8178139: Minor typo in API documentation of java.util.logging.Logger
Reviewed-by: lancea
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* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
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package java.util.logging;
import java.io.*;
import java.util.*;
import java.security.*;
import java.lang.ref.ReferenceQueue;
import java.lang.ref.WeakReference;
import java.util.concurrent.ConcurrentHashMap;
import java.nio.file.Paths;
import java.util.concurrent.CopyOnWriteArrayList;
import java.util.concurrent.locks.ReentrantLock;
import java.util.function.BiFunction;
import java.util.function.Function;
import java.util.function.Predicate;
import java.util.stream.Collectors;
import java.util.stream.Stream;
import jdk.internal.misc.JavaAWTAccess;
import jdk.internal.misc.SharedSecrets;
import sun.util.logging.internal.LoggingProviderImpl;
import java.lang.reflect.Module;
import static jdk.internal.logger.DefaultLoggerFinder.isSystem;
/**
* There is a single global LogManager object that is used to
* maintain a set of shared state about Loggers and log services.
* <p>
* This LogManager object:
* <ul>
* <li> Manages a hierarchical namespace of Logger objects. All
* named Loggers are stored in this namespace.
* <li> Manages a set of logging control properties. These are
* simple key-value pairs that can be used by Handlers and
* other logging objects to configure themselves.
* </ul>
* <p>
* The global LogManager object can be retrieved using LogManager.getLogManager().
* The LogManager object is created during class initialization and
* cannot subsequently be changed.
* <p>
* At startup the LogManager class is located using the
* java.util.logging.manager system property.
*
* <h3>LogManager Configuration</h3>
*
* A LogManager initializes the logging configuration via
* the {@link #readConfiguration()} method during LogManager initialization.
* By default, LogManager default configuration is used.
* The logging configuration read by LogManager must be in the
* {@linkplain Properties properties file} format.
* <p>
* The LogManager defines two optional system properties that allow control over
* the initial configuration, as specified in the {@link #readConfiguration()}
* method:
* <ul>
* <li>"java.util.logging.config.class"
* <li>"java.util.logging.config.file"
* </ul>
* <p>
* These two system properties may be specified on the command line to the "java"
* command, or as system property definitions passed to JNI_CreateJavaVM.
* <p>
* The {@linkplain Properties properties} for loggers and Handlers will have
* names starting with the dot-separated name for the handler or logger.<br>
* The global logging properties may include:
* <ul>
* <li>A property "handlers". This defines a whitespace or comma separated
* list of class names for handler classes to load and register as
* handlers on the root Logger (the Logger named ""). Each class
* name must be for a Handler class which has a default constructor.
* Note that these Handlers may be created lazily, when they are
* first used.
*
* <li>A property "<logger>.handlers". This defines a whitespace or
* comma separated list of class names for handlers classes to
* load and register as handlers to the specified logger. Each class
* name must be for a Handler class which has a default constructor.
* Note that these Handlers may be created lazily, when they are
* first used.
*
* <li>A property "<logger>.handlers.ensureCloseOnReset". This defines a
* a boolean value. If "<logger>.handlers" is not defined or is empty,
* this property is ignored. Otherwise it defaults to {@code true}. When the
* value is {@code true}, the handlers associated with the logger are guaranteed
* to be closed on {@linkplain #reset} and shutdown. This can be turned off
* by explicitly setting "<logger>.handlers.ensureCloseOnReset=false" in
* the configuration. Note that turning this property off causes the risk of
* introducing a resource leak, as the logger may get garbage collected before
* {@code reset()} is called, thus preventing its handlers from being closed
* on {@code reset()}. In that case it is the responsibility of the application
* to ensure that the handlers are closed before the logger is garbage
* collected.
*
* <li>A property "<logger>.useParentHandlers". This defines a boolean
* value. By default every logger calls its parent in addition to
* handling the logging message itself, this often result in messages
* being handled by the root logger as well. When setting this property
* to false a Handler needs to be configured for this logger otherwise
* no logging messages are delivered.
*
* <li>A property "config". This property is intended to allow
* arbitrary configuration code to be run. The property defines a
* whitespace or comma separated list of class names. A new instance will be
* created for each named class. The default constructor of each class
* may execute arbitrary code to update the logging configuration, such as
* setting logger levels, adding handlers, adding filters, etc.
* </ul>
* <p>
* Note that all classes loaded during LogManager configuration are
* first searched on the system class path before any user class path.
* That includes the LogManager class, any config classes, and any
* handler classes.
* <p>
* Loggers are organized into a naming hierarchy based on their
* dot separated names. Thus "a.b.c" is a child of "a.b", but
* "a.b1" and a.b2" are peers.
* <p>
* All properties whose names end with ".level" are assumed to define
* log levels for Loggers. Thus "foo.level" defines a log level for
* the logger called "foo" and (recursively) for any of its children
* in the naming hierarchy. Log Levels are applied in the order they
* are defined in the properties file. Thus level settings for child
* nodes in the tree should come after settings for their parents.
* The property name ".level" can be used to set the level for the
* root of the tree.
* <p>
* All methods on the LogManager object are multi-thread safe.
*
* @since 1.4
*/
public class LogManager {
// The global LogManager object
private static final LogManager manager;
// 'props' is assigned within a lock but accessed without it.
// Declaring it volatile makes sure that another thread will not
// be able to see a partially constructed 'props' object.
// (seeing a partially constructed 'props' object can result in
// NPE being thrown in Hashtable.get(), because it leaves the door
// open for props.getProperties() to be called before the construcor
// of Hashtable is actually completed).
private volatile Properties props = new Properties();
private final static Level defaultLevel = Level.INFO;
// LoggerContext for system loggers and user loggers
private final LoggerContext systemContext = new SystemLoggerContext();
private final LoggerContext userContext = new LoggerContext();
// non final field - make it volatile to make sure that other threads
// will see the new value once ensureLogManagerInitialized() has finished
// executing.
private volatile Logger rootLogger;
// Have we done the primordial reading of the configuration file?
// (Must be done after a suitable amount of java.lang.System
// initialization has been done)
private volatile boolean readPrimordialConfiguration;
// Have we initialized global (root) handlers yet?
// This gets set to STATE_UNINITIALIZED in readConfiguration
private static final int
STATE_INITIALIZED = 0, // initial state
STATE_INITIALIZING = 1,
STATE_READING_CONFIG = 2,
STATE_UNINITIALIZED = 3,
STATE_SHUTDOWN = 4; // terminal state
private volatile int globalHandlersState; // = STATE_INITIALIZED;
// A concurrency lock for reset(), readConfiguration() and Cleaner.
private final ReentrantLock configurationLock = new ReentrantLock();
// This list contains the loggers for which some handlers have been
// explicitly configured in the configuration file.
// It prevents these loggers from being arbitrarily garbage collected.
private static final class CloseOnReset {
private final Logger logger;
private CloseOnReset(Logger ref) {
this.logger = Objects.requireNonNull(ref);
}
@Override
public boolean equals(Object other) {
return (other instanceof CloseOnReset) && ((CloseOnReset)other).logger == logger;
}
@Override
public int hashCode() {
return System.identityHashCode(logger);
}
public Logger get() {
return logger;
}
public static CloseOnReset create(Logger logger) {
return new CloseOnReset(logger);
}
}
private final CopyOnWriteArrayList<CloseOnReset> closeOnResetLoggers =
new CopyOnWriteArrayList<>();
private final Map<Object, Runnable> listeners =
Collections.synchronizedMap(new IdentityHashMap<>());
static {
manager = AccessController.doPrivileged(new PrivilegedAction<LogManager>() {
@Override
public LogManager run() {
LogManager mgr = null;
String cname = null;
try {
cname = System.getProperty("java.util.logging.manager");
if (cname != null) {
try {
@SuppressWarnings("deprecation")
Object tmp = ClassLoader.getSystemClassLoader()
.loadClass(cname).newInstance();
mgr = (LogManager) tmp;
} catch (ClassNotFoundException ex) {
@SuppressWarnings("deprecation")
Object tmp = Thread.currentThread()
.getContextClassLoader().loadClass(cname).newInstance();
mgr = (LogManager) tmp;
}
}
} catch (Exception ex) {
System.err.println("Could not load Logmanager \"" + cname + "\"");
ex.printStackTrace();
}
if (mgr == null) {
mgr = new LogManager();
}
return mgr;
}
});
}
// This private class is used as a shutdown hook.
// It does a "reset" to close all open handlers.
private class Cleaner extends Thread {
private Cleaner() {
super(null, null, "Logging-Cleaner", 0, false);
/* Set context class loader to null in order to avoid
* keeping a strong reference to an application classloader.
*/
this.setContextClassLoader(null);
}
@Override
public void run() {
// This is to ensure the LogManager.<clinit> is completed
// before synchronized block. Otherwise deadlocks are possible.
LogManager mgr = manager;
// set globalHandlersState to STATE_SHUTDOWN atomically so that
// no attempts are made to (re)initialize the handlers or (re)read
// the configuration again. This is terminal state.
configurationLock.lock();
globalHandlersState = STATE_SHUTDOWN;
configurationLock.unlock();
// Do a reset to close all active handlers.
reset();
}
}
/**
* Protected constructor. This is protected so that container applications
* (such as J2EE containers) can subclass the object. It is non-public as
* it is intended that there only be one LogManager object, whose value is
* retrieved by calling LogManager.getLogManager.
*/
protected LogManager() {
this(checkSubclassPermissions());
}
private LogManager(Void checked) {
// Add a shutdown hook to close the global handlers.
try {
Runtime.getRuntime().addShutdownHook(new Cleaner());
} catch (IllegalStateException e) {
// If the VM is already shutting down,
// We do not need to register shutdownHook.
}
}
private static Void checkSubclassPermissions() {
final SecurityManager sm = System.getSecurityManager();
if (sm != null) {
// These permission will be checked in the LogManager constructor,
// in order to register the Cleaner() thread as a shutdown hook.
// Check them here to avoid the penalty of constructing the object
// etc...
sm.checkPermission(new RuntimePermission("shutdownHooks"));
sm.checkPermission(new RuntimePermission("setContextClassLoader"));
}
return null;
}
/**
* Lazy initialization: if this instance of manager is the global
* manager then this method will read the initial configuration and
* add the root logger and global logger by calling addLogger().
