#include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "STGrid.h" using namespace std ; using namespace casa ; using namespace asap ; namespace asap { // for performance check double eToInt = 0.0 ; double eGetWeight = 0.0 ; // constructor STGrid::STGrid() { init() ; } STGrid::STGrid( const string infile ) { init() ; setFileIn( infile ) ; } STGrid::STGrid( const vector infile ) { init() ; setFileList( infile ) ; } void STGrid::init() { ifno_ = -1 ; nx_ = -1 ; ny_ = -1 ; npol_ = 0 ; nchan_ = 0 ; nrow_ = 0 ; cellx_ = 0.0 ; celly_ = 0.0 ; center_ = Vector ( 2, 0.0 ) ; convType_ = "BOX" ; wtype_ = "UNIFORM" ; convSupport_ = -1 ; userSupport_ = -1 ; convSampling_ = 100 ; nprocessed_ = 0 ; nchunk_ = 0 ; // initialize user input nxUI_ = -1 ; nyUI_ = -1 ; cellxUI_ = "" ; cellyUI_ = "" ; centerUI_ = "" ; } void STGrid::setFileIn( const string infile ) { String name( infile ) ; if ( infileList_.size() == 0 || infileList_[0].compare( name ) != 0 ) { infileList_.resize( 1 ) ; infileList_[0] = String(infile) ; nfile_ = 1 ; } } void STGrid::setFileList( const vector infile ) { nfile_ = infile.size() ; infileList_.resize( nfile_ ) ; for ( uInt i = 0 ; i < nfile_ ; i++ ) { infileList_[i] = infile[i] ; } } void STGrid::setPolList( vector pols ) { pollist_.assign( Vector( pols ) ) ; } void STGrid::setScanList( vector scans ) { scanlist_.assign( Vector( scans ) ) ; } void STGrid::setWeight( const string wType ) { wtype_ = String( wType ) ; wtype_.upcase() ; } void STGrid::defineImage( int nx, int ny, string scellx, string scelly, string scenter ) { nxUI_ = (Int)nx ; nyUI_ = (Int)ny ; cellxUI_ = String( scellx ) ; cellyUI_ = String( scelly ) ; centerUI_ = String( scenter ) ; } void STGrid::setFunc( string convType, int convSupport ) { convType_ = String( convType ) ; convType_.upcase() ; userSupport_ = (Int)convSupport ; } #define NEED_UNDERSCORES #if defined(NEED_UNDERSCORES) #define ggridsd ggridsd_ #endif extern "C" { void ggridsd(Double*, const Complex*, Int*, Int*, Int*, const Int*, const Int*, const Float*, Int*, Int*, Complex*, Float*, Int*, Int*, Int *, Int *, Int*, Int*, Float*, Int*, Int*, Double*); } void STGrid::call_ggridsd( Array &xypos, Array &spectra, Int &nvispol, Int &nvischan, Array &flagtra, Array &flagrow, Array &weight, Int &nrow, Int &irow, Array &gdata, Array &gwgt, Int &nx, Int &ny, Int &npol, Int &nchan, Int &support, Int &sampling, Vector &convFunc, Int *chanMap, Int *polMap ) { // parameters for gridding Int idopsf = 0 ; Int len = npol*nchan ; Double *sumw_p = new Double[len] ; { Double *work_p = sumw_p ; for ( Int i = 0 ; i < len ; i++ ) { *work_p = 0.0 ; work_p++ ; } } // prepare pointer Bool deletePos, deleteData, deleteWgt, deleteFlag, deleteFlagR, deleteConv, deleteDataG, deleteWgtG ; Double *xy_p = xypos.getStorage( deletePos ) ; const Complex *values_p = spectra.getStorage( deleteData ) ; const Int *flag_p = flagtra.getStorage( deleteFlag ) ; const Int *rflag_p = flagrow.getStorage( deleteFlagR ) ; const Float *wgt_p = weight.getStorage( deleteWgt ) ; Complex *grid_p = gdata.getStorage( deleteDataG ) ; Float *wgrid_p = gwgt.getStorage( deleteWgtG ) ; Float *conv_p = convFunc.getStorage( deleteConv ) ; // pass copy of irow to ggridsd since it will be modified in theroutine Int irowCopy = irow ; // call ggridsd ggridsd( xy_p, values_p, &nvispol, &nvischan, &idopsf, flag_p, rflag_p, wgt_p, &nrow, &irowCopy, grid_p, wgrid_p, &nx, &ny, &npol, &nchan, &support, &sampling, conv_p, chanMap, polMap, sumw_p ) ; // finalization xypos.putStorage( xy_p, deletePos ) ; spectra.freeStorage( values_p, deleteData ) ; flagtra.freeStorage( flag_p, deleteFlag ) ; flagrow.freeStorage( rflag_p, deleteFlagR ) ; weight.freeStorage( wgt_p, deleteWgt ) ; gdata.putStorage( grid_p, deleteDataG ) ; gwgt.putStorage( wgrid_p, deleteWgtG ) ; convFunc.putStorage( conv_p, deleteConv ) ; delete sumw_p ; } Bool STGrid::pastEnd() { LogIO os( LogOrigin("STGrid","pastEnd",WHERE) ) ; Bool b = nprocessed_ >= nrow_ ; return b ; } void STGrid::grid() { LogIO os( LogOrigin("STGrid", "grid", WHERE) ) ; double t0,t1 ; // data selection t0 = mathutil::gettimeofday_sec() ; selectData() ; t1 = mathutil::gettimeofday_sec() ; os << "selectData: elapsed time is " << t1-t0 << " sec." << LogIO::POST ; setupGrid() ; setupArray() ; if ( wtype_.compare("UNIFORM") != 0 && wtype_.compare("TINT") != 0 && wtype_.compare("TSYS") != 0 && wtype_.compare("TINTSYS") != 0 ) { LogIO os( LogOrigin("STGrid", "grid", WHERE) ) ; os << LogIO::WARN << "Unsupported weight type '" << wtype_ << "', apply UNIFORM weight" << LogIO::POST ; wtype_ = "UNIFORM" ; } // grid parameter os << LogIO::DEBUGGING ; os << "----------" << endl ; os << "Data selection summary" << endl ; os << " ifno = " << ifno_ << endl ; os << " pollist = " << pollist_ << endl ; os << " scanlist = " << scanlist_ << endl ; os << "----------" << endl ; os << "Grid parameter summary" << endl ; os << " (nx,ny) = (" << nx_ << "," << ny_ << ")" << endl ; os << " (cellx,celly) = (" << cellx_ << "," << celly_ << ")" << endl ; os << " center = " << center_ << endl ; os << " weighting = " << wtype_ << endl ; os << " convfunc = " << convType_ << " with support " << convSupport_ << endl ; os << "----------" << LogIO::POST ; os << LogIO::NORMAL ; Bool doAll = examine() ; if ( doAll ) gridPerPol() ; else gridPerRow() ; } Bool STGrid::examine() { // TODO: nchunk_ must be determined from nchan_, npol_, and (nx_,ny_) // by considering data size to be allocated for ggridsd input/output nchunk_ = 400 ; Bool b = nchunk_ >= nrow_ ; nchunk_ = min( nchunk_, nrow_ ) ; return b ; } void STGrid::gridPerRow() { LogIO os( LogOrigin("STGrid", "gridPerRow", WHERE) ) ; double t0, t1 ; // convolution kernel Vector convFunc ; t0 = mathutil::gettimeofday_sec() ; setConvFunc( convFunc ) ; t1 = mathutil::gettimeofday_sec() ; os << "setConvFunc: elapsed time is " << t1-t0 << " sec." << LogIO::POST ; // grid data Int gnx = nx_ ; Int gny = ny_ ; // Extend grid plane with convSupport_ // Int gnx = nx_+convSupport_*2 ; // Int gny = ny_+convSupport_*2 ; IPosition gshape( 4, gnx, gny, npol_, nchan_ ) ; Array gdataArrC( gshape, 0.0 ) ; // 2011/12/20 TN // data_ and gwgtArr share storage data_.resize( gshape ) ; data_ = 0.0 ; Array gwgtArr( data_ ) ; // parameters for gridding Int *chanMap = new Int[nchan_] ; { Int *work_p = chanMap ; for ( Int i = 0 ; i < nchan_ ; i++ ) { *work_p = i ; work_p++ ; } } Int *polMap = new Int[1] ; Int nvispol = 1 ; Int irow = -1 ; // for performance check double eGetData = 0.0 ; double eToPixel = 0.0 ; double eGGridSD = 0.0 ; double eInitPol = 0.0 ; for ( uInt ifile = 0 ; ifile < nfile_ ; ifile++ ) { initTable( ifile ) ; os << "start table " << ifile << ": " << infileList_[ifile] << LogIO::POST ; for ( Int ipol = 0 ; ipol < npol_ ; ipol++ ) { t0 = mathutil::gettimeofday_sec() ; initPol( ipol ) ; t1 = mathutil::gettimeofday_sec() ; eInitPol += t1-t0 ; polMap[0] = ipol ; os << "start pol " << ipol << LogIO::POST ; while( !pastEnd() ) { // data storage IPosition cshape( 3, npol_, nchan_, nchunk_ ) ; IPosition mshape( 2, npol_, nchunk_ ) ; IPosition vshape( 1, nchunk_ ) ; IPosition dshape( 2, 2, nchunk_ ) ; IPosition wshape( 2, nchan_, nchunk_ ) ; Array spectra( wshape ) ; Array flagtra( wshape ) ; Array rflag( vshape ) ; Array weight( wshape ) ; Array direction( dshape ) ; Array xypos( dshape ) ; spectraF_.resize( wshape ) ; flagtraUC_.resize( wshape ) ; rflagUI_.resize( vshape ) ; // retrieve data t0 = mathutil::gettimeofday_sec() ; Int nrow = getDataChunk( spectra, direction, flagtra, rflag, weight ) ; t1 = mathutil::gettimeofday_sec() ; eGetData += t1-t0 ; // world -> pixel t0 = mathutil::gettimeofday_sec() ; toPixel( direction, xypos ) ; t1 = mathutil::gettimeofday_sec() ; eToPixel += t1-t0 ; // call ggridsd t0 = mathutil::gettimeofday_sec() ; call_ggridsd( xypos, spectra, nvispol, nchan_, flagtra, rflag, weight, nrow, irow, gdataArrC, gwgtArr, gnx, gny, npol_, nchan_, convSupport_, convSampling_, convFunc, chanMap, polMap ) ; t1 = mathutil::gettimeofday_sec() ; eGGridSD += t1-t0 ; } os << "end pol " << ipol << LogIO::POST ; nprocessed_ = 0 ; } } os << "initPol: elapsed time is " << eInitPol << " sec." << LogIO::POST ; os << "getData: elapsed time is " << eGetData-eToInt-eGetWeight << " sec." << LogIO::POST ; os << "toPixel: elapsed time is " << eToPixel << " sec." << LogIO::POST ; os << "ggridsd: elapsed time is " << eGGridSD << " sec." << LogIO::POST ; os << "toInt: elapsed time is " << eToInt << " sec." << LogIO::POST ; os << "getWeight: elapsed time is " << eGetWeight << " sec." << LogIO::POST ; delete polMap ; delete chanMap ; // set data setData( gdataArrC, gwgtArr ) ; } void STGrid::gridPerPol() { LogIO os( LogOrigin("STGrid", "gridPerPol", WHERE) ) ; double t0, t1 ; // convolution kernel Vector convFunc ; t0 = mathutil::gettimeofday_sec() ; setConvFunc( convFunc ) ; t1 = mathutil::gettimeofday_sec() ; os << "setConvFunc: elapsed time is " << t1-t0 << " sec." << LogIO::POST ; // prepare grid data storage Int gnx = nx_ ; Int gny = ny_ ; // // Extend grid plane with convSupport_ // Int gnx = nx_+convSupport_*2 ; // Int gny = ny_+convSupport_*2 ; IPosition gshape( 4, gnx, gny, npol_, nchan_ ) ; Array gdataArrC( gshape, 0.0 ) ; //Array gwgtArr( gshape, 0.0 ) ; // 2011/12/20 TN // data_ and weight array shares storage data_.resize( gshape ) ; data_ = 0.0 ; Array gwgtArr( data_ ) ; // maps Int *chanMap = new Int[nchan_] ; { Int *work_p = chanMap ; for ( Int i = 0 ; i < nchan_ ; i++ ) { *work_p = i ; work_p++ ; } } Int *polMap = new Int[1] ; // some parameters for ggridsd Int nvispol = 1 ; Int irow = -1 ; // for performance check double eInitPol = 0.0 ; double eGetData = 0.0 ; double eToPixel = 0.0 ; double eGGridSD = 0.0 ; double eToInt = 0.0 ; for ( uInt ifile = 0 ; ifile < nfile_ ; ifile++ ) { initTable( ifile ) ; os << "start table " << ifile << ": " << infileList_[ifile] << LogIO::POST ; // to read data from the table IPosition mshape( 2, nchan_, nrow_ ) ; IPosition dshape( 2, 2, nrow_ ) ; Array spectra( mshape ) ; Array direction( dshape ) ; Array flagtra( mshape ) ; Array rflag( IPosition(1,nrow_) ) ; Array weight( mshape ) ; Array xypos( dshape ) ; for ( Int ipol = 0 ; ipol < npol_ ; ipol++ ) { t0 = mathutil::gettimeofday_sec() ; initPol( ipol ) ; t1 = mathutil::gettimeofday_sec() ; eInitPol += t1-t0 ; // retrieve data t0 = mathutil::gettimeofday_sec() ; getDataPerPol( spectra, direction, flagtra, rflag, weight ) ; t1 = mathutil::gettimeofday_sec() ; eGetData += t1-t0 ; // world -> pixel t0 = mathutil::gettimeofday_sec() ; toPixel( direction, xypos ) ; t1 = mathutil::gettimeofday_sec() ; eToPixel += t1-t0 ; // call ggridsd polMap[0] = ipol ; t0 = mathutil::gettimeofday_sec() ; call_ggridsd( xypos, spectra, nvispol, nchan_, flagtra, rflag, weight, nrow_, irow, gdataArrC, gwgtArr, gnx, gny, npol_, nchan_, convSupport_, convSampling_, convFunc, chanMap, polMap ) ; t1 = mathutil::gettimeofday_sec() ; eGGridSD += t1-t0 ; } } os << "initPol: elapsed time is " << eInitPol << " sec." << LogIO::POST ; os << "getData: elapsed time is " << eGetData-eToInt-eGetWeight << " sec." << LogIO::POST ; os << "toPixel: elapsed time is " << eToPixel << " sec." << LogIO::POST ; os << "ggridsd: elapsed time is " << eGGridSD << " sec." << LogIO::POST ; os << "toInt: elapsed time is " << eToInt << " sec." << LogIO::POST ; os << "getWeight: elapsed time is " << eGetWeight << " sec." << LogIO::POST ; // delete maps delete polMap ; delete chanMap ; setData( gdataArrC, gwgtArr ) ; // os << "gdataArr = " << gdataArr << LogIO::POST ; // os << "gwgtArr = " << gwgtArr << LogIO::POST ; // os << "data_ " << data_ << LogIO::POST ; } void STGrid::initPol( Int ipol ) { LogIO os( LogOrigin("STGrid","initPol",WHERE) ) ; if ( npolOrg_ == 1 ) { os << "single polarization data." << LogIO::POST ; ptab_ = tab_ ; } else ptab_ = tab_( tab_.col("POLNO") == (uInt)ipol ) ; attach( ptab_ ) ; } void STGrid::initTable( uInt idx ) { tab_ = tableList_[idx] ; nrow_ = rows_[idx] ; } void STGrid::setData( Array &gdata, Array &gwgt ) { // 2011/12/20 TN // gwgt and data_ share storage LogIO os( LogOrigin("STGrid","setData",WHERE) ) ; double t0, t1 ; t0 = mathutil::gettimeofday_sec() ; uInt len = data_.nelements() ; const Complex *w1_p ; Float *w2_p ; Bool b1, b2 ; const Complex *gdata_p = gdata.getStorage( b1 ) ; Float *gwgt_p = data_.getStorage( b2 ) ; w1_p = gdata_p ; w2_p = gwgt_p ; for ( uInt i = 0 ; i < len ; i++ ) { if ( *w2_p > 0.0 ) *w2_p = (*w1_p).real() / *w2_p ; w1_p++ ; w2_p++ ; } gdata.freeStorage( gdata_p, b1 ) ; data_.putStorage( gwgt_p, b2 ) ; t1 = mathutil::gettimeofday_sec() ; os << "setData: elapsed time is " << t1-t0 << " sec." << LogIO::POST ; } void STGrid::setupGrid() { Double xmin,xmax,ymin,ymax ; mapExtent( xmin, xmax, ymin, ymax ) ; setupGrid( nxUI_, nyUI_, cellxUI_, cellyUI_, xmin, xmax, ymin, ymax, centerUI_ ) ; } void STGrid::setupGrid( Int &nx, Int &ny, String &cellx, String &celly, Double &xmin, Double &xmax, Double &ymin, Double &ymax, String ¢er ) { LogIO os( LogOrigin("STGrid","setupGrid",WHERE) ) ; //cout << "nx=" << nx << ", ny=" << ny << endl ; // center position if ( center.size() == 0 ) { center_(0) = 0.5 * ( xmin + xmax ) ; center_(1) = 0.5 * ( ymin + ymax ) ; } else { String::size_type pos0 = center.find( " " ) ; if ( pos0 == String::npos ) { throw AipsError( "bad string format in parameter center" ) ; } String::size_type pos1 = center.find( " ", pos0+1 ) ; String typestr, xstr, ystr ; if ( pos1 != String::npos ) { typestr = center.substr( 0, pos0 ) ; xstr = center.substr( pos0+1, pos1-pos0 ) ; ystr = center.substr( pos1+1 ) ; // todo: convert to J2000 (or direction ref for DIRECTION column) } else { typestr = "J2000" ; xstr = center.substr( 0, pos0 ) ; ystr = center.substr( pos0+1 ) ; } QuantumHolder qh ; String err ; qh.fromString( err, xstr ) ; Quantum xcen = qh.asQuantumDouble() ; qh.fromString( err, ystr ) ; Quantum ycen = qh.asQuantumDouble() ; center_(0) = xcen.getValue( "rad" ) ; center_(1) = ycen.getValue( "rad" ) ; } nx_ = nx ; ny_ = ny ; if ( nx < 0 && ny > 0 ) { nx_ = ny ; ny_ = ny ; } if ( ny < 0 && nx > 0 ) { nx_ = nx ; ny_ = nx ; } //Double wx = xmax - xmin ; //Double wy = ymax - ymin ; Double wx = max( abs(xmax-center_(0)), abs(xmin-center_(0)) ) * 2 ; Double wy = max( abs(ymax-center_(1)), abs(ymin-center_(1)) ) * 2 ; // take 10% margin wx *= 1.10 ; wy *= 1.10 ; Quantum qcellx ; Quantum qcelly ; //cout << "nx_ = " << nx_ << ", ny_ = " << ny_ << endl ; if ( cellx.size() != 0 && celly.size() != 0 ) { readQuantity( qcellx, cellx ) ; readQuantity( qcelly, celly ) ; } else if ( celly.size() != 0 ) { os << "Using celly to x-axis..." << LogIO::POST ; readQuantity( qcelly, celly ) ; qcellx = qcelly ; } else if ( cellx.size() != 0 ) { os << "Using cellx to y-axis..." << LogIO::POST ; readQuantity( qcellx, cellx ) ; qcelly = qcellx ; } else { if ( nx_ < 0 ) { os << "No user preference in grid setting. Using default..." << LogIO::POST ; readQuantity( qcellx, "1.0arcmin" ) ; qcelly = qcellx ; } else { if ( wx == 0.0 ) { os << "Using default spatial extent (10arcmin) in x" << LogIO::POST ; wx = 0.00290888 ; } if ( wy == 0.0 ) { os << "Using default spatial extent (10arcmin) in y" << LogIO::POST ; wy = 0.00290888 ; } qcellx = Quantum( wx/nx_, "rad" ) ; qcelly = Quantum( wy/ny_, "rad" ) ; } } cellx_ = qcellx.getValue( "rad" ) ; celly_ = qcelly.getValue( "rad" ) ; if ( nx_ < 0 ) { if ( wx == 0.0 ) { os << "Using default spatial extent (10arcmin) in x" << LogIO::POST ; wx = 0.00290888 ; } if ( wy == 0.0 ) { os << "Using default spatial extent (10arcmin) in y" << LogIO::POST ; wy = 0.00290888 ; } nx_ = Int( ceil( wx/cellx_ ) ) ; ny_ = Int( ceil( wy/celly_ ) ) ; } } void STGrid::mapExtent( Double &xmin, Double &xmax, Double &ymin, Double &ymax ) { //LogIO os( LogOrigin("STGrid","mapExtent",WHERE) ) ; directionCol_.attach( tableList_[0], "DIRECTION" ) ; Matrix direction = directionCol_.getColumn() ; //os << "dirCol.nrow() = " << dirCol.nrow() << LogIO::POST ; minMax( xmin, xmax, direction.row( 0 ) ) ; minMax( ymin, ymax, direction.row( 1 ) ) ; Double amin, amax, bmin, bmax ; for ( uInt i = 1 ; i < nfile_ ; i++ ) { directionCol_.attach( tableList_[i], "DIRECTION" ) ; direction.assign( directionCol_.getColumn() ) ; //os << "dirCol.nrow() = " << dirCol.nrow() << LogIO::POST ; minMax( amin, amax, direction.row( 0 ) ) ; minMax( bmin, bmax, direction.row( 1 ) ) ; xmin = min( xmin, amin ) ; xmax = max( xmax, amax ) ; ymin = min( ymin, bmin ) ; ymax = max( ymax, bmax ) ; } //os << "(xmin,xmax)=(" << xmin << "," << xmax << ")" << LogIO::POST ; //os << "(ymin,ymax)=(" << ymin << "," << ymax << ")" << LogIO::POST ; } void STGrid::selectData() { LogIO os( LogOrigin("STGrid","selectData",WHERE) ) ; Int ifno = ifno_ ; tableList_.resize( nfile_ ) ; for ( uInt i = 0 ; i < nfile_ ; i++ ) { Table taborg( infileList_[i] ) ; if ( ifno == -1 ) { ROScalarColumn ifnoCol( taborg, "IFNO" ) ; ifno = ifnoCol( 0 ) ; os << LogIO::WARN << "IFNO is not given. Using default IFNO: " << ifno << LogIO::POST ; } TableExprNode node ; if ( isMultiIF( taborg ) ) { os << "apply selection on IFNO" << LogIO::POST ; node = taborg.col("IFNO") == ifno ; } if ( scanlist_.size() > 0 ) { os << "apply selection on SCANNO" << LogIO::POST ; node = node && taborg.col("SCANNO").in( scanlist_ ) ; } if ( node.isNull() ) { tableList_[i] = taborg ; } else { tableList_[i] = taborg( node ) ; } if ( tableList_[i].nrow() == 0 ) { os << LogIO::SEVERE << "No corresponding rows for given selection: IFNO " << ifno ; if ( scanlist_.size() > 0 ) os << " SCANNO " << scanlist_ ; os << LogIO::EXCEPTION ; } } } Bool STGrid::isMultiIF( Table &tab ) { ROScalarColumn ifnoCol( tab, "IFNO" ) ; Vector ifnos = ifnoCol.getColumn() ; return anyNE( ifnos, ifnos[0] ) ; } void STGrid::attach( Table &tab ) { // attach to table spectraCol_.attach( tab, "SPECTRA" ) ; flagtraCol_.attach( tab, "FLAGTRA" ) ; directionCol_.attach( tab, "DIRECTION" ) ; flagRowCol_.attach( tab, "FLAGROW" ) ; tsysCol_.attach( tab, "TSYS" ) ; intervalCol_.attach( tab, "INTERVAL" ) ; } void STGrid::getDataPerPol( Array &spectra, Array &direction, Array &flagtra, Array &rflag, Array &weight ) { LogIO os( LogOrigin("STGrid","getDataPerPol",WHERE) ) ; // 2011/12/22 TN // weight and tsys shares its storage Array tsys( weight ) ; Array tint( rflag.shape() ) ; Vector rflagVec( rflag ) ; Vector tintVec( tint ) ; spectraCol_.getColumn( spectra ) ; flagtraCol_.getColumn( flagtra ) ; flagRowCol_.getColumn( rflagVec ) ; directionCol_.getColumn( direction ) ; intervalCol_.getColumn( tintVec ) ; Vector tsysTemp = tsysCol_( 0 ) ; if ( tsysTemp.nelements() == (uInt)nchan_ ) { tsysCol_.getColumn( tsys ) ; } else { tsys = tsysTemp[0] ; } double t0,t1 ; t0 = mathutil::gettimeofday_sec() ; getWeight( weight, tsys, tint ) ; t1 = mathutil::gettimeofday_sec() ; eGetWeight += t1-t0 ; } void STGrid::getDataPerPol( Array &spectra, Array &direction, Array &flagtra, Array &rflag, Array &weight ) { LogIO os( LogOrigin("STGrid","getDataPerPol",WHERE) ) ; double t0, t1 ; Array flagUC( flagtra.shape() ) ; Array rflagUI( rflag.shape() ) ; Array spectraF( spectra.shape() ) ; getDataPerPol( spectraF, direction, flagUC, rflagUI, weight ) ; convertArray( spectra, spectraF ) ; t0 = mathutil::gettimeofday_sec() ; toInt( flagUC, flagtra ) ; toInt( rflagUI, rflag ) ; t1 = mathutil::gettimeofday_sec() ; eToInt += t1-t0 ; //os << "toInt: elapsed time is " << t1-t0 << " sec." << LogIO::POST ; } Int STGrid::getDataChunk( Array &spectra, Array &direction, Array &flagtra, Array &rflag, Array &weight ) { LogIO os( LogOrigin("STGrid","getDataChunk",WHERE) ) ; Int nrow = getDataChunk( spectraF_, direction, flagtraUC_, rflagUI_, weight ) ; if ( nrow < nchunk_ ) { spectra.resize( spectraF_.shape() ) ; flagtra.resize( flagtraUC_.shape() ) ; rflag.resize( rflagUI_.shape() ) ; } double t0, t1 ; t0 = mathutil::gettimeofday_sec() ; convertArray( spectra, spectraF_ ) ; toInt( flagtraUC_, flagtra ) ; toInt( rflagUI_, rflag ) ; t1 = mathutil::gettimeofday_sec() ; eToInt = t1 - t0 ; return nrow ; } Int STGrid::getDataChunk( Array &spectra, Array &direction, Array &flagtra, Array &rflag, Array &weight ) { LogIO os( LogOrigin("STGrid","getDataChunk",WHERE) ) ; Int nrow = spectra.shape()[1] ; Int remainingRow = nrow_ - nprocessed_ ; if ( remainingRow < nrow ) { nrow = remainingRow ; IPosition mshape( 2, nchan_, nrow ) ; IPosition vshape( 1, nrow ) ; spectra.resize( mshape ) ; flagtra.resize( mshape ) ; direction.resize( IPosition(2,2,nrow) ) ; rflag.resize( vshape ) ; weight.resize( mshape ) ; } // 2011/12/22 TN // tsys shares its storage with weight Array tsys( weight ) ; Array tint( rflag.shape() ) ; Vector rflagVec( rflag ) ; Vector tintVec( tint ) ; RefRows rows( nprocessed_, nprocessed_+nrow-1, 1 ) ; //os< polnoCol( tableList_[0], "POLNO" ) ; Vector pols = polnoCol.getColumn() ; //os << pols << LogIO::POST ; Vector pollistOrg ; npolOrg_ = 0 ; uInt polno ; for ( uInt i = 0 ; i < polnoCol.nrow() ; i++ ) { polno = pols( i ) ; if ( allNE( pollistOrg, polno ) ) { pollistOrg.resize( npolOrg_+1, True ) ; pollistOrg[npolOrg_] = polno ; npolOrg_++ ; } } if ( pollist_.size() == 0 ) pollist_ = pollistOrg ; else { Vector newlist ; uInt newsize = 0 ; for ( uInt i = 0 ; i < pollist_.size() ; i++ ) { if ( anyEQ( pollistOrg, pollist_[i] ) ) { newlist.resize( newsize+1, True ) ; newlist[newsize] = pollist_[i] ; newsize++ ; } } pollist_.assign( newlist ) ; } npol_ = pollist_.size() ; if ( npol_ == 0 ) { os << LogIO::SEVERE << "Empty pollist" << LogIO::EXCEPTION ; } rows_.resize( nfile_ ) ; for ( uInt i = 0 ; i < nfile_ ; i++ ) { rows_[i] = tableList_[i].nrow() / npolOrg_ ; } flagtraCol_.attach( tableList_[0], "FLAGTRA" ) ; nchan_ = flagtraCol_( 0 ).nelements() ; // os << "npol_ = " << npol_ << "(" << pollist_ << ")" << endl // << "nchan_ = " << nchan_ << endl // << "nrow_ = " << nrow_ << LogIO::POST ; } void STGrid::getWeight( Array &w, Array &tsys, Array &tint ) { LogIO os( LogOrigin("STGrid","getWeight",WHERE) ) ; // 2011/12/22 TN // w (weight) and tsys share storage IPosition refShape = tsys.shape() ; Int nchan = refShape[0] ; Int nrow = refShape[1] ; // os << "nchan=" << nchan << ", nrow=" << nrow << LogIO::POST ; // os << "w.shape()=" << w.shape() << endl // << "tsys.shape()=" << tsys.shape() << endl // << "tint.shape()=" << tint.shape() << LogIO::POST ; // set weight if ( wtype_.compare( "UNIFORM" ) == 0 ) { w = 1.0 ; } else if ( wtype_.compare( "TINT" ) == 0 ) { Bool b0, b1 ; Float *w_p = w.getStorage( b0 ) ; Float *w0_p = w_p ; const Double *ti_p = tint.getStorage( b1 ) ; const Double *w1_p = ti_p ; for ( Int irow = 0 ; irow < nrow ; irow++ ) { for ( Int ichan = 0 ; ichan < nchan ; ichan++ ) { *w0_p = *w1_p ; w0_p++ ; } w1_p++ ; } w.putStorage( w_p, b0 ) ; tint.freeStorage( ti_p, b1 ) ; } else if ( wtype_.compare( "TSYS" ) == 0 ) { Bool b0 ; Float *w_p = w.getStorage( b0 ) ; Float *w0_p = w_p ; for ( Int irow = 0 ; irow < nrow ; irow++ ) { for ( Int ichan = 0 ; ichan < nchan ; ichan++ ) { Float temp = *w0_p ; *w0_p = 1.0 / ( temp * temp ) ; w0_p++ ; } } w.putStorage( w_p, b0 ) ; } else if ( wtype_.compare( "TINTSYS" ) == 0 ) { Bool b0, b1 ; Float *w_p = w.getStorage( b0 ) ; Float *w0_p = w_p ; const Double *ti_p = tint.getStorage( b1 ) ; const Double *w1_p = ti_p ; for ( Int irow = 0 ; irow < nrow ; irow++ ) { Float interval = *w1_p ; for ( Int ichan = 0 ; ichan < nchan ; ichan++ ) { Float temp = *w0_p ; *w0_p = interval / ( temp * temp ) ; w0_p++ ; } w1_p++ ; } w.putStorage( w_p, b0 ) ; tint.freeStorage( ti_p, b1 ) ; } else { //LogIO os( LogOrigin("STGrid", "getWeight", WHERE) ) ; //os << LogIO::WARN << "Unsupported weight type '" << wtype_ << "', apply UNIFORM weight" << LogIO::POST ; w = 1.0 ; } } void STGrid::toInt( Array &u, Array &v ) { uInt len = u.nelements() ; Int *int_p = new Int[len] ; Bool deleteIt ; const uChar *data_p = u.getStorage( deleteIt ) ; Int *i_p = int_p ; const uChar *u_p = data_p ; for ( uInt i = 0 ; i < len ; i++ ) { *i_p = ( *u_p == 0 ) ? 0 : 1 ; i_p++ ; u_p++ ; } u.freeStorage( data_p, deleteIt ) ; v.takeStorage( u.shape(), int_p, TAKE_OVER ) ; } void STGrid::toInt( Array &u, Array &v ) { uInt len = u.nelements() ; Int *int_p = new Int[len] ; Bool deleteIt ; const uInt *data_p = u.getStorage( deleteIt ) ; Int *i_p = int_p ; const uInt *u_p = data_p ; for ( uInt i = 0 ; i < len ; i++ ) { *i_p = ( *u_p == 0 ) ? 0 : 1 ; i_p++ ; u_p++ ; } u.freeStorage( data_p, deleteIt ) ; v.takeStorage( u.shape(), int_p, TAKE_OVER ) ; } void STGrid::toPixel( Array &world, Array &pixel ) { // gridding will be done on (nx_+2*convSupport_) x (ny_+2*convSupport_) // grid plane to avoid unexpected behavior on grid edge Block pixc( 2 ) ; pixc[0] = Double( nx_-1 ) * 0.5 ; pixc[1] = Double( ny_-1 ) * 0.5 ; // pixc[0] = Double( nx_+2*convSupport_-1 ) * 0.5 ; // pixc[1] = Double( ny_+2*convSupport_-1 ) * 0.5 ; uInt nrow = world.shape()[1] ; Bool bw, bp ; const Double *w_p = world.getStorage( bw ) ; Double *p_p = pixel.getStorage( bp ) ; const Double *ww_p = w_p ; Double *wp_p = p_p ; for ( uInt i = 0 ; i < nrow ; i++ ) { *wp_p = pixc[0] + ( *ww_p - center_[0] ) / cellx_ ; wp_p++ ; ww_p++ ; *wp_p = pixc[1] + ( *ww_p - center_[1] ) / celly_ ; wp_p++ ; ww_p++ ; } world.freeStorage( w_p, bw ) ; pixel.putStorage( p_p, bp ) ; // String gridfile = "grid."+convType_+"."+String::toString(convSupport_)+".dat" ; // ofstream ofs( gridfile.c_str(), ios::out ) ; // ofs << "center " << center_(0) << " " << pixc(0) // << " " << center_(1) << " " << pixc(1) << endl ; // for ( uInt irow = 0 ; irow < nrow ; irow++ ) { // ofs << irow ; // for ( uInt i = 0 ; i < 2 ; i++ ) { // ofs << " " << world(i, irow) << " " << pixel(i, irow) ; // } // ofs << endl ; // } // ofs.close() ; } void STGrid::boxFunc( Vector &convFunc, Int &convSize ) { convFunc = 0.0 ; for ( Int i = 0 ; i < convSize/2 ; i++ ) convFunc(i) = 1.0 ; } #define NEED_UNDERSCORES #if defined(NEED_UNDERSCORES) #define