# N-Body CUDA optimization

I'm developing an N-body algorithm in CUDA and I would like to learn some tips and tricks for optimization.

I've managed to get `16384` bodies to run at `20Flops` on an NVIDIA Geforce GTX 260, which has `27` Streaming Multiprocessors.

The `KernelcomputeForces` function is the slow poke taking about `95%` of the time and I was wondering if there is anymore that I can do to optimize my code.

As far as I see, I've optimized for memory-space-locality and memory-writing. Somewhere in the CUDA docs, it says shared-memory is faster but I dont see how I can make use of that. I've divided the work in `16` blocks with `512` threads on each, but thats a bit fuzzy for me.

``````n   is number of bodies

gm  is the gpu mass pointer

gpx is the gpu position x pointer

gpy is the gpu position y pointer

gpz is the gpu position z pointer

gfx is the gpu force x pointer

gfy is the gpu force y pointer

gfz is the gpu force z pointer
``````

The relevant kernel function

``````__global__ void KernelcomputeForces( unsigned int n, float* gm, float* gpx, float* gpy, float* gpz, float* gfx, float* gfy, float* gfz ){
int tid = blockDim.x * blockIdx.x + threadIdx.x;
int numThreads = blockDim.x * gridDim.x;

float GRAVITY = 0.00001f;

//compare all with all
for( unsigned int ia=tid; ia<n; ia+=numThreads ){
float lfx = 0.0f;
float lfy = 0.0f;
float lfz = 0.0f;

for( unsigned int ib=0; ib<n; ib++ ){
//compute distance
float dx = ( gpx[ib] - gpx[ia]);
float dy = ( gpy[ib] - gpy[ia] );
float dz = ( gpz[ib] - gpz[ia] );
//float distance = sqrt( dx*dx + dy*dy + dz*dz );
float distanceSquared = dx*dx + dy*dy + dz*dz;

//prevent slingshots and division by zero
//distance += 0.1f;
distanceSquared += 0.01f;

//calculate gravitational magnitude between the bodies
//float magnitude = GRAVITY * ( gm[ia] * gm[ib] ) / ( distance * distance * distance * distance );
float magnitude = GRAVITY * ( gm[ia] * gm[ib] ) / ( distanceSquared );

//calculate forces for the bodies
//magnitude times direction
lfx += magnitude * ( dx );
lfy += magnitude * ( dy );
lfz += magnitude * ( dz );
}

//stores local memory to global memory
gfx[ia] = lfx;
gfy[ia] = lfy;
gfz[ia] = lfz;
}
}

extern void GPUcomputeForces( unsigned int n, float* gm, float* gpx, float* gpy, float* gpz, float* gfx, float* gfy, float* gfz ){
dim3 gridDim( 16, 1, 1 ); //specifys how many blocks in three possible dimensions
dim3 blockDim( 512, 1, 1 ); //threads per block
KernelcomputeForces<<<gridDim, blockDim>>>( n, gm, gpx, gpy, gpz, gfx, gfy, gfz );
}
``````
-
I agree, I don't see an immediate way to use shared memory in this code as each thread accesses all of the global memory. –  jmilloy Apr 10 '11 at 16:02

Shared memory is going to be a useful optimization in this sort of kernel - it allows coalescing of the reads of particle positions and masses, which on a GT200 will be very important. I found this to be about twice as fast as your version (launched with your 16384 particles using a 128 blocks of 128 threads):

``````template<int blocksize>
__global__
void KernelcomputeForces1( unsigned int n1, float* gm, float* gpx,
float* gpy, float* gpz, float* gfx, float* gfy, float* gfz )
{
__shared__ float lgpx[blocksize], lgpy[blocksize],
lgpz[blocksize], lgm[blocksize];

const float GRAVITY = 0.00001f;

//compare all with all
float lfx = 0.0f, lfy = 0.0f, lfz = 0.0f;
int ia = blockDim.x * blockIdx.x + threadIdx.x;
float lgpx0 = gpx[ia], lgpy0 = gpy[ia],
lgpz0 = gpz[ia], lgm0 = gm[ia];

for( unsigned int ib=0; ib<n1; ib+=blocksize ){

#pragma unroll
for(unsigned int ic=0; ic<blocksize; ic++) {

//compute distance
float dx = ( lgpx[ic] - lgpx0 );
float dy = ( lgpy[ic] - lgpy0 );
float dz = ( lgpz[ic] - lgpz0 );
float distanceSquared = dx*dx + dy*dy + dz*dz;

//prevent slingshots and division by zero
distanceSquared += 0.01f;

//calculate gravitational magnitude between the bodies
float magnitude = GRAVITY * ( lgm0 * lgm[ic] )
/ ( distanceSquared );

//calculate forces for the bodies
//magnitude times direction
lfx += magnitude * ( dx );
lfy += magnitude * ( dy );
lfz += magnitude * ( dz );
}
}

//stores local memory to global memory
gfx[ia] = lfx;
gfy[ia] = lfy;
gfz[ia] = lfz;
}
``````