*
* Note that it is subtly different from what we do in LoggerContext.
* In LoggerContext we're patching up the logger context tree in order to add
* the root and global logger *to the context tree*.
*
* For this to work, addLogger() must have already have been called
* once on the LogManager instance for the default logger being
* added.
*
* This is why ensureLogManagerInitialized() needs to be called before
* any logger is added to any logger context.
*
*/
private boolean initializedCalled = false;
private volatile boolean initializationDone = false;
final void ensureLogManagerInitialized() {
final LogManager owner = this;
if (initializationDone || owner != manager) {
// we don't want to do this twice, and we don't want to do
// this on private manager instances.
return;
}
// Maybe another thread has called ensureLogManagerInitialized()
// before us and is still executing it. If so we will block until
// the log manager has finished initialized, then acquire the monitor,
// notice that initializationDone is now true and return.
// Otherwise - we have come here first! We will acquire the monitor,
// see that initializationDone is still false, and perform the
// initialization.
//
configurationLock.lock();
try {
// If initializedCalled is true it means that we're already in
// the process of initializing the LogManager in this thread.
// There has been a recursive call to ensureLogManagerInitialized().
final boolean isRecursiveInitialization = (initializedCalled == true);
assert initializedCalled || !initializationDone
: "Initialization can't be done if initialized has not been called!";
if (isRecursiveInitialization || initializationDone) {
// If isRecursiveInitialization is true it means that we're
// already in the process of initializing the LogManager in
// this thread. There has been a recursive call to
// ensureLogManagerInitialized(). We should not proceed as
// it would lead to infinite recursion.
//
// If initializationDone is true then it means the manager
// has finished initializing; just return: we're done.
return;
}
// Calling addLogger below will in turn call requiresDefaultLogger()
// which will call ensureLogManagerInitialized().
// We use initializedCalled to break the recursion.
initializedCalled = true;
try {
AccessController.doPrivileged(new PrivilegedAction<Object>() {
@Override
public Object run() {
assert rootLogger == null;
assert initializedCalled && !initializationDone;
// create root logger before reading primordial
// configuration - to ensure that it will be added
// before the global logger, and not after.
owner.rootLogger = owner.new RootLogger();
// Read configuration.
owner.readPrimordialConfiguration();
// Create and retain Logger for the root of the namespace.
owner.addLogger(owner.rootLogger);
if (!owner.rootLogger.isLevelInitialized()) {
owner.rootLogger.setLevel(defaultLevel);
}
// Adding the global Logger.
// Do not call Logger.getGlobal() here as this might trigger
// subtle inter-dependency issues.
@SuppressWarnings("deprecation")
final Logger global = Logger.global;
// Make sure the global logger will be registered in the
// global manager
owner.addLogger(global);
return null;
}
});
} finally {
initializationDone = true;
}
} finally {
configurationLock.unlock();
}
}
/**
* Returns the global LogManager object.
* @return the global LogManager object
*/
public static LogManager getLogManager() {
if (manager != null) {
manager.ensureLogManagerInitialized();
}
return manager;
}
private void readPrimordialConfiguration() { // must be called while holding configurationLock
if (!readPrimordialConfiguration) {
// If System.in/out/err are null, it's a good
// indication that we're still in the
// bootstrapping phase
if (System.out == null) {
return;
}
readPrimordialConfiguration = true;
try {
readConfiguration();
// Platform loggers begin to delegate to java.util.logging.Logger
jdk.internal.logger.BootstrapLogger.redirectTemporaryLoggers();
} catch (Exception ex) {
assert false : "Exception raised while reading logging configuration: " + ex;
}
}
}
// LoggerContext maps from AppContext
private WeakHashMap<Object, LoggerContext> contextsMap = null;
// Returns the LoggerContext for the user code (i.e. application or AppContext).
// Loggers are isolated from each AppContext.
private LoggerContext getUserContext() {
LoggerContext context = null;
SecurityManager sm = System.getSecurityManager();
JavaAWTAccess javaAwtAccess = SharedSecrets.getJavaAWTAccess();
if (sm != null && javaAwtAccess != null) {
// for each applet, it has its own LoggerContext isolated from others
final Object ecx = javaAwtAccess.getAppletContext();
if (ecx != null) {
synchronized (javaAwtAccess) {
// find the AppContext of the applet code
// will be null if we are in the main app context.
if (contextsMap == null) {
contextsMap = new WeakHashMap<>();
}
context = contextsMap.get(ecx);
if (context == null) {
// Create a new LoggerContext for the applet.
context = new LoggerContext();
contextsMap.put(ecx, context);
}
}
}
}
// for standalone app, return userContext
return context != null ? context : userContext;
}
// The system context.
final LoggerContext getSystemContext() {
return systemContext;
}
private List<LoggerContext> contexts() {
List<LoggerContext> cxs = new ArrayList<>();
cxs.add(getSystemContext());
cxs.add(getUserContext());
return cxs;
}
// Find or create a specified logger instance. If a logger has
// already been created with the given name it is returned.
// Otherwise a new logger instance is created and registered
// in the LogManager global namespace.
// This method will always return a non-null Logger object.
// Synchronization is not required here. All synchronization for
// adding a new Logger object is handled by addLogger().
//
// This method must delegate to the LogManager implementation to
// add a new Logger or return the one that has been added previously
// as a LogManager subclass may override the addLogger, getLogger,
// readConfiguration, and other methods.
Logger demandLogger(String name, String resourceBundleName, Class<?> caller) {
final Module module = caller == null ? null : caller.getModule();
return demandLogger(name, resourceBundleName, module);
}
Logger demandLogger(String name, String resourceBundleName, Module module) {
Logger result = getLogger(name);
if (result == null) {
// only allocate the new logger once
Logger newLogger = new Logger(name, resourceBundleName,
module, this, false);
do {
if (addLogger(newLogger)) {
// We successfully added the new Logger that we
// created above so return it without refetching.
return newLogger;
}
// We didn't add the new Logger that we created above
// because another thread added a Logger with the same
// name after our null check above and before our call
// to addLogger(). We have to refetch the Logger because
// addLogger() returns a boolean instead of the Logger
// reference itself. However, if the thread that created
// the other Logger is not holding a strong reference to
// the other Logger, then it is possible for the other
// Logger to be GC'ed after we saw it in addLogger() and
// before we can refetch it. If it has been GC'ed then
// we'll just loop around and try again.
result = getLogger(name);
} while (result == null);
}
return result;
}
Logger demandSystemLogger(String name, String resourceBundleName, Class<?> caller) {
final Module module = caller == null ? null : caller.getModule();
return demandSystemLogger(name, resourceBundleName, module);
}
Logger demandSystemLogger(String name, String resourceBundleName, Module module) {
// Add a system logger in the system context's namespace
final Logger sysLogger = getSystemContext()
.demandLogger(name, resourceBundleName, module);
// Add the system logger to the LogManager's namespace if not exist
// so that there is only one single logger of the given name.
// System loggers are visible to applications unless a logger of
// the same name has been added.
Logger logger;
do {
// First attempt to call addLogger instead of getLogger
// This would avoid potential bug in custom LogManager.getLogger
// implementation that adds a logger if does not exist
if (addLogger(sysLogger)) {
// successfully added the new system logger
logger = sysLogger;
} else {
logger = getLogger(name);
}
} while (logger == null);
// LogManager will set the sysLogger's handlers via LogManager.addLogger method.
if (logger != sysLogger) {
// if logger already exists we merge the two logger configurations.
final Logger l = logger;
AccessController.doPrivileged(new PrivilegedAction<Void>() {
@Override
public Void run() {
l.mergeWithSystemLogger(sysLogger);
return null;
}
});
}
return sysLogger;
}
// LoggerContext maintains the logger namespace per context.
// The default LogManager implementation has one system context and user
// context. The system context is used to maintain the namespace for
// all system loggers and is queried by the system code. If a system logger
// doesn't exist in the user context, it'll also be added to the user context.
// The user context is queried by the user code and all other loggers are
// added in the user context.
class LoggerContext {
// Table of named Loggers that maps names to Loggers.
private final ConcurrentHashMap<String,LoggerWeakRef> namedLoggers =
new ConcurrentHashMap<>();
// Tree of named Loggers
private final LogNode root;
private LoggerContext() {
this.root = new LogNode(null, this);
}
// Tells whether default loggers are required in this context.
// If true, the default loggers will be lazily added.
final boolean requiresDefaultLoggers() {
final boolean requiresDefaultLoggers = (getOwner() == manager);
if (requiresDefaultLoggers) {
getOwner().ensureLogManagerInitialized();
}
return requiresDefaultLoggers;
}
// This context's LogManager.
final LogManager getOwner() {
return LogManager.this;
}
// This context owner's root logger, which if not null, and if
// the context requires default loggers, will be added to the context
// logger's tree.
final Logger getRootLogger() {
return getOwner().rootLogger;
}
// The global logger, which if not null, and if
// the context requires default loggers, will be added to the context
// logger's tree.
final Logger getGlobalLogger() {
@SuppressWarnings("deprecation") // avoids initialization cycles.
final Logger global = Logger.global;
return global;
}
Logger demandLogger(String name, String resourceBundleName, Module module) {
// a LogManager subclass may have its own implementation to add and
// get a Logger. So delegate to the LogManager to do the work.
final LogManager owner = getOwner();
return owner.demandLogger(name, resourceBundleName, module);
}
// Due to subtle deadlock issues getUserContext() no longer
// calls addLocalLogger(rootLogger);
// Therefore - we need to add the default loggers later on.
// Checks that the context is properly initialized
// This is necessary before calling e.g. find(name)
// or getLoggerNames()
//
private void ensureInitialized() {
if (requiresDefaultLoggers()) {
// Ensure that the root and global loggers are set.
ensureDefaultLogger(getRootLogger());
ensureDefaultLogger(getGlobalLogger());
}
}
Logger findLogger(String name) {
// Attempt to find logger without locking.
LoggerWeakRef ref = namedLoggers.get(name);
Logger logger = ref == null ? null : ref.get();
// if logger is not null, then we can return it right away.
// if name is "" or "global" and logger is null
// we need to fall through and check that this context is
// initialized.
