java不能直接訪問操作系統底層,而是通過本地方法來訪問。Unsafe類提供了硬件級別的原子操作,主要提供了以下功能:
1、通過Unsafe類可以分配內存,可以釋放內存;
類中提供的3個本地方法allocateMemory、reallocateMemory、freeMemory分別用於分配內存,擴充內存和釋放內存,與C語言中的3個方法對應。
2、可以定位對象某字段的內存位置,也可以修改對象的字段值,即使它是私有的;
public native long allocateMemory(long l);
public native long reallocateMemory(long l, long l1);
public native void freeMemory(long l);
字段的定位:
JAVA中對象的字段的定位可能通過staticFieldOffset方法實現,該方法返回給定field的內存地址偏移量,這個值對於給定的filed是唯一的且是固定不變的。
getIntVolatile方法獲取對象中offset偏移地址對應的整型field的值,支持volatile load語義。
getLong方法獲取對象中offset偏移地址對應的long型field的值
數組元素定位:
Unsafe類中有很多以BASE_OFFSET結尾的常量,比如ARRAY_INT_BASE_OFFSET,ARRAY_BYTE_BASE_OFFSET等,這些常量值是通過arrayBaseOffset方法得到的。arrayBaseOffset方法是一個本地方法,可以獲取數組第一個元素的偏移地址。Unsafe類中還有很多以INDEX_SCALE結尾的常量,比如 ARRAY_INT_INDEX_SCALE , ARRAY_BYTE_INDEX_SCALE等,這些常量值是通過arrayIndexScale方法得到的。arrayIndexScale方法也是一個本地方法,可以獲取數組的轉換因子,也就是數組中元素的增量地址。將arrayBaseOffset與arrayIndexScale配合使用,可以定位數組中每個元素在內存中的位置。
複製代碼
public final class Unsafe {
public static final int ARRAY_INT_BASE_OFFSET;
public static final int ARRAY_INT_INDEX_SCALE;
public native long staticFieldOffset(Field field);
public native int getIntVolatile(Object obj, long l);
public native long getLong(Object obj, long l);
public native int arrayBaseOffset(Class class1);
public native int arrayIndexScale(Class class1);
static
{
ARRAY_INT_BASE_OFFSET = theUnsafe.arrayBaseOffset([I);
ARRAY_INT_INDEX_SCALE = theUnsafe.arrayIndexScale([I);
}
}
複製代碼
3、掛起與恢復
將一個線程進行掛起是通過park方法實現的,調用 park後,線程將一直阻塞直到超時或者中斷等條件出現。unpark可以終止一個掛起的線程,使其恢復正常。整個併發框架中對線程的掛起操作被封裝在 LockSupport類中,LockSupport類中有各種版本pack方法,但最終都調用了Unsafe.park()方法。
複製代碼
public class LockSupport {
public static void unpark(Thread thread) {
if (thread != null)
unsafe.unpark(thread);
}
public static void park(Object blocker) {
Thread t = Thread.currentThread();
setBlocker(t, blocker);
unsafe.park(false, 0L);
setBlocker(t, null);
}
public static void parkNanos(Object blocker, long nanos) {
if (nanos > 0) {
Thread t = Thread.currentThread();
setBlocker(t, blocker);
unsafe.park(false, nanos);
setBlocker(t, null);
}
}
public static void parkUntil(Object blocker, long deadline) {
Thread t = Thread.currentThread();
setBlocker(t, blocker);
unsafe.park(true, deadline);
setBlocker(t, null);
}
public static void park() {
unsafe.park(false, 0L);
}
public static void parkNanos(long nanos) {
if (nanos > 0)
unsafe.park(false, nanos);
}
public static void parkUntil(long deadline) {
unsafe.park(true, deadline);
}
}
複製代碼
4、CAS操作
是通過compareAndSwapXXX方法實現的
複製代碼
/**
* 比較obj的offset處內存位置中的值和期望的值,如果相同則更新。此更新是不可中斷的。
*
* @param obj 需要更新的對象
* @param offset obj中整型field的偏移量
* @param expect 希望field中存在的值
* @param update 如果期望值expect與field的當前值相同,設置filed的值爲這個新值
* @return 如果field的值被更改返回true
*/
public native boolean compareAndSwapInt(Object obj, long offset, int expect, int update);
複製代碼
CAS操作有3個操作數,內存值M,預期值E,新值U,如果M==E,則將內存值修改爲B,否則啥都不做。
參考資料:
Unsafe.h
源碼剖析之sun.misc.Unsafe
注:轉自http://blog.csdn.net/aesop_wubo/article/details/7537278
首先介紹一下什麼是Compare And Swap(CAS)?簡單的說就是比較並交換。
CAS 操作包含三個操作數 —— 內存位置(V)、預期原值(A)和新值(B)。如果內存位置的值與預期原值相匹配,那麼處理器會自動將該位置值更新爲新值。否則,處理器不做任何操作。無論哪種情況,它都會在 CAS 指令之前返回該位置的值。CAS 有效地說明了“我認爲位置 V 應該包含值 A;如果包含該值,則將 B 放到這個位置;否則,不要更改該位置,只告訴我這個位置現在的值即可。” Java併發包(java.util.concurrent)中大量使用了CAS操作,涉及到併發的地方都調用了sun.misc.Unsafe類方法進行CAS操作。
在看一下volatile, Volatile修飾的成員變量在每次被線程訪問時,都強迫從共享內存中重讀該成員變量的值。而且,當成員變量發生變化時,強迫線程將變化值回寫到共享內存。這樣在任何時刻,兩個不同的線程總是看到某個成員變量的值是相同的,更簡單一點理解就是volatile修飾的變量值發生變化時對於另外的線程是可見的。
如何正確使用volatile可以參考下面這篇文章:
http://www.ibm.com/developerworks/cn/java/j-jtp06197.html Java 理論與實踐: 正確使用 Volatile 變量
