/* * 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/CL/functions/CLFullyConnectedLayer.h" #include "arm_compute/core/Size2D.h" #include "arm_compute/core/Validate.h" #include "arm_compute/core/utils/misc/Cast.h" #include "arm_compute/core/utils/misc/ShapeCalculator.h" #include "arm_compute/core/utils/quantization/AsymmHelpers.h" #include "arm_compute/runtime/CL/CLScheduler.h" #include "support/MemorySupport.h" #include namespace arm_compute { using namespace arm_compute::misc::shape_calculator; using namespace arm_compute::utils::cast; namespace { Status construct_gemmlowp_output_stage(const ITensorInfo &input, const ITensorInfo &weights, const ITensorInfo &output, GEMMLowpOutputStageInfo &gemmlowp_output_stage, ActivationLayerInfo activation_info) { gemmlowp_output_stage.type = GEMMLowpOutputStageType::QUANTIZE_DOWN_FIXEDPOINT; gemmlowp_output_stage.gemmlowp_offset = 0; gemmlowp_output_stage.gemmlowp_multiplier = 0; gemmlowp_output_stage.gemmlowp_shift = 0; const auto data_type = input.data_type(); // Configure output stage for quantized case if(is_data_type_quantized_asymmetric(data_type)) { const QuantizationInfo oq_info = output.quantization_info(); const UniformQuantizationInfo iq_unif = input.quantization_info().uniform(); const UniformQuantizationInfo wq_unif = weights.quantization_info().uniform(); const UniformQuantizationInfo oq_unif = oq_info.uniform(); const auto output_quant_info = (output.total_size() == 0) ? iq_unif : oq_unif; const float multiplier = (iq_unif.scale * wq_unif.scale) / output_quant_info.scale; int output_multiplier = 0; int output_shift = 0; ARM_COMPUTE_RETURN_ON_ERROR(quantization::calculate_quantized_multiplier(multiplier, &output_multiplier, &output_shift)); PixelValue type_min{}; PixelValue type_max{}; std::tie(type_min, type_max) = get_min_max(data_type); if(activation_info.enabled()) { switch(activation_info.activation()) { case ActivationLayerInfo::ActivationFunction::RELU: type_min = PixelValue(oq_unif.offset); break; case ActivationLayerInfo::ActivationFunction::BOUNDED_RELU: type_min = PixelValue(oq_unif.offset); type_max = PixelValue(activation_info.a(), data_type, oq_info); break; case ActivationLayerInfo::ActivationFunction::LU_BOUNDED_RELU: type_min = PixelValue(activation_info.b(), data_type, oq_info); type_max = PixelValue(activation_info.a(), data_type, oq_info); break; default: ARM_COMPUTE_ERROR("Activation function not supported."); break; } } // Set the GEMMLowp output stage info gemmlowp_output_stage.gemmlowp_offset = output_quant_info.offset; gemmlowp_output_stage.gemmlowp_multiplier = output_multiplier; gemmlowp_output_stage.gemmlowp_shift = output_shift; gemmlowp_output_stage.gemmlowp_multipliers.push_back(output_multiplier); gemmlowp_output_stage.gemmlowp_shifts.push_back(output_shift); type_min.get(gemmlowp_output_stage.gemmlowp_min_bound); type_max.get(gemmlowp_output_stage.gemmlowp_max_bound); } return Status{}; } Status validate_mm(const ITensorInfo &input, const ITensorInfo &weights, const ITensorInfo *bias, const ITensorInfo &output, const FullyConnectedLayerInfo &fc_info) { GEMMLowpOutputStageInfo gemmlowp_output_stage; ARM_COMPUTE_RETURN_ON_ERROR(construct_gemmlowp_output_stage(input, weights, output, gemmlowp_output_stage, fc_info.activation_info)); const GEMMInfo &gemm_info = GEMMInfo(false, // is_a_reshaped false, // is_b_reshaped true, // reshape_b_only_on_first_run 0, // depth_output_gemm3d false, // reinterpret_input_as_3d fc_info.retain_internal_weights, // retain_internal_weights gemmlowp_output_stage, // gemmlowp_output_stage fc_info.fp_mixed_precision, // fp_mixed_precision