ArmNN
 26.07
DepthwiseConv2dOperator.hpp File Reference
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Functions

TosaSerializationBasicBlock * ConvertDepthwiseConv2dToTosaOperator (const Layer *layer, const std::vector< const TensorInfo * > &inputs, const std::vector< const TensorInfo * > &outputs, const DepthwiseConvolution2dDescriptor *conv2dDescriptor)
 

Function Documentation

◆ ConvertDepthwiseConv2dToTosaOperator()

TosaSerializationBasicBlock* ConvertDepthwiseConv2dToTosaOperator ( const Layer layer,
const std::vector< const TensorInfo * > &  inputs,
const std::vector< const TensorInfo * > &  outputs,
const DepthwiseConvolution2dDescriptor conv2dDescriptor 
)

Definition at line 10 of file DepthwiseConv2dOperator.cpp.

15 {
16  std::vector<std::string> inputNames;
17  std::string outputName = std::string("output0_");
18  std::string blockName = std::string("Op_DEPTHWISE_CONV2D_block_") + GetUniqueTosaMappingID();
19 
20  DType inputDType0 = ArmNNToDType(inputs[0]->GetDataType());
21  DType outputDType0 = ArmNNToDType(outputs[0]->GetDataType());
22 
23  // Set input names for validation purposes only.
24  if(layer == nullptr)
25  {
26  inputNames.emplace_back("input_0");
27  inputNames.emplace_back("input_1");
28  if(conv2dDescriptor->m_BiasEnabled)
29  {
30  inputNames.emplace_back("input_2");
31  }
32  }
33  // If a layer is present then the block will be used for execution, so input and output names need to be
34  // determined using the previous and following layers so the graph is connected correctly.
35  // For validation this doesn't matter.
36  else
37  {
38  // Get the layer connected to the input slot and determine unique tensor names.
39  for (uint32_t i = 0; i < inputs.size(); ++i)
40  {
41  std::string inputName = GenerateUniqueInputName(layer->GetInputSlot(i));
42  inputNames.push_back(inputName);
43  }
44 
45  // Determine unique output tensor name.
46  outputName = GenerateUniqueOutputName(*layer);
47  }
48 
49  std::vector<TosaSerializationTensor*> tensors;
50  std::vector<TosaSerializationOperator*> operators;
51 
52  // Setup input Tensor
53  // Only add tensor if connected layer is an input layer.
54  // As intermediate or constant tensors will be created separately.
55  // There also can't be duplicate tensors.
56  std::vector<int32_t> inputShape0 = GetTosaTensorShape(inputs[0]->GetShape());
57  if(inputNames[0].find("input_") != std::string::npos)
58  {
59  tensors.push_back(new TosaSerializationTensor(inputNames[0], inputShape0, inputDType0, {}));
60  }
61 
62  // Only add input tensors if weights and bias are not constant or if running validation.
63  // Constant tensors will be created in the ConvertConstantToTosaOperator function.
64  std::vector<int32_t> inputShape1 = GetTosaTensorShape(inputs[1]->GetShape());
65  if(!inputs[1]->IsConstant() || layer == nullptr)
66  {
67  int32_t multiplier = inputShape1[3]/inputShape0[3];
68 
69  // TOSA requires depthwise conv2d kernel to be converted from from [1, H, W, C * M] to [H, W, C, M]
70  std::vector<int32_t> inputShapeHWCM = {
71  inputShape1[1], inputShape1[2], inputShape0[3], multiplier
72  };
73 
74  DType inputDType1 = ArmNNToDType(inputs[1]->GetDataType());
75 
76  tensors.push_back(new TosaSerializationTensor(inputNames[1], inputShapeHWCM, inputDType1, {}));
77  }
78 
79  if(conv2dDescriptor->m_BiasEnabled)
80  {
81  if(!inputs[2]->IsConstant() || layer == nullptr)
82  {
83  std::vector<int32_t> inputShape2 = GetTosaTensorShape(inputs[2]->GetShape());
84  DType inputDType2 = ArmNNToDType(inputs[2]->GetDataType());
85 
86  tensors.push_back(new TosaSerializationTensor(inputNames[2], inputShape2, inputDType2, {}));
87  }
88  }
89  else
90  {
91  // If bias is disabled, create a constant bias of 0 as three inputs are required.
92  std::string constantName = std::string("constant_") + GetUniqueTosaMappingID();
93 
94  operators.push_back(new TosaSerializationOperator(Op_CONST, Attribute_NONE, nullptr, {}, {constantName}));
95 
96  // The size of the bias must match the channels dimension, so get the correct index.
97  unsigned int index = (conv2dDescriptor->m_DataLayout == DataLayout::NHWC) ? 3 : 1;
98 
99  const DType dType = (inputDType0 == DType_INT8) ? DType_INT32 : outputDType0;
100  std::vector<float> data(outputs[0]->GetShape()[index], 0);
101 
102  std::vector<uint8_t> uint8Data;
103  TosaSerializationHandler::ConvertF32toU8(data, uint8Data);
104 
105  tensors.push_back(new TosaSerializationTensor(constantName,
106  {static_cast<int32_t>(outputs[0]->GetShape()[index])},
107  dType,
108  uint8Data));
109  inputNames.emplace_back(constantName);
110  }
111 
112  // Setup Output Tensor
113  std::vector<int32_t> outputShape0 = {GetTosaTensorShape(outputs[0]->GetShape())};
114  std::string outputConv2dName;
115  bool isInputInt8 = (inputDType0 == DType_INT8);
116  if (isInputInt8)
117  {