下面來看看java中具體的CAS操作類sun.misc.Unsafe。Unsafe類提供了硬件級別的原子操作,Java無法直接訪問到操作系統底層(如系統硬件等),爲此Java使用native方法來擴展Java程序的功能。具體實現使用c++,詳見文件sun.misc.natUnsafe.cc();sun.misc包的源代碼可以在這裏找到:
http://www.oschina.net/code/explore/gcc-4.5.2/libjava/sun/misc
複製代碼
//下面是sun.misc.Unsafe.java類源碼
package sun.misc;
import java.lang.reflect.Field;
/*
* This class should provide access to low-level operations and its
* use should be limited to trusted code. Fields can be accessed using
* memory addresses, with undefined behaviour occurring if invalid memory
* addresses are given.
* 這個類提供了一個更底層的操作並且應該在受信任的代碼中使用。可以通過內存地址
* 存取fields,如果給出的內存地址是無效的那麼會有一個不確定的運行表現。
*
* @author Tom Tromey ([email protected])
* @author Andrew John Hughes ([email protected])
*/
public class Unsafe
{
// Singleton class.
private static Unsafe unsafe = new Unsafe();
/*
* Private default constructor to prevent creation of an arbitrary
* number of instances.
* 使用私有默認構造器防止創建多個實例
*/
private Unsafe()
{
}
/*
* Retrieve the singleton instance of Unsafe. The calling
* method should guard this instance from untrusted code, as it provides
* access to low-level operations such as direct memory access.
* 獲取Unsafe的單例,這個方法調用應該防止在不可信的代碼中實例,
* 因爲unsafe類提供了一個低級別的操作,例如直接內存存取。
*
* @throws SecurityException if a security manager exists and prevents
* access to the system properties.
* 如果安全管理器不存在或者禁止訪問系統屬性
*/
public static Unsafe getUnsafe()
{
SecurityManager sm = System.getSecurityManager();
if (sm != null)
sm.checkPropertiesAccess();
return unsafe;
}
/*
* Returns the memory address offset of the given static field.
* The offset is merely used as a means to access a particular field
* in the other methods of this class. The value is unique to the given
* field and the same value should be returned on each subsequent call.
* 返回指定靜態field的內存地址偏移量,在這個類的其他方法中這個值只是被用作一個訪問
* 特定field的一個方式。這個值對於 給定的field是唯一的,並且後續對該方法的調用都應該
* 返回相同的值。
*
* @param field the field whose offset should be returned.
* 需要返回偏移量的field
* @return the offset of the given field.
* 指定field的偏移量
*/
public native long objectFieldOffset(Field field);
/*
* Compares the value of the integer field at the specified offset
* in the supplied object with the given expected value, and updates
* it if they match. The operation of this method should be atomic,
* thus providing an uninterruptible way of updating an integer field.
* 在obj的offset位置比較integer field和期望的值,如果相同則更新。這個方法
* 的操作應該是原子的,因此提供了一種不可中斷的方式更新integer field。
*
* @param obj the object containing the field to modify.
* 包含要修改field的對象
* @param offset the offset of the integer field within obj.
* obj中整型field的偏移量
* @param expect the expected value of the field.
* 希望field中存在的值
* @param update the new value of the field if it equals expect.
* 如果期望值expect與field的當前值相同,設置filed的值爲這個新值
* @return true if the field was changed.
* 如果field的值被更改
*/
public native boolean compareAndSwapInt(Object obj, long offset,
int expect, int update);
/*
* Compares the value of the long field at the specified offset
* in the supplied object with the given expected value, and updates
* it if they match. The operation of this method should be atomic,
* thus providing an uninterruptible way of updating a long field.
* 在obj的offset位置比較long field和期望的值,如果相同則更新。這個方法
* 的操作應該是原子的,因此提供了一種不可中斷的方式更新long field。
*
* @param obj the object containing the field to modify.
* 包含要修改field的對象
* @param offset the offset of the long field within obj.
* obj中long型field的偏移量
* @param expect the expected value of the field.
* 希望field中存在的值
* @param update the new value of the field if it equals expect.
