/*
* Copyright 2002-2014 the original author or authors.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
package org.springframework.beans;
import java.beans.BeanInfo;
import java.beans.IntrospectionException;
import java.beans.Introspector;
import java.beans.PropertyDescriptor;
import java.util.Collections;
import java.util.Iterator;
import java.util.LinkedHashMap;
import java.util.List;
import java.util.Map;
import java.util.Set;
import java.util.concurrent.ConcurrentHashMap;
import java.util.concurrent.ConcurrentMap;
import org.apache.commons.logging.Log;
import org.apache.commons.logging.LogFactory;
import org.springframework.core.SpringProperties;
import org.springframework.core.convert.TypeDescriptor;
import org.springframework.core.io.support.SpringFactoriesLoader;
import org.springframework.util.ClassUtils;
import org.springframework.util.ConcurrentReferenceHashMap;
import org.springframework.util.StringUtils;
/**
* Internal class that caches JavaBeans {@link java.beans.PropertyDescriptor}
* information for a Java class. Not intended for direct use by application code.
*
* <p>Necessary for own caching of descriptors within the application's
* ClassLoader, rather than rely on the JDK's system-wide BeanInfo cache
* (in order to avoid leaks on ClassLoader shutdown).
*
* <p>Information is cached statically, so we don't need to create new
* objects of this class for every JavaBean we manipulate. Hence, this class
* implements the factory design pattern, using a private constructor and
* a static {@link #forClass(Class)} factory method to obtain instances.
*
* <p>Note that for caching to work effectively, some preconditions need to be met:
* Prefer an arrangement where the Spring jars live in the same ClassLoader as the
* application classes, which allows for clean caching along with the application's
* lifecycle in any case. For a web application, consider declaring a local
* {@link org.springframework.web.util.IntrospectorCleanupListener} in {@code web.xml}
* in case of a multi-ClassLoader layout, which will allow for effective caching as well.
*
* <p>In case of a non-clean ClassLoader arrangement without a cleanup listener having
* been set up, this class will fall back to a weak-reference-based caching model that
* recreates much-requested entries every time the garbage collector removed them. In
* such a scenario, consider the {@link #IGNORE_BEANINFO_PROPERTY_NAME} system property.
*
* @author Rod Johnson
* @author Juergen Hoeller
* @since 05 May 2001
* @see #acceptClassLoader(ClassLoader)
* @see #clearClassLoader(ClassLoader)
* @see #forClass(Class)
*/
public class CachedIntrospectionResults {
/**
* System property that instructs Spring to use the {@link Introspector#IGNORE_ALL_BEANINFO}
* mode when calling the JavaBeans {@link Introspector}: "spring.beaninfo.ignore", with a
* value of "true" skipping the search for {@code BeanInfo} classes (typically for scenarios
* where no such classes are being defined for beans in the application in the first place).
* <p>The default is "false", considering all {@code BeanInfo} metadata classes, like for
* standard {@link Introspector#getBeanInfo(Class)} calls. Consider switching this flag to
* "true" if you experience repeated ClassLoader access for non-existing {@code BeanInfo}
* classes, in case such access is expensive on startup or on lazy loading.
* <p>Note that such an effect may also indicate a scenario where caching doesn't work
* effectively: Prefer an arrangement where the Spring jars live in the same ClassLoader
* as the application classes, which allows for clean caching along with the application's
* lifecycle in any case. For a web application, consider declaring a local
* {@link org.springframework.web.util.IntrospectorCleanupListener} in {@code web.xml}
* in case of a multi-ClassLoader layout, which will allow for effective caching as well.
* @see Introspector#getBeanInfo(Class, int)
*/
public static final String IGNORE_BEANINFO_PROPERTY_NAME = "spring.beaninfo.ignore";
private static final boolean shouldIntrospectorIgnoreBeaninfoClasses =
SpringProperties.getFlag(IGNORE_BEANINFO_PROPERTY_NAME);
/** Stores the BeanInfoFactory instances */
private static List<BeanInfoFactory> beanInfoFactories = SpringFactoriesLoader.loadFactories(
BeanInfoFactory.class, CachedIntrospectionResults.class.getClassLoader());
private static final Log logger = LogFactory.getLog(CachedIntrospectionResults.class);
/**
* Set of ClassLoaders that this CachedIntrospectionResults class will always
* accept classes from, even if the classes do not qualify as cache-safe.
*/
static final Set<ClassLoader> acceptedClassLoaders =
Collections.newSetFromMap(new ConcurrentHashMap<ClassLoader, Boolean>(16));
/**
* Map keyed by Class containing CachedIntrospectionResults, strongly held.
* This variant is being used for cache-safe bean classes.
