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composable_kernel/test/mx_mfma_op/mx_mfma_op.cpp

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// SPDX-License-Identifier: MIT
// Copyright (c) 2025, Advanced Micro Devices, Inc. All rights reserved.
#include "gtest/gtest.h"
#include "mx_mfma_op.hpp"
using ck::e8m0_bexp_t;
using ck::f4_t;
using ck::f4x2_pk_t;
using ck::f8_t;
using ck::half_t;
using ck::type_convert;
/**
* @brief Run the test for the given MFMA instruction
*
* @param init - selects initialization algorithm for A and B tensors
*/
template <typename AType, typename BType, typename CType, ck::MFMA_F8F6F4 mfma>
bool run_mfma_km_kn_nm_test(ck::index_t init)
{
using ALayout = ck::tensor_layout::gemm::ColumnMajor;
using BLayout = ck::tensor_layout::gemm::ColumnMajor;
using CLayout = ck::tensor_layout::gemm::ColumnMajor;
using AccType = float; // only MFMA_F32 instructions supported
using CPUAccType = AccType;
ck::mfma_type<static_cast<ck::MfmaInstr>(mfma)> mfma_instr;
constexpr auto BLOCK_M = mfma_instr.m_per_blk;
constexpr auto BLOCK_N = mfma_instr.n_per_blk;
constexpr auto BLOCK_K = mfma_instr.num_input_blks * mfma_instr.k_per_blk;
const auto mfma_kernel = ck::
matmul<AType, BType, CType, AccType, BLOCK_M, BLOCK_N, BLOCK_K, ALayout, BLayout, CLayout>;
bool pass = true;
pass = ck::mfma_test::TestMFMA<decltype(mfma_kernel),
AType,
BType,
CType,
AccType,
CPUAccType,
ALayout,
BLayout,
CLayout,
BLOCK_M,
BLOCK_N,
BLOCK_K>{}(mfma_kernel, init);
return pass;
}
TEST(MFMA, FP8MFMA16x16x128)
{
auto AB_init = 5;
auto pass = run_mfma_km_kn_nm_test<f8_t, f8_t, half_t, ck::MFMA_F8F6F4::F32_16x16x128>(AB_init);
EXPECT_TRUE(pass);
}
TEST(MFMA, FP8MFMA32x32x64)
{
auto AB_init = 5;
auto pass = run_mfma_km_kn_nm_test<f8_t, f8_t, float, ck::MFMA_F8F6F4::F32_32x32x64>(AB_init);
EXPECT_TRUE(pass);
}
/**
* @brief Run the test for the given MFMA instruction
*
* @param init - selects initialization algorithm for A and B tensors
*/
template <typename AType, typename BType, typename CType, ck::MFMA_F8F6F4 mfma>
bool run_mfma_mk_kn_mn_test(ck::index_t init)
{
using ALayout = ck::tensor_layout::gemm::RowMajor;
using BLayout = ck::tensor_layout::gemm::ColumnMajor;
using CLayout = ck::tensor_layout::gemm::RowMajor;
using AccType = float; // only MFMA_F32 instructions supported
using CPUAccType = AccType;
ck::mfma_type<static_cast<ck::MfmaInstr>(mfma)> mfma_instr;
constexpr auto BLOCK_M = mfma_instr.m_per_blk;
constexpr auto BLOCK_N = mfma_instr.n_per_blk;
constexpr auto BLOCK_K = mfma_instr.num_input_blks * mfma_instr.k_per_blk;
const auto mfma_kernel = ck::
matmul<AType, BType, CType, AccType, BLOCK_M, BLOCK_N, BLOCK_K, ALayout, BLayout, CLayout>;
