/// <summary> /// Sets the distribution for operations using the current genrator /// </summary> /// <param name="distx">Distx.</param> public void setDistribution(distributions distx, Dictionary <string, double> args) { //TODO check arguments to ensure they are making a change to the distribution //otherwise throw an exception see laplace as a example of implementing this switch (distx) { case distributions.Bernoili: BernoulliDistribution x0 = new BernoulliDistribution(gen); if (args.ContainsKey("alpha")) { x0.Alpha = args["alpha"]; } else { throw new System.Exception("for Bernoili distribution you must provide an alpha"); } dist = x0; break; case distributions.Beta: BetaDistribution x1 = new BetaDistribution(gen); if (args.ContainsKey("alpha") && args.ContainsKey("beta")) { x1.Alpha = args["alpha"]; x1.Beta = args["beta"]; } else { throw new System.Exception(" for beta distribution you must provide alpha and beta"); } dist = x1; break; case distributions.BetaPrime: BetaPrimeDistribution x2 = new BetaPrimeDistribution(gen); if (args.ContainsKey("alpha") && args.ContainsKey("beta")) { x2.Alpha = args["alpha"]; x2.Beta = args["beta"]; } else { throw new System.Exception(" for betaPrime distribution you must provide alpha and beta"); } dist = x2; break; case distributions.Cauchy: CauchyDistribution x3 = new CauchyDistribution(gen); if (args.ContainsKey("alpha") && args.ContainsKey("gamma")) { x3.Alpha = args["alpha"]; x3.Gamma = args["gamma"]; } else { throw new System.Exception("for cauchy dist you must provide alpha and gamma"); } dist = x3; break; case distributions.Chi: ChiDistribution x4 = new ChiDistribution(gen); if (args.ContainsKey("alpha")) { x4.Alpha = (int)args["alpha"]; } else { throw new System.Exception("for chi you must provide alpha"); } dist = x4; break; case distributions.ChiSquared: ChiSquareDistribution x5 = new ChiSquareDistribution(gen); if (args.ContainsKey("alpha")) { x5.Alpha = (int)args["alpha"]; } else { throw new System.Exception("for chiSquared you must provide alpha"); } dist = x5; break; case distributions.ContinuousUniform: ContinuousUniformDistribution x6 = new ContinuousUniformDistribution(gen); if (args.ContainsKey("alpha") && args.ContainsKey("beta")) { x6.Alpha = args["alpha"]; x6.Beta = args["beta"]; } else { throw new System.Exception("for ContinuousUniform you must provide alpha and beta"); } dist = x6; break; case distributions.DiscreteUniform: DiscreteUniformDistribution x7 = new DiscreteUniformDistribution(gen); if (args.ContainsKey("alpha") && args.ContainsKey("beta")) { x7.Alpha = (int)args["alpha"]; x7.Beta = (int)args["beta"]; } else { throw new System.Exception("for discrete uniform distribution you must provide alpha and beta"); } dist = x7; break; case distributions.Erlang: ErlangDistribution x8 = new ErlangDistribution(gen); if (args.ContainsKey("alpha") && args.ContainsKey("lambda")) { x8.Alpha = (int)args["alpha"]; x8.Lambda = (int)args["lambda"]; } else { throw new System.Exception("for Erlang dist you must provide alpha and lambda"); } dist = x8; break; case distributions.Exponential: ExponentialDistribution x9 = new ExponentialDistribution(gen); if (args.ContainsKey("lambda")) { x9.Lambda = args["lambda"]; } else { throw new System.Exception("for exponential dist you must provide lambda"); } dist = x9; break; case distributions.FisherSnedecor: FisherSnedecorDistribution x10 = new FisherSnedecorDistribution(gen); if (args.ContainsKey("alpha") && args.ContainsKey("beta")) { x10.Alpha = (int)args["alpha"]; x10.Beta = (int)args["beta"]; } else { throw new System.Exception("for FisherSnedecor you must provide alpha and beta"); } dist = x10; break; case distributions.FisherTippett: FisherTippettDistribution x11 = new FisherTippettDistribution(gen); if (args.ContainsKey("alpha") && args.ContainsKey("mu")) { x11.Alpha = args["alpha"]; x11.Mu = args["mu"]; } else { throw new System.Exception("for FisherTippets you must provide alpha and mu"); } dist = x11; break; case distributions.Gamma: GammaDistribution x12 = new GammaDistribution(gen); if (args.ContainsKey("alpha") && args.ContainsKey("theta")) { x12.Alpha = args["alpha"]; x12.Theta = args["theta"]; } else { throw new System.Exception("for Gamma dist you must provide alpha and theta"); } dist = x12; break; case distributions.Geometric: GeometricDistribution x13 = new GeometricDistribution(gen); if (args.ContainsKey("alpha")) { x13.Alpha = args["alpha"]; } else { throw new System.Exception("Geometric distribution requires alpha value"); } dist = x13; break; case distributions.Binomial: BinomialDistribution x14 = new BinomialDistribution(gen); if (args.ContainsKey("alpha") && args.ContainsKey("beta")) { x14.Alpha = args["alpha"]; x14.Beta = (int)args["beta"]; } else { throw new System.Exception("binomial distribution requires alpha and beta"); } dist = x14; break; case distributions.None: break; case distributions.Laplace: LaplaceDistribution x15 = new LaplaceDistribution(gen); if (args.ContainsKey("alpha") && args.ContainsKey("mu")) { if (x15.IsValidAlpha(args["alpha"]) && x15.IsValidMu(args["mu"])) { x15.Alpha = args["alpha"]; x15.Mu = args["mu"]; } else { throw new ArgumentException("alpha must be greater than zero"); } } else { throw new System.Exception("Laplace dist requires alpha and mu"); } dist = x15; break; case distributions.LogNormal: LognormalDistribution x16 = new LognormalDistribution(gen); if (args.ContainsKey("mu") && args.ContainsKey("sigma")) { x16.Mu = args["mu"]; x16.Sigma = args["sigma"]; } else { throw new System.Exception("lognormal distribution requires mu and sigma"); } dist = x16; break; case distributions.Normal: NormalDistribution x17 = new NormalDistribution(gen); if (args.ContainsKey("mu") && args.ContainsKey("sigma")) { x17.Mu = args["mu"]; x17.Sigma = args["sigma"]; } else { throw new System.Exception("normal distribution requires mu and sigma"); } dist = x17; break; case distributions.Pareto: ParetoDistribution x18 = new ParetoDistribution(gen); if (args.ContainsKey("alpha") && args.ContainsKey("beta")) { x18.Alpha = args["alpha"]; x18.Beta = args["beta"]; } else { throw new System.Exception("pareto distribution requires alpha and beta"); } dist = x18; break; case distributions.Poisson: PoissonDistribution x19 = new PoissonDistribution(gen); if (args.ContainsKey("lambda")) { x19.Lambda = args["lambda"]; } else { throw new System.Exception("Poisson distribution requires lambda"); } dist = x19; break; case distributions.Power: PowerDistribution x20 = new PowerDistribution(gen); if (args.ContainsKey("alpha") && args.ContainsKey("beta")) { x20.Alpha = args["alpha"]; x20.Beta = args["beta"]; } else { throw new System.Exception("Power dist requires alpha and beta"); } dist = x20; break; case distributions.RayLeigh: RayleighDistribution x21 = new RayleighDistribution(gen); if (args.ContainsKey("sigma")) { x21.Sigma = args["sigma"]; } else { throw new System.Exception("Rayleigh dist requires sigma"); } dist = x21; break; case distributions.StudentsT: StudentsTDistribution x22 = new StudentsTDistribution(gen); if (args.ContainsKey("nu")) { x22.Nu = (int)args["nu"]; } else { throw new System.Exception("StudentsT dist requirres nu"); } dist = x22; break; case distributions.Triangular: TriangularDistribution x23 = new TriangularDistribution(gen); if (args.ContainsKey("alpha") && args.ContainsKey("beta") && args.ContainsKey("gamma")) { x23.Alpha = args["alpha"]; x23.Beta = args["beta"]; x23.Gamma = args["gamma"]; } else { throw new System.Exception("Triangular distribution requires alpha, beta and gamma"); } dist = x23; break; case distributions.WeiBull: WeibullDistribution x24 = new WeibullDistribution(gen); if (args.ContainsKey("alpha") && args.ContainsKey("lambda")) { x24.Alpha = args["alpha"]; x24.Lambda = args["lambda"]; } else { throw new System.Exception("WeiBull dist requires alpha and lambda"); } dist = x24; break; default: throw new NotImplementedException("the distribution you want has not yet been implemented " + "you could help everyone out by going and implementing it"); } }