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/*
* Copyright 2010-2024 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.resolve.calls
import org.jetbrains.kotlin.builtins.*
import org.jetbrains.kotlin.config.LanguageFeature
import org.jetbrains.kotlin.config.LanguageVersionSettings
import org.jetbrains.kotlin.descriptors.CallableDescriptor
import org.jetbrains.kotlin.descriptors.FunctionDescriptor
import org.jetbrains.kotlin.descriptors.TypeParameterDescriptor
import org.jetbrains.kotlin.descriptors.ValueParameterDescriptor
import org.jetbrains.kotlin.descriptors.impl.TypeAliasConstructorDescriptor
import org.jetbrains.kotlin.lexer.KtTokens
import org.jetbrains.kotlin.psi.*
import org.jetbrains.kotlin.psi.psiUtil.getBinaryWithTypeParent
import org.jetbrains.kotlin.resolve.BindingContext
import org.jetbrains.kotlin.resolve.FunctionDescriptorUtil
import org.jetbrains.kotlin.resolve.TemporaryBindingTrace
import org.jetbrains.kotlin.resolve.calls.context.CallCandidateResolutionContext
import org.jetbrains.kotlin.resolve.calls.context.ContextDependency.INDEPENDENT
import org.jetbrains.kotlin.resolve.calls.context.ResolutionContext
import org.jetbrains.kotlin.resolve.calls.context.ResolutionResultsCache
import org.jetbrains.kotlin.resolve.calls.context.TemporaryTraceAndCache
import org.jetbrains.kotlin.resolve.calls.inference.*
import org.jetbrains.kotlin.resolve.calls.inference.constraintPosition.ConstraintPosition
import org.jetbrains.kotlin.resolve.calls.inference.constraintPosition.ConstraintPositionKind
import org.jetbrains.kotlin.resolve.calls.inference.constraintPosition.ConstraintPositionKind.RECEIVER_POSITION
import org.jetbrains.kotlin.resolve.calls.inference.constraintPosition.ConstraintPositionKind.VALUE_PARAMETER_POSITION
import org.jetbrains.kotlin.resolve.calls.inference.constraintPosition.ValidityConstraintForConstituentType
import org.jetbrains.kotlin.resolve.calls.model.VariableAsFunctionResolvedCall
import org.jetbrains.kotlin.resolve.calls.results.ResolutionStatus
import org.jetbrains.kotlin.resolve.calls.results.ResolutionStatus.INCOMPLETE_TYPE_INFERENCE
import org.jetbrains.kotlin.resolve.calls.results.ResolutionStatus.OTHER_ERROR
import org.jetbrains.kotlin.resolve.calls.smartcasts.DataFlowValueFactory
import org.jetbrains.kotlin.resolve.calls.util.*
import org.jetbrains.kotlin.resolve.calls.util.ResolveArgumentsMode.RESOLVE_FUNCTION_ARGUMENTS
import org.jetbrains.kotlin.resolve.calls.util.ResolveArgumentsMode.SHAPE_FUNCTION_ARGUMENTS
import org.jetbrains.kotlin.resolve.calls.util.getCall
import org.jetbrains.kotlin.resolve.calls.util.isSafeCall
import org.jetbrains.kotlin.resolve.calls.util.makeNullableTypeIfSafeReceiver
import org.jetbrains.kotlin.resolve.isFunctionForExpectTypeFromCastFeature
import org.jetbrains.kotlin.resolve.scopes.receivers.ExpressionReceiver
import org.jetbrains.kotlin.types.*
import org.jetbrains.kotlin.types.TypeUtils.DONT_CARE
import org.jetbrains.kotlin.types.expressions.ControlStructureTypingUtils.ResolveConstruct
import org.jetbrains.kotlin.types.expressions.ExpressionTypingUtils
import org.jetbrains.kotlin.types.typeUtil.makeNullable
val SPECIAL_FUNCTION_NAMES = ResolveConstruct.entries.map { it.specialFunctionName }.toSet()
class GenericCandidateResolver(
private val argumentTypeResolver: ArgumentTypeResolver,
private val builderInferenceSupport: BuilderInferenceSupport,
private val languageVersionSettings: LanguageVersionSettings,
private val dataFlowValueFactory: DataFlowValueFactory
) {
fun inferTypeArguments(context: CallCandidateResolutionContext): ResolutionStatus {
val candidateCall = context.candidateCall
val candidate = candidateCall.candidateDescriptor
val builder = ConstraintSystemBuilderImpl()
builder.registerTypeVariables(candidateCall.call.toHandle(), candidate.typeParameters)
val substituteDontCare = makeConstantSubstitutor(candidate.typeParameters, DONT_CARE)
// Value parameters
for ((candidateParameter, resolvedValueArgument) in candidateCall.valueArguments) {
val valueParameterDescriptor = candidate.valueParameters[candidateParameter.index]
for (valueArgument in resolvedValueArgument.arguments) {
// TODO : more attempts, with different expected types
// Here we type check expecting an error type (DONT_CARE, substitution with substituteDontCare)
