//STARTHEADER
// $Id: ClusterSequence_TiledN2.cc 1332 2013-11-20 20:52:59Z pavel $
//
// Copyright (c) 2005-2011, Matteo Cacciari, Gavin P. Salam and Gregory Soyez
//
//----------------------------------------------------------------------
// This file is part of FastJet.
//
// FastJet is free software; you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation; either version 2 of the License, or
// (at your option) any later version.
//
// The algorithms that underlie FastJet have required considerable
// development and are described in hep-ph/0512210. If you use
// FastJet as part of work towards a scientific publication, please
// include a citation to the FastJet paper.
//
// FastJet is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
//
// You should have received a copy of the GNU General Public License
// along with FastJet. If not, see .
//----------------------------------------------------------------------
//ENDHEADER
// The plain N^2 part of the ClusterSequence class -- separated out
// from the rest of the class implementation so as to speed up
// compilation of this particular part while it is under test.
#include
#include
#include
#include
#include "fastjet/PseudoJet.hh"
#include "fastjet/ClusterSequence.hh"
#include "fastjet/internal/MinHeap.hh"
FASTJET_BEGIN_NAMESPACE // defined in fastjet/internal/base.hh
using namespace std;
//----------------------------------------------------------------------
void ClusterSequence::_bj_remove_from_tiles(TiledJet * const jet) {
Tile * tile = & _tiles[jet->tile_index];
if (jet->previous == NULL) {
// we are at head of the tile, so reset it.
// If this was the only jet on the tile then tile->head will now be NULL
tile->head = jet->next;
} else {
// adjust link from previous jet in this tile
jet->previous->next = jet->next;
}
if (jet->next != NULL) {
// adjust backwards-link from next jet in this tile
jet->next->previous = jet->previous;
}
}
//----------------------------------------------------------------------
/// Set up the tiles:
/// - decide the range in eta
/// - allocate the tiles
/// - set up the cross-referencing info between tiles
///
/// The neighbourhood of a tile is set up as follows
///
/// LRR
/// LXR
/// LLR
///
/// such that tiles is an array containing XLLLLRRRR with pointers
/// | \ RH_tiles
/// \ surrounding_tiles
///
/// with appropriate precautions when close to the edge of the tiled
/// region.
///
void ClusterSequence::_initialise_tiles() {
// first decide tile sizes (with a lower bound to avoid huge memory use with
// very small R)
double default_size = max(0.1,_Rparam);
_tile_size_eta = default_size;
// it makes no sense to go below 3 tiles in phi -- 3 tiles is
// sufficient to make sure all pair-wise combinations up to pi in
// phi are possible
_n_tiles_phi = max(3,int(floor(twopi/default_size)));
_tile_size_phi = twopi / _n_tiles_phi; // >= _Rparam and fits in 2pi
// always include zero rapidity in the tiling region
_tiles_eta_min = 0.0;
_tiles_eta_max = 0.0;
// but go no further than following
const double maxrap = 7.0;
// and find out how much further one should go
for(unsigned int i = 0; i < _jets.size(); i++) {
double eta = _jets[i].rap();
// first check if eta is in range -- to avoid taking into account
// very spurious rapidities due to particles with near-zero kt.
