Implemented power spectrum support in Euclidian/Healpix

2012-11-10 17:35:27 -05:00 · 2012-11-10 17:35:27 -05:00 · cc7996175c
commit cc7996175c
parent db6831e594
5 changed files with 178 additions and 16 deletions
--- a/sample/test_fft_calls.cpp
+++ b/sample/test_fft_calls.cpp
@ -1,13 +1,23 @@
+#include "yorick.hpp"
+#include <gsl/gsl_rng.h>
 #include <iostream>
+#include <cmath>
 #include "fourier/euclidian.hpp"

 using namespace CosmoTool;
 using namespace std;

+double spectrum_generator(double k)
+{
+  return 1/(0.1+pow(k, 3.0));
+}
+
 int main()
 {
  EuclidianFourierTransform_2d<double> dft(128,128,1.0,1.0);
+  EuclidianSpectrum_1D<double> spectrum(spectrum_generator);
  double volume = 128*128;
+  gsl_rng *rng = gsl_rng_alloc(gsl_rng_default);

  dft.realSpace().eigen().setRandom();
  dft.analysis();
@ -15,6 +25,17 @@ int main()
  cout << "Fourier dot-product = " << dft.fourierSpace().dot_product(dft.fourierSpace()).real()*volume << endl;
  dft.synthesis();
  cout << "Resynthesis dot-product = " << dft.realSpace().dot_product(dft.realSpace()) << endl;
+
+  dft.realSpace().scale(2.0);
+  dft.fourierSpace().scale(0.2);
+
+  SpectrumFunction<double>::FourierMapPtr m = spectrum.newRandomFourier(rng, dft.fourierSpace()); 
+  dft.fourierSpace() = *m.get();
+  dft.synthesis();
+
+  uint32_t dims[2] = { 128, 128 };
+  CosmoTool::saveArray("generated_map.nc", dft.realSpace().data(), dims, 2);
+  
  return 0;

 }
--- a/sample/test_healpix_calls.cpp
+++ b/sample/test_healpix_calls.cpp
@ -6,7 +6,7 @@ using namespace std;

 int main()
 {
-  HealpixFourierTransform<double> dft(128,3*128,3*128, 40);
+  HealpixFourierTransform<double> dft(128,2*128,2*128, 40);
  long Npix = dft.realSpace().size();

  dft.realSpace().eigen().setRandom();
--- a/src/fourier/base_types.hpp
+++ b/src/fourier/base_types.hpp
@ -24,14 +24,17 @@ namespace CosmoTool
    typedef Eigen::Map<VecType, Eigen::Aligned> MapType;
    typedef Eigen::Map<VecType const, Eigen::Aligned> ConstMapType;
    typedef FourierMap<std::complex<T> > FourierMapType;
+    typedef boost::shared_ptr<FourierMapType> FourierMapPtr;

-    virtual boost::shared_ptr<FourierMapType> 
+    virtual FourierMapPtr 
       newRandomFourier(gsl_rng *rng, const FourierMapType& like_map) const = 0;

-    virtual void mul(FourierMap<std::complex<T> >& m) const = 0;
+    virtual void mul(FourierMapType& m) const = 0;
+    virtual void mul_sqrt(FourierMapType& m) const = 0;
+    virtual void mul_inv(FourierMapType& m) const = 0;
+    virtual void mul_inv_sqrt(FourierMapType& m) const = 0;
  };

-
  template<typename T>
  class FourierMap
  {
@ -60,6 +63,12 @@ namespace CosmoTool
      return ConstMapType(data(), size());
    }

+    FourierMap<T>& operator=(const FourierMap<T>& m)
+    {
+      eigen() = m.eigen();
+      return *this;
+    }
+
    void sqrt()
    {
      MapType m = eigen();
@ -130,6 +139,14 @@ namespace CosmoTool
    virtual void synthesis_conjugate() = 0;
  };

+  template<typename T>
+  class MapUtilityFunction
+  {
+    typedef SpectrumFunction<T> Spectrum;
+    typedef Spectrum *Spectrum_ptr;
+    typedef FourierMap<std::complex<T> > FMap;
+    typedef Spectrum_ptr (*SpectrumFromMap)(const FMap& m);
+  };

 };

