LCOV - code coverage report
Current view: top level - components/ComponentModels - TwoSidedShape.cc (source / functions) Hit Total Coverage
Test: casacpp_coverage.info Lines: 0 455 0.0 %
Date: 2024-10-10 19:51:30 Functions: 0 37 0.0 %

          Line data    Source code
       1             : //# TwoSidedShape.cc:
       2             : //# Copyright (C) 1999,2000,2001,2002
       3             : //# Associated Universities, Inc. Washington DC, USA.
       4             : //#
       5             : //# This library is free software; you can redistribute it and/or modify it
       6             : //# under the terms of the GNU Library General Public License as published by
       7             : //# the Free Software Foundation; either version 2 of the License, or (at your
       8             : //# option) any later version.
       9             : //#
      10             : //# This library is distributed in the hope that it will be useful, but WITHOUT
      11             : //# ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
      12             : //# FITNESS FOR A PARTICULAR PURPOSE.  See the GNU Library General Public
      13             : //# License for more details.
      14             : //#
      15             : //# You should have received a copy of the GNU Library General Public License
      16             : //# along with this library; if not, write to the Free Software Foundation,
      17             : //# Inc., 675 Massachusetts Ave, Cambridge, MA 02139, USA.
      18             : //#
      19             : //# Correspondence concerning AIPS++ should be addressed as follows:
      20             : //#        Internet email: casa-feedback@nrao.edu.
      21             : //#        Postal address: AIPS++ Project Office
      22             : //#                        National Radio Astronomy Observatory
      23             : //#                        520 Edgemont Road
      24             : //#                        Charlottesville, VA 22903-2475 USA
      25             : //#
      26             : //# $Id: TwoSidedShape.cc 21292 2012-11-28 14:58:19Z gervandiepen $
      27             : 
      28             : #include <components/ComponentModels/TwoSidedShape.h>
      29             : #include <iomanip>
      30             : #include <casacore/casa/Arrays/Vector.h>
      31             : #include <casacore/casa/Arrays/ArrayLogical.h>
      32             : #include <casacore/casa/Containers/Record.h>
      33             : #include <casacore/casa/Containers/RecordFieldId.h>
      34             : #include <casacore/casa/Containers/RecordInterface.h>
      35             : #include <casacore/coordinates/Coordinates/DirectionCoordinate.h>
      36             : #include <casacore/casa/Exceptions/Error.h>
      37             : #include <casacore/casa/Logging/LogIO.h>
      38             : #include <casacore/casa/Logging/LogOrigin.h>
      39             : #include <casacore/casa/BasicSL/Constants.h>
      40             : #include <casacore/casa/BasicMath/Math.h>
      41             : #include <casacore/casa/Quanta/Quantum.h>
      42             : #include <casacore/casa/Quanta/QuantumHolder.h>
      43             : #include <casacore/casa/Quanta/MVAngle.h>
      44             : #include <casacore/casa/Utilities/Assert.h>
      45             : #include <casacore/casa/Utilities/Precision.h>
      46             : #include <casacore/casa/BasicSL/String.h>
      47             : 
      48             : using namespace casacore;
      49             : namespace casa { //# NAMESPACE CASA - BEGIN
      50             : 
      51           0 : TwoSidedShape::~TwoSidedShape() {
      52           0 :   DebugAssert(ok(), AipsError);
      53           0 : }
      54             : 
      55           0 : TwoSidedShape& TwoSidedShape::operator=(const TwoSidedShape& other) {
      56           0 :   if (this != &other) {
      57           0 :     ComponentShape::operator=(other);
      58           0 :     itsMajUnit = other.itsMajUnit;
      59           0 :     itsMinUnit = other.itsMinUnit;
      60           0 :     itsPaUnit = other.itsPaUnit;
      61           0 :     itsMajErr = other.itsMajErr;
      62           0 :     itsMinErr = other.itsMinErr;
      63           0 :     itsPaErr = other.itsPaErr;
      64             :   }
      65           0 :   DebugAssert(ok(), AipsError);
      66           0 :   return *this;
      67             : }
      68             : 
      69           0 : void TwoSidedShape::setWidth(const Quantity& majorAxis,
      70             :                              const Quantity& minorAxis,
      71             :                              const Quantity& positionAngle) {
      72           0 :   itsMajUnit = majorAxis.getFullUnit();
      73           0 :   itsMinUnit = minorAxis.getFullUnit();
      74           0 :   itsPaUnit = positionAngle.getFullUnit();
      75           0 :   const Unit rad("rad");
      76           0 :   setWidthInRad(majorAxis.getValue(rad), minorAxis.getValue(rad), 
      77             :                 positionAngle.getValue(rad));
      78           0 :   DebugAssert(ok(), AipsError);
      79           0 : }
      80             : 
      81           0 : void TwoSidedShape::setWidth(const Quantum<Double>& majorAxis,
