CuPBoP/examples/cfd/euler3d.cu

663 lines
24 KiB
Plaintext
Executable File

#include <fstream>
#include <helper_cuda.h>
#include <helper_timer.h>
#include <iostream>
/*
* Options
*
*/
#define GAMMA 1.4f
#define iterations 2
// #ifndef block_length
// #define block_length 192
// #endif
#define NDIM 3
#define NNB 4
#define RK 3 // 3rd order RK
#define ff_mach 1.2f
#define deg_angle_of_attack 0.0f
/*
* not options
*/
#ifdef RD_WG_SIZE_0_0
#define BLOCK_SIZE_0 RD_WG_SIZE_0_0
#elif defined(RD_WG_SIZE_0)
#define BLOCK_SIZE_0 RD_WG_SIZE_0
#elif defined(RD_WG_SIZE)
#define BLOCK_SIZE_0 RD_WG_SIZE
#else
#define BLOCK_SIZE_0 192
#endif
#ifdef RD_WG_SIZE_1_0
#define BLOCK_SIZE_1 RD_WG_SIZE_1_0
#elif defined(RD_WG_SIZE_1)
#define BLOCK_SIZE_1 RD_WG_SIZE_1
#elif defined(RD_WG_SIZE)
#define BLOCK_SIZE_1 RD_WG_SIZE
#else
#define BLOCK_SIZE_1 192
#endif
#ifdef RD_WG_SIZE_2_0
#define BLOCK_SIZE_2 RD_WG_SIZE_2_0
#elif defined(RD_WG_SIZE_1)
#define BLOCK_SIZE_2 RD_WG_SIZE_2
#elif defined(RD_WG_SIZE)
#define BLOCK_SIZE_2 RD_WG_SIZE
#else
#define BLOCK_SIZE_2 192
#endif
#ifdef RD_WG_SIZE_3_0
#define BLOCK_SIZE_3 RD_WG_SIZE_3_0
#elif defined(RD_WG_SIZE_3)
#define BLOCK_SIZE_3 RD_WG_SIZE_3
#elif defined(RD_WG_SIZE)
#define BLOCK_SIZE_3 RD_WG_SIZE
#else
#define BLOCK_SIZE_3 192
#endif
#ifdef RD_WG_SIZE_4_0
#define BLOCK_SIZE_4 RD_WG_SIZE_4_0
#elif defined(RD_WG_SIZE_4)
#define BLOCK_SIZE_4 RD_WG_SIZE_4
#elif defined(RD_WG_SIZE)
#define BLOCK_SIZE_4 RD_WG_SIZE
#else
#define BLOCK_SIZE_4 192
#endif
// #if block_length > 128
// #warning "the kernels may fail too launch on some systems if the block length
// is too large" #endif
#define VAR_DENSITY 0
#define VAR_MOMENTUM 1
#define VAR_DENSITY_ENERGY (VAR_MOMENTUM + NDIM)
#define NVAR (VAR_DENSITY_ENERGY + 1)
/*
* Generic functions
*/
template <typename T> T *alloc(int N) {
T *t;
checkCudaErrors(cudaMalloc((void **)&t, sizeof(T) * N));
return t;
}
template <typename T> void dealloc(T *array) {
checkCudaErrors(cudaFree((void *)array));
}
template <typename T> void copy(T *dst, T *src, int N) {
checkCudaErrors(cudaMemcpy((void *)dst, (void *)src, N * sizeof(T),
cudaMemcpyDeviceToDevice));
}
template <typename T> void upload(T *dst, T *src, int N) {
checkCudaErrors(cudaMemcpy((void *)dst, (void *)src, N * sizeof(T),
cudaMemcpyHostToDevice));
}
template <typename T> void download(T *dst, T *src, int N) {
checkCudaErrors(cudaMemcpy((void *)dst, (void *)src, N * sizeof(T),
cudaMemcpyDeviceToHost));
}
void dump(float *variables, int nel, int nelr) {
float *h_variables = new float[nelr * NVAR];
download(h_variables, variables, nelr * NVAR);
{
std::ofstream file("density");
file << nel << " " << nelr << std::endl;
for (int i = 0; i < nel; i++)
file << h_variables[i + VAR_DENSITY * nelr] << std::endl;
}
{
std::ofstream file("momentum");
file << nel << " " << nelr << std::endl;
for (int i = 0; i < nel; i++) {
for (int j = 0; j != NDIM; j++)
file << h_variables[i + (VAR_MOMENTUM + j) * nelr] << " ";
file << std::endl;
}
}
{
std::ofstream file("density_energy");
file << nel << " " << nelr << std::endl;
for (int i = 0; i < nel; i++)
