nutcracker/nutcracker.util/MonadObjectOutput

MonadObjectOutput

trait MonadObjectOutput[F[_], R, Ptr[_]] extends MonadTell[F, R] with BindRec[F]
trait BindRec[F]
trait MonadTell[F, R]
trait Monad[F]
trait Bind[F]
trait Applicative[F]
trait InvariantApplicative[F]
trait Apply[F]
trait Functor[F]
trait InvariantFunctor[F]
class Object
trait Matchable
class Any

Type members

Inherited classlikes

trait ApplicativeLaw extends ApplyLaw
Inherited from:
Applicative
trait ApplyLaw extends FunctorLaw
Inherited from:
Apply
trait BindLaw extends ApplyLaw
Inherited from:
Bind
trait BindRecLaw extends BindLaw
Inherited from:
BindRec
trait FunctorLaw extends InvariantFunctorLaw
Inherited from:
Functor
trait InvariantFunctorLaw
Inherited from:
InvariantFunctor
trait MonadLaw extends ApplicativeLaw with BindLaw
Inherited from:
Monad

Value members

Abstract methods

def nest[A](fa: F[A]): F[A]

A hint for displaying tree structure. The implementation is identity, which means ignoring the hint, i.e. no support for displaying tree structure.

A hint for displaying tree structure. The implementation is identity, which means ignoring the hint, i.e. no support for displaying tree structure.

def write(r: R): F[Unit]

Alias for tell.

Alias for tell.

def writeRec[A](pa: Ptr[A])(f: A => F[Unit]): F[Unit]

Concrete methods

def apply[A](a: A)(implicit ev: ObjectSerializer[A, R, Ptr]): F[Unit]
def empty: F[Unit]
def objectOutput: ObjectOutput[F[Unit], R, Ptr]
override def tell(r: R): F[Unit]
Definition Classes
MonadTell
def writeObject[A](pa: Ptr[A])(implicit ev: ObjectSerializer[A, R, Ptr]): F[Unit]
def writeSubObject[A, B](pa: Ptr[A])(f: A => B)(implicit ev: ObjectSerializer[B, R, Ptr]): F[Unit]

Inherited methods

override def ap[A, B](fa: => F[A])(f: => F[A => B]): F[B]
Definition Classes
Bind -> Apply
Inherited from:
Bind
def ap2[A, B, C](fa: => F[A], fb: => F[B])(f: F[(A, B) => C]): F[C]
Inherited from:
Apply
def ap3[A, B, C, D](fa: => F[A], fb: => F[B], fc: => F[C])(f: F[(A, B, C) => D]): F[D]
Inherited from:
Apply
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]
Inherited from:
Apply
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]
Inherited from:
Apply
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]
Inherited from:
Apply
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]
Inherited from:
Apply
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]
Inherited from:
Apply
def apF[A, B](f: => F[A => B]): F[A] => F[B]

Flipped variant of ap.

Flipped variant of ap.

Inherited from:
Apply
def applicativeLaw: ApplicativeLaw
Inherited from:
Applicative
def apply[A, B](fa: F[A])(f: A => B): F[B]

Alias for map.

Alias for map.

Inherited from:
Functor
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]
Inherited from:
Apply
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]
Inherited from:
Apply
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]
Inherited from:
Apply
override def apply2[A, B, C](fa: => F[A], fb: => F[B])(f: (A, B) => C): F[C]
Definition Classes
Bind -> Apply
Inherited from:
Bind
def apply3[A, B, C, D](fa: => F[A], fb: => F[B], fc: => F[C])(f: (A, B, C) => D): F[D]
Inherited from:
Apply
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]
Inherited from:
Apply
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]
Inherited from:
Apply
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]
Inherited from:
Apply
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]
Inherited from:
Apply
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]
Inherited from:
Apply
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]
Inherited from:
Apply
def applyApplicative: Applicative[[α] =>> F[α] \/ α]

Add a unit to any Apply to form an Applicative.

Add a unit to any Apply to form an Applicative.

