Working aas good as possible on 48^3 in double

CG improvements for smoother
Serialisation removal
2025-11-04 05:54:32 +00:00 · 2024-05-16 10:55:45 -04:00 · 2024-05-16 10:55:18 -04:00 · 2024-05-16 10:49:04 -04:00 · 2024-05-16 10:48:23 -04:00 · 2024-04-30 05:26:06 -04:00
88 changed files with 9847 additions and 1101 deletions
--- a/Grid/GridCore.h
+++ b/Grid/GridCore.h
@@ -59,6 +59,7 @@ Author: paboyle <paboyle@ph.ed.ac.uk>
 #include <Grid/lattice/Lattice.h>      
 #include <Grid/cshift/Cshift.h>       
 #include <Grid/stencil/Stencil.h>      
 #include <Grid/stencil/GeneralLocalStencil.h>      
 #include <Grid/parallelIO/BinaryIO.h>
 #include <Grid/algorithms/Algorithms.h>   
 NAMESPACE_CHECK(GridCore)
--- a/Grid/algorithms/Algorithms.h
+++ b/Grid/algorithms/Algorithms.h
@@ -29,6 +29,9 @@ Author: Peter Boyle <paboyle@ph.ed.ac.uk>
 #ifndef GRID_ALGORITHMS_H
 #define GRID_ALGORITHMS_H
 NAMESPACE_CHECK(blas);
 #include <Grid/algorithms/blas/BatchedBlas.h>
 NAMESPACE_CHECK(algorithms);
 #include <Grid/algorithms/SparseMatrix.h>
 #include <Grid/algorithms/LinearOperator.h>
@@ -44,7 +47,10 @@ NAMESPACE_CHECK(SparseMatrix);
 #include <Grid/algorithms/approx/RemezGeneral.h>
 #include <Grid/algorithms/approx/ZMobius.h>
 NAMESPACE_CHECK(approx);
-#include <Grid/algorithms/iterative/Deflation.h>
+#include <Grid/algorithms/deflation/Deflation.h>
 #include <Grid/algorithms/deflation/MultiRHSBlockProject.h>
 #include <Grid/algorithms/deflation/MultiRHSDeflation.h>
 NAMESPACE_CHECK(deflation);
 #include <Grid/algorithms/iterative/ConjugateGradient.h>
 NAMESPACE_CHECK(ConjGrad);
 #include <Grid/algorithms/iterative/BiCGSTAB.h>
@@ -67,10 +73,11 @@ NAMESPACE_CHECK(BiCGSTAB);
 #include <Grid/algorithms/iterative/MixedPrecisionFlexibleGeneralisedMinimalResidual.h>
 #include <Grid/algorithms/iterative/ImplicitlyRestartedLanczos.h>
 #include <Grid/algorithms/iterative/PowerMethod.h>
-
+#include <Grid/algorithms/iterative/AdefGeneric.h>
 #include <Grid/algorithms/iterative/AdefMrhs.h>
 NAMESPACE_CHECK(PowerMethod);
-#include <Grid/algorithms/CoarsenedMatrix.h>
+#include <Grid/algorithms/multigrid/MultiGrid.h>
-NAMESPACE_CHECK(CoarsendMatrix);
+NAMESPACE_CHECK(multigrid);
 #include <Grid/algorithms/FFT.h>
 #endif
--- a/Grid/algorithms/FFT.h
+++ b/Grid/algorithms/FFT.h
@@ -29,7 +29,7 @@ Author: Peter Boyle <paboyle@ph.ed.ac.uk>
 #define _GRID_FFT_H_
 #ifdef HAVE_FFTW
-#ifdef USE_MKL
+#if defined(USE_MKL) || defined(GRID_SYCL)
 #include <fftw/fftw3.h>
 #else
 #include <fftw3.h>
--- a/Grid/algorithms/LinearOperator.h
+++ b/Grid/algorithms/LinearOperator.h
@@ -145,6 +145,44 @@ public:
  }
 };
 ////////////////////////////////////////////////////////////////////
 // Create a shifted HermOp
 ////////////////////////////////////////////////////////////////////
 template<class Field>
 class ShiftedHermOpLinearOperator : public LinearOperatorBase<Field> {
  LinearOperatorBase<Field> &_Mat;
  RealD _shift;
 public:
  ShiftedHermOpLinearOperator(LinearOperatorBase<Field> &Mat,RealD shift): _Mat(Mat), _shift(shift){};
  // Support for coarsening to a multigrid
  void OpDiag (const Field &in, Field &out) {
    assert(0);
  }
  void OpDir  (const Field &in, Field &out,int dir,int disp) {
    assert(0);
  }
  void OpDirAll  (const Field &in, std::vector<Field> &out){
    assert(0);
  };
  void Op     (const Field &in, Field &out){
    HermOp(in,out);
  }
  void AdjOp     (const Field &in, Field &out){
    HermOp(in,out);
  }
  void HermOpAndNorm(const Field &in, Field &out,RealD &n1,RealD &n2){
    HermOp(in,out);
    ComplexD dot = innerProduct(in,out);
    n1=real(dot);
    n2=norm2(out);
  }
  void HermOp(const Field &in, Field &out){
    _Mat.HermOp(in,out);
    out = out + _shift*in;
  }
 };
 ////////////////////////////////////////////////////////////////////
 // Wrap an already herm matrix
 ////////////////////////////////////////////////////////////////////
--- a/Grid/algorithms/approx/Chebyshev.h
+++ b/Grid/algorithms/approx/Chebyshev.h
@@ -90,9 +90,8 @@ public:
    order=_order;
    if(order < 2) exit(-1);
-    Coeffs.resize(order);
+    Coeffs.resize(order,0.0);
-    Coeffs.assign(0.,order);
+    Coeffs[order-1] = 1.0;
    Coeffs[order-1] = 1.;
  };
  // PB - more efficient low pass drops high modes above the low as 1/x uses all Chebyshev's.
--- a/Grid/algorithms/approx/MultiShiftFunction.h
+++ b/Grid/algorithms/approx/MultiShiftFunction.h
@@ -40,7 +40,7 @@ public:
  RealD norm;
  RealD lo,hi;
-  MultiShiftFunction(int n,RealD _lo,RealD _hi): poles(n), residues(n), lo(_lo), hi(_hi) {;};
+  MultiShiftFunction(int n,RealD _lo,RealD _hi): poles(n), residues(n), tolerances(n), lo(_lo), hi(_hi) {;};
  RealD approx(RealD x);
  void csv(std::ostream &out);
  void gnuplot(std::ostream &out);
--- a/Grid/algorithms/blas/BatchedBlas.h
+++ b/Grid/algorithms/blas/BatchedBlas.h
@@ -42,6 +42,7 @@ Author: Peter Boyle <pboyle@bnl.gov>
 #ifdef GRID_ONE_MKL
 #include <oneapi/mkl.hpp>
 #endif
 ///////////////////////////////////////////////////////////////////////	  
 // Need to rearrange lattice data to be in the right format for a
 // batched multiply. Might as well make these static, dense packed
@@ -633,7 +634,6 @@ public:
    deviceVector<ComplexD> beta_p(1);
    acceleratorCopyToDevice((void *)&alpha,(void *)&alpha_p[0],sizeof(ComplexD));
    acceleratorCopyToDevice((void *)&beta ,(void *)&beta_p[0],sizeof(ComplexD));
    //    std::cout << "blasZgemmStridedBatched mnk  "<<m<<","<<n<<","<<k<<" count "<<batchCount<<std::endl;
    //    std::cout << "blasZgemmStridedBatched ld   "<<lda<<","<<ldb<<","<<ldc<<std::endl;
    //    std::cout << "blasZgemmStridedBatched sd   "<<sda<<","<<sdb<<","<<sdc<<std::endl;
--- a/Grid/algorithms/deflation/Deflation.h
+++ b/Grid/algorithms/deflation/Deflation.h
--- a/Grid/algorithms/deflation/MultiRHSBlockProject.h
+++ b/Grid/algorithms/deflation/MultiRHSBlockProject.h
@@ -0,0 +1,513 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: MultiRHSDeflation.h
    Copyright (C) 2023
 Author: Peter Boyle <pboyle@bnl.gov>
    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 */
 #pragma once
 NAMESPACE_BEGIN(Grid);
 /* 
   MultiRHS block projection
   Import basis -> nblock x nbasis x  (block x internal) 
   Import vector of fine lattice objects -> nblock x nrhs x (block x internal) 
   => coarse_(nrhs x nbasis )^block = via batched GEMM
 //template<class vobj,class CComplex,int nbasis,class VLattice>
 //inline void blockProject(Lattice<iVector<CComplex,nbasis > > &coarseData,
 //			   const VLattice &fineData,
 //			   const VLattice &Basis)
 */
 template<class Field>
 class MultiRHSBlockProject
 {
 public:
  typedef typename Field::scalar_type   scalar;
  typedef typename Field::scalar_object scalar_object;
  typedef Field Fermion;
  int nbasis;
  GridBase *coarse_grid;
  GridBase *fine_grid;
  uint64_t block_vol;
  uint64_t fine_vol;
  uint64_t coarse_vol;
  uint64_t words;
  // Row major layout "C" order:
  // BLAS_V[coarse_vol][nbasis][block_vol][words]
  // BLAS_F[coarse_vol][nrhs][block_vol][words]
  // BLAS_C[coarse_vol][nrhs][nbasis]
  /*
   * in Fortran column major notation (cuBlas order)
   *
   * Vxb = [v1(x)][..][vn(x)] ... x coarse vol
   *
   * Fxr = [r1(x)][..][rm(x)] ... x coarse vol
   *
   * Block project:
   * C_br = V^dag F x coarse vol
   *
   * Block promote:
   * F_xr = Vxb Cbr x coarse_vol
   */  
  deviceVector<scalar> BLAS_V;      // words * block_vol * nbasis x coarse_vol 
  deviceVector<scalar> BLAS_F;      // nrhs x fine_vol * words   -- the sources
  deviceVector<scalar> BLAS_C;      // nrhs x coarse_vol * nbasis -- the coarse coeffs
  RealD blasNorm2(deviceVector<scalar> &blas)
  {
    scalar ss(0.0);
    std::vector<scalar> tmp(blas.size());
    acceleratorCopyFromDevice(&blas[0],&tmp[0],blas.size()*sizeof(scalar));
    for(int64_t s=0;s<blas.size();s++){
      ss=ss+tmp[s]*adj(tmp[s]);
    }
    coarse_grid->GlobalSum(ss);
    return real(ss);
  }
  MultiRHSBlockProject(){};
 ~MultiRHSBlockProject(){ Deallocate(); };
  void Deallocate(void)
  {
    nbasis=0;
    coarse_grid=nullptr;
    fine_grid=nullptr;
    fine_vol=0;
    block_vol=0;
    coarse_vol=0;
    words=0;
    BLAS_V.resize(0);
    BLAS_F.resize(0);
    BLAS_C.resize(0);
  }
  void Allocate(int _nbasis,GridBase *_fgrid,GridBase *_cgrid)
  {
    nbasis=_nbasis;
    fine_grid=_fgrid;
    coarse_grid=_cgrid;
    fine_vol   = fine_grid->lSites();
    coarse_vol = coarse_grid->lSites();
    block_vol = fine_vol/coarse_vol;
    words = sizeof(scalar_object)/sizeof(scalar);
    BLAS_V.resize (fine_vol * words * nbasis );
  }
  void ImportFineGridVectors(std::vector <Field > &vecs, deviceVector<scalar> &blas)
  {
    int nvec = vecs.size();
    typedef typename Field::vector_object vobj;
    //    std::cout << GridLogMessage <<" BlockProjector importing "<<nvec<< " fine grid vectors" <<std::endl;
    assert(vecs[0].Grid()==fine_grid);
    subdivides(coarse_grid,fine_grid); // require they map
    int _ndimension = coarse_grid->_ndimension;
    assert(block_vol == fine_grid->oSites() / coarse_grid->oSites());
    Coordinate  block_r      (_ndimension);
    for(int d=0 ; d<_ndimension;d++){
      block_r[d] = fine_grid->_rdimensions[d] / coarse_grid->_rdimensions[d];
    }
    uint64_t sz = blas.size();
    acceleratorMemSet(&blas[0],0,blas.size()*sizeof(scalar));
    Coordinate fine_rdimensions = fine_grid->_rdimensions;
    Coordinate coarse_rdimensions = coarse_grid->_rdimensions;
    int64_t bv= block_vol;
    for(int v=0;v<vecs.size();v++){
      //      std::cout << " BlockProjector importing vector"<<v<<" "<<norm2(vecs[v])<<std::endl;
      autoView( fineData   , vecs[v], AcceleratorRead);
      auto blasData_p  = &blas[0];
      auto fineData_p  = &fineData[0];
      int64_t osites = fine_grid->oSites();
      // loop over fine sites
      const int Nsimd = vobj::Nsimd();
      //      std::cout << "sz "<<sz<<std::endl;
      //      std::cout << "prod "<<Nsimd * coarse_grid->oSites() * block_vol * nvec * words<<std::endl;
      assert(sz == Nsimd * coarse_grid->oSites() * block_vol * nvec * words);
      uint64_t lwords= words; // local variable for copy in to GPU
      accelerator_for(sf,osites,Nsimd,{
 #ifdef GRID_SIMT
        {
 	  int lane=acceleratorSIMTlane(Nsimd); // buffer lane
 #else
 	  for(int lane=0;lane<Nsimd;lane++) {
 #endif
 	  // One thread per fine site
 	  Coordinate coor_f(_ndimension);
 	  Coordinate coor_b(_ndimension);
 	  Coordinate coor_c(_ndimension);
 	  // Fine site to fine coor
 	  Lexicographic::CoorFromIndex(coor_f,sf,fine_rdimensions);
 	  for(int d=0;d<_ndimension;d++) coor_b[d] = coor_f[d]%block_r[d];
 	  for(int d=0;d<_ndimension;d++) coor_c[d] = coor_f[d]/block_r[d];
 	  int sc;// coarse site
 	  int sb;// block site
 	  Lexicographic::IndexFromCoor(coor_c,sc,coarse_rdimensions);
 	  Lexicographic::IndexFromCoor(coor_b,sb,block_r);
          scalar_object data = extractLane(lane,fineData[sf]);
 	  // BLAS layout address calculation
 	  // words * block_vol * nbasis x coarse_vol
 	  // coarse oSite x block vole x lanes
 	  int64_t site = (lane*osites + sc*bv)*nvec
   	               + v*bv
 	               + sb;
 	  //	  assert(site*lwords<sz);
 	  scalar_object * ptr = (scalar_object *)&blasData_p[site*lwords];
 	  *ptr = data;
 #ifdef GRID_SIMT
 	}
 #else
 	}
 #endif
      });
      //      std::cout << " import fine Blas norm "<<blasNorm2(blas)<<std::endl;
      //      std::cout << " BlockProjector imported vector"<<v<<std::endl;
    }
  }
  void ExportFineGridVectors(std::vector <Field> &vecs, deviceVector<scalar> &blas)
  {
    typedef typename Field::vector_object vobj;
    int nvec = vecs.size();
    assert(vecs[0].Grid()==fine_grid);
    subdivides(coarse_grid,fine_grid); // require they map
    int _ndimension = coarse_grid->_ndimension;
    assert(block_vol == fine_grid->oSites() / coarse_grid->oSites());
    Coordinate  block_r      (_ndimension);
    for(int d=0 ; d<_ndimension;d++){
      block_r[d] = fine_grid->_rdimensions[d] / coarse_grid->_rdimensions[d];
    }
    Coordinate fine_rdimensions = fine_grid->_rdimensions;
    Coordinate coarse_rdimensions = coarse_grid->_rdimensions;
    //    std::cout << " export fine Blas norm "<<blasNorm2(blas)<<std::endl;
    int64_t bv= block_vol;
    for(int v=0;v<vecs.size();v++){
      autoView( fineData   , vecs[v], AcceleratorWrite);
      auto blasData_p  = &blas[0];
      auto fineData_p    = &fineData[0];
      int64_t osites = fine_grid->oSites();
      uint64_t lwords = words;
      //      std::cout << " Nsimd is "<<vobj::Nsimd() << std::endl;
      //      std::cout << " lwords is "<<lwords << std::endl;
      //      std::cout << " sizeof(scalar_object) is "<<sizeof(scalar_object) << std::endl;
      // loop over fine sites
      accelerator_for(sf,osites,vobj::Nsimd(),{
 #ifdef GRID_SIMT
        {
 	  int lane=acceleratorSIMTlane(vobj::Nsimd()); // buffer lane
 #else
 	  for(int lane=0;lane<vobj::Nsimd();lane++) {
 #endif
 	  // One thread per fine site
 	  Coordinate coor_f(_ndimension);
 	  Coordinate coor_b(_ndimension);
 	  Coordinate coor_c(_ndimension);
 	  Lexicographic::CoorFromIndex(coor_f,sf,fine_rdimensions);
 	  for(int d=0;d<_ndimension;d++) coor_b[d] = coor_f[d]%block_r[d];
 	  for(int d=0;d<_ndimension;d++) coor_c[d] = coor_f[d]/block_r[d];
 	  int sc;
 	  int sb;
 	  Lexicographic::IndexFromCoor(coor_c,sc,coarse_rdimensions);
 	  Lexicographic::IndexFromCoor(coor_b,sb,block_r);
 	  // BLAS layout address calculation
 	  // words * block_vol * nbasis x coarse_vol 	  
 	  int64_t site = (lane*osites + sc*bv)*nvec
   	               + v*bv
 	               + sb;
 	  scalar_object * ptr = (scalar_object *)&blasData_p[site*lwords];
 	  scalar_object data = *ptr;
 	  insertLane(lane,fineData[sf],data);
 #ifdef GRID_SIMT
 	}
 #else
 	}
 #endif
      });
    }
  }
  template<class vobj>
  void ImportCoarseGridVectors(std::vector <Lattice<vobj> > &vecs, deviceVector<scalar> &blas)
  {
    int nvec = vecs.size();
    typedef typename vobj::scalar_object coarse_scalar_object;
    //    std::cout << " BlockProjector importing "<<nvec<< " coarse grid vectors" <<std::endl;
    assert(vecs[0].Grid()==coarse_grid);
    int _ndimension = coarse_grid->_ndimension;
    uint64_t sz = blas.size();
    Coordinate coarse_rdimensions = coarse_grid->_rdimensions;
    for(int v=0;v<vecs.size();v++){
      //      std::cout << " BlockProjector importing coarse vector"<<v<<" "<<norm2(vecs[v])<<std::endl;
      autoView( coarseData   , vecs[v], AcceleratorRead);
      auto blasData_p  = &blas[0];
      auto coarseData_p  = &coarseData[0];
      int64_t osites = coarse_grid->oSites();
      // loop over fine sites
      const int Nsimd = vobj::Nsimd();
      uint64_t cwords=sizeof(typename vobj::scalar_object)/sizeof(scalar);
      assert(cwords==nbasis);
      accelerator_for(sc,osites,Nsimd,{
 #ifdef GRID_SIMT
        {
 	  int lane=acceleratorSIMTlane(Nsimd); // buffer lane
 #else
 	  for(int lane=0;lane<Nsimd;lane++) {
 #endif
           // C_br per site
 	    int64_t blas_site = (lane*osites + sc)*nvec*cwords + v*cwords;
 	    coarse_scalar_object data = extractLane(lane,coarseData[sc]);
 	    coarse_scalar_object * ptr = (coarse_scalar_object *)&blasData_p[blas_site];
 	    *ptr = data;
 #ifdef GRID_SIMT
 	}
 #else
 	}
 #endif
      });
      //      std::cout << " import coarsee Blas norm "<<blasNorm2(blas)<<std::endl;
    }
  }
  template<class vobj>
  void ExportCoarseGridVectors(std::vector <Lattice<vobj> > &vecs, deviceVector<scalar> &blas)
  {
    int nvec = vecs.size();
    typedef typename vobj::scalar_object coarse_scalar_object;
    //    std::cout << GridLogMessage<<" BlockProjector exporting "<<nvec<< " coarse grid vectors" <<std::endl;
    assert(vecs[0].Grid()==coarse_grid);
    int _ndimension = coarse_grid->_ndimension;
    uint64_t sz = blas.size();
    Coordinate coarse_rdimensions = coarse_grid->_rdimensions;
    //    std::cout << " export coarsee Blas norm "<<blasNorm2(blas)<<std::endl;
    for(int v=0;v<vecs.size();v++){
      //  std::cout << " BlockProjector exporting coarse vector"<<v<<std::endl;
      autoView( coarseData   , vecs[v], AcceleratorWrite);
      auto blasData_p  = &blas[0];
      auto coarseData_p  = &coarseData[0];
      int64_t osites = coarse_grid->oSites();
      // loop over fine sites
      const int Nsimd = vobj::Nsimd();
      uint64_t cwords=sizeof(typename vobj::scalar_object)/sizeof(scalar);
      assert(cwords==nbasis);
      accelerator_for(sc,osites,Nsimd,{
 	  // Wrap in a macro "FOR_ALL_LANES(lane,{ ... });
 #ifdef GRID_SIMT
        {
 	  int lane=acceleratorSIMTlane(Nsimd); // buffer lane
 #else
 	  for(int lane=0;lane<Nsimd;lane++) {
 #endif
 	    int64_t blas_site = (lane*osites + sc)*nvec*cwords + v*cwords;
 	    coarse_scalar_object * ptr = (coarse_scalar_object *)&blasData_p[blas_site];
 	    coarse_scalar_object data = *ptr;
 	    insertLane(lane,coarseData[sc],data);
 #ifdef GRID_SIMT
 	}
 #else
 	}
 #endif
      });
    }
  }
  void ImportBasis(std::vector < Field > &vecs)
  {
    //    std::cout << " BlockProjector Import basis size "<<vecs.size()<<std::endl;
    ImportFineGridVectors(vecs,BLAS_V);
  }
  template<class cobj>
  void blockProject(std::vector<Field> &fine,std::vector< Lattice<cobj> > & coarse)
  {
    int nrhs=fine.size();
    int _nbasis = sizeof(typename cobj::scalar_object)/sizeof(scalar);
    //    std::cout << "blockProject nbasis " <<nbasis<<" " << _nbasis<<std::endl;
    assert(nbasis==_nbasis);
    BLAS_F.resize (fine_vol * words * nrhs );
    BLAS_C.resize (coarse_vol * nbasis * nrhs );
    /////////////////////////////////////////////
    // Copy in the multi-rhs sources to same data layout
    /////////////////////////////////////////////
    //    std::cout << "BlockProject import fine"<<std::endl;
    ImportFineGridVectors(fine,BLAS_F);
    deviceVector<scalar *> Vd(coarse_vol);
    deviceVector<scalar *> Fd(coarse_vol);
    deviceVector<scalar *> Cd(coarse_vol);
    //    std::cout << "BlockProject pointers"<<std::endl;
    for(int c=0;c<coarse_vol;c++){
      // BLAS_V[coarse_vol][nbasis][block_vol][words]
      // BLAS_F[coarse_vol][nrhs][block_vol][words]
      // BLAS_C[coarse_vol][nrhs][nbasis]
      scalar * Vh = & BLAS_V[c*nbasis*block_vol*words];
      scalar * Fh = & BLAS_F[c*nrhs*block_vol*words];
      scalar * Ch = & BLAS_C[c*nrhs*nbasis];
      acceleratorPut(Vd[c],Vh);
      acceleratorPut(Fd[c],Fh);
      acceleratorPut(Cd[c],Ch);
    }
    GridBLAS BLAS;
    //    std::cout << "BlockProject BLAS"<<std::endl;
    int64_t vw = block_vol * words;
    /////////////////////////////////////////
    // C_br = V^dag R
    /////////////////////////////////////////
    BLAS.gemmBatched(GridBLAS_OP_C,GridBLAS_OP_N, 
    		     nbasis,nrhs,vw,
 		     ComplexD(1.0),
 		     Vd,
 		     Fd,
 		     ComplexD(0.0),  // wipe out C
 		     Cd);
    BLAS.synchronise();
    //    std::cout << "BlockProject done"<<std::endl;
    ExportCoarseGridVectors(coarse, BLAS_C);
    //    std::cout << "BlockProject done"<<std::endl;
  }
  template<class cobj>
  void blockPromote(std::vector<Field> &fine,std::vector<Lattice<cobj> > & coarse)
  {
    int nrhs=fine.size();
    int _nbasis = sizeof(typename cobj::scalar_object)/sizeof(scalar);
    assert(nbasis==_nbasis);
    BLAS_F.resize (fine_vol * words * nrhs );
    BLAS_C.resize (coarse_vol * nbasis * nrhs );
    ImportCoarseGridVectors(coarse, BLAS_C);
    GridBLAS BLAS;
    deviceVector<scalar *> Vd(coarse_vol);
    deviceVector<scalar *> Fd(coarse_vol);
    deviceVector<scalar *> Cd(coarse_vol);
    for(int c=0;c<coarse_vol;c++){
      // BLAS_V[coarse_vol][nbasis][block_vol][words]
      // BLAS_F[coarse_vol][nrhs][block_vol][words]
      // BLAS_C[coarse_vol][nrhs][nbasis]
      scalar * Vh = & BLAS_V[c*nbasis*block_vol*words];
      scalar * Fh = & BLAS_F[c*nrhs*block_vol*words];
      scalar * Ch = & BLAS_C[c*nrhs*nbasis];
      acceleratorPut(Vd[c],Vh);
      acceleratorPut(Fd[c],Fh);
      acceleratorPut(Cd[c],Ch);
    }
    /////////////////////////////////////////
    // Block promote:
    // F_xr = Vxb Cbr (x coarse_vol)
    /////////////////////////////////////////
    int64_t vw = block_vol * words;
    BLAS.gemmBatched(GridBLAS_OP_N,GridBLAS_OP_N, 
    		     vw,nrhs,nbasis,
 		     ComplexD(1.0),
 		     Vd,
 		     Cd,
 		     ComplexD(0.0),  // wipe out C
 		     Fd);
    BLAS.synchronise();
    //    std::cout << " blas call done"<<std::endl;
    ExportFineGridVectors(fine, BLAS_F);
    //    std::cout << " exported "<<std::endl;
  }
 };
 NAMESPACE_END(Grid);
--- a/Grid/algorithms/deflation/MultiRHSDeflation.h
+++ b/Grid/algorithms/deflation/MultiRHSDeflation.h
@@ -0,0 +1,233 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: MultiRHSDeflation.h
    Copyright (C) 2023
 Author: Peter Boyle <pboyle@bnl.gov>
    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 */
 #pragma once
 NAMESPACE_BEGIN(Grid);
 /* Need helper object for BLAS accelerated mrhs projection
   i) MultiRHS Deflation
   Import Evecs -> nev x vol x internal 
   Import vector of Lattice objects -> nrhs x vol x internal
   => Cij (nrhs x Nev) via GEMM.
   => Guess  (nrhs x vol x internal)  = C x evecs (via GEMM)
   Export
   ii) MultiRHS block projection
   Import basis -> nblock x nbasis x  (block x internal) 
   Import vector of fine lattice objects -> nblock x nrhs x (block x internal) 
   => coarse_(nrhs x nbasis )^block = via batched GEMM
   iii)   Alternate interface: 
   Import higher dim Lattice object-> vol x nrhs layout
 */
 template<class Field>
 class MultiRHSDeflation
 {
 public:
  typedef typename Field::scalar_type   scalar;
  typedef typename Field::scalar_object scalar_object;
  int nev;
  std::vector<RealD> eval;
  GridBase *grid;
  uint64_t vol;
  uint64_t words;
  deviceVector<scalar> BLAS_E;      //  nev x vol -- the eigenbasis   (up to a 1/sqrt(lambda))
  deviceVector<scalar> BLAS_R;      // nrhs x vol -- the sources
  deviceVector<scalar> BLAS_G;      // nrhs x vol -- the guess
  deviceVector<scalar> BLAS_C;      // nrhs x nev -- the coefficients 
  MultiRHSDeflation(){};
  ~MultiRHSDeflation(){ Deallocate(); };
  void Deallocate(void)
  {
    nev=0;
    grid=nullptr;
    vol=0;
    words=0;
    BLAS_E.resize(0);
    BLAS_R.resize(0);
    BLAS_C.resize(0);
    BLAS_G.resize(0);
  }
  void Allocate(int _nev,GridBase *_grid)
  {
    nev=_nev;
    grid=_grid;
    vol   = grid->lSites();
    words = sizeof(scalar_object)/sizeof(scalar);
    eval.resize(nev);
    BLAS_E.resize (vol * words * nev );
    std::cout << GridLogMessage << " Allocate for "<<nev<<" eigenvectors and volume "<<vol<<std::endl;
  }
  void ImportEigenVector(Field &evec,RealD &_eval, int ev)
  {
    //    std::cout << " ev " <<ev<<" eval "<<_eval<< std::endl;
    assert(ev<eval.size());
    eval[ev] = _eval;
    int64_t offset = ev*vol*words;
    autoView(v,evec,AcceleratorRead);
    acceleratorCopyDeviceToDevice(&v[0],&BLAS_E[offset],sizeof(scalar_object)*vol);
  }
  void ImportEigenBasis(std::vector<Field> &evec,std::vector<RealD> &_eval)
  {
    ImportEigenBasis(evec,_eval,0,evec.size());
  }
  // Could use to import a batch of eigenvectors
  void ImportEigenBasis(std::vector<Field> &evec,std::vector<RealD> &_eval, int _ev0, int _nev)
  {
    assert(_ev0+_nev<=evec.size());
    Allocate(_nev,evec[0].Grid());
    // Imports a sub-batch of eigenvectors, _ev0, ..., _ev0+_nev-1
    for(int e=0;e<nev;e++){
      std::cout << "Importing eigenvector "<<e<<" evalue "<<_eval[_ev0+e]<<std::endl;
      ImportEigenVector(evec[_ev0+e],_eval[_ev0+e],e);
    }
  }
  void DeflateSources(std::vector<Field> &source,std::vector<Field> & guess)
  {
    int nrhs = source.size();
    assert(source.size()==guess.size());
    assert(grid == guess[0].Grid());
    conformable(guess[0],source[0]);
    int64_t vw = vol * words;
    RealD t0 = usecond();
    BLAS_R.resize(nrhs * vw); // cost free if size doesn't change
    BLAS_G.resize(nrhs * vw); // cost free if size doesn't change
    BLAS_C.resize(nev * nrhs);// cost free if size doesn't change
    /////////////////////////////////////////////
    // Copy in the multi-rhs sources
    /////////////////////////////////////////////
    //    for(int r=0;r<nrhs;r++){
    //      std::cout << " source["<<r<<"] = "<<norm2(source[r])<<std::endl;
    //    }
    for(int r=0;r<nrhs;r++){
      int64_t offset = r*vw;
      autoView(v,source[r],AcceleratorRead);
      acceleratorCopyDeviceToDevice(&v[0],&BLAS_R[offset],sizeof(scalar_object)*vol);
    }
  /*
   * in Fortran column major notation (cuBlas order)
   *
   * Exe = [e1(x)][..][en(x)]
   *
   * Rxr = [r1(x)][..][rm(x)]
   *
   * C_er = E^dag R
   * C_er = C_er / lambda_e 
   * G_xr = Exe Cer
   */
    deviceVector<scalar *> Ed(1);
    deviceVector<scalar *> Rd(1);
    deviceVector<scalar *> Cd(1);
    deviceVector<scalar *> Gd(1);
    scalar * Eh = & BLAS_E[0];
    scalar * Rh = & BLAS_R[0];
    scalar * Ch = & BLAS_C[0];
    scalar * Gh = & BLAS_G[0];
    acceleratorPut(Ed[0],Eh);
    acceleratorPut(Rd[0],Rh);
    acceleratorPut(Cd[0],Ch);
    acceleratorPut(Gd[0],Gh);
    GridBLAS BLAS;
    /////////////////////////////////////////
    // C_er = E^dag R
    /////////////////////////////////////////
    BLAS.gemmBatched(GridBLAS_OP_C,GridBLAS_OP_N, 
    		     nev,nrhs,vw,
 		     ComplexD(1.0),
 		     Ed,
 		     Rd,
 		     ComplexD(0.0),  // wipe out C
 		     Cd);
    BLAS.synchronise();
    assert(BLAS_C.size()==nev*nrhs);
    std::vector<scalar> HOST_C(BLAS_C.size());      // nrhs . nev -- the coefficients 
    acceleratorCopyFromDevice(&BLAS_C[0],&HOST_C[0],BLAS_C.size()*sizeof(scalar));
    grid->GlobalSumVector(&HOST_C[0],nev*nrhs);
    for(int e=0;e<nev;e++){
      RealD lam(1.0/eval[e]);
      for(int r=0;r<nrhs;r++){
 	int off = e+nev*r;
 	HOST_C[off]=HOST_C[off] * lam;
 	//	std::cout << "C["<<e<<"]["<<r<<"] ="<<HOST_C[off]<< " eval[e] "<<eval[e] <<std::endl;
      }
    }
    acceleratorCopyToDevice(&HOST_C[0],&BLAS_C[0],BLAS_C.size()*sizeof(scalar));
    /////////////////////////////////////////
    // Guess G_xr = Exe Cer
    /////////////////////////////////////////
    BLAS.gemmBatched(GridBLAS_OP_N,GridBLAS_OP_N, 
 		     vw,nrhs,nev,
 		     ComplexD(1.0),
 		     Ed, // x . nev
 		     Cd, // nev . nrhs
 		     ComplexD(0.0),
 		     Gd);
    BLAS.synchronise();
    ///////////////////////////////////////
    // Copy out the multirhs
    ///////////////////////////////////////
    for(int r=0;r<nrhs;r++){
      int64_t offset = r*vw;
      autoView(v,guess[r],AcceleratorWrite);
      acceleratorCopyDeviceToDevice(&BLAS_G[offset],&v[0],sizeof(scalar_object)*vol);
    }
    RealD t1 = usecond();
    std::cout << GridLogMessage << "MultiRHSDeflation for "<<nrhs<<" sources with "<<nev<<" eigenvectors took " << (t1-t0)/1e3 <<" ms"<<std::endl;
  }
 };
 NAMESPACE_END(Grid);
--- a/Grid/algorithms/iterative/AdefGeneric.h
+++ b/Grid/algorithms/iterative/AdefGeneric.h
@@ -33,109 +33,111 @@ Author: Peter Boyle <paboyle@ph.ed.ac.uk>
   * Script A = SolverMatrix 
   * Script P = Preconditioner
   *
   * Deflation methods considered
   *      -- Solve P A x = P b        [ like Luscher ]
   * DEF-1        M P A x = M P b     [i.e. left precon]
   * DEF-2        P^T M A x = P^T M b
   * ADEF-1       Preconditioner = M P + Q      [ Q + M + M A Q]
   * ADEF-2       Preconditioner = P^T M + Q
   * BNN          Preconditioner = P^T M P + Q
   * BNN2         Preconditioner = M P + P^TM +Q - M P A M 
   * 
   * Implement ADEF-2
   *
   * Vstart = P^Tx + Qb
   * M1 = P^TM + Q
   * M2=M3=1
   * Vout = x
   */
 NAMESPACE_BEGIN(Grid);
-// abstract base
+
-template<class Field, class CoarseField>
+template<class Field>
-class TwoLevelFlexiblePcg : public LinearFunction<Field>
+class TwoLevelCG : public LinearFunction<Field>
 {
 public:
  int verbose;
  RealD   Tolerance;
  Integer MaxIterations;
  const int mmax = 5;
  GridBase *grid;
  GridBase *coarsegrid;
-  LinearOperatorBase<Field>   *_Linop
+  // Fine operator, Smoother, CoarseSolver
-  OperatorFunction<Field>     *_Smoother,
+  LinearOperatorBase<Field>   &_FineLinop;
-  LinearFunction<CoarseField> *_CoarseSolver;
+  LinearFunction<Field>   &_Smoother;
  // Need somthing that knows how to get from Coarse to fine and back again
  // more most opertor functions
-  TwoLevelFlexiblePcg(RealD tol,
+  TwoLevelCG(RealD tol,
-		     Integer maxit,
+	     Integer maxit,
-		     LinearOperatorBase<Field> *Linop,
+	     LinearOperatorBase<Field>   &FineLinop,
-		     LinearOperatorBase<Field> *SmootherLinop,
+	     LinearFunction<Field>       &Smoother,
-		     OperatorFunction<Field>   *Smoother,
+	     GridBase *fine) : 
 		     OperatorFunction<CoarseField>  CoarseLinop
 		     ) : 
      Tolerance(tol), 
      MaxIterations(maxit),
-      _Linop(Linop),
+      _FineLinop(FineLinop),
-      _PreconditionerLinop(PrecLinop),
+      _Smoother(Smoother)
      _Preconditioner(Preconditioner)
  {
-    verbose=0;
+    grid       = fine;
  };
-  // The Pcg routine is common to all, but the various matrices differ from derived 
+  virtual void operator() (const Field &src, Field &x)
-  // implementation to derived implmentation
+  {
-  void operator() (const Field &src, Field &psi){
+    std::cout << GridLogMessage<<"HDCG: fPcg starting single RHS"<<std::endl;
  void operator() (const Field &src, Field &psi){
    psi.Checkerboard() = src.Checkerboard();
    grid             = src.Grid();
    RealD f;
    RealD rtzp,rtz,a,d,b;
    RealD rptzp;
    RealD tn;
    RealD guess = norm2(psi);
    RealD ssq   = norm2(src);
    RealD rsq   = ssq*Tolerance*Tolerance;
    /////////////////////////////
    // Set up history vectors
    /////////////////////////////
-    std::vector<Field> p  (mmax,grid);
+    int mmax = 5;
    std::cout << GridLogMessage<<"HDCG: fPcg allocating"<<std::endl;
    std::vector<Field> p(mmax,grid);
    std::vector<Field> mmp(mmax,grid);
    std::vector<RealD> pAp(mmax);
-
+    Field z(grid);
    Field x  (grid); x = psi;
    Field z  (grid);
    Field tmp(grid);
-    Field r  (grid);
+    Field  mp (grid);
-    Field mu (grid);
+    Field  r  (grid);
    Field  mu (grid);
    std::cout << GridLogMessage<<"HDCG: fPcg allocated"<<std::endl;
    //Initial residual computation & set up
    RealD guess   = norm2(x);
    std::cout << GridLogMessage<<"HDCG: fPcg guess nrm "<<guess<<std::endl;
    RealD src_nrm = norm2(src);
    std::cout << GridLogMessage<<"HDCG: fPcg src nrm "<<src_nrm<<std::endl;
    if ( src_nrm == 0.0 ) {
      std::cout << GridLogMessage<<"HDCG: fPcg given trivial source norm "<<src_nrm<<std::endl;
      x=Zero();
    }
    RealD tn;
    GridStopWatch HDCGTimer;
    HDCGTimer.Start();
    //////////////////////////
    // x0 = Vstart -- possibly modify guess
    //////////////////////////
    x=src;
    Vstart(x,src);
    // r0 = b -A x0
-    HermOp(x,mmp); // Shouldn't this be something else?
+    _FineLinop.HermOp(x,mmp[0]);
    axpy (r, -1.0,mmp[0], src);    // Recomputes r=src-Ax0
    {
      double n1 = norm2(x);
      double n2 = norm2(mmp[0]);
      double n3 = norm2(r);
      std::cout<<GridLogMessage<<"x,vstart,r = "<<n1<<" "<<n2<<" "<<n3<<std::endl;
    }
    //////////////////////////////////
    // Compute z = M1 x
    //////////////////////////////////
-    M1(r,z,tmp,mp,SmootherMirs);
+    PcgM1(r,z);
    rtzp =real(innerProduct(r,z));
    ///////////////////////////////////////
    // Solve for Mss mu = P A z and set p = z-mu
-    // Def2: p = 1 - Q Az = Pright z 
+    // Def2 p = 1 - Q Az = Pright z
    // Other algos M2 is trivial
    ///////////////////////////////////////
-    M2(z,p[0]);
+    PcgM2(z,p[0]);
    RealD ssq =  norm2(src);
    RealD rsq =  ssq*Tolerance*Tolerance;
    std::cout << GridLogMessage<<"HDCG: k=0 residual "<<rtzp<<" rsq "<<rsq<<"\n";
    Field pp(grid);
    for (int k=0;k<=MaxIterations;k++){
@@ -143,7 +145,7 @@ class TwoLevelFlexiblePcg : public LinearFunction<Field>
      int peri_kp = (k+1) % mmax;
      rtz=rtzp;
-      d= M3(p[peri_k],mp,mmp[peri_k],tmp);
+      d= PcgM3(p[peri_k],mmp[peri_k]);
      a = rtz/d;
      // Memorise this
@@ -153,21 +155,36 @@ class TwoLevelFlexiblePcg : public LinearFunction<Field>
      RealD rn = axpy_norm(r,-a,mmp[peri_k],r);
      // Compute z = M x
-      M1(r,z,tmp,mp);
+      PcgM1(r,z);
      {
 	RealD n1,n2;
 	n1=norm2(r);
 	n2=norm2(z);
 	std::cout << GridLogMessage<<"HDCG::fPcg iteration "<<k<<" : vector r,z "<<n1<<" "<<n2<<"\n";
      }
      rtzp =real(innerProduct(r,z));
      std::cout << GridLogMessage<<"HDCG::fPcg iteration "<<k<<" : inner rtzp "<<rtzp<<"\n";
-      M2(z,mu); // ADEF-2 this is identity. Axpy possible to eliminate
+      //    PcgM2(z,p[0]);
      PcgM2(z,mu); // ADEF-2 this is identity. Axpy possible to eliminate
-      p[peri_kp]=p[peri_k];
+      p[peri_kp]=mu;
-      // Standard search direction  p -> z + b p    ; b = 
+      // Standard search direction  p -> z + b p    
      b = (rtzp)/rtz;
      int northog;
      // k=zero  <=> peri_kp=1;        northog = 1
      // k=1     <=> peri_kp=2;        northog = 2
      // ...               ...                  ...
      // k=mmax-2<=> peri_kp=mmax-1;   northog = mmax-1
      // k=mmax-1<=> peri_kp=0;        northog = 1
      //    northog     = (peri_kp==0)?1:peri_kp; // This is the fCG(mmax) algorithm
      northog     = (k>mmax-1)?(mmax-1):k;        // This is the fCG-Tr(mmax-1) algorithm
      std::cout<<GridLogMessage<<"HDCG::fPcg iteration "<<k<<" : orthogonalising to last "<<northog<<" vectors\n";
      for(int back=0; back < northog; back++){
 	int peri_back = (k-back)%mmax;
 	RealD pbApk= real(innerProduct(mmp[peri_back],p[peri_kp]));
@@ -176,75 +193,324 @@ class TwoLevelFlexiblePcg : public LinearFunction<Field>
      }
      RealD rrn=sqrt(rn/ssq);
-      std::cout<<GridLogMessage<<"TwoLevelfPcg: k= "<<k<<" residual = "<<rrn<<std::endl;
+      RealD rtn=sqrt(rtz/ssq);
      RealD rtnp=sqrt(rtzp/ssq);
      std::cout<<GridLogMessage<<"HDCG: fPcg k= "<<k<<" residual = "<<rrn<<"\n";
      // Stopping condition
      if ( rn <= rsq ) { 
-	HermOp(x,mmp); // Shouldn't this be something else?
+	HDCGTimer.Stop();
 	std::cout<<GridLogMessage<<"HDCG: fPcg converged in "<<k<<" iterations and "<<HDCGTimer.Elapsed()<<std::endl;;
 	_FineLinop.HermOp(x,mmp[0]);			  
 	axpy(tmp,-1.0,src,mmp[0]);
-	RealD psinorm = sqrt(norm2(x));
+	RealD  mmpnorm = sqrt(norm2(mmp[0]));
-	RealD srcnorm = sqrt(norm2(src));
+	RealD  xnorm   = sqrt(norm2(x));
-	RealD tmpnorm = sqrt(norm2(tmp));
+	RealD  srcnorm = sqrt(norm2(src));
-	RealD true_residual = tmpnorm/srcnorm;
+	RealD  tmpnorm = sqrt(norm2(tmp));
-	std::cout<<GridLogMessage<<"TwoLevelfPcg:   true residual is "<<true_residual<<std::endl;
+	RealD  true_residual = tmpnorm/srcnorm;
-	std::cout<<GridLogMessage<<"TwoLevelfPcg: target residual was"<<Tolerance<<std::endl;
+	std::cout<<GridLogMessage
-	return k;
+	       <<"HDCG: true residual is "<<true_residual
 	       <<" solution "<<xnorm
 	       <<" source "<<srcnorm
 	       <<" mmp "<<mmpnorm	  
 	       <<std::endl;
 	return;
      }
    }
-    // Non-convergence
+    HDCGTimer.Stop();
-    assert(0);
+    std::cout<<GridLogMessage<<"HDCG: not converged "<<HDCGTimer.Elapsed()<<std::endl;
    RealD  xnorm   = sqrt(norm2(x));
    RealD  srcnorm = sqrt(norm2(src));
    std::cout<<GridLogMessage<<"HDCG: non-converged solution "<<xnorm<<" source "<<srcnorm<<std::endl;
  }
  virtual void operator() (std::vector<Field> &src, std::vector<Field> &x)
  {
    std::cout << GridLogMessage<<"HDCG: mrhs fPcg starting"<<std::endl;
    src[0].Grid()->Barrier();
    int nrhs = src.size();
    std::vector<RealD> f(nrhs);
    std::vector<RealD> rtzp(nrhs);
    std::vector<RealD> rtz(nrhs);
    std::vector<RealD> a(nrhs);
    std::vector<RealD> d(nrhs);
    std::vector<RealD> b(nrhs);
    std::vector<RealD> rptzp(nrhs);
    /////////////////////////////
    // Set up history vectors
    /////////////////////////////
    int mmax = 3;
    std::cout << GridLogMessage<<"HDCG: fPcg allocating"<<std::endl;
    src[0].Grid()->Barrier();
    std::vector<std::vector<Field> > p(nrhs);   for(int r=0;r<nrhs;r++)  p[r].resize(mmax,grid);
    std::cout << GridLogMessage<<"HDCG: fPcg allocated p"<<std::endl;
    src[0].Grid()->Barrier();
    std::vector<std::vector<Field> > mmp(nrhs); for(int r=0;r<nrhs;r++) mmp[r].resize(mmax,grid);
    std::cout << GridLogMessage<<"HDCG: fPcg allocated mmp"<<std::endl;
    src[0].Grid()->Barrier();
    std::vector<std::vector<RealD> > pAp(nrhs); for(int r=0;r<nrhs;r++) pAp[r].resize(mmax);
    std::cout << GridLogMessage<<"HDCG: fPcg allocated pAp"<<std::endl;
    src[0].Grid()->Barrier();
    std::vector<Field> z(nrhs,grid);
    std::vector<Field>  mp (nrhs,grid);
    std::vector<Field>  r  (nrhs,grid);
    std::vector<Field>  mu (nrhs,grid);
    std::cout << GridLogMessage<<"HDCG: fPcg allocated z,mp,r,mu"<<std::endl;
    src[0].Grid()->Barrier();
    //Initial residual computation & set up
    std::vector<RealD> src_nrm(nrhs);
    for(int rhs=0;rhs<nrhs;rhs++) {
      src_nrm[rhs]=norm2(src[rhs]);
      assert(src_nrm[rhs]!=0.0);
    }
    std::vector<RealD> tn(nrhs);
    GridStopWatch HDCGTimer;
    HDCGTimer.Start();
    //////////////////////////
    // x0 = Vstart -- possibly modify guess
    //////////////////////////
    Vstart(x,src);
    for(int rhs=0;rhs<nrhs;rhs++){
      // r0 = b -A x0
      _FineLinop.HermOp(x[rhs],mmp[rhs][0]);
      axpy (r[rhs], -1.0,mmp[rhs][0], src[rhs]);    // Recomputes r=src-Ax0
    }
    //////////////////////////////////
    // Compute z = M1 x
    //////////////////////////////////
    // This needs a multiRHS version for acceleration
    PcgM1(r,z);
    std::vector<RealD> ssq(nrhs);
    std::vector<RealD> rsq(nrhs);
    std::vector<Field> pp(nrhs,grid);
    for(int rhs=0;rhs<nrhs;rhs++){
      rtzp[rhs] =real(innerProduct(r[rhs],z[rhs]));
      p[rhs][0]=z[rhs];
      ssq[rhs]=norm2(src[rhs]);
      rsq[rhs]=  ssq[rhs]*Tolerance*Tolerance;
      std::cout << GridLogMessage<<"mrhs HDCG: "<<rhs<<" k=0 residual "<<rtzp[rhs]<<" rsq "<<rsq[rhs]<<"\n";
    }
    std::vector<RealD> rn(nrhs);
    for (int k=0;k<=MaxIterations;k++){
      int peri_k  = k % mmax;
      int peri_kp = (k+1) % mmax;
      for(int rhs=0;rhs<nrhs;rhs++){
 	rtz[rhs]=rtzp[rhs];
 	d[rhs]= PcgM3(p[rhs][peri_k],mmp[rhs][peri_k]);
 	a[rhs] = rtz[rhs]/d[rhs];
 	// Memorise this
 	pAp[rhs][peri_k] = d[rhs];
 	axpy(x[rhs],a[rhs],p[rhs][peri_k],x[rhs]);
 	rn[rhs] = axpy_norm(r[rhs],-a[rhs],mmp[rhs][peri_k],r[rhs]);
      }
      // Compute z = M x (for *all* RHS)
      PcgM1(r,z);
      std::cout << GridLogMessage<<"HDCG::fPcg M1 complete"<<std::endl;
      grid->Barrier();
      RealD max_rn=0.0;
      for(int rhs=0;rhs<nrhs;rhs++){
 	rtzp[rhs] =real(innerProduct(r[rhs],z[rhs]));
 	std::cout << GridLogMessage<<"HDCG::fPcg rhs"<<rhs<<" iteration "<<k<<" : inner rtzp "<<rtzp[rhs]<<"\n";
 	mu[rhs]=z[rhs];
 	p[rhs][peri_kp]=mu[rhs];
 	// Standard search direction p == z + b p 
 	b[rhs] = (rtzp[rhs])/rtz[rhs];
 	int northog = (k>mmax-1)?(mmax-1):k;        // This is the fCG-Tr(mmax-1) algorithm
 	std::cout<<GridLogMessage<<"HDCG::fPcg iteration "<<k<<" : orthogonalising to last "<<northog<<" vectors\n";
 	for(int back=0; back < northog; back++){
 	  int peri_back = (k-back)%mmax;
 	  RealD pbApk= real(innerProduct(mmp[rhs][peri_back],p[rhs][peri_kp]));
 	  RealD beta = -pbApk/pAp[rhs][peri_back];
 	  axpy(p[rhs][peri_kp],beta,p[rhs][peri_back],p[rhs][peri_kp]);
 	}
 	RealD rrn=sqrt(rn[rhs]/ssq[rhs]);
 	RealD rtn=sqrt(rtz[rhs]/ssq[rhs]);
 	RealD rtnp=sqrt(rtzp[rhs]/ssq[rhs]);
 	std::cout<<GridLogMessage<<"HDCG: rhs "<<rhs<<"fPcg k= "<<k<<" residual = "<<rrn<<"\n";
 	if ( rrn > max_rn ) max_rn = rrn;
      }
      // Stopping condition based on worst case
      if ( max_rn <= Tolerance ) { 
 	HDCGTimer.Stop();
 	std::cout<<GridLogMessage<<"HDCG: mrhs fPcg converged in "<<k<<" iterations and "<<HDCGTimer.Elapsed()<<std::endl;;
 	for(int rhs=0;rhs<nrhs;rhs++){
 	  _FineLinop.HermOp(x[rhs],mmp[rhs][0]);			  
 	  Field tmp(grid);
 	  axpy(tmp,-1.0,src[rhs],mmp[rhs][0]);
 	  RealD  mmpnorm = sqrt(norm2(mmp[rhs][0]));
 	  RealD  xnorm   = sqrt(norm2(x[rhs]));
 	  RealD  srcnorm = sqrt(norm2(src[rhs]));
 	  RealD  tmpnorm = sqrt(norm2(tmp));
 	  RealD  true_residual = tmpnorm/srcnorm;
 	  std::cout<<GridLogMessage
 		   <<"HDCG: true residual ["<<rhs<<"] is "<<true_residual
 		   <<" solution "<<xnorm
 		   <<" source "<<srcnorm
 		   <<" mmp "<<mmpnorm	  
 		   <<std::endl;
 	}
 	return;
      }
    }
    HDCGTimer.Stop();
    std::cout<<GridLogMessage<<"HDCG: not converged "<<HDCGTimer.Elapsed()<<std::endl;
    for(int rhs=0;rhs<nrhs;rhs++){
      RealD  xnorm   = sqrt(norm2(x[rhs]));
      RealD  srcnorm = sqrt(norm2(src[rhs]));
      std::cout<<GridLogMessage<<"HDCG: non-converged solution "<<xnorm<<" source "<<srcnorm<<std::endl;
    }
  }
 public:
-  virtual void M(Field & in,Field & out,Field & tmp) {
+  virtual void PcgM1(std::vector<Field> & in,std::vector<Field> & out)
  {
    std::cout << "PcgM1 default (cheat) mrhs version"<<std::endl;
    for(int rhs=0;rhs<in.size();rhs++){
      this->PcgM1(in[rhs],out[rhs]);
    }
  }
  virtual void PcgM1(Field & in, Field & out)     =0;
  virtual void Vstart(std::vector<Field> & x,std::vector<Field> & src)
  {
    std::cout << "Vstart default (cheat) mrhs version"<<std::endl;
    for(int rhs=0;rhs<x.size();rhs++){
      this->Vstart(x[rhs],src[rhs]);
    }
  }
  virtual void Vstart(Field & x,const Field & src)=0;
  virtual void PcgM2(const Field & in, Field & out) {
    out=in;
  }
-  virtual void M1(Field & in, Field & out) {// the smoother
+  virtual RealD PcgM3(const Field & p, Field & mmp){
    RealD dd;
    _FineLinop.HermOp(p,mmp);
    ComplexD dot = innerProduct(p,mmp);
    dd=real(dot);
    return dd;
  }
  /////////////////////////////////////////////////////////////////////
  // Only Def1 has non-trivial Vout.
