// // Copyright © 2023 Arm Ltd and Contributors. All rights reserved. // SPDX-License-Identifier: MIT // #pragma once #include namespace armnnOpaqueDelegate { TfLiteStatus ValidateTileOperator(DelegateData& delegateData, TfLiteOpaqueContext *tfLiteContext, const armnn::TensorInfo& inputInfo, const armnn::TensorInfo& outputInfo, const armnn::TileDescriptor& descriptor) { bool isSupported = false; FORWARD_LAYER_OPAQUE_SUPPORT_FUNC("TILE", tfLiteContext, IsTileSupported, delegateData.m_Backends, isSupported, armnn::BackendId(), inputInfo, outputInfo, descriptor); return isSupported ? kTfLiteOk : kTfLiteError; } TfLiteStatus VisitTileOperator(DelegateData& delegateData, TfLiteOpaqueContext* tfLiteContext, TfLiteOpaqueNode* tfLiteNode, int nodeIndex, int32_t tileOperatorCode) { TF_LITE_ENSURE_STATUS(ValidateNumInputs(tfLiteContext, tfLiteNode, 2, nodeIndex)); TF_LITE_ENSURE_STATUS(ValidateNumOutputs(tfLiteContext, tfLiteNode, 1, nodeIndex)); // Gather input tensors auto numInputs = TfLiteOpaqueNodeNumberOfInputs(tfLiteNode); const int* inputTensors; if (TfLiteOpaqueNodeInputs(tfLiteNode, &inputTensors, &numInputs) != kTfLiteOk) { TF_LITE_OPAQUE_MAYBE_KERNEL_LOG( tfLiteContext, "TfLiteArmnnOpaqueDelegate: Unable to gather input tensor indices from node #%d: ", nodeIndex); return kTfLiteError; } // Gather output tensors int numOutputs = 0; const int* outputTensors; if (TfLiteOpaqueNodeOutputs(tfLiteNode, &outputTensors, &numOutputs) != kTfLiteOk) { TF_LITE_OPAQUE_MAYBE_KERNEL_LOG( tfLiteContext, "TfLiteArmnnOpaqueDelegate: Unable to gather output tensor indices from node #%d: ", nodeIndex); return kTfLiteError; } // The input contains the data that should be tiled const TfLiteOpaqueTensor* tfLiteInputTensor = TfLiteOpaqueContextGetOpaqueTensor(tfLiteContext, inputTensors[0]); if (IsDynamicTensor(tfLiteInputTensor)) { TF_LITE_OPAQUE_MAYBE_KERNEL_LOG( tfLiteContext, "TfLiteArmnnOpaqueDelegate: Dynamic input tensors are not supported in operator #%d node #%d: ", tileOperatorCode, nodeIndex); return kTfLiteError; } // The multiples tensor contains the number of copies for each axis const TfLiteOpaqueTensor* tfLiteMultiplesTensor = TfLiteOpaqueContextGetOpaqueTensor(tfLiteContext, inputTensors[1]);; if (IsDynamicTensor(tfLiteMultiplesTensor)) { TF_LITE_OPAQUE_MAYBE_KERNEL_LOG( tfLiteContext, "TfLiteArmnnOpaqueDelegate: Dynamic input tensors are not supported in operator #%d node #%d: ", tileOperatorCode, nodeIndex); return kTfLiteError; } // The output tensor const TfLiteOpaqueTensor* tfLiteOutputTensor = TfLiteOpaqueContextGetOpaqueTensor(tfLiteContext, outputTensors[0]); if (IsDynamicTensor(tfLiteOutputTensor)) { TF_LITE_OPAQUE_MAYBE_KERNEL_LOG( tfLiteContext, "TfLiteArmnnOpaqueDelegate: Dynamic output tensors are not supported in operator #%d node #%d: ", tileOperatorCode, nodeIndex); return kTfLiteError; } const armnn::TensorInfo& inputTensorInfo = GetTensorInfoForTfLiteOpaqueTensor(tfLiteInputTensor); const armnn::TensorInfo& multiplesTensorInfo = GetTensorInfoForTfLiteOpaqueTensor(tfLiteMultiplesTensor); const armnn::TensorInfo& outputTensorInfo = GetTensorInfoForTfLiteOpaqueTensor(tfLiteOutputTensor, true); // Multiples length must be the same as the number of dimension in input tensor if (multiplesTensorInfo.GetNumElements() != inputTensorInfo.GetNumDimensions()) { TF_LITE_OPAQUE_MAYBE_KERNEL_LOG( tfLiteContext, "TfLiteArmnnOpaqueDelegate:", "The Multiples length must be the same as the number of dimension in input tensor", "Operator: #%d node #%d: ", tileOperatorCode, nodeIndex); return kTfLiteError; } // Get the Multiples data: In armnn, the values of the multiples input tensor is saved in the operator descriptor // We have to read it from the input tensor and write it the descriptor auto* multiplesTensorDataPtr = static_cast(TfLiteOpaqueTensorData(tfLiteMultiplesTensor)); auto multiplesTensorNum = TfLiteOpaqueTensorDim(tfLiteMultiplesTensor, 0); std::vector multiplesIntData(multiplesTensorDataPtr, multiplesTensorDataPtr + multiplesTensorNum); // The multiples must be positive for (auto multiple : multiplesIntData) { if (multiple < 0) { TF_LITE_OPAQUE_MAYBE_KERNEL_LOG( tfLiteContext, "TfLiteArmnnOpaqueDelegate: The Multiples must be positive values", "Operator: #%d node #%d: ", tileOperatorCode, nodeIndex); return kTfLiteError; } } // The original input from TFLite is int32, and we have to make it as uint32 for our descriptor std::vector multiplesUintData; std::transform(multiplesIntData.begin(), multiplesIntData.end(), std::back_inserter(multiplesUintData), [] (const int value) { return static_cast(value); }); armnn::TileDescriptor tileDescriptor; tileDescriptor.m_Multiples = multiplesUintData; // Check output dimensions if (inputTensorInfo.GetNumDimensions() != outputTensorInfo.GetNumDimensions()) { TF_LITE_OPAQUE_MAYBE_KERNEL_LOG( tfLiteContext, "TfLiteArmnnOpaqueDelegate: Input tensor dimension and output tensor dimension differ", "Operator: #%d node #%d: ", tileOperatorCode, nodeIndex); return kTfLiteError; } // No network pointer indicates that only support for this operator should be checked if (!delegateData.m_Network) { return ValidateTileOperator(delegateData, tfLiteContext, inputTensorInfo, outputTensorInfo, tileDescriptor); } auto layerName = GetName(armnn::LayerType::Tile, nodeIndex); armnn::IConnectableLayer* layer = delegateData.m_Network->AddTileLayer(tileDescriptor, layerName.c_str()); if (layer == nullptr) { return kTfLiteError; } layer->GetOutputSlot(0).SetTensorInfo(outputTensorInfo); if (ProcessInputs(layer, delegateData, tfLiteContext, tfLiteNode, nodeIndex) != kTfLiteOk) { return kTfLiteError; } return Connect(layer, tfLiteContext, tfLiteNode, delegateData); } } // namespace armnnOpaqueDelegate