src/runtime/NEON/functions/NESoftmaxLayer.cpp - ml/ComputeLibrary - Gitiles

 /*
  * Copyright (c) 2017-2020 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/NEON/functions/NESoftmaxLayer.h"

 #include "arm_compute/core/Helpers.h"
 #include "arm_compute/core/NEON/kernels/NESoftmaxLayerKernel.h"
 #include "arm_compute/core/utils/misc/ShapeCalculator.h"
 #include "arm_compute/runtime/NEON/NEScheduler.h"

 namespace arm_compute
 {
 template <bool IS_LOG>
 NESoftmaxLayerGeneric<IS_LOG>::NESoftmaxLayerGeneric(std::shared_ptr<IMemoryManager> memory_manager)
     : _memory_group(std::move(memory_manager)), _max_kernel(), _softmax_kernel(), _flat_or_reshape_ptr(nullptr), _fill_border_kernel(), _reshape(), _max(), _tmp(), _input_flattened(), _output_flattened(),
       _needs_flattening(false)
 {
 }

 template <bool IS_LOG>
 void NESoftmaxLayerGeneric<IS_LOG>::configure_reshape_input_kernel(const ITensor *input, const ITensor *output, int32_t first_n_reduce_axes)
 {
     // Flatten the input
     const TensorShape shape_flatten = misc::shape_calculator::compute_softmax_shape(input->info(), first_n_reduce_axes);

     // Initialize the flat input
     _input_flattened.allocator()->init(input->info()->clone()->set_is_resizable(true).reset_padding().set_tensor_shape(shape_flatten));

     // Note that the "other cases" include both:
     //   1. first_n_reduce_axes < 3: Reduce the first 1 (no need to reduce) or 2 dimensions (inclusive)
     //   2. first_n_reduce_axes == 4: Reduce all 4 dimensions. This can only be handled by NEReshapeKernel instead of NEFlattenKernel.
     if(first_n_reduce_axes == 3)
     {
         auto flatten_kernel_ptr = support::cpp14::make_unique<NEFlattenLayer>();
         flatten_kernel_ptr->configure(input, &_input_flattened);
         _flat_or_reshape_ptr = std::move(flatten_kernel_ptr);
     }
     else
     {
         auto reshape_kernel_ptr = support::cpp14::make_unique<NEReshapeLayer>();
         reshape_kernel_ptr->configure(input, &_input_flattened);
         _flat_or_reshape_ptr = std::move(reshape_kernel_ptr);
     }

     // We need to init the output tensor here. Indeed, the reshape kernel expects
     // both tensors to be already initialized
     auto_init_if_empty(*output->info(), *input->info()->clone());
 }

 template <bool IS_LOG>
 void NESoftmaxLayerGeneric<IS_LOG>::configure(ITensor *input, ITensor *output, float beta, int32_t axis)
 {
     // Perform validation step
     ARM_COMPUTE_ERROR_ON_NULLPTR(input, output);
     ARM_COMPUTE_ERROR_THROW_ON(NESoftmaxLayerGeneric::validate(input->info(), output->info(), beta, axis));

     // Convert reduce-before axis (inclusive) to first n axes to reduce
     size_t first_n_reduce_axes = dim_index_2_num_dims(axis, static_cast<int32_t>(input->info()->num_dimensions()));

     // We only need flattening when the number of axes to reduce is greater than 1
     _needs_flattening = first_n_reduce_axes > 1;

     // If we are dealing with a 4D tensor, we will:
     // - Flatten the input, so that we end up with a [width*height*depth] * batches 2D tensor
     // - Execute all the pipeline (reduction + normalization) on the flattened tensor
     // - Reshape the flattened output into the real output
     if(_needs_flattening)
     {
         // Add to the memory manager _input_flattened
         _memory_group.manage(&_input_flattened);

         // Configure  _flatten_kernel and _input_flattened
         configure_reshape_input_kernel(input, output, first_n_reduce_axes);
     }

     // We want to deal with a 2D input. Either it is the flattened version of the original input (4D case)
     // or it is the original input case (2D case)
     ITensor *input_2D = (_needs_flattening ? &_input_flattened : input);

     // Create intermediate tensors shapes
     const TensorInfo input_info    = input_2D->info()->clone()->reset_padding().set_is_resizable(true);
     DataType         tmp_data_type = is_data_type_quantized_asymmetric(input_2D->info()->data_type()) ? DataType::F32 : input_2D->info()->data_type();
     TensorInfo       tensor_info_tmp(input_info.clone()->set_data_type(tmp_data_type));

