Type Members

1.  final case class -\/[A, B](a: A) extends \/[A, B] with Product with Serializable

   A left disjunction

   A left disjunction

   Often used to represent the failure case of a result

2.  sealed class :+:[M, N] extends AnyRef

   The coproduct (or free product) of monoids M and N.

   The coproduct (or free product) of monoids M and N. Conceptually this is an alternating list of M and N values, with the identity as the empty list, and composition as list concatenation that combines adjacent elements when possible.

3.  type :<:[F[_], G[_]] = Inject[F, G]

   scalaz.Inject[F, G]

4.  type :≺:[F[_], G[_]] = Inject[F, G]

   scalaz.Inject[F, G]

5.  type <~[+F[_], -G[_]] = NaturalTransformation[G, F]

   A scalaz.NaturalTransformation[G, F].

6.  type ===[A, B] = Leibniz[⊥, ⊤, A, B]

   (A === B) is a supertype of Leibniz[L,H,A,B]

7.  sealed abstract class ==>>[A, B] extends AnyRef

   An immutable map of key/value pairs implemented as a balanced binary tree

   An immutable map of key/value pairs implemented as a balanced binary tree

   Based on Haskell's Data.Map

   Since

   7.0.3

8.  type =?>[E, A] = Kleisli[Option, E, A]
9.  type @>[A, B] = LensFamily[A, A, B, B]
   See also

   scalaz.Lens

10.  type @?>[A, B] = PLensFamily[A, A, B, B]
    See also

    scalaz.PLens

11.  type @@[T, Tag] = scalaz.TagKind.@@[T, Tag]

    Tag a type T with Tag.

    Tag a type T with Tag.

    The resulting type is used to discriminate between type class instances.

    See also

    scalaz.Tag and scalaz.Tags Credit to Miles Sabin for the idea.

12.  abstract class Adjunction[F[_], G[_]] extends AnyRef

    An adjunction formed by two functors F and G such that F is left-adjoint to G.

    An adjunction formed by two functors F and G such that F is left-adjoint to G. The composite functor GF is a monad and the composite functor FG is a comonad.

    The minimal definition is either (unit, counit) or (leftAdjunct, rightAdjunct)

13.  sealed abstract class AdjunctionInstances extends AnyRef
14.  trait Align[F[_]] extends Functor[F]

15.  sealed abstract class Alpha extends Product with Serializable

    An algebraic data type representing the characters 'a' to 'z'

16.  sealed abstract class AlphaInstances extends AnyRef
17.  final case class Alter[F[_], A](f: F[A]) extends Product with Serializable

    Derive a Semigroup or Monoid instance from a Plus or PlusEmpty.

    Derive a Semigroup or Monoid instance from a Plus or PlusEmpty.

    https://hackage.haskell.org/package/reducers-3.12.1/docs/Data-Semigroup-Alt.html#t:Alter

18.  sealed abstract class AlterInstances extends AlterInstances0
19.  sealed abstract class AlterInstances0 extends AnyRef
20.  type Alternative[F[_]] = ApplicativePlus[F]
21.  final case class Ap[F[_], A](f: F[A]) extends Product with Serializable

    Derive a Semigroup or Monoid instance from an Apply or Applicative.

    Derive a Semigroup or Monoid instance from an Apply or Applicative.

    https://hackage.haskell.org/package/reducers-3.12.1/docs/Data-Semigroup-Applicative.html#t:Ap

22.  sealed abstract class ApInstances extends ApInstances0
23.  sealed abstract class ApInstances0 extends AnyRef
24.  trait Applicative[F[_]] extends Apply[F] with ApplicativeDivisible[F]

    Applicative Functor, described in Applicative Programming with Effects

    Applicative Functor, described in Applicative Programming with Effects

    Whereas a scalaz.Functor allows application of a pure function to a value in a context, an Applicative also allows application of a function in a context to a value in a context (ap).

    It follows that a pure function can be applied to arguments in a context. (See apply2, apply3, ... )

    Applicative instances come in a few flavours:

    • All scalaz.Monads are also Applicative
    • Any scalaz.Monoid can be treated as an Applicative (see scalaz.Monoid#applicative)
    • Zipping together corresponding elements of Naperian data structures (those of of a fixed, possibly infinite shape)

    See also

    scalaz.Applicative.ApplicativeLaw

25.  trait ApplicativeDivisible[F[_]] extends ApplyDivide[F]

    an invariant parent of Applicative / Divisible

26.  trait ApplicativePlus[F[_]] extends Applicative[F] with PlusEmpty[F]

    scalaz.Applicative combined with scalaz.PlusEmpty.

27.  trait Apply[F[_]] extends Functor[F] with ApplyDivide[F]

    scalaz.Applicative without point.

    scalaz.Applicative without point.

    See also

    scalaz.Apply.ApplyLaw

28.  trait ApplyDivide[F[_]] extends InvariantFunctor[F]

29.  trait Arrow[=>:[_, _]] extends Split[=>:] with Strong[=>:] with Category[=>:]

    A scalaz.Category supporting all ordinary functions, as well as combining arrows product-wise.

    A scalaz.Category supporting all ordinary functions, as well as combining arrows product-wise. Every Arrow forms a scalaz.Contravariant in one type parameter, and a scalaz.Applicative in the other, just as with ordinary functions.

30.  trait Associative[=>:[_, _]] extends AnyRef

31.  trait Band[F] extends Semigroup[F]

    scalaz.Semigroup which is also idempotent, i.e.

    scalaz.Semigroup which is also idempotent, i.e. appending a value with itself results in the same value.

    See also

    scalaz.Band.BandLaw

32.  trait BiConstrainedNaturalTransformation[F[_, _], G[_, _], C[_], E[_]] extends AnyRef

    A constrained transformation natural in both sides of a bifunctor

33.  trait BiNaturalTransformation[-F[_, _], +G[_, _]] extends AnyRef

    A function universally quantified over two parameters.

34.  trait Bifoldable[F[_, _]] extends AnyRef

    A type giving rise to two unrelated scalaz.Foldables.

35.  trait Bifunctor[F[_, _]] extends AnyRef

    A type giving rise to two unrelated scalaz.Functors.

36.  final class BijectionT[F[_], G[_], A, B] extends AnyRef
37.  sealed abstract class BijectionTInstances extends BijectionTInstances0
38.  sealed abstract class BijectionTInstances0 extends AnyRef
39.  trait Bind[F[_]] extends Apply[F]

    An scalaz.Apply functor, where a lifted function can introduce new values _and_ new functor context to be incorporated into the lift context.

    An scalaz.Apply functor, where a lifted function can introduce new values _and_ new functor context to be incorporated into the lift context. The essential new operation of scalaz.Monads.

    See also

    scalaz.Bind.BindLaw

40.  trait BindRec[F[_]] extends Bind[F]

    scalaz.Bind capable of using constant stack space when doing recursive binds.

    scalaz.Bind capable of using constant stack space when doing recursive binds.

    Implementations of tailrecM should not make recursive calls without the @tailrec annotation.

    Based on Phil Freeman's work on stack safety in PureScript, described in Stack Safety for Free.

41.  trait Bitraverse[F[_, _]] extends Bifunctor[F] with Bifoldable[F]

    A type giving rise to two unrelated scalaz.Traverses.

42.  sealed abstract class CaseInsensitive[A] extends AnyRef
43.  sealed abstract class CaseInsensitiveInstances extends AnyRef
44.  trait Catchable[F[_]] extends AnyRef

    A context in which exceptions can be caught and thrown.

    A context in which exceptions can be caught and thrown.

    This class places no other class constraints on F, but it should be the case that exceptions raised via fail are caught by the nearest surrounding attempt and returned as a Left. In addition to catching explicitly raised exceptions via fail, we expect that attempt catch ambient exceptions that might occur when 'evaluating' an F.

    We can state the requirement that attempt catch all ambient exceptions by stipulating that for all total functions of the form g: forall A . F[Throwable \/ A] => B, g compose attempt is also total.

45.  trait Category[=>:[_, _]] extends Compose[=>:]

    scalaz.Compose with identity.

    scalaz.Compose with identity.

    See also

    scalaz.Category.CategoryLaw

46.  trait Choice[=>:[_, _]] extends Category[=>:]

47.  trait Coapplicative[F[_]] extends CoapplicativeCodivide[F]

    Coproduct analogue of Applicative

48.  trait CoapplicativeCodivide[F[_]] extends AnyRef

    Invariant parent of Coapplicative and Codivide

49.  trait Cobind[F[_]] extends Functor[F]

50.  abstract class Codensity[F[_], A] extends AnyRef
51.  sealed abstract class CodensityInstances extends AnyRef
52.  trait Codivide[F[_]] extends CoapplicativeCodivide[F]

    Coproduct analogue of Divide

53.  sealed abstract class Cofree[S[_], A] extends AnyRef

    A cofree comonad for some functor S, i.e.

    A cofree comonad for some functor S, i.e. an S-branching stream.

