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Coroutines support libraries for Kotlin
/*
* 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 kotlin.coroutines.*
/**
* Base class to be extended by all coroutine dispatcher implementations.
*
* The following standard implementations are provided by `kotlinx.coroutines` as properties on
* the [Dispatchers] object:
*
* * [Dispatchers.Default] — is used by all standard builders if no dispatcher or any other [ContinuationInterceptor]
* is specified in their context. It uses a common pool of shared background threads.
* This is an appropriate choice for compute-intensive coroutines that consume CPU resources.
* * [Dispatchers.IO] — uses a shared pool of on-demand created threads and is designed for offloading of IO-intensive _blocking_
* operations (like file I/O and blocking socket I/O).
* * [Dispatchers.Unconfined] — starts coroutine execution in the current call-frame until the first suspension,
* whereupon the coroutine builder function returns.
* The coroutine will later resume in whatever thread used by the
* corresponding suspending function, without confining it to any specific thread or pool.
* **The `Unconfined` dispatcher should not normally be used in code**.
* * Private thread pools can be created with [newSingleThreadContext] and [newFixedThreadPoolContext].
* * An arbitrary [Executor][java.util.concurrent.Executor] can be converted to a dispatcher with the [asCoroutineDispatcher] extension function.
*
* This class ensures that debugging facilities in [newCoroutineContext] function work properly.
*/
public abstract class CoroutineDispatcher :
AbstractCoroutineContextElement(ContinuationInterceptor), ContinuationInterceptor {
/** @suppress */
@ExperimentalStdlibApi
public companion object Key : AbstractCoroutineContextKey(
ContinuationInterceptor,
{ it as? CoroutineDispatcher })
/**
* Returns `true` if the execution of the coroutine should be performed with [dispatch] method.
* The default behavior for most dispatchers is to return `true`.
*
* If this method returns `false`, the coroutine is resumed immediately in the current thread,
* potentially forming an event-loop to prevent stack overflows.
* The event loop is an advanced topic and its implications can be found in [Dispatchers.Unconfined] documentation.
*
* The [context] parameter represents the context of the coroutine that is being dispatched,
* or [EmptyCoroutineContext] if a non-coroutine-specific [Runnable] is dispatched instead.
*
* A dispatcher can override this method to provide a performance optimization and avoid paying a cost of an unnecessary dispatch.
* E.g. [MainCoroutineDispatcher.immediate] checks whether we are already in the required UI thread in this method and avoids
* an additional dispatch when it is not required.
*
* While this approach can be more efficient, it is not chosen by default to provide a consistent dispatching behaviour
* so that users won't observe unexpected and non-consistent order of events by default.
*
* Coroutine builders like [launch][CoroutineScope.launch] and [async][CoroutineScope.async] accept an optional [CoroutineStart]
* parameter that allows one to optionally choose the [undispatched][CoroutineStart.UNDISPATCHED] behavior to start coroutine immediately,
* but to be resumed only in the provided dispatcher.
*
* This method should generally be exception-safe. An exception thrown from this method
* may leave the coroutines that use this dispatcher in the inconsistent and hard to debug state.
*
* @see dispatch
* @see Dispatchers.Unconfined
*/
public open fun isDispatchNeeded(context: CoroutineContext): Boolean = true
/**
* Creates a view of the current dispatcher that limits the parallelism to the given [value][parallelism].
* The resulting view uses the original dispatcher for execution, but with the guarantee that
* no more than [parallelism] coroutines are executed at the same time.
*
* This method does not impose restrictions on the number of views or the total sum of parallelism values,
* each view controls its own parallelism independently with the guarantee that the effective parallelism
* of all views cannot exceed the actual parallelism of the original dispatcher.
*
* ### Limitations
*
* The default implementation of `limitedParallelism` does not support direct dispatchers,
* such as executing the given runnable in place during [dispatch] calls.
* Any dispatcher that may return `false` from [isDispatchNeeded] is considered direct.
* For direct dispatchers, it is recommended to override this method
* and provide a domain-specific implementation or to throw an [UnsupportedOperationException].
*
* ### Example of usage
* ```
* private val backgroundDispatcher = newFixedThreadPoolContext(4, "App Background")
* // At most 2 threads will be processing images as it is really slow and CPU-intensive
* private val imageProcessingDispatcher = backgroundDispatcher.limitedParallelism(2)
* // At most 3 threads will be processing JSON to avoid image processing starvation
* private val jsonProcessingDispatcher = backgroundDispatcher.limitedParallelism(3)
* // At most 1 thread will be doing IO
* private val fileWriterDispatcher = backgroundDispatcher.limitedParallelism(1)
* ```
* Note how in this example the application has an executor with 4 threads, but the total sum of all limits
* is 6. Still, at most 4 coroutines can be executed simultaneously as each view limits only its own parallelism.