if (abs(eta) < maxrap) {
if (eta < _tiles_eta_min) {_tiles_eta_min = eta;}
if (eta > _tiles_eta_max) {_tiles_eta_max = eta;}
}
}
// now adjust the values
_tiles_ieta_min = int(floor(_tiles_eta_min/_tile_size_eta));
_tiles_ieta_max = int(floor( _tiles_eta_max/_tile_size_eta));
_tiles_eta_min = _tiles_ieta_min * _tile_size_eta;
_tiles_eta_max = _tiles_ieta_max * _tile_size_eta;
// allocate the tiles
_tiles.resize((_tiles_ieta_max-_tiles_ieta_min+1)*_n_tiles_phi);
// now set up the cross-referencing between tiles
for (int ieta = _tiles_ieta_min; ieta <= _tiles_ieta_max; ieta++) {
for (int iphi = 0; iphi < _n_tiles_phi; iphi++) {
Tile * tile = & _tiles[_tile_index(ieta,iphi)];
// no jets in this tile yet
tile->head = NULL; // first element of tiles points to itself
tile->begin_tiles[0] = tile;
Tile ** pptile = & (tile->begin_tiles[0]);
pptile++;
//
// set up L's in column to the left of X
tile->surrounding_tiles = pptile;
if (ieta > _tiles_ieta_min) {
// with the itile subroutine, we can safely run tiles from
// idphi=-1 to idphi=+1, because it takes care of
// negative and positive boundaries
for (int idphi = -1; idphi <=+1; idphi++) {
*pptile = & _tiles[_tile_index(ieta-1,iphi+idphi)];
pptile++;
}
}
// now set up last L (below X)
*pptile = & _tiles[_tile_index(ieta,iphi-1)];
pptile++;
// set up first R (above X)
tile->RH_tiles = pptile;
*pptile = & _tiles[_tile_index(ieta,iphi+1)];
pptile++;
// set up remaining R's, to the right of X
if (ieta < _tiles_ieta_max) {
for (int idphi = -1; idphi <= +1; idphi++) {
*pptile = & _tiles[_tile_index(ieta+1,iphi+idphi)];
pptile++;
}
}
// now put semaphore for end tile
tile->end_tiles = pptile;
// finally make sure tiles are untagged
tile->tagged = false;
}
}
}
//----------------------------------------------------------------------
/// return the tile index corresponding to the given eta,phi point
int ClusterSequence::_tile_index(const double & eta, const double & phi) const {
int ieta, iphi;
if (eta <= _tiles_eta_min) {ieta = 0;}
else if (eta >= _tiles_eta_max) {ieta = _tiles_ieta_max-_tiles_ieta_min;}
else {
//ieta = int(floor((eta - _tiles_eta_min) / _tile_size_eta));
ieta = int(((eta - _tiles_eta_min) / _tile_size_eta));
// following needed in case of rare but nasty rounding errors
if (ieta > _tiles_ieta_max-_tiles_ieta_min) {
ieta = _tiles_ieta_max-_tiles_ieta_min;}
}
// allow for some extent of being beyond range in calculation of phi
// as well
//iphi = (int(floor(phi/_tile_size_phi)) + _n_tiles_phi) % _n_tiles_phi;
// with just int and no floor, things run faster but beware
iphi = int((phi+twopi)/_tile_size_phi) % _n_tiles_phi;
return (iphi + ieta * _n_tiles_phi);
}
//----------------------------------------------------------------------
// overloaded version which additionally sets up information regarding the
// tiling
inline void ClusterSequence::_tj_set_jetinfo( TiledJet * const jet,
const int _jets_index) {
// first call the generic setup
_bj_set_jetinfo<>(jet, _jets_index);
// Then do the setup specific to the tiled case.
// Find out which tile it belonds to
jet->tile_index = _tile_index(jet->eta, jet->phi);
// Insert it into the tile's linked list of jets
Tile * tile = &_tiles[jet->tile_index];
jet->previous = NULL;
jet->next = tile->head;
if (jet->next != NULL) {jet->next->previous = jet;}
tile->head = jet;
}
//----------------------------------------------------------------------
/// output the contents of the tiles
void ClusterSequence::_print_tiles(TiledJet * briefjets ) const {
for (vector::const_iterator tile = _tiles.begin();
tile < _tiles.end(); tile++) {
cout << "Tile " << tile - _tiles.begin()<<" = ";
vector list;
for (TiledJet * jetI = tile->head; jetI != NULL; jetI = jetI->next) {
list.push_back(jetI-briefjets);
//cout <<" "< & tile_union, int & n_near_tiles) const {
for (Tile * const * near_tile = _tiles[tile_index].begin_tiles;
near_tile != _tiles[tile_index].end_tiles; near_tile++){
// get the tile number
tile_union[n_near_tiles] = *near_tile - & _tiles[0];
n_near_tiles++;
}
}
//----------------------------------------------------------------------
/// Like _add_neighbours_to_tile_union, but only adds neighbours if
/// their "tagged" status is false; when a neighbour is added its
/// tagged status is set to true.
