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/*
* Copyright 2010-2023 JetBrains s.r.o. and Kotlin Programming Language contributors.
* Use of this source code is governed by the Apache 2.0 license that can be found in the license/LICENSE.txt file.
*/
package org.jetbrains.kotlin.fir.resolve
import org.jetbrains.kotlin.KtFakeSourceElementKind
import org.jetbrains.kotlin.KtSourceElement
import org.jetbrains.kotlin.builtins.functions.FunctionTypeKind
import org.jetbrains.kotlin.descriptors.ClassKind
import org.jetbrains.kotlin.descriptors.Modality
import org.jetbrains.kotlin.fakeElement
import org.jetbrains.kotlin.fir.*
import org.jetbrains.kotlin.fir.declarations.*
import org.jetbrains.kotlin.fir.declarations.utils.*
import org.jetbrains.kotlin.fir.diagnostics.*
import org.jetbrains.kotlin.fir.expressions.*
import org.jetbrains.kotlin.fir.expressions.builder.*
import org.jetbrains.kotlin.fir.expressions.impl.FirUnitExpression
import org.jetbrains.kotlin.fir.references.*
import org.jetbrains.kotlin.fir.references.builder.buildErrorNamedReference
import org.jetbrains.kotlin.fir.references.builder.buildResolvedErrorReference
import org.jetbrains.kotlin.fir.resolve.calls.*
import org.jetbrains.kotlin.fir.resolve.dfa.cfg.FirAnonymousFunctionReturnExpressionInfo
import org.jetbrains.kotlin.fir.resolve.diagnostics.*
import org.jetbrains.kotlin.fir.resolve.providers.symbolProvider
import org.jetbrains.kotlin.fir.resolve.transformers.body.resolve.resultType
import org.jetbrains.kotlin.fir.scopes.FirTypeScope
import org.jetbrains.kotlin.fir.scopes.ProcessorAction
import org.jetbrains.kotlin.fir.scopes.impl.importedFromObjectOrStaticData
import org.jetbrains.kotlin.fir.scopes.processOverriddenFunctions
import org.jetbrains.kotlin.fir.symbols.ConeClassLikeLookupTag
import org.jetbrains.kotlin.fir.symbols.FirBasedSymbol
import org.jetbrains.kotlin.fir.symbols.impl.*
import org.jetbrains.kotlin.fir.symbols.lazyResolveToPhase
import org.jetbrains.kotlin.fir.types.*
import org.jetbrains.kotlin.fir.types.builder.buildErrorTypeRef
import org.jetbrains.kotlin.fir.types.builder.buildResolvedTypeRef
import org.jetbrains.kotlin.fir.types.impl.ConeClassLikeTypeImpl
import org.jetbrains.kotlin.fir.types.impl.ConeTypeParameterTypeImpl
import org.jetbrains.kotlin.fir.utils.exceptions.withFirEntry
import org.jetbrains.kotlin.fir.visitors.FirTransformer
import org.jetbrains.kotlin.name.ClassId
import org.jetbrains.kotlin.name.Name
import org.jetbrains.kotlin.name.StandardClassIds
import org.jetbrains.kotlin.resolve.ForbiddenNamedArgumentsTarget
import org.jetbrains.kotlin.resolve.calls.tower.CandidateApplicability
import org.jetbrains.kotlin.types.ConstantValueKind
import org.jetbrains.kotlin.types.SmartcastStability
import org.jetbrains.kotlin.types.model.safeSubstitute
import org.jetbrains.kotlin.utils.addIfNotNull
import org.jetbrains.kotlin.utils.exceptions.errorWithAttachment
import kotlin.contracts.ExperimentalContracts
import kotlin.contracts.contract
fun FirAnonymousFunction.shouldReturnUnit(returnStatements: Collection): Boolean =
isLambda && returnStatements.any { it is FirUnitExpression }
/**
* Infers the return type of an anonymous function from return expressions in its body.
*
* Note: this logic affects not only diagnostics, but also the runtime types of generated lambda classes (at least on JVM).