Inherited from:
Apply
def applyLaw: ApplyLaw
Inherited from:
Apply
final def applying1[Z, A1](f: A1 => Z)(implicit a1: F[A1]): F[Z]
Inherited from:
Apply
final def applying2[Z, A1, A2](f: (A1, A2) => Z)(implicit a1: F[A1], a2: F[A2]): F[Z]
Inherited from:
Apply
final def applying3[Z, A1, A2, A3](f: (A1, A2, A3) => Z)(implicit a1: F[A1], a2: F[A2], a3: F[A3]): F[Z]
Inherited from:
Apply
final def applying4[Z, A1, A2, A3, A4](f: (A1, A2, A3, A4) => Z)(implicit a1: F[A1], a2: F[A2], a3: F[A3], a4: F[A4]): F[Z]
Inherited from:
Apply
def bicompose[G[_, _] : Bifunctor]: Bifunctor[[α, β] =>> F[G[α, β]]]

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

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

Inherited from:
Functor
def bind[A, B](fa: F[A])(f: A => F[B]): F[B]

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

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

Inherited from:
Bind
def bindLaw: BindLaw
Inherited from:
Bind
def bindRecLaw: BindRecLaw
Inherited from:
BindRec
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

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

Inherited from:
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

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

Inherited from:
Functor
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

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

Inherited from:
Applicative
def counzip[A, B](a: F[A] \/ F[B]): F[A \/ B]
Inherited from:
Functor
def discardLeft[A, B](fa: => F[A], fb: => F[B]): F[B]

Combine fa and fb according to Apply[F] with a function that discards the A(s)

Combine fa and fb according to Apply[F] with a function that discards the A(s)

Inherited from:
Apply
def discardRight[A, B](fa: => F[A], fb: => F[B]): F[A]

Combine fa and fb according to Apply[F] with a function that discards the B(s)

Combine fa and fb according to Apply[F] with a function that discards the B(s)

Inherited from:
Apply
def filterM[A](l: IList[A])(f: A => F[Boolean]): F[IList[A]]

Filter l according to an applicative predicate.

Filter l according to an applicative predicate.

Inherited from:
Applicative
def filterM[A](l: List[A])(f: A => F[Boolean]): F[List[A]]

Filter l according to an applicative predicate.

Filter l according to an applicative predicate.

Inherited from:
Applicative
def filterM[A, B](map: A ==>> B)(f: B => F[Boolean])(implicit O: Order[A]): F[A ==>> B]

Filter map according to an applicative predicate. *

Filter map according to an applicative predicate. *

Inherited from:
Applicative
override def flip: Applicative[F]

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

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

Definition Classes
Applicative -> Apply
Inherited from:
Applicative
override def forever[A, B](fa: F[A]): F[B]
Definition Classes
BindRec -> Apply
Inherited from:
BindRec
def fpair[A](fa: F[A]): F[(A, A)]

Twin all As in fa.

Twin all As in fa.

Inherited from:
Functor
def fproduct[A, B](fa: F[A])(f: A => B): F[(A, B)]

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

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

Inherited from:
Functor
def functorLaw: FunctorLaw
Inherited from:
Functor
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.

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

Inherited from:
Functor
def ifM[B](value: F[Boolean], ifTrue: => F[B], ifFalse: => F[B]): F[B]

if lifted into a binding. Unlike lift3((t,c,a)=>if(t)c else a), this will only include context from the chosen of ifTrue and ifFalse, not the other.

if lifted into a binding. Unlike lift3((t,c,a)=>if(t)c else a), this will only include context from the chosen of ifTrue and ifFalse, not the other.

Inherited from:
Bind
def invariantFunctorLaw: InvariantFunctorLaw
Inherited from:
InvariantFunctor
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.

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

Inherited from:
Monad
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.

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

Inherited from:
Monad
def join[A](ffa: F[F[A]]): F[A]

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

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

Inherited from:
Bind
def lift[A, B](f: A => B): F[A] => F[B]

Lift f into F.

Lift f into F.

Inherited from:
Functor
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]
Inherited from:
Apply
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]
Inherited from:
Apply
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]
Inherited from:
Apply
def lift2[A, B, C](f: (A, B) => C): (F[A], F[B]) => F[C]
Inherited from:
Apply
def lift3[A, B, C, D](f: (A, B, C) => D): (F[A], F[B], F[C]) => F[D]
Inherited from:
Apply
def lift4[A, B, C, D, E](f: (A, B, C, D) => E): (F[A], F[B], F[C], F[D]) => F[E]
Inherited from:
Apply
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]
Inherited from:
Apply
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]
Inherited from:
Apply
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]
Inherited from:
Apply
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]
Inherited from:
Apply
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]
Inherited from:
Apply
def liftReducer[A, B](implicit r: Reducer[A, B]): Reducer[F[A], F[B]]
Inherited from:
Apply
override def map[A, B](fa: F[A])(f: A => B): F[B]
Definition Classes
Monad -> Applicative -> Functor
Inherited from:
Monad
def mapply[A, B](a: A)(f: F[A => B]): F[B]

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

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

Inherited from:
Functor
def monadLaw: MonadLaw
Inherited from:
Monad
def mproduct[A, B](fa: F[A])(f: A => F[B]): F[(A, B)]

Pair A with the result of function application.

