Ejemplo n.º 1
0
 def __init__(self):
     self.mazeDFS = Maze()
     self.free = False
     self.goal = []
     self.mazeDFS.findEnd(self.goal)
     self.start = []
     self.mazeDFS.findStart(self.start)
Ejemplo n.º 2
0
 def __init__(self):
     self.mazeM = Maze()
     self.goal = []
     self.mazeM.findEnd(self.goal)
     self.start = []
     self.mazeM.findStart(self.start)
Ejemplo n.º 3
0
class GreedySolver:
    # initial value that should always be greater than heuristic
    LARGE_NUM = 65234

    # Constructor of GreedySolver
    # duplicates the maze and initializes goal and start
    def __init__(self):
        self.mazeM = Maze()
        self.goal = []
        self.mazeM.findEnd(self.goal)
        self.start = []
        self.mazeM.findStart(self.start)

    # Finds the heuristic value from the current position to the goal
    # Returns the heuristic
    def heuristic(self, posX, posY):
        return abs(posX - self.goal[0]) + abs(posY - self.goal[1])

    # The main body (search method) for the GreedySolver
    # Uses an entered maze and start position
    # Searches through the maze by following the best heuristic path found
    # It also prints out the location on the map as it traverses toward the exit.
    def search(self, maze, start, goal):
        opened = []
        closed = []
        opened.append(MazeInfo(start[0], start[1], 0, self.heuristic(start[0], start[1])))

        while len(opened):
            h = self.LARGE_NUM
            tocheck = -1
            for x in range(len(opened)):
                if opened[x].h <= h:
                    h = opened[x].h
                    tocheck = x
            checking = opened[tocheck]
            closed.append(checking)

            if maze.checkExit(checking.x, checking.y):
                print(self.goal)
                print("Exit Found!\n")
                return

            # go left
            tempX = checking.x
            tempY = checking.y
            maze.maze[checking.y][checking.x] = 'X'
            tempX = tempX - 1
            tempChecking = MazeInfo(tempX, tempY, checking.g + 1, self.heuristic(tempX, tempY))
            if maze.moveable(tempX, tempY) and tempChecking not in closed:
                if tempChecking in opened:
                        for j in range(len(opened)):
                            if opened[j] == tempChecking:
                                opened[j] = tempChecking
                else:
                    opened.append(tempChecking)

            # go down
            tempX = checking.x
            tempY = checking.y
            tempY = tempY + 1
            tempChecking = MazeInfo(tempX, tempY, checking.g + 1, self.heuristic(tempX, tempY))
            if maze.moveable(tempX, tempY) and tempChecking not in closed:
                if tempChecking in opened:
                        for j in range(len(opened)):
                            if opened[j] == tempChecking:
                                opened[j] = tempChecking
                else:
                    opened.append(tempChecking)

            # go right
            tempX = checking.x
            tempY = checking.y
            tempX = tempX + 1
            tempChecking = MazeInfo(tempX, tempY, checking.g + 1, self.heuristic(tempX, tempY))
            if maze.moveable(tempX, tempY) and tempChecking not in closed:
                if tempChecking in opened:
                        for j in range(len(opened)):
                            if opened[j] == tempChecking:
                                opened[j] = tempChecking
                else:
                    opened.append(tempChecking)

            # go up
            tempX = checking.x
            tempY = checking.y
            tempY = tempY - 1
            tempChecking = MazeInfo(tempX, tempY, checking.g + 1, self.heuristic(tempX, tempY))
            if maze.moveable(tempX, tempY) and tempChecking not in closed:
                if tempChecking in opened:
                        for j in range(len(opened)):
                            if opened[j] == tempChecking:
                                opened[j] = tempChecking
                else:
                    opened.append(tempChecking)

            opened.remove(checking)
            print("[" + str(checking.x) + ", " + str(checking.y) + "]")
Ejemplo n.º 4
0
class DfsSolver:

    # Constructor
    # initializes a maze to use
    # A variable to know if it is free
    # and where the goal and start are
    def __init__(self):
        self.mazeDFS = Maze()
        self.free = False
        self.goal = []
        self.mazeDFS.findEnd(self.goal)
        self.start = []
        self.mazeDFS.findStart(self.start)

    # The main body for the DFS search
    # Uses entered coordinates being the start and solves for the end
    # uses recursion
    def solve(self, y, x):
        if self.mazeDFS.maze[y][x] != Maze.EXIT and self.mazeDFS.maze[y][
                x] != Maze.START:
            self.mazeDFS.maze[y][x] = Maze.VISITED
        if self.mazeDFS.maze[y][x] == Maze.EXIT:
            self.free = True
            return
        if self.mazeDFS.maze[y][x - 1] == Maze.OPEN or self.mazeDFS.maze[y][
                x - 1] == Maze.EXIT:  # Logic for moving left
            if self.free:
                return
            if self.mazeDFS.maze[y][x] != Maze.START:
                self.mazeDFS.maze[y][x] = Maze.VISITED
            print("[" + str(x) + ", " + str(y) + "]")
            self.solve(y, x - 1)
        if self.mazeDFS.maze[y + 1][x] == Maze.OPEN or self.mazeDFS.maze[
                y + 1][x] == Maze.EXIT:  # Logic for moving down
            if self.free:
                return
            if self.mazeDFS.maze[y][x] != Maze.START:
                self.mazeDFS.maze[y][x] = Maze.VISITED
            print("[" + str(x) + ", " + str(y) + "]")
            self.solve(y + 1, x)
        if self.mazeDFS.maze[y - 1][x] == Maze.OPEN or self.mazeDFS.maze[
                y - 1][x] == Maze.EXIT:  # Logic for moving up
            if self.free:
                return
            if self.mazeDFS.maze[y][x] != Maze.START:
                self.mazeDFS.maze[y][x] = Maze.VISITED
            print("[" + str(x) + ", " + str(y) + "]")
            self.solve(y - 1, x)
        if self.mazeDFS.maze[y][x + 1] == Maze.OPEN or self.mazeDFS.maze[y][
                x + 1] == Maze.EXIT:  # Logic for moving right
            if self.free:
                return
            if self.mazeDFS.maze[y][x] != Maze.START:
                self.mazeDFS.maze[y][x] = Maze.VISITED
            print("[" + str(x) + ", " + str(y) + "]")
            self.solve(y, x + 1)

