Pause thread from another thread(s) and also stop/start it yet from another thread

Question

I've found already good hints here. But I have much more difficult task - additional requests are:
- my low priority forever thread can be started/stopped from main thread (that's same) - but it also has to lock one resource for exclusive access.
- my low priority forever thread can be paused/continued from another high priority thread(s) (they then also lock and use that one resource)
- also I want the low priority thread to not release lock in each loop, but only release the lock once it is told to (for speed purposes - cos I would need to init/deinit resource) (If I would have release lock every loop then I may let java to manage competing threads and expect that high priority threads would win every now and then).

I come up with solution and I think it is safe and sound. But I'm newbie so I'm open for finding bug in my solution or suggestions for improvements. So my questions are:
1) Is my solution really thread safe in all cases?
2) Is it optimal solution or can I improve something?

If it is agreed by you then let it be used as a template.

Here is core code:

FlagNotify lowPriorRunReq   = new FlagNotify(false); // low priority task run request
FlagNotify lowPriorPauseReq = new FlagNotify(false); // low priority task pause request (it uses notify)
volatile boolean lowPriorRunFlag = false;  // low priority task run flag
Lock      groupLock        = new ReentrantLock();  // group lock (used to acquire lowPriorRunFlag always correctly)
Semaphore resourceSemaphore = new Semaphore(1);    // main semaphore protecting resource that has to be accessed sequentially

public class PrioritySingleTaskThread extends Thread {
    @Override
    public void run() {
        prn("High Priority Task created");
        groupLock.lock();
        if(lowPriorRunFlag == true) lowPriorPauseReq.setNotify(true);
        resourceSemaphore.acquireUninterruptibly();
        groupLock.unlock();
        accessResource("high priority task");
        resourceSemaphore.release();
        groupLock.lock();
        if(lowPriorPauseReq.get() == true) lowPriorPauseReq.setNotify(false);
        groupLock.unlock();
        prn("High Priority Task closed");
    }
}

public class LowPriorityContinuousThread extends Thread {
    void getResourceSemaphore(){
        groupLock.lock();
        resourceSemaphore.acquireUninterruptibly();
        lowPriorRunFlag = true;
        groupLock.unlock();
        accessResource("low priority init"); // here it is initialization and I want to happen only on request from priority thread
    }
    void releaseResourceSemaphore(){
        accessResource("low priority de-init"); // here it is de-initialization and I want to happen only on request from priority thread
        lowPriorRunFlag = false;
        resourceSemaphore.release();
    }

    @Override
    public void run() {
        while(true){
            //prn("Low Priority Run req: "+lowPriorRunReq.get());
            if(lowPriorRunReq.get() == true && lowPriorRunFlag == false){
                prn("Low  Priority Task starting");
                getResourceSemaphore();
                prn("Low  Priority Task started");
            }
            if(lowPriorRunReq.get() == false && lowPriorRunFlag == true){
                prn("Low  Priority Task stopping");
                releaseResourceSemaphore();
                prn("Low  Priority Task stopped");
                lowPriorRunReq.smartWait(true);
            }
            // note keep checking lowPriorRunFlag. Imagine there is RunFlag detected by high priority thread
            // before de-asserted, then pauseReq would be requested from high priority thread
            // then resource is released when low priority task stops.
            // High priority lock and use resource, but since pauseReq is set
            // this thread would try to access device in order to de-init and pause (unless we check runFlag)
            if(lowPriorPauseReq.get() == true && lowPriorRunFlag == true){
                prn("Low  Priority Task pausing");
                releaseResourceSemaphore();
                prn("Low  Priority Task paused");
                lowPriorPauseReq.smartWait(false);
                getResourceSemaphore();
                prn("Low  Priority Task continue");
            }
            if(lowPriorRunFlag){
                accessResource("low priority task");
            }
        }
    }
}

