{Ninja-Shell}
Home
Info
Upload
Command
View /etc/passwd
cPanel Reset Password
Filename: //lib/x86_64-linux-gnu/perl5//5.32/Net/DBus/Reactor.pm
# -*- perl -*- # # Copyright (C) 2004-2011 Daniel P. Berrange # # This program is free software; You can redistribute it and/or modify # it under the same terms as Perl itself. Either: # # a) the GNU General Public License as published by the Free # Software Foundation; either version 2, or (at your option) any # later version, # # or # # b) the "Artistic License" # # The file "COPYING" distributed along with this file provides full # details of the terms and conditions of the two licenses. =pod =head1 NAME Net::DBus::Reactor - application event loop =head1 SYNOPSIS Create and run an event loop: use Net::DBus::Reactor; my $reactor = Net::DBus::Reactor->main(); $reactor->run(); Manage some file handlers $reactor->add_read($fd, Net::DBus::Callback->new(method => sub { my $fd = shift; ...read some data... }, args => [$fd])); $reactor->add_write($fd, Net::DBus::Callback->new(method => sub { my $fd = shift; ...write some data... }, args => [$fd])); Temporarily (dis|en)able a handle # Disable $reactor->toggle_read($fd, 0); # Enable $reactor->toggle_read($fd, 1); Permanently remove a handle $reactor->remove_read($fd); Manage a regular timeout every 100 milliseconds my $timer = $reactor->add_timeout(100, Net::DBus::Callback->new( method => sub { ...process the alarm... })); Temporarily (dis|en)able a timer # Disable $reactor->toggle_timeout($timer, 0); # Enable $reactor->toggle_timeout($timer, 1); Permanently remove a timer $reactor->remove_timeout($timer); Add a post-dispatch hook my $hook = $reactor->add_hook(Net::DBus::Callback->new( method => sub { ... do some work... })); Remove a hook $reactor->remove_hook($hook); =head1 DESCRIPTION This class provides a general purpose event loop for the purposes of multiplexing I/O events and timeouts in a single process. The underlying implementation is done using the select system call. File handles can be registered for monitoring on read, write and exception (out-of-band data) events. Timers can be registered to expire with a periodic frequency. These are implemented using the timeout parameter of the select system call. Since this parameter merely represents an upper bound on the amount of time the select system call is allowed to sleep, the actual period of the timers may vary. Under normal load this variance is typically 10 milliseconds. Finally, hooks may be registered which will be invoked on each iteration of the event loop (ie after processing the file events, or timeouts indicated by the select system call returning). =head1 METHODS =over 4 =cut package Net::DBus::Reactor; use 5.006; use strict; use warnings; use Net::DBus::Binding::Watch; use Net::DBus::Callback; use Time::HiRes qw(gettimeofday); =item my $reactor = Net::DBus::Reactor->new(); Creates a new event loop ready for monitoring file handles, or generating timeouts. Except in very unusual circumstances (examples of which I can't think up) it is not necessary or desriable to explicitly create new reactor instances. Instead call the L<main> method to get a handle to the singleton instance. =cut sub new { my $proto = shift; my $class = ref($proto) || $proto; my %params = @_; my $self = {}; $self->{fds} = { read => {}, write => {}, exception => {} }; $self->{timeouts} = []; $self->{hooks} = []; bless $self, $class; return $self; } use vars qw($main_reactor); =item $reactor = Net::DBus::Reactor->main; Return a handle to the singleton instance of the reactor. This is the recommended way of getting hold of a reactor, since it removes the need for modules to pass around handles to their privately created reactors. =cut sub main { my $class = shift; $main_reactor = $class->new() unless defined $main_reactor; return $main_reactor; } =item $reactor->manage($connection); =item $reactor->manage($server); Registers a C<Net::DBus::Binding::Connection> or C<Net::DBus::Binding::Server> object for management by the event loop. This basically involves hooking up the watch & timeout callbacks to the event loop. For connections it will also register a hook to invoke the C<dispatch> method periodically. =cut sub manage { my $self = shift; my $object = shift; if ($object->can("set_watch_callbacks")) { $object->set_watch_callbacks(sub { my $object = shift; my $watch = shift; $self->_manage_watch_on($object, $watch); }, sub { my $object = shift; my $watch = shift; $self->_manage_watch_off($object, $watch); }, sub { my $object = shift; my $watch = shift; $self->_manage_watch_toggle($object, $watch); }); } if ($object->can("set_timeout_callbacks")) { $object->set_timeout_callbacks(sub { my $object = shift; my $timeout = shift; my $key = $self->add_timeout($timeout->get_interval, Net::DBus::Callback->new(object => $timeout, method => "handle", args => []), $timeout->is_enabled); $timeout->set_data($key); }, sub { my $object = shift; my $timeout = shift; my $key = $timeout->get_data; $self->remove_timeout($key); }, sub { my $object = shift; my $timeout = shift; my $key = $timeout->get_data; $self->toggle_timeout($key, $timeout->is_enabled, $timeout->get_interval); }); } if ($object->can("dispatch")) { $self->add_hook(Net::DBus::Callback->new(object => $object, method => "dispatch", args => []), 1); } if ($object->can("flush")) { $self->add_hook(Net::DBus::Callback->new(object => $object, method => "flush", args => []), 1); } } sub _manage_watch_on { my $self = shift; my $object = shift; my $watch = shift; my $flags = $watch->get_flags; if ($flags & &Net::DBus::Binding::Watch::READABLE) { $self->add_read($watch->get_fileno, Net::DBus::Callback->new(object => $watch, method => "handle", args => [&Net::DBus::Binding::Watch::READABLE]), $watch->is_enabled); } if ($flags & &Net::DBus::Binding::Watch::WRITABLE) { $self->add_write($watch->get_fileno, Net::DBus::Callback->new(object => $watch, method => "handle", args => [&Net::DBus::Binding::Watch::WRITABLE]), $watch->is_enabled); } # $self->add_exception($watch->get_fileno, $watch, # Net::DBus::Callback->new(object => $watch, # method => "handle", # args => [&Net::DBus::Binding::Watch::ERROR]), # $watch->is_enabled); } sub _manage_watch_off { my $self = shift; my $object = shift; my $watch = shift; my $flags = $watch->get_flags; if ($flags & &Net::DBus::Binding::Watch::READABLE) { $self->remove_read($watch->get_fileno); } if ($flags & &Net::DBus::Binding::Watch::WRITABLE) { $self->remove_write($watch->get_fileno); } # $self->remove_exception($watch->get_fileno); } sub _manage_watch_toggle { my $self = shift; my $object = shift; my $watch = shift; my $flags = $watch->get_flags; if ($flags & &Net::DBus::Binding::Watch::READABLE) { $self->toggle_read($watch->get_fileno, $watch->is_enabled); } if ($flags & &Net::DBus::Binding::Watch::WRITABLE) { $self->toggle_write($watch->get_fileno, $watch->is_enabled); } $self->toggle_exception($watch->get_fileno, $watch->is_enabled); } =item $reactor->run(); Starts the event loop monitoring any registered file handles and timeouts. At least one file handle, or timer must have been registered prior to running the reactor, otherwise it will immediately exit. The reactor will run until all registered file handles, or timeouts have been removed, or disabled. The reactor can be explicitly stopped by calling the C<shutdown> method. =cut sub run { my $self = shift; $self->{running} = 1; while ($self->{running}) { $self->step }; } =item $reactor->shutdown(); Explicitly shutdown the reactor after pending events have been processed. =cut sub shutdown { my $self = shift; $self->{running} = 0; } =item $reactor->step(); Perform one iteration of the event loop, going to sleep until an event occurs on a registered file handle, or a timeout occurrs. This method is generally not required in day-to-day use. =cut sub step { my $self = shift; my @callbacks = $self->_dispatch_hook(); foreach my $callback (@callbacks) { $callback->invoke; } my ($ri, $ric) = $self->_bits("read"); my ($wi, $wic) = $self->_bits("write"); my ($ei, $eic) = $self->_bits("exception"); my $timeout = $self->_timeout($self->_now); if (!$ric && !$wic && !$eic && !