#![allow(dead_code)] use core::{ cell::UnsafeCell, hint::spin_loop, mem::{self, ManuallyDrop}, ops::{Deref, DerefMut}, sync::atomic::{AtomicU32, Ordering}, }; use crate::{ arch::CurrentIrqArch, exception::{InterruptArch, IrqFlagsGuard}, process::ProcessManager, syscall::SystemError, }; ///RwLock读写锁 /// @brief READER位占据从右往左数第三个比特位 const READER: u32 = 1 << 2; /// @brief UPGRADED位占据从右到左数第二个比特位 const UPGRADED: u32 = 1 << 1; /// @brief WRITER位占据最右边的比特位 const WRITER: u32 = 1; const READER_BIT: u32 = 2; /// @brief 读写锁的基本数据结构 /// @param lock 32位原子变量,最右边的两位从左到右分别是UPGRADED,WRITER (标志位) /// 剩下的bit位存储READER数量(除了MSB) /// 对于标志位,0代表无, 1代表有 /// 对于剩下的比特位表征READER的数量的多少 /// lock的MSB必须为0,否则溢出 #[derive(Debug)] pub struct RwLock { lock: AtomicU32, data: UnsafeCell, } /// @brief READER守卫的数据结构 /// @param lock 是对RwLock的lock属性值的只读引用 pub struct RwLockReadGuard<'a, T: 'a> { data: *const T, lock: &'a AtomicU32, irq_guard: Option, } /// @brief UPGRADED是介于READER和WRITER之间的一种锁,它可以升级为WRITER, /// UPGRADED守卫的数据结构,注册UPGRADED锁只需要查看UPGRADED和WRITER的比特位 /// 但是当UPGRADED守卫注册后,不允许有新的读者锁注册 /// @param inner 是对RwLock数据结构的只读引用 pub struct RwLockUpgradableGuard<'a, T: 'a> { data: *const T, inner: &'a RwLock, irq_guard: Option, } /// @brief WRITER守卫的数据结构 /// @param data RwLock的data的可变引用 /// @param inner 是对RwLock数据结构的只读引用 pub struct RwLockWriteGuard<'a, T: 'a> { data: *mut T, inner: &'a RwLock, irq_guard: Option, } unsafe impl Send for RwLock {} unsafe impl Sync for RwLock {} /// @brief RwLock的API impl RwLock { #[inline] /// @brief RwLock的初始化 pub const fn new(data: T) -> Self { return RwLock { lock: AtomicU32::new(0), data: UnsafeCell::new(data), }; } #[allow(dead_code)] #[inline] /// @brief 将读写锁的皮扒掉,返回内在的data,返回的是一个真身而非引用 pub fn into_inner(self) -> T { let RwLock { data, .. } = self; return data.into_inner(); } #[allow(dead_code)] #[inline] /// @brief 返回data的raw pointer, /// unsafe pub fn as_mut_ptr(&self) -> *mut T { return self.data.get(); } #[allow(dead_code)] #[inline] /// @brief 获取实时的读者数并尝试加1,如果增加值成功则返回增加1后的读者数,否则panic fn current_reader(&self) -> Result { const MAX_READERS: u32 = core::u32::MAX >> READER_BIT >> 1; //右移3位 let value = self.lock.fetch_add(READER, Ordering::Acquire); //value二进制形式的MSB不能为1, 否则导致溢出 if value > MAX_READERS << READER_BIT { self.lock.fetch_sub(READER, Ordering::Release); //panic!("Too many lock readers, cannot safely proceed"); return Err(SystemError::EOVERFLOW); } else { return Ok(value); } } #[allow(dead_code)] #[inline] /// @brief 尝试获取READER守卫 pub fn try_read(&self) -> Option> { ProcessManager::preempt_disable(); let r = self.inner_try_read(); if r.is_none() { ProcessManager::preempt_enable(); } return r; } fn inner_try_read(&self) -> Option> { let reader_value = self.current_reader(); //得到自增后的reader_value, 包括了尝试获得READER守卫的进程 let value; if reader_value.is_err() { return None; //获取失败 } else { value = reader_value.unwrap(); } //判断有没有writer和upgrader //注意, 若upgrader存在,已经存在的读者继续占有锁,但新读者不允许获得锁 if value & (WRITER | UPGRADED) != 0 { self.lock.fetch_sub(READER, Ordering::Release); return None; } else { return Some(RwLockReadGuard { data: unsafe { &*self.data.get() }, lock: &self.lock, irq_guard: None, }); } } #[allow(dead_code)] #[inline] /// @brief 获得READER的守卫 pub fn read(&self) -> RwLockReadGuard { loop { match self.try_read() { Some(guard) => return guard, None => spin_loop(), } } //忙等待 } pub fn read_irqsave(&self) -> RwLockReadGuard { loop { let irq_guard = unsafe { CurrentIrqArch::save_and_disable_irq() }; match self.try_read() { Some(mut guard) => { guard.irq_guard = Some(irq_guard); return guard; } None => spin_loop(), } } } #[allow(dead_code)] #[inline] /// @brief 获取读者+UPGRADER的数量, 不能保证能否获得同步值 pub fn reader_count(&self) -> u32 { let state = self.lock.load(Ordering::Relaxed); return state / READER + (state & UPGRADED) / UPGRADED; } #[allow(dead_code)] #[inline] /// @brief 获取写者数量,不能保证能否获得同步值 pub fn writer_count(&self) -> u32 { return (self.lock.load(Ordering::Relaxed) & WRITER) / WRITER; } #[cfg(target_arch = "x86_64")] #[allow(dead_code)] #[inline] /// @brief 尝试获得WRITER守卫 pub fn try_write(&self) -> Option> { ProcessManager::preempt_disable(); let r = self.inner_try_write(); if r.is_none() { ProcessManager::preempt_enable(); } return r; } //当架构为arm时,有些代码需要作出调整compare_exchange=>compare_exchange_weak #[cfg(target_arch = "x86_64")] #[allow(dead_code)] fn inner_try_write(&self) -> Option> { let res: bool = self .lock .compare_exchange(0, WRITER, Ordering::Acquire, Ordering::Relaxed) .is_ok(); //只有lock大小为0的时候能获得写者守卫 if res { return Some(RwLockWriteGuard { data: unsafe { &mut *self.data.get() }, inner: self, irq_guard: None, }); } else { return None; } } #[allow(dead_code)] #[inline] /// @brief 获得WRITER守卫 pub fn write(&self) -> RwLockWriteGuard { loop { match self.try_write() { Some(guard) => return guard, None => spin_loop(), } } } #[allow(dead_code)] #[inline] /// @brief 获取WRITER守卫并关中断 pub fn write_irqsave(&self) -> RwLockWriteGuard { loop { let irq_guard = unsafe { CurrentIrqArch::save_and_disable_irq() }; match self.try_write() { Some(mut guard) => { guard.irq_guard = Some(irq_guard); return guard; } None => spin_loop(), } } } #[allow(dead_code)] #[inline] /// @brief 尝试获得UPGRADER守卫 pub fn try_upgradeable_read(&self) -> Option> { ProcessManager::preempt_disable(); let r = self.inner_try_upgradeable_read(); if r.is_none() { ProcessManager::preempt_enable(); } return r; } #[allow(dead_code)] pub fn try_upgradeable_read_irqsave(&self) -> Option> { let irq_guard = unsafe { CurrentIrqArch::save_and_disable_irq() }; ProcessManager::preempt_disable(); let mut r = self.inner_try_upgradeable_read(); if r.is_none() { ProcessManager::preempt_enable(); } else { r.as_mut().unwrap().irq_guard = Some(irq_guard); } return r; } fn inner_try_upgradeable_read(&self) -> Option> { // 获得UPGRADER守卫不需要查看读者位 // 如果获得读者锁失败,不需要撤回fetch_or的原子操作 if self.lock.fetch_or(UPGRADED, Ordering::Acquire) & (WRITER | UPGRADED) == 0 { return