And here is full compilable Java code including test bench (so I have a hint it is a safe solution - but you never know with those threads)

import java.util.concurrent.Semaphore;
import java.util.concurrent.atomic.AtomicInteger;
import java.util.concurrent.locks.Lock;
import java.util.concurrent.locks.ReentrantLock;

public class Main {
    // this inner class is only for setting flag and waiting to it by notify - which does not hog CPU
    public class FlagNotify{
        private Boolean flag; // do not synchro on Boolean - it is immutable, thus new object is created every value change....
        private Object synchro = new Object();

        public FlagNotify(boolean val) {
            flag = val;
        }

        public void setNotify(boolean val) {
            synchronized (synchro) {
                flag = val;
                synchro.notify();
            }
        }

        public boolean get(){
            return flag;
        }
        public void smartWait(boolean expVal){
            synchronized (synchro){
                while(flag != expVal){
                    try {
                        synchro.wait();
                    } catch (InterruptedException e) {
                        e.printStackTrace();
                    }
                }
            }
        }
    }

    FlagNotify lowPriorRunReq   = new FlagNotify(false); // low priority task run request
    FlagNotify lowPriorPauseReq = new FlagNotify(false); // low priority task pause request (it uses notify)
    volatile boolean lowPriorRunFlag = false;  // low priority task run flag
    Lock      groupLock        = new ReentrantLock();  // group lock (used to acquire lowPriorRunFlag always correctly)
    Semaphore resourceSemaphore = new Semaphore(1);    // main semaphore protecting resource that has to be accessed sequentially

    public class PrioritySingleTaskThread extends Thread {
        @Override
        public void run() {
            prn("High Priority Task created");
            groupLock.lock();
            if(lowPriorRunFlag == true) lowPriorPauseReq.setNotify(true);
            resourceSemaphore.acquireUninterruptibly();
            groupLock.unlock();
            accessResource("high priority task");
            resourceSemaphore.release();
            groupLock.lock();
            if(lowPriorPauseReq.get() == true) lowPriorPauseReq.setNotify(false);
            groupLock.unlock();
            prn("High Priority Task closed");
        }
    }

    public class LowPriorityContinuousThread extends Thread {
        void getResourceSemaphore(){
            groupLock.lock();
            resourceSemaphore.acquireUninterruptibly();
            lowPriorRunFlag = true;
            groupLock.unlock();
            accessResource("low priority init"); // here it is initialization and I want to happen only on request from priority thread
        }
        void releaseResourceSemaphore(){
            accessResource("low priority de-init"); // here it is de-initialization and I want to happen only on request from priority thread
            lowPriorRunFlag = false;
            resourceSemaphore.release();
        }

        @Override
        public void run() {
            while(true){
                //prn("Low Priority Run req: "+lowPriorRunReq.get());
                if(lowPriorRunReq.get() == true && lowPriorRunFlag == false){
                    prn("Low  Priority Task starting");
                    getResourceSemaphore();
                    prn("Low  Priority Task started");
                }
                if(lowPriorRunReq.get() == false && lowPriorRunFlag == true){
                    prn("Low  Priority Task stopping");
                    releaseResourceSemaphore();
                    prn("Low  Priority Task stopped");
                    lowPriorRunReq.smartWait(true);
                }
                // note keep checking lowPriorRunFlag. Imagine there is RunFlag detected by high priority thread
                // before de-asserted, then pauseReq would be requested from high priority thread
                // then resource is released when low priority task stops.
                // High priority lock and use resource, but since pauseReq is set
                // this thread would try to access device in order to de-init and pause (unless we check runFlag)
                if(lowPriorPauseReq.get() == true && lowPriorRunFlag == true){
                    prn("Low  Priority Task pausing");
                    releaseResourceSemaphore();
                    prn("Low  Priority Task paused");
                    lowPriorPauseReq.smartWait(false);
                    getResourceSemaphore();
                    prn("Low  Priority Task continue");
                }
                if(lowPriorRunFlag){
                    accessResource("low priority task");
                }
            }
        }
    }
//-------------------------------------------------------------------------
//-- following functions are meant only for testing
    AtomicInteger clashDetector = new AtomicInteger(0); // only for testing purposes

    public void accessResource(String from){
        prn("Resource used from "+from);
        if(clashDetector.addAndGet(1)>1){
            System.out.println("Clash detected - you are a bad programmer :((((((");
            System.exit(-1);
        }
        sleepRandom(5);
        clashDetector.getAndAdd(-1);
    }

    public void sleepRandom(long maxMiliSec){
        mySleep((long)(Math.random()*maxMiliSec));
    }

    public void mySleep(long miliSec){
        try{
            Thread.sleep(miliSec);
        }catch (InterruptedException e) {
            e.printStackTrace();
        }
    }

