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When a out-of-order processor encounters something like

LOAD R1, 0x1337
LOAD R2, $R1
LOAD R3, 0x42

Assuming that all accesses will result in a cache miss, can the processor ask the memory controller for the contents of 0x42 before the it asks for the content of $R1 or even 0x1337? If so, assuming that accessing $R1 will result in a exception (e.g., segmentation fault), we can consider that 0x42 was loaded speculatively, correct?

And by the way, when a load-store unit sends a request to the memory controller, can it send a second request before receiving the answer to the previous one?

My question doesn't target any architecture in particular. Answers related to any mainstream architecture are welcomed.

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3 Answers 3

up vote 4 down vote accepted

Answer to your question depends on the memory ordering model of your CPU, which is not the same as the CPU allowing out of order execution. If the CPU implements Total store ordering (eg x86 or Sparc) then the answer to your question is 0x42 will not be loaded before 0x1337

If the cpu implements a relaxed memory model (eg IA-64, PowerPC, alpha), then in the absence of a memory fence instruction all bets are off as to which will be accessed first. This should be of little relevance unless you are doing IO, or dealing with multi-threaded code.

you should note that some CPU's (eg Itanium) do have relaxed memory models (so reads may be out of order) but do NOT have any out of order execution logic since they expect the compiler to order the instructions and speculative instructions in an optimal way rather than spend silicon space on OOE

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Thank you for the answer! –  João Fernandes Oct 8 '12 at 9:48
    
Is this still true with today's NUMA x86? I can't think of a particularly efficient way to enforce write ordering across different memory controllers. –  tc. Jan 18 '13 at 22:45
    
Yes. It's true because the CPU's have a cache coherency protocol on the x86, as explained in detail in the intel developers manual. Intel can't change this without breaking binary compatibility with existing software (including my own). www.multicoreinfo.com/research/papers/2008/damp08-intel64.pdf or other intel documents. It's also why if you try and have different CPU's access different memory locations that are next to eachother and hence on the same cache line the performance is likely to be ghastly –  camelccc Jan 19 '13 at 12:46
    
Umm... I can assure you that Intel x86 processors perform speculative memory accesses. Since P6 circa 1996. However, they only perform such speculative memory accesses to memory locations that the OS has indicated are ordinary memory (WB), not uncached memory that may have side effects (UC), marked using the MTRRs. And processors that do such speculation typically have logic to detect violations of the memory ordering model. // I.e. Intel x86 does speculative loads, but detects violations so that most programmers won't notice. But some low level programmers may notice. –  Krazy Glew Jul 30 at 18:41
    
@ Krazy Glew x86 CPU's can indeed prefetch what they like into the cache any time they like. The question states cache misses though, and the CPU can't reorder reads from memory (or cache) into registers, since if it did you have a memory ordering violation if another core in the system writes to one of these locations. Any other CPU in the system can use 0x42 to indicate that it's finished some result stored in 0x1337 in this example, a fact which the programmer can use immediately, or after executing 100000 more instructions. (this in total contrast to RMO) –  camelccc Aug 2 at 20:57

This would seem to be the a logical conclusion for superscalor CPUs with multiple load-store units too. Multi-channel memory controllers are pretty common these days.

In the case of out-of-order instruction execution, an enormous amount of logic is expended in determining whether instructions have dependancies on others in the stream - not just register dependancies but also operations on memory as well. There's also an enormous amount of logic for handling exceptions: the CPU needs to complete all instructions in the stream up to the fault (or alternatively, offload some parts of this onto the operating system).

In terms of the programming model seen by most applications, the effects are never apparent. As seen by memory, it's implicit that loads will not always happen in the sequence expected - but this is the case any way when caches are in use.

Clearly, in circumstances where the order of loads and stores does matter - for instance in accessing device registers, OOE must be disabled. The POWER architecture has the wonderful EIEIO instruction for this purpose.

Some members of the ARM Cortex-A family offer OOE - I suspect with the power constraints of these devices, and the apparent lack of instructions for forcing ordering, that load-stores always complete in order

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Marko, thank you for your answer. As you state, I'm stating a logical assumption for OOE/superscalar CPUs, but I really want to know if it is really true or not :) –  João Fernandes Sep 21 '12 at 8:34
    
The ARM (v6?) Architecture Reference Manual refers to something called called DataMemoryBarrier (perhaps a pseudo-instruction or macro?) which is actually a write to CP15. I'm not sure if it's privileged (it's next to things like cache-disabling which ought to be privileged), but it's there. –  tc. Sep 22 '12 at 21:52
    
The dmb (pseudo)instruction is memory barrier (aka memory fence). It's the only such instruction provided in ARMv7 (other architectures provide much more specific load and store fences). This does indeed force completion ordering, but also protects against other hazards where hardware (or a thread running on another core) is relying on effects of stores becoming visible. It's a non-privilidged instruction, and there are a few scenarios in user-space code where you needs it - such as implementing atomic operations. –  marko Sep 22 '12 at 23:54
    
ARM also provides ISB and DSB, you can have a look at ARM ARM for their use cases and their effects on pipeline, system buses. –  user1075375 Sep 28 '12 at 6:17

A compliant SPARC processor must implement TSO but may also implement RMO and PSO. You need to know what mode your OS is running in unless you happen to know your specific hardware platform has not implemented RMO and PSO.

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Thank you Spark Ler. I was aware of that fact but is good to have it here for the sake of completion. –  João Fernandes Feb 8 '13 at 9:47
    
True, BUT all versions of Solaris run the thing in TSO only. The ultrasparc III and later only implement TSO, with the result that I'm pretty sure that linux dropped RMO and PSO support years ago. If anyone knows of a Sparc configuration that supports RMO I'd like to know about it. –  camelccc Feb 10 '13 at 21:08

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