* 如果期望值expect與field的當前值相同,設置filed的值爲這個新值
* @return true if the field was changed.
* 如果field的值被更改
*/
public native boolean compareAndSwapLong(Object obj, long offset,
long expect, long update);
/*
* Compares the value of the object field at the specified offset
* in the supplied object with the given expected value, and updates
* it if they match. The operation of this method should be atomic,
* thus providing an uninterruptible way of updating an object field.
* 在obj的offset位置比較object field和期望的值,如果相同則更新。這個方法
* 的操作應該是原子的,因此提供了一種不可中斷的方式更新object field。
*
* @param obj the object containing the field to modify.
* 包含要修改field的對象
* @param offset the offset of the object field within obj.
* obj中object型field的偏移量
* @param expect the expected value of the field.
* 希望field中存在的值
* @param update the new value of the field if it equals expect.
* 如果期望值expect與field的當前值相同,設置filed的值爲這個新值
* @return true if the field was changed.
* 如果field的值被更改
*/
public native boolean compareAndSwapObject(Object obj, long offset,
Object expect, Object update);
/*
* Sets the value of the integer field at the specified offset in the
* supplied object to the given value. This is an ordered or lazy
* version of putIntVolatile(Object,long,int), which
* doesn’t guarantee the immediate visibility of the change to other
* threads. It is only really useful where the integer field is
* volatile, and is thus expected to change unexpectedly.
* 設置obj對象中offset偏移地址對應的整型field的值爲指定值。這是一個有序或者
* 有延遲的putIntVolatile方法,並且不保證值的改變被其他線程立
* 即看到。只有在field被volatile修飾並且期望被意外修改的時候
* 使用纔有用。
*
* @param obj the object containing the field to modify.
* 包含需要修改field的對象
* @param offset the offset of the integer field within obj.
* obj中整型field的偏移量
* @param value the new value of the field.
* field將被設置的新值
* @see #putIntVolatile(Object,long,int)
*/
public native void putOrderedInt(Object obj, long offset, int value);
/*
* Sets the value of the long field at the specified offset in the
* supplied object to the given value. This is an ordered or lazy
* version of putLongVolatile(Object,long,long), which
* doesn’t guarantee the immediate visibility of the change to other
* threads. It is only really useful where the long field is
* volatile, and is thus expected to change unexpectedly.
* 設置obj對象中offset偏移地址對應的long型field的值爲指定值。這是一個有序或者
* 有延遲的putLongVolatile方法,並且不保證值的改變被其他線程立
* 即看到。只有在field被volatile修飾並且期望被意外修改的時候
* 使用纔有用。
*
* @param obj the object containing the field to modify.
* 包含需要修改field的對象
* @param offset the offset of the long field within obj.
* obj中long型field的偏移量
* @param value the new value of the field.
* field將被設置的新值
* @see #putLongVolatile(Object,long,long)
*/
public native void putOrderedLong(Object obj, long offset, long value);
/*
* Sets the value of the object field at the specified offset in the
* supplied object to the given value. This is an ordered or lazy
* version of putObjectVolatile(Object,long,Object), which
* doesn’t guarantee the immediate visibility of the change to other
* threads. It is only really useful where the object field is
* volatile, and is thus expected to change unexpectedly.
* 設置obj對象中offset偏移地址對應的object型field的值爲指定值。這是一個有序或者
* 有延遲的putObjectVolatile方法,並且不保證值的改變被其他線程立
* 即看到。只有在field被volatile修飾並且期望被意外修改的時候
* 使用纔有用。
*
* @param obj the object containing the field to modify.
* 包含需要修改field的對象
* @param offset the offset of the object field within obj.
* obj中long型field的偏移量
* @param value the new value of the field.
* field將被設置的新值
*/
public native void putOrderedObject(Object obj, long offset, Object value);
/*
* Sets the value of the integer field at the specified offset in the
* supplied object to the given value, with volatile store semantics.
* 設置obj對象中offset偏移地址對應的整型field的值爲指定值。支持volatile store語義
*
* @param obj the object containing the field to modify.
* 包含需要修改field的對象
* @param offset the offset of the integer field within obj.
* obj中整型field的偏移量
* @param value the new value of the field.
* field將被設置的新值
*/
public native void putIntVolatile(Object obj, long offset, int value);
/*
* Retrieves the value of the integer field at the specified offset in the
* supplied object with volatile load semantics.
* 獲取obj對象中offset偏移地址對應的整型field的值,支持volatile load語義。
*
* @param obj the object containing the field to read.
* 包含需要去讀取的field的對象
* @param offset the offset of the integer field within obj.
* obj中整型field的偏移量
*/
public native int getIntVolatile(Object obj, long offset);
/*
* Sets the value of the long field at the specified offset in the
* supplied object to the given value, with volatile store semantics.
* 設置obj對象中offset偏移地址對應的long型field的值爲指定值。支持volatile store語義
*
* @param obj the object containing the field to modify.
