NonEmptyTraverse

Companion object NonEmptyTraverse

trait NonEmptyTraverse[F[_]] extends Traverse[F] with Reducible[F]

NonEmptyTraverse, also known as Traversable1.

NonEmptyTraverse is like a non-empty Traverse. In addition to the traverse and sequence methods it provides nonEmptyTraverse and nonEmptySequence methods which require an Apply instance instead of Applicative.

Self Type: NonEmptyTraverse[F]
Annotations: @implicitNotFound( ... ) @typeclass( ... , ... )

Linear Supertypes

Reducible[F], Traverse[F], UnorderedTraverse[F], Foldable[F], UnorderedFoldable[F], Functor[F], Invariant[F], Serializable, Serializable, AnyRef, Any

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Inherited

NonEmptyTraverse
Reducible
Traverse
UnorderedTraverse
Foldable
UnorderedFoldable
Functor
Invariant
Serializable
Serializable
AnyRef
Any

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Visibility

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Abstract Value Members

abstract def foldLeft[A, B](fa: F[A], b: B)(f: (B, A) ⇒ B): B

Left associative fold on 'F' using the function 'f'.

Example:

scala> import cats.Foldable, cats.implicits._
scala> val fa = Option(1)

Folding by addition to zero:
scala> Foldable[Option].foldLeft(fa, Option(0))((a, n) => a.map(_ + n))
res0: Option[Int] = Some(1)

With syntax extensions, foldLeft can be used like:

Folding `Option` with addition from zero:
scala> fa.foldLeft(Option(0))((a, n) => a.map(_ + n))
res1: Option[Int] = Some(1)

There's also an alias `foldl` which is equivalent:
scala> fa.foldl(Option(0))((a, n) => a.map(_ + n))
res2: Option[Int] = Some(1)

Definition Classes: Foldable

abstract def foldRight[A, B](fa: F[A], lb: Eval[B])(f: (A, Eval[B]) ⇒ Eval[B]): Eval[B]

Right associative lazy fold on F using the folding function 'f'.

This method evaluates lb lazily (in some cases it will not be needed), and returns a lazy value. We are using (A, Eval[B]) => Eval[B] to support laziness in a stack-safe way. Chained computation should be performed via .map and .flatMap.

For more detailed information about how this method works see the documentation for Eval[_].

Example:

scala> import cats.Foldable, cats.Eval, cats.implicits._
scala> val fa = Option(1)

Folding by addition to zero:
scala> val folded1 = Foldable[Option].foldRight(fa, Eval.now(0))((n, a) => a.map(_ + n))
Since `foldRight` yields a lazy computation, we need to force it to inspect the result:
scala> folded1.value
res0: Int = 1

With syntax extensions, we can write the same thing like this:
scala> val folded2 = fa.foldRight(Eval.now(0))((n, a) => a.map(_ + n))
scala> folded2.value
res1: Int = 1

Unfortunately, since `foldRight` is defined on many collections - this
extension clashes with the operation defined in `Foldable`.

To get past this and make sure you're getting the lazy `foldRight` defined
in `Foldable`, there's an alias `foldr`:
scala> val folded3 = fa.foldr(Eval.now(0))((n, a) => a.map(_ + n))
scala> folded3.value
res1: Int = 1

Definition Classes: Foldable

abstract def nonEmptyTraverse[G[_], A, B](fa: F[A])(f: (A) ⇒ G[B])(implicit arg0: Apply[G]): G[F[B]]

Given a function which returns a G effect, thread this effect through the running of this function on all the values in F, returning an F[B] in a G context.

Example:

scala> import cats.implicits._
scala> import cats.data.NonEmptyList
scala> def countWords(words: List[String]): Map[String, Int] = words.groupBy(identity).map { case (k, v) => (k, v.length) }
scala> val expectedResult = Map("do" -> NonEmptyList.of(1, 2), "you" -> NonEmptyList.of(1, 1))
scala> val x = List("How", "do", "you", "fly")
scala> val y = List("What", "do", "you", "do")
scala> val result = NonEmptyList.of(x, y).nonEmptyTraverse(countWords)
scala> result === expectedResult
res0: Boolean = true

abstract def reduceLeftTo[A, B](fa: F[A])(f: (A) ⇒ B)(g: (B, A) ⇒ B): B
Apply f to the "initial element" of fa and combine it with every other value using the given function g.
Apply f to the "initial element" of fa and combine it with every other value using the given function g.

Definition Classes
Reducible
abstract def reduceRightTo[A, B](fa: F[A])(f: (A) ⇒ B)(g: (A, Eval[B]) ⇒ Eval[B]): Eval[B]
Apply f to the "initial element" of fa and lazily combine it with every other value using the given function g.
Apply f to the "initial element" of fa and lazily combine it with every other value using the given function g.

Definition Classes
Reducible

Concrete Value Members

final def !=(arg0: Any): Boolean

Definition Classes
AnyRef → Any
final def ##(): Int

Definition Classes
AnyRef → Any
final def ==(arg0: Any): Boolean

Definition Classes
AnyRef → Any

def as[A, B](fa: F[A], b: B): F[B]

Replaces the A value in F[A] with the supplied value.

Example:

scala> import cats.Functor
scala> import cats.implicits.catsStdInstancesForList

scala> Functor[List].as(List(1,2,3), "hello")
res0: List[String] = List(hello, hello, hello)

Definition Classes: Functor

final def asInstanceOf[T0]: T0

Definition Classes
Any
def clone(): AnyRef

Attributes
protected[lang]
Definition Classes
AnyRef
Annotations
@throws( ... ) @native()
def collectFirst[A, B](fa: F[A])(pf: PartialFunction[A, B]): Option[B]

Definition Classes
Foldable

def collectFirstSome[A, B](fa: F[A])(f: (A) ⇒ Option[B]): Option[B]

Like collectFirst from scala.collection.Traversable but takes A => Option[B] instead of PartialFunctions.

scala> import cats.implicits._
scala> val keys = List(1, 2, 4, 5)
scala> val map = Map(4 -> "Four", 5 -> "Five")
scala> keys.collectFirstSome(map.get)
res0: Option[String] = Some(Four)
scala> val map2 = Map(6 -> "Six", 7 -> "Seven")
scala> keys.collectFirstSome(map2.get)
res1: Option[String] = None

Definition Classes: Foldable

def collectFirstSomeM[G[_], A, B](fa: F[A])(f: (A) ⇒ G[Option[B]])(implicit G: Monad[G]): G[Option[B]]

Monadic version of collectFirstSome.

If there are no elements, the result is None. collectFirstSomeM short-circuits, i.e. once a Some element is found, no further effects are produced.

