pub mod clock; pub mod completion; pub mod cputime; pub mod fair; pub mod idle; pub mod pelt; pub mod prio; use core::{ intrinsics::{likely, unlikely}, sync::atomic::{compiler_fence, fence, AtomicUsize, Ordering}, }; use alloc::{ boxed::Box, collections::LinkedList, sync::{Arc, Weak}, vec::Vec, }; use system_error::SystemError; use crate::{ arch::{interrupt::ipi::send_ipi, CurrentIrqArch}, exception::{ ipi::{IpiKind, IpiTarget}, InterruptArch, }, libs::{ lazy_init::Lazy, spinlock::{SpinLock, SpinLockGuard}, }, mm::percpu::{PerCpu, PerCpuVar}, process::{ProcessControlBlock, ProcessFlags, ProcessManager, ProcessState, SchedInfo}, sched::idle::IdleScheduler, smp::{core::smp_get_processor_id, cpu::ProcessorId}, time::{clocksource::HZ, timer::clock}, }; use self::{ clock::{ClockUpdataFlag, SchedClock}, cputime::{irq_time_read, CpuTimeFunc, IrqTime}, fair::{CfsRunQueue, CompletelyFairScheduler, FairSchedEntity}, prio::PrioUtil, }; static mut CPU_IRQ_TIME: Option> = None; // 这里虽然rq是percpu的,但是在负载均衡的时候需要修改对端cpu的rq,所以仍需加锁 static CPU_RUNQUEUE: Lazy>> = PerCpuVar::define_lazy(); /// 用于记录系统中所有 CPU 的可执行进程数量的总和。 static CALCULATE_LOAD_TASKS: AtomicUsize = AtomicUsize::new(0); const LOAD_FREQ: usize = HZ as usize * 5 + 1; pub const SCHED_FIXEDPOINT_SHIFT: u64 = 10; #[allow(dead_code)] pub const SCHED_FIXEDPOINT_SCALE: u64 = 1 << SCHED_FIXEDPOINT_SHIFT; #[allow(dead_code)] pub const SCHED_CAPACITY_SHIFT: u64 = SCHED_FIXEDPOINT_SHIFT; #[allow(dead_code)] pub const SCHED_CAPACITY_SCALE: u64 = 1 << SCHED_CAPACITY_SHIFT; #[inline] pub fn cpu_irq_time(cpu: usize) -> &'static mut IrqTime { unsafe { CPU_IRQ_TIME.as_mut().unwrap()[cpu] } } #[inline] pub fn cpu_rq(cpu: usize) -> Arc { CPU_RUNQUEUE.ensure(); unsafe { CPU_RUNQUEUE .get() .force_get(ProcessorId::new(cpu as u32)) .clone() } } lazy_static! { pub static ref SCHED_FEATURES: SchedFeature = SchedFeature::GENTLE_FAIR_SLEEPERS | SchedFeature::START_DEBIT | SchedFeature::LAST_BUDDY | SchedFeature::CACHE_HOT_BUDDY | SchedFeature::WAKEUP_PREEMPTION | SchedFeature::NONTASK_CAPACITY | SchedFeature::TTWU_QUEUE | SchedFeature::SIS_UTIL | SchedFeature::RT_PUSH_IPI | SchedFeature::ALT_PERIOD | SchedFeature::BASE_SLICE | SchedFeature::UTIL_EST | SchedFeature::UTIL_EST_FASTUP; } pub trait Scheduler { /// ## 加入当任务进入可运行状态时调用。它将调度实体(任务)放到红黑树中,增加nr_running变量的值。 fn enqueue(rq: &mut CpuRunQueue, pcb: Arc, flags: EnqueueFlag); /// ## 当任务不再可运行时被调用,对应的调度实体被移出红黑树。它减少nr_running变量的值。 fn dequeue(rq: &mut CpuRunQueue, pcb: Arc, flags: DequeueFlag); /// ## 主动让出cpu,这个函数的行为基本上是出队,紧接着入队 fn yield_task(rq: &mut CpuRunQueue); /// ## 检查进入可运行状态的任务能否抢占当前正在运行的任务 fn check_preempt_currnet( rq: &mut CpuRunQueue, pcb: &Arc, flags: WakeupFlags, ); /// ## 选择接下来最适合运行的任务 fn pick_task(rq: &mut CpuRunQueue) -> Option>; /// ## 选择接下来最适合运行的任务 fn pick_next_task( rq: &mut CpuRunQueue, pcb: Option>, ) -> Option>; /// ## 被时间滴答函数调用,它可能导致进程切换。