minix/servers/pm/forkexit.c
Lionel Sambuc 4a0199d66d PM_TIME_SEC into 64bit
Change-Id: I609ee8cac7aae8af2c0c0381710433a5df0caebd
2014-03-03 20:45:28 +01:00

729 lines
25 KiB
C

/* This file deals with creating processes (via FORK) and deleting them (via
* EXIT/WAITPID). When a process forks, a new slot in the 'mproc' table is
* allocated for it, and a copy of the parent's core image is made for the
* child. Then the kernel and file system are informed. A process is removed
* from the 'mproc' table when two events have occurred: (1) it has exited or
* been killed by a signal, and (2) the parent has done a WAITPID. If the
* process exits first, it continues to occupy a slot until the parent does a
* WAITPID.
*
* The entry points into this file are:
* do_fork: perform the FORK system call
* do_srv_fork: special FORK, used by RS to create sys services
* do_exit: perform the EXIT system call (by calling exit_proc())
* exit_proc: actually do the exiting, and tell VFS about it
* exit_restart: continue exiting a process after VFS has replied
* do_waitpid: perform the WAITPID system call
* wait_test: check whether a parent is waiting for a child
*/
#include "pm.h"
#include <sys/wait.h>
#include <assert.h>
#include <minix/callnr.h>
#include <minix/com.h>
#include <minix/sched.h>
#include <minix/vm.h>
#include <sys/ptrace.h>
#include <sys/resource.h>
#include <signal.h>
#include "mproc.h"
#define LAST_FEW 2 /* last few slots reserved for superuser */
static void zombify(struct mproc *rmp);
static void check_parent(struct mproc *child, int try_cleanup);
static void tell_parent(struct mproc *child);
static void tell_tracer(struct mproc *child);
static void tracer_died(struct mproc *child);
static void cleanup(register struct mproc *rmp);
/*===========================================================================*
* do_fork *
*===========================================================================*/
int do_fork()
{
/* The process pointed to by 'mp' has forked. Create a child process. */
register struct mproc *rmp; /* pointer to parent */
register struct mproc *rmc; /* pointer to child */
pid_t new_pid;
static unsigned int next_child = 0;
int i, n = 0, s;
endpoint_t child_ep;
message m;
/* If tables might fill up during FORK, don't even start since recovery half
* way through is such a nuisance.
*/
rmp = mp;
if ((procs_in_use == NR_PROCS) ||
(procs_in_use >= NR_PROCS-LAST_FEW && rmp->mp_effuid != 0))
{
printf("PM: warning, process table is full!\n");
return(EAGAIN);
}
/* Find a slot in 'mproc' for the child process. A slot must exist. */
do {
next_child = (next_child+1) % NR_PROCS;
n++;
} while((mproc[next_child].mp_flags & IN_USE) && n <= NR_PROCS);
if(n > NR_PROCS)
panic("do_fork can't find child slot");
if(next_child >= NR_PROCS || (mproc[next_child].mp_flags & IN_USE))
panic("do_fork finds wrong child slot: %d", next_child);
/* Memory part of the forking. */
if((s=vm_fork(rmp->mp_endpoint, next_child, &child_ep)) != OK) {
return s;
}
/* PM may not fail fork after call to vm_fork(), as VM calls sys_fork(). */
rmc = &mproc[next_child];
/* Set up the child and its memory map; copy its 'mproc' slot from parent. */
procs_in_use++;
*rmc = *rmp; /* copy parent's process slot to child's */
rmc->mp_parent = who_p; /* record child's parent */
if (!(rmc->mp_trace_flags & TO_TRACEFORK)) {
rmc->mp_tracer = NO_TRACER; /* no tracer attached */
rmc->mp_trace_flags = 0;
(void) sigemptyset(&rmc->mp_sigtrace);
}
