… | |
… | |
26 | $cv->recv; |
26 | $cv->recv; |
27 | |
27 | |
28 | =head1 DESCRIPTION |
28 | =head1 DESCRIPTION |
29 | |
29 | |
30 | This module implements a simple RPC protocol and backend for processes |
30 | This module implements a simple RPC protocol and backend for processes |
31 | created via L<AnyEvent::Fork> (or L<AnyEvent::Fork::Remote>), allowing you |
31 | created via L<AnyEvent::Fork> or L<AnyEvent::Fork::Remote>, allowing you |
32 | to call a function in the child process and receive its return values (up |
32 | to call a function in the child process and receive its return values (up |
33 | to 4GB serialised). |
33 | to 4GB serialised). |
34 | |
34 | |
35 | It implements two different backends: a synchronous one that works like a |
35 | It implements two different backends: a synchronous one that works like a |
36 | normal function call, and an asynchronous one that can run multiple jobs |
36 | normal function call, and an asynchronous one that can run multiple jobs |
… | |
… | |
58 | |
58 | |
59 | my $rpc = AnyEvent::Fork |
59 | my $rpc = AnyEvent::Fork |
60 | ->new |
60 | ->new |
61 | ->require ("MyWorker") |
61 | ->require ("MyWorker") |
62 | ->AnyEvent::Fork::RPC::run ("MyWorker::run", |
62 | ->AnyEvent::Fork::RPC::run ("MyWorker::run", |
63 | on_error => sub { warn "FATAL: $_[0]"; exit 1 }, |
63 | on_error => sub { warn "ERROR: $_[0]"; exit 1 }, |
64 | on_event => sub { warn "$_[0] requests handled\n" }, |
64 | on_event => sub { warn "$_[0] requests handled\n" }, |
65 | on_destroy => $done, |
65 | on_destroy => $done, |
66 | ); |
66 | ); |
67 | |
67 | |
68 | for my $id (1..6) { |
68 | for my $id (1..6) { |
… | |
… | |
175 | you really I<are> done. |
175 | you really I<are> done. |
176 | |
176 | |
177 | =head2 Example 2: Asynchronous Backend |
177 | =head2 Example 2: Asynchronous Backend |
178 | |
178 | |
179 | This example implements multiple count-downs in the child, using |
179 | This example implements multiple count-downs in the child, using |
180 | L<AnyEvent> timers. While this is a bit silly (one could use timers in te |
180 | L<AnyEvent> timers. While this is a bit silly (one could use timers in the |
181 | parent just as well), it illustrates the ability to use AnyEvent in the |
181 | parent just as well), it illustrates the ability to use AnyEvent in the |
182 | child and the fact that responses can arrive in a different order then the |
182 | child and the fact that responses can arrive in a different order then the |
183 | requests. |
183 | requests. |
184 | |
184 | |
185 | It also shows how to embed the actual child code into a C<__DATA__> |
185 | It also shows how to embed the actual child code into a C<__DATA__> |
… | |
… | |
201 | ->new |
201 | ->new |
202 | ->require ("AnyEvent::Fork::RPC::Async") |
202 | ->require ("AnyEvent::Fork::RPC::Async") |
203 | ->eval (do { local $/; <DATA> }) |
203 | ->eval (do { local $/; <DATA> }) |
204 | ->AnyEvent::Fork::RPC::run ("run", |
204 | ->AnyEvent::Fork::RPC::run ("run", |
205 | async => 1, |
205 | async => 1, |
206 | on_error => sub { warn "FATAL: $_[0]"; exit 1 }, |
206 | on_error => sub { warn "ERROR: $_[0]"; exit 1 }, |
207 | on_event => sub { print $_[0] }, |
207 | on_event => sub { print $_[0] }, |
208 | on_destroy => $done, |
208 | on_destroy => $done, |
209 | ); |
209 | ); |
210 | |
210 | |
211 | for my $count (3, 2, 1) { |
211 | for my $count (3, 2, 1) { |
… | |
… | |
287 | |
287 | |
288 | This concludes the async example. Since L<AnyEvent::Fork> does not |
288 | This concludes the async example. Since L<AnyEvent::Fork> does not |
289 | actually fork, you are free to use about any module in the child, not just |
289 | actually fork, you are free to use about any module in the child, not just |
