A synchronous M essaging P rotocol Overview

A synchronous M essaging P rotocol Overview The purpose of this guide is to describe the uses for and usage of twisted.protocols.amp beyond what is explained in the API documentation. It will show you how to implement an AMP server which can respond to commands or interact directly with individual messages. It will also show you how to implement an AMP client which can issue commands to a server.

AMP is a bidirectional command/response-oriented protocol intended to be extended with application-specific request types and handlers. Various simple data types are supported and support for new data types can be added by applications.

Setting Up

AMP runs over a stream-oriented connection-based protocol, such as TCP or SSL. Before you can use any features of the AMP protocol, you need a connection. The protocol class to use to establish an AMP connection is AMP . Connection setup works as it does for almost all protocols in Twisted. For example, you can set up a listening AMP server using a server endpoint:

basic_server.tac

from twisted.protocols.amp import AMP
from twisted.internet import reactor
from twisted.internet.protocol import Factory
from twisted.internet.endpoints import TCP4ServerEndpoint
from twisted.application.service import Application
from twisted.application.internet import StreamServerEndpointService

application = Application("basic AMP server")

endpoint = TCP4ServerEndpoint(reactor, 8750)
factory = Factory()
factory.protocol = AMP
service = StreamServerEndpointService(endpoint, factory)
service.setServiceParent(application)

And you can connect to an AMP server using a client endpoint:

basic_client.py

if __name__ == '__main__':
    import basic_client
    raise SystemExit(basic_client.main())

from sys import stdout

from twisted.python.log import startLogging, err
from twisted.protocols.amp import AMP
from twisted.internet import reactor
from twisted.internet.protocol import Factory
from twisted.internet.endpoints import TCP4ClientEndpoint

def connect():
    endpoint = TCP4ClientEndpoint(reactor, "127.0.0.1", 8750)
    return endpoint.connect(Factory.forProtocol(AMP))


def main():
    startLogging(stdout)

    d = connect()
    d.addErrback(err, "Connection failed")
    def done(ignored):
        reactor.stop()
    d.addCallback(done)

    reactor.run()

Commands

Either side of an AMP connection can issue a command to the other side. Each kind of command is represented as a subclass of Command . A Command defines arguments, response values, and error conditions.

from twisted.protocols.amp import Integer, String, Unicode, Command

class UsernameUnavailable(Exception):
    pass

class RegisterUser(Command):
    arguments = [('username', Unicode()),
                 ('publickey', String())]

    response = [('uid', Integer())]

    errors = {UsernameUnavailable: 'username-unavailable'}

The definition of the command’s signature - its arguments, response, and possible error conditions - is separate from the implementation of the behavior to execute when the command is received. The Command subclass only defines the former.

Commands are issued by calling callRemote on either side of the connection. This method returns a Deferred which eventually fires with the result of the command.

command_client.py

if __name__ == '__main__':
    import command_client
    raise SystemExit(command_client.main())

from sys import stdout

from twisted.python.log import startLogging, err
from twisted.protocols.amp import Integer, String, Unicode, Command
from twisted.internet import reactor

from basic_client import connect

class UsernameUnavailable(Exception):
    pass


class RegisterUser(Command):
    arguments = [('username', Unicode()),
                 ('publickey', String())]

    response = [('uid', Integer())]

    errors = {UsernameUnavailable: 'username-unavailable'}


def main():
    startLogging(stdout)

    d = connect()
    def connected(protocol):
        return protocol.callRemote(
            RegisterUser,
            username=u'alice',
            publickey='ssh-rsa AAAAB3NzaC1yc2 alice@actinium')
    d.addCallback(connected)

    def registered(result):
        print 'Registration result:', result
    d.addCallback(registered)

    d.addErrback(err, "Failed to register")

    def finished(ignored):
        reactor.stop()
    d.addCallback(finished)

    reactor.run()

Locators

The logic for handling a command can be specified as an object separate from the AMP instance which interprets and formats bytes over the network.

from twisted.protocols.amp import CommandLocator
from twisted.python.filepath import FilePath

class UsernameUnavailable(Exception):
    pass

class UserRegistration(CommandLocator):
    uidCounter = 0

    @RegisterUser.responder
    def register(self, username, publickey):
        path = FilePath(username)
        if path.exists():
            raise UsernameUnavailable()
        self.uidCounter += 1
        path.setContent('%d %s\n' % (self.uidCounter, publickey))
        return self.uidCounter

When you define a separate CommandLocator subclass, use it by passing an instance of it to the AMP initializer.

factory = Factory()
factory.protocol = lambda: AMP(locator=UserRegistration())

If no locator is passed in, AMP acts as its own locator. Command responders can be defined on an AMP subclass, just as the responder was defined on the UserRegistration example above.

Box Receivers

AMP conversations consist of an exchange of messages called boxes . A box consists of a sequence of pairs of key and value (for example, the pair username and alice ). Boxes are generally represented as dict instances. Normally boxes are passed back and forth to implement the command request/response features described above. The logic for handling each box can be specified as an object separate from the AMP instance.

from zope.interface import implements

from twisted.protocols.amp import IBoxReceiver

class BoxReflector(object):
    implements(IBoxReceiver)

    def startReceivingBoxes(self, boxSender):
        self.boxSender = boxSender

    def ampBoxReceived(self, box):
        self.boxSender.sendBox(box)

    def stopReceivingBoxes(self, reason):
        self.boxSender = None

These methods parallel those of IProtocol . Startup notification is given by startReceivingBoxes . The argument passed to it is an IBoxSender provider, which can be used to send boxes back out over the network. ampBoxReceived delivers notification for a complete box having been received. And last, stopReceivingBoxes notifies the object that no more boxes will be received and no more can be sent. The argument passed to it is a Failure which may contain details about what caused the conversation to end.

To use a custom IBoxReceiver , pass it to the AMP initializer.

factory = Factory()
factory.protocol = lambda: AMP(boxReceiver=BoxReflector())

If no box receiver is passed in, AMP acts as its own box receiver. It handles boxes by treating them as command requests or responses and delivering them to the appropriate responder or as a result to a callRemote Deferred .