Infinite loop and recursion in Python

I am working on implementing an iterative deepening depth first search to find solutions for the 8 puzzle problem. I am not interested in finding the actual search paths themselves, but rather just to time how long it takes for the program to run. (I have not yet implemented the timing function).

However, I am having some issues trying to implement the actual search function (scroll down to see). I pasted all the code I have so far, so if you copy and paste this, you can run it as well. That may be the best way to describe the problems I'm having...I'm just not understanding why I'm getting infinite loops during the recursion, e.g. in the test for puzzle 2 (p2), where the first expansion should yield a solution. I thought it may have something to do with not adding a "Return" in front of one of the lines of code (it's commented below). When I add the return, I can pass the test for puzzle 2, but something more complex like puzzle 3 fails, since it appears that the now the code is only expanding the left most branch...

Been at this for hours, and giving up hope. I would really appreciate another set of eyes on this, and if you could point out my error(s). Thank you!

``````#Classic 8 puzzle game
#Data Structure: [0,1,2,3,4,5,6,7,8], which is the goal state. 0 represents the blank
#We also want to ignore "backward" moves (reversing the previous action)

p1 = [0,1,2,3,4,5,6,7,8]
p2 = [3,1,2,0,4,5,6,7,8]
p3 = [3,1,2,4,5,8,6,0,7]

def z(p):   #returns the location of the blank cell, which is represented by 0
return p.index(0)

def left(p):
zeroLoc = z(p)
p[zeroLoc] = p[zeroLoc-1]
p[zeroLoc-1] = 0
return p

def up(p):
zeroLoc = z(p)
p[zeroLoc] = p[zeroLoc-3]
p[zeroLoc-3] = 0
return p

def right(p):
zeroLoc = z(p)
p[zeroLoc] = p[zeroLoc+1]
p[zeroLoc+1] = 0
return p

def down(p):
zeroLoc = z(p)
p[zeroLoc] = p[zeroLoc+3]
p[zeroLoc+3] = 0
return p

def expand1(p):   #version 1, which generates all successors at once by copying parent
x = z(p)
#p[:] will make a copy of parent puzzle
s = []  #set s of successors

if x == 0:
s.append(right(p[:]))
s.append(down(p[:]))
elif x == 1:
s.append(left(p[:]))
s.append(right(p[:]))
s.append(down(p[:]))
elif x == 2:
s.append(left(p[:]))
s.append(down(p[:]))
elif x == 3:
s.append(up(p[:]))
s.append(right(p[:]))
s.append(down(p[:]))
elif x == 4:
s.append(left(p[:]))
s.append(up(p[:]))
s.append(right(p[:]))
s.append(down(p[:]))
elif x == 5:
s.append(left(p[:]))
s.append(up(p[:]))
s.append(down(p[:]))
elif x == 6:
s.append(up(p[:]))
s.append(right(p[:]))
elif x == 7:
s.append(left(p[:]))
s.append(up(p[:]))
s.append(right(p[:]))
else:   #x == 8
s.append(left(p[:]))
s.append(up(p[:]))

#returns set of all possible successors
return s

goal = [0,1,2,3,4,5,6,7,8]

def DFS(root, goal):    #iterative deepening DFS
limit = 0
while True:
result = DLS(root, goal, limit)
if result == goal:
return result
limit = limit + 1

visited = []

def DLS(node, goal, limit):    #limited DFS
if limit == 0 and node == goal:
print "hi"
return node
elif limit > 0:
visited.append(node)
children = [x for x in expand1(node) if x not in visited]
print "\n limit =", limit, "---",children   #for testing purposes only
for child in children:
DLS(child, goal, limit - 1)     #if I add "return" in front of this line, p2 passes the test below, but p3 will fail (only the leftmost branch of the tree is getting expanded...)
else:
return "No Solution"

#Below are tests

print "\ninput: ",p1
print "output: ",DFS(p1, goal)

print "\ninput: ",p2
print "output: ",DLS(p2, goal, 1)
#print "output: ",DFS(p2, goal)

print "\ninput: ",p3
print "output: ",DLS(p3, goal, 2)
#print "output: ",DFS(p2, goal)
``````
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There have been no less than 3 other questions about 8-puzzles in the last 2 days. Try the search. Especially Ashwin's question seems very similar to yours. –  Junuxx Oct 27 '12 at 20:27
just a note, python has very limited recursion depth. So use recursion wisely –  Aniket Oct 27 '12 at 20:31
Could someone please explain why (or point me in the right direction) as to why the node is not returned in the DLS function for p2, even though the if statement is satisfied? However, the node IS returned in p1 (where the input is just the solution). –  Amaranthine Oct 27 '12 at 20:53