54.  sealed abstract class CofreeInstances extends CofreeInstances0
55.  sealed abstract class CofreeInstances0 extends CofreeInstances1
56.  sealed abstract class CofreeInstances1 extends CofreeInstances2
57.  sealed abstract class CofreeInstances2 extends CofreeInstances3
58.  sealed abstract class CofreeInstances3 extends CofreeInstances4
59.  sealed abstract class CofreeInstances4 extends AnyRef
60.  trait Cohoist[F[_[_], _]] extends ComonadTrans[F]
61.  final case class Cokleisli[F[_], A, B](run: (F[A]) ⇒ B) extends Product with Serializable
62.  sealed abstract class CokleisliInstances extends CokleisliInstances0
63.  sealed abstract class CokleisliInstances0 extends AnyRef
64.  trait Comonad[F[_]] extends Cobind[F]

65.  trait ComonadStore[F[_], S] extends Comonad[F]

66.  trait ComonadTrans[F[_[_], _]] extends AnyRef
67.  trait Compose[=>:[_, _]] extends AnyRef

68.  final case class Const[A, B](getConst: A) extends Product with Serializable
69.  sealed abstract class ConstInstances extends ConstInstances0
70.  sealed abstract class ConstInstances0 extends ConstInstances1
71.  sealed abstract class ConstInstances1 extends AnyRef
72.  trait ConstrainedNaturalTransformation[F[_], G[_], E[_]] extends AnyRef

    A constrained natural transformation

73.  type Cont[R, A] = IndexedContsT[scalaz.Id.Id, scalaz.Id.Id, R, R, A]

74.  type ContT[M[_], R, A] = IndexedContsT[scalaz.Id.Id, M, R, R, A]

75.  trait Contravariant[F[_]] extends InvariantFunctor[F]

    Contravariant functors.

    Contravariant functors. For example, functions provide a scalaz.Functor in their result type, but a scalaz.Contravariant for each argument type.

    Note that the dual of a scalaz.Functor is just a scalaz.Functor itself.

    Providing an instance of this is a useful alternative to marking a type parameter with - in Scala.

    See also

    scalaz.Contravariant.ContravariantLaw

76.  sealed abstract class ContravariantCoyoneda[F[_], A] extends AnyRef

    Decomposition of fi.contramap(k) into its components, as it is frequently convenient to apply k separately from sorting or whatever process with fi, even when B is unknown, which is very common.

    Decomposition of fi.contramap(k) into its components, as it is frequently convenient to apply k separately from sorting or whatever process with fi, even when B is unknown, which is very common.

    This is isomorphic to F as long as F itself is a contravariant functor. The homomorphism from F[A] to ContravariantCoyoneda[F,A] exists even when F is not a contravariant functor.

    See ContravariantCoyonedaUsage.scala in the scalaz source tree for an interesting usage demonstration.

    As ContravariantCoyoneda(o)(identity).unlift = o, further factoring can occur as follows, for free:

    ContravariantCoyoneda(o contramap g)(f).unlift =
      ContravariantCoyoneda(o)(g compose f).unlift

    See also

    https://hackage.haskell.org/package/kan-extensions-4.0.1/docs/Data-Functor-Contravariant-Coyoneda.html

77.  sealed abstract class ContravariantCoyonedaInstances extends AnyRef
78.  trait ContravariantDerives[F[_]] extends Derives[F] with Codivide[F] with Divisible[F]

79.  type Conts[W[_], R, A] = IndexedContsT[W, scalaz.Id.Id, R, R, A]

80.  type ContsT[W[_], M[_], R, A] = IndexedContsT[W, M, R, R, A]

81.  final case class Coproduct[F[_], G[_], A](run: \/[F[A], G[A]]) extends Product with Serializable

    F on the left, and G on the right, of scalaz.\/.

    F on the left, and G on the right, of scalaz.\/.

    run

    The underlying scalaz.\/.

82.  sealed abstract class CoproductInstances extends CoproductInstances0
83.  sealed abstract class CoproductInstances0 extends CoproductInstances1
84.  sealed abstract class CoproductInstances1 extends CoproductInstances2
85.  sealed abstract class CoproductInstances2 extends CoproductInstances3
86.  sealed abstract class CoproductInstances3 extends AnyRef
87.  final case class Cord(self: FingerTree[Int, String]) extends Product with Serializable

    A Cord is a purely functional data structure for efficiently storing and manipulating Strings that are potentially very long.

    A Cord is a purely functional data structure for efficiently storing and manipulating Strings that are potentially very long. Very similar to Rope[Char], but with better constant factors and a simpler interface since it's specialized for Strings.

88.  sealed abstract class CorecursiveList[A] extends AnyRef

    The corecursive list; i.e.

    The corecursive list; i.e. the arguments to unfold saved off to a data structure. Generally does not have methods itself; as with scalaz.NonEmptyList, it provides typeclass instances instead, and you typically import typeclass syntax to get methods.

    The corecursive list can be a very efficient way to represent "listlike" things in some cases; because it is so unlike "normal" collections, though, it's important to understand how its operations are implemented and what their performance characteristics are going to be. For example, using cons iteratively to add a bunch of elements to the beginning of a scala.collection.immutable.List is very efficient; it's very inefficient for corecursive list.

    Operations are generally designed to preserve the isomorphism with scalaz.EphemeralStream; for example, ap could be a "zipping" ap, but instead is a less efficient "combination" style. This means that the scalaz.Monad has the same behavior as that of scalaz.EphemeralStream and more traditional strict list structures.

89.  sealed abstract class CorecursiveListInstances extends AnyRef
90.  abstract class Corepresentable[F[_], X] extends AnyRef

    Corepresentable functors

91.  trait CovariantDerives[F[_]] extends Derives[F] with Coapplicative[F] with Applicative[F]

92.  sealed abstract class Coyoneda[F[_], A] extends AnyRef

    The dual view of the Yoneda lemma.

    The dual view of the Yoneda lemma. Also a free functor on F. This is isomorphic to F as long as F itself is a functor. The homomorphism from F[A] to Coyoneda[F,A] exists even when F is not a functor.

93.  sealed abstract class CoyonedaInstances extends CoyonedaInstances0
94.  sealed abstract class CoyonedaInstances0 extends CoyonedaInstances1
95.  sealed abstract class CoyonedaInstances1 extends CoyonedaInstances2
96.  sealed abstract class CoyonedaInstances10 extends AnyRef
97.  sealed abstract class CoyonedaInstances2 extends CoyonedaInstances3
98.  sealed abstract class CoyonedaInstances3 extends CoyonedaInstances4
99.  sealed abstract class CoyonedaInstances4 extends CoyonedaInstances5
100.  sealed abstract class CoyonedaInstances5 extends CoyonedaInstances6
101.  sealed abstract class CoyonedaInstances6 extends CoyonedaInstances7
102.  sealed abstract class CoyonedaInstances7 extends CoyonedaInstances8
103.  sealed abstract class CoyonedaInstances8 extends CoyonedaInstances9
104.  sealed abstract class CoyonedaInstances9 extends CoyonedaInstances10
105.  trait Cozip[F[_]] extends AnyRef

106.  type DLeft[A, B] = -\/[A, B]
107.  final class DList[A] extends AnyRef

     Difference lists: a data structure for O(1) append on lists.

     Difference lists: a data structure for O(1) append on lists. Based on Data.DList, a Haskell library by Don Stewart.

     A difference list is a function that given a list, returns the original contents of the difference list prepended at the given list.

     This structure supports O(1) append and snoc operations on lists, making it very useful for append-heavy uses, such as logging and pretty printing.

108.  sealed abstract class DListInstances extends AnyRef
109.  type DRight[A, B] = \/-[A, B]
110.  sealed abstract class Dequeue[A] extends AnyRef

     A Double-ended queue, based on the Bankers Double Ended Queue as described by C.

     A Double-ended queue, based on the Bankers Double Ended Queue as described by C. Okasaki in "Purely Functional Data Structures"

     A queue that allows items to be put onto either the front (cons) or the back (snoc) of the queue in constant time, and constant time access to the element at the very front or the very back of the queue. Dequeueing an element from either end is constant time when amortized over a number of dequeues.

     This queue maintains an invariant that whenever there are at least two elements in the queue, neither the front list nor back list are empty. In order to maintain this invariant, a dequeue from either side which would leave that side empty constructs the resulting queue by taking elements from the opposite side

111.  sealed abstract class DequeueInstances extends AnyRef
112.  trait Derives[F[_]] extends CoapplicativeCodivide[F] with ApplicativeDivisible[F]

113.  trait DiNaturalTransformation[F[_, _], G[_, _]] extends AnyRef
114.  sealed abstract class Diev[A] extends AnyRef

     Implementation of a Discrete Interval Encoding Tree http://web.engr.oregonstate.edu/~erwig/diet/ that is actually implemented using a Vector and is balanced at all times as a result.

115.  trait DievImplementation extends AnyRef
116.  sealed abstract class DievInstances extends DievImplementation
117.  sealed abstract class Digit extends Product with Serializable

     An algebraic data type representing the digits 0 - 9

118.  sealed abstract class DigitInstances extends AnyRef
119.  type Disjunction[A, B] = \/[A, B]
120.  sealed abstract class DisjunctionInstances extends DisjunctionInstances0
121.  sealed abstract class DisjunctionInstances0 extends DisjunctionInstances1
122.  sealed abstract class DisjunctionInstances1 extends DisjunctionInstances2
123.  sealed abstract class DisjunctionInstances2 extends AnyRef
124.  type DisjunctionT[F[_], A, B] = EitherT[F, A, B]
125.  trait Distributive[F[_]] extends Functor[F]

     Dual of scalaz.Traverse.

     Dual of scalaz.Traverse. To transform F[G[B]] to G[F[B]], you may use Traverse[F] and Applicative[G], but alternatively Functor[F] and Distributive[G], which permits greater sharing and nonstrictness.

126.  trait Divide[F[_]] extends Contravariant[F] with ApplyDivide[F]

     Divide is the contravariant analogue of scalaz.Apply

     Divide is the contravariant analogue of scalaz.Apply

     See also

     https://github.com/ekmett/contravariant/issues/18

127.  trait Divisible[F[_]] extends Divide[F] with ApplicativeDivisible[F]

     Divisible is the contravariant analogue of scalaz.Applicative

     Divisible is the contravariant analogue of scalaz.Applicative

     See also

     https://github.com/ekmett/contravariant/blob/v1.3.2/src/Data/Functor/Contravariant/Divisible.hs

     ZuriHac 2015 - Discrimination is Wrong: Improving Productivity

128.  sealed abstract class DualInstances extends DualInstances0
129.  sealed abstract class DualInstances0 extends AnyRef
130.  sealed abstract class Either3[A, B, C] extends Product with Serializable
131.  final case class EitherT[F[_], A, B](run: F[\/[A, B]]) extends Product with Serializable

     Represents a computation of type F[A \/ B].