For example:

scala> import cats.implicits._
scala> def parseInt(s: String): Either[String, Int] = Either.catchOnly[NumberFormatException](s.toInt).leftMap(_.getMessage)
scala> val keys1 = List("1", "2", "4", "5")
scala> val map1 = Map(4 -> "Four", 5 -> "Five")
scala> Foldable[List].collectFirstSomeM(keys1)(parseInt(_) map map1.get)
res0: scala.util.Either[String,Option[String]] = Right(Some(Four))

scala> val map2 = Map(6 -> "Six", 7 -> "Seven")
scala> Foldable[List].collectFirstSomeM(keys1)(parseInt(_) map map2.get)
res1: scala.util.Either[String,Option[String]] = Right(None)

scala> val keys2 = List("1", "x", "4", "5")
scala> Foldable[List].collectFirstSomeM(keys2)(parseInt(_) map map1.get)
res2: scala.util.Either[String,Option[String]] = Left(For input string: "x")

scala> val keys3 = List("1", "2", "4", "x")
scala> Foldable[List].collectFirstSomeM(keys3)(parseInt(_) map map1.get)
res3: scala.util.Either[String,Option[String]] = Right(Some(Four))

Definition Classes: Foldable
Annotations: @noop()

def collectFold[A, B](fa: F[A])(f: PartialFunction[A, B])(implicit B: Monoid[B]): B
Tear down a subset of this structure using a PartialFunction.
Tear down a subset of this structure using a PartialFunction.
```
scala> import cats.implicits._
scala> val xs = List(1, 2, 3, 4)
scala> Foldable[List].collectFold(xs) { case n if n % 2 == 0 => n }
res0: Int = 6
```
Definition Classes
Foldable
Annotations
@noop()
def collectFoldSome[A, B](fa: F[A])(f: (A) ⇒ Option[B])(implicit B: Monoid[B]): B
Tear down a subset of this structure using a A => Option[M].
Tear down a subset of this structure using a A => Option[M].
```
scala> import cats.implicits._
scala> val xs = List(1, 2, 3, 4)
scala> def f(n: Int): Option[Int] = if (n % 2 == 0) Some(n) else None
scala> Foldable[List].collectFoldSome(xs)(f)
res0: Int = 6
```
Definition Classes
Foldable
def combineAll[A](fa: F[A])(implicit arg0: Monoid[A]): A
Alias for fold.
Alias for fold.

Definition Classes
Foldable
def combineAllOption[A](fa: F[A])(implicit ev: Semigroup[A]): Option[A]

Definition Classes
Foldable
def compose[G[_]](implicit arg0: NonEmptyTraverse[G]): NonEmptyTraverse[[α]F[G[α]]]
def compose[G[_]](implicit arg0: Reducible[G]): Reducible[[α]F[G[α]]]

Definition Classes
Reducible
def compose[G[_]](implicit arg0: Traverse[G]): Traverse[[α]F[G[α]]]

Definition Classes
Traverse
def compose[G[_]](implicit arg0: Foldable[G]): Foldable[[α]F[G[α]]]

Definition Classes
Foldable
def compose[G[_]](implicit arg0: Functor[G]): Functor[[α]F[G[α]]]

Definition Classes
Functor
def compose[G[_]](implicit arg0: Invariant[G]): Invariant[[α]F[G[α]]]

Definition Classes
Invariant
def composeContravariant[G[_]](implicit arg0: Contravariant[G]): Contravariant[[α]F[G[α]]]

Definition Classes
Functor → Invariant
def composeFunctor[G[_]](implicit arg0: Functor[G]): Invariant[[α]F[G[α]]]

Definition Classes
Invariant

def count[A](fa: F[A])(p: (A) ⇒ Boolean): Long

Count the number of elements in the structure that satisfy the given predicate.

For example:

scala> import cats.implicits._
scala> val map1 = Map[Int, String]()
scala> val p1: String => Boolean = _.length > 0
scala> UnorderedFoldable[Map[Int, *]].count(map1)(p1)
res0: Long = 0

scala> val map2 = Map(1 -> "hello", 2 -> "world", 3 -> "!")
scala> val p2: String => Boolean = _.length > 1
scala> UnorderedFoldable[Map[Int, *]].count(map2)(p2)
res1: Long = 2

Definition Classes: UnorderedFoldable
Annotations: @noop()

def dropWhile_[A](fa: F[A])(p: (A) ⇒ Boolean): List[A]
Convert F[A] to a List[A], dropping all initial elements which match p.
Convert F[A] to a List[A], dropping all initial elements which match p.

Definition Classes
Foldable
final def eq(arg0: AnyRef): Boolean

Definition Classes
AnyRef
def equals(arg0: Any): Boolean

Definition Classes
AnyRef → Any
def exists[A](fa: F[A])(p: (A) ⇒ Boolean): Boolean
Check whether at least one element satisfies the predicate.
Check whether at least one element satisfies the predicate.
If there are no elements, the result is false.

Definition Classes
Foldable → UnorderedFoldable

def existsM[G[_], A](fa: F[A])(p: (A) ⇒ G[Boolean])(implicit G: Monad[G]): G[Boolean]

Check whether at least one element satisfies the effectful predicate.

If there are no elements, the result is false. existsM short-circuits, i.e. once a true result is encountered, no further effects are produced.

For example:

scala> import cats.implicits._
scala> val F = Foldable[List]
scala> F.existsM(List(1,2,3,4))(n => Option(n <= 4))
res0: Option[Boolean] = Some(true)

scala> F.existsM(List(1,2,3,4))(n => Option(n > 4))
res1: Option[Boolean] = Some(false)

scala> F.existsM(List(1,2,3,4))(n => if (n <= 2) Option(true) else Option(false))
res2: Option[Boolean] = Some(true)

scala> F.existsM(List(1,2,3,4))(n => if (n <= 2) Option(true) else None)
res3: Option[Boolean] = Some(true)

scala> F.existsM(List(1,2,3,4))(n => if (n <= 2) None else Option(true))
res4: Option[Boolean] = None

Definition Classes: Foldable

def filter_[A](fa: F[A])(p: (A) ⇒ Boolean): List[A]
Convert F[A] to a List[A], only including elements which match p.
Convert F[A] to a List[A], only including elements which match p.

Definition Classes
Foldable
def finalize(): Unit

Attributes
protected[lang]
Definition Classes
AnyRef
Annotations
@throws( classOf[java.lang.Throwable] )
def find[A](fa: F[A])(f: (A) ⇒ Boolean): Option[A]
Find the first element matching the predicate, if one exists.
Find the first element matching the predicate, if one exists.

Definition Classes
Foldable

def findM[G[_], A](fa: F[A])(p: (A) ⇒ G[Boolean])(implicit G: Monad[G]): G[Option[A]]

Find the first element matching the effectful predicate, if one exists.

If there are no elements, the result is None. findM short-circuits, i.e. once an element is found, no further effects are produced.

