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 /***************************************************************************************************
* Copyright (c) 2017 - 2025 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
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* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
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**************************************************************************************************/
/* \file
\brief Defines operations for all CONV operation kinds in CUTLASS Library.
*/
#pragma once
#include <iostream>
#include "cutlass/cutlass.h"
#include "cutlass/conv/kernel/default_conv2d_fprop.h"
#include "cutlass/conv/kernel/default_conv2d_group_fprop.h"
#include "cutlass/conv/kernel/default_depthwise_fprop.h"
#include "cutlass/conv/kernel/default_conv2d_dgrad.h"
#include "cutlass/conv/kernel/default_conv2d_wgrad.h"
#include "cutlass/conv/device/implicit_gemm_convolution.h"
#include "cutlass/conv/device/direct_convolution.h"
#include "cutlass/library/library.h"
#include "library_internal.h"
#include "cutlass/util/host_tensor.h"
#include "cutlass/util/reference/host/convolution.h"
#include "cutlass/util/reference/host/tensor_compare.h"
#include "cutlass/core_io.h"
///////////////////////////////////////////////////////////////////////////////////////////////////
namespace cutlass {
namespace library {
///////////////////////////////////////////////////////////////////////////////////////////////////
template <typename Operator_>
class Conv2dOperationBase : public Operation {
public:
using Operator = Operator_;
using ElementA = typename Operator::ElementA;
using LayoutA = typename Operator::LayoutA;
using ElementB = typename Operator::ElementB;
using LayoutB = typename Operator::LayoutB;
using ElementC = typename Operator::ElementC;
using LayoutC = typename Operator::LayoutC;
using ElementAccumulator = typename Operator::ElementAccumulator;
using ElementCompute = typename Operator::EpilogueOutputOp::ElementCompute;
static cutlass::conv::IteratorAlgorithm const kIteratorAlgorithm = Operator::kIteratorAlgorithm;
static cutlass::conv::Operator const kConvolutionalOperator = Operator::kConvolutionalOperator;
using OperatorArguments = typename Operator::Arguments;
protected:
///
ConvDescription description_;
public:
/// Constructor
Conv2dOperationBase(char const *name = "unknown_conv2d") {
description_.name = name;
description_.provider = Provider::kCUTLASS;
description_.kind = OperationKind::kConv2d;
description_.conv_dim = Operator::kConvDim;
description_.iterator_algorithm = IteratorAlgorithmMap<Operator::kIteratorAlgorithm>::kId;
description_.tile_description.threadblock_shape = make_Coord(
Operator::ThreadblockShape::kM,
Operator::ThreadblockShape::kN,
Operator::ThreadblockShape::kK);
description_.tile_description.threadblock_stages = Operator::kStages;
description_.tile_description.warp_count = make_Coord(
Operator::UnderlyingKernel::WarpCount::kM,
Operator::UnderlyingKernel::WarpCount::kN,
Operator::UnderlyingKernel::WarpCount::kK);
description_.tile_description.math_instruction.instruction_shape = make_Coord(
Operator::InstructionShape::kM,
Operator::InstructionShape::kN,
Operator::InstructionShape::kK);
description_.tile_description.math_instruction.element_accumulator =
NumericTypeMap<ElementAccumulator>::kId;
description_.tile_description.math_instruction.opcode_class =
OpcodeClassMap<typename Operator::OperatorClass>::kId;
description_.tile_description.math_instruction.math_operation =
MathOperationMap<typename Operator::MathOperator>::kId;
description_.tile_description.minimum_compute_capability =
ArchMap<typename Operator::ArchTag, typename Operator::OperatorClass>::kMin;