290 | L<AnyEvent>, but also L<IO::AIO>, or L<Tk> for example. |
290 | L<AnyEvent>, but also L<IO::AIO>, or L<Tk> for example. |
291 | |
291 | |
|
|
292 | =head2 Example 3: Asynchronous backend with Coro |
|
|
293 | |
|
|
294 | With L<Coro> you can create a nice asynchronous backend implementation by |
|
|
295 | defining an rpc server function that creates a new Coro thread for every |
|
|
296 | request that calls a function "normally", i.e. the parameters from the |
|
|
297 | parent process are passed to it, and any return values are returned to the |
|
|
298 | parent process, e.g.: |
|
|
299 | |
|
|
300 | package My::Arith; |
|
|
301 | |
|
|
302 | sub add { |
|
|
303 | return $_[0] + $_[1]; |
|
|
304 | } |
|
|
305 | |
|
|
306 | sub mul { |
|
|
307 | return $_[0] * $_[1]; |
|
|
308 | } |
|
|
309 | |
|
|
310 | sub run { |
|
|
311 | my ($done, $func, @arg) = @_; |
|
|
312 | |
|
|
313 | Coro::async_pool { |
|
|
314 | $done->($func->(@arg)); |
|
|
315 | }; |
|
|
316 | } |
|
|
317 | |
|
|
318 | The C<run> function creates a new thread for every invocation, using the |
|
|
319 | first argument as function name, and calls the C<$done> callback on it's |
|
|
320 | return values. This makes it quite natural to define the C<add> and C<mul> |
|
|
321 | functions to add or multiply two numbers and return the result. |
|
|
322 | |
|
|
323 | Since this is the asynchronous backend, it's quite possible to define RPC |
|
|
324 | function that do I/O or wait for external events - their execution will |
|
|
325 | overlap as needed. |
|
|
326 | |
|
|
327 | The above could be used like this: |
|
|
328 | |
|
|
329 | my $rpc = AnyEvent::Fork |
|
|
330 | ->new |
|
|
331 | ->require ("MyWorker") |
|
|
332 | ->AnyEvent::Fork::RPC::run ("My::Arith::run", |
|
|
333 | on_error => ..., on_event => ..., on_destroy => ..., |
|
|
334 | ); |
|
|
335 | |
|
|
336 | $rpc->(add => 1, 3, Coro::rouse_cb); say Coro::rouse_wait; |
|
|
337 | $rpc->(mul => 3, 2, Coro::rouse_cb); say Coro::rouse_wait; |
|
|
338 | |
|
|
339 | The C<say>'s will print C<4> and C<6>. |
|
|
340 | |
|
|
341 | =head2 Example 4: Forward AnyEvent::Log messages using C<on_event> |
|
|
342 | |
|
|
343 | This partial example shows how to use the C<event> function to forward |
|
|
344 | L<AnyEvent::Log> messages to the parent. |
|
|
345 | |
|
|
346 | For this, the parent needs to provide a suitable C<on_event>: |
|
|
347 | |
|
|
348 | ->AnyEvent::Fork::RPC::run ( |
|
|
349 | on_event => sub { |
|
|
350 | if ($_[0] eq "ae_log") { |
|
|
351 | my (undef, $level, $message) = @_; |
|
|
352 | AE::log $level, $message; |
|
|
353 | } else { |
|
|
354 | # other event types |
|
|
355 | } |
|
|
356 | }, |
|
|
357 | ) |
|
|
358 | |
|
|
359 | In the child, as early as possible, the following code should reconfigure |
|
|
360 | L<AnyEvent::Log> to log via C<AnyEvent::Fork::RPC::event>: |
|
|
361 | |
|
|
362 | $AnyEvent::Log::LOG->log_cb (sub { |
|
|
363 | my ($timestamp, $orig_ctx, $level, $message) = @{+shift}; |
|
|
364 | |
|
|
365 | if (defined &AnyEvent::Fork::RPC::event) { |
|
|
366 | AnyEvent::Fork::RPC::event (ae_log => $level, $message); |
|
|
367 | } else { |
|
|
368 | warn "[$$ before init] $message\n"; |
|
|
369 | } |
|
|
370 | }); |
|
|
371 | |
|
|
372 | There is an important twist - the C<AnyEvent::Fork::RPC::event> function |
|
|
373 | is only defined when the child is fully initialised. If you redirect the |
|
|
374 | log messages in your C<init> function for example, then the C<event> |
|
|
375 | function might not yet be available. This is why the log callback checks |
|
|
376 | whether the fucntion is there using C<defined>, and only then uses it to |
|
|
377 | log the message. |
|
|
378 | |
292 | =head1 PARENT PROCESS USAGE |