inline void ClusterSequence::_add_untagged_neighbours_to_tile_union(
const int tile_index,
vector & tile_union, int & n_near_tiles) {
for (Tile ** near_tile = _tiles[tile_index].begin_tiles;
near_tile != _tiles[tile_index].end_tiles; near_tile++){
if (! (*near_tile)->tagged) {
(*near_tile)->tagged = true;
// get the tile number
tile_union[n_near_tiles] = *near_tile - & _tiles[0];
n_near_tiles++;
}
}
}
//----------------------------------------------------------------------
/// run a tiled clustering
void ClusterSequence::_tiled_N2_cluster() {
_initialise_tiles();
int n = _jets.size();
TiledJet * briefjets = new TiledJet[n];
TiledJet * jetA = briefjets, * jetB;
TiledJet oldB;
oldB.tile_index=0; // prevents a gcc warning
// will be used quite deep inside loops, but declare it here so that
// memory (de)allocation gets done only once
vector tile_union(3*n_tile_neighbours);
// initialise the basic jet info
for (int i = 0; i< n; i++) {
_tj_set_jetinfo(jetA, i);
//cout << i<<": "<tile_index<<"\n";
jetA++; // move on to next entry of briefjets
}
TiledJet * tail = jetA; // a semaphore for the end of briefjets
TiledJet * head = briefjets; // a nicer way of naming start
// set up the initial nearest neighbour information
vector::const_iterator tile;
for (tile = _tiles.begin(); tile != _tiles.end(); tile++) {
// first do it on this tile
for (jetA = tile->head; jetA != NULL; jetA = jetA->next) {
for (jetB = tile->head; jetB != jetA; jetB = jetB->next) {
double dist = _bj_dist(jetA,jetB);
if (dist < jetA->NN_dist) {jetA->NN_dist = dist; jetA->NN = jetB;}
if (dist < jetB->NN_dist) {jetB->NN_dist = dist; jetB->NN = jetA;}
}
}
// then do it for RH tiles
for (Tile ** RTile = tile->RH_tiles; RTile != tile->end_tiles; RTile++) {
for (jetA = tile->head; jetA != NULL; jetA = jetA->next) {
for (jetB = (*RTile)->head; jetB != NULL; jetB = jetB->next) {
double dist = _bj_dist(jetA,jetB);
if (dist < jetA->NN_dist) {jetA->NN_dist = dist; jetA->NN = jetB;}
if (dist < jetB->NN_dist) {jetB->NN_dist = dist; jetB->NN = jetA;}
}
}
}
}
// now create the diJ (where J is i's NN) table -- remember that
// we differ from standard normalisation here by a factor of R2
double * diJ = new double[n];
jetA = head;
for (int i = 0; i < n; i++) {
diJ[i] = _bj_diJ(jetA);
jetA++; // have jetA follow i
}
// now run the recombination loop
int history_location = n-1;
while (tail != head) {
// find the minimum of the diJ on this round
double diJ_min = diJ[0];
int diJ_min_jet = 0;
for (int i = 1; i < n; i++) {
if (diJ[i] < diJ_min) {diJ_min_jet = i; diJ_min = diJ[i];}
}
// do the recombination between A and B
history_location++;
jetA = & briefjets[diJ_min_jet];
jetB = jetA->NN;
// put the normalisation back in
diJ_min *= _invR2;
//if (n == 19) {cout << "Hello "<_jets_index, jetB->_jets_index, diJ_min, nn);
//OBS// get the two history indices
//OBSint hist_a = _jets[jetA->_jets_index].cluster_hist_index();