* See [KT-62550](https://youtrack.jetbrains.com/issue/KT-62550) and `compiler/testData/codegen/box/callableReference/kt62550.kt`
* for reference.
* Namely, this code basically decides what `T` should be in the `FunctionN` interface that the lambda class will implement.
* This can be observed through reflection.
*
* It's important to understand that the logic is a bit different for lambdas passed to functions and for all other lambdas:
* - the return type of a lambda passed to a function is always inferred to [expectedReturnType],
* except when the lambda's body implies that it's `Unit` — in that case, the return type is inferred to `Unit`;
* - the return type of other lambda expressions (e.g., assigned to a variable) is generally computed as a common supertype of
* the expressions in its `return` statements.
*/
internal fun FirAnonymousFunction.computeReturnType(
session: FirSession,
expectedReturnType: ConeKotlinType?,
isPassedAsFunctionArgument: Boolean,
returnExpressions: Collection,
): ConeKotlinType {
val expandedExpectedReturnType = expectedReturnType?.fullyExpandedType(session)
val unitType = session.builtinTypes.unitType.type
if (isLambda) {
if (expandedExpectedReturnType?.isUnitOrFlexibleUnit == true) {
// If the expected type is Unit or flexible Unit, always infer the lambda's type to Unit.
// If a return statement in a lambda has a different type, RETURN_TYPE_MISMATCH will be reported for that return statement
// by FirFunctionReturnTypeMismatchChecker.
//
// For example:
// val f: () -> Unit = l@ {
// return@l "" // RETURN_TYPE_MISMATCH reported here
// }
//
// Without this check, INITIALIZER_TYPE_MISMATCH would be reported on the whole lambda expression,
// because the return type of the lambda would be inferred to String.
//
// NOTE: If the lambda's expected type is flexible Unit, we forbid returning null from such a lambda.
// See KT-66909.
return unitType
}
if (returnExpressions.any { it.isExplicit && it.expression is FirUnitExpression }) {
// If the expected type is not Unit, and we have an explicit expressionless return, don't infer the return type to Unit.
// For this situation, RETURN_TYPE_MISMATCH will be reported later in FirFunctionReturnTypeMismatchChecker.
//
// For example:
// val f: () -> Any = l@ {
// if ("".hashCode() == 42) return@l // RETURN_TYPE_MISMATCH reported here
// return@l Unit
// }
//
// Without this check, INITIALIZER_TYPE_MISMATCH would be reported on the whole lambda expression,
// because the return type of the lambda would be inferred to Unit.
return if (expandedExpectedReturnType != null) {
expectedReturnType
} else {
unitType
}
}
}
// Here is a questionable moment where we could prefer the expected type over an inferred one.
// In correct code this doesn't matter, as all return expression types should be subtypes of the expected type.
// In incorrect code, this would change diagnostics: we can get errors either on the entire lambda, or only on its
// return statements. The former kind of makes more sense, but the latter is more readable.
val commonSuperType = session.typeContext.commonSuperTypeOrNull(returnExpressions.map { it.expression.resolvedType })
?: unitType
return if (isPassedAsFunctionArgument && !commonSuperType.fullyExpandedType(session).isUnit) {
expectedReturnType ?: commonSuperType
} else {
commonSuperType
}
}
fun FirAnonymousFunction.addReturnToLastStatementIfNeeded(session: FirSession) {
// If this lambda's resolved, expected return type is Unit, we don't need an explicit return statement.
// During conversion (to backend IR), the last expression will be coerced to Unit if needed.
if (returnTypeRef.coneType.fullyExpandedType(session).isUnit) return
val body = this.body ?: return
val lastStatement = body.statements.lastOrNull() as? FirExpression ?: return
if (lastStatement is FirReturnExpression) return
val returnType = body.resolvedType
if (returnType.isNothing) return
val returnTarget = FirFunctionTarget(null, isLambda = isLambda).also { it.bind(this) }
val returnExpression = buildReturnExpression {
// Always set the source to something because ControlFlowGraphBuilder#returnExpressionsOfAnonymousFunction may query
// the source kind for distinguishing an implicit return from the last statement.
