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/*******************************************************************************
 *  * Copyright (c) 2000, 2021 IBM Corporation and others.
 *
 * This program and the accompanying materials
 * are made available under the terms of the Eclipse Public License 2.0
 * which accompanies this distribution, and is available at
 * https://www.eclipse.org/legal/epl-2.0/
 *
 * SPDX-License-Identifier: EPL-2.0
 *
 *     IBM Corporation - initial API and implementation
 *     Stephan Herrmann - Contributions for
 *								bug 349326 - [1.7] new warning for missing try-with-resources
 *								bug 374605 - Unreasonable warning for enum-based switch statements
 *								bug 382353 - [1.8][compiler] Implementation property modifiers should be accepted on default methods.
 *								bug 382354 - [1.8][compiler] Compiler silent on conflicting modifier
 *								bug 401030 - [1.8][null] Null analysis support for lambda methods.
 *								Bug 416176 - [1.8][compiler][null] null type annotations cause grief on type variables
 *								Bug 429958 - [1.8][null] evaluate new DefaultLocation attribute of @NonNullByDefault
 *     Jesper S Moller - Contributions for
 *							bug 382701 - [1.8][compiler] Implement semantic analysis of Lambda expressions & Reference expression
 *******************************************************************************/
package org.eclipse.jdt.internal.compiler.lookup;

import java.util.Map;

import org.eclipse.jdt.core.compiler.CharOperation;
import org.eclipse.jdt.internal.compiler.ASTVisitor;
import org.eclipse.jdt.internal.compiler.ast.*;
import org.eclipse.jdt.internal.compiler.classfmt.ClassFileConstants;
import org.eclipse.jdt.internal.compiler.codegen.CodeStream;
import org.eclipse.jdt.internal.compiler.codegen.ConstantPool;
import org.eclipse.jdt.internal.compiler.flow.FlowInfo;
import org.eclipse.jdt.internal.compiler.flow.UnconditionalFlowInfo;
import org.eclipse.jdt.internal.compiler.impl.ReferenceContext;
import org.eclipse.jdt.internal.compiler.problem.ProblemReporter;

/**
 * Specific block scope used for methods, constructors or clinits, representing
 * its outermost blockscope. Note also that such a scope will be provided to enclose
 * field initializers subscopes as well.
 */
public class MethodScope extends BlockScope {

	public ReferenceContext referenceContext;
	public boolean isStatic; // method modifier or initializer one

	//fields used during name resolution
	public boolean isConstructorCall = false;
	public FieldBinding initializedField; // the field being initialized
	public int lastVisibleFieldID = -1; // the ID of the last field which got declared
	// note that #initializedField can be null AND lastVisibleFieldID >= 0, when processing instance field initializers.

	// flow analysis
	/* By specifying {@code -Djdt.flow.test.extra=true} tests can push all flow analysis into the extra bits of UnconditionalFlowInfo. */
	private static int baseAnalysisIndex = 0;
	public int analysisIndex = baseAnalysisIndex; // for setting flow-analysis id
	public boolean isPropagatingInnerClassEmulation;

	// for local variables table attributes
	public int lastIndex = 0;
	public long[] definiteInits = new long[4];
	public long[][] extraDefiniteInits = new long[4][];

	// inner-emulation
	public SyntheticArgumentBinding[] extraSyntheticArguments;

	// remember suppressed warning re missing 'default:' to give hints on possibly related flow problems
	public boolean hasMissingSwitchDefault; // TODO(stephan): combine flags to a bitset?

	public boolean isCompactConstructorScope = false;

	static {
		if (Boolean.getBoolean("jdt.flow.test.extra")) { //$NON-NLS-1$
			baseAnalysisIndex = 64;
			System.out.println("JDT/Core testing with -Djdt.flow.test.extra=true"); //$NON-NLS-1$
		}
	}

public MethodScope(Scope parent, ReferenceContext context, boolean isStatic) {
	super(METHOD_SCOPE, parent);
	this.locals = new LocalVariableBinding[5];
	this.referenceContext = context;
	this.isStatic = isStatic;
	this.startIndex = 0;
}

public MethodScope(Scope parent, ReferenceContext context, boolean isStatic, int lastVisibleFieldID) {
	this(parent, context, isStatic);
	this.lastVisibleFieldID = lastVisibleFieldID;
}

@Override
String basicToString(int tab) {
	String newLine = "\n"; //$NON-NLS-1$
	for (int i = tab; --i >= 0;)
		newLine += "\t"; //$NON-NLS-1$

