/*******************************************************************************
* Copyright (c) 2012, 2014 IBM Corporation and others.
* All rights reserved. This program and the accompanying materials
* are made available under the terms of the Eclipse Public License v1.0
* which accompanies this distribution, and is available at
* http://www.eclipse.org/legal/epl-v10.html
*
* Contributors:
* IBM Corporation - initial API and implementation
* Jesper S Moller - Contributions for
* bug 382701 - [1.8][compiler] Implement semantic analysis of Lambda expressions & Reference expression
* bug 382721 - [1.8][compiler] Effectively final variables needs special treatment
* Bug 416885 - [1.8][compiler]IncompatibleClassChange error (edit)
* Stephan Herrmann - Contribution for
* bug 401030 - [1.8][null] Null analysis support for lambda methods.
* Bug 392099 - [1.8][compiler][null] Apply null annotation on types for null analysis
* Bug 392238 - [1.8][compiler][null] Detect semantically invalid null type annotations
* Bug 400874 - [1.8][compiler] Inference infrastructure should evolve to meet JLS8 18.x (Part G of JSR335 spec)
* Bug 423504 - [1.8] Implement "18.5.3 Functional Interface Parameterization Inference"
* Bug 425142 - [1.8][compiler] NPE in ConstraintTypeFormula.reduceSubType
* Bug 425153 - [1.8] Having wildcard allows incompatible types in a lambda expression
* Bug 424205 - [1.8] Cannot infer type for diamond type with lambda on method invocation
* Bug 425798 - [1.8][compiler] Another NPE in ConstraintTypeFormula.reduceSubType
* Bug 425156 - [1.8] Lambda as an argument is flagged with incompatible error
* Bug 424403 - [1.8][compiler] Generic method call with method reference argument fails to resolve properly.
* Bug 426563 - [1.8] AIOOBE when method with error invoked with lambda expression as argument
* Bug 420525 - [1.8] [compiler] Incorrect error "The type Integer does not define sum(Object, Object) that is applicable here"
* Bug 427438 - [1.8][compiler] NPE at org.eclipse.jdt.internal.compiler.ast.ConditionalExpression.generateCode(ConditionalExpression.java:280)
* Bug 428294 - [1.8][compiler] Type mismatch: cannot convert from List<Object> to Collection<Object[]>
* Bug 428786 - [1.8][compiler] Inference needs to compute the "ground target type" when reducing a lambda compatibility constraint
* Bug 428980 - [1.8][null] simple expression as lambda body doesn't leverage null annotation on argument
* Bug 429430 - [1.8] Lambdas and method reference infer wrong exception type with generics (RuntimeException instead of IOException)
* Bug 432110 - [1.8][compiler] nested lambda type incorrectly inferred vs javac
* Andy Clement (GoPivotal, Inc) aclement@gopivotal.com - Contributions for
* Bug 405104 - [1.8][compiler][codegen] Implement support for serializeable lambdas
*******************************************************************************/
package org.eclipse.jdt.internal.compiler.ast;
import static org.eclipse.jdt.internal.compiler.ast.ExpressionContext.INVOCATION_CONTEXT;
import java.util.Collections;
import java.util.HashSet;
import java.util.LinkedHashSet;
import java.util.Set;
import org.eclipse.jdt.core.compiler.CategorizedProblem;
import org.eclipse.jdt.core.compiler.CharOperation;
import org.eclipse.jdt.core.compiler.IProblem;
import org.eclipse.jdt.internal.compiler.ASTVisitor;
import org.eclipse.jdt.internal.compiler.ClassFile;
import org.eclipse.jdt.internal.compiler.CompilationResult;
import org.eclipse.jdt.internal.compiler.IErrorHandlingPolicy;
import org.eclipse.jdt.internal.compiler.classfmt.ClassFileConstants;
import org.eclipse.jdt.internal.compiler.codegen.CodeStream;
import org.eclipse.jdt.internal.compiler.flow.ExceptionHandlingFlowContext;
import org.eclipse.jdt.internal.compiler.flow.FlowContext;
import org.eclipse.jdt.internal.compiler.flow.FlowInfo;
import org.eclipse.jdt.internal.compiler.flow.UnconditionalFlowInfo;
import org.eclipse.jdt.internal.compiler.impl.CompilerOptions;
import org.eclipse.jdt.internal.compiler.impl.Constant;
import org.eclipse.jdt.internal.compiler.impl.ReferenceContext;
import org.eclipse.jdt.internal.compiler.lookup.AnnotationBinding;
import org.eclipse.jdt.internal.compiler.lookup.Binding;
import org.eclipse.jdt.internal.compiler.lookup.BlockScope;
import org.eclipse.jdt.internal.compiler.lookup.ClassScope;
import org.eclipse.jdt.internal.compiler.lookup.ExtraCompilerModifiers;
import org.eclipse.jdt.internal.compiler.lookup.InferenceContext18;
import org.eclipse.jdt.internal.compiler.lookup.IntersectionCastTypeBinding;
import org.eclipse.jdt.internal.compiler.lookup.LocalVariableBinding;
import org.eclipse.jdt.internal.compiler.lookup.LookupEnvironment;
import org.eclipse.jdt.internal.compiler.lookup.MethodBinding;
import org.eclipse.jdt.internal.compiler.lookup.MethodScope;
import org.eclipse.jdt.internal.compiler.lookup.ParameterizedTypeBinding;
import org.eclipse.jdt.internal.compiler.lookup.PolyTypeBinding;
import org.eclipse.jdt.internal.compiler.lookup.ProblemMethodBinding;
import org.eclipse.jdt.internal.compiler.lookup.ProblemReasons;
import org.eclipse.jdt.internal.compiler.lookup.ReferenceBinding;
import org.eclipse.jdt.internal.compiler.lookup.Scope;
import org.eclipse.jdt.internal.compiler.lookup.SourceTypeBinding;
import org.eclipse.jdt.internal.compiler.lookup.SyntheticArgumentBinding;
import org.eclipse.jdt.internal.compiler.lookup.SyntheticMethodBinding;
import org.eclipse.jdt.internal.compiler.lookup.TagBits;
import org.eclipse.jdt.internal.compiler.lookup.TypeBinding;
import org.eclipse.jdt.internal.compiler.lookup.TypeConstants;
import org.eclipse.jdt.internal.compiler.lookup.TypeIds;
import org.eclipse.jdt.internal.compiler.lookup.VariableBinding;
import org.eclipse.jdt.internal.compiler.parser.Parser;
import org.eclipse.jdt.internal.compiler.problem.AbortCompilation;
import org.eclipse.jdt.internal.compiler.problem.AbortCompilationUnit;
import org.eclipse.jdt.internal.compiler.problem.AbortMethod;
import org.eclipse.jdt.internal.compiler.problem.AbortType;
import org.eclipse.jdt.internal.compiler.problem.ProblemSeverities;
@SuppressWarnings({"rawtypes", "unchecked"})
