2008-09-03 04:50:04 +00:00
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<title>L9</title>
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<html>
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<head>
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</head>
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<body>
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<h1>Coordination and more processes</h1>
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<p>Required reading: remainder of proc.c, sys_exec, sys_sbrk,
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sys_wait, sys_exit, and sys_kill.
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<h2>Overview</h2>
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<p>Big picture: more programs than processors. How to share the
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limited number of processors among the programs? Last lecture
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covered basic mechanism: threads and the distinction between process
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and thread. Today expand: how to coordinate the interactions
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between threads explicitly, and some operations on processes.
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<p>Sequence coordination. This is a diferrent type of coordination
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than mutual-exclusion coordination (which has its goal to make
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atomic actions so that threads don't interfere). The goal of
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sequence coordination is for threads to coordinate the sequences in
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which they run.
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<p>For example, a thread may want to wait until another thread
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terminates. One way to do so is to have the thread run periodically,
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let it check if the other thread terminated, and if not give up the
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processor again. This is wasteful, especially if there are many
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threads.
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<p>With primitives for sequence coordination one can do better. The
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thread could tell the thread manager that it is waiting for an event
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(e.g., another thread terminating). When the other thread
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terminates, it explicitly wakes up the waiting thread. This is more
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work for the programmer, but more efficient.
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<p>Sequence coordination often interacts with mutual-exclusion
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coordination, as we will see below.
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<p>The operating system literature has a rich set of primivites for
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sequence coordination. We study a very simple version of condition
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variables in xv6: sleep and wakeup, with a single lock.
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<h2>xv6 code examples</h2>
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<h3>Sleep and wakeup - usage</h3>
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Let's consider implementing a producer/consumer queue
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2009-07-13 01:33:37 +00:00
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(like a pipe) that can be used to hold a single non-null pointer:
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2008-09-03 04:50:04 +00:00
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<pre>
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struct pcq {
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void *ptr;
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};
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void*
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pcqread(struct pcq *q)
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{
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void *p;
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while((p = q->ptr) == 0)
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;
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q->ptr = 0;
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return p;
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}
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void
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pcqwrite(struct pcq *q, void *p)
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{
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while(q->ptr != 0)
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;
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q->ptr = p;
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}
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</pre>
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<p>Easy and correct, at least assuming there is at most one
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reader and at most one writer at a time.
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<p>Unfortunately, the while loops are inefficient.
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Instead of polling, it would be great if there were
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primitives saying ``wait for some event to happen''
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and ``this event happened''.
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That's what sleep and wakeup do.
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<p>Second try:
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<pre>
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void*
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pcqread(struct pcq *q)
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{
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void *p;
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if(q->ptr == 0)
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sleep(q);
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p = q->ptr;
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q->ptr = 0;
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wakeup(q); /* wake pcqwrite */
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return p;
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}
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void
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pcqwrite(struct pcq *q, void *p)
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{
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if(q->ptr != 0)
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sleep(q);
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q->ptr = p;
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wakeup(q); /* wake pcqread */
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return p;
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}
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</pre>
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That's better, but there is still a problem.
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What if the wakeup happens between the check in the if
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and the call to sleep?
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<p>Add locks:
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<pre>
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struct pcq {
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void *ptr;
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struct spinlock lock;
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};
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void*
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pcqread(struct pcq *q)
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{
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void *p;
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acquire(&q->lock);
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if(q->ptr == 0)
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sleep(q, &q->lock);
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p = q->ptr;
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q->ptr = 0;
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wakeup(q); /* wake pcqwrite */
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release(&q->lock);
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return p;
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}
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void
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pcqwrite(struct pcq *q, void *p)
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{
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acquire(&q->lock);
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if(q->ptr != 0)
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sleep(q, &q->lock);
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q->ptr = p;
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wakeup(q); /* wake pcqread */
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release(&q->lock);
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return p;
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}
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</pre>
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This is okay, and now safer for multiple readers and writers,
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except that wakeup wakes up everyone who is asleep on chan,
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not just one guy.
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So some of the guys who wake up from sleep might not
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be cleared to read or write from the queue. Have to go back to looping:
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<pre>
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struct pcq {
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void *ptr;
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struct spinlock lock;
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};
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void*
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pcqread(struct pcq *q)
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{
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void *p;
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acquire(&q->lock);
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while(q->ptr == 0)
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sleep(q, &q->lock);
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p = q->ptr;
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q->ptr = 0;
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wakeup(q); /* wake pcqwrite */
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release(&q->lock);
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return p;
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}
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void
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pcqwrite(struct pcq *q, void *p)
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{
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acquire(&q->lock);
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while(q->ptr != 0)
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sleep(q, &q->lock);
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q->ptr = p;
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wakeup(q); /* wake pcqread */
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release(&q->lock);
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return p;
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}
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</pre>
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The difference between this an our original is that
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the body of the while loop is a much more efficient way to pause.
