Module: EventMachine

Defined in:

lib/em/future.rb,
lib/em/queue.rb,
lib/em/timers.rb,
lib/em/channel.rb,
lib/em/version.rb,
lib/em/callback.rb,
lib/em/streamer.rb,
lib/em/processes.rb,
lib/em/protocols.rb,
lib/em/spawnable.rb,
lib/eventmachine.rb,
lib/em/connection.rb,
lib/em/deferrable.rb,
lib/em/file_watch.rb,
lib/evma/callback.rb,
lib/jeventmachine.rb,
lib/pr_eventmachine.rb,
lib/pr_eventmachine.rb,
lib/pr_eventmachine.rb,
lib/pr_eventmachine.rb,
lib/pr_eventmachine.rb,
lib/pr_eventmachine.rb,
lib/pr_eventmachine.rb,
lib/pr_eventmachine.rb,
lib/pr_eventmachine.rb,
lib/pr_eventmachine.rb,
lib/pr_eventmachine.rb,
lib/pr_eventmachine.rb,
lib/pr_eventmachine.rb,
lib/pr_eventmachine.rb,
lib/pr_eventmachine.rb,
lib/pr_eventmachine.rb,
lib/em/process_watch.rb,
lib/em/protocols/stomp.rb,
lib/em/protocols/socks4.rb,
lib/em/protocols/tcptest.rb,
lib/em/protocols/memcache.rb,
lib/em/protocols/saslauth.rb,
lib/em/protocols/linetext2.rb,
lib/em/protocols/postgres3.rb,
lib/em/protocols/httpclient.rb,
lib/em/protocols/smtpclient.rb,
lib/em/protocols/smtpserver.rb,
lib/em/protocols/httpclient2.rb,
lib/em/protocols/line_and_text.rb,
lib/em/protocols/object_protocol.rb,
lib/em/protocols/header_and_content.rb,
ext/rubymain.cpp,
ext/fastfilereader/rubymain.cpp

Overview

–

Author

Francis Cianfrocca (gmail: blackhedd)

Homepage

rubyeventmachine.com

Date

15 Nov 2006

See EventMachine and EventMachine::Connection for documentation and usage examples.

---

Copyright © 2006-07 by Francis Cianfrocca. All Rights Reserved. Gmail: blackhedd

This program is free software; you can redistribute it and/or modify it under the terms of either: 1) the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version; or 2) Ruby’s License.

See the file COPYING for complete licensing information.

---

Defined Under Namespace

Modules: Deferrable, Protocols, UuidGenerator Classes: Channel, Connection, ConnectionError, ConnectionNotBound, DatagramObject, DefaultDeferrable, DeferrableChildProcess, Error, EvmaKeyboard, EvmaTCPClient, EvmaTCPServer, EvmaUDPSocket, EvmaUNIXClient, EvmaUNIXServer, FastFileReader, FileNotFoundException, FileStreamer, FileWatch, JEM, LoopbreakReader, PeriodicTimer, ProcessWatch, Queue, Reactor, Selectable, SpawnedProcess, StreamObject, SystemCmd, Timer, UnknownTimerFired, Unsupported, YieldBlockFromSpawnedProcess

Constant Summary

VERSION =

"0.12.11"

P =

EventMachine::Protocols

TimerFired =

TODO: These event numbers are defined in way too many places. DRY them up.

INT2NUM(100)

ConnectionData =

INT2NUM(101)

ConnectionUnbound =

INT2NUM(102)

ConnectionAccepted =

INT2NUM(103)

ConnectionCompleted =

INT2NUM(104)

LoopbreakSignalled =

INT2NUM(105)

ConnectionNotifyReadable =

INT2NUM(106)

ConnectionNotifyWritable =

INT2NUM(107)

SslHandshakeCompleted =

INT2NUM(108)

Class Attribute Summary

• .reactor_thread ⇒ Object readonly

  Exposed to allow joining on the thread, when run in a multithreaded environment.

• .threadpool ⇒ Object readonly

  :nodoc:.

• .threadpool_size ⇒ Object

  Size of the EventMachine.defer threadpool (defaults to 20).

Class Method Summary

• .add_oneshot_timer(interval) ⇒ Object

  #add_oneshot_timer – Changed 04Oct06: intervals from the caller are now in milliseconds, but our native-ruby processor still wants them in seconds.

• .add_periodic_timer(*args, &block) ⇒ Object

  EventMachine#add_periodic_timer adds a periodic timer to the event loop.

• .add_timer(*args, &block) ⇒ Object

  EventMachine#add_timer adds a one-shot timer to the event loop.

• .attach(io, handler = nil, *args, &blk) ⇒ Object

  Attaches an IO object or file descriptor to the eventloop as a regular connection.

• .attach_fd(fileno, watch_mode) ⇒ Object
• .attach_io(io, watch_mode, handler = nil, *args) ⇒ Object

  :nodoc:.

• .bind_connect(bind_addr, bind_port, server, port = nil, handler = nil, *args) ⇒ Object

  EventMachine::bind_connect is like EventMachine::connect, but allows for a local address/port to bind the connection to.

• .bind_connect_server(bind_addr, bind_port, host, port) ⇒ Object
• .Callback(object = nil, method = nil, &blk) ⇒ Object

  Utility method for coercing arguments to an object that responds to #call Accepts an object and a method name to send to, or a block, or an object that responds to call.

• .cancel_timer(timer_or_sig) ⇒ Object

  Cancel a timer using its signature.

• .close_connection(target, after_writing) ⇒ Object

  #close_connection The extension version does NOT raise any kind of an error if an attempt is made to close a non-existent connection.

• .connect(server, port = nil, handler = nil, *args, &blk) ⇒ Object

  EventMachine#connect initiates a TCP connection to a remote server and sets up event-handling for the connection.

• .connect_server(host, port) ⇒ Object

  #connect_server.

• .connect_unix_domain(socketname, *args, &blk) ⇒ Object

  Make a connection to a Unix-domain socket.

• .connect_unix_server(chain) ⇒ Object

  #connect_unix_server.

• .connection_count ⇒ Object

  Returns the total number of connections (file descriptors) currently held by the reactor.

• .defer(op = nil, callback = nil, &blk) ⇒ Object

  #defer is for integrating blocking operations into EventMachine’s control flow.

• .detach_fd(sig) ⇒ Object
• .disable_proxy(from) ⇒ Object

  disable_proxy takes just one argument, a Connection that has proxying enabled via enable_proxy.

• .enable_proxy(from, to, bufsize = 0) ⇒ Object

  enable_proxy allows for direct writing of incoming data back out to another descriptor, at the C++ level in the reactor.

• .epoll ⇒ Object

  #epoll is a harmless no-op in the pure-Ruby implementation.

• .epoll=(val) ⇒ Object

  Epoll is a no-op for Java.

• .epoll? ⇒ Boolean
• .error_handler(cb = nil, &blk) ⇒ Object

  Catch-all for errors raised during event loop callbacks.

• .event_callback(target, opcode, data) ⇒ Object

  :nodoc:.

• .fork_reactor(&block) ⇒ Object

  fork_reactor forks a new process and calls EM#run inside of it, passing your block.

• .get_connection_count ⇒ Object
• .get_max_timer_count ⇒ Object
• .get_max_timers ⇒ Object

  Gets the current maximum number of allowed timers.

• .get_outbound_data_size(sig) ⇒ Object

  #get_outbound_data_size.

• .get_peername(sig) ⇒ Object

  #get_peername.

• .heartbeat_interval ⇒ Object

  Retrieve the heartbeat interval.

• .heartbeat_interval=(time) ⇒ Object

  Set the heartbeat interval.

• .initialize_event_machine ⇒ Object

  #initialize_event_machine.

• .invoke_popen(cmd) ⇒ Object
• .is_notify_readable(sig) ⇒ Object
• .is_notify_writable(sig) ⇒ Object
• .kqueue ⇒ Object
• .kqueue=(val) ⇒ Object
• .kqueue? ⇒ Boolean
• .library_type ⇒ Object

  This is mostly useful for automated tests.

• .next_tick(pr = nil, &block) ⇒ Object

  Schedules a proc for execution immediately after the next “turn” through the reactor core.

• .open_datagram_socket(address, port, handler = nil, *args) ⇒ Object

  EventMachine#open_datagram_socket is for support of UDP-based protocols.

• .open_keyboard(handler = nil, *args) ⇒ Object

  (Experimental).

• .open_udp_socket(host, port) ⇒ Object

  #open_udp_socket.

• .popen(cmd, handler = nil, *args) {|c| ... } ⇒ Object

  Run an external process.

• .reactor_running? ⇒ Boolean

  Tells you whether the EventMachine reactor loop is currently running.

