/** Run a processing round. */ void run(boolean lastRound, boolean errorStatus) { printRoundInfo(lastRound); TaskListener taskListener = context.get(TaskListener.class); if (taskListener != null) taskListener.started(new TaskEvent(TaskEvent.Kind.ANNOTATION_PROCESSING_ROUND)); try { if (lastRound) { filer.setLastRound(true); Set<Element> emptyRootElements = Collections.emptySet(); // immutable RoundEnvironment renv = new JavacRoundEnvironment( true, errorStatus, emptyRootElements, JavacProcessingEnvironment.this); discoveredProcs.iterator().runContributingProcs(renv); } else { discoverAndRunProcs(context, annotationsPresent, topLevelClasses, packageInfoFiles); } } finally { if (taskListener != null) taskListener.finished(new TaskEvent(TaskEvent.Kind.ANNOTATION_PROCESSING_ROUND)); } nMessagerErrors = messager.errorCount(); }
/** Print info about this round. */ private void printRoundInfo(boolean lastRound) { if (printRounds || verbose) { List<ClassSymbol> tlc = lastRound ? List.<ClassSymbol>nil() : topLevelClasses; Set<TypeElement> ap = lastRound ? Collections.<TypeElement>emptySet() : annotationsPresent; log.printNoteLines("x.print.rounds", number, "{" + tlc.toString(", ") + "}", ap, lastRound); } }
/** * Run all remaining processors on the procStateList that have not already run this round with * an empty set of annotations. */ public void runContributingProcs(RoundEnvironment re) { if (!onProcInterator) { Set<TypeElement> emptyTypeElements = Collections.emptySet(); while (innerIter.hasNext()) { ProcessorState ps = innerIter.next(); if (ps.contributed) callProcessor(ps.processor, emptyTypeElements, re); } } }
private Set<String> initPlatformAnnotations() { Set<String> platformAnnotations = new HashSet<String>(); platformAnnotations.add("java.lang.Deprecated"); platformAnnotations.add("java.lang.Override"); platformAnnotations.add("java.lang.SuppressWarnings"); platformAnnotations.add("java.lang.annotation.Documented"); platformAnnotations.add("java.lang.annotation.Inherited"); platformAnnotations.add("java.lang.annotation.Retention"); platformAnnotations.add("java.lang.annotation.Target"); return Collections.unmodifiableSet(platformAnnotations); }
/** * Returns an empty processor iterator if no processors are on the relevant path, otherwise if * processors are present, logs an error. Called when a service loader is unavailable for some * reason, either because a service loader class cannot be found or because a security policy * prevents class loaders from being created. * * @param key The resource key to use to log an error message * @param e If non-null, pass this exception to Abort */ private Iterator<Processor> handleServiceLoaderUnavailability(String key, Exception e) { JavaFileManager fileManager = context.get(JavaFileManager.class); if (fileManager instanceof JavacFileManager) { StandardJavaFileManager standardFileManager = (JavacFileManager) fileManager; Iterable<? extends File> workingPath = fileManager.hasLocation(ANNOTATION_PROCESSOR_PATH) ? standardFileManager.getLocation(ANNOTATION_PROCESSOR_PATH) : standardFileManager.getLocation(CLASS_PATH); if (needClassLoader(options.get(PROCESSOR), workingPath)) handleException(key, e); } else { handleException(key, e); } java.util.List<Processor> pl = Collections.emptyList(); return pl.iterator(); }
private Map<String, String> initProcessorOptions(Context context) { Options options = Options.instance(context); Set<String> keySet = options.keySet(); Map<String, String> tempOptions = new LinkedHashMap<String, String>(); for (String key : keySet) { if (key.startsWith("-A") && key.length() > 2) { int sepIndex = key.indexOf('='); String candidateKey = null; String candidateValue = null; if (sepIndex == -1) candidateKey = key.substring(2); else if (sepIndex >= 3) { candidateKey = key.substring(2, sepIndex); candidateValue = (sepIndex < key.length() - 1) ? key.substring(sepIndex + 1) : null; } tempOptions.put(candidateKey, candidateValue); } } return Collections.unmodifiableMap(tempOptions); }
/** * Objects of this class hold and manage the state needed to support annotation processing. * * <p><b>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.</b> */ public class JavacProcessingEnvironment implements ProcessingEnvironment, Closeable { Options options; private final boolean printProcessorInfo; private final boolean printRounds; private final boolean verbose; private final boolean lint; private final boolean procOnly; private final boolean fatalErrors; private final boolean werror; private final boolean showResolveErrors; private boolean foundTypeProcessors; private final JavacFiler filer; private final JavacMessager messager; private final JavacElements elementUtils; private final JavacTypes typeUtils; /** Holds relevant state history of which processors have been used. */ private DiscoveredProcessors discoveredProcs; /** Map of processor-specific options. */ private final Map<String, String> processorOptions; /** */ private final Set<String> unmatchedProcessorOptions; /** Annotations implicitly processed and claimed by javac. */ private final Set<String> platformAnnotations; /** Set of packages given on command line. */ private Set<PackageSymbol> specifiedPackages = Collections.emptySet(); /** The log to be used for error reporting. */ Log log; /** Diagnostic factory. */ JCDiagnostic.Factory diags; /** Source level of the compile. */ Source source; private ClassLoader processorClassLoader; /** JavacMessages object used for localization */ private JavacMessages messages; private Context context; public JavacProcessingEnvironment(Context context, Iterable<? extends Processor> processors) { this.context = context; log = Log.instance(context); source = Source.instance(context); diags = JCDiagnostic.Factory.instance(context); options = Options.instance(context); printProcessorInfo = options.isSet(XPRINTPROCESSORINFO); printRounds = options.isSet(XPRINTROUNDS); verbose = options.isSet(VERBOSE); lint = Lint.instance(context).isEnabled(PROCESSING); procOnly = options.isSet(PROC, "only") || options.isSet(XPRINT); fatalErrors = options.isSet("fatalEnterError"); showResolveErrors = options.isSet("showResolveErrors"); werror = options.isSet(WERROR); platformAnnotations = initPlatformAnnotations(); foundTypeProcessors = false; // Initialize services before any processors are initialized // in case processors use them. filer = new JavacFiler(context); messager = new JavacMessager(context, this); elementUtils = JavacElements.instance(context); typeUtils = JavacTypes.instance(context); processorOptions = initProcessorOptions(context); unmatchedProcessorOptions = initUnmatchedProcessorOptions(); messages = JavacMessages.instance(context); initProcessorIterator(context, processors); } private Set<String> initPlatformAnnotations() { Set<String> platformAnnotations = new HashSet<String>(); platformAnnotations.add("java.lang.Deprecated"); platformAnnotations.add("java.lang.Override"); platformAnnotations.add("java.lang.SuppressWarnings"); platformAnnotations.add("java.lang.annotation.Documented"); platformAnnotations.add("java.lang.annotation.Inherited"); platformAnnotations.add("java.lang.annotation.Retention"); platformAnnotations.add("java.lang.annotation.Target"); return Collections.unmodifiableSet(platformAnnotations); } private void initProcessorIterator(Context context, Iterable<? extends Processor> processors) { Log log = Log.instance(context); Iterator<? extends Processor> processorIterator; if (options.isSet(XPRINT)) { try { Processor processor = PrintingProcessor.class.newInstance(); processorIterator = List.of(processor).iterator(); } catch (Throwable t) { AssertionError assertError = new AssertionError("Problem instantiating PrintingProcessor."); assertError.initCause(t); throw assertError; } } else if (processors != null) { processorIterator = processors.iterator(); } else { String processorNames = options.get(PROCESSOR); JavaFileManager fileManager = context.get(JavaFileManager.class); try { // If processorpath is not explicitly set, use the classpath. processorClassLoader = fileManager.hasLocation(ANNOTATION_PROCESSOR_PATH) ? fileManager.getClassLoader(ANNOTATION_PROCESSOR_PATH) : fileManager.getClassLoader(CLASS_PATH); /* * If the "-processor" option is used, search the appropriate * path for the named class. Otherwise, use a service * provider mechanism to create the processor iterator. */ if (processorNames != null) { processorIterator = new NameProcessIterator(processorNames, processorClassLoader, log); } else { processorIterator = new ServiceIterator(processorClassLoader, log); } } catch (SecurityException e) { /* * A security exception will occur if we can't create a classloader. * Ignore the exception if, with hindsight, we didn't need it anyway * (i.e. no processor was specified either explicitly, or implicitly, * in service configuration file.) Otherwise, we cannot continue. */ processorIterator = handleServiceLoaderUnavailability("proc.cant.create.loader", e); } } discoveredProcs = new DiscoveredProcessors(processorIterator); } /** * Returns an empty processor iterator if no processors are on the relevant path, otherwise if * processors are present, logs an error. Called when a service loader is unavailable for some * reason, either because a service loader class cannot be found or because a security policy * prevents class loaders from being created. * * @param key The resource key to use to log an error message * @param e If non-null, pass this exception to Abort */ private Iterator<Processor> handleServiceLoaderUnavailability(String key, Exception e) { JavaFileManager fileManager = context.get(JavaFileManager.class); if (fileManager instanceof JavacFileManager) { StandardJavaFileManager standardFileManager = (JavacFileManager) fileManager; Iterable<? extends File> workingPath = fileManager.hasLocation(ANNOTATION_PROCESSOR_PATH) ? standardFileManager.getLocation(ANNOTATION_PROCESSOR_PATH) : standardFileManager.getLocation(CLASS_PATH); if (needClassLoader(options.get(PROCESSOR), workingPath)) handleException(key, e); } else { handleException(key, e); } java.util.List<Processor> pl = Collections.emptyList(); return pl.iterator(); } /** Handle a security exception thrown during initializing the Processor iterator. */ private void handleException(String key, Exception e) { if (e != null) { log.error(key, e.getLocalizedMessage()); throw new Abort(e); } else { log.error(key); throw new Abort(); } } /** * Use a service loader appropriate for the platform to provide an iterator over annotations * processors. If java.util.ServiceLoader is present use it, otherwise, use sun.misc.Service, * otherwise fail if a loader is needed. */ private class ServiceIterator implements Iterator<Processor> { // The to-be-wrapped iterator. private Iterator<?> iterator; private Log log; private Class<?> loaderClass; private boolean jusl; private Object loader; ServiceIterator(ClassLoader classLoader, Log log) { String loadMethodName; this.log = log; try { try { loaderClass = Class.forName("java.util.ServiceLoader"); loadMethodName = "load"; jusl = true; } catch (ClassNotFoundException cnfe) { try { loaderClass = Class.forName("sun.misc.Service"); loadMethodName = "providers"; jusl = false; } catch (ClassNotFoundException cnfe2) { // Fail softly if a loader is not actually needed. this.iterator = handleServiceLoaderUnavailability("proc.no.service", null); return; } } // java.util.ServiceLoader.load or sun.misc.Service.providers Method loadMethod = loaderClass.getMethod(loadMethodName, Class.class, ClassLoader.class); Object result = loadMethod.invoke(null, Processor.class, classLoader); // For java.util.ServiceLoader, we have to call another // method to get the iterator. if (jusl) { loader = result; // Store ServiceLoader to call reload later Method m = loaderClass.getMethod("iterator"); result = m.invoke(result); // serviceLoader.iterator(); } // The result should now be an iterator. this.iterator = (Iterator<?