The 15-puzzle is a classic problem that has captivated mathematics enthusiasts for centuries. The objective is to arrange the tiles in order by sliding them into the empty space. The challenge lies in its vast state space, with approximately 1013 possible configurations. Numerous algorithms have been developed to tackle the 15-puzzle, highlighting its complexity and the significant challenge it presents.
In this project, we employ advanced algorithms to effectively manage this large state space. Specifically, the A* algorithm utilizes multiple heuristics to reduce the number of states generated and expand fewer nodes, thereby improving efficiency. The heuristics, such as Manhattan Distance (MD), Linear Conflict (LC), and Walking Distance (WD), are combined in a hybrid approach to provide optimal or near-optimal solutions while maintaining manageable space complexity.
pip install fifteen-puzzle-solvers
# requires `tkinter` to be installed
from fifteen_puzzle_solvers import run_ui
run_ui()
This code implements two different puzzle solvers:
- Breadth First Algorithm
- A* Algorithm
- Heuristic 1: Counting the number of misplaced tiles
- Heuristic 2: Finding the sum of the Manhattan distances between each block and its position in the goal configuration
- Heuristic 3: Combining Manhattan distance, Linear Conflict, and walking distance for a comprehensive estimate (default heuristic)
from fifteen_puzzle_solvers.domain import Puzzle
from fifteen_puzzle_solvers.services.algorithms import AStar, BreadthFirst
from fifteen_puzzle_solvers.services.solver import PuzzleSolver
puzzle = Puzzle([[1, 2, 3, 4], [5, 6, 7, 8], [0, 10, 11, 12], [9, 13, 14, 15]])
for strategy in [BreadthFirst, AStar]:
puzzle_solver = PuzzleSolver(strategy(puzzle))
puzzle_solver.run()
puzzle_solver.print_performance()
puzzle_solver.print_solution()
Output
Breadth First - Expanded Nodes: 56
Solution:
—————————————
│ 1│ 2│ 3│ 4│
│ 5│ 6│ 7│ 8│
│ 0│10│11│12│
│ 9│13│14│15│
—————————————
—————————————
│ 1│ 2│ 3│ 4│
│ 5│ 6│ 7│ 8│
│ 9│10│11│12│
│ 0│13│14│15│
—————————————
—————————————
│ 1│ 2│ 3│ 4│
│ 5│ 6│ 7│ 8│
│ 9│10│11│12│
│13│ 0│14│15│
—————————————
—————————————
│ 1│ 2│ 3│ 4│
│ 5│ 6│ 7│ 8│
│ 9│10│11│12│
│13│14│ 0│15│
—————————————
—————————————
│ 1│ 2│ 3│ 4│
│ 5│ 6│ 7│ 8│
│ 9│10│11│12│
│13│14│15│ 0│
—————————————
A* - Expanded Nodes: 4
Solution:
—————————————
│ 1│ 2│ 3│ 4│
│ 5│ 6│ 7│ 8│
│ 0│10│11│12│
│ 9│13│14│15│
—————————————
—————————————
│ 1│ 2│ 3│ 4│
│ 5│ 6│ 7│ 8│
│ 9│10│11│12│
│ 0│13│14│15│
—————————————
—————————————
│ 1│ 2│ 3│ 4│
│ 5│ 6│ 7│ 8│
│ 9│10│11│12│
│13│ 0│14│15│
—————————————
—————————————
│ 1│ 2│ 3│ 4│
│ 5│ 6│ 7│ 8│
│ 9│10│11│12│
│13│14│ 0│15│
—————————————
—————————————
│ 1│ 2│ 3│ 4│
│ 5│ 6│ 7│ 8│
│ 9│10│11│12│
│13│14│15│ 0│
—————————————
from fifteen_puzzle_solvers.domain.puzzle import Puzzle
from fifteen_puzzle_solvers.services.algorithms import AStar
from fifteen_puzzle_solvers.services.solver import PuzzleSolver
from fifteen_puzzle_solvers.services.puzzle.shuffle import PuzzleShuffleService
# Generate a shuffled 3x3 puzzle using the PuzzleShuffleService
shuffled_puzzle = PuzzleShuffleService.shuffle_puzzle(3)
# Create a solver using the A* algorithm with the 'misplaced' heuristic
puzzle_solver = PuzzleSolver(AStar(shuffled_puzzle, heuristic='misplaced'))
puzzle_solver.run()
# Print the performance and the solution
puzzle_solver.print_performance()
>> Output: A* - Expanded Nodes: 979
puzzle_solver = PuzzleSolver(AStar(puzzle, heuristic='total')) # default
puzzle_solver.run()
puzzle_solver.print_performance()
>> Output: A* - Expanded Nodes: 68
Both the Breadth First and A* algorithms take an initial puzzle state as input and return a list of Puzzle objects that represent the sequence of moves needed to solve the puzzle.
Uses a queue list to keep track of the paths that need to be explored. The algorithm begins by adding the initial puzzle state to the queue list. Then, it repeatedly takes the first path from the queue list, gets all the possible moves from the last position in the path, and adds the new paths to the end of the queue list. This process continues until the end position of the puzzle is reached or there are no more paths to explore.
The A* algorithm is an extension of the Breadth-First Search that uses heuristics to prioritize which paths to explore. It maintains a priority queue where each path is associated with a cost, which is the sum of the path length and a heuristic estimate of the remaining cost to reach the goal.
Heuristics are used to estimate the cost of reaching the goal from a given state. The A* algorithm in this implementation supports the following heuristics:
-
Misplaced Tiles: This heuristic counts the number of tiles that are not in their goal position. It is simple but not always very accurate.
-
Manhattan Distance: This heuristic calculates the sum of the Manhattan distances (i.e., the sum of the absolute differences of the row and column indices) of the tiles from their goal positions. It is more accurate than the misplaced tiles heuristic.
-
Total Heuristic (Default): This heuristic combines multiple heuristic functions—Manhattan distance, linear conflict, and walking distance—to provide a comprehensive estimate. This combination balances accuracy and performance, making it the default choice for solving the puzzle efficiently.
- Shuffle: Click the "Shuffle" button to shuffle the puzzle.
- Solve: Click the "Solve" button to automatically solve the puzzle using the selected algorithm.
- Manual Play: Click on the tiles adjacent to the empty space to move them.
- Previous/Next Steps: After solving the puzzle, use the "Previous Step" and "Next Step" buttons to navigate through the solution steps.
- domain/: Contains the core logic and data structures for the puzzle game.
- services/: Includes the algorithms and services for shuffling and solving the puzzle.
- tests/: Contains test cases for the project.
- ui/: Holds the graphical user interface code.