// #![allow(dead_code)] use core::intrinsics::unlikely; use alloc::{collections::LinkedList, sync::Arc, vec::Vec}; use crate::{ arch::{sched::sched, CurrentIrqArch}, exception::InterruptArch, kerror, process::{ProcessControlBlock, ProcessManager, ProcessState}, }; use super::{ mutex::MutexGuard, spinlock::{SpinLock, SpinLockGuard}, }; #[derive(Debug)] struct InnerWaitQueue { /// 等待队列的链表 wait_list: LinkedList>, } /// 被自旋锁保护的等待队列 #[derive(Debug)] pub struct WaitQueue(SpinLock); #[allow(dead_code)] impl WaitQueue { pub const INIT: WaitQueue = WaitQueue(SpinLock::new(InnerWaitQueue::INIT)); /// @brief 让当前进程在等待队列上进行等待,并且,允许被信号打断 pub fn sleep(&self) { before_sleep_check(0); let mut guard: SpinLockGuard = self.0.lock_irqsave(); ProcessManager::mark_sleep(true).unwrap_or_else(|e| { panic!("sleep error: {:?}", e); }); guard.wait_list.push_back(ProcessManager::current_pcb()); drop(guard); sched(); } /// @brief 让当前进程在等待队列上进行等待,并且,在释放waitqueue的锁之前,执行f函数闭包 pub fn sleep_with_func(&self, f: F) where F: FnOnce(), { before_sleep_check(0); let mut guard: SpinLockGuard = self.0.lock(); let irq_guard = unsafe { CurrentIrqArch::save_and_disable_irq() }; ProcessManager::mark_sleep(true).unwrap_or_else(|e| { panic!("sleep error: {:?}", e); }); drop(irq_guard); guard.wait_list.push_back(ProcessManager::current_pcb()); f(); drop(guard); sched(); } /// @brief 让当前进程在等待队列上进行等待. 但是,在释放waitqueue的锁之后,不会调用调度函数。 /// 这样的设计,是为了让调用者可以在执行本函数之后,执行一些操作,然后再【手动调用调度函数】。 /// /// 执行本函数前,需要确保处于【中断禁止】状态。 /// /// 尽管sleep_with_func和sleep_without_schedule都可以实现这个功能,但是,sleep_with_func会在释放锁之前,执行f函数闭包。 /// /// 考虑这样一个场景: /// 等待队列位于某个自旋锁保护的数据结构A中,我们希望在进程睡眠的同时,释放数据结构A的锁。 /// 在这种情况下,如果使用sleep_with_func,所有权系统不会允许我们这么做。 /// 因此,sleep_without_schedule的设计,正是为了解决这个问题。 /// /// 由于sleep_without_schedule不会调用调度函数,因此,如果开发者忘记在执行本函数之后,手动调用调度函数, /// 由于时钟中断到来或者‘其他cpu kick了当前cpu’,可能会导致一些未定义的行为。 pub unsafe fn sleep_without_schedule(&self) { before_sleep_check(1); // 安全检查:确保当前处于中断禁止状态 assert!(CurrentIrqArch::is_irq_enabled() == false); let mut guard: SpinLockGuard = self.0.lock(); ProcessManager::mark_sleep(true).unwrap_or_else(|e| { panic!("sleep error: {:?}", e); }); guard.wait_list.push_back(ProcessManager::current_pcb()); drop(guard); } pub unsafe fn sleep_without_schedule_uninterruptible(&self) { before_sleep_check(0); // 安全检查:确保当前处于中断禁止状态 assert!(CurrentIrqArch::is_irq_enabled() == false); let mut guard: SpinLockGuard = self.0.lock(); ProcessManager::mark_sleep(false).unwrap_or_else(|e| { panic!("sleep error: {:?}", e); }); guard.wait_list.push_back(ProcessManager::current_pcb()); drop(guard); } /// @brief 让当前进程在等待队列上进行等待,并且,不允许被信号打断 pub fn sleep_uninterruptible(&self) { before_sleep_check(0); let mut guard: SpinLockGuard = self.0.lock(); let irq_guard = unsafe { CurrentIrqArch::save_and_disable_irq() }; ProcessManager::mark_sleep(false).unwrap_or_else(|e| { panic!("sleep error: {:?}", e); }); drop(irq_guard); guard.wait_list.push_back(ProcessManager::current_pcb()); drop(guard); sched(); } /// @brief 让当前进程在等待队列上进行等待,并且,允许被信号打断。 /// 在当前进程的pcb加入队列后,解锁指定的自旋锁。 pub fn sleep_unlock_spinlock(&self, to_unlock: SpinLockGuard) { before_sleep_check(1); let mut guard: SpinLockGuard = self.0.lock(); let irq_guard = unsafe { CurrentIrqArch::save_and_disable_irq() }; ProcessManager::mark_sleep(true).unwrap_or_else(|e| { panic!("sleep error: {:?}", e); }); drop(irq_guard); guard.wait_list.push_back(ProcessManager::current_pcb()); drop(to_unlock); drop(guard); sched(); } /// @brief 让当前进程在等待队列上进行等待,并且,允许被信号打断。 /// 在当前进程的pcb加入队列后,解锁指定的Mutex。 pub fn sleep_unlock_mutex(&self, to_unlock: MutexGuard) { before_sleep_check(1); let mut guard: SpinLockGuard = self.0.lock(); let irq_guard = unsafe { CurrentIrqArch::save_and_disable_irq() }; ProcessManager::mark_sleep(true).unwrap_or_else(|e| { panic!("sleep error: {:?}", e); }); drop(irq_guard); guard.wait_list.push_back(ProcessManager::current_pcb()); drop(to_unlock); drop(guard); sched(); } /// @brief 让当前进程在等待队列上进行等待,并且,不允许被信号打断。 /// 在当前进程的pcb加入队列后,解锁指定的自旋锁。 pub fn sleep_uninterruptible_unlock_spinlock(&self, to_unlock: SpinLockGuard) { before_sleep_check(1); let mut guard: SpinLockGuard = self.0.lock(); let irq_guard = unsafe { CurrentIrqArch::save_and_disable_irq() }; ProcessManager::mark_sleep(false).unwrap_or_else(|e| { panic!("sleep error: {:?}", e); }); drop(irq_guard); guard.wait_list.push_back(ProcessManager::current_pcb()); drop(to_unlock); drop(guard); sched(); } /// @brief 让当前进程在等待队列上进行等待,并且,不允许被信号打断。 /// 在当前进程的pcb加入队列后,解锁指定的Mutex。 pub fn sleep_uninterruptible_unlock_mutex(&self, to_unlock: MutexGuard) { before_sleep_check(1); let mut guard: SpinLockGuard = self.0.lock(); let irq_guard = unsafe { CurrentIrqArch::save_and_disable_irq() }; ProcessManager::mark_sleep(false).unwrap_or_else(|e| { panic!("sleep error: {:?}", e); }); drop(irq_guard); guard.wait_list.push_back(ProcessManager::current_pcb()); drop(to_unlock); drop(guard); sched(); } /// @brief 唤醒在队列中等待的第一个进程。 /// 如果这个进程的state与给定的state进行and操作之后,结果不为0,则唤醒它。 /// /// @param state 用于判断的state,如果队列第一个进程与这个state相同,或者为None(表示不进行这个判断),则唤醒这个进程。 /// /// @return true 成功唤醒进程 /// @return false 没有唤醒进程 pub fn wakeup(&self, state: Option) -> bool { let mut guard: SpinLockGuard = self.0.lock_irqsave(); // 如果队列为空,则返回 if guard.wait_list.is_empty() { return false; } // 如果队列头部的pcb的state与给定的state相与,结果不为0,则唤醒 if let Some(state) = state { if guard .wait_list .front() .unwrap() .sched_info() .inner_lock_read_irqsave() .state() != state { return false; } } let to_wakeup = guard.wait_list.pop_front().unwrap(); drop(guard); let res = ProcessManager::wakeup(&to_wakeup).is_ok(); return res; } /// @brief 唤醒在队列中,符合条件的所有进程。 /// /// @param state 用于判断的state,如果一个进程与这个state相同,或者为None(表示不进行这个判断),则唤醒这个进程。 pub fn wakeup_all(&self, state: Option) { let mut guard: SpinLockGuard = self.0.lock_irqsave(); // 如果队列为空,则返回 if guard.wait_list.is_empty() { return; } let mut to_push_back: Vec> = Vec::new(); // 如果队列头部的pcb的state与给定的state相与,结果不为0,则唤醒 while let Some(to_wakeup) = guard.wait_list.pop_front() { let mut wake = false; if let Some(state) = state { if to_wakeup.sched_info().inner_lock_read_irqsave().state() == state { wake = true; } } else { wake = true; } if wake { ProcessManager::wakeup(&to_wakeup).unwrap_or_else(|e| { kerror!