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review.mlplatform.org / ml / ComputeLibrary / 37f4b2ef1ea225a90ccb563fcb2c08f8fb0fb5d5 / . / src / runtime / CL / functions / CLGEMM.cpp
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/*
* Copyright (c) 2017-2021 Arm Limited.
*
* SPDX-License-Identifier: MIT
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to
* deal in the Software without restriction, including without limitation the
* rights to use, copy, modify, merge, publish, distribute, sublicense, and/or
* sell copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in all
* copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
* SOFTWARE.
*/
#include "arm_compute/runtime/CL/functions/CLGEMM.h"
#include "arm_compute/core/CL/CLKernelLibrary.h"
#include "arm_compute/core/CL/ICLTensor.h"
#include "arm_compute/core/Error.h"
#include "arm_compute/core/GPUTarget.h"
#include "arm_compute/core/Helpers.h"
#include "arm_compute/core/KernelDescriptors.h"
#include "arm_compute/core/Log.h"
#include "arm_compute/core/TensorInfo.h"
#include "arm_compute/core/Types.h"
#include "arm_compute/core/Utils.h"
#include "arm_compute/core/Validate.h"
#include "arm_compute/core/utils/misc/ShapeCalculator.h"
#include "arm_compute/runtime/CL/CLScheduler.h"
#include "arm_compute/runtime/ITensorAllocator.h"
#include "src/core/CL/kernels/CLGEMMMatrixMultiplyKernel.h"
#include "src/core/CL/kernels/CLGEMMMatrixMultiplyReshapedKernel.h"
#include "src/core/CL/kernels/CLGEMMMatrixMultiplyReshapedOnlyRHSKernel.h"
#include "src/core/CL/kernels/CLGEMMReshapeLHSMatrixKernel.h"
#include "src/core/CL/kernels/CLGEMMReshapeRHSMatrixKernel.h"
#include "src/core/helpers/AutoConfiguration.h"
#include "src/core/utils/helpers/float_ops.h"
#include "src/runtime/CL/gemm/CLGEMMKernelSelection.h"
#include "src/runtime/CL/gemm_auto_heuristics/CLGEMMAutoHeuristics.h"
#include "support/Cast.h"
#include "utils/TypePrinter.h"
namespace arm_compute
{
using namespace arm_compute::misc::shape_calculator;
using namespace arm_compute::cl_gemm;
using namespace arm_compute::utils::cast;
namespace weights_transformations
{
CLGEMMReshapeRHSMatrixKernelManaged::CLGEMMReshapeRHSMatrixKernelManaged()
: _kernel(std::make_unique<CLGEMMReshapeRHSMatrixKernel>())
{
}
CLGEMMReshapeRHSMatrixKernelManaged::~CLGEMMReshapeRHSMatrixKernelManaged() = default;
void CLGEMMReshapeRHSMatrixKernelManaged::run()
{
_output.allocator()->allocate();
CLScheduler::get().enqueue(*_kernel, false);
_reshape_run = true;
}
void CLGEMMReshapeRHSMatrixKernelManaged::release()
{
_output.allocator()->free();
}
ICLTensor *CLGEMMReshapeRHSMatrixKernelManaged::get_weights()
{
return &_output;
}
uint32_t CLGEMMReshapeRHSMatrixKernelManaged::uid()
{
return _uid;
}
void CLGEMMReshapeRHSMatrixKernelManaged::configure(const ICLTensor *input, GEMMRHSMatrixInfo info)
{
configure(CLKernelLibrary::get().get_compile_context(), input, info);
}
void CLGEMMReshapeRHSMatrixKernelManaged::configure(const CLCompileContext &compile_context, const ICLTensor *input, GEMMRHSMatrixInfo info)
{
_kernel->configure(compile_context, input, &_output, info);
}
} // namespace weights_transformations
namespace
{
inline bool validate_gemm_kernel(CLGEMMKernelType kernel_type)
{
switch(kernel_type)
{
case CLGEMMKernelType::NATIVE_V1:
case CLGEMMKernelType::RESHAPED_ONLY_RHS:
case CLGEMMKernelType::RESHAPED_V1:
case CLGEMMKernelType::RESHAPED:
{
return true;
}
default:
{
return false;
}
}
}
//Automatically select between mlgo (prioritized) and default heuristics for gemm kernel type
inline CLGEMMKernelType auto_select_gemm_kernel(auto_heuristics::CommonQuery query, bool reshape_b_only_on_first_run)
{
auto gemm_kernel = auto_heuristics::select_mlgo_gemm_kernel(query, reshape_b_only_on_first_run);
if(bool(gemm_kernel))
{
if(validate_gemm_kernel(gemm_kernel.gemm_type))
{
ARM_COMPUTE_LOG_INFO_MSG_WITH_FORMAT_CORE("Use gemm kernel from mlgo heuristics: %s.", to_string(gemm_kernel.gemm_type).c_str());
return gemm_kernel.gemm_type;
}
}
gemm_kernel = auto_heuristics::select_default_gemm_kernel(query, reshape_b_only_on_first_run);
ARM_COMPUTE_LOG_INFO_MSG_WITH_FORMAT_CORE("Use gemm kernel from default heuristics: %s.", to_string(gemm_kernel.gemm_type).c_str());
