MonadPlus

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

Equivalent to join(map(fa)(f)).

abstract def empty[A]: F[A]

abstract def plus[A](a: F[A], b: ⇒ F[A]): F[A]

abstract def point[A](a: ⇒ A): F[A]

final def !=(arg0: Any): Boolean

final def ##(): Int

final def ==(arg0: Any): Boolean

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

def ap2[A, B, C](fa: ⇒ F[A], fb: ⇒ F[B])(f: F[(A, B) ⇒ C]): F[C]

def ap3[A, B, C, D](fa: ⇒ F[A], fb: ⇒ F[B], fc: ⇒ F[C])(f: F[(A, B, C) ⇒ D]): F[D]

def ap4[A, B, C, D, E](fa: ⇒ F[A], fb: ⇒ F[B], fc: ⇒ F[C], fd: ⇒ F[D])(f: F[(A, B, C, D) ⇒ E]): F[E]

def ap5[A, B, C, D, E, R](fa: ⇒ F[A], fb: ⇒ F[B], fc: ⇒ F[C], fd: ⇒ F[D], fe: ⇒ F[E])(f: F[(A, B, C, D, E) ⇒ R]): F[R]

def ap6[A, B, C, D, E, FF, R](fa: ⇒ F[A], fb: ⇒ F[B], fc: ⇒ F[C], fd: ⇒ F[D], fe: ⇒ F[E], ff: ⇒ F[FF])(f: F[(A, B, C, D, E, FF) ⇒ R]): F[R]

def ap7[A, B, C, D, E, FF, G, R](fa: ⇒ F[A], fb: ⇒ F[B], fc: ⇒ F[C], fd: ⇒ F[D], fe: ⇒ F[E], ff: ⇒ F[FF], fg: ⇒ F[G])(f: F[(A, B, C, D, E, FF, G) ⇒ R]): F[R]

def ap8[A, B, C, D, E, FF, G, H, R](fa: ⇒ F[A], fb: ⇒ F[B], fc: ⇒ F[C], fd: ⇒ F[D], fe: ⇒ F[E], ff: ⇒ F[FF], fg: ⇒ F[G], fh: ⇒ F[H])(f: F[(A, B, C, D, E, FF, G, H) ⇒ R]): F[R]

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

Flipped variant of ap.

def applicativeLaw: ApplicativeLaw

val applicativePlusSyntax: ApplicativePlusSyntax[F]

val applicativeSyntax: ApplicativeSyntax[F]

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

Alias for map.

def apply10[A, B, C, D, E, FF, G, H, I, J, R](fa: ⇒ F[A], fb: ⇒ F[B], fc: ⇒ F[C], fd: ⇒ F[D], fe: ⇒ F[E], ff: ⇒ F[FF], fg: ⇒ F[G], fh: ⇒ F[H], fi: ⇒ F[I], fj: ⇒ F[J])(f: (A, B, C, D, E, FF, G, H, I, J) ⇒ R): F[R]

def apply11[A, B, C, D, E, FF, G, H, I, J, K, R](fa: ⇒ F[A], fb: ⇒ F[B], fc: ⇒ F[C], fd: ⇒ F[D], fe: ⇒ F[E], ff: ⇒ F[FF], fg: ⇒ F[G], fh: ⇒ F[H], fi: ⇒ F[I], fj: ⇒ F[J], fk: ⇒ F[K])(f: (A, B, C, D, E, FF, G, H, I, J, K) ⇒ R): F[R]

def apply12[A, B, C, D, E, FF, G, H, I, J, K, L, R](fa: ⇒ F[A], fb: ⇒ F[B], fc: ⇒ F[C], fd: ⇒ F[D], fe: ⇒ F[E], ff: ⇒ F[FF], fg: ⇒ F[G], fh: ⇒ F[H], fi: ⇒ F[I], fj: ⇒ F[J], fk: ⇒ F[K], fl: ⇒ F[L])(f: (A, B, C, D, E, FF, G, H, I, J, K, L) ⇒ R): F[R]

def apply2[A, B, C](fa: ⇒ F[A], fb: ⇒ F[B])(f: (A, B) ⇒ C): F[C]

def apply3[A, B, C, D](fa: ⇒ F[A], fb: ⇒ F[B], fc: ⇒ F[C])(f: (A, B, C) ⇒ D): F[D]

def apply4[A, B, C, D, E](fa: ⇒ F[A], fb: ⇒ F[B], fc: ⇒ F[C], fd: ⇒ F[D])(f: (A, B, C, D) ⇒ E): F[E]

