delegate/opaque/src/LogicalBinary.hpp - ml/armnn - Gitiles

 //
 // Copyright © 2023 Arm Ltd and Contributors. All rights reserved.
 // SPDX-License-Identifier: MIT
 //

 #pragma once

 #include <OpaqueDelegateUtils.hpp>

 namespace armnnOpaqueDelegate
 {

 std::string GetLayerName(armnn::LogicalBinaryOperation logicalBinaryOperation)
 {
     std::string layerName = "LOGICAL_BINARY";
     switch (logicalBinaryOperation)
     {
         case armnn::LogicalBinaryOperation::LogicalAnd:
             layerName += " LOGICAL_AND";
             break;
         case armnn::LogicalBinaryOperation::LogicalOr:
             layerName += " LOGICAL_OR";
             break;
         default:
             layerName += " UNKNOWN";
     }
     return layerName;
 }

 TfLiteStatus VisitLogicalBinaryOperator(DelegateData& delegateData,
                                         TfLiteOpaqueContext* tfLiteContext,
                                         TfLiteOpaqueNode* tfLiteNode,
                                         int nodeIndex,
                                         int32_t logicalOperatorCode,
                                         armnn::LogicalBinaryOperation binaryOperation)
 {
     TF_LITE_ENSURE_STATUS(ValidateNumInputs(tfLiteContext, tfLiteNode, 2, nodeIndex));
     TF_LITE_ENSURE_STATUS(ValidateNumOutputs(tfLiteContext, tfLiteNode, 1, nodeIndex));

     // Gather input indices and use to get input tensor.
     int numInputs = 0;
     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;
     }

     // Use input indices to get input tensors.
     const TfLiteOpaqueTensor* tfLiteInputTensor0 = TfLiteOpaqueContextGetOpaqueTensor(tfLiteContext, inputTensors[0]);
     if (!IsValid(tfLiteContext, tfLiteInputTensor0, logicalOperatorCode, nodeIndex))
     {
         return kTfLiteError;
     }

     const TfLiteOpaqueTensor* tfLiteInputTensor1 = TfLiteOpaqueContextGetOpaqueTensor(tfLiteContext, inputTensors[1]);
     if (!IsValid(tfLiteContext, tfLiteInputTensor1, logicalOperatorCode, nodeIndex))
     {
         return kTfLiteError;
     }

     // Gather output indices and use to get 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;
     }

     // Use output indices to get output tensor.
     const TfLiteOpaqueTensor* tfLiteOutputTensor = TfLiteOpaqueContextGetOpaqueTensor(tfLiteContext, outputTensors[0]);
     if (!IsValid(tfLiteContext, tfLiteOutputTensor, logicalOperatorCode, nodeIndex))
     {
         return kTfLiteError;
     }

     armnn::TensorInfo inputTensorInfo0 = GetTensorInfoForTfLiteOpaqueTensor(tfLiteInputTensor0);
     armnn::TensorInfo inputTensorInfo1 = GetTensorInfoForTfLiteOpaqueTensor(tfLiteInputTensor1);
     const armnn::TensorInfo& outputTensorInfo = GetTensorInfoForTfLiteOpaqueTensor(tfLiteOutputTensor, true);

     // Check if we need to expand the dims of any input tensor infos.
     // This is required for a few of the backends.
     if(inputTensorInfo0.GetNumDimensions() != inputTensorInfo1.GetNumDimensions())
     {
         ExpandTensorRankToEqual(inputTensorInfo0, inputTensorInfo1);
     }

     // Setup descriptor and assign operation
     armnn::LogicalBinaryDescriptor desc;
     desc.m_Operation = binaryOperation;

     // Check if supported
     bool isSupported = false;
     armnn::BackendId setBackend;
     auto validateFunc = [&](const armnn::TensorInfo& outputTensorInfo, bool& isSupported, std::string layerName)
     {
         FORWARD_LAYER_OPAQUE_SUPPORT_FUNC(layerName.c_str(),
                                           tfLiteContext,
                                           IsLogicalBinarySupported,
                                           delegateData.m_Backends,
                                           isSupported,
                                           setBackend,
                                           inputTensorInfo0,
                                           inputTensorInfo1,
                                           outputTensorInfo,
                                           desc);
     };

     if (!delegateData.m_Network)
     {
         validateFunc(outputTensorInfo, isSupported, GetLayerName(binaryOperation));
         return isSupported ? kTfLiteOk : kTfLiteError;
     }

     armnn::IConnectableLayer* logicalBinaryLayer = delegateData.m_Network->AddLogicalBinaryLayer(desc);
     logicalBinaryLayer->SetBackendId(setBackend);
     ARMNN_ASSERT(logicalBinaryLayer != nullptr);

     armnn::IOutputSlot& outputSlot = logicalBinaryLayer->GetOutputSlot(0);
     outputSlot.SetTensorInfo(outputTensorInfo);

     auto inputsTensorsProcess = ProcessInputs(logicalBinaryLayer,
                                               delegateData,
                                               tfLiteContext,
                                               tfLiteNode);
     if (inputsTensorsProcess == kTfLiteError)
     {
         return inputsTensorsProcess;
     }

     return Connect(logicalBinaryLayer, tfLiteContext, tfLiteNode, delegateData);
 }

 } // namespace armnnOpaqueDelegate
	//
	// Copyright © 2023 Arm Ltd and Contributors. All rights reserved.
	// SPDX-License-Identifier: MIT
	//

