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423 lines
17 KiB
423 lines
17 KiB
4 months ago
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/*
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* Copyright (C) 2017 The Android Open Source Project
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*
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* Licensed under the Apache License, Version 2.0 (the "License");
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* you may not use this file except in compliance with the License.
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* You may obtain a copy of the License at
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*
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* http://www.apache.org/licenses/LICENSE-2.0
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*
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* Unless required by applicable law or agreed to in writing, software
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* distributed under the License is distributed on an "AS IS" BASIS,
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* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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* See the License for the specific language governing permissions and
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* limitations under the License.
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*/
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#include <gmock/gmock.h>
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#include <gtest/gtest.h>
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#include <vector>
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#include "NeuralNetworksWrapper.h"
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#include "SVDF.h"
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using ::testing::FloatNear;
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using ::testing::Matcher;
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namespace android {
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namespace nn {
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namespace wrapper {
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namespace {
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std::vector<Matcher<float>> ArrayFloatNear(const std::vector<float>& values,
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float max_abs_error = 1.e-6) {
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std::vector<Matcher<float>> matchers;
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matchers.reserve(values.size());
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for (const float& v : values) {
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matchers.emplace_back(FloatNear(v, max_abs_error));
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}
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return matchers;
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}
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} // namespace
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using ::testing::ElementsAreArray;
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static float svdf_input[] = {
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0.12609188, -0.46347019, -0.89598465, 0.12609188, -0.46347019, -0.89598465,
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0.14278367, -1.64410412, -0.75222826, 0.14278367, -1.64410412, -0.75222826,
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0.49837467, 0.19278903, 0.26584083, 0.49837467, 0.19278903, 0.26584083,
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-0.11186574, 0.13164264, -0.05349274, -0.11186574, 0.13164264, -0.05349274,
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-0.68892461, 0.37783599, 0.18263303, -0.68892461, 0.37783599, 0.18263303,
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-0.81299269, -0.86831826, 1.43940818, -0.81299269, -0.86831826, 1.43940818,
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-1.45006323, -0.82251364, -1.69082689, -1.45006323, -0.82251364, -1.69082689,
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0.03966608, -0.24936394, -0.77526885, 0.03966608, -0.24936394, -0.77526885,
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0.11771342, -0.23761693, -0.65898693, 0.11771342, -0.23761693, -0.65898693,
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-0.89477462, 1.67204106, -0.53235275, -0.89477462, 1.67204106, -0.53235275};
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static float svdf_input_rank2[] = {
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0.12609188, -0.46347019, -0.89598465, 0.35867718, 0.36897406, 0.73463392,
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0.14278367, -1.64410412, -0.75222826, -0.57290924, 0.12729003, 0.7567004,
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0.49837467, 0.19278903, 0.26584083, 0.17660543, 0.52949083, -0.77931279,
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-0.11186574, 0.13164264, -0.05349274, -0.72674477, -0.5683046, 0.55900657,
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-0.68892461, 0.37783599, 0.18263303, -0.63690937, 0.44483393, -0.71817774,
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-0.81299269, -0.86831826, 1.43940818, -0.95760226, 1.82078898, 0.71135032,
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-1.45006323, -0.82251364, -1.69082689, -1.65087092, -1.89238167, 1.54172635,
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0.03966608, -0.24936394, -0.77526885, 2.06740379, -1.51439476, 1.43768692,
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0.11771342, -0.23761693, -0.65898693, 0.31088525, -1.55601168, -0.87661445,
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-0.89477462, 1.67204106, -0.53235275, -0.6230064, 0.29819036, 1.06939757,
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};
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static float svdf_golden_output[] = {0.014899, -0.0517661, -0.143725, -0.00271883,
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0.014899, -0.0517661, -0.143725, -0.00271883,
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0.068281, -0.162217, -0.152268, 0.00323521,
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0.068281, -0.162217, -0.152268, 0.00323521,
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-0.0317821, -0.0333089, 0.0609602, 0.0333759,
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-0.0317821, -0.0333089, 0.0609602, 0.0333759,
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-0.00623099, -0.077701, -0.391193, -0.0136691,
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-0.00623099, -0.077701, -0.391193, -0.0136691,
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0.201551, -0.164607, -0.179462, -0.0592739,
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0.201551, -0.164607, -0.179462, -0.0592739,
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0.0886511, -0.0875401, -0.269283, 0.0281379,
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0.0886511, -0.0875401, -0.269283, 0.0281379,
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-0.201174, -0.586145, -0.628624, -0.0330412,
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-0.201174, -0.586145, -0.628624, -0.0330412,
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-0.0839096, -0.299329, 0.108746, 0.109808,
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-0.0839096, -0.299329, 0.108746, 0.109808,
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0.419114, -0.237824, -0.422627, 0.175115,
