#include "TRolke.h"
#include "TMath.h"
#include "Riostream.h"
ClassImp(TRolke)
TRolke::TRolke(Double_t CL, Option_t * )
: fCL(CL),
fUpperLimit(0.0),
fLowerLimit(0.0),
fBounding(false),
fNumWarningsDeprecated1(0),
fNumWarningsDeprecated2(0)
{
SetModelParameters();
}
TRolke::~TRolke()
{
}
void TRolke::SetPoissonBkgBinomEff(Int_t x, Int_t y, Int_t z, Double_t tau, Int_t m)
{
SetModelParameters(
x ,
y ,
z ,
0 ,
0 ,
0 ,
1 ,
0 ,
0 ,
tau,
0 ,
m);
}
void TRolke::SetPoissonBkgGaussEff(Int_t x, Int_t y, Double_t em, Double_t tau, Double_t sde)
{
SetModelParameters(
x ,
y ,
0 ,
0 ,
em ,
0 ,
2 ,
sde,
0 ,
tau,
0 ,
0);
}
void TRolke::SetGaussBkgGaussEff(Int_t x, Double_t bm, Double_t em, Double_t sde, Double_t sdb)
{
SetModelParameters(
x ,
0 ,
0 ,
bm ,
em ,
0 ,
3 ,
sde,
sdb,
0 ,
0 ,
0);
}
void TRolke::SetPoissonBkgKnownEff(Int_t x, Int_t y, Double_t tau, Double_t e)
{
SetModelParameters(
x ,
y ,
0 ,
0 ,
0 ,
e ,
4 ,
0 ,
0 ,
tau,
0 ,
0);
}
void TRolke::SetGaussBkgKnownEff(Int_t x, Double_t bm, Double_t sdb, Double_t e)
{
SetModelParameters(
x ,
0 ,
0 ,
bm ,
0 ,
e ,
5 ,
0 ,
sdb,
0 ,
0 ,
0);
}
void TRolke::SetKnownBkgBinomEff(Int_t x, Int_t z, Int_t m, Double_t b)
{
SetModelParameters(
x ,
0 ,
z ,
0 ,
0 ,
0 ,
6 ,
0 ,
0 ,
0 ,
b ,
m);
}
void TRolke::SetKnownBkgGaussEff(Int_t x, Double_t em, Double_t sde, Double_t b)
{
SetModelParameters(
x ,
0 ,
0 ,
0 ,
em ,
0 ,
7 ,
sde,
0 ,
0 ,
b ,
0);
}
bool TRolke::GetLimits(Double_t& low, Double_t& high)
{
if ((f_mid<1)||(f_mid>7)) {
std::cerr << "TRolke - Error: Model id "<< f_mid<<std::endl;
if (f_mid<1) {
std::cerr << "TRolke - Please specify a model with e.g. 'SetGaussBkgGaussEff' (read the docs in Rolke.cxx )"<<std::endl;
}
return false;
}
ComputeInterval(f_x, f_y, f_z, f_bm, f_em, f_e, f_mid, f_sde, f_sdb, f_tau, f_b, f_m);
low = fLowerLimit;
high = fUpperLimit;
if (low < high) {
return true;
}else{
std::cerr << "TRolke - Warning: no limits found" <<std::endl;
return false;
}
}
Double_t TRolke::GetUpperLimit()
{
Double_t low(0), high(0);
GetLimits(low,high);
return fUpperLimit;
}
Double_t TRolke::GetLowerLimit()
{
Double_t low(0), high(0);
GetLimits(low,high);
return fLowerLimit;
}
Double_t TRolke::GetBackground()
{
Double_t background = 0;
switch (f_mid) {
case 1:
case 2:
case 4:
background = f_y / f_tau;
break;
case 3:
case 5:
background = f_bm;
break;
case 6:
case 7:
background = f_b;
break;
default:
std::cerr << "TRolke::GetBackground(): Model NR: " <<
f_mid << " unknown"<<std::endl;
return 0;
}
return background;
}
bool TRolke::GetSensitivity(Double_t& low, Double_t& high, Double_t pPrecision)
{
Double_t background = GetBackground();
Double_t weight = 0;
Double_t weightSum = 0;
int loop_x = 0;
while (1) {
