public static double MainFunctionFakeData(int[] translation, double phi, double[] axis, string macro)
{
//----------------------------------------PARAMETERS ---------------------------------------------
double threshold = 100; // percentage
int numberOfPointsMicro = 10_000;
int numberOfPointsMacro = 10_000;
string finalName = "d:\\ALPHAS/output_test" + phi + ".txt";
FileStream fileStream = new FileStream(finalName, FileMode.OpenOrCreate);
StreamWriter streamWriter = new StreamWriter(fileStream);
Stopwatch stopwatchL = new Stopwatch();
stopwatchL.Start();
streamWriter.WriteLine("Number of points in micro data: " + numberOfPointsMicro);
streamWriter.WriteLine("Number of points in macro data: " + numberOfPointsMacro);
TransData td = SettingFakeData(macro, translation, phi, axis);
Console.WriteLine("Artificial data created succesfully.");
//----------------------------------------DATA ---------------------------------------------------
IFeatureComputer fc = new FeatureComputer();
ISampler s = new Sampler(configuration);
Console.WriteLine("Sampling.");
Point3D[] pointsMicro = s.Sample(iDataMicro, numberOfPointsMicro);
//Point3D[] pointsMacro = s.Sample(iDataMacro, numberOfPointsMacro);
Point3D[] pointsMacro = td.SampleShifted(pointsMicro);
//Point3D[] pointsMacro = td.Sample(pointsMicro);
FeatureVector[] featureVectorsMicro = new FeatureVector[pointsMicro.Length];
FeatureVector[] featureVectorsMacro = new FeatureVector[pointsMacro.Length];
Console.WriteLine("Computing feature vectors.");
for (int i = 0; i < pointsMicro.Length; i++)
{
featureVectorsMicro[i] = fc.ComputeFeatureVector(iDataMicro, pointsMicro[i]);
}
for (int i = 0; i < pointsMacro.Length; i++)
{
featureVectorsMacro[i] = fc.ComputeFeatureVector(iDataMacro, pointsMacro[i]);
}
//----------------------------------------MATCHES-------------------------------------------------
IMatcher matcher = new Matcher();
//Matcher matcherFake = new Matcher();
Console.WriteLine("\nMatching.");
Match[] matches = matcher.Match(featureVectorsMicro, featureVectorsMacro, threshold);
//Match[] matches2 = matcher.Match(featureVectorsMicro2, featureVectorsMacro2, threshold);
//Match[] matches3 = matcher.Match(featureVectorsMicro3, featureVectorsMacro3, threshold);
//Match[] matchesFake = matcherFake.FakeMatch(featureVectorsMicro, featureVectorsMacro, threshold);
Console.WriteLine(axis[0] + " " + axis[1] + " " + axis[2] + "; " + phi + " .......................... AXIS & PHI ..............................");
streamWriter.WriteLine(axis[0] + " " + axis[1] + " " + axis[2] + "; " + phi + " .......................... AXIS & PHI ..............................");
Console.WriteLine("Count of matches: " + matches.Length);
streamWriter.WriteLine("Count of matches: " + matches.Length);
streamWriter.WriteLine();
//------------------------------------GET TRANSFORMATION -----------------------------------------
ITransformer transformer = new Transformer3D();
Console.WriteLine("Computing transformations.\n");
List <Transform3D> transformations = new List <Transform3D>();
//List<Transform3D> transformations2 = new List<Transform3D>();
//List<Transform3D> transformations3 = new List<Transform3D>();
//List<Transform3D> transformationsFake = new List<Transform3D>();
for (int i = 0; i < matches.Length; i++)
{
//transformations.Add(transformer.GetTransformation(matches[i], iDataMicro, iDataMacro));
transformations.Add(transformer.GetTransformation(matches[i], iDataMicro, iDataMacro));
//transformations2.Add(transformer.GetTransformation(matches2[i], iDataMicro, iDataMacro));
