// // Copyright © 2023 Arm Ltd and Contributors. All rights reserved. // SPDX-License-Identifier: MIT // #pragma once #include #include #include #include #include #include #include #include #include #include #include #include #include namespace { // Macro to call an IsSupported function and log caller name together with reason for lack of support #define FORWARD_LAYER_SUPPORT_FUNC(opName, tfLiteContext, func, backends, supported, setBackend, ...) \ try \ { \ for (auto&& backendId : backends) \ { \ auto layerSupportObject = armnn::GetILayerSupportByBackendId(backendId); \ if (layerSupportObject.IsBackendRegistered()) \ { \ std::string reasonIfUnsupported; \ supported = \ layerSupportObject.func(__VA_ARGS__, armnn::Optional(reasonIfUnsupported)); \ if (supported) \ { \ setBackend = backendId; \ break; \ } \ else \ { \ if (reasonIfUnsupported.size() > 0) \ { \ TFLITE_LOG_PROD(tflite::TFLITE_LOG_WARNING, \ "%s: not supported by armnn: %s", opName, reasonIfUnsupported.c_str()); \ } \ else \ { \ TFLITE_LOG_PROD(tflite::TFLITE_LOG_WARNING, \ "%s: not supported by armnn", opName); \ } \ } \ } \ else \ { \ TF_LITE_KERNEL_LOG(tfLiteContext, "%s: backend not registered: %s", opName, backendId.Get().c_str()); \ } \ } \ if (!supported) \ { \ TF_LITE_KERNEL_LOG(tfLiteContext, "%s: not supported by any specified backend", opName); \ } \ } \ catch (const armnn::InvalidArgumentException &e) \ { \ throw armnn::InvalidArgumentException(e, "Failed to check layer support", CHECK_LOCATION()); \ } TfLiteStatus ValidateNumInputs(TfLiteContext* tfLiteContext, TfLiteNode* tfLiteNode, const unsigned int expectedSize, int nodeIndex) { auto numInputs = tfLiteNode->inputs->size; if (static_cast(numInputs) != expectedSize) { TF_LITE_MAYBE_KERNEL_LOG( tfLiteContext, "TfLiteArmnnDelegate: Unexpected number of inputs (%d != %d) in node #%d", numInputs, expectedSize, nodeIndex); return kTfLiteError; } return kTfLiteOk; } TfLiteStatus ValidateNumOutputs(TfLiteContext* tfLiteContext, TfLiteNode* tfLiteNode, const unsigned int expectedSize, int nodeIndex) { auto numOutputs = tfLiteNode->outputs->size; if (static_cast(numOutputs) != expectedSize) { TF_LITE_MAYBE_KERNEL_LOG( tfLiteContext, "TfLiteArmnnDelegate: Unexpected number of outputs (%d != %d) in node #%d", numOutputs, expectedSize, nodeIndex); return kTfLiteError; } return kTfLiteOk; } bool IsDynamicTensor(const TfLiteTensor& tfLiteTensor) { auto tensorAllocationType = tfLiteTensor.allocation_type; if (tensorAllocationType == kTfLiteDynamic) { return true; } return false; } bool IsValid(const TfLiteTensor* tfLiteTensor) { return tfLiteTensor == nullptr ? false : true; } bool IsValid(TfLiteContext* tfLiteContext, const TfLiteTensor& tfLiteTensor, int32_t operatorCode, int32_t nodeIndex) { if(!IsValid(&tfLiteTensor)) { std::cout << "..Is Not Valid" << std::endl; TF_LITE_MAYBE_KERNEL_LOG( tfLiteContext, "TfLiteArmnnDelegate: Invalid TfLite tensor in operator #%d node #%d: ", operatorCode, nodeIndex); return false; } if (IsDynamicTensor(tfLiteTensor)) { std::cout << "..IsDynamicTensor" << std::endl; TF_LITE_MAYBE_KERNEL_LOG( tfLiteContext, "TfLiteArmnnDelegate: Dynamic tensors are not supported in operator #%d node #%d: ", operatorCode, nodeIndex); return false; } return true; } bool IsAffineQuantization(const TfLiteTensor& tfLiteTensor) { auto quantizationInfo = tfLiteTensor.quantization; if (quantizationInfo.type == kTfLiteAffineQuantization) { return true; } return false; } TfLiteStatus Connect(armnn::IConnectableLayer* layer, TfLiteNode* tfLiteNode, armnnDelegate::DelegateData& data) { ARMNN_ASSERT(static_cast(tfLiteNode->outputs->size) == layer->GetNumOutputSlots()); // Connect the input slots for (unsigned int inputIndex = 0; inputIndex < layer->GetNumInputSlots(); ++inputIndex) { if (data.m_OutputSlotForNode[tfLiteNode->inputs->data[inputIndex]] != nullptr) { data.m_OutputSlotForNode[tfLiteNode->inputs->data[inputIndex]]->Connect(layer->GetInputSlot(inputIndex)); } } // Prepare output slots for (unsigned int outputIndex = 0; outputIndex < layer->GetNumOutputSlots(); ++outputIndex) { armnn::IOutputSlot& outputSlot = layer->GetOutputSlot(outputIndex); data.m_OutputSlotForNode[static_cast(tfLiteNode->outputs->data[outputIndex])] = &outputSlot; } return kTfLiteOk; } TfLiteStatus FusedActivation(TfLiteContext* tfLiteContext, TfLiteNode* tfLiteNode, TfLiteFusedActivation activationType, armnn::IConnectableLayer* prevLayer, unsigned int outputSlotIndex, armnnDelegate::DelegateData& data) { const armnn::TensorInfo& activationOutputInfo = prevLayer->GetOutputSlot(outputSlotIndex).GetTensorInfo(); armnn::ActivationDescriptor activationDesc; switch (activationType) { case kTfLiteActNone: { // No Activation return kTfLiteOk; } case kTfLiteActRelu: { activationDesc.m_Function = armnn::ActivationFunction::ReLu; break; } // The name of kTfLiteActRelu1 changed after TF Lite v2.3 #if defined(ARMNN_POST_TFLITE_2_3) case kTfLiteActReluN1To1: #else case kTfLiteActRelu1: #endif { activationDesc.m_Function = armnn::ActivationFunction::BoundedReLu; activationDesc.m_A = 1.0f; activationDesc.m_B = -1.0f; break; } case kTfLiteActRelu6: { activationDesc.m_Function = armnn::ActivationFunction::BoundedReLu; activationDesc.m_A = 6.0f; activationDesc.m_B = 0.0f; break; } case kTfLiteActSigmoid: { activationDesc.m_Function = armnn::ActivationFunction::Sigmoid; break; } case kTfLiteActTanh: { activationDesc.m_Function = armnn::ActivationFunction::TanH; activationDesc.m_A = 1.0f; activationDesc.m_B = 1.0f; break; } default: return kTfLiteError; } bool isSupported = false; armnn::BackendId setBackend; FORWARD_LAYER_SUPPORT_FUNC("ACTIVATION", tfLiteContext, IsActivationSupported, data.m_Backends, isSupported, setBackend, activationOutputInfo, activationOutputInfo, activationDesc); if (!isSupported) { return kTfLiteError; } armnn::IConnectableLayer* activationLayer = data.m_Network->AddActivationLayer(activationDesc); activationLayer->SetBackendId(setBackend); ARMNN_ASSERT(activationLayer != nullptr); activationLayer->GetOutputSlot(0).SetTensorInfo(activationOutputInfo); // Connect and prepare output slots for (unsigned int outputIndex = 0; outputIndex < activationLayer->GetNumOutputSlots(); ++outputIndex) { data.m_OutputSlotForNode[static_cast( tfLiteNode->outputs->data[outputIndex])]->Connect(activationLayer->GetInputSlot(0)); armnn::IOutputSlot& outputSlot = activationLayer->GetOutputSlot(outputIndex); data.m_OutputSlotForNode[static_cast( tfLiteNode->outputs->data[outputIndex])] = &outputSlot; } return kTfLiteOk; } armnn::IConnectableLayer* AddReshapeLayer(TfLiteContext* tfLiteContext, TfLiteNode* tfLiteNode, armnn::IConnectableLayer* prevLayer, armnn::TensorInfo reshapedOutputTensorInfo, armnn::TensorInfo outputTensorInfo, armnnDelegate::DelegateData& data) { armnn::ReshapeDescriptor