/* * Copyright (C) 2010-2020 The Project Lombok Authors. * * Permission is hereby granted, free of charge, to any person obtaining a copy * of this software and associated documentation files (the "Software"), to deal * in the Software without restriction, including without limitation the rights * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell * copies of the Software, and to permit persons to whom the Software is * furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN * THE SOFTWARE. */ package lombok.eclipse.agent; import static lombok.eclipse.Eclipse.*; import static lombok.eclipse.EcjAugments.*; import static lombok.eclipse.handlers.EclipseHandlerUtil.*; import java.lang.reflect.Method; import java.util.ArrayList; import java.util.Arrays; import java.util.Collections; import java.util.HashMap; import java.util.HashSet; import java.util.List; import java.util.Map; import java.util.Set; import java.util.concurrent.ConcurrentHashMap; import java.util.concurrent.ConcurrentMap; import org.eclipse.jdt.core.ElementChangedEvent; import org.eclipse.jdt.core.IJavaElement; import org.eclipse.jdt.core.ILocalVariable; import org.eclipse.jdt.core.IType; import org.eclipse.jdt.core.JavaModelException; import org.eclipse.jdt.core.Signature; import org.eclipse.jdt.core.compiler.CharOperation; import org.eclipse.jdt.internal.compiler.CompilationResult; import org.eclipse.jdt.internal.compiler.ast.ASTNode; import org.eclipse.jdt.internal.compiler.ast.AbstractMethodDeclaration; import org.eclipse.jdt.internal.compiler.ast.Annotation; import org.eclipse.jdt.internal.compiler.ast.Argument; import org.eclipse.jdt.internal.compiler.ast.ArrayInitializer; import org.eclipse.jdt.internal.compiler.ast.ClassLiteralAccess; import org.eclipse.jdt.internal.compiler.ast.CompilationUnitDeclaration; import org.eclipse.jdt.internal.compiler.ast.Expression; import org.eclipse.jdt.internal.compiler.ast.FieldDeclaration; import org.eclipse.jdt.internal.compiler.ast.FieldReference; import org.eclipse.jdt.internal.compiler.ast.MemberValuePair; import org.eclipse.jdt.internal.compiler.ast.MessageSend; import org.eclipse.jdt.internal.compiler.ast.MethodDeclaration; import org.eclipse.jdt.internal.compiler.ast.ReturnStatement; import org.eclipse.jdt.internal.compiler.ast.SingleNameReference; import org.eclipse.jdt.internal.compiler.ast.SingleTypeReference; import org.eclipse.jdt.internal.compiler.ast.Statement; import org.eclipse.jdt.internal.compiler.ast.ThisReference; import org.eclipse.jdt.internal.compiler.ast.TypeDeclaration; import org.eclipse.jdt.internal.compiler.ast.TypeParameter; import org.eclipse.jdt.internal.compiler.ast.TypeReference; import org.eclipse.jdt.internal.compiler.classfmt.ClassFileConstants; import org.eclipse.jdt.internal.compiler.lookup.AnnotationBinding; import org.eclipse.jdt.internal.compiler.lookup.ArrayBinding; import org.eclipse.jdt.internal.compiler.lookup.BaseTypeBinding; import org.eclipse.jdt.internal.compiler.lookup.Binding; import org.eclipse.jdt.internal.compiler.lookup.ClassScope; import org.eclipse.jdt.internal.compiler.lookup.ExtraCompilerModifiers; import org.eclipse.jdt.internal.compiler.lookup.FieldBinding; import org.eclipse.jdt.internal.compiler.lookup.MethodBinding; import org.eclipse.jdt.internal.compiler.lookup.ParameterizedTypeBinding; import org.eclipse.jdt.internal.compiler.lookup.ReferenceBinding; import org.eclipse.jdt.internal.compiler.lookup.SourceTypeBinding; import org.eclipse.jdt.internal.compiler.lookup.TypeBinding; import org.eclipse.jdt.internal.compiler.lookup.TypeConstants; import org.eclipse.jdt.internal.compiler.lookup.TypeVariableBinding; import org.eclipse.jdt.internal.compiler.lookup.UnresolvedReferenceBinding; import org.eclipse.jdt.internal.compiler.lookup.WildcardBinding; import org.eclipse.jdt.internal.core.CompilationUnit; import org.eclipse.jdt.internal.core.DeltaProcessor; import org.eclipse.jdt.internal.core.JavaElement; import org.eclipse.jdt.internal.core.JavaElementDelta; import org.eclipse.jdt.internal.core.JavaModelManager; import org.eclipse.jdt.internal.core.LocalVariable; import org.eclipse.jdt.internal.core.SourceMethod; import org.eclipse.jdt.internal.core.SourceMethodInfo; import org.eclipse.jdt.internal.core.SourceType; import org.eclipse.jdt.internal.core.SourceTypeElementInfo; import lombok.core.AST.Kind; import lombok.eclipse.Eclipse; import lombok.eclipse.EclipseAST; import lombok.eclipse.EclipseNode; import lombok.eclipse.TransformEclipseAST; import lombok.eclipse.handlers.SetGeneratedByVisitor; import lombok.patcher.Symbols; import lombok.permit.Permit; public class PatchDelegate { private static class ClassScopeEntry { ClassScopeEntry(ClassScope scope) { this.scope = scope; } final ClassScope scope; String corruptedPath; } private static ThreadLocal> visited = new ThreadLocal>() { protected List initialValue() { return new ArrayList(); } }; private static String nameOfScope(ClassScope scope) { TypeDeclaration decl = scope.referenceContext; if (decl == null) return "(unknown)"; if (decl.name == null || decl.name.length == 0) return "(unknown)"; return new String(decl.name); } private static boolean hasDelegateMarkedFieldsOrMethods(TypeDeclaration decl) { if (decl.fields != null) for (FieldDeclaration field : decl.fields) { if (field.annotations == null) continue; for (Annotation ann : field.annotations) { if (isDelegate(ann, decl)) return true; } } if (decl.methods != null) for (AbstractMethodDeclaration method : decl.methods) { if (method.annotations == null) continue; for (Annotation ann : method.annotations) { if (isDelegate(ann, decl)) return true; } } return false; } public static boolean handleDelegateForType(ClassScope scope) { if (TransformEclipseAST.disableLombok) return false; CompilationUnitDeclaration cud = scope.compilationUnitScope().referenceContext; if (scope == scope.compilationUnitScope().topLevelTypes[0].scope) { cleanupDelegateMethods(cud); } if (!hasDelegateMarkedFieldsOrMethods(scope.referenceContext)) return false; List stack = visited.get(); StringBuilder corrupted = null; for (ClassScopeEntry entry : stack) { if (corrupted != null) { corrupted.append(" -> ").append(nameOfScope(entry.scope)); } else if (entry.scope == scope) { corrupted = new StringBuilder().append(nameOfScope(scope)); } } if (corrupted != null) { boolean found = false; String path = corrupted.toString(); for (ClassScopeEntry entry : stack) { if (!found && entry.scope == scope) found = true; if (found) entry.corruptedPath = path; } } else { ClassScopeEntry entry = new ClassScopeEntry(scope); stack.add(entry); try { TypeDeclaration decl = scope.referenceContext; if (decl != null) { EclipseAST eclipseAst = TransformEclipseAST.getAST(cud, true); List methodsToDelegate = new ArrayList(); fillMethodBindingsForFields(cud, scope, methodsToDelegate); if (entry.corruptedPath != null) { eclipseAst.get(scope.referenceContext).addError("No @Delegate methods created because there's a loop: " + entry.corruptedPath); } else { generateDelegateMethods(eclipseAst.get(decl), methodsToDelegate, DelegateReceiver.FIELD); } methodsToDelegate.clear(); fillMethodBindingsForMethods(cud, scope, methodsToDelegate); if (entry.corruptedPath != null) { eclipseAst.get(scope.referenceContext).addError("No @Delegate methods created because there's a loop: " + entry.corruptedPath); } else { generateDelegateMethods(eclipseAst.get(decl), methodsToDelegate, DelegateReceiver.METHOD); } } } finally { stack.remove(stack.size() - 1); if (stack.isEmpty()) { notifyDelegateMethodsAdded(cud); } } } return false; } public static IJavaElement[] getChildren(IJavaElement[] returnValue, SourceTypeElementInfo javaElement) { if (Symbols.hasSymbol("lombok.skipdelegates")) return returnValue; List delegateMethods = getDelegateMethods((SourceType) javaElement.getHandle()); if (delegateMethods != null) { return concat(returnValue, delegateMethods.toArray(new IJavaElement[0]), IJavaElement.class); } return returnValue; } /** * Returns a string containing the signature of a method that appears (erased) at least twice in the list. * If no duplicates are present, {@code null} is returned. */ private static String containsDuplicates(List tuples) { Set sigs = new HashSet(); for (BindingTuple tuple : tuples) { if (!sigs.add(printSig(tuple.parameterized))) return printSig(tuple.parameterized); } return null; } public static void markHandled(Annotation annotation) { Annotation_applied.set(annotation, true); } private static void fillMethodBindingsForFields(CompilationUnitDeclaration cud, ClassScope scope, List methodsToDelegate) { TypeDeclaration decl = scope.referenceContext; if (decl == null) return; if (decl.fields != null) for (FieldDeclaration field : decl.fields) { if (field.annotations == null) continue; for (Annotation ann : field.annotations) { if (!isDelegate(ann, decl)) continue; if (Annotation_applied.getAndSet(ann, true)) continue; if ((field.modifiers & ClassFileConstants.AccStatic) != 0) { EclipseAST eclipseAst = TransformEclipseAST.getAST(cud, true); eclipseAst.get(ann).addError(LEGALITY_OF_DELEGATE); break; } List rawTypes = rawTypes(ann, "types"); List excludedRawTypes = rawTypes(ann, "excludes"); List methodsToExclude = new ArrayList(); List methodsToDelegateForThisAnn = new ArrayList(); try { for (ClassLiteralAccess cla : excludedRawTypes) { addAllMethodBindings(methodsToExclude, cla.type.resolveType(decl.initializerScope), new HashSet(), field.name, ann); } Set banList = findAlreadyImplementedMethods(decl); for (BindingTuple excluded : methodsToExclude) banList.add(printSig(excluded.parameterized)); if (rawTypes.isEmpty()) { addAllMethodBindings(methodsToDelegateForThisAnn, field.type.resolveType(decl.initializerScope), banList, field.name, ann); } else { for (ClassLiteralAccess cla : rawTypes) { addAllMethodBindings(methodsToDelegateForThisAnn, cla.type.resolveType(decl.initializerScope), banList, field.name, ann); } } } catch (DelegateRecursion e) { EclipseAST eclipseAst = TransformEclipseAST.getAST(cud, true); eclipseAst.get(ann).addError(String.format(RECURSION_NOT_ALLOWED, new String(e.member), new String(e.type))); break; } // Not doing this right now because of problems - see commented-out-method for info. // removeExistingMethods(methodsToDelegate, decl, scope); String dupe = containsDuplicates(methodsToDelegateForThisAnn); if (dupe != null) { EclipseAST eclipseAst = TransformEclipseAST.getAST(cud, true); eclipseAst.get(ann).addError("The method '" + dupe + "' is being delegated by more than one specified type."); } else { methodsToDelegate.addAll(methodsToDelegateForThisAnn); } } } } private static final String LEGALITY_OF_DELEGATE = "@Delegate is legal only on instance fields or no-argument instance methods."; private static final String RECURSION_NOT_ALLOWED = "@Delegate does not support recursion (delegating to a type that itself has @Delegate members). Member \"%s\" is @Delegate in type \"%s\""; private static void fillMethodBindingsForMethods(CompilationUnitDeclaration cud, ClassScope scope, List methodsToDelegate) { TypeDeclaration decl = scope.referenceContext; if (decl == null) return; if (decl.methods != null) for (AbstractMethodDeclaration methodDecl : decl.methods) { if (methodDecl.annotations == null) continue; for (Annotation ann : methodDecl.annotations) { if (!isDelegate(ann, decl)) continue; if (Annotation_applied.getAndSet(ann, true)) continue; if (!(methodDecl instanceof MethodDeclaration)) { EclipseAST eclipseAst = TransformEclipseAST.getAST(cud, true); eclipseAst.get(ann).addError(LEGALITY_OF_DELEGATE); break; } if (methodDecl.arguments != null) { EclipseAST eclipseAst = TransformEclipseAST.getAST(cud, true); eclipseAst.get(ann).addError(LEGALITY_OF_DELEGATE); break; } if ((methodDecl.modifiers & ClassFileConstants.AccStatic) != 0) { EclipseAST eclipseAst = TransformEclipseAST.getAST(cud, true); eclipseAst.get(ann).addError(LEGALITY_OF_DELEGATE); break; } MethodDeclaration method = (MethodDeclaration) methodDecl; List rawTypes = rawTypes(ann, "types"); List excludedRawTypes = rawTypes(ann, "excludes"); List methodsToExclude = new ArrayList(); List methodsToDelegateForThisAnn = new ArrayList(); try { for (ClassLiteralAccess cla : excludedRawTypes) { addAllMethodBindings(methodsToExclude, cla.type.resolveType(decl.initializerScope), new HashSet(), method.selector, ann); } Set banList = findAlreadyImplementedMethods(decl); for (BindingTuple excluded : methodsToExclude) banList.add(printSig(excluded.parameterized)); if (rawTypes.isEmpty()) { if (method.returnType == null) continue; addAllMethodBindings(methodsToDelegateForThisAnn, method.returnType.resolveType(decl.initializerScope), banList, method.selector, ann); } else { for (ClassLiteralAccess cla : rawTypes) { addAllMethodBindings(methodsToDelegateForThisAnn, cla.type.resolveType(decl.initializerScope), banList, method.selector, ann); } } } catch (DelegateRecursion e) { EclipseAST eclipseAst = TransformEclipseAST.getAST(cud, true); eclipseAst.get(ann).addError(String.format(RECURSION_NOT_ALLOWED, new String(e.member), new String(e.type))); break; } // Not doing this right now because of problems - see commented-out-method for info. // removeExistingMethods(methodsToDelegate, decl, scope); String dupe = containsDuplicates(methodsToDelegateForThisAnn); if (dupe != null) { EclipseAST eclipseAst = TransformEclipseAST.getAST(cud, true); eclipseAst.get(ann).addError("The method '" + dupe + "' is being delegated by more than one specified type."); } else { methodsToDelegate.addAll(methodsToDelegateForThisAnn); } } } } private static boolean isDelegate(Annotation ann, TypeDeclaration decl) { if (ann.type == null) return false; if (!charArrayEquals("Delegate", ann.type.getLastToken())) return false; TypeBinding tb = ann.type.resolveType(decl.initializerScope); if (tb == null) return false; if (!charArrayEquals("lombok", tb.qualifiedPackageName()) && !charArrayEquals("lombok.experimental", tb.qualifiedPackageName())) return false; if (!charArrayEquals("Delegate", tb.qualifiedSourceName())) return false; return true; } private static List rawTypes(Annotation ann, String name) { List rawTypes = new ArrayList(); for (MemberValuePair pair : ann.memberValuePairs()) { if (charArrayEquals(name, pair.name)) { if (pair.value instanceof ArrayInitializer) { for (Expression expr : ((ArrayInitializer)pair.value).expressions) { if (expr instanceof ClassLiteralAccess) rawTypes.add((ClassLiteralAccess) expr); } } if (pair.value instanceof ClassLiteralAccess) { rawTypes.add((ClassLiteralAccess) pair.value); } } } return rawTypes; } /* * We may someday finish this method. Steps to be completed: * * (A) Turn any Parameterized anythings into non-parameterized versions. Resolving parameterized stuff will definitely not work safely. * (B) scope.problemReporter() will need to return a noop reporter as various errors are marked off. * (C) Find a way to do _something_ for references to typevars (i.e. 'T') which are declared on the method itself. * (D) getTypeBinding isn't public, so call it via reflection. */ // private static TypeBinding safeResolveAndErase(TypeReference ref, Scope scope) { // if (ref.resolvedType != null) { // return ref.resolvedType.isValidBinding() ? ref.resolvedType : null; // } // // try { // TypeBinding bind = ref.getTypeBinding(scope); // if (!bind.isValidBinding()) return null; // } catch (AbortCompilation e) { // return null; // } // return bind.erasure(); // } /* * Not using this because calling clone.resolveType() taints a bunch of caches and reports erroneous errors. */ // private static void removeExistingMethods(List list, TypeDeclaration decl, ClassScope scope) { // for (AbstractMethodDeclaration methodDecl : decl.methods) { // if (!