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  • Simplified illustration below, how does .NET deal with such a situation?
  • and if it would cause problems, would i have to lock/gate access to each and every field/property that might at times be written to + accessed from different threads?

A field somewhere

public class CrossRoads(){
    public int _timeouts;
}

A background thread writer

public void TimeIsUp(CrossRoads crossRoads){
    crossRoads._timeouts++;
}

Possibly at the same time, trying to read elsewhere

public void HowManyTimeOuts(CrossRoads crossRoads){
    int timeOuts = crossRoads._timeouts;
}
share|improve this question
up vote 9 down vote accepted

The simple answer is that the above code has the ability to cause problems if accessed simultaneously from multiple threads.

The .Net framework provides two solutions: interlocking and thread synchronization.

For simple data type manipulation (i.e. ints), interlocking using the Interlocked class will work correctly and is the recommended approach.

In fact, interlocked provides specific methods (Increment and Decrement) that make this process easy:

Add an IncrementCount method to your CrossRoads class:

public void IncrementCount() {
    Interlocked.Increment(ref _timeouts);
}

Then call this from your background worker:

public void TimeIsUp(CrossRoads crossRoads){
    crossRoads.IncrementCount();
}

The reading of the value, unless of a 64-bit value on a 32-bit OS, are atomic. See the Interlocked.Read method documentation for more detail.

For class objects or more complex operations, you will need to use thread synchronization locking (lock in C# or SyncLock in VB.Net).

This is accomplished by creating a static synchronization object at the level the lock is to be applied (for example, inside your class), obtaining a lock on that object, and performing (only) the necessary operations inside that lock:

    private static object SynchronizationObject = new Object();

    public void PerformSomeCriticalWork()
    {
        lock (SynchronizationObject)
        {
            // do some critical work
        }
    }
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Well, I'm not a C# developer, but this is how it typically works at this level:

how does .NET deal with such a situation?

Unlocked. Not likely to be guaranteed to be atomic.

Would i have to lock/gate access to each and every field/property that might at times be written to + accessed from different threads?

Yes. An alternative would be to make a lock for the object available to the clients, then tell the clients they must lock the object while using the instance. This will reduce the number of locks acquisitions, and guarantee a more consistent, predictable, state for your clients.

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The good news is that reads and writes to ints are guaranteed to be atomic, so no torn values. However, it is not guaranteed to do a safe ++, and the read could potentially be cached in registers. There's also the issue of instruction re-ordering.

I would use:

Interlocked.Increment(ref crossroads._timeouts);

For the write, which will ensure no values are lost, and;

int timeouts = Interlocked.CompareExchange(ref crossroads._timeouts, 0, 0);

For the read, since this observes the same rules as the increment. Strictly speaking "volatile" is probably enough for the read, but it is so poorly understood that the Interlocked seems (IMO) safer. Either way, we're avoiding a lock.

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Unless TimeIsUp is called in multiple threads, the code is safe, no need for locking mechanism.(HowManyTimeOuts can be called any time, before,after or in the middle of increment in TimeIsUp). It is always correct at the time it is called – L.B Jan 8 '12 at 0:53
1  
@L.B actually no; in a tight loop, it could stay on a register and not ever hit the field. An edge. Ase, it worth mentioning. To be robust it needs either a volatile read, an interlock, or a fence. – Marc Gravell Jan 8 '12 at 8:46
    
+1 the read should use interlocked too to provide a freshness guarantee. The other solutions do not mention this. You can also use Interlocked.Add(0). – Imran Jul 30 '13 at 10:53

Although an int may be 'native' size to a CPU (dealing in 32 or 64 bits at a time), if you are reading and writing from different threads to the same variable, you are best off locking this variable and synchronizing access.

There is never a guarantee that reads/writes maybe atomic to an int.

You can also use Interlocked.Increment for your purposes here.

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2  
Actually, it is guaranteed to be atomic, in the language spec. Long and double are not, for example, although references are ( guaranteed to be atomic), regardless of the platform. – Marc Gravell Jan 8 '12 at 0:09
    
@competent_tech because while reads and writes are individually guaranteed to be atomic, that does not mean that an increment (comprising several operations, including a read and a write) is atomic as a composite. You, however, state that reads/writes are not guaranteed to be atomic: they are. – Marc Gravell Jan 8 '12 at 0:22
    
@MarcGravell: Of course, sorry for the waste of time. I was thinking that this was in response to ++, not the individual read and write ops. – competent_tech Jan 8 '12 at 0:23

Forget dotnet. At the machine language level, crossRoads._timeouts++ will be implemented as an INC [memory] instruction. This is known as a Read-Modify-Write instruction. These instructions are atomic with respect to multi-threading on a single processor*, (essentially implemented with time-slicing,) but are not atomic with respect to multi-threading using multiple processors or multiple cores.

So:

If you can guarantee that only TimeIsUp() will ever modify crossRoads._timeouts, and if you can guarantee that only one thread will ever execute TimeIsUp(), then it will be safe to do this. The writing in TimeIsUp() will work fine, and the reading in HowManyTimeOuts() (and any place else) will work fine. But if you also modify crossRoads._timeouts elsewhere, or if you ever spawn one more background thread writer, you will be in trouble.

In either case, my advice would be to play it safe and lock it.

(*) They are atomic with respect to multi-threading on a single processor because context switches between threads happen on a periodic interrupt, and on the x86 architectures these instructions are atomic with respect to interrupts, meaning that if an interrupt occurs while the CPU is executing such an instruction, the interrupt will wait until the instruction completes. This does not hold true with more complex instructions, for example those with the REP prefix.

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