public static RangeTransform Read(Stream stream)
{
TemporaryCulture.Start();
StreamReader streamReader = new StreamReader(stream);
int num = int.Parse(streamReader.ReadLine());
double[] array = new double[num];
double[] array2 = new double[num];
string[] array3 = streamReader.ReadLine().Split();
for (int i = 0; i < num; i++)
{
array[i] = double.Parse(array3[i]);
}
array3 = streamReader.ReadLine().Split();
for (int j = 0; j < num; j++)
{
array2[j] = double.Parse(array3[j]);
}
array3 = streamReader.ReadLine().Split();
double outputStart = double.Parse(array3[0]);
double outputScale = double.Parse(array3[1]);
TemporaryCulture.Stop();
return(new RangeTransform(array, array2, outputStart, outputScale, num));
}
public static Problem Read(Stream stream)
{
TemporaryCulture.Start();
StreamReader streamReader = new StreamReader(stream);
List <double> list = new List <double>();
List <Node[]> list2 = new List <Node[]>();
int num = 0;
while (streamReader.Peek() > -1)
{
string[] array = streamReader.ReadLine().Trim().Split();
list.Add(double.Parse(array[0]));
int num2 = array.Length - 1;
Node[] array2 = new Node[num2];
for (int i = 0; i < num2; i++)
{
array2[i] = new Node();
string[] array3 = array[i + 1].Split(':');
array2[i].Index = int.Parse(array3[0]);
array2[i].Value = double.Parse(array3[1]);
}
if (num2 > 0)
{
num = Math.Max(num, array2[num2 - 1].Index);
}
list2.Add(array2);
}
TemporaryCulture.Stop();
return(new Problem(list.Count, list.ToArray(), list2.ToArray(), num));
}
public static void Write(Stream stream, GaussianTransform transform)
{
TemporaryCulture.Start();
StreamWriter streamWriter = new StreamWriter(stream);
streamWriter.WriteLine(transform._means.Length);
for (int i = 0; i < transform._means.Length; i++)
{
streamWriter.WriteLine("{0} {1}", transform._means[i], transform._stddevs[i]);
}
streamWriter.Flush();
TemporaryCulture.Stop();
}
public static GaussianTransform Read(Stream stream)
{
TemporaryCulture.Start();
StreamReader streamReader = new StreamReader(stream);
int num = int.Parse(streamReader.ReadLine(), CultureInfo.InvariantCulture);
double[] array = new double[num];
double[] array2 = new double[num];
for (int i = 0; i < num; i++)
{
string[] array3 = streamReader.ReadLine().Split();
array[i] = double.Parse(array3[0], CultureInfo.InvariantCulture);
array2[i] = double.Parse(array3[1], CultureInfo.InvariantCulture);
}
TemporaryCulture.Stop();
return(new GaussianTransform(array, array2));
}
public static void Write(Stream stream, Problem problem)
{
TemporaryCulture.Start();
StreamWriter streamWriter = new StreamWriter(stream);
for (int i = 0; i < problem.Count; i++)
{
streamWriter.Write(problem.Y[i]);
for (int j = 0; j < problem.X[i].Length; j++)
{
streamWriter.Write(" {0}:{1}", problem.X[i][j].Index, problem.X[i][j].Value);
}
streamWriter.WriteLine();
}
streamWriter.Flush();
TemporaryCulture.Stop();
}
public static void Write(Stream stream, RangeTransform r)
{
TemporaryCulture.Start();
StreamWriter streamWriter = new StreamWriter(stream);
streamWriter.WriteLine(r._length);
streamWriter.Write(r._inputStart[0]);
for (int i = 1; i < r._inputStart.Length; i++)
{
streamWriter.Write(" " + r._inputStart[i]);
}
streamWriter.WriteLine();
streamWriter.Write(r._inputScale[0]);