  /////////////////////////////////////////////////////////////////////
 };
 template<class Field, class CoarseField, class Aggregation>
 class TwoLevelADEF2 : public TwoLevelCG<Field>
 {
 public:
  ///////////////////////////////////////////////////////////////////////////////////
  // Need something that knows how to get from Coarse to fine and back again
  //  void ProjectToSubspace(CoarseVector &CoarseVec,const FineField &FineVec){
  //  void PromoteFromSubspace(const CoarseVector &CoarseVec,FineField &FineVec){
  ///////////////////////////////////////////////////////////////////////////////////
  GridBase *coarsegrid;
  Aggregation &_Aggregates;                    
  LinearFunction<CoarseField> &_CoarseSolver;
  LinearFunction<CoarseField> &_CoarseSolverPrecise;
  ///////////////////////////////////////////////////////////////////////////////////
  // more most opertor functions
  TwoLevelADEF2(RealD tol,
 		Integer maxit,
 		LinearOperatorBase<Field>    &FineLinop,
 		LinearFunction<Field>        &Smoother,
 		LinearFunction<CoarseField>  &CoarseSolver,
 		LinearFunction<CoarseField>  &CoarseSolverPrecise,
 		Aggregation &Aggregates
 		) :
      TwoLevelCG<Field>(tol,maxit,FineLinop,Smoother,Aggregates.FineGrid),
      _CoarseSolver(CoarseSolver),
      _CoarseSolverPrecise(CoarseSolverPrecise),
      _Aggregates(Aggregates)
  {
    coarsegrid = Aggregates.CoarseGrid;
  };
  virtual void PcgM1(Field & in, Field & out)
  {
    GRID_TRACE("MultiGridPreconditioner ");
    // [PTM+Q] in = [1 - Q A] M in + Q in = Min + Q [ in -A Min]
    Field tmp(grid);
    Field Min(grid);
-    PcgM(in,Min); // Smoother call
+    Field tmp(this->grid);
    Field Min(this->grid);
    CoarseField PleftProj(this->coarsegrid);
    CoarseField PleftMss_proj(this->coarsegrid);
-    HermOp(Min,out);
+    GridStopWatch SmootherTimer;
    GridStopWatch MatrixTimer;
    SmootherTimer.Start();
    this->_Smoother(in,Min);
    SmootherTimer.Stop();
    MatrixTimer.Start();
    this->_FineLinop.HermOp(Min,out);
    MatrixTimer.Stop();
    axpy(tmp,-1.0,out,in);          // tmp  = in - A Min
-    ProjectToSubspace(tmp,PleftProj);     
+    GridStopWatch ProjTimer;
-    ApplyInverse(PleftProj,PleftMss_proj); // Ass^{-1} [in - A Min]_s
+    GridStopWatch CoarseTimer;
-    PromoteFromSubspace(PleftMss_proj,tmp);// tmp = Q[in - A Min]  
+    GridStopWatch PromTimer;
    ProjTimer.Start();
    this->_Aggregates.ProjectToSubspace(PleftProj,tmp);     
    ProjTimer.Stop();
    CoarseTimer.Start();
    this->_CoarseSolver(PleftProj,PleftMss_proj); // Ass^{-1} [in - A Min]_s
    CoarseTimer.Stop();
    PromTimer.Start();
    this->_Aggregates.PromoteFromSubspace(PleftMss_proj,tmp);// tmp = Q[in - A Min]  
    PromTimer.Stop();
    std::cout << GridLogPerformance << "PcgM1 breakdown "<<std::endl;
    std::cout << GridLogPerformance << "\tSmoother   " << SmootherTimer.Elapsed() <<std::endl;
    std::cout << GridLogPerformance << "\tMatrix     " << MatrixTimer.Elapsed() <<std::endl;
    std::cout << GridLogPerformance << "\tProj       " << ProjTimer.Elapsed() <<std::endl;
    std::cout << GridLogPerformance << "\tCoarse     " << CoarseTimer.Elapsed() <<std::endl;
    std::cout << GridLogPerformance << "\tProm       " << PromTimer.Elapsed() <<std::endl;
    axpy(out,1.0,Min,tmp); // Min+tmp
  }
-  virtual void M2(const Field & in, Field & out) {
+  virtual void Vstart(Field & x,const Field & src)
-    out=in;
+  {
-    // Must override for Def2 only
+    std::cout << GridLogMessage<<"HDCG: fPcg Vstart "<<std::endl;
    //  case PcgDef2:
    //    Pright(in,out);
    //    break;
  }
  virtual RealD M3(const Field & p, Field & mmp){
    double d,dd;
    HermOpAndNorm(p,mmp,d,dd);
    return dd;
    // Must override for Def1 only
    //  case PcgDef1:
    //    d=linop_d->Mprec(p,mmp,tmp,0,1);// Dag no
    //      linop_d->Mprec(mmp,mp,tmp,1);// Dag yes
    //    Pleft(mp,mmp);
    //    d=real(linop_d->inner(p,mmp));
  }
  virtual void VstartDef2(Field & xconst Field & src){
    //case PcgDef2:
    //case PcgAdef2: 
    //case PcgAdef2f:
    //case PcgV11f:
    ///////////////////////////////////
    // Choose x_0 such that 
    // x_0 = guess +  (A_ss^inv) r_s = guess + Ass_inv [src -Aguess]
@@ -256,142 +522,78 @@ class TwoLevelFlexiblePcg : public LinearFunction<Field>
    //                   = src_s - (A guess)_s - src_s  + (A guess)_s 
    //                   = 0 
    ///////////////////////////////////
-    Field r(grid);
+    Field r(this->grid);
-    Field mmp(grid);
+    Field mmp(this->grid);
    CoarseField PleftProj(this->coarsegrid);
    CoarseField PleftMss_proj(this->coarsegrid);
-    HermOp(x,mmp);
+    std::cout << GridLogMessage<<"HDCG: fPcg Vstart projecting "<<std::endl;
-    axpy (r, -1.0, mmp, src);        // r_{-1} = src - A x
+    this->_Aggregates.ProjectToSubspace(PleftProj,src);     
-    ProjectToSubspace(r,PleftProj);     
+    std::cout << GridLogMessage<<"HDCG: fPcg Vstart coarse solve "<<std::endl;
-    ApplyInverseCG(PleftProj,PleftMss_proj); // Ass^{-1} r_s
+    this->_CoarseSolverPrecise(PleftProj,PleftMss_proj); // Ass^{-1} r_s
-    PromoteFromSubspace(PleftMss_proj,mmp);  
+    std::cout << GridLogMessage<<"HDCG: fPcg Vstart promote "<<std::endl;
-    x=x+mmp;
+    this->_Aggregates.PromoteFromSubspace(PleftMss_proj,x);  
  }
 };
 template<class Field>
 class TwoLevelADEF1defl : public TwoLevelCG<Field>
 {
 public:
  const std::vector<Field> &evec;
  const std::vector<RealD> &eval;
  TwoLevelADEF1defl(RealD tol,
 		   Integer maxit,
 		   LinearOperatorBase<Field>   &FineLinop,
 		   LinearFunction<Field>   &Smoother,
 		   std::vector<Field> &_evec,
 		   std::vector<RealD> &_eval) : 
    TwoLevelCG<Field>(tol,maxit,FineLinop,Smoother,_evec[0].Grid()),
    evec(_evec),
    eval(_eval)
  {};
  // Can just inherit existing M2
  // Can just inherit existing M3
  // Simple vstart - do nothing
  virtual void Vstart(Field & x,const Field & src){
-    return;
+    x=src; // Could apply Q
  };
  // Override PcgM1
  virtual void PcgM1(Field & in, Field & out)
  {
    GRID_TRACE("EvecPreconditioner ");
    int N=evec.size();
    Field Pin(this->grid);
    Field Qin(this->grid);
    //MP  + Q = M(1-AQ) + Q = M
    // // If we are eigenvector deflating in coarse space
    // // Q   = Sum_i |phi_i> 1/lambda_i <phi_i|
    // // A Q = Sum_i |phi_i> <phi_i|
    // // M(1-AQ) = M(1-proj) + Q
    Qin.Checkerboard()=in.Checkerboard();
    Qin = Zero();
    Pin = in;
    for (int i=0;i<N;i++) {
      const Field& tmp = evec[i];
      auto ip = TensorRemove(innerProduct(tmp,in));
      axpy(Qin, ip / eval[i],tmp,Qin);
      axpy(Pin, -ip ,tmp,Pin);
    }
    this->_Smoother(Pin,out);
    out = out + Qin;
  }
 };
-  /////////////////////////////////////////////////////////////////////
+NAMESPACE_END(Grid);
  // Only Def1 has non-trivial Vout. Override in Def1
  /////////////////////////////////////////////////////////////////////
  virtual void   Vout  (Field & in, Field & out,Field & src){
    out = in;
    //case PcgDef1:
    //    //Qb + PT x
    //    ProjectToSubspace(src,PleftProj);     
    //    ApplyInverse(PleftProj,PleftMss_proj); // Ass^{-1} r_s
    //    PromoteFromSubspace(PleftMss_proj,tmp);  
    //    
    //    Pright(in,out);
    //    
    //    linop_d->axpy(out,tmp,out,1.0);
    //    break;
  }
  ////////////////////////////////////////////////////////////////////////////////////////////////
  // Pright and Pleft are common to all implementations
  ////////////////////////////////////////////////////////////////////////////////////////////////
  virtual void Pright(Field & in,Field & out){
    // P_R  = [ 1              0 ] 
    //        [ -Mss^-1 Msb    0 ] 
    Field in_sbar(grid);
    ProjectToSubspace(in,PleftProj);     
    PromoteFromSubspace(PleftProj,out);  
    axpy(in_sbar,-1.0,out,in);       // in_sbar = in - in_s 
    HermOp(in_sbar,out);
    ProjectToSubspace(out,PleftProj);           // Mssbar in_sbar  (project)
    ApplyInverse     (PleftProj,PleftMss_proj); // Mss^{-1} Mssbar 
    PromoteFromSubspace(PleftMss_proj,out);     // 
    axpy(out,-1.0,out,in_sbar);     // in_sbar - Mss^{-1} Mssbar in_sbar
  }
  virtual void Pleft (Field & in,Field & out){
    // P_L  = [ 1  -Mbs Mss^-1] 
    //        [ 0   0         ] 
    Field in_sbar(grid);
    Field    tmp2(grid);
    Field    Mtmp(grid);
    ProjectToSubspace(in,PleftProj);     
    PromoteFromSubspace(PleftProj,out);  
    axpy(in_sbar,-1.0,out,in);      // in_sbar = in - in_s
    ApplyInverse(PleftProj,PleftMss_proj); // Mss^{-1} in_s
    PromoteFromSubspace(PleftMss_proj,out);
    HermOp(out,Mtmp);
    ProjectToSubspace(Mtmp,PleftProj);      // Msbar s Mss^{-1}
    PromoteFromSubspace(PleftProj,tmp2);
    axpy(out,-1.0,tmp2,Mtmp);
    axpy(out,-1.0,out,in_sbar);     // in_sbar - Msbars Mss^{-1} in_s
  }
 }
 template<class Field>
 class TwoLevelFlexiblePcgADef2 : public TwoLevelFlexiblePcg<Field> {
 public:
  virtual void M(Field & in,Field & out,Field & tmp){
  } 
  virtual void M1(Field & in, Field & out,Field & tmp,Field & mp){
  }
  virtual void M2(Field & in, Field & out){
  }
  virtual RealD M3(Field & p, Field & mp,Field & mmp, Field & tmp){
  }
  virtual void Vstart(Field & in, Field & src, Field & r, Field & mp, Field & mmp, Field & tmp){
  }
 }
 /*
 template<class Field>
 class TwoLevelFlexiblePcgAD : public TwoLevelFlexiblePcg<Field> {
 public:
  virtual void M(Field & in,Field & out,Field & tmp); 
  virtual void M1(Field & in, Field & out,Field & tmp,Field & mp);
  virtual void M2(Field & in, Field & out);
  virtual RealD M3(Field & p, Field & mp,Field & mmp, Field & tmp);
  virtual void Vstart(Field & in, Field & src, Field & r, Field & mp, Field & mmp, Field & tmp);
 }
 template<class Field>
 class TwoLevelFlexiblePcgDef1 : public TwoLevelFlexiblePcg<Field> {
 public:
  virtual void M(Field & in,Field & out,Field & tmp); 
  virtual void M1(Field & in, Field & out,Field & tmp,Field & mp);
  virtual void M2(Field & in, Field & out);
  virtual RealD M3(Field & p, Field & mp,Field & mmp, Field & tmp);
  virtual void Vstart(Field & in, Field & src, Field & r, Field & mp, Field & mmp, Field & tmp);
  virtual void   Vout  (Field & in, Field & out,Field & src,Field & tmp);
 }
 template<class Field>
 class TwoLevelFlexiblePcgDef2 : public TwoLevelFlexiblePcg<Field> {
 public:
  virtual void M(Field & in,Field & out,Field & tmp); 
  virtual void M1(Field & in, Field & out,Field & tmp,Field & mp);
  virtual void M2(Field & in, Field & out);
  virtual RealD M3(Field & p, Field & mp,Field & mmp, Field & tmp);
  virtual void Vstart(Field & in, Field & src, Field & r, Field & mp, Field & mmp, Field & tmp);
 }
 template<class Field>
 class TwoLevelFlexiblePcgV11: public TwoLevelFlexiblePcg<Field> {
 public:
  virtual void M(Field & in,Field & out,Field & tmp); 
  virtual void M1(Field & in, Field & out,Field & tmp,Field & mp);
  virtual void M2(Field & in, Field & out);
  virtual RealD M3(Field & p, Field & mp,Field & mmp, Field & tmp);
  virtual void Vstart(Field & in, Field & src, Field & r, Field & mp, Field & mmp, Field & tmp);
 }
 */
 #endif
--- a/Grid/algorithms/iterative/AdefMrhs.h
+++ b/Grid/algorithms/iterative/AdefMrhs.h
@@ -0,0 +1,414 @@
    /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./lib/algorithms/iterative/AdefGeneric.h
    Copyright (C) 2015
 Author: Peter Boyle <paboyle@ph.ed.ac.uk>
    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 */
 #pragma once
  /*
   * Compared to Tang-2009:  P=Pleft. P^T = PRight Q=MssInv. 
   * Script A = SolverMatrix 
   * Script P = Preconditioner
   *
   * Implement ADEF-2
   *
   * Vstart = P^Tx + Qb
   * M1 = P^TM + Q
   * M2=M3=1
   */
 NAMESPACE_BEGIN(Grid);
 template<class Field>
 class TwoLevelCGmrhs
 {
 public:
  RealD   Tolerance;
  Integer MaxIterations;
  GridBase *grid;
  // Fine operator, Smoother, CoarseSolver
  LinearOperatorBase<Field>   &_FineLinop;
  LinearFunction<Field>   &_Smoother;
  GridStopWatch ProjectTimer;
  GridStopWatch PromoteTimer;
  GridStopWatch DeflateTimer;
  GridStopWatch CoarseTimer;
  GridStopWatch FineTimer;
  GridStopWatch SmoothTimer;
  GridStopWatch InsertTimer;
  // more most opertor functions
  TwoLevelCGmrhs(RealD tol,
 		 Integer maxit,
 		 LinearOperatorBase<Field>   &FineLinop,
 		 LinearFunction<Field>       &Smoother,
 		 GridBase *fine) : 
    Tolerance(tol), 
    MaxIterations(maxit),
    _FineLinop(FineLinop),
    _Smoother(Smoother)
  {
    grid       = fine;
  };
  // Vector case
  virtual void operator() (std::vector<Field> &src, std::vector<Field> &x)
  {
    std::cout << GridLogMessage<<"HDCG: mrhs fPcg starting"<<std::endl;
    src[0].Grid()->Barrier();
    int nrhs = src.size();
    std::vector<RealD> f(nrhs);
    std::vector<RealD> rtzp(nrhs);
    std::vector<RealD> rtz(nrhs);
    std::vector<RealD> a(nrhs);
    std::vector<RealD> d(nrhs);
    std::vector<RealD> b(nrhs);
    std::vector<RealD> rptzp(nrhs);
    /////////////////////////////
    // Set up history vectors
    /////////////////////////////
    int mmax = 3;
    std::vector<std::vector<Field> > p(nrhs);   for(int r=0;r<nrhs;r++)  p[r].resize(mmax,grid);
    std::vector<std::vector<Field> > mmp(nrhs); for(int r=0;r<nrhs;r++) mmp[r].resize(mmax,grid);
    std::vector<std::vector<RealD> > pAp(nrhs); for(int r=0;r<nrhs;r++) pAp[r].resize(mmax);
    std::vector<Field> z(nrhs,grid);
    std::vector<Field>  mp (nrhs,grid);
    std::vector<Field>  r  (nrhs,grid);
    std::vector<Field>  mu (nrhs,grid);
    //Initial residual computation & set up
    std::vector<RealD> src_nrm(nrhs);
    for(int rhs=0;rhs<nrhs;rhs++) {
      src_nrm[rhs]=norm2(src[rhs]);
      assert(src_nrm[rhs]!=0.0);
    }
    std::vector<RealD> tn(nrhs);
    GridStopWatch HDCGTimer;
    //////////////////////////
    // x0 = Vstart -- possibly modify guess
    //////////////////////////
    Vstart(x,src);
    for(int rhs=0;rhs<nrhs;rhs++){
      // r0 = b -A x0
      _FineLinop.HermOp(x[rhs],mmp[rhs][0]);
      axpy (r[rhs], -1.0,mmp[rhs][0], src[rhs]);    // Recomputes r=src-Ax0
    }
    //////////////////////////////////
    // Compute z = M1 x
    //////////////////////////////////
    // This needs a multiRHS version for acceleration
    PcgM1(r,z);
    std::vector<RealD> ssq(nrhs);
    std::vector<RealD> rsq(nrhs);
    std::vector<Field> pp(nrhs,grid);
    for(int rhs=0;rhs<nrhs;rhs++){
      rtzp[rhs] =real(innerProduct(r[rhs],z[rhs]));
      p[rhs][0]=z[rhs];
      ssq[rhs]=norm2(src[rhs]);
      rsq[rhs]=  ssq[rhs]*Tolerance*Tolerance;
      //      std::cout << GridLogMessage<<"mrhs HDCG: "<<rhs<<" k=0 residual "<<rtzp[rhs]<<" rsq "<<rsq[rhs]<<"\n";
    }
    ProjectTimer.Reset();
    PromoteTimer.Reset();
    DeflateTimer.Reset();
    CoarseTimer.Reset();
    SmoothTimer.Reset();
    FineTimer.Reset();
    InsertTimer.Reset();
    GridStopWatch M1Timer;
    GridStopWatch M2Timer;
    GridStopWatch M3Timer;
    GridStopWatch LinalgTimer;
    HDCGTimer.Start();
    std::vector<RealD> rn(nrhs);
    for (int k=0;k<=MaxIterations;k++){
      int peri_k  = k % mmax;
      int peri_kp = (k+1) % mmax;
      for(int rhs=0;rhs<nrhs;rhs++){
 	rtz[rhs]=rtzp[rhs];
 	M3Timer.Start();
 	d[rhs]= PcgM3(p[rhs][peri_k],mmp[rhs][peri_k]);
 	M3Timer.Stop();
 	a[rhs] = rtz[rhs]/d[rhs];
 	LinalgTimer.Start();
 	// Memorise this
 	pAp[rhs][peri_k] = d[rhs];
 	axpy(x[rhs],a[rhs],p[rhs][peri_k],x[rhs]);
 	rn[rhs] = axpy_norm(r[rhs],-a[rhs],mmp[rhs][peri_k],r[rhs]);
 	LinalgTimer.Stop();
      }
      // Compute z = M x (for *all* RHS)
      M1Timer.Start();
      PcgM1(r,z);
      M1Timer.Stop();
      RealD max_rn=0.0;
      LinalgTimer.Start();
      for(int rhs=0;rhs<nrhs;rhs++){
 	rtzp[rhs] =real(innerProduct(r[rhs],z[rhs]));
 	//	std::cout << GridLogMessage<<"HDCG::fPcg rhs"<<rhs<<" iteration "<<k<<" : inner rtzp "<<rtzp[rhs]<<"\n";
 	mu[rhs]=z[rhs];
 	p[rhs][peri_kp]=mu[rhs];
 	// Standard search direction p == z + b p 
 	b[rhs] = (rtzp[rhs])/rtz[rhs];
 	int northog = (k>mmax-1)?(mmax-1):k;        // This is the fCG-Tr(mmax-1) algorithm
 	for(int back=0; back < northog; back++){
 	  int peri_back = (k-back)%mmax;
 	  RealD pbApk= real(innerProduct(mmp[rhs][peri_back],p[rhs][peri_kp]));
 	  RealD beta = -pbApk/pAp[rhs][peri_back];
 	  axpy(p[rhs][peri_kp],beta,p[rhs][peri_back],p[rhs][peri_kp]);
 	}
 	RealD rrn=sqrt(rn[rhs]/ssq[rhs]);
 	RealD rtn=sqrt(rtz[rhs]/ssq[rhs]);
 	RealD rtnp=sqrt(rtzp[rhs]/ssq[rhs]);
 	std::cout<<GridLogMessage<<"HDCG:fPcg rhs "<<rhs<<" k= "<<k<<" residual = "<<rrn<<"\n";
 	if ( rrn > max_rn ) max_rn = rrn;
      }
      LinalgTimer.Stop();
      // Stopping condition based on worst case
      if ( max_rn <= Tolerance ) { 
 	HDCGTimer.Stop();
 	std::cout<<GridLogMessage<<"HDCG: mrhs fPcg converged in "<<k<<" iterations and "<<HDCGTimer.Elapsed()<<std::endl;;
 	std::cout<<GridLogMessage<<"HDCG: mrhs fPcg : Linalg  "<<LinalgTimer.Elapsed()<<std::endl;;
 	std::cout<<GridLogMessage<<"HDCG: mrhs fPcg : fine M3 "<<M3Timer.Elapsed()<<std::endl;;
 	std::cout<<GridLogMessage<<"HDCG: mrhs fPcg : prec M1 "<<M1Timer.Elapsed()<<std::endl;;
 	std::cout<<GridLogMessage<<"**** M1 breakdown:"<<std::endl;
 	std::cout<<GridLogMessage<<"HDCG: mrhs fPcg : Project "<<ProjectTimer.Elapsed()<<std::endl;;
 	std::cout<<GridLogMessage<<"HDCG: mrhs fPcg : Promote "<<PromoteTimer.Elapsed()<<std::endl;;
 	std::cout<<GridLogMessage<<"HDCG: mrhs fPcg : Deflate "<<DeflateTimer.Elapsed()<<std::endl;;
 	std::cout<<GridLogMessage<<"HDCG: mrhs fPcg : Coarse  "<<CoarseTimer.Elapsed()<<std::endl;;
 	std::cout<<GridLogMessage<<"HDCG: mrhs fPcg : Fine    "<<FineTimer.Elapsed()<<std::endl;;
 	std::cout<<GridLogMessage<<"HDCG: mrhs fPcg : Smooth  "<<SmoothTimer.Elapsed()<<std::endl;;
 	std::cout<<GridLogMessage<<"HDCG: mrhs fPcg : Insert  "<<InsertTimer.Elapsed()<<std::endl;;
 	for(int rhs=0;rhs<nrhs;rhs++){
 	  _FineLinop.HermOp(x[rhs],mmp[rhs][0]);			  
 	  Field tmp(grid);
 	  axpy(tmp,-1.0,src[rhs],mmp[rhs][0]);
 	  RealD  mmpnorm = sqrt(norm2(mmp[rhs][0]));
 	  RealD  xnorm   = sqrt(norm2(x[rhs]));
 	  RealD  srcnorm = sqrt(norm2(src[rhs]));
 	  RealD  tmpnorm = sqrt(norm2(tmp));
 	  RealD  true_residual = tmpnorm/srcnorm;
 	  std::cout<<GridLogMessage
 		   <<"HDCG: true residual ["<<rhs<<"] is "<<true_residual
 		   <<" solution "<<xnorm
 		   <<" source "<<srcnorm
 		   <<" mmp "<<mmpnorm	  
 		   <<std::endl;
 	}
 	return;
      }
    }
    HDCGTimer.Stop();
    std::cout<<GridLogMessage<<"HDCG: not converged "<<HDCGTimer.Elapsed()<<std::endl;
    for(int rhs=0;rhs<nrhs;rhs++){
      RealD  xnorm   = sqrt(norm2(x[rhs]));
      RealD  srcnorm = sqrt(norm2(src[rhs]));
      std::cout<<GridLogMessage<<"HDCG: non-converged solution "<<xnorm<<" source "<<srcnorm<<std::endl;
    }
  }
 public:
  virtual void PcgM1(std::vector<Field> & in,std::vector<Field> & out) = 0;
  virtual void Vstart(std::vector<Field> & x,std::vector<Field> & src) = 0;
  virtual void PcgM2(const Field & in, Field & out) {
    out=in;
  }
  virtual RealD PcgM3(const Field & p, Field & mmp){
    RealD dd;
    _FineLinop.HermOp(p,mmp);
    ComplexD dot = innerProduct(p,mmp);
    dd=real(dot);
    return dd;
  }
 };
 template<class Field, class CoarseField>
 class TwoLevelADEF2mrhs : public TwoLevelCGmrhs<Field>
 {
 public:
  GridBase *coarsegrid;
  GridBase *coarsegridmrhs;
  LinearFunction<CoarseField> &_CoarseSolverMrhs;
  LinearFunction<CoarseField> &_CoarseSolverPreciseMrhs;
  MultiRHSBlockProject<Field>    &_Projector;
  MultiRHSDeflation<CoarseField> &_Deflator;
  TwoLevelADEF2mrhs(RealD tol,
 		    Integer maxit,
 		    LinearOperatorBase<Field>    &FineLinop,
 		    LinearFunction<Field>        &Smoother,
 		    LinearFunction<CoarseField>  &CoarseSolverMrhs,
 		    LinearFunction<CoarseField>  &CoarseSolverPreciseMrhs,
 		    MultiRHSBlockProject<Field>    &Projector,
 		    MultiRHSDeflation<CoarseField> &Deflator,
 		    GridBase *_coarsemrhsgrid) :
    TwoLevelCGmrhs<Field>(tol, maxit,FineLinop,Smoother,Projector.fine_grid),
    _CoarseSolverMrhs(CoarseSolverMrhs),
    _CoarseSolverPreciseMrhs(CoarseSolverPreciseMrhs),
    _Projector(Projector),
    _Deflator(Deflator)
  {
    coarsegrid = Projector.coarse_grid;
    coarsegridmrhs = _coarsemrhsgrid;// Thi could be in projector
  };
  // Override Vstart
  virtual void Vstart(std::vector<Field> & x,std::vector<Field> & src)
  {
    int nrhs=x.size();
    ///////////////////////////////////
    // Choose x_0 such that 
    // x_0 = guess +  (A_ss^inv) r_s = guess + Ass_inv [src -Aguess]
    //                               = [1 - Ass_inv A] Guess + Assinv src
    //                               = P^T guess + Assinv src 
    //                               = Vstart  [Tang notation]
    // This gives:
    // W^T (src - A x_0) = src_s - A guess_s - r_s
    //                   = src_s - (A guess)_s - src_s  + (A guess)_s 
    //                   = 0 
    ///////////////////////////////////
    std::vector<CoarseField> PleftProj(nrhs,this->coarsegrid);
    std::vector<CoarseField> PleftMss_proj(nrhs,this->coarsegrid);
    CoarseField PleftProjMrhs(this->coarsegridmrhs);
    CoarseField PleftMss_projMrhs(this->coarsegridmrhs);
    this->_Projector.blockProject(src,PleftProj);
    this->_Deflator.DeflateSources(PleftProj,PleftMss_proj);
    for(int rhs=0;rhs<nrhs;rhs++) {
      InsertSliceFast(PleftProj[rhs],PleftProjMrhs,rhs,0);
      InsertSliceFast(PleftMss_proj[rhs],PleftMss_projMrhs,rhs,0); // the guess
    }
    this->_CoarseSolverPreciseMrhs(PleftProjMrhs,PleftMss_projMrhs); // Ass^{-1} r_s
    for(int rhs=0;rhs<nrhs;rhs++) {
      ExtractSliceFast(PleftMss_proj[rhs],PleftMss_projMrhs,rhs,0);
    }
    this->_Projector.blockPromote(x,PleftMss_proj);
  }
  virtual void PcgM1(std::vector<Field> & in,std::vector<Field> & out){
    int nrhs=in.size();
    // [PTM+Q] in = [1 - Q A] M in + Q in = Min + Q [ in -A Min]
    std::vector<Field> tmp(nrhs,this->grid);
    std::vector<Field> Min(nrhs,this->grid);
    std::vector<CoarseField> PleftProj(nrhs,this->coarsegrid);
    std::vector<CoarseField> PleftMss_proj(nrhs,this->coarsegrid);
    CoarseField PleftProjMrhs(this->coarsegridmrhs);
    CoarseField PleftMss_projMrhs(this->coarsegridmrhs);
    for(int rhs=0;rhs<nrhs;rhs++) {
      this->SmoothTimer.Start();
      this->_Smoother(in[rhs],Min[rhs]);
      this->SmoothTimer.Stop();
      this->FineTimer.Start();
      this->_FineLinop.HermOp(Min[rhs],out[rhs]);
      axpy(tmp[rhs],-1.0,out[rhs],in[rhs]);          // resid  = in - A Min
      this->FineTimer.Stop();
    }
    this->ProjectTimer.Start();
    this->_Projector.blockProject(tmp,PleftProj);
    this->ProjectTimer.Stop();
    this->DeflateTimer.Start();
    this->_Deflator.DeflateSources(PleftProj,PleftMss_proj);
    this->DeflateTimer.Stop();
    this->InsertTimer.Start();
    for(int rhs=0;rhs<nrhs;rhs++) {
      InsertSliceFast(PleftProj[rhs],PleftProjMrhs,rhs,0);
      InsertSliceFast(PleftMss_proj[rhs],PleftMss_projMrhs,rhs,0); // the guess
    }
    this->InsertTimer.Stop();
    this->CoarseTimer.Start();
    this->_CoarseSolverMrhs(PleftProjMrhs,PleftMss_projMrhs); // Ass^{-1} [in - A Min]_s
    this->CoarseTimer.Stop();
    this->InsertTimer.Start();
    for(int rhs=0;rhs<nrhs;rhs++) {
      ExtractSliceFast(PleftMss_proj[rhs],PleftMss_projMrhs,rhs,0);
    }
    this->InsertTimer.Stop();
    this->PromoteTimer.Start();
    this->_Projector.blockPromote(tmp,PleftMss_proj);// tmp= Q[in - A Min]  
    this->PromoteTimer.Stop();
    this->FineTimer.Start();
    for(int rhs=0;rhs<nrhs;rhs++) {
      axpy(out[rhs],1.0,Min[rhs],tmp[rhs]); // Min+tmp
    }
    this->FineTimer.Stop();
  }
 };
 NAMESPACE_END(Grid);
--- a/Grid/algorithms/iterative/ConjugateGradient.h
+++ b/Grid/algorithms/iterative/ConjugateGradient.h
@@ -54,11 +54,14 @@ public:
  ConjugateGradient(RealD tol, Integer maxit, bool err_on_no_conv = true)
    : Tolerance(tol),
      MaxIterations(maxit),
-      ErrorOnNoConverge(err_on_no_conv){};
+      ErrorOnNoConverge(err_on_no_conv)
  {};
  void operator()(LinearOperatorBase<Field> &Linop, const Field &src, Field &psi) {
    GRID_TRACE("ConjugateGradient");
    GridStopWatch PreambleTimer;
    PreambleTimer.Start();
    psi.Checkerboard() = src.Checkerboard();
    conformable(psi, src);
@@ -66,22 +69,26 @@ public:
    RealD cp, c, a, d, b, ssq, qq;
    //RealD b_pred;
-    Field p(src);
+    // Was doing copies
-    Field mmp(src);
+    Field p(src.Grid());
-    Field r(src);
+    Field mmp(src.Grid());
    Field r(src.Grid());
    // Initial residual computation & set up
    ssq = norm2(src);
    RealD guess = norm2(psi);
    assert(std::isnan(guess) == 0);
-    
+    if ( guess == 0.0 ) {
-    Linop.HermOpAndNorm(psi, mmp, d, b);
+      r = src;
-    
+      p = r;
-    r = src - mmp;
+      a = ssq;
-    p = r;
+    } else { 
-
+      Linop.HermOpAndNorm(psi, mmp, d, b);
-    a = norm2(p);
+      r = src - mmp;
      p = r;
      a = norm2(p);
    }
    cp = a;
    ssq = norm2(src);
    // Handle trivial case of zero src
    if (ssq == 0.){
@@ -111,6 +118,7 @@ public:
    std::cout << GridLogIterative << std::setprecision(8)
              << "ConjugateGradient: k=0 residual " << cp << " target " << rsq << std::endl;
    PreambleTimer.Stop();
    GridStopWatch LinalgTimer;
    GridStopWatch InnerTimer;
    GridStopWatch AxpyNormTimer;
@@ -183,13 +191,14 @@ public:
 		  << "\tTrue residual " << true_residual
 		  << "\tTarget " << Tolerance << std::endl;
-        std::cout << GridLogMessage << "Time breakdown "<<std::endl;
+	//	std::cout << GridLogMessage << "\tPreamble   " << PreambleTimer.Elapsed() <<std::endl;
-	std::cout << GridLogMessage << "\tElapsed    " << SolverTimer.Elapsed() <<std::endl;
+	std::cout << GridLogMessage << "\tSolver Elapsed    " << SolverTimer.Elapsed() <<std::endl;
-	std::cout << GridLogMessage << "\tMatrix     " << MatrixTimer.Elapsed() <<std::endl;
+        std::cout << GridLogPerformance << "Time breakdown "<<std::endl;
-	std::cout << GridLogMessage << "\tLinalg     " << LinalgTimer.Elapsed() <<std::endl;
+	std::cout << GridLogPerformance << "\tMatrix     " << MatrixTimer.Elapsed() <<std::endl;
-	std::cout << GridLogMessage << "\tInner      " << InnerTimer.Elapsed() <<std::endl;
+	std::cout << GridLogPerformance << "\tLinalg     " << LinalgTimer.Elapsed() <<std::endl;
-	std::cout << GridLogMessage << "\tAxpyNorm   " << AxpyNormTimer.Elapsed() <<std::endl;
+	std::cout << GridLogPerformance << "\t\tInner      " << InnerTimer.Elapsed() <<std::endl;
-	std::cout << GridLogMessage << "\tLinearComb " << LinearCombTimer.Elapsed() <<std::endl;
+	std::cout << GridLogPerformance << "\t\tAxpyNorm   " << AxpyNormTimer.Elapsed() <<std::endl;
 	std::cout << GridLogPerformance << "\t\tLinearComb " << LinearCombTimer.Elapsed() <<std::endl;
 	std::cout << GridLogDebug << "\tMobius flop rate " << DwfFlops/ usecs<< " Gflops " <<std::endl;
@@ -202,12 +211,22 @@ public:
      }
    }
    // Failed. Calculate true residual before giving up                                                         
-    Linop.HermOpAndNorm(psi, mmp, d, qq);
+    // Linop.HermOpAndNorm(psi, mmp, d, qq);
-    p = mmp - src;
+    //    p = mmp - src;
    //TrueResidual = sqrt(norm2(p)/ssq);
    //    TrueResidual = 1;
-    TrueResidual = sqrt(norm2(p)/ssq);
+    std::cout << GridLogMessage << "ConjugateGradient did NOT converge "<<k<<" / "<< MaxIterations
-
+    	      <<" residual "<< std::sqrt(cp / ssq)<< std::endl;
-    std::cout << GridLogMessage << "ConjugateGradient did NOT converge "<<k<<" / "<< MaxIterations<< std::endl;
+    SolverTimer.Stop();
    std::cout << GridLogMessage << "\tPreamble   " << PreambleTimer.Elapsed() <<std::endl;
    std::cout << GridLogMessage << "\tSolver     " << SolverTimer.Elapsed() <<std::endl;
    std::cout << GridLogMessage << "Solver breakdown "<<std::endl;
    std::cout << GridLogMessage << "\tMatrix     " << MatrixTimer.Elapsed() <<std::endl;
    std::cout << GridLogMessage<< "\tLinalg     " << LinalgTimer.Elapsed() <<std::endl;
    std::cout << GridLogPerformance << "\t\tInner      " << InnerTimer.Elapsed() <<std::endl;
    std::cout << GridLogPerformance << "\t\tAxpyNorm   " << AxpyNormTimer.Elapsed() <<std::endl;
    std::cout << GridLogPerformance << "\t\tLinearComb " << LinearCombTimer.Elapsed() <<std::endl;
    if (ErrorOnNoConverge) assert(0);
    IterationsToComplete = k;
--- a/Grid/algorithms/iterative/ConjugateGradientMultiShift.h
+++ b/Grid/algorithms/iterative/ConjugateGradientMultiShift.h
@@ -144,7 +144,7 @@ public:
    for(int s=0;s<nshift;s++){
      rsq[s] = cp * mresidual[s] * mresidual[s];
      std::cout<<GridLogMessage<<"ConjugateGradientMultiShift: shift "<<s
-	       <<" target resid "<<rsq[s]<<std::endl;
+	       <<" target resid^2 "<<rsq[s]<<std::endl;
      ps[s] = src;
    }
    // r and p for primary
--- a/Grid/algorithms/iterative/ImplicitlyRestartedBlockLanczosCoarse.h
+++ b/Grid/algorithms/iterative/ImplicitlyRestartedBlockLanczosCoarse.h
--- a/Grid/algorithms/iterative/ImplicitlyRestartedLanczos.h
+++ b/Grid/algorithms/iterative/ImplicitlyRestartedLanczos.h
@@ -79,14 +79,16 @@ template<class Field> class ImplicitlyRestartedLanczosHermOpTester  : public Imp
    RealD vv = norm2(v) / ::pow(evalMaxApprox,2.0);
    std::cout.precision(13);
    std::cout<<GridLogIRL  << "[" << std::setw(3)<<j<<"] "
 	     <<"eval = "<<std::setw(25)<< eval << " (" << eval_poly << ")"
 	     <<" |H B[i] - eval[i]B[i]|^2 / evalMaxApprox^2 " << std::setw(25) << vv
 	     <<std::endl;
    int conv=0;
    if( (vv<eresid*eresid) ) conv = 1;
    std::cout<<GridLogIRL  << "[" << std::setw(3)<<j<<"] "
 	     <<"eval = "<<std::setw(25)<< eval << " (" << eval_poly << ")"
 	     <<" |H B[i] - eval[i]B[i]|^2 / evalMaxApprox^2 " << std::setw(25) << vv
 	     <<" target " << eresid*eresid << " conv " <<conv
 	     <<std::endl;
    return conv;
  }
 };
@@ -457,7 +459,7 @@ until convergence
 	    std::vector<Field>& evec,
 	    Field& w,int Nm,int k)
  {
-    std::cout<<GridLogIRL << "Lanczos step " <<k<<std::endl;
+    std::cout<<GridLogDebug << "Lanczos step " <<k<<std::endl;
    const RealD tiny = 1.0e-20;
    assert( k< Nm );
@@ -465,7 +467,7 @@ until convergence
    Field& evec_k = evec[k];
-    _PolyOp(evec_k,w);    std::cout<<GridLogIRL << "PolyOp" <<std::endl;
+    _PolyOp(evec_k,w);    std::cout<<GridLogDebug << "PolyOp" <<std::endl;
    if(k>0) w -= lme[k-1] * evec[k-1];
@@ -480,18 +482,18 @@ until convergence
    lme[k] = beta;
    if ( (k>0) && ( (k % orth_period) == 0 )) {
-      std::cout<<GridLogIRL << "Orthogonalising " <<k<<std::endl;
+      std::cout<<GridLogDebug << "Orthogonalising " <<k<<std::endl;
      orthogonalize(w,evec,k); // orthonormalise
-      std::cout<<GridLogIRL << "Orthogonalised " <<k<<std::endl;
+      std::cout<<GridLogDebug << "Orthogonalised " <<k<<std::endl;
    }
    if(k < Nm-1) evec[k+1] = w;
-    std::cout<<GridLogIRL << "alpha[" << k << "] = " << zalph << " beta[" << k << "] = "<<beta<<std::endl;
+    std::cout<<GridLogIRL << "Lanczos step alpha[" << k << "] = " << zalph << " beta[" << k << "] = "<<beta<<std::endl;
    if ( beta < tiny ) 
      std::cout<<GridLogIRL << " beta is tiny "<<beta<<std::endl;
-    std::cout<<GridLogIRL << "Lanczos step complete " <<k<<std::endl;
+    std::cout<<GridLogDebug << "Lanczos step complete " <<k<<std::endl;
  }
  void diagonalize_Eigen(std::vector<RealD>& lmd, std::vector<RealD>& lme, 
--- a/Grid/algorithms/iterative/NormalEquations.h
+++ b/Grid/algorithms/iterative/NormalEquations.h
@@ -33,7 +33,7 @@ NAMESPACE_BEGIN(Grid);
 ///////////////////////////////////////////////////////////////////////////////////////////////////////
 // Take a matrix and form an NE solver calling a Herm solver
 ///////////////////////////////////////////////////////////////////////////////////////////////////////
-template<class Field> class NormalEquations {
+template<class Field> class NormalEquations : public LinearFunction<Field>{
 private:
  SparseMatrixBase<Field> & _Matrix;
  OperatorFunction<Field> & _HermitianSolver;
@@ -60,7 +60,7 @@ public:
  }     
 };
-template<class Field> class HPDSolver {
+template<class Field> class HPDSolver : public LinearFunction<Field> {
 private:
  LinearOperatorBase<Field> & _Matrix;
  OperatorFunction<Field> & _HermitianSolver;
@@ -78,13 +78,13 @@ public:
  void operator() (const Field &in, Field &out){
    _Guess(in,out);
-    _HermitianSolver(_Matrix,in,out);  // Mdag M out = Mdag in
+    _HermitianSolver(_Matrix,in,out);  //M out = in
  }     
 };
-template<class Field> class MdagMSolver {
+template<class Field> class MdagMSolver : public LinearFunction<Field> {
 private:
  SparseMatrixBase<Field> & _Matrix;
  OperatorFunction<Field> & _HermitianSolver;
--- a/Grid/algorithms/iterative/PowerMethod.h
+++ b/Grid/algorithms/iterative/PowerMethod.h
@@ -20,7 +20,7 @@ template<class Field> class PowerMethod
    RealD evalMaxApprox = 0.0; 
    auto src_n = src; 
    auto tmp = src; 
-    const int _MAX_ITER_EST_ = 50; 
+    const int _MAX_ITER_EST_ = 100; 
    for (int i=0;i<_MAX_ITER_EST_;i++) { 
--- a/Grid/algorithms/multigrid/Aggregates.h
+++ b/Grid/algorithms/multigrid/Aggregates.h
@@ -0,0 +1,478 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./lib/algorithms/Aggregates.h
    Copyright (C) 2015
 Author: Azusa Yamaguchi <ayamaguc@staffmail.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>
    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 */
 #pragma once
 NAMESPACE_BEGIN(Grid);
 inline RealD AggregatePowerLaw(RealD x)
 {
  //  return std::pow(x,-4);
  //  return std::pow(x,-3);
  return std::pow(x,-5);
 }
 template<class Fobj,class CComplex,int nbasis>
 class Aggregation {
 public:
  constexpr int Nbasis(void) { return nbasis; };
  typedef iVector<CComplex,nbasis >             siteVector;
  typedef Lattice<siteVector>                 CoarseVector;
  typedef Lattice<iMatrix<CComplex,nbasis > > CoarseMatrix;
  typedef Lattice< CComplex >   CoarseScalar; // used for inner products on fine field
  typedef Lattice<Fobj >        FineField;
  GridBase *CoarseGrid;
  GridBase *FineGrid;
  std::vector<Lattice<Fobj> > subspace;
  int checkerboard;
  int Checkerboard(void){return checkerboard;}
  Aggregation(GridBase *_CoarseGrid,GridBase *_FineGrid,int _checkerboard) : 
    CoarseGrid(_CoarseGrid),
    FineGrid(_FineGrid),
    subspace(nbasis,_FineGrid),
    checkerboard(_checkerboard)
  {
  };
  void Orthogonalise(void){
    CoarseScalar InnerProd(CoarseGrid); 
    //    std::cout << GridLogMessage <<" Block Gramm-Schmidt pass 1"<<std::endl;
    blockOrthogonalise(InnerProd,subspace);
  } 
  void ProjectToSubspace(CoarseVector &CoarseVec,const FineField &FineVec){
    blockProject(CoarseVec,FineVec,subspace);
  }
  void PromoteFromSubspace(const CoarseVector &CoarseVec,FineField &FineVec){
    FineVec.Checkerboard() = subspace[0].Checkerboard();
    blockPromote(CoarseVec,FineVec,subspace);
  }
  virtual void CreateSubspaceRandom(GridParallelRNG  &RNG) {
    int nn=nbasis;
    RealD scale;
    FineField noise(FineGrid);
    for(int b=0;b<nn;b++){
      subspace[b] = Zero();
      gaussian(RNG,noise);
      scale = std::pow(norm2(noise),-0.5); 
      noise=noise*scale;
      subspace[b] = noise;
    }
  }
  virtual void CreateSubspace(GridParallelRNG  &RNG,LinearOperatorBase<FineField> &hermop,int nn=nbasis)
  {
    RealD scale;
    ConjugateGradient<FineField> CG(1.0e-2,100,false);
    FineField noise(FineGrid);
    FineField Mn(FineGrid);
    for(int b=0;b<nn;b++){
      subspace[b] = Zero();
      gaussian(RNG,noise);
      scale = std::pow(norm2(noise),-0.5); 
      noise=noise*scale;
      hermop.Op(noise,Mn); std::cout<<GridLogMessage << "noise   ["<<b<<"] <n|MdagM|n> "<<norm2(Mn)<<std::endl;
      for(int i=0;i<1;i++){
 	CG(hermop,noise,subspace[b]);
 	noise = subspace[b];
 	scale = std::pow(norm2(noise),-0.5); 
 	noise=noise*scale;
      }
      hermop.Op(noise,Mn); std::cout<<GridLogMessage << "filtered["<<b<<"] <f|MdagM|f> "<<norm2(Mn)<<std::endl;
      subspace[b]   = noise;
    }
  }
  ////////////////////////////////////////////////////////////////////////////////////////////////
  // World of possibilities here. But have tried quite a lot of experiments (250+ jobs run on Summit)
  // and this is the best I found
  ////////////////////////////////////////////////////////////////////////////////////////////////
  virtual void CreateSubspaceChebyshev(GridParallelRNG  &RNG,LinearOperatorBase<FineField> &hermop,
 				       int nn,
 				       double hi,
 				       double lo,
 				       int orderfilter,
 				       int ordermin,
 				       int orderstep,
 				       double filterlo
 				       ) {
    RealD scale;
    FineField noise(FineGrid);
    FineField Mn(FineGrid);
    FineField tmp(FineGrid);
    // New normalised noise
    gaussian(RNG,noise);
    scale = std::pow(norm2(noise),-0.5); 
    noise=noise*scale;
    std::cout << GridLogMessage<<" Chebyshev subspace pass-1 : ord "<<orderfilter<<" ["<<lo<<","<<hi<<"]"<<std::endl;
    std::cout << GridLogMessage<<" Chebyshev subspace pass-2 : nbasis"<<nn<<" min "
 	      <<ordermin<<" step "<<orderstep
 	      <<" lo"<<filterlo<<std::endl;
    // Initial matrix element
    hermop.Op(noise,Mn); std::cout<<GridLogMessage << "noise <n|MdagM|n> "<<norm2(Mn)<<std::endl;
    int b =0;
    {
      // Filter
      Chebyshev<FineField> Cheb(lo,hi,orderfilter);
      Cheb(hermop,noise,Mn);
      // normalise
      scale = std::pow(norm2(Mn),-0.5); 	Mn=Mn*scale;
      subspace[b]   = Mn;
      hermop.Op(Mn,tmp); 
      std::cout<<GridLogMessage << "filt ["<<b<<"] <n|MdagM|n> "<<norm2(tmp)<<std::endl;
      b++;
    }
    // Generate a full sequence of Chebyshevs
    {
      lo=filterlo;
      noise=Mn;
      FineField T0(FineGrid); T0 = noise;  
      FineField T1(FineGrid); 
      FineField T2(FineGrid);
      FineField y(FineGrid);
      FineField *Tnm = &T0;
      FineField *Tn  = &T1;
      FineField *Tnp = &T2;
      // Tn=T1 = (xscale M + mscale)in
      RealD xscale = 2.0/(hi-lo);
      RealD mscale = -(hi+lo)/(hi-lo);
      hermop.HermOp(T0,y);
      T1=y*xscale+noise*mscale;
      for(int n=2;n<=ordermin+orderstep*(nn-2);n++){
 	hermop.HermOp(*Tn,y);
 	autoView( y_v , y, AcceleratorWrite);
 	autoView( Tn_v , (*Tn), AcceleratorWrite);
 	autoView( Tnp_v , (*Tnp), AcceleratorWrite);
 	autoView( Tnm_v , (*Tnm), AcceleratorWrite);
 	const int Nsimd = CComplex::Nsimd();
 	accelerator_for(ss, FineGrid->oSites(), Nsimd, {
 	  coalescedWrite(y_v[ss],xscale*y_v(ss)+mscale*Tn_v(ss));
 	  coalescedWrite(Tnp_v[ss],2.0*y_v(ss)-Tnm_v(ss));
        });
 	// Possible more fine grained control is needed than a linear sweep,
 	// but huge productivity gain if this is simple algorithm and not a tunable
 	int m =1;
 	if ( n>=ordermin ) m=n-ordermin;
 	if ( (m%orderstep)==0 ) { 
 	  Mn=*Tnp;
 	  scale = std::pow(norm2(Mn),-0.5);         Mn=Mn*scale;
 	  subspace[b] = Mn;
 	  hermop.Op(Mn,tmp); 
 	  std::cout<<GridLogMessage << n<<" filt ["<<b<<"] <n|MdagM|n> "<<norm2(tmp)<<std::endl;
 	  b++;
 	}
 	// Cycle pointers to avoid copies
 	FineField *swizzle = Tnm;
 	Tnm    =Tn;
 	Tn     =Tnp;
 	Tnp    =swizzle;
      }
    }
    assert(b==nn);
  }
  virtual void CreateSubspaceChebyshev(GridParallelRNG  &RNG,LinearOperatorBase<FineField> &hermop,
 				       int nn,
 				       double hi,
 				       double lo,
 				       int orderfilter
 				       ) {
    RealD scale;
    FineField noise(FineGrid);
    FineField Mn(FineGrid);
    FineField tmp(FineGrid);
    // New normalised noise
    std::cout << GridLogMessage<<" Chebyshev subspace pure noise : ord "<<orderfilter<<" ["<<lo<<","<<hi<<"]"<<std::endl;
    std::cout << GridLogMessage<<" Chebyshev subspace pure noise  : nbasis "<<nn<<std::endl;
    for(int b =0;b<nbasis;b++)
    {
      gaussian(RNG,noise);
      scale = std::pow(norm2(noise),-0.5); 
      noise=noise*scale;
      // Initial matrix element
      hermop.Op(noise,Mn);
      if(b==0) std::cout<<GridLogMessage << "noise <n|MdagM|n> "<<norm2(Mn)<<std::endl;
      // Filter
      Chebyshev<FineField> Cheb(lo,hi,orderfilter);
      Cheb(hermop,noise,Mn);
      scale = std::pow(norm2(Mn),-0.5); 	Mn=Mn*scale;
      // Refine
      Chebyshev<FineField> PowerLaw(lo,hi,1000,AggregatePowerLaw);
      noise = Mn;
      PowerLaw(hermop,noise,Mn);
      scale = std::pow(norm2(Mn),-0.5); 	Mn=Mn*scale;
      // normalise
      subspace[b]   = Mn;
      hermop.Op(Mn,tmp); 
      std::cout<<GridLogMessage << "filt ["<<b<<"] <n|MdagM|n> "<<norm2(tmp)<<std::endl;
    }
  }
  virtual void CreateSubspaceChebyshevPowerLaw(GridParallelRNG  &RNG,LinearOperatorBase<FineField> &hermop,
 					       int nn,
 					       double hi,
 					       int orderfilter
 					       ) {
    RealD scale;
    FineField noise(FineGrid);
    FineField Mn(FineGrid);
    FineField tmp(FineGrid);
    // New normalised noise
    std::cout << GridLogMessage<<" Chebyshev subspace pure noise : ord "<<orderfilter<<" [0,"<<hi<<"]"<<std::endl;
    std::cout << GridLogMessage<<" Chebyshev subspace pure noise  : nbasis "<<nn<<std::endl;
    for(int b =0;b<nbasis;b++)
    {
      gaussian(RNG,noise);
      scale = std::pow(norm2(noise),-0.5); 
      noise=noise*scale;
      // Initial matrix element
      hermop.Op(noise,Mn);
      if(b==0) std::cout<<GridLogMessage << "noise <n|MdagM|n> "<<norm2(Mn)<<std::endl;
      // Filter
      Chebyshev<FineField> Cheb(0.0,hi,orderfilter,AggregatePowerLaw);
      Cheb(hermop,noise,Mn);
      // normalise
      scale = std::pow(norm2(Mn),-0.5); 	Mn=Mn*scale;
      subspace[b]   = Mn;
      hermop.Op(Mn,tmp); 
      std::cout<<GridLogMessage << "filt ["<<b<<"] <n|MdagM|n> "<<norm2(tmp)<<std::endl;
    }
  }
  virtual void CreateSubspaceChebyshevNew(GridParallelRNG  &RNG,LinearOperatorBase<FineField> &hermop,
 					  double hi
 					  ) {
    RealD scale;
    FineField noise(FineGrid);
    FineField Mn(FineGrid);
    FineField tmp(FineGrid);
    // New normalised noise
    for(int b =0;b<nbasis;b++)
    {
      gaussian(RNG,noise);
      scale = std::pow(norm2(noise),-0.5); 
      noise=noise*scale;
      // Initial matrix element
      hermop.Op(noise,Mn);
      if(b==0) std::cout<<GridLogMessage << "noise <n|MdagM|n> "<<norm2(Mn)<<std::endl;
      // Filter
      //#opt2(x) =  acheb(x,3,90,300)* acheb(x,1,90,50) * acheb(x,0.5,90,200) * acheb(x,0.05,90,400) * acheb(x,0.01,90,1500)
      /*266
      Chebyshev<FineField> Cheb1(3.0,hi,300);
      Chebyshev<FineField> Cheb2(1.0,hi,50);
      Chebyshev<FineField> Cheb3(0.5,hi,300);
      Chebyshev<FineField> Cheb4(0.05,hi,500);
      Chebyshev<FineField> Cheb5(0.01,hi,2000);
      */
      /* 242 */
      /*
      Chebyshev<FineField> Cheb3(0.1,hi,300);
      Chebyshev<FineField> Cheb2(0.02,hi,1000);
      Chebyshev<FineField> Cheb1(0.003,hi,2000);
      8?
      */
      /* How many??
