com.github.javaparser.symbolsolver.resolution.MethodResolutionLogic Maven / Gradle / Ivy
Go to download
Show more of this group Show more artifacts with this name
Show all versions of java-symbol-solver-core Show documentation
Show all versions of java-symbol-solver-core Show documentation
A Symbol Solver for Java, built on top of JavaParser (core)
/*
* Copyright 2016 Federico Tomassetti
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
package com.github.javaparser.symbolsolver.resolution;
import com.github.javaparser.symbolsolver.core.resolution.Context;
import com.github.javaparser.symbolsolver.javaparsermodel.declarations.JavaParserClassDeclaration;
import com.github.javaparser.symbolsolver.javaparsermodel.declarations.JavaParserEnumDeclaration;
import com.github.javaparser.symbolsolver.javaparsermodel.declarations.JavaParserInterfaceDeclaration;
import com.github.javaparser.symbolsolver.javaparsermodel.declarations.JavaParserMethodDeclaration;
import com.github.javaparser.symbolsolver.javassistmodel.JavassistClassDeclaration;
import com.github.javaparser.symbolsolver.javassistmodel.JavassistEnumDeclaration;
import com.github.javaparser.symbolsolver.javassistmodel.JavassistInterfaceDeclaration;
import com.github.javaparser.symbolsolver.model.declarations.*;
import com.github.javaparser.symbolsolver.model.methods.MethodUsage;
import com.github.javaparser.symbolsolver.model.resolution.SymbolReference;
import com.github.javaparser.symbolsolver.model.resolution.TypeSolver;
import com.github.javaparser.symbolsolver.model.typesystem.*;
import com.github.javaparser.symbolsolver.reflectionmodel.ReflectionClassDeclaration;
import com.github.javaparser.symbolsolver.reflectionmodel.ReflectionEnumDeclaration;
import com.github.javaparser.symbolsolver.reflectionmodel.ReflectionInterfaceDeclaration;
import java.util.*;
import java.util.stream.Collectors;
/**
* @author Federico Tomassetti
*/
public class MethodResolutionLogic {
private static List groupVariadicParamValues(List argumentsTypes, int startVariadic, Type variadicType) {
List res = new ArrayList<>(argumentsTypes.subList(0, startVariadic));
List variadicValues = argumentsTypes.subList(startVariadic, argumentsTypes.size());
if (variadicValues.isEmpty()) {
// TODO if there are no variadic values we should default to the bound of the formal type
res.add(variadicType);
} else {
Type componentType = findCommonType(variadicValues);
res.add(new ArrayType(componentType));
}
return res;
}
private static Type findCommonType(List variadicValues) {
if (variadicValues.isEmpty()) {
throw new IllegalArgumentException();
}
// TODO implement this decently
return variadicValues.get(0);
}
public static boolean isApplicable(MethodDeclaration method, String name, List argumentsTypes, TypeSolver typeSolver) {
return isApplicable(method, name, argumentsTypes, typeSolver, false);
}
private static boolean isApplicable(MethodDeclaration method, String name, List argumentsTypes, TypeSolver typeSolver, boolean withWildcardTolerance) {
if (!method.getName().equals(name)) {
return false;
}
if (method.hasVariadicParameter()) {
int pos = method.getNumberOfParams() - 1;
if (method.getNumberOfParams() == argumentsTypes.size()) {
// check if the last value is directly assignable as an array
Type expectedType = method.getLastParam().getType();
Type actualType = argumentsTypes.get(pos);
if (!expectedType.isAssignableBy(actualType)) {
for (TypeParameterDeclaration tp : method.getTypeParameters()) {
expectedType = replaceTypeParam(expectedType, tp, typeSolver);