--- a/src/fourier/euclidian.hpp
+++ b/src/fourier/euclidian.hpp
@ -30,6 +30,9 @@ namespace CosmoTool
    ptr_map newRandomFourier(gsl_rng *rng, const FourierMapType& like_map) const;

    void mul(FourierMap<std::complex<T> >& m) const;
+    void mul_sqrt(FourierMap<std::complex<T> >& m) const;
+    void mul_inv(FourierMap<std::complex<T> >& m) const;
+    void mul_inv_sqrt(FourierMap<std::complex<T> >& m) const;
  };
  
  template<typename T>
@ -140,7 +143,7 @@ namespace CosmoTool
      double k2 = 0;
      for (int q = 0; q < ik.size(); q++)
 	{
-	  int dk = ik;
+	  int dk = ik[q];

 	  if (dk > dims[q]/2)
 	    dk = dk - dims[q];
@ -349,18 +352,21 @@ namespace CosmoTool
   EuclidianSpectrum_1D<T>::newRandomFourier(gsl_rng *rng, const FourierMapType& like_map) const
  {
    typedef EuclidianFourierMapComplex<T> MapT;
+    typedef typename EuclidianSpectrum_1D<T>::ptr_map ptr_map;
    typedef typename MapT::DimArray DimArray;

-    MapT& m_c = dynamic_cast<MapT&>(like_map);
-    MapT *rand_map = m_c.mimick();
-    std::complex<T> *d = rand_map->data();
+    const MapT& m_c = dynamic_cast<const MapT&>(like_map);
+    ptr_map ret_map = ptr_map(m_c.mimick());
+    MapT& rand_map = dynamic_cast<MapT&>(*ret_map.get());
+
+    std::complex<T> *d = rand_map.data();
    long idx;
-    const DimArray& dims = rand_map->getDims();
+    const DimArray& dims = rand_map.getDims();
    long plane_size;

    for (long p = 1; p < m_c.size(); p++)
      {
-	double A_k = std::sqrt(0.5*f(rand_map->get_K(p)));
+	double A_k = std::sqrt(0.5*f(rand_map.get_K(p)));
 	d[p] = std::complex<T>(gsl_ran_gaussian(rng, A_k),
 			       gsl_ran_gaussian(rng, A_k));
      }
@ -372,7 +378,7 @@ namespace CosmoTool
    if (dims.size() == 1)
      {
 	d[idx] = std::complex<T>(d[idx].real() + d[idx].imag(), 0);
-	return boost::shared_ptr<EuclidianSpectrum_1D<T>::FourierMapType>(rand_map);
+        return ret_map;
      }

    plane_size = 1;
@ -391,6 +397,7 @@ namespace CosmoTool
      }
    long q = dims[0];
    d[q] = std::complex<T>(d[q].real() + d[q].imag());
+    return ret_map;
  }

  template<typename T>
@ -400,8 +407,51 @@ namespace CosmoTool
    std::complex<T> *d = m.data();

    for (long p = 0; p < m_c.size(); p++)
-      d[p] *= f(m.get_K(p));
+      d[p] *= f(m_c.get_K(p));
  }
+
+  template<typename T>
+  void EuclidianSpectrum_1D<T>::mul_sqrt(FourierMap<std::complex<T> >& m) const
+  {
+    EuclidianFourierMapComplex<T>& m_c = dynamic_cast<EuclidianFourierMapComplex<T>&>(m);
+    std::complex<T> *d = m.data();
+
+    for (long p = 0; p < m_c.size(); p++)
+      d[p] *= std::sqrt(f(m_c.get_K(p)));
+  }
+
+  template<typename T>
+  void EuclidianSpectrum_1D<T>::mul_inv(FourierMap<std::complex<T> >& m) const
+  {
+    EuclidianFourierMapComplex<T>& m_c = dynamic_cast<EuclidianFourierMapComplex<T>&>(m);
+    std::complex<T> *d = m.data();
+
+    for (long p = 0; p < m_c.size(); p++)
+     {
+        T A = f(m_c.get_K(p));
+        if (A==0)
+          d[p] = 0;
+        else
+          d[p] /= A;
+     }
+  }
+
+  template<typename T>
+  void EuclidianSpectrum_1D<T>::mul_inv_sqrt(FourierMap<std::complex<T> >& m) const
+  {
+    EuclidianFourierMapComplex<T>& m_c = dynamic_cast<EuclidianFourierMapComplex<T>&>(m);
+    std::complex<T> *d = m.data();
+
+    for (long p = 0; p < m_c.size(); p++)
+      {
+        T A = std::sqrt(f(m_c.get_K(p)));
+        if (A == 0)
+          d[p] = 0;
+        else
+          d[p] /= A;
+      }
+  }
+
 };

