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cutlass/test/unit/gemm/threadblock/mma_pipelined_wmma_sm70.cu

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/***************************************************************************************************
* Copyright (c) 2017 - 2024 NVIDIA CORPORATION & AFFILIATES. All rights reserved.
* SPDX-License-Identifier: BSD-3-Clause
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. 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.
*
* 3. Neither the name of the copyright holder 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 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 Unit tests for thread-level GEMM
*/
#include "cutlass/arch/wmma.h"
#ifdef CUTLASS_ARCH_WMMA_SM70_ENABLED
#include "mma_pipelined_testbed.h"
#include "cutlass/gemm/threadblock/default_mma_core_wmma.h"
/// All tests use double-buffered (kStages=2) mma pipeline for the gemm mainloop
/// Test name format: SM[arch]_gemm_threadblock_wmma_tensor_op_[alayout]_[blayout]_[clayout]_[dtype].[threadblock_shape]_[warp_shape]
//////////////// [START] Verifying all layouts {N,T}x{N,T}=>{N,T} for WMMA 16x16x16 [START] //////////////////////
///////////////////////////////////////////////////////////
/// wmma.mma.sync.aligned.alayout.blayout.shape.dtype.ctype
/// wmma.mma.sync.aligned.row.col.m16n16k16.f16.f16 (wmma native size 16x16x16)
////////////////////////////////////////////////////////////
// tests for {N,T}x{N,T}=>{T}
TEST(SM70_gemm_threadblock_wmma_tensor_op_row_col_row_f16, 64x64x32_64x64x32_16x16x16) {
using ElementA = cutlass::half_t;
using LayoutA = cutlass::layout::RowMajor;
using ElementB = cutlass::half_t;
using LayoutB = cutlass::layout::ColumnMajor;
using ElementC = cutlass::half_t;
using LayoutC = cutlass::layout::RowMajor;
static const int kStages = 2;
cutlass::gemm::GemmCoord problem_size(64, 64, 32);
using ThreadblockShape = cutlass::gemm::GemmShape<64, 64, 32>;
using WarpShape = cutlass::gemm::GemmShape<64, 64, 32>;
using InstructionShape = cutlass::gemm::GemmShape<16, 16, 16>;
float alpha = 1.f;
float beta = 0.0f;
// Define the MmaCore components
using MmaCore = typename cutlass::gemm::threadblock::DefaultMmaCore<
ThreadblockShape, WarpShape, InstructionShape, ElementA, LayoutA,
ElementB, LayoutB, ElementC, LayoutC,
cutlass::arch::OpClassWmmaTensorOp, kStages>;
dim3 grid(1, 1);
dim3 block(32, 1, 1);
test::gemm::threadblock::Testbed<MmaCore, kStages>(problem_size.m(), problem_size.n(),
problem_size.k(), alpha, beta)
.run(grid, block);
}
///////////////////////////////////////////////////////////////////////////////
/// wmma.mma.sync.aligned.alayout.blayout.shape.dtype.ctype
/// wmma.mma.sync.aligned.col.row.m16n16k16.f16.f16 (wmma native size 16x16x16)
///////////////////////////////////////////////////////////////////////////////
TEST(SM70_gemm_threadblock_wmma_tensor_op_col_row_row_f16, 64x64x32_64x64x32_16x16x16) {
using ElementA = cutlass::half_t;
using LayoutA = cutlass::layout::ColumnMajor;
using ElementB = cutlass::half_t;
using LayoutB = cutlass::layout::RowMajor;
using ElementC = cutlass::half_t;
using LayoutC = cutlass::layout::RowMajor;
static const int kStages = 2;
cutlass::gemm::GemmCoord problem_size(64, 64, 32);
using ThreadblockShape = cutlass::gemm::GemmShape<64, 64, 32>;
