xref: /DragonOS/kernel/src/process/mod.rs (revision 401699735b5ec29768c3c0c47df6c529991f108f)
1 use core::{
2     hash::Hash,
3     hint::spin_loop,
4     intrinsics::{likely, unlikely},
5     mem::ManuallyDrop,
6     sync::atomic::{compiler_fence, AtomicBool, AtomicIsize, AtomicUsize, Ordering},
7 };
8 
9 use alloc::{
10     string::{String, ToString},
11     sync::{Arc, Weak},
12     vec::Vec,
13 };
14 use hashbrown::HashMap;
15 use system_error::SystemError;
16 
17 use crate::{
18     arch::{
19         ipc::signal::{AtomicSignal, SigSet, Signal},
20         process::ArchPCBInfo,
21         sched::sched,
22         CurrentIrqArch,
23     },
24     driver::tty::tty_core::TtyCore,
25     exception::InterruptArch,
26     filesystem::{
27         procfs::procfs_unregister_pid,
28         vfs::{file::FileDescriptorVec, FileType},
29     },
30     ipc::signal_types::{SigInfo, SigPending, SignalStruct},
31     kdebug, kinfo,
32     libs::{
33         align::AlignedBox,
34         casting::DowncastArc,
35         futex::{
36             constant::{FutexFlag, FUTEX_BITSET_MATCH_ANY},
37             futex::Futex,
38         },
39         lock_free_flags::LockFreeFlags,
40         rwlock::{RwLock, RwLockReadGuard, RwLockUpgradableGuard, RwLockWriteGuard},
41         spinlock::{SpinLock, SpinLockGuard},
42         wait_queue::WaitQueue,
43     },
44     mm::{
45         percpu::{PerCpu, PerCpuVar},
46         set_IDLE_PROCESS_ADDRESS_SPACE,
47         ucontext::AddressSpace,
48         VirtAddr,
49     },
50     net::socket::SocketInode,
51     sched::{
52         completion::Completion,
53         core::{sched_enqueue, CPU_EXECUTING},
54         SchedPolicy, SchedPriority,
55     },
56     smp::{
57         cpu::{AtomicProcessorId, ProcessorId},
58         kick_cpu,
59     },
60     syscall::{user_access::clear_user, Syscall},
61 };
62 
63 use self::kthread::WorkerPrivate;
64 
65 pub mod abi;
66 pub mod c_adapter;
67 pub mod exec;
68 pub mod exit;
69 pub mod fork;
70 pub mod idle;
71 pub mod kthread;
72 pub mod pid;
73 pub mod resource;
74 pub mod stdio;
75 pub mod syscall;
76 pub mod utils;
77 
78 /// 系统中所有进程的pcb
79 static ALL_PROCESS: SpinLock<Option<HashMap<Pid, Arc<ProcessControlBlock>>>> = SpinLock::new(None);
80 
81 pub static mut PROCESS_SWITCH_RESULT: Option<PerCpuVar<SwitchResult>> = None;
82 
83 /// 一个只改变1次的全局变量,标志进程管理器是否已经初始化完成
84 static mut __PROCESS_MANAGEMENT_INIT_DONE: bool = false;
85 
86 #[derive(Debug)]
87 pub struct SwitchResult {
88     pub prev_pcb: Option<Arc<ProcessControlBlock>>,
89     pub next_pcb: Option<Arc<ProcessControlBlock>>,
90 }
91 
92 impl SwitchResult {
93     pub fn new() -> Self {
94         Self {
95             prev_pcb: None,
96             next_pcb: None,
97         }
98     }
99 }
100 
101 #[derive(Debug)]
102 pub struct ProcessManager;
103 impl ProcessManager {
104     #[inline(never)]
105     fn init() {
106         static INIT_FLAG: AtomicBool = AtomicBool::new(false);
107         if INIT_FLAG
108             .compare_exchange(false, true, Ordering::SeqCst, Ordering::SeqCst)
109             .is_err()
110         {
111             panic!("ProcessManager has been initialized!");
112         }
113 
114         unsafe {
115             compiler_fence(Ordering::SeqCst);
116             kdebug!("To create address space for INIT process.");
117             // test_buddy();
118             set_IDLE_PROCESS_ADDRESS_SPACE(
119                 AddressSpace::new(true).expect("Failed to create address space for INIT process."),
120             );
121             kdebug!("INIT process address space created.");
122             compiler_fence(Ordering::SeqCst);
123         };
124 
125         ALL_PROCESS.lock_irqsave().replace(HashMap::new());
126         Self::init_switch_result();
127         Self::arch_init();
128         kdebug!("process arch init done.");
129         Self::init_idle();
130         kdebug!("process idle init done.");
131 
132         unsafe { __PROCESS_MANAGEMENT_INIT_DONE = true };
133         kinfo!("Process Manager initialized.");
134     }
135 
136     fn init_switch_result() {
137         let mut switch_res_vec: Vec<SwitchResult> = Vec::new();
138         for _ in 0..PerCpu::MAX_CPU_NUM {
139             switch_res_vec.push(SwitchResult::new());
140         }
141         unsafe {
142             PROCESS_SWITCH_RESULT = Some(PerCpuVar::new(switch_res_vec).unwrap());
143         }
144     }
145 
146     /// 判断进程管理器是否已经初始化完成
147     pub fn initialized() -> bool {
148         unsafe { __PROCESS_MANAGEMENT_INIT_DONE }
149     }
150 
151     /// 获取当前进程的pcb
152     pub fn current_pcb() -> Arc<ProcessControlBlock> {
153         if unlikely(unsafe { !__PROCESS_MANAGEMENT_INIT_DONE }) {
154             kerror!("unsafe__PROCESS_MANAGEMENT_INIT_DONE == false");
155             loop {
156                 spin_loop();
157             }
158         }
159         return ProcessControlBlock::arch_current_pcb();
160     }
161 
162     /// 获取当前进程的pid
163     ///
164     /// 如果进程管理器未初始化完成,那么返回0
165     pub fn current_pid() -> Pid {
166         if unlikely(unsafe { !__PROCESS_MANAGEMENT_INIT_DONE }) {
167             return Pid(0);
168         }
169 
170         return ProcessManager::current_pcb().pid();
171     }
172 
173     /// 增加当前进程的锁持有计数
174     #[inline(always)]
175     pub fn preempt_disable() {
176         if likely(unsafe { __PROCESS_MANAGEMENT_INIT_DONE }) {
177             ProcessManager::current_pcb().preempt_disable();
178         }
179     }
180 
181     /// 减少当前进程的锁持有计数
182     #[inline(always)]
183     pub fn preempt_enable() {
184         if likely(unsafe { __PROCESS_MANAGEMENT_INIT_DONE }) {
185             ProcessManager::current_pcb().preempt_enable();
186         }
187     }
188 
