/// Constructor
/// @param M :: A matrix to copy.
GSLMatrix::GSLMatrix(const Kernel::Matrix<double> &M) {
m_matrix = gsl_matrix_alloc(M.numRows(), M.numCols());
for (size_t i = 0; i < size1(); ++i)
for (size_t j = 0; j < size2(); ++j) {
set(i, j, M[i][j]);
}
}
std::vector<Kernel::V3D> PeakShapeEllipsoid::getDirectionInSpecificFrame(
Kernel::Matrix<double> &invertedGoniometerMatrix) const {
std::vector<Kernel::V3D> directionsInFrame;
if ((invertedGoniometerMatrix.numCols() != m_directions.size()) ||
(invertedGoniometerMatrix.numRows() != m_directions.size())) {
throw std::invalid_argument("The inverted goniometer matrix is not "
"compatible with the direction vector");
}
for (const auto &direction : m_directions) {
directionsInFrame.push_back(invertedGoniometerMatrix * direction);
}
return directionsInFrame;
}
/**
* Checks the normalization workspace against the indices of the original
* dimensions.
* If not found, the corresponding dimension is integrated
* @param otherDimValues Values from non-HKL dimensions
* @param skipNormalization [InOut] Sets the flag true if normalization values
* are outside of original inputs
* @return Affine trasform matrix
*/
Kernel::Matrix<coord_t> MDNormDirectSC::findIntergratedDimensions(
const std::vector<coord_t> &otherDimValues, bool &skipNormalization) {
// Get indices of the original dimensions in the output workspace,
// and if not found, the corresponding dimension is integrated
Kernel::Matrix<coord_t> affineMat =
m_normWS->getTransformFromOriginal(0)->makeAffineMatrix();
const size_t nrm1 = affineMat.numRows() - 1;
const size_t ncm1 = affineMat.numCols() - 1;
for (size_t row = 0; row < nrm1; row++) // affine matrix, ignore last row
{
const auto dimen = m_normWS->getDimension(row);
const auto dimMin(dimen->getMinimum()), dimMax(dimen->getMaximum());
if (affineMat[row][0] == 1.) {
m_hIntegrated = false;
m_hIdx = row;
m_hmin = std::max(m_hmin, dimMin);
m_hmax = std::min(m_hmax, dimMax);
if (m_hmin > dimMax || m_hmax < dimMin) {
skipNormalization = true;
}
}
if (affineMat[row][1] == 1.) {
m_kIntegrated = false;
m_kIdx = row;
m_kmin = std::max(m_kmin, dimMin);
m_kmax = std::min(m_kmax, dimMax);
if (m_kmin > dimMax || m_kmax < dimMin) {
skipNormalization = true;
}
}
if (affineMat[row][2] == 1.) {
m_lIntegrated = false;
m_lIdx = row;
m_lmin = std::max(m_lmin, dimMin);
m_lmax = std::min(m_lmax, dimMax);
if (m_lmin > dimMax || m_lmax < dimMin) {
skipNormalization = true;
}
}
if (affineMat[row][3] == 1.) {
m_dEIntegrated = false;
m_eIdx = row;
m_dEmin = std::max(m_dEmin, dimMin);
m_dEmax = std::min(m_dEmax, dimMax);
if (m_dEmin > dimMax || m_dEmax < dimMin) {
skipNormalization = true;
}
}
for (size_t col = 4; col < ncm1; col++) // affine matrix, ignore last column
{
if (affineMat[row][col] == 1.) {
double val = otherDimValues.at(col - 3);
if (val > dimMax || val < dimMin) {
skipNormalization = true;
}
}
}
}
return affineMat;
}
/// Constructor
/// @param M :: A matrix to copy.
GSLMatrix::GSLMatrix(const Kernel::Matrix<double> &M)
: m_data(M.getVector()),
m_view(gsl_matrix_view_array(m_data.data(), M.numRows(), M.numCols())) {}
/**
* This function will create the skew matrix and basis for a non-orthogonal
* representation.
