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Related to this SO question (C state-machine design), could you SO folks share with me (and the community!) your Python state-machine design techniques?

Update3: At the moment, I am going for an engine based on the following:

class TrackInfoHandler(object):
    def __init__(self):

    ## ================================== Event callbacks

    def startElement(self, name, attrs):
        self._dispatch(("startElement", name, attrs))

    def characters(self, ch):

    def endElement(self, name):
        self._dispatch(("endElement", self._acc))

    ## ===================================
    def _missingState(self, _event):
        raise HandlerException("missing state(%s)" % self._state)

    def _dispatch(self, event):
        getattr(self, methodName, self._missingState)(event)

    ## =================================== State related callbacks

But I am sure there are tons of ways of going at it whilst leveraging Python's dynamic nature (e.g. dynamic dispatching).

Update2: I am after design techniques for the "engine" that receives the "events" and "dispatches" against those based on the "state" of the machine.

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To paraphrase Adam's point, I think some more concrete information about what you're trying to accomplish would help. –  Jason Orendorff Jan 20 '10 at 14:42
@Jason Orendorff: fair enough. I have updated the question accordingly. –  jldupont Jan 20 '10 at 14:45

11 Answers 11

up vote 25 down vote accepted

I don't really get the question. The State Design pattern is pretty clear. See the Design Patterns book.

class SuperState( object ):
    def someStatefulMethod( self ):
        raise NotImplementedError()
    def transitionRule( self, input ):
        raise NotImplementedError()

class SomeState( SuperState ):
    def someStatefulMethod( self ):
        actually do something()
    def transitionRule( self, input ):
        return NextState()

That's pretty common boilerplate, used in Java, C++, Python (and I'm sure other languages, also).

If your state transition rules happen to be trivial, there are some optimizations to push the transition rule itself into the superclass.

Note that we need to have forward references, so we refer to classes by name, and use eval to translate a class name to an actual class. The alternative is to make the transition rules instance variables instead of class variables and then create the instances after all the classes are defined.

class State( object ):
    def transitionRule( self, input ):
        return eval(self.map[input])()

class S1( State ): 
    map = { "input": "S2", "other": "S3" }
    pass # Overrides to state-specific methods

class S2( State ):
    map = { "foo": "S1", "bar": "S2" }

class S3( State ):
    map = { "quux": "S1" }

In some cases, your event isn't as simple as testing objects for equality, so a more general transition rule is to use a proper list of function-object pairs.

class State( object ):
    def transitionRule( self, input ):
        next_states = [ s for f,s in self.map if f(input)  ]
        assert len(next_states) >= 1, "faulty transition rule"
        return eval(next_states[0])()

class S1( State ):
    map = [ (lambda x: x == "input", "S2"), (lambda x: x == "other", "S3" ) ]

class S2( State ):
    map = [ (lambda x: "bar" <= x <= "foo", "S3"), (lambda x: True, "S1") ]

Since the rules are evaluated sequentially, this allows a "default" rule.

share|improve this answer
+1: interesting technique... thanks! –  jldupont Jan 20 '10 at 15:14
@jldupont: Right out of the book. Didn't invent it, just copied it from the GoF Design Patterns book. That's why I still don't get your question -- they cover this completely. –  S.Lott Jan 20 '10 at 15:19
@scott: ... and I thank you for your contribution. I do not believe I have "complained" but of course the definition of "complaining" falls in the "qualitative territory". Have a good day! –  jldupont Jan 20 '10 at 15:43
@scott: come to think of it, my previous "complaint" might have been triggered by your insistence in stating that you don't get my question. No hard feelings on my side. –  jldupont Jan 20 '10 at 15:58
Although you copied it out the book, it seems "nicer" to use something like globals()[self.map[input]]() (or a dict like {'S1': S1}) instead of eval? To further nitpick, it's redefining the built-in next` –  dbr Jan 20 '10 at 16:22

In the April, 2009 issue of Python Magazine, I wrote an article on embedding a State DSL within Python, using pyparsing and imputil. This code would allow you to write the module trafficLight.pystate:

