/* * Copyright (c) 2005, 2010, Oracle and/or its affiliates. All rights reserved. * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. * * This code is free software; you can redistribute it and/or modify it * under the terms of the GNU General Public License version 2 only, as * published by the Free Software Foundation. Oracle designates this * particular file as subject to the "Classpath" exception as provided * by Oracle in the LICENSE file that accompanied this code. * * This code 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 General Public License * version 2 for more details (a copy is included in the LICENSE file that * accompanied this code). * * You should have received a copy of the GNU General Public License version * 2 along with this work; if not, write to the Free Software Foundation, * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. * * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA * or visit www.oracle.com if you need additional information or have any * questions. */ package com.sun.tools.javac.model; import java.lang.annotation.Annotation; import java.lang.annotation.Inherited; import java.util.Map; import javax.lang.model.SourceVersion; import javax.lang.model.element.*; import javax.lang.model.type.DeclaredType; import javax.lang.model.util.Elements; import javax.tools.JavaFileObject; import com.sun.tools.javac.code.*; import com.sun.tools.javac.code.Symbol.*; import com.sun.tools.javac.code.TypeTags; import com.sun.tools.javac.comp.AttrContext; import com.sun.tools.javac.comp.Enter; import com.sun.tools.javac.comp.Env; import com.sun.tools.javac.main.JavaCompiler; import com.sun.tools.javac.processing.PrintingProcessor; import com.sun.tools.javac.tree.JCTree; import com.sun.tools.javac.tree.JCTree.*; import com.sun.tools.javac.tree.TreeInfo; import com.sun.tools.javac.tree.TreeScanner; import com.sun.tools.javac.util.*; import com.sun.tools.javac.util.Name; import static javax.lang.model.util.ElementFilter.methodsIn; /** * Utility methods for operating on program elements. * *

This is NOT part of any supported API. * If you write code that depends on this, you do so at your own * risk. This code and its internal interfaces are subject to change * or deletion without notice.

*/ public class JavacElements implements Elements { private JavaCompiler javaCompiler; private Symtab syms; private Names names; private Types types; private Enter enter; public static JavacElements instance(Context context) { JavacElements instance = context.get(JavacElements.class); if (instance == null) instance = new JavacElements(context); return instance; } /** * Public for use only by JavacProcessingEnvironment */ protected JavacElements(Context context) { setContext(context); } /** * Use a new context. May be called from outside to update * internal state for a new annotation-processing round. */ public void setContext(Context context) { context.put(JavacElements.class, this); javaCompiler = JavaCompiler.instance(context); syms = Symtab.instance(context); names = Names.instance(context); types = Types.instance(context); enter = Enter.instance(context); } /** * An internal-use utility that creates a reified annotation. */ public static A getAnnotation(Symbol annotated, Class annoType) { if (!annoType.isAnnotation()) throw new IllegalArgumentException("Not an annotation type: " + annoType); String name = annoType.getName(); for (Attribute.Compound anno : annotated.getAnnotationMirrors()) if (name.equals(anno.type.tsym.flatName().toString())) return AnnotationProxyMaker.generateAnnotation(anno, annoType); return null; } /** * An internal-use utility that creates a reified annotation. * This overloaded version take annotation inheritance into account. */ public static A getAnnotation(ClassSymbol annotated, Class annoType) { boolean inherited = annoType.isAnnotationPresent(Inherited.class); A result = null; while (annotated.name != annotated.name.table.names.java_lang_Object) { result = getAnnotation((Symbol)annotated, annoType); if (result != null || !inherited) break; Type sup = annotated.getSuperclass(); if (sup.tag != TypeTags.CLASS || sup.isErroneous()) break; annotated = (ClassSymbol) sup.tsym; } return result; } public PackageSymbol getPackageElement(CharSequence name) { String strName = name.toString(); if (strName.equals("")) return syms.unnamedPackage; return SourceVersion.isName(strName) ? nameToSymbol(strName, PackageSymbol.class) : null; } public