/* Some system servers like to call regular fork, such as RS spawning
* recovery scripts; in this case PM will take care of their scheduling
* because RS cannot do so for non-system processes */
if (rmc->mp_flags & PRIV_PROC) {
assert(rmc->mp_scheduler == NONE);
rmc->mp_scheduler = SCHED_PROC_NR;
}
/* Inherit only these flags. In normal fork(), PRIV_PROC is not inherited. */
rmc->mp_flags &= (IN_USE|DELAY_CALL|TAINTED);
rmc->mp_child_utime = 0; /* reset administration */
rmc->mp_child_stime = 0; /* reset administration */
rmc->mp_exitstatus = 0;
rmc->mp_sigstatus = 0;
rmc->mp_endpoint = child_ep; /* passed back by VM */
for (i = 0; i < NR_ITIMERS; i++)
rmc->mp_interval[i] = 0; /* reset timer intervals */
/* Find a free pid for the child and put it in the table. */
new_pid = get_free_pid();
rmc->mp_pid = new_pid; /* assign pid to child */
memset(&m, 0, sizeof(m));
m.m_type = VFS_PM_FORK;
m.VFS_PM_ENDPT = rmc->mp_endpoint;
m.VFS_PM_PENDPT = rmp->mp_endpoint;
m.VFS_PM_CPID = rmc->mp_pid;
m.VFS_PM_REUID = -1; /* Not used by VFS_PM_FORK */
m.VFS_PM_REGID = -1; /* Not used by VFS_PM_FORK */
tell_vfs(rmc, &m);
/* Tell the tracer, if any, about the new child */
if (rmc->mp_tracer != NO_TRACER)
sig_proc(rmc, SIGSTOP, TRUE /*trace*/, FALSE /* ksig */);
/* Do not reply until VFS is ready to process the fork
* request
*/
return SUSPEND;
}
/*===========================================================================*
* do_srv_fork *
*===========================================================================*/
int do_srv_fork()
{
/* The process pointed to by 'mp' has forked. Create a child process. */
register struct mproc *rmp; /* pointer to parent */
register struct mproc *rmc; /* pointer to child */
int s;
pid_t new_pid;
static unsigned int next_child = 0;
int i, n = 0;
endpoint_t child_ep;
message m;
/* Only RS is allowed to use srv_fork. */
if (mp->mp_endpoint != RS_PROC_NR)
return EPERM;
/* If tables might fill up during FORK, don't even start since recovery half
* way through is such a nuisance.
*/
rmp = mp;
if ((procs_in_use == NR_PROCS) ||
(procs_in_use >= NR_PROCS-LAST_FEW && rmp->mp_effuid != 0))
{
printf("PM: warning, process table is full!\n");
return(EAGAIN);
}
/* Find a slot in 'mproc' for the child process. A slot must exist. */
do {
next_child = (next_child+1) % NR_PROCS;
n++;
} while((mproc[next_child].mp_flags & IN_USE) && n <= NR_PROCS);
if(n > NR_PROCS)
panic("do_fork can't find child slot");
if(next_child >= NR_PROCS || (mproc[next_child].mp_flags & IN_USE))
panic("do_fork finds wrong child slot: %d", next_child);
if((s=vm_fork(rmp->mp_endpoint, next_child, &child_ep)) != OK) {
return s;
}
rmc = &mproc[next_child];
/* Set up the child and its memory map; copy its 'mproc' slot from parent. */
procs_in_use++;
*rmc = *rmp; /* copy parent's process slot to child's */
rmc->mp_parent = who_p; /* record child's parent */
if (!(rmc->mp_trace_flags & TO_TRACEFORK)) {
rmc->mp_tracer = NO_TRACER; /* no tracer attached */
rmc->mp_trace_flags = 0;
(void) sigemptyset(&rmc->mp_sigtrace);
}
/* inherit only these flags */
rmc->mp_flags &= (IN_USE|PRIV_PROC|DELAY_CALL);
rmc->mp_child_utime = 0; /* reset administration */
rmc->mp_child_stime = 0; /* reset administration */
rmc->mp_exitstatus = 0;
rmc->mp_sigstatus = 0;
rmc->mp_endpoint = child_ep; /* passed back by VM */
rmc->mp_realuid = (uid_t) m_in.PM_SRV_FORK_UID;
rmc->mp_effuid = (uid_t) m_in.PM_SRV_FORK_UID;
rmc->mp_realgid = (uid_t) m_in.PM_SRV_FORK_GID;
