ViewVC Help
View File | Revision Log | Show Annotations | Download File
/cvs/Async-Interrupt/Interrupt.pm
Revision: 1.27
Committed: Sat May 15 00:08:48 2010 UTC (14 years, 7 months ago) by root
Branch: MAIN
CVS Tags: rel-1_05
Changes since 1.26: +9 -6 lines
Log Message:
1.05

File Contents

# Content
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
9 =head1 DESCRIPTION
10
11 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
15 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.
21
22 This module implements asynchronous notifications that enable you to
23 signal running perl code from another thread, asynchronously, and
24 sometimes even without using a single syscall.
25
26 =head2 USAGE SCENARIOS
27
28 =over 4
29
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
46 =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
61 L<IO::AIO> and L<BDB> could also use this to speed up result reporting.
62
63 =item Speedy event loop invocation
64
65 One could use this module e.g. in L<Coro> to interrupt a running coro-thread
66 and cause it to enter the event loop.
67
68 Or one could bind to C<SIGIO> and tell some important sockets to send this
69 signal, causing the event loop to be entered to reduce network latency.
70
71 =back
72
73 =head2 HOW TO USE
74
75 You can use this module by creating an C<Async::Interrupt> object for each
76 such event source. This object stores a perl and/or a C-level callback
77 that is invoked when the C<Async::Interrupt> object gets signalled. It is
78 executed at the next time the perl interpreter is running (i.e. it will
79 interrupt a computation, but not an XS function or a syscall).
80
81 You can signal the C<Async::Interrupt> object either by calling it's C<<
82 ->signal >> method, or, more commonly, by calling a C function. There is
83 also the built-in (POSIX) signal source.
84
85 The C<< ->signal_func >> returns the address of the C function that is to
86 be called (plus an argument to be used during the call). The signalling
87 function also takes an integer argument in the range SIG_ATOMIC_MIN to
88 SIG_ATOMIC_MAX (guaranteed to allow at least 0..127).
89
90 Since this kind of interruption is fast, but can only interrupt a
91 I<running> interpreter, there is optional support for signalling a pipe
92 - that means you can also wait for the pipe to become readable (e.g. via
93 L<EV> or L<AnyEvent>). This, of course, incurs the overhead of a C<read>
94 and C<write> syscall.
95
96 =head1 USAGE EXAMPLES
97
98 =head2 Implementing race-free signal handling
99
100 This example uses a single event pipe for all signals, and one
101 Async::Interrupt per signal. This code is actually what the L<AnyEvent>
102 module uses itself when Async::Interrupt is available.
103
104 First, create the event pipe and hook it into the event loop
105
106 $SIGPIPE = new Async::Interrupt::EventPipe;
107 $SIGPIPE_W = AnyEvent->io (
108 fh => $SIGPIPE->fileno,
109 poll => "r",
110 cb => \&_signal_check, # defined later
111 );
112
113 Then, for each signal to hook, create an Async::Interrupt object. The
114 callback just sets a global variable, as we are only interested in
115 synchronous signals (i.e. when the event loop polls), which is why the
116 pipe draining is not done automatically.
117
118 my $interrupt = new Async::Interrupt
119 cb => sub { undef $SIGNAL_RECEIVED{$signum} }
120 signal => $signum,
121 pipe => [$SIGPIPE->filenos],
122 pipe_autodrain => 0,
123 ;
124
125 Finally, the I/O callback for the event pipe handles the signals:
126
127 sub _signal_check {
128 # drain the pipe first
129 $SIGPIPE->drain;
130
131 # two loops, just to be sure
132 while (%SIGNAL_RECEIVED) {
133 for (keys %SIGNAL_RECEIVED) {
134 delete $SIGNAL_RECEIVED{$_};
135 warn "signal $_ received\n";
136 }
137 }
138 }
139
140 =head2 Interrupt perl from another thread
141
142 This example interrupts the Perl interpreter from another thread, via the
143 XS API. This is used by e.g. the L<EV::Loop::Async> module.
144
145 On the Perl level, a new loop object (which contains the thread)
146 is created, by first calling some XS constructor, querying the
147 C-level callback function and feeding that as the C<c_cb> into the
148 Async::Interrupt constructor:
149
150 my $self = XS_thread_constructor;
151 my ($c_func, $c_arg) = _c_func $self; # return the c callback
152 my $asy = new Async::Interrupt c_cb => [$c_func, $c_arg];
153
154 Then the newly created Interrupt object is queried for the signaling
155 function that the newly created thread should call, and this is in turn
156 told to the thread object:
157
158 _attach $self, $asy->signal_func;
159
160 So to repeat: first the XS object is created, then it is queried for the
161 callback that should be called when the Interrupt object gets signalled.
162
163 Then the interrupt object is queried for the callback fucntion that the
164 thread should call to signal the Interrupt object, and this callback is
165 then attached to the thread.
166
167 You have to be careful that your new thread is not signalling before the
168 signal function was configured, for example by starting the background
169 thread only within C<_attach>.
