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/*******************************************************************************
 * Copyright (c) 2000, 2009 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
 *******************************************************************************/
package org.eclipse.jdt.internal.compiler.lookup;

import org.eclipse.jdt.internal.compiler.ast.MessageSend;

/**
 * Binding denoting a generic method after type parameter substitutions got performed.
 * On parameterized type bindings, all methods got substituted, regardless whether
 * their signature did involve generics or not, so as to get the proper declaringClass for
 * these methods.
 */
public class ParameterizedGenericMethodBinding extends ParameterizedMethodBinding implements Substitution {

    public TypeBinding[] typeArguments;
    private LookupEnvironment environment;
    public boolean inferredReturnType;
    public boolean wasInferred; // only set to true for instances resulting from method invocation inferrence
    public boolean isRaw; // set to true for method behaving as raw for substitution purpose
    private MethodBinding tiebreakMethod;

	/**
	 * Perform inference of generic method type parameters and/or expected type
	 */
	public static MethodBinding computeCompatibleMethod(MethodBinding originalMethod, TypeBinding[] arguments, Scope scope, InvocationSite invocationSite) {
		ParameterizedGenericMethodBinding methodSubstitute;
		TypeVariableBinding[] typeVariables = originalMethod.typeVariables;
		TypeBinding[] substitutes = invocationSite.genericTypeArguments();
		TypeBinding[] uncheckedArguments = null;
		computeSubstitutes: {
			if (substitutes != null) {
				// explicit type arguments got supplied
				if (substitutes.length != typeVariables.length) {
			        // incompatible due to wrong arity
			        return new ProblemMethodBinding(originalMethod, originalMethod.selector, substitutes, ProblemReasons.TypeParameterArityMismatch);
				}
				methodSubstitute = scope.environment().createParameterizedGenericMethod(originalMethod, substitutes);
				break computeSubstitutes;
			}
			// perform type argument inference (15.12.2.7)
			// initializes the map of substitutes (var --> type[][]{ equal, extends, super}
			TypeBinding[] parameters = originalMethod.parameters;
			InferenceContext inferenceContext = new InferenceContext(originalMethod);
			methodSubstitute = inferFromArgumentTypes(scope, originalMethod, arguments, parameters, inferenceContext);
			if (methodSubstitute == null)
				return null;
			
			// substitutes may hold null to denote unresolved vars, but null arguments got replaced with respective original variable in param method
			// 15.12.2.8 - inferring unresolved type arguments
			if (inferenceContext.hasUnresolvedTypeArgument()) {
				if (inferenceContext.isUnchecked) { // only remember unchecked status post 15.12.2.7
					int length = inferenceContext.substitutes.length;
					System.arraycopy(inferenceContext.substitutes, 0, uncheckedArguments = new TypeBinding[length], 0, length);
				}
				if (methodSubstitute.returnType != TypeBinding.VOID) {
					TypeBinding expectedType = null;
					// if message invocation has expected type
					if (invocationSite instanceof MessageSend) {
						MessageSend message = (MessageSend) invocationSite;
						expectedType = message.expectedType;
					}
					if (expectedType != null) {
						// record it was explicit from context, as opposed to assumed by default (see below)
						inferenceContext.hasExplicitExpectedType = true;
					} else {
						expectedType = scope.getJavaLangObject(); // assume Object by default
					}
					inferenceContext.expectedType = expectedType;
				}
				methodSubstitute = methodSubstitute.inferFromExpectedType(scope, inferenceContext);
				if (methodSubstitute == null)
					return null;
			}
		}