* 包含需要修改field的對象
* @param offset the offset of the long field within obj.
* obj中long型field的偏移量
* @param value the new value of the field.
* field將被設置的新值
* @see #putLong(Object,long,long)
*/
public native void putLongVolatile(Object obj, long offset, long value);
/*
* Sets the value of the long field at the specified offset in the
* supplied object to the given value.
* 設置obj對象中offset偏移地址對應的long型field的值爲指定值。
*
* @param obj the object containing the field to modify.
* 包含需要修改field的對象
* @param offset the offset of the long field within obj.
* obj中long型field的偏移量
* @param value the new value of the field.
* field將被設置的新值
* @see #putLongVolatile(Object,long,long)
*/
public native void putLong(Object obj, long offset, long value);
/*
* Retrieves the value of the long field at the specified offset in the
* supplied object with volatile load semantics.
* 獲取obj對象中offset偏移地址對應的long型field的值,支持volatile load語義。
*
* @param obj the object containing the field to read.
* 包含需要去讀取的field的對象
* @param offset the offset of the long field within obj.
* obj中long型field的偏移量
* @see #getLong(Object,long)
*/
public native long getLongVolatile(Object obj, long offset);
/*
* Retrieves the value of the long field at the specified offset in the
* supplied object.
* 獲取obj對象中offset偏移地址對應的long型field的值
*
* @param obj the object containing the field to read.
* 包含需要去讀取的field的對象
* @param offset the offset of the long field within obj.
* obj中long型field的偏移量
* @see #getLongVolatile(Object,long)
*/
public native long getLong(Object obj, long offset);
/*
* Sets the value of the object field at the specified offset in the
* supplied object to the given value, with volatile store semantics.
* 設置obj對象中offset偏移地址對應的object型field的值爲指定值。支持volatile store語義
*
* @param obj the object containing the field to modify.
* 包含需要修改field的對象
* @param offset the offset of the object field within obj.
* obj中object型field的偏移量
* @param value the new value of the field.
* field將被設置的新值
* @see #putObject(Object,long,Object)
*/
public native void putObjectVolatile(Object obj, long offset, Object value);
/*
* Sets the value of the object field at the specified offset in the
* supplied object to the given value.
* 設置obj對象中offset偏移地址對應的object型field的值爲指定值。
*
* @param obj the object containing the field to modify.
* 包含需要修改field的對象
* @param offset the offset of the object field within obj.
* obj中object型field的偏移量
* @param value the new value of the field.
* field將被設置的新值
* @see #putObjectVolatile(Object,long,Object)
*/
public native void putObject(Object obj, long offset, Object value);
/*
* Retrieves the value of the object field at the specified offset in the
* supplied object with volatile load semantics.
* 獲取obj對象中offset偏移地址對應的object型field的值,支持volatile load語義。
*
* @param obj the object containing the field to read.
* 包含需要去讀取的field的對象
* @param offset the offset of the object field within obj.
* obj中object型field的偏移量
*/
public native Object getObjectVolatile(Object obj, long offset);
/*
* Returns the offset of the first element for a given array class.
* To access elements of the array class, this value may be used along with
* with that returned by
* arrayIndexScale,
* if non-zero.
* 獲取給定數組中第一個元素的偏移地址。
* 爲了存取數組中的元素,這個偏移地址與arrayIndexScale 方法的非0返回值一起被使用。
*
* @param arrayClass the class for which the first element’s address should
* be obtained.
* 第一個元素地址被獲取的class
* @return the offset of the first element of the array class.
* 數組第一個元素 的偏移地址
* @see arrayIndexScale(Class)
*/
public native int arrayBaseOffset(Class arrayClass);
/*
* Returns the scale factor used for addressing elements of the supplied
* array class. Where a suitable scale factor can not be returned (e.g.
* for primitive types), zero should be returned. The returned value
* can be used with
* arrayBaseOffset
* to access elements of the class.
* 獲取用戶給定數組尋址的換算因子.一個合適的換算因子不能返回的時候(例如:基本類型),
* 返回0.這個返回值能夠與arrayBaseOffset
* 一起使用去存取這個數組class中的元素
*
* @param arrayClass the class whose scale factor should be returned.
* @return the scale factor, or zero if not supported for this array class.
*/
public native int arrayIndexScale(Class arrayClass);
/*
* Releases the block on a thread created by
* park. This method can also be used
* to terminate a blockage caused by a prior call to park.
* This operation is unsafe, as the thread must be guaranteed to be
* live. This is true of Java, but not native code.
* 釋放被park創建的在一個線程上的阻塞.這個
* 方法也可以被使用來終止一個先前調用park導致的阻塞.
* 這個操作操作時不安全的,因此線程必須保證是活的.這是java代碼不是native代碼。
* @param thread the thread to unblock.
* 要解除阻塞的線程
*/
public native void unpark(Thread thread);
/*
* Blocks the thread until a matching
* unpark occurs, the thread is
* interrupted or the optional timeout expires. If an unpark
* call has already occurred, this also counts. A timeout value of zero
* is defined as no timeout. When isAbsolute is
* true, the timeout is in milliseconds relative to the
* epoch. Otherwise, the value is the number of nanoseconds which must
* occur before timeout. This call may also return spuriously (i.e.
