# Why does padding the shared memory array by one column increase the speed of the kernel by 40%?

Why is this matrix transpose kernel faster, when the shared memory array is padded by one column?

I found the kernel at PyCuda/Examples/MatrixTranspose.

Source

``````import pycuda.gpuarray as gpuarray
import pycuda.autoinit
from pycuda.compiler import SourceModule
import numpy

block_size = 16

def _get_transpose_kernel(offset):
mod = SourceModule("""
#define BLOCK_SIZE %(block_size)d
#define A_BLOCK_STRIDE (BLOCK_SIZE * a_width)
#define A_T_BLOCK_STRIDE (BLOCK_SIZE * a_height)

__global__ void transpose(float *A_t, float *A, int a_width, int a_height)
{
// Base indices in A and A_t
int base_idx_a   = blockIdx.x * BLOCK_SIZE +
blockIdx.y * A_BLOCK_STRIDE;
int base_idx_a_t = blockIdx.y * BLOCK_SIZE +
blockIdx.x * A_T_BLOCK_STRIDE;

// Global indices in A and A_t
int glob_idx_a   = base_idx_a + threadIdx.x + a_width * threadIdx.y;
int glob_idx_a_t = base_idx_a_t + threadIdx.x + a_height * threadIdx.y;

/** why does the +1 offset make the kernel faster? **/
__shared__ float A_shared[BLOCK_SIZE][BLOCK_SIZE+%(offset)d];

// Store transposed submatrix to shared memory
A_shared[threadIdx.y][threadIdx.x] = A[glob_idx_a];

__syncthreads();

// Write transposed submatrix to global memory
A_t[glob_idx_a_t] = A_shared[threadIdx.x][threadIdx.y];
}
"""% {"block_size": block_size, "offset": offset})

kernel = mod.get_function("transpose")
kernel.prepare("PPii", block=(block_size, block_size, 1))
return kernel

def transpose(tgt, src,offset):
krnl = _get_transpose_kernel(offset)
w, h = src.shape
assert tgt.shape == (h, w)
assert w % block_size == 0
assert h % block_size == 0
krnl.prepared_call((w / block_size, h /block_size), tgt.gpudata, src.gpudata, w, h)

def run_benchmark():
from pycuda.curandom import rand
print pycuda.autoinit.device.name()
print "time\tGB/s\tsize\toffset\t"
for offset in [0,1]:
for size in [2048,2112]:

source = rand((size, size), dtype=numpy.float32)
target = gpuarray.empty((size, size), dtype=source.dtype)

start = pycuda.driver.Event()
stop = pycuda.driver.Event()

warmup = 2
for i in range(warmup):
transpose(target, source,offset)

pycuda.driver.Context.synchronize()
start.record()

count = 10
for i in range(count):
transpose(target, source,offset)

stop.record()
stop.synchronize()

elapsed_seconds = stop.time_since(start)*1e-3
mem_bw = source.nbytes / elapsed_seconds * 2 * count /1024/1024/1024

print "%6.4fs\t%6.4f\t%i\t%i" %(elapsed_seconds,mem_bw,size,offset)

run_benchmark()
``````

Output

``````Quadro FX 580
time    GB/s    size    offset
0.0802s 3.8949  2048    0
0.0829s 4.0105  2112    0
0.0651s 4.7984  2048    1
0.0595s 5.5816  2112    1
``````

Code adopted

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Adding the extra column probably reduces contention in shared memory. –  Paul R Aug 11 '11 at 10:43
Contention? Never heard of it in the CUDA context. Do you have some links to read about it? –  Framester Aug 11 '11 at 10:48
Does it, by any chance, pad the row's size to a power of 2? –  Piskvor Aug 11 '11 at 10:50
Hi Piskor, I was thinking the same, but the block_size (see top) is 16 and it is changed to 17. Also adding the padding to the row instead of the column, does not increase the speed... –  Framester Aug 11 '11 at 10:54
Contention = bank conflicts –  Paul R Aug 11 '11 at 22:01

## 1 Answer

The answer is shared memory bank conflicts. The CUDA hardware you are using arranges shared memory into 16 banks, and shared memory is sequentially "striped" across all of those 16 banks. If two threads try and access the same bank simultaneously, a conflict occurs and the threads must be serialized. This is what you are seeing here. By extending the stride of the shared memory array by 1, you are ensuring that the same column indices in successive rows of the shared array are on different banks, which eliminates most of the possible conflicts.

This phenomena (and an associated global memory phenomena called partition camping) is discussed in great depth in the "Optimizing Matrix Transpose in CUDA" paper which ships with the SDK matrix transpose example. It is well worth reading.

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Does this also explain, why 2112 is faster than 2048 with padding? Anyway +1 –  Framester Aug 11 '11 at 13:29