public class LambdaExpression extends FunctionalExpression implements ReferenceContext, ProblemSeverities {
public Argument [] arguments;
private TypeBinding [] argumentTypes;
public int arrowPosition;
public Statement body;
public boolean hasParentheses;
public MethodScope scope;
boolean voidCompatible = true;
boolean valueCompatible = false;
private boolean shapeAnalysisComplete = false;
boolean returnsValue;
public boolean isSerializable;
boolean returnsVoid;
public LambdaExpression original = this;
public SyntheticArgumentBinding[] outerLocalVariables = NO_SYNTHETIC_ARGUMENTS;
private int outerLocalVariablesSlotSize = 0;
public boolean shouldCaptureInstance = false;
private boolean assistNode = false;
private boolean hasIgnoredMandatoryErrors = false;
private ReferenceBinding classType;
public int ordinal;
private Set thrownExceptions;
private static final SyntheticArgumentBinding [] NO_SYNTHETIC_ARGUMENTS = new SyntheticArgumentBinding[0];
private static final Block NO_BODY = new Block(0, true);
public LambdaExpression(CompilationResult compilationResult, boolean assistNode) {
super(compilationResult);
this.assistNode = assistNode;
setArguments(NO_ARGUMENTS);
setBody(NO_BODY);
}
public void setArguments(Argument [] arguments) {
this.arguments = arguments != null ? arguments : ASTNode.NO_ARGUMENTS;
this.argumentTypes = new TypeBinding[arguments != null ? arguments.length : 0];
}
public Argument [] arguments() {
return this.arguments;
}
public TypeBinding[] argumentTypes() {
return this.argumentTypes;
}
public void setBody(Statement body) {
this.body = body == null ? NO_BODY : body;
}
public Statement body() {
return this.body;
}
public Expression[] resultExpressions() {
return this.resultExpressions;
}
public void setArrowPosition(int arrowPosition) {
this.arrowPosition = arrowPosition;
}
public int arrowPosition() {
return this.arrowPosition;
}
protected FunctionalExpression original() {
return this.original;
}
public void generateCode(BlockScope currentScope, CodeStream codeStream, boolean valueRequired) {
if (this.shouldCaptureInstance) {
this.binding.modifiers &= ~ClassFileConstants.AccStatic;
} else {
this.binding.modifiers |= ClassFileConstants.AccStatic;
}
SourceTypeBinding sourceType = currentScope.enclosingSourceType();
this.binding = sourceType.addSyntheticMethod(this);
int pc = codeStream.position;
StringBuffer signature = new StringBuffer();
signature.append('(');
if (this.shouldCaptureInstance) {
codeStream.aload_0();
signature.append(sourceType.signature());
}
for (int i = 0, length = this.outerLocalVariables == null ? 0 : this.outerLocalVariables.length; i < length; i++) {
SyntheticArgumentBinding syntheticArgument = this.outerLocalVariables[i];
if (this.shouldCaptureInstance) {
syntheticArgument.resolvedPosition++;
}
signature.append(syntheticArgument.type.signature());
LocalVariableBinding capturedOuterLocal = syntheticArgument.actualOuterLocalVariable;
VariableBinding[] path = currentScope.getEmulationPath(capturedOuterLocal);
codeStream.generateOuterAccess(path, this, capturedOuterLocal, currentScope);
}
signature.append(')');
if (this.expectedType instanceof IntersectionCastTypeBinding) {
signature.append(((IntersectionCastTypeBinding)this.expectedType).getSAMType(currentScope).signature());
} else {
signature.append(this.expectedType.signature());
}
int invokeDynamicNumber = codeStream.classFile.recordBootstrapMethod(this);
codeStream.invokeDynamic(invokeDynamicNumber, (this.shouldCaptureInstance ? 1 : 0) + this.outerLocalVariablesSlotSize, 1, this.descriptor.selector, signature.toString().toCharArray());
if (!valueRequired)
codeStream.pop();
codeStream.recordPositionsFrom(pc, this.sourceStart);
}
public boolean kosherDescriptor(Scope currentScope, MethodBinding sam, boolean shouldChatter) {
if (sam.typeVariables != Binding.NO_TYPE_VARIABLES) {
if (shouldChatter)
currentScope.problemReporter().lambdaExpressionCannotImplementGenericMethod(this, sam);
return false;
}
return super.kosherDescriptor(currentScope, sam, shouldChatter);
}
/* This code is arranged so that we can continue with as much analysis as possible while avoiding
* mine fields that would result in a slew of spurious messages. This method is a merger of:
* @see org.eclipse.jdt.internal.compiler.lookup.MethodScope.createMethod(AbstractMethodDeclaration)
* @see org.eclipse.jdt.internal.compiler.lookup.SourceTypeBinding.resolveTypesFor(MethodBinding)
* @see org.eclipse.jdt.internal.compiler.ast.AbstractMethodDeclaration.resolve(ClassScope)
*/
public TypeBinding resolveType(BlockScope blockScope) {
if (this.resolvedType != null)
return this.resolvedType;
if (this.expectedType != null && this.original == this) { // final resolution ? may be not - i.e may be, but only in a non-final universe.
this.ordinal = recordFunctionalType(blockScope);
}
this.constant = Constant.NotAConstant;
this.enclosingScope = blockScope;
boolean argumentsTypeElided = argumentsTypeElided();
int length = this.arguments == null ? 0 : this.arguments.length;
if (!argumentsTypeElided) {
for (int i = 0; i < length; i++)
this.argumentTypes[i] = this.arguments[i].type.resolveType(blockScope, true /* check bounds*/);
}
if (this.expectedType == null && this.expressionContext == INVOCATION_CONTEXT) {
return new PolyTypeBinding(this);
}
MethodScope methodScope = blockScope.methodScope();
this.scope = new MethodScope(blockScope, this, methodScope.isStatic, methodScope.lastVisibleFieldID);
this.scope.isConstructorCall = methodScope.isConstructorCall;
super.resolveType(blockScope); // compute & capture interface function descriptor in singleAbstractMethod.
final boolean haveDescriptor = this.descriptor != null;
if (!haveDescriptor || this.descriptor.typeVariables != Binding.NO_TYPE_VARIABLES) // already complained in kosher*
return this.resolvedType = null;
this.binding = new MethodBinding(ClassFileConstants.AccPrivate | ClassFileConstants.AccSynthetic | ExtraCompilerModifiers.AccUnresolved,
CharOperation.concat(TypeConstants.ANONYMOUS_METHOD, Integer.toString(this.ordinal).toCharArray()), // will be fixed up later.
haveDescriptor ? this.descriptor.returnType : TypeBinding.VOID,
Binding.NO_PARAMETERS, // for now.
