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=encoding utf-8 |
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|
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=head1 NAME |
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|
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libev - a high performance full-featured event loop written in C |
6 |
|
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=head1 SYNOPSIS |
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|
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#include <ev.h> |
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|
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=head2 EXAMPLE PROGRAM |
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|
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// a single header file is required |
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#include <ev.h> |
15 |
|
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#include <stdio.h> // for puts |
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|
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// every watcher type has its own typedef'd struct |
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// with the name ev_TYPE |
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ev_io stdin_watcher; |
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ev_timer timeout_watcher; |
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|
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// all watcher callbacks have a similar signature |
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// this callback is called when data is readable on stdin |
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static void |
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stdin_cb (EV_P_ ev_io *w, int revents) |
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{ |
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puts ("stdin ready"); |
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// for one-shot events, one must manually stop the watcher |
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// with its corresponding stop function. |
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ev_io_stop (EV_A_ w); |
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|
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// this causes all nested ev_run's to stop iterating |
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ev_break (EV_A_ EVBREAK_ALL); |
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} |
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|
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// another callback, this time for a time-out |
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static void |
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timeout_cb (EV_P_ ev_timer *w, int revents) |
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{ |
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puts ("timeout"); |
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// this causes the innermost ev_run to stop iterating |
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ev_break (EV_A_ EVBREAK_ONE); |
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} |
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|
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int |
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main (void) |
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{ |
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// use the default event loop unless you have special needs |
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struct ev_loop *loop = EV_DEFAULT; |
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|
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// initialise an io watcher, then start it |
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// this one will watch for stdin to become readable |
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ev_io_init (&stdin_watcher, stdin_cb, /*STDIN_FILENO*/ 0, EV_READ); |
55 |
ev_io_start (loop, &stdin_watcher); |
56 |
|
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// initialise a timer watcher, then start it |
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// simple non-repeating 5.5 second timeout |
59 |
ev_timer_init (&timeout_watcher, timeout_cb, 5.5, 0.); |
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ev_timer_start (loop, &timeout_watcher); |
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|
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// now wait for events to arrive |
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ev_run (loop, 0); |
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|
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// break was called, so exit |
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return 0; |
67 |
} |
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|
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=head1 ABOUT THIS DOCUMENT |
70 |
|
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This document documents the libev software package. |
72 |
|
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The newest version of this document is also available as an html-formatted |
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web page you might find easier to navigate when reading it for the first |
75 |
time: L<http://pod.tst.eu/http://cvs.schmorp.de/libev/ev.pod>. |
76 |
|
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While this document tries to be as complete as possible in documenting |
78 |
libev, its usage and the rationale behind its design, it is not a tutorial |
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on event-based programming, nor will it introduce event-based programming |
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with libev. |
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|
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Familiarity with event based programming techniques in general is assumed |
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throughout this document. |
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|
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=head1 WHAT TO READ WHEN IN A HURRY |
86 |
|
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This manual tries to be very detailed, but unfortunately, this also makes |
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it very long. If you just want to know the basics of libev, I suggest |
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reading L</ANATOMY OF A WATCHER>, then the L</EXAMPLE PROGRAM> above and |
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look up the missing functions in L</GLOBAL FUNCTIONS> and the C<ev_io> and |
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C<ev_timer> sections in L</WATCHER TYPES>. |
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|
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=head1 ABOUT LIBEV |
94 |
|
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Libev is an event loop: you register interest in certain events (such as a |
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file descriptor being readable or a timeout occurring), and it will manage |
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these event sources and provide your program with events. |
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|
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To do this, it must take more or less complete control over your process |
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(or thread) by executing the I<event loop> handler, and will then |
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communicate events via a callback mechanism. |
102 |
|
103 |
You register interest in certain events by registering so-called I<event |
104 |
watchers>, which are relatively small C structures you initialise with the |
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details of the event, and then hand it over to libev by I<starting> the |
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watcher. |
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|
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=head2 FEATURES |
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|
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Libev supports C<select>, C<poll>, the Linux-specific aio and C<epoll> |
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interfaces, the BSD-specific C<kqueue> and the Solaris-specific event port |
112 |
mechanisms for file descriptor events (C<ev_io>), the Linux C<inotify> |
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interface (for C<ev_stat>), Linux eventfd/signalfd (for faster and cleaner |
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inter-thread wakeup (C<ev_async>)/signal handling (C<ev_signal>)) relative |
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timers (C<ev_timer>), absolute timers with customised rescheduling |
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(C<ev_periodic>), synchronous signals (C<ev_signal>), process status |
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change events (C<ev_child>), and event watchers dealing with the event |
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loop mechanism itself (C<ev_idle>, C<ev_embed>, C<ev_prepare> and |
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C<ev_check> watchers) as well as file watchers (C<ev_stat>) and even |
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limited support for fork events (C<ev_fork>). |
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|
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It also is quite fast (see this |
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L<benchmark|http://libev.schmorp.de/bench.html> comparing it to libevent |
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for example). |
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|
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=head2 CONVENTIONS |
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|
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Libev is very configurable. In this manual the default (and most common) |
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configuration will be described, which supports multiple event loops. For |
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more info about various configuration options please have a look at |
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B<EMBED> section in this manual. If libev was configured without support |
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for multiple event loops, then all functions taking an initial argument of |
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name C<loop> (which is always of type C<struct ev_loop *>) will not have |
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this argument. |
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|
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=head2 TIME REPRESENTATION |
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|
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Libev represents time as a single floating point number, representing |
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the (fractional) number of seconds since the (POSIX) epoch (in practice |
140 |
somewhere near the beginning of 1970, details are complicated, don't |
141 |
ask). This type is called C<ev_tstamp>, which is what you should use |
142 |
too. It usually aliases to the C<double> type in C. When you need to do |
143 |
any calculations on it, you should treat it as some floating point value. |
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|
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Unlike the name component C<stamp> might indicate, it is also used for |
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time differences (e.g. delays) throughout libev. |
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|
148 |
=head1 ERROR HANDLING |
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|
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Libev knows three classes of errors: operating system errors, usage errors |
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and internal errors (bugs). |
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|
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When libev catches an operating system error it cannot handle (for example |
154 |
a system call indicating a condition libev cannot fix), it calls the callback |
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set via C<ev_set_syserr_cb>, which is supposed to fix the problem or |
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abort. The default is to print a diagnostic message and to call C<abort |
157 |
()>. |
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|
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When libev detects a usage error such as a negative timer interval, then |
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it will print a diagnostic message and abort (via the C<assert> mechanism, |
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so C<NDEBUG> will disable this checking): these are programming errors in |
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the libev caller and need to be fixed there. |
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|
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Via the C<EV_FREQUENT> macro you can compile in and/or enable extensive |
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consistency checking code inside libev that can be used to check for |
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internal inconsistencies, suually caused by application bugs. |
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|
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Libev also has a few internal error-checking C<assert>ions. These do not |
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trigger under normal circumstances, as they indicate either a bug in libev |
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or worse. |
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|
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|
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=head1 GLOBAL FUNCTIONS |
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|
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These functions can be called anytime, even before initialising the |
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library in any way. |
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|
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=over 4 |
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|
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=item ev_tstamp ev_time () |
181 |
|
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Returns the current time as libev would use it. Please note that the |
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C<ev_now> function is usually faster and also often returns the timestamp |
184 |
you actually want to know. Also interesting is the combination of |
185 |
C<ev_now_update> and C<ev_now>. |
186 |
|
187 |
=item ev_sleep (ev_tstamp interval) |
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|
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Sleep for the given interval: The current thread will be blocked |
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until either it is interrupted or the given time interval has |
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passed (approximately - it might return a bit earlier even if not |
192 |
interrupted). Returns immediately if C<< interval <= 0 >>. |
193 |
|
194 |
Basically this is a sub-second-resolution C<sleep ()>. |
195 |
|
196 |
The range of the C<interval> is limited - libev only guarantees to work |
197 |
with sleep times of up to one day (C<< interval <= 86400 >>). |
198 |
|
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=item int ev_version_major () |
200 |
|
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=item int ev_version_minor () |
202 |
|
203 |
You can find out the major and minor ABI version numbers of the library |
204 |
you linked against by calling the functions C<ev_version_major> and |
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C<ev_version_minor>. If you want, you can compare against the global |
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symbols C<EV_VERSION_MAJOR> and C<EV_VERSION_MINOR>, which specify the |
207 |
version of the library your program was compiled against. |
208 |
|
209 |
These version numbers refer to the ABI version of the library, not the |
210 |
release version. |
211 |
|
212 |
Usually, it's a good idea to terminate if the major versions mismatch, |
213 |
as this indicates an incompatible change. Minor versions are usually |
214 |
compatible to older versions, so a larger minor version alone is usually |
215 |
not a problem. |
216 |
|
217 |
Example: Make sure we haven't accidentally been linked against the wrong |
218 |
version (note, however, that this will not detect other ABI mismatches, |
219 |
such as LFS or reentrancy). |
220 |
|
221 |
assert (("libev version mismatch", |
222 |
ev_version_major () == EV_VERSION_MAJOR |
223 |
&& ev_version_minor () >= EV_VERSION_MINOR)); |
224 |
|
225 |
=item unsigned int ev_supported_backends () |
226 |
|
227 |
Return the set of all backends (i.e. their corresponding C<EV_BACKEND_*> |
228 |
value) compiled into this binary of libev (independent of their |
229 |
availability on the system you are running on). See C<ev_default_loop> for |
230 |
a description of the set values. |
231 |
|
232 |
Example: make sure we have the epoll method, because yeah this is cool and |
233 |
a must have and can we have a torrent of it please!!!11 |
234 |
|
235 |
assert (("sorry, no epoll, no sex", |
236 |
ev_supported_backends () & EVBACKEND_EPOLL)); |
237 |
|
238 |
=item unsigned int ev_recommended_backends () |
239 |
|
240 |
Return the set of all backends compiled into this binary of libev and |
241 |
also recommended for this platform, meaning it will work for most file |
242 |
descriptor types. This set is often smaller than the one returned by |
243 |
C<ev_supported_backends>, as for example kqueue is broken on most BSDs |
244 |
and will not be auto-detected unless you explicitly request it (assuming |
245 |
you know what you are doing). This is the set of backends that libev will |
246 |
probe for if you specify no backends explicitly. |
247 |
|
248 |
=item unsigned int ev_embeddable_backends () |
249 |
|
250 |
Returns the set of backends that are embeddable in other event loops. This |
251 |
value is platform-specific but can include backends not available on the |
252 |
current system. To find which embeddable backends might be supported on |
253 |
the current system, you would need to look at C<ev_embeddable_backends () |
254 |
& ev_supported_backends ()>, likewise for recommended ones. |
255 |
|
256 |
See the description of C<ev_embed> watchers for more info. |
257 |
|
258 |
=item ev_set_allocator (void *(*cb)(void *ptr, long size) throw ()) |
259 |
|
260 |
Sets the allocation function to use (the prototype is similar - the |
261 |
semantics are identical to the C<realloc> C89/SuS/POSIX function). It is |
262 |
used to allocate and free memory (no surprises here). If it returns zero |
263 |
when memory needs to be allocated (C<size != 0>), the library might abort |
264 |
or take some potentially destructive action. |
265 |
|
266 |
Since some systems (at least OpenBSD and Darwin) fail to implement |
267 |
correct C<realloc> semantics, libev will use a wrapper around the system |
268 |
C<realloc> and C<free> functions by default. |
269 |
|
270 |
You could override this function in high-availability programs to, say, |
271 |
free some memory if it cannot allocate memory, to use a special allocator, |
272 |
or even to sleep a while and retry until some memory is available. |
273 |
|
274 |
Example: The following is the C<realloc> function that libev itself uses |
275 |
which should work with C<realloc> and C<free> functions of all kinds and |
276 |
is probably a good basis for your own implementation. |
277 |
|
278 |
static void * |
279 |
ev_realloc_emul (void *ptr, long size) EV_NOEXCEPT |
280 |
{ |
281 |
if (size) |
282 |
return realloc (ptr, size); |
283 |
|
284 |
free (ptr); |
285 |
return 0; |
286 |
} |
287 |
|
288 |
Example: Replace the libev allocator with one that waits a bit and then |
289 |
retries. |
290 |
|
291 |
static void * |
292 |
persistent_realloc (void *ptr, size_t size) |
293 |
{ |
294 |
if (!size) |
295 |
{ |
296 |
free (ptr); |
297 |
return 0; |
298 |
} |
299 |
|
300 |
for (;;) |
301 |
{ |
302 |
void *newptr = realloc (ptr, size); |
303 |
|
304 |
if (newptr) |
305 |
return newptr; |
306 |
|
307 |
sleep (60); |
308 |
} |
309 |
} |
310 |
|
311 |
... |
312 |
ev_set_allocator (persistent_realloc); |
313 |
|
314 |
=item ev_set_syserr_cb (void (*cb)(const char *msg) throw ()) |
315 |
|
316 |
Set the callback function to call on a retryable system call error (such |
317 |
as failed select, poll, epoll_wait). The message is a printable string |
318 |
indicating the system call or subsystem causing the problem. If this |
319 |
callback is set, then libev will expect it to remedy the situation, no |
320 |
matter what, when it returns. That is, libev will generally retry the |
321 |
requested operation, or, if the condition doesn't go away, do bad stuff |
322 |
(such as abort). |
323 |
|
324 |
Example: This is basically the same thing that libev does internally, too. |
325 |
|
326 |
static void |
327 |
fatal_error (const char *msg) |
328 |
{ |
329 |
perror (msg); |
330 |
abort (); |
331 |
} |
332 |
|
333 |
... |
334 |
ev_set_syserr_cb (fatal_error); |
335 |
|
336 |
=item ev_feed_signal (int signum) |
337 |
|
338 |
This function can be used to "simulate" a signal receive. It is completely |
339 |
safe to call this function at any time, from any context, including signal |
340 |
handlers or random threads. |
341 |
|
342 |
Its main use is to customise signal handling in your process, especially |
343 |
in the presence of threads. For example, you could block signals |
344 |
by default in all threads (and specifying C<EVFLAG_NOSIGMASK> when |
345 |
creating any loops), and in one thread, use C<sigwait> or any other |
346 |
mechanism to wait for signals, then "deliver" them to libev by calling |
347 |
C<ev_feed_signal>. |
348 |
|
349 |
=back |
350 |
|
351 |
=head1 FUNCTIONS CONTROLLING EVENT LOOPS |
352 |
|
353 |
An event loop is described by a C<struct ev_loop *> (the C<struct> is |
354 |
I<not> optional in this case unless libev 3 compatibility is disabled, as |
355 |
libev 3 had an C<ev_loop> function colliding with the struct name). |
356 |
|
357 |
The library knows two types of such loops, the I<default> loop, which |
358 |
supports child process events, and dynamically created event loops which |
359 |
do not. |
360 |
|
361 |
=over 4 |
362 |
|
363 |
=item struct ev_loop *ev_default_loop (unsigned int flags) |
364 |
|
365 |
This returns the "default" event loop object, which is what you should |
366 |
normally use when you just need "the event loop". Event loop objects and |
367 |
the C<flags> parameter are described in more detail in the entry for |
368 |
C<ev_loop_new>. |
369 |
|
370 |
If the default loop is already initialised then this function simply |
371 |
returns it (and ignores the flags. If that is troubling you, check |
372 |
C<ev_backend ()> afterwards). Otherwise it will create it with the given |
373 |
flags, which should almost always be C<0>, unless the caller is also the |
374 |
one calling C<ev_run> or otherwise qualifies as "the main program". |
375 |
|
376 |
If you don't know what event loop to use, use the one returned from this |
377 |
function (or via the C<EV_DEFAULT> macro). |
378 |
|
379 |
Note that this function is I<not> thread-safe, so if you want to use it |
380 |
from multiple threads, you have to employ some kind of mutex (note also |
381 |
that this case is unlikely, as loops cannot be shared easily between |
382 |
threads anyway). |
383 |
|
384 |
The default loop is the only loop that can handle C<ev_child> watchers, |
385 |
and to do this, it always registers a handler for C<SIGCHLD>. If this is |
386 |
a problem for your application you can either create a dynamic loop with |
387 |
C<ev_loop_new> which doesn't do that, or you can simply overwrite the |
388 |
C<SIGCHLD> signal handler I<after> calling C<ev_default_init>. |
389 |
|
390 |
Example: This is the most typical usage. |
391 |
|
392 |
if (!ev_default_loop (0)) |
393 |
fatal ("could not initialise libev, bad $LIBEV_FLAGS in environment?"); |
394 |
|
395 |
Example: Restrict libev to the select and poll backends, and do not allow |
396 |
environment settings to be taken into account: |
397 |
|
398 |
ev_default_loop (EVBACKEND_POLL | EVBACKEND_SELECT | EVFLAG_NOENV); |
399 |
|
400 |
=item struct ev_loop *ev_loop_new (unsigned int flags) |
401 |
|
402 |
This will create and initialise a new event loop object. If the loop |
403 |
could not be initialised, returns false. |
404 |
|
405 |
This function is thread-safe, and one common way to use libev with |
406 |
threads is indeed to create one loop per thread, and using the default |
407 |
loop in the "main" or "initial" thread. |
408 |
|
409 |
The flags argument can be used to specify special behaviour or specific |
410 |
backends to use, and is usually specified as C<0> (or C<EVFLAG_AUTO>). |
411 |
|
412 |
The following flags are supported: |
413 |
|
414 |
=over 4 |
415 |
|
416 |
=item C<EVFLAG_AUTO> |
417 |
|
418 |
The default flags value. Use this if you have no clue (it's the right |
419 |
thing, believe me). |
420 |
|
421 |
=item C<EVFLAG_NOENV> |
422 |
|
423 |
If this flag bit is or'ed into the flag value (or the program runs setuid |
424 |
or setgid) then libev will I<not> look at the environment variable |
425 |
C<LIBEV_FLAGS>. Otherwise (the default), this environment variable will |
426 |
override the flags completely if it is found in the environment. This is |
427 |
useful to try out specific backends to test their performance, to work |
428 |
around bugs, or to make libev threadsafe (accessing environment variables |
429 |
cannot be done in a threadsafe way, but usually it works if no other |
430 |
thread modifies them). |
431 |
|
432 |
=item C<EVFLAG_FORKCHECK> |
433 |
|
434 |
Instead of calling C<ev_loop_fork> manually after a fork, you can also |
435 |
make libev check for a fork in each iteration by enabling this flag. |
436 |
|
437 |
This works by calling C<getpid ()> on every iteration of the loop, |
438 |
and thus this might slow down your event loop if you do a lot of loop |
439 |
iterations and little real work, but is usually not noticeable (on my |
440 |
GNU/Linux system for example, C<getpid> is actually a simple 5-insn |
441 |
sequence without a system call and thus I<very> fast, but my GNU/Linux |
442 |
system also has C<pthread_atfork> which is even faster). (Update: glibc |
443 |
versions 2.25 apparently removed the C<getpid> optimisation again). |
444 |
|
445 |
The big advantage of this flag is that you can forget about fork (and |
446 |
forget about forgetting to tell libev about forking, although you still |
447 |
have to ignore C<SIGPIPE>) when you use this flag. |
448 |
|
449 |
This flag setting cannot be overridden or specified in the C<LIBEV_FLAGS> |
450 |
environment variable. |
451 |
|
452 |
=item C<EVFLAG_NOINOTIFY> |
453 |
|
454 |
When this flag is specified, then libev will not attempt to use the |
455 |
I<inotify> API for its C<ev_stat> watchers. Apart from debugging and |
456 |
testing, this flag can be useful to conserve inotify file descriptors, as |
457 |
otherwise each loop using C<ev_stat> watchers consumes one inotify handle. |
458 |
|
459 |
=item C<EVFLAG_SIGNALFD> |
460 |
|
461 |
When this flag is specified, then libev will attempt to use the |
462 |
I<signalfd> API for its C<ev_signal> (and C<ev_child>) watchers. This API |
463 |
delivers signals synchronously, which makes it both faster and might make |
464 |
it possible to get the queued signal data. It can also simplify signal |
465 |
handling with threads, as long as you properly block signals in your |
466 |
threads that are not interested in handling them. |
467 |
|
468 |
Signalfd will not be used by default as this changes your signal mask, and |
469 |
there are a lot of shoddy libraries and programs (glib's threadpool for |
470 |
example) that can't properly initialise their signal masks. |
471 |
|
472 |
=item C<EVFLAG_NOSIGMASK> |
473 |
|
474 |
When this flag is specified, then libev will avoid to modify the signal |
475 |
mask. Specifically, this means you have to make sure signals are unblocked |
476 |
when you want to receive them. |
477 |
|
478 |
This behaviour is useful when you want to do your own signal handling, or |
479 |
want to handle signals only in specific threads and want to avoid libev |
480 |
unblocking the signals. |
481 |
|
482 |
It's also required by POSIX in a threaded program, as libev calls |
483 |
C<sigprocmask>, whose behaviour is officially unspecified. |
484 |
|
485 |
=item C<EVFLAG_NOTIMERFD> |
486 |
|
487 |
When this flag is specified, the libev will avoid using a C<timerfd> to |
488 |
detect time jumps. It will still be able to detect time jumps, but takes |
489 |
longer and has a lower accuracy in doing so, but saves a file descriptor |
490 |
per loop. |
491 |
|
492 |
The current implementation only tries to use a C<timerfd> when the first |
493 |
C<ev_periodic> watcher is started and falls back on other methods if it |
494 |
cannot be created, but this behaviour might change in the future. |
495 |
|
496 |
=item C<EVBACKEND_SELECT> (value 1, portable select backend) |
497 |
|
498 |
