int main() { struct compoundData cdtest; int i; XRayInit(); //if something goes wrong, the test will end with EXIT_FAILURE //SetHardExit(1); std::printf("Example of C++ program using xraylib\n"); std::printf("Ca K-alpha Fluorescence Line Energy: %f\n", LineEnergy(20,KA_LINE)); std::printf("Fe partial photoionization cs of L3 at 6.0 keV: %f\n",CS_Photo_Partial(26,L3_SHELL,6.0)); std::printf("Zr L1 edge energy: %f\n",EdgeEnergy(40,L1_SHELL)); std::printf("Pb Lalpha XRF production cs at 20.0 keV (jump approx): %f\n",CS_FluorLine(82,LA_LINE,20.0)); std::printf("Pb Lalpha XRF production cs at 20.0 keV (Kissel): %f\n",CS_FluorLine_Kissel(82,LA_LINE,20.0)); std::printf("Bi M1N2 radiative rate: %f\n",RadRate(83,M1N2_LINE)); std::printf("U M3O3 Fluorescence Line Energy: %f\n",LineEnergy(92,M3O3_LINE)); //parser test for Ca(HCO3)2 (calcium bicarbonate) if (CompoundParser("Ca(HCO3)2",&cdtest) == 0) return 1; std::printf("Ca(HCO3)2 contains %i atoms and %i elements\n",cdtest.nAtomsAll,cdtest.nElements); for (i = 0 ; i < cdtest.nElements ; i++) std::printf("Element %i: %lf %%\n",cdtest.Elements[i],cdtest.massFractions[i]*100.0); FREE_COMPOUND_DATA(cdtest) //parser test for SiO2 (quartz) if (CompoundParser("SiO2",&cdtest) == 0) return 1; std::printf("SiO2 contains %i atoms and %i elements\n",cdtest.nAtomsAll,cdtest.nElements); for (i = 0 ; i < cdtest.nElements ; i++) std::printf("Element %i: %lf %%\n",cdtest.Elements[i],cdtest.massFractions[i]*100.0); FREE_COMPOUND_DATA(cdtest) std::printf("Ca(HCO3)2 Rayleigh cs at 10.0 keV: %f\n",CS_Rayl_CP("Ca(HCO3)2",10.0f) ); std::printf("CS2 Refractive Index at 10.0 keV : %f - %f i\n",Refractive_Index_Re("CS2",10.0f,1.261f),Refractive_Index_Im("CS2",10.0f,1.261f)); std::printf("C16H14O3 Refractive Index at 1 keV : %f - %f i\n",Refractive_Index_Re("C16H14O3",1.0f,1.2f),Refractive_Index_Im("C16H14O3",1.0f,1.2f)); std::printf("SiO2 Refractive Index at 5 keV : %f - %f i\n",Refractive_Index_Re("SiO2",5.0f,2.65f),Refractive_Index_Im("SiO2",5.0f,2.65f)); std::printf("Compton profile for Fe at pz = 1.1 : %f\n",ComptonProfile(26,1.1f)); std::printf("M5 Compton profile for Fe at pz = 1.1 : %f\n",ComptonProfile_Partial(26,M5_SHELL,1.1f)); std::printf("K atomic level width for Fe: %f\n", AtomicLevelWidth(26,K_SHELL)); std::printf("M1->M5 Coster-Kronig transition probability for Au : %f\n",CosKronTransProb(79,FM15_TRANS)); std::printf("L1->L3 Coster-Kronig transition probability for Fe : %f\n",CosKronTransProb(26,FL13_TRANS)); std::printf("Au Ma1 XRF production cs at 10.0 keV (Kissel): %f\n", CS_FluorLine_Kissel(79,MA1_LINE,10.0f)); std::printf("Au Mb XRF production cs at 10.0 keV (Kissel): %f\n", CS_FluorLine_Kissel(79,MB_LINE,10.0f)); std::printf("Au Mg XRF production cs at 10.0 keV (Kissel): %f\n", CS_FluorLine_Kissel(79,MG_LINE,10.0f)); std::printf("Bi L2-M5M5 Auger non-radiative rate: %f\n",AugerRate(86,L2_M5M5_AUGER)); std::printf("Pb Malpha XRF production cs at 20.0 keV with cascade effect: %f\n",CS_FluorLine_Kissel(82,MA1_LINE,20.0)); std::printf("Pb Malpha XRF production cs at 20.0 keV with radiative cascade effect: %f\n",CS_FluorLine_Kissel_Radiative_Cascade(82,MA1_LINE,20.0)); std::printf("Pb Malpha XRF production cs at 20.0 keV with non-radiative cascade effect: %f\n",CS_FluorLine_Kissel_Nonradiative_Cascade(82,MA1_LINE,20.0)); std::printf("Pb Malpha XRF production cs at 20.0 keV without cascade effect: %f\n",CS_FluorLine_Kissel_no_Cascade(82,MA1_LINE,20.0)); /* Si Crystal structure */ Crystal_Struct* cryst = Crystal_GetCrystal("Si", NULL); if (cryst == NULL) return 1; std::printf ("Si unit cell dimensions are %f %f %f\n", cryst->a, cryst->b, cryst->c); std::printf ("Si unit cell angles are %f %f %f\n", cryst->alpha, cryst->beta, cryst->gamma); std::printf ("Si unit cell volume is %f\n", cryst->volume); std::printf ("Si atoms at:\n"); std::printf (" Z fraction X Y Z\n"); Crystal_Atom* atom; for (i = 0; i < cryst->n_atom; i++) { atom = &cryst->atom[i]; std::printf (" %3i %f %f %f %f\n", atom->Zatom, atom->fraction, atom->x, atom->y, atom->z); } /* Si diffraction parameters */ std::printf ("\nSi111 at 8 KeV. Incidence at the Bragg angle:\n"); float energy = 8; float debye_temp_factor = 1.0; float rel_angle = 1.0; float bragg = Bragg_angle (cryst, energy, 1, 1, 1); std::printf (" Bragg angle: Rad: %f Deg: %f\n", bragg, bragg*180/PI); float q = Q_scattering_amplitude (cryst, energy, 1, 1, 1, rel_angle); std::printf (" Q Scattering amplitude: %f\n", q); float f0, fp, fpp; Atomic_Factors (14, energy, q, debye_temp_factor, &f0, &fp, &fpp); std::printf (" Atomic factors (Z = 14) f0, fp, fpp: %f, %f, i*%f\n", f0, fp, fpp); Complex FH, F0; FH = Crystal_F_H_StructureFactor (cryst, energy, 1, 1, 1, debye_temp_factor, rel_angle); std::printf (" FH(1,1,1) structure factor: (%f, %f)\n", FH.re, FH.im); F0 = Crystal_F_H_StructureFactor (cryst, energy, 0, 0, 0, debye_temp_factor, rel_angle); std::printf (" F0=FH(0,0,0) structure factor: (%f, %f)\n", F0.re, F0.im); /* Diamond diffraction parameters */ cryst = Crystal_GetCrystal("Diamond", NULL); std::printf ("\nDiamond 111 at 8 KeV. Incidence at the Bragg angle:\n"); bragg = Bragg_angle (cryst, energy, 1, 1, 1); std::printf (" Bragg angle: Rad: %f Deg: %f\n", bragg, bragg*180/PI); q = Q_scattering_amplitude (cryst, energy, 1, 1, 1, rel_angle); std::printf (" Q Scattering amplitude: %f\n", q); Atomic_Factors (6, energy, q, debye_temp_factor, &f0, &fp, &fpp); std::printf (" Atomic factors (Z = 6) f0, fp, fpp: %f, %f, i*%f\n", f0, fp, fpp); FH = Crystal_F_H_StructureFactor (cryst, energy, 1, 1, 1, debye_temp_factor, rel_angle); std::printf (" FH(1,1,1) structure factor: (%f, %f)\n", FH.re, FH.im); F0 = Crystal_F_H_StructureFactor (cryst, energy, 0, 0, 0, debye_temp_factor, rel_angle); std::printf (" F0=FH(0,0,0) structure factor: (%f, %f)\n", F0.re, F0.im); Complex FHbar = Crystal_F_H_StructureFactor (cryst, energy, -1, -1, -1, debye_temp_factor, rel_angle); float dw = 1e10 * 2 * (R_E / cryst->volume) * (KEV2ANGST * KEV2ANGST/ (energy * energy)) * sqrt(c_abs(c_mul(FH, FHbar))) / PI / sin(2*bragg); std::printf (" Darwin width: %f micro-radians\n", 1e6*dw); /* Alpha Quartz diffraction parameters */ cryst = Crystal_GetCrystal("AlphaQuartz", NULL); std::printf ("\nAlpha Quartz 020 at 8 KeV. Incidence at the Bragg angle:\n"); bragg = Bragg_angle (cryst, energy, 0, 2, 0); std::printf (" Bragg angle: Rad: %f Deg: %f\n", bragg, bragg*180/PI); q = Q_scattering_amplitude (cryst, energy, 0, 2, 0, rel_angle); std::printf (" Q Scattering amplitude: %f\n", q); Atomic_Factors (8, energy, q, debye_temp_factor, &f0, &fp, &fpp); std::printf (" Atomic factors (Z = 8) f0, fp, fpp: %f, %f, i*%f\n", f0, fp, fpp); FH = Crystal_F_H_StructureFactor (cryst, energy, 0, 2, 0, debye_temp_factor, rel_angle); std::printf (" FH(0,2,0) structure factor: (%f, %f)\n", FH.re, FH.im); F0 = Crystal_F_H_StructureFactor (cryst, energy, 0, 0, 0, debye_temp_factor, rel_angle); std::printf (" F0=FH(0,0,0) structure factor: (%f, %f)\n", F0.re, F0.im); /* Muscovite diffraction parameters */ cryst = Crystal_GetCrystal("Muscovite", NULL); std::printf ("\nMuscovite 331 at 8 KeV. Incidence at the Bragg angle:\n"); bragg = Bragg_angle (cryst, energy, 3, 3, 1); std::printf (" Bragg angle: Rad: %f Deg: %f\n", bragg, bragg*180/PI); q = Q_scattering_amplitude (cryst, energy, 3, 3, 1, rel_angle); std::printf (" Q Scattering amplitude: %f\n", q); Atomic_Factors (19, energy, q, debye_temp_factor, &f0, &fp, &fpp); std::printf (" Atomic factors (Z = 19) f0, fp, fpp: %f, %f, i*%f\n", f0, fp, fpp); FH = Crystal_F_H_StructureFactor (cryst, energy, 3, 3, 1, debye_temp_factor, rel_angle); std::printf (" FH(3,3,1) structure factor: (%f, %f)\n", FH.re, FH.im); F0 = Crystal_F_H_StructureFactor (cryst, energy, 0, 0, 0, debye_temp_factor, rel_angle); std::printf (" F0=FH(0,0,0) structure factor: (%f, %f)\n", F0.re, F0.im); std::printf ("\n--------------------------- END OF XRLEXAMPLE6 -------------------------------\n"); return 0; }
Complex Crystal_F_H_StructureFactor_Partial (Crystal_Struct* crystal, float energy, int i_miller, int j_miller, int k_miller, float debye_factor, float rel_angle, int f0_flag, int f_prime_flag, int f_prime2_flag) { float f0, f_prime, f_prime2, q; float f_re[120], f_im[120], H_dot_r; int f_is_computed[120] = {0}; Complex F_H = {0, 0}; char buffer[512]; int i, Z; Crystal_Struct* cc = crystal; /* Just for an abbreviation. */ /* Loop over all atoms and compute the f values */ q = Q_scattering_amplitude(cc, energy, i_miller, j_miller, k_miller, rel_angle); for (i = 0; i < cc->n_atom; i++) { Z = cc->atom[i].Zatom; if (f_is_computed[Z]) continue; Atomic_Factors (Z, energy, q, debye_factor, &f0, &f_prime, &f_prime2); switch (f0_flag) { case 0: f_re[Z] = 0; break; case 1: f_re[Z] = 1; break; case 2: f_re[Z] = f0; break; default: sprintf (buffer, "Bad f0_flag argument in Crystal_F_H_StructureFactor_Partial: %i", f0_flag); ErrorExit(buffer); return F_H; } switch (f_prime_flag) { case 0: break; case 2: f_re[Z] = f_re[Z] + f_prime; break; default: sprintf (buffer, "Bad f_prime_flag argument in Crystal_F_H_StructureFactor_Partial: %i", f_prime_flag); ErrorExit(buffer); return F_H; } switch (f_prime2_flag) { case 0: f_im[Z] = 0; break; case 2: f_im[Z] = f_prime2; break; default: sprintf (buffer, "Bad