1 |
=head1 NAME |
2 |
|
3 |
Async::Interrupt - allow C/XS libraries to interrupt perl asynchronously |
4 |
|
5 |
=head1 SYNOPSIS |
6 |
|
7 |
use Async::Interrupt; |
8 |
|
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=head1 DESCRIPTION |
10 |
|
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This module implements a single feature only of interest to advanced perl |
12 |
modules, namely asynchronous interruptions (think "UNIX signals", which |
13 |
are very similar). |
14 |
|
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Sometimes, modules wish to run code asynchronously (in another thread, |
16 |
or from a signal handler), and then signal the perl interpreter on |
17 |
certain events. One common way is to write some data to a pipe and use an |
18 |
event handling toolkit to watch for I/O events. Another way is to send |
19 |
a signal. Those methods are slow, and in the case of a pipe, also not |
20 |
asynchronous - it won't interrupt a running perl interpreter. |
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|
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This module implements asynchronous notifications that enable you to |
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signal running perl code from another thread, asynchronously, and |
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sometimes even without using a single syscall. |
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|
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=head2 USAGE SCENARIOS |
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|
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=over 4 |
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|
30 |
=item Race-free signal handling |
31 |
|
32 |
There seems to be no way to do race-free signal handling in perl: to |
33 |
catch a signal, you have to execute Perl code, and between entering the |
34 |
interpreter C<select> function (or other blocking functions) and executing |
35 |
the select syscall is a small but relevant timespan during which signals |
36 |
will be queued, but perl signal handlers will not be executed and the |
37 |
blocking syscall will not be interrupted. |
38 |
|
39 |
You can use this module to bind a signal to a callback while at the same |
40 |
time activating an event pipe that you can C<select> on, fixing the race |
41 |
completely. |
42 |
|
43 |
This can be used to implement the signal hadling in event loops, |
44 |
e.g. L<AnyEvent>, L<POE>, L<IO::Async::Loop> and so on. |
45 |
|
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=item Background threads want speedy reporting |
47 |
|
48 |
Assume you want very exact timing, and you can spare an extra cpu core |
49 |
for that. Then you can run an extra thread that signals your perl |
50 |
interpreter. This means you can get a very exact timing source while your |
51 |
perl code is number crunching, without even using a syscall to communicate |
52 |
between your threads. |
53 |
|
54 |
For example the deliantra game server uses a variant of this technique |
55 |
to interrupt background processes regularly to send map updates to game |
56 |
clients. |
57 |
|
58 |
Or L<EV::Loop::Async> uses an interrupt object to wake up perl when new |
59 |
events have arrived. |
60 |
|
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L<IO::AIO> and L<BDB> could also use this to speed up result reporting. |
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|
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=item Speedy event loop invocation |
64 |
|
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One could use this module e.g. in L<Coro> to interrupt a running coro-thread |
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and cause it to enter the event loop. |
67 |
|
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Or one could bind to C<SIGIO> and tell some important sockets to send this |
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signal, causing the event loop to be entered to reduce network latency. |
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|
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=back |
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|
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=head2 HOW TO USE |
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|
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You can use this module by creating an C<Async::Interrupt> object for each |
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such event source. This object stores a perl and/or a C-level callback |
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that is invoked when the C<Async::Interrupt> object gets signalled. It is |
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executed at the next time the perl interpreter is running (i.e. it will |
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interrupt a computation, but not an XS function or a syscall). |
80 |
|
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You can signal the C<Async::Interrupt> object either by calling it's C<< |
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->signal >> method, or, more commonly, by calling a C function. There is |
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also the built-in (POSIX) signal source. |
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|
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The C<< ->signal_func >> returns the address of the C function that is to |
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be called (plus an argument to be used during the call). The signalling |
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function also takes an integer argument in the range SIG_ATOMIC_MIN to |
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SIG_ATOMIC_MAX (guaranteed to allow at least 0..127). |
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|
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Since this kind of interruption is fast, but can only interrupt a |
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I<running> interpreter, there is optional support for signalling a pipe |
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- that means you can also wait for the pipe to become readable (e.g. via |