189     /// 根据pid获取进程的pcb
190     ///
191     /// ## 参数
192     ///
193     /// - `pid` : 进程的pid
194     ///
195     /// ## 返回值
196     ///
197     /// 如果找到了对应的进程,那么返回该进程的pcb,否则返回None
198     pub fn find(pid: Pid) -> Option<Arc<ProcessControlBlock>> {
199         return ALL_PROCESS.lock_irqsave().as_ref()?.get(&pid).cloned();
200     }
201 
202     /// 向系统中添加一个进程的pcb
203     ///
204     /// ## 参数
205     ///
206     /// - `pcb` : 进程的pcb
207     ///
208     /// ## 返回值
209     ///
210     /// 无
211     pub fn add_pcb(pcb: Arc<ProcessControlBlock>) {
212         ALL_PROCESS
213             .lock_irqsave()
214             .as_mut()
215             .unwrap()
216             .insert(pcb.pid(), pcb.clone());
217     }
218 
219     /// 唤醒一个进程
220     pub fn wakeup(pcb: &Arc<ProcessControlBlock>) -> Result<(), SystemError> {
221         let _guard = unsafe { CurrentIrqArch::save_and_disable_irq() };
222         let state = pcb.sched_info().inner_lock_read_irqsave().state();
223         if state.is_blocked() {
224             let mut writer = pcb.sched_info().inner_lock_write_irqsave();
225             let state = writer.state();
226             if state.is_blocked() {
227                 writer.set_state(ProcessState::Runnable);
228                 // avoid deadlock
229                 drop(writer);
230 
231                 sched_enqueue(pcb.clone(), true);
232                 return Ok(());
233             } else if state.is_exited() {
234                 return Err(SystemError::EINVAL);
235             } else {
236                 return Ok(());
237             }
238         } else if state.is_exited() {
239             return Err(SystemError::EINVAL);
240         } else {
241             return Ok(());
242         }
243     }
244 
245     /// 唤醒暂停的进程
246     pub fn wakeup_stop(pcb: &Arc<ProcessControlBlock>) -> Result<(), SystemError> {
247         let _guard = unsafe { CurrentIrqArch::save_and_disable_irq() };
248         let state = pcb.sched_info().inner_lock_read_irqsave().state();
249         if let ProcessState::Stopped = state {
250             let mut writer = pcb.sched_info().inner_lock_write_irqsave();
251             let state = writer.state();
252             if let ProcessState::Stopped = state {
253                 writer.set_state(ProcessState::Runnable);
254                 // avoid deadlock
255                 drop(writer);
256 
257                 sched_enqueue(pcb.clone(), true);
258                 return Ok(());
259             } else if state.is_runnable() {
260                 return Ok(());
261             } else {
262                 return Err(SystemError::EINVAL);
263             }
264         } else if state.is_runnable() {
265             return Ok(());
266         } else {
267             return Err(SystemError::EINVAL);
268         }
269     }
270 
271     /// 标志当前进程永久睡眠,但是发起调度的工作,应该由调用者完成
272     ///
273     /// ## 注意
274     ///
275     /// - 进入当前函数之前,不能持有sched_info的锁
276     /// - 进入当前函数之前,必须关闭中断
277     /// - 进入当前函数之后必须保证逻辑的正确性,避免被重复加入调度队列
278     pub fn mark_sleep(interruptable: bool) -> Result<(), SystemError> {
279         assert!(
280             !CurrentIrqArch::is_irq_enabled(),
281             "interrupt must be disabled before enter ProcessManager::mark_sleep()"
282         );
283 
284         let pcb = ProcessManager::current_pcb();
285         let mut writer = pcb.sched_info().inner_lock_write_irqsave();
286         if !matches!(writer.state(), ProcessState::Exited(_)) {
287             writer.set_state(ProcessState::Blocked(interruptable));
288             pcb.flags().insert(ProcessFlags::NEED_SCHEDULE);
289             drop(writer);
290 
291             return Ok(());
292         }
293         return Err(SystemError::EINTR);
294     }
295 
296     /// 标志当前进程为停止状态,但是发起调度的工作,应该由调用者完成
297     ///
298     /// ## 注意
299     ///
300     /// - 进入当前函数之前,不能持有sched_info的锁
301     /// - 进入当前函数之前,必须关闭中断
302     pub fn mark_stop() -> Result<(), SystemError> {
303         assert!(
304             !CurrentIrqArch::is_irq_enabled(),
305             "interrupt must be disabled before enter ProcessManager::mark_stop()"
306         );
307 
308         let pcb = ProcessManager::current_pcb();
309         let mut writer = pcb.sched_info().inner_lock_write_irqsave();
310         if !matches!(writer.state(), ProcessState::Exited(_)) {
311             writer.set_state(ProcessState::Stopped);
312             pcb.flags().insert(ProcessFlags::NEED_SCHEDULE);
313             drop(writer);
314 
315             return Ok(());
316         }
317         return Err(SystemError::EINTR);
318     }
319     /// 当子进程退出后向父进程发送通知
320     fn exit_notify() {
321         let current = ProcessManager::current_pcb();
322         // 让INIT进程收养所有子进程
323         if current.pid() != Pid(1) {
324             unsafe {
325                 current
326                     .adopt_childen()
327                     .unwrap_or_else(|e| panic!("adopte_childen failed: error: {e:?}"))
328             };
329             let r = current.parent_pcb.read_irqsave().upgrade();
330             if r.is_none() {
331                 return;
332             }
333             let parent_pcb = r.unwrap();
334             let r = Syscall::kill(parent_pcb.pid(), Signal::SIGCHLD as i32);
335             if r.is_err() {
336                 kwarn!(
337                     "failed to send kill signal to {:?}'s parent pcb {:?}",
338                     current.pid(),
339                     parent_pcb.pid()
340                 );
341             }
342             // todo: 这里需要向父进程发送SIGCHLD信号
343             // todo: 这里还需要根据线程组的信息,决定信号的发送
344         }
345     }
346 
347     /// 退出当前进程
348     ///
349     /// ## 参数
350     ///
351     /// - `exit_code` : 进程的退出码