	String s = newLine + "--- Method Scope ---"; //$NON-NLS-1$
	newLine += "\t"; //$NON-NLS-1$
	s += newLine + "locals:"; //$NON-NLS-1$
	for (int i = 0; i < this.localIndex; i++)
		s += newLine + "\t" + this.locals[i].toString(); //$NON-NLS-1$
	s += newLine + "startIndex = " + this.startIndex; //$NON-NLS-1$
	s += newLine + "isConstructorCall = " + this.isConstructorCall; //$NON-NLS-1$
	s += newLine + "initializedField = " + this.initializedField; //$NON-NLS-1$
	s += newLine + "lastVisibleFieldID = " + this.lastVisibleFieldID; //$NON-NLS-1$
	s += newLine + "referenceContext = " + this.referenceContext; //$NON-NLS-1$
	return s;
}

/**
 * Spec : 8.4.3 & 9.4
 */
private void checkAndSetModifiersForConstructor(MethodBinding methodBinding) {
	int modifiers = methodBinding.modifiers;
	final ReferenceBinding declaringClass = methodBinding.declaringClass;
	if ((modifiers & ExtraCompilerModifiers.AccAlternateModifierProblem) != 0)
		problemReporter().duplicateModifierForMethod(declaringClass, (AbstractMethodDeclaration) this.referenceContext);

	int astNodeBits = ((ConstructorDeclaration) this.referenceContext).bits;
	if ((astNodeBits & ASTNode.IsDefaultConstructor) != 0
			||((astNodeBits & ASTNode.IsImplicit) != 0 && (astNodeBits & ASTNode.IsCanonicalConstructor) != 0))  {
		// certain flags are propagated from declaring class onto constructor
		final int DECLARING_FLAGS = ClassFileConstants.AccEnum|ClassFileConstants.AccPublic|ClassFileConstants.AccProtected;
		final int VISIBILITY_FLAGS = ClassFileConstants.AccPrivate|ClassFileConstants.AccPublic|ClassFileConstants.AccProtected;
		int flags;
		if ((flags = declaringClass.modifiers & DECLARING_FLAGS) != 0) {
			if ((flags & ClassFileConstants.AccEnum) != 0) {
				modifiers &= ~VISIBILITY_FLAGS;
				modifiers |= ClassFileConstants.AccPrivate; // default constructor is implicitly private in enum
			} else {
				modifiers &= ~VISIBILITY_FLAGS;
				modifiers |= flags; // propagate public/protected
			}
		}
	}

	// after this point, tests on the 16 bits reserved.
	int realModifiers = modifiers & ExtraCompilerModifiers.AccJustFlag;

	// check for abnormal modifiers
	final int UNEXPECTED_MODIFIERS = ~(ClassFileConstants.AccPublic | ClassFileConstants.AccPrivate | ClassFileConstants.AccProtected | ClassFileConstants.AccStrictfp);
	if (declaringClass.isEnum() && (((ConstructorDeclaration) this.referenceContext).bits & ASTNode.IsDefaultConstructor) == 0) {
		final int UNEXPECTED_ENUM_CONSTR_MODIFIERS = ~(ClassFileConstants.AccPrivate | ClassFileConstants.AccStrictfp);
		if ((realModifiers & UNEXPECTED_ENUM_CONSTR_MODIFIERS) != 0) {
			problemReporter().illegalModifierForEnumConstructor((AbstractMethodDeclaration) this.referenceContext);
			modifiers &= ~ExtraCompilerModifiers.AccJustFlag | ~UNEXPECTED_ENUM_CONSTR_MODIFIERS;
		} else if ((((AbstractMethodDeclaration) this.referenceContext).modifiers & ClassFileConstants.AccStrictfp) != 0) {
			// must check the parse node explicitly
			problemReporter().illegalModifierForMethod((AbstractMethodDeclaration) this.referenceContext);
		}
		modifiers |= ClassFileConstants.AccPrivate; // enum constructor is implicitly private
	} else if ((realModifiers & UNEXPECTED_MODIFIERS) != 0) {
		problemReporter().illegalModifierForMethod((AbstractMethodDeclaration) this.referenceContext);
		modifiers &= ~ExtraCompilerModifiers.AccJustFlag | ~UNEXPECTED_MODIFIERS;
	} else if ((((AbstractMethodDeclaration) this.referenceContext).modifiers & ClassFileConstants.AccStrictfp) != 0) {
		// must check the parse node explicitly
		problemReporter().illegalModifierForMethod((AbstractMethodDeclaration) this.referenceContext);
	}