using WarpShape = cutlass::gemm::GemmShape<64, 64, 32>;
using InstructionShape = cutlass::gemm::GemmShape<16, 16, 16>;
float alpha = 1.f;
float beta = 0.0f;
// Define the MmaCore components
using MmaCore = typename cutlass::gemm::threadblock::DefaultMmaCore<
ThreadblockShape, WarpShape, InstructionShape, ElementA, LayoutA,
ElementB, LayoutB, ElementC, LayoutC,
cutlass::arch::OpClassWmmaTensorOp, kStages>;
dim3 grid(1, 1);
dim3 block(32, 1, 1);
test::gemm::threadblock::Testbed<MmaCore, kStages>(problem_size.m(), problem_size.n(),
problem_size.k(), alpha, beta)
.run(grid, block);
}
TEST(SM70_gemm_threadblock_wmma_tensor_op_col_row_row_f16, 128x128x32_64x64x32_16x16x16) {
using ElementA = cutlass::half_t;
using LayoutA = cutlass::layout::ColumnMajor;
using ElementB = cutlass::half_t;
using LayoutB = cutlass::layout::RowMajor;
using ElementC = cutlass::half_t;
using LayoutC = cutlass::layout::RowMajor;
static const int kStages = 2;
cutlass::gemm::GemmCoord problem_size(128, 128, 64);
using ThreadblockShape = cutlass::gemm::GemmShape<128, 128, 32>;
using WarpShape = cutlass::gemm::GemmShape<64, 64, 32>;
using InstructionShape = cutlass::gemm::GemmShape<16, 16, 16>;
float alpha = 1.f;
float beta = 0.0f;
// Define the MmaCore components
using MmaCore = typename cutlass::gemm::threadblock::DefaultMmaCore<
ThreadblockShape, WarpShape, InstructionShape, ElementA, LayoutA,
ElementB, LayoutB, ElementC, LayoutC,
cutlass::arch::OpClassWmmaTensorOp, kStages>;
dim3 grid(1, 1);
dim3 block(32, 4, 1);
test::gemm::threadblock::Testbed<MmaCore, kStages>(problem_size.m(), problem_size.n(),
problem_size.k(), alpha, beta)
.run(grid, block);
}
///////////////////////////////////////////////////////////////////////////////
/// wmma.mma.sync.aligned.alayout.blayout.shape.dtype.ctype
/// wmma.mma.sync.aligned.row.row.m16n16k16.f16.f16 (wmma native size 16x16x16)
///////////////////////////////////////////////////////////////////////////////
TEST(SM70_gemm_threadblock_wmma_tensor_op_row_row_row_f16, 64x64x32_64x64x32_16x16x16) {
using ElementA = cutlass::half_t;
using LayoutA = cutlass::layout::RowMajor;
using ElementB = cutlass::half_t;
using LayoutB = cutlass::layout::RowMajor;
using ElementC = cutlass::half_t;
using LayoutC = cutlass::layout::RowMajor;
static const int kStages = 2;
cutlass::gemm::GemmCoord problem_size(64, 64, 32);
using ThreadblockShape = cutlass::gemm::GemmShape<64, 64, 32>;
using WarpShape = cutlass::gemm::GemmShape<64, 64, 32>;
using InstructionShape = cutlass::gemm::GemmShape<16, 16, 16>;
float alpha = 1.f;
float beta = 0.0f;
// Define the MmaCore components
using MmaCore = typename cutlass::gemm::threadblock::DefaultMmaCore<
ThreadblockShape, WarpShape, InstructionShape, ElementA, LayoutA,
ElementB, LayoutB, ElementC, LayoutC,
cutlass::arch::OpClassWmmaTensorOp, kStages>;
dim3 grid(1, 1);
dim3 block(32, 1, 1);
test::gemm::threadblock::Testbed<MmaCore, kStages>(problem_size.m(), problem_size.n(),
problem_size.k(), alpha, beta)
.run(grid, block);
}
TEST(SM70_gemm_threadblock_wmma_tensor_op_row_row_row_f16, 128x128x32_64x64x32_16x16x16) {
using ElementA = cutlass::half_t;
using LayoutA = cutlass::layout::RowMajor;
using ElementB = cutlass::half_t;
using LayoutB = cutlass::layout::RowMajor;
using ElementC = cutlass::half_t;