      82             :                              const Double axialRatio, 
      83             :                              const Quantum<Double>& positionAngle) {
      84           0 :   itsMinUnit = itsMajUnit = majorAxis.getFullUnit();
      85           0 :   itsPaUnit = positionAngle.getFullUnit();
      86           0 :   const Unit rad("rad");
      87           0 :   const Double majWidth = majorAxis.getValue(rad);
      88           0 :   setWidthInRad(majWidth, majWidth*axialRatio, positionAngle.getValue(rad));
      89           0 :   DebugAssert(ok(), AipsError);
      90           0 : }
      91             : 
      92           0 : Quantum<Double> TwoSidedShape::majorAxis() const {
      93           0 :   Quantum<Double> retVal(majorAxisInRad(), Unit("rad"));
      94           0 :   retVal.convert(itsMajUnit);
      95           0 :   return retVal;
      96           0 : }
      97             : 
      98           0 : Quantum<Double> TwoSidedShape::minorAxis() const {
      99           0 :   Quantum<Double> retVal(minorAxisInRad(), Unit("rad"));
     100           0 :   retVal.convert(itsMinUnit);
     101           0 :   return retVal;
     102           0 : }
     103             : 
     104           0 : Quantum<Double> TwoSidedShape::positionAngle() const {
     105           0 :   Quantum<Double> retVal(positionAngleInRad(), Unit("rad"));
     106           0 :   retVal.convert(itsPaUnit);
     107           0 :   return retVal;
     108           0 : }
     109             : 
     110           0 : Double TwoSidedShape::axialRatio() const {
     111           0 :   return minorAxisInRad()/majorAxisInRad();
     112             : }
     113             : 
     114           0 : void TwoSidedShape::setErrors(const Quantum<Double>& majorAxisError,
     115             :                               const Quantum<Double>& minorAxisError, 
     116             :                               const Quantum<Double>& positionAngleError) {
     117           0 :   if (ComponentShape::badError(majorAxisError) || 
     118           0 :       ComponentShape::badError(minorAxisError) || 
     119           0 :       ComponentShape::badError(positionAngleError)) {
     120           0 :     LogIO logErr(LogOrigin("TwoSidedShape", "setErrors(...)"));
     121             :     logErr << "The errors must be non-negative angular quantities."
     122           0 :            << LogIO::EXCEPTION;
     123           0 :   }
     124           0 :   itsMajErr = majorAxisError;
     125           0 :   itsMinErr = minorAxisError;
     126           0 :   itsPaErr = positionAngleError;
     127           0 : }
     128             : 
     129           0 : const Quantum<Double>& TwoSidedShape::majorAxisError() const {
     130           0 :   return itsMajErr;
     131             : }
     132             : 
     133           0 : const Quantum<Double>& TwoSidedShape::minorAxisError() const {
     134           0 :   return itsMinErr;
     135             : }
     136             : 
     137           0 : const Quantum<Double>& TwoSidedShape::positionAngleError() const {
     138           0 :   return itsPaErr;
     139             : }
     140             : 
     141           0 : Double TwoSidedShape::axialRatioError() const {
     142           0 :   const Unit rad("rad");
     143           0 :   const Double relErr = itsMajErr.getValue(rad)/majorAxisInRad() + 
     144           0 :     itsMinErr.getValue(rad)/minorAxisInRad();
     145           0 :   return axialRatio() * relErr;
     146           0 : }
     147             : 
     148           0 : void TwoSidedShape::sample(Vector<Double>& scale, 
     149             :                            const Vector<MDirection::MVType>& directions, 
     150             :                            const MDirection::Ref& refFrame,
     151             :                            const MVAngle& pixelLatSize,
     152             :                            const MVAngle& pixelLongSize) const {
     153           0 :   ComponentShape::sample(scale, directions, refFrame, pixelLatSize,
     154             :                          pixelLongSize);
     155           0 : }
     156             : 
     157           0 : void TwoSidedShape::visibility(Vector<DComplex>& scale,
     158             :                                const Matrix<Double>& uvw,
     159             :                                const Double& frequency) const {
     160           0 :   ComponentShape::visibility(scale, uvw, frequency);
     161           0 : }
     162             : 
     163           0 : void TwoSidedShape::visibility(Matrix<DComplex>& scale,
     164             :                                const Matrix<Double>& uvw,
     165             :                                const Vector<Double>& frequency) const {
     166           0 :   ComponentShape::visibility(scale, uvw, frequency);
     167           0 : }
     168             : 
     169           0 : Bool TwoSidedShape::isSymmetric() const {
     170           0 :   DebugAssert(ok(), AipsError);
     171           0 :   return true;
     172             : }
     173             : 
     174           0 : uInt TwoSidedShape::nParameters() const {
     175           0 :   DebugAssert(ok(), AipsError);
     176           0 :   return 3;
     177             : }
     178             : 