source = (lastStatement.source ?: body.source ?: [email protected])
?.fakeElement(KtFakeSourceElementKind.ImplicitReturn.FromLastStatement)
result = lastStatement
target = returnTarget
}
body.transformStatements(
object : FirTransformer() {
override fun transformElement(element: E, data: Nothing?): E =
@Suppress("UNCHECKED_CAST")
if (element == lastStatement) returnExpression as E else element
}, null
)
}
/**
* [kind] == null means that [FunctionTypeKind.Function] will be used
*/
fun FirFunction.constructFunctionType(kind: FunctionTypeKind? = null): ConeLookupTagBasedType {
val receiverTypeRef = when (this) {
is FirSimpleFunction -> receiverParameter
is FirAnonymousFunction -> receiverParameter
else -> null
}?.typeRef
val parameters = valueParameters.map {
it.returnTypeRef.coneTypeSafe() ?: ConeErrorType(
ConeSimpleDiagnostic(
"No type for parameter",
DiagnosticKind.ValueParameterWithNoTypeAnnotation
)
)
}
val rawReturnType = (this as FirCallableDeclaration).returnTypeRef.coneType
return createFunctionType(
kind ?: FunctionTypeKind.Function, parameters, receiverTypeRef?.coneType, rawReturnType,
contextReceivers = contextReceivers.map { it.typeRef.coneType }
)
}
/**
* [kind] == null means that [FunctionTypeKind.Function] will be used
*/
fun FirAnonymousFunction.constructFunctionTypeRef(session: FirSession, kind: FunctionTypeKind? = null): FirResolvedTypeRef {
var diagnostic: ConeDiagnostic? = null
val kinds = session.functionTypeService.extractAllSpecialKindsForFunction(symbol)
val kindFromDeclaration = when (kinds.size) {
0 -> null
1 -> kinds.single()
else -> {
diagnostic = ConeAmbiguousFunctionTypeKinds(kinds)
FunctionTypeKind.Function
}
}
val type = constructFunctionType(kindFromDeclaration ?: kind)
val source = [email protected]?.fakeElement(KtFakeSourceElementKind.ImplicitTypeRef)
return if (diagnostic == null) {
buildResolvedTypeRef {
this.source = source
this.type = type
}
} else {
buildErrorTypeRef {
this.source = source
this.type = type
this.diagnostic = diagnostic
}
}
}
fun createFunctionType(
kind: FunctionTypeKind,
parameters: List,
receiverType: ConeKotlinType?,
rawReturnType: ConeKotlinType,
contextReceivers: List = emptyList(),
): ConeLookupTagBasedType {
val receiverAndParameterTypes =
buildList {
addAll(contextReceivers)
addIfNotNull(receiverType)
addAll(parameters)
add(rawReturnType)
}
val functionTypeId = ClassId(kind.packageFqName, kind.numberedClassName(receiverAndParameterTypes.size - 1))
val attributes = when {
contextReceivers.isNotEmpty() -> ConeAttributes.create(
buildList {
add(CompilerConeAttributes.ContextFunctionTypeParams(contextReceivers.size))
if (receiverType != null) {
add(CompilerConeAttributes.ExtensionFunctionType)
}
}
)
receiverType != null -> ConeAttributes.WithExtensionFunctionType
else -> ConeAttributes.Empty
}
return ConeClassLikeTypeImpl(
functionTypeId.toLookupTag(),
receiverAndParameterTypes.toTypedArray(),
isNullable = false,
attributes = attributes
)
}
fun createKPropertyType(
receiverType: ConeKotlinType?,
rawReturnType: ConeKotlinType,
isMutable: Boolean,
): ConeLookupTagBasedType {
val arguments = if (receiverType != null) listOf(receiverType, rawReturnType) else listOf(rawReturnType)
val classId = StandardClassIds.reflectByName("K${if (isMutable) "Mutable" else ""}Property${arguments.size - 1}")
return ConeClassLikeTypeImpl(classId.toLookupTag(), arguments.toTypedArray(), isNullable = false)
}
fun BodyResolveComponents.buildResolvedQualifierForClass(
regularClass: FirClassLikeSymbol<*>,
sourceElement: KtSourceElement?,
// Note: we need type arguments here, see e.g. testIncompleteConstructorCall in diagnostic group
