// test using Multi-dim Distribution object interface // and compare results and CPU performances using TF3::GetRandom in case of 3D // and test also case of dim = 10 and 100 // // run within ROOT (.x unuranMultiDim.cxx+) or pass any extra parameter in the command line to get // a graphics output #include "TStopwatch.h" #include "TUnuran.h" #include "TUnuranMultiContDist.h" #include "TH3.h" #include "TF3.h" #include "TCanvas.h" #include "TMath.h" #include "TRandom3.h" #include "TSystem.h" #include "TApplication.h" #include "TError.h" // #include "Math/ProbFunc.h" // #include "Math/DistFunc.h" #include #include #include #include using std::cout; using std::endl; int n; bool useRandomSeed = false; // to use a random seed different every time double gaus3d(double *x, double *p) { double sigma_x = p[0]; double sigma_y = p[1]; double sigma_z = p[2]; double rho = p[3]; double u = x[0] / sigma_x ; double v = x[1] / sigma_y ; double w = x[2] / sigma_z ; double c = 1 - rho*rho ; double result = (1 / (2 * TMath::Pi() * sigma_x * sigma_y * sigma_z * sqrt(c))) * exp (-(u * u - 2 * rho * u * v + v * v + w*w) / (2 * c)); return result; } double log_gaus3d(double *x, double *p) { return std::log(gaus3d(x,p) ); } double gaus10d(double * x, double *) { int i; double tmp = 0.; for (i=0; i<10; i++) tmp -= x[i] * x[i]; return exp(tmp/2.); } double gaus100d(double * x, double *) { int i; double tmp = 0.; for (i=0; i<100; i++) tmp -= x[i] * x[i]; return exp(tmp/2.); } int testUnuran(TUnuran & unr, const std::string & method, const TUnuranMultiContDist & dist, TH3 * h1, const TH3 * href = 0, const int dim = 3 ) { assert (dim >=3); // init unuran bool ret = unr.Init(dist,method); if (!ret) { std::cerr << "Error initializing unuran with method " << unr.MethodName() << endl; return -1; } h1->Reset(); // test first the time TStopwatch w; w.Start(); std::vector x(dim); for (int i = 0; i < n; ++i) { unr.SampleMulti( &x[0]); h1->Fill(x[0],x[1],x[2]); } w.Stop(); double time = w.CpuTime()*1.E9/n; cout << "Time using Unuran " << unr.MethodName() << " \t=\t " << time << "\tns/call\t"; if (href != 0) { double prob = href->Chi2Test(h1,"UU"); double ksprob = href->KolmogorovTest(h1); std::cout << "\tChi2 Prob = "<< prob << "\tKS Prob = " << ksprob << std::endl; // use lower value since hitro is not very precise // use ks for hitro since chi2 gives too big error if (unr.MethodName() == "hitro") prob = ksprob; if (prob < 1.E-6 ) { std::cout << "\nChi2 Test failed ! " << std::endl; href->Chi2Test(h1,"UUP"); // print all chi2 test info return 1; } } else std::cout << std::endl; return 0; } int testGetRandom(TF3 * f, TH3 * h1, const TH3 * href = 0) { // test first the time h1->Reset(); TStopwatch w; w.Start(); double x[3] = {0,0,0}; for (int i = 0; i < n; ++i) { f->GetRandom3(x[0],x[1],x[2]); h1->Fill(x[0],x[1],x[2]); } w.Stop(); double time = w.CpuTime()*1.E9/n; if (href != 0) { double prob = href->Chi2Test(h1,"UU"); double ksprob = href->KolmogorovTest(h1); std::cout << "Time using TF1::GetRandom() \t=\t " << time << "\tns/call \t\tChi2 Prob = "<< prob << "\tKS Prob = " << ksprob << std::endl; if (prob < 1E-06) { std::cout << "\tChi2 Test failed ! " << std::endl; href->Chi2Test(h1,"UUP"); // print all chi2 test info return 2; } } else std::cout << "Time using TF1::GetRandom() \t=\t " << time << "\tns/call\n"; return 0; } int unuranMultiDim() { // switch off printing of info messages from chi2 test gErrorIgnoreLevel = 1001; // check if using a random seed if (useRandomSeed) gRandom->SetSeed(0); gSystem->Load("libMathCore"); gSystem->Load("libUnuran"); // simple test of unuran n = 100000; TH3D * h1 = new TH3D("h1","UNURAN gaussian 3D distribution",50,-10,10,50,-10,10,50,-10,10); TH3D * h2 = new TH3D("h2","TF1::GetRandom gaussian 3D distribution",50,-10,10,50,-10,10,50,-10,10); TH3D * h3 = new TH3D("h3","UNURAN truncated gaussian 3D distribution",50,-1,1,50,-1,1,50,-1,1); TH3D * h4 = new TH3D("h4","TF1::GetRandom truncated gaussian 3D distribution",50,-1,1,50,-1,1,50,-1,1); TF3 * f = new TF3("g3d",gaus3d,-10,10,-10,10,-10,10,4); double par[4] = {2,2,2,0.5}; f->SetParameters(par); TF3 * flog = new TF3("logg3d",log_gaus3d,-10,10,-10,10,-10,10,4); flog->SetParameters(par); std::cout << "Test using an undefined domain :\n\n"; std::cout << "Function Points used in GetRandom: [ " << f->GetNpx() << " , " << f->GetNpy() << " , " << f->GetNpz() << " ]" << std::endl; testGetRandom(f,h1); // test first with getrandom // need to have a larger value to get good quality int np = 100; f->SetNpx(np); f->SetNpy(np); f->SetNpz(np); std::cout << "Function Points used in GetRandom: [ " << f->GetNpx() << " , " << f->GetNpy() << " , " << f->GetNpz() << " ]" << std::endl; testGetRandom(f,h2,h1); *h1 = *h2; np = 200; f->SetNpx(np); f->SetNpy(np); f->SetNpz(np); std::cout << "Function Points used in GetRandom: [ " << f->GetNpx() << " , " << f->GetNpy() << " , " << f->GetNpz() << " ]" << std::endl; testGetRandom(f,h2,h1); // create multi-dim distribution TUnuranMultiContDist dist(f); TUnuran unr(gRandom,2); // 2 is debug level int iret = 0; TH3 * href = new TH3D(*h2); //vnrou method (requires only pdf) std::string method = "vnrou"; iret |= testUnuran(unr, method, dist, h1, href); //hitro method (requires only pdf) method = "hitro"; iret |= testUnuran(unr, method, dist, h1, href); //gibbs requires log of pdf and derivative #ifdef USE_GIBBS method = "gibbs"; // need to create a new multi-dim distribution with log of pdf TUnuranMultiContDist logdist(flog,0,true); iret |= testUnuran(unr, method, logdist, h1, href); #endif // test setting the mode cout << "\nTest setting the mode in Unuran distribution:\n\n"; double m[3] = {0,0,0}; dist.SetMode(m); method = "vnrou"; iret |= testUnuran(unr, method, dist, h1, href); method = "hitro"; iret |= testUnuran(unr, method, dist, h1, href); #ifdef USE_GIBBS method = "gibbs"; logdist.SetMode(m); iret |= testUnuran(unr, method, logdist, h1, href); #endif cout << "\nTest truncated distribution:\n\n"; double xmin[3] = { -1, -1, -1 }; double xmax[3] = { 1, 1, 1 }; f->SetRange(xmin[0],xmin[1],xmin[2],xmax[0],xmax[1],xmax[2]); // change function domain (not yet implemented in unuran for multidim