// and throw the results away
// We'll type check the arguments later, with the inferred types expected
addConstraintForValueArgument(
valueArgument, valueParameterDescriptor, substituteDontCare, builder, context, SHAPE_FUNCTION_ARGUMENTS
)
}
}
if (candidate is TypeAliasConstructorDescriptor) {
val substitutedReturnType = builder.compositeSubstitutor().safeSubstitute(candidate.returnType, Variance.INVARIANT)
addValidityConstraintsForConstituentTypes(builder, substitutedReturnType)
}
// Receiver
// Error is already reported if something is missing
val receiverArgument = candidateCall.extensionReceiver
val receiverParameter = candidate.extensionReceiverParameter
if (receiverArgument != null && receiverParameter != null) {
val receiverArgumentType = receiverArgument.type
var receiverType: KotlinType? = if (context.candidateCall.call.isSafeCall())
TypeUtils.makeNotNullable(receiverArgumentType)
else
receiverArgumentType
if (receiverArgument is ExpressionReceiver) {
receiverType = updateResultTypeForSmartCasts(receiverType, receiverArgument.expression, context)
}
builder.addSubtypeConstraint(
receiverType,
builder.compositeSubstitutor().substitute(receiverParameter.type, Variance.INVARIANT),
RECEIVER_POSITION.position()
)
}
val constraintSystem = builder.build()
candidateCall.setConstraintSystem(constraintSystem)
// Solution
val hasContradiction = constraintSystem.status.hasContradiction()
if (!hasContradiction) {
addExpectedTypeForExplicitCast(context, builder)
return INCOMPLETE_TYPE_INFERENCE
}
return OTHER_ERROR
}
private fun ConstraintSystem.Builder.typeInSystem(call: Call, type: KotlinType?): KotlinType? =
type?.let {
typeVariableSubstitutors[call.toHandle()]?.substitute(it, Variance.INVARIANT)
}
private fun addExpectedTypeForExplicitCast(
context: CallCandidateResolutionContext<*>,
builder: ConstraintSystem.Builder
) {
if (!languageVersionSettings.supportsFeature(LanguageFeature.ExpectedTypeFromCast)) return
if (context.candidateCall is VariableAsFunctionResolvedCall) return
val candidateDescriptor = context.candidateCall.candidateDescriptor as? FunctionDescriptor ?: return
val binaryParent = context.call.calleeExpression?.getBinaryWithTypeParent() ?: return
val operationType = binaryParent.operationReference.getReferencedNameElementType().takeIf {
it == KtTokens.AS_KEYWORD || it == KtTokens.AS_SAFE
} ?: return
val leftType = context.trace.get(BindingContext.TYPE, binaryParent.right ?: return) ?: return
val expectedType = if (operationType == KtTokens.AS_SAFE) leftType.makeNullable() else leftType
if (context.candidateCall.call.typeArgumentList != null || !candidateDescriptor.isFunctionForExpectTypeFromCastFeature()) return
val typeInSystem = builder.typeInSystem(context.call, candidateDescriptor.returnType ?: return) ?: return
context.trace.record(BindingContext.CAST_TYPE_USED_AS_EXPECTED_TYPE, binaryParent)
builder.addSubtypeConstraint(typeInSystem, expectedType, ConstraintPositionKind.SPECIAL.position())
}
private fun addValidityConstraintsForConstituentTypes(builder: ConstraintSystem.Builder, type: KotlinType) {
val typeConstructor = type.constructor
if (typeConstructor.declarationDescriptor is TypeParameterDescriptor) return
val boundsSubstitutor = TypeSubstitutor.create(type)
type.arguments.forEachIndexed forEachArgument@ { i, typeProjection ->
if (typeProjection.isStarProjection) return@forEachArgument // continue
val typeParameter = typeConstructor.parameters[i]
addValidityConstraintsForTypeArgument(builder, typeProjection, typeParameter, boundsSubstitutor)
addValidityConstraintsForConstituentTypes(builder, typeProjection.type)
}
}
private fun addValidityConstraintsForTypeArgument(
builder: ConstraintSystem.Builder,
substitutedArgument: TypeProjection,
typeParameter: TypeParameterDescriptor,
boundsSubstitutor: TypeSubstitutor
) {
val substitutedType = substitutedArgument.type
for (upperBound in typeParameter.upperBounds) {
val substitutedUpperBound = boundsSubstitutor.safeSubstitute(upperBound, Variance.INVARIANT).upperIfFlexible()
val constraintPosition = ValidityConstraintForConstituentType(substitutedType, typeParameter, substitutedUpperBound)
// Do not add extra constraints if upper bound is 'Any?';
// otherwise it will be treated incorrectly in nested calls processing.