typeArgumentsForQualifier: List = emptyList(),
diagnostic: ConeDiagnostic? = null,
nonFatalDiagnostics: List = emptyList(),
annotations: List = emptyList(),
): FirResolvedQualifier {
val classId = regularClass.classId
val builder: FirAbstractResolvedQualifierBuilder = if (diagnostic == null) {
FirResolvedQualifierBuilder()
} else {
FirErrorResolvedQualifierBuilder().apply { this.diagnostic = diagnostic }
}
return builder.apply {
source = sourceElement
packageFqName = classId.packageFqName
relativeClassFqName = classId.relativeClassName
typeArguments.addAll(typeArgumentsForQualifier)
symbol = regularClass
this.nonFatalDiagnostics.addAll(nonFatalDiagnostics)
this.annotations.addAll(annotations)
}.build().apply {
if (classId.isLocal) {
resultType = typeForQualifierByDeclaration(regularClass.fir, session, element = this@apply, file)
?.also { replaceCanBeValue(true) }
?: session.builtinTypes.unitType.type
} else {
setTypeOfQualifier(this@buildResolvedQualifierForClass)
}
}
}
fun FirResolvedQualifier.setTypeOfQualifier(components: BodyResolveComponents) {
val classSymbol = symbol
if (classSymbol != null) {
classSymbol.lazyResolveToPhase(FirResolvePhase.TYPES)
val declaration = classSymbol.fir
if (declaration !is FirTypeAlias || typeArguments.isEmpty()) {
val typeByDeclaration = typeForQualifierByDeclaration(declaration, components.session, element = this, components.file)
if (typeByDeclaration != null) {
this.resultType = typeByDeclaration
replaceCanBeValue(true)
return
}
}
}
this.resultType = components.session.builtinTypes.unitType.type
}
internal fun typeForReifiedParameterReference(parameterReferenceBuilder: FirResolvedReifiedParameterReferenceBuilder): ConeLookupTagBasedType {
val typeParameterSymbol = parameterReferenceBuilder.symbol
return typeParameterSymbol.constructType(emptyArray(), false)
}
internal fun typeForQualifierByDeclaration(
declaration: FirDeclaration, session: FirSession, element: FirElement, file: FirFile
): ConeKotlinType? {
if (declaration is FirTypeAlias) {
val expandedDeclaration = declaration.expandedConeType?.lookupTag?.toSymbol(session)?.fir ?: return null
return typeForQualifierByDeclaration(expandedDeclaration, session, element, file)
}
if (declaration is FirRegularClass) {
if (declaration.classKind == ClassKind.OBJECT) {
return declaration.symbol.constructType(emptyArray(), false)
} else {
val companionObjectSymbol = declaration.companionObjectSymbol
if (companionObjectSymbol != null) {
session.lookupTracker?.recordCompanionLookup(companionObjectSymbol.classId, element.source, file.source)
return companionObjectSymbol.constructType(emptyArray(), false)
}
}
}
return null
}
private fun FirPropertySymbol.isEffectivelyFinal(session: FirSession): Boolean {
if (isFinal) return true
val containingClass = dispatchReceiverType?.toRegularClassSymbol(session)
?: return false
return containingClass.modality == Modality.FINAL && containingClass.classKind != ClassKind.ENUM_CLASS
}
private fun FirPropertyWithExplicitBackingFieldResolvedNamedReference.getNarrowedDownSymbol(session: FirSession): FirBasedSymbol<*> {
val propertyReceiver = resolvedSymbol as? FirPropertySymbol ?: return resolvedSymbol
// This can happen in case of 2 properties referencing
// each other recursively. See: Jet81.fir.kt
if (
propertyReceiver.fir.returnTypeRef is FirImplicitTypeRef ||
propertyReceiver.fir.backingField?.returnTypeRef is FirImplicitTypeRef
) {
return resolvedSymbol
}
if (
propertyReceiver.isEffectivelyFinal(session) &&
hasVisibleBackingField &&
propertyReceiver.canNarrowDownGetterType
) {
