.kotlin.kotlin-compiler.1.3.11.source-code.UsageTracker.kt Maven / Gradle / Ivy
/*
* Copyright 2010-2016 JetBrains s.r.o.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
package org.jetbrains.kotlin.js.translate.context
import org.jetbrains.kotlin.descriptors.*
import org.jetbrains.kotlin.js.backend.ast.JsName
import org.jetbrains.kotlin.js.backend.ast.JsScope
import org.jetbrains.kotlin.js.backend.ast.metadata.descriptor
import org.jetbrains.kotlin.js.descriptorUtils.isCoroutineLambda
import org.jetbrains.kotlin.js.naming.NameSuggestion
import org.jetbrains.kotlin.resolve.DescriptorUtils
import org.jetbrains.kotlin.resolve.DescriptorUtils.*
import org.jetbrains.kotlin.resolve.calls.util.FakeCallableDescriptorForObject
private val CAPTURED_RECEIVER_NAME_PREFIX : String = "this$"
class UsageTracker(
private val parent: UsageTracker?,
val containingDescriptor: MemberDescriptor
) {
private val captured = linkedMapOf()
private val capturedTypesImpl = mutableMapOf()
// For readonly access from external places.
val capturedDescriptorToJsName: Map
get() = captured
val capturedDescriptors: Set
get() = captured.keys
val capturedTypes: Map
get() = capturedTypesImpl
fun used(descriptor: DeclarationDescriptor) {
if (isCaptured(descriptor)) return
if (descriptor is FakeCallableDescriptorForObject) return
// local named function
if (descriptor is FunctionDescriptor && descriptor.visibility == Visibilities.LOCAL) {
captureIfNeed(descriptor)
}
// local variable
else if (descriptor is VariableDescriptor && descriptor !is PropertyDescriptor) {
captureIfNeed(descriptor)
}
// this or receiver
else if (descriptor is ReceiverParameterDescriptor) {
captureIfNeed(descriptor)
}
else if (descriptor is TypeParameterDescriptor && descriptor.isReified) {
captureIfNeed(descriptor)
}
}
private fun captureIfNeed(descriptor: DeclarationDescriptor?) {
if (descriptor == null || isCaptured(descriptor) || !isInLocalDeclaration() ||
isAncestor(containingDescriptor, descriptor, /* strict = */ true) ||
isReceiverAncestor(descriptor) || isSingletonReceiver(descriptor)
) {
return
}
if (descriptor.isCoroutineLambda && descriptor == containingDescriptor) return
parent?.captureIfNeed(descriptor)
captured[descriptor] = descriptor.getJsNameForCapturedDescriptor()
if (descriptor is TypeParameterDescriptor && descriptor.containingDeclaration.original != containingDescriptor.original) {
val name = "typeClosure\$" + NameSuggestion.sanitizeName(descriptor.name.asString())
capturedTypesImpl[descriptor] = JsScope.declareTemporaryName(name)
}
}
private fun isInLocalDeclaration(): Boolean {
val container = containingDescriptor
return isDescriptorWithLocalVisibility(if (container is ConstructorDescriptor) container.containingDeclaration else container)
}
/**
* We shouldn't capture current `this` or outer `this`. Assuming `C` is current translating class,
* we have `descriptor == A::this` in the following cases:
* * `A == C`
* * `C` in inner class of `A`
* * `A <: C`
* * among outer classes of `C` there is `T` such that `A <: T`
*
* If fact, the latter case is the generalization of all previous cases, assuming that `is inner class of` and `<:` relations
* are reflective. All this cases allow to refer to `this` directly or via sequence of `outer` fields.
*
* Note that the continuous sequence of inner classes may be interrupted by non-class descriptor. This means that
* the last class of the sequence if a local class. We stop there, since this means that the next class in the sequence
* is referred by closure variable rather than by dedicated `$outer` field.
*
* The nested classes are out of scope, since nested class can't refer to outer's class `this`, thus frontend will
* never generate ReceiverParameterDescriptor for this case.