using LayoutC = cutlass::layout::RowMajor;
static const int kStages = 2;
cutlass::gemm::GemmCoord problem_size(128, 128, 96);
using ThreadblockShape = cutlass::gemm::GemmShape<128, 128, 32>;
using WarpShape = cutlass::gemm::GemmShape<64, 64, 32>;
using InstructionShape = cutlass::gemm::GemmShape<16, 16, 16>;
float alpha = 1.f;
float beta = 0.0f;
// Define the MmaCore components
using MmaCore = typename cutlass::gemm::threadblock::DefaultMmaCore<
ThreadblockShape, WarpShape, InstructionShape, ElementA, LayoutA,
ElementB, LayoutB, ElementC, LayoutC,
cutlass::arch::OpClassWmmaTensorOp, kStages>;
dim3 grid(1, 1);
dim3 block(32, 4, 1);
test::gemm::threadblock::Testbed<MmaCore, kStages>(problem_size.m(), problem_size.n(),
problem_size.k(), alpha, beta)
.run(grid, block);
}
///////////////////////////////////////////////////////////////////////////////
/// wmma.mma.sync.aligned.alayout.blayout.shape.dtype.ctype
/// wmma.mma.sync.aligned.col.col.m16n16k16.f16.f16 (wmma native size 16x16x16)
///////////////////////////////////////////////////////////////////////////////
TEST(SM70_gemm_threadblock_wmma_tensor_op_col_col_row_f16, 64x64x32_64x64x32_16x16x16) {
using ElementA = cutlass::half_t;
using LayoutA = cutlass::layout::ColumnMajor;
using ElementB = cutlass::half_t;
using LayoutB = cutlass::layout::ColumnMajor;
using ElementC = cutlass::half_t;
using LayoutC = cutlass::layout::RowMajor;
static const int kStages = 2;
cutlass::gemm::GemmCoord problem_size(64, 64, 32);
using ThreadblockShape = cutlass::gemm::GemmShape<64, 64, 32>;
using WarpShape = cutlass::gemm::GemmShape<64, 64, 32>;
using InstructionShape = cutlass::gemm::GemmShape<16, 16, 16>;
float alpha = 1.f;
float beta = 0.0f;
// Define the MmaCore components
using MmaCore = typename cutlass::gemm::threadblock::DefaultMmaCore<
ThreadblockShape, WarpShape, InstructionShape, ElementA, LayoutA,
ElementB, LayoutB, ElementC, LayoutC,
cutlass::arch::OpClassWmmaTensorOp, kStages>;
dim3 grid(1, 1);
dim3 block(32, 1, 1);
test::gemm::threadblock::Testbed<MmaCore, kStages>(problem_size.m(), problem_size.n(),
problem_size.k(), alpha, beta)
.run(grid, block);
}
TEST(SM70_gemm_threadblock_wmma_tensor_op_col_col_row_f16, 128x128x32_64x64x32_16x16x16) {
using ElementA = cutlass::half_t;
using LayoutA = cutlass::layout::ColumnMajor;
using ElementB = cutlass::half_t;
using LayoutB = cutlass::layout::ColumnMajor;
using ElementC = cutlass::half_t;
using LayoutC = cutlass::layout::RowMajor;
static const int kStages = 2;
cutlass::gemm::GemmCoord problem_size(128, 128, 96);
using ThreadblockShape = cutlass::gemm::GemmShape<128, 128, 32>;
using WarpShape = cutlass::gemm::GemmShape<64, 64, 32>;
using InstructionShape = cutlass::gemm::GemmShape<16, 16, 16>;
float alpha = 1.f;
float beta = 0.0f;
// Define the MmaCore components
using MmaCore = typename cutlass::gemm::threadblock::DefaultMmaCore<
ThreadblockShape, WarpShape, InstructionShape, ElementA, LayoutA,
ElementB, LayoutB, ElementC, LayoutC,
cutlass::arch::OpClassWmmaTensorOp, kStages>;
dim3 grid(1, 1);
dim3 block(32, 4, 1);
test::gemm::threadblock::Testbed<MmaCore, kStages>(problem_size.m(), problem_size.n(),
problem_size.k(), alpha, beta)
.run(grid, block);
}
// tests for {N,T}x{N,T}=>{N}
///////////////////////////////////////////////////////////
