11 #define M_PI 3.141592653589793238463
19 #if defined __cplusplus
103 xDataTOM_element *energyElement, *linearElement, *functional, *frameElement;
104 char const *nativeData;
105 double projectileMass_MeV, targetMass_MeV;
111 energy->
e_inCOMFactor = targetMass_MeV / ( projectileMass_MeV + targetMass_MeV );
114 energy->
type = energyType;
123 if( linearElement == NULL ) {
142 frameElement = functional; }
144 char const *toUnits[3] = {
"MeV",
"MeV",
"1/MeV" };
146 frameElement = linearElement;
169 if( strcmp( child->name,
"weighted" ) )
goto err;
187 char const *toUnits[2] = {
"MeV",
"" };
191 if( strcmp( child->
name,
"weight" ) == 0 ) {
193 else if( strcmp( child->
name,
"evaporation" ) == 0 ) {
217 char const *toUnits[2] = {
"MeV",
"MeV" };
229 if( std::fabs( 1. - norm ) > 0.001 )
printf(
"bad norm = %e\n", norm );
232 energy->
theta = theta;
245 char const *U, *toUnits[2] = {
"MeV",
"MeV" };
266 char const *U, *toUnits[2] = {
"MeV",
"MeV" };
287 char const *U, *toUnits[2] = {
"MeV",
"MeV" };
299 toUnits[1] =
"1/MeV";
314 int iE, length, nXs, i1,
n;
315 double E, T_M, EFL, EFH, argList[3], xs[] = { 1
e-5, 1
e-3, 1e-1, 1e1, 1e3, 1e5, 3e7 },
norm;
324 char const *EF, *TMUnits[2] = {
"MeV",
"MeV" };
326 nXs =
sizeof( xs ) /
sizeof( xs[0] );
349 if( ( dists->
Ws = (
double *)
smr_malloc2( smr, length *
sizeof(
double ), 1,
"dists->Ws" ) ) == NULL )
goto err;
352 for( iE = 0; iE < length; iE++ ) {
355 dist = &(dists->
dist[iE]);
359 (
void *) argList, 1
e-3, 0, 12, &status ) ) == NULL )
goto err;
368 if( ( dist->
Xs = (
double *)
smr_malloc2( smr, 3 * n *
sizeof(
double ), 0,
"dist->Xs" ) ) == NULL )
goto err;
370 dist->
pdf = &(dist->
Xs[
n]);
373 for( i1 = 0; i1 <
n; i1++ ) {
375 dist->
Xs[i1] = point->
x;
376 dist->
pdf[i1] = point->
y;
386 for( i1 = 0; i1 <
n; i1++ ) dist->
pdf[i1] /=
norm;
397 if( ptwXY_TM != NULL )
ptwXY_free( ptwXY_TM );
399 if( cdfX != NULL ) cdfX =
ptwX_free( cdfX );
408 double *parameters = (
double *) argList, EFL, EFH, T_M;
424 double u1, u2, E1, E2, gamma1, gamma2, signG = 1;
426 u1 = std::sqrt( Ep ) - std::sqrt( E_F );
428 u2 = std::sqrt( Ep ) + std::sqrt( E_F );
433 if( *status !=
nfu_Okay )
return( 0. );
442 if( *status !=
nfu_Okay )
return( 0. );
443 return( ( u2 * std::sqrt( u2 ) * E2 - u1 * std::sqrt( u1 ) * E1 + signG * ( gamma2 - gamma1 ) ) / ( 3 * std::sqrt( E_F * T_M ) ) );
452 double xs[2] = { 0.0, 1.0 }, productMass_MeV,
norm;
490 int numberOfProducts = *((
int *) argList);
491 double e = 0.5 * ( 3 * numberOfProducts - 8 );
508 switch( energy->
type ) {
516 randomEp = decaySamplingInfo->
rng( decaySamplingInfo->
rngState );
520 decaySamplingInfo->
Ep = sampled.
x;
526 decaySamplingInfo->
Ep = theta * sampled.