    void prn(String s){
        System.out.println(s);
    }

    public void test(){
        new LowPriorityContinuousThread().start();
        for(long i=0; i< (long)1e3; i++){
            lowPriorRunReq.setNotify(true);
            for(int j=0; j<Math.random()*100;j++){
                sleepRandom(10);
                new PrioritySingleTaskThread().start();
            }
            //sleepRandom(20);
            lowPriorRunReq.setNotify(false);

            for(int j=0; j<Math.random()*20;j++){
                sleepRandom(10);
                new PrioritySingleTaskThread().start();
            }
            //sleepRandom(20);
        }
        mySleep(200);
        System.out.println("Test OK :)))))))))))))))))))))");
        mySleep(200);
        System.exit(0);
    }

    public static void main(String[] args) throws Exception {
        new Main().test();
    }

}

Answer 1

I don't know what it means to "start/stop" a "forever thread", but one design pattern you can use for pausing a thread is called a "turnstile". Here's one that works when there is just one controller thread that is allowed to "lock" or "unlock" the turnstile:

import java.util.concurrent.Semaphore;

class Turnstile {
    private final Semaphore semaphore = Semaphore.new(1);

    // Called only from the "controller" thread.
    public void lock() {
        semaphore.acquire();
    }

    // Called only from the "controller" thread.
    public void unlock() {
        semaphore.release();
    }

    // Called from worker threads.
    public void passThrough() {
        semaphore.lock();
        semaphore.release();
    }
}

Initially, the turnstile is in the "unlocked" state, and the passThrough() method promptly returns when ever a worker calls it. If the master thread "locks" the turnstile, then any worker that calls passThrough() will be blocked until the master "unlocks" it again. Then, all of the workers will "pass through", one-by-one.

---

You could modify this example if you want to have more than one "master", but it's up to you to decide how to resolve the conflict when one master wants the turnstile to be locked, and another wants it to be unlocked.

---

Then again, instead of modifying Turnstile, you could write a new MultiMasterTurnstile that handles the conflict resolution and uses a Turnstile to actually block the workers.

Answer 2

As James Large suggested to use Turnstile in his response. I did rewrite the code and it looks nicer at least to me. So I did DoubleTurnstile it looks like this:

public class DoubleTurnstile{
    Semaphore  resourceSemaphore = new Semaphore(1);    // main semaphore protecting resource that has to be accessed sequentially
    volatile boolean  lowPriorRunReq    = false; // low priority task run request
    volatile boolean lowPriorPauseReq   = false; // low priority task pause request (it uses notify)
    private Object notifyWait = new Object();
    Lock       groupLock         = new ReentrantLock();  // group lock (used to acquire lowPriorRunFlag always correctly)
    volatile boolean lowPriorRunFlag = false;  // low priority task run flag

    private void myWaitNotify(){
        synchronized (notifyWait){
            try {
                notifyWait.wait();
            } catch (InterruptedException e) {
                e.printStackTrace();
            }
        }
    }
    private void myNotify(){
        synchronized (notifyWait){
            notifyWait.notify();
        }
    }

    public void highPriorityEnter() {
        groupLock.lock();
        //if (lowPriorRunFlag){ // "if" is not necessary, but correct
            lowPriorPauseReq = true;
        //}
        resourceSemaphore.acquireUninterruptibly();
        groupLock.unlock();
    }

    public void highPriorityLeaves() {
        resourceSemaphore.release();
        groupLock.lock();
        if(lowPriorPauseReq == true){
            lowPriorPauseReq = false;
            myNotify();
        }
        groupLock.unlock();
    }

    public void lowPriorityLoopEnter() {
        while(true){
            if((lowPriorRunReq == true)
                && (lowPriorPauseReq == false)) break;
            myWaitNotify();
        }
        groupLock.lock();
        resourceSemaphore.acquireUninterruptibly();
        lowPriorRunFlag = true;
        groupLock.unlock();
    }

    public boolean lowPriorityLoop_ShallEnd() {
        return (lowPriorRunReq == false)
                || (lowPriorPauseReq == true);
    }
    public void lowPriorityLoop_Leaves() {
        lowPriorRunFlag = false;
        resourceSemaphore.release();
    }

    public void masterLowPriorityRunEn(boolean shallRun) {
        lowPriorRunReq = shallRun;
        myNotify();
    }
}

