# A* pathfinding on 2D grid doesn't find optimal path

I am trying to implement the A* algorithm on a 2D square grid. However, it almost never finds an optimal path, and I just can't see why. The code is also suspiciously slow, even for python.

I've tried just anything, I'm out of ideas.

This is what I have so far:

file astar.py:

``````end = None

NLUT = [ (1,0) , (0,1) , (-1,0) , (0,-1) ]

class Tile:
def __init__(self,x,y,g=0,parent=None):
self.x = x
self.y = y
self.g = g
self.parent = parent

def __eq__(self,other):
if other == None:
return False
return ( (self.x == other.x) and (self.y == other.y))
def __ne__(self,other):
return not self.__eq__(other)
def __hash__(self):
return hash((self.x,self.y))

def __str__(self):
if self.parent == None:
sss = ""
else:
sss = " <- "+str(self.parent.coords())
return "<"+str(self.x)+"."+str(self.y)+"g"+str(self.g)+">"+sss
def __repr__(self):
return "<"+str(self.x)+"."+str(self.y)+">"

def coords(self):
return (self.x,self.y)

def f(self):
return self.g + self.h()

def h(self):
global end
return ((abs(self.x-end[0]) + abs(self.y-end[1])))

def nbd(self):
global NLUT
return [ Tile(self.x + n[0], self.y + n[1], self.g + 1, self) for n in NLUT]

def pathfind(mapfunction,start,endp):

global end
end = endp
DEBUG = False
#   DEBUG = True

def log(st):
if DEBUG:
print(st)

startile = Tile(start[0],start[1],0)
endtile = Tile(end[0],end[1])

path = []

# init openSet with the starting tile
openSet = set([startile])
closedSet = set()

stepcount = 0

#the loop, as long as openSet is not empty:
while len(openSet)>0:

log(str(stepcount)+"-"+str(openSet))
stepcount += 1
fcur = float("inf")
#find lowest f-count tile in the open set
for o in openSet:
if o.f() < fcur:
fcur = o.f()
current = o

log("current: "+str(current))

#move the current tile to the closed set
openSet.remove(o)

#find the von neumann neighbourhood
nbd = o.nbd()
log("nbd: "+str(nbd))
#work on the neighbours
for n in nbd:

log("processing "+str(n))

if mapfunction(n.x,n.y) != 0: #if it's blocked, ignore
log("it was blocked.")
continue
elif n in closedSet: #if it's in the closed set, ignore
log("it was in the closed set.")
continue
elif n in openSet: #if it's in the open set...
log("it's in the open set...")
for e in openSet:
if n==e:            #find the old copy of n in the open set
if n.g < e.g:   #if it's a better path, substitute
log("SUBSTITUTION")
openSet.remove(e)
else:
log("old path was better.")

break           #no need to go on...
else: #if it's not in the open set, add it
log("not in the open set, adding...")

if endtile in closedSet:          #if we're done
#find copy of endtile in closedSet
for e in closedSet:
if e == endtile:
rec = e
while (not rec == None) and rec != startile:  #reconstruct the path
path.append(rec.coords())
rec = rec.parent
path.append(startile.coords())
return path
#if openset is empty, no path was found. :(
return -1
``````

and this is a little demo program, astardemo.py:

``````import astar
from random import *

mapp = [[randint(0,10)//10 for _ in range(0,50)] for _ in range(0,50)]

def isblocked(x,y):
global mapp

if not (x in range(0,50) and y in range(0,50)):
return 1
return (mapp[x][y] != 0)

start = (randint(0,49),randint(0,49))
end = (randint(0,49),randint(0,49))

mapp[start[0]][start[1]] = 0
mapp[end[0]][end[1]] = 0

p = astar.pathfind(isblocked,start,end)

print p

l = ""

for i in range(0,50):
for j in range(0,50):
if (i,j) in p:
if mapp[i][j] > 0:
l+="E"
else:
l+=str(p.index((i,j))%10)

elif mapp[i][j] > 0:
l+="#"
else:
l+=" "
l+="\n"
print l
``````
-
Pick better names. `f`, `g`, and `h` on the same object, but `g` is an instance attribute and `f` and `h` are methods? What do these letters mean? – user2357112 Aug 7 '13 at 17:18
You mix up `current` and `o` a bunch of times. That could be your problem, or one of your problems. – user2357112 Aug 7 '13 at 17:19
Oh God, you're right. I used o instead of current. That's why it worked as if there was no f(), it just chose always the last tile on the openSet. Anyways, g is the path distance, h is the heuristic, and f is their sum. h and f are methods because I saw no point in keeping an array of h-values, since they are simply manhattan distances. Thanks for the quick answers – Riccardo Antonelli Aug 7 '13 at 17:26
@user2357112 `f(x), g(x), and h(x)` are the core values in A* search The names are fine if you know A*, otherwise heuristic and CSF might be better variable names – Stephan Aug 7 '13 at 18:00

``````    for o in openSet:
if o.f() < fcur:
fcur = o.f()
current = o

log("current: "+str(current))

#move the current tile to the closed set
openSet.remove(o)

#find the von neumann neighbourhood
nbd = o.nbd()
``````

In this code you use `o` but you are outside the loop, so it will always be the last value in the loop did you mean to use `current`?

``````    for o in openSet:
if o.f() < fcur:
fcur = o.f()
current = o

log("current: "+str(current))

#move the current tile to the closed set
openSet.remove(current)

#find the von neumann neighbourhood
nbd = current.nbd()
``````
-
It has access to it. Simply it will only be the last value of the iteration. – Bakuriu Aug 7 '13 at 19:40