bool mat_sqrt(const complex_vec_t& matrix, complex_vec_t& result) {
result.clear();
for(complex_vec_t::const_iterator i = matrix.begin(); i != matrix.end(); ++ i) {
result.push_back(sqrt(*i));
} // for
return true;
} // mat_sqrt()
bool mat_mul(complex_t scalar, const complex_vec_t& matrix, complex_vec_t& result) {
result.clear();
for(complex_vec_t::const_iterator i = matrix.begin(); i != matrix.end(); ++ i) {
result.push_back((*i) * scalar);
} // for
return true;
} // mat_mul()
bool AnalyticFormFactor::mat_sinc(unsigned int x_size, unsigned int y_size, unsigned int z_size,
const complex_vec_t& matrix, complex_vec_t& result) {
result.clear();
for(std::vector<complex_t>::const_iterator i = matrix.begin(); i != matrix.end(); ++ i) {
result.push_back(sinc(*i));
} // for
return true;
} // AnalyticFormFactor::mat_sinc()
bool AnalyticFormFactor::mat_fq_inv(unsigned int x_size, unsigned int y_size, unsigned int z_size,
const complex_vec_t& matrix, real_t y, complex_vec_t& result) {
result.clear();
for(complex_vec_t::const_iterator i = matrix.begin(); i != matrix.end(); ++ i) {
result.push_back(fq_inv(*i, y));
} // for
return true;
} // AnalyticFormFactor::mat_fq_inv()
bool AnalyticFormFactor::mat_fq_inv_in(unsigned int x_size,
unsigned int y_size,
unsigned int z_size,
complex_vec_t& matrix, real_t y) {
for(complex_vec_t::iterator i = matrix.begin(); i != matrix.end(); ++ i) {
*i = fq_inv(*i, y);
} // for
return true;
} // AnalyticFormFactor::mat_fq_inv()
complex_vec_t fourier_transform::backwards(const complex_vec_t &in, size_t n) const
{
if(n==0){
n=in.size();
}else{
if(n>in.size())
throw std::invalid_argument("Output size must be less than or equal to input size.");
}
complex_vec_t result(in.size());
complex_t wn=root_of_unity(n);
backwards_impl(n, wn, &in[0], 1, &result[0], 1);
result.resize(n);
return result;
}
complex_vec_t fourier_transform::forwards(const complex_vec_t &in) const
{
size_t n=calc_padded_size(in.size());
complex_vec_t result(n);
complex_t wn=root_of_unity(n);
if(n==in.size()){
forwards_impl(n, wn, &in[0], 1, &result[0], 1);
}else{
complex_vec_t buffer(in);
buffer.resize(n, complex_t(0.0,0.0) );
forwards_impl(n, wn, &buffer[0], 1, &result[0], 1);
}
return result;
}
/**
* computes element-by-element division of two matrices (matrix1 / matrix2) into result
*/
bool mat_dot_div(unsigned int nx1, unsigned int ny1, unsigned int nz1,
const complex_vec_t& matrix1,
unsigned int nx2, unsigned int ny2, unsigned int nz2,
const complex_vec_t& matrix2,
complex_vec_t& result) {
if(nx1 != nx2 || ny1 != ny2 || nz1 != nz2 || matrix1.size() != matrix2.size()) {
std::cerr << "error: matrix sizes are not the same for dot division operation"
<< std::endl;
return false;
} // if
result.clear();
complex_vec_t::const_iterator i1 = matrix1.begin();
complex_vec_t::const_iterator i2 = matrix2.begin();
for(; i1 != matrix1.end(); ++ i1, ++ i2) {
result.push_back((*i1) / (*i2));
} // for
return true;
} // mat_dot_div()
/**
* computes element-by-element product of two matrices into result
*/
bool mat_dot_prod(unsigned int x1_size, unsigned int y1_size, unsigned int z1_size,
const complex_vec_t& matrix1,
unsigned int x2_size, unsigned int y2_size, unsigned int z2_size,
const complex_vec_t& matrix2,
complex_vec_t& result) {
if(x1_size != x2_size || y1_size != y2_size || z1_size != z2_size
|| matrix1.size() != matrix2.size()) {
std::cerr << "error: matrix sizes are not the same for dot product operation" << std::endl;
return false;
} // if
result.clear();
complex_vec_t::const_iterator i1 = matrix1.begin();
complex_vec_t::const_iterator i2 = matrix2.begin();
for(; i1 != matrix1.end(); ++ i1, ++ i2) {
result.push_back((*i1) * (*i2));
} // for
return true;
} // mat_dot_prod()
/**
* Function to gather partial FF arrays from all processes to construct the final FF.