      */
      Chebyshev<FineField> Cheb2(0.001,hi,2500); // 169 iters on HDCG after refine
      Chebyshev<FineField> Cheb1(0.02,hi,600);
      //      Chebyshev<FineField> Cheb2(0.001,hi,1500);
      //      Chebyshev<FineField> Cheb1(0.02,hi,600);
      Cheb1(hermop,noise,Mn); scale = std::pow(norm2(Mn),-0.5); 	noise=Mn*scale;
      hermop.Op(noise,tmp); std::cout<<GridLogMessage << "Cheb1 <n|MdagM|n> "<<norm2(tmp)<<std::endl;
      Cheb2(hermop,noise,Mn); scale = std::pow(norm2(Mn),-0.5); 	noise=Mn*scale;
      hermop.Op(noise,tmp); std::cout<<GridLogMessage << "Cheb2 <n|MdagM|n> "<<norm2(tmp)<<std::endl;
      //      Cheb3(hermop,noise,Mn); scale = std::pow(norm2(Mn),-0.5); 	noise=Mn*scale;
      //      hermop.Op(noise,tmp); std::cout<<GridLogMessage << "Cheb3 <n|MdagM|n> "<<norm2(tmp)<<std::endl;
      //      Cheb4(hermop,noise,Mn); scale = std::pow(norm2(Mn),-0.5); 	noise=Mn*scale;
      //      hermop.Op(noise,tmp); std::cout<<GridLogMessage << "Cheb4 <n|MdagM|n> "<<norm2(tmp)<<std::endl;
      //      Cheb5(hermop,noise,Mn); scale = std::pow(norm2(Mn),-0.5); 	noise=Mn*scale;
      //      hermop.Op(noise,tmp); std::cout<<GridLogMessage << "Cheb5 <n|MdagM|n> "<<norm2(tmp)<<std::endl;
      subspace[b]   = noise;
      hermop.Op(subspace[b],tmp); 
      std::cout<<GridLogMessage << "filt ["<<b<<"] <n|MdagM|n> "<<norm2(tmp)<< " norm " << norm2(noise)<<std::endl;
    }
  }
  virtual void CreateSubspaceMultishift(GridParallelRNG  &RNG,LinearOperatorBase<FineField> &hermop,
 					double Lo,double tol,int maxit)
  {
    RealD scale;
    FineField noise(FineGrid);
    FineField Mn(FineGrid);
    FineField tmp(FineGrid);
    // New normalised noise
    std::cout << GridLogMessage<<" Multishift subspace : Lo "<<Lo<<std::endl;
    // Filter
    // [ 1/6(x+Lo)  - 1/2(x+2Lo) + 1/2(x+3Lo)  -1/6(x+4Lo) = Lo^3 /[ (x+1Lo)(x+2Lo)(x+3Lo)(x+4Lo) ]
    //
    // 1/(x+Lo)  - 1/(x+2 Lo)
    double epsilon      = Lo/3;
    std::vector<RealD> alpha({1.0/6.0,-1.0/2.0,1.0/2.0,-1.0/6.0});
    std::vector<RealD> shifts({Lo,Lo+epsilon,Lo+2*epsilon,Lo+3*epsilon});
    std::vector<RealD> tols({tol,tol,tol,tol});
    std::cout << "sizes "<<alpha.size()<<" "<<shifts.size()<<" "<<tols.size()<<std::endl;
    MultiShiftFunction msf(4,0.0,95.0);
    std::cout << "msf constructed "<<std::endl;
    msf.poles=shifts;
    msf.residues=alpha;
    msf.tolerances=tols;
    msf.norm=0.0;
    msf.order=alpha.size();
    ConjugateGradientMultiShift<FineField> MSCG(maxit,msf);
    for(int b =0;b<nbasis;b++)
    {
      gaussian(RNG,noise);
      scale = std::pow(norm2(noise),-0.5); 
      noise=noise*scale;
      // Initial matrix element
      hermop.Op(noise,Mn);
      if(b==0) std::cout<<GridLogMessage << "noise <n|MdagM|n> "<<norm2(Mn)<<std::endl;
      MSCG(hermop,noise,Mn);
      scale = std::pow(norm2(Mn),-0.5); 	Mn=Mn*scale;
      subspace[b]   = Mn;
      hermop.Op(Mn,tmp); 
      std::cout<<GridLogMessage << "filt ["<<b<<"] <n|MdagM|n> "<<norm2(tmp)<<std::endl;
    }
  }
  virtual void RefineSubspace(LinearOperatorBase<FineField> &hermop,
 			      double Lo,double tol,int maxit)
  {
    FineField tmp(FineGrid);
    for(int b =0;b<nbasis;b++)
    {
      ConjugateGradient<FineField>  CGsloppy(tol,maxit,false);
      ShiftedHermOpLinearOperator<FineField> ShiftedFineHermOp(hermop,Lo);
      tmp=Zero();
      CGsloppy(hermop,subspace[b],tmp);
      RealD scale = std::pow(norm2(tmp),-0.5); 	tmp=tmp*scale;
      subspace[b]=tmp;
      hermop.Op(subspace[b],tmp);
      std::cout<<GridLogMessage << "filt ["<<b<<"] <n|MdagM|n> "<<norm2(tmp)<<std::endl;
    }
  }
  virtual void RefineSubspaceHDCG(LinearOperatorBase<FineField> &hermop,
 				  TwoLevelADEF2mrhs<FineField,CoarseVector> & theHDCG,
 				  int nrhs)
  {
    std::vector<FineField> src_mrhs(nrhs,FineGrid);
    std::vector<FineField> res_mrhs(nrhs,FineGrid);
    FineField tmp(FineGrid);
    for(int b =0;b<nbasis;b+=nrhs)
    {
      tmp = subspace[b];
      RealD scale = std::pow(norm2(tmp),-0.5); 	tmp=tmp*scale;
      subspace[b] =tmp;
      hermop.Op(subspace[b],tmp);
      std::cout<<GridLogMessage << "before filt ["<<b<<"] <n|MdagM|n> "<<norm2(tmp)<<std::endl;
      for(int r=0;r<MIN(nbasis-b,nrhs);r++){
 	src_mrhs[r] = subspace[b+r];
      }
      for(int r=0;r<nrhs;r++){
 	res_mrhs[r] = Zero();
      }
      theHDCG(src_mrhs,res_mrhs);
      for(int r=0;r<MIN(nbasis-b,nrhs);r++){
 	tmp = res_mrhs[r];
 	RealD scale = std::pow(norm2(tmp),-0.5); tmp=tmp*scale;
 	subspace[b+r]=tmp;
      }
      hermop.Op(subspace[b],tmp);
      std::cout<<GridLogMessage << "after filt ["<<b<<"] <n|MdagM|n> "<<norm2(tmp)<<std::endl;
    }
  }
 };
 NAMESPACE_END(Grid);
--- a/Grid/algorithms/multigrid/CoarsenedMatrix.h
+++ b/Grid/algorithms/multigrid/CoarsenedMatrix.h
@@ -56,243 +56,6 @@ inline void blockMaskedInnerProduct(Lattice<CComplex> &CoarseInner,
  blockSum(CoarseInner,fine_inner_msk);
 }
 class Geometry {
 public:
  int npoint;
  int base;
  std::vector<int> directions   ;
  std::vector<int> displacements;
  std::vector<int> points_dagger;
  Geometry(int _d)  {
    base = (_d==5) ? 1:0;
    // make coarse grid stencil for 4d , not 5d
    if ( _d==5 ) _d=4;
    npoint = 2*_d+1;
    directions.resize(npoint);
    displacements.resize(npoint);
    points_dagger.resize(npoint);
    for(int d=0;d<_d;d++){
      directions[d   ] = d+base;
      directions[d+_d] = d+base;
      displacements[d  ] = +1;
      displacements[d+_d]= -1;
      points_dagger[d   ] = d+_d;
      points_dagger[d+_d] = d;
    }
    directions   [2*_d]=0;
    displacements[2*_d]=0;
    points_dagger[2*_d]=2*_d;
  }
  int point(int dir, int disp) {
    assert(disp == -1 || disp == 0 || disp == 1);
    assert(base+0 <= dir && dir < base+4);
    // directions faster index = new indexing
    // 4d (base = 0):
    // point 0  1  2  3  4  5  6  7  8
    // dir   0  1  2  3  0  1  2  3  0
    // disp +1 +1 +1 +1 -1 -1 -1 -1  0
    // 5d (base = 1):
    // point 0  1  2  3  4  5  6  7  8
    // dir   1  2  3  4  1  2  3  4  0
    // disp +1 +1 +1 +1 -1 -1 -1 -1  0
    // displacements faster index = old indexing
    // 4d (base = 0):
    // point 0  1  2  3  4  5  6  7  8
    // dir   0  0  1  1  2  2  3  3  0
    // disp +1 -1 +1 -1 +1 -1 +1 -1  0
    // 5d (base = 1):
    // point 0  1  2  3  4  5  6  7  8
    // dir   1  1  2  2  3  3  4  4  0
    // disp +1 -1 +1 -1 +1 -1 +1 -1  0
    if(dir == 0 and disp == 0)
      return 8;
    else // New indexing
      return (1 - disp) / 2 * 4 + dir - base;
    // else // Old indexing
    //   return (4 * (dir - base) + 1 - disp) / 2;
  }
 };
 template<class Fobj,class CComplex,int nbasis>
 class Aggregation   {
 public:
  typedef iVector<CComplex,nbasis >             siteVector;
  typedef Lattice<siteVector>                 CoarseVector;
  typedef Lattice<iMatrix<CComplex,nbasis > > CoarseMatrix;
  typedef Lattice< CComplex >   CoarseScalar; // used for inner products on fine field
  typedef Lattice<Fobj >        FineField;
  GridBase *CoarseGrid;
  GridBase *FineGrid;
  std::vector<Lattice<Fobj> > subspace;
  int checkerboard;
  int Checkerboard(void){return checkerboard;}
  Aggregation(GridBase *_CoarseGrid,GridBase *_FineGrid,int _checkerboard) : 
    CoarseGrid(_CoarseGrid),
    FineGrid(_FineGrid),
    subspace(nbasis,_FineGrid),
    checkerboard(_checkerboard)
  {
  };
  void Orthogonalise(void){
    CoarseScalar InnerProd(CoarseGrid); 
    std::cout << GridLogMessage <<" Block Gramm-Schmidt pass 1"<<std::endl;
    blockOrthogonalise(InnerProd,subspace);
  } 
  void ProjectToSubspace(CoarseVector &CoarseVec,const FineField &FineVec){
    blockProject(CoarseVec,FineVec,subspace);
  }
  void PromoteFromSubspace(const CoarseVector &CoarseVec,FineField &FineVec){
    FineVec.Checkerboard() = subspace[0].Checkerboard();
    blockPromote(CoarseVec,FineVec,subspace);
  }
  virtual void CreateSubspace(GridParallelRNG  &RNG,LinearOperatorBase<FineField> &hermop,int nn=nbasis) {
    RealD scale;
    ConjugateGradient<FineField> CG(1.0e-2,100,false);
    FineField noise(FineGrid);
    FineField Mn(FineGrid);
    for(int b=0;b<nn;b++){
      subspace[b] = Zero();
      gaussian(RNG,noise);
      scale = std::pow(norm2(noise),-0.5); 
      noise=noise*scale;
      hermop.Op(noise,Mn); std::cout<<GridLogMessage << "noise   ["<<b<<"] <n|MdagM|n> "<<norm2(Mn)<<std::endl;
      for(int i=0;i<1;i++){
 	CG(hermop,noise,subspace[b]);
 	noise = subspace[b];
 	scale = std::pow(norm2(noise),-0.5); 
 	noise=noise*scale;
      }
      hermop.Op(noise,Mn); std::cout<<GridLogMessage << "filtered["<<b<<"] <f|MdagM|f> "<<norm2(Mn)<<std::endl;
      subspace[b]   = noise;
    }
  }
  ////////////////////////////////////////////////////////////////////////////////////////////////
  // World of possibilities here. But have tried quite a lot of experiments (250+ jobs run on Summit)
  // and this is the best I found
  ////////////////////////////////////////////////////////////////////////////////////////////////
  virtual void CreateSubspaceChebyshev(GridParallelRNG  &RNG,LinearOperatorBase<FineField> &hermop,
 				       int nn,
 				       double hi,
 				       double lo,
 				       int orderfilter,
 				       int ordermin,
 				       int orderstep,
 				       double filterlo
 				       ) {
    RealD scale;
    FineField noise(FineGrid);
    FineField Mn(FineGrid);
    FineField tmp(FineGrid);
    // New normalised noise
    gaussian(RNG,noise);
    scale = std::pow(norm2(noise),-0.5); 
    noise=noise*scale;
    // Initial matrix element
    hermop.Op(noise,Mn); std::cout<<GridLogMessage << "noise <n|MdagM|n> "<<norm2(Mn)<<std::endl;
    int b =0;
    {
      // Filter
      Chebyshev<FineField> Cheb(lo,hi,orderfilter);
      Cheb(hermop,noise,Mn);
      // normalise
      scale = std::pow(norm2(Mn),-0.5); 	Mn=Mn*scale;
      subspace[b]   = Mn;
      hermop.Op(Mn,tmp); 
      std::cout<<GridLogMessage << "filt ["<<b<<"] <n|MdagM|n> "<<norm2(tmp)<<std::endl;
      b++;
    }
    // Generate a full sequence of Chebyshevs
    {
      lo=filterlo;
      noise=Mn;
      FineField T0(FineGrid); T0 = noise;  
      FineField T1(FineGrid); 
      FineField T2(FineGrid);
      FineField y(FineGrid);
      FineField *Tnm = &T0;
      FineField *Tn  = &T1;
      FineField *Tnp = &T2;
      // Tn=T1 = (xscale M + mscale)in
      RealD xscale = 2.0/(hi-lo);
      RealD mscale = -(hi+lo)/(hi-lo);
      hermop.HermOp(T0,y);
      T1=y*xscale+noise*mscale;
      for(int n=2;n<=ordermin+orderstep*(nn-2);n++){
 	hermop.HermOp(*Tn,y);
 	autoView( y_v , y, AcceleratorWrite);
 	autoView( Tn_v , (*Tn), AcceleratorWrite);
 	autoView( Tnp_v , (*Tnp), AcceleratorWrite);
 	autoView( Tnm_v , (*Tnm), AcceleratorWrite);
 	const int Nsimd = CComplex::Nsimd();
 	accelerator_for(ss, FineGrid->oSites(), Nsimd, {
 	  coalescedWrite(y_v[ss],xscale*y_v(ss)+mscale*Tn_v(ss));
 	  coalescedWrite(Tnp_v[ss],2.0*y_v(ss)-Tnm_v(ss));
        });
 	// Possible more fine grained control is needed than a linear sweep,
 	// but huge productivity gain if this is simple algorithm and not a tunable
 	int m =1;
 	if ( n>=ordermin ) m=n-ordermin;
 	if ( (m%orderstep)==0 ) { 
 	  Mn=*Tnp;
 	  scale = std::pow(norm2(Mn),-0.5);         Mn=Mn*scale;
 	  subspace[b] = Mn;
 	  hermop.Op(Mn,tmp); 
 	  std::cout<<GridLogMessage << n<<" filt ["<<b<<"] <n|MdagM|n> "<<norm2(tmp)<<std::endl;
 	  b++;
 	}
 	// Cycle pointers to avoid copies
 	FineField *swizzle = Tnm;
 	Tnm    =Tn;
 	Tn     =Tnp;
 	Tnp    =swizzle;
      }
    }
    assert(b==nn);
  }
 };
 // Fine Object == (per site) type of fine field
 // nbasis      == number of deflation vectors
 template<class Fobj,class CComplex,int nbasis>
--- a/Grid/algorithms/multigrid/GeneralCoarsenedMatrix.h
+++ b/Grid/algorithms/multigrid/GeneralCoarsenedMatrix.h
@@ -0,0 +1,619 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./lib/algorithms/GeneralCoarsenedMatrix.h
    Copyright (C) 2015
 Author: Peter Boyle <pboyle@bnl.gov>
    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 */
 #pragma once
 #include <Grid/qcd/QCD.h> // needed for Dagger(Yes|No), Inverse(Yes|No)
 #include <Grid/lattice/PaddedCell.h>
 #include <Grid/stencil/GeneralLocalStencil.h>
 NAMESPACE_BEGIN(Grid);
 // Fine Object == (per site) type of fine field
 // nbasis      == number of deflation vectors
 template<class Fobj,class CComplex,int nbasis>
 class GeneralCoarsenedMatrix : public SparseMatrixBase<Lattice<iVector<CComplex,nbasis > > >  {
 public:
  typedef GeneralCoarsenedMatrix<Fobj,CComplex,nbasis> GeneralCoarseOp;
  typedef iVector<CComplex,nbasis >           siteVector;
  typedef iMatrix<CComplex,nbasis >           siteMatrix;
  typedef Lattice<iScalar<CComplex> >         CoarseComplexField;
  typedef Lattice<siteVector>                 CoarseVector;
  typedef Lattice<iMatrix<CComplex,nbasis > > CoarseMatrix;
  typedef iMatrix<CComplex,nbasis >  Cobj;
  typedef iVector<CComplex,nbasis >  Cvec;
  typedef Lattice< CComplex >   CoarseScalar; // used for inner products on fine field
  typedef Lattice<Fobj >        FineField;
  typedef Lattice<CComplex >    FineComplexField;
  typedef CoarseVector Field;
  ////////////////////
  // Data members
  ////////////////////
  int hermitian;
  GridBase      *       _FineGrid; 
  GridCartesian *       _CoarseGrid; 
  NonLocalStencilGeometry &geom;
  PaddedCell Cell;
  GeneralLocalStencil Stencil;
  std::vector<CoarseMatrix> _A;
  std::vector<CoarseMatrix> _Adag;
  std::vector<CoarseVector> MultTemporaries;
  ///////////////////////
  // Interface
  ///////////////////////
  GridBase      * Grid(void)           { return _CoarseGrid; };   // this is all the linalg routines need to know
  GridBase      * FineGrid(void)       { return _FineGrid; };   // this is all the linalg routines need to know
  GridCartesian * CoarseGrid(void)     { return _CoarseGrid; };   // this is all the linalg routines need to know
  /*  void ShiftMatrix(RealD shift)
  {
    int Nd=_FineGrid->Nd(); 
    Coordinate zero_shift(Nd,0);
    for(int p=0;p<geom.npoint;p++){
      if ( zero_shift==geom.shifts[p] ) {
 	_A[p] = _A[p]+shift;
 	//	_Adag[p] = _Adag[p]+shift;
      }
    }    
  }
  void ProjectNearestNeighbour(RealD shift, GeneralCoarseOp &CopyMe)
  {
    int nfound=0;
    std::cout << GridLogMessage <<"GeneralCoarsenedMatrix::ProjectNearestNeighbour "<< CopyMe._A[0].Grid()<<std::endl;
    for(int p=0;p<geom.npoint;p++){
      for(int pp=0;pp<CopyMe.geom.npoint;pp++){
 	// Search for the same relative shift
 	// Avoids brutal handling of Grid pointers
 	if ( CopyMe.geom.shifts[pp]==geom.shifts[p] ) {
 	  _A[p] = CopyMe.Cell.Extract(CopyMe._A[pp]);
 	  //	  _Adag[p] = CopyMe.Cell.Extract(CopyMe._Adag[pp]);
 	  nfound++;
 	}
      }
    }
    assert(nfound==geom.npoint);
    ExchangeCoarseLinks();
  }
  */
  GeneralCoarsenedMatrix(NonLocalStencilGeometry &_geom,GridBase *FineGrid, GridCartesian * CoarseGrid)
    : geom(_geom),
      _FineGrid(FineGrid),
      _CoarseGrid(CoarseGrid),
      hermitian(1),
      Cell(_geom.Depth(),_CoarseGrid),
      Stencil(Cell.grids.back(),geom.shifts)
  {
    {
      int npoint = _geom.npoint;
    }
    _A.resize(geom.npoint,CoarseGrid);
    //    _Adag.resize(geom.npoint,CoarseGrid);
  }
  void M (const CoarseVector &in, CoarseVector &out)
  {
    Mult(_A,in,out);
  }
  void Mdag (const CoarseVector &in, CoarseVector &out)
  {
    assert(hermitian);
    Mult(_A,in,out);
    //    if ( hermitian ) M(in,out);
    //    else Mult(_Adag,in,out);
  }
  void Mult (std::vector<CoarseMatrix> &A,const CoarseVector &in, CoarseVector &out)
  {
    RealD tviews=0;    RealD ttot=0;    RealD tmult=0;   RealD texch=0;    RealD text=0; RealD ttemps=0; RealD tcopy=0;
    RealD tmult2=0;
    ttot=-usecond();
    conformable(CoarseGrid(),in.Grid());
    conformable(in.Grid(),out.Grid());
    out.Checkerboard() = in.Checkerboard();
    CoarseVector tin=in;
    texch-=usecond();
    CoarseVector pin = Cell.ExchangePeriodic(tin);
    texch+=usecond();
    CoarseVector pout(pin.Grid());
    int npoint = geom.npoint;
    typedef LatticeView<Cobj> Aview;
    typedef LatticeView<Cvec> Vview;
    const int Nsimd = CComplex::Nsimd();
    int64_t osites=pin.Grid()->oSites();
    RealD flops = 1.0* npoint * nbasis * nbasis * 8.0 * osites * CComplex::Nsimd();
    RealD bytes = 1.0*osites*sizeof(siteMatrix)*npoint
                + 2.0*osites*sizeof(siteVector)*npoint;
    {
      tviews-=usecond();
      autoView( in_v , pin, AcceleratorRead);
      autoView( out_v , pout, AcceleratorWriteDiscard);
      autoView( Stencil_v  , Stencil, AcceleratorRead);
      tviews+=usecond();
      // Static and prereserve to keep UVM region live and not resized across multiple calls
      ttemps-=usecond();
      MultTemporaries.resize(npoint,pin.Grid());       
      ttemps+=usecond();
      std::vector<Aview> AcceleratorViewContainer_h;
      std::vector<Vview> AcceleratorVecViewContainer_h; 
      tviews-=usecond();
      for(int p=0;p<npoint;p++) {
 	AcceleratorViewContainer_h.push_back(      A[p].View(AcceleratorRead));
 	AcceleratorVecViewContainer_h.push_back(MultTemporaries[p].View(AcceleratorWrite));
      }
      tviews+=usecond();
      static deviceVector<Aview> AcceleratorViewContainer; AcceleratorViewContainer.resize(npoint);
      static deviceVector<Vview> AcceleratorVecViewContainer; AcceleratorVecViewContainer.resize(npoint); 
      auto Aview_p = &AcceleratorViewContainer[0];
      auto Vview_p = &AcceleratorVecViewContainer[0];
      tcopy-=usecond();
      acceleratorCopyToDevice(&AcceleratorViewContainer_h[0],&AcceleratorViewContainer[0],npoint *sizeof(Aview));
      acceleratorCopyToDevice(&AcceleratorVecViewContainer_h[0],&AcceleratorVecViewContainer[0],npoint *sizeof(Vview));
      tcopy+=usecond();
      tmult-=usecond();
      accelerator_for(spb, osites*nbasis*npoint, Nsimd, {
 	  typedef decltype(coalescedRead(in_v[0](0))) calcComplex;
 	  int32_t ss   = spb/(nbasis*npoint);
 	  int32_t bp   = spb%(nbasis*npoint);
 	  int32_t point= bp/nbasis;
 	  int32_t b    = bp%nbasis;
 	  auto SE  = Stencil_v.GetEntry(point,ss);
 	  auto nbr = coalescedReadGeneralPermute(in_v[SE->_offset],SE->_permute,Nd);
 	  auto res = coalescedRead(Aview_p[point][ss](0,b))*nbr(0);
 	  for(int bb=1;bb<nbasis;bb++) {
 	    res = res + coalescedRead(Aview_p[point][ss](bb,b))*nbr(bb);
 	  }
 	  coalescedWrite(Vview_p[point][ss](b),res);
      });
      tmult2-=usecond();
      accelerator_for(sb, osites*nbasis, Nsimd, {
 	  int ss = sb/nbasis;
 	  int b  = sb%nbasis;
 	  auto res = coalescedRead(Vview_p[0][ss](b));
 	  for(int point=1;point<npoint;point++){
 	    res = res + coalescedRead(Vview_p[point][ss](b));
 	  }
 	  coalescedWrite(out_v[ss](b),res);
      });
      tmult2+=usecond();
      tmult+=usecond();
      for(int p=0;p<npoint;p++) {
 	AcceleratorViewContainer_h[p].ViewClose();
 	AcceleratorVecViewContainer_h[p].ViewClose();
      }
    }
    text-=usecond();
    out = Cell.Extract(pout);
    text+=usecond();
    ttot+=usecond();
    std::cout << GridLogPerformance<<"Coarse 1rhs Mult Aviews "<<tviews<<" us"<<std::endl;
    std::cout << GridLogPerformance<<"Coarse Mult exch "<<texch<<" us"<<std::endl;
    std::cout << GridLogPerformance<<"Coarse Mult mult "<<tmult<<" us"<<std::endl;
    std::cout << GridLogPerformance<<" of which mult2  "<<tmult2<<" us"<<std::endl;
    std::cout << GridLogPerformance<<"Coarse Mult ext  "<<text<<" us"<<std::endl;
    std::cout << GridLogPerformance<<"Coarse Mult temps "<<ttemps<<" us"<<std::endl;
    std::cout << GridLogPerformance<<"Coarse Mult copy  "<<tcopy<<" us"<<std::endl;
    std::cout << GridLogPerformance<<"Coarse Mult tot  "<<ttot<<" us"<<std::endl;
    //    std::cout << GridLogPerformance<<std::endl;
    std::cout << GridLogPerformance<<"Coarse Kernel flops "<< flops<<std::endl;
    std::cout << GridLogPerformance<<"Coarse Kernel flop/s "<< flops/tmult<<" mflop/s"<<std::endl;
    std::cout << GridLogPerformance<<"Coarse Kernel bytes/s "<< bytes/tmult<<" MB/s"<<std::endl;
    std::cout << GridLogPerformance<<"Coarse overall flops/s "<< flops/ttot<<" mflop/s"<<std::endl;
    std::cout << GridLogPerformance<<"Coarse total bytes   "<< bytes/1e6<<" MB"<<std::endl;
  };
  void PopulateAdag(void)
  {
    for(int64_t bidx=0;bidx<CoarseGrid()->gSites() ;bidx++){
      Coordinate bcoor;
      CoarseGrid()->GlobalIndexToGlobalCoor(bidx,bcoor);
      for(int p=0;p<geom.npoint;p++){
 	Coordinate scoor = bcoor;
 	for(int mu=0;mu<bcoor.size();mu++){
 	  int L = CoarseGrid()->GlobalDimensions()[mu];
 	  scoor[mu] = (bcoor[mu] - geom.shifts[p][mu] + L) % L; // Modulo arithmetic
 	}
 	// Flip to poke/peekLocalSite and not too bad
 	auto link = peekSite(_A[p],scoor);
 	int pp = geom.Reverse(p);
 	pokeSite(adj(link),_Adag[pp],bcoor);
      }
    }
  }
  /////////////////////////////////////////////////////////////
  // 
  // A) Only reduced flops option is to use a padded cell of depth 4
  // and apply MpcDagMpc in the padded cell.
  //
  // Makes for ONE application of MpcDagMpc per vector instead of 30 or 80.
  // With the effective cell size around (B+8)^4 perhaps 12^4/4^4 ratio
  // Cost is 81x more, same as stencil size.
  //
  // But: can eliminate comms and do as local dirichlet.
  //
  // Local exchange gauge field once.
  // Apply to all vectors, local only computation.
  // Must exchange ghost subcells in reverse process of PaddedCell to take inner products
  //
  // B) Can reduce cost: pad by 1, apply Deo      (4^4+6^4+8^4+8^4 )/ (4x 4^4)
  //                     pad by 2, apply Doe
  //                     pad by 3, apply Deo
  //                     then break out 8x directions; cost is ~10x MpcDagMpc per vector
  //
  // => almost factor of 10 in setup cost, excluding data rearrangement
  //
  // Intermediates -- ignore the corner terms, leave approximate and force Hermitian
  // Intermediates -- pad by 2 and apply 1+8+24 = 33 times.
  /////////////////////////////////////////////////////////////
    //////////////////////////////////////////////////////////
    // BFM HDCG style approach: Solve a system of equations to get Aij
    //////////////////////////////////////////////////////////
    /*
     *     Here, k,l index which possible shift within the 3^Nd "ball" connected by MdagM.
     *
     *     conj(phases[block]) proj[k][ block*Nvec+j ] =  \sum_ball  e^{i q_k . delta} < phi_{block,j} | MdagM | phi_{(block+delta),i} > 
     *                                                 =  \sum_ball e^{iqk.delta} A_ji
     *
     *     Must invert matrix M_k,l = e^[i q_k . delta_l]
     *
     *     Where q_k = delta_k . (2*M_PI/global_nb[mu])
     */
 #if 0
  void CoarsenOperator(LinearOperatorBase<Lattice<Fobj> > &linop,
 		       Aggregation<Fobj,CComplex,nbasis> & Subspace)
  {
    std::cout << GridLogMessage<< "GeneralCoarsenMatrix "<< std::endl;
    GridBase *grid = FineGrid();
    RealD tproj=0.0;
    RealD teigen=0.0;
    RealD tmat=0.0;
    RealD tphase=0.0;
    RealD tinv=0.0;
    /////////////////////////////////////////////////////////////
    // Orthogonalise the subblocks over the basis
    /////////////////////////////////////////////////////////////
    CoarseScalar InnerProd(CoarseGrid()); 
    blockOrthogonalise(InnerProd,Subspace.subspace);
    const int npoint = geom.npoint;
    Coordinate clatt = CoarseGrid()->GlobalDimensions();
    int Nd = CoarseGrid()->Nd();
      /*
       *     Here, k,l index which possible momentum/shift within the N-points connected by MdagM.
       *     Matrix index i is mapped to this shift via 
       *               geom.shifts[i]
       *
       *     conj(pha[block]) proj[k (which mom)][j (basis vec cpt)][block] 
       *       =  \sum_{l in ball}  e^{i q_k . delta_l} < phi_{block,j} | MdagM | phi_{(block+delta_l),i} > 
       *       =  \sum_{l in ball} e^{iqk.delta_l} A_ji^{b.b+l}
       *       = M_{kl} A_ji^{b.b+l}
       *
       *     Must assemble and invert matrix M_k,l = e^[i q_k . delta_l]
       *  
       *     Where q_k = delta_k . (2*M_PI/global_nb[mu])
       *
       *     Then A{ji}^{b,b+l} = M^{-1}_{lm} ComputeProj_{m,b,i,j}
       */
    teigen-=usecond();
    Eigen::MatrixXcd Mkl    = Eigen::MatrixXcd::Zero(npoint,npoint);
    Eigen::MatrixXcd invMkl = Eigen::MatrixXcd::Zero(npoint,npoint);
    ComplexD ci(0.0,1.0);
    for(int k=0;k<npoint;k++){ // Loop over momenta
      for(int l=0;l<npoint;l++){ // Loop over nbr relative
 	ComplexD phase(0.0,0.0);
 	for(int mu=0;mu<Nd;mu++){
 	  RealD TwoPiL =  M_PI * 2.0/ clatt[mu];
 	  phase=phase+TwoPiL*geom.shifts[k][mu]*geom.shifts[l][mu];
 	}
 	phase=exp(phase*ci);
 	Mkl(k,l) = phase;
      }
    }
    invMkl = Mkl.inverse();
    teigen+=usecond();
    ///////////////////////////////////////////////////////////////////////
    // Now compute the matrix elements of linop between the orthonormal
    // set of vectors.
    ///////////////////////////////////////////////////////////////////////
    FineField phaV(grid); // Phased block basis vector
    FineField MphaV(grid);// Matrix applied
    CoarseVector coarseInner(CoarseGrid());
    std::vector<CoarseVector> ComputeProj(npoint,CoarseGrid());
    std::vector<CoarseVector>          FT(npoint,CoarseGrid());
    for(int i=0;i<nbasis;i++){// Loop over basis vectors
      std::cout << GridLogMessage<< "CoarsenMatrixColoured vec "<<i<<"/"<<nbasis<< std::endl;
      for(int p=0;p<npoint;p++){ // Loop over momenta in npoint
 	/////////////////////////////////////////////////////
 	// Stick a phase on every block
 	/////////////////////////////////////////////////////
 	tphase-=usecond();
 	CoarseComplexField coor(CoarseGrid());
 	CoarseComplexField pha(CoarseGrid());	pha=Zero();
 	for(int mu=0;mu<Nd;mu++){
 	  LatticeCoordinate(coor,mu);
 	  RealD TwoPiL =  M_PI * 2.0/ clatt[mu];
 	  pha = pha + (TwoPiL * geom.shifts[p][mu]) * coor;
 	}
 	pha  =exp(pha*ci);
 	phaV=Zero();
 	blockZAXPY(phaV,pha,Subspace.subspace[i],phaV);
 	tphase+=usecond();
 	/////////////////////////////////////////////////////////////////////
 	// Multiple phased subspace vector by matrix and project to subspace
 	// Remove local bulk phase to leave relative phases
 	/////////////////////////////////////////////////////////////////////
 	tmat-=usecond();
 	linop.Op(phaV,MphaV);
 	tmat+=usecond();
 	tproj-=usecond();
 	blockProject(coarseInner,MphaV,Subspace.subspace);
 	coarseInner = conjugate(pha) * coarseInner;
 	ComputeProj[p] = coarseInner;
 	tproj+=usecond();
      }
      tinv-=usecond();
      for(int k=0;k<npoint;k++){
 	FT[k] = Zero();
 	for(int l=0;l<npoint;l++){
 	  FT[k]= FT[k]+ invMkl(l,k)*ComputeProj[l];
 	}
 	int osites=CoarseGrid()->oSites();
 	autoView( A_v  , _A[k], AcceleratorWrite);
 	autoView( FT_v  , FT[k], AcceleratorRead);
 	accelerator_for(sss, osites, 1, {
 	    for(int j=0;j<nbasis;j++){
 	      A_v[sss](i,j) = FT_v[sss](j);
 	    }
        });
      }
      tinv+=usecond();
    }
    // Only needed if nonhermitian
    if ( ! hermitian ) {
      //      std::cout << GridLogMessage<<"PopulateAdag  "<<std::endl;
      //      PopulateAdag();
    }
    // Need to write something to populate Adag from A
    ExchangeCoarseLinks();
    std::cout << GridLogMessage<<"CoarsenOperator eigen  "<<teigen<<" us"<<std::endl;
    std::cout << GridLogMessage<<"CoarsenOperator phase  "<<tphase<<" us"<<std::endl;
    std::cout << GridLogMessage<<"CoarsenOperator mat    "<<tmat <<" us"<<std::endl;
    std::cout << GridLogMessage<<"CoarsenOperator proj   "<<tproj<<" us"<<std::endl;
    std::cout << GridLogMessage<<"CoarsenOperator inv    "<<tinv<<" us"<<std::endl;
  }
 #else
  void CoarsenOperator(LinearOperatorBase<Lattice<Fobj> > &linop,
 		       Aggregation<Fobj,CComplex,nbasis> & Subspace)
  {
    std::cout << GridLogMessage<< "GeneralCoarsenMatrix "<< std::endl;
    GridBase *grid = FineGrid();
    RealD tproj=0.0;
    RealD teigen=0.0;
    RealD tmat=0.0;
    RealD tphase=0.0;
    RealD tphaseBZ=0.0;
    RealD tinv=0.0;
    /////////////////////////////////////////////////////////////
    // Orthogonalise the subblocks over the basis
    /////////////////////////////////////////////////////////////
    CoarseScalar InnerProd(CoarseGrid()); 
    blockOrthogonalise(InnerProd,Subspace.subspace);
    //    for(int s=0;s<Subspace.subspace.size();s++){
      //      std::cout << " subspace norm "<<norm2(Subspace.subspace[s])<<std::endl;
    //    }
    const int npoint = geom.npoint;
    Coordinate clatt = CoarseGrid()->GlobalDimensions();
    int Nd = CoarseGrid()->Nd();
      /*
       *     Here, k,l index which possible momentum/shift within the N-points connected by MdagM.
       *     Matrix index i is mapped to this shift via 
       *               geom.shifts[i]
       *
       *     conj(pha[block]) proj[k (which mom)][j (basis vec cpt)][block] 
       *       =  \sum_{l in ball}  e^{i q_k . delta_l} < phi_{block,j} | MdagM | phi_{(block+delta_l),i} > 
       *       =  \sum_{l in ball} e^{iqk.delta_l} A_ji^{b.b+l}
       *       = M_{kl} A_ji^{b.b+l}
       *
       *     Must assemble and invert matrix M_k,l = e^[i q_k . delta_l]
       *  
       *     Where q_k = delta_k . (2*M_PI/global_nb[mu])
       *
       *     Then A{ji}^{b,b+l} = M^{-1}_{lm} ComputeProj_{m,b,i,j}
       */
    teigen-=usecond();
    Eigen::MatrixXcd Mkl    = Eigen::MatrixXcd::Zero(npoint,npoint);
    Eigen::MatrixXcd invMkl = Eigen::MatrixXcd::Zero(npoint,npoint);
    ComplexD ci(0.0,1.0);
    for(int k=0;k<npoint;k++){ // Loop over momenta
      for(int l=0;l<npoint;l++){ // Loop over nbr relative
 	ComplexD phase(0.0,0.0);
 	for(int mu=0;mu<Nd;mu++){
 	  RealD TwoPiL =  M_PI * 2.0/ clatt[mu];
 	  phase=phase+TwoPiL*geom.shifts[k][mu]*geom.shifts[l][mu];
 	}
 	phase=exp(phase*ci);
 	Mkl(k,l) = phase;
      }
    }
    invMkl = Mkl.inverse();
    teigen+=usecond();
    ///////////////////////////////////////////////////////////////////////
    // Now compute the matrix elements of linop between the orthonormal
    // set of vectors.
    ///////////////////////////////////////////////////////////////////////
    FineField phaV(grid); // Phased block basis vector
    FineField MphaV(grid);// Matrix applied
    std::vector<FineComplexField> phaF(npoint,grid);
    std::vector<CoarseComplexField> pha(npoint,CoarseGrid());
    CoarseVector coarseInner(CoarseGrid());
    typedef typename CComplex::scalar_type SComplex;
    FineComplexField one(grid); one=SComplex(1.0);
    FineComplexField zz(grid); zz = Zero();
    tphase=-usecond();
    for(int p=0;p<npoint;p++){ // Loop over momenta in npoint
      /////////////////////////////////////////////////////
      // Stick a phase on every block
      /////////////////////////////////////////////////////
      CoarseComplexField coor(CoarseGrid());
      pha[p]=Zero();
      for(int mu=0;mu<Nd;mu++){
 	LatticeCoordinate(coor,mu);
 	RealD TwoPiL =  M_PI * 2.0/ clatt[mu];
 	pha[p] = pha[p] + (TwoPiL * geom.shifts[p][mu]) * coor;
      }
      pha[p]  =exp(pha[p]*ci);
      blockZAXPY(phaF[p],pha[p],one,zz);
    }
    tphase+=usecond();
    std::vector<CoarseVector> ComputeProj(npoint,CoarseGrid());
    std::vector<CoarseVector>          FT(npoint,CoarseGrid());
    for(int i=0;i<nbasis;i++){// Loop over basis vectors
      std::cout << GridLogMessage<< "CoarsenMatrixColoured vec "<<i<<"/"<<nbasis<< std::endl;
      for(int p=0;p<npoint;p++){ // Loop over momenta in npoint
 	tphaseBZ-=usecond();
 	phaV = phaF[p]*Subspace.subspace[i];
 	tphaseBZ+=usecond();
 	/////////////////////////////////////////////////////////////////////
 	// Multiple phased subspace vector by matrix and project to subspace
 	// Remove local bulk phase to leave relative phases
 	/////////////////////////////////////////////////////////////////////
 	tmat-=usecond();
 	linop.Op(phaV,MphaV);
 	tmat+=usecond();
 	//	std::cout << i << " " <<p << " MphaV "<<norm2(MphaV)<<" "<<norm2(phaV)<<std::endl;
 	tproj-=usecond();
 	blockProject(coarseInner,MphaV,Subspace.subspace);
 	coarseInner = conjugate(pha[p]) * coarseInner;
 	ComputeProj[p] = coarseInner;
 	tproj+=usecond();
 	//	std::cout << i << " " <<p << " ComputeProj "<<norm2(ComputeProj[p])<<std::endl;
      }
      tinv-=usecond();
      for(int k=0;k<npoint;k++){
 	FT[k] = Zero();
 	for(int l=0;l<npoint;l++){
 	  FT[k]= FT[k]+ invMkl(l,k)*ComputeProj[l];
 	}
 	int osites=CoarseGrid()->oSites();
 	autoView( A_v  , _A[k], AcceleratorWrite);
 	autoView( FT_v  , FT[k], AcceleratorRead);
 	accelerator_for(sss, osites, 1, {
 	    for(int j=0;j<nbasis;j++){
 	      A_v[sss](i,j) = FT_v[sss](j);
 	    }
        });
      }
      tinv+=usecond();
    }
    // Only needed if nonhermitian
    if ( ! hermitian ) {
      //      std::cout << GridLogMessage<<"PopulateAdag  "<<std::endl;
      //      PopulateAdag();
    }
    for(int p=0;p<geom.npoint;p++){
      std::cout << " _A["<<p<<"] "<<norm2(_A[p])<<std::endl;
    }
    // Need to write something to populate Adag from A
    ExchangeCoarseLinks();
    std::cout << GridLogMessage<<"CoarsenOperator eigen  "<<teigen<<" us"<<std::endl;
    std::cout << GridLogMessage<<"CoarsenOperator phase  "<<tphase<<" us"<<std::endl;
    std::cout << GridLogMessage<<"CoarsenOperator phaseBZ "<<tphaseBZ<<" us"<<std::endl;
    std::cout << GridLogMessage<<"CoarsenOperator mat    "<<tmat <<" us"<<std::endl;
    std::cout << GridLogMessage<<"CoarsenOperator proj   "<<tproj<<" us"<<std::endl;
    std::cout << GridLogMessage<<"CoarsenOperator inv    "<<tinv<<" us"<<std::endl;
  }
 #endif  
  void ExchangeCoarseLinks(void){
    for(int p=0;p<geom.npoint;p++){
      _A[p] = Cell.ExchangePeriodic(_A[p]);
      //      _Adag[p]= Cell.ExchangePeriodic(_Adag[p]);
    }
  }
  virtual  void Mdiag    (const Field &in, Field &out){ assert(0);};
  virtual  void Mdir     (const Field &in, Field &out,int dir, int disp){assert(0);};
  virtual  void MdirAll  (const Field &in, std::vector<Field> &out){assert(0);};
 };
 NAMESPACE_END(Grid);
--- a/Grid/algorithms/multigrid/GeneralCoarsenedMatrixMultiRHS.h
+++ b/Grid/algorithms/multigrid/GeneralCoarsenedMatrixMultiRHS.h
@@ -0,0 +1,729 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./lib/algorithms/GeneralCoarsenedMatrixMultiRHS.h
    Copyright (C) 2015
 Author: Peter Boyle <pboyle@bnl.gov>
    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 */
 #pragma once
 NAMESPACE_BEGIN(Grid);
 // Fine Object == (per site) type of fine field
 // nbasis      == number of deflation vectors
 template<class Fobj,class CComplex,int nbasis>
 class MultiGeneralCoarsenedMatrix : public SparseMatrixBase<Lattice<iVector<CComplex,nbasis > > >  {
 public:
  typedef typename CComplex::scalar_object SComplex;
  typedef GeneralCoarsenedMatrix<Fobj,CComplex,nbasis> GeneralCoarseOp;
  typedef MultiGeneralCoarsenedMatrix<Fobj,CComplex,nbasis> MultiGeneralCoarseOp;
  typedef iVector<CComplex,nbasis >           siteVector;
  typedef iMatrix<CComplex,nbasis >           siteMatrix;
  typedef iVector<SComplex,nbasis >           calcVector;
  typedef iMatrix<SComplex,nbasis >           calcMatrix;
  typedef Lattice<iScalar<CComplex> >         CoarseComplexField;
  typedef Lattice<siteVector>                 CoarseVector;
  typedef Lattice<iMatrix<CComplex,nbasis > > CoarseMatrix;
  typedef iMatrix<CComplex,nbasis >  Cobj;
  typedef iVector<CComplex,nbasis >  Cvec;
  typedef Lattice< CComplex >   CoarseScalar; // used for inner products on fine field
  typedef Lattice<Fobj >        FineField;
  typedef Lattice<CComplex >    FineComplexField;
  typedef CoarseVector Field;
  ////////////////////
  // Data members
  ////////////////////
  GridCartesian *       _CoarseGridMulti; 
  NonLocalStencilGeometry geom;
  NonLocalStencilGeometry geom_srhs;
  PaddedCell Cell;
  GeneralLocalStencil Stencil;
  deviceVector<calcVector> BLAS_B;
  deviceVector<calcVector> BLAS_C;
  std::vector<deviceVector<calcMatrix> > BLAS_A;
  std::vector<deviceVector<ComplexD *> > BLAS_AP;
  std::vector<deviceVector<ComplexD *> > BLAS_BP;
  deviceVector<ComplexD *>               BLAS_CP;
  ///////////////////////
  // Interface
  ///////////////////////
  GridBase      * Grid(void)           { return _CoarseGridMulti; };   // this is all the linalg routines need to know
  GridCartesian * CoarseGrid(void)     { return _CoarseGridMulti; };   // this is all the linalg routines need to know
  // Can be used to do I/O on the operator matrices externally
  void SetMatrix (int p,CoarseMatrix & A)
  {
    assert(A.size()==geom_srhs.npoint);
    GridtoBLAS(A[p],BLAS_A[p]);
  }
  void GetMatrix (int p,CoarseMatrix & A)
  {
    assert(A.size()==geom_srhs.npoint);
    BLAStoGrid(A[p],BLAS_A[p]);
  }
  void CopyMatrix (GeneralCoarseOp &_Op)
  {
    for(int p=0;p<geom.npoint;p++){
      auto Aup = _Op.Cell.Extract(_Op._A[p]);
      //Unpadded
      GridtoBLAS(Aup,BLAS_A[p]);
    }
  }
  /*
  void CheckMatrix (GeneralCoarseOp &_Op)
  {
    std::cout <<"************* Checking the little direc operator mRHS"<<std::endl;
    for(int p=0;p<geom.npoint;p++){
      //Unpadded
      auto Aup = _Op.Cell.Extract(_Op._A[p]);
      auto Ack = Aup;
      BLAStoGrid(Ack,BLAS_A[p]);
      std::cout << p<<" Ack "<<norm2(Ack)<<std::endl;
      std::cout << p<<" Aup "<<norm2(Aup)<<std::endl;
    }
    std::cout <<"************* "<<std::endl;
  }
  */
  MultiGeneralCoarsenedMatrix(NonLocalStencilGeometry &_geom,GridCartesian *CoarseGridMulti) :
    _CoarseGridMulti(CoarseGridMulti),
    geom_srhs(_geom),
    geom(_CoarseGridMulti,_geom.hops,_geom.skip+1),
    Cell(geom.Depth(),_CoarseGridMulti),
    Stencil(Cell.grids.back(),geom.shifts) // padded cell stencil
  {
    int32_t padded_sites   = Cell.grids.back()->lSites();
    int32_t unpadded_sites = CoarseGridMulti->lSites();
    int32_t nrhs  = CoarseGridMulti->FullDimensions()[0];  // # RHS
    int32_t orhs  = nrhs/CComplex::Nsimd();
    padded_sites   = padded_sites/nrhs;
    unpadded_sites = unpadded_sites/nrhs;
    /////////////////////////////////////////////////
    // Device data vector storage
    /////////////////////////////////////////////////
    BLAS_A.resize(geom.npoint);
    for(int p=0;p<geom.npoint;p++){
      BLAS_A[p].resize (unpadded_sites); // no ghost zone, npoint elements
    }
    BLAS_B.resize(nrhs *padded_sites);   // includes ghost zone
    BLAS_C.resize(nrhs *unpadded_sites); // no ghost zone
    BLAS_AP.resize(geom.npoint);
    BLAS_BP.resize(geom.npoint);
    for(int p=0;p<geom.npoint;p++){
      BLAS_AP[p].resize(unpadded_sites);
      BLAS_BP[p].resize(unpadded_sites);
    }
    BLAS_CP.resize(unpadded_sites);
    /////////////////////////////////////////////////
    // Pointers to data
    /////////////////////////////////////////////////
    // Site identity mapping for A
    for(int p=0;p<geom.npoint;p++){
      for(int ss=0;ss<unpadded_sites;ss++){
 	ComplexD *ptr = (ComplexD *)&BLAS_A[p][ss];
 	acceleratorPut(BLAS_AP[p][ss],ptr);
      }
    }
    // Site identity mapping for C
    for(int ss=0;ss<unpadded_sites;ss++){
      ComplexD *ptr = (ComplexD *)&BLAS_C[ss*nrhs];
      acceleratorPut(BLAS_CP[ss],ptr);
    }
    // Neighbour table is more complicated
    int32_t j=0; // Interior point counter (unpadded)
    for(int32_t s=0;s<padded_sites;s++){ // 4 volume, padded
      int ghost_zone=0;
      for(int32_t point = 0 ; point < geom.npoint; point++){
 	int i=s*orhs*geom.npoint+point;
 	if( Stencil._entries[i]._wrap ) { // stencil is indexed by the oSite of the CoarseGridMulti, hence orhs factor
 	  ghost_zone=1; // If general stencil wrapped in any direction, wrap=1
 	}
      }
      if( ghost_zone==0) {
 	for(int32_t point = 0 ; point < geom.npoint; point++){
 	  int i=s*orhs*geom.npoint+point;
 	  int32_t nbr = Stencil._entries[i]._offset*CComplex::Nsimd(); // oSite -> lSite
 	  assert(nbr<BLAS_B.size());
 	  ComplexD * ptr = (ComplexD *)&BLAS_B[nbr];
 	  acceleratorPut(BLAS_BP[point][j],ptr); // neighbour indexing in ghost zone volume
 	}
 	j++;
      }
    }
    assert(j==unpadded_sites);
  }
  template<class vobj> void GridtoBLAS(const Lattice<vobj> &from,deviceVector<typename vobj::scalar_object> &to)
  {
  typedef typename vobj::scalar_object sobj;
  typedef typename vobj::scalar_type scalar_type;
  typedef typename vobj::vector_type vector_type;
  GridBase *Fg = from.Grid();
  assert(!Fg->_isCheckerBoarded);
  int nd = Fg->_ndimension;
  to.resize(Fg->lSites());
  Coordinate LocalLatt = Fg->LocalDimensions();
  size_t nsite = 1;
  for(int i=0;i<nd;i++) nsite *= LocalLatt[i];
  ////////////////////////////////////////////////////////////////////////////////////////////////
  // do the index calc on the GPU
  ////////////////////////////////////////////////////////////////////////////////////////////////
  Coordinate f_ostride = Fg->_ostride;
  Coordinate f_istride = Fg->_istride;
  Coordinate f_rdimensions = Fg->_rdimensions;
  autoView(from_v,from,AcceleratorRead);
  auto to_v = &to[0];
  const int words=sizeof(vobj)/sizeof(vector_type);
  accelerator_for(idx,nsite,1,{
      Coordinate from_coor, base;
      Lexicographic::CoorFromIndex(base,idx,LocalLatt);
      for(int i=0;i<nd;i++){
 	from_coor[i] = base[i];
      }
      int from_oidx = 0; for(int d=0;d<nd;d++) from_oidx+=f_ostride[d]*(from_coor[d]%f_rdimensions[d]);
      int from_lane = 0; for(int d=0;d<nd;d++) from_lane+=f_istride[d]*(from_coor[d]/f_rdimensions[d]);
      const vector_type* from = (const vector_type *)&from_v[from_oidx];
      scalar_type* to = (scalar_type *)&to_v[idx];
      scalar_type stmp;
      for(int w=0;w<words;w++){
 	stmp = getlane(from[w], from_lane);
 	to[w] = stmp;
      }
    });
  }    
  template<class vobj> void BLAStoGrid(Lattice<vobj> &grid,deviceVector<typename vobj::scalar_object> &in)
  {
  typedef typename vobj::scalar_object sobj;
  typedef typename vobj::scalar_type scalar_type;
  typedef typename vobj::vector_type vector_type;
  GridBase *Tg = grid.Grid();
  assert(!Tg->_isCheckerBoarded);
  int nd = Tg->_ndimension;
  assert(in.size()==Tg->lSites());
  Coordinate LocalLatt = Tg->LocalDimensions();
  size_t nsite = 1;
  for(int i=0;i<nd;i++) nsite *= LocalLatt[i];
  ////////////////////////////////////////////////////////////////////////////////////////////////
  // do the index calc on the GPU
  ////////////////////////////////////////////////////////////////////////////////////////////////
  Coordinate t_ostride = Tg->_ostride;
  Coordinate t_istride = Tg->_istride;
  Coordinate t_rdimensions = Tg->_rdimensions;
  autoView(to_v,grid,AcceleratorWrite);
  auto from_v = &in[0];
  const int words=sizeof(vobj)/sizeof(vector_type);
  accelerator_for(idx,nsite,1,{
      Coordinate to_coor, base;
      Lexicographic::CoorFromIndex(base,idx,LocalLatt);
      for(int i=0;i<nd;i++){
 	to_coor[i] = base[i];
      }
      int to_oidx = 0; for(int d=0;d<nd;d++) to_oidx+=t_ostride[d]*(to_coor[d]%t_rdimensions[d]);
      int to_lane = 0; for(int d=0;d<nd;d++) to_lane+=t_istride[d]*(to_coor[d]/t_rdimensions[d]);
      vector_type* to = (vector_type *)&to_v[to_oidx];
      scalar_type* from = (scalar_type *)&from_v[idx];
      scalar_type stmp;
      for(int w=0;w<words;w++){
 	stmp=from[w];
 	putlane(to[w], stmp, to_lane);
      }
    });
  }
  void CoarsenOperator(LinearOperatorBase<Lattice<Fobj> > &linop,
 		       Aggregation<Fobj,CComplex,nbasis> & Subspace,
 		       GridBase *CoarseGrid)
  {
 #if 0
    std::cout << GridLogMessage<< "GeneralCoarsenMatrixMrhs "<< std::endl;
    GridBase *grid = Subspace.FineGrid;
    /////////////////////////////////////////////////////////////
    // Orthogonalise the subblocks over the basis
    /////////////////////////////////////////////////////////////
    CoarseScalar InnerProd(CoarseGrid); 
    blockOrthogonalise(InnerProd,Subspace.subspace);
    const int npoint = geom_srhs.npoint;
    Coordinate clatt = CoarseGrid->GlobalDimensions();
    int Nd = CoarseGrid->Nd();
      /*
       *     Here, k,l index which possible momentum/shift within the N-points connected by MdagM.
       *     Matrix index i is mapped to this shift via 
       *               geom.shifts[i]
       *
       *     conj(pha[block]) proj[k (which mom)][j (basis vec cpt)][block] 
       *       =  \sum_{l in ball}  e^{i q_k . delta_l} < phi_{block,j} | MdagM | phi_{(block+delta_l),i} > 
       *       =  \sum_{l in ball} e^{iqk.delta_l} A_ji^{b.b+l}
       *       = M_{kl} A_ji^{b.b+l}
       *
       *     Must assemble and invert matrix M_k,l = e^[i q_k . delta_l]
       *  
       *     Where q_k = delta_k . (2*M_PI/global_nb[mu])
       *
       *     Then A{ji}^{b,b+l} = M^{-1}_{lm} ComputeProj_{m,b,i,j}
       */
    Eigen::MatrixXcd Mkl    = Eigen::MatrixXcd::Zero(npoint,npoint);
    Eigen::MatrixXcd invMkl = Eigen::MatrixXcd::Zero(npoint,npoint);
    ComplexD ci(0.0,1.0);
    for(int k=0;k<npoint;k++){ // Loop over momenta
      for(int l=0;l<npoint;l++){ // Loop over nbr relative
 	ComplexD phase(0.0,0.0);
 	for(int mu=0;mu<Nd;mu++){
 	  RealD TwoPiL =  M_PI * 2.0/ clatt[mu];
 	  phase=phase+TwoPiL*geom_srhs.shifts[k][mu]*geom_srhs.shifts[l][mu];
 	}
 	phase=exp(phase*ci);
 	Mkl(k,l) = phase;
      }
    }
    invMkl = Mkl.inverse();
    ///////////////////////////////////////////////////////////////////////
    // Now compute the matrix elements of linop between the orthonormal
    // set of vectors.
