# How do I implement genetic algorithm on grid board to find optimal path

I am preparing algorithms for optimal path finding in terrain with obstacles. Till now i implemented Dijsktra and A* algorithms. Now i have to implement genetic algorithm and I have problem.

Firstly I will show you how my map representation looks. There are 7 different kinds of terrain (0- start, 7- end, 1-4 normal which can be passed, 5-6 cannot pass). Here is code for that in Python (the most important part of code, in my opinion, to understand problem is function `neighbors`):

``````class Graph():
def __init__(self, x=10, y=10):
self.width = x
self.height = y
self.board = ((1, 1, 1, 5, 1, 1, 1, 1, 1, 7),
(1, 1, 1, 5, 1, 1, 1, 1, 1, 1),
(1, 1, 1, 5, 1, 5, 1, 1, 1, 1),
(0, 1, 1, 1, 1, 5, 1, 1, 1, 1),
(1, 1, 1, 1, 1, 5, 1, 1, 1, 1),
(1, 1, 1, 1, 1, 1, 1, 1, 1, 1),
(1, 1, 1, 1, 1, 1, 1, 1, 1, 1),
(1, 1, 1, 1, 1, 1, 1, 1, 1, 1),
(1, 1, 1, 1, 1, 1, 1, 1, 1, 1),
(1, 1, 1, 1, 1, 1, 1, 1, 1, 1))
self.time = {0: None,
1: 1,
2: 4,
3: 7,
4: 4,
7: 1}
def cost(self, id):
(x, y)= id
return self.time.get(self.board[y][x])

def canPass(self, id):
(x, y) = id
return self.board[y][x] != 5 and self.board[y][x] != 6 and self.board[y][x] != 0

def inBounds(self, id):
(x, y) = id
return 0 <= x < self.width and 0 <= y < self.height

def neighbors(self, id):
(x, y) = id
nodes = [(x-1, y), (x, y-1), (x+1, y), (x, y+1)]
nodes = filter(self.inBounds, nodes)
nodes = filter(self.canPass, nodes)
return nodes
``````

I have no idea how to implement genetic algorithm from theoretical point because of my map and neighbor representation and i cannot change them.

What I did:

I prepared starting population using modification of my A* which find nearly the easiest connection from start to end without checking cost of that. Here's code

``````def heuristic(a, b):
(x1, y1) = a
(x2, y2) = b
return abs(x1 - x2) + abs(y1 - y2)

def StartingPopulation(graph, start, goal):
(x, y) = start
frontier = PriorityQueue()
frontier.put(start, 0)
came_from = {}
cost_so_far = [[0 for i in xrange(10)] for j in xrange(10)]
came_from[start] = None
cost_so_far[y][x] = 0
while not frontier.empty():
current = frontier.get()
(y1, x1) = current
if (y1, x1) == goal:
break
for next in graph.neighbors(current):
new_cost = cost_so_far[x1][y1] + graph.cost(next)
(y2, x2) = next
if cost_so_far[x2][y2] == 0 or new_cost < cost_so_far[x2][y2]:
cost_so_far[x2][y2] = new_cost
priority = new_cost + heuristic(goal, next)
frontier.put(next, priority)
came_from[next] = current
return came_from, cost_so_far
``````

That's all I invent. I have no idea how to do other steps for genetic algorithm like selection, crossover and mutation on data i have. I hope you can guide me and give some hints (if there is full code for what I need it would be also good to check and learn from it)

• My personal opinion is that whenever you can use something like A*, you should stick to it rather than a genetic algorithm. Is there any particular reason for trying to do this? – Patrick Trentin Jun 29 '16 at 8:54

A simple GA-based method for a 2D grid is to fractionate chromosomes (binary strings) into moves, eg:

``````00 = down
10 = left
01 = right
11 = up
``````

The `run(chromosome)` function, given a `chromosome`, performs the moves from the starting point (code `0`on the map) and returns the final point reached:

``````(f_y, f_x) = run(chromosome)
``````

The fitness function is the distance from the goal point:

``````def fitness(chromosome):
final = run(chromosome)
return 1.0 - (distance(final, goal) / max_possible_distance)
``````

or also:

``````# Returns negative values.
# Depending on the selection scheme, it can be problematic.
def fitness(chromosome):
final = run(chromosome)
return -distance(final, goal)
``````

Both fitness functions assume that greater is better.

Now an example:

1. `S` is the starting point, `F` is the final point reached, `G` is the goal point and `*` a wall
2. `chromosome` is `00 00 01 01 00 00 00 01 01 11` i.e. `↓ ↓ → → ↓ ↓ ↓ → → ↑`
3. `run(S, chromosome)` operates in the following way:

``````|---|---|---|---|---|---|
| S |   |***|   |   |   |
|-|-|---|---|---|---|---|
| | |   |***|   |   |   |
|-|-|---|---|---|---|---|
| +---+->***|   |***|***|
|---|-|-|---|---|---|---|
|   | | |***| F |   | G |
|---|-|-|---|-^-|---|---|
|   | +-------+ |***|   |
|---|-|-|---|---|---|---|
``````

The function simply ignores impossible moves

4. Fitness is `-2`

Standard One point crossover / two points crossover (or other forms) can be used, e.g.:

``````ONE POINT CROSSOVER

00 00 01 01 00 00|00 01 01 11      PARENTS
11 11 01 01 00 00|01 01 11 01
-----------------^-----------
00 00 01 01 00 00|01 01 11 01      OFFSPRING
11 11 01 01 00 00|00 01 01 11
``````

The first child (`00 00 01 01 00 00 01 01 11 01`) has fitness greater than both parents (`-1`):

``````|---|---|---|---|---|---|
| S |   |***|   |   |   |
|-|-|---|---|---|---|---|
| | |   |***|   |   |   |
|-|-|---|---|---|---|---|
| +---+->***|   |***|***|
|---|-|-|---|---|---|---|
|   | | |***| +-> F | G |
|---|-|-|---|-|-|---|---|
|   | +-------+ |***|   |
|---|---|---|---|---|---|
``````

NOTES

• Instead of ignoring impossible moves (as in the above example), the scheme can be extended using a gene repair operator which erases bad moves and adds random moves to fill up the chromosome (more complex but it takes advantage of full available length).
• Usually, in GA, chromosomes have a fixed length: allowing a length 30% - 40% longer than the best path is a good idea.
• Any path to the goal is considered up to standard. Searching for the best path requires adding a penalty term to the fitness function for deviations from the shortest path, e.g:

``````  def fitness(chromosome):
final = run(chromosome)
return -distance(final, goal) - length_of_path(chromosome) / 100.0
``````
• A completely different approach is using GA to optimize A* (further details in Using a Genetic Algorithm to Explore A*-like Pathfinding Algorithms by Ryan Leigh, Sushil J. Louis and Chris Miles).

• A third option, probably the most interesting from an AI point of view, is Genetic Programming (see Evolving Pathfinding Algorithms Using Genetic Programming by Rick Strom for an example).
• This is a good example of the flexibility of GA, but A* is ways better.