// if ref is not null and logger is null we also need to
// fall through.
if (logger != null || (ref == null && !name.isEmpty()
&& !name.equals(Logger.GLOBAL_LOGGER_NAME))) {
return logger;
}
// We either found a stale reference, or we were looking for
// "" or "global" and didn't find them.
// Make sure context is initialized (has the default loggers),
// and look up again, cleaning the stale reference if it hasn't
// been cleaned up in between. All this needs to be done inside
// a synchronized block.
synchronized(this) {
// ensure that this context is properly initialized before
// looking for loggers.
ensureInitialized();
ref = namedLoggers.get(name);
if (ref == null) {
return null;
}
logger = ref.get();
if (logger == null) {
// The namedLoggers map holds stale weak reference
// to a logger which has been GC-ed.
ref.dispose();
}
return logger;
}
}
// This method is called before adding a logger to the
// context.
// 'logger' is the context that will be added.
// This method will ensure that the defaults loggers are added
// before adding 'logger'.
//
private void ensureAllDefaultLoggers(Logger logger) {
if (requiresDefaultLoggers()) {
final String name = logger.getName();
if (!name.isEmpty()) {
ensureDefaultLogger(getRootLogger());
if (!Logger.GLOBAL_LOGGER_NAME.equals(name)) {
ensureDefaultLogger(getGlobalLogger());
}
}
}
}
private void ensureDefaultLogger(Logger logger) {
// Used for lazy addition of root logger and global logger
// to a LoggerContext.
// This check is simple sanity: we do not want that this
// method be called for anything else than Logger.global
// or owner.rootLogger.
if (!requiresDefaultLoggers() || logger == null
|| logger != getGlobalLogger() && logger != LogManager.this.rootLogger ) {
// the case where we have a non null logger which is neither
// Logger.global nor manager.rootLogger indicates a serious
// issue - as ensureDefaultLogger should never be called
// with any other loggers than one of these two (or null - if
// e.g manager.rootLogger is not yet initialized)...
assert logger == null;
return;
}
// Adds the logger if it's not already there.
if (!namedLoggers.containsKey(logger.getName())) {
// It is important to prevent addLocalLogger to
// call ensureAllDefaultLoggers when we're in the process
// off adding one of those default loggers - as this would
// immediately cause a stack overflow.
// Therefore we must pass addDefaultLoggersIfNeeded=false,
// even if requiresDefaultLoggers is true.
addLocalLogger(logger, false);
}
}
boolean addLocalLogger(Logger logger) {
// no need to add default loggers if it's not required
return addLocalLogger(logger, requiresDefaultLoggers());
}
// Add a logger to this context. This method will only set its level
// and process parent loggers. It doesn't set its handlers.
synchronized boolean addLocalLogger(Logger logger, boolean addDefaultLoggersIfNeeded) {
// addDefaultLoggersIfNeeded serves to break recursion when adding
// default loggers. If we're adding one of the default loggers
// (we're being called from ensureDefaultLogger()) then
// addDefaultLoggersIfNeeded will be false: we don't want to
// call ensureAllDefaultLoggers again.
//
// Note: addDefaultLoggersIfNeeded can also be false when
// requiresDefaultLoggers is false - since calling
// ensureAllDefaultLoggers would have no effect in this case.
if (addDefaultLoggersIfNeeded) {
ensureAllDefaultLoggers(logger);
}
final String name = logger.getName();
if (name == null) {
throw new NullPointerException();
}
LoggerWeakRef ref = namedLoggers.get(name);
if (ref != null) {
if (ref.get() == null) {
// It's possible that the Logger was GC'ed after a
// drainLoggerRefQueueBounded() call above so allow
// a new one to be registered.
ref.dispose();
} else {
// We already have a registered logger with the given name.
return false;
}
}
// We're adding a new logger.
// Note that we are creating a weak reference here.
final LogManager owner = getOwner();
logger.setLogManager(owner);
ref = owner.new LoggerWeakRef(logger);
// Apply any initial level defined for the new logger, unless
// the logger's level is already initialized
Level level = owner.getLevelProperty(name + ".level", null);
if (level != null && !logger.isLevelInitialized()) {
doSetLevel(logger, level);
}
// instantiation of the handler is done in the LogManager.addLogger
// implementation as a handler class may be only visible to LogManager
// subclass for the custom log manager case
processParentHandlers(logger, name, VisitedLoggers.NEVER);
// Find the new node and its parent.
LogNode node = getNode(name);
node.loggerRef = ref;
Logger parent = null;
LogNode nodep = node.parent;
while (nodep != null) {
LoggerWeakRef nodeRef = nodep.loggerRef;
if (nodeRef != null) {
parent = nodeRef.get();
if (parent != null) {
break;
}
}
nodep = nodep.parent;
}
if (parent != null) {
doSetParent(logger, parent);
}
// Walk over the children and tell them we are their new parent.
node.walkAndSetParent(logger);
// new LogNode is ready so tell the LoggerWeakRef about it
ref.setNode(node);
// Do not publish 'ref' in namedLoggers before the logger tree
// is fully updated - because the named logger will be visible as
// soon as it is published in namedLoggers (findLogger takes
// benefit of the ConcurrentHashMap implementation of namedLoggers
// to avoid synchronizing on retrieval when that is possible).
namedLoggers.put(name, ref);
return true;
}
void removeLoggerRef(String name, LoggerWeakRef ref) {
namedLoggers.remove(name, ref);
}
synchronized Enumeration<String> getLoggerNames() {
// ensure that this context is properly initialized before
// returning logger names.
ensureInitialized();
return Collections.enumeration(namedLoggers.keySet());
}
// If logger.getUseParentHandlers() returns 'true' and any of the logger's
// parents have levels or handlers defined, make sure they are instantiated.
private void processParentHandlers(final Logger logger, final String name,
Predicate<Logger> visited) {
final LogManager owner = getOwner();
AccessController.doPrivileged(new PrivilegedAction<Void>() {
@Override
public Void run() {
if (logger != owner.rootLogger) {
boolean useParent = owner.getBooleanProperty(name + ".useParentHandlers", true);
if (!useParent) {
logger.setUseParentHandlers(false);
}
}
return null;
}
});
int ix = 1;
for (;;) {
int ix2 = name.indexOf('.', ix);
if (ix2 < 0) {
break;
}
String pname = name.substring(0, ix2);
if (owner.getProperty(pname + ".level") != null ||
owner.getProperty(pname + ".handlers") != null) {
// This pname has a level/handlers definition.
// Make sure it exists.
if (visited.test(demandLogger(pname, null, null))) {
break;
}
}
ix = ix2+1;
}
}
// Gets a node in our tree of logger nodes.
// If necessary, create it.
LogNode getNode(String name) {
if (name == null || name.equals("")) {
return root;
}
LogNode node = root;
while (name.length() > 0) {
int ix = name.indexOf('.');
String head;
if (ix > 0) {
head = name.substring(0, ix);
name = name.substring(ix + 1);
} else {
head = name;
name = "";
}
if (node.children == null) {
node.children = new HashMap<>();
}
LogNode child = node.children.get(head);
if (child == null) {
child = new LogNode(node, this);
node.children.put(head, child);
}
node = child;
}
return node;
}
}
final class SystemLoggerContext extends LoggerContext {
// Add a system logger in the system context's namespace as well as
// in the LogManager's namespace if not exist so that there is only
// one single logger of the given name. System loggers are visible
// to applications unless a logger of the same name has been added.
@Override
Logger demandLogger(String name, String resourceBundleName,
Module module) {
Logger result = findLogger(name);
if (result == null) {
// only allocate the new system logger once
Logger newLogger = new Logger(name, resourceBundleName,
module, getOwner(), true);
do {
if (addLocalLogger(newLogger)) {
// We successfully added the new Logger that we
// created above so return it without refetching.
result = newLogger;
} else {
// We didn't add the new Logger that we created above
// because another thread added a Logger with the same
// name after our null check above and before our call
// to addLogger(). We have to refetch the Logger because
// addLogger() returns a boolean instead of the Logger
// reference itself. However, if the thread that created
// the other Logger is not holding a strong reference to
// the other Logger, then it is possible for the other
// Logger to be GC'ed after we saw it in addLogger() and
// before we can refetch it. If it has been GC'ed then
// we'll just loop around and try again.
result = findLogger(name);
}
} while (result == null);
}
return result;
}
}
// Add new per logger handlers.
// We need to raise privilege here. All our decisions will
// be made based on the logging configuration, which can
// only be modified by trusted code.
private void loadLoggerHandlers(final Logger logger, final String name,
final String handlersPropertyName)
{
AccessController.doPrivileged(new PrivilegedAction<Void>() {
@Override
public Void run() {
setLoggerHandlers(logger, name, handlersPropertyName,
createLoggerHandlers(name, handlersPropertyName));
return null;
}
});
}
private void setLoggerHandlers(final Logger logger, final String name,
final String handlersPropertyName,
List<Handler> handlers)
{
final boolean ensureCloseOnReset = ! handlers.isEmpty()
&& getBooleanProperty(handlersPropertyName + ".ensureCloseOnReset",true);
int count = 0;
for (Handler hdl : handlers) {
logger.addHandler(hdl);
if (++count == 1 && ensureCloseOnReset) {
// add this logger to the closeOnResetLoggers list.
closeOnResetLoggers.addIfAbsent(CloseOnReset.create(logger));
}
}
}
private List<Handler> createLoggerHandlers(final String name, final String handlersPropertyName)
{
String names[] = parseClassNames(handlersPropertyName);
List<Handler> handlers = new ArrayList<>(names.length);
for (String type : names) {
try {
@SuppressWarnings("deprecation")
Object o = ClassLoader.getSystemClassLoader().loadClass(type).newInstance();
Handler hdl = (Handler) o;
// Check if there is a property defining the
// this handler's level.
String levs = getProperty(type + ".level");
if (levs != null) {
Level l = Level.findLevel(levs);
if (l != null) {
hdl.setLevel(l);
} else {
// Probably a bad level. Drop through.
System.err.println("Can't set level for " + type);
}
}
// Add this Handler to the logger
handlers.add(hdl);
} catch (Exception ex) {
System.err.println("Can't load log handler \"" + type + "\"");
System.err.println("" + ex);
ex.printStackTrace();
}
}
return handlers;
}
// loggerRefQueue holds LoggerWeakRef objects for Logger objects
// that have been GC'ed.
private final ReferenceQueue<Logger> loggerRefQueue
= new ReferenceQueue<>();
// Package-level inner class.