     Represents a computation of type F[A \/ B].

     Example:

     val x: Option[String \/ Int] = Some(\/-(1))
     EitherT(x).map(1+).run // Some(\/-(2))

132.  sealed abstract class EitherTInstances extends EitherTInstances0
133.  sealed abstract class EitherTInstances0 extends EitherTInstances1
134.  sealed abstract class EitherTInstances1 extends EitherTInstances2
135.  sealed abstract class EitherTInstances2 extends EitherTInstances3
136.  sealed abstract class EitherTInstances3 extends EitherTInstances4
137.  sealed abstract class EitherTInstances4 extends EitherTInstances5
138.  sealed abstract class EitherTInstances5 extends AnyRef
139.  final case class Endo[A](run: (A) ⇒ A) extends Product with Serializable

     Endomorphisms.

     Endomorphisms. They have special properties among functions, so are captured in this newtype.

     run

     The captured function.

140.  final case class EndoByName[A](run: (⇒ A) ⇒ A) extends Product with Serializable

     Endomorphisms using by-name evaluation.

     Endomorphisms using by-name evaluation. They have special properties among functions, so are captured in this newtype.

     run

     The captured function.

141.  sealed abstract class EndoByNameInstances extends AnyRef
142.  sealed abstract class EndoInstances extends AnyRef
143.  final case class Endomorphic[=>:[_, _], A](run: =>:[A, A]) extends Product with Serializable

     Endomorphisms have special properties among arrows, so are captured in this newtype.

     Endomorphisms have special properties among arrows, so are captured in this newtype.

     Endomorphic[Function1, A] is equivalent to Endo[A]

144.  sealed abstract class EndomorphicInstances extends EndomorphicInstances0
145.  sealed abstract class EndomorphicInstances0 extends EndomorphicInstances1
146.  sealed abstract class EndomorphicInstances1 extends EndomorphicInstances2
147.  sealed abstract class EndomorphicInstances2 extends AnyRef
148.  trait Enum[F] extends Order[F]

     An scalaz.Orderable with discrete values.

149.  sealed abstract class EphemeralStream[A] extends AnyRef

     Like scala.collection.immutable.Stream, but doesn't save computed values.

     Like scala.collection.immutable.Stream, but doesn't save computed values. As such, it can be used to represent similar things, but without the space leak problem frequently encountered using that type.

150.  sealed abstract class EphemeralStreamInstances extends AnyRef
151.  trait Equal[F] extends AnyRef

     A type safe alternative to universal equality (scala.Any#==).

     A type safe alternative to universal equality (scala.Any#==).

     See also

     scalaz.Equal.EqualLaw

152.  final case class Failure[E, A](e: E) extends Validation[E, A] with Product with Serializable
153.  sealed abstract class FingerTree[V, A] extends AnyRef

     Finger trees with leaves of type A and Nodes that are annotated with type V.

     Finger trees with leaves of type A and Nodes that are annotated with type V.

     Finger Trees provide a base for implementations of various collection types, as described in "Finger trees: a simple general-purpose data structure", by Ralf Hinze and Ross Paterson. A gentle introduction is presented in the blog post "Monoids and Finger Trees" by Heinrich Apfelmus.

     This is done by choosing a suitable type to annotate the nodes. For example, a binary tree can be implemented by annotating each node with the size of its subtree, while a priority queue can be implemented by labelling the nodes by the minimum priority of its children.

     The operations on FingerTree enforce the constraint measured (in the form of a Reducer instance).

     Finger Trees have excellent (amortized) asymptotic performance:

     • Access to the first and last elements is O(1)
     • Appending/prepending a single value is O(1)
     • Concatenating two trees is (O lg min(l1, l2)) where l1 and l2 are their sizes
     • Random access to an element at n is O(lg min(n, l - n)), where l is the size of the tree.
     • Constructing a tree with n copies of a value is O(lg n).

     V

     The type of the annotations of the nodes (the measure)

     A

     The type of the elements stored at the leaves

     See also

     Finger trees: a simple general-purpose data structure

     http://apfelmus.nfshost.com/articles/monoid-fingertree.html

154.  sealed abstract class FingerTreeInstances extends AnyRef
155.  type FirstMaybe[A] = scalaz.TagKind.@@[Maybe[A], First]
156.  type FirstOf[A] = scalaz.TagKind.@@[A, FirstVal]
157.  type FirstOption[A] = scalaz.TagKind.@@[Option[A], First]
158.  trait FoldCase[A] extends AnyRef
159.  sealed abstract class FoldCaseInstances extends AnyRef
160.  trait Foldable[F[_]] extends AnyRef

     A type parameter implying the ability to extract zero or more values of that type.

161.  trait Foldable1[F[_]] extends Foldable[F]

     A scalaz.Foldable where foldMap is total over semigroups.

     A scalaz.Foldable where foldMap is total over semigroups. That is, toList cannot return an empty list.

162.  trait Forall[P[_]] extends AnyRef

     A universally quantified value

163.  trait Foralls extends AnyRef
164.  sealed abstract class Free[S[_], A] extends AnyRef

     A free monad for a type constructor S.

     A free monad for a type constructor S. Binding is done using the heap instead of the stack, allowing tail-call elimination.

165.  sealed abstract class FreeAp[F[_], A] extends AnyRef

     Free applicative functors.

     Free applicative functors. Less expressive than free monads, but more flexible to inspect and interpret.

166.  sealed abstract class FreeInstances extends FreeInstances0
167.  sealed abstract class FreeInstances0 extends FreeInstances1
168.  sealed abstract class FreeInstances1 extends FreeInstances2
169.  sealed abstract class FreeInstances2 extends FreeInstances3
170.  sealed abstract class FreeInstances3 extends FreeInstances4
171.  sealed abstract class FreeInstances4 extends AnyRef
172.  sealed abstract class FreeT[S[_], M[_], A] extends AnyRef
173.  sealed abstract class FreeTInstances extends FreeTInstances0
174.  sealed abstract class FreeTInstances0 extends FreeTInstances1
175.  sealed abstract class FreeTInstances1 extends FreeTInstances2
176.  sealed abstract class FreeTInstances2 extends FreeTInstances3
177.  sealed abstract class FreeTInstances3 extends FreeTInstances4
178.  sealed abstract class FreeTInstances4 extends FreeTInstances5
179.  sealed abstract class FreeTInstances5 extends FreeTInstances6
180.  sealed abstract class FreeTInstances6 extends AnyRef
181.  trait Functor[F[_]] extends InvariantFunctor[F]

     Functors, covariant by nature if not by Scala type.

     Functors, covariant by nature if not by Scala type. Their key operation is map, whose behavior is constrained only by type and the functor laws.

     Many useful functors also have natural scalaz.Apply or scalaz.Bind operations. Many also support scalaz.Traverse.

     See also

     scalaz.Functor.FunctorLaw

182.  trait Generator[C, Elem] extends AnyRef

     Generator a class of container of elements that knows how to efficiently apply a scalaz.Reducer to extract an answer by combining elements.

     Generator a class of container of elements that knows how to efficiently apply a scalaz.Reducer to extract an answer by combining elements. A Reducer may supply efficient left-to-right and right-to-left reduction strategies that a Generator may avail itself of.

183.  trait Generators extends AnyRef
184.  sealed abstract class Heap[A] extends AnyRef

     An efficient, asymptotically optimal, implementation of priority queues extended with support for efficient size.

     An efficient, asymptotically optimal, implementation of priority queues extended with support for efficient size.

     The implementation of 'Heap' is based on bootstrapped skew binomial heaps as described by: G. Brodal and C. Okasaki , "Optimal Purely Functional Priority Queues", Journal of Functional Programming 6:839-857 (1996),

     Based on the heaps Haskell library by Edward Kmett

185.  sealed abstract class HeapInstances extends AnyRef
186.  trait Hoist[F[_[_], _]] extends MonadTrans[F]
187.  final case class ICons[A](head: A, tail: IList[A]) extends IList[A] with Product with Serializable
188.  sealed abstract class IList[A] extends Product with Serializable

     Safe, invariant alternative to stdlib List.

     Safe, invariant alternative to stdlib List. Most methods on List have a sensible equivalent here, either on the IList interface itself or via typeclass instances (which are the same as those defined for stdlib List). All methods are total and stack-safe.

189.  sealed abstract class IListInstance0 extends AnyRef
190.  sealed abstract class IListInstances extends IListInstance0
191.  type IMap[A, B] = ==>>[A, B]
192.  sealed abstract case class INil[A] extends IList[A] with Product with Serializable
193.  type IRWS[-R, W, -S1, S2, A] = IndexedReaderWriterStateT[scalaz.Id.Id, R, W, S1, S2, A]
194.  type IRWST[F[_], -R, W, -S1, S2, A] = IndexedReaderWriterStateT[F, R, W, S1, S2, A]
195.  sealed abstract class ISet[A] extends AnyRef
     See also

     https://hackage.haskell.org/package/containers-0.5.7.1/docs/Data-Set.html

     https://github.com/haskell/containers/blob/v0.5.7.1/Data/Set/Base.hs

196.  sealed abstract class ISetInstances extends AnyRef
197.  trait IdInstances extends AnyRef

     Mixed into object Id in the package object scalaz.

