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	/*
	* Copyright (c) 1994, 2018, Oracle and/or its affiliates. All rights reserved.
	* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
	*
	* This code is free software; you can redistribute it and/or modify it
	* under the terms of the GNU General Public License version 2 only, as
	* published by the Free Software Foundation. Oracle designates this
	* particular file as subject to the "Classpath" exception as provided
	* by Oracle in the LICENSE file that accompanied this code.
	*
	* This code is distributed in the hope that it will be useful, but WITHOUT
	* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
	* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
	* version 2 for more details (a copy is included in the LICENSE file that
	* accompanied this code).
	*
	* You should have received a copy of the GNU General Public License version
	* 2 along with this work; if not, write to the Free Software Foundation,
	* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
	*
	* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
	* or visit www.oracle.com if you need additional information or have any
	* questions.
	*/

	package java.lang;

	import java.lang.annotation.Annotation;
	import java.lang.module.ModuleReader;
	import java.lang.ref.SoftReference;
	import java.io.IOException;
	import java.io.InputStream;
	import java.io.ObjectStreamField;
	import java.lang.reflect.AnnotatedElement;
	import java.lang.reflect.AnnotatedType;
	import java.lang.reflect.Array;
	import java.lang.reflect.Constructor;
	import java.lang.reflect.Executable;
	import java.lang.reflect.Field;
	import java.lang.reflect.GenericArrayType;
	import java.lang.reflect.GenericDeclaration;
	import java.lang.reflect.InvocationTargetException;
	import java.lang.reflect.Member;
	import java.lang.reflect.Method;
	import java.lang.reflect.Modifier;
	import java.lang.reflect.Proxy;
	import java.lang.reflect.Type;
	import java.lang.reflect.TypeVariable;
	import java.net.URL;
	import java.security.AccessController;
	import java.security.PrivilegedAction;
	import java.util.ArrayList;
	import java.util.Arrays;
	import java.util.Collection;
	import java.util.HashMap;
	import java.util.LinkedHashMap;
	import java.util.LinkedHashSet;
	import java.util.List;
	import java.util.Map;
	import java.util.Objects;
	import java.util.StringJoiner;

	import jdk.internal.HotSpotIntrinsicCandidate;
	import jdk.internal.loader.BootLoader;
	import jdk.internal.loader.BuiltinClassLoader;
	import jdk.internal.misc.Unsafe;
	import jdk.internal.misc.VM;
	import jdk.internal.module.Resources;
	import jdk.internal.reflect.CallerSensitive;
	import jdk.internal.reflect.ConstantPool;
	import jdk.internal.reflect.Reflection;
	import jdk.internal.reflect.ReflectionFactory;
	import jdk.internal.vm.annotation.ForceInline;
	import sun.reflect.generics.factory.CoreReflectionFactory;
	import sun.reflect.generics.factory.GenericsFactory;
	import sun.reflect.generics.repository.ClassRepository;
	import sun.reflect.generics.repository.MethodRepository;
	import sun.reflect.generics.repository.ConstructorRepository;
	import sun.reflect.generics.scope.ClassScope;
	import sun.security.util.SecurityConstants;
	import sun.reflect.annotation.*;
	import sun.reflect.misc.ReflectUtil;

	/**
	* Instances of the class {@code Class} represent classes and interfaces
	* in a running Java application. An enum type is a kind of class and an
	* annotation type is a kind of interface. Every array also
	* belongs to a class that is reflected as a {@code Class} object
	* that is shared by all arrays with the same element type and number
	* of dimensions. The primitive Java types ({@code boolean},
	* {@code byte}, {@code char}, {@code short},
	* {@code int}, {@code long}, {@code float}, and
	* {@code double}), and the keyword {@code void} are also
	* represented as {@code Class} objects.
	*
	* <p> {@code Class} has no public constructor. Instead a {@code Class}
	* object is constructed automatically by the Java Virtual Machine
	* when a class loader invokes one of the
	* {@link ClassLoader#defineClass(String,byte[], int,int) defineClass} methods
	* and passes the bytes of a {@code class} file.
	*
	* <p> The methods of class {@code Class} expose many characteristics of a
	* class or interface. Most characteristics are derived from the {@code class}
	* file that the class loader passed to the Java Virtual Machine. A few
	* characteristics are determined by the class loading environment at run time,
	* such as the module returned by {@link #getModule() getModule()}.
	*
	* <p> Some methods of class {@code Class} expose whether the declaration of
	* a class or interface in Java source code was <em>enclosed</em> within
	* another declaration. Other methods describe how a class or interface
	* is situated in a <em>nest</em>. A <a id="nest">nest</a> is a set of
	* classes and interfaces, in the same run-time package, that
	* allow mutual access to their {@code private} members.
	* The classes and interfaces are known as <em>nestmates</em>.
	* One nestmate acts as the
	* <em>nest host</em>, and enumerates the other nestmates which
	* belong to the nest; each of them in turn records it as the nest host.
	* The classes and interfaces which belong to a nest, including its host, are
	* determined when
	* {@code class} files are generated, for example, a Java compiler
	* will typically record a top-level class as the host of a nest where the
	* other members are the classes and interfaces whose declarations are
	* enclosed within the top-level class declaration.
	*
	* <p> The following example uses a {@code Class} object to print the
	* class name of an object:
	*
	* <blockquote><pre>
	* void printClassName(Object obj) {
	* System.out.println("The class of " + obj +
	* " is " + obj.getClass().getName());
	* }
	* </pre></blockquote>
	*
	* <p> It is also possible to get the {@code Class} object for a named
	* type (or for void) using a class literal. See Section 15.8.2 of
	* <cite>The Java™ Language Specification</cite>.
	* For example:
	*
	* <blockquote>
	* {@code System.out.println("The name of class Foo is: "+Foo.class.getName());}
	* </blockquote>
	*
	* @param <T> the type of the class modeled by this {@code Class}
	* object. For example, the type of {@code String.class} is {@code
	* Class<String>}. Use {@code Class<?>} if the class being modeled is
	* unknown.
	*
	* @author unascribed
	* @see java.lang.ClassLoader#defineClass(byte[], int, int)
	* @since 1.0
	*/
	public final class Class<T> implements java.io.Serializable,
	GenericDeclaration,
	Type,
	AnnotatedElement {
	private static final int ANNOTATION= 0x00002000;
	private static final int ENUM = 0x00004000;
	private static final int SYNTHETIC = 0x00001000;

	private static native void registerNatives();
	static {
	registerNatives();
	}

	/*
	* Private constructor. Only the Java Virtual Machine creates Class objects.
	* This constructor is not used and prevents the default constructor being
	* generated.
	*/
	private Class(ClassLoader loader, Class<?> arrayComponentType) {
	// Initialize final field for classLoader. The initialization value of non-null
	// prevents future JIT optimizations from assuming this final field is null.
	classLoader = loader;
	componentType = arrayComponentType;
	}

	/**
	* Converts the object to a string. The string representation is the
	* string "class" or "interface", followed by a space, and then by the
	* fully qualified name of the class in the format returned by
	* {@code getName}. If this {@code Class} object represents a
	* primitive type, this method returns the name of the primitive type. If
	* this {@code Class} object represents void this method returns
	* "void". If this {@code Class} object represents an array type,
	* this method returns "class " followed by {@code getName}.
	*
	* @return a string representation of this class object.
	*/
	public String toString() {
	return (isInterface() ? "interface " : (isPrimitive() ? "" : "class "))
	+ getName();
	}

	/**
	* Returns a string describing this {@code Class}, including
	* information about modifiers and type parameters.
	*
	* The string is formatted as a list of type modifiers, if any,
	* followed by the kind of type (empty string for primitive types
	* and {@code class}, {@code enum}, {@code interface}, or
	* <code>@</code>{@code interface}, as appropriate), followed
	* by the type's name, followed by an angle-bracketed
	* comma-separated list of the type's type parameters, if any.
	*
	* A space is used to separate modifiers from one another and to
	* separate any modifiers from the kind of type. The modifiers
	* occur in canonical order. If there are no type parameters, the
	* type parameter list is elided.
	*
	* For an array type, the string starts with the type name,
	* followed by an angle-bracketed comma-separated list of the
	* type's type parameters, if any, followed by a sequence of
	* {@code []} characters, one set of brackets per dimension of
	* the array.
	*
	* <p>Note that since information about the runtime representation
	* of a type is being generated, modifiers not present on the
	* originating source code or illegal on the originating source
	* code may be present.
	*
	* @return a string describing this {@code Class}, including
	* information about modifiers and type parameters
	*
	* @since 1.8
	*/
	public String toGenericString() {
	if (isPrimitive()) {
	return toString();
	} else {
	StringBuilder sb = new StringBuilder();
	Class<?> component = this;
	int arrayDepth = 0;

	if (isArray()) {
	do {
	arrayDepth++;
	component = component.getComponentType();
	} while (component.isArray());
	sb.append(component.getName());
	} else {
	// Class modifiers are a superset of interface modifiers
	int modifiers = getModifiers() & Modifier.classModifiers();
	if (modifiers != 0) {
	sb.append(Modifier.toString(modifiers));
	sb.append(' ');
	}

	if (isAnnotation()) {
	sb.append('@');
	}
	if (isInterface()) { // Note: all annotation types are interfaces
	sb.append("interface");
	} else {
	if (isEnum())
	sb.append("enum");
	else
	sb.append("class");
	}
	sb.append(' ');
	sb.append(getName());
	}

	TypeVariable<?>[] typeparms = component.getTypeParameters();
	if (typeparms.length > 0) {
	StringJoiner sj = new StringJoiner(",", "<", ">");
	for(TypeVariable<?> typeparm: typeparms) {
	sj.add(typeparm.getTypeName());
	}
	sb.append(sj.toString());
	}

	for (int i = 0; i < arrayDepth; i++)
	sb.append("[]");

	return sb.toString();
	}
	}

	/**
	* Returns the {@code Class} object associated with the class or
	* interface with the given string name. Invoking this method is
	* equivalent to:
	*
	* <blockquote>
	* {@code Class.forName(className, true, currentLoader)}
	* </blockquote>
	*
	* where {@code currentLoader} denotes the defining class loader of
	* the current class.
	*
	* <p> For example, the following code fragment returns the
	* runtime {@code Class} descriptor for the class named
	* {@code java.lang.Thread}:
	*
	* <blockquote>
	* {@code Class t = Class.forName("java.lang.Thread")}
	* </blockquote>
	* <p>
	* A call to {@code forName("X")} causes the class named
	* {@code X} to be initialized.
	*
	* @param className the fully qualified name of the desired class.
	* @return the {@code Class} object for the class with the
	* specified name.
	* @exception LinkageError if the linkage fails
	* @exception ExceptionInInitializerError if the initialization provoked
	* by this method fails
	* @exception ClassNotFoundException if the class cannot be located
	*/
	@CallerSensitive
	public static Class<?> forName(String className)
	throws ClassNotFoundException {
	Class<?> caller = Reflection.getCallerClass();
	return forName0(className, true, ClassLoader.getClassLoader(caller), caller);
	}


	/**
	* Returns the {@code Class} object associated with the class or
	* interface with the given string name, using the given class loader.
	* Given the fully qualified name for a class or interface (in the same
	* format returned by {@code getName}) this method attempts to
	* locate, load, and link the class or interface. The specified class
	* loader is used to load the class or interface. If the parameter
	* {@code loader} is null, the class is loaded through the bootstrap
	* class loader. The class is initialized only if the
	* {@code initialize} parameter is {@code true} and if it has
	* not been initialized earlier.
	*
	* <p> If {@code name} denotes a primitive type or void, an attempt
	* will be made to locate a user-defined class in the unnamed package whose
	* name is {@code name}. Therefore, this method cannot be used to
	* obtain any of the {@code Class} objects representing primitive
	* types or void.
	*
	* <p> If {@code name} denotes an array class, the component type of
	* the array class is loaded but not initialized.
	*
	* <p> For example, in an instance method the expression:
	*
	* <blockquote>
	* {@code Class.forName("Foo")}
	* </blockquote>
	*
	* is equivalent to:
	*
	* <blockquote>
	* {@code Class.forName("Foo", true, this.getClass().getClassLoader())}
	* </blockquote>
	*
	* Note that this method throws errors related to loading, linking or
	* initializing as specified in Sections 12.2, 12.3 and 12.4 of <em>The
	* Java Language Specification</em>.
	* Note that this method does not check whether the requested class
	* is accessible to its caller.
	*
	* @param name fully qualified name of the desired class
	* @param initialize if {@code true} the class will be initialized.
	* See Section 12.4 of <em>The Java Language Specification</em>.
	* @param loader class loader from which the class must be loaded
	* @return class object representing the desired class
	*
	* @exception LinkageError if the linkage fails
	* @exception ExceptionInInitializerError if the initialization provoked
	* by this method fails
	* @exception ClassNotFoundException if the class cannot be located by
	* the specified class loader
	* @exception SecurityException
	* if a security manager is present, and the {@code loader} is
	* {@code null}, and the caller's class loader is not
	* {@code null}, and the caller does not have the
	* {@link RuntimePermission}{@code ("getClassLoader")}
	*
	* @see java.lang.Class#forName(String)
	* @see java.lang.ClassLoader
	* @since 1.2
	*/
	@CallerSensitive
	public static Class<?> forName(String name, boolean initialize,
	ClassLoader loader)
	throws ClassNotFoundException
	{
	Class<?> caller = null;
	SecurityManager sm = System.getSecurityManager();
	if (sm != null) {
	// Reflective call to get caller class is only needed if a security manager
	// is present. Avoid the overhead of making this call otherwise.
	caller = Reflection.getCallerClass();
	if (loader == null) {
	ClassLoader ccl = ClassLoader.getClassLoader(caller);
	if (ccl != null) {
	sm.checkPermission(
	SecurityConstants.GET_CLASSLOADER_PERMISSION);
	}
	}
	}
	return forName0(name, initialize, loader, caller);
	}

	/** Called after security check for system loader access checks have been made. */
	private static native Class<?> forName0(String name, boolean initialize,
	ClassLoader loader,
	Class<?> caller)
	throws ClassNotFoundException;


	/**
	* Returns the {@code Class} with the given <a href="ClassLoader.html#name">
	* binary name</a> in the given module.
	*
	* <p> This method attempts to locate, load, and link the class or interface.
	* It does not run the class initializer. If the class is not found, this
	* method returns {@code null}. </p>
	*
	* <p> If the class loader of the given module defines other modules and
	* the given name is a class defined in a different module, this method
	* returns {@code null} after the class is loaded. </p>
	*
	* <p> This method does not check whether the requested class is
	* accessible to its caller. </p>
	*
	* @apiNote
	* This method returns {@code null} on failure rather than
	* throwing a {@link ClassNotFoundException}, as is done by
	* the {@link #forName(String, boolean, ClassLoader)} method.
	* The security check is a stack-based permission check if the caller
	* loads a class in another module.
	*
	* @param module A module
	* @param name The <a href="ClassLoader.html#name">binary name</a>
	* of the class
	* @return {@code Class} object of the given name defined in the given module;
	* {@code null} if not found.
	*
	* @throws NullPointerException if the given module or name is {@code null}
	*
	* @throws LinkageError if the linkage fails
	*
	* @throws SecurityException
	* <ul>
	* <li> if the caller is not the specified module and
	* {@code RuntimePermission("getClassLoader")} permission is denied; or</li>
	* <li> access to the module content is denied. For example,
	* permission check will be performed when a class loader calls
	* {@link ModuleReader#open(String)} to read the bytes of a class file
	* in a module.</li>
	* </ul>
	*
	* @since 9
	* @spec JPMS
	*/
	@CallerSensitive
	public static Class<?> forName(Module module, String name) {
	Objects.requireNonNull(module);
	Objects.requireNonNull(name);

	ClassLoader cl;
	SecurityManager sm = System.getSecurityManager();
	if (sm != null) {
	Class<?> caller = Reflection.getCallerClass();
	if (caller != null && caller.getModule() != module) {
	// if caller is null, Class.forName is the last java frame on the stack.
	// java.base has all permissions
	sm.checkPermission(SecurityConstants.GET_CLASSLOADER_PERMISSION);
	}
	PrivilegedAction<ClassLoader> pa = module::getClassLoader;
	cl = AccessController.doPrivileged(pa);
	} else {
	cl = module.getClassLoader();
	}

	if (cl != null) {
	return cl.loadClass(module, name);
	} else {
	return BootLoader.loadClass(module, name);
	}
	}

	/**
	* Creates a new instance of the class represented by this {@code Class}
	* object. The class is instantiated as if by a {@code new}
	* expression with an empty argument list. The class is initialized if it
	* has not already been initialized.
	*
	* @deprecated This method propagates any exception thrown by the
	* nullary constructor, including a checked exception. Use of
	* this method effectively bypasses the compile-time exception
	* checking that would otherwise be performed by the compiler.
	* The {@link
	* java.lang.reflect.Constructor#newInstance(java.lang.Object...)
	* Constructor.newInstance} method avoids this problem by wrapping
	* any exception thrown by the constructor in a (checked) {@link
	* java.lang.reflect.InvocationTargetException}.
	*
	* <p>The call
	*
	* <pre>{@code
	* clazz.newInstance()
	* }</pre>
	*
	* can be replaced by
	*
	* <pre>{@code
	* clazz.getDeclaredConstructor().newInstance()
	* }</pre>
	*
	* The latter sequence of calls is inferred to be able to throw
	* the additional exception types {@link
	* InvocationTargetException} and {@link
	* NoSuchMethodException}. Both of these exception types are
	* subclasses of {@link ReflectiveOperationException}.
	*
	* @return a newly allocated instance of the class represented by this
	* object.
	* @throws IllegalAccessException if the class or its nullary
	* constructor is not accessible.
	* @throws InstantiationException
	* if this {@code Class} represents an abstract class,
	* an interface, an array class, a primitive type, or void;
	* or if the class has no nullary constructor;
	* or if the instantiation fails for some other reason.
	* @throws ExceptionInInitializerError if the initialization
	* provoked by this method fails.
	* @throws SecurityException
	* If a security manager, <i>s</i>, is present and
	* the caller's class loader is not the same as or an
	* ancestor of the class loader for the current class and
	* invocation of {@link SecurityManager#checkPackageAccess
	* s.checkPackageAccess()} denies access to the package
	* of this class.
	*/
	@CallerSensitive
	@Deprecated(since="9")
	public T newInstance()
	throws InstantiationException, IllegalAccessException
	{
	SecurityManager sm = System.getSecurityManager();
	if (sm != null) {
	checkMemberAccess(sm, Member.PUBLIC, Reflection.getCallerClass(), false);
	}

	// NOTE: the following code may not be strictly correct under
	// the current Java memory model.

