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In a multi-thread or RTOS environment, are these codes below identical?

I believe they are not. But is the 1st code absolute save in a multi-thread environment? Is there a rule for compiler to assign a register for 'ga' and would not read 'ga' again later in func_a()?

I know I can use lock, but this is not a question about how to protect the data. It is just a question about the compiler behaviour.

// ga is a global variable.

int func_a() {

    int a = ga;
    return a>2 ? a-2 : 2-a;
}

int func_b() {

    return ga>2 ? ga-2 : 2-ga;
}

My intention is looking for a standard way (not platform specific) to read ga only once and assign its value to a local variable 'a'.

'a' can then be used consistently regardless of whether 'ga' has changed.

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Is the RTOS preemptive? –  RedX Apr 25 '12 at 10:16
    
Heh! Good point, but lets assume it is.. –  Martin James Apr 25 '12 at 10:17
    
Yes, assume it is preemptive and also ISR may change the 'ga'. –  user184258 Apr 25 '12 at 10:26
    
What threading standard are you using? Is this a Windows threads question? A POSIX threads question? You have all, and only, the guarantees your particular threading standard, compiler, or platform provide. Since you don't tell us any of those three things, all bets are off. It's completely undefined behavior by the C standard, since it never mentions threads. –  David Schwartz Apr 25 '12 at 11:05
2  
Then the answer is that it cannot be done. Using just the C standard, it is impossible to safely exchange data between threads. You need something beyond the C standard like atomic operations, memory barriers, or the like. –  David Schwartz Apr 25 '12 at 12:31

4 Answers 4

Both these versions of code have undefined behaviour in the face of multiple threads executing the functions. Certainly different compilers can do different things regarding saving the global variable into registers, or not. What's more, there's no guarantee that assigning to a local variable can be done in an atomic way with respect to threads that are mutating the global variable.

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Then what is the reliable way to get a 'snapshot' of a global variable and then play with it without caring about whether its value has been updated or not? - except for using a lock. –  user184258 Apr 25 '12 at 10:09
    
Using a lock works. A specific compiler's implementation of volatile may be do enough to allow atomic reads and writes. But obviously without a lock you will still have races. –  David Heffernan Apr 25 '12 at 10:17
    
What would happen if this function was passed the address of ga in a parameter and had to dereference it? Would that change anything? –  Martin James Apr 25 '12 at 10:20
    
@Martin No that would not –  David Heffernan Apr 25 '12 at 10:27
    
That's what locks are for. Why would you not want to use a lock when you have the precise problem that locks perfectly solve? If your particular platform provides something else that does the same thing, then you can use it. But why not use a lock? –  David Schwartz Apr 25 '12 at 11:03

There is no rule in the C standard that requires the compiler to implement those functions differently. e.g. When working with registers, the compiler may or may not 'optimize out' the assignment from ga to a (i.e. By 'optimize out', I mean: load ga into a REG, then use the same REG to do the rest of the computation, using it as a). Or it may not do so.

If you want to implement a lock-free data structure:

  1. C99 offers nothing that can help you.
  2. C11 (very recent standard) offers you atomic data types.

If you are using C99, then you either need to:

  1. Use locks (and hence, not lock-free code)
  2. Be ready to write architecture specific code. The least you need to do is use a minimal set of atomic operations, as done in this library that implements lock-free data structures using atomic operations provided by the x86, x86_64, and ARM ISAs.

In an earlier version of this answer, I touched upon a side issue (which has to do with volatile, and which is really not relevant to your real question):

There is one case that can put a restriction on how func_b is implemented, but I am actually going off on a tangent here: If ga is declared as a volatile.

If ga is volatile, then each read on ga must load ga from memory afresh. i.e. in func_b, ga will be loaded from memory two times. Once for the comparison, and once to calculate the return value. The expected use is, for example say ga refers to a memory mapped I/O port. Then if value of ga changes in between the two reads, this will reflect in the return value. However, if you change ga in another thread, don't expect sane/defined behavior.

On the other hand, not having a volatile qualifier does not mean that ga will be read exactly once in func_b. And there is no qualifier that is the 'opposite of volatile'.

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I understand the use of volatile. My question is more about the opposite of what 'volatile' intends to achieve. I want to read 'ga' only once and use its value afterwards without reading it again, in order not to get inconsistent result (i.e. a>2 ? a-2 : 2-a) –  user184258 Apr 25 '12 at 10:31
2  
@user184258: There's absolutely no guarantee in whether your compiled code will have one read of ga or many and whether that read will be atomic. Sorry, the language standard does not guarantee you anything here. This may work as you want on some CPUs and with some compilers, but doesn't have to and on other CPUs and with other compilers won't. –  Alexey Frunze Apr 25 '12 at 10:50
    
@Alex +1. Right. Also: I edited the answer to clarify that 'not having volatile' does not guarantee a single read. –  ArjunShankar Apr 25 '12 at 11:14

the behaviour depends on which compiler you're using, every compiler has its own rules regarding the optimisation.

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There can be hardware-specific behavior as well, not just compiler-specific. –  Alexey Frunze Apr 25 '12 at 10:51

The two snippets are likely going to end up with identical machine code. Neither of them is safe in a multi-thread case.

volatile would force the creation of a temporary variable, but since the copy from "ga" into the volatile variable is not guaranteed to be atomic, this is not thread-safe.

The only safe way to write such code is with guards:

int func_a() {

    mtx_lock(&ga_mutex);
    int a = ga;
    mtx_unlock(&ga_mutex);

    return a>2 ? a-2 : 2-a;
}
share|improve this answer
    
Doesn't ga still need to be volatile? How would the compiler now that it can't move its read to before/after mutex operations? –  Alexey Frunze Apr 25 '12 at 11:06
    
@Alex No, ga doesn't need to be volatile. The compiler could know it many ways, but it's not your problem, it's the problem of whoever designed the mutex operations and whoever built the compiler. It must know somehow, otherwise the mutex operations are broken. (One way it's commonly done is with a special compiler intrinsic built into the mutex invocations, called a clobber‌​. On some platforms, it "just works" because the compiler can't assume the mutex operations themselves don't modify ga. It's platform-specific.) –  David Schwartz Apr 25 '12 at 11:39
    
@Alex Compilers may change the order in which the code is executed, if it can prove that the order does not affect the result. It may do such optimizations to give better instruction piping, branch prediction and so on. In a multi-threaded, multi-core environment, such optimizations can be dangerous, if one core makes assumptions and decides to cache instructions before the code is executed, then the other core modifies the value. To prevent bugs like that, the concept of memory barriers must be used. (continued ->) –  Lundin Apr 25 '12 at 12:55
    
@Alex In some instances, the compiler implements memory barriers through the volatile keyword, but this is not guaranteed. Some compilers/OS implement memory barriers together with the mutex locks (I believe this is most common). There is no standard for it. –  Lundin Apr 25 '12 at 12:57

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