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#include <library/cpp/linear_regression/linear_regression.h>
#include <library/cpp/testing/unittest/registar.h>
#include <util/generic/vector.h>
#include <util/generic/ymath.h>
#include <util/random/random.h>
#include <util/system/defaults.h>
namespace {
void ValueIsCorrect(const double value, const double expectedValue, double possibleRelativeError) {
UNIT_ASSERT_DOUBLES_EQUAL(value, expectedValue, possibleRelativeError * expectedValue);
}
}
Y_UNIT_TEST_SUITE(TLinearRegressionTest) {
Y_UNIT_TEST(MeanAndDeviationTest) {
TVector<double> arguments;
TVector<double> weights;
const size_t argumentsCount = 100;
for (size_t i = 0; i < argumentsCount; ++i) {
arguments.push_back(i);
weights.push_back(i);
}
TDeviationCalculator deviationCalculator;
TMeanCalculator meanCalculator;
for (size_t i = 0; i < arguments.size(); ++i) {
meanCalculator.Add(arguments[i], weights[i]);
deviationCalculator.Add(arguments[i], weights[i]);
}
double actualMean = InnerProduct(arguments, weights) / Accumulate(weights, 0.0);
double actualDeviation = 0.;
for (size_t i = 0; i < arguments.size(); ++i) {
double deviation = arguments[i] - actualMean;
actualDeviation += deviation * deviation * weights[i];
}
UNIT_ASSERT(IsValidFloat(meanCalculator.GetMean()));
UNIT_ASSERT_DOUBLES_EQUAL(meanCalculator.GetMean(), actualMean, 1e-10);
UNIT_ASSERT(IsValidFloat(deviationCalculator.GetDeviation()));
UNIT_ASSERT_DOUBLES_EQUAL(meanCalculator.GetMean(), deviationCalculator.GetMean(), 0);
UNIT_ASSERT(IsValidFloat(meanCalculator.GetSumWeights()));
UNIT_ASSERT(IsValidFloat(deviationCalculator.GetSumWeights()));
UNIT_ASSERT_DOUBLES_EQUAL(meanCalculator.GetSumWeights(), deviationCalculator.GetSumWeights(), 0);
UNIT_ASSERT_DOUBLES_EQUAL(meanCalculator.GetSumWeights(), Accumulate(weights, 0.0), 0);
ValueIsCorrect(deviationCalculator.GetDeviation(), actualDeviation, 1e-5);
TMeanCalculator checkRemovingMeanCalculator;
TDeviationCalculator checkRemovingDeviationCalculator;
const size_t argumentsToRemoveCount = argumentsCount / 3;
for (size_t i = 0; i < argumentsCount; ++i) {
if (i < argumentsToRemoveCount) {
meanCalculator.Remove(arguments[i], weights[i]);
deviationCalculator.Remove(arguments[i], weights[i]);
} else {
checkRemovingMeanCalculator.Add(arguments[i], weights[i]);
checkRemovingDeviationCalculator.Add(arguments[i], weights[i]);
}
}
UNIT_ASSERT(IsValidFloat(meanCalculator.GetMean()));
UNIT_ASSERT(IsValidFloat(checkRemovingMeanCalculator.GetMean()));
UNIT_ASSERT(IsValidFloat(deviationCalculator.GetDeviation()));
UNIT_ASSERT(IsValidFloat(checkRemovingDeviationCalculator.GetDeviation()));
UNIT_ASSERT_DOUBLES_EQUAL(meanCalculator.GetMean(), deviationCalculator.GetMean(), 0);
UNIT_ASSERT_DOUBLES_EQUAL(meanCalculator.GetMean(), checkRemovingMeanCalculator.GetMean(), 1e-10);
ValueIsCorrect(deviationCalculator.GetDeviation(), checkRemovingDeviationCalculator.GetDeviation(), 1e-5);
}
Y_UNIT_TEST(CovariationTest) {
TVector<double> firstValues;
TVector<double> secondValues;
TVector<double> weights;
const size_t argumentsCount = 100;
for (size_t i = 0; i < argumentsCount; ++i) {
firstValues.push_back(i);
secondValues.push_back(i * i);
weights.push_back(i);
}
TCovariationCalculator covariationCalculator;
for (size_t i = 0; i < argumentsCount; ++i) {
covariationCalculator.Add(firstValues[i], secondValues[i], weights[i]);
}
const double firstValuesMean = InnerProduct(firstValues, weights) / Accumulate(weights, 0.0);
const double secondValuesMean = InnerProduct(secondValues, weights) / Accumulate(weights, 0.0);