x;
531 decaySamplingInfo->
Ep *= theta;
536 decaySamplingInfo->
Ep *= theta;
545 decaySamplingInfo->
Ep = sampled.
x;
566 double a = e_in_U_theta, b, c,
x, norm_a, xMin = 0., xMax =
a, sqrt_x, sqrt_pi_2 = std::sqrt(
M_PI ) / 2.;
568 sqrt_x = std::sqrt( a );
569 norm_a = sqrt_pi_2 * erf( sqrt_x ) - sqrt_x *
G4Exp( -a );
570 b = norm_a * decaySamplingInfo->
rng( decaySamplingInfo->
rngState );
571 for( i1 = 0; i1 < 16; i1++ ) {
572 x = 0.5 * ( xMin + xMax );
573 sqrt_x = std::sqrt( x );
574 c = sqrt_pi_2 * erf( sqrt_x ) - sqrt_x *
G4Exp( -x );
582 decaySamplingInfo->
Ep =
x;
592 double a = e_in_U_theta, b, c,
x, norm_a, xMin = 0., xMax =
a;
594 norm_a = 1 - ( 1 +
a ) *
G4Exp( -a );
595 b = 1. - norm_a * decaySamplingInfo->
rng( decaySamplingInfo->
rngState );
596 for( i1 = 0; i1 < 16; i1++ ) {
597 x = 0.5 * ( xMin + xMax );
598 c = ( 1 +
x ) *
G4Exp( -x );
606 decaySamplingInfo->
Ep =
x;
617 double WattMin = 0., WattMax = e_in_U,
x,
y,
z, energyOut, rand1, rand2;
619 x = 1. + ( Watt_b / ( 8. * Watt_a ) );
620 y = ( x + std::sqrt( x * x - 1. ) ) / Watt_a;
623 G4int icounter_max=1024;
627 if ( icounter > icounter_max ) {
628 G4cout <<
"Loop-counter exceeded the threshold value at " << __LINE__ <<
"th line of " << __FILE__ <<
"." <<
G4endl;
633 energyOut = y * rand1;
635 while( ( ( rand2 - z * ( rand1 + 1. ) ) * ( rand2 - z * ( rand1 + 1. ) ) > Watt_b * y * rand1 ) || ( energyOut < WattMin ) || ( energyOut > WattMax ) );
636 decaySamplingInfo->
Ep = energyOut;
649 double rW = decaySamplingInfo->
rng( decaySamplingInfo->
rngState ), cumulativeW = 0.,
weight;
656 if( cumulativeW >= rW )
break;
661 #if defined __cplusplus
G4double G4Exp(G4double initial_x)
Exponential Function double precision.
xDataTOM_element * xDataTOME_getNextElement(xDataTOM_element *element)
MCGIDI_energyNBodyPhaseSpace NBodyPhaseSpace
ptwXPoints * ptwX_free(ptwXPoints *ptwX)
ptwXY_interpolation interpolationXY
ptwXY_interpolation gInterpolation
double nf_incompleteGammaFunction(double a, double x, nfu_status *status)
std::vector< ExP01TrackerHit * > a
double primaryGammaMassFactor
ptwXYPoints * ptwXY_createFromFunction(int n, double *xs, ptwXY_createFromFunction_callback func, void *argList, double accuracy, int checkForRoots, int biSectionMax, nfu_status *status)
static int MCGIDI_energy_parseGeneralEvaporationFromTOM(statusMessageReporting *smr, xDataTOM_element *element, MCGIDI_energy *energy)
static int MCGIDI_energy_sampleWatt(statusMessageReporting *smr, double e_in_U, double Watt_a, double Watt_b, MCGIDI_decaySamplingInfo *decaySamplingInfo)
double MCGIDI_product_getProjectileMass_MeV(statusMessageReporting *smr, MCGIDI_product *product)
#define smr_setReportError2(smr, libraryID, code, fmt,...)