}
if (!expectedType.isAssignableBy(actualType)) {
if (actualType.isArray() && expectedType.isAssignableBy(actualType.asArrayType().getComponentType())) {
argumentsTypes.set(pos, actualType.asArrayType().getComponentType());
} else {
argumentsTypes = groupVariadicParamValues(argumentsTypes, pos, method.getLastParam().getType());
}
}
} // else it is already assignable, nothing to do
} else {
if (pos > argumentsTypes.size()) {
return false;
}
argumentsTypes = groupVariadicParamValues(argumentsTypes, pos, method.getLastParam().getType());
}
}
if (method.getNumberOfParams() != argumentsTypes.size()) {
return false;
}
Map matchedParameters = new HashMap<>();
boolean needForWildCardTolerance = false;
for (int i = 0; i < method.getNumberOfParams(); i++) {
Type expectedType = method.getParam(i).getType();
Type actualType = argumentsTypes.get(i);
if ((expectedType.isTypeVariable() && !(expectedType.isWildcard())) && expectedType.asTypeParameter().declaredOnMethod()) {
matchedParameters.put(expectedType.asTypeParameter().getName(), actualType);
continue;
}
boolean isAssignableWithoutSubstitution = expectedType.isAssignableBy(actualType) ||
(method.getParam(i).isVariadic() && new ArrayType(expectedType).isAssignableBy(actualType));
if (!isAssignableWithoutSubstitution && expectedType.isReferenceType() && actualType.isReferenceType()) {
isAssignableWithoutSubstitution = isAssignableMatchTypeParameters(
expectedType.asReferenceType(),
actualType.asReferenceType(),
matchedParameters);
}
if (!isAssignableWithoutSubstitution) {
List typeParameters = method.getTypeParameters();
typeParameters.addAll(method.declaringType().getTypeParameters());
for (TypeParameterDeclaration tp : typeParameters) {
expectedType = replaceTypeParam(expectedType, tp, typeSolver);
}
if (!expectedType.isAssignableBy(actualType)) {
if (actualType.isWildcard() && withWildcardTolerance && !expectedType.isPrimitive()) {
needForWildCardTolerance = true;
continue;
}
if (method.hasVariadicParameter() && i == method.getNumberOfParams() - 1) {
if (new ArrayType(expectedType).isAssignableBy(actualType)) {
continue;
}
}
return false;
}
}
}
return !withWildcardTolerance || needForWildCardTolerance;
}
public static boolean isAssignableMatchTypeParameters(Type expected, Type actual,
Map matchedParameters) {
if (expected.isReferenceType() && actual.isReferenceType()) {
return isAssignableMatchTypeParameters(expected.asReferenceType(), actual.asReferenceType(), matchedParameters);
} else if (expected.isTypeVariable()) {
matchedParameters.put(expected.asTypeParameter().getName(), actual);
return true;
} else {
throw new UnsupportedOperationException(expected.getClass().getCanonicalName() + " " + actual.getClass().getCanonicalName());
}
}
public static boolean isAssignableMatchTypeParameters(ReferenceType expected, ReferenceType actual,
Map matchedParameters) {
if (actual.getQualifiedName().equals(expected.getQualifiedName())) {
return isAssignableMatchTypeParametersMatchingQName(expected, actual, matchedParameters);
} else {
List ancestors = actual.getAllAncestors();
for (ReferenceType ancestor : ancestors) {
if (isAssignableMatchTypeParametersMatchingQName(expected, ancestor, matchedParameters)) {
return true;
}
}
}
return false;
}
private static boolean isAssignableMatchTypeParametersMatchingQName(ReferenceType expected, ReferenceType actual,
Map matchedParameters) {
if (!expected.getQualifiedName().equals(actual.getQualifiedName())) {
return false;
}
if (expected.typeParametersValues().size() != actual.typeParametersValues().size()) {