haveDescriptor ? this.descriptor.thrownExceptions : Binding.NO_EXCEPTIONS,
blockScope.enclosingSourceType());
this.binding.typeVariables = Binding.NO_TYPE_VARIABLES;
boolean buggyArguments = false;
if (haveDescriptor) {
int descriptorParameterCount = this.descriptor.parameters.length;
int lambdaArgumentCount = this.arguments != null ? this.arguments.length : 0;
if (descriptorParameterCount != lambdaArgumentCount) {
this.scope.problemReporter().lambdaSignatureMismatched(this);
if (argumentsTypeElided || this.original != this) // no interest in continuing to error check copy.
return this.resolvedType = null; // FUBAR, bail out ...
else {
this.resolvedType = null; // continue to type check.
buggyArguments = true;
}
}
}
TypeBinding[] newParameters = new TypeBinding[length];
AnnotationBinding [][] parameterAnnotations = null;
for (int i = 0; i < length; i++) {
Argument argument = this.arguments[i];
if (argument.isVarArgs()) {
if (i == length - 1) {
this.binding.modifiers |= ClassFileConstants.AccVarargs;
} else {
this.scope.problemReporter().illegalVarargInLambda(argument);
buggyArguments = true;
}
}
TypeBinding parameterType;
final TypeBinding expectedParameterType = haveDescriptor && i < this.descriptor.parameters.length ? this.descriptor.parameters[i] : null;
parameterType = argumentsTypeElided ? expectedParameterType : this.argumentTypes[i];
if (parameterType == null) {
buggyArguments = true;
} else if (parameterType == TypeBinding.VOID) {
this.scope.problemReporter().argumentTypeCannotBeVoid(this, argument);
buggyArguments = true;
} else {
if (!parameterType.isValidBinding()) {
this.binding.tagBits |= TagBits.HasUnresolvedArguments;
}
if ((parameterType.tagBits & TagBits.HasMissingType) != 0) {
this.binding.tagBits |= TagBits.HasMissingType;
}
}
}
if (!argumentsTypeElided && !buggyArguments) {
ReferenceBinding groundType = null;
ReferenceBinding expectedSAMType = null;
if (this.expectedType instanceof IntersectionCastTypeBinding)
expectedSAMType = (ReferenceBinding) ((IntersectionCastTypeBinding) this.expectedType).getSAMType(blockScope);
else if (this.expectedType instanceof ReferenceBinding)
expectedSAMType = (ReferenceBinding) this.expectedType;
if (expectedSAMType != null)
groundType = findGroundTargetType(blockScope, expectedSAMType, argumentsTypeElided);
if (groundType != null) {
this.descriptor = groundType.getSingleAbstractMethod(blockScope, true);
if (!this.descriptor.isValidBinding()) {
reportSamProblem(blockScope, this.descriptor);
} else {
this.resolvedType = groundType;
}
// TODO: in which cases do we have to assign this.resolvedType & this.descriptor (with problem bindings) to prevent NPE downstream??
}
}
for (int i = 0; i < length; i++) {
Argument argument = this.arguments[i];
TypeBinding parameterType;
final TypeBinding expectedParameterType = haveDescriptor && i < this.descriptor.parameters.length ? this.descriptor.parameters[i] : null;
parameterType = argumentsTypeElided ? expectedParameterType : this.argumentTypes[i];
if (parameterType != null && parameterType != TypeBinding.VOID) {
if (haveDescriptor && expectedParameterType != null && parameterType.isValidBinding() && TypeBinding.notEquals(parameterType, expectedParameterType)) {
if (expectedParameterType.isProperType(true)) {
this.scope.problemReporter().lambdaParameterTypeMismatched(argument, argument.type, expectedParameterType);
this.resolvedType = null; // continue to type check.
}
}
TypeBinding leafType = parameterType.leafComponentType();
if (leafType instanceof ReferenceBinding && (((ReferenceBinding) leafType).modifiers & ExtraCompilerModifiers.AccGenericSignature) != 0)
this.binding.modifiers |= ExtraCompilerModifiers.AccGenericSignature;
newParameters[i] = argument.bind(this.scope, parameterType, false);
if (argument.annotations != null) {
this.binding.tagBits |= TagBits.HasParameterAnnotations;
if (parameterAnnotations == null) {
parameterAnnotations = new AnnotationBinding[length][];
for (int j = 0; j < i; j++) {
parameterAnnotations[j] = Binding.NO_ANNOTATIONS;
}
}
parameterAnnotations[i] = argument.binding.getAnnotations();
} else if (parameterAnnotations != null) {
parameterAnnotations[i] = Binding.NO_ANNOTATIONS;
}
}
}
// only assign parameters if no problems are found
if (!buggyArguments) {
this.binding.parameters = newParameters;
if (parameterAnnotations != null)
this.binding.setParameterAnnotations(parameterAnnotations);
}
if (!argumentsTypeElided && this.binding.isVarargs()) {
if (!this.binding.parameters[this.binding.parameters.length - 1].isReifiable()) {
this.scope.problemReporter().possibleHeapPollutionFromVararg(this.arguments[this.arguments.length - 1]);
}
}
ReferenceBinding [] exceptions = this.binding.thrownExceptions;
length = exceptions.length;
for (int i = 0; i < length; i++) {
ReferenceBinding exception = exceptions[i];
if ((exception.tagBits & TagBits.HasMissingType) != 0) {
this.binding.tagBits |= TagBits.HasMissingType;
}
this.binding.modifiers |= (exception.modifiers & ExtraCompilerModifiers.AccGenericSignature);
}
TypeBinding returnType = this.binding.returnType;
if (returnType != null) {
if ((returnType.tagBits & TagBits.HasMissingType) != 0) {
this.binding.tagBits |= TagBits.HasMissingType;
}
TypeBinding leafType = returnType.leafComponentType();
if (leafType instanceof ReferenceBinding && (((ReferenceBinding) leafType).modifiers & ExtraCompilerModifiers.AccGenericSignature) != 0)
this.binding.modifiers |= ExtraCompilerModifiers.AccGenericSignature;
} // TODO (stephan): else? (can that happen?)
