ThreadLocal原理分析与代码验证

2019-11-23  本文已影响0人  明年我18

ThreadLocal提供了线程安全的数据存储和访问方式,利用不带key的get和set方法,居然能做到线程之间隔离,非常神奇。

比如

ThreadLocal<String> threadLocal = new ThreadLocal<>();

in thread 1

//in thread1
treadLocal.set("value1");
.....
//value的值是value1
String value = threadLocal.get();

in thread 2

//in thread2
treadLocal.set("value2");
.....
//value的值是value2
String value = threadLocal.get();

不论thread1和thread2是不是同时执行,都不会有线程安全问题,我们来测试一下。

线程安全测试

开10个线程,每个线程内都对同一个ThreadLocal对象set不同的值,会发现ThreadLocal在每个线程内部get出来的值,只会是自己线程内set进去的值,不会被别的线程影响。

static void testUsage() throws InterruptedException {
    Utils.println("-------------testUsage-------------------");
    ThreadLocal<Long> threadLocal = new ThreadLocal<>();

    AtomicBoolean threadSafe = new AtomicBoolean(true);
    int count = 10;
    CountDownLatch countDownLatch = new CountDownLatch(count);
    Random random = new Random(736832);
    for (int i = 0; i < count; i ++){
        new Thread(() -> {
            try {
                //生成一个随机数
                Long value = System.nanoTime() + random.nextInt();
                threadLocal.set(value);
                Thread.sleep(1000);

                Long value2 = threadLocal.get();
                if (!value.equals(value2)) {
                    //get和set的value不一致,说明被别的线程修改了,但这是不可能出现的
                    threadSafe.set(false);
                    Utils.println("thread unsafe, this could not be happen!");
                }
            } catch (InterruptedException e) {

            }finally {
                countDownLatch.countDown();
            }

        }).start();
    }

    countDownLatch.await();

    Utils.println("all thread done, and threadSafe is " + threadSafe.get());
    Utils.println("------------------------------------------");
}

输出:

-------------testUsage------------------
all thread done, and threadSafe is true
-----------------------------------------

原理浅析

翻开ThreadLocal的源码,会发现ThreadLocal只是一个空壳子,它并不存储具体的value,而是利用当前线程(Thread.currentThread())的threadLocalMap来存储value,key就是这个threadLocal对象本身。

public void set(T value) {
    Thread t = Thread.currentThread();
    ThreadLocalMap map = getMap(t);
    if (map != null)
        map.set(this, value);
    else
        createMap(t, value);
}

ThreadLocalMap getMap(Thread t) {
    return t.threadLocals;
}

Thread的threadLocals字段是ThreadLocalMap类型(你可以简单理解为一个key value的Map),key是ThreadLocal对象,value是我们在外层设置的值

这就相当于:

Thread.currentThread().threadLocals.set(threadLocal1, "value1");
.....
//value的值是value1
String value = Thread.currentThread().threadLocals.get(threadLocal1);

因为每个Thread都是不同的对象,所以他们的threadLocals也是不同的map,threadLocal在不同的线程里工作时,实际上是从不同的map里get/set,这也就是线程安全的原因了,了解到这一点就差不多了。

再深入一些,ThreadLocalMap的结构

如果继续翻ThreadLocalMap的源码,会发现它有个字段table,是Entry类型的数组。

我们不妨写段代码,把ThreadLocalMap的结构输出出来。

由于Thread.threadLocals和ThreadLocalMap类不是public的,我们只有通过反射来获取它的值。反射的代码如下(如果嫌长可以不看,直接看输出):

static Object getThreadLocalMap(Thread thread) throws NoSuchFieldException, IllegalAccessException {        
    //get thread.threadLocals
    Field threadLocals = Thread.class.getDeclaredField("threadLocals");
    threadLocals.setAccessible(true);
    return threadLocals.get(thread);
}

static void printThreadLocalMap(Object threadLocalMap) throws NoSuchFieldException, IllegalAccessException {
    String threadName = Thread.currentThread().getName();
    
    if(threadLocalMap == null){
        Utils.println("threadMap is null, threadName:" + threadName);
        return;
    }

    Utils.println(threadName);