>) result; } catch (Throwable t) { log.error("proc.service.problem"); throw new Abort(t); } } public boolean hasNext() { try { return iterator.hasNext(); } catch (Throwable t) { if ("ServiceConfigurationError".equals(t.getClass().getSimpleName())) { log.error("proc.bad.config.file", t.getLocalizedMessage()); } throw new Abort(t); } } public Processor next() { try { return (Processor) (iterator.next()); } catch (Throwable t) { if ("ServiceConfigurationError".equals(t.getClass().getSimpleName())) { log.error("proc.bad.config.file", t.getLocalizedMessage()); } else { log.error("proc.processor.constructor.error", t.getLocalizedMessage()); } throw new Abort(t); } } public void remove() { throw new UnsupportedOperationException(); } public void close() { if (jusl) { try { // Call java.util.ServiceLoader.reload Method reloadMethod = loaderClass.getMethod("reload"); reloadMethod.invoke(loader); } catch (Exception e) {; // Ignore problems during a call to reload. } } } } private static class NameProcessIterator implements Iterator<Processor> { Processor nextProc = null; Iterator<String> names; ClassLoader processorCL; Log log; NameProcessIterator(String names, ClassLoader processorCL, Log log) { this.names = Arrays.asList(names.split(",")).iterator(); this.processorCL = processorCL; this.log = log; } public boolean hasNext() { if (nextProc != null) return true; else { if (!names.hasNext()) return false; else { String processorName = names.next(); Processor processor; try { try { processor = (Processor) (processorCL.loadClass(processorName).newInstance()); } catch (ClassNotFoundException cnfe) { log.error("proc.processor.not.found", processorName); return false; } catch (ClassCastException cce) { log.error("proc.processor.wrong.type", processorName); return false; } catch (Exception e) { log.error("proc.processor.cant.instantiate", processorName); return false; } } catch (ClientCodeException e) { throw e; } catch (Throwable t) { throw new AnnotationProcessingError(t); } nextProc = processor; return true; } } } public Processor next() { if (hasNext()) { Processor p = nextProc; nextProc = null; return p; } else throw new NoSuchElementException(); } public void remove() { throw new UnsupportedOperationException(); } } public boolean atLeastOneProcessor() { return discoveredProcs.iterator().hasNext(); } private Map<String, String> initProcessorOptions(Context context) { Options options = Options.instance(context); Set<String> keySet = options.keySet(); Map<String, String> tempOptions = new LinkedHashMap<String, String>(); for (String key : keySet) { if (key.startsWith("-A") && key.length() > 2) { int sepIndex = key.indexOf('='); String candidateKey = null; String candidateValue = null; if (sepIndex == -1) candidateKey = key.substring(2); else if (sepIndex >= 3) { candidateKey = key.substring(2, sepIndex); candidateValue = (sepIndex < key.length() - 1) ? key.substring(sepIndex + 1) : null; } tempOptions.put(candidateKey, candidateValue); } } return Collections.unmodifiableMap(tempOptions); } private Set<String> initUnmatchedProcessorOptions() { Set<String> unmatchedProcessorOptions = new HashSet<String>(); unmatchedProcessorOptions.addAll(processorOptions.keySet()); return unmatchedProcessorOptions; } /** * State about how a processor has been used by the tool. If a processor has been used on a prior * round, its process method is called on all subsequent rounds, perhaps with an empty set of * annotations to process. The {@code annotatedSupported} method caches the supported annotation * information from the first (and only) getSupportedAnnotationTypes call to the processor. */ static class ProcessorState { public Processor processor; public boolean contributed; private ArrayList<Pattern> supportedAnnotationPatterns; private ArrayList<String> supportedOptionNames; ProcessorState(Processor p, Log log, Source source, ProcessingEnvironment env) { processor = p; contributed = false; try { processor.init(env); checkSourceVersionCompatibility(source, log); supportedAnnotationPatterns = new ArrayList<Pattern>(); for (String importString : processor.getSupportedAnnotationTypes()) { supportedAnnotationPatterns.add(importStringToPattern(importString, processor, log)); } supportedOptionNames = new ArrayList<String>(); for (String optionName : processor.getSupportedOptions()) { if (checkOptionName(optionName, log)) supportedOptionNames.add(optionName); } } catch (ClientCodeException e) { throw e; } catch (Throwable t) { throw new AnnotationProcessingError(t); } } /** * Checks whether or not a processor's source version is compatible with the compilation source * version. The processor's source version needs to be greater than or equal to the source * version of the compile. */ private void checkSourceVersionCompatibility(Source source, Log log) { SourceVersion procSourceVersion = processor.getSupportedSourceVersion(); if (procSourceVersion.compareTo(Source.toSourceVersion(source)) < 0) { log.warning( "proc.processor.incompatible.source.version", procSourceVersion, processor.getClass().getName(), source.name); } } private boolean checkOptionName(String optionName, Log log) { boolean valid = isValidOptionName(optionName); if (!valid) log.error("proc.processor.bad.option.name", optionName, processor.getClass().getName()); return valid; } public boolean annotationSupported(String annotationName) { for (Pattern p : supportedAnnotationPatterns) { if (p.matcher(annotationName).matches()) return true; } return false; } /** Remove options that are matched by this processor. */ public void removeSupportedOptions(Set<String> unmatchedProcessorOptions) { unmatchedProcessorOptions.removeAll(supportedOptionNames); } } // TODO: These two classes can probably be rewritten better... /** * This class holds information about the processors that have been discoverd so far as well as * the means to discover more, if necessary. A single iterator should be used per round of * annotation processing. The iterator first visits already discovered processors then fails over * to the service provider mechanism if additional queries are made. */ class DiscoveredProcessors implements Iterable<ProcessorState> { class ProcessorStateIterator implements