void two_level_test(const Kernel& K) { typedef Kernel kernel_type; typedef typename kernel_type::point_type point_type; typedef typename kernel_type::source_type source_type; typedef typename kernel_type::target_type target_type; typedef typename kernel_type::charge_type charge_type; typedef typename kernel_type::result_type result_type; typedef typename kernel_type::multipole_type multipole_type; typedef typename kernel_type::local_type local_type; // init source std::vector<source_type> s(1); s[0] = source_type(0,0,0); // init charge std::vector<charge_type> c(1); c[0][0] = 1.; c[0][1] = 2.; c[0][2] = 3.; c[0][3] = 1.; c[0][4] = 0.; c[0][5] = 1.; // init target std::vector<target_type> t(1); t[0] = target_type(0.98,0.98,0.98); // init results vectors for exact, FMM std::vector<result_type> rexact(1); result_type rm2p; result_type rfmm; // test direct K.P2P(s.begin(),s.end(),c.begin(),t.begin(),t.end(),rexact.begin()); // setup intial multipole expansion multipole_type M; const point_type M_center(0.05, 0.05, 0.05); INITM::eval(K, M, M_center, 2u); K.P2M(s[0], c[0], M_center, M); // perform M2M multipole_type M2; const point_type M2_center(0.1, 0.1, 0.1); INITM::eval(K, M2, M2_center, 1u); K.M2M(M, M2, M2_center - M_center); //K.P2M(s,c,M2_center,M2); // test M2P K.M2P(M2, M2_center, t[0], rm2p); // test M2L, L2P #ifndef TREECODE_ONLY local_type L2; point_type L2_center(0.9, 0.9, 0.9); INITL::eval(K, L2, L2_center, 1u); K.M2L(M2, L2, L2_center - M2_center); // test L2L local_type L; point_type L_center(0.95, 0.95, 0.95); INITL::eval(K, L, L_center, 2u); K.L2L(L2, L, L_center - L2_center); // test L2P K.L2P(L2, L2_center, t[0], rfmm); #endif // check errors std::cout << "rexact = " << rexact[0] << std::endl; std::cout << "rm2p = " << 1./6*rm2p << std::endl; std::cout << "rfmm = " << 1./6*rfmm << std::endl; /* std::cout << "M2P L1 rel error: " << std::scientific << l1_rel_error(rm2p, rexact) << std::endl; std::cout << "M2P L2 error: " << std::scientific << l2_error(rm2p, rexact) << std::endl; std::cout << "M2P L2 rel error: " << std::scientific << l2_rel_error(rm2p, rexact) << std::endl; #ifndef TREECODE_ONLY std::cout << "FMM L1 rel error: " << std::scientific << l1_rel_error(rfmm, rexact) << std::endl; std::cout << "FMM L2 error: " << std::scientific << l2_error(rfmm, rexact) << std::endl; std::cout << "FMM L2 rel error: " << std::scientific << l2_rel_error(rfmm, rexact) << std::endl; #endif */ }
void two_level_test(const Expansion& K) { typedef Expansion expansion_type; typedef typename expansion_type::source_type source_type; typedef typename expansion_type::target_type target_type; typedef typename expansion_type::charge_type charge_type; typedef typename expansion_type::result_type result_type; typedef typename expansion_type::point_type point_type; typedef typename expansion_type::multipole_type multipole_type; typedef typename expansion_type::local_type local_type; // init source std::vector<source_type> s(1); s[0] = source_type(0,0,0); // init charge std::vector<charge_type> c(1); c[0] = charge_type(1); // init target std::vector<target_type> t(1); t[0] = target_type(0.98,0.98,0.98); // init results vectors for exact, FMM std::vector<result_type> rexact(1); result_type rm2p; result_type rfmm; // test direct Direct::matvec(K, s, c, t, rexact); // setup intial multipole expansion multipole_type M; point_type M_center(0.05, 0.05, 0.05); point_type M_extent(0.1, 0.1, 0.1); INITM::eval(K, M, M_extent, 2u); K.P2M(s[0], c[0], M_center, M); // perform M2M multipole_type M2; point_type M2_center(0.1, 0.1, 0.1); point_type M2_extent(0.2, 0.2, 0.2); INITM::eval(K, M2, M2_extent, 1u); K.M2M(M, M2, M2_center - M_center); //K.P2M(s,c,M2_center,M2); // test M2P K.M2P(M2, M2_center, t[0], rm2p); // test M2L, L2P #ifndef TREECODE_ONLY local_type L2; point_type L2_center(0.9, 0.9, 0.9); point_type L2_extent(0.2, 0.2, 0.2); INITL::eval(K, L2, L2_center, 1u); K.M2L(M2, L2, L2_center - M2_center); // test L2L local_type L; point_type L_center(0.95, 0.95, 0.95); point_type L_extent(0.1, 0.1, 0.1); INITL::eval(K, L, L_extent, 2u); K.L2L(L2, L, L_center - L2_center); // test L2P K.L2P(L2, L2_center, t[0], rfmm); #endif // check errors std::cout << "rexact = " << rexact[0] << std::endl; std::cout << "rm2p = " << rm2p << "\n " << "[" << (rm2p - rexact[0]) << "]" << std::endl; std::cout << "rfmm = " << rfmm << "\n " << "[" << (rfmm - rexact[0]) << "]" << std::endl; }