rmc->mp_effgid = (uid_t) m_in.PM_SRV_FORK_GID;
for (i = 0; i < NR_ITIMERS; i++)
rmc->mp_interval[i] = 0; /* reset timer intervals */
/* Find a free pid for the child and put it in the table. */
new_pid = get_free_pid();
rmc->mp_pid = new_pid; /* assign pid to child */
memset(&m, 0, sizeof(m));
m.m_type = VFS_PM_SRV_FORK;
m.VFS_PM_ENDPT = rmc->mp_endpoint;
m.VFS_PM_PENDPT = rmp->mp_endpoint;
m.VFS_PM_CPID = rmc->mp_pid;
m.VFS_PM_REUID = m_in.PM_SRV_FORK_UID;
m.VFS_PM_REGID = m_in.PM_SRV_FORK_GID;
tell_vfs(rmc, &m);
/* Tell the tracer, if any, about the new child */
if (rmc->mp_tracer != NO_TRACER)
sig_proc(rmc, SIGSTOP, TRUE /*trace*/, FALSE /* ksig */);
/* Wakeup the newly created process */
reply(rmc-mproc, OK);
return rmc->mp_pid;
}
/*===========================================================================*
* do_exit *
*===========================================================================*/
int do_exit()
{
/* Perform the exit(status) system call. The real work is done by exit_proc(),
* which is also called when a process is killed by a signal. System processes
* do not use PM's exit() to terminate. If they try to, we warn the user
* and send a SIGKILL signal to the system process.
*/
if(mp->mp_flags & PRIV_PROC) {
printf("PM: system process %d (%s) tries to exit(), sending SIGKILL\n",
mp->mp_endpoint, mp->mp_name);
sys_kill(mp->mp_endpoint, SIGKILL);
}
else {
exit_proc(mp, m_in.PM_EXIT_STATUS, FALSE /*dump_core*/);
}
return(SUSPEND); /* can't communicate from beyond the grave */
}
/*===========================================================================*
* exit_proc *
*===========================================================================*/
void exit_proc(rmp, exit_status, dump_core)
register struct mproc *rmp; /* pointer to the process to be terminated */
int exit_status; /* the process' exit status (for parent) */
int dump_core; /* flag indicating whether to dump core */
{
/* A process is done. Release most of the process' possessions. If its
* parent is waiting, release the rest, else keep the process slot and
* become a zombie.
*/
register int proc_nr, proc_nr_e;
int r;
pid_t procgrp;
struct mproc *p_mp;
clock_t user_time, sys_time;
message m;
/* Do not create core files for set uid execution */
if (dump_core && rmp->mp_realuid != rmp->mp_effuid)
dump_core = FALSE;
/* System processes are destroyed before informing VFS, meaning that VFS can
* not get their CPU state, so we can't generate a coredump for them either.
*/
if (dump_core && (rmp->mp_flags & PRIV_PROC))
dump_core = FALSE;
proc_nr = (int) (rmp - mproc); /* get process slot number */
proc_nr_e = rmp->mp_endpoint;
/* Remember a session leader's process group. */
procgrp = (rmp->mp_pid == mp->mp_procgrp) ? mp->mp_procgrp : 0;
/* If the exited process has a timer pending, kill it. */
if (rmp->mp_flags & ALARM_ON) set_alarm(rmp, (clock_t) 0);
/* Do accounting: fetch usage times and accumulate at parent. */
if((r=sys_times(proc_nr_e, &user_time, &sys_time, NULL, NULL)) != OK)
panic("exit_proc: sys_times failed: %d", r);
p_mp = &mproc[rmp->mp_parent]; /* process' parent */
p_mp->mp_child_utime += user_time + rmp->mp_child_utime; /* add user time */
p_mp->mp_child_stime += sys_time + rmp->mp_child_stime; /* add system time */
/* Tell the kernel the process is no longer runnable to prevent it from
* being scheduled in between the following steps. Then tell VFS that it
* the process has exited and finally, clean up the process at the kernel.
