commonMain.flow.internal.ChannelFlow.kt Maven / Gradle / Ivy
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Coroutines support libraries for Kotlin
package kotlinx.coroutines.flow.internal
import kotlinx.coroutines.*
import kotlinx.coroutines.channels.*
import kotlinx.coroutines.flow.*
import kotlinx.coroutines.internal.*
import kotlin.coroutines.*
import kotlin.coroutines.intrinsics.*
import kotlin.jvm.*
internal fun Flow.asChannelFlow(): ChannelFlow =
this as? ChannelFlow ?: ChannelFlowOperatorImpl(this)
/**
* Operators that can fuse with **downstream** [buffer] and [flowOn] operators implement this interface.
*
* @suppress **This an internal API and should not be used from general code.**
*/
@InternalCoroutinesApi
public interface FusibleFlow : Flow {
/**
* This function is called by [flowOn] (with context) and [buffer] (with capacity) operators
* that are applied to this flow. Should not be used with [capacity] of [Channel.CONFLATED]
* (it shall be desugared to `capacity = 0, onBufferOverflow = DROP_OLDEST`).
*/
public fun fuse(
context: CoroutineContext = EmptyCoroutineContext,
capacity: Int = Channel.OPTIONAL_CHANNEL,
onBufferOverflow: BufferOverflow = BufferOverflow.SUSPEND
): Flow
}
/**
* Operators that use channels as their "output" extend this `ChannelFlow` and are always fused with each other.
* This class servers as a skeleton implementation of [FusibleFlow] and provides other cross-cutting
* methods like ability to [produceIn] the corresponding flow, thus making it
* possible to directly use the backing channel if it exists (hence the `ChannelFlow` name).
*
* @suppress **This an internal API and should not be used from general code.**
*/
@InternalCoroutinesApi
public abstract class ChannelFlow(
// upstream context
@JvmField public val context: CoroutineContext,
// buffer capacity between upstream and downstream context
@JvmField public val capacity: Int,
// buffer overflow strategy
@JvmField public val onBufferOverflow: BufferOverflow
) : FusibleFlow {
init {
assert { capacity != Channel.CONFLATED } // CONFLATED must be desugared to 0, DROP_OLDEST by callers
}
// shared code to create a suspend lambda from collectTo function in one place
internal val collectToFun: suspend (ProducerScope) -> Unit
get() = { collectTo(it) }
internal val produceCapacity: Int
get() = if (capacity == Channel.OPTIONAL_CHANNEL) Channel.BUFFERED else capacity
/**
* When this [ChannelFlow] implementation can work without a channel (supports [Channel.OPTIONAL_CHANNEL]),
* then it should return a non-null value from this function, so that a caller can use it without the effect of
* additional [flowOn] and [buffer] operators, by incorporating its
* [context], [capacity], and [onBufferOverflow] into its own implementation.
*/
public open fun dropChannelOperators(): Flow? = null
public override fun fuse(context: CoroutineContext, capacity: Int, onBufferOverflow: BufferOverflow): Flow {
assert { capacity != Channel.CONFLATED } // CONFLATED must be desugared to (0, DROP_OLDEST) by callers
// note: previous upstream context (specified before) takes precedence
val newContext = context + this.context
val newCapacity: Int
val newOverflow: BufferOverflow
if (onBufferOverflow != BufferOverflow.SUSPEND) {
// this additional buffer never suspends => overwrite preceding buffering configuration
newCapacity = capacity
newOverflow = onBufferOverflow
} else {
// combine capacities, keep previous overflow strategy
newCapacity = when {
this.capacity == Channel.OPTIONAL_CHANNEL -> capacity
capacity == Channel.OPTIONAL_CHANNEL -> this.capacity
this.capacity == Channel.BUFFERED -> capacity
capacity == Channel.BUFFERED -> this.capacity
else -> {
// sanity checks
assert { this.capacity >= 0 }
assert { capacity >= 0 }
// combine capacities clamping to UNLIMITED on overflow
val sum = this.capacity + capacity
if (sum >= 0) sum else Channel.UNLIMITED // unlimited on int overflow
}
}
newOverflow = this.onBufferOverflow
}
if (newContext == this.context && newCapacity == this.capacity && newOverflow == this.onBufferOverflow)
return this
return create(newContext, newCapacity, newOverflow)
}
protected abstract fun create(context: CoroutineContext, capacity: Int, onBufferOverflow: BufferOverflow): ChannelFlow
protected abstract suspend fun collectTo(scope: ProducerScope)
/**
* Here we use ATOMIC start for a reason (#1825).
* NB: [produceImpl] is used for [flowOn].
* For non-atomic start it is possible to observe the situation,
* where the pipeline after the [flowOn] call successfully executes (mostly, its `onCompletion`)
* handlers, while the pipeline before does not, because it was cancelled during its dispatch.
* Thus `onCompletion` and `finally` blocks won't be executed and it may lead to a different kinds of memory leaks.