    ///////////////////////////////////////////////////////////////////////
    FineField phaV(grid); // Phased block basis vector
    FineField MphaV(grid);// Matrix applied
    std::vector<FineComplexField> phaF(npoint,grid);
    std::vector<CoarseComplexField> pha(npoint,CoarseGrid);
    CoarseVector coarseInner(CoarseGrid);
    typedef typename CComplex::scalar_type SComplex;
    FineComplexField one(grid); one=SComplex(1.0);
    FineComplexField zz(grid); zz = Zero();
    for(int p=0;p<npoint;p++){ // Loop over momenta in npoint
      /////////////////////////////////////////////////////
      // Stick a phase on every block
      /////////////////////////////////////////////////////
      CoarseComplexField coor(CoarseGrid);
      pha[p]=Zero();
      for(int mu=0;mu<Nd;mu++){
 	LatticeCoordinate(coor,mu);
 	RealD TwoPiL =  M_PI * 2.0/ clatt[mu];
 	pha[p] = pha[p] + (TwoPiL * geom_srhs.shifts[p][mu]) * coor;
      }
      pha[p]  =exp(pha[p]*ci);	
      blockZAXPY(phaF[p],pha[p],one,zz);
    }
    // Could save on temporary storage here
    std::vector<CoarseMatrix> _A;
    _A.resize(geom_srhs.npoint,CoarseGrid);
    std::vector<CoarseVector> ComputeProj(npoint,CoarseGrid);
    CoarseVector          FT(CoarseGrid);
    for(int i=0;i<nbasis;i++){// Loop over basis vectors
      std::cout << GridLogMessage<< "CoarsenMatrixColoured vec "<<i<<"/"<<nbasis<< std::endl;
      for(int p=0;p<npoint;p++){ // Loop over momenta in npoint
 	phaV = phaF[p]*Subspace.subspace[i];
 	/////////////////////////////////////////////////////////////////////
 	// Multiple phased subspace vector by matrix and project to subspace
 	// Remove local bulk phase to leave relative phases
 	/////////////////////////////////////////////////////////////////////
 	linop.Op(phaV,MphaV);
 	// Fixme, could use batched block projector here
 	blockProject(coarseInner,MphaV,Subspace.subspace);
 	coarseInner = conjugate(pha[p]) * coarseInner;
 	ComputeProj[p] = coarseInner;
      }
      // Could do this with a block promote or similar BLAS call via the MultiRHSBlockProjector with a const matrix.
      for(int k=0;k<npoint;k++){
 	FT = Zero();
 	for(int l=0;l<npoint;l++){
 	  FT= FT+ invMkl(l,k)*ComputeProj[l];
 	}
 	int osites=CoarseGrid->oSites();
 	autoView( A_v  , _A[k], AcceleratorWrite);
 	autoView( FT_v  , FT, AcceleratorRead);
 	accelerator_for(sss, osites, 1, {
 	    for(int j=0;j<nbasis;j++){
 	      A_v[sss](i,j) = FT_v[sss](j);
 	    }
        });
      }
    }
    // Only needed if nonhermitian
    //    if ( ! hermitian ) {
    //      std::cout << GridLogMessage<<"PopulateAdag  "<<std::endl;
    //      PopulateAdag();
    //    }
    // Need to write something to populate Adag from A
    for(int p=0;p<geom_srhs.npoint;p++){
      GridtoBLAS(_A[p],BLAS_A[p]);
    }
    /*
 Grid : Message : 11698.730546 s : CoarsenOperator eigen  1334 us
 Grid : Message : 11698.730563 s : CoarsenOperator phase  34729 us
 Grid : Message : 11698.730565 s : CoarsenOperator phaseBZ 2423814 us
 Grid : Message : 11698.730566 s : CoarsenOperator mat    127890998 us
 Grid : Message : 11698.730567 s : CoarsenOperator proj   515840840 us
 Grid : Message : 11698.730568 s : CoarsenOperator inv    103948313 us
 Takes 600s to compute matrix elements, DOMINATED by the block project.
 Easy to speed up with the batched block project.
 Store npoint vectors, get npoint x Nbasis block projection, and 81 fold faster.
 // Block project below taks to 240s
 Grid : Message : 328.193418 s : CoarsenOperator phase      38338 us
 Grid : Message : 328.193434 s : CoarsenOperator phaseBZ  1711226 us
 Grid : Message : 328.193436 s : CoarsenOperator mat    122213270 us
 //Grid : Message : 328.193438 s : CoarsenOperator proj   1181154 us <-- this is mistimed
 //Grid : Message : 11698.730568 s : CoarsenOperator inv  103948313 us <-- Cut this ~10x if lucky by loop fusion
     */
 #else
    RealD tproj=0.0;
    RealD tmat=0.0;
    RealD tphase=0.0;
    RealD tphaseBZ=0.0;
    RealD tinv=0.0;
    std::cout << GridLogMessage<< "GeneralCoarsenMatrixMrhs "<< std::endl;
    GridBase *grid = Subspace.FineGrid;
    /////////////////////////////////////////////////////////////
    // Orthogonalise the subblocks over the basis
    /////////////////////////////////////////////////////////////
    CoarseScalar InnerProd(CoarseGrid); 
    blockOrthogonalise(InnerProd,Subspace.subspace);
    MultiRHSBlockProject<Lattice<Fobj> >    Projector;
    Projector.Allocate(nbasis,grid,CoarseGrid);
    Projector.ImportBasis(Subspace.subspace);
    const int npoint = geom_srhs.npoint;
    Coordinate clatt = CoarseGrid->GlobalDimensions();
    int Nd = CoarseGrid->Nd();
      /*
       *     Here, k,l index which possible momentum/shift within the N-points connected by MdagM.
       *     Matrix index i is mapped to this shift via 
       *               geom.shifts[i]
       *
       *     conj(pha[block]) proj[k (which mom)][j (basis vec cpt)][block] 
       *       =  \sum_{l in ball}  e^{i q_k . delta_l} < phi_{block,j} | MdagM | phi_{(block+delta_l),i} > 
       *       =  \sum_{l in ball} e^{iqk.delta_l} A_ji^{b.b+l}
       *       = M_{kl} A_ji^{b.b+l}
       *
       *     Must assemble and invert matrix M_k,l = e^[i q_k . delta_l]
       *  
       *     Where q_k = delta_k . (2*M_PI/global_nb[mu])
       *
       *     Then A{ji}^{b,b+l} = M^{-1}_{lm} ComputeProj_{m,b,i,j}
       */
    Eigen::MatrixXcd Mkl    = Eigen::MatrixXcd::Zero(npoint,npoint);
    Eigen::MatrixXcd invMkl = Eigen::MatrixXcd::Zero(npoint,npoint);
    ComplexD ci(0.0,1.0);
    for(int k=0;k<npoint;k++){ // Loop over momenta
      for(int l=0;l<npoint;l++){ // Loop over nbr relative
 	ComplexD phase(0.0,0.0);
 	for(int mu=0;mu<Nd;mu++){
 	  RealD TwoPiL =  M_PI * 2.0/ clatt[mu];
 	  phase=phase+TwoPiL*geom_srhs.shifts[k][mu]*geom_srhs.shifts[l][mu];
 	}
 	phase=exp(phase*ci);
 	Mkl(k,l) = phase;
      }
    }
    invMkl = Mkl.inverse();
    ///////////////////////////////////////////////////////////////////////
    // Now compute the matrix elements of linop between the orthonormal
    // set of vectors.
    ///////////////////////////////////////////////////////////////////////
    FineField phaV(grid); // Phased block basis vector
    FineField MphaV(grid);// Matrix applied
    std::vector<FineComplexField> phaF(npoint,grid);
    std::vector<CoarseComplexField> pha(npoint,CoarseGrid);
    CoarseVector coarseInner(CoarseGrid);
    tphase=-usecond();
    typedef typename CComplex::scalar_type SComplex;
    FineComplexField one(grid); one=SComplex(1.0);
    FineComplexField zz(grid); zz = Zero();
    for(int p=0;p<npoint;p++){ // Loop over momenta in npoint
      /////////////////////////////////////////////////////
      // Stick a phase on every block
      /////////////////////////////////////////////////////
      CoarseComplexField coor(CoarseGrid);
      pha[p]=Zero();
      for(int mu=0;mu<Nd;mu++){
 	LatticeCoordinate(coor,mu);
 	RealD TwoPiL =  M_PI * 2.0/ clatt[mu];
 	pha[p] = pha[p] + (TwoPiL * geom_srhs.shifts[p][mu]) * coor;
      }
      pha[p]  =exp(pha[p]*ci);	
      blockZAXPY(phaF[p],pha[p],one,zz);
    }
    tphase+=usecond();
    // Could save on temporary storage here
    std::vector<CoarseMatrix> _A;
    _A.resize(geom_srhs.npoint,CoarseGrid);
    // Count use small chunks than npoint == 81 and save memory
    int batch = 9;
    std::vector<FineField>    _MphaV(batch,grid);
    std::vector<CoarseVector> TmpProj(batch,CoarseGrid);
    std::vector<CoarseVector> ComputeProj(npoint,CoarseGrid);
    CoarseVector          FT(CoarseGrid);
    for(int i=0;i<nbasis;i++){// Loop over basis vectors
      std::cout << GridLogMessage<< "CoarsenMatrixColoured vec "<<i<<"/"<<nbasis<< std::endl;
      //      std::cout << GridLogMessage << " phasing the fine vector "<<std::endl;
      // Fixme : do this in batches
      for(int p=0;p<npoint;p+=batch){ // Loop over momenta in npoint
 	for(int b=0;b<MIN(batch,npoint-p);b++){
 	  tphaseBZ-=usecond();
 	  phaV = phaF[p+b]*Subspace.subspace[i];
 	  tphaseBZ+=usecond();
 	  /////////////////////////////////////////////////////////////////////
 	  // Multiple phased subspace vector by matrix and project to subspace
 	  // Remove local bulk phase to leave relative phases
 	  /////////////////////////////////////////////////////////////////////
 	  // Memory footprint was an issue
 	  tmat-=usecond();
 	  linop.Op(phaV,MphaV);
 	  _MphaV[b] = MphaV;
 	  tmat+=usecond();
 	}      
 	//	std::cout << GridLogMessage << " Calling block project "<<std::endl;
 	tproj-=usecond();
 	Projector.blockProject(_MphaV,TmpProj);
 	tproj+=usecond();
 	//	std::cout << GridLogMessage << " conj phasing the coarse vectors "<<std::endl;
 	for(int b=0;b<MIN(batch,npoint-p);b++){
 	  ComputeProj[p+b] = conjugate(pha[p+b])*TmpProj[b];
 	}
      }
      // Could do this with a block promote or similar BLAS call via the MultiRHSBlockProjector with a const matrix.
      // std::cout << GridLogMessage << " Starting FT inv "<<std::endl;
      tinv-=usecond();
      for(int k=0;k<npoint;k++){
 	FT = Zero();
 	// 81 kernel calls as many ComputeProj vectors
 	// Could fuse with a vector of views, but ugly
 	// Could unroll the expression and run fewer kernels -- much more attractive
 	// Could also do non blocking.
 #if 0	
 	for(int l=0;l<npoint;l++){
 	  FT= FT+ invMkl(l,k)*ComputeProj[l];
 	}
 #else
 	const int radix = 9;
 	int ll;
 	for(ll=0;ll+radix-1<npoint;ll+=radix){
 	  // When ll = npoint-radix, ll+radix-1 = npoint-1, and we do it all.
 	  FT = FT 
 	    + invMkl(ll+0,k)*ComputeProj[ll+0]
 	    + invMkl(ll+1,k)*ComputeProj[ll+1]
 	    + invMkl(ll+2,k)*ComputeProj[ll+2]
 	    + invMkl(ll+3,k)*ComputeProj[ll+3]
 	    + invMkl(ll+4,k)*ComputeProj[ll+4]
 	    + invMkl(ll+5,k)*ComputeProj[ll+5]
 	    + invMkl(ll+6,k)*ComputeProj[ll+6]
 	    + invMkl(ll+7,k)*ComputeProj[ll+7]
 	    + invMkl(ll+8,k)*ComputeProj[ll+8];
 	}
 	for(int l=ll;l<npoint;l++){
 	  FT= FT+ invMkl(l,k)*ComputeProj[l];
 	}
 #endif
 	// 1 kernel call -- must be cheaper
 	int osites=CoarseGrid->oSites();
 	autoView( A_v  , _A[k], AcceleratorWrite);
 	autoView( FT_v  , FT, AcceleratorRead);
 	accelerator_for(sss, osites, 1, {
 	    for(int j=0;j<nbasis;j++){
 	      A_v[sss](i,j) = FT_v[sss](j);
 	    }
        });
      }
      tinv+=usecond();
    }
    // Only needed if nonhermitian
    //    if ( ! hermitian ) {
    //      std::cout << GridLogMessage<<"PopulateAdag  "<<std::endl;
    //      PopulateAdag();
    //    }
    // Need to write something to populate Adag from A
    //    std::cout << GridLogMessage << " Calling GridtoBLAS "<<std::endl;
    for(int p=0;p<geom_srhs.npoint;p++){
      GridtoBLAS(_A[p],BLAS_A[p]);
    }
    std::cout << GridLogMessage<<"CoarsenOperator phase  "<<tphase<<" us"<<std::endl;
    std::cout << GridLogMessage<<"CoarsenOperator phaseBZ "<<tphaseBZ<<" us"<<std::endl;
    std::cout << GridLogMessage<<"CoarsenOperator mat    "<<tmat <<" us"<<std::endl;
    std::cout << GridLogMessage<<"CoarsenOperator proj   "<<tproj<<" us"<<std::endl;
    std::cout << GridLogMessage<<"CoarsenOperator inv    "<<tinv<<" us"<<std::endl;
 #endif
  }
  void Mdag(const CoarseVector &in, CoarseVector &out)
  {
    this->M(in,out);
  }
  void M (const CoarseVector &in, CoarseVector &out)
  {
    //    std::cout << GridLogMessage << "New Mrhs coarse"<<std::endl;
    conformable(CoarseGrid(),in.Grid());
    conformable(in.Grid(),out.Grid());
    out.Checkerboard() = in.Checkerboard();
    RealD t_tot;
    RealD t_exch;
    RealD t_GtoB;
    RealD t_BtoG;
    RealD t_mult;
    t_tot=-usecond();
    CoarseVector tin=in;
    t_exch=-usecond();
    CoarseVector pin = Cell.ExchangePeriodic(tin); //padded input
    t_exch+=usecond();
    CoarseVector pout(pin.Grid());
    int npoint = geom.npoint;
    typedef calcMatrix* Aview;
    typedef LatticeView<Cvec> Vview;
    const int Nsimd = CComplex::Nsimd();
    int64_t nrhs  =pin.Grid()->GlobalDimensions()[0];
    assert(nrhs>=1);
    RealD flops,bytes;
    int64_t osites=in.Grid()->oSites(); // unpadded
    int64_t unpadded_vol = CoarseGrid()->lSites()/nrhs;
    flops = 1.0* npoint * nbasis * nbasis * 8.0 * osites * CComplex::Nsimd();
    bytes = 1.0*osites*sizeof(siteMatrix)*npoint/pin.Grid()->GlobalDimensions()[0]
          + 2.0*osites*sizeof(siteVector)*npoint;
    t_GtoB=-usecond();
    GridtoBLAS(pin,BLAS_B);
    t_GtoB+=usecond();
    GridBLAS BLAS;
    t_mult=-usecond();
    for(int p=0;p<geom.npoint;p++){
      RealD c = 1.0;
      if (p==0) c = 0.0;
      ComplexD beta(c);
      BLAS.gemmBatched(nbasis,nrhs,nbasis,
 		       ComplexD(1.0),
 		       BLAS_AP[p], 
 		       BLAS_BP[p], 
 		       ComplexD(c), 
 		       BLAS_CP);
    }
    BLAS.synchronise();
    t_mult+=usecond();
    t_BtoG=-usecond();
    BLAStoGrid(out,BLAS_C);
    t_BtoG+=usecond();
    t_tot+=usecond();
    /*
    std::cout << GridLogMessage << "New Mrhs coarse DONE "<<std::endl;
    std::cout << GridLogMessage<<"Coarse Mult exch "<<t_exch<<" us"<<std::endl;
    std::cout << GridLogMessage<<"Coarse Mult mult "<<t_mult<<" us"<<std::endl;
    std::cout << GridLogMessage<<"Coarse Mult GtoB  "<<t_GtoB<<" us"<<std::endl;
    std::cout << GridLogMessage<<"Coarse Mult BtoG  "<<t_BtoG<<" us"<<std::endl;
    std::cout << GridLogMessage<<"Coarse Mult tot  "<<t_tot<<" us"<<std::endl;
    */
    //    std::cout << GridLogMessage<<std::endl;
    //    std::cout << GridLogMessage<<"Coarse Kernel flops "<< flops<<std::endl;
    //    std::cout << GridLogMessage<<"Coarse Kernel flop/s "<< flops/t_mult<<" mflop/s"<<std::endl;
    //    std::cout << GridLogMessage<<"Coarse Kernel bytes/s "<< bytes/t_mult/1000<<" GB/s"<<std::endl;
    //    std::cout << GridLogMessage<<"Coarse overall flops/s "<< flops/t_tot<<" mflop/s"<<std::endl;
    //    std::cout << GridLogMessage<<"Coarse total bytes   "<< bytes/1e6<<" MB"<<std::endl;
  };
  virtual  void Mdiag    (const Field &in, Field &out){ assert(0);};
  virtual  void Mdir     (const Field &in, Field &out,int dir, int disp){assert(0);};
  virtual  void MdirAll  (const Field &in, std::vector<Field> &out){assert(0);};
 };
 NAMESPACE_END(Grid);
--- a/Grid/algorithms/multigrid/Geometry.h
+++ b/Grid/algorithms/multigrid/Geometry.h
@@ -0,0 +1,238 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./lib/algorithms/GeneralCoarsenedMatrix.h
    Copyright (C) 2015
 Author: Peter Boyle <pboyle@bnl.gov>
    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 */
 #pragma once
 NAMESPACE_BEGIN(Grid);
 /////////////////////////////////////////////////////////////////
 // Geometry class in cartesian case
 /////////////////////////////////////////////////////////////////
 class Geometry {
 public:
  int npoint;
  int base;
  std::vector<int> directions   ;
  std::vector<int> displacements;
  std::vector<int> points_dagger;
  Geometry(int _d)  {
    base = (_d==5) ? 1:0;
    // make coarse grid stencil for 4d , not 5d
    if ( _d==5 ) _d=4;
    npoint = 2*_d+1;
    directions.resize(npoint);
    displacements.resize(npoint);
    points_dagger.resize(npoint);
    for(int d=0;d<_d;d++){
      directions[d   ] = d+base;
      directions[d+_d] = d+base;
      displacements[d  ] = +1;
      displacements[d+_d]= -1;
      points_dagger[d   ] = d+_d;
      points_dagger[d+_d] = d;
    }
    directions   [2*_d]=0;
    displacements[2*_d]=0;
    points_dagger[2*_d]=2*_d;
  }
  int point(int dir, int disp) {
    assert(disp == -1 || disp == 0 || disp == 1);
    assert(base+0 <= dir && dir < base+4);
    // directions faster index = new indexing
    // 4d (base = 0):
    // point 0  1  2  3  4  5  6  7  8
    // dir   0  1  2  3  0  1  2  3  0
    // disp +1 +1 +1 +1 -1 -1 -1 -1  0
    // 5d (base = 1):
    // point 0  1  2  3  4  5  6  7  8
    // dir   1  2  3  4  1  2  3  4  0
    // disp +1 +1 +1 +1 -1 -1 -1 -1  0
    // displacements faster index = old indexing
    // 4d (base = 0):
    // point 0  1  2  3  4  5  6  7  8
    // dir   0  0  1  1  2  2  3  3  0
    // disp +1 -1 +1 -1 +1 -1 +1 -1  0
    // 5d (base = 1):
    // point 0  1  2  3  4  5  6  7  8
    // dir   1  1  2  2  3  3  4  4  0
    // disp +1 -1 +1 -1 +1 -1 +1 -1  0
    if(dir == 0 and disp == 0)
      return 8;
    else // New indexing
      return (1 - disp) / 2 * 4 + dir - base;
    // else // Old indexing
    //   return (4 * (dir - base) + 1 - disp) / 2;
  }
 };
 /////////////////////////////////////////////////////////////////
 // Less local equivalent of Geometry class in cartesian case
 /////////////////////////////////////////////////////////////////
 class NonLocalStencilGeometry {
 public:
  //  int depth;
  int skip;
  int hops;
  int npoint;
  std::vector<Coordinate> shifts;
  Coordinate stencil_size;
  Coordinate stencil_lo;
  Coordinate stencil_hi;
  GridCartesian *grid;
  GridCartesian *Grid() {return grid;};
  int Depth(void){return 1;};   // Ghost zone depth
  int Hops(void){return hops;}; // # of hops=> level of corner fill in in stencil
  int DimSkip(void){return skip;};
  virtual ~NonLocalStencilGeometry() {};
  int  Reverse(int point)
  {
    int Nd = Grid()->Nd();
    Coordinate shft = shifts[point];
    Coordinate rev(Nd);
    for(int mu=0;mu<Nd;mu++) rev[mu]= -shft[mu];
    for(int p=0;p<npoint;p++){
      if(rev==shifts[p]){
 	return p;
      }
    }
    assert(0);
    return -1;
  }
  void BuildShifts(void)
  {
    this->shifts.resize(0);
    int Nd = this->grid->Nd();
    int dd = this->DimSkip();
    for(int s0=this->stencil_lo[dd+0];s0<=this->stencil_hi[dd+0];s0++){
    for(int s1=this->stencil_lo[dd+1];s1<=this->stencil_hi[dd+1];s1++){
    for(int s2=this->stencil_lo[dd+2];s2<=this->stencil_hi[dd+2];s2++){
    for(int s3=this->stencil_lo[dd+3];s3<=this->stencil_hi[dd+3];s3++){
      Coordinate sft(Nd,0);
      sft[dd+0] = s0;
      sft[dd+1] = s1;
      sft[dd+2] = s2;
      sft[dd+3] = s3;
      int nhops = abs(s0)+abs(s1)+abs(s2)+abs(s3);
      if(nhops<=this->hops) this->shifts.push_back(sft);
    }}}}
    this->npoint = this->shifts.size();
    std::cout << GridLogMessage << "NonLocalStencilGeometry has "<< this->npoint << " terms in stencil "<<std::endl;
  }
  NonLocalStencilGeometry(GridCartesian *_coarse_grid,int _hops,int _skip) : grid(_coarse_grid), hops(_hops), skip(_skip)
  {
    Coordinate latt = grid->GlobalDimensions();
    stencil_size.resize(grid->Nd());
    stencil_lo.resize(grid->Nd());
    stencil_hi.resize(grid->Nd());
    for(int d=0;d<grid->Nd();d++){
     if ( latt[d] == 1 ) {
      stencil_lo[d] = 0;
      stencil_hi[d] = 0;
      stencil_size[d]= 1;
     } else if ( latt[d] == 2 ) {
      stencil_lo[d] = -1;
      stencil_hi[d] = 0;
      stencil_size[d]= 2;
     } else if ( latt[d] > 2 ) {
       stencil_lo[d] = -1;
       stencil_hi[d] =  1;
       stencil_size[d]= 3;
     }
    }
    this->BuildShifts();
  };
 };
 // Need to worry about red-black now
 class NonLocalStencilGeometry4D : public NonLocalStencilGeometry {
 public:
  virtual int DerivedDimSkip(void) { return 0;};
  NonLocalStencilGeometry4D(GridCartesian *Coarse,int _hops) : NonLocalStencilGeometry(Coarse,_hops,0) { };
  virtual ~NonLocalStencilGeometry4D() {};
 };
 class NonLocalStencilGeometry5D : public NonLocalStencilGeometry {
 public:
  virtual int DerivedDimSkip(void) { return 1; }; 
  NonLocalStencilGeometry5D(GridCartesian *Coarse,int _hops) : NonLocalStencilGeometry(Coarse,_hops,1)  { };
  virtual ~NonLocalStencilGeometry5D() {};
 };
 /*
 * Bunch of different options classes
 */
 class NextToNextToNextToNearestStencilGeometry4D : public NonLocalStencilGeometry4D {
 public:
  NextToNextToNextToNearestStencilGeometry4D(GridCartesian *Coarse) :  NonLocalStencilGeometry4D(Coarse,4)
  {
  };
 };
 class NextToNextToNextToNearestStencilGeometry5D : public  NonLocalStencilGeometry5D {
 public:
  NextToNextToNextToNearestStencilGeometry5D(GridCartesian *Coarse) :  NonLocalStencilGeometry5D(Coarse,4)
  {
  };
 };
 class NextToNearestStencilGeometry4D : public  NonLocalStencilGeometry4D {
 public:
  NextToNearestStencilGeometry4D(GridCartesian *Coarse) :  NonLocalStencilGeometry4D(Coarse,2)
  {
  };
 };
 class NextToNearestStencilGeometry5D : public  NonLocalStencilGeometry5D {
 public:
  NextToNearestStencilGeometry5D(GridCartesian *Coarse) :  NonLocalStencilGeometry5D(Coarse,2)
  {
  };
 };
 class NearestStencilGeometry4D : public  NonLocalStencilGeometry4D {
 public:
  NearestStencilGeometry4D(GridCartesian *Coarse) :  NonLocalStencilGeometry4D(Coarse,1)
  {
  };
 };
 class NearestStencilGeometry5D : public  NonLocalStencilGeometry5D {
 public:
  NearestStencilGeometry5D(GridCartesian *Coarse) :  NonLocalStencilGeometry5D(Coarse,1)
  {
  };
 };
 NAMESPACE_END(Grid);
--- a/Grid/algorithms/multigrid/MultiGrid.h
+++ b/Grid/algorithms/multigrid/MultiGrid.h
@@ -0,0 +1,34 @@
    /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid
    Source file: Grid/algorithms/multigrid/MultiGrid.h
    Copyright (C) 2023
 Author: Peter Boyle <pboyle@bnl.gov>
    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 */
 #pragma once
 #include <Grid/algorithms/multigrid/Aggregates.h>
 #include <Grid/algorithms/multigrid/Geometry.h>
 #include <Grid/algorithms/multigrid/CoarsenedMatrix.h>
 #include <Grid/algorithms/multigrid/GeneralCoarsenedMatrix.h>
 #include <Grid/algorithms/multigrid/GeneralCoarsenedMatrixMultiRHS.h>
--- a/Grid/allocator/AlignedAllocator.h
+++ b/Grid/allocator/AlignedAllocator.h
@@ -175,9 +175,56 @@ template<class T> using cshiftAllocator = std::allocator<T>;
 template<class T> using Vector        = std::vector<T,uvmAllocator<T> >;           
 template<class T> using stencilVector = std::vector<T,alignedAllocator<T> >;           
-template<class T> using commVector = std::vector<T,devAllocator<T> >;
+template<class T> using commVector    = std::vector<T,devAllocator<T> >;
 template<class T> using deviceVector  = std::vector<T,devAllocator<T> >;
-template<class T> using cshiftVector = std::vector<T,cshiftAllocator<T> >;
+template<class T> using cshiftVector  = std::vector<T,cshiftAllocator<T> >;
 /*
 template<class T> class vecView
 {
 protected:
  T * data;
  uint64_t size;
  ViewMode mode;
  void * cpu_ptr;
 public:
  accelerator_inline T & operator[](size_t i) const { return this->data[i]; };
  vecView(std::vector<T> &refer_to_me,ViewMode _mode)
  {
    cpu_ptr = &refer_to_me[0];
    size = refer_to_me.size();
    mode = _mode;
    data =(T *) MemoryManager::ViewOpen(cpu_ptr,
 					size*sizeof(T),
 					mode,
 					AdviseDefault);
  }
  void ViewClose(void)
  { // Inform the manager
    MemoryManager::ViewClose(this->cpu_ptr,this->mode);    
  }
 };
 template<class T> vecView<T> VectorView(std::vector<T> &vec,ViewMode _mode)
 {
  vecView<T> ret(vec,_mode); // does the open
  return ret;                // must be closed
 }
 // Little autoscope assister
 template<class View> 
 class VectorViewCloser
 {
  View v;  // Take a copy of view and call view close when I go out of scope automatically
 public:
  VectorViewCloser(View &_v) : v(_v) {};
  ~VectorViewCloser() { auto ptr = v.cpu_ptr; v.ViewClose();  MemoryManager::NotifyDeletion(ptr);}
 };
 #define autoVecView(v_v,v,mode)					\
  auto v_v = VectorView(v,mode);				\
  ViewCloser<decltype(v_v)> _autoView##v_v(v_v);
 */
 NAMESPACE_END(Grid);
--- a/Grid/allocator/MemoryManager.h
+++ b/Grid/allocator/MemoryManager.h
@@ -209,9 +209,9 @@ private:
  static void     CpuViewClose(uint64_t Ptr);
  static uint64_t CpuViewOpen(uint64_t  CpuPtr,size_t bytes,ViewMode mode,ViewAdvise hint);
 #endif
  static void NotifyDeletion(void * CpuPtr);
 public:
  static void NotifyDeletion(void * CpuPtr);
  static void Print(void);
  static void PrintAll(void);
  static void PrintState( void* CpuPtr);
--- a/Grid/allocator/MemoryManagerCache.cc
+++ b/Grid/allocator/MemoryManagerCache.cc
@@ -8,7 +8,7 @@ NAMESPACE_BEGIN(Grid);
 static char print_buffer [ MAXLINE ];
 #define mprintf(...) snprintf (print_buffer,MAXLINE, __VA_ARGS__ ); std::cout << GridLogMemory << print_buffer;
-#define dprintf(...) snprintf (print_buffer,MAXLINE, __VA_ARGS__ ); std::cout << GridLogMemory << print_buffer;
+#define dprintf(...) snprintf (print_buffer,MAXLINE, __VA_ARGS__ ); std::cout << GridLogDebug << print_buffer;
 //#define dprintf(...) 
@@ -111,7 +111,7 @@ void MemoryManager::AccDiscard(AcceleratorViewEntry &AccCache)
  ///////////////////////////////////////////////////////////
  assert(AccCache.state!=Empty);
-  mprintf("MemoryManager: Discard(%lx) %lx\n",(uint64_t)AccCache.CpuPtr,(uint64_t)AccCache.AccPtr); 
+  dprintf("MemoryManager: Discard(%lx) %lx\n",(uint64_t)AccCache.CpuPtr,(uint64_t)AccCache.AccPtr); 
  assert(AccCache.accLock==0);
  assert(AccCache.cpuLock==0);
  assert(AccCache.CpuPtr!=(uint64_t)NULL);
@@ -141,7 +141,7 @@ void MemoryManager::Evict(AcceleratorViewEntry &AccCache)
  ///////////////////////////////////////////////////////////////////////////
  assert(AccCache.state!=Empty);
-  mprintf("MemoryManager: Evict cpu %lx acc %lx cpuLock %ld accLock %ld\n",
+  mprintf("MemoryManager: Evict CpuPtr %lx AccPtr %lx cpuLock %ld accLock %ld\n",
 	  (uint64_t)AccCache.CpuPtr,(uint64_t)AccCache.AccPtr,
 	  (uint64_t)AccCache.cpuLock,(uint64_t)AccCache.accLock); 
  if (AccCache.accLock!=0) return;
@@ -155,7 +155,7 @@ void MemoryManager::Evict(AcceleratorViewEntry &AccCache)
    AccCache.AccPtr=(uint64_t)NULL;
    AccCache.state=CpuDirty; // CPU primary now
    DeviceBytes   -=AccCache.bytes;
-    dprintf("MemoryManager: Free(%lx) footprint now %ld \n",(uint64_t)AccCache.AccPtr,DeviceBytes);  
+    dprintf("MemoryManager: Free(AccPtr %lx) footprint now %ld \n",(uint64_t)AccCache.AccPtr,DeviceBytes);  
  }
  //  uint64_t CpuPtr = AccCache.CpuPtr;
  DeviceEvictions++;
@@ -169,7 +169,7 @@ void MemoryManager::Flush(AcceleratorViewEntry &AccCache)
  assert(AccCache.AccPtr!=(uint64_t)NULL);
  assert(AccCache.CpuPtr!=(uint64_t)NULL);
  acceleratorCopyFromDevice((void *)AccCache.AccPtr,(void *)AccCache.CpuPtr,AccCache.bytes);
-  mprintf("MemoryManager: Flush  %lx -> %lx\n",(uint64_t)AccCache.AccPtr,(uint64_t)AccCache.CpuPtr); fflush(stdout);
+  mprintf("MemoryManager: acceleratorCopyFromDevice Flush AccPtr %lx -> CpuPtr %lx\n",(uint64_t)AccCache.AccPtr,(uint64_t)AccCache.CpuPtr); fflush(stdout);
  DeviceToHostBytes+=AccCache.bytes;
  DeviceToHostXfer++;
  AccCache.state=Consistent;
@@ -184,7 +184,7 @@ void MemoryManager::Clone(AcceleratorViewEntry &AccCache)
    AccCache.AccPtr=(uint64_t)AcceleratorAllocate(AccCache.bytes);
    DeviceBytes+=AccCache.bytes;
  }
-  mprintf("MemoryManager: Clone %lx <- %lx\n",(uint64_t)AccCache.AccPtr,(uint64_t)AccCache.CpuPtr); fflush(stdout);
+  mprintf("MemoryManager: acceleratorCopyToDevice   Clone AccPtr %lx <- CpuPtr %lx\n",(uint64_t)AccCache.AccPtr,(uint64_t)AccCache.CpuPtr); fflush(stdout);
  acceleratorCopyToDevice((void *)AccCache.CpuPtr,(void *)AccCache.AccPtr,AccCache.bytes);
  HostToDeviceBytes+=AccCache.bytes;
  HostToDeviceXfer++;
@@ -474,6 +474,7 @@ void  MemoryManager::Print(void)
  std::cout << GridLogMessage << DeviceEvictions  << " Evictions from device " << std::endl;
  std::cout << GridLogMessage << DeviceDestroy    << " Destroyed vectors on device " << std::endl;
  std::cout << GridLogMessage << AccViewTable.size()<< " vectors " << LRU.size()<<" evictable"<< std::endl;
  acceleratorMem();
  std::cout << GridLogMessage << "--------------------------------------------" << std::endl;
 }
 void  MemoryManager::PrintAll(void)
--- a/Grid/cartesian/Cartesian_base.h
+++ b/Grid/cartesian/Cartesian_base.h
@@ -70,8 +70,8 @@ public:
  Coordinate _istride;    // Inner stride i.e. within simd lane
  int _osites;                  // _isites*_osites = product(dimensions).
  int _isites;
-  int _fsites;                  // _isites*_osites = product(dimensions).
+  int64_t _fsites;                  // _isites*_osites = product(dimensions).
-  int _gsites;
+  int64_t _gsites;
  Coordinate _slice_block;// subslice information
  Coordinate _slice_stride;
  Coordinate _slice_nblock;
@@ -183,7 +183,7 @@ public:
  inline int Nsimd(void)  const { return _isites; };// Synonymous with iSites
  inline int oSites(void) const { return _osites; };
  inline int lSites(void) const { return _isites*_osites; }; 
-  inline int gSites(void) const { return _isites*_osites*_Nprocessors; }; 
+  inline int64_t gSites(void) const { return (int64_t)_isites*(int64_t)_osites*(int64_t)_Nprocessors; }; 
  inline int Nd    (void) const { return _ndimension;};
  inline const Coordinate LocalStarts(void)             { return _lstart;    };
@@ -214,7 +214,7 @@ public:
  ////////////////////////////////////////////////////////////////
  // Global addressing
  ////////////////////////////////////////////////////////////////
-  void GlobalIndexToGlobalCoor(int gidx,Coordinate &gcoor){
+  void GlobalIndexToGlobalCoor(int64_t gidx,Coordinate &gcoor){
    assert(gidx< gSites());
    Lexicographic::CoorFromIndex(gcoor,gidx,_gdimensions);
  }
@@ -222,7 +222,7 @@ public:
    assert(lidx<lSites());
    Lexicographic::CoorFromIndex(lcoor,lidx,_ldimensions);
  }
-  void GlobalCoorToGlobalIndex(const Coordinate & gcoor,int & gidx){
+  void GlobalCoorToGlobalIndex(const Coordinate & gcoor,int64_t & gidx){
    gidx=0;
    int mult=1;
    for(int mu=0;mu<_ndimension;mu++) {
--- a/Grid/communicator/Communicator_base.h
+++ b/Grid/communicator/Communicator_base.h
@@ -138,6 +138,14 @@ public:
  ////////////////////////////////////////////////////////////
  // Face exchange, buffer swap in translational invariant way
  ////////////////////////////////////////////////////////////
  void CommsComplete(std::vector<CommsRequest_t> &list);
  void SendToRecvFromBegin(std::vector<CommsRequest_t> &list,
 			   void *xmit,
 			   int dest,
 			   void *recv,
 			   int from,
 			   int bytes,int dir);
  void SendToRecvFrom(void *xmit,
 		      int xmit_to_rank,
 		      void *recv,
--- a/Grid/communicator/Communicator_mpi3.cc
+++ b/Grid/communicator/Communicator_mpi3.cc
@@ -306,6 +306,44 @@ void CartesianCommunicator::GlobalSumVector(double *d,int N)
  int ierr = MPI_Allreduce(MPI_IN_PLACE,d,N,MPI_DOUBLE,MPI_SUM,communicator);
  assert(ierr==0);
 }
 void CartesianCommunicator::SendToRecvFromBegin(std::vector<CommsRequest_t> &list,
 						void *xmit,
 						int dest,
 						void *recv,
 						int from,
 						int bytes,int dir)
 {
  MPI_Request xrq;
  MPI_Request rrq;
  assert(dest != _processor);
  assert(from != _processor);
  int tag;
  tag= dir+from*32;
  int ierr=MPI_Irecv(recv, bytes, MPI_CHAR,from,tag,communicator,&rrq);
  assert(ierr==0);
  list.push_back(rrq);
  tag= dir+_processor*32;
  ierr =MPI_Isend(xmit, bytes, MPI_CHAR,dest,tag,communicator,&xrq);
  assert(ierr==0);
  list.push_back(xrq);
 }
 void CartesianCommunicator::CommsComplete(std::vector<CommsRequest_t> &list)
 {
  int nreq=list.size();
  if (nreq==0) return;
  std::vector<MPI_Status> status(nreq);
  int ierr = MPI_Waitall(nreq,&list[0],&status[0]);
  assert(ierr==0);
  list.resize(0);
 }
 // Basic Halo comms primitive
 void CartesianCommunicator::SendToRecvFrom(void *xmit,
 					   int dest,
@@ -348,6 +386,7 @@ double CartesianCommunicator::StencilSendToRecvFrom( void *xmit,
  return offbytes;
 }
 #undef NVLINK_GET // Define to use get instead of put DMA
 double CartesianCommunicator::StencilSendToRecvFromBegin(std::vector<CommsRequest_t> &list,
 							 void *xmit,
 							 int dest,int dox,
@@ -380,9 +419,15 @@ double CartesianCommunicator::StencilSendToRecvFromBegin(std::vector<CommsReques
      list.push_back(rrq);
      off_node_bytes+=rbytes;
    }
 #ifdef NVLINK_GET
      void *shm = (void *) this->ShmBufferTranslate(from,xmit);
      assert(shm!=NULL);
      acceleratorCopyDeviceToDeviceAsynch(shm,recv,rbytes);
 #endif
  }
  if (dox) {
    //  rcrc = crc32(rcrc,(unsigned char *)recv,bytes);
    if ( (gdest == MPI_UNDEFINED) || Stencil_force_mpi ) {
      tag= dir+_processor*32;
      ierr =MPI_Isend(xmit, xbytes, MPI_CHAR,dest,tag,communicator_halo[commdir],&xrq);
@@ -390,9 +435,12 @@ double CartesianCommunicator::StencilSendToRecvFromBegin(std::vector<CommsReques
      list.push_back(xrq);
      off_node_bytes+=xbytes;
    } else {
 #ifndef NVLINK_GET
      void *shm = (void *) this->ShmBufferTranslate(dest,recv);
      assert(shm!=NULL);
      acceleratorCopyDeviceToDeviceAsynch(xmit,shm,xbytes);
 #endif
    }
  }
@@ -402,6 +450,8 @@ void CartesianCommunicator::StencilSendToRecvFromComplete(std::vector<CommsReque
 {
  int nreq=list.size();
  acceleratorCopySynchronise();
  if (nreq==0) return;
  std::vector<MPI_Status> status(nreq);
--- a/Grid/communicator/Communicator_none.cc
+++ b/Grid/communicator/Communicator_none.cc
@@ -91,6 +91,17 @@ void CartesianCommunicator::SendToRecvFrom(void *xmit,
 {
  assert(0);
 }
 void CartesianCommunicator::CommsComplete(std::vector<CommsRequest_t> &list){ assert(0);}
 void CartesianCommunicator::SendToRecvFromBegin(std::vector<CommsRequest_t> &list,
 						void *xmit,
 						int dest,
 						void *recv,
 						int from,
 						int bytes,int dir)
 {
  assert(0);
 }
 void CartesianCommunicator::AllToAll(int dim,void  *in,void *out,uint64_t words,uint64_t bytes)
 {
  bcopy(in,out,bytes*words);
--- a/Grid/communicator/SharedMemory.cc
+++ b/Grid/communicator/SharedMemory.cc
@@ -40,6 +40,9 @@ int                 GlobalSharedMemory::_ShmAlloc;
 uint64_t            GlobalSharedMemory::_ShmAllocBytes;
 std::vector<void *> GlobalSharedMemory::WorldShmCommBufs;
 #ifndef ACCELERATOR_AWARE_MPI
 void * GlobalSharedMemory::HostCommBuf;
 #endif
 Grid_MPI_Comm       GlobalSharedMemory::WorldShmComm;
 int                 GlobalSharedMemory::WorldShmRank;
@@ -66,6 +69,26 @@ void GlobalSharedMemory::SharedMemoryFree(void)
 /////////////////////////////////
 // Alloc, free shmem region
 /////////////////////////////////
 #ifndef ACCELERATOR_AWARE_MPI
 void *SharedMemory::HostBufferMalloc(size_t bytes){
  void *ptr = (void *)host_heap_top;
  host_heap_top  += bytes;
  host_heap_bytes+= bytes;
  if (host_heap_bytes >= host_heap_size) {
    std::cout<< " HostBufferMalloc exceeded heap size -- try increasing with --shm <MB> flag" <<std::endl;
    std::cout<< " Parameter specified in units of MB (megabytes) " <<std::endl;
    std::cout<< " Current alloc is " << (bytes/(1024*1024)) <<"MB"<<std::endl;
    std::cout<< " Current bytes is " << (host_heap_bytes/(1024*1024)) <<"MB"<<std::endl;
    std::cout<< " Current heap  is " << (host_heap_size/(1024*1024)) <<"MB"<<std::endl;
    assert(host_heap_bytes<host_heap_size);
  }
  return ptr;
 }
 void SharedMemory::HostBufferFreeAll(void) { 
  host_heap_top  =(size_t)HostCommBuf;
  host_heap_bytes=0;
 }
 #endif
 void *SharedMemory::ShmBufferMalloc(size_t bytes){
  //  bytes = (bytes+sizeof(vRealD))&(~(sizeof(vRealD)-1));// align up bytes
  void *ptr = (void *)heap_top;
--- a/Grid/communicator/SharedMemory.h
+++ b/Grid/communicator/SharedMemory.h
@@ -75,7 +75,9 @@ public:
  static int           Hugepages;
  static std::vector<void *> WorldShmCommBufs;
-
+#ifndef ACCELERATOR_AWARE_MPI
  static void *HostCommBuf;
 #endif
  static Grid_MPI_Comm WorldComm;
  static int           WorldRank;
  static int           WorldSize;
@@ -120,6 +122,13 @@ private:
  size_t heap_bytes;
  size_t heap_size;
 #ifndef ACCELERATOR_AWARE_MPI
  size_t host_heap_top;  // set in free all
  size_t host_heap_bytes;// set in free all
  void *HostCommBuf;     // set in SetCommunicator
  size_t host_heap_size; // set in SetCommunicator
 #endif
 protected:
  Grid_MPI_Comm    ShmComm; // for barriers
@@ -151,7 +160,10 @@ public:
  void *ShmBufferTranslate(int rank,void * local_p);
  void *ShmBufferMalloc(size_t bytes);
  void  ShmBufferFreeAll(void) ;
-  
+#ifndef ACCELERATOR_AWARE_MPI
  void *HostBufferMalloc(size_t bytes);
  void HostBufferFreeAll(void);
 #endif  
  //////////////////////////////////////////////////////////////////////////
  // Make info on Nodes & ranks and Shared memory available
  //////////////////////////////////////////////////////////////////////////
--- a/Grid/communicator/SharedMemoryMPI.cc
+++ b/Grid/communicator/SharedMemoryMPI.cc
@@ -39,10 +39,12 @@ Author: Christoph Lehner <christoph@lhnr.de>
 #include <hip/hip_runtime_api.h>
 #endif
 #ifdef GRID_SYCL
 #ifdef ACCELERATOR_AWARE_MPI
 #define GRID_SYCL_LEVEL_ZERO_IPC
 #include <syscall.h>
 #define SHM_SOCKETS
 #endif 
 #include <syscall.h>
 #endif
 #include <sys/socket.h>
 #include <sys/un.h>
@@ -512,46 +514,6 @@ void GlobalSharedMemory::SharedMemoryAllocate(uint64_t bytes, int flags)
 // Hugetlbfs mapping intended
 ////////////////////////////////////////////////////////////////////////////////////////////
 #if defined(GRID_CUDA) ||defined(GRID_HIP)  || defined(GRID_SYCL)
 //if defined(GRID_SYCL)
 #if 0
 void GlobalSharedMemory::SharedMemoryAllocate(uint64_t bytes, int flags)
 {
  void * ShmCommBuf ; 
  assert(_ShmSetup==1);
  assert(_ShmAlloc==0);
  //////////////////////////////////////////////////////////////////////////////////////////////////////////
  // allocate the pointer array for shared windows for our group
  //////////////////////////////////////////////////////////////////////////////////////////////////////////
  MPI_Barrier(WorldShmComm);
  WorldShmCommBufs.resize(WorldShmSize);
  ///////////////////////////////////////////////////////////////////////////////////////////////////////////
  // Each MPI rank should allocate our own buffer
  ///////////////////////////////////////////////////////////////////////////////////////////////////////////
  ShmCommBuf = acceleratorAllocDevice(bytes);
  if (ShmCommBuf == (void *)NULL ) {
    std::cerr << " SharedMemoryMPI.cc acceleratorAllocDevice failed NULL pointer for " << bytes<<" bytes " << std::endl;
    exit(EXIT_FAILURE);  
  }
  std::cout << WorldRank << Mheader " SharedMemoryMPI.cc acceleratorAllocDevice "<< bytes 
 	    << "bytes at "<< std::hex<< ShmCommBuf <<std::dec<<" for comms buffers " <<std::endl;
  SharedMemoryZero(ShmCommBuf,bytes);
  assert(WorldShmSize == 1);
  for(int r=0;r<WorldShmSize;r++){
    WorldShmCommBufs[r] = ShmCommBuf;
  }
  _ShmAllocBytes=bytes;
  _ShmAlloc=1;
 }
 #endif
 #if defined(GRID_CUDA) ||defined(GRID_HIP) ||defined(GRID_SYCL)  
 void GlobalSharedMemory::SharedMemoryAllocate(uint64_t bytes, int flags)
 {
  void * ShmCommBuf ; 
@@ -574,6 +536,9 @@ void GlobalSharedMemory::SharedMemoryAllocate(uint64_t bytes, int flags)
  ///////////////////////////////////////////////////////////////////////////////////////////////////////////
  // Each MPI rank should allocate our own buffer
  ///////////////////////////////////////////////////////////////////////////////////////////////////////////
 #ifndef ACCELERATOR_AWARE_MPI
  HostCommBuf= malloc(bytes);
 #endif  
  ShmCommBuf = acceleratorAllocDevice(bytes);
  if (ShmCommBuf == (void *)NULL ) {
    std::cerr << " SharedMemoryMPI.cc acceleratorAllocDevice failed NULL pointer for " << bytes<<" bytes " << std::endl;
@@ -738,7 +703,6 @@ void GlobalSharedMemory::SharedMemoryAllocate(uint64_t bytes, int flags)
  _ShmAllocBytes=bytes;
  _ShmAlloc=1;
 }
 #endif
 #else 
 #ifdef GRID_MPI3_SHMMMAP
@@ -962,6 +926,12 @@ void SharedMemory::SetCommunicator(Grid_MPI_Comm comm)
  }
  ShmBufferFreeAll();
 #ifndef ACCELERATOR_AWARE_MPI
  host_heap_size = heap_size;
  HostCommBuf= GlobalSharedMemory::HostCommBuf;
  HostBufferFreeAll();
 #endif  
  /////////////////////////////////////////////////////////////////////
  // find comm ranks in our SHM group (i.e. which ranks are on our node)
  /////////////////////////////////////////////////////////////////////
--- a/Grid/lattice/Lattice_base.h
+++ b/Grid/lattice/Lattice_base.h
@@ -234,9 +234,12 @@ public:
  }
  template<class sobj> inline Lattice<vobj> & operator = (const sobj & r){
-    auto me  = View(CpuWrite);
+    vobj vtmp;
-    thread_for(ss,me.size(),{
+    vtmp = r;
-	me[ss]= r;
+    auto me  = View(AcceleratorWrite);
    accelerator_for(ss,me.size(),vobj::Nsimd(),{
 	auto stmp=coalescedRead(vtmp);
 	coalescedWrite(me[ss],stmp);
    });
    me.ViewClose();
    return *this;
@@ -360,7 +363,7 @@ public:
 template<class vobj> std::ostream& operator<< (std::ostream& stream, const Lattice<vobj> &o){
  typedef typename vobj::scalar_object sobj;
-  for(int g=0;g<o.Grid()->_gsites;g++){
+  for(int64_t g=0;g<o.Grid()->_gsites;g++){
    Coordinate gcoor;
    o.Grid()->GlobalIndexToGlobalCoor(g,gcoor);
--- a/Grid/lattice/Lattice_crc.h
+++ b/Grid/lattice/Lattice_crc.h
@@ -29,7 +29,7 @@ Author: Peter Boyle <paboyle@ph.ed.ac.uk>
 NAMESPACE_BEGIN(Grid);
-template<class vobj> void DumpSliceNorm(std::string s,Lattice<vobj> &f,int mu=-1)
+template<class vobj> void DumpSliceNorm(std::string s,const Lattice<vobj> &f,int mu=-1)
 {
  auto ff = localNorm2(f);
  if ( mu==-1 ) mu = f.Grid()->Nd()-1;
--- a/Grid/lattice/Lattice_reduction.h
+++ b/Grid/lattice/Lattice_reduction.h
@@ -204,6 +204,27 @@ template<class vobj> inline RealD norm2(const Lattice<vobj> &arg){
  return real(nrm); 
 }
 template<class Op,class T1>
 inline auto norm2(const LatticeUnaryExpression<Op,T1> & expr)  ->RealD
 {
  return norm2(closure(expr));
 }
 template<class Op,class T1,class T2>
 inline auto norm2(const LatticeBinaryExpression<Op,T1,T2> & expr)      ->RealD
 {
  return norm2(closure(expr));
 }
 template<class Op,class T1,class T2,class T3>
 inline auto norm2(const LatticeTrinaryExpression<Op,T1,T2,T3> & expr)      ->RealD
 {
  return norm2(closure(expr));
 }
 //The global maximum of the site norm2
 template<class vobj> inline RealD maxLocalNorm2(const Lattice<vobj> &arg)
 {
@@ -281,12 +302,29 @@ inline ComplexD rankInnerProduct(const Lattice<vobj> &left,const Lattice<vobj> &
  return nrm;
 }
 template<class vobj>
 inline ComplexD innerProduct(const Lattice<vobj> &left,const Lattice<vobj> &right) {
  GridBase *grid = left.Grid();
 #ifdef GRID_SYCL
  uint64_t csum=0;
  if ( FlightRecorder::LoggingMode != FlightRecorder::LoggingModeNone)
  {
    // Hack
    // Fast integer xor checksum. Can also be used in comms now.
    autoView(l_v,left,AcceleratorRead);
    Integer words = left.Grid()->oSites()*sizeof(vobj)/sizeof(uint64_t);
    uint64_t *base= (uint64_t *)&l_v[0];
    csum=svm_xor(base,words);
  }
  FlightRecorder::CsumLog(csum);
 #endif
  ComplexD nrm = rankInnerProduct(left,right);
-  //  std::cerr<<"flight log " << std::hexfloat << nrm <<" "<<crc(left)<<std::endl;
+  RealD local = real(nrm);
  FlightRecorder::NormLog(real(nrm)); 
  grid->GlobalSum(nrm);
  FlightRecorder::ReductionLog(local,real(nrm)); 
  return nrm;
 }
--- a/Grid/lattice/Lattice_reduction_sycl.h
+++ b/Grid/lattice/Lattice_reduction_sycl.h
@@ -69,29 +69,30 @@ inline typename vobj::scalar_object sum_gpu_large(const vobj *lat, Integer osite
  return result;
 }
 NAMESPACE_END(Grid);
-/*
+template<class Word> Word svm_xor(Word *vec,uint64_t L)
 template<class Double> Double svm_reduce(Double *vec,uint64_t L)
 {
-  Double sumResult; zeroit(sumResult);
+  Word xorResult; xorResult = 0;
-  Double *d_sum =(Double *)cl::sycl::malloc_shared(sizeof(Double),*theGridAccelerator);
+  Word *d_sum =(Word *)cl::sycl::malloc_shared(sizeof(Word),*theGridAccelerator);
-  Double identity;  zeroit(identity);
+  Word identity;  identity=0;
  theGridAccelerator->submit([&](cl::sycl::handler &cgh) {
-     auto Reduction = cl::sycl::reduction(d_sum,identity,std::plus<>());
+     auto Reduction = cl::sycl::reduction(d_sum,identity,std::bit_xor<>());
     cgh.parallel_for(cl::sycl::range<1>{L},
 		      Reduction,
 		      [=] (cl::sycl::id<1> index, auto &sum) {
-	 sum +=vec[index];
+	 sum ^=vec[index];
     });
   });
  theGridAccelerator->wait();
-  Double ret = d_sum[0];
+  Word ret = d_sum[0];
  free(d_sum,*theGridAccelerator);
  std::cout << " svm_reduce finished "<<L<<" sites sum = " << ret <<std::endl;
  return ret;
 }
 NAMESPACE_END(Grid);
 /*
 template <class vobj>
 inline typename vobj::scalar_objectD sumD_gpu_repack(const vobj *lat, Integer osites)
 {
--- a/Grid/lattice/Lattice_rng.h
+++ b/Grid/lattice/Lattice_rng.h
@@ -365,9 +365,14 @@ public:
    _bernoulli.resize(_vol,std::discrete_distribution<int32_t>{1,1});
    _uid.resize(_vol,std::uniform_int_distribution<uint32_t>() );
  }
-
+  template <class vobj,class distribution> inline void fill(Lattice<vobj> &l,std::vector<distribution> &dist)
-  template <class vobj,class distribution> inline void fill(Lattice<vobj> &l,std::vector<distribution> &dist){
+  {
-
+    if ( l.Grid()->_isCheckerBoarded ) {
      Lattice<vobj> tmp(_grid);
      fill(tmp,dist);
      pickCheckerboard(l.Checkerboard(),l,tmp);
      return;
    }
    typedef typename vobj::scalar_object scalar_object;
    typedef typename vobj::scalar_type scalar_type;
    typedef typename vobj::vector_type vector_type;
@@ -411,7 +416,7 @@ public:
      std::cout << GridLogMessage << "Seed SHA256: " << GridChecksum::sha256_string(seeds) << std::endl;
      SeedFixedIntegers(seeds);
    }
-  void SeedFixedIntegers(const std::vector<int> &seeds){
+  void SeedFixedIntegers(const std::vector<int> &seeds, int britney=0){
    // Everyone generates the same seed_seq based on input seeds
    CartesianCommunicator::BroadcastWorld(0,(void *)&seeds[0],sizeof(int)*seeds.size());
@@ -428,10 +433,9 @@ public:
    // MT implementation does not implement fast discard even though
    // in principle this is possible
    ////////////////////////////////////////////////
 #if 1
    thread_for( lidx, _grid->lSites(), {
-	int gidx;
+	int64_t gidx;
 	int o_idx;
 	int i_idx;
 	int rank;
@@ -449,29 +453,12 @@ public:
 	int l_idx=generator_idx(o_idx,i_idx);
 	_generators[l_idx] = master_engine;
-	Skip(_generators[l_idx],gidx); // Skip to next RNG sequence
+	if ( britney ) { 
-    });
+	  Skip(_generators[l_idx],l_idx); // Skip to next RNG sequence
-#else
+	} else { 	
    // Everybody loops over global volume.
    thread_for( gidx, _grid->_gsites, {
 	// Where is it?