// Helper class for managing WeakReferences to Logger objects.
//
// LogManager.namedLoggers
// - has weak references to all named Loggers
// - namedLoggers keeps the LoggerWeakRef objects for the named
// Loggers around until we can deal with the book keeping for
// the named Logger that is being GC'ed.
// LogManager.LogNode.loggerRef
// - has a weak reference to a named Logger
// - the LogNode will also keep the LoggerWeakRef objects for
// the named Loggers around; currently LogNodes never go away.
// Logger.kids
// - has a weak reference to each direct child Logger; this
// includes anonymous and named Loggers
// - anonymous Loggers are always children of the rootLogger
// which is a strong reference; rootLogger.kids keeps the
// LoggerWeakRef objects for the anonymous Loggers around
// until we can deal with the book keeping.
//
final class LoggerWeakRef extends WeakReference<Logger> {
private String name; // for namedLoggers cleanup
private LogNode node; // for loggerRef cleanup
private WeakReference<Logger> parentRef; // for kids cleanup
private boolean disposed = false; // avoid calling dispose twice
LoggerWeakRef(Logger logger) {
super(logger, loggerRefQueue);
name = logger.getName(); // save for namedLoggers cleanup
}
// dispose of this LoggerWeakRef object
void dispose() {
// Avoid calling dispose twice. When a Logger is gc'ed, its
// LoggerWeakRef will be enqueued.
// However, a new logger of the same name may be added (or looked
// up) before the queue is drained. When that happens, dispose()
// will be called by addLocalLogger() or findLogger().
// Later when the queue is drained, dispose() will be called again
// for the same LoggerWeakRef. Marking LoggerWeakRef as disposed
// avoids processing the data twice (even though the code should
// now be reentrant).
synchronized(this) {
// Note to maintainers:
// Be careful not to call any method that tries to acquire
// another lock from within this block - as this would surely
// lead to deadlocks, given that dispose() can be called by
// multiple threads, and from within different synchronized
// methods/blocks.
if (disposed) return;
disposed = true;
}
final LogNode n = node;
if (n != null) {
// n.loggerRef can only be safely modified from within
// a lock on LoggerContext. removeLoggerRef is already
// synchronized on LoggerContext so calling
// n.context.removeLoggerRef from within this lock is safe.
synchronized (n.context) {
// if we have a LogNode, then we were a named Logger
// so clear namedLoggers weak ref to us
n.context.removeLoggerRef(name, this);
name = null; // clear our ref to the Logger's name
// LogNode may have been reused - so only clear
// LogNode.loggerRef if LogNode.loggerRef == this
if (n.loggerRef == this) {
n.loggerRef = null; // clear LogNode's weak ref to us
}
node = null; // clear our ref to LogNode
}
}
if (parentRef != null) {
// this LoggerWeakRef has or had a parent Logger
Logger parent = parentRef.get();
if (parent != null) {
// the parent Logger is still there so clear the
// parent Logger's weak ref to us
parent.removeChildLogger(this);
}
parentRef = null; // clear our weak ref to the parent Logger
}
}
// set the node field to the specified value
void setNode(LogNode node) {
this.node = node;
}
// set the parentRef field to the specified value
void setParentRef(WeakReference<Logger> parentRef) {
this.parentRef = parentRef;
}
}
// Package-level method.
// Drain some Logger objects that have been GC'ed.
//
// drainLoggerRefQueueBounded() is called by addLogger() below
// and by Logger.getAnonymousLogger(String) so we'll drain up to
// MAX_ITERATIONS GC'ed Loggers for every Logger we add.
//
// On a WinXP VMware client, a MAX_ITERATIONS value of 400 gives
// us about a 50/50 mix in increased weak ref counts versus
// decreased weak ref counts in the AnonLoggerWeakRefLeak test.
// Here are stats for cleaning up sets of 400 anonymous Loggers:
// - test duration 1 minute
// - sample size of 125 sets of 400
// - average: 1.99 ms
// - minimum: 0.57 ms
// - maximum: 25.3 ms
//
// The same config gives us a better decreased weak ref count
// than increased weak ref count in the LoggerWeakRefLeak test.
// Here are stats for cleaning up sets of 400 named Loggers:
// - test duration 2 minutes
// - sample size of 506 sets of 400
// - average: 0.57 ms
// - minimum: 0.02 ms
// - maximum: 10.9 ms
//
private final static int MAX_ITERATIONS = 400;
final void drainLoggerRefQueueBounded() {
for (int i = 0; i < MAX_ITERATIONS; i++) {
if (loggerRefQueue == null) {
// haven't finished loading LogManager yet
break;
}
LoggerWeakRef ref = (LoggerWeakRef) loggerRefQueue.poll();
if (ref == null) {
break;
}
// a Logger object has been GC'ed so clean it up
ref.dispose();
}
}
/**
* Add a named logger. This does nothing and returns false if a logger
* with the same name is already registered.
* <p>
* The Logger factory methods call this method to register each
* newly created Logger.
* <p>
* The application should retain its own reference to the Logger
* object to avoid it being garbage collected. The LogManager
* may only retain a weak reference.
*
* @param logger the new logger.
* @return true if the argument logger was registered successfully,
* false if a logger of that name already exists.
* @exception NullPointerException if the logger name is null.
*/
public boolean addLogger(Logger logger) {
final String name = logger.getName();
if (name == null) {
throw new NullPointerException();
}
drainLoggerRefQueueBounded();
LoggerContext cx = getUserContext();
if (cx.addLocalLogger(logger)) {
// Do we have a per logger handler too?
// Note: this will add a 200ms penalty
loadLoggerHandlers(logger, name, name + ".handlers");
return true;
} else {
return false;
}
}
// Private method to set a level on a logger.
// If necessary, we raise privilege before doing the call.
private static void doSetLevel(final Logger logger, final Level level) {
SecurityManager sm = System.getSecurityManager();
if (sm == null) {
// There is no security manager, so things are easy.
logger.setLevel(level);
return;
}
// There is a security manager. Raise privilege before
// calling setLevel.
AccessController.doPrivileged(new PrivilegedAction<Object>() {
@Override
public Object run() {
logger.setLevel(level);
return null;
}});
}
// Private method to set a parent on a logger.
// If necessary, we raise privilege before doing the setParent call.
private static void doSetParent(final Logger logger, final Logger parent) {
SecurityManager sm = System.getSecurityManager();
if (sm == null) {
// There is no security manager, so things are easy.
logger.setParent(parent);
return;
}
// There is a security manager. Raise privilege before
// calling setParent.
AccessController.doPrivileged(new PrivilegedAction<Object>() {
@Override
public Object run() {
logger.setParent(parent);
return null;
}});
}
/**
* Method to find a named logger.
* <p>
* Note that since untrusted code may create loggers with
* arbitrary names this method should not be relied on to
* find Loggers for security sensitive logging.
* It is also important to note that the Logger associated with the
* String {@code name} may be garbage collected at any time if there
* is no strong reference to the Logger. The caller of this method
* must check the return value for null in order to properly handle
* the case where the Logger has been garbage collected.
*
* @param name name of the logger
* @return matching logger or null if none is found
*/
public Logger getLogger(String name) {
return getUserContext().findLogger(name);
}
/**
* Get an enumeration of known logger names.
* <p>
* Note: Loggers may be added dynamically as new classes are loaded.
* This method only reports on the loggers that are currently registered.
* It is also important to note that this method only returns the name
* of a Logger, not a strong reference to the Logger itself.
* The returned String does nothing to prevent the Logger from being
* garbage collected. In particular, if the returned name is passed
* to {@code LogManager.getLogger()}, then the caller must check the
* return value from {@code LogManager.getLogger()} for null to properly
* handle the case where the Logger has been garbage collected in the
* time since its name was returned by this method.
*
* @return enumeration of logger name strings
*/
public Enumeration<String> getLoggerNames() {
return getUserContext().getLoggerNames();
}
/**
* Reads and initializes the logging configuration.
* <p>
* If the "java.util.logging.config.class" system property is set, then the
* property value is treated as a class name. The given class will be
* loaded, an object will be instantiated, and that object's constructor
* is responsible for reading in the initial configuration. (That object
* may use other system properties to control its configuration.) The
* alternate configuration class can use {@code readConfiguration(InputStream)}
* to define properties in the LogManager.
* <p>
* If "java.util.logging.config.class" system property is <b>not</b> set,
* then this method will read the initial configuration from a properties
* file and calls the {@link #readConfiguration(InputStream)} method to initialize
* the configuration. The "java.util.logging.config.file" system property can be used
* to specify the properties file that will be read as the initial configuration;
* if not set, then the LogManager default configuration is used.
* The default configuration is typically loaded from the
* properties file "{@code conf/logging.properties}" in the Java installation
* directory.
*
* <p>
* Any {@linkplain #addConfigurationListener registered configuration
* listener} will be invoked after the properties are read.
*
* @apiNote This {@code readConfiguration} method should only be used for
* initializing the configuration during LogManager initialization or
* used with the "java.util.logging.config.class" property.
* When this method is called after loggers have been created, and
* the "java.util.logging.config.class" system property is not set, all
* existing loggers will be {@linkplain #reset() reset}. Then any
* existing loggers that have a level property specified in the new
* configuration stream will be {@linkplain
* Logger#setLevel(java.util.logging.Level) set} to the specified log level.
* <p>
* To properly update the logging configuration, use the
* {@link #updateConfiguration(java.util.function.Function)} or
* {@link #updateConfiguration(java.io.InputStream, java.util.function.Function)}
* methods instead.
*
* @throws SecurityException if a security manager exists and if
* the caller does not have LoggingPermission("control").
* @throws IOException if there are IO problems reading the configuration.
*/
public void readConfiguration() throws IOException, SecurityException {
checkPermission();
// if a configuration class is specified, load it and use it.
