#include "pls/internal/scheduling/scheduler.h" #include "pls/internal/scheduling/parallel_result.h" #include "pls/internal/scheduling/scheduler_memory.h" #include "pls/internal/helpers/profiler.h" using namespace pls::internal::scheduling; #include #include #include #include "benchmark_runner.h" #include "benchmark_base/fib.h" using namespace comparison_benchmarks::base; parallel_result pls_fib(int n) { if (n <= 1) { return parallel_result{1}; } return scheduler::par([=]() { return pls_fib(n - 1); }, [=]() { return pls_fib(n - 2); }).then([=](int a, int b) { return parallel_result{a + b}; }); } constexpr int MAX_NUM_THREADS = 8; constexpr int MAX_NUM_TASKS = 64; constexpr int MAX_NUM_CONTS = 64; constexpr int MAX_CONT_SIZE = 256; int main(int argc, char **argv) { int num_threads; string directory; benchmark_runner::read_args(argc, argv, num_threads, directory); string test_name = to_string(num_threads) + ".csv"; string full_directory = directory + "/PLS_v2/"; benchmark_runner runner{full_directory, test_name}; static_scheduler_memory static_scheduler_memory; scheduler scheduler{static_scheduler_memory, (unsigned int) num_threads}; volatile int res; for (int i = 0; i < fib::NUM_WARMUP_ITERATIONS; i++) { scheduler.perform_work([&]() { return scheduler::par([&]() { return pls_fib(fib::INPUT_N); }, []() { return parallel_result{0}; }).then([&](int result, int) { res = result; return parallel_result{0}; }); }); } for (int i = 0; i < fib::NUM_ITERATIONS; i++) { scheduler.perform_work([&]() { runner.start_iteration(); return scheduler::par([&]() { return pls_fib(fib::INPUT_N); }, []() { return parallel_result{0}; }).then([&](int result, int) { res = result; runner.end_iteration(); return parallel_result{0}; }); }); } runner.commit_results(true); return 0; }