213 lines
6.2 KiB
C++
213 lines
6.2 KiB
C++
#include "hdf5_array.hpp"
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#include "miniargs.hpp"
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#include "mykdtree.hpp"
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#include "omptl/algorithm"
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#include "openmp.hpp"
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#include "sphSmooth.hpp"
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#include "yorick.hpp"
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#include <H5Cpp.h>
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#include <boost/bind.hpp>
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#include <boost/format.hpp>
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#include <cassert>
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#include <iostream>
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using namespace std;
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using namespace CosmoTool;
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#define N_SPH 32
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struct VCoord {
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float v[3];
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float mass;
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};
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using boost::format;
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using boost::str;
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typedef boost::multi_array<float, 2> array_type;
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typedef boost::multi_array<float, 3> array3_type;
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typedef boost::multi_array<float, 4> array4_type;
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ComputePrecision getVelocity(const VCoord &v, int i) { return v.mass * v.v[i]; }
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ComputePrecision getMass(const VCoord &v) { return v.mass; }
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typedef SPHSmooth<VCoord> MySmooth;
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typedef MySmooth::SPHTree MyTree;
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typedef MyTree::Cell MyCell;
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template <typename FuncT>
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void computeInterpolatedField(MyTree *tree1, double boxsize, int Nres,
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double cx, double cy, double cz,
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array3_type &bins, array3_type &arr, FuncT func,
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double rLimit2) {
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int rz_max = 0;
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#pragma omp parallel shared(rz_max)
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{
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MySmooth smooth1(tree1, N_SPH);
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#pragma omp for collapse(3) schedule(dynamic)
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for (int rz = 0; rz < Nres; rz++) {
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for (int ry = 0; ry < Nres; ry++) {
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for (int rx = 0; rx < Nres; rx++) {
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if (rz > rz_max) {
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rz_max = rz;
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cout << format("[%d] %d / %d") % smp_get_thread_id() % rz % Nres
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<< endl;
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}
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double px = (rx)*boxsize / Nres - cx;
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double py = (ry)*boxsize / Nres - cy;
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double pz = (rz)*boxsize / Nres - cz;
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MyTree::coords c = {float(px), float(py), float(pz)};
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double r2 = c[0] * c[0] + c[1] * c[1] + c[2] * c[2];
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if (r2 > rLimit2) {
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arr[rx][ry][rz] = 0;
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continue;
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}
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uint32_t numInCell = bins[rx][ry][rz];
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if (numInCell > N_SPH)
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smooth1.fetchNeighbours(c, numInCell);
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else
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smooth1.fetchNeighbours(c);
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arr[rx][ry][rz] = smooth1.computeSmoothedValue(c, func);
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}
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}
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}
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}
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}
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int main(int argc, char **argv) {
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char *fname1, *outFile;
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double rLimit, boxsize, rLimit2, cx, cy, cz;
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int Nres;
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int periodic;
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MiniArgDesc args[] = {{"INPUT DATA1", &fname1, MINIARG_STRING},
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{"RADIUS LIMIT", &rLimit, MINIARG_DOUBLE},
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{"BOXSIZE", &boxsize, MINIARG_DOUBLE},
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{"RESOLUTION", &Nres, MINIARG_INT},
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{"CX", &cx, MINIARG_DOUBLE},
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{"CY", &cy, MINIARG_DOUBLE},
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{"CZ", &cz, MINIARG_DOUBLE},
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{"OUTPUT FILE", &outFile, MINIARG_STRING},
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{"PERIODIC", &periodic, MINIARG_INT},
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{0, 0, MINIARG_NULL}};
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if (!parseMiniArgs(argc, argv, args))
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return 1;
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H5::H5File in_f(fname1, 0);
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H5::H5File out_f(outFile, H5F_ACC_TRUNC);
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array_type v1_data;
