# How can I multiply the elements of a list by all the other elements?

For example, `list = [1,2,3,4]`. `listProduct list` returns `[1,2,3,4,6,8,9,12,16]` i.e `[(1*1),(1*2),(1*3),(1*4),(2*3),(2*4),(3*3),(3*4),(4*4)]`

I remember seeing that there was something that did this, but I can't find that resource any more.

-
Why does your example not include `2*2` in the result? Perhaps you don't want duplicates. But then why does your example not include `3*3` in the result? –  dave4420 Jan 23 '12 at 6:52
THat was a typo, thanks! It's updated now –  ryanmehta Jan 24 '12 at 1:05

Why does your example not include `2*2` in the result?

If it's because it's the same as `1*4` --- that is, you don't want duplicates --- then

``````listProduct xs = nub [x * y | x <- xs, y <- xs]
``````

On the other hand, if you do want duplicates --- if you want to multiply each number by each subsequent number in the list, and include duplicates in the result --- then

``````listProduct' xs = triangularAutoZipWith (*)

triangularAutoZipWith op = concatMap f . tails
where f [] = []
f xs @ (x : _) = map (op x) xs
``````

You could use `triangularAutoZipWith` in a more efficient version of the first solution:

``````listProduct = nub . triangularAutoZipWith (*)
``````
-
Thanks. I kind of wanted to avoid using nub. It seems like nub has some serious performance repercussions. Though this does work. –  ryanmehta Jan 24 '12 at 1:49

You can write this in a simple manner using a list comprehension:

``````listProduct xs = [x * y | x <- xs, y <- xs]
``````

However, it's more idiomatic to use the list monad:

``````import Control.Monad

listProduct = join \$ liftM2 (*)
``````

(equivalent to `listProduct xs = liftM2 (*) xs xs`)

To understand this version, you can think of `liftM2` as a kind of generalised Cartesian product (`liftM2 (,)` is the Cartesian product itself). It's easier to see how this works if you specialise `liftM2`'s definition to the list monad:

``````liftM2 f mx my = do { x <- mx; y <- my; return (f x y) }
-- expand the do notation
liftM2 f mx my = mx >>= (\x -> my >>= (\y -> return (f x y)))
-- substitute the list monad's definition of (>>=)
liftM2 f mx my = concatMap (\x -> concatMap (\y -> [f x y]) my) mx
-- simplify
liftM2 f mx my = concatMap (\x -> map (\y -> f x y) my) mx
-- simplify again
liftM2 f mx my = concatMap (\x -> map (f x) my) mx
``````

So the monadic definition of `listProduct` expands to:

``````listProduct xs = concatMap (\x -> map (x *) xs) xs
``````

(Note that you don't technically need the full list monad here; all that's required is the `Applicative` instance for lists, and `listProduct = join \$ liftA2 (*)` would work just as well. However, it's easier to show how it works with the monadic definition, since the `Applicative` instance for lists is defined in terms of the `Monad` instance.)

-

Using...

``````import Control.Applicative
``````

... with duplicates ...

``````listProduct list = (*) <\$> list <*> list
``````

... and without...

``````listProduct list = concat (mul <\$> list <*> list) where
mul a b | a <= b = [a*b]
| otherwise = []
``````

If you are in rube-goldberg-mood, you could use...

``````listProduct list = concat \$ zipWith (map.(*)) list (map ((`filter` list).(<=)) list)
``````

... or simply ...

``````import Data.List

listProduct list = concat \$ zipWith (map.(*)) list \$ tails list
``````

Another way would be using `sequence`. With duplicates:

``````listProduct = map product . sequence . replicate 2
``````

Without:

``````listProduct = map product . filter(\[a,b] -> a <= b) . sequence . replicate 2
``````
-

Well, you've already got a few answers, but I'm going to toss in mine because I think the earlier ones, while all accurate, may be insufficiently helpful.

The easiest solution you've gotten for a beginner to understand is the list comprehension:

``````example1 = [ x*y | x <- list, y <- list ]
``````

This syntax exists in some popular languages like Python, and should be easy to understand in any case: "the list whose elements are the results of `x*y` where `x` is an element of `list` and `y` is an element of `list`." You can also add conditions into list comprehensions to filter out some combinations, e.g., if you don't want products where `x == y`:

``````example2 = [ x*y | x <- list, y <- list, x /= y ]
``````

The more complex answers have to do with the fact that list comprehensions are equivalent to the List Monad; the implementation of the standard `Monad` typeclass for the list type. This means that `example1` can also be implemented in these ways:

``````example1' = do x <- list
y <- list
return (x*y)
``````

The `do`-notation is just syntax sugar for this:

``````example1'' = list >>= (\x -> list >>= (\y -> return (x*y)))
``````

Landei's answer is based on the fact that if you're not using any conditions in your list comprehension, just Cartesian products, you can get away with using the `Applicative` type class, which is weaker than `Monad`.

-