grdsf grdsf_ #endif extern "C" { void grdsf(Double*, Double*); } void STGrid::spheroidalFunc( Vector &convFunc ) { convFunc = 0.0 ; for ( Int i = 0 ; i < convSampling_*convSupport_ ; i++ ) { Double nu = Double(i) / Double(convSupport_*convSampling_) ; Double val ; grdsf( &nu, &val ) ; convFunc(i) = ( 1.0 - nu * nu ) * val ; } } void STGrid::gaussFunc( Vector &convFunc ) { convFunc = 0.0 ; // HWHM of the Gaussian is convSupport_ / 4 // To take into account Gaussian tail, kernel cutoff is set to 4 * HWHM Int len = convSampling_ * convSupport_ ; Double hwhm = len * 0.25 ; for ( Int i = 0 ; i < len ; i++ ) { Double val = Double(i) / hwhm ; convFunc(i) = exp( -log(2)*val*val ) ; } } void STGrid::pbFunc( Vector &convFunc ) { convFunc = 0.0 ; } void STGrid::setConvFunc( Vector &convFunc ) { convSupport_ = userSupport_ ; if ( convType_ == "BOX" ) { if ( convSupport_ < 0 ) convSupport_ = 0 ; Int convSize = convSampling_ * ( 2 * convSupport_ + 2 ) ; convFunc.resize( convSize ) ; boxFunc( convFunc, convSize ) ; } else if ( convType_ == "SF" ) { if ( convSupport_ < 0 ) convSupport_ = 3 ; Int convSize = convSampling_ * ( 2 * convSupport_ + 2 ) ; convFunc.resize( convSize ) ; spheroidalFunc( convFunc ) ; } else if ( convType_ == "GAUSS" ) { // to take into account Gaussian tail if ( convSupport_ < 0 ) convSupport_ = 12 ; // 3 * 4 else { convSupport_ = userSupport_ * 4 ; } Int convSize = convSampling_ * ( 2 * convSupport_ + 2 ) ; convFunc.resize( convSize ) ; gaussFunc( convFunc ) ; } else if ( convType_ == "PB" ) { if ( convSupport_ < 0 ) convSupport_ = 0 ; pbFunc( convFunc ) ; } else { throw AipsError( "Unsupported convolution function" ) ; } } string STGrid::saveData( string outfile ) { LogIO os( LogOrigin("STGrid", "saveData", WHERE) ) ; double t0, t1 ; t0 = mathutil::gettimeofday_sec() ; String outfile_ ; if ( outfile.size() == 0 ) { if ( infileList_[0].lastchar() == '/' ) { outfile_ = infileList_[0].substr( 0, infileList_[0].size()-1 ) ; } else { outfile_ = infileList_[0] ; } outfile_ += ".grid" ; } else { outfile_ = outfile ; } Table tab ; prepareTable( tab, outfile_ ) ; IPosition dshape = data_.shape() ; Int nrow = nx_ * ny_ * npol_ ; tab.rwKeywordSet().define( "nPol", npol_ ) ; tab.addRow( nrow ) ; Vector cpix( 2 ) ; cpix(0) = Double( nx_ - 1 ) * 0.5 ; cpix(1) = Double( ny_ - 1 ) * 0.5 ; Vector dir( 2 ) ; ArrayColumn directionCol( tab, "DIRECTION" ) ; ArrayColumn spectraCol( tab, "SPECTRA" ) ; ScalarColumn polnoCol( tab, "POLNO" ) ; Int irow = 0 ; Vector sp( nchan_ ) ; Bool bsp, bdata ; const Float *data_p = data_.getStorage( bdata ) ; Float *wsp_p, *sp_p ; const Float *wdata_p = data_p ; long step = nx_ * ny_ * npol_ ; long offset ; for ( Int iy = 0 ; iy < ny_ ; iy++ ) { dir(1) = center_(1) - ( cpix(1) - (Double)iy ) * celly_ ; for ( Int ix = 0 ; ix < nx_ ; ix++ ) { dir(0) = center_(0) - ( cpix(0) - (Double)ix ) * cellx_ ; for ( Int ipol = 0 ; ipol < npol_ ; ipol++ ) { offset = ix + iy * nx_ + ipol * nx_ * ny_ ; //os << "offset = " << offset << LogIO::POST ; sp_p = sp.getStorage( bsp ) ; wsp_p = sp_p ; wdata_p = data_p + offset ; for ( Int ichan = 0 ; ichan < nchan_ ; ichan++ ) { *wsp_p = *wdata_p ; wsp_p++ ; wdata_p += step ; } sp.putStorage( sp_p, bsp ) ; spectraCol.put( irow, sp ) ; directionCol.put( irow, dir ) ; polnoCol.put( irow, pollist_[ipol] ) ; irow++ ; } } } data_.freeStorage( data_p, bdata ) ; t1 = mathutil::gettimeofday_sec() ; os << "saveData: elapsed time is " << t1-t0 << " sec." << LogIO::POST ; return outfile_ ; } void STGrid::prepareTable( Table &tab, String &name ) { Table t( infileList_[0], Table::Old ) ; t.deepCopy( name, Table::New, False, t.endianFormat(), True ) ; tab = Table( name, Table::Update ) ; } }