cutlass/test/unit/gemm/warp/wmma_sm72.cu

/***************************************************************************************************
 * Copyright (c) 2017-2021, NVIDIA CORPORATION.  All rights reserved.
 *
 * Redistribution and use in source and binary forms, with or without modification, are permitted
 * provided that the following conditions are met:
 *     * Redistributions of source code must retain the above copyright notice, this list of
 *       conditions and the following disclaimer.
 *     * Redistributions in binary form must reproduce the above copyright notice, this list of
 *       conditions and the following disclaimer in the documentation and/or other materials
 *       provided with the distribution.
 *     * Neither the name of the NVIDIA CORPORATION nor the names of its contributors may be used
 *       to endorse or promote products derived from this software without specific prior written
 *       permission.
 *
 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR
 * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND
 * FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL NVIDIA CORPORATION 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 Unit tests for thread-level GEMM
*/
#include "cutlass/arch/wmma.h"

#if defined(CUTLASS_ARCH_WMMA_SM72_ENABLED)

#include "../../common/cutlass_unit_test.h"

#include "cutlass/aligned_buffer.h"
#include "cutlass/half.h"

#include "cutlass/gemm/warp/default_mma_wmma_tensor_op.h"

#include "cutlass/core_io.h"
#include "cutlass/util/host_tensor.h"
#include "cutlass/util/tensor_view_io.h"

#include "cutlass/util/reference/host/tensor_fill.h"
#include "cutlass/util/reference/host/tensor_compare.h"
#include "cutlass/util/reference/host/gemm.h"

#include "testbed.h"

///////////////////////////////////////////////////////////////////////////////////////////////////////////////
///////////////////////////////////////////// Integer wmma.mma ////////////////////////////////////////////////
///////////////////////////////////////////////////////////////////////////////////////////////////////////////
// TODO: FIXME SM75 should SM72, but the compilation breaks as SM72 shows up and runs on VOLTA
TEST(SM75_warp_wmma_row_col_s8, 16x16x16_16x16x16_16x16x16) {
  // Threadblock and warp with just one native WMMA operation (most basic unit test)
  using WarpShape = cutlass::gemm::GemmShape<16, 16, 16>;
  using InstructionShape = cutlass::gemm::GemmShape<16, 16, 16>;
  using ElementA = int8_t;
  using ElementB = int8_t;
  using ElementC = int32_t;
  using LayoutA = cutlass::layout::RowMajor;
  using LayoutB = cutlass::layout::ColumnMajor;
  using LayoutC = cutlass::layout::RowMajor;

  using WmmaTensorOp = typename cutlass::gemm::warp::DefaultMmaTensorOpWmma<
    WarpShape, 
    InstructionShape, 
    ElementA, LayoutA, 
    ElementB, LayoutB, 
    ElementC, LayoutC>::Type;

  test::gemm::warp::Testbed<WmmaTensorOp, cutlass::gemm::GemmShape<16, 16, 16> >().run();
}

TEST(SM75_warp_wmma_row_col_s8, 32x8x16_32x8x16_32x8x16) {
  // Threadblock and warp with just one native WMMA operation (most basic unit test)
  using WarpShape = cutlass::gemm::GemmShape<32, 8, 16>;
  using InstructionShape = cutlass::gemm::GemmShape<32, 8, 16>;
  using ElementA = int8_t;
  using ElementB = int8_t;
  using ElementC = int32_t;
  using LayoutA = cutlass::layout::RowMajor;
  using LayoutB = cutlass::layout::ColumnMajor;
  using LayoutC = cutlass::layout::RowMajor;

  using WmmaTensorOp = typename cutlass::gemm::warp::DefaultMmaTensorOpWmma<
    WarpShape, 
    InstructionShape, 
    ElementA, LayoutA, 
    ElementB, LayoutB, 
    ElementC, LayoutC>::Type;

  test::gemm::warp::Testbed<WmmaTensorOp, cutlass::gemm::GemmShape<32, 8, 16> >().run();
}