*
* @param ol : The oriented lattice containing B matrix and crystal basis
*vectors
* @param w : The tranform requested when MDworkspace was created
* @param aff : The affine matrix taking care of coordinate transformations
*/
void vtkDataSetToNonOrthogonalDataSet::createSkewInformation(
Geometry::OrientedLattice &ol, Kernel::DblMatrix &w,
Kernel::Matrix<coord_t> &aff) {
// Get the B matrix
Kernel::DblMatrix bMat = ol.getB();
// Apply the W tranform matrix
bMat *= w;
// Create G*
Kernel::DblMatrix gStar = bMat.Tprime() * bMat;
Geometry::UnitCell uc(ol);
uc.recalculateFromGstar(gStar);
m_skewMat = uc.getB();
// Calculate the column normalisation
std::vector<double> bNorm;
for (std::size_t i = 0; i < m_skewMat.numCols(); i++) {
double sum = 0.0;
for (std::size_t j = 0; j < m_skewMat.numRows(); j++) {
sum += m_skewMat[j][i] * m_skewMat[j][i];
}
bNorm.push_back(std::sqrt(sum));
}
// Apply column normalisation to skew matrix
Kernel::DblMatrix scaleMat(3, 3, true);
scaleMat[0][0] /= bNorm[0];
scaleMat[1][1] /= bNorm[1];
scaleMat[2][2] /= bNorm[2];
m_skewMat *= scaleMat;
// Setup basis normalisation array
// Intel and MSBuild can't handle this
// m_basisNorm = {ol.astar(), ol.bstar(), ol.cstar()};
m_basisNorm.push_back(ol.astar());
m_basisNorm.push_back(ol.bstar());
m_basisNorm.push_back(ol.cstar());
// Expand matrix to 4 dimensions if necessary
if (4 == m_numDims) {
m_basisNorm.push_back(1.0);
Kernel::DblMatrix temp(4, 4, true);
for (std::size_t i = 0; i < 3; i++) {
for (std::size_t j = 0; j < 3; j++) {
temp[i][j] = m_skewMat[i][j];
}
}
m_skewMat = temp;
}
// Convert affine matrix to similar type as others
Kernel::DblMatrix affMat(aff.numRows(), aff.numCols());
for (std::size_t i = 0; i < aff.numRows(); i++) {
for (std::size_t j = 0; j < aff.numCols(); j++) {
affMat[i][j] = aff[i][j];
}
}
// Strip affine matrix down to correct dimensions
this->stripMatrix(affMat);
// Perform similarity transform to get coordinate orientation correct
m_skewMat = affMat.Tprime() * (m_skewMat * affMat);
m_basisNorm = affMat * m_basisNorm;
if (4 == m_numDims) {
this->stripMatrix(m_skewMat);
}
this->findSkewBasis(m_basisX, m_basisNorm[0]);
this->findSkewBasis(m_basisY, m_basisNorm[1]);
this->findSkewBasis(m_basisZ, m_basisNorm[2]);
}
/// Run the algorithm
void PredictFractionalPeaks::exec()
{
PeaksWorkspace_sptr Peaks=getProperty("Peaks");
vector<double> hOffsets = getProperty("HOffset");
vector<double> kOffsets = getProperty("KOffset");
vector<double> lOffsets = getProperty("LOffset");
if ( hOffsets.empty())hOffsets.push_back(0.0);
if ( kOffsets.empty())kOffsets.push_back(0.0);
if ( lOffsets.empty())lOffsets.push_back(0.0);
;
bool includePeaksInRange= getProperty("IncludeAllPeaksInRange");
if( Peaks->getNumberPeaks()<=0)
{
g_log.error()<<"There are No peaks in the input PeaksWorkspace\n";
return;
}
API::Sample samp= Peaks->sample();
Geometry::OrientedLattice &ol = samp.getOrientedLattice();
Geometry::Instrument_const_sptr Instr = Peaks->getInstrument();
boost::shared_ptr<IPeaksWorkspace> OutPeaks=WorkspaceFactory::Instance().createPeaks();
OutPeaks->setInstrument(Instr);
// AnalysisDataService::Instance().addOrReplace(getPropertyValue("FracPeaks"),OutPeaks);
V3D hkl;
int peakNum =0;
int NPeaks = Peaks->getNumberPeaks();
Kernel::Matrix<double> Gon;
Gon.identityMatrix();
double Hmin= getProperty("Hmin");
double Hmax= getProperty("Hmax");