This is your standard select(2) backend. Not I<completely> standard, as |
499 |
libev tries to roll its own fd_set with no limits on the number of fds, |
500 |
but if that fails, expect a fairly low limit on the number of fds when |
501 |
using this backend. It doesn't scale too well (O(highest_fd)), but its |
502 |
usually the fastest backend for a low number of (low-numbered :) fds. |
503 |
|
504 |
To get good performance out of this backend you need a high amount of |
505 |
parallelism (most of the file descriptors should be busy). If you are |
506 |
writing a server, you should C<accept ()> in a loop to accept as many |
507 |
connections as possible during one iteration. You might also want to have |
508 |
a look at C<ev_set_io_collect_interval ()> to increase the amount of |
509 |
readiness notifications you get per iteration. |
510 |
|
511 |
This backend maps C<EV_READ> to the C<readfds> set and C<EV_WRITE> to the |
512 |
C<writefds> set (and to work around Microsoft Windows bugs, also onto the |
513 |
C<exceptfds> set on that platform). |
514 |
|
515 |
=item C<EVBACKEND_POLL> (value 2, poll backend, available everywhere except on windows) |
516 |
|
517 |
And this is your standard poll(2) backend. It's more complicated |
518 |
than select, but handles sparse fds better and has no artificial |
519 |
limit on the number of fds you can use (except it will slow down |
520 |
considerably with a lot of inactive fds). It scales similarly to select, |
521 |
i.e. O(total_fds). See the entry for C<EVBACKEND_SELECT>, above, for |
522 |
performance tips. |
523 |
|
524 |
This backend maps C<EV_READ> to C<POLLIN | POLLERR | POLLHUP>, and |
525 |
C<EV_WRITE> to C<POLLOUT | POLLERR | POLLHUP>. |
526 |
|
527 |
=item C<EVBACKEND_EPOLL> (value 4, Linux) |
528 |
|
529 |
Use the Linux-specific epoll(7) interface (for both pre- and post-2.6.9 |
530 |
kernels). |
531 |
|
532 |
For few fds, this backend is a bit little slower than poll and select, but |
533 |
it scales phenomenally better. While poll and select usually scale like |
534 |
O(total_fds) where total_fds is the total number of fds (or the highest |
535 |
fd), epoll scales either O(1) or O(active_fds). |
536 |
|
537 |
The epoll mechanism deserves honorable mention as the most misdesigned |
538 |
of the more advanced event mechanisms: mere annoyances include silently |
539 |
dropping file descriptors, requiring a system call per change per file |
540 |
descriptor (and unnecessary guessing of parameters), problems with dup, |
541 |
returning before the timeout value, resulting in additional iterations |
542 |
(and only giving 5ms accuracy while select on the same platform gives |
543 |
0.1ms) and so on. The biggest issue is fork races, however - if a program |
544 |
forks then I<both> parent and child process have to recreate the epoll |
545 |
set, which can take considerable time (one syscall per file descriptor) |
546 |
and is of course hard to detect. |
547 |
|
548 |
Epoll is also notoriously buggy - embedding epoll fds I<should> work, |
549 |
but of course I<doesn't>, and epoll just loves to report events for |
550 |
totally I<different> file descriptors (even already closed ones, so |
551 |
one cannot even remove them from the set) than registered in the set |
552 |
(especially on SMP systems). Libev tries to counter these spurious |
553 |
notifications by employing an additional generation counter and comparing |
554 |
that against the events to filter out spurious ones, recreating the set |
555 |
when required. Epoll also erroneously rounds down timeouts, but gives you |
556 |
no way to know when and by how much, so sometimes you have to busy-wait |
557 |
because epoll returns immediately despite a nonzero timeout. And last |
558 |
not least, it also refuses to work with some file descriptors which work |
559 |
perfectly fine with C<select> (files, many character devices...). |
560 |
|
561 |
Epoll is truly the train wreck among event poll mechanisms, a frankenpoll, |
562 |
cobbled together in a hurry, no thought to design or interaction with |
563 |
others. Oh, the pain, will it ever stop... |
564 |
|
565 |
While stopping, setting and starting an I/O watcher in the same iteration |
566 |
will result in some caching, there is still a system call per such |
567 |
incident (because the same I<file descriptor> could point to a different |
568 |
I<file description> now), so its best to avoid that. Also, C<dup ()>'ed |
569 |
file descriptors might not work very well if you register events for both |
570 |
file descriptors. |
571 |
|
572 |
Best performance from this backend is achieved by not unregistering all |
573 |
watchers for a file descriptor until it has been closed, if possible, |
574 |
i.e. keep at least one watcher active per fd at all times. Stopping and |
575 |
starting a watcher (without re-setting it) also usually doesn't cause |
576 |
extra overhead. A fork can both result in spurious notifications as well |
577 |
as in libev having to destroy and recreate the epoll object, which can |
578 |
take considerable time and thus should be avoided. |
579 |
|
580 |
All this means that, in practice, C<EVBACKEND_SELECT> can be as fast or |
581 |
faster than epoll for maybe up to a hundred file descriptors, depending on |
582 |
the usage. So sad. |
583 |
|
584 |
While nominally embeddable in other event loops, this feature is broken in |
585 |
a lot of kernel revisions, but probably(!) works in current versions. |
586 |
|
587 |
This backend maps C<EV_READ> and C<EV_WRITE> in the same way as |
588 |
C<EVBACKEND_POLL>. |
589 |
|
590 |
=item C<EVBACKEND_LINUXAIO> (value 64, Linux) |
591 |
|
592 |
Use the Linux-specific Linux AIO (I<not> C<< aio(7) >> but C<< |
593 |
io_submit(2) >>) event interface available in post-4.18 kernels (but libev |
594 |
only tries to use it in 4.19+). |
595 |
|
596 |
This is another Linux train wreck of an event interface. |
597 |
|
598 |
If this backend works for you (as of this writing, it was very |
599 |
experimental), it is the best event interface available on Linux and might |
600 |
be well worth enabling it - if it isn't available in your kernel this will |
601 |
be detected and this backend will be skipped. |
602 |
|
603 |
This backend can batch oneshot requests and supports a user-space ring |
604 |
buffer to receive events. It also doesn't suffer from most of the design |
605 |
problems of epoll (such as not being able to remove event sources from |
606 |
the epoll set), and generally sounds too good to be true. Because, this |
607 |
being the Linux kernel, of course it suffers from a whole new set of |
608 |
limitations, forcing you to fall back to epoll, inheriting all its design |
609 |
issues. |
610 |
|
611 |
For one, it is not easily embeddable (but probably could be done using |
612 |
an event fd at some extra overhead). It also is subject to a system wide |
613 |
limit that can be configured in F</proc/sys/fs/aio-max-nr>. If no AIO |
614 |
requests are left, this backend will be skipped during initialisation, and |
615 |
will switch to epoll when the loop is active. |
616 |
|
617 |
Most problematic in practice, however, is that not all file descriptors |
618 |
work with it. For example, in Linux 5.1, TCP sockets, pipes, event fds, |
619 |
files, F</dev/null> and many others are supported, but ttys do not work |
620 |
properly (a known bug that the kernel developers don't care about, see |
621 |
L<https://lore.kernel.org/patchwork/patch/1047453/>), so this is not |
622 |
(yet?) a generic event polling interface. |
623 |
|
624 |
Overall, it seems the Linux developers just don't want it to have a |
625 |
generic event handling mechanism other than C<select> or C<poll>. |
626 |
|
627 |
To work around all these problem, the current version of libev uses its |
628 |
epoll backend as a fallback for file descriptor types that do not work. Or |
629 |
falls back completely to epoll if the kernel acts up. |
630 |
|
631 |
This backend maps C<EV_READ> and C<EV_WRITE> in the same way as |
632 |
C<EVBACKEND_POLL>. |
633 |
|
634 |
=item C<EVBACKEND_KQUEUE> (value 8, most BSD clones) |
635 |
|
636 |
Kqueue deserves special mention, as at the time this backend was |
637 |
implemented, it was broken on all BSDs except NetBSD (usually it doesn't |
638 |
work reliably with anything but sockets and pipes, except on Darwin, |
639 |
where of course it's completely useless). Unlike epoll, however, whose |
640 |
brokenness is by design, these kqueue bugs can be (and mostly have been) |
641 |
fixed without API changes to existing programs. For this reason it's not |
642 |
being "auto-detected" on all platforms unless you explicitly specify it |
643 |
in the flags (i.e. using C<EVBACKEND_KQUEUE>) or libev was compiled on a |
644 |
known-to-be-good (-enough) system like NetBSD. |
645 |
|
646 |
You still can embed kqueue into a normal poll or select backend and use it |
647 |
only for sockets (after having made sure that sockets work with kqueue on |
648 |
the target platform). See C<ev_embed> watchers for more info. |
649 |
|
650 |
It scales in the same way as the epoll backend, but the interface to the |
651 |
kernel is more efficient (which says nothing about its actual speed, of |
652 |
course). While stopping, setting and starting an I/O watcher does never |
653 |
cause an extra system call as with C<EVBACKEND_EPOLL>, it still adds up to |
654 |
two event changes per incident. Support for C<fork ()> is very bad (you |
655 |
might have to leak fds on fork, but it's more sane than epoll) and it |
656 |
drops fds silently in similarly hard-to-detect cases. |
657 |
|
658 |
This backend usually performs well under most conditions. |
659 |
|
660 |
While nominally embeddable in other event loops, this doesn't work |
661 |
everywhere, so you might need to test for this. And since it is broken |
662 |
almost everywhere, you should only use it when you have a lot of sockets |
663 |
(for which it usually works), by embedding it into another event loop |
664 |
(e.g. C<EVBACKEND_SELECT> or C<EVBACKEND_POLL> (but C<poll> is of course |
665 |
also broken on OS X)) and, did I mention it, using it only for sockets. |
666 |
|
667 |
This backend maps C<EV_READ> into an C<EVFILT_READ> kevent with |
668 |
C<NOTE_EOF>, and C<EV_WRITE> into an C<EVFILT_WRITE> kevent with |
669 |
C<NOTE_EOF>. |
670 |
|
671 |
=item C<EVBACKEND_DEVPOLL> (value 16, Solaris 8) |
672 |
|
673 |
This is not implemented yet (and might never be, unless you send me an |
674 |
implementation). According to reports, C</dev/poll> only supports sockets |
675 |
and is not embeddable, which would limit the usefulness of this backend |
676 |
immensely. |
677 |
|
678 |
=item C<EVBACKEND_PORT> (value 32, Solaris 10) |
679 |
|
680 |
This uses the Solaris 10 event port mechanism. As with everything on Solaris, |
681 |
it's really slow, but it still scales very well (O(active_fds)). |
682 |
|
683 |
While this backend scales well, it requires one system call per active |
684 |
file descriptor per loop iteration. For small and medium numbers of file |
685 |
descriptors a "slow" C<EVBACKEND_SELECT> or C<EVBACKEND_POLL> backend |
686 |
might perform better. |
687 |
|
688 |
On the positive side, this backend actually performed fully to |
689 |
specification in all tests and is fully embeddable, which is a rare feat |
690 |
among the OS-specific backends (I vastly prefer correctness over speed |
691 |
hacks). |
692 |
|
693 |
On the negative side, the interface is I<bizarre> - so bizarre that |
694 |
even sun itself gets it wrong in their code examples: The event polling |
695 |
function sometimes returns events to the caller even though an error |
696 |
occurred, but with no indication whether it has done so or not (yes, it's |
697 |
even documented that way) - deadly for edge-triggered interfaces where you |
698 |
absolutely have to know whether an event occurred or not because you have |
699 |
to re-arm the watcher. |
700 |
|
701 |
Fortunately libev seems to be able to work around these idiocies. |
702 |
|
703 |
This backend maps C<EV_READ> and C<EV_WRITE> in the same way as |
704 |
C<EVBACKEND_POLL>. |
705 |
|
706 |
=item C<EVBACKEND_ALL> |
707 |
|
708 |
Try all backends (even potentially broken ones that wouldn't be tried |
709 |
with C<EVFLAG_AUTO>). Since this is a mask, you can do stuff such as |
710 |
C<EVBACKEND_ALL & ~EVBACKEND_KQUEUE>. |
711 |
|
712 |
It is definitely not recommended to use this flag, use whatever |
713 |
C<ev_recommended_backends ()> returns, or simply do not specify a backend |
714 |
at all. |
715 |
|
716 |
=item C<EVBACKEND_MASK> |
717 |
|
718 |
Not a backend at all, but a mask to select all backend bits from a |
719 |
C<flags> value, in case you want to mask out any backends from a flags |
720 |
value (e.g. when modifying the C<LIBEV_FLAGS> environment variable). |
721 |
|
722 |
=back |
723 |
|
724 |
If one or more of the backend flags are or'ed into the flags value, |
725 |
then only these backends will be tried (in the reverse order as listed |
726 |
here). If none are specified, all backends in C<ev_recommended_backends |
727 |
()> will be tried. |
728 |
|
729 |
Example: Try to create a event loop that uses epoll and nothing else. |
730 |
|
731 |
struct ev_loop *epoller = ev_loop_new (EVBACKEND_EPOLL | EVFLAG_NOENV); |
732 |
if (!epoller) |
733 |
fatal ("no epoll found here, maybe it hides under your chair"); |
734 |
|
735 |
Example: Use whatever libev has to offer, but make sure that kqueue is |
736 |
used if available. |
737 |
|
738 |
struct ev_loop *loop = ev_loop_new (ev_recommended_backends () | EVBACKEND_KQUEUE); |
739 |
|
740 |
Example: Similarly, on linux, you mgiht want to take advantage of the |
741 |
linux aio backend if possible, but fall back to something else if that |
742 |
isn't available. |
743 |
|
744 |
struct ev_loop *loop = ev_loop_new (ev_recommended_backends () | EVBACKEND_LINUXAIO); |
745 |
|
746 |
=item ev_loop_destroy (loop) |
747 |
|
748 |
Destroys an event loop object (frees all memory and kernel state |
749 |
etc.). None of the active event watchers will be stopped in the normal |
750 |
sense, so e.g. C<ev_is_active> might still return true. It is your |
751 |
responsibility to either stop all watchers cleanly yourself I<before> |
752 |
calling this function, or cope with the fact afterwards (which is usually |
753 |
the easiest thing, you can just ignore the watchers and/or C<free ()> them |
754 |
for example). |
755 |
|
756 |
Note that certain global state, such as signal state (and installed signal |
757 |
handlers), will not be freed by this function, and related watchers (such |
758 |
as signal and child watchers) would need to be stopped manually. |
759 |
|
760 |
This function is normally used on loop objects allocated by |
761 |
C<ev_loop_new>, but it can also be used on the default loop returned by |
762 |
C<ev_default_loop>, in which case it is not thread-safe. |
763 |
|
764 |
Note that it is not advisable to call this function on the default loop |
765 |
except in the rare occasion where you really need to free its resources. |
766 |
If you need dynamically allocated loops it is better to use C<ev_loop_new> |
767 |
and C<ev_loop_destroy>. |
768 |
|
769 |
=item ev_loop_fork (loop) |
770 |
|
771 |
This function sets a flag that causes subsequent C<ev_run> iterations |
772 |
to reinitialise the kernel state for backends that have one. Despite |
773 |
the name, you can call it anytime you are allowed to start or stop |
774 |
watchers (except inside an C<ev_prepare> callback), but it makes most |
775 |
sense after forking, in the child process. You I<must> call it (or use |
776 |
C<EVFLAG_FORKCHECK>) in the child before resuming or calling C<ev_run>. |
777 |
|
778 |
In addition, if you want to reuse a loop (via this function or |
779 |
C<EVFLAG_FORKCHECK>), you I<also> have to ignore C<SIGPIPE>. |
780 |
|
781 |
Again, you I<have> to call it on I<any> loop that you want to re-use after |
782 |
a fork, I<even if you do not plan to use the loop in the parent>. This is |
783 |
because some kernel interfaces *cough* I<kqueue> *cough* do funny things |
784 |
during fork. |
785 |
|
786 |
On the other hand, you only need to call this function in the child |
787 |
process if and only if you want to use the event loop in the child. If |
788 |
you just fork+exec or create a new loop in the child, you don't have to |
789 |
call it at all (in fact, C<epoll> is so badly broken that it makes a |
790 |
difference, but libev will usually detect this case on its own and do a |
791 |
costly reset of the backend). |
792 |
|
793 |
The function itself is quite fast and it's usually not a problem to call |
794 |
it just in case after a fork. |
795 |
|
796 |
Example: Automate calling C<ev_loop_fork> on the default loop when |
797 |
using pthreads. |
798 |
|
799 |
static void |
800 |
post_fork_child (void) |
801 |
{ |
802 |
ev_loop_fork (EV_DEFAULT); |
803 |
} |
804 |
|
805 |
... |
806 |
pthread_atfork (0, 0, post_fork_child); |
807 |
|
808 |
=item int ev_is_default_loop (loop) |
809 |
|
810 |
Returns true when the given loop is, in fact, the default loop, and false |
811 |
otherwise. |
812 |
|
813 |
=item unsigned int ev_iteration (loop) |
814 |
|
815 |
Returns the current iteration count for the event loop, which is identical |
816 |
to the number of times libev did poll for new events. It starts at C<0> |
817 |
and happily wraps around with enough iterations. |
818 |
|
819 |
This value can sometimes be useful as a generation counter of sorts (it |
820 |
"ticks" the number of loop iterations), as it roughly corresponds with |
821 |
C<ev_prepare> and C<ev_check> calls - and is incremented between the |
822 |
prepare and check phases. |
823 |
|
824 |
=item unsigned int ev_depth (loop) |
825 |
|
826 |
Returns the number of times C<ev_run> was entered minus the number of |
827 |
times C<ev_run> was exited normally, in other words, the recursion depth. |
828 |
|
829 |
Outside C<ev_run>, this number is zero. In a callback, this number is |
830 |
C<1>, unless C<ev_run> was invoked recursively (or from another thread), |
831 |
in which case it is higher. |
832 |
|
833 |
Leaving C<ev_run> abnormally (setjmp/longjmp, cancelling the thread, |
834 |
throwing an exception etc.), doesn't count as "exit" - consider this |
835 |
as a hint to avoid such ungentleman-like behaviour unless it's really |
836 |
convenient, in which case it is fully supported. |
837 |
|
838 |
=item unsigned int ev_backend (loop) |
839 |
|
840 |
Returns one of the C<EVBACKEND_*> flags indicating the event backend in |
841 |
use. |
842 |
|
843 |
=item ev_tstamp ev_now (loop) |
844 |
|
845 |
Returns the current "event loop time", which is the time the event loop |
846 |
received events and started processing them. This timestamp does not |
847 |
change as long as callbacks are being processed, and this is also the base |
848 |
time used for relative timers. You can treat it as the timestamp of the |
849 |
event occurring (or more correctly, libev finding out about it). |
850 |
|
851 |
=item ev_now_update (loop) |
852 |
|
853 |
Establishes the current time by querying the kernel, updating the time |
854 |
returned by C<ev_now ()> in the progress. This is a costly operation and |
855 |
is usually done automatically within C<ev_run ()>. |
856 |
|
857 |
This function is rarely useful, but when some event callback runs for a |
858 |
very long time without entering the event loop, updating libev's idea of |
859 |
the current time is a good idea. |
860 |
|
861 |
See also L</The special problem of time updates> in the C<ev_timer> section. |
862 |
|
863 |
=item ev_suspend (loop) |
864 |
|
865 |
=item ev_resume (loop) |
866 |
|
867 |
These two functions suspend and resume an event loop, for use when the |
868 |
loop is not used for a while and timeouts should not be processed. |
869 |
|
870 |
A typical use case would be an interactive program such as a game: When |
871 |
the user presses C<^Z> to suspend the game and resumes it an hour later it |
872 |
would be best to handle timeouts as if no time had actually passed while |
873 |
the program was suspended. This can be achieved by calling C<ev_suspend> |
874 |
in your C<SIGTSTP> handler, sending yourself a C<SIGSTOP> and calling |
875 |
C<ev_resume> directly afterwards to resume timer processing. |
876 |
|
877 |
Effectively, all C<ev_timer> watchers will be delayed by the time spend |
878 |
between C<ev_suspend> and C<ev_resume>, and all C<ev_periodic> watchers |
879 |
will be rescheduled (that is, they will lose any events that would have |
880 |
occurred while suspended). |
881 |
|
882 |
After calling C<ev_suspend> you B<must not> call I<any> function on the |
883 |
given loop other than C<ev_resume>, and you B<must not> call C<ev_resume> |
884 |
without a previous call to C<ev_suspend>. |
885 |
|
886 |
Calling C<ev_suspend>/C<ev_resume> has the side effect of updating the |
887 |
event loop time (see C<ev_now_update>). |
888 |
|
889 |
=item bool ev_run (loop, int flags) |
890 |
|
891 |
Finally, this is it, the event handler. This function usually is called |
892 |
after you have initialised all your watchers and you want to start |
893 |
handling events. It will ask the operating system for any new events, call |
894 |
the watcher callbacks, and then repeat the whole process indefinitely: This |
895 |
is why event loops are called I<loops>. |
896 |
|
897 |
If the flags argument is specified as C<0>, it will keep handling events |
898 |
until either no event watchers are active anymore or C<ev_break> was |
899 |
called. |
900 |
|
901 |
The return value is false if there are no more active watchers (which |
902 |
usually means "all jobs done" or "deadlock"), and true in all other cases |
903 |
(which usually means " you should call C<ev_run> again"). |
904 |
|
905 |
Please note that an explicit C<ev_break> is usually better than |
906 |
relying on all watchers to be stopped when deciding when a program has |
907 |
finished (especially in interactive programs), but having a program |
908 |
that automatically loops as long as it has to and no longer by virtue |
909 |
of relying on its watchers stopping correctly, that is truly a thing of |
910 |
beauty. |
911 |
|
912 |
This function is I<mostly> exception-safe - you can break out of a |
913 |
C<ev_run> call by calling C<longjmp> in a callback, throwing a C++ |
914 |
exception and so on. This does not decrement the C<ev_depth> value, nor |
915 |
will it clear any outstanding C<EVBREAK_ONE> breaks. |
916 |
|
917 |
A flags value of C<EVRUN_NOWAIT> will look for new events, will handle |
918 |
those events and any already outstanding ones, but will not wait and |
919 |
block your process in case there are no events and will return after one |
920 |
iteration of the loop. This is sometimes useful to poll and handle new |
921 |
events while doing lengthy calculations, to keep the program responsive. |
922 |
|
923 |
A flags value of C<EVRUN_ONCE> will look for new events (waiting if |
924 |
necessary) and will handle those and any already outstanding ones. It |
925 |
will block your process until at least one new event arrives (which could |
926 |
be an event internal to libev itself, so there is no guarantee that a |
927 |
user-registered callback will be called), and will return after one |
928 |
iteration of the loop. |
929 |
|
930 |
This is useful if you are waiting for some external event in conjunction |
931 |
with something not expressible using other libev watchers (i.e. "roll your |
932 |
own C<ev_run>"). However, a pair of C<ev_prepare>/C<ev_check> watchers is |
933 |
usually a better approach for this kind of thing. |
934 |
|
935 |
Here are the gory details of what C<ev_run> does (this is for your |
936 |
understanding, not a guarantee that things will work exactly like this in |
937 |
future versions): |
938 |
|
939 |
- Increment loop depth. |
940 |
- Reset the ev_break status. |
941 |
- Before the first iteration, call any pending watchers. |
942 |
LOOP: |
943 |
- If EVFLAG_FORKCHECK was used, check for a fork. |
944 |
- If a fork was detected (by any means), queue and call all fork watchers. |
945 |
- Queue and call all prepare watchers. |
946 |
- If ev_break was called, goto FINISH. |
947 |
- If we have been forked, detach and recreate the kernel state |
948 |
as to not disturb the other process. |
949 |
- Update the kernel state with all outstanding changes. |
950 |
- Update the "event loop time" (ev_now ()). |
951 |
- Calculate for how long to sleep or block, if at all |
952 |
(active idle watchers, EVRUN_NOWAIT or not having |
953 |
any active watchers at all will result in not sleeping). |
954 |
- Sleep if the I/O and timer collect interval say so. |
955 |
- Increment loop iteration counter. |
956 |
- Block the process, waiting for any events. |
957 |
- Queue all outstanding I/O (fd) events. |
958 |
- Update the "event loop time" (ev_now ()), and do time jump adjustments. |
959 |
- Queue all expired timers. |
960 |
- Queue all expired periodics. |
961 |
- Queue all idle watchers with priority higher than that of pending events. |
962 |
- Queue all check watchers. |
963 |
- Call all queued watchers in reverse order (i.e. check watchers first). |
964 |
Signals and child watchers are implemented as I/O watchers, and will |
965 |
be handled here by queueing them when their watcher gets executed. |
966 |
- If ev_break has been called, or EVRUN_ONCE or EVRUN_NOWAIT |
967 |
were used, or there are no active watchers, goto FINISH, otherwise |
968 |
continue with step LOOP. |
969 |
FINISH: |
970 |
- Reset the ev_break status iff it was EVBREAK_ONE. |
971 |
- Decrement the loop depth. |
972 |
- Return. |
973 |
|
974 |
Example: Queue some jobs and then loop until no events are outstanding |
975 |
anymore. |
976 |
|
977 |
... queue jobs here, make sure they register event watchers as long |
978 |
... as they still have work to do (even an idle watcher will do..) |
979 |
ev_run (my_loop, 0); |
980 |
... jobs done or somebody called break. yeah! |
981 |
|
982 |
=item ev_break (loop, how) |
983 |
|
984 |
Can be used to make a call to C<ev_run> return early (but only after it |
985 |
has processed all outstanding events). The C<how> argument must be either |
986 |
C<EVBREAK_ONE>, which will make the innermost C<ev_run> call return, or |
987 |
C<EVBREAK_ALL>, which will make all nested C<ev_run> calls return. |
988 |
|
989 |
This "break state" will be cleared on the next call to C<ev_run>. |
990 |
|
991 |
It is safe to call C<ev_break> from outside any C<ev_run> calls, too, in |
992 |
which case it will have no effect. |
993 |
|
994 |
=item ev_ref (loop) |
995 |
|
996 |
=item ev_unref (loop) |
997 |
|
998 |
Ref/unref can be used to add or remove a reference count on the event |
999 |
loop: Every watcher keeps one reference, and as long as the reference |
1000 |
count is nonzero, C<ev_run> will not return on its own. |
1001 |
|
1002 |
This is useful when you have a watcher that you never intend to |
1003 |
unregister, but that nevertheless should not keep C<ev_run> from |
1004 |
returning. In such a case, call C<ev_unref> after starting, and C<ev_ref> |
1005 |
before stopping it. |
1006 |
|
1007 |
As an example, libev itself uses this for its internal signal pipe: It |
1008 |
is not visible to the libev user and should not keep C<ev_run> from |
1009 |
exiting if no event watchers registered by it are active. It is also an |
1010 |
excellent way to do this for generic recurring timers or from within |
1011 |
third-party libraries. Just remember to I<unref after start> and I<ref |
1012 |
before stop> (but only if the watcher wasn't active before, or was active |
1013 |
before, respectively. Note also that libev might stop watchers itself |
1014 |
(e.g. non-repeating timers) in which case you have to C<ev_ref> |
1015 |
in the callback). |
1016 |
|
1017 |
Example: Create a signal watcher, but keep it from keeping C<ev_run> |
1018 |
running when nothing else is active. |
1019 |
|
1020 |
ev_signal exitsig; |
1021 |
ev_signal_init (&exitsig, sig_cb, SIGINT); |
1022 |
ev_signal_start (loop, &exitsig); |
1023 |
ev_unref (loop); |
1024 |
|
1025 |
Example: For some weird reason, unregister the above signal handler again. |
1026 |
|
1027 |
ev_ref (loop); |
1028 |
ev_signal_stop (loop, &exitsig); |
1029 |
|
1030 |
=item ev_set_io_collect_interval (loop, ev_tstamp interval) |
1031 |
|
1032 |
=item ev_set_timeout_collect_interval (loop, ev_tstamp interval) |
1033 |
|
1034 |
These advanced functions influence the time that libev will spend waiting |
1035 |
for events. Both time intervals are by default C<0>, meaning that libev |
1036 |
will try to invoke timer/periodic callbacks and I/O callbacks with minimum |
1037 |
latency. |
1038 |
|
1039 |
Setting these to a higher value (the C<interval> I<must> be >= C<0>) |
1040 |
allows libev to delay invocation of I/O and timer/periodic callbacks |
1041 |
to increase efficiency of loop iterations (or to increase power-saving |
1042 |
opportunities). |
1043 |
|
1044 |
The idea is that sometimes your program runs just fast enough to handle |
1045 |
one (or very few) event(s) per loop iteration. While this makes the |
1046 |
program responsive, it also wastes a lot of CPU time to poll for new |
1047 |
events, especially with backends like C<select ()> which have a high |
1048 |
overhead for the actual polling but can deliver many events at once. |
1049 |
|
1050 |
By setting a higher I<io collect interval> you allow libev to spend more |
1051 |
time collecting I/O events, so you can handle more events per iteration, |
1052 |
at the cost of increasing latency. Timeouts (both C<ev_periodic> and |
1053 |
C<ev_timer>) will not be affected. Setting this to a non-null value will |
1054 |
introduce an additional C<ev_sleep ()> call into most loop iterations. The |
1055 |
sleep time ensures that libev will not poll for I/O events more often then |
1056 |
once per this interval, on average (as long as the host time resolution is |
1057 |
good enough). |
1058 |
|
1059 |
Likewise, by setting a higher I<timeout collect interval> you allow libev |
1060 |
to spend more time collecting timeouts, at the expense of increased |