/// wmma.mma.sync.aligned.alayout.blayout.shape.dtype.ctype
/// wmma.mma.sync.aligned.row.col.m16n16k16.f16.f16 (wmma native size 16x16x16)
////////////////////////////////////////////////////////////
TEST(SM70_gemm_threadblock_wmma_tensor_op_row_col_col_f16, 64x64x32_64x64x32_16x16x16) {
using ElementA = cutlass::half_t;
using LayoutA = cutlass::layout::RowMajor;
using ElementB = cutlass::half_t;
using LayoutB = cutlass::layout::ColumnMajor;
using ElementC = cutlass::half_t;
using LayoutC = cutlass::layout::ColumnMajor;
static const int kStages = 2;
cutlass::gemm::GemmCoord problem_size(64, 64, 32);
using ThreadblockShape = cutlass::gemm::GemmShape<64, 64, 32>;
using WarpShape = cutlass::gemm::GemmShape<64, 64, 32>;
using InstructionShape = cutlass::gemm::GemmShape<16, 16, 16>;
float alpha = 1.f;
float beta = 0.0f;
// Define the MmaCore components
using MmaCore = typename cutlass::gemm::threadblock::DefaultMmaCore<
ThreadblockShape, WarpShape, InstructionShape, ElementA, LayoutA,
ElementB, LayoutB, ElementC, LayoutC,
cutlass::arch::OpClassWmmaTensorOp, kStages>;
dim3 grid(1, 1);
dim3 block(32, 1, 1);
test::gemm::threadblock::Testbed<MmaCore, kStages>(problem_size.m(), problem_size.n(),
problem_size.k(), alpha, beta)
.run(grid, block);
}
///////////////////////////////////////////////////////////////////////////////
/// wmma.mma.sync.aligned.alayout.blayout.shape.dtype.ctype
/// wmma.mma.sync.aligned.col.row.m16n16k16.f16.f16 (wmma native size 16x16x16)
///////////////////////////////////////////////////////////////////////////////
TEST(SM70_gemm_threadblock_wmma_tensor_op_col_row_col_f16, 64x64x32_64x64x32_16x16x16) {
using ElementA = cutlass::half_t;
using LayoutA = cutlass::layout::ColumnMajor;
using ElementB = cutlass::half_t;
using LayoutB = cutlass::layout::RowMajor;
using ElementC = cutlass::half_t;
using LayoutC = cutlass::layout::ColumnMajor;
static const int kStages = 2;
cutlass::gemm::GemmCoord problem_size(64, 64, 32);
using ThreadblockShape = cutlass::gemm::GemmShape<64, 64, 32>;
using WarpShape = cutlass::gemm::GemmShape<64, 64, 32>;
using InstructionShape = cutlass::gemm::GemmShape<16, 16, 16>;
float alpha = 1.f;
float beta = 0.0f;
// Define the MmaCore components
using MmaCore = typename cutlass::gemm::threadblock::DefaultMmaCore<
ThreadblockShape, WarpShape, InstructionShape, ElementA, LayoutA,
ElementB, LayoutB, ElementC, LayoutC,
cutlass::arch::OpClassWmmaTensorOp, kStages>;
dim3 grid(1, 1);
dim3 block(32, 1, 1);
test::gemm::threadblock::Testbed<MmaCore, kStages>(problem_size.m(), problem_size.n(),
problem_size.k(), alpha, beta)
.run(grid, block);
}
///////////////////////////////////////////////////////////////////////////////
/// wmma.mma.sync.aligned.alayout.blayout.shape.dtype.ctype
/// wmma.mma.sync.aligned.row.row.m16n16k16.f16.f16 (wmma native size 16x16x16)
///////////////////////////////////////////////////////////////////////////////
TEST(SM70_gemm_threadblock_wmma_tensor_op_row_row_col_f16, 64x64x32_64x64x32_16x16x16) {
using ElementA = cutlass::half_t;
using LayoutA = cutlass::layout::RowMajor;
using ElementB = cutlass::half_t;
using LayoutB = cutlass::layout::RowMajor;
using ElementC = cutlass::half_t;
using LayoutC = cutlass::layout::ColumnMajor;
static const int kStages = 2;
cutlass::gemm::GemmCoord problem_size(64, 64, 32);