Iterator<ProcessorState> { DiscoveredProcessors psi; Iterator<ProcessorState> innerIter; boolean onProcInterator; ProcessorStateIterator(DiscoveredProcessors psi) { this.psi = psi; this.innerIter = psi.procStateList.iterator(); this.onProcInterator = false; } public ProcessorState next() { if (!onProcInterator) { if (innerIter.hasNext()) return innerIter.next(); else onProcInterator = true; } if (psi.processorIterator.hasNext()) { ProcessorState ps = new ProcessorState( psi.processorIterator.next(), log, source, JavacProcessingEnvironment.this); psi.procStateList.add(ps); return ps; } else throw new NoSuchElementException(); } public boolean hasNext() { if (onProcInterator) return psi.processorIterator.hasNext(); else return innerIter.hasNext() || psi.processorIterator.hasNext(); } public void remove() { throw new UnsupportedOperationException(); } /** * Run all remaining processors on the procStateList that have not already run this round with * an empty set of annotations. */ public void runContributingProcs(RoundEnvironment re) { if (!onProcInterator) { Set<TypeElement> emptyTypeElements = Collections.emptySet(); while (innerIter.hasNext()) { ProcessorState ps = innerIter.next(); if (ps.contributed) callProcessor(ps.processor, emptyTypeElements, re); } } } } Iterator<? extends Processor> processorIterator; ArrayList<ProcessorState> procStateList; public ProcessorStateIterator iterator() { return new ProcessorStateIterator(this); } DiscoveredProcessors(Iterator<? extends Processor> processorIterator) { this.processorIterator = processorIterator; this.procStateList = new ArrayList<ProcessorState>(); } /** Free jar files, etc. if using a service loader. */ public void close() { if (processorIterator != null && processorIterator instanceof ServiceIterator) { ((ServiceIterator) processorIterator).close(); } } } private void discoverAndRunProcs( Context context, Set<TypeElement> annotationsPresent, List<ClassSymbol> topLevelClasses, List<PackageSymbol> packageInfoFiles) { Map<String, TypeElement> unmatchedAnnotations = new HashMap<String, TypeElement>(annotationsPresent.size()); for (TypeElement a : annotationsPresent) { unmatchedAnnotations.put(a.getQualifiedName().toString(), a); } // Give "*" processors a chance to match if (unmatchedAnnotations.size() == 0) unmatchedAnnotations.put("", null); DiscoveredProcessors.ProcessorStateIterator psi = discoveredProcs.iterator(); // TODO: Create proper argument values; need past round // information to fill in this constructor. Note that the 1 // st round of processing could be the last round if there // were parse errors on the initial source files; however, we // are not doing processing in that case. Set<Element> rootElements = new LinkedHashSet<Element>(); rootElements.addAll(topLevelClasses); rootElements.addAll(packageInfoFiles); rootElements = Collections.unmodifiableSet(rootElements); RoundEnvironment renv = new JavacRoundEnvironment(false, false, rootElements, JavacProcessingEnvironment.this); while (unmatchedAnnotations.size() > 0 && psi.hasNext()) { ProcessorState ps = psi.next(); Set<String> matchedNames = new HashSet<String>(); Set<TypeElement> typeElements = new LinkedHashSet<TypeElement>(); for (Map.Entry<String, TypeElement> entry : unmatchedAnnotations.entrySet()) { String unmatchedAnnotationName = entry.getKey(); if (ps.annotationSupported(unmatchedAnnotationName)) { matchedNames.add(unmatchedAnnotationName); TypeElement te = entry.getValue(); if (te != null) typeElements.add(te); } } if (matchedNames.size() > 0 || ps.contributed) { boolean processingResult = callProcessor(ps.processor, typeElements, renv); ps.contributed = true; ps.removeSupportedOptions(unmatchedProcessorOptions); if (printProcessorInfo || verbose) { log.printNoteLines( "x.print.processor.info", ps.processor.getClass().getName(), matchedNames.toString(), processingResult); } if (processingResult) { unmatchedAnnotations.keySet().removeAll(matchedNames); } } } unmatchedAnnotations.remove(""); if (lint && unmatchedAnnotations.size() > 0) { // Remove annotations processed by javac unmatchedAnnotations.keySet().removeAll(platformAnnotations); if (unmatchedAnnotations.size() > 0) { log = Log.instance(context); log.warning("proc.annotations.without.processors", unmatchedAnnotations.keySet()); } } // Run contributing processors that haven't run yet psi.runContributingProcs(renv); // Debugging if (options.isSet("displayFilerState")) filer.displayState(); } /** * Computes the set of annotations on the symbol in question. Leave class public for external * testing purposes. */ public static class ComputeAnnotationSet extends ElementScanner7<Set<TypeElement>, Set<TypeElement>> { final Elements elements; public ComputeAnnotationSet(Elements elements) { super(); this.elements = elements; } @Override public Set<TypeElement> visitPackage(PackageElement e, Set<TypeElement> p) { // Don't scan enclosed elements of a package return p; } @Override public Set<TypeElement> scan(Element e, Set<TypeElement> p) { for (AnnotationMirror annotationMirror : elements.getAllAnnotationMirrors(e)) { Element e2 = annotationMirror.getAnnotationType().asElement(); p.add((TypeElement) e2); } return super.scan(e, p); } } private boolean callProcessor( Processor proc, Set<? extends TypeElement> tes, RoundEnvironment renv) { try { return proc.process(tes, renv); } catch (BadClassFile ex) { log.error("proc.cant.access.1", ex.sym, ex.getDetailValue()); return false; } catch (CompletionFailure ex) { StringWriter out = new StringWriter(); ex.printStackTrace(new PrintWriter(out)); log.error("proc.cant.access", ex.sym, ex.getDetailValue(), out.toString()); return false; } catch (ClientCodeException e) { throw e; } catch (Throwable t) { throw new AnnotationProcessingError(t); } } /** Helper object for a single round of annotation processing. */ class Round { /** The round number. */ final int number; /** The context for the round. */ final Context context; /** The compiler for the round. */ final JavaCompiler compiler; /** The log for the round. */ final Log