You would need to do something a little different for the number of particles which fall outside the nice multiple of block size, probably a second stanza which won't be unrolled. Watch the potential for warp divergence with the __syncthreads() calls, that can make the kernel hang if you are not careful.

-
thanks this was very helpful –  ColacX Apr 24 '11 at 19:44
i wonder though if i have 27 Multiprocessors wouldn't it be optimum to use 27 threads? –  ColacX Apr 24 '11 at 19:57
No. Every multiprocessor on a gt200 class gpu needs at least 192 threads just to cover the instruction pipeline latency. You want the number of blocks to be a round multiple of 27 - any block only ever run on a single multiprocessor, with each block having an round multiple of 32 threads, which is the basic scheduling granularity of the GPU. –  talonmies Apr 24 '11 at 20:23
okay thank all ive got all i wanted to know now. next up, water particle simulation :D –  ColacX Apr 25 '11 at 15:51

Before doing anything else, try running more blocks. A given block only ever runs on a single SM - by using only 16 blocks you are guaranteeing that about 40% of the GPU capacity will be idle. Some multiple of 27 should be the optimal number of blocks on your GTX260-216. You might also find that reducing the number of threads per block won't hurt performance, so that you can keep about the same amount of work per thread, but just do it with enough blocks to cover all the SM in the GPU.

EDIT: Just to illustrate the point, consider this little test harness for your kernel:

``````template<int blocksize, int gridsize>
extern float GPUcomputeForces( unsigned int n, float* gm, float* gpx, float* gpy, float* gpz, float* gfx, float* gfy, float* gfz ){
float time;

dim3 gridDim( gridsize, 1, 1 ); //specifys how many blocks in three possible dimensions
dim3 blockDim( blocksize, 1, 1 ); //threads per block

cudaEvent_t start, stop;
errchk( cudaEventCreate(&start) );
errchk( cudaEventCreate(&stop) );

errchk( cudaEventRecord(start, 0) );
KernelcomputeForces<<<gridDim, blockDim>>>( n, gm, gpx, gpy, gpz, gfx, gfy, gfz );
rterrchk;

errchk( cudaEventRecord(stop, 0) );
errchk( cudaEventSynchronize(stop) );
errchk( cudaEventElapsedTime(&time, start, stop) );

return time;
}

int main(void)
{
const int n = 16384;
size_t gsize = sizeof(float) * size_t(n);

float * g[4], * _g[7];

errchk( cudaSetDevice(1) );  // GTX 275

for(int i=0; i<7; i++)
errchk( cudaMalloc((void **)&_g[i], gsize) );

for(int i=0; i<4; i++)
g[i] = (float *)malloc(gsize);

for(int i=0; i<n; i++)
for(int j=0; j<4; j++)
*(g[j]+i) = (float)drand48();

for(int i=0; i<4; i++)
errchk( cudaMemcpy(_g[i], g[i], gsize, cudaMemcpyHostToDevice) );

// Warm up to take context establishment time out.
GPUcomputeForces<16,512>(n,_g[0],_g[1],_g[2],_g[3],_g[4],_g[5],_g[6]);

// Bench runs
printf("(1,1)@(512,1,1): %f\n", GPUcomputeForces<1,512>(n,_g[0],_g[1],_g[2],_g[3],_g[4],_g[5],_g[6]) );
printf("(8,1)@(512,1,1): %f\n", GPUcomputeForces<8,512>(n,_g[0],_g[1],_g[2],_g[3],_g[4],_g[5],_g[6]) );
printf("(16,1)@(512,1,1): %f\n", GPUcomputeForces<16,512>(n,_g[0],_g[1],_g[2],_g[3],_g[4],_g[5],_g[6]) );
printf("(30,1)@(256,1,1): %f\n", GPUcomputeForces<30,256>(n,_g[0],_g[1],_g[2],_g[3],_g[4],_g[5],_g[6]) );
printf("(60,1)@(128,1,1): %f\n", GPUcomputeForces<60,128>(n,_g[0],_g[1],_g[2],_g[3],_g[4],_g[5],_g[6]) );
printf("(120,1)@(64,1,1): %f\n", GPUcomputeForces<120,64>(n,_g[0],_g[1],_g[2],_g[3],_g[4],_g[5],_g[6]) );
printf("(240,1)@(32,1,1): %f\n", GPUcomputeForces<240,32>(n,_g[0],_g[1],_g[2],_g[3],_g[4],_g[5],_g[6]) );

return 0;
}
``````

