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org.jetbrains.kotlin.codegen.ClosureCodegen Maven / Gradle / Ivy
/*
* Copyright 2010-2018 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.codegen;
import com.google.common.collect.Lists;
import com.intellij.util.ArrayUtil;
import kotlin.Pair;
import kotlin.Unit;
import kotlin.collections.CollectionsKt;
import org.jetbrains.annotations.NotNull;
import org.jetbrains.annotations.Nullable;
import org.jetbrains.kotlin.builtins.KotlinBuiltIns;
import org.jetbrains.kotlin.codegen.binding.CalculatedClosure;
import org.jetbrains.kotlin.codegen.context.ClosureContext;
import org.jetbrains.kotlin.codegen.context.EnclosedValueDescriptor;
import org.jetbrains.kotlin.codegen.coroutines.CoroutineCodegenUtilKt;
import org.jetbrains.kotlin.codegen.serialization.JvmSerializerExtension;
import org.jetbrains.kotlin.codegen.signature.BothSignatureWriter;
import org.jetbrains.kotlin.codegen.signature.JvmSignatureWriter;
import org.jetbrains.kotlin.codegen.state.GenerationState;
import org.jetbrains.kotlin.codegen.state.KotlinTypeMapper;
import org.jetbrains.kotlin.config.LanguageVersionSettings;
import org.jetbrains.kotlin.descriptors.*;
import org.jetbrains.kotlin.descriptors.impl.SimpleFunctionDescriptorImpl;
import org.jetbrains.kotlin.incremental.components.NoLookupLocation;
import org.jetbrains.kotlin.load.java.JvmAbi;
import org.jetbrains.kotlin.load.kotlin.header.KotlinClassHeader;
import org.jetbrains.kotlin.metadata.ProtoBuf;
import org.jetbrains.kotlin.psi.KtElement;
import org.jetbrains.kotlin.resolve.DescriptorUtils;
import org.jetbrains.kotlin.resolve.InlineClassesUtilsKt;
import org.jetbrains.kotlin.resolve.calls.model.ResolvedCall;
import org.jetbrains.kotlin.resolve.descriptorUtil.DescriptorUtilsKt;
import org.jetbrains.kotlin.resolve.jvm.diagnostics.JvmDeclarationOriginKt;
import org.jetbrains.kotlin.resolve.scopes.MemberScope;
import org.jetbrains.kotlin.resolve.scopes.receivers.TransientReceiver;
import org.jetbrains.kotlin.serialization.DescriptorSerializer;
import org.jetbrains.kotlin.types.KotlinType;
import org.jetbrains.kotlin.types.SimpleType;
import org.jetbrains.kotlin.types.expressions.ExpressionTypingUtils;
import org.jetbrains.kotlin.util.OperatorNameConventions;
import org.jetbrains.org.objectweb.asm.MethodVisitor;
import org.jetbrains.org.objectweb.asm.Type;
import org.jetbrains.org.objectweb.asm.commons.InstructionAdapter;
import org.jetbrains.org.objectweb.asm.commons.Method;
import java.util.ArrayList;
import java.util.Collections;
import java.util.List;
import static org.jetbrains.kotlin.codegen.AsmUtil.CAPTURED_THIS_FIELD;
import static org.jetbrains.kotlin.codegen.CallableReferenceUtilKt.*;
import static org.jetbrains.kotlin.codegen.DescriptorAsmUtil.*;
import static org.jetbrains.kotlin.codegen.JvmCodegenUtil.isConst;
import static org.jetbrains.kotlin.codegen.binding.CodegenBinding.CLOSURE;
import static org.jetbrains.kotlin.codegen.serialization.JvmSerializationBindings.METHOD_FOR_FUNCTION;
import static org.jetbrains.kotlin.resolve.jvm.AsmTypes.*;
import static org.jetbrains.kotlin.resolve.jvm.diagnostics.JvmDeclarationOrigin.NO_ORIGIN;
import static org.jetbrains.org.objectweb.asm.Opcodes.*;
public class ClosureCodegen extends MemberCodegen {
protected final FunctionDescriptor funDescriptor;
private final ClassDescriptor classDescriptor;
private final SamType samType;
private final KotlinType superClassType;
private final List superInterfaceTypes;
private final ResolvedCall functionReferenceCall;
private final FunctionDescriptor functionReferenceTarget;
private final FunctionGenerationStrategy strategy;