double Kmin= getProperty("Kmin");
double Kmax= getProperty("Kmax");
double Lmin= getProperty("Lmin");
double Lmax= getProperty("Lmax");
int N=NPeaks;
if( includePeaksInRange)
{
N=(int)((Hmax-Hmin+1)*(Kmax-Kmin+1)*(Lmax-Lmin+1)+.5);
N=max<int>(100,N);
}
IPeak& peak0 =Peaks->getPeak(0);
int RunNumber = peak0.getRunNumber();
Gon=peak0.getGoniometerMatrix();
Progress prog(this, 0, 1,N);
if( includePeaksInRange)
{
hkl[0]=Hmin;
hkl[1]=Kmin;
hkl[2]=Lmin;
}else
{
hkl[0]=peak0.getH();
hkl[1]=peak0.getK();
hkl[2] =peak0.getL();
}
Kernel::DblMatrix UB= ol.getUB();
vector< vector<int> > AlreadyDonePeaks;
bool done = false;
int ErrPos = 1;//Used to determine position in code of a throw
while( !done)
{
for( size_t hoffset=0;hoffset<hOffsets.size();hoffset++)
for(size_t koffset=0;koffset<kOffsets.size();koffset++)
for( size_t loffset=0;loffset<lOffsets.size();loffset++)
try
{
V3D hkl1( hkl );
ErrPos = 0;
hkl1[0] += hOffsets[hoffset] ;
hkl1[1] += kOffsets[koffset] ;
hkl1[2] += lOffsets[loffset] ;
Kernel::V3D Qs = UB * hkl1 ;
Qs*= 2.0;
Qs*=M_PI;
Qs=Gon*Qs;
if( Qs[2] <= 0 )
continue;
ErrPos=1;
boost::shared_ptr<IPeak> peak( Peaks->createPeak( Qs, 1 ));
peak->setGoniometerMatrix(Gon);
if (Qs[2]>0 && peak->findDetector())
{
ErrPos=2;
vector<int> SavPk;
SavPk.push_back(RunNumber);
SavPk.push_back((int)floor(1000*hkl1[0]+.5));
SavPk.push_back((int)floor(1000*hkl1[1]+.5));
SavPk.push_back((int)floor(1000*hkl1[2]+.5));
//TODO keep list sorted so searching is faster?
vector<vector<int> >::iterator it = find(AlreadyDonePeaks.begin(),AlreadyDonePeaks.end(),SavPk);
ErrPos=3;
if( it == AlreadyDonePeaks.end())
AlreadyDonePeaks.push_back(SavPk);
else
continue;
ErrPos=4;
peak->setHKL(hkl1);
peak->setRunNumber(RunNumber);
OutPeaks->addPeak(*peak);
}
}catch(...)
{
if( ErrPos != 1)// setQLabFrame in createPeak throws exception
throw new std::invalid_argument( "Invalid data at this point");
}
if( includePeaksInRange)
{
hkl[0]++;
if( hkl[0]>Hmax)
{
hkl[0]=Hmin;
hkl[1]++;
if( hkl[1]> Kmax)
{
hkl[1]=Kmin;
hkl[2]++;
if( hkl[2]> Lmax)
done = true;
}
}
}else
{
peakNum++;
if( peakNum >= NPeaks)
done = true;
else
{// peak0= Peaks->getPeak(peakNum);
IPeak& peak1= Peaks->getPeak(peakNum);
//??? could not assign to peak0 above. Did not work
// the peak that peak0 was associated with did NOT change
hkl[0]=peak1.getH();
hkl[1]=peak1.getK();
hkl[2] =peak1.getL();
Gon=peak1.getGoniometerMatrix();
RunNumber = peak1.getRunNumber();
}
}
prog.report();
}
setProperty("FracPeaks",OutPeaks);
}
/* Execute the algorithm. */
void ConvertToQ3DdE::exec(){
Timer tim, timtotal;
CPUTimer cputim, cputimtotal;
// -------- Input workspace
MatrixWorkspace_sptr inMatrixWS = getProperty("InputWorkspace");
Workspace2D_sptr inWS2D = boost::dynamic_pointer_cast<Workspace2D>(inMatrixWS);
// get the energy axis
NumericAxis *pEnAxis = dynamic_cast<NumericAxis *>(inWS2D->getAxis(0));
if(!pEnAxis){
convert_log.error()<<"Can not get proper energy axis from processed workspace\n";
throw(std::invalid_argument("Input workspace is not propwer converted to energy workspace"));
}
size_t lastInd = inWS2D->getAxis(0)->length()-1;
double E_max = inWS2D->getAxis(0)->operator()(lastInd);
double E_min = inWS2D->getAxis(0)->operator()(0);
//double E_min = inWS2D->readX(0).front();
//double E_max = inWS2D->readX(0).back();
if(E_min>=E_max){
convert_log.error()<<" expecting to process energy form "<<E_min<<" to "<<E_max<<" but Emin>=Emax\n";