198.  final case class IdT[F[_], A](run: F[A]) extends Product with Serializable
199.  sealed abstract class IdTInstances extends IdTInstances0
200.  sealed abstract class IdTInstances0 extends IdTInstances1
201.  sealed abstract class IdTInstances1 extends IdTInstances2
202.  sealed abstract class IdTInstances2 extends IdTInstances3
203.  sealed abstract class IdTInstances3 extends IdTInstances4
204.  sealed abstract class IdTInstances4 extends AnyRef
205.  sealed abstract class ImmutableArray[+A] extends AnyRef

     An immutable wrapper for arrays

     An immutable wrapper for arrays

     A

     type of the elements of the array

206.  sealed abstract class ImmutableArrayInstances extends AnyRef
207.  final class IndSeq[A] extends AnyRef

     Indexed sequences, based on scalaz.FingerTree

     Indexed sequences, based on scalaz.FingerTree

     The measure is the count of the preceding elements, provided by UnitReducer((e: Int) => 1).

208.  sealed abstract class IndSeqInstances extends AnyRef
209.  type IndexedCont[R, O, A] = IndexedContsT[scalaz.Id.Id, scalaz.Id.Id, R, O, A]

210.  type IndexedContT[M[_], R, O, A] = IndexedContsT[scalaz.Id.Id, M, R, O, A]

211.  type IndexedConts[W[_], R, O, A] = IndexedContsT[W, scalaz.Id.Id, R, O, A]

212.  final case class IndexedContsT[W[_], M[_], R, O, A](_run: (W[(A) ⇒ M[O]]) ⇒ M[R]) extends Product with Serializable
213.  trait IndexedContsTFunctions extends AnyRef
214.  abstract class IndexedContsTInstances extends IndexedContsTInstances0
215.  sealed abstract class IndexedContsTInstances0 extends IndexedContsTInstances1
216.  sealed abstract class IndexedContsTInstances1 extends IndexedContsTInstances2
217.  sealed abstract class IndexedContsTInstances2 extends AnyRef
218.  type IndexedReaderWriterState[-R, W, -S1, S2, A] = IndexedReaderWriterStateT[scalaz.Id.Id, R, W, S1, S2, A]

219.  sealed abstract class IndexedReaderWriterStateT[F[_], -R, W, -S1, S2, A] extends AnyRef

     A monad transformer stack yielding (R, S1) => F[(W, A, S2)].

220.  sealed abstract class IndexedReaderWriterStateTInstances extends IndexedReaderWriterStateTInstances0
221.  sealed abstract class IndexedReaderWriterStateTInstances0 extends IndexedReaderWriterStateTInstances1
222.  sealed abstract class IndexedReaderWriterStateTInstances1 extends AnyRef
223.  type IndexedState[-S1, S2, A] = IndexedStateT[scalaz.Id.Id, S1, S2, A]

224.  trait IndexedStateFunctions extends AnyRef
225.  sealed abstract class IndexedStateT[F[_], -S1, S2, A] extends AnyRef
226.  trait IndexedStateTFunctions extends AnyRef
227.  sealed abstract class IndexedStateTInstances extends IndexedStateTInstances0
228.  sealed abstract class IndexedStateTInstances0 extends IndexedStateTInstances1
229.  sealed abstract class IndexedStateTInstances1 extends IndexedStateTInstances2
230.  sealed abstract class IndexedStateTInstances2 extends IndexedStateTInstances3
231.  sealed abstract class IndexedStateTInstances3 extends AnyRef
232.  type IndexedStore[I, A, B] = IndexedStoreT[scalaz.Id.Id, I, A, B]

233.  final case class IndexedStoreT[F[_], +I, A, B](run: (F[(A) ⇒ B], I)) extends Product with Serializable
     See also

     scalaz.Lens

234.  trait IndexedStoreTFunctions extends AnyRef
235.  sealed abstract class IndexedStoreTInstances extends IndexedStoreTInstances0
236.  sealed abstract class IndexedStoreTInstances0 extends IndexedStoreTInstances1
237.  sealed abstract class IndexedStoreTInstances1 extends IndexedStoreTInstances2
238.  sealed abstract class IndexedStoreTInstances2 extends AnyRef
239.  sealed abstract class Inject[F[_], G[_]] extends ~>[F, G]

     Inject type class as described in "Data types a la carte" (Swierstra 2008).

     Inject type class as described in "Data types a la carte" (Swierstra 2008).

     See also

     http://www.staff.science.uu.nl/~swier004/Publications/DataTypesALaCarte.pdf

240.  sealed abstract class InjectInstances extends AnyRef
241.  case class Injective[T[_]]() extends Product with Serializable

     Given Injective[Foo]: If type Foo[A] = Foo[B] then A ~ B

     Given Injective[Foo]: If type Foo[A] = Foo[B] then A ~ B

     This represents an assertion that is used by other code that requires this condition.

242.  case class Injective2[T[_, _]]() extends Product with Serializable
243.  case class Injective3[T[_, _, _]]() extends Product with Serializable
244.  case class Injective4[T[_, _, _, _]]() extends Product with Serializable
245.  case class Injective5[T[_, _, _, _, _]]() extends Product with Serializable
246.  trait InvariantFunctor[F[_]] extends AnyRef

     Unary type constructor that supports an xmap operation that converts an F[A] to an F[B] given two functions, A => B and B => A.

     Unary type constructor that supports an xmap operation that converts an F[A] to an F[B] given two functions, A => B and B => A.

     An invariant functor must satisfy two laws:

     • identity - xmap(ma)(identity, identity) == ma
     • composite - xmap(xmap(ma, f1, g1), f2, g2) == xmap(ma, f2 compose f1, g1, compose g2)

     Also known as an exponential functor.

     See also

     https://hackage.haskell.org/packages/archive/invariant/latest/doc/html/Data-Functor-Invariant.html

     http://comonad.com/reader/2008/rotten-bananas/

     scalaz.InvariantFunctor.InvariantFunctorLaw

247.  trait IsEmpty[F[_]] extends PlusEmpty[F]

     Typeclass that permits testing whether some type with an empty representation is in fact empty.

248.  trait IsomorphismAlign[F[_], G[_]] extends Align[F] with IsomorphismFunctor[F, G]
249.  trait IsomorphismApplicative[F[_], G[_]] extends Applicative[F] with IsomorphismApply[F, G]
250.  trait IsomorphismApplicativePlus[F[_], G[_]] extends ApplicativePlus[F] with IsomorphismEmpty[F, G] with IsomorphismApplicative[F, G]
251.  trait IsomorphismApply[F[_], G[_]] extends Apply[F] with IsomorphismFunctor[F, G]
252.  trait IsomorphismArrow[F[_, _], G[_, _]] extends Arrow[F] with IsomorphismSplit[F, G] with IsomorphismStrong[F, G] with IsomorphismCategory[F, G]
253.  trait IsomorphismAssociative[F[_, _], G[_, _]] extends Associative[F]
254.  trait IsomorphismBand[F, G] extends Band[F] with IsomorphismSemigroup[F, G]
255.  trait IsomorphismBifoldable[F[_, _], G[_, _]] extends Bifoldable[F]
256.  trait IsomorphismBifunctor[F[_, _], G[_, _]] extends Bifunctor[F]
257.  trait IsomorphismBind[F[_], G[_]] extends Bind[F] with IsomorphismApply[F, G]
258.  trait IsomorphismBindRec[F[_], G[_]] extends BindRec[F] with IsomorphismBind[F, G]
259.  trait IsomorphismBitraverse[F[_, _], G[_, _]] extends Bitraverse[F] with IsomorphismBifunctor[F, G] with IsomorphismBifoldable[F, G]
260.  trait IsomorphismCatchable[F[_], G[_]] extends Catchable[F]
261.  trait IsomorphismCategory[F[_, _], G[_, _]] extends Category[F] with IsomorphismCompose[F, G]
262.  trait IsomorphismChoice[F[_, _], G[_, _]] extends Choice[F] with IsomorphismCategory[F, G]
263.  trait IsomorphismCobind[F[_], G[_]] extends Cobind[F] with IsomorphismFunctor[F, G]
264.  trait IsomorphismComonad[F[_], G[_]] extends Comonad[F] with IsomorphismCobind[F, G]
265.  trait IsomorphismComonadStore[F[_], G[_], S] extends ComonadStore[F, S] with IsomorphismComonad[F, G]
266.  trait IsomorphismCompose[F[_, _], G[_, _]] extends Compose[F]
267.  trait IsomorphismContravariant[F[_], G[_]] extends Contravariant[F]
268.  trait IsomorphismCozip[F[_], G[_]] extends Cozip[F]
269.  trait IsomorphismDivide[F[_], G[_]] extends Divide[F] with IsomorphismContravariant[F, G]
270.  trait IsomorphismDivisible[F[_], G[_]] extends Divisible[F] with IsomorphismDivide[F, G]
271.  trait IsomorphismEmpty[F[_], G[_]] extends PlusEmpty[F] with IsomorphismPlus[F, G]
272.  trait IsomorphismEnum[F, G] extends Enum[F] with IsomorphismOrder[F, G]
273.  trait IsomorphismEqual[F, G] extends Equal[F]
274.  trait IsomorphismFoldable[F[_], G[_]] extends Foldable[F]
275.  trait IsomorphismFoldable1[F[_], G[_]] extends Foldable1[F] with IsomorphismFoldable[F, G]
276.  trait IsomorphismFunctor[F[_], G[_]] extends Functor[F]
277.  trait IsomorphismInvariantFunctor[F[_], G[_]] extends InvariantFunctor[F]
278.  trait IsomorphismIsEmpty[F[_], G[_]] extends IsEmpty[F] with IsomorphismEmpty[F, G]
279.  trait IsomorphismMonad[F[_], G[_]] extends Monad[F] with IsomorphismApplicative[F, G] with IsomorphismBind[F, G]
280.  trait IsomorphismMonadError[F[_], G[_], S] extends MonadError[F, S] with IsomorphismMonad[F, G]
281.  trait IsomorphismMonadPlus[F[_], G[_]] extends MonadPlus[F] with IsomorphismEmpty[F, G] with IsomorphismMonad[F, G]
282.  trait IsomorphismMonadReader[F[_], G[_], E] extends MonadReader[F, E] with IsomorphismMonad[F, G]
283.  trait IsomorphismMonadState[F[_], G[_], S] extends MonadState[F, S] with IsomorphismMonad[F, G]
284.  trait IsomorphismMonadTell[F[_], G[_], S] extends MonadTell[F, S] with IsomorphismMonad[F, G]
285.  trait IsomorphismMonoid[F, G] extends Monoid[F] with IsomorphismSemigroup[F, G]
286.  trait IsomorphismNondeterminism[F[_], G[_]] extends Nondeterminism[F] with IsomorphismMonad[F, G]
287.  trait IsomorphismOptional[F[_], G[_]] extends Optional[F]
288.  trait IsomorphismOrder[F, G] extends Order[F]
289.  trait IsomorphismPlus[F[_], G[_]] extends Plus[F]
290.  trait IsomorphismProChoice[F[_, _], G[_, _]] extends ProChoice[F] with IsomorphismProfunctor[F, G]
291.  trait IsomorphismProfunctor[F[_, _], G[_, _]] extends Profunctor[F]
292.  trait IsomorphismSemiLattice[F, G] extends SemiLattice[F] with IsomorphismBand[F, G]
293.  trait IsomorphismSemigroup[F, G] extends Semigroup[F]
294.  trait IsomorphismShow[F, G] extends Show[F]
295.  trait IsomorphismSplit[F[_, _], G[_, _]] extends Split[F] with IsomorphismCompose[F, G]
296.  trait IsomorphismStrong[F[_, _], G[_, _]] extends Strong[F] with IsomorphismProfunctor[F, G]
297.  trait IsomorphismTraverse[F[_], G[_]] extends Traverse[F] with IsomorphismFoldable[F, G] with IsomorphismFunctor[F, G]
298.  trait IsomorphismTraverse1[F[_], G[_]] extends Traverse1[F] with IsomorphismTraverse[F, G] with IsomorphismFoldable1[F, G]
299.  trait IsomorphismUnzip[F[_], G[_]] extends Unzip[F]
300.  trait IsomorphismZip[F[_], G[_]] extends Zip[F]
301.  sealed abstract class Isomorphisms extends AnyRef
302.  final case class Kleisli[M[_], A, B](run: (A) ⇒ M[B]) extends Product with Serializable

