Grid/lib/qcd/action/fermion/MobiusEOFAFermion.cc

/*************************************************************************************

Grid physics library, www.github.com/paboyle/Grid

Source file: ./lib/qcd/action/fermion/MobiusEOFAFermion.cc

Copyright (C) 2017

Author: Peter Boyle <pabobyle@ph.ed.ac.uk>
Author: Peter Boyle <paboyle@ph.ed.ac.uk>
Author: Peter Boyle <peterboyle@Peters-MacBook-Pro-2.local>
Author: paboyle <paboyle@ph.ed.ac.uk>
Author: David Murphy <dmurphy@phys.columbia.edu>

This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 2 of the License, or
(at your option) any later version.

This program 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.  See the
GNU General Public License for more details.

You should have received a copy of the GNU General Public License along
with this program; if not, write to the Free Software Foundation, Inc.,
51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.

See the full license in the file "LICENSE" in the top level distribution directory
*************************************************************************************/
			   /*  END LEGAL */

#include <Grid/Grid_Eigen_Dense.h>
#include <Grid/qcd/action/fermion/FermionCore.h>
#include <Grid/qcd/action/fermion/MobiusEOFAFermion.h>

NAMESPACE_BEGIN(Grid);

template<class Impl>
MobiusEOFAFermion<Impl>::MobiusEOFAFermion(
					   GaugeField            &_Umu,
					   GridCartesian         &FiveDimGrid,
					   GridRedBlackCartesian &FiveDimRedBlackGrid,
					   GridCartesian         &FourDimGrid,
					   GridRedBlackCartesian &FourDimRedBlackGrid,
					   RealD _mq1, RealD _mq2, RealD _mq3,
					   RealD _shift, int _pm, RealD _M5,
					   RealD _b, RealD _c, const ImplParams &p) :
  AbstractEOFAFermion<Impl>(_Umu, FiveDimGrid, FiveDimRedBlackGrid,
			    FourDimGrid, FourDimRedBlackGrid, _mq1, _mq2, _mq3,
			    _shift, _pm, _M5, _b, _c, p)
{
  int Ls = this->Ls;

  RealD eps = 1.0;
  Approx::zolotarev_data *zdata = Approx::higham(eps, this->Ls);
  assert(zdata->n == this->Ls);

  std::cout << GridLogMessage << "MobiusEOFAFermion (b=" << _b <<
    ",c=" << _c << ") with Ls=" << Ls << std::endl;
  this->SetCoefficientsTanh(zdata, _b, _c);
  std::cout << GridLogMessage << "EOFA parameters: (mq1=" << _mq1 <<
    ",mq2=" << _mq2 << ",mq3=" << _mq3 << ",shift=" << _shift <<
    ",pm=" << _pm << ")" << std::endl;

  Approx::zolotarev_free(zdata);

  if(_shift != 0.0){
    SetCoefficientsPrecondShiftOps();
  } else {
    Mooee_shift.resize(Ls, 0.0);
    MooeeInv_shift_lc.resize(Ls, 0.0);
    MooeeInv_shift_norm.resize(Ls, 0.0);
    MooeeInvDag_shift_lc.resize(Ls, 0.0);
    MooeeInvDag_shift_norm.resize(Ls, 0.0);
  }
}

/****************************************************************
 * Additional EOFA operators only called outside the inverter.  
 * Since speed is not essential, simple axpby-style
 * implementations should be fine.
 ***************************************************************/
template<class Impl>
void MobiusEOFAFermion<Impl>::Omega(const FermionField& psi, FermionField& Din, int sign, int dag)
{
  int Ls = this->Ls;
  RealD alpha = this->alpha;

  Din = zero;
  if((sign == 1) && (dag == 0)) { // \Omega_{+}
    for(int s=0; s<Ls; ++s){
      axpby_ssp(Din, 0.0, psi, 2.0*std::pow(1.0-alpha,Ls-s-1)/std::pow(1.0+alpha,Ls-s), psi, s, 0);
    }
  } else if((sign == -1) && (dag == 0)) { // \Omega_{-}
    for(int s=0; s<Ls; ++s){
      axpby_ssp(Din, 0.0, psi, 2.0*std::pow(1.0-alpha,s)/std::pow(1.0+alpha,s+1), psi, s, 0);
    }
  } else if((sign == 1 ) && (dag == 1)) { // \Omega_{+}^{\dagger}
    for(int sp=0; sp<Ls; ++sp){
      axpby_ssp(Din, 1.0, Din, 2.0*std::pow(1.0-alpha,Ls-sp-1)/std::pow(1.0+alpha,Ls-sp), psi, 0, sp);
    }
  } else if((sign == -1) && (dag == 1)) { // \Omega_{-}^{\dagger}
    for(int sp=0; sp<Ls; ++sp){
      axpby_ssp(Din, 1.0, Din, 2.0*std::pow(1.0-alpha,sp)/std::pow(1.0+alpha,sp+1), psi, 0, sp);
    }
  }
}