	// Constructor lookup
	if (cachedConstructor == null) {
	if (this == Class.class) {
	throw new IllegalAccessException(
	"Can not call newInstance() on the Class for java.lang.Class"
	);
	}
	try {
	Class<?>[] empty = {};
	final Constructor<T> c = getReflectionFactory().copyConstructor(
	getConstructor0(empty, Member.DECLARED));
	// Disable accessibility checks on the constructor
	// since we have to do the security check here anyway
	// (the stack depth is wrong for the Constructor's
	// security check to work)
	java.security.AccessController.doPrivileged(
	new java.security.PrivilegedAction<>() {
	public Void run() {
	c.setAccessible(true);
	return null;
	}
	});
	cachedConstructor = c;
	} catch (NoSuchMethodException e) {
	throw (InstantiationException)
	new InstantiationException(getName()).initCause(e);
	}
	}
	Constructor<T> tmpConstructor = cachedConstructor;
	// Security check (same as in java.lang.reflect.Constructor)
	Class<?> caller = Reflection.getCallerClass();
	if (newInstanceCallerCache != caller) {
	int modifiers = tmpConstructor.getModifiers();
	Reflection.ensureMemberAccess(caller, this, this, modifiers);
	newInstanceCallerCache = caller;
	}
	// Run constructor
	try {
	return tmpConstructor.newInstance((Object[])null);
	} catch (InvocationTargetException e) {
	Unsafe.getUnsafe().throwException(e.getTargetException());
	// Not reached
	return null;
	}
	}
	private transient volatile Constructor<T> cachedConstructor;
	private transient volatile Class<?> newInstanceCallerCache;


	/**
	* Determines if the specified {@code Object} is assignment-compatible
	* with the object represented by this {@code Class}. This method is
	* the dynamic equivalent of the Java language {@code instanceof}
	* operator. The method returns {@code true} if the specified
	* {@code Object} argument is non-null and can be cast to the
	* reference type represented by this {@code Class} object without
	* raising a {@code ClassCastException.} It returns {@code false}
	* otherwise.
	*
	* <p> Specifically, if this {@code Class} object represents a
	* declared class, this method returns {@code true} if the specified
	* {@code Object} argument is an instance of the represented class (or
	* of any of its subclasses); it returns {@code false} otherwise. If
	* this {@code Class} object represents an array class, this method
	* returns {@code true} if the specified {@code Object} argument
	* can be converted to an object of the array class by an identity
	* conversion or by a widening reference conversion; it returns
	* {@code false} otherwise. If this {@code Class} object
	* represents an interface, this method returns {@code true} if the
	* class or any superclass of the specified {@code Object} argument
	* implements this interface; it returns {@code false} otherwise. If
	* this {@code Class} object represents a primitive type, this method
	* returns {@code false}.
	*
	* @param obj the object to check
	* @return true if {@code obj} is an instance of this class
	*
	* @since 1.1
	*/
	@HotSpotIntrinsicCandidate
	public native boolean isInstance(Object obj);


	/**
	* Determines if the class or interface represented by this
	* {@code Class} object is either the same as, or is a superclass or
	* superinterface of, the class or interface represented by the specified
	* {@code Class} parameter. It returns {@code true} if so;
	* otherwise it returns {@code false}. If this {@code Class}
	* object represents a primitive type, this method returns
	* {@code true} if the specified {@code Class} parameter is
	* exactly this {@code Class} object; otherwise it returns
	* {@code false}.
	*
	* <p> Specifically, this method tests whether the type represented by the
	* specified {@code Class} parameter can be converted to the type
	* represented by this {@code Class} object via an identity conversion
	* or via a widening reference conversion. See <em>The Java Language
	* Specification</em>, sections 5.1.1 and 5.1.4 , for details.
	*
	* @param cls the {@code Class} object to be checked
	* @return the {@code boolean} value indicating whether objects of the
	* type {@code cls} can be assigned to objects of this class
	* @exception NullPointerException if the specified Class parameter is
	* null.
	* @since 1.1
	*/
	@HotSpotIntrinsicCandidate
	public native boolean isAssignableFrom(Class<?> cls);


	/**
	* Determines if the specified {@code Class} object represents an
	* interface type.
	*
	* @return {@code true} if this object represents an interface;
	* {@code false} otherwise.
	*/
	@HotSpotIntrinsicCandidate
	public native boolean isInterface();


	/**
	* Determines if this {@code Class} object represents an array class.
	*
	* @return {@code true} if this object represents an array class;
	* {@code false} otherwise.
	* @since 1.1
	*/
	@HotSpotIntrinsicCandidate
	public native boolean isArray();


	/**
	* Determines if the specified {@code Class} object represents a
	* primitive type.
	*
	* <p> There are nine predefined {@code Class} objects to represent
	* the eight primitive types and void. These are created by the Java
	* Virtual Machine, and have the same names as the primitive types that
	* they represent, namely {@code boolean}, {@code byte},
	* {@code char}, {@code short}, {@code int},
	* {@code long}, {@code float}, and {@code double}.
	*
	* <p> These objects may only be accessed via the following public static
	* final variables, and are the only {@code Class} objects for which
	* this method returns {@code true}.
	*
	* @return true if and only if this class represents a primitive type
	*
	* @see java.lang.Boolean#TYPE
	* @see java.lang.Character#TYPE
	* @see java.lang.Byte#TYPE
	* @see java.lang.Short#TYPE
	* @see java.lang.Integer#TYPE
	* @see java.lang.Long#TYPE
	* @see java.lang.Float#TYPE
	* @see java.lang.Double#TYPE
	* @see java.lang.Void#TYPE
	* @since 1.1
	*/
	@HotSpotIntrinsicCandidate
	public native boolean isPrimitive();

	/**
	* Returns true if this {@code Class} object represents an annotation
	* type. Note that if this method returns true, {@link #isInterface()}
	* would also return true, as all annotation types are also interfaces.
	*
	* @return {@code true} if this class object represents an annotation
	* type; {@code false} otherwise
	* @since 1.5
	*/
	public boolean isAnnotation() {
	return (getModifiers() & ANNOTATION) != 0;
	}

	/**
	* Returns {@code true} if this class is a synthetic class;
	* returns {@code false} otherwise.
	* @return {@code true} if and only if this class is a synthetic class as
	* defined by the Java Language Specification.
	* @jls 13.1 The Form of a Binary
	* @since 1.5
	*/
	public boolean isSynthetic() {
	return (getModifiers() & SYNTHETIC) != 0;
	}

	/**
	* Returns the name of the entity (class, interface, array class,
	* primitive type, or void) represented by this {@code Class} object,
	* as a {@code String}.
	*
	* <p> If this class object represents a reference type that is not an
	* array type then the binary name of the class is returned, as specified
	* by
	* <cite>The Java™ Language Specification</cite>.
	*
	* <p> If this class object represents a primitive type or void, then the
	* name returned is a {@code String} equal to the Java language
	* keyword corresponding to the primitive type or void.
	*
	* <p> If this class object represents a class of arrays, then the internal
	* form of the name consists of the name of the element type preceded by
	* one or more '{@code [}' characters representing the depth of the array
	* nesting. The encoding of element type names is as follows:
	*
	* <blockquote><table class="striped">
	* <caption style="display:none">Element types and encodings</caption>
	* <thead>
	* <tr><th scope="col"> Element Type <th scope="col"> Encoding
	* </thead>
	* <tbody style="text-align:left">
	* <tr><th scope="row"> boolean <td style="text-align:center"> Z
	* <tr><th scope="row"> byte <td style="text-align:center"> B
	* <tr><th scope="row"> char <td style="text-align:center"> C
	* <tr><th scope="row"> class or interface
	* <td style="text-align:center"> L<i>classname</i>;
	* <tr><th scope="row"> double <td style="text-align:center"> D
	* <tr><th scope="row"> float <td style="text-align:center"> F
	* <tr><th scope="row"> int <td style="text-align:center"> I
	* <tr><th scope="row"> long <td style="text-align:center"> J
	* <tr><th scope="row"> short <td style="text-align:center"> S
	* </tbody>
	* </table></blockquote>
	*
	* <p> The class or interface name <i>classname</i> is the binary name of
	* the class specified above.
	*
	* <p> Examples:
	* <blockquote><pre>
	* String.class.getName()
	* returns "java.lang.String"
	* byte.class.getName()
	* returns "byte"
	* (new Object[3]).getClass().getName()
	* returns "[Ljava.lang.Object;"
	* (new int[3][4][5][6][7][8][9]).getClass().getName()
	* returns "[[[[[[[I"
	* </pre></blockquote>
	*
	* @return the name of the class or interface
	* represented by this object.
	*/
	public String getName() {
	String name = this.name;
	if (name == null)
	this.name = name = getName0();
	return name;
	}

	// cache the name to reduce the number of calls into the VM
	private transient String name;
	private native String getName0();

	/**
	* Returns the class loader for the class. Some implementations may use
	* null to represent the bootstrap class loader. This method will return
	* null in such implementations if this class was loaded by the bootstrap
	* class loader.
	*
	* <p>If this object
	* represents a primitive type or void, null is returned.
	*
	* @return the class loader that loaded the class or interface
	* represented by this object.
	* @throws SecurityException
	* if a security manager is present, and the caller's class loader
	* is not {@code null} and is not the same as or an ancestor of the
	* class loader for the class whose class loader is requested,
	* and the caller does not have the
	* {@link RuntimePermission}{@code ("getClassLoader")}
	* @see java.lang.ClassLoader
	* @see SecurityManager#checkPermission
	* @see java.lang.RuntimePermission
	*/
	@CallerSensitive
	@ForceInline // to ensure Reflection.getCallerClass optimization
	public ClassLoader getClassLoader() {
	ClassLoader cl = getClassLoader0();
	if (cl == null)
	return null;
	SecurityManager sm = System.getSecurityManager();
	if (sm != null) {
	ClassLoader.checkClassLoaderPermission(cl, Reflection.getCallerClass());
	}
	return cl;
	}

	// Package-private to allow ClassLoader access
	ClassLoader getClassLoader0() { return classLoader; }

	/**
	* Returns the module that this class or interface is a member of.
	*
	* If this class represents an array type then this method returns the
	* {@code Module} for the element type. If this class represents a
	* primitive type or void, then the {@code Module} object for the
	* {@code java.base} module is returned.
	*
	* If this class is in an unnamed module then the {@linkplain
	* ClassLoader#getUnnamedModule() unnamed} {@code Module} of the class
	* loader for this class is returned.
	*
	* @return the module that this class or interface is a member of
	*
	* @since 9
	* @spec JPMS
	*/
	public Module getModule() {
	return module;
	}

	// set by VM
	private transient Module module;

	// Initialized in JVM not by private constructor
	// This field is filtered from reflection access, i.e. getDeclaredField
	// will throw NoSuchFieldException
	private final ClassLoader classLoader;

	/**
	* Returns an array of {@code TypeVariable} objects that represent the
	* type variables declared by the generic declaration represented by this
	* {@code GenericDeclaration} object, in declaration order. Returns an
	* array of length 0 if the underlying generic declaration declares no type
	* variables.
	*
	* @return an array of {@code TypeVariable} objects that represent
	* the type variables declared by this generic declaration
	* @throws java.lang.reflect.GenericSignatureFormatError if the generic
	* signature of this generic declaration does not conform to
	* the format specified in
	* <cite>The Java™ Virtual Machine Specification</cite>
	* @since 1.5
	*/
	@SuppressWarnings("unchecked")
	public TypeVariable<Class<T>>[] getTypeParameters() {
	ClassRepository info = getGenericInfo();
	if (info != null)
	return (TypeVariable<Class<T>>[])info.getTypeParameters();
	else
	return (TypeVariable<Class<T>>[])new TypeVariable<?>[0];
	}


	/**
	* Returns the {@code Class} representing the direct superclass of the
	* entity (class, interface, primitive type or void) represented by
	* this {@code Class}. If this {@code Class} represents either the
	* {@code Object} class, an interface, a primitive type, or void, then
	* null is returned. If this object represents an array class then the
	* {@code Class} object representing the {@code Object} class is
	* returned.
	*
	* @return the direct superclass of the class represented by this object
	*/
	@HotSpotIntrinsicCandidate
	public native Class<? super T> getSuperclass();


	/**
	* Returns the {@code Type} representing the direct superclass of
	* the entity (class, interface, primitive type or void) represented by
	* this {@code Class}.
	*
	* <p>If the superclass is a parameterized type, the {@code Type}
	* object returned must accurately reflect the actual type
	* parameters used in the source code. The parameterized type
	* representing the superclass is created if it had not been
	* created before. See the declaration of {@link
	* java.lang.reflect.ParameterizedType ParameterizedType} for the
	* semantics of the creation process for parameterized types. If
	* this {@code Class} represents either the {@code Object}
	* class, an interface, a primitive type, or void, then null is
	* returned. If this object represents an array class then the
	* {@code Class} object representing the {@code Object} class is
	* returned.
	*
	* @throws java.lang.reflect.GenericSignatureFormatError if the generic
	* class signature does not conform to the format specified in
	* <cite>The Java™ Virtual Machine Specification</cite>
	* @throws TypeNotPresentException if the generic superclass
	* refers to a non-existent type declaration
	* @throws java.lang.reflect.MalformedParameterizedTypeException if the
	* generic superclass refers to a parameterized type that cannot be
	* instantiated for any reason
	* @return the direct superclass of the class represented by this object
	* @since 1.5
	*/
	public Type getGenericSuperclass() {
	ClassRepository info = getGenericInfo();
	if (info == null) {
	return getSuperclass();
	}

	// Historical irregularity:
	// Generic signature marks interfaces with superclass = Object
	// but this API returns null for interfaces
	if (isInterface()) {
	return null;
	}

	return info.getSuperclass();
	}

	/**
	* Gets the package of this class.
	*
	* <p>If this class represents an array type, a primitive type or void,
	* this method returns {@code null}.
	*
	* @return the package of this class.
	* @revised 9
	* @spec JPMS
	*/
	public Package getPackage() {
	if (isPrimitive() \|\| isArray()) {
	return null;
	}
	ClassLoader cl = getClassLoader0();
	return cl != null ? cl.definePackage(this)
	: BootLoader.definePackage(this);
	}

	/**
	* Returns the fully qualified package name.
	*
	* <p> If this class is a top level class, then this method returns the fully
	* qualified name of the package that the class is a member of, or the
	* empty string if the class is in an unnamed package.
	*
	* <p> If this class is a member class, then this method is equivalent to
	* invoking {@code getPackageName()} on the {@linkplain #getEnclosingClass
	* enclosing class}.
	*
	* <p> If this class is a {@linkplain #isLocalClass local class} or an {@linkplain
	* #isAnonymousClass() anonymous class}, then this method is equivalent to
	* invoking {@code getPackageName()} on the {@linkplain #getDeclaringClass
	* declaring class} of the {@linkplain #getEnclosingMethod enclosing method} or
	* {@linkplain #getEnclosingConstructor enclosing constructor}.
	*
	* <p> If this class represents an array type then this method returns the
	* package name of the element type. If this class represents a primitive
	* type or void then the package name "{@code java.lang}" is returned.
	*
	* @return the fully qualified package name
	*
	* @since 9
	* @spec JPMS
	* @jls 6.7 Fully Qualified Names
	*/
	public String getPackageName() {
	String pn = this.packageName;
	if (pn == null) {
	Class<?> c = this;
	while (c.isArray()) {
	c = c.getComponentType();
	}
	if (c.isPrimitive()) {
	pn = "java.lang";
	} else {
	String cn = c.getName();
	int dot = cn.lastIndexOf('.');
	pn = (dot != -1) ? cn.substring(0, dot).intern() : "";
	}
	this.packageName = pn;
	}
	return pn;
	}

