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//------------------------------------------------------------------------------
// <auto-generated />
//
// This file was automatically generated by SWIG (http://www.swig.org).
// Version 3.0.12
//
// Do not make changes to this file unless you know what you are doing--modify
// the SWIG interface file instead.
//------------------------------------------------------------------------------
namespace QuantLib {
public class MirrorGaussianSimulatedAnnealing : OptimizationMethod {
private global::System.Runtime.InteropServices.HandleRef swigCPtr;
internal MirrorGaussianSimulatedAnnealing(global::System.IntPtr cPtr, bool cMemoryOwn) : base(NQuantLibcPINVOKE.MirrorGaussianSimulatedAnnealing_SWIGUpcast(cPtr), cMemoryOwn) {
swigCPtr = new global::System.Runtime.InteropServices.HandleRef(this, cPtr);
}
internal static global::System.Runtime.InteropServices.HandleRef getCPtr(MirrorGaussianSimulatedAnnealing obj) {
return (obj == null) ? new global::System.Runtime.InteropServices.HandleRef(null, global::System.IntPtr.Zero) : obj.swigCPtr;
}
~MirrorGaussianSimulatedAnnealing() {
Dispose();
}
public override void Dispose() {
lock(this) {
if (swigCPtr.Handle != global::System.IntPtr.Zero) {
if (swigCMemOwn) {
swigCMemOwn = false;
NQuantLibcPINVOKE.delete_MirrorGaussianSimulatedAnnealing(swigCPtr);
}
swigCPtr = new global::System.Runtime.InteropServices.HandleRef(null, global::System.IntPtr.Zero);
}
global::System.GC.SuppressFinalize(this);
base.Dispose();
}
}
public MirrorGaussianSimulatedAnnealing(SamplerMirrorGaussian sampler, ProbabilityBoltzmannDownhill probability, TemperatureExponential temperature, ReannealingTrivial reannealing, double startTemperature, double endTemperature, uint reAnnealSteps, MirrorGaussianSimulatedAnnealing.ResetScheme resetScheme, uint resetSteps) : this(NQuantLibcPINVOKE.new_MirrorGaussianSimulatedAnnealing__SWIG_0(SamplerMirrorGaussian.getCPtr(sampler), ProbabilityBoltzmannDownhill.getCPtr(probability), TemperatureExponential.getCPtr(temperature), ReannealingTrivial.getCPtr(reannealing), startTemperature, endTemperature, reAnnealSteps, (int)resetScheme, resetSteps), true) {
if (NQuantLibcPINVOKE.SWIGPendingException.Pending) throw NQuantLibcPINVOKE.SWIGPendingException.Retrieve();
}
public MirrorGaussianSimulatedAnnealing(SamplerMirrorGaussian sampler, ProbabilityBoltzmannDownhill probability, TemperatureExponential temperature, ReannealingTrivial reannealing, double startTemperature, double endTemperature, uint reAnnealSteps, MirrorGaussianSimulatedAnnealing.ResetScheme resetScheme) : this(NQuantLibcPINVOKE.new_MirrorGaussianSimulatedAnnealing__SWIG_1(SamplerMirrorGaussian.getCPtr(sampler), ProbabilityBoltzmannDownhill.getCPtr(probability), TemperatureExponential.getCPtr(temperature), ReannealingTrivial.getCPtr(reannealing), startTemperature, endTemperature, reAnnealSteps, (int)resetScheme), true) {
if (NQuantLibcPINVOKE.SWIGPendingException.Pending) throw NQuantLibcPINVOKE.SWIGPendingException.Retrieve();
}
public MirrorGaussianSimulatedAnnealing(SamplerMirrorGaussian sampler, ProbabilityBoltzmannDownhill probability, TemperatureExponential temperature, ReannealingTrivial reannealing, double startTemperature, double endTemperature, uint reAnnealSteps) : this(NQuantLibcPINVOKE.new_MirrorGaussianSimulatedAnnealing__SWIG_2(SamplerMirrorGaussian.getCPtr(sampler), ProbabilityBoltzmannDownhill.getCPtr(probability), TemperatureExponential.getCPtr(temperature), ReannealingTrivial.getCPtr(reannealing), startTemperature, endTemperature, reAnnealSteps), true) {
if (NQuantLibcPINVOKE.SWIGPendingException.Pending) throw NQuantLibcPINVOKE.SWIGPendingException.Retrieve();
}
public MirrorGaussianSimulatedAnnealing(SamplerMirrorGaussian sampler, ProbabilityBoltzmannDownhill probability, TemperatureExponential temperature, ReannealingTrivial reannealing, double startTemperature, double endTemperature) : this(NQuantLibcPINVOKE.new_MirrorGaussianSimulatedAnnealing__SWIG_3(SamplerMirrorGaussian.getCPtr(sampler), ProbabilityBoltzmannDownhill.getCPtr(probability), TemperatureExponential.getCPtr(temperature), ReannealingTrivial.getCPtr(reannealing), startTemperature, endTemperature), true) {
if (NQuantLibcPINVOKE.SWIGPendingException.Pending) throw NQuantLibcPINVOKE.SWIGPendingException.Retrieve();
}
public MirrorGaussianSimulatedAnnealing(SamplerMirrorGaussian sampler, ProbabilityBoltzmannDownhill probability, TemperatureExponential temperature, ReannealingTrivial reannealing, double startTemperature) : this(NQuantLibcPINVOKE.new_MirrorGaussianSimulatedAnnealing__SWIG_4(SamplerMirrorGaussian.getCPtr(sampler), ProbabilityBoltzmannDownhill.getCPtr(probability), TemperatureExponential.getCPtr(temperature), ReannealingTrivial.getCPtr(reannealing), startTemperature), true) {
if (NQuantLibcPINVOKE.SWIGPendingException.Pending) throw NQuantLibcPINVOKE.SWIGPendingException.Retrieve();
}
public MirrorGaussianSimulatedAnnealing(SamplerMirrorGaussian sampler, ProbabilityBoltzmannDownhill probability, TemperatureExponential temperature, ReannealingTrivial reannealing) : this(NQuantLibcPINVOKE.new_MirrorGaussianSimulatedAnnealing__SWIG_5(SamplerMirrorGaussian.getCPtr(sampler), ProbabilityBoltzmannDownhill.getCPtr(probability), TemperatureExponential.getCPtr(temperature), ReannealingTrivial.getCPtr(reannealing)), true) {
if (NQuantLibcPINVOKE.SWIGPendingException.Pending) throw NQuantLibcPINVOKE.SWIGPendingException.Retrieve();
}
public MirrorGaussianSimulatedAnnealing(SamplerMirrorGaussian sampler, ProbabilityBoltzmannDownhill probability, TemperatureExponential temperature) : this(NQuantLibcPINVOKE.new_MirrorGaussianSimulatedAnnealing__SWIG_6(SamplerMirrorGaussian.getCPtr(sampler), ProbabilityBoltzmannDownhill.getCPtr(probability), TemperatureExponential.getCPtr(temperature)), true) {
if (NQuantLibcPINVOKE.SWIGPendingException.Pending) throw NQuantLibcPINVOKE.SWIGPendingException.Retrieve();
}
public enum ResetScheme {
NoResetScheme,
ResetToBestPoint,
ResetToOrigin
}
}
}
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