(methodDecl instanceof MethodDeclaration)) continue; // MethodDeclaration md = (MethodDeclaration) methodDecl; // char[] name = md.selector; // TypeBinding[] args = md.arguments == null ? new TypeBinding[0] : new TypeBinding[md.arguments.length]; // for (int i = 0; i < args.length; i++) { // TypeReference clone = Eclipse.copyType(md.arguments[i].type, md.arguments[i]); // args[i] = clone.resolveType(scope).erasure(); // This is the problematic line // } // Iterator it = list.iterator(); // methods: // while (it.hasNext()) { // MethodBinding mb = it.next().parameterized; // if (!Arrays.equals(mb.selector, name)) continue; // int paramLen = mb.parameters == null ? 0 : mb.parameters.length; // if (paramLen != args.length) continue; // if (md.typeParameters == null || md.typeParameters.length == 0) { // for (int i = 0; i < paramLen; i++) { // if (!mb.parameters[i].erasure().isEquivalentTo(args[i])) continue methods; // } // } else { // for (int i = 0; i < paramLen; i++) { // if (!mb.parameters[i].erasure().isEquivalentTo(args[i])) ; // } // //BUG #???: We erase the method's parameter types using the class scope, but we should be using the method scope. // // In practice this is no problem UNLESS the method has type parameters, such as T[] toArray(T[] in). // // In this case the class scope cannot resolve the T[] parameter and erase it to Object[], which is a big problem because // // it would mean manually writing X[] toArray(X[] in) does NOT stop lombok from ALSO trying to make the delegated toArray method, // // thus causing an error (2 methods with post-erasure duplicate signatures). Our 'fix' for this is to treat any method with type parameters // // as if each parameter's type matches anything else; so, if the name matches and the parameter count, we DONT generate it, even if its just // // an overloaded method. // // // // The reason we do this now is because making that MethodScope properly is effectively impossible at this step, so we need to do the resolving // // ourselves, which involves chasing down array bindings (T[]), following the path down type variables, i.e. , and then // // resolving the final result of this exercise against the class scope. // // // When this crappy incomplete workaround of ours occurs, we end up in this else block, which does nothing and thus we fall through and remove // // the method. // } // it.remove(); // Method already exists in this class - don't create a delegating implementation. // } // } // } private static void generateDelegateMethods(EclipseNode typeNode, List methods, DelegateReceiver delegateReceiver) { CompilationUnitDeclaration top = (CompilationUnitDeclaration) typeNode.top().get(); String qualifiedName = new String(CharOperation.concatWith(getQualifiedInnerName(typeNode.up(), typeNode.getName().toCharArray()), '$')); SourceType sourceType = getSourceType(top, qualifiedName); List delegateSourceMethods = getDelegateMethods(sourceType); for (BindingTuple pair : methods) { EclipseNode annNode = typeNode.getAst().get(pair.responsible); MethodDeclaration method = createDelegateMethod(pair.fieldName, typeNode, pair, top.compilationResult, annNode, delegateReceiver); if (method != null) { SetGeneratedByVisitor visitor = new SetGeneratedByVisitor(annNode.get()); method.traverse(visitor, ((TypeDeclaration)typeNode.get()).scope); injectMethod(typeNode, method); if (delegateSourceMethods != null) { delegateSourceMethods.add(DelegateSourceMethod.forMethodDeclaration(sourceType, method)); } } } } public static void checkConflictOfTypeVarNames(BindingTuple binding, EclipseNode typeNode) throws CantMakeDelegates { TypeVariableBinding[] typeVars = binding.parameterized.typeVariables(); if (typeVars == null || typeVars.length == 0) return; Set usedInOurType = new HashSet(); EclipseNode enclosingType = typeNode; while (enclosingType != null) { if (enclosingType.getKind() == Kind.TYPE) { TypeParameter[] typeParameters = ((TypeDeclaration)enclosingType.get()).typeParameters; if (typeParameters != null) { for (TypeParameter param : typeParameters) { if (param.name != null) usedInOurType.add(new String(param.name)); } } } enclosingType = enclosingType.up(); } Set usedInMethodSig = new HashSet(); for (TypeVariableBinding var : typeVars) { char[] sourceName = var.sourceName(); if (sourceName != null) usedInMethodSig.add(new String(sourceName)); } usedInMethodSig.retainAll(usedInOurType); if (usedInMethodSig.isEmpty()) return; // We might be delegating a List, and we are making method toArray(). A conflict is possible. // But only if the toArray method also uses type vars from its class, otherwise we're only shadowing, // which is okay as we'll add a @SuppressWarnings. TypeVarFinder finder = new TypeVarFinder(); finder.visitRaw(binding.base); Set names = new HashSet(finder.getTypeVariables()); names.removeAll(usedInMethodSig); if (!names.isEmpty()) { // We have a confirmed conflict. We could dig deeper as this may still be a false alarm, but its already an exceedingly rare case. CantMakeDelegates cmd = new CantMakeDelegates(); cmd.conflicted = usedInMethodSig; throw cmd; } } public static class CantMakeDelegates extends Exception { public Set conflicted; } public static class TypeVarFinder extends EclipseTypeBindingScanner { private Set typeVars = new HashSet(); public Set getTypeVariables() { return typeVars; } @Override public void