	// cached package name
	private transient String packageName;

	/**
	* Returns the interfaces directly implemented by the class or interface
	* represented by this object.
	*
	* <p>If this object represents a class, the return value is an array
	* containing objects representing all interfaces directly implemented by
	* the class. The order of the interface objects in the array corresponds
	* to the order of the interface names in the {@code implements} clause of
	* the declaration of the class represented by this object. For example,
	* given the declaration:
	* <blockquote>
	* {@code class Shimmer implements FloorWax, DessertTopping { ... }}
	* </blockquote>
	* suppose the value of {@code s} is an instance of
	* {@code Shimmer}; the value of the expression:
	* <blockquote>
	* {@code s.getClass().getInterfaces()[0]}
	* </blockquote>
	* is the {@code Class} object that represents interface
	* {@code FloorWax}; and the value of:
	* <blockquote>
	* {@code s.getClass().getInterfaces()[1]}
	* </blockquote>
	* is the {@code Class} object that represents interface
	* {@code DessertTopping}.
	*
	* <p>If this object represents an interface, the array contains objects
	* representing all interfaces directly extended by the interface. The
	* order of the interface objects in the array corresponds to the order of
	* the interface names in the {@code extends} clause of the declaration of
	* the interface represented by this object.
	*
	* <p>If this object represents a class or interface that implements no
	* interfaces, the method returns an array of length 0.
	*
	* <p>If this object represents a primitive type or void, the method
	* returns an array of length 0.
	*
	* <p>If this {@code Class} object represents an array type, the
	* interfaces {@code Cloneable} and {@code java.io.Serializable} are
	* returned in that order.
	*
	* @return an array of interfaces directly implemented by this class
	*/
	public Class<?>[] getInterfaces() {
	// defensively copy before handing over to user code
	return getInterfaces(true);
	}

	private Class<?>[] getInterfaces(boolean cloneArray) {
	ReflectionData<T> rd = reflectionData();
	if (rd == null) {
	// no cloning required
	return getInterfaces0();
	} else {
	Class<?>[] interfaces = rd.interfaces;
	if (interfaces == null) {
	interfaces = getInterfaces0();
	rd.interfaces = interfaces;
	}
	// defensively copy if requested
	return cloneArray ? interfaces.clone() : interfaces;
	}
	}

	private native Class<?>[] getInterfaces0();

	/**
	* Returns the {@code Type}s representing the interfaces
	* directly implemented by the class or interface represented by
	* this object.
	*
	* <p>If a superinterface is a parameterized type, the
	* {@code Type} object returned for it must accurately reflect
	* the actual type parameters used in the source code. The
	* parameterized type representing each superinterface is created
	* if it had not been created before. See the declaration of
	* {@link java.lang.reflect.ParameterizedType ParameterizedType}
	* for the semantics of the creation process for parameterized
	* types.
	*
	* <p>If this object represents a class, the return value is an array
	* containing objects representing all interfaces directly implemented by
	* the class. The order of the interface objects in the array corresponds
	* to the order of the interface names in the {@code implements} clause of
	* the declaration of the class represented by this object.
	*
	* <p>If this object represents an interface, the array contains objects
	* representing all interfaces directly extended by the interface. The
	* order of the interface objects in the array corresponds to the order of
	* the interface names in the {@code extends} clause of the declaration of
	* the interface represented by this object.
	*
	* <p>If this object represents a class or interface that implements no
	* interfaces, the method returns an array of length 0.
	*
	* <p>If this object represents a primitive type or void, the method
	* returns an array of length 0.
	*
	* <p>If this {@code Class} object represents an array type, the
	* interfaces {@code Cloneable} and {@code java.io.Serializable} are
	* returned in that order.
	*
	* @throws java.lang.reflect.GenericSignatureFormatError
	* if the generic class signature does not conform to the format
	* specified in
	* <cite>The Java™ Virtual Machine Specification</cite>
	* @throws TypeNotPresentException if any of the generic
	* superinterfaces refers to a non-existent type declaration
	* @throws java.lang.reflect.MalformedParameterizedTypeException
	* if any of the generic superinterfaces refer to a parameterized
	* type that cannot be instantiated for any reason
	* @return an array of interfaces directly implemented by this class
	* @since 1.5
	*/
	public Type[] getGenericInterfaces() {
	ClassRepository info = getGenericInfo();
	return (info == null) ? getInterfaces() : info.getSuperInterfaces();
	}


	/**
	* Returns the {@code Class} representing the component type of an
	* array. If this class does not represent an array class this method
	* returns null.
	*
	* @return the {@code Class} representing the component type of this
	* class if this class is an array
	* @see java.lang.reflect.Array
	* @since 1.1
	*/
	public Class<?> getComponentType() {
	// Only return for array types. Storage may be reused for Class for instance types.
	if (isArray()) {
	return componentType;
	} else {
	return null;
	}
	}

	private final Class<?> componentType;


	/**
	* Returns the Java language modifiers for this class or interface, encoded
	* in an integer. The modifiers consist of the Java Virtual Machine's
	* constants for {@code public}, {@code protected},
	* {@code private}, {@code final}, {@code static},
	* {@code abstract} and {@code interface}; they should be decoded
	* using the methods of class {@code Modifier}.
	*
	* <p> If the underlying class is an array class, then its
	* {@code public}, {@code private} and {@code protected}
	* modifiers are the same as those of its component type. If this
	* {@code Class} represents a primitive type or void, its
	* {@code public} modifier is always {@code true}, and its
	* {@code protected} and {@code private} modifiers are always
	* {@code false}. If this object represents an array class, a
	* primitive type or void, then its {@code final} modifier is always
	* {@code true} and its interface modifier is always
	* {@code false}. The values of its other modifiers are not determined
	* by this specification.
	*
	* <p> The modifier encodings are defined in <em>The Java Virtual Machine
	* Specification</em>, table 4.1.
	*
	* @return the {@code int} representing the modifiers for this class
	* @see java.lang.reflect.Modifier
	* @since 1.1
	*/
	@HotSpotIntrinsicCandidate
	public native int getModifiers();


	/**
	* Gets the signers of this class.
	*
	* @return the signers of this class, or null if there are no signers. In
	* particular, this method returns null if this object represents
	* a primitive type or void.
	* @since 1.1
	*/
	public native Object[] getSigners();


	/**
	* Set the signers of this class.
	*/
	native void setSigners(Object[] signers);


	/**
	* If this {@code Class} object represents a local or anonymous
	* class within a method, returns a {@link
	* java.lang.reflect.Method Method} object representing the
	* immediately enclosing method of the underlying class. Returns
	* {@code null} otherwise.
	*
	* In particular, this method returns {@code null} if the underlying
	* class is a local or anonymous class immediately enclosed by a type
	* declaration, instance initializer or static initializer.
	*
	* @return the immediately enclosing method of the underlying class, if
	* that class is a local or anonymous class; otherwise {@code null}.
	*
	* @throws SecurityException
	* If a security manager, <i>s</i>, is present and any of the
	* following conditions is met:
	*
	* <ul>
	*
	* <li> the caller's class loader is not the same as the
	* class loader of the enclosing class and invocation of
	* {@link SecurityManager#checkPermission
	* s.checkPermission} method with
	* {@code RuntimePermission("accessDeclaredMembers")}
	* denies access to the methods within the enclosing class
	*
	* <li> the caller's class loader is not the same as or an
	* ancestor of the class loader for the enclosing class and
	* invocation of {@link SecurityManager#checkPackageAccess
	* s.checkPackageAccess()} denies access to the package
	* of the enclosing class
	*
	* </ul>
	* @since 1.5
	*/
	@CallerSensitive
	public Method getEnclosingMethod() throws SecurityException {
	EnclosingMethodInfo enclosingInfo = getEnclosingMethodInfo();

	if (enclosingInfo == null)
	return null;
	else {
	if (!enclosingInfo.isMethod())
	return null;

	MethodRepository typeInfo = MethodRepository.make(enclosingInfo.getDescriptor(),
	getFactory());
	Class<?> returnType = toClass(typeInfo.getReturnType());
	Type [] parameterTypes = typeInfo.getParameterTypes();
	Class<?>[] parameterClasses = new Class<?>[parameterTypes.length];

	// Convert Types to Classes; returned types should
	// be class objects since the methodDescriptor's used
	// don't have generics information
	for(int i = 0; i < parameterClasses.length; i++)
	parameterClasses[i] = toClass(parameterTypes[i]);

	// Perform access check
	final Class<?> enclosingCandidate = enclosingInfo.getEnclosingClass();
	SecurityManager sm = System.getSecurityManager();
	if (sm != null) {
	enclosingCandidate.checkMemberAccess(sm, Member.DECLARED,
	Reflection.getCallerClass(), true);
	}
	Method[] candidates = enclosingCandidate.privateGetDeclaredMethods(false);

	/*
	* Loop over all declared methods; match method name,
	* number of and type of parameters, and return
	* type. Matching return type is also necessary
	* because of covariant returns, etc.
	*/
	ReflectionFactory fact = getReflectionFactory();
	for (Method m : candidates) {
	if (m.getName().equals(enclosingInfo.getName()) &&
	arrayContentsEq(parameterClasses,
	fact.getExecutableSharedParameterTypes(m))) {
	// finally, check return type
	if (m.getReturnType().equals(returnType)) {
	return fact.copyMethod(m);
	}
	}
	}

	throw new InternalError("Enclosing method not found");
	}
	}

	private native Object[] getEnclosingMethod0();

	private EnclosingMethodInfo getEnclosingMethodInfo() {
	Object[] enclosingInfo = getEnclosingMethod0();
	if (enclosingInfo == null)
	return null;
	else {
	return new EnclosingMethodInfo(enclosingInfo);
	}
	}

	private static final class EnclosingMethodInfo {
	private final Class<?> enclosingClass;
	private final String name;
	private final String descriptor;

	static void validate(Object[] enclosingInfo) {
	if (enclosingInfo.length != 3)
	throw new InternalError("Malformed enclosing method information");
	try {
	// The array is expected to have three elements:

	// the immediately enclosing class
	Class<?> enclosingClass = (Class<?>)enclosingInfo[0];
	assert(enclosingClass != null);

	// the immediately enclosing method or constructor's
	// name (can be null).
	String name = (String)enclosingInfo[1];

	// the immediately enclosing method or constructor's
	// descriptor (null iff name is).
	String descriptor = (String)enclosingInfo[2];
	assert((name != null && descriptor != null) \|\| name == descriptor);
	} catch (ClassCastException cce) {
	throw new InternalError("Invalid type in enclosing method information", cce);
	}
	}

	EnclosingMethodInfo(Object[] enclosingInfo) {
	validate(enclosingInfo);
	this.enclosingClass = (Class<?>)enclosingInfo[0];
	this.name = (String)enclosingInfo[1];
	this.descriptor = (String)enclosingInfo[2];
	}

	boolean isPartial() {
	return enclosingClass == null \|\| name == null \|\| descriptor == null;
	}

	boolean isConstructor() { return !isPartial() && "<init>".equals(name); }

	boolean isMethod() { return !isPartial() && !isConstructor() && !"<clinit>".equals(name); }

	Class<?> getEnclosingClass() { return enclosingClass; }

	String getName() { return name; }

	String getDescriptor() { return descriptor; }

	}

	private static Class<?> toClass(Type o) {
	if (o instanceof GenericArrayType)
	return Array.newInstance(toClass(((GenericArrayType)o).getGenericComponentType()),
	0)
	.getClass();
	return (Class<?>)o;
	}

	/**
	* If this {@code Class} object represents a local or anonymous
	* class within a constructor, returns a {@link
	* java.lang.reflect.Constructor Constructor} object representing
	* the immediately enclosing constructor of the underlying
	* class. Returns {@code null} otherwise. In particular, this
	* method returns {@code null} if the underlying class is a local
	* or anonymous class immediately enclosed by a type declaration,
	* instance initializer or static initializer.
	*
	* @return the immediately enclosing constructor of the underlying class, if
	* that class is a local or anonymous class; otherwise {@code null}.
	* @throws SecurityException
	* If a security manager, <i>s</i>, is present and any of the
	* following conditions is met:
	*
	* <ul>
	*
	* <li> the caller's class loader is not the same as the
	* class loader of the enclosing class and invocation of
	* {@link SecurityManager#checkPermission
	* s.checkPermission} method with
	* {@code RuntimePermission("accessDeclaredMembers")}
	* denies access to the constructors within the enclosing class
	*
	* <li> the caller's class loader is not the same as or an
	* ancestor of the class loader for the enclosing class and
	* invocation of {@link SecurityManager#checkPackageAccess
	* s.checkPackageAccess()} denies access to the package
	* of the enclosing class
	*
	* </ul>
	* @since 1.5
	*/
	@CallerSensitive
	public Constructor<?> getEnclosingConstructor() throws SecurityException {
	EnclosingMethodInfo enclosingInfo = getEnclosingMethodInfo();

	if (enclosingInfo == null)
	return null;
	else {
	if (!enclosingInfo.isConstructor())
	return null;

	ConstructorRepository typeInfo = ConstructorRepository.make(enclosingInfo.getDescriptor(),
	getFactory());
	Type [] parameterTypes = typeInfo.getParameterTypes();
	Class<?>[] parameterClasses = new Class<?>[parameterTypes.length];

	// Convert Types to Classes; returned types should
	// be class objects since the methodDescriptor's used
	// don't have generics information
	for(int i = 0; i < parameterClasses.length; i++)
	parameterClasses[i] = toClass(parameterTypes[i]);

	// Perform access check
	final Class<?> enclosingCandidate = enclosingInfo.getEnclosingClass();
	SecurityManager sm = System.getSecurityManager();
	if (sm != null) {
	enclosingCandidate.checkMemberAccess(sm, Member.DECLARED,
	Reflection.getCallerClass(), true);
	}

	Constructor<?>[] candidates = enclosingCandidate
	.privateGetDeclaredConstructors(false);
	/*
	* Loop over all declared constructors; match number
	* of and type of parameters.
	*/
	ReflectionFactory fact = getReflectionFactory();
	for (Constructor<?> c : candidates) {
	if (arrayContentsEq(parameterClasses,
	fact.getExecutableSharedParameterTypes(c))) {
	return fact.copyConstructor(c);
	}
	}

	throw new InternalError("Enclosing constructor not found");
	}
	}


	/**
	* If the class or interface represented by this {@code Class} object
	* is a member of another class, returns the {@code Class} object
	* representing the class in which it was declared. This method returns
	* null if this class or interface is not a member of any other class. If
	* this {@code Class} object represents an array class, a primitive
	* type, or void,then this method returns null.
	*
	* @return the declaring class for this class
	* @throws SecurityException
	* If a security manager, <i>s</i>, is present and the caller's
	* class loader is not the same as or an ancestor of the class
	* loader for the declaring class and invocation of {@link
	* SecurityManager#checkPackageAccess s.checkPackageAccess()}
	* denies access to the package of the declaring class
	* @since 1.1
	*/
	@CallerSensitive
	public Class<?> getDeclaringClass() throws SecurityException {
	final Class<?> candidate = getDeclaringClass0();

	if (candidate != null) {
	SecurityManager sm = System.getSecurityManager();
	if (sm != null) {
	candidate.checkPackageAccess(sm,
	ClassLoader.getClassLoader(Reflection.getCallerClass()), true);
	}
	}
	return candidate;
	}

	private native Class<?> getDeclaringClass0();


	/**
	* Returns the immediately enclosing class of the underlying
	* class. If the underlying class is a top level class this
	* method returns {@code null}.
	* @return the immediately enclosing class of the underlying class
	* @exception SecurityException
	* If a security manager, <i>s</i>, is present and the caller's
	* class loader is not the same as or an ancestor of the class
	* loader for the enclosing class and invocation of {@link
	* SecurityManager#checkPackageAccess s.checkPackageAccess()}
	* denies access to the package of the enclosing class
	* @since 1.5
	*/
	@CallerSensitive
	public Class<?> getEnclosingClass() throws SecurityException {
	// There are five kinds of classes (or interfaces):
	// a) Top level classes
	// b) Nested classes (static member classes)
	// c) Inner classes (non-static member classes)
	// d) Local classes (named classes declared within a method)
	// e) Anonymous classes