Then priority task uses DoubleTurnstile as this:

public class PrioritySingleTaskThread extends Thread {
    @Override
    public void run() {
        prn("High Priority Task created");
        dblTurnstile.highPriorityEnter();
        accessResource("high priority task");
        dblTurnstile.highPriorityLeaves();
        prn("High Priority Task closed");
    }
}

and low priority continuous thread uses it like this:

public class LowPriorityContinuousThread extends Thread {
    @Override
    public void run() {
        while(true){
            dblTurnstile.lowPriorityLoopEnter();
            accessResource("low priority init"); // here it is initialization and I want to happen only on request from priority thread
            while(true){
                accessResource("low priority task");
                if(dblTurnstile.lowPriorityLoop_ShallEnd() == true){
                    accessResource("low priority de-init"); // here it is de-initialization and I want to happen only on request from priority thread
                    dblTurnstile.lowPriorityLoop_Leaves();
                    break;
                }

            }
        }
    }
}

Now it is more like pattern and more easily reusable.

Full compilable code with test method is as follows:

import java.util.concurrent.Semaphore;
import java.util.concurrent.atomic.AtomicInteger;
import java.util.concurrent.locks.Lock;
import java.util.concurrent.locks.ReentrantLock;

public class Main2 {

    DoubleTurnstile dblTurnstile = new DoubleTurnstile();

    public class DoubleTurnstile{
        Semaphore  resourceSemaphore = new Semaphore(1);    // main semaphore protecting resource that has to be accessed sequentially
        volatile boolean  lowPriorRunReq    = false; // low priority task run request
        volatile boolean lowPriorPauseReq   = false; // low priority task pause request (it uses notify)
        private Object notifyWait = new Object();
        Lock       groupLock         = new ReentrantLock();  // group lock (used to acquire lowPriorRunFlag always correctly)
        volatile boolean lowPriorRunFlag = false;  // low priority task run flag

        private void myWaitNotify(){
            synchronized (notifyWait){
                try {
                    notifyWait.wait();
                } catch (InterruptedException e) {
                    e.printStackTrace();
                }
            }
        }
        private void myNotify(){
            synchronized (notifyWait){
                notifyWait.notify();
            }
        }
        // call highPriorityLeaves() after used shared resources
        public void highPriorityEnter() {
            groupLock.lock();
            //if (lowPriorRunFlag){ // "if" is not necessary but correct
                lowPriorPauseReq = true;
            //}
            resourceSemaphore.acquireUninterruptibly();
            groupLock.unlock();
        }
        // call exactly once for each previous highPriorityEnter()
        public void highPriorityLeaves() {
            resourceSemaphore.release();
            groupLock.lock();
            if(lowPriorPauseReq == true){
                lowPriorPauseReq = false;
                myNotify();
            }
            groupLock.unlock();
        }

        public void lowPriorityLoopEnter() {
            while(true){
                if((lowPriorRunReq == true)
                    && (lowPriorPauseReq == false)) break;
                myWaitNotify();
            }
            groupLock.lock();
            resourceSemaphore.acquireUninterruptibly();
            lowPriorRunFlag = true;
            groupLock.unlock();
        }

        public boolean lowPriorityLoop_ShallEnd() {
            return (lowPriorRunReq == false)
                    || (lowPriorPauseReq == true);
        }
        public void lowPriorityLoop_Leaves() {
            lowPriorRunFlag = false;
            resourceSemaphore.release();
        }

        public void masterLowPriorityRunEn(boolean shallRun) {
            lowPriorRunReq = shallRun;
            myNotify();
        }
    }

    public class PrioritySingleTaskThread extends Thread {
        int id;
        public PrioritySingleTaskThread(int id){this.id=id;}
        @Override
        public void run() {
            prn("High Priority Task created");
            dblTurnstile.highPriorityEnter();
            accessResource("high priority task",true, id);
            dblTurnstile.highPriorityLeaves();
            prn("High Priority Task closed");
        }
    }

    public class LowPriorityContinuousThread extends Thread {
        public int id = 0;
        @Override
        public void run() {
            while(true){
                dblTurnstile.lowPriorityLoopEnter();
                accessResource("low priority init",false,id++); // here it is initialization and I want to happen only on request from priority thread
                while(true){
                    accessResource("low priority task",false,id++);
                    if(dblTurnstile.lowPriorityLoop_ShallEnd() == true){
                        accessResource("low priority de-init",false,id++); // here it is de-initialization and I want to happen only on request from priority thread
                        dblTurnstile.lowPriorityLoop_Leaves();
                        break;
                    }

