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#include "test_precomp.hpp"
#include <opencv2/structured_light/graycodepattern.hpp>
#include <opencv2/structured_light/sinusoidalpattern.hpp>
namespace opencv_test { namespace {
const string STRUCTURED_LIGHT_DIR = "structured_light";
const string FOLDER_DATA = "data";
TEST( SinusoidalPattern, unwrapPhaseMap )
{
string folder = cvtest::TS::ptr()->get_data_path() + "/" + STRUCTURED_LIGHT_DIR + "/" + FOLDER_DATA + "/";
Ptr<structured_light::SinusoidalPattern::Params> paramsPsp, paramsFtp, paramsFaps;
paramsPsp = makePtr<structured_light::SinusoidalPattern::Params>();
paramsFtp = makePtr<structured_light::SinusoidalPattern::Params>();
paramsFaps = makePtr<structured_light::SinusoidalPattern::Params>();
paramsFtp->methodId = 0;
paramsPsp->methodId = 1;
paramsFaps->methodId = 2;
Ptr<structured_light::SinusoidalPattern> sinusPsp = structured_light::SinusoidalPattern::create(paramsPsp);
Ptr<structured_light::SinusoidalPattern> sinusFtp = structured_light::SinusoidalPattern::create(paramsFtp);
Ptr<structured_light::SinusoidalPattern> sinusFaps = structured_light::SinusoidalPattern::create(paramsFaps);
vector<Mat> captures(3);
Mat unwrappedPhaseMapPspRef, unwrappedPhaseMapFtpRef, unwrappedPhaseMapFapsRef;
Mat shadowMask;
Mat wrappedPhaseMap, unwrappedPhaseMap, unwrappedPhaseMap8;
captures[0] = imread(folder + "capture_sin_0.jpg", IMREAD_GRAYSCALE);
captures[1] = imread(folder + "capture_sin_1.jpg", IMREAD_GRAYSCALE);
captures[2] = imread(folder + "capture_sin_2.jpg", IMREAD_GRAYSCALE);
unwrappedPhaseMapPspRef = imread(folder + "unwrappedPspTest.jpg", IMREAD_GRAYSCALE);
unwrappedPhaseMapFtpRef = imread(folder + "unwrappedFtpTest.jpg", IMREAD_GRAYSCALE);
unwrappedPhaseMapFapsRef = imread(folder + "unwrappedFapsTest.jpg", IMREAD_GRAYSCALE);
if( !captures[0].data || !captures[1].data || !captures[2].data || !unwrappedPhaseMapFapsRef.data
|| !unwrappedPhaseMapFtpRef.data || !unwrappedPhaseMapPspRef.data )
{
cerr << "invalid test data" << endl;
}
sinusPsp->computePhaseMap(captures, wrappedPhaseMap, shadowMask);
sinusPsp->unwrapPhaseMap(wrappedPhaseMap, unwrappedPhaseMap, Size(captures[0].cols, captures[1].rows), shadowMask);
unwrappedPhaseMap.convertTo(unwrappedPhaseMap8, CV_8U, 1, 128);
int sumOfDiff = 0;
int count = 0;
float ratio = 0;
for( int i = 0; i < unwrappedPhaseMap8.rows; ++i )
{
for( int j = 0; j < unwrappedPhaseMap8.cols; ++j )
{
int ref = unwrappedPhaseMapPspRef.at<uchar>(i, j);
int comp = unwrappedPhaseMap8.at<uchar>(i, j);
sumOfDiff += (ref - comp);
count ++;
}
}
ratio = (float)(sumOfDiff / count);
EXPECT_LE( ratio, 0.003 );
sinusFtp->computePhaseMap(captures, wrappedPhaseMap, shadowMask);
sinusFtp->unwrapPhaseMap(wrappedPhaseMap, unwrappedPhaseMap, Size(captures[0].cols, captures[1].rows), shadowMask);
unwrappedPhaseMap.convertTo(unwrappedPhaseMap8, CV_8U, 1, 128);
sumOfDiff = 0;
count = 0;
ratio = 0;
for( int i = 0; i < unwrappedPhaseMap8.rows; ++i )
{
for( int j = 0; j < unwrappedPhaseMap8.cols; ++j )
{
int ref = unwrappedPhaseMapFtpRef.at<uchar>(i, j);
int comp = unwrappedPhaseMap8.at<uchar>(i, j);
sumOfDiff += (ref - comp);
count ++;
}
}
ratio = (float)(sumOfDiff / count);
EXPECT_LE( ratio, 0.003 );
sinusFaps->computePhaseMap(captures, wrappedPhaseMap, shadowMask);
sinusFaps->unwrapPhaseMap(wrappedPhaseMap, unwrappedPhaseMap, Size(captures[0].cols, captures[1].rows), shadowMask);
unwrappedPhaseMap.convertTo(unwrappedPhaseMap8, CV_8U, 1, 128);
sumOfDiff = 0;
count = 0;
ratio = 0;
for( int i = 0; i < unwrappedPhaseMap8.rows; ++i )
{
for( int j = 0; j < unwrappedPhaseMap8.cols; ++j )
{
int ref = unwrappedPhaseMapFapsRef.at<uchar>(i, j);
int comp = unwrappedPhaseMap8.at<uchar>(i, j);
sumOfDiff += (ref - comp);
count ++;
}
}
ratio = (float)(sumOfDiff / count);
EXPECT_LE( ratio, 0.003 );
}
}} // namespace