379 | =head1 PARENT PROCESS USAGE |
293 | |
380 | |
294 | This module exports nothing, and only implements a single function: |
381 | This module exports nothing, and only implements a single function: |
295 | |
382 | |
296 | =over 4 |
383 | =over 4 |
… | |
… | |
304 | use Errno (); |
391 | use Errno (); |
305 | use Guard (); |
392 | use Guard (); |
306 | |
393 | |
307 | use AnyEvent; |
394 | use AnyEvent; |
308 | |
395 | |
309 | our $VERSION = 1.1; |
396 | our $VERSION = 1.21; |
310 | |
397 | |
311 | =item my $rpc = AnyEvent::Fork::RPC::run $fork, $function, [key => value...] |
398 | =item my $rpc = AnyEvent::Fork::RPC::run $fork, $function, [key => value...] |
312 | |
399 | |
313 | The traditional way to call it. But it is way cooler to call it in the |
400 | The traditional way to call it. But it is way cooler to call it in the |
314 | following way: |
401 | following way: |
… | |
… | |
334 | Called on (fatal) errors, with a descriptive (hopefully) message. If |
421 | Called on (fatal) errors, with a descriptive (hopefully) message. If |
335 | this callback is not provided, but C<on_event> is, then the C<on_event> |
422 | this callback is not provided, but C<on_event> is, then the C<on_event> |
336 | callback is called with the first argument being the string C<error>, |
423 | callback is called with the first argument being the string C<error>, |
337 | followed by the error message. |
424 | followed by the error message. |
338 | |
425 | |
339 | If neither handler is provided it prints the error to STDERR and will |
426 | If neither handler is provided, then the error is reported with loglevel |
340 | start failing badly. |
427 | C<error> via C<AE::log>. |
341 | |
428 | |
342 | =item on_event => $cb->(...) |
429 | =item on_event => $cb->(...) |
343 | |
430 | |
344 | Called for every call to the C<AnyEvent::Fork::RPC::event> function in the |
431 | Called for every call to the C<AnyEvent::Fork::RPC::event> function in the |
345 | child, with the arguments of that function passed to the callback. |
432 | child, with the arguments of that function passed to the callback. |
… | |
… | |
367 | It is called very early - before the serialisers are created or the |
454 | It is called very early - before the serialisers are created or the |
368 | C<$function> name is resolved into a function reference, so it could be |
455 | C<$function> name is resolved into a function reference, so it could be |
369 | used to load any modules that provide the serialiser or function. It can |
456 | used to load any modules that provide the serialiser or function. It can |
370 | not, however, create events. |
457 | not, however, create events. |
371 | |
458 | |
|
|
459 | =item done => $function (default C<CORE::exit>) |
|
|
460 | |
|
|
461 | The function to call when the asynchronous backend detects an end of file |
|
|
462 | condition when reading from the communications socket I<and> there are no |
|
|
463 | outstanding requests. It's ignored by the synchronous backend. |
|
|
464 | |
|
|
465 | By overriding this you can prolong the life of a RPC process after e.g. |
|
|
466 | the parent has exited by running the event loop in the provided function |
|
|
467 | (or simply calling it, for example, when your child process uses L<EV> you |
|
|
468 | could provide L<EV::run> as C<done> function). |
|
|
469 | |
|
|
470 | Of course, in that case you are responsible for exiting at the appropriate |
|
|
471 | time and not returning from |
|
|
472 | |
372 | =item async => $boolean (default: 0) |
473 | =item async => $boolean (default: 0) |
373 | |
474 | |
374 | The default server used in the child does all I/O blockingly, and only |
475 | The default server used in the child does all I/O blockingly, and only |