Some(RwLockUpgradableGuard { inner: self, data: unsafe { &mut *self.data.get() }, irq_guard: None, }); } else { return None; } } #[allow(dead_code)] #[inline] /// @brief 获得UPGRADER守卫 pub fn upgradeable_read(&self) -> RwLockUpgradableGuard { loop { match self.try_upgradeable_read() { Some(guard) => return guard, None => spin_loop(), } } } #[inline] /// @brief 获得UPGRADER守卫 pub fn upgradeable_read_irqsave(&self) -> RwLockUpgradableGuard { loop { let irq_guard = unsafe { CurrentIrqArch::save_and_disable_irq() }; match self.try_upgradeable_read() { Some(mut guard) => { guard.irq_guard = Some(irq_guard); return guard; } None => spin_loop(), } } } #[allow(dead_code)] #[inline] //extremely unsafe behavior /// @brief 强制减少READER数 pub unsafe fn force_read_decrement(&self) { debug_assert!(self.lock.load(Ordering::Relaxed) & !WRITER > 0); self.lock.fetch_sub(READER, Ordering::Release); } #[allow(dead_code)] #[inline] //extremely unsafe behavior /// @brief 强制给WRITER解锁 pub unsafe fn force_write_unlock(&self) { debug_assert_eq!(self.lock.load(Ordering::Relaxed) & !(WRITER | UPGRADED), 0); self.lock.fetch_and(!(WRITER | UPGRADED), Ordering::Release); } #[allow(dead_code)] pub unsafe fn get_mut(&mut self) -> &mut T { unsafe { &mut *self.data.get() } } } impl Default for RwLock { fn default() -> Self { Self::new(Default::default()) } } /// @brief 由原有的值创建新的锁 impl From for RwLock { fn from(data: T) -> Self { return Self::new(data); } } impl<'rwlock, T> RwLockReadGuard<'rwlock, T> { /// @brief 释放守卫,获得保护的值的不可变引用 /// /// ## Safety /// /// 由于这样做可能导致守卫在另一个线程中被释放，从而导致pcb的preempt count不正确， /// 因此必须小心的手动维护好preempt count。 /// /// 并且，leak还可能导致锁的状态不正确。因此请仔细考虑是否真的需要使用这个函数。 #[allow(dead_code)] #[inline] pub unsafe fn leak(this: Self) -> &'rwlock T { let this = ManuallyDrop::new(this); return unsafe { &*this.data }; } } impl<'rwlock, T> RwLockUpgradableGuard<'rwlock, T> { #[allow(dead_code)] #[inline] /// @brief 尝试将UPGRADER守卫升级为WRITER守卫 pub fn try_upgrade(mut self) -> Result, Self> { let res = self.inner.lock.compare_exchange( UPGRADED, WRITER, Ordering::Acquire, Ordering::Relaxed, ); //当且仅当只有UPGRADED守卫时可以升级 if res.is_ok() { let inner = self.inner; let irq_guard = self.irq_guard.take(); mem::forget(self); Ok(RwLockWriteGuard { data: unsafe { &mut *inner.data.get() }, inner, irq_guard, }) } else { Err(self) } } #[allow(dead_code)] #[inline] /// @brief 将upgrader升级成writer pub fn upgrade(mut self) -> RwLockWriteGuard<'rwlock, T> { loop { self = match self.try_upgrade() { Ok(writeguard) => return writeguard, Err(former) => former, }; spin_loop(); } } #[allow(dead_code)] #[inline] /// @brief UPGRADER降级为READER pub fn downgrade(mut self) -> RwLockReadGuard<'rwlock, T> { while self.inner.current_reader().is_err() { spin_loop(); } let inner: &RwLock = self.inner; let irq_guard = self.irq_guard.take(); // 自动移去UPGRADED比特位 mem::drop(self); RwLockReadGuard { data: unsafe { &*inner.data.get() }, lock: &inner.lock, irq_guard, } } #[allow(dead_code)] #[inline] /// @brief 返回内部数据的引用,消除守卫 /// /// ## Safety /// /// 由于这样做可能导致守卫在另一个线程中被释放，从而导致pcb的preempt count不正确， /// 因此必须小心的手动维护好preempt count。 /// /// 并且，leak还可能导致锁的状态不正确。因此请仔细考虑是否真的需要使用这个函数。 pub unsafe fn leak(this: Self) -> &'rwlock T { let this: ManuallyDrop> = ManuallyDrop::new(this); unsafe { &*this.data } } } impl<'rwlock, T> RwLockWriteGuard<'rwlock, T> { #[allow(dead_code)] #[inline] /// @brief 返回内部数据的引用,消除守卫 /// /// ## Safety /// /// 由于这样做可能导致守卫在另一个线程中被释放，从而导致pcb的preempt count不正确， /// 因此必须小心的手动维护好preempt count。 /// /// 并且，leak还可能导致锁的状态不正确。因此请仔细考虑是否真的需要使用这个函数。 pub unsafe fn leak(this: Self) -> &'rwlock T { let this = ManuallyDrop::new(this); return unsafe { &*this.data }; } #[allow(dead_code)] #[inline] /// @brief 将WRITER降级为READER pub fn downgrade(mut self) -> RwLockReadGuard<'rwlock, T> { while self.inner.current_reader().is_err() { spin_loop(); } //本质上来说绝对保证没有任何读者 let inner = self.inner; let irq_guard = self.irq_guard.take(); mem::drop(self); return RwLockReadGuard { data: unsafe { &*inner.data.get() }, lock: &inner.lock, irq_guard, }; } #[allow(dead_code)] #[inline] /// @brief 将WRITER降级为UPGRADER pub fn downgrade_to_upgradeable(mut self) -> RwLockUpgradableGuard<'rwlock, T> { debug_assert_eq!( self.inner.lock.load(Ordering::Acquire) & (WRITER | UPGRADED), WRITER ); self.inner.lock.store(UPGRADED, Ordering::Release); let inner = self.inner; let irq_guard = self.irq_guard.take(); mem::forget(self); return RwLockUpgradableGuard { inner, data: unsafe { &*inner.data.get() }, irq_guard, }; } } impl<'rwlock, T> Deref for RwLockReadGuard<'rwlock, T> { type Target = T; fn deref(&self) -> &Self::Target { return unsafe { &*self.data }; } } impl<'rwlock, T> Deref for RwLockUpgradableGuard<'rwlock, T> { type Target = T; fn deref(&self) -> &Self::Target { return unsafe { &*self.data }; } } impl<'rwlock, T> Deref for RwLockWriteGuard<'rwlock, T> { type Target = T; fn deref(&self) -> &Self::Target { return unsafe { &*self.data }; } } impl<'rwlock, T> DerefMut for RwLockWriteGuard<'rwlock, T> { fn deref_mut(&mut self) -> &mut Self::Target { return unsafe { &mut *self.data }; } } impl<'rwlock, T> Drop for RwLockReadGuard<'rwlock, T> { fn drop(&mut self) { debug_assert!(self.lock.load(Ordering::Relaxed) & !(WRITER | UPGRADED) > 0); self.lock.fetch_sub(READER, Ordering::Release); ProcessManager::preempt_enable(); } } impl<'rwlock, T> Drop for RwLockUpgradableGuard<'rwlock, T> { fn drop(&mut self) { debug_assert_eq!( self.inner.lock.load(Ordering::Relaxed) & (WRITER | UPGRADED), UPGRADED ); self.inner.lock.fetch_sub(UPGRADED, Ordering::AcqRel); ProcessManager::preempt_enable(); //这里为啥要AcqRel? Release应该就行了? } } impl<'rwlock, T> Drop for RwLockWriteGuard<'rwlock, T> { fn drop(&mut self) { debug_assert_eq!(self.inner.lock.load(Ordering::Relaxed) & WRITER, WRITER); self.inner .lock .fetch_and(!(WRITER | UPGRADED), Ordering::Release); self.irq_guard.take(); ProcessManager::preempt_enable(); } }