* This order is important so that VFS can tell drivers to cancel requests
* such as copying to/ from the exiting process, before it is gone.
*/
/* If the process is not yet stopped, we force a stop here. This means that
* the process may still have a delay call pending. For this reason, the main
* message loop discards requests from exiting processes.
*/
if (!(rmp->mp_flags & PROC_STOPPED)) {
if ((r = sys_stop(proc_nr_e)) != OK) /* stop the process */
panic("sys_stop failed: %d", r);
rmp->mp_flags |= PROC_STOPPED;
}
if((r=vm_willexit(proc_nr_e)) != OK) {
panic("exit_proc: vm_willexit failed: %d", r);
}
vm_notify_sig_wrapper(rmp->mp_endpoint);
if (proc_nr_e == INIT_PROC_NR)
{
printf("PM: INIT died\n");
return;
}
if (proc_nr_e == VFS_PROC_NR)
{
panic("exit_proc: VFS died: %d", r);
}
/* Tell VFS about the exiting process. */
memset(&m, 0, sizeof(m));
m.m_type = dump_core ? VFS_PM_DUMPCORE : VFS_PM_EXIT;
m.VFS_PM_ENDPT = rmp->mp_endpoint;
if (dump_core) {
m.VFS_PM_TERM_SIG = rmp->mp_sigstatus;
m.VFS_PM_PATH = rmp->mp_name;
}
tell_vfs(rmp, &m);
if (rmp->mp_flags & PRIV_PROC)
{
/* Destroy system processes without waiting for VFS. This is
* needed because the system process might be a block device
* driver that VFS is blocked waiting on.
*/
if((r= sys_clear(rmp->mp_endpoint)) != OK)
panic("exit_proc: sys_clear failed: %d", r);
}
/* Clean up most of the flags describing the process's state before the exit,
* and mark it as exiting.
*/
rmp->mp_flags &= (IN_USE|VFS_CALL|PRIV_PROC|TRACE_EXIT|PROC_STOPPED);
rmp->mp_flags |= EXITING;
/* Keep the process around until VFS is finished with it. */
rmp->mp_exitstatus = (char) exit_status;
/* For normal exits, try to notify the parent as soon as possible.
* For core dumps, notify the parent only once the core dump has been made.
*/
if (!dump_core)
zombify(rmp);
/* If the process has children, disinherit them. INIT is the new parent. */
for (rmp = &mproc[0]; rmp < &mproc[NR_PROCS]; rmp++) {
if (!(rmp->mp_flags & IN_USE)) continue;
if (rmp->mp_tracer == proc_nr) {
/* This child's tracer died. Do something sensible. */
tracer_died(rmp);
}
if (rmp->mp_parent == proc_nr) {
/* 'rmp' now points to a child to be disinherited. */
rmp->mp_parent = INIT_PROC_NR;
/* If the process is making a VFS call, remember that we set
* a new parent. This prevents FORK from replying to the wrong
* parent upon completion.
*/
if (rmp->mp_flags & VFS_CALL)
rmp->mp_flags |= NEW_PARENT;
/* Notify new parent. */
if (rmp->mp_flags & ZOMBIE)
check_parent(rmp, TRUE /*try_cleanup*/);
}
}
/* Send a hangup to the process' process group if it was a session leader. */
if (procgrp != 0) check_sig(-procgrp, SIGHUP, FALSE /* ksig */);
}
/*===========================================================================*
* exit_restart *
*===========================================================================*/
void exit_restart(rmp, dump_core)
struct mproc *rmp; /* pointer to the process being terminated */
int dump_core; /* flag indicating whether to dump core */
{
/* VFS replied to our exit or coredump request. Perform the second half of the
* exit code.