*/
private fun isReceiverAncestor(descriptor: DeclarationDescriptor): Boolean {
if (descriptor !is ReceiverParameterDescriptor) return false
if (containingDescriptor !is ClassDescriptor && containingDescriptor !is ConstructorDescriptor) return false
// Class in which we are trying to capture variable
val containingClass = getParentOfType(containingDescriptor, ClassDescriptor::class.java, false) ?: return false
// Class which instance we are trying to capture
val currentClass = descriptor.containingDeclaration as? ClassDescriptor ?: return false
for (outerDeclaration in generateSequence(containingClass) { it.containingDeclaration as? ClassDescriptor }) {
if (outerDeclaration == currentClass) return true
}
return false
}
/**
* Test for the case like this:
*
* ```
* object A {
* var x: Int
*
* class B {
* fun foo() {
* { x }
* }
* }
* }
* ```
*
* We don't want to capture `A::this`, since we always can refer A by its FQN
*/
private fun isSingletonReceiver(descriptor: DeclarationDescriptor): Boolean {
if (descriptor !is ReceiverParameterDescriptor) return false
val container = descriptor.containingDeclaration
if (!DescriptorUtils.isObject(container)) return false
// This code is necessary for one use case. If we don't treat `O::this` as a free variable of lambda, we'll get
// `this` in generated JS. `this` is generated since it's placed in aliasing context for `O::this`, so we will get
// it instead of generating FQN. However, we can't refer to `this` from lambda, since `this` points not to an instance of `C`,
// but to lambda function itself. We avoid it by treating `O::this` as a free variable.
// Example is:
//
// object A(val x: Int) {
// fun foo() = { x }
// }
if (containingDescriptor !is ClassDescriptor) {
val containingClass = getParentOfType(containingDescriptor, ClassDescriptor::class.java, false)
if (containingClass == container) return false
}
return true
}
private fun DeclarationDescriptor.getJsNameForCapturedDescriptor(): JsName {
val suggestedName = when (this) {
is ReceiverParameterDescriptor -> getNameForCapturedReceiver()
is TypeParameterDescriptor -> Namer.isInstanceSuggestedName(this)
// Append 'closure$' prefix to avoid name clash between closure and member fields in case of local classes
else -> {
val mangled = NameSuggestion.sanitizeName(NameSuggestion().suggest(this)!!.names.last())
"closure\$$mangled"
}
}
return JsScope.declareTemporaryName(suggestedName).apply { descriptor = this@getJsNameForCapturedDescriptor }
}
}
fun UsageTracker.getNameForCapturedDescriptor(descriptor: DeclarationDescriptor): JsName? = capturedDescriptorToJsName[descriptor]
fun UsageTracker.hasCapturedExceptContaining(): Boolean {
val hasNotCaptured =
capturedDescriptorToJsName.isEmpty() ||
(capturedDescriptorToJsName.size == 1 && capturedDescriptorToJsName.containsKey(containingDescriptor))
return !hasNotCaptured
}
fun UsageTracker.isCaptured(descriptor: DeclarationDescriptor): Boolean = capturedDescriptorToJsName.containsKey(descriptor)
// NOTE: don't use from other places to avoid name clashes! So, it is not in Namer.
private fun ReceiverParameterDescriptor.getNameForCapturedReceiver(): String {
fun DeclarationDescriptor.getNameForCapturedDescriptor(namePostfix: String = ""): String {
val name = this.name
val nameAsString = if (name.isSpecial) "" else name.asString()
return CAPTURED_RECEIVER_NAME_PREFIX + nameAsString + namePostfix
}
val containingDeclaration = this.containingDeclaration
assert(containingDeclaration is MemberDescriptor) {
"Unsupported descriptor type: ${containingDeclaration::class.java}, " +
"receiverDescriptor = $this, " + "containingDeclaration = $containingDeclaration"
}
if (DescriptorUtils.isCompanionObject(containingDeclaration)) {
return containingDeclaration.containingDeclaration!!.getNameForCapturedDescriptor(namePostfix = "$")
}
return containingDeclaration.getNameForCapturedDescriptor()
}