    //get threadLocalMap.table
    Field tableField = threadLocalMap.getClass().getDeclaredField("table");
    tableField.setAccessible(true);
    Object[] table = (Object[])tableField.get(threadLocalMap);
    Utils.println("----threadLocals (ThreadLocalMap), table.length = " + table.length);

    for (int i = 0; i < table.length; i ++){
        WeakReference<ThreadLocal<?>> entry = (WeakReference<ThreadLocal<?>>)table[i];
        printEntry(entry, i);
    }
}
static void printEntry(WeakReference<ThreadLocal<?>> entry, int i) throws NoSuchFieldException, IllegalAccessException {
    if(entry == null){
        Utils.println("--------table[" + i + "] -> null");
        return;
    }
    ThreadLocal key = entry.get();
    //get entry.value
    Field valueField = entry.getClass().getDeclaredField("value");
    valueField.setAccessible(true);
    Object value = valueField.get(entry);

    Utils.println("--------table[" + i + "] -> entry key = " + key + ", value = " + value);
}

测试代码:

static void testStructure() throws InterruptedException {
    Utils.println("-------------testStructure----------------");
    ThreadLocal<String> threadLocal1 = new ThreadLocal<>();
    ThreadLocal<String> threadLocal2 = new ThreadLocal<>();

    Thread thread1 = new Thread(() -> {
        threadLocal1.set("threadLocal1-value");
        threadLocal2.set("threadLocal2-value");

        try {
            Object threadLocalMap = getThreadLocalMap(Thread.currentThread());
            printThreadLocalMap(threadLocalMap);

        } catch (NoSuchFieldException | IllegalAccessException e) {
            e.printStackTrace();
        }

    }, "thread1");

    thread1.start();

    //wait thread1 done
    thread1.join();

    Thread thread2 = new Thread(() -> {
        threadLocal1.set("threadLocal1-value");
        try {
            Object threadLocalMap = getThreadLocalMap(Thread.currentThread());
            printThreadLocalMap(threadLocalMap);

        } catch (NoSuchFieldException | IllegalAccessException e) {
            e.printStackTrace();
        }

    }, "thread2");

    thread2.start();
    thread2.join();
    Utils.println("------------------------------------------");
}

我们在创建了两个ThreadLocal的对象threadLocal1和threadLocal2,在线程1里为这两个对象设置值,在线程2里只为threadLocal1设置值。然后分别打印出这两个线程的threadLocalMap。

输出结果为:

-------------testStructure----------------
thread1
----threadLocals (ThreadLocalMap), table.length = 16
--------table[0] -> null
--------table[1] -> entry key = java.lang.ThreadLocal@33baa315, value = threadLocal2-value
--------table[2] -> null
--------table[3] -> null
--------table[4] -> null
--------table[5] -> null
--------table[6] -> null
--------table[7] -> null
--------table[8] -> null
--------table[9] -> null
--------table[10] -> entry key = java.lang.ThreadLocal@4d42db5c, value = threadLocal1-value
--------table[11] -> null
--------table[12] -> null
--------table[13] -> null
--------table[14] -> null
--------table[15] -> null
thread2
----threadLocals (ThreadLocalMap), table.length = 16
--------table[0] -> null
--------table[1] -> null
--------table[2] -> null
--------table[3] -> null
--------table[4] -> null
--------table[5] -> null
--------table[6] -> null
--------table[7] -> null
--------table[8] -> null
--------table[9] -> null
--------table[10] -> entry key = java.lang.ThreadLocal@4d42db5c, value = threadLocal1-value
--------table[11] -> null
--------table[12] -> null
--------table[13] -> null
--------table[14] -> null
--------table[15] -> null
------------------------------------------

从结果上可以看出:

为什么是WeakReference

查看Entry的源码,会发现Entry继承自WeakReference:

static class Entry extends WeakReference<ThreadLocal<?>> {
    /** The value associated with this ThreadLocal. */
    Object value;

    Entry(ThreadLocal<?> k, Object v) {
        super(k);
        value = v;
    }
}

构造函数里把key传给了super,也就是说,ThreadLocalMap中对key的引用,是WeakReference的。

Weak reference objects, which do not prevent their referents from being
made finalizable, finalized, and then reclaimed. Weak references are most
often used to implement canonicalizing mappings.

