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.
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
f applied to the value of
opt if it has a one, and still
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:
map[C](f: A => C): Either[C,B]
map[C](f: B => C): Either[A,C].
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
joinLeft. The signature may be puzzling:
joinLeft [A1 >: A, B1 >: B, C] (implicit ev: <:<[A1, Either[C, B1]]):
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
Option equivalent would work on an
Some(Some(x)) would yield
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).