375 | allows a single RPC call to execute concurrently. |
476 | allows a single RPC call to execute concurrently. |
376 | |
477 | |
… | |
… | |
393 | |
494 | |
394 | All arguments, result data and event data have to be serialised to be |
495 | All arguments, result data and event data have to be serialised to be |
395 | transferred between the processes. For this, they have to be frozen and |
496 | transferred between the processes. For this, they have to be frozen and |
396 | thawed in both parent and child processes. |
497 | thawed in both parent and child processes. |
397 | |
498 | |
398 | By default, only octet strings can be passed between the processes, which |
499 | By default, only octet strings can be passed between the processes, |
399 | is reasonably fast and efficient and requires no extra modules. |
500 | which is reasonably fast and efficient and requires no extra modules |
|
|
501 | (the C<AnyEvent::Fork::RPC> distribution does not provide these extra |
|
|
502 | serialiser modules). |
400 | |
503 | |
401 | For more complicated use cases, you can provide your own freeze and thaw |
504 | For more complicated use cases, you can provide your own freeze and thaw |
402 | functions, by specifying a string with perl source code. It's supposed to |
505 | functions, by specifying a string with perl source code. It's supposed to |
403 | return two code references when evaluated: the first receives a list of |
506 | return two code references when evaluated: the first receives a list of |
404 | perl values and must return an octet string. The second receives the octet |
507 | perl values and must return an octet string. The second receives the octet |
… | |
… | |
411 | Here are some examples - some of them are also available as global |
514 | Here are some examples - some of them are also available as global |
412 | variables that make them easier to use. |
515 | variables that make them easier to use. |
413 | |
516 | |
414 | =over 4 |
517 | =over 4 |
415 | |
518 | |
416 | =item octet strings - C<$AnyEvent::Fork::RPC::STRING_SERIALISER> |
519 | =item C<$AnyEvent::Fork::RPC::STRING_SERIALISER> - octet strings only |
417 | |
520 | |
418 | This serialiser concatenates length-prefixes octet strings, and is the |
521 | This serialiser (currently the default) concatenates length-prefixes octet |
419 | default. |
522 | strings, and is the default. That means you can only pass (and return) |
|
|
523 | strings containing character codes 0-255. |
|
|
524 | |
|
|
525 | The main advantages of this serialiser are the high speed and that it |
|
|
526 | doesn't need another module. The main disadvantage is that you are very |
|
|
527 | limited in what you can pass - only octet strings. |
420 | |
528 | |
421 | Implementation: |
529 | Implementation: |
422 | |
530 | |
423 | ( |
531 | ( |
424 | sub { pack "(w/a*)*", @_ }, |
532 | sub { pack "(w/a*)*", @_ }, |
425 | sub { unpack "(w/a*)*", shift } |
533 | sub { unpack "(w/a*)*", shift } |
426 | ) |
534 | ) |
427 | |
535 | |
428 | =item json - C<$AnyEvent::Fork::RPC::JSON_SERIALISER> |
536 | =item C<$AnyEvent::Fork::RPC::CBOR_XS_SERIALISER> - uses L<CBOR::XS> |
|
|
537 | |
|
|
538 | This serialiser creates CBOR::XS arrays - you have to make sure the |
|
|
539 | L<CBOR::XS> module is installed for this serialiser to work. It can be |
|
|
540 | beneficial for sharing when you preload the L<CBOR::XS> module in a template |
|
|
541 | process. |
|
|
542 | |
|
|
543 | L<CBOR::XS> is about as fast as the octet string serialiser, but supports |
|
|
544 | complex data structures (similar to JSON) and is faster than any of the |
|
|
545 | other serialisers. If you have the L<CBOR::XS> module available, it's the |
|