 	int rank;
 	int o_idx;
 	int i_idx;
 	Coordinate gcoor;
 	_grid->GlobalIndexToGlobalCoor(gidx,gcoor);
 	_grid->GlobalCoorToRankIndex(rank,o_idx,i_idx,gcoor);
 	// If this is one of mine we take it
 	if( rank == _grid->ThisRank() ){
 	  int l_idx=generator_idx(o_idx,i_idx);
 	  _generators[l_idx] = master_engine;
 	  Skip(_generators[l_idx],gidx); // Skip to next RNG sequence
 	}
    });
 #endif
 #else 
    ////////////////////////////////////////////////////////////////
    // Machine and thread decomposition dependent seeding is efficient
--- a/Grid/lattice/Lattice_transfer.h
+++ b/Grid/lattice/Lattice_transfer.h
@@ -276,18 +276,33 @@ inline void blockProject(Lattice<iVector<CComplex,nbasis > > &coarseData,
  autoView( coarseData_ , coarseData, AcceleratorWrite);
  autoView( ip_         , ip,         AcceleratorWrite);
  RealD t_IP=0;
  RealD t_co=0;
  RealD t_za=0;
  for(int v=0;v<nbasis;v++) {
    t_IP-=usecond();
    blockInnerProductD(ip,Basis[v],fineDataRed); // ip = <basis|fine>
    t_IP+=usecond();
    t_co-=usecond();
    accelerator_for( sc, coarse->oSites(), vobj::Nsimd(), {
 	convertType(coarseData_[sc](v),ip_[sc]);
    });
    t_co+=usecond();
    // improve numerical stability of projection
    // |fine> = |fine> - <basis|fine> |basis>
    ip=-ip;
    t_za-=usecond();
    blockZAXPY(fineDataRed,ip,Basis[v],fineDataRed); 
    t_za+=usecond();
  }
  //  std::cout << GridLogPerformance << " blockProject : blockInnerProduct :  "<<t_IP<<" us"<<std::endl;
  //  std::cout << GridLogPerformance << " blockProject : conv              :  "<<t_co<<" us"<<std::endl;
  //  std::cout << GridLogPerformance << " blockProject : blockZaxpy        :  "<<t_za<<" us"<<std::endl;
 }
 // This only minimises data motion from CPU to GPU
 // there is chance of better implementation that does a vxk loop of inner products to data share
 // at the GPU thread level
 template<class vobj,class CComplex,int nbasis,class VLattice>
 inline void batchBlockProject(std::vector<Lattice<iVector<CComplex,nbasis>>> &coarseData,
                               const std::vector<Lattice<vobj>> &fineData,
@@ -393,8 +408,15 @@ template<class vobj,class CComplex>
  Lattice<dotp> coarse_inner(coarse);
  // Precision promotion
  RealD t;
  t=-usecond();
  fine_inner = localInnerProductD<vobj>(fineX,fineY);
  //  t+=usecond(); std::cout << GridLogPerformance << " blockInnerProduct : localInnerProductD "<<t<<" us"<<std::endl;
  t=-usecond();
  blockSum(coarse_inner,fine_inner);
  //  t+=usecond(); std::cout << GridLogPerformance << " blockInnerProduct : blockSum "<<t<<" us"<<std::endl;
  t=-usecond();
  {
    autoView( CoarseInner_  , CoarseInner,AcceleratorWrite);
    autoView( coarse_inner_ , coarse_inner,AcceleratorRead);
@@ -402,6 +424,7 @@ template<class vobj,class CComplex>
      convertType(CoarseInner_[ss], TensorRemove(coarse_inner_[ss]));
    });
  }
  //  t+=usecond(); std::cout << GridLogPerformance << " blockInnerProduct : convertType "<<t<<" us"<<std::endl;
 }
@@ -444,6 +467,9 @@ inline void blockNormalise(Lattice<CComplex> &ip,Lattice<vobj> &fineX)
 template<class vobj>
 inline void blockSum(Lattice<vobj> &coarseData,const Lattice<vobj> &fineData) 
 {
  const int maxsubsec=256;
  typedef iVector<vobj,maxsubsec> vSubsec;
  GridBase * fine  = fineData.Grid();
  GridBase * coarse= coarseData.Grid();
@@ -463,22 +489,40 @@ inline void blockSum(Lattice<vobj> &coarseData,const Lattice<vobj> &fineData)
  autoView( coarseData_ , coarseData, AcceleratorWrite);
  autoView( fineData_   , fineData, AcceleratorRead);
-  auto coarseData_p = &coarseData_[0];
+  auto coarseData_p  = &coarseData_[0];
-  auto fineData_p = &fineData_[0];
+  auto fineData_p    = &fineData_[0];
  Coordinate fine_rdimensions = fine->_rdimensions;
  Coordinate coarse_rdimensions = coarse->_rdimensions;
-  accelerator_for(sc,coarse->oSites(),1,{
+  vobj zz = Zero();
  // Somewhat lazy calculation
  // Find the biggest power of two subsection divisor less than or equal to maxsubsec
  int subsec=maxsubsec;
  int subvol;
  subvol=blockVol/subsec;
  while(subvol*subsec!=blockVol){
    subsec = subsec/2;
    subvol=blockVol/subsec;
  };
  Lattice<vSubsec> coarseTmp(coarse);
  autoView( coarseTmp_, coarseTmp, AcceleratorWriteDiscard);
  auto coarseTmp_p= &coarseTmp_[0];
  // Sum within subsecs in a first kernel
  accelerator_for(sce,subsec*coarse->oSites(),vobj::Nsimd(),{
      int sc=sce/subsec;
      int e=sce%subsec;
      // One thread per sub block
      Coordinate coor_c(_ndimension);
      Lexicographic::CoorFromIndex(coor_c,sc,coarse_rdimensions);  // Block coordinate
-      vobj cd = Zero();
+      auto cd = coalescedRead(zz);
-      
+      for(int sb=e*subvol;sb<MIN((e+1)*subvol,blockVol);sb++){
      for(int sb=0;sb<blockVol;sb++){
 	int sf;
 	Coordinate coor_b(_ndimension);
 	Coordinate coor_f(_ndimension);
@@ -486,12 +530,21 @@ inline void blockSum(Lattice<vobj> &coarseData,const Lattice<vobj> &fineData)
 	for(int d=0;d<_ndimension;d++) coor_f[d]=coor_c[d]*block_r[d] + coor_b[d];
 	Lexicographic::IndexFromCoor(coor_f,sf,fine_rdimensions);
-	cd=cd+fineData_p[sf];
+	cd=cd+coalescedRead(fineData_p[sf]);
      }
-      coarseData_p[sc] = cd;
+      coalescedWrite(coarseTmp_[sc](e),cd);
    });
   // Sum across subsecs in a second kernel
   accelerator_for(sc,coarse->oSites(),vobj::Nsimd(),{
      auto cd = coalescedRead(coarseTmp_p[sc](0));
      for(int e=1;e<subsec;e++){
 	cd=cd+coalescedRead(coarseTmp_p[sc](e));
      }
      coalescedWrite(coarseData_p[sc],cd);
   });
  return;
 }
@@ -548,7 +601,7 @@ inline void blockOrthogonalise(Lattice<CComplex> &ip,std::vector<Lattice<vobj> >
  blockOrthonormalize(ip,Basis);
 }
-#if 0
+#ifdef GRID_ACCELERATED
 // TODO: CPU optimized version here
 template<class vobj,class CComplex,int nbasis>
 inline void blockPromote(const Lattice<iVector<CComplex,nbasis > > &coarseData,
@@ -574,26 +627,37 @@ inline void blockPromote(const Lattice<iVector<CComplex,nbasis > > &coarseData,
  autoView( fineData_   , fineData, AcceleratorWrite);
  autoView( coarseData_ , coarseData, AcceleratorRead);
  typedef LatticeView<vobj> Vview;
  std::vector<Vview> AcceleratorVecViewContainer_h; 
  for(int v=0;v<nbasis;v++) {
    AcceleratorVecViewContainer_h.push_back(Basis[v].View(AcceleratorRead));
  }
  static deviceVector<Vview> AcceleratorVecViewContainer; AcceleratorVecViewContainer.resize(nbasis); 
  acceleratorCopyToDevice(&AcceleratorVecViewContainer_h[0],&AcceleratorVecViewContainer[0],nbasis *sizeof(Vview));
  auto Basis_p = &AcceleratorVecViewContainer[0];
  // Loop with a cache friendly loop ordering
-  accelerator_for(sf,fine->oSites(),1,{
+  Coordinate frdimensions=fine->_rdimensions;
  Coordinate crdimensions=coarse->_rdimensions;
  accelerator_for(sf,fine->oSites(),vobj::Nsimd(),{
    int sc;
    Coordinate coor_c(_ndimension);
    Coordinate coor_f(_ndimension);
-    Lexicographic::CoorFromIndex(coor_f,sf,fine->_rdimensions);
+    Lexicographic::CoorFromIndex(coor_f,sf,frdimensions);
    for(int d=0;d<_ndimension;d++) coor_c[d]=coor_f[d]/block_r[d];
-    Lexicographic::IndexFromCoor(coor_c,sc,coarse->_rdimensions);
+    Lexicographic::IndexFromCoor(coor_c,sc,crdimensions);
-    for(int i=0;i<nbasis;i++) {
+    auto sum= coarseData_(sc)(0) *Basis_p[0](sf);
-      /*      auto basis_ = Basis[i],  );*/
+    for(int i=1;i<nbasis;i++) sum = sum + coarseData_(sc)(i)*Basis_p[i](sf);
-      if(i==0) fineData_[sf]=coarseData_[sc](i) *basis_[sf]);
+    coalescedWrite(fineData_[sf],sum);
      else     fineData_[sf]=fineData_[sf]+coarseData_[sc](i)*basis_[sf]);
    }
  });
  for(int v=0;v<nbasis;v++) {
    AcceleratorVecViewContainer_h[v].ViewClose();
  }
  return;
 }
 #else
 // CPU version
 template<class vobj,class CComplex,int nbasis,class VLattice>
 inline void blockPromote(const Lattice<iVector<CComplex,nbasis > > &coarseData,
 			 Lattice<vobj>   &fineData,
@@ -680,7 +744,11 @@ void localCopyRegion(const Lattice<vobj> &From,Lattice<vobj> & To,Coordinate Fro
  typedef typename vobj::scalar_type scalar_type;
  typedef typename vobj::vector_type vector_type;
-  static const int words=sizeof(vobj)/sizeof(vector_type);
+  const int words=sizeof(vobj)/sizeof(vector_type);
  //////////////////////////////////////////////////////////////////////////////////////////
  // checks should guarantee that the operations are local
  //////////////////////////////////////////////////////////////////////////////////////////
  GridBase *Fg = From.Grid();
  GridBase *Tg = To.Grid();
@@ -695,39 +763,20 @@ void localCopyRegion(const Lattice<vobj> &From,Lattice<vobj> & To,Coordinate Fro
  for(int d=0;d<nd;d++){
    assert(Fg->_processors[d]  == Tg->_processors[d]);
  }
  // the above should guarantee that the operations are local
-#if 1
+  ///////////////////////////////////////////////////////////
  // do the index calc on the GPU
  ///////////////////////////////////////////////////////////
  Coordinate f_ostride = Fg->_ostride;
  Coordinate f_istride = Fg->_istride;
  Coordinate f_rdimensions = Fg->_rdimensions;
  Coordinate t_ostride = Tg->_ostride;
  Coordinate t_istride = Tg->_istride;
  Coordinate t_rdimensions = Tg->_rdimensions;
  size_t nsite = 1;
  for(int i=0;i<nd;i++) nsite *= RegionSize[i];
  size_t tbytes = 4*nsite*sizeof(int);
  int *table = (int*)malloc(tbytes);
  thread_for(idx, nsite, {
      Coordinate from_coor, to_coor;
      size_t rem = idx;
      for(int i=0;i<nd;i++){
 	size_t base_i  = rem % RegionSize[i]; rem /= RegionSize[i];
 	from_coor[i] = base_i + FromLowerLeft[i];
 	to_coor[i] = base_i + ToLowerLeft[i];
      }
      int foidx = Fg->oIndex(from_coor);
      int fiidx = Fg->iIndex(from_coor);
      int toidx = Tg->oIndex(to_coor);
      int tiidx = Tg->iIndex(to_coor);
      int* tt = table + 4*idx;
      tt[0] = foidx;
      tt[1] = fiidx;
      tt[2] = toidx;
      tt[3] = tiidx;
    });
  int* table_d = (int*)acceleratorAllocDevice(tbytes);
  acceleratorCopyToDevice(table,table_d,tbytes);
  typedef typename vobj::vector_type vector_type;
  typedef typename vobj::scalar_type scalar_type;
@@ -735,12 +784,17 @@ void localCopyRegion(const Lattice<vobj> &From,Lattice<vobj> & To,Coordinate Fro
  autoView(to_v,To,AcceleratorWrite);
  accelerator_for(idx,nsite,1,{
-      static const int words=sizeof(vobj)/sizeof(vector_type);
+
-      int* tt = table_d + 4*idx;
+      Coordinate from_coor, to_coor, base;
-      int from_oidx = *tt++;
+      Lexicographic::CoorFromIndex(base,idx,RegionSize);
-      int from_lane = *tt++;
+      for(int i=0;i<nd;i++){
-      int to_oidx = *tt++;
+	from_coor[i] = base[i] + FromLowerLeft[i];
-      int to_lane = *tt;
+	to_coor[i] = base[i] + ToLowerLeft[i];
      }
      int from_oidx = 0; for(int d=0;d<nd;d++) from_oidx+=f_ostride[d]*(from_coor[d]%f_rdimensions[d]);
      int from_lane = 0; for(int d=0;d<nd;d++) from_lane+=f_istride[d]*(from_coor[d]/f_rdimensions[d]);
      int to_oidx   = 0; for(int d=0;d<nd;d++) to_oidx+=t_ostride[d]*(to_coor[d]%t_rdimensions[d]);
      int to_lane   = 0; for(int d=0;d<nd;d++) to_lane+=t_istride[d]*(to_coor[d]/t_rdimensions[d]);
      const vector_type* from = (const vector_type *)&from_v[from_oidx];
      vector_type* to = (vector_type *)&to_v[to_oidx];
@@ -750,56 +804,146 @@ void localCopyRegion(const Lattice<vobj> &From,Lattice<vobj> & To,Coordinate Fro
 	stmp = getlane(from[w], from_lane);
 	putlane(to[w], stmp, to_lane);
      }
    });
  acceleratorFreeDevice(table_d);    
  free(table);
 #else  
  Coordinate ldf = Fg->_ldimensions;
  Coordinate rdf = Fg->_rdimensions;
  Coordinate isf = Fg->_istride;
  Coordinate osf = Fg->_ostride;
  Coordinate rdt = Tg->_rdimensions;
  Coordinate ist = Tg->_istride;
  Coordinate ost = Tg->_ostride;
  autoView( t_v , To, CpuWrite);
  autoView( f_v , From, CpuRead);
  thread_for(idx,Fg->lSites(),{
    sobj s;
    Coordinate Fcoor(nd);
    Coordinate Tcoor(nd);
    Lexicographic::CoorFromIndex(Fcoor,idx,ldf);
    int in_region=1;
    for(int d=0;d<nd;d++){
      if ( (Fcoor[d] < FromLowerLeft[d]) || (Fcoor[d]>=FromLowerLeft[d]+RegionSize[d]) ){ 
 	in_region=0;
      }
      Tcoor[d] = ToLowerLeft[d]+ Fcoor[d]-FromLowerLeft[d];
    }
    if (in_region) {
 #if 0      
      Integer idx_f = 0; for(int d=0;d<nd;d++) idx_f+=isf[d]*(Fcoor[d]/rdf[d]); // inner index from
      Integer idx_t = 0; for(int d=0;d<nd;d++) idx_t+=ist[d]*(Tcoor[d]/rdt[d]); // inner index to
      Integer odx_f = 0; for(int d=0;d<nd;d++) odx_f+=osf[d]*(Fcoor[d]%rdf[d]); // outer index from
      Integer odx_t = 0; for(int d=0;d<nd;d++) odx_t+=ost[d]*(Tcoor[d]%rdt[d]); // outer index to
      scalar_type * fp = (scalar_type *)&f_v[odx_f];
      scalar_type * tp = (scalar_type *)&t_v[odx_t];
      for(int w=0;w<words;w++){
 	tp[w].putlane(fp[w].getlane(idx_f),idx_t);
      }
 #else
    peekLocalSite(s,f_v,Fcoor);
    pokeLocalSite(s,t_v,Tcoor);
 #endif
    }
  });
 #endif
 }
 template<class vobj>
 void InsertSliceFast(const Lattice<vobj> &From,Lattice<vobj> & To,int slice, int orthog)
 {
  typedef typename vobj::scalar_object sobj;
  typedef typename vobj::scalar_type scalar_type;
  typedef typename vobj::vector_type vector_type;
  const int words=sizeof(vobj)/sizeof(vector_type);
  //////////////////////////////////////////////////////////////////////////////////////////
  // checks should guarantee that the operations are local
  //////////////////////////////////////////////////////////////////////////////////////////
  GridBase *Fg = From.Grid();
  GridBase *Tg = To.Grid();
  assert(!Fg->_isCheckerBoarded);
  assert(!Tg->_isCheckerBoarded);
  int Nsimd = Fg->Nsimd();
  int nF = Fg->_ndimension;
  int nT = Tg->_ndimension;
  assert(nF+1 == nT);
  ///////////////////////////////////////////////////////////
  // do the index calc on the GPU
  ///////////////////////////////////////////////////////////
  Coordinate f_ostride = Fg->_ostride;
  Coordinate f_istride = Fg->_istride;
  Coordinate f_rdimensions = Fg->_rdimensions;
  Coordinate t_ostride = Tg->_ostride;
  Coordinate t_istride = Tg->_istride;
  Coordinate t_rdimensions = Tg->_rdimensions;
  Coordinate RegionSize = Fg->_ldimensions;
  size_t nsite = 1;
  for(int i=0;i<nF;i++) nsite *= RegionSize[i]; // whole volume of lower dim grid
  typedef typename vobj::vector_type vector_type;
  typedef typename vobj::scalar_type scalar_type;
  autoView(from_v,From,AcceleratorRead);
  autoView(to_v,To,AcceleratorWrite);
  accelerator_for(idx,nsite,1,{
      Coordinate from_coor(nF), to_coor(nT);
      Lexicographic::CoorFromIndex(from_coor,idx,RegionSize);
      int j=0;
      for(int i=0;i<nT;i++){
 	if ( i!=orthog ) { 
 	  to_coor[i] = from_coor[j];
 	  j++;
 	} else {
 	  to_coor[i] = slice;
 	}
      }
      int from_oidx = 0; for(int d=0;d<nF;d++) from_oidx+=f_ostride[d]*(from_coor[d]%f_rdimensions[d]);
      int from_lane = 0; for(int d=0;d<nF;d++) from_lane+=f_istride[d]*(from_coor[d]/f_rdimensions[d]);
      int to_oidx   = 0; for(int d=0;d<nT;d++) to_oidx+=t_ostride[d]*(to_coor[d]%t_rdimensions[d]);
      int to_lane   = 0; for(int d=0;d<nT;d++) to_lane+=t_istride[d]*(to_coor[d]/t_rdimensions[d]);
      const vector_type* from = (const vector_type *)&from_v[from_oidx];
      vector_type* to = (vector_type *)&to_v[to_oidx];
      scalar_type stmp;
      for(int w=0;w<words;w++){
 	stmp = getlane(from[w], from_lane);
 	putlane(to[w], stmp, to_lane);
      }
  });
 }
 template<class vobj>
 void ExtractSliceFast(Lattice<vobj> &To,const Lattice<vobj> & From,int slice, int orthog)
 {
  typedef typename vobj::scalar_object sobj;
  typedef typename vobj::scalar_type scalar_type;
  typedef typename vobj::vector_type vector_type;
  const int words=sizeof(vobj)/sizeof(vector_type);
  //////////////////////////////////////////////////////////////////////////////////////////
  // checks should guarantee that the operations are local
  //////////////////////////////////////////////////////////////////////////////////////////
  GridBase *Fg = From.Grid();
  GridBase *Tg = To.Grid();
  assert(!Fg->_isCheckerBoarded);
  assert(!Tg->_isCheckerBoarded);
  int Nsimd = Fg->Nsimd();
  int nF = Fg->_ndimension;
  int nT = Tg->_ndimension;
  assert(nT+1 == nF);
  ///////////////////////////////////////////////////////////
  // do the index calc on the GPU
  ///////////////////////////////////////////////////////////
  Coordinate f_ostride = Fg->_ostride;
  Coordinate f_istride = Fg->_istride;
  Coordinate f_rdimensions = Fg->_rdimensions;
  Coordinate t_ostride = Tg->_ostride;
  Coordinate t_istride = Tg->_istride;
  Coordinate t_rdimensions = Tg->_rdimensions;
  Coordinate RegionSize = Tg->_ldimensions;
  size_t nsite = 1;
  for(int i=0;i<nT;i++) nsite *= RegionSize[i]; // whole volume of lower dim grid
  typedef typename vobj::vector_type vector_type;
  typedef typename vobj::scalar_type scalar_type;
  autoView(from_v,From,AcceleratorRead);
  autoView(to_v,To,AcceleratorWrite);
  accelerator_for(idx,nsite,1,{
      Coordinate from_coor(nF), to_coor(nT);
      Lexicographic::CoorFromIndex(to_coor,idx,RegionSize);
      int j=0;
      for(int i=0;i<nF;i++){
 	if ( i!=orthog ) { 
 	  from_coor[i] = to_coor[j];
 	  j++;
 	} else {
 	  from_coor[i] = slice;
 	}
      }
      int from_oidx = 0; for(int d=0;d<nF;d++) from_oidx+=f_ostride[d]*(from_coor[d]%f_rdimensions[d]);
      int from_lane = 0; for(int d=0;d<nF;d++) from_lane+=f_istride[d]*(from_coor[d]/f_rdimensions[d]);
      int to_oidx   = 0; for(int d=0;d<nT;d++) to_oidx+=t_ostride[d]*(to_coor[d]%t_rdimensions[d]);
      int to_lane   = 0; for(int d=0;d<nT;d++) to_lane+=t_istride[d]*(to_coor[d]/t_rdimensions[d]);
      const vector_type* from = (const vector_type *)&from_v[from_oidx];
      vector_type* to = (vector_type *)&to_v[to_oidx];
      scalar_type stmp;
      for(int w=0;w<words;w++){
 	stmp = getlane(from[w], from_lane);
 	putlane(to[w], stmp, to_lane);
      }
  });
 }
 template<class vobj>
 void InsertSlice(const Lattice<vobj> &lowDim,Lattice<vobj> & higherDim,int slice, int orthog)
@@ -889,9 +1033,7 @@ void ExtractSlice(Lattice<vobj> &lowDim,const Lattice<vobj> & higherDim,int slic
 }
-
+//Can I implement with local copyregion??
 //Insert subvolume orthogonal to direction 'orthog' with slice index 'slice_lo' from 'lowDim' onto slice index 'slice_hi' of higherDim
 //The local dimensions of both 'lowDim' and 'higherDim' orthogonal to 'orthog' should be the same
 template<class vobj>
 void InsertSliceLocal(const Lattice<vobj> &lowDim, Lattice<vobj> & higherDim,int slice_lo,int slice_hi, int orthog)
 {
@@ -912,121 +1054,18 @@ void InsertSliceLocal(const Lattice<vobj> &lowDim, Lattice<vobj> & higherDim,int
      assert(lg->_ldimensions[d] == hg->_ldimensions[d]);
    }
  }
-
+  Coordinate sz = lg->_ldimensions;
-#if 1
+  sz[orthog]=1;
-  size_t nsite = lg->lSites()/lg->LocalDimensions()[orthog];
+  Coordinate f_ll(nl,0); f_ll[orthog]=slice_lo;
-  size_t tbytes = 4*nsite*sizeof(int);
+  Coordinate t_ll(nh,0); t_ll[orthog]=slice_hi;
-  int *table = (int*)malloc(tbytes);
+  localCopyRegion(lowDim,higherDim,f_ll,t_ll,sz);
  thread_for(idx,nsite,{
    Coordinate lcoor(nl);
    Coordinate hcoor(nh);
    lcoor[orthog] = slice_lo;
    hcoor[orthog] = slice_hi;
    size_t rem = idx;
    for(int mu=0;mu<nl;mu++){
      if(mu != orthog){
 	int xmu = rem % lg->LocalDimensions()[mu];  rem /= lg->LocalDimensions()[mu];
 	lcoor[mu] = hcoor[mu] = xmu;
      }
    }
    int loidx = lg->oIndex(lcoor);
    int liidx = lg->iIndex(lcoor);
    int hoidx = hg->oIndex(hcoor);
    int hiidx = hg->iIndex(hcoor);
    int* tt = table + 4*idx;
    tt[0] = loidx;
    tt[1] = liidx;
    tt[2] = hoidx;
    tt[3] = hiidx;
    });
  int* table_d = (int*)acceleratorAllocDevice(tbytes);
  acceleratorCopyToDevice(table,table_d,tbytes);
  typedef typename vobj::vector_type vector_type;
  typedef typename vobj::scalar_type scalar_type;
  autoView(lowDim_v,lowDim,AcceleratorRead);
  autoView(higherDim_v,higherDim,AcceleratorWrite);
  accelerator_for(idx,nsite,1,{
      static const int words=sizeof(vobj)/sizeof(vector_type);
      int* tt = table_d + 4*idx;
      int from_oidx = *tt++;
      int from_lane = *tt++;
      int to_oidx = *tt++;
      int to_lane = *tt;
      const vector_type* from = (const vector_type *)&lowDim_v[from_oidx];
      vector_type* to = (vector_type *)&higherDim_v[to_oidx];
      scalar_type stmp;
      for(int w=0;w<words;w++){
 	stmp = getlane(from[w], from_lane);
 	putlane(to[w], stmp, to_lane);
      }
    });
  acceleratorFreeDevice(table_d);    
  free(table);
 #else
  // the above should guarantee that the operations are local
  autoView(lowDimv,lowDim,CpuRead);
  autoView(higherDimv,higherDim,CpuWrite);
  thread_for(idx,lg->lSites(),{
    sobj s;
    Coordinate lcoor(nl);
    Coordinate hcoor(nh);
    lg->LocalIndexToLocalCoor(idx,lcoor);
    if( lcoor[orthog] == slice_lo ) { 
      hcoor=lcoor;
      hcoor[orthog] = slice_hi;
      peekLocalSite(s,lowDimv,lcoor);
      pokeLocalSite(s,higherDimv,hcoor);
    }
  });
 #endif
 }
 template<class vobj>
 void ExtractSliceLocal(Lattice<vobj> &lowDim,const Lattice<vobj> & higherDim,int slice_lo,int slice_hi, int orthog)
 {
-  typedef typename vobj::scalar_object sobj;
+  InsertSliceLocal(higherDim,lowDim,slice_hi,slice_lo,orthog);
  GridBase *lg = lowDim.Grid();
  GridBase *hg = higherDim.Grid();
  int nl = lg->_ndimension;
  int nh = hg->_ndimension;
  assert(nl == nh);
  assert(orthog<nh);
  assert(orthog>=0);
  for(int d=0;d<nh;d++){
    if ( d!=orthog ) {
    assert(lg->_processors[d]  == hg->_processors[d]);
    assert(lg->_ldimensions[d] == hg->_ldimensions[d]);
  }
  }
  // the above should guarantee that the operations are local
  autoView(lowDimv,lowDim,CpuWrite);
  autoView(higherDimv,higherDim,CpuRead);
  thread_for(idx,lg->lSites(),{
    sobj s;
    Coordinate lcoor(nl);
    Coordinate hcoor(nh);
    lg->LocalIndexToLocalCoor(idx,lcoor);
    if( lcoor[orthog] == slice_lo ) { 
      hcoor=lcoor;
      hcoor[orthog] = slice_hi;
      peekLocalSite(s,higherDimv,hcoor);
      pokeLocalSite(s,lowDimv,lcoor);
    }
  });
 }
@@ -1052,7 +1091,7 @@ void Replicate(const Lattice<vobj> &coarse,Lattice<vobj> & fine)
  Coordinate fcoor(nd);
  Coordinate ccoor(nd);
-  for(int g=0;g<fg->gSites();g++){
+  for(int64_t g=0;g<fg->gSites();g++){
    fg->GlobalIndexToGlobalCoor(g,fcoor);
    for(int d=0;d<nd;d++){
@@ -1738,5 +1777,35 @@ void Grid_unsplit(std::vector<Lattice<Vobj> > & full,Lattice<Vobj>   & split)
  }
 }
 //////////////////////////////////////////////////////
 // Faster but less accurate blockProject
 //////////////////////////////////////////////////////
 template<class vobj,class CComplex,int nbasis,class VLattice>
 inline void blockProjectFast(Lattice<iVector<CComplex,nbasis > > &coarseData,
 			     const             Lattice<vobj>   &fineData,
 			     const VLattice &Basis)
 {
  GridBase * fine  = fineData.Grid();
  GridBase * coarse= coarseData.Grid();
  Lattice<iScalar<CComplex> > ip(coarse);
  autoView( coarseData_ , coarseData, AcceleratorWrite);
  autoView( ip_         , ip,         AcceleratorWrite);
  RealD t_IP=0;
  RealD t_co=0;
  for(int v=0;v<nbasis;v++) {
    t_IP-=usecond();
    blockInnerProductD(ip,Basis[v],fineData); 
    t_IP+=usecond();
    t_co-=usecond();
    accelerator_for( sc, coarse->oSites(), vobj::Nsimd(), {
 	convertType(coarseData_[sc](v),ip_[sc]);
      });
    t_co+=usecond();
  }
 }
 NAMESPACE_END(Grid);
--- a/Grid/lattice/PaddedCell.h
+++ b/Grid/lattice/PaddedCell.h
@@ -45,6 +45,188 @@ struct CshiftImplGauge: public CshiftImplBase<typename Gimpl::GaugeLinkField::ve
  typename Gimpl::GaugeLinkField Cshift(const typename Gimpl::GaugeLinkField &in, int dir, int shift) const override{ return Gimpl::CshiftLink(in,dir,shift); }
 };  
 /*
 *
 * TODO: 
 *  -- address elementsof vobj via thread block in Scatter/Gather
 *  -- overlap comms with motion in Face_exchange
 *
 */
 template<class vobj> inline void ScatterSlice(const cshiftVector<vobj> &buf,
 					      Lattice<vobj> &lat,
 					      int x,
 					      int dim,
 					      int offset=0)
 {
  const int Nsimd=vobj::Nsimd();
  typedef typename vobj::scalar_object sobj;
  typedef typename vobj::scalar_type scalar_type;
  typedef typename vobj::vector_type vector_type;
  GridBase *grid = lat.Grid();
  Coordinate simd = grid->_simd_layout;
  int Nd          = grid->Nd();
  int block       = grid->_slice_block[dim];
  int stride      = grid->_slice_stride[dim];
  int nblock      = grid->_slice_nblock[dim];
  int rd          = grid->_rdimensions[dim];
  int ox = x%rd;
  int ix = x/rd;
  int isites = 1; for(int d=0;d<Nd;d++) if( d!=dim) isites*=simd[d];
  Coordinate rsimd= simd;  rsimd[dim]=1; // maybe reduce Nsimd
  int rNsimd = 1; for(int d=0;d<Nd;d++) rNsimd*=rsimd[d];
  int rNsimda= Nsimd/simd[dim]; // should be equal
  assert(rNsimda==rNsimd);
  int face_ovol=block*nblock;
  //  assert(buf.size()==face_ovol*rNsimd);
  /*This will work GPU ONLY unless rNsimd is put in the lexico index*/
  //Let's make it work on GPU and then make a special accelerator_for that
  //doesn't hide the SIMD direction and keeps explicit in the threadIdx
  //for cross platform
  // FIXME -- can put internal indices into thread loop
  auto buf_p = & buf[0];
  autoView(lat_v, lat, AcceleratorWrite);
  accelerator_for(ss, face_ovol/simd[dim],Nsimd,{
    // scalar layout won't coalesce
 #ifdef GRID_SIMT
      {
 	int blane=acceleratorSIMTlane(Nsimd); // buffer lane
 #else
      for(int blane=0;blane<Nsimd;blane++) {
 #endif
 	int olane=blane%rNsimd;               // reduced lattice lane
 	int obit =blane/rNsimd;
 	///////////////////////////////////////////////////////////////
 	// osite -- potentially one bit from simd in the buffer: (ss<<1)|obit
 	///////////////////////////////////////////////////////////////
 	int ssp = ss*simd[dim]+obit;
 	int b    = ssp%block;
 	int n    = ssp/block;
 	int osite= b+n*stride + ox*block;
 	////////////////////////////////////////////
 	// isite -- map lane within buffer to lane within lattice
 	////////////////////////////////////////////
 	Coordinate icoor;
 	int lane;
 	Lexicographic::CoorFromIndex(icoor,olane,rsimd);
 	icoor[dim]=ix;
 	Lexicographic::IndexFromCoor(icoor,lane,simd);
 	///////////////////////////////////////////
 	// Transfer into lattice - will coalesce
 	///////////////////////////////////////////
 	//	sobj obj = extractLane(blane,buf_p[ss+offset]);
 	//	insertLane(lane,lat_v[osite],obj);
 	const int words=sizeof(vobj)/sizeof(vector_type);
 	vector_type * from = (vector_type *)&buf_p[ss+offset];
 	vector_type * to   = (vector_type *)&lat_v[osite];
 	scalar_type stmp;
 	for(int w=0;w<words;w++){
 	  stmp = getlane(from[w], blane);
 	  putlane(to[w], stmp, lane);
 	}
      }
  });
 }
 template<class vobj> inline void GatherSlice(cshiftVector<vobj> &buf,
 					     const Lattice<vobj> &lat,
 					     int x,
 					     int dim,
 					     int offset=0)
 {
  const int Nsimd=vobj::Nsimd();
  typedef typename vobj::scalar_object sobj;
  typedef typename vobj::scalar_type scalar_type;
  typedef typename vobj::vector_type vector_type;
  autoView(lat_v, lat, AcceleratorRead);
  GridBase *grid = lat.Grid();
  Coordinate simd = grid->_simd_layout;
  int Nd          = grid->Nd();
  int block       = grid->_slice_block[dim];
  int stride      = grid->_slice_stride[dim];
  int nblock      = grid->_slice_nblock[dim];
  int rd          = grid->_rdimensions[dim];
  int ox = x%rd;
  int ix = x/rd;
  int isites = 1; for(int d=0;d<Nd;d++) if( d!=dim) isites*=simd[d];
  Coordinate rsimd= simd;  rsimd[dim]=1; // maybe reduce Nsimd
  int rNsimd = 1; for(int d=0;d<Nd;d++) rNsimd*=rsimd[d];
  int face_ovol=block*nblock;
  //  assert(buf.size()==face_ovol*rNsimd);
  /*This will work GPU ONLY unless rNsimd is put in the lexico index*/
  //Let's make it work on GPU and then make a special accelerator_for that
  //doesn't hide the SIMD direction and keeps explicit in the threadIdx
  //for cross platform
  //For CPU perhaps just run a loop over Nsimd
  auto buf_p = & buf[0];
  accelerator_for(ss, face_ovol/simd[dim],Nsimd,{
    // scalar layout won't coalesce
 #ifdef GRID_SIMT
      {
 	int blane=acceleratorSIMTlane(Nsimd); // buffer lane
 #else
      for(int blane=0;blane<Nsimd;blane++) {
 #endif
 	int olane=blane%rNsimd;               // reduced lattice lane
 	int obit =blane/rNsimd;
 	////////////////////////////////////////////
 	// osite
 	////////////////////////////////////////////
 	int ssp = ss*simd[dim]+obit;
 	int b    = ssp%block;
 	int n    = ssp/block;
 	int osite= b+n*stride + ox*block;
 	////////////////////////////////////////////
 	// isite -- map lane within buffer to lane within lattice
 	////////////////////////////////////////////
 	Coordinate icoor;
 	int lane;
 	Lexicographic::CoorFromIndex(icoor,olane,rsimd);
 	icoor[dim]=ix;
 	Lexicographic::IndexFromCoor(icoor,lane,simd);
 	///////////////////////////////////////////
 	// Take out of lattice
 	///////////////////////////////////////////
 	//	sobj obj = extractLane(lane,lat_v[osite]);
 	//	insertLane(blane,buf_p[ss+offset],obj);
 	const int words=sizeof(vobj)/sizeof(vector_type);
 	vector_type * to    = (vector_type *)&buf_p[ss+offset];
 	vector_type * from  = (vector_type *)&lat_v[osite];
 	scalar_type stmp;
 	for(int w=0;w<words;w++){
 	  stmp = getlane(from[w], lane);
 	  putlane(to[w], stmp, blane);
 	}
      }
  });
 }
 class PaddedCell {
 public:
  GridCartesian * unpadded_grid;
@@ -63,14 +245,18 @@ public:
    dims=_grid->Nd();
    AllocateGrids();
    Coordinate local     =unpadded_grid->LocalDimensions();
    Coordinate procs     =unpadded_grid->ProcessorGrid();
    for(int d=0;d<dims;d++){
-      assert(local[d]>=depth);
+      if ( procs[d] > 1 ) assert(local[d]>=depth);
    }
  }
  void DeleteGrids(void)
  {
    Coordinate processors=unpadded_grid->_processors;
    for(int d=0;d<grids.size();d++){
-      delete grids[d];
+      if ( processors[d] > 1 ) { 
 	delete grids[d];
      }
    }
    grids.resize(0);
  };
@@ -81,27 +267,36 @@ public:
    Coordinate processors=unpadded_grid->_processors;
    Coordinate plocal    =unpadded_grid->LocalDimensions();
    Coordinate global(dims);
-
+    GridCartesian *old_grid = unpadded_grid;
    // expand up one dim at a time
    for(int d=0;d<dims;d++){
-      plocal[d] += 2*depth; 
+      if ( processors[d] > 1 ) { 
 	plocal[d] += 2*depth; 
-      for(int d=0;d<dims;d++){
+	for(int d=0;d<dims;d++){
-	global[d] = plocal[d]*processors[d];
+	  global[d] = plocal[d]*processors[d];
 	}
 	old_grid = new GridCartesian(global,simd,processors);
      }
-
+      grids.push_back(old_grid);
      grids.push_back(new GridCartesian(global,simd,processors));
    }
  };
  template<class vobj>
  inline Lattice<vobj> Extract(const Lattice<vobj> &in) const
  {
    Coordinate processors=unpadded_grid->_processors;
    Lattice<vobj> out(unpadded_grid);
    Coordinate local     =unpadded_grid->LocalDimensions();
-    Coordinate fll(dims,depth); // depends on the MPI spread
+    // depends on the MPI spread      
    Coordinate fll(dims,depth);
    Coordinate tll(dims,0); // depends on the MPI spread
    for(int d=0;d<dims;d++){
      if( processors[d]==1 ) fll[d]=0;
    }
    localCopyRegion(in,out,fll,tll,local);
    return out;
  }
@@ -116,10 +311,22 @@ public:
    }
    return tmp;
  }
  template<class vobj>
  inline Lattice<vobj> ExchangePeriodic(const Lattice<vobj> &in) const
  {
    GridBase *old_grid = in.Grid();
    int dims = old_grid->Nd();
    Lattice<vobj> tmp = in;
    for(int d=0;d<dims;d++){
      tmp = ExpandPeriodic(d,tmp); // rvalue && assignment
    }
    return tmp;
  }
  // expand up one dim at a time
  template<class vobj>
  inline Lattice<vobj> Expand(int dim, const Lattice<vobj> &in, const CshiftImplBase<vobj> &cshift = CshiftImplDefault<vobj>()) const
  {
    Coordinate processors=unpadded_grid->_processors;
    GridBase *old_grid = in.Grid();
    GridCartesian *new_grid = grids[dim];//These are new grids
    Lattice<vobj>  padded(new_grid);
@@ -129,46 +336,236 @@ public:
    if(dim==0) conformable(old_grid,unpadded_grid);
    else       conformable(old_grid,grids[dim-1]);
    std::cout << " dim "<<dim<<" local "<<local << " padding to "<<plocal<<std::endl;
    double tins=0, tshift=0;
-    // Middle bit
+    int islocal = 0 ;
-    double t = usecond();
+    if ( processors[dim] == 1 ) islocal = 1;
-    for(int x=0;x<local[dim];x++){
+
-      InsertSliceLocal(in,padded,x,depth+x,dim);
+    if ( islocal ) {
      // replace with a copy and maybe grid swizzle
      // return in;??
      double t = usecond();
      padded = in;
      tins += usecond() - t;
    } else {
      //////////////////////////////////////////////
      // Replace sequence with
      // ---------------------
      // (i) Gather high face(s); start comms
      // (ii) Gather low  face(s); start comms
      // (iii) Copy middle bit with localCopyRegion
      // (iv) Complete high face(s), insert slice(s)
      // (iv) Complete low  face(s), insert slice(s)
      //////////////////////////////////////////////
      // Middle bit
      double t = usecond();
      for(int x=0;x<local[dim];x++){
 	InsertSliceLocal(in,padded,x,depth+x,dim);
      }
      tins += usecond() - t;
      // High bit
      t = usecond();
      shifted = cshift.Cshift(in,dim,depth);
      tshift += usecond() - t;
      t=usecond();
      for(int x=0;x<depth;x++){
 	InsertSliceLocal(shifted,padded,local[dim]-depth+x,depth+local[dim]+x,dim);
      }
      tins += usecond() - t;
      // Low bit
      t = usecond();
      shifted = cshift.Cshift(in,dim,-depth);
      tshift += usecond() - t;
      t = usecond();
      for(int x=0;x<depth;x++){
 	InsertSliceLocal(shifted,padded,x,x,dim);
      }
      tins += usecond() - t;
    }
    tins += usecond() - t;
    // High bit
    t = usecond();
    shifted = cshift.Cshift(in,dim,depth);
    tshift += usecond() - t;
    t=usecond();
    for(int x=0;x<depth;x++){
      InsertSliceLocal(shifted,padded,local[dim]-depth+x,depth+local[dim]+x,dim);
    }
    tins += usecond() - t;
    // Low bit
    t = usecond();
    shifted = cshift.Cshift(in,dim,-depth);
    tshift += usecond() - t;
    t = usecond();
    for(int x=0;x<depth;x++){
      InsertSliceLocal(shifted,padded,x,x,dim);
    }
    tins += usecond() - t;
    std::cout << GridLogPerformance << "PaddedCell::Expand timings: cshift:" << tshift/1000 << "ms, insert-slice:" << tins/1000 << "ms" << std::endl;
    return padded;
  }
  template<class vobj>
  inline Lattice<vobj> ExpandPeriodic(int dim, const Lattice<vobj> &in) const
  {
    Coordinate processors=unpadded_grid->_processors;
    GridBase *old_grid = in.Grid();
    GridCartesian *new_grid = grids[dim];//These are new grids
    Lattice<vobj>  padded(new_grid);
    //    Lattice<vobj> shifted(old_grid);    
    Coordinate local     =old_grid->LocalDimensions();
    Coordinate plocal    =new_grid->LocalDimensions();
    if(dim==0) conformable(old_grid,unpadded_grid);
    else       conformable(old_grid,grids[dim-1]);
    //    std::cout << " dim "<<dim<<" local "<<local << " padding to "<<plocal<<std::endl;
    double tins=0, tshift=0;
    int islocal = 0 ;
    if ( processors[dim] == 1 ) islocal = 1;
    if ( islocal ) {
      padded=in; // slightly different interface could avoid a copy operation
    } else {
      Face_exchange(in,padded,dim,depth);
      return padded;
    }
    return padded;
  }
  template<class vobj>
  void Face_exchange(const Lattice<vobj> &from,
 		     Lattice<vobj> &to,
 		     int dimension,int depth) const
  {
    typedef typename vobj::vector_type vector_type;
    typedef typename vobj::scalar_type scalar_type;
    typedef typename vobj::scalar_object sobj;
    RealD t_gather=0.0;
    RealD t_scatter=0.0;
    RealD t_comms=0.0;
    RealD t_copy=0.0;
    //    std::cout << GridLogMessage << "dimension " <<dimension<<std::endl;
    //    DumpSliceNorm(std::string("Face_exchange from"),from,dimension);
    GridBase *grid=from.Grid();
    GridBase *new_grid=to.Grid();
    Coordinate lds = from.Grid()->_ldimensions;
    Coordinate nlds=   to.Grid()->_ldimensions;
    Coordinate simd= from.Grid()->_simd_layout;
    int ld    = lds[dimension];
    int nld   = to.Grid()->_ldimensions[dimension];
    const int Nsimd = vobj::Nsimd();
    assert(depth<=lds[dimension]); // A must be on neighbouring node
    assert(depth>0);   // A caller bug if zero
    assert(ld+2*depth==nld);
    ////////////////////////////////////////////////////////////////////////////
    // Face size and byte calculations
    ////////////////////////////////////////////////////////////////////////////
    int buffer_size = 1;
    for(int d=0;d<lds.size();d++){
      if ( d!= dimension) buffer_size=buffer_size*lds[d];
    }
    buffer_size = buffer_size  / Nsimd;
    int rNsimd = Nsimd / simd[dimension];
    assert( buffer_size == from.Grid()->_slice_nblock[dimension]*from.Grid()->_slice_block[dimension] / simd[dimension]);
    static cshiftVector<vobj> send_buf; 
    static cshiftVector<vobj> recv_buf;
    send_buf.resize(buffer_size*2*depth);    
    recv_buf.resize(buffer_size*2*depth);
    std::vector<CommsRequest_t> fwd_req;   
    std::vector<CommsRequest_t> bwd_req;   
    int words = buffer_size;
    int bytes = words * sizeof(vobj);
    ////////////////////////////////////////////////////////////////////////////
    // Communication coords
    ////////////////////////////////////////////////////////////////////////////
    int comm_proc = 1;
    int xmit_to_rank;
    int recv_from_rank;
    grid->ShiftedRanks(dimension,comm_proc,xmit_to_rank,recv_from_rank);
    ////////////////////////////////////////////////////////////////////////////
    // Gather all surface terms up to depth "d"
    ////////////////////////////////////////////////////////////////////////////
    RealD t;
    RealD t_tot=-usecond();
    int plane=0;
    for ( int d=0;d < depth ; d ++ ) {
      int tag = d*1024 + dimension*2+0;
      t=usecond();
      GatherSlice(send_buf,from,d,dimension,plane*buffer_size); plane++;
      t_gather+=usecond()-t;
      t=usecond();
      grid->SendToRecvFromBegin(fwd_req,
 				(void *)&send_buf[d*buffer_size], xmit_to_rank,
 				(void *)&recv_buf[d*buffer_size], recv_from_rank, bytes, tag);
      t_comms+=usecond()-t;
     }
    for ( int d=0;d < depth ; d ++ ) {
      int tag = d*1024 + dimension*2+1;
      t=usecond();
      GatherSlice(send_buf,from,ld-depth+d,dimension,plane*buffer_size); plane++;
      t_gather+= usecond() - t;
      t=usecond();
      grid->SendToRecvFromBegin(bwd_req,
 				(void *)&send_buf[(d+depth)*buffer_size], recv_from_rank,
 				(void *)&recv_buf[(d+depth)*buffer_size], xmit_to_rank, bytes,tag);
      t_comms+=usecond()-t;
    }
    ////////////////////////////////////////////////////////////////////////////
    // Copy interior -- overlap this with comms
    ////////////////////////////////////////////////////////////////////////////
    int Nd = new_grid->Nd();
    Coordinate LL(Nd,0);
    Coordinate sz = grid->_ldimensions;
    Coordinate toLL(Nd,0);
    toLL[dimension]=depth;
    t=usecond();
    localCopyRegion(from,to,LL,toLL,sz);
    t_copy= usecond() - t;
    ////////////////////////////////////////////////////////////////////////////
    // Scatter all faces
    ////////////////////////////////////////////////////////////////////////////
    plane=0;
    t=usecond();
    grid->CommsComplete(fwd_req);
    t_comms+= usecond() - t;
    t=usecond();
    for ( int d=0;d < depth ; d ++ ) {
      ScatterSlice(recv_buf,to,nld-depth+d,dimension,plane*buffer_size); plane++;
    }
    t_scatter= usecond() - t;
    t=usecond();
    grid->CommsComplete(bwd_req);
    t_comms+= usecond() - t;
    t=usecond();
    for ( int d=0;d < depth ; d ++ ) {
      ScatterSlice(recv_buf,to,d,dimension,plane*buffer_size); plane++;
    }
    t_scatter+= usecond() - t;
    t_tot+=usecond();
    std::cout << GridLogPerformance << "PaddedCell::Expand new timings: gather :" << t_gather/1000  << "ms"<<std::endl;
    std::cout << GridLogPerformance << "PaddedCell::Expand new timings: scatter:" << t_scatter/1000   << "ms"<<std::endl;
    std::cout << GridLogPerformance << "PaddedCell::Expand new timings: copy   :" << t_copy/1000      << "ms"<<std::endl;
    std::cout << GridLogPerformance << "PaddedCell::Expand new timings: comms  :" << t_comms/1000     << "ms"<<std::endl;
    std::cout << GridLogPerformance << "PaddedCell::Expand new timings: total  :" << t_tot/1000     << "ms"<<std::endl;
    std::cout << GridLogPerformance << "PaddedCell::Expand new timings: gather :" << depth*4.0*bytes/t_gather << "MB/s"<<std::endl;
    std::cout << GridLogPerformance << "PaddedCell::Expand new timings: scatter:" << depth*4.0*bytes/t_scatter<< "MB/s"<<std::endl;
    std::cout << GridLogPerformance << "PaddedCell::Expand new timings: comms  :" << (RealD)4.0*bytes/t_comms   << "MB/s"<<std::endl;
    std::cout << GridLogPerformance << "PaddedCell::Expand new timings: face bytes  :" << depth*bytes/1e6 << "MB"<<std::endl;
  }
 };
 NAMESPACE_END(Grid);
--- a/Grid/parallelIO/BinaryIO.h
+++ b/Grid/parallelIO/BinaryIO.h
@@ -165,7 +165,7 @@ class BinaryIO {
 	 * FIXME -- 128^3 x 256 x 16 will overflow.
