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//
// Copyright © 2022 Arm Ltd and Contributors. All rights reserved.
// SPDX-License-Identifier: MIT
//
#pragma once
#include "DelegateUtils.hpp"
#include <tensorflow/lite/builtin_ops.h>
#include <tensorflow/lite/c/builtin_op_data.h>
#include <tensorflow/lite/c/common.h>
#include <tensorflow/lite/minimal_logging.h>
#include <flatbuffers/flexbuffers.h>
namespace armnnDelegate
{
TfLiteStatus VisitPooling2dOperator(DelegateData& delegateData,
TfLiteContext* tfLiteContext,
TfLiteNode* tfLiteNode,
int nodeIndex,
int32_t tfLitePoolingOperatorCode)
{
TF_LITE_ENSURE_STATUS(ValidateNumInputs(tfLiteContext, tfLiteNode, 1, nodeIndex));
TF_LITE_ENSURE_STATUS(ValidateNumOutputs(tfLiteContext, tfLiteNode, 1, nodeIndex));
const TfLiteTensor* tfLiteTensors = tfLiteContext->tensors;
const TfLiteTensor& tfLiteInputTensor = tfLiteTensors[tfLiteNode->inputs->data[0]];
if (IsDynamicTensor(tfLiteInputTensor))
{
TF_LITE_MAYBE_KERNEL_LOG(
tfLiteContext,
"TfLiteArmnnDelegate: Dynamic input tensors are not supported in operator #%d node #%d: ",
tfLitePoolingOperatorCode, nodeIndex);
return kTfLiteError;
}
const TfLiteTensor& tfLiteOutputTensor = tfLiteTensors[tfLiteNode->outputs->data[0]];
if (IsDynamicTensor(tfLiteOutputTensor))
{
TF_LITE_MAYBE_KERNEL_LOG(
tfLiteContext,
"TfLiteArmnnDelegate: Dynamic output tensors are not supported in operator #%d node #%d: ",
tfLitePoolingOperatorCode, nodeIndex);
return kTfLiteError;
}
const armnn::TensorInfo& inputTensorInfo = GetTensorInfoForTfLiteTensor(tfLiteInputTensor);
const armnn::TensorInfo& outputTensorInfo = GetTensorInfoForTfLiteTensor(tfLiteOutputTensor);
armnn::PoolingAlgorithm poolingAlgorithm;
switch(tfLitePoolingOperatorCode)
{
case kTfLiteBuiltinAveragePool2d:
poolingAlgorithm = armnn::PoolingAlgorithm::Average;
break;
case kTfLiteBuiltinL2Pool2d:
poolingAlgorithm = armnn::PoolingAlgorithm::L2;
break;
case kTfLiteBuiltinMaxPool2d:
poolingAlgorithm = armnn::PoolingAlgorithm::Max;
break;
default:
return kTfLiteError;
}
armnn::Pooling2dDescriptor descriptor;
descriptor.m_PoolType = poolingAlgorithm;
auto* params = reinterpret_cast<TfLitePoolParams*>(tfLiteNode->builtin_data);
descriptor.m_PoolWidth = params->filter_width;
descriptor.m_PoolHeight = params->filter_height;
descriptor.m_StrideX = params->stride_width;
descriptor.m_StrideY = params->stride_height;
descriptor.m_DataLayout = armnn::DataLayout::NHWC;
unsigned int inputHeight = inputTensorInfo.GetShape()[1];
unsigned int inputWidth = inputTensorInfo.GetShape()[2];
CalcPadding(inputHeight, descriptor.m_PoolHeight, descriptor.m_StrideY, 1u,
descriptor.m_PadTop, descriptor.m_PadBottom, params->padding);
CalcPadding(inputWidth, descriptor.m_PoolWidth, descriptor.m_StrideX, 1u,
descriptor.m_PadLeft, descriptor.m_PadRight, params->padding);
bool isSupported = false;
auto validateFunc = [&](const armnn::TensorInfo& outputTensorInfo, bool& isSupported)
{
FORWARD_LAYER_SUPPORT_FUNC("POOLING_2D",