     Represents a function A => M[B].

303.  abstract class KleisliInstances extends KleisliInstances0
304.  sealed abstract class KleisliInstances0 extends KleisliInstances1
305.  sealed abstract class KleisliInstances1 extends KleisliInstances2
306.  sealed abstract class KleisliInstances10 extends KleisliInstances11
307.  sealed abstract class KleisliInstances11 extends KleisliInstances12
308.  sealed abstract class KleisliInstances12 extends KleisliInstances13
309.  sealed abstract class KleisliInstances13 extends AnyRef
310.  sealed abstract class KleisliInstances2 extends KleisliInstances3
311.  sealed abstract class KleisliInstances3 extends KleisliInstances4
312.  sealed abstract class KleisliInstances4 extends KleisliInstances5
313.  sealed abstract class KleisliInstances5 extends KleisliInstances6
314.  sealed abstract class KleisliInstances6 extends KleisliInstances7
315.  sealed abstract class KleisliInstances7 extends KleisliInstances8
316.  sealed abstract class KleisliInstances8 extends KleisliInstances9
317.  sealed abstract class KleisliInstances9 extends KleisliInstances10
318.  trait Konst[A] extends AnyRef
319.  trait Lan[G[_], H[_], A] extends AnyRef

     The left Kan extension of H along G

320.  sealed abstract class LanInstances extends LanInstances0
321.  sealed abstract class LanInstances0 extends AnyRef
322.  type LastMaybe[A] = scalaz.TagKind.@@[Maybe[A], Last]
323.  type LastOf[A] = scalaz.TagKind.@@[A, LastVal]
324.  type LastOption[A] = scalaz.TagKind.@@[Option[A], Last]
325.  sealed abstract class LazyEither[A, B] extends AnyRef

     scala.Either, but with a value by name.

326.  sealed abstract class LazyEitherInstances extends AnyRef
327.  final case class LazyEitherT[F[_], A, B](run: F[LazyEither[A, B]]) extends Product with Serializable
328.  sealed abstract class LazyEitherTInstances extends LazyEitherTInstances0
329.  sealed abstract class LazyEitherTInstances0 extends LazyEitherTInstances1
330.  sealed abstract class LazyEitherTInstances1 extends AnyRef
331.  sealed abstract class LazyOption[A] extends Product with Serializable

     scala.Option, but with a value by name.

332.  sealed abstract class LazyOptionInstances extends AnyRef
333.  final case class LazyOptionT[F[_], A](run: F[LazyOption[A]]) extends Product with Serializable
334.  sealed abstract class LazyOptionTInstances extends LazyOptionTInstances0
335.  sealed abstract class LazyOptionTInstances0 extends LazyOptionTInstances1
336.  sealed abstract class LazyOptionTInstances1 extends AnyRef
337.  sealed abstract class LazyTuple2[A, B] extends AnyRef

     scala.Tuple2, but with values by name.

338.  sealed abstract class LazyTuple2Instances extends LazyTuple2Instances0
339.  sealed abstract class LazyTuple2Instances0 extends AnyRef
340.  sealed abstract class LazyTuple3[A, B, C] extends AnyRef

     scala.Tuple3, but with values by name.

341.  sealed abstract class LazyTuple3Instances extends LazyTuple3Instances0
342.  sealed abstract class LazyTuple3Instances0 extends AnyRef
343.  sealed abstract class LazyTuple4[A, B, C, D] extends AnyRef

     scala.Tuple4, but with values by name.

344.  sealed abstract class LazyTuple4Instances extends LazyTuple4Instances0
345.  sealed abstract class LazyTuple4Instances0 extends AnyRef
346.  final case class Left3[A, B, C](a: A) extends Either3[A, B, C] with Product with Serializable
347.  sealed abstract class Leibniz[-L, +H >: L, A >: L <: H, B >: L <: H] extends AnyRef

     Leibnizian equality: a better =:=

     Leibnizian equality: a better =:=

     This technique was first used in Typing Dynamic Typing (Baars and Swierstra, ICFP 2002).

     It is generalized here to handle subtyping so that it can be used with constrained type constructors.

     Leibniz[L,H,A,B] says that A = B, and that both of its types are between L and H. Subtyping lets you loosen the bounds on L and H.

     If you just need a witness that A = B, then you can use A===B which is a supertype of any Leibniz[L,H,A,B]

     The more refined types are useful if you need to be able to substitute into restricted contexts.

348.  sealed abstract class LeibnizF[A[_], B[_]] extends AnyRef
349.  sealed abstract class LeibnizInstances extends AnyRef
350.  type Lens[A, B] = LensFamily[A, A, B, B]

     A lens that doesn't transform the type of the record.

     A lens that doesn't transform the type of the record.

     See also

     scalaz.@>

351.  sealed abstract class LensFamily[A1, A2, B1, B2] extends AnyRef

     A Lens Family, offering a purely functional means to access and retrieve a field transitioning from type B1 to type B2 in a record simultaneously transitioning from type A1 to type A2.

     A Lens Family, offering a purely functional means to access and retrieve a field transitioning from type B1 to type B2 in a record simultaneously transitioning from type A1 to type A2. scalaz.Lens is a convenient alias for when A1 === A2, and B1 === B2.

     The term field should not be interpreted restrictively to mean a member of a class. For example, a lens family can address membership of a Set.

     A1

     The initial type of the record

     A2

     The final type of the record

     B1

     The initial type of the field

     B2

     The final type of the field

     See also

     scalaz.PLens

352.  trait LensFamilyFunctions extends AnyRef
353.  trait LensFunctions extends LensFamilyFunctions
354.  abstract class LensInstances extends LensInstances0
355.  sealed abstract class LensInstances0 extends AnyRef
356.  sealed abstract class Liskov[-A, +B] extends AnyRef

     Liskov substitutability: A better <:<

     Liskov substitutability: A better <:<

     A <: B holds whenever A could be used in any negative context that expects a B. (e.g. if you could pass an A into any function that expects a B.)

357.  sealed abstract class LiskovInstances extends AnyRef
358.  final case class ListT[M[_], A](run: M[IList[A]]) extends Product with Serializable

     ListT monad transformer.

359.  sealed abstract class ListTInstances extends ListTInstances1
360.  sealed abstract class ListTInstances1 extends ListTInstances2
361.  sealed abstract class ListTInstances2 extends AnyRef
362.  sealed abstract class MapInstances extends MapInstances0
363.  sealed abstract class MapInstances0 extends MapInstances1
364.  sealed abstract class MapInstances1 extends MapInstances2
365.  sealed abstract class MapInstances2 extends AnyRef
366.  type MaxMaybe[A] = scalaz.TagKind.@@[Maybe[A], Max]
367.  type MaxOf[A] = scalaz.TagKind.@@[A, MaxVal]
368.  type MaxOption[A] = scalaz.TagKind.@@[Option[A], Max]
369.  sealed abstract class Maybe[A] extends AnyRef

     An optional value

     An optional value

     A Maybe[A] will either be a wrapped A instance (Just[A]), or a lack of underlying A instance (Empty[A]).

     Maybe[A] is isomorphic to Option[A], however there are some differences between the two. Maybe is invariant in A while Option is covariant. Maybe[A] does not expose an unsafe get operation to access the underlying A value (that may not exist) like Option[A] does. Maybe[A] does not come with an implicit conversion to Iterable[A] (a trait with over a dozen super types).