if (haveDescriptor && !buggyArguments && blockScope.compilerOptions().isAnnotationBasedNullAnalysisEnabled) {
if (!argumentsTypeElided) {
AbstractMethodDeclaration.createArgumentBindings(this.arguments, this.binding, this.scope);
validateNullAnnotations();
// no application of null-ness default, hence also no warning regarding redundant null annotation
mergeParameterNullAnnotations(blockScope);
}
this.binding.tagBits |= (this.descriptor.tagBits & TagBits.AnnotationNullMASK);
}
this.binding.modifiers &= ~ExtraCompilerModifiers.AccUnresolved;
if (this.body instanceof Expression) {
Expression expression = (Expression) this.body;
new ReturnStatement(expression, expression.sourceStart, expression.sourceEnd, true).resolve(this.scope); // :-) ;-)
} else {
this.body.resolve(this.scope);
}
if (this.expectedType instanceof IntersectionCastTypeBinding) {
ReferenceBinding[] intersectingTypes = ((IntersectionCastTypeBinding)this.expectedType).intersectingTypes;
for (int t = 0, max = intersectingTypes.length; t < max; t++) {
if (intersectingTypes[t].findSuperTypeOriginatingFrom(TypeIds.T_JavaIoSerializable, false /*Serializable is not a class*/) != null) {
this.isSerializable = true;
break;
}
}
} else if (this.expectedType != null &&
this.expectedType.findSuperTypeOriginatingFrom(TypeIds.T_JavaIoSerializable, false /*Serializable is not a class*/) != null) {
this.isSerializable = true;
}
if ((this.binding.tagBits & TagBits.HasMissingType) != 0) {
this.scope.problemReporter().missingTypeInLambda(this, this.binding);
}
return this.resolvedType;
}
private ReferenceBinding findGroundTargetType(BlockScope blockScope, ReferenceBinding targetType, boolean argumentTypesElided) {
if (!targetType.isValidBinding())
return null;
ParameterizedTypeBinding withWildCards = InferenceContext18.parameterizedWithWildcard(targetType);
if (withWildCards != null) {
if (!argumentTypesElided)
return new InferenceContext18(blockScope).inferFunctionalInterfaceParameterization(this, blockScope, withWildCards);
else
return findGroundTargetTypeForElidedLambda(blockScope, withWildCards);
}
return targetType;
}
public ReferenceBinding findGroundTargetTypeForElidedLambda(BlockScope blockScope, ParameterizedTypeBinding withWildCards) {
// non-wildcard parameterization (9.8) of the target type
TypeBinding[] types = withWildCards.getNonWildcardParameterization(blockScope);
if (types == null)
return null;
ReferenceBinding genericType = withWildCards.genericType();
return blockScope.environment().createParameterizedType(genericType, types, genericType.enclosingType());
}
public boolean argumentsTypeElided() {
return this.arguments.length > 0 && this.arguments[0].hasElidedType();
}
private boolean doesNotCompleteNormally() {
try {
return this.body.analyseCode(this.scope,
new ExceptionHandlingFlowContext(null, this, Binding.NO_EXCEPTIONS, null, this.scope, FlowInfo.DEAD_END),
UnconditionalFlowInfo.fakeInitializedFlowInfo(this.scope.outerMostMethodScope().analysisIndex, this.scope.referenceType().maxFieldCount)) == FlowInfo.DEAD_END;
} catch (RuntimeException e) {
this.scope.problemReporter().lambdaShapeComputationError(this);
return this.valueCompatible;
}
}
public FlowInfo analyseCode(BlockScope currentScope, FlowContext flowContext, final FlowInfo flowInfo) {
if (this.ignoreFurtherInvestigation)
return flowInfo;
FlowInfo lambdaInfo = flowInfo.copy(); // what happens in vegas, stays in vegas ...
ExceptionHandlingFlowContext methodContext =
new ExceptionHandlingFlowContext(
flowContext,
this,
this.binding.thrownExceptions,
null,
this.scope,
FlowInfo.DEAD_END);
// nullity and mark as assigned
MethodBinding methodWithParameterDeclaration = argumentsTypeElided() ? this.descriptor : this.binding;
AbstractMethodDeclaration.analyseArguments18(lambdaInfo, this.arguments, methodWithParameterDeclaration);
if (this.arguments != null) {
for (int i = 0, count = this.arguments.length; i < count; i++) {
this.bits |= (this.arguments[i].bits & ASTNode.HasTypeAnnotations);
}
}
lambdaInfo = this.body.analyseCode(this.scope, methodContext, lambdaInfo);
// check for missing returning path for block body's ...
if (this.body instanceof Block) {
TypeBinding returnTypeBinding = expectedResultType();
if ((returnTypeBinding == TypeBinding.VOID)) {
if ((lambdaInfo.tagBits & FlowInfo.UNREACHABLE_OR_DEAD) == 0 || ((Block) this.body).statements == null) {
this.bits |= ASTNode.NeedFreeReturn;
}
} else {
if (lambdaInfo != FlowInfo.DEAD_END) {
this.scope.problemReporter().shouldReturn(returnTypeBinding, this);
}
}
} else { // Expression
if (currentScope.compilerOptions().isAnnotationBasedNullAnalysisEnabled
&& lambdaInfo.reachMode() == FlowInfo.REACHABLE)
{
Expression expression = (Expression)this.body;
checkAgainstNullAnnotation(flowContext, expression, expression.nullStatus(lambdaInfo, flowContext));
}
}
return flowInfo;
}
// cf. AbstractMethodDeclaration.validateNullAnnotations()
// pre: !argumentTypeElided()
void validateNullAnnotations() {
// null annotations on parameters?
if (this.binding != null) {
int length = this.binding.parameters.length;
for (int i=0; i<length; i++) {
if (!this.scope.validateNullAnnotation(this.binding.returnType.tagBits, this.arguments[i].type, this.arguments[i].annotations))
this.binding.returnType = this.binding.returnType.unannotated();
}
}
}
// pre: !argumentTypeElided()
// try to merge null annotations from descriptor into binding, complaining about any incompatibilities found
private void mergeParameterNullAnnotations(BlockScope currentScope) {
LookupEnvironment env = currentScope.environment();
TypeBinding[] ourParameters = this.binding.parameters;
TypeBinding[] descParameters = this.descriptor.parameters;
int len = Math.min(ourParameters.length, descParameters.length);
for (int i = 0; i < len; i++) {
long ourTagBits = ourParameters[i].tagBits & TagBits.AnnotationNullMASK;
long descTagBits = descParameters[i].tagBits & TagBits.AnnotationNullMASK;
if (ourTagBits == 0L) {
if (descTagBits != 0L && !ourParameters[i].isBaseType()) {
AnnotationBinding [] annotations = descParameters[i].getTypeAnnotations();
for (int j = 0, length = annotations.length; j < length; j++) {
AnnotationBinding annotation = annotations[j];
if (annotation != null) {
switch (annotation.getAnnotationType().id) {
case TypeIds.T_ConfiguredAnnotationNullable :
case TypeIds.T_ConfiguredAnnotationNonNull :
ourParameters[i] = env.createAnnotatedType(ourParameters[i], new AnnotationBinding [] { annotation });
break;
}
}
}
}