tfLiteContext,
IsPooling2dSupported,
delegateData.m_Backends,
isSupported,
inputTensorInfo,
outputTensorInfo,
descriptor);
};
if (!delegateData.m_Network)
{
validateFunc(outputTensorInfo, isSupported);
return isSupported ? kTfLiteOk : kTfLiteError;
}
armnn::IConnectableLayer* poolingLayer = delegateData.m_Network->AddPooling2dLayer(descriptor);
ARMNN_ASSERT(poolingLayer != nullptr);
armnn::IOutputSlot& outputSlot = poolingLayer->GetOutputSlot(0);
outputSlot.SetTensorInfo(outputTensorInfo);
Connect(poolingLayer, tfLiteNode, delegateData);
// Check activation
TfLiteFusedActivation activationType = params->activation;
return FusedActivation(tfLiteContext, tfLiteNode, activationType, poolingLayer, 0, delegateData);
}
TfLiteStatus VisitPooling3dOperator(DelegateData& delegateData,
TfLiteContext* tfLiteContext,
TfLiteNode* tfLiteNode,
int nodeIndex,
std::string customOperatorName)
{
TF_LITE_ENSURE_STATUS(ValidateNumInputs(tfLiteContext, tfLiteNode, 1, nodeIndex));
TF_LITE_ENSURE_STATUS(ValidateNumOutputs(tfLiteContext, tfLiteNode, 1, nodeIndex));
const TfLiteTensor* tfLiteTensors = tfLiteContext->tensors;
const TfLiteTensor& tfLiteInputTensor = tfLiteTensors[tfLiteNode->inputs->data[0]];
if (IsDynamicTensor(tfLiteInputTensor))
{
TF_LITE_MAYBE_KERNEL_LOG(
tfLiteContext,
"TfLiteArmnnDelegate: Dynamic input tensors are not supported in operator #%d node #%d: ",
customOperatorName.c_str(), nodeIndex);
return kTfLiteError;
}
const TfLiteTensor& tfLiteOutputTensor = tfLiteTensors[tfLiteNode->outputs->data[0]];
if (IsDynamicTensor(tfLiteOutputTensor))
{
TF_LITE_MAYBE_KERNEL_LOG(
tfLiteContext,
"TfLiteArmnnDelegate: Dynamic output tensors are not supported in operator #%d node #%d: ",
customOperatorName.c_str(), nodeIndex);
return kTfLiteError;
}
// Set the input and output info
const armnn::TensorInfo& inputTensorInfo = GetTensorInfoForTfLiteTensor(tfLiteInputTensor);
const armnn::TensorInfo& outputTensorInfo = GetTensorInfoForTfLiteTensor(tfLiteOutputTensor);
// Custom Operators are defined by the name string associated to the operator. Use this to determine
// which pooling algorithm to create the armnn operator with. L2 Pooling3D is unsupported in TfLite.
armnn::PoolingAlgorithm poolingAlgorithm;
if (customOperatorName == "MaxPool3D")
{
poolingAlgorithm = armnn::PoolingAlgorithm::Max;
}
else if (customOperatorName == "AveragePool3D")
{
poolingAlgorithm = armnn::PoolingAlgorithm::Average;
}
else
{
return kTfLiteError;
}
// Create the armnn pool3d descriptor and set the algorithm parsed above.
armnn::Pooling3dDescriptor descriptor;
descriptor.m_PoolType = poolingAlgorithm;
// custom_initial_data and custom_initial_data_size are void* variables defined in the tflite registration
// used to access the custom option buffer for the operator.
auto custom_data = tfLiteNode->custom_initial_data;
auto custom_data_size = tfLiteNode->custom_initial_data_size;
// Reinterpret the void* to a byte buffer to access the options data in the flexbuffers map.