• .reactor_thread? ⇒ Boolean

  Returns true if the calling thread is the same thread as the reactor.

• .read_keyboard ⇒ Object

  #read_keyboard.

• .reconnect(server, port, handler) ⇒ Object

  Connect to a given host/port and re-use the provided EventMachine::Connection instance – Observe, the test for already-connected FAILS if we call a reconnect inside post_init, because we haven’t set up the connection in @conns by that point.

• .release_machine ⇒ Object

  release_machine.

• .run(blk = nil, tail = nil, &block) ⇒ Object

  EventMachine::run initializes and runs an event loop.

• .run_block(&block) ⇒ Object

  Sugars a common use case.

• .run_deferred_callbacks ⇒ Object

  – The is the responder for the loopback-signalled event.

• .run_machine ⇒ Object

  run_machine.

• .schedule(*a, &b) ⇒ Object

  Runs the given callback on the reactor thread, or immediately if called from the reactor thread.

• .send_data(target, data, datalength) ⇒ Object

  #send_data.

• .send_datagram(target, data, datalength, host, port) ⇒ Object

  #send_datagram.

• .send_file_data(sig, filename) ⇒ Object

  #send_file_data.

• .set_comm_inactivity_timeout(sig, tm) ⇒ Object

  #set_comm_inactivity_timeout.

• .set_descriptor_table_size(n_descriptors = nil) ⇒ Object

  Sets the maximum number of file or socket descriptors that your process may open.

• .set_effective_user(username) ⇒ Object

  A wrapper over the setuid system call.

• .set_max_timer_count(n) ⇒ Object

  #set_max_timer_count is a harmless no-op in pure Ruby, which doesn’t have a built-in limit on the number of available timers.

• .set_max_timers(ct) ⇒ Object

  Sets the maximum number of timers and periodic timers that may be outstanding at any given time.

• .set_notify_readable(sig, mode) ⇒ Object
• .set_notify_writable(sig, mode) ⇒ Object
• .set_quantum(mills) ⇒ Object

  For advanced users.

• .set_rlimit_nofile(n) ⇒ Object

  #set_rlimit_nofile is a no-op in the pure-Ruby implementation.

• .set_timer_quantum(interval) ⇒ Object

  #set_timer_quantum in milliseconds.

• .signal_loopbreak ⇒ Object

  #signal_loopbreak.

• .spawn(&block) ⇒ Object

  Spawn an erlang-style process.

• .spawn_threadpool ⇒ Object

  :nodoc:.

• .ssl? ⇒ Boolean

  #ssl? is not implemented for pure-Ruby implementation.

• .start_server(server, port = nil, handler = nil, *args, &block) ⇒ Object

  EventMachine::start_server initiates a TCP server (socket acceptor) on the specified IP address and port.

• .start_tcp_server(host, port) ⇒ Object

  #start_tcp_server.

• .start_tls(sig) ⇒ Object
• .start_unix_domain_server(filename, *args, &block) ⇒ Object

  Start a Unix-domain server.

• .start_unix_server(chain) ⇒ Object

  #start_unix_server.

• .stop ⇒ Object

  #stop.

• .stop_event_loop ⇒ Object

  stop_event_loop may called from within a callback method while EventMachine’s processing loop is running.

• .stop_server(signature) ⇒ Object

  Stop a TCP server socket that was started with EventMachine#start_server.

• .stop_tcp_server(sig) ⇒ Object

  #stop_tcp_server.

• .system(cmd, *args, &cb) ⇒ Object

  EM::system is a simple wrapper for EM::popen.

• .watch(io, handler = nil, *args, &blk) ⇒ Object

  EventMachine::watch registers a given file descriptor or IO object with the eventloop.

• .watch_file(filename, handler = nil, *args) ⇒ Object

  EventMachine’s file monitoring API.

• .watch_process(pid, handler = nil, *args) ⇒ Object

  EventMachine’s process monitoring API.

• .yield(&block) ⇒ Object

  :nodoc:.

• .yield_and_notify(&block) ⇒ Object

  :nodoc:.

Class Attribute Details

.reactor_thread ⇒ Object (readonly)

Exposed to allow joining on the thread, when run in a multithreaded environment. Performing other actions on the thread has undefined semantics.

# File 'lib/eventmachine.rb', line 188

def reactor_thread
  @reactor_thread
end

.threadpool ⇒ Object (readonly)

:nodoc:

# File 'lib/eventmachine.rb', line 1069

def threadpool
  @threadpool
end

.threadpool_size ⇒ Object

Size of the EventMachine.defer threadpool (defaults to 20)

# File 'lib/eventmachine.rb', line 1072

def threadpool_size
  @threadpool_size
end

Class Method Details

.add_oneshot_timer(interval) ⇒ Object

#add_oneshot_timer – Changed 04Oct06: intervals from the caller are now in milliseconds, but our native-ruby processor still wants them in seconds.

# File 'lib/pr_eventmachine.rb', line 58

def self.add_oneshot_timer interval
  @em.installOneshotTimer interval
end

.add_periodic_timer(*args, &block) ⇒ Object

EventMachine#add_periodic_timer adds a periodic timer to the event loop. It takes the same parameters as the one-shot timer method, EventMachine#add_timer. This method schedules execution of the given block repeatedly, at intervals of time at least as great as the number of seconds given in the first parameter to the call.

Usage example

The following sample program will write a dollar-sign to stderr every five seconds. (Of course if the program defined network clients and/or servers, they would be doing their work while the periodic timer is counting off.)

EventMachine::run {
  EventMachine::add_periodic_timer( 5 ) { $stderr.write "$" }
}

Also see EventMachine::PeriodicTimer

# File 'lib/eventmachine.rb', line 400

def self.add_periodic_timer *args, &block
  interval = args.shift
  code = args.shift || block

  EventMachine::PeriodicTimer.new(interval, code)
end

.add_timer(*args, &block) ⇒ Object

EventMachine#add_timer adds a one-shot timer to the event loop. Call it with one or two parameters. The first parameters is a delay-time expressed in seconds (not milliseconds). The second parameter, if present, must be a proc object. If a proc object is not given, then you can also simply pass a block to the method call.

EventMachine#add_timer may be called from the block passed to EventMachine#run or from any callback method. It schedules execution of the proc or block passed to add_timer, after the passage of an interval of time equal to at least the number of seconds specified in the first parameter to the call.

EventMachine#add_timer is a non-blocking call. Callbacks can and will be called during the interval of time that the timer is in effect. There is no built-in limit to the number of timers that can be outstanding at any given time.

Usage example

This example shows how easy timers are to use. Observe that two timers are initiated simultaneously. Also, notice that the event loop will continue to run even after the second timer event is processed, since there was no call to EventMachine#stop_event_loop. There will be no activity, of course, since no network clients or servers are defined. Stop the program with Ctrl-C.

EventMachine::run {
  puts "Starting the run now: #{Time.now}"
  EventMachine::add_timer 5, proc { puts "Executing timer event: #{Time.now}" }
  EventMachine::add_timer( 10 ) { puts "Executing timer event: #{Time.now}" }
}

Also see EventMachine::Timer – Changed 04Oct06: We now pass the interval as an integer number of milliseconds.

# File 'lib/eventmachine.rb', line 370

def self.add_timer *args, &block
  interval = args.shift
  code = args.shift || block
  if code
    # check too many timers!
    s = add_oneshot_timer((interval.to_f * 1000).to_i)
    @timers[s] = code
    s
  end
end

.attach(io, handler = nil, *args, &blk) ⇒ Object

Attaches an IO object or file descriptor to the eventloop as a regular connection. The file descriptor will be set as non-blocking, and EventMachine will process receive_data and send_data events on it as it would for any other connection.

To watch a fd instead, use EventMachine::watch, which will not alter the state of the socket and fire notify_readable and notify_writable events instead.