description_.tile_description.maximum_compute_capability =
ArchMap<typename Operator::ArchTag, typename Operator::OperatorClass>::kMax;
description_.A = make_TensorDescription<ElementA, LayoutA>();
description_.B = make_TensorDescription<ElementB, LayoutB>();
description_.C = make_TensorDescription<ElementC, LayoutC>();
description_.element_epilogue = NumericTypeMap<ElementCompute>::kId;
// TODO: Add split k mode Serial and parallel to convolutions
// description_.split_k_mode = Operator::kSplitK ? SplitKMode::kSerial : SplitKMode::kNone;
}
/// Returns the description of the GEMM operation
virtual OperationDescription const & description() const {
return description_;
}
};
///////////////////////////////////////////////////////////////////////////////////////////////////
//
// Conv2d library operation class for cutlass profiler
//
///////////////////////////////////////////////////////////////////////////////////////////////////
template <typename Operator_>
class Conv2dOperation : public Conv2dOperationBase<Operator_> {
public:
using Operator = Operator_;
using ElementA = typename Operator::ElementA;
using LayoutA = typename Operator::LayoutA;
using ElementB = typename Operator::ElementB;
using LayoutB = typename Operator::LayoutB;
using ElementC = typename Operator::ElementC;
using LayoutC = typename Operator::LayoutC;
using ElementAccumulator = typename Operator::ElementAccumulator;
using ElementCompute = typename Operator::EpilogueOutputOp::ElementCompute;
static cutlass::conv::Operator const kConvolutionalOperator = Operator::kConvolutionalOperator;
using OperatorArguments = typename Operator::Arguments;
public:
/// Constructor
Conv2dOperation(char const *name = "unknown_conv2d_fprop") : Conv2dOperationBase<Operator_>(name) {
this->description_.conv_kind = ConvKindMap<kConvolutionalOperator>::kId;
}
protected:
/// Constructs the arguments structure given the configuration and arguments
static Status construct_arguments_(
OperatorArguments &operator_args,
Conv2dConfiguration const *configuration) {
operator_args.problem_size = configuration->problem_size;
operator_args.ref_A =
{
nullptr,
LayoutA::packed(implicit_gemm_tensor_a_extent(kConvolutionalOperator, configuration->problem_size))
};
operator_args.ref_B =
{
nullptr,
LayoutB::packed(implicit_gemm_tensor_b_extent(kConvolutionalOperator, configuration->problem_size))
};
operator_args.ref_C =
{
nullptr,
LayoutC::packed(implicit_gemm_tensor_c_extent(kConvolutionalOperator, configuration->problem_size))
};
operator_args.ref_D =
{
nullptr,
LayoutC::packed(implicit_gemm_tensor_c_extent(kConvolutionalOperator, configuration->problem_size))
};
operator_args.split_k_mode = configuration->split_k_mode;
return Status::kSuccess;
}
/// Constructs the arguments structure given the configuration and arguments
static Status update_arguments_(
OperatorArguments &operator_args,
ConvArguments const *arguments) {
if (arguments->pointer_mode == ScalarPointerMode::kHost) {
typename Operator::EpilogueOutputOp::Params params(
*static_cast<ElementCompute const *>(arguments->alpha),
*static_cast<ElementCompute const *>(arguments->beta)
);
operator_args.output_op = params;
}
else if (arguments->pointer_mode == ScalarPointerMode::kDevice){
typename Operator::EpilogueOutputOp::Params params(
static_cast<ElementCompute const *>(arguments->alpha),
static_cast<ElementCompute const *>(arguments->beta)
);
operator_args.output_op = params;
}
else {
return Status::kErrorInvalidProblem;
}
operator_args.ref_A.reset(static_cast<ElementA *>(const_cast<void *>(arguments->A)));
operator_args.ref_B.reset(static_cast<ElementB *>(const_cast<void *>(arguments->B)));
operator_args.ref_C.reset(static_cast<ElementC *>(const_cast<void *>(arguments->C)));