f_prime2_flag argument in Crystal_F_H_StructureFactor_Partial: %i", f_prime2_flag); ErrorExit(buffer); return F_H;; } f_is_computed[Z] = 1; } /* Now compute F_H */ for (i = 0; i < cc->n_atom; i++) { Z = cc->atom[i].Zatom; H_dot_r = TWOPI * (i_miller * cc->atom[i].x + j_miller * cc->atom[i].y + k_miller * cc->atom[i].z); F_H.re = F_H.re + cc->atom[i].fraction * (f_re[Z] * cos(H_dot_r) - f_im[Z] * sin(H_dot_r)); F_H.im = F_H.im + cc->atom[i].fraction * (f_re[Z] * sin(H_dot_r) + f_im[Z] * cos(H_dot_r)); } return F_H; }
int main() { struct compoundData *cdtest; int i; XRayInit(); SetErrorMessages(0); //if something goes wrong, the test will end with EXIT_FAILURE //SetHardExit(1); std::printf("Example of C++ program using xraylib\n"); std::printf("Density of pure Al: %f g/cm3\n", ElementDensity(13)); std::printf("Ca K-alpha Fluorescence Line Energy: %f\n", LineEnergy(20,KA_LINE)); std::printf("Fe partial photoionization cs of L3 at 6.0 keV: %f\n",CS_Photo_Partial(26,L3_SHELL,6.0)); std::printf("Zr L1 edge energy: %f\n",EdgeEnergy(40,L1_SHELL)); std::printf("Pb Lalpha XRF production cs at 20.0 keV (jump approx): %f\n",CS_FluorLine(82,LA_LINE,20.0)); std::printf("Pb Lalpha XRF production cs at 20.0 keV (Kissel): %f\n",CS_FluorLine_Kissel(82,LA_LINE,20.0)); std::printf("Bi M1N2 radiative rate: %f\n",RadRate(83,M1N2_LINE)); std::printf("U M3O3 Fluorescence Line Energy: %f\n",LineEnergy(92,M3O3_LINE)); //parser test for Ca(HCO3)2 (calcium bicarbonate) if ((cdtest = CompoundParser("Ca(HCO3)2")) == NULL) return 1; std::printf("Ca(HCO3)2 contains %g atoms, %i elements and has a molar mass of %g g/mol\n", cdtest->nAtomsAll, cdtest->nElements, cdtest->molarMass); for (i = 0 ; i < cdtest->nElements ; i++) std::printf("Element %i: %f %% and %g atoms\n", cdtest->Elements[i], cdtest->massFractions[i]*100.0, cdtest->nAtoms[i]); FreeCompoundData(cdtest); //parser test for SiO2 (quartz) if ((cdtest = CompoundParser("SiO2")) == NULL) return 1; std::printf("SiO2 contains %g atoms, %i elements and has a molar mass of %g g/mol\n", cdtest->nAtomsAll, cdtest->nElements, cdtest->molarMass); for (i = 0 ; i < cdtest->nElements ; i++) std::printf("Element %i: %f %% and %g atoms\n", cdtest->Elements[i], cdtest->massFractions[i]*100.0, cdtest->nAtoms[i]); FreeCompoundData(cdtest); std::printf("Ca(HCO3)2 Rayleigh cs at 10.0 keV: %f\n",CS_Rayl_CP("Ca(HCO3)2",10.0f) ); std::printf("CS2 Refractive Index at 10.0 keV : %f - %f i\n",Refractive_Index_Re("CS2",10.0f,1.261f),Refractive_Index_Im("CS2",10.0f,1.261f)); std::printf("C16H14O3 Refractive Index at 1 keV : %f - %f i\n",Refractive_Index_Re("C16H14O3",1.0f,1.2f),Refractive_Index_Im("C16H14O3",1.0f,1.2f)); std::printf("SiO2 Refractive Index at 5 keV : %f - %f i\n",Refractive_Index_Re("SiO2",5.0f,2.65f),Refractive_Index_Im("SiO2",5.0f,2.65f)); std::printf("Compton profile for Fe at pz = 1.1 : %f\n",ComptonProfile(26,1.1f)); std::printf("M5 Compton profile for Fe at pz = 1.1 : %f\n",ComptonProfile_Partial(26,M5_SHELL,1.1f)); std::printf("K atomic level width for Fe: %f\n", AtomicLevelWidth(26,K_SHELL)); std::printf("M1->M5 