visitTypeVariable(TypeVariableBinding binding) { if (binding.sourceName != null) typeVars.add(new String(binding.sourceName)); super.visitTypeVariable(binding); } } public abstract static class EclipseTypeBindingScanner { public void visitRaw(Binding binding) { if (binding == null) return; if (binding instanceof MethodBinding) visitMethod((MethodBinding) binding); if (binding instanceof BaseTypeBinding) visitBase((BaseTypeBinding) binding); if (binding instanceof ArrayBinding) visitArray((ArrayBinding) binding); if (binding instanceof UnresolvedReferenceBinding) visitUnresolved((UnresolvedReferenceBinding) binding); if (binding instanceof WildcardBinding) visitWildcard((WildcardBinding) binding); if (binding instanceof TypeVariableBinding) visitTypeVariable((TypeVariableBinding) binding); if (binding instanceof ParameterizedTypeBinding) visitParameterized((ParameterizedTypeBinding) binding); if (binding instanceof ReferenceBinding) visitReference((ReferenceBinding) binding); } public void visitReference(ReferenceBinding binding) { } public void visitParameterized(ParameterizedTypeBinding binding) { visitRaw(binding.genericType()); TypeVariableBinding[] typeVars = binding.typeVariables(); if (typeVars != null) for (TypeVariableBinding child : typeVars) { visitRaw(child); } } public void visitTypeVariable(TypeVariableBinding binding) { visitRaw(binding.superclass); ReferenceBinding[] supers = binding.superInterfaces(); if (supers != null) for (ReferenceBinding child : supers) { visitRaw(child); } } public void visitWildcard(WildcardBinding binding) { visitRaw(binding.bound); } public void visitUnresolved(UnresolvedReferenceBinding binding) { } public void visitArray(ArrayBinding binding) { visitRaw(binding.leafComponentType()); } public void visitBase(BaseTypeBinding binding) { } public void visitMethod(MethodBinding binding) { if (binding.parameters != null) for (TypeBinding child : binding.parameters) { visitRaw(child); } visitRaw(binding.returnType); if (binding.thrownExceptions != null) for (TypeBinding child : binding.thrownExceptions) { visitRaw(child); } TypeVariableBinding[] typeVars = binding.typeVariables(); if (typeVars != null) for (TypeVariableBinding child : typeVars) { visitRaw(child.superclass); ReferenceBinding[] supers = child.superInterfaces(); if (supers != null) for (ReferenceBinding child2 : supers) { visitRaw(child2); } } } } private static MethodDeclaration createDelegateMethod(char[] name, EclipseNode typeNode, BindingTuple pair, CompilationResult compilationResult, EclipseNode annNode, DelegateReceiver delegateReceiver) { /* public ReturnType methodName(ParamType1 name1, ParamType2 name2, ...) throws T1, T2, ... { * (return) delegate.methodName(name1, name2); * } */ boolean isVarargs = (pair.base.modifiers & ClassFileConstants.AccVarargs) != 0; try { checkConflictOfTypeVarNames(pair, typeNode); } catch (CantMakeDelegates e) { annNode.addError("There's a conflict in the names of type parameters. Fix it by renaming the following type parameters of your class: " + e.conflicted); return null; } ASTNode source = annNode.get(); int pS = source.sourceStart, pE = source.sourceEnd; MethodBinding binding = pair.parameterized; MethodDeclaration method = new MethodDeclaration(compilationResult); setGeneratedBy(method, source); method.sourceStart = pS; method.sourceEnd = pE; method.modifiers = ClassFileConstants.AccPublic; method.returnType = makeType(binding.returnType, source, false); boolean isDeprecated = binding.isDeprecated(); method.selector = binding.selector; if (binding.thrownExceptions != null && binding.thrownExceptions.length > 0) { method.thrownExceptions = new TypeReference[binding.thrownExceptions.length]; for (int i = 0; i < method.thrownExceptions.length; i++) { method.thrownExceptions[i] = makeType(binding.thrownExceptions[i], source, false); } } MessageSend call = new MessageSend(); call.sourceStart = pS; call.sourceEnd = pE; call.nameSourcePosition = pos(source); setGeneratedBy(call, source); call.receiver = delegateReceiver.get(source, name); call.selector = binding.selector; if (binding.typeVariables != null && binding.typeVariables.length > 0) { method.typeParameters = new TypeParameter[binding.typeVariables.length]; call.typeArguments = new TypeReference[binding.typeVariables.length]; for (int i = 0; i < method.typeParameters.length; i++) { method.typeParameters[i] = new TypeParameter(); method.typeParameters[i].sourceStart = pS; method.typeParameters[i].sourceEnd = pE; setGeneratedBy(method.typeParameters[i], source); method.typeParameters[i].name = binding.typeVariables[i].sourceName; call.typeArguments[i] = new SingleTypeReference(binding.typeVariables[i].sourceName, pos(source)); setGeneratedBy(call.typeArguments[i], source); ReferenceBinding super1 = binding.typeVariables[i].superclass; ReferenceBinding[] super2 = binding.typeVariables[i].superInterfaces; if (super2 == null) super2 = new ReferenceBinding[0]; if (super1 != null || super2.length > 0) { int offset = super1 == null ? 0 : 1; method.typeParameters[i].bounds = new TypeReference[super2.length + offset - 1]; if (super1 != null) method.typeParameters[i].type = makeType(super1, source, false); else method.typeParameters[i].type = makeType(super2[0], source, false); int ctr = 0; for (int j = (super1 == null) ? 