First, let's see their declaration:

```
implicit def mkNumericOps (lhs: T): IntegralOps
implicit def mkOrderingOps (lhs: T): Ops
```

The fact that they are implicit means their goal is to provide some automatic value or conversion. Note that they both convert from `T`

to some other type, where `T`

is the type parameter of the trait: `Integral[T]`

.

So, if you have `Integral[Int]`

, then `mkNumericOps`

will give you an automatic conversion from `Int`

to `IntegralOps`

. That means you'll be able to call methods from `IntegralOps`

or `Ops`

on an `Int`

(or whatever it is the type of your `Integral`

).

Now, let's see what methods are these:

```
def % (rhs: T): T
def * (rhs: T): T
def + (rhs: T): T
def - (rhs: T): T
def / (rhs: T): T
def /% (rhs: T): (T, T)
def abs (): T
def signum (): Int
def toDouble (): Double
def toFloat (): Float
def toInt (): Int
def toLong (): Long
def unary_- (): T
```

These are from `IntegralOps`

, which extends `Ops`

. An interesting thing about them is that many of them are already defined on `Int`

! So, how and why one would use them? Here's an example:

```
def sum[T](list: List[T])(implicit integral: Integral[T]): T = {
import integral._ // get the implicits in question into scope
list.foldLeft(integral.zero)(_ + _)
}
```

So, given any type `T`

for which there's an `Integral[T]`

implicitly available, you can pass a list of that type to `sum`

.

If, on the other hand, I made my method specific for the type `Int`

, I could write it without `Integral`

. On the other hand, I can't write something that will work for both `Int`

and `Long`

and `BigInt`

, because they do not share a common ancestor defining the method `+`

(much less a `zero´).

The `foldLeft`

above is effectively translated as this:

```
list.foldLeft(integral.zero)((x, y) => mkNumericOps(x).+(y))
```

trait methodsandclass methods? All methods are defined on a class or a trait, though some are defined on anonymous subclasses that in a seemless manner. – Daniel C. Sobral Mar 31 '11 at 22:19