	// check for incompatible modifiers in the visibility bits, isolate the visibility bits
	int accessorBits = realModifiers & (ClassFileConstants.AccPublic | ClassFileConstants.AccProtected | ClassFileConstants.AccPrivate);
	if ((accessorBits & (accessorBits - 1)) != 0) {
		problemReporter().illegalVisibilityModifierCombinationForMethod(declaringClass, (AbstractMethodDeclaration) this.referenceContext);

		// need to keep the less restrictive so disable Protected/Private as necessary
		if ((accessorBits & ClassFileConstants.AccPublic) != 0) {
			if ((accessorBits & ClassFileConstants.AccProtected) != 0)
				modifiers &= ~ClassFileConstants.AccProtected;
			if ((accessorBits & ClassFileConstants.AccPrivate) != 0)
				modifiers &= ~ClassFileConstants.AccPrivate;
		} else if ((accessorBits & ClassFileConstants.AccProtected) != 0 && (accessorBits & ClassFileConstants.AccPrivate) != 0) {
			modifiers &= ~ClassFileConstants.AccPrivate;
		}
	}

//		// if the receiver's declaring class is a private nested type, then make sure the receiver is not private (causes problems for inner type emulation)
//		if (declaringClass.isPrivate() && (modifiers & ClassFileConstants.AccPrivate) != 0)
//			modifiers &= ~ClassFileConstants.AccPrivate;

	methodBinding.modifiers = modifiers;
}

/**
 * Spec : 8.4.3 & 9.4
 * TODO: Add the spec section number for private interface methods from jls 9
 */
private void checkAndSetModifiersForMethod(MethodBinding methodBinding) {
	int modifiers = methodBinding.modifiers;
	final ReferenceBinding declaringClass = methodBinding.declaringClass;
	if ((modifiers & ExtraCompilerModifiers.AccAlternateModifierProblem) != 0)
		problemReporter().duplicateModifierForMethod(declaringClass, (AbstractMethodDeclaration) this.referenceContext);

	// after this point, tests on the 16 bits reserved.
	int realModifiers = modifiers & ExtraCompilerModifiers.AccJustFlag;
	long sourceLevel = compilerOptions().sourceLevel;
	// set the requested modifiers for a method in an interface/annotation
	if (declaringClass.isInterface()) {
		int expectedModifiers = ClassFileConstants.AccPublic | ClassFileConstants.AccAbstract;
		boolean isDefaultMethod = (modifiers & ExtraCompilerModifiers.AccDefaultMethod) != 0; // no need to check validity, is done by the parser
		boolean reportIllegalModifierCombination = false;
		if (sourceLevel >= ClassFileConstants.JDK1_8 && !declaringClass.isAnnotationType()) {
			expectedModifiers |= ClassFileConstants.AccStrictfp
					| ExtraCompilerModifiers.AccDefaultMethod | ClassFileConstants.AccStatic;
			expectedModifiers |= sourceLevel >= ClassFileConstants.JDK9 ? ClassFileConstants.AccPrivate : 0;
			if (!methodBinding.isAbstract()) {
				reportIllegalModifierCombination = isDefaultMethod && methodBinding.isStatic();
			} else {
				reportIllegalModifierCombination = isDefaultMethod || methodBinding.isStatic();
				if (methodBinding.isStrictfp()) {
					problemReporter().illegalAbstractModifierCombinationForMethod((AbstractMethodDeclaration) this.referenceContext);
				}
			}
			if (reportIllegalModifierCombination) {
				problemReporter().illegalModifierCombinationForInterfaceMethod((AbstractMethodDeclaration) this.referenceContext);
			}
			if (sourceLevel >= ClassFileConstants.JDK9 && (methodBinding.modifiers & ClassFileConstants.AccPrivate) != 0) {
				int remaining = realModifiers & ~expectedModifiers;
				if (remaining == 0) { // check for the combination of allowed modifiers with private
					remaining = realModifiers & ~(ClassFileConstants.AccPrivate | ClassFileConstants.AccStatic | ClassFileConstants.AccStrictfp);
					if (isDefaultMethod || remaining != 0)
						problemReporter().illegalModifierCombinationForPrivateInterfaceMethod((AbstractMethodDeclaration) this.referenceContext);
				}
			}
			// Kludge - The AccDefaultMethod bit is outside the lower 16 bits and got removed earlier. Putting it back.
			if (isDefaultMethod) {
				realModifiers |= ExtraCompilerModifiers.AccDefaultMethod;
			}
		}
		if ((realModifiers & ~expectedModifiers) != 0) {
			if ((declaringClass.modifiers & ClassFileConstants.AccAnnotation) != 0)
				problemReporter().illegalModifierForAnnotationMember((AbstractMethodDeclaration) this.referenceContext);
			else
				problemReporter().illegalModifierForInterfaceMethod((AbstractMethodDeclaration) this.referenceContext, sourceLevel);
			methodBinding.modifiers &= (expectedModifiers | ~ExtraCompilerModifiers.AccJustFlag);
		}
		return;
	} else if (declaringClass.isAnonymousType() && sourceLevel >= ClassFileConstants.JDK9) {
		// If the class instance creation expression elides the supertype's type arguments using '<>',
		// then for all non-private methods declared in the class body, it is as if the method declaration
		// is annotated with @Override - https://bugs.openjdk.java.net/browse/JDK-8073593
		LocalTypeBinding local = (LocalTypeBinding) declaringClass;
		TypeReference ref = local.scope.referenceContext.allocation.type;
		if (ref != null && (ref.bits & ASTNode.IsDiamond) != 0) {
			//
			if ((realModifiers & (ClassFileConstants.AccPrivate | ClassFileConstants.AccStatic )) == 0) {
				methodBinding.tagBits |= TagBits.AnnotationOverride;
			}
		}
	}