true, // broadcast_bias ActivationLayerInfo()); // activation_info if(is_data_type_quantized_asymmetric(input.data_type())) { const UniformQuantizationInfo iq_info = input.quantization_info().uniform(); const UniformQuantizationInfo wq_info = weights.quantization_info().uniform(); // Since we need negative offsets for computing convolution, we need to change QuantizationInfo() // Extract and negate input and weights offset const QuantizationInfo input_quantization_info(iq_info.scale, -iq_info.offset); const QuantizationInfo weights_quantization_info(wq_info.scale, -wq_info.offset); // Validate gemmlowp function ARM_COMPUTE_RETURN_ON_ERROR(CLGEMMLowpMatrixMultiplyCore::validate(&input.clone()->set_quantization_info(input_quantization_info), &weights.clone()->set_quantization_info(weights_quantization_info), bias, &output, gemm_info)); } else { ARM_COMPUTE_RETURN_ON_ERROR(CLGEMM::validate(&input, &weights, bias, &output, 1.f, 1.f, gemm_info)); } return Status{}; } } // namespace void CLFullyConnectedLayerReshapeWeights::configure(const ICLTensor *input, ICLTensor *output) { configure(CLKernelLibrary::get().get_compile_context(), input, output); } void CLFullyConnectedLayerReshapeWeights::configure(const CLCompileContext &compile_context, const ICLTensor *input, ICLTensor *output) { auto k = arm_compute::support::cpp14::make_unique(); k->configure(compile_context, input, output); _kernel = std::move(k); } Status CLFullyConnectedLayerReshapeWeights::validate(const ITensorInfo *input, const ITensorInfo *output) { return CLTransposeKernel::validate(input, output); } CLFullyConnectedLayer::CLFullyConnectedLayer(std::shared_ptr memory_manager, IWeightsManager *weights_manager) : _memory_group(memory_manager), _weights_manager(weights_manager), _convert_weights(), _convert_weights_managed(), _reshape_weights_managed_function(), _flatten_layer(), _reshape_weights_function(), _mm_gemm(memory_manager, weights_manager), _mm_gemmlowp(memory_manager), _flatten_output(), _converted_weights_output(), _reshape_weights_output(), _are_weights_converted(true), _are_weights_reshaped(true), _is_fc_after_conv(true), _is_quantized(false), _is_prepared(false), _original_weights(nullptr) { } void CLFullyConnectedLayer::configure_mm(const CLCompileContext &compile_context, const ICLTensor *input, const ICLTensor *weights, const ICLTensor *bias, ICLTensor *output, const FullyConnectedLayerInfo &fc_info) { GEMMLowpOutputStageInfo gemmlowp_output_stage; construct_gemmlowp_output_stage(*input->info(), *weights->info(), *output->info(), gemmlowp_output_stage, fc_info.activation_info); const GEMMInfo &gemm_info = GEMMInfo(false, // is_a_reshaped false, // is_b_reshaped true, // reshape_b_only_on_first_run 0, // depth_output_gemm3d false, // reinterpret_input_as_3d fc_info.retain_internal_weights, // retain_internal_weights gemmlowp_output_stage, // gemmlowp_output_stage fc_info.fp_mixed_precision, // fp_mixed_precision true, // broadcast_bias fc_info.activation_info); // activation_info if(_is_quantized) { // Since we need negative offsets for computing convolution, we need to change QuantizationInfo() // Extract and negate input and weights offset const QuantizationInfo input_quantization_info = input->info()->quantization_info(); const QuantizationInfo weights_quantization_info = weights->info()->quantization_info(); input->info()->set_quantization_info(QuantizationInfo(input_quantization_info.uniform().scale, -input_quantization_info.uniform().offset)); weights->info()->set_quantization_info(QuantizationInfo(weights_quantization_info.uniform().scale, -weights_quantization_info.uniform().offset)); // Configure