When I run that, I get the following execution times on a stock GTX 275 (all times are in milliseconds):

``````(1,1)@(512,1,1): 1087.107910
(8,1)@(512,1,1): 135.582458
(16,1)@(512,1,1): 67.876671
(30,1)@(256,1,1): 54.881279
(60,1)@(128,1,1): 35.261280
(120,1)@(64,1,1): 36.316288
(240,1)@(32,1,1): 39.870495
``````

Ie: Running at least as many blocks as there are MP on the card is critical to improving performance, even when using very small block sizes.

-
what you just asked me to do was just plain wrong. changed from 16 -> 27 reduced my fps to 16. changed from 512 -> 256 reduced my fps to 10 –  ColacX Apr 10 '11 at 15:27
@ColacX - you will want to try MANY kernel configurations. Different configurations have a major impact, and usually have sweet spots. –  jmilloy Apr 10 '11 at 15:43
@ColacX - I am very surprised by that. My own benchmarking of your kernel on a similar card (a GTX 275) clearly shows that the kernel execution time with at least as many blocks as your card has SM gives almost a halving of kernel execution time. Precisely as I predicted. See my edit for more information. –  talonmies Apr 10 '11 at 17:31
`code (16,1)@(512,1,1): 36.050186 ms (32,1)@(256,1,1): 35.151672 ms (48,1)@(256,1,1): 34.227173 ms (64,1)@(128,1,1): 31.856787 ms (27,1)@(512,1,1): 40.098667 ms (54,1)@(64,1,1): 60.681877 ms (54,1)@(128,1,1): 40.320881 ms (54,1)@(256,1,1): 36.719494 ms (54,1)@(512,1,1): 39.685223 ms (81,1)@(64,1,1): 50.386776 ms (81,1)@(128,1,1): 31.069546 ms (81,1)@(256,1,1): 36.522266 ms (81,1)@(512,1,1): 39.731533 ms (108,1)@(64,1,1): 40.844597 ms (108,1)@(128,1,1): 35.667061 ms (108,1)@(256,1,1): 35.841301 ms (108,1)@(512,1,1): 39.554295 ms ` multiples of 27 does not seem to improve that much –  ColacX Apr 11 '11 at 23:12
damnit where did my newlines go??? –  ColacX Apr 11 '11 at 23:14

The cuda profiler will tell you information about occupancy, conditional branching, global memory usage (cache misses or uncoalesced reads, depending on cuda version), and more. It is an essential part of optimizing your kernel.

-
oh didnt know there was one ill check it out although i bet theres nothing obvious i can see in the profiler. could still use some tips on changing the code –  ColacX Apr 11 '11 at 23:16

@talonmies has already answered this question, showing how shared memory is helpful to improve performance. So, there is not much more to add. I just want to provide a full code, with different optimization steps, including tiling, shared memory, and shuffle operations, and show some results of a testing performed on a Kepler K20c.

The code below, moulded around what presented by @talonmies, has `5` kernel functions, namely

`KernelcomputeForces`: no optimization

`KernelcomputeForces_Shared`: exploits tiling in the source masses and shared memory

`KernelcomputeForces_Tiling`: exploits tiling in the destination masses

`KernelcomputeForces_Tiling_Shared`: exploits both tiling in the source and destination masses and exploits shared memory

`KernelcomputeForces_Tiling_Shuffle`: same as above, but uses shuffle operations instead of shared memory.

Perhaps, as compared to what already published in the literature (Fast N-Body Simulation with CUDA) and what already available as codes (see the above answers and Mark Harris' GitHub N-body page, the last kernel is the only new thing. But I have played a bit with N-body, and found it useful to post this answer, potentially useful to next users.