//transformations3.Add(transformer.GetTransformation(matches3[i], iDataMicro, iDataMacro));
}
Console.WriteLine("Looking for optimal transformation.\n");
Candidate.initSums(iDataMicro.Measures[0] / iDataMicro.XSpacing, iDataMicro.Measures[1] / iDataMicro.YSpacing, iDataMicro.Measures[2] / iDataMicro.ZSpacing); // micro
Density d = new Density(); // finder, we need an instance for certain complicated reason
Transform3D solution = d.Find(transformations.ToArray());
stopwatchL.Stop();
double alpha = td.GetAlpha(solution.RotationMatrix);
Console.WriteLine("Solution found.");
Console.WriteLine(solution);
Console.WriteLine("Expected rotation and translation.");
Console.WriteLine(td.RotationM);
Console.WriteLine(translation[0] * iDataMicro.XSpacing + " " + translation[1] * iDataMicro.YSpacing + " " + translation[2] * iDataMicro.ZSpacing);
Console.WriteLine();
Console.WriteLine("Alpha: " + alpha);
double[] computedAxis = td.GetAxis(solution.RotationMatrix);
double computedPhi = td.GetAngle(solution.RotationMatrix);
Console.WriteLine(Math.Round(computedAxis[0], 2) + " " + Math.Round(computedAxis[1], 2) + " " + Math.Round(computedAxis[2], 2) + "; " + Math.Round(computedPhi, 2) + " .......................... AXIS & PHI ..............................");
streamWriter.WriteLine("Solution:");
streamWriter.WriteLine(solution);
streamWriter.WriteLine("Expected rotation and translation:");
streamWriter.WriteLine(td.RotationM);
streamWriter.WriteLine(translation[0] * iDataMicro.XSpacing + " " + translation[1] * iDataMicro.YSpacing + " " + translation[2] * iDataMicro.ZSpacing);
streamWriter.WriteLine("Alpha: " + alpha);
streamWriter.WriteLine(Math.Round(computedAxis[0], 2) + " " + Math.Round(computedAxis[1], 2) + " " + Math.Round(computedAxis[2], 2) + "; " + Math.Round(computedPhi, 2) + " .......................... AXIS & PHI ..............................");
streamWriter.WriteLine("Elapsed Time is {0} s", stopwatchL.ElapsedMilliseconds / 1000.0);
streamWriter.Close();
fileStream.Close();
List <double> a1 = new List <double>();
List <Test> testik = new List <Test>();
List <Test> testik2 = new List <Test>();
List <Test> testikF1 = new List <Test>();
for (int i = 0; i < matches.Length; i++)
{
a1.Add(td.GetAlpha(transformations[i].RotationMatrix));
testik.Add(new Test(transformations[i], td.GetAlpha(transformations[i].RotationMatrix)));
testik2.Add(new Test(transformations[i], td.GetAlpha(transformations[i].RotationMatrix), matches[i].F1.Point));
testikF1.Add(new Test(transformations[i], td.GetAlpha(transformations[i].RotationMatrix), matches[i].F1.Point, matches[i].F2.Point, matches[i].Similarity));
}
double[] alphasNonSorted = a1.ToArray();
a1.Sort();
//a2.Sort();
double[] alphas = a1.ToArray();
//double[] alphasFake = a2.ToArray();
testik.Sort((x, y) => x.alpha.CompareTo(y.alpha));
testik2.Sort((x, y) => x.alpha.CompareTo(y.alpha));
testikF1.Sort((x, y) => x.alpha.CompareTo(y.alpha));
WriteCSVdouble(alphasNonSorted, "d:\\ALPHAS/nonSortedAlphas" + phi + "_001_hFAKE" + ".csv");
WriteCSVdouble(alphas, "d:\\ALPHAS/alphas" + phi + "_001_hFAKE" + ".csv");
//__________________________________________________________________________TEST_____________________________________________________________
//Chart ch = MakeChart(alphas);
//Form1 formik = new Form1();
//formik.AddChart(ch);
//formik.ShowDialog();
FileStream fs2 = new FileStream("d:\\ALPHAS/testAlpha" + phi + ".txt", FileMode.OpenOrCreate);
StreamWriter sw2 = new StreamWriter(fs2);
sw2.WriteLine("Expected rotation: ");
sw2.WriteLine(td.RotationM);
sw2.WriteLine();
foreach (Test t in testik)
{
sw2.WriteLine("Alpha: " + t.alpha);