 	 */
-	int global_site;
+	int64_t global_site;
 	Lexicographic::CoorFromIndex(coor,local_site,local_vol);
@@ -175,8 +175,8 @@ class BinaryIO {
 	Lexicographic::IndexFromCoor(coor,global_site,global_vol);
-	uint32_t gsite29   = global_site%29;
+	uint64_t gsite29   = global_site%29;
-	uint32_t gsite31   = global_site%31;
+	uint64_t gsite31   = global_site%31;
 	site_crc = crc32(0,(unsigned char *)site_buf,sizeof(fobj));
 	//	std::cout << "Site "<<local_site << " crc "<<std::hex<<site_crc<<std::dec<<std::endl;
@@ -545,7 +545,9 @@ class BinaryIO {
 				       const std::string &format,
 				       uint32_t &nersc_csum,
 				       uint32_t &scidac_csuma,
-				       uint32_t &scidac_csumb)
+				       uint32_t &scidac_csumb,
 				       int control=BINARYIO_LEXICOGRAPHIC
 				       )
  {
    typedef typename vobj::scalar_object sobj;
    typedef typename vobj::Realified::scalar_type word;    word w=0;
@@ -556,7 +558,7 @@ class BinaryIO {
    std::vector<sobj> scalardata(lsites); 
    std::vector<fobj>     iodata(lsites); // Munge, checksum, byte order in here
-    IOobject(w,grid,iodata,file,offset,format,BINARYIO_READ|BINARYIO_LEXICOGRAPHIC,
+    IOobject(w,grid,iodata,file,offset,format,BINARYIO_READ|control,
 	     nersc_csum,scidac_csuma,scidac_csumb);
    GridStopWatch timer; 
@@ -582,7 +584,8 @@ class BinaryIO {
 					  const std::string &format,
 					  uint32_t &nersc_csum,
 					  uint32_t &scidac_csuma,
-					  uint32_t &scidac_csumb)
+					  uint32_t &scidac_csumb,
 					  int control=BINARYIO_LEXICOGRAPHIC)
  {
    typedef typename vobj::scalar_object sobj;
    typedef typename vobj::Realified::scalar_type word;    word w=0;
@@ -607,7 +610,7 @@ class BinaryIO {
    while (attemptsLeft >= 0)
    {
      grid->Barrier();
-      IOobject(w,grid,iodata,file,offset,format,BINARYIO_WRITE|BINARYIO_LEXICOGRAPHIC,
+      IOobject(w,grid,iodata,file,offset,format,BINARYIO_WRITE|control,
 	             nersc_csum,scidac_csuma,scidac_csumb);
      if (checkWrite)
      {
@@ -617,7 +620,7 @@ class BinaryIO {
        std::cout << GridLogMessage << "writeLatticeObject: read back object" << std::endl;
        grid->Barrier();
-        IOobject(w,grid,ckiodata,file,ckoffset,format,BINARYIO_READ|BINARYIO_LEXICOGRAPHIC,
+        IOobject(w,grid,ckiodata,file,ckoffset,format,BINARYIO_READ|control,
 	               cknersc_csum,ckscidac_csuma,ckscidac_csumb);
        if ((cknersc_csum != nersc_csum) or (ckscidac_csuma != scidac_csuma) or (ckscidac_csumb != scidac_csumb))
        {
--- a/Grid/parallelIO/IldgIO.h
+++ b/Grid/parallelIO/IldgIO.h
@@ -162,8 +162,14 @@ template<class vobj> void ScidacMetaData(Lattice<vobj> & field,
 {
   uint32_t scidac_checksuma = stoull(scidacChecksum_.suma,0,16);
   uint32_t scidac_checksumb = stoull(scidacChecksum_.sumb,0,16);
-   if ( scidac_csuma !=scidac_checksuma) return 0;
+   std::cout << GridLogMessage << " scidacChecksumVerify computed "<<scidac_csuma<<" expected "<<scidac_checksuma <<std::endl;
-   if ( scidac_csumb !=scidac_checksumb) return 0;
+   std::cout << GridLogMessage << " scidacChecksumVerify computed "<<scidac_csumb<<" expected "<<scidac_checksumb <<std::endl;
   if ( scidac_csuma !=scidac_checksuma) {
     return 0;
   };
   if ( scidac_csumb !=scidac_checksumb) {
     return 0;
   };
   return 1;
 }
@@ -206,7 +212,7 @@ class GridLimeReader : public BinaryIO {
  // Read a generic lattice field and verify checksum
  ////////////////////////////////////////////
  template<class vobj>
-  void readLimeLatticeBinaryObject(Lattice<vobj> &field,std::string record_name)
+  void readLimeLatticeBinaryObject(Lattice<vobj> &field,std::string record_name,int control=BINARYIO_LEXICOGRAPHIC)
  {
    typedef typename vobj::scalar_object sobj;
    scidacChecksum scidacChecksum_;
@@ -238,7 +244,7 @@ class GridLimeReader : public BinaryIO {
 	uint64_t offset= ftello(File);
 	//	std::cout << " ReadLatticeObject from offset "<<offset << std::endl;
 	BinarySimpleMunger<sobj,sobj> munge;
-	BinaryIO::readLatticeObject< vobj, sobj >(field, filename, munge, offset, format,nersc_csum,scidac_csuma,scidac_csumb);
+	BinaryIO::readLatticeObject< vobj, sobj >(field, filename, munge, offset, format,nersc_csum,scidac_csuma,scidac_csumb,control);
 	std::cout << GridLogMessage << "SciDAC checksum A " << std::hex << scidac_csuma << std::dec << std::endl;
 	std::cout << GridLogMessage << "SciDAC checksum B " << std::hex << scidac_csumb << std::dec << std::endl;
 	/////////////////////////////////////////////
@@ -408,7 +414,7 @@ class GridLimeWriter : public BinaryIO
  // in communicator used by the field.Grid()
  ////////////////////////////////////////////////////
  template<class vobj>
-  void writeLimeLatticeBinaryObject(Lattice<vobj> &field,std::string record_name)
+  void writeLimeLatticeBinaryObject(Lattice<vobj> &field,std::string record_name,int control=BINARYIO_LEXICOGRAPHIC)
  {
    ////////////////////////////////////////////////////////////////////
    // NB: FILE and iostream are jointly writing disjoint sequences in the
@@ -459,7 +465,7 @@ class GridLimeWriter : public BinaryIO
    ///////////////////////////////////////////
    std::string format = getFormatString<vobj>();
    BinarySimpleMunger<sobj,sobj> munge;
-    BinaryIO::writeLatticeObject<vobj,sobj>(field, filename, munge, offset1, format,nersc_csum,scidac_csuma,scidac_csumb);
+    BinaryIO::writeLatticeObject<vobj,sobj>(field, filename, munge, offset1, format,nersc_csum,scidac_csuma,scidac_csumb,control);
    ///////////////////////////////////////////
    // Wind forward and close the record
@@ -512,7 +518,8 @@ class ScidacWriter : public GridLimeWriter {
  ////////////////////////////////////////////////
  template <class vobj, class userRecord>
  void writeScidacFieldRecord(Lattice<vobj> &field,userRecord _userRecord,
-                              const unsigned int recordScientificPrec = 0) 
+                              const unsigned int recordScientificPrec = 0,
 			      int control=BINARYIO_LEXICOGRAPHIC)
  {
    GridBase * grid = field.Grid();
@@ -534,7 +541,7 @@ class ScidacWriter : public GridLimeWriter {
      writeLimeObject(0,0,_scidacRecord,_scidacRecord.SerialisableClassName(),std::string(SCIDAC_PRIVATE_RECORD_XML));
    }
    // Collective call
-    writeLimeLatticeBinaryObject(field,std::string(ILDG_BINARY_DATA));      // Closes message with checksum
+    writeLimeLatticeBinaryObject(field,std::string(ILDG_BINARY_DATA),control);      // Closes message with checksum
  }
 };
@@ -553,7 +560,8 @@ class ScidacReader : public GridLimeReader {
  // Write generic lattice field in scidac format
  ////////////////////////////////////////////////
  template <class vobj, class userRecord>
-  void readScidacFieldRecord(Lattice<vobj> &field,userRecord &_userRecord) 
+  void readScidacFieldRecord(Lattice<vobj> &field,userRecord &_userRecord,
 			     int control=BINARYIO_LEXICOGRAPHIC) 
  {
    typedef typename vobj::scalar_object sobj;
    GridBase * grid = field.Grid();
@@ -571,7 +579,7 @@ class ScidacReader : public GridLimeReader {
    readLimeObject(header ,std::string("FieldMetaData"),std::string(GRID_FORMAT)); // Open message 
    readLimeObject(_userRecord,_userRecord.SerialisableClassName(),std::string(SCIDAC_RECORD_XML));
    readLimeObject(_scidacRecord,_scidacRecord.SerialisableClassName(),std::string(SCIDAC_PRIVATE_RECORD_XML));
-    readLimeLatticeBinaryObject(field,std::string(ILDG_BINARY_DATA));
+    readLimeLatticeBinaryObject(field,std::string(ILDG_BINARY_DATA),control);
  }
  void skipPastBinaryRecord(void) {
    std::string rec_name(ILDG_BINARY_DATA);
--- a/Grid/qcd/action/fermion/implementation/WilsonKernelsImplementation.h
+++ b/Grid/qcd/action/fermion/implementation/WilsonKernelsImplementation.h
@@ -462,6 +462,7 @@ void WilsonKernels<Impl>::DhopKernel(int Opt,StencilImpl &st,  DoubledGaugeField
    autoView(st_v , st,AcceleratorRead);
   if( interior && exterior ) {
     acceleratorFenceComputeStream();
     if (Opt == WilsonKernelsStatic::OptGeneric    ) { KERNEL_CALL(GenericDhopSite); return;}
     if (Opt == WilsonKernelsStatic::OptHandUnroll ) { KERNEL_CALL(HandDhopSite);    return;}
 #ifndef GRID_CUDA
@@ -495,6 +496,7 @@ void WilsonKernels<Impl>::DhopKernel(int Opt,StencilImpl &st,  DoubledGaugeField
    autoView(st_v ,st,AcceleratorRead);
   if( interior && exterior ) {
     acceleratorFenceComputeStream();
     if (Opt == WilsonKernelsStatic::OptGeneric    ) { KERNEL_CALL(GenericDhopSiteDag); return;}
     if (Opt == WilsonKernelsStatic::OptHandUnroll ) { KERNEL_CALL(HandDhopSiteDag);    return;}
 #ifndef GRID_CUDA
--- a/Grid/qcd/smearing/HISQSmearing.h
+++ b/Grid/qcd/smearing/HISQSmearing.h
@@ -170,7 +170,7 @@ public:
            typedef decltype(coalescedReadGeneralPermute(U_v[0](0),gStencil.GetEntry(0,0)->_permute,Nd)) U3matrix;
            int Nsites = U_v.size();
-            auto gStencil_v = gStencil.View(); 
+            auto gStencil_v = gStencil.View(AcceleratorRead); 
            accelerator_for(site,Nsites,Simd::Nsimd(),{ // ----------- 3-link constructs
                stencilElement SE0, SE1, SE2, SE3, SE4, SE5;
--- a/Grid/qcd/utils/WilsonLoops.h
+++ b/Grid/qcd/utils/WilsonLoops.h
@@ -488,7 +488,7 @@ public:
    for(int mu=0;mu<Nd;mu++){
      { //view scope
 	autoView( gStaple_v , gStaple, AcceleratorWrite);
-	auto gStencil_v = gStencil.View();
+	auto gStencil_v = gStencil.View(AcceleratorRead);
 	accelerator_for(ss, ggrid->oSites(), (size_t)ggrid->Nsimd(), {
 	    decltype(coalescedRead(Ug_dirs_v[0][0])) stencil_ss;
@@ -1200,7 +1200,7 @@ public:
      { //view scope
 	autoView( gStaple_v , gStaple, AcceleratorWrite);
-	auto gStencil_v = gStencil.View();
+	auto gStencil_v = gStencil.View(AcceleratorRead);
 	accelerator_for(ss, ggrid->oSites(), (size_t)ggrid->Nsimd(), {
 	    decltype(coalescedRead(Ug_dirs_v[0][0])) stencil_ss;
--- a/Grid/simd/Grid_vector_types.h
+++ b/Grid/simd/Grid_vector_types.h
@@ -1130,6 +1130,14 @@ static_assert(sizeof(SIMD_Ftype) == sizeof(SIMD_Itype), "SIMD vector lengths inc
 #endif
 #endif
 // Fixme need coalesced read gpermute
 template<class vobj> void gpermute(vobj & inout,int perm){
  vobj tmp=inout;
  if (perm & 0x1 ) { permute(inout,tmp,0); tmp=inout;}
  if (perm & 0x2 ) { permute(inout,tmp,1); tmp=inout;}
  if (perm & 0x4 ) { permute(inout,tmp,2); tmp=inout;}
  if (perm & 0x8 ) { permute(inout,tmp,3); tmp=inout;}
 }
 NAMESPACE_END(Grid);
--- a/Grid/stencil/GeneralLocalStencil.h
+++ b/Grid/stencil/GeneralLocalStencil.h
@@ -32,7 +32,12 @@ NAMESPACE_BEGIN(Grid);
 struct GeneralStencilEntry { 
  uint64_t _offset;            // 4 bytes 
  uint8_t _permute;            // 1 bytes // Horrible alignment properties
  uint8_t _wrap;               // 1 bytes // Horrible alignment properties
 };
 struct GeneralStencilEntryReordered : public GeneralStencilEntry {
  uint64_t _input;
 };
 // Could pack to 8 + 4 + 4 = 128 bit and use 
 class GeneralLocalStencilView {
@@ -46,7 +51,7 @@ class GeneralLocalStencilView {
  accelerator_inline GeneralStencilEntry * GetEntry(int point,int osite) const { 
    return & this->_entries_p[point+this->_npoints*osite]; 
  }
-
+  void ViewClose(void){};
 };
 ////////////////////////////////////////
 // The Stencil Class itself
@@ -61,7 +66,7 @@ protected:
 public: 
  GridBase *Grid(void) const { return _grid; }
-  View_type View(void) const {
+  View_type View(int mode) const {
    View_type accessor(*( (View_type *) this));
    return accessor;
  }
@@ -101,17 +106,23 @@ public:
 	  // Simpler version using icoor calculation
 	  ////////////////////////////////////////////////
 	  SE._permute =0;
 	  SE._wrap=0;
 	  for(int d=0;d<Coor.size();d++){
 	    int fd = grid->_fdimensions[d];
 	    int rd = grid->_rdimensions[d];
 	    int ld = grid->_ldimensions[d];
 	    int ly = grid->_simd_layout[d];
-	    assert((ly==1)||(ly==2));
+	    assert((ly==1)||(ly==2)||(ly==grid->Nsimd()));
 	    int shift = (shifts[ii][d]+fd)%fd;  // make it strictly positive 0.. L-1
 	    int x = Coor[d];                // x in [0... rd-1] as an oSite 
 	    if ( (x + shift)%fd != (x+shift)%ld ){
 	      SE._wrap = 1;
 	    }
 	    int permute_dim  = grid->PermuteDim(d);
 	    int permute_slice=0;
 	    if(permute_dim){    
--- a/Grid/stencil/Stencil.h
+++ b/Grid/stencil/Stencil.h
@@ -70,57 +70,6 @@ struct DefaultImplParams {
 void Gather_plane_table_compute (GridBase *grid,int dimension,int plane,int cbmask,
 				 int off,std::vector<std::pair<int,int> > & table);
 /*
 template<class vobj,class cobj,class compressor>
 void Gather_plane_simple_table (commVector<std::pair<int,int> >& table,const Lattice<vobj> &rhs,cobj *buffer,compressor &compress, int off,int so)   __attribute__((noinline));
 template<class vobj,class cobj,class compressor>
 void Gather_plane_simple_table (commVector<std::pair<int,int> >& table,const Lattice<vobj> &rhs,cobj *buffer,compressor &compress, int off,int so)
 {
  int num=table.size();
  std::pair<int,int> *table_v = & table[0];
  auto rhs_v = rhs.View(AcceleratorRead);
  accelerator_forNB( i,num, vobj::Nsimd(), {
    compress.Compress(buffer[off+table_v[i].first],rhs_v[so+table_v[i].second]);
  });
  rhs_v.ViewClose();
 }
 ///////////////////////////////////////////////////////////////////
 // Gather for when there *is* need to SIMD split with compression
 ///////////////////////////////////////////////////////////////////
 template<class cobj,class vobj,class compressor>
 void Gather_plane_exchange_table(const Lattice<vobj> &rhs,
 				 commVector<cobj *> pointers,
 				 int dimension,int plane,
 				 int cbmask,compressor &compress,int type) __attribute__((noinline));
 template<class cobj,class vobj,class compressor>
 void Gather_plane_exchange_table(commVector<std::pair<int,int> >& table,
 				 const Lattice<vobj> &rhs,
 				 std::vector<cobj *> &pointers,int dimension,int plane,int cbmask,
 				 compressor &compress,int type)
 {
  assert( (table.size()&0x1)==0);
  int num=table.size()/2;
  int so  = plane*rhs.Grid()->_ostride[dimension]; // base offset for start of plane
  auto rhs_v = rhs.View(AcceleratorRead);
  auto rhs_p = &rhs_v[0];
  auto p0=&pointers[0][0];
  auto p1=&pointers[1][0];
  auto tp=&table[0];
  accelerator_forNB(j, num, vobj::Nsimd(), {
      compress.CompressExchange(p0,p1, rhs_p, j,
 				so+tp[2*j  ].second,
 				so+tp[2*j+1].second,
 				type);
  });
  rhs_v.ViewClose();
 }
 */
 void DslashResetCounts(void);
 void DslashGetCounts(uint64_t &dirichlet,uint64_t &partial,uint64_t &full);
 void DslashLogFull(void);
@@ -258,6 +207,10 @@ public:
  struct Packet {
    void * send_buf;
    void * recv_buf;
 #ifndef ACCELERATOR_AWARE_MPI
    void * host_send_buf; // Allocate this if not MPI_CUDA_AWARE
    void * host_recv_buf; // Allocate this if not MPI_CUDA_AWARE
 #endif
    Integer to_rank;
    Integer from_rank;
    Integer do_send;
@@ -324,7 +277,7 @@ public:
  Vector<int> surface_list;
  stencilVector<StencilEntry>  _entries; // Resident in managed memory
-  commVector<StencilEntry>     _entries_device; // Resident in managed memory
+  commVector<StencilEntry>     _entries_device; // Resident in device memory
  std::vector<Packet> Packets;
  std::vector<Merge> Mergers;
  std::vector<Merge> MergersSHM;
@@ -408,33 +361,16 @@ public:
  // Use OpenMP Tasks for cleaner ???
  // must be called *inside* parallel region
  //////////////////////////////////////////
  /*
  void CommunicateThreaded()
  {
 #ifdef GRID_OMP
    int mythread = omp_get_thread_num();
    int nthreads = CartesianCommunicator::nCommThreads;
 #else
    int mythread = 0;
    int nthreads = 1;
 #endif
    if (nthreads == -1) nthreads = 1;
    if (mythread < nthreads) {
      for (int i = mythread; i < Packets.size(); i += nthreads) {
 	uint64_t bytes = _grid->StencilSendToRecvFrom(Packets[i].send_buf,
 						      Packets[i].to_rank,
 						      Packets[i].recv_buf,
 						      Packets[i].from_rank,
 						      Packets[i].bytes,i);
      }
    }
  }
  */
  ////////////////////////////////////////////////////////////////////////
  // Non blocking send and receive. Necessarily parallel.
  ////////////////////////////////////////////////////////////////////////
  void CommunicateBegin(std::vector<std::vector<CommsRequest_t> > &reqs)
  {
    // All GPU kernel tasks must complete
    //    accelerator_barrier();     // All kernels should ALREADY be complete
    //    _grid->StencilBarrier();   // Everyone is here, so noone running slow and still using receive buffer
                               // But the HaloGather had a barrier too.
 #ifdef ACCELERATOR_AWARE_MPI
    for(int i=0;i<Packets.size();i++){
      _grid->StencilSendToRecvFromBegin(MpiReqs,
 					Packets[i].send_buf,
@@ -443,16 +379,54 @@ public:
 					Packets[i].from_rank,Packets[i].do_recv,
 					Packets[i].xbytes,Packets[i].rbytes,i);
    }
 #else
 #warning "Using COPY VIA HOST BUFFERS IN STENCIL"
    for(int i=0;i<Packets.size();i++){
      // Introduce a host buffer with a cheap slab allocator and zero cost wipe all
      Packets[i].host_send_buf = _grid->HostBufferMalloc(Packets[i].xbytes);
      Packets[i].host_recv_buf = _grid->HostBufferMalloc(Packets[i].rbytes);
      if ( Packets[i].do_send ) {
 	acceleratorCopyFromDevice(Packets[i].send_buf, Packets[i].host_send_buf,Packets[i].xbytes);
      }
      _grid->StencilSendToRecvFromBegin(MpiReqs,
 					Packets[i].host_send_buf,
 					Packets[i].to_rank,Packets[i].do_send,
 					Packets[i].host_recv_buf,
 					Packets[i].from_rank,Packets[i].do_recv,
 					Packets[i].xbytes,Packets[i].rbytes,i);
    }
 #endif
    // Get comms started then run checksums
    // Having this PRIOR to the dslash seems to make Sunspot work... (!)
    for(int i=0;i<Packets.size();i++){
      if ( Packets[i].do_send )
 	FlightRecorder::xmitLog(Packets[i].send_buf,Packets[i].xbytes);
    }
  }
  void CommunicateComplete(std::vector<std::vector<CommsRequest_t> > &reqs)
  {
-    _grid->StencilSendToRecvFromComplete(MpiReqs,0);
+    _grid->StencilSendToRecvFromComplete(MpiReqs,0); // MPI is done
    if   ( this->partialDirichlet ) DslashLogPartial();
    else if ( this->fullDirichlet ) DslashLogDirichlet();
    else DslashLogFull();
-    acceleratorCopySynchronise();
+    // acceleratorCopySynchronise() is in the StencilSendToRecvFromComplete
    //    accelerator_barrier(); 
    _grid->StencilBarrier(); 
 #ifndef ACCELERATOR_AWARE_MPI
 #warning "Using COPY VIA HOST BUFFERS IN STENCIL"
    for(int i=0;i<Packets.size();i++){
      if ( Packets[i].do_recv ) {
 	acceleratorCopyToDevice(Packets[i].host_recv_buf, Packets[i].recv_buf,Packets[i].rbytes);
      }
    }
    _grid->HostBufferFreeAll();
 #endif
    // run any checksums
    for(int i=0;i<Packets.size();i++){
      if ( Packets[i].do_recv )
 	FlightRecorder::recvLog(Packets[i].recv_buf,Packets[i].rbytes,Packets[i].from_rank);
    }
  }
  ////////////////////////////////////////////////////////////////////////
  // Blocking send and receive. Either sequential or parallel.
@@ -528,6 +502,7 @@ public:
  template<class compressor>
  void HaloGather(const Lattice<vobj> &source,compressor &compress)
  {
    //    accelerator_barrier();
    _grid->StencilBarrier();// Synch shared memory on a single nodes
    assert(source.Grid()==_grid);
@@ -540,10 +515,9 @@ public:
      compress.Point(point);
      HaloGatherDir(source,compress,point,face_idx);
    }
-    accelerator_barrier();
+    accelerator_barrier(); // All my local gathers are complete
    face_table_computed=1;
    assert(u_comm_offset==_unified_buffer_size);
  }
  /////////////////////////
@@ -579,6 +553,7 @@ public:
      accelerator_forNB(j, words, cobj::Nsimd(), {
 	  coalescedWrite(to[j] ,coalescedRead(from [j]));
      });
      acceleratorFenceComputeStream();
    }
  }
@@ -669,6 +644,7 @@ public:
    for(int i=0;i<dd.size();i++){
      decompressor::DecompressFace(decompress,dd[i]);
    }
    acceleratorFenceComputeStream(); // dependent kernels
  }
  ////////////////////////////////////////
  // Set up routines
@@ -1224,7 +1200,6 @@ public:
 	  ///////////////////////////////////////////////////////////
 	  int do_send = (comms_send|comms_partial_send) && (!shm_send );
 	  int do_recv = (comms_send|comms_partial_send) && (!shm_recv );
 	  AddPacket((void *)&send_buf[comm_off],
 		    (void *)&recv_buf[comm_off],
 		    xmit_to_rank, do_send,
--- a/Grid/tensors/Tensor_traits.h
+++ b/Grid/tensors/Tensor_traits.h
@@ -405,11 +405,4 @@ NAMESPACE_BEGIN(Grid);
 NAMESPACE_END(Grid);
 #ifdef GRID_SYCL
 template<typename T> struct
 sycl::is_device_copyable<T, typename std::enable_if<
 			      Grid::isGridTensor<T>::value  && (!std::is_trivially_copyable<T>::value),
 			      void>::type>
  : public std::true_type {};
 #endif
--- a/Grid/threads/Accelerator.cc
+++ b/Grid/threads/Accelerator.cc
@@ -122,7 +122,7 @@ hipStream_t computeStream;
 void acceleratorInit(void)
 {
  int nDevices = 1;
-  hipGetDeviceCount(&nDevices);
+  auto discard = hipGetDeviceCount(&nDevices);
  gpu_props = new hipDeviceProp_t[nDevices];
  char * localRankStr = NULL;
@@ -149,7 +149,7 @@ void acceleratorInit(void)
 #define GPU_PROP_FMT(canMapHostMemory,FMT)     printf("AcceleratorHipInit:   " #canMapHostMemory ": " FMT" \n",prop.canMapHostMemory);
 #define GPU_PROP(canMapHostMemory)             GPU_PROP_FMT(canMapHostMemory,"%d");
-    auto r=hipGetDeviceProperties(&gpu_props[i], i);
+    discard = hipGetDeviceProperties(&gpu_props[i], i);
    hipDeviceProp_t prop; 
    prop = gpu_props[i];
    totalDeviceMem = prop.totalGlobalMem;
@@ -186,13 +186,13 @@ void acceleratorInit(void)
  }
  int device = rank;
 #endif
-  hipSetDevice(device);
+  discard = hipSetDevice(device);
-  hipStreamCreate(&copyStream);
+  discard = hipStreamCreate(&copyStream);
-  hipStreamCreate(&computeStream);
+  discard = hipStreamCreate(&computeStream);
  const int len=64;
  char busid[len];
  if( rank == world_rank ) { 
-    hipDeviceGetPCIBusId(busid, len, device);
+    discard = hipDeviceGetPCIBusId(busid, len, device);
    printf("local rank %d device %d bus id: %s\n", rank, device, busid);
  }
  if ( world_rank == 0 )  printf("AcceleratorHipInit: ================================================\n");
--- a/Grid/threads/Accelerator.h
+++ b/Grid/threads/Accelerator.h
@@ -117,7 +117,7 @@ accelerator_inline int acceleratorSIMTlane(int Nsimd) {
 #endif
 } // CUDA specific
-inline void cuda_mem(void)
+inline void acceleratorMem(void)
 {
  size_t free_t,total_t,used_t;
  cudaMemGetInfo(&free_t,&total_t);
@@ -125,6 +125,11 @@ inline void cuda_mem(void)
  std::cout << " MemoryManager : GPU used "<<used_t<<" free "<<free_t<< " total "<<total_t<<std::endl;
 }
 inline void cuda_mem(void)
 {
  acceleratorMem();
 }
 #define accelerator_for2dNB( iter1, num1, iter2, num2, nsimd, ... )	\
  {									\
    int nt=acceleratorThreads();					\
@@ -137,6 +142,18 @@ inline void cuda_mem(void)
    dim3 cu_blocks ((num1+nt-1)/nt,num2,1);				\
    LambdaApply<<<cu_blocks,cu_threads,0,computeStream>>>(num1,num2,nsimd,lambda);	\
  }
 #define prof_accelerator_for2dNB( iter1, num1, iter2, num2, nsimd, ... )	\
  {									\
    int nt=acceleratorThreads();					\
    typedef uint64_t Iterator;						\
    auto lambda = [=] accelerator					\
      (Iterator iter1,Iterator iter2,Iterator lane) mutable {		\
      __VA_ARGS__;							\
    };									\
    dim3 cu_threads(nsimd,acceleratorThreads(),1);			\
    dim3 cu_blocks ((num1+nt-1)/nt,num2,1);				\
    ProfileLambdaApply<<<cu_blocks,cu_threads,0,computeStream>>>(num1,num2,nsimd,lambda); \
  }
 #define accelerator_for6dNB(iter1, num1,				\
                            iter2, num2,				\
@@ -157,6 +174,20 @@ inline void cuda_mem(void)
    Lambda6Apply<<<cu_blocks,cu_threads,0,computeStream>>>(num1,num2,num3,num4,num5,num6,lambda); \
  }
 #define accelerator_for2dNB( iter1, num1, iter2, num2, nsimd, ... )	\
  {									\
    int nt=acceleratorThreads();					\
    typedef uint64_t Iterator;						\
    auto lambda = [=] accelerator					\
      (Iterator iter1,Iterator iter2,Iterator lane) mutable {		\
      __VA_ARGS__;							\
    };									\
    dim3 cu_threads(nsimd,acceleratorThreads(),1);			\
    dim3 cu_blocks ((num1+nt-1)/nt,num2,1);				\
    LambdaApply<<<cu_blocks,cu_threads,0,computeStream>>>(num1,num2,nsimd,lambda);	\
  }
 template<typename lambda>  __global__
 void LambdaApply(uint64_t num1, uint64_t num2, uint64_t num3, lambda Lambda)
 {
@@ -168,6 +199,17 @@ void LambdaApply(uint64_t num1, uint64_t num2, uint64_t num3, lambda Lambda)
    Lambda(x,y,z);
  }
 }
 template<typename lambda>  __global__
 void ProfileLambdaApply(uint64_t num1, uint64_t num2, uint64_t num3, lambda Lambda)
 {
  // Weird permute is to make lane coalesce for large blocks
  uint64_t x = threadIdx.y + blockDim.y*blockIdx.x;
  uint64_t y = threadIdx.z + blockDim.z*blockIdx.y;
  uint64_t z = threadIdx.x;
  if ( (x < num1) && (y<num2) && (z<num3) ) {
    Lambda(x,y,z);
  }
 }
 template<typename lambda>  __global__
 void Lambda6Apply(uint64_t num1, uint64_t num2, uint64_t num3,
@@ -208,6 +250,7 @@ inline void *acceleratorAllocShared(size_t bytes)
  if( err != cudaSuccess ) {
    ptr = (void *) NULL;
    printf(" cudaMallocManaged failed for %d %s \n",bytes,cudaGetErrorString(err));
    assert(0);
  }
  return ptr;
 };
@@ -234,6 +277,7 @@ inline void acceleratorCopyDeviceToDeviceAsynch(void *from,void *to,size_t bytes
 }
 inline void acceleratorCopySynchronise(void) { cudaStreamSynchronize(copyStream); };
 inline int  acceleratorIsCommunicable(void *ptr)
 {
  //  int uvm=0;
@@ -265,6 +309,11 @@ NAMESPACE_END(Grid);
 NAMESPACE_BEGIN(Grid);
 inline void acceleratorMem(void)
 {
  std::cout <<" SYCL acceleratorMem not implemented"<<std::endl;
 }
 extern cl::sycl::queue *theGridAccelerator;
 extern cl::sycl::queue *theCopyAccelerator;
@@ -344,6 +393,15 @@ NAMESPACE_BEGIN(Grid);
 #define accelerator        __host__ __device__
 #define accelerator_inline __host__ __device__ inline
 inline void acceleratorMem(void)
 {
  size_t free_t,total_t,used_t;
  auto discard = hipMemGetInfo(&free_t,&total_t);
  used_t=total_t-free_t;
  std::cout << " MemoryManager : GPU used "<<used_t<<" free "<<free_t<< " total "<<total_t<<std::endl;
 }
 extern hipStream_t copyStream;
 extern hipStream_t computeStream;
 /*These routines define mapping from thread grid to loop & vector lane indexing */
@@ -404,7 +462,7 @@ void LambdaApply(uint64_t numx, uint64_t numy, uint64_t numz, lambda Lambda)
 #define accelerator_barrier(dummy)				\
  {								\
-    auto r=hipStreamSynchronize(computeStream);			\
+    auto tmp=hipStreamSynchronize(computeStream);		\
    auto err = hipGetLastError();				\
    if ( err != hipSuccess ) {					\
      printf("After hipDeviceSynchronize() : HIP error %s \n", hipGetErrorString( err )); \
@@ -420,7 +478,7 @@ inline void *acceleratorAllocShared(size_t bytes)
  auto err = hipMallocManaged((void **)&ptr,bytes);
  if( err != hipSuccess ) {
    ptr = (void *) NULL;
-    printf(" hipMallocManaged failed for %ld %s \n",bytes,hipGetErrorString(err));
+    fprintf(stderr," hipMallocManaged failed for %ld %s \n",bytes,hipGetErrorString(err)); fflush(stderr);
  }
  return ptr;
 };
@@ -432,26 +490,30 @@ inline void *acceleratorAllocDevice(size_t bytes)
  auto err = hipMalloc((void **)&ptr,bytes);
  if( err != hipSuccess ) {
    ptr = (void *) NULL;
-    printf(" hipMalloc failed for %ld %s \n",bytes,hipGetErrorString(err));
+    fprintf(stderr," hipMalloc failed for %ld %s \n",bytes,hipGetErrorString(err)); fflush(stderr);
  }
  return ptr;
 };
-inline void acceleratorFreeShared(void *ptr){ auto r=hipFree(ptr);};
+inline void acceleratorFreeShared(void *ptr){ auto discard=hipFree(ptr);};
-inline void acceleratorFreeDevice(void *ptr){ auto r=hipFree(ptr);};
+inline void acceleratorFreeDevice(void *ptr){ auto discard=hipFree(ptr);};
-inline void acceleratorCopyToDevice(void *from,void *to,size_t bytes)  { auto r=hipMemcpy(to,from,bytes, hipMemcpyHostToDevice);}
+inline void acceleratorCopyToDevice(void *from,void *to,size_t bytes)  { auto discard=hipMemcpy(to,from,bytes, hipMemcpyHostToDevice);}
-inline void acceleratorCopyFromDevice(void *from,void *to,size_t bytes){ auto r=hipMemcpy(to,from,bytes, hipMemcpyDeviceToHost);}
+inline void acceleratorCopyFromDevice(void *from,void *to,size_t bytes){ auto discard=hipMemcpy(to,from,bytes, hipMemcpyDeviceToHost);}
 inline void acceleratorCopyToDeviceAsync(void *from, void *to, size_t bytes, hipStream_t stream = copyStream) { auto r = hipMemcpyAsync(to,from,bytes, hipMemcpyHostToDevice, stream);}
 inline void acceleratorCopyFromDeviceAsync(void *from, void *to, size_t bytes, hipStream_t stream = copyStream) { auto r = hipMemcpyAsync(to,from,bytes, hipMemcpyDeviceToHost, stream);}
 //inline void acceleratorCopyDeviceToDeviceAsynch(void *from,void *to,size_t bytes)  { hipMemcpy(to,from,bytes, hipMemcpyDeviceToDevice);}
 //inline void acceleratorCopySynchronise(void) {  }
-inline void acceleratorMemSet(void *base,int value,size_t bytes) { auto r=hipMemset(base,value,bytes);}
+inline void acceleratorMemSet(void *base,int value,size_t bytes) { auto discard=hipMemset(base,value,bytes);}
 inline void acceleratorCopyDeviceToDeviceAsynch(void *from,void *to,size_t bytes) // Asynch
 {
-  auto r=hipMemcpyDtoDAsync(to,from,bytes, copyStream);
+  auto discard=hipMemcpyDtoDAsync(to,from,bytes, copyStream);
 }
-inline void acceleratorCopySynchronise(void) { auto r=hipStreamSynchronize(copyStream); };
+inline void acceleratorCopyToDeviceAsync(void *from, void *to, size_t bytes, hipStream_t stream = copyStream) {
  auto r = hipMemcpyAsync(to,from,bytes, hipMemcpyHostToDevice, stream);
 }
 inline void acceleratorCopyFromDeviceAsync(void *from, void *to, size_t bytes, hipStream_t stream = copyStream) {
  auto r = hipMemcpyAsync(to,from,bytes, hipMemcpyDeviceToHost, stream);
 }
 inline void acceleratorCopySynchronise(void) { auto discard=hipStreamSynchronize(copyStream); };
 #endif
@@ -461,6 +523,9 @@ inline void acceleratorCopySynchronise(void) { auto r=hipStreamSynchronize(copyS
 #if defined(GRID_SYCL) || defined(GRID_CUDA) || defined(GRID_HIP)
 // FIXME -- the non-blocking nature got broken March 30 2023 by PAB
 #define accelerator_forNB( iter1, num1, nsimd, ... ) accelerator_for2dNB( iter1, num1, iter2, 1, nsimd, {__VA_ARGS__} );  
 #define prof_accelerator_for( iter1, num1, nsimd, ... ) \
  prof_accelerator_for2dNB( iter1, num1, iter2, 1, nsimd, {__VA_ARGS__} );\
  accelerator_barrier(dummy);
 #define accelerator_for( iter, num, nsimd, ... )		\
  accelerator_forNB(iter, num, nsimd, { __VA_ARGS__ } );	\
@@ -474,6 +539,12 @@ inline void acceleratorCopySynchronise(void) { auto r=hipStreamSynchronize(copyS
 #endif
 inline void acceleratorCopyDeviceToDevice(void *from,void *to,size_t bytes)
 {
  acceleratorCopyDeviceToDeviceAsynch(from,to,bytes);
  acceleratorCopySynchronise();
 }
 //////////////////////////////////////////////
 // CPU Target - No accelerator just thread instead
 //////////////////////////////////////////////
@@ -483,6 +554,15 @@ inline void acceleratorCopySynchronise(void) { auto r=hipStreamSynchronize(copyS
 #undef GRID_SIMT
 inline void acceleratorMem(void)
 {
  /*
    struct rusage rusage;
    getrusage( RUSAGE_SELF, &rusage );
    return (size_t)rusage.ru_maxrss;
  */
  std::cout <<" system acceleratorMem not implemented"<<std::endl;
 }
 #define accelerator 
 #define accelerator_inline strong_inline
@@ -576,11 +656,18 @@ accelerator_inline void acceleratorFence(void)
  return;
 }
-inline void acceleratorCopyDeviceToDevice(void *from,void *to,size_t bytes)
+template<class T> void acceleratorPut(T& dev,T&host)
 {
-  acceleratorCopyDeviceToDeviceAsynch(from,to,bytes);
+  acceleratorCopyToDevice(&host,&dev,sizeof(T));
-  acceleratorCopySynchronise();
+}
 template<class T> T acceleratorGet(T& dev)
 {
  T host;
  acceleratorCopyFromDevice(&dev,&host,sizeof(T));
  return host;
 }
 NAMESPACE_END(Grid);
--- a/Grid/util/Coordinate.h
+++ b/Grid/util/Coordinate.h
@@ -94,6 +94,13 @@ static constexpr int MaxDims = GRID_MAX_LATTICE_DIMENSION;
 typedef AcceleratorVector<int,MaxDims> Coordinate;
 template<class T,int _ndim>
 inline bool operator==(const AcceleratorVector<T,_ndim> &v,const AcceleratorVector<T,_ndim> &w)
 {
  if (v.size()!=w.size()) return false;
  for(int i=0;i<v.size();i++) if ( v[i]!=w[i] ) return false;
  return true;
 }
 template<class T,int _ndim>
 inline std::ostream & operator<<(std::ostream &os, const AcceleratorVector<T,_ndim> &v)
 {
--- a/Grid/util/FlightRecorder.cc
+++ b/Grid/util/FlightRecorder.cc
@@ -0,0 +1,333 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid
    Source file: ./lib/Init.cc
    Copyright (C) 2015
 Author: Azusa Yamaguchi <ayamaguc@staffmail.ed.ac.uk>
 Author: Peter Boyle <paboyle@ph.ed.ac.uk>
 Author: Peter Boyle <peterboyle@MacBook-Pro.local>
 Author: paboyle <paboyle@ph.ed.ac.uk>
    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.h>
 NAMESPACE_BEGIN(Grid);
 ///////////////////////////////////////////////////////
 // Grid Norm logging for repro testing
 ///////////////////////////////////////////////////////
 int FlightRecorder::PrintEntireLog;
 int FlightRecorder::ContinueOnFail;
 int FlightRecorder::LoggingMode;
 int FlightRecorder::ChecksumComms;
 int FlightRecorder::ChecksumCommsSend;
 int32_t  FlightRecorder::XmitLoggingCounter;
 int32_t  FlightRecorder::RecvLoggingCounter;
 int32_t  FlightRecorder::CsumLoggingCounter;
 int32_t  FlightRecorder::NormLoggingCounter;
 int32_t  FlightRecorder::ReductionLoggingCounter;
 uint64_t FlightRecorder::ErrorCounter;
 std::vector<double> FlightRecorder::NormLogVector;
 std::vector<double> FlightRecorder::ReductionLogVector;
 std::vector<uint64_t> FlightRecorder::CsumLogVector;
 std::vector<uint64_t> FlightRecorder::XmitLogVector;
 std::vector<uint64_t> FlightRecorder::RecvLogVector;
 void FlightRecorder::ResetCounters(void)
 {
  XmitLoggingCounter=0;
  RecvLoggingCounter=0;
  CsumLoggingCounter=0;
  NormLoggingCounter=0;
  ReductionLoggingCounter=0;
 }
 void FlightRecorder::Truncate(void)
 {
  ResetCounters();
  XmitLogVector.resize(0);
  RecvLogVector.resize(0);
  NormLogVector.resize(0);
  CsumLogVector.resize(0);
  ReductionLogVector.resize(0);
 }
 void FlightRecorder::SetLoggingMode(FlightRecorder::LoggingMode_t mode)
 {
  switch ( mode ) {
  case LoggingModePrint:
    SetLoggingModePrint();
    break;
  case LoggingModeRecord:
    SetLoggingModeRecord();
    break;
  case LoggingModeVerify:
    SetLoggingModeVerify();
    break;
  case LoggingModeNone:
    LoggingMode = mode;
    Truncate();
    break;
  default:
    assert(0);
  }
 }
 void FlightRecorder::SetLoggingModePrint(void)
 {
  std::cout << " FlightRecorder: set to print output " <<std::endl;
  Truncate();
  LoggingMode = LoggingModePrint;
 }
 void FlightRecorder::SetLoggingModeRecord(void)
 {
  std::cout << " FlightRecorder: set to RECORD " <<std::endl;
  Truncate();
  LoggingMode = LoggingModeRecord;
 }
 void FlightRecorder::SetLoggingModeVerify(void)
 {
  std::cout << " FlightRecorder: set to VERIFY " << NormLogVector.size()<< " log entries "<<std::endl;
  ResetCounters();
  LoggingMode = LoggingModeVerify;
 }
 uint64_t FlightRecorder::ErrorCount(void)
 {
  return ErrorCounter;
 }
 void FlightRecorder::NormLog(double value)
 {
  uint64_t hex = * ( (uint64_t *)&value );
  if(LoggingMode == LoggingModePrint) {
    std::cerr<<"FlightRecorder::NormLog : "<< NormLoggingCounter <<" "<<std::hex<< hex<<std::dec <<std::endl;
    NormLoggingCounter++;
  }
  if(LoggingMode == LoggingModeRecord) {
    std::cerr<<"FlightRecorder::NormLog RECORDING : "<< NormLoggingCounter <<" "<<std::hex<< hex<<std::dec <<std::endl;
    NormLogVector.push_back(value);
    NormLoggingCounter++;
  }
  if(LoggingMode == LoggingModeVerify) {
    if(NormLoggingCounter < NormLogVector.size()){
      uint64_t hexref  = * ( (uint64_t *)&NormLogVector[NormLoggingCounter] );
      if ( (value != NormLogVector[NormLoggingCounter]) || std::isnan(value) ) {
 	std::cerr<<"FlightRecorder::NormLog Oops, I did it again "<< NormLoggingCounter
 		 <<std::hex<<" "<<hex<<" "<<hexref<<std::dec<<" "
 		 <<std::hexfloat<<value<<" "<< NormLogVector[NormLoggingCounter]<<std::endl;
 	std::cerr << " Oops got norm "<< std::hexfloat<<value<<" expect "<<NormLogVector[NormLoggingCounter] <<std::endl;
 	fprintf(stderr,"%s:%d Oops, I did it again! Reproduce failure for norm %d/%zu %.16e expect %.16e\n",
 		GridHostname(),
 		GlobalSharedMemory::WorldShmRank,
 		NormLoggingCounter,NormLogVector.size(),
 		value, NormLogVector[NormLoggingCounter]); fflush(stderr);
 	if(!ContinueOnFail)assert(0); // Force takedown of job
 	ErrorCounter++;
      } else {
 	if ( PrintEntireLog ) { 
 	  std::cerr<<"FlightRecorder::NormLog VALID "<< NormLoggingCounter << std::hex
 		   <<" "<<hex<<" "<<hexref
 		   <<" "<<std::hexfloat<<value<<" "<< NormLogVector[NormLoggingCounter]<<std::dec<<std::endl;
 	}
      }
    }
    if ( NormLogVector.size()==NormLoggingCounter ) {
      std::cout << "FlightRecorder:: Verified entire sequence of "<<NormLoggingCounter<<" norms "<<std::endl;
    }
    NormLoggingCounter++;
  }
 }
 void FlightRecorder::CsumLog(uint64_t hex)
 {
  if(LoggingMode == LoggingModePrint) {
    std::cerr<<"FlightRecorder::CsumLog : "<< CsumLoggingCounter <<" "<<std::hex<< hex<<std::dec <<std::endl;
    CsumLoggingCounter++;
  }
  if(LoggingMode == LoggingModeRecord) {
    std::cerr<<"FlightRecorder::CsumLog RECORDING : "<< NormLoggingCounter <<" "<<std::hex<< hex<<std::dec <<std::endl;
    CsumLogVector.push_back(hex);
    CsumLoggingCounter++;
  }
  if(LoggingMode == LoggingModeVerify) {
    if(CsumLoggingCounter < CsumLogVector.size()) {
      uint64_t hexref  = CsumLogVector[CsumLoggingCounter] ;
      if ( hex != hexref ) {
        std::cerr<<"FlightRecorder::CsumLog Oops, I did it again "<< CsumLoggingCounter
 		 <<std::hex<<" "<<hex<<" "<<hexref<<std::dec<<std::endl;
 	fprintf(stderr,"%s:%d Oops, I did it again! Reproduce failure for csum %d %lx expect %lx\n",
 		GridHostname(),
 		GlobalSharedMemory::WorldShmRank,
 		CsumLoggingCounter,hex, hexref);
 	fflush(stderr);
 	if(!ContinueOnFail) assert(0); // Force takedown of job
 	ErrorCounter++;
      } else {
 	if ( PrintEntireLog ) { 
 	  std::cerr<<"FlightRecorder::CsumLog VALID "<< CsumLoggingCounter << std::hex
 		   <<" "<<hex<<" "<<hexref<<std::dec<<std::endl;
 	}
      }
    }  
    if ( CsumLogVector.size()==CsumLoggingCounter ) {
      std::cout << "FlightRecorder:: Verified entire sequence of "<<CsumLoggingCounter<<" checksums "<<std::endl;
    }
    CsumLoggingCounter++;
  }
 }
 void FlightRecorder::ReductionLog(double local,double global)
 {
  uint64_t hex_l = * ( (uint64_t *)&local );
  uint64_t hex_g = * ( (uint64_t *)&global );
  if(LoggingMode == LoggingModePrint) {
    std::cerr<<"FlightRecorder::ReductionLog : "<< ReductionLoggingCounter <<" "<< std::hex << hex_l << " -> " <<hex_g<<std::dec <<std::endl;
    ReductionLoggingCounter++;
  }
  if(LoggingMode == LoggingModeRecord) {
    std::cerr<<"FlightRecorder::ReductionLog RECORDING : "<< ReductionLoggingCounter <<" "<< std::hex << hex_l << " -> " <<hex_g<<std::dec <<std::endl;
    ReductionLogVector.push_back(global);
    ReductionLoggingCounter++;
  }
  if(LoggingMode == LoggingModeVerify) {
    if(ReductionLoggingCounter < ReductionLogVector.size()){
      if ( global != ReductionLogVector[ReductionLoggingCounter] ) {
 	fprintf(stderr,"%s:%d Oops, MPI_Allreduce did it again! Reproduce failure for norm %d/%zu glb %.16e lcl %.16e expect glb %.16e\n",
 		GridHostname(),
 		GlobalSharedMemory::WorldShmRank,
 		ReductionLoggingCounter,ReductionLogVector.size(),
 		global, local, ReductionLogVector[ReductionLoggingCounter]); fflush(stderr);
 	if ( !ContinueOnFail ) assert(0);
 	ErrorCounter++;
      } else {
 	if ( PrintEntireLog ) { 
 	  std::cerr<<"FlightRecorder::ReductionLog : VALID "<< ReductionLoggingCounter <<" "<< std::hexfloat << local << "-> "<< global <<std::endl;
 	}
      }
    }
    if ( ReductionLogVector.size()==ReductionLoggingCounter ) {
      std::cout << "FlightRecorder::ReductionLog : Verified entire sequence of "<<ReductionLoggingCounter<<" norms "<<std::endl;
    }
    ReductionLoggingCounter++;
  }
 }
 void FlightRecorder::xmitLog(void *buf,uint64_t bytes)
 {
  if ( ChecksumCommsSend ){
  uint64_t *ubuf = (uint64_t *)buf;
  if(LoggingMode == LoggingModeNone) return;
 #ifdef GRID_SYCL
  uint64_t _xor = svm_xor(ubuf,bytes/sizeof(uint64_t));
  if(LoggingMode == LoggingModePrint) {
    std::cerr<<"FlightRecorder::xmitLog : "<< XmitLoggingCounter <<" "<< std::hex << _xor <<std::dec <<std::endl;
    XmitLoggingCounter++;
  }
  if(LoggingMode == LoggingModeRecord) {
    std::cerr<<"FlightRecorder::xmitLog RECORD : "<< XmitLoggingCounter <<" "<< std::hex << _xor <<std::dec <<std::endl;
    XmitLogVector.push_back(_xor);
    XmitLoggingCounter++;
  }
  if(LoggingMode == LoggingModeVerify) {
    if(XmitLoggingCounter < XmitLogVector.size()){
      if ( _xor != XmitLogVector[XmitLoggingCounter] ) {
 	fprintf(stderr,"%s:%d Oops, send buf difference! Reproduce failure for xmit %d/%zu  %lx expect glb %lx\n",
 		GridHostname(),
 		GlobalSharedMemory::WorldShmRank,
 		XmitLoggingCounter,XmitLogVector.size(),
 		_xor, XmitLogVector[XmitLoggingCounter]); fflush(stderr);
 	if ( !ContinueOnFail ) assert(0);
 	ErrorCounter++;
      } else {
 	if ( PrintEntireLog ) { 
 	  std::cerr<<"FlightRecorder::XmitLog : VALID "<< XmitLoggingCounter <<" "<< std::hexfloat << _xor << " "<<  XmitLogVector[XmitLoggingCounter] <<std::endl;
 	}
      }
    }
    if ( XmitLogVector.size()==XmitLoggingCounter ) {
      std::cout << "FlightRecorder::ReductionLog : Verified entire sequence of "<<XmitLoggingCounter<<" sends "<<std::endl;
    }
    XmitLoggingCounter++;
  }
 #endif
  }
 }
 void FlightRecorder::recvLog(void *buf,uint64_t bytes,int rank)
 {
  if ( ChecksumComms ){
  uint64_t *ubuf = (uint64_t *)buf;
  if(LoggingMode == LoggingModeNone) return;
 #ifdef GRID_SYCL
  uint64_t _xor = svm_xor(ubuf,bytes/sizeof(uint64_t));
  if(LoggingMode == LoggingModePrint) {
    std::cerr<<"FlightRecorder::recvLog : "<< RecvLoggingCounter <<" "<< std::hex << _xor <<std::dec <<std::endl;
    RecvLoggingCounter++;
  }
  if(LoggingMode == LoggingModeRecord) {
    std::cerr<<"FlightRecorder::recvLog RECORD : "<< RecvLoggingCounter <<" "<< std::hex << _xor <<std::dec <<std::endl;
    RecvLogVector.push_back(_xor);
    RecvLoggingCounter++;
  }
  if(LoggingMode == LoggingModeVerify) {
    if(RecvLoggingCounter < RecvLogVector.size()){
      if ( _xor != RecvLogVector[RecvLoggingCounter] ) {
 	fprintf(stderr,"%s:%d Oops, recv buf difference! Reproduce failure for recv %d/%zu  %lx expect glb %lx from MPI rank %d\n",
 		GridHostname(),
 		GlobalSharedMemory::WorldShmRank,
 		RecvLoggingCounter,RecvLogVector.size(),
 		_xor, RecvLogVector[RecvLoggingCounter],rank); fflush(stderr);
 	if ( !ContinueOnFail ) assert(0);
 	ErrorCounter++;
      } else {
 	if ( PrintEntireLog ) { 
 	  std::cerr<<"FlightRecorder::RecvLog : VALID "<< RecvLoggingCounter <<" "<< std::hexfloat << _xor << " "<<  RecvLogVector[RecvLoggingCounter] <<std::endl;
 	}
      }
    }
    if ( RecvLogVector.size()==RecvLoggingCounter ) {
      std::cout << "FlightRecorder::ReductionLog : Verified entire sequence of "<<RecvLoggingCounter<<" sends "<<std::endl;
    }
    RecvLoggingCounter++;
  }
 #endif
  }
 }
 NAMESPACE_END(Grid);
--- a/Grid/util/FlightRecorder.h
+++ b/Grid/util/FlightRecorder.h
@@ -0,0 +1,43 @@
 #pragma once
 NAMESPACE_BEGIN(Grid);
 class FlightRecorder {
 public:
  enum LoggingMode_t {
    LoggingModeNone,
    LoggingModePrint,
    LoggingModeRecord,
    LoggingModeVerify
  };
  static int                   LoggingMode;
  static uint64_t              ErrorCounter;
  static int32_t               XmitLoggingCounter;
  static int32_t               RecvLoggingCounter;
  static int32_t               CsumLoggingCounter;
  static int32_t               NormLoggingCounter;
  static int32_t               ReductionLoggingCounter;
  static std::vector<uint64_t> XmitLogVector;
  static std::vector<uint64_t> RecvLogVector;
  static std::vector<uint64_t> CsumLogVector;
  static std::vector<double>   NormLogVector;
  static std::vector<double>   ReductionLogVector;
  static int ContinueOnFail;
  static int PrintEntireLog;
  static int ChecksumComms;
  static int ChecksumCommsSend;
  static void SetLoggingModePrint(void);
  static void SetLoggingModeRecord(void);
  static void SetLoggingModeVerify(void);
  static void SetLoggingMode(LoggingMode_t mode);
  static void NormLog(double value);
  static void CsumLog(uint64_t csum);
  static void ReductionLog(double lcl, double glbl);
  static void Truncate(void);
  static void ResetCounters(void);
  static uint64_t ErrorCount(void);
  static void xmitLog(void *,uint64_t bytes);
  static void recvLog(void *,uint64_t bytes,int rank);
 };
 NAMESPACE_END(Grid);
--- a/Grid/util/Init.cc
+++ b/Grid/util/Init.cc
@@ -94,7 +94,12 @@ int GridThread::_threads =1;
 int GridThread::_hyperthreads=1;
 int GridThread::_cores=1;
 char hostname[HOST_NAME_MAX+1];
 char *GridHostname(void)
 {
  return hostname;
 }
 const Coordinate &GridDefaultLatt(void)     {return Grid_default_latt;};
 const Coordinate &GridDefaultMpi(void)      {return Grid_default_mpi;};
 const Coordinate GridDefaultSimd(int dims,int nsimd)
@@ -287,6 +292,7 @@ void GridBanner(void)
    std::cout << "Build " << GRID_BUILD_STR(GRID_BUILD_REF) << std::endl;
 #endif
    std::cout << std::endl;
    std::cout << std::setprecision(9);
 }
 void Grid_init(int *argc,char ***argv)
@@ -397,7 +403,6 @@ void Grid_init(int *argc,char ***argv)
  std::cout << GridLogMessage << "MPI is initialised and logging filters activated "<<std::endl;
  std::cout << GridLogMessage << "================================================ "<<std::endl;
  char hostname[HOST_NAME_MAX+1];
  gethostname(hostname, HOST_NAME_MAX+1);
  std::cout << GridLogMessage << "This rank is running on host "<< hostname<<std::endl;
@@ -420,7 +425,7 @@ void Grid_init(int *argc,char ***argv)
  // Logging
  ////////////////////////////////////
  std::vector<std::string> logstreams;
-  std::string defaultLog("Error,Warning,Message,Performance");
+  std::string defaultLog("Error,Warning,Message");
  GridCmdOptionCSL(defaultLog,logstreams);
  GridLogConfigure(logstreams);
@@ -544,6 +549,10 @@ void Grid_init(int *argc,char ***argv)
 void Grid_finalize(void)
 {
  std::cout<<GridLogMessage<<"*******************************************"<<std::endl;
  std::cout<<GridLogMessage<<"******* Grid Finalize                ******"<<std::endl;
  std::cout<<GridLogMessage<<"*******************************************"<<std::endl;
 #if defined (GRID_COMMS_MPI) || defined (GRID_COMMS_MPI3) || defined (GRID_COMMS_MPIT)
  MPI_Barrier(MPI_COMM_WORLD);
  MPI_Finalize();
--- a/Grid/util/Init.h
+++ b/Grid/util/Init.h
@@ -34,6 +34,8 @@ NAMESPACE_BEGIN(Grid);
 void Grid_init(int *argc,char ***argv);
 void Grid_finalize(void);
 char * GridHostname(void);
 // internal, controled with --handle
 void Grid_sa_signal_handler(int sig,siginfo_t *si,void * ptr);
 void Grid_debug_handler_init(void);
@@ -68,5 +70,6 @@ void GridParseLayout(char **argv,int argc,
 void printHash(void);
 NAMESPACE_END(Grid);
--- a/Grid/util/Lexicographic.h
+++ b/Grid/util/Lexicographic.h
@@ -8,7 +8,7 @@ namespace Grid{
  public:
    template<class coor_t>
-    static accelerator_inline void CoorFromIndex (coor_t& coor,int index,const coor_t &dims){
+    static accelerator_inline void CoorFromIndex (coor_t& coor,int64_t index,const coor_t &dims){
      int nd= dims.size();
      coor.resize(nd);
      for(int d=0;d<nd;d++){
@@ -18,28 +18,45 @@ namespace Grid{
    }
    template<class coor_t>
-    static accelerator_inline void IndexFromCoor (const coor_t& coor,int &index,const coor_t &dims){
+    static accelerator_inline void IndexFromCoor (const coor_t& coor,int64_t &index,const coor_t &dims){
      int nd=dims.size();
      int stride=1;
      index=0;
      for(int d=0;d<nd;d++){
-	index = index+stride*coor[d];
+	index = index+(int64_t)stride*coor[d];
 	stride=stride*dims[d];
      }
    }
    template<class coor_t>
    static accelerator_inline void IndexFromCoor (const coor_t& coor,int &index,const coor_t &dims){
      int64_t index64;
      IndexFromCoor(coor,index64,dims);
      assert(index64<2*1024*1024*1024LL);
      index = (int) index64;
    }
    template<class coor_t>
-    static inline void IndexFromCoorReversed (const coor_t& coor,int &index,const coor_t &dims){
+    static inline void IndexFromCoorReversed (const coor_t& coor,int64_t &index,const coor_t &dims){
      int nd=dims.size();
      int stride=1;
      index=0;
      for(int d=nd-1;d>=0;d--){
-	index = index+stride*coor[d];
+	index = index+(int64_t)stride*coor[d];
 	stride=stride*dims[d];
      }
    }
    template<class coor_t>
-    static inline void CoorFromIndexReversed (coor_t& coor,int index,const coor_t &dims){
+    static inline void IndexFromCoorReversed (const coor_t& coor,int &index,const coor_t &dims){
      int64_t index64;
      IndexFromCoorReversed(coor,index64,dims);
      if ( index64>=2*1024*1024*1024LL ){
 	std::cout << " IndexFromCoorReversed " << coor<<" index " << index64<< " dims "<<dims<<std::endl;
      }
      assert(index64<2*1024*1024*1024LL);
      index = (int) index64;
    }
    template<class coor_t>
    static inline void CoorFromIndexReversed (coor_t& coor,int64_t index,const coor_t &dims){
      int nd= dims.size();
      coor.resize(nd);
      for(int d=nd-1;d>=0;d--){
--- a/Grid/util/Util.h
+++ b/Grid/util/Util.h
@@ -1,6 +1,6 @@
-#ifndef GRID_UTIL_H
+#pragma once
 #define GRID_UTIL_H
 #include <Grid/util/Coordinate.h>
 #include <Grid/util/Lexicographic.h>
 #include <Grid/util/Init.h>
-#endif
+#include <Grid/util/FlightRecorder.h>
--- a/HMC/site_autocorrelation.cc
+++ b/HMC/site_autocorrelation.cc
@@ -0,0 +1,90 @@
 /*************************************************************************************
 Grid physics library, www.github.com/paboyle/Grid
 Source file: 
 Copyright (C) 2017
 Author: Peter Boyle
 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.h>
 #include <string>
 template <class T> void readFile(T& out, std::string const fname){
  Grid::emptyUserRecord record;
  Grid::ScidacReader RD;
  RD.open(fname);
  RD.readScidacFieldRecord(out,record);
  RD.close();
 }
 int main(int argc, char **argv) {
  using namespace Grid;
  Grid_init(&argc, &argv);
  GridLogLayout();
  auto latt_size   = GridDefaultLatt();
  auto simd_layout = GridDefaultSimd(Nd, vComplex::Nsimd());
  auto mpi_layout  = GridDefaultMpi();
  GridCartesian               Grid(latt_size, simd_layout, mpi_layout);
  LatticeComplexD plaq1(&Grid), plaq2(&Grid);
  FieldMetaData header;
  double vol = plaq1.Grid()->gSites();
  std::string file1(argv[1]);
  std::cout << "Reading "<<file1<<std::endl;
  readFile(plaq1,file1);
  std::string file2(argv[2]);
  std::cout << "Reading "<<file2<<std::endl;
  readFile(plaq2,file2);
  auto p1bar = TensorRemove(sum(plaq1));
  auto p2bar = TensorRemove(sum(plaq2));
  p1bar = p1bar / vol;
  p2bar = p2bar / vol;
  std::cout<< GridLogMessage << "p1bar = "<<p1bar<<std::endl;
  std::cout<< GridLogMessage << "p2bar = "<<p2bar<<std::endl;
  auto corr_site = plaq1 * plaq2 - p1bar * p2bar;
  auto corr_bar  = TensorRemove(sum(corr_site))/vol;
  auto cov1_site = plaq1 * plaq1 - p1bar * p1bar;
  auto cov1_bar  = TensorRemove(sum(cov1_site))/vol;
  auto cov2_site = plaq2 * plaq2 - p2bar * p2bar;
  auto cov2_bar  = TensorRemove(sum(cov2_site))/vol;
  std::cout<< GridLogMessage << "cov_bar = "<<corr_bar<<std::endl;
  std::cout<< GridLogMessage << "corr_bar = "<<corr_bar/sqrt(cov1_bar*cov2_bar)<<std::endl;
  Grid_finalize();
 }  // main
--- a/HMC/site_plaquette.cc
+++ b/HMC/site_plaquette.cc
@@ -0,0 +1,79 @@
 /*************************************************************************************
 Grid physics library, www.github.com/paboyle/Grid
 Source file: 
 Copyright (C) 2017
 Author: Peter Boyle
 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.h>
 #include <string>
 NAMESPACE_BEGIN(Grid);
 template <class T> void writeFile(T& out, std::string const fname){
  emptyUserRecord record;
  ScidacWriter WR(out.Grid()->IsBoss());
  WR.open(fname);
  WR.writeScidacFieldRecord(out,record,0,Grid::BinaryIO::BINARYIO_LEXICOGRAPHIC);
  WR.close();
 }
 NAMESPACE_END(Grid);
 int main(int argc, char **argv) {
  using namespace Grid;
  Grid_init(&argc, &argv);
  GridLogLayout();
  auto latt_size   = GridDefaultLatt();
  auto simd_layout = GridDefaultSimd(Nd, vComplex::Nsimd());
  auto mpi_layout  = GridDefaultMpi();
  GridCartesian               Grid(latt_size, simd_layout, mpi_layout);
  LatticeGaugeField Umu(&Grid);
  std::vector<LatticeColourMatrix> U(4,&Grid);
  LatticeComplexD plaq(&Grid);
  FieldMetaData header;
  double vol = Umu.Grid()->gSites();
  double faces = (1.0 * Nd * (Nd - 1)) / 2.0;
  double Ncdiv = 1.0/Nc;
  std::string file1(argv[1]);
  std::string file2(argv[2]);
  std::cout << "Reading "<<file1<<std::endl;
  NerscIO::readConfiguration(Umu,header,file1);
  for(int mu=0;mu<Nd;mu++){
    U[mu] = PeekIndex<LorentzIndex>(Umu,mu);
  }
  SU3WilsonLoops::sitePlaquette(plaq,U);
  plaq = plaq *(Ncdiv/faces);
  std::cout << "Writing "<<file2<<std::endl;
  writeFile(plaq,file2);
  Grid_finalize();
 }  // main
--- a/49
+++ b/49
@@ -1,6 +1,50 @@
- - Slice sum optimisation & A2A - atomic addition
+i)    Refine subspace with HDCG & recompute
 ii)   Block Lanczos in coarse space
 iii)  Batched block project in the operator computation
 -------
 i) Clean up CoarsenedMatrix, GeneralCoarsenedMatrix, GeneralCoarsenedMatrixMultiRHS
 -- Ideally want a SINGLE implementation that does MultiRHS **AND** works with one RHS.