using ThreadblockShape = cutlass::gemm::GemmShape<64, 64, 32>;
using WarpShape = cutlass::gemm::GemmShape<64, 64, 32>;
using InstructionShape = cutlass::gemm::GemmShape<16, 16, 16>;
float alpha = 1.f;
float beta = 0.0f;
// Define the MmaCore components
using MmaCore = typename cutlass::gemm::threadblock::DefaultMmaCore<
ThreadblockShape, WarpShape, InstructionShape, ElementA, LayoutA,
ElementB, LayoutB, ElementC, LayoutC,
cutlass::arch::OpClassWmmaTensorOp, kStages>;
dim3 grid(1, 1);
dim3 block(32, 1, 1);
test::gemm::threadblock::Testbed<MmaCore, kStages>(problem_size.m(), problem_size.n(),
problem_size.k(), alpha, beta)
.run(grid, block);
}
///////////////////////////////////////////////////////////////////////////////
/// wmma.mma.sync.aligned.alayout.blayout.shape.dtype.ctype
/// wmma.mma.sync.aligned.col.col.m16n16k16.f16.f16 (wmma native size 16x16x16)
///////////////////////////////////////////////////////////////////////////////
TEST(SM70_gemm_threadblock_wmma_tensor_op_col_col_col_f16, 64x64x32_64x64x32_16x16x16) {
using ElementA = cutlass::half_t;
using LayoutA = cutlass::layout::ColumnMajor;
using ElementB = cutlass::half_t;
using LayoutB = cutlass::layout::ColumnMajor;
using ElementC = cutlass::half_t;
using LayoutC = cutlass::layout::ColumnMajor;
static const int kStages = 2;
cutlass::gemm::GemmCoord problem_size(64, 64, 32);
using ThreadblockShape = cutlass::gemm::GemmShape<64, 64, 32>;
using WarpShape = cutlass::gemm::GemmShape<64, 64, 32>;
using InstructionShape = cutlass::gemm::GemmShape<16, 16, 16>;
float alpha = 1.f;
float beta = 0.0f;
// Define the MmaCore components
using MmaCore = typename cutlass::gemm::threadblock::DefaultMmaCore<
ThreadblockShape, WarpShape, InstructionShape, ElementA, LayoutA,
ElementB, LayoutB, ElementC, LayoutC,
cutlass::arch::OpClassWmmaTensorOp, kStages>;
dim3 grid(1, 1);
dim3 block(32, 1, 1);
test::gemm::threadblock::Testbed<MmaCore, kStages>(problem_size.m(), problem_size.n(),
problem_size.k(), alpha, beta)
.run(grid, block);
}
//////////////// [END] Verifying all layouts {N,T}x{N,T}=>{N,T} for WMMA 16x16x16 [END] //////////////////////
TEST(SM70_gemm_threadblock_wmma_tensor_op_row_col_row_f16, 128x128x32_64x64x32_16x16x16) {
using ElementA = cutlass::half_t;
using LayoutA = cutlass::layout::RowMajor;
using ElementB = cutlass::half_t;
using LayoutB = cutlass::layout::ColumnMajor;
using ElementC = cutlass::half_t;
using LayoutC = cutlass::layout::RowMajor;
static const int kStages = 2;
cutlass::gemm::GemmCoord problem_size(128, 128, 64);
using ThreadblockShape = cutlass::gemm::GemmShape<128, 128, 32>;
using WarpShape = cutlass::gemm::GemmShape<64, 64, 32>;
using InstructionShape = cutlass::gemm::GemmShape<16, 16, 16>;
float alpha = 1.f;
float beta = 0.0f;
// Define the MmaCore components
using MmaCore = typename cutlass::gemm::threadblock::DefaultMmaCore<
ThreadblockShape, WarpShape, InstructionShape, ElementA, LayoutA,
ElementB, LayoutB, ElementC, LayoutC,
cutlass::arch::OpClassWmmaTensorOp, kStages>;
dim3 grid(1, 1);
dim3 block(32, 4, 1);
test::gemm::threadblock::Testbed<MmaCore, kStages>(problem_size.m(), problem_size.n(),
problem_size.k(), alpha, beta)
.run(grid, block);
}
TEST(SM70_gemm_threadblock_wmma_tensor_op_row_col_row_f16, multicta_256x256x96_128x128x32_64x64x32_16x16x16) {