通俗点解释:

当一个对象仅仅被weak reference(弱引用), 而没有任何其他strong reference(强引用)的时候, 不论当前的内存空间是否足够,当GC运行的时候, 这个对象就会被回收。

看不明白没关系,还是写代码测试一下什么是WeakReference吧...

static void testWeakReference(){
    Object obj1 = new Object();
    Object obj2 = new Object();
    WeakReference<Object> obj1WeakRef = new WeakReference<>(obj1);
    WeakReference<Object> obj2WeakRf = new WeakReference<>(obj2);
    //obj32StrongRef是强引用
    Object obj2StrongRef = obj2;
    Utils.println("before gc: obj1WeakRef = " + obj1WeakRef.get() + ", obj2WeakRef = " + obj2WeakRf.get() + ", obj2StrongRef = " + obj2StrongRef);

    //把obj1和obj2设为null
    obj1 = null;
    obj2 = null;
    //强制gc
    forceGC();

    Utils.println("after gc: obj1WeakRef = " + obj1WeakRef.get() + ", obj2WeakRef = " + obj2WeakRf.get() + ", obj2StrongRef = " + obj2StrongRef);
}

结果输出:

before gc: obj1WeakRef = java.lang.Object@4554617c, obj2WeakRef = java.lang.Object@74a14482, obj2StrongRef = java.lang.Object@74a14482
after gc: obj1WeakRef = null, obj2WeakRef = java.lang.Object@74a14482, obj2StrongRef = java.lang.Object@74a14482

从结果上可以看出:

那么,ThreadLocalMap中对key的引用,为什么是WeakReference的呢?

因为大部分情况下,线程不死

大部分情况下,线程不会频繁的创建和销毁,一般都会用线程池。所以线程对象一般不会被清除,线程的threadLocalMap就一直存在。
如果key对ThreadLocal是强引用,那么key永远不会被回收,即使我们程序里再也不用它了。

但是key是弱引用的话,情况就会得到改善:只要没有指向threadLocal的强引用了,这个ThreadLocal对象就会被清理。

我们还是写代码测试一下吧。

/**
 * 测试ThreadLocal对象什么时候被回收
 * @throws InterruptedException
 */
static void testGC() throws InterruptedException {
    Utils.println("-----------------testGC-------------------");
    Thread thread1 = new Thread(() -> {
        ThreadLocal<String> threadLocal1 = new ThreadLocal<>();
        ThreadLocal<String> threadLocal2 = new ThreadLocal<>();

        threadLocal1.set("threadLocal1-value");
        threadLocal2.set("threadLocal2-value");

        try {
            Object threadLocalMap = getThreadLocalMap(Thread.currentThread());
            Utils.println("print threadLocalMap before gc");
            printThreadLocalMap(threadLocalMap);

            //set threadLocal1 unreachable
            threadLocal1 = null;

            forceGC();

            Utils.println("print threadLocalMap after gc");
            printThreadLocalMap(threadLocalMap);


        } catch (NoSuchFieldException | IllegalAccessException e) {
            e.printStackTrace();
        }

    }, "thread1");

    thread1.start();
    thread1.join();
    Utils.println("------------------------------------------");
}

我们在一个线程里为两个ThreadLocal对象赋值,最后把其中一个对象的强引用移除,gc后打印当前线程的threadLocalMap。
输出结果如下:

-----------------testGC-------------------
print threadLocalMap before gc
thread1
----threadLocals (ThreadLocalMap), table.length = 16
--------table[0] -> null
--------table[1] -> entry key = java.lang.ThreadLocal@7bf9cebf, value = threadLocal2-value
--------table[2] -> null
--------table[3] -> null
--------table[4] -> null
--------table[5] -> null
--------table[6] -> null
--------table[7] -> null
--------table[8] -> null
--------table[9] -> null
--------table[10] -> entry key = java.lang.ThreadLocal@56342d38, value = threadLocal1-value
--------table[11] -> null
--------table[12] -> null
--------table[13] -> null
--------table[14] -> null
--------table[15] -> null
print threadLocalMap after gc
thread1
----threadLocals (ThreadLocalMap), table.length = 16
--------table[0] -> null
--------table[1] -> entry key = java.lang.ThreadLocal@7bf9cebf, value = threadLocal2-value
--------table[2] -> null
--------table[3] -> null
--------table[4] -> null
--------table[5] -> null
--------table[6] -> null
--------table[7] -> null
--------table[8] -> null
--------table[9] -> null
--------table[10] -> entry key = null, value = threadLocal1-value
--------table[11] -> null
--------table[12] -> null
--------table[13] -> null
--------table[14] -> null
--------table[15] -> null
------------------------------------------

从输出结果可以看到,当我们把threadLocal1的强引用移除并gc之后,table[10]的key变成了null,说明threadLocal1这个对象被回收了;threadLocal2的强引用还在,所以table[1]的key不是null,没有被回收。

但是你发现没有,table[10]的key虽然是null了,但value还活着! table[10]这个entry对象,也活着!

