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I have 3 questions that i need help.

  1. What are the correct object/reference to be passed in lock statement parameter? I've seen a lot of sample codes and i noticed that the objects/reference passed in could possibly be non related to the current class or any other class in the program as long as the access modifier static is non public? Eg:

    private Object anyObj = new Object();
    lock(anyObj){.....}
    
    private static readonly object Locker = new object();
    lock(Locker){.....}
    

    It just doesn't make sense to me.

  2. I found a sample code in MSDN about multi threading where it uses lock statements also. In the sample, there are two try catch blocks with the Monitor.Wait() within it. If i understand the logic correctly, the readerFlag will forbid the the program to ever enter the try catch block at all. The code is example 2 and its here: http://msdn.microsoft.com/en-us/library/aa645740(v=vs.71).aspx

  3. How do i run a thread that runs in the background as long as the Windows Form is active?

Can anyone help me please? I've been scouring the web for many many hours and i can't get the answer i wanted.

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4  
3) is totally unrelated, ask in a separate question. –  Henk Holterman Dec 7 '12 at 13:24

3 Answers 3

How and what you lock on depends upon what you're doing.

Let's say that you're working with a device of some kind - say a coffee maker. You might have a class that looks like this:

public CoffeeMaker {
    private IntPtr _coffeeHandle;
    private Object _lock = new Object();
}

In this case, you are protecting access to the _coffeeHandle - a pointer/handle to a real physical device, so this is pretty easy:

public int AvailableCups {
    get {
        lock (_coffeeHandle) {
            return GetAvailableCups(_coffeeHandle); // P/Invoked
        }
    }
}

public void Dispense(int nCups)
{
    lock (_coffeeHandle) {
        int nAvail = GetAvailableCups(_coffeeHandle);
        if (nAvail < nCups) throw new CoffeeException("not enough coffee.");
        Dispense(_coffeeHandle, nCups); // P/Invoked
    }
 }

So if I'm running a multithreaded app, I (probably) don't want to read the number of cups that are available while I'm dispensing (maybe it's a hardware error). By protecting accesses to the handle, I can ensure that. Also, I can't be asked to dispense while I'm already dispensing - that would be bad, so that's protected too. Finally, I don't dispense unless I have enough coffee available and you notice that I don't use my public property to check that - this way the action of ensuring there's enough coffee and dispensing are tied together. The magic word is atomic - they can't be cut apart without creating issues.

You use a static object as a lock if you have one and only one instance of a resource that needs protecting. Think, "do I have a singleton?" and that will be a guideline for when you might need a static lock. For example, let's say that CoffeeMaker has a private constructor. Instead, you have a factory method that constructs coffee machines:

static Object _factLock = new Object();

private CoffeeMaker(IntPtr handle) { _coffeeHandle = handle; }

public static CoffeeMaker GetCoffeeMaker()
{
    lock (_factLock) {
        IntPtr _handle = GetCoffeeMakerHandle(); // P/Invoked
        if (_handle == IntPtr.Zero) return null;
        return new CoffeeMaker(_handle);
    }
 }

Now in this case, it feels like CoffeeMaker should implement IDisposable so that handle gets taken care of, because if you don't release it then somebody might not be getting their coffee.

There are a few problems though - maybe if there's not enough coffee, we should make more - and that takes a long time. Heck - dispensing coffee takes a long time, which is why we're careful to protect our resources. Now you're thinking that really all this coffee maker stuff should be in a thread of its own and that there should be an event that gets fired when the coffee is done, and then it starts to get complicated and you understand the importance of knowing what you're locking on and when so that you don't block making coffee because you asked how many cups are there.

And if the words "deadlock", "atomic", "monitor", "wait", and "pulse" all sound foreign to you, you should consider reading up on multiprocessing/multithreading in general and see if you can solve the fair barbershop problem or the dining philosophers problem, both quintessential examples of resource contention.

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Thanks for the answer plinth, there is so much to take in. I'll need to really read this up properly. :) –  user1885498 Dec 8 '12 at 4:20
    
This is an excellent and very complete example. Deserves way more upvotes than it has! –  Tim Jul 30 at 12:47

1) your code is incomplete. You always lock around a certain (shared) resource. The anyObject should have a close 1-1 correspondence in lifetime with that shared object.

For instance:

a) the simple but most direct pattern:

List<MyClass> sharedList = ...;
...
lock (sharedList) { sharedList.Add(item); }

there is a drawback in this pattern: what if other code also locks on sharedList for other reasons? Usually not a practical problem, but it is the reason that the recommended pattern is (b):

List<MyClass> sharedList = ...;
private lockList = new object();
...
lock (lockList) { sharedList.Add(item); }

Or, when the shared object is static (c) :

static List<MyClass> sharedList = ...;
private static lockList = new object();
...
lock (lockList) { sharedList.Add(item); }

2) The threads alternate setting readerFlag to true or false so the try/catch blocks will be entered. The synchronization is done with Monitor.Pulse() and .Wait(). Note that Wait() will yield the lock for the duration s there is no deadlock.

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Hi Henk, I can't thank you enough for your quick reply. So in summary, can i say that the private member(lockList) is just there so that i can lock it in a proper way? If thats the case, i can just blindly just create a private member(such as lockList) whenever i use lock statements? –  user1885498 Dec 8 '12 at 4:12
    
As for the sample code, initially the readerFlag was false. So when the threads are executed, the WriteToCell method is called first. But since the flag is false it doesn't go into the try catch block. It then change the flag to true and the ReadFromCell is executed also causing the try catch block not to be executed. I don't see when the try catch is executed? Did i get the flow wrong? Thank you so so much! –  user1885498 Dec 8 '12 at 4:23
    
You are right that the sample code is not the easiest to follow. Note that the 2nd call to Write will enter the try-catch and call Wait(). Also note you can run and debug this, it's a complete program. –  Henk Holterman Dec 8 '12 at 8:50
    
just create a private member whenever i use lock statements No, the lockObject belongs to the shared resource, not to the lock statement. It's very important all related locks use the same object. –  Henk Holterman Dec 8 '12 at 8:52
    
Arrgghh this is so confusing having this private member. Sorry for being so silly. I still don't really get how it works. Can you give me a url or something? –  user1885498 Dec 9 '12 at 16:26

1: the object you use defines / is-defined-by the lock granularity you are trying to enforce. If is is "anything calling against the current instance", then a private readonly object syncLock = new object() would be reasonable. If it is "any code, regardless of the instance" (static, in particular), then private readonly static object syncLock = new object(). Sometimes there is an obvious "thing" you are trying to protect that will also serve: a list, a queue, etc. The main wrong decisions are: this, typeof(...), any string, any value-type that you are boxing for each lock, and anything that you have leaked outside of the instance.

2: Monitor.Wait releases the locks from the current thread, waiting for either a "pulse" or a timeout, at which point it wakes up and joins the queue to regain to locks it had (note the "s" there is for re-entrancy). That means that two threads can use a Monitor to signal between themselves, by pulsing and waiting.

3: unrelated; but basically "check a flag periodically, and when being pulsed"

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