* This is a bottleneck for large num procs ...
*/
bool NumericFormFactor::construct_ff(int p_nqx, int p_nqy, int p_nqz,
int nqx, int nqy, int nqz,
int p_y, int p_z,
#ifdef FF_NUM_GPU
cucomplex_t* p_ff,
#else
complex_t* p_ff,
#endif
complex_vec_t& ff,
#ifdef USE_MPI
woo::MultiNode& world_comm, std::string comm_key,
#endif
real_t& mem_time, real_t& comm_time) {
real_t mem_start = 0, mem_end = 0, comm_start = 0, comm_end = 0;
woo::BoostChronoTimer memtimer, commtimer;
mem_time = 0; comm_time = 0;
#ifdef USE_MPI
bool master = world_comm.is_master(comm_key);
int size = world_comm.size(comm_key);
int rank = world_comm.rank(comm_key);
#else
bool master = true;
int size = 1;
int rank = 0;
#endif
memtimer.start();
int local_qpoints = p_nqx * p_nqy * p_nqz;
unsigned long int total_qpoints = nqx * nqy * nqz;
// process 0 creates the main ff, and collects computed p_ff from all others (just use gather)
ff.clear();
#ifdef FF_NUM_GPU
cucomplex_t* all_ff = NULL; // TODO: improve this ...
#else
complex_t* all_ff = NULL;
#endif
if(master) {
ff.reserve(total_qpoints);
ff.assign(total_qpoints, complex_t(0.0, 0.0));
#ifdef FF_NUM_GPU
all_ff = new (std::nothrow) cucomplex_t[total_qpoints];
#else
all_ff = new (std::nothrow) complex_t[total_qpoints];
#endif
} // if
mem_time += memtimer.elapsed_msec();
int *recv_p_nqy = new (std::nothrow) int[p_y]();
recv_p_nqy[0] = p_nqy;
int *off_p_nqy = new (std::nothrow) int[p_y]();
off_p_nqy[0] = 0;
#ifdef FF_NUM_GPU
cucomplex_t *ff_buffer = new (std::nothrow) cucomplex_t[total_qpoints];
#else
complex_t *ff_buffer = new (std::nothrow) complex_t[total_qpoints];
#endif
if(ff_buffer == NULL) {
std::cerr << "error: failed to allocate memory for ff buffer" << std::endl;
return false;
} // if
#ifdef USE_MPI
// construct stuff for gatherv
int *recv_counts = new (std::nothrow) int[size]();
int *displs = new (std::nothrow) int[size]();
commtimer.start();
//comm.Allgather(&local_qpoints, 1, MPI::INT, recv_counts, 1, MPI::INT);
world_comm.allgather(comm_key, &local_qpoints, 1, recv_counts, 1);
commtimer.stop();
comm_time += commtimer.elapsed_msec();
memtimer.start();
displs[0] = 0;
for(int i = 1; i < size; ++ i) {
displs[i] = displs[i - 1] + recv_counts[i - 1];
} // for
complex_t *cast_p_ff, *cast_ff;
#ifdef FF_NUM_GPU
cast_p_ff = reinterpret_cast<complex_t*>(p_ff);
cast_ff = reinterpret_cast<complex_t*>(ff_buffer);
#else
cast_p_ff = p_ff;
cast_ff = ff_buffer;
#endif
memtimer.stop();
mem_time += memtimer.elapsed_msec();
commtimer.start();
world_comm.gatherv(comm_key, cast_p_ff, local_qpoints, cast_ff, recv_counts, displs);
world_comm.gather("ff_num_col_comm", &p_nqy, 1, recv_p_nqy, 1);
commtimer.stop();
comm_time += commtimer.elapsed_msec();
for(int i = 1; i < p_y; ++ i) off_p_nqy[i] = off_p_nqy[i - 1] + recv_p_nqy[i - 1];
#else
#ifdef FF_NUM_GPU
memcpy(ff_buffer, p_ff, total_qpoints * sizeof(cucomplex_t));
#else
memcpy(ff_buffer, p_ff, total_qpoints * sizeof(complex_t));
#endif
#endif // USE_MPI
memtimer.start();
// move all the data to correct places
if(rank == 0) {
unsigned long int ff_index = 0;
for(int i_nqz = 0; i_nqz < nqz; ++ i_nqz) {
