source: Sophya/trunk/SophyaLib/SkyMap/spherethetaphi.cc@ 2742

#include "sopnamsp.h"
#include "spherethetaphi.h"
#include "smathconst.h"
#include <complex>
#include "fiondblock.h"
#include <iostream>


/*!
  \class SOPHYA::SphereThetaPhi
  \ingroup SkyMap
  Class implementing spherical maps, with equal latitude (iso-theta) rings 
  pixelisation scheme - with template data types (double, float, complex, ...)

    sphere splitted with respect to theta, phi : each hemisphere is 
    splitted into (m-1) parallels (equator does not enter into account).
    This operation defines m slices, each of which is splitted into 
    equidistant meridians. This splitting is realized in such a way that 
    all pixels have the same area and are as square as possible.

    One begins with the hemisphere with positive z, starting from the pole
    toward the equator. The first pixel is the polar cap ; it is circular
    and centered on theta=0. 
*/

//***************************************************************
//++ 
// Class        SphereThetaPhi
// 
//
// include      spherethetaphi.h 
//--
//++
//
// Links        Parents
//
//    SphericalMap 
//-- 

/* --Methode-- */
//++
// Titre        Constructors
//--
//++

template <class T>
SphereThetaPhi<T>::SphereThetaPhi()
  : NPhi_(), TNphi_(), Theta_(), pixels_() 

//--
{
  InitNul();
}


/* --Methode-- */

//++
template <class T>
SphereThetaPhi<T>::SphereThetaPhi(int_4 m)

//    m is the number of slices in theta on an hemisphere (the polar cap
//    forms the first slice).
//--
{
  InitNul();
  Pixelize(m);
}

template <class T>
SphereThetaPhi<T>::SphereThetaPhi(const SphereThetaPhi<T>& s, bool share)
  : NPhi_(s.NPhi_, share), TNphi_(s.TNphi_, share), Theta_(s.Theta_, share),
    pixels_(s.pixels_ , share) 
{

  NTheta_= s.NTheta_;
  NPix_  = s.NPix_;
  Omega_ = s.Omega_;
  if(s.mInfo_) mInfo_= new DVList(*s.mInfo_);
}

template <class T>
SphereThetaPhi<T>::SphereThetaPhi(const SphereThetaPhi<T>& s)
  : NPhi_(s.NPhi_), TNphi_(s.TNphi_), Theta_(s.Theta_), pixels_(s.pixels_) 
{

  NTheta_= s.NTheta_;
  NPix_  = s.NPix_;
  Omega_ = s.Omega_;
  if(s.mInfo_) mInfo_= new DVList(*s.mInfo_);
}

//++
// Titre        Destructor
//--
//++
template <class T>
SphereThetaPhi<T>::~SphereThetaPhi()

//--
{}

//++
// Titre        Public Méthods
//--
template <class T>
void SphereThetaPhi<T>::InitNul()
//
{
  NTheta_= 0;
  NPix_  = 0;
//  pixels_.Reset();  Pas de reset par InitNul (en cas de share) - Reza 20/11/99 $CHECK$
}


//++
template <class T>
void SphereThetaPhi<T>::Resize(int_4 m)
//   re-pixelize the sphere
//--
{
  InitNul();
  Pixelize(m);
}

template<class T>
void  SphereThetaPhi<T>::CloneOrShare(const  SphereThetaPhi<T>& a)
{

  NTheta_= a.NTheta_;
  NPix_  = a.NPix_;
  Omega_ = a.Omega_;
  NPhi_.CloneOrShare(a.NPhi_);
  TNphi_.CloneOrShare(a.TNphi_);
  Theta_.CloneOrShare(a.Theta_);
  pixels_.CloneOrShare(a.pixels_);
  if (mInfo_) {delete mInfo_; mInfo_ = NULL;}
  if (a.mInfo_) mInfo_ = new DVList(*(a.mInfo_));
}
template<class T>
void  SphereThetaPhi<T>::Share(const  SphereThetaPhi<T>& a)
{