1 : 0; j < super2.length; j++) { method.typeParameters[i].bounds[ctr] = makeType(super2[j], source, false); method.typeParameters[i].bounds[ctr++].bits |= ASTNode.IsSuperType; } } } } if (isDeprecated) { method.annotations = new Annotation[] { generateDeprecatedAnnotation(source) }; } method.bits |= ECLIPSE_DO_NOT_TOUCH_FLAG; if (binding.parameters != null && binding.parameters.length > 0) { method.arguments = new Argument[binding.parameters.length]; call.arguments = new Expression[method.arguments.length]; for (int i = 0; i < method.arguments.length; i++) { AbstractMethodDeclaration sourceElem; try { sourceElem = pair.base.sourceMethod(); } catch (Exception e) { sourceElem = null; } char[] argName; if (sourceElem == null) argName = ("arg" + i).toCharArray(); else { argName = sourceElem.arguments[i].name; } method.arguments[i] = new Argument( argName, pos(source), makeType(binding.parameters[i], source, false), ClassFileConstants.AccFinal); setGeneratedBy(method.arguments[i], source); call.arguments[i] = new SingleNameReference(argName, pos(source)); setGeneratedBy(call.arguments[i], source); } if (isVarargs) { method.arguments[method.arguments.length - 1].type.bits |= ASTNode.IsVarArgs; } } Statement body; if (method.returnType instanceof SingleTypeReference && ((SingleTypeReference)method.returnType).token == TypeConstants.VOID) { body = call; } else { body = new ReturnStatement(call, source.sourceStart, source.sourceEnd); setGeneratedBy(body, source); } method.statements = new Statement[] {body}; return method; } private static void cleanupDelegateMethods(CompilationUnitDeclaration cud) { CompilationUnit compilationUnit = getCompilationUnit(cud); if (compilationUnit != null) { EclipseAugments.CompilationUnit_delegateMethods.clear(compilationUnit); } } private static boolean javaModelManagerAvailable = true; private static void notifyDelegateMethodsAdded(CompilationUnitDeclaration cud) { CompilationUnit compilationUnit = getCompilationUnit(cud); if (compilationUnit != null && javaModelManagerAvailable) { try { DeltaProcessor deltaProcessor = JavaModelManager.getJavaModelManager().getDeltaProcessor(); deltaProcessor.fire(new JavaElementDelta(compilationUnit), ElementChangedEvent.POST_CHANGE); } catch (NoClassDefFoundError e) { javaModelManagerAvailable = false; } } } private static CompilationUnit getCompilationUnit(Object iCompilationUnit) { if (iCompilationUnit instanceof CompilationUnit) { CompilationUnit compilationUnit = (CompilationUnit) iCompilationUnit; return compilationUnit.originalFromClone(); } return null; } private static CompilationUnit getCompilationUnit(CompilationUnitDeclaration cud) { return getCompilationUnit(cud.compilationResult.compilationUnit); } private static final class DelegateSourceMethod extends SourceMethod { private DelegateSourceMethodInfo sourceMethodInfo; private static DelegateSourceMethod forMethodDeclaration(JavaElement parent, MethodDeclaration method) { Argument[] arguments = method.arguments != null ? method.arguments : new Argument[0]; String[] parameterTypes = new String[arguments.length]; for (int i = 0; i < arguments.length; i++) { parameterTypes[i] = Signature.createTypeSignature(CharOperation.concatWith(arguments[i].type.getParameterizedTypeName(), '.'), false); } return new DelegateSourceMethod(parent, new String(method.selector), parameterTypes, method); } private DelegateSourceMethod(JavaElement parent, String name, String[] parameterTypes, MethodDeclaration md) { super(parent, name, parameterTypes); sourceMethodInfo = new DelegateSourceMethodInfo(this, md); } @Override public Object getElementInfo() throws JavaModelException { return sourceMethodInfo; } /** * Disable refactoring for delegate methods */ @Override public boolean isReadOnly() { return true; } /** * This is required to prevent duplicate entries in the outline */ @Override public boolean equals(Object o) { return this == o; } public static final class DelegateSourceMethodInfo extends SourceMethodInfo { DelegateSourceMethodInfo(DelegateSourceMethod delegateSourceMethod, MethodDeclaration md) { int pS = md.sourceStart; int pE = md.sourceEnd; Argument[] methodArguments = md.arguments != null ? md.arguments : new Argument[0]; char[][] argumentNames = new char[methodArguments.length][]; arguments = new ILocalVariable[methodArguments.length]; for (int i = 0; i < methodArguments.length; i++) { Argument argument = methodArguments[i]; argumentNames[i] = argument.name; arguments[i] = new LocalVariable(delegateSourceMethod, new String(argument.name), pS, pE, pS, pS, delegateSourceMethod.getParameterTypes()[i], argument.annotations, argument.modifiers, true); } setArgumentNames(argumentNames); setSourceRangeStart(pS); setSourceRangeEnd(pE); setNameSourceStart(pS); setNameSourceEnd(pE); setExceptionTypeNames(CharOperation.NO_CHAR_CHAR); setReturnType(md.returnType == null ? new char[]{'v', 'o','i', 'd'} : CharOperation.concatWith(md.returnType.getParameterizedTypeName(), '.')); setFlags(md.modifiers); } } } private static List getDelegateMethods(SourceType sourceType) { if (sourceType != null) { CompilationUnit compilationUnit = getCompilationUnit(sourceType.getCompilationUnit()); if (compilationUnit != null) { ConcurrentMap> map = EclipseAugments.CompilationUnit_delegateMethods.setIfAbsent(compilationUnit, new ConcurrentHashMap>()); List newList = new ArrayList(); List oldList = map.putIfAbsent(sourceType.getTypeQualifiedName(), newList); return oldList != null ? oldList : newList; } } return null; } private static SourceType getSourceType(CompilationUnitDeclaration cud, String typeName) { CompilationUnit compilationUnit = getCompilationUnit(cud); if (compilationUnit != null) { try { for (IType type : compilationUnit.getAllTypes()) { if (type instanceof SourceType && type.getTypeQualifiedName().equals(typeName)) { return (SourceType) type; } } } catch (JavaModelException e) { // Ignore } } return null; } private static final class Reflection { public static final Method classScopeBuildFieldsAndMethodsMethod; public static final Throwable initCause; static { Method m = null; Throwable c = null; try { m = Permit.getMethod(ClassScope.class, "buildFieldsAndMethods"); } catch (Throwable t) { c = t; // That's problematic, but as long as no local classes are used we don't actually need it. // Better fail on local classes than crash altogether. } classScopeBuildFieldsAndMethodsMethod = m; initCause = c; } } private static void addAllMethodBindings(List list, TypeBinding binding, Set banList, char[] fieldName, ASTNode responsible) throws DelegateRecursion { banList.addAll(METHODS_IN_OBJECT); addAllMethodBindings0(list, binding, banList, fieldName, responsible); } private static class DelegateRecursion extends Throwable { final char[] type, member; public DelegateRecursion(char[] type, char[] member) { this.type = type; this.member = member; } } private static void addAllMethodBindings0(List list, TypeBinding binding, Set banList, char[] fieldName, ASTNode responsible) throws DelegateRecursion { if (binding instanceof SourceTypeBinding) { ClassScope scope = ((SourceTypeBinding) binding).scope; if (scope != null) scope.environment().globalOptions.storeAnnotations = true; } if (binding == null) return; TypeBinding inner; if (binding instanceof ParameterizedTypeBinding) { inner = ((ParameterizedTypeBinding) binding).genericType(); } else { inner = binding; } if (inner instanceof SourceTypeBinding) { ClassScope cs = ((SourceTypeBinding)inner).scope; if (cs != null) { try { Permit.invoke(Reflection.initCause, Reflection.classScopeBuildFieldsAndMethodsMethod, cs); } catch (Exception e) { // See 'Reflection' class for why we ignore this exception. } } } if (!(binding instanceof ReferenceBinding)) return; ReferenceBinding rb = (ReferenceBinding) binding; MethodBinding[] availableMethods = rb.availableMethods(); FieldBinding[] availableFields = rb.availableFields(); failIfContainsAnnotation(binding, availableMethods); failIfContainsAnnotation(binding, availableFields); MethodBinding[] parameterizedSigs = availableMethods; MethodBinding[] baseSigs = parameterizedSigs; if (binding instanceof ParameterizedTypeBinding) { baseSigs = ((ParameterizedTypeBinding)binding).genericType().availableMethods(); if (baseSigs.length != parameterizedSigs.length) { // The last known state of eclipse source says this can't happen, so we rely on it, // but if this invariant is broken, better to go with 'arg0' naming instead of crashing. baseSigs = parameterizedSigs; } } for (int i = 0; i < parameterizedSigs.length; i++) { MethodBinding mb = parameterizedSigs[i]; String sig = printSig(mb); if (mb.isStatic()) continue; if (mb.isBridge()) continue; if (mb.isConstructor()) continue; if (mb.isDefaultAbstract()) continue; if (!mb.isPublic()) continue; if (mb.isSynthetic()) continue; if (!banList.add(sig)) continue; // If add returns false, it was already in there. BindingTuple pair = new BindingTuple(mb, baseSigs[i], fieldName, responsible); list.add(pair); } addAllMethodBindings0(list, rb.superclass(), banList, fieldName, responsible); ReferenceBinding[] interfaces = rb.superInterfaces(); if (interfaces != null) { for (ReferenceBinding iface : interfaces) addAllMethodBindings0(list, iface, banList, fieldName, responsible); } } private static Set findAlreadyImplementedMethods(TypeDeclaration decl) { Set sigs = new HashSet(); for (AbstractMethodDeclaration md : decl.methods) { if (md.isStatic()) continue; if ((md.modifiers & ClassFileConstants.AccBridge) != 0) continue; if (md.isConstructor()) continue; if ((md.modifiers & ExtraCompilerModifiers.AccDefaultAbstract) != 0) continue; if ((md.modifiers & ClassFileConstants.AccPublic) == 0) continue; if ((md.modifiers & ClassFileConstants.AccSynthetic) != 0) continue; sigs.add(printSig(md, decl.scope)); } return sigs; } private static final char[] STRING_LOMBOK = new char[] {'l', 'o', 'm', 'b', 'o', 'k'}; private static final char[] STRING_EXPERIMENTAL = new char[] {'e', 'x', 'p', 'e', 'r', 'i', 'm', 'e', 'n', 't', 'a', 'l'}; private static final char[] STRING_DELEGATE = new char[] {'D', 'e', 'l', 'e', 'g', 'a', 't', 'e'}; private static void failIfContainsAnnotation(TypeBinding parent, Binding[] bindings) throws DelegateRecursion { if (bindings == null) return; for (Binding b : bindings) { AnnotationBinding[] anns = null; if (b instanceof MethodBinding) anns = ((MethodBinding) b).getAnnotations(); if (b instanceof FieldBinding) anns = ((FieldBinding) b).getAnnotations(); // anns = b.getAnnotations() would make