if (KotlinBuiltIns.isNullableAny(substitutedUpperBound)) continue
builder.addSubtypeConstraint(substitutedType, substitutedUpperBound, constraintPosition)
}
}
// Creates a substitutor which maps types to their representation in the constraint system.
// In case when some type parameter descriptor is represented by more than one variable in the system, the behavior is undefined.
private fun ConstraintSystem.Builder.compositeSubstitutor(): TypeSubstitutor {
return TypeSubstitutor.create(object : TypeSubstitution() {
override fun get(key: KotlinType): TypeProjection? {
return typeVariableSubstitutors.values.reversed().asSequence().mapNotNull { it.substitution.get(key) }.firstOrNull()
}
})
}
private fun addConstraintForValueArgument(
valueArgument: ValueArgument,
valueParameterDescriptor: ValueParameterDescriptor,
substitutor: TypeSubstitutor,
builder: ConstraintSystem.Builder,
context: CallCandidateResolutionContext<*>,
resolveFunctionArgumentBodies: ResolveArgumentsMode
) {
val effectiveExpectedType = getEffectiveExpectedType(valueParameterDescriptor, valueArgument, context)
val argumentExpression = valueArgument.getArgumentExpression()
val expectedType = substitutor.substitute(effectiveExpectedType, Variance.INVARIANT)
val dataFlowInfoForArgument = context.candidateCall.dataFlowInfoForArguments.getInfo(valueArgument)
val newContext = context.replaceExpectedType(expectedType).replaceDataFlowInfo(dataFlowInfoForArgument)
val typeInfoForCall = argumentTypeResolver.getArgumentTypeInfo(
argumentExpression,
newContext,
resolveFunctionArgumentBodies,
expectedType?.isSuspendFunctionType == true
)
context.candidateCall.dataFlowInfoForArguments.updateInfo(valueArgument, typeInfoForCall.dataFlowInfo)
val constraintPosition = VALUE_PARAMETER_POSITION.position(valueParameterDescriptor.index)
if (addConstraintForNestedCall(argumentExpression, constraintPosition, builder, newContext, effectiveExpectedType)) return
val type =
updateResultTypeForSmartCasts(typeInfoForCall.type, argumentExpression, context.replaceDataFlowInfo(dataFlowInfoForArgument))
if (argumentExpression is KtCallableReferenceExpression && type == null) return
builder.addSubtypeConstraint(
type,
builder.compositeSubstitutor().substitute(effectiveExpectedType, Variance.INVARIANT),
constraintPosition
)
}
private fun addConstraintForNestedCall(
argumentExpression: KtExpression?,
constraintPosition: ConstraintPosition,
builder: ConstraintSystem.Builder,
context: CallCandidateResolutionContext<*>,
effectiveExpectedType: KotlinType
): Boolean {
val resolutionResults = getResolutionResultsCachedData(argumentExpression, context)?.resolutionResults
if (resolutionResults == null || !resolutionResults.isSingleResult) return false
val nestedCall = resolutionResults.resultingCall
if (nestedCall.isCompleted) return false
val nestedConstraintSystem = nestedCall.constraintSystem ?: return false
val candidateDescriptor = nestedCall.candidateDescriptor
val returnType = candidateDescriptor.returnType ?: return false
val nestedTypeVariables = nestedConstraintSystem.getNestedTypeVariables(returnType)
// we add an additional type variable only if no information is inferred for it.