for(int i_py = 0; i_py < p_y; ++ i_py) {
unsigned long int ffb_index = nqx * (i_nqz * recv_p_nqy[i_py] +
nqz * off_p_nqy[i_py]);
#ifdef FF_NUM_GPU
memcpy(&all_ff[ff_index], &ff_buffer[ffb_index],
nqx * recv_p_nqy[i_py] * sizeof(cucomplex_t));
#else
memcpy(&all_ff[ff_index], &ff_buffer[ffb_index],
nqx * recv_p_nqy[i_py] * sizeof(complex_t));
#endif
ff_index += nqx * recv_p_nqy[i_py];
} // for i_py
} // for i_nqz
// put into the final ff buffer
#ifdef FF_NUM_GPU
ff.assign(reinterpret_cast<complex_t*>(all_ff),
reinterpret_cast<complex_t*>(all_ff + total_qpoints));
#else
ff.assign(all_ff, all_ff + total_qpoints);
#endif
} // if
delete[] ff_buffer;
#ifdef USE_MPI
delete[] displs;
delete[] recv_counts;
#endif
delete[] off_p_nqy;
delete[] recv_p_nqy;
delete[] all_ff;
memtimer.stop();
mem_time += memtimer.elapsed_msec();
return true;
} // NumericFormFactor::construct_ff()
bool NumericFormFactor::compute2(const char * filename, complex_vec_t &ff,
RotMatrix_t & rot
#ifdef USE_MPI
, woo::MultiNode & world_comm, std::string comm_key
#endif
) {
// initialize
init (rot, ff);
// read file
std::vector<vertex_t> vertices;
std::vector<std::vector<int>> faces;
std::vector<std::vector<int>> dummy;
ObjectShapeReader shape_reader;
if (!shape_reader.load_object (filename, vertices, faces, dummy)) {
std::cerr << "Error: shape reader failed to load triangles" << std::endl;
return false;
}
// create triangles
int num_triangles = faces.size();
triangle_t * triangles = new (std::nothrow) triangle_t [num_triangles];
for (int i = 0; i < num_triangles; i++) {
triangles[i].v1[0] = vertices[faces[i][0]-1].x;
triangles[i].v1[1] = vertices[faces[i][0]-1].y;
triangles[i].v1[2] = vertices[faces[i][0]-1].z;
triangles[i].v2[0] = vertices[faces[i][1]-1].x;
triangles[i].v2[1] = vertices[faces[i][1]-1].y;
triangles[i].v2[2] = vertices[faces[i][1]-1].z;
triangles[i].v3[0] = vertices[faces[i][2]-1].x;
triangles[i].v3[1] = vertices[faces[i][2]-1].y;
triangles[i].v3[2] = vertices[faces[i][2]-1].z;
}
//#ifndef __SSE3__
real_vec_t shape_def;
//#else
//#ifdef USE_GPU
// real_vec_t shape_def;
//#else
// real_t * shape_def = NULL;
//#endif
//#endif
//unsigned int num_triangles = read_shapes_file(filename, shape_def);
#ifdef USE_MPI
int num_procs = world_comm.size(comm_key);
int rank = world_comm.rank(comm_key);
bool master = world_comm.is_master(comm_key);
#else
bool master = true;
#endif
if(master) {
std::cout << "-- Numerical form factor computation ..." << std::endl
<< "** Using input shape file: " << filename << std::endl
<< "** Number of input triangles: " << num_triangles << std::endl
<< "** Q-grid resolution (q-points): " << nqy_ << std::endl
#ifdef USE_MPI
<< "** Number of processes requested: " << num_procs << std::endl
#endif
<< std::flush;
} // if
// copy q-points
real_t * qx = new (std::nothrow) real_t [nqy_];
if (qx == NULL) {
std::cerr << "Error: failure in allocation memeroy." << std::endl;
return false;
}
for (int i = 0; i < nqy_; i++ ) qx[i] = QGrid::instance().qx(i);
real_t * qy = new (std::nothrow) real_t [nqy_];
if (qy == NULL) {
std::cerr << "Error: failure in allocation memeroy." << std::endl;