TEST(SM75_warp_wmma_row_col_s8, 8x32x16_8x32x16_8x32x16) {
  // Threadblock and warp with just one native WMMA operation (most basic unit test)
  using WarpShape = cutlass::gemm::GemmShape<8, 32, 16>;
  using InstructionShape = cutlass::gemm::GemmShape<8, 32, 16>;
  using ElementA = int8_t;
  using ElementB = int8_t;
  using ElementC = int32_t;
  using LayoutA = cutlass::layout::RowMajor;
  using LayoutB = cutlass::layout::ColumnMajor;
  using LayoutC = cutlass::layout::RowMajor;

  using WmmaTensorOp = typename cutlass::gemm::warp::DefaultMmaTensorOpWmma<
    WarpShape, 
    InstructionShape, 
    ElementA, LayoutA, 
    ElementB, LayoutB, 
    ElementC, LayoutC>::Type;

  test::gemm::warp::Testbed<WmmaTensorOp, cutlass::gemm::GemmShape<8, 32, 16> >().run();
}

TEST(SM75_warp_wmma_row_col_u8, 16x16x16_16x16x16_16x16x16) {
  // Threadblock and warp with just one native WMMA operation (most basic unit test)
  using WarpShape = cutlass::gemm::GemmShape<16, 16, 16>;
  using InstructionShape = cutlass::gemm::GemmShape<16, 16, 16>;
  using ElementA = uint8_t;
  using ElementB = uint8_t;
  using ElementC = int32_t;
  using LayoutA = cutlass::layout::RowMajor;
  using LayoutB = cutlass::layout::ColumnMajor;
  using LayoutC = cutlass::layout::RowMajor;

  using WmmaTensorOp = typename cutlass::gemm::warp::DefaultMmaTensorOpWmma<
    WarpShape, 
    InstructionShape, 
    ElementA, LayoutA, 
    ElementB, LayoutB, 
    ElementC, LayoutC>::Type;

  test::gemm::warp::Testbed<WmmaTensorOp, cutlass::gemm::GemmShape<16, 16, 16> >().run();
}

TEST(SM75_warp_wmma_row_col_u8, 32x8x16_32x8x16_32x8x16) {
  // Threadblock and warp with just one native WMMA operation (most basic unit test)
  using WarpShape = cutlass::gemm::GemmShape<32, 8, 16>;
  using InstructionShape = cutlass::gemm::GemmShape<32, 8, 16>;
  using ElementA = uint8_t;
  using ElementB = uint8_t;
  using ElementC = int32_t;
  using LayoutA = cutlass::layout::RowMajor;
  using LayoutB = cutlass::layout::ColumnMajor;
  using LayoutC = cutlass::layout::RowMajor;

  using WmmaTensorOp = typename cutlass::gemm::warp::DefaultMmaTensorOpWmma<
    WarpShape, 
    InstructionShape, 
    ElementA, LayoutA, 
    ElementB, LayoutB, 
    ElementC, LayoutC>::Type;

  test::gemm::warp::Testbed<WmmaTensorOp, cutlass::gemm::GemmShape<32, 8, 16> >().run();
}

TEST(SM75_warp_wmma_row_col_u8, 8x32x16_8x32x16_8x32x16) {
  // Threadblock and warp with just one native WMMA operation (most basic unit test)
  using WarpShape = cutlass::gemm::GemmShape<8, 32, 16>;
  using InstructionShape = cutlass::gemm::GemmShape<8, 32, 16>;
  using ElementA = uint8_t;
  using ElementB = uint8_t;
  using ElementC = int32_t;
  using LayoutA = cutlass::layout::RowMajor;
  using LayoutB = cutlass::layout::ColumnMajor;
  using LayoutC = cutlass::layout::RowMajor;

  using WmmaTensorOp = typename cutlass::gemm::warp::DefaultMmaTensorOpWmma<
    WarpShape, 
    InstructionShape, 
    ElementA, LayoutA, 
    ElementB, LayoutB, 
    ElementC, LayoutC>::Type;

