230 lines
6.5 KiB
C++
230 lines
6.5 KiB
C++
#include <omp.h>
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#include <iostream>
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#include <boost/format.hpp>
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#include <boost/multi_array.hpp>
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#include <sys/types.h>
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#include <cmath>
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using std::cout;
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using std::endl;
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using boost::format;
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#if defined _WIN32 || defined __CYGWIN__
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#ifdef BUILDING_DLL
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#ifdef __GNUC__
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#define DLL_PUBLIC __attribute__ ((dllexport))
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#else
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#define DLL_PUBLIC __declspec(dllexport) // Note: actually gcc seems to also supports this syntax.
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#endif
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#else
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#ifdef __GNUC__
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#define DLL_PUBLIC __attribute__ ((dllimport))
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#else
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#define DLL_PUBLIC __declspec(dllimport) // Note: actually gcc seems to also supports this syntax.
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#endif
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#endif
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#define DLL_LOCAL
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#else
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#if __GNUC__ >= 4
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#define DLL_PUBLIC __attribute__ ((visibility ("default")))
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#define DLL_LOCAL __attribute__ ((visibility ("hidden")))
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#else
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#define DLL_PUBLIC
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#define DLL_LOCAL
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#endif
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#endif
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struct ModeSet
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{
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size_t N1, N2, N3;
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bool omp;
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struct TriangleIterator
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{
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ssize_t i1, i2, i3;
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size_t N1, N2, N3;
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TriangleIterator& operator++() {
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i3++;
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if (i3==N3) { i3 = 0; i2++; }
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if (i2==N2) { i2 = 0; i1++; }
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return *this;
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}
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bool operator!=(const TriangleIterator& t) const {
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return i1!=t.i1 || i2!=t.i2 || i3 != t.i3;
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}
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bool in_box() const {
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ssize_t hN1 = N1/2, hN2 = N2/2, hN3 = N3/2;
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return (i1 >= -hN1) && (i1 < hN1) && (i2 >= -hN2) && (i2 < hN2) && (i3 >= -hN3) && (i3 < hN3);
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}
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TriangleIterator operator+(const TriangleIterator& other_t) const {
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TriangleIterator t = *this;
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t.i1 = (t.i1+other_t.i1);
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t.i2 = (t.i2+other_t.i2);
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t.i3 = (t.i3+other_t.i3);
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return t;
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}
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TriangleIterator real() const {
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TriangleIterator t = *this;
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if (t.i1 >= N1/2)
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t.i1 -= N1;
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if (t.i2 >= N2/2)
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t.i2 -= N2;
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if (t.i3 >= N3/2)
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t.i3 -= N3;
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return t;
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}
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double norm() const {
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double r1 = i1, r2 = i3, r3 = i3;
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return std::sqrt(r1*r1 + r2*r2 + r3*r3);
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}
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void reverse() { i1=-i1; i2=-i2; i3=-i3; }
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TriangleIterator& operator*() { return *this; }
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};
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ModeSet(size_t N1_, size_t N2_, size_t N3_, bool do_openmp = false)
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: N1(N1_), N2(N2_), N3(N3_),omp(do_openmp) {
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}
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TriangleIterator begin() const {
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TriangleIterator t;
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t.i1 = t.i2 = t.i3 = 0;
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t.N2 = N2;
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t.N3 = N3;
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t.N1 = N1;
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return t;
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}
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TriangleIterator end() const {
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TriangleIterator t;
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t.i2 = t.i3 = 0;
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t.i1 = N1;
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t.N1 = N1;
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t.N2 = N2;
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t.N3 = N3;
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return t;
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}
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};
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template<typename T>
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static T no_conj(const T& a) { return a; }
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extern "C" DLL_PUBLIC