		// bounds check
		for (int i = 0, length = typeVariables.length; i < length; i++) {
		    TypeVariableBinding typeVariable = typeVariables[i];
		    TypeBinding substitute = methodSubstitute.typeArguments[i];
		    if (uncheckedArguments != null && uncheckedArguments[i] == null) continue; // only bound check if inferred through 15.12.2.6
			switch (typeVariable.boundCheck(methodSubstitute, substitute)) {
				case TypeConstants.MISMATCH :
			        // incompatible due to bound check
					int argLength = arguments.length;
					TypeBinding[] augmentedArguments = new TypeBinding[argLength + 2]; // append offending substitute and typeVariable
					System.arraycopy(arguments, 0, augmentedArguments, 0, argLength);
					augmentedArguments[argLength] = substitute;
					augmentedArguments[argLength+1] = typeVariable;
			        return new ProblemMethodBinding(methodSubstitute, originalMethod.selector, augmentedArguments, ProblemReasons.ParameterBoundMismatch);
				case TypeConstants.UNCHECKED :
					// tolerate unchecked bounds
					methodSubstitute.tagBits |= TagBits.HasUncheckedTypeArgumentForBoundCheck;
					break;
			}
		}
		// check presence of unchecked argument conversion a posteriori (15.12.2.6)
		return methodSubstitute;
	}

	/**
	 * Collect argument type mapping, handling varargs
	 */
	private static ParameterizedGenericMethodBinding inferFromArgumentTypes(Scope scope, MethodBinding originalMethod, TypeBinding[] arguments, TypeBinding[] parameters, InferenceContext inferenceContext) {
		if (originalMethod.isVarargs()) {
			int paramLength = parameters.length;
			int minArgLength = paramLength - 1;
			int argLength = arguments.length;
			// process mandatory arguments
			for (int i = 0; i < minArgLength; i++) {
				parameters[i].collectSubstitutes(scope, arguments[i], inferenceContext, TypeConstants.CONSTRAINT_EXTENDS);
				if (inferenceContext.status == InferenceContext.FAILED) return null; // impossible substitution
			}
			// process optional arguments
			if (minArgLength < argLength) {
				TypeBinding varargType = parameters[minArgLength]; // last arg type - as is ?
				TypeBinding lastArgument = arguments[minArgLength];
				checkVarargDimension: {
					if (paramLength == argLength) {
						if (lastArgument == TypeBinding.NULL) break checkVarargDimension;
						switch (lastArgument.dimensions()) {
							case 0 :
								break; // will remove one dim
							case 1 :
								if (!lastArgument.leafComponentType().isBaseType()) break checkVarargDimension;
								break; // will remove one dim
							default :
								break checkVarargDimension;
						}
					}
					// eliminate one array dimension
					varargType = ((ArrayBinding)varargType).elementsType();
				}
				for (int i = minArgLength; i < argLength; i++) {
					varargType.collectSubstitutes(scope, arguments[i], inferenceContext, TypeConstants.CONSTRAINT_EXTENDS);
					if (inferenceContext.status == InferenceContext.FAILED) return null; // impossible substitution
				}
			}
		} else {
			int paramLength = parameters.length;
			for (int i = 0; i < paramLength; i++) {
				parameters[i].collectSubstitutes(scope, arguments[i], inferenceContext, TypeConstants.CONSTRAINT_EXTENDS);
				if (inferenceContext.status == InferenceContext.FAILED) return null; // impossible substitution
			}
		}
		TypeVariableBinding[] originalVariables = originalMethod.typeVariables;
		if (!resolveSubstituteConstraints(scope, originalVariables , inferenceContext, false/*ignore Ti<:Uk*/))
			return null; // impossible substitution

		// apply inferred variable substitutions - replacing unresolved variable with original ones in param method
		TypeBinding[] inferredSustitutes = inferenceContext.substitutes;
		TypeBinding[] actualSubstitutes = inferredSustitutes;
		for (int i = 0, varLength = originalVariables.length; i < varLength; i++) {
			if (inferredSustitutes[i] == null) {
				if (actualSubstitutes == inferredSustitutes) {
					System.arraycopy(inferredSustitutes, 0, actualSubstitutes = new TypeBinding[varLength], 0, i); // clone to replace null with original variable in param method
				}
				actualSubstitutes[i] = originalVariables[i];
			} else if (actualSubstitutes != inferredSustitutes) {
				actualSubstitutes[i] = inferredSustitutes[i];
			}
		}
		ParameterizedGenericMethodBinding paramMethod = scope.environment().createParameterizedGenericMethod(originalMethod, actualSubstitutes);
		return paramMethod;
	}