352     pub fn exit(exit_code: usize) -> ! {
353         // 关中断
354         unsafe { CurrentIrqArch::interrupt_disable() };
355         let pcb = ProcessManager::current_pcb();
356         let pid = pcb.pid();
357         pcb.sched_info
358             .inner_lock_write_irqsave()
359             .set_state(ProcessState::Exited(exit_code));
360         pcb.wait_queue.wakeup(Some(ProcessState::Blocked(true)));
361 
362         // 进行进程退出后的工作
363         let thread = pcb.thread.write_irqsave();
364         if let Some(addr) = thread.set_child_tid {
365             unsafe { clear_user(addr, core::mem::size_of::<i32>()).expect("clear tid failed") };
366         }
367 
368         if let Some(addr) = thread.clear_child_tid {
369             if Arc::strong_count(&pcb.basic().user_vm().expect("User VM Not found")) > 1 {
370                 let _ =
371                     Futex::futex_wake(addr, FutexFlag::FLAGS_MATCH_NONE, 1, FUTEX_BITSET_MATCH_ANY);
372             }
373             unsafe { clear_user(addr, core::mem::size_of::<i32>()).expect("clear tid failed") };
374         }
375 
376         // 如果是vfork出来的进程,则需要处理completion
377         if thread.vfork_done.is_some() {
378             thread.vfork_done.as_ref().unwrap().complete_all();
379         }
380         drop(thread);
381         unsafe { pcb.basic_mut().set_user_vm(None) };
382         drop(pcb);
383         ProcessManager::exit_notify();
384         unsafe { CurrentIrqArch::interrupt_enable() };
385 
386         sched();
387         kerror!("pid {pid:?} exited but sched again!");
388         #[allow(clippy::empty_loop)]
389         loop {
390             spin_loop();
391         }
392     }
393 
394     pub unsafe fn release(pid: Pid) {
395         let pcb = ProcessManager::find(pid);
396         if pcb.is_some() {
397             // let pcb = pcb.unwrap();
398             // 判断该pcb是否在全局没有任何引用
399             // TODO: 当前,pcb的Arc指针存在泄露问题,引用计数不正确,打算在接下来实现debug专用的Arc,方便调试,然后解决这个bug。
400             //          因此目前暂时注释掉,使得能跑
401             // if Arc::strong_count(&pcb) <= 2 {
402             //     drop(pcb);
403             //     ALL_PROCESS.lock().as_mut().unwrap().remove(&pid);
404             // } else {
405             //     // 如果不为1就panic
406             //     let msg = format!("pcb '{:?}' is still referenced, strong count={}",pcb.pid(),  Arc::strong_count(&pcb));
407             //     kerror!("{}", msg);
408             //     panic!()
409             // }
410 
411             ALL_PROCESS.lock_irqsave().as_mut().unwrap().remove(&pid);
412         }
413     }
414 
415     /// 上下文切换完成后的钩子函数
416     unsafe fn switch_finish_hook() {
417         // kdebug!("switch_finish_hook");
418         let prev_pcb = PROCESS_SWITCH_RESULT
419             .as_mut()
420             .unwrap()
421             .get_mut()
422             .prev_pcb
423             .take()
424             .expect("prev_pcb is None");
425         let next_pcb = PROCESS_SWITCH_RESULT
426             .as_mut()
427             .unwrap()
428             .get_mut()
429             .next_pcb
430             .take()
431             .expect("next_pcb is None");
432 
433         // 由于进程切换前使用了SpinLockGuard::leak(),所以这里需要手动释放锁
434         prev_pcb.arch_info.force_unlock();
435         next_pcb.arch_info.force_unlock();
436     }
437 
438     /// 如果目标进程正在目标CPU上运行,那么就让这个cpu陷入内核态
439     ///
440     /// ## 参数
441     ///
442     /// - `pcb` : 进程的pcb
443     #[allow(dead_code)]
444     pub fn kick(pcb: &Arc<ProcessControlBlock>) {
445         ProcessManager::current_pcb().preempt_disable();
446         let cpu_id = pcb.sched_info().on_cpu();
447 
448         if let Some(cpu_id) = cpu_id {
449             if pcb.pid() == CPU_EXECUTING.get(cpu_id) {
450                 kick_cpu(cpu_id).expect("ProcessManager::kick(): Failed to kick cpu");
451             }
452         }
453 
454         ProcessManager::current_pcb().preempt_enable();
455     }
456 }
457 
458 /// 上下文切换的钩子函数,当这个函数return的时候,将会发生上下文切换
459 #[cfg(target_arch = "x86_64")]
460 #[inline(never)]
461 pub unsafe extern "sysv64" fn switch_finish_hook() {
462     ProcessManager::switch_finish_hook();
463 }
464 #[cfg(target_arch = "riscv64")]
465 pub unsafe extern "C" fn switch_finish_hook() {
466     ProcessManager::switch_finish_hook();
467 }
468 
469 int_like!(Pid, AtomicPid, usize, AtomicUsize);
470 
471 impl ToString for Pid {
472     fn to_string(&self) -> String {
473         self.0.to_string()
474     }
475 }
476 
477 #[derive(Debug, Clone, Copy, PartialEq, Eq)]
478 pub enum ProcessState {
479     /// The process is running on a CPU or in a run queue.
480     Runnable,
481     /// The process is waiting for an event to occur.
482     /// 其中的bool表示该等待过程是否可以被打断。
483     /// - 如果该bool为true,那么,硬件中断/信号/其他系统事件都可以打断该等待过程,使得该进程重新进入Runnable状态。
484     /// - 如果该bool为false,那么,这个进程必须被显式的唤醒,才能重新进入Runnable状态。
485     Blocked(bool),
486     /// 进程被信号终止
487     Stopped,
488     /// 进程已经退出,usize表示进程的退出码
489     Exited(usize),
490 }
491 
492 #[allow(dead_code)]
493 impl ProcessState {
494     #[inline(always)]
495     pub fn is_runnable(&self) -> bool {
496         return matches!(self, ProcessState::Runnable);
497     }
498 
499     #[inline(always)]
500     pub fn is_blocked(&self) -> bool {
501         return matches!(self, ProcessState::Blocked(_));
502     }
503 
504     #[inline(always)]
505     pub fn is_blocked_interruptable(&self) -> bool {
506         return matches!(self, ProcessState::Blocked(true));
507     }
508 
509     /// Returns `true` if the process state is [`Exited`].
510     #[inline(always)]
511     pub fn is_exited(&self) -> bool {
512         return matches!(self, ProcessState::Exited(_));
513     }
514 
515     /// Returns `true` if the process state is [`Stopped`].