1061 |
latency/jitter/inexactness (the watcher callback will be called |
1062 |
later). C<ev_io> watchers will not be affected. Setting this to a non-null |
1063 |
value will not introduce any overhead in libev. |
1064 |
|
1065 |
Many (busy) programs can usually benefit by setting the I/O collect |
1066 |
interval to a value near C<0.1> or so, which is often enough for |
1067 |
interactive servers (of course not for games), likewise for timeouts. It |
1068 |
usually doesn't make much sense to set it to a lower value than C<0.01>, |
1069 |
as this approaches the timing granularity of most systems. Note that if |
1070 |
you do transactions with the outside world and you can't increase the |
1071 |
parallelity, then this setting will limit your transaction rate (if you |
1072 |
need to poll once per transaction and the I/O collect interval is 0.01, |
1073 |
then you can't do more than 100 transactions per second). |
1074 |
|
1075 |
Setting the I<timeout collect interval> can improve the opportunity for |
1076 |
saving power, as the program will "bundle" timer callback invocations that |
1077 |
are "near" in time together, by delaying some, thus reducing the number of |
1078 |
times the process sleeps and wakes up again. Another useful technique to |
1079 |
reduce iterations/wake-ups is to use C<ev_periodic> watchers and make sure |
1080 |
they fire on, say, one-second boundaries only. |
1081 |
|
1082 |
Example: we only need 0.1s timeout granularity, and we wish not to poll |
1083 |
more often than 100 times per second: |
1084 |
|
1085 |
ev_set_timeout_collect_interval (EV_DEFAULT_UC_ 0.1); |
1086 |
ev_set_io_collect_interval (EV_DEFAULT_UC_ 0.01); |
1087 |
|
1088 |
=item ev_invoke_pending (loop) |
1089 |
|
1090 |
This call will simply invoke all pending watchers while resetting their |
1091 |
pending state. Normally, C<ev_run> does this automatically when required, |
1092 |
but when overriding the invoke callback this call comes handy. This |
1093 |
function can be invoked from a watcher - this can be useful for example |
1094 |
when you want to do some lengthy calculation and want to pass further |
1095 |
event handling to another thread (you still have to make sure only one |
1096 |
thread executes within C<ev_invoke_pending> or C<ev_run> of course). |
1097 |
|
1098 |
=item int ev_pending_count (loop) |
1099 |
|
1100 |
Returns the number of pending watchers - zero indicates that no watchers |
1101 |
are pending. |
1102 |
|
1103 |
=item ev_set_invoke_pending_cb (loop, void (*invoke_pending_cb)(EV_P)) |
1104 |
|
1105 |
This overrides the invoke pending functionality of the loop: Instead of |
1106 |
invoking all pending watchers when there are any, C<ev_run> will call |
1107 |
this callback instead. This is useful, for example, when you want to |
1108 |
invoke the actual watchers inside another context (another thread etc.). |
1109 |
|
1110 |
If you want to reset the callback, use C<ev_invoke_pending> as new |
1111 |
callback. |
1112 |
|
1113 |
=item ev_set_loop_release_cb (loop, void (*release)(EV_P) throw (), void (*acquire)(EV_P) throw ()) |
1114 |
|
1115 |
Sometimes you want to share the same loop between multiple threads. This |
1116 |
can be done relatively simply by putting mutex_lock/unlock calls around |
1117 |
each call to a libev function. |
1118 |
|
1119 |
However, C<ev_run> can run an indefinite time, so it is not feasible |
1120 |
to wait for it to return. One way around this is to wake up the event |
1121 |
loop via C<ev_break> and C<ev_async_send>, another way is to set these |
1122 |
I<release> and I<acquire> callbacks on the loop. |
1123 |
|
1124 |
When set, then C<release> will be called just before the thread is |
1125 |
suspended waiting for new events, and C<acquire> is called just |
1126 |
afterwards. |
1127 |
|
1128 |
Ideally, C<release> will just call your mutex_unlock function, and |
1129 |
C<acquire> will just call the mutex_lock function again. |
1130 |
|
1131 |
While event loop modifications are allowed between invocations of |
1132 |
C<release> and C<acquire> (that's their only purpose after all), no |
1133 |
modifications done will affect the event loop, i.e. adding watchers will |
1134 |
have no effect on the set of file descriptors being watched, or the time |
1135 |
waited. Use an C<ev_async> watcher to wake up C<ev_run> when you want it |
1136 |
to take note of any changes you made. |
1137 |
|
1138 |
In theory, threads executing C<ev_run> will be async-cancel safe between |
1139 |
invocations of C<release> and C<acquire>. |
1140 |
|
1141 |
See also the locking example in the C<THREADS> section later in this |
1142 |
document. |
1143 |
|
1144 |
=item ev_set_userdata (loop, void *data) |
1145 |
|
1146 |
=item void *ev_userdata (loop) |
1147 |
|
1148 |
Set and retrieve a single C<void *> associated with a loop. When |
1149 |
C<ev_set_userdata> has never been called, then C<ev_userdata> returns |
1150 |
C<0>. |
1151 |
|
1152 |
These two functions can be used to associate arbitrary data with a loop, |
1153 |
and are intended solely for the C<invoke_pending_cb>, C<release> and |
1154 |
C<acquire> callbacks described above, but of course can be (ab-)used for |
1155 |
any other purpose as well. |
1156 |
|
1157 |
=item ev_verify (loop) |
1158 |
|
1159 |
This function only does something when C<EV_VERIFY> support has been |
1160 |
compiled in, which is the default for non-minimal builds. It tries to go |
1161 |
through all internal structures and checks them for validity. If anything |
1162 |
is found to be inconsistent, it will print an error message to standard |
1163 |
error and call C<abort ()>. |
1164 |
|
1165 |
This can be used to catch bugs inside libev itself: under normal |
1166 |
circumstances, this function will never abort as of course libev keeps its |
1167 |
data structures consistent. |
1168 |
|
1169 |
=back |
1170 |
|
1171 |
|
1172 |
=head1 ANATOMY OF A WATCHER |
1173 |
|
1174 |
In the following description, uppercase C<TYPE> in names stands for the |
1175 |
watcher type, e.g. C<ev_TYPE_start> can mean C<ev_timer_start> for timer |
1176 |
watchers and C<ev_io_start> for I/O watchers. |
1177 |
|
1178 |
A watcher is an opaque structure that you allocate and register to record |
1179 |
your interest in some event. To make a concrete example, imagine you want |
1180 |
to wait for STDIN to become readable, you would create an C<ev_io> watcher |
1181 |
for that: |
1182 |
|
1183 |
static void my_cb (struct ev_loop *loop, ev_io *w, int revents) |
1184 |
{ |
1185 |
ev_io_stop (w); |
1186 |
ev_break (loop, EVBREAK_ALL); |
1187 |
} |
1188 |
|
1189 |
struct ev_loop *loop = ev_default_loop (0); |
1190 |
|
1191 |
ev_io stdin_watcher; |
1192 |
|
1193 |
ev_init (&stdin_watcher, my_cb); |
1194 |
ev_io_set (&stdin_watcher, STDIN_FILENO, EV_READ); |
1195 |
ev_io_start (loop, &stdin_watcher); |
1196 |
|
1197 |
ev_run (loop, 0); |
1198 |
|
1199 |
As you can see, you are responsible for allocating the memory for your |
1200 |
watcher structures (and it is I<usually> a bad idea to do this on the |
1201 |
stack). |
1202 |
|
1203 |
Each watcher has an associated watcher structure (called C<struct ev_TYPE> |
1204 |
or simply C<ev_TYPE>, as typedefs are provided for all watcher structs). |
1205 |
|
1206 |
Each watcher structure must be initialised by a call to C<ev_init (watcher |
1207 |
*, callback)>, which expects a callback to be provided. This callback is |
1208 |
invoked each time the event occurs (or, in the case of I/O watchers, each |
1209 |
time the event loop detects that the file descriptor given is readable |
1210 |
and/or writable). |
1211 |
|
1212 |
Each watcher type further has its own C<< ev_TYPE_set (watcher *, ...) >> |
1213 |
macro to configure it, with arguments specific to the watcher type. There |
1214 |
is also a macro to combine initialisation and setting in one call: C<< |
1215 |
ev_TYPE_init (watcher *, callback, ...) >>. |
1216 |
|
1217 |
To make the watcher actually watch out for events, you have to start it |
1218 |
with a watcher-specific start function (C<< ev_TYPE_start (loop, watcher |
1219 |
*) >>), and you can stop watching for events at any time by calling the |
1220 |
corresponding stop function (C<< ev_TYPE_stop (loop, watcher *) >>. |
1221 |
|
1222 |
As long as your watcher is active (has been started but not stopped) you |
1223 |
must not touch the values stored in it except when explicitly documented |
1224 |
otherwise. Most specifically you must never reinitialise it or call its |
1225 |
C<ev_TYPE_set> macro. |
1226 |
|
1227 |
Each and every callback receives the event loop pointer as first, the |
1228 |
registered watcher structure as second, and a bitset of received events as |
1229 |
third argument. |
1230 |
|
1231 |
The received events usually include a single bit per event type received |
1232 |
(you can receive multiple events at the same time). The possible bit masks |
1233 |
are: |
1234 |
|
1235 |
=over 4 |
1236 |
|
1237 |
=item C<EV_READ> |
1238 |
|
1239 |
=item C<EV_WRITE> |
1240 |
|
1241 |
The file descriptor in the C<ev_io> watcher has become readable and/or |
1242 |
writable. |
1243 |
|
1244 |
=item C<EV_TIMER> |
1245 |
|
1246 |
The C<ev_timer> watcher has timed out. |
1247 |
|
1248 |
=item C<EV_PERIODIC> |
1249 |
|
1250 |
The C<ev_periodic> watcher has timed out. |
1251 |
|
1252 |
=item C<EV_SIGNAL> |
1253 |
|
1254 |
The signal specified in the C<ev_signal> watcher has been received by a thread. |
1255 |
|
1256 |
=item C<EV_CHILD> |
1257 |
|
1258 |
The pid specified in the C<ev_child> watcher has received a status change. |
1259 |
|
1260 |
=item C<EV_STAT> |
1261 |
|
1262 |
The path specified in the C<ev_stat> watcher changed its attributes somehow. |
1263 |
|
1264 |
=item C<EV_IDLE> |
1265 |
|
1266 |
The C<ev_idle> watcher has determined that you have nothing better to do. |
1267 |
|
1268 |
=item C<EV_PREPARE> |
1269 |
|
1270 |
=item C<EV_CHECK> |
1271 |
|
1272 |
All C<ev_prepare> watchers are invoked just I<before> C<ev_run> starts to |
1273 |
gather new events, and all C<ev_check> watchers are queued (not invoked) |
1274 |
just after C<ev_run> has gathered them, but before it queues any callbacks |
1275 |
for any received events. That means C<ev_prepare> watchers are the last |
1276 |
watchers invoked before the event loop sleeps or polls for new events, and |
1277 |
C<ev_check> watchers will be invoked before any other watchers of the same |
1278 |
or lower priority within an event loop iteration. |
1279 |
|
1280 |
Callbacks of both watcher types can start and stop as many watchers as |
1281 |
they want, and all of them will be taken into account (for example, a |
1282 |
C<ev_prepare> watcher might start an idle watcher to keep C<ev_run> from |
1283 |
blocking). |
1284 |
|
1285 |
=item C<EV_EMBED> |
1286 |
|
1287 |
The embedded event loop specified in the C<ev_embed> watcher needs attention. |
1288 |
|
1289 |
=item C<EV_FORK> |
1290 |
|
1291 |
The event loop has been resumed in the child process after fork (see |
1292 |
C<ev_fork>). |
1293 |
|
1294 |
=item C<EV_CLEANUP> |
1295 |
|
1296 |
The event loop is about to be destroyed (see C<ev_cleanup>). |
1297 |
|
1298 |
=item C<EV_ASYNC> |
1299 |
|
1300 |
The given async watcher has been asynchronously notified (see C<ev_async>). |
1301 |
|
1302 |
=item C<EV_CUSTOM> |
1303 |
|
1304 |
Not ever sent (or otherwise used) by libev itself, but can be freely used |
1305 |
by libev users to signal watchers (e.g. via C<ev_feed_event>). |
1306 |
|
1307 |
=item C<EV_ERROR> |
1308 |
|
1309 |
An unspecified error has occurred, the watcher has been stopped. This might |
1310 |
happen because the watcher could not be properly started because libev |
1311 |
ran out of memory, a file descriptor was found to be closed or any other |
1312 |
problem. Libev considers these application bugs. |
1313 |
|
1314 |
You best act on it by reporting the problem and somehow coping with the |
1315 |
watcher being stopped. Note that well-written programs should not receive |
1316 |
an error ever, so when your watcher receives it, this usually indicates a |
1317 |
bug in your program. |
1318 |
|
1319 |
Libev will usually signal a few "dummy" events together with an error, for |
1320 |
example it might indicate that a fd is readable or writable, and if your |
1321 |
callbacks is well-written it can just attempt the operation and cope with |
1322 |
the error from read() or write(). This will not work in multi-threaded |
1323 |
programs, though, as the fd could already be closed and reused for another |
1324 |
thing, so beware. |
1325 |
|
1326 |
=back |
1327 |
|
1328 |
=head2 GENERIC WATCHER FUNCTIONS |
1329 |
|
1330 |
=over 4 |
1331 |
|
1332 |
=item C<ev_init> (ev_TYPE *watcher, callback) |
1333 |
|
1334 |
This macro initialises the generic portion of a watcher. The contents |
1335 |
of the watcher object can be arbitrary (so C<malloc> will do). Only |
1336 |
the generic parts of the watcher are initialised, you I<need> to call |
1337 |
the type-specific C<ev_TYPE_set> macro afterwards to initialise the |
1338 |
type-specific parts. For each type there is also a C<ev_TYPE_init> macro |
1339 |
which rolls both calls into one. |
1340 |
|
1341 |
You can reinitialise a watcher at any time as long as it has been stopped |
1342 |
(or never started) and there are no pending events outstanding. |
1343 |
|
1344 |
The callback is always of type C<void (*)(struct ev_loop *loop, ev_TYPE *watcher, |
1345 |
int revents)>. |
1346 |
|
1347 |
Example: Initialise an C<ev_io> watcher in two steps. |
1348 |
|
1349 |
ev_io w; |
1350 |
ev_init (&w, my_cb); |
1351 |
ev_io_set (&w, STDIN_FILENO, EV_READ); |
1352 |
|
1353 |
=item C<ev_TYPE_set> (ev_TYPE *watcher, [args]) |
1354 |
|
1355 |
This macro initialises the type-specific parts of a watcher. You need to |
1356 |
call C<ev_init> at least once before you call this macro, but you can |
1357 |
call C<ev_TYPE_set> any number of times. You must not, however, call this |
1358 |
macro on a watcher that is active (it can be pending, however, which is a |
1359 |
difference to the C<ev_init> macro). |
1360 |
|
1361 |
Although some watcher types do not have type-specific arguments |
1362 |
(e.g. C<ev_prepare>) you still need to call its C<set> macro. |
1363 |
|
1364 |
See C<ev_init>, above, for an example. |
1365 |
|
1366 |
=item C<ev_TYPE_init> (ev_TYPE *watcher, callback, [args]) |
1367 |
|
1368 |
This convenience macro rolls both C<ev_init> and C<ev_TYPE_set> macro |
1369 |
calls into a single call. This is the most convenient method to initialise |
1370 |
a watcher. The same limitations apply, of course. |
1371 |
|
1372 |
Example: Initialise and set an C<ev_io> watcher in one step. |
1373 |
|
1374 |
ev_io_init (&w, my_cb, STDIN_FILENO, EV_READ); |
1375 |
|
1376 |
=item C<ev_TYPE_start> (loop, ev_TYPE *watcher) |
1377 |
|
1378 |
Starts (activates) the given watcher. Only active watchers will receive |
1379 |
events. If the watcher is already active nothing will happen. |
1380 |
|
1381 |
Example: Start the C<ev_io> watcher that is being abused as example in this |
1382 |
whole section. |
1383 |
|
1384 |
ev_io_start (EV_DEFAULT_UC, &w); |
1385 |
|
1386 |
=item C<ev_TYPE_stop> (loop, ev_TYPE *watcher) |
1387 |
|
1388 |
Stops the given watcher if active, and clears the pending status (whether |
1389 |
the watcher was active or not). |
1390 |
|
1391 |
It is possible that stopped watchers are pending - for example, |
1392 |
non-repeating timers are being stopped when they become pending - but |
1393 |
calling C<ev_TYPE_stop> ensures that the watcher is neither active nor |
1394 |
pending. If you want to free or reuse the memory used by the watcher it is |
1395 |
therefore a good idea to always call its C<ev_TYPE_stop> function. |
1396 |
|
1397 |
=item bool ev_is_active (ev_TYPE *watcher) |
1398 |
|
1399 |
Returns a true value iff the watcher is active (i.e. it has been started |
1400 |
and not yet been stopped). As long as a watcher is active you must not modify |
1401 |
it. |
1402 |
|
1403 |
=item bool ev_is_pending (ev_TYPE *watcher) |
1404 |
|
1405 |
Returns a true value iff the watcher is pending, (i.e. it has outstanding |
1406 |
events but its callback has not yet been invoked). As long as a watcher |
1407 |
is pending (but not active) you must not call an init function on it (but |
1408 |
C<ev_TYPE_set> is safe), you must not change its priority, and you must |
1409 |
make sure the watcher is available to libev (e.g. you cannot C<free ()> |
1410 |
it). |
1411 |
|
1412 |
=item callback ev_cb (ev_TYPE *watcher) |
1413 |
|
1414 |
Returns the callback currently set on the watcher. |
1415 |
|
1416 |
=item ev_set_cb (ev_TYPE *watcher, callback) |
1417 |
|
1418 |
Change the callback. You can change the callback at virtually any time |
1419 |
(modulo threads). |
1420 |
|
1421 |
=item ev_set_priority (ev_TYPE *watcher, int priority) |
1422 |
|
1423 |
=item int ev_priority (ev_TYPE *watcher) |
1424 |
|
1425 |
Set and query the priority of the watcher. The priority is a small |
1426 |
integer between C<EV_MAXPRI> (default: C<2>) and C<EV_MINPRI> |
1427 |
(default: C<-2>). Pending watchers with higher priority will be invoked |
1428 |
before watchers with lower priority, but priority will not keep watchers |
1429 |
from being executed (except for C<ev_idle> watchers). |
1430 |
|
1431 |
If you need to suppress invocation when higher priority events are pending |
1432 |
you need to look at C<ev_idle> watchers, which provide this functionality. |
1433 |
|
1434 |
You I<must not> change the priority of a watcher as long as it is active or |
1435 |
pending. |
1436 |
|
1437 |
Setting a priority outside the range of C<EV_MINPRI> to C<EV_MAXPRI> is |
1438 |
fine, as long as you do not mind that the priority value you query might |
1439 |
or might not have been clamped to the valid range. |
1440 |
|
1441 |
The default priority used by watchers when no priority has been set is |
1442 |
always C<0>, which is supposed to not be too high and not be too low :). |
1443 |
|
1444 |
See L</WATCHER PRIORITY MODELS>, below, for a more thorough treatment of |
1445 |
priorities. |
1446 |
|
1447 |
=item ev_invoke (loop, ev_TYPE *watcher, int revents) |
1448 |
|
1449 |
Invoke the C<watcher> with the given C<loop> and C<revents>. Neither |
1450 |
C<loop> nor C<revents> need to be valid as long as the watcher callback |
1451 |
can deal with that fact, as both are simply passed through to the |
1452 |
callback. |
1453 |
|
1454 |
=item int ev_clear_pending (loop, ev_TYPE *watcher) |
1455 |
|
1456 |
If the watcher is pending, this function clears its pending status and |
1457 |
returns its C<revents> bitset (as if its callback was invoked). If the |
1458 |
watcher isn't pending it does nothing and returns C<0>. |
1459 |
|
1460 |
Sometimes it can be useful to "poll" a watcher instead of waiting for its |
1461 |
callback to be invoked, which can be accomplished with this function. |
1462 |
|
1463 |
=item ev_feed_event (loop, ev_TYPE *watcher, int revents) |
1464 |
|
1465 |
Feeds the given event set into the event loop, as if the specified event |
1466 |
had happened for the specified watcher (which must be a pointer to an |
1467 |
initialised but not necessarily started event watcher). Obviously you must |
1468 |
not free the watcher as long as it has pending events. |
1469 |
|
1470 |
Stopping the watcher, letting libev invoke it, or calling |
1471 |
C<ev_clear_pending> will clear the pending event, even if the watcher was |
1472 |
not started in the first place. |
1473 |
|
1474 |
See also C<ev_feed_fd_event> and C<ev_feed_signal_event> for related |
1475 |
functions that do not need a watcher. |
1476 |
|
1477 |
=back |
1478 |
|
1479 |
See also the L</ASSOCIATING CUSTOM DATA WITH A WATCHER> and L</BUILDING YOUR |
1480 |
OWN COMPOSITE WATCHERS> idioms. |
1481 |
|
1482 |
=head2 WATCHER STATES |
1483 |
|
1484 |
There are various watcher states mentioned throughout this manual - |
1485 |
active, pending and so on. In this section these states and the rules to |
1486 |
transition between them will be described in more detail - and while these |
1487 |
rules might look complicated, they usually do "the right thing". |
1488 |
|
1489 |
=over 4 |
1490 |
|
1491 |
=item initialised |
1492 |
|
1493 |
Before a watcher can be registered with the event loop it has to be |
1494 |
initialised. This can be done with a call to C<ev_TYPE_init>, or calls to |
1495 |
C<ev_init> followed by the watcher-specific C<ev_TYPE_set> function. |
1496 |
|
1497 |
In this state it is simply some block of memory that is suitable for |
1498 |
use in an event loop. It can be moved around, freed, reused etc. at |
1499 |
will - as long as you either keep the memory contents intact, or call |
1500 |
C<ev_TYPE_init> again. |
1501 |
|
1502 |
=item started/running/active |
1503 |
|
1504 |
Once a watcher has been started with a call to C<ev_TYPE_start> it becomes |
1505 |
property of the event loop, and is actively waiting for events. While in |
1506 |
this state it cannot be accessed (except in a few documented ways), moved, |
1507 |
freed or anything else - the only legal thing is to keep a pointer to it, |
1508 |
and call libev functions on it that are documented to work on active watchers. |
1509 |
|
1510 |
=item pending |
1511 |
|
1512 |
If a watcher is active and libev determines that an event it is interested |
1513 |
in has occurred (such as a timer expiring), it will become pending. It will |
1514 |
stay in this pending state until either it is stopped or its callback is |
1515 |
about to be invoked, so it is not normally pending inside the watcher |
1516 |
callback. |
1517 |
|
1518 |
The watcher might or might not be active while it is pending (for example, |
1519 |
an expired non-repeating timer can be pending but no longer active). If it |
1520 |
is stopped, it can be freely accessed (e.g. by calling C<ev_TYPE_set>), |
1521 |
but it is still property of the event loop at this time, so cannot be |
1522 |
moved, freed or reused. And if it is active the rules described in the |
1523 |
previous item still apply. |
1524 |
|
1525 |
It is also possible to feed an event on a watcher that is not active (e.g. |
1526 |
via C<ev_feed_event>), in which case it becomes pending without being |
1527 |
active. |
1528 |
|
1529 |
=item stopped |
1530 |
|
1531 |
A watcher can be stopped implicitly by libev (in which case it might still |
1532 |
be pending), or explicitly by calling its C<ev_TYPE_stop> function. The |
1533 |
latter will clear any pending state the watcher might be in, regardless |
1534 |
of whether it was active or not, so stopping a watcher explicitly before |
1535 |
freeing it is often a good idea. |
1536 |
|
1537 |
While stopped (and not pending) the watcher is essentially in the |
1538 |
initialised state, that is, it can be reused, moved, modified in any way |
1539 |
you wish (but when you trash the memory block, you need to C<ev_TYPE_init> |
1540 |
it again). |
1541 |
|
1542 |
=back |
1543 |
|
1544 |
=head2 WATCHER PRIORITY MODELS |
1545 |
|
1546 |
Many event loops support I<watcher priorities>, which are usually small |
1547 |
integers that influence the ordering of event callback invocation |
1548 |
between watchers in some way, all else being equal. |
1549 |
|
1550 |
In libev, watcher priorities can be set using C<ev_set_priority>. See its |
1551 |
description for the more technical details such as the actual priority |
1552 |
range. |
1553 |
|
1554 |
There are two common ways how these these priorities are being interpreted |
1555 |
by event loops: |
1556 |
|
1557 |
In the more common lock-out model, higher priorities "lock out" invocation |
1558 |
of lower priority watchers, which means as long as higher priority |
1559 |
watchers receive events, lower priority watchers are not being invoked. |
1560 |
|
1561 |
The less common only-for-ordering model uses priorities solely to order |
1562 |
callback invocation within a single event loop iteration: Higher priority |
1563 |
watchers are invoked before lower priority ones, but they all get invoked |
1564 |
before polling for new events. |
1565 |
|
1566 |
Libev uses the second (only-for-ordering) model for all its watchers |
1567 |
except for idle watchers (which use the lock-out model). |
1568 |
|
1569 |
The rationale behind this is that implementing the lock-out model for |
1570 |
watchers is not well supported by most kernel interfaces, and most event |
1571 |
libraries will just poll for the same events again and again as long as |
1572 |
their callbacks have not been executed, which is very inefficient in the |
1573 |
common case of one high-priority watcher locking out a mass of lower |
1574 |
priority ones. |
1575 |
|
1576 |
Static (ordering) priorities are most useful when you have two or more |
1577 |
watchers handling the same resource: a typical usage example is having an |
1578 |
C<ev_io> watcher to receive data, and an associated C<ev_timer> to handle |
1579 |
timeouts. Under load, data might be received while the program handles |
1580 |
other jobs, but since timers normally get invoked first, the timeout |
1581 |
handler will be executed before checking for data. In that case, giving |
1582 |
the timer a lower priority than the I/O watcher ensures that I/O will be |
1583 |
handled first even under adverse conditions (which is usually, but not |
1584 |
always, what you want). |
1585 |
|
1586 |
Since idle watchers use the "lock-out" model, meaning that idle watchers |
1587 |
will only be executed when no same or higher priority watchers have |
1588 |
received events, they can be used to implement the "lock-out" model when |
1589 |
required. |
1590 |
|
1591 |
For example, to emulate how many other event libraries handle priorities, |
1592 |
you can associate an C<ev_idle> watcher to each such watcher, and in |
1593 |
the normal watcher callback, you just start the idle watcher. The real |
1594 |
processing is done in the idle watcher callback. This causes libev to |
1595 |
continuously poll and process kernel event data for the watcher, but when |
1596 |
the lock-out case is known to be rare (which in turn is rare :), this is |
1597 |
workable. |
1598 |
|
1599 |
Usually, however, the lock-out model implemented that way will perform |
1600 |
miserably under the type of load it was designed to handle. In that case, |
1601 |
it might be preferable to stop the real watcher before starting the |
1602 |
idle watcher, so the kernel will not have to process the event in case |
1603 |
the actual processing will be delayed for considerable time. |
1604 |
|
1605 |
Here is an example of an I/O watcher that should run at a strictly lower |
1606 |
priority than the default, and which should only process data when no |
1607 |
other events are pending: |
1608 |
|
1609 |
ev_idle idle; // actual processing watcher |
1610 |
ev_io io; // actual event watcher |
1611 |
|
1612 |
static void |
1613 |
io_cb (EV_P_ ev_io *w, int revents) |
1614 |
{ |
1615 |
// stop the I/O watcher, we received the event, but |
1616 |
// are not yet ready to handle it. |
1617 |
ev_io_stop (EV_A_ w); |
1618 |
|
1619 |
// start the idle watcher to handle the actual event. |
1620 |
// it will not be executed as long as other watchers |
1621 |
// with the default priority are receiving events. |
1622 |
ev_idle_start (EV_A_ &idle); |
1623 |
} |
1624 |
|
1625 |
static void |
1626 |
idle_cb (EV_P_ ev_idle *w, int revents) |
1627 |
{ |
1628 |
// actual processing |
1629 |
read (STDIN_FILENO, ...); |
1630 |
|
1631 |
// have to start the I/O watcher again, as |
1632 |
// we have handled the event |
1633 |
ev_io_start (EV_P_ &io); |
1634 |
} |
1635 |
|
1636 |
// initialisation |
1637 |
ev_idle_init (&idle, idle_cb); |
1638 |
ev_io_init (&io, io_cb, STDIN_FILENO, EV_READ); |
1639 |
ev_io_start (EV_DEFAULT_ &io); |
1640 |
|
1641 |
In the "real" world, it might also be beneficial to start a timer, so that |
1642 |
low-priority connections can not be locked out forever under load. This |
1643 |
enables your program to keep a lower latency for important connections |
1644 |
during short periods of high load, while not completely locking out less |
1645 |
important ones. |
1646 |
|
1647 |
|
1648 |
=head1 WATCHER TYPES |
1649 |
|
1650 |
This section describes each watcher in detail, but will not repeat |
1651 |
information given in the last section. Any initialisation/set macros, |
1652 |
functions and members specific to the watcher type are explained. |
1653 |
|
1654 |
Most members are additionally marked with either I<[read-only]>, meaning |
1655 |
that, while the watcher is active, you can look at the member and expect |
1656 |
some sensible content, but you must not modify it (you can modify it while |
1657 |
the watcher is stopped to your hearts content), or I<[read-write]>, which |
1658 |
means you can expect it to have some sensible content while the watcher |
1659 |
is active, but you can also modify it. Modifying it may not do something |
1660 |
sensible or take immediate effect (or do anything at all), but libev will |
1661 |
not crash or malfunction in any way. |
1662 |
|
1663 |
In any case, the documentation for each member will explain what the |
1664 |
effects are, and if there are any additional access restrictions. |
1665 |
|
1666 |
=head2 C<ev_io> - is this file descriptor readable or writable? |
1667 |
|
1668 |
I/O watchers check whether a file descriptor is readable or writable |
1669 |
in each iteration of the event loop, or, more precisely, when reading |
1670 |
would not block the process and writing would at least be able to write |
1671 |
some data. This behaviour is called level-triggering because you keep |
1672 |
receiving events as long as the condition persists. Remember you can stop |
1673 |
the watcher if you don't want to act on the event and neither want to |
1674 |
receive future events. |
1675 |
|
1676 |
In general you can register as many read and/or write event watchers per |
1677 |
fd as you want (as long as you don't confuse yourself). Setting all file |
1678 |
descriptors to non-blocking mode is also usually a good idea (but not |
1679 |
required if you know what you are doing). |
1680 |
|
1681 |