String cname = System.getProperty("java.util.logging.config.class");
if (cname != null) {
try {
// Instantiate the named class. It is its constructor's
// responsibility to initialize the logging configuration, by
// calling readConfiguration(InputStream) with a suitable stream.
try {
Class<?> clz = ClassLoader.getSystemClassLoader().loadClass(cname);
@SuppressWarnings("deprecation")
Object witness = clz.newInstance();
return;
} catch (ClassNotFoundException ex) {
Class<?> clz = Thread.currentThread().getContextClassLoader().loadClass(cname);
@SuppressWarnings("deprecation")
Object witness = clz.newInstance();
return;
}
} catch (Exception ex) {
System.err.println("Logging configuration class \"" + cname + "\" failed");
System.err.println("" + ex);
// keep going and useful config file.
}
}
String fname = getConfigurationFileName();
try (final InputStream in = new FileInputStream(fname)) {
final BufferedInputStream bin = new BufferedInputStream(in);
readConfiguration(bin);
}
}
String getConfigurationFileName() throws IOException {
String fname = System.getProperty("java.util.logging.config.file");
if (fname == null) {
fname = System.getProperty("java.home");
if (fname == null) {
throw new Error("Can't find java.home ??");
}
fname = Paths.get(fname, "conf", "logging.properties")
.toAbsolutePath().normalize().toString();
}
return fname;
}
/**
* Reset the logging configuration.
* <p>
* For all named loggers, the reset operation removes and closes
* all Handlers and (except for the root logger) sets the level
* to {@code null}. The root logger's level is set to {@code Level.INFO}.
*
* @apiNote Calling this method also clears the LogManager {@linkplain
* #getProperty(java.lang.String) properties}. The {@link
* #updateConfiguration(java.util.function.Function)
* updateConfiguration(Function)} or
* {@link #updateConfiguration(java.io.InputStream, java.util.function.Function)
* updateConfiguration(InputStream, Function)} method can be used to
* properly update to a new configuration.
*
* @throws SecurityException if a security manager exists and if
* the caller does not have LoggingPermission("control").
*/
public void reset() throws SecurityException {
checkPermission();
List<CloseOnReset> persistent;
// We don't want reset() and readConfiguration()
// to run in parallel
configurationLock.lock();
try {
// install new empty properties
props = new Properties();
// make sure we keep the loggers persistent until reset is done.
// Those are the loggers for which we previously created a
// handler from the configuration, and we need to prevent them
// from being gc'ed until those handlers are closed.
persistent = new ArrayList<>(closeOnResetLoggers);
closeOnResetLoggers.clear();
// if reset has been called from shutdown-hook (Cleaner),
// or if reset has been called from readConfiguration() which
// already holds the lock and will change the state itself,
// then do not change state here...
if (globalHandlersState != STATE_SHUTDOWN &&
globalHandlersState != STATE_READING_CONFIG) {
// ...else user called reset()...
// Since we are doing a reset we no longer want to initialize
// the global handlers, if they haven't been initialized yet.
globalHandlersState = STATE_INITIALIZED;
}
for (LoggerContext cx : contexts()) {
resetLoggerContext(cx);
}
persistent.clear();
} finally {
configurationLock.unlock();
}
}
private void resetLoggerContext(LoggerContext cx) {
Enumeration<String> enum_ = cx.getLoggerNames();
while (enum_.hasMoreElements()) {
String name = enum_.nextElement();
Logger logger = cx.findLogger(name);
if (logger != null) {
resetLogger(logger);
}
}
}
private void closeHandlers(Logger logger) {
Handler[] targets = logger.getHandlers();
for (Handler h : targets) {
logger.removeHandler(h);
try {
h.close();
} catch (Exception ex) {
// Problems closing a handler? Keep going...
} catch (Error e) {
// ignore Errors while shutting down
if (globalHandlersState != STATE_SHUTDOWN) {
throw e;
}
}
}
}
// Private method to reset an individual target logger.
private void resetLogger(Logger logger) {
// Close all the Logger handlers.
closeHandlers(logger);
// Reset Logger level
String name = logger.getName();
if (name != null && name.equals("")) {
// This is the root logger.
logger.setLevel(defaultLevel);
} else {
logger.setLevel(null);
}
}
// get a list of whitespace separated classnames from a property.
private String[] parseClassNames(String propertyName) {
String hands = getProperty(propertyName);
if (hands == null) {
return new String[0];
}
hands = hands.trim();
int ix = 0;
final List<String> result = new ArrayList<>();
while (ix < hands.length()) {
int end = ix;
while (end < hands.length()) {
if (Character.isWhitespace(hands.charAt(end))) {
break;
}
if (hands.charAt(end) == ',') {
break;
}
end++;
}
String word = hands.substring(ix, end);
ix = end+1;
word = word.trim();
if (word.length() == 0) {
continue;
}
result.add(word);
}
return result.toArray(new String[result.size()]);
}
/**
* Reads and initializes the logging configuration from the given input stream.
*
* <p>
* Any {@linkplain #addConfigurationListener registered configuration
* listener} will be invoked after the properties are read.
*
* @apiNote This {@code readConfiguration} method should only be used for
* initializing the configuration during LogManager initialization or
* used with the "java.util.logging.config.class" property.
* When this method is called after loggers have been created, all
* existing loggers will be {@linkplain #reset() reset}. Then any
* existing loggers that have a level property specified in the
* given input stream will be {@linkplain
* Logger#setLevel(java.util.logging.Level) set} to the specified log level.
* <p>
* To properly update the logging configuration, use the
* {@link #updateConfiguration(java.util.function.Function)} or
* {@link #updateConfiguration(java.io.InputStream, java.util.function.Function)}
* method instead.
*
* @param ins stream to read properties from
* @throws SecurityException if a security manager exists and if
* the caller does not have LoggingPermission("control").
* @throws IOException if there are problems reading from the stream,
* or the given stream is not in the
* {@linkplain java.util.Properties properties file} format.
*/
public void readConfiguration(InputStream ins) throws IOException, SecurityException {
checkPermission();
// We don't want reset() and readConfiguration() to run
// in parallel.
configurationLock.lock();
try {
if (globalHandlersState == STATE_SHUTDOWN) {
// already in terminal state: don't even bother
// to read the configuration
return;
}
// change state to STATE_READING_CONFIG to signal reset() to not change it
globalHandlersState = STATE_READING_CONFIG;
try {
// reset configuration which leaves globalHandlersState at STATE_READING_CONFIG
// so that while reading configuration, any ongoing logging requests block and
// wait for the outcome (see the end of this try statement)
reset();
try {
// Load the properties
props.load(ins);
} catch (IllegalArgumentException x) {
// props.load may throw an IllegalArgumentException if the stream
// contains malformed Unicode escape sequences.
// We wrap that in an IOException as readConfiguration is
// specified to throw IOException if there are problems reading
// from the stream.
// Note: new IOException(x.getMessage(), x) allow us to get a more
// concise error message than new IOException(x);
throw new IOException(x.getMessage(), x);
}
// Instantiate new configuration objects.
String names[] = parseClassNames("config");
for (String word : names) {
try {
Class<?> clz = ClassLoader.getSystemClassLoader().loadClass(word);
@SuppressWarnings("deprecation")
Object witness = clz.newInstance();
} catch (Exception ex) {
System.err.println("Can't load config class \"" + word + "\"");
System.err.println("" + ex);
// ex.printStackTrace();
}
}
// Set levels on any pre-existing loggers, based on the new properties.
setLevelsOnExistingLoggers();
// Note that we need to reinitialize global handles when
// they are first referenced.
globalHandlersState = STATE_UNINITIALIZED;
} catch (Throwable t) {
// If there were any trouble, then set state to STATE_INITIALIZED
// so that no global handlers reinitialization is performed on not fully
// initialized configuration.
globalHandlersState = STATE_INITIALIZED;
// re-throw
throw t;
}
} finally {
configurationLock.unlock();
}
// should be called out of lock to avoid dead-lock situations
// when user code is involved
invokeConfigurationListeners();
}
// This enum enumerate the configuration properties that will be
// updated on existing loggers when the configuration is updated
// with LogManager.updateConfiguration().
//
// Note that this works properly only for the global LogManager - as
// Handler and its subclasses get their configuration from
// LogManager.getLogManager().
//
static enum ConfigProperty {
LEVEL(".level"), HANDLERS(".handlers"), USEPARENT(".useParentHandlers");
final String suffix;
final int length;
private ConfigProperty(String suffix) {
this.suffix = Objects.requireNonNull(suffix);
length = suffix.length();
}
public boolean handleKey(String key) {
if (this == HANDLERS && suffix.substring(1).equals(key)) return true;
if (this == HANDLERS && suffix.equals(key)) return false;
return key.endsWith(suffix);
}
String key(String loggerName) {
if (this == HANDLERS && (loggerName == null || loggerName.isEmpty())) {
return suffix.substring(1);
}
return loggerName + suffix;
}
String loggerName(String key) {
assert key.equals(suffix.substring(1)) && this == HANDLERS || key.endsWith(suffix);
if (this == HANDLERS && suffix.substring(1).equals(key)) return "";
return key.substring(0, key.length() - length);
}
/**
* If the property is one that should be updated on existing loggers by
* updateConfiguration, returns the name of the logger for which the
* property is configured. Otherwise, returns null.
* @param property a property key in 'props'
* @return the name of the logger on which the property is to be set,
* if the property is one that should be updated on existing
* loggers, {@code null} otherwise.
*/
static String getLoggerName(String property) {
for (ConfigProperty p : ConfigProperty.ALL) {
if (p.handleKey(property)) {
return p.loggerName(property);
}
}
return null; // Not a property that should be updated.
}
/**
* Find the ConfigProperty corresponding to the given
* property key (may find none).
* @param property a property key in 'props'
* @return An optional containing a ConfigProperty object,
* if the property is one that should be updated on existing
* loggers, empty otherwise.
*/
static Optional<ConfigProperty> find(String property) {
return ConfigProperty.ALL.stream()
.filter(p -> p.handleKey(property))
.findFirst();
}
/**
* Returns true if the given property is one that should be updated
* on existing loggers.
* Used to filter property name streams.
* @param property a property key from the configuration.
* @return true if this property is of interest for updateConfiguration.
*/
static boolean matches(String property) {
return find(property).isPresent();
}
/**
* Returns true if the new property value is different from the old,
* and therefore needs to be updated on existing loggers.
* @param k a property key in the configuration
* @param previous the old configuration
* @param next the new configuration
* @return true if the property is changing value between the two
* configurations.
