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As far as I have understood, mfence is a hardware memory barrier while asm volatile ("" : : : "memory") is a compiler barrier. But,can asm volatile ("" : : : "memory") be used in place of mfence.

The reason I have got confused is this link

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What CPU are you compiling for? x86/x64? –  Peter Ritchie Aug 29 '12 at 17:36
    
I am using both x86 and x64. Should the answer vary for x86 and x64 machines? –  Neal Aug 30 '12 at 4:57
    
Well, a memory barrier is only needed on architectures that have weak memory ordering. x86 and x64 don't have weak memory ordering. on x86/x64 all stores have a release fence and all loads have an acquire fence. so, you should only really need asm volatile ("" : : : "memory") –  Peter Ritchie Aug 30 '12 at 15:03
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"on x86/x64 all stores have a release fence and all loads have an acquire fence". can you point to me some relevant docs regarding this. You can also make that an answer and I will accept, as that will answer my question :) –  Neal Aug 30 '12 at 19:00
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2 Answers

Well, a memory barrier is only needed on architectures that have weak memory ordering. x86 and x64 don't have weak memory ordering. on x86/x64 all stores have a release fence and all loads have an acquire fence. so, you should only really need asm volatile ("" : : : "memory")

For a good overview of both Intel and AMD as well as references to the relavent manufacturer specs, see http://bartoszmilewski.com/2008/11/05/who-ordered-memory-fences-on-an-x86/

Generally things like "volatile" are used on a per-field basis where loads and stores to that field are natively atomic. Where loads and stores to a field are already atomic (i.e. the "operation" in question is a load or a store to a single field and thus the entire operation is atomic) the volatile field modifier or memory barriers are not needed on x86/x64. Portable code notwithstanding.

When it comes to "operations" that are not atomic--e.g. loads or stores to a field that is larger than a native word or loads or stores to multiple fields within an "operation"--a means by which the operation can be viewed as atomic are required regardless of CPU architecture. generally this is done by means of a synchronization primitive like a mutex. Mutexes (the ones I've used) include memory barriers to avoid issues like processor reordering so you don't have to add extra memory barrier instructions. I generally consider not using synchronization primitives a premature optimization; but, the nature of premature optimization is, of course, 97% of the time :)

Where you don't use a synchronization primitive and you're dealing with a multi-field invariant, memory barriers that ensure the processor does not reorder stores and loads to different memory locations is important.

Now, in terms of not issuing an "mfence" instruction in asm volatile but using "memory" in the clobber list. From what I've been able to read

If your assembler instructions access memory in an unpredictable fashion, add `memory' to the list of clobbered registers. This will cause GCC to not keep memory values cached in registers across the assembler instruction and not optimize stores or loads to that memory.

When they say "GCC" and don't mention anything about the CPU, this means it applies to only the compiler. The lack of "mfence" means there is no CPU memory barrier. You can verify this by disassembling the resulting binary. If no "mfence" instruction is issued (depending on the target platform) then it's clear the CPU is not being told to issue a memory fence.

Depending on the platform you're on and what you're trying to do, there maybe something "better" or more clear... portability not withstanding.

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+1 This is 99.9% correct, with the exception that stores to different locations are unordered in a multi-core system (if you need this, you need MFENCE). However, this is usually a "Yeah WTF... who cares?" thing. Instructions on the same core are always realized in the order they execute anyway, and loads/stores on different cores to the same location have the guarantees as you've described. –  Damon Aug 30 '12 at 21:15
    
@Peter thank you for posting this link. I had referred to it earlier as well and my doubt originated from the Peterson lock problem. So, the author mentions "Loads may be reordered with older stores to different locations" which may break the implementation of Peterson's algorithm and an mfence would be required to correctly implement it. But, would "asm volatile" be sufficient too? as it is just a compiler barrier and as mentioned on wikipedia too(en.wikipedia.org/wiki/… barriers prevent a compiler reordering, not the CPU reordering. –  Neal Aug 31 '12 at 10:07
    
@neal I had assumed you were talking about a single field that you wanted to synchronize across threads/cpus... I've added some detail to my answer w.r.t. non-atomic "operations". –  Peter Ritchie Aug 31 '12 at 14:43
    
Will MFENCE prevent out-of-order execution on the CPU? Often I see quoted use a serializing call like cpuid before rdtsc when your CPUI doesn't support rdtscp to prevent reordering around the call to rdtsc. Would using MFENCE have the same effect as cpuid? –  Steve Lorimer Sep 28 '12 at 5:54
    
MFENCE is full memory barrier (a combination of SFENCE and LFENCE), it "Performs a serializing operation on all load-from-memory and store-to-memory instructions that were issued prior the MFENCE instruction. This serializing operation guarantees that every load and store instruction that precedes the MFENCE instruction in program order becomes globally visible before any load or store instruction that follows the MFENCE instruction." –  Peter Ritchie Oct 1 '12 at 16:05
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In addition to the reference already given, here are some good references regarding memory consistency models, memory barriers, and the Intel white paper on memory ordering supported by their processors:

Shared memory consistency models: A tutorial (1996)

Memory Barriers: a Hardware View for Software Hackers

Intel 64 Architecture Memory Ordering

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thanks. I am a little low on time right now. I will read them later. –  Neal Aug 31 '12 at 10:09
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