def to_formula(self, node, parameter_map=None):
"""
Return a formula out of this PDDL_Tree node.
For now, will assume this makes sense.
"""
# forall is so weird that we can treat it as an entirely seperate entity
if "forall" == node.name:
# treat args differently in this case
assert len(node.children) in[2, 4],\
"Forall must have a variable(typed or untyped) and formula that it quantifies"
i = len(node.children) - 1
if len(node.children) == 2 and len(node.children[0].children) > 0:
# adjust this node by changing the structure of the first child
new_child = PDDL_Tree(PDDL_Tree.EMPTY)
new_child.add_child(PDDL_Tree(node.children[0].name))
for c in node.children[0].children:
new_child.add_child(c)
node.children[0] = new_child
l = PDDL_Utils.read_type(new_child)
for v, t in l:
parameter_map[v] = t
args = [self.to_formula(c, parameter_map) for c in node.children[i:]]
for v, t in l:
del(parameter_map[v])
return Forall(l, args)
i = 0
args = [self.to_formula(c, parameter_map) for c in node.children[i:]]
if "and" == node.name:
return And(args)
elif "or" == node.name:
return Or(args)
elif "oneof" == node.name:
return Oneof(args)
elif "not" == node.name:
return Not(args)
elif "xor" == node.name:
return Xor(args)
elif "nondet" == node.name:
assert len(node.children) == 1,\
"nondet must only have a single child as a predicate"
# make p != p2, otherwise might run into issues with mutation in some later step
return Oneof([args[0], Not(args)])
elif "unknown" == node.name:
assert len(node.children) == 1,\
"unknown must only have a single child as a predicate"
# make p != p2, otherwise might run into issues with mutation in some later step
p = Primitive(self.to_predicate(node.children[0], map=parameter_map))
p2 = Primitive(self.to_predicate(node.children[0], map=parameter_map))
return Xor([p, Not([p2])])
elif "when" == node.name:
assert len(args) == 2,\
"When clause must have exactly 2 children"
return When(args[0], args[1])
else:
# it's a predicate
return Primitive(self.to_predicate(node, map=parameter_map))
def to_formula(self, node, parameter_map=None):
"""
Return a formula out of this PDDL_Tree node.
For now, will assume this makes sense.
"""
# forall is so weird that we can treat it as an entirely seperate entity
if "forall" == node.name:
# treat args differently in this case
assert len(node.children) in[2, 4],\
"Forall must have a variable(typed or untyped) and formula that it quantifies"
i = len(node.children) - 1
if len(node.children) == 2 and len(node.children[0].children) > 0:
# adjust this node by changing the structure of the first child
new_child = PDDL_Tree(PDDL_Tree.EMPTY)
new_child.add_child(PDDL_Tree(node.children[0].name))
for c in node.children[0].children:
new_child.add_child(c)
node.children[0] = new_child
l = PDDL_Utils.read_type(new_child)
for v, t in l:
parameter_map[v] = t
args = [
self.to_formula(c, parameter_map) for c in node.children[i:]
]
for v, t in l:
del (parameter_map[v])
return Forall(l, args)
i = 0
args = [self.to_formula(c, parameter_map) for c in node.children[i:]]
if "and" == node.name:
return And(args)
elif "or" == node.name:
return Or(args)
elif "oneof" == node.name:
return Oneof(args)
elif "not" == node.name:
return Not(args)
elif "xor" == node.name:
return Xor(args)
elif "nondet" == node.name:
assert len(node.children) == 1,\
"nondet must only have a single child as a predicate"
# make p != p2, otherwise might run into issues with mutation in some later step
return Oneof([args[0], Not(args)])
elif "unknown" == node.name:
assert len(node.children) == 1,\
"unknown must only have a single child as a predicate"
# make p != p2, otherwise might run into issues with mutation in some later step
p = Primitive(
self.to_predicate(node.children[0], map=parameter_map))
p2 = Primitive(
self.to_predicate(node.children[0], map=parameter_map))
return Xor([p, Not([p2])])
elif "when" == node.name:
assert len(args) == 2,\
"When clause must have exactly 2 children"
return When(args[0], args[1])
else:
# it's a predicate
return Primitive(self.to_predicate(node, map=parameter_map))
def to_formula(self, node, parameter_map=None):
"""
Return a formula out of this PDDL_Tree node.
For now, will assume this makes sense.
"""
# forall is so weird that we can treat it as an entirely seperate entity
if "forall" == node.name:
# treat args differently in this case
assert len(node.children) in[2, 4],\
"Forall must have a variable(typed or untyped) and formula that it quantifies"
i = len(node.children) - 1
if len(node.children) == 2 and len(node.children[0].children) > 0:
# adjust this node by changing the structure of the first child
new_child = PDDL_Tree(PDDL_Tree.EMPTY)
new_child.add_child(PDDL_Tree(node.children[0].name))
for c in node.children[0].children:
new_child.add_child(c)
node.children[0] = new_child
l = PDDL_Utils.read_type(new_child)
else:
l = [(node.children[0].name, node.children[2].name)]
for v, t in l:
parameter_map[v] = t
args = [
self.to_formula(c, parameter_map) for c in node.children[i:]
]
for v, t in l:
del (parameter_map[v])
return Forall(l, args)
i = 0
args = [self.to_formula(c, parameter_map) for c in node.children[i:]]
def handle_modality(node, pref_len, modality):
assert 1 <= len(
node.children) <= 2, "Error: Found %d children." % len(
node.children)
#print "%s / %s / %s" % (str(node), str(pref_len), str(modality))
ag = node.name[pref_len:-1]
if len(node.children) == 1:
pred = self.to_formula(node.children[0], parameter_map)
else:
pred = self.to_formula(node.children[1], parameter_map)
pred.negated_rml = True
assert not isinstance(
pred, Not
), "Error: Cannot nest lack of belief with (not ...): %s" % pred.dump(
)
assert isinstance(
pred, Primitive
), "Error: Type should have been Primitive, but was %s" % str(
type(pred))
pred.agent_list = "%s%s %s" % (modality, ag, pred.agent_list)
return pred
if "and" == node.name:
return And(args)
elif "or" == node.name:
return Or(args)
elif "oneof" == node.name:
return Oneof(args)
elif "not" == node.name:
return Not(args)
elif "xor" == node.name:
return Xor(args)
elif "nondet" == node.name:
assert len(node.children) == 1,\
"nondet must only have a single child as a predicate"
# make p != p2, otherwise might run into issues with mutation in some later step
return Oneof([args[0], Not(args)])
elif "unknown" == node.name:
assert len(node.children) == 1,\
"unknown must only have a single child as a predicate"
# make p != p2, otherwise might run into issues with mutation in some later step
p = Primitive(
self.to_predicate(node.children[0], map=parameter_map))
p2 = Primitive(
self.to_predicate(node.children[0], map=parameter_map))
return Xor([p, Not([p2])])
elif "when" == node.name:
assert len(args) == 2,\
"When clause must have exactly 2 children"
return When(args[0], args[1])
elif "P{" == node.name[:2]:
return handle_modality(node, 2, 'P')
elif "!P{" == node.name[:3]:
return handle_modality(node, 3, '!P')
elif "B{" == node.name[:2]:
return handle_modality(node, 2, 'B')
elif "!B{" == node.name[:3]:
return handle_modality(node, 3, '!B')
elif "!" == node.name[0]:
node.name = node.name[1:]
pred = Primitive(self.to_predicate(node, map=parameter_map))
pred.negated_rml = True
return pred
else:
# it's a predicate
return Primitive(self.to_predicate(node, map=parameter_map))