file << h_variables[i + VAR_DENSITY_ENERGY * nelr] << std::endl;
}
delete[] h_variables;
}
/*
* Element-based Cell-centered FVM solver functions
*/
__constant__ float ff_variable[NVAR];
__constant__ float3 ff_flux_contribution_momentum_x[1];
__constant__ float3 ff_flux_contribution_momentum_y[1];
__constant__ float3 ff_flux_contribution_momentum_z[1];
__constant__ float3 ff_flux_contribution_density_energy[1];
__global__ void cuda_initialize_variables(int nelr, float *variables) {
const int i = (blockDim.x * blockIdx.x + threadIdx.x);
for (int j = 0; j < NVAR; j++)
variables[i + j * nelr] = ff_variable[j];
}
void initialize_variables(int nelr, float *variables) {
dim3 Dg(nelr / BLOCK_SIZE_1), Db(BLOCK_SIZE_1);
cuda_initialize_variables<<<Dg, Db>>>(nelr, variables);
getLastCudaError("initialize_variables failed");
}
__device__ __host__ inline void compute_flux_contribution(
float &density, float3 &momentum, float &density_energy, float &pressure,
float3 &velocity, float3 &fc_momentum_x, float3 &fc_momentum_y,
float3 &fc_momentum_z, float3 &fc_density_energy) {
fc_momentum_x.x = velocity.x * momentum.x + pressure;
fc_momentum_x.y = velocity.x * momentum.y;
fc_momentum_x.z = velocity.x * momentum.z;
fc_momentum_y.x = fc_momentum_x.y;
fc_momentum_y.y = velocity.y * momentum.y + pressure;
fc_momentum_y.z = velocity.y * momentum.z;
fc_momentum_z.x = fc_momentum_x.z;
fc_momentum_z.y = fc_momentum_y.z;
fc_momentum_z.z = velocity.z * momentum.z + pressure;
float de_p = density_energy + pressure;
fc_density_energy.x = velocity.x * de_p;
fc_density_energy.y = velocity.y * de_p;
fc_density_energy.z = velocity.z * de_p;
}
__device__ inline void compute_velocity(float &density, float3 &momentum,
float3 &velocity) {
velocity.x = momentum.x / density;
velocity.y = momentum.y / density;
velocity.z = momentum.z / density;
}
__device__ inline float compute_speed_sqd(float3 &velocity) {
return velocity.x * velocity.x + velocity.y * velocity.y +
velocity.z * velocity.z;
}
__device__ inline float compute_pressure(float &density, float &density_energy,
float &speed_sqd) {
return (float(GAMMA) - float(1.0f)) *
(density_energy - float(0.5f) * density * speed_sqd);
}
__device__ inline float compute_speed_of_sound(float &density,
float &pressure) {
return sqrtf(float(GAMMA) * pressure / density);
}
__global__ void cuda_compute_step_factor(int nelr, float *variables,
float *areas, float *step_factors) {
const int i = (blockDim.x * blockIdx.x + threadIdx.x);
float density = variables[i + VAR_DENSITY * nelr];
float3 momentum;
momentum.x = variables[i + (VAR_MOMENTUM + 0) * nelr];
momentum.y = variables[i + (VAR_MOMENTUM + 1) * nelr];
momentum.z = variables[i + (VAR_MOMENTUM + 2) * nelr];
float density_energy = variables[i + VAR_DENSITY_ENERGY * nelr];
float3 velocity;
compute_velocity(density, momentum, velocity);
float speed_sqd = compute_speed_sqd(velocity);
float pressure = compute_pressure(density, density_energy, speed_sqd);
float speed_of_sound = compute_speed_of_sound(density, pressure);
// dt = float(0.5f) * sqrtf(areas[i]) / (||v|| + c).... but when we do time
