# Cartesian product of 2 lists in Haskell

I wish to produce the Cartesian product of 2 lists in Haskell, but I cannot work out how to do it. The cartesian product gives all combinations of the list elements:

``````xs = [1,2,3]
ys = [4,5,6]

cartProd :: [a] -> [b] -> [(a,b)]
cartProd xs ys ==> [(1,4),(1,5),(1,6),(2,4),(2,5),(2,6),(3,4),(3,5),(3,6)]
``````

This is not an actual homework question and is not related to any such question, but the way in which this problem is solved may help with one I am stuck on.

This is very easy with list comprehensions. To get the cartesian product of the lists `xs` and `ys`, we just need to take the tuple `(x,y)` for each element `x` in `xs` and each element `y` in `ys`.

This gives us the following list comprehension:

``````cartProd xs ys = [(x,y) | x <- xs, y <- ys]
``````
• Thanks, so simple yet elegant, really helped with the other problem :) Nov 8, 2010 at 9:20
• Good also for Erlang, thanks. Little changing in syntax: cartProd(Xs, Ys) -> [{X,Y} || X <- Xs, Y <- Ys]. Oct 31, 2011 at 11:18

As other answers have noted, using a list comprehension is the most natural way to do this in Haskell.

If you're learning Haskell and want to work on developing intuitions about type classes like `Monad`, however, it's a fun exercise to figure out why this slightly shorter definition is equivalent:

``````import Control.Monad (liftM2)

cartProd :: [a] -> [b] -> [(a, b)]
cartProd = liftM2 (,)
``````

You probably wouldn't ever want to write this in real code, but the basic idea is something you'll see in Haskell all the time: we're using `liftM2` to lift the non-monadic function `(,)` into a monad—in this case specifically the list monad.

If this doesn't make any sense or isn't useful, forget it—it's just another way to look at the problem.

• Probably a good idea to learn what monads actually do first :P Nov 7, 2010 at 22:02
• As a footnote (three years later): I'd guess now that I originally used the monadic `liftM2` here for the sake of clarity (more people have heard about monads than applicative functors?), but all you need is the applicative functor instance for lists, so `liftA2` will work equivalently. Sep 19, 2013 at 12:27

If your input lists are of the same type, you can get the cartesian product of an arbitrary number of lists using `sequence` (using the `List` monad). This will get you a list of lists instead of a list of tuples:

``````> sequence [[1,2,3],[4,5,6]]
[[1,4],[1,5],[1,6],[2,4],[2,5],[2,6],[3,4],[3,5],[3,6]]
``````

There is a very elegant way to do this with Applicative Functors:

``````import Control.Applicative

(,) <\$> [1,2,3] <*> [4,5,6]
-- [(1,4),(1,5),(1,6),(2,4),(2,5),(2,6),(3,4),(3,5),(3,6)]
``````

The basic idea is to apply a function on "wrapped" arguments, e.g.

``````(+) <\$> (Just 4) <*> (Just 10)
-- Just 14
``````

In case of lists, the function will be applied to all combinations, so all you have to do is to "tuple" them with `(,)`.

See http://learnyouahaskell.com/functors-applicative-functors-and-monoids#applicative-functors or (more theoretical) http://www.soi.city.ac.uk/~ross/papers/Applicative.pdf for details.

• Pretty cool that you can actually expand the tuple as needed: (,,) <\$> [1..3] <*> [4..6] <*> [7..9] Aug 3, 2016 at 5:52

Other answers assume that the two input lists are finite. Frequently, idiomatic Haskell code includes infinite lists, and so it is worthwhile commenting briefly on how to produce an infinite Cartesian product in case that is needed.