# File 'lib/eventmachine.rb', line 778

def EventMachine::attach io, handler=nil, *args, &blk
  attach_io io, false, handler, *args, &blk
end

.attach_fd(fileno, watch_mode) ⇒ Object

# File 'lib/jeventmachine.rb', line 192

def self.attach_fd fileno, watch_mode
  # 3Aug09: We could pass in the actual SocketChannel, but then it would be modified (set as non-blocking), and
  # we would need some logic to make sure detach_fd below didn't clobber it. For now, we just always make a new
  # SocketChannel for the underlying file descriptor
  # if fileno.java_kind_of? SocketChannel
  #   ch = fileno
  #   ch.configureBlocking(false)
  #   fileno = nil
  # elsif fileno.java_kind_of? java.nio.channels.Channel

  if fileno.java_kind_of? java.nio.channels.Channel
    field = fileno.getClass.getDeclaredField('fdVal')
    field.setAccessible(true)
    fileno = field.get(fileno)
  else
    raise ArgumentError, 'attach_fd requires Java Channel or POSIX fileno' unless fileno.is_a? Fixnum
  end

  if fileno == 0
    raise "can't open STDIN as selectable in Java =("
  elsif fileno.is_a? Fixnum
    # 8Aug09: The following code is specific to the sun jvm's SocketChannelImpl. Is there a cross-platform
    # way of implementing this? If so, also remember to update EventableSocketChannel#close and #cleanup
    fd = FileDescriptor.new
    fd.set_field 'fd', fileno

    ch = SocketChannel.open
    ch.configureBlocking(false)
    ch.kill
    ch.set_field 'fd', fd
    ch.set_field 'fdVal', fileno
    ch.set_field 'state', ch.get_field('ST_CONNECTED')
  end

  @em.attachChannel(ch,watch_mode)
end

.attach_io(io, watch_mode, handler = nil, *args) ⇒ Object

:nodoc:

# File 'lib/eventmachine.rb', line 782

def EventMachine::attach_io io, watch_mode, handler=nil, *args # :nodoc:
  klass = klass_from_handler(Connection, handler, *args)

  if !watch_mode and klass.public_instance_methods.any?{|m| [:notify_readable, :notify_writable].include? m.to_sym }
    raise ArgumentError, "notify_readable/writable with EM.attach is not supported. Use EM.watch(io){ |c| c.notify_readable = true }"
  end

  if io.respond_to?(:fileno)
    fd = defined?(JRuby) ? JRuby.runtime.getDescriptorByFileno(io.fileno).getChannel : io.fileno
  else
    fd = io
  end

  s = attach_fd fd, watch_mode
  c = klass.new s, *args

  c.instance_variable_set(:@io, io)
  c.instance_variable_set(:@fd, fd)

  @conns[s] = c
  block_given? and yield c
  c
end

.bind_connect(bind_addr, bind_port, server, port = nil, handler = nil, *args) ⇒ Object

EventMachine::bind_connect is like EventMachine::connect, but allows for a local address/port to bind the connection to.

# File 'lib/eventmachine.rb', line 697

def self.bind_connect bind_addr, bind_port, server, port=nil, handler=nil, *args
  begin
    port = Integer(port)
  rescue ArgumentError, TypeError
    # there was no port, so server must be a unix domain socket
    # the port argument is actually the handler, and the handler is one of the args
    args.unshift handler if handler
    handler = port
    port = nil
  end if port

  klass = klass_from_handler(Connection, handler, *args)

  s = if port
        if bind_addr
          bind_connect_server bind_addr, bind_port.to_i, server, port
        else
          connect_server server, port
        end
      else
        connect_unix_server server
      end

  c = klass.new s, *args
  @conns[s] = c
  block_given? and yield c
  c
end

.bind_connect_server(bind_addr, bind_port, host, port) ⇒ Object

# File 'lib/jeventmachine.rb', line 125

def self.bind_connect_server bind_addr, bind_port, server, port
  @em.connectTcpServer bind_addr, bind_port.to_i, server, port
end

.Callback(object = nil, method = nil, &blk) ⇒ Object

Utility method for coercing arguments to an object that responds to #call Accepts an object and a method name to send to, or a block, or an object that responds to call.

cb = EM.Callback{ |msg| puts(msg) }
cb.call('hello world')

cb = EM.Callback(Object, :puts)
cb.call('hello world')

cb = EM.Callback(proc{ |msg| puts(msg) })
cb.call('hello world')

# File 'lib/em/callback.rb', line 15

def self.Callback(object = nil, method = nil, &blk)
  if object && method
    lambda { |*args| object.send method, *args }
  else
    if object.respond_to? :call
      object
    else 
      blk || raise(ArgumentError)
    end
  end
end

.cancel_timer(timer_or_sig) ⇒ Object

Cancel a timer using its signature. You can also use EventMachine::Timer#cancel

# File 'lib/eventmachine.rb', line 409

def self.cancel_timer timer_or_sig
  if timer_or_sig.respond_to? :cancel
    timer_or_sig.cancel
  else
    @timers[timer_or_sig] = false if @timers.has_key?(timer_or_sig)
  end
end

.close_connection(target, after_writing) ⇒ Object

#close_connection The extension version does NOT raise any kind of an error if an attempt is made to close a non-existent connection. Not sure whether we should. For now, we’ll raise an error here in that case.

# File 'lib/pr_eventmachine.rb', line 96

def self.close_connection sig, after_writing
  @em.closeConnection sig, after_writing
end

.connect(server, port = nil, handler = nil, *args, &blk) ⇒ Object

EventMachine#connect initiates a TCP connection to a remote server and sets up event-handling for the connection. You can call EventMachine#connect in the block supplied to EventMachine#run or in any callback method.

EventMachine#connect takes the IP address (or hostname) and port of the remote server you want to connect to. It also takes an optional handler Module which you must define, that contains the callbacks that will be invoked by the event loop on behalf of the connection.

See the description of EventMachine#start_server for a discussion of the handler Module. All of the details given in that description apply for connections created with EventMachine#connect.

Usage Example

Here’s a program which connects to a web server, sends a naive request, parses the HTTP header of the response, and then (antisocially) ends the event loop, which automatically drops the connection (and incidentally calls the connection’s unbind method).

module DumbHttpClient
  def post_init
    send_data "GET / HTTP/1.1\r\nHost: _\r\n\r\n"
    @data = ""
    @parsed = false
  end

  def receive_data data
    @data << data
    if !@parsed and @data =~ /[\n][\r]*[\n]/m
      @parsed = true
      puts "RECEIVED HTTP HEADER:"
      $`.each {|line| puts ">>> #{line}" }

      puts "Now we'll terminate the loop, which will also close the connection"
      EventMachine::stop_event_loop
    end
  end

  def unbind
    puts "A connection has terminated"
  end
end

EventMachine::run {
  EventMachine::connect "www.bayshorenetworks.com", 80, DumbHttpClient
}
puts "The event loop has ended"

There are times when it’s more convenient to define a protocol handler as a Class rather than a Module. Here’s how to do this:

class MyProtocolHandler < EventMachine::Connection
  def initialize *args
    super
    # whatever else you want to do here
  end

  #.......your other class code
end

If you do this, then an instance of your class will be instantiated to handle every network connection created by your code or accepted by servers that you create. If you redefine #post_init in your protocol-handler class, your #post_init method will be called inside the call to #super that you will make in your #initialize method (if you provide one).

– EventMachine::connect initiates a TCP connection to a remote server and sets up event-handling for the connection. It internally creates an object that should not be handled by the caller. HOWEVER, it’s often convenient to get the object to set up interfacing to other objects in the system. We return the newly-created anonymous-class object to the caller. It’s expected that a considerable amount of code will depend on this behavior, so don’t change it.

Ok, added support for a user-defined block, 13Apr06. This leads us to an interesting choice because of the presence of the post_init call, which happens in the initialize method of the new object. We call the user’s block and pass the new object to it. This is a great way to do protocol-specific initiation. It happens AFTER post_init has been called on the object, which I certainly hope is the right choice. Don’t change this lightly, because accepted connections are different from connected ones and we don’t want to have them behave differently with respect to post_init if at all possible.

# File 'lib/eventmachine.rb', line 691

def self.connect server, port=nil, handler=nil, *args, &blk
  bind_connect nil, nil, server, port, handler, *args, &blk
end

.connect_server(host, port) ⇒ Object

#connect_server. Return a connection descriptor to the caller. TODO, what do we return here if we can’t connect?

# File 'lib/pr_eventmachine.rb', line 78

def self.connect_server server, port
  bind_connect_server nil, nil, server, port
end

.connect_unix_domain(socketname, *args, &blk) ⇒ Object

Make a connection to a Unix-domain socket. This is not implemented on Windows platforms. The parameter socketname is a String which identifies the Unix-domain socket you want to connect to. socketname is the name of a file on your local system, and in most cases is a fully-qualified path name. Make sure that your process has enough local permissions to open the Unix-domain socket. See also the documentation for #connect. This method behaves like #connect in all respects except for the fact that it connects to a local Unix-domain socket rather than a TCP socket.

Note that this method is simply an alias for #connect, which can connect to both TCP and Unix-domain sockets – For making connections to Unix-domain sockets. Eventually this has to get properly documented and unified with the TCP-connect methods. Note how nearly identical this is to EventMachine#connect

# File 'lib/eventmachine.rb', line 845

def self.connect_unix_domain socketname, *args, &blk
  connect socketname, *args, &blk
end

.connect_unix_server(chain) ⇒ Object

#connect_unix_server

# File 'lib/pr_eventmachine.rb', line 120

def connect_unix_server chain
  EvmaUNIXClient.connect(chain).uuid
end

.connection_count ⇒ Object

Returns the total number of connections (file descriptors) currently held by the reactor. Note that a tick must pass after the ‘initiation’ of a connection for this number to increment. It’s usually accurate, but don’t rely on the exact precision of this number unless you really know EM internals.

