12 #include "vdt/vdtMath.h" 23 maxIterations_ = 1000;
37 vertexSizeTime_ = conf.
getParameter<
double>(
"vertexSizeTime");
38 coolingFactor_ = conf.
getParameter<
double>(
"coolingFactor");
43 uniquetrkweight_ = conf.
getParameter<
double>(
"uniquetrkweight");
44 uniquetrkminp_ = conf.
getParameter<
double>(
"uniquetrkminp");
48 convergence_mode_ = conf.
getParameter<
int>(
"convergence_mode");
53 std::cout <<
"DAClusterizerInZT_vect: mintrkweight = " << mintrkweight_ << std::endl;
54 std::cout <<
"DAClusterizerInZT_vect: uniquetrkweight = " << uniquetrkweight_ << std::endl;
55 std::cout <<
"DAClusterizerInZT_vect: uniquetrkminp = " << uniquetrkminp_ << std::endl;
56 std::cout <<
"DAClusterizerInZT_vect: zmerge = " << zmerge_ << std::endl;
57 std::cout <<
"DAClusterizerInZT_vect: tmerge = " << tmerge_ << std::endl;
58 std::cout <<
"DAClusterizerInZT_vect: Tmin = " <<
minT << std::endl;
59 std::cout <<
"DAClusterizerInZT_vect: Tpurge = " << purgeT << std::endl;
60 std::cout <<
"DAClusterizerInZT_vect: Tstop = " << stopT << std::endl;
61 std::cout <<
"DAClusterizerInZT_vect: vertexSize = " << vertexSize_ << std::endl;
62 std::cout <<
"DAClusterizerInZT_vect: vertexSizeTime = " << vertexSizeTime_ << std::endl;
63 std::cout <<
"DAClusterizerInZT_vect: coolingFactor = " << coolingFactor_ << std::endl;
64 std::cout <<
"DAClusterizerInZT_vect: d0CutOff = " << d0CutOff_ << std::endl;
65 std::cout <<
"DAClusterizerInZT_vect: dzCutOff = " << dzCutOff_ << std::endl;
66 std::cout <<
"DAClusterizerInZT_vect: dtCutoff = " << dtCutOff_ << std::endl;
67 std::cout <<
"DAClusterizerInZT_vect: zrange = " << sel_zrange_ << std::endl;
68 std::cout <<
"DAClusterizerinZT_vect: convergence mode = " << convergence_mode_ << std::endl;
69 std::cout <<
"DAClusterizerinZT_vect: delta_highT = " << delta_highT_ << std::endl;
70 std::cout <<
"DAClusterizerinZT_vect: delta_lowT = " << delta_lowT_ << std::endl;
71 std::cout <<
"DAClusterizerinZT_vect: DEBUGLEVEL " << DEBUGLEVEL << std::endl;
74 if (convergence_mode_ > 1) {
76 <<
"DAClusterizerInZT_vect: invalid convergence_mode " << convergence_mode_ <<
" reset to default " << 0;
77 convergence_mode_ = 0;
83 <<
"DAClusterizerInZT_vect: invalid Tmin " <<
minT <<
" reset to default " << 1. / betamax_;
88 if ((purgeT >
minT) || (purgeT == 0)) {
90 <<
"DAClusterizerInZT_vect: invalid Tpurge " << purgeT <<
" set to " <<
minT;
93 betapurge_ = 1. / purgeT;
95 if ((stopT > purgeT) || (stopT == 0)) {
97 <<
"DAClusterizerInZT_vect: invalid Tstop " << stopT <<
" set to " <<
max(1., purgeT);
98 stopT =
max(1., purgeT);
100 betastop_ = 1. / stopT;
104 inline double local_exp(
double const& inp) {
return vdt::fast_exp(inp); }
106 inline void local_exp_list_range(
double const* __restrict__ arg_inp,
107 double* __restrict__ arg_out,
110 for (
auto i = kmin;
i != kmax; ++
i)
111 arg_out[
i] = vdt::fast_exp(arg_inp[
i]);
130 assert(
v.zvtx_vec.size() == nv);
131 assert(
v.tvtx_vec.size() == nv);
133 assert(
v.dt2_vec.size() == nv);
134 assert(
v.sumw_vec.size() == nv);
136 assert(
v.rho_vec.size() == nv);
137 assert(
v.swz_vec.size() == nv);
138 assert(
v.swt_vec.size() == nv);
139 assert(
v.exp_arg_vec.size() == nv);
140 assert(
v.exp_vec.size() == nv);
142 assert(
v.nuz_vec.size() == nv);
143 assert(
v.nut_vec.size() == nv);
144 assert(
v.szz_vec.size() == nv);
145 assert(
v.stt_vec.size() == nv);
146 assert(
v.szt_vec.size() == nv);
148 assert(
v.zvtx == &
v.zvtx_vec.front());
149 assert(
v.tvtx == &
v.tvtx_vec.front());
150 assert(
v.rho == &
v.rho_vec.front());
151 assert(
v.exp_arg == &
v.exp_arg_vec.front());
152 assert(
v.swz == &
v.swz_vec.front());
153 assert(
v.swt == &
v.swt_vec.front());
155 assert(
v.nuz == &
v.nuz_vec.front());
156 assert(
v.nut == &
v.nut_vec.front());
157 assert(
v.szz == &
v.szz_vec.front());
158 assert(
v.stt == &
v.stt_vec.front());
159 assert(
v.szt == &
v.szt_vec.front());
161 assert(
v.sumw == &
v.sumw_vec.front());
162 assert(
v.dt2 == &
v.dt2_vec.front());
165 for (
unsigned int k = 0;
k < nv - 1;
k++) {
166 if (
v.zvtx[
k] <=
v.zvtx[
k + 1])
168 cout <<
" ZT, cluster z-ordering assertion failure z[" <<
k <<
"] =" <<
v.zvtx[
k] <<
" z[" <<
k + 1
169 <<
"] =" <<
v.zvtx[
k + 1] << endl;
193 for (
unsigned int i = 0;
i <
nt;
i++) {
196 cout <<
"track vertex range assertion failure" <<
i <<
"/" <<
nt <<
" kmin,kmax=" << tks.