  NTheta_= a.NTheta_;
  NPix_  = a.NPix_;
  Omega_ = a.Omega_;
  NPhi_.Share(a.NPhi_);
  TNphi_.Share(a.TNphi_);
  Theta_.Share(a.Theta_);
  pixels_.Share(a.pixels_);
  if (mInfo_) {delete mInfo_; mInfo_ = NULL;}
  if (a.mInfo_) mInfo_ = new DVList(*(a.mInfo_));
}

////////////////////////// methodes de copie/share
template<class T>
SphereThetaPhi<T>& SphereThetaPhi<T>::Set(const SphereThetaPhi<T>& a)
{
  if (this != &a) 
    { 
      
      
      if (a.NbPixels() < 1) 
        throw RangeCheckError("SphereThetaPhi<T>::Set(a ) - Array a not allocated ! ");
      if (NbPixels() < 1) CloneOrShare(a);
      else CopyElt(a);
      if (mInfo_) delete mInfo_;
      mInfo_ = NULL;
      if (a.mInfo_) mInfo_ = new DVList(*(a.mInfo_));
    }
  return(*this);
}

template<class T>
SphereThetaPhi<T>& SphereThetaPhi<T>::CopyElt(const SphereThetaPhi<T>& a)
{
  if (NbPixels() < 1) 
    throw RangeCheckError("SphereThetaPhi<T>::CopyElt(const SphereThetaPhi<T>& )  - Not Allocated Array ! ");
  if (NbPixels() != a.NbPixels()) 
    throw(SzMismatchError("SphereThetaPhi<T>::CopyElt(const SphereThetaPhi<T>&) SizeMismatch")) ;

  NTheta_= a.NTheta_;
  NPix_  = a.NPix_;
  Omega_ = a.Omega_;
  int k;
  for (k=0; k< NPix_; k++) pixels_(k) = a.pixels_(k);
  for (k=0; k< a.NPhi_.Size(); k++) NPhi_(k) = a.NPhi_(k);
  for (k=0; k< a.TNphi_.Size(); k++) TNphi_(k) = a.TNphi_(k);
  for (k=0; k< a.Theta_.Size(); k++) Theta_(k) = a.Theta_(k);
  return(*this);

}

/* --Methode-- */
//++
template <class T>
int_4 SphereThetaPhi<T>::NbPixels() const

//    Return total number of pixels 
//--
{
  return(NPix_);
}

/* --Methode-- */
//++
template <class T>
T& SphereThetaPhi<T>::PixVal(int_4 k)

//    Return value of pixel with index k
//--
{
  if((k < 0) || (k >= NPix_)) 
    {
      throw RangeCheckError("SphereThetaPhi::PIxVal Pixel index out of range");
    }
  return pixels_(k);
}

//++
template <class T>
T const& SphereThetaPhi<T>::PixVal(int_4 k) const

//    Return value of pixel with index k
//--
{
  if((k < 0) || (k >= NPix_)) 
    {
       throw RangeCheckError("SphereThetaPhi::PIxVal Pixel index out of range");
    } 
  return *(pixels_.Data()+k);
}

/* --Methode-- */
//++
template <class T>
bool SphereThetaPhi<T>::ContainsSph(double /*theta*/, double /*phi*/) const
//--
{
  return(true);
}

/* --Methode-- */
//++
template <class T>
int_4 SphereThetaPhi<T>::PixIndexSph(double theta, double phi) const

//    Return index of the pixel corresponding to 
//    direction (theta, phi).
//--
{
  double dphi;
  int i,k;
  bool fgzn = false;

  if((theta > Pi) || (theta < 0.)) return(-1);
  if((phi < 0.) || (phi > DeuxPi)) return(-1);
  if(theta > Pi*0.5) {fgzn = true; theta = Pi-theta;}
  
