This adds a couple of optimizations to @GreggLind's good solution, cutting the run time in half:

```
def is_palindrome(n):
s = str(n)
return s == s[::-1]
def biggest():
big_x, big_y, max_seen = 0,0, 0
for x in xrange(999,99,-1):
# Optim. 1: Nothing in any row from here on can be bigger.
if x*x < max_seen: break
for y in xrange(x, 99,-1): # so we don't double count
# Optim. 2: break, not continue
if x*y < max_seen: break # since we're decreasing,
# nothing else in the row can be bigger
if is_palindrome(x*y):
big_x, big_y, max_seen = x,y, x*y
return big_x,big_y,max_seen
biggest()
# (993, 913, 906609)
```

The line

```
if x*x < max_seen: break
```

means that once we get to the point where x is less than sqrt of largest palindrome yet seen, not only do we not need to investigate any more factors on that row; we don't even need to investigate any more rows at all, since all remaining rows would start from a number less than the current value of x.

This doesn't reduce the number of times we call `is_palindrome()`

, but it means many fewer iterations of the outer loop. The value of `x`

that it breaks on is 952, so we've eliminated the checking of 853 rows (albeit the "smaller" ones, thanks to the other `break`

).

I also noticed that

```
if x*y < max_seen: continue
```

should be

```
if x*y < max_seen: break
```

We are trying to short-circuit the whole row, not just the current iteration of the inner loop.

When I ran this script using cProfile, the cumulative time for `biggest()`

was about 56 msec on average, before the optimizations. The optimizations shrank it to about 23 msec. Either optimization alone would deliver most of that improvement, but the first one is slightly more helpful than the second.

pleaseretitle this question to show that it's for #4? – Gregg Lind Feb 18 '09 at 16:25