	// check for abnormal modifiers
	final int UNEXPECTED_MODIFIERS = ~(ClassFileConstants.AccPublic | ClassFileConstants.AccPrivate | ClassFileConstants.AccProtected
		| ClassFileConstants.AccAbstract | ClassFileConstants.AccStatic | ClassFileConstants.AccFinal | ClassFileConstants.AccSynchronized | ClassFileConstants.AccNative | ClassFileConstants.AccStrictfp);
	if ((realModifiers & UNEXPECTED_MODIFIERS) != 0) {
		problemReporter().illegalModifierForMethod((AbstractMethodDeclaration) this.referenceContext);
		modifiers &= ~ExtraCompilerModifiers.AccJustFlag | ~UNEXPECTED_MODIFIERS;
	}

	// check for incompatible modifiers in the visibility bits, isolate the visibility bits
	int accessorBits = realModifiers & (ClassFileConstants.AccPublic | ClassFileConstants.AccProtected | ClassFileConstants.AccPrivate);
	if ((accessorBits & (accessorBits - 1)) != 0) {
		problemReporter().illegalVisibilityModifierCombinationForMethod(declaringClass, (AbstractMethodDeclaration) this.referenceContext);

		// need to keep the less restrictive so disable Protected/Private as necessary
		if ((accessorBits & ClassFileConstants.AccPublic) != 0) {
			if ((accessorBits & ClassFileConstants.AccProtected) != 0)
				modifiers &= ~ClassFileConstants.AccProtected;
			if ((accessorBits & ClassFileConstants.AccPrivate) != 0)
				modifiers &= ~ClassFileConstants.AccPrivate;
		} else if ((accessorBits & ClassFileConstants.AccProtected) != 0 && (accessorBits & ClassFileConstants.AccPrivate) != 0) {
			modifiers &= ~ClassFileConstants.AccPrivate;
		}
	}

	// check for modifiers incompatible with abstract modifier
	if ((modifiers & ClassFileConstants.AccAbstract) != 0) {
		int incompatibleWithAbstract = ClassFileConstants.AccPrivate | ClassFileConstants.AccStatic | ClassFileConstants.AccFinal | ClassFileConstants.AccSynchronized | ClassFileConstants.AccNative | ClassFileConstants.AccStrictfp;
		if ((modifiers & incompatibleWithAbstract) != 0)
			problemReporter().illegalAbstractModifierCombinationForMethod(declaringClass, (AbstractMethodDeclaration) this.referenceContext);
		if (!methodBinding.declaringClass.isAbstract())
			problemReporter().abstractMethodInAbstractClass((SourceTypeBinding) declaringClass, (AbstractMethodDeclaration) this.referenceContext);
	}

	/* DISABLED for backward compatibility with javac (if enabled should also mark private methods as final)
	// methods from a final class are final : 8.4.3.3
	if (methodBinding.declaringClass.isFinal())
		modifiers |= AccFinal;
	*/
	// native methods cannot also be tagged as strictfp
	if ((modifiers & ClassFileConstants.AccNative) != 0 && (modifiers & ClassFileConstants.AccStrictfp) != 0)
		problemReporter().nativeMethodsCannotBeStrictfp(declaringClass, (AbstractMethodDeclaration) this.referenceContext);