516     ///
517     /// [`Stopped`]: ProcessState::Stopped
518     #[inline(always)]
519     pub fn is_stopped(&self) -> bool {
520         matches!(self, ProcessState::Stopped)
521     }
522 
523     /// Returns exit code if the process state is [`Exited`].
524     #[inline(always)]
525     pub fn exit_code(&self) -> Option<usize> {
526         match self {
527             ProcessState::Exited(code) => Some(*code),
528             _ => None,
529         }
530     }
531 }
532 
533 bitflags! {
534     /// pcb的标志位
535     pub struct ProcessFlags: usize {
536         /// 当前pcb表示一个内核线程
537         const KTHREAD = 1 << 0;
538         /// 当前进程需要被调度
539         const NEED_SCHEDULE = 1 << 1;
540         /// 进程由于vfork而与父进程存在资源共享
541         const VFORK = 1 << 2;
542         /// 进程不可被冻结
543         const NOFREEZE = 1 << 3;
544         /// 进程正在退出
545         const EXITING = 1 << 4;
546         /// 进程由于接收到终止信号唤醒
547         const WAKEKILL = 1 << 5;
548         /// 进程由于接收到信号而退出.(Killed by a signal)
549         const SIGNALED = 1 << 6;
550         /// 进程需要迁移到其他cpu上
551         const NEED_MIGRATE = 1 << 7;
552         /// 随机化的虚拟地址空间,主要用于动态链接器的加载
553         const RANDOMIZE = 1 << 8;
554     }
555 }
556 
557 #[derive(Debug)]
558 pub struct ProcessControlBlock {
559     /// 当前进程的pid
560     pid: Pid,
561     /// 当前进程的线程组id(这个值在同一个线程组内永远不变)
562     tgid: Pid,
563 
564     basic: RwLock<ProcessBasicInfo>,
565     /// 当前进程的自旋锁持有计数
566     preempt_count: AtomicUsize,
567 
568     flags: LockFreeFlags<ProcessFlags>,
569     worker_private: SpinLock<Option<WorkerPrivate>>,
570     /// 进程的内核栈
571     kernel_stack: RwLock<KernelStack>,
572 
573     /// 系统调用栈
574     syscall_stack: RwLock<KernelStack>,
575 
576     /// 与调度相关的信息
577     sched_info: ProcessSchedulerInfo,
578     /// 与处理器架构相关的信息
579     arch_info: SpinLock<ArchPCBInfo>,
580     /// 与信号处理相关的信息(似乎可以是无锁的)
581     sig_info: RwLock<ProcessSignalInfo>,
582     /// 信号处理结构体
583     sig_struct: SpinLock<SignalStruct>,
584     /// 退出信号S
585     exit_signal: AtomicSignal,
586 
587     /// 父进程指针
588     parent_pcb: RwLock<Weak<ProcessControlBlock>>,
589     /// 真实父进程指针
590     real_parent_pcb: RwLock<Weak<ProcessControlBlock>>,
591 
592     /// 子进程链表
593     children: RwLock<Vec<Pid>>,
594 
595     /// 等待队列
596     wait_queue: WaitQueue,
597 
598     /// 线程信息
599     thread: RwLock<ThreadInfo>,
600 }
601 
602 impl ProcessControlBlock {
603     /// Generate a new pcb.
604     ///
605     /// ## 参数
606     ///
607     /// - `name` : 进程的名字
608     /// - `kstack` : 进程的内核栈
609     ///
610     /// ## 返回值
611     ///
612     /// 返回一个新的pcb
613     pub fn new(name: String, kstack: KernelStack) -> Arc<Self> {
614         return Self::do_create_pcb(name, kstack, false);
615     }
616 
617     /// 创建一个新的idle进程
618     ///
619     /// 请注意,这个函数只能在进程管理初始化的时候调用。
620     pub fn new_idle(cpu_id: u32, kstack: KernelStack) -> Arc<Self> {
621         let name = format!("idle-{}", cpu_id);
622         return Self::do_create_pcb(name, kstack, true);
623     }
624 
625     #[inline(never)]
626     fn do_create_pcb(name: String, kstack: KernelStack, is_idle: bool) -> Arc<Self> {
627         let (pid, ppid, cwd) = if is_idle {
628             (Pid(0), Pid(0), "/".to_string())
629         } else {
630             let ppid = ProcessManager::current_pcb().pid();
631             let cwd = ProcessManager::current_pcb().basic().cwd();
632             (Self::generate_pid(), ppid, cwd)
633         };
634 
635         let basic_info = ProcessBasicInfo::new(Pid(0), ppid, name, cwd, None);
636         let preempt_count = AtomicUsize::new(0);
637         let flags = unsafe { LockFreeFlags::new(ProcessFlags::empty()) };
638 
639         let sched_info = ProcessSchedulerInfo::new(None);
640         let arch_info = SpinLock::new(ArchPCBInfo::new(&kstack));
641 
642         let ppcb: Weak<ProcessControlBlock> = ProcessManager::find(ppid)
643             .map(|p| Arc::downgrade(&p))
644             .unwrap_or_default();
645 
646         let pcb = Self {
647             pid,
648             tgid: pid,
649             basic: basic_info,
650             preempt_count,
651             flags,
652             kernel_stack: RwLock::new(kstack),
653             syscall_stack: RwLock::new(KernelStack::new().unwrap()),
654             worker_private: SpinLock::new(None),
655             sched_info,
656             arch_info,
657             sig_info: RwLock::new(ProcessSignalInfo::default()),
658             sig_struct: SpinLock::new(SignalStruct::new()),
659             exit_signal: AtomicSignal::new(Signal::SIGCHLD),
660             parent_pcb: RwLock::new(ppcb.clone()),
661             real_parent_pcb: RwLock::new(ppcb),
662             children: RwLock::new(Vec::new()),
663             wait_queue: WaitQueue::default(),
664             thread: RwLock::new(ThreadInfo::new()),
665         };
666 
667         // 初始化系统调用栈
668         #[cfg(target_arch = "x86_64")]
669         pcb.arch_info
670             .lock()
671             .init_syscall_stack(&pcb.syscall_stack.read());
672 
673         let pcb = Arc::new(pcb);
674 
675         // 设置进程的arc指针到内核栈和系统调用栈的最低地址处
676         unsafe {
677             pcb.kernel_stack
678                 .write()
679                 .set_pcb(Arc::downgrade(&pcb))
680                 .unwrap();
681 
682             pcb.syscall_stack
683                 .write()
