more doc tweaks
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Russ Cox
parent
2c5f7aba38
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26
TRICKS
26
TRICKS
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@ -4,6 +4,9 @@ might be worth pointing out in a longer explanation or in class.
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---
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[2009/07/12: No longer relevant; forkret1 changed
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and this is now cleaner.]
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forkret1 in trapasm.S is called with a tf argument.
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In order to use it, forkret1 copies the tf pointer into
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%esp and then jumps to trapret, which pops the
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@ -45,21 +48,21 @@ always.
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There is a (harmless) race in pushcli, which does
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eflags = read_eflags();
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eflags = readeflags();
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cli();
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if(cpus[cpu()].ncli++ == 0)
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cpus[cpu()].intena = eflags & FL_IF;
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if(c->ncli++ == 0)
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c->intena = eflags & FL_IF;
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Consider a bottom-level pushcli.
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If interrupts are disabled already, then the right thing
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happens: read_eflags finds that FL_IF is not set,
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and intena = 1. If interrupts are enabled, then
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and intena = 0. If interrupts are enabled, then
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it is less clear that the right thing happens:
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the read_eflags can execute, then the process
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the readeflags can execute, then the process
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can get preempted and rescheduled on another cpu,
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and then once it starts running, perhaps with
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interrupts disabled (can happen since the scheduler
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only disables interrupts once per scheduling loop,
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only enables interrupts once per scheduling loop,
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not every time it schedules a process), it will
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incorrectly record that interrupts *were* enabled.
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This doesn't matter, because if it was safe to be
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@ -112,17 +115,13 @@ processors will need it.
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---
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The code in sys_fork needs to read np->pid before
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The code in fork needs to read np->pid before
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setting np->state to RUNNABLE.
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int
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sys_fork(void)
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fork(void)
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{
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int pid;
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struct proc *np;
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if((np = copyproc(cp)) == 0)
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return -1;
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...
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pid = np->pid;
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np->state = RUNNABLE;
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return pid;
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@ -134,3 +133,4 @@ get reused for a different process (with a new pid), all
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before the return statement. So it's not safe to just do
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"return np->pid;".
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This works because proc.h marks the pid as volatile.
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40
pipe.c
40
pipe.c
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@ -9,12 +9,12 @@
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#define PIPESIZE 512
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struct pipe {
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int readopen; // read fd is still open
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int writeopen; // write fd is still open
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uint writep; // next index to write
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uint readp; // next index to read
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struct spinlock lock;
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char data[PIPESIZE];
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uint nread; // number of bytes read
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uint nwrite; // number of bytes written
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int readopen; // read fd is still open
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int writeopen; // write fd is still open
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};
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int
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@ -30,8 +30,8 @@ pipealloc(struct file **f0, struct file **f1)
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goto bad;
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p->readopen = 1;
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p->writeopen = 1;
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p->writep = 0;
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p->readp = 0;
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p->nwrite = 0;
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p->nread = 0;
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initlock(&p->lock, "pipe");
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(*f0)->type = FD_PIPE;
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(*f0)->readable = 1;
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@ -60,10 +60,10 @@ pipeclose(struct pipe *p, int writable)
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acquire(&p->lock);
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if(writable){
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p->writeopen = 0;
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wakeup(&p->readp);
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wakeup(&p->nread);
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} else {
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p->readopen = 0;
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wakeup(&p->writep);
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wakeup(&p->nwrite);
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}
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if(p->readopen == 0 && p->writeopen == 0) {
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release(&p->lock);
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@ -80,19 +80,19 @@ pipewrite(struct pipe *p, char *addr, int n)
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acquire(&p->lock);
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for(i = 0; i < n; i++){
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while(p->writep == p->readp + PIPESIZE) {
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while(p->nwrite == p->nread + PIPESIZE) { //DOC: pipewrite-full
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if(p->readopen == 0 || cp->killed){
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release(&p->lock);
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return -1;
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}
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wakeup(&p->readp);