Here is the code

``````#include <stdio.h>

#define GRAVITATIONAL_CONST 6.67*1e−11
#define SOFTENING 1e-9f

/********************/
/* CUDA ERROR CHECK */
/********************/
#define gpuErrchk(ans) { gpuAssert((ans), __FILE__, __LINE__); }
inline void gpuAssert(cudaError_t code, char *file, int line, bool abort=true)
{
if (code != cudaSuccess)
{
fprintf(stderr,"GPUassert: %s %s %d\n", cudaGetErrorString(code), file, line);
if (abort) exit(code);
}
}

/**********/
/* iDivUp */
/**********/
int iDivUp(int a, int b) { return ((a % b) != 0) ? (a / b + 1) : (a / b); }

/*******************/
/* KERNEL FUNCTION */
/*******************/
template<int BLOCKSIZE>
__global__
void KernelcomputeForces(float* m_d, float* x_d, float* y_d, float* z_d, float* fx_d, float* fy_d, float* fz_d, unsigned int N)
{
int tid = blockDim.x * blockIdx.x + threadIdx.x;

if (tid < N) {

float invDist, invDist3;

// --- Initialize register accumulators for forces
float fx_temp = 0.0f, fy_temp = 0.0f, fz_temp = 0.0f;

// --- Move target particle data to registers
float x_reg = x_d[tid], y_reg = y_d[tid], z_reg = z_d[tid], m_reg = m_d[tid];

// --- Interact all with all
for(unsigned int ib=0; ib<N; ib++) {

// --- Compute relative distances
float dx = (x_d[ib] - x_reg);
float dy = (y_d[ib] - y_reg);
float dz = (z_d[ib] - z_reg);
float distanceSquared = dx*dx + dy*dy + dz*dz;

// --- Prevent slingshots and division by zero
distanceSquared += SOFTENING;

float invDist = rsqrtf(distanceSquared);
float invDist3 = invDist * invDist * invDist;

// --- Calculate gravitational magnitude between the bodies
float magnitude = GRAVITATIONAL_CONST * (m_reg * m_d[ib]) * invDist3;

// --- Calculate forces for the bodies: magnitude times direction
fx_temp += magnitude*dx;
fy_temp += magnitude*dy;
fz_temp += magnitude*dz;
}

// --- Stores local memory to global memory
fx_d[tid] = fx_temp;
fy_d[tid] = fy_temp;
fz_d[tid] = fz_temp;
}
}

/**********************************/
/* KERNEL FUNCTION: SHARED MEMORY */
/**********************************/
template<int BLOCKSIZE>
__global__
void KernelcomputeForces_Shared(float* m_d, float* x_d, float* y_d, float* z_d, float* fx_d, float* fy_d, float* fz_d, unsigned int N)
{
int tid = blockDim.x * blockIdx.x + threadIdx.x;

if (tid < N) {

float invDist, invDist3;

__shared__ float x_sh[BLOCKSIZE], y_sh[BLOCKSIZE], z_sh[BLOCKSIZE], m_sh[BLOCKSIZE];

// --- Initialize register accumulators for forces
float fx_temp = 0.0f, fy_temp = 0.0f, fz_temp = 0.0f;

// --- Move target particle data to registers
float x_reg = x_d[tid], y_reg = y_d[tid], z_reg = z_d[tid], m_reg = m_d[tid];

// --- Interact all with all
for(unsigned int ib=0; ib<N; ib+=BLOCKSIZE) {

#pragma unroll
for(unsigned int ic=0; ic<BLOCKSIZE; ic++) {

// --- Compute relative distances
float dx = (x_sh[ic] - x_reg);
float dy = (y_sh[ic] - y_reg);
float dz = (z_sh[ic] - z_reg);
float distanceSquared = dx*dx + dy*dy + dz*dz;

// --- Prevent slingshots and division by zero
distanceSquared += SOFTENING;

float invDist = rsqrtf(distanceSquared);
float invDist3 = invDist * invDist * invDist;

// --- Calculate gravitational magnitude between the bodies
float magnitude = GRAVITATIONAL_CONST * (m_reg * m_sh[ic]) * invDist3;

// --- Calculate forces for the bodies: magnitude times direction
fx_temp += magnitude*dx;
fy_temp += magnitude*dy;
fz_temp += magnitude*dz;
}
}

// --- Stores local memory to global memory
fx_d[tid] = fx_temp;
fy_d[tid] = fy_temp;
fz_d[tid] = fz_temp;
}
}

/***************************/
/* KERNEL FUNCTION: TILING */
/***************************/
template<int BLOCKSIZE>
__global__
void KernelcomputeForces_Tiling(float* m_d, float* x_d, float* y_d, float* z_d, float* fx_d, float* fy_d, float* fz_d, unsigned int N)
{