sw2.WriteLine("Rotation: ");
sw2.WriteLine(t.t.RotationMatrix);
sw2.WriteLine();
}
sw2.Close();
fs2.Close();
FileStream fs4 = new FileStream("d:\\ALPHAS/testMatcherFC2" + phi + ".txt", FileMode.OpenOrCreate);
StreamWriter sw4 = new StreamWriter(fs4);
sw4.WriteLine("Alpha: " + alpha);
foreach (Test t in testikF1)
{
sw4.WriteLine("Alpha: " + t.alpha);
sw4.Write("p micro: " + t.pointMicro.ToString() + ", p macro: " + t.pointMacro.ToString());
sw4.WriteLine();
sw4.WriteLine("Similarity: " + t.similarity);
sw4.WriteLine();
}
sw4.Close();
fs4.Close();
//______________________________________________________________________END TEST_____________________________________________________________
return(alpha);
}
public static void MainFunction(string micro, string macro, Point3D[] pointsMicro, Point3D[] pointsMacro) // the truly main function
{
//----------------------------------------PARAMETERS----------------------------------------------
int numberOfPointsMicro = 1_000;
int numberOfPointsMacro = 1_000;
double threshold = 10; //percentage
ISampler s = new Sampler(configuration);
IFeatureComputer fc = new FeatureComputer();
IMatcher matcher = new Matcher();
ITransformer transformer = new Transformer3D();
//----------------------------------------MICRO CT------------------------------------------------
Console.WriteLine("Reading micro data.");
VolumetricData vDataMicro = new VolumetricData(micro);
iDataMicro = vDataMicro;
Console.WriteLine("Data read succesfully.");
Console.WriteLine("Sampling.");
//Point3D[] pointsMicro = s.Sample(iDataMicro, numberOfPointsMicro);
FeatureVector[] featureVectorsMicro = new FeatureVector[pointsMicro.Length];
Console.WriteLine("Computing feature vectors.");
for (int i = 0; i < pointsMicro.Length; i++)
{
featureVectorsMicro[i] = fc.ComputeFeatureVector(iDataMicro, pointsMicro[i]);
}
//----------------------------------------MACRO CT------------------------------------------------
Console.WriteLine("\nReading macro data.");
VolumetricData vDataMacro = new VolumetricData(macro);
iDataMacro = vDataMacro;
Console.WriteLine("Data read succesfully.");
Console.WriteLine("Sampling.");
//Point3D[] pointsMacro = s.Sample(iDataMacro, numberOfPointsMacro);
FeatureVector[] featureVectorsMacro = new FeatureVector[pointsMacro.Length];
Console.WriteLine("Computing feature vectors.");
for (int i = 0; i < pointsMacro.Length; i++)
{
featureVectorsMacro[i] = fc.ComputeFeatureVector(iDataMacro, pointsMacro[i]);
}
//----------------------------------------MATCHES-------------------------------------------------
Console.WriteLine("\nMatching.");
Match[] matches = matcher.Match(featureVectorsMicro, featureVectorsMacro, threshold);
Console.WriteLine("Count of matches: " + matches.Length);
//------------------------------------GET TRANSFORMATION -----------------------------------------
Console.WriteLine("Computing transformations.\n");
List <Transform3D> transformations = new List <Transform3D>();
for (int i = 0; i < matches.Length; i++)
{
transformations.Add(transformer.GetTransformation(matches[i], iDataMicro, iDataMacro));
//transformations.Add(transformer.GetTransformation(matches[i], vData, vData2, configuration));
}
Candidate.initSums(iDataMicro.Measures[0] / iDataMicro.XSpacing, iDataMicro.Measures[1] / iDataMicro.YSpacing, iDataMicro.Measures[2] / iDataMicro.ZSpacing);
Density d = new Density(); // finder, we need an instance for certain complicated reason
Transform3D solution = d.Find(transformations.ToArray());
Console.WriteLine("Solution found.");
Console.WriteLine(solution);
Cut(solution.RotationMatrix, solution.TranslationVector);
}