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mma_tensor_op.h
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mma_tensor_op.h
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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 Templates implementing warp-level matrix multiply-accumulate operations targeting
Tensor Cores.
*/
#pragma once
#include "cutlass/cutlass.h"
#include "cutlass/array.h"
#include "cutlass/platform/platform.h"
#include "cutlass/numeric_conversion.h"
#include "cutlass/numeric_types.h"
#include "cutlass/matrix_shape.h"
#include "cutlass/arch/memory_sm75.h"
#include "cutlass/arch/mma_sm75.h"
#include "cutlass/arch/mma_sm80.h"
#include "cutlass/gemm/gemm.h"
#include "cutlass/gemm/warp/mma.h"
#include "cutlass/gemm/warp/mma_tensor_op_policy.h"
#include "cutlass/gemm/warp/mma_tensor_op_tile_iterator.h"
#include "cutlass/gemm/warp/mma_tensor_op_tile_iterator_sm80.h"
/////////////////////////////////////////////////////////////////////////////////////////////////
namespace cutlass {
namespace gemm {
namespace warp {
/////////////////////////////////////////////////////////////////////////////////////////////////
namespace detail {
template <typename T, typename S, int N, FloatRoundStyle Round>
struct ConvertAndPack {
using Converter = NumericArrayConverter<T, S, N, Round>;
CUTLASS_HOST_DEVICE
Array<T, N> operator()(Array<S, N> const &source) {
Converter converter;
return converter(source);
}
};
template <typename T, int N, FloatRoundStyle Round>
struct ConvertAndPack<T, T, N, Round> {
CUTLASS_HOST_DEVICE
Array<T, N> operator()(Array<T, N> const &source) {
return source;
}
};
template <int N, FloatRoundStyle Round>
struct ConvertAndPack<bfloat16_t, float, N, Round> {
using Converter = NumericArrayConverter<bfloat16_t, float, N, Round>;
CUTLASS_HOST_DEVICE
Array<bfloat16_t, N> operator()(Array<float, N> const &source) {
Converter converter;
Array<float, N> tmp;
CUTLASS_PRAGMA_UNROLL
for (int i = 0; i < N; ++i) {
int idx = (((i << 1) & 2) | ((i >> 1) & 1) | (i & 0xfffffffc));
tmp[i] = source[idx];
}
return converter(tmp);
}
};
template <int N, FloatRoundStyle Round>
struct ConvertAndPack<half_t, float, N, Round> {
using Converter = NumericArrayConverter<half_t, float, N, Round>;
CUTLASS_HOST_DEVICE
Array<half_t, N> operator()(Array<float, N> const &source) {
Converter converter;
Array<float, N> tmp;
CUTLASS_PRAGMA_UNROLL
for (int i = 0; i < N; ++i) {
int idx = (((i << 1) & 2) | ((i >> 1) & 1) | (i & 0xfffffffc));
tmp[i] = source[idx];
}
return converter(tmp);
}
};
/////////////////////////////////////////////////////////////////////////////////////////////////
/////////////////////////////////////////////////////////////////////////////////////////////////
} // namespace detail
/////////////////////////////////////////////////////////////////////////////////////////////////
/// Structure to compute the matrix product targeting CUDA cores and SIMT math instructions.
template <
/// Size of the Gemm problem - concept: gemm::GemmShape<>
typename Shape_,
/// Data type of A elements
typename ElementA_,
/// Layout of A matrix (concept: MatrixLayout)
typename LayoutA_,
/// Data type of B elements
typename ElementB_,
/// Layout of B matrix (concept: MatrixLayout)
typename LayoutB_,
/// Element type of C matrix
typename ElementC_,
/// Layout of C matrix (concept: MatrixLayout)
typename LayoutC_,
/// Policy describing warp-level MmaTensorOp (concept: MmaTensorOp policy)
typename Policy_,
/// Number of partitions along K dimension
int PartitionsK_ = 1,
/// Store the accumulators in row major or column major. Row major is used
/// when output layout is interleaved.