return gemm_kernel.gemm_type;
}
// Validate lhs_info and rhs_info for reshaped only rhs kernel
inline bool validate_lhs_rhs_info_reshaped_only_rhs(const GEMMLHSMatrixInfo &lhs_info, const GEMMRHSMatrixInfo &rhs_info, const ITensorInfo *a, const ITensorInfo *b, const ITensorInfo *c,
const ITensorInfo *output, GEMMKernelInfo gemm_kernel_info)
{
// Validate GEMMLHSMatrixInfo and GEMMRHSMatrixInfo for reshaped only rhs kernel
TensorInfo tmp_b_info{};
// Validate reshape RHS kernel
auto_init_if_empty(tmp_b_info, b->clone()->set_tensor_shape(compute_rhs_reshaped_shape(*b, rhs_info)));
if(!bool(CLGEMMReshapeRHSMatrixKernel::validate(b, &tmp_b_info, rhs_info)))
{
return false;
}
// Validate mm kernel
gemm_kernel_info.lhs_info = lhs_info;
gemm_kernel_info.rhs_info = rhs_info;
gemm_kernel_info.has_pad_y = false;
if(!bool(CLGEMMMatrixMultiplyReshapedOnlyRHSKernel::validate(a, &tmp_b_info, c, output, 1.f, 0.f, lhs_info, rhs_info, gemm_kernel_info)))
{
return false;
}
gemm_kernel_info.has_pad_y = true;
if(!bool(CLGEMMMatrixMultiplyReshapedOnlyRHSKernel::validate(a, &tmp_b_info, c, output, 1.f, 0.f, lhs_info, rhs_info, gemm_kernel_info)))
{
return false;
}
return true;
}
//Automatically select between mlgo (prioritized) and default heuristics for reshaped only rhs kernel configs
inline std::pair<GEMMLHSMatrixInfo, GEMMRHSMatrixInfo> auto_select_gemm_config_reshaped_only_rhs(auto_heuristics::CommonQuery query, GEMMKernelInfo kernel_info, const ITensorInfo *a,
const ITensorInfo *b,
const ITensorInfo *c, const ITensorInfo *output)
{
auto config = auto_heuristics::select_mlgo_gemm_config_reshaped_only_rhs(query);
if(config)
{
if(validate_lhs_rhs_info_reshaped_only_rhs(config.lhs_info, config.rhs_info, a, b, c, output, kernel_info))
{
ARM_COMPUTE_LOG_INFO_MSG_WITH_FORMAT_CORE("Use reshaped_only_rhs config from mlgo heuristics: LHS info: %s ; RHS info: %s ", to_string(config.lhs_info).c_str(), to_string(config.rhs_info).c_str());
return { config.lhs_info, config.rhs_info };
}
}
config = auto_heuristics::select_default_gemm_config_reshaped_only_rhs(query);
ARM_COMPUTE_LOG_INFO_MSG_WITH_FORMAT_CORE("Use reshaped_only_rhs config from default heuristics: LHS info: %s ; RHS info: %s ", to_string(config.lhs_info).c_str(), to_string(config.rhs_info).c_str());
return { config.lhs_info, config.rhs_info };
}
// Validate lhs_info and rhs_info for reshaped kernel
inline bool validate_lhs_rhs_info_reshaped(const GEMMLHSMatrixInfo &lhs_info, const GEMMRHSMatrixInfo &rhs_info, const ITensorInfo *a, const ITensorInfo *b, const ITensorInfo *c,
const ITensorInfo *output, GEMMKernelInfo gemm_kernel_info, bool reinterpret_input_as_3d)
{
// Validate GEMMLHSMatrixInfo and GEMMRHSMatrixInfo for reshaped kernel
TensorInfo tmp_a_info{};
TensorInfo tmp_b_info{};
// Validate reshape LHS kernel
auto_init_if_empty(tmp_a_info, a->clone()->set_tensor_shape(compute_lhs_reshaped_shape(*a, lhs_info, reinterpret_input_as_3d)));
if(!bool(CLGEMMReshapeLHSMatrixKernel::validate(a, &tmp_a_info, lhs_info, reinterpret_input_as_3d)))
{
return false;
}
// Validate reshape RHS kernel
auto_init_if_empty(tmp_b_info, b->clone()->set_tensor_shape(compute_rhs_reshaped_shape(*b, rhs_info)));
if(!bool(CLGEMMReshapeRHSMatrixKernel::validate(b, &tmp_b_info, rhs_info)))
{
return false;
}
// Validate mm kernel
gemm_kernel_info.lhs_info = lhs_info;
gemm_kernel_info.rhs_info = rhs_info;
if(!bool(CLGEMMMatrixMultiplyReshapedKernel::validate(&tmp_a_info, &tmp_b_info, c, output, 1.f, 0.f, lhs_info, rhs_info, gemm_kernel_info)))
{
return false;
}
return true;
}
//Automatically select between mlgo (prioritized) and default heuristics for reshaped kernel configs
inline std::pair<GEMMLHSMatrixInfo, GEMMRHSMatrixInfo> auto_select_gemm_config_reshaped(auto_heuristics::CommonQuery query, GEMMKernelInfo kernel_info, const ITensorInfo *a, const ITensorInfo *b,
const ITensorInfo *c, const ITensorInfo *output, bool reinterpret_input_as_3d)
{
auto config = auto_heuristics::select_mlgo_gemm_config_reshaped(query);
if(config)
{
if(validate_lhs_rhs_info_reshaped(config.lhs_info, config.rhs_info, a, b, c, output, kernel_info, reinterpret_input_as_3d))