float invDist, invDist3;

for (unsigned int tid = blockIdx.x*blockDim.x + threadIdx.x;
tid < N;
tid += blockDim.x*gridDim.x) {

// --- Initialize register accumulators for forces
float fx_temp = 0.0f, fy_temp = 0.0f, fz_temp = 0.0f;

// --- Move target particle data to registers
float x_reg = x_d[tid], y_reg = y_d[tid], z_reg = z_d[tid], m_reg = m_d[tid];

// --- Interact all with all
for(unsigned int ib=0; ib<N; ib++) {

// --- Compute relative distances
float dx = (x_d[ib] - x_reg);
float dy = (y_d[ib] - y_reg);
float dz = (z_d[ib] - z_reg);
float distanceSquared = dx*dx + dy*dy + dz*dz;

// --- Prevent slingshots and division by zero
distanceSquared += SOFTENING;

float invDist = rsqrtf(distanceSquared);
float invDist3 = invDist * invDist * invDist;

// --- Calculate gravitational magnitude between the bodies
float magnitude = GRAVITATIONAL_CONST * (m_reg * m_d[ib]) * invDist3;

// --- Calculate forces for the bodies: magnitude times direction
fx_temp += magnitude*dx;
fy_temp += magnitude*dy;
fz_temp += magnitude*dz;
}

// --- Stores local memory to global memory
fx_d[tid] = fx_temp;
fy_d[tid] = fy_temp;
fz_d[tid] = fz_temp;
}
}

/*******************************************/
/* KERNEL FUNCTION: TILING + SHARED MEMORY */
/*******************************************/
template<int BLOCKSIZE>
__global__
void KernelcomputeForces_Tiling_Shared(float* m_d, float* x_d, float* y_d, float* z_d, float* fx_d, float* fy_d, float* fz_d, unsigned int N)
{
float invDist, invDist3;

for (unsigned int tid = blockIdx.x*blockDim.x + threadIdx.x;
tid < N;
tid += blockDim.x*gridDim.x) {

__shared__ float x_sh[BLOCKSIZE], y_sh[BLOCKSIZE], z_sh[BLOCKSIZE], m_sh[BLOCKSIZE];

// --- Initialize register accumulators for forces
float fx_temp = 0.0f, fy_temp = 0.0f, fz_temp = 0.0f;

// --- Move target particle data to registers
float x_reg = x_d[tid], y_reg = y_d[tid], z_reg = z_d[tid], m_reg = m_d[tid];

// --- Interact all with all
for(unsigned int ib=0; ib<N; ib+=BLOCKSIZE) {

#pragma unroll
for(unsigned int ic=0; ic<BLOCKSIZE; ic++) {

// --- Compute relative distances
float dx = (x_sh[ic] - x_reg);
float dy = (y_sh[ic] - y_reg);
float dz = (z_sh[ic] - z_reg);
float distanceSquared = dx*dx + dy*dy + dz*dz;

// --- Prevent slingshots and division by zero
distanceSquared += SOFTENING;

float invDist = rsqrtf(distanceSquared);
float invDist3 = invDist * invDist * invDist;

// --- Calculate gravitational magnitude between the bodies
float magnitude = GRAVITATIONAL_CONST * (m_reg * m_sh[ic]) * invDist3;

// --- Calculate forces for the bodies: magnitude times direction
fx_temp += magnitude*dx;
fy_temp += magnitude*dy;
fz_temp += magnitude*dz;
}
}

// --- Stores local memory to global memory
fx_d[tid] = fx_temp;
fy_d[tid] = fy_temp;
fz_d[tid] = fz_temp;
}
}

/************************************************/
/* KERNEL FUNCTION: TILING + SHUFFLE OPERATIONS */
/************************************************/
__global__
oid KernelcomputeForces_Tiling_Shuffle(float* m_d, float* x_d, float* y_d, float* z_d, float* fx_d, float* fy_d, float* fz_d, unsigned int N)
{
float invDist, invDist3;

const int laneid = threadIdx.x & 31;

for (unsigned int tid = blockIdx.x*blockDim.x + threadIdx.x;
tid < N;
tid += blockDim.x*gridDim.x) {

// --- Initialize register accumulators for forces
float fx_temp = 0.0f, fy_temp = 0.0f, fz_temp = 0.0f;

// --- Move target particle data to registers
float x_reg = x_d[tid], y_reg = y_d[tid], z_reg = z_d[tid], m_reg = m_d[tid];

// --- Interact all with all
for(unsigned int ib=0; ib<N; ib+=32) {

float x_src = x_d[ib + laneid];
float y_src = y_d[ib + laneid];
float z_src = z_d[ib + laneid];
float m_src = m_d[ib + laneid];

#pragma unroll 32
for(unsigned int ic=0; ic<32; ic++) {