// This is the operator relating the usual Ddwf to TWQCD's EOFA Dirac operator (arXiv:1706.05843, Eqn. 6).
// It also relates the preconditioned and unpreconditioned systems described in Appendix B.2.
template<class Impl>
void MobiusEOFAFermion<Impl>::Dtilde(const FermionField& psi, FermionField& chi)
{
  int Ls    = this->Ls;
  RealD b   = 0.5 * ( 1.0 + this->alpha );
  RealD c   = 0.5 * ( 1.0 - this->alpha );
  RealD mq1 = this->mq1;

  for(int s=0; s<Ls; ++s){
    if(s == 0) {
      axpby_ssp_pminus(chi, b, psi, -c, psi, s, s+1);
      axpby_ssp_pplus (chi, 1.0, chi, mq1*c, psi, s, Ls-1);
    } else if(s == (Ls-1)) {
      axpby_ssp_pminus(chi, b, psi, mq1*c, psi, s, 0);
      axpby_ssp_pplus (chi, 1.0, chi, -c, psi, s, s-1);
    } else {
      axpby_ssp_pminus(chi, b, psi, -c, psi, s, s+1);
      axpby_ssp_pplus (chi, 1.0, chi, -c, psi, s, s-1);
    }
  }
}

template<class Impl>
void MobiusEOFAFermion<Impl>::DtildeInv(const FermionField& psi, FermionField& chi)
{
  int Ls = this->Ls;
  RealD m = this->mq1;
  RealD c = 0.5 * this->alpha;
  RealD d = 0.5;

  RealD DtInv_p(0.0), DtInv_m(0.0);
  RealD N = std::pow(c+d,Ls) + m*std::pow(c-d,Ls);
  FermionField tmp(this->FermionGrid());

  for(int s=0; s<Ls; ++s){
    for(int sp=0; sp<Ls; ++sp){

      DtInv_p = m * std::pow(-1.0,s-sp+1) * std::pow(c-d,Ls+s-sp) / std::pow(c+d,s-sp+1) / N;
      DtInv_p += (s < sp) ? 0.0 : std::pow(-1.0,s-sp) * std::pow(c-d,s-sp) / std::pow(c+d,s-sp+1);
      DtInv_m = m * std::pow(-1.0,sp-s+1) * std::pow(c-d,Ls+sp-s) / std::pow(c+d,sp-s+1) / N;
      DtInv_m += (s > sp) ? 0.0 : std::pow(-1.0,sp-s) * std::pow(c-d,sp-s) / std::pow(c+d,sp-s+1);

      if(sp == 0){
	axpby_ssp_pplus (tmp, 0.0, tmp, DtInv_p, psi, s, sp);
	axpby_ssp_pminus(tmp, 0.0, tmp, DtInv_m, psi, s, sp);
      } else {
	axpby_ssp_pplus (tmp, 1.0, tmp, DtInv_p, psi, s, sp);
	axpby_ssp_pminus(tmp, 1.0, tmp, DtInv_m, psi, s, sp);
      }

    }}
}

/*****************************************************************************************************/

template<class Impl>
RealD MobiusEOFAFermion<Impl>::M(const FermionField& psi, FermionField& chi)
{
  int Ls = this->Ls;

  FermionField Din(psi._grid);

  this->Meooe5D(psi, Din);
  this->DW(Din, chi, DaggerNo);
  axpby(chi, 1.0, 1.0, chi, psi);
  this->M5D(psi, chi);
  return(norm2(chi));
}

template<class Impl>
RealD MobiusEOFAFermion<Impl>::Mdag(const FermionField& psi, FermionField& chi)
{
  int Ls = this->Ls;

  FermionField Din(psi._grid);

  this->DW(psi, Din, DaggerYes);
  this->MeooeDag5D(Din, chi);
  this->M5Ddag(psi, chi);
  axpby(chi, 1.0, 1.0, chi, psi);
  return(norm2(chi));
}

