thanks in advance for any help.
I am making a pathfinder visualiser using python in pygame. I have tried to make the A* algorithm, but sometimes it does not find the shortest path. I have been looking through several previous questions with the same issue, which has led me to believe it may be a problem with the heuristic. If I set the hueristic value to 0, then the algorithm becomes dijkstra's and always gets the shortest path.
A grid is used for the algorithm, with x being the number row and y being the number column (I believe might be the other way around but it doesnt matter)
Each square on the grid is an object, with x and y values, as well as a gScore, hScore and fScore. On initialisation these are all set to None.
I also have some functions at the bottom to do calculations, such as find the lowest fScore node from an array, find the gScore, find the hScore, fScore and get the distance between two grid squares.
I think the problem is in the hueristic function and have tried several different methods of fixing to no avail. From looking at the code below would anyone be able to see the problem, or point me in the right direction? Any help is much appreciated .
For simplicity I have only included the A* function without any of the pygame stuff, but I can add the entire program if need be, including the gridsquare object.
def a_star(): for row in grid: for square in row: if square.state == "start_pos": start_pos = square elif square.state == "end_pos": end_pos = square start_pos.gScore = find_g(start_pos, start_pos) start_pos.hScore = find_h(start_pos, end_pos) start_pos.fScore = find_f(start_pos.gScore, start_pos.hScore) openList = [start_pos] closedList =  while len(openList) > 0: current_node = get_lowest_f_node(openList) if current_node.state == "end_pos": print("found") path = [end_pos] node = current_node while node.parent != None: time.sleep(SHORTEST_PATH_DELAY) node = node.parent path.append(node) return openList.remove(current_node) closedList.append(current_node) x = current_node.x y = current_node.y # get nodes around current node node1 = grid[x][y - 1] node2 = grid[x][y + 1] node3 = grid[x - 1][y] node4 = grid[x + 1][y] successor_nodes = [node1, node2, node3, node4] for node in successor_nodes: # check if walkable if (node.state == "wall") or (node in closedList): continue if node.gScore == None: node.gScore = current_node.gScore tentative_g_score = current_node.gScore + get_distance(node, current_node) if (node in closedList) and (tentative_g_score >= node.gScore): continue if (node not in openList) or (tentative_g_score < node.gScore): node.parent = current_node node.gScore = tentative_g_score node.fScore = node.gScore + find_h(node, end_pos) if node not in openList: openList.append(node) def get_lowest_f_node(array): min_f = min(array, key = attrgetter("fScore")) return min_f # distance from current node and start node def find_g(current, start_pos): g = get_distance(current, start_pos) return g # distance from current node and target / destination / finish node def find_h(current, end_pos): h = get_distance(current, end_pos) return h # hscore and gscore added together def find_f(score1, score2): return score1 + score2 # distance from 2 points def get_distance(start, end): x1 = start.x y1 = start.y x2 = end.x y2 = end.y distancex = sqr(x2 - x1) distancey = sqr(y2 - y1) #distance = sqrt(distancex + distancey) distance = distancex + distancey return distance def sqr(number): return number * number
Below are some images of the result of the path finding, with different patters. The starting node is always the bottom red square.
^^^ This is where the A* algorithm finds the correct, shortest path. All good.
^^^This is where A* finds a path, but it is not the shortest path. This is what I am trying to fix, any help is much appreciated.
^^^ this is dijkstra's finding the correct path when presented with the same arrangement of walls.
I am very grateful for any help.