	// JVM Spec 4.7.7: A class must have an EnclosingMethod
	// attribute if and only if it is a local class or an
	// anonymous class.
	EnclosingMethodInfo enclosingInfo = getEnclosingMethodInfo();
	Class<?> enclosingCandidate;

	if (enclosingInfo == null) {
	// This is a top level or a nested class or an inner class (a, b, or c)
	enclosingCandidate = getDeclaringClass0();
	} else {
	Class<?> enclosingClass = enclosingInfo.getEnclosingClass();
	// This is a local class or an anonymous class (d or e)
	if (enclosingClass == this \|\| enclosingClass == null)
	throw new InternalError("Malformed enclosing method information");
	else
	enclosingCandidate = enclosingClass;
	}

	if (enclosingCandidate != null) {
	SecurityManager sm = System.getSecurityManager();
	if (sm != null) {
	enclosingCandidate.checkPackageAccess(sm,
	ClassLoader.getClassLoader(Reflection.getCallerClass()), true);
	}
	}
	return enclosingCandidate;
	}

	/**
	* Returns the simple name of the underlying class as given in the
	* source code. Returns an empty string if the underlying class is
	* anonymous.
	*
	* <p>The simple name of an array is the simple name of the
	* component type with "[]" appended. In particular the simple
	* name of an array whose component type is anonymous is "[]".
	*
	* @return the simple name of the underlying class
	* @since 1.5
	*/
	public String getSimpleName() {
	ReflectionData<T> rd = reflectionData();
	String simpleName = rd.simpleName;
	if (simpleName == null) {
	rd.simpleName = simpleName = getSimpleName0();
	}
	return simpleName;
	}

	private String getSimpleName0() {
	if (isArray()) {
	return getComponentType().getSimpleName() + "[]";
	}
	String simpleName = getSimpleBinaryName();
	if (simpleName == null) { // top level class
	simpleName = getName();
	simpleName = simpleName.substring(simpleName.lastIndexOf('.') + 1); // strip the package name
	}
	return simpleName;
	}

	/**
	* Return an informative string for the name of this type.
	*
	* @return an informative string for the name of this type
	* @since 1.8
	*/
	public String getTypeName() {
	if (isArray()) {
	try {
	Class<?> cl = this;
	int dimensions = 0;
	do {
	dimensions++;
	cl = cl.getComponentType();
	} while (cl.isArray());
	StringBuilder sb = new StringBuilder();
	sb.append(cl.getName());
	for (int i = 0; i < dimensions; i++) {
	sb.append("[]");
	}
	return sb.toString();
	} catch (Throwable e) { /FALLTHRU/ }
	}
	return getName();
	}

	/**
	* Returns the canonical name of the underlying class as
	* defined by the Java Language Specification. Returns null if
	* the underlying class does not have a canonical name (i.e., if
	* it is a local or anonymous class or an array whose component
	* type does not have a canonical name).
	* @return the canonical name of the underlying class if it exists, and
	* {@code null} otherwise.
	* @since 1.5
	*/
	public String getCanonicalName() {
	ReflectionData<T> rd = reflectionData();
	String canonicalName = rd.canonicalName;
	if (canonicalName == null) {
	rd.canonicalName = canonicalName = getCanonicalName0();
	}
	return canonicalName == ReflectionData.NULL_SENTINEL? null : canonicalName;
	}

	private String getCanonicalName0() {
	if (isArray()) {
	String canonicalName = getComponentType().getCanonicalName();
	if (canonicalName != null)
	return canonicalName + "[]";
	else
	return ReflectionData.NULL_SENTINEL;
	}
	if (isLocalOrAnonymousClass())
	return ReflectionData.NULL_SENTINEL;
	Class<?> enclosingClass = getEnclosingClass();
	if (enclosingClass == null) { // top level class
	return getName();
	} else {
	String enclosingName = enclosingClass.getCanonicalName();
	if (enclosingName == null)
	return ReflectionData.NULL_SENTINEL;
	return enclosingName + "." + getSimpleName();
	}
	}

	/**
	* Returns {@code true} if and only if the underlying class
	* is an anonymous class.
	*
	* @return {@code true} if and only if this class is an anonymous class.
	* @since 1.5
	*/
	public boolean isAnonymousClass() {
	return !isArray() && isLocalOrAnonymousClass() &&
	getSimpleBinaryName0() == null;
	}

	/**
	* Returns {@code true} if and only if the underlying class
	* is a local class.
	*
	* @return {@code true} if and only if this class is a local class.
	* @since 1.5
	*/
	public boolean isLocalClass() {
	return isLocalOrAnonymousClass() &&
	(isArray() \|\| getSimpleBinaryName0() != null);
	}

	/**
	* Returns {@code true} if and only if the underlying class
	* is a member class.
	*
	* @return {@code true} if and only if this class is a member class.
	* @since 1.5
	*/
	public boolean isMemberClass() {
	return !isLocalOrAnonymousClass() && getDeclaringClass0() != null;
	}

	/**
	* Returns the "simple binary name" of the underlying class, i.e.,
	* the binary name without the leading enclosing class name.
	* Returns {@code null} if the underlying class is a top level
	* class.
	*/
	private String getSimpleBinaryName() {
	if (isTopLevelClass())
	return null;
	String name = getSimpleBinaryName0();
	if (name == null) // anonymous class
	return "";
	return name;
	}

	private native String getSimpleBinaryName0();

	/**
	* Returns {@code true} if this is a top level class. Returns {@code false}
	* otherwise.
	*/
	private boolean isTopLevelClass() {
	return !isLocalOrAnonymousClass() && getDeclaringClass0() == null;
	}

	/**
	* Returns {@code true} if this is a local class or an anonymous
	* class. Returns {@code false} otherwise.
	*/
	private boolean isLocalOrAnonymousClass() {
	// JVM Spec 4.7.7: A class must have an EnclosingMethod
	// attribute if and only if it is a local class or an
	// anonymous class.
	return hasEnclosingMethodInfo();
	}

	private boolean hasEnclosingMethodInfo() {
	Object[] enclosingInfo = getEnclosingMethod0();
	if (enclosingInfo != null) {
	EnclosingMethodInfo.validate(enclosingInfo);
	return true;
	}
	return false;
	}

	/**
	* Returns an array containing {@code Class} objects representing all
	* the public classes and interfaces that are members of the class
	* represented by this {@code Class} object. This includes public
	* class and interface members inherited from superclasses and public class
	* and interface members declared by the class. This method returns an
	* array of length 0 if this {@code Class} object has no public member
	* classes or interfaces. This method also returns an array of length 0 if
	* this {@code Class} object represents a primitive type, an array
	* class, or void.
	*
	* @return the array of {@code Class} objects representing the public
	* members of this class
	* @throws SecurityException
	* If a security manager, <i>s</i>, is present and
	* the caller's class loader is not the same as or an
	* ancestor of the class loader for the current class and
	* invocation of {@link SecurityManager#checkPackageAccess
	* s.checkPackageAccess()} denies access to the package
	* of this class.
	*
	* @since 1.1
	*/
	@CallerSensitive
	public Class<?>[] getClasses() {
	SecurityManager sm = System.getSecurityManager();
	if (sm != null) {
	checkMemberAccess(sm, Member.PUBLIC, Reflection.getCallerClass(), false);
	}

	// Privileged so this implementation can look at DECLARED classes,
	// something the caller might not have privilege to do. The code here
	// is allowed to look at DECLARED classes because (1) it does not hand
	// out anything other than public members and (2) public member access
	// has already been ok'd by the SecurityManager.

	return java.security.AccessController.doPrivileged(
	new java.security.PrivilegedAction<>() {
	public Class<?>[] run() {
	List<Class<?>> list = new ArrayList<>();
	Class<?> currentClass = Class.this;
	while (currentClass != null) {
	for (Class<?> m : currentClass.getDeclaredClasses()) {
	if (Modifier.isPublic(m.getModifiers())) {
	list.add(m);
	}
	}
	currentClass = currentClass.getSuperclass();
	}
	return list.toArray(new Class<?>[0]);
	}
	});
	}


	/**
	* Returns an array containing {@code Field} objects reflecting all
	* the accessible public fields of the class or interface represented by
	* this {@code Class} object.
	*
	* <p> If this {@code Class} object represents a class or interface with
	* no accessible public fields, then this method returns an array of length
	* 0.
	*
	* <p> If this {@code Class} object represents a class, then this method
	* returns the public fields of the class and of all its superclasses and
	* superinterfaces.
	*
	* <p> If this {@code Class} object represents an interface, then this
	* method returns the fields of the interface and of all its
	* superinterfaces.
	*
	* <p> If this {@code Class} object represents an array type, a primitive
	* type, or void, then this method returns an array of length 0.
	*
	* <p> The elements in the returned array are not sorted and are not in any
	* particular order.
	*
	* @return the array of {@code Field} objects representing the
	* public fields
	* @throws SecurityException
	* If a security manager, <i>s</i>, is present and
	* the caller's class loader is not the same as or an
	* ancestor of the class loader for the current class and
	* invocation of {@link SecurityManager#checkPackageAccess
	* s.checkPackageAccess()} denies access to the package
	* of this class.
	*
	* @since 1.1
	* @jls 8.2 Class Members
	* @jls 8.3 Field Declarations
	*/
	@CallerSensitive
	public Field[] getFields() throws SecurityException {
	SecurityManager sm = System.getSecurityManager();
	if (sm != null) {
	checkMemberAccess(sm, Member.PUBLIC, Reflection.getCallerClass(), true);
	}
	return copyFields(privateGetPublicFields());
	}


	/**
	* Returns an array containing {@code Method} objects reflecting all the
	* public methods of the class or interface represented by this {@code
	* Class} object, including those declared by the class or interface and
	* those inherited from superclasses and superinterfaces.
	*
	* <p> If this {@code Class} object represents an array type, then the
	* returned array has a {@code Method} object for each of the public
	* methods inherited by the array type from {@code Object}. It does not
	* contain a {@code Method} object for {@code clone()}.
	*
	* <p> If this {@code Class} object represents an interface then the
	* returned array does not contain any implicitly declared methods from
	* {@code Object}. Therefore, if no methods are explicitly declared in
	* this interface or any of its superinterfaces then the returned array
	* has length 0. (Note that a {@code Class} object which represents a class
	* always has public methods, inherited from {@code Object}.)
	*
	* <p> The returned array never contains methods with names "{@code <init>}"
	* or "{@code <clinit>}".
	*
	* <p> The elements in the returned array are not sorted and are not in any
	* particular order.
	*
	* <p> Generally, the result is computed as with the following 4 step algorithm.
	* Let C be the class or interface represented by this {@code Class} object:
	* <ol>
	* <li> A union of methods is composed of:
	* <ol type="a">
	* <li> C's declared public instance and static methods as returned by
	* {@link #getDeclaredMethods()} and filtered to include only public
	* methods.</li>
	* <li> If C is a class other than {@code Object}, then include the result
	* of invoking this algorithm recursively on the superclass of C.</li>
	* <li> Include the results of invoking this algorithm recursively on all
	* direct superinterfaces of C, but include only instance methods.</li>
	* </ol></li>
	* <li> Union from step 1 is partitioned into subsets of methods with same
	* signature (name, parameter types) and return type.</li>
	* <li> Within each such subset only the most specific methods are selected.
	* Let method M be a method from a set of methods with same signature
	* and return type. M is most specific if there is no such method
	* N != M from the same set, such that N is more specific than M.
	* N is more specific than M if:
	* <ol type="a">
	* <li> N is declared by a class and M is declared by an interface; or</li>
	* <li> N and M are both declared by classes or both by interfaces and
	* N's declaring type is the same as or a subtype of M's declaring type
	* (clearly, if M's and N's declaring types are the same type, then
	* M and N are the same method).</li>
	* </ol></li>
	* <li> The result of this algorithm is the union of all selected methods from
	* step 3.</li>
	* </ol>
	*
	* @apiNote There may be more than one method with a particular name
	* and parameter types in a class because while the Java language forbids a
	* class to declare multiple methods with the same signature but different
	* return types, the Java virtual machine does not. This
	* increased flexibility in the virtual machine can be used to
	* implement various language features. For example, covariant
	* returns can be implemented with {@linkplain
	* java.lang.reflect.Method#isBridge bridge methods}; the bridge
	* method and the overriding method would have the same
	* signature but different return types.
	*
	* @return the array of {@code Method} objects representing the
	* public methods of this class
	* @throws SecurityException
	* If a security manager, <i>s</i>, is present and
	* the caller's class loader is not the same as or an
	* ancestor of the class loader for the current class and
	* invocation of {@link SecurityManager#checkPackageAccess
	* s.checkPackageAccess()} denies access to the package
	* of this class.
	*
	* @jls 8.2 Class Members
	* @jls 8.4 Method Declarations
	* @since 1.1
	*/
	@CallerSensitive
	public Method[] getMethods() throws SecurityException {
	SecurityManager sm = System.getSecurityManager();
	if (sm != null) {
	checkMemberAccess(sm, Member.PUBLIC, Reflection.getCallerClass(), true);
	}
	return copyMethods(privateGetPublicMethods());
	}


	/**
	* Returns an array containing {@code Constructor} objects reflecting
	* all the public constructors of the class represented by this
	* {@code Class} object. An array of length 0 is returned if the
	* class has no public constructors, or if the class is an array class, or
	* if the class reflects a primitive type or void.
	*
	* Note that while this method returns an array of {@code
	* Constructor<T>} objects (that is an array of constructors from
	* this class), the return type of this method is {@code
	* Constructor<?>[]} and <em>not</em> {@code Constructor<T>[]} as
	* might be expected. This less informative return type is
	* necessary since after being returned from this method, the
	* array could be modified to hold {@code Constructor} objects for
	* different classes, which would violate the type guarantees of
	* {@code Constructor<T>[]}.
	*
	* @return the array of {@code Constructor} objects representing the
	* public constructors of this class
	* @throws SecurityException
	* If a security manager, <i>s</i>, is present and
	* the caller's class loader is not the same as or an
	* ancestor of the class loader for the current class and
	* invocation of {@link SecurityManager#checkPackageAccess
	* s.checkPackageAccess()} denies access to the package
	* of this class.
	*
	* @since 1.1
	*/
	@CallerSensitive
	public Constructor<?>[] getConstructors() throws SecurityException {
	SecurityManager sm = System.getSecurityManager();
	if (sm != null) {
	checkMemberAccess(sm, Member.PUBLIC, Reflection.getCallerClass(), true);
	}
	return copyConstructors(privateGetDeclaredConstructors(true));
	}


	/**
	* Returns a {@code Field} object that reflects the specified public member
	* field of the class or interface represented by this {@code Class}
	* object. The {@code name} parameter is a {@code String} specifying the
	* simple name of the desired field.
	*
	* <p> The field to be reflected is determined by the algorithm that
	* follows. Let C be the class or interface represented by this object:
	*
	* <OL>
	* <LI> If C declares a public field with the name specified, that is the
	* field to be reflected.</LI>
	* <LI> If no field was found in step 1 above, this algorithm is applied
	* recursively to each direct superinterface of C. The direct
	* superinterfaces are searched in the order they were declared.</LI>
	* <LI> If no field was found in steps 1 and 2 above, and C has a
	* superclass S, then this algorithm is invoked recursively upon S.
	* If C has no superclass, then a {@code NoSuchFieldException}
	* is thrown.</LI>
	* </OL>
	*
	* <p> If this {@code Class} object represents an array type, then this
	* method does not find the {@code length} field of the array type.
	*
	* @param name the field name
	* @return the {@code Field} object of this class specified by
	* {@code name}
	* @throws NoSuchFieldException if a field with the specified name is
	* not found.
	* @throws NullPointerException if {@code name} is {@code null}
	* @throws SecurityException
	* If a security manager, <i>s</i>, is present and
	* the caller's class loader is not the same as or an
	* ancestor of the class loader for the current class and
	* invocation of {@link SecurityManager#checkPackageAccess
	* s.checkPackageAccess()} denies access to the package
	* of this class.
	*
	* @since 1.1
	* @jls 8.2 Class Members
	* @jls 8.3 Field Declarations
	*/
	@CallerSensitive
	public Field getField(String name)
	throws NoSuchFieldException, SecurityException {
	Objects.requireNonNull(name);
	SecurityManager sm = System.getSecurityManager();
	if (sm != null) {
	checkMemberAccess(sm, Member.PUBLIC, Reflection.getCallerClass(), true);
	}
	Field field = getField0(name);
	if (field == null) {
	throw new NoSuchFieldException(name);
	}
	return getReflectionFactory().copyField(field);
	}