{
ARM_COMPUTE_LOG_INFO_MSG_WITH_FORMAT_CORE("Use reshaped config from mlgo heuristics: LHS info: %s ; RHS info: %s ", to_string(config.lhs_info).c_str(), to_string(config.rhs_info).c_str());
return { config.lhs_info, config.rhs_info };
}
}
config = auto_heuristics::select_default_gemm_config_reshaped(query);
ARM_COMPUTE_LOG_INFO_MSG_WITH_FORMAT_CORE("Use reshaped config from default heuristics: LHS info: %s ; RHS info: %s ", to_string(config.lhs_info).c_str(), to_string(config.rhs_info).c_str());
return { config.lhs_info, config.rhs_info };
}
} // namespace
CLGEMM::CLGEMM(std::shared_ptr<IMemoryManager> memory_manager, IWeightsManager *weights_manager)
: _memory_group(std::move(memory_manager)),
_weights_manager(weights_manager),
_mm_kernel(std::make_unique<CLGEMMMatrixMultiplyKernel>()),
_reshape_lhs_kernel(std::make_unique<CLGEMMReshapeLHSMatrixKernel>()),
_reshape_rhs_kernel(std::make_unique<CLGEMMReshapeRHSMatrixKernel>()),
_reshape_rhs_kernel_managed(std::make_unique<weights_transformations::CLGEMMReshapeRHSMatrixKernelManaged>()),
_mm_reshaped_kernel(std::make_unique<CLGEMMMatrixMultiplyReshapedKernel>()),
_mm_reshaped_only_rhs_kernel(std::make_unique<CLGEMMMatrixMultiplyReshapedOnlyRHSKernel>()),
_mm_reshaped_only_rhs_fallback_kernel(std::make_unique<CLGEMMMatrixMultiplyReshapedOnlyRHSKernel>()),
_tmp_a(),
_tmp_b(),
_original_b(nullptr),
_lhs(nullptr),
_dst(nullptr),
_reshape_b_only_on_first_run(false),
_is_prepared(false),
_gemm_kernel_type(CLGEMMKernelType::NATIVE_V1)
{
}
CLGEMM::~CLGEMM() = default;
void CLGEMM::configure_native_v1(const CLCompileContext &compile_context, const ICLTensor *a, const ICLTensor *b, const ICLTensor *c, ICLTensor *output, float alpha, float beta,
const GEMMInfo &gemm_info)
{
const unsigned int m = gemm_info.reinterpret_input_as_3d() ? (a->info()->dimension(1) * a->info()->dimension(2)) : a->info()->dimension(1);
const unsigned int n = b->info()->dimension(0);
const unsigned int k = a->info()->dimension(0);
const GPUTarget gpu_target = CLScheduler::get().target();
// Set the target for the kernels
_mm_kernel->set_target(gpu_target);
GEMMReshapeInfo reshape_info(m, n, k, 1, 1, gemm_info.depth_output_gemm3d(), gemm_info.reinterpret_input_as_3d(), gemm_info.broadcast_bias());
// Configure and tune matrix multiply kernel
_mm_kernel->configure(compile_context, a, b, c, output, alpha, beta, false, reshape_info, gemm_info.fp_mixed_precision(), gemm_info.activation_info());
// Tune kernel statically
CLScheduler::get().tune_kernel_static(*_mm_kernel);
}
void CLGEMM::configure_reshaped_v1(const CLCompileContext &compile_context, const ICLTensor *a, const ICLTensor *b, const ICLTensor *c, ICLTensor *output, float alpha, float beta,
const GEMMInfo &gemm_info)
{
bool reinterpret_input_as_3d = gemm_info.reinterpret_input_as_3d();
const unsigned int m = reinterpret_input_as_3d ? (a->info()->dimension(1) * a->info()->dimension(2)) : a->info()->dimension(1);
const unsigned int n = b->info()->dimension(0);
const unsigned int k = a->info()->dimension(0);
const int depth_output_gemm3d = gemm_info.depth_output_gemm3d();
const GPUTarget gpu_target = CLScheduler::get().target();
int mult_transpose1xW_width = 1;
int mult_interleave4x4_height = 1;
// Set the target for the kernels
_reshape_lhs_kernel->set_target(gpu_target);
_mm_kernel->set_target(gpu_target);
if(get_arch_from_target(gpu_target) == GPUTarget::BIFROST)
{
mult_transpose1xW_width = 4;
mult_interleave4x4_height = 2;
}
GEMMRHSMatrixInfo rhs_info;
rhs_info.n0 = 16 / b->info()->element_size();
rhs_info.k0 = 1;
rhs_info.h0 = mult_transpose1xW_width;
rhs_info.interleave = false;
rhs_info.transpose = false;
GEMMLHSMatrixInfo lhs_info;
lhs_info.m0 = 4;
lhs_info.k0 = 4;
lhs_info.v0 = mult_interleave4x4_height;
lhs_info.interleave = true;
lhs_info.transpose = true;
GEMMReshapeInfo reshape_info(m, n, k, mult_transpose1xW_width, mult_interleave4x4_height, depth_output_gemm3d, false, gemm_info.broadcast_bias());
const bool use_mm_b = (!_weights_manager || !_weights_manager->are_weights_managed(b));
// Manage intermediate buffers
_memory_group.manage(&_tmp_a);
if(!_reshape_b_only_on_first_run && use_mm_b)
