#include "pls/pls.h" using namespace pls; #include "benchmark_runner.h" #include "benchmark_base/matrix.h" #include using namespace comparison_benchmarks::base; template class pls_matrix : public matrix::matrix { public: explicit pls_matrix(size_t size) : matrix::matrix(size) {} void multiply(const matrix::matrix &a, const matrix::matrix &b) override { pls::algorithm::for_each_range(0, this->size_, [&](int i) { this->multiply_column(i, a, b); }); } }; constexpr int MAX_NUM_TASKS = 10; constexpr int MAX_STACK_SIZE = 4096 * 1; int main(int argc, char **argv) { auto settings = benchmark_runner::parse_parameters(argc, argv); pls_matrix a{settings.size_}; pls_matrix b{settings.size_}; pls_matrix result{settings.size_}; string test_name = to_string(settings.num_threads_) + ".csv"; string full_directory = settings.output_directory_ + "/PLS_v3/"; benchmark_runner runner{full_directory, test_name}; pls::scheduler scheduler{(unsigned) settings.num_threads_, MAX_NUM_TASKS, MAX_STACK_SIZE}; if (settings.type_ == benchmark_runner::benchmark_settings::ISOLATED) { #if PLS_PROFILING_ENABLED scheduler.get_profiler().disable_memory_measure(); runner.add_custom_stats_field("T_1"); runner.add_custom_stats_field("T_inf"); #endif printf("Running isolated measurement...\n"); runner.enable_memory_stats(); runner.pre_allocate_stats(); runner.run_iterations(settings.iterations_, [&]() { scheduler.perform_work([&]() { result.multiply(a, b); }); }, [&]() {}, [&]() { #if PLS_PROFILING_ENABLED runner.store_custom_stat("T_1", scheduler.get_profiler().current_run().t_1_); runner.store_custom_stat("T_inf", scheduler.get_profiler().current_run().t_inf_); #endif }); runner.commit_results(true); } else { printf("Running periodic measurement...\n"); runner.enable_wall_time_stats(); runner.pre_allocate_stats(); runner.run_periodic(settings.iterations_, settings.interval_period_, settings.interval_deadline_, [&]() { scheduler.perform_work([&]() { result.multiply(a, b); }); }); runner.commit_results(true); } }