/* Copyright 2020 The TensorFlow Authors. All Rights Reserved. Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except in compliance with the License. You may obtain a copy of the License at http://www.apache.org/licenses/LICENSE-2.0 Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License. ==============================================================================*/ #include "tensorflow/lite/delegates/xnnpack/pad_tester.h" #include #include #include #include #include #include #include #include #include #include #include "fp16.h" // from @FP16 #include "flatbuffers/buffer.h" // from @flatbuffers #include "flatbuffers/flatbuffer_builder.h" // from @flatbuffers #include "flatbuffers/string.h" // from @flatbuffers #include "tensorflow/compiler/mlir/lite/schema/schema_conversion_utils.h" #include "tensorflow/lite/core/interpreter_builder.h" #include "tensorflow/lite/core/kernels/register.h" #include "tensorflow/lite/interpreter.h" #include "tensorflow/lite/schema/schema_generated.h" #include "tensorflow/lite/version.h" namespace tflite { namespace xnnpack { std::vector PadTester::OutputShape() const { std::vector output_shape; output_shape.reserve(InputShape().size()); for (size_t i = 0; i < InputShape().size(); i++) { int32_t output_dim = InputShape()[i]; if (i < InputPrePaddings().size()) { output_dim += InputPrePaddings()[i]; } if (i < InputPostPaddings().size()) { output_dim += InputPostPaddings()[i]; } output_shape.push_back(output_dim); } return output_shape; } void PadTester::Test(TfLiteDelegate* delegate) const { ASSERT_EQ(InputPrePaddings().size(), InputPostPaddings().size()); ASSERT_LE(InputPrePaddings().size(), InputShape().size()); std::random_device random_device; auto rng = std::mt19937(random_device()); auto input_rng = std::bind(std::uniform_real_distribution(), std::ref(rng)); std::vector buffer = CreateTfLiteModel(); const Model* model = GetModel(buffer.data()); std::unique_ptr delegate_interpreter; ASSERT_EQ( InterpreterBuilder( model, ::tflite::ops::builtin::BuiltinOpResolverWithoutDefaultDelegates())( &delegate_interpreter), kTfLiteOk); std::unique_ptr default_interpreter; ASSERT_EQ( InterpreterBuilder( model, ::tflite::ops::builtin::BuiltinOpResolverWithoutDefaultDelegates())( &default_interpreter), kTfLiteOk); ASSERT_TRUE(delegate_interpreter); ASSERT_TRUE(default_interpreter); ASSERT_EQ(delegate_interpreter->inputs().size(), 1); ASSERT_EQ(default_interpreter->inputs().size(), 1); ASSERT_EQ(delegate_interpreter->outputs().size(), 1); ASSERT_EQ(default_interpreter->outputs().size(), 1); ASSERT_EQ(delegate_interpreter->AllocateTensors(), kTfLiteOk); ASSERT_EQ(default_interpreter->AllocateTensors(), kTfLiteOk); ASSERT_EQ(delegate_interpreter->ModifyGraphWithDelegate(delegate), kTfLiteOk); if (FP16()) { TfLiteFloat16* default_input_data = default_interpreter->typed_input_tensor(0); std::generate_n( default_input_data, ComputeSize(InputShape()), [&]() -> TfLiteFloat16 { return TfLiteFloat16{fp16_ieee_from_fp32_value(input_rng())}; }); TfLiteFloat16* delegate_input_data = delegate_interpreter->typed_input_tensor(0); std::copy_n(default_input_data, ComputeSize(InputShape()), delegate_input_data); ASSERT_EQ(default_interpreter->Invoke(), kTfLiteOk); ASSERT_EQ(delegate_interpreter->Invoke(), kTfLiteOk); TfLiteFloat16* default_output_data = default_interpreter->typed_output_tensor(0); TfLiteFloat16* delegate_output_data = delegate_interpreter->typed_output_tensor(0); for (size_t i = 0; i < ComputeSize(OutputShape()); i++) { ASSERT_EQ(default_output_data[i].data, delegate_output_data[i].data); } } else { float* default_input_data = default_interpreter->typed_input_tensor(0); std::generate_n(default_input_data, ComputeSize(InputShape()), std::ref(input_rng)); float* delegate_input_data = delegate_interpreter->typed_input_tensor(0); std::copy_n(default_input_data, ComputeSize(InputShape()), delegate_input_data); ASSERT_EQ(default_interpreter->Invoke(), kTfLiteOk); ASSERT_EQ(delegate_interpreter->Invoke(), kTfLiteOk); float* default_output_data = default_interpreter->typed_output_tensor(0); float* delegate_output_data = delegate_interpreter->typed_output_tensor(0); for (size_t i = 0; i < ComputeSize(OutputShape()); i++) { ASSERT_EQ(default_output_data[i], delegate_output_data[i]); } } } std::vector PadTester::CreateTfLiteModel() const { flatbuffers::FlatBufferBuilder builder; flatbuffers::Offset operator_code = CreateOperatorCode(builder, BuiltinOperator_PAD); std::vector paddings(InputPrePaddings().size() + InputPostPaddings().size()); for (size_t i = 0; i < InputPrePaddings().size(); i++) { paddings[i * 2] = InputPrePaddings()[i]; paddings[i * 2 + 1] = InputPostPaddings()[i]; } const std::array, 2> buffers{{ CreateBuffer(builder, builder.CreateVector({})), CreateBuffer(builder, builder.CreateVector( reinterpret_cast(paddings.data()), sizeof(int32_t) * paddings.size())), }}; const std::vector output_shape = OutputShape(); const std::array paddings_shape{ {static_cast(InputPrePaddings().size()), 2}}; const std::array, 3> tensors{{ CreateTensor(builder, builder.CreateVector(InputShape().data(), InputShape().size()), FP16() ? TensorType_FLOAT16 : TensorType_FLOAT32), CreateTensor(builder, builder.CreateVector(paddings_shape.data(), paddings_shape.size()), TensorType_INT32, /*buffer=*/1), CreateTensor(builder, builder.CreateVector(output_shape.data(), output_shape.size()), FP16() ? TensorType_FLOAT16 : TensorType_FLOAT32), }}; const std::array op_inputs{{0, 1}}; const std::array op_outputs{{2}}; flatbuffers::Offset op = CreateOperator( builder, /*opcode_index=*/0, builder.CreateVector(op_inputs.data(), op_inputs.size()), builder.CreateVector(op_outputs.data(), op_outputs.size())); const std::array subgraph_inputs{{0}}; const std::array subgraph_outputs{{2}}; flatbuffers::Offset subgraph = CreateSubGraph( builder, builder.CreateVector(tensors.data(), tensors.size()), builder.CreateVector(subgraph_inputs.data(), subgraph_inputs.size()), builder.CreateVector(subgraph_outputs.data(), subgraph_outputs.size()), builder.CreateVector(&op, 1)); flatbuffers::Offset description = builder.CreateString("Pad model"); flatbuffers::Offset model_buffer = CreateModel( builder, TFLITE_SCHEMA_VERSION, builder.CreateVector(&operator_code, 1), builder.CreateVector(&subgraph, 1), description, builder.CreateVector(buffers.data(), buffers.size())); builder.Finish(model_buffer); return std::vector(builder.GetBufferPointer(), builder.GetBufferPointer() + builder.GetSize()); } int32_t PadTester::ComputeSize(const std::vector& shape) { return std::accumulate(shape.cbegin(), shape.cend(), 1, std::multiplies()); } } // namespace xnnpack } // namespace tflite