return false;
}
for (int i = 0; i < nqy_; i++) qy[i] = QGrid::instance().qy(i);
#ifdef FF_NUM_GPU
cucomplex_t * qz = new (std::nothrow) cucomplex_t [nqz_];
if (qz == NULL) {
std::cerr << "Error: failure in memeroy allocation." << std::endl;
return 0;
}
for (int i = 0; i < nqz_; i++) {
qz[i].x = QGrid::instance().qz_extended(i).real();
qz[i].y = QGrid::instance().qz_extended(i).imag();
}
#else
complex_t * qz = new (std::nothrow) complex_t [nqz_];
if (qz == NULL) {
std::cerr << "Error: failure in memeroy allocation." << std::endl;
return 0;
}
for (int i = 0; i < nqz_; i++) qz[i] = QGrid::instance().qz_extended(i);
#endif
real_t compute_time = 0.;
#ifdef FF_NUM_GPU
cucomplex_t * p_ff = NULL;
// call kernel
if (num_triangles != gff_.compute_exact_triangle(triangles, num_triangles,
p_ff, nqy_, qx, qy,
nqz_, qz, rot_, compute_time)) {
std::cerr << "Calculation of numerical form-factor failed" << std::endl;
return false;
}
for (int i = 0; i < nqz_; i++) ff.push_back (complex_t(p_ff[i].x, p_ff[i].y));
std::cout << "** FF GPU compute time: " << compute_time << " ms." << std::endl;
#else
complex_t * p_ff = new (std::nothrow) complex_t[nqz_];
if (p_ff == NULL){
std::cerr << "Error: failed to allocate memory of size: "
<< nqz_ * sizeof(complex_t) << std::endl;
return false;
}
if (num_triangles != cff_.compute_exact_triangle(triangles, num_triangles,
p_ff, nqy_, qx, qy,
nqz_, qz, rot_, compute_time)) {
std::cerr << "Calculation of numerical form-factor failed" << std::endl;
return false;
}
for (int i = 0; i < nqz_; i++) ff.push_back(p_ff[i]);
std::cout << "** FF CPU compute time: " << compute_time << " ms." << std::endl;
#endif
delete [] qx;
delete [] qy;
delete [] qz;
delete [] triangles;
if (p_ff != NULL) delete [] p_ff;
return true;
}
/**
* main host function
*/
bool NumericFormFactor::compute(const char* filename, complex_vec_t& ff,
vector3_t& rot1, vector3_t& rot2, vector3_t& rot3
#ifdef USE_MPI
, woo::MultiNode& world_comm, std::string comm_key
#endif
) {
real_t comp_start = 0.0, comp_end = 0.0, comm_start = 0.0, comm_end = 0.0;
real_t mem_start = 0.0, mem_end = 0.0;
real_t comp_time = 0.0, comm_time = 0.0, mem_time = 0.0, kernel_time = 0.0, red_time = 0.0;
real_t total_start = 0.0, total_end = 0.0, total_time = 0.0;
woo::BoostChronoTimer maintimer, computetimer;
woo::BoostChronoTimer commtimer, memtimer;
unsigned int nqx = QGrid::instance().nqx();
unsigned int nqy = QGrid::instance().nqy();
unsigned int nqz = QGrid::instance().nqz_extended();
#ifdef USE_MPI
bool master = world_comm.is_master(comm_key);
commtimer.start();
world_comm.barrier(comm_key);
commtimer.stop();
comm_time += commtimer.elapsed_msec();
#else
bool master = true;
#endif
// warning: all procs read the shape file!!!!
// TODO: improve to parallel IO, or one proc reading and sending to all ...
// #ifndef __SSE3__
real_vec_t shape_def;
// #else
// #ifdef USE_GPU
// real_vec_t shape_def;
// #else
// real_t* shape_def = NULL;
// #endif
// #endif
// use the new file reader instead ...
unsigned int num_triangles = read_shapes_file(filename, shape_def);
// TODO ... <--- sadly all procs read this! IMPROVE!!!
