Open Source Computer Vision Library https://opencv.org/
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#include "test_precomp.hpp"
namespace opencv_test { namespace {
using cv::ml::SVMSGD;
using cv::ml::TrainData;
class CV_SVMSGDTrainTest : public cvtest::BaseTest
{
public:
enum TrainDataType
{
UNIFORM_SAME_SCALE,
UNIFORM_DIFFERENT_SCALES
};
CV_SVMSGDTrainTest(const Mat &_weights, float shift, TrainDataType type, double precision = 0.01);
private:
virtual void run( int start_from );
static float decisionFunction(const Mat &sample, const Mat &weights, float shift);
void makeData(int samplesCount, const Mat &weights, float shift, RNG &rng, Mat &samples, Mat & responses);
void generateSameBorders(int featureCount);
void generateDifferentBorders(int featureCount);
TrainDataType type;
double precision;
std::vector<std::pair<float,float> > borders;
cv::Ptr<TrainData> data;
cv::Mat testSamples;
cv::Mat testResponses;
static const int TEST_VALUE_LIMIT = 500;
};
void CV_SVMSGDTrainTest::generateSameBorders(int featureCount)
{
float lowerLimit = -TEST_VALUE_LIMIT;
float upperLimit = TEST_VALUE_LIMIT;
for (int featureIndex = 0; featureIndex < featureCount; featureIndex++)
{
borders.push_back(std::pair<float,float>(lowerLimit, upperLimit));
}
}
void CV_SVMSGDTrainTest::generateDifferentBorders(int featureCount)
{
float lowerLimit = -TEST_VALUE_LIMIT;
float upperLimit = TEST_VALUE_LIMIT;
cv::RNG rng(0);
for (int featureIndex = 0; featureIndex < featureCount; featureIndex++)
{
int crit = rng.uniform(0, 2);
if (crit > 0)
{
borders.push_back(std::pair<float,float>(lowerLimit, upperLimit));
}
else
{
borders.push_back(std::pair<float,float>(lowerLimit/1000, upperLimit/1000));
}
}
}
float CV_SVMSGDTrainTest::decisionFunction(const Mat &sample, const Mat &weights, float shift)
{
return static_cast<float>(sample.dot(weights)) + shift;
}
void CV_SVMSGDTrainTest::makeData(int samplesCount, const Mat &weights, float shift, RNG &rng, Mat &samples, Mat & responses)
{
int featureCount = weights.cols;
samples.create(samplesCount, featureCount, CV_32FC1);
for (int featureIndex = 0; featureIndex < featureCount; featureIndex++)
{
rng.fill(samples.col(featureIndex), RNG::UNIFORM, borders[featureIndex].first, borders[featureIndex].second);
}
responses.create(samplesCount, 1, CV_32FC1);
for (int i = 0 ; i < samplesCount; i++)
{
responses.at<float>(i) = decisionFunction(samples.row(i), weights, shift) > 0 ? 1.f : -1.f;
}
}
CV_SVMSGDTrainTest::CV_SVMSGDTrainTest(const Mat &weights, float shift, TrainDataType _type, double _precision)
{
type = _type;
precision = _precision;
int featureCount = weights.cols;
switch(type)
{
case UNIFORM_SAME_SCALE:
generateSameBorders(featureCount);
break;
case UNIFORM_DIFFERENT_SCALES:
generateDifferentBorders(featureCount);
break;
default:
CV_Error(CV_StsBadArg, "Unknown train data type");
}
RNG rng(0);
Mat trainSamples;
Mat trainResponses;
int trainSamplesCount = 10000;
makeData(trainSamplesCount, weights, shift, rng, trainSamples, trainResponses);
data = TrainData::create(trainSamples, cv::ml::ROW_SAMPLE, trainResponses);
int testSamplesCount = 100000;
makeData(testSamplesCount, weights, shift, rng, testSamples, testResponses);
}
void CV_SVMSGDTrainTest::run( int /*start_from*/ )
{
cv::Ptr<SVMSGD> svmsgd = SVMSGD::create();
svmsgd->train(data);
Mat responses;