For example, $count will be 0 in this case:

EM.run {
  EM.connect("rubyeventmachine.com", 80)
  $count = EM.connection_count
}

In this example, $count will be 1 since the connection has been established in the next loop of the reactor.

EM.run {
  EM.connect("rubyeventmachine.com", 80)
  EM.next_tick {
    $count = EM.connection_count
  }
}

# File 'lib/eventmachine.rb', line 974

def self.connection_count
  self.get_connection_count
end

.defer(op = nil, callback = nil, &blk) ⇒ Object

#defer is for integrating blocking operations into EventMachine’s control flow. Call #defer with one or two blocks, as shown below (the second block is optional):

operation = proc {
  # perform a long-running operation here, such as a database query.
  "result" # as usual, the last expression evaluated in the block will be the return value.
}
callback = proc {|result|
  # do something with result here, such as send it back to a network client.
}

EventMachine.defer( operation, callback )

The action of #defer is to take the block specified in the first parameter (the “operation”) and schedule it for asynchronous execution on an internal thread pool maintained by EventMachine. When the operation completes, it will pass the result computed by the block (if any) back to the EventMachine reactor. Then, EventMachine calls the block specified in the second parameter to #defer (the “callback”), as part of its normal, synchronous event handling loop. The result computed by the operation block is passed as a parameter to the callback. You may omit the callback parameter if you don’t need to execute any code after the operation completes.

Caveats

Note carefully that the code in your deferred operation will be executed on a separate thread from the main EventMachine processing and all other Ruby threads that may exist in your program. Also, multiple deferred operations may be running at once! Therefore, you are responsible for ensuring that your operation code is threadsafe. [Need more explanation and examples.] Don’t write a deferred operation that will block forever. If so, the current implementation will not detect the problem, and the thread will never be returned to the pool. EventMachine limits the number of threads in its pool, so if you do this enough times, your subsequent deferred operations won’t get a chance to run. [We might put in a timer to detect this problem.]

– OBSERVE that #next_tick hacks into this mechanism, so don’t make any changes here without syncing there.

Running with $VERBOSE set to true gives a warning unless all ivars are defined when they appear in rvalues. But we DON’T ever want to initialize @threadqueue unless we need it, because the Ruby threads are so heavyweight. We end up with this bizarre way of initializing @threadqueue because EventMachine is a Module, not a Class, and has no constructor.

# File 'lib/eventmachine.rb', line 1042

def self.defer op = nil, callback = nil, &blk
  unless @threadpool
    require 'thread'
    @threadpool = []
    @threadqueue = ::Queue.new
    @resultqueue = ::Queue.new
    spawn_threadpool
  end

  @threadqueue << [op||blk,callback]
end

.detach_fd(sig) ⇒ Object

# File 'lib/jeventmachine.rb', line 228

def self.detach_fd sig
  if ch = @em.detachChannel(sig)
    ch.get_field 'fdVal'
  end
end

.disable_proxy(from) ⇒ Object

disable_proxy takes just one argument, a Connection that has proxying enabled via enable_proxy. Calling this method will remove that functionality and your connection will begin receiving data via receive_data again.

# File 'lib/eventmachine.rb', line 1378

def self.disable_proxy(from)
  EM::stop_proxy(from.signature)
end

.enable_proxy(from, to, bufsize = 0) ⇒ Object

enable_proxy allows for direct writing of incoming data back out to another descriptor, at the C++ level in the reactor. This is especially useful for proxies where high performance is required. Propogating data from a server response all the way up to Ruby, and then back down to the reactor to be sent back to the client, is often unnecessary and incurs a significant performance decrease.

The two arguments are Connections, ‘from’ and ‘to’. ‘from’ is the connection whose inbound data you want relayed back out. ‘to’ is the connection to write it to.

Once you call this method, the ‘from’ connection will no longer get receive_data callbacks from the reactor, except in the case that ‘to’ connection has already closed when attempting to write to it. You can see in the example, that proxy_target_unbound will be called when this occurs. After that, further incoming data will be passed into receive_data as normal.

Note also that this feature supports different types of descriptors - TCP, UDP, and pipes. You can relay data from one kind to another.

Example:

module ProxyConnection
  def initialize(client, request)
    @client, @request = client, request
  end

  def post_init
    EM::enable_proxy(self, @client)
  end

  def connection_completed
    send_data @request
  end

  def proxy_target_unbound
    close_connection
  end

  def unbind
    @client.close_connection_after_writing
  end
end

module ProxyServer
  def receive_data(data)
    (@buf ||= "") << data
    if @buf =~ /\r\n\r\n/ # all http headers received
      EM.connect("10.0.0.15", 80, ProxyConnection, self, data)
    end
  end
end

EM.run {
  EM.start_server("127.0.0.1", 8080, ProxyServer)
}

# File 'lib/eventmachine.rb', line 1371

def self.enable_proxy(from, to, bufsize=0)
  EM::start_proxy(from.signature, to.signature, bufsize)
end

.epoll ⇒ Object

#epoll is a harmless no-op in the pure-Ruby implementation. This is intended to ensure that user code behaves properly across different EM implementations.

# File 'lib/pr_eventmachine.rb', line 156

def self.epoll
  # Epoll is a no-op for Java.
  # The latest Java versions run epoll when possible in NIO.
end

.epoll=(val) ⇒ Object

Epoll is a no-op for Java. The latest Java versions run epoll when possible in NIO.

# File 'lib/jeventmachine.rb', line 150

def self.epoll= val
end

.epoll? ⇒ Boolean

Returns:

• (Boolean)

# File 'lib/jeventmachine.rb', line 156

def self.epoll?
  false
end

.error_handler(cb = nil, &blk) ⇒ Object

Catch-all for errors raised during event loop callbacks.

EM.error_handler{ |e|
  puts "Error raised during event loop: #{e.message}"
}

# File 'lib/eventmachine.rb', line 1311

def self.error_handler cb = nil, &blk
  if cb or blk
    @error_handler = cb || blk
  elsif instance_variable_defined? :@error_handler
    remove_instance_variable :@error_handler
  end
end

.event_callback(target, opcode, data) ⇒ Object

:nodoc:

# File 'lib/eventmachine.rb', line 1398

def self.event_callback conn_binding, opcode, data # :nodoc:
  #
  # Changed 27Dec07: Eliminated the hookable error handling.
  # No one was using it, and it degraded performance significantly.
  # It's in original_event_callback, which is dead code.
  #
  # Changed 25Jul08: Added a partial solution to the problem of exceptions
  # raised in user-written event-handlers. If such exceptions are not caught,
  # we must cause the reactor to stop, and then re-raise the exception.
  # Otherwise, the reactor doesn't stop and it's left on the call stack.
  # This is partial because we only added it to #unbind, where it's critical
  # (to keep unbind handlers from being re-entered when a stopping reactor
  # runs down open connections). It should go on the other calls to user
  # code, but the performance impact may be too large.
  #
  if opcode == ConnectionUnbound
    if c = @conns.delete( conn_binding )
      begin
        c.unbind
      rescue
        @wrapped_exception = $!
        stop
      end
    elsif c = @acceptors.delete( conn_binding )
      # no-op
    else
      raise ConnectionNotBound, "recieved ConnectionUnbound for an unknown signature: #{conn_binding}"
    end
  elsif opcode == ConnectionAccepted
    accep,args,blk = @acceptors[conn_binding]
    raise NoHandlerForAcceptedConnection unless accep
    c = accep.new data, *args
    @conns[data] = c
    blk and blk.call(c)
    c # (needed?)
  ##
  # The remaining code is a fallback for the pure ruby and java reactors.
  # In the C++ reactor, these events are handled in the C event_callback() in rubymain.cpp
  elsif opcode == ConnectionCompleted
    c = @conns[conn_binding] or raise ConnectionNotBound, "received ConnectionCompleted for unknown signature: #{conn_binding}"
    c.connection_completed
  elsif opcode == TimerFired
    t = @timers.delete( data )
    return if t == false # timer cancelled
    t or raise UnknownTimerFired, "timer data: #{data}"
    t.call
  elsif opcode == ConnectionData
    c = @conns[conn_binding] or raise ConnectionNotBound, "received data #{data} for unknown signature: #{conn_binding}"
    c.receive_data data
  elsif opcode == LoopbreakSignalled
    run_deferred_callbacks
  elsif opcode == ConnectionNotifyReadable
    c = @conns[conn_binding] or raise ConnectionNotBound
    c.notify_readable
  elsif opcode == ConnectionNotifyWritable
    c = @conns[conn_binding] or raise ConnectionNotBound
    c.notify_writable
  end
end

.fork_reactor(&block) ⇒ Object

fork_reactor forks a new process and calls EM#run inside of it, passing your block. – This implementation is subject to change, especially if we clean up the relationship of EM#run to @reactor_running. Original patch by Aman Gupta.