protected final CalculatedClosure closure;
protected final Type asmType;
protected final int visibilityFlag;
private final boolean shouldHaveBoundReferenceReceiver;
private final boolean isLegacyFunctionReference;
private final boolean isOptimizedFunctionReference;
private final boolean isAdaptedFunctionReference;
private Method constructor;
protected Type superClassAsmType;
public ClosureCodegen(
@NotNull GenerationState state,
@NotNull KtElement element,
@Nullable SamType samType,
@NotNull ClosureContext context,
@Nullable ResolvedCall functionReferenceCall,
@NotNull FunctionGenerationStrategy strategy,
@NotNull MemberCodegen parentCodegen,
@NotNull ClassBuilder classBuilder
) {
super(state, parentCodegen, context, element, classBuilder);
this.funDescriptor = context.getFunctionDescriptor();
this.classDescriptor = context.getContextDescriptor();
this.samType = samType;
this.functionReferenceCall = functionReferenceCall;
this.functionReferenceTarget = functionReferenceCall != null ? functionReferenceCall.getResultingDescriptor() : null;
this.strategy = strategy;
if (samType == null) {
this.superInterfaceTypes = new ArrayList<>();
KotlinType superClassType = null;
for (KotlinType supertype : classDescriptor.getTypeConstructor().getSupertypes()) {
ClassifierDescriptor classifier = supertype.getConstructor().getDeclarationDescriptor();
if (DescriptorUtils.isInterface(classifier)) {
superInterfaceTypes.add(supertype);
}
else {
assert superClassType == null : "Closure class can't have more than one superclass: " + funDescriptor;
superClassType = supertype;
}
}
assert superClassType != null : "Closure class should have a superclass: " + funDescriptor;
this.superClassType = superClassType;
}
else {
this.superInterfaceTypes = Collections.singletonList(samType.getType());
this.superClassType = DescriptorUtilsKt.getBuiltIns(funDescriptor).getAnyType();
}
this.closure = bindingContext.get(CLOSURE, classDescriptor);
assert closure != null : "Closure must be calculated for class: " + classDescriptor;
this.shouldHaveBoundReferenceReceiver = CallableReferenceUtilKt.isForBoundCallableReference(closure);
ClassifierDescriptor superClassDescriptor = superClassType.getConstructor().getDeclarationDescriptor();
this.isLegacyFunctionReference =
functionReferenceTarget != null &&
superClassDescriptor == state.getJvmRuntimeTypes().getFunctionReference();
this.isOptimizedFunctionReference =
functionReferenceTarget != null &&
superClassDescriptor == state.getJvmRuntimeTypes().getFunctionReferenceImpl();
this.isAdaptedFunctionReference =
functionReferenceTarget != null &&
superClassDescriptor == state.getJvmRuntimeTypes().getAdaptedFunctionReference();
this.asmType = typeMapper.mapClass(classDescriptor);
visibilityFlag = DescriptorAsmUtil.getVisibilityAccessFlagForClass(classDescriptor);
}
@Override
protected void generateDeclaration() {
JvmSignatureWriter sw = new BothSignatureWriter(BothSignatureWriter.Mode.CLASS);
if (samType != null) {
typeMapper.writeFormalTypeParameters(samType.getType().getConstructor().getParameters(), sw);
}
sw.writeSuperclass();
superClassAsmType = typeMapper.mapSupertype(superClassType, sw);
sw.writeSuperclassEnd();
String[] superInterfaceAsmTypes = new String[superInterfaceTypes.size()];
for (int i = 0; i < superInterfaceTypes.size(); i++) {
KotlinType superInterfaceType = superInterfaceTypes.get(i);
sw.writeInterface();
superInterfaceAsmTypes[i] = typeMapper.mapSupertype(superInterfaceType, sw).getInternalName();
sw.writeInterfaceEnd();
}
v.defineClass(
element,
state.getClassFileVersion(),
ACC_FINAL | ACC_SUPER | visibilityFlag | getSyntheticAccessFlagForLambdaClass(classDescriptor),
