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/*
 * Written by Doug Lea with assistance from members of JCP JSR-166
 * Expert Group and released to the public domain, as explained at
 * http://creativecommons.org/publicdomain/zero/1.0/
 */

package java.util.concurrent.atomic;
import dalvik.system.VMStack; // android-added
import sun.misc.Unsafe;
import java.lang.reflect.Field;
import java.lang.reflect.Modifier;

/**
 * A reflection-based utility that enables atomic updates to
 * designated {@code volatile} reference fields of designated
 * classes.  This class is designed for use in atomic data structures
 * in which several reference fields of the same node are
 * independently subject to atomic updates. For example, a tree node
 * might be declared as
 *
 *  
 {@code
 * class Node {
 *   private volatile Node left, right;
 *
 *   private static final AtomicReferenceFieldUpdater leftUpdater =
 *     AtomicReferenceFieldUpdater.newUpdater(Node.class, Node.class, "left");
 *   private static AtomicReferenceFieldUpdater rightUpdater =
 *     AtomicReferenceFieldUpdater.newUpdater(Node.class, Node.class, "right");
 *
 *   Node getLeft() { return left;  }
 *   boolean compareAndSetLeft(Node expect, Node update) {
 *     return leftUpdater.compareAndSet(this, expect, update);
 *   }
 *   // ... and so on
 * }}
* *

Note that the guarantees of the {@code compareAndSet} * method in this class are weaker than in other atomic classes. * Because this class cannot ensure that all uses of the field * are appropriate for purposes of atomic access, it can * guarantee atomicity only with respect to other invocations of * {@code compareAndSet} and {@code set} on the same updater. * * @since 1.5 * @author Doug Lea * @param The type of the object holding the updatable field * @param The type of the field */ public abstract class AtomicReferenceFieldUpdater { /** * Creates and returns an updater for objects with the given field. * The Class arguments are needed to check that reflective types and * generic types match. * * @param tclass the class of the objects holding the field * @param vclass the class of the field * @param fieldName the name of the field to be updated * @return the updater * @throws IllegalArgumentException if the field is not a volatile reference type * @throws RuntimeException with a nested reflection-based * exception if the class does not hold field or is the wrong type, * or the field is inaccessible to the caller according to Java language * access control */ public static AtomicReferenceFieldUpdater newUpdater(Class tclass, Class vclass, String fieldName) { return new AtomicReferenceFieldUpdaterImpl(tclass, vclass, fieldName); } /** * Protected do-nothing constructor for use by subclasses. */ protected AtomicReferenceFieldUpdater() { } /** * Atomically sets the field of the given object managed by this updater * to the given updated value if the current value {@code ==} the * expected value. This method is guaranteed to be atomic with respect to * other calls to {@code compareAndSet} and {@code set}, but not * necessarily with respect to other changes in the field. * * @param obj An object whose field to conditionally set * @param expect the expected value * @param update the new value * @return true if successful */ public abstract boolean compareAndSet(T obj, V expect, V update); /** * Atomically sets the field of the given object managed by this updater * to the given updated value if the current value {@code ==} the * expected value. This method is guaranteed to be atomic with respect to * other calls to {@code compareAndSet} and {@code set}, but not * necessarily with respect to other changes in the field. * *

