from aimacode.planning import Action from aimacode.search import Problem from aimacode.utils import expr from lp_utils import decode_state class PgNode(): """Base class for planning graph nodes. includes instance sets common to both types of nodes used in a planning graph parents: the set of nodes in the previous level children: the set of nodes in the subsequent level mutex: the set of sibling nodes that are mutually exclusive with this node """ def __init__(self): self.parents = set() self.children = set() self.mutex = set() def is_mutex(self, other) -> bool: """Boolean test for mutual exclusion :param other: PgNode the other node to compare with :return: bool True if this node and the other are marked mutually exclusive (mutex) """ if other in self.mutex: return True return False def show(self): """helper print for debugging shows counts of parents, children, siblings :return: print only """ print("{} parents".format(len(self.parents))) print("{} children".format(len(self.children))) print("{} mutex".format(len(self.mutex))) class PgNode_s(PgNode): """A planning graph node representing a state (literal fluent) from a planning problem. Args: symbol : str A string representing a literal expression from a planning problem domain. is_pos : bool Boolean flag indicating whether the literal expression is positive or negative. """ def __init__(self, symbol: str, is_pos: bool): """S-level Planning Graph node constructor. :param symbol: expr :param is_pos: bool Instance variables calculated: literal: expr fluent in its literal form including negative operator if applicable Instance variables inherited from PgNode: parents: set of nodes connected to this node in previous A level; children: set of nodes connected to this node in next A level; mutex: set of sibling S-nodes that this node has mutual exclusion with; """ PgNode.__init__(self) self.symbol = symbol self.is_pos = is_pos self.literal = expr(self.symbol) if not self.is_pos: self.literal = expr('~{}'.format(self.symbol)) def show(self): """Helper print for debugging shows literal plus counts of parents, children, siblings. :return: print only """ print("\n*** {}".format(self.literal)) PgNode.show(self) def __eq__(self, other): '''equality test for nodes - compares only the literal for equality :param other: PgNode_s :return: bool ''' if isinstance(other, self.__class__): return (self.symbol == other.symbol) \ and (self.is_pos == other.is_pos) def __hash__(self): return hash(self.symbol) ^ hash(self.is_pos) class PgNode_a(PgNode): """A-type (action) Planning Graph node - inherited from PgNode """ def __init__(self, action: Action): """A-level Planning Graph node constructor :param action: Action a ground action, i.e. this action cannot contain any variables Instance variables calculated: An A-level will always have an S-level as its parent and an S-level as its child. The preconditions and effects will become the parents and children of the A-level node. However, when this node is created, it is not yet connected to the graph. prenodes: set of *possible* parent S-nodes effnodes: set of *possible* child S-nodes is_persistent: bool True if this is a persistence action, i.e. a no-op action Instance variables inherited from PgNode: parents: set of nodes connected to this node in previous A level; children: set of nodes connected to this node in next A level; mutex: set of sibling S-nodes that this node has mutual exclusion with; """ PgNode.__init__(self) self.action = action self.prenodes = self.precond_s_nodes() self.effnodes = self.effect_s_nodes() self.is_persistent = False if self.prenodes == self.effnodes: self.is_persistent = True def show(self): """helper print for debugging shows action plus counts of parents, children, siblings. :return: print only """ print("\n*** {}{}".format(self.action.name, self.action.args)) PgNode.show(self) def precond_s_nodes(self): """precondition literals as S-nodes (represents possible parents for this node). It is computationally expensive to call this function; it is only called by the class constructor to populate the `prenodes` attribute. :return: set of PgNode_s """ nodes = set() for p in self.action.precond_pos: n = PgNode_s(p, True) nodes.add(n) for p in self.action.precond_neg: n = PgNode_s(p, False) nodes.add(n) return nodes def effect_s_nodes(self): """effect literals as S-nodes (represents possible children for this node). It is computationally expensive to call this function; it is only called by the class constructor to populate the `effnodes` attribute. :return: set of PgNode_s """ nodes = set() for e in self.action.effect_add: n = PgNode_s(e, True) nodes.add(n) for e in self.action.effect_rem: n = PgNode_s(e, False) nodes.add(n) return nodes def __eq__(self, other): """equality test for nodes - compares only the action name for equality :param other: PgNode_a :return: bool """ if isinstance(other, self.