*/
int r;
if((r = sched_stop(rmp->mp_scheduler, rmp->mp_endpoint)) != OK) {
/* If the scheduler refuses to give up scheduling, there is
* little we can do, except report it. This may cause problems
* later on, if this scheduler is asked to schedule another proc
* that has an endpoint->schedproc mapping identical to the proc
* we just tried to stop scheduling.
*/
printf("PM: The scheduler did not want to give up "
"scheduling %s, ret=%d.\n", rmp->mp_name, r);
}
/* sched_stop is either called when the process is exiting or it is
* being moved between schedulers. If it is being moved between
* schedulers, we need to set the mp_scheduler to NONE so that PM
* doesn't forward messages to the process' scheduler while being moved
* (such as sched_nice). */
rmp->mp_scheduler = NONE;
/* For core dumps, now is the right time to try to contact the parent. */
if (dump_core)
zombify(rmp);
if (!(rmp->mp_flags & PRIV_PROC))
{
/* destroy the (user) process */
if((r=sys_clear(rmp->mp_endpoint)) != OK)
panic("exit_restart: sys_clear failed: %d", r);
}
/* Release the memory occupied by the child. */
if((r=vm_exit(rmp->mp_endpoint)) != OK) {
panic("exit_restart: vm_exit failed: %d", r);
}
if (rmp->mp_flags & TRACE_EXIT)
{
/* Wake up the tracer, completing the ptrace(T_EXIT) call */
mproc[rmp->mp_tracer].mp_reply.PM_PTRACE_DATA = 0;
reply(rmp->mp_tracer, OK);
}
/* Clean up if the parent has collected the exit status */
if (rmp->mp_flags & TOLD_PARENT)
cleanup(rmp);
}
/*===========================================================================*
* do_waitpid *
*===========================================================================*/
int do_waitpid()
{
/* A process wants to wait for a child to terminate. If a child is already
* waiting, go clean it up and let this WAITPID call terminate. Otherwise,
* really wait.
* A process calling WAITPID never gets a reply in the usual way at the end
* of the main loop (unless WNOHANG is set or no qualifying child exists).
* If a child has already exited, the routine tell_parent() sends the reply
* to awaken the caller.
*/
register struct mproc *rp;
int i, pidarg, options, children;
/* Set internal variables. */
pidarg = m_in.PM_WAITPID_PID; /* 1st param */
options = m_in.PM_WAITPID_OPTIONS; /* 3rd param */
if (pidarg == 0) pidarg = -mp->mp_procgrp; /* pidarg < 0 ==> proc grp */
/* Is there a child waiting to be collected? At this point, pidarg != 0:
* pidarg > 0 means pidarg is pid of a specific process to wait for
* pidarg == -1 means wait for any child
* pidarg < -1 means wait for any child whose process group = -pidarg
*/
children = 0;
for (rp = &mproc[0]; rp < &mproc[NR_PROCS]; rp++) {
if ((rp->mp_flags & (IN_USE | TOLD_PARENT)) != IN_USE) continue;
if (rp->mp_parent != who_p && rp->mp_tracer != who_p) continue;
if (rp->mp_parent != who_p && (rp->mp_flags & ZOMBIE)) continue;
/* The value of pidarg determines which children qualify. */
if (pidarg > 0 && pidarg != rp->mp_pid) continue;
if (pidarg < -1 && -pidarg != rp->mp_procgrp) continue;
children++; /* this child is acceptable */
if (rp->mp_tracer == who_p) {
if (rp->mp_flags & TRACE_ZOMBIE) {
/* Traced child meets the pid test and has exited. */
tell_tracer(rp);
check_parent(rp, TRUE /*try_cleanup*/);
return(SUSPEND);
}
if (rp->mp_flags & TRACE_STOPPED) {
/* This child meets the pid test and is being traced.