(defined $timeout)) { $self->{running} = 0; } # One of the hooks we ran might have requested shutdown # so check here to avoid a undesirable wait in select() # cf RT #39068 return unless $self->{running}; my ($ro, $wo, $eo); my $n = select($ro=$ri,$wo=$wi,$eo=$ei, (defined $timeout ? ($timeout ? $timeout/1000 : 0) : undef)); @callbacks = (); if ($n > 0) { push @callbacks, $self->_dispatch_fd("read", $ro); push @callbacks, $self->_dispatch_fd("write", $wo); push @callbacks, $self->_dispatch_fd("exception", $eo); } push @callbacks, $self->_dispatch_timeout($self->_now); #push @callbacks, $self->_dispatch_hook(); foreach my $callback (@callbacks) { $callback->invoke; } return 1; } sub _now { my $self = shift; my @now = gettimeofday; return $now[0] * 1000 + (($now[1] - ($now[1] % 1000)) / 1000); } sub _bits { my $self = shift; my $type = shift; my $vec = ''; my $count = 0; foreach (keys %{$self->{fds}->{$type}}) { next unless $self->{fds}->{$type}->{$_}->{enabled}; $count++; vec($vec, $_, 1) = 1; } return ($vec, $count); } sub _timeout { my $self = shift; my $now = shift; my $timeout; foreach (@{$self->{timeouts}}) { next unless defined && $_->{enabled}; my $expired = $now - $_->{last_fired}; # In case the clock was moved we handle $expired being < 0 (see t/26-reactor-time-adjusted.t) $expired = 0 if ($expired < 0); my $interval = ($expired > $_->{interval} ? 0 : $_->{interval} - $expired); $timeout = $interval if !(defined $timeout) || ($interval < $timeout); } return $timeout; } sub _dispatch_fd { my $self = shift; my $type = shift; my $vec = shift; my @callbacks; foreach my $fd (keys %{$self->{fds}->{$type}}) { next unless $self->{fds}->{$type}->{$fd}->{enabled}; if (vec($vec, $fd, 1)) { my $rec = $self->{fds}->{$type}->{$fd}; push @callbacks, $self->{fds}->{$type}->{$fd}->{callback}; } } return @callbacks; } sub _dispatch_timeout { my $self = shift; my $now = shift; my @callbacks; foreach my $timeout (@{$self->{timeouts}}) { next unless defined($timeout) && $timeout->{enabled}; my $expired = $now - $timeout->{last_fired}; # if system clock was adjusted last_fired can be in the future # (see t/26-reactor-time-adjusted.t) $expired = $timeout->{interval} if ($expired < 0); # Select typically returns a little (0-10 ms) before we # asked it for. (8 milliseconds seems reasonable balance # between early timeouts & extra select calls if ($expired >= ($timeout->{interval}-8)) { $timeout->{last_fired} = $now; push @callbacks, $timeout->{callback}; } } return @callbacks; } sub _dispatch_hook { my $self = shift; my $now = shift; my @callbacks; foreach my $hook (@{$self->{hooks}}) { next unless $hook->{enabled}; push @callbacks, $hook->{callback}; } return @callbacks; } =item $reactor->add_read($fd, $callback[, $status]); Registers a file handle for monitoring of read events. The C<$callback> parameter specifies either a code reference to a subroutine, or an instance of the C<Net::DBus::Callback> object to invoke each time an event occurs. The optional C<$status> parameter is a boolean value to specify whether the watch is initially enabled. =cut sub add_read { my $self = shift; $self->_add("read", @_); } =item $reactor->add_write($fd, $callback[, $status]); Registers a file handle for monitoring of write events. The C<$callback> parameter specifies either a code reference to a subroutine, or an instance of the C<Net::DBus::Callback> object to invoke each time an event occurs. The optional C<$status> parameter is a boolean value to specify whether the watch is initially enabled. =cut sub add_write { my $self = shift; $self->_add("write", @_); } =item $reactor->add_exception($fd, $callback[, $status]); Registers a file handle for monitoring of exception events. The C<$callback> parameter specifies either a code reference to a subroutine, or an instance of the C<Net::DBus::Callback> object to invoke each time an event occurs. The optional C<$status> parameter is a boolean value to specify whether the watch is initially enabled. =cut sub add_exception { my $self = shift; $self->_add("exception", @_); } =item my $id = $reactor->add_timeout($interval, $callback, $status); Registers a new timeout to expire every C<$interval> milliseconds. The C<$callback> parameter specifies either a code reference to a subroutine, or an instance of the C<Net::DBus::Callback> object to invoke each time the timeout expires. The optional C<$status> parameter is a boolean value to specify whether the timeout is initially enabled. The return parameter is a unique identifier which can be used to later remove or disable the timeout. =cut sub add_timeout { my $self = shift; my $interval = shift; my $callback = shift; my $enabled = shift; $enabled = 1 unless defined $enabled; if (ref($callback) eq "CODE") { $callback = Net::DBus::Callback->new(method => $callback); } my $key; for (my $i = 0 ; $i <= $#{$self->{timeouts}} && !