throw new UnsupportedOperationException();
//return true;
}
for (int i = 0; i < expected.typeParametersValues().size(); i++) {
Type expectedParam = expected.typeParametersValues().get(i);
Type actualParam = actual.typeParametersValues().get(i);
// In the case of nested parameterizations eg. List <-> List
// we should peel off one layer and ensure R <-> Integer
if (expectedParam.isReferenceType() && actualParam.isReferenceType()){
ReferenceType r1 = expectedParam.asReferenceType();
ReferenceType r2 = actualParam.asReferenceType();
return isAssignableMatchTypeParametersMatchingQName(r1, r2, matchedParameters);
}
if (expectedParam.isTypeVariable()) {
String expectedParamName = expectedParam.asTypeParameter().getName();
if (!actualParam.isTypeVariable() || !actualParam.asTypeParameter().getName().equals(expectedParamName)) {
if (matchedParameters.containsKey(expectedParamName)) {
Type matchedParameter = matchedParameters.get(expectedParamName);
if (matchedParameter.isAssignableBy(actualParam)) {
return true;
} else if (actualParam.isAssignableBy(matchedParameter)) {
matchedParameters.put(expectedParamName, actualParam);
return true;
}
return false;
} else {
matchedParameters.put(expectedParamName, actualParam);
}
}
} else if (expectedParam.isReferenceType()) {
if (!expectedParam.equals(actualParam)) {
return false;
}
} else if (expectedParam.isWildcard()) {
if (expectedParam.asWildcard().isExtends()) {
return isAssignableMatchTypeParameters(expectedParam.asWildcard().getBoundedType(), actual, matchedParameters);
}
// TODO verify super bound
return true;
} else {
throw new UnsupportedOperationException(expectedParam.describe());
}
}
return true;
}
public static Type replaceTypeParam(Type type, TypeParameterDeclaration tp, TypeSolver typeSolver) {
if (type.isTypeVariable()) {
if (type.describe().equals(tp.getName())) {
List bounds = tp.getBounds(typeSolver);
if (bounds.size() > 1) {
throw new UnsupportedOperationException();
} else if (bounds.size() == 1) {
return bounds.get(0).getType();
} else {
return new ReferenceTypeImpl(typeSolver.solveType(Object.class.getCanonicalName()), typeSolver);
}
}
return type;
} else if (type.isPrimitive()) {
return type;
} else if (type.isArray()) {
return new ArrayType(replaceTypeParam(type.asArrayType().getComponentType(), tp, typeSolver));
} else if (type.isReferenceType()) {
ReferenceType result = type.asReferenceType();
result = result.transformTypeParameters(typeParam -> replaceTypeParam(typeParam, tp, typeSolver)).asReferenceType();
return result;
} else if (type.isWildcard()) {
if (type.describe().equals(tp.getName())) {
List bounds = tp.getBounds(typeSolver);
if (bounds.size() > 1) {
throw new UnsupportedOperationException();
} else if (bounds.size() == 1) {
return bounds.get(0).getType();
} else {
return new ReferenceTypeImpl(typeSolver.solveType(Object.class.getCanonicalName()), typeSolver);
}
}
return type;
} else {
throw new UnsupportedOperationException("Replacing " + type + ", param " + tp + " with " + type.getClass().getCanonicalName());
}
}
public static boolean isApplicable(MethodUsage method, String name, List argumentsTypes, TypeSolver typeSolver) {
if (!method.getName().equals(name)) {
return false;
}
// TODO Consider varargs
if (method.getNoParams() != argumentsTypes.size()) {
return false;
}
for (int i = 0; i < method.getNoParams(); i++) {
Type expectedType = method.getParamType(i);
Type expectedTypeWithoutSubstitutions = expectedType;
Type expectedTypeWithInference = method.getParamType(i);
Type actualType = argumentsTypes.get(i);