ComputeInterval(loop_x, f_y, f_z, f_bm, f_em, f_e, f_mid, f_sde, f_sdb, f_tau, f_b, f_m);
weight = TMath::PoissonI(loop_x, background);
low += fLowerLimit * weight;
high += fUpperLimit * weight;
weightSum += weight;
if (loop_x > (background + 1)) {
if ((weightSum > (1 - pPrecision)) || (weight < 1e-12)) break;
}
loop_x++;
}
low /= weightSum;
high /= weightSum;
return (low < high);
}
bool TRolke::GetLimitsQuantile(Double_t& low, Double_t& high, Int_t& out_x, Double_t integral)
{
Double_t background = GetBackground();
Double_t weight = 0;
Double_t weightSum = 0;
Int_t loop_x = 0;
while (1) {
weight = TMath::PoissonI(loop_x, background);
weightSum += weight;
if (weightSum >= integral) {
break;
}
loop_x++;
}
out_x = loop_x;
ComputeInterval(loop_x, f_y, f_z, f_bm, f_em, f_e, f_mid, f_sde, f_sdb, f_tau, f_b, f_m);
low = fLowerLimit;
high = fUpperLimit;
return (low < high);
}
bool TRolke::GetLimitsML(Double_t& low, Double_t& high, Int_t& out_x)
{
Double_t background = GetBackground();
Int_t loop_x = 0;
Int_t loop_max = 1000 + (Int_t)background;
Double_t max = TMath::PoissonI(loop_x, background);
while (loop_x <= loop_max) {
if (TMath::PoissonI(loop_x + 1, background) < max) {
break;
}
loop_x++;
max = TMath::PoissonI(loop_x, background);
}
if (loop_x >= loop_max) {
std::cout << "internal error finding maximum of distribution" << endl;
return false;
}
out_x = loop_x;
ComputeInterval(loop_x, f_y, f_z, f_bm, f_em, f_e, f_mid, f_sde, f_sdb, f_tau, f_b, f_m);
low = fLowerLimit;
high = fUpperLimit;
return (low < high);
}
bool TRolke::GetCriticalNumber(Int_t& ncrit, Int_t maxtry)
{
Double_t background = GetBackground();
int j = 0;
int rolke_ncrit = -1;
int maxj =maxtry ;
if(maxtry<1){
maxj = 1000 + (Int_t)background;
}
for (j = 0;j < maxj;j++) {
Int_t rolke_x = j;
ComputeInterval(rolke_x, f_y, f_z, f_bm, f_em, f_e, f_mid, f_sde, f_sdb, f_tau, f_b, f_m);
double rolke_ll = fLowerLimit;
if (rolke_ll > 0) {
rolke_ncrit = j;
break;
}
}
if (rolke_ncrit == -1) {
std::cerr << "TRolke GetCriticalNumber : Error: problem finding rolke inverse. Specify a larger maxtry value. maxtry was: " << maxj << ". highest x considered was j "<< j<< endl;
ncrit = -1;
return false;
} else {
ncrit = rolke_ncrit;
return true;
}
}
void TRolke::SetSwitch(bool bnd) {
if(fNumWarningsDeprecated1<2){
std::cerr << "*******************************************" <<std::endl;
std::cerr << "TRolke - Warning: 'SetSwitch' is depricated and may be removed from future releases:" <<std::endl;
std::cerr << " - Use 'SetBounding' instead "<<std::endl;
std::cerr << "*******************************************" <<std::endl;
fNumWarningsDeprecated1++;
}
SetBounding(bnd);
}
void TRolke::Print(Option_t*) const {