//OBSint hist_b = _jets[jetB->_jets_index].cluster_hist_index();
//OBS// create the recombined jet
//OBS_jets.push_back(_jets[jetA->_jets_index] + _jets[jetB->_jets_index]);
//OBSint nn = _jets.size() - 1;
//OBS_jets[nn].set_cluster_hist_index(history_location);
//OBS// update history
//OBS//cout <_jets_index, diJ_min);
//OBS// get the hist_index
//OBSint hist_a = _jets[jetA->_jets_index].cluster_hist_index();
//OBS//cout <tile_index, tile_union, n_near_tiles);
if (jetB != NULL) {
bool sort_it = false;
if (jetB->tile_index != jetA->tile_index) {
sort_it = true;
_add_neighbours_to_tile_union(jetB->tile_index,tile_union,n_near_tiles);
}
if (oldB.tile_index != jetA->tile_index &&
oldB.tile_index != jetB->tile_index) {
sort_it = true;
_add_neighbours_to_tile_union(oldB.tile_index,tile_union,n_near_tiles);
}
if (sort_it) {
// sort the tiles before then compressing the list
sort(tile_union.begin(), tile_union.begin()+n_near_tiles);
// and now condense the list
int nnn = 1;
for (int i = 1; i < n_near_tiles; i++) {
if (tile_union[i] != tile_union[nnn-1]) {
tile_union[nnn] = tile_union[i];
nnn++;
}
}
n_near_tiles = nnn;
}
}
// now update our nearest neighbour info and diJ table
// first reduce size of table
tail--; n--;
if (jetA == tail) {
// there is nothing to be done
} else {
// Copy last jet contents and diJ info into position of jetA
*jetA = *tail;
diJ[jetA - head] = diJ[tail-head];
// IN the tiling fix pointers to tail and turn them into
// pointers to jetA (from predecessors, successors and the tile
// head if need be)
if (jetA->previous == NULL) {
_tiles[jetA->tile_index].head = jetA;
} else {
jetA->previous->next = jetA;
}
if (jetA->next != NULL) {jetA->next->previous = jetA;}
}
// Initialise jetB's NN distance as well as updating it for
// other particles.
for (int itile = 0; itile < n_near_tiles; itile++) {
Tile * tile_ptr = &_tiles[tile_union[itile]];
for (TiledJet * jetI = tile_ptr->head; jetI != NULL; jetI = jetI->next) {
// see if jetI had jetA or jetB as a NN -- if so recalculate the NN
if (jetI->NN == jetA || (jetI->NN == jetB && jetB != NULL)) {
jetI->NN_dist = _R2;
jetI->NN = NULL;
// now go over tiles that are neighbours of I (include own tile)
for (Tile ** near_tile = tile_ptr->begin_tiles;
near_tile != tile_ptr->end_tiles; near_tile++) {
// and then over the contents of that tile
for (TiledJet * jetJ = (*near_tile)->head;
jetJ != NULL; jetJ = jetJ->next) {
double dist = _bj_dist(jetI,jetJ);
if (dist < jetI->NN_dist && jetJ != jetI) {
jetI->NN_dist = dist; jetI->NN = jetJ;
}
}
}
diJ[jetI-head] = _bj_diJ(jetI); // update diJ
}
// check whether new jetB is closer than jetI's current NN and
// if need to update things
if (jetB != NULL) {
double dist = _bj_dist(jetI,jetB);
if (dist < jetI->NN_dist) {
if (jetI != jetB) {
jetI->NN_dist = dist;
jetI->NN = jetB;
diJ[jetI-head] = _bj_diJ(jetI); // update diJ...