__class__): return (self.action.name == other.action.name) \ and (self.action.args == other.action.args) def __hash__(self): return hash(self.action.name) ^ hash(self.action.args) def mutexify(node1: PgNode, node2: PgNode): """Adds sibling nodes to each other's mutual exclusion (mutex) set. These should be sibling nodes! :param node1: PgNode (or inherited PgNode_a, PgNode_s types) :param node2: PgNode (or inherited PgNode_a, PgNode_s types) :return: node mutex sets modified """ if type(node1) != type(node2): raise TypeError('Attempted to mutex two nodes of different types') node1.mutex.add(node2) node2.mutex.add(node1) class PlanningGraph(): """ A planning graph as described in chapter 10 of the AIMA text. The planning graph can be used to reason about """ def __init__(self, problem: Problem, state: str, serial_planning=True): """ :param problem: PlanningProblem (or subclass such as AirCargoProblem or HaveCakeProblem) :param state: str (will be in form TFTTFF... representing fluent states) :param serial_planning: bool (whether or not to assume that only one action can occur at a time) Instance variable calculated: fs: FluentState the state represented as positive and negative fluent literal lists all_actions: list of the PlanningProblem valid ground actions combined with calculated no-op actions s_levels: list of sets of PgNode_s, where each set in the list represents an S-level in the planning graph. a_levels: list of sets of PgNode_a, where each set in the list represents an A-level in the planning graph. """ self.problem = problem self.fs = decode_state(state, problem.state_map) self.serial = serial_planning self.all_actions = self.problem.actions_list + \ self.noop_actions(self.problem.state_map) self.s_levels = [] self.a_levels = [] self.create_graph() def noop_actions(self, literal_list): """create persistent action for each possible fluent "No-Op" actions are virtual actions (i.e., actions that only exist in the planning graph, not in the planning problem domain) that operate on each fluent (literal expression) from the problem domain. No op actions "pass through" the literal expressions from one level of the planning graph to the next. The no-op action list requires both a positive and a negative action for each literal expression. Positive no-op actions require the literal as a positive precondition and add the literal expression as an effect in the output, and negative no-op actions require the literal as a negative precondition and remove the literal expression as an effect in the output. This function should only be called by the class constructor. :param literal_list: :return: list of Action """ action_list = [] for fluent in literal_list: act1 = Action(expr("Noop_pos({})".format(fluent)),\ ([fluent], []), ([fluent], [])) action_list.append(act1) act2 = Action(expr("Noop_neg({})".format(fluent)),\ ([], [fluent]), ([], [fluent])) action_list.append(act2) return action_list def create_graph(self): """Build a Planning Graph as described in Russell-Norvig 3rd Ed 10.3 or 2nd Ed 11.4 The S0 initial level has been implemented for you. It has no parents and includes all of the literal fluents that are part of the initial state passed to the constructor. At the start of a problem planning search, this will be the same as the initial state of the problem. However, the planning graph can be built from any state in the Planning Problem. This function should only be called by the class constructor. :return: builds the graph by filling s_levels[] and a_levels[] lists with node sets for each level. """ # the graph should only be built during class construction if (len(self.s_levels) != 0) or (len(self.a_levels) != 0): raise Exception( 'Planning Graph already created;\ construct a new planning graph for each new state in the\ planning sequence') # initialize S0 to literals in initial state provided. leveled = False level = 0 self.s_levels.append(set()) # S0 set of s_nodes - empty to start # for each fluent in the initial state, add the correct literal PgNode_s for literal in self.fs.pos: self.s_levels[level].add(PgNode_s(literal, True)) for literal in self.fs.neg: self.s_levels[level].add(PgNode_s(literal, False)) # no mutexes at the first level # continue to build the graph alternating A, # S levels until last two S levels contain the same literals, # i.e. until it is "leveled" while not leveled: self.add_action_level(level) self.update_a_mutex(self.a_levels[level]) level += 1 self.add_literal_level(level) self.update_s_mutex(self.s_levels[level]) if self.s_levels[level] == self.s_levels[level - 1]: leveled = True def add_action_level(self, level): """ add an A (action) level to the Planning Graph :param level: int the level number alternates S0, A0, S1, A1, S2, ...etc. the level number is also used as the index for the node set lists self.a_levels[] and self.s_levels[] :return: adds A nodes to the current level in self.a_levels[level] """ previous_s_level = self.s_levels[level] # Previous state level (previous to this level of actions) actions = self.all_actions # List of all possible actions self.a_levels.append(set()) # Initialize this level of actions for action in actions: a_node = PgNode_a(action) if a_node.prenodes.issubset(previous_s_level): for s_node in previous_s_level: # Connect action level to state and vice-versa s_node.children.add(a_node) a_node.parents.add(s_node) # Add newly created action to this new level of actions self.a_levels[level].add(a_node) def add_literal_level(self, level): """ add an S (literal) level to the Planning Graph :param level: int the level number alternates S0, A0, S1, A1, S2, ....etc. the level number is also used as the index for the node set lists self.a_levels[] and self.s_levels[] :return: adds S nodes to the current level in self.s_levels[level] """ previous_a_level = self.a_levels[level - 1] #Previous action level (previous to this level of states) self.s_levels.append(set()) # Initialize this