`left`

and `right`

are the important ones. `Either`

is useful without projections (mostly you do pattern matching), but projections are quite worthy of attention, as they give a much richer API. You will use joins much less.

`Either`

is often used to mean "a proper value or an error". In this respect, it is like an extended `Option`

. When there is no data, instead of `None`

, you have an error.
`Option`

has a rich API. The same can be made available on `Either`

, provided we know, in Either, which one is the result and which one is the error.

`left`

and `right`

projection says just that. It is the `Either`

, plus the added knowledge that the value is respectively at left or at right, and the other one is the error.

For instance, in `Option`

, you can map, so `opt.map(f)`

returns an `Option`

with `f`

applied to the value of `opt`

if it has a one, and still `None`

if `opt`

was `None`

. On a left projection, it will apply `f`

on the value at left if it is a `Left`

, and leave it unchanged if it is a `Right`

. Observe the signatures:

- In
`LeftProjection[A,B]`

, `map[C](f: A => C): Either[C,B]`

- In
`RightProjection[A,B]`

, `map[C](f: B => C): Either[A,C]`

.

`left`

and `right`

are simply the way to say which side is considered the value when you want to use one of the usual API routines.

Alternatives could have been:

- set a convention, as in Haskell, where there were strong syntactical reasons to put the value at right. When you want to apply a method on the other side (you may well want to change the error with a
`map`

for instance), do a `swap`

before and after.
- postfix method names with Left or Right (maybe just L and R). That would prevent using for comprehension. With
`for`

comprehensions (`flatMap`

in fact, but the for notation is quite convenient) `Either`

is an alternative to (checked) exceptions.

Now the joins. Left and Right means the same thing as for the projections, and they are closely related to `flatMap`

. Consider `joinLeft`

. The signature may be puzzling:

```
joinLeft [A1 >: A, B1 >: B, C] (implicit ev: <:<[A1, Either[C, B1]]):
Either[C, B1]
```

`A1`

and `B1`

are technically necessary, but not critical to the understanding, let's simplify

```
joinLeft[C](implicit ev: <:<[A, Either[C, B])
```

What the implicit means is that the method can only be called if `A`

is an `Either[C,B]`

. The method is not available on an `Either[A,B]`

in general, but only on an `Either[Either[C,B], B]`

. As with left projection, we consider that the value is at left (that would be right for `joinRight`

). What the join does is flatten this (think `flatMap`

). When one join, one does not care whether the error (B) is inside or outside, we just want Either[C,B]. So Left(Left(c)) yields Left(c), both Left(Right(b)) and Right(b) yield Right(b). The relation with flatMap is as follows:

```
joinLeft(e) = e.left.flatMap(identity)
e.left.flatMap(f) = e.left.map(f).joinLeft
```

The `Option`

equivalent would work on an `Option[Option[A]]`

, `Some(Some(x))`

would yield `Some(x)`

both `Some(None)`

and `None`

would yield `None`

. It can be written o.flatMap(identity). Note that `Option[A]`

is isomorphic to `Either[A,Unit]`

(if you use left projections and joins) and also to `Either[Unit, A]`

(using right projections).