} else if (ourTagBits != descTagBits) {
if (ourTagBits == TagBits.AnnotationNonNull) { // requested @NonNull not provided
char[][] inheritedAnnotationName = null;
if (descTagBits == TagBits.AnnotationNullable)
inheritedAnnotationName = env.getNullableAnnotationName();
currentScope.problemReporter().illegalRedefinitionToNonNullParameter(this.arguments[i], this.descriptor.declaringClass, inheritedAnnotationName);
}
}
}
}
// simplified version of ReturnStatement.checkAgainstNullAnnotation()
void checkAgainstNullAnnotation(FlowContext flowContext, Expression expression, int nullStatus) {
if (nullStatus != FlowInfo.NON_NULL) {
// if we can't prove non-null check against declared null-ness of the descriptor method:
// Note that this.binding never has a return type declaration, always inherit null-ness from the descriptor
if ((this.descriptor.returnType.tagBits & TagBits.AnnotationNonNull) != 0) {
flowContext.recordNullityMismatch(this.scope, expression, expression.resolvedType, this.descriptor.returnType, nullStatus);
}
}
}
public boolean isPertinentToApplicability(TypeBinding targetType, MethodBinding method) {
if (targetType == null) // assumed to signal another primary error
return true;
if (argumentsTypeElided())
return false;
if (!super.isPertinentToApplicability(targetType, method))
return false;
if (this.body instanceof Expression) {
if (!((Expression) this.body).isPertinentToApplicability(targetType, method))
return false;
} else {
Expression [] returnExpressions = this.resultExpressions;
for (int i = 0, length = returnExpressions.length; i < length; i++) {
if (!returnExpressions[i].isPertinentToApplicability(targetType, method))
return false;
}
}
return true;
}
public boolean isVoidCompatible() {
if (!this.shapeAnalysisComplete)
throw new IllegalStateException("asking isVoidCompatible before shape analysis is complete"); //$NON-NLS-1$
return this.voidCompatible;
}
public boolean isValueCompatible() {
if (!this.shapeAnalysisComplete)
throw new IllegalStateException("asking isValueCompatible before shape analysis is complete"); //$NON-NLS-1$
return this.valueCompatible;
}
public StringBuffer printExpression(int tab, StringBuffer output) {
return printExpression(tab, output, false);
}
public StringBuffer printExpression(int tab, StringBuffer output, boolean makeShort) {
int parenthesesCount = (this.bits & ASTNode.ParenthesizedMASK) >> ASTNode.ParenthesizedSHIFT;
String suffix = ""; //$NON-NLS-1$
for(int i = 0; i < parenthesesCount; i++) {
output.append('(');
suffix += ')';
}
output.append('(');
if (this.arguments != null) {
for (int i = 0; i < this.arguments.length; i++) {
if (i > 0) output.append(", "); //$NON-NLS-1$
this.arguments[i].print(0, output);
}
}
output.append(") -> " ); //$NON-NLS-1$
if (makeShort) {
output.append("{}"); //$NON-NLS-1$
} else {
if (this.body != null)
this.body.print(this.body instanceof Block ? tab : 0, output);
else
output.append("<@incubator>"); //$NON-NLS-1$
}
return output.append(suffix);
}
public TypeBinding expectedResultType() {
return this.descriptor != null && this.descriptor.isValidBinding() ? this.descriptor.returnType : null;
}
public void traverse(ASTVisitor visitor, BlockScope blockScope) {
if (visitor.visit(this, blockScope)) {
if (this.arguments != null) {
int argumentsLength = this.arguments.length;
for (int i = 0; i < argumentsLength; i++)
this.arguments[i].traverse(visitor, this.scope);
}
if (this.body != null) {
this.body.traverse(visitor, this.scope);
}
}
visitor.endVisit(this, blockScope);
}
public MethodScope getScope() {
return this.scope;
}
private boolean enclosingScopesHaveErrors() {
Scope skope = this.enclosingScope;
while (skope != null) {
ReferenceContext context = skope.referenceContext();
if (context != null && context.hasErrors())
return true;
skope = skope.parent;
}
return false;
}
private void analyzeShape() { // simple minded analysis for code assist.
class ShapeComputer extends ASTVisitor {
public boolean visit(TypeDeclaration type, BlockScope skope) {
return false;
}
public boolean visit(TypeDeclaration type, ClassScope skope) {
return false;
}
public boolean visit(LambdaExpression type, BlockScope skope) {
return false;
}
public boolean visit(ReturnStatement returnStatement, BlockScope skope) {
if (returnStatement.expression != null) {
LambdaExpression.this.valueCompatible = true;
LambdaExpression.this.voidCompatible = false;
} else {
LambdaExpression.this.voidCompatible = true;
LambdaExpression.this.valueCompatible = false;
}
return false;
}
}
if (this.body instanceof Expression) {
this.voidCompatible = ((Expression) this.body).statementExpression();
this.valueCompatible = true;
} else {
// We need to be a bit tolerant/fuzzy here: the code is being written "just now", if we are too pedantic, selection/completion will break;
this.voidCompatible = true;
this.valueCompatible = true;
this.body.traverse(new ShapeComputer(), null);
}
this.shapeAnalysisComplete = true;
}
public boolean isCompatibleWith(TypeBinding left, final Scope someScope) {
if (!(left instanceof ReferenceBinding))
return false;
left = left.uncapture(this.enclosingScope);
shapeAnalysis: if (!this.shapeAnalysisComplete) {
IErrorHandlingPolicy oldPolicy = this.enclosingScope.problemReporter().switchErrorHandlingPolicy(silentErrorHandlingPolicy);
final CompilerOptions compilerOptions = this.enclosingScope.compilerOptions();
boolean analyzeNPE = compilerOptions.isAnnotationBasedNullAnalysisEnabled;
compilerOptions.isAnnotationBasedNullAnalysisEnabled = false;
try {
final LambdaExpression copy = copy();
if (copy == null) {
if (this.assistNode) {
analyzeShape(); // not on terra firma here !
// FIXME: we don't yet have the same, should we compute it here & now?
// if (sam.returnType.id == TypeIds.T_void) {
// if (!this.voidCompatible)
// return false;
// } else {
// if (!this.valueCompatible)
// return false;
// }
}
return !isPertinentToApplicability(left, null);
}
copy.setExpressionContext(this.expressionContext);
copy.setExpectedType(left);
this.hasIgnoredMandatoryErrors = false;
TypeBinding type = copy.resolveType(this.enclosingScope);
if (type == null || !type.isValidBinding())
return false;
if (this.body instanceof Block) {
if (this.returnsVoid) {
this.shapeAnalysisComplete = true;
}
} else {
this.voidCompatible = ((Expression) this.body).statementExpression();
// TODO: in getResolvedCopyForInferenceTargeting() we need to check if the expression
// *could* also produce a value and set valueCompatible accordingly.