def apply5[A, B, C, D, E, R](fa: ⇒ F[A], fb: ⇒ F[B], fc: ⇒ F[C], fd: ⇒ F[D], fe: ⇒ F[E])(f: (A, B, C, D, E) ⇒ R): F[R]

def apply6[A, B, C, D, E, FF, R](fa: ⇒ F[A], fb: ⇒ F[B], fc: ⇒ F[C], fd: ⇒ F[D], fe: ⇒ F[E], ff: ⇒ F[FF])(f: (A, B, C, D, E, FF) ⇒ R): F[R]

def apply7[A, B, C, D, E, FF, G, R](fa: ⇒ F[A], fb: ⇒ F[B], fc: ⇒ F[C], fd: ⇒ F[D], fe: ⇒ F[E], ff: ⇒ F[FF], fg: ⇒ F[G])(f: (A, B, C, D, E, FF, G) ⇒ R): F[R]

def apply8[A, B, C, D, E, FF, G, H, R](fa: ⇒ F[A], fb: ⇒ F[B], fc: ⇒ F[C], fd: ⇒ F[D], fe: ⇒ F[E], ff: ⇒ F[FF], fg: ⇒ F[G], fh: ⇒ F[H])(f: (A, B, C, D, E, FF, G, H) ⇒ R): F[R]

def apply9[A, B, C, D, E, FF, G, H, I, R](fa: ⇒ F[A], fb: ⇒ F[B], fc: ⇒ F[C], fd: ⇒ F[D], fe: ⇒ F[E], ff: ⇒ F[FF], fg: ⇒ F[G], fh: ⇒ F[H], fi: ⇒ F[I])(f: (A, B, C, D, E, FF, G, H, I) ⇒ R): F[R]

def applyApplicative: Applicative[[α]\/[F[α], α]]

Add a unit to any Apply to form an Applicative.

def applyLaw: ApplyLaw

val applySyntax: ApplySyntax[F]

final def asInstanceOf[T0]: T0

def bicompose[G[_, _]](implicit arg0: Bifunctor[G]): Bifunctor[[α, β]F[G[α, β]]]

The composition of Functor F and Bifunctor G, [x, y]F[G[x, y]], is a Bifunctor

def bindLaw: BindLaw

val bindSyntax: BindSyntax[F]

def clone(): AnyRef

def compose[G[_]](implicit G0: ApplicativePlus[G]): ApplicativePlus[[α]F[G[α]]]

The composition of ApplicativePlus F and G, [x]F[G[x]], is a ApplicativePlus

def compose[G[_]](implicit G0: PlusEmpty[G]): PlusEmpty[[α]F[G[α]]]

The composition of PlusEmpty F and G, [x]F[G[x]], is a PlusEmpty

def compose[G[_]](implicit G0: Plus[G]): Plus[[α]F[G[α]]]

The composition of Plus F and G, [x]F[G[x]], is a Plus

def compose[G[_]](implicit G0: Applicative[G]): Applicative[[α]F[G[α]]]

The composition of Applicatives F and G, [x]F[G[x]], is an Applicative

def compose[G[_]](implicit G0: Apply[G]): Apply[[α]F[G[α]]]

The composition of Applys F and G, [x]F[G[x]], is a Apply

def compose[G[_]](implicit G0: Functor[G]): Functor[[α]F[G[α]]]

The composition of Functors F and G, [x]F[G[x]], is a Functor

def counzip[A, B](a: \/[F[A], F[B]]): F[\/[A, B]]

final def eq(arg0: AnyRef): Boolean

def equals(arg0: Any): Boolean

def filter[A](fa: F[A])(f: (A) ⇒ Boolean): F[A]

Remove f-failing As in fa, by which we mean: in the expression filter(filter(fa)(f))(g), g will never be invoked for any a where f(a) returns false.

def filterM[A](l: List[A])(f: (A) ⇒ F[Boolean]): F[List[A]]

Filter l according to an applicative predicate.

def finalize(): Unit

def flip: Applicative[F]

An Applicative for F in which effects happen in the opposite order.

def forever[A, B](fa: F[A]): F[B]

Repeats a monadic action infinitely

def fpair[A](fa: F[A]): F[(A, A)]

Twin all As in fa.