List typeParameters = method.getDeclaration().getTypeParameters();
typeParameters.addAll(method.declaringType().getTypeParameters());
if (expectedType.describe().equals(actualType.describe())){
return true;
}
Map derivedValues = new HashMap<>();
for (int j = 0; j < method.getParamTypes().size(); j++) {
ParameterDeclaration parameter = method.getDeclaration().getParam(i);
Type parameterType = parameter.getType();
if (parameter.isVariadic()) {
parameterType = parameterType.asArrayType().getComponentType();
}
inferTypes(argumentsTypes.get(j), parameterType, derivedValues);
}
for (Map.Entry entry : derivedValues.entrySet()){
TypeParameterDeclaration tp = entry.getKey();
expectedTypeWithInference = expectedTypeWithInference.replaceTypeVariables(tp, entry.getValue());
}
for (TypeParameterDeclaration tp : typeParameters) {
if (tp.getBounds(typeSolver).isEmpty()) {
//expectedType = expectedType.replaceTypeVariables(tp.getName(), new ReferenceTypeUsageImpl(typeSolver.solveType(Object.class.getCanonicalName()), typeSolver));
expectedType = expectedType.replaceTypeVariables(tp, Wildcard.extendsBound(new ReferenceTypeImpl(typeSolver.solveType(Object.class.getCanonicalName()), typeSolver)));
} else if (tp.getBounds(typeSolver).size() == 1) {
TypeParameterDeclaration.Bound bound = tp.getBounds(typeSolver).get(0);
if (bound.isExtends()) {
//expectedType = expectedType.replaceTypeVariables(tp.getName(), bound.getType());
expectedType = expectedType.replaceTypeVariables(tp, Wildcard.extendsBound(bound.getType()));
} else {
//expectedType = expectedType.replaceTypeVariables(tp.getName(), new ReferenceTypeUsageImpl(typeSolver.solveType(Object.class.getCanonicalName()), typeSolver));
expectedType = expectedType.replaceTypeVariables(tp, Wildcard.superBound(bound.getType()));
}
} else {
throw new UnsupportedOperationException();
}
}
Type expectedType2 = expectedTypeWithoutSubstitutions;
for (TypeParameterDeclaration tp : typeParameters) {
if (tp.getBounds(typeSolver).isEmpty()) {
expectedType2 = expectedType2.replaceTypeVariables(tp, new ReferenceTypeImpl(typeSolver.solveType(Object.class.getCanonicalName()), typeSolver));
} else if (tp.getBounds(typeSolver).size() == 1) {
TypeParameterDeclaration.Bound bound = tp.getBounds(typeSolver).get(0);
if (bound.isExtends()) {
expectedType2 = expectedType2.replaceTypeVariables(tp, bound.getType());
} else {
expectedType2 = expectedType2.replaceTypeVariables(tp, new ReferenceTypeImpl(typeSolver.solveType(Object.class.getCanonicalName()), typeSolver));
}
} else {
throw new UnsupportedOperationException();
}
}
if (!expectedType.isAssignableBy(actualType)
&& !expectedType2.isAssignableBy(actualType)
&& !expectedTypeWithInference.isAssignableBy(actualType)
&& !expectedTypeWithoutSubstitutions.isAssignableBy(actualType)) {
return false;
}
}
return true;
}
private static List getMethodsWithoutDuplicates(List methods) {
Set s = new TreeSet(new Comparator() {
@Override
public int compare(MethodDeclaration m1, MethodDeclaration m2) {
if (m1 instanceof JavaParserMethodDeclaration && m2 instanceof JavaParserMethodDeclaration &&
((JavaParserMethodDeclaration) m1).getWrappedNode().equals(((JavaParserMethodDeclaration) m2).getWrappedNode())) {
return 0;
}
return 1;
}
});
s.addAll(methods);
List res = new ArrayList<>();
Set usedSignatures = new HashSet<>();
for (MethodDeclaration md : methods) {
String signature = md.getQualifiedSignature();
if (!usedSignatures.contains(signature)) {
usedSignatures.add(signature);
res.add(md);
}
}
return res;
}
/**