}
}
if (dist < jetB->NN_dist) {
if (jetI != jetB) {
jetB->NN_dist = dist;
jetB->NN = jetI;}
}
}
}
}
if (jetB != NULL) {diJ[jetB-head] = _bj_diJ(jetB);}
//cout << n<<" "<tile_index].begin_tiles;
near_tile!= _tiles[tail->tile_index].end_tiles; near_tile++){
// and then the contents of that tile
for (TiledJet * jetJ = (*near_tile)->head;
jetJ != NULL; jetJ = jetJ->next) {
if (jetJ->NN == tail) {jetJ->NN = jetA;}
}
}
//for (int i = 0; i < n; i++) {
// if (briefjets[i].NN-briefjets >= n && briefjets[i].NN != NULL) {cout <<"YOU MUST BE CRAZY for n ="< tile_union(3*n_tile_neighbours);
// initialise the basic jet info
for (int i = 0; i< n; i++) {
_tj_set_jetinfo(jetA, i);
//cout << i<<": "<tile_index<<"\n";
jetA++; // move on to next entry of briefjets
}
TiledJet * head = briefjets; // a nicer way of naming start
// set up the initial nearest neighbour information
vector::const_iterator tile;
for (tile = _tiles.begin(); tile != _tiles.end(); tile++) {
// first do it on this tile
for (jetA = tile->head; jetA != NULL; jetA = jetA->next) {
for (jetB = tile->head; jetB != jetA; jetB = jetB->next) {
double dist = _bj_dist(jetA,jetB);
if (dist < jetA->NN_dist) {jetA->NN_dist = dist; jetA->NN = jetB;}
if (dist < jetB->NN_dist) {jetB->NN_dist = dist; jetB->NN = jetA;}
}
}
// then do it for RH tiles
for (Tile ** RTile = tile->RH_tiles; RTile != tile->end_tiles; RTile++) {
for (jetA = tile->head; jetA != NULL; jetA = jetA->next) {
for (jetB = (*RTile)->head; jetB != NULL; jetB = jetB->next) {
double dist = _bj_dist(jetA,jetB);
if (dist < jetA->NN_dist) {jetA->NN_dist = dist; jetA->NN = jetB;}
if (dist < jetB->NN_dist) {jetB->NN_dist = dist; jetB->NN = jetA;}
}
}
}
// no need to do it for LH tiles, since they are implicitly done
// when we set NN for both jetA and jetB on the RH tiles.
}
// now create the diJ (where J is i's NN) table -- remember that
// we differ from standard normalisation here by a factor of R2
// (corrected for at the end).
struct diJ_plus_link {
double diJ; // the distance
TiledJet * jet; // the jet (i) for which we've found this distance
// (whose NN will the J).
};
diJ_plus_link * diJ = new diJ_plus_link[n];
jetA = head;
for (int i = 0; i < n; i++) {
diJ[i].diJ = _bj_diJ(jetA); // kt distance * R^2
diJ[i].jet = jetA; // our compact diJ table will not be in
jetA->diJ_posn = i; // one-to-one corresp. with non-compact jets,
// so set up bi-directional correspondence here.
jetA++; // have jetA follow i
}
// now run the recombination loop
int history_location = n-1;
while (n > 0) {
// find the minimum of the diJ on this round
diJ_plus_link * best, *stop; // pointers a bit faster than indices
// could use best to keep track of diJ min, but it turns out to be
// marginally faster to have a separate variable (avoids n
// dereferences at the expense of n/2 assignments).
double diJ_min = diJ[0].diJ; // initialise the best one here.
best = diJ; // and here
stop = diJ+n;
for (diJ_plus_link * here = diJ+1; here != stop; here++) {
if (here->diJ < diJ_min) {best = here; diJ_min = here->diJ;}
}
// do the recombination between A and B
history_location++;
jetA = best->jet;
jetB = jetA->NN;
// put the normalisation back in
diJ_min *= _invR2;
if (jetB != NULL) {
// jet-jet recombination
// If necessary relabel A & B to ensure jetB < jetA, that way if
// the larger of them == newtail then that ends up being jetA and
// the new jet that is added as jetB is inserted in a position that
// has a future!