是的,因为只有key是WeakReference....

无用的entry什么时候被回收?

通过查看ThreadLocal的源码,发现在ThreadLocal对象的get/set/remove方法执行时,都有机会清除掉map中已经无用的entry。

最容易验证清除无用entry的场景分别是:

还有其他场景,但不好验证,这里就不提了。

ThreadLocal源码就不贴了,贴了也讲不明白,相关逻辑在setInitialValue、cleanSomeSlots、expungeStaleEntries、rehash、resize等方法里。

在我们写代码验证entry回收逻辑之前,还需要简单的提一下ThreadLocalMap的hash算法。

entry数组的下标如何确定?

每个ThreadLocal对象,都有一个threadLocalHashCode变量,在加入ThreadLocalMap的时候,根据这个threadLocalHashCode的值,对entry数组的长度取余(hash & (len - 1)),余数作为下标。

那么threadLocalHashCode是怎么计算的呢?看源码:

public class ThreadLocal<T>{
    private final int threadLocalHashCode = nextHashCode();
    private static AtomicInteger nextHashCode = new AtomicInteger();

    private static final int HASH_INCREMENT = 0x61c88647;

    private static int nextHashCode() {
        return nextHashCode.getAndAdd(HASH_INCREMENT);
    }
    ...
}

ThreadLocal类维护了一个全局静态字段nextHashCode,每new一个ThreadLocal对象,nextHashCode都会递增0x61c88647,作为下一个ThreadLocal对象的threadLocalHashCode。

这个0x61c88647,是个神奇的数字,只要以它为递增值,那么和2的N次方取余时,在有限的次数内不会发生重复。
比如和16取余,那么在16次递增内,不会发生重复。还是写代码验证一下吧。

int hashCode = 0;
int HASH_INCREMENT = 0x61c88647;
int length = 16;

for(int i = 0; i < length ; i ++){
    int h = hashCode & (length - 1);
    hashCode += HASH_INCREMENT;
    System.out.println("h = " + h + ", i = " + i);
}

输出结果为:

h = 0, i = 0
h = 7, i = 1
h = 14, i = 2
h = 5, i = 3
h = 12, i = 4
h = 3, i = 5
h = 10, i = 6
h = 1, i = 7
h = 8, i = 8
h = 15, i = 9
h = 6, i = 10
h = 13, i = 11
h = 4, i = 12
h = 11, i = 13
h = 2, i = 14
h = 9, i = 15

你看,h的值在16次递增内,没有发生重复。 但是要记住,2的N次方作为长度才会有这个效果,这也解释了为什么ThreadLocalMap的entry数组初始长度是16,每次都是2倍的扩容。

验证新threadLocal的get和set时回收部分无效的entry

为了验证出结果,我们需要先给ThreadLocal的nextHashCode重置一个初始值,这样在测试的时候,每个threadLocal的数组下标才会按照我们设计的思路走。

static void resetNextHashCode() throws NoSuchFieldException, IllegalAccessException {
    Field nextHashCodeField = ThreadLocal.class.getDeclaredField("nextHashCode");
    nextHashCodeField.setAccessible(true);
    nextHashCodeField.set(null, new AtomicInteger(1253254570));
}

然后在测试代码里,我们先调用resetNextHashCode方法,然后加两个ThreadLocal对象并set值,gc前把强引用去除,gc后再new两个新的theadLocal对象,分别调用他们的get和set方法。
在每个关键点打印出threadLocalMap做比较。

static void testExpungeSomeEntriesWhenGetOrSet() throws InterruptedException {
    Utils.println("----------testExpungeStaleEntries----------");
    Thread thread1 = new Thread(() -> {
        try {
            resetNextHashCode();