/********************************************************************
 * Performance critical fermion operators called inside the inverter
 ********************************************************************/

template<class Impl>
void MobiusEOFAFermion<Impl>::M5D(const FermionField& psi, FermionField& chi)
{
  int Ls = this->Ls;

  std::vector<Coeff_t> diag(Ls,1.0);
  std::vector<Coeff_t> upper(Ls,-1.0);  upper[Ls-1] = this->mq1;
  std::vector<Coeff_t> lower(Ls,-1.0);  lower[0]    = this->mq1;

  // no shift term
  if(this->shift == 0.0){ this->M5D(psi, chi, chi, lower, diag, upper); }

  // fused M + shift operation
  else{ this->M5D_shift(psi, chi, chi, lower, diag, upper, Mooee_shift); }
}

template<class Impl>
void MobiusEOFAFermion<Impl>::M5Ddag(const FermionField& psi, FermionField& chi)
{
  int Ls = this->Ls;

  std::vector<Coeff_t> diag(Ls,1.0);
  std::vector<Coeff_t> upper(Ls,-1.0);  upper[Ls-1] = this->mq1;
  std::vector<Coeff_t> lower(Ls,-1.0);  lower[0]    = this->mq1;

  // no shift term
  if(this->shift == 0.0){ this->M5Ddag(psi, chi, chi, lower, diag, upper); }

  // fused M + shift operation
  else{ this->M5Ddag_shift(psi, chi, chi, lower, diag, upper, Mooee_shift); }
}

// half checkerboard operations
template<class Impl>
void MobiusEOFAFermion<Impl>::Mooee(const FermionField& psi, FermionField& chi)
{
  int Ls = this->Ls;

  // coefficients of Mooee
  std::vector<Coeff_t> diag = this->bee;
  std::vector<Coeff_t> upper(Ls);
  std::vector<Coeff_t> lower(Ls);
  for(int s=0; s<Ls; s++){
    upper[s] = -this->cee[s];
    lower[s] = -this->cee[s];
  }
  upper[Ls-1] *= -this->mq1;
  lower[0]    *= -this->mq1;

  // no shift term
  if(this->shift == 0.0){ this->M5D(psi, psi, chi, lower, diag, upper); }

  // fused M + shift operation
  else { this->M5D_shift(psi, psi, chi, lower, diag, upper, Mooee_shift); }
}

template<class Impl>
void MobiusEOFAFermion<Impl>::MooeeDag(const FermionField& psi, FermionField& chi)
{
  int Ls = this->Ls;

  // coefficients of MooeeDag
  std::vector<Coeff_t> diag = this->bee;
  std::vector<Coeff_t> upper(Ls);
  std::vector<Coeff_t> lower(Ls);
  for(int s=0; s<Ls; s++){
    if(s==0) {
      upper[s] = -this->cee[s+1];
      lower[s] = this->mq1*this->cee[Ls-1];
    } else if(s==(Ls-1)) {
      upper[s] = this->mq1*this->cee[0];
      lower[s] = -this->cee[s-1];
    } else {
      upper[s] = -this->cee[s+1];
      lower[s] = -this->cee[s-1];
    }
  }

  // no shift term
  if(this->shift == 0.0){ this->M5Ddag(psi, psi, chi, lower, diag, upper); }

  // fused M + shift operation
  else{ this->M5Ddag_shift(psi, psi, chi, lower, diag, upper, Mooee_shift); }
}

/****************************************************************************************/

// Computes coefficients for applying Cayley preconditioned shift operators
//  (Mooee + \Delta) --> Mooee_shift
//  (Mooee + \Delta)^{-1} --> MooeeInv_shift_lc, MooeeInv_shift_norm
//  (Mooee + \Delta)^{-dag} --> MooeeInvDag_shift_lc, MooeeInvDag_shift_norm
// For the latter two cases, the operation takes the form
//  [ (Mooee + \Delta)^{-1} \psi ]_{i} = Mooee_{ij} \psi_{j} +
//      ( MooeeInv_shift_norm )_{i} ( \sum_{j} [ MooeeInv_shift_lc ]_{j} P_{pm} \psi_{j} )
template<class Impl>
void MobiusEOFAFermion<Impl>::SetCoefficientsPrecondShiftOps()
{
  int   Ls    = this->Ls;
  int   pm    = this->pm;
  RealD alpha = this->alpha;
  RealD k     = this->k;
  RealD mq1   = this->mq1;
  RealD shift = this->shift;

  // Initialize
  Mooee_shift.resize(Ls);
  MooeeInv_shift_lc.resize(Ls);
  MooeeInv_shift_norm.resize(Ls);
  MooeeInvDag_shift_lc.resize(Ls);
  MooeeInvDag_shift_norm.resize(Ls);