# File 'lib/eventmachine.rb', line 322

def self.fork_reactor &block
  Kernel.fork do
    if self.reactor_running?
      self.stop_event_loop
      self.release_machine
      self.instance_variable_set( '@reactor_running', false )
    end
    self.run block
  end
end

.get_connection_count ⇒ Object

# File 'lib/jeventmachine.rb', line 247

def self.get_connection_count
  @em.getConnectionCount
end

.get_max_timer_count ⇒ Object

# File 'lib/jeventmachine.rb', line 180

def self.get_max_timer_count
  # harmless no-op in Java. There's no built-in timer limit.
  @max_timer_count || 100_000
end

.get_max_timers ⇒ Object

Gets the current maximum number of allowed timers

# File 'lib/eventmachine.rb', line 950

def self.get_max_timers
  get_max_timer_count
end

.get_outbound_data_size(sig) ⇒ Object

#get_outbound_data_size

# File 'lib/pr_eventmachine.rb', line 190

def get_outbound_data_size sig
  r = Reactor.instance.get_selectable( sig ) or raise "unknown get_outbound_data_size target"
  r.get_outbound_data_size
end

.get_peername(sig) ⇒ Object

#get_peername

# File 'lib/pr_eventmachine.rb', line 130

def self.get_peername sig
  if peer = @em.getPeerName(sig)
    Socket.pack_sockaddr_in *peer
  end
end

.heartbeat_interval ⇒ Object

Retrieve the heartbeat interval. This is how often EventMachine will check for dead connections that have had an InactivityTimeout set via Connection#set_comm_inactivity_timeout. Default is 2 seconds.

# File 'lib/eventmachine.rb', line 1385

def self.heartbeat_interval
  EM::get_heartbeat_interval
end

.heartbeat_interval=(time) ⇒ Object

Set the heartbeat interval. This is how often EventMachine will check for dead connections that have had an InactivityTimeout set via Connection#set_comm_inactivity_timeout. Takes a Numeric number of seconds. Default is 2.

# File 'lib/eventmachine.rb', line 1392

def self.heartbeat_interval= (time)
  EM::set_heartbeat_interval time.to_f
end

.initialize_event_machine ⇒ Object

#initialize_event_machine

# File 'lib/jeventmachine.rb', line 91

def self.initialize_event_machine
  @em = JEM.new
end

.invoke_popen(cmd) ⇒ Object

# File 'lib/jeventmachine.rb', line 168

def self.invoke_popen cmd
  # TEMPORARILY unsupported until someone figures out how to do it.
  raise "unsupported on this platform"
end

.is_notify_readable(sig) ⇒ Object

# File 'lib/jeventmachine.rb', line 241

def self.is_notify_readable sig
  @em.isNotifyReadable(sig)
end

.is_notify_writable(sig) ⇒ Object

# File 'lib/jeventmachine.rb', line 244

def self.is_notify_writable sig
  @em.isNotifyWritable(sig)
end

.kqueue ⇒ Object

# File 'lib/jeventmachine.rb', line 152

def self.kqueue
end

.kqueue=(val) ⇒ Object

# File 'lib/jeventmachine.rb', line 154

def self.kqueue= val
end

.kqueue? ⇒ Boolean

Returns:

• (Boolean)

# File 'lib/jeventmachine.rb', line 159

def self.kqueue?
  false
end

.library_type ⇒ Object

This is mostly useful for automated tests. Return a distinctive symbol so the caller knows whether he’s dealing with an extension or with a pure-Ruby library.

# File 'lib/pr_eventmachine.rb', line 45

def self.library_type
  :java
end

.next_tick(pr = nil, &block) ⇒ Object

Schedules a proc for execution immediately after the next “turn” through the reactor core. An advanced technique, this can be useful for improving memory management and/or application responsiveness, especially when scheduling large amounts of data for writing to a network connection. TODO, we need a FAQ entry on this subject.

#next_tick takes either a single argument (which must be a Proc) or a block. – This works by adding to the @resultqueue that’s used for #defer. The general idea is that next_tick is used when we want to give the reactor a chance to let other operations run, either to balance the load out more evenly, or to let outbound network buffers drain, or both. So we probably do NOT want to block, and we probably do NOT want to be spinning any threads. A program that uses next_tick but not #defer shouldn’t suffer the penalty of having Ruby threads running. They’re extremely expensive even if they’re just sleeping.

Raises:

• (ArgumentError)

# File 'lib/eventmachine.rb', line 1091

def self.next_tick pr=nil, &block
  raise ArgumentError, "no proc or block given" unless ((pr && pr.respond_to?(:call)) or block)
  @next_tick_mutex.synchronize do
    @next_tick_queue << ( pr || block )
  end
  signal_loopbreak if reactor_running?
end

.open_datagram_socket(address, port, handler = nil, *args) ⇒ Object

EventMachine#open_datagram_socket is for support of UDP-based protocols. Its usage is similar to that of EventMachine#start_server. It takes three parameters: an IP address (which must be valid on the machine which executes the method), a port number, and an optional Module name which will handle the data. This method will create a new UDP (datagram) socket and bind it to the address and port that you specify. The normal callbacks (see EventMachine#start_server) will be called as events of interest occur on the newly-created socket, but there are some differences in how they behave.

Connection#receive_data will be called when a datagram packet is received on the socket, but unlike TCP sockets, the message boundaries of the received data will be respected. In other words, if the remote peer sent you a datagram of a particular size, you may rely on Connection#receive_data to give you the exact data in the packet, with the original data length. Also observe that Connection#receive_data may be called with a zero-length data payload, since empty datagrams are permitted in UDP.

Connection#send_data is available with UDP packets as with TCP, but there is an important difference. Because UDP communications are connectionless, there is no implicit recipient for the packets you send. Ordinarily you must specify the recipient for each packet you send. However, EventMachine provides for the typical pattern of receiving a UDP datagram from a remote peer, performing some operation, and then sending one or more packets in response to the same remote peer. To support this model easily, just use Connection#send_data in the code that you supply for Connection:receive_data. EventMachine will provide an implicit return address for any messages sent to Connection#send_data within the context of a Connection#receive_data callback, and your response will automatically go to the correct remote peer. (TODO: Example-code needed!)

Observe that the port number that you supply to EventMachine#open_datagram_socket may be zero. In this case, EventMachine will create a UDP socket that is bound to an ephemeral (not well-known) port. This is not appropriate for servers that must publish a well-known port to which remote peers may send datagrams. But it can be useful for clients that send datagrams to other servers. If you do this, you will receive any responses from the remote servers through the normal Connection#receive_data callback. Observe that you will probably have issues with firewalls blocking the ephemeral port numbers, so this technique is most appropriate for LANs. (TODO: Need an example!)

If you wish to send datagrams to arbitrary remote peers (not necessarily ones that have sent data to which you are responding), then see Connection#send_datagram.

DO NOT call send_data from a datagram socket outside of a #receive_data method. Use #send_datagram. If you do use #send_data outside of a #receive_data method, you’ll get a confusing error because there is no “peer,” as #send_data requires. (Inside of #receive_data, #send_data “fakes” the peer as described above.)

– Replaced the implementation on 01Oct06. Thanks to Tobias Gustafsson for pointing out that this originally did not take a class but only a module.

# File 'lib/eventmachine.rb', line 913

def self.open_datagram_socket address, port, handler=nil, *args
  klass = klass_from_handler(Connection, handler, *args)
  s = open_udp_socket address, port.to_i
  c = klass.new s, *args
  @conns[s] = c
  block_given? and yield c
  c
end

.open_keyboard(handler = nil, *args) ⇒ Object

(Experimental)

# File 'lib/eventmachine.rb', line 1190

def self.open_keyboard handler=nil, *args
  klass = klass_from_handler(Connection, handler, *args)

  s = read_keyboard
  c = klass.new s, *args
  @conns[s] = c
  block_given? and yield c
  c
end

.open_udp_socket(host, port) ⇒ Object

#open_udp_socket

# File 'lib/jeventmachine.rb', line 165

def self.open_udp_socket server, port
  @em.openUdpSocket server, port
end

.popen(cmd, handler = nil, *args) {|c| ... } ⇒ Object

Run an external process. This does not currently work on Windows.

module RubyCounter
  def post_init
    # count up to 5
    send_data "5\n"
  end
  def receive_data data
    puts "ruby sent me: #{data}"
  end
  def unbind
    puts "ruby died with exit status: #{get_status.exitstatus}"
  end
end

EM.run{
  EM.popen("ruby -e' $stdout.sync = true; gets.to_i.times{ |i| puts i+1; sleep 1 } '", RubyCounter)
}

Also see EventMachine::DeferrableChildProcess and EventMachine.system – At this moment, it’s only available on Unix. Perhaps misnamed since the underlying function uses socketpair and is full-duplex.