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<p>Now we've figured out how to use it, but we
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still need to figure out how to implement it.
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<h3>Sleep and wakeup - implementation</h3>
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<p>
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Simple implementation:
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<pre>
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void
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sleep(void *chan, struct spinlock *lk)
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{
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struct proc *p = curproc[cpu()];
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release(lk);
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p->chan = chan;
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p->state = SLEEPING;
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sched();
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}
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void
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wakeup(void *chan)
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{
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for(each proc p) {
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if(p->state == SLEEPING && p->chan == chan)
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p->state = RUNNABLE;
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}
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}
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</pre>
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<p>What's wrong? What if the wakeup runs right after
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the release(lk) in sleep?
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It still misses the sleep.
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<p>Move the lock down:
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<pre>
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void
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sleep(void *chan, struct spinlock *lk)
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{
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struct proc *p = curproc[cpu()];
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p->chan = chan;
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p->state = SLEEPING;
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release(lk);
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sched();
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}
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void
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wakeup(void *chan)
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{
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for(each proc p) {
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if(p->state == SLEEPING && p->chan == chan)
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p->state = RUNNABLE;
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}
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}
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</pre>
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<p>This almost works. Recall from last lecture that we also need
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to acquire the proc_table_lock before calling sched, to
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protect p->jmpbuf.
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<pre>
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void
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sleep(void *chan, struct spinlock *lk)
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{
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struct proc *p = curproc[cpu()];
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p->chan = chan;
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p->state = SLEEPING;
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acquire(&proc_table_lock);
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release(lk);
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sched();
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}
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</pre>
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<p>The problem is that now we're using lk to protect
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access to the p->chan and p->state variables
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but other routines besides sleep and wakeup
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(in particular, proc_kill) will need to use them and won't
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know which lock protects them.
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So instead of protecting them with lk, let's use proc_table_lock:
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<pre>
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void
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sleep(void *chan, struct spinlock *lk)
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{
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struct proc *p = curproc[cpu()];
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acquire(&proc_table_lock);
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release(lk);
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p->chan = chan;
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p->state = SLEEPING;
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sched();
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}
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void
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wakeup(void *chan)
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{
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acquire(&proc_table_lock);
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for(each proc p) {
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if(p->state == SLEEPING && p->chan == chan)
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p->state = RUNNABLE;
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}
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release(&proc_table_lock);
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}
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</pre>
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<p>One could probably make things work with lk as above,
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but the relationship between data and locks would be
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more complicated with no real benefit. Xv6 takes the easy way out
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and says that elements in the proc structure are always protected
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by proc_table_lock.
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<h3>Use example: exit and wait</h3>
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<p>If proc_wait decides there are children to be waited for,
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it calls sleep at line 2462.
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When a process exits, we proc_exit scans the process table
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to find the parent and wakes it at 2408.
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<p>Which lock protects sleep and wakeup from missing each other?
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Proc_table_lock. Have to tweak sleep again to avoid double-acquire:
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<pre>
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if(lk != &proc_table_lock) {
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acquire(&proc_table_lock);
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release(lk);
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}
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</pre>
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<h3>New feature: kill</h3>
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<p>Proc_kill marks a process as killed (line 2371).
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When the process finally exits the kernel to user space,
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or if a clock interrupt happens while it is in user space,
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it will be destroyed (line 2886, 2890, 2912).
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<p>Why wait until the process ends up in user space?
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<p>What if the process is stuck in sleep? It might take a long
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time to get back to user space.
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Don't want to have to wait for it, so make sleep wake up early
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(line 2373).
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<p>This means all callers of sleep should check
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whether they have been killed, but none do.
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Bug in xv6.
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<h3>System call handlers</h3>
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<p>Sheet 32
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<p>Fork: discussed copyproc in earlier lectures.
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Sys_fork (line 3218) just calls copyproc
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and marks the new proc runnable.
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Does fork create a new process or a new thread?
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Is there any shared context?
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<p>Exec: we'll talk about exec later, when we talk about file systems.
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<p>Sbrk: Saw growproc earlier. Why setupsegs before returning?
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