* Deliver a signal to the tracer, if any.
*/
for (i = 1; i < _NSIG; i++) {
if (sigismember(&rp->mp_sigtrace, i)) {
sigdelset(&rp->mp_sigtrace, i);
mp->mp_reply.PM_WAITPID_STATUS = W_STOPCODE(i);
return(rp->mp_pid);
}
}
}
}
if (rp->mp_parent == who_p) {
if (rp->mp_flags & ZOMBIE) {
/* This child meets the pid test and has exited. */
tell_parent(rp); /* this child has already exited */
if (!(rp->mp_flags & VFS_CALL))
cleanup(rp);
return(SUSPEND);
}
}
}
/* No qualifying child has exited. Wait for one, unless none exists. */
if (children > 0) {
/* At least 1 child meets the pid test exists, but has not exited. */
if (options & WNOHANG) {
return(0); /* parent does not want to wait */
}
mp->mp_flags |= WAITING; /* parent wants to wait */
mp->mp_wpid = (pid_t) pidarg; /* save pid for later */
return(SUSPEND); /* do not reply, let it wait */
} else {
/* No child even meets the pid test. Return error immediately. */
return(ECHILD); /* no - parent has no children */
}
}
/*===========================================================================*
* wait_test *
*===========================================================================*/
int wait_test(rmp, child)
struct mproc *rmp; /* process that may be waiting */
struct mproc *child; /* process that may be waited for */
{
/* See if a parent or tracer process is waiting for a child process.
* A tracer is considered to be a pseudo-parent.
*/
int parent_waiting, right_child;
pid_t pidarg;
pidarg = rmp->mp_wpid; /* who's being waited for? */
parent_waiting = rmp->mp_flags & WAITING;
right_child = /* child meets one of the 3 tests? */
(pidarg == -1 || pidarg == child->mp_pid ||
-pidarg == child->mp_procgrp);
return (parent_waiting && right_child);
}
/*===========================================================================*
* zombify *
*===========================================================================*/
static void zombify(rmp)
struct mproc *rmp;
{
/* Zombify a process. First check if the exiting process is traced by a process
* other than its parent; if so, the tracer must be notified about the exit
* first. Once that is done, the real parent may be notified about the exit of
* its child.
*/
struct mproc *t_mp;
if (rmp->mp_flags & (TRACE_ZOMBIE | ZOMBIE))
panic("zombify: process was already a zombie");
/* See if we have to notify a tracer process first. */
if (rmp->mp_tracer != NO_TRACER && rmp->mp_tracer != rmp->mp_parent) {
rmp->mp_flags |= TRACE_ZOMBIE;
t_mp = &mproc[rmp->mp_tracer];
/* Do not bother sending SIGCHLD signals to tracers. */
if (!wait_test(t_mp, rmp))
return;
tell_tracer(rmp);
}
else {
rmp->mp_flags |= ZOMBIE;
}
/* No tracer, or tracer is parent, or tracer has now been notified. */
check_parent(rmp, FALSE /*try_cleanup*/);
}
/*===========================================================================*
* check_parent *
*===========================================================================*/
static void check_parent(child, try_cleanup)
struct mproc *child; /* tells which process is exiting */
int try_cleanup; /* clean up the child when done? */
{
/* We would like to inform the parent of an exiting child about the child's
* death. If the parent is waiting for the child, tell it immediately;
* otherwise, send it a SIGCHLD signal.
*
* Note that we may call this function twice on a single child; first with
* its original parent, later (if the parent died) with INIT as its parent.
*/
struct mproc *p_mp;
p_mp = &mproc[child->mp_parent];
if (p_mp->mp_flags & EXITING) {
/* This may trigger if the child of a dead parent dies. The child will
* be assigned to INIT and rechecked shortly after. Do nothing.