log; /** The ASTs to be compiled. */ List<JCCompilationUnit> roots; /** The classes to be compiler that have were generated. */ Map<String, JavaFileObject> genClassFiles; /** The set of annotations to be processed this round. */ Set<TypeElement> annotationsPresent; /** The set of top level classes to be processed this round. */ List<ClassSymbol> topLevelClasses; /** The set of package-info files to be processed this round. */ List<PackageSymbol> packageInfoFiles; /** The number of Messager errors generated in this round. */ int nMessagerErrors; /** Create a round (common code). */ private Round(Context context, int number, int priorErrors, int priorWarnings) { this.context = context; this.number = number; compiler = JavaCompiler.instance(context); log = Log.instance(context); log.nerrors = priorErrors; log.nwarnings += priorWarnings; log.deferDiagnostics = true; // the following is for the benefit of JavacProcessingEnvironment.getContext() JavacProcessingEnvironment.this.context = context; // the following will be populated as needed topLevelClasses = List.nil(); packageInfoFiles = List.nil(); } /** Create the first round. */ Round(Context context, List<JCCompilationUnit> roots, List<ClassSymbol> classSymbols) { this(context, 1, 0, 0); this.roots = roots; genClassFiles = new HashMap<String, JavaFileObject>(); compiler.todo.clear(); // free the compiler's resources // The reverse() in the following line is to maintain behavioural // compatibility with the previous revision of the code. Strictly speaking, // it should not be necessary, but a javah golden file test fails without it. topLevelClasses = getTopLevelClasses(roots).prependList(classSymbols.reverse()); packageInfoFiles = getPackageInfoFiles(roots); findAnnotationsPresent(); } /** Create a new round. */ private Round( Round prev, Set<JavaFileObject> newSourceFiles, Map<String, JavaFileObject> newClassFiles) { this(prev.nextContext(), prev.number + 1, prev.nMessagerErrors, prev.compiler.log.nwarnings); this.genClassFiles = prev.genClassFiles; List<JCCompilationUnit> parsedFiles = compiler.parseFiles(newSourceFiles); roots = cleanTrees(prev.roots).appendList(parsedFiles); // Check for errors after parsing if (unrecoverableError()) return; enterClassFiles(genClassFiles); List<ClassSymbol> newClasses = enterClassFiles(newClassFiles); genClassFiles.putAll(newClassFiles); enterTrees(roots); if (unrecoverableError()) return; topLevelClasses = join(getTopLevelClasses(parsedFiles), getTopLevelClassesFromClasses(newClasses)); packageInfoFiles = join(getPackageInfoFiles(parsedFiles), getPackageInfoFilesFromClasses(newClasses)); findAnnotationsPresent(); } /** Create the next round to be used. */ Round next(Set<JavaFileObject> newSourceFiles, Map<String, JavaFileObject> newClassFiles) { try { return new Round(this, newSourceFiles, newClassFiles); } finally { compiler.close(false); } } /** Create the compiler to be used for the final compilation. */ JavaCompiler finalCompiler(boolean errorStatus) { try { JavaCompiler c = JavaCompiler.instance(nextContext()); c.log.nwarnings += compiler.log.nwarnings; if (errorStatus) { c.log.nerrors += compiler.log.nerrors; } return c; } finally { compiler.close(false); } } /** * Return the number of errors found so far in this round. This may include uncoverable errors, * such as parse errors, and transient errors, such as missing symbols. */ int errorCount() { return compiler.errorCount(); } /** Return the number of warnings found so far in this round. */ int warningCount() { return compiler.warningCount(); } /** Return whether or not an unrecoverable error has occurred. */ boolean unrecoverableError() { if (messager.errorRaised()) return true; for (JCDiagnostic d : log.deferredDiagnostics) { switch (d.getKind()) { case WARNING: if (werror) return true; break; case ERROR: if (fatalErrors || !d.isFlagSet(RECOVERABLE)) return true; break; } } return false; } /** * Find the set of annotations present in the set of top level classes and package info files to * be processed this round. */ void findAnnotationsPresent() { ComputeAnnotationSet annotationComputer = new ComputeAnnotationSet(elementUtils); // Use annotation processing to compute the set of annotations present annotationsPresent = new LinkedHashSet<TypeElement>(); for (ClassSymbol classSym : topLevelClasses) annotationComputer.scan(classSym, annotationsPresent); for (PackageSymbol pkgSym : packageInfoFiles) annotationComputer.scan(pkgSym, annotationsPresent); } /** Enter a set of generated class files. */ private List<ClassSymbol> enterClassFiles(Map<String, JavaFileObject> classFiles) { ClassReader reader = ClassReader.instance(context); Names names = Names.instance(context); List<ClassSymbol> list = List.nil(); for (Map.Entry<String, JavaFileObject> entry : classFiles.entrySet()) { Name name = names.fromString(entry.getKey()); JavaFileObject file = entry.getValue(); if (file.getKind() != JavaFileObject.Kind.CLASS) throw new AssertionError(file); ClassSymbol cs; if (isPkgInfo(file, JavaFileObject.Kind.CLASS)) { Name packageName = Convert.packagePart(name); PackageSymbol p = reader.enterPackage(packageName); if (p.package_info == null) p.package_info = reader.enterClass(Convert.shortName(name), p); cs = p.package_info; if (cs.classfile == null) cs.classfile = file; } else cs = reader.enterClass(name, file); list = list.prepend(cs); } return list.reverse(); } /** Enter a set of syntax trees. */ private void enterTrees(List<JCCompilationUnit> roots) { compiler.enterTrees(roots); } /** Run a processing round. */ void run(boolean lastRound, boolean errorStatus) { printRoundInfo(lastRound); TaskListener taskListener = context.get(TaskListener.class); if (taskListener != null) taskListener.started(new TaskEvent(TaskEvent.Kind.ANNOTATION_PROCESSING_ROUND)); try { if (lastRound) { filer.setLastRound(true); Set<Element> emptyRootElements = Collections.emptySet(); // immutable RoundEnvironment renv = new JavacRoundEnvironment( true, errorStatus, emptyRootElements, JavacProcessingEnvironment.this); discoveredProcs.iterator().runContributingProcs(renv); } else { discoverAndRunProcs(context, annotationsPresent, topLevelClasses, packageInfoFiles); } } finally { if (taskListener != null) taskListener.finished(new TaskEvent(TaskEvent.Kind.ANNOTATION_PROCESSING_ROUND)); } nMessagerErrors = messager.errorCount(); } void showDiagnostics(boolean showAll) { Set<JCDiagnostic.Kind> kinds = EnumSet.allOf(JCDiagnostic.Kind.class); if (!showAll) { // suppress errors, which are all presumed to be transient resolve errors kinds.remove(JCDiagnostic.Kind.ERROR); } log.reportDeferredDiagnostics(kinds); } /** Print info about this round. */ private void printRoundInfo(boolean lastRound) { if (printRounds || verbose) { List<ClassSymbol> tlc = lastRound ? List.