kmin[
i] <<
", " 197 << tks.
kmax[
i] <<
" nv=" << nv << endl;
200 for (
unsigned int i = 0;
i <
nt;
i++) {
211 for (
const auto& tk :
tracks) {
215 double t_z = tk.stateAtBeamLine().trackStateAtPCA().position().z();
216 double t_t = tk.timeExt();
218 if (std::fabs(
t_z) > 1000.)
225 auto const& t_mom = tk.stateAtBeamLine().trackStateAtPCA().momentum();
228 double t_dz2 =
std::pow(tk.track().dzError(), 2)
234 edm::LogWarning(
"DAClusterizerinZT_vect") <<
"rejected track t_dz2 " << t_dz2;
241 if ((tk.dtErrorExt() > 0.3) || (
std::abs(t_t) > t0Max_)) {
246 edm::LogWarning(
"DAClusterizerinZT_vect") <<
"rejected track t_dt2 " << t_dt2;
256 edm::LogWarning(
"DAClusterizerinZT_vect") <<
"rejected track t_tkwt " << t_tkwt;
261 tks.
addItem(
t_z, t_t, t_dz2, t_dt2, &tk, t_tkwt);
266 tks.
osumtkwt = sumtkwt > 0 ? 1. / sumtkwt : 0.;
269 if (DEBUGLEVEL > 0) {
278 inline double Eik(
double t_z,
double k_z,
double t_dz2,
double t_t,
double k_t,
double t_dt2) {
284 const unsigned int nv = gvertices.
getSize();
285 const unsigned int nt = gtracks.
getSize();
288 edm::LogWarning(
"DAClusterizerinZT_vect") <<
"empty cluster list in set_vtx_range";
292 for (
auto itrack = 0
U; itrack <
nt; ++itrack) {
296 unsigned int kmin =
min(nv - 1, gtracks.
kmin[itrack]);
299 while ((kmin > 0) && (gvertices.
zvtx[kmin - 1] >
zmin)) {
303 while ((kmin < (nv - 1)) && (gvertices.
zvtx[kmin] <
zmin)) {
309 unsigned int kmax =
min(nv - 1, gtracks.
kmax[itrack] - 1);
313 while ((kmax < (nv - 1)) && (gvertices.
zvtx[kmax + 1] <
zmax)) {
317 while ((kmax > 0) && (gvertices.
zvtx[kmax] >
zmax)) {
323 gtracks.
kmin[itrack] = kmin;
324 gtracks.
kmax[itrack] = kmax + 1;
327 gtracks.
kmax[itrack] =
min(nv,
max(kmin, kmax) + 1);
331 if (gtracks.
kmin[itrack] >= gtracks.
kmax[itrack]) {
332 cout <<
"set_vtx_range trk = " << itrack <<
" kmin,kmax=" << kmin <<
"," << kmax
333 <<
" gtrack.kmin,kmax = " << gtracks.
kmin[itrack] <<
"," << gtracks.
kmax[itrack] <<
" zrange = " <<
zrange 341 const unsigned int nt = gtracks.
getSize();
342 const unsigned int nv = gvertices.
getSize();
343 for (
auto itrack = 0
U; itrack <
nt; ++itrack) {
344 gtracks.
kmin[itrack] = 0;
345 gtracks.
kmax[itrack] = nv;
350 double beta,
track_t& gtracks,
vertex_t& gvertices,
const double rho0,
const bool updateTc)
const {
355 const unsigned int nt = gtracks.
getSize();
356 const unsigned int nv = gvertices.
getSize();
361 Z_init = rho0 * local_exp(-
beta * dzCutOff_ * dzCutOff_);
366 auto kernel_calc_exp_arg_range = [
beta](
const unsigned int itrack,
369 const unsigned int kmin,
370 const unsigned int kmax) {
371 const auto track_z =
tracks.zpca[itrack];
373 const auto botrack_dz2 = -
beta *
tracks.dz2[itrack];
375 const auto botrack_dt2 = -
beta *
tracks.dt2[itrack];
378 for (
unsigned int ivertex = kmin; ivertex < kmax; ++ivertex) {
379 const auto mult_resz = track_z -
vertices.zvtx[ivertex];
382 const auto botrack_dt2 =
385 vertices.exp_arg[ivertex] = botrack_dz2 * (mult_resz * mult_resz) + botrack_dt2 * (mult_rest * mult_rest);
389 auto kernel_add_Z_range = [Z_init](
390 vertex_t const&
vertices,
const unsigned int kmin,
const unsigned int kmax) ->
double {
391 double ZTemp = Z_init;
392 for (
unsigned int ivertex = kmin; ivertex < kmax; ++ivertex) {
398 auto kernel_calc_normalization_range = [updateTc](
const unsigned int track_num,
401 const unsigned int kmin,
402 const unsigned int kmax) {
403 auto tmp_trk_tkwt =
tracks.tkwt[track_num];
404 auto o_trk_sum_Z = 1. /
tracks.sum_Z[track_num];
405 auto o_trk_err_z =
tracks.dz2[track_num];
406 auto o_trk_err_t =
tracks.dt2[track_num];
407 auto tmp_trk_z =
tracks.zpca[track_num];
408 auto tmp_trk_t =
tracks.tpca[track_num];
412 for (
unsigned int k = kmin;
k < kmax; ++
k) {
416 const auto wz =
w * o_trk_err_z;
417 const auto wt =
w * o_trk_err_t;
426 const auto dsz = (tmp_trk_z -
vertices.zvtx[
k]) * o_trk_err_z;
427 const auto dst = (tmp_trk_t -
vertices.tvtx[
k]) * o_trk_err_t;
434 for (
unsigned int k = kmin;
k < kmax; ++
k) {
437 const auto wz =
w * o_trk_err_z;
438 const auto wt =
w * o_trk_err_t;
450 for (
auto ivertex = 0
U; ivertex < nv; ++ivertex) {
451 gvertices.
