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/*
 * Copyright (C) 2013 Google, Inc.
 * Copyright (C) 2013 Square, Inc.
 *
 * 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.google.auto.common;

import static javax.lang.model.element.ElementKind.PACKAGE;

import com.google.common.annotations.Beta;
import com.google.common.base.Optional;
import com.google.common.base.Predicate;
import com.google.common.collect.ImmutableList;
import com.google.common.collect.ImmutableSet;
import com.google.common.collect.LinkedHashMultimap;
import com.google.common.collect.SetMultimap;
import java.lang.annotation.Annotation;
import java.util.Collection;
import java.util.LinkedHashSet;
import java.util.List;
import java.util.Set;
import javax.lang.model.element.AnnotationMirror;
import javax.lang.model.element.Element;
import javax.lang.model.element.ExecutableElement;
import javax.lang.model.element.Modifier;
import javax.lang.model.element.PackageElement;
import javax.lang.model.element.TypeElement;
import javax.lang.model.element.VariableElement;
import javax.lang.model.type.TypeKind;
import javax.lang.model.type.TypeMirror;
import javax.lang.model.util.ElementFilter;
import javax.lang.model.util.Elements;
import javax.lang.model.util.SimpleElementVisitor6;
import javax.lang.model.util.Types;

/**
 * Static utility methods pertaining to {@link Element} instances.
 *
 * @author Gregory Kick
 */
@Beta
public final class MoreElements {
  /**
   * An alternate implementation of {@link Elements#getPackageOf} that does not require an
   * {@link Elements} instance.
   *
   * @throws NullPointerException if {@code element} is {@code null}
   */
  public static PackageElement getPackage(Element element) {
    while (element.getKind() != PACKAGE) {
      element = element.getEnclosingElement();
    }
    return (PackageElement) element;
  }

  private static final class PackageElementVisitor extends CastingElementVisitor {
    private static final PackageElementVisitor INSTANCE = new PackageElementVisitor();

    PackageElementVisitor() {
      super("package element");
    }

    @Override
    public PackageElement visitPackage(PackageElement e, Void ignore) {
      return e;
    }
  }

  /**
   * Returns the given {@link Element} instance as {@link PackageElement}.
   *
   * 

This method is functionally equivalent to an {@code instanceof} check and a cast, but should * always be used over that idiom as instructed in the documentation for {@link Element}. * * @throws NullPointerException if {@code element} is {@code null} * @throws IllegalArgumentException if {@code element} isn't a {@link PackageElement}. */ public static PackageElement asPackage(Element element) { return element.accept(PackageElementVisitor.INSTANCE, null); } private static final class TypeElementVisitor extends CastingElementVisitor { private static final TypeElementVisitor INSTANCE = new TypeElementVisitor(); TypeElementVisitor() { super("type element"); } @Override public TypeElement visitType(TypeElement e, Void ignore) { return e; } } /** * Returns true if the given {@link Element} instance is a {@link TypeElement}. * *

This method is functionally equivalent to an {@code instanceof} check, but should * always be used over that idiom as instructed in the documentation for {@link Element}. * * @throws NullPointerException if {@code element} is {@code null} */ public static boolean isType(Element element) { return element.getKind().isClass() || element.getKind().isInterface(); } /** * Returns the given {@link Element} instance as {@link TypeElement}. * *

This method is functionally equivalent to an {@code instanceof} check and a cast, but should * always be used over that idiom as instructed in the documentation for {@link Element}. * * @throws NullPointerException if {@code element} is {@code null} * @throws IllegalArgumentException if {@code element} isn't a {@link TypeElement}. */ public static TypeElement asType(Element element) { return element.accept(TypeElementVisitor.INSTANCE, null); } private static final class VariableElementVisitor extends CastingElementVisitor { private static final VariableElementVisitor INSTANCE = new VariableElementVisitor(); VariableElementVisitor() { super("variable element"); } @Override public VariableElement visitVariable(VariableElement e, Void ignore) { return e; } } /** * Returns the given {@link Element} instance as {@link VariableElement}. * *

This method is functionally equivalent to an {@code instanceof} check and a cast, but should * always be used over that idiom as instructed in the documentation for {@link Element}. * * @throws NullPointerException if {@code element} is {@code null} * @throws IllegalArgumentException if {@code element} isn't a {@link VariableElement}. */ public static VariableElement asVariable(Element element) { return element.accept(VariableElementVisitor.INSTANCE, null); } private static final class ExecutableElementVisitor extends CastingElementVisitor { private static final ExecutableElementVisitor INSTANCE = new ExecutableElementVisitor(); ExecutableElementVisitor() { super("executable element"); } @Override public ExecutableElement visitExecutable(ExecutableElement e, Void label) { return e; } } /** * Returns the given {@link Element} instance as {@link ExecutableElement}. * *