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L<EV> or L<AnyEvent>). This, of course, incurs the overhead of a C<read> |
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and C<write> syscall. |
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|
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=head1 USAGE EXAMPLES |
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|
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=head2 Implementing race-free signal handling |
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|
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This example uses a single event pipe for all signals, and one |
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Async::Interrupt per signal. This code is actually what the L<AnyEvent> |
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module uses itself when Async::Interrupt is available. |
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|
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First, create the event pipe and hook it into the event loop |
105 |
|
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$SIGPIPE = new Async::Interrupt::EventPipe; |
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$SIGPIPE_W = AnyEvent->io ( |
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fh => $SIGPIPE->fileno, |
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poll => "r", |
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cb => \&_signal_check, # defined later |
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); |
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|
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Then, for each signal to hook, create an Async::Interrupt object. The |
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callback just sets a global variable, as we are only interested in |
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synchronous signals (i.e. when the event loop polls), which is why the |
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pipe draining is not done automatically. |
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|
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my $interrupt = new Async::Interrupt |
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cb => sub { undef $SIGNAL_RECEIVED{$signum} } |
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signal => $signum, |
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pipe => [$SIGPIPE->filenos], |
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pipe_autodrain => 0, |
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; |
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|
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Finally, the I/O callback for the event pipe handles the signals: |
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|
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sub _signal_check { |
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# drain the pipe first |
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$SIGPIPE->drain; |
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|
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# two loops, just to be sure |
132 |
while (%SIGNAL_RECEIVED) { |
133 |
for (keys %SIGNAL_RECEIVED) { |
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delete $SIGNAL_RECEIVED{$_}; |
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warn "signal $_ received\n"; |
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} |
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} |
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} |
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|
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=head2 Interrupt perl from another thread |
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|
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This example interrupts the Perl interpreter from another thread, via the |
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XS API. This is used by e.g. the L<EV::Loop::Async> module. |
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|
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On the Perl level, a new loop object (which contains the thread) |
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is created, by first calling some XS constructor, querying the |
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C-level callback function and feeding that as the C<c_cb> into the |
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Async::Interrupt constructor: |
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|
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my $self = XS_thread_constructor; |
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my ($c_func, $c_arg) = _c_func $self; # return the c callback |
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my $asy = new Async::Interrupt c_cb => [$c_func, $c_arg]; |
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|
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Then the newly created Interrupt object is queried for the signaling |
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function that the newly created thread should call, and this is in turn |
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told to the thread object: |
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|
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_attach $self, $asy->signal_func; |
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|
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So to repeat: first the XS object is created, then it is queried for the |
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callback that should be called when the Interrupt object gets signalled. |
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|
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Then the interrupt object is queried for the callback fucntion that the |
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thread should call to signal the Interrupt object, and this callback is |
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then attached to the thread. |
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|