throw(std::invalid_argument(" Emin>=Emax"));
}
//*** Input energy
// get and check input energy
double Ei = getProperty("EnergyInput");
// check if workspace knows better
if(inWS2D->run().hasProperty("Ei")){
double Ei_t = boost::lexical_cast<double>(inWS2D->run().getProperty("Ei")->value());
if(std::fabs(Ei-Ei_t)>double(FLT_EPSILON)){
g_log.information()<<" energy: "<<Ei<<" obtained from the algorithm parameters has been replaced by the energy:"<<Ei_t<<", obtained from the workspace\n";
Ei=Ei_t;
setProperty("EnergyInput", Ei);
}
}
if (E_max >Ei){
convert_log.error()<<"Maximal elergy transferred to sample eq "<<E_max<<" and exceeds the input energy "<<Ei<<std::endl;
throw(std::invalid_argument("Maximal transferred energy exceeds input energy"));
}
// the wawe vector of input neutrons;
double ki=sqrt(Ei/PhysicalConstants::E_mev_toNeutronWavenumberSq);
std::vector<double> QEmin = getProperty("MinQdE_values");
std::vector<double> QEmax = getProperty("MaxQdE_values");
// Try to get the output workspace
IMDEventWorkspace_sptr i_out = getProperty("OutputWorkspace");
boost::shared_ptr<MDEvents::MDEventWorkspace<MDE,4> > ws = boost::dynamic_pointer_cast<MDEvents::MDEventWorkspace<MDE,4> >( i_out );
std::string dimensionNames[4] = {"Q_x", "Q_y", "Q_z","DeltaE"};
if (ws){
//check existing worspace limits and agree these with new limits if they were specified;
if(QEmin.empty())QEmin.assign(4, FLT_MAX);
if(QEmax.empty())QEmax.assign(4,-FLT_MAX);
for(int i=0;i<4;i++){
// Check that existing workspace dimensions make sense with the desired one (using the name)
if (ws->getDimension(i)->getName() != dimensionNames[i]){
convert_log.error()<<"The existing MDEventWorkspace " + ws->getName() + " has different dimensions than were requested! Either give a different name for the output, or change the OutputDimensions parameter.\n";
throw std::runtime_error("The existing MDEventWorkspace " + ws->getName() + " has different dimensions than were requested! Either give a different name for the output, or change the OutputDimensions parameter.");
}
// coordinate existing and nwe
double ws_min = ws->getDimension(i)->getMinimum();
double ws_max = ws->getDimension(i)->getMaximum();
if(ws_min>QEmin[i])QEmin[i]=ws_min;
if(ws_max<QEmax[i])QEmax[i]=ws_max;
}
// verify that final limits are correct
check_max_morethen_min(QEmin,QEmax);
}else{
if(QEmin.empty()||QEmax.empty()){
convert_log.error()<<" min and max Q-dE values can not be empty when creating new workspace";
throw(std::invalid_argument(" min-max property is empty"));
}
if(QEmin.size()!=4||QEmax.size()!=4){
convert_log.error()<<" min and max Q-dE values have to had 4 elements each";
throw(std::invalid_argument(" min-max is not 4Dimensional"));
}
check_max_morethen_min(QEmin,QEmax);
std::string dimensionUnits[4] = {"Amgstroms^-1", "Amgstroms^-1", "Amgstroms^-1","meV"};
ws = create_empty4DEventWS(dimensionNames,dimensionUnits,QEmin,QEmax);
}
ws->splitBox();
//BoxController_sptr bc = ws->getBoxController();
// if (!bc)
// throw std::runtime_error("Output MDEventWorkspace does not have a BoxController!");
// copy experiment info into
ExperimentInfo_sptr ExperimentInfo(inWS2D->cloneExperimentInfo());
uint16_t runIndex = ws->addExperimentInfo(ExperimentInfo);
// Initalize the matrix to 3x3 identity
Kernel::Matrix<double> mat = Kernel::Matrix<double>(3,3, true);
// Set the matrix based on UB etc.
