add json output to Benchmark_Quda
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@ -4,17 +4,22 @@
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#include <cassert>
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#include <color_spinor_field.h>
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#include <dirac_quda.h>
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#include <fstream>
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#include <gauge_tools.h>
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#include <memory>
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#include <mpi.h>
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#include <stdio.h>
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#include <stdlib.h>
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using namespace quda;
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// remove to use QUDA's own flop counting instead of Grid's convention
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#define FLOP_COUNTING_GRID
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#include "json.hpp"
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using nlohmann::json;
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json json_results;
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using namespace quda;
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// This is the MPI grid, i.e. the layout of ranks
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int nranks = -1;
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std::array<int, 4> mpi_grid = {1, 1, 1, 1};
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@ -43,6 +48,9 @@ void initComms(int argc, char **argv)
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for (int d = 0; d < 4; d++)
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if (mpi_grid[d] > 1)
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commDimPartitionedSet(d);
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json_results["geometry"]["ranks"] = nranks;
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json_results["geometry"]["mpi"] = mpi_grid;
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}
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// creates a random gauge field. L = local(!) size
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@ -149,9 +157,8 @@ ColorSpinorField make_source(int L, int Ls = 1)
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return src;
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}
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void benchmark_wilson()
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void benchmark_wilson(std::vector<int> const &L_list, int niter)
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{
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int niter = 20;
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int niter_warmup = 10;
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printfQuda("==================== wilson dirac operator ====================\n");
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@ -163,7 +170,7 @@ void benchmark_wilson()
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#endif
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printfQuda("%5s %15s %15s\n", "L", "time (usec)", "Gflop/s/rank");
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for (int L : {8, 12, 16, 24, 32, 48})
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for (int L : L_list)
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{
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auto U = make_gauge_field(L);
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auto src = make_source(L);
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@ -180,18 +187,18 @@ void benchmark_wilson()
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// Not used for simple Wilson fermions)
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dirac.updateFields(&U, nullptr, nullptr, nullptr);
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auto tmp = ColorSpinorField(ColorSpinorParam(src));
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auto res = ColorSpinorField(ColorSpinorParam(src));
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// couple iterations without timing to warm up
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for (int iter = 0; iter < niter_warmup; ++iter)
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dirac.Dslash(tmp, src, QUDA_EVEN_PARITY);
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dirac.Dslash(res, src, QUDA_EVEN_PARITY);
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// actual benchmark with timings
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dirac.Flops(); // reset flops counter
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device_timer_t device_timer;
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device_timer.start();
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for (int iter = 0; iter < niter; ++iter)
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dirac.Dslash(tmp, src, QUDA_EVEN_PARITY);
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dirac.Dslash(res, src, QUDA_EVEN_PARITY);
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device_timer.stop();
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double secs = device_timer.last() / niter;
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@ -209,12 +216,16 @@ void benchmark_wilson()
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#endif
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printfQuda("%5d %15.2f %15.2f\n", L, secs * 1e6, flops / secs * 1e-9);
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json tmp;
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tmp["L"] = L;
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tmp["Gflops_wilson"] = flops / secs * 1e-9;
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json_results["flops"]["results"].push_back(tmp);
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}
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}
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void benchmark_dwf()
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void benchmark_dwf(std::vector<int> const &L_list, int niter)
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{
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int niter = 20;
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int niter_warmup = 10;
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printfQuda("==================== domain wall dirac operator ====================\n");
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@ -226,7 +237,7 @@ void benchmark_dwf()
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#endif
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printfQuda("%5s %15s %15s\n", "L", "time (usec)", "Gflop/s/rank");
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int Ls = 12;
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for (int L : {8, 12, 16, 24})
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for (int L : L_list)
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{
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auto U = make_gauge_field(L);
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auto src = make_source(L, Ls);
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@ -244,18 +255,18 @@ void benchmark_dwf()
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// (the additional nullptr's are for smeared links and fancy preconditioners and such)
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dirac.updateFields(&U, nullptr, nullptr, nullptr);
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auto tmp = ColorSpinorField(ColorSpinorParam(src));
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auto res = ColorSpinorField(ColorSpinorParam(src));