bool AccumulatorsInRowMajor = false,
/// Used for partial specialization
typename Enable = bool
>
class MmaTensorOp {
public:
/// Shape of warp-level matrix operation (concept: GemmShape)
using Shape = Shape_;
/// Data type of multiplicand A
using ElementA = ElementA_;
/// Layout of multiplicand A
using LayoutA = LayoutA_;
/// Data type of multiplicand B
using ElementB = ElementB_;
/// Layout of multiplicand B
using LayoutB = LayoutB_;
/// Data type of accumulator matrix C
using ElementC = ElementC_;
/// Layout of accumulator matrix C
using LayoutC = LayoutC_;
/// Shape of the warp in units of thread (concept: MmaLanePolicySimt)
using Policy = Policy_;
/// Underlying matrix multiply operator (concept: arch::Mma)
using ArchMmaOperator = typename Policy::Operator;
/// Indicates math operator
using MathOperator = typename ArchMmaOperator::Operator;
/// Architecture tag from underlying instruction
using ArchTag = typename ArchMmaOperator::ArchTag;
/// Indicates class of matrix operator
using OperatorClass = arch::OpClassTensorOp;
/// Shape of underlying instruction
using InstructionShape = typename ArchMmaOperator::Shape;
/// Complex transform on A operand
static ComplexTransform const kTransformA = ComplexTransform::kNone;
/// Complex transform on B operand
static ComplexTransform const kTransformB = ComplexTransform::kNone;
/// Number of threads participating in warp-level matrix product
static int const kThreadCount = 32;
/// Number of partitions along K dimension
static int const kPartitionsK = PartitionsK_;
#if defined(__CUDA_ARCH__) && ((__CUDA_ARCH__ < 800) || (__CUDA_ARCH__ == 890))
static int const kVerticalVisit = true;
#else
static int const kVerticalVisit = false;
#endif
public:
/// Iterates over the A operand in memory
using IteratorA = MmaTensorOpMultiplicandTileIterator<
MatrixShape<Shape::kM, Shape::kK>, Operand::kA, ElementA, LayoutA,
MatrixShape<ArchMmaOperator::Shape::kM, ArchMmaOperator::Shape::kK>,
Policy::OpDelta::kRow, kThreadCount, kPartitionsK>;
/// Storage for A tile
using FragmentA = typename IteratorA::Fragment;
/// Storage for transformed A tile
using TransformedFragmentA =
Array<typename ArchMmaOperator::ElementA, FragmentA::kElements>;
/// Iterates over the B operand in memory
using IteratorB = MmaTensorOpMultiplicandTileIterator<
MatrixShape<Shape::kK, Shape::kN>, Operand::kB, ElementB, LayoutB,
MatrixShape<ArchMmaOperator::Shape::kK, ArchMmaOperator::Shape::kN>,
Policy::OpDelta::kRow, kThreadCount, kPartitionsK>;
/// Storage for B tile
using FragmentB = typename IteratorB::Fragment;
/// Storage for transformed B tile
using TransformedFragmentB =
Array<typename ArchMmaOperator::ElementB, FragmentB::kElements>;
/// Iterates over the C operand in memory
using IteratorC = MmaTensorOpAccumulatorTileIterator<
MatrixShape<Shape::kM, Shape::kN>, ElementC, LayoutC,
typename ArchMmaOperator::Shape, typename Policy::OpDelta>;
/// Storage for C tile
using FragmentC = typename IteratorC::Fragment;
/// Number of mma operations performed
using MmaIterations = MatrixShape<
(Shape::kM + ArchMmaOperator::Shape::kM - 1) / ArchMmaOperator::Shape::kM,
(Shape::kN + ArchMmaOperator::Shape::kN - 1) / ArchMmaOperator::Shape::kN
>;
public:
/// Underlying matrix multiply operator (concept: arch::Mma)
ArchMmaOperator mma;
public:
//
// Methods
//
/// Ctor
CUTLASS_DEVICE
MmaTensorOp() {}
/// Performs a warp-level matrix multiply-accumulate operation
CUTLASS_DEVICE
void operator()(
FragmentC &D,
TransformedFragmentA const &A,
TransformedFragmentB const &B,
FragmentC const &C
) const {
using MmaOperandA = typename ArchMmaOperator::FragmentA;