using ElementA = cutlass::half_t;
using LayoutA = cutlass::layout::RowMajor;
using ElementB = cutlass::half_t;
using LayoutB = cutlass::layout::ColumnMajor;
using ElementC = cutlass::half_t;
using LayoutC = cutlass::layout::RowMajor;
static const int kStages = 2;
cutlass::gemm::GemmCoord problem_size(256, 256, 96);
using ThreadblockShape = cutlass::gemm::GemmShape<128, 128, 32>;
using WarpShape = cutlass::gemm::GemmShape<64, 64, 32>;
using InstructionShape = cutlass::gemm::GemmShape<16, 16, 16>;
float alpha = 1.f;
float beta = 0.0f;
// Define the MmaCore components
using MmaCore = typename cutlass::gemm::threadblock::DefaultMmaCore<
ThreadblockShape, WarpShape, InstructionShape, ElementA, LayoutA,
ElementB, LayoutB, ElementC, LayoutC,
cutlass::arch::OpClassWmmaTensorOp, kStages>;
dim3 grid(2, 2);
dim3 block(32, 4, 1);
test::gemm::threadblock::Testbed<MmaCore, kStages>(problem_size.m(), problem_size.n(),
problem_size.k(), alpha, beta)
.run(grid, block);
}
///////////////////////////////////////////////////////////////////////////////
/// wmma.mma.sync.aligned.alayout.blayout.shape.dtype.ctype
/// wmma.mma.sync.aligned.row.col.m32n8k16.f16.f16 (wmma native size 32x8x16)
///////////////////////////////////////////////////////////////////////////////
TEST(SM70_gemm_threadblock_wmma_tensor_op_row_col_row_f16, 64x64x32_64x64x32_32x8x16) {
using ElementA = cutlass::half_t;
using LayoutA = cutlass::layout::RowMajor;
using ElementB = cutlass::half_t;
using LayoutB = cutlass::layout::ColumnMajor;
using ElementC = cutlass::half_t;
using LayoutC = cutlass::layout::RowMajor;
static const int kStages = 2;
cutlass::gemm::GemmCoord problem_size(64, 64, 128);
using ThreadblockShape = cutlass::gemm::GemmShape<64, 64, 32>;
using WarpShape = cutlass::gemm::GemmShape<64, 64, 32>;
using InstructionShape = cutlass::gemm::GemmShape<32, 8, 16>;
float alpha = 1.f;
float beta = 0.0f;
// Define the MmaCore components
using MmaCore = typename cutlass::gemm::threadblock::DefaultMmaCore<
ThreadblockShape, WarpShape, InstructionShape, ElementA, LayoutA,
ElementB, LayoutB, ElementC, LayoutC,
cutlass::arch::OpClassWmmaTensorOp, kStages>;
dim3 grid(1, 1);
dim3 block(32, 1, 1);
test::gemm::threadblock::Testbed<MmaCore, kStages>(problem_size.m(), problem_size.n(),
problem_size.k(), alpha, beta)
.run(grid, block);
}
//////////////////////////////////////////////////////////////////////////////
/// wmma.mma.sync.aligned.alayout.blayout.shape.dtype.ctype
/// wmma.mma.sync.aligned.row.col.m8n32k16.f16.f16 (wmma native size 8x32x16)
//////////////////////////////////////////////////////////////////////////////
TEST(SM70_gemm_threadblock_wmma_tensor_op_row_col_row_f16, 64x64x32_64x64x32_8x32x16) {
using ElementA = cutlass::half_t;
using LayoutA = cutlass::layout::RowMajor;
using ElementB = cutlass::half_t;
using LayoutB = cutlass::layout::ColumnMajor;
using ElementC = cutlass::half_t;
using LayoutC = cutlass::layout::RowMajor;
static const int kStages = 2;
cutlass::gemm::GemmCoord problem_size(64, 64, 128);
using ThreadblockShape = cutlass::gemm::GemmShape<64, 64, 32>;
using WarpShape = cutlass::gemm::GemmShape<64, 64, 32>;
using InstructionShape = cutlass::gemm::GemmShape<8, 32, 16>;
float alpha = 1.f;
float beta = 0.0f;
// Define the MmaCore components
