             return;
601         }
602 
603         let action = action.unwrap();
604 
605         let action_guard = action.inner();
606         if action_guard.thread().is_none() {
607             return;
608         }
609 
610         ProcessManager::wakeup(&action_guard.thread().unwrap()).ok();
611         drop(action_guard);
612         action
613             .thread_completion()
614             .wait_for_completion()
615             .map_err(|e| {
616                 warn!(
617                     "Failed to wait for irq thread ready for {} (irq {:?}), error {:?}",
618                     action.inner().name(),
619                     desc.irq_data().irq(),
620                     e
621                 );
622             })
623             .ok();
624     }
625 
626     pub(super) fn irq_activate_and_startup(
627         &self,
628         desc: &Arc<IrqDesc>,
629         desc_inner_guard: &mut SpinLockGuard<'_, InnerIrqDesc>,
630         resend: bool,
631     ) -> Result<(), SystemError> {
632         debug!(
633             "irq_activate_and_startup: irq: {}, name: {:?}",
634             desc.irq().data(),
635             desc_inner_guard.name()
636         );
637         self.irq_activate(desc, desc_inner_guard)?;
638         self.irq_startup(desc, desc_inner_guard, resend, Self::IRQ_START_FORCE)
639     }
640 
641     pub(super) fn irq_activate(
642         &self,
643         _desc: &Arc<IrqDesc>,
644         desc_inner_guard: &mut SpinLockGuard<'_, InnerIrqDesc>,
645     ) -> Result<(), SystemError> {
646         let irq_data = desc_inner_guard.irq_data();
647 
648         if !desc_inner_guard.common_data().status().affinity_managed() {
649             return irq_domain_manager().activate_irq(irq_data, false);
650         }
651 
652         return Ok(());
653     }
654 
655     /// 设置CPU亲和性并开启中断
656     pub(super) fn irq_startup(
657         &self,
658         desc: &Arc<IrqDesc>,
659         desc_inner_guard: &mut SpinLockGuard<'_, InnerIrqDesc>,
660         resend: bool,
661         force: bool,
662     ) -> Result<(), SystemError> {
663         debug!(
664             "irq_startup: irq: {}, name: {:?}",
665             desc_inner_guard.irq_data().irq().data(),
666             desc_inner_guard.name()
667         );
668         let mut ret = Ok(());
669         let irq_data = desc_inner_guard.irq_data().clone();
670         let affinity = desc_inner_guard.common_data().affinity();
671         desc_inner_guard.set_depth(0);
672 
673         if desc_inner_guard.common_data().status().started() {
674             self.irq_enable(desc_inner_guard);
675         } else {
676             match self.__irq_startup_managed(desc_inner_guard, &affinity, force) {
677                 IrqStartupResult::Normal => {
678                     if irq_data
679                         .chip_info_read_irqsave()
680                         .chip()
681                         .flags()
682                         .contains(IrqChipFlags::IRQCHIP_AFFINITY_PRE_STARTUP)
683                     {
684                         self.irq_setup_affinity(desc, desc_inner_guard).ok();
685                     }
686 
687                     ret = self.__irq_startup(desc_inner_guard);
688 
689                     if !irq_data
690                         .chip_info_read_irqsave()
691                         .chip()
692                         .flags()
693                         .contains(IrqChipFlags::IRQCHIP_AFFINITY_PRE_STARTUP)
694                     {
695                         self.irq_setup_affinity(desc, desc_inner_guard).ok();
696                     }
697                 }
698                 IrqStartupResult::Managed => {
699                     self.irq_do_set_affinity(&irq_data, desc_inner_guard, &affinity, false)