For example:

scala> import cats.implicits._
scala> val list = List(1,2,3,4)
scala> Foldable[List].findM(list)(n => (n >= 2).asRight[String])
res0: Either[String,Option[Int]] = Right(Some(2))

scala> Foldable[List].findM(list)(n => (n > 4).asRight[String])
res1: Either[String,Option[Int]] = Right(None)

scala> Foldable[List].findM(list)(n => Either.cond(n < 3, n >= 2, "error"))
res2: Either[String,Option[Int]] = Right(Some(2))

scala> Foldable[List].findM(list)(n => Either.cond(n < 3, false, "error"))
res3: Either[String,Option[Int]] = Left(error)

Definition Classes: Foldable
Annotations: @noop()

def flatSequence[G[_], A](fgfa: F[G[F[A]]])(implicit G: Applicative[G], F: FlatMap[F]): G[F[A]]
Thread all the G effects through the F structure and flatten to invert the structure from F[G[F[A]]] to G[F[A]].
Thread all the G effects through the F structure and flatten to invert the structure from F[G[F[A]]] to G[F[A]].
Example:
```
scala> import cats.implicits._
scala> val x: List[Option[List[Int]]] = List(Some(List(1, 2)), Some(List(3)))
scala> val y: List[Option[List[Int]]] = List(None, Some(List(3)))
scala> x.flatSequence
res0: Option[List[Int]] = Some(List(1, 2, 3))
scala> y.flatSequence
res1: Option[List[Int]] = None
```
Definition Classes
Traverse

def flatTraverse[G[_], A, B](fa: F[A])(f: (A) ⇒ G[F[B]])(implicit G: Applicative[G], F: FlatMap[F]): G[F[B]]

A traverse followed by flattening the inner result.

Example:

scala> import cats.implicits._
scala> def parseInt(s: String): Option[Int] = Either.catchOnly[NumberFormatException](s.toInt).toOption
scala> val x = Option(List("1", "two", "3"))
scala> x.flatTraverse(_.map(parseInt))
res0: List[Option[Int]] = List(Some(1), None, Some(3))

Definition Classes: Traverse

final def fmap[A, B](fa: F[A])(f: (A) ⇒ B): F[B]
Alias for map, since map can't be injected as syntax if the implementing type already had a built-in .map method.
Alias for map, since map can't be injected as syntax if the implementing type already had a built-in .map method.
Example:
```
scala> import cats.implicits._

scala> val m: Map[Int, String] = Map(1 -> "hi", 2 -> "there", 3 -> "you")

scala> m.fmap(_ ++ "!")
res0: Map[Int,String] = Map(1 -> hi!, 2 -> there!, 3 -> you!)
```
Definition Classes
Functor
def fold[A](fa: F[A])(implicit A: Monoid[A]): A
Fold implemented using the given Monoid[A] instance.
Fold implemented using the given Monoid[A] instance.

Definition Classes
Foldable
def foldA[G[_], A](fga: F[G[A]])(implicit G: Applicative[G], A: Monoid[A]): G[A]
Fold implemented using the given Applicative[G] and Monoid[A] instance.
Fold implemented using the given Applicative[G] and Monoid[A] instance.
This method is similar to fold, but may short-circuit.
For example:
```
scala> import cats.implicits._
scala> val F = Foldable[List]
scala> F.foldA(List(Either.right[String, Int](1), Either.right[String, Int](2)))
res0: Either[String, Int] = Right(3)
```
See this issue for an explanation of @noop usage.
Definition Classes
Foldable
Annotations
@noop()
def foldK[G[_], A](fga: F[G[A]])(implicit G: MonoidK[G]): G[A]
Fold implemented using the given MonoidK[G] instance.
Fold implemented using the given MonoidK[G] instance.
This method is identical to fold, except that we use the universal monoid (MonoidK[G]) to get a Monoid[G[A]] instance.
For example:
```
scala> import cats.implicits._
scala> val F = Foldable[List]
scala> F.foldK(List(1 :: 2 :: Nil, 3 :: 4 :: 5 :: Nil))
res0: List[Int] = List(1, 2, 3, 4, 5)
```
Definition Classes
Foldable
final def foldLeftM[G[_], A, B](fa: F[A], z: B)(f: (B, A) ⇒ G[B])(implicit G: Monad[G]): G[B]
Alias for foldM.
Alias for foldM.

Definition Classes
Foldable
def foldM[G[_], A, B](fa: F[A], z: B)(f: (B, A) ⇒ G[B])(implicit G: Monad[G]): G[B]
Perform a stack-safe monadic left fold from the source context F into the target monad G.
Perform a stack-safe monadic left fold from the source context F into the target monad G.
This method can express short-circuiting semantics. Even when fa is an infinite structure, this method can potentially terminate if the foldRight implementation for F and the tailRecM implementation for G are sufficiently lazy.
Instances for concrete structures (e.g. List) will often have a more efficient implementation than the default one in terms of foldRight.

Definition Classes
Foldable
def foldMap[A, B](fa: F[A])(f: (A) ⇒ B)(implicit B: Monoid[B]): B
Fold implemented by mapping A values into B and then combining them using the given Monoid[B] instance.
Fold implemented by mapping A values into B and then combining them using the given Monoid[B] instance.

Definition Classes
Foldable

def foldMapA[G[_], A, B](fa: F[A])(f: (A) ⇒ G[B])(implicit G: Applicative[G], B: Monoid[B]): G[B]

Fold in an Applicative context by mapping the A values to G[B].

Fold in an Applicative context by mapping the A values to G[B]. combining the B values using the given Monoid[B] instance.

Similar to foldMapM, but will typically be less efficient.

scala> import cats.Foldable
scala> import cats.implicits._
scala> val evenNumbers = List(2,4,6,8,10)
scala> val evenOpt: Int => Option[Int] =
     |   i => if (i % 2 == 0) Some(i) else None
scala> Foldable[List].foldMapA(evenNumbers)(evenOpt)
res0: Option[Int] = Some(30)
scala> Foldable[List].foldMapA(evenNumbers :+ 11)(evenOpt)
res1: Option[Int] = None

Definition Classes: Foldable

def foldMapK[G[_], A, B](fa: F[A])(f: (A) ⇒ G[B])(implicit G: MonoidK[G]): G[B]
Fold implemented by mapping A values into B in a context G and then combining them using the MonoidK[G] instance.
Fold implemented by mapping A values into B in a context G and then combining them using the MonoidK[G] instance.
```
scala> import cats._, cats.implicits._
scala> val f: Int => Endo[String] = i => (s => s + i)
scala> val x: Endo[String] = Foldable[List].foldMapK(List(1, 2, 3))(f)
scala> val a = x("foo")
a: String = "foo321"
```
Definition Classes
Foldable
Annotations
@noop()
def foldMapM[G[_], A, B](fa: F[A])(f: (A) ⇒ G[B])(implicit G: Monad[G], B: Monoid[B]): G[B]
Monadic folding on F by mapping A values to G[B], combining the B values using the given Monoid[B] instance.
Monadic folding on F by mapping A values to G[B], combining the B values using the given Monoid[B] instance.
Similar to foldM, but using a Monoid[B]. Will typically be more efficient than foldMapA.
```
scala> import cats.Foldable
scala> import cats.implicits._
scala> val evenNumbers = List(2,4,6,8,10)
scala> val evenOpt: Int => Option[Int] =
     |   i => if (i % 2 == 0) Some(i) else None
scala> Foldable[List].foldMapM(evenNumbers)(evenOpt)
res0: Option[Int] = Some(30)
scala> Foldable[List].foldMapM(evenNumbers :+ 11)(evenOpt)
res1: Option[Int] = None
```
Definition Classes
Foldable
def foldRightDefer[G[_], A, B](fa: F[A], gb: G[B])(fn: (A, G[B]) ⇒ G[B])(implicit arg0: Defer[G]): G[B]

Definition Classes
Foldable
def forall[A](fa: F[A])(p: (A) ⇒ Boolean): Boolean
Check whether all elements satisfy the predicate.
Check whether all elements satisfy the predicate.
If there are no elements, the result is true.