# trafficLight.pystate

# define state machine
statemachine TrafficLight:
    Red -> Green
    Green -> Yellow
    Yellow -> Red

# define some class level constants
Red.carsCanGo = False
Yellow.carsCanGo = True
Green.carsCanGo = True

Red.delay = wait(20)
Yellow.delay = wait(3)
Green.delay = wait(15)

and the DSL compiler would create all the necessary TrafficLight, Red, Yellow, and Green classes, and the proper state transition methods. Code could call these classes using something like this:

import statemachine
import trafficLight

tl = trafficLight.Red()
for i in range(6):
    print tl, "GO" if tl.carsCanGo else "STOP"
    tl = tl.next_state()

(Unfortunately, imputil has been dropped in Python 3.)

share|improve this answer
+1: interesting nonetheless... thanks! –  jldupont Jan 20 '10 at 19:15
Matt Anderson submitted this version of my statemachine code to the pyparsing wiki (pyparsing.wikispaces.com/message/view/Publications/18439845) which is compatible with Py2.7 and up. –  Paul McGuire Jan 20 '10 at 19:22

There is this design pattern for using decorators to implement state machines. From the description on the page:

Decorators are used to specify which methods are the event handlers for the class.

There is example code on the page as well (it is quite long so I won't paste it here).

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+1 for the useful link. –  jldupont Jan 20 '10 at 14:54
Great mention. Always wondered how I would implement exactly that! –  erikb85 Sep 3 '13 at 16:05

I think S. Lott's answer is a much better way to implement a state machine, but if you still want to continue with your approach, using (state,event) as the key for your dict is better. Modifying your code:

class HandlerFsm(object):

  _fsm = {
    ("state_a","event"): "next_state",
share|improve this answer
+1: thanks, I was contemplating this possibility too. I haven't settled on an implementation just yet. –  jldupont Jan 20 '10 at 14:58

It probably depends on how complex your state machine is. For simple state machines, a dict of dicts (of event-keys to state-keys for DFAs, or event-keys to lists/sets/tuples of state-keys for NFAs) will probably be the simplest thing to write and understand.

For more complex state machines, I've heard good things about SMC, which can compile declarative state machine descriptions to code in a wide variety of languages, including Python.

share|improve this answer
+1 for this interesting link. –  neuro Sep 11 '12 at 8:06

I think that the tool PySCXML needs a closer look too. This project uses the W3C definition: State Chart XML (SCXML): State Machine Notation for Control Abstraction

SCXML provides a generic state-machine based execution environment based on CCXML and Harel State Tables

Currently, SCXML is a working draft; but chances are quite high that it is getting a W3C recommendation soon (It is the 9th draft).

Another interesting point to highlight is that there is an Apache Commons project aimed at creating and maintaining a Java SCXML engine capable of executing a state machine defined using a SCXML document, while abstracting out the environment interfaces... And for certain other tools supporting this technology will emerge in future when SCXML is leaving it's draft-status...

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I wouldn't think to reach for a finite state machine for handling XML. The usual way to do this, I think, is to use a stack:

class TrackInfoHandler(object):
    def __init__(self):

    ## ================================== Event callbacks

    def startElement(self, name, attrs):
        cls = self.elementClasses[name]

    def characters(self, ch):

    def endElement(self, name):
        e = self._stack.pop()
        if self._stack:

For each kind of element, you just need a class that supports the addCharacters, addElement, and close methods.

EDIT: To clarify, yes I do mean to argue that finite state machines are usually the wrong answer, that as a general-purpose programming technique they're rubbish and you should stay away.

There are a few really well-understood, cleanly-delineated problems for which FSMs are a nice solution. lex, for example, is good stuff.

That said, FSMs typically don't cope well with change. Suppose someday you want to add a bit of state, perhaps a "have we seen element X yet?" flag. In the code above, you add a boolean attribute to the appropriate element class and you're done. In a finite state machine, you double the number of states and transitions.