bool pass = true;
pass = ck::mfma_test::TestMFMA<decltype(mfma_kernel),
AType,
BType,
CType,
AccType,
CPUAccType,
ALayout,
BLayout,
CLayout,
BLOCK_M,
BLOCK_N,
BLOCK_K>{}(mfma_kernel, init);
return pass;
}
TEST(MFMA, FP4MFMA16x16x128)
{
auto AB_init = 4;
auto pass = run_mfma_mk_kn_mn_test<f4x2_pk_t, f4x2_pk_t, float, ck::MFMA_F8F6F4::F32_16x16x128>(
AB_init);
EXPECT_TRUE(pass);
}
TEST(MFMA, FP4MFMA32x32x64)
{
auto AB_init = 4;
auto pass = run_mfma_mk_kn_mn_test<f4x2_pk_t, f4x2_pk_t, half_t, ck::MFMA_F8F6F4::F32_32x32x64>(
AB_init);
EXPECT_TRUE(pass);
}
/**
* @brief Run the test for the given MX MFMA instruction
*
* @param init - selects initialization algorithm for A and B tensors
*/
template <typename AType, typename BType, typename CType, ck::MFMA_F8F6F4 mfma>
bool run_mxmfma_mk_kn_mn_test(ck::index_t init)
{
static_assert(mfma == ck::MFMA_F8F6F4::SCALE_F32_16x16x128 ||
mfma == ck::MFMA_F8F6F4::SCALE_F32_32x32x64,
"Only SCALE_F32_16x16x128 and SCALE_F32_32x32x64 are supported");
using ALayout = ck::tensor_layout::gemm::RowMajor;
using BLayout = ck::tensor_layout::gemm::ColumnMajor;
using CLayout = ck::tensor_layout::gemm::RowMajor;
using AccType = float; // only MFMA_F32 instructions supported
using ScaleType = ck::e8m0_bexp_t; // biased exponent type
ck::mfma_type<static_cast<ck::MfmaInstr>(mfma)> mfma_instr;
constexpr auto BLOCK_M = mfma_instr.m_per_blk;
constexpr auto BLOCK_N = mfma_instr.n_per_blk;
constexpr auto BLOCK_K = mfma_instr.num_input_blks * mfma_instr.k_per_blk;
constexpr auto BLOCK_X = 32; // scaling vector size
const auto mx_mfma_kernel = ck::matmul<AType,
BType,
ScaleType,
CType,
AccType,
BLOCK_M,
BLOCK_N,
BLOCK_K,
BLOCK_X,
ALayout,
BLayout,
CLayout>;
bool pass = true;
pass = ck::mxmfma_test::TestMXMFMA<decltype(mx_mfma_kernel),
AType,
BType,
ScaleType,
CType,
ALayout,
BLayout,
CLayout,
BLOCK_M,
BLOCK_N,
BLOCK_K,
BLOCK_X>{}(mx_mfma_kernel, init);
return pass;
}
TEST(MXMFMA, MXFP8MFMA16x16x128)
{
auto AB_init = 5;
auto pass =
run_mxmfma_mk_kn_mn_test<f8_t, f8_t, float, ck::MFMA_F8F6F4::SCALE_F32_16x16x128>(AB_init);
EXPECT_TRUE(pass);
}
TEST(MXMFMA, MXFP8MFMA32x32x64)
{
auto AB_init = 5;
auto pass =
run_mxmfma_mk_kn_mn_test<f8_t, f8_t, half_t, ck::MFMA_F8F6F4::SCALE_F32_32x32x64>(AB_init);
EXPECT_TRUE(pass);
}
TEST(MXMFMA, MXFP4MFMA16x16x128)
{
auto AB_init = 4;
auto pass =
run_mxmfma_mk_kn_mn_test<f4x2_pk_t, f4x2_pk_t, float, ck::MFMA_F8F6F4::SCALE_F32_16x16x128>(
AB_init);
EXPECT_TRUE(pass);
}
TEST(MXMFMA, MXFP4MFMA32x32x64)
{
auto AB_init = 4;
auto pass =
run_mxmfma_mk_kn_mn_test<f4x2_pk_t, f4x2_pk_t, half_t, ck::MFMA_F8F6F4::SCALE_F32_32x32x64>(
AB_init);
EXPECT_TRUE(pass);
}
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