|
546 | best choice. |
|
|
547 | |
|
|
548 | The encoder enables C<allow_sharing> (so this serialisation method can |
|
|
549 | encode cyclic and self-referencing data structures). |
|
|
550 | |
|
|
551 | Implementation: |
|
|
552 | |
|
|
553 | use CBOR::XS (); |
|
|
554 | ( |
|
|
555 | sub { CBOR::XS::encode_cbor_sharing \@_ }, |
|
|
556 | sub { @{ CBOR::XS::decode_cbor shift } } |
|
|
557 | ) |
|
|
558 | |
|
|
559 | =item C<$AnyEvent::Fork::RPC::JSON_SERIALISER> - uses L<JSON::XS> or L<JSON> |
429 | |
560 | |
430 | This serialiser creates JSON arrays - you have to make sure the L<JSON> |
561 | This serialiser creates JSON arrays - you have to make sure the L<JSON> |
431 | module is installed for this serialiser to work. It can be beneficial for |
562 | module is installed for this serialiser to work. It can be beneficial for |
432 | sharing when you preload the L<JSON> module in a template process. |
563 | sharing when you preload the L<JSON> module in a template process. |
433 | |
564 | |
… | |
… | |
441 | ( |
572 | ( |
442 | sub { JSON::encode_json \@_ }, |
573 | sub { JSON::encode_json \@_ }, |
443 | sub { @{ JSON::decode_json shift } } |
574 | sub { @{ JSON::decode_json shift } } |
444 | ) |
575 | ) |
445 | |
576 | |
446 | =item storable - C<$AnyEvent::Fork::RPC::STORABLE_SERIALISER> |
577 | =item C<$AnyEvent::Fork::RPC::STORABLE_SERIALISER> - L<Storable> |
447 | |
578 | |
448 | This serialiser uses L<Storable>, which means it has high chance of |
579 | This serialiser uses L<Storable>, which means it has high chance of |
449 | serialising just about anything you throw at it, at the cost of having |
580 | serialising just about anything you throw at it, at the cost of having |
450 | very high overhead per operation. It also comes with perl. |
581 | very high overhead per operation. It also comes with perl. It should be |
|
|
582 | used when you need to serialise complex data structures. |
451 | |
583 | |
452 | Implementation: |
584 | Implementation: |
453 | |
585 | |
454 | use Storable (); |
586 | use Storable (); |
455 | ( |
587 | ( |
456 | sub { Storable::freeze \@_ }, |
588 | sub { Storable::freeze \@_ }, |
457 | sub { @{ Storable::thaw shift } } |
589 | sub { @{ Storable::thaw shift } } |
458 | ) |
590 | ) |
459 | |
591 | |
460 | =item portable storable - C<$AnyEvent::Fork::RPC::NSTORABLE_SERIALISER> |
592 | =item C<$AnyEvent::Fork::RPC::NSTORABLE_SERIALISER> - portable Storable |
461 | |
593 | |
462 | This serialiser also uses L<Storable>, but uses it's "network" format |
594 | This serialiser also uses L<Storable>, but uses it's "network" format |
463 | to serialise data, which makes it possible to talk to incompatible |
595 | to serialise data, which makes it possible to talk to different |
464 | perl versions (for example, when talking to a process created with |
596 | perl binaries (for example, when talking to a process created with |
465 | L<AnyEvent::Fork::Remote>). |
597 | L<AnyEvent::Fork::Remote>). |
466 | |
598 | |
467 | Implementation: |
599 | Implementation: |
468 | |
600 | |
469 | use Storable (); |
601 | use Storable (); |
… | |
… | |
480 | examples. |
612 | examples. |
481 | |
613 | |
482 | =cut |
614 | =cut |
483 | |
615 | |
484 | our $STRING_SERIALISER = '(sub { pack "(w/a*)*", @_ }, sub { unpack "(w/a*)*", shift })'; |
616 | our $STRING_SERIALISER = '(sub { pack "(w/a*)*", @_ }, sub { unpack "(w/a*)*", shift })'; |
|
|
617 | our $CBOR_XS_SERIALISER = 'use CBOR::XS (); (sub { CBOR::XS::encode_cbor_sharing \@_ }, sub { @{ CBOR::XS::decode_cbor shift } })'; |
485 | our $JSON_SERIALISER = 'use JSON (); (sub { JSON::encode_json \@_ }, sub { @{ JSON::decode_json shift } })'; |
618 | our $JSON_SERIALISER = 'use JSON (); (sub { JSON::encode_json \@_ }, sub { @{ JSON::decode_json shift } })'; |
