I find that extending the list comprehension makes this easier to read:

```
[ m | n <- [1..5], m <- [2*n,3*n] ]
```

It might be helpful to examine exactly what this does, and how it relates to other solutions. Let's define it as a function:

```
mult lst = [ m | n <- lst, m <- [2*n,3*n] ]
```

After a fashion, this desugars to

```
mult' lst =
concatMap (\n -> concatMap (\m -> [m]) [2*n,3*n]) lst
```

The expression `concatMap (\m -> [m])`

is wrapping `m`

up in a list in order to immediately flatten it—it is equivalent to `map id`

.

Compare this to @FunctorSalad's answer:

```
mult1 lst = concatMap (\n -> [n*2,n*3]) lst
```

We've optimized away `concatMap (\m -> [m])`

.

Now @vili's answer:

```
mult2 lst = concat [ [(n*2),(n*3)] | n <- lst]
```

This desugars to:

```
mult2' lst = concat (concatMap (\n -> [[2*n,3*n]]) lst)
```

As in the first solution above, we are unnecessarily creating a list of lists that we have to `concat`

away.

I don't think there is a solution that uses list comprehensions, but desugars to `mult1`

. My intuition is that Haskell compilers are generally clever enough that this wouldn't matter (or, alternatively, that unnecessary `concat`

s are cheap due to lazy evaluation (whereas they're lethal in eager languages)).