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IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR * SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER * CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. * **************************************************************************************************/ /*! \file \brief Tests for device-wide GEMM interface */ #pragma once #include #include #include #include "../../common/cutlass_unit_test.h" #include "cutlass/util/host_tensor.h" #include "cutlass/util/tensor_view_io.h" #include "cutlass/util/distribution.h" #include "cutlass/util/reference/host/tensor_fill.h" #include "cutlass/util/reference/host/tensor_copy.h" #include "cutlass/util/reference/host/tensor_compare.h" #include "cutlass/util/reference/host/tensor_norm.h" #include "cutlass/util/reference/host/gemm.h" #include "cutlass/util/reference/host/gemm_complex.h" #include "testbed_utils.h" namespace test { namespace gemm { namespace device { ///////////////////////////////////////////////////////////////////////////////////////////////// template struct TestbedUniversal { using ElementA = typename Gemm::ElementA; using ElementB = typename Gemm::ElementB; using ElementC = typename Gemm::ElementC; using ElementAccumulator = typename Gemm::ElementAccumulator; using ElementCompute = typename Gemm::GemmKernel::Epilogue::OutputOp::ElementCompute; /// Initialization cutlass::Distribution::Kind init_A; cutlass::Distribution::Kind init_B; cutlass::Distribution::Kind init_C; uint64_t seed; cutlass::HostTensor tensor_A; cutlass::HostTensor tensor_B; cutlass::HostTensor tensor_C; cutlass::HostTensor tensor_D; cutlass::HostTensor reference_D; // // Methods // TestbedUniversal( cutlass::Distribution::Kind init_A_ = cutlass::Distribution::Uniform, cutlass::Distribution::Kind init_B_ = cutlass::Distribution::Uniform, cutlass::Distribution::Kind init_C_ = cutlass::Distribution::Uniform, uint64_t seed_ = 2080 ): init_A(init_A_), init_B(init_B_), init_C(init_C_), seed(seed_) { } /// Helper to initialize a tensor view template bool initialize_tensor( cutlass::TensorView view, cutlass::Distribution::Kind dist_kind, uint64_t seed) { if (dist_kind == cutlass::Distribution::Uniform) { double scope_max, scope_min; int bits_input = cutlass::sizeof_bits::value; int bits_output = cutlass::sizeof_bits::value; bool is_unsigned_int = std::numeric_limits::is_integer && !std::numeric_limits::is_signed; if (bits_input == 1) { scope_max = 2; scope_min = 0; } else if (bits_input <= 8) { scope_max = is_unsigned_int ? 4 : 2; scope_min = is_unsigned_int ? 0 : -2; } else if (bits_output == 16) { scope_max = is_unsigned_int ? 10 : 5; scope_min = is_unsigned_int ? 0 : -5; } else { scope_max = 8; scope_min = -8; } cutlass::reference::host::TensorFillRandomUniform( view, seed, scope_max, scope_min, 0); } else if (dist_kind == cutlass::Distribution::Identity) { cutlass::reference::host::TensorFillIdentity(view); } else if (dist_kind == cutlass::Distribution::Gaussian) { cutlass::reference::host::TensorFillRandomGaussian(view, seed, 0, 0.5); } else if (dist_kind == cutlass::Distribution::Sequential) { cutlass::reference::host::BlockFillSequential( view.data(), view.capacity()); } else { EXPECT_TRUE(false) << "Not implemented"; return false; } return true; } /// Initializes data structures void initialize(cutlass::gemm::GemmCoord problem_size) { // // Allocate the GEMM workspace // tensor_A.resize(problem_size.mk()); tensor_B.resize(problem_size.kn()); tensor_C.resize(problem_size.mn()); tensor_D.resize(problem_size.mn()); reference_D.resize(problem_size.mn(), false); EXPECT_TRUE(initialize_tensor(tensor_A.host_view(), init_A, seed + 2019)); EXPECT_TRUE(initialize_tensor(tensor_B.host_view(), init_B, seed + 2018)); EXPECT_TRUE(initialize_tensor(tensor_C.host_view(), init_C, seed + 2017)); // It is possible to randomly initialize to all zeros, so override this with non-zeros // in the upper left corner of each operand. cutlass::Coord<2> origin(0); tensor_A.host_view().at(origin) = typename Gemm::ElementA(1); tensor_B.host_view().at(origin) = typename Gemm::ElementB(1); tensor_C.host_view().at(origin) = typename