int64_t ptwXY_length(ptwXYPoints *ptwXY)
MCGIDI_outputChannel * outputChannel
int MCGIDI_fromTOM_pdfsOfXGivenW(statusMessageReporting *smr, xDataTOM_element *element, MCGIDI_pdfsOfXGivenW *dists, ptwXYPoints *norms, char const *toUnits[3])
int MCGIDI_fromTOM_pdfOfX(statusMessageReporting *smr, ptwXYPoints *pdfXY, MCGIDI_pdfOfX *dist, double *norm)
nfu_status(* ptwXY_createFromFunction_callback)(double x, double *y, void *argList)
statusMessageReporting * smr
ptwXYPoints * MCGIDI_misc_dataFromXYs2ptwXYPointsInUnitsOf(statusMessageReporting *smr, xDataTOM_XYs *XYs, ptwXY_interpolation interpolation, char const *units[2])
static nfu_status MCGIDI_energy_NBodyPhaseSpacePDF_callback(double x, double *y, void *argList)
static int MCGIDI_energy_parseMadlandNixFromTOM(statusMessageReporting *smr, xDataTOM_element *functional, MCGIDI_energy *energy)
MCGIDI_energyWeightedFunctionals weightedFunctionals
xDataTOM_element * xDataTOME_getFirstElement(xDataTOM_element *element)
ptwXPoints * ptwXY_runningIntegral(ptwXYPoints *ptwXY, nfu_status *status)
double ptwX_getPointAtIndex_Unsafely(ptwXPoints *ptwX, int64_t index)
int MCGIDI_misc_PQUStringToDoubleInUnitOf(statusMessageReporting *smr, char const *str, char const *toUnit, double *value)
static int MCGIDI_energy_parseSimpleMaxwellianFissionFromTOM(statusMessageReporting *smr, xDataTOM_element *element, MCGIDI_energy *energy)
G4double G4Log(G4double x)
int MCGIDI_sampling_pdfsOfX_release(statusMessageReporting *smr, MCGIDI_pdfOfX *dist)
void * xDataTOME_getXDataIfID(statusMessageReporting *smr, xDataTOM_element *TE, char const *ID)
static int MCGIDI_energy_parseNBodyPhaseSpaceFromTOM(statusMessageReporting *smr, xDataTOM_element *functional, MCGIDI_energy *energy, MCGIDI_distribution *distribution)
ptwXY_interpolation interpolationWY
enum MCGIDI_energyType type
MCGIDI_energy * MCGIDI_energy_new(statusMessageReporting *smr)
static constexpr double g
double MCGIDI_outputChannel_getQ_MeV(statusMessageReporting *smr, MCGIDI_outputChannel *outputChannel, double e_in)
#define smr_malloc2(smr, size, zero, forItem)
xDataTOM_element * xDataTOME_getOneElementByName(statusMessageReporting *smr, xDataTOM_element *element, char const *name, int required)
enum xDataTOM_frame MCGIDI_misc_getProductFrame(statusMessageReporting *smr, xDataTOM_element *frameElement)
char const * xDataTOM_getAttributesValueInElement(xDataTOM_element *element, char const *name)
ptwXYPoints * MCGIDI_misc_dataFromElement2ptwXYPointsInUnitsOf(statusMessageReporting *smr, xDataTOM_element *linear, char const *toUnits[2])
double nf_incompleteGammaFunctionComplementary(double a, double x, nfu_status *status)
static G4Pow * GetInstance()
int MCGIDI_energy_initialize(statusMessageReporting *smr, MCGIDI_energy *energy)
MCGIDI_energy * MCGIDI_energy_free(statusMessageReporting *smr, MCGIDI_energy *energy)
G4double powA(G4double A, G4double y) const
int MCGIDI_sampling_sampleX_from_pdfsOfXGivenW(MCGIDI_pdfsOfXGivenW *dists, MCGIDI_pdfsOfXGivenW_sampled *sampled, double r)
double MCGIDI_sampling_ptwXY_getValueAtX(ptwXYPoints *ptwXY, double x1)
int smr_isOk(statusMessageReporting *smr)