     179           0 : void TwoSidedShape::setParameters(const Vector<Double>& newParms) {
     180           0 :   DebugAssert(newParms.nelements() == nParameters(), AipsError);
     181           0 :   DebugAssert(newParms(0) >= newParms(1), AipsError);
     182           0 :   DebugAssert(abs(newParms(2)) <= C::_2pi, AipsError);
     183           0 :   setWidthInRad(newParms(0), newParms(1), newParms(2));
     184           0 :   DebugAssert(ok(), AipsError);
     185           0 : }
     186             : 
     187           0 : Vector<Double> TwoSidedShape::parameters() const {
     188           0 :   DebugAssert(ok(), AipsError);
     189           0 :   Vector<Double> compParms(3);
     190           0 :   compParms(0) = majorAxisInRad();
     191           0 :   compParms(1) = minorAxisInRad();
     192           0 :   compParms(2) = positionAngleInRad();
     193           0 :   return compParms;
     194           0 : }
     195             : 
     196           0 : void TwoSidedShape::setErrors(const Vector<Double>& newErrors) {
     197           0 :   DebugAssert(newErrors.nelements() == nParameters(), AipsError);
     198           0 :   DebugAssert(allGE(newErrors, 0.0), AipsError);
     199           0 :   const Unit rad("rad");
     200           0 :   itsMajErr.setValue(newErrors(0));
     201           0 :   itsMajErr.setUnit(rad);
     202           0 :   itsMinErr.setValue(newErrors(1));
     203           0 :   itsMinErr.setUnit(rad);
     204           0 :   itsPaErr.setValue(newErrors(2));
     205           0 :   itsPaErr.setUnit(rad);
     206           0 :   DebugAssert(ok(), AipsError);
     207           0 : }
     208             : 
     209           0 : Vector<Double> TwoSidedShape::errors() const {
     210           0 :   DebugAssert(ok(), AipsError);
     211           0 :   Vector<Double> compErrors(3);
     212           0 :   compErrors(0) = itsMajErr.getBaseValue();
     213           0 :   compErrors(1) = itsMinErr.getBaseValue();
     214           0 :   compErrors(2) = itsPaErr.getBaseValue();
     215           0 :   return compErrors;
     216           0 : }
     217             : 
     218           0 : Vector<Double> TwoSidedShape::optParameters() const {
     219           0 :   DebugAssert(ok(), AipsError);
     220           0 :   return Vector<Double>(0);
     221             : }
     222             : 
     223           0 : void TwoSidedShape::setOptParameters(const Vector<Double>& newOptParms){
     224           0 :   DebugAssert(ok(), AipsError);
     225             :   // squash compiler warning, maybe just get rid of DebugAssert statement
     226           0 :   if (newOptParms.empty()) {};
     227           0 : }
     228             : 
     229           0 : Bool TwoSidedShape::fromRecord(String& errorMessage,
     230             :                                const RecordInterface& record) {
     231           0 :   if (!ComponentShape::fromRecord(errorMessage, record)) return false;
     232           0 :   Quantum<Double> majorAxis, minorAxis, pa;
     233           0 :   if (!fromAngQRecord(majorAxis, errorMessage, "majoraxis", record) ||
     234           0 :       !fromAngQRecord(minorAxis, errorMessage, "minoraxis", record) ||
     235           0 :       !fromAngQRecord(pa, errorMessage, "positionangle", record)) {
     236           0 :     errorMessage += "Shape not changed\n";
     237           0 :     return false;
     238             :   }
     239           0 :   const Unit rad("rad");
     240           0 :   const Double majorAxisInRad = majorAxis.getValue(rad);
     241           0 :   const Double minorAxisInRad = minorAxis.getValue(rad);
     242             : //   // The near function is necessary for Intel processors (and doesn't hurt for
     243             : //   // other architectures) because of the extra precision that floating point
     244             : //   // variables have when returned in floating point registers. See
     245             : //   // http://aips2.nrao.edu/mail/aips2-lib/1101 for a discussion of this. The
     246             : //   // near function was added here and in the setMinorAxis function to fix
     247             : //   // defect AOCso00071
     248           0 :   if (majorAxisInRad < minorAxisInRad && 
     249           0 :       !near(minorAxisInRad, minorAxisInRad, 2*C::dbl_epsilon)) {
     250           0 :     errorMessage += "The major axis cannot be smaller than the minor axis\n";
     251           0 :     return false;
     252             :   }
     253           0 :   setWidth(majorAxis, minorAxis, pa);
     254           0 :   if (!fromAngQRecord(majorAxis, errorMessage, "majoraxiserror", record) ||
     255           0 :       !fromAngQRecord(minorAxis, errorMessage, "minoraxiserror", record) ||
     256           0 :       !fromAngQRecord(pa, errorMessage, "positionangleerror", record)) {
     257           0 :     errorMessage += "Shape errors not changed\n";
     258           0 :     return false;
     259             :   }
     260           0 :   setErrors(majorAxis, minorAxis, pa);
     261           0 :   DebugAssert(ok(), AipsError);
     262           0 :   return true;
     263           0 : }
     264             : 
     265           0 : Bool TwoSidedShape::toRecord(String& errorMessage,
