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I have a sorted list of inputs:

let x = [2; 4; 6; 8; 8; 10; 12]
let y = [-8; -7; 2; 2; 3; 4; 4; 8; 8; 8;]

I want to write a function which behaves similar to an SQL INNER JOIN. In other words, I want to return the cartesian product of x and y which contains only items shared in both lists:

join(x, y) = [2; 2; 4; 4; 8; 8; 8; 8; 8; 8]

I've written a naive version as follows:

let join x y =
    [for x' in x do
        for y' in y do
            yield (x', y')]
    |> List.choose (fun (x, y) -> if x = y then Some x else None)

It works, but this runs in O(x.length * y.length). Since both my lists are sorted, I think its possible to get the results I want in O(min(x.length, y.length)).

How can I find common elements in two sorted lists in linear time?

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This is neither a join nor a cartesian product. Cartesian product of two lists of numbers would be a list of tuples of two numbers each. See – Pavel Minaev Sep 25 '09 at 20:10
For what its worth, the following returns a distinct list of elements shared between two lists: – Juliet Sep 25 '09 at 20:16
Oh, and if a proof exists to show that its not possible to generate the set I want in linear time or any faster than I already have, that works too :) – Juliet Sep 25 '09 at 20:24
What you want here would be an intersection of two lists (i.e. a list containing all items from either list that appear in both lists). – Pavel Minaev Sep 25 '09 at 20:52
The theoretical worst case complexity for any algorithm has to be O(x.length + y.length). O(min(x.length, y.length)) is the theoretical best case complexity; i.e. when the lists meet certain preconditions. – Stephen C Sep 26 '09 at 13:06

9 Answers 9

up vote 8 down vote accepted

O(min(n,m)) time is impossible: Take two lists [x;x;...;x;y] and [x;x;...;x;z]. You have to browse both lists till the end to compare y and z.

Even O(n+m) is impossible. Take [1,1,...,1] - n times and [1,1,...,1] - m times Then the resulting list should have n*m elements. You need at least O(n m) (correctly Omega(n m)) time do create such list.

Without cartesian product (simple merge), this is quite easy. Ocaml code (I don't know F#, should be reasonably close; compiled but not tested):

let rec merge a b = match (a,b) with
   ([], xs) -> xs
|  (xs, []) -> xs
|  (x::xs, y::ys) -> if x <= y then x::(merge xs (y::ys))
                else y::(merge (x::xs) (y::ys));;

(Edit: I was too late)

So your code in O(n m) is the best possible in worst case. However, IIUIC it performs always n*m operations, which is not optimal.

My approach would be

1) write a function

group : 'a list -> ('a * int) list

that counts the number of same elements:

group [1,1,1,1,1,2,2,3] == [(1,5);(2,2);(3,1)]

2) use it to merge both lists using similar code as before (there you can multiply those coefficients)

3) write a function

ungroup : ('a * int) list -> 'a list

and compose those three.

This has complexity O(n+m+x) where x is the length of resulting list. This is the best possible up to constant.

Edit: Here you go:

let group x =
  let rec group2 l m =
    match l with
    | [] -> []
    | a1::a2::r when a1 == a2 -> group2 (a2::r) (m+1)
    | x::r -> (x, m+1)::(group2 r 0)
  in group2 x 0;;

let rec merge a b = match (a,b) with
   ([], xs) -> []
|  (xs, []) -> []
|  ((x, xm)::xs, (y, ym)::ys) -> if x == y then (x, xm*ym)::(merge xs ys)
                           else  if x <  y then merge xs ((y, ym)::ys)
                                           else merge ((x, xm)::xs) ys;;

let rec ungroup a =
  match a with
    [] -> []
  | (x, 0)::l -> ungroup l
  | (x, m)::l -> x::(ungroup ((x,m-1)::l));;

let crossjoin x y = ungroup (merge (group x) (group y));;

# crossjoin [2; 4; 6; 8; 8; 10; 12] [-7; -8; 2; 2; 3; 4; 4; 8; 8; 8;];;
- : int list = [2; 2; 4; 4; 8; 8; 8; 8; 8; 8]
share|improve this answer
I cannot say about F#, but it is certainly not impossible in general. – RBarryYoung Sep 25 '09 at 20:36
Could you elaborate? You are aware these are lists, not arrays? – sdcvvc Sep 25 '09 at 20:40
Consider two lists containing identical elements, of length n and m, say. Then the inner join must return nm elements. How, then, can the worst case complexity be better than O(nm)? – Stephan202 Sep 25 '09 at 20:41
The question is worded wrongly. If you look at the expected output, this isn't join at all. It's an intersection of two lists (as in, no discarding of duplicate elements). – Pavel Minaev Sep 25 '09 at 20:43
Sorry, the above comment is wrong - this is indeed a cartesian product (in disguise), so your explanation as to why it is O(m*n) in worst case is absolutely correct. – Pavel Minaev Sep 25 '09 at 21:13

I can't help you with the F#, but the basic idea is to use two indices, one for each list. Choose the item in each list at the current index for that list. If the two items are the same value, then add that value to your result set and increment both indices. If the items have different values, increment just the index for the list containing the lesser of the two values. Repeat the comparison until one of your lists is empty and then return the result set.

