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So I have a program where i spawn off some children who do some useful tasks. I then spawn off another child who needs to wait for the first children to stop before doing its work. The parent program then continues running and at the end waits for the last forked child to stop.

I'm getting an issue where the child who needs to wait on the others doesn't.

use strict;
use warnings;
use diagnostics;

my $pid1;
my $child1 = fork();
if ($child1) {
    # parent
    #print "pid is $pid, parent $$\n";
    $pid1 = $child1;
} elsif ($child1 == 0) {
        # child1
        # do something
        sleep 20;
        print "Child1\n";

        exit 0;
} else {
        die "couldnt fork: $!\n";
}

my $pid2;
my $child2 = fork();
if ($child2) {
    # parent
    #print "pid is $pid, parent $$\n";
    $pid2 = $child2;
} elsif ($child2 == 0) {
        # child2
        # wait for child1 to finish
        my $tmp = waitpid($pid1, 0);

        # do something else
        print "Child2\n";

        exit 0;
} else {
        die "couldnt fork: $!\n";
}

# do more stuff

# wait for child2 to finish
my $tmp = waitpid($pid2, 0);

Is there an easy way to do this? Possibly without having to wrap the first child in the second?

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Can you have the parent wait on child1 to finish before spawning child2? Is there a requirement that child2 be spawned before child1 has completed? –  Joel Jan 18 '13 at 22:49
    
The reason why I need the wait is that the thing the parent does after spawning the children is somewhat time sensitive. –  Joel Boulet Jan 21 '13 at 18:10
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4 Answers

up vote 1 down vote accepted

The easy way to do this is with Forks::Super.

use Forks::Super;
my $child1 = fork();
if ($child1 != 0) {
    # ... parent code ...
} else {
    # ... child code ...
    exit;
}

my $child2 = fork { 
    depend_on => $child1, 
    on_busy => 'queue',
    sub => sub {
       # ... code to execute in 2nd child ...
    }
};
# ... more code to run in the parent ...
# ... and at the end of the program:
waitall;

In Forks::Super, waitpid is still called in the parent (behind the scenes). But when the first child is finished, Forks::Super will know it is time to start launch the second child process in the background.

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Assuming your perl has semop and friends, you could use System V semaphores for synchronization among the children. See below for a working example program.

We begin with the usual front matter. Rather than calling the low-level semaphore operations directly, the code uses the built-in IPC::SysV and IPC::Semaphore modules.

#! /usr/bin/env perl

use strict;
use warnings;

use IPC::Semaphore;
use IPC::SysV qw/ IPC_PRIVATE S_IRUSR S_IWUSR IPC_CREAT /;

This program separates child processes into the two stages. Children in the first stage run to completion, performing their processing with no synchronization concerns. We can have arbitrarily many of these.

We have a single second-stage process, but it executes after all first-stage children have finished.

Below are simple placeholder implementations.

# how many other children the last child must wait for
my $FIRST_STAGE_CHILDREN = 2;

sub first_stage {
  my($id) = @_;

  print "[$$] hello from child $id\n";
  sleep rand 10;
  print "[$$] child $id done\n";
}

sub second_stage {
  print "[$$] hello from second-stage child!\n";
}

To implement synchronization between the first and second stages, the program creates a set of semaphores whose size equals the number of first-stage children. When a first-stage child completes, the program releases the particular semaphore corresponding to that child.

my $sem = IPC::Semaphore->new(
  IPC_PRIVATE, $FIRST_STAGE_CHILDREN,
  S_IRUSR | S_IWUSR | IPC_CREAT)
    or die "$0: failed to create semaphore: $!";

As we will see later, the second-stage child waits on his brethren by attempting to decrement their semaphores. By starting the value at zero, when the second-stage child attempts these decrements, the OS will put the child to sleep because. Only after all first-stage children have exited and released their semaphores will the system unblock the second-stage child.

# start in blocked state
$sem->setall((0) x $FIRST_STAGE_CHILDREN);

First we fork the first-stage children. In this design, the parent process does as much bookkeeping as possible. This keeps the definition of first_stage and second_stage simple. Also, if a first-stage child somehow exited without releasing its semaphore, the second stage would have no hope of running.

my %kids;
foreach my $id (0 .. $FIRST_STAGE_CHILDREN - 1) {
  my $pid = fork;
  die "$0: fork: $!" unless defined $pid;

  if ($pid) {
    ++$kids{$pid};
  }
  else {
    first_stage $id;
    $sem->op($id, 1, 0);  # release
    exit 0;
  }
}

Now we fork the second-stage child. Important: although the code performs an operation on multiple semaphores, this happens atomically, that is, either it works for all of them or none of them. In no observable state will it appear that the second stage was able to grab any fewer than all of the first-stage semaphores. This is an important property. In more complex systems, haphazard onesie-twosie taking and releasing will result in deadlock.

my $pid = fork;
die "$0: fork: $!" unless defined $pid;

if ($pid) {
  ++$kids{$pid};
}
else {
  # block waiting on all first-stage children
  my @op = map +($_, -1, 0), 0 .. $FIRST_STAGE_CHILDREN - 1;
  $sem->op(@op);

  second_stage;
  exit 0;
}

Finally, the parent process waits for all children to complete.

do {
  $pid = waitpid -1, 0;
  print "[$$] reaped $pid\n";
  warn "$0: unknown child $pid" unless delete $kids{$pid};
} while $pid > 0 && keys %kids;

Sample output is below. It’s more interesting to watch live where you can see the pauses.

[18389] hello from child 0
[18390] hello from child 1
[18390] child 1 done
[18388] reaped 18390
[18389] child 0 done
[18391] hello from second-stage child!
[18388] reaped 18389
[18388] reaped 18391
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Spawn one child, have that process spawn sub-child processes, and then wait for them to finish before continuing in the first child process.

Then have the parent do its work and wait on the child process when it's ready to wait.

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In Unix-like systems, a given process can only wait for its own children to die. It can't wait for siblings, ancestors or grandchildren to die.

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