Python finite-state machines made easy.
Welcome to python-statemachine, an intuitive and powerful state machine library designed for a great developer experience. We provide a pythonic and expressive API for implementing state machines in sync or asynchonous Python codebases.
- β¨ Basic components: Easily define States, Events, and Transitions to model your logic.
- βοΈ Actions and handlers: Attach actions and handlers to states, events, and transitions to control behavior dynamically.
- π‘οΈ Conditional transitions: Implement Guards and Validators to conditionally control transitions, ensuring they only occur when specific conditions are met.
- π Full async support: Enjoy full asynchronous support. Await events, and dispatch callbacks asynchronously for seamless integration with async codebases.
- π Full sync support: Use the same state machine from synchronous codebases without any modifications.
- π¨ Declarative and simple API: Utilize a clean, elegant, and readable API to define your state machine, making it easy to maintain and understand.
- π Observer pattern support: Register external and generic objects to watch events and register callbacks.
- π Decoupled design: Separate concerns with a decoupled "state machine" and "model" design, promoting cleaner architecture and easier maintenance.
- β
Correctness guarantees: Ensured correctness with validations at class definition time:
- Ensures exactly one
initial
state. - Disallows transitions from
final
states. - Requires ongoing transitions for all non-final states.
- Guarantees all non-final states have at least one path to a final state if final states are declared.
- Validates the state machine graph representation has a single component.
- Ensures exactly one
- π¦ Flexible event dispatching: Dispatch events with any extra data, making it available to all callbacks, including actions and guards.
- π§ Dependency injection: Needed parameters are injected into callbacks.
- π Graphical representation: Generate and output graphical representations of state machines. Create diagrams from the command line, at runtime, or even in Jupyter notebooks.
- π Internationalization support: Provides error messages in different languages, making the library accessible to a global audience.
- π‘οΈ Robust testing: Ensured reliability with a codebase that is 100% covered by automated tests, including all docs examples. Releases follow semantic versioning for predictable releases.
- ποΈ Domain model integration: Seamlessly integrate with domain models using Mixins.
- π§ Django integration: Automatically discover state machines in Django applications.
To install Python State Machine, run this command in your terminal:
pip install python-statemachine
To generate diagrams from your machines, you'll also need pydot
and Graphviz
. You can
install this library already with pydot
dependency using the extras
install option. See
our docs for more details.
pip install python-statemachine[diagrams]
Define your state machine:
>>> from statemachine import StateMachine, State
>>> class TrafficLightMachine(StateMachine):
... "A traffic light machine"
... green = State(initial=True)
... yellow = State()
... red = State()
...
... cycle = (
... green.to(yellow)
... | yellow.to(red)
... | red.to(green)
... )
...
... def before_cycle(self, event: str, source: State, target: State, message: str = ""):
... message = ". " + message if message else ""
... return f"Running {event} from {source.id} to {target.id}{message}"
...
... def on_enter_red(self):
... print("Don't move.")
...
... def on_exit_red(self):
... print("Go ahead!")
You can now create an instance:
>>> sm = TrafficLightMachine()
This state machine can be represented graphically as follows:
>>> img_path = "docs/images/readme_trafficlightmachine.png"
>>> sm._graph().write_png(img_path)
Where on the TrafficLightMachine
, we've defined green
, yellow
, and red
as states, and
one event called cycle
, which is bound to the transitions from green
to yellow
, yellow
to red
,
and red
to green
. We also have defined three callbacks by name convention, before_cycle
, on_enter_red
, and on_exit_red
.
Then start sending events to your new state machine:
>>> sm.send("cycle")
'Running cycle from green to yellow'
That's it. This is all an external object needs to know about your state machine: How to send events. Ideally, all states, transitions, and actions should be kept internally and not checked externally to avoid unnecessary coupling.
But if your use case needs, you can inspect state machine properties, like the current state:
>>> sm.current_state.id
'yellow'
Or get a complete state representation for debugging purposes:
>>> sm.current_state
State('Yellow', id='yellow', value='yellow', initial=False, final=False)
The State
instance can also be checked by equality:
>>> sm.current_state == TrafficLightMachine.yellow
True
>>> sm.current_state == sm.yellow
True
Or you can check if a state is active at any time:
>>> sm.green.is_active
False
>>> sm.yellow.is_active
True
>>> sm.red.is_active
False
Easily iterate over all states:
>>> [s.id for s in sm.states]
['green', 'red', 'yellow']
Or over events:
>>> [t.name for t in sm.events]
['cycle']
Call an event by its name:
>>> sm.cycle()
Don't move.