se[ivertex] = 0.0;
452 gvertices.
nuz[ivertex] = 0.0;
453 gvertices.
nut[ivertex] = 0.0;
454 gvertices.
swz[ivertex] = 0.0;
455 gvertices.
swt[ivertex] = 0.0;
456 gvertices.
szz[ivertex] = 0.0;
457 gvertices.
stt[ivertex] = 0.0;
458 gvertices.
szt[ivertex] = 0.0;
460 gvertices.sumw[ivertex] = 0.0;
465 for (
auto itrack = 0
U; itrack <
nt; ++itrack) {
466 const unsigned int kmin = gtracks.
kmin[itrack];
467 const unsigned int kmax = gtracks.
kmax[itrack];
470 assert((kmin < kmax) && (kmax <= nv));
474 kernel_calc_exp_arg_range(itrack, gtracks, gvertices, kmin, kmax);
475 local_exp_list_range(gvertices.
exp_arg, gvertices.
exp, kmin, kmax);
476 gtracks.
sum_Z[itrack] = kernel_add_Z_range(gvertices, kmin, kmax);
479 gtracks.
sum_Z[itrack] = 0.0;
481 if (gtracks.
sum_Z[itrack] > 1.e-100) {
482 kernel_calc_normalization_range(itrack, gtracks, gvertices, kmin, kmax);
491 for (
unsigned int ivertex = 0; ivertex < nv; ++ivertex) {
518 edm::LogInfo(
"sumw") <<
"invalid sum of weights in fit: " << endl;
521 <<
" sumw(z,t) =" <<
vertices.nuz[ivertex] <<
"," <<
vertices.nut[ivertex] << endl;
527 for (
unsigned int ivertex = 0; ivertex < nv; ++ivertex) {
534 double delta = kernel_calc_zt(gvertices);
536 if (zorder(gvertices)) {
537 set_vtx_range(
beta, gtracks, gvertices);
545 const unsigned int nv = y.getSize();
548 assert(y.zvtx_vec.size() == nv);
549 assert(y.tvtx_vec.size() == nv);
550 assert(y.rho_vec.size() == nv);
556 bool reordering =
true;
557 bool modified =
false;
561 for (
unsigned int k = 0; (
k + 1) < nv;
k++) {
562 if (y.zvtx[
k + 1] < y.zvtx[
k]) {
563 auto ztemp = y.zvtx[
k];
564 y.zvtx[
k] = y.zvtx[
k + 1];
565 y.zvtx[
k + 1] = ztemp;
566 auto ttemp = y.tvtx[
k];
567 y.tvtx[
k] = y.tvtx[
k + 1];
568 y.tvtx[
k + 1] = ttemp;
570 auto dt2temp = y.dt2[
k];
571 y.dt2[
k] = y.dt2[
k + 1];
572 y.dt2[
k + 1] = dt2temp;
574 auto ptemp = y.rho[
k];
575 y.rho[
k] = y.rho[
k + 1];
576 y.rho[
k + 1] = ptemp;
580 modified |= reordering;
592 double z,
double t,
vertex_t& y,
unsigned int& k_min,
double dz,
double dt)
const {
598 unsigned int nv = y.getSize();
606 for (
unsigned int k0 = 1;
k0 < nv;
k0++) {
612 double delta_min = 1.;
616 while ((k1 > 0) && ((y.zvtx[
k] - y.zvtx[--k1]) <
dz)) {
618 if (
delta < delta_min) {
626 while (((++k1) < nv) && ((y.zvtx[k1] - y.zvtx[
k]) <
dz)) {
628 if (
delta < delta_min) {
634 return (delta_min < 1.);
639 unsigned int niter = 0;
641 double delta_max = delta_lowT_;
643 if (convergence_mode_ == 0) {
644 delta_max = delta_max0;
645 }
else if (convergence_mode_ == 1) {
650 set_vtx_range(
beta, tks,
v);
652 double delta_sum_range = 0;
653 std::vector<double> z0 =
v.zvtx_vec;
655 while (niter++ < maxIterations_) {
657 delta_sum_range +=
delta;
659 if (delta_sum_range > zrange_min_) {
660 for (
unsigned int k = 0;
k <
v.getSize();
k++) {
661 if (
std::abs(
v.zvtx_vec[
k] - z0[
k]) > zrange_min_) {
663 set_vtx_range(
beta, tks,
v);
671 if (
delta < delta_max) {
677 if (DEBUGLEVEL > 0) {
678 std::cout <<
"DAClusterizerInZT_vect.thermalize niter = " << niter <<
" at T = " << 1 /
beta 679 <<
" nv = " <<
v.getSize() << std::endl;
691 const unsigned int nv = y.getSize();
697 unsigned int k1_min = 0, k2_min = 0;
698 double delta_min = 0;
700 for (
unsigned int k1 = 0; (k1 + 1) < nv; k1++) {
701 unsigned int k2 = k1;
702 while ((++k2 < nv) && (std::fabs(y.zvtx[k2] - y.zvtx[k1]) < zmerge_)) {