using MmaCore = typename cutlass::gemm::threadblock::DefaultMmaCore<
ThreadblockShape, WarpShape, InstructionShape, ElementA, LayoutA,
ElementB, LayoutB, ElementC, LayoutC,
cutlass::arch::OpClassWmmaTensorOp, kStages>;
dim3 grid(1, 1);
dim3 block(32, 1, 1);
test::gemm::threadblock::Testbed<MmaCore, kStages>(problem_size.m(), problem_size.n(),
problem_size.k(), alpha, beta)
.run(grid, block);
}
//////////////////////////////////////////////////////////////////////////////////
/// wmma.mma.sync.aligned.alayout.blayout.shape.dtype.ctype
/// wmma.mma.sync.aligned.row.col.m16n16k16.f32.f32 (wmma native size 16x16x16)
//////////////////////////////////////////////////////////////////////////////////
TEST(SM70_gemm_threadblock_wmma_tensor_op_row_col_row_f32, 64x64x32_64x64x32_16x16x16) {
using ElementA = cutlass::half_t;
using LayoutA = cutlass::layout::RowMajor;
using ElementB = cutlass::half_t;
using LayoutB = cutlass::layout::ColumnMajor;
using ElementC = float;
using LayoutC = cutlass::layout::RowMajor;
static const int kStages = 2;
cutlass::gemm::GemmCoord problem_size(64, 64, 128);
using ThreadblockShape = cutlass::gemm::GemmShape<64, 64, 32>;
using WarpShape = cutlass::gemm::GemmShape<64, 64, 32>;
using InstructionShape = cutlass::gemm::GemmShape<16, 16, 16>;
float alpha = 1.f;
float beta = 0.0f;
// Define the MmaCore components
using MmaCore = typename cutlass::gemm::threadblock::DefaultMmaCore<
ThreadblockShape, WarpShape, InstructionShape, ElementA, LayoutA,
ElementB, LayoutB, ElementC, LayoutC,
cutlass::arch::OpClassWmmaTensorOp, kStages>;
dim3 grid(1, 1);
dim3 block(32, 1, 1);
test::gemm::threadblock::Testbed<MmaCore, kStages>(problem_size.m(), problem_size.n(),
problem_size.k(), alpha, beta)
.run(grid, block);
}
TEST(SM70_gemm_threadblock_wmma_tensor_op_row_col_row_f32, 128x128x32_64x64x32_16x16x16) {
using ElementA = cutlass::half_t;
using LayoutA = cutlass::layout::RowMajor;
using ElementB = cutlass::half_t;
using LayoutB = cutlass::layout::ColumnMajor;
using ElementC = float;
using LayoutC = cutlass::layout::RowMajor;
static const int kStages = 2;
cutlass::gemm::GemmCoord problem_size(128, 128, 128);
using ThreadblockShape = cutlass::gemm::GemmShape<128, 128, 32>;
using WarpShape = cutlass::gemm::GemmShape<64, 64, 32>;
using InstructionShape = cutlass::gemm::GemmShape<16, 16, 16>;
float alpha = 1.f;
float beta = 0.0f;
// Define the MmaCore components
using MmaCore = typename cutlass::gemm::threadblock::DefaultMmaCore<
ThreadblockShape, WarpShape, InstructionShape, ElementA, LayoutA,
ElementB, LayoutB, ElementC, LayoutC,
cutlass::arch::OpClassWmmaTensorOp, kStages>;
dim3 grid(1, 1);
dim3 block(32, 4, 1);
test::gemm::threadblock::Testbed<MmaCore, kStages>(problem_size.m(), problem_size.n(),
problem_size.k(), alpha, beta)
.run(grid, block);
}
TEST(SM70_gemm_threadblock_wmma_tensor_op_row_col_row_f32, multicta_256x256x96_128x128x32_64x64x32_16x16x16) {
using ElementA = cutlass::half_t;
using LayoutA = cutlass::layout::RowMajor;
using ElementB = cutlass::half_t;
using LayoutB = cutlass::layout::ColumnMajor;
using ElementC = float;
using LayoutC = cutlass::layout::RowMajor;
static const int kStages = 2;
cutlass::gemm::GemmCoord problem_size(256, 256, 96);
using ThreadblockShape = cutlass::gemm::GemmShape<128, 128, 32>;
using WarpShape = cutlass::gemm::GemmShape<64, 64, 32>;