This method is functionally equivalent to an {@code instanceof} check and a cast, but should * always be used over that idiom as instructed in the documentation for {@link Element}. * * @throws NullPointerException if {@code element} is {@code null} * @throws IllegalArgumentException if {@code element} isn't a {@link ExecutableElement}. */ public static ExecutableElement asExecutable(Element element) { return element.accept(ExecutableElementVisitor.INSTANCE, null); } /** * Returns {@code true} iff the given element has an {@link AnnotationMirror} whose * {@linkplain AnnotationMirror#getAnnotationType() annotation type} has the same canonical name * as that of {@code annotationClass}. This method is a safer alternative to calling * {@link Element#getAnnotation} and checking for {@code null} as it avoids any interaction with . This() { super(); } . This() { super(); } * annotation proxies. */ public static boolean isAnnotationPresent(Element element, Class annotationClass) { return getAnnotationMirror(element, annotationClass).isPresent(); } /** * Returns an {@link AnnotationMirror} for the annotation of type {@code annotationClass} on * {@code element}, or {@link Optional#absent()} if no such annotation exists. This method is a * safer alternative to calling {@link Element#getAnnotation} as it avoids any interaction with * annotation proxies. */ public static Optional getAnnotationMirror(Element element, Class annotationClass) { String annotationClassName = annotationClass.getCanonicalName(); for (AnnotationMirror annotationMirror : element.getAnnotationMirrors()) { TypeElement annotationTypeElement = asType(annotationMirror.getAnnotationType().asElement()); if (annotationTypeElement.getQualifiedName().contentEquals(annotationClassName)) { return Optional.of(annotationMirror); } } return Optional.absent(); } /** * Returns a {@link Predicate} that can be used to filter elements by {@link Modifier}. * The predicate returns {@code true} if the input {@link Element} has all of the given * {@code modifiers}, perhaps in addition to others. * *

Here is an example how one could get a List of static methods of a class: *

{@code
   * FluentIterable.from(ElementFilter.methodsIn(clazzElement.getEnclosedElements()))
   *     .filter(MoreElements.hasModifiers(Modifier.STATIC).toList();
   * }
*/ public static Predicate hasModifiers(Modifier... modifiers) { return hasModifiers(ImmutableSet.copyOf(modifiers)); } /** * Returns a {@link Predicate} that can be used to filter elements by {@link Modifier}. * The predicate returns {@code true} if the input {@link Element} has all of the given * {@code modifiers}, perhaps in addition to others. * *

Here is an example how one could get a List of methods with certain modifiers of a class: *

{@code
   * Set modifiers = ...;
   * FluentIterable.from(ElementFilter.methodsIn(clazzElement.getEnclosedElements()))
   *     .filter(MoreElements.hasModifiers(modifiers).toList();}
   * 
*/ public static Predicate hasModifiers(final Set modifiers) { return new Predicate() { @Override public boolean apply(T input) { return input.getModifiers().containsAll(modifiers); } }; } /** * Returns the set of all non-private methods from {@code type}, including methods that it * inherits from its ancestors. Inherited methods that are overridden are not included in the * result. So if {@code type} defines {@code public String toString()}, the returned set will * contain that method, but not the {@code toString()} method defined by {@code Object}. * *

The returned set may contain more than one method with the same signature, if * {@code type} inherits those methods from different ancestors. For example, if it * inherits from unrelated interfaces {@code One} and {@code Two} which each define * {@code void foo();}, and if it does not itself override the {@code foo()} method, * then both {@code One.foo()} and {@code Two.foo()} will be in the returned set. * * @param type the type whose own and inherited methods are to be returned * @param elementUtils an {@link Elements} object, typically returned by * {@link javax.annotation.processing.AbstractProcessor#processingEnv processingEnv}.{@link javax.annotation.processing.ProcessingEnvironment#getElementUtils * getElementUtils()} * * @deprecated The method {@link #getLocalAndInheritedMethods(TypeElement, Types, Elements)} * has better consistency between Java compilers. */ @Deprecated public static ImmutableSet getLocalAndInheritedMethods( TypeElement type, Elements elementUtils) { Overrides overrides = new Overrides.NativeOverrides(elementUtils); return getLocalAndInheritedMethods(type, overrides); } /** * Returns the set of all non-private methods from {@code type}, including methods that it * inherits from its ancestors. Inherited methods that are overridden are not included in the * result. So if {@code type} defines {@code public String toString()}, the returned set will * contain that method, but not the {@code toString()} method defined by {@code Object}. * *

