First I'd simplify the syntax of the body a bit:

```
def foldMap[A, B](as: List[A], m: Monoid[B])(f: A => B): B =
as.map(f).foldLeft(m.zero)(m.ops)
```

Then I'd move the monoid instance into its own implicit parameter list:

```
def foldMap[A, B](as: List[A])(f: A => B)(implicit m: Monoid[B]): B =
as.map(f).foldLeft(m.zero)(m.ops)
```

See the original "Type Classes as Objects and Implicits" paper for more detail about how Scala implements type classes using implicit parameter resolution, or this answer by Rex Kerr that I've also linked above.

Next I'd switch the order of the other two parameter lists:

```
def foldMap[A, B](f: A => B)(as: List[A])(implicit m: Monoid[B]): B =
as.map(f).foldLeft(m.zero)(m.ops)
```

In general you want to place the parameter lists containing parameters that change the least often first, in order to make partial application more useful. In this case there may only be one possible useful value of `A => B`

for any `A`

and `B`

, but there are lots of values of `List[A]`

.

For example, switching the order allows us to write the following (which assumes a monoid instance for `Bar`

):

```
val fooSum: List[Foo] => Bar = foldMap(fooToBar)
```

Finally, as a performance optimization (mentioned by stew above), you could avoid creating an intermediate list by moving the application of `f`

into the fold:

```
def foldMap[A, B](f: A => B)(as: List[A])(implicit m: Monoid[B]): B =
as.foldLeft(m.zero) {
case (acc, a) => m.op(acc, f(a))
}
```

This is equivalent and more efficient, but to my eye much less clear, so I'd suggest treating it like any optimization—if you need it, use it, but think twice about whether the gains are really worth the loss of clarity.

`Monoid`

instance implicit, switch the order of the other parameter lists, and write`as.map(f).foldLeft(m.zero)(m.op)`

, but otherwise this looks reasonable. – Travis Brown Oct 28 '13 at 2:10`Monoid`

instance implicit? – Kevin Meredith Oct 28 '13 at 2:17