level of states for a_node in previous_a_level: for effect_node in a_node.effnodes: # Connect state level to action and vice-versa a_node.children.add(effect_node) effect_node.parents.add(a_node) # Add newly state to this new level of states self.s_levels[level].add(effect_node) def update_a_mutex(self, nodeset): """ Determine and update sibling mutual exclusion for A-level nodes Mutex action tests section from 3rd Ed. 10.3 or 2nd Ed. 11.4 A mutex relation holds between two actions a given level if the planning graph is a serial planning graph and the pair are nonpersistence actions or if any of the three conditions hold between the pair: Inconsistent Effects Interference Competing needs :param nodeset: set of PgNode_a (siblings in the same level) :return: mutex set in each PgNode_a in the set is appropriately updated """ nodelist = list(nodeset) for i, n1 in enumerate(nodelist[:-1]): for n2 in nodelist[i + 1:]: if (self.serialize_actions(n1, n2) or self.inconsistent_effects_mutex(n1, n2) or self.interference_mutex(n1, n2) or self.competing_needs_mutex(n1, n2)): mutexify(n1, n2) def serialize_actions(self, node_a1: PgNode_a, node_a2: PgNode_a) -> bool: ''' Test a pair of actions for mutual exclusion, returning True if the planning graph is serial, and if either action is persistent; otherwise return False. Two serial actions are mutually exclusive if they are both non-persistent. :param node_a1: PgNode_a :param node_a2: PgNode_a :return: bool ''' # if not self.serial: return False if node_a1.is_persistent or node_a2.is_persistent: return False return True def inconsistent_effects_mutex(self, node_a1: PgNode_a,\ node_a2: PgNode_a) -> bool: ''' Test a pair of actions for inconsistent effects, returning True if one action negates an effect of the other, and False otherwise. :param node_a1: PgNode_a :param node_a2: PgNode_a :return: bool ''' return bool( # Are actions from node 1 negated by actions in node 2? set(node_a1.action.effect_add) & set(node_a2.action.effect_rem) | # Are actions from node 2 negated by actions in node 1? set(node_a2.action.effect_add) & set(node_a1.action.effect_rem) ) def interference_mutex(self, node_a1: PgNode_a, node_a2: PgNode_a) -> bool: ''' Test a pair of actions for mutual exclusion, returning True if the effect of one action is the negation of a precondition of the other. :param node_a1: PgNode_a :param node_a2: PgNode_a :return: bool ''' return bool( # Are actions in node 1 the negation of a precondition of node 2? set(node_a1.action.effect_add) & set(node_a2.action.precond_neg) | set(node_a1.action.effect_rem) & set(node_a2.action.precond_pos) | # Are actions in node 2 the negation of a precondition of node 1? set(node_a2.action.effect_add) & set(node_a1.action.precond_neg) | set(node_a2.action.effect_rem) & set(node_a1.action.precond_pos) ) def competing_needs_mutex(self, node_a1: PgNode_a,\ node_a2: PgNode_a) -> bool: ''' Test a pair of actions for mutual exclusion, returning True if one of the precondition of one action is mutex with a precondition of the other action. :param node_a1: PgNode_a :param node_a2: PgNode_a :return: bool ''' for a1_parent in node_a1.parents: for a2_parent in node_a2.parents: if a1_parent.is_mutex(a2_parent): return True return False def update_s_mutex(self, nodeset: set): ''' Determine and update sibling mutual exclusion for S-level nodes Mutex action tests section from 3rd Ed. 10.3 or 2nd Ed. 11.4 A mutex relation holds between literals at a given level if either of the two conditions hold between the pair: Negation Inconsistent support :param nodeset: set of PgNode_a (siblings in the same level) :return: mutex set in each PgNode_a in the set is appropriately updated ''' nodelist = list(nodeset) for i, n1 in enumerate(nodelist[:-1]): for n2 in nodelist[i + 1:]: if self.negation_mutex(n1, n2) or\ self.inconsistent_support_mutex(n1, n2): mutexify(n1, n2) def negation_mutex(self, node_s1: PgNode_s, node_s2: PgNode_s) -> bool: ''' Test a pair of state literals for mutual exclusion, returning True if one node is the negation of the other, and False otherwise. :param node_s1: PgNode_s :param node_s2: PgNode_s :return: bool ''' # Verify both state represent the same symbol is_same_symbol = node_s1.symbol == node_s2.symbol # Verify 1 state is the negation of the other is_negation = node_s1.is_pos != node_s2.is_pos return is_same_symbol and is_negation def inconsistent_support_mutex(self, node_s1: PgNode_s, node_s2: PgNode_s): ''' Test a pair of state literals for mutual exclusion, returning True if there are no actions that could achieve the two literals at the same time, and False otherwise. In other words, the two literal nodes are mutex if all of the actions that could achieve the first literal node are pairwise mutually exclusive with all of the actions that could achieve the second literal node. :param node_s1: PgNode_s :param node_s2: PgNode_s :return: bool ''' for s1_parent in node_s1.parents: for s2_parent in node_s2.parents: if not s1_parent.is_mutex(s2_parent): return False return True def h_levelsum(self) -> int: '''The sum of the level costs of the individual goals (admissible if goals independent) :return: int ''' level_sum = 0 goals = self.problem.goal s_levels = self.s_levels for goal in goals: node = PgNode_s(goal, True) s_levels_list = enumerate(s_levels) for level, s_nodes in s_levels_list: if node in s_nodes: level_sum += level break return level_sum