// TODO: temporary ... remove ...
std::vector<short int> axes(4); // axes[i] = j
// i: x=0 y=1 z=2
// j: 0=a 1=b 2=c
#ifndef AXIS_ROT
axes[0] = 0; axes[1] = 1; axes[2] = 2; // default values
#else
find_axes_orientation(shape_def, axes);
#endif
#ifdef USE_MPI
int num_procs = world_comm.size(comm_key);
int rank = world_comm.rank(comm_key);
#endif
if(master) {
std::cout << "-- Numerical form factor computation ..." << std::endl
<< "** Using input shape file: " << filename << std::endl
<< "** Number of input triangles: " << num_triangles << std::endl
<< "** Q-grid resolution (q-points): " << nqx * nqy * nqz << std::endl
<< "** NQX x NQY x NQZ: "
<< nqx << " x " << nqy << " x " << nqz << std::endl
#ifdef USE_MPI
<< "** Number of processes requested: " << num_procs << std::endl
#endif
<< std::flush;
} // if
if(num_triangles < 1) {
std::cerr << "error: no triangles found in specified definition file" << std::endl;
return false;
} // if
#ifdef USE_MPI
// decompose along y and z directions into blocks
int p_y = std::floor(sqrt((real_t) num_procs)); // some procs may be idle ...
int p_z = num_procs / p_y;
int p_nqx = nqx;
int p_nqy = nqy / p_y + (((rank / p_z) < (int)nqy % p_y) ? 1 : 0);
int p_nqz = nqz / p_z + (((rank % p_z) < (int)nqz % p_z) ? 1 : 0);
commtimer.start();
int idle = 0;
if(world_comm.rank(comm_key) >= p_y * p_z) idle = 1;
std::string real_world("ff_num_real_world");
world_comm.split(real_world, comm_key, idle);
commtimer.stop();
comm_time += commtimer.elapsed_msec();
#else
int p_y = 1, p_z = 1;
int p_nqx = nqx;
int p_nqy = nqy;
int p_nqz = nqz;
#endif // USE_MPI
#ifdef FINDBLOCK
int block_x = 0, block_y = 0, block_z = 0, block_t = 0;
int block_x_max = 0, block_y_max = 0, block_z_max = 0, block_t_max = 0;
block_x_max = (nqx < 400) ? nqx : 400;
block_y_max = (nqy < 400) ? nqy : 400;
block_z_max = (nqz < 400) ? nqz : 400;
block_t_max = (num_triangles < 2500) ? num_triangles : 2500;
block_t = block_t_max;
for(block_t = block_t_max; block_t > std::min(99, block_t_max - 1); block_t -= 100) {
for(block_x = block_x_max; block_x > std::min(3, block_x_max - 1); block_x -= 2) {
for(block_y = block_y_max; block_y > std::min(3, block_y_max - 1); block_y -= 2) {
for(block_z = block_z_max; block_z > std::min(3, block_z_max - 1); block_z -= 2) {
#endif
maintimer.start();
#ifdef USE_MPI
if(world_comm.rank(comm_key) < p_y * p_z) { // only the non-idle processors
bool master = world_comm.is_master(real_world);
if(master) {
std::cout << "++ Number of MPI processes used: "
<< world_comm.size(real_world) << std::endl
<< "++ MPI grid size: 1 x " << p_y << " x " << p_z
<< std::endl << std::flush;
} // if
commtimer.start();
int rank = world_comm.rank(real_world);
int size = world_comm.size(real_world);
// create row-wise and column-wise communicators
int row = rank / p_z, col = rank % p_z;
world_comm.split("ff_num_row_comm", real_world, row);
world_comm.split("ff_num_col_comm", real_world, col);
// perform MPI scan operation to compute y_offset and z_offset
unsigned int y_offset = 0, z_offset = 0;
world_comm.scan_sum("ff_num_col_comm", p_nqy, y_offset);
world_comm.scan_sum("ff_num_row_comm", p_nqz, z_offset);
commtimer.stop();
comm_time += commtimer.elapsed_msec();
y_offset -= p_nqy;
z_offset -= p_nqz;
#else
master = true;
unsigned int y_offset = 0, z_offset = 0;
int rank = 0;
int size = 1;
#endif // USE_MPI
memtimer.start();
// FIXME: this is a yucky temporary fix ... fix properly ...