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sleep(&p->writep, &p->lock);
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wakeup(&p->nread);
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sleep(&p->nwrite, &p->lock); //DOC: pipewrite-sleep
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}
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p->data[p->writep++ % PIPESIZE] = addr[i];
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p->data[p->nwrite++ % PIPESIZE] = addr[i];
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}
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wakeup(&p->readp);
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wakeup(&p->nread); //DOC: pipewrite-wakeup1
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release(&p->lock);
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return i;
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return n;
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}
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int
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@ -101,19 +101,19 @@ piperead(struct pipe *p, char *addr, int n)
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int i;
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acquire(&p->lock);
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while(p->readp == p->writep && p->writeopen){
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while(p->nread == p->nwrite && p->writeopen){ //DOC: pipe-empty
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if(cp->killed){
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release(&p->lock);
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return -1;
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}
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sleep(&p->readp, &p->lock);
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sleep(&p->nread, &p->lock); //DOC: piperead-sleep
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}
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for(i = 0; i < n; i++){
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if(p->readp == p->writep)
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for(i = 0; i < n; i++){ //DOC: piperead-copy
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if(p->nread == p->nwrite)
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break;
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addr[i] = p->data[p->readp++ % PIPESIZE];
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addr[i] = p->data[p->nread++ % PIPESIZE];
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}
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wakeup(&p->writep);
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wakeup(&p->nwrite); //DOC: piperead-wakeup
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release(&p->lock);
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return i;
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}
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38
proc.c
38
proc.c
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@ -290,8 +290,8 @@ sleep(void *chan, struct spinlock *lk)
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// guaranteed that we won't miss any wakeup
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// (wakeup runs with ptable.lock locked),
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// so it's okay to release lk.
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if(lk != &ptable.lock){
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acquire(&ptable.lock);
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if(lk != &ptable.lock){ //DOC: sleeplock0
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acquire(&ptable.lock); //DOC: sleeplock1
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release(lk);
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}
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@ -304,7 +304,7 @@ sleep(void *chan, struct spinlock *lk)
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cp->chan = 0;
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// Reacquire original lock.
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if(lk != &ptable.lock){
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if(lk != &ptable.lock){ //DOC: sleeplock2
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release(&ptable.lock);
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acquire(lk);
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}
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@ -393,7 +393,6 @@ exit(void)
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}
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// Jump into the scheduler, never to return.
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cp->killed = 0;
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cp->state = ZOMBIE;
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sched();
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panic("zombie exit");
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@ -412,22 +411,21 @@ wait(void)
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// Scan through table looking for zombie children.
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havekids = 0;
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for(p = ptable.proc; p < &ptable.proc[NPROC]; p++){
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if(p->state == UNUSED)
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if(p->parent != cp)
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continue;
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if(p->parent == cp){
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havekids = 1;
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if(p->state == ZOMBIE){
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// Found one.
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kfree(p->mem, p->sz);
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kfree(p->kstack, KSTACKSIZE);
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pid = p->pid;
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p->state = UNUSED;
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p->pid = 0;
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p->parent = 0;
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p->name[0] = 0;
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release(&ptable.lock);
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return pid;
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}
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havekids = 1;
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if(p->state == ZOMBIE){
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// Found one.
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pid = p->pid;
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kfree(p->mem, p->sz);
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kfree(p->kstack, KSTACKSIZE);
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p->state = UNUSED;
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p->pid = 0;
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p->parent = 0;
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p->name[0] = 0;
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p->killed = 0;
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release(&ptable.lock);
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return pid;
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}
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}
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@ -438,7 +436,7 @@ wait(void)
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}
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// Wait for children to exit. (See wakeup1 call in proc_exit.)
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sleep(cp, &ptable.lock);
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sleep(cp, &ptable.lock); //DOC: wait-sleep
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}
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}
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@ -47,7 +47,7 @@
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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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(like a pipe) that can be used to hold a single non-null char pointer:
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(like a pipe) that can be used to hold a single non-null pointer:
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<pre>
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struct pcq {
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