Yields:

• (c)

# File 'lib/eventmachine.rb', line 1160

def self.popen cmd, handler=nil, *args
  klass = klass_from_handler(Connection, handler, *args)
  w = Shellwords::shellwords( cmd )
  w.unshift( w.first ) if w.first
  s = invoke_popen( w )
  c = klass.new s, *args
  @conns[s] = c
  yield(c) if block_given?
  c
end

.reactor_running? ⇒ Boolean

Tells you whether the EventMachine reactor loop is currently running. Returns true or false. Useful when writing libraries that want to run event-driven code, but may be running in programs that are already event-driven. In such cases, if EventMachine#reactor_running? returns false, your code can invoke EventMachine#run and run your application code inside the block passed to that method. If EventMachine#reactor_running? returns true, just execute your event-aware code.

This method is necessary because calling EventMachine#run inside of another call to EventMachine#run generates a fatal error.

Returns:

• (Boolean)

# File 'lib/eventmachine.rb', line 1182

def self.reactor_running?
  (@reactor_running || false)
end

.reactor_thread? ⇒ Boolean

Returns true if the calling thread is the same thread as the reactor.

Returns:

• (Boolean)

# File 'lib/eventmachine.rb', line 301

def self.reactor_thread?
  Thread.current == @reactor_thread
end

.read_keyboard ⇒ Object

#read_keyboard

# File 'lib/pr_eventmachine.rb', line 197

def self.read_keyboard
  # TEMPORARILY unsupported until someone figures out how to do it.
  raise "temporarily unsupported on this platform"
end

.reconnect(server, port, handler) ⇒ Object

Connect to a given host/port and re-use the provided EventMachine::Connection instance – Observe, the test for already-connected FAILS if we call a reconnect inside post_init, because we haven’t set up the connection in @conns by that point. RESIST THE TEMPTATION to “fix” this problem by redefining the behavior of post_init.

Changed 22Nov06: if called on an already-connected handler, just return the handler and do nothing more. Originally this condition raised an exception. We may want to change it yet again and call the block, if any.

# File 'lib/eventmachine.rb', line 817

def self.reconnect server, port, handler # :nodoc:
  raise "invalid handler" unless handler.respond_to?(:connection_completed)
  #raise "still connected" if @conns.has_key?(handler.signature)
  return handler if @conns.has_key?(handler.signature)

  s = connect_server server, port
  handler.signature = s
  @conns[s] = handler
  block_given? and yield handler
  handler
end

.release_machine ⇒ Object

release_machine. Probably a no-op.

# File 'lib/pr_eventmachine.rb', line 68

def self.release_machine
  @em = nil
end

.run(blk = nil, tail = nil, &block) ⇒ Object

EventMachine::run initializes and runs an event loop. This method only returns if user-callback code calls stop_event_loop. Use the supplied block to define your clients and servers. The block is called by EventMachine::run immediately after initializing its internal event loop but before running the loop. Therefore this block is the right place to call start_server if you want to accept connections from remote clients.

For programs that are structured as servers, it’s usually appropriate to start an event loop by calling EventMachine::run, and let it run forever. It’s also possible to use EventMachine::run to make a single client-connection to a remote server, process the data flow from that single connection, and then call stop_event_loop to force EventMachine::run to return. Your program will then continue from the point immediately following the call to EventMachine::run.

You can of course do both client and servers simultaneously in the same program. One of the strengths of the event-driven programming model is that the handling of network events on many different connections will be interleaved, and scheduled according to the actual events themselves. This maximizes efficiency.

Server usage example

See EventMachine.start_server

Client usage example

See EventMachine.connect

– Obsoleted the use_threads mechanism. 25Nov06: Added the begin/ensure block. We need to be sure that release_machine gets called even if an exception gets thrown within any of the user code that the event loop runs. The best way to see this is to run a unit test with two functions, each of which calls EventMachine#run and each of which throws something inside of #run. Without the ensure, the second test will start without release_machine being called and will immediately throw a C++ runtime error.

# File 'lib/eventmachine.rb', line 236

def self.run blk=nil, tail=nil, &block
  @tails ||= []
  tail and @tails.unshift(tail)

  if reactor_running?
    (b = blk || block) and b.call # next_tick(b)
  else
    @conns = {}
    @acceptors = {}
    @timers = {}
    @wrapped_exception = nil
    @next_tick_queue ||= []
    begin
      @reactor_running = true
      initialize_event_machine
      (b = blk || block) and add_timer(0, b)
      if @next_tick_queue && !@next_tick_queue.empty?
        add_timer(0) { signal_loopbreak }
      end
      @reactor_thread = Thread.current
      run_machine
    ensure
      until @tails.empty?
        @tails.pop.call
      end

      begin
        release_machine
      ensure
        if @threadpool
          @threadpool.each { |t| t.exit }
          @threadpool.each do |t|
            next unless t.alive?
            # ruby 1.9 has no kill!
            t.respond_to?(:kill!) ? t.kill! : t.kill
          end
          @threadqueue = nil
          @resultqueue = nil
          @threadpool = nil
        end

        @next_tick_queue = []
      end
      @reactor_running = false
      @reactor_thread = nil
    end

    raise @wrapped_exception if @wrapped_exception
  end
end

.run_block(&block) ⇒ Object

Sugars a common use case. Will pass the given block to #run, but will terminate the reactor loop and exit the function as soon as the code in the block completes. (Normally, #run keeps running indefinitely, even after the block supplied to it finishes running, until user code calls #stop.)

# File 'lib/eventmachine.rb', line 292

def self.run_block &block
  pr = proc {
    block.call
    EventMachine::stop
  }
  run(&pr)
end

.run_deferred_callbacks ⇒ Object

– The is the responder for the loopback-signalled event. It can be fired either by code running on a separate thread (EM#defer) or on the main thread (EM#next_tick). It will often happen that a next_tick handler will reschedule itself. We consume a copy of the tick queue so that tick events scheduled by tick events have to wait for the next pass through the reactor core.

# File 'lib/eventmachine.rb', line 986

def self.run_deferred_callbacks # :nodoc:
  until (@resultqueue ||= []).empty?
    result,cback = @resultqueue.pop
    cback.call result if cback
  end

  @next_tick_mutex.synchronize do
    jobs, @next_tick_queue = @next_tick_queue, []
    jobs
  end.each { |j| j.call }
end

.run_machine ⇒ Object

run_machine

# File 'lib/pr_eventmachine.rb', line 63

def self.run_machine
  @em.run
end

.schedule(*a, &b) ⇒ Object

Runs the given callback on the reactor thread, or immediately if called from the reactor thread. Accepts the same arguments as EM::Callback

# File 'lib/eventmachine.rb', line 307

def self.schedule(*a, &b)
  cb = Callback(*a, &b)
  if reactor_running? && reactor_thread?
    cb.call
  else
    next_tick { cb.call }
  end
end

.send_data(target, data, datalength) ⇒ Object

#send_data

# File 'lib/pr_eventmachine.rb', line 87

def self.send_data sig, data, length
  @em.sendData sig, data.to_java_bytes
end

.send_datagram(target, data, datalength, host, port) ⇒ Object

#send_datagram. This is currently only for UDP! We need to make it work with unix-domain sockets as well.

# File 'lib/pr_eventmachine.rb', line 142

def self.send_datagram sig, data, length, address, port
  @em.sendDatagram sig, data, length, address, port
end

.send_file_data(sig, filename) ⇒ Object

#send_file_data

# File 'lib/pr_eventmachine.rb', line 176

def send_file_data sig, filename
  sz = File.size(filename)
  raise "file too large" if sz > 32*1024
  data =
  begin
    File.read filename
  rescue
    ""
  end
  send_data sig, data, data.length
end

.set_comm_inactivity_timeout(sig, tm) ⇒ Object

#set_comm_inactivity_timeout

# File 'lib/pr_eventmachine.rb', line 203

def self.set_comm_inactivity_timeout sig, interval
  @em.setCommInactivityTimeout sig, interval
end

.set_descriptor_table_size(n_descriptors = nil) ⇒ Object

Sets the maximum number of file or socket descriptors that your process may open. You can pass this method an integer specifying the new size of the descriptor table. Returns the new descriptor-table size, which may be less than the number you requested. If you call this method with no arguments, it will simply return the current size of the descriptor table without attempting to change it.