Coster-Kronig transition probability for Au : %f\n",CosKronTransProb(79,FM15_TRANS)); std::printf("L1->L3 Coster-Kronig transition probability for Fe : %f\n",CosKronTransProb(26,FL13_TRANS)); std::printf("Au Ma1 XRF production cs at 10.0 keV (Kissel): %f\n", CS_FluorLine_Kissel(79,MA1_LINE,10.0f)); std::printf("Au Mb XRF production cs at 10.0 keV (Kissel): %f\n", CS_FluorLine_Kissel(79,MB_LINE,10.0f)); std::printf("Au Mg XRF production cs at 10.0 keV (Kissel): %f\n", CS_FluorLine_Kissel(79,MG_LINE,10.0f)); std::printf("Bi L2-M5M5 Auger non-radiative rate: %f\n",AugerRate(86,L2_M5M5_AUGER)); std::printf("Bi L3 Auger yield: %f\n", AugerYield(86, L3_SHELL)); std::printf("Sr anomalous scattering factor Fi at 10.0 keV: %f\n", Fi(38, 10.0)); std::printf("Sr anomalous scattering factor Fii at 10.0 keV: %f\n", Fii(38, 10.0)); char *symbol = AtomicNumberToSymbol(26); std::printf("Symbol of element 26 is: %s\n",symbol); xrlFree(symbol); std::printf("Number of element Fe is: %i\n",SymbolToAtomicNumber("Fe")); std::printf("Pb Malpha XRF production cs at 20.0 keV with cascade effect: %f\n",CS_FluorLine_Kissel(82,MA1_LINE,20.0)); std::printf("Pb Malpha XRF production cs at 20.0 keV with radiative cascade effect: %f\n",CS_FluorLine_Kissel_Radiative_Cascade(82,MA1_LINE,20.0)); std::printf("Pb Malpha XRF production cs at 20.0 keV with non-radiative cascade effect: %f\n",CS_FluorLine_Kissel_Nonradiative_Cascade(82,MA1_LINE,20.0)); std::printf("Pb Malpha XRF production cs at 20.0 keV without cascade effect: %f\n",CS_FluorLine_Kissel_no_Cascade(82,MA1_LINE,20.0)); std::printf("Al mass energy-absorption cs at 20.0 keV: %f\n", CS_Energy(13, 20.0)); std::printf("Pb mass energy-absorption cs at 40.0 keV: %f\n", CS_Energy(82, 40.0)); std::printf("CdTe mass energy-absorption cs at 40.0 keV: %f\n", CS_Energy_CP("CdTe", 40.0)); /* Si Crystal structure */ Crystal_Struct* cryst = Crystal_GetCrystal("Si", NULL); if (cryst == NULL) return 1; std::printf ("Si unit cell dimensions are %f %f %f\n", cryst->a, cryst->b, cryst->c); std::printf ("Si unit cell angles are %f %f %f\n", cryst->alpha, cryst->beta, cryst->gamma); std::printf ("Si unit cell volume is %f\n", cryst->volume); std::printf ("Si atoms at:\n"); std::printf (" Z fraction X Y Z\n"); Crystal_Atom* atom; for (i = 0; i < cryst->n_atom; i++) { atom = &cryst->atom[i]; std::printf (" %3i %f %f %f %f\n", atom->Zatom, atom->fraction, atom->x, atom->y, atom->z); } /* Si diffraction parameters */ std::printf ("\nSi111 at 8 KeV. Incidence at the Bragg angle:\n"); double energy = 8; double debye_temp_factor = 1.0; double rel_angle = 1.0; double bragg = Bragg_angle (cryst, energy, 1, 1, 1); std::printf (" Bragg angle: Rad: %f Deg: %f\n", bragg, bragg*180/PI); double q = Q_scattering_amplitude (cryst, energy, 1, 1, 1, rel_angle); std::printf (" Q Scattering amplitude: %f\n", q); double f0, fp, fpp; Atomic_Factors (14, energy, q, debye_temp_factor, &f0, &fp, &fpp); std::printf (" Atomic factors (Z = 14) f0, fp, fpp: %f, %f, i*%f\n", f0, fp, fpp); xrlComplex FH, F0; FH = Crystal_F_H_StructureFactor (cryst, energy, 