// Is that needed also here?
this.shapeAnalysisComplete = true;
}
// Do not proceed with data/control flow analysis if resolve encountered errors.
if (this.hasIgnoredMandatoryErrors || enclosingScopesHaveErrors()) {
if (!isPertinentToApplicability(left, null))
break shapeAnalysis;
if (this.arguments.length != 0) // error not because of the target type imposition, but is inherent. Just say compatible since errors in body aren't to influence applicability.
return false;
break shapeAnalysis;
}
// value compatibility of block lambda's is the only open question.
if (!this.shapeAnalysisComplete)
this.valueCompatible = copy.doesNotCompleteNormally();
this.shapeAnalysisComplete = true;
} finally {
compilerOptions.isAnnotationBasedNullAnalysisEnabled = analyzeNPE;
this.hasIgnoredMandatoryErrors = false;
this.enclosingScope.problemReporter().switchErrorHandlingPolicy(oldPolicy);
}
}
ReferenceBinding expectedSAMType = null;
if (left instanceof IntersectionCastTypeBinding)
expectedSAMType = (ReferenceBinding) ((IntersectionCastTypeBinding) left).getSAMType(this.enclosingScope);
else if (left instanceof ReferenceBinding)
expectedSAMType = (ReferenceBinding) left;
ReferenceBinding groundTargetType = expectedSAMType != null ? findGroundTargetType(this.enclosingScope, expectedSAMType, argumentsTypeElided()) : null;
if (groundTargetType == null)
return false;
MethodBinding sam = groundTargetType.getSingleAbstractMethod(this.enclosingScope, true);
if (sam == null || !sam.isValidBinding())
return false;
if (sam.parameters.length != this.arguments.length)
return false;
if (!isPertinentToApplicability(left, null)) // This check should happen after return type check below, but for buggy javac compatibility we have left it in.
return true;
if (sam.returnType.id == TypeIds.T_void) {
if (!this.voidCompatible)
return false;
} else {
if (!this.valueCompatible)
return false;
}
Expression [] returnExpressions = this.resultExpressions;
for (int i = 0, length = returnExpressions.length; i < length; i++) {
if (returnExpressions[i] instanceof FunctionalExpression) { // don't want to use the resolvedType - polluted from some other overload resolution candidate
if (!returnExpressions[i].isCompatibleWith(sam.returnType, this.enclosingScope))
return false;
} else {
if (this.enclosingScope.parameterCompatibilityLevel(returnExpressions[i].resolvedType, sam.returnType) == Scope.NOT_COMPATIBLE) {
if (!returnExpressions[i].isConstantValueOfTypeAssignableToType(returnExpressions[i].resolvedType, sam.returnType))
if (sam.returnType.id != TypeIds.T_void || this.body instanceof Block)
return false;
}
}
}
TypeBinding [] samPararameterTypes = sam.parameters;
for (int i = 0, length = samPararameterTypes.length; i < length; i++) { // lengths known to be equal.
if (TypeBinding.notEquals(samPararameterTypes[i], this.argumentTypes[i]))
return false;
}
return true;
}
/**
* Get a resolved copy of this lambda for use by type inference, as to avoid spilling any premature
* type results into the original lambda.
*
* @param targetType the target functional type against which inference is attempted, must be a non-null valid functional type
* @return a resolved copy of 'this' or null if significant errors where encountered
*/
public LambdaExpression getResolvedCopyForInferenceTargeting(TypeBinding targetType) {
// note: this is essentially a simplified extract from isCompatibleWith(TypeBinding,Scope).
if (this.shapeAnalysisComplete && this.binding != null)
return this;
targetType = targetType.uncapture(this.enclosingScope);
// TODO: caching
IErrorHandlingPolicy oldPolicy = this.enclosingScope.problemReporter().switchErrorHandlingPolicy(silentErrorHandlingPolicy);
final CompilerOptions compilerOptions = this.enclosingScope.compilerOptions();
boolean analyzeNPE = compilerOptions.isAnnotationBasedNullAnalysisEnabled;
final LambdaExpression copy = copy();
if (copy == null) {
return null;
}
try {
compilerOptions.isAnnotationBasedNullAnalysisEnabled = false;
copy.setExpressionContext(this.expressionContext);
copy.setExpectedType(targetType);
this.hasIgnoredMandatoryErrors = false;
TypeBinding type = copy.resolveType(this.enclosingScope);
if (type == null || !type.isValidBinding())
return null;
if (this.body instanceof Block) {
if (copy.returnsVoid) {
copy.shapeAnalysisComplete = true;
} else {
copy.valueCompatible = this.returnsValue;
}
} else {
copy.voidCompatible = ((Expression) this.body).statementExpression();
TypeBinding resultType = ((Expression) this.body).resolvedType;
if (resultType == null) // case of a yet-unresolved poly expression?
copy.valueCompatible = true;
else
copy.valueCompatible = (resultType != TypeBinding.VOID);
copy.shapeAnalysisComplete = true;
}
// Do not proceed with data/control flow analysis if resolve encountered errors.
if (!this.hasIgnoredMandatoryErrors && !enclosingScopesHaveErrors()) {
// value compatibility of block lambda's is the only open question.
if (!copy.shapeAnalysisComplete)
copy.valueCompatible = copy.doesNotCompleteNormally();
} else {
if (!copy.returnsVoid)
copy.valueCompatible = true; // optimistically, TODO: is this OK??
}
copy.shapeAnalysisComplete = true;
copy.resultExpressions = this.resultExpressions;
this.resultExpressions = NO_EXPRESSIONS;
} finally {
compilerOptions.isAnnotationBasedNullAnalysisEnabled = analyzeNPE;
this.hasIgnoredMandatoryErrors = false;
this.enclosingScope.problemReporter().switchErrorHandlingPolicy(oldPolicy);
}
return copy;
}
public boolean sIsMoreSpecific(TypeBinding s, TypeBinding t, Scope skope) {
// 15.12.2.5
if (super.sIsMoreSpecific(s, t, skope))
return true;
if (argumentsTypeElided() || t.findSuperTypeOriginatingFrom(s) != null)
return false;
s = s.capture(this.enclosingScope, this.sourceEnd);
MethodBinding sSam = s.getSingleAbstractMethod(this.enclosingScope, true);
if (sSam == null || !sSam.isValidBinding())
return false;
TypeBinding r1 = sSam.returnType;
MethodBinding tSam = t.getSingleAbstractMethod(this.enclosingScope, true);
if (tSam == null || !tSam.isValidBinding())
return false;
TypeBinding r2 = tSam.returnType;
if (r2.id == TypeIds.T_void)
return true;
if (r1.id == TypeIds.T_void)
return false;
// r1 <: r2
if (r1.isCompatibleWith(r2, skope))
return true;
Expression [] returnExpressions = this.resultExpressions;
int returnExpressionsLength = returnExpressions == null ? 0 : returnExpressions.length;
int i;
// r1 is a primitive type, r2 is a reference type, and each result expression is a standalone expression (15.2) of a primitive type
if (r1.isBaseType() && !r2.isBaseType()) {
for (i = 0; i < returnExpressionsLength; i++) {
if (returnExpressions[i].isPolyExpression() || !returnExpressions[i].resolvedType.isBaseType())
break;
}
if (i == returnExpressionsLength)
return true;
}
if (!r1.isBaseType() && r2.isBaseType()) {
for (i = 0; i < returnExpressionsLength; i++) {
if (returnExpressions[i].resolvedType.isBaseType())
break;
}
if (i == returnExpressionsLength)
return true;
}
if (r1.isFunctionalInterface(this.enclosingScope) && r2.isFunctionalInterface(this.enclosingScope)) {
for (i = 0; i < returnExpressionsLength; i++) {
Expression resultExpression = returnExpressions[i];
if (!resultExpression.sIsMoreSpecific(r1, r2, skope))
break;
}
if (i == returnExpressionsLength)
return true;
}
return false;
}
LambdaExpression copy() {
final Parser parser = new Parser(this.enclosingScope.problemReporter(), false);
final char[] source = this.compilationResult.getCompilationUnit().getContents();
LambdaExpression copy = (LambdaExpression) parser.parseLambdaExpression(source, this.sourceStart, this.sourceEnd - this.sourceStart + 1,
this.enclosingScope.referenceCompilationUnit(), false /* record line separators */);
if (copy != null) { // ==> syntax errors == null
copy.original = this;
}
return copy;
}
public void returnsExpression(Expression expression, TypeBinding resultType) {
if (this.original == this) // not in overload resolution context.