  // La bande d'indice kt est limitée par les valeurs de theta contenues dans
  // Theta_[kt] et Theta_[kt+1]
  for( i=1; i< NTheta_; i++ ) 
    if( theta < Theta_(i) ) break;
  
  dphi= DeuxPi/(double)NPhi_(i-1);
  
  if (fgzn)  k= NPix_-TNphi_(i)+(int_4)(phi/dphi);
  else k= TNphi_(i-1)+(int_4)(phi/dphi); 
  return(k);
}

/* --Methode-- */
//++
template <class T>
void SphereThetaPhi<T>::PixThetaPhi(int_4 k,double& theta,double& phi) const

//   Return (theta,phi) coordinates of middle of  pixel with  index k
//--
{
  int i; 
  bool fgzn = false;
  
  if((k < 0) || (k >= NPix_)) {theta = -99999.; phi = -99999.; return; }
  if( k >= NPix_/2)  {fgzn = true; k = NPix_-1-k;}

  // recupère l'indice i de la tranche qui contient le pixel k
  for( i=0; i< NTheta_; i++ ) 
    if( k < TNphi_(i+1) ) break;

  // angle theta
  theta= 0.5*(Theta_(i)+Theta_(i+1));
  if (fgzn) theta= Pi-theta;
  
  // angle phi
  k -= TNphi_(i);
  phi= DeuxPi/(double)NPhi_(i)*(double)(k+.5);
  if (fgzn) phi= DeuxPi-phi;
}

template <class T>
T SphereThetaPhi<T>::SetPixels(T v)
{
pixels_.Reset(v);
return(v);
}

//++
template <class T>
double SphereThetaPhi<T>::PixSolAngle(int_4 /*dummy*/) const

//    Pixel Solid angle  (steradians)
//    All the pixels have the same solid angle. The dummy argument is
//    for compatibility with eventual pixelizations which would not 
//    fulfil this requirement.
//--
{
  return Omega_;
}

/* --Methode-- */
//++
template <class T>
void SphereThetaPhi<T>::Limits(int_4 k,double& tetMin,double& tetMax,double& phiMin,double& phiMax) 

//   Return values of theta,phi which limit the pixel with  index k
//--
  {
  int j;
  double dphi;
  bool fgzn= false;
  
  if((k < 0) || (k >= NPix_)) {
    tetMin= -99999.; 
    phiMin= -99999.;  
    tetMax= -99999.; 
    phiMax= -99999.;  
    return;
  }
  
  // si on se trouve dans l'hémisphère Sud
  if(k >= NPix_/2) { 
    fgzn= true; 
    k= NPix_-1-k; 
  }
  
  // on recupere l'indice i de la tranche qui contient le pixel k
  int i;
  for( i=0; i< NTheta_; i++ ) 
    if(k < TNphi_(i+1)) break;
  
  // valeurs limites de theta dans l'hemisphere Nord
  tetMin= Theta_(i);
  tetMax= Theta_(i+1);
  // valeurs limites de theta dans l'hemisphere Sud
  if (fgzn) {
    tetMin= Pi - Theta_(i+1);
    tetMax= Pi - Theta_(i);
  }
  
  // pixel correspondant dans l'hemisphere Nord
  if (fgzn) k= TNphi_(i+1)-k+TNphi_(i)-1;
  
  // indice j de discretisation ( phi= j*dphi )
  j= k-TNphi_(i);
  dphi= DeuxPi/(double)NPhi_(i);
  
  // valeurs limites de phi 
  phiMin= dphi*(double)(j);
  phiMax= dphi*(double)(j+1);
  return;
}

/* --Methode-- */
//++
template <class T>
uint_4 SphereThetaPhi<T>::NbThetaSlices() const

//    Return number of theta-slices on the sphere
//--
{
  if (NTheta_<=0) 
    {
      throw PException(" sphere not pixelized, NbSlice=0 ");
    }
  return( 2*NTheta_);
}