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uint64_t N1_points, N2_points;
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array3_type bins(boost::extents[Nres][Nres][Nres]);
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rLimit2 = rLimit * rLimit;
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hdf5_read_array(in_f, "particles", v1_data);
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assert(v1_data.shape()[1] == 7);
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N1_points = v1_data.shape()[0];
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cout << "Got " << N1_points << " in the first file." << endl;
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MyCell *allCells_1 = new MyCell[N1_points];
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#pragma omp parallel for schedule(static)
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for (uint32_t i = 0; i < Nres * Nres * Nres; i++)
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bins.data()[i] = 0;
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cout << "Shuffling data in cells..." << endl;
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#pragma omp parallel for schedule(static)
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for (uint64_t i = 0; i < N1_points; i++) {
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for (int j = 0; j < 3; j++)
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allCells_1[i].coord[j] = v1_data[i][j];
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for (int k = 0; k < 3; k++)
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allCells_1[i].val.pValue.v[k] = v1_data[i][3 + k];
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allCells_1[i].val.pValue.mass = v1_data[i][6];
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allCells_1[i].active = true;
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allCells_1[i].val.weight = 0.0;
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long rx = floor((allCells_1[i].coord[0] + cx) * Nres / boxsize + 0.5);
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long ry = floor((allCells_1[i].coord[1] + cy) * Nres / boxsize + 0.5);
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long rz = floor((allCells_1[i].coord[2] + cz) * Nres / boxsize + 0.5);
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if (rx < 0 || rx >= Nres || ry < 0 || ry >= Nres || rz < 0 || rz >= Nres)
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continue;
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auto &b = bins[rx][ry][rz];
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#pragma omp atomic
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b++;
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}
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v1_data.resize(boost::extents[1][1]);
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hdf5_write_array(out_f, "num_in_cell", bins);
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cout << "Building trees..." << endl;
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MyTree tree1(allCells_1, N1_points);
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tree1.setPeriodic(periodic != 0);
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cout << "Creating smoothing filter..." << endl;
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// array3_type out_rad_1(boost::extents[Nres][Nres][Nres]);
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cout << "Weighing..." << endl;
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int rz_max = 0;
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#pragma omp parallel shared(rz_max)
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{
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MySmooth smooth1(&tree1, N_SPH);
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#pragma omp for collapse(3) schedule(dynamic, 8)
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for (int rz = 0; rz < Nres; rz++) {
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for (int ry = 0; ry < Nres; ry++) {
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for (int rx = 0; rx < Nres; rx++) {
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if (rz > rz_max) {
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rz_max = rz;
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(cout << rz << " / " << Nres << endl).flush();
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}
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double pz = (rz)*boxsize / Nres - cz;
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double py = (ry)*boxsize / Nres - cy;
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double px = (rx)*boxsize / Nres - cx;
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MyTree::coords c = {float(px), float(py), float(pz)};
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double r2 = c[0] * c[0] + c[1] * c[1] + c[2] * c[2];
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if (r2 > rLimit2) {
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continue;
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}
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uint32_t numInCell = bins[rx][ry][rz];
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if (numInCell > N_SPH)
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smooth1.fetchNeighbours(c, numInCell);
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else
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smooth1.fetchNeighbours(c);
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smooth1.addGridSite(c);
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}
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}
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}
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}
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cout << "Interpolating..." << endl;
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array3_type interpolated(boost::extents[Nres][Nres][Nres]);
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computeInterpolatedField(&tree1, boxsize, Nres, cx, cy, cz, bins,
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interpolated, getMass, rLimit2);
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hdf5_write_array(out_f, "density", interpolated);
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// out_f.flush();
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for (int i = 0; i < 3; i++) {
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computeInterpolatedField(&tree1, boxsize, Nres, cx, cy, cz, bins,
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interpolated, boost::bind(getVelocity, _1, i),
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rLimit2);
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hdf5_write_array(out_f, str(format("p%d") % i), interpolated);
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}
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return 0;
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};
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