118  outputConv2dName = std::string("layer_intermediate0_") + GetUniqueTosaMappingID();
119  tensors.push_back(new TosaSerializationTensor(outputConv2dName, outputShape0, DType_INT32, {}));
120  }
121  else
122  {
123  tensors.push_back(new TosaSerializationTensor(outputName, outputShape0, outputDType0, {}));
124  }
125 
126  // Set up CONV2D operator
127  std::vector<int> pad = {static_cast<int>(conv2dDescriptor->m_PadTop),
128  static_cast<int>(conv2dDescriptor->m_PadBottom),
129  static_cast<int>(conv2dDescriptor->m_PadLeft),
130  static_cast<int>(conv2dDescriptor->m_PadRight)};
131  std::vector<int> stride = {static_cast<int>(conv2dDescriptor->m_StrideY),
132  static_cast<int>(conv2dDescriptor->m_StrideX)};
133  std::vector<int> dilation = {static_cast<int>(conv2dDescriptor->m_DilationY),
134  static_cast<int>(conv2dDescriptor->m_DilationX)};
135  TosaConvAttribute attribute(pad, stride, dilation,
136  inputs[0]->GetQuantizationOffset(), // input_zp
137  inputs[1]->GetQuantizationOffset(), // weight_zp
138  false); // local_bound
139 
140  std::string sliceOutputName = GetInputSlicedToItsUsedSize(inputShape0,
141  inputNames[0],
142  conv2dDescriptor->m_DataLayout,
143  inputDType0,
144  inputShape1,
145  pad,
146  stride,
147  dilation,
148  tensors,
149  operators);
150 
151  std::string& convOutStr = isInputInt8 ? outputConv2dName : outputName;
152  auto* conv2d_op = new TosaSerializationOperator(Op_DEPTHWISE_CONV2D,
153  Attribute_ConvAttribute,
154  &attribute,
155  {sliceOutputName, inputNames[1], inputNames[2]},
156  {convOutStr});
157  operators.push_back(conv2d_op);
158 
159  if (isInputInt8)
160  {
161  int32_t output_zp = outputs[0]->GetQuantizationOffset();
162  double output_scale = outputs[0]->GetQuantizationScales()[0];
163  double input_scale = inputs[0]->GetQuantizationScales()[0];
164  const std::vector<float>& weight_scales = inputs[1]->GetQuantizationScales();
165 
166  TosaSerializationOperator* rescaleOp = nullptr;
167  CreateRescaleTosaOperatorForWeights(outputConv2dName,
168  outputName,
169  0,
170  output_zp,
171  false,
172  false,
173  true,
174  true,
175  input_scale,
176  output_scale,
177  weight_scales,
178  &rescaleOp);
179  operators.push_back(rescaleOp);
180  tensors.push_back(new TosaSerializationTensor(outputName,
181  outputShape0,
182  DType_INT8, {}));
183  }
184 
185  // operatorInputNames/operatorOutputNames ends up being the same as
186  // blockInputNames/blockOutputNames for one-to-one ArmNN to TOSA mappings
187  return new TosaSerializationBasicBlock(blockName, // name
188  mainName, // region name
189  operators, // operators
190  tensors, // tensors
191  inputNames, // inputs
192  {outputName}); // outputs
193 }
std::string GenerateUniqueOutputName(const Layer &layer, uint32_t layerSlot=0)
const std::string mainName
DType ArmNNToDType(const DataType &type)
std::vector< int32_t > GetTosaTensorShape(const TensorShape &shape)
std::string GenerateUniqueInputName(const armnn::InputSlot &slot)
std::string GetInputSlicedToItsUsedSize(const std::vector< int32_t > &inputShape, const std::string &inputName, const DataLayout layout, const DType datatype, const std::vector< int32_t > &kernel, const std::vector< int32_t > &pad, const std::vector< int32_t > &stride, const std::vector< int32_t > &dilations, std::vector< TosaSerializationTensor * > &tensors, std::vector< TosaSerializationOperator * > &operators, const bool isPoolingOp=false)
std::string GetUniqueTosaMappingID()
void CreateRescaleTosaOperatorForWeights(const std::string &inputName, const std::string &outputName, int32_t input_zp, int32_t output_zp, bool input_unsigned, bool output_unsigned, bool double_round, bool scale32, double input_scale, double output_scale, const std::vector< float > &weight_scales, TosaSerializationOperator **op)
Creates a TOSA rescale operator for weight tensors.
const InputSlot & GetInputSlot(unsigned int index) const override
Get a const input slot handle by slot index.
Definition: Layer.hpp:337
uint32_t m_PadRight
Padding right value in the width dimension.
uint32_t m_DilationY
Dilation factor value for height dimension.
uint32_t m_PadTop
Padding top value in the height dimension.
DataLayout m_DataLayout
The data layout to be used (NCHW, NHWC).
uint32_t m_DilationX
Dilation factor value for width dimension.
uint32_t m_PadBottom
Padding bottom value in the height dimension.
uint32_t m_PadLeft
Padding left value in the width dimension.
uint32_t m_StrideY
Stride value when proceeding through input for the height dimension.
bool m_BiasEnabled
Enable/disable bias.
uint32_t m_StrideX
Stride value when proceeding through input for the width dimension.

References ArmNNToDType(), GenerateUniqueInputName(), GenerateUniqueOutputName(), Layer::GetInputSlot(), GetTosaTensorShape(), GetUniqueTosaMappingID(), and DepthwiseConvolution2dDescriptor::m_BiasEnabled.

Referenced by GetTosaMapping().