From the CUDA Programming Guide (v. 5.5):
The CUDA programming model assumes a device with a weakly-ordered memory model, that is:
- The order in which a CUDA thread writes data to shared memory, global memory, page-locked host memory, or the memory of a peer device is not necessarily the order in which the data is observed being written by another CUDA or host thread;
- The order in which a CUDA thread reads data from shared memory, global memory, page-locked host memory, or the memory of a peer device is not necessarily the order in which the read instructions appear in the program for instructions that are independent of each other
However, do we have a guarantee that the (dependent) memory operations as seen from the single thread are actually consistent? If I do - say:
arr[x] = 1; int z = arr[y];
x happens to be equal to
y, and no other thread is touching the memory, do I have a guarantee that
z is 1? Or do I still need to put some
volatile or a barrier between those two operations?
In response to Orpedo's answer.
If your compiler doesn't compile the functionality stated by your code into equal functionality in machine-code, the compiler is either broken or you haven't taken the optimizations into consideration...
My problem is what optimizations (done either by compiler or hardware) are allowed?
It could happen --- for example --- that
store instruction is non-blocking and the
load instruction that follows somehow is managed by the memory controller faster than the already queued-up
I don't know CUDA hardware. Do I have a guarantee that the above will never happen?