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/*
* Copyright (C) 2007-2010 Júlio Vilmar Gesser.
* Copyright (C) 2011, 2013-2016 The JavaParser Team.
*
* This file is part of JavaParser.
*
* JavaParser can be used either under the terms of
* a) the GNU Lesser General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
* b) the terms of the Apache License
*
* You should have received a copy of both licenses in LICENCE.LGPL and
* LICENCE.APACHE. Please refer to those files for details.
*
* JavaParser is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU Lesser General Public License for more details.
*/
package com.github.javaparser.resolution.declarations;
import com.github.javaparser.ast.AccessSpecifier;
import com.github.javaparser.resolution.MethodUsage;
import com.github.javaparser.resolution.UnsolvedSymbolException;
import com.github.javaparser.resolution.types.ResolvedReferenceType;
import com.github.javaparser.resolution.types.ResolvedType;
import java.util.ArrayList;
import java.util.List;
import java.util.Optional;
import java.util.Set;
import java.util.stream.Collectors;
/**
* @author Federico Tomassetti
*/
public interface ResolvedReferenceTypeDeclaration extends ResolvedTypeDeclaration,
ResolvedTypeParametrizable {
@Override
default ResolvedReferenceTypeDeclaration asReferenceType() {
return this;
}
///
/// Ancestors
///
/**
* The list of all the direct ancestors of the current declaration.
* Note that the ancestor can be parametrized types with values specified. For example:
* <p>
* class A implements Comparable<String> {}
* <p>
* In this case the ancestor is Comparable<String>
*/
List<ResolvedReferenceType> getAncestors();
/**
* The list of all the ancestors of the current declaration, direct and indirect.
* This list does not contains duplicates with the exacting same type parameters.
*/
default List<ResolvedReferenceType> getAllAncestors() {
List<ResolvedReferenceType> ancestors = new ArrayList<>();
// We want to avoid infinite recursion in case of Object having Object as ancestor
if (!(Object.class.getCanonicalName().equals(getQualifiedName()))) {
for (ResolvedReferenceType ancestor : getAncestors()) {
ancestors.add(ancestor);
for (ResolvedReferenceType inheritedAncestor : ancestor.getAllAncestors()) {
if (!ancestors.contains(inheritedAncestor)) {
ancestors.add(inheritedAncestor);
}
}
}
}
return ancestors;
}
///
/// Fields
///
/**
* Note that the type of the field should be expressed using the type variables of this particular type.
* Consider for example:
* <p>
* class Foo<E> { E field; }
* <p>
* class Bar extends Foo<String> { }
* <p>
* When calling getField("field") on Foo I should get a FieldDeclaration with type E, while calling it on
* Bar I should get a FieldDeclaration with type String.
*/
default ResolvedFieldDeclaration getField(String name) {
Optional<ResolvedFieldDeclaration> field = this.getAllFields().stream().filter(f -> f.getName().equals(name)).findFirst();
if (field.isPresent()) {
return field.get();
} else {
throw new UnsolvedSymbolException("Field not found: " + name);
}
}
/**
* Consider only field or inherited field which is not private.
*/
default ResolvedFieldDeclaration getVisibleField(String name) {
Optional<ResolvedFieldDeclaration> field = getVisibleFields().stream().filter(f -> f.getName().equals(name)).findFirst();
if (field.isPresent()) {
return field.get();
} else {
throw new IllegalArgumentException();
}
}
/**
* Has this type a field with the given name?
*/
default boolean hasField(String name) {
return this.getAllFields().stream().filter(f -> f.getName().equals(name)).findFirst().isPresent();
}
/**
* Either a declared field or inherited field which is not private.
*/
default boolean hasVisibleField(String name) {
return getVisibleFields().stream().filter(f -> f.getName().equals(name)).findFirst().isPresent();
}
/**
* Return a list of all fields, either declared in this declaration or inherited.
*/
List<ResolvedFieldDeclaration> getAllFields();
/**
* Return a list of all fields declared and the inherited ones which are not private.
*/
default List<ResolvedFieldDeclaration> getVisibleFields() {
return getAllFields().stream()
.filter(f -> f.declaringType().equals(this) || f.accessSpecifier() != AccessSpecifier.PRIVATE)
.collect(Collectors.toList());
}
/**
* Return a list of all the non static fields, either declared or inherited.
*/
default List<ResolvedFieldDeclaration> getAllNonStaticFields() {
return getAllFields().stream().filter(it -> !it.isStatic()).collect(Collectors.toList());
}
/**
* Return a list of all the static fields, either declared or inherited.
*/
default List<ResolvedFieldDeclaration> getAllStaticFields() {
return getAllFields().stream().filter(it -> it.isStatic()).collect(Collectors.toList());
}
/**
* Return a list of all the fields declared in this type.
*/
default List<ResolvedFieldDeclaration> getDeclaredFields() {
return getAllFields().stream().filter(it -> it.declaringType().getQualifiedName().equals(getQualifiedName())).collect(Collectors.toList());
}
///
/// Methods
///
/**
* Return a list of all the methods declared in this type declaration.
*/
Set<ResolvedMethodDeclaration> getDeclaredMethods();
/**
* Return a list of all the methods declared of this type declaration, either declared or inherited.
* Note that it should not include overridden methods.
*/
Set<MethodUsage> getAllMethods();
///
/// Assignability
///
/**
* Can we assign instances of the given type to variables having the type defined
* by this declaration?
*/
boolean isAssignableBy(ResolvedType type);
/**
* Can we assign instances of the type defined by this declaration to variables having the type defined
* by the given type?
*/
default boolean canBeAssignedTo(ResolvedReferenceTypeDeclaration other) {
return other.isAssignableBy(this);
}
/**
* Can we assign instances of the given type to variables having the type defined
* by this declaration?
*/
boolean isAssignableBy(ResolvedReferenceTypeDeclaration other);
///
/// Annotations
///
/**
* Has the type at least one annotation declared having the specified qualified name?
*/
boolean hasDirectlyAnnotation(String qualifiedName);
/**
* Has the type at least one annotation declared or inherited having the specified qualified name?
*/
default boolean hasAnnotation(String qualifiedName) {
if (hasDirectlyAnnotation(qualifiedName)) {
return true;
}
return getAllAncestors().stream().anyMatch(it -> it.asReferenceType().getTypeDeclaration().hasDirectlyAnnotation(qualifiedName));
}
/**
* This means that the type has a functional method. Conceptually, a functional interface has exactly one abstract method.
* Typically these classes has the FunctionInterface annotation but this is not mandatory.
*/
boolean isFunctionalInterface();
///
/// Type parameters
///
@Override
default Optional<ResolvedTypeParameterDeclaration> findTypeParameter(String name) {
for (ResolvedTypeParameterDeclaration tp : this.getTypeParameters()) {
if (tp.getName().equals(name)) {
return Optional.of(tp);
}
}
if (this.containerType().isPresent()) {
return this.containerType().get().findTypeParameter(name);
}
return Optional.empty();
}
}
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