驱动了运行时抢占。 fn tick(rq: &mut CpuRunQueue, pcb: Arc, queued: bool); /// ## 在进程fork时,如需加入cfs,则调用 fn task_fork(pcb: Arc); fn put_prev_task(rq: &mut CpuRunQueue, prev: Arc); } /// 调度策略 #[allow(dead_code)] #[derive(Debug, Clone, Copy, PartialEq, Eq, PartialOrd, Ord)] pub enum SchedPolicy { /// 实时进程 RT, /// 先进先出调度 FIFO, /// 完全公平调度 CFS, /// IDLE IDLE, } #[allow(dead_code)] pub struct TaskGroup { /// CFS管理的调度实体,percpu的 entitys: Vec>, /// 每个CPU的CFS运行队列 cfs: Vec>, /// 父节点 parent: Option>, shares: u64, } #[derive(Debug, Default)] pub struct LoadWeight { /// 负载权重 pub weight: u64, /// weight的倒数,方便计算 pub inv_weight: u32, } impl LoadWeight { /// 用于限制权重在一个合适的区域内 pub const SCHED_FIXEDPOINT_SHIFT: u32 = 10; pub const WMULT_SHIFT: u32 = 32; pub const WMULT_CONST: u32 = !0; pub const NICE_0_LOAD_SHIFT: u32 = Self::SCHED_FIXEDPOINT_SHIFT + Self::SCHED_FIXEDPOINT_SHIFT; pub fn update_load_add(&mut self, inc: u64) { self.weight += inc; self.inv_weight = 0; } pub fn update_load_sub(&mut self, dec: u64) { self.weight -= dec; self.inv_weight = 0; } pub fn update_load_set(&mut self, weight: u64) { self.weight = weight; self.inv_weight = 0; } /// ## 更新负载权重的倒数 pub fn update_inv_weight(&mut self) { // 已经更新 if likely(self.inv_weight != 0) { return; } let w = Self::scale_load_down(self.weight); if unlikely(w >= Self::WMULT_CONST as u64) { // 高位有数据 self.inv_weight = 1; } else if unlikely(w == 0) { // 倒数去最大 self.inv_weight = Self::WMULT_CONST; } else { // 计算倒数 self.inv_weight = Self::WMULT_CONST / w as u32; } } /// ## 计算任务的执行时间差 /// /// 计算公式:(delta_exec * (weight * self.inv_weight)) >> WMULT_SHIFT pub fn calculate_delta(&mut self, delta_exec: u64, weight: u64) -> u64 { // 降低精度 let mut fact = Self::scale_load_down(weight); // 记录fact高32位 let mut fact_hi = (fact >> 32) as u32; // 用于恢复 let mut shift = Self::WMULT_SHIFT; self.update_inv_weight(); if unlikely(fact_hi != 0) { // 这里表示高32位还有数据 // 需要计算最高位,然后继续调整fact let fs = 32 - fact_hi.leading_zeros(); shift -= fs; // 确保高32位全为0 fact >>= fs; } // 这里确定了fact已经在32位内 fact *= self.inv_weight as u64; fact_hi = (fact >> 32) as u32; if fact_hi != 0 { // 这里表示高32位还有数据 // 需要计算最高位,然后继续调整fact let fs = 32 - fact_hi.leading_zeros(); shift -= fs; // 确保高32位全为0 fact >>= fs; } return ((delta_exec as u128 * fact as u128) >> shift) as u64; } /// ## 将负载权重缩小到到一个小的范围中计算,相当于减小精度计算 pub const fn scale_load_down(mut weight: u64) -> u64 { if weight != 0 { weight >>= Self::SCHED_FIXEDPOINT_SHIFT; if weight < 2 { weight = 2; } } weight } #[allow(dead_code)] pub const fn scale_load(weight: u64) -> u64 { weight << Self::SCHED_FIXEDPOINT_SHIFT } } pub trait SchedArch { /// 开启当前核心的调度 fn enable_sched_local(); /// 关闭当前核心的调度 fn disable_sched_local(); /// 在第一次开启调度之前,进行初始化工作。 /// /// 注意区别于sched_init,这个函数只是做初始化时钟的工作等等。 fn initial_setup_sched_local() {} } /// ## PerCpu的运行队列,其中维护了各个调度器对应的rq #[allow(dead_code)] #[derive(Debug)] pub struct CpuRunQueue { lock: SpinLock<()>, lock_on_who: AtomicUsize, cpu: usize, clock_task: u64, clock: u64, prev_irq_time: u64, clock_updata_flags: ClockUpdataFlag, /// 过载 overload: bool, next_balance: u64, /// 运行任务数 nr_running: usize, /// 被阻塞的任务数量 nr_uninterruptible: usize, /// 记录上次更新负载时间 cala_load_update: usize, cala_load_active: usize, /// CFS调度器 cfs: Arc, clock_pelt: u64, lost_idle_time: u64, clock_idle: u64, cfs_tasks: LinkedList>, /// 最近一次的调度信息 sched_info: SchedInfo, /// 当前在运行队列上执行的进程 current: Weak, idle: Weak, } impl CpuRunQueue { pub fn new(cpu: usize) -> Self { Self { lock: SpinLock::new(()), lock_on_who: AtomicUsize::new(usize::MAX), cpu, clock_task: 0, clock: 0, prev_irq_time: 0, clock_updata_flags: ClockUpdataFlag::empty(), overload: false, next_balance: 0, nr_running: 0, nr_uninterruptible: 0, cala_load_update: (clock() + (5 * HZ + 1)) as usize, cala_load_active: 0, cfs: Arc::new(CfsRunQueue::new()), clock_pelt: 0, lost_idle_time: 0, clock_idle: 0, cfs_tasks: LinkedList::new(), sched_info: SchedInfo::default(), current: Weak::new(), idle: Weak::new(), } } /// 此函数只能在关中断的情况下使用!!! /// 获取到rq的可变引用,需要注意的是返回的第二个值需要确保其生命周期 /// 所以可以说这个函数是unsafe的,需要确保正确性 /// 在中断上下文,关中断的情况下,此函数是安全的 pub fn self_lock(&self) -> (&mut Self, Option>) { if self.lock.is_locked() && smp_get_processor_id().data() as usize == self.lock_on_who.load(Ordering::SeqCst) { // 在本cpu已上锁则可以直接拿 ( unsafe { &mut *(self as *const Self as usize as *mut Self) }, None, ) } else { // 否则先上锁再拿 let guard = self.lock(); ( unsafe { &mut *(self as *const Self as usize as *mut Self) }, Some(guard), ) } } fn lock(&self) -> SpinLockGuard<()> { let guard = self.lock.lock_irqsave(); // 更新在哪一个cpu上锁 self.lock_on_who .store(smp_get_processor_id().data() as usize, Ordering::SeqCst); guard } pub fn enqueue_task(&mut self, pcb: Arc, flags: EnqueueFlag) { if !flags.contains(EnqueueFlag::ENQUEUE_NOCLOCK) { self.update_rq_clock(); } if !flags.contains(EnqueueFlag::ENQUEUE_RESTORE) { let sched_info = pcb.sched_info().sched_stat.upgradeable_read_irqsave(); if sched_info.last_queued == 0 { sched_info.upgrade().last_queued = self.clock; } } match pcb.sched_info().policy() { SchedPolicy::CFS => CompletelyFairScheduler::enqueue(self, pcb, flags), SchedPolicy::FIFO => todo!(), SchedPolicy::RT => todo!