// stepping, this later would need to be divided by the area, so we just do it
// all at once
step_factors[i] =
float(0.5f) / (sqrtf(areas[i]) * (sqrtf(speed_sqd) + speed_of_sound));
}
void compute_step_factor(int nelr, float *variables, float *areas,
float *step_factors) {
dim3 Dg(nelr / BLOCK_SIZE_2), Db(BLOCK_SIZE_2);
cuda_compute_step_factor<<<Dg, Db>>>(nelr, variables, areas, step_factors);
getLastCudaError("compute_step_factor failed");
}
/*
*
*
*/
__global__ void cuda_compute_flux(int nelr, int *elements_surrounding_elements,
float *normals, float *variables,
float *fluxes) {
const float smoothing_coefficient = float(0.2f);
const int i = (blockDim.x * blockIdx.x + threadIdx.x);
int j, nb;
float3 normal;
float normal_len;
float factor;
float density_i = variables[i + VAR_DENSITY * nelr];
float3 momentum_i;
momentum_i.x = variables[i + (VAR_MOMENTUM + 0) * nelr];
momentum_i.y = variables[i + (VAR_MOMENTUM + 1) * nelr];
momentum_i.z = variables[i + (VAR_MOMENTUM + 2) * nelr];
float density_energy_i = variables[i + VAR_DENSITY_ENERGY * nelr];
float3 velocity_i;
compute_velocity(density_i, momentum_i, velocity_i);
float speed_sqd_i = compute_speed_sqd(velocity_i);
float speed_i = sqrtf(speed_sqd_i);
float pressure_i = compute_pressure(density_i, density_energy_i, speed_sqd_i);
float speed_of_sound_i = compute_speed_of_sound(density_i, pressure_i);
float3 flux_contribution_i_momentum_x, flux_contribution_i_momentum_y,
flux_contribution_i_momentum_z;
float3 flux_contribution_i_density_energy;
compute_flux_contribution(
density_i, momentum_i, density_energy_i, pressure_i, velocity_i,
flux_contribution_i_momentum_x, flux_contribution_i_momentum_y,
flux_contribution_i_momentum_z, flux_contribution_i_density_energy);
float flux_i_density = float(0.0f);
float3 flux_i_momentum;
flux_i_momentum.x = float(0.0f);
flux_i_momentum.y = float(0.0f);
flux_i_momentum.z = float(0.0f);
float flux_i_density_energy = float(0.0f);
float3 velocity_nb;
float density_nb, density_energy_nb;
float3 momentum_nb;
float3 flux_contribution_nb_momentum_x, flux_contribution_nb_momentum_y,
flux_contribution_nb_momentum_z;
float3 flux_contribution_nb_density_energy;
float speed_sqd_nb, speed_of_sound_nb, pressure_nb;
#pragma unroll
for (j = 0; j < NNB; j++) {
nb = elements_surrounding_elements[i + j * nelr];
normal.x = normals[i + (j + 0 * NNB) * nelr];
normal.y = normals[i + (j + 1 * NNB) * nelr];
normal.z = normals[i + (j + 2 * NNB) * nelr];
normal_len =
sqrtf(normal.x * normal.x + normal.y * normal.y + normal.z * normal.z);
if (nb >= 0) // a legitimate neighbor
{
density_nb = variables[nb + VAR_DENSITY * nelr];
momentum_nb.x = variables[nb + (VAR_MOMENTUM + 0) * nelr];
momentum_nb.y = variables[nb + (VAR_MOMENTUM + 1) * nelr];
momentum_nb.z = variables[nb + (VAR_MOMENTUM + 2) * nelr];
density_energy_nb = variables[nb + VAR_DENSITY_ENERGY * nelr];
compute_velocity(density_nb, momentum_nb, velocity_nb);
speed_sqd_nb = compute_speed_sqd(velocity_nb);
pressure_nb =
compute_pressure(density_nb, density_energy_nb, speed_sqd_nb);
