SingleParticle2dx::DataStructures::ParticleShift::ParticleShift ()
: m_data ( value_array_type(0,0) )
{}
SingleParticle2dx::DataStructures::ParticleShift::ParticleShift (value_type x, value_type y)
: m_data ( value_array_type(x,y) )
{}
void run_experiment(
int repeatcount, idx nv, idx ne,
idx_array_type kok_xadj,
idx_edge_array_type kok_adj,
value_array_type kok_mtx_vals
){
value_array_type kok_x_original = create_x_vector(nv, MAXVAL);
value_array_type kok_b_vector = create_b_vector(
nv,
kok_xadj,
kok_adj,
kok_mtx_vals,
kok_x_original);
Experimental::KokkosKernels::Example::CrsMatrix<wt, idx, MyExecSpace> A(nv ,ne, kok_xadj, kok_adj, kok_mtx_vals);
//create X vector
value_array_type kok_x_vector("kok_x_vector", nv);
double gs_time = 0;
const unsigned cg_iteration_limit = 100000;
const double cg_iteration_tolerance = 1e-7 ;
Experimental::KokkosKernels::Example::CGSolveResult cg_result ;
typedef Experimental::KokkosKernels::KokkosKernelsHandle
<idx_array_type,idx_edge_array_type, value_array_type,
MyExecSpace, TemporaryWorkSpace,PersistentWorkSpace > KernelHandle;
KernelHandle kh;
kh.set_row_map(A.graph.row_map);
kh.set_entries(A.graph.entries);
kh.set_values(A.coeff);
Kokkos::Impl::Timer timer1;
Experimental::KokkosKernels::Example::pcgsolve(
kh
, A
, kok_b_vector
, kok_x_vector
, cg_iteration_limit
, cg_iteration_tolerance
, & cg_result
, true
);
Kokkos::fence();
gs_time = timer1.seconds();
std::cout << " cg_iteration[" << cg_result.iteration << "]"
<< " matvec_time[" << cg_result.matvec_time << "]"
<< " cg_residual[" << cg_result.norm_res << "]"
<< " cg_iter_time[" << cg_result.iter_time << "]"
<< " precond_time[" << cg_result.precond_time << "]"
<< " precond_init_time[" << cg_result.precond_init_time << "]"
<< " precond_time/iter[" << cg_result.precond_time / (cg_result.iteration + 1) << "]"
<< " GSTIME[" << gs_time<< "]"
<< std::endl ;
kh.create_graph_coloring_handle(Experimental::KokkosKernels::Graph::COLORING_VB);
Experimental::KokkosKernels::Graph::graph_color_solve<KernelHandle> (&kh);
kok_x_vector = value_array_type("kok_x_vector", nv);
timer1.reset();
Experimental::KokkosKernels::Example::pcgsolve(
kh
, A
, kok_b_vector
, kok_x_vector
, cg_iteration_limit
, cg_iteration_tolerance
, & cg_result
, true
);
Kokkos::fence();
gs_time = timer1.seconds();
std::cout << "\n\nCOLORING_VB PRECALL:\n cg_iteration[" << cg_result.iteration << "]"
<< " matvec_time[" << cg_result.matvec_time << "]"
<< " cg_residual[" << cg_result.norm_res << "]"
<< " cg_iter_time[" << cg_result.iter_time << "]"
<< " precond_time[" << cg_result.precond_time << "]"
<< " precond_init_time[" << cg_result.precond_init_time << "]"
<< " precond_time/iter[" << cg_result.precond_time / (cg_result.iteration + 1) << "]"
<< " GSTIME[" << gs_time<< "]"
<< " numColor[" << kh.get_graph_coloring_handle()->get_num_colors()<<"]"
<< std::endl ;
kh.destroy_graph_coloring_handle();
kh.create_graph_coloring_handle(Experimental::KokkosKernels::Graph::COLORING_EB);
Experimental::KokkosKernels::Graph::graph_color_solve<KernelHandle> (&kh);
kok_x_vector = value_array_type("kok_x_vector", nv);
timer1.reset();
Experimental::KokkosKernels::Example::pcgsolve(
kh
, A
, kok_b_vector
, kok_x_vector
, cg_iteration_limit
, cg_iteration_tolerance
, & cg_result
, true
);
Kokkos::fence();
gs_time = timer1.seconds();
std::cout << "\n\nCOLORING_EB PRECALL:\n cg_iteration[" << cg_result.iteration << "]"
<< " matvec_time[" << cg_result.matvec_time << "]"
<< " cg_residual[" << cg_result.norm_res << "]"
<< " cg_iter_time[" << cg_result.iter_time << "]"
<< " precond_time[" << cg_result.precond_time << "]"
<< " precond_init_time[" << cg_result.precond_init_time << "]"
<< " precond_time/iter[" << cg_result.precond_time / (cg_result.iteration + 1) << "]"
<< " GSTIME[" << gs_time<< "]"
<< " numColor[" << kh.get_graph_coloring_handle()->get_num_colors()<<"]"
<< std::endl ;
kh.destroy_graph_coloring_handle();
kh.destroy_gs_handle();
kh.create_gs_handle(Experimental::KokkosKernels::Graph::GS_PERMUTED);
kok_x_vector = value_array_type("kok_x_vector", nv);
timer1.reset();
Experimental::KokkosKernels::Example::pcgsolve(
kh
, A
, kok_b_vector
, kok_x_vector
, cg_iteration_limit
, cg_iteration_tolerance
, & cg_result
, true
);
Kokkos::fence();
gs_time = timer1.seconds();
std::cout << "\n\nPERMUTED:\n cg_iteration[" << cg_result.iteration << "]"
<< " matvec_time[" << cg_result.matvec_time << "]"
<< " cg_residual[" << cg_result.norm_res << "]"
<< " cg_iter_time[" << cg_result.iter_time << "]"
<< " precond_time[" << cg_result.precond_time << "]"
<< " precond_init_time[" << cg_result.precond_init_time << "]"
<< " precond_time/iter[" << cg_result.precond_time / (cg_result.iteration + 1) << "]"
<< " GSTIME[" << gs_time<< "]"
<< std::endl ;
kh.destroy_graph_coloring_handle();
kh.destroy_gs_handle();
kh.create_gs_handle(Experimental::KokkosKernels::Graph::GS_TEAM);
kok_x_vector = value_array_type("kok_x_vector", nv);
timer1.reset();
Experimental::KokkosKernels::Example::pcgsolve(
kh
, A
, kok_b_vector
, kok_x_vector
, cg_iteration_limit
, cg_iteration_tolerance
, & cg_result
, true
);
Kokkos::fence();
gs_time = timer1.seconds();
std::cout << "\n\nGSTEAM:\n cg_iteration[" << cg_result.iteration << "]"
<< " matvec_time[" << cg_result.matvec_time << "]"
<< " cg_residual[" << cg_result.norm_res << "]"
<< " cg_iter_time[" << cg_result.iter_time << "]"
<< " precond_time[" << cg_result.precond_time << "]"
<< " precond_init_time[" << cg_result.precond_init_time << "]"
<< " precond_time/iter[" << cg_result.precond_time / (cg_result.iteration + 1) << "]"
<< " GSTIME[" << gs_time<< "]"
<< std::endl ;
}