(), SchedPolicy::IDLE => IdleScheduler::enqueue(self, pcb, flags), } // TODO:https://code.dragonos.org.cn/xref/linux-6.6.21/kernel/sched/core.c#239 } pub fn dequeue_task(&mut self, pcb: Arc, flags: DequeueFlag) { // TODO:sched_core if !flags.contains(DequeueFlag::DEQUEUE_NOCLOCK) { self.update_rq_clock() } if !flags.contains(DequeueFlag::DEQUEUE_SAVE) { let sched_info = pcb.sched_info().sched_stat.upgradeable_read_irqsave(); if sched_info.last_queued > 0 { let delta = self.clock - sched_info.last_queued; let mut sched_info = sched_info.upgrade(); sched_info.last_queued = 0; sched_info.run_delay += delta as usize; self.sched_info.run_delay += delta as usize; } } match pcb.sched_info().policy() { SchedPolicy::CFS => CompletelyFairScheduler::dequeue(self, pcb, flags), SchedPolicy::FIFO => todo!(), SchedPolicy::RT => todo!(), SchedPolicy::IDLE => todo!(), } } /// 启用一个任务,将加入队列 pub fn activate_task(&mut self, pcb: &Arc, mut flags: EnqueueFlag) { if *pcb.sched_info().on_rq.lock_irqsave() == OnRq::Migrating { flags |= EnqueueFlag::ENQUEUE_MIGRATED; } if flags.contains(EnqueueFlag::ENQUEUE_MIGRATED) { todo!() } self.enqueue_task(pcb.clone(), flags); *pcb.sched_info().on_rq.lock_irqsave() = OnRq::Queued; } /// 检查对应的task是否可以抢占当前运行的task #[allow(clippy::comparison_chain)] pub fn check_preempt_currnet(&mut self, pcb: &Arc, flags: WakeupFlags) { if pcb.sched_info().policy() == self.current().sched_info().policy() { match self.current().sched_info().policy() { SchedPolicy::CFS => { CompletelyFairScheduler::check_preempt_currnet(self, pcb, flags) } SchedPolicy::FIFO => todo!(), SchedPolicy::RT => todo!(), SchedPolicy::IDLE => IdleScheduler::check_preempt_currnet(self, pcb, flags), } } else if pcb.sched_info().policy() < self.current().sched_info().policy() { // 调度优先级更高 self.resched_current(); } if *self.current().sched_info().on_rq.lock_irqsave() == OnRq::Queued && self.current().flags().contains(ProcessFlags::NEED_SCHEDULE) { self.clock_updata_flags .insert(ClockUpdataFlag::RQCF_REQ_SKIP); } } /// 禁用一个任务,将离开队列 pub fn deactivate_task(&mut self, pcb: Arc, flags: DequeueFlag) { *pcb.sched_info().on_rq.lock_irqsave() = if flags.contains(DequeueFlag::DEQUEUE_SLEEP) { OnRq::None } else { OnRq::Migrating }; self.dequeue_task(pcb, flags); } #[inline] pub fn cfs_rq(&self) -> Arc { self.cfs.clone() } /// 更新rq时钟 pub fn update_rq_clock(&mut self) { // 需要跳过这次时钟更新 if self .clock_updata_flags .contains(ClockUpdataFlag::RQCF_ACT_SKIP) { return; } let clock = SchedClock::sched_clock_cpu(self.cpu); if clock < self.clock { return; } let delta = clock - self.clock; self.clock += delta; // kerror!("clock {}", self.clock); self.update_rq_clock_task(delta); } /// 更新任务时钟 pub fn update_rq_clock_task(&mut self, mut delta: u64) { let mut irq_delta = irq_time_read(self.cpu) - self.prev_irq_time; // if self.cpu == 0 { // kerror!