operator_args.ref_D.reset(static_cast<ElementC *>(const_cast<void *>(arguments->D)));
if (arguments->use_pdl) {
return Status::kErrorNotSupported;
}
return Status::kSuccess;
}
public:
/// Returns success if the operation can proceed
virtual Status can_implement(
void const *configuration_ptr,
void const *arguments_ptr) const {
Conv2dConfiguration const *configuration =
static_cast<Conv2dConfiguration const *>(configuration_ptr);
ConvArguments const *arguments =
static_cast<ConvArguments const *>(arguments_ptr);
OperatorArguments args;
Status status = construct_arguments_(args, configuration);
if (status != Status::kSuccess) {
return status;
}
status = update_arguments_(args, arguments);
if (status != Status::kSuccess) {
return status;
}
return Operator::can_implement(args);
}
/// Gets the host-side workspace
virtual uint64_t get_host_workspace_size(
void const *configuration) const {
return sizeof(Operator);
}
/// Gets the device-side workspace
virtual uint64_t get_device_workspace_size(
void const *configuration_ptr,
void const *arguments_ptr = nullptr) const {
OperatorArguments args;
Status status = construct_arguments_(
args,
static_cast<Conv2dConfiguration const *>(configuration_ptr));
if (status != Status::kSuccess) {
return 0;
}
return Operator::get_workspace_size(args);
}
/// Initializes the workspace
virtual Status initialize(
void const *configuration_ptr,
void *host_workspace,
void *device_workspace,
cudaStream_t stream = nullptr) const {
OperatorArguments args;
Status status = construct_arguments_(
args,
static_cast<Conv2dConfiguration const *>(configuration_ptr));
if (status != Status::kSuccess) {
return status;
}
Operator *op = new (host_workspace) Operator;
//std::cout << "initialize library::Conv2dOperation" << std::endl;
//print_operator_args(args);
return op->initialize(args, device_workspace, stream);
}
/// Runs the kernel
virtual Status run(
void const *arguments_ptr,
void *host_workspace,
void *device_workspace = nullptr,
cudaStream_t stream = nullptr) const {
OperatorArguments args;
Status status = update_arguments_(
args,
static_cast<ConvArguments const *>(arguments_ptr));
if (status != Status::kSuccess) {
return status;
}
Operator *op = static_cast<Operator *>(host_workspace);
status = op->update(args, device_workspace);
if (status != Status::kSuccess) {
return status;
}
//std::cout << "run library::Conv2dOperation" << std::endl;
//print_operator_args(args);
return op->run(stream);
}
/// Call print_operator_args from the Conv2dOperation::initialize()
// to dump arguments passed on to cutlass operator for debugging
void print_operator_args(OperatorArguments &operator_args) const {
std::cout << "Conv2dOperation::OperatorArguments" << std::endl
<< " problem_size:" << std::endl
<< operator_args.problem_size << std::endl
<< " split_k_mode: "
<< (operator_args.split_k_mode == cutlass::conv::SplitKMode::kSerial ? "serial" : "parallel") << std::endl
<< " epilogue (alpha, beta): "
<< operator_args.output_op.alpha << ", "
<< operator_args.output_op.beta << std::endl
<< " ref_A (ptr, {stride}): "
<< operator_args.ref_A.data() << ", {"
<< operator_args.ref_A.stride(0) << ", "
<< operator_args.ref_A.stride(1) << ", "
<< operator_args.ref_A.stride(2) << "}" << std::endl
<< " ref_B (ptr, {stride}): "
<< operator_args.ref_B.data() << ", {"
<< operator_args.ref_B.stride(0) << ", "
<< operator_args.ref_B.stride(1) << ", "
<< operator_args.ref_B.stride(2) << "}" << std::endl
<< " ref_C (ptr, {stride}): "
<< operator_args.ref_C.data() << ", {"
<< operator_args.ref_C.stride(0) << ", "
<< operator_args.ref_C.stride(1) << ", "
<< operator_args.ref_C.stride(2) << "}" << std::endl
<< " ref_D (ptr, {stride}): "
<< operator_args.ref_D.data() << ", {"
<< operator_args.ref_D.stride(0) << ", "