	/**
	* Returns a {@code Method} object that reflects the specified public
	* member method of the class or interface represented by this
	* {@code Class} object. The {@code name} parameter is a
	* {@code String} specifying the simple name of the desired method. The
	* {@code parameterTypes} parameter is an array of {@code Class}
	* objects that identify the method's formal parameter types, in declared
	* order. If {@code parameterTypes} is {@code null}, it is
	* treated as if it were an empty array.
	*
	* <p> If this {@code Class} object represents an array type, then this
	* method finds any public method inherited by the array type from
	* {@code Object} except method {@code clone()}.
	*
	* <p> If this {@code Class} object represents an interface then this
	* method does not find any implicitly declared method from
	* {@code Object}. Therefore, if no methods are explicitly declared in
	* this interface or any of its superinterfaces, then this method does not
	* find any method.
	*
	* <p> This method does not find any method with name "{@code <init>}" or
	* "{@code <clinit>}".
	*
	* <p> Generally, the method to be reflected is determined by the 4 step
	* algorithm that follows.
	* Let C be the class or interface represented by this {@code Class} object:
	* <ol>
	* <li> A union of methods is composed of:
	* <ol type="a">
	* <li> C's declared public instance and static methods as returned by
	* {@link #getDeclaredMethods()} and filtered to include only public
	* methods that match given {@code name} and {@code parameterTypes}</li>
	* <li> If C is a class other than {@code Object}, then include the result
	* of invoking this algorithm recursively on the superclass of C.</li>
	* <li> Include the results of invoking this algorithm recursively on all
	* direct superinterfaces of C, but include only instance methods.</li>
	* </ol></li>
	* <li> This union is partitioned into subsets of methods with same
	* return type (the selection of methods from step 1 also guarantees that
	* they have the same method name and parameter types).</li>
	* <li> Within each such subset only the most specific methods are selected.
	* Let method M be a method from a set of methods with same VM
	* signature (return type, name, parameter types).
	* M is most specific if there is no such method N != M from the same
	* set, such that N is more specific than M. N is more specific than M
	* if:
	* <ol type="a">
	* <li> N is declared by a class and M is declared by an interface; or</li>
	* <li> N and M are both declared by classes or both by interfaces and
	* N's declaring type is the same as or a subtype of M's declaring type
	* (clearly, if M's and N's declaring types are the same type, then
	* M and N are the same method).</li>
	* </ol></li>
	* <li> The result of this algorithm is chosen arbitrarily from the methods
	* with most specific return type among all selected methods from step 3.
	* Let R be a return type of a method M from the set of all selected methods
	* from step 3. M is a method with most specific return type if there is
	* no such method N != M from the same set, having return type S != R,
	* such that S is a subtype of R as determined by
	* R.class.{@link #isAssignableFrom}(S.class).
	* </ol>
	*
	* @apiNote There may be more than one method with matching name and
	* parameter types in a class because while the Java language forbids a
	* class to declare multiple methods with the same signature but different
	* return types, the Java virtual machine does not. This
	* increased flexibility in the virtual machine can be used to
	* implement various language features. For example, covariant
	* returns can be implemented with {@linkplain
	* java.lang.reflect.Method#isBridge bridge methods}; the bridge
	* method and the overriding method would have the same
	* signature but different return types. This method would return the
	* overriding method as it would have a more specific return type.
	*
	* @param name the name of the method
	* @param parameterTypes the list of parameters
	* @return the {@code Method} object that matches the specified
	* {@code name} and {@code parameterTypes}
	* @throws NoSuchMethodException if a matching method is not found
	* or if the name is "<init>"or "<clinit>".
	* @throws NullPointerException if {@code name} is {@code null}
	* @throws SecurityException
	* If a security manager, <i>s</i>, is present and
	* the caller's class loader is not the same as or an
	* ancestor of the class loader for the current class and
	* invocation of {@link SecurityManager#checkPackageAccess
	* s.checkPackageAccess()} denies access to the package
	* of this class.
	*
	* @jls 8.2 Class Members
	* @jls 8.4 Method Declarations
	* @since 1.1
	*/
	@CallerSensitive
	public Method getMethod(String name, Class<?>... parameterTypes)
	throws NoSuchMethodException, SecurityException {
	Objects.requireNonNull(name);
	SecurityManager sm = System.getSecurityManager();
	if (sm != null) {
	checkMemberAccess(sm, Member.PUBLIC, Reflection.getCallerClass(), true);
	}
	Method method = getMethod0(name, parameterTypes);
	if (method == null) {
	throw new NoSuchMethodException(methodToString(name, parameterTypes));
	}
	return getReflectionFactory().copyMethod(method);
	}

	/**
	* Returns a {@code Constructor} object that reflects the specified
	* public constructor of the class represented by this {@code Class}
	* object. The {@code parameterTypes} parameter is an array of
	* {@code Class} objects that identify the constructor's formal
	* parameter types, in declared order.
	*
	* If this {@code Class} object represents an inner class
	* declared in a non-static context, the formal parameter types
	* include the explicit enclosing instance as the first parameter.
	*
	* <p> The constructor to reflect is the public constructor of the class
	* represented by this {@code Class} object whose formal parameter
	* types match those specified by {@code parameterTypes}.
	*
	* @param parameterTypes the parameter array
	* @return the {@code Constructor} object of the public constructor that
	* matches the specified {@code parameterTypes}
	* @throws NoSuchMethodException if a matching method is not found.
	* @throws SecurityException
	* If a security manager, <i>s</i>, is present and
	* the caller's class loader is not the same as or an
	* ancestor of the class loader for the current class and
	* invocation of {@link SecurityManager#checkPackageAccess
	* s.checkPackageAccess()} denies access to the package
	* of this class.
	*
	* @since 1.1
	*/
	@CallerSensitive
	public Constructor<T> getConstructor(Class<?>... parameterTypes)
	throws NoSuchMethodException, SecurityException
	{
	SecurityManager sm = System.getSecurityManager();
	if (sm != null) {
	checkMemberAccess(sm, Member.PUBLIC, Reflection.getCallerClass(), true);
	}
	return getReflectionFactory().copyConstructor(
	getConstructor0(parameterTypes, Member.PUBLIC));
	}


	/**
	* Returns an array of {@code Class} objects reflecting all the
	* classes and interfaces declared as members of the class represented by
	* this {@code Class} object. This includes public, protected, default
	* (package) access, and private classes and interfaces declared by the
	* class, but excludes inherited classes and interfaces. This method
	* returns an array of length 0 if the class declares no classes or
	* interfaces as members, or if this {@code Class} object represents a
	* primitive type, an array class, or void.
	*
	* @return the array of {@code Class} objects representing all the
	* declared members of this class
	* @throws SecurityException
	* If a security manager, <i>s</i>, is present and any of the
	* following conditions is met:
	*
	* <ul>
	*
	* <li> the caller's class loader is not the same as the
	* class loader of this class and invocation of
	* {@link SecurityManager#checkPermission
	* s.checkPermission} method with
	* {@code RuntimePermission("accessDeclaredMembers")}
	* denies access to the declared classes within this class
	*
	* <li> the caller's class loader is not the same as or an
	* ancestor of the class loader for the current class and
	* invocation of {@link SecurityManager#checkPackageAccess
	* s.checkPackageAccess()} denies access to the package
	* of this class
	*
	* </ul>
	*
	* @since 1.1
	*/
	@CallerSensitive
	public Class<?>[] getDeclaredClasses() throws SecurityException {
	SecurityManager sm = System.getSecurityManager();
	if (sm != null) {
	checkMemberAccess(sm, Member.DECLARED, Reflection.getCallerClass(), false);
	}
	return getDeclaredClasses0();
	}


	/**
	* Returns an array of {@code Field} objects reflecting all the fields
	* declared by the class or interface represented by this
	* {@code Class} object. This includes public, protected, default
	* (package) access, and private fields, but excludes inherited fields.
	*
	* <p> If this {@code Class} object represents a class or interface with no
	* declared fields, then this method returns an array of length 0.
	*
	* <p> If this {@code Class} object represents an array type, a primitive
	* type, or void, then this method returns an array of length 0.
	*
	* <p> The elements in the returned array are not sorted and are not in any
	* particular order.
	*
	* @return the array of {@code Field} objects representing all the
	* declared fields of this class
	* @throws SecurityException
	* If a security manager, <i>s</i>, is present and any of the
	* following conditions is met:
	*
	* <ul>
	*
	* <li> the caller's class loader is not the same as the
	* class loader of this class and invocation of
	* {@link SecurityManager#checkPermission
	* s.checkPermission} method with
	* {@code RuntimePermission("accessDeclaredMembers")}
	* denies access to the declared fields within this class
	*
	* <li> the caller's class loader is not the same as or an
	* ancestor of the class loader for the current class and
	* invocation of {@link SecurityManager#checkPackageAccess
	* s.checkPackageAccess()} denies access to the package
	* of this class
	*
	* </ul>
	*
	* @since 1.1
	* @jls 8.2 Class Members
	* @jls 8.3 Field Declarations
	*/
	@CallerSensitive
	public Field[] getDeclaredFields() throws SecurityException {
	SecurityManager sm = System.getSecurityManager();
	if (sm != null) {
	checkMemberAccess(sm, Member.DECLARED, Reflection.getCallerClass(), true);
	}
	return copyFields(privateGetDeclaredFields(false));
	}


	/**
	* Returns an array containing {@code Method} objects reflecting all the
	* declared methods of the class or interface represented by this {@code
	* Class} object, including public, protected, default (package)
	* access, and private methods, but excluding inherited methods.
	*
	* <p> If this {@code Class} object represents a type that has multiple
	* declared methods with the same name and parameter types, but different
	* return types, then the returned array has a {@code Method} object for
	* each such method.
	*
	* <p> If this {@code Class} object represents a type that has a class
	* initialization method {@code <clinit>}, then the returned array does
	* <em>not</em> have a corresponding {@code Method} object.
	*
	* <p> If this {@code Class} object represents a class or interface with no
	* declared methods, then the returned array has length 0.
	*
	* <p> If this {@code Class} object represents an array type, a primitive
	* type, or void, then the returned array has length 0.
	*
	* <p> The elements in the returned array are not sorted and are not in any
	* particular order.
	*
	* @return the array of {@code Method} objects representing all the
	* declared methods of this class
	* @throws SecurityException
	* If a security manager, <i>s</i>, is present and any of the
	* following conditions is met:
	*
	* <ul>
	*
	* <li> the caller's class loader is not the same as the
	* class loader of this class and invocation of
	* {@link SecurityManager#checkPermission
	* s.checkPermission} method with
	* {@code RuntimePermission("accessDeclaredMembers")}
	* denies access to the declared methods within this class
	*
	* <li> the caller's class loader is not the same as or an
	* ancestor of the class loader for the current class and
	* invocation of {@link SecurityManager#checkPackageAccess
	* s.checkPackageAccess()} denies access to the package
	* of this class
	*
	* </ul>
	*
	* @jls 8.2 Class Members
	* @jls 8.4 Method Declarations
	* @since 1.1
	*/
	@CallerSensitive
	public Method[] getDeclaredMethods() throws SecurityException {
	SecurityManager sm = System.getSecurityManager();
	if (sm != null) {
	checkMemberAccess(sm, Member.DECLARED, Reflection.getCallerClass(), true);
	}
	return copyMethods(privateGetDeclaredMethods(false));
	}


	/**
	* Returns an array of {@code Constructor} objects reflecting all the
	* constructors declared by the class represented by this
	* {@code Class} object. These are public, protected, default
	* (package) access, and private constructors. The elements in the array
	* returned are not sorted and are not in any particular order. If the
	* class has a default constructor, it is included in the returned array.
	* This method returns an array of length 0 if this {@code Class}
	* object represents an interface, a primitive type, an array class, or
	* void.
	*
	* <p> See <em>The Java Language Specification</em>, section 8.2.
	*
	* @return the array of {@code Constructor} objects representing all the
	* declared constructors of this class
	* @throws SecurityException
	* If a security manager, <i>s</i>, is present and any of the
	* following conditions is met:
	*
	* <ul>
	*
	* <li> the caller's class loader is not the same as the
	* class loader of this class and invocation of
	* {@link SecurityManager#checkPermission
	* s.checkPermission} method with
	* {@code RuntimePermission("accessDeclaredMembers")}
	* denies access to the declared constructors within this class
	*
	* <li> the caller's class loader is not the same as or an
	* ancestor of the class loader for the current class and
	* invocation of {@link SecurityManager#checkPackageAccess
	* s.checkPackageAccess()} denies access to the package
	* of this class
	*
	* </ul>
	*
	* @since 1.1
	*/
	@CallerSensitive
	public Constructor<?>[] getDeclaredConstructors() throws SecurityException {
	SecurityManager sm = System.getSecurityManager();
	if (sm != null) {
	checkMemberAccess(sm, Member.DECLARED, Reflection.getCallerClass(), true);
	}
	return copyConstructors(privateGetDeclaredConstructors(false));
	}


	/**
	* Returns a {@code Field} object that reflects the specified declared
	* field of the class or interface represented by this {@code Class}
	* object. The {@code name} parameter is a {@code String} that specifies
	* the simple name of the desired field.
	*
	* <p> If this {@code Class} object represents an array type, then this
	* method does not find the {@code length} field of the array type.
	*
	* @param name the name of the field
	* @return the {@code Field} object for the specified field in this
	* class
	* @throws NoSuchFieldException if a field with the specified name is
	* not found.
	* @throws NullPointerException if {@code name} is {@code null}
	* @throws SecurityException
	* If a security manager, <i>s</i>, is present and any of the
	* following conditions is met:
	*
	* <ul>
	*
	* <li> the caller's class loader is not the same as the
	* class loader of this class and invocation of
	* {@link SecurityManager#checkPermission
	* s.checkPermission} method with
	* {@code RuntimePermission("accessDeclaredMembers")}
	* denies access to the declared field
	*
	* <li> the caller's class loader is not the same as or an
	* ancestor of the class loader for the current class and
	* invocation of {@link SecurityManager#checkPackageAccess
	* s.checkPackageAccess()} denies access to the package
	* of this class
	*
	* </ul>
	*
	* @since 1.1
	* @jls 8.2 Class Members
	* @jls 8.3 Field Declarations
	*/
	@CallerSensitive
	public Field getDeclaredField(String name)
	throws NoSuchFieldException, SecurityException {
	Objects.requireNonNull(name);
	SecurityManager sm = System.getSecurityManager();
	if (sm != null) {
	checkMemberAccess(sm, Member.DECLARED, Reflection.getCallerClass(), true);
	}
	Field field = searchFields(privateGetDeclaredFields(false), name);
	if (field == null) {
	throw new NoSuchFieldException(name);
	}
	return getReflectionFactory().copyField(field);
	}


	/**
	* Returns a {@code Method} object that reflects the specified
	* declared method of the class or interface represented by this
	* {@code Class} object. The {@code name} parameter is a
	* {@code String} that specifies the simple name of the desired
	* method, and the {@code parameterTypes} parameter is an array of
	* {@code Class} objects that identify the method's formal parameter
	* types, in declared order. If more than one method with the same
	* parameter types is declared in a class, and one of these methods has a
	* return type that is more specific than any of the others, that method is
	* returned; otherwise one of the methods is chosen arbitrarily. If the
	* name is "<init>"or "<clinit>" a {@code NoSuchMethodException}
	* is raised.
	*
	* <p> If this {@code Class} object represents an array type, then this
	* method does not find the {@code clone()} method.
	*
	* @param name the name of the method
	* @param parameterTypes the parameter array
	* @return the {@code Method} object for the method of this class
	* matching the specified name and parameters
	* @throws NoSuchMethodException if a matching method is not found.
	* @throws NullPointerException if {@code name} is {@code null}
	* @throws SecurityException
	* If a security manager, <i>s</i>, is present and any of the
	* following conditions is met:
	*
	* <ul>
	*
	* <li> the caller's class loader is not the same as the
	* class loader of this class and invocation of
	* {@link SecurityManager#checkPermission
	* s.checkPermission} method with
	* {@code RuntimePermission("accessDeclaredMembers")}
	* denies access to the declared method
	*
	* <li> the caller's class loader is not the same as or an
	* ancestor of the class loader for the current class and
	* invocation of {@link SecurityManager#checkPackageAccess
	* s.checkPackageAccess()} denies access to the package
	* of this class
	*
	* </ul>
	*
	* @jls 8.2 Class Members
	* @jls 8.4 Method Declarations
	* @since 1.1
	*/
	@CallerSensitive
	public Method getDeclaredMethod(String name, Class<?>... parameterTypes)
	throws NoSuchMethodException, SecurityException {
	Objects.requireNonNull(name);
	SecurityManager sm = System.getSecurityManager();
	if (sm != null) {
	checkMemberAccess(sm, Member.DECLARED, Reflection.getCallerClass(), true);
	}
	Method method = searchMethods(privateGetDeclaredMethods(false), name, parameterTypes);
	if (method == null) {
	throw new NoSuchMethodException(methodToString(name, parameterTypes));
	}
	return getReflectionFactory().copyMethod(method);
	}