	// static members are only authorized in a static member or top level type
	if (sourceLevel < ClassFileConstants.JDK16) {
		if (((realModifiers & ClassFileConstants.AccStatic) != 0) && declaringClass.isNestedType() && !declaringClass.isStatic())
			problemReporter().unexpectedStaticModifierForMethod(declaringClass, (AbstractMethodDeclaration) this.referenceContext);
	}

	methodBinding.modifiers = modifiers;
}

public void checkUnusedParameters(MethodBinding method) {
	if (method.isAbstract()
			|| (method.isImplementing() && !compilerOptions().reportUnusedParameterWhenImplementingAbstract)
			|| (method.isOverriding() && !method.isImplementing() && !compilerOptions().reportUnusedParameterWhenOverridingConcrete)
			|| method.isMain()) {
		// do not want to check
		return;
	}
	for (int i = 0, maxLocals = this.localIndex; i < maxLocals; i++) {
		LocalVariableBinding local = this.locals[i];
		if (local == null || ((local.tagBits & TagBits.IsArgument) == 0)) {
			break; // done with arguments
		}
		if (local.useFlag == LocalVariableBinding.UNUSED &&
				// do not report fake used variable
				((local.declaration.bits & ASTNode.IsLocalDeclarationReachable) != 0)) { // declaration is reachable
			problemReporter().unusedArgument(local.declaration);
		}
	}
}

/**
 * Compute variable positions in scopes given an initial position offset
 * ignoring unused local variables.
 *
 * Deal with arguments here, locals and subscopes are processed in BlockScope method
 */
public void computeLocalVariablePositions(int initOffset, CodeStream codeStream) {
	this.offset = initOffset;
	this.maxOffset = initOffset;

	// manage arguments
	int ilocal = 0, maxLocals = this.localIndex;
	while (ilocal < maxLocals) {
		LocalVariableBinding local = this.locals[ilocal];
		if (local == null || ((local.tagBits & TagBits.IsArgument) == 0)) break; // done with arguments

		// record user-defined argument for attribute generation
		codeStream.record(local);

		// assign variable position
		local.resolvedPosition = this.offset;

		if ((TypeBinding.equalsEquals(local.type, TypeBinding.LONG)) || (TypeBinding.equalsEquals(local.type, TypeBinding.DOUBLE))) {
			this.offset += 2;
		} else {
			this.offset++;
		}
		// check for too many arguments/local variables
		if (this.offset > 0xFF) { // no more than 255 words of arguments
			problemReporter().noMoreAvailableSpaceForArgument(local, local.declaration);
		}
		ilocal++;
	}

	// sneak in extra argument before other local variables
	if (this.extraSyntheticArguments != null) {
		for (int iarg = 0, maxArguments = this.extraSyntheticArguments.length; iarg < maxArguments; iarg++){
			SyntheticArgumentBinding argument = this.extraSyntheticArguments[iarg];
			argument.resolvedPosition = this.offset;
			if ((TypeBinding.equalsEquals(argument.type, TypeBinding.LONG)) || (TypeBinding.equalsEquals(argument.type, TypeBinding.DOUBLE))){
				this.offset += 2;
			} else {
				this.offset++;
			}
			if (this.offset > 0xFF) { // no more than 255 words of arguments
				problemReporter().noMoreAvailableSpaceForArgument(argument, (ASTNode)this.referenceContext);
			}
		}
	}
	this.computeLocalVariablePositions(ilocal, this.offset, codeStream);
}

/**
 * Error management:
 * 		keep null for all the errors that prevent the method to be created
 * 		otherwise return a correct method binding (but without the element
 *		that caused the problem) : i.e. Incorrect thrown exception
 */
MethodBinding createMethod(AbstractMethodDeclaration method) {
	// is necessary to ensure error reporting
	this.referenceContext = method;
	method.scope = this;
	long sourceLevel = compilerOptions().sourceLevel;
	SourceTypeBinding declaringClass = referenceType().binding;
	int modifiers = method.modifiers | ExtraCompilerModifiers.AccUnresolved;
	if (method.isConstructor()) {
		if (method.isDefaultConstructor())
			modifiers |= ExtraCompilerModifiers.AccIsDefaultConstructor;
		method.binding = new MethodBinding(modifiers, null, null, declaringClass);
		checkAndSetModifiersForConstructor(method.binding);
	} else {
		if (declaringClass.isInterface()) {// interface or annotation type
			if (sourceLevel >= ClassFileConstants.JDK9 && ((method.modifiers & ClassFileConstants.AccPrivate) != 0)) { // private method
				// do nothing
			} else if (method.isDefaultMethod() || method.isStatic()) {
				modifiers |= ClassFileConstants.AccPublic; // default method is not abstract
			} else {
				modifiers |= ClassFileConstants.AccPublic | ClassFileConstants.AccAbstract;
			}
		}
		method.binding =
			new MethodBinding(modifiers, method.selector, null, null, null, declaringClass);
		checkAndSetModifiersForMethod(method.binding);
	}
	this.isStatic = method.binding.isStatic();