real_t* qx = new (std::nothrow) real_t[nqx]();
real_t* qy = new (std::nothrow) real_t[nqy]();
#ifdef FF_NUM_GPU
cucomplex_t* qz = new (std::nothrow) cucomplex_t[nqz]();
#else
complex_t* qz = new (std::nothrow) complex_t[nqz]();
#endif
// create qy_and qz using qgrid instance
for(unsigned int i = 0; i < nqx; ++ i) {
qx[i] = QGrid::instance().qx(i);
} // for
for(unsigned int i = 0; i < nqy; ++ i) {
qy[i] = QGrid::instance().qy(i);
} // for
for(unsigned int i = 0; i < nqz; ++ i) {
#ifdef FF_NUM_GPU
qz[i].x = QGrid::instance().qz_extended(i).real();
qz[i].y = QGrid::instance().qz_extended(i).imag();
#else
qz[i] = QGrid::instance().qz_extended(i);
#endif
} // for
#ifdef USE_MPI
// create p_ff buffers <----- TODO: IMPROVE for all procs!!!
real_t *p_qy = NULL;
p_qy = new (std::nothrow) real_t[p_nqy]();
if(p_qy == NULL) { return 0; }
memcpy(p_qy, (void*) (qy + y_offset), p_nqy * sizeof(real_t));
#ifdef FF_NUM_GPU
cucomplex_t *p_qz = NULL;
p_qz = new (std::nothrow) cucomplex_t[p_nqz]();
if(p_qz == NULL) { delete[] p_qy; return 0; }
memcpy(p_qz, (void*) (qz + z_offset), p_nqz * sizeof(cucomplex_t));
#else // TODO: avoid the following ...
complex_t *p_qz = NULL;
p_qz = new (std::nothrow) complex_t[p_nqz]();
if(p_qz == NULL) { delete[] p_qy; return 0; }
memcpy(p_qz, (void*) (qz + z_offset), p_nqz * sizeof(complex_t));
#endif // FF_NUM_GPU
#else // no MPI
real_t *p_qy = qy;
#ifdef FF_NUM_GPU
cucomplex_t *p_qz = qz;
#else
complex_t *p_qz = qz;
#endif // FF_NUM_GPU
#endif // USE_MPI
memtimer.stop();
mem_time += memtimer.elapsed_msec();
// compute local
#ifdef FF_NUM_GPU
cucomplex_t *p_ff = NULL;
#else
complex_t *p_ff = NULL;
#endif
computetimer.reset();
computetimer.start();
unsigned int ret_numtriangles = 0;
real_t temp_mem_time = 0.0;
#ifdef FF_NUM_GPU // use GPU
#ifdef FF_NUM_GPU_FUSED
ret_numtriangles = gff_.compute_form_factor_kb_fused(rank, shape_def, axes, p_ff,
qx, p_nqx, p_qy, p_nqy, p_qz, p_nqz, 3,
rot_,
kernel_time, red_time, temp_mem_time
#ifdef FINDBLOCK
, block_x, block_y, block_z, block_t
#endif
);
#else
ret_numtriangles = gff_.compute_form_factor_db(rank, shape_def, axes, p_ff,
qx, p_nqx, p_qy, p_nqy, p_qz, p_nqz,
rot_,
kernel_time, red_time, temp_mem_time
#ifdef FINDBLOCK
, block_x, block_y, block_z, block_t
#endif
);
#endif
/* #elif defined USE_MIC // use MIC
#ifndef FF_NUM_MIC_KB
ret_numtriangles = mff_.compute_form_factor_db(rank, shape_def, p_ff,
qx, p_nqx, p_qy, p_nqy, p_qz, p_nqz,
rot_,
kernel_time, red_time, temp_mem_time
#ifdef FINDBLOCK
, block_x, block_y, block_z, block_t
#endif
);
#else
ret_numtriangles = mff_.compute_form_factor_kb(rank, shape_def,
num_triangles,
p_ff,
qx, p_nqx, p_qy, p_nqy, p_qz, p_nqz, 3,
rot_,
kernel_time, red_time, temp_mem_time
#ifdef FINDBLOCK
, block_x, block_y, block_z, block_t
#endif
);
#endif */
#else // use only CPU
ret_numtriangles = cff_.compute_form_factor(rank, shape_def,
// #ifdef __SSE3__
// num_triangles,
// #endif
p_ff,
qx, p_nqx, p_qy, p_nqy, p_qz, p_nqz,
rot_,
kernel_time, red_time, temp_mem_time