Another thing you have to watch out for is that it is quite easy to |
1682 |
receive "spurious" readiness notifications, that is, your callback might |
1683 |
be called with C<EV_READ> but a subsequent C<read>(2) will actually block |
1684 |
because there is no data. It is very easy to get into this situation even |
1685 |
with a relatively standard program structure. Thus it is best to always |
1686 |
use non-blocking I/O: An extra C<read>(2) returning C<EAGAIN> is far |
1687 |
preferable to a program hanging until some data arrives. |
1688 |
|
1689 |
If you cannot run the fd in non-blocking mode (for example you should |
1690 |
not play around with an Xlib connection), then you have to separately |
1691 |
re-test whether a file descriptor is really ready with a known-to-be good |
1692 |
interface such as poll (fortunately in the case of Xlib, it already does |
1693 |
this on its own, so its quite safe to use). Some people additionally |
1694 |
use C<SIGALRM> and an interval timer, just to be sure you won't block |
1695 |
indefinitely. |
1696 |
|
1697 |
But really, best use non-blocking mode. |
1698 |
|
1699 |
=head3 The special problem of disappearing file descriptors |
1700 |
|
1701 |
Some backends (e.g. kqueue, epoll, linuxaio) need to be told about closing |
1702 |
a file descriptor (either due to calling C<close> explicitly or any other |
1703 |
means, such as C<dup2>). The reason is that you register interest in some |
1704 |
file descriptor, but when it goes away, the operating system will silently |
1705 |
drop this interest. If another file descriptor with the same number then |
1706 |
is registered with libev, there is no efficient way to see that this is, |
1707 |
in fact, a different file descriptor. |
1708 |
|
1709 |
To avoid having to explicitly tell libev about such cases, libev follows |
1710 |
the following policy: Each time C<ev_io_set> is being called, libev |
1711 |
will assume that this is potentially a new file descriptor, otherwise |
1712 |
it is assumed that the file descriptor stays the same. That means that |
1713 |
you I<have> to call C<ev_io_set> (or C<ev_io_init>) when you change the |
1714 |
descriptor even if the file descriptor number itself did not change. |
1715 |
|
1716 |
This is how one would do it normally anyway, the important point is that |
1717 |
the libev application should not optimise around libev but should leave |
1718 |
optimisations to libev. |
1719 |
|
1720 |
=head3 The special problem of dup'ed file descriptors |
1721 |
|
1722 |
Some backends (e.g. epoll), cannot register events for file descriptors, |
1723 |
but only events for the underlying file descriptions. That means when you |
1724 |
have C<dup ()>'ed file descriptors or weirder constellations, and register |
1725 |
events for them, only one file descriptor might actually receive events. |
1726 |
|
1727 |
There is no workaround possible except not registering events |
1728 |
for potentially C<dup ()>'ed file descriptors, or to resort to |
1729 |
C<EVBACKEND_SELECT> or C<EVBACKEND_POLL>. |
1730 |
|
1731 |
=head3 The special problem of files |
1732 |
|
1733 |
Many people try to use C<select> (or libev) on file descriptors |
1734 |
representing files, and expect it to become ready when their program |
1735 |
doesn't block on disk accesses (which can take a long time on their own). |
1736 |
|
1737 |
However, this cannot ever work in the "expected" way - you get a readiness |
1738 |
notification as soon as the kernel knows whether and how much data is |
1739 |
there, and in the case of open files, that's always the case, so you |
1740 |
always get a readiness notification instantly, and your read (or possibly |
1741 |
write) will still block on the disk I/O. |
1742 |
|
1743 |
Another way to view it is that in the case of sockets, pipes, character |
1744 |
devices and so on, there is another party (the sender) that delivers data |
1745 |
on its own, but in the case of files, there is no such thing: the disk |
1746 |
will not send data on its own, simply because it doesn't know what you |
1747 |
wish to read - you would first have to request some data. |
1748 |
|
1749 |
Since files are typically not-so-well supported by advanced notification |
1750 |
mechanism, libev tries hard to emulate POSIX behaviour with respect |
1751 |
to files, even though you should not use it. The reason for this is |
1752 |
convenience: sometimes you want to watch STDIN or STDOUT, which is |
1753 |
usually a tty, often a pipe, but also sometimes files or special devices |
1754 |
(for example, C<epoll> on Linux works with F</dev/random> but not with |
1755 |
F</dev/urandom>), and even though the file might better be served with |
1756 |
asynchronous I/O instead of with non-blocking I/O, it is still useful when |
1757 |
it "just works" instead of freezing. |
1758 |
|
1759 |
So avoid file descriptors pointing to files when you know it (e.g. use |
1760 |
libeio), but use them when it is convenient, e.g. for STDIN/STDOUT, or |
1761 |
when you rarely read from a file instead of from a socket, and want to |
1762 |
reuse the same code path. |
1763 |
|
1764 |
=head3 The special problem of fork |
1765 |
|
1766 |
Some backends (epoll, kqueue, linuxaio, iouring) do not support C<fork ()> |
1767 |
at all or exhibit useless behaviour. Libev fully supports fork, but needs |
1768 |
to be told about it in the child if you want to continue to use it in the |
1769 |
child. |
1770 |
|
1771 |
To support fork in your child processes, you have to call C<ev_loop_fork |
1772 |
()> after a fork in the child, enable C<EVFLAG_FORKCHECK>, or resort to |
1773 |
C<EVBACKEND_SELECT> or C<EVBACKEND_POLL>. |
1774 |
|
1775 |
=head3 The special problem of SIGPIPE |
1776 |
|
1777 |
While not really specific to libev, it is easy to forget about C<SIGPIPE>: |
1778 |
when writing to a pipe whose other end has been closed, your program gets |
1779 |
sent a SIGPIPE, which, by default, aborts your program. For most programs |
1780 |
this is sensible behaviour, for daemons, this is usually undesirable. |
1781 |
|
1782 |
So when you encounter spurious, unexplained daemon exits, make sure you |
1783 |
ignore SIGPIPE (and maybe make sure you log the exit status of your daemon |
1784 |
somewhere, as that would have given you a big clue). |
1785 |
|
1786 |
=head3 The special problem of accept()ing when you can't |
1787 |
|
1788 |
Many implementations of the POSIX C<accept> function (for example, |
1789 |
found in post-2004 Linux) have the peculiar behaviour of not removing a |
1790 |
connection from the pending queue in all error cases. |
1791 |
|
1792 |
For example, larger servers often run out of file descriptors (because |
1793 |
of resource limits), causing C<accept> to fail with C<ENFILE> but not |
1794 |
rejecting the connection, leading to libev signalling readiness on |
1795 |
the next iteration again (the connection still exists after all), and |
1796 |
typically causing the program to loop at 100% CPU usage. |
1797 |
|
1798 |
Unfortunately, the set of errors that cause this issue differs between |
1799 |
operating systems, there is usually little the app can do to remedy the |
1800 |
situation, and no known thread-safe method of removing the connection to |
1801 |
cope with overload is known (to me). |
1802 |
|
1803 |
One of the easiest ways to handle this situation is to just ignore it |
1804 |
- when the program encounters an overload, it will just loop until the |
1805 |
situation is over. While this is a form of busy waiting, no OS offers an |
1806 |
event-based way to handle this situation, so it's the best one can do. |
1807 |
|
1808 |
A better way to handle the situation is to log any errors other than |
1809 |
C<EAGAIN> and C<EWOULDBLOCK>, making sure not to flood the log with such |
1810 |
messages, and continue as usual, which at least gives the user an idea of |
1811 |
what could be wrong ("raise the ulimit!"). For extra points one could stop |
1812 |
the C<ev_io> watcher on the listening fd "for a while", which reduces CPU |
1813 |
usage. |
1814 |
|
1815 |
If your program is single-threaded, then you could also keep a dummy file |
1816 |
descriptor for overload situations (e.g. by opening F</dev/null>), and |
1817 |
when you run into C<ENFILE> or C<EMFILE>, close it, run C<accept>, |
1818 |
close that fd, and create a new dummy fd. This will gracefully refuse |
1819 |
clients under typical overload conditions. |
1820 |
|
1821 |
The last way to handle it is to simply log the error and C<exit>, as |
1822 |
is often done with C<malloc> failures, but this results in an easy |
1823 |
opportunity for a DoS attack. |
1824 |
|
1825 |
=head3 Watcher-Specific Functions |
1826 |
|
1827 |
=over 4 |
1828 |
|
1829 |
=item ev_io_init (ev_io *, callback, int fd, int events) |
1830 |
|
1831 |
=item ev_io_set (ev_io *, int fd, int events) |
1832 |
|
1833 |
Configures an C<ev_io> watcher. The C<fd> is the file descriptor to |
1834 |
receive events for and C<events> is either C<EV_READ>, C<EV_WRITE>, both |
1835 |
C<EV_READ | EV_WRITE> or C<0>, to express the desire to receive the given |
1836 |
events. |
1837 |
|
1838 |
Note that setting the C<events> to C<0> and starting the watcher is |
1839 |
supported, but not specially optimized - if your program sometimes happens |
1840 |
to generate this combination this is fine, but if it is easy to avoid |
1841 |
starting an io watcher watching for no events you should do so. |
1842 |
|
1843 |
=item ev_io_modify (ev_io *, int events) |
1844 |
|
1845 |
Similar to C<ev_io_set>, but only changes the event mask. Using this might |
1846 |
be faster with some backends, as libev can assume that the C<fd> still |
1847 |
refers to the same underlying file description, something it cannot do |
1848 |
when using C<ev_io_set>. |
1849 |
|
1850 |
=item int fd [no-modify] |
1851 |
|
1852 |
The file descriptor being watched. While it can be read at any time, you |
1853 |
must not modify this member even when the watcher is stopped - always use |
1854 |
C<ev_io_set> for that. |
1855 |
|
1856 |
=item int events [no-modify] |
1857 |
|
1858 |
The set of events the fd is being watched for, among other flags. Remember |
1859 |
that this is a bit set - to test for C<EV_READ>, use C<< w->events & |
1860 |
EV_READ >>, and similarly for C<EV_WRITE>. |
1861 |
|
1862 |
As with C<fd>, you must not modify this member even when the watcher is |
1863 |
stopped, always use C<ev_io_set> or C<ev_io_modify> for that. |
1864 |
|
1865 |
=back |
1866 |
|
1867 |
=head3 Examples |
1868 |
|
1869 |
Example: Call C<stdin_readable_cb> when STDIN_FILENO has become, well |
1870 |
readable, but only once. Since it is likely line-buffered, you could |
1871 |
attempt to read a whole line in the callback. |
1872 |
|
1873 |
static void |
1874 |
stdin_readable_cb (struct ev_loop *loop, ev_io *w, int revents) |
1875 |
{ |
1876 |
ev_io_stop (loop, w); |
1877 |
.. read from stdin here (or from w->fd) and handle any I/O errors |
1878 |
} |
1879 |
|
1880 |
... |
1881 |
struct ev_loop *loop = ev_default_init (0); |
1882 |
ev_io stdin_readable; |
1883 |
ev_io_init (&stdin_readable, stdin_readable_cb, STDIN_FILENO, EV_READ); |
1884 |
ev_io_start (loop, &stdin_readable); |
1885 |
ev_run (loop, 0); |
1886 |
|
1887 |
|
1888 |
=head2 C<ev_timer> - relative and optionally repeating timeouts |
1889 |
|
1890 |
Timer watchers are simple relative timers that generate an event after a |
1891 |
given time, and optionally repeating in regular intervals after that. |
1892 |
|
1893 |
The timers are based on real time, that is, if you register an event that |
1894 |
times out after an hour and you reset your system clock to January last |
1895 |
year, it will still time out after (roughly) one hour. "Roughly" because |
1896 |
detecting time jumps is hard, and some inaccuracies are unavoidable (the |
1897 |
monotonic clock option helps a lot here). |
1898 |
|
1899 |
The callback is guaranteed to be invoked only I<after> its timeout has |
1900 |
passed (not I<at>, so on systems with very low-resolution clocks this |
1901 |
might introduce a small delay, see "the special problem of being too |
1902 |
early", below). If multiple timers become ready during the same loop |
1903 |
iteration then the ones with earlier time-out values are invoked before |
1904 |
ones of the same priority with later time-out values (but this is no |
1905 |
longer true when a callback calls C<ev_run> recursively). |
1906 |
|
1907 |
=head3 Be smart about timeouts |
1908 |
|
1909 |
Many real-world problems involve some kind of timeout, usually for error |
1910 |
recovery. A typical example is an HTTP request - if the other side hangs, |
1911 |
you want to raise some error after a while. |
1912 |
|
1913 |
What follows are some ways to handle this problem, from obvious and |
1914 |
inefficient to smart and efficient. |
1915 |
|
1916 |
In the following, a 60 second activity timeout is assumed - a timeout that |
1917 |
gets reset to 60 seconds each time there is activity (e.g. each time some |
1918 |
data or other life sign was received). |
1919 |
|
1920 |
=over 4 |
1921 |
|
1922 |
=item 1. Use a timer and stop, reinitialise and start it on activity. |
1923 |
|
1924 |
This is the most obvious, but not the most simple way: In the beginning, |
1925 |
start the watcher: |
1926 |
|
1927 |
ev_timer_init (timer, callback, 60., 0.); |
1928 |
ev_timer_start (loop, timer); |
1929 |
|
1930 |
Then, each time there is some activity, C<ev_timer_stop> it, initialise it |
1931 |
and start it again: |
1932 |
|
1933 |
ev_timer_stop (loop, timer); |
1934 |
ev_timer_set (timer, 60., 0.); |
1935 |
ev_timer_start (loop, timer); |
1936 |
|
1937 |
This is relatively simple to implement, but means that each time there is |
1938 |
some activity, libev will first have to remove the timer from its internal |
1939 |
data structure and then add it again. Libev tries to be fast, but it's |
1940 |
still not a constant-time operation. |
1941 |
|
1942 |
=item 2. Use a timer and re-start it with C<ev_timer_again> inactivity. |
1943 |
|
1944 |
This is the easiest way, and involves using C<ev_timer_again> instead of |
1945 |
C<ev_timer_start>. |
1946 |
|
1947 |
To implement this, configure an C<ev_timer> with a C<repeat> value |
1948 |
of C<60> and then call C<ev_timer_again> at start and each time you |
1949 |
successfully read or write some data. If you go into an idle state where |
1950 |
you do not expect data to travel on the socket, you can C<ev_timer_stop> |
1951 |
the timer, and C<ev_timer_again> will automatically restart it if need be. |
1952 |
|
1953 |
That means you can ignore both the C<ev_timer_start> function and the |
1954 |
C<after> argument to C<ev_timer_set>, and only ever use the C<repeat> |
1955 |
member and C<ev_timer_again>. |
1956 |
|
1957 |
At start: |
1958 |
|
1959 |
ev_init (timer, callback); |
1960 |
timer->repeat = 60.; |
1961 |
ev_timer_again (loop, timer); |
1962 |
|
1963 |
Each time there is some activity: |
1964 |
|
1965 |
ev_timer_again (loop, timer); |
1966 |
|
1967 |
It is even possible to change the time-out on the fly, regardless of |
1968 |
whether the watcher is active or not: |
1969 |
|
1970 |
timer->repeat = 30.; |
1971 |
ev_timer_again (loop, timer); |
1972 |
|
1973 |
This is slightly more efficient then stopping/starting the timer each time |
1974 |
you want to modify its timeout value, as libev does not have to completely |
1975 |
remove and re-insert the timer from/into its internal data structure. |
1976 |
|
1977 |
It is, however, even simpler than the "obvious" way to do it. |
1978 |
|
1979 |
=item 3. Let the timer time out, but then re-arm it as required. |
1980 |
|
1981 |
This method is more tricky, but usually most efficient: Most timeouts are |
1982 |
relatively long compared to the intervals between other activity - in |
1983 |
our example, within 60 seconds, there are usually many I/O events with |
1984 |
associated activity resets. |
1985 |
|
1986 |
In this case, it would be more efficient to leave the C<ev_timer> alone, |
1987 |
but remember the time of last activity, and check for a real timeout only |
1988 |
within the callback: |
1989 |
|
1990 |
ev_tstamp timeout = 60.; |
1991 |
ev_tstamp last_activity; // time of last activity |
1992 |
ev_timer timer; |
1993 |
|
1994 |
static void |
1995 |
callback (EV_P_ ev_timer *w, int revents) |
1996 |
{ |
1997 |
// calculate when the timeout would happen |
1998 |
ev_tstamp after = last_activity - ev_now (EV_A) + timeout; |
1999 |
|
2000 |
// if negative, it means we the timeout already occurred |
2001 |
if (after < 0.) |
2002 |
{ |
2003 |
// timeout occurred, take action |
2004 |
} |
2005 |
else |
2006 |
{ |
2007 |
// callback was invoked, but there was some recent |
2008 |
// activity. simply restart the timer to time out |
2009 |
// after "after" seconds, which is the earliest time |
2010 |
// the timeout can occur. |
2011 |
ev_timer_set (w, after, 0.); |
2012 |
ev_timer_start (EV_A_ w); |
2013 |
} |
2014 |
} |
2015 |
|
2016 |
To summarise the callback: first calculate in how many seconds the |
2017 |
timeout will occur (by calculating the absolute time when it would occur, |
2018 |
C<last_activity + timeout>, and subtracting the current time, C<ev_now |
2019 |
(EV_A)> from that). |
2020 |
|
2021 |
If this value is negative, then we are already past the timeout, i.e. we |
2022 |
timed out, and need to do whatever is needed in this case. |
2023 |
|
2024 |
Otherwise, we now the earliest time at which the timeout would trigger, |
2025 |
and simply start the timer with this timeout value. |
2026 |
|
2027 |
In other words, each time the callback is invoked it will check whether |
2028 |
the timeout occurred. If not, it will simply reschedule itself to check |
2029 |
again at the earliest time it could time out. Rinse. Repeat. |
2030 |
|
2031 |
This scheme causes more callback invocations (about one every 60 seconds |
2032 |
minus half the average time between activity), but virtually no calls to |
2033 |
libev to change the timeout. |
2034 |
|
2035 |
To start the machinery, simply initialise the watcher and set |
2036 |
C<last_activity> to the current time (meaning there was some activity just |
2037 |
now), then call the callback, which will "do the right thing" and start |
2038 |
the timer: |
2039 |
|
2040 |
last_activity = ev_now (EV_A); |
2041 |
ev_init (&timer, callback); |
2042 |
callback (EV_A_ &timer, 0); |
2043 |
|
2044 |
When there is some activity, simply store the current time in |
2045 |
C<last_activity>, no libev calls at all: |
2046 |
|
2047 |
if (activity detected) |
2048 |
last_activity = ev_now (EV_A); |
2049 |
|
2050 |
When your timeout value changes, then the timeout can be changed by simply |
2051 |
providing a new value, stopping the timer and calling the callback, which |
2052 |
will again do the right thing (for example, time out immediately :). |
2053 |
|
2054 |
timeout = new_value; |
2055 |
ev_timer_stop (EV_A_ &timer); |
2056 |
callback (EV_A_ &timer, 0); |
2057 |
|
2058 |
This technique is slightly more complex, but in most cases where the |
2059 |
time-out is unlikely to be triggered, much more efficient. |
2060 |
|
2061 |
=item 4. Wee, just use a double-linked list for your timeouts. |
2062 |
|
2063 |
If there is not one request, but many thousands (millions...), all |
2064 |
employing some kind of timeout with the same timeout value, then one can |
2065 |
do even better: |
2066 |
|
2067 |
When starting the timeout, calculate the timeout value and put the timeout |
2068 |
at the I<end> of the list. |
2069 |
|
2070 |
Then use an C<ev_timer> to fire when the timeout at the I<beginning> of |
2071 |
the list is expected to fire (for example, using the technique #3). |
2072 |
|
2073 |
When there is some activity, remove the timer from the list, recalculate |
2074 |
the timeout, append it to the end of the list again, and make sure to |
2075 |
update the C<ev_timer> if it was taken from the beginning of the list. |
2076 |
|
2077 |
This way, one can manage an unlimited number of timeouts in O(1) time for |
2078 |
starting, stopping and updating the timers, at the expense of a major |
2079 |
complication, and having to use a constant timeout. The constant timeout |
2080 |
ensures that the list stays sorted. |
2081 |
|
2082 |
=back |
2083 |
|
2084 |
So which method the best? |
2085 |
|
2086 |
Method #2 is a simple no-brain-required solution that is adequate in most |
2087 |
situations. Method #3 requires a bit more thinking, but handles many cases |
2088 |
better, and isn't very complicated either. In most case, choosing either |
2089 |
one is fine, with #3 being better in typical situations. |
2090 |
|
2091 |
Method #1 is almost always a bad idea, and buys you nothing. Method #4 is |
2092 |
rather complicated, but extremely efficient, something that really pays |
2093 |
off after the first million or so of active timers, i.e. it's usually |
2094 |
overkill :) |
2095 |
|
2096 |
=head3 The special problem of being too early |
2097 |
|
2098 |
If you ask a timer to call your callback after three seconds, then |
2099 |
you expect it to be invoked after three seconds - but of course, this |
2100 |
cannot be guaranteed to infinite precision. Less obviously, it cannot be |
2101 |
guaranteed to any precision by libev - imagine somebody suspending the |
2102 |
process with a STOP signal for a few hours for example. |
2103 |
|
2104 |
So, libev tries to invoke your callback as soon as possible I<after> the |
2105 |
delay has occurred, but cannot guarantee this. |
2106 |
|
2107 |
A less obvious failure mode is calling your callback too early: many event |
2108 |
loops compare timestamps with a "elapsed delay >= requested delay", but |
2109 |
this can cause your callback to be invoked much earlier than you would |
2110 |
expect. |
2111 |
|
2112 |
To see why, imagine a system with a clock that only offers full second |
2113 |
resolution (think windows if you can't come up with a broken enough OS |
2114 |
yourself). If you schedule a one-second timer at the time 500.9, then the |
2115 |
event loop will schedule your timeout to elapse at a system time of 500 |
2116 |
(500.9 truncated to the resolution) + 1, or 501. |
2117 |
|
2118 |
If an event library looks at the timeout 0.1s later, it will see "501 >= |
2119 |
501" and invoke the callback 0.1s after it was started, even though a |
2120 |
one-second delay was requested - this is being "too early", despite best |
2121 |
intentions. |
2122 |
|
2123 |
This is the reason why libev will never invoke the callback if the elapsed |
2124 |
delay equals the requested delay, but only when the elapsed delay is |
2125 |
larger than the requested delay. In the example above, libev would only invoke |
2126 |
the callback at system time 502, or 1.1s after the timer was started. |
2127 |
|
2128 |
So, while libev cannot guarantee that your callback will be invoked |
2129 |
exactly when requested, it I<can> and I<does> guarantee that the requested |
2130 |
delay has actually elapsed, or in other words, it always errs on the "too |
2131 |
late" side of things. |
2132 |
|
2133 |
=head3 The special problem of time updates |
2134 |
|
2135 |
Establishing the current time is a costly operation (it usually takes |
2136 |
at least one system call): EV therefore updates its idea of the current |
2137 |
time only before and after C<ev_run> collects new events, which causes a |
2138 |
growing difference between C<ev_now ()> and C<ev_time ()> when handling |
2139 |
lots of events in one iteration. |
2140 |
|
2141 |
The relative timeouts are calculated relative to the C<ev_now ()> |
2142 |
time. This is usually the right thing as this timestamp refers to the time |
2143 |
of the event triggering whatever timeout you are modifying/starting. If |
2144 |
you suspect event processing to be delayed and you I<need> to base the |
2145 |
timeout on the current time, use something like the following to adjust |
2146 |
for it: |
2147 |
|
2148 |
ev_timer_set (&timer, after + (ev_time () - ev_now ()), 0.); |
2149 |
|
2150 |
If the event loop is suspended for a long time, you can also force an |
2151 |
update of the time returned by C<ev_now ()> by calling C<ev_now_update |
2152 |
()>, although that will push the event time of all outstanding events |
2153 |
further into the future. |
2154 |
|
2155 |
=head3 The special problem of unsynchronised clocks |
2156 |
|
2157 |
Modern systems have a variety of clocks - libev itself uses the normal |
2158 |
"wall clock" clock and, if available, the monotonic clock (to avoid time |
2159 |
jumps). |
2160 |
|
2161 |
Neither of these clocks is synchronised with each other or any other clock |
2162 |
on the system, so C<ev_time ()> might return a considerably different time |
2163 |
than C<gettimeofday ()> or C<time ()>. On a GNU/Linux system, for example, |
2164 |
a call to C<gettimeofday> might return a second count that is one higher |
2165 |
than a directly following call to C<time>. |
2166 |
|
2167 |
The moral of this is to only compare libev-related timestamps with |
2168 |
C<ev_time ()> and C<ev_now ()>, at least if you want better precision than |
2169 |
a second or so. |
2170 |
|
2171 |
One more problem arises due to this lack of synchronisation: if libev uses |
2172 |
the system monotonic clock and you compare timestamps from C<ev_time> |
2173 |
or C<ev_now> from when you started your timer and when your callback is |
2174 |
invoked, you will find that sometimes the callback is a bit "early". |
2175 |
|
2176 |
This is because C<ev_timer>s work in real time, not wall clock time, so |
2177 |
libev makes sure your callback is not invoked before the delay happened, |
2178 |
I<measured according to the real time>, not the system clock. |
2179 |
|
2180 |
If your timeouts are based on a physical timescale (e.g. "time out this |
2181 |
connection after 100 seconds") then this shouldn't bother you as it is |
2182 |
exactly the right behaviour. |
2183 |
|
2184 |
If you want to compare wall clock/system timestamps to your timers, then |
2185 |
you need to use C<ev_periodic>s, as these are based on the wall clock |
2186 |
time, where your comparisons will always generate correct results. |
2187 |
|
2188 |
=head3 The special problems of suspended animation |
2189 |
|
2190 |
When you leave the server world it is quite customary to hit machines that |
2191 |
can suspend/hibernate - what happens to the clocks during such a suspend? |
2192 |
|
2193 |
Some quick tests made with a Linux 2.6.28 indicate that a suspend freezes |
2194 |
all processes, while the clocks (C<times>, C<CLOCK_MONOTONIC>) continue |
2195 |
to run until the system is suspended, but they will not advance while the |
2196 |
system is suspended. That means, on resume, it will be as if the program |
2197 |
was frozen for a few seconds, but the suspend time will not be counted |
2198 |
towards C<ev_timer> when a monotonic clock source is used. The real time |
2199 |
clock advanced as expected, but if it is used as sole clocksource, then a |
2200 |
long suspend would be detected as a time jump by libev, and timers would |
2201 |
be adjusted accordingly. |
2202 |
|
2203 |
I would not be surprised to see different behaviour in different between |
2204 |
operating systems, OS versions or even different hardware. |
2205 |
|
2206 |
The other form of suspend (job control, or sending a SIGSTOP) will see a |
2207 |
time jump in the monotonic clocks and the realtime clock. If the program |
2208 |
is suspended for a very long time, and monotonic clock sources are in use, |
2209 |
then you can expect C<ev_timer>s to expire as the full suspension time |
2210 |
will be counted towards the timers. When no monotonic clock source is in |
2211 |
use, then libev will again assume a timejump and adjust accordingly. |
2212 |
|
2213 |
It might be beneficial for this latter case to call C<ev_suspend> |
2214 |
and C<ev_resume> in code that handles C<SIGTSTP>, to at least get |
2215 |
deterministic behaviour in this case (you can do nothing against |
2216 |
C<SIGSTOP>). |
2217 |
|
2218 |
=head3 Watcher-Specific Functions and Data Members |
2219 |
|
2220 |
=over 4 |
2221 |
|
2222 |
=item ev_timer_init (ev_timer *, callback, ev_tstamp after, ev_tstamp repeat) |
2223 |
|
2224 |
=item ev_timer_set (ev_timer *, ev_tstamp after, ev_tstamp repeat) |
2225 |
|
2226 |
Configure the timer to trigger after C<after> seconds (fractional and |
2227 |
negative values are supported). If C<repeat> is C<0.>, then it will |
2228 |
automatically be stopped once the timeout is reached. If it is positive, |
2229 |
then the timer will automatically be configured to trigger again C<repeat> |
2230 |
seconds later, again, and again, until stopped manually. |
2231 |
|
2232 |
The timer itself will do a best-effort at avoiding drift, that is, if |
2233 |
you configure a timer to trigger every 10 seconds, then it will normally |
2234 |
trigger at exactly 10 second intervals. If, however, your program cannot |
2235 |
keep up with the timer (because it takes longer than those 10 seconds to |
2236 |
do stuff) the timer will not fire more than once per event loop iteration. |
2237 |
|
2238 |
=item ev_timer_again (loop, ev_timer *) |
2239 |
|
2240 |
This will act as if the timer timed out, and restarts it again if it is |
2241 |
repeating. It basically works like calling C<ev_timer_stop>, updating the |
2242 |
timeout to the C<repeat> value and calling C<ev_timer_start>. |
2243 |
|
2244 |
The exact semantics are as in the following rules, all of which will be |
2245 |
applied to the watcher: |
2246 |
|
2247 |
=over 4 |
2248 |
|
2249 |
=item If the timer is pending, the pending status is always cleared. |
2250 |
|
2251 |
=item If the timer is started but non-repeating, stop it (as if it timed |
2252 |
out, without invoking it). |
2253 |
|
2254 |
=item If the timer is repeating, make the C<repeat> value the new timeout |
2255 |
and start the timer, if necessary. |
2256 |
|
2257 |
=back |
2258 |
|
2259 |
This sounds a bit complicated, see L</Be smart about timeouts>, above, for a |
2260 |
usage example. |
2261 |
|
2262 |
=item ev_tstamp ev_timer_remaining (loop, ev_timer *) |
2263 |
|
2264 |