*
* Note that this example was structured in such a way that it illustrates the parallelism guarantees.
* In practice, it is usually better to use [Dispatchers.IO] or [Dispatchers.Default] instead of creating a
* `backgroundDispatcher`. It is both possible and advised to call `limitedParallelism` on them.
*/
@ExperimentalCoroutinesApi
public open fun limitedParallelism(parallelism: Int): CoroutineDispatcher {
parallelism.checkParallelism()
return LimitedDispatcher(this, parallelism)
}
/**
* Requests execution of a runnable [block].
* The dispatcher guarantees that [block] will eventually execute, typically by dispatching it to a thread pool,
* using a dedicated thread, or just executing the block in place.
* The [context] parameter represents the context of the coroutine that is being dispatched,
* or [EmptyCoroutineContext] if a non-coroutine-specific [Runnable] is dispatched instead.
* Implementations may use [context] for additional context-specific information,
* such as priority, whether the dispatched coroutine can be invoked in place,
* coroutine name, and additional diagnostic elements.
*
* This method should guarantee that the given [block] will be eventually invoked,
* otherwise the system may reach a deadlock state and never leave it.
* The cancellation mechanism is transparent for [CoroutineDispatcher] and is managed by [block] internals.
*
* This method should generally be exception-safe. An exception thrown from this method
* may leave the coroutines that use this dispatcher in an inconsistent and hard-to-debug state.
*
* This method must not immediately call [block]. Doing so may result in `StackOverflowError`
* when `dispatch` is invoked repeatedly, for example when [yield] is called in a loop.
* In order to execute a block in place, it is required to return `false` from [isDispatchNeeded]
* and delegate the `dispatch` implementation to `Dispatchers.Unconfined.dispatch` in such cases.
* To support this, the coroutines machinery ensures in-place execution and forms an event-loop to
* avoid unbound recursion.
*
* @see isDispatchNeeded
* @see Dispatchers.Unconfined
*/
public abstract fun dispatch(context: CoroutineContext, block: Runnable)
/**
* Dispatches execution of a runnable `block` onto another thread in the given `context`
* with a hint for the dispatcher that the current dispatch is triggered by a [yield] call, so that the execution of this
* continuation may be delayed in favor of already dispatched coroutines.
*
* Though the `yield` marker may be passed as a part of [context], this
* is a separate method for performance reasons.
*
* @suppress **This an internal API and should not be used from general code.**
*/
@InternalCoroutinesApi
public open fun dispatchYield(context: CoroutineContext, block: Runnable): Unit = dispatch(context, block)
/**
* Returns a continuation that wraps the provided [continuation], thus intercepting all resumptions.
*
* This method should generally be exception-safe. An exception thrown from this method
* may leave the coroutines that use this dispatcher in the inconsistent and hard to debug state.
*/
public final override fun interceptContinuation(continuation: Continuation): Continuation =
DispatchedContinuation(this, continuation)
public final override fun releaseInterceptedContinuation(continuation: Continuation<*>) {
/*
* Unconditional cast is safe here: we only return DispatchedContinuation from `interceptContinuation`,
* any ClassCastException can only indicate compiler bug
*/
val dispatched = continuation as DispatchedContinuation<*>
dispatched.release()
}
/**
* @suppress **Error**: Operator '+' on two CoroutineDispatcher objects is meaningless.
* CoroutineDispatcher is a coroutine context element and `+` is a set-sum operator for coroutine contexts.
* The dispatcher to the right of `+` just replaces the dispatcher to the left.
*/
@Suppress("DeprecatedCallableAddReplaceWith")
@Deprecated(
message = "Operator '+' on two CoroutineDispatcher objects is meaningless. " +
"CoroutineDispatcher is a coroutine context element and `+` is a set-sum operator for coroutine contexts. " +
"The dispatcher to the right of `+` just replaces the dispatcher to the left.",
level = DeprecationLevel.ERROR
)
public operator fun plus(other: CoroutineDispatcher): CoroutineDispatcher = other
/** @suppress for nicer debugging */
override fun toString(): String = "$classSimpleName@$hexAddress"
}
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