  test::gemm::warp::Testbed<WmmaTensorOp, cutlass::gemm::GemmShape<8, 32, 16> >().run();
}
#endif //CUTLASS_ARCH_WMMA_SM72_ENABLED
CUTLASS 2.0 (#62) CUTLASS 2.0 Substantially refactored for - Better performance, particularly for native Turing Tensor Cores - Robust and durable templates spanning the design space - Encapsulated functionality embodying modern C++11 programming techniques - Optimized containers and data types for efficient, generic, portable device code Updates to: - Quick start guide - Documentation - Utilities - CUTLASS Profiler Native Turing Tensor Cores - Efficient GEMM kernels targeting Turing Tensor Cores - Mixed-precision floating point, 8-bit integer, 4-bit integer, and binarized operands Coverage of existing CUTLASS functionality: - GEMM kernels targeting CUDA and Tensor Cores in NVIDIA GPUs - Volta Tensor Cores through native mma.sync and through WMMA API - Optimizations such as parallel reductions, threadblock rasterization, and intra-threadblock reductions - Batched GEMM operations - Complex-valued GEMMs Note: this commit and all that follow require a host compiler supporting C++11 or greater. 2019-11-20 08:55:34 +08:00			`/***************************************************************************************************`
CUTLASS 2.5 2021-02-26 22:58:26 +08:00			`* Copyright (c) 2017-2021, NVIDIA CORPORATION. All rights reserved.`
CUTLASS 2.0 (#62) CUTLASS 2.0 Substantially refactored for - Better performance, particularly for native Turing Tensor Cores - Robust and durable templates spanning the design space - Encapsulated functionality embodying modern C++11 programming techniques - Optimized containers and data types for efficient, generic, portable device code Updates to: - Quick start guide - Documentation - Utilities - CUTLASS Profiler Native Turing Tensor Cores - Efficient GEMM kernels targeting Turing Tensor Cores - Mixed-precision floating point, 8-bit integer, 4-bit integer, and binarized operands Coverage of existing CUTLASS functionality: - GEMM kernels targeting CUDA and Tensor Cores in NVIDIA GPUs - Volta Tensor Cores through native mma.sync and through WMMA API - Optimizations such as parallel reductions, threadblock rasterization, and intra-threadblock reductions - Batched GEMM operations - Complex-valued GEMMs Note: this commit and all that follow require a host compiler supporting C++11 or greater. 2019-11-20 08:55:34 +08:00			`*`
			`* Redistribution and use in source and binary forms, with or without modification, are permitted`
			`* provided that the following conditions are met:`
			`* * Redistributions of source code must retain the above copyright notice, this list of`
			`* conditions and the following disclaimer.`
			`* * Redistributions in binary form must reproduce the above copyright notice, this list of`
			`* conditions and the following disclaimer in the documentation and/or other materials`
			`* provided with the distribution.`
			`* * Neither the name of the NVIDIA CORPORATION nor the names of its contributors may be used`
			`* to endorse or promote products derived from this software without specific prior written`
			`* permission.`
			`*`
			`* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR`
			`* IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND`
			`* FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL NVIDIA CORPORATION 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,`
Cutlass 2.6 Update 1 (#301) * cutlass 2.6 update * remove debug prints 2021-07-28 08:58:30 +08:00			`* STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE`
CUTLASS 2.0 (#62) CUTLASS 2.0 Substantially refactored for - Better performance, particularly for native Turing Tensor Cores - Robust and durable templates spanning the design space - Encapsulated functionality embodying modern C++11 programming techniques - Optimized containers and data types for efficient, generic, portable device code Updates to: - Quick start guide - Documentation - Utilities - CUTLASS Profiler Native Turing Tensor Cores - Efficient GEMM kernels targeting Turing Tensor Cores - Mixed-precision floating point, 8-bit integer, 4-bit integer, and binarized operands Coverage of existing CUTLASS functionality: - GEMM kernels targeting CUDA and Tensor Cores in NVIDIA GPUs - Volta Tensor Cores through native mma.sync and through WMMA API - Optimizations such as parallel reductions, threadblock rasterization, and intra-threadblock reductions - Batched GEMM operations - Complex-valued GEMMs Note: this commit and all that follow require a host compiler supporting C++11 or greater. 2019-11-20 08:55:34 +08:00			`* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.`
			`*`
			`**************************************************************************************************/`
			`/*! \file`