684                 .set_pcb(Arc::downgrade(&pcb))
685                 .unwrap()
686         };
687 
688         // 将当前pcb加入父进程的子进程哈希表中
689         if pcb.pid() > Pid(1) {
690             if let Some(ppcb_arc) = pcb.parent_pcb.read_irqsave().upgrade() {
691                 let mut children = ppcb_arc.children.write_irqsave();
692                 children.push(pcb.pid());
693             } else {
694                 panic!("parent pcb is None");
695             }
696         }
697 
698         return pcb;
699     }
700 
701     /// 生成一个新的pid
702     #[inline(always)]
703     fn generate_pid() -> Pid {
704         static NEXT_PID: AtomicPid = AtomicPid::new(Pid(1));
705         return NEXT_PID.fetch_add(Pid(1), Ordering::SeqCst);
706     }
707 
708     /// 返回当前进程的锁持有计数
709     #[inline(always)]
710     pub fn preempt_count(&self) -> usize {
711         return self.preempt_count.load(Ordering::SeqCst);
712     }
713 
714     /// 增加当前进程的锁持有计数
715     #[inline(always)]
716     pub fn preempt_disable(&self) {
717         self.preempt_count.fetch_add(1, Ordering::SeqCst);
718     }
719 
720     /// 减少当前进程的锁持有计数
721     #[inline(always)]
722     pub fn preempt_enable(&self) {
723         self.preempt_count.fetch_sub(1, Ordering::SeqCst);
724     }
725 
726     #[inline(always)]
727     pub unsafe fn set_preempt_count(&self, count: usize) {
728         self.preempt_count.store(count, Ordering::SeqCst);
729     }
730 
731     #[inline(always)]
732     pub fn flags(&self) -> &mut ProcessFlags {
733         return self.flags.get_mut();
734     }
735 
736     /// 请注意,这个值能在中断上下文中读取,但不能被中断上下文修改
737     /// 否则会导致死锁
738     #[inline(always)]
739     pub fn basic(&self) -> RwLockReadGuard<ProcessBasicInfo> {
740         return self.basic.read_irqsave();
741     }
742 
743     #[inline(always)]
744     pub fn set_name(&self, name: String) {
745         self.basic.write().set_name(name);
746     }
747 
748     #[inline(always)]
749     pub fn basic_mut(&self) -> RwLockWriteGuard<ProcessBasicInfo> {
750         return self.basic.write_irqsave();
751     }
752 
753     /// # 获取arch info的锁,同时关闭中断
754     #[inline(always)]
755     pub fn arch_info_irqsave(&self) -> SpinLockGuard<ArchPCBInfo> {
756         return self.arch_info.lock_irqsave();
757     }
758 
759     /// # 获取arch info的锁,但是不关闭中断
760     ///
761     /// 由于arch info在进程切换的时候会使用到,
762     /// 因此在中断上下文外,获取arch info 而不irqsave是不安全的.
763     ///
764     /// 只能在以下情况下使用这个函数:
765     /// - 在中断上下文中(中断已经禁用),获取arch info的锁。
766     /// - 刚刚创建新的pcb
767     #[inline(always)]
768     pub unsafe fn arch_info(&self) -> SpinLockGuard<ArchPCBInfo> {
769         return self.arch_info.lock();
770     }
771 
772     #[inline(always)]
773     pub fn kernel_stack(&self) -> RwLockReadGuard<KernelStack> {
774         return self.kernel_stack.read();
775     }
776 
777     #[inline(always)]
778     #[allow(dead_code)]
779     pub fn kernel_stack_mut(&self) -> RwLockWriteGuard<KernelStack> {
780         return self.kernel_stack.write();
781     }
782 
783     #[inline(always)]
784     pub fn sched_info(&self) -> &ProcessSchedulerInfo {
785         return &self.sched_info;
786     }
787 
788     #[inline(always)]
789     pub fn worker_private(&self) -> SpinLockGuard<Option<WorkerPrivate>> {
790         return self.worker_private.lock();
791     }
792 
793     #[inline(always)]
794     pub fn pid(&self) -> Pid {
795         return self.pid;
796     }
797 
798     #[inline(always)]
799     pub fn tgid(&self) -> Pid {
800         return self.tgid;
801     }
802 
803     /// 获取文件描述符表的Arc指针
804     #[inline(always)]
805     pub fn fd_table(&self) -> Arc<RwLock<FileDescriptorVec>> {
806         return self.basic.read().fd_table().unwrap();
807     }
808 
809     /// 根据文件描述符序号,获取socket对象的Arc指针
810     ///
811     /// ## 参数
812     ///
813     /// - `fd` 文件描述符序号
814     ///
815     /// ## 返回值
816     ///
817     /// Option(&mut Box<dyn Socket>) socket对象的可变引用. 如果文件描述符不是socket,那么返回None
818     pub fn get_socket(&self, fd: i32) -> Option<Arc<SocketInode>> {
819         let binding = ProcessManager::current_pcb().fd_table();
820         let fd_table_guard = binding.read();
821 
822         let f = fd_table_guard.get_file_by_fd(fd)?;
823         drop(fd_table_guard);
824 
825         let guard = f.lock();
826         if guard.file_type() != FileType::Socket {
827             return None;
828         }
829         let socket: Arc<SocketInode> = guard
830             .inode()
831             .downcast_arc::<SocketInode>()
832             .expect("Not a socket inode");
833         return Some(socket);
834     }
835 
836     /// 当前进程退出时,让初始进程收养所有子进程
837     unsafe fn adopt_childen(&self) -> Result<(), SystemError> {
838         match ProcessManager::find(Pid(1)) {
839             Some(init_pcb) => {
840                 let childen_guard = self.children.write();
841                 let mut init_childen_guard = init_pcb.children.write();
842 
843                 childen_guard.iter().for_each(|pid| {
844                     init_childen_guard.push(*pid);
845                 });
846 
847                 return Ok(());
848             }
849             _ => Err(SystemError::ECHILD),
850         }
851     }
852 
853     /// 生成进程的名字
854     pub fn generate_name(program_path: &str, args: &Vec<String>) -> String {
855         let mut name = program_path.to_string();
856         for arg in args {
857             name.push(' ');