/* --Methode-- */
//++
template <class T>
int_4 SphereThetaPhi<T>::NPhi(int_4 kt) const

//    Return number of pixels in phi-direction of the kt-th slice
//-- 
{
  int nbpix;  
  // verification
  if((kt < 0) || (kt >= 2*NTheta_)) return(-1);
  
  // si on se trouve dans l'hemisphere Sud
  if(kt >= NTheta_) {
    kt= 2*NTheta_-1-kt; 
  }
  
  // nombre de pixels
  nbpix= NPhi_(kt);
  return(nbpix);
}


/* --Methode-- */
//++
template <class T>
void SphereThetaPhi<T>::Theta(int_4 kt,double& tetMin,double& tetMax) 

//    Return  theta values which limit the slice kt
//--
{
  bool fgzn= false;
  // verification
  if( (kt< 0) || (kt>= 2*NTheta_) ) {
    tetMin= -99999.; 
    tetMax= -99999.; 
    return;
  }

  // si on se trouve dans l'hemisphere Sud
  if( kt >= NTheta_ ) {
    fgzn= true;
    kt= 2*NTheta_-1-kt; 
  }
  
  // valeurs limites de theta dans l'hemisphere Nord
  tetMin= Theta_(kt);
  tetMax= Theta_(kt+1);
  // valeurs limites de theta dans l'hemisphere Sud
  if (fgzn) {
    tetMin= Pi - Theta_(kt+1);
    tetMax= Pi - Theta_(kt);
  }  
}

/* --Methode-- */
//++
template <class T>
void SphereThetaPhi<T>::Phi(int_4 kt,int_4 jp,double& phiMin,double& phiMax) 

//   Return values of phi which limit the jp-th pixel of the kt-th slice
//--
{
  // verification
  if((kt < 0) || (kt >= 2*NTheta_)) {
    phiMin= -99999.; 
    phiMax= -99999.; 
    return;
  }
  
  // si on se trouve dans l'hemisphere Sud
  if(kt >= NTheta_) kt= 2*NTheta_-1-kt;
  
  // verifie si la tranche kt contient au moins jp pixels
  if( (jp< 0) || (jp >= NPhi_(kt)) ) {
    phiMin= -88888.; 
    phiMax= -88888.; 
    return;
  }
  
  double dphi= DeuxPi/(double)NPhi_(kt);
  phiMin= dphi*(double)(jp);
  phiMax= dphi*(double)(jp+1);
  return;
}

/* --Methode-- */
//++
template <class T>
int_4 SphereThetaPhi<T>::Index(int_4 kt,int_4 jp) const

//    Return pixel index  with sequence index jp in the slice kt 
//--
{
  int k;
  bool fgzn= false;
  
  // si on se trouve dans l'hemisphere Sud
  if(kt >= NTheta_) {
    fgzn= true; 
    kt= 2*NTheta_-1-kt;
  }
  
  // si la tranche kt contient au moins i pixels
  if( (jp>=0) && (jp<NPhi_(kt)) ) 
    {
      // dans l'hemisphere Sud
      if (fgzn) k= NPix_-TNphi_(kt+1)+jp;
      // dans l'hemisphere Nord
      else k= TNphi_(kt)+jp;
    }
  else
    {
      k= 9999;
      printf("\n la tranche %d ne contient pas un pixel de rang %d",kt,jp);
    }
  return(k);
}

/* --Methode-- */
//++
template <class T>
void SphereThetaPhi<T>::ThetaPhiIndex(int_4 k,int_4& kt,int_4& jp) 

//    Return indices kt (theta) and jp (phi) of  pixel with index k
//--
{
  bool fgzn= false;  
  // si on se trouve dans l'hemisphere Sud
  if(k >= NPix_/2) 
    { 
      fgzn= true; 
      k= NPix_-1-k; 
    }
  
  // on recupere l'indice kt de la tranche qui contient le pixel k
  int i;
  for(i = 0; i < NTheta_; i++) 
    if(k < TNphi_(i+1)) break;
  