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0.419114, -0.237824, -0.422627, 0.175115,
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0.36726, -0.522303, -0.456502, -0.175475,
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0.36726, -0.522303, -0.456502, -0.175475};
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static float svdf_golden_output_rank_2[] = {
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-0.09623547, -0.10193135, 0.11083051, -0.0347917,
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0.1141196, 0.12965347, -0.12652366, 0.01007236,
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-0.16396809, -0.21247184, 0.11259045, -0.04156673,
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0.10132131, -0.06143532, -0.00924693, 0.10084561,
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0.01257364, 0.0506071, -0.19287863, -0.07162561,
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-0.02033747, 0.22673416, 0.15487903, 0.02525555,
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-0.1411963, -0.37054959, 0.01774767, 0.05867489,
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0.09607603, -0.0141301, -0.08995658, 0.12867066,
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-0.27142537, -0.16955489, 0.18521598, -0.12528358,
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0.00331409, 0.11167502, 0.02218599, -0.07309391,
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0.09593632, -0.28361851, -0.0773851, 0.17199151,
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-0.00075242, 0.33691186, -0.1536046, 0.16572715,
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-0.27916506, -0.27626723, 0.42615682, 0.3225764,
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-0.37472126, -0.55655634, -0.05013514, 0.289112,
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-0.24418658, 0.07540751, -0.1940318, -0.08911639,
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0.00732617, 0.46737891, 0.26449674, 0.24888524,
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-0.17225097, -0.54660404, -0.38795233, 0.08389944,
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0.07736043, -0.28260678, 0.15666828, 1.14949894,
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-0.57454878, -0.64704704, 0.73235172, -0.34616736,
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0.21120001, -0.22927976, 0.02455296, -0.35906726,
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};
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#define FOR_ALL_INPUT_AND_WEIGHT_TENSORS(ACTION) \
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ACTION(Input) \
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ACTION(WeightsFeature) \
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ACTION(WeightsTime) \
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ACTION(Bias) \
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ACTION(StateIn)
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// For all output and intermediate states
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#define FOR_ALL_OUTPUT_TENSORS(ACTION) \
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ACTION(StateOut) \
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ACTION(Output)
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// Derived class of SingleOpModel, which is used to test SVDF TFLite op.
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class SVDFOpModel {
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public:
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SVDFOpModel(uint32_t batches, uint32_t units, uint32_t input_size, uint32_t memory_size,
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uint32_t rank)
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: batches_(batches),
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units_(units),
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input_size_(input_size),
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memory_size_(memory_size),
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rank_(rank) {
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std::vector<std::vector<uint32_t>> input_shapes{
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{batches_, input_size_}, // Input tensor
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{units_ * rank_, input_size_}, // weights_feature tensor
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{units_ * rank_, memory_size_}, // weights_time tensor
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{units_}, // bias tensor
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{batches_, memory_size * units_ * rank_}, // state in tensor
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};
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std::vector<uint32_t> inputs;
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auto it = input_shapes.begin();
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// Input and weights
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#define AddInput(X) \
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OperandType X##OpndTy(Type::TENSOR_FLOAT32, *it++); \
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inputs.push_back(model_.addOperand(&X##OpndTy));
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FOR_ALL_INPUT_AND_WEIGHT_TENSORS(AddInput);
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#undef AddInput
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// Parameters
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OperandType RankParamTy(Type::INT32, {});
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inputs.push_back(model_.addOperand(&RankParamTy));
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OperandType ActivationParamTy(Type::INT32, {});
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inputs.push_back(model_.addOperand(&ActivationParamTy));
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// Output and other intermediate state
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std::vector<std::vector<uint32_t>> output_shapes{{batches_, memory_size_ * units_ * rank_},
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{batches_, units_}};
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std::vector<uint32_t> outputs;
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auto it2 = output_shapes.begin();
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#define AddOutput(X) \
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OperandType X##OpndTy(Type::TENSOR_FLOAT32, *it2++); \
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outputs.push_back(model_.addOperand(&X##OpndTy));
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FOR_ALL_OUTPUT_TENSORS(AddOutput);
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#undef AddOutput
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Input_.insert(Input_.end(), batches_ * input_size_, 0.f);
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StateIn_.insert(StateIn_.end(), batches_ * units_ * rank_ * memory_size_, 0.f);
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auto multiAll = [](const std::vector<uint32_t>& dims) -> uint32_t {
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uint32_t sz = 1;
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for (uint32_t d : dims) {
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sz *= d;
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}
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return sz;
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};
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it2 = output_shapes.begin();
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#define ReserveOutput(X) X##_.insert(X##_.end(), multiAll(*it2++), 0.f);