return propertyReceiver.fir.backingField?.symbol ?: resolvedSymbol
}
return resolvedSymbol
}
fun BodyResolveComponents.typeFromCallee(access: T): FirResolvedTypeRef {
val calleeReference = access.calleeReference
return typeFromCallee(access, calleeReference)
}
fun BodyResolveComponents.typeFromCallee(access: FirElement, calleeReference: FirReference): FirResolvedTypeRef {
return when (calleeReference) {
is FirErrorNamedReference ->
buildErrorTypeRef {
source = access.source?.fakeElement(KtFakeSourceElementKind.ErrorTypeRef)
diagnostic = ConeStubDiagnostic(calleeReference.diagnostic)
}
is FirNamedReferenceWithCandidate -> {
typeFromSymbol(calleeReference.candidateSymbol)
}
is FirPropertyWithExplicitBackingFieldResolvedNamedReference -> {
val symbol = calleeReference.getNarrowedDownSymbol(session)
typeFromSymbol(symbol)
}
is FirResolvedNamedReference -> {
typeFromSymbol(calleeReference.resolvedSymbol)
}
is FirThisReference -> {
val labelName = calleeReference.labelName
val implicitReceiver = implicitReceiverStack[labelName]
buildResolvedTypeRef {
source = null
type = implicitReceiver?.type ?: ConeErrorType(
ConeSimpleDiagnostic(
"Unresolved this@$labelName",
DiagnosticKind.UnresolvedLabel
)
)
}
}
is FirSuperReference -> {
val labelName = calleeReference.labelName
val implicitReceiver =
if (labelName != null) implicitReceiverStack[labelName] as? ImplicitDispatchReceiverValue
else implicitReceiverStack.lastDispatchReceiver()
val resolvedTypeRef =
calleeReference.superTypeRef as? FirResolvedTypeRef
?: implicitReceiver?.boundSymbol?.fir?.superTypeRefs?.singleOrNull() as? FirResolvedTypeRef
resolvedTypeRef ?: buildErrorTypeRef {
source = calleeReference.source
diagnostic = ConeUnresolvedNameError(Name.identifier("super"))
}
}
else -> errorWithAttachment("Failed to extract type from: ${calleeReference::class.simpleName}") {
withFirEntry("reference", calleeReference)
}
}
}
private fun BodyResolveComponents.typeFromSymbol(symbol: FirBasedSymbol<*>): FirResolvedTypeRef {
return when (symbol) {
is FirSyntheticPropertySymbol -> typeFromSymbol(symbol.getterSymbol!!.delegateFunctionSymbol)
is FirCallableSymbol<*> -> {
val returnTypeRef = returnTypeCalculator.tryCalculateReturnType(symbol.fir)
returnTypeRef.copyWithNewSource(null)
}
is FirClassifierSymbol<*> -> {
buildResolvedTypeRef {
source = null
type = symbol.constructType(emptyArray(), isNullable = false)
}
}
else -> errorWithAttachment("Failed to extract type from symbol: ${symbol::class.java}") {
withFirEntry("declaration", symbol.fir)
}
}
}
fun BodyResolveComponents.transformExpressionUsingSmartcastInfo(expression: FirExpression): FirExpression {
val (stability, typesFromSmartCast) = dataFlowAnalyzer.getTypeUsingSmartcastInfo(expression) ?: return expression
return transformExpressionUsingSmartcastInfo(expression, stability, typesFromSmartCast) ?: expression
}
fun BodyResolveComponents.transformWhenSubjectExpressionUsingSmartcastInfo(
whenSubjectExpression: FirWhenSubjectExpression,
): FirExpression {
val (stability, typesFromSmartCast) = dataFlowAnalyzer.getTypeUsingSmartcastInfo(whenSubjectExpression)
?: return whenSubjectExpression
return transformExpressionUsingSmartcastInfo(whenSubjectExpression, stability, typesFromSmartCast)
?: whenSubjectExpression
}
fun BodyResolveComponents.transformDesugaredAssignmentValueUsingSmartcastInfo(
expression: FirDesugaredAssignmentValueReferenceExpression,
): FirExpression {
val (stability, typesFromSmartCast) =
dataFlowAnalyzer.getTypeUsingSmartcastInfo(expression.expressionRef.value)
?: return expression
return transformExpressionUsingSmartcastInfo(expression, stability, typesFromSmartCast)
