I wanted to update the former answer, but since you created separate question, I put it here.

**scalaz.syntax**

Let's consider the `point`

example, and you can apply the same reasoning for other methods.

`point`

(or haskell's `return`

) or `pure`

(just a type alias) belongs to `Applicative`

trait. If you want to put something inside some `F`

, you need at least `Applicative`

instance for this `F`

.

Usually, you will provide it implicitly with imports, but you can specify it explicitly as well.

In example from the first question, I assigned it to `val`

```
implicit val KA = scalaz.Kleisli.kleisliIdApplicative[Int]
```

because scala was not able to figure out the corresponding `Int`

type for this applicative. In other words, it did not know Applicative for *which Reader* to bring in. (though sometimes compiler can figure it out)

For the Applicatives with one type parameter, we can bring implicit instances in just by using import

```
import scalaz.std.option.optionInstance
import scalaz.std.list.listInstance
```

etc...

Okay, you have the instance. Now you need to invoke `point`

on it.
You have few options:

**1. Access method directly**:

```
scalaz.std.option.optionInstance.point("hello")
KA.pure("hello")
```

**2. Explicitly pull it from implicit context**:

```
Applicative[Option].point("hello")
```

If you look into Applicative object, you would see

```
object Applicative {
@inline def apply[F[_]](implicit F: Applicative[F]): Applicative[F] = F
}
```

Implementation of `apply`

, is only returning the corresponding `Applicative[F]`

instance for some type `F`

.

So `Applicative[Option].point("hello")`

is converted to
`Applicative[Option].apply(scalaz.std.option.optionInstance)`

which in the end is just `optionInstance`

**3. Use syntax**

```
import scalaz.syntax.applicative._
```

brings this method into implicit scope:

```
implicit def ApplicativeIdV[A](v: => A) = new ApplicativeIdV[A] {
val nv = Need(v)
def self = nv.value
}
trait ApplicativeIdV[A] extends Ops[A] {
def point[F[_] : Applicative]: F[A] = Applicative[F].point(self)
def pure[F[_] : Applicative]: F[A] = Applicative[F].point(self)
def η[F[_] : Applicative]: F[A] = Applicative[F].point(self)
} ////
```

So then, whenever you try to invoke `point`

on a `String`

```
"hello".point[Option]
```

compiler realizes, that `String`

does not have the method `point`

and begins to look through implicits, how it can get something which has `point`

, from `String`

.

It finds, that it can convert `String`

to `ApplicativeIdV[String]`

, which indeed has method `point`

:

```
def point[F[_] : Applicative]: F[A] = Applicative[F].point(self)
```

So in the end - your call desugares to

```
new ApplicativeIdV[Option]("hello")
```

More or less all typeclasses in scalaz are working the same way.
For `sequence`

, the implementation is

```
def sequence[G[_]: Applicative, A](fga: F[G[A]]): G[F[A]] =
traverse(fga)(ga => ga)
```

This colon after `G`

means, that `Applicative[G]`

should be provided implicitly.
It is essentialy the same as:

```
def sequence[G[_], A](fga: F[G[A]])(implicit ev: Applicative[G[_]]): G[F[A]] =
traverse(fga)(ga => ga)
```

So all you need is the Applicative[G], and Traverse[F].

```
import scalaz.std.list.listInstance
import scalaz.std.option.optionInstance
Traverse[List].sequence[Option, String](Option("hello"))
```