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FOR_ALL_OUTPUT_TENSORS(ReserveOutput);
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model_.addOperation(ANEURALNETWORKS_SVDF, inputs, outputs);
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model_.identifyInputsAndOutputs(inputs, outputs);
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model_.finish();
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}
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void Invoke() {
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ASSERT_TRUE(model_.isValid());
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Compilation compilation(&model_);
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compilation.finish();
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Execution execution(&compilation);
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StateIn_.swap(StateOut_);
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#define SetInputOrWeight(X) \
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ASSERT_EQ(execution.setInput(SVDF::k##X##Tensor, X##_.data(), sizeof(float) * X##_.size()), \
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Result::NO_ERROR);
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FOR_ALL_INPUT_AND_WEIGHT_TENSORS(SetInputOrWeight);
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#undef SetInputOrWeight
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#define SetOutput(X) \
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EXPECT_TRUE(X##_.data() != nullptr); \
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ASSERT_EQ(execution.setOutput(SVDF::k##X##Tensor, X##_.data(), sizeof(float) * X##_.size()), \
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Result::NO_ERROR);
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FOR_ALL_OUTPUT_TENSORS(SetOutput);
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#undef SetOutput
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ASSERT_EQ(execution.setInput(SVDF::kRankParam, &rank_, sizeof(rank_)), Result::NO_ERROR);
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int activation = TfLiteFusedActivation::kTfLiteActNone;
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ASSERT_EQ(execution.setInput(SVDF::kActivationParam, &activation, sizeof(activation)),
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Result::NO_ERROR);
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ASSERT_EQ(execution.compute(), Result::NO_ERROR);
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}
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#define DefineSetter(X) \
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void Set##X(const std::vector<float>& f) { X##_.insert(X##_.end(), f.begin(), f.end()); }
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FOR_ALL_INPUT_AND_WEIGHT_TENSORS(DefineSetter);
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#undef DefineSetter
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void SetInput(int offset, float* begin, float* end) {
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for (; begin != end; begin++, offset++) {
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Input_[offset] = *begin;
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}
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}
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// Resets the state of SVDF op by filling it with 0's.
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void ResetState() {
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std::fill(StateIn_.begin(), StateIn_.end(), 0.f);
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std::fill(StateOut_.begin(), StateOut_.end(), 0.f);
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}
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// Extracts the output tensor from the SVDF op.
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const std::vector<float>& GetOutput() const { return Output_; }
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int input_size() const { return input_size_; }
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int num_units() const { return units_; }
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int num_batches() const { return batches_; }
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private:
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Model model_;
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const uint32_t batches_;
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const uint32_t units_;
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const uint32_t input_size_;
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const uint32_t memory_size_;
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const uint32_t rank_;
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#define DefineTensor(X) std::vector<float> X##_;
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FOR_ALL_INPUT_AND_WEIGHT_TENSORS(DefineTensor);
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FOR_ALL_OUTPUT_TENSORS(DefineTensor);
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#undef DefineTensor
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};
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TEST(SVDFOpTest, BlackBoxTest) {
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SVDFOpModel svdf(/*batches=*/2, /*units=*/4, /*input_size=*/3,
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/*memory_size=*/10, /*rank=*/1);
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svdf.SetWeightsFeature({-0.31930989, -0.36118156, 0.0079667, 0.37613347, 0.22197971, 0.12416199,
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0.27901134, 0.27557442, 0.3905206, -0.36137494, -0.06634006,
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-0.10640851});
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svdf.SetWeightsTime({-0.31930989, 0.37613347, 0.27901134, -0.36137494, -0.36118156,
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0.22197971, 0.27557442, -0.06634006, 0.0079667, 0.12416199,
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0.3905206, -0.10640851, -0.0976817, 0.15294972, 0.39635518,
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-0.02702999, 0.39296314, 0.15785322, 0.21931258, 0.31053296,
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-0.36916667, 0.38031587, -0.21580373, 0.27072677, 0.23622236,
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0.34936687, 0.18174365, 0.35907319, -0.17493086, 0.324846,
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-0.10781813, 0.27201805, 0.14324132, -0.23681851, -0.27115166,
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-0.01580888, -0.14943552, 0.15465137, 0.09784451, -0.0337657});
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svdf.SetBias({});
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svdf.ResetState();
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const int svdf_num_batches = svdf.num_batches();
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const int svdf_input_size = svdf.input_size();
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const int svdf_num_units = svdf.num_units();
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const int input_sequence_size =
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sizeof(svdf_input) / sizeof(float) / (svdf_input_size * svdf_num_batches);
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// Going over each input batch, setting the input tensor, invoking the SVDF op
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// and checking the output with the expected golden values.