Returns the remaining time until a timer fires. If the timer is active, |
2265 |
then this time is relative to the current event loop time, otherwise it's |
2266 |
the timeout value currently configured. |
2267 |
|
2268 |
That is, after an C<ev_timer_set (w, 5, 7)>, C<ev_timer_remaining> returns |
2269 |
C<5>. When the timer is started and one second passes, C<ev_timer_remaining> |
2270 |
will return C<4>. When the timer expires and is restarted, it will return |
2271 |
roughly C<7> (likely slightly less as callback invocation takes some time, |
2272 |
too), and so on. |
2273 |
|
2274 |
=item ev_tstamp repeat [read-write] |
2275 |
|
2276 |
The current C<repeat> value. Will be used each time the watcher times out |
2277 |
or C<ev_timer_again> is called, and determines the next timeout (if any), |
2278 |
which is also when any modifications are taken into account. |
2279 |
|
2280 |
=back |
2281 |
|
2282 |
=head3 Examples |
2283 |
|
2284 |
Example: Create a timer that fires after 60 seconds. |
2285 |
|
2286 |
static void |
2287 |
one_minute_cb (struct ev_loop *loop, ev_timer *w, int revents) |
2288 |
{ |
2289 |
.. one minute over, w is actually stopped right here |
2290 |
} |
2291 |
|
2292 |
ev_timer mytimer; |
2293 |
ev_timer_init (&mytimer, one_minute_cb, 60., 0.); |
2294 |
ev_timer_start (loop, &mytimer); |
2295 |
|
2296 |
Example: Create a timeout timer that times out after 10 seconds of |
2297 |
inactivity. |
2298 |
|
2299 |
static void |
2300 |
timeout_cb (struct ev_loop *loop, ev_timer *w, int revents) |
2301 |
{ |
2302 |
.. ten seconds without any activity |
2303 |
} |
2304 |
|
2305 |
ev_timer mytimer; |
2306 |
ev_timer_init (&mytimer, timeout_cb, 0., 10.); /* note, only repeat used */ |
2307 |
ev_timer_again (&mytimer); /* start timer */ |
2308 |
ev_run (loop, 0); |
2309 |
|
2310 |
// and in some piece of code that gets executed on any "activity": |
2311 |
// reset the timeout to start ticking again at 10 seconds |
2312 |
ev_timer_again (&mytimer); |
2313 |
|
2314 |
|
2315 |
=head2 C<ev_periodic> - to cron or not to cron? |
2316 |
|
2317 |
Periodic watchers are also timers of a kind, but they are very versatile |
2318 |
(and unfortunately a bit complex). |
2319 |
|
2320 |
Unlike C<ev_timer>, periodic watchers are not based on real time (or |
2321 |
relative time, the physical time that passes) but on wall clock time |
2322 |
(absolute time, the thing you can read on your calendar or clock). The |
2323 |
difference is that wall clock time can run faster or slower than real |
2324 |
time, and time jumps are not uncommon (e.g. when you adjust your |
2325 |
wrist-watch). |
2326 |
|
2327 |
You can tell a periodic watcher to trigger after some specific point |
2328 |
in time: for example, if you tell a periodic watcher to trigger "in 10 |
2329 |
seconds" (by specifying e.g. C<ev_now () + 10.>, that is, an absolute time |
2330 |
not a delay) and then reset your system clock to January of the previous |
2331 |
year, then it will take a year or more to trigger the event (unlike an |
2332 |
C<ev_timer>, which would still trigger roughly 10 seconds after starting |
2333 |
it, as it uses a relative timeout). |
2334 |
|
2335 |
C<ev_periodic> watchers can also be used to implement vastly more complex |
2336 |
timers, such as triggering an event on each "midnight, local time", or |
2337 |
other complicated rules. This cannot easily be done with C<ev_timer> |
2338 |
watchers, as those cannot react to time jumps. |
2339 |
|
2340 |
As with timers, the callback is guaranteed to be invoked only when the |
2341 |
point in time where it is supposed to trigger has passed. If multiple |
2342 |
timers become ready during the same loop iteration then the ones with |
2343 |
earlier time-out values are invoked before ones with later time-out values |
2344 |
(but this is no longer true when a callback calls C<ev_run> recursively). |
2345 |
|
2346 |
=head3 Watcher-Specific Functions and Data Members |
2347 |
|
2348 |
=over 4 |
2349 |
|
2350 |
=item ev_periodic_init (ev_periodic *, callback, ev_tstamp offset, ev_tstamp interval, reschedule_cb) |
2351 |
|
2352 |
=item ev_periodic_set (ev_periodic *, ev_tstamp offset, ev_tstamp interval, reschedule_cb) |
2353 |
|
2354 |
Lots of arguments, let's sort it out... There are basically three modes of |
2355 |
operation, and we will explain them from simplest to most complex: |
2356 |
|
2357 |
=over 4 |
2358 |
|
2359 |
=item * absolute timer (offset = absolute time, interval = 0, reschedule_cb = 0) |
2360 |
|
2361 |
In this configuration the watcher triggers an event after the wall clock |
2362 |
time C<offset> has passed. It will not repeat and will not adjust when a |
2363 |
time jump occurs, that is, if it is to be run at January 1st 2011 then it |
2364 |
will be stopped and invoked when the system clock reaches or surpasses |
2365 |
this point in time. |
2366 |
|
2367 |
=item * repeating interval timer (offset = offset within interval, interval > 0, reschedule_cb = 0) |
2368 |
|
2369 |
In this mode the watcher will always be scheduled to time out at the next |
2370 |
C<offset + N * interval> time (for some integer N, which can also be |
2371 |
negative) and then repeat, regardless of any time jumps. The C<offset> |
2372 |
argument is merely an offset into the C<interval> periods. |
2373 |
|
2374 |
This can be used to create timers that do not drift with respect to the |
2375 |
system clock, for example, here is an C<ev_periodic> that triggers each |
2376 |
hour, on the hour (with respect to UTC): |
2377 |
|
2378 |
ev_periodic_set (&periodic, 0., 3600., 0); |
2379 |
|
2380 |
This doesn't mean there will always be 3600 seconds in between triggers, |
2381 |
but only that the callback will be called when the system time shows a |
2382 |
full hour (UTC), or more correctly, when the system time is evenly divisible |
2383 |
by 3600. |
2384 |
|
2385 |
Another way to think about it (for the mathematically inclined) is that |
2386 |
C<ev_periodic> will try to run the callback in this mode at the next possible |
2387 |
time where C<time = offset (mod interval)>, regardless of any time jumps. |
2388 |
|
2389 |
The C<interval> I<MUST> be positive, and for numerical stability, the |
2390 |
interval value should be higher than C<1/8192> (which is around 100 |
2391 |
microseconds) and C<offset> should be higher than C<0> and should have |
2392 |
at most a similar magnitude as the current time (say, within a factor of |
2393 |
ten). Typical values for offset are, in fact, C<0> or something between |
2394 |
C<0> and C<interval>, which is also the recommended range. |
2395 |
|
2396 |
Note also that there is an upper limit to how often a timer can fire (CPU |
2397 |
speed for example), so if C<interval> is very small then timing stability |
2398 |
will of course deteriorate. Libev itself tries to be exact to be about one |
2399 |
millisecond (if the OS supports it and the machine is fast enough). |
2400 |
|
2401 |
=item * manual reschedule mode (offset ignored, interval ignored, reschedule_cb = callback) |
2402 |
|
2403 |
In this mode the values for C<interval> and C<offset> are both being |
2404 |
ignored. Instead, each time the periodic watcher gets scheduled, the |
2405 |
reschedule callback will be called with the watcher as first, and the |
2406 |
current time as second argument. |
2407 |
|
2408 |
NOTE: I<This callback MUST NOT stop or destroy any periodic watcher, ever, |
2409 |
or make ANY other event loop modifications whatsoever, unless explicitly |
2410 |
allowed by documentation here>. |
2411 |
|
2412 |
If you need to stop it, return C<now + 1e30> (or so, fudge fudge) and stop |
2413 |
it afterwards (e.g. by starting an C<ev_prepare> watcher, which is the |
2414 |
only event loop modification you are allowed to do). |
2415 |
|
2416 |
The callback prototype is C<ev_tstamp (*reschedule_cb)(ev_periodic |
2417 |
*w, ev_tstamp now)>, e.g.: |
2418 |
|
2419 |
static ev_tstamp |
2420 |
my_rescheduler (ev_periodic *w, ev_tstamp now) |
2421 |
{ |
2422 |
return now + 60.; |
2423 |
} |
2424 |
|
2425 |
It must return the next time to trigger, based on the passed time value |
2426 |
(that is, the lowest time value larger than to the second argument). It |
2427 |
will usually be called just before the callback will be triggered, but |
2428 |
might be called at other times, too. |
2429 |
|
2430 |
NOTE: I<< This callback must always return a time that is higher than or |
2431 |
equal to the passed C<now> value >>. |
2432 |
|
2433 |
This can be used to create very complex timers, such as a timer that |
2434 |
triggers on "next midnight, local time". To do this, you would calculate |
2435 |
the next midnight after C<now> and return the timestamp value for |
2436 |
this. Here is a (completely untested, no error checking) example on how to |
2437 |
do this: |
2438 |
|
2439 |
#include <time.h> |
2440 |
|
2441 |
static ev_tstamp |
2442 |
my_rescheduler (ev_periodic *w, ev_tstamp now) |
2443 |
{ |
2444 |
time_t tnow = (time_t)now; |
2445 |
struct tm tm; |
2446 |
localtime_r (&tnow, &tm); |
2447 |
|
2448 |
tm.tm_sec = tm.tm_min = tm.tm_hour = 0; // midnight current day |
2449 |
++tm.tm_mday; // midnight next day |
2450 |
|
2451 |
return mktime (&tm); |
2452 |
} |
2453 |
|
2454 |
Note: this code might run into trouble on days that have more then two |
2455 |
midnights (beginning and end). |
2456 |
|
2457 |
=back |
2458 |
|
2459 |
=item ev_periodic_again (loop, ev_periodic *) |
2460 |
|
2461 |
Simply stops and restarts the periodic watcher again. This is only useful |
2462 |
when you changed some parameters or the reschedule callback would return |
2463 |
a different time than the last time it was called (e.g. in a crond like |
2464 |
program when the crontabs have changed). |
2465 |
|
2466 |
=item ev_tstamp ev_periodic_at (ev_periodic *) |
2467 |
|
2468 |
When active, returns the absolute time that the watcher is supposed |
2469 |
to trigger next. This is not the same as the C<offset> argument to |
2470 |
C<ev_periodic_set>, but indeed works even in interval and manual |
2471 |
rescheduling modes. |
2472 |
|
2473 |
=item ev_tstamp offset [read-write] |
2474 |
|
2475 |
When repeating, this contains the offset value, otherwise this is the |
2476 |
absolute point in time (the C<offset> value passed to C<ev_periodic_set>, |
2477 |
although libev might modify this value for better numerical stability). |
2478 |
|
2479 |
Can be modified any time, but changes only take effect when the periodic |
2480 |
timer fires or C<ev_periodic_again> is being called. |
2481 |
|
2482 |
=item ev_tstamp interval [read-write] |
2483 |
|
2484 |
The current interval value. Can be modified any time, but changes only |
2485 |
take effect when the periodic timer fires or C<ev_periodic_again> is being |
2486 |
called. |
2487 |
|
2488 |
=item ev_tstamp (*reschedule_cb)(ev_periodic *w, ev_tstamp now) [read-write] |
2489 |
|
2490 |
The current reschedule callback, or C<0>, if this functionality is |
2491 |
switched off. Can be changed any time, but changes only take effect when |
2492 |
the periodic timer fires or C<ev_periodic_again> is being called. |
2493 |
|
2494 |
=back |
2495 |
|
2496 |
=head3 Examples |
2497 |
|
2498 |
Example: Call a callback every hour, or, more precisely, whenever the |
2499 |
system time is divisible by 3600. The callback invocation times have |
2500 |
potentially a lot of jitter, but good long-term stability. |
2501 |
|
2502 |
static void |
2503 |
clock_cb (struct ev_loop *loop, ev_periodic *w, int revents) |
2504 |
{ |
2505 |
... its now a full hour (UTC, or TAI or whatever your clock follows) |
2506 |
} |
2507 |
|
2508 |
ev_periodic hourly_tick; |
2509 |
ev_periodic_init (&hourly_tick, clock_cb, 0., 3600., 0); |
2510 |
ev_periodic_start (loop, &hourly_tick); |
2511 |
|
2512 |
Example: The same as above, but use a reschedule callback to do it: |
2513 |
|
2514 |
#include <math.h> |
2515 |
|
2516 |
static ev_tstamp |
2517 |
my_scheduler_cb (ev_periodic *w, ev_tstamp now) |
2518 |
{ |
2519 |
return now + (3600. - fmod (now, 3600.)); |
2520 |
} |
2521 |
|
2522 |
ev_periodic_init (&hourly_tick, clock_cb, 0., 0., my_scheduler_cb); |
2523 |
|
2524 |
Example: Call a callback every hour, starting now: |
2525 |
|
2526 |
ev_periodic hourly_tick; |
2527 |
ev_periodic_init (&hourly_tick, clock_cb, |
2528 |
fmod (ev_now (loop), 3600.), 3600., 0); |
2529 |
ev_periodic_start (loop, &hourly_tick); |
2530 |
|
2531 |
|
2532 |
=head2 C<ev_signal> - signal me when a signal gets signalled! |
2533 |
|
2534 |
Signal watchers will trigger an event when the process receives a specific |
2535 |
signal one or more times. Even though signals are very asynchronous, libev |
2536 |
will try its best to deliver signals synchronously, i.e. as part of the |
2537 |
normal event processing, like any other event. |
2538 |
|
2539 |
If you want signals to be delivered truly asynchronously, just use |
2540 |
C<sigaction> as you would do without libev and forget about sharing |
2541 |
the signal. You can even use C<ev_async> from a signal handler to |
2542 |
synchronously wake up an event loop. |
2543 |
|
2544 |
You can configure as many watchers as you like for the same signal, but |
2545 |
only within the same loop, i.e. you can watch for C<SIGINT> in your |
2546 |
default loop and for C<SIGIO> in another loop, but you cannot watch for |
2547 |
C<SIGINT> in both the default loop and another loop at the same time. At |
2548 |
the moment, C<SIGCHLD> is permanently tied to the default loop. |
2549 |
|
2550 |
Only after the first watcher for a signal is started will libev actually |
2551 |
register something with the kernel. It thus coexists with your own signal |
2552 |
handlers as long as you don't register any with libev for the same signal. |
2553 |
|
2554 |
If possible and supported, libev will install its handlers with |
2555 |
C<SA_RESTART> (or equivalent) behaviour enabled, so system calls should |
2556 |
not be unduly interrupted. If you have a problem with system calls getting |
2557 |
interrupted by signals you can block all signals in an C<ev_check> watcher |
2558 |
and unblock them in an C<ev_prepare> watcher. |
2559 |
|
2560 |
=head3 The special problem of inheritance over fork/execve/pthread_create |
2561 |
|
2562 |
Both the signal mask (C<sigprocmask>) and the signal disposition |
2563 |
(C<sigaction>) are unspecified after starting a signal watcher (and after |
2564 |
stopping it again), that is, libev might or might not block the signal, |
2565 |
and might or might not set or restore the installed signal handler (but |
2566 |
see C<EVFLAG_NOSIGMASK>). |
2567 |
|
2568 |
While this does not matter for the signal disposition (libev never |
2569 |
sets signals to C<SIG_IGN>, so handlers will be reset to C<SIG_DFL> on |
2570 |
C<execve>), this matters for the signal mask: many programs do not expect |
2571 |
certain signals to be blocked. |
2572 |
|
2573 |
This means that before calling C<exec> (from the child) you should reset |
2574 |
the signal mask to whatever "default" you expect (all clear is a good |
2575 |
choice usually). |
2576 |
|
2577 |
The simplest way to ensure that the signal mask is reset in the child is |
2578 |
to install a fork handler with C<pthread_atfork> that resets it. That will |
2579 |
catch fork calls done by libraries (such as the libc) as well. |
2580 |
|
2581 |
In current versions of libev, the signal will not be blocked indefinitely |
2582 |
unless you use the C<signalfd> API (C<EV_SIGNALFD>). While this reduces |
2583 |
the window of opportunity for problems, it will not go away, as libev |
2584 |
I<has> to modify the signal mask, at least temporarily. |
2585 |
|
2586 |
So I can't stress this enough: I<If you do not reset your signal mask when |
2587 |
you expect it to be empty, you have a race condition in your code>. This |
2588 |
is not a libev-specific thing, this is true for most event libraries. |
2589 |
|
2590 |
=head3 The special problem of threads signal handling |
2591 |
|
2592 |
POSIX threads has problematic signal handling semantics, specifically, |
2593 |
a lot of functionality (sigfd, sigwait etc.) only really works if all |
2594 |
threads in a process block signals, which is hard to achieve. |
2595 |
|
2596 |
When you want to use sigwait (or mix libev signal handling with your own |
2597 |
for the same signals), you can tackle this problem by globally blocking |
2598 |
all signals before creating any threads (or creating them with a fully set |
2599 |
sigprocmask) and also specifying the C<EVFLAG_NOSIGMASK> when creating |
2600 |
loops. Then designate one thread as "signal receiver thread" which handles |
2601 |
these signals. You can pass on any signals that libev might be interested |
2602 |
in by calling C<ev_feed_signal>. |
2603 |
|
2604 |
=head3 Watcher-Specific Functions and Data Members |
2605 |
|
2606 |
=over 4 |
2607 |
|
2608 |
=item ev_signal_init (ev_signal *, callback, int signum) |
2609 |
|
2610 |
=item ev_signal_set (ev_signal *, int signum) |
2611 |
|
2612 |
Configures the watcher to trigger on the given signal number (usually one |
2613 |
of the C<SIGxxx> constants). |
2614 |
|
2615 |
=item int signum [read-only] |
2616 |
|
2617 |
The signal the watcher watches out for. |
2618 |
|
2619 |
=back |
2620 |
|
2621 |
=head3 Examples |
2622 |
|
2623 |
Example: Try to exit cleanly on SIGINT. |
2624 |
|
2625 |
static void |
2626 |
sigint_cb (struct ev_loop *loop, ev_signal *w, int revents) |
2627 |
{ |
2628 |
ev_break (loop, EVBREAK_ALL); |
2629 |
} |
2630 |
|
2631 |
ev_signal signal_watcher; |
2632 |
ev_signal_init (&signal_watcher, sigint_cb, SIGINT); |
2633 |
ev_signal_start (loop, &signal_watcher); |
2634 |
|
2635 |
|
2636 |
=head2 C<ev_child> - watch out for process status changes |
2637 |
|
2638 |
Child watchers trigger when your process receives a SIGCHLD in response to |
2639 |
some child status changes (most typically when a child of yours dies or |
2640 |
exits). It is permissible to install a child watcher I<after> the child |
2641 |
has been forked (which implies it might have already exited), as long |
2642 |
as the event loop isn't entered (or is continued from a watcher), i.e., |
2643 |
forking and then immediately registering a watcher for the child is fine, |
2644 |
but forking and registering a watcher a few event loop iterations later or |
2645 |
in the next callback invocation is not. |
2646 |
|
2647 |
Only the default event loop is capable of handling signals, and therefore |
2648 |
you can only register child watchers in the default event loop. |
2649 |
|
2650 |
Due to some design glitches inside libev, child watchers will always be |
2651 |
handled at maximum priority (their priority is set to C<EV_MAXPRI> by |
2652 |
libev) |
2653 |
|
2654 |
=head3 Process Interaction |
2655 |
|
2656 |
Libev grabs C<SIGCHLD> as soon as the default event loop is |
2657 |
initialised. This is necessary to guarantee proper behaviour even if the |
2658 |
first child watcher is started after the child exits. The occurrence |
2659 |
of C<SIGCHLD> is recorded asynchronously, but child reaping is done |
2660 |
synchronously as part of the event loop processing. Libev always reaps all |
2661 |
children, even ones not watched. |
2662 |
|
2663 |
=head3 Overriding the Built-In Processing |
2664 |
|
2665 |
Libev offers no special support for overriding the built-in child |
2666 |
processing, but if your application collides with libev's default child |
2667 |
handler, you can override it easily by installing your own handler for |
2668 |
C<SIGCHLD> after initialising the default loop, and making sure the |
2669 |
default loop never gets destroyed. You are encouraged, however, to use an |
2670 |
event-based approach to child reaping and thus use libev's support for |
2671 |
that, so other libev users can use C<ev_child> watchers freely. |
2672 |
|
2673 |
=head3 Stopping the Child Watcher |
2674 |
|
2675 |
Currently, the child watcher never gets stopped, even when the |
2676 |
child terminates, so normally one needs to stop the watcher in the |
2677 |
callback. Future versions of libev might stop the watcher automatically |
2678 |
when a child exit is detected (calling C<ev_child_stop> twice is not a |
2679 |
problem). |
2680 |
|
2681 |
=head3 Watcher-Specific Functions and Data Members |
2682 |
|
2683 |
=over 4 |
2684 |
|
2685 |
=item ev_child_init (ev_child *, callback, int pid, int trace) |
2686 |
|
2687 |
=item ev_child_set (ev_child *, int pid, int trace) |
2688 |
|
2689 |
Configures the watcher to wait for status changes of process C<pid> (or |
2690 |
I<any> process if C<pid> is specified as C<0>). The callback can look |
2691 |
at the C<rstatus> member of the C<ev_child> watcher structure to see |
2692 |
the status word (use the macros from C<sys/wait.h> and see your systems |
2693 |
C<waitpid> documentation). The C<rpid> member contains the pid of the |
2694 |
process causing the status change. C<trace> must be either C<0> (only |
2695 |
activate the watcher when the process terminates) or C<1> (additionally |
2696 |
activate the watcher when the process is stopped or continued). |
2697 |
|
2698 |
=item int pid [read-only] |
2699 |
|
2700 |
The process id this watcher watches out for, or C<0>, meaning any process id. |
2701 |
|
2702 |
=item int rpid [read-write] |
2703 |
|
2704 |
The process id that detected a status change. |
2705 |
|
2706 |
=item int rstatus [read-write] |
2707 |
|
2708 |
The process exit/trace status caused by C<rpid> (see your systems |
2709 |
C<waitpid> and C<sys/wait.h> documentation for details). |
2710 |
|
2711 |
=back |
2712 |
|
2713 |
=head3 Examples |
2714 |
|
2715 |
Example: C<fork()> a new process and install a child handler to wait for |
2716 |
its completion. |
2717 |
|
2718 |
ev_child cw; |
2719 |
|
2720 |
static void |
2721 |
child_cb (EV_P_ ev_child *w, int revents) |
2722 |
{ |
2723 |
ev_child_stop (EV_A_ w); |
2724 |
printf ("process %d exited with status %x\n", w->rpid, w->rstatus); |
2725 |
} |
2726 |
|
2727 |
pid_t pid = fork (); |
2728 |
|
2729 |
if (pid < 0) |
2730 |
// error |
2731 |
else if (pid == 0) |
2732 |
{ |
2733 |
// the forked child executes here |
2734 |
exit (1); |
2735 |
} |
2736 |
else |
2737 |
{ |
2738 |
ev_child_init (&cw, child_cb, pid, 0); |
2739 |
ev_child_start (EV_DEFAULT_ &cw); |
2740 |
} |
2741 |
|
2742 |
|
2743 |
=head2 C<ev_stat> - did the file attributes just change? |
2744 |
|
2745 |
This watches a file system path for attribute changes. That is, it calls |
2746 |
C<stat> on that path in regular intervals (or when the OS says it changed) |
2747 |
and sees if it changed compared to the last time, invoking the callback |
2748 |
if it did. Starting the watcher C<stat>'s the file, so only changes that |
2749 |
happen after the watcher has been started will be reported. |
2750 |
|
2751 |
The path does not need to exist: changing from "path exists" to "path does |
2752 |
not exist" is a status change like any other. The condition "path does not |
2753 |
exist" (or more correctly "path cannot be stat'ed") is signified by the |
2754 |
C<st_nlink> field being zero (which is otherwise always forced to be at |
2755 |
least one) and all the other fields of the stat buffer having unspecified |
2756 |
contents. |
2757 |
|
2758 |
The path I<must not> end in a slash or contain special components such as |
2759 |
C<.> or C<..>. The path I<should> be absolute: If it is relative and |
2760 |
your working directory changes, then the behaviour is undefined. |
2761 |
|
2762 |
Since there is no portable change notification interface available, the |
2763 |
portable implementation simply calls C<stat(2)> regularly on the path |
2764 |
to see if it changed somehow. You can specify a recommended polling |
2765 |
interval for this case. If you specify a polling interval of C<0> (highly |
2766 |
recommended!) then a I<suitable, unspecified default> value will be used |
2767 |
(which you can expect to be around five seconds, although this might |
2768 |
change dynamically). Libev will also impose a minimum interval which is |
2769 |
currently around C<0.1>, but that's usually overkill. |
2770 |
|
2771 |
This watcher type is not meant for massive numbers of stat watchers, |
2772 |
as even with OS-supported change notifications, this can be |
2773 |
resource-intensive. |
2774 |
|
2775 |
At the time of this writing, the only OS-specific interface implemented |
2776 |
is the Linux inotify interface (implementing kqueue support is left as an |
2777 |
exercise for the reader. Note, however, that the author sees no way of |
2778 |
implementing C<ev_stat> semantics with kqueue, except as a hint). |
2779 |
|
2780 |
=head3 ABI Issues (Largefile Support) |
2781 |
|
2782 |
Libev by default (unless the user overrides this) uses the default |
2783 |
compilation environment, which means that on systems with large file |
2784 |
support disabled by default, you get the 32 bit version of the stat |
2785 |
structure. When using the library from programs that change the ABI to |
2786 |
use 64 bit file offsets the programs will fail. In that case you have to |
2787 |
compile libev with the same flags to get binary compatibility. This is |
2788 |
obviously the case with any flags that change the ABI, but the problem is |
2789 |
most noticeably displayed with ev_stat and large file support. |
2790 |
|
2791 |
The solution for this is to lobby your distribution maker to make large |
2792 |
file interfaces available by default (as e.g. FreeBSD does) and not |
2793 |
optional. Libev cannot simply switch on large file support because it has |
2794 |
to exchange stat structures with application programs compiled using the |
2795 |
default compilation environment. |
2796 |
|
2797 |
=head3 Inotify and Kqueue |
2798 |
|
2799 |
When C<inotify (7)> support has been compiled into libev and present at |
2800 |
runtime, it will be used to speed up change detection where possible. The |
2801 |
inotify descriptor will be created lazily when the first C<ev_stat> |
2802 |
watcher is being started. |
2803 |
|
2804 |
Inotify presence does not change the semantics of C<ev_stat> watchers |
2805 |
except that changes might be detected earlier, and in some cases, to avoid |
2806 |
making regular C<stat> calls. Even in the presence of inotify support |
2807 |
there are many cases where libev has to resort to regular C<stat> polling, |
2808 |
but as long as kernel 2.6.25 or newer is used (2.6.24 and older have too |
2809 |
many bugs), the path exists (i.e. stat succeeds), and the path resides on |
2810 |
a local filesystem (libev currently assumes only ext2/3, jfs, reiserfs and |
2811 |
xfs are fully working) libev usually gets away without polling. |
2812 |
|
2813 |
There is no support for kqueue, as apparently it cannot be used to |
2814 |
implement this functionality, due to the requirement of having a file |
2815 |
descriptor open on the object at all times, and detecting renames, unlinks |
2816 |
etc. is difficult. |
2817 |
|
2818 |
=head3 C<stat ()> is a synchronous operation |
2819 |
|
2820 |
Libev doesn't normally do any kind of I/O itself, and so is not blocking |
2821 |
the process. The exception are C<ev_stat> watchers - those call C<stat |
2822 |
()>, which is a synchronous operation. |
2823 |
|
2824 |
For local paths, this usually doesn't matter: unless the system is very |
2825 |
busy or the intervals between stat's are large, a stat call will be fast, |
2826 |
as the path data is usually in memory already (except when starting the |
2827 |
watcher). |
2828 |
|
2829 |
For networked file systems, calling C<stat ()> can block an indefinite |
2830 |
time due to network issues, and even under good conditions, a stat call |
2831 |
often takes multiple milliseconds. |
2832 |
|
2833 |
Therefore, it is best to avoid using C<ev_stat> watchers on networked |
2834 |
paths, although this is fully supported by libev. |
2835 |
|
2836 |
=head3 The special problem of stat time resolution |
2837 |
|
2838 |
The C<stat ()> system call only supports full-second resolution portably, |
2839 |
and even on systems where the resolution is higher, most file systems |
2840 |
still only support whole seconds. |
2841 |
|
2842 |
That means that, if the time is the only thing that changes, you can |
2843 |
easily miss updates: on the first update, C<ev_stat> detects a change and |
2844 |
calls your callback, which does something. When there is another update |
2845 |
within the same second, C<ev_stat> will be unable to detect unless the |
2846 |
stat data does change in other ways (e.g. file size). |
2847 |
|
2848 |
The solution to this is to delay acting on a change for slightly more |
2849 |
than a second (or till slightly after the next full second boundary), using |
2850 |
a roughly one-second-delay C<ev_timer> (e.g. C<ev_timer_set (w, 0., 1.02); |
2851 |
ev_timer_again (loop, w)>). |
2852 |
|
2853 |
The C<.02> offset is added to work around small timing inconsistencies |
2854 |
of some operating systems (where the second counter of the current time |
2855 |
might be be delayed. One such system is the Linux kernel, where a call to |
2856 |
C<gettimeofday> might return a timestamp with a full second later than |
2857 |
a subsequent C<time> call - if the equivalent of C<time ()> is used to |
2858 |
update file times then there will be a small window where the kernel uses |
2859 |
the previous second to update file times but libev might already execute |
2860 |
the timer callback). |
2861 |
|
2862 |
=head3 Watcher-Specific Functions and Data Members |
2863 |
|
2864 |
=over 4 |
2865 |
|
2866 |
=item ev_stat_init (ev_stat *, callback, const char *path, ev_tstamp interval) |
2867 |
|
2868 |
=item ev_stat_set (ev_stat *, const char *path, ev_tstamp interval) |
2869 |
|
2870 |
Configures the watcher to wait for status changes of the given |
2871 |
C<path>. The C<interval> is a hint on how quickly a change is expected to |
2872 |
be detected and should normally be specified as C<0> to let libev choose |
2873 |
a suitable value. The memory pointed to by C<path> must point to the same |
2874 |
path for as long as the watcher is active. |
2875 |
|
2876 |
The callback will receive an C<EV_STAT> event when a change was detected, |
2877 |