858             name.push_str(arg);
859         }
860         return name;
861     }
862 
863     pub fn sig_info_irqsave(&self) -> RwLockReadGuard<ProcessSignalInfo> {
864         self.sig_info.read_irqsave()
865     }
866 
867     pub fn try_siginfo_irqsave(&self, times: u8) -> Option<RwLockReadGuard<ProcessSignalInfo>> {
868         for _ in 0..times {
869             if let Some(r) = self.sig_info.try_read_irqsave() {
870                 return Some(r);
871             }
872         }
873 
874         return None;
875     }
876 
877     pub fn sig_info_mut(&self) -> RwLockWriteGuard<ProcessSignalInfo> {
878         self.sig_info.write_irqsave()
879     }
880 
881     pub fn try_siginfo_mut(&self, times: u8) -> Option<RwLockWriteGuard<ProcessSignalInfo>> {
882         for _ in 0..times {
883             if let Some(r) = self.sig_info.try_write_irqsave() {
884                 return Some(r);
885             }
886         }
887 
888         return None;
889     }
890 
891     pub fn sig_struct(&self) -> SpinLockGuard<SignalStruct> {
892         self.sig_struct.lock_irqsave()
893     }
894 
895     pub fn try_sig_struct_irqsave(&self, times: u8) -> Option<SpinLockGuard<SignalStruct>> {
896         for _ in 0..times {
897             if let Ok(r) = self.sig_struct.try_lock_irqsave() {
898                 return Some(r);
899             }
900         }
901 
902         return None;
903     }
904 
905     pub fn sig_struct_irqsave(&self) -> SpinLockGuard<SignalStruct> {
906         self.sig_struct.lock_irqsave()
907     }
908 }
909 
910 impl Drop for ProcessControlBlock {
911     fn drop(&mut self) {
912         let irq_guard = unsafe { CurrentIrqArch::save_and_disable_irq() };
913         // 在ProcFS中,解除进程的注册
914         procfs_unregister_pid(self.pid())
915             .unwrap_or_else(|e| panic!("procfs_unregister_pid failed: error: {e:?}"));
916 
917         if let Some(ppcb) = self.parent_pcb.read_irqsave().upgrade() {
918             ppcb.children
919                 .write_irqsave()
920                 .retain(|pid| *pid != self.pid());
921         }
922 
923         drop(irq_guard);
924     }
925 }
926 
927 /// 线程信息
928 #[derive(Debug)]
929 pub struct ThreadInfo {
930     // 来自用户空间记录用户线程id的地址,在该线程结束时将该地址置0以通知父进程
931     clear_child_tid: Option<VirtAddr>,
932     set_child_tid: Option<VirtAddr>,
933 
934     vfork_done: Option<Arc<Completion>>,
935     /// 线程组的组长
936     group_leader: Weak<ProcessControlBlock>,
937 }
938 
939 impl ThreadInfo {
940     pub fn new() -> Self {
941         Self {
942             clear_child_tid: None,
943             set_child_tid: None,
944             vfork_done: None,
945             group_leader: Weak::default(),
946         }
947     }
948 
949     pub fn group_leader(&self) -> Option<Arc<ProcessControlBlock>> {
950         return self.group_leader.upgrade();
951     }
952 }
953 
954 /// 进程的基本信息
955 ///
956 /// 这个结构体保存进程的基本信息,主要是那些不会随着进程的运行而经常改变的信息。
957 #[derive(Debug)]
958 pub struct ProcessBasicInfo {
959     /// 当前进程的进程组id
960     pgid: Pid,
961     /// 当前进程的父进程的pid
962     ppid: Pid,
963     /// 进程的名字
964     name: String,
965 
966     /// 当前进程的工作目录
967     cwd: String,
968 
969     /// 用户地址空间
970     user_vm: Option<Arc<AddressSpace>>,
971 
972     /// 文件描述符表
973     fd_table: Option<Arc<RwLock<FileDescriptorVec>>>,
974 }
975 
976 impl ProcessBasicInfo {
977     #[inline(never)]
978     pub fn new(
979         pgid: Pid,
980         ppid: Pid,
981         name: String,
982         cwd: String,
983         user_vm: Option<Arc<AddressSpace>>,
984     ) -> RwLock<Self> {
985         let fd_table = Arc::new(RwLock::new(FileDescriptorVec::new()));
986         return RwLock::new(Self {
987             pgid,
988             ppid,
989             name,
990             cwd,
991             user_vm,
992             fd_table: Some(fd_table),
993         });
994     }
995 
996     pub fn pgid(&self) -> Pid {
997         return self.pgid;
998     }
999 
1000     pub fn ppid(&self) -> Pid {
1001         return self.ppid;
1002     }
1003 
1004     pub fn name(&self) -> &str {
1005         return &self.name;
1006     }
1007 
1008     pub fn set_name(&mut self, name: String) {
1009         self.name = name;
1010     }
1011 
1012     pub fn cwd(&self) -> String {
1013         return self.cwd.clone();
1014     }
1015     pub fn set_cwd(&mut self, path: String) {
1016         return self.cwd = path;
1017     }
1018 
1019     pub fn user_vm(&self) -> Option<Arc<AddressSpace>> {
1020         return self.user_vm.clone();
1021     }
1022 
1023     pub unsafe fn set_user_vm(&mut self, user_vm: Option<Arc<AddressSpace>>) {
1024         self.user_vm = user_vm;
1025     }
1026 
1027     pub fn fd_table(&self) -> Option<Arc<RwLock<FileDescriptorVec>>> {
1028         return self.fd_table.clone();
1029     }
1030 
1031     pub fn set_fd_table(&mut self, fd_table: Option<Arc<RwLock<FileDescriptorVec>>>) {
1032         self.fd_table = fd_table;
1033     }
1034 }
1035 
1036 #[derive(Debug)]
1037 pub struct ProcessSchedulerInfo {
1038     /// 当前进程所在的cpu
1039     on_cpu: AtomicProcessorId,
1040     /// 如果当前进程等待被迁移到另一个cpu核心上(也就是flags中的PF_NEED_MIGRATE被置位),
1041     /// 该字段存储要被迁移到的目标处理器核心号
1042     migrate_to: AtomicProcessorId,
1043     inner_locked: RwLock<InnerSchedInfo>,
1044     /// 进程的调度优先级
1045     priority: SchedPriority,
1046     /// 当前进程的虚拟运行时间
1047     virtual_runtime: AtomicIsize,