Problems that require finite state at first very often evolve to require even more state, like maybe a number, at which point either your FSM scheme is toast, or worse, you evolve it into some kind of generalized state machine, and at that point you're really in trouble. The further you go, the more your rules start to act like code—but code in a slow interpreted language you invented that nobody else knows, for which there's no debugger and no tools.

share|improve this answer
@Jason: as far as I am concerned, any (but the trivial) piece of software acts as a "state-machine" in some form or another. The statement that an FSM is of limited use falls in bottomless pit on my territory. Of course, if you are referring to a particular FSM pattern, that might be the case but I tend to be flexible when it comes to applying patterns. –  jldupont Jan 20 '10 at 16:35
Just about any algorithm can be implemented as a state machine. Very few of them should be. –  Robert Rossney Jan 20 '10 at 17:23
@jldupont: The ranty part of my answer refers to a specific technique where you actually design part of your program as a finite state machine in the ordinary sense of the term, states and transitions are explicit in the code, and some logic is encoded in a state transition table. Like your example and all the other answers. :) –  Jason Orendorff Jan 20 '10 at 18:21

The following code is a really simple solution. The only interesting part is:

   def next_state(self,cls):
      self.__class__ = cls

All the logic for each state is contained in a separate class. The 'state' is changed by replacing the '__class__' of the running instance.

#!/usr/bin/env python

class State(object):
   call = 0 # shared state variable
   def next_state(self,cls):
      print '-> %s' % (cls.__name__,),
      self.__class__ = cls

   def show_state(self,i):
      print '%2d:%2d:%s' % (self.call,i,self.__class__.__name__),

class State1(State):
   __call = 0  # state variable
   def __call__(self,ok):
      self.call += 1
      self.__call += 1
      # transition
      if ok: self.next_state(State2)
      print '' # force new line

class State2(State):
   __call = 0
   def __call__(self,ok):
      self.call += 1
      self.__call += 1
      # transition
      if ok: self.next_state(State3)
      else: self.next_state(State1)
      print '' # force new line

class State3(State):
   __call = 0
   def __call__(self,ok):
      self.call += 1
      self.__call += 1
      # transition
      if not ok: self.next_state(State2)
      print '' # force new line

if __name__ == '__main__':
   sm = State1()
   for v in [1,1,1,0,0,0,1,1,0,1,1,0,0,1,0,0,1,0,0]:
   print '---------'
   print vars(sm


 0: 0:State1 -> State2 
 1: 0:State2 -> State3 
 2: 0:State3 
 3: 1:State3 -> State2 
 4: 1:State2 -> State1 
 5: 1:State1 
 6: 2:State1 -> State2 
 7: 2:State2 -> State3 
 8: 2:State3 -> State2 
 9: 3:State2 -> State3 
10: 3:State3 
11: 4:State3 -> State2 
12: 4:State2 -> State1 
13: 3:State1 -> State2 
14: 5:State2 -> State1 
15: 4:State1 
16: 5:State1 -> State2 
17: 6:State2 -> State1 
18: 6:State1 
{'_State1__call': 7, 'call': 19, '_State3__call': 5, '_State2__call': 7}
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I've written a few python state machines using this design, and I have to say I think it's the cleanest one out of all the options here. It doesn't require a external library, the internal mechanics are quite simple and concise, and it works very well. –  Fake Name Aug 16 at 2:03

Check this and this.

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Another related projects:



You can paint state-machine and than use it in your code.

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I also was not happy with the current options for state_machines so I wrote the state_machine library

you can install it by pip install state_machine and use it like so:

class Person():
    name = 'Billy'

    sleeping = State(initial=True)
    running = State()
    cleaning = State()

    run = Event(from_states=sleeping, to_state=running)
    cleanup = Event(from_states=running, to_state=cleaning)
    sleep = Event(from_states=(running, cleaning), to_state=sleeping)

    def do_one_thing(self):
        print "{} is sleepy".format(self.name)

    def do_another_thing(self):
        print "{} is REALLY sleepy".format(self.name)

    def snore(self):
        print "Zzzzzzzzzzzz"

    def big_snore(self):
        print "Zzzzzzzzzzzzzzzzzzzzzz"

person = Person()
print person.current_state == person.sleeping       # True
print person.is_sleeping                            # True
print person.is_running                             # False
print person.is_running                             # True

# Billy is sleepy
# Billy is REALLY sleepy
# Zzzzzzzzzzzz
# Zzzzzzzzzzzzzzzzzzzzzz

print person.is_sleeping                            # True
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