     266             :                              RecordInterface& record) const {
     267           0 :   DebugAssert(ok(), AipsError);
     268           0 :   if (!ComponentShape::toRecord(errorMessage, record)) return false;
     269             :   {
     270           0 :     const QuantumHolder qHolder(majorAxis());
     271           0 :     Record qRecord;
     272           0 :     if (!qHolder.toRecord(errorMessage, qRecord)) {
     273           0 :       errorMessage += "Cannot convert the major axis to a record\n";
     274           0 :       return false;
     275             :     }
     276           0 :     record.defineRecord(RecordFieldId("majoraxis"), qRecord);
     277           0 :   }
     278             :   {
     279           0 :     const QuantumHolder qHolder(minorAxis());
     280           0 :     Record qRecord;
     281           0 :     if (!qHolder.toRecord(errorMessage, qRecord)) {
     282           0 :       errorMessage += "Cannot convert the minor axis to a record\n";
     283           0 :       return false;
     284             :     }
     285           0 :     record.defineRecord(RecordFieldId("minoraxis"), qRecord);
     286           0 :   }
     287             :   {
     288           0 :     const QuantumHolder qHolder(positionAngle());
     289           0 :     Record qRecord;
     290           0 :     if (!qHolder.toRecord(errorMessage, qRecord)) {
     291           0 :       errorMessage += "Cannot convert the position angle to a record\n";
     292           0 :       return false;
     293             :     }
     294           0 :     record.defineRecord(RecordFieldId("positionangle"), qRecord);
     295           0 :   }
     296             :   {
     297           0 :     const QuantumHolder qHolder(majorAxisError());
     298           0 :     Record qRecord;
     299           0 :     if (!qHolder.toRecord(errorMessage, qRecord)) {
     300           0 :       errorMessage += "Cannot convert the major axis error to a record\n";
     301           0 :       return false;
     302             :     }
     303           0 :     record.defineRecord(RecordFieldId("majoraxiserror"), qRecord);
     304           0 :   }
     305             :   {
     306           0 :     const QuantumHolder qHolder(minorAxisError());
     307           0 :     Record qRecord;
     308           0 :     if (!qHolder.toRecord(errorMessage, qRecord)) {
     309           0 :       errorMessage += "Cannot convert the minor axis error to a record\n";
     310           0 :       return false;
     311             :     }
     312           0 :     record.defineRecord(RecordFieldId("minoraxiserror"), qRecord);
     313           0 :   }
     314             :   {
     315           0 :     const QuantumHolder qHolder(positionAngleError());
     316           0 :     Record qRecord;
     317           0 :     if (!qHolder.toRecord(errorMessage, qRecord)) {
     318           0 :       errorMessage += "Cannot convert the position angle error to a record\n";
     319           0 :       return false;
     320             :     }
     321           0 :     record.defineRecord(RecordFieldId("positionangleerror"), qRecord);
     322           0 :   }
     323           0 :   return true;
     324             : }
     325             : 
     326           0 : Bool TwoSidedShape::convertUnit(String& errorMessage,
     327             :                                 const RecordInterface& record) {
     328           0 :   const Unit deg("deg");
     329             :   {
     330           0 :     const String fieldString("majoraxis");
     331           0 :     if (!record.isDefined(fieldString)) {
     332           0 :       errorMessage += "The 'majoraxis' field does not exist\n";
     333           0 :       return false;
     334             :     }
     335           0 :     const RecordFieldId field(fieldString);
     336           0 :     if (!((record.dataType(field) == TpString) && 
     337           0 :           (record.shape(field) == IPosition(1,1)))) {
     338           0 :       errorMessage += "The 'majoraxis' field must be a string\n";
     339           0 :       errorMessage += "(but not a vector of strings)\n";
     340           0 :       return false;
     341             :     }
     342           0 :     const Unit unit = Unit(record.asString(field));
     343           0 :     if (unit != deg) {
     344             :       errorMessage += 
     345           0 :         "Cannot convert the major axis width to a non angular unit";
     346           0 :       return false;
     347             :     }
     348           0 :     itsMajUnit = unit;
     349           0 :   }
     350             :   {
     351           0 :     const String fieldString("minoraxis");
     352           0 :     if (!record.isDefined(fieldString)) {
     353           0 :       errorMessage += "The 'minoraxis' field does not exist\n";
     354           0 :       return false;
     355             :     }
     356           0 :     const RecordFieldId field(fieldString);
     357           0 :     if (!((record.dataType(field) == TpString) && 
     358           0 :           (record.shape(field) == IPosition(1,1)))) {
     359           0 :       errorMessage += "The 'minoraxis' field must be a string\n";