*/
public open fun produceImpl(scope: CoroutineScope): ReceiveChannel =
scope.produce(context, produceCapacity, onBufferOverflow, start = CoroutineStart.ATOMIC, block = collectToFun)
override suspend fun collect(collector: FlowCollector): Unit =
coroutineScope {
collector.emitAll(produceImpl(this))
}
protected open fun additionalToStringProps(): String? = null
// debug toString
override fun toString(): String {
val props = ArrayList(4)
additionalToStringProps()?.let { props.add(it) }
if (context !== EmptyCoroutineContext) props.add("context=$context")
if (capacity != Channel.OPTIONAL_CHANNEL) props.add("capacity=$capacity")
if (onBufferOverflow != BufferOverflow.SUSPEND) props.add("onBufferOverflow=$onBufferOverflow")
return "$classSimpleName[${props.joinToString(", ")}]"
}
}
// ChannelFlow implementation that operates on another flow before it
internal abstract class ChannelFlowOperator(
@JvmField protected val flow: Flow,
context: CoroutineContext,
capacity: Int,
onBufferOverflow: BufferOverflow
) : ChannelFlow(context, capacity, onBufferOverflow) {
protected abstract suspend fun flowCollect(collector: FlowCollector)
// Changes collecting context upstream to the specified newContext, while collecting in the original context
private suspend fun collectWithContextUndispatched(collector: FlowCollector, newContext: CoroutineContext) {
val originalContextCollector = collector.withUndispatchedContextCollector(coroutineContext)
// invoke flowCollect(originalContextCollector) in the newContext
return withContextUndispatched(newContext, block = { flowCollect(it) }, value = originalContextCollector)
}
// Slow path when output channel is required
protected override suspend fun collectTo(scope: ProducerScope) =
flowCollect(SendingCollector(scope))
// Optimizations for fast-path when channel creation is optional
override suspend fun collect(collector: FlowCollector) {
// Fast-path: When channel creation is optional (flowOn/flowWith operators without buffer)
if (capacity == Channel.OPTIONAL_CHANNEL) {
val collectContext = coroutineContext
val newContext = collectContext.newCoroutineContext(context) // compute resulting collect context
// #1: If the resulting context happens to be the same as it was -- fallback to plain collect
if (newContext == collectContext)
return flowCollect(collector)
// #2: If we don't need to change the dispatcher we can go without channels
if (newContext[ContinuationInterceptor] == collectContext[ContinuationInterceptor])
return collectWithContextUndispatched(collector, newContext)
}
// Slow-path: create the actual channel
super.collect(collector)
}
// debug toString
override fun toString(): String = "$flow -> ${super.toString()}"
}
/**
* Simple channel flow operator: [flowOn], [buffer], or their fused combination.
*/
internal class ChannelFlowOperatorImpl(
flow: Flow,
context: CoroutineContext = EmptyCoroutineContext,
capacity: Int = Channel.OPTIONAL_CHANNEL,
onBufferOverflow: BufferOverflow = BufferOverflow.SUSPEND
) : ChannelFlowOperator(flow, context, capacity, onBufferOverflow) {
override fun create(context: CoroutineContext, capacity: Int, onBufferOverflow: BufferOverflow): ChannelFlow =
ChannelFlowOperatorImpl(flow, context, capacity, onBufferOverflow)
override fun dropChannelOperators(): Flow = flow
override suspend fun flowCollect(collector: FlowCollector) =
flow.collect(collector)
}
// Now if the underlying collector was accepting concurrent emits, then this one is too
// todo: we might need to generalize this pattern for "thread-safe" operators that can fuse with channels
private fun FlowCollector.withUndispatchedContextCollector(emitContext: CoroutineContext): FlowCollector = when (this) {
// SendingCollector & NopCollector do not care about the context at all and can be used as is
is SendingCollector, is NopCollector -> this
// Otherwise just wrap into UndispatchedContextCollector interface implementation
else -> UndispatchedContextCollector(this, emitContext)
}
private class UndispatchedContextCollector(
downstream: FlowCollector,
private val emitContext: CoroutineContext
) : FlowCollector {
private val countOrElement = threadContextElements(emitContext) // precompute for fast withContextUndispatched
private val emitRef: suspend (T) -> Unit = { downstream.emit(it) } // allocate suspend function ref once on creation
override suspend fun emit(value: T): Unit =
withContextUndispatched(emitContext, value, countOrElement, emitRef)
}
// Efficiently computes block(value) in the newContext
internal suspend fun withContextUndispatched(
newContext: CoroutineContext,
value: V,
countOrElement: Any = threadContextElements(newContext), // can be precomputed for speed
block: suspend (V) -> T
): T =
suspendCoroutineUninterceptedOrReturn { uCont ->
withCoroutineContext(newContext, countOrElement) {
block.startCoroutineUninterceptedOrReturn(value, StackFrameContinuation(uCont, newContext))
}
}
// Continuation that links the caller with uCont with walkable CoroutineStackFrame
private class StackFrameContinuation(
private val uCont: Continuation, override val context: CoroutineContext
) : Continuation, CoroutineStackFrame {
override val callerFrame: CoroutineStackFrame?
get() = uCont as? CoroutineStackFrame
override fun resumeWith(result: Result) {
uCont.resumeWith(result)
}
override fun getStackTraceElement(): StackTraceElement? = null
}