370.  sealed abstract class MaybeInstances extends MaybeInstances0
371.  sealed abstract class MaybeInstances0 extends MaybeInstances1
372.  sealed abstract class MaybeInstances1 extends AnyRef
373.  final case class MaybeT[F[_], A](run: F[Maybe[A]]) extends Product with Serializable

     monad transformer for Maybe

374.  sealed abstract class MaybeTInstances extends MaybeTInstances0
375.  sealed abstract class MaybeTInstances0 extends MaybeTInstances1
376.  sealed abstract class MaybeTInstances1 extends MaybeTInstances2
377.  sealed abstract class MaybeTInstances2 extends MaybeTInstances3
378.  sealed abstract class MaybeTInstances3 extends AnyRef
379.  sealed abstract class Memo[K, V] extends AnyRef

     A function memoization strategy.

     A function memoization strategy. See companion for various instances employing various strategies.

380.  sealed abstract class MemoInstances extends AnyRef
381.  final case class Middle3[A, B, C](b: B) extends Either3[A, B, C] with Product with Serializable
382.  type MinMaybe[A] = scalaz.TagKind.@@[Maybe[A], Min]
383.  type MinOf[A] = scalaz.TagKind.@@[A, MinVal]
384.  type MinOption[A] = scalaz.TagKind.@@[Option[A], Min]
385.  trait Monad[F[_]] extends Applicative[F] with Bind[F]

     Monad, an scalaz.Applicative that also supports scalaz.Bind, circumscribed by the monad laws.

     Monad, an scalaz.Applicative that also supports scalaz.Bind, circumscribed by the monad laws.

     See also

     scalaz.Monad.MonadLaw

386.  trait MonadError[F[_], S] extends Monad[F]

387.  trait MonadListen[F[_], W] extends MonadTell[F, W]
388.  trait MonadPlus[F[_]] extends Monad[F] with ApplicativePlus[F]
     See also

     scalaz.Monad

     scalaz.PlusEmpty

389.  trait MonadReader[F[_], S] extends Monad[F]

390.  trait MonadState[F[_], S] extends Monad[F]

     The class of monads supporting the operations of scalaz.State.

391.  trait MonadTell[F[_], S] extends Monad[F]

     The class of monads supporting write operations

392.  trait MonadTrans[F[_[_], _]] extends AnyRef

     Class of monad transformers.

393.  trait Monoid[F] extends Semigroup[F]

     Provides an identity element (zero) to the binary append operation in scalaz.Semigroup, subject to the monoid laws.

     Provides an identity element (zero) to the binary append operation in scalaz.Semigroup, subject to the monoid laws.

     Example instances:

     • Monoid[Int]: zero and append are 0 and Int#+ respectively
     • Monoid[List[A]]: zero and append are Nil and List#++ respectively

     References:

     • http://mathworld.wolfram.com/Monoid.html

     See also

     scalaz.syntax.MonoidOps

     scalaz.Monoid.MonoidLaw

394.  sealed abstract class Name[+A] extends AnyRef

     Call by name

395.  trait NaturalTransformation[-F[_], +G[_]] extends AnyRef

     A universally quantified function, usually written as F ~> G, for symmetry with A => B.

     A universally quantified function, usually written as F ~> G, for symmetry with A => B.

     Can be used to encode first-class functor transformations in the same way functions encode first-class concrete value morphisms; for example, sequence from scalaz.Traverse and cosequence from scalaz.Distributive give rise to ([a]T[A[a]]) ~> ([a]A[T[a]]), for varying A and T constraints.

396.  trait NaturalTransformations extends AnyRef
397.  final class Need[+A] extends Name[A]

     Call by need

398.  final class NonEmptyList[A] extends AnyRef

     A singly-linked list that is guaranteed to be non-empty.

399.  sealed abstract class NonEmptyListInstances extends NonEmptyListInstances0
400.  sealed abstract class NonEmptyListInstances0 extends AnyRef
401.  trait Nondeterminism[F[_]] extends Monad[F]

     A context supporting nondeterministic choice.

     A context supporting nondeterministic choice. Unlike Monad.bind, which imposes a total order on the sequencing of effects throughout a computation, the choose and chooseAny operations let us partially order the sequencing of effects. Canonical instances are concurrent.Future and concurrent.Task, which run their arguments in parallel, returning whichever comes back 'first'.

     TODO - laws

402.  sealed trait NotNothing[A] extends AnyRef
403.  final class NullArgument[A, B] extends AnyRef
404.  sealed abstract class NullArgumentInstances extends NullArgumentInstances0
405.  sealed abstract class NullArgumentInstances0 extends AnyRef
406.  final class NullResult[A, B] extends AnyRef
407.  sealed abstract class NullResultInstances extends NullResultInstances0
408.  sealed abstract class NullResultInstances0 extends AnyRef
409.  final case class OneAnd[F[_], A](head: A, tail: F[A]) extends Product with Serializable

     A generalization of NonEmptyList to non-List things.

     A generalization of NonEmptyList to non-List things. For example, OneAnd[Vector, A] is a non-empty Vector of A.

     Only head and tail are provided as direct methods, because there's little you can do with a OneAnd without knowing a bit about F. So useful functions are provided in the form of typeclass instances on OneAnd's companion; in combination with syntax extensions provided by scalaz.syntax, OneAnd has a large possible set of methods available by importing. For example, Applicative on this requires ApplicativePlus[F], and Traverse1 on this requires Traverse[F]. See the companion documentation for a complete list of instances.

     Additionally, unlike λ[α => (α, F[α])], the behavior of typeclass operations on OneAnd should be preserved across the natural transformation to scalaz.NonEmptyList where one exists. That is it should "be like" a nonempty structure. For example, ap-ing two OneAnd[Vector, ?]s or NonEmptyLists of lengths *a* and *b* yields a sequence of same type of length *a*×*b*, but two λ[α => (α, Vector[α])]s of length *c* and *d* ap to one of length 1+(*c*–1)×(*d*–1). For another example, point of the former two yield a one-element sequence, but point of the latter yields a two-element sequence.

     Since

     7.0.3

410.  sealed abstract class OneAndInstances extends OneAndInstances0
411.  sealed abstract class OneAndInstances0 extends OneAndInstances1
412.  sealed abstract class OneAndInstances1 extends OneAndInstances2
413.  sealed abstract class OneAndInstances2 extends OneAndInstances3
414.  sealed abstract class OneAndInstances3 extends OneAndInstances4
415.  sealed abstract class OneAndInstances4 extends OneAndInstances5
416.  sealed abstract class OneAndInstances5 extends AnyRef
417.  final case class OneOr[F[_], A](run: \/[F[A], A]) extends Product with Serializable
     Since

     7.0.3

418.  sealed abstract class OneOrInstances extends OneOrInstances0
419.  sealed abstract class OneOrInstances0 extends OneOrInstances1
420.  sealed abstract class OneOrInstances1 extends OneOrInstances2
421.  sealed abstract class OneOrInstances2 extends OneOrInstances3
422.  sealed abstract class OneOrInstances3 extends OneOrInstances4
423.  sealed abstract class OneOrInstances4 extends OneOrInstances5
424.  sealed abstract class OneOrInstances5 extends OneOrInstances6
425.  sealed abstract class OneOrInstances6 extends AnyRef
426.  final case class OptionT[F[_], A](run: F[Option[A]]) extends Product with Serializable

     OptionT monad transformer.

427.  sealed abstract class OptionTInstances extends OptionTInstances0
428.  sealed abstract class OptionTInstances0 extends OptionTInstances1
429.  sealed abstract class OptionTInstances1 extends OptionTInstances2
430.  sealed abstract class OptionTInstances2 extends OptionTInstances3
431.  sealed abstract class OptionTInstances3 extends AnyRef
432.  trait Optional[F[_]] extends AnyRef

     Abstraction over a container/context which may or may not provide a value.

     Abstraction over a container/context which may or may not provide a value.

     F

     the container/context type

     See also

     syntax.OptionalOps

433.  sealed abstract class OrdSeq[A] extends Ops[FingerTree[LastOption[A], A]]

     Ordered sequences, based on scalaz.FingerTree

     Ordered sequences, based on scalaz.FingerTree

     a has a higher priority than b if Order[A].greaterThan(a, b).

     insert and ++ maintains the ordering.

     The measure is calculated with a Monoid[Option[A] @@ Last], whose append operation favours the first argument. Accordingly, the measuer of a node is the item with the highest priority contained recursively below that node.

434.  trait Order[F] extends Equal[F]

     Safer version of scala.math.Ordering.

435.  sealed abstract class Ordering extends Product with Serializable

     A ternary marker of how two values relate in an ordering.

     A ternary marker of how two values relate in an ordering.

     Note

     scalaz calls its version of scala.math.Ordering, scalaz.Order. This Ordering is analogous to the Ints returned by scala.math.Ordering.

436.  sealed abstract class OrderingInstances extends AnyRef
437.  type PIndexedState[-S1, S2, A] = IndexedStateT[scalaz.Id.Id, S1, S2, Option[A]]

438.  type PIndexedStateT[F[_], -S1, S2, A] = IndexedStateT[F, S1, S2, Option[A]]

439.  type PLens[A, B] = PLensFamily[A, A, B, B]

     A partial lens that doesn't transform the type of the record.

     A partial lens that doesn't transform the type of the record.

     See also

     scalaz.@?>

440.  sealed abstract class PLensFamily[A1, A2, B1, B2] extends AnyRef

     Partial Lens Families, offering a purely functional means to access and retrieve an optional field transitioning from type B1 to type B2 in a record that is simultaneously transitioning from type A1 to type A2.

     Partial Lens Families, offering a purely functional means to access and retrieve an optional field transitioning from type B1 to type B2 in a record that is simultaneously transitioning from type A1 to type A2. scalaz.PLens is a convenient alias for when A1 === A2, and B1 === B2.

     The term field should not be interpreted restrictively to mean a member of a class. For example, a partial lens family can address the nth element of a List.