( // "cpu 0 delta {delta} irq_delta {} irq_time_read(self.cpu) {} self.prev_irq_time {}", // irq_delta, // irq_time_read(self.cpu), // self.prev_irq_time // ); // } compiler_fence(Ordering::SeqCst); if irq_delta > delta { irq_delta = delta; } self.prev_irq_time += irq_delta; delta -= irq_delta; // todo: psi? // send_to_default_serial8250_port(format!("\n{delta}\n",).as_bytes()); compiler_fence(Ordering::SeqCst); self.clock_task += delta; compiler_fence(Ordering::SeqCst); // if self.cpu == 0 { // kerror!("cpu {} clock_task {}", self.cpu, self.clock_task); // } // todo: pelt? } /// 计算当前进程中的可执行数量 fn calculate_load_fold_active(&mut self, adjust: usize) -> usize { let mut nr_active = self.nr_running - adjust; nr_active += self.nr_uninterruptible; let mut delta = 0; if nr_active != self.cala_load_active { delta = nr_active - self.cala_load_active; self.cala_load_active = nr_active; } delta } /// ## tick计算全局负载 pub fn calculate_global_load_tick(&mut self) { if clock() < self.cala_load_update as u64 { // 如果当前时间在上次更新时间之前,则直接返回 return; } let delta = self.calculate_load_fold_active(0); if delta != 0 { CALCULATE_LOAD_TASKS.fetch_add(delta, Ordering::SeqCst); } self.cala_load_update += LOAD_FREQ; } pub fn add_nr_running(&mut self, nr_running: usize) { let prev = self.nr_running; self.nr_running = prev + nr_running; if prev < 2 && self.nr_running >= 2 && !self.overload { self.overload = true; } } pub fn sub_nr_running(&mut self, count: usize) { self.nr_running -= count; } /// 在运行idle? pub fn sched_idle_rq(&self) -> bool { return unlikely( self.nr_running == self.cfs.idle_h_nr_running as usize && self.nr_running > 0, ); } #[inline] pub fn current(&self) -> Arc { self.current.upgrade().unwrap() } #[inline] pub fn set_current(&mut self, pcb: Weak) { self.current = pcb; } #[inline] pub fn set_idle(&mut self, pcb: Weak) { self.idle = pcb; } #[inline] pub fn clock_task(&self) -> u64 { self.clock_task } /// 重新调度当前进程 pub fn resched_current(&self) { let current = self.current(); // 又需要被调度? if unlikely(current.flags().contains(ProcessFlags::NEED_SCHEDULE)) { return; } let cpu = self.cpu; if cpu == smp_get_processor_id().data() as usize { // assert!( // Arc::ptr_eq(¤t, &ProcessManager::current_pcb()), // "rq current name {} process current {}", // current.basic().name().to_string(), // ProcessManager::current_pcb().basic().name().to_string(), // ); // 设置需要调度 ProcessManager::current_pcb() .flags() .insert(ProcessFlags::NEED_SCHEDULE); return; } // 向目标cpu发送重调度ipi send_resched_ipi(ProcessorId::new(cpu as u32)); } /// 选择下一个task pub fn pick_next_task(&mut self, prev: Arc) -> Arc { if likely(prev.sched_info().policy() >= SchedPolicy::CFS) && self.nr_running == self.cfs.h_nr_running as usize { let p = CompletelyFairScheduler::pick_next_task(self, Some(prev.clone())); if let Some(pcb) = p.as_ref() { return pcb.clone(); } else { // kerror!( // "pick idle cfs rq {:?