relative to the attributes at the time the watcher was started (or the |
2878 |
last change was detected). |
2879 |
|
2880 |
=item ev_stat_stat (loop, ev_stat *) |
2881 |
|
2882 |
Updates the stat buffer immediately with new values. If you change the |
2883 |
watched path in your callback, you could call this function to avoid |
2884 |
detecting this change (while introducing a race condition if you are not |
2885 |
the only one changing the path). Can also be useful simply to find out the |
2886 |
new values. |
2887 |
|
2888 |
=item ev_statdata attr [read-only] |
2889 |
|
2890 |
The most-recently detected attributes of the file. Although the type is |
2891 |
C<ev_statdata>, this is usually the (or one of the) C<struct stat> types |
2892 |
suitable for your system, but you can only rely on the POSIX-standardised |
2893 |
members to be present. If the C<st_nlink> member is C<0>, then there was |
2894 |
some error while C<stat>ing the file. |
2895 |
|
2896 |
=item ev_statdata prev [read-only] |
2897 |
|
2898 |
The previous attributes of the file. The callback gets invoked whenever |
2899 |
C<prev> != C<attr>, or, more precisely, one or more of these members |
2900 |
differ: C<st_dev>, C<st_ino>, C<st_mode>, C<st_nlink>, C<st_uid>, |
2901 |
C<st_gid>, C<st_rdev>, C<st_size>, C<st_atime>, C<st_mtime>, C<st_ctime>. |
2902 |
|
2903 |
=item ev_tstamp interval [read-only] |
2904 |
|
2905 |
The specified interval. |
2906 |
|
2907 |
=item const char *path [read-only] |
2908 |
|
2909 |
The file system path that is being watched. |
2910 |
|
2911 |
=back |
2912 |
|
2913 |
=head3 Examples |
2914 |
|
2915 |
Example: Watch C</etc/passwd> for attribute changes. |
2916 |
|
2917 |
static void |
2918 |
passwd_cb (struct ev_loop *loop, ev_stat *w, int revents) |
2919 |
{ |
2920 |
/* /etc/passwd changed in some way */ |
2921 |
if (w->attr.st_nlink) |
2922 |
{ |
2923 |
printf ("passwd current size %ld\n", (long)w->attr.st_size); |
2924 |
printf ("passwd current atime %ld\n", (long)w->attr.st_mtime); |
2925 |
printf ("passwd current mtime %ld\n", (long)w->attr.st_mtime); |
2926 |
} |
2927 |
else |
2928 |
/* you shalt not abuse printf for puts */ |
2929 |
puts ("wow, /etc/passwd is not there, expect problems. " |
2930 |
"if this is windows, they already arrived\n"); |
2931 |
} |
2932 |
|
2933 |
... |
2934 |
ev_stat passwd; |
2935 |
|
2936 |
ev_stat_init (&passwd, passwd_cb, "/etc/passwd", 0.); |
2937 |
ev_stat_start (loop, &passwd); |
2938 |
|
2939 |
Example: Like above, but additionally use a one-second delay so we do not |
2940 |
miss updates (however, frequent updates will delay processing, too, so |
2941 |
one might do the work both on C<ev_stat> callback invocation I<and> on |
2942 |
C<ev_timer> callback invocation). |
2943 |
|
2944 |
static ev_stat passwd; |
2945 |
static ev_timer timer; |
2946 |
|
2947 |
static void |
2948 |
timer_cb (EV_P_ ev_timer *w, int revents) |
2949 |
{ |
2950 |
ev_timer_stop (EV_A_ w); |
2951 |
|
2952 |
/* now it's one second after the most recent passwd change */ |
2953 |
} |
2954 |
|
2955 |
static void |
2956 |
stat_cb (EV_P_ ev_stat *w, int revents) |
2957 |
{ |
2958 |
/* reset the one-second timer */ |
2959 |
ev_timer_again (EV_A_ &timer); |
2960 |
} |
2961 |
|
2962 |
... |
2963 |
ev_stat_init (&passwd, stat_cb, "/etc/passwd", 0.); |
2964 |
ev_stat_start (loop, &passwd); |
2965 |
ev_timer_init (&timer, timer_cb, 0., 1.02); |
2966 |
|
2967 |
|
2968 |
=head2 C<ev_idle> - when you've got nothing better to do... |
2969 |
|
2970 |
Idle watchers trigger events when no other events of the same or higher |
2971 |
priority are pending (prepare, check and other idle watchers do not count |
2972 |
as receiving "events"). |
2973 |
|
2974 |
That is, as long as your process is busy handling sockets or timeouts |
2975 |
(or even signals, imagine) of the same or higher priority it will not be |
2976 |
triggered. But when your process is idle (or only lower-priority watchers |
2977 |
are pending), the idle watchers are being called once per event loop |
2978 |
iteration - until stopped, that is, or your process receives more events |
2979 |
and becomes busy again with higher priority stuff. |
2980 |
|
2981 |
The most noteworthy effect is that as long as any idle watchers are |
2982 |
active, the process will not block when waiting for new events. |
2983 |
|
2984 |
Apart from keeping your process non-blocking (which is a useful |
2985 |
effect on its own sometimes), idle watchers are a good place to do |
2986 |
"pseudo-background processing", or delay processing stuff to after the |
2987 |
event loop has handled all outstanding events. |
2988 |
|
2989 |
=head3 Abusing an C<ev_idle> watcher for its side-effect |
2990 |
|
2991 |
As long as there is at least one active idle watcher, libev will never |
2992 |
sleep unnecessarily. Or in other words, it will loop as fast as possible. |
2993 |
For this to work, the idle watcher doesn't need to be invoked at all - the |
2994 |
lowest priority will do. |
2995 |
|
2996 |
This mode of operation can be useful together with an C<ev_check> watcher, |
2997 |
to do something on each event loop iteration - for example to balance load |
2998 |
between different connections. |
2999 |
|
3000 |
See L</Abusing an ev_check watcher for its side-effect> for a longer |
3001 |
example. |
3002 |
|
3003 |
=head3 Watcher-Specific Functions and Data Members |
3004 |
|
3005 |
=over 4 |
3006 |
|
3007 |
=item ev_idle_init (ev_idle *, callback) |
3008 |
|
3009 |
Initialises and configures the idle watcher - it has no parameters of any |
3010 |
kind. There is a C<ev_idle_set> macro, but using it is utterly pointless, |
3011 |
believe me. |
3012 |
|
3013 |
=back |
3014 |
|
3015 |
=head3 Examples |
3016 |
|
3017 |
Example: Dynamically allocate an C<ev_idle> watcher, start it, and in the |
3018 |
callback, free it. Also, use no error checking, as usual. |
3019 |
|
3020 |
static void |
3021 |
idle_cb (struct ev_loop *loop, ev_idle *w, int revents) |
3022 |
{ |
3023 |
// stop the watcher |
3024 |
ev_idle_stop (loop, w); |
3025 |
|
3026 |
// now we can free it |
3027 |
free (w); |
3028 |
|
3029 |
// now do something you wanted to do when the program has |
3030 |
// no longer anything immediate to do. |
3031 |
} |
3032 |
|
3033 |
ev_idle *idle_watcher = malloc (sizeof (ev_idle)); |
3034 |
ev_idle_init (idle_watcher, idle_cb); |
3035 |
ev_idle_start (loop, idle_watcher); |
3036 |
|
3037 |
|
3038 |
=head2 C<ev_prepare> and C<ev_check> - customise your event loop! |
3039 |
|
3040 |
Prepare and check watchers are often (but not always) used in pairs: |
3041 |
prepare watchers get invoked before the process blocks and check watchers |
3042 |
afterwards. |
3043 |
|
3044 |
You I<must not> call C<ev_run> (or similar functions that enter the |
3045 |
current event loop) or C<ev_loop_fork> from either C<ev_prepare> or |
3046 |
C<ev_check> watchers. Other loops than the current one are fine, |
3047 |
however. The rationale behind this is that you do not need to check |
3048 |
for recursion in those watchers, i.e. the sequence will always be |
3049 |
C<ev_prepare>, blocking, C<ev_check> so if you have one watcher of each |
3050 |
kind they will always be called in pairs bracketing the blocking call. |
3051 |
|
3052 |
Their main purpose is to integrate other event mechanisms into libev and |
3053 |
their use is somewhat advanced. They could be used, for example, to track |
3054 |
variable changes, implement your own watchers, integrate net-snmp or a |
3055 |
coroutine library and lots more. They are also occasionally useful if |
3056 |
you cache some data and want to flush it before blocking (for example, |
3057 |
in X programs you might want to do an C<XFlush ()> in an C<ev_prepare> |
3058 |
watcher). |
3059 |
|
3060 |
This is done by examining in each prepare call which file descriptors |
3061 |
need to be watched by the other library, registering C<ev_io> watchers |
3062 |
for them and starting an C<ev_timer> watcher for any timeouts (many |
3063 |
libraries provide exactly this functionality). Then, in the check watcher, |
3064 |
you check for any events that occurred (by checking the pending status |
3065 |
of all watchers and stopping them) and call back into the library. The |
3066 |
I/O and timer callbacks will never actually be called (but must be valid |
3067 |
nevertheless, because you never know, you know?). |
3068 |
|
3069 |
As another example, the Perl Coro module uses these hooks to integrate |
3070 |
coroutines into libev programs, by yielding to other active coroutines |
3071 |
during each prepare and only letting the process block if no coroutines |
3072 |
are ready to run (it's actually more complicated: it only runs coroutines |
3073 |
with priority higher than or equal to the event loop and one coroutine |
3074 |
of lower priority, but only once, using idle watchers to keep the event |
3075 |
loop from blocking if lower-priority coroutines are active, thus mapping |
3076 |
low-priority coroutines to idle/background tasks). |
3077 |
|
3078 |
When used for this purpose, it is recommended to give C<ev_check> watchers |
3079 |
highest (C<EV_MAXPRI>) priority, to ensure that they are being run before |
3080 |
any other watchers after the poll (this doesn't matter for C<ev_prepare> |
3081 |
watchers). |
3082 |
|
3083 |
Also, C<ev_check> watchers (and C<ev_prepare> watchers, too) should not |
3084 |
activate ("feed") events into libev. While libev fully supports this, they |
3085 |
might get executed before other C<ev_check> watchers did their job. As |
3086 |
C<ev_check> watchers are often used to embed other (non-libev) event |
3087 |
loops those other event loops might be in an unusable state until their |
3088 |
C<ev_check> watcher ran (always remind yourself to coexist peacefully with |
3089 |
others). |
3090 |
|
3091 |
=head3 Abusing an C<ev_check> watcher for its side-effect |
3092 |
|
3093 |
C<ev_check> (and less often also C<ev_prepare>) watchers can also be |
3094 |
useful because they are called once per event loop iteration. For |
3095 |
example, if you want to handle a large number of connections fairly, you |
3096 |
normally only do a bit of work for each active connection, and if there |
3097 |
is more work to do, you wait for the next event loop iteration, so other |
3098 |
connections have a chance of making progress. |
3099 |
|
3100 |
Using an C<ev_check> watcher is almost enough: it will be called on the |
3101 |
next event loop iteration. However, that isn't as soon as possible - |
3102 |
without external events, your C<ev_check> watcher will not be invoked. |
3103 |
|
3104 |
This is where C<ev_idle> watchers come in handy - all you need is a |
3105 |
single global idle watcher that is active as long as you have one active |
3106 |
C<ev_check> watcher. The C<ev_idle> watcher makes sure the event loop |
3107 |
will not sleep, and the C<ev_check> watcher makes sure a callback gets |
3108 |
invoked. Neither watcher alone can do that. |
3109 |
|
3110 |
=head3 Watcher-Specific Functions and Data Members |
3111 |
|
3112 |
=over 4 |
3113 |
|
3114 |
=item ev_prepare_init (ev_prepare *, callback) |
3115 |
|
3116 |
=item ev_check_init (ev_check *, callback) |
3117 |
|
3118 |
Initialises and configures the prepare or check watcher - they have no |
3119 |
parameters of any kind. There are C<ev_prepare_set> and C<ev_check_set> |
3120 |
macros, but using them is utterly, utterly, utterly and completely |
3121 |
pointless. |
3122 |
|
3123 |
=back |
3124 |
|
3125 |
=head3 Examples |
3126 |
|
3127 |
There are a number of principal ways to embed other event loops or modules |
3128 |
into libev. Here are some ideas on how to include libadns into libev |
3129 |
(there is a Perl module named C<EV::ADNS> that does this, which you could |
3130 |
use as a working example. Another Perl module named C<EV::Glib> embeds a |
3131 |
Glib main context into libev, and finally, C<Glib::EV> embeds EV into the |
3132 |
Glib event loop). |
3133 |
|
3134 |
Method 1: Add IO watchers and a timeout watcher in a prepare handler, |
3135 |
and in a check watcher, destroy them and call into libadns. What follows |
3136 |
is pseudo-code only of course. This requires you to either use a low |
3137 |
priority for the check watcher or use C<ev_clear_pending> explicitly, as |
3138 |
the callbacks for the IO/timeout watchers might not have been called yet. |
3139 |
|
3140 |
static ev_io iow [nfd]; |
3141 |
static ev_timer tw; |
3142 |
|
3143 |
static void |
3144 |
io_cb (struct ev_loop *loop, ev_io *w, int revents) |
3145 |
{ |
3146 |
} |
3147 |
|
3148 |
// create io watchers for each fd and a timer before blocking |
3149 |
static void |
3150 |
adns_prepare_cb (struct ev_loop *loop, ev_prepare *w, int revents) |
3151 |
{ |
3152 |
int timeout = 3600000; |
3153 |
struct pollfd fds [nfd]; |
3154 |
// actual code will need to loop here and realloc etc. |
3155 |
adns_beforepoll (ads, fds, &nfd, &timeout, timeval_from (ev_time ())); |
3156 |
|
3157 |
/* the callback is illegal, but won't be called as we stop during check */ |
3158 |
ev_timer_init (&tw, 0, timeout * 1e-3, 0.); |
3159 |
ev_timer_start (loop, &tw); |
3160 |
|
3161 |
// create one ev_io per pollfd |
3162 |
for (int i = 0; i < nfd; ++i) |
3163 |
{ |
3164 |
ev_io_init (iow + i, io_cb, fds [i].fd, |
3165 |
((fds [i].events & POLLIN ? EV_READ : 0) |
3166 |
| (fds [i].events & POLLOUT ? EV_WRITE : 0))); |
3167 |
|
3168 |
fds [i].revents = 0; |
3169 |
ev_io_start (loop, iow + i); |
3170 |
} |
3171 |
} |
3172 |
|
3173 |
// stop all watchers after blocking |
3174 |
static void |
3175 |
adns_check_cb (struct ev_loop *loop, ev_check *w, int revents) |
3176 |
{ |
3177 |
ev_timer_stop (loop, &tw); |
3178 |
|
3179 |
for (int i = 0; i < nfd; ++i) |
3180 |
{ |
3181 |
// set the relevant poll flags |
3182 |
// could also call adns_processreadable etc. here |
3183 |
struct pollfd *fd = fds + i; |
3184 |
int revents = ev_clear_pending (iow + i); |
3185 |
if (revents & EV_READ ) fd->revents |= fd->events & POLLIN; |
3186 |
if (revents & EV_WRITE) fd->revents |= fd->events & POLLOUT; |
3187 |
|
3188 |
// now stop the watcher |
3189 |
ev_io_stop (loop, iow + i); |
3190 |
} |
3191 |
|
3192 |
adns_afterpoll (adns, fds, nfd, timeval_from (ev_now (loop)); |
3193 |
} |
3194 |
|
3195 |
Method 2: This would be just like method 1, but you run C<adns_afterpoll> |
3196 |
in the prepare watcher and would dispose of the check watcher. |
3197 |
|
3198 |
Method 3: If the module to be embedded supports explicit event |
3199 |
notification (libadns does), you can also make use of the actual watcher |
3200 |
callbacks, and only destroy/create the watchers in the prepare watcher. |
3201 |
|
3202 |
static void |
3203 |
timer_cb (EV_P_ ev_timer *w, int revents) |
3204 |
{ |
3205 |
adns_state ads = (adns_state)w->data; |
3206 |
update_now (EV_A); |
3207 |
|
3208 |
adns_processtimeouts (ads, &tv_now); |
3209 |
} |
3210 |
|
3211 |
static void |
3212 |
io_cb (EV_P_ ev_io *w, int revents) |
3213 |
{ |
3214 |
adns_state ads = (adns_state)w->data; |
3215 |
update_now (EV_A); |
3216 |
|
3217 |
if (revents & EV_READ ) adns_processreadable (ads, w->fd, &tv_now); |
3218 |
if (revents & EV_WRITE) adns_processwriteable (ads, w->fd, &tv_now); |
3219 |
} |
3220 |
|
3221 |
// do not ever call adns_afterpoll |
3222 |
|
3223 |
Method 4: Do not use a prepare or check watcher because the module you |
3224 |
want to embed is not flexible enough to support it. Instead, you can |
3225 |
override their poll function. The drawback with this solution is that the |
3226 |
main loop is now no longer controllable by EV. The C<Glib::EV> module uses |
3227 |
this approach, effectively embedding EV as a client into the horrible |
3228 |
libglib event loop. |
3229 |
|
3230 |
static gint |
3231 |
event_poll_func (GPollFD *fds, guint nfds, gint timeout) |
3232 |
{ |
3233 |
int got_events = 0; |
3234 |
|
3235 |
for (n = 0; n < nfds; ++n) |
3236 |
// create/start io watcher that sets the relevant bits in fds[n] and increment got_events |
3237 |
|
3238 |
if (timeout >= 0) |
3239 |
// create/start timer |
3240 |
|
3241 |
// poll |
3242 |
ev_run (EV_A_ 0); |
3243 |
|
3244 |
// stop timer again |
3245 |
if (timeout >= 0) |
3246 |
ev_timer_stop (EV_A_ &to); |
3247 |
|
3248 |
// stop io watchers again - their callbacks should have set |
3249 |
for (n = 0; n < nfds; ++n) |
3250 |
ev_io_stop (EV_A_ iow [n]); |
3251 |
|
3252 |
return got_events; |
3253 |
} |
3254 |
|
3255 |
|
3256 |
=head2 C<ev_embed> - when one backend isn't enough... |
3257 |
|
3258 |
This is a rather advanced watcher type that lets you embed one event loop |
3259 |
into another (currently only C<ev_io> events are supported in the embedded |
3260 |
loop, other types of watchers might be handled in a delayed or incorrect |
3261 |
fashion and must not be used). |
3262 |
|
3263 |
There are primarily two reasons you would want that: work around bugs and |
3264 |
prioritise I/O. |
3265 |
|
3266 |
As an example for a bug workaround, the kqueue backend might only support |
3267 |
sockets on some platform, so it is unusable as generic backend, but you |
3268 |
still want to make use of it because you have many sockets and it scales |
3269 |
so nicely. In this case, you would create a kqueue-based loop and embed |
3270 |
it into your default loop (which might use e.g. poll). Overall operation |
3271 |
will be a bit slower because first libev has to call C<poll> and then |
3272 |
C<kevent>, but at least you can use both mechanisms for what they are |
3273 |
best: C<kqueue> for scalable sockets and C<poll> if you want it to work :) |
3274 |
|
3275 |
As for prioritising I/O: under rare circumstances you have the case where |
3276 |
some fds have to be watched and handled very quickly (with low latency), |
3277 |
and even priorities and idle watchers might have too much overhead. In |
3278 |
this case you would put all the high priority stuff in one loop and all |
3279 |
the rest in a second one, and embed the second one in the first. |
3280 |
|
3281 |
As long as the watcher is active, the callback will be invoked every |
3282 |
time there might be events pending in the embedded loop. The callback |
3283 |
must then call C<ev_embed_sweep (mainloop, watcher)> to make a single |
3284 |
sweep and invoke their callbacks (the callback doesn't need to invoke the |
3285 |
C<ev_embed_sweep> function directly, it could also start an idle watcher |
3286 |
to give the embedded loop strictly lower priority for example). |
3287 |
|
3288 |
You can also set the callback to C<0>, in which case the embed watcher |
3289 |
will automatically execute the embedded loop sweep whenever necessary. |
3290 |
|
3291 |
Fork detection will be handled transparently while the C<ev_embed> watcher |
3292 |
is active, i.e., the embedded loop will automatically be forked when the |
3293 |
embedding loop forks. In other cases, the user is responsible for calling |
3294 |
C<ev_loop_fork> on the embedded loop. |
3295 |
|
3296 |
Unfortunately, not all backends are embeddable: only the ones returned by |
3297 |
C<ev_embeddable_backends> are, which, unfortunately, does not include any |
3298 |
portable one. |
3299 |
|
3300 |
So when you want to use this feature you will always have to be prepared |
3301 |
that you cannot get an embeddable loop. The recommended way to get around |
3302 |
this is to have a separate variables for your embeddable loop, try to |
3303 |
create it, and if that fails, use the normal loop for everything. |
3304 |
|
3305 |
=head3 C<ev_embed> and fork |
3306 |
|
3307 |
While the C<ev_embed> watcher is running, forks in the embedding loop will |
3308 |
automatically be applied to the embedded loop as well, so no special |
3309 |
fork handling is required in that case. When the watcher is not running, |
3310 |
however, it is still the task of the libev user to call C<ev_loop_fork ()> |
3311 |
as applicable. |
3312 |
|
3313 |
=head3 Watcher-Specific Functions and Data Members |
3314 |
|
3315 |
=over 4 |
3316 |
|
3317 |
=item ev_embed_init (ev_embed *, callback, struct ev_loop *embedded_loop) |
3318 |
|
3319 |
=item ev_embed_set (ev_embed *, struct ev_loop *embedded_loop) |
3320 |
|
3321 |
Configures the watcher to embed the given loop, which must be |
3322 |
embeddable. If the callback is C<0>, then C<ev_embed_sweep> will be |
3323 |
invoked automatically, otherwise it is the responsibility of the callback |
3324 |
to invoke it (it will continue to be called until the sweep has been done, |
3325 |
if you do not want that, you need to temporarily stop the embed watcher). |
3326 |
|
3327 |
=item ev_embed_sweep (loop, ev_embed *) |
3328 |
|
3329 |
Make a single, non-blocking sweep over the embedded loop. This works |
3330 |
similarly to C<ev_run (embedded_loop, EVRUN_NOWAIT)>, but in the most |
3331 |
appropriate way for embedded loops. |
3332 |
|
3333 |
=item struct ev_loop *other [read-only] |
3334 |
|
3335 |
The embedded event loop. |
3336 |
|
3337 |
=back |
3338 |
|
3339 |
=head3 Examples |
3340 |
|
3341 |
Example: Try to get an embeddable event loop and embed it into the default |
3342 |
event loop. If that is not possible, use the default loop. The default |
3343 |
loop is stored in C<loop_hi>, while the embeddable loop is stored in |
3344 |
C<loop_lo> (which is C<loop_hi> in the case no embeddable loop can be |
3345 |
used). |
3346 |
|
3347 |
struct ev_loop *loop_hi = ev_default_init (0); |
3348 |
struct ev_loop *loop_lo = 0; |
3349 |
ev_embed embed; |
3350 |
|
3351 |
// see if there is a chance of getting one that works |
3352 |
// (remember that a flags value of 0 means autodetection) |
3353 |
loop_lo = ev_embeddable_backends () & ev_recommended_backends () |
3354 |
? ev_loop_new (ev_embeddable_backends () & ev_recommended_backends ()) |
3355 |
: 0; |
3356 |
|
3357 |
// if we got one, then embed it, otherwise default to loop_hi |
3358 |
if (loop_lo) |
3359 |
{ |
3360 |
ev_embed_init (&embed, 0, loop_lo); |
3361 |
ev_embed_start (loop_hi, &embed); |
3362 |
} |
3363 |
else |
3364 |
loop_lo = loop_hi; |
3365 |
|
3366 |
Example: Check if kqueue is available but not recommended and create |
3367 |
a kqueue backend for use with sockets (which usually work with any |
3368 |
kqueue implementation). Store the kqueue/socket-only event loop in |
3369 |
C<loop_socket>. (One might optionally use C<EVFLAG_NOENV>, too). |
3370 |
|
3371 |
struct ev_loop *loop = ev_default_init (0); |
3372 |
struct ev_loop *loop_socket = 0; |
3373 |
ev_embed embed; |
3374 |
|
3375 |
if (ev_supported_backends () & ~ev_recommended_backends () & EVBACKEND_KQUEUE) |
3376 |
if ((loop_socket = ev_loop_new (EVBACKEND_KQUEUE)) |
3377 |
{ |
3378 |
ev_embed_init (&embed, 0, loop_socket); |
3379 |
ev_embed_start (loop, &embed); |
3380 |
} |
3381 |
|
3382 |
if (!loop_socket) |
3383 |
loop_socket = loop; |
3384 |
|
3385 |
// now use loop_socket for all sockets, and loop for everything else |
3386 |
|
3387 |
|
3388 |
=head2 C<ev_fork> - the audacity to resume the event loop after a fork |
3389 |
|
3390 |
Fork watchers are called when a C<fork ()> was detected (usually because |
3391 |
whoever is a good citizen cared to tell libev about it by calling |
3392 |
C<ev_loop_fork>). The invocation is done before the event loop blocks next |
3393 |
and before C<ev_check> watchers are being called, and only in the child |
3394 |
after the fork. If whoever good citizen calling C<ev_default_fork> cheats |
3395 |
and calls it in the wrong process, the fork handlers will be invoked, too, |
3396 |
of course. |
3397 |
|
3398 |
=head3 The special problem of life after fork - how is it possible? |
3399 |
|
3400 |
Most uses of C<fork ()> consist of forking, then some simple calls to set |
3401 |
up/change the process environment, followed by a call to C<exec()>. This |
3402 |
sequence should be handled by libev without any problems. |
3403 |
|
3404 |
This changes when the application actually wants to do event handling |
3405 |
in the child, or both parent in child, in effect "continuing" after the |
3406 |
fork. |
3407 |
|
3408 |
The default mode of operation (for libev, with application help to detect |
3409 |
forks) is to duplicate all the state in the child, as would be expected |
3410 |
when I<either> the parent I<or> the child process continues. |
3411 |
|
3412 |
When both processes want to continue using libev, then this is usually the |
3413 |
wrong result. In that case, usually one process (typically the parent) is |
3414 |
supposed to continue with all watchers in place as before, while the other |
3415 |
process typically wants to start fresh, i.e. without any active watchers. |
3416 |
|
3417 |
The cleanest and most efficient way to achieve that with libev is to |
3418 |
simply create a new event loop, which of course will be "empty", and |
3419 |
use that for new watchers. This has the advantage of not touching more |
3420 |
memory than necessary, and thus avoiding the copy-on-write, and the |
3421 |
disadvantage of having to use multiple event loops (which do not support |
3422 |
signal watchers). |
3423 |
|
3424 |
When this is not possible, or you want to use the default loop for |
3425 |
other reasons, then in the process that wants to start "fresh", call |
3426 |
C<ev_loop_destroy (EV_DEFAULT)> followed by C<ev_default_loop (...)>. |
3427 |
Destroying the default loop will "orphan" (not stop) all registered |
3428 |
watchers, so you have to be careful not to execute code that modifies |
3429 |
those watchers. Note also that in that case, you have to re-register any |
3430 |
signal watchers. |
3431 |
|
3432 |
=head3 Watcher-Specific Functions and Data Members |
3433 |
|
3434 |
=over 4 |
3435 |
|
3436 |
=item ev_fork_init (ev_fork *, callback) |
3437 |
|
3438 |
Initialises and configures the fork watcher - it has no parameters of any |
3439 |
kind. There is a C<ev_fork_set> macro, but using it is utterly pointless, |
3440 |
really. |
3441 |
|
3442 |
=back |
3443 |
|
3444 |
|
3445 |
=head2 C<ev_cleanup> - even the best things end |
3446 |
|
3447 |
Cleanup watchers are called just before the event loop is being destroyed |
3448 |
by a call to C<ev_loop_destroy>. |
3449 |
|
3450 |
While there is no guarantee that the event loop gets destroyed, cleanup |
3451 |
watchers provide a convenient method to install cleanup hooks for your |
3452 |
program, worker threads and so on - you just to make sure to destroy the |
3453 |
loop when you want them to be invoked. |
3454 |
|
3455 |
Cleanup watchers are invoked in the same way as any other watcher. Unlike |
3456 |
all other watchers, they do not keep a reference to the event loop (which |
3457 |
makes a lot of sense if you think about it). Like all other watchers, you |
3458 |
can call libev functions in the callback, except C<ev_cleanup_start>. |
3459 |
|
3460 |
=head3 Watcher-Specific Functions and Data Members |
3461 |
|
3462 |
=over 4 |
3463 |
|
3464 |
=item ev_cleanup_init (ev_cleanup *, callback) |
3465 |
|
3466 |
Initialises and configures the cleanup watcher - it has no parameters of |
3467 |
any kind. There is a C<ev_cleanup_set> macro, but using it is utterly |
3468 |
pointless, I assure you. |
3469 |
|
3470 |
=back |
3471 |
|
3472 |
Example: Register an atexit handler to destroy the default loop, so any |
3473 |
cleanup functions are called. |
3474 |
|
3475 |
static void |
3476 |
program_exits (void) |
3477 |
{ |
3478 |
ev_loop_destroy (EV_DEFAULT_UC); |
3479 |
} |
3480 |
|
3481 |
... |
3482 |
atexit (program_exits); |
3483 |
|
3484 |
|
3485 |
=head2 C<ev_async> - how to wake up an event loop |
3486 |
|
3487 |
In general, you cannot use an C<ev_loop> from multiple threads or other |
3488 |
asynchronous sources such as signal handlers (as opposed to multiple event |
3489 |
loops - those are of course safe to use in different threads). |
3490 |
|
3491 |
Sometimes, however, you need to wake up an event loop you do not control, |
3492 |
for example because it belongs to another thread. This is what C<ev_async> |
3493 |
watchers do: as long as the C<ev_async> watcher is active, you can signal |
3494 |
it by calling C<ev_async_send>, which is thread- and signal safe. |
3495 |
|
3496 |
This functionality is very similar to C<ev_signal> watchers, as signals, |
3497 |
too, are asynchronous in nature, and signals, too, will be compressed |
3498 |
(i.e. the number of callback invocations may be less than the number of |
3499 |
C<ev_async_send> calls). In fact, you could use signal watchers as a kind |
3500 |
of "global async watchers" by using a watcher on an otherwise unused |
3501 |
signal, and C<ev_feed_signal> to signal this watcher from another thread, |
3502 |
even without knowing which loop owns the signal. |
3503 |
|
3504 |
=head3 Queueing |
3505 |
|
3506 |
C<ev_async> does not support queueing of data in any way. The reason |
3507 |
is that the author does not know of a simple (or any) algorithm for a |
3508 |
multiple-writer-single-reader queue that works in all cases and doesn't |
3509 |
need elaborate support such as pthreads or unportable memory access |
3510 |
semantics. |
3511 |
|
3512 |
That means that if you want to queue data, you have to provide your own |
3513 |
queue. But at least I can tell you how to implement locking around your |
3514 |
queue: |
3515 |
|
3516 |
=over 4 |
3517 |
|
3518 |
=item queueing from a signal handler context |
3519 |
|
3520 |
To implement race-free queueing, you simply add to the queue in the signal |
3521 |
handler but you block the signal handler in the watcher callback. Here is |
3522 |
an example that does that for some fictitious SIGUSR1 handler: |
3523 |
|
3524 |
static ev_async mysig; |
3525 |
|
3526 |
static void |
3527 |
sigusr1_handler (void) |
3528 |
{ |
3529 |
sometype data; |
3530 |
|
3531 |
// no locking etc. |
3532 |
queue_put (data); |
3533 |
ev_async_send (EV_DEFAULT_ &mysig); |
3534 |
} |
3535 |
|
3536 |
static void |
3537 |
mysig_cb (EV_P_ ev_async *w, int revents) |
3538 |
{ |
3539 |
sometype data; |
3540 |
sigset_t block, prev; |
3541 |
|
3542 |
sigemptyset (&block); |
3543 |
sigaddset (&block, SIGUSR1); |
3544 |
sigprocmask (SIG_BLOCK, &block, &prev); |
3545 |
|
3546 |
while (queue_get (&data)) |
3547 |
process (data); |
3548 |
|
3549 |
if (sigismember (&prev, SIGUSR1) |