     360           0 :       errorMessage += "(but not a vector of strings)\n";
     361           0 :       return false;
     362             :     }
     363           0 :     const Unit unit = Unit(record.asString(field));
     364           0 :     if (unit != deg) {
     365             :       errorMessage += 
     366           0 :         "Cannot convert the minor axis width to a non angular unit";
     367           0 :       return false;
     368             :     }
     369           0 :     itsMinUnit = unit;
     370           0 :   }
     371             :   {
     372           0 :     const String fieldString("positionangle");
     373           0 :     if (!record.isDefined(fieldString)) {
     374           0 :       errorMessage += "The 'positionangle' field does not exist\n";
     375           0 :       return false;
     376             :     }
     377           0 :     const RecordFieldId field(fieldString);
     378           0 :     if (!((record.dataType(field) == TpString) && 
     379           0 :           (record.shape(field) == IPosition(1,1)))) {
     380           0 :       errorMessage += "The 'positionangle' field must be a string\n";
     381           0 :       errorMessage += "(but not a vector of strings)\n";
     382           0 :       return false;
     383             :     }
     384           0 :     const Unit unit = Unit(record.asString(field));
     385           0 :     if (unit != deg) {
     386             :       errorMessage += 
     387           0 :         "Cannot convert the position angle to a non angular unit";
     388           0 :       return false;
     389             :     }
     390           0 :     itsPaUnit = unit;
     391           0 :   }
     392           0 :   DebugAssert(ok(), AipsError);
     393           0 :   return true;
     394           0 : }
     395             : 
     396           0 : Bool TwoSidedShape::ok() const {
     397             :   // The LogIO class is only constructed if an error is detected for
     398             :   // performance reasons. Both function static and file static variables
     399             :   // where considered and rejected for this purpose.
     400           0 :   if (!ComponentShape::ok()) return false;
     401           0 :   const Unit deg("deg");
     402           0 :   if (itsMajUnit != deg) {
     403           0 :     LogIO logErr(LogOrigin("TwoSidedCompRep", "ok()"));
     404             :     logErr << LogIO::SEVERE << "The major axis does not have angular units."
     405           0 :            << LogIO::POST;
     406           0 :     return false;
     407           0 :   }
     408           0 :   if (itsMinUnit != deg) {
     409           0 :     LogIO logErr(LogOrigin("TwoSidedCompRep", "ok()"));
     410             :     logErr << LogIO::SEVERE << "The minor axis does not have angular units."
     411           0 :            << LogIO::POST;
     412           0 :     return false;
     413           0 :   }
     414           0 :   if (itsPaUnit != deg) {
     415           0 :     LogIO logErr(LogOrigin("TwoSidedCompRep", "ok()"));
     416             :     logErr << LogIO::SEVERE <<"The position angle does not have angular units."
     417           0 :            << LogIO::POST;
     418           0 :     return false;
     419           0 :   }
     420           0 :   return true;
     421           0 : }
     422             : 
     423           0 : TwoSidedShape::TwoSidedShape()
     424             :   :ComponentShape(),
     425           0 :    itsMajUnit("arcmin"),
     426           0 :    itsMinUnit("arcmin"),
     427           0 :    itsPaUnit("deg"),
     428           0 :    itsMajErr(0, "arcmin"),
     429           0 :    itsMinErr(0, "arcmin"),
     430           0 :    itsPaErr(0, "deg")
     431             : {
     432           0 :   DebugAssert(ok(), AipsError);
     433           0 : }
     434             : 
     435           0 : TwoSidedShape::TwoSidedShape(const MDirection& direction, 
     436             :                              const Unit& majorAxisUnit,
     437             :                              const Unit& minorAxisUnit, 
     438           0 :                              const Unit& paUnit) 
     439             :   :ComponentShape(direction),
     440           0 :    itsMajUnit(majorAxisUnit),
     441           0 :    itsMinUnit(minorAxisUnit),
     442           0 :    itsPaUnit(paUnit),
     443           0 :    itsMajErr(0, "arcmin"),
     444           0 :    itsMinErr(0, "arcmin"),
     445           0 :    itsPaErr(0, "deg")
     446             : {
     447           0 : }
     448             : 
     449           0 : TwoSidedShape::TwoSidedShape(const TwoSidedShape& other) 
     450             :   :ComponentShape(other),
     451           0 :    itsMajUnit(other.itsMajUnit),
     452           0 :    itsMinUnit(other.itsMinUnit),
     453           0 :    itsPaUnit(other.itsPaUnit),
     454           0 :    itsMajErr(other.itsMajErr),
     455           0 :    itsMinErr(other.itsMinErr),
     456           0 :    itsPaErr(other.itsPaErr)
     457             : {
     458           0 :   DebugAssert(ok(), AipsError);
     459           0 : }
     460             : 
     461             : 
     462           0 : Vector<Double> TwoSidedShape::toPixel (const DirectionCoordinate& dirCoord)  const