// --- Compute relative distances
float dx = (__shfl(x_src, ic) - x_reg);
float dy = (__shfl(y_src, ic) - y_reg);
float dz = (__shfl(z_src, ic) - z_reg);
float distanceSquared = dx*dx + dy*dy + dz*dz;

// --- Prevent slingshots and division by zero
distanceSquared += SOFTENING;

float invDist = rsqrtf(distanceSquared);
float invDist3 = invDist * invDist * invDist;

// --- Calculate gravitational magnitude between the bodies
float magnitude = GRAVITATIONAL_CONST * (m_reg * __shfl(m_src, ic)) * invDist3;

// --- Calculate forces for the bodies: magnitude times direction
fx_temp += magnitude*dx;
fy_temp += magnitude*dy;
fz_temp += magnitude*dz;
}
}

// --- Stores local memory to global memory
fx_d[tid] = fx_temp;
fy_d[tid] = fy_temp;
fz_d[tid] = fz_temp;
}
}

/*****************************************/
/* WRAPPER FUNCTION FOR GPU CALCULATIONS */
/*****************************************/
template<int BLOCKSIZE>
float GPUcomputeForces(float* m_d, float* x_d, float* y_d, float* z_d, float* fx_d, float* fy_d, float* fz_d, unsigned int N) {
float time;

dim3 grid(iDivUp(N,BLOCKSIZE), 1, 1);       // --- Specifys how many blocks in three possible dimensions
dim3 block(BLOCKSIZE, 1, 1);                // --- Threads per block

cudaEvent_t start, stop;
gpuErrchk(cudaEventCreate(&start));
gpuErrchk(cudaEventCreate(&stop));

gpuErrchk(cudaEventRecord(start, 0));
KernelcomputeForces_Shared<BLOCKSIZE><<<grid, block>>>(m_d, x_d, y_d, z_d, fx_d, fy_d, fz_d, N);
//KernelcomputeForces_Tiling<BLOCKSIZE><<<grid, block>>>(m_d, x_d, y_d, z_d, fx_d, fy_d, fz_d, N);
//KernelcomputeForces<BLOCKSIZE><<<grid, block>>>(m_d, x_d, y_d, z_d, fx_d, fy_d, fz_d, N);
gpuErrchk(cudaPeekAtLastError());

gpuErrchk(cudaEventRecord(stop, 0));
gpuErrchk(cudaEventSynchronize(stop));
gpuErrchk(cudaEventElapsedTime(&time, start, stop));

return time;
}

/*****************************************/
/* WRAPPER FUNCTION FOR GPU CALCULATIONS */
/*****************************************/
template<int GRIDSIZE, int BLOCKSIZE>
float GPUcomputeForces_Tiling(float* m_d, float* x_d, float* y_d, float* z_d, float* fx_d, float* fy_d, float* fz_d, unsigned int N) {
float time;

dim3 grid(GRIDSIZE, 1, 1);      // --- Specifys how many blocks in three possible dimensions
dim3 block(BLOCKSIZE, 1, 1);    // --- Threads per block

cudaEvent_t start, stop;
gpuErrchk(cudaEventCreate(&start));
gpuErrchk(cudaEventCreate(&stop));

gpuErrchk(cudaEventRecord(start, 0));
//KernelcomputeForces_Tiling<BLOCKSIZE><<<grid, block>>>(m_d, x_d, y_d, z_d, fx_d, fy_d, fz_d, N);
KernelcomputeForces_Tiling_Shuffle<<<grid, block>>>(m_d, x_d, y_d, z_d, fx_d, fy_d, fz_d, N);
gpuErrchk(cudaPeekAtLastError());

gpuErrchk(cudaEventRecord(stop, 0));
gpuErrchk(cudaEventSynchronize(stop));
gpuErrchk(cudaEventElapsedTime(&time, start, stop));

return time;
}

/********************/
/* CPU CALCULATIONS */
/********************/
void CPUcomputeForces(float* m_h, float* x_h, float* y_h, float* z_h, float* fx_h, float* fy_h, float* fz_h, unsigned int N) {

for (unsigned int i=0; i<N; i++) {

float invDist, invDist3;

float fx_temp = 0.0f, fy_temp = 0.0f, fz_temp = 0.0f;

// --- Interact all with all
for(unsigned int ib=0; ib<N; ib++) {

// --- Compute relative distances
float dx = (x_h[ib] - x_h[i]);
float dy = (y_h[ib] - y_h[i]);
float dz = (z_h[ib] - z_h[i]);
float distanceSquared = dx*dx + dy*dy + dz*dz;

// --- Prevent slingshots and division by zero
distanceSquared += SOFTENING;

float invDist = 1.f / sqrtf(distanceSquared);
float invDist3 = invDist * invDist * invDist;

// --- Calculate gravitational magnitude between the bodies
float magnitude = GRAVITATIONAL_CONST * (m_h[i] * m_h[ib]) * invDist3;

// --- Calculate forces for the bodies: magnitude times direction