*/
static boolean needsUpdating(String k, Properties previous, Properties next) {
final String p = trim(previous.getProperty(k, null));
final String n = trim(next.getProperty(k, null));
return ! Objects.equals(p,n);
}
/**
* Applies the mapping function for the given key to the next
* configuration.
* If the mapping function is null then this method does nothing.
* Otherwise, it calls the mapping function to compute the value
* that should be associated with {@code key} in the resulting
* configuration, and applies it to {@code next}.
* If the mapping function returns {@code null} the key is removed
* from {@code next}.
*
* @param k a property key in the configuration
* @param previous the old configuration
* @param next the new configuration (modified by this function)
* @param remappingFunction the mapping function.
*/
static void merge(String k, Properties previous, Properties next,
BiFunction<String, String, String> mappingFunction) {
String p = trim(previous.getProperty(k, null));
String n = trim(next.getProperty(k, null));
String mapped = trim(mappingFunction.apply(p,n));
if (!Objects.equals(n, mapped)) {
if (mapped == null) {
next.remove(k);
} else {
next.setProperty(k, mapped);
}
}
}
private static final EnumSet<ConfigProperty> ALL =
EnumSet.allOf(ConfigProperty.class);
}
// trim the value if not null.
private static String trim(String value) {
return value == null ? null : value.trim();
}
/**
* An object that keep track of loggers we have already visited.
* Used when updating configuration, to avoid processing the same logger
* twice.
*/
static final class VisitedLoggers implements Predicate<Logger> {
final IdentityHashMap<Logger,Boolean> visited;
private VisitedLoggers(IdentityHashMap<Logger,Boolean> visited) {
this.visited = visited;
}
VisitedLoggers() {
this(new IdentityHashMap<>());
}
@Override
public boolean test(Logger logger) {
return visited != null && visited.put(logger, Boolean.TRUE) != null;
}
public void clear() {
if (visited != null) visited.clear();
}
// An object that considers that no logger has ever been visited.
// This is used when processParentHandlers is called from
// LoggerContext.addLocalLogger
static final VisitedLoggers NEVER = new VisitedLoggers(null);
}
/**
* Type of the modification for a given property. One of SAME, ADDED, CHANGED,
* or REMOVED.
*/
static enum ModType {
SAME, // property had no value in the old and new conf, or had the
// same value in both.
ADDED, // property had no value in the old conf, but has one in the new.
CHANGED, // property has a different value in the old conf and the new conf.
REMOVED; // property has no value in the new conf, but had one in the old.
static ModType of(String previous, String next) {
if (previous == null && next != null) {
return ADDED;
}
if (next == null && previous != null) {
return REMOVED;
}
if (!Objects.equals(trim(previous), trim(next))) {
return CHANGED;
}
return SAME;
}
}
/**
* Updates the logging configuration.
* <p>
* If the "java.util.logging.config.file" system property is set,
* then the property value specifies the properties file to be read
* as the new configuration. Otherwise, the LogManager default
* configuration is used.
* <br>The default configuration is typically loaded from the
* properties file "{@code conf/logging.properties}" in the
* Java installation directory.
* <p>
* This method reads the new configuration and calls the {@link
* #updateConfiguration(java.io.InputStream, java.util.function.Function)
* updateConfiguration(ins, mapper)} method to
* update the configuration.
*
* @apiNote
* This method updates the logging configuration from reading
* a properties file and ignores the "java.util.logging.config.class"
* system property. The "java.util.logging.config.class" property is
* only used by the {@link #readConfiguration()} method to load a custom
* configuration class as an initial configuration.
*
* @param mapper a functional interface that takes a configuration
* key <i>k</i> and returns a function <i>f(o,n)</i> whose returned
* value will be applied to the resulting configuration. The
* function <i>f</i> may return {@code null} to indicate that the property
* <i>k</i> will not be added to the resulting configuration.
* <br>
* If {@code mapper} is {@code null} then {@code (k) -> ((o, n) -> n)} is
* assumed.
* <br>
* For each <i>k</i>, the mapped function <i>f</i> will
* be invoked with the value associated with <i>k</i> in the old
* configuration (i.e <i>o</i>) and the value associated with
* <i>k</i> in the new configuration (i.e. <i>n</i>).
* <br>A {@code null} value for <i>o</i> or <i>n</i> indicates that no
* value was present for <i>k</i> in the corresponding configuration.
*
* @throws SecurityException if a security manager exists and if
* the caller does not have LoggingPermission("control"), or
* does not have the permissions required to set up the
* configuration (e.g. open file specified for FileHandlers
* etc...)
*
* @throws NullPointerException if {@code mapper} returns a {@code null}
* function when invoked.
*
* @throws IOException if there are problems reading from the
* logging configuration file.
*
* @see #updateConfiguration(java.io.InputStream, java.util.function.Function)
* @since 9
*/
public void updateConfiguration(Function<String, BiFunction<String,String,String>> mapper)
throws IOException {
checkPermission();
ensureLogManagerInitialized();
drainLoggerRefQueueBounded();
String fname = getConfigurationFileName();
try (final InputStream in = new FileInputStream(fname)) {
final BufferedInputStream bin = new BufferedInputStream(in);
updateConfiguration(bin, mapper);
}
}
/**
* Updates the logging configuration.
* <p>
* For each configuration key in the {@linkplain
* #getProperty(java.lang.String) existing configuration} and
* the given input stream configuration, the given {@code mapper} function
* is invoked to map from the configuration key to a function,
* <i>f(o,n)</i>, that takes the old value and new value and returns
* the resulting value to be applied in the resulting configuration,
* as specified in the table below.
* <p>Let <i>k</i> be a configuration key in the old or new configuration,
* <i>o</i> be the old value (i.e. the value associated
* with <i>k</i> in the old configuration), <i>n</i> be the
* new value (i.e. the value associated with <i>k</i> in the new
* configuration), and <i>f</i> be the function returned
* by {@code mapper.apply(}<i>k</i>{@code )}: then <i>v = f(o,n)</i> is the
* resulting value. If <i>v</i> is not {@code null}, then a property
* <i>k</i> with value <i>v</i> will be added to the resulting configuration.
* Otherwise, it will be omitted.
* <br>A {@code null} value may be passed to function
* <i>f</i> to indicate that the corresponding configuration has no
* configuration key <i>k</i>.
* The function <i>f</i> may return {@code null} to indicate that
* there will be no value associated with <i>k</i> in the resulting
* configuration.
* <p>
* If {@code mapper} is {@code null}, then <i>v</i> will be set to
* <i>n</i>.
* <p>
* LogManager {@linkplain #getProperty(java.lang.String) properties} are
* updated with the resulting value in the resulting configuration.
* <p>
* The registered {@linkplain #addConfigurationListener configuration
* listeners} will be invoked after the configuration is successfully updated.
* <br><br>
* <table summary="Updating configuration properties">
* <tr>
* <th>Property</th>
* <th>Resulting Behavior</th>
* </tr>
* <tr>
* <td valign="top">{@code <logger>.level}</td>
* <td>
* <ul>
* <li>If the resulting configuration defines a level for a logger and
* if the resulting level is different than the level specified in the
* the old configuration, or not specified in
* the old configuration, then if the logger exists or if children for
* that logger exist, the level for that logger will be updated,
* and the change propagated to any existing logger children.
* This may cause the logger to be created, if necessary.
* </li>
* <li>If the old configuration defined a level for a logger, and the
* resulting configuration doesn't, then this change will not be
* propagated to existing loggers, if any.
* To completely replace a configuration - the caller should therefore
* call {@link #reset() reset} to empty the current configuration,
* before calling {@code updateConfiguration}.
* </li>
* </ul>
* </td>
* <tr>
* <td valign="top">{@code <logger>.useParentHandlers}</td>
* <td>
* <ul>
* <li>If either the resulting or the old value for the useParentHandlers
* property is not null, then if the logger exists or if children for
* that logger exist, that logger will be updated to the resulting
* value.
* The value of the useParentHandlers property is the value specified
* in the configuration; if not specified, the default is true.
* </li>
* </ul>
* </td>
* </tr>
* <tr>
* <td valign="top">{@code <logger>.handlers}</td>
* <td>
* <ul>
* <li>If the resulting configuration defines a list of handlers for a
* logger, and if the resulting list is different than the list
* specified in the old configuration for that logger (that could be
* empty), then if the logger exists or its children exist, the
* handlers associated with that logger are closed and removed and
* the new handlers will be created per the resulting configuration
* and added to that logger, creating that logger if necessary.
* </li>
* <li>If the old configuration defined some handlers for a logger, and
* the resulting configuration doesn't, if that logger exists,
* its handlers will be removed and closed.
* </li>
* <li>Changing the list of handlers on an existing logger will cause all
* its previous handlers to be removed and closed, regardless of whether
* they had been created from the configuration or programmatically.
* The old handlers will be replaced by new handlers, if any.
* </li>
* </ul>
* </td>
* </tr>
* <tr>
* <td valign="top">{@code <handler-name>.*}</td>
* <td>
* <ul>
* <li>Properties configured/changed on handler classes will only affect
* newly created handlers. If a node is configured with the same list
* of handlers in the old and the resulting configuration, then these
* handlers will remain unchanged.
* </li>
* </ul>
* </td>
* </tr>
* <tr>
* <td valign="top">{@code config} and any other property</td>
* <td>
* <ul>
* <li>The resulting value for these property will be stored in the
* LogManager properties, but {@code updateConfiguration} will not parse
* or process their values.
* </li>
* </ul>
* </td>
* </tr>
* </table>
* <p>
* <em>Example mapper functions:</em>
* <br><br>
* <ul>
* <li>Replace all logging properties with the new configuration:
* <br><br>{@code (k) -> ((o, n) -> n)}:
* <br><br>this is equivalent to passing a null {@code mapper} parameter.