700                         .ok();
701                     ret = self.__irq_startup(desc_inner_guard);
702                 }
703                 IrqStartupResult::Abort => {
704                     desc_inner_guard
705                         .common_data()
706                         .insert_status(IrqStatus::IRQD_MANAGED_SHUTDOWN);
707                     return Ok(());
708                 }
709             }
710         }
711 
712         if resend {
713             if let Err(e) = self.irq_check_and_resend(desc_inner_guard, false) {
714                 error!(
715                     "Failed to check and resend irq {}, error {:?}",
716                     irq_data.irq().data(),
717                     e
718                 );
719             }
720         }
721 
722         return ret;
723     }
724 
725     pub fn irq_enable(&self, desc_inner_guard: &SpinLockGuard<'_, InnerIrqDesc>) {
726         let common_data = desc_inner_guard.common_data();
727         if !common_data.status().disabled() {
728             self.unmask_irq(desc_inner_guard);
729         } else {
730             common_data.clear_disabled();
731 
732             let chip = desc_inner_guard.irq_data().chip_info_read_irqsave().chip();
733 
734             if let Err(e) = chip.irq_enable(desc_inner_guard.irq_data()) {
735                 if e == SystemError::ENOSYS {
736                     self.unmask_irq(desc_inner_guard);
737                 }
738                 error!(
739                     "Failed to enable irq {} (name: {:?}), error {:?}",
740                     desc_inner_guard.irq_data().irq().data(),
741                     desc_inner_guard.name(),
742                     e
743                 );
744             } else {
745                 common_data.clear_masked();
746             }
747         }
748     }
749 
750     /// 自动设置中断的CPU亲和性
751     ///
752     ///
753     /// 参考 https://code.dragonos.org.cn/xref/linux-6.1.9/kernel/irq/manage.c#589
754     pub fn irq_setup_affinity(
755         &self,
756         _desc: &Arc<IrqDesc>,
757         desc_inner_guard: &mut SpinLockGuard<'_, InnerIrqDesc>,
758     ) -> Result<(), SystemError> {
759         let common_data = desc_inner_guard.common_data();
760         if !desc_inner_guard.can_set_affinity() {
761             return Ok(());
762         }
763 
764         let mut to_set = IRQ_DEFAULT_AFFINITY.clone();
765         if common_data.status().affinity_managed()
766             || common_data.status().contains(IrqStatus::IRQD_AFFINITY_SET)
767         {
768             // FIXME: 要判断affinity跟已上线的CPU是否有交集
769 
770             let irq_aff = common_data.affinity();
771             if irq_aff.is_empty() {
772                 common_data.clear_status(IrqStatus::IRQD_AFFINITY_SET);
773             } else {
774                 to_set = irq_aff;
775             }
776         }
777 
778         // FIXME: 求to_set和在线CPU的交集
779 
780         return self.irq_do_set_affinity(
781             desc_inner_guard.irq_data(),
782             desc_inner_guard,
783             &to_set,
784             false,
785         );
786     }
787 
788     pub fn irq_set_affinity(
789         &self,
790         irq_data: &Arc<IrqData>,
791         desc_inner_guard: &SpinLockGuard<'_, InnerIrqDesc>,
792         cpumask: &CpuMask,
793     ) -> Result<(), SystemError> {
794         return self.irq_do_set_affinity(irq_data, desc_inner_guard, cpumask, false);
795     }
796     fn irq_do_set_affinity(
797         &self,
798         irq_data: &Arc<IrqData>,
799         desc_inner_guard: &SpinLockGuard<'_, InnerIrqDesc>,
800         cpumask: &CpuMask,
801         force: bool,
802     ) -> Result<(), SystemError> {
803         let chip = irq_data.chip_info_read_irqsave().chip();
