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* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
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* accompanied this code).
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package sun.invoke.util;
import java.lang.reflect.Modifier;
import static java.lang.reflect.Modifier.*;
import java.util.Objects;
import jdk.internal.reflect.Reflection;
/**
* This class centralizes information about the JVM's linkage access control.
* @author jrose
*/
public class VerifyAccess {
private VerifyAccess() { } // cannot instantiate
private static final int UNCONDITIONAL_ALLOWED = java.lang.invoke.MethodHandles.Lookup.UNCONDITIONAL;
private static final int MODULE_ALLOWED = java.lang.invoke.MethodHandles.Lookup.MODULE;
private static final int PACKAGE_ONLY = 0;
private static final int PACKAGE_ALLOWED = java.lang.invoke.MethodHandles.Lookup.PACKAGE;
private static final int PROTECTED_OR_PACKAGE_ALLOWED = (PACKAGE_ALLOWED|PROTECTED);
private static final int ALL_ACCESS_MODES = (PUBLIC|PRIVATE|PROTECTED|PACKAGE_ONLY);
private static final boolean ALLOW_NESTMATE_ACCESS = false;
/**
* Evaluate the JVM linkage rules for access to the given method
* on behalf of a caller class which proposes to perform the access.
* Return true if the caller class has privileges to invoke a method
* or access a field with the given properties.
* This requires an accessibility check of the referencing class,
* plus an accessibility check of the member within the class,
* which depends on the member's modifier flags.
* <p>
* The relevant properties include the defining class ({@code defc})
* of the member, and its modifier flags ({@code mods}).
* Also relevant is the class used to make the initial symbolic reference
* to the member ({@code refc}). If this latter class is not distinguished,
* the defining class should be passed for both arguments ({@code defc == refc}).
* <h3>JVM Specification, 5.4.4 "Access Control"</h3>
* A field or method R is accessible to a class or interface D if
* and only if any of the following conditions is true:<ul>
* <li>R is public.
* <li>R is protected and is declared in a class C, and D is either
* a subclass of C or C itself. Furthermore, if R is not
* static, then the symbolic reference to R must contain a
* symbolic reference to a class T, such that T is either a
* subclass of D, a superclass of D or D itself.
* <li>R is either protected or has default access (that is,
* neither public nor protected nor private), and is declared
* by a class in the same runtime package as D.
* <li>R is private and is declared in D.
* </ul>
* This discussion of access control omits a related restriction
* on the target of a protected field access or method invocation
* (the target must be of class D or a subtype of D). That
* requirement is checked as part of the verification process
* (5.4.1); it is not part of link-time access control.
* @param refc the class used in the symbolic reference to the proposed member
* @param defc the class in which the proposed member is actually defined
* @param mods modifier flags for the proposed member
* @param lookupClass the class for which the access check is being made
* @return true iff the accessing class can access such a member
*/
public static boolean isMemberAccessible(Class<?> refc, // symbolic ref class
Class<?> defc, // actual def class
int mods, // actual member mods
Class<?> lookupClass,
int allowedModes) {
if (allowedModes == 0) return false;
assert((allowedModes & PUBLIC) != 0 &&
(allowedModes & ~(ALL_ACCESS_MODES|PACKAGE_ALLOWED|MODULE_ALLOWED|UNCONDITIONAL_ALLOWED)) == 0);
// The symbolic reference class (refc) must always be fully verified.
if (!isClassAccessible(refc, lookupClass, allowedModes)) {
return false;
}
// Usually refc and defc are the same, but verify defc also in case they differ.
if (defc == lookupClass &&
(allowedModes & PRIVATE) != 0)
return true; // easy check; all self-access is OK
switch (mods & ALL_ACCESS_MODES) {
case PUBLIC:
return true; // already checked above
case PROTECTED:
assert !defc.isInterface(); // protected members aren't allowed in interfaces
if ((allowedModes & PROTECTED_OR_PACKAGE_ALLOWED) != 0 &&
isSamePackage(defc, lookupClass))
return true;
if ((allowedModes & PROTECTED) == 0)
return false;
// Protected members are accessible by subclasses, which does not include interfaces.