double actualCovariation = 0.;
for (size_t i = 0; i < argumentsCount; ++i) {
actualCovariation += (firstValues[i] - firstValuesMean) * (secondValues[i] - secondValuesMean) * weights[i];
}
UNIT_ASSERT(IsValidFloat(covariationCalculator.GetCovariation()));
UNIT_ASSERT(IsValidFloat(covariationCalculator.GetFirstValueMean()));
UNIT_ASSERT(IsValidFloat(covariationCalculator.GetSecondValueMean()));
UNIT_ASSERT_DOUBLES_EQUAL(covariationCalculator.GetFirstValueMean(), firstValuesMean, 1e-10);
UNIT_ASSERT_DOUBLES_EQUAL(covariationCalculator.GetSecondValueMean(), secondValuesMean, 1e-10);
UNIT_ASSERT(IsValidFloat(covariationCalculator.GetSumWeights()));
UNIT_ASSERT_DOUBLES_EQUAL(covariationCalculator.GetSumWeights(), Accumulate(weights, 0.0), 0);
ValueIsCorrect(covariationCalculator.GetCovariation(), actualCovariation, 1e-5);
TCovariationCalculator checkRemovingCovariationCalculator;
const size_t argumentsToRemoveCount = argumentsCount / 3;
for (size_t i = 0; i < argumentsCount; ++i) {
if (i < argumentsToRemoveCount) {
covariationCalculator.Remove(firstValues[i], secondValues[i], weights[i]);
} else {
checkRemovingCovariationCalculator.Add(firstValues[i], secondValues[i], weights[i]);
}
}
ValueIsCorrect(covariationCalculator.GetCovariation(), checkRemovingCovariationCalculator.GetCovariation(), 1e-5);
}
template <typename TSLRSolverType>
void SLRTest() {
TVector<double> arguments;
TVector<double> weights;
TVector<double> goals;
const double factor = 2.;
const double intercept = 105.;
const double randomError = 0.01;
const size_t argumentsCount = 10;
for (size_t i = 0; i < argumentsCount; ++i) {
arguments.push_back(i);
weights.push_back(i);
goals.push_back(arguments.back() * factor + intercept + 2 * (i % 2 - 0.5) * randomError);
}
TSLRSolverType slrSolver;
for (size_t i = 0; i < argumentsCount; ++i) {
slrSolver.Add(arguments[i], goals[i], weights[i]);
}
for (double regularizationThreshold = 0.; regularizationThreshold < 0.05; regularizationThreshold += 0.01) {
double solutionFactor, solutionIntercept;
slrSolver.Solve(solutionFactor, solutionIntercept, regularizationThreshold);
double predictedSumSquaredErrors = slrSolver.SumSquaredErrors(regularizationThreshold);
UNIT_ASSERT(IsValidFloat(solutionFactor));
UNIT_ASSERT(IsValidFloat(solutionIntercept));
UNIT_ASSERT(IsValidFloat(predictedSumSquaredErrors));
UNIT_ASSERT_DOUBLES_EQUAL(solutionFactor, factor, 1e-2);
UNIT_ASSERT_DOUBLES_EQUAL(solutionIntercept, intercept, 1e-2);
double sumSquaredErrors = 0.;
for (size_t i = 0; i < argumentsCount; ++i) {
double error = goals[i] - arguments[i] * solutionFactor - solutionIntercept;
sumSquaredErrors += error * error * weights[i];
}
if (!regularizationThreshold) {
UNIT_ASSERT(predictedSumSquaredErrors < Accumulate(weights, 0.0) * randomError * randomError);
}
UNIT_ASSERT_DOUBLES_EQUAL(predictedSumSquaredErrors, sumSquaredErrors, 1e-8);
}
}
Y_UNIT_TEST(FastSLRTest) {
SLRTest<TFastSLRSolver>();
}
Y_UNIT_TEST(KahanSLRTest) {
SLRTest<TKahanSLRSolver>();
}
Y_UNIT_TEST(SLRTest) {
SLRTest<TSLRSolver>();
}
template <typename TLinearRegressionSolverType>
void LinearRegressionTest() {
const size_t featuresCount = 10;
const size_t instancesCount = 10000;
const double randomError = 0.01;
TVector<double> coefficients;
for (size_t featureNumber = 0; featureNumber < featuresCount; ++featureNumber) {
coefficients.push_back(featureNumber);
}
const double intercept = 10;
TVector<TVector<double>> featuresMatrix;
TVector<double> goals;
TVector<double> weights;
for (size_t instanceNumber = 0; instanceNumber < instancesCount; ++instanceNumber) {
TVector<double> features;