svmsgd->predict(testSamples, responses);
int errCount = 0;
int testSamplesCount = testSamples.rows;
CV_Assert((responses.type() == CV_32FC1) && (testResponses.type() == CV_32FC1));
for (int i = 0; i < testSamplesCount; i++)
{
if (responses.at<float>(i) * testResponses.at<float>(i) < 0)
errCount++;
}
float err = (float)errCount / testSamplesCount;
if ( err > precision )
{
ts->set_failed_test_info(cvtest::TS::FAIL_BAD_ACCURACY);
}
}
void makeWeightsAndShift(int featureCount, Mat &weights, float &shift)
{
weights.create(1, featureCount, CV_32FC1);
cv::RNG rng(0);
double lowerLimit = -1;
double upperLimit = 1;
rng.fill(weights, RNG::UNIFORM, lowerLimit, upperLimit);
9 years ago
shift = static_cast<float>(rng.uniform(-featureCount, featureCount));
}
TEST(ML_SVMSGD, trainSameScale2)
{
int featureCount = 2;
Mat weights;
float shift = 0;
makeWeightsAndShift(featureCount, weights, shift);
CV_SVMSGDTrainTest test(weights, shift, CV_SVMSGDTrainTest::UNIFORM_SAME_SCALE);
test.safe_run();
}
TEST(ML_SVMSGD, trainSameScale5)
{
int featureCount = 5;
Mat weights;
float shift = 0;
makeWeightsAndShift(featureCount, weights, shift);
CV_SVMSGDTrainTest test(weights, shift, CV_SVMSGDTrainTest::UNIFORM_SAME_SCALE);
test.safe_run();
}
TEST(ML_SVMSGD, trainSameScale100)
{
int featureCount = 100;
Mat weights;
float shift = 0;
makeWeightsAndShift(featureCount, weights, shift);
CV_SVMSGDTrainTest test(weights, shift, CV_SVMSGDTrainTest::UNIFORM_SAME_SCALE, 0.02);
test.safe_run();
}
TEST(ML_SVMSGD, trainDifferentScales2)
{
int featureCount = 2;
Mat weights;
float shift = 0;
makeWeightsAndShift(featureCount, weights, shift);
CV_SVMSGDTrainTest test(weights, shift, CV_SVMSGDTrainTest::UNIFORM_DIFFERENT_SCALES, 0.01);
test.safe_run();
}
TEST(ML_SVMSGD, trainDifferentScales5)
{
int featureCount = 5;
Mat weights;
float shift = 0;
makeWeightsAndShift(featureCount, weights, shift);
CV_SVMSGDTrainTest test(weights, shift, CV_SVMSGDTrainTest::UNIFORM_DIFFERENT_SCALES, 0.01);
test.safe_run();
}
TEST(ML_SVMSGD, trainDifferentScales100)
{
int featureCount = 100;
Mat weights;
float shift = 0;
makeWeightsAndShift(featureCount, weights, shift);
CV_SVMSGDTrainTest test(weights, shift, CV_SVMSGDTrainTest::UNIFORM_DIFFERENT_SCALES, 0.01);
test.safe_run();
}
TEST(ML_SVMSGD, twoPoints)
{
Mat samples(2, 2, CV_32FC1);
samples.at<float>(0,0) = 0;
samples.at<float>(0,1) = 0;
samples.at<float>(1,0) = 1000;
samples.at<float>(1,1) = 1;
Mat responses(2, 1, CV_32FC1);
responses.at<float>(0) = -1;
responses.at<float>(1) = 1;
cv::Ptr<TrainData> trainData = TrainData::create(samples, cv::ml::ROW_SAMPLE, responses);
Mat realWeights(1, 2, CV_32FC1);
realWeights.at<float>(0) = 1000;
realWeights.at<float>(1) = 1;
float realShift = -500000.5;
float normRealWeights = static_cast<float>(cv::norm(realWeights)); // TODO cvtest
realWeights /= normRealWeights;
realShift /= normRealWeights;
cv::Ptr<SVMSGD> svmsgd = SVMSGD::create();
svmsgd->setOptimalParameters();
svmsgd->train( trainData );
Mat foundWeights = svmsgd->getWeights();
float foundShift = svmsgd->getShift();
float normFoundWeights = static_cast<float>(cv::norm(foundWeights)); // TODO cvtest
foundWeights /= normFoundWeights;
foundShift /= normFoundWeights;
EXPECT_LE(cv::norm(Mat(foundWeights - realWeights)), 0.001); // TODO cvtest
EXPECT_LE(std::abs((foundShift - realShift) / realShift), 0.05);
}
}} // namespace