* for no apparent reason).
* 阻塞一個線程直到unpark出現、線程
* 被中斷或者timeout時間到期。如果一個unpark調用已經出現了,
* 這裏只計數。timeout爲0表示永不過期.當isAbsolute爲true時,
* timeout是相對於新紀元之後的毫秒。否則這個值就是超時前的納秒數。這個方法執行時
* 也可能不合理地返回(沒有具體原因)
*
* @param isAbsolute true if the timeout is specified in milliseconds from
* the epoch.
* 如果爲true timeout的值是一個相對於新紀元之後的毫秒數
* @param time either the number of nanoseconds to wait, or a time in
* milliseconds from the epoch to wait for.
* 可以是一個要等待的納秒數,或者是一個相對於新紀元之後的毫秒數直到
* 到達這個時間點
*/
public native void park(boolean isAbsolute, long time);
}
複製代碼
注:轉自http://blog.csdn.net/zgmzyr/article/details/8902683
下面這個例子演示了簡單的修改一個byte[]的數據。
這個例子在eclipse裏不能直接編譯,要到項目的屬性,Java Compiler,Errors/Warnings中Forbidden reference(access rules)中設置爲warning。
另外,因爲sun.misc.Unsafe包不能直接使用,所有代碼裏用反射的技巧得到了一個Unsafe的實例。
複製代碼
import java.lang.reflect.Field;
import java.util.Arrays;
import sun.misc.Unsafe;
public class Test {
private static int byteArrayBaseOffset;
public static void main(String[] args) throws SecurityException,
NoSuchFieldException, IllegalArgumentException,
IllegalAccessException {
Field theUnsafe = Unsafe.class.getDeclaredField("theUnsafe");
theUnsafe.setAccessible(true);
Unsafe UNSAFE = (Unsafe) theUnsafe.get(null);
System.out.println(UNSAFE);
byte[] data = new byte[10];
System.out.println(Arrays.toString(data));
byteArrayBaseOffset = UNSAFE.arrayBaseOffset(byte[].class);
System.out.println(byteArrayBaseOffset);
UNSAFE.putByte(data, byteArrayBaseOffset, (byte) 1);
UNSAFE.putByte(data, byteArrayBaseOffset + 5, (byte) 5);
System.out.println(Arrays.toString(data));
}
}
複製代碼
運行結果:
sun.misc.Unsafe@6af62373
[0, 0, 0, 0, 0, 0, 0, 0, 0, 0]
24
[1, 0, 0, 0, 0, 5, 0, 0, 0, 0]
注:轉自http://blog.csdn.net/hengyunabc/article/details/7657934
以下爲Unsafe類涉及到的源碼:
natUnsafe.cc
Service.h
ServiceConfigurationError.h
Unsafe.h
Unsafe.java
複製代碼
/** Unsafe.java - Unsafe operations needed for concurrency
Copyright (C) 2006 Free Software Foundation
This file is part of GNU Classpath.
GNU Classpath is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 2, or (at your option)
any later version.
GNU Classpath 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 for more details.
You should have received a copy of the GNU General Public License
along with GNU Classpath; see the file COPYING. If not, write to the
Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA
02110-1301 USA.
Linking this library statically or dynamically with other modules is
making a combined work based on this library. Thus, the terms and
conditions of the GNU General Public License cover the whole
combination.
As a special exception, the copyright holders of this library give you
permission to link this library with independent modules to produce an
executable, regardless of the license terms of these independent
modules, and to copy and distribute the resulting executable under
terms of your choice, provided that you also meet, for each linked
independent module, the terms and conditions of the license of that
module. An independent module is a module which is not derived from
or based on this library. If you modify this library, you may extend
this exception to your version of the library, but you are not
obligated to do so. If you do not wish to do so, delete this
exception statement from your version. */
package sun.misc;
import java.lang.reflect.Field;
/*
* This class should provide access to low-level operations and its
* use should be limited to trusted code. Fields can be accessed using
* memory addresses, with undefined behaviour occurring if invalid memory
* addresses are given.
*
* @author Tom Tromey ([email protected])
* @author Andrew John Hughes ([email protected])
*/
public class Unsafe
{
// Singleton class.
private static Unsafe unsafe = new Unsafe();
/*
* Private default constructor to prevent creation of an arbitrary
* number of instances.
*/
private Unsafe()
{
}
/*
* Retrieve the singleton instance of Unsafe. The calling
* method should guard this instance from untrusted code, as it provides
* access to low-level operations such as direct memory access.
*
* @throws SecurityException if a security manager exists and prevents
* access to the system properties.
*/
public static Unsafe getUnsafe()
{
SecurityManager sm = System.getSecurityManager();
if (sm != null)
sm.checkPropertiesAccess();
return unsafe;
}
/*
* Returns the memory address offset of the given static field.
