This is a very simple C++ implementation of the A* algorithm for pathfinding on a two-dimensional grid. The solver itself is implemented in C++, but is callable from Python. This combines the speed of C++ with the convenience of Python.
I have not done any formal benchmarking, but the solver finds the solution to a 1802 by 1802 maze in 0.29s and a 4008 by 4008 maze in 0.83s when running on my nine-year-old Intel(R) Core(TM) i7-2630QM CPU @ 2.00GHz. See Example Results for more details.
See src/cpp/astar.cpp
for the core C++ implementation of the A* shortest
path search algorithm, src/pyastar2d/astar_wrapper.py
for the Python wrapper
and examples/example.py
for example usage.
When determining legal moves, 4-connectivity is the default, but it is possible
to set allow_diagonal=True
for 8-connectivity.
Instructions for installing pyastar2d
are given below.
The easiest way to install pyastar2d
is directly from the Python package index:
pip install pyastar2d
You can also install pyastar2d
by cloning this repository and building it
yourself. If running on Linux or MacOS, simply run
pip install .
from the root directory. If you are using Windows you may have to install Cython manually first:
pip install Cython
pip install .
To check that everything worked, run the example:
python examples/example.py
Include pyastar2d
in your requirements.txt
to install from pypi
, or add
this line to requirements.txt
:
pyastar2d @ git+git://github.com/hjweide/pyastar2d.git@master#egg=pyastar2d
A simple example is given below:
import numpy as np
import pyastar2d
# The minimum cost must be 1 for the heuristic to be valid.
# The weights array must have np.float32 dtype to be compatible with the C++ code.
weights = np.array([[1, 3, 3, 3, 3],
[2, 1, 3, 3, 3],
[2, 2, 1, 3, 3],
[2, 2, 2, 1, 3],
[2, 2, 2, 2, 1]], dtype=np.float32)
# The start and goal coordinates are in matrix coordinates (i, j).
path = pyastar2d.astar_path(weights, (0, 0), (4, 4), allow_diagonal=True)
print(path)
# The path is returned as a numpy array of (i, j) coordinates.
array([[0, 0],
[1, 1],
[2, 2],
[3, 3],
[4, 4]])
Note that all grid points are represented as (i, j)
coordinates. An example
of using pyastar2d
to solve a maze is given in examples/maze_solver.py
.
To test the implementation, I grabbed two nasty mazes from Wikipedia. They are
included in the mazes
directory, but are originally from here:
Small and
Large.
I load the .png
files as grayscale images, and set the white pixels to 1
(open space) and the black pixels to INF
(walls).
To run the examples specify the input and output files using the --input
and
--output
flags. For example, the following commands will solve the small and
large mazes:
python examples/maze_solver.py --input mazes/maze_small.png --output solns/maze_small.png
python examples/maze_solver.py --input mazes/maze_large.png --output solns/maze_large.png
time python examples/maze_solver.py --input mazes/maze_small.png --output solns/maze_small.png
Loaded maze of shape (1802, 1802) from mazes/maze_small.png
Found path of length 10032 in 0.292794s
Plotting path to solns/maze_small.png
Done
real 0m1.214s
user 0m1.526s
sys 0m0.606s
The solution found for the small maze is shown below:
time python examples/maze_solver.py --input mazes/maze_large.png --output solns/maze_large.png
Loaded maze of shape (4002, 4002) from mazes/maze_large.png
Found path of length 783737 in 0.829181s
Plotting path to solns/maze_large.png
Done
real 0m29.385s
user 0m29.563s
sys 0m0.728s
The solution found for the large maze is shown below:
I recently needed an implementation of the A* algorithm in Python to find the
shortest path between two points in a cost matrix representing an image.
Normally I would simply use networkx, but for
graphs with millions of nodes the overhead incurred to construct the graph can
be expensive. Considering that I was only interested in graphs that may be
represented as two-dimensional grids, I decided to implement it myself using
this special structure of the graph to make various optimizations.
Specifically, the graph is represented as a one-dimensional array because there
is no need to store the neighbors. Additionally, the lookup tables for
previously-explored nodes (their costs and paths) are also stored as
one-dimensional arrays. The implication of this is that checking the lookup
table can be done in O(1), at the cost of using O(n) memory. Alternatively, we
could store only the nodes we traverse in a hash table to reduce the memory
usage. Empirically I found that replacing the one-dimensional array with a
hash table (std::unordered_map
) was about five times slower.
The default installation does not include the dependencies necessary to run the tests. To install these, first run
pip install -r requirements-dev.txt
before running
py.test
The tests are fairly basic but cover some of the more common pitfalls. Pull requests for more extensive tests are welcome.