     463             : //
     464             : // pars(0) = long cen   abs pix
     465             : // pars(1) = lat  cen   abs pix
     466             : // pars(2) = major   pix
     467             : // pars(3) = minor   pix
     468             : // pars(4) = pa radians;  pos +x (long) -> +y (lat)
     469             : //
     470             : {
     471           0 :    LogIO os(LogOrigin("TwoSidedShape", "toPixel"));
     472           0 :    Vector<Double> parameters(5);
     473             : 
     474             : // Do locations
     475             : 
     476           0 :    Vector<Double> pixelCen = ComponentShape::toPixel (dirCoord);
     477           0 :    parameters(0) = pixelCen(0);
     478           0 :    parameters(1) = pixelCen(1);
     479             : 
     480             : // Now convert the tip of the major axis to x/y pixel coordinates
     481             : 
     482           0 :    const MDirection dirRef = refDirection();
     483           0 :    Quantum<Double> majorWorld = majorAxis();
     484           0 :    Quantum<Double> paMajor = positionAngle();
     485           0 :    majorWorld.scale(0.5);
     486           0 :    Vector<Double> majorCart = widthToCartesian (majorWorld, paMajor, dirRef, dirCoord, pixelCen);
     487             : 
     488             : // Position angle of major axis.  
     489             : // atan2 gives pos +x (long) -> +y (lat).   put in range +/- pi
     490             :                                         
     491           0 :    MVAngle pa(atan2(majorCart(1), majorCart(0)));
     492           0 :    pa();
     493             : 
     494             : // I cannot just add 90deg to the world position angle. It is 90deg in the
     495             : // pixel coordinate frame, not the world frame.    So I have to work
     496             : // my way along the minor axis in pixel coordinates and locate
     497             : // the tip of the minor axis iteratively.  The algorithm
     498             : // below could be much smarter/faster with a binary search.
     499             : 
     500           0 :    Quantum<Double> minorWorld = minorAxis();
     501           0 :    Quantum<Double> paMinor = paMajor + Quantum<Double>(C::pi/2.0, Unit("rad"));
     502           0 :    minorWorld.scale(0.5);
     503             : //
     504           0 :    Double dX = sin(pa.radian());
     505           0 :    Double dY = cos(pa.radian());
     506             : //
     507           0 :    Vector<Double> posPix = pixelCen.copy();
     508           0 :    MDirection posWorld;
     509           0 :    MVDirection mvdRef = dirRef.getValue();
     510           0 :    Vector<Double> prevPosPix(2);
     511             : //
     512           0 :    Double minorWorldRad = minorWorld.getValue(Unit("rad"));
     513           0 :    Double sep = 0.0;
     514           0 :    Double prevSep = 0.0;
     515           0 :    Bool more = true;
     516           0 :    while (more) {
     517           0 :       dirCoord.toWorld(posWorld, posPix);
     518           0 :       MVDirection mvd = posWorld.getValue();
     519           0 :       sep = mvdRef.separation(mvd);
     520           0 :       if (sep > minorWorldRad) break;
     521             : //  
     522           0 :       prevPosPix = posPix;
     523           0 :       prevSep = sep;
     524             : //
     525           0 :       posPix(0) += dX;
     526           0 :       posPix(1) += dY;
     527           0 :    }
     528           0 :    Double frac = (minorWorldRad - prevSep) / (sep - prevSep);
     529           0 :    Double fracX = dX * frac;
     530           0 :    Double fracY = dY * frac;
     531             : //
     532           0 :    Vector<Double> minorCart(2);
     533           0 :    minorCart(0) = prevPosPix(0) + fracX - pixelCen(0);
     534           0 :    minorCart(1) = prevPosPix(1) + fracY - pixelCen(1);
     535             : //
     536           0 :    Double tmp1 =  2.0 * hypot(majorCart(0), majorCart(1));
     537           0 :    Double tmp2 =  2.0 * hypot(minorCart(0), minorCart(1));
     538             : //
     539           0 :    parameters(2) = max(tmp1,tmp2);
     540           0 :    parameters(3) = min(tmp1,tmp2);
     541           0 :    parameters(4) = pa.radian();
     542             : //
     543           0 :    return parameters;
     544           0 : }
     545             :  
     546           0 : Bool TwoSidedShape::fromPixel (const Vector<Double>& parameters,
     547             :                                const DirectionCoordinate& dirCoord)
     548             : //
     549             : // pars(0) = long cen   abs pix
     550             : // pars(1) = lat  cen   abs pix
     551             : // pars(2) = major   pix
     552             : // pars(3) = minor   pix
     553             : // pars(4) = pa radians; pos +x (long) -> +y (lat)
     554             : //
     555             : {
     556             : // Direction first
     557             : 
     558           0 :    Vector<Double> pixelCen(2);
     559           0 :    pixelCen(0) = parameters(0);
     560           0 :    pixelCen(1) = parameters(1);
     561           0 :    ComponentShape::fromPixel (pixelCen, dirCoord);