	/**
	* Returns the list of {@code Method} objects for the declared public
	* methods of this class or interface that have the specified method name
	* and parameter types.
	*
	* @param name the name of the method
	* @param parameterTypes the parameter array
	* @return the list of {@code Method} objects for the public methods of
	* this class matching the specified name and parameters
	*/
	List<Method> getDeclaredPublicMethods(String name, Class<?>... parameterTypes) {
	Method[] methods = privateGetDeclaredMethods(/* publicOnly */ true);
	ReflectionFactory factory = getReflectionFactory();
	List<Method> result = new ArrayList<>();
	for (Method method : methods) {
	if (method.getName().equals(name)
	&& Arrays.equals(
	factory.getExecutableSharedParameterTypes(method),
	parameterTypes)) {
	result.add(factory.copyMethod(method));
	}
	}
	return result;
	}

	/**
	* Returns a {@code Constructor} object that reflects the specified
	* constructor of the class or interface represented by this
	* {@code Class} object. The {@code parameterTypes} parameter is
	* an array of {@code Class} objects that identify the constructor's
	* formal parameter types, in declared order.
	*
	* If this {@code Class} object represents an inner class
	* declared in a non-static context, the formal parameter types
	* include the explicit enclosing instance as the first parameter.
	*
	* @param parameterTypes the parameter array
	* @return The {@code Constructor} object for the constructor with the
	* specified parameter list
	* @throws NoSuchMethodException if a matching method is not found.
	* @throws SecurityException
	* If a security manager, <i>s</i>, is present and any of the
	* following conditions is met:
	*
	* <ul>
	*
	* <li> the caller's class loader is not the same as the
	* class loader of this class and invocation of
	* {@link SecurityManager#checkPermission
	* s.checkPermission} method with
	* {@code RuntimePermission("accessDeclaredMembers")}
	* denies access to the declared constructor
	*
	* <li> the caller's class loader is not the same as or an
	* ancestor of the class loader for the current class and
	* invocation of {@link SecurityManager#checkPackageAccess
	* s.checkPackageAccess()} denies access to the package
	* of this class
	*
	* </ul>
	*
	* @since 1.1
	*/
	@CallerSensitive
	public Constructor<T> getDeclaredConstructor(Class<?>... parameterTypes)
	throws NoSuchMethodException, SecurityException
	{
	SecurityManager sm = System.getSecurityManager();
	if (sm != null) {
	checkMemberAccess(sm, Member.DECLARED, Reflection.getCallerClass(), true);
	}

	return getReflectionFactory().copyConstructor(
	getConstructor0(parameterTypes, Member.DECLARED));
	}

	/**
	* Finds a resource with a given name.
	*
	* <p> If this class is in a named {@link Module Module} then this method
	* will attempt to find the resource in the module. This is done by
	* delegating to the module's class loader {@link
	* ClassLoader#findResource(String,String) findResource(String,String)}
	* method, invoking it with the module name and the absolute name of the
	* resource. Resources in named modules are subject to the rules for
	* encapsulation specified in the {@code Module} {@link
	* Module#getResourceAsStream getResourceAsStream} method and so this
	* method returns {@code null} when the resource is a
	* non-"{@code .class}" resource in a package that is not open to the
	* caller's module.
	*
	* <p> Otherwise, if this class is not in a named module then the rules for
	* searching resources associated with a given class are implemented by the
	* defining {@linkplain ClassLoader class loader} of the class. This method
	* delegates to this object's class loader. If this object was loaded by
	* the bootstrap class loader, the method delegates to {@link
	* ClassLoader#getSystemResourceAsStream}.
	*
	* <p> Before delegation, an absolute resource name is constructed from the
	* given resource name using this algorithm:
	*
	* <ul>
	*
	* <li> If the {@code name} begins with a {@code '/'}
	* (<code>'\u002f'</code>), then the absolute name of the resource is the
	* portion of the {@code name} following the {@code '/'}.
	*
	* <li> Otherwise, the absolute name is of the following form:
	*
	* <blockquote>
	* {@code modified_package_name/name}
	* </blockquote>
	*
	* <p> Where the {@code modified_package_name} is the package name of this
	* object with {@code '/'} substituted for {@code '.'}
	* (<code>'\u002e'</code>).
	*
	* </ul>
	*
	* @param name name of the desired resource
	* @return A {@link java.io.InputStream} object; {@code null} if no
	* resource with this name is found, the resource is in a package
	* that is not {@linkplain Module#isOpen(String, Module) open} to at
	* least the caller module, or access to the resource is denied
	* by the security manager.
	* @throws NullPointerException If {@code name} is {@code null}
	*
	* @see Module#getResourceAsStream(String)
	* @since 1.1
	* @revised 9
	* @spec JPMS
	*/
	@CallerSensitive
	public InputStream getResourceAsStream(String name) {
	name = resolveName(name);

	Module thisModule = getModule();
	if (thisModule.isNamed()) {
	// check if resource can be located by caller
	if (Resources.canEncapsulate(name)
	&& !isOpenToCaller(name, Reflection.getCallerClass())) {
	return null;
	}

	// resource not encapsulated or in package open to caller
	String mn = thisModule.getName();
	ClassLoader cl = getClassLoader0();
	try {

	// special-case built-in class loaders to avoid the
	// need for a URL connection
	if (cl == null) {
	return BootLoader.findResourceAsStream(mn, name);
	} else if (cl instanceof BuiltinClassLoader) {
	return ((BuiltinClassLoader) cl).findResourceAsStream(mn, name);
	} else {
	URL url = cl.findResource(mn, name);
	return (url != null) ? url.openStream() : null;
	}

	} catch (IOException \| SecurityException e) {
	return null;
	}
	}

	// unnamed module
	ClassLoader cl = getClassLoader0();
	if (cl == null) {
	return ClassLoader.getSystemResourceAsStream(name);
	} else {
	return cl.getResourceAsStream(name);
	}
	}

	/**
	* Finds a resource with a given name.
	*
	* <p> If this class is in a named {@link Module Module} then this method
	* will attempt to find the resource in the module. This is done by
	* delegating to the module's class loader {@link
	* ClassLoader#findResource(String,String) findResource(String,String)}
	* method, invoking it with the module name and the absolute name of the
	* resource. Resources in named modules are subject to the rules for
	* encapsulation specified in the {@code Module} {@link
	* Module#getResourceAsStream getResourceAsStream} method and so this
	* method returns {@code null} when the resource is a
	* non-"{@code .class}" resource in a package that is not open to the
	* caller's module.
	*
	* <p> Otherwise, if this class is not in a named module then the rules for
	* searching resources associated with a given class are implemented by the
	* defining {@linkplain ClassLoader class loader} of the class. This method
	* delegates to this object's class loader. If this object was loaded by
	* the bootstrap class loader, the method delegates to {@link
	* ClassLoader#getSystemResource}.
	*
	* <p> Before delegation, an absolute resource name is constructed from the
	* given resource name using this algorithm:
	*
	* <ul>
	*
	* <li> If the {@code name} begins with a {@code '/'}
	* (<code>'\u002f'</code>), then the absolute name of the resource is the
	* portion of the {@code name} following the {@code '/'}.
	*
	* <li> Otherwise, the absolute name is of the following form:
	*
	* <blockquote>
	* {@code modified_package_name/name}
	* </blockquote>
	*
	* <p> Where the {@code modified_package_name} is the package name of this
	* object with {@code '/'} substituted for {@code '.'}
	* (<code>'\u002e'</code>).
	*
	* </ul>
	*
	* @param name name of the desired resource
	* @return A {@link java.net.URL} object; {@code null} if no resource with
	* this name is found, the resource cannot be located by a URL, the
	* resource is in a package that is not
	* {@linkplain Module#isOpen(String, Module) open} to at least the caller
	* module, or access to the resource is denied by the security
	* manager.
	* @throws NullPointerException If {@code name} is {@code null}
	* @since 1.1
	* @revised 9
	* @spec JPMS
	*/
	@CallerSensitive
	public URL getResource(String name) {
	name = resolveName(name);

	Module thisModule = getModule();
	if (thisModule.isNamed()) {
	// check if resource can be located by caller
	if (Resources.canEncapsulate(name)
	&& !isOpenToCaller(name, Reflection.getCallerClass())) {
	return null;
	}

	// resource not encapsulated or in package open to caller
	String mn = thisModule.getName();
	ClassLoader cl = getClassLoader0();
	try {
	if (cl == null) {
	return BootLoader.findResource(mn, name);
	} else {
	return cl.findResource(mn, name);
	}
	} catch (IOException ioe) {
	return null;
	}
	}

	// unnamed module
	ClassLoader cl = getClassLoader0();
	if (cl == null) {
	return ClassLoader.getSystemResource(name);
	} else {
	return cl.getResource(name);
	}
	}

	/**
	* Returns true if a resource with the given name can be located by the
	* given caller. All resources in a module can be located by code in
	* the module. For other callers, then the package needs to be open to
	* the caller.
	*/
	private boolean isOpenToCaller(String name, Class<?> caller) {
	// assert getModule().isNamed();
	Module thisModule = getModule();
	Module callerModule = (caller != null) ? caller.getModule() : null;
	if (callerModule != thisModule) {
	String pn = Resources.toPackageName(name);
	if (thisModule.getDescriptor().packages().contains(pn)) {
	if (callerModule == null && !thisModule.isOpen(pn)) {
	// no caller, package not open
	return false;
	}
	if (!thisModule.isOpen(pn, callerModule)) {
	// package not open to caller
	return false;
	}
	}
	}
	return true;
	}


	/** protection domain returned when the internal domain is null */
	private static java.security.ProtectionDomain allPermDomain;

	/**
	* Returns the {@code ProtectionDomain} of this class. If there is a
	* security manager installed, this method first calls the security
	* manager's {@code checkPermission} method with a
	* {@code RuntimePermission("getProtectionDomain")} permission to
	* ensure it's ok to get the
	* {@code ProtectionDomain}.
	*
	* @return the ProtectionDomain of this class
	*
	* @throws SecurityException
	* if a security manager exists and its
	* {@code checkPermission} method doesn't allow
	* getting the ProtectionDomain.
	*
	* @see java.security.ProtectionDomain
	* @see SecurityManager#checkPermission
	* @see java.lang.RuntimePermission
	* @since 1.2
	*/
	public java.security.ProtectionDomain getProtectionDomain() {
	SecurityManager sm = System.getSecurityManager();
	if (sm != null) {
	sm.checkPermission(SecurityConstants.GET_PD_PERMISSION);
	}
	java.security.ProtectionDomain pd = getProtectionDomain0();
	if (pd == null) {
	if (allPermDomain == null) {
	java.security.Permissions perms =
	new java.security.Permissions();
	perms.add(SecurityConstants.ALL_PERMISSION);
	allPermDomain =
	new java.security.ProtectionDomain(null, perms);
	}
	pd = allPermDomain;
	}
	return pd;
	}


	/**
	* Returns the ProtectionDomain of this class.
	*/
	private native java.security.ProtectionDomain getProtectionDomain0();

	/*
	* Return the Virtual Machine's Class object for the named
	* primitive type.
	*/
	static native Class<?> getPrimitiveClass(String name);

	/*
	* Check if client is allowed to access members. If access is denied,
	* throw a SecurityException.
	*
	* This method also enforces package access.
	*
	* <p> Default policy: allow all clients access with normal Java access
	* control.
	*
	* <p> NOTE: should only be called if a SecurityManager is installed
	*/
	private void checkMemberAccess(SecurityManager sm, int which,
	Class<?> caller, boolean checkProxyInterfaces) {
	/* Default policy allows access to all {@link Member#PUBLIC} members,
	* as well as access to classes that have the same class loader as the caller.
	* In all other cases, it requires RuntimePermission("accessDeclaredMembers")
	* permission.
	*/
	final ClassLoader ccl = ClassLoader.getClassLoader(caller);
	if (which != Member.PUBLIC) {
	final ClassLoader cl = getClassLoader0();
	if (ccl != cl) {
	sm.checkPermission(SecurityConstants.CHECK_MEMBER_ACCESS_PERMISSION);
	}
	}
	this.checkPackageAccess(sm, ccl, checkProxyInterfaces);
	}

	/*
	* Checks if a client loaded in ClassLoader ccl is allowed to access this
	* class under the current package access policy. If access is denied,
	* throw a SecurityException.
	*
	* NOTE: this method should only be called if a SecurityManager is active
	*/
	private void checkPackageAccess(SecurityManager sm, final ClassLoader ccl,
	boolean checkProxyInterfaces) {
	final ClassLoader cl = getClassLoader0();

	if (ReflectUtil.needsPackageAccessCheck(ccl, cl)) {
	String pkg = this.getPackageName();
	if (pkg != null && !pkg.isEmpty()) {
	// skip the package access check on a proxy class in default proxy package
	if (!Proxy.isProxyClass(this) \|\| ReflectUtil.isNonPublicProxyClass(this)) {
	sm.checkPackageAccess(pkg);
	}
	}
	}
	// check package access on the proxy interfaces
	if (checkProxyInterfaces && Proxy.isProxyClass(this)) {
	ReflectUtil.checkProxyPackageAccess(ccl, this.getInterfaces());
	}
	}

	/**
	* Add a package name prefix if the name is not absolute Remove leading "/"
	* if name is absolute
	*/
	private String resolveName(String name) {
	if (!name.startsWith("/")) {
	Class<?> c = this;
	while (c.isArray()) {
	c = c.getComponentType();
	}
	String baseName = c.getPackageName();
	if (baseName != null && !baseName.isEmpty()) {
	name = baseName.replace('.', '/') + "/" + name;
	}
	} else {
	name = name.substring(1);
	}
	return name;
	}

	/**
	* Atomic operations support.
	*/
	private static class Atomic {
	// initialize Unsafe machinery here, since we need to call Class.class instance method
	// and have to avoid calling it in the static initializer of the Class class...
	private static final Unsafe unsafe = Unsafe.getUnsafe();
	// offset of Class.reflectionData instance field
	private static final long reflectionDataOffset
	= unsafe.objectFieldOffset(Class.class, "reflectionData");
	// offset of Class.annotationType instance field
	private static final long annotationTypeOffset
	= unsafe.objectFieldOffset(Class.class, "annotationType");
	// offset of Class.annotationData instance field
	private static final long annotationDataOffset
	= unsafe.objectFieldOffset(Class.class, "annotationData");

	static <T> boolean casReflectionData(Class<?> clazz,
	SoftReference<ReflectionData<T>> oldData,
	SoftReference<ReflectionData<T>> newData) {
	return unsafe.compareAndSetObject(clazz, reflectionDataOffset, oldData, newData);
	}

	static <T> boolean casAnnotationType(Class<?> clazz,
	AnnotationType oldType,
	AnnotationType newType) {
	return unsafe.compareAndSetObject(clazz, annotationTypeOffset, oldType, newType);
	}

	static <T> boolean casAnnotationData(Class<?> clazz,
	AnnotationData oldData,
	AnnotationData newData) {
	return unsafe.compareAndSetObject(clazz, annotationDataOffset, oldData, newData);
	}
	}

	/**
	* Reflection support.
	*/

	// Reflection data caches various derived names and reflective members. Cached
	// values may be invalidated when JVM TI RedefineClasses() is called
	private static class ReflectionData<T> {
	volatile Field[] declaredFields;
	volatile Field[] publicFields;
	volatile Method[] declaredMethods;
	volatile Method[] publicMethods;
	volatile Constructor<T>[] declaredConstructors;
	volatile Constructor<T>[] publicConstructors;
	// Intermediate results for getFields and getMethods
	volatile Field[] declaredPublicFields;
	volatile Method[] declaredPublicMethods;
	volatile Class<?>[] interfaces;

	// Cached names
	String simpleName;
	String canonicalName;
	static final String NULL_SENTINEL = new String();

	// Value of classRedefinedCount when we created this ReflectionData instance
	final int redefinedCount;

	ReflectionData(int redefinedCount) {
	this.redefinedCount = redefinedCount;
	}
	}

	private transient volatile SoftReference<ReflectionData<T>> reflectionData;

	// Incremented by the VM on each call to JVM TI RedefineClasses()
	// that redefines this class or a superclass.
	private transient volatile int classRedefinedCount;

	// Lazily create and cache ReflectionData
	private ReflectionData<T> reflectionData() {
	SoftReference<ReflectionData<T>> reflectionData = this.reflectionData;
	int classRedefinedCount = this.classRedefinedCount;
	ReflectionData<T> rd;
	if (reflectionData != null &&
	(rd = reflectionData.get()) != null &&
	rd.redefinedCount == classRedefinedCount) {
	return rd;
	}
	// else no SoftReference or cleared SoftReference or stale ReflectionData
	// -> create and replace new instance
	return newReflectionData(reflectionData, classRedefinedCount);
	}

	private ReflectionData<T> newReflectionData(SoftReference<ReflectionData<T>> oldReflectionData,
	int classRedefinedCount) {
	while (true) {
	ReflectionData<T> rd = new ReflectionData<>(classRedefinedCount);
	// try to CAS it...
	if (Atomic.casReflectionData(this, oldReflectionData, new SoftReference<>(rd))) {
	return rd;
	}
	// else retry
	oldReflectionData = this.reflectionData;
	classRedefinedCount = this.classRedefinedCount;
	if (oldReflectionData != null &&
	(rd = oldReflectionData.get()) != null &&
	rd.redefinedCount == classRedefinedCount) {
	return rd;
	}
	}
	}