Pair A with the result of function application.

Inherited from:
Bind
def par: Par[F]

A lawful implementation of this that is isomorphic up to the methods defined on Applicative allowing for optimised parallel implementations that would otherwise violate laws of more specific typeclasses (e.g. Monad).

A lawful implementation of this that is isomorphic up to the methods defined on Applicative allowing for optimised parallel implementations that would otherwise violate laws of more specific typeclasses (e.g. Monad).

Inherited from:
Applicative
def plusA[A](x: => F[A], y: => F[A])(implicit sa: Semigroup[A]): F[A]

Semigroups can be added within an Applicative

Semigroups can be added within an Applicative

Inherited from:
Applicative
def point[A](a: => A): F[A]
Inherited from:
Applicative
def product[G[_]](implicit G0: BindRec[G]): BindRec[[α] =>> (F[α], G[α])]

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

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

Inherited from:
BindRec
def product[G[_]](implicit G0: Bind[G]): Bind[[α] =>> (F[α], G[α])]

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

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

Inherited from:
Bind
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

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

Inherited from:
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

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

Inherited from:
Functor
def product[G[_]](implicit G0: Monad[G]): Monad[[α] =>> (F[α], G[α])]

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

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

Inherited from:
Monad
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

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

Inherited from:
Applicative
final def pure[A](a: => A): F[A]
Inherited from:
Applicative
def replicateM[A](n: Int, fa: F[A]): F[IList[A]]

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

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

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

Performs the action n times, returning nothing.

Performs the action n times, returning nothing.

Inherited from:
Applicative
def sequence[A, G[_] : Traverse](as: G[F[A]]): F[G[A]]
Inherited from:
Applicative
def sequence1[A, G[_] : Traverse1](as: G[F[A]]): F[G[A]]
Inherited from:
Apply
def strengthL[A, B](a: A, f: F[B]): F[(A, B)]

Inject a to the left of Bs in f.

Inject a to the left of Bs in f.

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

Inject b to the right of As in f.

Inject b to the right of As in f.

Inherited from:
Functor
def tailrecM[A, B](a: A)(f: A => F[A \/ B]): F[B]
Inherited from:
BindRec
def traverse[A, G[_], B](value: G[A])(f: A => F[B])(implicit G: Traverse[G]): F[G[B]]
Inherited from:
Applicative
def traverse1[A, G[_], B](value: G[A])(f: A => F[B])(implicit G: Traverse1[G]): F[G[B]]
Inherited from:
Apply
def tuple2[A, B](fa: => F[A], fb: => F[B]): F[(A, B)]
Inherited from:
Apply
def tuple3[A, B, C](fa: => F[A], fb: => F[B], fc: => F[C]): F[(A, B, C)]
Inherited from:
Apply
def tuple4[A, B, C, D](fa: => F[A], fb: => F[B], fc: => F[C], fd: => F[D]): F[(A, B, C, D)]
Inherited from:
Apply
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)]
Inherited from:
Apply
def unfoldrOpt[S, A, B](seed: S)(f: S => Maybe[(F[A], S)])(implicit R: Reducer[A, B]): Maybe[F[B]]

Unfold seed to the right and combine effects left-to-right, using the given Reducer to combine values. Implementations may override this method to not unfold more than is necessary to determine the result.

Unfold seed to the right and combine effects left-to-right, using the given Reducer to combine values. Implementations may override this method to not unfold more than is necessary to determine the result.

Inherited from:
Apply
def unlessM[A](cond: Boolean)(f: => F[A]): F[Unit]

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

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

Inherited from:
Applicative
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. The condition is evaluated after the loop body. Collects results into an arbitrary MonadPlus value, such as a List.

Execute an action repeatedly until the Boolean condition returns true. The condition is evaluated after the loop body. Collects results into an arbitrary MonadPlus value, such as a List.

Inherited from:
Monad
def untilM_[A](f: F[A], cond: => F[Boolean]): F[Unit]

Execute an action repeatedly until the Boolean condition returns true. The condition is evaluated after the loop body. Discards results.

Execute an action repeatedly until the Boolean condition returns true. The condition is evaluated after the loop body. Discards results.

Inherited from:
Monad
def void[A](fa: F[A]): F[Unit]

Empty fa of meaningful pure values, preserving its structure.

Empty fa of meaningful pure values, preserving its structure.

