It seems pretty clear what the problem is: you only increment
count when it is possible to get the exact quantity. Any time you don't increment
count you reset it to 0, and the loop only stops when this exceeds 6. That might take a while.
You wrote a triply-nested
for loop, so the larger
n gets, the slower these loops get. It's possible that if you let it run long enough it might succeed and finish someday; but your basic algorithm is just too slow.
You can find out more by instrumenting your loops with print statements. When I tried it, I wasn't getting output; I figured that was probably due to buffering issues, so I wrote a simple output function that outputs a string and then flushes to make sure I can see the output right away.
Here's your program so edited:
sys.stdout.write(s + "\n")
count = 0
n = 1
while count < 6:
six_consecutive = True
for a in range(n):
for b in range(n):
for c in range(n):
#out("a: %d b: %d c: %d n: %d" % (a, b, c, n))
if 6*a + 9*b + 20*c == n:
six_consecutive = False
out("n == %d count == %d six_consecutive == %s" %
(n, count, str(six_consecutive)))
count += 1
count = 0
n += 1
print("Largest number of McNuggets that cannot be bought in exact quantity: %d." % (n - 5))
I also fixed the spelling on "six_consecutive".
So, how should you fix this? I think you should throw this away and rewrite with a better algorithm. You might want to check and see how other people have solved this problem, or a similar problem. This strikes me as being very similar to the classic problem of how to make change, when given a set of coins of different denominations.
NOTE: The classic problem of making change usually assumes a sensible set of coins, including a coin with the value 1. A simple "greedy" algorithm, starting with the largest coin and working down, will always succeed. This is a bit more interesting because the "coins" set is weird and there are values that cannot be found, so maybe the classic coin problem isn't as relevant as I thought.