	private static boolean resolveSubstituteConstraints(Scope scope, TypeVariableBinding[] typeVariables, InferenceContext inferenceContext, boolean considerEXTENDSConstraints) {
		TypeBinding[] substitutes = inferenceContext.substitutes;
		int varLength = typeVariables.length;
		// check Tj=U constraints
		nextTypeParameter:
			for (int i = 0; i < varLength; i++) {
				TypeVariableBinding current = typeVariables[i];
				TypeBinding substitute = substitutes[i];
				if (substitute != null) continue nextTypeParameter; // already inferred previously
				TypeBinding [] equalSubstitutes = inferenceContext.getSubstitutes(current, TypeConstants.CONSTRAINT_EQUAL);
				if (equalSubstitutes != null) {
					nextConstraint:
						for (int j = 0, equalLength = equalSubstitutes.length; j < equalLength; j++) {
							TypeBinding equalSubstitute = equalSubstitutes[j];
							if (equalSubstitute == null) continue nextConstraint;
							if (equalSubstitute == current) {
								// try to find a better different match if any in subsequent equal candidates
								for (int k = j+1; k < equalLength; k++) {
									equalSubstitute = equalSubstitutes[k];
									if (equalSubstitute != current && equalSubstitute != null) {
										substitutes[i] = equalSubstitute;
										continue nextTypeParameter;
									}
								}
								substitutes[i] = current;
								continue nextTypeParameter;
							}
//							if (equalSubstitute.isTypeVariable()) {
//								TypeVariableBinding variable = (TypeVariableBinding) equalSubstitute;
//								// substituted by a variable of the same method, ignore
//								if (variable.rank < varLength && typeVariables[variable.rank] == variable) {
//									// TODO (philippe) rewrite all other constraints to use current instead.
//									continue nextConstraint;
//								}
//							}
							substitutes[i] = equalSubstitute;
							continue nextTypeParameter; // pick first match, applicability check will rule out invalid scenario where others were present
						}
				}
			}
		if (inferenceContext.hasUnresolvedTypeArgument()) {
			// check Tj>:U constraints
			nextTypeParameter:
				for (int i = 0; i < varLength; i++) {
					TypeVariableBinding current = typeVariables[i];
					TypeBinding substitute = substitutes[i];
					if (substitute != null) continue nextTypeParameter; // already inferred previously
					TypeBinding [] bounds = inferenceContext.getSubstitutes(current, TypeConstants.CONSTRAINT_SUPER);
					if (bounds == null) continue nextTypeParameter;
					TypeBinding mostSpecificSubstitute = scope.lowerUpperBound(bounds);
					if (mostSpecificSubstitute == null) {
						return false; // incompatible
					}
					if (mostSpecificSubstitute != TypeBinding.VOID) {
						substitutes[i] = mostSpecificSubstitute;
					}
				}
		}
		if (considerEXTENDSConstraints && inferenceContext.hasUnresolvedTypeArgument()) {
			// check Tj<:U constraints
			nextTypeParameter:
				for (int i = 0; i < varLength; i++) {
					TypeVariableBinding current = typeVariables[i];
					TypeBinding substitute = substitutes[i];
					if (substitute != null) continue nextTypeParameter; // already inferred previously
					TypeBinding [] bounds = inferenceContext.getSubstitutes(current, TypeConstants.CONSTRAINT_EXTENDS);
					if (bounds == null) continue nextTypeParameter;
					TypeBinding[] glb = Scope.greaterLowerBound(bounds);
					TypeBinding mostSpecificSubstitute = null;
					if (glb != null) mostSpecificSubstitute = glb[0]; // TODO (philippe) need to improve
						//TypeBinding mostSpecificSubstitute = scope.greaterLowerBound(bounds);
						if (mostSpecificSubstitute != null) {
							substitutes[i] = mostSpecificSubstitute;
						}
					}
		}
		return true;
	}