{
_memory_group.manage(&_tmp_b);
}
// Configure interleave kernel
_reshape_lhs_kernel->configure(compile_context, a, &_tmp_a, lhs_info, reinterpret_input_as_3d);
// Configure transpose kernel
ICLTensor *reshaped_rhs = &_tmp_b;
if(_weights_manager && _weights_manager->are_weights_managed(b))
{
_reshape_rhs_kernel_managed->configure(compile_context, b, rhs_info);
reshaped_rhs = utils::cast::polymorphic_downcast<ICLTensor *>(_weights_manager->acquire(b, _reshape_rhs_kernel_managed.get()));
}
else
{
_reshape_rhs_kernel->configure(compile_context, b, &_tmp_b, rhs_info);
}
// Configure and tune matrix multiply kernel
_mm_kernel->configure(compile_context, &_tmp_a, reshaped_rhs, c, output, alpha, beta, true, reshape_info, gemm_info.fp_mixed_precision(), gemm_info.activation_info());
CLScheduler::get().tune_kernel_static(*_mm_kernel);
// Allocate intermediate tensors
_tmp_a.allocator()->allocate();
if(!_reshape_b_only_on_first_run && use_mm_b)
{
_tmp_b.allocator()->allocate();
}
}
void CLGEMM::configure_reshaped_v2(const CLCompileContext &compile_context, const ICLTensor *a, const ICLTensor *b, const ICLTensor *c, ICLTensor *output, float alpha, float beta,
const GEMMInfo &gemm_info)
{
DataType data_type = a->info()->data_type();
bool reinterpret_input_as_3d = gemm_info.reinterpret_input_as_3d();
const unsigned int m = reinterpret_input_as_3d ? (a->info()->dimension(1) * a->info()->dimension(2)) : a->info()->dimension(1);
const unsigned int n = b->info()->dimension(0);
const unsigned int k = a->info()->dimension(0);
const unsigned int batch_size = reinterpret_input_as_3d ? a->info()->dimension(3) : a->info()->dimension(2);
const int depth_output_gemm3d = gemm_info.depth_output_gemm3d();
const GPUTarget gpu_target = CLScheduler::get().target();
bool broadcast_bias = gemm_info.broadcast_bias();
GEMMKernelInfo kernel_info;
kernel_info.m = m;
kernel_info.n = n;
kernel_info.k = k;
kernel_info.depth_output_gemm3d = depth_output_gemm3d;
kernel_info.reinterpret_input_as_3d = false;
kernel_info.broadcast_bias = broadcast_bias;
kernel_info.activation_info = gemm_info.activation_info();
// Set the target for the kernels
_reshape_lhs_kernel->set_target(gpu_target);
_mm_kernel->set_target(gpu_target);
const bool use_mm_b = (!_weights_manager || !_weights_manager->are_weights_managed(b));
// Manage intermediate buffers
_memory_group.manage(&_tmp_a);
if(!_reshape_b_only_on_first_run && use_mm_b)
{
_memory_group.manage(&_tmp_b);
}
// _tmp_a and _tmp_b will be auto configured in _interleave_kernel and in _transpose_kernel
GEMMLHSMatrixInfo lhs_info{};
GEMMRHSMatrixInfo rhs_info{};
// Pick up the GEMM configuration
std::tie(lhs_info, rhs_info) = auto_select_gemm_config_reshaped(auto_heuristics::CommonQuery{ gpu_target, data_type, m, n, k, batch_size }, kernel_info, a->info(), b->info(),
c == nullptr ? nullptr : c->info(), output->info(), gemm_info.reinterpret_input_as_3d());
_reshape_lhs_kernel->configure(compile_context, a, &_tmp_a, lhs_info, gemm_info.reinterpret_input_as_3d());
ICLTensor *reshaped_rhs = &_tmp_b;
if(_weights_manager && _weights_manager->are_weights_managed(b))
{
_reshape_rhs_kernel_managed->configure(compile_context, b, rhs_info);
reshaped_rhs = utils::cast::polymorphic_downcast<ICLTensor *>(_weights_manager->acquire(b, _reshape_rhs_kernel_managed.get()));
}
else
{
_reshape_rhs_kernel->configure(compile_context, b, &_tmp_b, rhs_info);
}
// Configure and tune matrix multiply kernel
_mm_reshaped_kernel->configure(compile_context, &_tmp_a, reshaped_rhs, c, output, alpha, beta, lhs_info, rhs_info, kernel_info);
// Allocate intermediate tensors
_tmp_a.allocator()->allocate();
if(!_reshape_b_only_on_first_run && use_mm_b)
{
_tmp_b.allocator()->allocate();
}
}
void CLGEMM::configure_reshaped_only_rhs(const CLCompileContext &compile_context, const ICLTensor *a, const ICLTensor *b, const ICLTensor *c, ICLTensor *output, float alpha, float beta,
const GEMMInfo &gemm_info)
{
DataType data_type = a->info()->data_type();
bool reinterpret_input_as_3d = gemm_info.reinterpret_input_as_3d();
const unsigned int m = reinterpret_input_as_3d ? (a->info()->dimension(1) * a->info()->dimension(2)) : a->info()->dimension(1);