     // Init intermediate tensors
     TensorShape max_sum_shape = input_2D->info()->tensor_shape();
     max_sum_shape.set(0, 1);
     _max.allocator()->init(input_info.clone()->set_tensor_shape(max_sum_shape));
     _tmp.allocator()->init(tensor_info_tmp);

     // Manage intermediate buffers
     _memory_group.manage(&_max);
     _memory_group.manage(&_tmp);

     // Configure Kernels
     _max_kernel.configure(input_2D, &_max);
     if(_needs_flattening)
     {
         // Add to the memory manager _output_flattened
         _memory_group.manage(&_output_flattened);

         // The normalization kernel stores the result in a flat output tensor
         _softmax_kernel.configure(input_2D, &_max, &_output_flattened, beta, &_tmp);
         _input_flattened.allocator()->allocate();

         // Reshape the flat output into the requested (4D) output
         _reshape.configure(&_output_flattened, output);

         // Allocate the intermediate flat tensors
         _output_flattened.allocator()->allocate();
     }
     else
     {
         // Softmax 2D case
         _fill_border_kernel.configure(input_2D, _max_kernel.border_size(), BorderMode::REPLICATE);
         _softmax_kernel.configure(input_2D, &_max, output, beta, &_tmp);
     }

     // Allocate intermediate buffers
     _max.allocator()->allocate();
     _tmp.allocator()->allocate();
 }

 template <bool IS_LOG>
 Status NESoftmaxLayerGeneric<IS_LOG>::validate(const ITensorInfo *input, const ITensorInfo *output, float beta, int32_t axis)
 {
     // Perform validation step
     ARM_COMPUTE_RETURN_ERROR_ON_NULLPTR(input, output);
     ARM_COMPUTE_RETURN_ERROR_ON_MSG(input->num_dimensions() > 4, "Only up to 4 dimensions are supported");
     ARM_COMPUTE_UNUSED(beta);
     ARM_COMPUTE_RETURN_ERROR_ON_MSG(axis != 0, "Only axis 0 supported");
     ARM_COMPUTE_RETURN_ERROR_ON(axis < static_cast<int32_t>(-input->num_dimensions()) || static_cast<int32_t>(input->num_dimensions()) <= axis);

     // Convert reduce-before axis (inclusive) to first n axes to reduce
     size_t first_n_reduce_axes = dim_index_2_num_dims(axis, static_cast<int32_t>(input->num_dimensions()));

     // Create intermediate tensor info
     DataType         tmp_data_type = input->data_type();
     const TensorInfo tensor_info_tmp(input->clone()->set_data_type(tmp_data_type).set_is_resizable(true));

     TensorShape max_sum_shape = input->tensor_shape();
     max_sum_shape.set(0, 1);
     const TensorInfo tensor_info_max_sum(input->clone()->set_tensor_shape(max_sum_shape).set_data_type(tmp_data_type).set_quantization_info(input->quantization_info()).set_is_resizable(true));
     const TensorInfo dont_care;

     const bool needs_flattening = (first_n_reduce_axes > 1);

     if(needs_flattening)
     {
         const TensorShape shape_flatten = misc::shape_calculator::compute_softmax_shape(input, first_n_reduce_axes);
         TensorInfo        tensor_info_flat(input->clone()->set_tensor_shape(shape_flatten).set_is_resizable(true));

         if(first_n_reduce_axes == 3)
         {
             ARM_COMPUTE_RETURN_ON_ERROR(NEFlattenLayer::validate(input, &tensor_info_flat));
         }
         else
         {
             ARM_COMPUTE_RETURN_ON_ERROR(NEReshapeLayer::validate(input, &tensor_info_flat));
         }
     }

     ARM_COMPUTE_RETURN_ON_ERROR(NELogits1DMaxKernel::validate(input, &tensor_info_max_sum));
     ARM_COMPUTE_RETURN_ON_ERROR(NELogits1DSoftmaxKernel<IS_LOG>::validate(&tensor_info_tmp, &tensor_info_max_sum, output, beta, &dont_care));

     return Status{};
 }

 template <bool IS_LOG>
 void           NESoftmaxLayerGeneric<IS_LOG>::run()
 {
     MemoryGroupResourceScope scope_mg(_memory_group);

     if(_needs_flattening)
     {
         _flat_or_reshape_ptr->run();
     }

     NEScheduler::get().schedule(&_fill_border_kernel, Window::DimY);
     NEScheduler::get().schedule(&_max_kernel, Window::DimY);
     NEScheduler::get().schedule(&_softmax_kernel, Window::DimY);

     if(_needs_flattening)
     {
         _reshape.run();
     }
 }

 template class NESoftmaxLayerGeneric<false>;
 template class NESoftmaxLayerGeneric<true>;