<< operator_args.ref_D.stride(1) << ", "
<< operator_args.ref_D.stride(2) << "}" << std::endl;
}
};
///////////////////////////////////////////////////////////////////////////////////////////////////
//
// DirectConv2d library operation class for cutlass profiler
//
///////////////////////////////////////////////////////////////////////////////////////////////////
template <typename Operator_>
class DirectConv2dOperation : public Conv2dOperation<Operator_> {
public:
using Operator = Operator_;
using Base = Conv2dOperation<Operator_>;
using ElementA = typename Operator::ElementA;
using LayoutA = typename Operator::LayoutA;
using ElementB = typename Operator::ElementB;
using LayoutB = typename Operator::LayoutB;
using ElementC = typename Operator::ElementC;
using LayoutC = typename Operator::LayoutC;
using ElementAccumulator = typename Operator::ElementAccumulator;
using ElementCompute = typename Operator::EpilogueOutputOp::ElementCompute;
static cutlass::conv::Operator const kConvolutionalOperator = Operator::kConvolutionalOperator;
using OperatorArguments = typename Operator::Arguments;
public:
/// Constructor
DirectConv2dOperation(char const *name = "unknown_direct)conv2d_fprop") : Conv2dOperation<Operator_>(name) {
this->description_.conv_kind = ConvKindMap<kConvolutionalOperator>::kId;
}
protected:
/// Constructs the arguments structure given the configuration and arguments
static Status construct_arguments_(
OperatorArguments &operator_args,
Conv2dConfiguration const *configuration) {
operator_args.problem_size = configuration->problem_size;
operator_args.ref_A =
{
nullptr,
LayoutA::packed(implicit_gemm_tensor_a_extent(kConvolutionalOperator, configuration->problem_size))
};
operator_args.ref_B =
{
nullptr,
LayoutB::packed(implicit_gemm_tensor_b_extent(kConvolutionalOperator, configuration->problem_size))
};
operator_args.ref_reordered_B =
{
nullptr,
LayoutB::packed(implicit_gemm_tensor_b_extent(kConvolutionalOperator, configuration->problem_size))
};
operator_args.ref_C =
{
nullptr,
LayoutC::packed(implicit_gemm_tensor_c_extent(kConvolutionalOperator, configuration->problem_size))
};
operator_args.ref_D =
{
nullptr,
LayoutC::packed(implicit_gemm_tensor_c_extent(kConvolutionalOperator, configuration->problem_size))
};
operator_args.split_k_mode = configuration->split_k_mode;
return Status::kSuccess;
}
/// Constructs the arguments structure given the configuration and arguments
static Status update_arguments_(
OperatorArguments &operator_args,
ConvArguments const *arguments) {
if (arguments->pointer_mode == ScalarPointerMode::kHost) {
typename Operator::EpilogueOutputOp::Params params(
*static_cast<ElementCompute const *>(arguments->alpha),
*static_cast<ElementCompute const *>(arguments->beta)
);
operator_args.output_op = params;
}
else if (arguments->pointer_mode == ScalarPointerMode::kDevice){
typename Operator::EpilogueOutputOp::Params params(
static_cast<ElementCompute const *>(arguments->alpha),
static_cast<ElementCompute const *>(arguments->beta)
);
operator_args.output_op = params;
}
else {
return Status::kErrorInvalidProblem;
}
operator_args.ref_A.reset(static_cast<ElementA *>(const_cast<void *>(arguments->A)));
operator_args.ref_B.reset(static_cast<ElementB *>(const_cast<void *>(arguments->B)));
operator_args.ref_C.reset(static_cast<ElementC *>(const_cast<void *>(arguments->C)));
operator_args.ref_D.reset(static_cast<ElementC *>(const_cast<void *>(arguments->D)));
operator_args.ref_reordered_B.reset(static_cast<ElementC *>(const_cast<void *>(arguments->reordered_B)));
if (arguments->use_pdl) {
return Status::kErrorNotSupported;
}
return Status::kSuccess;
}
public:
/// Returns success if the operation can proceed
virtual Status can_implement(