The new limit on open descriptors ONLY applies to sockets and other descriptors that belong to EventMachine. It has NO EFFECT on the number of descriptors you can create in ordinary Ruby code.

Not available on all platforms. Increasing the number of descriptors beyond its default limit usually requires superuser privileges. (See #set_effective_user for a way to drop superuser privileges while your program is running.)

# File 'lib/eventmachine.rb', line 1130

def self.set_descriptor_table_size n_descriptors=nil
  EventMachine::set_rlimit_nofile n_descriptors
end

.set_effective_user(username) ⇒ Object

A wrapper over the setuid system call. Particularly useful when opening a network server on a privileged port because you can use this call to drop privileges after opening the port. Also very useful after a call to #set_descriptor_table_size, which generally requires that you start your process with root privileges.

This method has no effective implementation on Windows or in the pure-Ruby implementation of EventMachine. Call #set_effective_user by passing it a string containing the effective name of the user whose privilege-level your process should attain. This method is intended for use in enforcing security requirements, consequently it will throw a fatal error and end your program if it fails.

# File 'lib/eventmachine.rb', line 1111

def self.set_effective_user username
  EventMachine::setuid_string username
end

.set_max_timer_count(n) ⇒ Object

#set_max_timer_count is a harmless no-op in pure Ruby, which doesn’t have a built-in limit on the number of available timers.

# File 'lib/pr_eventmachine.rb', line 172

def self.set_max_timer_count num
  # harmless no-op in Java. There's no built-in timer limit.
  @max_timer_count = num
end

.set_max_timers(ct) ⇒ Object

Sets the maximum number of timers and periodic timers that may be outstanding at any given time. You only need to call #set_max_timers if you need more than the default number of timers, which on most platforms is 1000. Call this method before calling EventMachine#run.

# File 'lib/eventmachine.rb', line 944

def self.set_max_timers ct
  set_max_timer_count ct
end

.set_notify_readable(sig, mode) ⇒ Object

# File 'lib/jeventmachine.rb', line 234

def self.set_notify_readable sig, mode
  @em.setNotifyReadable(sig, mode)
end

.set_notify_writable(sig, mode) ⇒ Object

# File 'lib/jeventmachine.rb', line 237

def self.set_notify_writable sig, mode
  @em.setNotifyWritable(sig, mode)
end

.set_quantum(mills) ⇒ Object

For advanced users. This function sets the default timer granularity, which by default is slightly smaller than 100 milliseconds. Call this function to set a higher or lower granularity. The function affects the behavior of #add_timer and #add_periodic_timer. Most applications will not need to call this function.

The argument is a number of milliseconds. Avoid setting the quantum to very low values because that may reduce performance under some extreme conditions. We recommend that you not set a quantum lower than 10.

You may only call this function while an EventMachine loop is running (that is, after a call to EventMachine#run and before a subsequent call to EventMachine#stop).

# File 'lib/eventmachine.rb', line 935

def self.set_quantum mills
  set_timer_quantum mills.to_i
end

.set_rlimit_nofile(n) ⇒ Object

#set_rlimit_nofile is a no-op in the pure-Ruby implementation. We simply return Ruby’s built-in per-process file-descriptor limit.

# File 'lib/pr_eventmachine.rb', line 166

def self.set_rlimit_nofile n_descriptors
  # Currently a no-op for Java.
end

.set_timer_quantum(interval) ⇒ Object

#set_timer_quantum in milliseconds. The underlying Reactor function wants a (possibly fractional) number of seconds.

# File 'lib/pr_eventmachine.rb', line 150

def self.set_timer_quantum q
  @em.setTimerQuantum q
end

.signal_loopbreak ⇒ Object

#signal_loopbreak

# File 'lib/pr_eventmachine.rb', line 125

def self.signal_loopbreak
  @em.signalLoopbreak
end

.spawn(&block) ⇒ Object

Spawn an erlang-style process

# File 'lib/em/spawnable.rb', line 72

def self.spawn &block
  s = SpawnedProcess.new
  s.set_receiver block
  s
end

.spawn_threadpool ⇒ Object

:nodoc:

# File 'lib/eventmachine.rb', line 1054

def self.spawn_threadpool # :nodoc:
  until @threadpool.size == @threadpool_size.to_i
    thread = Thread.new do
      while true
        op, cback = *@threadqueue.pop
        result = op.call
        @resultqueue << [result, cback]
        EventMachine.signal_loopbreak
      end
    end
    @threadpool << thread
  end
end

.ssl? ⇒ Boolean

#ssl? is not implemented for pure-Ruby implementation

Returns:

• (Boolean)

# File 'lib/pr_eventmachine.rb', line 160

def self.ssl?
  false
end

.start_server(server, port = nil, handler = nil, *args, &block) ⇒ Object

EventMachine::start_server initiates a TCP server (socket acceptor) on the specified IP address and port. The IP address must be valid on the machine where the program runs, and the process must be privileged enough to listen on the specified port (on Unix-like systems, superuser privileges are usually required to listen on any port lower than 1024). Only one listener may be running on any given address/port combination. start_server will fail if the given address and port are already listening on the machine, either because of a prior call to start_server or some unrelated process running on the machine. If start_server succeeds, the new network listener becomes active immediately and starts accepting connections from remote peers, and these connections generate callback events that are processed by the code specified in the handler parameter to start_server.

The optional handler which is passed to start_server is the key to EventMachine’s ability to handle particular network protocols. The handler parameter passed to start_server must be a Ruby Module that you must define. When the network server that is started by start_server accepts a new connection, it instantiates a new object of an anonymous class that is inherited from EventMachine::Connection, into which the methods from your handler have been mixed. Your handler module may redefine any of the methods in EventMachine::Connection in order to implement the specific behavior of the network protocol.

Callbacks invoked in response to network events always take place within the execution context of the object derived from EventMachine::Connection extended by your handler module. There is one object per connection, and all of the callbacks invoked for a particular connection take the form of instance methods called against the corresponding EventMachine::Connection object. Therefore, you are free to define whatever instance variables you wish, in order to contain the per-connection state required by the network protocol you are implementing.

start_server is often called inside the block passed to EventMachine::run, but it can be called from any EventMachine callback. start_server will fail unless the EventMachine event loop is currently running (which is why it’s often called in the block suppled to EventMachine::run).

You may call start_server any number of times to start up network listeners on different address/port combinations. The servers will all run simultaneously. More interestingly, each individual call to start_server can specify a different handler module and thus implement a different network protocol from all the others.

Usage example

Here is an example of a server that counts lines of input from the remote peer and sends back the total number of lines received, after each line. Try the example with more than one client connection opened via telnet, and you will see that the line count increments independently on each of the client connections. Also very important to note, is that the handler for the receive_data function, which our handler redefines, may not assume that the data it receives observes any kind of message boundaries. Also, to use this example, be sure to change the server and port parameters to the start_server call to values appropriate for your environment.

require 'rubygems'
require 'eventmachine'

module LineCounter
  MaxLinesPerConnection = 10

  def post_init
    puts "Received a new connection"
    @data_received = ""
    @line_count = 0
  end

  def receive_data data
    @data_received << data
    while @data_received.slice!( /^[^\n]*[\n]/m )
      @line_count += 1
      send_data "received #{@line_count} lines so far\r\n"
      @line_count == MaxLinesPerConnection and close_connection_after_writing
    end
  end
end

EventMachine::run {
  host,port = "192.168.0.100", 8090
  EventMachine::start_server host, port, LineCounter
  puts "Now accepting connections on address #{host}, port #{port}..."
  EventMachine::add_periodic_timer( 10 ) { $stderr.write "*" }
}

# File 'lib/eventmachine.rb', line 558

def self.start_server server, port=nil, handler=nil, *args, &block
  begin
    port = Integer(port)
  rescue ArgumentError, TypeError
    # there was no port, so server must be a unix domain socket
    # the port argument is actually the handler, and the handler is one of the args
    args.unshift handler if handler
    handler = port
    port = nil
  end if port

  klass = klass_from_handler(Connection, handler, *args)

  s = if port
        start_tcp_server server, port
      else
        start_unix_server server
      end
  @acceptors[s] = [klass,args,block]
  s
end

.start_tcp_server(host, port) ⇒ Object

#start_tcp_server

# File 'lib/pr_eventmachine.rb', line 102

def self.start_tcp_server server, port
  @em.startTcpServer server, port
end

.start_tls(sig) ⇒ Object

# File 'lib/jeventmachine.rb', line 134

def self.start_tls sig
  @em.startTls sig
end

.start_unix_domain_server(filename, *args, &block) ⇒ Object

Start a Unix-domain server

Note that this is an alias for EventMachine::start_server, which can be used to start both TCP and Unix-domain servers

# File 'lib/eventmachine.rb', line 594

def self.start_unix_domain_server filename, *args, &block
  start_server filename, *args, &block
end

.start_unix_server(chain) ⇒ Object

#start_unix_server

# File 'lib/pr_eventmachine.rb', line 114

def self.start_unix_server filename
  # TEMPORARILY unsupported until someone figures out how to do it.
  raise "unsupported on this platform"
end

.stop ⇒ Object

#stop

# File 'lib/pr_eventmachine.rb', line 72

def self.stop
  @em.stop
end

.stop_event_loop ⇒ Object

stop_event_loop may called from within a callback method while EventMachine’s processing loop is running. It causes the processing loop to stop executing, which will cause all open connections and accepting servers to be run down and closed. Callbacks for connection-termination will be called as part of the processing of stop_event_loop. (There currently is no option to panic-stop the loop without closing connections.) When all of this processing is complete, the call to EventMachine::run which started the processing loop will return and program flow will resume from the statement following EventMachine::run call.