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I think this approach might need some modification considering he wants a cartesian-product-style repetition of elements in the result set. – mquander Sep 25 '09 at 20:07
Easily modified though, whenever you find a match, find out the range of the matches in both lists, and produce the cartesian result, before moving on past the matches. – Lasse V. Karlsen Sep 25 '09 at 20:11
@mquander: she, not he ;) – Juliet Sep 25 '09 at 20:17
I was thinking sets, but you could adjust for lists. Simply keep a placeholder for an element where you find a match, go forward on one list as long as you keep finding matches, then back up and increment the other list forward one. Repeat this until all matches are consumed. – tvanfosson Sep 25 '09 at 20:35
...of course, in the worst case this is still O(n*m), but I don't think that can be helped. – tvanfosson Sep 25 '09 at 20:38

The following is also tail-recursive (so far as I can tell), but the output list is consequently reversed:

let rec merge xs ys acc =
    match (xs, ys) with
    | ((x :: xt), (y :: yt)) ->
        if x = y then
            let rec count_and_remove_leading zs acc =
                match zs with
                | z :: zt when z = x -> count_and_remove_leading zt (acc + 1)
                | _ -> (acc, zs)
            let rec replicate_and_prepend zs n =
                if n = 0 then
                    replicate_and_prepend (x :: zs) (n - 1)
            let xn, xt = count_and_remove_leading xs 0
            let yn, yt = count_and_remove_leading ys 0
            merge xt yt (replicate_and_prepend acc (xn * yn))
        else if x < y then
            merge xt ys acc
            merge xs yt acc
    | _ -> acc

let xs = [2; 4; 6; 8; 8; 10; 12]
let ys = [-7; -8; 2; 2; 3; 4; 4; 8; 8; 8;]
printf "%A" (merge xs ys [])


[8; 8; 8; 8; 8; 8; 4; 4; 2; 2]

Note that, as sdcvvc says in his answer, this is still O(x.length * y.length) in worst case, simply because the edge case of two lists of repeating identical elements would require the creation of x.length * y.length values in the output list, which is by itself inherently an O(m*n) operation.

share|improve this answer
@Pavel: beautiful code, but the result is wrong. I'm not looking for an intersection, I'm looking for a cartesian product, but constraining the output such that each x' = y' for each (x', y') in x*y. Note that there are 8 appears twice in the first list, three times in the second list, so it should appear 2*3=6 times in the output. – Juliet Sep 25 '09 at 21:06
Nevermind... and check the updated version. – Pavel Minaev Sep 25 '09 at 21:24

I don't know F#, however I suppose it has arrays and binary-search implementation over arrays(can be implemented also)

  1. choose smallest list
  2. copy it to array (for O(1) random access, if F# already gives you that, you can skip this step)
  3. go over big list and using binary search find in small array elements from big list,
  4. if found add it to result list

Complexity O(min + max*log min), where min = sizeof small list and max - sizeof(big list)

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I don't know F#, but I can provide a functional Haskell implementation, based on the algorithm outlined by tvanfosson (further specified by Lasse V. Karlsen).

import Data.List

join :: (Ord a) => [a] -> [a] -> [a]
join l r = gjoin (group l) (group r)
    gjoin [] _ = []
    gjoin _ [] = []
    gjoin l@(lh@(x:_):xs) r@(rh@(y:_):ys)
      | x == y    = replicate (length lh * length rh) x ++ gjoin xs ys
      | x < y     = gjoin xs r
      | otherwise = gjoin l ys

main :: IO ()
main = print $ join [2, 4, 6, 8, 8, 10, 12] [-7, -8, 2, 2, 3, 4, 4, 8, 8, 8]

This prints [2,2,4,4,8,8,8,8,8,8]. I case you're not familiar with Haskell, some references to the documentation:

share|improve this answer
This isn't tail recursive though, and ++ is itself O(n). – Pavel Minaev Sep 25 '09 at 21:02
The output of the algorithm is fundamentally is O(nm). Since ++ is used to concatenate the pieces which make up the output, its O(n) complexity does not increase the overall complexity. Furthermore, can you explain to me why you think this code is not tail recursive? It looks fine to me. – Stephan202 Sep 26 '09 at 6:47
gjoin calls itself recursively in a non-tail-call position (right side of ++). – Pavel Minaev Sep 26 '09 at 8:09
In the case x == y, the value of gjoin xs ys is not evaluated until the left-hand argument of ++ is completely evaluated. So where's the issue? – Stephan202 Sep 26 '09 at 8:38

I think it can be done simply by using hash tables. The hash tables store the frequencies of the elements in each list. These are then used to create a list where the frequency of each element e is frequency of e in X multiplied by the frequency of e in Y. This has a complexity of O(n+m).

(EDIT: Just noticed that this can be worst case O(n^2), after reading comments on other posts. Something very much like this has already been posted. Sorry for the duplicate. I'm keeping the post in case the code helps.)