            //注意,这里必须有两个ThreadLocal,才能验证出threadLocal1被清理
            ThreadLocal<String> threadLocal1 = new ThreadLocal<>();
            ThreadLocal<String> threadLocal2 = new ThreadLocal<>();

            threadLocal1.set("threadLocal1-value");
            threadLocal2.set("threadLocal2-value");


            Object threadLocalMap = getThreadLocalMap(Thread.currentThread());
            //set threadLocal1 unreachable
            threadLocal1 = null;
            threadLocal2 = null;
            forceGC();

            Utils.println("print threadLocalMap after gc");
            printThreadLocalMap(threadLocalMap);

            ThreadLocal<String> newThreadLocal1 = new ThreadLocal<>();
            newThreadLocal1.get();
            Utils.println("print threadLocalMap after call a new newThreadLocal1.get");
            printThreadLocalMap(threadLocalMap);

            ThreadLocal<String> newThreadLocal2 = new ThreadLocal<>();
            newThreadLocal2.set("newThreadLocal2-value");
            Utils.println("print threadLocalMap after call a new newThreadLocal2.set");
            printThreadLocalMap(threadLocalMap);


        } catch (NoSuchFieldException | IllegalAccessException e) {
            e.printStackTrace();
        }

    }, "thread1");

    thread1.start();
    thread1.join();
    Utils.println("------------------------------------------");
}

程序输出结果为:

----------testExpungeStaleEntries----------
print threadLocalMap after gc
thread1
----threadLocals (ThreadLocalMap), table.length = 16
--------table[0] -> null
--------table[1] -> entry key = null, value = threadLocal2-value
--------table[2] -> null
--------table[3] -> null
--------table[4] -> null
--------table[5] -> null
--------table[6] -> null
--------table[7] -> null
--------table[8] -> null
--------table[9] -> null
--------table[10] -> entry key = null, value = threadLocal1-value
--------table[11] -> null
--------table[12] -> null
--------table[13] -> null
--------table[14] -> null
--------table[15] -> null
print threadLocalMap after call a new newThreadLocal1.get
thread1
----threadLocals (ThreadLocalMap), table.length = 16
--------table[0] -> null
--------table[1] -> entry key = null, value = threadLocal2-value
--------table[2] -> null
--------table[3] -> null
--------table[4] -> null
--------table[5] -> null
--------table[6] -> null
--------table[7] -> null
--------table[8] -> entry key = java.lang.ThreadLocal@2b63dc81, value = null
--------table[9] -> null
--------table[10] -> null
--------table[11] -> null
--------table[12] -> null
--------table[13] -> null
--------table[14] -> null
--------table[15] -> null
print threadLocalMap after call a new newThreadLocal2.set
thread1
----threadLocals (ThreadLocalMap), table.length = 16
--------table[0] -> null
--------table[1] -> null
--------table[2] -> null
--------table[3] -> null
--------table[4] -> null
--------table[5] -> null
--------table[6] -> null
--------table[7] -> null
--------table[8] -> entry key = java.lang.ThreadLocal@2b63dc81, value = null
--------table[9] -> null
--------table[10] -> null
--------table[11] -> null
--------table[12] -> null
--------table[13] -> null
--------table[14] -> null
--------table[15] -> entry key = java.lang.ThreadLocal@2e93c547, value = newThreadLocal2-value
------------------------------------------

从结果上来看,

验证map的size大于等于table.length的2/3时回收所有无效的entry

    static void testExpungeAllEntries() throws InterruptedException {
        Utils.println("----------testExpungeStaleEntries----------");
        Thread thread1 = new Thread(() -> {
            try {
                resetNextHashCode();

                int threshold = 16 * 2 / 3;
                ThreadLocal[] threadLocals = new ThreadLocal[threshold - 1];
                for(int i = 0; i < threshold - 1; i ++){
                    threadLocals[i] = new ThreadLocal<String>();
                    threadLocals[i].set("threadLocal" + i + "-value");
                }

                Object threadLocalMap = getThreadLocalMap(Thread.currentThread());

                threadLocals[1] = null;
                threadLocals[8] = null;
                //threadLocals[6] = null;
                //threadLocals[4] = null;
                //threadLocals[2] = null;
                forceGC();

                Utils.println("print threadLocalMap after gc");
                printThreadLocalMap(threadLocalMap);

