base/process/kill_mac.cc

   1 // Copyright (c) 2013 The Chromium Authors. All rights reserved.
   2 // Use of this source code is governed by a BSD-style license that can be
   3 // found in the LICENSE file.
   4
   5 #include "base/process/kill.h"
   6
   7 #include <signal.h>
   8 #include <sys/event.h>
   9 #include <sys/types.h>
  10 #include <sys/wait.h>
  11
  12 #include "base/files/file_util.h"
  13 #include "base/files/scoped_file.h"
  14 #include "base/logging.h"
  15 #include "base/posix/eintr_wrapper.h"
  16
  17 namespace base {
  18
  19 namespace {
  20
  21 const int kWaitBeforeKillSeconds = 2;
  22
  23 // Reap |child| process. This call blocks until completion.
  24 void BlockingReap(pid_t child) {
  25   const pid_t result = HANDLE_EINTR(waitpid(child, NULL, 0));
  26   if (result == -1) {
  27     DPLOG(ERROR) << "waitpid(" << child << ", NULL, 0)";
  28   }
  29 }
  30
  31 // Waits for |timeout| seconds for the given |child| to exit and reap it. If
  32 // the child doesn't exit within the time specified, kills it.
  33 //
  34 // This function takes two approaches: first, it tries to use kqueue to
  35 // observe when the process exits. kevent can monitor a kqueue with a
  36 // timeout, so this method is preferred to wait for a specified period of
  37 // time. Once the kqueue indicates the process has exited, waitpid will reap
  38 // the exited child. If the kqueue doesn't provide an exit event notification,
  39 // before the timeout expires, or if the kqueue fails or misbehaves, the
  40 // process will be mercilessly killed and reaped.
  41 //
  42 // A child process passed to this function may be in one of several states:
  43 // running, terminated and not yet reaped, and (apparently, and unfortunately)
  44 // terminated and already reaped. Normally, a process will at least have been
  45 // asked to exit before this function is called, but this is not required.
  46 // If a process is terminating and unreaped, there may be a window between the
  47 // time that kqueue will no longer recognize it and when it becomes an actual
  48 // zombie that a non-blocking (WNOHANG) waitpid can reap. This condition is
  49 // detected when kqueue indicates that the process is not running and a
  50 // non-blocking waitpid fails to reap the process but indicates that it is
  51 // still running. In this event, a blocking attempt to reap the process
  52 // collects the known-dying child, preventing zombies from congregating.
  53 //
  54 // In the event that the kqueue misbehaves entirely, as it might under a
  55 // EMFILE condition ("too many open files", or out of file descriptors), this
  56 // function will forcibly kill and reap the child without delay. This
  57 // eliminates another potential zombie vector. (If you're out of file
  58 // descriptors, you're probably deep into something else, but that doesn't
  59 // mean that zombies be allowed to kick you while you're down.)
  60 //
  61 // The fact that this function seemingly can be called to wait on a child
  62 // that's not only already terminated but already reaped is a bit of a
  63 // problem: a reaped child's pid can be reclaimed and may refer to a distinct
  64 // process in that case. The fact that this function can seemingly be called
  65 // to wait on a process that's not even a child is also a problem: kqueue will
  66 // work in that case, but waitpid won't, and killing a non-child might not be
  67 // the best approach.
  68 void WaitForChildToDie(pid_t child, int timeout) {
  69   DCHECK(child > 0);
  70   DCHECK(timeout > 0);
  71
  72   // DON'T ADD ANY EARLY RETURNS TO THIS FUNCTION without ensuring that
  73   // |child| has been reaped. Specifically, even if a kqueue, kevent, or other
  74   // call fails, this function should fall back to the last resort of trying
  75   // to kill and reap the process. Not observing this rule will resurrect
  76   // zombies.
  77
  78   int result;
  79
  80   ScopedFD kq(HANDLE_EINTR(kqueue()));
  81   if (!kq.is_valid()) {
  82     DPLOG(ERROR) << "kqueue()";
  83   } else {
  84     struct kevent change = {0};
  85     EV_SET(&change, child, EVFILT_PROC, EV_ADD, NOTE_EXIT, 0, NULL);
  86     result = HANDLE_EINTR(kevent(kq.get(), &change, 1, NULL, 0, NULL));
  87
  88     if (result == -1) {
  89       if (errno != ESRCH) {
  90         DPLOG(ERROR) << "kevent (setup " << child << ")";
  91       } else {
  92         // At this point, one of the following has occurred:
  93         // 1. The process has died but has not yet been reaped.
  94         // 2. The process has died and has already been reaped.
  95         // 3. The process is in the process of dying. It's no longer
  96         //    kqueueable, but it may not be waitable yet either. Mark calls
  97         //    this case the "zombie death race".
  98
  99         result = HANDLE_EINTR(waitpid(child, NULL, WNOHANG));
 100
 101         if (result != 0) {
 102           // A positive result indicates case 1. waitpid succeeded and reaped
 103           // the child. A result of -1 indicates case 2. The child has already
 104           // been reaped. In both of these cases, no further action is
 105           // necessary.
 106           return;
 107         }
 108
 109         // |result| is 0, indicating case 3. The process will be waitable in
 110         // short order. Fall back out of the kqueue code to kill it (for good
 111         // measure) and reap it.
 112       }
 113     } else {
 114       // Keep track of the elapsed time to be able to restart kevent if it's
 115       // interrupted.
 116       TimeDelta remaining_delta = TimeDelta::FromSeconds(timeout);
 117       TimeTicks deadline = TimeTicks::Now() + remaining_delta;
 118       result = -1;
 119       struct kevent event = {0};
 120       while (remaining_delta.InMilliseconds() > 0) {
 121         const struct timespec remaining_timespec = remaining_delta.ToTimeSpec();
 122         result = kevent(kq.get(), NULL, 0, &event, 1, &remaining_timespec);
 123         if (result == -1 && errno == EINTR) {
 124           remaining_delta = deadline - TimeTicks::Now();
 125           result = 0;
 126         } else {
 127           break;
 128         }
 129       }
 130
 131       if (result == -1) {
 132         DPLOG(ERROR) << "kevent (wait " << child << ")";
 133       } else if (result > 1) {
 134         DLOG(ERROR) << "kevent (wait " << child << "): unexpected result "
 135                     << result;
 136       } else if (result == 1) {
 137         if ((event.fflags & NOTE_EXIT) &&
 138             (event.ident == static_cast<uintptr_t>(child))) {
 139           // The process is dead or dying. This won't block for long, if at
 140           // all.
 141           BlockingReap(child);
 142           return;
 143         } else {
 144           DLOG(ERROR) << "kevent (wait " << child
 145                       << "): unexpected event: fflags=" << event.fflags
 146                       << ", ident=" << event.ident;
 147         }
 148       }
 149     }
 150   }
 151
 152   // The child is still alive, or is very freshly dead. Be sure by sending it
 153   // a signal. This is safe even if it's freshly dead, because it will be a
 154   // zombie (or on the way to zombiedom) and kill will return 0 even if the
 155   // signal is not delivered to a live process.
 156   result = kill(child, SIGKILL);
 157   if (result == -1) {
 158     DPLOG(ERROR) << "kill(" << child << ", SIGKILL)";
 159   } else {
 160     // The child is definitely on the way out now. BlockingReap won't need to
 161     // wait for long, if at all.
 162     BlockingReap(child);
 163   }
 164 }
 165
 166 }  // namespace
 167
 168 void EnsureProcessTerminated(Process process) {
 169   WaitForChildToDie(process.Pid(), kWaitBeforeKillSeconds);
 170 }
 171
 172 }  // namespace base