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I'm studying multithreading and trying to understand the concept of semaphores and mutual exclusion. Most of the examples I find online use some sort of library (e.g. pthread) to implement the semaphore or mutex, but I'm more interested in the implementation of a simple semaphore that establishes a critical section -- no more than one thread accessing a particular region of memory.

For this task, I believe I would need a mutex (a.k.a. a binary semaphore if I understand the terminology correctly). I can see how the semaphore would prevent a race condition by "locking" the section of code to a single thread, but what prevents a race condition from occurring at the semaphore itself?

I imagine a binary semaphore to hold an int value to keep track of the lock:

Semaphore
---------
int lock = 1;

unsigned P(void){
    if(lock > 0){
        lock--;
        return 0; /* success */
    }
    return 1; /* fail */
}

void V(void){
    lock++;
}

Suppose two threads call the P function at the same time, they both reach the if(lock > 0) check at the same time and evaluate the condition as true -- this creates a race condition where both threads are granted access to the same region of memory at the same time.

So what prevents this race condition from occurring in real world implementations of semaphores?

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2 Answers 2

up vote 1 down vote accepted

Locking and relasing semaphores and/or mutexes happen as atomic operations, this means the CPU cannot be withdrawn from the current process. This ensures, that as soon as a mutex-lock is started (it consists of either a single or a few CPU-instruction (microcode)), the process keeps the CPU until the locking/releasing is done.
There are also different ways to implement threading, which can either be a direct support by CPU (kernel-space) or through a library (such as pthreads) in user-space.


From OSDev.org

An atomic operation is an operation that will always be executed without any other process being able to read or change state that is read or changed during the operation. It is effectively executed as a single step, and is an important quality in a number of algorithms that deal with multiple indepent processes, both in synchronization and algorithms that update shared data without requiring synchronization.


Here is a nice article on atomicity, too (although in Delphi).

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So once a thread calls the P function, it executes the instructions as "atomic" operations which guarantee that the CPU does not switch to another process while in the middle of the call. Does this also prevent another CPU from calling the P function at the same time and clobbering the memory? –  Vilhelm Gray Apr 23 '13 at 13:24
    
First is true, this is guaranteed. Secondly, all processes are scheduled by the scheduler and due to virtual memory there is no other CPU that can corrupt that memory, at least not under normal conditions. –  bash.d Apr 23 '13 at 13:26
    
@bash.d Almost all threading implementations allow multiple CPUs access the same virtual address space at the same time. Nobody bothers with guaranteeing atomicity through the scheduler, that would be way too slow for most practical applications. –  Art Apr 23 '13 at 13:30
    
The same virtual address-space does not refer to the actual address in memory, so this doesn't matter in this case. Apart from that, who does guarantee? –  bash.d Apr 23 '13 at 13:34
1  
No, the locking operations occur atomically. The entire locked are will not be executed atomically. And remember, threads share a common address-space and are all bound to a process. –  bash.d Apr 23 '13 at 14:01

The most common (although definitely not the only) way to implement most locking primitives are compare-and-set instructions. An normal move instruction would just set the value of a memory location to whatever value you ask it to while a compare-and-set instruction does "atomically set this memory location to value X only if the value of the memory location is Y, then set some flag if the operation succeeded or not". The keyword "atomic" is that the CPU can in hardware make sure that nothing else can interfere with that operation.

Using a compare-and-swap instruction your example P could be implemented as:

int oldlock;
retry:
oldlock = lock;
if (oldlock > 0) {
    if (compare_and_swap(&lock, oldlock, oldlock - 1))
        goto retry;
    return 0;
}
return 1;

Of course reality is much more complex than that, but compare-and-set is easy to understand and explain and has the nice property that it can implement (almost?) all other locking primitives.

Here's a wikipedia article.

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