std::cout << "*******************************************" <<std::endl;
std::cout << "* TRolke::Print() - dump of internals: " <<std::endl;
std::cout << "*"<<std::endl;
std::cout << "* model id, mid = "<<f_mid <<endl;
std::cout << "*"<<std::endl;
std::cout << "* x = "<<f_x <<std::endl;
std::cout << "* bm = "<<f_bm <<endl;
std::cout << "* em = "<<f_em <<endl;
std::cout << "* sde = "<<f_sde <<endl;
std::cout << "* sdb = "<<f_sdb <<endl;
std::cout << "* y = "<<f_y <<endl;
std::cout << "* tau = "<<f_tau <<endl;
std::cout << "* e = "<<f_e <<endl;
std::cout << "* b = "<<f_b <<endl;
std::cout << "* m = "<<f_m <<endl;
std::cout << "* z = "<<f_z <<endl;
std::cout << "*"<<std::endl;
std::cout << "* CL = "<<fCL <<endl;
std::cout << "* Bounding = "<<fBounding <<endl;
std::cout << "*"<<std::endl;
std::cout << "* calculated on demand only:"<<std::endl;
std::cout << "* fUpperLimit = "<<fUpperLimit<<endl;
std::cout << "* fLowerLimit = "<<fLowerLimit<<endl;
std::cout << "*******************************************" <<std::endl;
}
Double_t TRolke::CalculateInterval(Int_t x, Int_t y, Int_t z, Double_t bm, Double_t em, Double_t e, Int_t mid, Double_t sde, Double_t sdb, Double_t tau, Double_t b, Int_t m){
if (fNumWarningsDeprecated2<2 ) {
std::cerr << "*******************************************" <<std::endl;
std::cerr << "TRolke - Warning: 'CalculateInterval' is depricated and may be removed from future releases:" <<std::endl;
std::cerr << " - Use e.g. 'SetGaussBkgGaussEff' and 'GetLimits' instead (read the docs in Rolke.cxx )"<<std::endl;
std::cerr << "*******************************************" <<std::endl;
fNumWarningsDeprecated2++;
}
SetModelParameters(
x,
y,
z,
bm,
em,
e,
mid,
sde,
sdb,
tau,
b,
m);
return ComputeInterval(f_x, f_y, f_z, f_bm, f_em, f_e, f_mid, f_sde, f_sdb, f_tau, f_b, f_m);
}
void TRolke::SetModelParameters(Int_t x, Int_t y, Int_t z, Double_t bm, Double_t em, Double_t e, Int_t mid, Double_t sde, Double_t sdb, Double_t tau, Double_t b, Int_t m)
{
f_x = x ;
f_y = y ;
f_z = z ;
f_bm = bm ;
f_em = em ;
f_e = e ;
f_mid = mid ;
f_sde = sde ;
f_sdb = sdb ;
f_tau = tau ;
f_b = b ;
f_m = m ;
}
void TRolke::SetModelParameters()
{
SetModelParameters(0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0);
f_mid=0;
}
Double_t TRolke::ComputeInterval(Int_t x, Int_t y, Int_t z, Double_t bm, Double_t em, Double_t e, Int_t mid, Double_t sde, Double_t sdb, Double_t tau, Double_t b, Int_t m)
{
Int_t done = 0;
Double_t limit[2];
limit[1] = Interval(x, y, z, bm, em, e, mid, sde, sdb, tau, b, m);
if (limit[1] > 0) {
done = 1;
}
if (! fBounding) {
Int_t trial_x = x;
while (done == 0) {
trial_x++;
limit[1] = Interval(trial_x, y, z, bm, em, e, mid, sde, sdb, tau, b, m);