("wakeup pid: {:?} error: {:?}", to_wakeup.pid(), e); }); continue; } else { to_push_back.push(to_wakeup); } } for to_wakeup in to_push_back { guard.wait_list.push_back(to_wakeup); } } /// @brief 获得当前等待队列的大小 pub fn len(&self) -> usize { return self.0.lock().wait_list.len(); } } impl InnerWaitQueue { pub const INIT: InnerWaitQueue = InnerWaitQueue { wait_list: LinkedList::new(), }; } fn before_sleep_check(max_preempt: usize) { let pcb = ProcessManager::current_pcb(); if unlikely(pcb.preempt_count() > max_preempt) { kwarn!( "Process {:?}: Try to sleep when preempt count is {}", pcb.pid(), pcb.preempt_count() ); } } /// 事件等待队列 #[derive(Debug)] pub struct EventWaitQueue { wait_list: SpinLock)>>, } #[allow(dead_code)] impl EventWaitQueue { pub fn new() -> Self { Self { wait_list: SpinLock::new(Vec::new()), } } /// ## 让当前进程在该队列上等待感兴趣的事件 /// /// ### 参数 /// - events: 进程感兴趣的事件,events最好是为位表示,一位表示一个事件 /// /// 注意,使用前应该注意有可能其他地方定义了冲突的事件,可能会导致未定义行为 pub fn sleep(&self, events: u64) { before_sleep_check(0); let mut guard = self.wait_list.lock_irqsave(); ProcessManager::mark_sleep(true).unwrap_or_else(|e| { panic!("sleep error: {:?}", e); }); guard.push((events, ProcessManager::current_pcb())); drop(guard); sched(); } pub unsafe fn sleep_without_schedule(&self, events: u64) { before_sleep_check(1); let mut guard = self.wait_list.lock_irqsave(); ProcessManager::mark_sleep(true).unwrap_or_else(|e| { panic!("sleep error: {:?}", e); }); guard.push((events, ProcessManager::current_pcb())); drop(guard); } pub fn sleep_unlock_spinlock(&self, events: u64, to_unlock: SpinLockGuard) { before_sleep_check(1); let mut guard = self.wait_list.lock_irqsave(); let irq_guard = unsafe { CurrentIrqArch::save_and_disable_irq() }; ProcessManager::mark_sleep(true).unwrap_or_else(|e| { panic!("sleep error: {:?}", e); }); drop(irq_guard); guard.push((events, ProcessManager::current_pcb())); drop(to_unlock); drop(guard); sched(); } /// ### 唤醒该队列上等待events的进程 /// /// ### 参数 /// - events: 发生的事件 /// /// 需要注意的是,只要触发了events中的任意一件事件,进程都会被唤醒 pub fn wakeup_any(&self, events: u64) -> usize { let mut ret = 0; let mut wq_guard = self.wait_list.lock_irqsave(); wq_guard.retain(|(es, pcb)| { if *es & events > 0 { // 有感兴趣的事件 if ProcessManager::wakeup(pcb).is_ok() { ret += 1; return false; } else { return true; } } else { return true; } }); ret } /// ### 唤醒该队列上等待events的进程 /// /// ### 参数 /// - events: 发生的事件 /// /// 需要注意的是,只有满足所有事件的进程才会被唤醒 pub fn wakeup(&self, events: u64) -> usize { let mut ret = 0; let mut wq_guard = self.wait_list.lock_irqsave(); wq_guard.retain(|(es, pcb)| { if *es == events { // 有感兴趣的事件 if ProcessManager::wakeup(pcb).is_ok() { ret += 1; return false; } else { return true; } } else { return true; } }); ret } pub fn wakeup_all(&self) { self.wakeup_any(u64::MAX); } }