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package libretto.scaletto
import libretto.crash.CrashDSL
import libretto.puro.{Puro, PuroLib}
import libretto.timer.TimerDSL
import libretto.lambda.util.SourcePos
import libretto.util.Async
import scala.concurrent.duration.FiniteDuration
import scala.reflect.TypeTest
/** Supports manipulating Scala values via pure Scala functions.
* Also extends [[TimerDSL]] and [[CrashDSL]],
* since these are expected to be possible on a target platform that already supports Scala functions.
*/
trait Scaletto extends Puro with TimerDSL with CrashDSL {
/** Scala value of type `A`.
*
* Somewhat analogous to [[scala.concurrent.Future]].
*/
type Val[A]
/** Demand for a Scala value of type `A`.
*
* Somewhat analogous to [[scala.concurrent.Promise]]
*/
type Neg[A] = -[Val[A]]
/** Resource that is a Scala object of type [[A]].
* Unlike [[Val]], a resource can be mutable, cannot in general be [[neglect]]ed or [[dup]]licated, and is
* automatically cleaned-up in case of crash.
*
* It is recommended to define custom opaque type aliases of resources, such as
*
* ```
* opaque type Input = Res[java.io.InputStream]
* ```
*/
type Res[A]
override val UInt31: UInt31Scaletto
trait UInt31Scaletto extends UInt31s {
def fromInt: Val[Int] -⚬ UInt31
def toInt: UInt31 -⚬ Val[Int]
}
type ScalaFun[A, B]
val ScalaFun: ScalaFuns
trait ScalaFuns {
def apply[A, B](f: A => B): ScalaFun[A, B]
def blocking[A, B](f: A => B): ScalaFun[A, B]
def async[A, B](f: A => Async[B]): ScalaFun[A, B]
def adapt[A, B, Z, C](f: ScalaFun[A, B])(pre: Z => A, post: B => C): ScalaFun[Z, C]
def adaptWith[A, B, Z, P, C](f: ScalaFun[A, B])(pre: Z => (P, A), post: (P, B) => C): ScalaFun[Z, C]
def eval[A, B]: ScalaFun[(ScalaFun[A, B], A), B]
}
extension [A, B](f: ScalaFun[A, B]) {
def adapt[Z, C](pre: Z => A, post: B => C): ScalaFun[Z, C] =
ScalaFun.adapt(f)(pre, post)
def adaptPre[Z](pre: Z => A): ScalaFun[Z, B] =
ScalaFun.adapt(f)(pre, identity)
def adaptPost[C](post: B => C): ScalaFun[A, C] =
ScalaFun.adapt(f)(identity, post)
def adaptWith[Z, P, C](pre: Z => (P, A), post: (P, B) => C): ScalaFun[Z, C] =
ScalaFun.adaptWith(f)(pre, post)
}
private val lib = PuroLib(this)
import lib.*
/** Creates an entangled pair of demand ([[Neg]]) and supply ([[Val]]) such that when the demand is fulfilled
* with a value, that value will be produced by the supply.
*/
def promise[A]: One -⚬ (Neg[A] |*| Val[A]) =
forevert[Val[A]]
/** Uses the value (eventually) produced by [[Val]] to satisfy the demand of [[Neg]]. */
def fulfill[A]: (Val[A] |*| Neg[A]) -⚬ One =
backvert[Val[A]]
def liftEither[A, B]: Val[Either[A, B]] -⚬ (Val[A] |+| Val[B])
def unliftEither[A, B]: (Val[A] |+| Val[B]) -⚬ Val[Either[A, B]] =
either(mapVal(Left(_)), mapVal(Right(_)))
def liftPair[A, B]: Val[(A, B)] -⚬ (Val[A] |*| Val[B])
def unliftPair[A, B]: (Val[A] |*| Val[B]) -⚬ Val[(A, B)]
def liftNegPair[A, B]: Neg[(A, B)] -⚬ (Neg[A] |*| Neg[B]) =
introFst(parFromOne(promise[A], promise[B]) > IXI > snd(unliftPair)) > assocLR > elimSnd(fulfill)
def unliftNegPair[A, B]: (Neg[A] |*| Neg[B]) -⚬ Neg[(A, B)] =
introFst(promise[(A, B)] > snd(liftPair)) > assocLR > elimSnd(IXI > parToOne(fulfill, fulfill))
def mapVal[A, B](f: ScalaFun[A, B]): Val[A] -⚬ Val[B]
/** Lifts an ordinary Scala function to a linear function on [[Val]]s. */
def mapVal[A, B](f: A => B): Val[A] -⚬ Val[B] =
mapVal(ScalaFun(f))