170
171 That concludes the Perl part.
172
173 The XS part consists of the actual constructor which creates a thread,
174 which is not relevant for this example, and two functions, C<_c_func>,
175 which returns the Perl-side callback, and C<_attach>, which configures
176 the signalling functioon that is safe toc all from another thread. For
177 simplicity, we will use global variables to store the functions, normally
178 you would somehow attach them to C<$self>.
179
180 The C<c_func> simply returns the address of a static function and arranges
181 for the object pointed to by C<$self> to be passed to it, as an integer:
182
183 void
184 _c_func (SV *loop)
185 PPCODE:
186 EXTEND (SP, 2);
187 PUSHs (sv_2mortal (newSViv (PTR2IV (c_func))));
188 PUSHs (sv_2mortal (newSViv (SvRV (loop))));
189
190 This would be the callback (since it runs in a normal Perl context, it is
191 permissible to manipulate Perl values):
192
193 static void
194 c_func (pTHX_ void *loop_, int value)
195 {
196 SV *loop_object = (SV *)loop_;
197 ...
198 }
199
200 And this attaches the signalling callback:
201
202 static void (*my_sig_func) (void *signal_arg, int value);
203 static void *my_sig_arg;
204
205 void
206 _attach (SV *loop_, IV sig_func, void *sig_arg)
207 CODE:
208 {
209 my_sig_func = sig_func;
210 my_sig_arg = sig_arg;
211
212 /* now run the thread */
213 thread_create (&u->tid, l_run, 0);
214 }
215
216 And C<l_run> (the background thread) would eventually call the signaling
217 function:
218
219 my_sig_func (my_sig_arg, 0);
220
221 You can have a look at L<EV::Loop::Async> for an actual example using
222 intra-thread communication, locking and so on.
223
224
225 =head1 THE Async::Interrupt CLASS
226
227 =over 4
228
229 =cut
230
231 package Async::Interrupt;
232
233 use common::sense;
234
235 BEGIN {
236 # the next line forces initialisation of internal
237 # signal handling variables, otherwise, PL_sig_pending
238 # etc. might be null pointers.
239 $SIG{KILL} = sub { };
240
241 our $VERSION = '1.05';
242
243 require XSLoader;
244 XSLoader::load ("Async::Interrupt", $VERSION);
245 }
246
247 our $DIED = sub { warn "$@" };
248
249 =item $async = new Async::Interrupt key => value...
250
251 Creates a new Async::Interrupt object. You may only use async
252 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
255 Optional constructor arguments include (normally you would specify at
256 least one of C<cb> or C<c_cb>).
257
258 =over 4
259
260 =item cb => $coderef->($value)
261
262 Registers a perl callback to be invoked whenever the async interrupt is
263 signalled.
264
265 Note that, since this callback can be invoked at basically any time, it
266 must not modify any well-known global variables such as C<$/> without
267 restoring them again before returning.
268
269 The exceptions are C<$!> and C<$@>, which are saved and restored by
270 Async::Interrupt.
271
272 If the callback should throw an exception, then it will be caught,
273 and C<$Async::Interrupt::DIED> will be called with C<$@> containing
274 the exception. The default will simply C<warn> about the message and
275 continue.
276
277 =item c_cb => [$c_func, $c_arg]
278
279 Registers a C callback the be invoked whenever the async interrupt is
280 signalled.
281
282 The C callback must have the following prototype:
283
284 void c_func (pTHX_ void *c_arg, int value);
285
286 Both C<$c_func> and C<$c_arg> must be specified as integers/IVs, and
287 C<$value> is the C<value> passed to some earlier call to either C<$signal>
288 or the C<signal_func> function.
289
290 Note that, because the callback can be invoked at almost any time, you
291 have to be careful at saving and restoring global variables that Perl
292 might use (the exception is C<errno>, which is saved and restored by
293 Async::Interrupt). The callback itself runs as part of the perl context,
294 so you can call any perl functions and modify any perl data structures (in
295 which case the requirements set out for C<cb> apply as well).
296
297 =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
301 object will set it to the passed value, handling the interrupt will reset
302 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
306 string, or printing it, will I<destroy> it and might cause your program to
307 crash or worse).
308
309 =item signal => $signame_or_value
310
311 When this parameter is specified, then the Async::Interrupt will hook the
312 given signal, that is, it will effectively call C<< ->signal (0) >> each time
313 the given signal is caught by the process.
314
315 Only one async can hook a given signal, and the signal will be restored to
316 defaults when the Async::Interrupt object gets destroyed.
317
318 =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
327 be written to it, and before the callback is being invoked, it will be
328 read again. Due to races, it is unlikely but possible that multiple octets
329 are written. It is required that the file handles are both in nonblocking
330 mode.
331
332 The object will keep a reference to the file handles.
333
334 This can be used to ensure that async notifications will interrupt event
335 frameworks as well.
336
337 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
341 If you want to share a single event pipe between multiple Async::Interrupt
342 objects, you can use the C<Async::Interrupt::EventPipe> class to manage
343 those.
344
345 =item pipe_autodrain => $boolean
346
347 Sets the initial autodrain state, see the C<pipe_autodrain> method, below.
348
349 =back
350
351 =cut
352
353 sub new {
354 my ($class, %arg) = @_;
355
356 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