const unsigned int n = b->info()->dimension(0);
const unsigned int k = a->info()->dimension(0);
const unsigned int batch_size = reinterpret_input_as_3d ? a->info()->dimension(3) : a->info()->dimension(2);
const int depth_output_gemm3d = gemm_info.depth_output_gemm3d();
const GPUTarget gpu_target = CLScheduler::get().target();
bool broadcast_bias = gemm_info.broadcast_bias();
GEMMKernelInfo kernel_info;
kernel_info.m = m;
kernel_info.n = n;
kernel_info.k = k;
kernel_info.depth_output_gemm3d = depth_output_gemm3d;
kernel_info.reinterpret_input_as_3d = reinterpret_input_as_3d;
kernel_info.broadcast_bias = broadcast_bias;
kernel_info.activation_info = gemm_info.activation_info();
// Set the target for the kernels
_mm_kernel->set_target(gpu_target);
const bool use_mm_b = (!_weights_manager || !_weights_manager->are_weights_managed(b));
// Manage intermediate buffers
if(!_reshape_b_only_on_first_run && use_mm_b)
{
_memory_group.manage(&_tmp_b);
}
GEMMLHSMatrixInfo lhs_info{};
GEMMRHSMatrixInfo rhs_info{};
// Pick up the GEMM configuration
std::tie(lhs_info, rhs_info) = auto_select_gemm_config_reshaped_only_rhs(auto_heuristics::CommonQuery{ gpu_target, data_type, m, n, k, batch_size }, kernel_info, a->info(), b->info(),
c == nullptr ? nullptr : c->info(), output->info());
ICLTensor *reshaped_rhs = &_tmp_b;
if(_weights_manager && _weights_manager->are_weights_managed(b))
{
_reshape_rhs_kernel_managed->configure(compile_context, b, rhs_info);
reshaped_rhs = utils::cast::polymorphic_downcast<ICLTensor *>(_weights_manager->acquire(b, _reshape_rhs_kernel_managed.get()));
}
else
{
_reshape_rhs_kernel->configure(compile_context, b, &_tmp_b, rhs_info);
}
// Configure two variants of CLGEMMMatrixMultiplyReshapedOnlyRHSKernel (has_pad_y = false/true)
// During the prepare stage we check the padding requirement for the lhs and dst tensors. If they do not have
// pad y, we dispatch CLGEMMMatrixMultiplyReshapedOnlyRHSKernel with has_pad_y = false
// Configure matrix multiply kernel with no y padding support
kernel_info.has_pad_y = false;
_mm_reshaped_only_rhs_kernel->configure(compile_context, a, reshaped_rhs, c, output, alpha, beta, lhs_info, rhs_info, kernel_info);
// Configure matrix multiply kernel with y padding support
kernel_info.has_pad_y = true;
_mm_reshaped_only_rhs_fallback_kernel->configure(compile_context, a, reshaped_rhs, c, output, alpha, beta, lhs_info, rhs_info, kernel_info);
if(!_reshape_b_only_on_first_run && use_mm_b)
{
_tmp_b.allocator()->allocate();
}
}
Status CLGEMM::validate_native_v1(const ITensorInfo *a, const ITensorInfo *b, const ITensorInfo *c, const ITensorInfo *output, float alpha, float beta, const GEMMInfo &gemm_info)
{
ARM_COMPUTE_UNUSED(alpha);
ARM_COMPUTE_UNUSED(output);
// Get the GPU target
const GPUTarget gpu_target = CLScheduler::get().target();
bool reinterpret_input_as_3d = gemm_info.reinterpret_input_as_3d();
const unsigned int m = reinterpret_input_as_3d ? (a->dimension(1) * a->dimension(2)) : a->dimension(1);
const unsigned int n = b->dimension(0);
const unsigned int k = a->dimension(0);
const int depth_output_gemm3d = gemm_info.depth_output_gemm3d();
const GEMMReshapeInfo reshape_info = GEMMReshapeInfo(m, n, k, 1, 1, depth_output_gemm3d, reinterpret_input_as_3d, gemm_info.broadcast_bias());
// Validate matrix multiply
ARM_COMPUTE_RETURN_ON_ERROR(CLGEMMMatrixMultiplyKernel::validate(a, b, c, output, alpha, beta,
false, reshape_info, gpu_target, gemm_info.fp_mixed_precision(), gemm_info.activation_info()));
return Status{};
}
Status CLGEMM::validate_reshaped_v1(const ITensorInfo *a, const ITensorInfo *b, const ITensorInfo *c, const ITensorInfo *output, float alpha, float beta, const GEMMInfo &gemm_info)
{
ARM_COMPUTE_UNUSED(alpha);
ARM_COMPUTE_UNUSED(output);
TensorInfo tmp_a_info{};
TensorInfo tmp_b_info{};
// Get the GPU target
const GPUTarget gpu_target = CLScheduler::get().target();
const unsigned int m = gemm_info.reinterpret_input_as_3d() ? (a->dimension(1) * a->dimension(2)) : a->dimension(1);
const unsigned int n = b->dimension(0);
const unsigned int k = a->dimension(0);
int mult_transpose1xW_width = 1;
int mult_interleave4x4_height = 1;