void const *configuration_ptr,
void const *arguments_ptr) const {
Conv2dConfiguration const *configuration =
static_cast<Conv2dConfiguration const *>(configuration_ptr);
ConvArguments const *arguments =
static_cast<ConvArguments const *>(arguments_ptr);
OperatorArguments args;
Status status = construct_arguments_(args, configuration);
if (status != Status::kSuccess) {
return status;
}
status = update_arguments_(args, arguments);
if (status != Status::kSuccess) {
return status;
}
return Operator::can_implement(args);
}
/// Gets the host-side workspace
virtual uint64_t get_host_workspace_size(
void const *configuration) const {
return sizeof(Operator);
}
/// Gets the device-side workspace
virtual uint64_t get_device_workspace_size(
void const *configuration_ptr,
void const *arguments_ptr = nullptr) const {
OperatorArguments args;
Status status = construct_arguments_(
args,
static_cast<Conv2dConfiguration const *>(configuration_ptr));
if (status != Status::kSuccess) {
return 0;
}
return Operator::get_workspace_size(args);
}
/// Initializes the workspace
virtual Status initialize(
void const *configuration_ptr,
void *host_workspace,
void *device_workspace,
cudaStream_t stream = nullptr) const {
OperatorArguments args;
Status status = construct_arguments_(
args,
static_cast<Conv2dConfiguration const *>(configuration_ptr));
if (status != Status::kSuccess) {
return status;
}
Operator *op = new (host_workspace) Operator;
//std::cout << "initialize library::Conv2dOperation" << std::endl;
//print_operator_args(args);
return op->initialize(args, device_workspace, stream);
}
/// Runs the kernel
virtual Status run(
void const *arguments_ptr,
void *host_workspace,
void *device_workspace = nullptr,
cudaStream_t stream = nullptr) const {
OperatorArguments args;
Status status = update_arguments_(
args,
static_cast<ConvArguments const *>(arguments_ptr));
if (status != Status::kSuccess) {
return status;
}
Operator *op = static_cast<Operator *>(host_workspace);
status = op->update(args, device_workspace);
if (status != Status::kSuccess) {
return status;
}
//std::cout << "run library::Conv2dOperation" << std::endl;
//print_operator_args(args);
return op->run(stream);
}
/// Call print_operator_args from the Conv2dOperation::initialize()
// to dump arguments passed on to cutlass operator for debugging
void print_operator_args(OperatorArguments &operator_args) const {
std::cout << "Conv2dOperation::OperatorArguments" << std::endl
<< " problem_size:" << std::endl
<< operator_args.problem_size << std::endl
<< " split_k_mode: "
<< (operator_args.split_k_mode == cutlass::conv::SplitKMode::kSerial ? "serial" : "parallel") << std::endl
<< " epilogue (alpha, beta): "
<< operator_args.output_op.alpha << ", "
<< operator_args.output_op.beta << std::endl
<< " ref_A (ptr, {stride}): "
<< operator_args.ref_A.data() << ", {"
<< operator_args.ref_A.stride(0) << ", "
<< operator_args.ref_A.stride(1) << ", "
<< operator_args.ref_A.stride(2) << "}" << std::endl
<< " ref_B (ptr, {stride}): "
<< operator_args.ref_B.data() << ", {"
<< operator_args.ref_B.stride(0) << ", "
<< operator_args.ref_B.stride(1) << ", "
<< operator_args.ref_B.stride(2) << "}" << std::endl
<< " ref_C (ptr, {stride}): "
<< operator_args.ref_C.data() << ", {"
<< operator_args.ref_C.stride(0) << ", "
<< operator_args.ref_C.stride(1) << ", "
<< operator_args.ref_C.stride(2) << "}" << std::endl
<< " ref_D (ptr, {stride}): "
<< operator_args.ref_D.data() << ", {"
<< operator_args.ref_D.stride(0) << ", "
<< operator_args.ref_D.stride(1) << ", "
<< operator_args.ref_D.stride(2) << "}" << std::endl;
}
};
} // namespace library
} // namespace cutlass
///////////////////////////////////////////////////////////////////////////////////////////////////