Kernel::Matrix<double> ub = inWS2D->sample().getOrientedLattice().getUB();
Kernel::Matrix<double> gon =inWS2D->run().getGoniometer().getR();
// As per Busing and Levy 1967, HKL = Goniometer * UB * q_lab_frame
mat = gon * ub;
std::vector<double> rotMat = mat.get_vector();
const size_t numSpec = inWS2D->getNumberHistograms();
const size_t specSize = inWS2D->blocksize();
// Initialise the progress reporting object
Progress progress(this,0.0,1.0,numSpec);
// Try to check if one should use preprocessed detector positions or try to calculate the new one
bool reuse_preprocecced_detectors = getProperty("UsePreprocessedDetectors");
if(!(reuse_preprocecced_detectors&&det_loc.is_defined()))process_detectors_positions(inWS2D);
// allocate the events buffer;
// std::vector<MDE> out_events;
// out_events.reserve(specSize);
// To track when to split up boxes
// size_t eventsAdded = 0;
// size_t lastNumBoxes = ws->getBoxController()->getTotalNumMDBoxes();
// // Create the thread pool that will run all of these.
// ThreadScheduler * ts = new ThreadSchedulerLargestCost();
// ThreadPool tp(ts);
// boost::function<void ()> func;
// func = boost::bind(&ConvertToQ3DdE::convertEventList<TofEvent>, &*this, static_cast<int>(wi));
//
size_t n_added_events(0);
size_t SPLIT_LEVEL(1000);
// PARALLEL_FOR1(inWS2D)
for (int64_t i = 0; i < int64_t(numSpec); ++i)
{
// PARALLEL_START_INTERUPT_REGION
const MantidVec& E_transfer = inWS2D->readX(i);
const MantidVec& Signal = inWS2D->readY(i);
const MantidVec& Error = inWS2D->readE(i);
int32_t det_id = det_loc.det_id[i];
coord_t QE[4];
for (size_t j = 0; j < specSize; ++j)
{
// drop emtpy events
if(Signal[j]<FLT_EPSILON)continue;
double E_tr = 0.5*(E_transfer[j]+E_transfer[j+1]);
if(E_tr<E_min||E_tr>=E_max)continue;
double k_tr = sqrt((Ei-E_tr)/PhysicalConstants::E_mev_toNeutronWavenumberSq);
double ex = det_loc.det_dir[i].X();
double ey = det_loc.det_dir[i].Y();
double ez = det_loc.det_dir[i].Z();
double qx = -ex*k_tr;
double qy = -ey*k_tr;
double qz = ki - ez*k_tr;
QE[0] = (coord_t)(rotMat[0]*qx+rotMat[3]*qy+rotMat[6]*qz); if(QE[0]<QEmin[0]||QE[0]>=QEmax[0])continue;
QE[1] = (coord_t)(rotMat[1]*qx+rotMat[4]*qy+rotMat[7]*qz); if(QE[1]<QEmin[1]||QE[1]>=QEmax[1])continue;
QE[2] = (coord_t)(rotMat[2]*qx+rotMat[5]*qy+rotMat[8]*qz); if(QE[2]<QEmin[2]||QE[2]>=QEmax[2])continue;
QE[3] = (coord_t)E_tr;
float ErrSq = float(Error[j]*Error[j]);
ws->addEvent(MDE(float(Signal[j]),ErrSq,runIndex,det_id,QE));
n_added_events++;
}
// This splits up all the boxes according to split thresholds and sizes.