1, 1, 1, debye_temp_factor, rel_angle); std::printf (" FH(1,1,1) structure factor: (%f, %f)\n", FH.re, FH.im); F0 = Crystal_F_H_StructureFactor (cryst, energy, 0, 0, 0, debye_temp_factor, rel_angle); std::printf (" F0=FH(0,0,0) structure factor: (%f, %f)\n", F0.re, F0.im); /* Diamond diffraction parameters */ cryst = Crystal_GetCrystal("Diamond", NULL); std::printf ("\nDiamond 111 at 8 KeV. Incidence at the Bragg angle:\n"); bragg = Bragg_angle (cryst, energy, 1, 1, 1); std::printf (" Bragg angle: Rad: %f Deg: %f\n", bragg, bragg*180/PI); q = Q_scattering_amplitude (cryst, energy, 1, 1, 1, rel_angle); std::printf (" Q Scattering amplitude: %f\n", q); Atomic_Factors (6, energy, q, debye_temp_factor, &f0, &fp, &fpp); std::printf (" Atomic factors (Z = 6) f0, fp, fpp: %f, %f, i*%f\n", f0, fp, fpp); FH = Crystal_F_H_StructureFactor (cryst, energy, 1, 1, 1, debye_temp_factor, rel_angle); std::printf (" FH(1,1,1) structure factor: (%f, %f)\n", FH.re, FH.im); F0 = Crystal_F_H_StructureFactor (cryst, energy, 0, 0, 0, debye_temp_factor, rel_angle); std::printf (" F0=FH(0,0,0) structure factor: (%f, %f)\n", F0.re, F0.im); xrlComplex FHbar = Crystal_F_H_StructureFactor (cryst, energy, -1, -1, -1, debye_temp_factor, rel_angle); double dw = 1e10 * 2 * (R_E / cryst->volume) * (KEV2ANGST * KEV2ANGST/ (energy * energy)) * std::sqrt(c_abs(c_mul(FH, FHbar))) / PI / std::sin(2*bragg); std::printf (" Darwin width: %f micro-radians\n", 1e6*dw); /* Alpha Quartz diffraction parameters */ cryst = Crystal_GetCrystal("AlphaQuartz", NULL); std::printf ("\nAlpha Quartz 020 at 8 KeV. Incidence at the Bragg angle:\n"); bragg = Bragg_angle (cryst, energy, 0, 2, 0); std::printf (" Bragg angle: Rad: %f Deg: %f\n", bragg, bragg*180/PI); q = Q_scattering_amplitude (cryst, energy, 0, 2, 0, rel_angle); std::printf (" Q Scattering amplitude: %f\n", q); Atomic_Factors (8, energy, q, debye_temp_factor, &f0, &fp, &fpp); std::printf (" Atomic factors (Z = 8) f0, fp, fpp: %f, %f, i*%f\n", f0, fp, fpp); FH = Crystal_F_H_StructureFactor (cryst, energy, 0, 2, 0, debye_temp_factor, rel_angle); std::printf (" FH(0,2,0) structure factor: (%f, %f)\n", FH.re, FH.im); F0 = Crystal_F_H_StructureFactor (cryst, energy, 0, 0, 0, debye_temp_factor, rel_angle); std::printf (" F0=FH(0,0,0) structure factor: (%f, %f)\n", F0.re, F0.im); /* Muscovite diffraction parameters */ cryst = Crystal_GetCrystal("Muscovite", NULL); std::printf ("\nMuscovite 331 at 8 KeV. Incidence at the Bragg angle:\n"); bragg = Bragg_angle (cryst, energy, 3, 3, 1); std::printf (" Bragg angle: Rad: %f Deg: %f\n", bragg, bragg*180/PI); q = Q_scattering_amplitude (cryst, energy, 3, 3, 1, rel_angle); std::printf (" Q Scattering amplitude: %f\n", q); Atomic_Factors (19, energy, q, debye_temp_factor, &f0, &fp, &fpp); std::printf (" Atomic factors (Z = 19) f0, fp, fpp: %f, %f, i*%f\n", f0, fp, fpp); FH = Crystal_F_H_StructureFactor (cryst, energy, 3, 3, 1, debye_temp_factor, rel_angle); std::printf (" FH(3,3,1) structure factor: (%f, %f)\n", FH.re, FH.im); F0 = Crystal_F_H_StructureFactor (cryst, energy, 0, 0, 