Definition Classes
Foldable → UnorderedFoldable

def forallM[G[_], A](fa: F[A])(p: (A) ⇒ G[Boolean])(implicit G: Monad[G]): G[Boolean]

Check whether all elements satisfy the effectful predicate.

If there are no elements, the result is true. forallM short-circuits, i.e. once a false result is encountered, no further effects are produced.

For example:

scala> import cats.implicits._
scala> val F = Foldable[List]
scala> F.forallM(List(1,2,3,4))(n => Option(n <= 4))
res0: Option[Boolean] = Some(true)

scala> F.forallM(List(1,2,3,4))(n => Option(n <= 1))
res1: Option[Boolean] = Some(false)

scala> F.forallM(List(1,2,3,4))(n => if (n <= 2) Option(true) else Option(false))
res2: Option[Boolean] = Some(false)

scala> F.forallM(List(1,2,3,4))(n => if (n <= 2) Option(false) else None)
res3: Option[Boolean] = Some(false)

scala> F.forallM(List(1,2,3,4))(n => if (n <= 2) None else Option(false))
res4: Option[Boolean] = None

Definition Classes: Foldable

def fproduct[A, B](fa: F[A])(f: (A) ⇒ B): F[(A, B)]
Tuple the values in fa with the result of applying a function with the value
Tuple the values in fa with the result of applying a function with the value
Example:
```
scala> import cats.Functor
scala> import cats.implicits.catsStdInstancesForOption

scala> Functor[Option].fproduct(Option(42))(_.toString)
res0: Option[(Int, String)] = Some((42,42))
```
Definition Classes
Functor

def fproductLeft[A, B](fa: F[A])(f: (A) ⇒ B): F[(B, A)]

Pair the result of function application with A.

Example:

scala> import cats.Functor
scala> import cats.implicits.catsStdInstancesForOption

scala> Functor[Option].fproductLeft(Option(42))(_.toString)
res0: Option[(String, Int)] = Some((42,42))

Definition Classes: Functor

def get[A](fa: F[A])(idx: Long): Option[A]
Get the element at the index of the Foldable.
Get the element at the index of the Foldable.

Definition Classes
Foldable
final def getClass(): Class[_]

Definition Classes
AnyRef → Any
Annotations
@native()
def hashCode(): Int

Definition Classes
AnyRef → Any
Annotations
@native()

def ifF[A](fb: F[Boolean])(ifTrue: ⇒ A, ifFalse: ⇒ A): F[A]

Lifts if to Functor

Example:

scala> import cats.Functor
scala> import cats.implicits.catsStdInstancesForList

scala> Functor[List].ifF(List(true, false, false))(1, 0)
res0: List[Int] = List(1, 0, 0)

Definition Classes: Functor
Annotations: @noop()

def imap[A, B](fa: F[A])(f: (A) ⇒ B)(g: (B) ⇒ A): F[B]

Transform an F[A] into an F[B] by providing a transformation from A to B and one from B to A.

Example:

scala> import cats.implicits._
scala> import scala.concurrent.duration._
scala> val durSemigroup: Semigroup[FiniteDuration] =
     | Invariant[Semigroup].imap(Semigroup[Long])(Duration.fromNanos)(_.toNanos)
scala> durSemigroup.combine(2.seconds, 3.seconds)
res1: FiniteDuration = 5 seconds

Definition Classes: Functor → Invariant

def intercalate[A](fa: F[A], a: A)(implicit A: Monoid[A]): A

Intercalate/insert an element between the existing elements while folding.

scala> import cats.implicits._
scala> Foldable[List].intercalate(List("a","b","c"), "-")
res0: String = a-b-c
scala> Foldable[List].intercalate(List("a"), "-")
res1: String = a
scala> Foldable[List].intercalate(List.empty[String], "-")
res2: String = ""
scala> Foldable[Vector].intercalate(Vector(1,2,3), 1)
res3: Int = 8

Definition Classes: Foldable

def intersperseList[A](xs: List[A], x: A): List[A]

Attributes
protected
Definition Classes
Foldable
def isEmpty[A](fa: F[A]): Boolean
Returns true if there are no elements.
Returns true if there are no elements. Otherwise false.

Definition Classes
Reducible → Foldable → UnorderedFoldable
final def isInstanceOf[T0]: Boolean

Definition Classes
Any

def lift[A, B](f: (A) ⇒ B): (F[A]) ⇒ F[B]

Lift a function f to operate on Functors

Example:

scala> import cats.Functor
scala> import cats.implicits.catsStdInstancesForOption

scala> val o = Option(42)
scala> Functor[Option].lift((x: Int) => x + 10)(o)
res0: Option[Int] = Some(52)

Definition Classes: Functor

def map[A, B](fa: F[A])(f: (A) ⇒ B): F[B]

Definition Classes
Traverse → Functor
def mapWithIndex[A, B](fa: F[A])(f: (A, Int) ⇒ B): F[B]
Akin to map, but also provides the value's index in structure F when calling the function.
Akin to map, but also provides the value's index in structure F when calling the function.

Definition Classes
Traverse
def maximum[A](fa: F[A])(implicit A: Order[A]): A

Definition Classes
Reducible
def maximumBy[A, B](fa: F[A])(f: (A) ⇒ B)(implicit arg0: Order[B]): A
Find the maximum A item in this structure according to an Order.by(f).
Find the maximum A item in this structure according to an Order.by(f).

Definition Classes
Reducible
See also
minimumBy for minimum instead of maximum.
def maximumByOption[A, B](fa: F[A])(f: (A) ⇒ B)(implicit arg0: Order[B]): Option[A]
Find the maximum A item in this structure according to an Order.by(f).
Find the maximum A item in this structure according to an Order.by(f).
returns
None if the structure is empty, otherwise the maximum element wrapped in a Some.

Definition Classes
Foldable
See also
Reducible#maximumBy for a version that doesn't need to return an Option for structures that are guaranteed to be non-empty.
minimumByOption for minimum instead of maximum.
def maximumOption[A](fa: F[A])(implicit A: Order[A]): Option[A]
Find the maximum A item in this structure according to the Order[A].
Find the maximum A item in this structure according to the Order[A].
returns
None if the structure is empty, otherwise the maximum element wrapped in a Some.

Definition Classes
Reducible → Foldable
See also
Reducible#maximum for a version that doesn't need to return an Option for structures that are guaranteed to be non-empty.
minimumOption for minimum instead of maximum.
def minimum[A](fa: F[A])(implicit A: Order[A]): A

Definition Classes
Reducible
def minimumBy[A, B](fa: F[A])(f: (A) ⇒ B)(implicit arg0: Order[B]): A
Find the minimum A item in this structure according to an Order.by(f).
Find the minimum A item in this structure according to an Order.by(f).

