# Tic Tac Toe with recursion (Python)

I can't figure out how to tie these functions together for a hard AI, in which it can never lose. I'm supposed to be using recursion in some form or fasion and these function names and contracts were pre-written, I filled in the actual definition. Much googling later, I can't find anything that relates. Any ideas fellas?

``````"""

State S2 is a *successor* of state S1 if S2 can be the the
next state after S1 in a legal game of tic tac toe.

safe: state -> Bool
successor: state x state -> Bool

1. If S is over, then S is safe if 'x' does not have 3 in a row in S.
2. If it is o's move in S, then S is safe iff at least one successor of S is safe.
3. If it is x's move in S, then S is safe iff all successors of S are safe.

A *stateList* is a list of states.
"""

# safe: state-> Bool
#
# A state S is *safe* if player 'o' can force a win or tie from S.

def safe(S):
if over(S): return not threeInRow('x',S)
if turn(S)=='o': return someSafeSuccessor(S)
if turn(S)=='x': return allSafeSuccessors(S)

def threeInRow(p,S):
if p == 'x':
if all(t in S[0] for t in (1,2,3)):
return True
elif all(t in S[0] for t in (4,5,6)):
return True
elif all(t in S[0] for t in (7,8,9)):
return True
elif all(t in S[0] for t in (1,4,7)):
return True
elif all(t in S[0] for t in (2,5,8)):
return True
elif all(t in S[0] for t in (3,6,9)):
return True
elif all(t in S[0] for t in (1,5,9)):
return True
elif all(t in S[0] for t in (3,5,7)):
return True
else:
if all(t in S[1] for t in (1,2,3)):
return True
elif all(t in S[1] for t in (4,5,6)):
return True
elif all(t in S[1] for t in (7,8,9)):
return True
elif all(t in S[1] for t in (1,4,7)):
return True
elif all(t in S[1] for t in (2,5,8)):
return True
elif all(t in S[1] for t in (3,6,9)):
return True
elif all(t in S[1] for t in (1,5,9)):
return True
elif all(t in S[1] for t in (3,5,7)):
return True

# someSafeSuccessor: state -> Bool
#
# If S is a state, someSafeSuccessor(S) means that S has
# at least one safe successor.

def someSafeSuccessor(S):
flag = False
# flag means we have found a safe successor
for x in successors(S):
if safe(x): flag = True
return flag

# allSafeSuccessors: state -> Bool
#
# If S is a state, allSafeSuccessors(S) means that every
# successor of S is safe.
def allSafeSuccessors(S):
flag = True
for x in successors(S):
if not safe(x): flag = False
return flag

# successors: state -> stateList
#
# successors(S) is a list whose members are all of the successors of S.
def successors(S):
stateList=[]
for i in range(1,10):
if empty(i,S):
stateList.extend(S[0],S[1]+[i])
return stateList
``````
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I suggest you google minimax (minimax tree, min-max tree...) and alpha-beta pruning. –  Patashu Apr 18 '13 at 5:14
@shx2 You clearly did not read the question :) –  Patashu Apr 18 '13 at 5:15
I can't use those trees sadly which sucks because there's so much information on them. I'm supposed to be using the functions that I supplied above to make the decision –  user2293538 Apr 18 '13 at 5:20