* The offset is merely used as a means to access a particular field
* in the other methods of this class. The value is unique to the given
* field and the same value should be returned on each subsequent call.
*
* @param field the field whose offset should be returned.
* @return the offset of the given field.
*/
public native long objectFieldOffset(Field field);
/*
* Compares the value of the integer field at the specified offset
* in the supplied object with the given expected value, and updates
* it if they match. The operation of this method should be atomic,
* thus providing an uninterruptible way of updating an integer field.
*
* @param obj the object containing the field to modify.
* @param offset the offset of the integer field within obj.
* @param expect the expected value of the field.
* @param update the new value of the field if it equals expect.
* @return true if the field was changed.
*/
public native boolean compareAndSwapInt(Object obj, long offset,
int expect, int update);
/*
* Compares the value of the long field at the specified offset
* in the supplied object with the given expected value, and updates
* it if they match. The operation of this method should be atomic,
* thus providing an uninterruptible way of updating a long field.
*
* @param obj the object containing the field to modify.
* @param offset the offset of the long field within obj.
* @param expect the expected value of the field.
* @param update the new value of the field if it equals expect.
* @return true if the field was changed.
*/
public native boolean compareAndSwapLong(Object obj, long offset,
long expect, long update);
/*
* Compares the value of the object field at the specified offset
* in the supplied object with the given expected value, and updates
* it if they match. The operation of this method should be atomic,
* thus providing an uninterruptible way of updating an object field.
*
* @param obj the object containing the field to modify.
* @param offset the offset of the object field within obj.
* @param expect the expected value of the field.
* @param update the new value of the field if it equals expect.
* @return true if the field was changed.
*/
public native boolean compareAndSwapObject(Object obj, long offset,
Object expect, Object update);
/*
* Sets the value of the integer field at the specified offset in the
* supplied object to the given value. This is an ordered or lazy
* version of putIntVolatile(Object,long,int), which
* doesn’t guarantee the immediate visibility of the change to other
* threads. It is only really useful where the integer field is
* volatile, and is thus expected to change unexpectedly.
*
* @param obj the object containing the field to modify.
* @param offset the offset of the integer field within obj.
* @param value the new value of the field.
* @see #putIntVolatile(Object,long,int)
*/
public native void putOrderedInt(Object obj, long offset, int value);
/*
* Sets the value of the long field at the specified offset in the
* supplied object to the given value. This is an ordered or lazy
* version of putLongVolatile(Object,long,long), which
* doesn’t guarantee the immediate visibility of the change to other
* threads. It is only really useful where the long field is
* volatile, and is thus expected to change unexpectedly.
*
* @param obj the object containing the field to modify.
* @param offset the offset of the long field within obj.
* @param value the new value of the field.
* @see #putLongVolatile(Object,long,long)
*/
public native void putOrderedLong(Object obj, long offset, long value);
/*
* Sets the value of the object field at the specified offset in the
* supplied object to the given value. This is an ordered or lazy
* version of putObjectVolatile(Object,long,Object), which
* doesn’t guarantee the immediate visibility of the change to other
* threads. It is only really useful where the object field is
* volatile, and is thus expected to change unexpectedly.
*
* @param obj the object containing the field to modify.
* @param offset the offset of the object field within obj.
* @param value the new value of the field.
*/
public native void putOrderedObject(Object obj, long offset, Object value);
/*
* Sets the value of the integer field at the specified offset in the
* supplied object to the given value, with volatile store semantics.
*
* @param obj the object containing the field to modify.
* @param offset the offset of the integer field within obj.
* @param value the new value of the field.
*/
public native void putIntVolatile(Object obj, long offset, int value);
/*
* Retrieves the value of the integer field at the specified offset in the
* supplied object with volatile load semantics.
*
* @param obj the object containing the field to read.
* @param offset the offset of the integer field within obj.
*/
public native int getIntVolatile(Object obj, long offset);
/*
* Sets the value of the long field at the specified offset in the
* supplied object to the given value, with volatile store semantics.
*
* @param obj the object containing the field to modify.
* @param offset the offset of the long field within obj.
* @param value the new value of the field.
* @see #putLong(Object,long,long)
*/
public native void putLongVolatile(Object obj, long offset, long value);
/*
* Sets the value of the long field at the specified offset in the
* supplied object to the given value.
*
* @param obj the object containing the field to modify.
* @param offset the offset of the long field within obj.
* @param value the new value of the field.
* @see #putLongVolatile(Object,long,long)
*/
public native void putLong(Object obj, long offset, long value);
/*
* Retrieves the value of the long field at the specified offset in the
* supplied object with volatile load semantics.
*
* @param obj the object containing the field to read.
* @param offset the offset of the long field within obj.
* @see #getLong(Object,long)
*/
public native long getLongVolatile(Object obj, long offset);
/*
* Retrieves the value of the long field at the specified offset in the
* supplied object.
*
* @param obj the object containing the field to read.
* @param offset the offset of the long field within obj.