804         if !chip.can_set_affinity() {
805             return Err(SystemError::EINVAL);
806         }
807 
808         // todo: 处理CPU中断隔离相关的逻辑
809 
810         let common_data = desc_inner_guard.common_data();
811         let r = if force || !cpumask.is_empty() {
812             chip.irq_set_affinity(irq_data, cpumask, force)
813         } else {
814             return Err(SystemError::EINVAL);
815         };
816 
817         let mut ret = Ok(());
818         if let Ok(rs) = r {
819             match rs {
820                 IrqChipSetMaskResult::Success | IrqChipSetMaskResult::Done => {
821                     common_data.set_affinity(cpumask.clone());
822                 }
823                 IrqChipSetMaskResult::NoChange => {
824 
825                     // irq_validate_effective_affinity(data);
826                     // irq_set_thread_affinity(desc);
827                 }
828             }
829         } else {
830             ret = Err(r.unwrap_err());
831         }
832 
833         return ret;
834     }
835 
836     fn __irq_startup(
837         &self,
838         desc_inner_guard: &SpinLockGuard<'_, InnerIrqDesc>,
839     ) -> Result<(), SystemError> {
840         let common_data = desc_inner_guard.common_data();
841 
842         if let Err(e) = desc_inner_guard
843             .irq_data()
844             .chip_info_read_irqsave()
845             .chip()
846             .irq_startup(desc_inner_guard.irq_data())
847         {
848             if e == SystemError::ENOSYS {
849                 self.irq_enable(desc_inner_guard);
850             } else {
851                 return Err(e);
852             }
853         } else {
854             common_data.clear_disabled();
855             common_data.clear_masked();
856         }
857 
858         common_data.set_started();
859 
860         return Ok(());
861     }
862 
863     fn __irq_startup_managed(
864         &self,
865         desc_inner_guard: &SpinLockGuard<'_, InnerIrqDesc>,
866         _affinity: &CpuMask,
867         _force: bool,
868     ) -> IrqStartupResult {
869         let irq_data = desc_inner_guard.irq_data();
870         let common_data = desc_inner_guard.common_data();
871 
872         if !common_data.status().affinity_managed() {
873             return IrqStartupResult::Normal;
874         }
875 
876         common_data.clear_managed_shutdown();
877 
878         /*
879             - 检查Affinity掩码是否包括所有的在线CPU。如果是,这意味着有代码试图在管理的中断上使用enable_irq(),
880                 这可能是非法的。在这种情况下,如果force不是真值,函数会返回IRQ_STARTUP_ABORT,表示中断处理应该被放弃。
881             - 如果Affinity掩码中没有任何在线的CPU,那么中断请求是不可用的,因为没有任何CPU可以处理它。
882                 在这种情况下,如果force不是真值,函数同样会返回IRQ_STARTUP_ABORT。
883             - 如果以上条件都不满足,尝试激活中断,并将其设置为管理模式。这是通过调用 `irq_domain_manager().activate_irq()` 函数来实现的。
884                 如果这个调用失败,表示有保留的资源无法访问,函数会返回IRQ_STARTUP_ABORT。
885             - 如果一切顺利,函数会返回IRQ_STARTUP_MANAGED,表示中断已经被成功管理并激活。
886         */
887 
888         // if (cpumask_any_and(aff, cpu_online_mask) >= nr_cpu_ids) {
889         //     /*
890         //      * Catch code which fiddles with enable_irq() on a managed
891         //      * and potentially shutdown IRQ. Chained interrupt
892         //      * installment or irq auto probing should not happen on
893         //      * managed irqs either.
894         //      */
895         //     if (WARN_ON_ONCE(force))
896         //         return IRQ_STARTUP_ABORT;
897         //     /*
898         //      * The interrupt was requested, but there is no online CPU
899         //      * in it's affinity mask. Put it into managed shutdown
900         //      * state and let the cpu hotplug mechanism start it up once
901         //      * a CPU in the mask becomes available.
