# haskell infinite list of incrementing pairs

Create an infinite list pairs :: [(Integer, Integer)] containing pairs of the form (m,n), where each of m and n is a member of [0 ..]. An additional requirement is that if (m,n) is a legit member of the list, then (elem (m,n) pairs) should return True in finite time. An implementation of pairs that violates this requirement is considered a non- solution. *Fresh edit Thank you for the comments, Lets see if I can make some progress*

``````    pairs :: [(Integer, Integer)]
pairs = [(m,n) | t <- [0..], m <- [0..], n <-[0..], m+n == t]
``````

Something like this? I just don't know where it's going to return True in finite time.

I feel the way the question is worded elem doesn't have to be part of my answer. Just if you call (elem (m,n) pairs) it should return true. Sound right?

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Hint: Generate them one diagonal at a time. Set `t = x + y` and generate all pairs `(x, y)` for each `t` in `[0..]`. Since there are only a finite number of pairs for each `t`, this will satsify the requirements. –  hammar Mar 23 '13 at 6:32
I like this method. Except i'm not sure how to implement it. –  john stamos Mar 23 '13 at 6:46
Instead of filtering, generate only the possible values for `m` and `n`. For a fixed `t`, what is the highest value `m` can have? Once you've picked a `t` and `m`, you can use `t = m + n` to calculate `n` directly. –  hammar Mar 23 '13 at 7:43
Are you sure you're explaining the problem correctly? What is the list `(m,n)` meant to hold? Perhaps the problem is to generate all `(m,n)` pairs where `m` and `n` satisfy `helper m n == True` (i.e., you know what `helper` is when you make the list)? –  Andrew Jaffe Mar 23 '13 at 7:56
In your last revision, the question didn't make any sense anymore (as pretty much everything had been removed). I rolled it back; not sure what your intention was there (if you indeed wanted to say "this here is done, no more answers please" then don't modify your question but just accept the most helpful answer). –  leftaroundabout Mar 23 '13 at 10:52

Ignoring the `helper` method, the list comprehension you have will list out all pairs but the order of elements is a problem. You'll have a infinitely many pairs like `(0, m)` which are followed by infinitely many pairs like `(1, m)`. Of course `elem` will forever iterate all the `(0, m)` pairs never reaching `(1, m)` or `(2, m)` etc.

I'm not sure why you have the `helper` method -- with it, you are only building a list of pairs like `[(0,0), (1,1), (2,2), ...]` because you've filtered on `m = n`. Was that part of the requirements?

Like @hammar suggested, start with `0 = m + n` and list out the pairs (m, n). Then list pairs (m, n) where `1 = m + n`. Then your list will look like `[(0,0), (0,1), (1,0), (0,2), (1,1), (2,0), ...]`.

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The only requirements are specified. I don't think I need it. How do I implement a list that does this??? using list comp and having 't' go up in step holding m and n back as they increment? –  john stamos Mar 23 '13 at 7:04
Yes, you'll most likely have `[(m,_) | t <- [0..], m <- _]`. Try starting with that and see if you can fill in the blanks. –  kputnam Mar 23 '13 at 7:17
Tried it out, Concerned on the True value. –  john stamos Mar 23 '13 at 7:28

The helper function ensures that pairs is a list of the form `[ (0,0) , (1,1) , (2,2) ... ]`.

So `elem ( m , n )` pairs can be implemented as:

``````elem (m , n) _ |  m == n    = True
|  otherwise = False
``````

This is a constant time implementation.