I don't know F#, so I'm attaching Python code. I'm hoping the code is readable enough to be converted to F# easily.

def join(x,y):

    for elem in x:
    for elem in y:

    for elem in x_count:
    	if elem in y_count:
    		answer.extend( [elem]*(x_count[elem]*y_count[elem] ) )
    return answer

A=[2, 4, 6, 8, 8, 10, 12]
B=[-8, -7, 2, 2, 3, 4, 4, 8, 8, 8]
print join(A,B)
share|improve this answer

The problem with what he wants is that it obviously has to re-traverse the list.

In order to get 8,8,8 to show up twice, the function has to loop thru the second list a bit. Worst case scenario (two identical lists) will still yield O(x * y)

As a note, this is not utilizing external functions that loop on their own.

for (int i = 0; i < shorterList.Length; i++)
    if (shorterList[i] > longerList[longerList.Length - 1])
    for (int j = i; j < longerList.Length && longerList[j] <= shorterList[i]; j++)
        if (shorterList[i] == longerList[j])
share|improve this answer
No, it doesn't "obviously" have to re-traverse the list. You can just count the number of equal elements in both lists once you run into the first matching pair. – Pavel Minaev Sep 25 '09 at 21:00
Which means that you have to traverse the second list in order to find all the things that match with your currently selected element in the first list. Once you have all the matches, you move to the second element in the first list, and traverse a portion of the 2nd list again. – JustLoren Sep 25 '09 at 21:03
You don't have to traverse the entire second list - they are sorted. Well, okay, you will have to traverse the entire list if the input is two identical lists of all equal values, like [1;1;...1] - but then you still end up traversing both lists to the end once (to calculate the number of 1s), since after you do that, the remaining of both is an empty list. So it will still be O(min(m,n)). – Pavel Minaev Sep 25 '09 at 21:06
... er, sorry, O(max(m,n)). – Pavel Minaev Sep 25 '09 at 21:07
Hrm, so you're saying count the matches then do math? if 8 shows up in the first list twice, then the second list three times, do 2 * 3 and add the 8 to the list six times? – JustLoren Sep 25 '09 at 21:11

I think this is O(n) on the intersect/join code, though the full thing traverses each list twice:

// list unique elements and their multiplicity (also reverses sorting)
// e.g. pack y = [(8, 3); (4, 2); (3, 1); (2, 2); (-8, 1); (-7, 1)]
// we assume xs is ordered
let pack xs = Seq.fold (fun acc x ->
    match acc with
    | (y,ny) :: tl -> if y=x then (x,ny+1) :: tl else (x,1) :: acc
    | [] -> [(x,1)]) [] xs

let unpack px = [ for (x,nx) in px do for i in 1 .. nx do yield x ]

// for lists of (x,nx) and (y,ny), returns list of (x,nx*ny) when x=y
// assumes inputs are sorted descending (from pack function)
// and returns results sorted ascending
let intersect_mult xs ys =
    let rec aux rx ry acc =
        match (rx,ry) with
        | (x,nx)::xtl, (y,ny)::ytl -> 
            if x = y then aux xtl ytl ((x,nx*ny) :: acc)
            elif x < y then aux rx ytl acc
            else aux xtl ry acc
        | _,_ -> acc
    aux xs ys []

let inner_join x y = intersect_mult (pack x) (pack y) |> unpack

Now we test it on your sample data

let x = [2; 4; 6; 8; 8; 10; 12]
let y = [-7; -8; 2; 2; 3; 4; 4; 8; 8; 8;]

> inner_join x y;;
val it : int list = [2; 2; 4; 4; 8; 8; 8; 8; 8; 8]

EDIT: I just realized this is the same idea as the earlier answer by sdcvvc (after the edit).

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You can't get O(min(x.length, y.length)), because the output may be greater than that. Supppose all elements of x and y are equal, for instance. Then the output size is the product of the size of x and y, which gives a lower bound to the efficiency of the algorithm.

Here's the algorithm in F#. It is not tail-recursive, which can be easily fixed. The trick is doing mutual recursion. Also note that I may invert the order of the list given to prod to avoid unnecessary work.

let rec prod xs ys = 
    match xs with
    | [] -> []
    | z :: zs -> reps xs ys ys
and reps xs ys zs =
    match zs with
    | [] -> []
    | w :: ws -> if  xs.Head = w then w :: reps xs ys ws
                 else if xs.Head > w then reps xs ys ws
                 else match ys with
                      | [] -> []
                      | y :: yss -> if y < xs.Head then prod ys xs.Tail else prod xs.Tail ys

The original algorithm in Scala:

def prod(x: List[Int], y: List[Int]): List[Int] = x match {
  case Nil => Nil
  case z :: zs => reps(x, y, y)

def reps(x: List[Int], y: List[Int], z: List[Int]): List[Int] = z match {
  case w :: ws if x.head == w => w :: reps(x, y, ws)
  case w :: ws if x.head > w => reps(x, y, ws)
  case _ => y match {
    case Nil => Nil
    case y1 :: ys if y1 < x.head => prod(y, x.tail)
    case _ => prod(x.tail, y)
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