902         //      */
903         //     return IRQ_STARTUP_ABORT;
904         // }
905 
906         let r = irq_domain_manager().activate_irq(irq_data, false);
907         if r.is_err() {
908             return IrqStartupResult::Abort;
909         }
910 
911         return IrqStartupResult::Managed;
912     }
913 
914     pub fn do_enable_irq(
915         &self,
916         _desc: Arc<IrqDesc>,
917         _desc_inner_guard: &mut SpinLockGuard<'_, InnerIrqDesc>,
918     ) -> Result<(), SystemError> {
919         // https://code.dragonos.org.cn/xref/linux-6.1.9/kernel/irq/manage.c?r=&mo=59252&fi=2138#776
920         todo!("do_enable_irq")
921     }
922 
923     #[inline(never)]
924     pub fn do_set_irq_trigger(
925         &self,
926         _desc: Arc<IrqDesc>,
927         desc_inner_guard: &mut SpinLockGuard<'_, InnerIrqDesc>,
928         mut trigger_type: IrqLineStatus,
929     ) -> Result<(), SystemError> {
930         let chip = desc_inner_guard.irq_data().chip_info_read_irqsave().chip();
931         let mut to_unmask = false;
932 
933         if !chip.can_set_flow_type() {
934             // debug!(
935             //     "No set_irq_type function for irq {}, chip {}",
936             //     desc_inner_guard.irq_data().irq().data(),
937             //     chip.name()
938             // );
939             return Ok(());
940         }
941 
942         if chip.flags().contains(IrqChipFlags::IRQCHIP_SET_TYPE_MASKED) {
943             if !desc_inner_guard.common_data().status().masked() {
944                 self.mask_irq(desc_inner_guard.irq_data());
945             }
946             if !desc_inner_guard.common_data().status().disabled() {
947                 to_unmask = true;
948             }
949         }
950 
951         trigger_type &= IrqLineStatus::IRQ_TYPE_SENSE_MASK;
952 
953         let r = chip.irq_set_type(desc_inner_guard.irq_data(), trigger_type);
954         let ret;
955         if let Ok(rs) = r {
956             match rs {
957                 IrqChipSetMaskResult::Success | IrqChipSetMaskResult::Done => {
958                     let common_data = desc_inner_guard.common_data();
959                     common_data.clear_status(IrqStatus::IRQD_TRIGGER_MASK);
960                     let mut irqstatus = IrqStatus::empty();
961                     irqstatus.set_trigger_type(trigger_type);
962                     common_data.insert_status(irqstatus);
963                 }
964                 IrqChipSetMaskResult::NoChange => {
965                     let flags = desc_inner_guard.common_data().trigger_type();
966                     desc_inner_guard.set_trigger_type(flags);
967                     desc_inner_guard
968                         .common_data()
969                         .clear_status(IrqStatus::IRQD_LEVEL);
970                     desc_inner_guard.clear_level();
971 
972                     if !(flags & IrqLineStatus::IRQ_TYPE_LEVEL_MASK).is_empty() {
973                         desc_inner_guard.set_level();
974                         desc_inner_guard
975                             .common_data()
976                             .insert_status(IrqStatus::IRQD_LEVEL);
977                     }
978                 }
979             }
980 
981             ret = Ok(());
982         } else {
983             error!(
984                 "Failed to set irq {} trigger type to {:?} on irqchip {}, error {:?}",
985                 desc_inner_guard.irq_data().irq().data(),
986                 trigger_type,
987                 chip.name(),
988                 r
989             );
990 
991             ret = Err(r.unwrap_err());
992         }
993 
994         if to_unmask {
995             self.unmask_irq(desc_inner_guard);
996         }
997         return ret;
998     }
999 
1000     fn irq_request_resources(&self, desc: Arc<IrqDesc>) -> Result<(), SystemError> {
1001         let irq_data = desc.irq_data();
1002         let irq_chip = irq_data.chip_info_read_irqsave().chip();
1003         irq_chip.irq_request_resources(&irq_data)
1004     }
1005 
1006     /// 参考 https://code.dragonos.org.cn/xref/linux-6.1.9/kernel/irq/manage.c?r=&mo=59252&fi=2138#1448
1007     fn setup_irq_thread(
1008         &self,
1009         _irq: IrqNumber,
1010         _action: &InnerIrqAction,