*/
}
else if (wait_test(p_mp, child)) {
tell_parent(child);
/* The 'try_cleanup' flag merely saves us from having to be really
* careful with statement ordering in exit_proc() and exit_restart().
*/
if (try_cleanup && !(child->mp_flags & VFS_CALL))
cleanup(child);
}
else {
/* Parent is not waiting. */
sig_proc(p_mp, SIGCHLD, TRUE /*trace*/, FALSE /* ksig */);
}
}
/*===========================================================================*
* tell_parent *
*===========================================================================*/
static void tell_parent(child)
register struct mproc *child; /* tells which process is exiting */
{
int mp_parent;
struct mproc *parent;
mp_parent= child->mp_parent;
if (mp_parent <= 0)
panic("tell_parent: bad value in mp_parent: %d", mp_parent);
if(!(child->mp_flags & ZOMBIE))
panic("tell_parent: child not a zombie");
if(child->mp_flags & TOLD_PARENT)
panic("tell_parent: telling parent again");
parent = &mproc[mp_parent];
/* Wake up the parent by sending the reply message. */
parent->mp_reply.PM_WAITPID_STATUS =
W_EXITCODE(child->mp_exitstatus, child->mp_sigstatus);
reply(child->mp_parent, child->mp_pid);
parent->mp_flags &= ~WAITING; /* parent no longer waiting */
child->mp_flags &= ~ZOMBIE; /* child no longer a zombie */
child->mp_flags |= TOLD_PARENT; /* avoid informing parent twice */
}
/*===========================================================================*
* tell_tracer *
*===========================================================================*/
static void tell_tracer(child)
struct mproc *child; /* tells which process is exiting */
{
int mp_tracer;
struct mproc *tracer;
mp_tracer = child->mp_tracer;
if (mp_tracer <= 0)
panic("tell_tracer: bad value in mp_tracer: %d", mp_tracer);
if(!(child->mp_flags & TRACE_ZOMBIE))
panic("tell_tracer: child not a zombie");
tracer = &mproc[mp_tracer];
tracer->mp_reply.PM_WAITPID_STATUS =
W_EXITCODE(child->mp_exitstatus, (child->mp_sigstatus & 0377));
reply(child->mp_tracer, child->mp_pid);
tracer->mp_flags &= ~WAITING; /* tracer no longer waiting */
child->mp_flags &= ~TRACE_ZOMBIE; /* child no longer zombie to tracer */
child->mp_flags |= ZOMBIE; /* child is now zombie to parent */
}
/*===========================================================================*
* tracer_died *
*===========================================================================*/
static void tracer_died(child)
struct mproc *child; /* process being traced */
{
/* The process that was tracing the given child, has died for some reason.
* This is really the tracer's fault, but we can't let INIT deal with this.
*/
child->mp_tracer = NO_TRACER;
child->mp_flags &= ~TRACE_EXIT;
/* If the tracer died while the child was running or stopped, we have no
* idea what state the child is in. Avoid a trainwreck, by killing the child.
* Note that this may cause cascading exits.
*/
if (!(child->mp_flags & EXITING)) {
sig_proc(child, SIGKILL, TRUE /*trace*/, FALSE /* ksig */);
return;
}
/* If the tracer died while the child was telling it about its own death,
* forget about the tracer and notify the real parent instead.
*/
if (child->mp_flags & TRACE_ZOMBIE) {
child->mp_flags &= ~TRACE_ZOMBIE;
child->mp_flags |= ZOMBIE;
check_parent(child, TRUE /*try_cleanup*/);
}
}
/*===========================================================================*
* cleanup *
*===========================================================================*/
static void cleanup(rmp)
register struct mproc *rmp; /* tells which process is exiting */
{
/* Release the process table entry and reinitialize some field. */
rmp->mp_pid = 0;
rmp->mp_flags = 0;
rmp->mp_child_utime = 0;
rmp->mp_child_stime = 0;
procs_in_use--;
}