?: expression
}
private val ConeKotlinType.isKindOfNothing
get() = lowerBoundIfFlexible().let { it.isNothing || it.isNullableNothing }
private fun FirSmartCastExpressionBuilder.applyResultTypeRef() {
coneTypeOrNull =
if (smartcastStability == SmartcastStability.STABLE_VALUE)
smartcastType.coneTypeOrNull
else
originalExpression.resolvedType
}
private fun BodyResolveComponents.transformExpressionUsingSmartcastInfo(
expression: T,
smartcastStability: SmartcastStability,
typesFromSmartCast: MutableList,
): FirSmartCastExpression? {
val originalType = expression.resolvedType.fullyExpandedType(session)
val allTypes = typesFromSmartCast.also {
if (originalType !is ConeStubType) {
it += originalType.fullyExpandedType(session)
}
}
if (allTypes.all { it is ConeDynamicType }) return null
val intersectedType = ConeTypeIntersector.intersectTypes(session.typeContext, allTypes)
if (intersectedType == originalType && intersectedType !is ConeDynamicType) return null
val intersectedTypeRef = buildResolvedTypeRef {
source = expression.source?.fakeElement(KtFakeSourceElementKind.SmartCastedTypeRef)
type = intersectedType
}
// Example (1): if (x is String) { ... }, where x: dynamic
// the dynamic type will "consume" all other, erasing information.
// Example (2): if (x == null) { ... },
// we need to track the type without `Nothing?` so that resolution with this as receiver can go through properly.
if (
intersectedType.isKindOfNothing &&
!originalType.isNullableNothing &&
!originalType.isNothing &&
originalType !is ConeStubType
) {
val reducedTypes = typesFromSmartCast.filterTo(mutableListOf()) { !it.isKindOfNothing }
val reducedIntersectedType = ConeTypeIntersector.intersectTypes(session.typeContext, reducedTypes)
val reducedIntersectedTypeRef = buildResolvedTypeRef {
source = expression.source?.fakeElement(KtFakeSourceElementKind.SmartCastedTypeRef)
type = reducedIntersectedType
}
return buildSmartCastExpression {
originalExpression = expression
smartcastType = intersectedTypeRef
smartcastTypeWithoutNullableNothing = reducedIntersectedTypeRef
this.typesFromSmartCast = typesFromSmartCast
this.smartcastStability = smartcastStability
applyResultTypeRef()
}
}
return buildSmartCastExpression {
originalExpression = expression
smartcastType = intersectedTypeRef
this.typesFromSmartCast = typesFromSmartCast
this.smartcastStability = smartcastStability
applyResultTypeRef()
}
}
fun FirCheckedSafeCallSubject.propagateTypeFromOriginalReceiver(
nullableReceiverExpression: FirExpression,
session: FirSession,
file: FirFile,
) {
// If the receiver expression is smartcast to `null`, it would have `Nothing?` as its type, which may not have members called by user
// code. Hence, we fallback to the type before intersecting with `Nothing?`.
val receiverType = (nullableReceiverExpression as? FirSmartCastExpression)
?.takeIf { it.isStable }
?.smartcastTypeWithoutNullableNothing
?.coneTypeSafe()
?: nullableReceiverExpression.resolvedType
val expandedReceiverType = receiverType.fullyExpandedType(session).makeConeTypeDefinitelyNotNullOrNotNull(session.typeContext)
replaceConeTypeOrNull(expandedReceiverType)
session.lookupTracker?.recordTypeResolveAsLookup(expandedReceiverType, source, file.source)
}
fun FirSafeCallExpression.propagateTypeFromQualifiedAccessAfterNullCheck(
session: FirSession,
file: FirFile,
) {
val selector = selector
val resultingType = when {
selector is FirExpression && !selector.isStatementLikeExpression -> {
val type = selector.resolvedType
type.withNullability(ConeNullability.NULLABLE, session.typeContext)
}
// Branch for things that shouldn't be used as expressions.