* @param methods we expect the methods to be ordered such that inherited methods are later in the list
* @param name
* @param argumentsTypes
* @param typeSolver
* @return
*/
public static SymbolReference findMostApplicable(List methods, String name, List argumentsTypes, TypeSolver typeSolver) {
SymbolReference res = findMostApplicable(methods, name, argumentsTypes, typeSolver, false);
if (res.isSolved()) {
return res;
}
return findMostApplicable(methods, name, argumentsTypes, typeSolver, true);
}
public static SymbolReference findMostApplicable(List methods, String name, List argumentsTypes, TypeSolver typeSolver, boolean wildcardTolerance) {
List applicableMethods = getMethodsWithoutDuplicates(methods).stream().filter((m) -> isApplicable(m, name, argumentsTypes, typeSolver, wildcardTolerance)).collect(Collectors.toList());
if (applicableMethods.isEmpty()) {
return SymbolReference.unsolved(MethodDeclaration.class);
}
if (applicableMethods.size() > 1) {
List nullParamIndexes = new ArrayList<>();
for (int i = 0; i < argumentsTypes.size(); i++) {
if (argumentsTypes.get(i).isNull()) {
nullParamIndexes.add(i);
}
}
if (!nullParamIndexes.isEmpty()) {
// remove method with array param if a non array exists and arg is null
Set removeCandidates = new HashSet<>();
for (Integer nullParamIndex: nullParamIndexes) {
for (MethodDeclaration methDecl: applicableMethods) {
if (methDecl.getParam(nullParamIndex.intValue()).getType().isArray()) {
removeCandidates.add(methDecl);
}
}
}
if (!removeCandidates.isEmpty() && removeCandidates.size() < applicableMethods.size()) {
applicableMethods.removeAll(removeCandidates);
}
}
}
if (applicableMethods.size() == 1) {
return SymbolReference.solved(applicableMethods.get(0));
} else {
MethodDeclaration winningCandidate = applicableMethods.get(0);
MethodDeclaration other = null;
boolean possibleAmbiguity = false;
for (int i = 1; i < applicableMethods.size(); i++) {
other = applicableMethods.get(i);
if (isMoreSpecific(winningCandidate, other, argumentsTypes, typeSolver)) {
possibleAmbiguity = false;
} else if (isMoreSpecific(other, winningCandidate, argumentsTypes, typeSolver)) {
possibleAmbiguity = false;
winningCandidate = other;
} else {
if (winningCandidate.declaringType().getQualifiedName().equals(other.declaringType().getQualifiedName())) {
possibleAmbiguity = true;
} else {
// we expect the methods to be ordered such that inherited methods are later in the list
}
}
}
if (possibleAmbiguity) {
// pick the first exact match if it exists
if (!isExactMatch(winningCandidate, argumentsTypes)) {
if (isExactMatch(other, argumentsTypes)) {
winningCandidate = other;
} else {
throw new MethodAmbiguityException("Ambiguous method call: cannot find a most applicable method: " + winningCandidate + ", " + other);
}
}
}
return SymbolReference.solved(winningCandidate);
}
}
protected static boolean isExactMatch(MethodLikeDeclaration method, List argumentsTypes) {
for (int i = 0; i < method.getNumberOfParams(); i++) {
if (!method.getParam(i).getType().equals(argumentsTypes.get(i))) {
return false;
}
}
return true;
}
private static boolean isMoreSpecific(MethodDeclaration methodA, MethodDeclaration methodB, List argumentTypes, TypeSolver typeSolver) {
boolean oneMoreSpecificFound = false;
if (methodA.getNumberOfParams() < methodB.getNumberOfParams()) {
return true;
}
if (methodA.getNumberOfParams() > methodB.getNumberOfParams()) {
return false;
}
for (int i = 0; i < methodA.getNumberOfParams(); i++) {
Type tdA = methodA.getParam(i).getType();
Type tdB = methodB.getParam(i).getType();