gemmlowp function _mm_gemmlowp.configure(compile_context, input, weights, bias, output, gemm_info); // Revert back QuantizatioInfo as input and weights could be used in other fully connected layers input->info()->set_quantization_info(input_quantization_info); weights->info()->set_quantization_info(weights_quantization_info); } else { // Configure matrix multiply kernel _mm_gemm.configure(compile_context, input, weights, bias, output, 1.f, 1.f, gemm_info); } } void CLFullyConnectedLayer::configure_conv_fc(const CLCompileContext &compile_context, const ICLTensor *input, const ICLTensor *weights, const ICLTensor *bias, ICLTensor *output, const FullyConnectedLayerInfo &fc_info) { ARM_COMPUTE_ERROR_ON((weights->info()->dimension(1) != (input->info()->dimension(0) * input->info()->dimension(1) * input->info()->dimension(2)))); // If the fully connected layer is called after a convolution layer, the input tensor must be linearized // Initialize output tensor for flatten TensorShape shape_flatten = compute_flatten_shape(input->info()); _flatten_output.allocator()->init(input->info()->clone()->set_is_resizable(true).reset_padding().set_tensor_shape(shape_flatten).set_data_layout(DataLayout::NCHW)); // Configure flatten kernel _memory_group.manage(&_flatten_output); _flatten_layer.configure(compile_context, input, &_flatten_output); // Configure matrix multiply kernel configure_mm(compile_context, &_flatten_output, weights, bias, output, fc_info); // Allocate the output tensor for flatten once all the configure methods have been called _flatten_output.allocator()->allocate(); } void CLFullyConnectedLayer::configure_fc_fc(const CLCompileContext &compile_context, const ICLTensor *input, const ICLTensor *weights, const ICLTensor *bias, ICLTensor *output, const FullyConnectedLayerInfo &fc_info) { ARM_COMPUTE_ERROR_ON(input->info()->dimension(0) != weights->info()->dimension(1)); // Configure matrix multiply kernel configure_mm(compile_context, input, weights, bias, output, fc_info); } void CLFullyConnectedLayer::configure(const ICLTensor *input, const ICLTensor *weights, const ICLTensor *biases, ICLTensor *output, FullyConnectedLayerInfo fc_info) { configure(CLKernelLibrary::get().get_compile_context(), input, weights, biases, output, fc_info); } void CLFullyConnectedLayer::configure(const CLCompileContext &compile_context, const ICLTensor *input, const ICLTensor *weights, const ICLTensor *biases, ICLTensor *output, FullyConnectedLayerInfo fc_info) { ARM_COMPUTE_ERROR_ON_NULLPTR(input, weights, output); // Perform validate step ARM_COMPUTE_ERROR_THROW_ON(CLFullyConnectedLayer::validate(input->info(), weights->info(), biases != nullptr ? biases->info() : nullptr, output->info(), fc_info)); _are_weights_converted = true; _are_weights_reshaped = fc_info.transpose_weights ? fc_info.are_weights_reshaped : true; _is_fc_after_conv = true; _is_quantized = is_data_type_quantized_asymmetric(input->info()->data_type()); _is_prepared = fc_info.retain_internal_weights; _original_weights = weights; if(_weights_manager) { _weights_manager->manage(weights); } const ICLTensor *weights_to_use = weights; // With the Fully Connected layer we can have 4 different cases: // 1) Convolution layer -> Fully Connected layer without batches // 2) Fully Connected layer -> Fully Connected layer without batches // 3) Convolution layer -> Fully Connected layer with batches // 4) Fully Connected layer -> Fully Connected layer with batches // Check if we have a fully connected layer with batches const bool is_batched_fc_layer = output->info()->dimension(1) > 1; if(is_batched_fc_layer) { _is_fc_after_conv = (TensorShape::num_max_dimensions >= 4) && (std::equal(input->info()->tensor_shape().cbegin() + 3, input->info()->tensor_shape().cend(), output->info()->tensor_shape().cbegin() + 1)); } else { _is_fc_after_conv = input->info()->num_dimensions() > 1; } // Reshape weights if needed if(!