May fail * spuriously and does not provide ordering guarantees, so is * only rarely an appropriate alternative to {@code compareAndSet}. * * @param obj An object whose field to conditionally set * @param expect the expected value * @param update the new value * @return true if successful */ public abstract boolean weakCompareAndSet(T obj, V expect, V update); /** * Sets the field of the given object managed by this updater to the * given updated value. This operation is guaranteed to act as a volatile * store with respect to subsequent invocations of {@code compareAndSet}. * * @param obj An object whose field to set * @param newValue the new value */ public abstract void set(T obj, V newValue); /** * Eventually sets the field of the given object managed by this * updater to the given updated value. * * @param obj An object whose field to set * @param newValue the new value * @since 1.6 */ public abstract void lazySet(T obj, V newValue); /** * Gets the current value held in the field of the given object managed * by this updater. * * @param obj An object whose field to get * @return the current value */ public abstract V get(T obj); /** * Atomically sets the field of the given object managed by this updater * to the given value and returns the old value. * * @param obj An object whose field to get and set * @param newValue the new value * @return the previous value */ public V getAndSet(T obj, V newValue) { for (;;) { V current = get(obj); if (compareAndSet(obj, current, newValue)) return current; } } private static final class AtomicReferenceFieldUpdaterImpl extends AtomicReferenceFieldUpdater { private static final Unsafe unsafe = Unsafe.getUnsafe(); private final long offset; private final Class tclass; private final Class vclass; private final Class cclass; /* * Internal type checks within all update methods contain * internal inlined optimizations checking for the common * cases where the class is final (in which case a simple * getClass comparison suffices) or is of type Object (in * which case no check is needed because all objects are * instances of Object). The Object case is handled simply by * setting vclass to null in constructor. The targetCheck and * updateCheck methods are invoked when these faster * screenings fail. */ AtomicReferenceFieldUpdaterImpl(final Class tclass, Class vclass, final String fieldName) { final Field field; final Class fieldClass; final Class caller; final int modifiers; try { field = tclass.getDeclaredField(fieldName); // android-changed caller = VMStack.getStackClass2(); // android-changed modifiers = field.getModifiers(); // BEGIN android-removed // sun.reflect.misc.ReflectUtil.ensureMemberAccess( // caller, tclass, null, modifiers); // ClassLoader cl = tclass.getClassLoader(); // ClassLoader ccl = caller.getClassLoader(); // if ((ccl != null) && (ccl != cl) && // ((cl == null) || !isAncestor(cl, ccl))) { // sun.reflect.misc.ReflectUtil.checkPackageAccess(tclass); // } // END android-removed fieldClass = field.getType(); // BEGIN android-removed // } catch (PrivilegedActionException pae) { // throw new RuntimeException(pae.getException()); // END android-removed } catch (Exception ex) { throw new RuntimeException(ex); } if (vclass != fieldClass) throw new ClassCastException(); if (!Modifier.isVolatile(modifiers)) throw new IllegalArgumentException("Must be volatile type"); this.cclass = (Modifier.isProtected(modifiers) && caller != tclass) ? caller : null; this.tclass = tclass; if (vclass == Object.class) this.vclass = null; else this.vclass = vclass; offset = unsafe.objectFieldOffset(field); } // BEGIN android-removed // /** // * Returns true if the second classloader can be found in the first // * classloader's delegation chain. // * Equivalent to the inaccessible: first.isAncestor(second). // */ // // private static boolean isAncestor(ClassLoader first, ClassLoader second) { // ClassLoader acl = first; // do { // acl = acl.getParent(); // if (second == acl) { // return true; // } // } while (acl != null); // return false; // } // END android-removed void targetCheck(T obj) { if (!tclass.isInstance(obj)) throw new ClassCastException(); if (cclass != null) ensureProtectedAccess(obj); } void updateCheck(T obj, V update) { if (!tclass.isInstance(obj) || (update != null && vclass != null && !vclass.isInstance(update))) throw new ClassCastException(); if (cclass != null) ensureProtectedAccess(obj); } public boolean compareAndSet(T obj, V expect, V update) { if (obj == null || obj.getClass() != tclass || cclass != null || (update != null && vclass != null && vclass != update.getClass())) updateCheck(obj, update); return unsafe.compareAndSwapObject(obj, offset, expect, update); } public boolean weakCompareAndSet(T obj, V expect, V update) { // same implementation as strong form for now if (obj == null || obj.getClass() != tclass || cclass != null || (update != null && vclass != null && vclass != update.getClass())) updateCheck(obj, update); return unsafe.compareAndSwapObject(obj, offset, expect, update); } public void set(T obj, V newValue) { if (obj == null || obj.getClass() != tclass || cclass != null || (newValue != null && vclass != null && vclass != newValue.getClass())) updateCheck(obj, newValue); unsafe.putObjectVolatile(obj, offset, newValue); } public void lazySet(T obj, V newValue) { if (obj == null || obj.getClass() != tclass || cclass != null || (newValue != null && vclass != null && vclass != newValue.getClass())) updateCheck(obj, newValue); unsafe.putOrderedObject(obj, offset, newValue); } @SuppressWarnings("unchecked") public V get(T obj) { if (obj == null || obj.getClass() != tclass || cclass != null) targetCheck(obj); return (V)unsafe.getObjectVolatile(obj, offset); } private void ensureProtectedAccess(T obj) { if (cclass.isInstance(obj)) { return; } throw new RuntimeException( new IllegalAccessException("Class " + cclass.getName() + " can not access a protected member of class " + tclass.getName() + " using an instance of " + obj.getClass().getName() ) ); } } }





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