for (int j = 1; j < r._inputScale.Length; j++)
{
streamWriter.Write(" " + r._inputScale[j]);
}
streamWriter.WriteLine();
streamWriter.WriteLine("{0} {1}", r._outputStart, r._outputScale);
streamWriter.Flush();
TemporaryCulture.Stop();
}
public static void Write(Stream stream, Model model)
{
TemporaryCulture.Start();
StreamWriter streamWriter = new StreamWriter(stream);
Parameter parameter = model.Parameter;
streamWriter.Write("svm_type " + parameter.SvmType + "\n");
streamWriter.Write("kernel_type " + parameter.KernelType + "\n");
if (parameter.KernelType == KernelType.POLY)
{
streamWriter.Write("degree " + parameter.Degree + "\n");
}
if (parameter.KernelType == KernelType.POLY || parameter.KernelType == KernelType.RBF || parameter.KernelType == KernelType.SIGMOID)
{
streamWriter.Write("gamma " + parameter.Gamma + "\n");
}
if (parameter.KernelType == KernelType.POLY || parameter.KernelType == KernelType.SIGMOID)
{
streamWriter.Write("coef0 " + parameter.Coefficient0 + "\n");
}
int numberOfClasses = model.NumberOfClasses;
int supportVectorCount = model.SupportVectorCount;
streamWriter.Write("nr_class " + numberOfClasses + "\n");
streamWriter.Write("total_sv " + supportVectorCount + "\n");
streamWriter.Write("rho");
for (int i = 0; i < numberOfClasses * (numberOfClasses - 1) / 2; i++)
{
streamWriter.Write(" " + model.Rho[i]);
}
streamWriter.Write("\n");
if (model.ClassLabels != null)
{
streamWriter.Write("label");
for (int j = 0; j < numberOfClasses; j++)
{
streamWriter.Write(" " + model.ClassLabels[j]);
}
streamWriter.Write("\n");
}
if (model.PairwiseProbabilityA != null)
{
streamWriter.Write("probA");
for (int k = 0; k < numberOfClasses * (numberOfClasses - 1) / 2; k++)
{
streamWriter.Write(" " + model.PairwiseProbabilityA[k]);
}
streamWriter.Write("\n");
}
if (model.PairwiseProbabilityB != null)
{
streamWriter.Write("probB");
for (int l = 0; l < numberOfClasses * (numberOfClasses - 1) / 2; l++)
{
streamWriter.Write(" " + model.PairwiseProbabilityB[l]);
}
streamWriter.Write("\n");
}
if (model.NumberOfSVPerClass != null)
{
streamWriter.Write("nr_sv");
for (int m = 0; m < numberOfClasses; m++)
{
streamWriter.Write(" " + model.NumberOfSVPerClass[m]);
}
streamWriter.Write("\n");
}
streamWriter.Write("SV\n");
double[][] supportVectorCoefficients = model.SupportVectorCoefficients;
Node[][] supportVectors = model.SupportVectors;
for (int n = 0; n < supportVectorCount; n++)
{
for (int num = 0; num < numberOfClasses - 1; num++)
{
streamWriter.Write(supportVectorCoefficients[num][n] + " ");
}
Node[] array = supportVectors[n];
if (array.Length == 0)
{
streamWriter.WriteLine();
}
else
{
if (parameter.KernelType == KernelType.PRECOMPUTED)
{
streamWriter.Write("0:{0}", (int)array[0].Value);
}
else
{
streamWriter.Write("{0}:{1}", array[0].Index, array[0].Value);
for (int num2 = 1; num2 < array.Length; num2++)
{
streamWriter.Write(" {0}:{1}", array[num2].Index, array[num2].Value);
}
}
streamWriter.WriteLine();
}
}
streamWriter.Flush();
TemporaryCulture.Stop();
}
public static Model Read(Stream stream)
{
TemporaryCulture.Start();
StreamReader streamReader = new StreamReader(stream);
Model model = new Model();
Parameter parameter2 = model.Parameter = new Parameter();
model.Rho = null;
model.PairwiseProbabilityA = null;