const int depth_output_gemm3d = gemm_info.depth_output_gemm3d();
if(get_arch_from_target(gpu_target) == GPUTarget::BIFROST)
{
mult_transpose1xW_width = 4;
mult_interleave4x4_height = 2;
}
GEMMRHSMatrixInfo rhs_info;
rhs_info.n0 = 16 / b->element_size();
rhs_info.k0 = 1;
rhs_info.h0 = mult_transpose1xW_width;
rhs_info.interleave = false;
rhs_info.transpose = false;
GEMMLHSMatrixInfo lhs_info;
lhs_info.m0 = 4;
lhs_info.k0 = 4;
lhs_info.v0 = mult_interleave4x4_height;
lhs_info.interleave = true;
lhs_info.transpose = true;
const GEMMReshapeInfo reshape_info = GEMMReshapeInfo(m, n, k, mult_transpose1xW_width, mult_interleave4x4_height, depth_output_gemm3d, false, gemm_info.broadcast_bias());
// Validate interleave kernel
auto_init_if_empty(tmp_a_info, a->clone()->set_tensor_shape(compute_lhs_reshaped_shape(*a, lhs_info, gemm_info.reinterpret_input_as_3d())));
ARM_COMPUTE_RETURN_ON_ERROR(CLGEMMReshapeLHSMatrixKernel::validate(a, &tmp_a_info, lhs_info, gemm_info.reinterpret_input_as_3d()));
// Validate transpose kernel
auto_init_if_empty(tmp_b_info, b->clone()->set_tensor_shape(compute_rhs_reshaped_shape(*b, rhs_info)));
ARM_COMPUTE_RETURN_ON_ERROR(CLGEMMReshapeRHSMatrixKernel::validate(b, &tmp_b_info, rhs_info));
// Validate matrix multiply
ARM_COMPUTE_RETURN_ON_ERROR(CLGEMMMatrixMultiplyKernel::validate(&tmp_a_info, &tmp_b_info, c, output, alpha, beta,
true, reshape_info, gpu_target, gemm_info.fp_mixed_precision(), gemm_info.activation_info()));
return Status{};
}
Status CLGEMM::validate_reshaped(const ITensorInfo *a, const ITensorInfo *b, const ITensorInfo *c, const ITensorInfo *output, float alpha, float beta, const GEMMInfo &gemm_info)
{
ARM_COMPUTE_UNUSED(alpha);
ARM_COMPUTE_UNUSED(output);
TensorInfo tmp_a_info{};
TensorInfo tmp_b_info{};
// Get the GPU target
const GPUTarget gpu_target = CLScheduler::get().target();
DataType data_type = a->data_type();
bool reinterpret_input_as_3d = gemm_info.reinterpret_input_as_3d();
const unsigned int m = reinterpret_input_as_3d ? (a->dimension(1) * a->dimension(2)) : a->dimension(1);
const unsigned int n = b->dimension(0);
const unsigned int k = a->dimension(0);
const unsigned int batch_size = reinterpret_input_as_3d ? a->dimension(3) : a->dimension(2);
const int depth_output_gemm3d = gemm_info.depth_output_gemm3d();
const bool broadcast_bias = gemm_info.broadcast_bias();
GEMMKernelInfo kernel_info;
kernel_info.m = m;
kernel_info.n = n;
kernel_info.k = k;
kernel_info.depth_output_gemm3d = depth_output_gemm3d;
kernel_info.reinterpret_input_as_3d = false;
kernel_info.broadcast_bias = broadcast_bias;
kernel_info.activation_info = gemm_info.activation_info();
GEMMLHSMatrixInfo lhs_info;
GEMMRHSMatrixInfo rhs_info;
// Pick up the GEMM configuration
// NOTE: No need to validate mlgo configurations as they automatically fall back to default heuristics if validation fails
const auto gemm_config = select_default_gemm_config_reshaped(auto_heuristics::CommonQuery{ gpu_target, data_type, m, n, k, batch_size });
lhs_info = gemm_config.lhs_info;
rhs_info = gemm_config.rhs_info;
auto_init_if_empty(tmp_a_info, a->clone()->set_tensor_shape(compute_lhs_reshaped_shape(*a, lhs_info, gemm_info.reinterpret_input_as_3d())));
ARM_COMPUTE_RETURN_ON_ERROR(CLGEMMReshapeLHSMatrixKernel::validate(a, &tmp_a_info, lhs_info, gemm_info.reinterpret_input_as_3d()));
auto_init_if_empty(tmp_b_info, b->clone()->set_tensor_shape(compute_rhs_reshaped_shape(*b, rhs_info)));
ARM_COMPUTE_RETURN_ON_ERROR(CLGEMMReshapeRHSMatrixKernel::validate(b, &tmp_b_info, rhs_info));
// Validate matrix multiply
ARM_COMPUTE_RETURN_ON_ERROR(CLGEMMMatrixMultiplyReshapedKernel::validate(&tmp_a_info, &tmp_b_info, c, output, alpha, beta, lhs_info, rhs_info, kernel_info));
return Status{};
}
Status CLGEMM::validate_reshaped_only_rhs(const ITensorInfo *a, const ITensorInfo *b, const ITensorInfo *c, const ITensorInfo *output, float alpha, float beta, const GEMMInfo &gemm_info)
{
ARM_COMPUTE_UNUSED(alpha);
ARM_COMPUTE_UNUSED(output);
TensorInfo tmp_b_info{};
// Get the GPU target
const GPUTarget gpu_target = CLScheduler::get().target();
const DataType data_type = a->data_type();