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void CosmoTool_compute_bispectrum(
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double *delta_hat, size_t Nx, size_t Ny, size_t Nz,
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size_t *Ntriangles,
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double* B, double delta_k, size_t Nk )
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{
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// First remap to multi_array for easy access
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size_t kNz = Nz/2+1;
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int Ntasks = omp_get_max_threads();
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boost::multi_array_ref<std::complex<double>, 3> a_delta(reinterpret_cast<std::complex<double>*>(delta_hat), boost::extents[Nx][Ny][kNz]);
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boost::multi_array_ref<size_t, 3> a_Nt(Ntriangles, boost::extents[Nk][Nk][Nk]);
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boost::multi_array_ref<std::complex<double>, 3> a_B(reinterpret_cast<std::complex<double>*>(B), boost::extents[Nk][Nk][Nk]);
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boost::multi_array<std::complex<double>, 4> b_B(boost::extents[Ntasks][Nk][Nk][Nk]);
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boost::multi_array<size_t, 4> b_Nt(boost::extents[Ntasks][Nk][Nk][Nk]);
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typedef std::complex<double> CType;
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// First loop over m1
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#pragma omp parallel
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{
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#pragma omp single
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{
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for (auto m1 : ModeSet(Nx, Ny, Nz, true)) {
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int tid = omp_get_thread_num();
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#pragma omp task
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{
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CType v1 = (m1.i3 >= kNz) ? std::conj(a_delta[m1.i1][m1.i2][(m1.N3-m1.i3)%m1.N3]) : a_delta[m1.i1][m1.i2][m1.i3];
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auto rm1 = m1.real();
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// Second mode m2
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for (auto m2 : ModeSet(Nx, Ny, Nz)) {
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// Now derive m3
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CType v2 = (m2.i3 >= kNz) ? std::conj(a_delta[m2.i1][m2.i2][(m2.N3-m2.i3)%m2.N3]) : a_delta[m2.i1][m2.i2][m2.i3];
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auto rm2 = m2.real();
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auto m3 = (rm1+rm2);
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if (!m3.in_box())
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continue;
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size_t q1 = std::floor(rm1.norm()/delta_k);
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size_t q2 = std::floor(rm2.norm()/delta_k);
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size_t q3 = std::floor(m3.norm()/delta_k);
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if (q1 >= Nk || q2 >= Nk || q3 >= Nk)
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continue;
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CType prod = v1*v2;
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bool do_conj = false;
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// We use hermitic symmetry to get -m3, it is just the mode in m3 but conjugated.
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m3.reverse();
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if (m3.i3 > 0) {
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assert(m3.i3 < kNz);
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} else {
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m3.i3 = -m3.i3;
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do_conj = !do_conj;
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}
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m3.i1 = (m3.N1 - m1.i1)%m3.N1;
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m3.i2 = (m3.N2 - m3.i2)%m3.N2;
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if (do_conj)
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prod *= std::conj(a_delta[m3.i1][m3.i2][m3.i3]);
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else
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prod *= (a_delta[m3.i1][m3.i2][m3.i3]);
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b_Nt[tid][q1][q2][q3] ++;
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b_B[tid][q1][q2][q3] += prod;
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}
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}
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}
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}
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}
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for (int tid = 0; tid < Ntasks; tid++)
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for (auto m1 : ModeSet(Nk, Nk, Nk)) {
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a_Nt[m1.i1][m1.i2][m1.i3] += b_Nt[tid][m1.i1][m1.i2][m1.i3];
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a_B[m1.i1][m1.i2][m1.i3] += b_B[tid][m1.i1][m1.i2][m1.i3];
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}
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}
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extern "C" DLL_PUBLIC
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void CosmoTool_compute_powerspectrum(
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double *delta_hat, size_t Nx, size_t Ny, size_t Nz,
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size_t *Ncounts,
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double* P, double delta_k, size_t Nk )
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{
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// First remap to multi_array for easy access
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size_t kNz = Nz/2+1;
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boost::multi_array_ref<std::complex<double>, 3> a_delta(reinterpret_cast<std::complex<double>*>(delta_hat), boost::extents[Nx][Ny][kNz]);
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boost::multi_array_ref<size_t, 1> a_Nc(Ncounts, boost::extents[Nk]);
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boost::multi_array_ref<double, 1> a_P(reinterpret_cast<double*>(P), boost::extents[Nk]);
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typedef std::complex<double> CType;
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// First loop over m1
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for (auto m1 : ModeSet(Nx, Ny, kNz)) {
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CType& v1 = a_delta[m1.i1][m1.i2][m1.i3];
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size_t q1 = std::floor(m1.norm()/delta_k);
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if (q1 >= Nk)
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continue;
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a_Nc[q1] ++;
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a_P[q1] += std::norm(v1);
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}
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}
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