kotlinx-coroutines-core/js/src/JSDispatcher.kt - platform/external/kotlinx.coroutines - Git at Google

 /*
  * Copyright 2016-2021 JetBrains s.r.o. Use of this source code is governed by the Apache 2.0 license.
  */

 package kotlinx.coroutines

 import kotlinx.coroutines.internal.*
 import org.w3c.dom.*
 import kotlin.coroutines.*
 import kotlin.js.Promise

 private const val MAX_DELAY = Int.MAX_VALUE.toLong()

 private fun delayToInt(timeMillis: Long): Int =
     timeMillis.coerceIn(0, MAX_DELAY).toInt()

 internal sealed class SetTimeoutBasedDispatcher: CoroutineDispatcher(), Delay {
     inner class ScheduledMessageQueue : MessageQueue() {
         internal val processQueue: dynamic = { process() }

         override fun schedule() {
             scheduleQueueProcessing()
         }

         override fun reschedule() {
             setTimeout(processQueue, 0)
         }
     }

     internal val messageQueue = ScheduledMessageQueue()

     abstract fun scheduleQueueProcessing()

     override fun limitedParallelism(parallelism: Int): CoroutineDispatcher {
         parallelism.checkParallelism()
         return this
     }

     override fun dispatch(context: CoroutineContext, block: Runnable) {
         messageQueue.enqueue(block)
     }

     override fun invokeOnTimeout(timeMillis: Long, block: Runnable, context: CoroutineContext): DisposableHandle {
         val handle = setTimeout({ block.run() }, delayToInt(timeMillis))
         return ClearTimeout(handle)
     }

     override fun scheduleResumeAfterDelay(timeMillis: Long, continuation: CancellableContinuation<Unit>) {
         val handle = setTimeout({ with(continuation) { resumeUndispatched(Unit) } }, delayToInt(timeMillis))
         // Actually on cancellation, but clearTimeout is idempotent
         continuation.invokeOnCancellation(handler = ClearTimeout(handle).asHandler)
     }
 }

 internal object NodeDispatcher : SetTimeoutBasedDispatcher() {
     override fun scheduleQueueProcessing() {
         process.nextTick(messageQueue.processQueue)
     }
 }

 internal object SetTimeoutDispatcher : SetTimeoutBasedDispatcher() {
     override fun scheduleQueueProcessing() {
         setTimeout(messageQueue.processQueue, 0)
     }
 }

 private class ClearTimeout(private val handle: Int) : CancelHandler(), DisposableHandle {

     override fun dispose() {
         clearTimeout(handle)
     }

     override fun invoke(cause: Throwable?) {
         dispose()
     }

     override fun toString(): String = "ClearTimeout[$handle]"
 }

 internal class WindowDispatcher(private val window: Window) : CoroutineDispatcher(), Delay {
     private val queue = WindowMessageQueue(window)

     override fun dispatch(context: CoroutineContext, block: Runnable) = queue.enqueue(block)

     override fun scheduleResumeAfterDelay(timeMillis: Long, continuation: CancellableContinuation<Unit>) {
         window.setTimeout({ with(continuation) { resumeUndispatched(Unit) } }, delayToInt(timeMillis))
     }

     override fun invokeOnTimeout(timeMillis: Long, block: Runnable, context: CoroutineContext): DisposableHandle {
         val handle = window.setTimeout({ block.run() }, delayToInt(timeMillis))
         return object : DisposableHandle {
             override fun dispose() {
                 window.clearTimeout(handle)
             }
         }
     }
 }

 private class WindowMessageQueue(private val window: Window) : MessageQueue() {
     private val messageName = "dispatchCoroutine"

     init {
         window.addEventListener("message", { event: dynamic ->
             if (event.source == window && event.data == messageName) {
                 event.stopPropagation()
                 process()
             }
         }, true)
     }

     override fun schedule() {
         Promise.resolve(Unit).then({ process() })
     }

     override fun reschedule() {
         window.postMessage(messageName, "*")
     }
 }

 /**
  * An abstraction over JS scheduling mechanism that leverages micro-batching of dispatched blocks without
  * paying the cost of JS callbacks scheduling on every dispatch.
  *
  * Queue uses two scheduling mechanisms:
  * 1) [schedule] is used to schedule the initial processing of the message queue.
  *    JS engine-specific microtask mechanism is used in order to boost performance on short runs and a dispatch batch
  * 2) [reschedule] is used to schedule processing of the queue after yield to the JS event loop.
  *    JS engine-specific macrotask mechanism is used not to starve animations and non-coroutines macrotasks.
  *
  * Yet there could be a long tail of "slow" reschedules, but it should be amortized by the queue size.
  */
 internal abstract class MessageQueue : ArrayQueue<Runnable>() {
     val yieldEvery = 16 // yield to JS macrotask event loop after this many processed messages
     private var scheduled = false

     abstract fun schedule()

     abstract fun reschedule()

     fun enqueue(element: Runnable) {
         addLast(element)
         if (!scheduled) {
             scheduled = true
             schedule()
         }
     }

     fun process() {
         try {
             // limit number of processed messages
             repeat(yieldEvery) {
                 val element = removeFirstOrNull() ?: return@process
                 element.run()
             }
         } finally {
             if (isEmpty) {
                 scheduled = false
             } else {
                 reschedule()
             }
         }
     }
 }