if (limit[1] > 0) done = 1;
}
}
return limit[1];
}
Double_t TRolke::Interval(Int_t x, Int_t y, Int_t z, Double_t bm, Double_t em, Double_t e, Int_t mid, Double_t sde, Double_t sdb, Double_t tau, Double_t b, Int_t m)
{
Double_t dchi2 = TMath::ChisquareQuantile(fCL, 1);
Double_t tempxy[2], limits[2] = {0, 0};
Double_t slope, fmid, low, flow, high, fhigh, test, ftest, mu0, maximum, target, l, f0;
Double_t med = 0;
Double_t maxiter = 1000, acc = 0.00001;
Int_t i;
Int_t bp = 0;
if ((mid != 3) && (mid != 5)) bm = y;
if ((mid == 3) || (mid == 5)) {
if (bm == 0) bm = 0.00001;
}
if ((mid == 6) || (mid == 7)) {
if (bm == 0) bm = 0.00001;
}
if ((mid <= 2) || (mid == 4)) bp = 1;
if (bp == 1 && x == 0 && bm > 0) {
for (i = 0; i < 2; i++) {
x++;
tempxy[i] = Interval(x, y, z, bm, em, e, mid, sde, sdb, tau, b, m);
}
slope = tempxy[1] - tempxy[0];
limits[1] = tempxy[0] - slope;
limits[0] = 0.0;
if (limits[1] < 0) limits[1] = 0.0;
goto done;
}
if (bp != 1 && x == 0) {
for (i = 0; i < 2; i++) {
x++;
tempxy[i] = Interval(x, y, z, bm, em, e, mid, sde, sdb, tau, b, m);
}
slope = tempxy[1] - tempxy[0];
limits[1] = tempxy[0] - slope;
limits[0] = 0.0;
if (limits[1] < 0) limits[1] = 0.0;
goto done;
}
if (bp != 1 && bm == 0) {
for (i = 0; i < 2; i++) {
bm++;
limits[1] = Interval(x, y, z, bm, em, e, mid, sde, sdb, tau, b, m);
tempxy[i] = limits[1];
}
slope = tempxy[1] - tempxy[0];
limits[1] = tempxy[0] - slope;
if (limits[1] < 0) limits[1] = 0;
goto done;
}
if (x == 0 && bm == 0) {
x++;
bm++;
limits[1] = Interval(x, y, z, bm, em, e, mid, sde, sdb, tau, b, m);
tempxy[0] = limits[1];
x = 1;
bm = 2;
limits[1] = Interval(x, y, z, bm, em, e, mid, sde, sdb, tau, b, m);
tempxy[1] = limits[1];
x = 2;
bm = 1;
limits[1] = Interval(x, y, z, bm, em, e, mid, sde, sdb, tau, b, m);
limits[1] = 3 * tempxy[0] - tempxy[1] - limits[1];
if (limits[1] < 0) limits[1] = 0;
goto done;
}
mu0 = Likelihood(0, x, y, z, bm, em, mid, sde, sdb, tau, b, m, 1);
maximum = Likelihood(0, x, y, z, bm, em, mid, sde, sdb, tau, b, m, 2);
test = 0;
f0 = Likelihood(test, x, y, z, bm, em, mid, sde, sdb, tau, b, m, 3);
if (fBounding) {
if (mu0 < 0) maximum = f0;
}
target = maximum - dchi2;
if (f0 > target) {
limits[0] = 0;
} else {
if (mu0 < 0) {
limits[0] = 0;
limits[1] = 0;
}
low = 0;
flow = f0;
high = mu0;
fhigh = maximum;
for (i = 0; i < maxiter; i++) {
l = (target - fhigh) / (flow - fhigh);
if (l < 0.2) l = 0.2;
if (l > 0.8) l = 0.8;
med = l * low + (1 - l) * high;
if (med < 0.01) {
limits[1] = 0.0;
goto done;
}
fmid = Likelihood(med, x, y, z, bm, em, mid, sde, sdb, tau, b, m, 3);
if (fmid > target) {
high = med;
fhigh = fmid;
} else {
low = med;
flow = fmid;
}
if ((high - low) < acc*high) break;