// otherwise we add currently inferred return type as before
if (nestedTypeVariables.any { nestedConstraintSystem.getTypeBounds(it).bounds.isNotEmpty() }) return false
val candidateWithFreshVariables = FunctionDescriptorUtil.alphaConvertTypeParameters(candidateDescriptor)
val conversion = candidateDescriptor.typeParameters.zip(candidateWithFreshVariables.typeParameters).toMap()
val freshVariables = returnType.getNestedTypeParameters().mapNotNull { conversion[it] }
builder.registerTypeVariables(nestedCall.call.toHandle(), freshVariables, external = true)
// Safe call result must be nullable if receiver is nullable
val argumentExpressionType = nestedCall.makeNullableTypeIfSafeReceiver(candidateWithFreshVariables.returnType, context)
builder.addSubtypeConstraint(
argumentExpressionType,
builder.compositeSubstitutor().substitute(effectiveExpectedType, Variance.INVARIANT),
constraintPosition
)
return true
}
private fun updateResultTypeForSmartCasts(
type: KotlinType?,
argumentExpression: KtExpression?,
context: ResolutionContext<*>
): KotlinType? {
val deparenthesizedArgument = KtPsiUtil.getLastElementDeparenthesized(argumentExpression, context.statementFilter)
if (deparenthesizedArgument == null || type == null) return type
val dataFlowValue = dataFlowValueFactory.createDataFlowValue(deparenthesizedArgument, type, context)
if (!dataFlowValue.isStable) return type
val possibleTypes = context.dataFlowInfo.getCollectedTypes(dataFlowValue, context.languageVersionSettings)
if (possibleTypes.isEmpty()) return type
return TypeIntersector.intersectTypes(possibleTypes + type)
}
fun completeTypeInferenceDependentOnFunctionArgumentsForCall(context: CallCandidateResolutionContext) {
val resolvedCall = context.candidateCall
val constraintSystem = resolvedCall.constraintSystem?.toBuilder() ?: return
// `resolvedCall` can contain wrapped call (e.g. CallForImplicitInvoke). Meanwhile, `context` contains simple call which leads
// to inconsistency and errors in inference. See definition of `effectiveExpectedTypeInSystem` in `addConstraintForFunctionLiteralArgument`
val newContext = if (resolvedCall is VariableAsFunctionResolvedCall) {
CallCandidateResolutionContext.create(
resolvedCall, context, context.trace, context.tracing, resolvedCall.functionCall.call, context.candidateResolveMode
)
} else {
context
}
// constraints for function literals
// Value parameters
for ((valueParameterDescriptor, resolvedValueArgument) in resolvedCall.valueArguments) {
for (valueArgument in resolvedValueArgument.arguments) {
valueArgument.getArgumentExpression()?.let { argumentExpression ->
ArgumentTypeResolver.getFunctionLiteralArgumentIfAny(argumentExpression, newContext)?.let { functionLiteral ->
addConstraintForFunctionLiteralArgument(
functionLiteral, valueArgument, valueParameterDescriptor, constraintSystem, newContext,
resolvedCall.candidateDescriptor.returnType
)
}
// as inference for callable references depends on expected type,
// we should postpone reporting errors on them until all types will be inferred
// We do not replace trace for special calls (e.g. if-expressions) because of their specific analysis
// For example, type info for arguments is needed before call will be completed (See ControlStructureTypingVisitor.visitIfExpression)
val temporaryContextForCall = if (resolvedCall.candidateDescriptor.name in SPECIAL_FUNCTION_NAMES) {
newContext
} else {
val temporaryBindingTrace = TemporaryBindingTrace.create(
newContext.trace, "Trace to complete argument for call that might be not resulting call"
)
newContext.replaceBindingTrace(temporaryBindingTrace)
}
ArgumentTypeResolver.getCallableReferenceExpressionIfAny(argumentExpression, newContext)?.let { callableReference ->
addConstraintForCallableReference(
callableReference,
valueArgument,
valueParameterDescriptor,
constraintSystem,
temporaryContextForCall
)
}
}
}
}
val resultingSystem = constraintSystem.build()
resolvedCall.setConstraintSystem(resultingSystem)
val isNewInferenceEnabled = languageVersionSettings.supportsFeature(LanguageFeature.NewInference)
val resultingSubstitutor = if (isNewInferenceEnabled) {
resultingSystem.resultingSubstitutor.replaceWithContravariantApproximatingSubstitution()
} else resultingSystem.resultingSubstitutor
resolvedCall.setSubstitutor(resultingSubstitutor)
}
// See KT-5385
// When literal returns T, and it's an argument of a function that also returns T,
// and we have some expected type Type, we can expected from literal to return Type
// Otherwise we do not care about literal's exact return type
private fun estimateLiteralReturnType(
context: CallCandidateResolutionContext<*>,
literalExpectedType: KotlinType,
ownerReturnType: KotlinType?