_are_weights_reshaped) { if(_weights_manager && _weights_manager->are_weights_managed(weights)) { _reshape_weights_managed_function.configure(compile_context, weights); weights_to_use = utils::cast::polymorphic_downcast(_weights_manager->acquire(weights, &_reshape_weights_managed_function)); } else { // Reshape the weights _reshape_weights_function.configure(compile_context, weights, &_reshape_weights_output); weights_to_use = &_reshape_weights_output; } } // Convert weights if needed if(_is_fc_after_conv && (input->info()->data_layout() != fc_info.weights_trained_layout)) { if(_weights_manager && _weights_manager->are_weights_managed(weights_to_use)) { _convert_weights_managed.configure(compile_context, weights_to_use, input->info()->tensor_shape(), fc_info.weights_trained_layout); weights_to_use = utils::cast::polymorphic_downcast(_weights_manager->acquire(weights, &_convert_weights_managed)); } else { // Convert weights _convert_weights.configure(compile_context, weights_to_use, &_converted_weights_output, input->info()->tensor_shape(), fc_info.weights_trained_layout); weights_to_use = &_converted_weights_output; } _are_weights_converted = false; } if(_is_fc_after_conv) { // Fully Connected layer after a Convolution Layer without batches configure_conv_fc(compile_context, input, weights_to_use, biases, output, fc_info); } else { // Fully Connected layer after a Fully Connected Layer without batches configure_fc_fc(compile_context, input, weights_to_use, biases, output, fc_info); } } Status CLFullyConnectedLayer::validate(const ITensorInfo *input, const ITensorInfo *weights, const ITensorInfo *biases, const ITensorInfo *output, FullyConnectedLayerInfo fc_info) { ARM_COMPUTE_RETURN_ERROR_ON_NULLPTR(input, weights, output); ARM_COMPUTE_RETURN_ERROR_ON_DATA_TYPE_CHANNEL_NOT_IN(input, 1, DataType::QASYMM8, DataType::QASYMM8_SIGNED, DataType::F16, DataType::F32); ARM_COMPUTE_RETURN_ERROR_ON_MISMATCHING_DATA_TYPES(input, weights, output); ARM_COMPUTE_RETURN_ERROR_ON(weights->num_dimensions() > 2); ARM_COMPUTE_RETURN_ERROR_ON(fc_info.activation_info.enabled() && is_data_type_quantized(input->data_type()) && fc_info.activation_info.activation() != ActivationLayerInfo::ActivationFunction::RELU && fc_info.activation_info.activation() != ActivationLayerInfo::ActivationFunction::BOUNDED_RELU && fc_info.activation_info.activation() != ActivationLayerInfo::ActivationFunction::LU_BOUNDED_RELU); bool weights_reshaped = fc_info.transpose_weights ? fc_info.are_weights_reshaped : true; bool is_fc_after_conv = true; const ITensorInfo &flatten_input = TensorInfo(input->clone()->set_is_resizable(true).reset_padding().set_tensor_shape(compute_flatten_shape(input)).set_data_layout(DataLayout::NCHW)); const ITensorInfo &reshaped_weights = TensorInfo(weights->clone()->set_is_resizable(true).reset_padding().set_tensor_shape(compute_transposed_shape(*weights))); const ITensorInfo &converted_weights = weights_reshaped ? TensorInfo(weights->clone()->set_is_resizable(true).reset_padding()) : TensorInfo(*reshaped_weights.clone()); // With the Fully Connected layer we can have 4 different cases: // 1) Convolution layer -> Fully Connected layer without batches // 2) Fully Connected layer -> Fully Connected layer without batches // 3) Convolution layer -> Fully Connected layer with batches // 