1048     /// 由实时调度器管理的时间片
1049     rt_time_slice: AtomicIsize,
1050 }
1051 
1052 #[derive(Debug)]
1053 pub struct InnerSchedInfo {
1054     /// 当前进程的状态
1055     state: ProcessState,
1056     /// 进程的调度策略
1057     sched_policy: SchedPolicy,
1058 }
1059 
1060 impl InnerSchedInfo {
1061     pub fn state(&self) -> ProcessState {
1062         return self.state;
1063     }
1064 
1065     pub fn set_state(&mut self, state: ProcessState) {
1066         self.state = state;
1067     }
1068 
1069     pub fn policy(&self) -> SchedPolicy {
1070         return self.sched_policy;
1071     }
1072 }
1073 
1074 impl ProcessSchedulerInfo {
1075     #[inline(never)]
1076     pub fn new(on_cpu: Option<ProcessorId>) -> Self {
1077         let cpu_id = on_cpu.unwrap_or(ProcessorId::INVALID);
1078         return Self {
1079             on_cpu: AtomicProcessorId::new(cpu_id),
1080             migrate_to: AtomicProcessorId::new(ProcessorId::INVALID),
1081             inner_locked: RwLock::new(InnerSchedInfo {
1082                 state: ProcessState::Blocked(false),
1083                 sched_policy: SchedPolicy::CFS,
1084             }),
1085             virtual_runtime: AtomicIsize::new(0),
1086             rt_time_slice: AtomicIsize::new(0),
1087             priority: SchedPriority::new(100).unwrap(),
1088         };
1089     }
1090 
1091     pub fn on_cpu(&self) -> Option<ProcessorId> {
1092         let on_cpu = self.on_cpu.load(Ordering::SeqCst);
1093         if on_cpu == ProcessorId::INVALID {
1094             return None;
1095         } else {
1096             return Some(on_cpu);
1097         }
1098     }
1099 
1100     pub fn set_on_cpu(&self, on_cpu: Option<ProcessorId>) {
1101         if let Some(cpu_id) = on_cpu {
1102             self.on_cpu.store(cpu_id, Ordering::SeqCst);
1103         } else {
1104             self.on_cpu.store(ProcessorId::INVALID, Ordering::SeqCst);
1105         }
1106     }
1107 
1108     pub fn migrate_to(&self) -> Option<ProcessorId> {
1109         let migrate_to = self.migrate_to.load(Ordering::SeqCst);
1110         if migrate_to == ProcessorId::INVALID {
1111             return None;
1112         } else {
1113             return Some(migrate_to);
1114         }
1115     }
1116 
1117     pub fn set_migrate_to(&self, migrate_to: Option<ProcessorId>) {
1118         if let Some(data) = migrate_to {
1119             self.migrate_to.store(data, Ordering::SeqCst);
1120         } else {
1121             self.migrate_to
1122                 .store(ProcessorId::INVALID, Ordering::SeqCst)
1123         }
1124     }
1125 
1126     pub fn inner_lock_write_irqsave(&self) -> RwLockWriteGuard<InnerSchedInfo> {
1127         return self.inner_locked.write_irqsave();
1128     }
1129 
1130     pub fn inner_lock_read_irqsave(&self) -> RwLockReadGuard<InnerSchedInfo> {
1131         return self.inner_locked.read_irqsave();
1132     }
1133 
1134     pub fn inner_lock_try_read_irqsave(
1135         &self,
1136         times: u8,
1137     ) -> Option<RwLockReadGuard<InnerSchedInfo>> {
1138         for _ in 0..times {
1139             if let Some(r) = self.inner_locked.try_read_irqsave() {
1140                 return Some(r);
1141             }
1142         }
1143 
1144         return None;
1145     }
1146 
1147     pub fn inner_lock_try_upgradable_read_irqsave(
1148         &self,
1149         times: u8,
1150     ) -> Option<RwLockUpgradableGuard<InnerSchedInfo>> {
1151         for _ in 0..times {
1152             if let Some(r) = self.inner_locked.try_upgradeable_read_irqsave() {
1153                 return Some(r);
1154             }
1155         }
1156 
1157         return None;
1158     }
1159 
1160     pub fn virtual_runtime(&self) -> isize {
1161         return self.virtual_runtime.load(Ordering::SeqCst);
1162     }
1163 
1164     pub fn set_virtual_runtime(&self, virtual_runtime: isize) {
1165         self.virtual_runtime
1166             .store(virtual_runtime, Ordering::SeqCst);
1167     }
1168     pub fn increase_virtual_runtime(&self, delta: isize) {
1169         self.virtual_runtime.fetch_add(delta, Ordering::SeqCst);
1170     }
1171 
1172     pub fn rt_time_slice(&self) -> isize {
1173         return self.rt_time_slice.load(Ordering::SeqCst);
1174     }
1175 
1176     pub fn set_rt_time_slice(&self, rt_time_slice: isize) {
1177         self.rt_time_slice.store(rt_time_slice, Ordering::SeqCst);
1178     }
1179 
1180     pub fn increase_rt_time_slice(&self, delta: isize) {
1181         self.rt_time_slice.fetch_add(delta, Ordering::SeqCst);
1182     }
1183 
1184     pub fn priority(&self) -> SchedPriority {
1185         return self.priority;
1186     }
1187 }
1188 
1189 #[derive(Debug, Clone)]
1190 pub struct KernelStack {
1191     stack: Option<AlignedBox<[u8; KernelStack::SIZE], { KernelStack::ALIGN }>>,
1192     /// 标记该内核栈是否可以被释放
1193     can_be_freed: bool,
1194 }
1195 
1196 impl KernelStack {
1197     pub const SIZE: usize = 0x4000;
1198     pub const ALIGN: usize = 0x4000;
1199 
1200     pub fn new() -> Result<Self, SystemError> {
1201         return Ok(Self {
1202             stack: Some(
1203                 AlignedBox::<[u8; KernelStack::SIZE], { KernelStack::ALIGN }>::new_zeroed()?,
1204             ),
1205             can_be_freed: true,
1206         });
1207     }
1208 
1209     /// 根据已有的空间,构造一个内核栈结构体
1210     ///
1211     /// 仅仅用于BSP启动时,为idle进程构造内核栈。其他时候使用这个函数,很可能造成错误!