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// couple iterations without timing to warm up
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for (int iter = 0; iter < niter_warmup; ++iter)
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dirac.Dslash(tmp, src, QUDA_EVEN_PARITY);
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dirac.Dslash(res, src, QUDA_EVEN_PARITY);
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// actual benchmark with timings
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dirac.Flops(); // reset flops counter
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device_timer_t device_timer;
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device_timer.start();
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for (int iter = 0; iter < niter; ++iter)
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dirac.Dslash(tmp, src, QUDA_EVEN_PARITY);
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dirac.Dslash(res, src, QUDA_EVEN_PARITY);
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device_timer.stop();
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double secs = device_timer.last() / niter;
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@ -273,15 +284,18 @@ void benchmark_dwf()
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#endif
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printfQuda("%5d %15.2f %15.2f\n", L, secs * 1e6, flops / secs * 1e-9);
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json tmp;
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tmp["L"] = L;
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tmp["Gflops_dwf4"] = flops / secs * 1e-9;
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json_results["flops"]["results"].push_back(tmp);
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}
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}
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void benchmark_axpy()
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void benchmark_axpy(std::vector<int> const &L_list, int niter)
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{
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// number of iterations for warmup / measurement
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// (feel free to change for noise/time tradeoff)
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constexpr int niter_warmup = 10;
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constexpr int niter = 20;
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printfQuda("==================== axpy / memory ====================\n");
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@ -305,7 +319,6 @@ void benchmark_axpy()
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printfQuda("%5s %15s %15s %15s %15s\n", "L", "size (MiB/rank)", "time (usec)",
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"GiB/s/rank", "Gflop/s/rank");
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std::vector L_list = {8, 12, 16, 24, 32, 48};
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for (int L : L_list)
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{
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// IMPORTANT: all of `param.x`, `field_elements`, `field.Bytes()`
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@ -348,14 +361,29 @@ void benchmark_axpy()
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blas::axpy(1.234, fieldA, fieldB);
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device_timer.stop();
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double secs = device_timer.last() / niter; // seconds per iteration
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double mem_MiB = memory / 1024. / 1024.;
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double GBps = mem_MiB / 1024 / secs;
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printfQuda("%5d %15.2f %15.2f %15.2f %15.2f\n", L, mem_MiB, secs * 1e6, GBps,
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flops / secs * 1e-9);
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printfQuda("%5d %15.2f %15.2f %15.2f %15.2f\n", L, memory / 1024. / 1024., secs * 1e6,
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memory / secs / 1024. / 1024. / 1024., flops / secs * 1e-9);
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json tmp;
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tmp["L"] = L;
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tmp["size_MB"] = mem_MiB;
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tmp["GBps"] = GBps;
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tmp["GFlops"] = flops / secs * 1e-9;
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json_results["axpy"].push_back(tmp);
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}
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}
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int main(int argc, char **argv)
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{
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std::string json_filename = ""; // empty indicates no json output
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for (int i = 0; i < argc; i++)
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{
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if (std::string(argv[i]) == "--json-out")
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json_filename = argv[i + 1];
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}
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initComms(argc, argv);
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initQuda(-1); // -1 for multi-gpu. otherwise this selects the device to be used
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@ -367,14 +395,28 @@ int main(int argc, char **argv)
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printfQuda("MPI layout = %d %d %d %d\n", mpi_grid[0], mpi_grid[1], mpi_grid[2],
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mpi_grid[3]);
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benchmark_axpy();
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benchmark_axpy({8, 12, 16, 24, 32, 48}, 20);
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setVerbosity(QUDA_SILENT);
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benchmark_wilson();
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benchmark_dwf();
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benchmark_wilson({8, 12, 16, 24, 32, 48}, 20);
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benchmark_dwf({8, 12, 16, 24, 32}, 20);
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setVerbosity(QUDA_SUMMARIZE);
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printfQuda("==================== done with all benchmarks ====================\n");
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if (!json_filename.empty())
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{
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printfQuda("writing benchmark results to %s\n", json_filename.c_str());
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int me = 0;
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MPI_Comm_rank(MPI_COMM_WORLD, &me);
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if (me == 0)
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{
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std::ofstream json_file(json_filename);
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json_file << std::setw(2) << json_results;
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}
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}
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endQuda();
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quda::comm_finalize();
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MPI_Finalize();
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