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I have the following code for interprocess communication through shared memory. One process writes to a log and the other reads from it. One way is to use semaphores, but here I'm using atomic flag (log_flag) of type atomic_t which resides inside the shared memory. The log (log_data) is also shared.

Now the question is, would this work for x86 architecture or do I need semaphores or mutexes? What if I make log_flag non-atomic? Given x86 has a strict memory model and proactive cache coherence, and optimizations are not applied on pointers, I think it would still work?

EDIT: Note that I have a multicore processor with 8 cores, so I don't have any problem with busy waits here!

// Process 1 calls this function
void write_log( void * data, size_t size )
    while( *log_flag )
    memcpy( log_data, data, size );
    *log_flag = 1;

// Process 2 calls this function
void read_log( void * data, size_t size )
    while( !( *log_flag ) )
    memcpy( data, log_data, size );
    *log_flag = 0;
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Having a multi-core processor doesn't make a busy-wait loop a good idea - you're needlessly burning power, and blocking out other unrelated processes. –  Oliver Charlesworth Jan 2 '12 at 18:55
Because you're just sending data serially, blocking is acceptable, and you don't want to mess with semaphores, you should use pipes. –  John K Jan 2 '12 at 19:49
@JonathanLeffler: volatile is useless for multithreading. –  GManNickG Jan 2 '12 at 20:17
@GMan, volatile is not useless in every case. Here is will say to compiler that it should re-read the *log_flag from memory at every iteration, and not to cache the value in register (converting busy-loop into infinite loop). When we have 2 processes on 2 CPUs and there is a shared memory, the change in the memory looks for compiler very like memory-mapped hardware operation or like signal handler operation. –  osgx Jan 2 '12 at 23:53
Without volatile the compiler is free to optimize this code while( *log_flag ) ; to int tmp = *log_flag; while(tmp) ;. Volatile is not useless, it just doesn't work like volatile in Java. –  Bartosz Milewski Jan 3 '12 at 18:11

4 Answers 4

You may want to use the following macro in the loop, to avoid stressing the memory bus:

#if defined(__x86_64) || defined(__i386)
#define cpu_relax() __asm__("pause":::"memory")
#define cpu_relax() __asm__("":::"memory")

Also, it acts as a memory barrier ("memory" param.), so no need to declare log_flag as volatile.

But I think this is overkill, it should only be done for hard real-time stuff. You should be fine using a futex. And maybe you could simply use a pipe, it's sufficiently fast for almost all purposes.

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Unless log_flag is volatile, there is no guarantee that it is read or written at all. A barrier only affects observable behaviour. –  Simon Richter Jan 4 '12 at 9:39
@SimonRichter: What are you talking about? that just doesn't make any sense... isn't exactly observable behavior what matters for consistency? –  Ismael Jan 4 '12 at 10:05
sorry, my bad, I was thinking about run-time barriers rather than compile time. –  Simon Richter Jan 4 '12 at 10:16

I wouldn't recommend that for two reasons: first, although pointer access may not be optimized by the compiler, that doesn't mean the pointed value won't be cached by the processor. Second, the fact that it is atomic won't prevent a read access between the end of the while loop and the line that does *log_flag=0. A mutex is safer, though a lot slower.

If you're using pthreads, consider using an RW mutex to protect the whole buffer, that way you don't need a flag to control it, the mutex is itself the flag and you'll have better performance when doing frequent reads.

I also don't recommend doing empty while() loops, you'll hog all the processor that way. Put a usleep(1000) inside the loop to give the processor a chance to breathe.

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Busy waits aren't as bad as you put it out to be. Particularly if you have a multiprocessor system and want to take advantage of it. –  Jeff Mercado Jan 2 '12 at 18:50
@Jeff: Can you elaborate? I don't see how causing 100% CPU utilization and completely using up your scheduled time slice every time during the wait, thus lowering the priority of the process should be "taking advantage of MP systems". –  Niklas B. Jan 2 '12 at 18:55
@NiklasBaumstark: If you know you won't be waiting very long for a resource, the busy wait can save you the overhead of context switching out and waiting to be scheduled again. It won't work well if on a single processor system (since you'll have to context switch out anyway). They have their uses, you just have to be mindful of what resources are being protected and the system architecture. –  Jeff Mercado Jan 2 '12 at 19:18
@FabioCeconello: doesn't make any difference. Unless you're talking about the early (i.e. pre-Pentium) x86 SMP systems... –  Ismael Jan 3 '12 at 1:33
@Ismael I think your suggestion about futex is probably the best balance of performance and safety. Didn't know it existed, one more thing learned :-) . –  Fabio Ceconello Jan 3 '12 at 20:05

There are a whole bunch of reasons why you should use a semaphore and not rely on a flag.

  1. Your read log while loop is spinning unnnecessarily. This consumes system resources like power unnecessarly. It also means that the CPU cannot be used for other tasks.
  2. I will be surprised if x86 fully guarantees read and write ordering. incoming data may set log flag to 1 only to have outgoing data set it to 0. This may potentially mean that you end up losing data.
  3. I don't know where you got it from that optimizations are not applied on pointers as a general use. Optimization can be applied anywhere where there is no difference to external change. The compiler will probably not know that log_flag can be changed by a concurrent process.

Problem 2 might appear very may appear rarely and tracking down the issue will be hard. So do yourself a favour and use the correct operating system primitives. They will guarantee that things work as expected.

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If pointers could be optimized, why was the restrict keyword invented in C99? The compiler takes no risk with pointers, as they can point anywhere in the memory. –  MetallicPriest Jan 2 '12 at 19:27
x86 guarantees write ordering, but only within a CPU, and doesn't guarantee read ordering even within a CPU. –  ugoren Jan 2 '12 at 19:44
@doron: x86 snoops the memory bus and invalidates proactively. –  Ismael Jan 3 '12 at 0:34
@ugoren: x86 cache is strongly coherent, so by-design it can't do write re-ordering, unless the corresponding memory page is marked for write-combining (via MTRRs or PAT), something you must do explicitly anyway... –  Ismael Jan 3 '12 at 0:34
@MetallicPriest: Well, broken is perhaps a bit strong, sorry. Instead, I'll say subtle and fragile, and in the absence of benchmarks showing that the OS provided synchronization primitives are too slow, pointless for production code (it's fine as a learning exercise, of course!). Also, what is atomic_t? Neither C, C++, GCC or POSIX has any type like that, and Googling only finds some Linux kernel internal type. So presumably it's your own type(def). Thus for all we know, it might be a type for which x86 does not guarantee atomic reads/writes. –  janneb Jan 4 '12 at 10:00

As long as log_flag is atomic you will be fine.

If log_flag was just a regular bool, you have no guarantee it will work.

The compiler could reorder you instructions

*log_flag = 1;
memcpy( log_data, data, size );

This is semantically identical on a uniprocessor system as long as log_flag is not accessed inside memcpy. Your only saving grace may be an inferior optimizer that cant deduce what variables are accessed in memcpy.

The cpu can reorder your instructions
It may choose to load the log_flag before the loop to optimize the pipeline.

The cache may reorder you memory writes.
The cache line that contains log_flag may get synced to the other processor before the cache line containing data.

What you need is a way to tell the compiler, cpu, and cache "hands off", so that they don't make assumptions about the order. That can only be done with a memory fence. std::atomic, std::mutex, and semaphore all have the correct memory fence instructions embedded in their code.

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log_flag is not accessed inside memcpy, its log_data. –  MetallicPriest Jan 5 '12 at 18:07

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