I have to write a function (without using preloaded functions) that decides if a certain list of Ints is triangular or not, and by triangular I mean if it increases up to a certain number and then decreases, for example:

[2,4,5,7,4,3] but also: [], [1], [1,1], [1, 2, 3], [3, 2, 1], [1, 2, 2], [2, 2, 1] (so non-strict increasing and decreasing)

I came up with this but I dont know what to do next, any advice is appreciated:

``````ex :: [Int] -> Bool
ex [] = True
ex (x:xs) |
``````
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What have you tried? What algorithm do you have in your mind? –  Joachim Breitner Oct 6 '13 at 20:42
imagine your function is at an `(x:xs)` at some random point in the list: what other information or state do you need besides the head and tail to determine whether you should return `False` at that point? –  jberryman Oct 6 '13 at 20:44
If you want another solution to this problem, remember that what you're really calculating here is the sign of the derivative of the list. You could easily write a function that calculates the difference between successive elements, then just check the sign of the values. –  bheklilr Oct 6 '13 at 21:41

I’ll try to explain you some code while I develop it. The problem can obviously be split in two: Detecting the increasing part of the list, and the decreasing part of a list. The key idea of working with lists in Haskell is that you (if you don’t already have the empty list at hand) always look at the head of the list, and the tail, and you usually try to go through the list in that order.

So let us write a function that detect whether a list is non-strictly decreasing first. There are of course several ways, to do this. Let’s try a recursive approach that does without extra parameters. You already had a good start

``````dec :: [Int] -> Bool
dec [] = True
``````

now lets continue pattern matching. The next largest list that is not empty is the list with one element, which is obviously always decreasing:

``````dec [x] = True
``````

the next step is interesting. If we have a list with two elements (`x` and `y`) at the beginning (and possibly more) then for the list to de decreasing, clearly `x >= y` needs to hold, but also the remaining list, starting at `y`, needs to be decreasing. As that is sufficient, we just have to write it out

``````dec (x:y:rest) = x >= y && dec (y:res)
``````

And thats it!

Now to your exercise function, where can do the same thing. The only difference is once the list fails to be increasing, we allow check if the the list might be decreasing from this point on:

``````ex :: [Int] -> Bool
ex [] = True
ex [x] = True
ex (x:y:rest) = (x <= y && ex (y:res)) || dec (x:y:rest)
``````

I hope the explanation of how I came to write that code helps you with your next exercises. Also note that there are many other, also more efficient, ways to solve this.

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Thank you so much for the excellent explanation, it was really helpful! –  haskelllearner Oct 6 '13 at 21:23

Just for fun, I thought I'd throw together a solution with a very different flavor. Imagine for a moment that instead of a list of numbers, we had a string with an `L` when the numbers decreased, an `E` when they stayed the same, or a `G` when they got bigger. Then being triangular means testing whether that string is in the regular language `[LE]*[GE]*`. So that's what we'll do in this solution: write a regex and check whether the numbers' summary matches it. I'm using regex-applicative, but you can use your favorite regex library instead if you like.

``````{-# LANGUAGE NoMonomorphismRestriction #-}
import Data.Maybe
import Text.Regex.Applicative

triangular = many (sym LT <|> sym EQ) *> many (sym GT <|> sym EQ)
summarize xs = zipWith compare xs (tail xs)

ex = isJust . match triangular . summarize
``````

We can try it on all your examples in ghci:

``````*Main> map ex [[2,4,5,7,4,3], [], [1], [1, 2, 3], [3, 2, 1], [1, 2, 2], [2, 2, 1]]
[True,True,True,True,True,True,True]
*Main> ex [2,3,4,3,2,3,4] -- plus one I made up to check it's not const True
False
``````
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+1 for introducing me to regex-applicative. –  J. Abrahamson Oct 7 '13 at 0:09