Gemm::ElementC(1); cutlass::reference::host::TensorCopy(reference_D.host_view(), tensor_C.host_view()); tensor_A.sync_device(); tensor_B.sync_device(); tensor_C.sync_device(); tensor_D.sync_device(); } /// Compares computed reference with device reference and outputs to a file if incorrect bool compare_reference( cutlass::gemm::GemmCoord problem_size, ElementCompute alpha, ElementCompute beta) { tensor_D.sync_host(); EXPECT_GT(cutlass::reference::host::TensorNorm(tensor_A.host_view()), 0); EXPECT_GT(cutlass::reference::host::TensorNorm(tensor_B.host_view()), 0); EXPECT_GT(cutlass::reference::host::TensorNorm(tensor_C.host_view()), 0); EXPECT_GT(cutlass::reference::host::TensorNorm(tensor_D.host_view()), 0); EXPECT_GT(cutlass::reference::host::TensorNorm(reference_D.host_view()), 0); bool passed = cutlass::reference::host::TensorEquals(reference_D.host_view(), tensor_D.host_view()); EXPECT_TRUE(passed) << " mismatched reference"; if (!passed) { /* std::stringstream fname; fname << "error_Gemm_device_" << problem_size.m() << "x" << problem_size.n() << "x" << problem_size.k() << "_" << Gemm::ThreadblockShape::kM << "x" << Gemm::ThreadblockShape::kN << "x" << Gemm::ThreadblockShape::kK << "_" << Gemm::WarpShape::kM << "x" << Gemm::WarpShape::kN << "x" << Gemm::WarpShape::kK << ".txt"; std::ofstream file(fname.str()); */ std::ofstream file("testbed_universal_errors.txt"); file << "problem: " << problem_size << ", alpha: " << alpha << ", beta: " << beta << "\n\n"; file << "A =\n" << tensor_A.host_view() << "\nB =\n" << tensor_B.host_view() << "\nC =\n" << tensor_C.host_view() << "\n\nReference =\n" << reference_D.host_view() << "\nComputed =\n" << tensor_D.host_view(); } return passed; } /// Verifies the result is a GEMM bool verify( cutlass::gemm::GemmCoord problem_size, ElementCompute alpha, ElementCompute beta) { // // Verify // cutlass::reference::host::GemmComplex< typename Gemm::ElementA, typename Gemm::LayoutA, typename Gemm::ElementB, typename Gemm::LayoutB, typename Gemm::ElementC, typename Gemm::LayoutC, ElementCompute, ElementAccumulator >( problem_size, alpha, tensor_A.host_ref(), Gemm::kTransformA, tensor_B.host_ref(), Gemm::kTransformB, beta, tensor_C.host_ref(), reference_D.host_ref(), ElementAccumulator(0) ); if (Relu) { for (int i = 0; i < problem_size.m(); ++i) { for (int j = 0; j < problem_size.n(); ++j) { reference_D.at(cutlass::MatrixCoord(i, j)) = ((ElementCompute)reference_D.at(cutlass::MatrixCoord(i, j)) < (ElementCompute)0) ? (typename Gemm::ElementC)0 : reference_D.at(cutlass::MatrixCoord(i, j)); } } } return compare_reference(problem_size, alpha, beta); } /// Returns true if the CUDA device is sufficient to execute the kernel. bool sufficient() const { // // Determine SMEM requirements and waive if not satisfied // int smem_size = int(sizeof(typename Gemm::GemmKernel::SharedStorage)); cudaDeviceProp properties; int device_idx; cudaError_t result = cudaGetDevice(&device_idx); if (result != cudaSuccess) { throw std::runtime_error("cudaGetDevice() API call failed."); } result = cudaGetDeviceProperties(&properties, device_idx); if (result != cudaSuccess) { throw std::runtime_error("cudaGetDeviceProperties() failed"); } if (properties.sharedMemPerBlockOptin < smem_size) { return false; } return true; } /// Executes one test bool run( cutlass::gemm::GemmUniversalMode mode, cutlass::gemm::GemmCoord problem_size, int batch_count = 1, ElementCompute alpha = ElementCompute(1), ElementCompute beta = ElementCompute(0)) { /* std::cout << "\n-----------------------\n"; std::cout << "mode: " << (int) mode << "\n"; std::cout << "problem size: " << problem_size << "\n"; std::cout << "batch_count: " << batch_count << "\n"; std::cout << "alpha: " << alpha << "\n"; std::cout << "beta: " << beta << "\n"; std::cout << "-----------------------\n\n"; */ // Waive test if insufficient CUDA device if (!sufficient()) { if (CUTLASS_TEST_UNIT_ENABLE_WARNINGS) { std::cerr << "Test waived due to insufficient CUDA device." << std::endl; } return true; } this->initialize(problem_size); // // Initialize the GEMM operator // typename Gemm::Arguments arguments{ mode, problem_size, batch_count, {alpha, beta}, tensor_A.device_data(), tensor_B.device_data(), tensor_C.device_data(), tensor_D.device_data(), problem_size.m() * problem_size.k(), problem_size.n() * problem_size.k(), problem_size.m() * problem_size.n(), problem_size.m() * problem_size.n(), tensor_A.layout().stride(0), tensor_B.layout().stride(0), tensor_C.layout().stride(0), tensor_D.layout().stride(0) }; Gemm gemm_op; size_t workspace_size = Gemm::get_workspace_size(arguments); cutlass::device_memory::allocation workspace(workspace_size); cutlass::Status status = gemm_op.initialize(arguments, workspace.get()); EXPECT_TRUE(status == cutlass::Status::kSuccess) << to_string(status); // // Run the GEMM // status = gemm_op(); EXPECT_TRUE(status == cutlass::Status::kSuccess) << to_string(status); // // Verify // bool passed = this->verify(problem_size, alpha, beta); if (!passed) { std::cout << "Failed with batch_count/split_k_slices = " << batch_count << std::endl; } return passed; } }; ///////////////////////////////////////////////////////////////////////////////////////////////// template bool TestGemmUniversal( cutlass::gemm::GemmCoord const & problem_size, cutlass::gemm::GemmUniversalMode mode, int batch_count, double alpha = 1.0, double beta = 2.0) { bool passed = true; TestbedUniversal testbed; using ElementCompute = typename Gemm::EpilogueOutputOp::ElementCompute; passed = testbed.run( mode, problem_size, batch_count, cutlass::from_real(alpha), cutlass::from_real(beta) ); return passed; } template bool TestAllGemmUniversal() { bool passed = true; int const kMinimumOperandElementSize = std::min( int(cutlass::sizeof_bits::value), int(cutlass::sizeof_bits::value)); int const kAlignment = cutlass::platform::is_same< typename Gemm::OperatorClass, cutlass::arch::OpClassSimt>::value ? 1 : 128 / kMinimumOperandElementSize; // int8_t gemm alignment constraints int const kAlignmentM = cutlass::platform::is_same::value && cutlass::platform::is_same::value && cutlass::platform::is_same::value ? 4 : kAlignment; int const kAlignmentN = cutlass::platform::is_same::value && cutlass::platform::is_same::value && cutlass::platform::is_same::value ? 4 : kAlignment; int const kAlignmentK = cutlass::platform::is_same::value && cutlass::platform::is_same::value && cutlass::platform::is_same::value && (cutlass::platform::is_same::value || cutlass::platform::is_same::value) ? 4 : kAlignment; cutlass::gemm::GemmUniversalMode modes[] = { cutlass::gemm::GemmUniversalMode::kGemm, }; int problem_size_m[] = { kAlignmentM, 512 - 3*kAlignmentM }; int problem_size_n[] = { kAlignmentN, 512 - 2*kAlignmentN }; int problem_size_k[] = { kAlignmentK, Gemm::ThreadblockShape::kK * Gemm::kStages - kAlignmentK, Gemm::ThreadblockShape::kK * Gemm::kStages * 3 - kAlignmentK }; int batch_counts[] = { // may be interpretted as batch count or split-K slices 1, 2, 3, 5, 7 }; double problem_alpha[] = { 1 }; double problem_beta[] = { 2.0 }; using ElementCompute = typename Gemm::EpilogueOutputOp::ElementCompute; for (cutlass::gemm::GemmUniversalMode mode : modes) { for (int m : problem_size_m) { for (int n : problem_size_n) { for (int k : problem_size_k) { for (int batch_count : batch_counts) { for (auto alpha : problem_alpha) { for (auto beta : problem_beta) { if (mode == cutlass::gemm::GemmUniversalMode::kGemm || mode == cutlass::gemm::GemmUniversalMode::kGemmSplitKParallel) { // skip very small K problems if (k / batch_count < 2 * Gemm::ThreadblockShape::kK) { continue; } } cutlass::gemm::GemmCoord problem_size(m, n, k); TestbedUniversal testbed; passed = testbed.run( mode, problem_size, batch_count, cutlass::from_real(alpha), cutlass::from_real(beta) ); if (!passed) { return false; } } } } } } } } /* // large problem with high coverage for (int split_k_slices = 1; split_k_slices <= 3; ++split_k_slices) { TestbedUniversal testbed; cutlass::gemm::GemmCoord problem_size(72, 56, 8192); passed = testbed.run( cutlass::gemm::GemmUniversalMode::kGemm, problem_size, split_k_slices, cutlass::from_real(1.0), cutlass::from_real(2.0) ); if (!passed) { break; } } */ return passed; } ///////////////////////////////////////////////////////////////////////////////////////////////// } // namespace device } // namespace gemm } // namespace test /////////////////////////////////////////////////////////////////////////////////////////////////