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Update: I can't use any List.function stuff.

I'm new to OCaml and I'm learning this course in which I'm supposed to calculate a list of non decreasing values from a list of values.

So for e.g. I have a list [1; 2; 3; 1; 2; 7; 6]

So function mono that takes in a list returns the following:

# mono [1; 2; 3; 1; 2; 7; 6];;
- : int list = [1; 2; 3; 7]

I do the following:

let rec calculateCheck value lst = (
    match lst with
     [] -> true
    | x :: xs -> (
        if (value < x) then
            calculateCheck value xs

let rec reverse_list lst = (

    match lst with
     [] -> []
    | x :: xs -> (
        reverse_list xs @ [x]

let shouldReverse = ref 1;; 

let cancelReverse somelist lst = (
    shouldReverse := 0;
    reverse_list lst

let rec mono lst = (
    let somelist = ref lst in
        if (!shouldReverse = 1) then
            somelist := cancelReverse somelist lst
            somelist := lst;

    match !somelist with
     [] -> []
    | x :: xs -> (
        if (calculateCheck x xs) then
            [x] @ mono xs
            [] @ mono xs


  1. This only works once because of shouldReverse.
  2. I cannot reverse the value; mono list should return non decreasing list.


  1. Any easy way to do this?
  2. Specifically how to get a subset of the list. For e.g. for [1; 2; 3; 5; 6], I want [1; 2; 3] as an output for 5 so that I can solve this issue recursively. The other thing, is you can have a list as [1; 2; 3; 5; 6; 5]:: so for the second 5, the output should be [1; 2; 3; 5; 6].

Any ideas?


share|improve this question
For what it's worth, it's difficult to help because the problem statement isn't at all clear. It's easy to calculate a non-decreasing sublist of any list. The empty list is a non-decreasing list. Any list with just one element is a non-decreasing list. Most likely the requirement is much more specific than this. Are you supposed to find one of the (possibly several) longest non-decreasing sublists? –  Jeffrey Scofield Feb 10 '13 at 7:41
No. Actually, I could've made my self clearer. Sorry about that. What I effectively want is that to get a backlist. Say for example I need to remove duplicates in a list and only keep the first one. For e.g. for list [1;2;2;4;3;1;3;5], the answer should be: [1; 2; 4; 3; 5]. Consider the second 1 in the list above : there is no way for me to go back in the list and see if 1 exists. –  p0lAris Feb 10 '13 at 8:22
In this new (completely different?) example, if you just pass your partially computed result along to each recursive call, you don't need to go back in the original list. You can check your partial result to see if the value is already there. Passing your accumulated answer along to each call is a standard technique in FP. (In fact this is a good way to reverse a list, also.) –  Jeffrey Scofield Feb 10 '13 at 8:39

1 Answer 1

up vote 3 down vote accepted

A good way to approach this kind of problem is to force yourself to formulate what you're looking for formally, in a mathematically correct way. With some training, this will usually get you a description that is close to the final program you will write.

We are trying to define a function incr li that contains the a strictly increasing subsequence of li. As Jeffrey Scoffield asked, you may be looking for the longest such subsequence: this is an interesting and non-trivial algorithmic problem that is well-studied, but given that you're a beginner I suppose your teacher is asking for something simpler. Here is my suggestion of a simpler specification: you are looking for all the elements that are greater than all the elements before them in the list.

A good way to produce mathematical definitions that are easy to turn into algorithms is reasoning by induction: define a property on natural numbers P(n) in terms of the predecessor P(n-1), or define a property on a given list in terms of this property on a list of one less element. Consider you want to define incr [x1; x2; x3; x4]. You may express it either in terms of incr [x1; x2; x3] and x4, or in terms of x1 and incr [x2; x3; x4].

  • incr [x1;x2;x3;x4] is incr[x1;x2;x3], plus x4 if it is bigger than all the elements before it in the list, or, equivalently, the biggest element of incr[x1;x2;x3]

  • incr [x1;x2;x3;x4] is incr[x2;x3;x4] where all the elements smaller than x1 have been removed (they're not bigger than all elements before them), and x1 added

These two precise definitions can of course be generalized to lists of any length, and they give two different ways to write incr.

(* `incr1` defines `incr [x1;x2;x3;x4]` from `incr [x1;x2;x3]`,
   keeping as intermediate values `subli` that corresponds to
   `incr [x1;x2;x3]` in reverse order, and `biggest` the biggest
   value encountered so far. *)
let incr1 li =
  let rec incr subli biggest = function
    | [] -> List.rev subli
    | h::t ->
      if h > biggest
      then incr (h::subli) h t
      else incr subli biggest t
  match li with
    | [] -> []
    | h::t -> incr [h] h t

(* `incr2` defines `incr [x1;x2;x3;x4]` from `incr [x2;x3;x4]`; it
   needs no additional parameter as this is just a recursive call on
   the tail of the input list. *)
let rec incr2 = function
  | [] -> []
  | h::t ->
    (* to go from `incr [x2;x3;x4]` to `incr [x1;x2;x3;x4]`, one
       must remove all the elements of `incr [x2;x3;x4]` that are
       smaller than `x1`, then add `x1` to it *)
    let rec remove = function
      | [] -> []
      | h'::t ->
        if h >= h' then remove t
        else h'::t
    in h :: remove (incr2 t)
share|improve this answer
Thanks a lot gasche. I guess, I've under the philosophy behind this. I'm still not sure about a couple of things, but I think I'll be able to work them out. Thanks! –  p0lAris Feb 10 '13 at 13:55
@flippex17: thanks for your kind words. I must warn you that there is a pedagogical trap here: the reason why subli is passed to incr "in reverse order" in the first function will be obvious to practitioners (it is a classic instance of "passing accumulator arguments" that Jeffrey described), but you may find this troubling as a beginner. This is an idea that will become clear for more practice, but that I feel I failed to explain elegantly. –  gasche Feb 10 '13 at 14:04
Actually on further thoughts, I'm totally lost. Maybe it's sleep; I don't know. I get the idea of doing the passing my partially computer result to a recursive call but I'am not following the code. Sorry. –  p0lAris Feb 10 '13 at 14:48
@flippex17: well, it's probably the lack of sleep! I think the second version should be rather easier for beginners to understand, so maybe you should start there. –  gasche Feb 10 '13 at 14:58
There you go, @flippex17: updated with the complete code. –  gasche Feb 11 '13 at 5:54

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