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What is the underscores function here? I'll update my code now. –  john stamos Mar 23 '13 at 6:39
@johnstamos: It's a wildcard pattern which doesn't bind the second argument of `elem` to a name. This is because this implementation doesn't actually need to see the list to check membership. –  kputnam Mar 23 '13 at 6:41
You can eliminate the guard in the pattern match here: `elem (m, n) _ = m == n` would suffice. –  kputnam Mar 23 '13 at 6:42
Is that still part of helper though? –  john stamos Mar 23 '13 at 6:43
If this is a homework assignment, I would assume you aren't allowed to provide your own definition of `elem`. Instead, you're probably supposed to write `pairs` to satisfy the requirements using the `elem` from Prelude. –  kputnam Mar 23 '13 at 6:47

I first posted

``````Prelude> let pairs = [(m, n) | t <- [0..]
, let m = head \$ take 1 \$ drop t [0..]
, let n = head \$ take 1 \$ drop (t + 1) [0..]]
``````

Which, I believed answered the three conditions set by the professor. But hammar pointed out that if I chose this list as an answer, that is, the list of pairs of the form (t, t+1), then I might as well choose the list

``````repeat [(0,0)]
``````

Well, both of these do seem to answer the professor's question, considering there seems to be no mention of the list having to contain all combinations of [0..] and [0..].

That aside, hammer helped me see how you can list all combinations, facilitating the evaluation of elem in finite time by building the infinite list from finite lists. Here are two other finite lists - less succinct than Hammar's suggestion of the diagonals - that seem to build all combinations of [0..] and [0..]:

``````edges = concat [concat [[(m,n),(n,m)] | let m = t, n <- take m [0..]] ++ [(t,t)]
| t <- [0..]]

*Main> take 9 edges
[(0,0),(1,0),(0,1),(1,1),(2,0),(0,2),(2,1),(1,2),(2,2)]
``````

which construct the edges (t, 0..t) (0..t, t), and

``````oddSpirals size = concat [spiral m size' | m <- n] where
size' = if size < 3 then 3 else if even size then size - 1 else size
n = map (\y -> (fst y * size' + div size' 2, snd y * size' + div size' 2))
[(x, t-x) | let size' = 5, t <- [0..], x <- [0..t]]
spiral seed size = spiral' (size - 1) "-" 1 [seed]
spiral' limit op count result
| count == limit =
let op' = if op == "-" then (-) else (+)
m = foldl (\a b -> a ++ [(op' (fst \$ last a) b, snd \$ last a)]) result (replicate count 1)
nextOp = if op == "-" then "+" else "-"
nextOp' = if op == "-" then (+) else (-)
n = foldl (\a b -> a ++ [(fst \$ last a, nextOp' (snd \$ last a) b)]) m (replicate count 1)
n' = foldl (\a b -> a ++ [(nextOp' (fst \$ last a) b, snd \$ last a)]) n (replicate count 1)
in n'
| otherwise      =
let op' = if op == "-" then (-) else (+)
m = foldl (\a b -> a ++ [(op' (fst \$ last a) b, snd \$ last a)]) result (replicate count 1)
nextOp = if op == "-" then "+" else "-"
nextOp' = if op == "-" then (+) else (-)
n = foldl (\a b -> a ++ [(fst \$ last a, nextOp' (snd \$ last a) b)]) m (replicate count 1)
in spiral' limit nextOp (count + 1) n

*Main> take 9 \$ oddSpirals 3
[(1,1),(0,1),(0,2),(1,2),(2,2),(2,1),(2,0),(1,0),(0,0)]
``````

which build clockwise spirals of length 'size' squared, superimposed on hammar's diagonals algorithm.

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This only generates pairs of the form `(t, t+1)`. –  hammar Mar 23 '13 at 12:59
@hammar How is that not answering the professor's question? –  גלעד ברקן Mar 23 '13 at 13:00
The problem is to generate all pairs of natural numbers, such that for any given pair it is found at some finite index in the list. –  hammar Mar 23 '13 at 13:01
@hammar I believe I answered the three conditions: (1) infinite list pairs :: [(Integer, Integer)], (2) containing pairs of the form (m,n), where each of m and n is a member of [0 ..], and (3) elem (m,n) pairs) should return True in finite time. Did I not? –  גלעד ברקן Mar 23 '13 at 13:03
Since it's clearly homework, I've been trying to avoid giving the solution, but here it is: `[(x, t-x) | t <- [0..], x <- [0..t]]`. –  hammar Mar 23 '13 at 13:15