  // indice  kt de tranche
  if (fgzn) kt= 2*NTheta_-1-i;
  else kt= i;
  
  // indice jp de pixel
  if (fgzn) jp= TNphi_(i+1)-k-1;
  else jp= k-TNphi_(i);  
}
//++
template <class T>
void  SphereThetaPhi<T>::Pixelize(int_4 m) 

//    achieve the splitting into pixels (m has the same signification 
//    as for the constructor)
//
//    Each theta-slice of the north hemisphere will be spitted starting f
//    from  phi=0 ...
//
//    South hemisphere is scanned in the same direction according to phi
//    and from equator to the pole (the pixel following the last one of
//    the slice closest to the equator with z>0, is the pixel with lowest 
//    phi of the slice closest of the equator with z<0).
//--
{
  int ntotpix,j;
  
  // Decodage et controle des arguments d'appel :
  // au moins 2 et au plus 16384 bandes d'un hemisphere en theta
  if (m < 2) m = 2;
  if (m > 16384) m = 16384;
  
  // On memorise les arguments d'appel
  NTheta_ = m;  
  
  // On commence par decouper l'hemisphere z>0.
  // Creation des vecteurs contenant :
  // Les valeurs limites de theta (une valeur de plus que le nombre de bandes...)
  //  Theta_= new double[m+1];
  Theta_.ReSize(m+1);
  
  // Le nombre de pixels en phi de chacune des bandes en theta
  //  NPhi_ = new int_4[m];
  // une taille de m suffit, mais je mets m+1 pour que les 3 tableaux aient 
  // la meme taille pour une manipulation plus faciles par la librairie 
  // cfitsio -- GLM (13-04-00)
  NPhi_.ReSize(m+1);
  
  // Le nombre/Deuxpi total des pixels contenus dans les bandes de z superieur a une
  // bande donnee (mTPphi[m] contient le nombre de pixels total de l'hemisphere)
  //  TNphi_= new int_4[m+1];
    TNphi_.ReSize(m+1);
  
  // Calcul du nombre total de pixels dans chaque bande pour optimiser
  // le rapport largeur/hauteur des pixels 
  
  //calotte polaire
  TNphi_(0)= 0;
  NPhi_(0) = 1;
  
  //bandes jusqu'a l'equateur
  for(j = 1; j < m; j++) 
    {
      TNphi_(j)= TNphi_(j-1)+NPhi_(j-1);
      NPhi_(j) = (int_4)(.5+4.*(double)(m-.5)*sin(Pi*(double)j/(double)(2.*m-1.))) ;
    }
  
  // Nombre total de pixels sur l'hemisphere
  ntotpix  = TNphi_(m-1)+NPhi_(m-1);
  TNphi_(m)= ntotpix;
  // et sur la sphere entiere
  NPix_= 2*ntotpix;
  
  // Creation et initialisation du vecteur des contenus des pixels 
  pixels_.ReSize(NPix_);
  pixels_.Reset();

  // Determination des limites des bandes en theta :
  // omeg est l'angle solide couvert par chaque pixel,
  // une bande donnee kt couvre un angle solide NPhi_[kt]*omeg
  // egal a 2* Pi*(cos Theta_[kt]-cos Theta_[kt+1]). De meme, l'angle solide 
  //de la
  // calotte allant du pole a la limite haute de la bande kt vaut
  // 2* Pi*(1.-cos Theta_[kt+1])= TNphi_[kt]*omeg...
  
  double omeg2pi= 1./(double)ntotpix;
  Omega_ = omeg2pi*DeuxPi;
  
  for(j=0; j <= m; j++) 
    {
      Theta_(j)= acos(1.-(double)TNphi_(j)*omeg2pi);
    }
}

//++
template <class T>
void SphereThetaPhi<T>::GetThetaSlice(int_4 index,r_8& theta, TVector<r_8>& phi, TVector<T>& value) const 