     562             : // Shape.  First put x/y p.a. into +y -> -x system
     563             : 
     564           0 :    Double pa0 = parameters(4) - C::pi_2; 
     565           0 :    MDirection tipMajor = directionFromCartesian (parameters(2), pa0, dirCoord, pixelCen);
     566             : //
     567           0 :    pa0 += C::pi_2;                      // minor axis position angle
     568           0 :    MDirection tipMinor = directionFromCartesian (parameters(3), pa0, dirCoord, pixelCen);
     569             : 
     570             : // Find tip directions
     571           0 :    const MDirection& directionRef = refDirection();       
     572           0 :    MVDirection mvdRef = directionRef.getValue();
     573           0 :    MVDirection mvdMajor = tipMajor.getValue();
     574           0 :    MVDirection mvdMinor = tipMinor.getValue();
     575             : 
     576             : // Separations
     577             : 
     578           0 :    Double tmp1 = 2 * mvdRef.separation(mvdMajor) * 3600 * 180.0 / C::pi;
     579           0 :    Double tmp2 = 2 * mvdRef.separation(mvdMinor) * 3600 * 180.0 / C::pi;
     580             : 
     581           0 :    Quantity majorAxis(max(tmp1,tmp2), Unit("arcsec"));
     582           0 :    Quantity minorAxis(min(tmp1,tmp2), Unit("arcsec"));
     583           0 :    Bool flipped = tmp2 > tmp1;
     584           0 :    Quantity pa;
     585           0 :    if (!flipped) {
     586           0 :       pa = mvdRef.positionAngle(mvdMajor, Unit("deg"));
     587             :    } else {
     588           0 :       pa = mvdRef.positionAngle(mvdMinor, Unit("deg"));
     589             :    }
     590           0 :    setWidth (majorAxis, minorAxis, pa);
     591           0 :    return flipped;
     592           0 : }
     593             : 
     594           0 : Vector<Double> TwoSidedShape::widthToCartesian (const Quantum<Double>& width,
     595             :                                                 const Quantum<Double>& pa,
     596             :                                                 const MDirection& dirRef,
     597             :                                                 const DirectionCoordinate& dirCoord,
     598             :                                                 const Vector<Double>& pixelCen) const
     599             : {
     600             : 
     601             : // Find MDirection of tip of axis
     602             :   
     603           0 :    MDirection dirTip = dirRef;
     604           0 :    dirTip.shiftAngle(width, pa);
     605             : 
     606             : // Convert to pixel 
     607             : 
     608           0 :    Vector<Double> pixelTip(2);
     609           0 :    if (!dirCoord.toPixel(pixelTip, dirTip)) {
     610           0 :       LogIO os(LogOrigin("TwoSidedShape", "widthToCartesian"));
     611             :       os << "DirectionCoordinate conversion to pixel failed because "
     612           0 :          << dirCoord.errorMessage() << LogIO::EXCEPTION;
     613           0 :    }
     614             : 
     615             : // Find offset cartesian components
     616             :    
     617           0 :    Vector<Double> cart(2);
     618           0 :    cart(0) = pixelTip(0) - pixelCen(0);
     619           0 :    cart(1) = pixelTip(1) - pixelCen(1);
     620           0 :    return cart;
     621           0 : }
     622             : 
     623           0 : MDirection TwoSidedShape::directionFromCartesian (Double width, Double pa,
     624             :                                                   const DirectionCoordinate& dirCoord,
     625             :                                                   const Vector<Double>& pixelCen) const
     626             : {
     627             : 
     628             : // Now find tips of major and minor axes in pixel coordinates
     629             : // and convert to world
     630             : 
     631           0 :    Double z = width / 2.0;
     632           0 :    Double x = -z * sin(pa);
     633           0 :    Double y =  z * cos(pa);
     634           0 :    MDirection dir;
     635           0 :    Vector<Double> pixelTip(2);
     636           0 :    pixelTip(0) = pixelCen(0) + x;
     637           0 :    pixelTip(1) = pixelCen(1) + y;
     638           0 :    ThrowIf(
     639             :                    ! dirCoord.toWorld(dir, pixelTip),
     640             :       "DirectionCoordinate conversion failed because "
     641             :          + dirCoord.errorMessage()
     642             :    );
     643           0 :    return dir;
     644           0 : }
     645             : 
     646           0 : String TwoSidedShape::sizeToString(
     647             :                 Quantity major, Quantity minor, Quantity posangle,
     648             :                 Bool includeUncertainties, Quantity majorErr,
     649             :                 Quantity minorErr, Quantity posanErr
     650             : ) {
     651             :         // Inputs all as angle quanta
     652           0 :         Vector<String> angUnits(5);
     653           0 :         angUnits[0] = "deg";
     654           0 :         angUnits[1] = "arcmin";
     655           0 :         angUnits[2] = "arcsec";