// Interfaces are types, not classes. They should not have access to
// protected members in j.l.Object, even though it is their superclass.
if ((mods & STATIC) != 0 &&
!isRelatedClass(refc, lookupClass))
return false;
if ((allowedModes & PROTECTED) != 0 &&
isSubClass(lookupClass, defc))
return true;
return false;
case PACKAGE_ONLY: // That is, zero. Unmarked member is package-only access.
assert !defc.isInterface(); // package-private members aren't allowed in interfaces
return ((allowedModes & PACKAGE_ALLOWED) != 0 &&
isSamePackage(defc, lookupClass));
case PRIVATE:
// Loosened rules for privates follows access rules for inner classes.
return (ALLOW_NESTMATE_ACCESS &&
(allowedModes & PRIVATE) != 0 &&
isSamePackageMember(defc, lookupClass));
default:
throw new IllegalArgumentException("bad modifiers: "+Modifier.toString(mods));
}
}
static boolean isRelatedClass(Class<?> refc, Class<?> lookupClass) {
return (refc == lookupClass ||
isSubClass(refc, lookupClass) ||
isSubClass(lookupClass, refc));
}
static boolean isSubClass(Class<?> lookupClass, Class<?> defc) {
return defc.isAssignableFrom(lookupClass) &&
!lookupClass.isInterface(); // interfaces are types, not classes.
}
static int getClassModifiers(Class<?> c) {
// This would return the mask stored by javac for the source-level modifiers.
// return c.getModifiers();
// But what we need for JVM access checks are the actual bits from the class header.
// ...But arrays and primitives are synthesized with their own odd flags:
if (c.isArray() || c.isPrimitive())
return c.getModifiers();
return Reflection.getClassAccessFlags(c);
}
/**
* Evaluate the JVM linkage rules for access to the given class on behalf of caller.
* <h3>JVM Specification, 5.4.4 "Access Control"</h3>
* A class or interface C is accessible to a class or interface D
* if and only if any of the following conditions are true:<ul>
* <li>C is public and in the same module as D.
* <li>D is in a module that reads the module containing C, C is public and in a
* package that is exported to the module that contains D.
* <li>C and D are members of the same runtime package.
* </ul>
* @param refc the symbolic reference class to which access is being checked (C)
* @param lookupClass the class performing the lookup (D)
*/
public static boolean isClassAccessible(Class<?> refc, Class<?> lookupClass,
int allowedModes) {
if (allowedModes == 0) return false;
assert((allowedModes & PUBLIC) != 0 &&
(allowedModes & ~(ALL_ACCESS_MODES|PACKAGE_ALLOWED|MODULE_ALLOWED|UNCONDITIONAL_ALLOWED)) == 0);
int mods = getClassModifiers(refc);
if (isPublic(mods)) {
Module lookupModule = lookupClass.getModule();
Module refModule = refc.getModule();
// early VM startup case, java.base not defined
if (lookupModule == null) {
assert refModule == null;
return true;
}
// trivially allow
if ((allowedModes & MODULE_ALLOWED) != 0 &&
(lookupModule == refModule))
return true;
// check readability when UNCONDITIONAL not allowed
if (((allowedModes & UNCONDITIONAL_ALLOWED) != 0)
|| lookupModule.canRead(refModule)) {
// check that refc is in an exported package
if ((allowedModes & MODULE_ALLOWED) != 0) {
if (refModule.isExported(refc.getPackageName(), lookupModule))
return true;
} else {
// exported unconditionally
if (refModule.isExported(refc.getPackageName()))
return true;
}
// not exported but allow access during VM initialization
// because java.base does not have its exports setup
if (!jdk.internal.misc.VM.isModuleSystemInited())
return true;
}
// public class not accessible to lookupClass
return false;
}
if ((allowedModes & PACKAGE_ALLOWED) != 0 &&
isSamePackage(lookupClass, refc))
return true;
return false;
}
/**
* Decide if the given method type, attributed to a member or symbolic
* reference of a given reference class, is really visible to that class.
* @param type the supposed type of a member or symbolic reference of refc
* @param refc the class attempting to make the reference
*/
public static boolean isTypeVisible(Class<?> type, Class<?> refc) {
if (type == refc) {
return true; // easy check
}
while (type.isArray()) type = type.getComponentType();
if (type.isPrimitive() || type == Object.class) {
return true;
}
ClassLoader typeLoader = type.getClassLoader();
ClassLoader refcLoader = refc.getClassLoader();
if (typeLoader == refcLoader) {
return true;
}
if (refcLoader == null && typeLoader != null) {
return false;
}
if (typeLoader == null && type.getName().startsWith("java.")) {
// Note: The API for actually loading classes, ClassLoader.defineClass,
// guarantees that classes with names beginning "java." cannot be aliased,
// because class loaders cannot load them directly.
return true;
}
// Do it the hard way: Look up the type name from the refc loader.
//
// Force the refc loader to report and commit to a particular binding for this type name (type.getName()).
//
// In principle, this query might force the loader to load some unrelated class,
// which would cause this query to fail (and the original caller to give up).
// This would be wasted effort, but it is expected to be very rare, occurring
// only when an attacker is attempting to create a type alias.