//    For a theta-slice with index 'index', return : 
//    the corresponding "theta" 
//    a vector containing the phi's of the pixels of the slice
//    a vector containing the corresponding values of pixels 
//--

{

  if(index < 0 || index >= NbThetaSlices()) 
    {
       throw RangeCheckError("SphereThetaPhi::PIxVal Pixel index out of range"); 
    }

  int iring= Index(index,0);
  int lring  = NPhi(index);

  phi.ReSize(lring);
  value.ReSize(lring);
  double Te= 0.;
  double Fi= 0.;
  for(int kk = 0; kk < lring; kk++) 
    {
      PixThetaPhi(kk+iring,Te,Fi);
      phi(kk)= Fi;
      value(kk)= PixVal(kk+iring);
    }
  theta= Te;
}

//++
template <class T>
void SphereThetaPhi<T>::GetThetaSlice(int_4 index,r_8& theta, r_8& phi0,TVector<int_4>& pixelIndices, TVector<T>& value) const 

//    For a theta-slice with index 'index', return : 
//    the corresponding "theta" 
//    the corresponding "phi" for first pixel of the slice 
//    a vector containing the indices of the pixels of the slice
//    (equally distributed in phi)
//    a vector containing the corresponding values of pixels 
//--

{

  if(index < 0 || index >= NbThetaSlices()) 
    {
       throw RangeCheckError("SphereThetaPhi::PIxVal Pixel index out of range"); 
 
    }

  int iring= Index(index,0);
  int lring  = NPhi(index);

  pixelIndices.ReSize(lring);
  value.ReSize(lring);
  double Te= 0.;
  double Fi= 0.;
  for(int kk = 0; kk < lring; kk++) 
    {
      pixelIndices(kk)=kk+iring ;
      value(kk)= PixVal(kk+iring);
    }
      PixThetaPhi(iring,theta,phi0);
}




template <class T>
void SphereThetaPhi<T>::print(ostream& os) const
{
  if(mInfo_) os << "  DVList Info= " << *mInfo_ << endl;
  //
  os << " NTheta_= " << NTheta_ << endl;
  os << " NPix_    = " << NPix_   << endl;
  os << " Omega_  =  " << Omega_   << endl;

  os << " contenu de NPhi_ : ";
  int i;
  for(i=0; i < NTheta_; i++)
    {
      if(i%5 == 0) os << endl;
      os << NPhi_(i) <<", ";
    }
  os << endl;

  os << " contenu de Theta_ : ";
  for(i=0; i < NTheta_+1; i++)
    {
      if(i%5 == 0) os << endl;
      os << Theta_(i) <<", ";
    }
  os << endl;

  os << " contenu de TNphi_ : ";
  for(i=0; i < NTheta_+1; i++)
    {
      if(i%5 == 0) os << endl;
      os << TNphi_(i) <<", ";
    }
  os << endl;

  os << " contenu de pixels : ";
  for(i=0; i < NPix_; i++)
    {
      if(i%5 == 0) os << endl;
      os <<  pixels_(i) <<", ";
    }
  os << endl;
}

//   ...... Operations de calcul  ......


//! Fill a SphereThetaPhi with a constant value \b a
template <class T>
SphereThetaPhi<T>& SphereThetaPhi<T>::SetT(T a) 
{
  if (NbPixels() < 1) 
    throw RangeCheckError("SphereThetaPhi<T>::SetT(T )  - SphereThetaPhi not dimensionned ! ");
  pixels_ = a;
  return (*this);
}

/*! Add a constant value \b x to a SphereThetaPhi */
template <class T>
SphereThetaPhi<T>& SphereThetaPhi<T>::Add(T a)
 {
  if (NbPixels()< 1) 
    throw RangeCheckError("SphereThetaPhi<T>::Add(T )  - SphereThetaPhi not dimensionned ! ");
  pixels_ += a; 
  return (*this);
}