703 auto delta =
std::pow((y.zvtx[k2] - y.zvtx[k1]) / zmerge_, 2) +
std::pow((y.tvtx[k2] - y.tvtx[k1]) / tmerge_, 2);
704 if ((
delta < delta_min) || (k1_min == k2_min)) {
712 if ((k1_min == k2_min) || (delta_min > 1)) {
716 double rho = y.rho[k1_min] + y.rho[k2_min];
719 assert((k1_min < nv) && (k2_min < nv));
720 if (DEBUGLEVEL > 1) {
721 std::cout <<
"merging (" << setw(8) <<
fixed << setprecision(4) << y.zvtx[k1_min] <<
',' << y.tvtx[k1_min]
722 <<
") and (" << y.zvtx[k2_min] <<
',' << y.tvtx[k2_min] <<
")" 723 <<
" idx=" << k1_min <<
"," << k2_min << std::endl;
728 y.zvtx[k1_min] = (y.rho[k1_min] * y.zvtx[k1_min] + y.rho[k2_min] * y.zvtx[k2_min]) / rho;
729 y.tvtx[k1_min] = (y.rho[k1_min] * y.tvtx[k1_min] + y.rho[k2_min] * y.tvtx[k2_min]) / rho;
731 y.dt2[k1_min] = (y.rho[k1_min] * y.dt2[k1_min] + y.rho[k2_min] * y.dt2[k2_min]) / rho;
734 y.zvtx[k1_min] = 0.5 * (y.zvtx[k1_min] + y.zvtx[k2_min]);
735 y.tvtx[k1_min] = 0.5 * (y.tvtx[k1_min] + y.tvtx[k2_min]);
738 y.removeItem(k2_min, tks);
741 set_vtx_range(
beta, tks, y);
747 constexpr
double eps = 1.e-100;
749 const unsigned int nv = y.getSize();
755 std::vector<double> sump_v(nv), arg_cache_v(nv), exp_cache_v(nv), pcut_cache_v(nv);
756 std::vector<int> nUnique_v(nv);
757 double* __restrict__ parg_cache;
758 double* __restrict__ pexp_cache;
759 double* __restrict__ ppcut_cache;
760 double* __restrict__ psump;
761 int* __restrict__ pnUnique;
762 int constexpr nunique_min_ = 2;
765 set_vtx_range(
beta, tks, y);
767 parg_cache = arg_cache_v.data();
768 pexp_cache = exp_cache_v.data();
769 ppcut_cache = pcut_cache_v.data();
770 psump = sump_v.data();
771 pnUnique = nUnique_v.data();
773 const auto rhoconst = rho0 * local_exp(-
beta * dzCutOff_ * dzCutOff_);
774 for (
unsigned int k = 0;
k < nv; ++
k) {
775 const double pmax = y.rho[
k] / (y.rho[
k] + rhoconst);
776 ppcut_cache[
k] = uniquetrkweight_ * pmax;
779 for (
unsigned int i = 0;
i <
nt;
i++) {
780 const auto invZ = ((tks.
sum_Z[
i] >
eps) && (tks.
tkwt[
i] > uniquetrkminp_)) ? 1. / tks.
sum_Z[
i] : 0.;
781 const auto track_z = tks.
zpca[
i];
783 const auto botrack_dz2 = -
beta * tks.
dz2[
i];
784 const auto botrack_dt2 = -
beta * tks.
dt2[
i];
785 const auto kmin = tks.
kmin[
i];
786 const auto kmax = tks.
kmax[
i];
788 for (
unsigned int k = kmin;
k < kmax;
k++) {
789 const auto mult_resz = track_z - y.zvtx[
k];
790 const auto mult_rest =
track_t - y.tvtx[
k];
791 parg_cache[
k] = botrack_dz2 * (mult_resz * mult_resz) + botrack_dt2 * (mult_rest * mult_rest);
794 local_exp_list_range(parg_cache, pexp_cache, kmin, kmax);
796 for (
unsigned int k = kmin;
k < kmax;
k++) {
797 const double p = y.rho[
k] * pexp_cache[
k] * invZ;
799 pnUnique[
k] += (
p > ppcut_cache[
k]) ? 1 : 0;
804 unsigned int k0 = nv;
805 for (
unsigned k = 0;
k < nv;
k++) {
806 if ((pnUnique[
k] < nunique_min_) && (psump[
k] < sumpmin)) {
815 if (DEBUGLEVEL > 1) {
816 std::cout <<
"eliminating prototype at " << std::setw(10) << std::setprecision(4) << y.zvtx[
k0] <<
"," 817 << y.tvtx[
k0] <<
" with sump=" << sumpmin <<
" rho*nt =" << y.rho[
k0] *
nt << endl;
820 y.removeItem(
k0, tks);
821 set_vtx_range(
beta, tks, y);
832 const unsigned int nv = y.getSize();
834 for (
unsigned int k = 0;
k < nv;
k++) {
840 for (
unsigned int i = 0;
i <
nt;
i++) {
843 sumwz += w_z * tks.