fx_temp += magnitude*dx;
fy_temp += magnitude*dy;
fz_temp += magnitude*dz;

}

// --- Stores local memory to global memory
fx_h[i] = fx_temp;
fy_h[i] = fy_temp;
fz_h[i] = fz_temp;
}
}

/********/
/* MAIN */
/********/
int main(void)
{
const int N = 16384;

size_t gsize = sizeof(float) * size_t(N);

float * g[10], * _g[7];

for(int i=0; i<7; i++) gpuErrchk( cudaMalloc((void **)&_g[i], gsize));

for(int i=0; i<10; i++) g[i] = (float *)malloc(gsize);

for(int i=0; i<N; i++)
for(int j=0; j<4; j++)
*(g[j]+i) = (float)rand();

for(int i=0; i<4; i++) gpuErrchk(cudaMemcpy(_g[i], g[i], gsize, cudaMemcpyHostToDevice));

// --- Warm up to take context establishment time out.
GPUcomputeForces<512>(_g[0],_g[1],_g[2],_g[3],_g[4],_g[5],_g[6],N);
//GPUcomputeForces_Tiling<32,512>(_g[0],_g[1],_g[2],_g[3],_g[4],_g[5],_g[6],N);

// --- Bench runs
printf("1024: %f\n",    GPUcomputeForces<512>   (_g[0],_g[1],_g[2],_g[3],_g[4],_g[5],_g[6],N));
printf("512:  %f\n",    GPUcomputeForces<512>   (_g[0],_g[1],_g[2],_g[3],_g[4],_g[5],_g[6],N));
printf("256:  %f\n",    GPUcomputeForces<256>   (_g[0],_g[1],_g[2],_g[3],_g[4],_g[5],_g[6],N));
printf("128:  %f\n",    GPUcomputeForces<128>   (_g[0],_g[1],_g[2],_g[3],_g[4],_g[5],_g[6],N));
printf("64:   %f\n",    GPUcomputeForces<64>    (_g[0],_g[1],_g[2],_g[3],_g[4],_g[5],_g[6],N));
printf("32:   %f\n",    GPUcomputeForces<32>    (_g[0],_g[1],_g[2],_g[3],_g[4],_g[5],_g[6],N));

printf("16, 1024: %f\n",    GPUcomputeForces_Tiling<16,512> (_g[0],_g[1],_g[2],_g[3],_g[4],_g[5],_g[6],N));
printf("8,  1024: %f\n",    GPUcomputeForces_Tiling<8,512>  (_g[0],_g[1],_g[2],_g[3],_g[4],_g[5],_g[6],N));
printf("4,  1024: %f\n",    GPUcomputeForces_Tiling<4,512>  (_g[0],_g[1],_g[2],_g[3],_g[4],_g[5],_g[6],N));
printf("32, 512: %f\n",     GPUcomputeForces_Tiling<32,512> (_g[0],_g[1],_g[2],_g[3],_g[4],_g[5],_g[6],N));
printf("16, 512: %f\n",     GPUcomputeForces_Tiling<16,512> (_g[0],_g[1],_g[2],_g[3],_g[4],_g[5],_g[6],N));
printf("8,  512: %f\n",     GPUcomputeForces_Tiling<8,512>  (_g[0],_g[1],_g[2],_g[3],_g[4],_g[5],_g[6],N));
printf("64, 256:  %f\n",    GPUcomputeForces_Tiling<64,256> (_g[0],_g[1],_g[2],_g[3],_g[4],_g[5],_g[6],N));
printf("32, 256:  %f\n",    GPUcomputeForces_Tiling<32,256> (_g[0],_g[1],_g[2],_g[3],_g[4],_g[5],_g[6],N));
printf("16, 256:  %f\n",    GPUcomputeForces_Tiling<16,256> (_g[0],_g[1],_g[2],_g[3],_g[4],_g[5],_g[6],N));
printf("128,128:  %f\n",    GPUcomputeForces_Tiling<128,128>(_g[0],_g[1],_g[2],_g[3],_g[4],_g[5],_g[6],N));
printf("64, 128:  %f\n",    GPUcomputeForces_Tiling<64,128> (_g[0],_g[1],_g[2],_g[3],_g[4],_g[5],_g[6],N));
printf("32, 128:  %f\n",    GPUcomputeForces_Tiling<32,128> (_g[0],_g[1],_g[2],_g[3],_g[4],_g[5],_g[6],N));
printf("256,64:   %f\n",    GPUcomputeForces_Tiling<256,64> (_g[0],_g[1],_g[2],_g[3],_g[4],_g[5],_g[6],N));
printf("128,64:   %f\n",    GPUcomputeForces_Tiling<128,64> (_g[0],_g[1],_g[2],_g[3],_g[4],_g[5],_g[6],N));
printf("64, 64:   %f\n",    GPUcomputeForces_Tiling<64,64>  (_g[0],_g[1],_g[2],_g[3],_g[4],_g[5],_g[6],N));
printf("512,32:   %f\n",    GPUcomputeForces_Tiling<512,32> (_g[0],_g[1],_g[2],_g[3],_g[4],_g[5],_g[6],N));
printf("256,32:   %f\n",    GPUcomputeForces_Tiling<512,32> (_g[0],_g[1],_g[2],_g[3],_g[4],_g[5],_g[6],N));
printf("128,32:   %f\n",    GPUcomputeForces_Tiling<512,32> (_g[0],_g[1],_g[2],_g[3],_g[4],_g[5],_g[6],N));

for(int i=8; i<10; i++) gpuErrchk(cudaMemcpy(g[i], _g[i-3], gsize, cudaMemcpyDeviceToHost));

CPUcomputeForces(g[0],g[1],g[2],g[3],g[4],g[5],g[6],N);

for(int i=0; i<N; i++)
for(int j=8; j<10; j++) {

if (abs(*(g[j]+i) - *(g[j-3]+i)) > 0.001f) {
printf("Error at %i, %i; GPU = %f; CPU = %f\n",i, (j-8), *(g[j-3]+i), *(g[j]+i));
return;
}
}

printf("Test passed!\n");

return 0;
}
``````

