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I'm working with a simple system that does NOT have mutexes, but rather a limited array of hardware binary semaphores. Typically, all multithreading is been done with heavy Semaphore techniques that makes code both poor in performance and difficult to write correctly without deadlocks.

A naive implementation is to use one semaphore globally in order to ensure atomic access to a critical section. However, this means that unrelated objects (even of different types) will block if any critical section is being accessed.

My current solution to this problem is to use a single global semaphore to ensure atomic access to a guard byte that then ensures atomic access to the particular critical section. I currently have this so far:

while (true) {
    while (mutexLock == Mutex::Locked) {
    } //wait on mutex
    Semaphore semaLock(SemaphoreIndex::Mutex); //RAII semaphore object
    if (mutexLock == Mutex::Unlocked) {
        mutexLock = Mutex::Locked;
        break;
    }
} //Semaphore is released by destructor here
// ... atomically safe code
mutexLock = Mutex::Unlocked;

I have a few questions: Is this the best way to approach this problem? Is this code thread-safe? Is this the same as a "double checked lock"? If so, does it suffer from the same problems and therefore need memory barriers?

EDIT: A few notes on the system this is being implemented on...

It is a RISC 16-bit processor with 32kB RAM. While it has heavy multithreading capabilities, its memory model is very primitive. Loads and stores are atomic, there is no caching, no branch prediction or branch target prediction, one core with many threads. Memory barriers are mostly for the compiler to know it should reload memory into general purpose registers, not for any hardware reason (no cache)

share|improve this question
    
This is, obviously, non-portable code. So we'd have to know your platform's rules. – David Schwartz Oct 4 '13 at 19:48
    
Which in particular? The semaphore is an atomic lock at the index given when constructed, and the destruction releases across all threads. – Sam Cristall Oct 4 '13 at 19:51
    
Why must you restrict yourself to a global semaphore? – Troy Oct 4 '13 at 19:52
    
Knowing its memory visibility rules would be a start. Knowing if it provides memory barriers and, if so, what kinds and when they're needed would be good. Is it multi-processor or multi-core? Does it reorder memory operations? Does it have cores that share execution resources? You need detailed platform knowledge to construct good synchronization primitives. – David Schwartz Oct 4 '13 at 19:53
    
For example, if this is a modern x86 platform, this code is a disaster. Your loop on the mutexLock will cause the CPU to mispredict the branch when mutexLock is released. So at the worst possible time, when you absolutely need to go as quickly as possible, you completely blow up the pipelines. And what about hyper-threading? That loop will consume CPU resources like mad. What if the lock is held by the other virtual core? How is it supposed to make forward progress efficiently with that loop consuming limited execution resources? You need detailed platform knowledge to do this right. – David Schwartz Oct 4 '13 at 19:57

Even if the processor has heavy multithreading capabilities (not sure what you mean by that btw.), but is a single core processor, it still means that only one thread can execute at any one time.

A task switching system must be employed (which would normally run in a privileged mode) Using this system you must be able to define critical sections to atomically execute a (software implemented) mutex lock/unlock.

When you say "one core, many threads" does that mean that you have some kind of kernel running on your processor? The task switching system will be implemented by that kernel. It might pay to look through the documentation of your kernel or ask your vendor for any tips.

Good luck.

share|improve this answer
    
We actually are the vendor haha, and I'm implementing a library to help with multi-threading on it. There is no kernel, as it is a simple MCU with the novel addition that up to N instructions are executed in parallel per instruction tick. This is implemented in hardware, not software, with no true task switching. Unfortunately, the hardware only comes with N*2 semaphore locks for handling multi-threading, which is not typically enough, and thus spawned this question. – Sam Cristall Nov 27 '13 at 15:41

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