#ifdef FINDBLOCK
, block_x, block_y, block_z, block_t
#endif
);
#endif
computetimer.stop();
comp_time += computetimer.elapsed_msec();
mem_time += (temp_mem_time / 1000);
// gather everything on proc 0
if(ret_numtriangles > 0) {
real_t temp_mem_time = 0.0, temp_comm_time = 0.0;
construct_ff(p_nqx, p_nqy, p_nqz, nqx, nqy, nqz, p_y, p_z, p_ff, ff,
#ifdef USE_MPI
world_comm, real_world,
#endif
temp_mem_time, temp_comm_time);
mem_time += temp_mem_time;
comm_time += temp_comm_time;
} // if
/*if(rank == 0) {
write_slice_to_file(ff, nqx, nqy, nqz, filename, 0, 0); // x = 0, y = 1, z = 2
// only slice along x implemented for now
} // if*/
#ifdef USE_MPI
world_comm.barrier(real_world);
#endif
memtimer.start();
#ifdef FINDBLOCK
ff.clear();
#endif
if(p_ff != NULL) delete[] p_ff;
#ifdef USE_MPI
delete[] p_qz;
delete[] p_qy;
#endif
delete[] qz;
delete[] qy;
delete[] qx;
memtimer.stop();
maintimer.stop();
total_time = maintimer.elapsed_msec();
mem_time += memtimer.elapsed_msec();
if(master) {
#ifdef TIME_DETAIL_1
std::cout
<< "** FF kernel time: " << kernel_time << " ms." << std::endl
<< "** FF compute time: " << computetimer.elapsed_msec() << " ms."
<< std::endl
<< "** FF memory and IO time: " << mem_time * 1000 << " ms." << std::endl
<< "** Communication time: " << comm_time * 1000 << " ms." << std::endl
<< "** Total FF time: " << maintimer.elapsed_msec() << " ms."
<< std::endl << std::flush;
#endif // TIME_DETAIL_1
double mflop = 0.0; real_t gflops = 0.0;
#ifdef USE_GPU
// flop count for GPU
//mflop = (double) nqx * nqy * nqz * (42 * num_triangles + 2) / 1000000;
mflop = (double) nqx * nqy * nqz * (69 * num_triangles + 52) / 1000000;
#elif defined USE_MIC
// flop count for MIC
//mflop = (double) nqx * nqy * nqz * (78 * num_triangles + 18) / 1000000;
mflop = (double) nqx * nqy * nqz * (111 * num_triangles + 50) / 1000000;
#elif defined INTEL_SB_AVX
// flop count for Sandy Bridge with AVX
// TODO: recount flops ...
mflop = (double) nqx * nqy * nqz * (85 * num_triangles + 16) / 1000000;
#else
// flop count for SSE3 CPU (hopper)
// TODO: recount flops ...
mflop = (double) nqx * nqy * nqz * (68 * num_triangles + 20) / 1000000;
#endif
//gflops = nidle_num_procs * mflop / kernel_time;
gflops = mflop / kernel_time;
std::cout << "** Kernel performance: " << gflops << " GFLOPS/s" << std::endl;
} // if
#ifdef USE_MPI
world_comm.free("ff_num_row_comm");
world_comm.free("ff_num_col_comm");
} // if
#endif
#ifdef USE_MPI
world_comm.barrier(comm_key);
world_comm.free(real_world);
#endif
#ifdef FINDBLOCK
} // block_t
} // block_z
} // block_y
} // block_x
#endif
return true;
} // NumericFormFactor::compute()
bool NumericFormFactor::compute(const char * filename, complex_vec_t & ff,
RotMatrix_t & rot
#ifdef USE_MPI
, woo::MultiNode &world_comm, std::string comm_key
#endif
){
real_t comp_time = 0.0;
// initialize
init (rot, ff);
unsigned int nqy = QGrid::instance().nqy();
unsigned int nqz = QGrid::instance().nqz_extended();
// warning: all procs read the shape file!!!!
