/* ----------------------------------------------------------------------
    This is the

    ██╗     ██╗ ██████╗  ██████╗  ██████╗ ██╗  ██╗████████╗███████╗
    ██║     ██║██╔════╝ ██╔════╝ ██╔════╝ ██║  ██║╚══██╔══╝██╔════╝
    ██║     ██║██║  ███╗██║  ███╗██║  ███╗███████║   ██║   ███████╗
    ██║     ██║██║   ██║██║   ██║██║   ██║██╔══██║   ██║   ╚════██║
    ███████╗██║╚██████╔╝╚██████╔╝╚██████╔╝██║  ██║   ██║   ███████║
    ╚══════╝╚═╝ ╚═════╝  ╚═════╝  ╚═════╝ ╚═╝  ╚═╝   ╚═╝   ╚══════╝®

    DEM simulation engine, released by
    DCS Computing Gmbh, Linz, Austria
    http://www.dcs-computing.com, office@dcs-computing.com

    LIGGGHTS® is part of CFDEM®project:
    http://www.liggghts.com | http://www.cfdem.com

    Core developer and main author:
    Christoph Kloss, christoph.kloss@dcs-computing.com

    LIGGGHTS® is open-source, distributed under the terms of the GNU Public
    License, version 2 or later. It is distributed in the hope that it will
    be useful, but WITHOUT ANY WARRANTY; without even the implied warranty
    of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. You should have
    received a copy of the GNU General Public License along with LIGGGHTS®.
    If not, see http://www.gnu.org/licenses . See also top-level README
    and LICENSE files.

    LIGGGHTS® and CFDEM® are registered trade marks of DCS Computing GmbH,
    the producer of the LIGGGHTS® software and the CFDEM®coupling software
    See http://www.cfdem.com/terms-trademark-policy for details.

-------------------------------------------------------------------------
    Contributing author and copyright for this file:

    Alexander Podlozhnyuk (DCS Computing GmbH, Linz)
    Andreas Aigner (DCS Computing GmbH, Linz)
    Andreas Aigner (JKU Linz)
    Christoph Kloss (DCS Computing GmbH, Linz)
    Christoph Kloss (JKU Linz)
    Richard Berger (JKU Linz)

    Copyright 2012-     DCS Computing GmbH, Linz
    Copyright 2009-2012 JKU Linz
------------------------------------------------------------------------- */

#ifdef ROLLING_MODEL

ROLLING_MODEL(ROLLING_EPSD2,epsd2,3)

#else

#ifndef ROLLING_MODEL_EPSD2_H_
#define ROLLING_MODEL_EPSD2_H_

#include "contact_models.h"
#include "rolling_model_base.h"
#include <algorithm>
#include <cmath>
#include "domain.h"
#include "math_extra_liggghts.h"

namespace LIGGGHTS {
namespace ContactModels
{
  using namespace LAMMPS_NS;

  template<>
  class RollingModel<ROLLING_EPSD2> : public RollingModelBase
  {
  public:
    RollingModel(class LAMMPS * lmp, IContactHistorySetup * hsetup,class ContactModelBase * c) :
        RollingModelBase(lmp, hsetup, c), coeffRollFrict(NULL)
    {
      history_offset = hsetup->add_history_value("r_torquex_old", "1");
      hsetup->add_history_value("r_torquey_old", "1");
      hsetup->add_history_value("r_torquez_old", "1");
      
    }

    void registerSettings(Settings& settings)
    {
       settings.registerOnOff("torsionTorque", torsion_torque, false);
    }

    void postSettings(IContactHistorySetup * hsetup, ContactModelBase *cmb)
    {}

    void connectToProperties(PropertyRegistry & registry) {
      registry.registerProperty("coeffRollFrict", &MODEL_PARAMS::createCoeffRollFrict);
      registry.connect("coeffRollFrict", coeffRollFrict,"rolling_model epsd2");

      // error checks on coarsegraining
      if(force->cg_active())
        error->cg(FLERR,"rolling model epsd2");
    }

    void surfacesIntersect(SurfacesIntersectData & sidata, ForceData & i_forces, ForceData & j_forces) 
    {
      double r_torque[3];
      vectorZeroize3D(r_torque);

      if(sidata.contact_flags) *sidata.contact_flags |= CONTACT_ROLLING_MODEL;

      const double radi = sidata.radi;
      const double radj = sidata.radj;
      double reff=sidata.is_wall ? radi : (radi*radj/(radi+radj));

