/* * Copyright (C) 2013-2021 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.handlers; import static lombok.core.handlers.HandlerUtil.handleFlagUsage; import static lombok.eclipse.Eclipse.*; import static lombok.eclipse.handlers.EclipseHandlerUtil.*; import java.util.ArrayList; import java.util.Arrays; import java.util.List; import org.eclipse.jdt.internal.compiler.ast.ASTNode; import org.eclipse.jdt.internal.compiler.ast.AbstractMethodDeclaration; import org.eclipse.jdt.internal.compiler.ast.AbstractVariableDeclaration; import org.eclipse.jdt.internal.compiler.ast.Annotation; import org.eclipse.jdt.internal.compiler.ast.Argument; import org.eclipse.jdt.internal.compiler.ast.AssertStatement; import org.eclipse.jdt.internal.compiler.ast.Assignment; import org.eclipse.jdt.internal.compiler.ast.Block; import org.eclipse.jdt.internal.compiler.ast.CompilationUnitDeclaration; import org.eclipse.jdt.internal.compiler.ast.ConstructorDeclaration; import org.eclipse.jdt.internal.compiler.ast.EqualExpression; import org.eclipse.jdt.internal.compiler.ast.ExplicitConstructorCall; 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.IfStatement; import org.eclipse.jdt.internal.compiler.ast.MessageSend; import org.eclipse.jdt.internal.compiler.ast.NullLiteral; import org.eclipse.jdt.internal.compiler.ast.QualifiedTypeReference; 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.SynchronizedStatement; import org.eclipse.jdt.internal.compiler.ast.ThisReference; import org.eclipse.jdt.internal.compiler.ast.ThrowStatement; import org.eclipse.jdt.internal.compiler.ast.TryStatement; import org.eclipse.jdt.internal.compiler.ast.TypeDeclaration; import org.eclipse.jdt.internal.compiler.ast.TypeReference; import org.eclipse.jdt.internal.compiler.classfmt.ClassFileConstants; import lombok.ConfigurationKeys; import lombok.NonNull; import lombok.core.AST.Kind; import lombok.core.AnnotationValues; import lombok.core.HandlerPriority; import lombok.eclipse.EcjAugments; import lombok.eclipse.EclipseAnnotationHandler; import lombok.eclipse.EclipseNode; import lombok.spi.Provides; @Provides @HandlerPriority(value = 512) // 2^9; onParameter=@__(@NonNull) has to run first. public class HandleNonNull extends EclipseAnnotationHandler { private static final char[] REQUIRE_NON_NULL = "requireNonNull".toCharArray(); private static final char[] CHECK_NOT_NULL = "checkNotNull".toCharArray(); public static final HandleNonNull INSTANCE = new HandleNonNull(); public void fix(EclipseNode method) { for (EclipseNode m : method.down()) { if (m.getKind() != Kind.ARGUMENT) continue; for (EclipseNode c : m.down()) { if (c.getKind() == Kind.ANNOTATION) { if (annotationTypeMatches(NonNull.class, c)) { handle0((Annotation) c.get(), c, true); } } } } } private List getRecordComponents(EclipseNode typeNode) { List list = new ArrayList(); for (EclipseNode child : typeNode.down()) { if (child.getKind() == Kind.FIELD) { FieldDeclaration fd = (FieldDeclaration) child.get(); if ((fd.modifiers & AccRecord) != 0) list.add(fd); } } return list; } private EclipseNode addCompactConstructorIfNeeded(EclipseNode typeNode, EclipseNode annotationNode) { // explicit Compact Constructor has bits set: Bit32, IsCanonicalConstructor (10). // implicit Compact Constructor has bits set: Bit32, IsCanonicalConstructor (10), and IsImplicit (11). // explicit constructor with long-form shows up as a normal constructor (Bit32 set, that's all), but the // implicit CC is then also present and will presumably be stripped out in some later phase. EclipseNode toRemove = null; EclipseNode existingCompactConstructor = null; List recordComponents = null; for (EclipseNode child : typeNode.down()) { if (!