// TODO: improve to parallel IO, or one proc reading and sending to all ...
// #ifndef __SSE3__
real_vec_t shape_def;
// #else
// #ifdef USE_GPU
// real_vec_t shape_def;
// #else
// real_t* shape_def = NULL;
// #endif
// #endif
// use the new file reader instead ...
unsigned int num_triangles = read_shapes_file(filename, shape_def);
// TODO ... <--- sadly all procs read this! IMPROVE!!!
#ifdef USE_MPI
int num_procs = world_comm.size(comm_key);
int rank = world_comm.rank(comm_key);
bool master = world_comm.is_master(comm_key);
#else
bool master = true;
#endif
if(master) {
std::cout << "-- Numerical form factor computation ..." << std::endl
<< "** Using input shape file: " << filename << std::endl
<< "** Number of input triangles: " << num_triangles << std::endl
<< "** Q-grid resolution (q-points): " << nqz << std::endl
#ifdef USE_MPI
<< "** Number of processes requested: " << num_procs << std::endl
#endif
<< std::flush;
} // if
if(num_triangles < 1) {
std::cerr << "error: no triangles found in specified definition file" << std::endl;
return false;
} // if
// FIXME: this is a yucky temporary fix ... fix properly ...
real_t* qx = new (std::nothrow) real_t[nqy]();
real_t* qy = new (std::nothrow) real_t[nqy]();
#ifdef FF_NUM_GPU
cucomplex_t* qz = new (std::nothrow) cucomplex_t[nqz]();
#else
complex_t* qz = new (std::nothrow) complex_t[nqz]();
#endif
// create qy_and qz using qgrid instance
for(unsigned int i = 0; i < nqy; ++ i) qx[i] = QGrid::instance().qx(i);
for(unsigned int i = 0; i < nqy; ++ i) qy[i] = QGrid::instance().qy(i);
for(unsigned int i = 0; i < nqz; ++ i) {
#ifdef FF_NUM_GPU
qz[i].x = QGrid::instance().qz_extended(i).real();
qz[i].y = QGrid::instance().qz_extended(i).imag();
#else
qz[i] = QGrid::instance().qz_extended(i);
#endif
} // for
#ifdef FF_NUM_GPU
cucomplex_t *p_ff = NULL;
#else
complex_t *p_ff = NULL;
#endif
real_t kernel_time = 0.;
unsigned int ret_numtriangles = 0;
#ifdef FF_NUM_GPU // use GPU
ret_numtriangles = gff_.compute_approx_triangle(shape_def,
p_ff, nqy, qx, qy, nqz, qz, rot_, kernel_time);
for (int i = 0; i < nqz; i++) ff.push_back(complex_t(p_ff[i].x, p_ff[i].y));
std::cout << "** FF GPU compute time: " << kernel_time << " ms." << std::endl;
#else // use only CPU
ret_numtriangles = cff_.compute_approx_triangle(shape_def,
p_ff, nqy, qx, qy, nqz, qz, rot_, kernel_time);
for (int i = 0; i < nqz; i++) ff.push_back(p_ff[i]);
std::cout << "** FF CPU compute time: " << kernel_time << " ms." << std::endl;
#endif
if(p_ff != NULL) delete[] p_ff;
delete[] qz;
delete[] qy;
delete[] qx;
}
bool mat_exp_in(complex_vec_t& matrix) {
for(complex_vec_t::iterator i = matrix.begin(); i != matrix.end(); ++ i) *i = exp(*i);
} // mat_exp_in()
bool mat_exp(complex_vec_t& matrix, complex_vec_t& result) {
result.clear();
for(complex_vec_t::iterator i = matrix.begin(); i != matrix.end(); ++ i)
result.push_back(exp(*i));
} // mat_exp()
bool mat_mul_in(complex_t scalar, complex_vec_t& matrix) {
for(complex_vec_t::iterator i = matrix.begin(); i != matrix.end(); ++ i) {
*i = (*i) * scalar;
} // for
return true;
} // mat_mul()
