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fsm.py
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fsm.py
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import logging,os
from enum import Enum
import graphviz as gv
## @brief generic hierarchial state machine class.
#
# states can have substates. If the machine is in a state, then it is also implicitly in that state's parent state
# this basically provides for polymorphism/subclassing of state machines
#
# There are three methods corresponding to each state:
# * on_enter_STATE
# * execute_STATE
# * on_exit_STATE
#
# Subclasses of StateMachine can optionally implement them and they will automatically be called at the appropriate times.
class StateMachine(object):
def __init__(self, start_state):
#print "fsm"
# stores all states in the form _state_hierarchy[state] = parent_state
self._state_hierarchy = {}
self._transitions = {}
self._start_state = start_state
self._state = None
@property
def start_state(self):
return self._start_state
## Resets the FSM back into the start state
def restart(self):
self.transition(self.start_state)
## Registers a new state (which can optionally be a substate of an existing state)
def add_state(self, state, parent_state=None):
if not isinstance(state, Enum):
raise TypeError("State should be an Enum type")
self._state_hierarchy[state] = parent_state
## Runs the FSM
# checks transition conditions for all edges leading away from the current state
# if one evaluates to true, we transition to it
# if more than one evaluates to true, we throw a RuntimeError
def spin(self):
s1 = self.state
print "current State : "+str(self.state)
# call execute_STATENAME
if self.state is not None:
for state in self.ancestors_of_state(self.state) + [self.state]:
method_name = "execute_" + state.name
print method_name
state_method = None
try:
state_method = getattr(self, method_name)
# print("calling " + str(state_method))
except AttributeError:
pass
if state_method is not None:
drive_mhd = state.name
state_method()
if self.state is None:
self.transition(self.start_state)
else:
# transition if an 'event' fires
next_states = []
if self.state in self._transitions:
for next_state, transition in self._transitions[self.state].items():
if transition['condition']():
next_states += [next_state]
if len(next_states) > 1:
logging.warn(
"Ambiguous fsm transitions from state'" + str(self.state) +
"'. The following states are reachable now: " + str(
next_states) +
"; Proceeding by taking the first option.")
if len(next_states) > 0:
self.transition(next_states[0])
# if a transition occurred during the spin, we'll spin again
# note: this could potentially cause infinite recursion (although it shouldn't)
print "inside fsm from "+str(s1)+' to '+str(self.state)
# if :
if s1 != self.state :
StateMachine.spin(self)
# if you add a transition that already exists, the old one will be overwritten
def add_transition(self, from_state, to_state, condition, event_name):
if from_state not in self._transitions:
self._transitions[from_state] = {}
self._transitions[from_state][to_state] = {'condition' : condition,
'name' : event_name}
# sets @state to the new_state given
# calls 'on_exit_STATENAME()' if it exists
# calls 'on_enter_STATENAME()' if it exists
def transition(self, new_state):
# print("TRANSITION: " + str(self.__class__.__name__) + ": " + str(self.state) + " -> " + str(new_state))
if self.state is not None:
for state in self.ancestors_of_state(self.state) + [self.state]:
if not self.state_is_substate(new_state, state):
method_name = "on_exit_" + state.name
print method_name
state_method = None
try:
state_method = getattr(self, method_name) # call the transition FROM method if it exists
except AttributeError:
pass
if state_method is not None:
state_method()
for state in self.ancestors_of_state(new_state) + [new_state]:
if not self.state_is_substate(self.state, state):
method_name = "on_enter_" + state.name
print method_name
state_method = None
try:
state_method = getattr(self, method_name) # call the transition TO method if it exists
except AttributeError:
pass
if state_method is not None:
state_method()
self._state = new_state
# traverses the state hierarchy to see if it's in @state or one of @state's descendent states
def is_in_state(self, state):
return self.state_is_substate(self.state, state)
def state_is_substate(self, state, possible_parent):
ancestor = state
while ancestor is not None:
if possible_parent == ancestor:
return True
ancestor = self._state_hierarchy[ancestor]
return False
# looks at the list @ancestors and returns the one that the current state is a descendant of
# returns None if the current state doesn't descend from one in the list
def corresponding_ancestor_state(self, ancestors):
state = self.state
while state is not None:
if state in ancestors:
return state
state = self._state_hierarchy[state]
return None
# returns a list of the ancestors of the given state
# if B is a child state of A and C is a child state of B, ancestors_of_state(C) == [A, B]
# if @state has no ancestors, returns an empty list
def ancestors_of_state(self, state):
ancestors = []
state = self._state_hierarchy[state]
while state is not None:
ancestors.insert(0, state)
state = self._state_hierarchy[state]
return ancestors
# returns a graphviz.Digraph object
def as_graphviz(self):
g = gv.Digraph(self.__class__.__name__, format='png')
cluster_index = 0
subgraphs = {}
subgraphs[None] = g
for state in self._state_hierarchy:
if state not in subgraphs and state in self._state_hierarchy.values(
):
sg = gv.Digraph(
'cluster_' + str(cluster_index),
graph_attr={'label': state.__module__ + "::" + state.name,
'style': 'dotted'})
cluster_index += 1
subgraphs[state] = sg
for state in self._state_hierarchy:
has_children = state in self._state_hierarchy.values()
if not has_children:
enclosing_graph = subgraphs[self._state_hierarchy[state]]
shape = 'diamond' if state == self.start_state else 'ellipse'
enclosing_graph.node(
state.name,
label=state.__module__ + "::" + state.name,
shape=shape)
for state, subgraph in subgraphs.items():
if state is not None:
subgraphs[self._state_hierarchy[state]].subgraph(subgraph)
for start in self._transitions:
for end, event in self._transitions[start].items():
g.edge(start.name,
end.name,
label=event['name'],
decorate='True')
return g
# writes a png file of the graphviz output to the specified location
def write_diagram_png(self):
g = self.as_graphviz()
if not os.path.exists(os.getcwd() + '/Digraph/'):
os.mkdir(os.getcwd() + '/Digraph/')
g.render(os.getcwd() + '/Digraph/' + self.__class__.__name__, cleanup=True)
@property
def state(self):
return self._state