functions) dist.SetDomain(xmin,xmax); np = 30; f->SetNpx(np); f->SetNpy(np); f->SetNpz(np); std::cout << "Function Points used in GetRandom: [ " << f->GetNpx() << " , " << f->GetNpy() << " , " << f->GetNpz() << " ]" << std::endl; testGetRandom(f,h3); href = h3; np = 100; f->SetNpx(np); f->SetNpy(np); f->SetNpz(np); std::cout << "Function Points used in GetRandom: [ " << f->GetNpx() << " , " << f->GetNpy() << " , " << f->GetNpz() << " ]" << std::endl; testGetRandom(f,h4,href); href = h4; method = "vnrou"; iret |= testUnuran(unr, method, dist, h3, href); method = "hitro"; iret |= testUnuran(unr, method, dist, h3, href); #ifdef USE_GIBBS method = "gibbs"; logdist.SetDomain(xmin,xmax); iret |= testUnuran(unr, method, logdist, h3, href); #endif TCanvas * c1 = new TCanvas("c1_unuranMulti","Multidimensional distribution",10,10,900,900); c1->Divide(2,2); c1->cd(1); h1->Draw(); c1->cd(2); h2->Draw(); c1->cd(3); h3->Draw(); c1->cd(4); h4->Draw(); // make a ref histo for 10 dim using first 3 dim c1->Update(); TH3D * hrefN = new TH3D("hrefN","UNURAN gaussian ref N-Dim distribution (first 3 dim)",30,-3,3,30,-3,3,30,-3,3); TH3D * h10v = new TH3D("h10v","UNURAN gaussian N-Dim distribution (first 3 dim)",30,-3,3,30,-3,3,30,-3,3); TH3D * h10h = new TH3D("h10h","UNURAN gaussian N-Dim distribution (first 3 dim)",30,-3,3,30,-3,3,30,-3,3); TH3D * h100 = new TH3D("h100","UNURAN gaussian N-Dim distribution (first 3 dim)",30,-3,3,30,-3,3,30,-3,3); int scale = 5; double par2[4] = {1,1,1,0.}; f->SetParameters(par2); TUnuranMultiContDist dist3(f); method = "vnrou"; n/= scale; iret |= testUnuran(unr, method, dist3, hrefN); cout << "\nTest 10 dimension: (be patient , it takes time....)\n\n"; TF1 * f10 = new TF1("g10d",gaus10d,-10,10,0); TUnuranMultiContDist dist10(f10,10); TCanvas * c2 = new TCanvas("c2_unuranMulti","Multidimensional distribution",100,10,900,900); c2->Divide(2,2); c2->cd(1); hrefN->Draw(); //n/= scale; method = "vnrou"; iret |= testUnuran(unr, method, dist10, h10v, hrefN,10); c2->cd(2); h10v->Draw(); c2->Update(); //n*=scale; method = "hitro;thinning=20"; iret |= testUnuran(unr, method, dist10, h10h, hrefN,10); c2->cd(3); h10h->Draw(); c2->Update(); // 100 dim cout << "\nTest 100 dimension: ( be patient , it takes time....)\n\n"; TF1 * f100 = new TF1("g100d",gaus100d,-10,10,0); TUnuranMultiContDist dist100(f100,100); // scale = 5; // n/=scale; std::cout << "number of events to be generated = " << n << endl; method = "hitro;thinning=200"; iret |= testUnuran(unr, method, dist100, h100, hrefN,100); // n/= 100; // method = "vnrou"; // iret |= testUnuran(unr, method, dist100, hN, hrefN,100); c2->cd(4); h100->Draw(); c2->Update(); if (iret != 0) std::cerr <<"\n\nUnuRan MultiDim Continous Distribution Test:\t Failed !!!!!!!\n" << std::endl; else std::cerr << "\n\nUnuRan MultiDim Continous Distribution Test:\t OK\n" << std::endl; return iret; } #ifndef __CINT__ int main(int argc, char **argv) { int iret = 0; if (argc > 1) { TApplication theApp("App",&argc,argv); iret = unuranMultiDim(); theApp.Run(); } else iret = unuranMultiDim(); return iret; } #endif