Inherited from:
Functor
def whenM[A](cond: Boolean)(f: => F[A]): F[Unit]

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

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

Inherited from:
Applicative
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. The condition is evaluated before the loop body. Collects the results into an arbitrary MonadPlus value, such as a List.

Execute an action repeatedly as long as the given Boolean expression returns true. The condition is evaluated before the loop body. Collects the results into an arbitrary MonadPlus value, such as a List.

Inherited from:
Monad
def whileM_[A](p: F[Boolean], body: => F[A]): F[Unit]

Execute an action repeatedly as long as the given Boolean expression returns true. The condition is evaluated before the loop body. Discards results.

Execute an action repeatedly as long as the given Boolean expression returns true. The condition is evaluated before the loop body. Discards results.

Inherited from:
Monad
def widen[A, B](fa: F[A])(implicit ev: Liskov[A, B]): F[B]

Functors are covariant by nature, so we can treat an F[A] as an F[B] if A is a subtype of B.

Functors are covariant by nature, so we can treat an F[A] as an F[B] if A is a subtype of B.

Inherited from:
Functor
def writer[A](w: R, v: A): F[A]
Inherited from:
MonadTell
final def xderiving0[Z](z: => Z): F[Z]
Inherited from:
InvariantApplicative
final def xderiving1[Z, A1](f: A1 => Z, g: Z => A1)(implicit a1: F[A1]): F[Z]
Inherited from:
InvariantApplicative
final def xderiving2[Z, A1, A2](f: (A1, A2) => Z, g: Z => (A1, A2))(implicit a1: F[A1], a2: F[A2]): F[Z]
Inherited from:
InvariantApplicative
final def xderiving3[Z, A1, A2, A3](f: (A1, A2, A3) => Z, g: Z => (A1, A2, A3))(implicit a1: F[A1], a2: F[A2], a3: F[A3]): F[Z]
Inherited from:
InvariantApplicative
final def xderiving4[Z, A1, A2, A3, A4](f: (A1, A2, A3, A4) => Z, g: Z => (A1, A2, A3, A4))(implicit a1: F[A1], a2: F[A2], a3: F[A3], a4: F[A4]): F[Z]
Inherited from:
InvariantApplicative
def xmap[A, B](fa: F[A], f: A => B, g: B => A): F[B]
Inherited from:
Functor
def xmapb[A, B](ma: F[A])(b: Bijection[A, B]): F[B]

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

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

Inherited from:
InvariantFunctor
def xmapi[A, B](ma: F[A])(iso: IsoSet[A, B]): F[B]

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

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

Inherited from:
InvariantFunctor
override def xproduct0[Z](z: => Z): F[Z]
Definition Classes
Applicative -> InvariantApplicative
Inherited from:
Applicative
override def xproduct1[Z, A1](a1: => F[A1])(f: A1 => Z, g: Z => A1): F[Z]
Definition Classes
Applicative -> InvariantApplicative
Inherited from:
Applicative
override def xproduct2[Z, A1, A2](a1: => F[A1], a2: => F[A2])(f: (A1, A2) => Z, g: Z => (A1, A2)): F[Z]
Definition Classes
Applicative -> InvariantApplicative
Inherited from:
Applicative
override def xproduct3[Z, A1, A2, A3](a1: => F[A1], a2: => F[A2], a3: => F[A3])(f: (A1, A2, A3) => Z, g: Z => (A1, A2, A3)): F[Z]
Definition Classes
Applicative -> InvariantApplicative
Inherited from:
Applicative
override def xproduct4[Z, A1, A2, A3, A4](a1: => F[A1], a2: => F[A2], a3: => F[A3], a4: => F[A4])(f: (A1, A2, A3, A4) => Z, g: Z => (A1, A2, A3, A4)): F[Z]
Definition Classes
Applicative -> InvariantApplicative
Inherited from:
Applicative

Inherited fields

val applicativeSyntax: ApplicativeSyntax[F]
Inherited from:
Applicative
val applySyntax: ApplySyntax[F]
Inherited from:
Apply
val bindRecSyntax: BindRecSyntax[F]
Inherited from:
BindRec
val bindSyntax: BindSyntax[F]
Inherited from:
Bind
val functorSyntax: FunctorSyntax[F]
Inherited from:
Functor
val invariantApplicativeSyntax: InvariantApplicativeSyntax[F]
Inherited from:
InvariantApplicative
val invariantFunctorSyntax: InvariantFunctorSyntax[F]
Inherited from:
InvariantFunctor
val monadSyntax: MonadSyntax[F]
Inherited from:
Monad
val monadTellSyntax: MonadTellSyntax[F, R]
Inherited from:
MonadTell