     656           0 :         angUnits[3] = "marcsec";
     657           0 :         angUnits[4] = "uarcsec";
     658             :         // First force position angle to be between 0 and 180 deg
     659           0 :         if(posangle.getValue() < 0) {
     660           0 :                 posangle += Quantity(180, "deg");
     661             :         }
     662             : 
     663           0 :         String prefUnits;
     664           0 :         Quantity vmax(max(fabs(major.getValue("arcsec")), fabs(minor.getValue("arcsec"))), "arcsec");
     665             : 
     666           0 :         for (uInt i=0; i<angUnits.size(); i++) {
     667           0 :                 prefUnits = angUnits[i];
     668           0 :                 if(vmax.getValue(prefUnits) > 1) {
     669           0 :                         break;
     670             :                 }
     671             :         }
     672           0 :         major.convert(prefUnits);
     673           0 :         minor.convert(prefUnits);
     674           0 :         majorErr.convert(prefUnits);
     675           0 :         minorErr.convert(prefUnits);
     676             : 
     677           0 :         Double vmaj = major.getValue();
     678           0 :         Double vmin = minor.getValue();
     679             : 
     680             :         // Formatting as "value +/- err" for symmetric errors
     681             : 
     682           0 :         Double dmaj = majorErr.getValue();
     683           0 :         Double dmin = minorErr.getValue();
     684             :         // position angle is always in degrees cuz users like that
     685           0 :         Double pa  = posangle.getValue("deg");
     686           0 :         Double dpa = posanErr.getValue("deg");
     687             : 
     688           0 :         Vector<Double> majVec(2), minVec(2), paVec(2);
     689           0 :         majVec[0] = vmaj;
     690           0 :         majVec[1] = dmaj;
     691           0 :         minVec[0] = vmin;
     692           0 :         minVec[1] = dmin;
     693           0 :         paVec[0] = pa;
     694           0 :         paVec[1] = dpa;
     695           0 :         uInt precision1 = precisionForValueErrorPairs(majVec, minVec);
     696           0 :         uInt precision2 = precisionForValueErrorPairs(paVec, Vector<Double>(0));
     697             : 
     698           0 :         ostringstream summary;
     699           0 :         summary << std::fixed << std::setprecision(precision1);
     700           0 :         summary << "       --- major axis FWHM:     " << major.getValue();
     701           0 :         if (includeUncertainties) {
     702           0 :                 if (majorErr.getValue() == 0) {
     703           0 :                         summary << " " << prefUnits << " (fixed)" << endl;
     704             :                 }
     705             :                 else {
     706           0 :                         summary << " +/- " << majorErr.getValue()
     707           0 :                                 << " " << prefUnits << endl;
     708             :                 }
     709             :         }
     710             :         else {
     711           0 :                 summary << " " << prefUnits << endl;
     712             :         }
     713           0 :         summary << "       --- minor axis FWHM:     " << minor.getValue();
     714           0 :         if (includeUncertainties) {
     715           0 :                 if (minorErr.getValue() == 0) {
     716           0 :                         summary << " " << prefUnits << " (fixed)" << endl;
     717             :                 }
     718             :                 else {
     719           0 :                         summary << " +/- " << minorErr.getValue()
     720           0 :                                 << " " << prefUnits << endl;
     721             :                 }
     722             :         }
     723             :         else {
     724           0 :                 summary << " " << prefUnits << endl;
     725             :         }
     726           0 :         summary << std::setprecision(precision2);
     727           0 :         summary << "       --- position angle: " << pa;
     728           0 :         if (includeUncertainties) {
     729           0 :                 if (dpa == 0) {
     730           0 :                         summary << "deg (fixed)" << endl;
     731             :                 }
     732             :                 else {
     733           0 :                         summary << " +/- " << dpa << " deg" << endl;
     734             :                 }
     735             :         }
     736             :         else {
     737           0 :                 summary << " deg" << endl;
     738             :         }
     739           0 :         return summary.str();
     740           0 : }
     741             : 
     742             : 
     743             : // Local Variables: 
     744             : // compile-command: "gmake OPTLIB=1 TwoSidedShape"
     745             : // End: 
     746             : 
     747             : 
     748             : } //# NAMESPACE CASA - END
     749             : 

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