     A1

     The initial type of the record

     A2

     The final type of the record

     B1

     The initial type of the optional field

     B2

     The final type of the optional field

     See also

     scalaz.Lens

441.  trait PLensFamilyFunctions extends PLensInstances
442.  trait PLensFunctions extends PLensInstances with PLensFamilyFunctions
443.  abstract class PLensInstances extends AnyRef
444.  type PState[S, A] = IndexedStateT[scalaz.Id.Id, S, S, Option[A]]

445.  type PStateT[F[_], S, A] = IndexedStateT[F, S, S, Option[A]]

446.  trait Plus[F[_]] extends AnyRef

     Universally quantified scalaz.Semigroup.

447.  trait PlusEmpty[F[_]] extends Plus[F]

     Universally quantified scalaz.Monoid.

448.  trait ProChoice[=>:[_, _]] extends Profunctor[=>:]

     Strength on a coproduct.

449.  trait Profunctor[=>:[_, _]] extends AnyRef

     Profunctors are covariant on the right and contravariant on the left.

450.  type RWS[-R, W, S, A] = IndexedReaderWriterStateT[scalaz.Id.Id, R, W, S, S, A]
451.  type RWST[F[_], -R, W, S, A] = IndexedReaderWriterStateT[F, R, W, S, S, A]
452.  trait Ran[G[_], H[_], A] extends AnyRef

     The right Kan extension of H along G

453.  type Reader[E, A] = Kleisli[scalaz.Id.Id, E, A]

454.  type ReaderT[F[_], E, A] = Kleisli[F, E, A]
455.  type ReaderWriterState[-R, W, S, A] = IndexedReaderWriterStateT[scalaz.Id.Id, R, W, S, S, A]

456.  type ReaderWriterStateT[F[_], -R, W, S, A] = IndexedReaderWriterStateT[F, R, W, S, S, A]

457.  trait ReaderWriterStateTFunctions extends AnyRef
458.  abstract class ReaderWriterStateTInstances extends ReaderWriterStateTInstances0
459.  sealed abstract class ReaderWriterStateTInstances0 extends IndexedReaderWriterStateTInstances
460.  trait Reducer[C, M] extends AnyRef

     A Reducer[C,M] is a scalaz.Semigroup[M] that maps values of type C through unit to values of type M.

     A Reducer[C,M] is a scalaz.Semigroup[M] that maps values of type C through unit to values of type M. A C-Reducer may also supply operations which tack on another C to an existing Semigroup M on the left or right. These specialized reductions may be more efficient in some scenarios and are used when appropriate by a scalaz.Generator. The names cons and snoc work by analogy to the synonymous operations in the list semigroup.

     Minimal definition: unit or snoc

     Based on the Reducer Haskell library by Edward Kmett (https://hackage.haskell.org/package/reducers).

461.  sealed abstract class ReducerInstances extends AnyRef
462.  abstract class Representable[F[_], X] extends AnyRef

     Representable functors, that is to say, those with isomorphisms to and from [a](X => a).

     Representable functors, that is to say, those with isomorphisms to and from [a](X => a). As such, all typeclasses and operations on [a](X => a), that is, fixed in X, can be trivially derived for F.

463.  sealed abstract class RepresentableInstances extends AnyRef
464.  final case class Right3[A, B, C](c: C) extends Either3[A, B, C] with Product with Serializable
465.  trait SemiLattice[F] extends Band[F]

     scalaz.Band which is also commutative, i.e.

     scalaz.Band which is also commutative, i.e. A + B == B + A

     See also

     scalaz.SemiLattice.SemiLatticeLaw

466.  trait Semigroup[F] extends AnyRef

     An associative binary operation, circumscribed by type and the semigroup laws.

     An associative binary operation, circumscribed by type and the semigroup laws. Unlike scalaz.Monoid, there is not necessarily a zero.

     See also

     scalaz.Semigroup.SemigroupLaw

     scalaz.syntax.SemigroupOps

     http://mathworld.wolfram.com/Semigroup.html

467.  trait Show[F] extends AnyRef

     A typeclass for conversion to textual representation, done via scalaz.Cord for efficiency.

468.  trait Split[=>:[_, _]] extends Compose[=>:]

     A scalaz.Compose (semigroupoid) permitting products.

469.  type State[S, A] = IndexedStateT[scalaz.Id.Id, S, S, A]

     A state transition, representing a function S => (S, A).

470.  trait StateFunctions extends IndexedStateFunctions
471.  type StateT[F[_], S, A] = IndexedStateT[F, S, S, A]

472.  trait StateTFunctions extends IndexedStateTFunctions
473.  abstract class StateTInstances extends StateTInstances0
474.  sealed abstract class StateTInstances0 extends StateTInstances1
475.  sealed abstract class StateTInstances1 extends StateTInstances2
476.  sealed abstract class StateTInstances2 extends StateTInstances3
477.  sealed abstract class StateTInstances3 extends IndexedStateTInstances
478.  type Store[A, B] = IndexedStoreT[scalaz.Id.Id, A, A, B]

479.  type StoreT[F[_], A, B] = IndexedStoreT[F, A, A, B]

480.  trait StoreTFunctions extends IndexedStoreTFunctions
481.  abstract class StoreTInstances extends StoreTInstances0
482.  sealed abstract class StoreTInstances0 extends StoreTInstances1
483.  sealed abstract class StoreTInstances1 extends StoreTInstances2
484.  sealed abstract class StoreTInstances2 extends IndexedStoreTInstances
485.  sealed class StreamT[M[_], A] extends AnyRef

     StreamT monad transformer.

486.  sealed abstract class StreamTInstances extends StreamTInstances0
487.  sealed abstract class StreamTInstances0 extends AnyRef
488.  case class StrictTree[A](rootLabel: A, subForest: Vector[StrictTree[A]]) extends Product with Serializable
     rootLabel

     The label at the root of this tree.

     subForest

     The child nodes of this tree.

489.  sealed abstract class StrictTreeInstances extends AnyRef
490.  final class StrictTreeUnzip[A1, A2] extends AnyVal
491.  trait Strong[=>:[_, _]] extends Profunctor[=>:]

     Strength on a product.

492.  final case class Success[E, A](a: A) extends Validation[E, A] with Product with Serializable
493.  sealed abstract class TagKind extends AnyRef
494.  final case class Tannen[F[_], G[_, _], A, B](f: F[G[A, B]]) extends Product with Serializable

     Composes a Functor on the outside of a Bifunctor.

     Composes a Functor on the outside of a Bifunctor.

     https://hackage.haskell.org/package/bifunctors-5.5/docs/Data-Bifunctor-Tannen.html#t:Tannen

495.  sealed abstract class TannenInstances extends TannenInstances0
496.  sealed abstract class TannenInstances0 extends AnyRef
497.  sealed abstract class TheseInstances extends TheseInstances0
498.  sealed abstract class TheseInstances0 extends TheseInstances1
499.  sealed abstract class TheseInstances1 extends AnyRef
500.  final case class TheseT[F[_], A, B](run: F[\&/[A, B]]) extends Product with Serializable
501.  sealed abstract class TheseTInstances extends TheseTInstances0
502.  sealed abstract class TheseTInstances0 extends TheseTInstances1
503.  sealed abstract class TheseTInstances1 extends AnyRef
504.  type Traced[A, B] = TracedT[scalaz.Id.Id, A, B]

505.  final case class TracedT[W[_], A, B](run: W[(A) ⇒ B]) extends Product with Serializable
     See also

     https://github.com/ekmett/comonad/blob/v4.2.7.2/src/Control/Comonad/Trans/Traced.hs

506.  sealed abstract class TracedTInstances extends TracedTInstances0
507.  sealed abstract class TracedTInstances0 extends TracedTInstances1
508.  sealed abstract class TracedTInstances1 extends TracedTInstances2
509.  sealed abstract class TracedTInstances2 extends TracedTInstances3
510.  sealed abstract class TracedTInstances3 extends TracedTInstances4
511.  sealed abstract class TracedTInstances4 extends TracedTInstances5
512.  sealed abstract class TracedTInstances5 extends AnyRef
513.  trait Traverse[F[_]] extends Functor[F] with Foldable[F]

     Idiomatic traversal of a structure, as described in The Essence of the Iterator Pattern.

     Idiomatic traversal of a structure, as described in The Essence of the Iterator Pattern.

     See also

     scalaz.Traverse.TraverseLaw

514.  trait Traverse1[F[_]] extends Traverse[F] with Foldable1[F]

     A scalaz.Traverse where traverse is total over scalaz.Applys.

     A scalaz.Traverse where traverse is total over scalaz.Applys. That is, toList cannot return an empty list.

515.  sealed abstract class Tree[A] extends AnyRef

     A multi-way tree, also known as a rose tree.

     A multi-way tree, also known as a rose tree. Also known as Cofree[Stream, A].

516.  sealed abstract class TreeInstances extends AnyRef
517.  final case class TreeLoc[A](tree: Tree[A], lefts: TreeForest[A], rights: TreeForest[A], parents: Parents[A]) extends Product with Serializable

     A rose-tree zipper.

     A rose-tree zipper. Represents a scalaz.Tree together with a position in that tree. Provides navigation, persistent update, insertion, and deletes.

     tree

     The currently selected node.

     lefts

     The left siblings of the current node.

     rights

     The right siblings of the current node.

     parents

     The parent contexts of the current node.

518.  sealed abstract class TreeLocInstances extends AnyRef
519.  trait Unapply[TC[_[_]], MA] extends AnyRef

     Represents a type MA that has been destructured into as a type constructor M[_] applied to type A, along with a corresponding type class instance TC[M].

     Represents a type MA that has been destructured into as a type constructor M[_] applied to type A, along with a corresponding type class instance TC[M].