) = if (!TypeUtils.noExpectedType(context.expectedType) &&
ownerReturnType != null &&
TypeUtils.isTypeParameter(ownerReturnType) &&
literalExpectedType.isFunctionTypeOrSubtype &&
getReturnTypeForCallable(literalExpectedType) == ownerReturnType)
context.expectedType
else DONT_CARE
private fun addConstraintForFunctionLiteralArgument(
functionLiteral: KtFunction,
valueArgument: ValueArgument,
valueParameterDescriptor: ValueParameterDescriptor,
constraintSystem: ConstraintSystem.Builder,
context: CallCandidateResolutionContext,
argumentOwnerReturnType: KotlinType?
) {
val argumentExpression = valueArgument.getArgumentExpression() ?: return
val effectiveExpectedType = getEffectiveExpectedType(valueParameterDescriptor, valueArgument, context)
if (isBuilderInferenceCall(valueParameterDescriptor, valueArgument, languageVersionSettings)) {
builderInferenceSupport.analyzeBuilderInferenceCall(functionLiteral, valueArgument, constraintSystem, context, effectiveExpectedType)
}
val currentSubstitutor = constraintSystem.build().currentSubstitutor
val newSubstitution = object : DelegatedTypeSubstitution(currentSubstitutor.substitution) {
override fun approximateContravariantCapturedTypes() = true
}
var expectedType = newSubstitution.buildSubstitutor().substitute(effectiveExpectedType, Variance.IN_VARIANCE)
if (expectedType == null || TypeUtils.isDontCarePlaceholder(expectedType)) {
expectedType = argumentTypeResolver.getShapeTypeOfFunctionLiteral(
functionLiteral,
context.scope,
context.trace,
false,
expectedType?.isSuspendFunctionType == true
)
}
if (expectedType == null || !expectedType.isBuiltinFunctionalType || hasUnknownFunctionParameter(expectedType)) {
return
}
val dataFlowInfoForArguments = context.candidateCall.dataFlowInfoForArguments
val dataFlowInfoForArgument = dataFlowInfoForArguments.getInfo(valueArgument)
val effectiveExpectedTypeInSystem =
constraintSystem.typeVariableSubstitutors[context.call.toHandle()]?.substitute(effectiveExpectedType, Variance.INVARIANT)
//todo analyze function literal body once in 'dependent' mode, then complete it with respect to expected type
val hasExpectedReturnType = !hasUnknownReturnType(expectedType)
val position = VALUE_PARAMETER_POSITION.position(valueParameterDescriptor.index)
if (hasExpectedReturnType) {
val temporaryToResolveFunctionLiteral = TemporaryTraceAndCache.create(
context, "trace to resolve function literal with expected return type", argumentExpression
)
val statementExpression = KtPsiUtil.getExpressionOrLastStatementInBlock(functionLiteral.bodyExpression) ?: return
val mismatch = BooleanArray(1)
val errorInterceptingTrace = ExpressionTypingUtils.makeTraceInterceptingTypeMismatch(
temporaryToResolveFunctionLiteral.trace, statementExpression, mismatch
)
val newContext = context.replaceBindingTrace(errorInterceptingTrace).replaceExpectedType(expectedType)
.replaceDataFlowInfo(dataFlowInfoForArgument).replaceResolutionResultsCache(temporaryToResolveFunctionLiteral.cache)
.replaceContextDependency(INDEPENDENT)
val type = argumentTypeResolver.getFunctionLiteralTypeInfo(
argumentExpression, functionLiteral, newContext, RESOLVE_FUNCTION_ARGUMENTS,
expectedType.isSuspendFunctionType
).type
if (!mismatch[0]) {
constraintSystem.addSubtypeConstraint(type, effectiveExpectedTypeInSystem, position)
temporaryToResolveFunctionLiteral.commit()
return
}
}
val estimatedReturnType = estimateLiteralReturnType(context, effectiveExpectedType, argumentOwnerReturnType)
val expectedTypeWithEstimatedReturnType = replaceReturnTypeForCallable(expectedType, estimatedReturnType)
val newContext = context.replaceExpectedType(expectedTypeWithEstimatedReturnType).replaceDataFlowInfo(dataFlowInfoForArgument)
.replaceContextDependency(INDEPENDENT)
val type =