const flexbuffers::Map& m = flexbuffers::GetRoot(reinterpret_cast<const uint8_t*>(custom_data),
custom_data_size).AsMap();
// poolDims is a vector of [ 1, Depth, Height, Width, 1 ]
const auto poolDims = m["ksize"].AsTypedVector();
descriptor.m_PoolWidth = poolDims[3].AsInt32();
descriptor.m_PoolHeight = poolDims[2].AsInt32();
descriptor.m_PoolDepth = poolDims[1].AsInt32();
// strideDimes is a vector of [ 1, Z, Y, X, 1]
const auto strideDims = m["strides"].AsTypedVector();
descriptor.m_StrideX = strideDims[3].AsInt32();
descriptor.m_StrideY = strideDims[2].AsInt32();
descriptor.m_StrideZ = strideDims[1].AsInt32();
descriptor.m_DataLayout = armnn::DataLayout::NDHWC;
unsigned int inputDepth = inputTensorInfo.GetShape()[1];
unsigned int inputHeight = inputTensorInfo.GetShape()[2];
unsigned int inputWidth = inputTensorInfo.GetShape()[3];
// CalcPadding expects a TfLitePadding type. Parse flexbuffers to extract padding string and create TfLitePadding.
std::string paddingStr = m["padding"].AsString().str();
TfLitePadding padding;
if (paddingStr == "VALID")
{
padding = kTfLitePaddingValid;
}
else if (paddingStr == "SAME")
{
padding = kTfLitePaddingSame;
}
else
{
padding = kTfLitePaddingUnknown;
}
// Calculates padding for each pooling dimension separately
CalcPadding(inputHeight, descriptor.m_PoolHeight, descriptor.m_StrideY, 1u,
descriptor.m_PadTop, descriptor.m_PadBottom, padding);
CalcPadding(inputWidth, descriptor.m_PoolWidth, descriptor.m_StrideX, 1u,
descriptor.m_PadLeft, descriptor.m_PadRight, padding);
CalcPadding(inputDepth, descriptor.m_PoolDepth, descriptor.m_StrideZ, 1u,
descriptor.m_PadFront, descriptor.m_PadBack, padding);
// Validate the output info.
bool isSupported = false;
auto validateFunc = [&](const armnn::TensorInfo& outputTensorInfo, bool& isSupported) {
FORWARD_LAYER_SUPPORT_FUNC("POOLING_3D",
tfLiteContext,
IsPooling3dSupported,
delegateData.m_Backends,
isSupported,
inputTensorInfo,
outputTensorInfo,
descriptor);
};
if (!delegateData.m_Network)
{
validateFunc(outputTensorInfo, isSupported);
return isSupported ? kTfLiteOk : kTfLiteError;
}
// Create the Layer
armnn::IConnectableLayer* poolingLayer = delegateData.m_Network->AddPooling3dLayer(descriptor);
ARMNN_ASSERT(poolingLayer != nullptr);
// Create and set output slots
armnn::IOutputSlot& outputSlot = poolingLayer->GetOutputSlot(0);
outputSlot.SetTensorInfo(outputTensorInfo);
Connect(poolingLayer, tfLiteNode, delegateData);
// Check activation by parsing the string from the flexbuffer map
std::string activationTypeStr = m["activation"].AsString().str();
TfLiteFusedActivation activationType;
if (activationTypeStr == "kTfLiteActRelu")
{
activationType = kTfLiteActRelu;
}
else if (activationTypeStr == "kTfLiteActReluN1To1")
{
activationType = kTfLiteActReluN1To1;
}
else if (activationTypeStr == "kTfLiteActRelu6")
{
activationType = kTfLiteActRelu6;
}
else if (activationTypeStr == "kTfLiteActTanh")
{
activationType = kTfLiteActTanh;
}
else if (activationTypeStr == "kTfLiteActSignBit")
{
activationType = kTfLiteActSignBit;
}
else if (activationTypeStr == "kTfLiteActSigmoid")
{
activationType = kTfLiteActSigmoid;
}
else
{
activationType = kTfLiteActNone;
}
return FusedActivation(tfLiteContext, tfLiteNode, activationType, poolingLayer, 0, delegateData);
}
} // namespace armnnDelegate
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