zpca[
i];
844 sumwt += w_t * tks.
tpca[
i];
848 y.zvtx[
k] = sumwz / sumw_z;
849 y.tvtx[
k] = sumwt / sumw_t;
852 double szz = 0, stt = 0, szt = 0;
853 double nuz = 0, nut = 0;
854 for (
unsigned int i = 0;
i <
nt;
i++) {
861 nuz +=
w * tks.
dz2[
i];
862 nut +=
w * tks.
dt2[
i];
864 double Tz = szz / nuz;
869 Tc = Tz + Tt +
sqrt(
pow(Tz - Tt, 2) + 4 * szt * szt / nuz / nut);
879 if (DEBUGLEVEL > 0) {
880 std::cout <<
"DAClusterizerInZT_vect.beta0: Tc = " << T0 << std::endl;
882 std::cout <<
"DAClusterizerInZT_vect.beta0: nstep = " << coolingsteps << std::endl;
886 if (T0 > 1. / betamax) {
888 return betamax *
std::pow(coolingFactor_, coolingsteps);
891 return betamax * coolingFactor_;
896 double Tz = y.szz[
k] / y.nuz[
k];
899 Tt = y.stt[
k] / y.nut[
k];
900 double mx = y.szt[
k] / y.nuz[
k] * y.szt[
k] / y.nut[
k];
901 return Tz + Tt +
sqrt(
pow(Tz - Tt, 2) + 4 * mx);
911 constexpr
double epsilonz = 1
e-3;
912 constexpr
double epsilont = 1
e-2;
913 unsigned int nv = y.getSize();
914 const double twoBeta = 2.0 *
beta;
918 std::vector<std::pair<double, unsigned int> >
critical;
919 for (
unsigned int k = 0;
k < nv;
k++) {
920 double Tc = get_Tc(y,
k);
928 std::stable_sort(
critical.begin(),
critical.end(), std::greater<std::pair<double, unsigned int> >());
933 for (
unsigned int ic = 0; ic <
critical.size(); ic++) {
938 double Mzz = y.nuz[
k] - twoBeta * y.szz[
k];
939 double Mtt = y.nut[
k] - twoBeta * y.stt[
k];
940 double Mzt = -twoBeta * y.szt[
k];
941 const double twoMzt = 2.0 * Mzt;
942 double D =
sqrt(
pow(Mtt - Mzz, 2) + twoMzt * twoMzt);
943 double q1 = atan2(-Mtt + Mzz +
D, -twoMzt);
944 double l1 = 0.5 * (-Mzz - Mtt +
D);
945 double l2 = 0.5 * (-Mzz - Mtt -
D);
947 edm::LogWarning(
"DAClusterizerInZT_vect") <<
"warning, bad eigenvalues! idx=" <<
k <<
" z= " << y.zvtx[
k]
948 <<
" Mzz=" << Mzz <<
" Mtt=" << Mtt <<
" Mzt=" << Mzt << endl;
952 double cq =
cos(qsplit);
953 double sq =
sin(qsplit);
960 double p1 = 0, z1 = 0,
t1 = 0, wz1 = 0, wt1 = 0;
961 double p2 = 0,
z2 = 0,
t2 = 0, wz2 = 0, wt2 = 0;
962 for (
unsigned int i = 0;
i <
nt; ++
i) {
963 if (tks.
sum_Z[
i] > 1.e-100) {
964 double lr = (tks.
zpca[
i] - y.zvtx[
k]) * cq + (tks.
tpca[
i] - y.tvtx[
k]) * sq;
966 double tl = lr < 0 ? 1. : 0.;
972 double t = local_exp(-
arg);
977 double p = y.rho[
k] * tks.
tkwt[
i] *
980 double wz =
p * tks.
dz2[
i];
981 double wt =
p * tks.
dt2[
i];
983 z1 += wz * tl * tks.