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You have to be careful that your new thread is not signalling before the |
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signal function was configured, for example by starting the background |
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thread only within C<_attach>. |
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|
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That concludes the Perl part. |
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|
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The XS part consists of the actual constructor which creates a thread, |
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which is not relevant for this example, and two functions, C<_c_func>, |
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which returns the Perl-side callback, and C<_attach>, which configures |
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the signalling functioon that is safe toc all from another thread. For |
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simplicity, we will use global variables to store the functions, normally |
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you would somehow attach them to C<$self>. |
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|
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The C<c_func> simply returns the address of a static function and arranges |
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for the object pointed to by C<$self> to be passed to it, as an integer: |
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|
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void |
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_c_func (SV *loop) |
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PPCODE: |
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EXTEND (SP, 2); |
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PUSHs (sv_2mortal (newSViv (PTR2IV (c_func)))); |
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PUSHs (sv_2mortal (newSViv (SvRV (loop)))); |
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|
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This would be the callback (since it runs in a normal Perl context, it is |
191 |
permissible to manipulate Perl values): |
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|
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static void |
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c_func (pTHX_ void *loop_, int value) |
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{ |
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SV *loop_object = (SV *)loop_; |
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... |
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} |
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|
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And this attaches the signalling callback: |
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|
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static void (*my_sig_func) (void *signal_arg, int value); |
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static void *my_sig_arg; |
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|
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void |
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_attach (SV *loop_, IV sig_func, void *sig_arg) |
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CODE: |
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{ |
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my_sig_func = sig_func; |
210 |
my_sig_arg = sig_arg; |
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|
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/* now run the thread */ |
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thread_create (&u->tid, l_run, 0); |
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} |
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|
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And C<l_run> (the background thread) would eventually call the signaling |
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function: |
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|
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my_sig_func (my_sig_arg, 0); |
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|
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You can have a look at L<EV::Loop::Async> for an actual example using |
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intra-thread communication, locking and so on. |
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|
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|
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=head1 THE Async::Interrupt CLASS |
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|
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=over 4 |
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|
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=cut |
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|
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package Async::Interrupt; |
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|
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use common::sense; |
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|
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BEGIN { |
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# the next line forces initialisation of internal |
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# signal handling variables, otherwise, PL_sig_pending |
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# etc. might be null pointers. |
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$SIG{KILL} = sub { }; |
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|
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our $VERSION = '1.05'; |
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|
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require XSLoader; |
244 |
XSLoader::load ("Async::Interrupt", $VERSION); |
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} |
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|
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our $DIED = sub { warn "$@" }; |
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|