	// Generic signature handling
	private native String getGenericSignature0();

	// Generic info repository; lazily initialized
	private transient volatile ClassRepository genericInfo;

	// accessor for factory
	private GenericsFactory getFactory() {
	// create scope and factory
	return CoreReflectionFactory.make(this, ClassScope.make(this));
	}

	// accessor for generic info repository;
	// generic info is lazily initialized
	private ClassRepository getGenericInfo() {
	ClassRepository genericInfo = this.genericInfo;
	if (genericInfo == null) {
	String signature = getGenericSignature0();
	if (signature == null) {
	genericInfo = ClassRepository.NONE;
	} else {
	genericInfo = ClassRepository.make(signature, getFactory());
	}
	this.genericInfo = genericInfo;
	}
	return (genericInfo != ClassRepository.NONE) ? genericInfo : null;
	}

	// Annotations handling
	native byte[] getRawAnnotations();
	// Since 1.8
	native byte[] getRawTypeAnnotations();
	static byte[] getExecutableTypeAnnotationBytes(Executable ex) {
	return getReflectionFactory().getExecutableTypeAnnotationBytes(ex);
	}

	native ConstantPool getConstantPool();

	//
	//
	// java.lang.reflect.Field handling
	//
	//

	// Returns an array of "root" fields. These Field objects must NOT
	// be propagated to the outside world, but must instead be copied
	// via ReflectionFactory.copyField.
	private Field[] privateGetDeclaredFields(boolean publicOnly) {
	Field[] res;
	ReflectionData<T> rd = reflectionData();
	if (rd != null) {
	res = publicOnly ? rd.declaredPublicFields : rd.declaredFields;
	if (res != null) return res;
	}
	// No cached value available; request value from VM
	res = Reflection.filterFields(this, getDeclaredFields0(publicOnly));
	if (rd != null) {
	if (publicOnly) {
	rd.declaredPublicFields = res;
	} else {
	rd.declaredFields = res;
	}
	}
	return res;
	}

	// Returns an array of "root" fields. These Field objects must NOT
	// be propagated to the outside world, but must instead be copied
	// via ReflectionFactory.copyField.
	private Field[] privateGetPublicFields() {
	Field[] res;
	ReflectionData<T> rd = reflectionData();
	if (rd != null) {
	res = rd.publicFields;
	if (res != null) return res;
	}

	// Use a linked hash set to ensure order is preserved and
	// fields from common super interfaces are not duplicated
	LinkedHashSet<Field> fields = new LinkedHashSet<>();

	// Local fields
	addAll(fields, privateGetDeclaredFields(true));

	// Direct superinterfaces, recursively
	for (Class<?> si : getInterfaces()) {
	addAll(fields, si.privateGetPublicFields());
	}

	// Direct superclass, recursively
	Class<?> sc = getSuperclass();
	if (sc != null) {
	addAll(fields, sc.privateGetPublicFields());
	}

	res = fields.toArray(new Field[0]);
	if (rd != null) {
	rd.publicFields = res;
	}
	return res;
	}

	private static void addAll(Collection<Field> c, Field[] o) {
	for (Field f : o) {
	c.add(f);
	}
	}


	//
	//
	// java.lang.reflect.Constructor handling
	//
	//

	// Returns an array of "root" constructors. These Constructor
	// objects must NOT be propagated to the outside world, but must
	// instead be copied via ReflectionFactory.copyConstructor.
	private Constructor<T>[] privateGetDeclaredConstructors(boolean publicOnly) {
	Constructor<T>[] res;
	ReflectionData<T> rd = reflectionData();
	if (rd != null) {
	res = publicOnly ? rd.publicConstructors : rd.declaredConstructors;
	if (res != null) return res;
	}
	// No cached value available; request value from VM
	if (isInterface()) {
	@SuppressWarnings("unchecked")
	Constructor<T>[] temporaryRes = (Constructor<T>[]) new Constructor<?>[0];
	res = temporaryRes;
	} else {
	res = getDeclaredConstructors0(publicOnly);
	}
	if (rd != null) {
	if (publicOnly) {
	rd.publicConstructors = res;
	} else {
	rd.declaredConstructors = res;
	}
	}
	return res;
	}

	//
	//
	// java.lang.reflect.Method handling
	//
	//

	// Returns an array of "root" methods. These Method objects must NOT
	// be propagated to the outside world, but must instead be copied
	// via ReflectionFactory.copyMethod.
	private Method[] privateGetDeclaredMethods(boolean publicOnly) {
	Method[] res;
	ReflectionData<T> rd = reflectionData();
	if (rd != null) {
	res = publicOnly ? rd.declaredPublicMethods : rd.declaredMethods;
	if (res != null) return res;
	}
	// No cached value available; request value from VM
	res = Reflection.filterMethods(this, getDeclaredMethods0(publicOnly));
	if (rd != null) {
	if (publicOnly) {
	rd.declaredPublicMethods = res;
	} else {
	rd.declaredMethods = res;
	}
	}
	return res;
	}

	// Returns an array of "root" methods. These Method objects must NOT
	// be propagated to the outside world, but must instead be copied
	// via ReflectionFactory.copyMethod.
	private Method[] privateGetPublicMethods() {
	Method[] res;
	ReflectionData<T> rd = reflectionData();
	if (rd != null) {
	res = rd.publicMethods;
	if (res != null) return res;
	}

	// No cached value available; compute value recursively.
	// Start by fetching public declared methods...
	PublicMethods pms = new PublicMethods();
	for (Method m : privateGetDeclaredMethods(/* publicOnly */ true)) {
	pms.merge(m);
	}
	// ...then recur over superclass methods...
	Class<?> sc = getSuperclass();
	if (sc != null) {
	for (Method m : sc.privateGetPublicMethods()) {
	pms.merge(m);
	}
	}
	// ...and finally over direct superinterfaces.
	for (Class<?> intf : getInterfaces(/* cloneArray */ false)) {
	for (Method m : intf.privateGetPublicMethods()) {
	// static interface methods are not inherited
	if (!Modifier.isStatic(m.getModifiers())) {
	pms.merge(m);
	}
	}
	}

	res = pms.toArray();
	if (rd != null) {
	rd.publicMethods = res;
	}
	return res;
	}


	//
	// Helpers for fetchers of one field, method, or constructor
	//

	// This method does not copy the returned Field object!
	private static Field searchFields(Field[] fields, String name) {
	for (Field field : fields) {
	if (field.getName().equals(name)) {
	return field;
	}
	}
	return null;
	}

	// Returns a "root" Field object. This Field object must NOT
	// be propagated to the outside world, but must instead be copied
	// via ReflectionFactory.copyField.
	private Field getField0(String name) {
	// Note: the intent is that the search algorithm this routine
	// uses be equivalent to the ordering imposed by
	// privateGetPublicFields(). It fetches only the declared
	// public fields for each class, however, to reduce the number
	// of Field objects which have to be created for the common
	// case where the field being requested is declared in the
	// class which is being queried.
	Field res;
	// Search declared public fields
	if ((res = searchFields(privateGetDeclaredFields(true), name)) != null) {
	return res;
	}
	// Direct superinterfaces, recursively
	Class<?>[] interfaces = getInterfaces(/* cloneArray */ false);
	for (Class<?> c : interfaces) {
	if ((res = c.getField0(name)) != null) {
	return res;
	}
	}
	// Direct superclass, recursively
	if (!isInterface()) {
	Class<?> c = getSuperclass();
	if (c != null) {
	if ((res = c.getField0(name)) != null) {
	return res;
	}
	}
	}
	return null;
	}

	// This method does not copy the returned Method object!
	private static Method searchMethods(Method[] methods,
	String name,
	Class<?>[] parameterTypes)
	{
	ReflectionFactory fact = getReflectionFactory();
	Method res = null;
	for (Method m : methods) {
	if (m.getName().equals(name)
	&& arrayContentsEq(parameterTypes,
	fact.getExecutableSharedParameterTypes(m))
	&& (res == null
	\|\| (res.getReturnType() != m.getReturnType()
	&& res.getReturnType().isAssignableFrom(m.getReturnType()))))
	res = m;
	}
	return res;
	}

	private static final Class<?>[] EMPTY_CLASS_ARRAY = new Class<?>[0];

	// Returns a "root" Method object. This Method object must NOT
	// be propagated to the outside world, but must instead be copied
	// via ReflectionFactory.copyMethod.
	private Method getMethod0(String name, Class<?>[] parameterTypes) {
	PublicMethods.MethodList res = getMethodsRecursive(
	name,
	parameterTypes == null ? EMPTY_CLASS_ARRAY : parameterTypes,
	/* includeStatic */ true);
	return res == null ? null : res.getMostSpecific();
	}

	// Returns a list of "root" Method objects. These Method objects must NOT
	// be propagated to the outside world, but must instead be copied
	// via ReflectionFactory.copyMethod.
	private PublicMethods.MethodList getMethodsRecursive(String name,
	Class<?>[] parameterTypes,
	boolean includeStatic) {
	// 1st check declared public methods
	Method[] methods = privateGetDeclaredMethods(/* publicOnly */ true);
	PublicMethods.MethodList res = PublicMethods.MethodList
	.filter(methods, name, parameterTypes, includeStatic);
	// if there is at least one match among declared methods, we need not
	// search any further as such match surely overrides matching methods
	// declared in superclass(es) or interface(s).
	if (res != null) {
	return res;
	}

	// if there was no match among declared methods,
	// we must consult the superclass (if any) recursively...
	Class<?> sc = getSuperclass();
	if (sc != null) {
	res = sc.getMethodsRecursive(name, parameterTypes, includeStatic);
	}

	// ...and coalesce the superclass methods with methods obtained
	// from directly implemented interfaces excluding static methods...
	for (Class<?> intf : getInterfaces(/* cloneArray */ false)) {
	res = PublicMethods.MethodList.merge(
	res, intf.getMethodsRecursive(name, parameterTypes,
	/* includeStatic */ false));
	}

	return res;
	}

	// Returns a "root" Constructor object. This Constructor object must NOT
	// be propagated to the outside world, but must instead be copied
	// via ReflectionFactory.copyConstructor.
	private Constructor<T> getConstructor0(Class<?>[] parameterTypes,
	int which) throws NoSuchMethodException
	{
	ReflectionFactory fact = getReflectionFactory();
	Constructor<T>[] constructors = privateGetDeclaredConstructors((which == Member.PUBLIC));
	for (Constructor<T> constructor : constructors) {
	if (arrayContentsEq(parameterTypes,
	fact.getExecutableSharedParameterTypes(constructor))) {
	return constructor;
	}
	}
	throw new NoSuchMethodException(methodToString("<init>", parameterTypes));
	}

	//
	// Other helpers and base implementation
	//

	private static boolean arrayContentsEq(Object[] a1, Object[] a2) {
	if (a1 == null) {
	return a2 == null \|\| a2.length == 0;
	}

	if (a2 == null) {
	return a1.length == 0;
	}

	if (a1.length != a2.length) {
	return false;
	}

	for (int i = 0; i < a1.length; i++) {
	if (a1[i] != a2[i]) {
	return false;
	}
	}

	return true;
	}

	private static Field[] copyFields(Field[] arg) {
	Field[] out = new Field[arg.length];
	ReflectionFactory fact = getReflectionFactory();
	for (int i = 0; i < arg.length; i++) {
	out[i] = fact.copyField(arg[i]);
	}
	return out;
	}

	private static Method[] copyMethods(Method[] arg) {
	Method[] out = new Method[arg.length];
	ReflectionFactory fact = getReflectionFactory();
	for (int i = 0; i < arg.length; i++) {
	out[i] = fact.copyMethod(arg[i]);
	}
	return out;
	}

	private static <U> Constructor<U>[] copyConstructors(Constructor<U>[] arg) {
	Constructor<U>[] out = arg.clone();
	ReflectionFactory fact = getReflectionFactory();
	for (int i = 0; i < out.length; i++) {
	out[i] = fact.copyConstructor(out[i]);
	}
	return out;
	}

	private native Field[] getDeclaredFields0(boolean publicOnly);
	private native Method[] getDeclaredMethods0(boolean publicOnly);
	private native Constructor<T>[] getDeclaredConstructors0(boolean publicOnly);
	private native Class<?>[] getDeclaredClasses0();

	/**
	* Helper method to get the method name from arguments.
	*/
	private String methodToString(String name, Class<?>[] argTypes) {
	StringJoiner sj = new StringJoiner(", ", getName() + "." + name + "(", ")");
	if (argTypes != null) {
	for (int i = 0; i < argTypes.length; i++) {
	Class<?> c = argTypes[i];
	sj.add((c == null) ? "null" : c.getName());
	}
	}
	return sj.toString();
	}

	/** use serialVersionUID from JDK 1.1 for interoperability */
	private static final long serialVersionUID = 3206093459760846163L;


	/**
	* Class Class is special cased within the Serialization Stream Protocol.
	*
	* A Class instance is written initially into an ObjectOutputStream in the
	* following format:
	* <pre>
	* {@code TC_CLASS} ClassDescriptor
	* A ClassDescriptor is a special cased serialization of
	* a {@code java.io.ObjectStreamClass} instance.
	* </pre>
	* A new handle is generated for the initial time the class descriptor
	* is written into the stream. Future references to the class descriptor
	* are written as references to the initial class descriptor instance.
	*
	* @see java.io.ObjectStreamClass
	*/
	private static final ObjectStreamField[] serialPersistentFields =
	new ObjectStreamField[0];


	/**
	* Returns the assertion status that would be assigned to this
	* class if it were to be initialized at the time this method is invoked.
	* If this class has had its assertion status set, the most recent
	* setting will be returned; otherwise, if any package default assertion
	* status pertains to this class, the most recent setting for the most
	* specific pertinent package default assertion status is returned;
	* otherwise, if this class is not a system class (i.e., it has a
	* class loader) its class loader's default assertion status is returned;
	* otherwise, the system class default assertion status is returned.
	* <p>
	* Few programmers will have any need for this method; it is provided
	* for the benefit of the JRE itself. (It allows a class to determine at
	* the time that it is initialized whether assertions should be enabled.)
	* Note that this method is not guaranteed to return the actual
	* assertion status that was (or will be) associated with the specified
	* class when it was (or will be) initialized.
	*
	* @return the desired assertion status of the specified class.
	* @see java.lang.ClassLoader#setClassAssertionStatus
	* @see java.lang.ClassLoader#setPackageAssertionStatus
	* @see java.lang.ClassLoader#setDefaultAssertionStatus
	* @since 1.4
	*/
	public boolean desiredAssertionStatus() {
	ClassLoader loader = getClassLoader0();
	// If the loader is null this is a system class, so ask the VM
	if (loader == null)
	return desiredAssertionStatus0(this);

	// If the classloader has been initialized with the assertion
	// directives, ask it. Otherwise, ask the VM.
	synchronized(loader.assertionLock) {
	if (loader.classAssertionStatus != null) {
	return loader.desiredAssertionStatus(getName());
	}
	}
	return desiredAssertionStatus0(this);
	}

	// Retrieves the desired assertion status of this class from the VM
	private static native boolean desiredAssertionStatus0(Class<?> clazz);

	/**
	* Returns true if and only if this class was declared as an enum in the
	* source code.
	*
	* @return true if and only if this class was declared as an enum in the
	* source code
	* @since 1.5
	*/
	public boolean isEnum() {
	// An enum must both directly extend java.lang.Enum and have
	// the ENUM bit set; classes for specialized enum constants
	// don't do the former.
	return (this.getModifiers() & ENUM) != 0 &&
	this.getSuperclass() == java.lang.Enum.class;
	}

	// Fetches the factory for reflective objects
	private static ReflectionFactory getReflectionFactory() {
	if (reflectionFactory == null) {
	reflectionFactory =
	java.security.AccessController.doPrivileged
	(new ReflectionFactory.GetReflectionFactoryAction());
	}
	return reflectionFactory;
	}
	private static ReflectionFactory reflectionFactory;

	/**
	* Returns the elements of this enum class or null if this
	* Class object does not represent an enum type.
	*
	* @return an array containing the values comprising the enum class
	* represented by this Class object in the order they're
	* declared, or null if this Class object does not
	* represent an enum type
	* @since 1.5
	*/
	public T[] getEnumConstants() {
	T[] values = getEnumConstantsShared();
	return (values != null) ? values.clone() : null;
	}