model.PairwiseProbabilityB = null;
model.ClassLabels = null;
model.NumberOfSVPerClass = null;
bool flag = false;
while (!flag)
{
string text = streamReader.ReadLine();
int num = text.IndexOf(' ');
string text2;
string text3;
if (num >= 0)
{
text2 = text.Substring(0, num);
text3 = text.Substring(num + 1);
}
else
{
text2 = text;
text3 = "";
}
text3 = text3.ToLower();
switch (text2)
{
case "svm_type":
parameter2.SvmType = (SvmType)Enum.Parse(typeof(SvmType), text3.ToUpper());
break;
case "kernel_type":
parameter2.KernelType = (KernelType)Enum.Parse(typeof(KernelType), text3.ToUpper());
break;
case "degree":
parameter2.Degree = int.Parse(text3);
break;
case "gamma":
parameter2.Gamma = double.Parse(text3);
break;
case "coef0":
parameter2.Coefficient0 = double.Parse(text3);
break;
case "nr_class":
model.NumberOfClasses = int.Parse(text3);
break;
case "total_sv":
model.SupportVectorCount = int.Parse(text3);
break;
case "rho":
{
int numberOfClasses = model.NumberOfClasses * (model.NumberOfClasses - 1) / 2;
model.Rho = new double[numberOfClasses];
string[] array5 = text3.Split();
for (int i = 0; i < numberOfClasses; i++)
{
model.Rho[i] = double.Parse(array5[i]);
}
break;
}
case "label":
{
int numberOfClasses = model.NumberOfClasses;
model.ClassLabels = new int[numberOfClasses];
string[] array4 = text3.Split();
for (int i = 0; i < numberOfClasses; i++)
{
model.ClassLabels[i] = int.Parse(array4[i]);
}
break;
}
case "probA":
{
int numberOfClasses = model.NumberOfClasses * (model.NumberOfClasses - 1) / 2;
model.PairwiseProbabilityA = new double[numberOfClasses];
string[] array3 = text3.Split();
for (int i = 0; i < numberOfClasses; i++)
{
model.PairwiseProbabilityA[i] = double.Parse(array3[i]);
}
break;
}
case "probB":
{
int numberOfClasses = model.NumberOfClasses * (model.NumberOfClasses - 1) / 2;
model.PairwiseProbabilityB = new double[numberOfClasses];
string[] array2 = text3.Split();
for (int i = 0; i < numberOfClasses; i++)
{
model.PairwiseProbabilityB[i] = double.Parse(array2[i]);
}
break;
}
case "nr_sv":
{
int numberOfClasses = model.NumberOfClasses;
model.NumberOfSVPerClass = new int[numberOfClasses];
string[] array = text3.Split();
for (int i = 0; i < numberOfClasses; i++)
{
model.NumberOfSVPerClass[i] = int.Parse(array[i]);
}
break;
}
case "SV":
flag = true;
break;
default:
throw new Exception("Unknown text in model file");
}
}
int num2 = model.NumberOfClasses - 1;
int supportVectorCount = model.SupportVectorCount;
model.SupportVectorCoefficients = new double[num2][];
for (int j = 0; j < num2; j++)
{
model.SupportVectorCoefficients[j] = new double[supportVectorCount];
}
model.SupportVectors = new Node[supportVectorCount][];
for (int k = 0; k < supportVectorCount; k++)
{
string[] array6 = streamReader.ReadLine().Trim().Split();
for (int l = 0; l < num2; l++)
{
model.SupportVectorCoefficients[l][k] = double.Parse(array6[l]);
}
int num3 = array6.Length - num2;
model.SupportVectors[k] = new Node[num3];
for (int m = 0; m < num3; m++)
{
string[] array7 = array6[num2 + m].Split(':');
model.SupportVectors[k][m] = new Node();
model.SupportVectors[k][m].Index = int.Parse(array7[0]);
model.SupportVectors[k][m].Value = double.Parse(array7[1]);
}
}
TemporaryCulture.Stop();
return(model);
}