3550 |
sigprocmask (SIG_UNBLOCK, &block, 0); |
3551 |
} |
3552 |
|
3553 |
(Note: pthreads in theory requires you to use C<pthread_setmask> |
3554 |
instead of C<sigprocmask> when you use threads, but libev doesn't do it |
3555 |
either...). |
3556 |
|
3557 |
=item queueing from a thread context |
3558 |
|
3559 |
The strategy for threads is different, as you cannot (easily) block |
3560 |
threads but you can easily preempt them, so to queue safely you need to |
3561 |
employ a traditional mutex lock, such as in this pthread example: |
3562 |
|
3563 |
static ev_async mysig; |
3564 |
static pthread_mutex_t mymutex = PTHREAD_MUTEX_INITIALIZER; |
3565 |
|
3566 |
static void |
3567 |
otherthread (void) |
3568 |
{ |
3569 |
// only need to lock the actual queueing operation |
3570 |
pthread_mutex_lock (&mymutex); |
3571 |
queue_put (data); |
3572 |
pthread_mutex_unlock (&mymutex); |
3573 |
|
3574 |
ev_async_send (EV_DEFAULT_ &mysig); |
3575 |
} |
3576 |
|
3577 |
static void |
3578 |
mysig_cb (EV_P_ ev_async *w, int revents) |
3579 |
{ |
3580 |
pthread_mutex_lock (&mymutex); |
3581 |
|
3582 |
while (queue_get (&data)) |
3583 |
process (data); |
3584 |
|
3585 |
pthread_mutex_unlock (&mymutex); |
3586 |
} |
3587 |
|
3588 |
=back |
3589 |
|
3590 |
|
3591 |
=head3 Watcher-Specific Functions and Data Members |
3592 |
|
3593 |
=over 4 |
3594 |
|
3595 |
=item ev_async_init (ev_async *, callback) |
3596 |
|
3597 |
Initialises and configures the async watcher - it has no parameters of any |
3598 |
kind. There is a C<ev_async_set> macro, but using it is utterly pointless, |
3599 |
trust me. |
3600 |
|
3601 |
=item ev_async_send (loop, ev_async *) |
3602 |
|
3603 |
Sends/signals/activates the given C<ev_async> watcher, that is, feeds |
3604 |
an C<EV_ASYNC> event on the watcher into the event loop, and instantly |
3605 |
returns. |
3606 |
|
3607 |
Unlike C<ev_feed_event>, this call is safe to do from other threads, |
3608 |
signal or similar contexts (see the discussion of C<EV_ATOMIC_T> in the |
3609 |
embedding section below on what exactly this means). |
3610 |
|
3611 |
Note that, as with other watchers in libev, multiple events might get |
3612 |
compressed into a single callback invocation (another way to look at |
3613 |
this is that C<ev_async> watchers are level-triggered: they are set on |
3614 |
C<ev_async_send>, reset when the event loop detects that). |
3615 |
|
3616 |
This call incurs the overhead of at most one extra system call per event |
3617 |
loop iteration, if the event loop is blocked, and no syscall at all if |
3618 |
the event loop (or your program) is processing events. That means that |
3619 |
repeated calls are basically free (there is no need to avoid calls for |
3620 |
performance reasons) and that the overhead becomes smaller (typically |
3621 |
zero) under load. |
3622 |
|
3623 |
=item bool = ev_async_pending (ev_async *) |
3624 |
|
3625 |
Returns a non-zero value when C<ev_async_send> has been called on the |
3626 |
watcher but the event has not yet been processed (or even noted) by the |
3627 |
event loop. |
3628 |
|
3629 |
C<ev_async_send> sets a flag in the watcher and wakes up the loop. When |
3630 |
the loop iterates next and checks for the watcher to have become active, |
3631 |
it will reset the flag again. C<ev_async_pending> can be used to very |
3632 |
quickly check whether invoking the loop might be a good idea. |
3633 |
|
3634 |
Not that this does I<not> check whether the watcher itself is pending, |
3635 |
only whether it has been requested to make this watcher pending: there |
3636 |
is a time window between the event loop checking and resetting the async |
3637 |
notification, and the callback being invoked. |
3638 |
|
3639 |
=back |
3640 |
|
3641 |
|
3642 |
=head1 OTHER FUNCTIONS |
3643 |
|
3644 |
There are some other functions of possible interest. Described. Here. Now. |
3645 |
|
3646 |
=over 4 |
3647 |
|
3648 |
=item ev_once (loop, int fd, int events, ev_tstamp timeout, callback, arg) |
3649 |
|
3650 |
This function combines a simple timer and an I/O watcher, calls your |
3651 |
callback on whichever event happens first and automatically stops both |
3652 |
watchers. This is useful if you want to wait for a single event on an fd |
3653 |
or timeout without having to allocate/configure/start/stop/free one or |
3654 |
more watchers yourself. |
3655 |
|
3656 |
If C<fd> is less than 0, then no I/O watcher will be started and the |
3657 |
C<events> argument is being ignored. Otherwise, an C<ev_io> watcher for |
3658 |
the given C<fd> and C<events> set will be created and started. |
3659 |
|
3660 |
If C<timeout> is less than 0, then no timeout watcher will be |
3661 |
started. Otherwise an C<ev_timer> watcher with after = C<timeout> (and |
3662 |
repeat = 0) will be started. C<0> is a valid timeout. |
3663 |
|
3664 |
The callback has the type C<void (*cb)(int revents, void *arg)> and is |
3665 |
passed an C<revents> set like normal event callbacks (a combination of |
3666 |
C<EV_ERROR>, C<EV_READ>, C<EV_WRITE> or C<EV_TIMER>) and the C<arg> |
3667 |
value passed to C<ev_once>. Note that it is possible to receive I<both> |
3668 |
a timeout and an io event at the same time - you probably should give io |
3669 |
events precedence. |
3670 |
|
3671 |
Example: wait up to ten seconds for data to appear on STDIN_FILENO. |
3672 |
|
3673 |
static void stdin_ready (int revents, void *arg) |
3674 |
{ |
3675 |
if (revents & EV_READ) |
3676 |
/* stdin might have data for us, joy! */; |
3677 |
else if (revents & EV_TIMER) |
3678 |
/* doh, nothing entered */; |
3679 |
} |
3680 |
|
3681 |
ev_once (STDIN_FILENO, EV_READ, 10., stdin_ready, 0); |
3682 |
|
3683 |
=item ev_feed_fd_event (loop, int fd, int revents) |
3684 |
|
3685 |
Feed an event on the given fd, as if a file descriptor backend detected |
3686 |
the given events. |
3687 |
|
3688 |
=item ev_feed_signal_event (loop, int signum) |
3689 |
|
3690 |
Feed an event as if the given signal occurred. See also C<ev_feed_signal>, |
3691 |
which is async-safe. |
3692 |
|
3693 |
=back |
3694 |
|
3695 |
|
3696 |
=head1 COMMON OR USEFUL IDIOMS (OR BOTH) |
3697 |
|
3698 |
This section explains some common idioms that are not immediately |
3699 |
obvious. Note that examples are sprinkled over the whole manual, and this |
3700 |
section only contains stuff that wouldn't fit anywhere else. |
3701 |
|
3702 |
=head2 ASSOCIATING CUSTOM DATA WITH A WATCHER |
3703 |
|
3704 |
Each watcher has, by default, a C<void *data> member that you can read |
3705 |
or modify at any time: libev will completely ignore it. This can be used |
3706 |
to associate arbitrary data with your watcher. If you need more data and |
3707 |
don't want to allocate memory separately and store a pointer to it in that |
3708 |
data member, you can also "subclass" the watcher type and provide your own |
3709 |
data: |
3710 |
|
3711 |
struct my_io |
3712 |
{ |
3713 |
ev_io io; |
3714 |
int otherfd; |
3715 |
void *somedata; |
3716 |
struct whatever *mostinteresting; |
3717 |
}; |
3718 |
|
3719 |
... |
3720 |
struct my_io w; |
3721 |
ev_io_init (&w.io, my_cb, fd, EV_READ); |
3722 |
|
3723 |
And since your callback will be called with a pointer to the watcher, you |
3724 |
can cast it back to your own type: |
3725 |
|
3726 |
static void my_cb (struct ev_loop *loop, ev_io *w_, int revents) |
3727 |
{ |
3728 |
struct my_io *w = (struct my_io *)w_; |
3729 |
... |
3730 |
} |
3731 |
|
3732 |
More interesting and less C-conformant ways of casting your callback |
3733 |
function type instead have been omitted. |
3734 |
|
3735 |
=head2 BUILDING YOUR OWN COMPOSITE WATCHERS |
3736 |
|
3737 |
Another common scenario is to use some data structure with multiple |
3738 |
embedded watchers, in effect creating your own watcher that combines |
3739 |
multiple libev event sources into one "super-watcher": |
3740 |
|
3741 |
struct my_biggy |
3742 |
{ |
3743 |
int some_data; |
3744 |
ev_timer t1; |
3745 |
ev_timer t2; |
3746 |
} |
3747 |
|
3748 |
In this case getting the pointer to C<my_biggy> is a bit more |
3749 |
complicated: Either you store the address of your C<my_biggy> struct in |
3750 |
the C<data> member of the watcher (for woozies or C++ coders), or you need |
3751 |
to use some pointer arithmetic using C<offsetof> inside your watchers (for |
3752 |
real programmers): |
3753 |
|
3754 |
#include <stddef.h> |
3755 |
|
3756 |
static void |
3757 |
t1_cb (EV_P_ ev_timer *w, int revents) |
3758 |
{ |
3759 |
struct my_biggy big = (struct my_biggy *) |
3760 |
(((char *)w) - offsetof (struct my_biggy, t1)); |
3761 |
} |
3762 |
|
3763 |
static void |
3764 |
t2_cb (EV_P_ ev_timer *w, int revents) |
3765 |
{ |
3766 |
struct my_biggy big = (struct my_biggy *) |
3767 |
(((char *)w) - offsetof (struct my_biggy, t2)); |
3768 |
} |
3769 |
|
3770 |
=head2 AVOIDING FINISHING BEFORE RETURNING |
3771 |
|
3772 |
Often you have structures like this in event-based programs: |
3773 |
|
3774 |
callback () |
3775 |
{ |
3776 |
free (request); |
3777 |
} |
3778 |
|
3779 |
request = start_new_request (..., callback); |
3780 |
|
3781 |
The intent is to start some "lengthy" operation. The C<request> could be |
3782 |
used to cancel the operation, or do other things with it. |
3783 |
|
3784 |
It's not uncommon to have code paths in C<start_new_request> that |
3785 |
immediately invoke the callback, for example, to report errors. Or you add |
3786 |
some caching layer that finds that it can skip the lengthy aspects of the |
3787 |
operation and simply invoke the callback with the result. |
3788 |
|
3789 |
The problem here is that this will happen I<before> C<start_new_request> |
3790 |
has returned, so C<request> is not set. |
3791 |
|
3792 |
Even if you pass the request by some safer means to the callback, you |
3793 |
might want to do something to the request after starting it, such as |
3794 |
canceling it, which probably isn't working so well when the callback has |
3795 |
already been invoked. |
3796 |
|
3797 |
A common way around all these issues is to make sure that |
3798 |
C<start_new_request> I<always> returns before the callback is invoked. If |
3799 |
C<start_new_request> immediately knows the result, it can artificially |
3800 |
delay invoking the callback by using a C<prepare> or C<idle> watcher for |
3801 |
example, or more sneakily, by reusing an existing (stopped) watcher and |
3802 |
pushing it into the pending queue: |
3803 |
|
3804 |
ev_set_cb (watcher, callback); |
3805 |
ev_feed_event (EV_A_ watcher, 0); |
3806 |
|
3807 |
This way, C<start_new_request> can safely return before the callback is |
3808 |
invoked, while not delaying callback invocation too much. |
3809 |
|
3810 |
=head2 MODEL/NESTED EVENT LOOP INVOCATIONS AND EXIT CONDITIONS |
3811 |
|
3812 |
Often (especially in GUI toolkits) there are places where you have |
3813 |
I<modal> interaction, which is most easily implemented by recursively |
3814 |
invoking C<ev_run>. |
3815 |
|
3816 |
This brings the problem of exiting - a callback might want to finish the |
3817 |
main C<ev_run> call, but not the nested one (e.g. user clicked "Quit", but |
3818 |
a modal "Are you sure?" dialog is still waiting), or just the nested one |
3819 |
and not the main one (e.g. user clocked "Ok" in a modal dialog), or some |
3820 |
other combination: In these cases, a simple C<ev_break> will not work. |
3821 |
|
3822 |
The solution is to maintain "break this loop" variable for each C<ev_run> |
3823 |
invocation, and use a loop around C<ev_run> until the condition is |
3824 |
triggered, using C<EVRUN_ONCE>: |
3825 |
|
3826 |
// main loop |
3827 |
int exit_main_loop = 0; |
3828 |
|
3829 |
while (!exit_main_loop) |
3830 |
ev_run (EV_DEFAULT_ EVRUN_ONCE); |
3831 |
|
3832 |
// in a modal watcher |
3833 |
int exit_nested_loop = 0; |
3834 |
|
3835 |
while (!exit_nested_loop) |
3836 |
ev_run (EV_A_ EVRUN_ONCE); |
3837 |
|
3838 |
To exit from any of these loops, just set the corresponding exit variable: |
3839 |
|
3840 |
// exit modal loop |
3841 |
exit_nested_loop = 1; |
3842 |
|
3843 |
// exit main program, after modal loop is finished |
3844 |
exit_main_loop = 1; |
3845 |
|
3846 |
// exit both |
3847 |
exit_main_loop = exit_nested_loop = 1; |
3848 |
|
3849 |
=head2 THREAD LOCKING EXAMPLE |
3850 |
|
3851 |
Here is a fictitious example of how to run an event loop in a different |
3852 |
thread from where callbacks are being invoked and watchers are |
3853 |
created/added/removed. |
3854 |
|
3855 |
For a real-world example, see the C<EV::Loop::Async> perl module, |
3856 |
which uses exactly this technique (which is suited for many high-level |
3857 |
languages). |
3858 |
|
3859 |
The example uses a pthread mutex to protect the loop data, a condition |
3860 |
variable to wait for callback invocations, an async watcher to notify the |
3861 |
event loop thread and an unspecified mechanism to wake up the main thread. |
3862 |
|
3863 |
First, you need to associate some data with the event loop: |
3864 |
|
3865 |
typedef struct { |
3866 |
mutex_t lock; /* global loop lock */ |
3867 |
ev_async async_w; |
3868 |
thread_t tid; |
3869 |
cond_t invoke_cv; |
3870 |
} userdata; |
3871 |
|
3872 |
void prepare_loop (EV_P) |
3873 |
{ |
3874 |
// for simplicity, we use a static userdata struct. |
3875 |
static userdata u; |
3876 |
|
3877 |
ev_async_init (&u->async_w, async_cb); |
3878 |
ev_async_start (EV_A_ &u->async_w); |
3879 |
|
3880 |
pthread_mutex_init (&u->lock, 0); |
3881 |
pthread_cond_init (&u->invoke_cv, 0); |
3882 |
|
3883 |
// now associate this with the loop |
3884 |
ev_set_userdata (EV_A_ u); |
3885 |
ev_set_invoke_pending_cb (EV_A_ l_invoke); |
3886 |
ev_set_loop_release_cb (EV_A_ l_release, l_acquire); |
3887 |
|
3888 |
// then create the thread running ev_run |
3889 |
pthread_create (&u->tid, 0, l_run, EV_A); |
3890 |
} |
3891 |
|
3892 |
The callback for the C<ev_async> watcher does nothing: the watcher is used |
3893 |
solely to wake up the event loop so it takes notice of any new watchers |
3894 |
that might have been added: |
3895 |
|
3896 |
static void |
3897 |
async_cb (EV_P_ ev_async *w, int revents) |
3898 |
{ |
3899 |
// just used for the side effects |
3900 |
} |
3901 |
|
3902 |
The C<l_release> and C<l_acquire> callbacks simply unlock/lock the mutex |
3903 |
protecting the loop data, respectively. |
3904 |
|
3905 |
static void |
3906 |
l_release (EV_P) |
3907 |
{ |
3908 |
userdata *u = ev_userdata (EV_A); |
3909 |
pthread_mutex_unlock (&u->lock); |
3910 |
} |
3911 |
|
3912 |
static void |
3913 |
l_acquire (EV_P) |
3914 |
{ |
3915 |
userdata *u = ev_userdata (EV_A); |
3916 |
pthread_mutex_lock (&u->lock); |
3917 |
} |
3918 |
|
3919 |
The event loop thread first acquires the mutex, and then jumps straight |
3920 |
into C<ev_run>: |
3921 |
|
3922 |
void * |
3923 |
l_run (void *thr_arg) |
3924 |
{ |
3925 |
struct ev_loop *loop = (struct ev_loop *)thr_arg; |
3926 |
|
3927 |
l_acquire (EV_A); |
3928 |
pthread_setcanceltype (PTHREAD_CANCEL_ASYNCHRONOUS, 0); |
3929 |
ev_run (EV_A_ 0); |
3930 |
l_release (EV_A); |
3931 |
|
3932 |
return 0; |
3933 |
} |
3934 |
|
3935 |
Instead of invoking all pending watchers, the C<l_invoke> callback will |
3936 |
signal the main thread via some unspecified mechanism (signals? pipe |
3937 |
writes? C<Async::Interrupt>?) and then waits until all pending watchers |
3938 |
have been called (in a while loop because a) spurious wakeups are possible |
3939 |
and b) skipping inter-thread-communication when there are no pending |
3940 |
watchers is very beneficial): |
3941 |
|
3942 |
static void |
3943 |
l_invoke (EV_P) |
3944 |
{ |
3945 |
userdata *u = ev_userdata (EV_A); |
3946 |
|
3947 |
while (ev_pending_count (EV_A)) |
3948 |
{ |
3949 |
wake_up_other_thread_in_some_magic_or_not_so_magic_way (); |
3950 |
pthread_cond_wait (&u->invoke_cv, &u->lock); |
3951 |
} |
3952 |
} |
3953 |
|
3954 |
Now, whenever the main thread gets told to invoke pending watchers, it |
3955 |
will grab the lock, call C<ev_invoke_pending> and then signal the loop |
3956 |
thread to continue: |
3957 |
|
3958 |
static void |
3959 |
real_invoke_pending (EV_P) |
3960 |
{ |
3961 |
userdata *u = ev_userdata (EV_A); |
3962 |
|
3963 |
pthread_mutex_lock (&u->lock); |
3964 |
ev_invoke_pending (EV_A); |
3965 |
pthread_cond_signal (&u->invoke_cv); |
3966 |
pthread_mutex_unlock (&u->lock); |
3967 |
} |
3968 |
|
3969 |
Whenever you want to start/stop a watcher or do other modifications to an |
3970 |
event loop, you will now have to lock: |
3971 |
|
3972 |
ev_timer timeout_watcher; |
3973 |
userdata *u = ev_userdata (EV_A); |
3974 |
|
3975 |
ev_timer_init (&timeout_watcher, timeout_cb, 5.5, 0.); |
3976 |
|
3977 |
pthread_mutex_lock (&u->lock); |
3978 |
ev_timer_start (EV_A_ &timeout_watcher); |
3979 |
ev_async_send (EV_A_ &u->async_w); |
3980 |
pthread_mutex_unlock (&u->lock); |
3981 |
|
3982 |
Note that sending the C<ev_async> watcher is required because otherwise |
3983 |
an event loop currently blocking in the kernel will have no knowledge |
3984 |
about the newly added timer. By waking up the loop it will pick up any new |
3985 |
watchers in the next event loop iteration. |
3986 |
|
3987 |
=head2 THREADS, COROUTINES, CONTINUATIONS, QUEUES... INSTEAD OF CALLBACKS |
3988 |
|
3989 |
While the overhead of a callback that e.g. schedules a thread is small, it |
3990 |
is still an overhead. If you embed libev, and your main usage is with some |
3991 |
kind of threads or coroutines, you might want to customise libev so that |
3992 |
doesn't need callbacks anymore. |
3993 |
|
3994 |
Imagine you have coroutines that you can switch to using a function |
3995 |
C<switch_to (coro)>, that libev runs in a coroutine called C<libev_coro> |
3996 |
and that due to some magic, the currently active coroutine is stored in a |
3997 |
global called C<current_coro>. Then you can build your own "wait for libev |
3998 |
event" primitive by changing C<EV_CB_DECLARE> and C<EV_CB_INVOKE> (note |
3999 |
the differing C<;> conventions): |
4000 |
|
4001 |
#define EV_CB_DECLARE(type) struct my_coro *cb; |
4002 |
#define EV_CB_INVOKE(watcher) switch_to ((watcher)->cb) |
4003 |
|
4004 |
That means instead of having a C callback function, you store the |
4005 |
coroutine to switch to in each watcher, and instead of having libev call |
4006 |
your callback, you instead have it switch to that coroutine. |
4007 |
|
4008 |
A coroutine might now wait for an event with a function called |
4009 |
C<wait_for_event>. (the watcher needs to be started, as always, but it doesn't |
4010 |
matter when, or whether the watcher is active or not when this function is |
4011 |
called): |
4012 |
|
4013 |
void |
4014 |
wait_for_event (ev_watcher *w) |
4015 |
{ |
4016 |
ev_set_cb (w, current_coro); |
4017 |
switch_to (libev_coro); |
4018 |
} |
4019 |
|
4020 |
That basically suspends the coroutine inside C<wait_for_event> and |
4021 |
continues the libev coroutine, which, when appropriate, switches back to |
4022 |
this or any other coroutine. |
4023 |
|
4024 |
You can do similar tricks if you have, say, threads with an event queue - |
4025 |
instead of storing a coroutine, you store the queue object and instead of |
4026 |
switching to a coroutine, you push the watcher onto the queue and notify |
4027 |
any waiters. |
4028 |
|
4029 |
To embed libev, see L</EMBEDDING>, but in short, it's easiest to create two |
4030 |
files, F<my_ev.h> and F<my_ev.c> that include the respective libev files: |
4031 |
|
4032 |
// my_ev.h |
4033 |
#define EV_CB_DECLARE(type) struct my_coro *cb; |
4034 |
#define EV_CB_INVOKE(watcher) switch_to ((watcher)->cb) |
4035 |
#include "../libev/ev.h" |
4036 |
|
4037 |
// my_ev.c |
4038 |
#define EV_H "my_ev.h" |
4039 |
#include "../libev/ev.c" |
4040 |
|
4041 |
And then use F<my_ev.h> when you would normally use F<ev.h>, and compile |
4042 |
F<my_ev.c> into your project. When properly specifying include paths, you |
4043 |
can even use F<ev.h> as header file name directly. |
4044 |
|
4045 |
|
4046 |
=head1 LIBEVENT EMULATION |
4047 |
|
4048 |
Libev offers a compatibility emulation layer for libevent. It cannot |
4049 |
emulate the internals of libevent, so here are some usage hints: |
4050 |
|
4051 |
=over 4 |
4052 |
|
4053 |
=item * Only the libevent-1.4.1-beta API is being emulated. |
4054 |
|
4055 |
This was the newest libevent version available when libev was implemented, |
4056 |
and is still mostly unchanged in 2010. |
4057 |
|
4058 |
=item * Use it by including <event.h>, as usual. |
4059 |
|
4060 |
=item * The following members are fully supported: ev_base, ev_callback, |
4061 |
ev_arg, ev_fd, ev_res, ev_events. |
4062 |
|
4063 |
=item * Avoid using ev_flags and the EVLIST_*-macros, while it is |
4064 |
maintained by libev, it does not work exactly the same way as in libevent (consider |
4065 |
it a private API). |
4066 |
|
4067 |
=item * Priorities are not currently supported. Initialising priorities |
4068 |
will fail and all watchers will have the same priority, even though there |
4069 |
is an ev_pri field. |
4070 |
|
4071 |
=item * In libevent, the last base created gets the signals, in libev, the |
4072 |
base that registered the signal gets the signals. |
4073 |
|
4074 |
=item * Other members are not supported. |
4075 |
|
4076 |
=item * The libev emulation is I<not> ABI compatible to libevent, you need |
4077 |
to use the libev header file and library. |
4078 |
|
4079 |
=back |
4080 |
|
4081 |
=head1 C++ SUPPORT |
4082 |
|
4083 |
=head2 C API |
4084 |
|
4085 |
The normal C API should work fine when used from C++: both ev.h and the |
4086 |
libev sources can be compiled as C++. Therefore, code that uses the C API |
4087 |
will work fine. |
4088 |
|
4089 |
Proper exception specifications might have to be added to callbacks passed |
4090 |
to libev: exceptions may be thrown only from watcher callbacks, all other |
4091 |
callbacks (allocator, syserr, loop acquire/release and periodic reschedule |
4092 |
callbacks) must not throw exceptions, and might need a C<noexcept> |
4093 |
specification. If you have code that needs to be compiled as both C and |
4094 |
C++ you can use the C<EV_NOEXCEPT> macro for this: |
4095 |
|
4096 |
static void |
4097 |
fatal_error (const char *msg) EV_NOEXCEPT |
4098 |
{ |
4099 |
perror (msg); |
4100 |
abort (); |
4101 |
} |
4102 |
|
4103 |
... |
4104 |
ev_set_syserr_cb (fatal_error); |
4105 |
|
4106 |
The only API functions that can currently throw exceptions are C<ev_run>, |
4107 |
C<ev_invoke>, C<ev_invoke_pending> and C<ev_loop_destroy> (the latter |
4108 |
because it runs cleanup watchers). |
4109 |
|
4110 |
Throwing exceptions in watcher callbacks is only supported if libev itself |
4111 |
is compiled with a C++ compiler or your C and C++ environments allow |
4112 |
throwing exceptions through C libraries (most do). |
4113 |
|
4114 |
=head2 C++ API |
4115 |
|
4116 |
Libev comes with some simplistic wrapper classes for C++ that mainly allow |
4117 |
you to use some convenience methods to start/stop watchers and also change |
4118 |
the callback model to a model using method callbacks on objects. |
4119 |
|
4120 |
To use it, |
4121 |
|
4122 |
#include <ev++.h> |
4123 |
|
4124 |
This automatically includes F<ev.h> and puts all of its definitions (many |
4125 |
of them macros) into the global namespace. All C++ specific things are |
4126 |
put into the C<ev> namespace. It should support all the same embedding |
4127 |
options as F<ev.h>, most notably C<EV_MULTIPLICITY>. |
4128 |
|
4129 |
Care has been taken to keep the overhead low. The only data member the C++ |
4130 |
classes add (compared to plain C-style watchers) is the event loop pointer |
4131 |
that the watcher is associated with (or no additional members at all if |
4132 |
you disable C<EV_MULTIPLICITY> when embedding libev). |
4133 |
|
4134 |
Currently, functions, static and non-static member functions and classes |
4135 |
with C<operator ()> can be used as callbacks. Other types should be easy |
4136 |
to add as long as they only need one additional pointer for context. If |
4137 |
you need support for other types of functors please contact the author |
4138 |
(preferably after implementing it). |
4139 |
|
4140 |
For all this to work, your C++ compiler either has to use the same calling |
4141 |
conventions as your C compiler (for static member functions), or you have |
4142 |
to embed libev and compile libev itself as C++. |
4143 |
|
4144 |
Here is a list of things available in the C<ev> namespace: |
4145 |
|
4146 |
=over 4 |
4147 |
|
4148 |
=item C<ev::READ>, C<ev::WRITE> etc. |
4149 |
|
4150 |
These are just enum values with the same values as the C<EV_READ> etc. |
4151 |
macros from F<ev.h>. |
4152 |
|
4153 |
=item C<ev::tstamp>, C<ev::now> |
4154 |
|
4155 |
Aliases to the same types/functions as with the C<ev_> prefix. |
4156 |
|
4157 |
=item C<ev::io>, C<ev::timer>, C<ev::periodic>, C<ev::idle>, C<ev::sig> etc. |
4158 |
|
4159 |
For each C<ev_TYPE> watcher in F<ev.h> there is a corresponding class of |
4160 |
the same name in the C<ev> namespace, with the exception of C<ev_signal> |
4161 |
which is called C<ev::sig> to avoid clashes with the C<signal> macro |
4162 |
defined by many implementations. |
4163 |
|
4164 |
All of those classes have these methods: |
4165 |
|
4166 |
=over 4 |
4167 |
|
4168 |
=item ev::TYPE::TYPE () |
4169 |
|
4170 |
=item ev::TYPE::TYPE (loop) |
4171 |
|
4172 |
=item ev::TYPE::~TYPE |
4173 |
|
4174 |
The constructor (optionally) takes an event loop to associate the watcher |
4175 |
with. If it is omitted, it will use C<EV_DEFAULT>. |
4176 |
|
4177 |
The constructor calls C<ev_init> for you, which means you have to call the |
4178 |
C<set> method before starting it. |
4179 |
|
4180 |
It will not set a callback, however: You have to call the templated C<set> |
4181 |
method to set a callback before you can start the watcher. |
4182 |
|
4183 |
(The reason why you have to use a method is a limitation in C++ which does |
4184 |
not allow explicit template arguments for constructors). |
4185 |
|
4186 |
The destructor automatically stops the watcher if it is active. |
4187 |
|
4188 |
=item w->set<class, &class::method> (object *) |
4189 |
|
4190 |
This method sets the callback method to call. The method has to have a |
4191 |
signature of C<void (*)(ev_TYPE &, int)>, it receives the watcher as |
4192 |
first argument and the C<revents> as second. The object must be given as |
4193 |
parameter and is stored in the C<data> member of the watcher. |
4194 |
|
4195 |
This method synthesizes efficient thunking code to call your method from |
4196 |
the C callback that libev requires. If your compiler can inline your |
4197 |
callback (i.e. it is visible to it at the place of the C<set> call and |
4198 |
your compiler is good :), then the method will be fully inlined into the |
4199 |
thunking function, making it as fast as a direct C callback. |
4200 |
|
4201 |
Example: simple class declaration and watcher initialisation |
4202 |
|
4203 |
struct myclass |
4204 |
{ |
4205 |
void io_cb (ev::io &w, int revents) { } |
4206 |
} |
4207 |
|
4208 |
myclass obj; |
4209 |
ev::io iow; |
4210 |
iow.set <myclass, &myclass::io_cb> (&obj); |
4211 |
|
4212 |
=item w->set (object *) |
4213 |
|
4214 |
This is a variation of a method callback - leaving out the method to call |
4215 |
will default the method to C<operator ()>, which makes it possible to use |
4216 |
functor objects without having to manually specify the C<operator ()> all |
4217 |
the time. Incidentally, you can then also leave out the template argument |
4218 |
list. |
4219 |
|
4220 |
The C<operator ()> method prototype must be C<void operator ()(watcher &w, |
4221 |
int revents)>. |
4222 |
|
4223 |
See the method-C<set> above for more details. |
4224 |
|
4225 |
Example: use a functor object as callback. |
4226 |
|
4227 |
struct myfunctor |
4228 |
{ |
4229 |
void operator() (ev::io &w, int revents) |
4230 |
{ |
4231 |
... |
4232 |
} |
4233 |
} |
4234 |
|
4235 |
myfunctor f; |
4236 |
|
4237 |
ev::io w; |
4238 |
w.set (&f); |
4239 |
|
4240 |
=item w->set<function> (void *data = 0) |
4241 |
|
4242 |
Also sets a callback, but uses a static method or plain function as |
4243 |
callback. The optional C<data> argument will be stored in the watcher's |
4244 |
C<data> member and is free for you to use. |
4245 |
|
4246 |
The prototype of the C<function> must be C<void (*)(ev::TYPE &w, int)>. |
4247 |
|
4248 |
See the method-C<set> above for more details. |
4249 |
|
4250 |
Example: Use a plain function as callback. |
4251 |
|
4252 |
static void io_cb (ev::io &w, int revents) { } |
4253 |
iow.set <io_cb> (); |
4254 |
|
4255 |
=item w->set (loop) |
4256 |
|
4257 |
Associates a different C<struct ev_loop> with this watcher. You can only |
4258 |
do this when the watcher is inactive (and not pending either). |
4259 |
|
4260 |
=item w->set ([arguments]) |
4261 |
|
4262 |
Basically the same as C<ev_TYPE_set> (except for C<ev::embed> watchers>), |
4263 |
with the same arguments. Either this method or a suitable start method |
4264 |
must be called at least once. Unlike the C counterpart, an active watcher |
4265 |
gets automatically stopped and restarted when reconfiguring it with this |
4266 |
method. |
4267 |
|
4268 |
For C<ev::embed> watchers this method is called C<set_embed>, to avoid |
4269 |
clashing with the C<set (loop)> method. |
4270 |
|
4271 |
For C<ev::io> watchers there is an additional C<set> method that acepts a |
4272 |
new event mask only, and internally calls C<ev_io_modfify>. |
4273 |
|
4274 |
=item w->start () |
4275 |
|
4276 |
Starts the watcher. Note that there is no C<loop> argument, as the |
4277 |
constructor already stores the event loop. |
4278 |
|
4279 |
=item w->start ([arguments]) |
4280 |
|
4281 |
Instead of calling C<set> and C<start> methods separately, it is often |
4282 |
convenient to wrap them in one call. Uses the same type of arguments as |
4283 |
the configure C<set> method of the watcher. |
4284 |
|
4285 |
=item w->stop () |
4286 |
|
4287 |
Stops the watcher if it is active. Again, no C<loop> argument. |
4288 |
|
4289 |
=item w->again () (C<ev::timer>, C<ev::periodic> only) |
4290 |
|
4291 |