}", // self.cfs_rq() // .entities // .iter() // .map(|x| x.1.pid) // .collect::>() // ); match prev.sched_info().policy() { SchedPolicy::FIFO => todo!(), SchedPolicy::RT => todo!(), SchedPolicy::CFS => CompletelyFairScheduler::put_prev_task(self, prev), SchedPolicy::IDLE => IdleScheduler::put_prev_task(self, prev), } // 选择idle return self.idle.upgrade().unwrap(); } } todo!() } } bitflags! { pub struct SchedFeature:u32 { /// 给予睡眠任务仅有 50% 的服务赤字。这意味着睡眠任务在被唤醒后会获得一定的服务,但不能过多地占用资源。 const GENTLE_FAIR_SLEEPERS = 1 << 0; /// 将新任务排在前面,以避免已经运行的任务被饿死 const START_DEBIT = 1 << 1; /// 在调度时优先选择上次唤醒的任务,因为它可能会访问之前唤醒的任务所使用的数据,从而提高缓存局部性。 const NEXT_BUDDY = 1 << 2; /// 在调度时优先选择上次运行的任务,因为它可能会访问与之前运行的任务相同的数据,从而提高缓存局部性。 const LAST_BUDDY = 1 << 3; /// 认为任务的伙伴(buddy)在缓存中是热点,减少缓存伙伴被迁移的可能性,从而提高缓存局部性。 const CACHE_HOT_BUDDY = 1 << 4; /// 允许唤醒时抢占当前任务。 const WAKEUP_PREEMPTION = 1 << 5; /// 基于任务未运行时间来减少 CPU 的容量。 const NONTASK_CAPACITY = 1 << 6; /// 将远程唤醒排队到目标 CPU,并使用调度器 IPI 处理它们,以减少运行队列锁的争用。 const TTWU_QUEUE = 1 << 7; /// 在唤醒时尝试限制对最后级联缓存(LLC)域的无谓扫描。 const SIS_UTIL = 1 << 8; /// 在 RT(Real-Time)任务迁移时,通过发送 IPI 来减少 CPU 之间的锁竞争。 const RT_PUSH_IPI = 1 << 9; /// 启用估计的 CPU 利用率功能,用于调度决策。 const UTIL_EST = 1 << 10; const UTIL_EST_FASTUP = 1 << 11; /// 启用备选调度周期 const ALT_PERIOD = 1 << 12; /// 启用基本时间片 const BASE_SLICE = 1 << 13; } pub struct EnqueueFlag: u8 { const ENQUEUE_WAKEUP = 0x01; const ENQUEUE_RESTORE = 0x02; const ENQUEUE_MOVE = 0x04; const ENQUEUE_NOCLOCK = 0x08; const ENQUEUE_MIGRATED = 0x40; const ENQUEUE_INITIAL = 0x80; } pub struct DequeueFlag: u8 { const DEQUEUE_SLEEP = 0x01; const DEQUEUE_SAVE = 0x02; /* Matches ENQUEUE_RESTORE */ const DEQUEUE_MOVE = 0x04; /* Matches ENQUEUE_MOVE */ const DEQUEUE_NOCLOCK = 0x08; /* Matches ENQUEUE_NOCLOCK */ } pub struct WakeupFlags: u8 { /* Wake flags. The first three directly map to some SD flag value */ const WF_EXEC = 0x02; /* Wakeup after exec; maps to SD_BALANCE_EXEC */ const WF_FORK = 0x04; /* Wakeup after fork; maps to SD_BALANCE_FORK */ const WF_TTWU = 0x08; /* Wakeup; maps to SD_BALANCE_WAKE */ const WF_SYNC = 0x10; /* Waker goes to sleep after wakeup */ const WF_MIGRATED = 0x20; /* Internal use, task got migrated */ const WF_CURRENT_CPU = 0x40; /* Prefer to move the wakee to the current CPU. */ } pub struct SchedMode: u8 { /* * Constants for the sched_mode argument of __schedule(). * * The mode argument allows RT enabled kernels to differentiate a * preemption from blocking on an 'sleeping' spin/rwlock. Note that * SM_MASK_PREEMPT for !RT has all bits set, which allows the compiler to * optimize the AND operation out and just check for zero. */ /// 在调度过程中不会再次进入队列,即需要手动唤醒 const SM_NONE = 0x0; /// 重新加入队列,即当前进程被抢占,需要时钟调度 const SM_PREEMPT = 0x1; /// rt相关 const SM_RTLOCK_WAIT = 0x2; /// 默认与SM_PREEMPT相同 const SM_MASK_PREEMPT = Self::SM_PREEMPT.bits; } } #[derive(Copy, Clone, Debug, PartialEq)] pub enum OnRq { Queued, Migrating, None, } impl ProcessManager { pub fn update_process_times(user_tick: bool) { let pcb = Self::current_pcb(); CpuTimeFunc::irqtime_account_process_tick(&pcb, user_tick, 1); scheduler_tick(); } } /// ## 时钟tick时调用此函数 pub fn scheduler_tick() { fence(Ordering::SeqCst); // 获取当前CPU索引 let cpu_idx = smp_get_processor_id().data() as usize; // 获取当前CPU的请求队列 let rq = cpu_rq(cpu_idx); let (rq, guard) = rq.self_lock(); // 获取当前请求队列的当前请求 let current = rq.current(); // 更新请求队列时钟 rq.update_rq_clock(); match current.sched_info().policy() { SchedPolicy::CFS => CompletelyFairScheduler::tick(rq, current, false), SchedPolicy::FIFO => todo!(), SchedPolicy::RT => todo!(), SchedPolicy::IDLE => IdleScheduler::tick(rq, current, false), } rq.calculate_global_load_tick(); drop(guard); // TODO:处理负载均衡 } /// ## 执行调度 /// 若preempt_count不为0则报错 #[inline] pub fn schedule(sched_mod: SchedMode) { let _guard = unsafe { CurrentIrqArch::save_and_disable_irq() }; assert_eq!(ProcessManager::current_pcb().preempt_count(), 0); __schedule(sched_mod); } /// ## 执行调度 /// 此函数与schedule的区别为,该函数不会检查preempt_count /// 适用于时钟中断等场景 pub fn __schedule(sched_mod: SchedMode) { let cpu = smp_get_processor_id().data() as usize; let rq = cpu_rq(cpu); let mut prev = rq.current(); if let ProcessState::Exited(_) = prev.clone().sched_info().inner_lock_read_irqsave().state() { // 从exit进的Schedule prev = ProcessManager::current_pcb(); } // TODO: hrtick_clear(rq); let (rq, _guard) = rq.self_lock(); rq.clock_updata_flags = ClockUpdataFlag::from_bits_truncate(rq.clock_updata_flags.bits() << 1); rq.update_rq_clock(); rq.clock_updata_flags = ClockUpdataFlag::RQCF_UPDATE; // kBUG!( // "before cfs rq pcbs {:?}\nvruntimes {:?}\n", // rq.cfs // .entities // .iter() // .map(|x| { x.1.pcb().pid() }) // .collect::>(), // rq.cfs // .entities // .iter() // .map(|x| { x.1.vruntime }) // .collect::>(), // ); // kwarn!( // "before cfs rq {:?} prev {:?}", // rq.cfs // .entities // .iter() // .map(|x| { x.1.pcb().pid() }) // .collect::>(), // prev.pid() // ); // kerror!("prev pid {:?} {:?}", prev.pid(), prev.sched_info().policy()); if !sched_mod.contains(SchedMode::SM_MASK_PREEMPT) && prev.sched_info().policy() != SchedPolicy::IDLE && prev.sched_info().inner_lock_read_irqsave().is_mark_sleep() { // kwarn!("deactivate_task prev {:?}", prev.pid()); // TODO: 这里需要处理信号 // https://code.dragonos.org.cn/xref/linux-6.6.21/kernel/sched/core.c?r=&mo=172979&fi=6578#6630 rq.deactivate_task( prev.clone(), DequeueFlag::DEQUEUE_SLEEP | DequeueFlag::DEQUEUE_NOCLOCK, ); } let next = rq.pick_next_task(prev.clone()); // kBUG!( // "after cfs rq pcbs {:?}\nvruntimes {:?