/** Lifts an ordinary Scala function to a linear function on demands, in opposite direction. */
def contramapNeg[A, B](f: A => B): Neg[B] -⚬ Neg[A] =
contrapositive(mapVal(f))
def constVal[A](a: A): Done -⚬ Val[A]
def constNeg[A](a: A): Neg[A] -⚬ Need
transparent inline def constVal[A]: Done -⚬ Val[A] =
constVal(scala.compiletime.constValue[A])
transparent inline def constNeg[A]: Neg[A] -⚬ Need =
constNeg(scala.compiletime.constValue[A])
def neglect[A]: Val[A] -⚬ Done
def inflate[A]: Need -⚬ Neg[A] =
introFst(promise[A] > snd(neglect)) > assocLR > elimSnd(rInvertSignal)
def notifyVal[A]: Val[A] -⚬ (Ping |*| Val[A])
def notifyNeg[A]: (Pong |*| Neg[A]) -⚬ Neg[A]
def dup[A]: Val[A] -⚬ (Val[A] |*| Val[A]) =
mapVal[A, (A, A)](a => (a, a)) > liftPair
def dupNeg[A]: (Neg[A] |*| Neg[A]) -⚬ Neg[A] =
unliftNegPair[A, A] > contramapNeg(a => (a, a))
def switchVal[A, R](
a: $[Val[A]],
cases: ValSwitch.Cases[A, A, R],
)(pos: SourcePos)(using
LambdaContext,
): $[R]
def switch[A](using pos: SourcePos)(a: $[Val[A]])(using LambdaContext): ValSwitchInit[A] =
ValSwitchInit(a, pos)
def delay: Val[FiniteDuration] -⚬ Done
def delayNeed: Need -⚬ Neg[FiniteDuration] =
id [ Need ]
./>(introFst(promise[FiniteDuration])) .to[ (Neg[FiniteDuration] |*| Val[FiniteDuration]) |*| Need ]
./>(assocLR) .to[ Neg[FiniteDuration] |*| (Val[FiniteDuration] |*| Need) ]
./>.snd.fst(delay) .to[ Neg[FiniteDuration] |*| ( Done |*| Need) ]
./>(elimSnd(rInvertSignal)) .to[ Neg[FiniteDuration] ]
override def delay(d: FiniteDuration): Done -⚬ Done =
constVal(d) > delay
def acquire[A, R, B](
acquire: ScalaFun[A, (R, B)],
release: Option[ScalaFun[R, Unit]],
): Val[A] -⚬ (Res[R] |*| Val[B])
/** Acquires a resource of type [[R]].
*
* @param acquire
* @param release called to release the resource in case of a crash. `None` means no cleanup is needed
* @tparam A parameters of the `acquire` function
* @tparam R type of the resource
* @tparam B additional data produced by acquiring the resource
*/
def acquire[A, R, B](
acquire: A => (R, B),
release: Option[R => Unit],
): Val[A] -⚬ (Res[R] |*| Val[B]) =
this.acquire(ScalaFun(acquire), release.map(ScalaFun(_)))
def acquireAsync[A, R, B](
acquire: A => Async[(R, B)],
release: Option[R => Async[Unit]],
): Val[A] -⚬ (Res[R] |*| Val[B]) =
this.acquire(ScalaFun.async(acquire), release.map(ScalaFun.async(_)))
/** Acquires a resource of type [[R]]. Might fail with an error of type [[E]].
*
* @param acquire
* @param release called to release the resource in case of a crash. `None` means no cleanup is needed
* @tparam A parameters of the `acquire` function
* @tparam R type of the resource
* @tparam B additional data produced by acquiring the resource
* @tparam E type of the error
*/
def tryAcquire[A, R, B, E](
acquire: A => Either[E, (R, B)],
release: Option[R => Unit],
): Val[A] -⚬ (Val[E] |+| (Res[R] |*| Val[B])) =
tryAcquire(
ScalaFun(acquire),
release.map(ScalaFun(_)),
)
def tryAcquire[A, R, B, E](
acquire: ScalaFun[A, Either[E, (R, B)]],
release: Option[ScalaFun[R, Unit]],
): Val[A] -⚬ (Val[E] |+| (Res[R] |*| Val[B]))
/** Releases a resource using the `release` function registered during resource acquisition. */
def release[R]: Res[R] -⚬ Done
def releaseWith[R, A, B](f: ScalaFun[(R, A), B]): (Res[R] |*| Val[A]) -⚬ Val[B]
/** Releases a resource using the given function. The `release` function previously registered during resource
* acquisition is not used.
