Exemplo n.º 1
0
    def safeMoves(self, loc=None):
        if loc == None:
            loc = self._pawns['X'].getLocation()
        if loc == -1:
            raise BaseAIProtocolError(
                "Cannot determine safe X moves when X location is unknown")

        dets = ['Red', 'Yellow', 'Green', 'Blue', 'Black']
        detLocs = [self._pawns[d].getLocation() for d in dets]
        # log.msg("DETETIVE LOCATIONS: "+detLocs)
        # f = open("abc.txt", "a")
        # f.write("Now the file has more content!")
        # f.close()
        allMoves = path.possible_destinations(loc,
                                              1,
                                              eliminate=[sets.Set(detLocs)])
        distances = [
            path.distance(self._pawns[d].getLocation(),
                          tickets=self._pawns[d]._tickets) for d in dets
        ]

        def findSafe(threshold):
            safe = allMoves.copy()
            for dest in allMoves:
                for dist in distances:
                    if dist[dest] < threshold:
                        safe.remove(dest)
                        break
            return safe

        return [
            findSafe(threshold) for threshold in range(1, map.MAX_DISTANCE + 1)
        ]
Exemplo n.º 2
0
    def safeMoves(self, loc=None):
        if loc == None:
            loc = self._pawns['X'].getLocation()
        if loc == -1:
            raise BaseAIProtocolError(
                "Cannot determine safe X moves when X location is unknown")

        dets = ['Red', 'Yellow', 'Green', 'Blue', 'Black']
        detLocs = [self._pawns[d].getLocation() for d in dets]
        allMoves = path.possible_destinations(loc,
                                              1,
                                              eliminate=[sets.Set(detLocs)])
        distances = [
            path.distance(self._pawns[d].getLocation(),
                          tickets=self._pawns[d]._tickets) for d in dets
        ]

        def findSafe(threshold):
            safe = allMoves.copy()
            for dest in allMoves:
                for dist in distances:
                    if dist[dest] < threshold:
                        safe.remove(dest)
                        break
            return safe

        return [
            findSafe(threshold) for threshold in range(1, map.MAX_DISTANCE + 1)
        ]
Exemplo n.º 3
0
   def doTurn(self, pawnName):

      # Taxis are best, because they hide position to some degree.
      # Underground is relatively expensive because it tells detectives where
      # you might be.  black is very expensive because supplies are limited.
      def cost(ticket_amounts, ticket):
         if ticket == 'taxi':
            return 1
         elif ticket == 'bus':
            return 1.6
         elif ticket == 'underground':
            return 3
         elif ticket == 'black':
            return 5

      all_paths = path.cheapest_path(self._pawns['X'].getLocation(), 
                                     tickets=self._pawns['X']._tickets,
                                     cost=cost)

      # look at the available moves in order from most safe to least safe
      safe = self.safeMoves()
      safe.reverse()
      bestMove      = None
      bestTransport = None
      bestCost      = 1000000
      for moves in safe:
         moves_list = list(moves)
         random.shuffle(moves_list)
         for move in moves_list:
            p = all_paths[move]
            dest, transport = p[0]
            if cost(self._pawns['X']._tickets, transport) < bestCost:
               bestMove = move
               bestTransport = transport
               bestCost = cost(self._pawns['X']._tickets, transport)
         if bestMove != None:
            log.msg("found a safe move at this threshold")
            break
         else:
            log.msg("could not find a safe move at this threshold")

      # if no safe moves can be found, then move randomly
      if bestMove == None:
         log.msg("detectives have me trapped--moving randomly")
         moves = path.possible_destinations(self._pawns['X'].getLocation, 1,
                 tickets=self._pawns['X']._tickets)[0]
         selected_move = random.choice(list(moves))
         bestMove, bestTransport = all_paths[selected_move]

      log.msg("making a move")    
      self.makeMove(['x', str(bestMove), str(bestTransport)])
   def doTurn(self, pawnName):

      # Taxis are best, because they hide position to some degree.
      # Underground is relatively expensive because it tells detectives where
      # you might be.  black is very expensive because supplies are limited.
      def cost(ticket_amounts, ticket):
         if ticket == 'taxi':
            return 1
         elif ticket == 'bus':
            return 1.6
         elif ticket == 'underground':
            return 3
         elif ticket == 'black':
            return 5

      all_paths = path.cheapest_path(self._pawns['X'].getLocation(), 
                                     tickets=self._pawns['X']._tickets,
                                     cost=cost)

      # look at the available moves in order from most safe to least safe

      safe = self.safeMoves()
      safe.reverse()
      bestMove      = None
      bestTransport = None
      bestCost      = 1000000
      for moves in safe:
         moves_list = list(moves)
         random.shuffle(moves_list)
         for move in moves_list:
            p = all_paths[move]
            dest, transport = p[0]
            if cost(self._pawns['X']._tickets, transport) < bestCost:
               bestMove = move
               bestTransport = transport
               bestCost = cost(self._pawns['X']._tickets, transport)
         if bestMove != None:
            log.msg("found a safe move at this threshold")
            break
         else:
            log.msg("could not find a safe move at this threshold")