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=item $async = new Async::Interrupt key => value... |
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|
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Creates a new Async::Interrupt object. You may only use async |
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notifications on this object while it exists, so you need to keep a |
253 |
reference to it at all times while it is used. |
254 |
|
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Optional constructor arguments include (normally you would specify at |
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least one of C<cb> or C<c_cb>). |
257 |
|
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=over 4 |
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|
260 |
=item cb => $coderef->($value) |
261 |
|
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Registers a perl callback to be invoked whenever the async interrupt is |
263 |
signalled. |
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|
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Note that, since this callback can be invoked at basically any time, it |
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must not modify any well-known global variables such as C<$/> without |
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restoring them again before returning. |
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|
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The exceptions are C<$!> and C<$@>, which are saved and restored by |
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Async::Interrupt. |
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|
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If the callback should throw an exception, then it will be caught, |
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and C<$Async::Interrupt::DIED> will be called with C<$@> containing |
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the exception. The default will simply C<warn> about the message and |
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continue. |
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|
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=item c_cb => [$c_func, $c_arg] |
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|
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Registers a C callback the be invoked whenever the async interrupt is |
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signalled. |
281 |
|
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The C callback must have the following prototype: |
283 |
|
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void c_func (pTHX_ void *c_arg, int value); |
285 |
|
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Both C<$c_func> and C<$c_arg> must be specified as integers/IVs, and |
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C<$value> is the C<value> passed to some earlier call to either C<$signal> |
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or the C<signal_func> function. |
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|
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Note that, because the callback can be invoked at almost any time, you |
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have to be careful at saving and restoring global variables that Perl |
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might use (the exception is C<errno>, which is saved and restored by |
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Async::Interrupt). The callback itself runs as part of the perl context, |
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so you can call any perl functions and modify any perl data structures (in |
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which case the requirements set out for C<cb> apply as well). |
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|
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=item var => $scalar_ref |
298 |
|
299 |
When specified, then the given argument must be a reference to a |
300 |
scalar. The scalar will be set to C<0> initially. Signalling the interrupt |
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object will set it to the passed value, handling the interrupt will reset |
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it to C<0> again. |
303 |
|
304 |
Note that the only thing you are legally allowed to do is to is to check |
305 |
the variable in a boolean or integer context (e.g. comparing it with a |
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string, or printing it, will I<destroy> it and might cause your program to |
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crash or worse). |
308 |
|
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=item signal => $signame_or_value |
310 |
|
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When this parameter is specified, then the Async::Interrupt will hook the |
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given signal, that is, it will effectively call C<< ->signal (0) >> each time |
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the given signal is caught by the process. |
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|
315 |
Only one async can hook a given signal, and the signal will be restored to |
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defaults when the Async::Interrupt object gets destroyed. |
317 |
|
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=item signal_hysteresis => $boolean |
319 |
|
320 |
Sets the initial signal hysteresis state, see the C<signal_hysteresis> |
321 |
method, below. |
322 |
|
323 |
=item pipe => [$fileno_or_fh_for_reading, $fileno_or_fh_for_writing] |
324 |
|
325 |
Specifies two file descriptors (or file handles) that should be signalled |
326 |
whenever the async interrupt is signalled. This means a single octet will |
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be written to it, and before the callback is being invoked, it will be |
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read again. Due to races, it is unlikely but possible that multiple octets |
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are written. It is required that the file handles are both in nonblocking |