 -- -- Getting there. One RHS is hard due to vectorisation & hardwired coarse5d layout
 -- Compromise: Wrap it in a copy in/out for a slice.
 -- Bad for Lanczos: need to do a BLOCK Lanczos instead. Longer term.
 -- **** Make the test do ONLY the single RHS. ****
 -- I/O for the matrix elements required.
 -- Make the Adef2 build an eigenvector deflater and a block projector
 -- 
 -- Work with Regensburg on tests.
 -- Plan interface preserving the coarsened matrix interface (??)
 -- Move functionality from GeneralCoarsenedMatrix INTO GeneralCoarsenedMatrixMultiRHS -- DONE
   -- Don't immediately delete original
   -- Instead make the new one self contained, then delete.
   -- New DWF inverter test.
  // void PopulateAdag(void)
  void CoarsenOperator(LinearOperatorBase<Lattice<Fobj> > &linop, Aggregation<Fobj,CComplex,nbasis> & Subspace) -- DONE
  ExchangeCoarseLinks();
 iii) Aurora -- christoph's problem -- DONE
     Aurora -- Carleton's problem staggered.
 iv) Dennis merge and test Aurora -- DONE (save test)
 v) Merge Ed Bennet's request --DONE 
 vi) Repro CG  -- get down to the level of single node testing via split grid test 
 =========================
 ===============
 - - Slice sum optimisation & A2A - atomic addition -- Dennis
 - - Also faster non-atomic reduction
 - - Remaining PRs
 - - DDHMC
  - - MixedPrec is the action eval, high precision
  - - MixedPrecCleanup is the force eval, low precision
@@ -17,7 +61,6 @@ DDHMC
 -- Multishift Mixed Precision - DONE
 -- Pole dependent residual  - DONE
 =======
 -- comms threads issue??
 -- Part done: Staggered kernel performance on GPU
--- a/configure.ac
+++ b/configure.ac
@@ -226,23 +226,14 @@ case ${ac_SFW_FP16} in
 esac
 ############### Default to accelerator cshift, but revert to host if UCX is buggy or other reasons
-AC_ARG_ENABLE([accelerator-cshift],
+AC_ARG_ENABLE([accelerator-aware-mpi],
-    [AS_HELP_STRING([--enable-accelerator-cshift=yes|no],[run cshift on the device])],
+    [AS_HELP_STRING([--enable-accelerator-aware-mpi=yes|no],[run mpi transfers from device])],
-    [ac_ACC_CSHIFT=${enable_accelerator_cshift}], [ac_ACC_CSHIFT=yes])
+    [ac_ACCELERATOR_AWARE_MPI=${enable_accelerator_aware_mpi}], [ac_ACCELERATOR_AWARE_MPI=yes])
-AC_ARG_ENABLE([ucx-buggy],
+case ${ac_ACCELERATOR_AWARE_MPI} in
    [AS_HELP_STRING([--enable-ucx-buggy=yes|no],[enable workaround for UCX device buffer bugs])],
    [ac_UCXBUGGY=${enable_ucx_buggy}], [ac_UCXBUGGY=no])
 case ${ac_UCXBUGGY} in
    yes)
-    ac_ACC_CSHIFT=no;;
+      AC_DEFINE([ACCELERATOR_CSHIFT],[1],[ Cshift runs on host])
-    *);;
+      AC_DEFINE([ACCELERATOR_AWARE_MPI],[1],[ Stencil can use device pointers]);;
 esac
 case ${ac_ACC_CSHIFT} in
    yes)
      AC_DEFINE([ACCELERATOR_CSHIFT],[1],[ UCX device buffer bugs are not present]);;
    *);;
 esac
--- a/scripts/prequisites.sh
+++ b/scripts/prequisites.sh
@@ -0,0 +1,44 @@
 #!/bin/bash
 if [ $1 = "install" ]
 then
    dir=`pwd`
    cd $HOME
    git clone -c feature.manyFiles=true https://github.com/spack/spack.git
    source $HOME/spack/share/spack/setup-env.sh
    spack install autoconf
    spack install automake
    spack install c-lime cppflags=-fPIE
    spack install fftw
    spack install llvm
    spack install gmp
    spack install mpfr
    spack install cuda@11.8
    spack install openmpi
    spack install openssl
    spack install hdf5
 else
    source $HOME/spack/share/spack/setup-env.sh
 fi
 spack load autoconf
 spack load automake
 spack load c-lime
 spack load fftw
 spack load llvm
 spack load gmp
 spack load mpfr
 spack load cuda@11.8
 spack load openmpi
 spack load openssl
 spack load hdf5
 export FFTW=`spack find --paths fftw    | grep ^fftw   | awk '{print $2}' `
 export HDF5=`spack find --paths hdf5    | grep ^hdf5   | awk '{print $2}' `
 export CLIME=`spack find --paths c-lime | grep ^c-lime | awk '{print $2}' `
 export MPFR=`spack find --paths mpfr    | grep ^mpfr  | awk '{print $2}' `
 export GMP=`spack find --paths gmp      | grep ^gmp | awk '{print $2}' `
 export NVIDIA=$CUDA_HOME
 export NVIDIALIB=$NVIDIA/targets/x86_64-linux/lib/
 export LD_LIBRARY_PATH=$NVIDIALIB:$FFTW/lib/:$MPFR/lib:$LD_LIBRARY_PATH
--- a/systems/Aurora/config-command
+++ b/systems/Aurora/config-command
@@ -1,16 +1,16 @@
-TOOLS=$HOME/tools
+
 ../../configure \
 	--enable-simd=GPU \
 	--enable-gen-simd-width=64 \
 	--enable-comms=mpi-auto \
 	--enable-accelerator-cshift \
 	--disable-gparity \
 	--disable-fermion-reps \
 	--enable-shm=nvlink \
 	--enable-accelerator=sycl \
 	--enable-accelerator-aware-mpi=no\
 	--enable-unified=no \
 	MPICXX=mpicxx \
 	CXX=icpx \
-	LDFLAGS="-fiopenmp -fsycl -fsycl-device-code-split=per_kernel -fsycl-device-lib=all -lze_loader -L$TOOLS/lib64/ -L${MKLROOT}/lib -qmkl=parallel " \
+	LDFLAGS="-fiopenmp -fsycl -fsycl-device-code-split=per_kernel -fsycl-device-lib=all -lze_loader -L${MKLROOT}/lib -qmkl=parallel -lsycl" \
-	CXXFLAGS="-fiopenmp -fsycl-unnamed-lambda -fsycl -I$INSTALL/include -Wno-tautological-compare -I$HOME/ -I$TOOLS/include -qmkl=parallel"
+	CXXFLAGS="-fiopenmp -fsycl-unnamed-lambda -fsycl -I$INSTALL/include -Wno-tautological-compare -I$HOME/ -qmkl=parallel"
--- a/systems/Aurora/sourceme-sunspot-deterministic.sh
+++ b/systems/Aurora/sourceme-sunspot-deterministic.sh
@@ -0,0 +1,2 @@
 module load oneapi/eng-compiler/2023.05.15.003
 module load mpich/51.2/icc-all-deterministic-pmix-gpu
--- a/systems/Aurora/tests/repro128.pbs
+++ b/systems/Aurora/tests/repro128.pbs
@@ -0,0 +1,41 @@
 #!/bin/bash
 ## qsub -q EarlyAppAccess -A Aurora_Deployment -I -l select=1 -l walltime=60:00
 #PBS -q EarlyAppAccess
 #PBS -l select=128
 #PBS -l walltime=02:00:00
 #PBS -A LatticeQCD_aesp_CNDA
 #export OMP_PROC_BIND=spread
 #unset OMP_PLACES
 cd $PBS_O_WORKDIR
 source ../sourceme.sh
 cat $PBS_NODEFILE
 export OMP_NUM_THREADS=3
 export MPIR_CVAR_CH4_OFI_ENABLE_GPU_PIPELINE=1
 #unset MPIR_CVAR_CH4_OFI_GPU_PIPELINE_D2H_ENGINE_TYPE
 #unset MPIR_CVAR_CH4_OFI_GPU_PIPELINE_H2D_ENGINE_TYPE
 #unset MPIR_CVAR_GPU_USE_IMMEDIATE_COMMAND_LIST
 export MPIR_CVAR_CH4_OFI_GPU_PIPELINE_D2H_ENGINE_TYPE=0
 export MPIR_CVAR_CH4_OFI_GPU_PIPELINE_H2D_ENGINE_TYPE=0
 export MPIR_CVAR_GPU_USE_IMMEDIATE_COMMAND_LIST=1
 export MPIR_CVAR_CH4_OFI_GPU_PIPELINE_BUFFER_SZ=1048576
 export MPIR_CVAR_CH4_OFI_GPU_PIPELINE_THRESHOLD=131072
 export MPIR_CVAR_CH4_OFI_GPU_PIPELINE_NUM_BUFFERS_PER_CHUNK=16
 export MPIR_CVAR_CH4_OFI_GPU_PIPELINE_MAX_NUM_BUFFERS=16
 export MPICH_OFI_NIC_POLICY=GPU
 # 12 ppn, 16 nodes, 192 ranks
 # 12 ppn, 128 nodes, 1536 ranks
 CMD="mpiexec -np 1536 -ppn 12  -envall \
 	     ./gpu_tile_compact.sh \
 	     ./Test_dwf_mixedcg_prec --mpi 4.4.4.24 --grid 128.128.128.384 \
 		--shm-mpi 1 --shm 4096 --device-mem 32000 --accelerator-threads 32 --seconds 7000 --comms-overlap "
 $CMD 
--- a/systems/Aurora/tests/repro16.pbs
+++ b/systems/Aurora/tests/repro16.pbs
@@ -2,26 +2,39 @@
 ## qsub -q EarlyAppAccess -A Aurora_Deployment -I -l select=1 -l walltime=60:00
-#PBS -q EarlyAppAccess
+#PBS -l select=16:system=sunspot,place=scatter
 #PBS -l select=16
 #PBS -l walltime=01:00:00
 #PBS -A LatticeQCD_aesp_CNDA
 #PBS -l walltime=01:00:00
 #PBS -N dwf
 #PBS -k doe
 #export OMP_PROC_BIND=spread
 #unset OMP_PLACES
 cd $PBS_O_WORKDIR
-source ../sourceme.sh
+#source ../sourceme.sh
 cat $PBS_NODEFILE
 #export MPICH_COLL_SYNC=1
 #export MPICH_ENV_DISPLAY=1
 export MPICH_
 export OMP_NUM_THREADS=3
 export MPIR_CVAR_CH4_OFI_ENABLE_GPU_PIPELINE=1
 module load oneapi/eng-compiler/2023.05.15.003
 module load mpich/51.2/icc-all-deterministic-pmix-gpu
 #export LD_LIBRARY_PATH=/soft/restricted/CNDA/updates/2023.05.15.001/oneapi/compiler/eng-20230512/compiler/linux/lib/:$LD_LIBRARY_PATH
 #unset MPIR_CVAR_CH4_OFI_GPU_PIPELINE_D2H_ENGINE_TYPE
 #unset MPIR_CVAR_CH4_OFI_GPU_PIPELINE_H2D_ENGINE_TYPE
 #unset MPIR_CVAR_GPU_USE_IMMEDIATE_COMMAND_LIST
 export MPIR_CVAR_ALLREDUCE_DEVICE_COLLECTIVE=0
 export MPIR_CVAR_REDUCE_DEVICE_COLLECTIVE=0
 export MPIR_CVAR_ALLREDUCE_INTRA_ALGORITHM=recursive_doubling
 unset MPIR_CVAR_CH4_COLL_SELECTION_TUNING_JSON_FILE
 unset MPIR_CVAR_COLL_SELECTION_TUNING_JSON_FILE
 unset MPIR_CVAR_CH4_POSIX_COLL_SELECTION_TUNING_JSON_FILE
 export MPIR_CVAR_CH4_OFI_GPU_PIPELINE_D2H_ENGINE_TYPE=0
 export MPIR_CVAR_CH4_OFI_GPU_PIPELINE_H2D_ENGINE_TYPE=0
@@ -32,9 +45,17 @@ export MPIR_CVAR_CH4_OFI_GPU_PIPELINE_NUM_BUFFERS_PER_CHUNK=16
 export MPIR_CVAR_CH4_OFI_GPU_PIPELINE_MAX_NUM_BUFFERS=16
 export MPICH_OFI_NIC_POLICY=GPU
-# 12 ppn, 16 nodes, 192 ranks
+DIR=repro.$PBS_JOBID
 mkdir $DIR
 cd $DIR
 CMD="mpiexec -np 192 -ppn 12  -envall \
-	     ./gpu_tile_compact.sh \
+	     ../gpu_tile_compact.sh \
-	     ./Test_dwf_mixedcg_prec --mpi 2.4.4.6 --grid 64.128.128.192 \
+	     ../Test_dwf_mixedcg_prec --mpi 2.4.4.6 --grid 64.128.128.192 \
-		--shm-mpi 1 --shm 4096 --device-mem 32000 --accelerator-threads 32 --seconds 3000"
+		--shm-mpi 1 --shm 4096 --device-mem 32000 --accelerator-threads 32 --seconds 3000 --debug-stdout --log Message,Iterative"
 #--comms-overlap
 $CMD 
 grep Oops Grid.stderr.* > failures.$PBS_JOBID
 rm core.*
--- a/systems/Aurora/tests/repro1gpu.pbs
+++ b/systems/Aurora/tests/repro1gpu.pbs
@@ -0,0 +1,82 @@
 #!/bin/bash
 #PBS -l select=16:system=sunspot,place=scatter
 #PBS -A LatticeQCD_aesp_CNDA
 #PBS -l walltime=02:00:00
 #PBS -N repro1gpu
 #PBS -k doe
 #export OMP_PROC_BIND=spread
 #unset OMP_PLACES
 module load oneapi/eng-compiler/2023.05.15.003
 module load mpich/51.2/icc-all-deterministic-pmix-gpu
 # 56 cores / 6 threads ~9
 export OMP_NUM_THREADS=6
 export MPIR_CVAR_CH4_OFI_ENABLE_GPU_PIPELINE=1
 export MPIR_CVAR_CH4_OFI_GPU_PIPELINE_D2H_ENGINE_TYPE=0
 export MPIR_CVAR_CH4_OFI_GPU_PIPELINE_H2D_ENGINE_TYPE=0
 export MPIR_CVAR_GPU_USE_IMMEDIATE_COMMAND_LIST=1
 export MPIR_CVAR_CH4_OFI_GPU_PIPELINE_BUFFER_SZ=1048576
 export MPIR_CVAR_CH4_OFI_GPU_PIPELINE_THRESHOLD=131072
 export MPIR_CVAR_CH4_OFI_GPU_PIPELINE_NUM_BUFFERS_PER_CHUNK=16
 export MPIR_CVAR_CH4_OFI_GPU_PIPELINE_MAX_NUM_BUFFERS=16
 export MPICH_OFI_NIC_POLICY=GPU
 export MPIR_CVAR_ALLREDUCE_DEVICE_COLLECTIVE=0
 export MPIR_CVAR_REDUCE_DEVICE_COLLECTIVE=0
 export MPIR_CVAR_ALLREDUCE_INTRA_ALGORITHM=recursive_doubling
 unset MPIR_CVAR_CH4_COLL_SELECTION_TUNING_JSON_FILE
 unset MPIR_CVAR_COLL_SELECTION_TUNING_JSON_FILE
 unset MPIR_CVAR_CH4_POSIX_COLL_SELECTION_TUNING_JSON_FILE
 export SYCL_PROGRAM_COMPILE_OPTIONS="-ze-opt-large-register-file"
 cd $PBS_O_WORKDIR
 NN=`cat $PBS_NODEFILE | wc -l`
 echo $PBS_NODEFILE
 cat $PBS_NODEFILE
 echo $NN nodes in node file
 for n in `eval echo {1..$NN}`
 do
 THIS_NODE=`head -n$n $PBS_NODEFILE | tail -n1 `
 echo Node $n is $THIS_NODE
 for g in {0..11}
 do
 export NUMA_MAP=(0 0 0 1 1 1 0 0 0 1 1 1 )
 export TILE_MAP=(0 0 0 0 0 0 1 1 1 1 1 1 )
 export  GPU_MAP=(0 1 2 3 4 5 0 1 2 3 4 5 )
 export numa=${NUMA_MAP[$g]}
 export gpu_id=${GPU_MAP[$g]}
 export tile_id=${TILE_MAP[$g]}
 export gpu=$gpu_id.$tile_id
 cd $PBS_O_WORKDIR
 DIR=repro.1gpu.$PBS_JOBID/node-$n-$THIS_NODE-GPU-$gpu
 mkdir -p $DIR
 cd $DIR
 echo $THIS_NODE > nodefile
 echo $gpu > gpu
 export ZE_AFFINITY_MASK=$gpu
 export ONEAPI_DEVICE_FILTER=gpu,level_zero
 CMD="mpiexec -np 1 -ppn 1  -envall --hostfile nodefile \
 	     numactl -N $numa -m $numa ../../Test_dwf_mixedcg_prec --mpi 1.1.1.1 --grid 16.16.32.32 \
 		--shm-mpi 0 --shm 4096 --device-mem 32000 --accelerator-threads 32 --seconds 6000 --debug-stdout --log Message"
 echo $CMD
 $CMD &
 done
 done
 wait
--- a/systems/Aurora/tests/reproN.pbs
+++ b/systems/Aurora/tests/reproN.pbs
@@ -0,0 +1,98 @@
 #!/bin/bash
 #PBS -l select=32:system=sunspot,place=scatter
 #PBS -A LatticeQCD_aesp_CNDA
 #PBS -l walltime=02:00:00
 #PBS -N reproN
 #PBS -k doe
 #export OMP_PROC_BIND=spread
 #unset OMP_PLACES
 module load oneapi/eng-compiler/2023.05.15.003
 module load mpich/51.2/icc-all-deterministic-pmix-gpu
 # 56 cores / 6 threads ~9
 export OMP_NUM_THREADS=6
 export MPIR_CVAR_CH4_OFI_ENABLE_GPU_PIPELINE=1
 #export MPIR_CVAR_CH4_OFI_GPU_PIPELINE_D2H_ENGINE_TYPE=0
 #export MPIR_CVAR_CH4_OFI_GPU_PIPELINE_H2D_ENGINE_TYPE=0
 #export MPIR_CVAR_CH4_OFI_GPU_PIPELINE_BUFFER_SZ=1048576
 #export MPIR_CVAR_CH4_OFI_GPU_PIPELINE_THRESHOLD=131072
 #export MPIR_CVAR_CH4_OFI_GPU_PIPELINE_NUM_BUFFERS_PER_CHUNK=16
 #export MPIR_CVAR_CH4_OFI_GPU_PIPELINE_MAX_NUM_BUFFERS=16
 #export MPIR_CVAR_GPU_USE_IMMEDIATE_COMMAND_LIST=1
 export SYCL_PI_LEVEL_ZERO_USE_IMMEDIATE_COMMANDLISTS=1
 export SYCL_PI_LEVEL_ZERO_USE_COPY_ENGINE=1
 export SYCL_PI_LEVEL_ZERO_USE_COPY_ENGINE_FOR_D2D_COPY=1
 export SYCL_PROGRAM_COMPILE_OPTIONS="-ze-opt-large-register-file"
 export GRID_PRINT_ENTIRE_LOG=0
 export GRID_CHECKSUM_RECV_BUF=0
 export GRID_CHECKSUM_SEND_BUF=0
 export MPICH_OFI_NIC_POLICY=GPU
 export MPIR_CVAR_ALLREDUCE_DEVICE_COLLECTIVE=0
 export MPIR_CVAR_REDUCE_DEVICE_COLLECTIVE=0
 export MPIR_CVAR_ALLREDUCE_INTRA_ALGORITHM=recursive_doubling
 unset MPIR_CVAR_CH4_COLL_SELECTION_TUNING_JSON_FILE
 unset MPIR_CVAR_COLL_SELECTION_TUNING_JSON_FILE
 unset MPIR_CVAR_CH4_POSIX_COLL_SELECTION_TUNING_JSON_FILE
 cd $PBS_O_WORKDIR
 NN=`cat $PBS_NODEFILE | wc -l`
 echo $PBS_NODEFILE
 cat $PBS_NODEFILE
 echo $NN nodes in node file
 for n in `eval echo {1..$NN}`
 do
 cd $PBS_O_WORKDIR
 THIS_NODE=`head -n$n $PBS_NODEFILE | tail -n1 `
 echo Node $n is $THIS_NODE
 DIR=reproN.$PBS_JOBID/node-$n-$THIS_NODE
 mkdir -p $DIR
 cd $DIR
 echo $THIS_NODE > nodefile
 #CMD="mpiexec -np 12 -ppn 12  -envall --hostfile nodefile \
 #	     ../../gpu_tile_compact.sh \
 #	     ../../Test_dwf_mixedcg_prec --mpi 1.2.2.3 --grid 32.64.64.96 \
 #		--shm-mpi 0 --shm 4096 --device-mem 32000 --accelerator-threads 32 --seconds 6000 --debug-stdout --log Message --comms-overlap"
 CMD="mpiexec -np 12 -ppn 12  -envall --hostfile nodefile \
 	     ../../gpu_tile_compact.sh \
 	     ../../Test_dwf_mixedcg_prec --mpi 1.2.2.3 --grid 32.64.64.96 \
 		--shm-mpi 1 --shm 4096 --device-mem 32000 --accelerator-threads 32 --seconds 6000 --debug-stdout --log Message --comms-overlap"
 echo $CMD > command-line
 env > environment
 $CMD &
 done
 # Suspicious wait is allowing jobs to collide and knock out
 #wait
 sleep 6500
 for n in ` eval echo {1..$NN} `
 do
 THIS_NODE=`head -n$n $PBS_NODEFILE | tail -n1 `
 DIR=reproN.$PBS_JOBID/node-$n-$THIS_NODE
 cd $DIR
 grep Oops Grid.stderr.* > failures.$PBS_JOBID
 rm core.*
 done
--- a/systems/Aurora/tests/solver/stag16.pbs
+++ b/systems/Aurora/tests/solver/stag16.pbs
@@ -36,5 +36,5 @@ export MPICH_OFI_NIC_POLICY=GPU
 CMD="mpiexec -np 192 -ppn 12  -envall \
 	     ./gpu_tile_compact.sh \
 	     ./Test_staggered_cg_prec --mpi 2.4.4.6 --grid 128.128.128.192 \
-	     --shm-mpi 1 --shm 4096 --device-mem 32000 --accelerator-threads 32 --seconds 3000"
+	     --shm-mpi 1 --shm 4096 --device-mem 32000 --accelerator-threads 32 --seconds 3000 --comms-overlap"
 $CMD 
--- a/systems/Frontier/benchmarks/bench2.slurm
+++ b/systems/Frontier/benchmarks/bench2.slurm
@@ -0,0 +1,43 @@
 #!/bin/bash -l
 #SBATCH --job-name=bench
 ##SBATCH --partition=small-g
 #SBATCH --nodes=2
 #SBATCH --ntasks-per-node=8
 #SBATCH --cpus-per-task=7
 #SBATCH --gpus-per-node=8
 #SBATCH --time=00:10:00
 #SBATCH --account=phy157_dwf
 #SBATCH --gpu-bind=none
 #SBATCH --exclusive
 #SBATCH --mem=0
 cat << EOF > select_gpu
 #!/bin/bash
 export GPU_MAP=(0 1 2 3 7 6 5 4)
 export NUMA_MAP=(3 3 1 1 2 2 0 0)
 export GPU=\${GPU_MAP[\$SLURM_LOCALID]}
 export NUMA=\${NUMA_MAP[\$SLURM_LOCALID]}
 export HIP_VISIBLE_DEVICES=\$GPU
 unset ROCR_VISIBLE_DEVICES
 echo RANK \$SLURM_LOCALID using GPU \$GPU    
 exec numactl -m \$NUMA -N \$NUMA \$*
 EOF
 chmod +x ./select_gpu
 root=$HOME/Frontier/Grid/systems/Frontier/
 source ${root}/sourceme.sh
 export OMP_NUM_THREADS=7
 export MPICH_GPU_SUPPORT_ENABLED=1
 export MPICH_SMP_SINGLE_COPY_MODE=XPMEM
 for vol in 32.32.32.64
 do
 srun ./select_gpu ./Benchmark_dwf_fp32 --mpi 2.2.2.2 --accelerator-threads 8 --comms-overlap --shm 2048 --shm-mpi 0 --grid $vol  > log.shm0.ov.$vol
 srun ./select_gpu ./Benchmark_dwf_fp32 --mpi 2.2.2.2 --accelerator-threads 8 --comms-overlap --shm 2048 --shm-mpi 1 --grid $vol  > log.shm1.ov.$vol
 srun ./select_gpu ./Benchmark_dwf_fp32 --mpi 2.2.2.2 --accelerator-threads 8 --comms-sequential --shm 2048 --shm-mpi 0 --grid $vol  > log.shm0.seq.$vol
 srun ./select_gpu ./Benchmark_dwf_fp32 --mpi 2.2.2.2 --accelerator-threads 8 --comms-sequential --shm 2048 --shm-mpi 1 --grid $vol > log.shm1.seq.$vol
 done
--- a/systems/Frontier/config-command
+++ b/systems/Frontier/config-command
@@ -15,8 +15,8 @@ CLIME=`spack find --paths c-lime@2-3-9 | grep c-lime| cut -c 15-`
 --with-mpfr=/opt/cray/pe/gcc/mpfr/3.1.4/ \
 --disable-fermion-reps \
 CXX=hipcc MPICXX=mpicxx \
-CXXFLAGS="-fPIC -I{$ROCM_PATH}/include/ -I${MPICH_DIR}/include -L/lib64 -fgpu-sanitize" \
+CXXFLAGS="-fPIC -I{$ROCM_PATH}/include/ -I${MPICH_DIR}/include -L/lib64 " \
- LDFLAGS="-L/lib64 -L${MPICH_DIR}/lib -lmpi -L${CRAY_MPICH_ROOTDIR}/gtl/lib -lmpi_gtl_hsa -lamdhip64  -lhipblas -lrocblas"
+ LDFLAGS="-L/lib64 -L${MPICH_DIR}/lib -lmpi -L${CRAY_MPICH_ROOTDIR}/gtl/lib -lmpi_gtl_hsa -lamdhip64 -lhipblas -lrocblas"
--- a/systems/Frontier/mpiwrapper.sh
+++ b/systems/Frontier/mpiwrapper.sh
@@ -0,0 +1,13 @@
 #!/bin/bash
 lrank=$SLURM_LOCALID
 lgpu=(0 1 2 3 7 6 5 4)
 export ROCR_VISIBLE_DEVICES=${lgpu[$lrank]}
 echo "`hostname` - $lrank device=$ROCR_VISIBLE_DEVICES "
 $*
--- a/systems/Frontier/sourceme.sh
+++ b/systems/Frontier/sourceme.sh
@@ -1,6 +1,5 @@
 . /autofs/nccs-svm1_home1/paboyle/Crusher/Grid/spack/share/spack/setup-env.sh
 spack load c-lime
 #export LD_LIBRARY_PATH=$LD_LIBRARY_PATH:/sw/crusher/spack-envs/base/opt/cray-sles15-zen3/gcc-11.2.0/gperftools-2.9.1-72ubwtuc5wcz2meqltbfdb76epufgzo2/lib
 module load emacs 
 module load PrgEnv-gnu
 module load rocm
--- a/systems/Frontier/wrap.sh
+++ b/systems/Frontier/wrap.sh
@@ -0,0 +1,9 @@
 #!/bin/sh
 export HIP_VISIBLE_DEVICES=$ROCR_VISIBLE_DEVICES
 unset ROCR_VISIBLE_DEVICES
 #rank=$SLURM_PROCID
 #rocprof -d rocprof.$rank -o rocprof.$rank/results.rank$SLURM_PROCID.csv --sys-trace $@
 $@
--- a/systems/Sunspot/config-command
+++ b/systems/Sunspot/config-command
@@ -1,4 +1,4 @@
-TOOLS=$HOME/tools
+
 ../../configure \
 	--enable-simd=GPU \
 	--enable-gen-simd-width=64 \
@@ -11,6 +11,6 @@ TOOLS=$HOME/tools
 	--enable-unified=no \
 	MPICXX=mpicxx \
 	CXX=icpx \
-	LDFLAGS="-fiopenmp -fsycl -fsycl-device-code-split=per_kernel -fsycl-device-lib=all -lze_loader -L$TOOLS/lib64/" \
+	LDFLAGS="-fiopenmp -fsycl -fsycl-device-code-split=per_kernel -fsycl-device-lib=all -lze_loader -L${MKLROOT}/lib -qmkl=parallel -lsycl" \
-	CXXFLAGS="-fiopenmp -fsycl-unnamed-lambda -fsycl -I$INSTALL/include -Wno-tautological-compare -I$HOME/ -I$TOOLS/include"
+	CXXFLAGS="-fiopenmp -fsycl-unnamed-lambda -fsycl -I$INSTALL/include -Wno-tautological-compare -I$HOME/ -qmkl=parallel"
--- a/systems/Sunspot/sourceme.sh
+++ b/systems/Sunspot/sourceme.sh
@@ -0,0 +1,2 @@
 module load oneapi/eng-compiler/2023.05.15.003
 module load mpich/51.2/icc-all-deterministic-pmix-gpu
--- a/systems/Sunspot/tests/repro1gpu.pbs
+++ b/systems/Sunspot/tests/repro1gpu.pbs
@@ -0,0 +1,81 @@
 #!/bin/bash
 #PBS -l select=16:system=sunspot,place=scatter
 #PBS -A LatticeQCD_aesp_CNDA
 #PBS -l walltime=02:00:00
 #PBS -N repro1gpu
 #PBS -k doe
 #export OMP_PROC_BIND=spread
 #unset OMP_PLACES
 module load oneapi/eng-compiler/2023.05.15.003
 module load mpich/51.2/icc-all-deterministic-pmix-gpu
 # 56 cores / 6 threads ~9
 export OMP_NUM_THREADS=6
 export MPIR_CVAR_CH4_OFI_ENABLE_GPU_PIPELINE=1
 export MPIR_CVAR_CH4_OFI_GPU_PIPELINE_D2H_ENGINE_TYPE=0
 export MPIR_CVAR_CH4_OFI_GPU_PIPELINE_H2D_ENGINE_TYPE=0
 export MPIR_CVAR_GPU_USE_IMMEDIATE_COMMAND_LIST=1
 export MPIR_CVAR_CH4_OFI_GPU_PIPELINE_BUFFER_SZ=1048576
 export MPIR_CVAR_CH4_OFI_GPU_PIPELINE_THRESHOLD=131072
 export MPIR_CVAR_CH4_OFI_GPU_PIPELINE_NUM_BUFFERS_PER_CHUNK=16
 export MPIR_CVAR_CH4_OFI_GPU_PIPELINE_MAX_NUM_BUFFERS=16
 export MPICH_OFI_NIC_POLICY=GPU
 export MPIR_CVAR_ALLREDUCE_DEVICE_COLLECTIVE=0
 export MPIR_CVAR_REDUCE_DEVICE_COLLECTIVE=0
 export MPIR_CVAR_ALLREDUCE_INTRA_ALGORITHM=recursive_doubling
 unset MPIR_CVAR_CH4_COLL_SELECTION_TUNING_JSON_FILE
 unset MPIR_CVAR_COLL_SELECTION_TUNING_JSON_FILE
 unset MPIR_CVAR_CH4_POSIX_COLL_SELECTION_TUNING_JSON_FILE
 cd $PBS_O_WORKDIR
 NN=`cat $PBS_NODEFILE | wc -l`
 echo $PBS_NODEFILE
 cat $PBS_NODEFILE
 echo $NN nodes in node file
 for n in `eval echo {1..$NN}`
 do
 THIS_NODE=`head -n$n $PBS_NODEFILE | tail -n1 `
 echo Node $n is $THIS_NODE
 for g in {0..11}
 do
 export NUMA_MAP=(0 0 0 1 1 1 0 0 0 1 1 1 )
 export TILE_MAP=(0 0 0 0 0 0 1 1 1 1 1 1 )
 export  GPU_MAP=(0 1 2 3 4 5 0 1 2 3 4 5 )
 export numa=${NUMA_MAP[$g]}
 export gpu_id=${GPU_MAP[$g]}
 export tile_id=${TILE_MAP[$g]}
 export gpu=$gpu_id.$tile_id
 cd $PBS_O_WORKDIR
 DIR=repro.1gpu.$PBS_JOBID/node-$n-$THIS_NODE-GPU-$gpu
 mkdir -p $DIR
 cd $DIR
 echo $THIS_NODE > nodefile
 echo $gpu > gpu
 export ZE_AFFINITY_MASK=$gpu
 export ONEAPI_DEVICE_FILTER=gpu,level_zero
 CMD="mpiexec -np 1 -ppn 1  -envall --hostfile nodefile \
 	     numactl -N $numa -m $numa ../../Test_dwf_mixedcg_prec --mpi 1.1.1.1 --grid 16.16.32.32 \
 		--shm-mpi 0 --shm 4096 --device-mem 32000 --accelerator-threads 32 --seconds 6000 --debug-stdout --log Message"
 echo $CMD
 $CMD &
 done
 done
 wait
--- a/systems/Sunspot/tests/reproN.pbs
+++ b/systems/Sunspot/tests/reproN.pbs
@@ -0,0 +1,97 @@
 #!/bin/bash
 #PBS -l select=32:system=sunspot,place=scatter
 #PBS -A LatticeQCD_aesp_CNDA
 #PBS -l walltime=02:00:00
 #PBS -N reproN
 #PBS -k doe
 #export OMP_PROC_BIND=spread
 #unset OMP_PLACES
 module load oneapi/eng-compiler/2023.05.15.003
 module load mpich/51.2/icc-all-deterministic-pmix-gpu
 # 56 cores / 6 threads ~9
 export OMP_NUM_THREADS=6
 export MPIR_CVAR_CH4_OFI_ENABLE_GPU_PIPELINE=1
 #export MPIR_CVAR_CH4_OFI_GPU_PIPELINE_D2H_ENGINE_TYPE=0
 #export MPIR_CVAR_CH4_OFI_GPU_PIPELINE_H2D_ENGINE_TYPE=0
 #export MPIR_CVAR_CH4_OFI_GPU_PIPELINE_BUFFER_SZ=1048576
 #export MPIR_CVAR_CH4_OFI_GPU_PIPELINE_THRESHOLD=131072
 #export MPIR_CVAR_CH4_OFI_GPU_PIPELINE_NUM_BUFFERS_PER_CHUNK=16
 #export MPIR_CVAR_CH4_OFI_GPU_PIPELINE_MAX_NUM_BUFFERS=16
 #export MPIR_CVAR_GPU_USE_IMMEDIATE_COMMAND_LIST=1
 export SYCL_PI_LEVEL_ZERO_USE_IMMEDIATE_COMMANDLISTS=1
 export SYCL_PI_LEVEL_ZERO_USE_COPY_ENGINE=1
 export SYCL_PI_LEVEL_ZERO_USE_COPY_ENGINE_FOR_D2D_COPY=1
 export GRID_PRINT_ENTIRE_LOG=0
 export GRID_CHECKSUM_RECV_BUF=1
 export GRID_CHECKSUM_SEND_BUF=0
 export MPICH_OFI_NIC_POLICY=GPU
 export MPIR_CVAR_ALLREDUCE_DEVICE_COLLECTIVE=0
 export MPIR_CVAR_REDUCE_DEVICE_COLLECTIVE=0
 export MPIR_CVAR_ALLREDUCE_INTRA_ALGORITHM=recursive_doubling
 unset MPIR_CVAR_CH4_COLL_SELECTION_TUNING_JSON_FILE
 unset MPIR_CVAR_COLL_SELECTION_TUNING_JSON_FILE
 unset MPIR_CVAR_CH4_POSIX_COLL_SELECTION_TUNING_JSON_FILE
 cd $PBS_O_WORKDIR
 NN=`cat $PBS_NODEFILE | wc -l`
 echo $PBS_NODEFILE
 cat $PBS_NODEFILE
 echo $NN nodes in node file
 for n in `eval echo {1..$NN}`
 do
 cd $PBS_O_WORKDIR
 THIS_NODE=`head -n$n $PBS_NODEFILE | tail -n1 `
 echo Node $n is $THIS_NODE
 DIR=reproN.$PBS_JOBID/node-$n-$THIS_NODE
 mkdir -p $DIR
 cd $DIR
 echo $THIS_NODE > nodefile
 #CMD="mpiexec -np 12 -ppn 12  -envall --hostfile nodefile \
 #	     ../../gpu_tile_compact.sh \
 #	     ../../Test_dwf_mixedcg_prec --mpi 1.2.2.3 --grid 32.64.64.96 \
 #		--shm-mpi 0 --shm 4096 --device-mem 32000 --accelerator-threads 32 --seconds 6000 --debug-stdout --log Message --comms-overlap"
 CMD="mpiexec -np 12 -ppn 12  -envall --hostfile nodefile \
 	     ../../gpu_tile_compact.sh \
 	     ../../Test_dwf_mixedcg_prec --mpi 1.2.2.3 --grid 32.64.64.96 \
 		--shm-mpi 1 --shm 4096 --device-mem 32000 --accelerator-threads 32 --seconds 6000 --debug-stdout --log Message --comms-overlap"
 echo $CMD > command-line
 env > environment
 $CMD &
 done
 # Suspicious wait is allowing jobs to collide and knock out
 #wait
 sleep 6500
 for n in ` eval echo {1..$NN} `
 do
 THIS_NODE=`head -n$n $PBS_NODEFILE | tail -n1 `
 DIR=reproN.$PBS_JOBID/node-$n-$THIS_NODE
 cd $DIR
 grep Oops Grid.stderr.* > failures.$PBS_JOBID
 rm core.*
 done
--- a/systems/mac-arm/config-command-mpi
+++ b/systems/mac-arm/config-command-mpi
@@ -1,3 +1,2 @@
 CXXFLAGS=-I/opt/local/include LDFLAGS=-L/opt/local/lib/ CXX=c++-13 MPICXX=mpicxx ../../configure --enable-simd=GEN --enable-comms=mpi-auto --enable-unified=yes --prefix $HOME/QCD/GridInstall --with-lime=/Users/peterboyle/QCD/SciDAC/install/ --with-openssl=$BREW --disable-fermion-reps --disable-gparity --disable-debug 
--- a/tests/Test_dwf_mixedcg_prec.cc
+++ b/tests/Test_dwf_mixedcg_prec.cc
@@ -34,6 +34,46 @@ using namespace Grid;
 #define HOST_NAME_MAX _POSIX_HOST_NAME_MAX
 #endif
 NAMESPACE_BEGIN(Grid);
 template<class Matrix,class Field>
  class SchurDiagMooeeOperatorParanoid :  public SchurOperatorBase<Field> {
 public:
    Matrix &_Mat;
    SchurDiagMooeeOperatorParanoid (Matrix &Mat): _Mat(Mat){};
    virtual  void Mpc      (const Field &in, Field &out) {
      Field tmp(in.Grid());
      tmp.Checkerboard() = !in.Checkerboard();
      //      std::cout <<" Mpc starting"<<std::endl;
      RealD nn = norm2(in); // std::cout <<" Mpc Prior to dslash norm is "<<nn<<std::endl;
      _Mat.Meooe(in,tmp);
      nn = norm2(tmp); //std::cout <<" Mpc Prior to Mooeinv "<<nn<<std::endl;
      _Mat.MooeeInv(tmp,out);
      nn = norm2(out); //std::cout <<" Mpc Prior to dslash norm is "<<nn<<std::endl;
      _Mat.Meooe(out,tmp);
      nn = norm2(tmp); //std::cout <<" Mpc Prior to Mooee "<<nn<<std::endl;
      _Mat.Mooee(in,out);
      nn = norm2(out); //std::cout <<" Mpc Prior to axpy "<<nn<<std::endl;
      axpy(out,-1.0,tmp,out);
    }
    virtual void MpcDag   (const Field &in, Field &out){
      Field tmp(in.Grid());
      //      std::cout <<" MpcDag starting"<<std::endl;
      RealD nn = norm2(in);// std::cout <<" MpcDag Prior to dslash norm is "<<nn<<std::endl;
      _Mat.MeooeDag(in,tmp);
      _Mat.MooeeInvDag(tmp,out);
      nn = norm2(out);// std::cout <<" MpcDag Prior to dslash norm is "<<nn<<std::endl;
      _Mat.MeooeDag(out,tmp);
      nn = norm2(tmp);// std::cout <<" MpcDag Prior to Mooee "<<nn<<std::endl;
      _Mat.MooeeDag(in,out);
      nn = norm2(out);// std::cout <<" MpcDag Prior to axpy "<<nn<<std::endl;
      axpy(out,-1.0,tmp,out);
    }
 };
 NAMESPACE_END(Grid);
 int main (int argc, char ** argv)
 {
  char hostname[HOST_NAME_MAX+1];
@@ -82,8 +122,8 @@ int main (int argc, char ** argv)
  result_o_2.Checkerboard() = Odd;
  result_o_2 = Zero();
-  SchurDiagMooeeOperator<DomainWallFermionD,LatticeFermionD> HermOpEO(Ddwf);
+  SchurDiagMooeeOperatorParanoid<DomainWallFermionD,LatticeFermionD> HermOpEO(Ddwf);
-  SchurDiagMooeeOperator<DomainWallFermionF,LatticeFermionF> HermOpEO_f(Ddwf_f);
+  SchurDiagMooeeOperatorParanoid<DomainWallFermionF,LatticeFermionF> HermOpEO_f(Ddwf_f);
  int nsecs=600;
  if( GridCmdOptionExists(argv,argv+argc,"--seconds") ){
@@ -104,10 +144,22 @@ int main (int argc, char ** argv)
  time_t start = time(NULL);
-  uint32_t csum, csumref;
+  FlightRecorder::ContinueOnFail = 0;
-  csumref=0;
+  FlightRecorder::PrintEntireLog = 0;
  FlightRecorder::ChecksumComms  = 1;
  FlightRecorder::ChecksumCommsSend=0;
  if(char *s=getenv("GRID_PRINT_ENTIRE_LOG"))  FlightRecorder::PrintEntireLog     = atoi(s);
  if(char *s=getenv("GRID_CHECKSUM_RECV_BUF")) FlightRecorder::ChecksumComms      = atoi(s);
  if(char *s=getenv("GRID_CHECKSUM_SEND_BUF")) FlightRecorder::ChecksumCommsSend  = atoi(s);
  int iter=0;
  do {
    if ( iter == 0 ) {
      FlightRecorder::SetLoggingMode(FlightRecorder::LoggingModeRecord);
    } else {
      FlightRecorder::SetLoggingMode(FlightRecorder::LoggingModeVerify);
    }
    std::cerr << "******************* SINGLE PRECISION SOLVE "<<iter<<std::endl;
    result_o = Zero();
    t1=usecond();
@@ -118,27 +170,23 @@ int main (int argc, char ** argv)
    flops+= CGsiteflops*FrbGrid->gSites()*iters;
    std::cout << " SinglePrecision iterations/sec "<< iters/(t2-t1)*1000.*1000.<<std::endl;
    std::cout << " SinglePrecision GF/s "<< flops/(t2-t1)/1000.<<std::endl;
    std::cout << " SinglePrecision error count "<< FlightRecorder::ErrorCount()<<std::endl;
-    csum = crc(result_o);
+    assert(FlightRecorder::ErrorCount()==0);
-    if ( csumref == 0 ) {
+    std::cout << " FlightRecorder is OK! "<<std::endl;
      csumref = csum;
    } else {
      if ( csum != csumref ) { 
 	std::cerr << host<<" FAILURE " <<iter <<" csum "<<std::hex<<csum<< " != "<<csumref <<std::dec<<std::endl;
 	assert(0);
      } else {
 	std::cout << host <<" OK " <<iter <<" csum "<<std::hex<<csum<<std::dec<<" -- OK! "<<std::endl;
      }
    }
    iter ++;
-  } while (time(NULL) < (start + nsecs/2) );
+  } while (time(NULL) < (start + nsecs/10) );
  std::cout << GridLogMessage << "::::::::::::: Starting double precision CG" << std::endl;
  ConjugateGradient<LatticeFermionD> CG(1.0e-8,10000);
  csumref=0;
  int i=0;
  do { 
    if ( i == 0 ) {
      FlightRecorder::SetLoggingMode(FlightRecorder::LoggingModeRecord);
    } else {
      FlightRecorder::SetLoggingMode(FlightRecorder::LoggingModeVerify);
    }
    std::cerr << "******************* DOUBLE PRECISION SOLVE "<<i<<std::endl;
    result_o_2 = Zero();
    t1=usecond();
@@ -150,19 +198,9 @@ int main (int argc, char ** argv)
    std::cout << " DoublePrecision iterations/sec "<< iters/(t2-t1)*1000.*1000.<<std::endl;
    std::cout << " DoublePrecision GF/s "<< flops/(t2-t1)/1000.<<std::endl;
-
+    std::cout << " DoublePrecision error count "<< FlightRecorder::ErrorCount()<<std::endl;
-    csum = crc(result_o);
+    assert(FlightRecorder::ErrorCount()==0);
-
+    std::cout << " FlightRecorder is OK! "<<std::endl;
    if ( csumref == 0 ) {
      csumref = csum;
    } else {
      if ( csum != csumref ) { 
 	std::cerr << i <<" csum "<<std::hex<<csum<< " != "<<csumref <<std::dec<<std::endl;
 	assert(0);
      } else {
 	std::cout << i <<" csum "<<std::hex<<csum<<std::dec<<" -- OK! "<<std::endl;
      }
    }
    i++;
  } while (time(NULL) < (start + nsecs) );
--- a/tests/debug/Test_general_coarse.cc
+++ b/tests/debug/Test_general_coarse.cc
@@ -0,0 +1,319 @@
    /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./tests/Test_padded_cell.cc
    Copyright (C) 2023
 Author: Peter Boyle <paboyle@ph.ed.ac.uk>
    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.h>
 #include <Grid/lattice/PaddedCell.h>
 #include <Grid/stencil/GeneralLocalStencil.h>
 #include <Grid/algorithms/iterative/PrecGeneralisedConjugateResidual.h>
 #include <Grid/algorithms/iterative/PrecGeneralisedConjugateResidualNonHermitian.h>
 #include <Grid/algorithms/iterative/BiCGSTAB.h>
 using namespace std;
 using namespace Grid;
 gridblasHandle_t GridBLAS::gridblasHandle;
 int            GridBLAS::gridblasInit;
 ///////////////////////
 // Tells little dirac op to use MdagM as the .Op()
 ///////////////////////
 template<class Field>
 class HermOpAdaptor : public LinearOperatorBase<Field>
 {
  LinearOperatorBase<Field> & wrapped;
 public:
  HermOpAdaptor(LinearOperatorBase<Field> &wrapme) : wrapped(wrapme)  {};
  void OpDiag (const Field &in, Field &out) {    assert(0);  }
  void OpDir  (const Field &in, Field &out,int dir,int disp) {    assert(0);  }
  void OpDirAll  (const Field &in, std::vector<Field> &out){    assert(0);  };
  void Op     (const Field &in, Field &out){
    wrapped.HermOp(in,out);
  }
  void AdjOp     (const Field &in, Field &out){
    wrapped.HermOp(in,out);
  }
  void HermOpAndNorm(const Field &in, Field &out,RealD &n1,RealD &n2){    assert(0);  }
  void HermOp(const Field &in, Field &out){
    wrapped.HermOp(in,out);
  }
 };
 int main (int argc, char ** argv)
 {
  Grid_init(&argc,&argv);
  const int Ls=4;
  GridCartesian         * UGrid   = SpaceTimeGrid::makeFourDimGrid(GridDefaultLatt(),
 								   GridDefaultSimd(Nd,vComplex::Nsimd()),
 								   GridDefaultMpi());
  GridRedBlackCartesian * UrbGrid = SpaceTimeGrid::makeFourDimRedBlackGrid(UGrid);
  GridCartesian         * FGrid   = SpaceTimeGrid::makeFiveDimGrid(Ls,UGrid);
  GridRedBlackCartesian * FrbGrid = SpaceTimeGrid::makeFiveDimRedBlackGrid(Ls,UGrid);
  // Construct a coarsened grid
  Coordinate clatt = GridDefaultLatt();
  for(int d=0;d<clatt.size();d++){
    clatt[d] = clatt[d]/4;
  }
  GridCartesian *Coarse4d =  SpaceTimeGrid::makeFourDimGrid(clatt,
 							    GridDefaultSimd(Nd,vComplex::Nsimd()),
 							    GridDefaultMpi());;
  GridCartesian *Coarse5d =  SpaceTimeGrid::makeFiveDimGrid(1,Coarse4d);
  std::vector<int> seeds4({1,2,3,4});
  std::vector<int> seeds5({5,6,7,8});
  std::vector<int> cseeds({5,6,7,8});
  GridParallelRNG          RNG5(FGrid);   RNG5.SeedFixedIntegers(seeds5);
  GridParallelRNG          RNG4(UGrid);   RNG4.SeedFixedIntegers(seeds4);
  GridParallelRNG          CRNG(Coarse5d);CRNG.SeedFixedIntegers(cseeds);
  LatticeFermion    src(FGrid); random(RNG5,src);
  LatticeFermion result(FGrid); result=Zero();
  LatticeFermion    ref(FGrid); ref=Zero();
  LatticeFermion    tmp(FGrid);
  LatticeFermion    err(FGrid);
  LatticeGaugeField Umu(UGrid);
  SU<Nc>::HotConfiguration(RNG4,Umu);
  //  Umu=Zero();
  RealD mass=0.1;
  RealD M5=1.8;
  DomainWallFermionD Ddwf(Umu,*FGrid,*FrbGrid,*UGrid,*UrbGrid,mass,M5);
  const int nbasis = 62;
  const int cb = 0 ;
  LatticeFermion prom(FGrid);
  std::vector<LatticeFermion> subspace(nbasis,FGrid);
  std::cout<<GridLogMessage<<"Calling Aggregation class" <<std::endl;
  ///////////////////////////////////////////////////////////
  // Squared operator is in HermOp
  ///////////////////////////////////////////////////////////
  MdagMLinearOperator<DomainWallFermionD,LatticeFermion> HermDefOp(Ddwf);
  ///////////////////////////////////////////////////
  // Random aggregation space
  ///////////////////////////////////////////////////
  std::cout<<GridLogMessage << "Building random aggregation class"<< std::endl;
  typedef Aggregation<vSpinColourVector,vTComplex,nbasis> Subspace;
  Subspace Aggregates(Coarse5d,FGrid,cb);
  Aggregates.CreateSubspaceRandom(RNG5);
  ///////////////////////////////////////////////////
  // Build little dirac op
  ///////////////////////////////////////////////////
  std::cout<<GridLogMessage << "Building little Dirac operator"<< std::endl;
  typedef GeneralCoarsenedMatrix<vSpinColourVector,vTComplex,nbasis> LittleDiracOperator;
  typedef LittleDiracOperator::CoarseVector CoarseVector;
  NextToNextToNextToNearestStencilGeometry5D geom(Coarse5d);
  LittleDiracOperator LittleDiracOp(geom,FGrid,Coarse5d);
  LittleDiracOperator LittleDiracOpCol(geom,FGrid,Coarse5d);
  HermOpAdaptor<LatticeFermionD> HOA(HermDefOp);
  LittleDiracOp.CoarsenOperator(HOA,Aggregates);
  ///////////////////////////////////////////////////
  // Test the operator
  ///////////////////////////////////////////////////
  CoarseVector c_src (Coarse5d);
  CoarseVector c_res (Coarse5d);
  CoarseVector c_res_dag(Coarse5d);
  CoarseVector c_proj(Coarse5d);
  subspace=Aggregates.subspace;
  //  random(CRNG,c_src);
  c_src = 1.0;
  blockPromote(c_src,err,subspace);
  prom=Zero();
  for(int b=0;b<nbasis;b++){
    prom=prom+subspace[b];
  }
  err=err-prom; 
  std::cout<<GridLogMessage<<"Promoted back from subspace: err "<<norm2(err)<<std::endl;
  std::cout<<GridLogMessage<<"c_src "<<norm2(c_src)<<std::endl;
  std::cout<<GridLogMessage<<"prom  "<<norm2(prom)<<std::endl;
  HermDefOp.HermOp(prom,tmp);
  blockProject(c_proj,tmp,subspace);
  std::cout<<GridLogMessage<<" Called Big Dirac Op "<<norm2(tmp)<<std::endl;
  std::cout<<GridLogMessage<<" Calling little Dirac Op "<<std::endl;
  LittleDiracOp.M(c_src,c_res);
  LittleDiracOp.Mdag(c_src,c_res_dag);
  std::cout<<GridLogMessage<<"Little dop : "<<norm2(c_res)<<std::endl;
  std::cout<<GridLogMessage<<"Little dop dag : "<<norm2(c_res_dag)<<std::endl;
  std::cout<<GridLogMessage<<"Big dop in subspace : "<<norm2(c_proj)<<std::endl;
  c_proj = c_proj - c_res;
  std::cout<<GridLogMessage<<" ldop error: "<<norm2(c_proj)<<std::endl;
  c_res_dag = c_res_dag - c_res;
  std::cout<<GridLogMessage<<"Little dopDag - dop: "<<norm2(c_res_dag)<<std::endl;
  std::cout<<GridLogMessage << "Testing Hermiticity stochastically "<< std::endl;
  CoarseVector phi(Coarse5d);
  CoarseVector chi(Coarse5d);
  CoarseVector Aphi(Coarse5d);
  CoarseVector Achi(Coarse5d);
  random(CRNG,phi);
  random(CRNG,chi);
  std::cout<<GridLogMessage<<"Made randoms "<<norm2(phi)<<" " << norm2(chi)<<std::endl;
  LittleDiracOp.M(phi,Aphi);
  LittleDiracOp.Mdag(chi,Achi);
  std::cout<<GridLogMessage<<"Aphi "<<norm2(Aphi)<<" A chi" << norm2(Achi)<<std::endl;
  ComplexD pAc = innerProduct(chi,Aphi);
  ComplexD cAp = innerProduct(phi,Achi);
  ComplexD cAc = innerProduct(chi,Achi);
  ComplexD pAp = innerProduct(phi,Aphi);
  std::cout<<GridLogMessage<< "pAc "<<pAc<<" cAp "<< cAp<< " diff "<<pAc-adj(cAp)<<std::endl;
  std::cout<<GridLogMessage<< "pAp "<<pAp<<" cAc "<< cAc<<"Should be real"<< std::endl;
  std::cout<<GridLogMessage<<"Testing linearity"<<std::endl;
  CoarseVector PhiPlusChi(Coarse5d);
  CoarseVector APhiPlusChi(Coarse5d);
  CoarseVector linerr(Coarse5d);
  PhiPlusChi = phi+chi;
  LittleDiracOp.M(PhiPlusChi,APhiPlusChi);
  linerr= APhiPlusChi-Aphi;
  linerr= linerr-Achi;
  std::cout<<GridLogMessage<<"**Diff "<<norm2(linerr)<<std::endl;
  std::cout<<GridLogMessage<<std::endl;
  std::cout<<GridLogMessage<<std::endl;
  std::cout<<GridLogMessage<<"*******************************************"<<std::endl;
  std::cout<<GridLogMessage<<"*******************************************"<<std::endl;
  std::cout<<GridLogMessage<<"*******************************************"<<std::endl;
  //////////////////////////////////////////////////////////////////////////////////////
  //  Create a higher dim coarse grid
  //////////////////////////////////////////////////////////////////////////////////////
  const int nrhs=vComplex::Nsimd()*3;
  Coordinate mpi=GridDefaultMpi();
  Coordinate rhMpi ({1,1,mpi[0],mpi[1],mpi[2],mpi[3]});
  Coordinate rhLatt({nrhs,1,clatt[0],clatt[1],clatt[2],clatt[3]});
  Coordinate rhSimd({vComplex::Nsimd(),1, 1,1,1,1});
  GridCartesian *CoarseMrhs = new GridCartesian(rhLatt,rhSimd,rhMpi); 
  MultiGeneralCoarsenedMatrix mrhs(LittleDiracOp,CoarseMrhs);
  typedef decltype(mrhs) MultiGeneralCoarsenedMatrix_t;
  //////////////////////////////////////////
  // Test against single RHS
  //////////////////////////////////////////
  {
    GridParallelRNG          rh_CRNG(CoarseMrhs);rh_CRNG.SeedFixedIntegers(cseeds);
    CoarseVector rh_phi(CoarseMrhs);
    CoarseVector rh_res(CoarseMrhs);
    random(rh_CRNG,rh_phi);
    std::cout << "Warmup"<<std::endl;
    mrhs.M(rh_phi,rh_res);
    const int ncall=5;
    RealD t0=-usecond();
    for(int i=0;i<ncall;i++){
      std::cout << "Call "<<i<<"/"<<ncall<<std::endl;
      mrhs.M(rh_phi,rh_res);
    }
    t0+=usecond();
    RealD t1=0;
    for(int r=0;r<nrhs;r++){
      std::cout << " compare to single RHS "<<r<<"/"<<nrhs<<std::endl;
      ExtractSlice(phi,rh_phi,r,0);
      ExtractSlice(chi,rh_res,r,0);
      LittleDiracOp.M(phi,Aphi);
      t1-=usecond();
      for(int i=0;i<ncall;i++){
 	std::cout << "Call "<<i<<"/"<<ncall<<std::endl;
 	LittleDiracOp.M(phi,Aphi);
      }
      t1+=usecond();
      Coordinate site({0,0,0,0,0});
      auto  bad = peekSite(chi,site);
      auto good = peekSite(Aphi,site);
      std::cout << " mrhs [" <<r <<"] "<< norm2(chi)<<std::endl;
      std::cout << " srhs [" <<r <<"] "<< norm2(Aphi)<<std::endl;
      chi=chi-Aphi;
      RealD diff =norm2(chi);