*/
static final ConcurrentMap<Class<?>, CachedIntrospectionResults> strongClassCache =
new ConcurrentHashMap<Class<?>, CachedIntrospectionResults>(64);
/**
* Map keyed by Class containing CachedIntrospectionResults, softly held.
* This variant is being used for non-cache-safe bean classes.
*/
static final ConcurrentMap<Class<?>, CachedIntrospectionResults> softClassCache =
new ConcurrentReferenceHashMap<Class<?>, CachedIntrospectionResults>(64);
/**
* Accept the given ClassLoader as cache-safe, even if its classes would
* not qualify as cache-safe in this CachedIntrospectionResults class.
* <p>This configuration method is only relevant in scenarios where the Spring
* classes reside in a 'common' ClassLoader (e.g. the system ClassLoader)
* whose lifecycle is not coupled to the application. In such a scenario,
* CachedIntrospectionResults would by default not cache any of the application's
* classes, since they would create a leak in the common ClassLoader.
* <p>Any {@code acceptClassLoader} call at application startup should
* be paired with a {@link #clearClassLoader} call at application shutdown.
* @param classLoader the ClassLoader to accept
*/
public static void acceptClassLoader(ClassLoader classLoader) {
if (classLoader != null) {
acceptedClassLoaders.add(classLoader);
}
}
/**
* Clear the introspection cache for the given ClassLoader, removing the
* introspection results for all classes underneath that ClassLoader, and
* removing the ClassLoader (and its children) from the acceptance list.
* @param classLoader the ClassLoader to clear the cache for
*/
public static void clearClassLoader(ClassLoader classLoader) {
for (Iterator<ClassLoader> it = acceptedClassLoaders.iterator(); it.hasNext();) {
ClassLoader registeredLoader = it.next();
if (isUnderneathClassLoader(registeredLoader, classLoader)) {
it.remove();
}
}
for (Iterator<Class<?>> it = strongClassCache.keySet().iterator(); it.hasNext();) {
Class<?> beanClass = it.next();
if (isUnderneathClassLoader(beanClass.getClassLoader(), classLoader)) {
it.remove();
}
}
for (Iterator<Class<?>> it = softClassCache.keySet().iterator(); it.hasNext();) {
Class<?> beanClass = it.next();
if (isUnderneathClassLoader(beanClass.getClassLoader(), classLoader)) {
it.remove();
}
}
}
/**
* Create CachedIntrospectionResults for the given bean class.
* @param beanClass the bean class to analyze
* @return the corresponding CachedIntrospectionResults
* @throws BeansException in case of introspection failure
*/
@SuppressWarnings("unchecked")
static CachedIntrospectionResults forClass(Class<?> beanClass) throws BeansException {
CachedIntrospectionResults results = strongClassCache.get(beanClass);
if (results != null) {
return results;
}
results = softClassCache.get(beanClass);
if (results != null) {
return results;
}
results = new CachedIntrospectionResults(beanClass);
ConcurrentMap<Class<?>, CachedIntrospectionResults> classCacheToUse;
if (ClassUtils.isCacheSafe(beanClass, CachedIntrospectionResults.class.getClassLoader()) ||
isClassLoaderAccepted(beanClass.getClassLoader())) {
classCacheToUse = strongClassCache;
}
else {
if (logger.isDebugEnabled()) {
logger.debug("Not strongly caching class [" + beanClass.getName() + "] because it is not cache-safe");
}
classCacheToUse = softClassCache;
}
CachedIntrospectionResults existing = classCacheToUse.putIfAbsent(beanClass, results);
return (existing != null ? existing : results);
}
/**
* Check whether this CachedIntrospectionResults class is configured
* to accept the given ClassLoader.
* @param classLoader the ClassLoader to check
* @return whether the given ClassLoader is accepted
* @see #acceptClassLoader
*/
private static boolean isClassLoaderAccepted(ClassLoader classLoader) {
for (ClassLoader acceptedLoader : acceptedClassLoaders) {
if (isUnderneathClassLoader(classLoader, acceptedLoader)) {
return true;
}
}
return false;
}
/**
* Check whether the given ClassLoader is underneath the given parent,
* that is, whether the parent is within the candidate's hierarchy.
* @param candidate the candidate ClassLoader to check
* @param parent the parent ClassLoader to check for
*/
private static boolean isUnderneathClassLoader(ClassLoader candidate, ClassLoader parent) {
if (candidate == parent) {
return true;
}
if (candidate == null) {
return false;
}
ClassLoader classLoaderToCheck = candidate;
while (classLoaderToCheck != null) {
classLoaderToCheck = classLoaderToCheck.getParent();
if (classLoaderToCheck == parent) {
return true;
}
}
return false;
}
/** The BeanInfo object for the introspected bean class */
private final BeanInfo beanInfo;
/** PropertyDescriptor objects keyed by property name String */
private final Map<String, PropertyDescriptor> propertyDescriptorCache;
/** TypeDescriptor objects keyed by PropertyDescriptor */
private final ConcurrentMap<PropertyDescriptor, TypeDescriptor> typeDescriptorCache;
/**
* Create a new CachedIntrospectionResults instance for the given class.