                }
            }
        }
    }

    //-------------------------------------------------------------------------
    //-- following functions are meant only for testing
    AtomicInteger clashDetector = new AtomicInteger(0); // only for testing purposes
    int hiPriorityCnt; // only for testing purposes
    int loPriorityCnt; // only for testing purposes
    int lastLowPriorityId=-1;
    int lastHiPriorityId=-1;
    int hiPriorityOutOfOrder=0;

    public void accessResource(String from,boolean hiPriority, int id) {
        prn("Resource used from " + from+" id: "+id);
        if(hiPriority){
            if( (id - lastHiPriorityId) < 1) {
                // note if id - lastHiPriorityId=+2 (one sample over-jumped) it will be detected
                // when returned to the over-jumped sample,
                // or at the end of the test one sample missing will be detected
                // so no injustice will escape it's punishment ;)
                // On the other hand if we want strictly ==1 then one error will be reported 3 times -
                // 1st when ID: 1->3
                // 2nd when ID: 3->2 // correct error
                // 3rd when ID: 2->4
                System.out.println("High priority jumped over each other - it's not nice but it can happen");
                hiPriorityOutOfOrder++;
            }
            lastHiPriorityId = id;
            hiPriorityCnt++;
        }
        else{
            if( (id - lastLowPriorityId) < 1) {
                System.out.println("LowPriorityLoop request swapped - you are a bad programmer :((((((");
                System.exit(-1);
            }
            lastLowPriorityId = id;
            loPriorityCnt++;
        }
        if (clashDetector.addAndGet(1) > 1) {
            System.out.println("Clash detected - you are a bad programmer :((((((");
            System.exit(-1);
        }
        sleepRandom(5);
        clashDetector.getAndAdd(-1);
    }

    public void sleepRandom(long maxMiliSec) {
        mySleep((long) (Math.random() * maxMiliSec));
    }

    public void mySleep(long miliSec) {
        try {
            Thread.sleep(miliSec);
        } catch (InterruptedException e) {
            e.printStackTrace();
        }
    }

    void prn(String s) {
        System.out.println(s);
    }

    public void test() {
        int idHiPriority = 0;
        LowPriorityContinuousThread lowPriorThrd = new LowPriorityContinuousThread();
        lowPriorThrd.start();
        for (long i = 0; i < (long) 1e3; i++) {
            dblTurnstile.masterLowPriorityRunEn(true);
            for (int j = 0; j < Math.random() * 100; j++) {
                sleepRandom(10);
                new PrioritySingleTaskThread(idHiPriority++).start();
            }
            //sleepRandom(20);
            dblTurnstile.masterLowPriorityRunEn(false);

            for (int j = 0; j < Math.random() * 20; j++) {
                sleepRandom(10);
                new PrioritySingleTaskThread(idHiPriority++).start();
            }
            //sleepRandom(20);
        }
        mySleep(500);
        boolean testOk = true;
        if(hiPriorityCnt != idHiPriority){
            System.out.println(String.format("Error hiPriorityCnt(%d) != idHiPriority(%d)",
                    hiPriorityCnt, idHiPriority));
            testOk = false;
        }
        if(loPriorityCnt != lowPriorThrd.id){
            System.out.println(String.format("Error loPriorityCnt(%d) != lowPriorThrd.id(%d)",
                    loPriorityCnt, lowPriorThrd.id));
            testOk = false;
        }
        System.out.println("High priority tasks performed: "+hiPriorityCnt);
        System.out.println("High priority out of order: "+hiPriorityOutOfOrder);
        System.out.println("Low priority tasks performed: "+loPriorityCnt);
        if(testOk){
            System.out.println("Test2 OK :)))))))))))))))))))))");
        }else{
            System.out.println("Test Failed :(((((((((((((((((((((");
        }
        mySleep(200);
        System.exit(0);
    }

    public static void main(String[] args) throws Exception {
        new Main2().test();
    }
}

The logic of the locks did not change too much. So I still would appreciate if you leave a comment if you think that my DoubleTurnstile class is thread safe under all conditions. Tests suggests so.