/*! Substract a constant value \b a to a SphereThetaPhi */
template <class T>
SphereThetaPhi<T>& SphereThetaPhi<T>::Sub(T a,bool fginv) 
{
  if (NbPixels()< 1) 
    throw RangeCheckError("SphereThetaPhi<T>::Sub(T )  - SphereThetaPhi not dimensionned ! ");
  pixels_.Sub(a,fginv); 
  return (*this);
} 

/*! multiply a SphereThetaPhi by a constant value \b a */
template <class T>
SphereThetaPhi<T>& SphereThetaPhi<T>::Mul(T a) 
{
  if (NbPixels()< 1) 
    throw RangeCheckError("SphereThetaPhi<T>::Mul(T )  - SphereThetaPhi not dimensionned ! ");
  pixels_ *= a; 
  return (*this);
}

/*! divide a SphereThetaPhi by a constant value \b a */
template <class T>
SphereThetaPhi<T>& SphereThetaPhi<T>::Div(T a) 
{
  if (NbPixels()< 1) 
    throw RangeCheckError("SphereThetaPhi<T>::Div(T )  - SphereThetaPhi not dimensionned ! ");
  pixels_ /= a; 
  return (*this);
} 

//  >>>> Operations avec 2nd membre de type SphereThetaPhi
//! Add two SphereThetaPhi

template <class T>
SphereThetaPhi<T>& SphereThetaPhi<T>::AddElt(const SphereThetaPhi<T>& a)
{
  if (NbPixels()!= a.NbPixels())
    {
    throw(SzMismatchError("SphereThetaPhi<T>::AddElt(const SphereThetaPhi<T>&) SizeMismatch")) ;
    }
  pixels_ += a.pixels_;
  return (*this);
}

//! Substract two SphereThetaPhi
template <class T>
SphereThetaPhi<T>& SphereThetaPhi<T>::SubElt(const SphereThetaPhi<T>& a)
{
  if (NbPixels()!= a.NbPixels())
    {
    throw(SzMismatchError("SphereThetaPhi<T>::SubElt(const SphereThetaPhi<T>&) SizeMismatch")) ;
    }
  pixels_ -= a.pixels_;
  return (*this);
}

//! Multiply two SphereThetaPhi (elements by elements)
template <class T>
SphereThetaPhi<T>& SphereThetaPhi<T>::MulElt(const SphereThetaPhi<T>& a)
{
  if (NbPixels()!= a.NbPixels())
    {
    throw(SzMismatchError("SphereThetaPhi<T>::MulElt(const SphereThetaPhi<T>&) SizeMismatch")) ;
    }
  pixels_ *= a.pixels_;
  return (*this);
}

//! Divide two SphereThetaPhi (elements by elements) - No protection for divide by 0
template <class T>
SphereThetaPhi<T>& SphereThetaPhi<T>::DivElt(const SphereThetaPhi<T>& a)
{
  if (NbPixels()!= a.NbPixels())
    {
    throw(SzMismatchError("SphereThetaPhi<T>::DivElt(const SphereThetaPhi<T>&) SizeMismatch")) ;
    }
  pixels_ /= a.pixels_;
  return (*this);
}



#ifdef __CXX_PRAGMA_TEMPLATES__
#pragma define_template SphereThetaPhi<int_4>
#pragma define_template SphereThetaPhi<r_8>
#pragma define_template SphereThetaPhi<r_4>
#pragma define_template SphereThetaPhi< complex<r_4> >
#pragma define_template SphereThetaPhi< complex<r_8> >
#endif
#if defined(ANSI_TEMPLATES) || defined(GNU_TEMPLATES)
template class SphereThetaPhi<int_4>;
template class SphereThetaPhi<r_8>;
template class SphereThetaPhi<r_4>;
template class SphereThetaPhi< complex<r_4> >;
template class SphereThetaPhi< complex<r_8> >;
#endif