For C<ev::timer> and C<ev::periodic>, this invokes the corresponding |
4292 |
C<ev_TYPE_again> function. |
4293 |
|
4294 |
=item w->sweep () (C<ev::embed> only) |
4295 |
|
4296 |
Invokes C<ev_embed_sweep>. |
4297 |
|
4298 |
=item w->update () (C<ev::stat> only) |
4299 |
|
4300 |
Invokes C<ev_stat_stat>. |
4301 |
|
4302 |
=back |
4303 |
|
4304 |
=back |
4305 |
|
4306 |
Example: Define a class with two I/O and idle watchers, start the I/O |
4307 |
watchers in the constructor. |
4308 |
|
4309 |
class myclass |
4310 |
{ |
4311 |
ev::io io ; void io_cb (ev::io &w, int revents); |
4312 |
ev::io io2 ; void io2_cb (ev::io &w, int revents); |
4313 |
ev::idle idle; void idle_cb (ev::idle &w, int revents); |
4314 |
|
4315 |
myclass (int fd) |
4316 |
{ |
4317 |
io .set <myclass, &myclass::io_cb > (this); |
4318 |
io2 .set <myclass, &myclass::io2_cb > (this); |
4319 |
idle.set <myclass, &myclass::idle_cb> (this); |
4320 |
|
4321 |
io.set (fd, ev::WRITE); // configure the watcher |
4322 |
io.start (); // start it whenever convenient |
4323 |
|
4324 |
io2.start (fd, ev::READ); // set + start in one call |
4325 |
} |
4326 |
}; |
4327 |
|
4328 |
|
4329 |
=head1 OTHER LANGUAGE BINDINGS |
4330 |
|
4331 |
Libev does not offer other language bindings itself, but bindings for a |
4332 |
number of languages exist in the form of third-party packages. If you know |
4333 |
any interesting language binding in addition to the ones listed here, drop |
4334 |
me a note. |
4335 |
|
4336 |
=over 4 |
4337 |
|
4338 |
=item Perl |
4339 |
|
4340 |
The EV module implements the full libev API and is actually used to test |
4341 |
libev. EV is developed together with libev. Apart from the EV core module, |
4342 |
there are additional modules that implement libev-compatible interfaces |
4343 |
to C<libadns> (C<EV::ADNS>, but C<AnyEvent::DNS> is preferred nowadays), |
4344 |
C<Net::SNMP> (C<Net::SNMP::EV>) and the C<libglib> event core (C<Glib::EV> |
4345 |
and C<EV::Glib>). |
4346 |
|
4347 |
It can be found and installed via CPAN, its homepage is at |
4348 |
L<http://software.schmorp.de/pkg/EV>. |
4349 |
|
4350 |
=item Python |
4351 |
|
4352 |
Python bindings can be found at L<http://code.google.com/p/pyev/>. It |
4353 |
seems to be quite complete and well-documented. |
4354 |
|
4355 |
=item Ruby |
4356 |
|
4357 |
Tony Arcieri has written a ruby extension that offers access to a subset |
4358 |
of the libev API and adds file handle abstractions, asynchronous DNS and |
4359 |
more on top of it. It can be found via gem servers. Its homepage is at |
4360 |
L<http://rev.rubyforge.org/>. |
4361 |
|
4362 |
Roger Pack reports that using the link order C<-lws2_32 -lmsvcrt-ruby-190> |
4363 |
makes rev work even on mingw. |
4364 |
|
4365 |
=item Haskell |
4366 |
|
4367 |
A haskell binding to libev is available at |
4368 |
L<http://hackage.haskell.org/cgi-bin/hackage-scripts/package/hlibev>. |
4369 |
|
4370 |
=item D |
4371 |
|
4372 |
Leandro Lucarella has written a D language binding (F<ev.d>) for libev, to |
4373 |
be found at L<http://www.llucax.com.ar/proj/ev.d/index.html>. |
4374 |
|
4375 |
=item Ocaml |
4376 |
|
4377 |
Erkki Seppala has written Ocaml bindings for libev, to be found at |
4378 |
L<http://modeemi.cs.tut.fi/~flux/software/ocaml-ev/>. |
4379 |
|
4380 |
=item Lua |
4381 |
|
4382 |
Brian Maher has written a partial interface to libev for lua (at the |
4383 |
time of this writing, only C<ev_io> and C<ev_timer>), to be found at |
4384 |
L<http://github.com/brimworks/lua-ev>. |
4385 |
|
4386 |
=item Javascript |
4387 |
|
4388 |
Node.js (L<http://nodejs.org>) uses libev as the underlying event library. |
4389 |
|
4390 |
=item Others |
4391 |
|
4392 |
There are others, and I stopped counting. |
4393 |
|
4394 |
=back |
4395 |
|
4396 |
|
4397 |
=head1 MACRO MAGIC |
4398 |
|
4399 |
Libev can be compiled with a variety of options, the most fundamental |
4400 |
of which is C<EV_MULTIPLICITY>. This option determines whether (most) |
4401 |
functions and callbacks have an initial C<struct ev_loop *> argument. |
4402 |
|
4403 |
To make it easier to write programs that cope with either variant, the |
4404 |
following macros are defined: |
4405 |
|
4406 |
=over 4 |
4407 |
|
4408 |
=item C<EV_A>, C<EV_A_> |
4409 |
|
4410 |
This provides the loop I<argument> for functions, if one is required ("ev |
4411 |
loop argument"). The C<EV_A> form is used when this is the sole argument, |
4412 |
C<EV_A_> is used when other arguments are following. Example: |
4413 |
|
4414 |
ev_unref (EV_A); |
4415 |
ev_timer_add (EV_A_ watcher); |
4416 |
ev_run (EV_A_ 0); |
4417 |
|
4418 |
It assumes the variable C<loop> of type C<struct ev_loop *> is in scope, |
4419 |
which is often provided by the following macro. |
4420 |
|
4421 |
=item C<EV_P>, C<EV_P_> |
4422 |
|
4423 |
This provides the loop I<parameter> for functions, if one is required ("ev |
4424 |
loop parameter"). The C<EV_P> form is used when this is the sole parameter, |
4425 |
C<EV_P_> is used when other parameters are following. Example: |
4426 |
|
4427 |
// this is how ev_unref is being declared |
4428 |
static void ev_unref (EV_P); |
4429 |
|
4430 |
// this is how you can declare your typical callback |
4431 |
static void cb (EV_P_ ev_timer *w, int revents) |
4432 |
|
4433 |
It declares a parameter C<loop> of type C<struct ev_loop *>, quite |
4434 |
suitable for use with C<EV_A>. |
4435 |
|
4436 |
=item C<EV_DEFAULT>, C<EV_DEFAULT_> |
4437 |
|
4438 |
Similar to the other two macros, this gives you the value of the default |
4439 |
loop, if multiple loops are supported ("ev loop default"). The default loop |
4440 |
will be initialised if it isn't already initialised. |
4441 |
|
4442 |
For non-multiplicity builds, these macros do nothing, so you always have |
4443 |
to initialise the loop somewhere. |
4444 |
|
4445 |
=item C<EV_DEFAULT_UC>, C<EV_DEFAULT_UC_> |
4446 |
|
4447 |
Usage identical to C<EV_DEFAULT> and C<EV_DEFAULT_>, but requires that the |
4448 |
default loop has been initialised (C<UC> == unchecked). Their behaviour |
4449 |
is undefined when the default loop has not been initialised by a previous |
4450 |
execution of C<EV_DEFAULT>, C<EV_DEFAULT_> or C<ev_default_init (...)>. |
4451 |
|
4452 |
It is often prudent to use C<EV_DEFAULT> when initialising the first |
4453 |
watcher in a function but use C<EV_DEFAULT_UC> afterwards. |
4454 |
|
4455 |
=back |
4456 |
|
4457 |
Example: Declare and initialise a check watcher, utilising the above |
4458 |
macros so it will work regardless of whether multiple loops are supported |
4459 |
or not. |
4460 |
|
4461 |
static void |
4462 |
check_cb (EV_P_ ev_timer *w, int revents) |
4463 |
{ |
4464 |
ev_check_stop (EV_A_ w); |
4465 |
} |
4466 |
|
4467 |
ev_check check; |
4468 |
ev_check_init (&check, check_cb); |
4469 |
ev_check_start (EV_DEFAULT_ &check); |
4470 |
ev_run (EV_DEFAULT_ 0); |
4471 |
|
4472 |
=head1 EMBEDDING |
4473 |
|
4474 |
Libev can (and often is) directly embedded into host |
4475 |
applications. Examples of applications that embed it include the Deliantra |
4476 |
Game Server, the EV perl module, the GNU Virtual Private Ethernet (gvpe) |
4477 |
and rxvt-unicode. |
4478 |
|
4479 |
The goal is to enable you to just copy the necessary files into your |
4480 |
source directory without having to change even a single line in them, so |
4481 |
you can easily upgrade by simply copying (or having a checked-out copy of |
4482 |
libev somewhere in your source tree). |
4483 |
|
4484 |
=head2 FILESETS |
4485 |
|
4486 |
Depending on what features you need you need to include one or more sets of files |
4487 |
in your application. |
4488 |
|
4489 |
=head3 CORE EVENT LOOP |
4490 |
|
4491 |
To include only the libev core (all the C<ev_*> functions), with manual |
4492 |
configuration (no autoconf): |
4493 |
|
4494 |
#define EV_STANDALONE 1 |
4495 |
#include "ev.c" |
4496 |
|
4497 |
This will automatically include F<ev.h>, too, and should be done in a |
4498 |
single C source file only to provide the function implementations. To use |
4499 |
it, do the same for F<ev.h> in all files wishing to use this API (best |
4500 |
done by writing a wrapper around F<ev.h> that you can include instead and |
4501 |
where you can put other configuration options): |
4502 |
|
4503 |
#define EV_STANDALONE 1 |
4504 |
#include "ev.h" |
4505 |
|
4506 |
Both header files and implementation files can be compiled with a C++ |
4507 |
compiler (at least, that's a stated goal, and breakage will be treated |
4508 |
as a bug). |
4509 |
|
4510 |
You need the following files in your source tree, or in a directory |
4511 |
in your include path (e.g. in libev/ when using -Ilibev): |
4512 |
|
4513 |
ev.h |
4514 |
ev.c |
4515 |
ev_vars.h |
4516 |
ev_wrap.h |
4517 |
|
4518 |
ev_win32.c required on win32 platforms only |
4519 |
|
4520 |
ev_select.c only when select backend is enabled |
4521 |
ev_poll.c only when poll backend is enabled |
4522 |
ev_epoll.c only when the epoll backend is enabled |
4523 |
ev_linuxaio.c only when the linux aio backend is enabled |
4524 |
ev_iouring.c only when the linux io_uring backend is enabled |
4525 |
ev_kqueue.c only when the kqueue backend is enabled |
4526 |
ev_port.c only when the solaris port backend is enabled |
4527 |
|
4528 |
F<ev.c> includes the backend files directly when enabled, so you only need |
4529 |
to compile this single file. |
4530 |
|
4531 |
=head3 LIBEVENT COMPATIBILITY API |
4532 |
|
4533 |
To include the libevent compatibility API, also include: |
4534 |
|
4535 |
#include "event.c" |
4536 |
|
4537 |
in the file including F<ev.c>, and: |
4538 |
|
4539 |
#include "event.h" |
4540 |
|
4541 |
in the files that want to use the libevent API. This also includes F<ev.h>. |
4542 |
|
4543 |
You need the following additional files for this: |
4544 |
|
4545 |
event.h |
4546 |
event.c |
4547 |
|
4548 |
=head3 AUTOCONF SUPPORT |
4549 |
|
4550 |
Instead of using C<EV_STANDALONE=1> and providing your configuration in |
4551 |
whatever way you want, you can also C<m4_include([libev.m4])> in your |
4552 |
F<configure.ac> and leave C<EV_STANDALONE> undefined. F<ev.c> will then |
4553 |
include F<config.h> and configure itself accordingly. |
4554 |
|
4555 |
For this of course you need the m4 file: |
4556 |
|
4557 |
libev.m4 |
4558 |
|
4559 |
=head2 PREPROCESSOR SYMBOLS/MACROS |
4560 |
|
4561 |
Libev can be configured via a variety of preprocessor symbols you have to |
4562 |
define before including (or compiling) any of its files. The default in |
4563 |
the absence of autoconf is documented for every option. |
4564 |
|
4565 |
Symbols marked with "(h)" do not change the ABI, and can have different |
4566 |
values when compiling libev vs. including F<ev.h>, so it is permissible |
4567 |
to redefine them before including F<ev.h> without breaking compatibility |
4568 |
to a compiled library. All other symbols change the ABI, which means all |
4569 |
users of libev and the libev code itself must be compiled with compatible |
4570 |
settings. |
4571 |
|
4572 |
=over 4 |
4573 |
|
4574 |
=item EV_COMPAT3 (h) |
4575 |
|
4576 |
Backwards compatibility is a major concern for libev. This is why this |
4577 |
release of libev comes with wrappers for the functions and symbols that |
4578 |
have been renamed between libev version 3 and 4. |
4579 |
|
4580 |
You can disable these wrappers (to test compatibility with future |
4581 |
versions) by defining C<EV_COMPAT3> to C<0> when compiling your |
4582 |
sources. This has the additional advantage that you can drop the C<struct> |
4583 |
from C<struct ev_loop> declarations, as libev will provide an C<ev_loop> |
4584 |
typedef in that case. |
4585 |
|
4586 |
In some future version, the default for C<EV_COMPAT3> will become C<0>, |
4587 |
and in some even more future version the compatibility code will be |
4588 |
removed completely. |
4589 |
|
4590 |
=item EV_STANDALONE (h) |
4591 |
|
4592 |
Must always be C<1> if you do not use autoconf configuration, which |
4593 |
keeps libev from including F<config.h>, and it also defines dummy |
4594 |
implementations for some libevent functions (such as logging, which is not |
4595 |
supported). It will also not define any of the structs usually found in |
4596 |
F<event.h> that are not directly supported by the libev core alone. |
4597 |
|
4598 |
In standalone mode, libev will still try to automatically deduce the |
4599 |
configuration, but has to be more conservative. |
4600 |
|
4601 |
=item EV_USE_FLOOR |
4602 |
|
4603 |
If defined to be C<1>, libev will use the C<floor ()> function for its |
4604 |
periodic reschedule calculations, otherwise libev will fall back on a |
4605 |
portable (slower) implementation. If you enable this, you usually have to |
4606 |
link against libm or something equivalent. Enabling this when the C<floor> |
4607 |
function is not available will fail, so the safe default is to not enable |
4608 |
this. |
4609 |
|
4610 |
=item EV_USE_MONOTONIC |
4611 |
|
4612 |
If defined to be C<1>, libev will try to detect the availability of the |
4613 |
monotonic clock option at both compile time and runtime. Otherwise no |
4614 |
use of the monotonic clock option will be attempted. If you enable this, |
4615 |
you usually have to link against librt or something similar. Enabling it |
4616 |
when the functionality isn't available is safe, though, although you have |
4617 |
to make sure you link against any libraries where the C<clock_gettime> |
4618 |
function is hiding in (often F<-lrt>). See also C<EV_USE_CLOCK_SYSCALL>. |
4619 |
|
4620 |
=item EV_USE_REALTIME |
4621 |
|
4622 |
If defined to be C<1>, libev will try to detect the availability of the |
4623 |
real-time clock option at compile time (and assume its availability |
4624 |
at runtime if successful). Otherwise no use of the real-time clock |
4625 |
option will be attempted. This effectively replaces C<gettimeofday> |
4626 |
by C<clock_get (CLOCK_REALTIME, ...)> and will not normally affect |
4627 |
correctness. See the note about libraries in the description of |
4628 |
C<EV_USE_MONOTONIC>, though. Defaults to the opposite value of |
4629 |
C<EV_USE_CLOCK_SYSCALL>. |
4630 |
|
4631 |
=item EV_USE_CLOCK_SYSCALL |
4632 |
|
4633 |
If defined to be C<1>, libev will try to use a direct syscall instead |
4634 |
of calling the system-provided C<clock_gettime> function. This option |
4635 |
exists because on GNU/Linux, C<clock_gettime> is in C<librt>, but C<librt> |
4636 |
unconditionally pulls in C<libpthread>, slowing down single-threaded |
4637 |
programs needlessly. Using a direct syscall is slightly slower (in |
4638 |
theory), because no optimised vdso implementation can be used, but avoids |
4639 |
the pthread dependency. Defaults to C<1> on GNU/Linux with glibc 2.x or |
4640 |
higher, as it simplifies linking (no need for C<-lrt>). |
4641 |
|
4642 |
=item EV_USE_NANOSLEEP |
4643 |
|
4644 |
If defined to be C<1>, libev will assume that C<nanosleep ()> is available |
4645 |
and will use it for delays. Otherwise it will use C<select ()>. |
4646 |
|
4647 |
=item EV_USE_EVENTFD |
4648 |
|
4649 |
If defined to be C<1>, then libev will assume that C<eventfd ()> is |
4650 |
available and will probe for kernel support at runtime. This will improve |
4651 |
C<ev_signal> and C<ev_async> performance and reduce resource consumption. |
4652 |
If undefined, it will be enabled if the headers indicate GNU/Linux + Glibc |
4653 |
2.7 or newer, otherwise disabled. |
4654 |
|
4655 |
=item EV_USE_SIGNALFD |
4656 |
|
4657 |
If defined to be C<1>, then libev will assume that C<signalfd ()> is |
4658 |
available and will probe for kernel support at runtime. This enables |
4659 |
the use of EVFLAG_SIGNALFD for faster and simpler signal handling. If |
4660 |
undefined, it will be enabled if the headers indicate GNU/Linux + Glibc |
4661 |
2.7 or newer, otherwise disabled. |
4662 |
|
4663 |
=item EV_USE_TIMERFD |
4664 |
|
4665 |
If defined to be C<1>, then libev will assume that C<timerfd ()> is |
4666 |
available and will probe for kernel support at runtime. This allows |
4667 |
libev to detect time jumps accurately. If undefined, it will be enabled |
4668 |
if the headers indicate GNU/Linux + Glibc 2.8 or newer and define |
4669 |
C<TFD_TIMER_CANCEL_ON_SET>, otherwise disabled. |
4670 |
|
4671 |
=item EV_USE_EVENTFD |
4672 |
|
4673 |
If defined to be C<1>, then libev will assume that C<eventfd ()> is |
4674 |
available and will probe for kernel support at runtime. This will improve |
4675 |
C<ev_signal> and C<ev_async> performance and reduce resource consumption. |
4676 |
If undefined, it will be enabled if the headers indicate GNU/Linux + Glibc |
4677 |
2.7 or newer, otherwise disabled. |
4678 |
|
4679 |
=item EV_USE_SELECT |
4680 |
|
4681 |
If undefined or defined to be C<1>, libev will compile in support for the |
4682 |
C<select>(2) backend. No attempt at auto-detection will be done: if no |
4683 |
other method takes over, select will be it. Otherwise the select backend |
4684 |
will not be compiled in. |
4685 |
|
4686 |
=item EV_SELECT_USE_FD_SET |
4687 |
|
4688 |
If defined to C<1>, then the select backend will use the system C<fd_set> |
4689 |
structure. This is useful if libev doesn't compile due to a missing |
4690 |
C<NFDBITS> or C<fd_mask> definition or it mis-guesses the bitset layout |
4691 |
on exotic systems. This usually limits the range of file descriptors to |
4692 |
some low limit such as 1024 or might have other limitations (winsocket |
4693 |
only allows 64 sockets). The C<FD_SETSIZE> macro, set before compilation, |
4694 |
configures the maximum size of the C<fd_set>. |
4695 |
|
4696 |
=item EV_SELECT_IS_WINSOCKET |
4697 |
|
4698 |
When defined to C<1>, the select backend will assume that |
4699 |
select/socket/connect etc. don't understand file descriptors but |
4700 |
wants osf handles on win32 (this is the case when the select to |
4701 |
be used is the winsock select). This means that it will call |
4702 |
C<_get_osfhandle> on the fd to convert it to an OS handle. Otherwise, |
4703 |
it is assumed that all these functions actually work on fds, even |
4704 |
on win32. Should not be defined on non-win32 platforms. |
4705 |
|
4706 |
=item EV_FD_TO_WIN32_HANDLE(fd) |
4707 |
|
4708 |
If C<EV_SELECT_IS_WINSOCKET> is enabled, then libev needs a way to map |
4709 |
file descriptors to socket handles. When not defining this symbol (the |
4710 |
default), then libev will call C<_get_osfhandle>, which is usually |
4711 |
correct. In some cases, programs use their own file descriptor management, |
4712 |
in which case they can provide this function to map fds to socket handles. |
4713 |
|
4714 |
=item EV_WIN32_HANDLE_TO_FD(handle) |
4715 |
|
4716 |
If C<EV_SELECT_IS_WINSOCKET> then libev maps handles to file descriptors |
4717 |
using the standard C<_open_osfhandle> function. For programs implementing |
4718 |
their own fd to handle mapping, overwriting this function makes it easier |
4719 |
to do so. This can be done by defining this macro to an appropriate value. |
4720 |
|
4721 |
=item EV_WIN32_CLOSE_FD(fd) |
4722 |
|
4723 |
If programs implement their own fd to handle mapping on win32, then this |
4724 |
macro can be used to override the C<close> function, useful to unregister |
4725 |
file descriptors again. Note that the replacement function has to close |
4726 |
the underlying OS handle. |
4727 |
|
4728 |
=item EV_USE_WSASOCKET |
4729 |
|
4730 |
If defined to be C<1>, libev will use C<WSASocket> to create its internal |
4731 |
communication socket, which works better in some environments. Otherwise, |
4732 |
the normal C<socket> function will be used, which works better in other |
4733 |
environments. |
4734 |
|
4735 |
=item EV_USE_POLL |
4736 |
|
4737 |
If defined to be C<1>, libev will compile in support for the C<poll>(2) |
4738 |
backend. Otherwise it will be enabled on non-win32 platforms. It |
4739 |
takes precedence over select. |
4740 |
|
4741 |
=item EV_USE_EPOLL |
4742 |
|
4743 |
If defined to be C<1>, libev will compile in support for the Linux |
4744 |
C<epoll>(7) backend. Its availability will be detected at runtime, |
4745 |
otherwise another method will be used as fallback. This is the preferred |
4746 |
backend for GNU/Linux systems. If undefined, it will be enabled if the |
4747 |
headers indicate GNU/Linux + Glibc 2.4 or newer, otherwise disabled. |
4748 |
|
4749 |
=item EV_USE_LINUXAIO |
4750 |
|
4751 |
If defined to be C<1>, libev will compile in support for the Linux aio |
4752 |
backend (C<EV_USE_EPOLL> must also be enabled). If undefined, it will be |
4753 |
enabled on linux, otherwise disabled. |
4754 |
|
4755 |
=item EV_USE_IOURING |
4756 |
|
4757 |
If defined to be C<1>, libev will compile in support for the Linux |
4758 |
io_uring backend (C<EV_USE_EPOLL> must also be enabled). Due to it's |
4759 |
current limitations it has to be requested explicitly. If undefined, it |
4760 |
will be enabled on linux, otherwise disabled. |
4761 |
|
4762 |
=item EV_USE_KQUEUE |
4763 |
|
4764 |
If defined to be C<1>, libev will compile in support for the BSD style |
4765 |
C<kqueue>(2) backend. Its actual availability will be detected at runtime, |
4766 |
otherwise another method will be used as fallback. This is the preferred |
4767 |
backend for BSD and BSD-like systems, although on most BSDs kqueue only |
4768 |
supports some types of fds correctly (the only platform we found that |
4769 |
supports ptys for example was NetBSD), so kqueue might be compiled in, but |
4770 |
not be used unless explicitly requested. The best way to use it is to find |
4771 |
out whether kqueue supports your type of fd properly and use an embedded |
4772 |
kqueue loop. |
4773 |
|
4774 |
=item EV_USE_PORT |
4775 |
|
4776 |
If defined to be C<1>, libev will compile in support for the Solaris |
4777 |
10 port style backend. Its availability will be detected at runtime, |
4778 |
otherwise another method will be used as fallback. This is the preferred |
4779 |
backend for Solaris 10 systems. |
4780 |
|
4781 |
=item EV_USE_DEVPOLL |
4782 |
|
4783 |
Reserved for future expansion, works like the USE symbols above. |
4784 |
|
4785 |
=item EV_USE_INOTIFY |
4786 |
|
4787 |
If defined to be C<1>, libev will compile in support for the Linux inotify |
4788 |
interface to speed up C<ev_stat> watchers. Its actual availability will |
4789 |
be detected at runtime. If undefined, it will be enabled if the headers |
4790 |
indicate GNU/Linux + Glibc 2.4 or newer, otherwise disabled. |
4791 |
|
4792 |
=item EV_NO_SMP |
4793 |
|
4794 |
If defined to be C<1>, libev will assume that memory is always coherent |
4795 |
between threads, that is, threads can be used, but threads never run on |
4796 |
different cpus (or different cpu cores). This reduces dependencies |
4797 |
and makes libev faster. |
4798 |
|
4799 |
=item EV_NO_THREADS |
4800 |
|
4801 |
If defined to be C<1>, libev will assume that it will never be called from |
4802 |
different threads (that includes signal handlers), which is a stronger |
4803 |
assumption than C<EV_NO_SMP>, above. This reduces dependencies and makes |
4804 |
libev faster. |
4805 |
|
4806 |
=item EV_ATOMIC_T |
4807 |
|
4808 |
Libev requires an integer type (suitable for storing C<0> or C<1>) whose |
4809 |
access is atomic with respect to other threads or signal contexts. No |
4810 |
such type is easily found in the C language, so you can provide your own |
4811 |
type that you know is safe for your purposes. It is used both for signal |
4812 |
handler "locking" as well as for signal and thread safety in C<ev_async> |
4813 |
watchers. |
4814 |
|
4815 |
In the absence of this define, libev will use C<sig_atomic_t volatile> |
4816 |
(from F<signal.h>), which is usually good enough on most platforms. |
4817 |
|
4818 |
=item EV_H (h) |
4819 |
|
4820 |
The name of the F<ev.h> header file used to include it. The default if |
4821 |
undefined is C<"ev.h"> in F<event.h>, F<ev.c> and F<ev++.h>. This can be |
4822 |
used to virtually rename the F<ev.h> header file in case of conflicts. |
4823 |
|
4824 |
=item EV_CONFIG_H (h) |
4825 |
|
4826 |
If C<EV_STANDALONE> isn't C<1>, this variable can be used to override |
4827 |
F<ev.c>'s idea of where to find the F<config.h> file, similarly to |
4828 |
C<EV_H>, above. |
4829 |
|
4830 |
=item EV_EVENT_H (h) |
4831 |
|
4832 |
Similarly to C<EV_H>, this macro can be used to override F<event.c>'s idea |
4833 |
of how the F<event.h> header can be found, the default is C<"event.h">. |
4834 |
|
4835 |
=item EV_PROTOTYPES (h) |
4836 |
|
4837 |
If defined to be C<0>, then F<ev.h> will not define any function |
4838 |
prototypes, but still define all the structs and other symbols. This is |
4839 |
occasionally useful if you want to provide your own wrapper functions |
4840 |
around libev functions. |
4841 |
|
4842 |
=item EV_MULTIPLICITY |
4843 |
|
4844 |
If undefined or defined to C<1>, then all event-loop-specific functions |
4845 |
will have the C<struct ev_loop *> as first argument, and you can create |
4846 |
additional independent event loops. Otherwise there will be no support |
4847 |
for multiple event loops and there is no first event loop pointer |
4848 |
argument. Instead, all functions act on the single default loop. |
4849 |
|
4850 |
Note that C<EV_DEFAULT> and C<EV_DEFAULT_> will no longer provide a |
4851 |
default loop when multiplicity is switched off - you always have to |
4852 |
initialise the loop manually in this case. |
4853 |
|
4854 |
=item EV_MINPRI |
4855 |
|
4856 |
=item EV_MAXPRI |
4857 |
|
4858 |
The range of allowed priorities. C<EV_MINPRI> must be smaller or equal to |
4859 |
C<EV_MAXPRI>, but otherwise there are no non-obvious limitations. You can |
4860 |
provide for more priorities by overriding those symbols (usually defined |
4861 |
to be C<-2> and C<2>, respectively). |
4862 |
|
4863 |
When doing priority-based operations, libev usually has to linearly search |
4864 |
all the priorities, so having many of them (hundreds) uses a lot of space |
4865 |
and time, so using the defaults of five priorities (-2 .. +2) is usually |
4866 |
fine. |
4867 |
|
4868 |
If your embedding application does not need any priorities, defining these |
4869 |
both to C<0> will save some memory and CPU. |
4870 |
|
4871 |
=item EV_PERIODIC_ENABLE, EV_IDLE_ENABLE, EV_EMBED_ENABLE, EV_STAT_ENABLE, |
4872 |
EV_PREPARE_ENABLE, EV_CHECK_ENABLE, EV_FORK_ENABLE, EV_SIGNAL_ENABLE, |
4873 |
EV_ASYNC_ENABLE, EV_CHILD_ENABLE. |
4874 |
|
4875 |
If undefined or defined to be C<1> (and the platform supports it), then |
4876 |
the respective watcher type is supported. If defined to be C<0>, then it |
4877 |
is not. Disabling watcher types mainly saves code size. |
4878 |
|
4879 |
=item EV_FEATURES |
4880 |
|
4881 |
If you need to shave off some kilobytes of code at the expense of some |
4882 |
speed (but with the full API), you can define this symbol to request |
4883 |
certain subsets of functionality. The default is to enable all features |
4884 |
that can be enabled on the platform. |
4885 |
|
4886 |
A typical way to use this symbol is to define it to C<0> (or to a bitset |
4887 |
with some broad features you want) and then selectively re-enable |
4888 |
additional parts you want, for example if you want everything minimal, |
4889 |
but multiple event loop support, async and child watchers and the poll |
4890 |
backend, use this: |
4891 |
|
4892 |
#define EV_FEATURES 0 |
4893 |
#define EV_MULTIPLICITY 1 |
4894 |
#define EV_USE_POLL 1 |
4895 |
#define EV_CHILD_ENABLE 1 |
4896 |
#define EV_ASYNC_ENABLE 1 |
4897 |
|
4898 |
The actual value is a bitset, it can be a combination of the following |
4899 |
values (by default, all of these are enabled): |
4900 |
|
4901 |
=over 4 |
4902 |
|
4903 |
=item C<1> - faster/larger code |
4904 |
|
4905 |
Use larger code to speed up some operations. |
4906 |
|
4907 |
Currently this is used to override some inlining decisions (enlarging the |
4908 |
code size by roughly 30% on amd64). |
4909 |
|
4910 |
When optimising for size, use of compiler flags such as C<-Os> with |
4911 |
gcc is recommended, as well as C<-DNDEBUG>, as libev contains a number of |
4912 |
assertions. |
4913 |
|
4914 |
The default is off when C<__OPTIMIZE_SIZE__> is defined by your compiler |
4915 |
(e.g. gcc with C<-Os>). |
4916 |
|
4917 |
=item C<2> - faster/larger data structures |
4918 |
|
4919 |
Replaces the small 2-heap for timer management by a faster 4-heap, larger |
4920 |
hash table sizes and so on. This will usually further increase code size |
4921 |
and can additionally have an effect on the size of data structures at |
4922 |
runtime. |
4923 |
|
4924 |
The default is off when C<__OPTIMIZE_SIZE__> is defined by your compiler |
4925 |
(e.g. gcc with C<-Os>). |
4926 |
|
4927 |
=item C<4> - full API configuration |
4928 |
|
4929 |
This enables priorities (sets C<EV_MAXPRI>=2 and C<EV_MINPRI>=-2), and |
4930 |
enables multiplicity (C<EV_MULTIPLICITY>=1). |
4931 |
|
4932 |
=item C<8> - full API |
4933 |
|
4934 |
This enables a lot of the "lesser used" API functions. See C<ev.h> for |
4935 |
details on which parts of the API are still available without this |
4936 |
feature, and do not complain if this subset changes over time. |
4937 |
|
4938 |
=item C<16> - enable all optional watcher types |
4939 |
|
4940 |
Enables all optional watcher types. If you want to selectively enable |
4941 |
only some watcher types other than I/O and timers (e.g. prepare, |
4942 |
embed, async, child...) you can enable them manually by defining |
4943 |
C<EV_watchertype_ENABLE> to C<1> instead. |
4944 |
|
4945 |
=item C<32> - enable all backends |
4946 |
|
4947 |
This enables all backends - without this feature, you need to enable at |
4948 |
least one backend manually (C<EV_USE_SELECT> is a good choice). |
4949 |
|
4950 |
=item C<64> - enable OS-specific "helper" APIs |
4951 |
|
4952 |
Enable inotify, eventfd, signalfd and similar OS-specific helper APIs by |
4953 |
default. |
4954 |
|
4955 |
=back |
4956 |
|
4957 |
Compiling with C<gcc -Os -DEV_STANDALONE -DEV_USE_EPOLL=1 -DEV_FEATURES=0> |
4958 |
reduces the compiled size of libev from 24.7Kb code/2.8Kb data to 6.5Kb |
4959 |
code/0.3Kb data on my GNU/Linux amd64 s |