bool reinterpret_input_as_3d = gemm_info.reinterpret_input_as_3d();
const unsigned int m = reinterpret_input_as_3d ? (a->dimension(1) * a->dimension(2)) : a->dimension(1);
const unsigned int n = b->dimension(0);
const unsigned int k = a->dimension(0);
const unsigned int batch_size = reinterpret_input_as_3d ? a->dimension(3) : a->dimension(2);
const int depth_output_gemm3d = gemm_info.depth_output_gemm3d();
const bool broadcast_bias = gemm_info.broadcast_bias();
GEMMKernelInfo kernel_info;
kernel_info.m = m;
kernel_info.n = n;
kernel_info.k = k;
kernel_info.depth_output_gemm3d = depth_output_gemm3d;
kernel_info.reinterpret_input_as_3d = reinterpret_input_as_3d;
kernel_info.broadcast_bias = broadcast_bias;
kernel_info.activation_info = gemm_info.activation_info();
GEMMLHSMatrixInfo lhs_info;
GEMMRHSMatrixInfo rhs_info;
// Pick up the GEMM configuration
// NOTE: No need to validate mlgo configurations as they automatically fall back to default heuristics if validation fails
const auto gemm_config = select_default_gemm_config_reshaped_only_rhs(auto_heuristics::CommonQuery{ gpu_target, data_type, m, n, k, batch_size });
lhs_info = gemm_config.lhs_info;
rhs_info = gemm_config.rhs_info;
auto_init_if_empty(tmp_b_info, b->clone()->set_tensor_shape(compute_rhs_reshaped_shape(*b, rhs_info)));
ARM_COMPUTE_RETURN_ON_ERROR(CLGEMMReshapeRHSMatrixKernel::validate(b, &tmp_b_info, rhs_info));
// Validate matrix multiply
kernel_info.has_pad_y = false;
ARM_COMPUTE_RETURN_ON_ERROR(CLGEMMMatrixMultiplyReshapedOnlyRHSKernel::validate(a, &tmp_b_info, c, output, alpha, beta, lhs_info, rhs_info, kernel_info));
kernel_info.has_pad_y = true;
ARM_COMPUTE_RETURN_ON_ERROR(CLGEMMMatrixMultiplyReshapedOnlyRHSKernel::validate(a, &tmp_b_info, c, output, alpha, beta, lhs_info, rhs_info, kernel_info));
return Status{};
}
void CLGEMM::configure(const ICLTensor *a, const ICLTensor *b, const ICLTensor *c, ICLTensor *output, float alpha, float beta, const GEMMInfo &gemm_info)
{
configure(CLKernelLibrary::get().get_compile_context(), a, b, c, output, alpha, beta, gemm_info);
}
void CLGEMM::configure(const CLCompileContext &compile_context, const ICLTensor *a, const ICLTensor *b, const ICLTensor *c, ICLTensor *output, float alpha, float beta, const GEMMInfo &gemm_info)
{
ARM_COMPUTE_ERROR_ON_NULLPTR(a, b, output);
// Perform validation step
ARM_COMPUTE_ERROR_THROW_ON(validate(a->info(), b->info(), c != nullptr ? c->info() : nullptr, output->info(), alpha, beta, gemm_info));
// Check if we need to reshape the matrix B only on the first run
_reshape_b_only_on_first_run = gemm_info.reshape_b_only_on_first_run();
_is_prepared = gemm_info.retain_internal_weights();
_original_b = b;
_lhs = a;
_dst = output;
bool reinterpret_input_as_3d = gemm_info.reinterpret_input_as_3d();
const unsigned int m = reinterpret_input_as_3d ? (a->info()->dimension(1) * a->info()->dimension(2)) : a->info()->dimension(1);
const unsigned int n = b->info()->dimension(0);
const unsigned int k = a->info()->dimension(0);
const unsigned int batch_size = reinterpret_input_as_3d ? a->info()->dimension(3) : a->info()->dimension(2);
// Select GEMMType
_gemm_kernel_type = auto_select_gemm_kernel(auto_heuristics::CommonQuery{ CLScheduler::get().target(), a->info()->data_type(), m, n, k, batch_size }, _reshape_b_only_on_first_run);
const bool fuse_add_c = (!(helpers::float_ops::is_zero(beta)) && c != nullptr);
const ICLTensor *c_to_use = fuse_add_c ? c : nullptr;
switch(_gemm_kernel_type)
{
case CLGEMMKernelType::NATIVE_V1:
{
configure_native_v1(compile_context, a, b, c_to_use, output, alpha, beta, gemm_info);
break;
}
case CLGEMMKernelType::RESHAPED_V1:
{
configure_reshaped_v1(compile_context, a, b, c_to_use, output, alpha, beta, gemm_info);
break;
}
case CLGEMMKernelType::RESHAPED:
{
configure_reshaped_v2(compile_context, a, b, c_to_use, output, alpha, beta, gemm_info);
break;
}
case CLGEMMKernelType::RESHAPED_ONLY_RHS:
{
configure_reshaped_only_rhs(compile_context, a, b, c_to_use, output, alpha, beta, gemm_info);
break;
}
default:
{
ARM_COMPUTE_ERROR("GEMMType not supported");
}
}
}
Status CLGEMM::validate(const ITensorInfo *a, const ITensorInfo *b, const ITensorInfo *c, const ITensorInfo *output, float alpha, float beta, const GEMMInfo &gemm_info)