}\n", // rq.cfs // .entities // .iter() // .map(|x| { x.1.pcb().pid() }) // .collect::>(), // rq.cfs // .entities // .iter() // .map(|x| { x.1.vruntime }) // .collect::>(), // ); // kerror!("next {:?}", next.pid()); prev.flags().remove(ProcessFlags::NEED_SCHEDULE); fence(Ordering::SeqCst); if likely(!Arc::ptr_eq(&prev, &next)) { rq.set_current(Arc::downgrade(&next)); // kwarn!( // "switch_process prev {:?} next {:?} sched_mode {sched_mod:?}", // prev.pid(), // next.pid() // ); // send_to_default_serial8250_port( // format!( // "switch_process prev {:?} next {:?} sched_mode {sched_mod:?}\n", // prev.pid(), // next.pid() // ) // .as_bytes(), // ); // CurrentApic.send_eoi(); compiler_fence(Ordering::SeqCst); unsafe { ProcessManager::switch_process(prev, next) }; } else { kwarn!( "!!!switch_process {} {:?} to self ", prev.basic().name(), prev.pid(), ); assert!( Arc::ptr_eq(&ProcessManager::current_pcb(), &prev), "{}", ProcessManager::current_pcb().basic().name() ); } } pub fn sched_fork(pcb: &Arc) -> Result<(), SystemError> { let mut prio_guard = pcb.sched_info().prio_data.write_irqsave(); let current = ProcessManager::current_pcb(); prio_guard.prio = current.sched_info().prio_data.read_irqsave().normal_prio; if PrioUtil::dl_prio(prio_guard.prio) { return Err(SystemError::EAGAIN_OR_EWOULDBLOCK); } else if PrioUtil::rt_prio(prio_guard.prio) { let policy = &pcb.sched_info().sched_policy; *policy.write_irqsave() = SchedPolicy::RT; } else { let policy = &pcb.sched_info().sched_policy; *policy.write_irqsave() = SchedPolicy::CFS; } pcb.sched_info() .sched_entity() .force_mut() .init_entity_runnable_average(); Ok(()) } pub fn sched_cgroup_fork(pcb: &Arc) { __set_task_cpu(pcb, smp_get_processor_id()); match pcb.sched_info().policy() { SchedPolicy::RT => todo!(), SchedPolicy::FIFO => todo!(), SchedPolicy::CFS => CompletelyFairScheduler::task_fork(pcb.clone()), SchedPolicy::IDLE => todo!(), } } fn __set_task_cpu(pcb: &Arc, cpu: ProcessorId) { // TODO: Fixme There is not implement group sched; let se = pcb.sched_info().sched_entity(); let rq = cpu_rq(cpu.data() as usize); se.force_mut().set_cfs(Arc::downgrade(&rq.cfs)); } #[inline(never)] pub fn sched_init() { // 初始化percpu变量 unsafe { CPU_IRQ_TIME = Some(Vec::with_capacity(PerCpu::MAX_CPU_NUM as usize)); CPU_IRQ_TIME .as_mut() .unwrap() .resize_with(PerCpu::MAX_CPU_NUM as usize, || Box::leak(Box::default())); let mut cpu_runqueue = Vec::with_capacity(PerCpu::MAX_CPU_NUM as usize); for cpu in 0..PerCpu::MAX_CPU_NUM as usize { let rq = Arc::new(CpuRunQueue::new(cpu)); rq.cfs.force_mut().set_rq(Arc::downgrade(&rq)); cpu_runqueue.push(rq); } CPU_RUNQUEUE.init(PerCpuVar::new(cpu_runqueue).unwrap()); }; } #[inline] pub fn send_resched_ipi(cpu: ProcessorId) { send_ipi(IpiKind::KickCpu, IpiTarget::Specified(cpu)); }