The standard approach is to use diagonalization; writing the one input along the top and the other input along the left, we could write a two-dimensional table that contained the full Cartesian product like this:

``````   1  2  3  4 ...
a a1 a2 a3 a4 ...
b b1 b2 b3 b4 ...
c c1 c2 c3 c4 ...
d d1 d2 d3 d4 ...

.  .  .  .  . .
.  .  .  .  .  .
.  .  .  .  .   .
``````

Of course, working across any single row will give us infinitely elements before it reaches the next row; similarly going column-wise would be disastrous. But we can go along diagonals that go down and to the left, starting again in a bit farther to the right each time we reach the edge of the grid.

``````a1

a2
b1

a3
b2
c1

a4
b3
c2
d1
``````

...and so on. In order, this would give us:

``````a1 a2 b1 a3 b2 c1 a4 b3 c2 d1 ...
``````

To code this in Haskell, we can first write the version that produces the two-dimensional table:

``````cartesian2d :: [a] -> [b] -> [[(a, b)]]
cartesian2d as bs = [[(a, b) | a <- as] | b <- bs]
``````

An inefficient method of diagonalizing is to then iterate first along diagonals and then along depth of each diagonal, pulling out the appropriate element each time. For simplicity of explanation, I'll assume that both the input lists are infinite, so we don't have to mess around with bounds checking.

``````diagonalBad :: [[a]] -> [a]
[ xs !! row !! col
| diagonal <- [0..]
, depth <- [0..diagonal]
, let row = depth
col = diagonal - depth
]
``````

This implementation is a bit unfortunate: the repeated list indexing operation `!!` gets more and more expensive as we go, giving quite a bad asymptotic performance. A more efficient implementation will take the above idea but implement it using zippers. So, we'll divide our infinite grid into three shapes like this:

``````a1 a2 / a3 a4 ...
/
/
b1 / b2 b3 b4 ...
/
/
/
c1 c2 c3 c4 ...
---------------------------------
d1 d2 d3 d4 ...

.  .  .  . .
.  .  .  .  .
.  .  .  .   .
``````

The top left triangle will be the bits we've already emitted; the top right quadrilateral will be rows that have been partially emitted but will still contribute to the result; and the bottom rectangle will be rows that we have not yet started emitting. To begin with, the upper triangle and upper quadrilateral will be empty, and the bottom rectangle will be the entire grid. On each step, we can emit the first element of each row in the upper quadrilateral (essentially moving the slanted line over by one), then add one new row from the bottom rectangle to the upper quadrilateral (essentially moving the horizontal line down by one).

``````diagonal :: [[a]] -> [a]
diagonal = go [] where
go upper lower = [h | h:_ <- upper] ++ case lower of
[]         -> concat (transpose upper')
row:lower' -> go (row:upper') lower'
where upper' = [t | _:t <- upper]
``````

Although this looks a bit more complicated, it is significantly more efficient. It also handles the bounds checking that we punted on in the simpler version.

But you shouldn't write all this code yourself, of course! Instead, you should use the universe package. In `Data.Universe.Helpers`, there is `(+*+)`, which packages together the above `cartesian2d` and `diagonal` functions to give just the Cartesian product operation:

``````Data.Universe.Helpers> "abcd" +*+ [1..4]
[('a',1),('a',2),('b',1),('a',3),('b',2),('c',1),('a',4),('b',3),('c',2),('d',1),('b',4),('c',3),('d',2),('c',4),('d',3),('d',4)]
``````

You can also see the diagonals themselves if that structure becomes useful:

``````Data.Universe.Helpers> mapM_ print . diagonals \$ cartesian2d "abcd" [1..4]
[('a',1)]
[('a',2),('b',1)]
[('a',3),('b',2),('c',1)]
[('a',4),('b',3),('c',2),('d',1)]
[('b',4),('c',3),('d',2)]
[('c',4),('d',3)]
[('d',4)]
``````

If you have many lists to product together, iterating `(+*+)` can unfairly bias certain lists; you can use `choices :: [[a]] -> [[a]]` for your n-dimensional Cartesian product needs.

• I just installed Universe-1.1 and It is fabulous. Thank you so very much. Yeah, your name is all over it so we know to trust it. The value is uncalculable. I was doing diagonals and these initial results look spot-on. Cartesian products are a pain but you are a pain killer. Thank you again. May 10, 2019 at 22:47
• @fp_mora Glad to hear you're enjoying it! May 10, 2019 at 23:16
• @Daniel Wagner It is a godsend. I was not clear. It's the infinite lists that are a pain. You handle them adroitly. May 10, 2019 at 23:30

Yet another way to accomplish this is using applicatives:

``````import Control.Applicative

cartProd :: [a] -> [b] -> [(a,b)]
cartProd xs ys = (,) <\$> xs <*> ys
``````

