private List<FieldNode> getAnnotatedFieldOfClass(ClassNode target, ClassNode annotation) {
List<FieldNode> result = new ArrayList<FieldNode>();
for (FieldNode fieldNode : target.getFields())
if (!fieldNode.getAnnotations(annotation).isEmpty()) result.add(fieldNode);
return result;
}
/**
* Adds the annotation to the internal target list if a match is found.
*
* @param node the node to be processed
*/
public void visitAnnotations(AnnotatedNode node) {
super.visitAnnotations(node);
for (AnnotationNode annotation : node.getAnnotations()) {
if (transforms.containsKey(annotation)) {
targetNodes.add(new ASTNode[] {annotation, node});
}
}
}
/**
* This method is used to add "bridge" methods for private methods of an inner/outer class, so
* that the outer class is capable of calling them. It does basically the same job as access$000
* like methods in Java.
*
* @param node an inner/outer class node for which to generate bridge methods
*/
@SuppressWarnings("unchecked")
private void addPrivateBridgeMethods(final ClassNode node) {
Set<ASTNode> accessedMethods =
(Set<ASTNode>) node.getNodeMetaData(StaticTypesMarker.PV_METHODS_ACCESS);
if (accessedMethods == null) return;
List<MethodNode> methods = new ArrayList<MethodNode>(node.getAllDeclaredMethods());
Map<MethodNode, MethodNode> privateBridgeMethods =
(Map<MethodNode, MethodNode>) node.getNodeMetaData(PRIVATE_BRIDGE_METHODS);
if (privateBridgeMethods != null) {
// private bridge methods already added
return;
}
privateBridgeMethods = new HashMap<MethodNode, MethodNode>();
int i = -1;
final int access = Opcodes.ACC_STATIC | Opcodes.ACC_PUBLIC | Opcodes.ACC_SYNTHETIC;
for (MethodNode method : methods) {
if (accessedMethods.contains(method)) {
i++;
Parameter[] methodParameters = method.getParameters();
Parameter[] newParams = new Parameter[methodParameters.length + 1];
System.arraycopy(methodParameters, 0, newParams, 1, methodParameters.length);
newParams[0] = new Parameter(node.getPlainNodeReference(), "$that");
Expression arguments;
if (method.getParameters() == null || method.getParameters().length == 0) {
arguments = ArgumentListExpression.EMPTY_ARGUMENTS;
} else {
List<Expression> args = new LinkedList<Expression>();
for (Parameter parameter : methodParameters) {
args.add(new VariableExpression(parameter));
}
arguments = new ArgumentListExpression(args);
}
Expression receiver =
method.isStatic() ? new ClassExpression(node) : new VariableExpression(newParams[0]);
MethodCallExpression mce = new MethodCallExpression(receiver, method.getName(), arguments);
mce.setMethodTarget(method);
ExpressionStatement returnStatement = new ExpressionStatement(mce);
MethodNode bridge =
node.addMethod(
"access$" + i,
access,
method.getReturnType(),
newParams,
method.getExceptions(),
returnStatement);
privateBridgeMethods.put(method, bridge);
bridge.addAnnotation(new AnnotationNode(COMPILESTATIC_CLASSNODE));
}
}
if (!privateBridgeMethods.isEmpty()) {
node.setNodeMetaData(PRIVATE_BRIDGE_METHODS, privateBridgeMethods);
}
}
private List<ClassNode> getSorted(int[] index, List<ClassNode> unsorted) {
List<ClassNode> sorted = new ArrayList<ClassNode>(unsorted.size());
for (int i = 0; i < unsorted.size(); i++) {
int min = -1;
for (int j = 0; j < unsorted.size(); j++) {
if (index[j] == -1) continue;
if (min == -1) {
min = j;
} else if (index[j] < index[min]) {
min = j;
}
}
if (min == -1) break;
sorted.add(unsorted.get(min));
index[min] = -1;
}
return sorted;
}
private Collection createPropertiesForBelongsToExpression(Expression e, ClassNode classNode) {
List properties = new ArrayList();
if (e instanceof MapExpression) {
MapExpression me = (MapExpression) e;
List mapEntries = me.getMapEntryExpressions();
for (Iterator i = mapEntries.iterator(); i.hasNext(); ) {
MapEntryExpression mme = (MapEntryExpression) i.next();
String key = mme.getKeyExpression().getText();
String type = mme.getValueExpression().getText();
properties.add(
new PropertyNode(
key, Modifier.PUBLIC, ClassHelper.make(type), classNode, null, null, null));
}
}
return properties;
}
/**
* Dequeues any source units add through addSource and resets the compiler phase to
* initialization.