  // Construct Mooee_shift
  int idx(0);
  Coeff_t N = ( (pm == 1) ? 1.0 : -1.0 ) * (2.0*shift*k) *
    ( std::pow(alpha+1.0,Ls) + mq1*std::pow(alpha-1.0,Ls) );
  for(int s=0; s<Ls; ++s){
    idx = (pm == 1) ? (s) : (Ls-1-s);
    Mooee_shift[idx] = N * std::pow(-1.0,s) * std::pow(alpha-1.0,s) / std::pow(alpha+1.0,Ls+s+1);
  }

  // Tridiagonal solve for MooeeInvDag_shift_lc
  {
    Coeff_t m(0.0);
    std::vector<Coeff_t> d = Mooee_shift;
    std::vector<Coeff_t> u(Ls,0.0);
    std::vector<Coeff_t> y(Ls,0.0);
    std::vector<Coeff_t> q(Ls,0.0);
    if(pm == 1){ u[0] = 1.0; }
    else{ u[Ls-1] = 1.0; }

    // Tridiagonal matrix algorithm + Sherman-Morrison formula
    //
    // We solve
    //  ( Mooee' + u \otimes v ) MooeeInvDag_shift_lc = Mooee_shift
    // where Mooee' is the tridiagonal part of Mooee_{+}, and
    // u = (1,0,...,0) and v = (0,...,0,mq1*cee[0]) are chosen
    // so that the outer-product u \otimes v gives the (0,Ls-1)
    // entry of Mooee_{+}.
    //
    // We do this as two solves: Mooee'*y = d and Mooee'*q = u,
    // and then construct the solution to the original system
    //  MooeeInvDag_shift_lc = y - <v,y> / ( 1 + <v,q> ) q
    if(pm == 1){
      for(int s=1; s<Ls; ++s){
	m = -this->cee[s] / this->bee[s-1];
	d[s] -= m*d[s-1];
	u[s] -= m*u[s-1];
      }
    }
    y[Ls-1] = d[Ls-1] / this->bee[Ls-1];
    q[Ls-1] = u[Ls-1] / this->bee[Ls-1];
    for(int s=Ls-2; s>=0; --s){
      if(pm == 1){
	y[s] = d[s] / this->bee[s];
	q[s] = u[s] / this->bee[s];
      } else {
	y[s] = ( d[s] + this->cee[s]*y[s+1] ) / this->bee[s];
	q[s] = ( u[s] + this->cee[s]*q[s+1] ) / this->bee[s];
      }
    }

    // Construct MooeeInvDag_shift_lc
    for(int s=0; s<Ls; ++s){
      if(pm == 1){
	MooeeInvDag_shift_lc[s] = y[s] - mq1*this->cee[0]*y[Ls-1] /
	  (1.0+mq1*this->cee[0]*q[Ls-1]) * q[s];
      } else {
	MooeeInvDag_shift_lc[s] = y[s] - mq1*this->cee[Ls-1]*y[0] /
	  (1.0+mq1*this->cee[Ls-1]*q[0]) * q[s];
      }
    }

    // Compute remaining coefficients
    N = (pm == 1) ? (1.0 + MooeeInvDag_shift_lc[Ls-1]) : (1.0 + MooeeInvDag_shift_lc[0]);
    for(int s=0; s<Ls; ++s){

      // MooeeInv_shift_lc
      if(pm == 1){ MooeeInv_shift_lc[s] = std::pow(this->bee[s],s) * std::pow(this->cee[s],Ls-1-s); }
      else{ MooeeInv_shift_lc[s] = std::pow(this->bee[s],Ls-1-s) * std::pow(this->cee[s],s); }

      // MooeeInv_shift_norm
      MooeeInv_shift_norm[s] = -MooeeInvDag_shift_lc[s] /
	( std::pow(this->bee[s],Ls) + mq1*std::pow(this->cee[s],Ls) ) / N;

      // MooeeInvDag_shift_norm
      if(pm == 1){ MooeeInvDag_shift_norm[s] = -std::pow(this->bee[s],s) * std::pow(this->cee[s],Ls-1-s) /
	  ( std::pow(this->bee[s],Ls) + mq1*std::pow(this->cee[s],Ls) ) / N; }
      else{ MooeeInvDag_shift_norm[s] = -std::pow(this->bee[s],Ls-1-s) * std::pow(this->cee[s],s) /
	  ( std::pow(this->bee[s],Ls) + mq1*std::pow(this->cee[s],Ls) ) / N; }
    }
  }
}