	/**
	 * Create raw generic method for raw type (double substitution from type vars with raw type arguments, and erasure of method variables)
	 * Only invoked for non-static generic methods of raw type
	 */
	public ParameterizedGenericMethodBinding(MethodBinding originalMethod, RawTypeBinding rawType, LookupEnvironment environment) {
		TypeVariableBinding[] originalVariables = originalMethod.typeVariables;
		int length = originalVariables.length;
		TypeBinding[] rawArguments = new TypeBinding[length];
		for (int i = 0; i < length; i++) {
			rawArguments[i] =  environment.convertToRawType(originalVariables[i].erasure(), false /*do not force conversion of enclosing types*/);
		}
	    this.isRaw = true;
	    this.tagBits = originalMethod.tagBits;
	    this.environment = environment;
		this.modifiers = originalMethod.modifiers;
		this.selector = originalMethod.selector;
		this.declaringClass = rawType == null ? originalMethod.declaringClass : rawType;
	    this.typeVariables = Binding.NO_TYPE_VARIABLES;
	    this.typeArguments = rawArguments;
	    this.originalMethod = originalMethod;
		boolean ignoreRawTypeSubstitution = rawType == null || originalMethod.isStatic();
	    this.parameters = Scope.substitute(this, ignoreRawTypeSubstitution
	    									? originalMethod.parameters // no substitution if original was static
	    									: Scope.substitute(rawType, originalMethod.parameters));
	    this.thrownExceptions = Scope.substitute(this, 	ignoreRawTypeSubstitution
	    									? originalMethod.thrownExceptions // no substitution if original was static
	    									: Scope.substitute(rawType, originalMethod.thrownExceptions));
	    // error case where exception type variable would have been substituted by a non-reference type (207573)
	    if (this.thrownExceptions == null) this.thrownExceptions = Binding.NO_EXCEPTIONS;
	    this.returnType = Scope.substitute(this, ignoreRawTypeSubstitution
	    									? originalMethod.returnType // no substitution if original was static
	    									: Scope.substitute(rawType, originalMethod.returnType));
	    this.wasInferred = false; // not resulting from method invocation inferrence
	}

    /**
     * Create method of parameterized type, substituting original parameters with type arguments.
     */
	public ParameterizedGenericMethodBinding(MethodBinding originalMethod, TypeBinding[] typeArguments, LookupEnvironment environment) {
	    this.environment = environment;
		this.modifiers = originalMethod.modifiers;
		this.selector = originalMethod.selector;
		this.declaringClass = originalMethod.declaringClass;
	    this.typeVariables = Binding.NO_TYPE_VARIABLES;
	    this.typeArguments = typeArguments;
	    this.isRaw = false;
	    this.tagBits = originalMethod.tagBits;
	    this.originalMethod = originalMethod;
	    this.parameters = Scope.substitute(this, originalMethod.parameters);
	    // error case where exception type variable would have been substituted by a non-reference type (207573)
	    this.returnType = Scope.substitute(this, originalMethod.returnType);
	    this.thrownExceptions = Scope.substitute(this, originalMethod.thrownExceptions);
	    if (this.thrownExceptions == null) this.thrownExceptions = Binding.NO_EXCEPTIONS;
		checkMissingType: {
			if ((this.tagBits & TagBits.HasMissingType) != 0)
				break checkMissingType;
			if ((this.returnType.tagBits & TagBits.HasMissingType) != 0) {
				this.tagBits |=  TagBits.HasMissingType;
				break checkMissingType;
			}
			for (int i = 0, max = this.parameters.length; i < max; i++) {
				if ((this.parameters[i].tagBits & TagBits.HasMissingType) != 0) {
					this.tagBits |=  TagBits.HasMissingType;
					break checkMissingType;
				}
			}
			for (int i = 0, max = this.thrownExceptions.length; i < max; i++) {
				if ((this.thrownExceptions[i].tagBits & TagBits.HasMissingType) != 0) {
					this.tagBits |=  TagBits.HasMissingType;
					break checkMissingType;
				}
			}
		}
	    this.wasInferred = true;// resulting from method invocation inferrence
	}