Yet another way, using the `do` notation:

``````cartProd :: [a] -> [b] -> [(a,b)]
cartProd xs ys = do x <- xs
y <- ys
return (x,y)
``````

The right way is using list comprehensions, as other people have already pointed out, but if you wanted to do it without using list comprehensions for any reason, then you could do this:

``````cartProd :: [a] -> [b] -> [(a,b)]
cartProd xs [] = []
cartProd [] ys = []
cartProd (x:xs) ys = map (\y -> (x,y)) ys ++ cartProd xs ys
``````
• An easier way without list comprehensions is `cartProd xs ys = xs >>= \x -> ys >>= \y -> [(x,y)]` Nov 7, 2010 at 21:53
• Instead of `map (\y -> (x,y))` you can write `map ((,) x)`.
– Yitz
Nov 8, 2010 at 9:19
• @Chuck: Nice :) It's been a while for me Haskell-wise, which is why I err on the side of simplistic solutions... Nov 8, 2010 at 12:16
• @Yitz: Yup, good call. I'd forgotten about that (see above on the "it's been a while")... Nov 8, 2010 at 12:17
• @Stuart List comprehensions may be the "right way" but is there really any downside to doing it this way? Seems fine to me, and it helps a beginner wrap their minds around a simple implementation of cartesian products. +1 Aug 3, 2016 at 5:35

Well, one very easy way to do this would be with list comprehensions:

``````cartProd :: [a] -> [b] -> [(a, b)]
cartProd xs ys = [(x, y) | x <- xs, y <- ys]
``````

Which I suppose is how I would do this, although I'm not a Haskell expert (by any means).

something like:

``````cartProd x y = [(a,b) | a <- x, b <- y]
``````

It's a job for `sequence`ing. A monadic implementation of it could be:

``````cartesian :: [[a]] -> [[a]]
cartesian [] = return []
cartesian (x:xs) = x >>= \x' -> cartesian xs >>= \xs' -> return (x':xs')

*Main> cartesian [[1,2,3],[4,5,6]]
[[1,4],[1,5],[1,6],[2,4],[2,5],[2,6],[3,4],[3,5],[3,6]]
``````

As you may notice, the above resembles the implementation of `map` by pure functions but in monadic type. Accordingly you can simplify it down to

``````cartesian :: [[a]] -> [[a]]
cartesian = mapM id

*Main> cartesian [[1,2,3],[4,5,6]]
[[1,4],[1,5],[1,6],[2,4],[2,5],[2,6],[3,4],[3,5],[3,6]]
``````

Just adding one more way for the enthusiast, using only recursive pattern matching.

``````cartProd :: [a]->[b]->[(a,b)]
cartProd _ []=[]
cartProd [] _ = []
cartProd (x:xs) (y:ys) = [(x,y)] ++ cartProd [x] ys  ++ cartProd xs ys ++  cartProd xs [y]
``````

Here is my implementation of n-ary cartesian product:

``````crossProduct :: [[a]] -> [[a]]
crossProduct (axis:[]) = [ [v] | v <- axis ]
crossProduct (axis:rest) = [ v:r | v <- axis, r <- crossProduct rest ]
``````
• How about `crossProduct = sequence`? Apr 19, 2016 at 6:42
• What if the list is empty? I'm guessing you identified the wrong base case here. Oct 24, 2017 at 2:53

Recursive pattern matching with out List comprehension

``````crossProduct [] b=[]
crossProduct (x : xs) b= [(x,b)] ++ crossProduct xs b

cartProd _ []=[]
cartProd x (u:uv) = crossProduct x u ++ cartProd x uv
``````
• Code only answers are discouraged. Please add some explanation as to how this solves the problem, or how this differs from the existing answers. From Review
– Nick
Nov 17, 2019 at 2:43

If all you want is the Cartesian product, any of the above answers will do. Usually, though, the Cartesian product is a means to an end. Usually, this means binding the elements of the tuple to some variables, `x` and `y`, then calling some function `f x y` on them. If this is the plan anyway, you might be better off just going full monad:

``````do
x <- [1, 2]
y <- [6, 8, 10]
pure \$ f x y
``````

This will produce the list `[f 1 6, f 1 8, f 1 10, f 2 6, f 2 8, f 2 10]`.