speed_of_sound_nb = compute_speed_of_sound(density_nb, pressure_nb);
compute_flux_contribution(
density_nb, momentum_nb, density_energy_nb, pressure_nb, velocity_nb,
flux_contribution_nb_momentum_x, flux_contribution_nb_momentum_y,
flux_contribution_nb_momentum_z, flux_contribution_nb_density_energy);
// artificial viscosity
factor = -normal_len * smoothing_coefficient * float(0.5f) *
(speed_i + sqrtf(speed_sqd_nb) + speed_of_sound_i +
speed_of_sound_nb);
flux_i_density += factor * (density_i - density_nb);
flux_i_density_energy += factor * (density_energy_i - density_energy_nb);
flux_i_momentum.x += factor * (momentum_i.x - momentum_nb.x);
flux_i_momentum.y += factor * (momentum_i.y - momentum_nb.y);
flux_i_momentum.z += factor * (momentum_i.z - momentum_nb.z);
// accumulate cell-centered fluxes
factor = float(0.5f) * normal.x;
flux_i_density += factor * (momentum_nb.x + momentum_i.x);
flux_i_density_energy += factor * (flux_contribution_nb_density_energy.x +
flux_contribution_i_density_energy.x);
flux_i_momentum.x += factor * (flux_contribution_nb_momentum_x.x +
flux_contribution_i_momentum_x.x);
flux_i_momentum.y += factor * (flux_contribution_nb_momentum_y.x +
flux_contribution_i_momentum_y.x);
flux_i_momentum.z += factor * (flux_contribution_nb_momentum_z.x +
flux_contribution_i_momentum_z.x);
factor = float(0.5f) * normal.y;
flux_i_density += factor * (momentum_nb.y + momentum_i.y);
flux_i_density_energy += factor * (flux_contribution_nb_density_energy.y +
flux_contribution_i_density_energy.y);
flux_i_momentum.x += factor * (flux_contribution_nb_momentum_x.y +
flux_contribution_i_momentum_x.y);
flux_i_momentum.y += factor * (flux_contribution_nb_momentum_y.y +
flux_contribution_i_momentum_y.y);
flux_i_momentum.z += factor * (flux_contribution_nb_momentum_z.y +
flux_contribution_i_momentum_z.y);
factor = float(0.5f) * normal.z;
flux_i_density += factor * (momentum_nb.z + momentum_i.z);
flux_i_density_energy += factor * (flux_contribution_nb_density_energy.z +
flux_contribution_i_density_energy.z);
flux_i_momentum.x += factor * (flux_contribution_nb_momentum_x.z +
flux_contribution_i_momentum_x.z);
flux_i_momentum.y += factor * (flux_contribution_nb_momentum_y.z +
flux_contribution_i_momentum_y.z);
flux_i_momentum.z += factor * (flux_contribution_nb_momentum_z.z +
flux_contribution_i_momentum_z.z);
} else if (nb == -1) // a wing boundary
{
flux_i_momentum.x += normal.x * pressure_i;
flux_i_momentum.y += normal.y * pressure_i;
flux_i_momentum.z += normal.z * pressure_i;
} else if (nb == -2) // a far field boundary
{
factor = float(0.5f) * normal.x;
flux_i_density += factor * (ff_variable[VAR_MOMENTUM + 0] + momentum_i.x);
flux_i_density_energy +=
factor * (ff_flux_contribution_density_energy[0].x +
flux_contribution_i_density_energy.x);
flux_i_momentum.x += factor * (ff_flux_contribution_momentum_x[0].x +
flux_contribution_i_momentum_x.x);
flux_i_momentum.y += factor * (ff_flux_contribution_momentum_y[0].x +
flux_contribution_i_momentum_y.x);
flux_i_momentum.z += factor * (ff_flux_contribution_momentum_z[0].x +
flux_contribution_i_momentum_z.x);