return;
if (this.body instanceof Expression) {
this.original.valueCompatible = resultType != null && resultType.id != TypeIds.T_void;
this.original.resultExpressions = new Expression[1];
this.original.resultExpressions[0] = expression;
return; // void compatibility determined via statementExpression()
}
if (expression != null) {
this.original.returnsValue = true;
this.original.voidCompatible = false;
this.original.valueCompatible = !this.original.returnsVoid;
if (resultType != null) {
Expression [] returnExpressions = this.original.resultExpressions;
int resultsLength = returnExpressions.length;
System.arraycopy(returnExpressions, 0, returnExpressions = new Expression[resultsLength + 1], 0, resultsLength);
returnExpressions[resultsLength] = expression;
this.original.resultExpressions = returnExpressions;
}
} else {
this.original.returnsVoid = true;
this.original.valueCompatible = false;
this.original.voidCompatible = !this.original.returnsValue;
}
}
public CompilationResult compilationResult() {
return this.compilationResult;
}
public void abort(int abortLevel, CategorizedProblem problem) {
switch (abortLevel) {
case AbortCompilation :
throw new AbortCompilation(this.compilationResult, problem);
case AbortCompilationUnit :
throw new AbortCompilationUnit(this.compilationResult, problem);
case AbortType :
throw new AbortType(this.compilationResult, problem);
default :
throw new AbortMethod(this.compilationResult, problem);
}
}
public CompilationUnitDeclaration getCompilationUnitDeclaration() {
return this.enclosingScope == null ? null : this.enclosingScope.compilationUnitScope().referenceContext;
}
public boolean hasErrors() {
return this.ignoreFurtherInvestigation;
}
public void tagAsHavingErrors() {
this.ignoreFurtherInvestigation = true;
Scope parent = this.enclosingScope.parent;
while (parent != null) {
switch(parent.kind) {
case Scope.CLASS_SCOPE:
case Scope.METHOD_SCOPE:
parent.referenceContext().tagAsHavingErrors();
return;
default:
parent = parent.parent;
break;
}
}
}
public void tagAsHavingIgnoredMandatoryErrors(int problemId) {
switch (problemId) {
// 15.27.3 requires exception throw related errors to not influence congruence. Other errors should. Also don't abort shape analysis.
case IProblem.UnhandledExceptionOnAutoClose:
case IProblem.UnhandledExceptionInDefaultConstructor:
case IProblem.UnhandledException:
return;
/* The following structural problems can occur only because of target type imposition. Filter, so we can distinguish inherent errors
in explicit lambdas. This is to help decide whether to proceed with data/control flow analysis to discover shape. In case of inherent
errors, we will not call analyze code as it is not prepared to analyze broken programs.
*/
case IProblem.VoidMethodReturnsValue:
case IProblem.ShouldReturnValueHintMissingDefault:
case IProblem.ShouldReturnValue:
case IProblem.ReturnTypeMismatch:
case IProblem.IncompatibleLambdaParameterType:
case IProblem.lambdaParameterTypeMismatched:
case IProblem.lambdaSignatureMismatched:
case IProblem.LambdaDescriptorMentionsUnmentionable:
case IProblem.TargetTypeNotAFunctionalInterface:
case IProblem.illFormedParameterizationOfFunctionalInterface:
case IProblem.MultipleFunctionalInterfaces:
case IProblem.NoGenericLambda:
return;
default:
this.original.hasIgnoredMandatoryErrors = true;
MethodScope enclosingLambdaScope = this.scope == null ? null : this.scope.enclosingLambdaScope();
while (enclosingLambdaScope != null) {
LambdaExpression enclosingLambda = (LambdaExpression) enclosingLambdaScope.referenceContext;
if (enclosingLambda.original != enclosingLambda)
enclosingLambda.original.hasIgnoredMandatoryErrors = true;
enclosingLambdaScope = enclosingLambdaScope.enclosingLambdaScope();
}
return;
}
}
public void throwsException(TypeBinding exceptionType) {
if (this.expressionContext != INVOCATION_CONTEXT)
return;
if (this.thrownExceptions == null)
this.thrownExceptions = new HashSet<TypeBinding>();
this.thrownExceptions.add(exceptionType);
}
public Set<TypeBinding> getThrownExceptions() {
if (this.thrownExceptions == null)
return Collections.emptySet();
return this.thrownExceptions;
}
public void generateCode(ClassScope classScope, ClassFile classFile) {
int problemResetPC = 0;
classFile.codeStream.wideMode = false;
boolean restart = false;
do {
try {
problemResetPC = classFile.contentsOffset;
this.generateCode(classFile);
restart = false;
} catch (AbortMethod e) {
// Restart code generation if possible ...
if (e.compilationResult == CodeStream.RESTART_IN_WIDE_MODE) {
// a branch target required a goto_w, restart code generation in wide mode.