// They are forced to return not-null `Unit`, regardless of the receiver.
else -> {
StandardClassIds.Unit.constructClassLikeType(emptyArray(), isNullable = false)
}
}
replaceConeTypeOrNull(resultingType)
session.lookupTracker?.recordTypeResolveAsLookup(resultingType, source, file.source)
}
fun FirAnnotation.getCorrespondingClassSymbolOrNull(session: FirSession): FirRegularClassSymbol? {
return annotationTypeRef.coneType.fullyExpandedType(session).toRegularClassSymbol(session)
}
fun BodyResolveComponents.initialTypeOfCandidate(candidate: Candidate): ConeKotlinType {
val typeRef = typeFromSymbol(candidate.symbol)
return typeRef.initialTypeOfCandidate(candidate)
}
fun FirResolvedTypeRef.initialTypeOfCandidate(candidate: Candidate): ConeKotlinType {
val system = candidate.system
val resultingSubstitutor = system.buildCurrentSubstitutor()
return resultingSubstitutor.safeSubstitute(system, candidate.substitutor.substituteOrSelf(type)) as ConeKotlinType
}
fun FirCallableDeclaration.getContainingClass(session: FirSession): FirRegularClass? =
this.containingClassLookupTag()?.let { lookupTag ->
session.symbolProvider.getSymbolByLookupTag(lookupTag)?.fir as? FirRegularClass
}
internal fun FirFunction.areNamedArgumentsForbiddenIgnoringOverridden(): Boolean =
forbiddenNamedArgumentsTargetOrNullIgnoringOverridden() != null
private fun FirFunction.forbiddenNamedArgumentsTargetOrNullIgnoringOverridden(): ForbiddenNamedArgumentsTarget? =
forbiddenNamedArgumentsTargetOrNull(originScope = null)
/**
* Returns a non-null value when named arguments are forbidden for calls to this function.
*
* When [originScope] is provided, overrides of the function will be checked.
* If one of the overridden functions allows named arguments, `null` will be returned.
*
* One example of this behavior is a Java function that overrides a Kotlin function.
* In this case, `null` will be returned, if [originScope] is provided.
* Otherwise, [ForbiddenNamedArgumentsTarget.NON_KOTLIN_FUNCTION] will be returned.
*
* To check if a function allows named arguments regardless of its overrides, it is recommended to use
* [FirFunction.areNamedArgumentsForbiddenIgnoringOverridden].
*/
internal fun FirFunction.forbiddenNamedArgumentsTargetOrNull(originScope: FirTypeScope?): ForbiddenNamedArgumentsTarget? {
if (hasStableParameterNames) return null
return when (origin) {
FirDeclarationOrigin.ImportedFromObjectOrStatic ->
importedFromObjectOrStaticData?.original?.forbiddenNamedArgumentsTargetOrNullIgnoringOverridden()
FirDeclarationOrigin.IntersectionOverride, is FirDeclarationOrigin.SubstitutionOverride, FirDeclarationOrigin.Delegated -> {
val initial = unwrapFakeOverridesOrDelegated().forbiddenNamedArgumentsTargetOrNullIgnoringOverridden() ?: return null
initial.takeUnless { symbol.hasOverrideThatAllowsNamedArguments(originScope) }
}
FirDeclarationOrigin.Enhancement -> {
ForbiddenNamedArgumentsTarget.NON_KOTLIN_FUNCTION.takeUnless { symbol.hasOverrideThatAllowsNamedArguments(originScope) }
}
FirDeclarationOrigin.BuiltIns -> ForbiddenNamedArgumentsTarget.INVOKE_ON_FUNCTION_TYPE
is FirDeclarationOrigin.Plugin -> null // TODO: figure out what to do with plugin generated functions
else -> ForbiddenNamedArgumentsTarget.NON_KOTLIN_FUNCTION
}
}
private fun FirFunctionSymbol<*>.hasOverrideThatAllowsNamedArguments(originScope: FirTypeScope?): Boolean {
var result = false
if (this is FirNamedFunctionSymbol) {
originScope?.processOverriddenFunctions(this) {
// If an override allows named arguments, it overrides the initial result.