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for (int i = 0; i < input_sequence_size; i++) {
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float* batch_start = svdf_input + i * svdf_input_size * svdf_num_batches;
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float* batch_end = batch_start + svdf_input_size * svdf_num_batches;
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svdf.SetInput(0, batch_start, batch_end);
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svdf.Invoke();
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float* golden_start = svdf_golden_output + i * svdf_num_units * svdf_num_batches;
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float* golden_end = golden_start + svdf_num_units * svdf_num_batches;
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std::vector<float> expected;
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expected.insert(expected.end(), golden_start, golden_end);
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EXPECT_THAT(svdf.GetOutput(), ElementsAreArray(ArrayFloatNear(expected)));
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}
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}
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TEST(SVDFOpTest, BlackBoxTestRank2) {
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SVDFOpModel svdf(/*batches=*/2, /*units=*/4, /*input_size=*/3,
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/*memory_size=*/10, /*rank=*/2);
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svdf.SetWeightsFeature({-0.31930989, 0.0079667, 0.39296314, 0.37613347, 0.12416199,
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0.15785322, 0.27901134, 0.3905206, 0.21931258, -0.36137494,
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-0.10640851, 0.31053296, -0.36118156, -0.0976817, -0.36916667,
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0.22197971, 0.15294972, 0.38031587, 0.27557442, 0.39635518,
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-0.21580373, -0.06634006, -0.02702999, 0.27072677});
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svdf.SetWeightsTime({-0.31930989, 0.37613347, 0.27901134, -0.36137494, -0.36118156,
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0.22197971, 0.27557442, -0.06634006, 0.0079667, 0.12416199,
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|
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0.3905206, -0.10640851, -0.0976817, 0.15294972, 0.39635518,
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|
-0.02702999, 0.39296314, 0.15785322, 0.21931258, 0.31053296,
|
||
|
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|
-0.36916667, 0.38031587, -0.21580373, 0.27072677, 0.23622236,
|
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|
0.34936687, 0.18174365, 0.35907319, -0.17493086, 0.324846,
|
||
|
|
||
|
-0.10781813, 0.27201805, 0.14324132, -0.23681851, -0.27115166,
|
||
|
-0.01580888, -0.14943552, 0.15465137, 0.09784451, -0.0337657,
|
||
|
|
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|
-0.14884081, 0.19931212, -0.36002168, 0.34663299, -0.11405486,
|
||
|
0.12672701, 0.39463779, -0.07886535, -0.06384811, 0.08249187,
|
||
|
|
||
|
-0.26816407, -0.19905911, 0.29211238, 0.31264046, -0.28664589,
|
||
|
0.05698794, 0.11613581, 0.14078894, 0.02187902, -0.21781836,
|
||
|
|
||
|
-0.15567942, 0.08693647, -0.38256618, 0.36580828, -0.22922277,
|
||
|
-0.0226903, 0.12878349, -0.28122205, -0.10850525, -0.11955214,
|
||
|
|
||
|
0.27179423, -0.04710215, 0.31069002, 0.22672787, 0.09580326,
|
||
|
0.08682203, 0.1258215, 0.1851041, 0.29228821, 0.12366763});
|
||
|
|
||
|
svdf.SetBias({});
|
||
|
|
||
|
svdf.ResetState();
|
||
|
const int svdf_num_batches = svdf.num_batches();
|
||
|
const int svdf_input_size = svdf.input_size();
|
||
|
const int svdf_num_units = svdf.num_units();
|
||
|
const int input_sequence_size =
|
||
|
sizeof(svdf_input_rank2) / sizeof(float) / (svdf_input_size * svdf_num_batches);
|
||
|
// Going over each input batch, setting the input tensor, invoking the SVDF op
|
||
|
// and checking the output with the expected golden values.
|
||
|
for (int i = 0; i < input_sequence_size; i++) {
|
||
|
float* batch_start = svdf_input_rank2 + i * svdf_input_size * svdf_num_batches;
|
||
|
float* batch_end = batch_start + svdf_input_size * svdf_num_batches;
|
||
|
svdf.SetInput(0, batch_start, batch_end);
|
||
|
|
||
|
svdf.Invoke();
|
||
|
|
||
|
float* golden_start = svdf_golden_output_rank_2 + i * svdf_num_units * svdf_num_batches;
|
||
|
float* golden_end = golden_start + svdf_num_units * svdf_num_batches;
|
||
|
std::vector<float> expected;
|
||
|
expected.insert(expected.end(), golden_start, golden_end);
|
||
|
|
||
|
EXPECT_THAT(svdf.GetOutput(), ElementsAreArray(ArrayFloatNear(expected)));
|
||
|
}
|
||
|
}
|
||
|
|
||
|
} // namespace wrapper
|
||
|
} // namespace nn
|
||
|
} // namespace android
|