ClassSymbol getTypeElement(CharSequence name) { String strName = name.toString(); return SourceVersion.isName(strName) ? nameToSymbol(strName, ClassSymbol.class) : null; } /** * Returns a symbol given the type's or packages's canonical name, * or null if the name isn't found. */ private S nameToSymbol(String nameStr, Class clazz) { Name name = names.fromString(nameStr); // First check cache. Symbol sym = (clazz == ClassSymbol.class) ? syms.classes.get(name) : syms.packages.get(name); try { if (sym == null) sym = javaCompiler.resolveIdent(nameStr); sym.complete(); return (sym.kind != Kinds.ERR && sym.exists() && clazz.isInstance(sym) && name.equals(sym.getQualifiedName())) ? clazz.cast(sym) : null; } catch (CompletionFailure e) { return null; } } public JavacSourcePosition getSourcePosition(Element e) { Pair treeTop = getTreeAndTopLevel(e); if (treeTop == null) return null; JCTree tree = treeTop.fst; JCCompilationUnit toplevel = treeTop.snd; JavaFileObject sourcefile = toplevel.sourcefile; if (sourcefile == null) return null; return new JavacSourcePosition(sourcefile, tree.pos, toplevel.lineMap); } public JavacSourcePosition getSourcePosition(Element e, AnnotationMirror a) { Pair treeTop = getTreeAndTopLevel(e); if (treeTop == null) return null; JCTree tree = treeTop.fst; JCCompilationUnit toplevel = treeTop.snd; JavaFileObject sourcefile = toplevel.sourcefile; if (sourcefile == null) return null; JCTree annoTree = matchAnnoToTree(a, e, tree); if (annoTree == null) return null; return new JavacSourcePosition(sourcefile, annoTree.pos, toplevel.lineMap); } public JavacSourcePosition getSourcePosition(Element e, AnnotationMirror a, AnnotationValue v) { // TODO: better accuracy in getSourcePosition(... AnnotationValue) return getSourcePosition(e, a); } /** * Returns the tree for an annotation given the annotated element * and the element's own tree. Returns null if the tree cannot be found. */ private JCTree matchAnnoToTree(AnnotationMirror findme, Element e, JCTree tree) { Symbol sym = cast(Symbol.class, e); class Vis extends JCTree.Visitor { List result = null; public void visitTopLevel(JCCompilationUnit tree) { result = tree.packageAnnotations; } public void visitClassDef(JCClassDecl tree) { result = tree.mods.annotations; } public void visitMethodDef(JCMethodDecl tree) { result = tree.mods.annotations; } public void visitVarDef(JCVariableDecl tree) { result = tree.mods.annotations; } } Vis vis = new Vis(); tree.accept(vis); if (vis.result == null) return null; return matchAnnoToTree(cast(Attribute.Compound.class, findme), sym.getAnnotationMirrors(), vis.result); } /** * Returns the tree for an annotation given a list of annotations * in which to search (recursively) and their corresponding trees. * Returns null if the tree cannot be found. */ private JCTree matchAnnoToTree(Attribute.Compound findme, List annos, List trees) { for (Attribute.Compound anno : annos) { for (JCAnnotation tree : trees) { JCTree match = matchAnnoToTree(findme, anno, tree); if (match != null) return match; } } return null; } /** * Returns the tree for an annotation given an Attribute to * search (recursively) and its corresponding tree. * Returns null if the tree cannot be found. */ private JCTree matchAnnoToTree(final Attribute.Compound findme, final Attribute attr, final JCTree tree) { if (attr == findme) return (tree.type.tsym == findme.type.tsym) ? tree : null; class Vis implements Attribute.Visitor { JCTree result = null; public void visitConstant(Attribute.Constant value) { } public void visitClass(Attribute.Class clazz) { } public void visitCompound(Attribute.Compound anno) { for (Pair pair : anno.values) { JCExpression expr = scanForAssign(pair.fst, tree); if (expr != null) { JCTree match = matchAnnoToTree(findme, pair.snd, expr); if (match != null) { result = match; return; } } } } public void visitArray(Attribute.Array array) { if (tree.getTag() == JCTree.NEWARRAY && types.elemtype(array.type).tsym == findme.type.tsym) { List elems = ((JCNewArray) tree).elems; for (Attribute value : array.values) { if (value == findme) { result = elems.head; return; } elems = elems.tail; } } } public void visitEnum(Attribute.Enum e) { } public void visitError(Attribute.Error e) { } } Vis vis = new Vis(); attr.accept(vis); return vis.result; } /** * Scans for a JCAssign node with a LHS matching a given * symbol, and returns its RHS. Does not scan nested JCAnnotations. */ private JCExpression scanForAssign(final MethodSymbol sym, final JCTree tree) { class TS extends TreeScanner { JCExpression result = null; public void scan(JCTree t) { if (t != null && result == null) t.accept(this); } public void visitAnnotation(JCAnnotation t) { if (t == tree) scan(t.args); } public void visitAssign(JCAssign t) { if (t.lhs.getTag() == JCTree.IDENT) { JCIdent ident = (JCIdent) t.lhs; if (ident.sym == sym) result = t.rhs; } } } TS scanner = new TS(); tree.accept(scanner); return scanner.result; } /** * Returns the tree node corresponding to this element, or null * if none can be found. */ public JCTree getTree(Element e) { Pair treeTop = getTreeAndTopLevel(e); return (treeTop != null) ? treeTop.fst : null; } public String getDocComment(Element e) { // Our doc comment is contained in a map in our toplevel, // indexed by our tree. Find our enter environment, which gives // us our toplevel. It also gives us a tree that contains our // tree: walk it to find our tree. This is painful. Pair treeTop = getTreeAndTopLevel(e); if (treeTop == null) return null; JCTree tree = treeTop.fst; JCCompilationUnit toplevel = treeTop.snd; if (toplevel.docComments == null) return null; return toplevel.docComments.get(tree); } public PackageElement getPackageOf(Element e) { return cast(Symbol.class, e).packge(); } public boolean isDeprecated(Element e) { Symbol sym = cast(Symbol.class, e); return (sym.flags() & Flags.DEPRECATED) != 0; } public Name getBinaryName(TypeElement type) { return cast(TypeSymbol.class, type).flatName(); } public Map getElementValuesWithDefaults( AnnotationMirror a) { Attribute.Compound anno = cast(Attribute.Compound.class, a); DeclaredType annotype = a.getAnnotationType(); Map valmap = anno.getElementValues(); for (ExecutableElement ex : methodsIn(annotype.asElement().getEnclosedElements())) { MethodSymbol meth = (MethodSymbol) ex; Attribute defaultValue = meth.getDefaultValue(); if (defaultValue != null && !valmap.containsKey(meth)) { valmap.put(meth, defaultValue); } } return valmap; } /** * {@inheritDoc} */ public FilteredMemberList getAllMembers(TypeElement element) { Symbol sym = cast(Symbol.class, element); Scope scope = sym.members().dupUnshared(); List closure = types.closure(sym.asType()); for (Type t : closure) addMembers(scope, t); return new FilteredMemberList(scope); } // where private void addMembers(Scope scope, Type type) { members: for (Scope.Entry e = type.asElement().members().elems; e != null; e = e.sibling) { Scope.Entry overrider = scope.lookup(e.sym.getSimpleName()); while (overrider.scope != null) { if (overrider.sym.kind == e.sym.kind && (overrider.sym.flags() & Flags.SYNTHETIC) == 0) { if (overrider.sym.getKind() == ElementKind.METHOD && overrides((ExecutableElement)overrider.sym, (ExecutableElement)e.sym, (TypeElement)type.asElement())) { continue members; } } overrider = overrider.next(); } boolean derived = e.sym.getEnclosingElement() != scope.owner; ElementKind kind = e.sym.getKind(); boolean initializer = kind == ElementKind.CONSTRUCTOR || kind == ElementKind.INSTANCE_INIT || kind == ElementKind.STATIC_INIT; if (!derived || (!initializer && e.sym.isInheritedIn(scope.owner, types))) scope.enter(e.sym); } } /** * Returns all annotations of an element, whether * inherited or directly present. * * @param e the element being examined * @return all annotations of the element */ public List getAllAnnotationMirrors(Element e) { Symbol sym = cast(Symbol.class, e); List annos = sym.getAnnotationMirrors(); while (sym.getKind() == ElementKind.CLASS) { Type sup = ((ClassSymbol) sym).getSuperclass(); if (sup.tag != TypeTags.CLASS || sup.isErroneous() || sup.tsym == syms.objectType.tsym) { break; } sym = sup.tsym; List oldAnnos = annos; for (Attribute.Compound anno : sym.getAnnotationMirrors()) { if (isInherited(anno.type) && !containsAnnoOfType(oldAnnos, anno.type)) { annos = annos.prepend(anno); } } } return annos; } /** * Tests whether an annotation type is @Inherited. */ private boolean isInherited(Type annotype) { for (Attribute.Compound anno : annotype.tsym.getAnnotationMirrors()) { if (anno.type.tsym == syms.inheritedType.tsym) return true; } return false; } /** * Tests whether a list of annotations contains an annotation * of a given type. */ private static boolean containsAnnoOfType(List annos, Type type) { for (Attribute.Compound anno : annos) { if (anno.type.tsym == type.tsym) return true; } return