asmType.getInternalName(),
sw.makeJavaGenericSignature(),
superClassAsmType.getInternalName(),
superInterfaceAsmTypes
);
initDefaultSourceMappingIfNeeded();
v.visitSource(element.getContainingFile().getName(), null);
}
@Nullable
@Override
protected ClassDescriptor classForInnerClassRecord() {
return JvmCodegenUtil.isArgumentWhichWillBeInlined(bindingContext, funDescriptor) ? null : classDescriptor;
}
@Override
protected void generateBody() {
generateBridges();
generateClosureBody();
if (samType != null) {
SamWrapperCodegen.generateDelegatesToDefaultImpl(
asmType, classDescriptor, samType.getClassDescriptor(), functionCodegen, state
);
}
this.constructor = generateConstructor();
if (isConst(closure)) {
generateConstInstance(asmType, asmType);
}
genClosureFields(closure, v, typeMapper, state.getLanguageVersionSettings());
}
protected void generateClosureBody() {
functionCodegen.generateMethod(JvmDeclarationOriginKt.OtherOrigin(element, funDescriptor), funDescriptor, strategy);
if (isLegacyFunctionReference) {
generateFunctionReferenceMethods(functionReferenceTarget);
}
functionCodegen.generateDefaultIfNeeded(
context.intoFunction(funDescriptor), funDescriptor, context.getContextKind(), DefaultParameterValueLoader.DEFAULT, null
);
}
protected void generateBridges() {
FunctionDescriptor erasedInterfaceFunction;
if (samType == null) {
erasedInterfaceFunction = getErasedInvokeFunction(funDescriptor);
}
else {
erasedInterfaceFunction = samType.getOriginalAbstractMethod();
}
List bridgeParameterKotlinTypes = CollectionsKt.map(erasedInterfaceFunction.getValueParameters(), ValueDescriptor::getType);
generateBridge(
typeMapper.mapAsmMethod(erasedInterfaceFunction),
bridgeParameterKotlinTypes,
erasedInterfaceFunction.getReturnType(),
typeMapper.mapAsmMethod(funDescriptor),
funDescriptor.getReturnType(),
JvmCodegenUtil.isDeclarationOfBigArityFunctionInvoke(erasedInterfaceFunction)
);
//TODO: rewrite cause ugly hack
if (samType != null) {
generateBridgesForSAM(erasedInterfaceFunction, funDescriptor, functionCodegen);
}
}
static void generateBridgesForSAM(
FunctionDescriptor erasedInterfaceFunction,
FunctionDescriptor descriptor,
FunctionCodegen codegen
) {
SimpleFunctionDescriptorImpl descriptorForBridges = SimpleFunctionDescriptorImpl
.create(descriptor.getContainingDeclaration(), descriptor.getAnnotations(),
erasedInterfaceFunction.getName(),
CallableMemberDescriptor.Kind.DECLARATION, descriptor.getSource());
descriptorForBridges
.initialize(erasedInterfaceFunction.getExtensionReceiverParameter(), erasedInterfaceFunction.getDispatchReceiverParameter(),
erasedInterfaceFunction.getTypeParameters(), erasedInterfaceFunction.getValueParameters(),
erasedInterfaceFunction.getReturnType(), Modality.OPEN, erasedInterfaceFunction.getVisibility());
descriptorForBridges.setSuspend(descriptor.isSuspend());
DescriptorUtilsKt.setSingleOverridden(descriptorForBridges, erasedInterfaceFunction);
codegen.generateBridges(descriptorForBridges);
}
@Override
protected void generateKotlinMetadataAnnotation() {
FunctionDescriptor frontendFunDescriptor = CodegenUtilKt.unwrapFrontendVersion(funDescriptor);
Method method = v.getSerializationBindings().get(METHOD_FOR_FUNCTION, frontendFunDescriptor);
assert method != null : "No method for " + frontendFunDescriptor;
FunctionDescriptor freeLambdaDescriptor = FakeDescriptorsForReferencesKt.createFreeFakeLambdaDescriptor(
frontendFunDescriptor, state.getTypeApproximator()
);
v.getSerializationBindings().put(METHOD_FOR_FUNCTION, freeLambdaDescriptor, method);
DescriptorSerializer serializer =
DescriptorSerializer.createForLambda(new JvmSerializerExtension(v.getSerializationBindings(), state));