Definition Classes
Reducible
See also
maximumBy for maximum instead of minimum.
def minimumByOption[A, B](fa: F[A])(f: (A) ⇒ B)(implicit arg0: Order[B]): Option[A]
Find the minimum A item in this structure according to an Order.by(f).
Find the minimum A item in this structure according to an Order.by(f).
returns
None if the structure is empty, otherwise the minimum element wrapped in a Some.

Definition Classes
Foldable
See also
Reducible#minimumBy for a version that doesn't need to return an Option for structures that are guaranteed to be non-empty.
maximumByOption for maximum instead of minimum.
def minimumOption[A](fa: F[A])(implicit A: Order[A]): Option[A]
Find the minimum A item in this structure according to the Order[A].
Find the minimum A item in this structure according to the Order[A].
returns
None if the structure is empty, otherwise the minimum element wrapped in a Some.

Definition Classes
Reducible → Foldable
See also
Reducible#minimum for a version that doesn't need to return an Option for structures that are guaranteed to be non-empty.
maximumOption for maximum instead of minimum.
final def ne(arg0: AnyRef): Boolean

Definition Classes
AnyRef
def nonEmpty[A](fa: F[A]): Boolean

Definition Classes
Reducible → Foldable → UnorderedFoldable

def nonEmptyFlatSequence[G[_], A](fgfa: F[G[F[A]]])(implicit G: Apply[G], F: FlatMap[F]): G[F[A]]

Thread all the G effects through the F structure and flatten to invert the structure from F[G[F[A]]] to G[F[A]].

Example:

scala> import cats.implicits._
scala> import cats.data.NonEmptyList
scala> val x = NonEmptyList.of(Map(0 ->NonEmptyList.of(1, 2)), Map(0 -> NonEmptyList.of(3)))
scala> val y: NonEmptyList[Map[Int, NonEmptyList[Int]]] = NonEmptyList.of(Map(), Map(1 -> NonEmptyList.of(3)))
scala> x.nonEmptyFlatSequence
res0: Map[Int,cats.data.NonEmptyList[Int]] = Map(0 -> NonEmptyList(1, 2, 3))
scala> y.nonEmptyFlatSequence
res1: Map[Int,cats.data.NonEmptyList[Int]] = Map()

def nonEmptyFlatTraverse[G[_], A, B](fa: F[A])(f: (A) ⇒ G[F[B]])(implicit G: Apply[G], F: FlatMap[F]): G[F[B]]

A nonEmptyTraverse followed by flattening the inner result.

Example:

scala> import cats.implicits._
scala> import cats.data.NonEmptyList
scala> val x = NonEmptyList.of(List("How", "do", "you", "fly"), List("What", "do", "you", "do"))
scala> x.nonEmptyFlatTraverse(_.groupByNel(identity) : Map[String, NonEmptyList[String]])
res0: Map[String,cats.data.NonEmptyList[String]] = Map(do -> NonEmptyList(do, do, do), you -> NonEmptyList(you, you))

def nonEmptyIntercalate[A](fa: F[A], a: A)(implicit A: Semigroup[A]): A

Intercalate/insert an element between the existing elements while reducing.

scala> import cats.implicits._
scala> import cats.data.NonEmptyList
scala> val nel = NonEmptyList.of("a", "b", "c")
scala> Reducible[NonEmptyList].nonEmptyIntercalate(nel, "-")
res0: String = a-b-c
scala> Reducible[NonEmptyList].nonEmptyIntercalate(NonEmptyList.of("a"), "-")
res1: String = a

Definition Classes: Reducible

def nonEmptyPartition[A, B, C](fa: F[A])(f: (A) ⇒ Either[B, C]): Ior[NonEmptyList[B], NonEmptyList[C]]

Partition this Reducible by a separating function A => Either[B, C]

scala> import cats.data.NonEmptyList
scala> val nel = NonEmptyList.of(1,2,3,4)
scala> Reducible[NonEmptyList].nonEmptyPartition(nel)(a => if (a % 2 == 0) Left(a.toString) else Right(a))
res0: cats.data.Ior[cats.data.NonEmptyList[String],cats.data.NonEmptyList[Int]] = Both(NonEmptyList(2, 4),NonEmptyList(1, 3))
scala> Reducible[NonEmptyList].nonEmptyPartition(nel)(a => Right(a * 4))
res1: cats.data.Ior[cats.data.NonEmptyList[Nothing],cats.data.NonEmptyList[Int]] = Right(NonEmptyList(4, 8, 12, 16))

Definition Classes: Reducible

def nonEmptySequence[G[_], A](fga: F[G[A]])(implicit arg0: Apply[G]): G[F[A]]

Thread all the G effects through the F structure to invert the structure from F[G[A]] to G[F[A]].

Example:

scala> import cats.implicits._
scala> import cats.data.NonEmptyList
scala> val x = NonEmptyList.of(Map("do" -> 1, "you" -> 1), Map("do" -> 2, "you" -> 1))
scala> val y = NonEmptyList.of(Map("How" -> 3, "do" -> 1, "you" -> 1), Map[String,Int]())
scala> x.nonEmptySequence
res0: Map[String,NonEmptyList[Int]] = Map(do -> NonEmptyList(1, 2), you -> NonEmptyList(1, 1))
scala> y.nonEmptySequence
res1: Map[String,NonEmptyList[Int]] = Map()

def nonEmptySequence_[G[_], A](fga: F[G[A]])(implicit G: Apply[G]): G[Unit]
Sequence F[G[A]] using Apply[G].
Sequence F[G[A]] using Apply[G].
This method is similar to Foldable.sequence_ but requires only an Apply instance for G instead of Applicative. See the nonEmptyTraverse_ documentation for a description of the differences.

Definition Classes
Reducible
def nonEmptyTraverse_[G[_], A, B](fa: F[A])(f: (A) ⇒ G[B])(implicit G: Apply[G]): G[Unit]
Traverse F[A] using Apply[G].
Traverse F[A] using Apply[G].
A values will be mapped into G[B] and combined using Apply#map2.
This method is similar to Foldable.traverse_. There are two main differences:
1. We only need an Apply instance for G here, since we don't need to call Applicative.pure for a starting value. 2. This performs a strict left-associative traversal and thus must always traverse the entire data structure. Prefer Foldable.traverse_ if you have an Applicative instance available for G and want to take advantage of short-circuiting the traversal.