* @see #getLongVolatile(Object,long)
*/
public native long getLong(Object obj, long offset);
/*
* Sets the value of the object field at the specified offset in the
* supplied object to the given value, with volatile store semantics.
*
* @param obj the object containing the field to modify.
* @param offset the offset of the object field within obj.
* @param value the new value of the field.
* @see #putObject(Object,long,Object)
*/
public native void putObjectVolatile(Object obj, long offset, Object value);
/*
* Sets the value of the object field at the specified offset in the
* supplied object to the given value.
*
* @param obj the object containing the field to modify.
* @param offset the offset of the object field within obj.
* @param value the new value of the field.
* @see #putObjectVolatile(Object,long,Object)
*/
public native void putObject(Object obj, long offset, Object value);
/*
* Retrieves the value of the object field at the specified offset in the
* supplied object with volatile load semantics.
*
* @param obj the object containing the field to read.
* @param offset the offset of the object field within obj.
*/
public native Object getObjectVolatile(Object obj, long offset);
/*
* Returns the offset of the first element for a given array class.
* To access elements of the array class, this value may be used along
* with that returned by
* arrayIndexScale,
* if non-zero.
*
* @param arrayClass the class for which the first element’s address should
* be obtained.
* @return the offset of the first element of the array class.
* @see arrayIndexScale(Class)
*/
public native int arrayBaseOffset(Class arrayClass);
/*
* Returns the scale factor used for addressing elements of the supplied
* array class. Where a suitable scale factor can not be returned (e.g.
* for primitive types), zero should be returned. The returned value
* can be used with
* arrayBaseOffset
* to access elements of the class.
*
* @param arrayClass the class whose scale factor should be returned.
* @return the scale factor, or zero if not supported for this array class.
*/
public native int arrayIndexScale(Class arrayClass);
/*
* Releases the block on a thread created by
* park. This method can also be used
* to terminate a blockage caused by a prior call to park.
* This operation is unsafe, as the thread must be guaranteed to be
* live. This is true of Java, but not native code.
*
* @param thread the thread to unblock.
*/
public native void unpark(Thread thread);
/*
* Blocks the thread until a matching
* unpark occurs, the thread is
* interrupted or the optional timeout expires. If an unpark
* call has already occurred, this also counts. A timeout value of zero
* is defined as no timeout. When isAbsolute is
* true, the timeout is in milliseconds relative to the
* epoch. Otherwise, the value is the number of nanoseconds which must
* occur before timeout. This call may also return spuriously (i.e.
* for no apparent reason).
*
* @param isAbsolute true if the timeout is specified in milliseconds from
* the epoch.
* @param time either the number of nanoseconds to wait, or a time in
* milliseconds from the epoch to wait for.
*/
public native void park(boolean isAbsolute, long time);
}
複製代碼
Unsafe.h
複製代碼
// DO NOT EDIT THIS FILE - it is machine generated -- c++ --
ifndef sun_misc_Unsafe
define sun_misc_Unsafe
pragma interface
include
endif // sun_misc_Unsafe
複製代碼
ServiceConfigurationError.h
複製代碼
// DO NOT EDIT THIS FILE - it is machine generated -- c++ --
ifndef sun_misc_ServiceConfigurationError
define sun_misc_ServiceConfigurationError
pragma interface
include
endif // sun_misc_ServiceConfigurationError
複製代碼
Service.h
複製代碼
// DO NOT EDIT THIS FILE - it is machine generated -- c++ --
ifndef sun_misc_Service
define sun_misc_Service
pragma interface
include
endif // sun_misc_Service
複製代碼
natUnsafe.cc
複製代碼
// natUnsafe.cc - Implementation of sun.misc.Unsafe native methods.
/** Copyright (C) 2006, 2007
Free Software Foundation
This file is part of libgcj.
This software is copyrighted work licensed under the terms of the
Libgcj License. Please consult the file “LIBGCJ_LICENSE” for
details. */
include
include
include
include
include
include
include
include
include
include “sysdep/locks.h”
// Use a spinlock for multi-word accesses
class spinlock
{
static volatile obj_addr_t lock;
public:
spinlock ()
{
while (! compare_and_swap (&lock, 0, 1))
_Jv_ThreadYield ();
}
~spinlock ()
{
release_set (&lock, 0);
}
};
// This is a single lock that is used for all synchronized accesses if
// the compiler can’t generate inline compare-and-swap operations. In
// most cases it’ll never be used, but the i386 needs it for 64-bit
// locked accesses and so does PPC32. It’s worth building libgcj with
// target=i486 (or above) to get the inlines.