330 |
mode. |
331 |
|
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The object will keep a reference to the file handles. |
333 |
|
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This can be used to ensure that async notifications will interrupt event |
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frameworks as well. |
336 |
|
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Note that C<Async::Interrupt> will create a suitable signal fd |
338 |
automatically when your program requests one, so you don't have to specify |
339 |
this argument when all you want is an extra file descriptor to watch. |
340 |
|
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If you want to share a single event pipe between multiple Async::Interrupt |
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objects, you can use the C<Async::Interrupt::EventPipe> class to manage |
343 |
those. |
344 |
|
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=item pipe_autodrain => $boolean |
346 |
|
347 |
Sets the initial autodrain state, see the C<pipe_autodrain> method, below. |
348 |
|
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=back |
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|
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=cut |
352 |
|
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sub new { |
354 |
my ($class, %arg) = @_; |
355 |
|
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my $self = bless \(_alloc $arg{cb}, @{$arg{c_cb}}[0,1], @{$arg{pipe}}[0,1], $arg{signal}, $arg{var}), $class; |
357 |
|
358 |
# urgs, reminds me of Event |
359 |
for my $attr (qw(pipe_autodrain signal_hysteresis)) { |
360 |
$self->$attr ($arg{$attr}) if exists $arg{$attr}; |
361 |
} |
362 |
|
363 |
$self |
364 |
} |
365 |
|
366 |
=item ($signal_func, $signal_arg) = $async->signal_func |
367 |
|
368 |
Returns the address of a function to call asynchronously. The function |
369 |
has the following prototype and needs to be passed the specified |
370 |
C<$signal_arg>, which is a C<void *> cast to C<IV>: |
371 |
|
372 |
void (*signal_func) (void *signal_arg, int value) |
373 |
|
374 |
An example call would look like: |
375 |
|
376 |
signal_func (signal_arg, 0); |
377 |
|
378 |
The function is safe to call from within signal and thread contexts, at |
379 |
any time. The specified C<value> is passed to both C and Perl callback. |
380 |
|
381 |
C<$value> must be in the valid range for a C<sig_atomic_t>, except C<0> |
382 |
(1..127 is portable). |
383 |
|
384 |
If the function is called while the Async::Interrupt object is already |
385 |
signaled but before the callbacks are being executed, then the stored |
386 |
C<value> is either the old or the new one. Due to the asynchronous |
387 |
nature of the code, the C<value> can even be passed to two consecutive |
388 |
invocations of the callback. |
389 |
|
390 |
=item $address = $async->c_var |
391 |
|
392 |
Returns the address (cast to IV) of an C<IV> variable. The variable is set |
393 |
to C<0> initially and gets set to the passed value whenever the object |
394 |
gets signalled, and reset to C<0> once the interrupt has been handled. |
395 |
|
396 |
Note that it is often beneficial to just call C<PERL_ASYNC_CHECK ()> to |
397 |
handle any interrupts. |
398 |
|
399 |
Example: call some XS function to store the address, then show C code |
400 |
waiting for it. |
401 |
|
402 |
my_xs_func $async->c_var; |
403 |
|
404 |
static IV *valuep; |
405 |
|
406 |
void |
407 |
my_xs_func (void *addr) |
408 |
CODE: |
409 |
valuep = (IV *)addr; |
410 |
|
411 |
// code in a loop, waiting |
412 |
while (!*valuep) |
413 |
; // do something |
414 |
|
415 |
=item $async->signal ($value=1) |
416 |
|
417 |
This signals the given async object from Perl code. Semi-obviously, this |
418 |
will instantly trigger the callback invocation (it does not, as the name |
419 |
might imply, do anything with POSIX signals). |
420 |
|
421 |
C<$value> must be in the valid range for a C<sig_atomic_t>, except C<0> |
422 |
(1..127 is portable). |
423 |
|
424 |
=item $async->signal_hysteresis ($enable) |
425 |
|
426 |
Enables or disables signal hysteresis (default: disabled). If a POSIX |
427 |
signal is used as a signal source for the interrupt object, then enabling |
428 |
signal hysteresis causes Async::Interrupt to reset the signal action to |
429 |
C<SIG_IGN> in the signal handler and restore it just before handling the |
430 |
interruption. |
431 |
|
432 |
When you expect a lot of signals (e.g. when using SIGIO), then enabling |
433 |
signal hysteresis can reduce the number of handler invocations |
434 |
considerably, at the cost of two extra syscalls. |
435 |
|
436 |
Note that setting the signal to C<SIG_IGN> can have unintended side |
437 |
effects when you fork and exec other programs, as often they do nto expect |
438 |
signals to be ignored by default. |
439 |
|
440 |
=item $async->block |
441 |
|
442 |
=item $async->unblock |
443 |
|
444 |
Sometimes you need a "critical section" of code that will not be |
445 |
interrupted by an Async::Interrupt. This can be implemented by calling C<< |
446 |
$async->block >> before the critical section, and C<< $async->unblock >> |
447 |
afterwards. |
448 |
|
449 |
Note that there must be exactly one call of C<unblock> for every previous |
450 |
call to C<block> (i.e. calls can nest). |
451 |
|
452 |
Since ensuring this in the presence of exceptions and threads is |
453 |
usually more difficult than you imagine, I recommend using C<< |
454 |
$async->scoped_block >> instead. |
455 |
|
456 |
=item $async->scope_block |
457 |
|
458 |
This call C<< $async->block >> and installs a handler that is called when |
459 |
the current scope is exited (via an exception, by canceling the Coro |
460 |
thread, by calling last/goto etc.). |
461 |
|
462 |
This is the recommended (and fastest) way to implement critical sections. |
463 |
|
464 |
=item ($block_func, $block_arg) = $async->scope_block_func |
465 |
|
466 |
Returns the address of a function that implements the C<scope_block> |
467 |
functionality. |
468 |
|
469 |
It has the following prototype and needs to be passed the specified |
470 |
C<$block_arg>, which is a C<void *> cast to C<IV>: |
471 |
|
472 |
void (*block_func) (void *block_arg) |
473 |
|
474 |