 } // namespace arm_compute
	/*
	* Copyright (c) 2017-2020 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/NEON/functions/NESoftmaxLayer.h"

	#include "arm_compute/core/Helpers.h"
	#include "arm_compute/core/NEON/kernels/NESoftmaxLayerKernel.h"
	#include "arm_compute/core/utils/misc/ShapeCalculator.h"
	#include "arm_compute/runtime/NEON/NEScheduler.h"

	namespace arm_compute
	{
	template <bool IS_LOG>
	NESoftmaxLayerGeneric<IS_LOG>::NESoftmaxLayerGeneric(std::shared_ptr<IMemoryManager> memory_manager)
	: _memory_group(std::move(memory_manager)), _max_kernel(), _softmax_kernel(), _flat_or_reshape_ptr(nullptr), _fill_border_kernel(), _reshape(), _max(), _tmp(), _input_flattened(), _output_flattened(),
	_needs_flattening(false)
	{
	}

	template <bool IS_LOG>
	void NESoftmaxLayerGeneric<IS_LOG>::configure_reshape_input_kernel(const ITensor input, const ITensor output, int32_t first_n_reduce_axes)
	{
	// Flatten the input
	const TensorShape shape_flatten = misc::shape_calculator::compute_softmax_shape(input->info(), first_n_reduce_axes);

	// Initialize the flat input
	_input_flattened.allocator()->init(input->info()->clone()->set_is_resizable(true).reset_padding().set_tensor_shape(shape_flatten));

	// Note that the "other cases" include both:
	// 1. first_n_reduce_axes < 3: Reduce the first 1 (no need to reduce) or 2 dimensions (inclusive)
	// 2. first_n_reduce_axes == 4: Reduce all 4 dimensions. This can only be handled by NEReshapeKernel instead of NEFlattenKernel.
	if(first_n_reduce_axes == 3)
	{
	auto flatten_kernel_ptr = support::cpp14::make_unique<NEFlattenLayer>();
	flatten_kernel_ptr->configure(input, &_input_flattened);
	_flat_or_reshape_ptr = std::move(flatten_kernel_ptr);
	}
	else
	{
	auto reshape_kernel_ptr = support::cpp14::make_unique<NEReshapeLayer>();
	reshape_kernel_ptr->configure(input, &_input_flattened);
	_flat_or_reshape_ptr = std::move(reshape_kernel_ptr);
	}

	// We need to init the output tensor here. Indeed, the reshape kernel expects
	// both tensors to be already initialized
	auto_init_if_empty(output->info(), input->info()->clone());
	}

	template <bool IS_LOG>
	void NESoftmaxLayerGeneric<IS_LOG>::configure(ITensor input, ITensor output, float beta, int32_t axis)
	{
	// Perform validation step
	ARM_COMPUTE_ERROR_ON_NULLPTR(input, output);
	ARM_COMPUTE_ERROR_THROW_ON(NESoftmaxLayerGeneric::validate(input->info(), output->info(), beta, axis));

	// Convert reduce-before axis (inclusive) to first n axes to reduce
	size_t first_n_reduce_axes = dim_index_2_num_dims(axis, static_cast<int32_t>(input->info()->num_dimensions()));

	// We only need flattening when the number of axes to reduce is greater than 1
	_needs_flattening = first_n_reduce_axes > 1;

	// If we are dealing with a 4D tensor, we will:
	// - Flatten the input, so that we end up with a [widthheightdepth] * batches 2D tensor
	// - Execute all the pipeline (reduction + normalization) on the flattened tensor
	// - Reshape the flattened output into the real output
	if(_needs_flattening)
	{
	// Add to the memory manager _input_flattened
	_memory_group.manage(&_input_flattened);

	// Configure _flatten_kernel and _input_flattened
	configure_reshape_input_kernel(input, output, first_n_reduce_axes);
	}

	// We want to deal with a 2D input. Either it is the flattened version of the original input (4D case)
	// or it is the original input case (2D case)
	ITensor *input_2D = (_needs_flattening ? &_input_flattened : input);

	// Create intermediate tensors shapes
	const TensorInfo input_info = input_2D->info()->clone()->reset_padding().set_is_resizable(true);
	DataType tmp_data_type = is_data_type_quantized_asymmetric(input_2D->info()->data_type()) ? DataType::F32 : input_2D->info()->data_type();
	TensorInfo tensor_info_tmp(input_info.clone()->set_data_type(tmp_data_type));