			`\brief Unit tests for thread-level GEMM`
			`*/`
			`#include "cutlass/arch/wmma.h"`

			`#if defined(CUTLASS_ARCH_WMMA_SM72_ENABLED)`

			`#include "../../common/cutlass_unit_test.h"`

			`#include "cutlass/aligned_buffer.h"`
			`#include "cutlass/half.h"`

			`#include "cutlass/gemm/warp/default_mma_wmma_tensor_op.h"`

			`#include "cutlass/core_io.h"`
			`#include "cutlass/util/host_tensor.h"`
			`#include "cutlass/util/tensor_view_io.h"`

			`#include "cutlass/util/reference/host/tensor_fill.h"`
			`#include "cutlass/util/reference/host/tensor_compare.h"`
			`#include "cutlass/util/reference/host/gemm.h"`

			`#include "testbed.h"`

			`///////////////////////////////////////////////////////////////////////////////////////////////////////////////`
			`///////////////////////////////////////////// Integer wmma.mma ////////////////////////////////////////////////`
			`///////////////////////////////////////////////////////////////////////////////////////////////////////////////`
			`// TODO: FIXME SM75 should SM72, but the compilation breaks as SM72 shows up and runs on VOLTA`
			`TEST(SM75_warp_wmma_row_col_s8, 16x16x16_16x16x16_16x16x16) {`
			`// Threadblock and warp with just one native WMMA operation (most basic unit test)`
			`using WarpShape = cutlass::gemm::GemmShape<16, 16, 16>;`
			`using InstructionShape = cutlass::gemm::GemmShape<16, 16, 16>;`
			`using ElementA = int8_t;`
			`using ElementB = int8_t;`
			`using ElementC = int32_t;`
			`using LayoutA = cutlass::layout::RowMajor;`
			`using LayoutB = cutlass::layout::ColumnMajor;`
			`using LayoutC = cutlass::layout::RowMajor;`

			`using WmmaTensorOp = typename cutlass::gemm::warp::DefaultMmaTensorOpWmma<`
			`WarpShape,`
			`InstructionShape,`
			`ElementA, LayoutA,`
			`ElementB, LayoutB,`
			`ElementC, LayoutC>::Type;`

			`test::gemm::warp::Testbed<WmmaTensorOp, cutlass::gemm::GemmShape<16, 16, 16> >().run();`
			`}`

			`TEST(SM75_warp_wmma_row_col_s8, 32x8x16_32x8x16_32x8x16) {`
			`// Threadblock and warp with just one native WMMA operation (most basic unit test)`
			`using WarpShape = cutlass::gemm::GemmShape<32, 8, 16>;`
			`using InstructionShape = cutlass::gemm::GemmShape<32, 8, 16>;`
			`using ElementA = int8_t;`
			`using ElementB = int8_t;`
			`using ElementC = int32_t;`
			`using LayoutA = cutlass::layout::RowMajor;`
			`using LayoutB = cutlass::layout::ColumnMajor;`
			`using LayoutC = cutlass::layout::RowMajor;`

			`using WmmaTensorOp = typename cutlass::gemm::warp::DefaultMmaTensorOpWmma<`
			`WarpShape,`
			`InstructionShape,`
			`ElementA, LayoutA,`
			`ElementB, LayoutB,`
			`ElementC, LayoutC>::Type;`

			`test::gemm::warp::Testbed<WmmaTensorOp, cutlass::gemm::GemmShape<32, 8, 16> >().run();`
			`}`

			`TEST(SM75_warp_wmma_row_col_s8, 8x32x16_8x32x16_8x32x16) {`
			`// Threadblock and warp with just one native WMMA operation (most basic unit test)`
			`using WarpShape = cutlass::gemm::GemmShape<8, 32, 16>;`
			`using InstructionShape = cutlass::gemm::GemmShape<8, 32, 16>;`
			`using ElementA = int8_t;`
			`using ElementB = int8_t;`
			`using ElementC = int32_t;`
			`using LayoutA = cutlass::layout::RowMajor;`
			`using LayoutB = cutlass::layout::ColumnMajor;`
			`using LayoutC = cutlass::layout::RowMajor;`

