# How can I collect the Lefts of an Either from a tuple?

After doing a match on a bunch of Eithers that have type Either[String, A] (where A is more than one type), I'd like to accumulate any strings on the left into a list.

``````(a, b, c, d, e) match {
case (Right(a), Right(b), Right(c), Right(d), Right(e)) => {
"All good, use a, b, c, d, and e!"
}
case anythingElse => {
val strings = accLefts(anythingElse)
doSomethingWithStrings(strings)
}
}
``````

If I try to `.productIterator.toList` the tuple, I end up with List[Any]. If I handle each failing case separately (combinations of Rights and Lefts), I end up with an exponential number of case statements.

How can I get a List[Either[String, Any]] at the end there to pass to my accLefts call? Or should I have done something other than a match?

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Maybe do a partition based on isLeft? –  Ron Dahlgren Mar 1 '13 at 20:20
partition isn't defined on tuple, and isLeft doesn't work on a List[Any] –  Jim Hunziker Mar 1 '13 at 20:22

Perhaps with nested pattern matching?

``````case anythingElse => {
val strings = anythingElse
.productIterator
.collect { case Left(str: String) => str }
.toList
doSomethingWithStrings(strings)
}
``````

Note that `str: String` here is to guide type inference so strings would have type `List[String]` not `List[Any]`

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That works if you change it to `Left(str: String)`. –  Jim Hunziker Mar 1 '13 at 20:25
Small nitpick: `str: String` does more than just "guide type inference", it is actually fully part of the pattern matching (it might look like mere type ascription, but here it is not) and will perform a runtime cast. –  Régis Jean-Gilles Mar 2 '13 at 10:14

This is precisely the kind of thing that `ValidationNEL` in Scalaz (which is essentially a beefed-up `Either`) is designed to support. For example, suppose we have the following setup using Scalaz 7:

``````import scalaz._, Scalaz._

case class Person(first: String, last: String, initial: Char, age: Int)

val first = "John".successNel[String]

val last = "Doe".successNel[String]
val badLast = "Empty last name".failureNel[String]

val initial = 'H'.successNel[String]

val age = 45.successNel[String]
val badAge = "Negative age provided".failureNel[Int]
``````

Note that the `Nel` here stands for non-empty list, and that `"John".successNel[String]` is more or less equivalent to `Right("John"): Either[List[String], String]`, etc.

Now we can write the following:

``````scala> println((first |@| last |@| initial |@| age)(Person.apply))
Success(Person(John,Doe,H,45))
``````

Or:

``````scala> println((first |@| badLast |@| initial |@| badAge)(Person.apply))
Failure(NonEmptyList(Empty last name, Negative age provided))
``````

Or:

``````scala> println((first |@| badLast |@| badInitial |@| badAge)(Person.apply))
Failure(NonEmptyList(Empty last name, Non-alphabetic MI, Negative age provided))
``````

Any errors are accumulated in the left side of the `ValidationNEL`. See e.g. my answer here for more details.

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I'd probably create a set of utility functions like

``````def fromTuple2[A, That](t: Tuple2[A,A])(implicit bf : CanBuildFrom[Nothing, A, That]): That =
(bf.apply() += (t._1, t._2)).result();
``````

for all the n-tuples you need. While it's a lot of boiler-plate code, it's just one-time job. And then you can do things like:

``````val e1: Either[String,Int] = Right(3);
val e2: Either[String,String] = Left("3");
val test: List[Either[String,Any]] = fromTuple2(e1, e2);
``````

Perhaps better, we can use enrichment implicit methods such as

``````implicit def fromTuple2Impl[A](t: Tuple2[A,A]) = new {
def asCollection[That](implicit bf : CanBuildFrom[Nothing, A, That]): That =
(bf.apply() += (t._1, t._2)).result();
}
``````

to write just

``````val test: List[Either[String,Any]] = (e1, e2).asCollection;
``````

Edit: We can even enrich tuples to be `Traversable`s, which gets us all methods like `toList`, folding etc.:

``````implicit def fromTuple2Impl3[A](t: Tuple2[A,A]) = new Traversable[A] {
def asCollection[That](implicit bf : CanBuildFrom[Nothing, A, That]): That =
(bf.apply() += (t._1, t._2)).result();
override def foreach[U](f: (A) => U): Unit = {
f(t._1); f(t._2);
}
}
``````

With some more work, we could take it further to implement `IndexedSeq`.

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