Definition Classes
Reducible
final def notify(): Unit

Definition Classes
AnyRef
Annotations
@native()
final def notifyAll(): Unit

Definition Classes
AnyRef
Annotations
@native()

def partitionBifold[H[_, _], A, B, C](fa: F[A])(f: (A) ⇒ H[B, C])(implicit A: Alternative[F], H: Bifoldable[H]): (F[B], F[C])

Separate this Foldable into a Tuple by a separating function A => H[B, C] for some Bifoldable[H] Equivalent to Functor#map and then Alternative#separate.

scala> import cats.implicits._, cats.Foldable, cats.data.Const
scala> val list = List(1,2,3,4)
scala> Foldable[List].partitionBifold(list)(a => ("value " + a.toString(), if (a % 2 == 0) -a else a))
res0: (List[String], List[Int]) = (List(value 1, value 2, value 3, value 4),List(1, -2, 3, -4))
scala> Foldable[List].partitionBifold(list)(a => Const[Int, Nothing with Any](a))
res1: (List[Int], List[Nothing with Any]) = (List(1, 2, 3, 4),List())

Definition Classes: Foldable
Annotations: @noop()

def partitionBifoldM[G[_], H[_, _], A, B, C](fa: F[A])(f: (A) ⇒ G[H[B, C]])(implicit A: Alternative[F], M: Monad[G], H: Bifoldable[H]): G[(F[B], F[C])]
Separate this Foldable into a Tuple by an effectful separating function A => G[H[B, C]] for some Bifoldable[H] Equivalent to Traverse#traverse over Alternative#separate
Separate this Foldable into a Tuple by an effectful separating function A => G[H[B, C]] for some Bifoldable[H] Equivalent to Traverse#traverse over Alternative#separate
```
scala> import cats.implicits._, cats.Foldable, cats.data.Const
scala> val list = List(1,2,3,4)
`Const`'s second parameter is never instantiated, so we can use an impossible type:
scala> Foldable[List].partitionBifoldM(list)(a => Option(Const[Int, Nothing with Any](a)))
res0: Option[(List[Int], List[Nothing with Any])] = Some((List(1, 2, 3, 4),List()))
```
Definition Classes
Foldable
Annotations
@noop()
def partitionEither[A, B, C](fa: F[A])(f: (A) ⇒ Either[B, C])(implicit A: Alternative[F]): (F[B], F[C])
Separate this Foldable into a Tuple by a separating function A => Either[B, C] Equivalent to Functor#map and then Alternative#separate.
Separate this Foldable into a Tuple by a separating function A => Either[B, C] Equivalent to Functor#map and then Alternative#separate.
```
scala> import cats.implicits._
scala> val list = List(1,2,3,4)
scala> Foldable[List].partitionEither(list)(a => if (a % 2 == 0) Left(a.toString) else Right(a))
res0: (List[String], List[Int]) = (List(2, 4),List(1, 3))
scala> Foldable[List].partitionEither(list)(a => Right(a * 4))
res1: (List[Nothing], List[Int]) = (List(),List(4, 8, 12, 16))
```
Definition Classes
Foldable

def partitionEitherM[G[_], A, B, C](fa: F[A])(f: (A) ⇒ G[Either[B, C]])(implicit A: Alternative[F], M: Monad[G]): G[(F[B], F[C])]

Separate this Foldable into a Tuple by an effectful separating function A => G[Either[B, C]] Equivalent to Traverse#traverse over Alternative#separate

scala> import cats.implicits._, cats.Foldable, cats.Eval
scala> val list = List(1,2,3,4)
scala> val partitioned1 = Foldable[List].partitionEitherM(list)(a => if (a % 2 == 0) Eval.now(Either.left[String, Int](a.toString)) else Eval.now(Either.right[String, Int](a)))
Since `Eval.now` yields a lazy computation, we need to force it to inspect the result:
scala> partitioned1.value
res0: (List[String], List[Int]) = (List(2, 4),List(1, 3))
scala> val partitioned2 = Foldable[List].partitionEitherM(list)(a => Eval.later(Either.right(a * 4)))
scala> partitioned2.value
res1: (List[Nothing], List[Int]) = (List(),List(4, 8, 12, 16))

Definition Classes: Foldable
Annotations: @noop()

def reduce[A](fa: F[A])(implicit A: Semigroup[A]): A
Reduce a F[A] value using the given Semigroup[A].
Reduce a F[A] value using the given Semigroup[A].

Definition Classes
Reducible
def reduceA[G[_], A](fga: F[G[A]])(implicit G: Apply[G], A: Semigroup[A]): G[A]
Reduce a F[G[A]] value using Applicative[G] and Semigroup[A], a universal semigroup for G[_].
Reduce a F[G[A]] value using Applicative[G] and Semigroup[A], a universal semigroup for G[_].
This method is similar to reduce, but may short-circuit.
See this issue for an explanation of @noop usage.

Definition Classes
Reducible
Annotations
@noop()
def reduceK[G[_], A](fga: F[G[A]])(implicit G: SemigroupK[G]): G[A]
Reduce a F[G[A]] value using SemigroupK[G], a universal semigroup for G[_].
Reduce a F[G[A]] value using SemigroupK[G], a universal semigroup for G[_].
This method is a generalization of reduce.

Definition Classes
Reducible
def reduceLeft[A](fa: F[A])(f: (A, A) ⇒ A): A
Left-associative reduction on F using the function f.
Left-associative reduction on F using the function f.
Implementations should override this method when possible.

Definition Classes
Reducible
def reduceLeftM[G[_], A, B](fa: F[A])(f: (A) ⇒ G[B])(g: (B, A) ⇒ G[B])(implicit G: FlatMap[G]): G[B]
Monadic variant of reduceLeftTo.
Monadic variant of reduceLeftTo.

Definition Classes
Reducible
def reduceLeftOption[A](fa: F[A])(f: (A, A) ⇒ A): Option[A]
Reduce the elements of this structure down to a single value by applying the provided aggregation function in a left-associative manner.
Reduce the elements of this structure down to a single value by applying the provided aggregation function in a left-associative manner.
returns
None if the structure is empty, otherwise the result of combining the cumulative left-associative result of the f operation over all of the elements.
Definition Classes
Foldable
See also
reduceRightOption for a right-associative alternative.
Reducible#reduceLeft for a version that doesn't need to return an Option for structures that are guaranteed to be non-empty. Example:
scala> import cats.implicits._ scala> val l = List(6, 3, 2) This is equivalent to (6 - 3) - 2 scala> Foldable[List].reduceLeftOption(l)(_ - _) res0: Option[Int] = Some(1) scala> Foldable[List].reduceLeftOption(List.empty[Int])(_ - _) res1: Option[Int] = None
def reduceLeftToOption[A, B](fa: F[A])(f: (A) ⇒ B)(g: (B, A) ⇒ B): Option[B]
Overridden from Foldable for efficiency.
Overridden from Foldable for efficiency.

Definition Classes
Reducible → Foldable
def reduceMap[A, B](fa: F[A])(f: (A) ⇒ B)(implicit B: Semigroup[B]): B
Apply f to each element of fa and combine them using the given Semigroup[B].
Apply f to each element of fa and combine them using the given Semigroup[B].

Definition Classes
Reducible

def reduceMapA[G[_], A, B](fa: F[A])(f: (A) ⇒ G[B])(implicit G: Apply[G], B: Semigroup[B]): G[B]

Reduce in an Apply context by mapping the A values to G[B].

Reduce in an Apply context by mapping the A values to G[B]. combining the B values using the given Semigroup[B] instance.