 #endif
--- a/src/fourier/healpix.hpp
+++ b/src/fourier/healpix.hpp
@ -32,7 +32,12 @@ namespace CosmoTool
    const T *data() const { return &cls[0]; }
    long size() const { return cls.size(); }

-    ptr_map newRandomFourier(gsl_rng *rng, const FourierMapType& like_map) const = 0;
+    ptr_map newRandomFourier(gsl_rng *rng, const FourierMapType& like_map) const; 
+
+    void mul(FourierMapType& m) const;
+    void mul_sqrt(FourierMapType& m) const;
+    void mul_inv(FourierMapType& m) const;
+    void mul_inv_sqrt(FourierMapType& m) const;
  };

  template<typename T>
@ -248,13 +253,13 @@ namespace CosmoTool
    long lmaxGen = std::min(cls.size()-1, alms.Lmax());
    std::complex<T> *new_data = new_alms->data();

-    for (long l = 0; l < lmaxGen; l++)
+    for (long l = 0; l <= lmaxGen; l++)
      {
        double Al = std::sqrt(cls[l]);

        new_data[alms.index(l,0)] = gsl_ran_gaussian(rng, Al);
        Al *= M_SQRT1_2;
-        for (long m = 1; m < alms.Mmax(); m++)
+        for (long m = 1; m <= std::min(l,alms.Mmax()); m++)
          {
            std::complex<T>& c = new_data[alms.index(l,m)];
            c.real() = gsl_ran_gaussian(rng, Al); 
@ -263,6 +268,75 @@ namespace CosmoTool
      }
    return r;
  } 
+
+ template<typename T>
+ void HealpixSpectrum<T>::mul(FourierMapType& like_map) const
+  {
+    HealpixFourierALM<T>& alms = dynamic_cast<HealpixFourierALM<T>&>(like_map);
+    std::complex<T> *data = alms.data();
+
+    for (long l = 0; l <= alms.Lmax(); l++)
+      {
+        double Al = cls[l];
+
+        for (long m = 0; m <= std::min(l,alms.Mmax()); m++)
+          {
+            data[alms.index(l,m)] *= Al;
+          }
+      }
+  }
+
+ template<typename T>
+ void HealpixSpectrum<T>::mul_sqrt(FourierMapType& like_map) const
+  {
+    HealpixFourierALM<T>& alms = dynamic_cast<const HealpixFourierALM<T>&>(like_map);
+    std::complex<T> *data = alms.data();
+
+    for (long l = 0; l <= alms.Lmax(); l++)
+      {
+        double Al = std::sqrt(cls[l]);
+
+        for (long m = 0; m <= std::min(l,alms.Mmax()); m++)
+          {
+            data[alms.index(l,m)] *= Al;
+          }
+      }
+  }
+
+ template<typename T>
+ void HealpixSpectrum<T>::mul_inv(FourierMapType& like_map) const
+  {
+    HealpixFourierALM<T>& alms = dynamic_cast<HealpixFourierALM<T>&>(like_map);
+    std::complex<T> *data = alms.data();
+
+    for (long l = 0; l <= alms.Lmax(); l++)
+      {
+        double Al = (cls[l] <= 0) ? 0 : (1/cls[l]);
+
+        for (long m = 0; m <= std::min(l,alms.Mmax()); m++)
+          {
+            data[alms.index(l,m)] *= Al;
+          }
+      }
+  }
+
+ template<typename T>
+ void HealpixSpectrum<T>::mul_inv_sqrt(FourierMapType& like_map) const
+  {
+    HealpixFourierALM<T>& alms = dynamic_cast<HealpixFourierALM<T>&>(like_map);
+    std::complex<T> *data = alms.data();
+
+    for (long l = 0; l <= alms.Lmax(); l++)
+      {
+        double Al = (cls[l] <= 0) ? 0 : std::sqrt(1/cls[l]);
+
+        for (long m = 0; m <= std::min(l,alms.Mmax()); m++)
+          {
+            data[alms.index(l,m)] *= Al;
+          }
+      }
+  }
+
 };

 #endif