if (jetA < jetB) {std::swap(jetA,jetB);}
int nn; // new jet index
_do_ij_recombination_step(jetA->_jets_index, jetB->_jets_index, diJ_min, nn);
//OBS// get the two history indices
//OBSint ihstry_a = _jets[jetA->_jets_index].cluster_hist_index();
//OBSint ihstry_b = _jets[jetB->_jets_index].cluster_hist_index();
//OBS// create the recombined jet
//OBS_jets.push_back(_jets[jetA->_jets_index] + _jets[jetB->_jets_index]);
//OBSint nn = _jets.size() - 1;
//OBS_jets[nn].set_cluster_hist_index(history_location);
//OBS// update history
//OBS//cout <_jets_index, diJ_min);
//OBSint ihstry_a = _jets[jetA->_jets_index].cluster_hist_index();
//OBS//cout <tile_index,
tile_union, n_near_tiles);
if (jetB != NULL) {
if (jetB->tile_index != jetA->tile_index) {
_add_untagged_neighbours_to_tile_union(jetB->tile_index,
tile_union,n_near_tiles);
}
if (oldB.tile_index != jetA->tile_index &&
oldB.tile_index != jetB->tile_index) {
_add_untagged_neighbours_to_tile_union(oldB.tile_index,
tile_union,n_near_tiles);
}
}
// now update our nearest neighbour info and diJ table
// first reduce size of table
n--;
// then compactify the diJ by taking the last of the diJ and copying
// it to the position occupied by the diJ for jetA
diJ[n].jet->diJ_posn = jetA->diJ_posn;
diJ[jetA->diJ_posn] = diJ[n];
// Initialise jetB's NN distance as well as updating it for
// other particles.
// Run over all tiles in our union
for (int itile = 0; itile < n_near_tiles; itile++) {
Tile * tile_ptr = &_tiles[tile_union[itile]];
tile_ptr->tagged = false; // reset tag, since we're done with unions
// run over all jets in the current tile
for (TiledJet * jetI = tile_ptr->head; jetI != NULL; jetI = jetI->next) {
// see if jetI had jetA or jetB as a NN -- if so recalculate the NN
if (jetI->NN == jetA || (jetI->NN == jetB && jetB != NULL)) {
jetI->NN_dist = _R2;
jetI->NN = NULL;
// now go over tiles that are neighbours of I (include own tile)
for (Tile ** near_tile = tile_ptr->begin_tiles;
near_tile != tile_ptr->end_tiles; near_tile++) {
// and then over the contents of that tile
for (TiledJet * jetJ = (*near_tile)->head;
jetJ != NULL; jetJ = jetJ->next) {
double dist = _bj_dist(jetI,jetJ);
if (dist < jetI->NN_dist && jetJ != jetI) {
jetI->NN_dist = dist; jetI->NN = jetJ;
}
}
}
diJ[jetI->diJ_posn].diJ = _bj_diJ(jetI); // update diJ kt-dist
}
// check whether new jetB is closer than jetI's current NN and
// if jetI is closer than jetB's current (evolving) nearest
// neighbour. Where relevant update things
if (jetB != NULL) {
double dist = _bj_dist(jetI,jetB);
if (dist < jetI->NN_dist) {
if (jetI != jetB) {
jetI->NN_dist = dist;
jetI->NN = jetB;
diJ[jetI->diJ_posn].diJ = _bj_diJ(jetI); // update diJ...