static double MCGIDI_energy_parseMadlandNixFromTOM_callback_g(double Ep, double EFL, double T_M, nfu_status *status)
static int MCGIDI_energy_parseWeightedFunctionalsFromTOM(statusMessageReporting *smr, xDataTOM_element *element, MCGIDI_energy *energy)
MCGIDI_pdfsOfXGivenW dists
int MCGIDI_energy_release(statusMessageReporting *smr, MCGIDI_energy *energy)
int MCGIDI_energy_sampleEnergy(statusMessageReporting *smr, MCGIDI_energy *energy, MCGIDI_quantitiesLookupModes &modes, MCGIDI_decaySamplingInfo *decaySamplingInfo)
enum nfu_status_e nfu_status
printf("%d Experimental points found\n", nlines)
typedef int(XMLCALL *XML_NotStandaloneHandler)(void *userData)
static int MCGIDI_energy_sampleEvaporation(statusMessageReporting *smr, double e_in_U_theta, MCGIDI_decaySamplingInfo *decaySamplingInfo)
enum xDataTOM_frame frame
int MCGIDI_sampling_sampleX_from_pdfOfX(MCGIDI_pdfOfX *dist, MCGIDI_pdfsOfXGivenW_sampled *sampled, double r)
double MCGIDI_product_getTargetMass_MeV(statusMessageReporting *smr, MCGIDI_product *product)
double nf_exponentialIntegral(int n, double x, nfu_status *status)
static int MCGIDI_energy_sampleWeightedFunctional(statusMessageReporting *smr, MCGIDI_energy *energy, MCGIDI_quantitiesLookupModes &modes, MCGIDI_decaySamplingInfo *decaySamplingInfo)
int MCGIDI_misc_PQUStringToDouble(statusMessageReporting *smr, char const *str, char const *unit, double conversion, double *value)
void * smr_freeMemory(void **p)
ptwXY_interpolation interpolationXY
static int MCGIDI_energy_parseWeightFromTOM(statusMessageReporting *smr, xDataTOM_element *element, MCGIDI_energyWeightedFunctional *weightedFunctional)
int xDataTOME_convertAttributeToInteger(statusMessageReporting *smr, xDataTOM_element *element, char const *name, int *n)
static int MCGIDI_energy_parseEvaporationFromTOM(statusMessageReporting *smr, xDataTOM_element *element, MCGIDI_energy *energy)
ptwXYPoint * ptwXY_getPointAtIndex_Unsafely(ptwXYPoints *ptwXY, int64_t index)
static nfu_status MCGIDI_energy_parseMadlandNixFromTOM_callback(double x, double *y, void *argList)
nfu_status ptwXY_getXYPairAtIndex(ptwXYPoints *ptwXY, int64_t index, double *x, double *y)
ptwXYPoints * ptwXY_free(ptwXYPoints *ptwXY)
MCGIDI_energyWeightedFunctional weightedFunctional[4]
nfu_status ptwXY_simpleCoalescePoints(ptwXYPoints *ptwXY)
double getProjectileEnergy(void) const
G4GLOB_DLL std::ostream G4cout
enum xDataTOM_frame frame
nfu_status ptwXY_normalize(ptwXYPoints *ptwXY1)
const char * nfu_statusMessage(nfu_status status)
int MCGIDI_sampling_pdfsOfXGivenW_release(statusMessageReporting *smr, MCGIDI_pdfsOfXGivenW *dists)
static int MCGIDI_energy_sampleSimpleMaxwellianFission(statusMessageReporting *smr, double e_in_U_theta, MCGIDI_decaySamplingInfo *decaySamplingInfo)
double MCGIDI_product_getMass_MeV(statusMessageReporting *smr, MCGIDI_product *product)
int MCGIDI_energy_parseFromTOM(statusMessageReporting *smr, xDataTOM_element *element, MCGIDI_distribution *distribution, ptwXYPoints *norms, enum MCGIDI_energyType energyType, double gammaEnergy_MeV)
ptwXY_interpolation ptwXY_getInterpolation(ptwXYPoints *ptwXY)
static int MCGIDI_energy_parseWattFromTOM(statusMessageReporting *smr, xDataTOM_element *element, MCGIDI_energy *energy)