using MmaOperandB = typename ArchMmaOperator::FragmentB;
using MmaOperandC = typename ArchMmaOperator::FragmentC;
D = C;
MmaOperandA const *ptr_A = reinterpret_cast<MmaOperandA const *>(&A);
MmaOperandB const *ptr_B = reinterpret_cast<MmaOperandB const *>(&B);
MmaOperandC *ptr_D = reinterpret_cast<MmaOperandC *>(&D);
if (kVerticalVisit) {
CUTLASS_PRAGMA_UNROLL
for (int n = 0; n < MmaIterations::kColumn; ++n) {
CUTLASS_PRAGMA_UNROLL
for (int m = 0; m < MmaIterations::kRow; ++m) {
int m_serpentine = ((n % 2) ? (MmaIterations::kRow - 1 - m) : m);
if (AccumulatorsInRowMajor) { // matrix B is reordered
mma(
ptr_D[n + m_serpentine * MmaIterations::kColumn],
ptr_A[m_serpentine],
ptr_B[n],
ptr_D[n + m_serpentine * MmaIterations::kColumn]);
} else {
mma(
ptr_D[m_serpentine + n * MmaIterations::kRow],
ptr_A[m_serpentine],
ptr_B[n],
ptr_D[m_serpentine + n * MmaIterations::kRow]);
}
}
}
} else {
CUTLASS_PRAGMA_UNROLL
for (int m = 0; m < MmaIterations::kRow; ++m) {
CUTLASS_PRAGMA_UNROLL
for (int n = 0; n < MmaIterations::kColumn; ++n) {
int n_serpentine = ((m % 2) ? (MmaIterations::kColumn - 1 - n) : n);
if (AccumulatorsInRowMajor) { // matrix B is reordered
mma(
ptr_D[n_serpentine + m * MmaIterations::kColumn],
ptr_A[m],
ptr_B[n_serpentine],
ptr_D[n_serpentine + m * MmaIterations::kColumn]);
} else {
mma(ptr_D[m + n_serpentine * MmaIterations::kRow],
ptr_A[m],
ptr_B[n_serpentine],
ptr_D[m + n_serpentine * MmaIterations::kRow]);
}
}
}
}
}
/// Transform the mma operands to the required types
CUTLASS_DEVICE
void transform(TransformedFragmentA &dst_A, TransformedFragmentB &dst_B,
FragmentA const &A, FragmentB const &B) const {
//
// Define conversions from source type to instruction type
//
FloatRoundStyle const kRoundA =
PreferredRoundingMode<typename ArchMmaOperator::ElementA,
ElementA>::kRound;
FloatRoundStyle const kRoundB =
PreferredRoundingMode<typename ArchMmaOperator::ElementB,
ElementB>::kRound;
if (kVerticalVisit) {
detail::ConvertAndPack<typename ArchMmaOperator::ElementA, ElementA,
FragmentA::kElements, kRoundA>
convert_A;
NumericArrayConverter<typename ArchMmaOperator::ElementB, ElementB,
FragmentB::kElements / 2, kRoundB>
convert_B;
Array<ElementB, FragmentB::kElements / 2> const *ptr_B =
reinterpret_cast<Array<ElementB, FragmentB::kElements / 2> const *>(&B);
Array<typename ArchMmaOperator::ElementB, FragmentB::kElements / 2> *
ptr_dst_B = reinterpret_cast<Array<typename ArchMmaOperator::ElementB,
FragmentB::kElements / 2> *>(&dst_B);
dst_A = convert_A(A);
ptr_dst_B[0] = convert_B(ptr_B[0]);
ptr_dst_B[1] = convert_B(ptr_B[1]);
} else {
detail::ConvertAndPack<typename ArchMmaOperator::ElementA, ElementA,
FragmentA::kElements / 2, kRoundA>
convert_A;
NumericArrayConverter<typename ArchMmaOperator::ElementB, ElementB,
FragmentB::kElements, kRoundB>
convert_B;
Array<ElementA, FragmentA::kElements / 2> const *ptr_A =
reinterpret_cast<Array<ElementA, FragmentA::kElements / 2> const *>(&A);
Array<typename ArchMmaOperator::ElementA, FragmentA::kElements / 2> *
ptr_dst_A = reinterpret_cast<Array<typename ArchMmaOperator::ElementA,
FragmentA::kElements / 2> *>(&dst_A);
dst_B = convert_B(B);
ptr_dst_A[0] = convert_A(ptr_A[0]);
ptr_dst_A[1] = convert_A(ptr_A[1]);
}
}
};
/////////////////////////////////////////////////////////////////////////////////////////////////
} // namespace warp
} // namespace gemm
} // namespace cutlass
/////////////////////////////////////////////////////////////////////////////////////////////////
#include "cutlass/gemm/warp/mma_tensor_op_fast_f32.h"
/////////////////////////////////////////////////////////////////////////////////////////////////