Similar to reduceMapM, but may be less efficient.

scala> import cats.Reducible
scala> import cats.data.NonEmptyList
scala> import cats.implicits._
scala> val evenOpt: Int => Option[Int] =
     |   i => if (i % 2 == 0) Some(i) else None
scala> val allEven = NonEmptyList.of(2,4,6,8,10)
allEven: cats.data.NonEmptyList[Int] = NonEmptyList(2, 4, 6, 8, 10)
scala> val notAllEven = allEven ++ List(11)
notAllEven: cats.data.NonEmptyList[Int] = NonEmptyList(2, 4, 6, 8, 10, 11)
scala> Reducible[NonEmptyList].reduceMapA(allEven)(evenOpt)
res0: Option[Int] = Some(30)
scala> Reducible[NonEmptyList].reduceMapA(notAllEven)(evenOpt)
res1: Option[Int] = None

Definition Classes: Reducible

def reduceMapK[G[_], A, B](fa: F[A])(f: (A) ⇒ G[B])(implicit G: SemigroupK[G]): G[B]
Apply f to each element of fa and combine them using the given SemigroupK[G].
Apply f to each element of fa and combine them using the given SemigroupK[G].
```
scala> import cats._, cats.data._, cats.implicits._
scala> val f: Int => Endo[String] = i => (s => s + i)
scala> val x: Endo[String] = Reducible[NonEmptyList].reduceMapK(NonEmptyList.of(1, 2, 3))(f)
scala> val a = x("foo")
a: String = "foo321"
```
Definition Classes
Reducible
Annotations
@noop()

def reduceMapM[G[_], A, B](fa: F[A])(f: (A) ⇒ G[B])(implicit G: FlatMap[G], B: Semigroup[B]): G[B]

Reduce in an FlatMap context by mapping the A values to G[B].

Reduce in an FlatMap context by mapping the A values to G[B]. combining the B values using the given Semigroup[B] instance.

Similar to reduceLeftM, but using a Semigroup[B]. May be more efficient than reduceMapA.

scala> import cats.Reducible
scala> import cats.data.NonEmptyList
scala> import cats.implicits._
scala> val evenOpt: Int => Option[Int] =
     |   i => if (i % 2 == 0) Some(i) else None
scala> val allEven = NonEmptyList.of(2,4,6,8,10)
allEven: cats.data.NonEmptyList[Int] = NonEmptyList(2, 4, 6, 8, 10)
scala> val notAllEven = allEven ++ List(11)
notAllEven: cats.data.NonEmptyList[Int] = NonEmptyList(2, 4, 6, 8, 10, 11)
scala> Reducible[NonEmptyList].reduceMapM(allEven)(evenOpt)
res0: Option[Int] = Some(30)
scala> Reducible[NonEmptyList].reduceMapM(notAllEven)(evenOpt)
res1: Option[Int] = None

Definition Classes: Reducible

def reduceRight[A](fa: F[A])(f: (A, Eval[A]) ⇒ Eval[A]): Eval[A]
Right-associative reduction on F using the function f.
Right-associative reduction on F using the function f.

Definition Classes
Reducible
def reduceRightOption[A](fa: F[A])(f: (A, Eval[A]) ⇒ Eval[A]): Eval[Option[A]]
Reduce the elements of this structure down to a single value by applying the provided aggregation function in a right-associative manner.
Reduce the elements of this structure down to a single value by applying the provided aggregation function in a right-associative manner.
returns
None if the structure is empty, otherwise the result of combining the cumulative right-associative result of the f operation over the A elements.
Definition Classes
Foldable
See also
reduceLeftOption for a left-associative alternative
Reducible#reduceRight for a version that doesn't need to return an Option for structures that are guaranteed to be non-empty. Example:
scala> import cats.implicits._ scala> val l = List(6, 3, 2) This is equivalent to 6 - (3 - 2) scala> Foldable[List].reduceRightOption(l)((current, rest) => rest.map(current - _)).value res0: Option[Int] = Some(5) scala> Foldable[List].reduceRightOption(List.empty[Int])((current, rest) => rest.map(current - _)).value res1: Option[Int] = None
def reduceRightToOption[A, B](fa: F[A])(f: (A) ⇒ B)(g: (A, Eval[B]) ⇒ Eval[B]): Eval[Option[B]]
Overridden from Foldable for efficiency.
Overridden from Foldable for efficiency.

Definition Classes
Reducible → Foldable
def sequence[G[_], A](fga: F[G[A]])(implicit arg0: Applicative[G]): G[F[A]]
Thread all the G effects through the F structure to invert the structure from F[G[A]] to G[F[A]].
Thread all the G effects through the F structure to invert the structure from F[G[A]] to G[F[A]].
Example:
```
scala> import cats.implicits._
scala> val x: List[Option[Int]] = List(Some(1), Some(2))
scala> val y: List[Option[Int]] = List(None, Some(2))
scala> x.sequence
res0: Option[List[Int]] = Some(List(1, 2))
scala> y.sequence
res1: Option[List[Int]] = None
```
Definition Classes
Traverse
def sequence_[G[_], A](fga: F[G[A]])(implicit arg0: Applicative[G]): G[Unit]
Sequence F[G[A]] using Applicative[G].
Sequence F[G[A]] using Applicative[G].
This is similar to traverse_ except it operates on F[G[A]] values, so no additional functions are needed.
For example:
```
scala> import cats.implicits._
scala> val F = Foldable[List]
scala> F.sequence_(List(Option(1), Option(2), Option(3)))
res0: Option[Unit] = Some(())
scala> F.sequence_(List(Option(1), None, Option(3)))
res1: Option[Unit] = None
```
Definition Classes
Foldable
def size[A](fa: F[A]): Long
The size of this UnorderedFoldable.
The size of this UnorderedFoldable.
This is overridden in structures that have more efficient size implementations (e.g. Vector, Set, Map).
Note: will not terminate for infinite-sized collections.

Definition Classes
UnorderedFoldable
final def synchronized[T0](arg0: ⇒ T0): T0

Definition Classes
AnyRef
def takeWhile_[A](fa: F[A])(p: (A) ⇒ Boolean): List[A]
Convert F[A] to a List[A], retaining only initial elements which match p.
Convert F[A] to a List[A], retaining only initial elements which match p.

Definition Classes
Foldable
def toIterable[A](fa: F[A]): Iterable[A]
Convert F[A] to an Iterable[A].
Convert F[A] to an Iterable[A].
This method may be overridden for the sake of performance, but implementers should take care not to force a full materialization of the collection.

Definition Classes
Foldable
def toList[A](fa: F[A]): List[A]
Convert F[A] to a List[A].
Convert F[A] to a List[A].

