/* * Copyright (c) Meta Platforms, Inc. and affiliates. * All rights reserved. * This source code is licensed under the BSD-style license found in the * LICENSE file in the root directory of this source tree. */ #include <algorithm> #include <chrono> #include <cmath> #include <iomanip> #include <iostream> #include <vector> #ifdef _OPENMP #include <omp.h> #endif #ifdef USE_MKL #include <mkl.h> #endif #include "./BenchUtils.h" #include "fbgemm/Fbgemm.h" #include "src/RefImplementations.h" #include "test/QuantizationHelpers.h" using namespace std; using namespace fbgemm; void performance_test() { // clang-format off static const vector<vector<int>> shapes = { // NOTE: clang-format wants to use a different formatting but the current // formatting should be easier to read. // m, n, k {64, 800, 320}, {64, 768, 512}, {16, 256, 512}, {128, 128, 128}, {256, 512, 256}, {1024, 1024, 1024}, }; // clang-format on bool flush = true; std::vector<char> llc; if (flush) { llc.resize(128 * 1024 * 1024, 1.0); } constexpr int NWARMUP = 4; constexpr int NITER = 10; #ifdef FBGEMM_MEASURE_TIME_BREAKDOWN cout << "WARNING: the timer may be inaccurate when used by multiple threads." << endl; cout << setw(8) << "M, " << setw(8) << "N, " << setw(8) << "K, " << setw(18) << "Type, " << setw(18) << "Packing (us), " << setw(18) << "Kernel (us), " << setw(18) << "Postproc (us), " << setw(18) << "Total (us), " << setw(5) << "GOPs" << endl; #else cout << setw(8) << "M, " << setw(8) << "N, " << setw(8) << "K, " << setw(18) << "Type, " << setw(5) << "GOPS" << endl; #endif chrono::time_point<chrono::high_resolution_clock> start, end; for (const auto& shape : shapes) { int m = shape[0]; int n = shape[1]; int k = shape[2]; aligned_vector<uint8_t> Aint8(m * k); aligned_vector<int8_t> Bint8(k * n); aligned_vector<float> Cfp32_mkl(m * n); aligned_vector<int32_t> Cint32_mkl(Cfp32_mkl.size()); aligned_vector<int32_t> Cint32_ref(Cfp32_mkl.size()); aligned_vector<int32_t> Cint32_fb_acc32(Cfp32_mkl.size()); aligned_vector<int32_t> Cint32_fb_acc16(Cfp32_mkl.size()); // A matrix randFill<uint8_t>(Aint8, 0, 5); aligned_vector<float> Afp32(Aint8.begin(), Aint8.end()); randFill<int8_t>(Bint8, -4, 4); avoidOverflow(m, n, k, Aint8.data(), Bint8.data()); aligned_vector<float> Bfp32(Bint8.begin(), Bint8.end()); double nops = 2.0 * m * n * k; double ttot = 0.0; string runType; #ifdef USE_MKL const float alpha = 1.f; const float beta = 0.f; runType = "MKL_fp32"; ttot = measureWithWarmup( [&]() { cblas_sgemm( CblasRowMajor, CblasNoTrans, CblasNoTrans, m, n, k, alpha, Afp32.data(), k, Bfp32.data(), n, beta, Cfp32_mkl.data(), n); }, NWARMUP, NITER, [&]() { if (flush) { llc_flush(llc); } }); ttot *= 1e9; // convert to ns ((volatile char*)(llc.data())); cout << setw(6) << m << ", " << setw(6) << n << ", " << setw(6) << k << ", " << setw(16) << runType << ", " #ifdef FBGEMM_MEASURE_TIME_BREAKDOWN << setw(16) << 0 << ", " << setw(16) << 0 << ", " << setw(16) << 0 << ", " << setw(16) << ttot / 1e3 << ", " #endif << setw(5) << fixed << setw(5) << setprecision(1) << nops / ttot << endl; for (size_t i = 0; i < Cfp32_mkl.size(); ++i) { Cint32_mkl[i] = (int32_t)Cfp32_mkl[i]; } #endif vector<int32_t> row_offsets(m); matmul_u8i8acc32_ref( m, n, k, k, n, n, Aint8.data(), Bint8.data(), Cint32_ref.data()); // printMatrix(matrix_op_t::NoTranspose, Bint8.data(), k, n, n, "B // unpacked"); // printMatrix(matrix_op_t::NoTranspose, Aint8.data(), m, k, k, // "A unpacked"); // printMatrix(matrix_op_t::NoTranspose, Cint32_ref.data(), // m, n, n, "C int32"); PackBMatrix<int8_t> packedB_int32( matrix_op_t::NoTranspose, k, n, Bint8.data(), n, nullptr, 1); ttot = 0.0; runType = "FBGEMM_i8_acc32"; #ifdef FBGEMM_MEASURE_TIME_BREAKDOWN double total_packing_time = 0.0; double total_computing_time = 0.0; double total_kernel_time = 0.0; double total_postprocessing_time = 0.0; double total_run_time = 0.0; #endif cout << setw(6) << m << ", " << setw(6) << n << ", " << setw(6) << k << ", " << setw(16) << runType; for (auto i = 0; i < NWARMUP + NITER; ++i) { #ifdef FBGEMM_MEASURE_TIME_BREAKDOWN packing_time = 0.0; computing_time = 0.0; kernel_time = 0.0; postprocessing_time = 0.0; run_time = 0.0; #endif llc_flush(llc); start = chrono::high_resolution_clock::now(); #ifdef _OPENMP #pragma omp parallel #endif { PackAMatrix<uint8_t> packA_int32( matrix_op_t::NoTranspose, m, k, Aint8.data(), k, nullptr, 1); DoNothing<int32_t, int32_t> doNothing32BitObj; memCopy<> memcopyObj(doNothing32BitObj); int num_threads = fbgemm_get_num_threads(); int tid = fbgemm_get_thread_num(); // printf ( "tid: %d, num_threads: %d\n", tid, num_threads ); fbgemmPacked( packA_int32, packedB_int32, Cint32_fb_acc32.data(), Cint32_fb_acc32.data(), n, memcopyObj, tid, num_threads); } end = chrono::high_resolution_clock::now(); if (i >= NWARMUP) { auto dur = chrono::duration_cast<chrono::nanoseconds>(end - start); ttot += dur.count(); #ifdef FBGEMM_MEASURE_TIME_BREAKDOWN total_packing_time += packing_time; total_computing_time += computing_time; total_kernel_time += kernel_time; total_postprocessing_time += postprocessing_time; total_run_time += run_time; #endif } } if (flush) { ((volatile char*)(llc.data()))[0] += 1; } // printMatrix(matrix_op_t::NoTranspose, Bint8.data(), k, n, n, "B // unpacked"); // printMatrix(matrix_op_t::NoTranspose, Aint8.data(), m, k, k, // "A unpacked"); // printMatrix(matrix_op_t::NoTranspose, // Cint8_fb.data(), m, n, n, "C fb"); #ifdef FBGEMM_MEASURE_TIME_BREAKDOWN cout << ", " << setw(16) << total_packing_time / (double)NITER / 1e3 << ", " << setw(16) << total_kernel_time / (double)NITER / 1e3 << ", " << setw(16) << total_postprocessing_time / (double)NITER / 1e3 << ", " << setw(16) << total_run_time / (double)NITER / 1e3; #endif cout << ", " << setw(5) << fixed << setw(5) << setprecision(1) << NITER * nops / ttot << endl; compare_buffers(Cint32_ref.data(), Cint32_fb_acc32.data(), m, n, n, 5); PackBMatrix<int8_t, int16_t> packedB_int16( matrix_op_t::NoTranspose, k, n, Bint8.data(), n, nullptr, 1); ttot = 0.0; runType = "FBGEMM_i8_acc16"; #ifdef FBGEMM_MEASURE_TIME_BREAKDOWN total_packing_time = 0.0; total_computing_time = 0.0; total_kernel_time = 0.0; total_postprocessing_time = 0.0; total_run_time = 0.0; #endif cout << setw(6) << m << ", " << setw(6) << n << ", " << setw(6) << k << ", " << setw(16) << runType; for (auto i = 0; i < NWARMUP + NITER; ++i) { #ifdef FBGEMM_MEASURE_TIME_BREAKDOWN packing_time = 0.0; computing_time = 0.0; kernel_time = 0.0; postprocessing_time = 0.0; run_time = 0.0; #endif llc_flush(llc); start = chrono::high_resolution_clock::now(); #ifdef _OPENMP #pragma omp parallel #endif { PackAMatrix<uint8_t, int16_t> packA_int16( matrix_op_t::NoTranspose, m, k, Aint8.data(), k, nullptr, 1); DoNothing<int32_t, int32_t> doNothing32BitObj; memCopy<> memcopyObj(doNothing32BitObj); int num_threads = fbgemm_get_num_threads(); int tid = fbgemm_get_thread_num(); // printf ( "tid: %d, num_threads: %d\n", tid, num_threads ); fbgemmPacked( packA_int16, packedB_int16, Cint32_fb_acc16.data(), Cint32_fb_acc16.data(), n, memcopyObj, tid, num_threads); } end = chrono::high_resolution_clock::now(); if (i >= NWARMUP) { auto dur = chrono::duration_cast<chrono::nanoseconds>(end - start); ttot += dur.count(); #ifdef FBGEMM_MEASURE_TIME_BREAKDOWN total_packing_time += packing_time; total_computing_time += computing_time; total_kernel_time += kernel_time; total_postprocessing_time += postprocessing_time; total_run_time += run_time; #endif } } if (flush) { ((volatile char*)(llc.data()))[0] += 1; } // printMatrix(matrix_op_t::NoTranspose, Bint8.data(), k, n, n, "B // unpacked"); // printMatrix(matrix_op_t::NoTranspose, Aint8.data(), m, k, k, // "A unpacked"); // printMatrix(matrix_op_t::NoTranspose, // Cint8_fb.data(), m, n, n, "C fb"); // compare_buffers(row_offsets.data(), row_offset_buf.data(), // row_offsets.size(), 5); #ifdef FBGEMM_MEASURE_TIME_BREAKDOWN cout << ", " << setw(16) << total_packing_time / (double)NITER / 1e3 << ", " << setw(16) << total_kernel_time / (double)NITER / 1e3 << ", " << setw(16) << total_postprocessing_time / (double)NITER / 1e3 << ", " << setw(16) << total_run_time / (double)NITER / 1e3; #endif cout << ", " << setw(5) << fixed << setw(5) << setprecision(1) << NITER * nops / ttot << endl; cout << endl; compare_buffers(Cint32_ref.data(), Cint32_fb_acc16.data(), m, n, n, 5); } } int main(int /* unused */, char** /* unused */) { #ifdef _OPENMP // Use 1 thread unless OMP_NUM_THREADS is explicit set. const char* val = getenv("OMP_NUM_THREADS"); if (val == nullptr || !*val) { omp_set_num_threads(1); } #endif performance_test(); return 0; }