package org.gerweck.scalafx.util import language.implicitConversions import scalaz._ import scalafx.beans.property._ import scalafx.beans.value._ import scalafx.collections._ trait ObservableImplicits { /* NOTE: (Sarah) I believe that the synchronization in these helpers is not * _really_ required in the JavaFX threading model. However, the overhead of * uncontended synchronization is relatively low, and typical UIs won't have * enough change events for it to be a serious issue. (If you're updating * a property in a tight loop, I expect you'll have bigger performance * issues.) */ implicit val observableInstances = new Applicative[Observable] with Functor[Observable] with Monad[Observable] { /* Map can be derived from `ap`, but this adds less overhead. */ override def map[A, B](a: Observable[A])(f: A => B): ObservableValue[B, B] = { @inline def recalculate(): B = f(a.value) val originalValue = recalculate() val prop = ObjectProperty[B](originalValue) var prevValue = originalValue def changeHandler = prop.synchronized { val newVal = recalculate() if (prevValue != newVal) { prop.value = recalculate() prevValue = newVal } } a onChange changeHandler prop } def point[A](a: => A): ObservableValue[A, A] = { ObjectProperty[A](a) } /* Ap can be derived from `point` and `bind`, but this has less overhead. */ override def ap[A, B](fa: => Observable[A])(f: => Observable[A => B]): ObservableValue[B, B] = { @inline def recalculate(): B = (f.value)(fa.value) val originalValue = recalculate() val prop = ObjectProperty[B](originalValue) var prevValue = originalValue def changeHandler = prop.synchronized { val newVal = recalculate() if (prevValue != newVal) { prop.value = newVal prevValue = newVal } } fa onChange changeHandler f onChange changeHandler prop } /* Aka `flatMap` */ override def bind[A, B](fa: Observable[A])(f: A => Observable[B]): ObservableValue[B, B] = { join(map(fa)(f)) } /* Aka `flatten` */ override def join[A](ooa: Observable[Observable[A]]): ObservableValue[A, A] = { @inline def oa() = ooa.value @inline def calc(): A = oa().value val originalValue = calc() val prop = ObjectProperty[A](originalValue) var prevValue = originalValue def innerHandle() = prop.synchronized { val newVal = calc() if (prevValue != newVal) { prop.value = newVal prevValue = newVal } } var innerSub = oa() onChange innerHandle var prevOuter = oa() def outerHandle() = prop.synchronized { val newOuter = oa() /* We need reference equality here: we're subscribing to a specific object. */ if (prevOuter ne newOuter) { innerSub.cancel() innerSub = newOuter onChange innerHandle prevOuter = newOuter innerHandle() } } ooa onChange outerHandle prop } } implicit def enrichObservable[A, B](o: ObservableValue[A, B]) = new RichObservable(o) implicit def enrichObservableOfIterable[A, B](ooi: ObservableValue[B, B])(implicit ev1: B => Iterable[A]) = new ObservableOfIterable[A, B](ooi) implicit def enrichObservableOfMapLike[A, B, C](ooml: ObservableValue[C, C])(implicit ev1: C => Iterable[(A, B)]) = new ObservableOfMapLike[A, B, C](ooml) implicit def enrichProperty[A, B](o: Property[A, B]) = new RichProperty(o) implicit def enrichTuple[A <: Product](a: A) = new RichTuple(a) } final class RichTuple[A <: Product](val self: A) extends AnyVal { import shapeless._ import shapeless.ops.hlist._ /* It's possible to do this operation without conversion directly using * Shapeless's `tuple` package, but it can't infer the exact output type, * which is far less useful. */ def observe [L <: HList, Unwrapped <: HList, Tupled <: Product] (implicit tohl: Generic.Aux[A, L], lister: ToTraversable.Aux[L, List, Observable[_]], uw: Mapper.Aux[ObservableUnwrapper.type, L, Unwrapped], tplr: Tupler.Aux[Unwrapped, Tupled]): ObservableValue[Tupled, Tupled] = { val asHList: L = tohl.to(self) def calculate(): Tupled = uw(asHList).tupled val original = calculate() val prop = ObjectProperty[Tupled](original) for { component <- asHList.to[List] } { component onChange { prop.value = calculate() } } prop } // def omap[B] } final class RichObservable[A, C](val self: ObservableValue[A, C]) extends AnyVal { private type ObjObs[X] = ObservableValue[X, X] @inline private def oapp = observableInstances def map[B](f: A => B) = oapp.map(self)(f) def flatMap[B](f: A => Observable[B]) = oapp.bind(self)(f) def <*>[B](f: Observable[A => B]): ObservableValue[B, B] = oapp.ap(self)(f) def tuple[B](f: Observable[B]): Observable[(A,B)] = oapp.tuple2(self, f) final def *>[B](fb: ObjObs[B]): Observable[B] = oapp.apply2(self,fb)((_,b) => b) final def <*[B](fb: ObjObs[B]): Observable[A] = oapp.apply2(self,fb)((a,_) => a) final def |@|[B, B1](fb: ObservableValue[B, B1]) = ObservableTupler(self, fb) /** Alias for `|@|` */ final def ⊛[B, B1](fb: ObservableValue[B, B1]) = |@|(fb) } final class ObservableOfIterable[A, B](val self: ObservableValue[B, B])(implicit ev1: B => Iterable[A]) { def observeBuffer: ObservableBuffer[A] = { val buff = ObservableBuffer(self.value.toSeq) self onChange { (_, oldV, newV) => fillCollection(buff.delegate, newV) } buff } def observeSet: ObservableSet[A] = { val set = ObservableSet[A](self.value.toSet.toSeq: _*) self onChange { (_, oldV, newV) => val newSet = newV.toSet if (oldV.toSet != newSet) { set.clear() set ++= newSet } } set } } final class ObservableOfMapLike[A, B, C](val self: ObservableValue[C, C])(implicit ev1: C => Iterable[(A, B)]) { def observeMap: ObservableMap[A, B] = { val map = ObservableMap[A, B](self.value.toMap.toSeq: _*) self onChange { (_, oldV, newV) => val newMap = newV.toMap if (oldV.toMap != newV.toMap) { map.clear() map ++= newMap } } map } } final class RichProperty[A, B](val inner: Property[A, B]) extends AnyVal { def biMap[B <: AnyRef](push: A => B, pull: B => A): ObjectProperty[B] = { val original = push(inner.value) val op = ObjectProperty[B](original) inner onChange { val oldVal = op.value val newVal = push(inner.value) if (oldVal != newVal) { op.value = push(inner.value) } } op onChange { val oldVal = inner.value val newVal = pull(op.value) if (oldVal != newVal) { inner.value = newVal } } op } }