ProtoBuf.Function.Builder builder = serializer.functionProto(freeLambdaDescriptor);
if (builder == null) return;
ProtoBuf.Function functionProto = builder.build();
WriteAnnotationUtilKt.writeKotlinMetadata(v, state, KotlinClassHeader.Kind.SYNTHETIC_CLASS, 0, av -> {
writeAnnotationData(av, serializer, functionProto);
return Unit.INSTANCE;
});
}
@Override
protected void done() {
writeOuterClassAndEnclosingMethod();
super.done();
}
@NotNull
public StackValue putInstanceOnStack(@NotNull ExpressionCodegen codegen, @Nullable StackValue functionReferenceReceiver) {
return StackValue.operation(
functionReferenceTarget != null ? K_FUNCTION : asmType,
v -> {
if (isConst(closure)) {
v.getstatic(asmType.getInternalName(), JvmAbi.INSTANCE_FIELD, asmType.getDescriptor());
}
else {
v.anew(asmType);
v.dup();
codegen.pushClosureOnStack(classDescriptor, true, codegen.defaultCallGenerator, functionReferenceReceiver);
v.invokespecial(asmType.getInternalName(), "", constructor.getDescriptor(), false);
}
return Unit.INSTANCE;
}
);
}
private void generateBridge(
@NotNull Method bridge,
@NotNull List bridgeParameterKotlinTypes,
@Nullable KotlinType bridgeReturnType,
@NotNull Method delegate,
@Nullable KotlinType delegateReturnType,
boolean isVarargInvoke
) {
if (bridge.equals(delegate)) return;
MethodVisitor mv =
v.newMethod(JvmDeclarationOriginKt.OtherOrigin(element, funDescriptor), ACC_PUBLIC | ACC_BRIDGE | ACC_SYNTHETIC,
bridge.getName(), bridge.getDescriptor(), null, ArrayUtil.EMPTY_STRING_ARRAY);
if (!state.getClassBuilderMode().generateBodies) return;
mv.visitCode();
InstructionAdapter iv = new InstructionAdapter(mv);
MemberCodegen.markLineNumberForDescriptor(DescriptorUtils.getParentOfType(funDescriptor, ClassDescriptor.class), iv);
Type[] bridgeParameterTypes = bridge.getArgumentTypes();
if (isVarargInvoke) {
assert bridgeParameterTypes.length == 1 && bridgeParameterTypes[0].equals(AsmUtil.getArrayType(OBJECT_TYPE)) :
"Vararg invoke must have one parameter of type [Ljava/lang/Object;: " + bridge;
generateVarargInvokeArityAssert(iv, delegate.getArgumentTypes().length);
}
else {
assert bridgeParameterTypes.length == bridgeParameterKotlinTypes.size() :
"Asm parameter types should be the same length as Kotlin parameter types";
}
iv.load(0, asmType);
List calleeParameters = CollectionsKt.plus(
CollectionsKt.listOfNotNull(funDescriptor.getExtensionReceiverParameter()),
funDescriptor.getValueParameters()
);
int slot = 1;
for (int i = 0; i < calleeParameters.size(); i++) {
ParameterDescriptor calleeParameter = calleeParameters.get(i);
KotlinType parameterType = calleeParameter.getType();
StackValue value;
if (isVarargInvoke) {
value = StackValue.arrayElement(
OBJECT_TYPE, null,
StackValue.local(1, bridgeParameterTypes[0], bridgeParameterKotlinTypes.get(0)),
StackValue.constant(i)
);
}
else {
Type type = bridgeParameterTypes[i];
value = StackValue.local(slot, type, bridgeParameterKotlinTypes.get(i));
slot += type.getSize();
}
if (InlineClassesCodegenUtilKt.isInlineClassWithUnderlyingTypeAnyOrAnyN(parameterType) &&
functionReferenceCall == null
) {
parameterType = InlineClassesUtilsKt.unsubstitutedUnderlyingParameter(parameterType).getType();
}
value.put(typeMapper.mapType(calleeParameter), parameterType, iv);
}
iv.invokevirtual(asmType.getInternalName(), delegate.getName(), delegate.getDescriptor(), false);
StackValue
.onStack(delegate.getReturnType(), delegateReturnType)
.put(bridge.getReturnType(), bridgeReturnType, iv);
iv.areturn(bridge.getReturnType());
FunctionCodegen.endVisit(mv, "bridge", element);
}
// TODO: ImplementationBodyCodegen.markLineNumberForSyntheticFunction?