}
limits[0] = med;
}
if (mu0 > 0) {
low = mu0;
flow = maximum;
} else {
low = 0;
flow = f0;
}
test = low + 1 ;
ftest = Likelihood(test, x, y, z, bm, em, mid, sde, sdb, tau, b, m, 3);
if (ftest < target) {
high = test;
fhigh = ftest;
} else {
slope = (ftest - flow) / (test - low);
high = test + (target - ftest) / slope;
fhigh = Likelihood(high, x, y, z, bm, em, mid, sde, sdb, tau, b, m, 3);
}
for (i = 0; i < maxiter; i++) {
l = (target - fhigh) / (flow - fhigh);
if (l < 0.2) l = 0.2;
if (l > 0.8) l = 0.8;
med = l * low + (1. - l) * high;
fmid = Likelihood(med, x, y, z, bm, em, mid, sde, sdb, tau, b, m, 3);
if (fmid < target) {
high = med;
fhigh = fmid;
} else {
low = med;
flow = fmid;
}
if (high - low < acc*high) break;
}
limits[1] = med;
done:
if ((mid == 4) || (mid == 5)) {
limits[0] /= e;
limits[1] /= e;
}
fUpperLimit = limits[1];
fLowerLimit = TMath::Max(limits[0], 0.0);
return limits[1];
}
Double_t TRolke::Likelihood(Double_t mu, Int_t x, Int_t y, Int_t z, Double_t bm, Double_t em, Int_t mid, Double_t sde, Double_t sdb, Double_t tau, Double_t b, Int_t m, Int_t what)
{
switch (mid) {
case 1:
return EvalLikeMod1(mu, x, y, z, tau, m, what);
case 2:
return EvalLikeMod2(mu, x, y, em, sde, tau, what);
case 3:
return EvalLikeMod3(mu, x, bm, em, sde, sdb, what);
case 4:
return EvalLikeMod4(mu, x, y, tau, what);
case 5:
return EvalLikeMod5(mu, x, bm, sdb, what);
case 6:
return EvalLikeMod6(mu, x, z, b, m, what);
case 7:
return EvalLikeMod7(mu, x, em, sde, b, what);
default:
std::cerr << "TRolke::Likelihood(...): Model NR: " <<
f_mid << " unknown"<<std::endl;
return 0;
}
return 0;
}
Double_t TRolke::EvalLikeMod1(Double_t mu, Int_t x, Int_t y, Int_t z, Double_t tau, Int_t m, Int_t what)
{
Double_t f = 0;
Double_t zm = Double_t(z) / m;
if (what == 1) {
f = (x - y / tau) / zm;
}
if (what == 2) {
mu = (x - y / tau) / zm;
Double_t b = y / tau;
Double_t e = zm;
f = LikeMod1(mu, b, e, x, y, z, tau, m);
}
if (what == 3) {
if (mu == 0) {
Double_t b = (x + y) / (1.0 + tau);
Double_t e = zm;
f = LikeMod1(mu, b, e, x, y, z, tau, m);
} else {
Double_t e = 0;
Double_t b = 0;
ProfLikeMod1(mu, b, e, x, y, z, tau, m);
f = LikeMod1(mu, b, e, x, y, z, tau, m);
}
}
return f;
}
Double_t TRolke::LikeMod1(Double_t mu, Double_t b, Double_t e, Int_t x, Int_t y, Int_t z, Double_t tau, Int_t m)
{
double s = e*mu+b;
double lls = - s;
if (x > 0) lls = x*TMath::Log(s) - s - LogFactorial(x);
double bg = tau*b;
double llb = -bg;
if ( y > 0) llb = y*TMath::Log( bg) - bg - LogFactorial(y);
double lle = 0;
if (z == 0) lle = m * TMath::Log(1-e);
else if ( z == m) lle = m * TMath::Log(e);
else lle = z * TMath::Log(e) + (m - z)*TMath::Log(1 - e) + LogFactorial(m) - LogFactorial(m-z) - LogFactorial(z);