1212     pub unsafe fn from_existed(base: VirtAddr) -> Result<Self, SystemError> {
1213         if base.is_null() || !base.check_aligned(Self::ALIGN) {
1214             return Err(SystemError::EFAULT);
1215         }
1216 
1217         return Ok(Self {
1218             stack: Some(
1219                 AlignedBox::<[u8; KernelStack::SIZE], { KernelStack::ALIGN }>::new_unchecked(
1220                     base.data() as *mut [u8; KernelStack::SIZE],
1221                 ),
1222             ),
1223             can_be_freed: false,
1224         });
1225     }
1226 
1227     /// 返回内核栈的起始虚拟地址(低地址)
1228     pub fn start_address(&self) -> VirtAddr {
1229         return VirtAddr::new(self.stack.as_ref().unwrap().as_ptr() as usize);
1230     }
1231 
1232     /// 返回内核栈的结束虚拟地址(高地址)(不包含该地址)
1233     pub fn stack_max_address(&self) -> VirtAddr {
1234         return VirtAddr::new(self.stack.as_ref().unwrap().as_ptr() as usize + Self::SIZE);
1235     }
1236 
1237     pub unsafe fn set_pcb(&mut self, pcb: Weak<ProcessControlBlock>) -> Result<(), SystemError> {
1238         // 将一个Weak<ProcessControlBlock>放到内核栈的最低地址处
1239         let p: *const ProcessControlBlock = Weak::into_raw(pcb);
1240         let stack_bottom_ptr = self.start_address().data() as *mut *const ProcessControlBlock;
1241 
1242         // 如果内核栈的最低地址处已经有了一个pcb,那么,这里就不再设置,直接返回错误
1243         if unlikely(unsafe { !(*stack_bottom_ptr).is_null() }) {
1244             kerror!("kernel stack bottom is not null: {:p}", *stack_bottom_ptr);
1245             return Err(SystemError::EPERM);
1246         }
1247         // 将pcb的地址放到内核栈的最低地址处
1248         unsafe {
1249             *stack_bottom_ptr = p;
1250         }
1251 
1252         return Ok(());
1253     }
1254 
1255     /// 清除内核栈的pcb指针
1256     ///
1257     /// ## 参数
1258     ///
1259     /// - `force` : 如果为true,那么,即使该内核栈的pcb指针不为null,也会被强制清除而不处理Weak指针问题
1260     pub unsafe fn clear_pcb(&mut self, force: bool) {
1261         let stack_bottom_ptr = self.start_address().data() as *mut *const ProcessControlBlock;
1262         if unlikely(unsafe { (*stack_bottom_ptr).is_null() }) {
1263             return;
1264         }
1265 
1266         if !force {
1267             let pcb_ptr: Weak<ProcessControlBlock> = Weak::from_raw(*stack_bottom_ptr);
1268             drop(pcb_ptr);
1269         }
1270 
1271         *stack_bottom_ptr = core::ptr::null();
1272     }
1273 
1274     /// 返回指向当前内核栈pcb的Arc指针
1275     #[allow(dead_code)]
1276     pub unsafe fn pcb(&self) -> Option<Arc<ProcessControlBlock>> {
1277         // 从内核栈的最低地址处取出pcb的地址
1278         let p = self.stack.as_ref().unwrap().as_ptr() as *const *const ProcessControlBlock;
1279         if unlikely(unsafe { (*p).is_null() }) {
1280             return None;
1281         }
1282 
1283         // 为了防止内核栈的pcb指针被释放,这里需要将其包装一下,使得Arc的drop不会被调用
1284         let weak_wrapper: ManuallyDrop<Weak<ProcessControlBlock>> =
1285             ManuallyDrop::new(Weak::from_raw(*p));
1286 
1287         let new_arc: Arc<ProcessControlBlock> = weak_wrapper.upgrade()?;
1288         return Some(new_arc);
1289     }
1290 }
1291 
1292 impl Drop for KernelStack {
1293     fn drop(&mut self) {
1294         if self.stack.is_some() {
1295             let ptr = self.stack.as_ref().unwrap().as_ptr() as *const *const ProcessControlBlock;
1296             if unsafe { !(*ptr).is_null() } {
1297                 let pcb_ptr: Weak<ProcessControlBlock> = unsafe { Weak::from_raw(*ptr) };
1298                 drop(pcb_ptr);
1299             }
1300         }
1301         // 如果该内核栈不可以被释放,那么,这里就forget,不调用AlignedBox的drop函数
1302         if !self.can_be_freed {
1303             let bx = self.stack.take();
1304             core::mem::forget(bx);
1305         }
1306     }
1307 }
1308 
1309 pub fn process_init() {
1310     ProcessManager::init();
1311 }
1312 
1313 #[derive(Debug)]
1314 pub struct ProcessSignalInfo {
1315     // 当前进程
1316     sig_block: SigSet,
1317     // sig_pending 中存储当前线程要处理的信号
1318     sig_pending: SigPending,
1319     // sig_shared_pending 中存储当前线程所属进程要处理的信号
1320     sig_shared_pending: SigPending,
1321     // 当前进程对应的tty
1322     tty: Option<Arc<TtyCore>>,
1323 }
1324 
1325 impl ProcessSignalInfo {
1326     pub fn sig_block(&self) -> &SigSet {
1327         &self.sig_block
1328     }
1329 
1330     pub fn sig_pending(&self) -> &SigPending {
1331         &self.sig_pending
1332     }
1333 
1334     pub fn sig_pending_mut(&mut self) -> &mut SigPending {
1335         &mut self.sig_pending
1336     }
1337 
1338     pub fn sig_block_mut(&mut self) -> &mut SigSet {
1339         &mut self.sig_block
1340     }
1341 
1342     pub fn sig_shared_pending_mut(&mut self) -> &mut SigPending {
1343         &mut self.sig_shared_pending
1344     }
1345 
1346     pub fn sig_shared_pending(&self) -> &SigPending {
1347         &self.sig_shared_pending
1348     }
1349 
1350     pub fn tty(&self) -> Option<Arc<TtyCore>> {
1351         self.tty.clone()
1352     }
1353 
1354     pub fn set_tty(&mut self, tty: Arc<TtyCore>) {
1355         self.tty = Some(tty);
1356     }
1357 
1358     /// 从 pcb 的 siginfo中取出下一个要处理的信号,先处理线程信号,再处理进程信号
1359     ///
1360     /// ## 参数
1361     ///
1362     /// - `sig_mask` 被忽略掉的信号
1363     ///
1364     pub fn dequeue_signal(&mut self, sig_mask: &SigSet) -> (Signal, Option<SigInfo>) {
1365         let res = self.sig_pending.dequeue_signal(sig_mask);
1366         if res.0 != Signal::INVALID {
1367             return res;
1368         } else {
1369             return self.sig_shared_pending.dequeue_signal(sig_mask);
1370         }
1371     }
1372 }
1373 
1374 impl Default for ProcessSignalInfo {
1375     fn default() -> Self {
1376         Self {
1377             sig_block: SigSet::empty(),
1378             sig_pending: SigPending::default(),
1379             sig_shared_pending: SigPending::default(),
1380             tty: None,
1381         }
1382     }
1383 }
1384