using InstructionShape = cutlass::gemm::GemmShape<16, 16, 16>;
float alpha = 1.f;
float beta = 0.0f;
// Define the MmaCore components
using MmaCore = typename cutlass::gemm::threadblock::DefaultMmaCore<
ThreadblockShape, WarpShape, InstructionShape, ElementA, LayoutA,
ElementB, LayoutB, ElementC, LayoutC,
cutlass::arch::OpClassWmmaTensorOp, kStages>;
dim3 grid(2, 2);
dim3 block(32, 4, 1);
test::gemm::threadblock::Testbed<MmaCore, kStages>(problem_size.m(), problem_size.n(),
problem_size.k(), alpha, beta)
.run(grid, block);
}
///////////////////////////////////////////////////////////
/// wmma.mma.sync.aligned.alayout.blayout.shape.dtype.ctype
/// wmma.mma.sync.aligned.row.col.m32n8k16.f32.f32 (wmma native size 32x8x16)
////////////////////////////////////////////////////////////
TEST(SM70_gemm_threadblock_wmma_tensor_op_row_col_row_f32, 64x64x32_64x64x32_32x8x16) {
using ElementA = cutlass::half_t;
using LayoutA = cutlass::layout::RowMajor;
using ElementB = cutlass::half_t;
using LayoutB = cutlass::layout::ColumnMajor;
using ElementC = float;
using LayoutC = cutlass::layout::RowMajor;
static const int kStages = 2;
cutlass::gemm::GemmCoord problem_size(64, 64, 128);
using ThreadblockShape = cutlass::gemm::GemmShape<64, 64, 32>;
using WarpShape = cutlass::gemm::GemmShape<64, 64, 32>;
using InstructionShape = cutlass::gemm::GemmShape<32, 8, 16>;
float alpha = 1.f;
float beta = 0.0f;
// Define the MmaCore components
using MmaCore = typename cutlass::gemm::threadblock::DefaultMmaCore<
ThreadblockShape, WarpShape, InstructionShape, ElementA, LayoutA,
ElementB, LayoutB, ElementC, LayoutC,
cutlass::arch::OpClassWmmaTensorOp, kStages>;
dim3 grid(1, 1);
dim3 block(32, 1, 1);
test::gemm::threadblock::Testbed<MmaCore, kStages>(problem_size.m(), problem_size.n(),
problem_size.k(), alpha, beta)
.run(grid, block);
}
/////////////////////////////////////////////////////////////////////////////////
/// wmma.mma.sync.aligned.alayout.blayout.shape.dtype.ctype
/// wmma.mma.sync.aligned.row.col.m8n32k16.f32.f32 (wmma native size 8x32x16)
/////////////////////////////////////////////////////////////////////////////////
TEST(SM70_gemm_threadblock_wmma_tensor_op_row_col_row_f32, 64x64x32_64x64x32_8x32x16) {
using ElementA = cutlass::half_t;
using LayoutA = cutlass::layout::RowMajor;
using ElementB = cutlass::half_t;
using LayoutB = cutlass::layout::ColumnMajor;
using ElementC = float;
using LayoutC = cutlass::layout::RowMajor;
static const int kStages = 2;
cutlass::gemm::GemmCoord problem_size(64, 64, 128);
using ThreadblockShape = cutlass::gemm::GemmShape<64, 64, 32>;
using WarpShape = cutlass::gemm::GemmShape<64, 64, 32>;
using InstructionShape = cutlass::gemm::GemmShape<8, 32, 16>;
float alpha = 1.f;
float beta = 0.0f;
// Define the MmaCore components
using MmaCore = typename cutlass::gemm::threadblock::DefaultMmaCore<
ThreadblockShape, WarpShape, InstructionShape, ElementA, LayoutA,
ElementB, LayoutB, ElementC, LayoutC,
cutlass::arch::OpClassWmmaTensorOp, kStages>;
dim3 grid(1, 1);
dim3 block(32, 1, 1);
test::gemm::threadblock::Testbed<MmaCore, kStages>(problem_size.m(), problem_size.n(),
problem_size.k(), alpha, beta)
.run(grid, block);
}
#endif //CUTLASS_ARCH_WMMA_SM70_ENABLED
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