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As someone relatively new to Haskell and functional programming, and coming mainly from a Python background, I'd like to know why the following function results in a stack overflow in Haskell, even if I use a very low number like 4, or 5 as the input variable, whereas the exact same function in Python can process an integer of 20 and up without overflowing. Why is this so?

countStairs <0 = 0
countStairs 0 = 1
countStairs n = countStairs(n-1) + countStairs(n-2) + countStairs(n-3)

I've read other responses on Haskell and stack overflows that address code optimization and solving specific overflowing code, whereas I'm interested in understanding the specifc reason for the difference in how the two languages handle recursion here, or more generally why the Haskell code results in a stack overflow.

EDIT: I didn't include the full python code because this is my first question in Stack Overflow and I'm struggling to figure out how to get my Python to format properly (nice welcome from some of you, btw). Here it is, poor formatting and all, but the Python as written does work properly with the integer 20, whereas my undoubtedly poor Haskell has not. I've edited the Haskell code to show the corresponding code I originally omitted. I thought I was including the relevant recursive part, but obviously I was wrong to omit the base case. Still, as written, my Haskell stack overflows and my Python doesn't, and I'm still interested in learning why. Even though I don't come from a programming background, I really like learning Haskell and was just trying to learn some more. Thanks to those who tried to address the question in spite of my incomplete question.

def countStairs(n):
    if n < 0:
        return 0
    elif n == 0:
        return 1
        return countStairs(n-1) + countStairs(n-2) + countStairs(n-3)

myint = int(raw_input("Please enter an integer: "))
print countStairs(myint)
share|improve this question
Python can run an infinite recursion without overflowing its stack, and in finite time?? – Rahul Dec 31 '11 at 5:02
@Rahul: Well, it already has antigravity. Performing infinite computations can't be that much harder. – C. A. McCann Dec 31 '11 at 5:07
@EricS.Bullington Since it is a common "next mistake", please note that there is no automatic memoizing going on either. OTOH as the link shows, it isn't hard to add. – Thomas M. DuBuisson Dec 31 '11 at 5:56
-1 for not reporting what the exact same python program outputs for countStairs 20 – Ingo Dec 31 '11 at 12:15
Exact same program in python overflows. Huge stack trace is super helpful. ;) – Dan Burton Dec 31 '11 at 20:25
up vote 10 down vote accepted

Another way to add a terminating condition is to use a guard (this also addresses the <= 2 condition Corbin mentioned:

countStairs n | n > 0 = countStairs(n-1) + countStairs(n-2) + countStairs(n-3)
              | otherwise = 1


Your updated Haskell example doesn't work because you misunderstand a how pattern matching works. You were expecting it to work like a guard (seeing as you tried to provide a boolean expression < 0 in a pattern match), however, that version of your function never matches (when you call the countStairs function). Consider this example:

countStairs < 0 = "Matched '< 0'"
countStairs   0 = "Matched '0'"
countStairs   n = "Matched n"

main = do
    putStrLn $ countStairs (-1)  -- outputs: "Matched n"
    putStrLn $ countStairs 0     -- outputs: "Matched 0"
    putStrLn $ countStairs 20    -- outputs: "Matched n"

The interesting thing here is that your function actually compiles. To find out why, load the above code into ghci and type :browse. This will give you a list of the functions you've defined in this module. You should see something like this:

(Main.<) :: Num a => t -> a -> [Char]
countStairs :: Num a => a -> [Char]
main :: IO ()

You've got countStairs and main which both make sense. But you've also got this function called Main.<. What is this? You've redefined the < function in this module! In case you're not familiar, you can define infix functions (like +, <, >, etc.) like so:

infix <
a < b = True

-- also defined as
(<) a b = True

Normally, you need that infix FUNCTION_NAME to indicate your function is infix. But.. prelude already defines < as an infix function, therefore, you didn't need to, and instead just gave your own definition of <.

Now, lets rearrange our countStairs < 0 = "Matched '< 0'" like we did with a < b, and you get this:

(<) countStairs 0 = "Matched '< 0'"

In this function, countStairs is actually the first argument to your < function.

Here's one more example to drive home the point. Try running 1 < 0 in ghci (with your module still loaded). Here's what you'll get:

*Main> 1 < 0

    Ambiguous occurrence `<'
    It could refer to either `Main.<', defined at foo.hs:3:13
                          or `Prelude.<', imported from Prelude

Normally, you'd get False, but in this case, ghci doesn't know if it should use your function (since < is just a regular function, not a special syntax) or the built-in (Prelude) version of <.

Long story short... use guards (or case, or if) for boolean tests, not pattern matches.

share|improve this answer
Ah, was not aware of that syntax (my haskell knowledge is very limited :p). I quite like that syntax ([and C A McCann's] and how it captures more cases than just n = 0) better than my own answer. +1 :) – Corbin Dec 31 '11 at 5:16
@Corbin: That syntax is called "guards", and the bit after the | can be an arbitrary boolean expression. Oh, and otherwise is just a cute way of writing True that the standard library provides. – C. A. McCann Dec 31 '11 at 5:20
Haskell is on my list of languages to learn, but have only looked at it very briefly :). – Corbin Dec 31 '11 at 5:23
@Corbin: You should spend some time learning it when you can; I've enjoyed it immensely, myself. And I hear the community tends to be pretty helpful, especially on Stack Overflow. ;] – C. A. McCann Dec 31 '11 at 5:38
Ah, I know a bit of Scheme, but have never messed with Haskell. I find functional programming to be enthralling though and want to learn more in the future. I shall keep your suggestion in mind :). – Corbin Dec 31 '11 at 5:39

Not very familiar with haskell, but it looks like there's no terminating condition. I believe that will keep going with n approaching negative infinity.

Try something like:

countStairs 0 = 1
countStairs n = countStairs(n-1) + countStairs(n-2) + countStairs(n-3)

That will mean that countStairs(0) = 1.

You might need to worry about negatives too if you ever plan on calling countStairs(n) | n <= 2.

share|improve this answer
One needs three consecutive base cases or it will become an infinite recursion. – Daniel Fischer Dec 31 '11 at 10:00
Thanks, Corbin. My full program had a terminating condition but I made the (now) obvious mistake of omitting it. See above for my original code, which still stack overflows. – Eric S. Bullington Jan 1 '12 at 3:21

Using this:

countStairs n | n <= 0 = 1
countStairs n = countStairs(n-1) + countStairs(n-2) + countStairs(n-3)

Gives me this in GHCi:

∀x. x ⊢ countStairs 20

...in about two seconds. So yes, Corbin seems to be correct.

share|improve this answer
Thanks for your serious response. Please see my edited code above in response to your comment about antigravity. Looking at your response, I re-coded my Haskell above, but with guards like you used instead of the kind of pattern matching I used, and it worked. I'm left wondering why. – Eric S. Bullington Jan 1 '12 at 3:19
@EricS.Bullington: See Adam Wagner's answer--you were unintentionally re-defining <, rather than expressing a condition like you wanted. Pattern matching only works for exact matches. In this case, guards are what you wanted in the first place. – C. A. McCann Jan 1 '12 at 7:48
thanks for the explanation. Yes, I was confusing guards and pattern matching. I'll be careful now to use pattern matching on with exact matches. – Eric S. Bullington Jan 1 '12 at 12:46

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