			`using WmmaTensorOp = typename cutlass::gemm::warp::DefaultMmaTensorOpWmma<`
			`WarpShape,`
			`InstructionShape,`
			`ElementA, LayoutA,`
			`ElementB, LayoutB,`
			`ElementC, LayoutC>::Type;`

			`test::gemm::warp::Testbed<WmmaTensorOp, cutlass::gemm::GemmShape<8, 32, 16> >().run();`
			`}`

			`TEST(SM75_warp_wmma_row_col_u8, 16x16x16_16x16x16_16x16x16) {`
			`// Threadblock and warp with just one native WMMA operation (most basic unit test)`
			`using WarpShape = cutlass::gemm::GemmShape<16, 16, 16>;`
			`using InstructionShape = cutlass::gemm::GemmShape<16, 16, 16>;`
			`using ElementA = uint8_t;`
			`using ElementB = uint8_t;`
			`using ElementC = int32_t;`
			`using LayoutA = cutlass::layout::RowMajor;`
			`using LayoutB = cutlass::layout::ColumnMajor;`
			`using LayoutC = cutlass::layout::RowMajor;`

			`using WmmaTensorOp = typename cutlass::gemm::warp::DefaultMmaTensorOpWmma<`
			`WarpShape,`
			`InstructionShape,`
			`ElementA, LayoutA,`
			`ElementB, LayoutB,`
			`ElementC, LayoutC>::Type;`

			`test::gemm::warp::Testbed<WmmaTensorOp, cutlass::gemm::GemmShape<16, 16, 16> >().run();`
			`}`

			`TEST(SM75_warp_wmma_row_col_u8, 32x8x16_32x8x16_32x8x16) {`
			`// Threadblock and warp with just one native WMMA operation (most basic unit test)`
			`using WarpShape = cutlass::gemm::GemmShape<32, 8, 16>;`
			`using InstructionShape = cutlass::gemm::GemmShape<32, 8, 16>;`
			`using ElementA = uint8_t;`
			`using ElementB = uint8_t;`
			`using ElementC = int32_t;`
			`using LayoutA = cutlass::layout::RowMajor;`
			`using LayoutB = cutlass::layout::ColumnMajor;`
			`using LayoutC = cutlass::layout::RowMajor;`

			`using WmmaTensorOp = typename cutlass::gemm::warp::DefaultMmaTensorOpWmma<`
			`WarpShape,`
			`InstructionShape,`
			`ElementA, LayoutA,`
			`ElementB, LayoutB,`
			`ElementC, LayoutC>::Type;`

			`test::gemm::warp::Testbed<WmmaTensorOp, cutlass::gemm::GemmShape<32, 8, 16> >().run();`
			`}`

			`TEST(SM75_warp_wmma_row_col_u8, 8x32x16_8x32x16_8x32x16) {`
			`// Threadblock and warp with just one native WMMA operation (most basic unit test)`
			`using WarpShape = cutlass::gemm::GemmShape<8, 32, 16>;`
			`using InstructionShape = cutlass::gemm::GemmShape<8, 32, 16>;`
			`using ElementA = uint8_t;`
			`using ElementB = uint8_t;`
			`using ElementC = int32_t;`
			`using LayoutA = cutlass::layout::RowMajor;`
			`using LayoutB = cutlass::layout::ColumnMajor;`
			`using LayoutC = cutlass::layout::RowMajor;`

			`using WmmaTensorOp = typename cutlass::gemm::warp::DefaultMmaTensorOpWmma<`
			`WarpShape,`
			`InstructionShape,`
			`ElementA, LayoutA,`
			`ElementB, LayoutB,`
			`ElementC, LayoutC>::Type;`

			`test::gemm::warp::Testbed<WmmaTensorOp, cutlass::gemm::GemmShape<8, 32, 16> >().run();`
			`}`
			`#endif //CUTLASS_ARCH_WMMA_SM72_ENABLED`