    # prints the maze that the dfs solver initialized
    def printDfsMaze(self):
        for i in range(len(self.mazeDFS.maze)):
            for j in range(len(self.mazeDFS.maze[i])):
                print(self.mazeDFS.maze[i][j], end='')
            print()
Ejemplo n.º 5
0
# Project 1
# Contributors: Logan Garza, Timothy Kempster, Aidan Zastrow
# The problem we addressed in our project was the solving a linear maze in an [x,y] plane using python.
# When traversing in a maze, there are four basic actions you can proceed with at any given point,
# you can check for a wall and attempt to move: right, up, down, or left.
# Our project aimed to automate this decision making based on different algorithms and heuristics.
# We implemented a depth first search algorithm,
# A star heuristic, and greedy best-first heuristic to address different ways to traverse and
# solve a maze given that it has one specific entry point and one specific exit/goal point.
from bin.Maze import Maze
from bin.AStarSolver import AStarSolver
from bin.DfsSolver import DfsSolver
from bin.GreedySolver import GreedySolver
test = Maze()
test2 = AStarSolver()
test3 = DfsSolver()
test4 = GreedySolver()
print("\n")

# Main Body. Runs through all the algorithms.
print("Start of DFS Solver")
print("Original Maze: 1 = wall, 0 = free, 2 = start, 3 = exit, X = visited")
test3.printDfsMaze()
print()
print("Printing locations visited by the solver in form of [x, y]")
test3.solve(test3.start[1], test3.start[0])
print("Finished Maze:")
test3.printDfsMaze()
print("End of DFS Solver\n")

print("Start of Greedy Solver")
Ejemplo n.º 6
0
class AStarSolver:
    # used to determine the object in opened with the lowest path cost function
    LARGE_NUM = 65234

    # Constructor of A*
    # initializes goal and start and a maze to use
    def __init__(self):
        self.mazeM = Maze()
        self.goal = []
        self.mazeM.findEnd(self.goal)
        self.start = []
        self.mazeM.findStart(self.start)

    # Finds the heuristic value from the current position to the goal
    # Returns the heuristic
    def heuristic(self, posX, posY):
        return abs(posX - self.goal[0]) + abs(posY - self.goal[1])

    # The main body for the A* search
    # Uses an entered maze and start position
    # Searches through the maze using A* until it finds the goal
    # Will print out the path taken as it goes
    def solve(self, maze, start):
        opened = []
        closed = []
        opened.append(
            MazeInfo(start[0], start[1], 0, self.heuristic(start[0],
                                                           start[1])))

        while len(opened):
            f = self.LARGE_NUM
            tocheck = -1
            for x in range(len(opened)):
                if (opened[x].f < f):
                    f = opened[x].f
                    tocheck = x
            checking = opened[tocheck]

            print("[", checking.x, ",", checking.y, "]")
            closed.append(checking)

            ## go left
            tempX = checking.x
            tempY = checking.y
            if maze.checkExit(checking.x, checking.y):
                return

            maze.visited(checking.y, checking.x)
            tempX = tempX - 1
            tempChecking = MazeInfo(tempX, tempY, checking.g + 1,
                                    self.heuristic(tempX, tempY))
            if maze.moveable(tempX, tempY) and tempChecking not in closed:
                if tempChecking in opened:
                    if tempChecking.g >= checking.g + 1:
                        for j in range(len(opened)):
                            if opened[j] == tempChecking:
                                opened[j] = tempChecking
                else:
                    opened.append(tempChecking)

            ## go down
            tempX = checking.x
            tempY = checking.y

            tempY = tempY + 1
            tempChecking = MazeInfo(tempX, tempY, checking.g + 1,
                                    self.heuristic(tempX, tempY))
            if maze.moveable(tempX, tempY) and tempChecking not in closed:
                if tempChecking in opened:
                    if tempChecking.g >= checking.g + 1:
                        for j in range(len(opened)):
                            if opened[j] == tempChecking:
                                opened[j] = tempChecking
                else:
                    opened.append(tempChecking)

            ##right

            tempX = checking.x
            tempY = checking.y

            tempX = tempX + 1
            tempChecking = MazeInfo(tempX, tempY, checking.g + 1,
                                    self.heuristic(tempX, tempY))
            if maze.moveable(tempX, tempY) and tempChecking not in closed:
                if tempChecking in opened:
                    if tempChecking.g >= checking.g + 1:
                        for j in range(len(opened)):
                            if opened[j] == tempChecking:
                                opened[j] = tempChecking
                else:
                    opened.append(tempChecking)

            ## up
            tempX = checking.x
            tempY = checking.y

            tempY = tempY - 1
            tempChecking = MazeInfo(tempX, tempY, checking.g + 1,
                                    self.heuristic(tempX, tempY))
            if maze.moveable(tempX, tempY) and tempChecking not in closed:
                if tempChecking in opened:
                    if tempChecking.g >= checking.g + 1:
                        for j in range(len(opened)):
                            if opened[j] == tempChecking:
                                opened[j] = tempChecking
                else:
                    opened.append(tempChecking)

            opened.remove(checking)