     The implicit conversions in the companion object provide a means to obtain type class instances for partially applied type constructors, in lieu of direct compiler support as described in SI-2712.

     // Directly depending on Applicative[G]
     def traverse[G[_], B](f: A => G[B])(implicit G: Applicative[G]): G[F[B]] =
       G.traverse(self)(f)
     
     // Indirect lookup of the Applicative instance
     def traverseI[GB](f: A => GB)(implicit G: Unapply[Applicative, GB]): G.M[F[G.A]] /*G[F[B]*/ = {
       G.TC.traverse(self)(a => G(f(a)))
     }
     
     // Deforested version of traverseI
     def traverseI2[GB](f: A => GB)(implicit G: Unapply[Applicative, GB]): G.M[F[G.A]] /*G[F[B]*/ = {
       G.TC.traverse(self)(G.leibniz.onF(f))
     }
     
     // Old usage
     def stateTraverse1 {
       import scalaz._, Scalaz._
       import State.{State, stateMonad}
       val ls = List(1, 2, 3)
       val traverseOpt: Option[List[Int]] = ls.traverse(a => Some(a))
       val traverseState: State[Int, List[Int]] = ls.traverse[State[Int, ?], Int](a => State((x: Int) => (x + 1, a)))
     }
     
     // New usage
     def stateTraverse2 {
       import scalaz._, Scalaz._
       val ls = List(1, 2, 3)
       val traverseOpt: Option[List[Int]] = ls.traverseI(a => some(a))
       val traverseState = ls.traverseI(a => State((x: Int) => (x + 1, a)))
     }

     Credits to Miles Sabin.

     Annotations

     @implicitNotFound( ... )

520.  trait Unapply2[TC[_[_, _]], MAB] extends AnyRef
521.  trait Unapply21[TC[_[_, _], _], MAB] extends AnyRef
522.  trait UnapplyProduct[TC[_[_]], MA, MB] extends AnyRef
523.  sealed abstract class Unapply_0 extends Unapply_2
524.  sealed abstract class Unapply_2 extends Unapply_3
525.  sealed abstract class Unapply_3 extends Unapply_4
526.  sealed abstract class Unapply_4 extends AnyRef
527.  sealed abstract class UnitReducer[C, M] extends Reducer[C, M]
528.  type Unwriter[W, A] = UnwriterT[scalaz.Id.Id, W, A]

529.  final case class UnwriterT[F[_], U, A](run: F[(U, A)]) extends Product with Serializable

     This data type is isomorphic to WriterT, however, it is NOT a monad.

     This data type is isomorphic to WriterT, however, it is NOT a monad.

     It implements flatMap+map and drops the write value. There is no Monoid or Semigroup required. There is no point operation. You can switch between WriterT and UnwriterT with unary_+ and unary_-.

530.  trait UnwriterTFunctions extends AnyRef
531.  sealed abstract class UnwriterTInstances extends UnwriterTInstances0
532.  sealed abstract class UnwriterTInstances0 extends UnwriterTInstances1
533.  sealed abstract class UnwriterTInstances1 extends UnwriterTInstances2
534.  sealed abstract class UnwriterTInstances2 extends AnyRef
535.  trait Unzip[F[_]] extends AnyRef

536.  sealed abstract class Validation[E, A] extends Product with Serializable

     Represents either:

     Represents either:

     • Success(a), or
     • Failure(e).

     Isomorphic to scala.Either and scalaz.\/. The motivation for a Validation is to provide the instance Applicativea that accumulate failures through a scalaz.Semigroup[E].

     scalaz.NonEmptyList is commonly chosen as a type constructor for the type E. As a convenience, an alias scalaz.ValidationNel[E] is provided as a shorthand for scalaz.Validation[NonEmptyList[E]], and a method Validation#toValidationNel converts Validation[E] to ValidationNel[E].

     Example:

     import scalaz._, std.AllInstances._
     
     def parseInt(s: String): Validation[String, Int] =
       try { Success(s.toInt) } catch { case ex: NumberFormatException => Failure(ex.getMessage) }
     val V = Applicative[ValidationNel[String, ?]]
     
     val x: ValidationNel[String, Int] =
       V.apply2(parseInt("1.x").toValidationNel, parseInt("1..0").toValidationNel)(_ * _)
       // Failure(NonEmptyList(For input string: "1..0", For input string: "1.x"))

     E

     The type of the Failure

     A

     The type of the Success

537.  final class ValidationFlatMap[E, A] extends AnyVal
538.  sealed abstract class ValidationInstances extends ValidationInstances0
539.  sealed abstract class ValidationInstances0 extends ValidationInstances1
540.  sealed abstract class ValidationInstances1 extends ValidationInstances2
541.  sealed abstract class ValidationInstances2 extends ValidationInstances3
542.  sealed abstract class ValidationInstances3 extends AnyRef
543.  type ValidationNel[E, X] = Validation[NonEmptyList[E], X]

     An scalaz.Validation with a scalaz.NonEmptyList as the failure type.

544.  final case class Value[+A](value: A) extends Name[A] with Product with Serializable

     Call by value

545.  type Writer[W, A] = WriterT[scalaz.Id.Id, W, A]

546.  final case class WriterT[F[_], W, A](run: F[(W, A)]) extends Product with Serializable
547.  trait WriterTFunctions extends AnyRef
548.  sealed abstract class WriterTInstance5 extends WriterTInstances6
549.  sealed abstract class WriterTInstances extends WriterTInstances0
550.  sealed abstract class WriterTInstances0 extends WriterTInstances1
551.  sealed abstract class WriterTInstances1 extends WriterTInstances2
552.  sealed abstract class WriterTInstances10 extends WriterTInstances11
553.  sealed abstract class WriterTInstances11 extends WriterTInstances12
554.  sealed abstract class WriterTInstances12 extends WriterTInstances13
555.  sealed abstract class WriterTInstances13 extends WriterTInstances14
556.  sealed abstract class WriterTInstances14 extends WriterTInstances15
557.  sealed abstract class WriterTInstances15 extends AnyRef
558.  sealed abstract class WriterTInstances2 extends WriterTInstances3
559.  sealed abstract class WriterTInstances3 extends WriterTInstances4
560.  sealed abstract class WriterTInstances4 extends WriterTInstance5
561.  sealed abstract class WriterTInstances6 extends WriterTInstances7
562.  sealed abstract class WriterTInstances7 extends WriterTInstances8
563.  sealed abstract class WriterTInstances8 extends WriterTInstances9
564.  sealed abstract class WriterTInstances9 extends WriterTInstances10
565.  abstract class Yoneda[F[_], A] extends AnyRef

     The cofree functor generated by F.

     The cofree functor generated by F. The Yoneda lemma says that Yoneda[F,A] is isomorphic to F[A] for any functor F. The homomorphism from Yoneda[F,A] to F[A] exists even when we have forgotten that F is a functor. Can be seen as a partially applied map for the functor F.

566.  trait Zap[F[_], G[_]] extends AnyRef

     Functors that annihilate each other.

567.  sealed abstract class ZapInstances extends AnyRef
568.  trait Zip[F[_]] extends AnyRef

569.  final case class Zipper[+A](lefts: Stream[A], focus: A, rights: Stream[A]) extends Product with Serializable

     Provides a pointed stream, which is a non-empty zipper-like stream structure that tracks an index (focus) position in a stream.

     Provides a pointed stream, which is a non-empty zipper-like stream structure that tracks an index (focus) position in a stream. Focus can be moved forward and backwards through the stream, elements can be inserted before or after the focused position, and the focused item can be deleted.

     Based on the pointedlist library by Jeff Wheeler.

570.  sealed abstract class ZipperInstances extends AnyRef
571.  sealed abstract class \&/[A, B] extends Product with Serializable
     Since

     7.0.3

572.  sealed abstract class \/[A, B] extends Product with Serializable

     Represents a disjunction: a result that is either an A or a B.

     Represents a disjunction: a result that is either an A or a B.

     An instance of A \/ B is either a -\/[A] (aka a "left") or a \/-[B] (aka a "right").

     A common use of a disjunction is to explicitly represent the possibility of failure in a result as opposed to throwing an exception. By convention, the left is used for errors and the right is reserved for successes. For example, a function that attempts to parse an integer from a string may have a return type of NumberFormatException \/ Int. However, since there is no need to actually throw an exception, the type (A) chosen for the "left" could be any type representing an error and has no need to actually extend Exception.

     A \/ B is isomorphic to scala.Either[A, B], but \/ is right-biased for all Scala versions, so methods such as map and flatMap apply only in the context of the "right" case. This right bias makes \/ more convenient to use than scala.Either in a monadic context in Scala versions <2.12. Methods such as swap, swapped, and leftMap provide functionality that scala.Either exposes through left projections.

     A \/ B is also isomorphic to Validation[A, B]. The subtle but important difference is that Applicative instances for Validation accumulates errors ("lefts") while Applicative instances for \/ fail fast on the first "left" they evaluate. This fail-fast behavior allows \/ to have lawful Monad instances that are consistent with their Applicative instances, while Validation cannot.

573.  final case class \/-[A, B](b: B) extends \/[A, B] with Product with Serializable

     A right disjunction

     A right disjunction

     Often used to represent the success case of a result

574.  class unused extends deprecated

     Mark an explicit or implicit parameter as known to be unused, as shorthand for the longer form, useful in combination with -Ywarn-unused:explicits,implicits compiler options.

575.  type |-->[A, B] = IndexedStoreT[scalaz.Id.Id, B, B, A]
576.  type ~>[-F[_], +G[_]] = NaturalTransformation[F, G]

     A scalaz.NaturalTransformation[F, G].

577.  type ~~>[-F[_, _], +G[_, _]] = BiNaturalTransformation[F, G]
578.  type ∨[A, B] = \/[A, B]
579.  type ⊤ = Any
580.  type ⊥ = Nothing