factor = float(0.5f) * normal.y;
flux_i_density += factor * (ff_variable[VAR_MOMENTUM + 1] + momentum_i.y);
flux_i_density_energy +=
factor * (ff_flux_contribution_density_energy[0].y +
flux_contribution_i_density_energy.y);
flux_i_momentum.x += factor * (ff_flux_contribution_momentum_x[0].y +
flux_contribution_i_momentum_x.y);
flux_i_momentum.y += factor * (ff_flux_contribution_momentum_y[0].y +
flux_contribution_i_momentum_y.y);
flux_i_momentum.z += factor * (ff_flux_contribution_momentum_z[0].y +
flux_contribution_i_momentum_z.y);
factor = float(0.5f) * normal.z;
flux_i_density += factor * (ff_variable[VAR_MOMENTUM + 2] + momentum_i.z);
flux_i_density_energy +=
factor * (ff_flux_contribution_density_energy[0].z +
flux_contribution_i_density_energy.z);
flux_i_momentum.x += factor * (ff_flux_contribution_momentum_x[0].z +
flux_contribution_i_momentum_x.z);
flux_i_momentum.y += factor * (ff_flux_contribution_momentum_y[0].z +
flux_contribution_i_momentum_y.z);
flux_i_momentum.z += factor * (ff_flux_contribution_momentum_z[0].z +
flux_contribution_i_momentum_z.z);
}
}
fluxes[i + VAR_DENSITY * nelr] = flux_i_density;
fluxes[i + (VAR_MOMENTUM + 0) * nelr] = flux_i_momentum.x;
fluxes[i + (VAR_MOMENTUM + 1) * nelr] = flux_i_momentum.y;
fluxes[i + (VAR_MOMENTUM + 2) * nelr] = flux_i_momentum.z;
fluxes[i + VAR_DENSITY_ENERGY * nelr] = flux_i_density_energy;
}
void compute_flux(int nelr, int *elements_surrounding_elements, float *normals,
float *variables, float *fluxes) {
dim3 Dg(nelr / BLOCK_SIZE_3), Db(BLOCK_SIZE_3);
cuda_compute_flux<<<Dg, Db>>>(nelr, elements_surrounding_elements, normals,
variables, fluxes);
getLastCudaError("compute_flux failed");
}
__global__ void cuda_time_step(int j, int nelr, float *old_variables,
float *variables, float *step_factors,
float *fluxes) {
const int i = (blockDim.x * blockIdx.x + threadIdx.x);
float factor = step_factors[i] / float(RK + 1 - j);
variables[i + VAR_DENSITY * nelr] = old_variables[i + VAR_DENSITY * nelr] +
factor * fluxes[i + VAR_DENSITY * nelr];
variables[i + VAR_DENSITY_ENERGY * nelr] =
old_variables[i + VAR_DENSITY_ENERGY * nelr] +
factor * fluxes[i + VAR_DENSITY_ENERGY * nelr];
variables[i + (VAR_MOMENTUM + 0) * nelr] =
old_variables[i + (VAR_MOMENTUM + 0) * nelr] +
factor * fluxes[i + (VAR_MOMENTUM + 0) * nelr];
variables[i + (VAR_MOMENTUM + 1) * nelr] =
old_variables[i + (VAR_MOMENTUM + 1) * nelr] +
factor * fluxes[i + (VAR_MOMENTUM + 1) * nelr];
variables[i + (VAR_MOMENTUM + 2) * nelr] =
old_variables[i + (VAR_MOMENTUM + 2) * nelr] +
factor * fluxes[i + (VAR_MOMENTUM + 2) * nelr];
}
void time_step(int j, int nelr, float *old_variables, float *variables,
float *step_factors, float *fluxes) {
dim3 Dg(nelr / BLOCK_SIZE_4), Db(BLOCK_SIZE_4);
cuda_time_step<<<Dg, Db>>>(j, nelr, old_variables, variables, step_factors,
fluxes);
getLastCudaError("update failed");
}
/*
* Main function
*/
int main(int argc, char **argv) {
printf("WG size of kernel:initialize = %d, WG size of "
"kernel:compute_step_factor = %d, WG size of kernel:compute_flux = "
"%d, WG size of kernel:time_step = %d\n",