Here are some results for `N = 16384`.

`KernelcomputeForces`: optimal `BLOCKSIZE = 128`; `t = 10.07ms`.

`KernelcomputeForces_Shared`: optimal `BLOCKSIZE = 128`; `t = 7.04ms`.

`KernelcomputeForces_Tiling`: optimal `BLOCKSIZE = 128`; `t = 11.14ms`.

`KernelcomputeForces_Tiling_Shared`: optimal `GRIDSIZE = 64`; optimal `BLOCKSIZE = 256`; `t = 7.20ms`.

`KernelcomputeForces_Tiling_Shuffle`: optimal `GRIDSIZE = 128`; optimal `BLOCKSIZE = 128`; `t = 6.84ms`.

Warp shuffle operations seem to very slightly improve the performance against shared memory.

-

I want to provide a separate, additional answer to the one provided above which, I think, will be useful to next users.

A way to further optimize the N-body problem is to resort to tree-based approaches, like the Barnes-Hut one, which was parallelized in

``````M. Burtscher, K. Pingali, "An Efficient CUDA Implementation of the Tree-Based Barnes Hut n-Body
``````

Algorithm", GPU Computing Gems, Emerald Edition.

Comparing the above shared- and shuffle-based kernels with the mentioned implementation on a Kepler K20c, I have obtained the following results (times in ms)

``````N           Barnes-Hut          Shared          Shuffle
16384       19.1                5.7             7.2
32768       46.9                25.5            21.7
65536       107.7               102.6           74.6
131072      255.1               355             296.2
262144      548.3               1408.8          1108.9
524288      1246                5434            4688
1048576     2674                21544           18632
2097152     5664                85980           74454
``````

Please, note that such an analysis is not available in the original publication quoted above.

-