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for nearly six month now, I am developing a special purpose ray caster based on CUDA that works quite well except for its GFLOPS-utilization of the GPU. In the NSIGHT 2.2 VS2010 profiler, all normally critical values - as branch efficiency, warp issue efficiency or replay overheads - seem to be ok (see below).

According to the profiler's measurements, the ray caster achieves only 17 % of the GPU's peak performance (216 vs 1267 GFLOPS).

My thought was that the relatively low number of executed IPC [1.92] (max for compute capability 2.1 is 4) is responsible for this result. As far as I know, this number depends on

  • the occupancy [0.77] (and with it the number of eligible warps [3.79])
  • the instruction serialization [0.04] as well as
  • the execution dependency cycles [16.42] and
  • the instruction mix [0.65 FMA].

Given these values, I cannot see any other factor that may limit the ray caster that much than the high number of average execution dependency cycles. As the execution dependency [0.49] is also the main stall reason my questions are:

  1. How to decrease these execution dependency cycles?

  2. Is there any other profiler's value that may cause the weak GFLOPS performance?

  3. What is a realistic ratio of achievable performance any way?

For completion:

  • I use only float precision operations.
  • The global load cache hit rates are not very good because the ray caster copies the triangles from their acceleration structure into a special shared memory cache only once and leaves them and the global memory untouched further on (except for local memory accesses of course).

Thank you for your time,

Tratos


Profiler Measurements

General

GPU:                        Geforce 560 Ti
compute capability:                    2.1
code generation:          compute_20,sm_21
number or CUDA cores:                  384
peak performance:              1267 GFLOPS

Setting

registers per thread:                   20
dynamic shared memory:         6,748 bytes
local memory:             25,952,256 bytes
grid dimension:                  {68,68,1}
block dimension:                  {32,2,4}

Occupancy

achieved occupancy:                   0.77
theoretical occupancy:                1.00

Instruction Statistic

GPU issued IPC:                       2.00
GPU executed IPC:                     1.92
GPU SM activity:                      1.00
GPU serialization:                    0.04

Branch Statistic

branch efficiency:                    0.92
divergence:                           0.08
control flow efficiency:              0.92

Issue Efficiency

active warps per active cycle:       36.73
eligible warps per active cycle:      3.79

execution dependency cycles (short): 16.42
execution dependency cycles (long):   5.31
max dependency utilization:           0.92

warp issue efficiency (no eligible):  0.07
warp issue efficiency (one eligible): 0.15

instruction fetch stall reason:       0.35
execution dependency stall reason:    0.49
data request stall reason:            0.08
synchronization stall reason:         0.02
other stall reason:                   0.06

Memory Statistic

global replay overhead:               0.01
local replay overhead:                0.06
local replay overhead:                0.06
shared replay overhead:               0.01
bank conflicts/shared requests:       0.03

global transactions/requests (load):  2.44
global transactions/requests (store): 2.00
local transactions/requests (load):   1.04
local transactions/requests (store):  1.00
shared transactions/requests (load):  1.03
shared transactions/requests (store): 2.83

global L1 cache hit rate (load):      0.42
local L1 cache hit rate (load):       0.25
local L1 cache hit rate (store):      0.36
L2 cache hit rate (load):             0.67

FLOPS and Operations

FMA operations percentage:            0.65
MUL operations percentage:            0.24
ADD operations percentage:            0.10
special operations percentage:        0.01

singe FLOP count:            6,873,872,383
runtime:                             32 ms
single GFLOPS:                      216.63
share|improve this question
    
What does "local memory: 25,952,256" mean? –  talonmies Mar 28 '13 at 17:35
    
@talonmies The ray caster's kernel uses 25952256 bytes in local memory, which are all statically allocated. –  Tratos Mar 29 '13 at 13:59
    
I understand that, but the number doesn't make sense, It isn't evenly divisible by the block size, for example. I don't use Nsight and have never seen local memory usage written like that before. It is probably why your kernel isn't meeting your performance expectations and why the cache hit performance is rather low. –  talonmies Mar 29 '13 at 15:25
    
According to the ptxas info, a thread needs a stack frame of 8320 byte in local memory. Given that we have 256 threads per block and 6 active blocks per SM, with 8 SMs (560 Ti), the allocated local memory should be 102,236,160 bytes; meaning factor 4!? –  Tratos Mar 29 '13 at 17:32
    
Forget my last comment: I read that the number of mentioned local memory bytes are reserved (!) for the kernel function(s). Furthermore, the stack frame size was not correct: My kernel has a stack frame of 152 bytes; a second kernel that is compiled together with the first one needs 424 bytes. Concerning the local memory: According to the profiler, the kernel loads 1.76 GB and stores 2.52 GB. Since Data Request is only for 7.7% a stall reason, I don't think that the local memory access is the major problem. –  Tratos Mar 30 '13 at 13:42

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