// Recompute coefficients for a different value of shift constant
template<class Impl>
void MobiusEOFAFermion<Impl>::RefreshShiftCoefficients(RealD new_shift)
{
  this->shift = new_shift;
  if(new_shift != 0.0){
    SetCoefficientsPrecondShiftOps();
  } else {
    int Ls = this->Ls;
    Mooee_shift.resize(Ls,0.0);
    MooeeInv_shift_lc.resize(Ls,0.0);
    MooeeInv_shift_norm.resize(Ls,0.0);
    MooeeInvDag_shift_lc.resize(Ls,0.0);
    MooeeInvDag_shift_norm.resize(Ls,0.0);
  }
}

template<class Impl>
void MobiusEOFAFermion<Impl>::MooeeInternalCompute(int dag, int inv,
						   Vector<iSinglet<Simd> >& Matp, Vector<iSinglet<Simd> >& Matm)
{
  int Ls = this->Ls;

  GridBase* grid = this->FermionRedBlackGrid();
  int LLs = grid->_rdimensions[0];

  if(LLs == Ls){ return; } // Not vectorised in 5th direction

  Eigen::MatrixXcd Pplus  = Eigen::MatrixXcd::Zero(Ls,Ls);
  Eigen::MatrixXcd Pminus = Eigen::MatrixXcd::Zero(Ls,Ls);

  for(int s=0; s<Ls; s++){
    Pplus(s,s)  = this->bee[s];
    Pminus(s,s) = this->bee[s];
  }

  for(int s=0; s<Ls-1; s++){
    Pminus(s,s+1) = -this->cee[s];
    Pplus(s+1,s) = -this->cee[s+1];
  }

  Pplus (0,Ls-1) = this->mq1*this->cee[0];
  Pminus(Ls-1,0) = this->mq1*this->cee[Ls-1];

  if(this->shift != 0.0){
    RealD c = 0.5 * this->alpha;
    RealD d = 0.5;
    RealD N = this->shift * this->k * ( std::pow(c+d,Ls) + this->mq1*std::pow(c-d,Ls) );
    if(this->pm == 1) {
      for(int s=0; s<Ls; ++s){
	Pplus(s,Ls-1) += N * std::pow(-1.0,s) * std::pow(c-d,s) / std::pow(c+d,Ls+s+1);
      }
    } else {
      for(int s=0; s<Ls; ++s){
	Pminus(s,0) += N * std::pow(-1.0,s+1) * std::pow(c-d,Ls-1-s) / std::pow(c+d,2*Ls-s);
      }
    }
  }

  Eigen::MatrixXcd PplusMat ;
  Eigen::MatrixXcd PminusMat;

  if(inv) {
    PplusMat  = Pplus.inverse();
    PminusMat = Pminus.inverse();
  } else {
    PplusMat  = Pplus;
    PminusMat = Pminus;
  }

  if(dag){
    PplusMat.adjointInPlace();
    PminusMat.adjointInPlace();
  }

  typedef typename SiteHalfSpinor::scalar_type scalar_type;
  const int Nsimd = Simd::Nsimd();
  Matp.resize(Ls*LLs);
  Matm.resize(Ls*LLs);

  for(int s2=0; s2<Ls; s2++){
    for(int s1=0; s1<LLs; s1++){
      int istride = LLs;
      int ostride = 1;
      Simd Vp;
      Simd Vm;
      scalar_type *sp = (scalar_type*) &Vp;
      scalar_type *sm = (scalar_type*) &Vm;
      for(int l=0; l<Nsimd; l++){
	if(switcheroo<Coeff_t>::iscomplex()) {
	  sp[l] = PplusMat (l*istride+s1*ostride,s2);
	  sm[l] = PminusMat(l*istride+s1*ostride,s2);
	} else {
	  // if real
	  scalar_type tmp;
	  tmp = PplusMat (l*istride+s1*ostride,s2);
	  sp[l] = scalar_type(tmp.real(),tmp.real());
	  tmp = PminusMat(l*istride+s1*ostride,s2);
	  sm[l] = scalar_type(tmp.real(),tmp.real());
	}
      }
      Matp[LLs*s2+s1] = Vp;
      Matm[LLs*s2+s1] = Vm;
    }}
}

FermOpTemplateInstantiate(MobiusEOFAFermion);
GparityFermOpTemplateInstantiate(MobiusEOFAFermion);

NAMESPACE_END(Grid);