#ifdef SUPERQUADRIC_ACTIVE_FLAG
      if(sidata.is_non_spherical && atom->superquadric_flag)
        reff = sidata.reff;
#endif

      if(sidata.is_wall) {
        const double wr1 = sidata.wr1;
        const double wr2 = sidata.wr2;
        const double wr3 = sidata.wr3;

        calcRollTorque(r_torque,sidata,reff,wr1,wr2,wr3);

      } else {
        double wr_roll[3];

        const int i = sidata.i;
        const int j = sidata.j;

        const double * const * const omega = atom->omega;

        // relative rotational velocity
        vectorSubtract3D(omega[i],omega[j],wr_roll);

        calcRollTorque(r_torque,sidata,reff,wr_roll[0],wr_roll[1],wr_roll[2]);

      }

      i_forces.delta_torque[0] -= r_torque[0];
      i_forces.delta_torque[1] -= r_torque[1];
      i_forces.delta_torque[2] -= r_torque[2];
      j_forces.delta_torque[0] += r_torque[0];
      j_forces.delta_torque[1] += r_torque[1];
      j_forces.delta_torque[2] += r_torque[2];
    }

    void surfacesClose(SurfacesCloseData & scdata, ForceData&, ForceData&)
    {
      if(scdata.contact_flags) *scdata.contact_flags &= ~CONTACT_ROLLING_MODEL;
      double * const c_history = &scdata.contact_history[history_offset];
      c_history[0] = 0.0; // this is the r_torque_old
      c_history[1] = 0.0; // this is the r_torque_old
      c_history[2] = 0.0; // this is the r_torque_old
    }

    void beginPass(SurfacesIntersectData&, ForceData&, ForceData&){}
    void endPass(SurfacesIntersectData&, ForceData&, ForceData&){}

  private:
    double ** coeffRollFrict;
    int history_offset;
    bool torsion_torque;

    void calcRollTorque(double (&r_torque)[3],const SurfacesIntersectData & sidata,double reff,double wr1,double wr2,double wr3) {

      double wr_tot[3], dr_torque[3];

      const double enx = sidata.en[0];
      const double eny = sidata.en[1];
      const double enz = sidata.en[2];

      const double dt = update->dt; 

      double * const c_history = &sidata.contact_history[history_offset]; // requires Style::TANGENTIAL == TANGENTIAL_HISTORY
      const double rmu= coeffRollFrict[sidata.itype][sidata.jtype];

      if(torsion_torque) {
        // use full relative rotation for rolling torque
        wr_tot[0] = wr1;
        wr_tot[1] = wr2;
        wr_tot[2] = wr3;
      } else {
        // remove normal (torsion) part of relative rotation
        // use only tangential parts for rolling torque
        double wr_n[3];
        const double wr_dot_delta = wr1*enx+ wr2*eny + wr3*enz;
        wr_n[0] = enx * wr_dot_delta;
        wr_n[1] = eny * wr_dot_delta;
        wr_n[2] = enz * wr_dot_delta;
        wr_tot[0] = wr1 - wr_n[0]; // wr_t[0];
        wr_tot[1] = wr2 - wr_n[1]; // wr_t[1];
        wr_tot[2] = wr3 - wr_n[2]; // wr_t[2];
      }

      // spring (reff depends on wall-particle or particle-particle contact)
      const double kr = sidata.kt*reff*reff; 

      vectorScalarMult3D(wr_tot,dt*kr,dr_torque);

      r_torque[0] = c_history[0] + dr_torque[0];
      r_torque[1] = c_history[1] + dr_torque[1];
      r_torque[2] = c_history[2] + dr_torque[2];

      // limit max. torque
      const double r_torque_mag = vectorMag3D(r_torque);
      const double r_torque_max = fabs(sidata.Fn)*reff*rmu;
      if(r_torque_mag > r_torque_max)
      {
        //printf("[%d] %e > %e\n", update->ntimestep, r_torque_mag, r_torque_max);
        const double factor = r_torque_max / r_torque_mag;

        r_torque[0] *= factor;
        r_torque[1] *= factor;
        r_torque[2] *= factor;

      } else {
        // nothing to do
      }

      const bool update_history = sidata.computeflag && sidata.shearupdate;
      if (update_history)
      {
          // save rolling torque due to spring
          c_history[0] = r_torque[0];
          c_history[1] = r_torque[1];
          c_history[2] = r_torque[2];
      }

      // dashpot only for the original epsd model

    }
  };
}
}
#endif // ROLLING_MODEL_EPSD_H_
#endif