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

Pair all As in fa with the result of function application.

def functorLaw: FunctorLaw

val functorSyntax: FunctorSyntax[F]

final def getClass(): Class[_]

def hashCode(): Int

def icompose[G[_]](implicit G0: Contravariant[G]): Contravariant[[α]F[G[α]]]

The composition of Functor F and Contravariant G, [x]F[G[x]], is contravariant.

def ifM[B](value: F[Boolean], ifTrue: ⇒ F[B], ifFalse: ⇒ F[B]): F[B]

if lifted into a binding.

def invariantFunctorLaw: InvariantFunctorLaw

val invariantFunctorSyntax: InvariantFunctorSyntax[F]

final def isInstanceOf[T0]: Boolean

def iterateUntil[A](f: F[A])(p: (A) ⇒ Boolean): F[A]

Execute an action repeatedly until its result satisfies the given predicate and return that result, discarding all others.

def iterateWhile[A](f: F[A])(p: (A) ⇒ Boolean): F[A]

Execute an action repeatedly until its result fails to satisfy the given predicate and return that result, discarding all others.

def join[A](ffa: F[F[A]]): F[A]

Sequence the inner F of FFA after the outer F, forming a single F[A].

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

Lift f into F.

def lift10[A, B, C, D, E, FF, G, H, I, J, R](f: (A, B, C, D, E, FF, G, H, I, J) ⇒ R): (F[A], F[B], F[C], F[D], F[E], F[FF], F[G], F[H], F[I], F[J]) ⇒ F[R]

def lift11[A, B, C, D, E, FF, G, H, I, J, K, R](f: (A, B, C, D, E, FF, G, H, I, J, K) ⇒ R): (F[A], F[B], F[C], F[D], F[E], F[FF], F[G], F[H], F[I], F[J], F[K]) ⇒ F[R]

def lift12[A, B, C, D, E, FF, G, H, I, J, K, L, R](f: (A, B, C, D, E, FF, G, H, I, J, K, L) ⇒ R): (F[A], F[B], F[C], F[D], F[E], F[FF], F[G], F[H], F[I], F[J], F[K], F[L]) ⇒ F[R]

def lift2[A, B, C](f: (A, B) ⇒ C): (F[A], F[B]) ⇒ F[C]

def lift3[A, B, C, D](f: (A, B, C) ⇒ D): (F[A], F[B], F[C]) ⇒ F[D]

def lift4[A, B, C, D, E](f: (A, B, C, D) ⇒ E): (F[A], F[B], F[C], F[D]) ⇒ F[E]

def lift5[A, B, C, D, E, R](f: (A, B, C, D, E) ⇒ R): (F[A], F[B], F[C], F[D], F[E]) ⇒ F[R]

def lift6[A, B, C, D, E, FF, R](f: (A, B, C, D, E, FF) ⇒ R): (F[A], F[B], F[C], F[D], F[E], F[FF]) ⇒ F[R]

def lift7[A, B, C, D, E, FF, G, R](f: (A, B, C, D, E, FF, G) ⇒ R): (F[A], F[B], F[C], F[D], F[E], F[FF], F[G]) ⇒ F[R]

def lift8[A, B, C, D, E, FF, G, H, R](f: (A, B, C, D, E, FF, G, H) ⇒ R): (F[A], F[B], F[C], F[D], F[E], F[FF], F[G], F[H]) ⇒ F[R]

def lift9[A, B, C, D, E, FF, G, H, I, R](f: (A, B, C, D, E, FF, G, H, I) ⇒ R): (F[A], F[B], F[C], F[D], F[E], F[FF], F[G], F[H], F[I]) ⇒ F[R]

def many[A](a: F[A]): F[List[A]]

A list of results acquired by repeating a.

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

Lift f into F and apply to F[A].

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

Lift apply(a), and apply the result to f.

def monadLaw: MonadLaw

def monadPlusLaw: MonadPlusLaw

val monadPlusSyntax: MonadPlusSyntax[F]

val monadSyntax: MonadSyntax[F]

def monoid[A]: Monoid[F[A]]

final def ne(arg0: AnyRef): Boolean

final def notify(): Unit

final def notifyAll(): Unit

def plusEmptyLaw: EmptyLaw

val plusEmptySyntax: PlusEmptySyntax[F]

def plusLaw: PlusLaw

val plusSyntax: PlusSyntax[F]

def product[G[_]](implicit G0: ApplicativePlus[G]): ApplicativePlus[[α](F[α], G[α])]

The product of ApplicativePlus F and G, [x](F[x], G[x]]), is a ApplicativePlus

def product[G[_]](implicit G0: PlusEmpty[G]): PlusEmpty[[α](F[α], G[α])]

The product of PlusEmpty F and G, [x](F[x], G[x]]), is a PlusEmpty

def product[G[_]](implicit G0: Plus[G]): Plus[[α](F[α], G[α])]

The product of Plus F and G, [x](F[x], G[x]]), is a Plus

def product[G[_]](implicit G0: Applicative[G]): Applicative[[α](F[α], G[α])]