}
}
if (dist < jetB->NN_dist) {
if (jetI != jetB) {
jetB->NN_dist = dist;
jetB->NN = jetI;}
}
}
}
}
// finally, register the updated kt distance for B
if (jetB != NULL) {diJ[jetB->diJ_posn].diJ = _bj_diJ(jetB);}
}
// final cleaning up;
delete[] diJ;
delete[] briefjets;
}
//----------------------------------------------------------------------
/// run a tiled clustering, with our minheap for keeping track of the
/// smallest dij
void ClusterSequence::_minheap_faster_tiled_N2_cluster() {
_initialise_tiles();
int n = _jets.size();
TiledJet * briefjets = new TiledJet[n];
TiledJet * jetA = briefjets, * jetB;
TiledJet oldB;
oldB.tile_index=0; // prevents a gcc warning
// will be used quite deep inside loops, but declare it here so that
// memory (de)allocation gets done only once
vector tile_union(3*n_tile_neighbours);
// initialise the basic jet info
for (int i = 0; i< n; i++) {
_tj_set_jetinfo(jetA, i);
//cout << i<<": "<tile_index<<"\n";
jetA++; // move on to next entry of briefjets
}
TiledJet * head = briefjets; // a nicer way of naming start
// set up the initial nearest neighbour information
vector::const_iterator tile;
for (tile = _tiles.begin(); tile != _tiles.end(); tile++) {
// first do it on this tile
for (jetA = tile->head; jetA != NULL; jetA = jetA->next) {
for (jetB = tile->head; jetB != jetA; jetB = jetB->next) {
double dist = _bj_dist(jetA,jetB);
if (dist < jetA->NN_dist) {jetA->NN_dist = dist; jetA->NN = jetB;}
if (dist < jetB->NN_dist) {jetB->NN_dist = dist; jetB->NN = jetA;}
}
}
// then do it for RH tiles
for (Tile ** RTile = tile->RH_tiles; RTile != tile->end_tiles; RTile++) {
for (jetA = tile->head; jetA != NULL; jetA = jetA->next) {
for (jetB = (*RTile)->head; jetB != NULL; jetB = jetB->next) {
double dist = _bj_dist(jetA,jetB);
if (dist < jetA->NN_dist) {jetA->NN_dist = dist; jetA->NN = jetB;}
if (dist < jetB->NN_dist) {jetB->NN_dist = dist; jetB->NN = jetA;}
}
}
}
// no need to do it for LH tiles, since they are implicitly done
// when we set NN for both jetA and jetB on the RH tiles.
}
//// now create the diJ (where J is i's NN) table -- remember that
//// we differ from standard normalisation here by a factor of R2
//// (corrected for at the end).
//struct diJ_plus_link {
// double diJ; // the distance
// TiledJet * jet; // the jet (i) for which we've found this distance
// // (whose NN will the J).
//};
//diJ_plus_link * diJ = new diJ_plus_link[n];
//jetA = head;
//for (int i = 0; i < n; i++) {
// diJ[i].diJ = _bj_diJ(jetA); // kt distance * R^2
// diJ[i].jet = jetA; // our compact diJ table will not be in
// jetA->diJ_posn = i; // one-to-one corresp. with non-compact jets,
// // so set up bi-directional correspondence here.
// jetA++; // have jetA follow i
//}
vector diJs(n);
for (int i = 0; i < n; i++) {
diJs[i] = _bj_diJ(&briefjets[i]);
briefjets[i].label_minheap_update_done();
}
MinHeap minheap(diJs);
// have a stack telling us which jets we'll have to update on the heap
vector jets_for_minheap;
jets_for_minheap.reserve(n);
// now run the recombination loop
int history_location = n-1;
while (n > 0) {
double diJ_min = minheap.minval() *_invR2;
jetA = head + minheap.minloc();
// do the recombination between A and B
history_location++;
jetB = jetA->NN;
if (jetB != NULL) {
// jet-jet recombination
// If necessary relabel A & B to ensure jetB < jetA, that way if
// the larger of them == newtail then that ends up being jetA and
// the new jet that is added as jetB is inserted in a position that
// has a future!
if (jetA < jetB) {std::swap(jetA,jetB);}
int nn; // new jet index
_do_ij_recombination_step(jetA->_jets_index, jetB->_jets_index, diJ_min, nn);
// what was jetB will now become the new jet
_bj_remove_from_tiles(jetA);
oldB = * jetB; // take a copy because we will need it...