The returned set may contain more than one method with the same signature, if * {@code type} inherits those methods from different ancestors. For example, if it * inherits from unrelated interfaces {@code One} and {@code Two} which each define * {@code void foo();}, and if it does not itself override the {@code foo()} method, * then both {@code One.foo()} and {@code Two.foo()} will be in the returned set. * * @param type the type whose own and inherited methods are to be returned * @param typeUtils a {@link Types} object, typically returned by * {@link javax.annotation.processing.AbstractProcessor#processingEnv processingEnv}.{@link javax.annotation.processing.ProcessingEnvironment#getTypeUtils * getTypeUtils()} * @param elementUtils an {@link Elements} object, typically returned by * {@link javax.annotation.processing.AbstractProcessor#processingEnv processingEnv}.{@link javax.annotation.processing.ProcessingEnvironment#getElementUtils * getElementUtils()} */ public static ImmutableSet getLocalAndInheritedMethods( TypeElement type, Types typeUtils, Elements elementUtils) { // TODO(emcmanus): detect if the Types and Elements are the javac ones, and use // NativeOverrides if so. We may need to adjust the logic further to avoid the bug // tested for by MoreElementsTest.getLocalAndInheritedMethods_DaggerBug. Overrides overrides = new Overrides.ExplicitOverrides(typeUtils); return getLocalAndInheritedMethods(type, overrides); } private static ImmutableSet getLocalAndInheritedMethods( TypeElement type, Overrides overrides) { SetMultimap methodMap = LinkedHashMultimap.create(); getLocalAndInheritedMethods(getPackage(type), type, methodMap); // Find methods that are overridden. We do this using `Elements.overrides`, which means // that it is inherently a quadratic operation, since we have to compare every method against // every other method. We reduce the performance impact by (a) grouping methods by name, since // a method cannot override another method with a different name, and (b) making sure that // methods in ancestor types precede those in descendant types, which means we only have to // check a method against the ones that follow it in that order. Set overridden = new LinkedHashSet(); for (Collection methods : methodMap.asMap().values()) { List methodList = ImmutableList.copyOf(methods); for (int i = 0; i < methodList.size(); i++) { ExecutableElement methodI = methodList.get(i); for (int j = i + 1; j < methodList.size(); j++) { ExecutableElement methodJ = methodList.get(j); if (overrides.overrides(methodJ, methodI, type)) { overridden.add(methodI); } } } } Set methods = new LinkedHashSet(methodMap.values()); methods.removeAll(overridden); return ImmutableSet.copyOf(methods); } // Add to `methods` the instance methods from `type` that are visible to code in the // package `pkg`. This means all the instance methods from `type` itself and all instance methods // it inherits from its ancestors, except private methods and package-private methods in other // packages. This method does not take overriding into account, so it will add both an ancestor // method and a descendant method that overrides it. // `methods` is a multimap from a method name to all of the methods with that name, including // methods that override or overload one another. Within those methods, those in ancestor types // always precede those in descendant types. private static void getLocalAndInheritedMethods( PackageElement pkg, TypeElement type, SetMultimap methods) { for (TypeMirror superInterface : type.getInterfaces()) { getLocalAndInheritedMethods(pkg, MoreTypes.asTypeElement(superInterface), methods); } if (type.getSuperclass().getKind() != TypeKind.NONE) { // Visit the superclass after superinterfaces so we will always see the implementation of a // method after any interfaces that declared it. getLocalAndInheritedMethods(pkg, MoreTypes.asTypeElement(type.getSuperclass()), methods); } for (ExecutableElement method : ElementFilter.methodsIn(type.getEnclosedElements())) { if (!method.getModifiers().contains(Modifier.STATIC) && methodVisibleFromPackage(method, pkg)) { methods.put(method.getSimpleName().toString(), method); } } } static boolean methodVisibleFromPackage(ExecutableElement method, PackageElement pkg) { // We use Visibility.ofElement rather than .effectiveVisibilityOfElement because it doesn't // really matter whether the containing class is visible. If you inherit a public method // then you have a public method, regardless of whether you inherit it from a public class. Visibility visibility = Visibility.ofElement(method); switch (visibility) { case PRIVATE: return false; case DEFAULT: return getPackage(method).equals(pkg); default: return true; } } private abstract static class CastingElementVisitor extends SimpleElementVisitor6 { private final String label; CastingElementVisitor(String label) { this.label = label; } @Override protected final T defaultAction(Element e, Void ignore) { throw new IllegalArgumentException(e + " does not represent a " + label); } } private MoreElements() {} }





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