	/*
	 * parameterizedDeclaringUniqueKey dot selector originalMethodGenericSignature percent typeArguments
	 * p.X {  void bar(T t, U u) { new X().bar(this, "") } } --> Lp/X;.bar(TT;Ljava/lang/String;)V%
	 */
	public char[] computeUniqueKey(boolean isLeaf) {
		StringBuffer buffer = new StringBuffer();
		buffer.append(this.originalMethod.computeUniqueKey(false/*not a leaf*/));
		buffer.append('%');
		buffer.append('<');
		if (!this.isRaw) {
			int length = this.typeArguments.length;
			for (int i = 0; i < length; i++) {
				TypeBinding typeArgument = this.typeArguments[i];
				buffer.append(typeArgument.computeUniqueKey(false/*not a leaf*/));
			}
		}
		buffer.append('>');
		int resultLength = buffer.length();
		char[] result = new char[resultLength];
		buffer.getChars(0, resultLength, result, 0);
		return result;
	}

	/**
	 * @see org.eclipse.jdt.internal.compiler.lookup.Substitution#environment()
	 */
	public LookupEnvironment environment() {
		return this.environment;
	}
	/**
	 * Returns true if some parameters got substituted.
	 * NOTE: generic method invocation delegates to its declaring method (could be a parameterized one)
	 */
	public boolean hasSubstitutedParameters() {
		// generic parameterized method can represent either an invocation or a raw generic method
		if (this.wasInferred)
			return this.originalMethod.hasSubstitutedParameters();
		return super.hasSubstitutedParameters();
	}
	/**
	 * Returns true if the return type got substituted.
	 * NOTE: generic method invocation delegates to its declaring method (could be a parameterized one)
	 */
	public boolean hasSubstitutedReturnType() {
		if (this.inferredReturnType)
			return this.originalMethod.hasSubstitutedReturnType();
		return super.hasSubstitutedReturnType();
	}
	/**
	 * Given some type expectation, and type variable bounds, perform some inference.
	 * Returns true if still had unresolved type variable at the end of the operation
	 */
	private ParameterizedGenericMethodBinding inferFromExpectedType(Scope scope, InferenceContext inferenceContext) {
	    TypeVariableBinding[] originalVariables = this.originalMethod.typeVariables; // immediate parent (could be a parameterized method)
		int varLength = originalVariables.length;
	    // infer from expected return type
		if (inferenceContext.expectedType != null) {
		    this.returnType.collectSubstitutes(scope, inferenceContext.expectedType, inferenceContext, TypeConstants.CONSTRAINT_SUPER);
		    if (inferenceContext.status == InferenceContext.FAILED) return null; // impossible substitution
		}
	    // infer from bounds of type parameters
		for (int i = 0; i < varLength; i++) {
			TypeVariableBinding originalVariable = originalVariables[i];
			TypeBinding argument = this.typeArguments[i];
			boolean argAlreadyInferred = argument != originalVariable;
			if (originalVariable.firstBound == originalVariable.superclass) {
				TypeBinding substitutedBound = Scope.substitute(this, originalVariable.superclass);
				argument.collectSubstitutes(scope, substitutedBound, inferenceContext, TypeConstants.CONSTRAINT_SUPER);
				if (inferenceContext.status == InferenceContext.FAILED) return null; // impossible substitution
				// JLS 15.12.2.8 claims reverse inference shouldn't occur, however it improves inference
				// e.g. given: > S test1(S param)
				//                   invocation: test1(new Vector())    will infer: S=Vector  and with code below: E=String
				if (argAlreadyInferred) {
					substitutedBound.collectSubstitutes(scope, argument, inferenceContext, TypeConstants.CONSTRAINT_EXTENDS);
					if (inferenceContext.status == InferenceContext.FAILED) return null; // impossible substitution
				}
			}
			for (int j = 0, max = originalVariable.superInterfaces.length; j < max; j++) {
				TypeBinding substitutedBound = Scope.substitute(this, originalVariable.superInterfaces[j]);
				argument.collectSubstitutes(scope, substitutedBound, inferenceContext, TypeConstants.CONSTRAINT_SUPER);
				if (inferenceContext.status == InferenceContext.FAILED) return null; // impossible substitution
				// JLS 15.12.2.8 claims reverse inference shouldn't occur, however it improves inference
				if (argAlreadyInferred) {
					substitutedBound.collectSubstitutes(scope, argument, inferenceContext, TypeConstants.CONSTRAINT_EXTENDS);
					if (inferenceContext.status == InferenceContext.FAILED) return null; // impossible substitution
				}
			}
		}
		if (!resolveSubstituteConstraints(scope, originalVariables, inferenceContext, true/*consider Ti<:Uk*/))
			return null; // incompatible
		// this.typeArguments = substitutes; - no op since side effects got performed during #resolveSubstituteConstraints
    	for (int i = 0; i < varLength; i++) {
    		TypeBinding substitute = inferenceContext.substitutes[i];
    		if (substitute != null) {
    			this.typeArguments[i] = inferenceContext.substitutes[i];
    		} else {
    			// remaining unresolved variable are considered to be Object (or their bound actually)
	    		this.typeArguments[i] = originalVariables[i].upperBound();
	    	}
    	}
		// may still need an extra substitution at the end (see https://bugs.eclipse.org/bugs/show_bug.cgi?id=121369)
		// to properly substitute a remaining unresolved variable which also appear in a formal bound
    	this.typeArguments = Scope.substitute(this, this.typeArguments);