// B is more specific
if (tdB.isAssignableBy(tdA) && !tdA.isAssignableBy(tdB)) {
oneMoreSpecificFound = true;
}
// A is more specific
if (tdA.isAssignableBy(tdB) && !tdB.isAssignableBy(tdA)) {
return false;
}
}
if (!oneMoreSpecificFound) {
int lastIndex = argumentTypes.size() - 1;
if (methodA.hasVariadicParameter() && !methodB.hasVariadicParameter()) {
// if the last argument is an array then m1 is more specific
if (argumentTypes.get(lastIndex).isArray()) {
return true;
}
if (!argumentTypes.get(lastIndex).isArray()) {
return false;
}
}
if (!methodA.hasVariadicParameter() && methodB.hasVariadicParameter()) {
// if the last argument is an array and m1 is not variadic then
// it is not more specific
if (argumentTypes.get(lastIndex).isArray()) {
return false;
}
if (!argumentTypes.get(lastIndex).isArray()) {
return true;
}
}
}
return oneMoreSpecificFound;
}
private static boolean isMoreSpecific(MethodUsage methodA, MethodUsage methodB, TypeSolver typeSolver) {
boolean oneMoreSpecificFound = false;
for (int i = 0; i < methodA.getNoParams(); i++) {
Type tdA = methodA.getParamType(i);
Type tdB = methodB.getParamType(i);
boolean aIsAssignableByB = tdA.isAssignableBy(tdB);
boolean bIsAssignableByA = tdB.isAssignableBy(tdA);
// B is more specific
if (bIsAssignableByA && !aIsAssignableByB) {
oneMoreSpecificFound = true;
}
// A is more specific
if (aIsAssignableByB && !bIsAssignableByA) {
return false;
}
}
return oneMoreSpecificFound;
}
public static Optional findMostApplicableUsage(List methods, String name, List argumentsTypes, TypeSolver typeSolver) {
List applicableMethods = methods.stream().filter((m) -> isApplicable(m, name, argumentsTypes, typeSolver)).collect(Collectors.toList());
if (applicableMethods.isEmpty()) {
return Optional.empty();
}
if (applicableMethods.size() == 1) {
return Optional.of(applicableMethods.get(0));
} else {
MethodUsage winningCandidate = applicableMethods.get(0);
for (int i = 1; i < applicableMethods.size(); i++) {
MethodUsage other = applicableMethods.get(i);
if (isMoreSpecific(winningCandidate, other, typeSolver)) {
// nothing to do
} else if (isMoreSpecific(other, winningCandidate, typeSolver)) {
winningCandidate = other;
} else {
if (winningCandidate.declaringType().getQualifiedName().equals(other.declaringType().getQualifiedName())) {
if (!areOverride(winningCandidate, other)) {
throw new MethodAmbiguityException("Ambiguous method call: cannot find a most applicable method: " + winningCandidate + ", " + other + ". First declared in " + winningCandidate.declaringType().getQualifiedName());
}
} else {
// we expect the methods to be ordered such that inherited methods are later in the list
//throw new UnsupportedOperationException();
}
}
}
return Optional.of(winningCandidate);
}
}
private static boolean areOverride(MethodUsage winningCandidate, MethodUsage other) {
if (!winningCandidate.getName().equals(other.getName())) {
return false;
}
if (winningCandidate.getNoParams() != other.getNoParams()) {
return false;
}
for (int i = 0; i < winningCandidate.getNoParams(); i++) {
if (!winningCandidate.getParamTypes().get(i).equals(other.getParamTypes().get(i))) {
return false;
}
}
return true;
}
public static SymbolReference solveMethodInType(TypeDeclaration typeDeclaration, String name, List argumentsTypes, TypeSolver typeSolver) {
return solveMethodInType(typeDeclaration, name, argumentsTypes, false, typeSolver);
}
/**
* Replace TypeDeclaration.solveMethod
*
* @param typeDeclaration
* @param name
* @param argumentsTypes
* @param staticOnly
* @return
*/
