jS5t3r/astar.py

## astar.py
# Enter your code here. Read input from STDIN. Print output to STDOUT
class Node:
    def __init__(self,value,point):
        self.value = value
        self.point = point
        self.parent = None
        self.H = 0
        self.G = 0
    def move_cost(self,other):
        return 0 if self.value == '.' else 1

def children(point,grid):
    x,y = point.point
    links = [grid[d[0]][d[1]] for d in [(x-1, y),(x,y - 1),(x,y + 1),(x+1,y)]]
    return [link for link in links if link.value != '%']
def manhattan(point,point2):
    return abs(point.point[0] - point2.point[0]) + abs(point.point[1]-point2.point[0])
def aStar(start, goal, grid):
    #The open and closed sets
    openset = set()
    closedset = set()
    #Current point is the starting point
    current = start
    #Add the starting point to the open set
    openset.add(current)
    #While the open set is not empty
    while openset:
        #Find the item in the open set with the lowest G + H score
        current = min(openset, key=lambda o:o.G + o.H)
        #If it is the item we want, retrace the path and return it
        if current == goal:
            path = []
            while current.parent:
                path.append(current)
                current = current.parent
            path.append(current)
            return path[::-1]
        #Remove the item from the open set
        openset.remove(current)
        #Add it to the closed set
        closedset.add(current)
        #Loop through the node's children/siblings
        for node in children(current,grid):
            #If it is already in the closed set, skip it
            if node in closedset:
                continue
            #Otherwise if it is already in the open set
            if node in openset:
                #Check if we beat the G score
                new_g = current.G + current.move_cost(node)
                if node.G > new_g:
                    #If so, update the node to have a new parent
                    node.G = new_g
                    node.parent = current
            else:
                #If it isn't in the open set, calculate the G and H score for the node
                node.G = current.G + current.move_cost(node)
                node.H = manhattan(node, goal)
                #Set the parent to our current item
                node.parent = current
                #Add it to the set
                openset.add(node)
    #Throw an exception if there is no path
    raise ValueError('No Path Found')
def next_move(pacman,food,grid):
    #Convert all the points to instances of Node
    for x in xrange(len(grid)):
        for y in xrange(len(grid[x])):
            grid[x][y] = Node(grid[x][y],(x,y))
    #Get the path
    path = aStar(grid[pacman[0]][pacman[1]],grid[food[0]][food[1]],grid)
    #Output the path
    print len(path) - 1
    for node in path:
        x, y = node.point
        print x, y
pacman_x, pacman_y = [ int(i) for i in raw_input().strip().split() ]
food_x, food_y = [ int(i) for i in raw_input().strip().split() ]
x,y = [ int(i) for i in raw_input().strip().split() ]

grid = []
for i in xrange(0, x):
    grid.append(list(raw_input().strip()))

next_move((pacman_x, pacman_y),(food_x, food_y), grid)
	# Enter your code here. Read input from STDIN. Print output to STDOUT
	class Node:
	def __init__(self,value,point):
	self.value = value
	self.point = point
	self.parent = None
	self.H = 0
	self.G = 0
	def move_cost(self,other):
	return 0 if self.value == '.' else 1

	def children(point,grid):
	x,y = point.point
	links = [grid[d[0]][d[1]] for d in [(x-1, y),(x,y - 1),(x,y + 1),(x+1,y)]]
	return [link for link in links if link.value != '%']
	def manhattan(point,point2):
	return abs(point.point[0] - point2.point[0]) + abs(point.point[1]-point2.point[0])
	def aStar(start, goal, grid):
	#The open and closed sets
	openset = set()
	closedset = set()
	#Current point is the starting point
	current = start
	#Add the starting point to the open set
	openset.add(current)
	#While the open set is not empty
	while openset:
	#Find the item in the open set with the lowest G + H score
	current = min(openset, key=lambda o:o.G + o.H)
	#If it is the item we want, retrace the path and return it
	if current == goal:
	path = []
	while current.parent:
	path.append(current)
	current = current.parent
	path.append(current)
	return path[::-1]
	#Remove the item from the open set
	openset.remove(current)
	#Add it to the closed set
	closedset.add(current)
	#Loop through the node's children/siblings
	for node in children(current,grid):
	#If it is already in the closed set, skip it
	if node in closedset:
	continue
	#Otherwise if it is already in the open set
	if node in openset:
	#Check if we beat the G score
	new_g = current.G + current.move_cost(node)
	if node.G > new_g:
	#If so, update the node to have a new parent
	node.G = new_g
	node.parent = current
	else:
	#If it isn't in the open set, calculate the G and H score for the node
	node.G = current.G + current.move_cost(node)
	node.H = manhattan(node, goal)
	#Set the parent to our current item
	node.parent = current
	#Add it to the set
	openset.add(node)
	#Throw an exception if there is no path
	raise ValueError('No Path Found')
	def next_move(pacman,food,grid):
	#Convert all the points to instances of Node
	for x in xrange(len(grid)):
	for y in xrange(len(grid[x])):
	grid[x][y] = Node(grid[x][y],(x,y))
	#Get the path
	path = aStar(grid[pacman[0]][pacman[1]],grid[food[0]][food[1]],grid)
	#Output the path
	print len(path) - 1
	for node in path:
	x, y = node.point
	print x, y
	pacman_x, pacman_y = [ int(i) for i in raw_input().strip().split() ]
	food_x, food_y = [ int(i) for i in raw_input().strip().split() ]
	x,y = [ int(i) for i in raw_input().strip().split() ]

	grid = []
	for i in xrange(0, x):
	grid.append(list(raw_input().strip()))

	next_move((pacman_x, pacman_y),(food_x, food_y), grid)