      # if no safe moves can be found, then move randomly
      if bestMove == None:
         log.msg("detectives have me trapped--moving randomly")
         moves = path.possible_destinations(self._pawns['X'].getLocation, 1,
                 tickets=self._pawns['X']._tickets)[0]
         selected_move = random.choice(list(moves))
         bestMove, bestTransport = all_paths[selected_move]

      log.msg("\n\n\n") 
      log.msg("Mr. X location: ", self._pawns['X'].getLocation()) 

      log.msg("Mr. X Tickets: "+ str(self._pawns['X']._tickets)+"\n")
      dets      = ['Red', 'Yellow', 'Green', 'Blue', 'Black']
      detLocs   = [self._pawns[d].getLocation() for d in dets]
      log.msg("DETETIVE LOCATIONS: "+ str(detLocs))
      det_tickets = [self._pawns[d]._tickets for d in dets]
      log.msg("DETECTIVE TICKETS: "+ str(det_tickets)+"\n")
      log.msg("Turn number: "+ str(self._turnNum)+"\n")
      # self.turnNo += 1
      # log.msg("Turn No: "+ str(self.turnNo)+"\n")
      self.generate_feature_space()
      # log.msg("Mr. x options are: ", self.safeMoves())
      move_file = "/Users/shreyasi/Desktop/LondonLaw/move.txt"
      f = open(move_file, "w")
      f.write(str(bestMove)+" , "+bestTransport+"\n\n")
      f.close()
      log.msg("Best move is from: ", self._pawns['X'].getLocation(), "to : ", bestMove, "using: ",  bestTransport)
      self.makeMove(['x', str(bestMove), str(bestTransport)])
      log.msg("making a move " +"\n\n\n") 
   def doTurn(self, pawnName):

      pawn = self._pawns[pawnName]

      def cost(ticket_amounts, ticket):
         if ticket == 'taxi':
            if ticket_amounts['taxi'] > 2:
               return 1
            else:
               return 2
         elif ticket == 'bus':
            if ticket_amounts['bus'] > 2:
               return 1.2
            else:
               return 2
         elif ticket == 'underground':
            if ticket_amounts['underground'] > 1:
               return 3
            else:
               return 5
         elif ticket == 'black':
            return 1000000

      all_paths = path.cheapest_path(pawn.getLocation(), tickets=pawn._tickets,
                                      cost=cost)
      detective_locs = [self._pawns[p].getLocation() for p in self._pawns if p != 'X']

      #log.msg("Detectives Bot")
      self.generate_feature_space(pawnName)

      if self._turnNum < 3:
         # Before X has surfaced, just try to get to high-mobility locations.
         # Compute locations we can get to by the end of turn 2, with the constraint
         # that we don't spend any undergrounds
         t = pawn._tickets.copy()
         t['underground'] = 0
         e = [sets.Set()] * (3 - self._turnNum)
         e[0].union_update(detective_locs)
         locs = list(path.possible_destinations(pawn.getLocation(), 3 - self._turnNum, 
               tickets=t, eliminate=e))
         random.shuffle(locs)
         # evaluate the mobility of each location
         bestLoc      = None
         bestMobility = 0
         for loc in locs:
            # how well-connected is this location?
            mobility = len(path.possible_destinations(loc, 1, pawn._tickets))
            if mobility > bestMobility:
               bestLoc      = loc
               bestMobility = mobility
         if bestLoc != None and all_paths[bestLoc] != None:
            self.makeMove([pawnName.lower(), str(all_paths[bestLoc][0][0]), all_paths[bestLoc][0][1]])
            log.msg("Best Move for ", pawnName.lower(), "detective is to", str(all_paths[bestLoc][0][0]), "using", all_paths[bestLoc][0][1])
         else:
            # shouldn't happen
            raise DetectiveSimpleAIProtocolError("failed to find a move for turnNum < 3")
      else:
         # after X has surfaced, just try to go somewhere where he *might* be (use game
         # history to eliminate detective positions as possible locations)
         lastXLoc = self._history[self._lastXSurfacingTurn]['X'][0]
         xTransports = []
         e           = []
         for i in range(self._lastXSurfacingTurn + 1, self._turnNum + 1):
            xTransports.append(self._history[i]['X'][1])
            detPos = []
            for p in self._pawns:
               if p != 'X' and p in self._history[i-1].keys():
                  detPos.append(self._history[i-1][p][0])
            e.append(sets.Set(detPos))
         #log.msg('x transports = ' + str(xTransports))
         xLocs = path.possible_locations(lastXLoc, xTransports, eliminate=e)
         #log.msg('x possible locations = ' + str(xLocs))

         # determine which of these locations is closest with a path that is
         # attainable
         minDist = 1000000
         bestLoc = None
         for loc in xLocs:
            if (all_paths[loc] != None and len(all_paths[loc]) < minDist and
                  len(all_paths[loc]) > 0 and all_paths[loc][0][0] not in detective_locs):
               bestLoc = loc

         if bestLoc != None and all_paths[bestLoc] != None:
            self.makeMove([pawnName.lower(), str(all_paths[bestLoc][0][0]), all_paths[bestLoc][0][1]])
            log.msg("Best Move for ", pawnName.lower(), "detective is to", str(all_paths[bestLoc][0][0]), "using", all_paths[bestLoc][0][1])
         else:
            # if we can't find anything good, make a random move
            log.msg("moving randomly")
            availableMoves = list(path.possible_destinations(pawn.getLocation(), 1,
               tickets=pawn._tickets, eliminate = [sets.Set(detective_locs)]))
            move = random.choice(availableMoves)
            self.makeMove([pawnName.lower(), str(all_paths[move][0][0]), all_paths[move][0][1]])
            log.msg("Best Move for ", pawnName.lower(), "detective is to", str(all_paths[move][0][0]), "using", all_paths[move][0][1])