argumentTypeResolver.getFunctionLiteralTypeInfo(
argumentExpression, functionLiteral, newContext, RESOLVE_FUNCTION_ARGUMENTS,
expectedType.isSuspendFunctionType
).type
constraintSystem.addSubtypeConstraint(type, effectiveExpectedTypeInSystem, position)
}
private fun addConstraintForCallableReference(
callableReference: KtCallableReferenceExpression,
valueArgument: ValueArgument,
valueParameterDescriptor: ValueParameterDescriptor,
constraintSystem: ConstraintSystem.Builder,
context: CallCandidateResolutionContext
) {
val effectiveExpectedType = getEffectiveExpectedType(valueParameterDescriptor, valueArgument, context)
val expectedType = getExpectedTypeForCallableReference(callableReference, constraintSystem, context, effectiveExpectedType)
?: return
if (!expectedType.isApplicableExpectedTypeForCallableReference()) return
val resolvedType = getResolvedTypeForCallableReference(callableReference, context, expectedType, valueArgument) ?: return
val position = VALUE_PARAMETER_POSITION.position(valueParameterDescriptor.index)
constraintSystem.addSubtypeConstraint(
resolvedType,
constraintSystem.typeVariableSubstitutors[context.call.toHandle()]?.substitute(effectiveExpectedType, Variance.INVARIANT),
position
)
}
private fun getExpectedTypeForCallableReference(
callableReference: KtCallableReferenceExpression,
constraintSystem: ConstraintSystem.Builder,
context: CallCandidateResolutionContext,
effectiveExpectedType: KotlinType
): KotlinType? {
val substitutedType = constraintSystem.build().currentSubstitutor.substitute(effectiveExpectedType, Variance.INVARIANT)
if (substitutedType != null && !TypeUtils.isDontCarePlaceholder(substitutedType))
return substitutedType
val shapeType = argumentTypeResolver.getShapeTypeOfCallableReference(callableReference, context, false)
if (shapeType != null && shapeType.isFunctionTypeOrSubtype && !hasUnknownFunctionParameter(shapeType))
return shapeType
return null
}
private fun getResolvedTypeForCallableReference(
callableReference: KtCallableReferenceExpression,
context: CallCandidateResolutionContext,
expectedType: KotlinType,
valueArgument: ValueArgument
): KotlinType? {
val dataFlowInfoForArgument = context.candidateCall.dataFlowInfoForArguments.getInfo(valueArgument)
val expectedTypeWithoutReturnType =
if (!hasUnknownReturnType(expectedType)) replaceReturnTypeByUnknown(expectedType) else expectedType
val newContext = context
.replaceExpectedType(expectedTypeWithoutReturnType)
.replaceDataFlowInfo(dataFlowInfoForArgument)
.replaceContextDependency(INDEPENDENT)
return argumentTypeResolver.getCallableReferenceTypeInfo(
callableReference, callableReference, newContext, RESOLVE_FUNCTION_ARGUMENTS
).type
}
}
fun getResolutionResultsCachedData(expression: KtExpression?, context: ResolutionContext<*>): ResolutionResultsCache.CachedData? {
if (!ExpressionTypingUtils.dependsOnExpectedType(expression)) return null
val argumentCall = expression?.getCall(context.trace.bindingContext) ?: return null
return context.resolutionResultsCache[argumentCall]
}
fun makeConstantSubstitutor(typeParameterDescriptors: Collection, type: KotlinType): TypeSubstitutor {
val constructors = typeParameterDescriptors.map { it.typeConstructor }.toSet()
val projection = TypeProjectionImpl(type)
return TypeSubstitutor.create(object : TypeConstructorSubstitution() {
override operator fun get(key: TypeConstructor) =
if (key in constructors) projection else null
override fun isEmpty() = false
})
}
private fun KotlinType.isApplicableExpectedTypeForCallableReference(): Boolean {
return this.isFunctionType ||
ReflectionTypes.isBaseTypeForNumberedReferenceTypes(this) ||
ReflectionTypes.isNumberedKFunctionOrKSuspendFunction(this) ||
ReflectionTypes.isNumberedKPropertyOrKMutablePropertyType(this)
}