zpca[
i];
998 z1 = y.zvtx[
k] - epsilonz * cq;
999 edm::LogWarning(
"DAClusterizerInZT_vect") <<
"warning, wz1 = " << scientific << wz1 << endl;
1004 t1 = y.tvtx[
k] - epsilont * sq;
1005 edm::LogWarning(
"DAClusterizerInZT_vect") <<
"warning, wt1 = " << scientific << wt1 << endl;
1010 z2 = y.zvtx[
k] + epsilonz * cq;
1011 edm::LogWarning(
"DAClusterizerInZT_vect") <<
"warning, wz2 = " << scientific << wz2 << endl;
1016 t2 = y.tvtx[
k] + epsilont * sq;
1017 edm::LogWarning(
"DAClusterizerInZT_vect") <<
"warning, wt2 = " << scientific << wt2 << endl;
1020 unsigned int k_min1 =
k, k_min2 =
k;
1021 constexpr
double spliteps = 1
e-8;
1022 while (((find_nearest(z1,
t1, y, k_min1, epsilonz, epsilont) && (k_min1 !=
k)) ||
1023 (find_nearest(
z2,
t2, y, k_min2, epsilonz, epsilont) && (k_min2 !=
k))) &&
1025 z1 = 0.5 * (z1 + y.zvtx[
k]);
1026 t1 = 0.5 * (
t1 + y.tvtx[
k]);
1027 z2 = 0.5 * (
z2 + y.zvtx[
k]);
1028 t2 = 0.5 * (
t2 + y.tvtx[
k]);
1033 if (DEBUGLEVEL > 1) {
1034 if (std::fabs(y.zvtx[
k] - zdumpcenter_) < zdumpwidth_) {
1035 std::cout <<
" T= " << std::setw(10) << std::setprecision(1) << 1. /
beta <<
" Tc= " <<
critical[ic].first
1036 <<
" direction =" << std::setprecision(4) << qsplit <<
" splitting (" << std::setw(8) <<
std::fixed 1037 << std::setprecision(4) << y.zvtx[
k] <<
"," << y.tvtx[
k] <<
")" 1038 <<
" --> (" << z1 <<
',' <<
t1 <<
"),(" <<
z2 <<
',' <<
t2 <<
") [" <<
p1 <<
"," <<
p2 <<
"]";
1039 if (std::fabs(
z2 - z1) > epsilonz || std::fabs(
t2 -
t1) > epsilont) {
1049 edm::LogInfo(
"DAClusterizerInZT") <<
"warning swapping z in split qsplit=" << qsplit <<
" cq=" << cq
1050 <<
" sq=" << sq << endl;
1063 if (std::fabs(
z2 - z1) > epsilonz || std::fabs(
t2 -
t1) > epsilont) {
1065 double rho1 =
p1 * y.rho[
k] / (
p1 +
p2);
1066 double rho2 =
p2 * y.rho[
k] / (
p1 +
p2);
1069 y.removeItem(
k, tks);
1070 unsigned int k2 = y.insertOrdered(
z2,
t2, rho2, tks);
1074 std::cout <<
"unexpected z-ordering in split" << std::endl;
1080 for (
unsigned int jc = ic; jc <
critical.size(); jc++) {
1091 unsigned int k1 = y.insertOrdered(z1,
t1, rho1, tks);
1095 for (
unsigned int jc = ic; jc <
critical.size(); jc++) {
1102 std::cout <<
"warning ! split rejected, too small." << endl;
1124 y.addItem(0, 0, 1.0);
1125 clear_vtx_range(tks, y);
1128 double beta = beta0(betamax_, tks, y);
1134 thermalize(
beta, tks, y, delta_highT_, 0.);
1138 double betafreeze = betamax_ *
sqrt(coolingFactor_);
1140 while (
beta < betafreeze) {
1144 set_vtx_range(
beta, tks, y);
1150 thermalize(
beta, tks, y, delta_highT_, 0.);
1156 if (DEBUGLEVEL > 0) {
1157 std::cout <<
"DAClusterizerInZT_vect::vertices :" 1158 <<
"merging at T=" << 1 /
beta << std::endl;
1163 set_vtx_range(
beta, tks, y);
1169 set_vtx_range(
beta, tks, y);
1175 if (DEBUGLEVEL > 0) {
1176 std::cout <<
"DAClusterizerInZT_vect::vertices :" 1177 <<
"splitting/merging at T=" << 1 /
beta << std::endl;
1181 unsigned int ntry = 0;
1184 thermalize(
beta, tks, y, delta_highT_, 0.);
1188 set_vtx_range(
beta, tks, y);
1202 if (DEBUGLEVEL > 0) {
1203 std::cout <<
"DAClusterizerInZT_vect::vertices :" 1204 <<
"turning on outlier rejection at T=" << 1 /
beta << std::endl;
1209 if (dzCutOff_ > 0) {
1211 for (
unsigned int a = 0;
a < 5;
a++) {
1216 thermalize(
beta, tks, y, delta_lowT_, rho0);
1220 if (DEBUGLEVEL > 0) {
1221 std::cout <<
"DAClusterizerInZT_vect::vertices :" 1222 <<
"merging with outlier rejection at T=" << 1 /
beta << std::endl;
1231 set_vtx_range(
beta, tks, y);
1236 if (DEBUGLEVEL > 0) {
1237 std::cout <<
"DAClusterizerInZT_vect::vertices :" 1238 <<
"after merging with outlier rejection at T=" << 1 /
beta << std::endl;
1245 while (
beta < betapurge_) {
1247 thermalize(
beta, tks, y, delta_lowT_, rho0);
1252 if (DEBUGLEVEL > 0) {
1253 std::cout <<
"DAClusterizerInZT_vect::vertices :" 1254 <<
"purging at T=" << 1 /
beta << std::endl;
1259 while (purge(y, tks, rho0,
beta)) {
1260 thermalize(
beta, tks, y, delta_lowT_, rho0);
1262 set_vtx_range(
beta, tks, y);
1268 if (DEBUGLEVEL > 0) {
1269 std::cout <<
"DAClusterizerInZT_vect::vertices :" 1270 <<
"last cooling T=" << 1 /
beta << std::endl;
1275 while (
beta < betastop_) {
1277 thermalize(
beta, tks, y, delta_lowT_, rho0);
1279 set_vtx_range(
beta, tks, y);
1285 if (DEBUGLEVEL > 0) {
1286 std::cout <<
"DAClusterizerInZT_vect::vertices :" 1287 <<
"stop cooling at T=" << 1 /
beta << std::endl;
1295 double betadummy = 1;
1296 while (
merge(y, tks, betadummy))
1301 set_vtx_range(
beta, tks, y);
1302 const unsigned int nv = y.getSize();
1303 for (
unsigned int k = 0;
k < nv;
k++)
1309 const auto z_sum_init = rho0 * local_exp(-
beta * dzCutOff_ * dzCutOff_);
1310 std::vector<std::vector<unsigned int> > vtx_track_indices(nv);
1311 for (
unsigned int i = 0;
i <
nt;
i++) {
1312 const auto kmin = tks.