* @param beanClass the bean class to analyze
* @throws BeansException in case of introspection failure
*/
private CachedIntrospectionResults(Class<?> beanClass) throws BeansException {
try {
if (logger.isTraceEnabled()) {
logger.trace("Getting BeanInfo for class [" + beanClass.getName() + "]");
}
BeanInfo beanInfo = null;
for (BeanInfoFactory beanInfoFactory : beanInfoFactories) {
beanInfo = beanInfoFactory.getBeanInfo(beanClass);
if (beanInfo != null) {
break;
}
}
if (beanInfo == null) {
// If none of the factories supported the class, fall back to the default
beanInfo = (shouldIntrospectorIgnoreBeaninfoClasses ?
Introspector.getBeanInfo(beanClass, Introspector.IGNORE_ALL_BEANINFO) :
Introspector.getBeanInfo(beanClass));
}
this.beanInfo = beanInfo;
if (logger.isTraceEnabled()) {
logger.trace("Caching PropertyDescriptors for class [" + beanClass.getName() + "]");
}
this.propertyDescriptorCache = new LinkedHashMap<String, PropertyDescriptor>();
// This call is slow so we do it once.
PropertyDescriptor[] pds = this.beanInfo.getPropertyDescriptors();
for (PropertyDescriptor pd : pds) {
if (Class.class == beanClass &&
("classLoader".equals(pd.getName()) || "protectionDomain".equals(pd.getName()))) {
// Ignore Class.getClassLoader() and getProtectionDomain() methods - nobody needs to bind to those
continue;
}
if (logger.isTraceEnabled()) {
logger.trace("Found bean property '" + pd.getName() + "'" +
(pd.getPropertyType() != null ? " of type [" + pd.getPropertyType().getName() + "]" : "") +
(pd.getPropertyEditorClass() != null ?
"; editor [" + pd.getPropertyEditorClass().getName() + "]" : ""));
}
pd = buildGenericTypeAwarePropertyDescriptor(beanClass, pd);
this.propertyDescriptorCache.put(pd.getName(), pd);
}
this.typeDescriptorCache = new ConcurrentReferenceHashMap<PropertyDescriptor, TypeDescriptor>();
}
catch (IntrospectionException ex) {
throw new FatalBeanException("Failed to obtain BeanInfo for class [" + beanClass.getName() + "]", ex);
}
}
BeanInfo getBeanInfo() {
return this.beanInfo;
}
Class<?> getBeanClass() {
return this.beanInfo.getBeanDescriptor().getBeanClass();
}
PropertyDescriptor getPropertyDescriptor(String name) {
PropertyDescriptor pd = this.propertyDescriptorCache.get(name);
if (pd == null && StringUtils.hasLength(name)) {
// Same lenient fallback checking as in PropertyTypeDescriptor...
pd = this.propertyDescriptorCache.get(name.substring(0, 1).toLowerCase() + name.substring(1));
if (pd == null) {
pd = this.propertyDescriptorCache.get(name.substring(0, 1).toUpperCase() + name.substring(1));
}
}
return (pd == null || pd instanceof GenericTypeAwarePropertyDescriptor ? pd :
buildGenericTypeAwarePropertyDescriptor(getBeanClass(), pd));
}
PropertyDescriptor[] getPropertyDescriptors() {
PropertyDescriptor[] pds = new PropertyDescriptor[this.propertyDescriptorCache.size()];
int i = 0;
for (PropertyDescriptor pd : this.propertyDescriptorCache.values()) {
pds[i] = (pd instanceof GenericTypeAwarePropertyDescriptor ? pd :
buildGenericTypeAwarePropertyDescriptor(getBeanClass(), pd));
i++;
}
return pds;
}
private PropertyDescriptor buildGenericTypeAwarePropertyDescriptor(Class<?> beanClass, PropertyDescriptor pd) {
try {
return new GenericTypeAwarePropertyDescriptor(beanClass, pd.getName(), pd.getReadMethod(),
pd.getWriteMethod(), pd.getPropertyEditorClass());
}
catch (IntrospectionException ex) {
throw new FatalBeanException("Failed to re-introspect class [" + beanClass.getName() + "]", ex);
}
}
TypeDescriptor addTypeDescriptor(PropertyDescriptor pd, TypeDescriptor td) {
TypeDescriptor existing = this.typeDescriptorCache.putIfAbsent(pd, td);
return (existing != null ? existing : td);
}
TypeDescriptor getTypeDescriptor(PropertyDescriptor pd) {
return this.typeDescriptorCache.get(pd);
}
}