false; } public boolean hides(Element hiderEl, Element hideeEl) { Symbol hider = cast(Symbol.class, hiderEl); Symbol hidee = cast(Symbol.class, hideeEl); // Fields only hide fields; methods only methods; types only types. // Names must match. Nothing hides itself (just try it). if (hider == hidee || hider.kind != hidee.kind || hider.name != hidee.name) { return false; } // Only static methods can hide other methods. // Methods only hide methods with matching signatures. if (hider.kind == Kinds.MTH) { if (!hider.isStatic() || !types.isSubSignature(hider.type, hidee.type)) { return false; } } // Hider must be in a subclass of hidee's class. // Note that if M1 hides M2, and M2 hides M3, and M3 is accessible // in M1's class, then M1 and M2 both hide M3. ClassSymbol hiderClass = hider.owner.enclClass(); ClassSymbol hideeClass = hidee.owner.enclClass(); if (hiderClass == null || hideeClass == null || !hiderClass.isSubClass(hideeClass, types)) { return false; } // Hidee must be accessible in hider's class. // The method isInheritedIn is poorly named: it checks only access. return hidee.isInheritedIn(hiderClass, types); } public boolean overrides(ExecutableElement riderEl, ExecutableElement rideeEl, TypeElement typeEl) { MethodSymbol rider = cast(MethodSymbol.class, riderEl); MethodSymbol ridee = cast(MethodSymbol.class, rideeEl); ClassSymbol origin = cast(ClassSymbol.class, typeEl); return rider.name == ridee.name && // not reflexive as per JLS rider != ridee && // we don't care if ridee is static, though that wouldn't // compile !rider.isStatic() && // Symbol.overrides assumes the following ridee.isMemberOf(origin, types) && // check access and signatures; don't check return types rider.overrides(ridee, origin, types, false); } public String getConstantExpression(Object value) { return Constants.format(value); } /** * Print a representation of the elements to the given writer in * the specified order. The main purpose of this method is for * diagnostics. The exact format of the output is not * specified and is subject to change. * * @param w the writer to print the output to * @param elements the elements to print */ public void printElements(java.io.Writer w, Element... elements) { for (Element element : elements) (new PrintingProcessor.PrintingElementVisitor(w, this)).visit(element).flush(); } public Name getName(CharSequence cs) { return names.fromString(cs.toString()); } /** * Returns the tree node and compilation unit corresponding to this * element, or null if they can't be found. */ private Pair getTreeAndTopLevel(Element e) { Symbol sym = cast(Symbol.class, e); Env enterEnv = getEnterEnv(sym); if (enterEnv == null) return null; JCTree tree = TreeInfo.declarationFor(sym, enterEnv.tree); if (tree == null || enterEnv.toplevel == null) return null; return new Pair(tree, enterEnv.toplevel); } /** * Returns the best approximation for the tree node and compilation unit * corresponding to the given element, annotation and value. * If the element is null, null is returned. * If the annotation is null or cannot be found, the tree node and * compilation unit for the element is returned. * If the annotation value is null or cannot be found, the tree node and * compilation unit for the annotation is returned. */ public Pair getTreeAndTopLevel( Element e, AnnotationMirror a, AnnotationValue v) { if (e == null) return null; Pair elemTreeTop = getTreeAndTopLevel(e); if (elemTreeTop == null) return null; if (a == null) return elemTreeTop; JCTree annoTree = matchAnnoToTree(a, e, elemTreeTop.fst); if (annoTree == null) return elemTreeTop; // 6388543: if v != null, we should search within annoTree to find // the tree matching v. For now, we ignore v and return the tree of // the annotation. return new Pair(annoTree, elemTreeTop.snd); } /** * Returns a symbol's enter environment, or null if it has none. */ private Env getEnterEnv(Symbol sym) { // Get enclosing class of sym, or sym itself if it is a class // or package. TypeSymbol ts = (sym.kind != Kinds.PCK) ? sym.enclClass() : (PackageSymbol) sym; return (ts != null) ? enter.getEnv(ts) : null; } /** * Returns an object cast to the specified type. * @throws NullPointerException if the object is {@code null} * @throws IllegalArgumentException if the object is of the wrong type */ private static T cast(Class clazz, Object o) { if (! clazz.isInstance(o)) throw new IllegalArgumentException(o.toString()); return clazz.cast(o); } }