    	// adjust method types to reflect latest inference
		TypeBinding oldReturnType = this.returnType;
		this.returnType = Scope.substitute(this, this.returnType);
		this.inferredReturnType = inferenceContext.hasExplicitExpectedType && this.returnType != oldReturnType;
	    this.parameters = Scope.substitute(this, this.parameters);
	    this.thrownExceptions = Scope.substitute(this, this.thrownExceptions);
	    // error case where exception type variable would have been substituted by a non-reference type (207573)
	    if (this.thrownExceptions == null) this.thrownExceptions = Binding.NO_EXCEPTIONS;
		checkMissingType: {
			if ((this.tagBits & TagBits.HasMissingType) != 0)
				break checkMissingType;
			if ((this.returnType.tagBits & TagBits.HasMissingType) != 0) {
				this.tagBits |=  TagBits.HasMissingType;
				break checkMissingType;
			}
			for (int i = 0, max = this.parameters.length; i < max; i++) {
				if ((this.parameters[i].tagBits & TagBits.HasMissingType) != 0) {
					this.tagBits |=  TagBits.HasMissingType;
					break checkMissingType;
				}
			}
			for (int i = 0, max = this.thrownExceptions.length; i < max; i++) {
				if ((this.thrownExceptions[i].tagBits & TagBits.HasMissingType) != 0) {
					this.tagBits |=  TagBits.HasMissingType;
					break checkMissingType;
				}
			}
		}
	    return this;
	}

	/**
	 * @see org.eclipse.jdt.internal.compiler.lookup.Substitution#isRawSubstitution()
	 */
	public boolean isRawSubstitution() {
		return this.isRaw;
	}

	/**
	 * @see org.eclipse.jdt.internal.compiler.lookup.Substitution#substitute(org.eclipse.jdt.internal.compiler.lookup.TypeVariableBinding)
	 */
	public TypeBinding substitute(TypeVariableBinding originalVariable) {
        TypeVariableBinding[] variables = this.originalMethod.typeVariables;
        int length = variables.length;
        // check this variable can be substituted given parameterized type
        if (originalVariable.rank < length && variables[originalVariable.rank] == originalVariable) {
			return this.typeArguments[originalVariable.rank];
        }
	    return originalVariable;
	}
	/**
	 * @see org.eclipse.jdt.internal.compiler.lookup.MethodBinding#tiebreakMethod()
	 */
	public MethodBinding tiebreakMethod() {
		if (this.tiebreakMethod == null)
			this.tiebreakMethod = this.originalMethod.asRawMethod(this.environment);
		return this.tiebreakMethod;
	}
}




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