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use super::UPIntrFreeCell;
use crate::task::TaskControlBlock;
use crate::task::{block_current_and_run_next, suspend_current_and_run_next};
use crate::task::{current_task, wakeup_task};
use alloc::{collections::VecDeque, sync::Arc};
pub trait Mutex: Sync + Send {
fn lock(&self);
fn unlock(&self);
}
pub struct MutexSpin {
locked: UPIntrFreeCell<bool>,
}
impl MutexSpin {
pub fn new() -> Self {
Self {
locked: unsafe { UPIntrFreeCell::new(false) },
}
}
}
impl Mutex for MutexSpin {
fn lock(&self) {
loop {
let mut locked = self.locked.exclusive_access();
if *locked {
drop(locked);
suspend_current_and_run_next();
continue;
} else {
*locked = true;
return;
}
}
}
fn unlock(&self) {
let mut locked = self.locked.exclusive_access();
*locked = false;
}
}
pub struct MutexBlocking {
inner: UPIntrFreeCell<MutexBlockingInner>,
}
pub struct MutexBlockingInner {
locked: bool,
wait_queue: VecDeque<Arc<TaskControlBlock>>,
}
impl MutexBlocking {
pub fn new() -> Self {
Self {
inner: unsafe {
UPIntrFreeCell::new(MutexBlockingInner {
locked: false,
wait_queue: VecDeque::new(),
})
},
}
}
}
impl Mutex for MutexBlocking {
fn lock(&self) {
let mut mutex_inner = self.inner.exclusive_access();
if mutex_inner.locked {
mutex_inner.wait_queue.push_back(current_task().unwrap());
drop(mutex_inner);
block_current_and_run_next();
} else {
mutex_inner.locked = true;
}
}
fn unlock(&self) {
let mut mutex_inner = self.inner.exclusive_access();
assert!(mutex_inner.locked);
if let Some(waking_task) = mutex_inner.wait_queue.pop_front() {
wakeup_task(waking_task);
} else {
mutex_inner.locked = false;
}
}
}