double f = 2*( lls + llb + lle);
return f;
}
struct LikeFunction1 {
};
void TRolke::ProfLikeMod1(Double_t mu, Double_t &b, Double_t &e, Int_t x, Int_t y, Int_t z, Double_t tau, Int_t m)
{
Double_t med = 0.0, fmid;
Int_t maxiter = 1000;
Double_t acc = 0.00001;
Double_t emin = ((m + mu * tau) - TMath::Sqrt((m + mu * tau) * (m + mu * tau) - 4 * mu * tau * z)) / 2 / mu / tau;
Double_t low = TMath::Max(1e-10, emin + 1e-10);
Double_t high = 1 - 1e-10;
for (Int_t i = 0; i < maxiter; i++) {
med = (low + high) / 2.;
fmid = LikeGradMod1(med, mu, x, y, z, tau, m);
if (high < 0.5) acc = 0.00001 * high;
else acc = 0.00001 * (1 - high);
if ((high - low) < acc*high) break;
if (fmid > 0) low = med;
else high = med;
}
e = med;
Double_t eta = Double_t(z) / e - Double_t(m - z) / (1 - e);
b = Double_t(y) / (tau - eta / mu);
}
Double_t TRolke::LikeGradMod1(Double_t e, Double_t mu, Int_t x, Int_t y, Int_t z, Double_t tau, Int_t m)
{
Double_t eta, etaprime, bprime, f;
eta = static_cast<double>(z) / e - static_cast<double>(m - z) / (1.0 - e);
etaprime = (-1) * (static_cast<double>(m - z) / ((1.0 - e) * (1.0 - e)) + static_cast<double>(z) / (e * e));
Double_t b = y / (tau - eta / mu);
bprime = (b * b * etaprime) / mu / y;
f = (mu + bprime) * (x / (e * mu + b) - 1) + (y / b - tau) * bprime + eta;
return f;
}
Double_t TRolke::EvalLikeMod2(Double_t mu, Int_t x, Int_t y, Double_t em, Double_t sde, Double_t tau, Int_t what)
{
Double_t v = sde * sde;
Double_t coef[4], roots[3];
Double_t f = 0;
if (what == 1) {
f = (x - y / tau) / em;
}
if (what == 2) {
mu = (x - y / tau) / em;
Double_t b = y / tau;
Double_t e = em;
f = LikeMod2(mu, b, e, x, y, em, tau, v);
}
if (what == 3) {
if (mu == 0) {
Double_t b = (x + y) / (1 + tau);
Double_t e = em ;
f = LikeMod2(mu, b, e, x, y, em, tau, v);
} else {
coef[3] = mu;
coef[2] = mu * mu * v - 2 * em * mu - mu * mu * v * tau;
coef[1] = (- x) * mu * v - mu * mu * mu * v * v * tau - mu * mu * v * em + em * mu * mu * v * tau + em * em * mu - y * mu * v;
coef[0] = x * mu * mu * v * v * tau + x * em * mu * v - y * mu * mu * v * v + y * em * mu * v;
TMath::RootsCubic(coef, roots[0], roots[1], roots[2]);
Double_t e = roots[1];
Double_t b;
if ( v > 0) b = y / (tau + (em - e) / mu / v);
else b = y/tau;
f = LikeMod2(mu, b, e, x, y, em, tau, v);
}
}
return f;
}
Double_t TRolke::LikeMod2(Double_t mu, Double_t b, Double_t e, Int_t x, Int_t y, Double_t em, Double_t tau, Double_t v)
{
double s = e*mu+b;
double lls = - s;
if (x > 0) lls = x*TMath::Log(s) - s - LogFactorial(x);
double bg = tau*b;
double llb = -bg;
if ( y > 0) llb = y*TMath::Log( bg) - bg - LogFactorial(y);
double lle = 0;
if ( v > 0) lle = - 0.9189385 - TMath::Log(v) / 2 - (em - e)*(em - e) / v / 2;