*
* @param f the release function
* @tparam R type of the resource
* @tparam A additional parameter of the release function
* @tparam B additional data produced by the release function
*/
def release[R, A, B](f: (R, A) => B): (Res[R] |*| Val[A]) -⚬ Val[B] =
releaseWith(ScalaFun(f.tupled))
def releaseAsync[R, A, B](f: (R, A) => Async[B]): (Res[R] |*| Val[A]) -⚬ Val[B] =
releaseWith(ScalaFun.async(f.tupled))
def effect[R, A, B](f: ScalaFun[(R, A), B]): (Res[R] |*| Val[A]) -⚬ (Res[R] |*| Val[B])
/** Performs a (potentially) effectful operation on a resource, producing some output.
*
* @param f the effectful operation
* @tparam R type of the resource
* @tparam A additional parameter of the operation
* @tparam B additional output of the operation
*/
def effect[R, A, B](f: (R, A) => B): (Res[R] |*| Val[A]) -⚬ (Res[R] |*| Val[B]) =
effect(ScalaFun(f.tupled))
def effectAsync[R, A, B](f: (R, A) => Async[B]): (Res[R] |*| Val[A]) -⚬ (Res[R] |*| Val[B]) =
effect(ScalaFun.async(f.tupled))
def effectWr[R, A](f: ScalaFun[(R, A), Unit]): (Res[R] |*| Val[A]) -⚬ Res[R]
/** Variant of [[effect]] that does not produce output in addition to performing the effect.
* Can be viewed as ''wr''iting an [[A]] into the resource.
*/
def effectWr[R, A](f: (R, A) => Unit): (Res[R] |*| Val[A]) -⚬ Res[R] =
effectWr(ScalaFun(f.tupled))
def effectWrAsync[R, A](f: (R, A) => Async[Unit]): (Res[R] |*| Val[A]) -⚬ Res[R] =
effectWr(ScalaFun.async(f.tupled))
def tryEffectAcquire[R, A, S, B, E](
f: ScalaFun[(R, A), Either[E, (S, B)]],
release: Option[ScalaFun[S, Unit]],
): (Res[R] |*| Val[A]) -⚬ (Res[R] |*| (Val[E] |+| (Res[S] |*| Val[B])))
/** Transforms a resource into a resource of (possibly) different type.
*
* @param f the transformation function. It receives the input resource and additional input of type [[A]].
* It returns the new resource and additional output of type [[B]].
* @param release called to release the new resource in case of a crash. `None` means no cleanup is needed
* @tparam R type of the input resource
* @tparam A additional parameter of the transformation
* @tparam S type of the output resource
* @tparam B additional output of the transformation
*/
def transformResource[R, A, S, B](
f: (R, A) => (S, B),
release: Option[S => Unit],
): (Res[R] |*| Val[A]) -⚬ (Res[S] |*| Val[B]) =
transformResourceAsync(
(r, a) => Async.now(f(r, a)),
release.map(_ andThen Async.now),
)
def transformResourceAsync[R, A, S, B](
f: (R, A) => Async[(S, B)],
release: Option[S => Async[Unit]],
): (Res[R] |*| Val[A]) -⚬ (Res[S] |*| Val[B]) =
tryTransformResourceAsync[R, A, S, B, Nothing](
(r, a) => f(r, a).map(Right(_)),
release,
) .to[ Val[Nothing] |+| (Res[S] |*| Val[B]) ]
> either(anyResourceFromNothing, id) .to[ Res[S] |*| Val[B] ]
def tryTransformResource[R, A, S, B, E](
f: ScalaFun[(R, A), Either[E, (S, B)]],
release: Option[ScalaFun[S, Unit]],
): (Res[R] |*| Val[A]) -⚬ (Val[E] |+| (Res[S] |*| Val[B]))
/** Transforms a resource into a resource of (possibly) different type. Might fail with an error of type [[E]].
*
* @param f the transformation function. It receives the input resource and additional input of type [[A]].
* It returns either an error of type [[E]] or the new resource and additional output of type [[B]].
* In case the transformation results in an error, the original resource is ''not'' released automatically—
* the passing of the original resource `R` to the transformation function `f` indicates transfer of
* responsibility for the resource to the function `f`.