* </li>
* <li>Merge the new configuration and old configuration and use the
* new value if <i>k</i> exists in the new configuration:
* <br><br>{@code (k) -> ((o, n) -> n == null ? o : n)}:
* <br><br>as if merging two collections as follows:
* {@code result.putAll(oldc); result.putAll(newc)}.<br></li>
* <li>Merge the new configuration and old configuration and use the old
* value if <i>k</i> exists in the old configuration:
* <br><br>{@code (k) -> ((o, n) -> o == null ? n : o)}:
* <br><br>as if merging two collections as follows:
* {@code result.putAll(newc); result.putAll(oldc)}.<br></li>
* <li>Replace all properties with the new configuration except the handler
* property to configure Logger's handler that is not root logger:
* <br>
* <pre>{@code (k) -> k.endsWith(".handlers")}
* {@code ? ((o, n) -> (o == null ? n : o))}
* {@code : ((o, n) -> n)}</pre>
* </li>
* </ul>
* <p>
* To completely reinitialize a configuration, an application can first call
* {@link #reset() reset} to fully remove the old configuration, followed by
* {@code updateConfiguration} to initialize the new configuration.
*
* @param ins a stream to read properties from
* @param mapper a functional interface that takes a configuration
* key <i>k</i> and returns a function <i>f(o,n)</i> whose returned
* value will be applied to the resulting configuration. The
* function <i>f</i> may return {@code null} to indicate that the property
* <i>k</i> will not be added to the resulting configuration.
* <br>
* If {@code mapper} is {@code null} then {@code (k) -> ((o, n) -> n)} is
* assumed.
* <br>
* For each <i>k</i>, the mapped function <i>f</i> will
* be invoked with the value associated with <i>k</i> in the old
* configuration (i.e <i>o</i>) and the value associated with
* <i>k</i> in the new configuration (i.e. <i>n</i>).
* <br>A {@code null} value for <i>o</i> or <i>n</i> indicates that no
* value was present for <i>k</i> in the corresponding configuration.
*
* @throws SecurityException if a security manager exists and if
* the caller does not have LoggingPermission("control"), or
* does not have the permissions required to set up the
* configuration (e.g. open files specified for FileHandlers)
*
* @throws NullPointerException if {@code ins} is null or if
* {@code mapper} returns a null function when invoked.
*
* @throws IOException if there are problems reading from the stream,
* or the given stream is not in the
* {@linkplain java.util.Properties properties file} format.
* @since 9
*/
public void updateConfiguration(InputStream ins,
Function<String, BiFunction<String,String,String>> mapper)
throws IOException {
checkPermission();
ensureLogManagerInitialized();
drainLoggerRefQueueBounded();
final Properties previous;
final Set<String> updatePropertyNames;
List<LoggerContext> cxs = Collections.emptyList();
final VisitedLoggers visited = new VisitedLoggers();
final Properties next = new Properties();
try {
// Load the properties
next.load(ins);
} catch (IllegalArgumentException x) {
// props.load may throw an IllegalArgumentException if the stream
// contains malformed Unicode escape sequences.
// We wrap that in an IOException as updateConfiguration is
// specified to throw IOException if there are problems reading
// from the stream.
// Note: new IOException(x.getMessage(), x) allow us to get a more
// concise error message than new IOException(x);
throw new IOException(x.getMessage(), x);
}
if (globalHandlersState == STATE_SHUTDOWN) return;
// exclusive lock: readConfiguration/reset/updateConfiguration can't
// run concurrently.
// configurationLock.writeLock().lock();
configurationLock.lock();
try {
if (globalHandlersState == STATE_SHUTDOWN) return;
previous = props;
// Builds a TreeSet of all (old and new) property names.
updatePropertyNames =
Stream.concat(previous.stringPropertyNames().stream(),
next.stringPropertyNames().stream())
.collect(Collectors.toCollection(TreeSet::new));
if (mapper != null) {
// mapper will potentially modify the content of
// 'next', so we need to call it before affecting props=next.
// give a chance to the mapper to control all
// properties - not just those we will reset.
updatePropertyNames.stream()
.forEachOrdered(k -> ConfigProperty
.merge(k, previous, next,
Objects.requireNonNull(mapper.apply(k))));
}
props = next;
// allKeys will contain all keys:
// - which correspond to a configuration property we are interested in
// (first filter)
// - whose value needs to be updated (because it's new, removed, or
// different) in the resulting configuration (second filter)
final Stream<String> allKeys = updatePropertyNames.stream()
.filter(ConfigProperty::matches)
.filter(k -> ConfigProperty.needsUpdating(k, previous, next));
// Group configuration properties by logger name
// We use a TreeMap so that parent loggers will be visited before
// child loggers.
final Map<String, TreeSet<String>> loggerConfigs =
allKeys.collect(Collectors.groupingBy(ConfigProperty::getLoggerName,
TreeMap::new,
Collectors.toCollection(TreeSet::new)));
if (!loggerConfigs.isEmpty()) {
cxs = contexts();
}
final List<Logger> loggers = cxs.isEmpty()
? Collections.emptyList() : new ArrayList<>(cxs.size());
for (Map.Entry<String, TreeSet<String>> e : loggerConfigs.entrySet()) {
// This can be a logger name, or something else...
// The only thing we know is that we found a property
// we are interested in.
// For instance, if we found x.y.z.level, then x.y.z could be
// a logger, but it could also be a handler class...
// Anyway...
final String name = e.getKey();
final Set<String> properties = e.getValue();
loggers.clear();
for (LoggerContext cx : cxs) {
Logger l = cx.findLogger(name);
if (l != null && !visited.test(l)) {
loggers.add(l);
}
}
if (loggers.isEmpty()) continue;
for (String pk : properties) {
ConfigProperty cp = ConfigProperty.find(pk).get();
String p = previous.getProperty(pk, null);
String n = next.getProperty(pk, null);
// Determines the type of modification.
ModType mod = ModType.of(p, n);
// mod == SAME means that the two values are equals, there
// is nothing to do. Usually, this should not happen as such
// properties should have been filtered above.
// It could happen however if the properties had
// trailing/leading whitespaces.
if (mod == ModType.SAME) continue;
switch (cp) {
case LEVEL:
if (mod == ModType.REMOVED) continue;
Level level = Level.findLevel(trim(n));
if (level != null) {
if (name.isEmpty()) {
rootLogger.setLevel(level);
}
for (Logger l : loggers) {
if (!name.isEmpty() || l != rootLogger) {
l.setLevel(level);
}
}
}
break;
case USEPARENT:
if (!name.isEmpty()) {
boolean useParent = getBooleanProperty(pk, true);
if (n != null || p != null) {
// reset the flag only if the previous value
// or the new value are not null.
for (Logger l : loggers) {
l.setUseParentHandlers(useParent);
}
}
}
break;
case HANDLERS:
List<Handler> hdls = null;
if (name.isEmpty()) {
// special handling for the root logger.
globalHandlersState = STATE_READING_CONFIG;
try {
closeHandlers(rootLogger);
globalHandlersState = STATE_UNINITIALIZED;
} catch (Throwable t) {
globalHandlersState = STATE_INITIALIZED;
throw t;
}
}
for (Logger l : loggers) {
if (l == rootLogger) continue;
closeHandlers(l);
if (mod == ModType.REMOVED) {
closeOnResetLoggers.removeIf(c -> c.logger == l);
continue;
}
if (hdls == null) {
hdls = name.isEmpty()
? Arrays.asList(rootLogger.getHandlers())
: createLoggerHandlers(name, pk);
}
setLoggerHandlers(l, name, pk, hdls);
}
break;
default: break;
}
}
}
} finally {
configurationLock.unlock();
visited.clear();
}
// Now ensure that if an existing logger has acquired a new parent
// in the configuration, this new parent will be created - if needed,
// and added to the context of the existing child.
//
drainLoggerRefQueueBounded();
for (LoggerContext cx : cxs) {
for (Enumeration<String> names = cx.getLoggerNames() ; names.hasMoreElements();) {
String name = names.nextElement();
if (name.isEmpty()) continue; // don't need to process parents on root.
Logger l = cx.findLogger(name);
if (l != null && !visited.test(l)) {
// should pass visited here to cut the processing when
// reaching a logger already visited.
cx.processParentHandlers(l, name, visited);
}
}
}
// We changed the configuration: invoke configuration listeners
invokeConfigurationListeners();
}
/**
* Get the value of a logging property.
* The method returns null if the property is not found.
* @param name property name
* @return property value
*/
public String getProperty(String name) {
return props.getProperty(name);
}
// Package private method to get a String property.
// If the property is not defined we return the given
// default value.
String getStringProperty(String name, String defaultValue) {
String val = getProperty(name);
if (val == null) {
return defaultValue;
}
return val.trim();
}
// Package private method to get an integer property.
// If the property is not defined or cannot be parsed
// we return the given default value.
int getIntProperty(String name, int defaultValue) {
String val = getProperty(name);
if (val == null) {
return defaultValue;
}
try {
return Integer.parseInt(val.trim());
} catch (Exception ex) {
return defaultValue;
}
}
// Package private method to get a long property.
// If the property is not defined or cannot be parsed
// we return the given default value.
long getLongProperty(String name, long defaultValue) {
String val = getProperty(name);
if (val == null) {
return defaultValue;
}
try {
return Long.parseLong(val.trim());
} catch (Exception ex) {
return defaultValue;
}
}
// Package private method to get a boolean property.
// If the property is not defined or cannot be parsed
// we return the given default value.
boolean getBooleanProperty(String name, boolean defaultValue) {
String val = getProperty(name);
if (val == null) {
return defaultValue;
}
val = val.toLowerCase();
if (val.equals("true") || val.equals("1")) {
return true;
} else if (val.equals("false") || val.equals("0")) {
return false;
}
return defaultValue;
}
// Package private method to get a Level property.
// If the property is not defined or cannot be parsed
// we return the given default value.
Level getLevelProperty(String name, Level defaultValue) {
String val = getProperty(name);
if (val == null) {
return defaultValue;
}
Level l = Level.findLevel(val.trim());
return l != null ? l : defaultValue;
}
// Package private method to get a filter property.
// We return an instance of the class named by the "name"
// property. If the property is not defined or has problems
// we return the defaultValue.
Filter getFilterProperty(String name, Filter defaultValue) {
String val = getProperty(name);
try {
if (val != null) {
@SuppressWarnings("deprecation")
Object o = ClassLoader.getSystemClassLoader().loadClass(val).newInstance();
return (Filter) o;
}
} catch (Exception ex) {
// We got one of a variety of exceptions in creating the
// class or creating an instance.
// Drop through.
}
// We got an exception. Return the defaultValue.
return defaultValue;
}
// Package private method to get a formatter property.
// We return an instance of the class named by the "name"
// property. If the property is not defined or has problems
// we return the defaultValue.