	Argument[] argTypes = method.arguments;
	int argLength = argTypes == null ? 0 : argTypes.length;
	if (argLength > 0) {
		Argument argument = argTypes[argLength - 1];
		method.binding.parameterNames = new char[argLength][];
		method.binding.parameterNames[--argLength] = argument.name;
		if (argument.isVarArgs() && sourceLevel >= ClassFileConstants.JDK1_5)
			method.binding.modifiers |= ClassFileConstants.AccVarargs;
		if (CharOperation.equals(argument.name, ConstantPool.This)) {
			problemReporter().illegalThisDeclaration(argument);
		}
		while (--argLength >= 0) {
			argument = argTypes[argLength];
			method.binding.parameterNames[argLength] = argument.name;
			if (argument.isVarArgs() && sourceLevel >= ClassFileConstants.JDK1_5)
				problemReporter().illegalVararg(argument, method);
			if (CharOperation.equals(argument.name, ConstantPool.This)) {
				problemReporter().illegalThisDeclaration(argument);
			}
		}
	}
	if (method.receiver != null) {
		if (sourceLevel <= ClassFileConstants.JDK1_7) {
			problemReporter().illegalSourceLevelForThis(method.receiver);
		}
		if (method.receiver.annotations != null) {
			method.bits |= ASTNode.HasTypeAnnotations;
		}
	}

	TypeParameter[] typeParameters = method.typeParameters();
	// https://bugs.eclipse.org/bugs/show_bug.cgi?id=324850, If they exist at all, process type parameters irrespective of source level.
	if (typeParameters == null || typeParameters.length == 0) {
		method.binding.typeVariables = Binding.NO_TYPE_VARIABLES;
	} else {
		method.binding.typeVariables = createTypeVariables(typeParameters, method.binding);
		method.binding.modifiers |= ExtraCompilerModifiers.AccGenericSignature;
	}
    checkAndSetRecordCanonicalConsAndMethods(method);
	return method.binding;
}
private void checkAndSetRecordCanonicalConsAndMethods(AbstractMethodDeclaration am) {
	if (am.binding != null && (am.bits & ASTNode.IsImplicit) != 0) {
		am.binding.extendedTagBits |= ExtendedTagBits.isImplicit;
		if ((am.bits & ASTNode.IsCanonicalConstructor) != 0)
			am.binding.extendedTagBits |= ExtendedTagBits.IsCanonicalConstructor;
	}
}

/**
 * Overridden to detect the error case inside an explicit constructor call:
class X {
	int i;
	X myX;
	X(X x) {
		this(i, myX.i, x.i); // same for super calls... only the first 2 field accesses are errors
	}
}
 */
@Override
public FieldBinding findField(TypeBinding receiverType, char[] fieldName, InvocationSite invocationSite, boolean needResolve) {

	FieldBinding field = super.findField(receiverType, fieldName, invocationSite, needResolve);
	if (field == null)
		return null;
	if (!field.isValidBinding())
		return field; // answer the error field

	if (receiverType.isInterface() && invocationSite.isQualifiedSuper())
		return new ProblemFieldBinding(
				field, // closest match
				field.declaringClass,
				fieldName,
				ProblemReasons.NoProperEnclosingInstance);

	if (field.isStatic())
		return field; // static fields are always accessible

	if (!this.isConstructorCall || TypeBinding.notEquals(receiverType, enclosingSourceType()))
		return field;

	if (invocationSite instanceof SingleNameReference)
		return new ProblemFieldBinding(
			field, // closest match
			field.declaringClass,
			fieldName,
			ProblemReasons.NonStaticReferenceInConstructorInvocation);
	if (invocationSite instanceof QualifiedNameReference) {
		// look to see if the field is the first binding
		QualifiedNameReference name = (QualifiedNameReference) invocationSite;
		if (name.binding == null)
			// only true when the field is the fieldbinding at the beginning of name's tokens
			return new ProblemFieldBinding(
				field, // closest match
				field.declaringClass,
				fieldName,
				ProblemReasons.NonStaticReferenceInConstructorInvocation);
	}
	return field;
}