*
* <p>Note: this does not mean a file is recompiled. If a SourceUnit has already passed a phase it
* is skipped until a higher phase is reached.
*
* @return true if there was a queued source
* @throws CompilationFailedException
*/
protected boolean dequeued() throws CompilationFailedException {
boolean dequeue = !queuedSources.isEmpty();
while (!queuedSources.isEmpty()) {
SourceUnit su = queuedSources.removeFirst();
String name = su.getName();
// GRECLIPSE: start
if (iterating) {
GroovyBugError gbe =
new GroovyBugError(
"Damaging 'names' whilst already iterating. Name getting added is '"
+ su.getName()
+ "'");
gbe.printStackTrace();
throw gbe;
}
// end
names.add(name);
sources.put(name, su);
}
if (dequeue) {
gotoPhase(Phases.INITIALIZATION);
}
return dequeue;
}
/**
* Main loop entry.
*
* <p>First, it delegates to the super visitClass so we can collect the relevant annotations in an
* AST tree walk.
*
* <p>Second, it calls the visit method on the transformation for each relevant annotation found.
*
* @param classNode the class to visit
*/
public void visitClass(ClassNode classNode) {
// only descend if we have annotations to look for
Map<Class<? extends ASTTransformation>, Set<ASTNode>> baseTransforms =
classNode.getTransforms(phase);
if (!baseTransforms.isEmpty()) {
final Map<Class<? extends ASTTransformation>, ASTTransformation> transformInstances =
new HashMap<Class<? extends ASTTransformation>, ASTTransformation>();
for (Class<? extends ASTTransformation> transformClass : baseTransforms.keySet()) {
try {
transformInstances.put(transformClass, transformClass.newInstance());
} catch (InstantiationException e) {
source
.getErrorCollector()
.addError(
new SimpleMessage(
"Could not instantiate Transformation Processor "
+ transformClass, // + " declared by " +
// annotation.getClassNode().getName(),
source));
} catch (IllegalAccessException e) {
source
.getErrorCollector()
.addError(
new SimpleMessage(
"Could not instantiate Transformation Processor "
+ transformClass, // + " declared by " +
// annotation.getClassNode().getName(),
source));
}
}
// invert the map, is now one to many
transforms = new HashMap<ASTNode, List<ASTTransformation>>();
for (Map.Entry<Class<? extends ASTTransformation>, Set<ASTNode>> entry :
baseTransforms.entrySet()) {
for (ASTNode node : entry.getValue()) {
List<ASTTransformation> list = transforms.get(node);
if (list == null) {
list = new ArrayList<ASTTransformation>();
transforms.put(node, list);
}
list.add(transformInstances.get(entry.getKey()));
}
}
targetNodes = new LinkedList<ASTNode[]>();
// first pass, collect nodes
super.visitClass(classNode);
// second pass, call visit on all of the collected nodes
for (ASTNode[] node : targetNodes) {
for (ASTTransformation snt : transforms.get(node[0])) {
if (snt instanceof CompilationUnitAware) {
((CompilationUnitAware) snt).setCompilationUnit(context.getCompilationUnit());
}
snt.visit(node, source);
}
}
}
}
public void call(SourceUnit source, GeneratorContext context, ClassNode classNode)
throws CompilationFailedException {
optimizer.visitClass(
classNode, source); // GROOVY-4272: repositioned it here from staticImport
if (!classNode.isSynthetic()) {
GenericsVisitor genericsVisitor = new GenericsVisitor(source);
genericsVisitor.visitClass(classNode);
}
//
// Run the Verifier on the outer class
//
try {
verifier.visitClass(classNode);
} catch (GroovyRuntimeException rpe) {
ASTNode node = rpe.getNode();
getErrorCollector()
.addError(
new SyntaxException(
rpe.getMessage(),
node.getLineNumber(),
node.getColumnNumber(),
node.getLastLineNumber(),
node.getLastColumnNumber()),
source);
}
LabelVerifier lv = new LabelVerifier(source);
lv.visitClass(classNode);
ClassCompletionVerifier completionVerifier = new ClassCompletionVerifier(source);
completionVerifier.visitClass(classNode);
ExtendedVerifier xverifier = new ExtendedVerifier(source);
xverifier.visitClass(classNode);
// because the class may be generated even if a error was found
// and that class may have an invalid format we fail here if needed
getErrorCollector().failIfErrors();
//
// Prep the generator machinery
//
ClassVisitor visitor = createClassVisitor();
String sourceName =
(source == null ? classNode.getModule().getDescription() : source.getName());
// only show the file name and its extension like javac does in its stacktraces rather
// than the full path
// also takes care of both \ and / depending on the host compiling environment
if (sourceName != null)
sourceName =
sourceName.substring(
Math.max(sourceName.lastIndexOf('\\'), sourceName.lastIndexOf('/')) + 1);
AsmClassGenerator generator = new AsmClassGenerator(source, context, visitor, sourceName);
//
// Run the generation and create the class (if required)
//
// GRECLIPSE: if there are errors, don't generate code.