* @param release called to release the new resource in case of a crash. `None` means no cleanup is needed
* @tparam R type of the input resource
* @tparam A additional parameter of the transformation
* @tparam S type of the output resource
* @tparam B additional output of the transformation
* @tparam E type of the error
*/
def tryTransformResource[R, A, S, B, E](
f: (R, A) => Either[E, (S, B)],
release: Option[S => Unit],
): (Res[R] |*| Val[A]) -⚬ (Val[E] |+| (Res[S] |*| Val[B])) =
tryTransformResource(
ScalaFun(f.tupled),
release.map(ScalaFun(_)),
)
def tryTransformResourceAsync[R, A, S, B, E](
f: (R, A) => Async[Either[E, (S, B)]],
release: Option[S => Async[Unit]],
): (Res[R] |*| Val[A]) -⚬ (Val[E] |+| (Res[S] |*| Val[B])) =
tryTransformResource(
ScalaFun.async(f.tupled),
release.map(ScalaFun.async(_)),
)
def splitResource[R, A, S, T, B](
f: ScalaFun[(R, A), (S, T, B)],
release1: Option[ScalaFun[S, Unit]],
release2: Option[ScalaFun[T, Unit]],
): (Res[R] |*| Val[A]) -⚬ ((Res[S] |*| Res[T]) |*| Val[B]) =
trySplitResource(
ScalaFun.adapt(f)(identity[(R, A)], Right[Nothing, (S, T, B)]),
release1,
release2,
) > either(anyTwoResourcesFromNothing, id)
def splitResource[R, A, S, T, B](
f: (R, A) => (S, T, B),
release1: Option[S => Unit],
release2: Option[T => Unit],
): (Res[R] |*| Val[A]) -⚬ ((Res[S] |*| Res[T]) |*| Val[B]) =
splitResource(
ScalaFun(f.tupled),
release1.map(ScalaFun(_)),
release2.map(ScalaFun(_)),
)
def splitResourceAsync[R, A, S, T, B](
f: (R, A) => Async[(S, T, B)],
release1: Option[S => Async[Unit]],
release2: Option[T => Async[Unit]],
): (Res[R] |*| Val[A]) -⚬ ((Res[S] |*| Res[T]) |*| Val[B]) =
splitResource(
ScalaFun.async(f.tupled),
release1.map(ScalaFun.async(_)),
release2.map(ScalaFun.async(_)),
)
def trySplitResource[R, A, S, T, B, E](
f: ScalaFun[(R, A), Either[E, (S, T, B)]],
release1: Option[ScalaFun[S, Unit]],
release2: Option[ScalaFun[T, Unit]],
): (Res[R] |*| Val[A]) -⚬ (Val[E] |+| ((Res[S] |*| Res[T]) |*| Val[B]))
def trySplitResource[R, A, S, T, B, E](
f: (R, A) => Either[E, (S, T, B)],
release1: Option[S => Unit],
release2: Option[T => Unit],
): (Res[R] |*| Val[A]) -⚬ (Val[E] |+| ((Res[S] |*| Res[T]) |*| Val[B])) =
trySplitResource(
ScalaFun(f.tupled),
release1.map(ScalaFun(_)),
release2.map(ScalaFun(_)),
)
def trySplitResourceAsync[R, A, S, T, B, E](
f: (R, A) => Async[Either[E, (S, T, B)]],
release1: Option[S => Async[Unit]],
release2: Option[T => Async[Unit]],
): (Res[R] |*| Val[A]) -⚬ (Val[E] |+| ((Res[S] |*| Res[T]) |*| Val[B])) =
trySplitResource(
ScalaFun.async(f.tupled),
release1.map(ScalaFun.async(_)),
release2.map(ScalaFun.async(_)),
)
private def anyResourceFromNothing[R, B]: Val[Nothing] -⚬ (Res[R] |*| Val[B])=
acquire(x => x, release = None)
private def anyTwoResourcesFromNothing[S, T, B]: Val[Nothing] -⚬ ((Res[S] |*| Res[T]) |*| Val[B]) =
dup[Nothing] .to[ Val[Nothing] |*| Val[Nothing] ]
.>( par(anyResourceFromNothing[S, Nothing], anyResourceFromNothing[T, Nothing]) ) .to[ (Res[S] |*| Val[Nothing]) |*| ( Res[T] |*| Val[Nothing]) ]
.>( IXI ) .to[ (Res[S] |*| Res[T] ) |*| (Val[Nothing] |*| Val[Nothing]) ]
.>( par(id, unliftPair > mapVal(_._1)) ) .to[ (Res[S] |*| Res[T] ) |*| Val[B] ]
/** Executes a potentially blocking operation.