0, debye_temp_factor, rel_angle); std::printf (" F0=FH(0,0,0) structure factor: (%f, %f)\n", F0.re, F0.im); char **crystals; crystals = Crystal_GetCrystalsList(NULL, NULL); std::printf ("List of available crystals:\n"); for (i = 0 ; crystals[i] != NULL ; i++) { std::printf (" Crystal %i: %s\n", i, crystals[i]); xrlFree(crystals[i]); } xrlFree(crystals); std::printf ("\n"); /* compoundDataNIST tests */ struct compoundDataNIST *cdn; cdn = GetCompoundDataNISTByName("Uranium Monocarbide"); std::printf ("Uranium Monocarbide\n"); std::printf (" Name: %s\n", cdn->name); std::printf (" Density: %lf g/cm3\n", cdn->density); for (i = 0 ; i < cdn->nElements ; i++) { std::printf(" Element %i: %lf %%\n",cdn->Elements[i],cdn->massFractions[i]*100.0); } FreeCompoundDataNIST(cdn); cdn = NULL; cdn = GetCompoundDataNISTByIndex(NIST_COMPOUND_BRAIN_ICRP); std::printf ("NIST_COMPOUND_BRAIN_ICRP\n"); std::printf (" Name: %s\n", cdn->name); std::printf (" Density: %lf g/cm3\n", cdn->density); for (i = 0 ; i < cdn->nElements ; i++) { std::printf(" Element %i: %lf %%\n",cdn->Elements[i],cdn->massFractions[i]*100.0); } FreeCompoundDataNIST(cdn); cdn = NULL; char **nistCompounds = GetCompoundDataNISTList(NULL); std::printf ("List of available NIST compounds:\n"); for (i = 0 ; nistCompounds[i] != NULL ; i++) { std::printf (" Compound %i: %s\n", i, nistCompounds[i]); xrlFree(nistCompounds[i]); } xrlFree(nistCompounds); std::printf ("\n"); /* radioNuclideData tests */ struct radioNuclideData *rnd; rnd = GetRadioNuclideDataByName("109Cd"); std::printf ("109Cd\n"); std::printf (" Name: %s\n", rnd->name); std::printf (" Z: %i\n", rnd->Z); std::printf (" A: %i\n", rnd->A); std::printf (" N: %i\n", rnd->N); std::printf (" Z_xray: %i\n", rnd->Z_xray); std::printf (" X-rays:\n"); for (i = 0 ; i < rnd->nXrays ; i++) std::printf (" %f keV -> %f\n", LineEnergy(rnd->Z_xray, rnd->XrayLines[i]), rnd->XrayIntensities[i]); std::printf (" Gamma rays:\n"); for (i = 0 ; i < rnd->nGammas ; i++) std::printf (" %f keV -> %f\n", rnd->GammaEnergies[i], rnd->GammaIntensities[i]); FreeRadioNuclideData(rnd); rnd = GetRadioNuclideDataByIndex(RADIO_NUCLIDE_125I); std::printf ("RADIO_NUCLIDE_125I\n"); std::printf (" Name: %s\n", rnd->name); std::printf (" Z: %i\n", rnd->Z); std::printf (" A: %i\n", rnd->A); std::printf (" N: %i\n", rnd->N); std::printf (" Z_xray: %i\n", rnd->Z_xray); std::printf (" X-rays:\n"); for (i = 0 ; i < rnd->nXrays ; i++) std::printf (" %f keV -> %f\n", LineEnergy(rnd->Z_xray, rnd->XrayLines[i]), rnd->XrayIntensities[i]); std::printf (" Gamma rays:\n"); for (i = 0 ; i < rnd->nGammas ; i++) std::printf (" %f keV -> %f\n", rnd->GammaEnergies[i], rnd->GammaIntensities[i]); FreeRadioNuclideData(rnd); char **radioNuclides; radioNuclides = GetRadioNuclideDataList(NULL); std::printf ("List of available radionuclides:\n"); for (i = 0 ; radioNuclides[i] != NULL ; i++) { std::printf (" Radionuclide %i: %s\n", i, radioNuclides[i]); xrlFree(radioNuclides[i]); } xrlFree(radioNuclides); std::printf ("\n--------------------------- END OF XRLEXAMPLE6 -------------------------------\n"); return 0; }