public static SymbolReference solveMethodInType(TypeDeclaration typeDeclaration, String name, List argumentsTypes, boolean staticOnly, TypeSolver typeSolver) {
if (typeDeclaration instanceof JavaParserClassDeclaration) {
Context ctx = ((JavaParserClassDeclaration) typeDeclaration).getContext();
return ctx.solveMethod(name, argumentsTypes, staticOnly, typeSolver);
}
if (typeDeclaration instanceof JavaParserInterfaceDeclaration) {
Context ctx = ((JavaParserInterfaceDeclaration) typeDeclaration).getContext();
return ctx.solveMethod(name, argumentsTypes, staticOnly, typeSolver);
}
if (typeDeclaration instanceof JavaParserEnumDeclaration) {
if (name.equals("values") && argumentsTypes.isEmpty()) {
return SymbolReference.solved(new JavaParserEnumDeclaration.ValuesMethod((JavaParserEnumDeclaration) typeDeclaration, typeSolver));
}
Context ctx = ((JavaParserEnumDeclaration) typeDeclaration).getContext();
return ctx.solveMethod(name, argumentsTypes, staticOnly, typeSolver);
}
if (typeDeclaration instanceof ReflectionClassDeclaration) {
return ((ReflectionClassDeclaration) typeDeclaration).solveMethod(name, argumentsTypes, staticOnly);
}
if (typeDeclaration instanceof ReflectionInterfaceDeclaration) {
return ((ReflectionInterfaceDeclaration) typeDeclaration).solveMethod(name, argumentsTypes, staticOnly);
}
if (typeDeclaration instanceof ReflectionEnumDeclaration) {
return ((ReflectionEnumDeclaration) typeDeclaration).solveMethod(name, argumentsTypes, staticOnly);
}
if (typeDeclaration instanceof JavassistInterfaceDeclaration) {
return ((JavassistInterfaceDeclaration) typeDeclaration).solveMethod(name, argumentsTypes, staticOnly);
}
if (typeDeclaration instanceof JavassistClassDeclaration) {
return ((JavassistClassDeclaration) typeDeclaration).solveMethod(name, argumentsTypes, staticOnly);
}
if (typeDeclaration instanceof JavassistEnumDeclaration) {
return ((JavassistEnumDeclaration) typeDeclaration).solveMethod(name, argumentsTypes, staticOnly);
}
throw new UnsupportedOperationException(typeDeclaration.getClass().getCanonicalName());
}
private static void inferTypes(Type source, Type target, Map mappings) {
if (source.equals(target)) {
return;
}
if (source.isReferenceType() && target.isReferenceType()) {
ReferenceType sourceRefType = source.asReferenceType();
ReferenceType targetRefType = target.asReferenceType();
if (sourceRefType.getQualifiedName().equals(targetRefType.getQualifiedName())) {
if (!sourceRefType.isRawType() && !targetRefType.isRawType()) {
for (int i = 0; i < sourceRefType.typeParametersValues().size(); i++) {
inferTypes(sourceRefType.typeParametersValues().get(i), targetRefType.typeParametersValues().get(i), mappings);
}
}
}
return;
}
if (source.isReferenceType() && target.isWildcard()) {
if (target.asWildcard().isBounded()) {
inferTypes(source, target.asWildcard().getBoundedType(), mappings);
return;
}
return;
}
if (source.isWildcard() && target.isWildcard()) {
return;
}
if (source.isReferenceType() && target.isTypeVariable()) {
mappings.put(target.asTypeParameter(), source);
return;
}
if (source.isWildcard() && target.isReferenceType()){
if (source.asWildcard().isBounded()){
inferTypes(source.asWildcard().getBoundedType(), target, mappings);
}
return;
}
if (source.isWildcard() && target.isTypeVariable()) {
mappings.put(target.asTypeParameter(), source);
return;
}
if (source.isTypeVariable() && target.isTypeVariable()) {
mappings.put(target.asTypeParameter(), source);
return;
}
if (source.isPrimitive() || target.isPrimitive()) {
return;
}
if (source.isNull()) {
return;
}
}
}