if (!it.fir.areNamedArgumentsForbiddenIgnoringOverridden()) {
result = true
ProcessorAction.STOP
} else {
ProcessorAction.NEXT
}
}
}
return result
}
@OptIn(ExperimentalContracts::class)
fun FirExpression?.isIntegerLiteralOrOperatorCall(): Boolean {
contract {
returns(true) implies (this@isIntegerLiteralOrOperatorCall != null)
}
return when (this) {
is FirLiteralExpression<*> -> kind == ConstantValueKind.Int
|| kind == ConstantValueKind.IntegerLiteral
|| kind == ConstantValueKind.UnsignedInt
|| kind == ConstantValueKind.UnsignedIntegerLiteral
is FirIntegerLiteralOperatorCall -> true
is FirNamedArgumentExpression -> this.expression.isIntegerLiteralOrOperatorCall()
else -> false
}
}
fun createConeDiagnosticForCandidateWithError(
applicability: CandidateApplicability,
candidate: Candidate,
): ConeDiagnostic {
val symbol = candidate.symbol
return when (applicability) {
CandidateApplicability.HIDDEN -> ConeHiddenCandidateError(candidate)
CandidateApplicability.K2_VISIBILITY_ERROR -> {
val session = candidate.callInfo.session
val declaration = symbol.fir
if (declaration is FirMemberDeclaration &&
session.visibilityChecker.isVisible(declaration, candidate, skipCheckForContainingClassVisibility = true)
) {
// We can have declarations that are visible by themselves, but some containing declaration is invisible.
// We report the nearest invisible containing declaration, otherwise we'll get a confusing diagnostic like
// Cannot access 'foo', it is public in 'Bar'.
declaration
.parentDeclarationSequence(session, candidate.dispatchReceiver, candidate.callInfo.containingDeclarations)
?.firstOrNull {
!session.visibilityChecker.isVisible(
it,
session,
candidate.callInfo.containingFile,
candidate.callInfo.containingDeclarations,
dispatchReceiver = null,
skipCheckForContainingClassVisibility = true,
)
}?.let {
return ConeVisibilityError(it.symbol)
}
}
ConeVisibilityError(symbol)
}
CandidateApplicability.INAPPLICABLE_WRONG_RECEIVER -> ConeInapplicableWrongReceiver(listOf(candidate))
CandidateApplicability.K2_NO_COMPANION_OBJECT -> ConeNoCompanionObject(candidate)
else -> {
if (TypeParameterAsExpression in candidate.diagnostics) {
ConeTypeParameterInQualifiedAccess(symbol as FirTypeParameterSymbol)
} else {
ConeInapplicableCandidateError(applicability, candidate)
}
}
}
}
fun FirNamedReferenceWithCandidate.toErrorReference(diagnostic: ConeDiagnostic): FirNamedReference {
val calleeReference = this
return when (calleeReference.candidateSymbol) {
is FirErrorPropertySymbol, is FirErrorFunctionSymbol -> buildErrorNamedReference {
source = calleeReference.source
this.diagnostic = diagnostic
}
else -> buildResolvedErrorReference {
source = calleeReference.source
name = calleeReference.name
resolvedSymbol = calleeReference.candidateSymbol
this.diagnostic = diagnostic
}
}
}
val FirTypeParameterSymbol.defaultType: ConeTypeParameterType
get() = ConeTypeParameterTypeImpl(toLookupTag(), isNullable = false)
fun ConeClassLikeLookupTag.isRealOwnerOf(declarationSymbol: FirCallableSymbol<*>): Boolean =
this == declarationSymbol.dispatchReceiverClassLookupTagOrNull()