private void generateFunctionReferenceMethods(@NotNull FunctionDescriptor descriptor) {
int flags = ACC_PUBLIC | ACC_FINAL;
boolean generateBody = state.getClassBuilderMode().generateBodies;
{
MethodVisitor mv =
v.newMethod(NO_ORIGIN, flags, "getOwner", Type.getMethodDescriptor(K_DECLARATION_CONTAINER_TYPE), null, null);
if (generateBody) {
mv.visitCode();
InstructionAdapter iv = new InstructionAdapter(mv);
generateCallableReferenceDeclarationContainer(iv, descriptor, state);
iv.areturn(K_DECLARATION_CONTAINER_TYPE);
FunctionCodegen.endVisit(iv, "function reference getOwner", element);
}
}
{
MethodVisitor mv =
v.newMethod(NO_ORIGIN, flags, "getName", Type.getMethodDescriptor(JAVA_STRING_TYPE), null, null);
if (generateBody) {
mv.visitCode();
InstructionAdapter iv = new InstructionAdapter(mv);
iv.aconst(descriptor.getName().asString());
iv.areturn(JAVA_STRING_TYPE);
FunctionCodegen.endVisit(iv, "function reference getName", element);
}
}
{
MethodVisitor mv = v.newMethod(NO_ORIGIN, flags, "getSignature", Type.getMethodDescriptor(JAVA_STRING_TYPE), null, null);
if (generateBody) {
mv.visitCode();
InstructionAdapter iv = new InstructionAdapter(mv);
CallableReferenceUtilKt.generateFunctionReferenceSignature(iv, descriptor, state);
iv.areturn(JAVA_STRING_TYPE);
FunctionCodegen.endVisit(iv, "function reference getSignature", element);
}
}
}
@NotNull
protected Method generateConstructor() {
List args = calculateConstructorParameters(typeMapper, state.getLanguageVersionSettings(), closure, asmType);
Type[] argTypes = fieldListToTypeArray(args);
Method constructor = new Method("", Type.VOID_TYPE, argTypes);
MethodVisitor mv = v.newMethod(JvmDeclarationOriginKt.OtherOrigin(element, funDescriptor), visibilityFlag, "", constructor.getDescriptor(), null,
ArrayUtil.EMPTY_STRING_ARRAY);
if (state.getClassBuilderMode().generateBodies) {
mv.visitCode();
InstructionAdapter iv = new InstructionAdapter(mv);
Pair receiverIndexAndFieldInfo =
CallableReferenceUtilKt.generateClosureFieldsInitializationFromParameters(iv, closure, args);
if (shouldHaveBoundReferenceReceiver && receiverIndexAndFieldInfo == null) {
throw new AssertionError("No bound reference receiver in constructor parameters: " + args);
}
int boundReceiverParameterIndex;
Type boundReceiverType;
KotlinType boundReceiverKotlinType;
if (shouldHaveBoundReferenceReceiver) {
boundReceiverParameterIndex = receiverIndexAndFieldInfo.getFirst();
boundReceiverType = receiverIndexAndFieldInfo.getSecond().getFieldType();
boundReceiverKotlinType = receiverIndexAndFieldInfo.getSecond().getFieldKotlinType();
}
else {
boundReceiverParameterIndex = -1;
boundReceiverType = null;
boundReceiverKotlinType = null;
}
iv.load(0, superClassAsmType);
List superCtorArgTypes = new ArrayList<>();
if (superClassAsmType.equals(LAMBDA) || functionReferenceTarget != null ||
CoroutineCodegenUtilKt.isCoroutineSuperClass(state.getLanguageVersionSettings(), superClassAsmType.getInternalName())
) {
iv.iconst(CodegenUtilKt.getArity(funDescriptor));
superCtorArgTypes.add(Type.INT_TYPE);
if (shouldHaveBoundReferenceReceiver) {
CallableReferenceUtilKt.loadBoundReferenceReceiverParameter(
iv, boundReceiverParameterIndex, boundReceiverType, boundReceiverKotlinType
);
superCtorArgTypes.add(OBJECT_TYPE);
}
if (isOptimizedFunctionReference || isAdaptedFunctionReference) {
assert functionReferenceTarget != null : "No function reference target: " + funDescriptor;
generateCallableReferenceDeclarationContainerClass(iv, functionReferenceTarget, state);
iv.aconst(functionReferenceTarget.getName().asString());
CallableReferenceUtilKt.generateFunctionReferenceSignature(iv, functionReferenceTarget, state);
int flags =
getCallableReferenceTopLevelFlag(functionReferenceTarget) +
(calculateFunctionReferenceFlags(functionReferenceCall, funDescriptor) << 1);
iv.aconst(flags);
superCtorArgTypes.add(JAVA_CLASS_TYPE);
superCtorArgTypes.add(JAVA_STRING_TYPE);
superCtorArgTypes.add(JAVA_STRING_TYPE);
superCtorArgTypes.add(Type.INT_TYPE);
}
}
else {
assert !shouldHaveBoundReferenceReceiver : "Unexpected bound reference with supertype " + superClassAsmType;
}
iv.invokespecial(
superClassAsmType.getInternalName(), "",
Type.getMethodDescriptor(Type.VOID_TYPE, superCtorArgTypes.toArray(new Type[0])), false
);
iv.visitInsn(RETURN);
FunctionCodegen.endVisit(iv, "constructor", element);
}
return constructor;
}
private static int calculateFunctionReferenceFlags(
@NotNull ResolvedCall call,
@NotNull FunctionDescriptor anonymousAdapterFunction
) {
boolean hasVarargMappedToElement = false;
FunctionDescriptor target = (FunctionDescriptor) call.getResultingDescriptor();
int shift =
(call.getDispatchReceiver() instanceof TransientReceiver ? 1 : 0) +
(call.getExtensionReceiver() instanceof TransientReceiver ? 1 : 0);
for (int i = shift;
i < anonymousAdapterFunction.getValueParameters().size() && i - shift < target.getValueParameters().size();
i++) {
ValueParameterDescriptor targetParameter = target.getValueParameters().get(i - shift);
ValueParameterDescriptor adaptedParameter = anonymousAdapterFunction.getValueParameters().get(i);
// Vararg to element conversion is happening if the target parameter is vararg (e.g. `vararg xs: Int`),
// but the adapted parameter's type is not equal to the target parameter's type (which is `IntArray`).