486 | our $STORABLE_SERIALISER = 'use Storable (); (sub { Storable::freeze \@_ }, sub { @{ Storable::thaw shift } })'; |
619 | our $STORABLE_SERIALISER = 'use Storable (); (sub { Storable::freeze \@_ }, sub { @{ Storable::thaw shift } })'; |
487 | our $NSTORABLE_SERIALISER = 'use Storable (); (sub { Storable::nfreeze \@_ }, sub { @{ Storable::thaw shift } })'; |
620 | our $NSTORABLE_SERIALISER = 'use Storable (); (sub { Storable::nfreeze \@_ }, sub { @{ Storable::thaw shift } })'; |
488 | |
621 | |
489 | sub run { |
622 | sub run { |
490 | my ($self, $function, %arg) = @_; |
623 | my ($self, $function, %arg) = @_; |
… | |
… | |
495 | my $on_destroy = delete $arg{on_destroy}; |
628 | my $on_destroy = delete $arg{on_destroy}; |
496 | |
629 | |
497 | # default for on_error is to on_event, if specified |
630 | # default for on_error is to on_event, if specified |
498 | $on_error ||= $on_event |
631 | $on_error ||= $on_event |
499 | ? sub { $on_event->(error => shift) } |
632 | ? sub { $on_event->(error => shift) } |
500 | : sub { die "AnyEvent::Fork::RPC: uncaught error: $_[0].\n" }; |
633 | : sub { AE::log die => "AnyEvent::Fork::RPC: uncaught error: $_[0]." }; |
501 | |
634 | |
502 | # default for on_event is to raise an error |
635 | # default for on_event is to raise an error |
503 | $on_event ||= sub { $on_error->("event received, but no on_event handler") }; |
636 | $on_event ||= sub { $on_error->("event received, but no on_event handler") }; |
504 | |
637 | |
505 | my ($f, $t) = eval $serialiser; die $@ if $@; |
638 | my ($f, $t) = eval $serialiser; die $@ if $@; |
… | |
… | |
526 | }; |
659 | }; |
527 | |
660 | |
528 | my $module = "AnyEvent::Fork::RPC::" . ($arg{async} ? "Async" : "Sync"); |
661 | my $module = "AnyEvent::Fork::RPC::" . ($arg{async} ? "Async" : "Sync"); |
529 | |
662 | |
530 | $self->require ($module) |
663 | $self->require ($module) |
531 | ->send_arg ($function, $arg{init}, $serialiser) |
664 | ->send_arg ($function, $arg{init}, $serialiser, $arg{done} || "$module\::do_exit") |
532 | ->run ("$module\::run", sub { |
665 | ->run ("$module\::run", sub { |
533 | $fh = shift; |
666 | $fh = shift; |
534 | |
667 | |
535 | my ($id, $len); |
668 | my ($id, $len); |
536 | $rw = AE::io $fh, 0, sub { |
669 | $rw = AE::io $fh, 0, sub { |
… | |
… | |
652 | See the examples section earlier in this document for some actual |
785 | See the examples section earlier in this document for some actual |
653 | examples. |
786 | examples. |
654 | |
787 | |
655 | =back |
788 | =back |
656 | |
789 | |
|
|
790 | =head2 PROCESS EXIT |
|
|
791 | |
|
|
792 | If and when the child process exits depends on the backend and |
|
|
793 | configuration. Apart from explicit exits (e.g. by calling C<exit>) or |
|
|
794 | runtime conditions (uncaught exceptions, signals etc.), the backends exit |
|
|
795 | under these conditions: |
|
|
796 | |
|
|
797 | =over 4 |
|
|
798 | |
|
|
799 | =item Synchronous Backend |
|
|
800 | |
|
|
801 | The synchronous backend is very simple: when the process waits for another |
|
|
802 | request to arrive and the writing side (usually in the parent) is closed, |
|
|
803 | it will exit normally, i.e. as if your main program reached the end of the |
|
|
804 | file. |
|
|
805 | |
|
|
806 | That means that if your parent process exits, the RPC process will usually |
|
|
807 | exit as well, either because it is idle anyway, or because it executes a |
|
|
808 | request. In the latter case, you will likely get an error when the RPc |
|
|
809 | process tries to send the results to the parent (because agruably, you |
|
|
810 | shouldn't exit your parent while there are still outstanding requests). |
|
|