 // We need to reference global setTimeout and clearTimeout so that it works on Node.JS as opposed to
 // using them via "window" (which only works in browser)
 private external fun setTimeout(handler: dynamic, timeout: Int = definedExternally): Int
 private external fun clearTimeout(handle: Int = definedExternally)
	/*
	* Copyright 2016-2021 JetBrains s.r.o. Use of this source code is governed by the Apache 2.0 license.
	*/

	package kotlinx.coroutines

	import kotlinx.coroutines.internal.*
	import org.w3c.dom.*
	import kotlin.coroutines.*
	import kotlin.js.Promise

	private const val MAX_DELAY = Int.MAX_VALUE.toLong()

	private fun delayToInt(timeMillis: Long): Int =
	timeMillis.coerceIn(0, MAX_DELAY).toInt()

	internal sealed class SetTimeoutBasedDispatcher: CoroutineDispatcher(), Delay {
	inner class ScheduledMessageQueue : MessageQueue() {
	internal val processQueue: dynamic = { process() }

	override fun schedule() {
	scheduleQueueProcessing()
	}

	override fun reschedule() {
	setTimeout(processQueue, 0)
	}
	}

	internal val messageQueue = ScheduledMessageQueue()

	abstract fun scheduleQueueProcessing()

	override fun limitedParallelism(parallelism: Int): CoroutineDispatcher {
	parallelism.checkParallelism()
	return this
	}

	override fun dispatch(context: CoroutineContext, block: Runnable) {
	messageQueue.enqueue(block)
	}

	override fun invokeOnTimeout(timeMillis: Long, block: Runnable, context: CoroutineContext): DisposableHandle {
	val handle = setTimeout({ block.run() }, delayToInt(timeMillis))
	return ClearTimeout(handle)
	}

	override fun scheduleResumeAfterDelay(timeMillis: Long, continuation: CancellableContinuation<Unit>) {
	val handle = setTimeout({ with(continuation) { resumeUndispatched(Unit) } }, delayToInt(timeMillis))
	// Actually on cancellation, but clearTimeout is idempotent
	continuation.invokeOnCancellation(handler = ClearTimeout(handle).asHandler)
	}
	}

	internal object NodeDispatcher : SetTimeoutBasedDispatcher() {
	override fun scheduleQueueProcessing() {
	process.nextTick(messageQueue.processQueue)
	}
	}

	internal object SetTimeoutDispatcher : SetTimeoutBasedDispatcher() {
	override fun scheduleQueueProcessing() {
	setTimeout(messageQueue.processQueue, 0)
	}
	}

	private class ClearTimeout(private val handle: Int) : CancelHandler(), DisposableHandle {

	override fun dispose() {
	clearTimeout(handle)
	}

	override fun invoke(cause: Throwable?) {
	dispose()
	}

	override fun toString(): String = "ClearTimeout[$handle]"
	}

	internal class WindowDispatcher(private val window: Window) : CoroutineDispatcher(), Delay {
	private val queue = WindowMessageQueue(window)

	override fun dispatch(context: CoroutineContext, block: Runnable) = queue.enqueue(block)

	override fun scheduleResumeAfterDelay(timeMillis: Long, continuation: CancellableContinuation<Unit>) {
	window.setTimeout({ with(continuation) { resumeUndispatched(Unit) } }, delayToInt(timeMillis))
	}

	override fun invokeOnTimeout(timeMillis: Long, block: Runnable, context: CoroutineContext): DisposableHandle {
	val handle = window.setTimeout({ block.run() }, delayToInt(timeMillis))
	return object : DisposableHandle {
	override fun dispose() {
	window.clearTimeout(handle)
	}
	}
	}
	}

	private class WindowMessageQueue(private val window: Window) : MessageQueue() {
	private val messageName = "dispatchCoroutine"

	init {
	window.addEventListener("message", { event: dynamic ->
	if (event.source == window && event.data == messageName) {
	event.stopPropagation()
	process()
	}
	}, true)
	}

	override fun schedule() {
	Promise.resolve(Unit).then({ process() })
	}

	override fun reschedule() {
	window.postMessage(messageName, "*")
	}
	}

	/**
	* An abstraction over JS scheduling mechanism that leverages micro-batching of dispatched blocks without
	* paying the cost of JS callbacks scheduling on every dispatch.
	*
	* Queue uses two scheduling mechanisms:
	* 1) [schedule] is used to schedule the initial processing of the message queue.
	* JS engine-specific microtask mechanism is used in order to boost performance on short runs and a dispatch batch
	* 2) [reschedule] is used to schedule processing of the queue after yield to the JS event loop.
	* JS engine-specific macrotask mechanism is used not to starve animations and non-coroutines macrotasks.
	*
	* Yet there could be a long tail of "slow" reschedules, but it should be amortized by the queue size.
	*/
	internal abstract class MessageQueue : ArrayQueue<Runnable>() {
	val yieldEvery = 16 // yield to JS macrotask event loop after this many processed messages
	private var scheduled = false

	abstract fun schedule()

	abstract fun reschedule()

	fun enqueue(element: Runnable) {
	addLast(element)
	if (!scheduled) {
	scheduled = true
	schedule()
	}
	}

	fun process() {
	try {
	// limit number of processed messages
	repeat(yieldEvery) {
	val element = removeFirstOrNull() ?: return@process
	element.run()
	}
	} finally {
	if (isEmpty) {
	scheduled = false
	} else {
	reschedule()
	}
	}
	}
	}

	// We need to reference global setTimeout and clearTimeout so that it works on Node.JS as opposed to
	// using them via "window" (which only works in browser)
	private external fun setTimeout(handler: dynamic, timeout: Int = definedExternally): Int
	private external fun clearTimeout(handle: Int = definedExternally)