_bj_remove_from_tiles(jetB);
_tj_set_jetinfo(jetB, nn); // cause jetB to become _jets[nn]
// (also registers the jet in the tiling)
} else {
// jet-beam recombination
// get the hist_index
_do_iB_recombination_step(jetA->_jets_index, diJ_min);
_bj_remove_from_tiles(jetA);
}
// remove the minheap entry for jetA
minheap.remove(jetA-head);
// first establish the set of tiles over which we are going to
// have to run searches for updated and new nearest-neighbours --
// basically a combination of vicinity of the tiles of the two old
// and one new jet.
int n_near_tiles = 0;
_add_untagged_neighbours_to_tile_union(jetA->tile_index,
tile_union, n_near_tiles);
if (jetB != NULL) {
if (jetB->tile_index != jetA->tile_index) {
_add_untagged_neighbours_to_tile_union(jetB->tile_index,
tile_union,n_near_tiles);
}
if (oldB.tile_index != jetA->tile_index &&
oldB.tile_index != jetB->tile_index) {
// GS: the line below generates a warning that oldB.tile_index
// may be used uninitialised. However, to reach this point, we
// ned jetB != NULL (see test a few lines above) and is jetB
// !=NULL, one would have gone through "oldB = *jetB before
// (see piece of code ~20 line above), so the index is
// initialised. We do not do anything to avoid the warning to
// avoid any potential speed impact.
_add_untagged_neighbours_to_tile_union(oldB.tile_index,
tile_union,n_near_tiles);
}
// indicate that we'll have to update jetB in the minheap
jetB->label_minheap_update_needed();
jets_for_minheap.push_back(jetB);
}
// Initialise jetB's NN distance as well as updating it for
// other particles.
// Run over all tiles in our union
for (int itile = 0; itile < n_near_tiles; itile++) {
Tile * tile_ptr = &_tiles[tile_union[itile]];
tile_ptr->tagged = false; // reset tag, since we're done with unions
// run over all jets in the current tile
for (TiledJet * jetI = tile_ptr->head; jetI != NULL; jetI = jetI->next) {
// see if jetI had jetA or jetB as a NN -- if so recalculate the NN
if (jetI->NN == jetA || (jetI->NN == jetB && jetB != NULL)) {
jetI->NN_dist = _R2;
jetI->NN = NULL;
// label jetI as needing heap action...
if (!jetI->minheap_update_needed()) {
jetI->label_minheap_update_needed();
jets_for_minheap.push_back(jetI);}
// now go over tiles that are neighbours of I (include own tile)
for (Tile ** near_tile = tile_ptr->begin_tiles;
near_tile != tile_ptr->end_tiles; near_tile++) {
// and then over the contents of that tile
for (TiledJet * jetJ = (*near_tile)->head;
jetJ != NULL; jetJ = jetJ->next) {
double dist = _bj_dist(jetI,jetJ);
if (dist < jetI->NN_dist && jetJ != jetI) {
jetI->NN_dist = dist; jetI->NN = jetJ;
}
}
}
}
// check whether new jetB is closer than jetI's current NN and
// if jetI is closer than jetB's current (evolving) nearest
// neighbour. Where relevant update things
if (jetB != NULL) {
double dist = _bj_dist(jetI,jetB);
if (dist < jetI->NN_dist) {
if (jetI != jetB) {
jetI->NN_dist = dist;
jetI->NN = jetB;
// label jetI as needing heap action...
if (!jetI->minheap_update_needed()) {
jetI->label_minheap_update_needed();
jets_for_minheap.push_back(jetI);}
}
}
if (dist < jetB->NN_dist) {
if (jetI != jetB) {
jetB->NN_dist = dist;
jetB->NN = jetI;}
}
}
}
}
// deal with jets whose minheap entry needs updating
while (jets_for_minheap.size() > 0) {
TiledJet * jetI = jets_for_minheap.back();
jets_for_minheap.pop_back();
minheap.update(jetI-head, _bj_diJ(jetI));
jetI->label_minheap_update_done();
}
n--;
}
// final cleaning up;
delete[] briefjets;
}
FASTJET_END_NAMESPACE