	#pragma once

	#include <OpaqueDelegateUtils.hpp>

	namespace armnnOpaqueDelegate
	{

	std::string GetLayerName(armnn::LogicalBinaryOperation logicalBinaryOperation)
	{
	std::string layerName = "LOGICAL_BINARY";
	switch (logicalBinaryOperation)
	{
	case armnn::LogicalBinaryOperation::LogicalAnd:
	layerName += " LOGICAL_AND";
	break;
	case armnn::LogicalBinaryOperation::LogicalOr:
	layerName += " LOGICAL_OR";
	break;
	default:
	layerName += " UNKNOWN";
	}
	return layerName;
	}

	TfLiteStatus VisitLogicalBinaryOperator(DelegateData& delegateData,
	TfLiteOpaqueContext* tfLiteContext,
	TfLiteOpaqueNode* tfLiteNode,
	int nodeIndex,
	int32_t logicalOperatorCode,
	armnn::LogicalBinaryOperation binaryOperation)
	{
	TF_LITE_ENSURE_STATUS(ValidateNumInputs(tfLiteContext, tfLiteNode, 2, nodeIndex));
	TF_LITE_ENSURE_STATUS(ValidateNumOutputs(tfLiteContext, tfLiteNode, 1, nodeIndex));

	// Gather input indices and use to get input tensor.
	int numInputs = 0;
	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;
	}

	// Use input indices to get input tensors.
	const TfLiteOpaqueTensor* tfLiteInputTensor0 = TfLiteOpaqueContextGetOpaqueTensor(tfLiteContext, inputTensors[0]);
	if (!IsValid(tfLiteContext, tfLiteInputTensor0, logicalOperatorCode, nodeIndex))
	{
	return kTfLiteError;
	}

	const TfLiteOpaqueTensor* tfLiteInputTensor1 = TfLiteOpaqueContextGetOpaqueTensor(tfLiteContext, inputTensors[1]);
	if (!IsValid(tfLiteContext, tfLiteInputTensor1, logicalOperatorCode, nodeIndex))
	{
	return kTfLiteError;
	}

	// Gather output indices and use to get 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;
	}

	// Use output indices to get output tensor.
	const TfLiteOpaqueTensor* tfLiteOutputTensor = TfLiteOpaqueContextGetOpaqueTensor(tfLiteContext, outputTensors[0]);
	if (!IsValid(tfLiteContext, tfLiteOutputTensor, logicalOperatorCode, nodeIndex))
	{
	return kTfLiteError;
	}

	armnn::TensorInfo inputTensorInfo0 = GetTensorInfoForTfLiteOpaqueTensor(tfLiteInputTensor0);
	armnn::TensorInfo inputTensorInfo1 = GetTensorInfoForTfLiteOpaqueTensor(tfLiteInputTensor1);
	const armnn::TensorInfo& outputTensorInfo = GetTensorInfoForTfLiteOpaqueTensor(tfLiteOutputTensor, true);

	// Check if we need to expand the dims of any input tensor infos.
	// This is required for a few of the backends.
	if(inputTensorInfo0.GetNumDimensions() != inputTensorInfo1.GetNumDimensions())
	{
	ExpandTensorRankToEqual(inputTensorInfo0, inputTensorInfo1);
	}

	// Setup descriptor and assign operation
	armnn::LogicalBinaryDescriptor desc;
	desc.m_Operation = binaryOperation;

	// Check if supported
	bool isSupported = false;
	armnn::BackendId setBackend;
	auto validateFunc = [&](const armnn::TensorInfo& outputTensorInfo, bool& isSupported, std::string layerName)
	{
	FORWARD_LAYER_OPAQUE_SUPPORT_FUNC(layerName.c_str(),
	tfLiteContext,
	IsLogicalBinarySupported,
	delegateData.m_Backends,
	isSupported,
	setBackend,
	inputTensorInfo0,
	inputTensorInfo1,
	outputTensorInfo,
	desc);
	};

	if (!delegateData.m_Network)
	{
	validateFunc(outputTensorInfo, isSupported, GetLayerName(binaryOperation));
	return isSupported ? kTfLiteOk : kTfLiteError;
	}

	armnn::IConnectableLayer* logicalBinaryLayer = delegateData.m_Network->AddLogicalBinaryLayer(desc);
	logicalBinaryLayer->SetBackendId(setBackend);
	ARMNN_ASSERT(logicalBinaryLayer != nullptr);

	armnn::IOutputSlot& outputSlot = logicalBinaryLayer->GetOutputSlot(0);
	outputSlot.SetTensorInfo(outputTensorInfo);

	auto inputsTensorsProcess = ProcessInputs(logicalBinaryLayer,
	delegateData,
	tfLiteContext,
	tfLiteNode);
	if (inputsTensorsProcess == kTfLiteError)
	{
	return inputsTensorsProcess;
	}

	return Connect(logicalBinaryLayer, tfLiteContext, tfLiteNode, delegateData);
	}

	} // namespace armnnOpaqueDelegate