Definition Classes
Foldable
def toNonEmptyList[A](fa: F[A]): NonEmptyList[A]

Definition Classes
Reducible
def toString(): String

Definition Classes
AnyRef → Any
def traverse[G[_], A, B](fa: F[A])(f: (A) ⇒ G[B])(implicit arg0: Applicative[G]): G[F[B]]
Given a function which returns a G effect, thread this effect through the running of this function on all the values in F, returning an F[B] in a G context.
Given a function which returns a G effect, thread this effect through the running of this function on all the values in F, returning an F[B] in a G context.
Example:
```
scala> import cats.implicits._
scala> def parseInt(s: String): Option[Int] = Either.catchOnly[NumberFormatException](s.toInt).toOption
scala> List("1", "2", "3").traverse(parseInt)
res0: Option[List[Int]] = Some(List(1, 2, 3))
scala> List("1", "two", "3").traverse(parseInt)
res1: Option[List[Int]] = None
```
Definition Classes
NonEmptyTraverse → Traverse
def traverseWithIndexM[G[_], A, B](fa: F[A])(f: (A, Int) ⇒ G[B])(implicit G: Monad[G]): G[F[B]]
Akin to traverse, but also provides the value's index in structure F when calling the function.
Akin to traverse, but also provides the value's index in structure F when calling the function.
This performs the traversal in a single pass but requires that effect G is monadic. An applicative traversal can be performed in two passes using zipWithIndex followed by traverse.

Definition Classes
Traverse
def traverse_[G[_], A, B](fa: F[A])(f: (A) ⇒ G[B])(implicit G: Applicative[G]): G[Unit]
Traverse F[A] using Applicative[G].
Traverse F[A] using Applicative[G].
A values will be mapped into G[B] and combined using Applicative#map2.
For example:
```
scala> import cats.implicits._
scala> def parseInt(s: String): Option[Int] = Either.catchOnly[NumberFormatException](s.toInt).toOption
scala> val F = Foldable[List]
scala> F.traverse_(List("333", "444"))(parseInt)
res0: Option[Unit] = Some(())
scala> F.traverse_(List("333", "zzz"))(parseInt)
res1: Option[Unit] = None
```
This method is primarily useful when G[_] represents an action or effect, and the specific A aspect of G[A] is not otherwise needed.
Definition Classes
Foldable

def tupleLeft[A, B](fa: F[A], b: B): F[(B, A)]

Tuples the A value in F[A] with the supplied B value, with the B value on the left.

Example:

scala> import scala.collection.immutable.Queue
scala> import cats.Functor
scala> import cats.implicits.catsStdInstancesForQueue

scala> Functor[Queue].tupleLeft(Queue("hello", "world"), 42)
res0: scala.collection.immutable.Queue[(Int, String)] = Queue((42,hello), (42,world))

Definition Classes: Functor

def tupleRight[A, B](fa: F[A], b: B): F[(A, B)]

Tuples the A value in F[A] with the supplied B value, with the B value on the right.

Example:

scala> import scala.collection.immutable.Queue
scala> import cats.Functor
scala> import cats.implicits.catsStdInstancesForQueue

scala> Functor[Queue].tupleRight(Queue("hello", "world"), 42)
res0: scala.collection.immutable.Queue[(String, Int)] = Queue((hello,42), (world,42))

Definition Classes: Functor

def unorderedFold[A](fa: F[A])(implicit arg0: CommutativeMonoid[A]): A

Definition Classes
Foldable → UnorderedFoldable
def unorderedFoldMap[A, B](fa: F[A])(f: (A) ⇒ B)(implicit arg0: CommutativeMonoid[B]): B

Definition Classes
Foldable → UnorderedFoldable
def unorderedSequence[G[_], A](fga: F[G[A]])(implicit arg0: CommutativeApplicative[G]): G[F[A]]

Definition Classes
Traverse → UnorderedTraverse
def unorderedTraverse[G[_], A, B](sa: F[A])(f: (A) ⇒ G[B])(implicit arg0: CommutativeApplicative[G]): G[F[B]]

Definition Classes
Traverse → UnorderedTraverse
def unzip[A, B](fab: F[(A, B)]): (F[A], F[B])
Un-zips an F[(A, B)] consisting of element pairs or Tuple2 into two separate F's tupled.
Un-zips an F[(A, B)] consisting of element pairs or Tuple2 into two separate F's tupled.
NOTE: Check for effect duplication, possibly memoize before
```
scala> import cats.Functor
scala> import cats.implicits.catsStdInstancesForList

scala> Functor[List].unzip(List((1,2), (3, 4)))
res0: (List[Int], List[Int]) = (List(1, 3),List(2, 4))
```
Definition Classes
Functor
Annotations
@noop()
def void[A](fa: F[A]): F[Unit]
Empty the fa of the values, preserving the structure
Empty the fa of the values, preserving the structure
Example:
```
scala> import cats.Functor
scala> import cats.implicits.catsStdInstancesForList

scala> Functor[List].void(List(1,2,3))
res0: List[Unit] = List((), (), ())
```
Definition Classes
Functor
final def wait(): Unit

Definition Classes
AnyRef
Annotations
@throws( ... )
final def wait(arg0: Long, arg1: Int): Unit

Definition Classes
AnyRef
Annotations
@throws( ... )
final def wait(arg0: Long): Unit

Definition Classes
AnyRef
Annotations
@throws( ... ) @native()
def widen[A, B >: A](fa: F[A]): F[B]
Lifts natural subtyping covariance of covariant Functors.
Lifts natural subtyping covariance of covariant Functors.
NOTE: In certain (perhaps contrived) situations that rely on universal equality this can result in a ClassCastException, because it is implemented as a type cast. It could be implemented as map(identity), but according to the functor laws, that should be equal to fa, and a type cast is often much more performant. See this example of widen creating a ClassCastException.
Example:
```
scala> import cats.Functor
scala> import cats.implicits.catsStdInstancesForOption

scala> val s = Some(42)
scala> Functor[Option].widen(s)
res0: Option[Int] = Some(42)
```
Definition Classes
Functor
def zipWithIndex[A](fa: F[A]): F[(A, Int)]
Traverses through the structure F, pairing the values with assigned indices.
Traverses through the structure F, pairing the values with assigned indices.
The behavior is consistent with the Scala collection library's zipWithIndex for collections such as List.

Definition Classes
Traverse

Packages

NonEmptyTraverse

Companion object NonEmptyTraverse

trait NonEmptyTraverse[F[_]] extends Traverse[F] with Reducible[F]

Abstract Value Members

Concrete Value Members

Inherited from Reducible[F]

Inherited from Traverse[F]

Inherited from UnorderedTraverse[F]

Inherited from Foldable[F]

Inherited from UnorderedFoldable[F]

Inherited from Functor[F]

Inherited from Invariant[F]

Inherited from Serializable

Inherited from Serializable

Inherited from AnyRef

Inherited from Any

Ungrouped

Packages

NonEmptyTraverse 

Companion object NonEmptyTraverse

trait NonEmptyTraverse[F[_]] extends Traverse[F] with Reducible[F]

Abstract Value Members

Concrete Value Members

Inherited from Reducible[F]

Inherited from Traverse[F]

Inherited from UnorderedTraverse[F]

Inherited from Foldable[F]

Inherited from UnorderedFoldable[F]

Inherited from Functor[F]

Inherited from Invariant[F]

Inherited from Serializable

Inherited from Serializable

Inherited from AnyRef

Inherited from Any

Ungrouped

NonEmptyTraverse