How can I generate all the possible nondecreasing sets of the elements of a list with current length?

getSets :: [Int] -> Int -> [[Int]]

> getSets [0..9] 3

Let's start a bit simpler, with a function that produces all sets of the given size from the given list elements:

getAllSets :: [Int] -> Int -> [[Int]]
getAllSets _  0 = [[]]
getAllSets xs n = [(x:ys) | x <- xs, ys <- getAllSets xs (n-1)]

You can think of this function as building the sets one element at a time. It adds x onto the front of each shorter set ys, and it does this for as many elements as there are in xs.

What we can do to get the final answer is decide to not build a longer set for each element in xs, but only for those x that are less than or equal to every element in ys:

getSets :: [Int] -> Int -> [[Int]]
getSets _  0 = [[]]
getSets xs n = [(x:ys) | x <- xs, ys <- getSets xs (n-1), all (x <=) ys]

This is a nice-looking solution, but it does more work than we actually need. After all, why compare x against every element in ys? We know that ys is already in the right order because we've built it that way recursively, so let's just make sure x is less than or equal to the first element of ys, if there is one:

getSets' :: [Int] -> Int -> [[Int]]
getSets' _  0 = [[]]
getSets' xs n = [(x:ys) | x <- xs, 
                          ys <- getSets' xs (n-1), 
                          null ys || x <= head ys]

Update: In addition to incorporating Thomas M. DuBuisson's much cleaner predicate, I also benchmarked his, chrisdb's, and my solutions: http://hpaste.org/50195

Update x2: Fixed incorrect Criterion labels; benchmarks were correct but the output was confusing.

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    I wonder which of our solutions is faster.... I suspect there's not much between them. You might be doing more comparisons because you don't presort the list, but those should be very cheap for Ints. – chrisdb Aug 11 '11 at 21:42
  • @pelotom: that would be a bit off from the specification of the problem, since even when xs is sorted, the first element might be taken from the end, and the second might be taken from the beginning, for example. – acfoltzer Aug 11 '11 at 21:42
  • @acfoltzer - oops, I removed my comment a few seconds after posting because I realized it didn't work :) – Tom Crockett Aug 11 '11 at 21:49
  • Nice explanation – ДМИТРИЙ МАЛИКОВ Aug 11 '11 at 21:51
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    The ltOrNull can be more concisely (and readably) written as null ys || x <= head ys, thus eliminating the function and just inlining the expression (notice the head there is perfectly safe). – Thomas M. DuBuisson Aug 11 '11 at 22:05
getSets s n = filter nonDec $ replicateM n s
  where nonDec xs = and $ zipWith (>=) (drop 1 xs) xs

Here is a clean version that should also be rather fast (i.e. it only constructs correct lists and doesn't construct then drop incorrect lists).

import Data.List

getSets _ 0 = [[]]
getSets xs n = do
        a <- xs
        rest <- getSets (filter (>= a) xs) (n - 1)
        return (a : rest)

EDIT: But it's slower than ACF's - using filter is expensive and ACF has intelligently built his lists so a "bad" list will be discovered after adding only one more element for very cheap. Very nice now that I recognize that.

  • Btw, this solution works faster, than @acfoltzer's one. – ДМИТРИЙ МАЛИКОВ Aug 11 '11 at 22:04
  • @garm0nboz1a How did you determine that? That was my suspicion when I made it but a Criterion benchmark has made me see otherwise. – Thomas M. DuBuisson Aug 11 '11 at 22:07
  • length $ getSets' [0..9] 8 runs 18secs, and length $ getSets [0..9] 8 only 0.5 secs – ДМИТРИЙ МАЛИКОВ Aug 11 '11 at 22:21

Does this do what you want?

import Data.List

getSets :: [Int] -> Int -> [[Int]]

getSets xs n
    | n > 0     = getSets' (sort xs) n
    | otherwise = []

getSets' _ 0          = [[]]
getSets' [] _         = [] 
getSets' xs@(x:xss) n = map (x:) (getSets' xs (n-1)) ++ getSets' xss n 
  • 1
    It works, but looks terrible :G – ДМИТРИЙ МАЛИКОВ Aug 11 '11 at 21:32
  • Part of that is because I wanted to check positive n and sort just once before constructing the list. IMO this is better than repeated filtering and the n >= 0 test needs to be done to make the function well behaved. But I agree that the last line is a bit ugly, and something using the List monad on a list comprehension like the others have done might be a bit prettier – chrisdb Aug 11 '11 at 21:56

Maybe this? For a list x = [a1, ..., an], nondec k x returns list of all subsequences [ai1, ai2, ..., aik] of length k with i1 <= i2 <= ... <= ik.

import Data.List

nondec 0 _ = return []
nondec n x = do (a,y) <- zip x (tails x)
                map (a:) $ nondec (n-1) y

x = nondec 3 [0..9]

I've done some timings for the [0..9] 3 case, and I get:

benchmarking subsets/chrisdb
mean: 193.2204 us, lb 193.0333 us, ub 193.4622 us, ci 0.950
std dev: 1.076765 us, lb 865.2091 ns, ub 1.456463 us, ci 0.950

benchmarking subsets/acfoltzer
mean: 218.5110 us, lb 218.2996 us, ub 218.8322 us, ci 0.950
std dev: 1.309867 us, lb 951.4661 ns, ub 1.793697 us, ci 0.950

benchmarking subsets/TMD
mean: 198.9438 us, lb 194.3482 us, ub 206.6694 us, ci 0.950
std dev: 29.88779 us, lb 20.14344 us, ub 41.98061 us, ci 0.950

I excluded the solution of sdcwc because I don't think it solves the problem. In particular, if the initial list is not sorted then it won't produce non-decreasing sub-lists. As you can see, there's not a huge difference but the solutions of Thomas M. DuBuisson and myself are slightly faster on average.

  • How do those results scale with larger inputs? I got fairly different results with [0..20] 5 – acfoltzer Aug 11 '11 at 22:36
  • Also, now that I think of it, this should probably be edited into the original answer rather than being separate. – acfoltzer Aug 11 '11 at 22:39
  • I reproduce your results for the [0..20] 5 case more or less – chrisdb Aug 11 '11 at 22:42

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