# How to DRY up directional logic from a try/except mess

I'm trying to simplify my solution to Project Euler's problem 11 (find the greatest product of 4-in-a-row numbers in a 20x20 grid).

My main gripe with my answer are the four try/except clauses in the definition of sub_lists_at_xy. I have one for each direction (east, south, southeast, and southwest) of 4-in-a-row lists that could possibly run off the board. Do you have any suggestions for simplifying or DRYing up this implementation?

``````from operator import mul

with open("11.txt") as f:
nums = [[int(num) for num in line.split(' ')] for line in f.read().split('\n')]

def prod(lst):
return reduce(mul, lst, 1)

def sub_lists_at_xy(array, length, x, y):

try:
east=array[y][x:x+length]
except IndexError:
east=[0]*length

try:
south=[list[x] for list in array[y:y+length]]
except IndexError:
south=[0]*length

try:
southeast=[array[y+i][x+i] for i in range(length)]
except IndexError:
southeast=[0]*length

try:
southwest=[array[y+i][x-i] for i in range(length)]
except IndexError:
southwest=[0]*length

return east, south, southeast, southwest

sub_lists=[]

for x in range(len(nums[0])):
for y in range(len(nums)):
sub_lists += sub_lists_at_xy(nums, 4, x, y)
best = max(prod(lst) for lst in sub_lists)
print(best)
``````
• Why don't you test that your x and y values are within bounds first, then you can avoid all of the `try...excepts`. Commented Jul 28, 2012 at 0:12
• is there an elegant way to do this? It was my first inclination that each of east, south, southeast, and southwest would require different checks for x and/or y. And when I did some research I found that it was suggested to get in the habit of using `try...except`s to avoid race conditions (though this isn't a concern in this case).
– dyln
Commented Jul 28, 2012 at 0:21
• @dylan - Where did you read this about race conditions and try/catch? They aren't very closely related - exceptions won't prevent race conditions.
– dfb
Commented Jul 28, 2012 at 0:26
• @dfb cant find it now but I was reading a discussion about the virtues of look before you leap and easier to ask forgiveness than permission. You're right, I'm not sure I understand why EAFP would prevent a race condition. More importantly the whole race condition thing is irrelevant in this case, as there's no chance of that happening here.
– dyln
Commented Jul 28, 2012 at 20:23

To follow the don't-repeat-yourself rule, you could pull out the direction logic:

``````def sub_lists_at_xy(array, length, x, y):
directions = [(1, 0), (0, 1), (1, 1), (-1, 1)]
sublists = []
for dx, dy in directions:
try:
seq = [array[y+dy*i][x+dx*i] for i in range(length)]
sublists.append(seq)
except IndexError:
pass
return sublists
``````

You might want to check that I didn't get the directions wrong -- I usually make sign errors all over the place -- but you get the idea.

[Note: this isn't how I myself would do it, but it's how I would simplify your code.]

• I like where you're going with this. Thanks @DSM.
– dyln
Commented Jul 28, 2012 at 20:24

You could check the input, but you could also pad your array

``````with open("11.txt") as f:
nums = [["X"] + [int(num) for num in line.split(' ')] + ["X"] for line in f.read().split('\n')]
nums = ["X"]*(len(nums[0])+2) + nums + ["X"]*(len(nums[0])+2)
``````

You can then filter your data

``````reduce(mul, [x for x in lst if x != "X"], 1)
``````
• You can, but it's not very pythonic. Commented Jul 28, 2012 at 0:16
• @JoelCornett - Why is padding the data not Pythonic? IMO it's cleaner than putting in a bunch of if statements to replace the try/except
– dfb
Commented Jul 28, 2012 at 0:19
• yeah i was thinking of padding my array, but couldn't find an elegant way to do so. Your solution is intriguing.
– dyln
Commented Jul 28, 2012 at 0:23
• @JoelCornett perhaps there's a more "implicit"/elegant way of padding that would achieve the same end.
– dyln
Commented Jul 28, 2012 at 0:25
• @JoelCornett - :). Fair point with the comments. This is the typical solution for ACM style programming contests as well.
– dfb
Commented Jul 28, 2012 at 0:28