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example_have_cake.py
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example_have_cake.py
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from aimacode.logic import PropKB
from aimacode.planning import Action
from aimacode.search import (
Node, breadth_first_search, astar_search, depth_first_graph_search,
uniform_cost_search, greedy_best_first_graph_search, Problem,
)
from aimacode.utils import expr
from lp_utils import (
FluentState, encode_state, decode_state
)
from my_planning_graph import PlanningGraph
from run_search import run_search
from functools import lru_cache
class HaveCakeProblem(Problem):
def __init__(self, initial: FluentState, goal: list):
self.state_map = initial.pos + initial.neg
Problem.__init__(self, encode_state(initial, self.state_map), goal=goal)
self.actions_list = self.get_actions()
def get_actions(self):
precond_pos = [expr("Have(Cake)")]
precond_neg = []
effect_add = [expr("Eaten(Cake)")]
effect_rem = [expr("Have(Cake)")]
eat_action = Action(expr("Eat(Cake)"),
[precond_pos, precond_neg],
[effect_add, effect_rem])
precond_pos = []
precond_neg = [expr("Have(Cake)")]
effect_add = [expr("Have(Cake)")]
effect_rem = []
bake_action = Action(expr("Bake(Cake)"),
[precond_pos, precond_neg],
[effect_add, effect_rem])
return [eat_action, bake_action]
def actions(self, state: str) -> list: # of Action
possible_actions = []
kb = PropKB()
kb.tell(decode_state(state, self.state_map).pos_sentence())
for action in self.actions_list:
is_possible = True
for clause in action.precond_pos:
if clause not in kb.clauses:
is_possible = False
for clause in action.precond_neg:
if clause in kb.clauses:
is_possible = False
if is_possible:
possible_actions.append(action)
return possible_actions
def result(self, state: str, action: Action):
new_state = FluentState([], [])
old_state = decode_state(state, self.state_map)
for fluent in old_state.pos:
if fluent not in action.effect_rem:
new_state.pos.append(fluent)
for fluent in action.effect_add:
if fluent not in new_state.pos:
new_state.pos.append(fluent)
for fluent in old_state.neg:
if fluent not in action.effect_add:
new_state.neg.append(fluent)
for fluent in action.effect_rem:
if fluent not in new_state.neg:
new_state.neg.append(fluent)
return encode_state(new_state, self.state_map)
def goal_test(self, state: str) -> bool:
kb = PropKB()
kb.tell(decode_state(state, self.state_map).pos_sentence())
for clause in self.goal:
if clause not in kb.clauses:
return False
return True
def h_1(self, node: Node):
# note that this is not a true heuristic
h_const = 1
return h_const
@lru_cache(maxsize=8192)
def h_pg_levelsum(self, node: Node):
# uses the planning graph level-sum heuristic calculated
# from this node to the goal
# requires implementation in PlanningGraph
pg = PlanningGraph(self, node.state)
pg_levelsum = pg.h_levelsum()
return pg_levelsum
@lru_cache(maxsize=8192)
def h_ignore_preconditions(self, node: Node):
# not implemented
count = 0
return count
def have_cake():
def get_init():
pos = [expr('Have(Cake)'),
]
neg = [expr('Eaten(Cake)'),
]
return FluentState(pos, neg)
def get_goal():
return [expr('Have(Cake)'),
expr('Eaten(Cake)'),
]
return HaveCakeProblem(get_init(), get_goal())
if __name__ == '__main__':
p = have_cake()
print("**** Have Cake example problem setup ****")
print("Initial state for this problem is {}".format(p.initial))
print("Actions for this domain are:")
for a in p.actions_list:
print(' {}{}'.format(a.name, a.args))
print("Fluents in this problem are:")
for f in p.state_map:
print(' {}'.format(f))
print("Goal requirement for this problem are:")
for g in p.goal:
print(' {}'.format(g))
print()
print("*** Breadth First Search")
run_search(p, breadth_first_search)
print("*** Depth First Search")
run_search(p, depth_first_graph_search)
print("*** Uniform Cost Search")
run_search(p, uniform_cost_search)
print("*** Greedy Best First Graph Search - null heuristic")
run_search(p, greedy_best_first_graph_search, parameter=p.h_1)
print("*** A-star null heuristic")
run_search(p, astar_search, p.h_1)
# print("A-star ignore preconditions heuristic")
# rs(p, "astar_search - ignore preconditions heuristic", astar_search, p.h_ignore_preconditions)
# print(""A-star levelsum heuristic)
# rs(p, "astar_search - levelsum heuristic", astar_search, p.h_pg_levelsum)