1011         _secondary: bool,
1012     ) -> Result<(), SystemError> {
1013         // if secondary {
1014         //     KernelThreadMechanism::create(func, name)
1015         // }
1016 
1017         todo!("setup_irq_thread")
1018     }
1019 
1020     fn setup_forced_threading(&self, _action: &mut InnerIrqAction) -> Result<(), SystemError> {
1021         // todo: 处理强制线程化的逻辑,参考linux的`irq_setup_forced_threading()`
1022         return Ok(());
1023     }
1024 
1025     pub fn irq_clear_status_flags(
1026         &self,
1027         irq: IrqNumber,
1028         status: IrqLineStatus,
1029     ) -> Result<(), SystemError> {
1030         let desc = irq_desc_manager().lookup(irq).ok_or(SystemError::EINVAL)?;
1031         desc.modify_status(status, IrqLineStatus::empty());
1032         return Ok(());
1033     }
1034 
1035     /// 屏蔽中断
1036     pub(super) fn mask_irq(&self, irq_data: &Arc<IrqData>) {
1037         if irq_data.common_data().status().masked() {
1038             return;
1039         }
1040 
1041         let chip = irq_data.chip_info_read_irqsave().chip();
1042         let r = chip.irq_mask(irq_data);
1043 
1044         if r.is_ok() {
1045             irq_data.common_data().set_masked();
1046         }
1047     }
1048 
1049     /// 解除屏蔽中断
1050     pub(super) fn unmask_irq(&self, desc_inner_guard: &SpinLockGuard<'_, InnerIrqDesc>) {
1051         if !desc_inner_guard.common_data().status().masked() {
1052             return;
1053         }
1054 
1055         let r = desc_inner_guard
1056             .irq_data()
1057             .chip_info_read_irqsave()
1058             .chip()
1059             .irq_unmask(desc_inner_guard.irq_data());
1060 
1061         if let Err(e) = r {
1062             if e != SystemError::ENOSYS {
1063                 error!(
1064                     "Failed to unmask irq {} on irqchip {}, error {:?}",
1065                     desc_inner_guard.irq_data().irq().data(),
1066                     desc_inner_guard
1067                         .irq_data()
1068                         .chip_info_read_irqsave()
1069                         .chip()
1070                         .name(),
1071                     e
1072                 );
1073             }
1074         } else {
1075             desc_inner_guard
1076                 .common_data()
1077                 .clear_status(IrqStatus::IRQD_IRQ_MASKED);
1078         }
1079     }
1080 
1081     /// 释放使用request_irq分配的中断
1082     ///
1083     /// ## 参数
1084     ///
1085     /// - irq: 要释放的中断线
1086     /// - dev_id: 要释放的设备身份
1087     ///
1088     /// ## 返回
1089     ///
1090     /// 返回传递给request_irq的devname参数
1091     ///
1092     /// ## 说明
1093     ///
1094     /// 移除一个中断处理程序。处理程序被移除,如果该中断线不再被任何驱动程序使用,则会被禁用。
1095     ///
1096     /// 在共享IRQ的情况下,调用者必须确保在调用此功能之前,它在所驱动的卡上禁用了中断。
1097     ///
1098     /// ## 注意
1099     ///
1100     /// 此函数不可以在中断上下文中调用。
1101     ///
1102     /// 参考 https://code.dragonos.org.cn/xref/linux-6.6.21/kernel/irq/manage.c#2026
1103     pub fn free_irq(&self, _irq: IrqNumber, _dev_id: Option<Arc<DeviceId>>) {
1104         warn!("Unimplemented free_irq");
1105     }
1106 }
1107 
1108 enum IrqStartupResult {
1109     Normal,
1110     Managed,
1111     Abort,
1112 }
1113 /// 默认的初级中断处理函数
1114 ///
1115 /// 该处理函数仅仅返回`WakeThread`,即唤醒中断线程
1116 #[derive(Debug)]
1117 struct DefaultPrimaryIrqHandler;
1118 
1119 impl IrqHandler for DefaultPrimaryIrqHandler {
1120     fn handle(
1121         &self,
1122         _irq: IrqNumber,
1123         _static_data: Option<&dyn IrqHandlerData>,
1124         _dynamic_data: Option<Arc<dyn IrqHandlerData>>,
1125     ) -> Result<IrqReturn, SystemError> {
1126         return Ok(IrqReturn::WakeThread);
1127     }
1128 }
1129 
1130 /// Primary handler for nested threaded interrupts.
1131 /// Should never be called.
1132 #[derive(Debug)]
1133 struct IrqNestedPrimaryHandler;
1134 
1135 impl IrqHandler for IrqNestedPrimaryHandler {
1136     fn handle(
1137         &self,
1138         irq: IrqNumber,
1139         _static_data: Option<&dyn IrqHandlerData>,
1140         _dynamic_data: Option<Arc<dyn IrqHandlerData>>,
1141     ) -> Result<IrqReturn, SystemError> {
1142         warn!("Primary handler called for nested irq {}", irq.data());
1143         return Ok(IrqReturn::NotHandled);
1144     }
1145 }
1146