	// Init intermediate tensors
	TensorShape max_sum_shape = input_2D->info()->tensor_shape();
	max_sum_shape.set(0, 1);
	_max.allocator()->init(input_info.clone()->set_tensor_shape(max_sum_shape));
	_tmp.allocator()->init(tensor_info_tmp);

	// Manage intermediate buffers
	_memory_group.manage(&_max);
	_memory_group.manage(&_tmp);

	// Configure Kernels
	_max_kernel.configure(input_2D, &_max);
	if(_needs_flattening)
	{
	// Add to the memory manager _output_flattened
	_memory_group.manage(&_output_flattened);

	// The normalization kernel stores the result in a flat output tensor
	_softmax_kernel.configure(input_2D, &_max, &_output_flattened, beta, &_tmp);
	_input_flattened.allocator()->allocate();

	// Reshape the flat output into the requested (4D) output
	_reshape.configure(&_output_flattened, output);

	// Allocate the intermediate flat tensors
	_output_flattened.allocator()->allocate();
	}
	else
	{
	// Softmax 2D case
	_fill_border_kernel.configure(input_2D, _max_kernel.border_size(), BorderMode::REPLICATE);
	_softmax_kernel.configure(input_2D, &_max, output, beta, &_tmp);
	}

	// Allocate intermediate buffers
	_max.allocator()->allocate();
	_tmp.allocator()->allocate();
	}

	template <bool IS_LOG>
	Status NESoftmaxLayerGeneric<IS_LOG>::validate(const ITensorInfo input, const ITensorInfo output, float beta, int32_t axis)
	{
	// Perform validation step
	ARM_COMPUTE_RETURN_ERROR_ON_NULLPTR(input, output);
	ARM_COMPUTE_RETURN_ERROR_ON_MSG(input->num_dimensions() > 4, "Only up to 4 dimensions are supported");
	ARM_COMPUTE_UNUSED(beta);
	ARM_COMPUTE_RETURN_ERROR_ON_MSG(axis != 0, "Only axis 0 supported");
	ARM_COMPUTE_RETURN_ERROR_ON(axis < static_cast<int32_t>(-input->num_dimensions()) \|\| static_cast<int32_t>(input->num_dimensions()) <= axis);

	// Convert reduce-before axis (inclusive) to first n axes to reduce
	size_t first_n_reduce_axes = dim_index_2_num_dims(axis, static_cast<int32_t>(input->num_dimensions()));

	// Create intermediate tensor info
	DataType tmp_data_type = input->data_type();
	const TensorInfo tensor_info_tmp(input->clone()->set_data_type(tmp_data_type).set_is_resizable(true));

	TensorShape max_sum_shape = input->tensor_shape();
	max_sum_shape.set(0, 1);
	const TensorInfo tensor_info_max_sum(input->clone()->set_tensor_shape(max_sum_shape).set_data_type(tmp_data_type).set_quantization_info(input->quantization_info()).set_is_resizable(true));
	const TensorInfo dont_care;

	const bool needs_flattening = (first_n_reduce_axes > 1);

	if(needs_flattening)
	{
	const TensorShape shape_flatten = misc::shape_calculator::compute_softmax_shape(input, first_n_reduce_axes);
	TensorInfo tensor_info_flat(input->clone()->set_tensor_shape(shape_flatten).set_is_resizable(true));

	if(first_n_reduce_axes == 3)
	{
	ARM_COMPUTE_RETURN_ON_ERROR(NEFlattenLayer::validate(input, &tensor_info_flat));
	}
	else
	{
	ARM_COMPUTE_RETURN_ON_ERROR(NEReshapeLayer::validate(input, &tensor_info_flat));
	}
	}

	ARM_COMPUTE_RETURN_ON_ERROR(NELogits1DMaxKernel::validate(input, &tensor_info_max_sum));
	ARM_COMPUTE_RETURN_ON_ERROR(NELogits1DSoftmaxKernel<IS_LOG>::validate(&tensor_info_tmp, &tensor_info_max_sum, output, beta, &dont_care));

	return Status{};
	}

	template <bool IS_LOG>
	void NESoftmaxLayerGeneric<IS_LOG>::run()
	{
	MemoryGroupResourceScope scope_mg(_memory_group);

	if(_needs_flattening)
	{
	_flat_or_reshape_ptr->run();
	}

	NEScheduler::get().schedule(&_fill_border_kernel, Window::DimY);
	NEScheduler::get().schedule(&_max_kernel, Window::DimY);
	NEScheduler::get().schedule(&_softmax_kernel, Window::DimY);

	if(_needs_flattening)
	{
	_reshape.run();
	}
	}

	template class NESoftmaxLayerGeneric<false>;
	template class NESoftmaxLayerGeneric<true>;

	} // namespace arm_compute