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I'm profiling a kernel that uses 25 registers per thread and 3568 bytes of shared memory per block in a GTX480. The kernel is configured to launch 16x16 threads and the thread cache preference is set to shared.

According to the specifications of the GTX480, the device has 32768 registers per SM, so It would be possible have 25 regs x 256 threads per block x 6 blocks per SM blocks running concurrently.

However, the Compute Visual Profiler and the Cuda Occupancy Calculator report that only 4 blocks will be active per SM. I was wondering why only 4 blocks would be active and not 5, as I expected.

The reason I found is that CUDA round up the number of registers used to 26, in which case, the number of active block is 4.

Why CUDA round up the number of registers? Because with 25 registers per thread and 256 threads per block it would be possible have up to 5 blocks per SM, which is obviously an advantage.

Environment setup:

Device 0: "GeForce GTX 480"
CUDA Driver Version / Runtime Version          5.0 / 4.0
ptxas info: Compiling entry function '_Z13kernellS_PiS0_iiS0_' for 'sm_20'
ptxas info: Used 25 registers, 3568+0 bytes smem, 80 bytes cmem[0], 16 bytes cmem[2]
0 bytes stack frame, 0 bytes spill stores, 0 bytes spill loads
kernel config: 16x16 threads per block
kernel config: cudaFuncCachePreferShared
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I'm not one of the chip designers, but I would expect this saves some logic on the chip. Nvidia might have opted to use a dedicated multiplier net for addressing registers (as opposed to using offset registers which need to be set up at kernel launch), in which case every bit eliminated from the multiplier saves quite a bit of logic and die space. – tera Oct 24 '12 at 10:22
    
tera's right, that is just how the hardware works. For kernels like this one, you probably can specify -maxregcount=24 and the compiler will fit everything it needs. – ArchaeaSoftware Oct 25 '12 at 13:23
    
@ArchaeaSoftware but that may split the register to local memory, or at least that it was i expected. I've compile it with that regcount and indeed only use 24 register and none of them split to local memory. Is that the nvcc magic behaviour? – pQB Oct 25 '12 at 15:18
    
You would think so, but CUDA's code generator knows that spilling to local memory is really slow, so if you impose a limit on the register count it will work hard to fit within that limit without spilling. For example, it might get rid of an induction variable and do a bit of extra computation instead. – ArchaeaSoftware Oct 25 '12 at 16:51
up vote 4 down vote accepted

You haven't interpreted what is happening correctly. There is no rounding of the number of registers per thread happening here, there is rounding of the number of registers per warp.

Your GPU allocated registers on a per warp basis, with a register "page size" of 64 registers (note I use that term loosely, I am not privy to the precise register file design). In your case a warp requires 25*32 = 800 registers, which must be rounded up to the nearest "page size" of 64, giving 832 registers per warp. Each block contains 8 warps (256 threads), so each block requires 6656 registers. The maximum number of blocks per SM for this kernel is then 32768 / 6656 rounded down to the nearest integer, ie. 4 blocks per SM rather than the 5 you expect.

So the very short answer is register file allocation granularity and page size is dictating how many blocks can be run per SM in this case.

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Exactly correct. The occupancy calculator lists the register allocation unit size (64 for sm_20) and register allocation granularity (per warp for sm_20). Note there is also a shared mem allocation unit size. – harrism Oct 24 '12 at 11:52

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