if (targetParameter.getVarargElementType() != null &&
!targetParameter.getType().equals(adaptedParameter.getType())) {
hasVarargMappedToElement = true;
break;
}
}
//noinspection ConstantConditions
boolean hasCoercionToUnit = KotlinBuiltIns.isUnit(anonymousAdapterFunction.getReturnType()) &&
!KotlinBuiltIns.isUnit(target.getReturnType());
boolean hasSuspendConversion = !target.isSuspend() && anonymousAdapterFunction.isSuspend();
return (hasVarargMappedToElement ? 1 : 0) +
(hasSuspendConversion ? 2 : 0) +
((hasCoercionToUnit ? 1 : 0) << 2);
}
@NotNull
public static List calculateConstructorParameters(
@NotNull KotlinTypeMapper typeMapper,
@NotNull LanguageVersionSettings languageVersionSettings,
@NotNull CalculatedClosure closure,
@NotNull Type ownerType
) {
List args = Lists.newArrayList();
ClassDescriptor captureThis = closure.getCapturedOuterClassDescriptor();
if (captureThis != null) {
SimpleType thisType = captureThis.getDefaultType();
Type type = typeMapper.mapType(thisType);
args.add(FieldInfo.createForHiddenField(ownerType, type, thisType, CAPTURED_THIS_FIELD));
}
KotlinType captureReceiverType = closure.getCapturedReceiverFromOuterContext();
if (captureReceiverType != null) {
String fieldName = closure.getCapturedReceiverFieldName(typeMapper.getBindingContext(), languageVersionSettings);
args.add(FieldInfo.createForHiddenField(ownerType, typeMapper.mapType(captureReceiverType), captureReceiverType, fieldName));
}
for (EnclosedValueDescriptor enclosedValueDescriptor : closure.getCaptureVariables().values()) {
DeclarationDescriptor descriptor = enclosedValueDescriptor.getDescriptor();
if ((descriptor instanceof VariableDescriptor && !(descriptor instanceof PropertyDescriptor)) ||
ExpressionTypingUtils.isLocalFunction(descriptor)) {
args.add(
FieldInfo.createForHiddenField(
ownerType,
enclosedValueDescriptor.getType(),
enclosedValueDescriptor.getKotlinType(),
enclosedValueDescriptor.getFieldName()
)
);
}
else if (descriptor instanceof FunctionDescriptor) {
assert captureReceiverType != null;
}
}
return args;
}
private static Type[] fieldListToTypeArray(List args) {
Type[] argTypes = new Type[args.size()];
for (int i = 0; i != argTypes.length; ++i) {
argTypes[i] = args.get(i).getFieldType();
}
return argTypes;
}
@NotNull
public static FunctionDescriptor getErasedInvokeFunction(@NotNull FunctionDescriptor function) {
ClassDescriptor functionClass = DescriptorUtilsKt.getBuiltIns(function).getFunction(
function.getValueParameters().size() + (function.getExtensionReceiverParameter() != null ? 1 : 0)
);
MemberScope scope = functionClass.getDefaultType().getMemberScope();
return scope.getContributedFunctions(OperatorNameConventions.INVOKE, NoLookupLocation.FROM_BACKEND).iterator().next();
}
public boolean isCallableReference() {
return functionReferenceTarget != null;
}
}
