There are some handy compiler flags when dealing with implicits: `-Xlog-implicits`

, `-Xprint:typer`

and `-Ytyper-debug`

In this case you can use `-Xprint:typer`

flag to see expressions with applied implicits. Then, first snippet `List(3, 4, 5).asMA.foldMap(identity)`

will expand to

```
scalaz.this.Scalaz.SeqMA[List, Int](immutable.this.List.apply[Int](3, 4, 5)).asMA.foldMap[Int]({
((x: Int) => scala.this.Predef.identity[Int](x))
})(scalaz.this.Foldable.ListFoldable,
scalaz.this.Monoid.monoid[Int](scalaz.this.Semigroup.IntSemigroup, scalaz.this.Zero.IntZero));
```

Now it is clear that

```
Monoid.monoid[Int](Semigroup.IntSemigroup, Zero.IntZero)
```

is used to create `Monoid[Int]`

instance (with append = + and zero = 0)

Second snippet, `List(3, 4, 5).foldMap(multiplication)`

will expand to

```
scalaz.this.Scalaz.SeqMA[List, Int](immutable.this.List.apply[Int](3, 4, 5)).foldMap[scalaz.IntMultiplication]({
((n: Int) => scalaz.Scalaz.multiplication(n))
})(scalaz.this.Foldable.ListFoldable,
scalaz.this.Monoid.monoid[scalaz.IntMultiplication](scalaz.this.Semigroup.IntMultiplicationSemigroup, scalaz.this.Zero.IntMultiplicationZero));
```

In this case `Monoid[IntMultiplication]`

(with append = * and zero = 1) is used as implicit parameter.

### Update

To create `Monoid`

for your type, you need to have implicit `Semigroup`

and `Zero`

in scope

```
case class Foo(x: Int)
implicit def FooSemigroup: Semigroup[Foo] = semigroup((f1, f2) => Foo(f1.x + f2.x))
implicit def FooZero: Zero[Foo] = zero(Foo(0))
scala> (1 to 10) map Foo foldMap identity
res5: Foo = Foo(55)
```