volatile obj_addr_t spinlock::lock;
static inline bool
compareAndSwap (volatile jint *addr, jint old, jint new_val)
{
jboolean result = false;
spinlock lock;
if ((result = (*addr == old)))
*addr = new_val;
return result;
}
static inline bool
compareAndSwap (volatile jlong *addr, jlong old, jlong new_val)
{
jboolean result = false;
spinlock lock;
if ((result = (*addr == old)))
*addr = new_val;
return result;
}
static inline bool
compareAndSwap (volatile jobject *addr, jobject old, jobject new_val)
{
jboolean result = false;
spinlock lock;
if ((result = (*addr == old)))
*addr = new_val;
return result;
}
jlong
sun::misc::Unsafe::objectFieldOffset (::java::lang::reflect::Field *field)
{
_Jv_Field *fld = _Jv_FromReflectedField (field);
// FIXME: what if it is not an instance field?
return fld->getOffset();
}
jint
sun::misc::Unsafe::arrayBaseOffset (jclass arrayClass)
{
// FIXME: assert that arrayClass is array.
jclass eltClass = arrayClass->getComponentType();
return (jint)(jlong) _Jv_GetArrayElementFromElementType (NULL, eltClass);
}
jint
sun::misc::Unsafe::arrayIndexScale (jclass arrayClass)
{
// FIXME: assert that arrayClass is array.
jclass eltClass = arrayClass->getComponentType();
if (eltClass->isPrimitive())
return eltClass->size();
return sizeof (void *);
}
// These methods are used when the compiler fails to generate inline
// versions of the compare-and-swap primitives.
jboolean
sun::misc::Unsafe::compareAndSwapInt (jobject obj, jlong offset,
jint expect, jint update)
{
jint addr = (jint )((char *)obj + offset);
return compareAndSwap (addr, expect, update);
}
jboolean
sun::misc::Unsafe::compareAndSwapLong (jobject obj, jlong offset,
jlong expect, jlong update)
{
volatile jlong addr = (jlong)((char *) obj + offset);
return compareAndSwap (addr, expect, update);
}
jboolean
sun::misc::Unsafe::compareAndSwapObject (jobject obj, jlong offset,
jobject expect, jobject update)
{
jobject addr = (jobject)((char *) obj + offset);
return compareAndSwap (addr, expect, update);
}
void
sun::misc::Unsafe::putOrderedInt (jobject obj, jlong offset, jint value)
{
volatile jint addr = (jint ) ((char *) obj + offset);
*addr = value;
}
void
sun::misc::Unsafe::putOrderedLong (jobject obj, jlong offset, jlong value)
{
volatile jlong addr = (jlong ) ((char *) obj + offset);
spinlock lock;
*addr = value;
}
void
sun::misc::Unsafe::putOrderedObject (jobject obj, jlong offset, jobject value)
{
volatile jobject addr = (jobject ) ((char *) obj + offset);
*addr = value;
}
void
sun::misc::Unsafe::putIntVolatile (jobject obj, jlong offset, jint value)
{
write_barrier ();
volatile jint addr = (jint ) ((char *) obj + offset);
*addr = value;
}
void
sun::misc::Unsafe::putLongVolatile (jobject obj, jlong offset, jlong value)
{
volatile jlong addr = (jlong ) ((char *) obj + offset);
spinlock lock;
*addr = value;
}
void
sun::misc::Unsafe::putObjectVolatile (jobject obj, jlong offset, jobject value)
{
write_barrier ();
volatile jobject addr = (jobject ) ((char *) obj + offset);
*addr = value;
}
if 0 // FIXME
void
sun::misc::Unsafe::putInt (jobject obj, jlong offset, jint value)
{
jint addr = (jint ) ((char *) obj + offset);
*addr = value;
}
endif
void
sun::misc::Unsafe::putLong (jobject obj, jlong offset, jlong value)
{
jlong addr = (jlong ) ((char *) obj + offset);
spinlock lock;
*addr = value;
}
void
sun::misc::Unsafe::putObject (jobject obj, jlong offset, jobject value)
{
jobject addr = (jobject ) ((char *) obj + offset);
*addr = value;
}
jint
sun::misc::Unsafe::getIntVolatile (jobject obj, jlong offset)
{
volatile jint addr = (jint ) ((char *) obj + offset);
jint result = *addr;
read_barrier ();
return result;
}
jobject
sun::misc::Unsafe::getObjectVolatile (jobject obj, jlong offset)
{
volatile jobject addr = (jobject ) ((char *) obj + offset);
jobject result = *addr;
read_barrier ();
return result;
}
jlong
sun::misc::Unsafe::getLong (jobject obj, jlong offset)
{
jlong addr = (jlong ) ((char *) obj + offset);
spinlock lock;
return *addr;
}
jlong
sun::misc::Unsafe::getLongVolatile (jobject obj, jlong offset)
{
volatile jlong addr = (jlong ) ((char *) obj + offset);
spinlock lock;
return *addr;
}
void
sun::misc::Unsafe::unpark (::java::lang::Thread *thread)
{
natThread nt = (natThread ) thread->data;
nt->park_helper.unpark ();
}
void
sun::misc::Unsafe::park (jboolean isAbsolute, jlong time)
{
using namespace ::java::lang;
Thread *thread = Thread::currentThread();
natThread nt = (natThread ) thread->data;
nt->park_helper.park (isAbsolute, time);
}