BLOCK_SIZE_1, BLOCK_SIZE_2, BLOCK_SIZE_3, BLOCK_SIZE_4);
if (argc < 2) {
std::cout << "specify data file name" << std::endl;
return 0;
}
const char *data_file_name = argv[1];
cudaDeviceProp prop;
int dev;
checkCudaErrors(cudaSetDevice(0));
// set far field conditions and load them into constant memory on the gpu
{
float h_ff_variable[NVAR];
const float angle_of_attack =
float(3.1415926535897931 / 180.0f) * float(deg_angle_of_attack);
h_ff_variable[VAR_DENSITY] = float(1.4);
float ff_pressure = float(1.0f);
float ff_speed_of_sound =
sqrt(GAMMA * ff_pressure / h_ff_variable[VAR_DENSITY]);
float ff_speed = float(ff_mach) * ff_speed_of_sound;
float3 ff_velocity;
ff_velocity.x = ff_speed * float(cos((float)angle_of_attack));
ff_velocity.y = ff_speed * float(sin((float)angle_of_attack));
ff_velocity.z = 0.0f;
h_ff_variable[VAR_MOMENTUM + 0] =
h_ff_variable[VAR_DENSITY] * ff_velocity.x;
h_ff_variable[VAR_MOMENTUM + 1] =
h_ff_variable[VAR_DENSITY] * ff_velocity.y;
h_ff_variable[VAR_MOMENTUM + 2] =
h_ff_variable[VAR_DENSITY] * ff_velocity.z;
h_ff_variable[VAR_DENSITY_ENERGY] =
h_ff_variable[VAR_DENSITY] * (float(0.5f) * (ff_speed * ff_speed)) +
(ff_pressure / float(GAMMA - 1.0f));
float3 h_ff_momentum;
h_ff_momentum.x = *(h_ff_variable + VAR_MOMENTUM + 0);
h_ff_momentum.y = *(h_ff_variable + VAR_MOMENTUM + 1);
h_ff_momentum.z = *(h_ff_variable + VAR_MOMENTUM + 2);
float3 h_ff_flux_contribution_momentum_x;
float3 h_ff_flux_contribution_momentum_y;
float3 h_ff_flux_contribution_momentum_z;
float3 h_ff_flux_contribution_density_energy;
compute_flux_contribution(h_ff_variable[VAR_DENSITY], h_ff_momentum,
h_ff_variable[VAR_DENSITY_ENERGY], ff_pressure,
ff_velocity, h_ff_flux_contribution_momentum_x,
h_ff_flux_contribution_momentum_y,
h_ff_flux_contribution_momentum_z,
h_ff_flux_contribution_density_energy);
// copy far field conditions to the gpu
checkCudaErrors(
cudaMemcpyToSymbol(ff_variable, h_ff_variable, NVAR * sizeof(float)));
checkCudaErrors(cudaMemcpyToSymbol(ff_flux_contribution_momentum_x,
&h_ff_flux_contribution_momentum_x,
sizeof(float3)));
checkCudaErrors(cudaMemcpyToSymbol(ff_flux_contribution_momentum_y,
&h_ff_flux_contribution_momentum_y,
sizeof(float3)));
checkCudaErrors(cudaMemcpyToSymbol(ff_flux_contribution_momentum_z,
&h_ff_flux_contribution_momentum_z,
sizeof(float3)));
checkCudaErrors(cudaMemcpyToSymbol(ff_flux_contribution_density_energy,
&h_ff_flux_contribution_density_energy,
sizeof(float3)));
}
int nel;
int nelr;
// read in domain geometry
float *areas;
int *elements_surrounding_elements;
float *normals;
{
std::ifstream file(data_file_name);
file >> nel;
nelr =
BLOCK_SIZE_0 * ((nel / BLOCK_SIZE_0) + std::min(1, nel % BLOCK_SIZE_0));
float *h_areas = new float[nelr];
int *h_elements_surrounding_elements = new int[nelr * NNB];
float *h_normals = new float[nelr * NDIM * NNB];
// read in data
for (int i = 0; i < nel; i++) {
file >> h_areas[i];
for (int j = 0; j < NNB; j++) {
file >> h_elements_surrounding_elements[i + j * nelr];
if (h_elements_surrounding_elements[i + j * nelr] < 0)