protected Object[] getSyntheticEnclosingArgumentOfLambda(ReferenceBinding targetEnclosingType) {
	SyntheticArgumentBinding sa = null;
	if (this.isConstructorCall && this.referenceContext instanceof LambdaExpression) {
		Map stbToSynthetic = ((LambdaExpression) this.referenceContext).mapSyntheticEnclosingTypes;
		if (stbToSynthetic != null)
			sa = stbToSynthetic.get(targetEnclosingType);
	}
	return sa != null ? new Object[] {sa} : null;
}

public boolean isInsideConstructor() {
	return (this.referenceContext instanceof ConstructorDeclaration);
}

public boolean isInsideInitializer() {
	return (this.referenceContext instanceof TypeDeclaration);
}

@Override
public boolean isLambdaScope() {
	return this.referenceContext instanceof LambdaExpression;
}

public boolean isInsideInitializerOrConstructor() {
	return (this.referenceContext instanceof TypeDeclaration)
		|| (this.referenceContext instanceof ConstructorDeclaration);
}

/**
 * Answer the problem reporter to use for raising new problems.
 *
 * Note that as a side-effect, this updates the current reference context
 * (unit, type or method) in case the problem handler decides it is necessary
 * to abort.
 */
@Override
public ProblemReporter problemReporter() {
	ProblemReporter problemReporter = referenceCompilationUnit().problemReporter;
	problemReporter.referenceContext = this.referenceContext;
	return problemReporter;
}

public final int recordInitializationStates(FlowInfo flowInfo) {
	if ((flowInfo.tagBits & FlowInfo.UNREACHABLE_OR_DEAD) != 0) return -1;
	UnconditionalFlowInfo unconditionalFlowInfo = flowInfo.unconditionalInitsWithoutSideEffect();
	long[] extraInits = unconditionalFlowInfo.extra == null ?
			null : unconditionalFlowInfo.extra[0];
	long inits = unconditionalFlowInfo.definiteInits;
	checkNextEntry : for (int i = this.lastIndex; --i >= 0;) {
		if (this.definiteInits[i] == inits) {
			long[] otherInits = this.extraDefiniteInits[i];
			if ((extraInits != null) && (otherInits != null)) {
				if (extraInits.length == otherInits.length) {
					int j, max;
					for (j = 0, max = extraInits.length; j < max; j++) {
						if (extraInits[j] != otherInits[j]) {
							continue checkNextEntry;
						}
					}
					return i;
				}
			} else {
				if ((extraInits == null) && (otherInits == null)) {
					return i;
				}
			}
		}
	}

	// add a new entry
	if (this.definiteInits.length == this.lastIndex) {
		// need a resize
		System.arraycopy(
			this.definiteInits,
			0,
			(this.definiteInits = new long[this.lastIndex + 20]),
			0,
			this.lastIndex);
		System.arraycopy(
			this.extraDefiniteInits,
			0,
			(this.extraDefiniteInits = new long[this.lastIndex + 20][]),
			0,
			this.lastIndex);
	}
	this.definiteInits[this.lastIndex] = inits;
	if (extraInits != null) {
		this.extraDefiniteInits[this.lastIndex] = new long[extraInits.length];
		System.arraycopy(
			extraInits,
			0,
			this.extraDefiniteInits[this.lastIndex],
			0,
			extraInits.length);
	}
	return this.lastIndex++;
}

/**
 *  Answer the reference method of this scope, or null if initialization scope or lambda scope.
 */
public AbstractMethodDeclaration referenceMethod() {
	if (this.referenceContext instanceof AbstractMethodDeclaration) return (AbstractMethodDeclaration) this.referenceContext;
	return null;
}

/**
 * Answers the binding of the reference method or reference lambda expression.
 */
public MethodBinding referenceMethodBinding() {
	if (this.referenceContext instanceof LambdaExpression)
		return ((LambdaExpression)this.referenceContext).binding;
	if (this.referenceContext instanceof AbstractMethodDeclaration)
		return ((AbstractMethodDeclaration)this.referenceContext).binding;
	return null;
}

/**
 *  Answer the reference type of this scope.
 * It is the nearest enclosing type of this scope.
 */
@Override
public TypeDeclaration referenceType() {
	ClassScope scope = enclosingClassScope();
	return scope == null ? null : scope.referenceContext;
}