for (size_t featureNumber = 0; featureNumber < featuresCount; ++featureNumber) {
features.push_back(RandomNumber<double>());
}
featuresMatrix.push_back(features);
const double goal = InnerProduct(coefficients, features) + intercept + 2 * (instanceNumber % 2 - 0.5) * randomError;
goals.push_back(goal);
weights.push_back(instanceNumber);
}
TLinearRegressionSolverType lrSolver;
for (size_t instanceNumber = 0; instanceNumber < instancesCount; ++instanceNumber) {
lrSolver.Add(featuresMatrix[instanceNumber], goals[instanceNumber], weights[instanceNumber]);
}
const TLinearModel model = lrSolver.Solve();
for (size_t featureNumber = 0; featureNumber < featuresCount; ++featureNumber) {
UNIT_ASSERT_DOUBLES_EQUAL(model.GetCoefficients()[featureNumber], coefficients[featureNumber], 1e-2);
}
UNIT_ASSERT_DOUBLES_EQUAL(model.GetIntercept(), intercept, 1e-2);
const double expectedSumSquaredErrors = randomError * randomError * Accumulate(weights, 0.0);
UNIT_ASSERT_DOUBLES_EQUAL(lrSolver.SumSquaredErrors(), expectedSumSquaredErrors, expectedSumSquaredErrors * 0.01);
}
Y_UNIT_TEST(FastLRTest) {
LinearRegressionTest<TFastLinearRegressionSolver>();
}
Y_UNIT_TEST(LRTest) {
LinearRegressionTest<TLinearRegressionSolver>();
}
void TransformationTest(const ETransformationType transformationType, const size_t pointsCount) {
TVector<float> arguments;
TVector<float> goals;
const double regressionFactor = 10.;
const double regressionIntercept = 100;
const double featureOffset = -1.5;
const double featureNormalizer = 15;
const double left = -100.;
const double right = +100.;
const double step = (right - left) / pointsCount;
for (double argument = left; argument <= right; argument += step) {
const double goal = regressionIntercept + regressionFactor * (argument - featureOffset) / (fabs(argument - featureOffset) + featureNormalizer);
arguments.push_back(argument);
goals.push_back(goal);
}
TFastFeaturesTransformerLearner learner(transformationType);
for (size_t instanceNumber = 0; instanceNumber < arguments.size(); ++instanceNumber) {
learner.Add(arguments[instanceNumber], goals[instanceNumber]);
}
TFeaturesTransformer transformer = learner.Solve();
double sse = 0.;
for (size_t instanceNumber = 0; instanceNumber < arguments.size(); ++instanceNumber) {
const double error = transformer.Transformation(arguments[instanceNumber]) - goals[instanceNumber];
sse += error * error;
}
const double rmse = sqrt(sse / arguments.size());
UNIT_ASSERT_DOUBLES_EQUAL(rmse, 0., 1e-3);
}
Y_UNIT_TEST(SigmaTest100) {
TransformationTest(ETransformationType::TT_SIGMA, 100);
}
Y_UNIT_TEST(SigmaTest1000) {
TransformationTest(ETransformationType::TT_SIGMA, 1000);
}
Y_UNIT_TEST(SigmaTest10000) {
TransformationTest(ETransformationType::TT_SIGMA, 10000);
}
Y_UNIT_TEST(SigmaTest100000) {
TransformationTest(ETransformationType::TT_SIGMA, 100000);
}
Y_UNIT_TEST(SigmaTest1000000) {
TransformationTest(ETransformationType::TT_SIGMA, 1000000);
}
Y_UNIT_TEST(SigmaTest10000000) {
TransformationTest(ETransformationType::TT_SIGMA, 10000000);
}
Y_UNIT_TEST(ResetCalculatorTest) {
TVector<double> arguments;
TVector<double> weights;
const double eps = 1e-10;
const size_t argumentsCount = 100;
for (size_t i = 0; i < argumentsCount; ++i) {
arguments.push_back(i);
weights.push_back(i);
}
TDeviationCalculator deviationCalculator1, deviationCalculator2;
TMeanCalculator meanCalculator1, meanCalculator2;
TCovariationCalculator covariationCalculator1, covariationCalculator2;
for (size_t i = 0; i < arguments.size(); ++i) {
meanCalculator1.Add(arguments[i], weights[i]);