                ThreadLocal<String> newThreadLocal1 = new ThreadLocal<>();
                newThreadLocal1.set("newThreadLocal1-value");
                Utils.println("print threadLocalMap after call a new newThreadLocal1.get");
                printThreadLocalMap(threadLocalMap);

            } catch (NoSuchFieldException | IllegalAccessException e) {
                e.printStackTrace();
            }

        }, "thread1");

        thread1.start();
        thread1.join();
        Utils.println("------------------------------------------");
    }

我们先创建了9个threadLocal对象并设置了值,然后去掉了其中2个的强引用(注意这2个可不是随意挑选的)。
gc后再添加一个新的threadLocal,最后打印出最新的map。输出为:

----------testExpungeStaleEntries----------
print threadLocalMap after gc
thread1
----threadLocals (ThreadLocalMap), table.length = 16
--------table[0] -> null
--------table[1] -> entry key = null, value = threadLocal1-value
--------table[2] -> entry key = null, value = threadLocal8-value
--------table[3] -> null
--------table[4] -> entry key = java.lang.ThreadLocal@60523912, value = threadLocal6-value
--------table[5] -> null
--------table[6] -> entry key = java.lang.ThreadLocal@48fccd7a, value = threadLocal4-value
--------table[7] -> null
--------table[8] -> entry key = java.lang.ThreadLocal@188bbe72, value = threadLocal2-value
--------table[9] -> null
--------table[10] -> entry key = java.lang.ThreadLocal@19e0ebe8, value = threadLocal0-value
--------table[11] -> entry key = java.lang.ThreadLocal@688bcb6f, value = threadLocal7-value
--------table[12] -> null
--------table[13] -> entry key = java.lang.ThreadLocal@46324c19, value = threadLocal5-value
--------table[14] -> null
--------table[15] -> entry key = java.lang.ThreadLocal@38f1283, value = threadLocal3-value
print threadLocalMap after call a new newThreadLocal1.get
thread1
----threadLocals (ThreadLocalMap), table.length = 32
--------table[0] -> null
--------table[1] -> null
--------table[2] -> null
--------table[3] -> null
--------table[4] -> null
--------table[5] -> null
--------table[6] -> entry key = java.lang.ThreadLocal@48fccd7a, value = threadLocal4-value
--------table[7] -> null
--------table[8] -> null
--------table[9] -> entry key = java.lang.ThreadLocal@1dae16b1, value = newThreadLocal1-value
--------table[10] -> entry key = java.lang.ThreadLocal@19e0ebe8, value = threadLocal0-value
--------table[11] -> null
--------table[12] -> null
--------table[13] -> entry key = java.lang.ThreadLocal@46324c19, value = threadLocal5-value
--------table[14] -> null
--------table[15] -> null
--------table[16] -> null
--------table[17] -> null
--------table[18] -> null
--------table[19] -> null
--------table[20] -> entry key = java.lang.ThreadLocal@60523912, value = threadLocal6-value
--------table[21] -> null
--------table[22] -> null
--------table[23] -> null
--------table[24] -> entry key = java.lang.ThreadLocal@188bbe72, value = threadLocal2-value
--------table[25] -> null
--------table[26] -> null
--------table[27] -> entry key = java.lang.ThreadLocal@688bcb6f, value = threadLocal7-value
--------table[28] -> null
--------table[29] -> null
--------table[30] -> null
--------table[31] -> entry key = java.lang.ThreadLocal@38f1283, value = threadLocal3-value
------------------------------------------

从结果上看:

如果在gc前,我们把threadLocals[1、8、6、4、2]都去掉强引用,加入新threadLocal后会发现1、8、6、4、2被清除了,但没有扩容,因为此时size是5,小于10-10/4。这个逻辑就不贴测试结果了,你可以取消注释上面代码中相关的逻辑试试。

大部分场景下,ThreadLocal对象的生命周期是和app一致的,弱引用形同虚设

回到现实中。

我们用ThreadLocal的目的,无非是在跨方法调用时更方便的线程安全地存储和使用变量。这就意味着ThreadLocal的生命周期很长,甚至和app是一起存活的,强引用一直在。

既然强引用一直存在,那么弱引用就形同虚设了。

所以在确定不再需要ThreadLocal中的值的情况下,还是老老实实的调用remove方法吧!

代码地址

https://github.com/kongxiangxin/pine/tree/master/threadlocal

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