a heck of a lot more sense, but that is a late addition to ecj, so would cause NoSuchMethodErrors! Don't use that! if (anns == null) continue; for (AnnotationBinding ann : anns) { char[][] name = null; try { name = ann.getAnnotationType().compoundName; } catch (Exception ignore) {} if (name == null || name.length < 2 || name.length > 3) continue; if (!Arrays.equals(STRING_LOMBOK, name[0])) continue; if (!Arrays.equals(STRING_DELEGATE, name[name.length - 1])) continue; if (name.length == 3 && !Arrays.equals(STRING_EXPERIMENTAL, name[1])) continue; throw new DelegateRecursion(parent.readableName(), b.readableName()); } } } private static final class BindingTuple { BindingTuple(MethodBinding parameterized, MethodBinding base, char[] fieldName, ASTNode responsible) { this.parameterized = parameterized; this.base = base; this.fieldName = fieldName; this.responsible = responsible; } final MethodBinding parameterized, base; final char[] fieldName; final ASTNode responsible; @Override public String toString() { return String.format("{param: %s, base: %s, fieldName: %s}", parameterized == null ? "(null)" : printSig(parameterized), base == null ? "(null)" : printSig(base), new String(fieldName)); } } private static final List METHODS_IN_OBJECT = Collections.unmodifiableList(Arrays.asList( "hashCode()", "canEqual(java.lang.Object)", //Not in j.l.Object, but it goes with hashCode and equals so if we ignore those two, we should ignore this one. "equals(java.lang.Object)", "wait()", "wait(long)", "wait(long, int)", "notify()", "notifyAll()", "toString()", "getClass()", "clone()", "finalize()")); private static String printSig(MethodBinding binding) { StringBuilder signature = new StringBuilder(); signature.append(binding.selector); signature.append("("); boolean first = true; if (binding.parameters != null) for (TypeBinding param : binding.parameters) { if (!first) signature.append(", "); first = false; signature.append(typeBindingToSignature(param)); } signature.append(")"); return signature.toString(); } private static String printSig(AbstractMethodDeclaration md, ClassScope scope) { StringBuilder signature = new StringBuilder(); signature.append(md.selector); signature.append("("); boolean first = true; if (md.arguments != null) { TypeParameter[] typeParameters = md.typeParameters(); Map typeParametersMap = new HashMap(); if (typeParameters != null) { for (TypeParameter typeParameter : typeParameters) { typeParametersMap.put(new String(typeParameter.name), typeParameter); } } for (Argument argument : md.arguments) { TypeBinding typeBinding = makeTypeBinding(argument.type, typeParametersMap, scope); if (!first) signature.append(", "); first = false; signature.append(typeBindingToSignature(typeBinding)); } } signature.append(")"); return signature.toString(); } private static TypeBinding makeTypeBinding(TypeReference typeReference, Map typeParametersMap, ClassScope scope) { char[][] typeName = typeReference.getTypeName(); String typeNameString = Eclipse.toQualifiedName(typeName); TypeParameter typeParameter = typeParametersMap.get(typeNameString); if (typeParameter != null) { if (typeParameter.type != null) { typeName = typeParameter.type.getTypeName(); } else { typeName = TypeConstants.JAVA_LANG_OBJECT; } } TypeBinding typeBinding = scope.getType(typeName, typeName.length); if (typeReference.dimensions() > 0) { typeBinding = scope.createArrayType(typeBinding, typeReference.dimensions()); } return typeBinding; } private static String typeBindingToSignature(TypeBinding binding) { binding = binding.erasure(); if (binding != null && binding.isBaseType()) { return new String (binding.sourceName()); } else if (binding instanceof ReferenceBinding) { String pkg = binding.qualifiedPackageName() == null ? "" : new String(binding.qualifiedPackageName()); String qsn = binding.qualifiedSourceName() == null ? "" : new String(binding.qualifiedSourceName()); return pkg.isEmpty() ? qsn : (pkg + "." + qsn); } else if (binding instanceof ArrayBinding) { StringBuilder out = new StringBuilder(); out.append(typeBindingToSignature(binding.leafComponentType())); for (int i = 0; i < binding.dimensions(); i++) out.append("[]"); return out.toString(); } return ""; } private static boolean charArrayEquals(String s, char[] c) { if (s == null) return c == null; if (c == null) return false; if (s.length() != c.length) return false; for (int i = 0; i < s.length(); i++) if (s.charAt(i) != c[i]) return false; return true; } private enum DelegateReceiver { METHOD { public Expression get(final ASTNode source, char[] name) { MessageSend call = new MessageSend(); call.sourceStart = source.sourceStart; call.sourceEnd = source.sourceEnd; call.nameSourcePosition = pos(source); setGeneratedBy(call, source); call.selector = name; call.receiver = new ThisReference(source.sourceStart, source.sourceEnd); setGeneratedBy(call.receiver, source); return call; } }, FIELD { public Expression get(final ASTNode source, char[] name) { FieldReference fieldRef = new FieldReference(name, pos(source)); setGeneratedBy(fieldRef, source); fieldRef.receiver = new ThisReference(source.sourceStart, source.sourceEnd); setGeneratedBy(fieldRef.receiver, source); return fieldRef; } }; public abstract Expression get(final ASTNode source, char[] name); } }