* The runtime will ensure that the blocking operation does not impede
* any of the concurrently happening non-blocking computations.
*/
def blocking[A, B](f: A => B): Val[A] -⚬ Val[B] =
mapVal(ScalaFun.blocking(f))
/** Prints the given message to the console, without creating an obligation to await. */
def debugPrint(msg: String): Ping -⚬ One
def constantVal[A](a: A)(using SourcePos, LambdaContext): $[Val[A]] =
constant(done) |> constVal(a)
def tuple[A, B](a: $[Val[A]], b: $[Val[B]])(using
SourcePos,
LambdaContext,
): $[Val[(A, B)]] =
(a |*| b) |> unliftPair
def tuple[A, B, C](a: $[Val[A]], b: $[Val[B]], c: $[Val[C]])(using
SourcePos,
LambdaContext,
): $[Val[(A, B, C)]] =
tuple(tuple(a, b), c) |> mapVal { case ((a, b), c) => (a, b, c) }
def tuple[A, B, C, D](a: $[Val[A]], b: $[Val[B]], c: $[Val[C]], d: $[Val[D]])(using
SourcePos,
LambdaContext,
): $[Val[(A, B, C, D)]] =
tuple(tuple(a, b), tuple(c, d)) |> mapVal { case ((a, b), (c, d)) => (a, b, c, d) }
def tuple[A, B, C, D, E](a: $[Val[A]], b: $[Val[B]], c: $[Val[C]], d: $[Val[D]], e: $[Val[E]])(using
SourcePos,
LambdaContext,
): $[Val[(A, B, C, D, E)]] =
tuple(tuple(a, b, c), tuple(d, e)) |> mapVal { case ((a, b, c), (d, e)) => (a, b, c, d, e) }
def tuple[A, B, C, D, E, F](a: $[Val[A]], b: $[Val[B]], c: $[Val[C]], d: $[Val[D]], e: $[Val[E]], f: $[Val[F]])(using
SourcePos,
LambdaContext,
): $[Val[(A, B, C, D, E, F)]] =
tuple(tuple(a, b, c), tuple(d, e, f)) |> mapVal { case ((a, b, c), (d, e, f)) => (a, b, c, d, e, f) }
class ValSwitchInit[A](a: $[Val[A]], pos: SourcePos)(using LambdaContext) {
def Case[A0 <: A](using tt: TypeTest[A, A0], casePos: SourcePos): ValSwitchInitCase[A, A0] =
ValSwitchInitCase[A, A0](a, pos, tt, casePos)
}
class ValSwitchInitCase[A, A0 <: A](a: $[Val[A]], pos: SourcePos, tt: TypeTest[A, A0], casePos: SourcePos)(using LambdaContext) {
def apply[R](f: LambdaContext ?=> $[Val[A0]] => $[R]): ValSwitch[A, A0, R] =
ValSwitch(a, pos, ValSwitch.FirstCase(tt, f, casePos))
}
/**
*
* @tparam A type of the scrutinee (the value to match on)
* @tparam A0 subtype of A covered so far
* @tparam R result type that each case must produce
*/
class ValSwitch[A, A0, R](a: $[Val[A]], pos: SourcePos, cases: ValSwitch.Cases[A, A0, R])(using LambdaContext) {
def endswitch(using ev: A0 =:= A): $[R] =
switchVal[A, R](a, ev.substituteCo[[a] =>> ValSwitch.Cases[A, a, R]](cases))(pos)
def Case[A1 <: A](using tt: TypeTest[A, A1], pos: SourcePos)(
f: LambdaContext ?=> $[Val[A1]] => $[R],
): ValSwitch[A, A0 | A1, R] =
ValSwitch(a, pos, ValSwitch.NextCase(cases, tt, f, pos))
}
object ValSwitch {
sealed trait Cases[A, A0, R]
class FirstCase[A, A0, R](
val typeTest: TypeTest[A, A0],
val f: LambdaContext ?=> $[Val[A0]] => $[R],
val pos: SourcePos,
) extends Cases[A, A0, R]
class NextCase[A, A0, A1, R](
val base: Cases[A, A0, R],
val typeTest: TypeTest[A, A1],
val f: LambdaContext ?=> $[Val[A1]] => $[R],
val pos: SourcePos,
) extends Cases[A, A0 | A1, R]
}
/** Returns the size of the given program, in further unspecified units.
* Useful only for approximate relative comparisons.
*/
def sizeOf[A, B](f: A -⚬ B): Long
}
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