<ClassSymbol>nil() : topLevelClasses; Set<TypeElement> ap = lastRound ? Collections.<TypeElement>emptySet() : annotationsPresent; log.printNoteLines("x.print.rounds", number, "{" + tlc.toString(", ") + "}", ap, lastRound); } } /** * Get the context for the next round of processing. Important values are propogated from round * to round; other values are implicitly reset. */ private Context nextContext() { Context next = new Context(context); Options options = Options.instance(context); Assert.checkNonNull(options); next.put(Options.optionsKey, options); PrintWriter out = context.get(Log.outKey); Assert.checkNonNull(out); next.put(Log.outKey, out); Locale locale = context.get(Locale.class); if (locale != null) next.put(Locale.class, locale); Assert.checkNonNull(messages); next.put(JavacMessages.messagesKey, messages); final boolean shareNames = true; if (shareNames) { Names names = Names.instance(context); Assert.checkNonNull(names); next.put(Names.namesKey, names); } DiagnosticListener<?> dl = context.get(DiagnosticListener.class); if (dl != null) next.put(DiagnosticListener.class, dl); TaskListener tl = context.get(TaskListener.class); if (tl != null) next.put(TaskListener.class, tl); FSInfo fsInfo = context.get(FSInfo.class); if (fsInfo != null) next.put(FSInfo.class, fsInfo); JavaFileManager jfm = context.get(JavaFileManager.class); Assert.checkNonNull(jfm); next.put(JavaFileManager.class, jfm); if (jfm instanceof JavacFileManager) { ((JavacFileManager) jfm).setContext(next); } Names names = Names.instance(context); Assert.checkNonNull(names); next.put(Names.namesKey, names); Keywords keywords = Keywords.instance(context); Assert.checkNonNull(keywords); next.put(Keywords.keywordsKey, keywords); JavaCompiler oldCompiler = JavaCompiler.instance(context); JavaCompiler nextCompiler = JavaCompiler.instance(next); nextCompiler.initRound(oldCompiler); filer.newRound(next); messager.newRound(next); elementUtils.setContext(next); typeUtils.setContext(next); JavacTaskImpl task = context.get(JavacTaskImpl.class); if (task != null) { next.put(JavacTaskImpl.class, task); task.updateContext(next); } JavacTrees trees = context.get(JavacTrees.class); if (trees != null) { next.put(JavacTrees.class, trees); trees.updateContext(next); } context.clear(); return next; } } // TODO: internal catch clauses?; catch and rethrow an annotation // processing error public JavaCompiler doProcessing( Context context, List<JCCompilationUnit> roots, List<ClassSymbol> classSymbols, Iterable<? extends PackageSymbol> pckSymbols) { TaskListener taskListener = context.get(TaskListener.class); log = Log.instance(context); Set<PackageSymbol> specifiedPackages = new LinkedHashSet<PackageSymbol>(); for (PackageSymbol psym : pckSymbols) specifiedPackages.add(psym); this.specifiedPackages = Collections.unmodifiableSet(specifiedPackages); Round round = new Round(context, roots, classSymbols); boolean errorStatus; boolean moreToDo; do { // Run processors for round n round.run(false, false); // Processors for round n have run to completion. // Check for errors and whether there is more work to do. errorStatus = round.unrecoverableError(); moreToDo = moreToDo(); round.showDiagnostics(errorStatus || showResolveErrors); // Set up next round. // Copy mutable collections returned from filer. round = round.next( new LinkedHashSet<JavaFileObject>(filer.getGeneratedSourceFileObjects()), new LinkedHashMap<String, JavaFileObject>(filer.getGeneratedClasses())); // Check for errors during setup. if (round.unrecoverableError()) errorStatus = true; } while (moreToDo && !errorStatus); // run last round round.run(true, errorStatus); round.showDiagnostics(true); filer.warnIfUnclosedFiles(); warnIfUnmatchedOptions(); /* * If an annotation processor raises an error in a round, * that round runs to completion and one last round occurs. * The last round may also occur because no more source or * class files have been generated. Therefore, if an error * was raised on either of the last *two* rounds, the compile * should exit with a nonzero exit code. The current value of * errorStatus holds whether or not an error was raised on the * second to last round; errorRaised() gives the error status * of the last round. */ if (messager.errorRaised() || werror && round.warningCount() > 0 && round.errorCount() > 0) errorStatus = true; Set<JavaFileObject> newSourceFiles = new LinkedHashSet<JavaFileObject>(filer.getGeneratedSourceFileObjects()); roots = cleanTrees(round.roots); JavaCompiler compiler = round.finalCompiler(errorStatus); if (newSourceFiles.size() > 0) roots = roots.appendList(compiler.parseFiles(newSourceFiles)); errorStatus = errorStatus || (compiler.errorCount() > 0); // Free resources this.close(); if (taskListener != null) taskListener.finished(new TaskEvent(TaskEvent.Kind.ANNOTATION_PROCESSING)); if (errorStatus) { if (compiler.errorCount() == 0) compiler.log.nerrors++; return compiler; } if (procOnly && !foundTypeProcessors) { compiler.todo.clear(); } else { if (procOnly && foundTypeProcessors) compiler.shouldStopPolicy = CompileState.FLOW; compiler.enterTrees(roots); } return compiler; } private void warnIfUnmatchedOptions() { if (!unmatchedProcessorOptions.isEmpty()) { log.warning("proc.unmatched.processor.options", unmatchedProcessorOptions.toString()); } } /** Free resources related to