kmin[
i];
1313 const auto kmax = tks.
kmax[
i];
1314 for (
auto k = kmin;
k < kmax;
k++) {
1318 local_exp_list_range(y.exp_arg, y.exp, kmin, kmax);
1320 tks.
sum_Z[
i] = z_sum_init;
1321 for (
auto k = kmin;
k < kmax;
k++) {
1322 tks.
sum_Z[
i] += y.rho[
k] * y.exp[
k];
1324 const double invZ = tks.
sum_Z[
i] > 1
e-100 ? 1. / tks.
sum_Z[
i] : 0.0;
1326 for (
auto k = kmin;
k < kmax;
k++) {
1327 double p = y.rho[
k] * y.exp[
k] * invZ;
1328 if (
p > mintrkweight_) {
1330 vtx_track_indices[
k].push_back(
i);
1337 GlobalError dummyError(0.01, 0, 0.01, 0., 0., 0.01);
1338 for (
unsigned int k = 0;
k < nv;
k++) {
1339 if (!vtx_track_indices[
k].
empty()) {
1341 vector<reco::TransientTrack> vertexTracks;
1342 for (
auto i : vtx_track_indices[
k]) {
1343 vertexTracks.push_back(*(tks.
tt[
i]));
1354 const vector<reco::TransientTrack>&
tracks)
const {
1355 vector<vector<reco::TransientTrack> >
clusters;
1359 if (DEBUGLEVEL > 0) {
1360 std::cout <<
"###################################################" << endl;
1361 std::cout <<
"# vectorized DAClusterizerInZT_vect::clusterize nt=" <<
tracks.size() << endl;
1362 std::cout <<
"# DAClusterizerInZT_vect::clusterize pv.size=" <<
pv.size() << endl;
1363 std::cout <<
"###################################################" << endl;
1372 for (
auto k =
pv.begin();
k !=
pv.end();
k++) {
1373 vector<reco::TransientTrack> aCluster =
k->originalTracks();
1374 if (aCluster.size() > 1) {
1384 const unsigned int nv = y.getSize();
1387 std::vector<unsigned int> iz;
1388 for (
unsigned int j = 0;
j <
nt;
j++) {
1391 std::sort(iz.begin(), iz.end(), [tks](
unsigned int a,
unsigned int b) {
return tks.
zpca[
a] < tks.
zpca[
b]; });
1393 std::cout <<
"-----DAClusterizerInZT::dump ----" << nv <<
" clusters " << std::endl;
1396 for (
unsigned int ivertex = 0; ivertex < nv; ++ivertex) {
1397 if (std::fabs(y.zvtx[ivertex] - zdumpcenter_) < zdumpwidth_) {
1405 for (
unsigned int ivertex = 0; ivertex < nv; ++ivertex) {
1406 if (std::fabs(y.zvtx[ivertex] - zdumpcenter_) < zdumpwidth_) {
1414 for (
unsigned int ivertex = 0; ivertex < nv; ++ivertex) {
1415 if (std::fabs(y.zvtx[ivertex] - zdumpcenter_) < zdumpwidth_) {
1421 std::cout <<
"T=" << setw(15) << 1. /
beta <<
" Tmin =" << setw(10) << 1. / betamax_
1423 for (
unsigned int ivertex = 0; ivertex < nv; ++ivertex) {
1424 if (std::fabs(y.zvtx[ivertex] - zdumpcenter_) < zdumpwidth_) {
1425 double Tc = get_Tc(y, ivertex);
1433 for (
unsigned int ivertex = 0; ivertex < nv; ++ivertex) {
1434 sumrho += y.rho[ivertex];
1435 if (std::fabs(y.zvtx[ivertex] - zdumpcenter_) > zdumpwidth_)
1437 std::cout << setw(8) << setprecision(4) <<
fixed << y.rho[ivertex];
1442 for (
unsigned int ivertex = 0; ivertex < nv; ++ivertex) {
1443 sumrho += y.rho[ivertex];
1444 if (std::fabs(y.zvtx[ivertex] - zdumpcenter_) > zdumpwidth_)
1451 double E = 0,
F = 0;
1453 std::cout <<
"---- z +/- dz t +/- dt ip +/-dip pt phi eta weights ----" 1456 for (
unsigned int i0 = 0; i0 <
nt; i0++) {
1457 unsigned int i = iz[i0];
1461 double tz = tks.
zpca[
i];
1463 if (std::fabs(tz - zdumpcenter_) > zdumpwidth_)
1465 std::cout << setw(4) <<
i <<
")" << setw(8) <<
fixed << setprecision(4) << tz <<
" +/-" << setw(6)
1468 if (tks.
dt2[
i] > 0) {
1488 .pixelBarrelLayersWithMeasurement();
1489 std::cout << setw(1) << tks.
tt[
i]->track().hitPattern().pixelEndcapLayersWithMeasurement();
1491 << tks.
tt[
i]->track().hitPattern().trackerLayersWithMeasurement() -
1492 tks.
tt[
i]->track().hitPattern().pixelLayersWithMeasurement()
1498 std::cout << setw(8) <<
IP.value() <<
"+/-" << setw(6) <<
IP.error();
1499 std::cout <<
" " << setw(6) << setprecision(2) << tks.
tt[
i]->track().pt() * tks.