h_elements_surrounding_elements[i + j * nelr] = -1;
h_elements_surrounding_elements[i + j * nelr]--; // it's coming in with
// Fortran numbering
for (int k = 0; k < NDIM; k++) {
file >> h_normals[i + (j + k * NNB) * nelr];
h_normals[i + (j + k * NNB) * nelr] =
-h_normals[i + (j + k * NNB) * nelr];
}
}
}
// fill in remaining data
int last = nel - 1;
for (int i = nel; i < nelr; i++) {
h_areas[i] = h_areas[last];
for (int j = 0; j < NNB; j++) {
// duplicate the last element
h_elements_surrounding_elements[i + j * nelr] =
h_elements_surrounding_elements[last + j * nelr];
for (int k = 0; k < NDIM; k++)
h_normals[last + (j + k * NNB) * nelr] =
h_normals[last + (j + k * NNB) * nelr];
}
}
areas = alloc<float>(nelr);
upload<float>(areas, h_areas, nelr);
elements_surrounding_elements = alloc<int>(nelr * NNB);
upload<int>(elements_surrounding_elements, h_elements_surrounding_elements,
nelr * NNB);
normals = alloc<float>(nelr * NDIM * NNB);
upload<float>(normals, h_normals, nelr * NDIM * NNB);
delete[] h_areas;
delete[] h_elements_surrounding_elements;
delete[] h_normals;
}
// Create arrays and set initial conditions
float *variables = alloc<float>(nelr * NVAR);
initialize_variables(nelr, variables);
float *old_variables = alloc<float>(nelr * NVAR);
float *fluxes = alloc<float>(nelr * NVAR);
float *step_factors = alloc<float>(nelr);
// make sure all memory is floatly allocated before we start timing
initialize_variables(nelr, old_variables);
initialize_variables(nelr, fluxes);
cudaMemset((void *)step_factors, 0, sizeof(float) * nelr);
// make sure CUDA isn't still doing something before we start timing
cudaThreadSynchronize();
// these need to be computed the first time in order to compute time step
std::cout << "Starting..." << std::endl;
StopWatchInterface *timer = 0;
// unsigned int timer = 0;
// CUT_SAFE_CALL( cutCreateTimer( &timer));
// CUT_SAFE_CALL( cutStartTimer( timer));
sdkCreateTimer(&timer);
sdkStartTimer(&timer);
// Begin iterations
for (int i = 0; i < iterations; i++) {
copy<float>(old_variables, variables, nelr * NVAR);
// for the first iteration we compute the time step
compute_step_factor(nelr, variables, areas, step_factors);
getLastCudaError("compute_step_factor failed");
for (int j = 0; j < RK; j++) {
compute_flux(nelr, elements_surrounding_elements, normals, variables,
fluxes);
getLastCudaError("compute_flux failed");
time_step(j, nelr, old_variables, variables, step_factors, fluxes);
getLastCudaError("time_step failed");
}
}
cudaThreadSynchronize();
// CUT_SAFE_CALL( cutStopTimer(timer) );
sdkStopTimer(&timer);
std::cout << (sdkGetAverageTimerValue(&timer) / 1000.0) / iterations
<< " seconds per iteration" << std::endl;
std::cout << "Saving solution..." << std::endl;
dump(variables, nel, nelr);
std::cout << "Saved solution..." << std::endl;
std::cout << "Cleaning up..." << std::endl;
dealloc<float>(areas);
dealloc<int>(elements_surrounding_elements);
dealloc<float>(normals);
dealloc<float>(variables);
dealloc<float>(old_variables);
dealloc<float>(fluxes);
dealloc<float>(step_factors);
std::cout << "Done..." << std::endl;
return 0;
}