	/**
	* Returns the elements of this enum class or null if this
	* Class object does not represent an enum type;
	* identical to getEnumConstants except that the result is
	* uncloned, cached, and shared by all callers.
	*/
	T[] getEnumConstantsShared() {
	T[] constants = enumConstants;
	if (constants == null) {
	if (!isEnum()) return null;
	try {
	final Method values = getMethod("values");
	java.security.AccessController.doPrivileged(
	new java.security.PrivilegedAction<>() {
	public Void run() {
	values.setAccessible(true);
	return null;
	}
	});
	@SuppressWarnings("unchecked")
	T[] temporaryConstants = (T[])values.invoke(null);
	enumConstants = constants = temporaryConstants;
	}
	// These can happen when users concoct enum-like classes
	// that don't comply with the enum spec.
	catch (InvocationTargetException \| NoSuchMethodException \|
	IllegalAccessException ex) { return null; }
	}
	return constants;
	}
	private transient volatile T[] enumConstants;

	/**
	* Returns a map from simple name to enum constant. This package-private
	* method is used internally by Enum to implement
	* {@code public static <T extends Enum<T>> T valueOf(Class<T>, String)}
	* efficiently. Note that the map is returned by this method is
	* created lazily on first use. Typically it won't ever get created.
	*/
	Map<String, T> enumConstantDirectory() {
	Map<String, T> directory = enumConstantDirectory;
	if (directory == null) {
	T[] universe = getEnumConstantsShared();
	if (universe == null)
	throw new IllegalArgumentException(
	getName() + " is not an enum type");
	directory = new HashMap<>((int)(universe.length / 0.75f) + 1);
	for (T constant : universe) {
	directory.put(((Enum<?>)constant).name(), constant);
	}
	enumConstantDirectory = directory;
	}
	return directory;
	}
	private transient volatile Map<String, T> enumConstantDirectory;

	/**
	* Casts an object to the class or interface represented
	* by this {@code Class} object.
	*
	* @param obj the object to be cast
	* @return the object after casting, or null if obj is null
	*
	* @throws ClassCastException if the object is not
	* null and is not assignable to the type T.
	*
	* @since 1.5
	*/
	@SuppressWarnings("unchecked")
	@HotSpotIntrinsicCandidate
	public T cast(Object obj) {
	if (obj != null && !isInstance(obj))
	throw new ClassCastException(cannotCastMsg(obj));
	return (T) obj;
	}

	private String cannotCastMsg(Object obj) {
	return "Cannot cast " + obj.getClass().getName() + " to " + getName();
	}

	/**
	* Casts this {@code Class} object to represent a subclass of the class
	* represented by the specified class object. Checks that the cast
	* is valid, and throws a {@code ClassCastException} if it is not. If
	* this method succeeds, it always returns a reference to this class object.
	*
	* <p>This method is useful when a client needs to "narrow" the type of
	* a {@code Class} object to pass it to an API that restricts the
	* {@code Class} objects that it is willing to accept. A cast would
	* generate a compile-time warning, as the correctness of the cast
	* could not be checked at runtime (because generic types are implemented
	* by erasure).
	*
	* @param <U> the type to cast this class object to
	* @param clazz the class of the type to cast this class object to
	* @return this {@code Class} object, cast to represent a subclass of
	* the specified class object.
	* @throws ClassCastException if this {@code Class} object does not
	* represent a subclass of the specified class (here "subclass" includes
	* the class itself).
	* @since 1.5
	*/
	@SuppressWarnings("unchecked")
	public <U> Class<? extends U> asSubclass(Class<U> clazz) {
	if (clazz.isAssignableFrom(this))
	return (Class<? extends U>) this;
	else
	throw new ClassCastException(this.toString());
	}

	/**
	* @throws NullPointerException {@inheritDoc}
	* @since 1.5
	*/
	@SuppressWarnings("unchecked")
	public <A extends Annotation> A getAnnotation(Class<A> annotationClass) {
	Objects.requireNonNull(annotationClass);

	return (A) annotationData().annotations.get(annotationClass);
	}

	/**
	* {@inheritDoc}
	* @throws NullPointerException {@inheritDoc}
	* @since 1.5
	*/
	@Override
	public boolean isAnnotationPresent(Class<? extends Annotation> annotationClass) {
	return GenericDeclaration.super.isAnnotationPresent(annotationClass);
	}

	/**
	* @throws NullPointerException {@inheritDoc}
	* @since 1.8
	*/
	@Override
	public <A extends Annotation> A[] getAnnotationsByType(Class<A> annotationClass) {
	Objects.requireNonNull(annotationClass);

	AnnotationData annotationData = annotationData();
	return AnnotationSupport.getAssociatedAnnotations(annotationData.declaredAnnotations,
	this,
	annotationClass);
	}

	/**
	* @since 1.5
	*/
	public Annotation[] getAnnotations() {
	return AnnotationParser.toArray(annotationData().annotations);
	}

	/**
	* @throws NullPointerException {@inheritDoc}
	* @since 1.8
	*/
	@Override
	@SuppressWarnings("unchecked")
	public <A extends Annotation> A getDeclaredAnnotation(Class<A> annotationClass) {
	Objects.requireNonNull(annotationClass);

	return (A) annotationData().declaredAnnotations.get(annotationClass);
	}

	/**
	* @throws NullPointerException {@inheritDoc}
	* @since 1.8
	*/
	@Override
	public <A extends Annotation> A[] getDeclaredAnnotationsByType(Class<A> annotationClass) {
	Objects.requireNonNull(annotationClass);

	return AnnotationSupport.getDirectlyAndIndirectlyPresent(annotationData().declaredAnnotations,
	annotationClass);
	}

	/**
	* @since 1.5
	*/
	public Annotation[] getDeclaredAnnotations() {
	return AnnotationParser.toArray(annotationData().declaredAnnotations);
	}

	// annotation data that might get invalidated when JVM TI RedefineClasses() is called
	private static class AnnotationData {
	final Map<Class<? extends Annotation>, Annotation> annotations;
	final Map<Class<? extends Annotation>, Annotation> declaredAnnotations;

	// Value of classRedefinedCount when we created this AnnotationData instance
	final int redefinedCount;

	AnnotationData(Map<Class<? extends Annotation>, Annotation> annotations,
	Map<Class<? extends Annotation>, Annotation> declaredAnnotations,
	int redefinedCount) {
	this.annotations = annotations;
	this.declaredAnnotations = declaredAnnotations;
	this.redefinedCount = redefinedCount;
	}
	}

	// Annotations cache
	@SuppressWarnings("UnusedDeclaration")
	private transient volatile AnnotationData annotationData;

	private AnnotationData annotationData() {
	while (true) { // retry loop
	AnnotationData annotationData = this.annotationData;
	int classRedefinedCount = this.classRedefinedCount;
	if (annotationData != null &&
	annotationData.redefinedCount == classRedefinedCount) {
	return annotationData;
	}
	// null or stale annotationData -> optimistically create new instance
	AnnotationData newAnnotationData = createAnnotationData(classRedefinedCount);
	// try to install it
	if (Atomic.casAnnotationData(this, annotationData, newAnnotationData)) {
	// successfully installed new AnnotationData
	return newAnnotationData;
	}
	}
	}

	private AnnotationData createAnnotationData(int classRedefinedCount) {
	Map<Class<? extends Annotation>, Annotation> declaredAnnotations =
	AnnotationParser.parseAnnotations(getRawAnnotations(), getConstantPool(), this);
	Class<?> superClass = getSuperclass();
	Map<Class<? extends Annotation>, Annotation> annotations = null;
	if (superClass != null) {
	Map<Class<? extends Annotation>, Annotation> superAnnotations =
	superClass.annotationData().annotations;
	for (Map.Entry<Class<? extends Annotation>, Annotation> e : superAnnotations.entrySet()) {
	Class<? extends Annotation> annotationClass = e.getKey();
	if (AnnotationType.getInstance(annotationClass).isInherited()) {
	if (annotations == null) { // lazy construction
	annotations = new LinkedHashMap<>((Math.max(
	declaredAnnotations.size(),
	Math.min(12, declaredAnnotations.size() + superAnnotations.size())
	) * 4 + 2) / 3
	);
	}
	annotations.put(annotationClass, e.getValue());
	}
	}
	}
	if (annotations == null) {
	// no inherited annotations -> share the Map with declaredAnnotations
	annotations = declaredAnnotations;
	} else {
	// at least one inherited annotation -> declared may override inherited
	annotations.putAll(declaredAnnotations);
	}
	return new AnnotationData(annotations, declaredAnnotations, classRedefinedCount);
	}

	// Annotation types cache their internal (AnnotationType) form

	@SuppressWarnings("UnusedDeclaration")
	private transient volatile AnnotationType annotationType;

	boolean casAnnotationType(AnnotationType oldType, AnnotationType newType) {
	return Atomic.casAnnotationType(this, oldType, newType);
	}

	AnnotationType getAnnotationType() {
	return annotationType;
	}

	Map<Class<? extends Annotation>, Annotation> getDeclaredAnnotationMap() {
	return annotationData().declaredAnnotations;
	}

	/* Backing store of user-defined values pertaining to this class.
	* Maintained by the ClassValue class.
	*/
	transient ClassValue.ClassValueMap classValueMap;

	/**
	* Returns an {@code AnnotatedType} object that represents the use of a
	* type to specify the superclass of the entity represented by this {@code
	* Class} object. (The <em>use</em> of type Foo to specify the superclass
	* in '... extends Foo' is distinct from the <em>declaration</em> of type
	* Foo.)
	*
	* <p> If this {@code Class} object represents a type whose declaration
	* does not explicitly indicate an annotated superclass, then the return
	* value is an {@code AnnotatedType} object representing an element with no
	* annotations.
	*
	* <p> If this {@code Class} represents either the {@code Object} class, an
	* interface type, an array type, a primitive type, or void, the return
	* value is {@code null}.
	*
	* @return an object representing the superclass
	* @since 1.8
	*/
	public AnnotatedType getAnnotatedSuperclass() {
	if (this == Object.class \|\|
	isInterface() \|\|
	isArray() \|\|
	isPrimitive() \|\|
	this == Void.TYPE) {
	return null;
	}

	return TypeAnnotationParser.buildAnnotatedSuperclass(getRawTypeAnnotations(), getConstantPool(), this);
	}

	/**
	* Returns an array of {@code AnnotatedType} objects that represent the use
	* of types to specify superinterfaces of the entity represented by this
	* {@code Class} object. (The <em>use</em> of type Foo to specify a
	* superinterface in '... implements Foo' is distinct from the
	* <em>declaration</em> of type Foo.)
	*
	* <p> If this {@code Class} object represents a class, the return value is
	* an array containing objects representing the uses of interface types to
	* specify interfaces implemented by the class. The order of the objects in
	* the array corresponds to the order of the interface types used in the
	* 'implements' clause of the declaration of this {@code Class} object.
	*
	* <p> If this {@code Class} object represents an interface, the return
	* value is an array containing objects representing the uses of interface
	* types to specify interfaces directly extended by the interface. The
	* order of the objects in the array corresponds to the order of the
	* interface types used in the 'extends' clause of the declaration of this
	* {@code Class} object.
	*
	* <p> If this {@code Class} object represents a class or interface whose
	* declaration does not explicitly indicate any annotated superinterfaces,
	* the return value is an array of length 0.
	*
	* <p> If this {@code Class} object represents either the {@code Object}
	* class, an array type, a primitive type, or void, the return value is an
	* array of length 0.
	*
	* @return an array representing the superinterfaces
	* @since 1.8
	*/
	public AnnotatedType[] getAnnotatedInterfaces() {
	return TypeAnnotationParser.buildAnnotatedInterfaces(getRawTypeAnnotations(), getConstantPool(), this);
	}

	private native Class<?> getNestHost0();

	/**
	* Returns the nest host of the <a href=#nest>nest</a> to which the class
	* or interface represented by this {@code Class} object belongs.
	* Every class and interface is a member of exactly one nest.
	* A class or interface that is not recorded as belonging to a nest
	* belongs to the nest consisting only of itself, and is the nest
	* host.
	*
	* <p>Each of the {@code Class} objects representing array types,
	* primitive types, and {@code void} returns {@code this} to indicate
	* that the represented entity belongs to the nest consisting only of
	* itself, and is the nest host.
	*
	* <p>If there is a {@linkplain LinkageError linkage error} accessing
	* the nest host, or if this class or interface is not enumerated as
	* a member of the nest by the nest host, then it is considered to belong
	* to its own nest and {@code this} is returned as the host.
	*
	* @apiNote A {@code class} file of version 55.0 or greater may record the
	* host of the nest to which it belongs by using the {@code NestHost}
	* attribute (JVMS 4.7.28). Alternatively, a {@code class} file of
	* version 55.0 or greater may act as a nest host by enumerating the nest's
	* other members with the
	* {@code NestMembers} attribute (JVMS 4.7.29).
	* A {@code class} file of version 54.0 or lower does not use these
	* attributes.
	*
	* @return the nest host of this class or interface
	*
	* @throws SecurityException
	* If the returned class is not the current class, and
	* if a security manager, <i>s</i>, is present and the caller's
	* class loader is not the same as or an ancestor of the class
	* loader for the returned class and invocation of {@link
	* SecurityManager#checkPackageAccess s.checkPackageAccess()}
	* denies access to the package of the returned class
	* @since 11
	* @jvms 4.7.28 and 4.7.29 NestHost and NestMembers attributes
	* @jvms 5.4.4 Access Control
	*/
	@CallerSensitive
	public Class<?> getNestHost() {
	if (isPrimitive() \|\| isArray()) {
	return this;
	}
	Class<?> host;
	try {
	host = getNestHost0();
	} catch (LinkageError e) {
	// if we couldn't load our nest-host then we
	// act as-if we have no nest-host attribute
	return this;
	}
	// if null then nest membership validation failed, so we
	// act as-if we have no nest-host attribute
	if (host == null \|\| host == this) {
	return this;
	}
	// returning a different class requires a security check
	SecurityManager sm = System.getSecurityManager();
	if (sm != null) {
	checkPackageAccess(sm,
	ClassLoader.getClassLoader(Reflection.getCallerClass()), true);
	}
	return host;
	}

	/**
	* Determines if the given {@code Class} is a nestmate of the
	* class or interface represented by this {@code Class} object.
	* Two classes or interfaces are nestmates
	* if they have the same {@linkplain #getNestHost() nest host}.
	*
	* @param c the class to check
	* @return {@code true} if this class and {@code c} are members of
	* the same nest; and {@code false} otherwise.
	*
	* @since 11
	*/
	public boolean isNestmateOf(Class<?> c) {
	if (this == c) {
	return true;
	}
	if (isPrimitive() \|\| isArray() \|\|
	c.isPrimitive() \|\| c.isArray()) {
	return false;
	}
	try {
	return getNestHost0() == c.getNestHost0();
	} catch (LinkageError e) {
	return false;
	}
	}

	private native Class<?>[] getNestMembers0();

	/**
	* Returns an array containing {@code Class} objects representing all the
	* classes and interfaces that are members of the nest to which the class
	* or interface represented by this {@code Class} object belongs.
	* The {@linkplain #getNestHost() nest host} of that nest is the zeroth
	* element of the array. Subsequent elements represent any classes or
	* interfaces that are recorded by the nest host as being members of
	* the nest; the order of such elements is unspecified. Duplicates are
	* permitted.
	* If the nest host of that nest does not enumerate any members, then the
	* array has a single element containing {@code this}.
	*
	* <p>Each of the {@code Class} objects representing array types,
	* primitive types, and {@code void} returns an array containing only
	* {@code this}.
	*
	* <p>This method validates that, for each class or interface which is
	* recorded as a member of the nest by the nest host, that class or
	* interface records itself as a member of that same nest. Any exceptions
	* that occur during this validation are rethrown by this method.
	*
	* @return an array of all classes and interfaces in the same nest as
	* this class
	*
	* @throws LinkageError
	* If there is any problem loading or validating a nest member or
	* its nest host
	* @throws SecurityException
	* If any returned class is not the current class, and
	* if a security manager, <i>s</i>, is present and the caller's
	* class loader is not the same as or an ancestor of the class
	* loader for that returned class and invocation of {@link
	* SecurityManager#checkPackageAccess s.checkPackageAccess()}
	* denies access to the package of that returned class
	*
	* @since 11
	* @see #getNestHost()
	*/
	@CallerSensitive
	public Class<?>[] getNestMembers() {
	if (isPrimitive() \|\| isArray()) {
	return new Class<?>[] { this };
	}
	Class<?>[] members = getNestMembers0();
	// Can't actually enable this due to bootstrapping issues
	// assert(members.length != 1 \|\| members[0] == this); // expected invariant from VM

	if (members.length > 1) {
	// If we return anything other than the current class we need
	// a security check
	SecurityManager sm = System.getSecurityManager();
	if (sm != null) {
	checkPackageAccess(sm,
	ClassLoader.getClassLoader(Reflection.getCallerClass()), true);
	}
	}
	return members;
	}
	}

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