Last active
January 17, 2025 21:18
-
-
Save Nicholas-Swift/003e1932ef2804bebef2710527008f44 to your computer and use it in GitHub Desktop.
A* pathfinding algorithm. Please see comments below for a fork of this gist that includes bug fixes!
This file contains hidden or bidirectional Unicode text that may be interpreted or compiled differently than what appears below. To review, open the file in an editor that reveals hidden Unicode characters.
Learn more about bidirectional Unicode characters
| class Node(): | |
| """A node class for A* Pathfinding""" | |
| def __init__(self, parent=None, position=None): | |
| self.parent = parent | |
| self.position = position | |
| self.g = 0 | |
| self.h = 0 | |
| self.f = 0 | |
| def __eq__(self, other): | |
| return self.position == other.position | |
| def astar(maze, start, end): | |
| """Returns a list of tuples as a path from the given start to the given end in the given maze""" | |
| # Create start and end node | |
| start_node = Node(None, start) | |
| start_node.g = start_node.h = start_node.f = 0 | |
| end_node = Node(None, end) | |
| end_node.g = end_node.h = end_node.f = 0 | |
| # Initialize both open and closed list | |
| open_list = [] | |
| closed_list = [] | |
| # Add the start node | |
| open_list.append(start_node) | |
| # Loop until you find the end | |
| while len(open_list) > 0: | |
| # Get the current node | |
| current_node = open_list[0] | |
| current_index = 0 | |
| for index, item in enumerate(open_list): | |
| if item.f < current_node.f: | |
| current_node = item | |
| current_index = index | |
| # Pop current off open list, add to closed list | |
| open_list.pop(current_index) | |
| closed_list.append(current_node) | |
| # Found the goal | |
| if current_node == end_node: | |
| path = [] | |
| current = current_node | |
| while current is not None: | |
| path.append(current.position) | |
| current = current.parent | |
| return path[::-1] # Return reversed path | |
| # Generate children | |
| children = [] | |
| for new_position in [(0, -1), (0, 1), (-1, 0), (1, 0), (-1, -1), (-1, 1), (1, -1), (1, 1)]: # Adjacent squares | |
| # Get node position | |
| node_position = (current_node.position[0] + new_position[0], current_node.position[1] + new_position[1]) | |
| # Make sure within range | |
| if node_position[0] > (len(maze) - 1) or node_position[0] < 0 or node_position[1] > (len(maze[len(maze)-1]) -1) or node_position[1] < 0: | |
| continue | |
| # Make sure walkable terrain | |
| if maze[node_position[0]][node_position[1]] != 0: | |
| continue | |
| # Create new node | |
| new_node = Node(current_node, node_position) | |
| # Append | |
| children.append(new_node) | |
| # Loop through children | |
| for child in children: | |
| # Child is on the closed list | |
| for closed_child in closed_list: | |
| if child == closed_child: | |
| continue | |
| # Create the f, g, and h values | |
| child.g = current_node.g + 1 | |
| child.h = ((child.position[0] - end_node.position[0]) ** 2) + ((child.position[1] - end_node.position[1]) ** 2) | |
| child.f = child.g + child.h | |
| # Child is already in the open list | |
| for open_node in open_list: | |
| if child == open_node and child.g > open_node.g: | |
| continue | |
| # Add the child to the open list | |
| open_list.append(child) | |
| def main(): | |
| maze = [[0, 0, 0, 0, 1, 0, 0, 0, 0, 0], | |
| [0, 0, 0, 0, 1, 0, 0, 0, 0, 0], | |
| [0, 0, 0, 0, 1, 0, 0, 0, 0, 0], | |
| [0, 0, 0, 0, 1, 0, 0, 0, 0, 0], | |
| [0, 0, 0, 0, 1, 0, 0, 0, 0, 0], | |
| [0, 0, 0, 0, 0, 0, 0, 0, 0, 0], | |
| [0, 0, 0, 0, 1, 0, 0, 0, 0, 0], | |
| [0, 0, 0, 0, 1, 0, 0, 0, 0, 0], | |
| [0, 0, 0, 0, 1, 0, 0, 0, 0, 0], | |
| [0, 0, 0, 0, 0, 0, 0, 0, 0, 0]] | |
| start = (0, 0) | |
| end = (7, 6) | |
| path = astar(maze, start, end) | |
| print(path) | |
| if __name__ == '__main__': | |
| main() |
Here is a little change for the "stuck" problem on line 81.
# Child is on the closed list
is_closed = False
for closed_child in closed_list:
if child == closed_child:
is_closed = True
if is_closed : continue
This is taking way too many iterations. For example when start = (0, 0) and goal = (0, 19) in the following maze, number of iterations = 2465. The following implementation solved in 322 iterations. What could be the reason?
maze and implementation link: https://www.analytics-link.com/post/2018/09/14/applying-the-a-path-finding-algorithm-in-python-part-1-2d-square-Grid
Hi,
you're checking to see if the child is in the open list in a for loop when you could just use "in" and then use the index which quite a bit faster
# Child is already in the open list
if child in open_list:
childIndex = open_list.index(child)
if child.g > open_list[childIndex].g:
continue
You might want to use a set (for closed_list) and a heapq (for open_list) instead of scanning these lists all the time.
@dfour You could use find which is even faster as it doesn't scan the list twice.
Sign up for free
to join this conversation on GitHub.
Already have an account?
Sign in to comment
Shouldn't "continue" be replaced with "break" on both lines then ?