// code gen can fail unexpectedly if there was an earlier error.
if (!source.getErrorCollector().hasErrors()) {
// end
generator.visitClass(classNode);
byte[] bytes = ((ClassWriter) visitor).toByteArray();
/// GRECLIPSE: start: added classNode, sourceUnit
/*old{
generatedClasses.add(new GroovyClass(classNode.getName(), bytes));
}*/
// newcode
generatedClasses.add(new GroovyClass(classNode.getName(), bytes, classNode, source));
// end
//
// Handle any callback that's been set
//
if (CompilationUnit.this.classgenCallback != null) {
classgenCallback.call(visitor, classNode);
}
//
// Recurse for inner classes
//
LinkedList innerClasses = generator.getInnerClasses();
while (!innerClasses.isEmpty()) {
classgen.call(source, context, (ClassNode) innerClasses.removeFirst());
}
// GRECLIPSE: if there are errors, don't generate code
}
// end
}
private List getPrimaryClassNodes(boolean sort) {
if (sort == true) {
List<ModuleNode> sortedModules = this.ast.getSortedModules();
if (sortedModules != null) {
return sortedModules;
}
}
// FIXASC (groovychange) rewritten
/*old{
List unsorted = new ArrayList();
Iterator modules = this.ast.getModules().iterator();
while (modules.hasNext()) {
ModuleNode module = (ModuleNode) modules.next();
Iterator classNodes = module.getClasses().iterator();
while (classNodes.hasNext()) {
ClassNode classNode = (ClassNode) classNodes.next();
unsorted.add(classNode);
}
}
*/
// new
List<ClassNode> unsorted = new ArrayList<ClassNode>();
for (ModuleNode module : this.ast.getModules()) {
unsorted.addAll(module.getClasses());
}
// FIXASC (groovychange) end
if (!sort) return unsorted;
// GRECLIPSE: start: rewritten sort algorithm
/*old{
int[] indexClass = new int[unsorted.size()];
int[] indexInterface = new int[unsorted.size()];
{
int i = 0;
for (Iterator<ClassNode> iter = unsorted.iterator(); iter.hasNext(); i++) {
ClassNode element = iter.next();
if (element.isInterface()) {
indexInterface[i] = getSuperInterfaceCount(element);
indexClass[i] = -1;
} else {
indexClass[i] = getSuperClassCount(element);
indexInterface[i] = -1;
}
}
}
List<ClassNode> sorted = getSorted(indexInterface, unsorted);
sorted.addAll(getSorted(indexClass, unsorted));
*/
// newcode:
// Sort them by how many types are in their hierarchy, but all interfaces first.
// Algorithm:
// Create a list of integers. Each integer captures the index into the unsorted
// list (bottom 16bits) and the count of how many types are in that types
// hierarchy (top 16bits). For classes the count is augmented by 2000 so that
// when sorting the classes will come out after the interfaces.
// This list of integers is sorted. We then just go through it and for the
// lower 16bits of each entry (0xffff) that is the index of the next value to
// pull from the unsorted list and put into the sorted list.
// Will break down if more than 2000 interfaces in the type hierarchy for an
// individual type, or a project contains > 65535 files... but if you've got
// that kind of setup, you have other problems...
List<Integer> countIndexPairs = new ArrayList<Integer>();
{
int i = 0;
for (Iterator iter = unsorted.iterator(); iter.hasNext(); i++) {
ClassNode node = (ClassNode) iter.next();
if (node.isInterface()) {
countIndexPairs.add((getSuperInterfaceCount(node) << 16) + i);
} else {
countIndexPairs.add(((getSuperClassCount(node) + 2000) << 16) + i);
}
}
}
Collections.sort(countIndexPairs);
List sorted = new ArrayList();
for (int i : countIndexPairs) {
sorted.add(unsorted.get(i & 0xffff));
}
this.ast.setSortedModules(sorted);
// end
return sorted;
}
private void addAssociationForKey(String key, List properties, ClassNode classNode) {
properties.add(
new PropertyNode(
key, Modifier.PUBLIC, new ClassNode(Set.class), classNode, null, null, null));
}