return 2*( lls + llb + lle);
}
Double_t TRolke::EvalLikeMod3(Double_t mu, Int_t x, Double_t bm, Double_t em, Double_t sde, Double_t sdb, Int_t what)
{
Double_t f = 0.;
Double_t v = sde * sde;
Double_t u = sdb * sdb;
if (what == 1) {
f = (x - bm) / em;
}
if (what == 2) {
mu = (x - bm) / em;
Double_t b = bm;
Double_t e = em;
f = LikeMod3(mu, b, e, x, bm, em, u, v);
}
if (what == 3) {
if (mu == 0.0) {
Double_t b = ((bm - u) + TMath::Sqrt((bm - u) * (bm - u) + 4 * x * u)) / 2.;
Double_t e = em;
f = LikeMod3(mu, b, e, x, bm, em, u, v);
} else {
Double_t e = em;
Double_t b = bm;
if ( v > 0) {
Double_t temp[3];
temp[0] = mu * mu * v + u;
temp[1] = mu * mu * mu * v * v + mu * v * u - mu * mu * v * em + mu * v * bm - 2 * u * em;
temp[2] = mu * mu * v * v * bm - mu * v * u * em - mu * v * bm * em + u * em * em - mu * mu * v * v * x;
e = (-temp[1] + TMath::Sqrt(temp[1] * temp[1] - 4 * temp[0] * temp[2])) / 2 / temp[0];
b = bm - (u * (em - e)) / v / mu;
}
f = LikeMod3(mu, b, e, x, bm, em, u, v);
}
}
return f;
}
Double_t TRolke::LikeMod3(Double_t mu, Double_t b, Double_t e, Int_t x, Double_t bm, Double_t em, Double_t u, Double_t v)
{
double s = e*mu+b;
double lls = - s;
if (x > 0) lls = x*TMath::Log(s) - s - LogFactorial(x);
double llb = 0;
if ( u > 0) llb = - 0.9189385 - TMath::Log(u) / 2 - (bm - b)*(bm - b) / u / 2;
double lle = 0;
if ( v > 0) lle = - 0.9189385 - TMath::Log(v) / 2 - (em - e)*(em - e) / v / 2;
return 2*( lls + llb + lle);
}
Double_t TRolke::EvalLikeMod4(Double_t mu, Int_t x, Int_t y, Double_t tau, Int_t what)
{
Double_t f = 0.0;
if (what == 1) f = x - y / tau;
if (what == 2) {
mu = x - y / tau;
Double_t b = y / tau;
f = LikeMod4(mu, b, x, y, tau);
}
if (what == 3) {
if (mu == 0.0) {
Double_t b = Double_t(x + y) / (1 + tau);
f = LikeMod4(mu, b, x, y, tau);
} else {
Double_t b = (x + y - (1 + tau) * mu + sqrt((x + y - (1 + tau) * mu) * (x + y - (1 + tau) * mu) + 4 * (1 + tau) * y * mu)) / 2 / (1 + tau);
f = LikeMod4(mu, b, x, y, tau);
}
}
return f;
}
Double_t TRolke::LikeMod4(Double_t mu, Double_t b, Int_t x, Int_t y, Double_t tau)
{
double s = mu+b;
double lls = - s;
if (x > 0) lls = x*TMath::Log(s) - s - LogFactorial(x);
double bg = tau*b;
double llb = -bg;
if ( y > 0) llb = y*TMath::Log( bg) - bg - LogFactorial(y);
return 2*( lls + llb);
}
Double_t TRolke::EvalLikeMod5(Double_t mu, Int_t x, Double_t bm, Double_t sdb, Int_t what)
{
Double_t u = sdb * sdb;
Double_t f = 0;
if (what == 1) {
f = x - bm;
}
if (what == 2) {
mu = x - bm;
Double_t b = bm;
f = LikeMod5(mu, b, x, bm, u);
}
if (what == 3) {
Double_t b = ((bm - u - mu) + TMath::Sqrt((bm - u - mu) * (bm - u - mu) - 4 * (mu * u - mu * bm - u * x))) / 2;
