First let’s take a look at the non-thread-safe initialization singleton mode
public class UnsafeLazyInitialization { private static UnsafeLazyInitialization instance; public static UnsafeLazyInitialization getInstance(){ if(instance == null){ //1: 线程A执行 instance = new UnsafeLazyInitialization(); //2: 线程B执行 } return instance; } }
In the UnsafeLazyInitialization class, assume that when thread A executes code 1, thread B When code 2 is executed, thread A may see that the instance reference object has not yet been initialized.
For the UnsafeLazyInitialization class, we can synchronize the getInstance() method to achieve thread-safe delayed initialization. The sample code is as follows:
public static synchronized UnsafeLazyInitialization getInstance(){ if(instance == null){ //1: 线程A执行 instance = new UnsafeLazyInitialization(); //2: 线程B执行 } return instance; } }
Because the above code does the getInstance() method Without synchronization processing, this may lead to increased synchronization program overhead. If getInstance() is frequently called by multiple threads, the program execution performance will be reduced. On the contrary, if it is not called by multiple threads, the delayed initialization method of the getInstance() method will affect performance.
Before JVM 1.6, synchronized was a heavyweight lock, so it was very performance-consuming, so people thought of a double-check locking (Dobule-check Locking) solution to improve performance. The sample code is as follows:
public class DoubleCheckedLocking { //1、 private static Instance instance; //2、 public static Instance getInstance(){ //3、 if(instance == null){ //4、第一次检查 synchronized (DoubleCheckedLocking.class){ //5、枷锁 if(instance == null){ //6、第二次检查 instance = new Instance(); //7、问题的根源在这里 } //8、 } } return instance; } }
As shown in the above code: If the first check instance in step 4 is not null, there is no need to perform the following locking operation, which greatly reduces the performance problems caused by synchronized locks. There seems to be no problem with the above code. 1. When multiple thread views create new objects, the synchronized keyword can be used to ensure that only one thread successfully creates the object.
2. If the instance object has been created, obtain the object instance directly through the getInstatnce() method.
The above code looks perfect, but when step 4 is executed, instatnce! =null, the reference object of instatnce may not be initialized yet.
When we execute the above code to step 7, instance = new Instance();, an object is created. The steps to create an object can be divided into three steps, as follows :
memory = allocate() //1.分配内存空间memory ctorInstance(memory) //2, 初始化对象在内存 分配内存空间memory上初始化 Singleton 对象 instance = memory //3、设置 instance 指向刚分配的内存地址memory
The above three lines of code 2 and 3 may be reordered. (On the JTI compiler, this reordering really happens) The execution sequence after the reordering of steps 2 and 3
memory = allocate() //1.分配内存空间memory instance = memory //3、设置 instance 指向刚分配的内存地址memory // 注意此时instance对象还没有被初始化,但是instance的引用已经不是null了。 ctorInstance(memory) //2, 初始化对象在内存 分配内存空间memory上初始化 Singleton 对象
Let’s take a look at the multi-thread execution sequence
##Line 7 of the above code instance = new Instance(); If thread A If instruction reordering (2,3) occurs, then another thread B may determine that instance is not empty in line 4 of code. Thread B next accesses the reference object of instance, but the instance object may not have been initialized by A. At this time, thread B may access an object that has not been initialized, resulting in a null pointer error. Problem Solution1. Instructions 2 and 3 are not allowed to be rearranged. 2. Allow 2 and 3 to be reordered, but do not allow other threads to see the reorderingvolatile-based solutionBased on the above code, you only need to add the volatile keyword to the instance statement That’s it, the following codepublic class DoubleCheckedLocking { //1、 private static volatile Instance instance; //2、 public static Instance getInstance(){ //3、 if(instance == null){ //4、第一次检查 synchronized (DoubleCheckedLocking.class){ //5、枷锁 if(instance == null){ //6、第二次检查 instance = new Instance(); //7、问题的根源在这里 } //8、 } } return instance; } }
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