(child.get() instanceof ConstructorDeclaration)) continue; ConstructorDeclaration cd = (ConstructorDeclaration) child.get(); if ((cd.bits & IsCanonicalConstructor) != 0) { if ((cd.bits & IsImplicit) != 0) { toRemove = child; } else { existingCompactConstructor = child; } } else { // If this constructor has exact matching types vs. the record components, // this is the canonical constructor in long form and we should not generate one. if (recordComponents == null) recordComponents = getRecordComponents(typeNode); int argLength = cd.arguments == null ? 0 : cd.arguments.length; int compLength = recordComponents.size(); boolean isCanonical = argLength == compLength; if (isCanonical) top: for (int i = 0; i < argLength; i++) { TypeReference a = recordComponents.get(i).type; TypeReference b = cd.arguments[i] == null ? null : cd.arguments[i].type; // technically this won't match e.g. `java.lang.String` to just `String`; // to use this feature you'll need to use the same way to write it, which seems // like a fair requirement. char[][] ta = getRawTypeName(a); char[][] tb = getRawTypeName(b); if (ta == null || tb == null || ta.length != tb.length) { isCanonical = false; break top; } for (int j = 0; j < ta.length; j++) { if (!Arrays.equals(ta[j], tb[j])) { isCanonical = false; break top; } } } if (isCanonical) { return null; } } } if (existingCompactConstructor != null) return existingCompactConstructor; int posToInsert = -1; TypeDeclaration td = (TypeDeclaration) typeNode.get(); if (toRemove != null) { int idxToRemove = -1; for (int i = 0; i < td.methods.length; i++) { if (td.methods[i] == toRemove.get()) idxToRemove = i; } if (idxToRemove != -1) { System.arraycopy(td.methods, idxToRemove + 1, td.methods, idxToRemove, td.methods.length - idxToRemove - 1); posToInsert = td.methods.length - 1; typeNode.removeChild(toRemove); } } if (posToInsert == -1) { AbstractMethodDeclaration[] na = new AbstractMethodDeclaration[td.methods.length + 1]; posToInsert = td.methods.length; System.arraycopy(td.methods, 0, na, 0, posToInsert); td.methods = na; } ConstructorDeclaration cd = new ConstructorDeclaration(((CompilationUnitDeclaration) typeNode.top().get()).compilationResult); cd.modifiers = ClassFileConstants.AccPublic; cd.bits = ASTNode.Bit32 | ECLIPSE_DO_NOT_TOUCH_FLAG | IsCanonicalConstructor; cd.selector = td.name; cd.constructorCall = new ExplicitConstructorCall(ExplicitConstructorCall.ImplicitSuper); if (recordComponents == null) recordComponents = getRecordComponents(typeNode); cd.arguments = new Argument[recordComponents.size()]; cd.statements = new Statement[recordComponents.size()]; cd.bits = IsCanonicalConstructor; for (int i = 0; i < cd.arguments.length; i++) { FieldDeclaration cmp = recordComponents.get(i); cd.arguments[i] = new Argument(cmp.name, cmp.sourceStart, cmp.type, 0); cd.arguments[i].bits = ASTNode.IsArgument | ASTNode.IgnoreRawTypeCheck | ASTNode.IsReachable; FieldReference lhs = new FieldReference(cmp.name, 0); lhs.receiver = new ThisReference(0, 0); SingleNameReference rhs = new SingleNameReference(cmp.name, 0); cd.statements[i] = new Assignment(lhs, rhs, cmp.sourceEnd); } setGeneratedBy(cd, annotationNode.get()); for (int i = 0; i < cd.arguments.length; i++) { FieldDeclaration cmp = recordComponents.get(i); cd.arguments[i].sourceStart = cmp.sourceStart; cd.arguments[i].sourceEnd = cmp.sourceStart; cd.arguments[i].declarationSourceEnd = cmp.sourceStart; cd.arguments[i].declarationEnd = cmp.sourceStart; } td.methods[posToInsert] = cd; cd.annotations = addSuppressWarningsAll(typeNode, cd, cd.annotations); cd.annotations = addGenerated(typeNode, cd, cd.annotations); return typeNode.add(cd, Kind.METHOD); } private static char[][] getRawTypeName(TypeReference a) { if (a instanceof QualifiedTypeReference) return ((QualifiedTypeReference) a).tokens; if (a instanceof SingleTypeReference) return new char[][] {((SingleTypeReference) a).token}; return null; } @Override public void handle(AnnotationValues annotation, Annotation ast, EclipseNode annotationNode) { // Generating new methods is only possible during diet parse but modifying existing methods requires a full parse. // As we need both for @NonNull we reset the handled flag during diet parse. if (!annotationNode.isCompleteParse()) { final EclipseNode node; if (annotationNode.up().getKind() == Kind.TYPE_USE) { node = annotationNode.directUp().directUp(); } else { node = annotationNode.up(); } if (node.getKind() == Kind.FIELD) { //Check if this is a record and we need to generate the compact form constructor. EclipseNode typeNode = node.up(); if (typeNode.getKind() == Kind.TYPE) { if (isRecord(typeNode)) { addCompactConstructorIfNeeded(typeNode, annotationNode); } } } EcjAugments.ASTNode_handled.clear(ast); return; } handle0(ast, annotationNode, false); } private EclipseNode findCompactConstructor(EclipseNode typeNode) { for (EclipseNode child : typeNode.down()) { if (!(child.get() instanceof ConstructorDeclaration)) continue; ConstructorDeclaration cd = (ConstructorDeclaration) child.get(); if ((cd.bits & IsCanonicalConstructor) != 0 && (cd.bits & IsImplicit) == 0) return child; } return null; } private void handle0(Annotation ast, EclipseNode annotationNode, boolean force) { handleFlagUsage(annotationNode, ConfigurationKeys.NON_NULL_FLAG_USAGE, "@NonNull"); final EclipseNode node; if (annotationNode.up().getKind() == Kind.TYPE_USE) { node = annotationNode.directUp().directUp(); } else { node = annotationNode.up(); } if (node.getKind() == Kind.FIELD) { // This is meaningless unless the field is used to generate a method (@Setter, @RequiredArgsConstructor, etc), // but in that case those handlers will take care of it. However, we DO check if the annotation is applied to // a primitive, because those handlers trigger on any annotation named @NonNull and we only want the warning // behaviour on _OUR_ 'lombok.NonNull'. EclipseNode fieldNode = node; EclipseNode typeNode = fieldNode.up(); try { if (isPrimitive(((AbstractVariableDeclaration) node.get()).type)) { annotationNode.addWarning("@NonNull is meaningless on a primitive."); return; } } catch (Exception ignore) {} if (isRecord(typeNode)) { // well, these kinda double as parameters (of the compact constructor), so we do some work here. // NB:Tthe diet parse run already added an explicit compact constructor if we need to take any actions. EclipseNode compactConstructor = findCompactConstructor(typeNode); if (compactConstructor != null) { addNullCheckIfNeeded((AbstractMethodDeclaration) compactConstructor.get(), (AbstractVariableDeclaration) fieldNode.get(), annotationNode); } } return; } if (node.getKind() != Kind.ARGUMENT) return; Argument param; AbstractMethodDeclaration declaration; try { param = (Argument) node.get(); declaration = (AbstractMethodDeclaration) node.up().get(); } catch (Exception e) { return; } if (!force && isGenerated(declaration)) return; if (declaration.isAbstract()) { // This used to be a warning, but as @NonNull also has a documentary purpose, better to not warn about this. Since 1.16.7 return; } addNullCheckIfNeeded(declaration, param, annotationNode); node.up().rebuild(); } private void addNullCheckIfNeeded(AbstractMethodDeclaration declaration, AbstractVariableDeclaration param, EclipseNode annotationNode) { // Possibly, if 'declaration instanceof ConstructorDeclaration', fetch declaration.constructorCall, search it for any references to our parameter, // and if they exist, create a new method in the class: 'private static T lombok$nullCheck(T expr, String msg) {if (expr == null) throw NPE; return expr;}' and // wrap all references to it in the super/this to a call to this method. Statement nullCheck = generateNullCheck(param, annotationNode, null); if (nullCheck == null) { // @NonNull applied to a primitive. Kinda pointless. Let's generate a warning. annotationNode.addWarning("@NonNull is meaningless on a primitive."); return; } if (declaration.statements == null) { declaration.statements = new Statement[] {nullCheck}; } else { char[] expectedName = param.name; /* Abort if the null check is already there, delving into try and synchronized statements */ { Statement[] stats = declaration.statements; int idx = 0; while (stats != null && stats.length > idx) { Statement stat = stats[idx++]; if (stat instanceof TryStatement) { stats = ((TryStatement) stat).tryBlock.statements; idx = 0; continue; } if (stat instanceof SynchronizedStatement) { stats = ((SynchronizedStatement) stat).block.statements; idx = 0; continue; } char[] varNameOfNullCheck = returnVarNameIfNullCheck(stat); if (varNameOfNullCheck == null) break; if (Arrays.equals(varNameOfNullCheck, expectedName)) return; } } Statement[] newStatements = new Statement[declaration.statements.length + 1]; int skipOver = 0; for (Statement stat : declaration.statements) { if (isGenerated(stat) && isNullCheck(stat)) skipOver++; else break; } System.arraycopy(declaration.statements, 0, newStatements, 0, skipOver); System.arraycopy(declaration.statements, skipOver, newStatements, skipOver + 1, declaration.statements.length - skipOver); newStatements[skipOver] = nullCheck; declaration.statements = newStatements; } } public boolean isNullCheck(Statement stat) { return returnVarNameIfNullCheck(stat) != null; } public char[] returnVarNameIfNullCheck(Statement stat) { boolean isIf = stat instanceof IfStatement; boolean isExpression = stat instanceof Expression; if (!isIf && !(stat instanceof AssertStatement) && !isExpression) return null; if (isExpression) { /* Check if the statements contains a call to checkNotNull or requireNonNull */ Expression expression = (Expression) stat; if (expression instanceof Assignment) expression = ((Assignment) expression).expression; if (!(expression instanceof MessageSend)) return null; MessageSend invocation = (MessageSend) expression; if (!Arrays.equals(invocation.selector, CHECK_NOT_NULL) && !Arrays.equals(invocation.selector, REQUIRE_NON_NULL)) return null; if (invocation.arguments == null || invocation.arguments.length == 0) return null; Expression firstArgument = invocation.arguments[0]; if (!(firstArgument instanceof SingleNameReference)) return null; return ((SingleNameReference) firstArgument).token; } if (isIf) { /* Check that the if's statement is a throw statement, possibly in a block. */ Statement then = ((IfStatement) stat).thenStatement; if (then instanceof Block) { Statement[] blockStatements = ((Block) then).statements; if (blockStatements == null || blockStatements.length == 0) return null; then = blockStatements[0]; } if (!(then instanceof ThrowStatement)) return null; } /* Check that the if's conditional is like 'x == null'. Return from this method (don't generate a nullcheck) if 'x' is equal to our own variable's name: There's already a nullcheck here. */ { Expression cond = isIf ? ((IfStatement) stat).condition : ((AssertStatement) stat).assertExpression; if (!(cond instanceof EqualExpression)) return null; EqualExpression bin = (EqualExpression) cond; String op = bin.operatorToString(); if (isIf) { if (!"==".equals(op)) return null; } else { if (!"!=".equals(op)) return null; } if (!(bin.left instanceof SingleNameReference)) return null; if (!(bin.right instanceof NullLiteral)) return null; return ((SingleNameReference) bin.left).token; } } }