f = LikeMod5(mu, b, x, bm, u);
}
return f;
}
Double_t TRolke::LikeMod5(Double_t mu, Double_t b, Int_t x, Double_t bm, Double_t u)
{
double s = mu+b;
double lls = - s;
if (x > 0) lls = x*TMath::Log(s) - s - LogFactorial(x);
double llb = 0;
if ( u > 0) llb = - 0.9189385 - TMath::Log(u) / 2 - (bm - b)*(bm - b) / u / 2;
return 2*( lls + llb);
}
Double_t TRolke::EvalLikeMod6(Double_t mu, Int_t x, Int_t z, Double_t b, Int_t m, Int_t what)
{
Double_t coef[4], roots[3];
Double_t f = 0.;
Double_t zm = Double_t(z) / m;
if (what == 1) {
f = (x - b) / zm;
}
if (what == 2) {
mu = (x - b) / zm;
Double_t e = zm;
f = LikeMod6(mu, b, e, x, z, m);
}
if (what == 3) {
Double_t e;
if (mu == 0) {
e = zm;
} else {
coef[3] = mu * mu;
coef[2] = mu * b - mu * x - mu * mu - mu * m;
coef[1] = mu * x - mu * b + mu * z - m * b;
coef[0] = b * z;
TMath::RootsCubic(coef, roots[0], roots[1], roots[2]);
e = roots[1];
}
f = LikeMod6(mu, b, e, x, z, m);
}
return f;
}
Double_t TRolke::LikeMod6(Double_t mu, Double_t b, Double_t e, Int_t x, Int_t z, Int_t m)
{
double s = e*mu+b;
double lls = - s;
if (x > 0) lls = x*TMath::Log(s) - s - LogFactorial(x);
double lle = 0;
if (z == 0) lle = m * TMath::Log(1-e);
else if ( z == m) lle = m * TMath::Log(e);
else lle = z * TMath::Log(e) + (m - z)*TMath::Log(1 - e) + LogFactorial(m) - LogFactorial(m-z) - LogFactorial(z);
return 2* (lls + lle);
}
Double_t TRolke::EvalLikeMod7(Double_t mu, Int_t x, Double_t em, Double_t sde, Double_t b, Int_t what)
{
Double_t v = sde * sde;
Double_t f = 0.;
if (what == 1) {
f = (x - b) / em;
}
if (what == 2) {
mu = (x - b) / em;
Double_t e = em;
f = LikeMod7(mu, b, e, x, em, v);
}
if (what == 3) {
Double_t e;
if (mu == 0) {
e = em;
} else {
e = (-(mu * em - b - mu * mu * v) - TMath::Sqrt((mu * em - b - mu * mu * v) * (mu * em - b - mu * mu * v) + 4 * mu * (x * mu * v - mu * b * v + b * em))) / (- mu) / 2;
}
f = LikeMod7(mu, b, e, x, em, v);
}
return f;
}
Double_t TRolke::LikeMod7(Double_t mu, Double_t b, Double_t e, Int_t x, Double_t em, Double_t v)
{
double s = e*mu+b;
double lls = - s;
if (x > 0) lls = x*TMath::Log(s) - s - LogFactorial(x);
double lle = 0;
if ( v > 0) lle = - 0.9189385 - TMath::Log(v) / 2 - (em - e)*(em - e) / v / 2;
return 2*( lls + lle);
}
Double_t TRolke::EvalPolynomial(Double_t x, const Int_t coef[], Int_t N)
{
const Int_t *p;
p = coef;
Double_t ans = *p++;
Int_t i = N;
do
ans = ans * x + *p++;
while (--i);
return ans;
}
Double_t TRolke::EvalMonomial(Double_t x, const Int_t coef[], Int_t N)
{
Double_t ans;
const Int_t *p;
p = coef;
ans = x + *p++;
Int_t i = N - 1;
do
ans = ans * x + *p++;
while (--i);
return ans;
}
Double_t TRolke::LogFactorial(Int_t n)
{
return TMath::LnGamma(n+1);
}