(defined $key); $i++) { $key = $i unless defined $self->{timeouts}->[$i]; } $key = $#{$self->{timeouts}}+1 unless defined $key; $self->{timeouts}->[$key] = { interval => $interval, last_fired => $self->_now, callback => $callback, enabled => $enabled }; return $key; } =item $reactor->remove_timeout($id); Removes a previously registered timeout specified by the C<$id> parameter. =cut sub remove_timeout { my $self = shift; my $key = shift; die "no timeout active with key '$key'" unless defined $self->{timeouts}->[$key]; $self->{timeouts}->[$key] = undef; } =item $reactor->toggle_timeout($id, $status[, $interval]); Updates the state of a previously registered timeout specified by the C<$id> parameter. The C<$status> parameter specifies whether the timeout is to be enabled or disabled, while the optional C<$interval> parameter can be used to change the period of the timeout. =cut sub toggle_timeout { my $self = shift; my $key = shift; my $enabled = shift; die "no timeout active with key '$key'" unless defined $self->{timeouts}->[$key]; $self->{timeouts}->[$key]->{enabled} = $enabled; $self->{timeouts}->[$key]->{interval} = shift if @_; } =item my $id = $reactor->add_hook($callback[, $status]); Registers a new hook to be fired on each iteration of the event loop. The C<$callback> parameter specifies either a code reference to a subroutine, or an instance of the C<Net::DBus::Callback> class to invoke. The C<$status> parameter determines whether the hook is initially enabled, or disabled. The return parameter is a unique id which should be used to later remove, or disable the hook. =cut sub add_hook { my $self = shift; my $callback = shift; my $enabled = shift; $enabled = 1 unless defined $enabled; if (ref($callback) eq "CODE") { $callback = Net::DBus::Callback->new(method => $callback); } my $key; for (my $i = 0 ; $i <= $#{$self->{hooks}} && !(defined $key); $i++) { $key = $i unless defined $self->{hooks}->[$i]; } $key = $#{$self->{hooks}}+1 unless defined $key; $self->{hooks}->[$key] = { callback => $callback, enabled => $enabled }; return $key; } =item $reactor->remove_hook($id) Removes the previously registered hook identified by C<$id>. =cut sub remove_hook { my $self = shift; my $key = shift; die "no hook present with key '$key'" unless defined $self->{hooks}->[$key]; $self->{hooks}->[$key] = undef; } =item $reactor->toggle_hook($id, $status) Updates the status of the previously registered hook identified by C<$id>. The C<$status> parameter determines whether the hook is to be enabled or disabled. =cut sub toggle_hook { my $self = shift; my $key = shift; my $enabled = shift; $self->{hooks}->[$key]->{enabled} = $enabled; } sub _add { my $self = shift; my $type = shift; my $fd = shift; my $callback = shift; my $enabled = shift; $enabled = 1 unless defined $enabled; if (ref($callback) eq "CODE") { $callback = Net::DBus::Callback->new(method => $callback); } $self->{fds}->{$type}->{$fd} = { callback => $callback, enabled => $enabled }; } =item $reactor->remove_read($fd); =item $reactor->remove_write($fd); =item $reactor->remove_exception($fd); Removes a watch on the file handle C<$fd>. =cut sub remove_read { my $self = shift; $self->_remove("read", @_); } sub remove_write { my $self = shift; $self->_remove("write", @_); } sub remove_exception { my $self = shift; $self->_remove("exception", @_); } sub _remove { my $self = shift; my $type = shift; my $fd = shift; die "no handle ($type) active with fd '$fd'" unless exists $self->{fds}->{$type}->{$fd}; delete $self->{fds}->{$type}->{$fd}; } =item $reactor->toggle_read($fd, $status); =item $reactor->toggle_write($fd, $status); =item $reactor->toggle_exception($fd, $status); Updates the status of a watch on the file handle C<$fd>. The C<$status> parameter species whether the watch is to be enabled or disabled. =cut sub toggle_read { my $self = shift; $self->_toggle("read", @_); } sub toggle_write { my $self = shift; $self->_toggle("write", @_); } sub toggle_exception { my $self = shift; $self->_toggle("exception", @_); } sub _toggle { my $self = shift; my $type = shift; my $fd = shift; my $enabled = shift; $self->{fds}->{$type}->{$fd}->{enabled} = $enabled; } 1; =pod =back =head1 SEE ALSO L<Net::DBus::Callback>, L<Net::DBus::Connection>, L<Net::DBus::Server> =head1 AUTHOR Daniel Berrange E<lt>dan@berrange.comE<gt> =head1 COPYRIGHT Copyright 2004-2011 by Daniel Berrange =cut
./Ninja\.