'Running cycle from yellow to red'
Or send an event with the event name:
>>> sm.send('cycle')
Go ahead!
'Running cycle from red to green'
>>> sm.green.is_active
True
You can pass arbitrary positional or keyword arguments to the event, and they will be propagated to all actions and callbacks using something similar to dependency injection. In other words, the library will only inject the parameters declared on the callback method.
Note how before_cycle
was declared:
def before_cycle(self, event: str, source: State, target: State, message: str = ""):
message = ". " + message if message else ""
return f"Running {event} from {source.id} to {target.id}{message}"
The params event
, source
, target
(and others) are available built-in to be used on any action.
The param message
is user-defined, in our example we made it default empty so we can call cycle
with
or without a message
parameter.
If we pass a message
parameter, it will be used on the before_cycle
action:
>>> sm.send("cycle", message="Please, now slowdown.")
'Running cycle from green to yellow. Please, now slowdown.'
By default, events with transitions that cannot run from the current state or unknown events
raise a TransitionNotAllowed
exception:
>>> sm.send("go")
Traceback (most recent call last):
statemachine.exceptions.TransitionNotAllowed: Can't go when in Yellow.
Keeping the same state as expected:
>>> sm.yellow.is_active
True
A human-readable name is automatically derived from the State.id
, which is used on the messages
and in diagrams:
>>> sm.current_state.name
'Yellow'
We support native coroutine using asyncio
, enabling seamless integration with asynchronous code.
There's no change on the public API of the library to work on async codebases.
>>> class AsyncStateMachine(StateMachine):
... initial = State('Initial', initial=True)
... final = State('Final', final=True)
...
... advance = initial.to(final)
...
... async def on_advance(self):
... return 42
>>> async def run_sm():
... sm = AsyncStateMachine()
... result = await sm.advance()
... print(f"Result is {result}")
... print(sm.current_state)
>>> asyncio.run(run_sm())
Result is 42
Final
A simple didactic state machine for controlling an Order
:
>>> class OrderControl(StateMachine):
... waiting_for_payment = State(initial=True)
... processing = State()
... shipping = State()
... completed = State(final=True)
...
... add_to_order = waiting_for_payment.to(waiting_for_payment)
... receive_payment = (
... waiting_for_payment.to(processing, cond="payments_enough")
... | waiting_for_payment.to(waiting_for_payment, unless="payments_enough")
... )
... process_order = processing.to(shipping, cond="payment_received")
... ship_order = shipping.to(completed)
...
... def __init__(self):
... self.order_total = 0
... self.payments = []
... self.payment_received = False
... super(OrderControl, self).__init__()
...
... def payments_enough(self, amount):
... return sum(self.payments) + amount >= self.order_total
...
... def before_add_to_order(self, amount):
... self.order_total += amount
... return self.order_total
...
... def before_receive_payment(self, amount):
... self.payments.append(amount)
... return self.payments
...
... def after_receive_payment(self):
... self.payment_received = True
...
... def on_enter_waiting_for_payment(self):
... self.payment_received = False
You can use this machine as follows.
>>> control = OrderControl()
>>> control.add_to_order(3)
3
>>> control.add_to_order(7)
10
>>> control.receive_payment(4)
[4]
>>> control.current_state.id
'waiting_for_payment'
>>> control.current_state.name
'Waiting for payment'
>>> control.process_order()
Traceback (most recent call last):
...
statemachine.exceptions.TransitionNotAllowed: Can't process_order when in Waiting for payment.
>>> control.receive_payment(6)
[4, 6]
>>> control.current_state.id
'processing'
>>> control.process_order()
>>> control.ship_order()
>>> control.payment_received
True
>>> control.order_total
10
>>> control.payments
[4, 6]
>>> control.completed.is_active
True
There's a lot more to cover, please take a look at our docs: https://python-statemachine.readthedocs.io.
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