The product of Applicatives F and G, [x](F[x], G[x]]), is an Applicative

def product[G[_]](implicit G0: Apply[G]): Apply[[α](F[α], G[α])]

The product of Applys F and G, [x](F[x], G[x]]), is a Apply

def product[G[_]](implicit G0: Functor[G]): Functor[[α](F[α], G[α])]

The product of Functors F and G, [x](F[x], G[x]]), is a Functor

final def pure[A](a: ⇒ A): F[A]

def replicateM[A](n: Int, fa: F[A]): F[List[A]]

Performs the action n times, returning the list of results.

def replicateM_[A](n: Int, fa: F[A]): F[Unit]

Performs the action n times, returning nothing.

def semigroup[A]: Semigroup[F[A]]

def separate[G[_, _], A, B](value: F[G[A, B]])(implicit G: Bifoldable[G]): (F[A], F[B])

Generalized version of Haskell's partitionEithers

def sequence[A, G[_]](as: G[F[A]])(implicit arg0: Traverse[G]): F[G[A]]

def sequence1[A, G[_]](as: G[F[A]])(implicit arg0: Traverse1[G]): F[G[A]]

def some[A](a: F[A]): F[List[A]]

empty or a non-empty list of results acquired by repeating a.

def strengthL[A, B](a: A, f: F[B]): F[(A, B)]

Inject a to the left of Bs in f.

def strengthR[A, B](f: F[A], b: B): F[(A, B)]

Inject b to the right of As in f.

def strongMonadPlusLaw: StrongMonadPlusLaw

final def synchronized[T0](arg0: ⇒ T0): T0

def toString(): String

def traverse[A, G[_], B](value: G[A])(f: (A) ⇒ F[B])(implicit G: Traverse[G]): F[G[B]]

def traverse1[A, G[_], B](value: G[A])(f: (A) ⇒ F[B])(implicit G: Traverse1[G]): F[G[B]]

def tuple2[A, B](fa: ⇒ F[A], fb: ⇒ F[B]): F[(A, B)]

def tuple3[A, B, C](fa: ⇒ F[A], fb: ⇒ F[B], fc: ⇒ F[C]): F[(A, B, C)]

def tuple4[A, B, C, D](fa: ⇒ F[A], fb: ⇒ F[B], fc: ⇒ F[C], fd: ⇒ F[D]): F[(A, B, C, D)]

def tuple5[A, B, C, D, E](fa: ⇒ F[A], fb: ⇒ F[B], fc: ⇒ F[C], fd: ⇒ F[D], fe: ⇒ F[E]): F[(A, B, C, D, E)]

def unite[T[_], A](value: F[T[A]])(implicit T: Foldable[T]): F[A]

Generalized version of Haskell's catMaybes

final def uniteU[T](value: F[T])(implicit T: Unapply[Foldable, T]): F[A]

A version of unite that infers the type constructor T.

def unlessM[A](cond: Boolean)(f: ⇒ F[A]): F[Unit]

Returns the given argument if cond is false, otherwise, unit lifted into F.

def untilM[G[_], A](f: F[A], cond: ⇒ F[Boolean])(implicit G: MonadPlus[G]): F[G[A]]

Execute an action repeatedly until the Boolean condition returns true.

def untilM_[A](f: F[A], cond: ⇒ F[Boolean]): F[Unit]

Execute an action repeatedly until the Boolean condition returns true.

def void[A](fa: F[A]): F[Unit]

Empty fa of meaningful pure values, preserving its structure.

final def wait(): Unit

final def wait(arg0: Long, arg1: Int): Unit

final def wait(arg0: Long): Unit

def whenM[A](cond: Boolean)(f: ⇒ F[A]): F[Unit]

Returns the given argument if cond is true, otherwise, unit lifted into F.

def whileM[G[_], A](p: F[Boolean], body: ⇒ F[A])(implicit G: MonadPlus[G]): F[G[A]]

Execute an action repeatedly as long as the given Boolean expression returns true.

def whileM_[A](p: F[Boolean], body: ⇒ F[A]): F[Unit]

Execute an action repeatedly as long as the given Boolean expression returns true.

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

Converts ma to a value of type F[B] using the provided functions f and g.

def xmapb[A, B](ma: F[A])(b: BijectionT.Bijection[A, B]): F[B]

Converts ma to a value of type F[B] using the provided bijection.

def xmapi[A, B](ma: F[A])(iso: Isomorphism.<=>[A, B]): F[B]

Converts ma to a value of type F[B] using the provided isomorphism.

def zip: Zip[F]

scalaz.Zip derived from tuple2.