@Override
void resolveTypeParameter(TypeParameter typeParameter) {
	typeParameter.resolve(this);
}
@Override
public boolean hasDefaultNullnessFor(int location, int sourceStart) {
	int nonNullByDefaultValue = localNonNullByDefaultValue(sourceStart);
	if(nonNullByDefaultValue != 0) {
		return (nonNullByDefaultValue & location) != 0;
	}
	AbstractMethodDeclaration referenceMethod = referenceMethod();
	if (referenceMethod != null) {
		MethodBinding binding = referenceMethod.binding;
		if (binding != null && binding.defaultNullness != 0) {
			return (binding.defaultNullness & location) != 0;
		}
	}
	return this.parent.hasDefaultNullnessFor(location, sourceStart);
}
@Override
public Binding checkRedundantDefaultNullness(int nullBits, int sourceStart) {
	Binding target = localCheckRedundantDefaultNullness(nullBits, sourceStart);
	if (target != null) {
		return target;
	}
	AbstractMethodDeclaration referenceMethod = referenceMethod();
	if (referenceMethod != null) {
		MethodBinding binding = referenceMethod.binding;
		if (binding != null && binding.defaultNullness != 0) {
			return (binding.defaultNullness == nullBits) ? binding : null;
		}
	}
	return this.parent.checkRedundantDefaultNullness(nullBits, sourceStart);
}
public boolean shouldCheckAPILeaks(ReferenceBinding declaringClass, boolean memberIsPublic) {
	if (environment().useModuleSystem)
		return memberIsPublic && declaringClass.isPublic() && declaringClass.fPackage.isExported();
	return false;
}
public void detectAPILeaks(ASTNode typeNode, TypeBinding type) {
	if (environment().useModuleSystem) {
		// NB: using an ASTVisitor yields more precise locations than a TypeBindingVisitor would
		ASTVisitor visitor = new ASTVisitor() {
			@Override
			public boolean visit(SingleTypeReference typeReference, BlockScope scope) {
				if (typeReference.resolvedType instanceof ReferenceBinding)
					checkType((ReferenceBinding) typeReference.resolvedType, typeReference.sourceStart, typeReference.sourceEnd);
				return true;
			}
			@Override
			public boolean visit(QualifiedTypeReference typeReference, BlockScope scope) {
				if (typeReference.resolvedType instanceof ReferenceBinding)
					checkType((ReferenceBinding) typeReference.resolvedType, typeReference.sourceStart, typeReference.sourceEnd);
				return true;
			}
			@Override
			public boolean visit(ArrayTypeReference typeReference, BlockScope scope) {
				TypeBinding leafComponentType = typeReference.resolvedType.leafComponentType();
				if (leafComponentType instanceof ReferenceBinding)
					checkType((ReferenceBinding) leafComponentType, typeReference.sourceStart, typeReference.originalSourceEnd);
				return true;
			}
			private void checkType(ReferenceBinding referenceBinding, int sourceStart, int sourceEnd) {
				if (!referenceBinding.isValidBinding())
					return;
				ModuleBinding otherModule = referenceBinding.module();
				if (otherModule == otherModule.environment.javaBaseModule())
					return; // always accessible
				if (!isFullyPublic(referenceBinding)) {
					problemReporter().nonPublicTypeInAPI(referenceBinding, sourceStart, sourceEnd);
				} else if (!referenceBinding.fPackage.isExported()) {
					problemReporter().notExportedTypeInAPI(referenceBinding, sourceStart, sourceEnd);
				} else if (isUnrelatedModule(referenceBinding.fPackage)) {
					problemReporter().missingRequiresTransitiveForTypeInAPI(referenceBinding, sourceStart, sourceEnd);
				}
			}
			private boolean isFullyPublic(ReferenceBinding referenceBinding) {
				if (!referenceBinding.isPublic())
					return false;
				if (referenceBinding instanceof NestedTypeBinding)
					return isFullyPublic(((NestedTypeBinding) referenceBinding).enclosingType);
				return true;
			}
			private boolean isUnrelatedModule(PackageBinding fPackage) {
				ModuleBinding otherModule = fPackage.enclosingModule;
				ModuleBinding thisModule = module();
				if (thisModule != otherModule) {
					return !thisModule.isTransitivelyRequired(otherModule);
				}
				return false;
			}
		};
		typeNode.traverse(visitor, this);
	}
}
}




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