# When using an EitherT[StateWithSomeFixedStateType, T, U], how do you do some state manipulation when a left is returned?

Say you have an EitherT that looks something like this:

``````type StateListOfString[+T] = State[List[String], T]
type MyEitherT = EitherT[StateListOfString, Int, Boolean]
``````

If you have a for-comprehension that could return a left:

``````my computation = for {
a <- thingThatCouldReturnLeft
b <- otherThingThatCouldReturnLeft
} yield b
``````

How can you follow up with a for-comprehension that manipulates state before itself returning the left?

I think I want something very close to orElse, but orElse doesn't have access to the value of the left:

``````  def orElse[AA >: A, BB >: B](x: => EitherT[F, AA, BB])(implicit F: Bind[F]): EitherT[F, AA, BB] = {
``````

If it took something like (x: => Int => EitherT[F, AA, BB]) instead of just (x: => EitherT[F, AA, BB]), it would work.

``````for {
a <- myComputation.isLeft
// OK, now I have something sensible, and I can follow up with something like
// a leftMap
``````

But if I start by calling isLeft, it looks like the computation is run at least twice, once for the isLeft, and again when I call something like leftMap.

What's the right thing to use here?

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Looking at the sources of `orElse` it seems that it can be naturally generalized as

``````import scala.language.higherKinds

def onLeft[F[+_],A,B](x: => EitherT[F, A, B])
(y: A => EitherT[F, A, B])
(implicit F: Bind[F]): EitherT[F, A, B] =
{
val g = x.run
EitherT(F.bind(g) {
case -\/(l) => y(l).run
case \/-(_) => g
})
}
``````

This is basically the same thing as swapping left/right and then using monadic binding

``````def onLeft1[F[+_],A,B](x: => EitherT[F, A, B])
(y: A => EitherT[F, A, B])
(implicit F: Monad[F]): EitherT[F, A, B] =
x.swap.flatMap((a: A) => y(a).swap).swap
``````

but of course the first variant is more efficient (and also a bit more general in `F`).

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