tt[
i]->track().charge();
1500 std::cout <<
" " << setw(5) << setprecision(2) << tks.
tt[
i]->track().phi() <<
" " << setw(5) << setprecision(2)
1501 << tks.
tt[
i]->track().eta();
1504 for (
unsigned int ivertex = 0; ivertex < nv; ++ivertex) {
1505 if (std::fabs(y.zvtx[ivertex] - zdumpcenter_) > zdumpwidth_)
1512 Eik(tks.
zpca[
i], y.zvtx[ivertex], tks.
dz2[
i], tks.
tpca[
i], y.tvtx[ivertex], tks.
dt2[
i])) /
1515 if ((ivertex >= tks.
kmin[
i]) && (ivertex < tks.
kmax[
i])) {
1517 std::cout << setw(8) << setprecision(3) <<
p;
1521 E +=
p * Eik(tks.
zpca[
i], y.zvtx[ivertex], tks.
dz2[
i], tks.
tpca[
i], y.tvtx[ivertex], tks.
dt2[
i]);
1526 }
else if (
p > 0.0001) {
1527 std::cout <<
"X" << setw(6) << setprecision(3) <<
p <<
"X";
1536 std::cout <<
" ( " << std::setw(3) << tks.
kmin[
i] <<
"," << std::setw(3) << tks.
kmax[
i] - 1 <<
" ) ";
1540 for (
unsigned int ivertex = 0; ivertex < nv; ++ivertex) {
1541 if (std::fabs(y.zvtx[ivertex] - zdumpcenter_) < zdumpwidth_) {
1542 std::cout <<
" " << setw(3) << ivertex <<
" ";
1548 for (
unsigned int ivertex = 0; ivertex < nv; ++ivertex) {
1549 if (std::fabs(y.zvtx[ivertex] - zdumpcenter_) < zdumpwidth_) {
1555 <<
"T=" << 1 /
beta <<
" E=" << E <<
" n=" << y.getSize() <<
" F= " <<
F << endl
1556 <<
"----------" << endl;
1563 desc.add<
double>(
"tmerge", 0.01);
1564 desc.add<
double>(
"dtCutOff", 4.);
1565 desc.add<
double>(
"t0Max", 1.0);
1566 desc.add<
double>(
"vertexSizeTime", 0.008);
T getParameter(std::string const &) const
double *__restrict__ tpca
std::vector< double > dt2_vec
constexpr bool isNotFinite(T x)
for(int i=first, nt=offsets[nh];i< nt;i+=gridDim.x *blockDim.x)
std::vector< unsigned int > kmin
double *__restrict__ exp_arg
std::vector< TransientVertex > vertices(const std::vector< reco::TransientTrack > &tracks) const
Sin< T >::type sin(const T &t)
static void fillPSetDescription(edm::ParameterSetDescription &desc)
double get_Tc(const vertex_t &y, int k) const
DAClusterizerInZT_vect(const edm::ParameterSet &conf)
std::vector< double > tkwt_vec
bool purge(vertex_t &, track_t &, double &, const double) const
void addItem(double new_zpca, double new_tpca, double new_dz2, double new_dt2, const reco::TransientTrack *new_tt, double new_tkwt)
T getUntrackedParameter(std::string const &, T const &) const
std::vector< unsigned int > kmax
U second(std::pair< T, U > const &p)
double *__restrict__ zpca
double update(double beta, track_t >racks, vertex_t &gvertices, const double rho0=0, const bool updateTc=false) const
bool split(const double beta, track_t &t, vertex_t &y, double threshold=1.) const
double beta0(const double betamax, track_t const &tks, vertex_t const &y) const
void set_vtx_range(double beta, track_t >racks, vertex_t &gvertices) const
int merge(int argc, char *argv[])
double *__restrict__ tkwt
Cos< T >::type cos(const T &t)
Abs< T >::type abs(const T &t)
bool zorder(vertex_t &y) const
bool merge(vertex_t &, track_t &, double &beta) const
std::vector< double > sum_Z_vec
double *__restrict__ zvtx
track_t fill(const std::vector< reco::TransientTrack > &tracks) const
void verify(const vertex_t &v, const track_t &tks, unsigned int nv=999999, unsigned int nt=999999) const
def split(sequence, size)
std::vector< double > zpca_vec
Log< level::Info, false > LogInfo
auto const & tracks
cannot be loose
DecomposeProduct< arg, typename Div::arg > D
std::vector< double > tpca_vec
static void fillPSetDescription(edm::ParameterSetDescription &desc)
double *__restrict__ sum_Z
void dump(const double beta, const vertex_t &y, const track_t &tks, const int verbosity=0) const
std::vector< const reco::TransientTrack * > tt
std::vector< std::vector< reco::TransientTrack > > clusterize(const std::vector< reco::TransientTrack > &tracks) const override
std::vector< double > dz2_vec
unsigned int thermalize(double beta, track_t >racks, vertex_t &gvertices, const double delta_max, const double rho0=0.) const
Log< level::Warning, false > LogWarning
static uInt32 F(BLOWFISH_CTX *ctx, uInt32 x)
bool find_nearest(double z, double t, vertex_t &y, unsigned int &k_min, double dz, double dt) const
The Signals That Services Can Subscribe To This is based on ActivityRegistry h
Helper function to determine trigger accepts.
unsigned int getSize() const
void clear_vtx_range(track_t >racks, vertex_t &gvertices) const
Power< A, B >::type pow(const A &a, const B &b)
unsigned int getSize() const