annotation processing. */ public void close() { filer.close(); if (discoveredProcs != null) // Make calling close idempotent discoveredProcs.close(); discoveredProcs = null; if (processorClassLoader != null && processorClassLoader instanceof Closeable) { try { ((Closeable) processorClassLoader).close(); } catch (IOException e) { JCDiagnostic msg = diags.fragment("fatal.err.cant.close.loader"); throw new FatalError(msg, e); } } } private List<ClassSymbol> getTopLevelClasses(List<? extends JCCompilationUnit> units) { List<ClassSymbol> classes = List.nil(); for (JCCompilationUnit unit : units) { for (JCTree node : unit.defs) { if (node.getTag() == JCTree.CLASSDEF) { ClassSymbol sym = ((JCClassDecl) node).sym; Assert.checkNonNull(sym); classes = classes.prepend(sym); } } } return classes.reverse(); } private List<ClassSymbol> getTopLevelClassesFromClasses(List<? extends ClassSymbol> syms) { List<ClassSymbol> classes = List.nil(); for (ClassSymbol sym : syms) { if (!isPkgInfo(sym)) { classes = classes.prepend(sym); } } return classes.reverse(); } private List<PackageSymbol> getPackageInfoFiles(List<? extends JCCompilationUnit> units) { List<PackageSymbol> packages = List.nil(); for (JCCompilationUnit unit : units) { if (isPkgInfo(unit.sourcefile, JavaFileObject.Kind.SOURCE)) { packages = packages.prepend(unit.packge); } } return packages.reverse(); } private List<PackageSymbol> getPackageInfoFilesFromClasses(List<? extends ClassSymbol> syms) { List<PackageSymbol> packages = List.nil(); for (ClassSymbol sym : syms) { if (isPkgInfo(sym)) { packages = packages.prepend((PackageSymbol) sym.owner); } } return packages.reverse(); } // avoid unchecked warning from use of varargs private static <T> List<T> join(List<T> list1, List<T> list2) { return list1.appendList(list2); } private boolean isPkgInfo(JavaFileObject fo, JavaFileObject.Kind kind) { return fo.isNameCompatible("package-info", kind); } private boolean isPkgInfo(ClassSymbol sym) { return isPkgInfo(sym.classfile, JavaFileObject.Kind.CLASS) && (sym.packge().package_info == sym); } /* * Called retroactively to determine if a class loader was required, * after we have failed to create one. */ private boolean needClassLoader(String procNames, Iterable<? extends File> workingpath) { if (procNames != null) return true; String procPath; URL[] urls = new URL[1]; for (File pathElement : workingpath) { try { urls[0] = pathElement.toURI().toURL(); if (ServiceProxy.hasService(Processor.class, urls)) return true; } catch (MalformedURLException ex) { throw new AssertionError(ex); } catch (ServiceProxy.ServiceConfigurationError e) { log.error("proc.bad.config.file", e.getLocalizedMessage()); return true; } } return false; } private static <T extends JCTree> List<T> cleanTrees(List<T> nodes) { for (T node : nodes) treeCleaner.scan(node); return nodes; } private static TreeScanner treeCleaner = new TreeScanner() { public void scan(JCTree node) { super.scan(node); if (node != null) node.type = null; } public void visitTopLevel(JCCompilationUnit node) { node.packge = null; super.visitTopLevel(node); } public void visitClassDef(JCClassDecl node) { node.sym = null; super.visitClassDef(node); } public void visitMethodDef(JCMethodDecl node) { node.sym = null; super.visitMethodDef(node); } public void visitVarDef(JCVariableDecl node) { node.sym = null; super.visitVarDef(node); } public void visitNewClass(JCNewClass node) { node.constructor = null; super.visitNewClass(node); } public void visitAssignop(JCAssignOp node) { node.operator = null; super.visitAssignop(node); } public void visitUnary(JCUnary node) { node.operator = null; super.visitUnary(node); } public void visitBinary(JCBinary node) { node.operator = null; super.visitBinary(node); } public void visitSelect(JCFieldAccess node) { node.sym = null; super.visitSelect(node); } public void visitIdent(JCIdent node) { node.sym = null; super.visitIdent(node); } }; private boolean moreToDo() { return filer.newFiles(); } /** * {@inheritdoc} * * <p>Command line options suitable for presenting to annotation processors. "-Afoo=bar" should be * "-Afoo" => "bar". */ public Map<String, String> getOptions() { return processorOptions; } public Messager getMessager() { return messager; } public Filer getFiler() { return filer; } public JavacElements getElementUtils() { return elementUtils; } public JavacTypes getTypeUtils() { return typeUtils; } public SourceVersion getSourceVersion() { return Source.toSourceVersion(source); } public Locale getLocale() { return messages.getCurrentLocale(); } public Set<Symbol.PackageSymbol> getSpecifiedPackages() { return specifiedPackages; } private static final Pattern allMatches = Pattern.compile(".*"); public static final Pattern noMatches = Pattern.compile("(\\P{all})+"); /** * Convert import-style string for supported annotations into a regex matching that string. If the * string is a valid import-style string, return a regex that won't match anything. */ private static Pattern importStringToPattern(String s, Processor p, Log log) { if (isValidImportString(s)) { return validImportStringToPattern(s); } else { log.warning("proc.malformed.supported.string", s, p.getClass().getName()); return noMatches; // won't match any valid identifier } } /** * Return true if the argument string is a valid import-style string specifying claimed * annotations; return false otherwise. */ public static boolean isValidImportString(String s) { if (s.equals("*")) return true; boolean valid = true; String t = s; int index = t.indexOf('*'); if (index != -1) { // '*' must be last character... if (index == t.length() - 1) { // ... any and preceding character must be '.' if (index - 1 >= 0) { valid = t.charAt(index - 1) == '.'; // Strip off ".*$" for identifier checks t = t.substring(0, t.length() - 2); } } else return false; } // Verify string is off the form (javaId \.)+ or javaId if (valid) { String[] javaIds = t.split("\\.", t.length() + 2); for (String javaId : javaIds) valid &= SourceVersion.isIdentifier(javaId); } return valid; } public static Pattern validImportStringToPattern(String s) { if (s.equals("*")) { return allMatches; } else { String s_prime = s.replace(".", "\\."); if (s_prime.endsWith("*")) { s_prime = s_prime.substring(0, s_prime.length() - 1) + ".+"; } return Pattern.compile(s_prime); } } /** For internal use only. This method will be removed without warning. */ public Context getContext() { return context; } public String toString() { return "javac ProcessingEnvironment"; } public static boolean isValidOptionName(String optionName) { for (String s : optionName.split("\\.", -1)) { if (!SourceVersion.isIdentifier(s)) return false; } return true; } }