desc; desc.m_TargetShape = outputTensorInfo.GetShape(); bool isSupported = false; armnn::BackendId setBackend; FORWARD_LAYER_SUPPORT_FUNC("RESHAPE", tfLiteContext, IsReshapeSupported, data.m_Backends, isSupported, setBackend, reshapedOutputTensorInfo, outputTensorInfo, desc); if (!isSupported) { return nullptr; } armnn::IConnectableLayer* reshapeLayer = data.m_Network->AddReshapeLayer(desc); reshapeLayer->SetBackendId(setBackend); ARMNN_ASSERT(reshapeLayer != nullptr); prevLayer->GetOutputSlot(0).SetTensorInfo(reshapedOutputTensorInfo); reshapeLayer->GetOutputSlot(0).SetTensorInfo(outputTensorInfo); // Connect and prepare output slots for (unsigned int outputIndex = 0; outputIndex < reshapeLayer->GetNumOutputSlots(); ++outputIndex) { data.m_OutputSlotForNode[static_cast( tfLiteNode->outputs->data[outputIndex])]->Connect(reshapeLayer->GetInputSlot(0)); armnn::IOutputSlot& outputSlot = reshapeLayer->GetOutputSlot(outputIndex); data.m_OutputSlotForNode[static_cast( tfLiteNode->outputs->data[outputIndex])] = &outputSlot; } return reshapeLayer; } armnn::DataType GetDataType(const TfLiteTensor& tfLiteTensor) { switch (tfLiteTensor.type) { case kTfLiteBool: return armnn::DataType::Boolean; case kTfLiteFloat32: return armnn::DataType::Float32; case kTfLiteFloat16: return armnn::DataType::Float16; case kTfLiteUInt8: return armnn::DataType::QAsymmU8; case kTfLiteInt8: { auto quantizationInfo = tfLiteTensor.quantization; if (quantizationInfo.type == kTfLiteAffineQuantization) { auto* quantization = reinterpret_cast(tfLiteTensor.quantization.params); if (quantization->zero_point != nullptr && quantization->zero_point->size == 1) { return armnn::DataType::QAsymmS8; } else { return armnn::DataType::QSymmS8; } } else { return armnn::DataType::QAsymmS8; } } case kTfLiteInt16: return armnn::DataType::QSymmS16; case kTfLiteInt32: return armnn::DataType::Signed32; case kTfLiteInt64: return armnn::DataType::Signed64; default: throw armnn::Exception(&"TfLiteArmnnDelegate: Unsupported data type: " [ tfLiteTensor.type]); } } armnn::TensorInfo GetTensorInfoForTfLiteTensor(const TfLiteTensor& tfLiteTensor, bool isOutput = false) { armnn::DataType type = GetDataType(tfLiteTensor); armnn::TensorInfo ret; auto tensorDimensionSize = tfLiteTensor.dims->size; if (tensorDimensionSize == 0) { // If input tensor does not have a shape // assuming that it has 1D tensor if (!isOutput) { std::vector safeShape = { 1 }; bool dimensionsSpecificity[1] = { true }; armnn::TensorShape tensorShape(armnn::numeric_cast(safeShape.size()), safeShape.data(), dimensionsSpecificity); ret = armnn::TensorInfo(tensorShape, type); if(tflite::IsConstantTensor(&tfLiteTensor)) { ret.SetConstant(true); } } else { armnn::TensorShape tensorShape(armnn::Dimensionality::NotSpecified); ret = armnn::TensorInfo(tensorShape, type); } } else { std::vector tensorDims(static_cast(tensorDimensionSize)); bool dimensionsSpecificity[5] = { true, true, true, true, true }; for (unsigned int i = 0; i < static_cast(tensorDimensionSize); ++i) { auto dim = tfLiteTensor.dims->data[i]; if (dim == 0) { dimensionsSpecificity[i] = false; } tensorDims[i] = static_cast(dim); } armnn::TensorShape tensorShape(static_cast(tensorDimensionSize), tensorDims.data(), dimensionsSpecificity); if(tflite::IsConstantTensor(&tfLiteTensor)) { ret = armnn::TensorInfo(tensorShape, type); ret.SetConstant(true); } else { ret = armnn::TensorInfo(tensorShape, type); } } auto quantizationInfo = tfLiteTensor.quantization; if (quantizationInfo.type == kTfLiteAffineQuantization) { // get per-channel quantization parameters const auto* affineQuantization = reinterpret_cast(tfLiteTensor.quantization.params); if (affineQuantization->scale->size > 1) { std::vector quantizationScales; for (unsigned int i = 0; i < static_cast(affineQuantization->scale->size); ++i) { quantizationScales.push_back(affineQuantization->scale->data[i]); } ret.SetQuantizationScales(quantizationScales); ret.SetQuantizationDim(armnn::numeric_cast(affineQuantization->quantized_dimension)); } else { ret.SetQuantizationScale(affineQuantization->scale->data[0]); ret.SetQuantizationOffset(affineQuantization->zero_point->data[0]); } } else { auto quantizationParameters = tfLiteTensor.params; ret.SetQuantizationScale(quantizationParameters.scale); ret.SetQuantizationOffset(quantizationParameters.zero_point); } return ret; } armnn::ConstTensor CreateConstTensor(const TfLiteTensor* tfLiteTensor, const armnn::TensorInfo& tensorInfo) { if (tfLiteTensor->allocation_type != kTfLiteMmapRo) { throw armnn::Exception( "TfLiteArmnnDelegate: Not constant allocation type: " + std::to_string(tfLiteTensor->allocation_type)); } return armnn::ConstTensor(tensorInfo, tfLiteTensor->data.data); } armnn::ConstTensor* GetConstTensorForTfLiteTensor(const TfLiteTensor* tfLiteTensors, TfLiteNode* tfLiteNode, int index) { const TfLiteTensor &tfLiteTensor = tfLiteTensors[tfLiteNode->inputs->data[index]]; armnn::TensorInfo tensorInfo = GetTensorInfoForTfLiteTensor(tfLiteTensor); return new armnn::ConstTensor(tensorInfo, tfLiteTensor.data.data); } bool IsOptionalOperandPresent(TfLiteNode* tfLiteNode, const int operandIndex) { // If the inputs array has fewer than operandIndex entries or if the entry at operandIndex has a value of -1 or // less then the input is not present. if (tfLiteNode->inputs->size > operandIndex && tfLiteNode->inputs->data[operandIndex] >= 0) { return true; } return false; } TfLiteStatus ProcessInputs(armnn::IConnectableLayer* layer, armnnDelegate::DelegateData& delegateData, TfLiteContext* tfLiteContext, TfLiteNode* tfLiteNode) { const TfLiteTensor* tfLiteTensors = tfLiteContext->tensors; // Process input tensors // If input tensor is a Constant tensor create a constant layer and connect it to the network for (unsigned int inputIndex = 0; inputIndex < layer->GetNumInputSlots(); ++inputIndex) { const TfLiteTensor& tfLiteInputTensor = tfLiteTensors[tfLiteNode->inputs->data[inputIndex]]; if (tflite::IsConstantTensor(&tfLiteInputTensor)) { armnn::TensorInfo inputTensorInfo = GetTensorInfoForTfLiteTensor(tfLiteInputTensor); bool isSupported = false; armnn::BackendId setBackend; FORWARD_LAYER_SUPPORT_FUNC("CONSTANT", tfLiteContext, IsConstantSupported, delegateData.m_Backends, isSupported, setBackend, inputTensorInfo); if (!isSupported) { return kTfLiteError; } auto constantInput = CreateConstTensor(&tfLiteInputTensor, inputTensorInfo); armnn::IConnectableLayer* constantLayer = delegateData.m_Network->AddConstantLayer(constantInput); constantLayer->SetBackendId(setBackend); armnn::IOutputSlot& outputSlot = constantLayer->GetOutputSlot(0); outputSlot.SetTensorInfo(inputTensorInfo); delegateData.m_OutputSlotForNode[tfLiteNode->inputs->data[inputIndex]] = &outputSlot; } } return kTfLiteOk; } } // namespace anonymous