classFile.contentsOffset = problemResetPC;
classFile.methodCount--;
classFile.codeStream.resetInWideMode(); // request wide mode
restart = true;
} else if (e.compilationResult == CodeStream.RESTART_CODE_GEN_FOR_UNUSED_LOCALS_MODE) {
classFile.contentsOffset = problemResetPC;
classFile.methodCount--;
classFile.codeStream.resetForCodeGenUnusedLocals();
restart = true;
} else {
throw new AbortType(this.compilationResult, e.problem);
}
}
} while (restart);
}
public void generateCode(ClassFile classFile) {
classFile.generateMethodInfoHeader(this.binding);
int methodAttributeOffset = classFile.contentsOffset;
int attributeNumber = classFile.generateMethodInfoAttributes(this.binding);
int codeAttributeOffset = classFile.contentsOffset;
classFile.generateCodeAttributeHeader();
CodeStream codeStream = classFile.codeStream;
codeStream.reset(this, classFile);
// initialize local positions
this.scope.computeLocalVariablePositions(this.outerLocalVariablesSlotSize + (this.binding.isStatic() ? 0 : 1), codeStream);
if (this.outerLocalVariables != null) {
for (int i = 0, max = this.outerLocalVariables.length; i < max; i++) {
LocalVariableBinding argBinding;
codeStream.addVisibleLocalVariable(argBinding = this.outerLocalVariables[i]);
codeStream.record(argBinding);
argBinding.recordInitializationStartPC(0);
}
}
// arguments initialization for local variable debug attributes
if (this.arguments != null) {
for (int i = 0, max = this.arguments.length; i < max; i++) {
LocalVariableBinding argBinding;
codeStream.addVisibleLocalVariable(argBinding = this.arguments[i].binding);
argBinding.recordInitializationStartPC(0);
}
}
if (this.body instanceof Block) {
this.body.generateCode(this.scope, codeStream);
if ((this.bits & ASTNode.NeedFreeReturn) != 0) {
codeStream.return_();
}
} else {
Expression expression = (Expression) this.body;
expression.generateCode(this.scope, codeStream, true);
if (this.binding.returnType == TypeBinding.VOID) {
codeStream.return_();
} else {
codeStream.generateReturnBytecode(expression);
}
}
// local variable attributes
codeStream.exitUserScope(this.scope);
codeStream.recordPositionsFrom(0, this.sourceEnd); // WAS declarationSourceEnd.
try {
classFile.completeCodeAttribute(codeAttributeOffset);
} catch(NegativeArraySizeException e) {
throw new AbortMethod(this.scope.referenceCompilationUnit().compilationResult, null);
}
attributeNumber++;
classFile.completeMethodInfo(this.binding, methodAttributeOffset, attributeNumber);
}
public void addSyntheticArgument(LocalVariableBinding actualOuterLocalVariable) {
if (this.original != this || this.binding == null)
return; // Do not bother tracking outer locals for clones created during overload resolution.
SyntheticArgumentBinding syntheticLocal = null;
int newSlot = this.outerLocalVariables.length;
for (int i = 0; i < newSlot; i++) {
if (this.outerLocalVariables[i].actualOuterLocalVariable == actualOuterLocalVariable)
return;
}
System.arraycopy(this.outerLocalVariables, 0, this.outerLocalVariables = new SyntheticArgumentBinding[newSlot + 1], 0, newSlot);
this.outerLocalVariables[newSlot] = syntheticLocal = new SyntheticArgumentBinding(actualOuterLocalVariable);
syntheticLocal.resolvedPosition = this.outerLocalVariablesSlotSize; // may need adjusting later if we need to generate an instance method for the lambda.
syntheticLocal.declaringScope = this.scope;
int parameterCount = this.binding.parameters.length;
TypeBinding [] newParameters = new TypeBinding[parameterCount + 1];
newParameters[newSlot] = actualOuterLocalVariable.type;
for (int i = 0, j = 0; i < parameterCount; i++, j++) {
if (i == newSlot) j++;
newParameters[j] = this.binding.parameters[i];
}
this.binding.parameters = newParameters;
switch (syntheticLocal.type.id) {
case TypeIds.T_long :
case TypeIds.T_double :
this.outerLocalVariablesSlotSize += 2;
break;
default :
this.outerLocalVariablesSlotSize++;
break;
}
}
public SyntheticArgumentBinding getSyntheticArgument(LocalVariableBinding actualOuterLocalVariable) {
for (int i = 0, length = this.outerLocalVariables == null ? 0 : this.outerLocalVariables.length; i < length; i++)
if (this.outerLocalVariables[i].actualOuterLocalVariable == actualOuterLocalVariable)
return this.outerLocalVariables[i];
return null;
}
// Return the actual method binding devoid of synthetics.
public MethodBinding getMethodBinding() {
if (this.actualMethodBinding == null) {
if (this.binding != null) {
this.actualMethodBinding = new MethodBinding(this.binding.modifiers, this.binding.selector, this.binding.returnType,
this.binding instanceof SyntheticMethodBinding ? this.descriptor.parameters : this.binding.parameters, // retain any faults in parameter list.
this.binding.thrownExceptions, this.binding.declaringClass);
this.actualMethodBinding.tagBits = this.binding.tagBits;
} else {
this.actualMethodBinding = new ProblemMethodBinding(CharOperation.NO_CHAR, null, ProblemReasons.NoSuchSingleAbstractMethod);
}
}
return this.actualMethodBinding;
}
public int diagnosticsSourceEnd() {
return this.body instanceof Block ? this.arrowPosition : this.sourceEnd;
}
public TypeBinding[] getMarkerInterfaces() {
if (this.expectedType instanceof IntersectionCastTypeBinding) {
Set markerBindings = new LinkedHashSet();
TypeBinding[] intersectionTypes = ((IntersectionCastTypeBinding)this.expectedType).intersectingTypes;
for (int i = 0,max = intersectionTypes.length; i < max; i++) {
TypeBinding typeBinding = intersectionTypes[i];
MethodBinding methodBinding = typeBinding.getSingleAbstractMethod(this.scope, true);
// Why doesn't getSingleAbstractMethod do as the javadoc says, and return null
// when it is not a SAM type
if (!(methodBinding instanceof ProblemMethodBinding && ((ProblemMethodBinding)methodBinding).problemId()==ProblemReasons.NoSuchSingleAbstractMethod)) {
continue;
}
if (typeBinding.id == TypeIds.T_JavaIoSerializable) {
// Serializable is captured as a bitflag
continue;
}
markerBindings.add(typeBinding);
}
if (markerBindings.size() > 0) {
return (TypeBinding[])markerBindings.toArray(new TypeBinding[markerBindings.size()]);
}
}
return null;
}
public ReferenceBinding getTypeBinding() {
if (this.classType != null || this.resolvedType == null)
return null;
class LambdaTypeBinding extends ReferenceBinding {
public MethodBinding[] methods() {
return new MethodBinding [] { getMethodBinding() };
}
public char[] sourceName() {
return TypeConstants.LAMBDA_TYPE;
}
public ReferenceBinding superclass() {
return LambdaExpression.this.scope.getJavaLangObject();
}
public ReferenceBinding[] superInterfaces() {
return new ReferenceBinding[] { (ReferenceBinding) LambdaExpression.this.resolvedType };
}
@Override
public char[] computeUniqueKey() {
return LambdaExpression.this.descriptor.declaringClass.computeUniqueKey();
}
public String toString() {
StringBuffer output = new StringBuffer("()->{} implements "); //$NON-NLS-1$
output.append(LambdaExpression.this.descriptor.declaringClass.sourceName());
output.append('.');
output.append(LambdaExpression.this.descriptor.toString());
return output.toString();
}
}
return this.classType = new LambdaTypeBinding();
}
}