private void discoverAndRunProcs( Context context, Set<TypeElement> annotationsPresent, List<ClassSymbol> topLevelClasses, List<PackageSymbol> packageInfoFiles) { Map<String, TypeElement> unmatchedAnnotations = new HashMap<String, TypeElement>(annotationsPresent.size()); for (TypeElement a : annotationsPresent) { unmatchedAnnotations.put(a.getQualifiedName().toString(), a); } // Give "*" processors a chance to match if (unmatchedAnnotations.size() == 0) unmatchedAnnotations.put("", null); DiscoveredProcessors.ProcessorStateIterator psi = discoveredProcs.iterator(); // TODO: Create proper argument values; need past round // information to fill in this constructor. Note that the 1 // st round of processing could be the last round if there // were parse errors on the initial source files; however, we // are not doing processing in that case. Set<Element> rootElements = new LinkedHashSet<Element>(); rootElements.addAll(topLevelClasses); rootElements.addAll(packageInfoFiles); rootElements = Collections.unmodifiableSet(rootElements); RoundEnvironment renv = new JavacRoundEnvironment(false, false, rootElements, JavacProcessingEnvironment.this); while (unmatchedAnnotations.size() > 0 && psi.hasNext()) { ProcessorState ps = psi.next(); Set<String> matchedNames = new HashSet<String>(); Set<TypeElement> typeElements = new LinkedHashSet<TypeElement>(); for (Map.Entry<String, TypeElement> entry : unmatchedAnnotations.entrySet()) { String unmatchedAnnotationName = entry.getKey(); if (ps.annotationSupported(unmatchedAnnotationName)) { matchedNames.add(unmatchedAnnotationName); TypeElement te = entry.getValue(); if (te != null) typeElements.add(te); } } if (matchedNames.size() > 0 || ps.contributed) { boolean processingResult = callProcessor(ps.processor, typeElements, renv); ps.contributed = true; ps.removeSupportedOptions(unmatchedProcessorOptions); if (printProcessorInfo || verbose) { log.printNoteLines( "x.print.processor.info", ps.processor.getClass().getName(), matchedNames.toString(), processingResult); } if (processingResult) { unmatchedAnnotations.keySet().removeAll(matchedNames); } } } unmatchedAnnotations.remove(""); if (lint && unmatchedAnnotations.size() > 0) { // Remove annotations processed by javac unmatchedAnnotations.keySet().removeAll(platformAnnotations); if (unmatchedAnnotations.size() > 0) { log = Log.instance(context); log.warning("proc.annotations.without.processors", unmatchedAnnotations.keySet()); } } // Run contributing processors that haven't run yet psi.runContributingProcs(renv); // Debugging if (options.isSet("displayFilerState")) filer.displayState(); }
// TODO: internal catch clauses?; catch and rethrow an annotation // processing error public JavaCompiler doProcessing( Context context, List<JCCompilationUnit> roots, List<ClassSymbol> classSymbols, Iterable<? extends PackageSymbol> pckSymbols) { TaskListener taskListener = context.get(TaskListener.class); log = Log.instance(context); Set<PackageSymbol> specifiedPackages = new LinkedHashSet<PackageSymbol>(); for (PackageSymbol psym : pckSymbols) specifiedPackages.add(psym); this.specifiedPackages = Collections.unmodifiableSet(specifiedPackages); Round round = new Round(context, roots, classSymbols); boolean errorStatus; boolean moreToDo; do { // Run processors for round n round.run(false, false); // Processors for round n have run to completion. // Check for errors and whether there is more work to do. errorStatus = round.unrecoverableError(); moreToDo = moreToDo(); round.showDiagnostics(errorStatus || showResolveErrors); // Set up next round. // Copy mutable collections returned from filer. round = round.next( new LinkedHashSet<JavaFileObject>(filer.getGeneratedSourceFileObjects()), new LinkedHashMap<String, JavaFileObject>(filer.getGeneratedClasses())); // Check for errors during setup. if (round.unrecoverableError()) errorStatus = true; } while (moreToDo && !errorStatus); // run last round round.run(true, errorStatus); round.showDiagnostics(true); filer.warnIfUnclosedFiles(); warnIfUnmatchedOptions(); /* * If an annotation processor raises an error in a round, * that round runs to completion and one last round occurs. * The last round may also occur because no more source or * class files have been generated. Therefore, if an error * was raised on either of the last *two* rounds, the compile * should exit with a nonzero exit code. The current value of * errorStatus holds whether or not an error was raised on the * second to last round; errorRaised() gives the error status * of the last round. */ if (messager.errorRaised() || werror && round.warningCount() > 0 && round.errorCount() > 0) errorStatus = true; Set<JavaFileObject> newSourceFiles = new LinkedHashSet<JavaFileObject>(filer.getGeneratedSourceFileObjects()); roots = cleanTrees(round.roots); JavaCompiler compiler = round.finalCompiler(errorStatus); if (newSourceFiles.size() > 0) roots = roots.appendList(compiler.parseFiles(newSourceFiles)); errorStatus = errorStatus || (compiler.errorCount() > 0); // Free resources this.close(); if (taskListener != null) taskListener.finished(new TaskEvent(TaskEvent.Kind.ANNOTATION_PROCESSING)); if (errorStatus) { if (compiler.errorCount() == 0) compiler.log.nerrors++; return compiler; } if (procOnly && !foundTypeProcessors) { compiler.todo.clear(); } else { if (procOnly && foundTypeProcessors) compiler.shouldStopPolicy = CompileState.FLOW; compiler.enterTrees(roots); } return compiler; }