Formatter getFormatterProperty(String name, Formatter defaultValue) {
String val = getProperty(name);
try {
if (val != null) {
@SuppressWarnings("deprecation")
Object o = ClassLoader.getSystemClassLoader().loadClass(val).newInstance();
return (Formatter) o;
}
} catch (Exception ex) {
// We got one of a variety of exceptions in creating the
// class or creating an instance.
// Drop through.
}
// We got an exception. Return the defaultValue.
return defaultValue;
}
// Private method to load the global handlers.
// We do the real work lazily, when the global handlers
// are first used.
private void initializeGlobalHandlers() {
int state = globalHandlersState;
if (state == STATE_INITIALIZED ||
state == STATE_SHUTDOWN) {
// Nothing to do: return.
return;
}
// If we have not initialized global handlers yet (or need to
// reinitialize them), lets do it now (this case is indicated by
// globalHandlersState == STATE_UNINITIALIZED).
// If we are in the process of initializing global handlers we
// also need to lock & wait (this case is indicated by
// globalHandlersState == STATE_INITIALIZING).
// If we are in the process of reading configuration we also need to
// wait to see what the outcome will be (this case
// is indicated by globalHandlersState == STATE_READING_CONFIG)
// So in either case we need to wait for the lock.
configurationLock.lock();
try {
if (globalHandlersState != STATE_UNINITIALIZED) {
return; // recursive call or nothing to do
}
// set globalHandlersState to STATE_INITIALIZING first to avoid
// getting an infinite recursion when loadLoggerHandlers(...)
// is going to call addHandler(...)
globalHandlersState = STATE_INITIALIZING;
try {
loadLoggerHandlers(rootLogger, null, "handlers");
} finally {
globalHandlersState = STATE_INITIALIZED;
}
} finally {
configurationLock.unlock();
}
}
static final Permission controlPermission =
new LoggingPermission("control", null);
void checkPermission() {
SecurityManager sm = System.getSecurityManager();
if (sm != null)
sm.checkPermission(controlPermission);
}
/**
* Check that the current context is trusted to modify the logging
* configuration. This requires LoggingPermission("control").
* <p>
* If the check fails we throw a SecurityException, otherwise
* we return normally.
*
* @exception SecurityException if a security manager exists and if
* the caller does not have LoggingPermission("control").
*/
public void checkAccess() throws SecurityException {
checkPermission();
}
// Nested class to represent a node in our tree of named loggers.
private static class LogNode {
HashMap<String,LogNode> children;
LoggerWeakRef loggerRef;
LogNode parent;
final LoggerContext context;
LogNode(LogNode parent, LoggerContext context) {
this.parent = parent;
this.context = context;
}
// Recursive method to walk the tree below a node and set
// a new parent logger.
void walkAndSetParent(Logger parent) {
if (children == null) {
return;
}
for (LogNode node : children.values()) {
LoggerWeakRef ref = node.loggerRef;
Logger logger = (ref == null) ? null : ref.get();
if (logger == null) {
node.walkAndSetParent(parent);
} else {
doSetParent(logger, parent);
}
}
}
}
// We use a subclass of Logger for the root logger, so
// that we only instantiate the global handlers when they
// are first needed.
private final class RootLogger extends Logger {
private RootLogger() {
// We do not call the protected Logger two args constructor here,
// to avoid calling LogManager.getLogManager() from within the
// RootLogger constructor.
super("", null, null, LogManager.this, true);
}
@Override
public void log(LogRecord record) {
// Make sure that the global handlers have been instantiated.
initializeGlobalHandlers();
super.log(record);
}
@Override
public void addHandler(Handler h) {
initializeGlobalHandlers();
super.addHandler(h);
}
@Override
public void removeHandler(Handler h) {
initializeGlobalHandlers();
super.removeHandler(h);
}
@Override
Handler[] accessCheckedHandlers() {
initializeGlobalHandlers();
return super.accessCheckedHandlers();
}
}
// Private method to be called when the configuration has
// changed to apply any level settings to any pre-existing loggers.
private void setLevelsOnExistingLoggers() {
Enumeration<?> enum_ = props.propertyNames();
while (enum_.hasMoreElements()) {
String key = (String)enum_.nextElement();
if (!key.endsWith(".level")) {
// Not a level definition.
continue;
}
int ix = key.length() - 6;
String name = key.substring(0, ix);
Level level = getLevelProperty(key, null);
if (level == null) {
System.err.println("Bad level value for property: " + key);
continue;
}
for (LoggerContext cx : contexts()) {
Logger l = cx.findLogger(name);
if (l == null) {
continue;
}
l.setLevel(level);
}
}
}
/**
* String representation of the
* {@link javax.management.ObjectName} for the management interface
* for the logging facility.
*
* @see java.lang.management.PlatformLoggingMXBean
*
* @since 1.5
*/
public final static String LOGGING_MXBEAN_NAME
= "java.util.logging:type=Logging";
/**
* Returns {@code LoggingMXBean} for managing loggers.
*
* @return a {@link LoggingMXBean} object.
*
* @deprecated {@code java.util.logging.LoggingMXBean} is deprecated and
* replaced with {@code java.lang.management.PlatformLoggingMXBean}. Use
* {@link java.lang.management.ManagementFactory#getPlatformMXBean(Class)
* ManagementFactory.getPlatformMXBean}(PlatformLoggingMXBean.class)
* instead.
*
* @see java.lang.management.PlatformLoggingMXBean
* @since 1.5
*/
@Deprecated(since="9")
public static synchronized LoggingMXBean getLoggingMXBean() {
return Logging.getInstance();
}
/**
* Adds a configuration listener to be invoked each time the logging
* configuration is read.
* If the listener is already registered the method does nothing.
* <p>
* The listener is invoked with privileges that are restricted by the
* calling context of this method.
* The order in which the listeners are invoked is unspecified.
* <p>
* It is recommended that listeners do not throw errors or exceptions.
*
* If a listener terminates with an uncaught error or exception then
* the first exception will be propagated to the caller of
* {@link #readConfiguration()} (or {@link #readConfiguration(java.io.InputStream)})
* after all listeners have been invoked.
*
* @implNote If more than one listener terminates with an uncaught error or
* exception, an implementation may record the additional errors or
* exceptions as {@linkplain Throwable#addSuppressed(java.lang.Throwable)
* suppressed exceptions}.
*
* @param listener A configuration listener that will be invoked after the
* configuration changed.
* @return This LogManager.
* @throws SecurityException if a security manager exists and if the
* caller does not have LoggingPermission("control").
* @throws NullPointerException if the listener is null.
*
* @since 9
*/
public LogManager addConfigurationListener(Runnable listener) {
final Runnable r = Objects.requireNonNull(listener);
checkPermission();
final SecurityManager sm = System.getSecurityManager();
final AccessControlContext acc =
sm == null ? null : AccessController.getContext();
final PrivilegedAction<Void> pa =
acc == null ? null : () -> { r.run() ; return null; };
final Runnable pr =
acc == null ? r : () -> AccessController.doPrivileged(pa, acc);
// Will do nothing if already registered.
listeners.putIfAbsent(r, pr);
return this;
}
/**
* Removes a previously registered configuration listener.
*
* Returns silently if the listener is not found.
*
* @param listener the configuration listener to remove.
* @throws NullPointerException if the listener is null.
* @throws SecurityException if a security manager exists and if the
* caller does not have LoggingPermission("control").
*
* @since 9
*/
public void removeConfigurationListener(Runnable listener) {
final Runnable key = Objects.requireNonNull(listener);
checkPermission();
listeners.remove(key);
}
private void invokeConfigurationListeners() {
Throwable t = null;
// We're using an IdentityHashMap because we want to compare
// keys using identity (==).
// We don't want to loop within a block synchronized on 'listeners'
// to avoid invoking listeners from yet another synchronized block.
// So we're taking a snapshot of the values list to avoid the risk of
// ConcurrentModificationException while looping.
//
for (Runnable c : listeners.values().toArray(new Runnable[0])) {
try {
c.run();
} catch (ThreadDeath death) {
throw death;
} catch (Error | RuntimeException x) {
if (t == null) t = x;
else t.addSuppressed(x);
}
}
// Listeners are not supposed to throw exceptions, but if that
// happens, we will rethrow the first error or exception that is raised
// after all listeners have been invoked.
if (t instanceof Error) throw (Error)t;
if (t instanceof RuntimeException) throw (RuntimeException)t;
}
/**
* This class allows the {@link LoggingProviderImpl} to demand loggers on
* behalf of system and application classes.
*/
private static final class LoggingProviderAccess
implements LoggingProviderImpl.LogManagerAccess,
PrivilegedAction<Void> {
private LoggingProviderAccess() {
}
/**
* Demands a logger on behalf of the given {@code module}.
* <p>
* If a named logger suitable for the given module is found
* returns it.
* Otherwise, creates a new logger suitable for the given module.
*
* @param name The logger name.
* @param module The module on which behalf the logger is created/retrieved.
* @return A logger for the given {@code module}.
*
* @throws NullPointerException if {@code name} is {@code null}
* or {@code module} is {@code null}.
* @throws IllegalArgumentException if {@code manager} is not the default
* LogManager.
* @throws SecurityException if a security manager is present and the
* calling code doesn't have the
* {@link LoggingPermission LoggingPermission("demandLogger", null)}.
*/
@Override
public Logger demandLoggerFor(LogManager manager, String name, Module module) {
if (manager != getLogManager()) {
// having LogManager as parameter just ensures that the
// caller will have initialized the LogManager before reaching
// here.
throw new IllegalArgumentException("manager");
}
Objects.requireNonNull(name);
Objects.requireNonNull(module);
SecurityManager sm = System.getSecurityManager();
if (sm != null) {
sm.checkPermission(controlPermission);
}
if (isSystem(module)) {
return manager.demandSystemLogger(name,
Logger.SYSTEM_LOGGER_RB_NAME, module);
} else {
return manager.demandLogger(name, null, module);
}
}
@Override
public Void run() {
LoggingProviderImpl.setLogManagerAccess(INSTANCE);
return null;
}
static final LoggingProviderAccess INSTANCE = new LoggingProviderAccess();
}
static {
AccessController.doPrivileged(LoggingProviderAccess.INSTANCE, null,
controlPermission);
}
}