// In the normal case, one class loader will simply delegate to the other,
// and the same type will be visible through both, with no extra loading.
//
// It is important to go through Class.forName instead of ClassLoader.loadClass
// because Class.forName goes through the JVM system dictionary, which records
// the class lookup once for all. This means that even if a not-well-behaved class loader
// would "change its mind" about the meaning of the name, the Class.forName request
// will use the result cached in the JVM system dictionary. Note that the JVM system dictionary
// will record the first successful result. Unsuccessful results are not stored.
//
// We use doPrivileged in order to allow an unprivileged caller to ask an arbitrary
// class loader about the binding of the proposed name (type.getName()).
// The looked up type ("res") is compared for equality against the proposed
// type ("type") and then is discarded. Thus, the worst that can happen to
// the "child" class loader is that it is bothered to load and report a class
// that differs from "type"; this happens once due to JVM system dictionary
// memoization. And the caller never gets to look at the alternate type binding
// ("res"), whether it exists or not.
final String name = type.getName();
Class<?> res = java.security.AccessController.doPrivileged(
new java.security.PrivilegedAction<>() {
public Class<?> run() {
try {
return Class.forName(name, false, refcLoader);
} catch (ClassNotFoundException | LinkageError e) {
return null; // Assume the class is not found
}
}
});
return (type == res);
}
/**
* Decide if the given method type, attributed to a member or symbolic
* reference of a given reference class, is really visible to that class.
* @param type the supposed type of a member or symbolic reference of refc
* @param refc the class attempting to make the reference
*/
public static boolean isTypeVisible(java.lang.invoke.MethodType type, Class<?> refc) {
if (!isTypeVisible(type.returnType(), refc)) {
return false;
}
for (int n = 0, max = type.parameterCount(); n < max; n++) {
if (!isTypeVisible(type.parameterType(n), refc)) {
return false;
}
}
return true;
}
/**
* Tests if two classes are in the same module.
* @param class1 a class
* @param class2 another class
* @return whether they are in the same module
*/
public static boolean isSameModule(Class<?> class1, Class<?> class2) {
return class1.getModule() == class2.getModule();
}
/**
* Test if two classes have the same class loader and package qualifier.
* @param class1 a class
* @param class2 another class
* @return whether they are in the same package
*/
public static boolean isSamePackage(Class<?> class1, Class<?> class2) {
assert(!class1.isArray() && !class2.isArray());
if (class1 == class2)
return true;
if (class1.getClassLoader() != class2.getClassLoader())
return false;
return Objects.equals(class1.getPackageName(), class2.getPackageName());
}
/** Return the package name for this class.
*/
public static String getPackageName(Class<?> cls) {
assert (!cls.isArray());
String name = cls.getName();
int dot = name.lastIndexOf('.');
if (dot < 0) return "";
return name.substring(0, dot);
}
/**
* Test if two classes are defined as part of the same package member (top-level class).
* If this is true, they can share private access with each other.
* @param class1 a class
* @param class2 another class
* @return whether they are identical or nested together
*/
public static boolean isSamePackageMember(Class<?> class1, Class<?> class2) {
if (class1 == class2)
return true;
if (!isSamePackage(class1, class2))
return false;
if (getOutermostEnclosingClass(class1) != getOutermostEnclosingClass(class2))
return false;
return true;
}
private static Class<?> getOutermostEnclosingClass(Class<?> c) {
Class<?> pkgmem = c;
for (Class<?> enc = c; (enc = enc.getEnclosingClass()) != null; )
pkgmem = enc;
return pkgmem;
}
private static boolean loadersAreRelated(ClassLoader loader1, ClassLoader loader2,
boolean loader1MustBeParent) {
if (loader1 == loader2 || loader1 == null
|| (loader2 == null && !loader1MustBeParent)) {
return true;
}
for (ClassLoader scan2 = loader2;
scan2 != null; scan2 = scan2.getParent()) {
if (scan2 == loader1) return true;
}
if (loader1MustBeParent) return false;
// see if loader2 is a parent of loader1:
for (ClassLoader scan1 = loader1;
scan1 != null; scan1 = scan1.getParent()) {
if (scan1 == loader2) return true;
}
return false;
}
/**
* Is the class loader of parentClass identical to, or an ancestor of,
* the class loader of childClass?
* @param parentClass a class
* @param childClass another class, which may be a descendent of the first class
* @return whether parentClass precedes or equals childClass in class loader order
*/
public static boolean classLoaderIsAncestor(Class<?> parentClass, Class<?> childClass) {
return loadersAreRelated(parentClass.getClassLoader(), childClass.getClassLoader(), true);
}
}