meanCalculator2.Add(arguments[i], weights[i]);
deviationCalculator1.Add(arguments[i], weights[i]);
deviationCalculator2.Add(arguments[i], weights[i]);
covariationCalculator1.Add(arguments[i], arguments[arguments.size() - i - 1], weights[i]);
covariationCalculator2.Add(arguments[i], arguments[arguments.size() - i - 1], weights[i]);
}
UNIT_ASSERT_DOUBLES_EQUAL(meanCalculator1.GetMean(), meanCalculator2.GetMean(), eps);
UNIT_ASSERT_DOUBLES_EQUAL(meanCalculator1.GetSumWeights(), meanCalculator2.GetSumWeights(), eps);
UNIT_ASSERT_DOUBLES_EQUAL(deviationCalculator1.GetMean(), deviationCalculator2.GetMean(), eps);
UNIT_ASSERT_DOUBLES_EQUAL(deviationCalculator1.GetDeviation(), deviationCalculator2.GetDeviation(), eps);
UNIT_ASSERT_DOUBLES_EQUAL(deviationCalculator1.GetStdDev(), deviationCalculator2.GetStdDev(), eps);
UNIT_ASSERT_DOUBLES_EQUAL(deviationCalculator1.GetSumWeights(), deviationCalculator2.GetSumWeights(), eps);
UNIT_ASSERT_DOUBLES_EQUAL(covariationCalculator1.GetFirstValueMean(), covariationCalculator2.GetFirstValueMean(), eps);
UNIT_ASSERT_DOUBLES_EQUAL(covariationCalculator1.GetSecondValueMean(), covariationCalculator2.GetSecondValueMean(), eps);
UNIT_ASSERT_DOUBLES_EQUAL(covariationCalculator1.GetCovariation(), covariationCalculator2.GetCovariation(), eps);
UNIT_ASSERT_DOUBLES_EQUAL(covariationCalculator1.GetSumWeights(), covariationCalculator2.GetSumWeights(), eps);
meanCalculator2.Reset();
deviationCalculator2.Reset();
covariationCalculator2.Reset();
UNIT_ASSERT_DOUBLES_EQUAL(0.0, meanCalculator2.GetMean(), eps);
UNIT_ASSERT_DOUBLES_EQUAL(0.0, meanCalculator2.GetSumWeights(), eps);
UNIT_ASSERT_DOUBLES_EQUAL(0.0, deviationCalculator2.GetMean(), eps);
UNIT_ASSERT_DOUBLES_EQUAL(0.0, deviationCalculator2.GetDeviation(), eps);
UNIT_ASSERT_DOUBLES_EQUAL(0.0, deviationCalculator2.GetStdDev(), eps);
UNIT_ASSERT_DOUBLES_EQUAL(0.0, deviationCalculator2.GetSumWeights(), eps);
UNIT_ASSERT_DOUBLES_EQUAL(0.0, covariationCalculator2.GetFirstValueMean(), eps);
UNIT_ASSERT_DOUBLES_EQUAL(0.0, covariationCalculator2.GetSecondValueMean(), eps);
UNIT_ASSERT_DOUBLES_EQUAL(0.0, covariationCalculator2.GetCovariation(), eps);
UNIT_ASSERT_DOUBLES_EQUAL(0.0, covariationCalculator2.GetSumWeights(), eps);
for (size_t i = 0; i < arguments.size(); ++i) {
meanCalculator2.Add(arguments[i], weights[i]);
deviationCalculator2.Add(arguments[i], weights[i]);
covariationCalculator2.Add(arguments[i], arguments[arguments.size() - i - 1], weights[i]);
}
UNIT_ASSERT_DOUBLES_EQUAL(meanCalculator1.GetMean(), meanCalculator2.GetMean(), 1e-10);
UNIT_ASSERT_DOUBLES_EQUAL(meanCalculator1.GetSumWeights(), meanCalculator2.GetSumWeights(), 1e-10);
UNIT_ASSERT_DOUBLES_EQUAL(deviationCalculator1.GetMean(), deviationCalculator2.GetMean(), eps);
UNIT_ASSERT_DOUBLES_EQUAL(deviationCalculator1.GetDeviation(), deviationCalculator2.GetDeviation(), eps);
UNIT_ASSERT_DOUBLES_EQUAL(deviationCalculator1.GetStdDev(), deviationCalculator2.GetStdDev(), eps);
UNIT_ASSERT_DOUBLES_EQUAL(deviationCalculator1.GetSumWeights(), deviationCalculator2.GetSumWeights(), eps);
UNIT_ASSERT_DOUBLES_EQUAL(covariationCalculator1.GetFirstValueMean(), covariationCalculator2.GetFirstValueMean(), eps);
UNIT_ASSERT_DOUBLES_EQUAL(covariationCalculator1.GetSecondValueMean(), covariationCalculator2.GetSecondValueMean(), eps);
UNIT_ASSERT_DOUBLES_EQUAL(covariationCalculator1.GetCovariation(), covariationCalculator2.GetCovariation(), eps);
UNIT_ASSERT_DOUBLES_EQUAL(covariationCalculator1.GetSumWeights(), covariationCalculator2.GetSumWeights(), eps);
}
}
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