Usage example

require 'rubygems'
require 'eventmachine'

module Redmond
  def post_init
    puts "We're sending a dumb HTTP request to the remote peer."
    send_data "GET / HTTP/1.1\r\nHost: www.microsoft.com\r\n\r\n"
  end

  def receive_data data
    puts "We received #{data.length} bytes from the remote peer."
    puts "We're going to stop the event loop now."
    EventMachine::stop_event_loop
  end

  def unbind
    puts "A connection has terminated."
  end
end

puts "We're starting the event loop now."
EventMachine::run {
  EventMachine::connect "www.microsoft.com", 80, Redmond
}
puts "The event loop has stopped."

This program will produce approximately the following output:

We're starting the event loop now.
We're sending a dumb HTTP request to the remote peer.
We received 1440 bytes from the remote peer.
We're going to stop the event loop now.
A connection has terminated.
The event loop has stopped.

# File 'lib/eventmachine.rb', line 468

def self.stop_event_loop
  EventMachine::stop
end

.stop_server(signature) ⇒ Object

Stop a TCP server socket that was started with EventMachine#start_server. – Requested by Kirk Haines. TODO, this isn’t OOP enough. We ought somehow to have #start_server return an object that has a close or a stop method on it.

# File 'lib/eventmachine.rb', line 586

def self.stop_server signature
  EventMachine::stop_tcp_server signature
end

.stop_tcp_server(sig) ⇒ Object

#stop_tcp_server

# File 'lib/pr_eventmachine.rb', line 108

def self.stop_tcp_server sig
  @em.stopTcpServer sig
end

.system(cmd, *args, &cb) ⇒ Object

EM::system is a simple wrapper for EM::popen. It is similar to Kernel::system, but requires a single string argument for the command and performs no shell expansion.

The block or proc passed to EM::system is called with two arguments: the output generated by the command, and a Process::Status that contains information about the command’s execution.

EM.run{
  EM.system('ls'){ |output,status| puts output if status.exitstatus == 0 }
}

You can also supply an additional proc to send some data to the process:

EM.run{
  EM.system('sh', proc{ |process|
    process.send_data("echo hello\n")
    process.send_data("exit\n")
  }, proc{ |out,status|
    puts(out)
  })
}

Like EventMachine.popen, EventMachine.system currently does not work on windows. It returns the pid of the spawned process.

# File 'lib/em/processes.rb', line 108

def EventMachine::system cmd, *args, &cb
  cb ||= args.pop if args.last.is_a? Proc
  init = args.pop if args.last.is_a? Proc

  # merge remaining arguments into the command
  cmd = ([cmd] + args.map{|a|a.to_s.dump}).join(' ')

  EM.get_subprocess_pid(EM.popen(cmd, SystemCmd, cb) do |c|
    init[c] if init
  end.signature)
end

.watch(io, handler = nil, *args, &blk) ⇒ Object

EventMachine::watch registers a given file descriptor or IO object with the eventloop. The file descriptor will not be modified (it will remain blocking or non-blocking).

The eventloop can be used to process readable and writable events on the file descriptor, using EventMachine::Connection#notify_readable= and EventMachine::Connection#notify_writable=

EventMachine::Connection#notify_readable? and EventMachine::Connection#notify_writable? can be used to check what events are enabled on the connection.

To detach the file descriptor, use EventMachine::Connection#detach

Usage Example

module SimpleHttpClient
  def notify_readable
    header = @io.readline

    if header == "\r\n"
      # detach returns the file descriptor number (fd == @io.fileno)
      fd = detach
    end
  rescue EOFError
    detach
  end

  def unbind
    EM.next_tick do
      # socket is detached from the eventloop, but still open
      data = @io.read
    end
  end
end

EM.run{
  $sock = TCPSocket.new('site.com', 80)
  $sock.write("GET / HTTP/1.0\r\n\r\n")
  conn = EM.watch $sock, SimpleHttpClient
  conn.notify_readable = true
}

– Thanks to Riham Aldakkak (eSpace Technologies) for the initial patch

# File 'lib/eventmachine.rb', line 768

def EventMachine::watch io, handler=nil, *args, &blk
  attach_io io, true, handler, *args, &blk
end

.watch_file(filename, handler = nil, *args) ⇒ Object

EventMachine’s file monitoring API. Currently supported are the following events on individual files, using inotify on Linux systems, and kqueue for OSX/BSD:

• File modified (written to)

• File moved/renamed

• File deleted

EventMachine::watch_file takes a filename and a handler Module containing your custom callback methods. This will setup the low level monitoring on the specified file, and create a new EventMachine::FileWatch object with your Module mixed in. FileWatch is a subclass of EM::Connection, so callbacks on this object work in the familiar way. The callbacks that will be fired by EventMachine are:

• file_modified

• file_moved

• file_deleted

You can access the filename being monitored from within this object using FileWatch#path.

When a file is deleted, FileWatch#stop_watching will be called after your file_deleted callback, to clean up the underlying monitoring and remove EventMachine’s reference to the now-useless FileWatch. This will in turn call unbind, if you wish to use it.

The corresponding system-level Errno will be raised when attempting to monitor non-existent files, files with wrong permissions, or if an error occurs dealing with inotify/kqueue.

Usage example:

Make sure we have a file to monitor:
$ echo "bar" > /tmp/foo

module Handler
  def file_modified
    puts "#{path} modified"
  end

  def file_moved
    puts "#{path} moved"
  end

  def file_deleted
    puts "#{path} deleted"
  end

  def unbind
    puts "#{path} monitoring ceased"
  end
end

EM.kqueue = true if EM.kqueue? # file watching requires kqueue on OSX

EM.run {
  EM.watch_file("/tmp/foo", Handler)
}

$ echo "baz" >> /tmp/foo    =>    "/tmp/foo modified"
$ mv /tmp/foo /tmp/oof      =>    "/tmp/foo moved"
$ rm /tmp/oof               =>    "/tmp/foo deleted"
                            =>    "/tmp/foo monitoring ceased"

Note that we have not implemented the ability to pick up on the new filename after a rename. Calling #path will always return the filename you originally used.

# File 'lib/eventmachine.rb', line 1262

def self.watch_file(filename, handler=nil, *args)
  klass = klass_from_handler(FileWatch, handler, *args)

  s = EM::watch_filename(filename)
  c = klass.new s, *args
  # we have to set the path like this because of how Connection.new works
  c.instance_variable_set("@path", filename)
  @conns[s] = c
  block_given? and yield c
  c
end

.watch_process(pid, handler = nil, *args) ⇒ Object

EventMachine’s process monitoring API. Currently supported using kqueue for OSX/BSD.

Usage example:

module ProcessWatcher
  def process_exited
    put 'the forked child died!'
  end
end

pid = fork{ sleep }

EM.run{
  EM.watch_process(pid, ProcessWatcher)
  EM.add_timer(1){ Process.kill('TERM', pid) }
}

# File 'lib/eventmachine.rb', line 1291

def self.watch_process(pid, handler=nil, *args)
  pid = pid.to_i

  klass = klass_from_handler(ProcessWatch, handler, *args)

  s = EM::watch_pid(pid)
  c = klass.new s, *args
  # we have to set the path like this because of how Connection.new works
  c.instance_variable_set("@pid", pid)
  @conns[s] = c
  block_given? and yield c
  c
end

.yield(&block) ⇒ Object

:nodoc:

# File 'lib/em/spawnable.rb', line 78

def self.yield &block # :nodoc:
  return YieldBlockFromSpawnedProcess.new( block, false )
end

.yield_and_notify(&block) ⇒ Object

:nodoc:

# File 'lib/em/spawnable.rb', line 82

def self.yield_and_notify &block # :nodoc:
  return YieldBlockFromSpawnedProcess.new( block, true )
end