The immediate issue you're having with your recursion is that you're not returning anything when you hit your recursive step. However, unconditionally returning the value from the first recursive call won't work either, since the first child isn't guaranteed to be the one that finds the solution. Instead, you need to test to see which (if any) of the recursive searches you're doing on your child states is successful. Here's how I'd change the end of your `DLS` function:

``````    for child in children:
child_result = DLS(child, goal, limit - 1)
if child_result != "No Solution":
return child_result

# note, "else" removed here, so you can fall through to the return from above
return "No Solution"
``````

A slightly more "pythonic" (and faster) way of doing this would be to use `None` as the sentinel value rather than the "No Solution" string. Then your test would simply be `if child_result: return child_result` and you could optionally leave off the return statement for the failed searches (since `None` is the default return value of a function).

There are some other issues going on with your code that you'll run into once this recursion issue is fixed. For instance, using a global `visited` variable is problematic, unless you reset it each time you restart another recursive search. But I'll leave those to you!

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Thank you for taking the time to go through a detailed explanation of why this way is correct! –  Amaranthine Oct 27 '12 at 23:16

Use classes for your states! This should make things much easier. To get you started. Don't want to post the whole solution right now, but this makes things much easier.

``````#example usage
cur = initialPuzzle
for k in range(0,5): # for 5 iterations. this will cycle through, so there is some coding to do
allsucc = cur.succ() # get all successors as puzzle instances
cur = allsucc[0] # expand first
print 'expand ',cur
``````

``````import copy

class puzzle:

'''
orientation
[0, 1, 2
3, 4, 5
6, 7, 8]
'''

def __init__(self,p):
self.p = p

def z(self):
''' returns the location of the blank cell, which is represented by 0 '''
return self.p.index(0)

def swap(self,a,b):
self.p[a] = self.p[b]
self.p[b] = 0

def left(self):
self.swap(self.z(),self.z()+1) #FIXME: raise exception if not allowed

def up(self):
self.swap(self.z(),self.z()+3)

def right(self):
self.swap(self.z(),self.z()-1)

def down(self):
self.swap(self.z(),self.z()-3)

def __str__(self):
return str(self.p)

def copyApply(self,func):
cpy = self.copy()
func(cpy)
return cpy

def makeCopies(self,s):
''' some bookkeeping '''
flist = list()
if 'U' in s:
flist.append(self.copyApply(puzzle.up))
if 'L' in s:
flist.append(self.copyApply(puzzle.left))
if 'R' in s:
flist.append(self.copyApply(puzzle.right))
if 'D' in s:
flist.append(self.copyApply(puzzle.down))

return flist

def succ(self):
# return all successor states for this puzzle state
# short hand of allowed success states
m = ['UL','ULR','UR','UDR','ULRD','UDL','DL','LRD','DR']
ss= self.makeCopies(m[self.z()]) # map them to copies of puzzles
return ss

def copy(self):
return copy.deepcopy(self)

# some initial state
p1 = [0,1,2,3,4,5,6,7,8]

print '*'*20
pz = puzzle(p1)
print pz

a,b = pz.succ()
print a,b
``````
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