//Kernel::ThreadScheduler * ts = new ThreadSchedulerFIFO();
//ThreadPool tp(NULL);
if(n_added_events>SPLIT_LEVEL){
ws->splitAllIfNeeded(NULL);
n_added_events=0;
}
//tp.joinAll();
progress.report(i);
// PARALLEL_END_INTERUPT_REGION
}
// PARALLEL_CHECK_INTERUPT_REGION
if(n_added_events>0){
ws->splitAllIfNeeded(NULL);
n_added_events=0;
}
ws->refreshCache();
progress.report();
// Save the output
setProperty("OutputWorkspace", boost::dynamic_pointer_cast<IMDEventWorkspace>(ws));
//
//
// // ------------------- Cache values that are common for all ---------------------------
// // Extract some parameters global to the instrument
// in_ws->getInstrument()->getInstrumentParameters(l1,beamline,beamline_norm, samplePos);
// beamline_norm = beamline.norm();
// beamDir = beamline / beamline.norm();
//
// //To get all the detector ID's
// in_ws->getInstrument()->getDetectors(allDetectors);
//
// size_t totalCost = in_ws->getNumberEvents();
// prog = new Progress(this, 0, 1.0, totalCost);
//// if (DODEBUG) prog = new ProgressText(0, 1.0, totalCost, true);
//// if (DODEBUG) prog->setNotifyStep(1);
//
// // Create the thread pool that will run all of these.
// ThreadScheduler * ts = new ThreadSchedulerLargestCost();
// ThreadPool tp(ts);
//
// if (DODEBUG) std::cout << cputim << ": initial setup. There are " << lastNumBoxes << " MDBoxes.\n";
//
// for (size_t wi=0; wi < in_ws->getNumberHistograms(); wi++)
// {
// // Equivalent of: this->convertEventList(wi);
// EventList & el = in_ws->getEventList(wi);
//
// // We want to bind to the right templated function, so we have to know the type of TofEvent contained in the EventList.
// boost::function<void ()> func;
// switch (el.getEventType())
// {
// case TOF:
// func = boost::bind(&ConvertToQ3DdE::convertEventList<TofEvent>, &*this, static_cast<int>(wi));
// break;
// case WEIGHTED:
// func = boost::bind(&ConvertToQ3DdE::convertEventList<WeightedEvent>, &*this, static_cast<int>(wi));
// break;
// case WEIGHTED_NOTIME:
// func = boost::bind(&ConvertToQ3DdE::convertEventList<WeightedEventNoTime>, &*this, static_cast<int>(wi));
// break;
// default:
// throw std::runtime_error("EventList had an unexpected data type!");
// }
//
// // Give this task to the scheduler
// double cost = double(el.getNumberEvents());
// ts->push( new FunctionTask( func, cost) );
//
// // Keep a running total of how many events we've added
// eventsAdded += el.getNumberEvents();
// if (bc->shouldSplitBoxes(eventsAdded, lastNumBoxes))
// {
// if (DODEBUG) std::cout << cputim << ": Added tasks worth " << eventsAdded << " events.\n";
// // Do all the adding tasks
// tp.joinAll();
// if (DODEBUG) std::cout << cputim << ": Performing the addition of these events.\n";
//
// // Now do all the splitting tasks
// ws->splitAllIfNeeded(ts);
// if (ts->size() > 0)
// prog->doReport("Splitting Boxes");
// tp.joinAll();
//
// // Count the new # of boxes.
// lastNumBoxes = ws->getBoxController()->getTotalNumMDBoxes();
// if (DODEBUG) std::cout << cputim << ": Performing the splitting. There are now " << lastNumBoxes << " boxes.\n";
// eventsAdded = 0;
// }
// }
//
// if (DODEBUG) std::cout << cputim << ": We've added tasks worth " << eventsAdded << " events.\n";
//
// tp.joinAll();
// if (DODEBUG) std::cout << cputim << ": Performing the FINAL addition of these events.\n";
//
// // Do a final splitting of everything
// ws->splitAllIfNeeded(ts);
// tp.joinAll();
// if (DODEBUG) std::cout << cputim << ": Performing the FINAL splitting of boxes. There are now " << ws->getBoxController()->getTotalNumMDBoxes() <<" boxes\n";
//
//
// // Recount totals at the end.
// cputim.reset();
// ws->refreshCache();
// if (DODEBUG) std::cout << cputim << ": Performing the refreshCache().\n";
//
// //TODO: Centroid in parallel, maybe?
// ws->getBox()->refreshCentroid(NULL);
// if (DODEBUG) std::cout << cputim << ": Performing the refreshCentroid().\n";
//
//
// if (DODEBUG)
// {
// std::cout << "Workspace has " << ws->getNPoints() << " events. This took " << cputimtotal << " in total.\n";
// std::vector<std::string> stats = ws->getBoxControllerStats();
// for (size_t i=0; i<stats.size(); ++i)
// std::cout << stats[i] << "\n";
// std::cout << std::endl;
// }
//
//
}
