vtk-m2/vtkm/worklet/splatkernels/Spline3rdOrder.h

//============================================================================
//  Copyright (c) Kitware, Inc.
//  All rights reserved.
//  See LICENSE.txt for details.
//  This software is distributed WITHOUT ANY WARRANTY; without even
//  the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR
//  PURPOSE.  See the above copyright notice for more information.
//
//  Copyright 2014 Sandia Corporation.
//  Copyright 2014 UT-Battelle, LLC.
//  Copyright 2014 Los Alamos National Security.
//
//  Under the terms of Contract DE-AC04-94AL85000 with Sandia Corporation,
//  the U.S. Government retains certain rights in this software.
//
//  Under the terms of Contract DE-AC52-06NA25396 with Los Alamos National
//  Laboratory (LANL), the U.S. Government retains certain rights in
//  this software.
//============================================================================
#ifndef VTKM_KERNEL_SPLINE_3RD_ORDER_H
#define VTKM_KERNEL_SPLINE_3RD_ORDER_H

#include "KernelBase.h"

//
// Spline 3rd Order kernel.
//

namespace vtkm { namespace worklet {
namespace splatkernels {

template <int Dimensions>
struct Spline3rdOrder : public KernelBase< Spline3rdOrder<Dimensions> >
{
    //---------------------------------------------------------------------
    // Constructor
    // Calculate coefficients used repeatedly when evaluating the kernel
    // value or gradient
    VTKM_EXEC_CONT
    Spline3rdOrder(double smoothingLength)
    : KernelBase< Spline3rdOrder<Dimensions> >(smoothingLength)
      {
        Hinverse_   = 1.0/smoothingLength;
        Hinverse2_  = Hinverse_*Hinverse_;
        maxRadius_  = 2.0*smoothingLength;
        maxRadius2_ = maxRadius_*maxRadius_;
        //
        if (Dimensions==2) {
            norm_ = 10.0/(7.0*M_PI);
        }
        if (Dimensions==3) {
            norm_ = 1.0/M_PI;
        }
        scale_W_     = norm_ * PowerExpansion<Dimensions>  (Hinverse_);
        scale_GradW_ = norm_ * PowerExpansion<Dimensions+1>(Hinverse_);
      }
    //---------------------------------------------------------------------
    // Calculates the kernel value for the given distance
    VTKM_EXEC_CONT
    double w(double distance) const
    {
        // compute Q=(r/h)
        double Q = distance * Hinverse_;
        if (Q<1.0) {
            return scale_W_ *(1.0 - (3.0/2.0)*Q*Q + (3.0/4.0)*Q*Q*Q);
        }
        else if (Q<2.0) {
            double q2 = (2.0-Q);
            return scale_W_ * (1.0/4.0) * (q2*q2*q2);;
        }
        else {
            return 0.0;
        }
    }

    //---------------------------------------------------------------------
    // Calculates the kernel value for the given squared distance
    VTKM_EXEC_CONT
    double w2(double distance2) const
    {
        // compute Q
        double Q = sqrt(distance2) * Hinverse_;
        if (Q<1.0) {
            return scale_W_ *(1.0 - (3.0/2.0)*Q*Q + (3.0/4.0)*Q*Q*Q);
        }
        else if (Q<2.0) {
            double q2 = (2.0-Q);
            return scale_W_ * (1.0/4.0) * (q2*q2*q2);;
        }
        else {
            return 0.0;
        }
    }

    //---------------------------------------------------------------------
    // compute w(h) for a variable h kernel
    VTKM_EXEC_CONT
    double w(double h, double distance) const
    {
        double Hinverse = 1.0/h;
        double scale_W = norm_ * PowerExpansion<Dimensions>(Hinverse);
        double Q = distance * Hinverse;
        if (Q<1.0) {
          return scale_W *(1.0 - (3.0/2.0)*Q*Q + (3.0/4.0)*Q*Q*Q);
        }
        else if (Q<2.0) {
          double q2 = (2.0-Q);
          return scale_W * (1.0/4.0) * (q2*q2*q2);;
        }
        else {
          return 0.0;
        }
    }

    //---------------------------------------------------------------------
    // compute w(h) for a variable h kernel using distance squared
    VTKM_EXEC_CONT
    double w2(double h, double distance2) const
    {
        double Hinverse = 1.0/h;
        double scale_W = norm_ * PowerExpansion<Dimensions>(Hinverse);
        double Q = sqrt(distance2) * Hinverse;
        if (Q<1.0) {
          return scale_W *(1.0 - (3.0/2.0)*Q*Q + (3.0/4.0)*Q*Q*Q);
        }
        else if (Q<2.0) {
          double q2 = (2.0-Q);
          return scale_W * (1.0/4.0) * (q2*q2*q2);;
        }
        else {
          return 0.0;
        }
    }

    //---------------------------------------------------------------------
    // Calculates the kernel derivation for the given distance of two particles.
    // The used formula is the derivation of Speith (3.126) for the value
    // with (3.21) for the direction of the gradient vector.
    // Be careful: grad W is antisymmetric in r (3.25)!.
    VTKM_EXEC_CONT
    vector_type gradW(double distance, const vector_type& pos) const
    {
        double Q = distance * Hinverse_;
        if (Q==0.0) {
          return vector_type(0.0);
        }
        else if (Q<1.0) {
          return scale_GradW_ * (-3.0*Q + (9.0/4.0)*Q*Q) * pos;
        }
        else if (Q<2.0) {
          double q2 = (2.0-Q);
          return scale_GradW_ * (-3.0/4.0)*q2*q2 * pos;
        }
        else {
          return vector_type(0.0);
        }
    }

    //---------------------------------------------------------------------
    VTKM_EXEC_CONT
    vector_type gradW(double h, double distance, const vector_type& pos) const
    {
        double Hinverse = 1.0/h;
        double scale_GradW = norm_ * PowerExpansion<Dimensions+1>(Hinverse);
        double Q = distance * Hinverse;
        if (Q==0.0) {
          return vector_type(0.0);
        }
        else if (Q<1.0) {
          return scale_GradW * (-3.0*Q + (9.0/4.0)*Q*Q) * pos;
        }
        else if (Q<2.0) {
          double q2 = (2.0-Q);
          return scale_GradW * (-3.0/4.0)*q2*q2 * pos;
        }
        else {
          return vector_type(0.0);
        }
    }

    //---------------------------------------------------------------------
    // return the maximum distance at which this kernel is non zero
    VTKM_EXEC_CONT
    double maxDistance() const
    {
        return maxRadius_;
    }

    //---------------------------------------------------------------------
    // return the maximum distance at which this variable h kernel is non zero
    VTKM_EXEC_CONT
    double maxDistance(double h) const
    {
        return 2.0*h;
    }

    //---------------------------------------------------------------------
    // return the maximum distance at which this kernel is non zero
    VTKM_EXEC_CONT
    double maxSquaredDistance() const
    {
        return maxRadius2_;
    }

    //---------------------------------------------------------------------
    // return the maximum distance at which this kernel is non zero
    VTKM_EXEC_CONT
    double maxSquaredDistance(double h) const
    {
        return 4.0*h*h;
    }

    //---------------------------------------------------------------------
    // return the multiplier between smoothing length and max cutoff distance
    VTKM_EXEC_CONT
    double getDilationFactor() const { return 2.0; }

private:
    double norm_;
    double Hinverse_;
    double Hinverse2_;
    double maxRadius_;
    double maxRadius2_;
    double scale_W_;
    double scale_GradW_;
};

}}}

#endif