4) Fully Connected layer -> Fully Connected layer with batches const ITensorInfo *input_to_use = input; const ITensorInfo *weights_to_use = weights; // Check if we have a fully connected layer with batches const bool is_batched_fc_layer = output->dimension(1) > 1; if(is_batched_fc_layer) { is_fc_after_conv = (TensorShape::num_max_dimensions >= 4) && (std::equal(input->tensor_shape().cbegin() + 3, input->tensor_shape().cend(), output->tensor_shape().cbegin() + 1)); } else { is_fc_after_conv = input->num_dimensions() > 1; } if(!weights_reshaped) { // Validate reshape weights kernel ARM_COMPUTE_RETURN_ON_ERROR(CLFullyConnectedLayerReshapeWeights::validate(weights, &reshaped_weights)); weights_to_use = &reshaped_weights; } if(is_fc_after_conv && (input->data_layout() != fc_info.weights_trained_layout)) { // Validate convert weights kernel ARM_COMPUTE_RETURN_ON_ERROR(CLConvertFullyConnectedWeights::validate(weights_to_use, &converted_weights, input->tensor_shape(), fc_info.weights_trained_layout)); weights_to_use = &converted_weights; } if(is_fc_after_conv) { // Fully Connected layer after a Convolution Layer without batches ARM_COMPUTE_RETURN_ERROR_ON((weights_to_use->dimension(1) != (input->dimension(0) * input->dimension(1) * input->dimension(2)))); // Validate flatten kernel ARM_COMPUTE_RETURN_ON_ERROR(CLFlattenLayer::validate(input, &flatten_input)); input_to_use = &flatten_input; } else { // Fully Connected layer after a Fully Connected Layer without batches ARM_COMPUTE_RETURN_ERROR_ON(input->dimension(0) != weights_to_use->dimension(1)); } // Validate matrix multiply kernel ARM_COMPUTE_RETURN_ON_ERROR(validate_mm(*input_to_use, *weights_to_use, biases, *output, fc_info)); return Status{}; } void CLFullyConnectedLayer::run() { prepare(); MemoryGroupResourceScope scope_mg(_memory_group); // Linearize input if it comes from a convolutional layer if(_is_fc_after_conv) { _flatten_layer.run(); } // Run matrix multiply if(_is_quantized) { _mm_gemmlowp.run(); } else { _mm_gemm.run(); } } void CLFullyConnectedLayer::prepare() { if(!_is_prepared) { if(!_weights_manager) { ARM_COMPUTE_ERROR_ON(!_original_weights->is_used()); } auto release_unused = [](CLTensor * w) { if(!w->is_used()) { CLScheduler::get().queue().finish(); w->allocator()->free(); } }; // Pointer to current weights const ICLTensor *cur_weights = _original_weights; // Reshape of the weights if needed (happens only once) if(!_are_weights_reshaped) { if(_weights_manager && _weights_manager->are_weights_managed(_original_weights)) { cur_weights = utils::cast::polymorphic_downcast(_weights_manager->run(cur_weights, &_reshape_weights_managed_function)); } else { // Run reshape weights kernel and mark weights as unused _reshape_weights_output.allocator()->allocate(); _reshape_weights_function.run(); cur_weights->mark_as_unused(); cur_weights = &_reshape_weights_output; } _are_weights_reshaped = true; } // Convert weights if needed (happens only once) if(!_are_weights_converted) { if(_weights_manager && _weights_manager->are_weights_managed(cur_weights)) { _weights_manager->run(cur_weights, &_convert_weights_managed); } else { _converted_weights_output.allocator()->allocate(); _convert_weights.run(); cur_weights->mark_as_unused(); } _are_weights_converted = true; } // Release reshaped weights if unused release_unused(&_reshape_weights_output); // Prepare GEMM prepare and release unused weights if(!_is_quantized) { _mm_gemm.prepare(); } // Release converted weights if unused release_unused(&_reshape_weights_output); release_unused(&_converted_weights_output); _is_prepared = true; } } } // namespace arm_compute