811 | |
|
|
812 | The process is usually quiescent when it happens, so it should rarely be a |
|
|
813 | problem, and C<END> handlers can be used to clean up. |
|
|
814 | |
|
|
815 | =item Asynchronous Backend |
|
|
816 | |
|
|
817 | For the asynchronous backend, things are more complicated: Whenever it |
|
|
818 | listens for another request by the parent, it might detect that the socket |
|
|
819 | was closed (e.g. because the parent exited). It will sotp listening for |
|
|
820 | new requests and instead try to write out any remaining data (if any) or |
|
|
821 | simply check whether the socket can be written to. After this, the RPC |
|
|
822 | process is effectively done - no new requests are incoming, no outstanding |
|
|
823 | request data can be written back. |
|
|
824 | |
|
|
825 | Since chances are high that there are event watchers that the RPC server |
|
|
826 | knows nothing about (why else would one use the async backend if not for |
|
|
827 | the ability to register watchers?), the event loop would often happily |
|
|
828 | continue. |
|
|
829 | |
|
|
830 | This is why the asynchronous backend explicitly calls C<CORE::exit> when |
|
|
831 | it is done (under other circumstances, such as when there is an I/O error |
|
|
832 | and there is outstanding data to write, it will log a fatal message via |
|
|
833 | L<AnyEvent::Log>, also causing the program to exit). |
|
|
834 | |
|
|
835 | You can override this by specifying a function name to call via the C<done> |
|
|
836 | parameter instead. |
|
|
837 | |
|
|
838 | =back |
|
|
839 | |
657 | =head1 ADVANCED TOPICS |
840 | =head1 ADVANCED TOPICS |
658 | |
841 | |
659 | =head2 Choosing a backend |
842 | =head2 Choosing a backend |
660 | |
843 | |
661 | So how do you decide which backend to use? Well, that's your problem to |
844 | So how do you decide which backend to use? Well, that's your problem to |
… | |
… | |
714 | are queued and the jobs are slow, they will all run concurrently. The |
897 | are queued and the jobs are slow, they will all run concurrently. The |
715 | child must implement some queueing/limiting mechanism if this causes |
898 | child must implement some queueing/limiting mechanism if this causes |
716 | problems. Alternatively, the parent could limit the amount of rpc calls |
899 | problems. Alternatively, the parent could limit the amount of rpc calls |
717 | that are outstanding. |
900 | that are outstanding. |
718 | |
901 | |
719 | Blocking use of condvars is not supported. |
902 | Blocking use of condvars is not supported (in the main thread, outside of |
|
|
903 | e.g. L<Coro> threads). |
720 | |
904 | |
721 | Using event-based modules such as L<IO::AIO>, L<Gtk2>, L<Tk> and so on is |
905 | Using event-based modules such as L<IO::AIO>, L<Gtk2>, L<Tk> and so on is |
722 | easy. |
906 | easy. |
723 | |
907 | |
724 | =back |
908 | =back |
… | |
… | |
790 | gory details. |
974 | gory details. |
791 | |
975 | |
792 | =head1 EXCEPTIONS |
976 | =head1 EXCEPTIONS |
793 | |
977 | |
794 | There are no provisions whatsoever for catching exceptions at this time - |
978 | There are no provisions whatsoever for catching exceptions at this time - |
795 | in the child, exeptions might kill the process, causing calls to be lost |
979 | in the child, exceptions might kill the process, causing calls to be lost |
796 | and the parent encountering a fatal error. In the parent, exceptions in |
980 | and the parent encountering a fatal error. In the parent, exceptions in |
797 | the result callback will not be caught and cause undefined behaviour. |
981 | the result callback will not be caught and cause undefined behaviour. |
798 | |
982 | |
799 | =head1 SEE ALSO |
983 | =head1 SEE ALSO |
800 | |
984 | |