{
// Get the GPU target
bool reinterpret_input_as_3d = gemm_info.reinterpret_input_as_3d();
const unsigned int m = reinterpret_input_as_3d ? (a->dimension(1) * a->dimension(2)) : a->dimension(1);
const unsigned int n = b->dimension(0);
const unsigned int k = a->dimension(0);
const unsigned int batch_size = reinterpret_input_as_3d ? a->dimension(3) : a->dimension(2);
// Select GEMMType
CLGEMMKernelType gemm_kernel_type = auto_select_gemm_kernel(auto_heuristics::CommonQuery
{
CLScheduler::get().target(), a->data_type(), m, n, k, batch_size,
},
gemm_info.reshape_b_only_on_first_run());
const bool fuse_add_c = (!(helpers::float_ops::is_zero(beta)) && c != nullptr);
const ITensorInfo *c_to_use = fuse_add_c ? c : nullptr;
switch(gemm_kernel_type)
{
case CLGEMMKernelType::NATIVE_V1:
{
ARM_COMPUTE_RETURN_ON_ERROR(validate_native_v1(a, b, c_to_use, output, alpha, beta, gemm_info));
break;
}
case CLGEMMKernelType::RESHAPED_V1:
{
ARM_COMPUTE_RETURN_ON_ERROR(validate_reshaped_v1(a, b, c_to_use, output, alpha, beta, gemm_info));
break;
}
case CLGEMMKernelType::RESHAPED:
{
ARM_COMPUTE_RETURN_ON_ERROR(validate_reshaped(a, b, c_to_use, output, alpha, beta, gemm_info));
break;
}
case CLGEMMKernelType::RESHAPED_ONLY_RHS:
{
ARM_COMPUTE_RETURN_ON_ERROR(validate_reshaped_only_rhs(a, b, c_to_use, output, alpha, beta, gemm_info));
break;
}
default:
{
ARM_COMPUTE_RETURN_ERROR_MSG("GEMMType not supported");
}
}
return Status{};
}
void CLGEMM::run()
{
prepare();
MemoryGroupResourceScope scope_mg(_memory_group);
// Run matrix multiply kernel
switch(_gemm_kernel_type)
{
case CLGEMMKernelType::NATIVE_V1:
{
CLScheduler::get().enqueue(*_mm_kernel, true);
break;
}
case CLGEMMKernelType::RESHAPED_V1:
{
// Run interleave kernel
CLScheduler::get().enqueue(*_reshape_lhs_kernel, false);
if(!_reshape_b_only_on_first_run)
{
// Run transpose kernel
if(_weights_manager && _weights_manager->are_weights_managed(_original_b))
{
_weights_manager->run(_original_b, _reshape_rhs_kernel_managed.get());
}
else
{
CLScheduler::get().enqueue(*_reshape_rhs_kernel, false);
}
}
CLScheduler::get().enqueue(*_mm_kernel, true);
break;
}
case CLGEMMKernelType::RESHAPED:
{
// Run interleave kernel
CLScheduler::get().enqueue(*_reshape_lhs_kernel, false);
if(!_reshape_b_only_on_first_run)
{
// Run transpose kernel
if(_weights_manager && _weights_manager->are_weights_managed(_original_b))
{
_weights_manager->run(_original_b, _reshape_rhs_kernel_managed.get());
}
else
{
CLScheduler::get().enqueue(*_reshape_rhs_kernel, false);
}
}
CLScheduler::get().enqueue(*_mm_reshaped_kernel, true);
break;
}
case CLGEMMKernelType::RESHAPED_ONLY_RHS:
{
if(!_reshape_b_only_on_first_run)
{
// Run transpose kernel
if(_weights_manager && _weights_manager->are_weights_managed(_original_b))
{
_weights_manager->run(_original_b, _reshape_rhs_kernel_managed.get());
}
else
{
CLScheduler::get().enqueue(*_reshape_rhs_kernel, false);
}
}
// In case of RESHAPED_ONLY_RHS, we need to check the padding requirement
// Check if the lhs or dst tensors have padding
const unsigned int cross_plane_pad_lhs = _lhs->info()->padding().top + _lhs->info()->padding().bottom;
const unsigned int cross_plane_pad_dst = _dst->info()->padding().top + _dst->info()->padding().bottom;
bool has_pad_y = (cross_plane_pad_lhs != 0) || (cross_plane_pad_dst != 0);
if(has_pad_y)
{
CLScheduler::get().enqueue(*_mm_reshaped_only_rhs_fallback_kernel, true);
}
else
{
CLScheduler::get().enqueue(*_mm_reshaped_only_rhs_kernel, true);
}
break;
}
default:
{
ARM_COMPUTE_ERROR("GEMMType not supported");
}
}
}
void CLGEMM::prepare()
{
if(!_is_prepared)
{
if(_gemm_kernel_type != CLGEMMKernelType::NATIVE_V1 && _reshape_b_only_on_first_run)
{
if(_weights_manager && _weights_manager->are_weights_managed(_original_b))
{
_weights_manager->run(_original_b, _reshape_rhs_kernel_managed.get());
}
else
{
// Run transpose kernel and mark original weights tensor as unused
_tmp_b.allocator()->allocate();
CLScheduler::get().enqueue(*_reshape_rhs_kernel, false);
_original_b->mark_as_unused();
}
}
CLScheduler::get().queue().finish();
_is_prepared = true;
}
}
} // namespace arm_compute