An example call would look like: |
475 |
|
476 |
block_func (block_arg); |
477 |
|
478 |
The function is safe to call only from within the toplevel of a perl XS |
479 |
function and will call C<LEAVE> and C<ENTER> (in this order!). |
480 |
|
481 |
=item $async->pipe_enable |
482 |
|
483 |
=item $async->pipe_disable |
484 |
|
485 |
Enable/disable signalling the pipe when the interrupt occurs (default is |
486 |
enabled). Writing to a pipe is relatively expensive, so it can be disabled |
487 |
when you know you are not waiting for it (for example, with L<EV> you |
488 |
could disable the pipe in a check watcher, and enable it in a prepare |
489 |
watcher). |
490 |
|
491 |
Note that currently, while C<pipe_disable> is in effect, no attempt to |
492 |
read from the pipe will be done when handling events. This might change as |
493 |
soon as I realize why this is a mistake. |
494 |
|
495 |
=item $fileno = $async->pipe_fileno |
496 |
|
497 |
Returns the reading side of the signalling pipe. If no signalling pipe is |
498 |
currently attached to the object, it will dynamically create one. |
499 |
|
500 |
Note that the only valid oepration on this file descriptor is to wait |
501 |
until it is readable. The fd might belong currently to a pipe, a tcp |
502 |
socket, or an eventfd, depending on the platform, and is guaranteed to be |
503 |
C<select>able. |
504 |
|
505 |
=item $async->pipe_autodrain ($enable) |
506 |
|
507 |
Enables (C<1>) or disables (C<0>) automatic draining of the pipe (default: |
508 |
enabled). When automatic draining is enabled, then Async::Interrupt will |
509 |
automatically clear the pipe. Otherwise the user is responsible for this |
510 |
draining. |
511 |
|
512 |
This is useful when you want to share one pipe among many Async::Interrupt |
513 |
objects. |
514 |
|
515 |
=item $async->post_fork |
516 |
|
517 |
The object will not normally be usable after a fork (as the pipe fd is |
518 |
shared between processes). Calling this method after a fork in the child |
519 |
ensures that the object will work as expected again. It only needs to be |
520 |
called when the async object is used in the child. |
521 |
|
522 |
This only works when the pipe was created by Async::Interrupt. |
523 |
|
524 |
Async::Interrupt ensures that the reading file descriptor does not change |
525 |
it's value. |
526 |
|
527 |
=item $signum = Async::Interrupt::sig2num $signame_or_number |
528 |
|
529 |
=item $signame = Async::Interrupt::sig2name $signame_or_number |
530 |
|
531 |
These two convenience functions simply convert a signal name or number to |
532 |
the corresponding name or number. They are not used by this module and |
533 |
exist just because perl doesn't have a nice way to do this on its own. |
534 |
|
535 |
They will return C<undef> on illegal names or numbers. |
536 |
|
537 |
=back |
538 |
|
539 |
=head1 THE Async::Interrupt::EventPipe CLASS |
540 |
|
541 |
Pipes are the predominant utility to make asynchronous signals |
542 |
synchronous. However, pipes are hard to come by: they don't exist on the |
543 |
broken windows platform, and on GNU/Linux systems, you might want to use |
544 |
an C<eventfd> instead. |
545 |
|
546 |
This class creates selectable event pipes in a portable fashion: on |
547 |
windows, it will try to create a tcp socket pair, on GNU/Linux, it will |
548 |
try to create an eventfd and everywhere else it will try to use a normal |
549 |
pipe. |
550 |
|
551 |
=over 4 |
552 |
|
553 |
=item $epipe = new Async::Interrupt::EventPipe |
554 |
|
555 |
This creates and returns an eventpipe object. This object is simply a |
556 |
blessed array reference: |
557 |
|
558 |
=item ($r_fd, $w_fd) = $epipe->filenos |
559 |
|
560 |
Returns the read-side file descriptor and the write-side file descriptor. |
561 |
|
562 |
Example: pass an eventpipe object as pipe to the Async::Interrupt |
563 |
constructor, and create an AnyEvent watcher for the read side. |
564 |
|
565 |
my $epipe = new Async::Interrupt::EventPipe; |
566 |
my $asy = new Async::Interrupt pipe => [$epipe->filenos]; |
567 |
my $iow = AnyEvent->io (fh => $epipe->fileno, poll => 'r', cb => sub { }); |
568 |
|
569 |
=item $r_fd = $epipe->fileno |
570 |
|
571 |
Return only the reading/listening side. |
572 |
|
573 |
=item $epipe->signal |
574 |
|
575 |
Write something to the pipe, in a portable fashion. |
576 |
|
577 |
=item $epipe->drain |
578 |
|
579 |
Drain (empty) the pipe. |
580 |
|
581 |
=item ($c_func, $c_arg) = $epipe->signal_func |
582 |
|
583 |
=item ($c_func, $c_arg) = $epipe->drain_func |
584 |
|
585 |
These two methods returns a function pointer and C<void *> argument |
586 |
that can be called to have the effect of C<< $epipe->signal >> or C<< |
587 |
$epipe->drain >>, respectively, on the XS level. |
588 |
|
589 |
They both have the following prototype and need to be passed their |
590 |
C<$c_arg>, which is a C<void *> cast to an C<IV>: |
591 |
|
592 |
void (*c_func) (void *c_arg) |
593 |
|
594 |
An example call would look like: |
595 |
|
596 |
c_func (c_arg); |
597 |
|
598 |
=item $epipe->renew |
599 |
|
600 |
Recreates the pipe (useful after a fork). The reading side will not change |
601 |
it's file descriptor number, but the writing side might. |
602 |
|
603 |
=item $epipe->wait |
604 |
|
605 |
This method blocks the process until there are events on the pipe. This is |
606 |
not a very event-based or ncie way of usign an event pipe, but it can be |
607 |
occasionally useful. |
608 |
|
609 |
=back |
610 |
|
611 |
=cut |
612 |
|
613 |
1; |
614 |
|
615 |
=head1 IMPLEMENTATION DETAILS AND LIMITATIONS |
616 |
|
617 |
This module works by "hijacking" SIGKILL, which is guaranteed to always |
618 |
exist, but also cannot be caught, so is always available. |
619 |
|
620 |
Basically, this module fakes the occurance of a SIGKILL signal and |
621 |
then intercepts the interpreter handling it. This makes normal signal |
622 |
handling slower (probably unmeasurably, though), but has the advantage |
623 |
of not requiring a special runops function, nor slowing down normal perl |
624 |
execution a bit. |
625 |
|
626 |
It assumes that C<sig_atomic_t>, C<int> and C<IV> are all async-safe to |
627 |
modify. |
628 |
|
629 |
=head1 AUTHOR |
630 |
|
631 |
Marc Lehmann <schmorp@schmorp.de> |
632 |
http://home.schmorp.de/ |
633 |
|
634 |
=cut |
635 |
|