Traktor/source/astar.py

from area.constants import TILE_SIZE, ROWS
import copy
import heapq
from area.field import tiles, fieldX, fieldY
from bfs import get_moves

class Node:

    def __init__(self, priority, x, y, direction, parent, action, cost=0):
        self.x = x
        self.y = y
        self.direction = direction
        self.action = action
        self.parent = parent
        self.cost = cost
        self.priority = priority


    def __int__(self):
        return self.priority

        # getters and setters:

    def get_parent(self):
        return self.parent

    def set_parent(self, _parent):
        self.parent = _parent

    def get_action(self):
        return self.action

    def set_action(self, _action):
        self.parent = _action

    def get_x(self):
        return self.x

    def set_x(self, _x):
        self.x = _x

    def get_y(self):
        return self.y

    def set_y(self, _y):
        self.y = _y

    def get_direction(self):
        return self.direction

    def set_direction(self, _direction):
        self.parent = _direction

    def get_cost(self):
        return self.cost

    def set_cost(self, _cost):
        self.cost = _cost

    def get_priority(self):
        return self.priority

    def set_priority(self, _priority):
        self.priority = _priority

    def __lt__(self, other):
        return self.get_priority() < other.get_priority()

    def copy(self):
        return copy.copy(self)


def goal_test(elem, goalstate):
    if elem.get_x() == goalstate[0] and elem.get_y() == goalstate[1]:
        return True
    else:
        return False

def tile_cost(tile):
    if tile.image == "resources/images/sampling.png":
        return 100
    if tile.image == "resources/images/rock_dirt.png":
        return 500
    else:
        return 1

def heuristic(current_x, current_y, end_x, end_y):
    return abs(end_x - current_x) + abs(end_y - current_y)
# State as a tuple (x,y,direction)

# actions(string): move, rotate_to_left, rotate_to_right

# main search function:
def a_star(istate, succ, goaltest, tractor):
    fringe = []
    explored = set()
    node = Node(0, istate.get_x(), istate.get_y(), istate.get_direction(), None, None, 0)
    heapq.heappush(fringe, node)

    while True:

        if not fringe:
            return False

        elem = heapq.heappop(fringe)
        temp = copy.copy(elem)
        if goal_test(elem, goaltest) is True:  # jesli True zwroc ciag akcji
            return get_moves(elem)

        explored.add(elem)

        for (action, state) in succ(temp, tractor):
            fringe_tuple = []
            explored_tuple = []

            for node in fringe:
                fringe_tuple.append((node.get_x(), node.get_y(), node.get_direction()))
            for node in explored:
                explored_tuple.append((node.get_x(), node.get_y(), node.get_direction()))


            tile = int((temp.get_y() - fieldY) / TILE_SIZE) * ROWS + int((temp.get_x() - fieldX) / TILE_SIZE)
            cost = temp.cost + tile_cost(tiles[tile])
            priority = cost + heuristic(state[0], state[1], goaltest[0], goaltest[1])

            x = Node(priority, state[0], state[1], state[2], elem, action, cost)

            if state not in fringe_tuple and state not in explored_tuple:
                heapq.heappush(fringe, x)

            elif state in fringe_tuple and elem.get_priority() < priority:
                elem.set_priority(priority)
dodanie algorytmu a* 2024-04-27 22:49:47 +02:00			`from area.constants import TILE_SIZE, ROWS`
			`import copy`
			`import heapq`
			`from area.field import tiles, fieldX, fieldY`
			`from bfs import get_moves`

			`class Node:`

			`def __init__(self, priority, x, y, direction, parent, action, cost=0):`
			`self.x = x`
			`self.y = y`
			`self.direction = direction`
			`self.action = action`
			`self.parent = parent`
			`self.cost = cost`
			`self.priority = priority`


			`def __int__(self):`
			`return self.priority`

			`# getters and setters:`

			`def get_parent(self):`
			`return self.parent`

			`def set_parent(self, _parent):`
			`self.parent = _parent`

			`def get_action(self):`
			`return self.action`

			`def set_action(self, _action):`
			`self.parent = _action`

			`def get_x(self):`
			`return self.x`

			`def set_x(self, _x):`
			`self.x = _x`

			`def get_y(self):`
			`return self.y`

			`def set_y(self, _y):`
			`self.y = _y`

			`def get_direction(self):`
			`return self.direction`

			`def set_direction(self, _direction):`
			`self.parent = _direction`

			`def get_cost(self):`
			`return self.cost`

			`def set_cost(self, _cost):`
			`self.cost = _cost`

			`def get_priority(self):`
			`return self.priority`

			`def set_priority(self, _priority):`
			`self.priority = _priority`

			`def __lt__(self, other):`
			`return self.get_priority() < other.get_priority()`

			`def copy(self):`
			`return copy.copy(self)`


			`def goal_test(elem, goalstate):`
			`if elem.get_x() == goalstate[0] and elem.get_y() == goalstate[1]:`
			`return True`
			`else:`
			`return False`

			`def tile_cost(tile):`
			`if tile.image == "resources/images/sampling.png":`
			`return 100`
dodano koszt wjazdu na kamien 2024-06-09 14:55:33 +02:00			`if tile.image == "resources/images/rock_dirt.png":`
			`return 500`
dodanie algorytmu a* 2024-04-27 22:49:47 +02:00			`else:`
			`return 1`

			`def heuristic(current_x, current_y, end_x, end_y):`
			`return abs(end_x - current_x) + abs(end_y - current_y)`
			`# State as a tuple (x,y,direction)`

			`# actions(string): move, rotate_to_left, rotate_to_right`

			`# main search function:`
			`def a_star(istate, succ, goaltest, tractor):`
			`fringe = []`
			`explored = set()`
			`node = Node(0, istate.get_x(), istate.get_y(), istate.get_direction(), None, None, 0)`
			`heapq.heappush(fringe, node)`

			`while True:`

			`if not fringe:`
			`return False`

			`elem = heapq.heappop(fringe)`
			`temp = copy.copy(elem)`
			`if goal_test(elem, goaltest) is True: # jesli True zwroc ciag akcji`
			`return get_moves(elem)`

			`explored.add(elem)`

			`for (action, state) in succ(temp, tractor):`
			`fringe_tuple = []`
			`explored_tuple = []`

			`for node in fringe:`
			`fringe_tuple.append((node.get_x(), node.get_y(), node.get_direction()))`
			`for node in explored:`
			`explored_tuple.append((node.get_x(), node.get_y(), node.get_direction()))`


			`tile = int((temp.get_y() - fieldY) / TILE_SIZE) * ROWS + int((temp.get_x() - fieldX) / TILE_SIZE)`
			`cost = temp.cost + tile_cost(tiles[tile])`
			`priority = cost + heuristic(state[0], state[1], goaltest[0], goaltest[1])`

			`x = Node(priority, state[0], state[1], state[2], elem, action, cost)`

			`if state not in fringe_tuple and state not in explored_tuple:`
			`heapq.heappush(fringe, x)`

			`elif state in fringe_tuple and elem.get_priority() < priority:`
			`elem.set_priority(priority)`