      std::cout << r << " diff " << diff<<std::endl;
      assert(diff < 1.0e-10);
    }
    std::cout << nrhs<< " mrhs " << t0/ncall/nrhs <<" us"<<std::endl;
    std::cout << nrhs<< " srhs " << t1/ncall/nrhs <<" us"<<std::endl;
  }
  //////////////////////////////////////////
  // Test against single RHS
  //////////////////////////////////////////
  {
    typedef HermitianLinearOperator<MultiGeneralCoarsenedMatrix_t,CoarseVector> HermMatrix;
    HermMatrix MrhsCoarseOp     (mrhs);
    GridParallelRNG          rh_CRNG(CoarseMrhs);rh_CRNG.SeedFixedIntegers(cseeds);
    ConjugateGradient<CoarseVector>  mrhsCG(1.0e-8,2000,true);
    CoarseVector rh_res(CoarseMrhs);
    CoarseVector rh_src(CoarseMrhs);
    random(rh_CRNG,rh_src);
    rh_res= Zero();
    mrhsCG(MrhsCoarseOp,rh_src,rh_res);
  }
  std::cout<<GridLogMessage<<std::endl;
  std::cout<<GridLogMessage<<std::endl;
  std::cout<<GridLogMessage<<"*******************************************"<<std::endl;
  std::cout<<GridLogMessage<<"*******************************************"<<std::endl;
  std::cout<<GridLogMessage<<"*******************************************"<<std::endl;
  Grid_finalize();
  return 0;
 }
--- a/tests/debug/Test_general_coarse_hdcg.cc
+++ b/tests/debug/Test_general_coarse_hdcg.cc
@@ -0,0 +1,426 @@
    /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./tests/Test_general_coarse_hdcg.cc
    Copyright (C) 2023
 Author: Peter Boyle <pboyle@bnl.gov>
    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.h>
 #include <Grid/lattice/PaddedCell.h>
 #include <Grid/stencil/GeneralLocalStencil.h>
 //#include <Grid/algorithms/GeneralCoarsenedMatrix.h>
 #include <Grid/algorithms/iterative/AdefGeneric.h>
 using namespace std;
 using namespace Grid;
 template<class Coarsened>
 void SaveOperator(Coarsened &Operator,std::string file)
 {
 #ifdef HAVE_LIME
  emptyUserRecord record;
  ScidacWriter WR(Operator.Grid()->IsBoss());
  assert(Operator._A.size()==Operator.geom.npoint);
  WR.open(file);
  for(int p=0;p<Operator._A.size();p++){
    auto tmp = Operator.Cell.Extract(Operator._A[p]);
    WR.writeScidacFieldRecord(tmp,record);
  }
  WR.close();
 #endif
 }
 template<class Coarsened>
 void LoadOperator(Coarsened &Operator,std::string file)
 {
 #ifdef HAVE_LIME
  emptyUserRecord record;
  Grid::ScidacReader RD ;
  RD.open(file);
  assert(Operator._A.size()==Operator.geom.npoint);
  for(int p=0;p<Operator.geom.npoint;p++){
    conformable(Operator._A[p].Grid(),Operator.CoarseGrid());
    RD.readScidacFieldRecord(Operator._A[p],record);
  }    
  RD.close();
  Operator.ExchangeCoarseLinks();
 #endif
 }
 template<class aggregation>
 void SaveBasis(aggregation &Agg,std::string file)
 {
 #ifdef HAVE_LIME
  emptyUserRecord record;
  ScidacWriter WR(Agg.FineGrid->IsBoss());
  WR.open(file);
  for(int b=0;b<Agg.subspace.size();b++){
    WR.writeScidacFieldRecord(Agg.subspace[b],record);
  }
  WR.close();
 #endif
 }
 template<class aggregation>
 void LoadBasis(aggregation &Agg, std::string file)
 {
 #ifdef HAVE_LIME
  emptyUserRecord record;
  ScidacReader RD ;
  RD.open(file);
  for(int b=0;b<Agg.subspace.size();b++){
    RD.readScidacFieldRecord(Agg.subspace[b],record);
  }    
  RD.close();
 #endif
 }
 template<class Field> class TestSolver : public LinearFunction<Field> {
 public:
  TestSolver() {};
  void operator() (const Field &in, Field &out){    out = Zero();  }     
 };
 RealD InverseApproximation(RealD x){
  return 1.0/x;
 }
 // Want Op in CoarsenOp to call MatPcDagMatPc
 template<class Field>
 class HermOpAdaptor : public LinearOperatorBase<Field>
 {
  LinearOperatorBase<Field> & wrapped;
 public:
  HermOpAdaptor(LinearOperatorBase<Field> &wrapme) : wrapped(wrapme)  {};
  void Op     (const Field &in, Field &out)   { wrapped.HermOp(in,out);  }
  void HermOp(const Field &in, Field &out)    { wrapped.HermOp(in,out); }
  void AdjOp     (const Field &in, Field &out){ wrapped.HermOp(in,out);  }
  void OpDiag (const Field &in, Field &out)                  {    assert(0);  }
  void OpDir  (const Field &in, Field &out,int dir,int disp) {    assert(0);  }
  void OpDirAll  (const Field &in, std::vector<Field> &out)  {    assert(0);  };
  void HermOpAndNorm(const Field &in, Field &out,RealD &n1,RealD &n2){    assert(0);  }
 };
 template<class Field,class Matrix> class ChebyshevSmoother : public LinearFunction<Field>
 {
 public:
  using LinearFunction<Field>::operator();
  typedef LinearOperatorBase<Field> FineOperator;
  FineOperator   & _SmootherOperator;
  Chebyshev<Field> Cheby;
  ChebyshevSmoother(RealD _lo,RealD _hi,int _ord, FineOperator &SmootherOperator) :
    _SmootherOperator(SmootherOperator),
    Cheby(_lo,_hi,_ord,InverseApproximation)
  {
    std::cout << GridLogMessage<<" Chebyshev smoother order "<<_ord<<" ["<<_lo<<","<<_hi<<"]"<<std::endl;
  };
  void operator() (const Field &in, Field &out) 
  {
    Field tmp(in.Grid());
    tmp = in;
    Cheby(_SmootherOperator,tmp,out);
  }
 };
 int main (int argc, char ** argv)
 {
  Grid_init(&argc,&argv);
  const int Ls=24;
  const int nbasis = 40;
  const int cb = 0 ;
  RealD mass=0.00078;
  RealD M5=1.8;
  RealD b=1.5;
  RealD c=0.5;
  GridCartesian         * UGrid   = SpaceTimeGrid::makeFourDimGrid(GridDefaultLatt(),
 								   GridDefaultSimd(Nd,vComplex::Nsimd()),
 								   GridDefaultMpi());
  GridRedBlackCartesian * UrbGrid = SpaceTimeGrid::makeFourDimRedBlackGrid(UGrid);
  GridCartesian         * FGrid   = SpaceTimeGrid::makeFiveDimGrid(Ls,UGrid);
  GridRedBlackCartesian * FrbGrid = SpaceTimeGrid::makeFiveDimRedBlackGrid(Ls,UGrid);
  // Construct a coarsened grid with 4^4 cell
  Coordinate clatt = GridDefaultLatt();
  for(int d=0;d<clatt.size();d++){
    clatt[d] = clatt[d]/4;
  }
  GridCartesian *Coarse4d =  SpaceTimeGrid::makeFourDimGrid(clatt,
 							    GridDefaultSimd(Nd,vComplex::Nsimd()),
 							    GridDefaultMpi());;
  GridCartesian *Coarse5d =  SpaceTimeGrid::makeFiveDimGrid(1,Coarse4d);
  ///////////////////////// RNGs /////////////////////////////////
  std::vector<int> seeds4({1,2,3,4});
  std::vector<int> seeds5({5,6,7,8});
  std::vector<int> cseeds({5,6,7,8});
  GridParallelRNG          RNG5(FGrid);   RNG5.SeedFixedIntegers(seeds5);
  GridParallelRNG          RNG4(UGrid);   RNG4.SeedFixedIntegers(seeds4);
  GridParallelRNG          CRNG(Coarse5d);CRNG.SeedFixedIntegers(cseeds);
  ///////////////////////// Configuration /////////////////////////////////
  LatticeGaugeField Umu(UGrid);
  FieldMetaData header;
  std::string file("ckpoint_lat.4000");
  NerscIO::readConfiguration(Umu,header,file);
  //////////////////////// Fermion action //////////////////////////////////
  MobiusFermionD Ddwf(Umu,*FGrid,*FrbGrid,*UGrid,*UrbGrid,mass,M5,b,c);
  SchurDiagMooeeOperator<MobiusFermionD, LatticeFermion> HermOpEO(Ddwf);
  typedef HermOpAdaptor<LatticeFermionD> HermFineMatrix;
  HermFineMatrix FineHermOp(HermOpEO);
  LatticeFermion result(FrbGrid); result=Zero();
  LatticeFermion    src(FrbGrid); random(RNG5,src);
  // Run power method on FineHermOp
  PowerMethod<LatticeFermion>       PM;   PM(HermOpEO,src);
  ////////////////////////////////////////////////////////////
  ///////////// Coarse basis and Little Dirac Operator ///////
  ////////////////////////////////////////////////////////////
  typedef GeneralCoarsenedMatrix<vSpinColourVector,vTComplex,nbasis> LittleDiracOperator;
  typedef LittleDiracOperator::CoarseVector CoarseVector;
  NextToNextToNextToNearestStencilGeometry5D geom(Coarse5d);
  NearestStencilGeometry5D geom_nn(Coarse5d);
  // Warning: This routine calls PVdagM.Op, not PVdagM.HermOp
  typedef Aggregation<vSpinColourVector,vTComplex,nbasis> Subspace;
  Subspace Aggregates(Coarse5d,FrbGrid,cb);
  ////////////////////////////////////////////////////////////
  // Need to check about red-black grid coarsening
  ////////////////////////////////////////////////////////////
  LittleDiracOperator LittleDiracOp(geom,FrbGrid,Coarse5d);
  bool load=false;
  if ( load ) {
    LoadBasis(Aggregates,"/lustre/orion/phy157/proj-shared/phy157_dwf/paboyle/Subspace.scidac");
    LoadOperator(LittleDiracOp,"/lustre/orion/phy157/proj-shared/phy157_dwf/paboyle/LittleDiracOp.scidac");
  } else {
    Aggregates.CreateSubspaceChebyshev(RNG5,HermOpEO,nbasis,
 				       95.0,0.1,
 				       //				     400,200,200 -- 48 iters
 				       //				     600,200,200 -- 38 iters, 162s
 				       //				     600,200,100 -- 38 iters, 169s
 				       //				     600,200,50  -- 88 iters. 370s 
 				       800,
 				       200,
 				       100,
 				       0.0);
    LittleDiracOp.CoarsenOperator(FineHermOp,Aggregates);
    SaveBasis(Aggregates,"/lustre/orion/phy157/proj-shared/phy157_dwf/paboyle/Subspace.scidac");
    SaveOperator(LittleDiracOp,"/lustre/orion/phy157/proj-shared/phy157_dwf/paboyle/LittleDiracOp.scidac");
  }
  // Try projecting to one hop only
  LittleDiracOperator LittleDiracOpProj(geom_nn,FrbGrid,Coarse5d);
  LittleDiracOpProj.ProjectNearestNeighbour(0.01,LittleDiracOp); // smaller shift 0.02? n
  typedef HermitianLinearOperator<LittleDiracOperator,CoarseVector> HermMatrix;
  HermMatrix CoarseOp     (LittleDiracOp);
  HermMatrix CoarseOpProj (LittleDiracOpProj);
  //////////////////////////////////////////
  // Build a coarse lanczos
  //////////////////////////////////////////
  Chebyshev<CoarseVector>      IRLCheby(0.2,40.0,71);  // 1 iter
  FunctionHermOp<CoarseVector> IRLOpCheby(IRLCheby,CoarseOp);
  PlainHermOp<CoarseVector>    IRLOp    (CoarseOp);
  int Nk=48;
  int Nm=64;
  int Nstop=Nk;
  ImplicitlyRestartedLanczos<CoarseVector> IRL(IRLOpCheby,IRLOp,Nstop,Nk,Nm,1.0e-5,20);
  int Nconv;
  std::vector<RealD>            eval(Nm);
  std::vector<CoarseVector>     evec(Nm,Coarse5d);
  CoarseVector c_src(Coarse5d);
  //c_src=1.0;
  random(CRNG,c_src);
  CoarseVector c_res(Coarse5d); 
  CoarseVector c_ref(Coarse5d); 
  PowerMethod<CoarseVector>       cPM;   cPM(CoarseOp,c_src);
  IRL.calc(eval,evec,c_src,Nconv);
  DeflatedGuesser<CoarseVector> DeflCoarseGuesser(evec,eval);
  //////////////////////////////////////////
  // Build a coarse space solver
  //////////////////////////////////////////
  int maxit=20000;
  ConjugateGradient<CoarseVector>  CG(1.0e-8,maxit,false);
  ConjugateGradient<LatticeFermionD>  CGfine(1.0e-8,10000,false);
  ZeroGuesser<CoarseVector> CoarseZeroGuesser;
  //  HPDSolver<CoarseVector> HPDSolve(CoarseOp,CG,CoarseZeroGuesser);
  HPDSolver<CoarseVector> HPDSolve(CoarseOp,CG,DeflCoarseGuesser);
  c_res=Zero();
  HPDSolve(c_src,c_res); c_ref = c_res;
  std::cout << GridLogMessage<<"src norm "<<norm2(c_src)<<std::endl;
  std::cout << GridLogMessage<<"ref norm "<<norm2(c_ref)<<std::endl;
  //////////////////////////////////////////////////////////////////////////
  // Deflated (with real op EV's) solve for the projected coarse op
  // Work towards ADEF1 in the coarse space
  //////////////////////////////////////////////////////////////////////////
  HPDSolver<CoarseVector> HPDSolveProj(CoarseOpProj,CG,DeflCoarseGuesser);
  c_res=Zero();
  HPDSolveProj(c_src,c_res);
  std::cout << GridLogMessage<<"src norm "<<norm2(c_src)<<std::endl;
  std::cout << GridLogMessage<<"res norm "<<norm2(c_res)<<std::endl;
  c_res = c_res - c_ref;
  std::cout << "Projected solver error "<<norm2(c_res)<<std::endl;
  //////////////////////////////////////////////////////////////////////
  // Coarse ADEF1 with deflation space
  //////////////////////////////////////////////////////////////////////
  ChebyshevSmoother<CoarseVector,HermMatrix >
    CoarseSmoother(1.0,37.,8,CoarseOpProj);  // just go to sloppy 0.1 convergence
    //  CoarseSmoother(0.1,37.,8,CoarseOpProj);  //
  //  CoarseSmoother(0.5,37.,6,CoarseOpProj);  //  8 iter 0.36s
  //    CoarseSmoother(0.5,37.,12,CoarseOpProj);  // 8 iter, 0.55s
  //    CoarseSmoother(0.5,37.,8,CoarseOpProj);// 7-9 iter
  //  CoarseSmoother(1.0,37.,8,CoarseOpProj); // 0.4 - 0.5s solve to 0.04, 7-9 iter
  //  ChebyshevSmoother<CoarseVector,HermMatrix > CoarseSmoother(0.5,36.,10,CoarseOpProj);  // 311
  ////////////////////////////////////////////////////////
  // CG, Cheby mode spacing 200,200
  // Unprojected Coarse CG solve to 1e-8 : 190 iters, 4.9s
  // Unprojected Coarse CG solve to 4e-2 :  33 iters, 0.8s
  // Projected Coarse CG solve to 1e-8 : 100 iters, 0.36s
  ////////////////////////////////////////////////////////
  // CoarseSmoother(1.0,48.,8,CoarseOpProj); 48 evecs 
  ////////////////////////////////////////////////////////
  // ADEF1 Coarse solve to 1e-8 : 44 iters, 2.34s  2.1x gain
  // ADEF1 Coarse solve to 4e-2 : 7 iters, 0.4s
  // HDCG 38 iters 162s
  //
  // CoarseSmoother(1.0,40.,8,CoarseOpProj); 48 evecs 
  // ADEF1 Coarse solve to 1e-8 : 37 iters, 2.0s  2.1x gain
  // ADEF1 Coarse solve to 4e-2 : 6 iters, 0.36s
  // HDCG 38 iters 169s
  TwoLevelADEF1defl<CoarseVector>
    cADEF1(1.0e-8, 500,
 	   CoarseOp,
 	   CoarseSmoother,
 	   evec,eval);
  c_res=Zero();
  cADEF1(c_src,c_res);
  std::cout << GridLogMessage<<"src norm "<<norm2(c_src)<<std::endl;
  std::cout << GridLogMessage<<"cADEF1 res norm "<<norm2(c_res)<<std::endl;
  c_res = c_res - c_ref;
  std::cout << "cADEF1 solver error "<<norm2(c_res)<<std::endl;
  //  cADEF1.Tolerance = 4.0e-2;
  //  cADEF1.Tolerance = 1.0e-1;
  cADEF1.Tolerance = 5.0e-2;
  c_res=Zero();
  cADEF1(c_src,c_res);
  std::cout << GridLogMessage<<"src norm "<<norm2(c_src)<<std::endl;
  std::cout << GridLogMessage<<"cADEF1 res norm "<<norm2(c_res)<<std::endl;
  c_res = c_res - c_ref;
  std::cout << "cADEF1 solver error "<<norm2(c_res)<<std::endl;
  //////////////////////////////////////////
  // Build a smoother
  //////////////////////////////////////////
  //  ChebyshevSmoother<LatticeFermionD,HermFineMatrix > Smoother(10.0,100.0,10,FineHermOp); //499
  //  ChebyshevSmoother<LatticeFermionD,HermFineMatrix > Smoother(3.0,100.0,10,FineHermOp);  //383
  //  ChebyshevSmoother<LatticeFermionD,HermFineMatrix > Smoother(1.0,100.0,10,FineHermOp);  //328
  //  std::vector<RealD> los({0.5,1.0,3.0}); // 147/142/146 nbasis 1
  //  std::vector<RealD> los({1.0,2.0}); // Nbasis 24: 88,86 iterations
  //  std::vector<RealD> los({2.0,4.0}); // Nbasis 32 == 52, iters
  //  std::vector<RealD> los({2.0,4.0}); // Nbasis 40 == 36,36 iters
  //
  // Turns approx 2700 iterations into 340 fine multiplies with Nbasis 40
  // Need to measure cost of coarse space.
  //
  // -- i) Reduce coarse residual   -- 0.04
  // -- ii) Lanczos on coarse space -- done
  // -- iii) Possible 1 hop project and/or preconditioning it - easy - PrecCG it and
  //         use a limited stencil. Reread BFM code to check on evecs / deflation strategy with prec
  //
  std::vector<RealD> los({3.0}); // Nbasis 40 == 36,36 iters
  //  std::vector<int> ords({7,8,10}); // Nbasis 40 == 40,38,36 iters (320,342,396 mults)
  std::vector<int> ords({7}); // Nbasis 40 == 40 iters (320 mults)  
  for(int l=0;l<los.size();l++){
    RealD lo = los[l];
    for(int o=0;o<ords.size();o++){
      ConjugateGradient<CoarseVector>  CGsloppy(4.0e-2,maxit,false);
      HPDSolver<CoarseVector> HPDSolveSloppy(CoarseOp,CGsloppy,DeflCoarseGuesser);
      //    ChebyshevSmoother<LatticeFermionD,HermFineMatrix > Smoother(lo,92,10,FineHermOp); // 36 best case
      ChebyshevSmoother<LatticeFermionD,HermFineMatrix > Smoother(lo,92,ords[o],FineHermOp);  // 311
      //////////////////////////////////////////
      // Build a HDCG solver
      //////////////////////////////////////////
      TwoLevelADEF2<LatticeFermion,CoarseVector,Subspace>
 	HDCG(1.0e-8, 100,
 	     FineHermOp,
 	     Smoother,
 	     HPDSolveSloppy,
 	     HPDSolve,
 	     Aggregates);
      TwoLevelADEF2<LatticeFermion,CoarseVector,Subspace>
 	HDCGdefl(1.0e-8, 100,
 		 FineHermOp,
 		 Smoother,
 		 cADEF1,
 		 HPDSolve,
 		 Aggregates);
      result=Zero();
      HDCGdefl(src,result);
      result=Zero();
      HDCG(src,result);
    }
  }
  // Standard CG
  result=Zero();
  CGfine(HermOpEO, src, result);
  Grid_finalize();
  return 0;
 }
--- a/tests/debug/Test_general_coarse_hdcg_phys.cc
+++ b/tests/debug/Test_general_coarse_hdcg_phys.cc
@@ -0,0 +1,444 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./tests/Test_general_coarse_hdcg.cc
    Copyright (C) 2023
 Author: Peter Boyle <pboyle@bnl.gov>
    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.h>
 #include <Grid/lattice/PaddedCell.h>
 #include <Grid/stencil/GeneralLocalStencil.h>
 //#include <Grid/algorithms/GeneralCoarsenedMatrix.h>
 #include <Grid/algorithms/iterative/AdefGeneric.h>
 using namespace std;
 using namespace Grid;
 template<class Coarsened>
 void SaveOperator(Coarsened &Operator,std::string file)
 {
 #ifdef HAVE_LIME
  emptyUserRecord record;
  ScidacWriter WR(Operator.Grid()->IsBoss());
  assert(Operator._A.size()==Operator.geom.npoint);
  WR.open(file);
  for(int p=0;p<Operator._A.size();p++){
    auto tmp = Operator.Cell.Extract(Operator._A[p]);
    WR.writeScidacFieldRecord(tmp,record,0,0);
    //    WR.writeScidacFieldRecord(tmp,record,0,BINARYIO_LEXICOGRAPHIC);
  }
  WR.close();
 #endif
 }
 template<class Coarsened>
 void LoadOperator(Coarsened &Operator,std::string file)
 {
 #ifdef HAVE_LIME
  emptyUserRecord record;
  Grid::ScidacReader RD ;
  RD.open(file);
  assert(Operator._A.size()==Operator.geom.npoint);
  for(int p=0;p<Operator.geom.npoint;p++){
    conformable(Operator._A[p].Grid(),Operator.CoarseGrid());
    //    RD.readScidacFieldRecord(Operator._A[p],record,BINARYIO_LEXICOGRAPHIC);
    RD.readScidacFieldRecord(Operator._A[p],record,0);
  }    
  RD.close();
  Operator.ExchangeCoarseLinks();
 #endif
 }
 template<class Coarsened>
 void ReLoadOperator(Coarsened &Operator,std::string file)
 {
 #ifdef HAVE_LIME
  emptyUserRecord record;
  Grid::ScidacReader RD ;
  RD.open(file);
  assert(Operator._A.size()==Operator.geom.npoint);
  for(int p=0;p<Operator.geom.npoint;p++){
    auto tmp=Operator.Cell.Extract(Operator._A[p]);
    RD.readScidacFieldRecord(tmp,record,0);
    Operator._A[p] = Operator.Cell.ExchangePeriodic(tmp);
  }    
  RD.close();
 #endif
 }
 template<class aggregation>
 void SaveBasis(aggregation &Agg,std::string file)
 {
 #ifdef HAVE_LIME
  emptyUserRecord record;
  ScidacWriter WR(Agg.FineGrid->IsBoss());
  WR.open(file);
  for(int b=0;b<Agg.subspace.size();b++){
    //WR.writeScidacFieldRecord(Agg.subspace[b],record,0,BINARYIO_LEXICOGRAPHIC);
    WR.writeScidacFieldRecord(Agg.subspace[b],record,0,0);
  }
  WR.close();
 #endif
 }
 template<class aggregation>
 void LoadBasis(aggregation &Agg, std::string file)
 {
 #ifdef HAVE_LIME
  emptyUserRecord record;
  ScidacReader RD ;
  RD.open(file);
  for(int b=0;b<Agg.subspace.size();b++){
    //    RD.readScidacFieldRecord(Agg.subspace[b],record,BINARYIO_LEXICOGRAPHIC);
    RD.readScidacFieldRecord(Agg.subspace[b],record,0);
  }    
  RD.close();
 #endif
 }
 RealD InverseApproximation(RealD x){
  return 1.0/x;
 }
 // Want Op in CoarsenOp to call MatPcDagMatPc
 template<class Field>
 class HermOpAdaptor : public LinearOperatorBase<Field>
 {
  LinearOperatorBase<Field> & wrapped;
 public:
  HermOpAdaptor(LinearOperatorBase<Field> &wrapme) : wrapped(wrapme)  {};
  void Op     (const Field &in, Field &out)   { wrapped.HermOp(in,out);  }
  void HermOp(const Field &in, Field &out)    { wrapped.HermOp(in,out); }
  void AdjOp     (const Field &in, Field &out){ wrapped.HermOp(in,out);  }
  void OpDiag (const Field &in, Field &out)                  {    assert(0);  }
  void OpDir  (const Field &in, Field &out,int dir,int disp) {    assert(0);  }
  void OpDirAll  (const Field &in, std::vector<Field> &out)  {    assert(0);  };
  void HermOpAndNorm(const Field &in, Field &out,RealD &n1,RealD &n2){    assert(0);  }
 };
 /*
 template<class Field> class ChebyshevSmoother : public LinearFunction<Field>
 {
 public:
  using LinearFunction<Field>::operator();
  typedef LinearOperatorBase<Field> FineOperator;
  FineOperator   & _SmootherOperator;
  Chebyshev<Field> Cheby;
  ChebyshevSmoother(RealD _lo,RealD _hi,int _ord, FineOperator &SmootherOperator) :
    _SmootherOperator(SmootherOperator),
    Cheby(_lo,_hi,_ord,InverseApproximation)
  {
    std::cout << GridLogMessage<<" Chebyshev smoother order "<<_ord<<" ["<<_lo<<","<<_hi<<"]"<<std::endl;
  };
  void operator() (const Field &in, Field &out) 
  {
    Field tmp(in.Grid());
    tmp = in;
    Cheby(_SmootherOperator,tmp,out);
  }
 };
 */
 template<class Field> class CGSmoother : public LinearFunction<Field>
 {
 public:
  using LinearFunction<Field>::operator();
  typedef LinearOperatorBase<Field> FineOperator;
  FineOperator   & _SmootherOperator;
  int iters;
  CGSmoother(int _iters, FineOperator &SmootherOperator) :
    _SmootherOperator(SmootherOperator),
    iters(_iters)
  {
    std::cout << GridLogMessage<<" Mirs smoother order "<<iters<<std::endl;
  };
  void operator() (const Field &in, Field &out) 
  {
    ConjugateGradient<Field>  CG(0.0,iters,false); // non-converge is just fine in a smoother
    CG(_SmootherOperator,in,out);
  }
 };
 int main (int argc, char ** argv)
 {
  Grid_init(&argc,&argv);
  const int Ls=24;
  const int nbasis = 62;
  const int cb = 0 ;
  RealD mass=0.00078;
  RealD M5=1.8;
  RealD b=1.5;
  RealD c=0.5;
  GridCartesian         * UGrid   = SpaceTimeGrid::makeFourDimGrid(GridDefaultLatt(),
 								   GridDefaultSimd(Nd,vComplex::Nsimd()),
 								   GridDefaultMpi());
  GridRedBlackCartesian * UrbGrid = SpaceTimeGrid::makeFourDimRedBlackGrid(UGrid);
  GridCartesian         * FGrid   = SpaceTimeGrid::makeFiveDimGrid(Ls,UGrid);
  GridRedBlackCartesian * FrbGrid = SpaceTimeGrid::makeFiveDimRedBlackGrid(Ls,UGrid);
  // Construct a coarsened grid with 4^4 cell
  Coordinate Block({4,4,6,4});
  Coordinate clatt = GridDefaultLatt();
  for(int d=0;d<clatt.size();d++){
    clatt[d] = clatt[d]/Block[d];
  }
  GridCartesian *Coarse4d =  SpaceTimeGrid::makeFourDimGrid(clatt,
 							    GridDefaultSimd(Nd,vComplex::Nsimd()),
 							    GridDefaultMpi());;
  GridCartesian *Coarse5d =  SpaceTimeGrid::makeFiveDimGrid(1,Coarse4d);
  ///////////////////////// RNGs /////////////////////////////////
  std::vector<int> seeds4({1,2,3,4});
  std::vector<int> seeds5({5,6,7,8});
  std::vector<int> cseeds({5,6,7,8});
  GridParallelRNG          RNG5(FGrid);   RNG5.SeedFixedIntegers(seeds5);
  GridParallelRNG          RNG4(UGrid);   RNG4.SeedFixedIntegers(seeds4);
  GridParallelRNG          CRNG(Coarse5d);CRNG.SeedFixedIntegers(cseeds);
  ///////////////////////// Configuration /////////////////////////////////
  LatticeGaugeField Umu(UGrid);
  FieldMetaData header;
  std::string file("ckpoint_lat.1000");
  NerscIO::readConfiguration(Umu,header,file);
  //////////////////////// Fermion action //////////////////////////////////
  MobiusFermionD Ddwf(Umu,*FGrid,*FrbGrid,*UGrid,*UrbGrid,mass,M5,b,c);
  SchurDiagMooeeOperator<MobiusFermionD, LatticeFermion> HermOpEO(Ddwf);
  typedef HermOpAdaptor<LatticeFermionD> HermFineMatrix;
  HermFineMatrix FineHermOp(HermOpEO);
  LatticeFermion result(FrbGrid); result=Zero();
  LatticeFermion    src(FrbGrid); random(RNG5,src);
  // Run power method on FineHermOp
  PowerMethod<LatticeFermion>       PM;   PM(HermOpEO,src);
  ////////////////////////////////////////////////////////////
  ///////////// Coarse basis and Little Dirac Operator ///////
  ////////////////////////////////////////////////////////////
  typedef GeneralCoarsenedMatrix<vSpinColourVector,vTComplex,nbasis> LittleDiracOperator;
  typedef LittleDiracOperator::CoarseVector CoarseVector;
  NextToNextToNextToNearestStencilGeometry5D geom(Coarse5d);
  NearestStencilGeometry5D geom_nn(Coarse5d);
  // Warning: This routine calls PVdagM.Op, not PVdagM.HermOp
  typedef Aggregation<vSpinColourVector,vTComplex,nbasis> Subspace;
  Subspace Aggregates(Coarse5d,FrbGrid,cb);
  ////////////////////////////////////////////////////////////
  // Need to check about red-black grid coarsening
  ////////////////////////////////////////////////////////////
  LittleDiracOperator LittleDiracOp(geom,FrbGrid,Coarse5d);
  std::string subspace_file("/lustre/orion/phy157/proj-shared/phy157_dwf/paboyle/Subspace.phys48.rat.scidac.62");
  std::string refine_file("/lustre/orion/phy157/proj-shared/phy157_dwf/paboyle/Refine.phys48.rat.scidac.62");
  std::string ldop_file("/lustre/orion/phy157/proj-shared/phy157_dwf/paboyle/LittleDiracOp.phys48.rat.scidac.62");
  bool load_agg=true;
  bool load_refine=true;
  bool load_mat=true;
  if ( load_agg ) {
    LoadBasis(Aggregates,subspace_file);
  } else {
    // NBASIS=40
    // Best so far: ord 2000 [0.01,95], 500,500  -- 466 iters
    // slurm-398626.out:Grid : Message : 141.295253 s : 500 filt [1] <n|MdagM|n> 0.000103622063
    //Grid : Message : 33.870465 s :  Chebyshev subspace pass-1 : ord 2000 [0.001,95]
    //Grid : Message : 33.870485 s :  Chebyshev subspace pass-2 : nbasis40 min 1000 step 1000 lo0
    //slurm-1482200.out : filt ~ 0.004 -- not as low mode projecting -- took 626 iters
    // To try: 2000 [0.1,95]  ,2000,500,500 -- slurm-1482213.out 586 iterations
    // To try: 2000 [0.01,95] ,2000,500,500 -- 469 (think I bumped 92 to 95) (??)
    // To try: 2000 [0.025,95],2000,500,500
    // To try: 2000 [0.005,95],2000,500,500
    // NBASIS=44 -- HDCG paper was 64 vectors; AMD compiler craps out at 48
    // To try: 2000 [0.01,95] ,2000,500,500 -- 419 lowest slurm-1482355.out
    // To try: 2000 [0.025,95] ,2000,500,500 -- 487 
    // To try: 2000 [0.005,95] ,2000,500,500
    /*
      Smoother [3,92] order 16
 slurm-1482355.out:Grid : Message : 35.239686 s :  Chebyshev subspace pass-1 : ord 2000 [0.01,95]
 slurm-1482355.out:Grid : Message : 35.239714 s :  Chebyshev subspace pass-2 : nbasis44 min 500 step 500 lo0
 slurm-1482355.out:Grid : Message : 5561.305552 s : HDCG: Pcg converged in 419 iterations and 2616.202598 s
 slurm-1482367.out:Grid : Message : 43.157235 s :  Chebyshev subspace pass-1 : ord 2000 [0.025,95]
 slurm-1482367.out:Grid : Message : 43.157257 s :  Chebyshev subspace pass-2 : nbasis44 min 500 step 500 lo0
 slurm-1482367.out:Grid : Message : 6169.469330 s : HDCG: Pcg converged in 487 iterations and 3131.185821 s
    */
 		 /*
 		   Aggregates.CreateSubspaceChebyshev(RNG5,HermOpEO,nbasis,
 				       95.0,0.0075,
 				       2500,
 				       500,
 				       500,
 				       0.0);
 		 */
 		 /*
 		   Aggregates.CreateSubspaceChebyshevPowerLaw(RNG5,HermOpEO,nbasis,
 							      95.0,
 							      2000);
 		 */
    Aggregates.CreateSubspaceMultishift(RNG5,HermOpEO,
 					0.0003,1.0e-5,2000); // Lo, tol, maxit
  /*
    Aggregates.CreateSubspaceChebyshev(RNG5,HermOpEO,nbasis,
 				       95.0,0.05,
 				       2000,
 				       500,
 				       500,
 				       0.0);
 */
    /*
      Aggregates.CreateSubspaceChebyshev(RNG5,HermOpEO,nbasis,
 				       95.0,0.01,
 				       2000,
 				       500,
 				       500,
 				       0.0);
    */
    //    Aggregates.CreateSubspaceChebyshev(RNG5,HermOpEO,nbasis,95.,0.01,1500); -- running slurm-1484934.out nbasis 56
    //    Aggregates.CreateSubspaceChebyshev(RNG5,HermOpEO,nbasis,95.,0.01,1500); <== last run
    SaveBasis(Aggregates,subspace_file);
  }
  int refine=1;
  if(refine){
    if ( load_refine ) {
      LoadBasis(Aggregates,refine_file);
    } else {
      // HDCG used Pcg to refine
      Aggregates.RefineSubspace(HermOpEO,0.001,1.0e-3,3000);
      SaveBasis(Aggregates,refine_file);
    }
  }
  Aggregates.Orthogonalise();
  if ( load_mat ) {
    LoadOperator(LittleDiracOp,ldop_file);
  } else {
    LittleDiracOp.CoarsenOperator(FineHermOp,Aggregates);
    SaveOperator(LittleDiracOp,ldop_file);
  }
  // I/O test:
  CoarseVector c_src(Coarse5d);   random(CRNG,c_src);
  CoarseVector c_res(Coarse5d); 
  CoarseVector c_ref(Coarse5d);
  //////////////////////////////////////////
  // Build a coarse lanczos
  //////////////////////////////////////////
  typedef HermitianLinearOperator<LittleDiracOperator,CoarseVector> HermMatrix;
  HermMatrix CoarseOp     (LittleDiracOp);
  int Nk=192;
  int Nm=256;
  int Nstop=Nk;
  Chebyshev<CoarseVector>      IRLCheby(0.005,40.0,201);
  //  Chebyshev<CoarseVector>      IRLCheby(0.010,45.0,201);  // 1 iter
  FunctionHermOp<CoarseVector> IRLOpCheby(IRLCheby,CoarseOp);
  PlainHermOp<CoarseVector>    IRLOp    (CoarseOp);
  ImplicitlyRestartedLanczos<CoarseVector> IRL(IRLOpCheby,IRLOp,Nstop,Nk,Nm,1e-5,10);
  int Nconv;
  std::vector<RealD>            eval(Nm);
  std::vector<CoarseVector>     evec(Nm,Coarse5d);
  PowerMethod<CoarseVector>       cPM;   cPM(CoarseOp,c_src);
  IRL.calc(eval,evec,c_src,Nconv);
  //////////////////////////////////////////
  // Deflated guesser
  //////////////////////////////////////////
  DeflatedGuesser<CoarseVector> DeflCoarseGuesser(evec,eval);
  int maxit=30000;
  ConjugateGradient<CoarseVector>  CG(1.0e-10,maxit,false);
  ConjugateGradient<LatticeFermionD>  CGfine(1.0e-8,30000,false);
  //////////////////////////////////////////
  // HDCG
  //////////////////////////////////////////
  std::vector<RealD> los({2.0,2.5}); // Nbasis 40 == 36,36 iters
  std::vector<int> ords({9}); // Nbasis 40 == 40 iters (320 mults)  
  for(int l=0;l<los.size();l++){
    RealD lo = los[l];
    for(int o=0;o<ords.size();o++){
      //////////////////////////////////////////
      // Sloppy coarse solve
      //////////////////////////////////////////
      ConjugateGradient<CoarseVector>  CGsloppy(4.0e-2,maxit,false);
      HPDSolver<CoarseVector> HPDSolveSloppy(CoarseOp,CGsloppy,DeflCoarseGuesser);
      HPDSolver<CoarseVector> HPDSolve(CoarseOp,CG,DeflCoarseGuesser);
      //////////////////////////////////////////
      // IRS shifted smoother based on CG
      //////////////////////////////////////////
      RealD MirsShift = lo;
      ShiftedHermOpLinearOperator<LatticeFermionD> ShiftedFineHermOp(HermOpEO,MirsShift);
      CGSmoother<LatticeFermionD> CGsmooth(ords[o],ShiftedFineHermOp) ;
      //////////////////////////////////////////
      // Build a HDCG solver
      //////////////////////////////////////////
      TwoLevelADEF2<LatticeFermion,CoarseVector,Subspace>
 	HDCG(1.0e-8, 700,
 	     FineHermOp,
 	     CGsmooth,
 	     HPDSolveSloppy,
 	     HPDSolve,
 	     Aggregates);
      result=Zero();
      HDCG(src,result);
    }
  }
  // Standard CG
  result=Zero();
  CGfine(HermOpEO, src, result);
  Grid_finalize();
  return 0;
 }
--- a/tests/debug/Test_general_coarse_hdcg_phys48.cc
+++ b/tests/debug/Test_general_coarse_hdcg_phys48.cc
@@ -0,0 +1,513 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./tests/Test_general_coarse_hdcg.cc
    Copyright (C) 2023
 Author: Peter Boyle <pboyle@bnl.gov>
    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.h>
 #include <Grid/algorithms/iterative/ImplicitlyRestartedBlockLanczos.h>
 #include <Grid/algorithms/iterative/ImplicitlyRestartedBlockLanczosCoarse.h>
 #include <Grid/algorithms/iterative/AdefMrhs.h>
 using namespace std;
 using namespace Grid;
 class HDCGwrapper {
 };
 /*
 template<class Coarsened>
 void SaveOperator(Coarsened &Operator,std::string file)
 {
 #ifdef HAVE_LIME
  emptyUserRecord record;
  ScidacWriter WR(Operator.Grid()->IsBoss());
  assert(Operator._A.size()==Operator.geom.npoint);
  WR.open(file);
  for(int p=0;p<Operator._A.size();p++){
    auto tmp = Operator.Cell.Extract(Operator._A[p]);
    WR.writeScidacFieldRecord(tmp,record,0,0);
    //    WR.writeScidacFieldRecord(tmp,record,0,BINARYIO_LEXICOGRAPHIC);
  }
  WR.close();
 #endif
 }
 template<class Coarsened>
 void LoadOperator(Coarsened &Operator,std::string file)
 {
 #ifdef HAVE_LIME
  emptyUserRecord record;
  Grid::ScidacReader RD ;
  RD.open(file);
  assert(Operator._A.size()==Operator.geom.npoint);
  for(int p=0;p<Operator.geom.npoint;p++){
    conformable(Operator._A[p].Grid(),Operator.CoarseGrid());
    //    RD.readScidacFieldRecord(Operator._A[p],record,BINARYIO_LEXICOGRAPHIC);
    RD.readScidacFieldRecord(Operator._A[p],record,0);
  }    
  RD.close();
  Operator.ExchangeCoarseLinks();
 #endif
 }
 template<class Coarsened>
 void ReLoadOperator(Coarsened &Operator,std::string file)
 {
 #ifdef HAVE_LIME
  emptyUserRecord record;
  Grid::ScidacReader RD ;
  RD.open(file);
  assert(Operator._A.size()==Operator.geom.npoint);
  for(int p=0;p<Operator.geom.npoint;p++){
    auto tmp=Operator.Cell.Extract(Operator._A[p]);
    RD.readScidacFieldRecord(tmp,record,0);
    Operator._A[p] = Operator.Cell.ExchangePeriodic(tmp);
  }    
  RD.close();
 #endif
 }
 */
 template<class aggregation>
 void SaveBasis(aggregation &Agg,std::string file)
 {
 #ifdef HAVE_LIME
  emptyUserRecord record;
  ScidacWriter WR(Agg.FineGrid->IsBoss());
  WR.open(file);
  for(int b=0;b<Agg.subspace.size();b++){
    //WR.writeScidacFieldRecord(Agg.subspace[b],record,0,BINARYIO_LEXICOGRAPHIC);
    WR.writeScidacFieldRecord(Agg.subspace[b],record,0,0);
  }
  WR.close();
 #endif
 }
 template<class aggregation>
 void LoadBasis(aggregation &Agg, std::string file)
 {
 #ifdef HAVE_LIME
  emptyUserRecord record;
  ScidacReader RD ;
  RD.open(file);
  for(int b=0;b<Agg.subspace.size();b++){
    //    RD.readScidacFieldRecord(Agg.subspace[b],record,BINARYIO_LEXICOGRAPHIC);
    RD.readScidacFieldRecord(Agg.subspace[b],record,0);
  }    
  RD.close();
 #endif
 }
 template<class CoarseVector>
 void SaveEigenvectors(std::vector<RealD>            &eval,
 		      std::vector<CoarseVector>     &evec,
 		      std::string evec_file,
 		      std::string eval_file)
 {
 #ifdef HAVE_LIME
  emptyUserRecord record;
  ScidacWriter WR(evec[0].Grid()->IsBoss());
  WR.open(evec_file);
  for(int b=0;b<evec.size();b++){
    WR.writeScidacFieldRecord(evec[b],record,0,0);
  }
  WR.close();
  XmlWriter WRx(eval_file);
  write(WRx,"evals",eval);
 #endif
 }
 template<class CoarseVector>
 void LoadEigenvectors(std::vector<RealD>            &eval,
 		      std::vector<CoarseVector>     &evec,
 		      std::string evec_file,
 		      std::string eval_file)
 {
 #ifdef HAVE_LIME
    XmlReader RDx(eval_file);
    read(RDx,"evals",eval);
    emptyUserRecord record;
    Grid::ScidacReader RD ;
    RD.open(evec_file);
    assert(evec.size()==eval.size());
    for(int k=0;k<eval.size();k++) {
      RD.readScidacFieldRecord(evec[k],record);
    }
    RD.close();
 #endif
 }
 // Want Op in CoarsenOp to call MatPcDagMatPc
 template<class Field>
 class HermOpAdaptor : public LinearOperatorBase<Field>
 {
  LinearOperatorBase<Field> & wrapped;
 public:
  HermOpAdaptor(LinearOperatorBase<Field> &wrapme) : wrapped(wrapme)  {};
  void Op     (const Field &in, Field &out)   { wrapped.HermOp(in,out);  }
  void HermOp(const Field &in, Field &out)    { wrapped.HermOp(in,out); }
  void AdjOp     (const Field &in, Field &out){ wrapped.HermOp(in,out);  }
  void OpDiag (const Field &in, Field &out)                  {    assert(0);  }
  void OpDir  (const Field &in, Field &out,int dir,int disp) {    assert(0);  }
  void OpDirAll  (const Field &in, std::vector<Field> &out)  {    assert(0);  };
  void HermOpAndNorm(const Field &in, Field &out,RealD &n1,RealD &n2){    assert(0);  }
 };
 template<class Field> class CGSmoother : public LinearFunction<Field>
 {
 public:
  using LinearFunction<Field>::operator();
  typedef LinearOperatorBase<Field> FineOperator;
  FineOperator   & _SmootherOperator;
  int iters;
  CGSmoother(int _iters, FineOperator &SmootherOperator) :
    _SmootherOperator(SmootherOperator),
    iters(_iters)
  {
    std::cout << GridLogMessage<<" Mirs smoother order "<<iters<<std::endl;
  };
  void operator() (const Field &in, Field &out) 
  {
    ConjugateGradient<Field>  CG(0.0,iters,false); // non-converge is just fine in a smoother
    out=Zero();
    CG(_SmootherOperator,in,out);
  }
 };
 int main (int argc, char ** argv)
 {
  Grid_init(&argc,&argv);
  const int Ls=24;
  const int nbasis = 62;
  const int cb = 0 ;
  RealD mass=0.00078;
  RealD M5=1.8;
  RealD b=1.5;
  RealD c=0.5;
  GridCartesian         * UGrid   = SpaceTimeGrid::makeFourDimGrid(GridDefaultLatt(),
 								   GridDefaultSimd(Nd,vComplex::Nsimd()),
 								   GridDefaultMpi());
  GridRedBlackCartesian * UrbGrid = SpaceTimeGrid::makeFourDimRedBlackGrid(UGrid);
  GridCartesian         * FGrid   = SpaceTimeGrid::makeFiveDimGrid(Ls,UGrid);
  GridRedBlackCartesian * FrbGrid = SpaceTimeGrid::makeFiveDimRedBlackGrid(Ls,UGrid);
  // Construct a coarsened grid with 4^4 cell
  Coordinate Block({4,4,6,4});
  Coordinate clatt = GridDefaultLatt();
  for(int d=0;d<clatt.size();d++){
    clatt[d] = clatt[d]/Block[d];
  }
  GridCartesian *Coarse4d =  SpaceTimeGrid::makeFourDimGrid(clatt,
 							    GridDefaultSimd(Nd,vComplex::Nsimd()),
 							    GridDefaultMpi());;
  GridCartesian *Coarse5d =  SpaceTimeGrid::makeFiveDimGrid(1,Coarse4d);
  ///////////////////////// RNGs /////////////////////////////////
  std::vector<int> seeds4({1,2,3,4});
  std::vector<int> seeds5({5,6,7,8});
  std::vector<int> cseeds({5,6,7,8});
  GridParallelRNG          RNG5(FGrid);   RNG5.SeedFixedIntegers(seeds5);
  GridParallelRNG          RNG4(UGrid);   RNG4.SeedFixedIntegers(seeds4);
  GridParallelRNG          CRNG(Coarse5d);CRNG.SeedFixedIntegers(cseeds);
  ///////////////////////// Configuration /////////////////////////////////
  LatticeGaugeField Umu(UGrid);
  FieldMetaData header;
  std::string file("ckpoint_lat.1000");
  NerscIO::readConfiguration(Umu,header,file);
  //////////////////////// Fermion action //////////////////////////////////
  MobiusFermionD Ddwf(Umu,*FGrid,*FrbGrid,*UGrid,*UrbGrid,mass,M5,b,c);
  SchurDiagMooeeOperator<MobiusFermionD, LatticeFermion> HermOpEO(Ddwf);
  typedef HermOpAdaptor<LatticeFermionD> HermFineMatrix;
  HermFineMatrix FineHermOp(HermOpEO);
  // Run power method on FineHermOp
  // PowerMethod<LatticeFermion>       PM;   PM(HermOpEO,src);
  ////////////////////////////////////////////////////////////
  ///////////// Coarse basis and Little Dirac Operator ///////
  ////////////////////////////////////////////////////////////
  typedef GeneralCoarsenedMatrix<vSpinColourVector,vTComplex,nbasis> LittleDiracOperator;
  typedef LittleDiracOperator::CoarseVector CoarseVector;
  NextToNextToNextToNearestStencilGeometry5D geom(Coarse5d);
  // Warning: This routine calls PVdagM.Op, not PVdagM.HermOp
  typedef Aggregation<vSpinColourVector,vTComplex,nbasis> Subspace;
  Subspace Aggregates(Coarse5d,FrbGrid,cb);
  ////////////////////////////////////////////////////////////
  // Need to check about red-black grid coarsening
  ////////////////////////////////////////////////////////////
  //  LittleDiracOperator LittleDiracOp(geom,FrbGrid,Coarse5d);
  std::string subspace_file("/lustre/orion/phy157/proj-shared/phy157_dwf/paboyle/Subspace.phys48.new.62");
  std::string refine_file("/lustre/orion/phy157/proj-shared/phy157_dwf/paboyle/Refine.phys48.hdcg.62");
  std::string ldop_file("/lustre/orion/phy157/proj-shared/phy157_dwf/paboyle/LittleDiracOp.phys48.new.62");
  std::string evec_file("/lustre/orion/phy157/proj-shared/phy157_dwf/paboyle/evecs.scidac");
  std::string eval_file("/lustre/orion/phy157/proj-shared/phy157_dwf/paboyle/eval.xml");
  bool load_agg=false;
  bool load_refine=false;
  bool load_mat=false;
  bool load_evec=false;
  std::cout << GridLogMessage <<" Restoring from checkpoint "<<std::endl;
  int refine=1;
  if ( load_agg ) {
    if ( !(refine) || (!load_refine) ) { 
      LoadBasis(Aggregates,subspace_file);
    }
  } else {
    //    Aggregates.CreateSubspaceMultishift(RNG5,HermOpEO,
    //					0.0003,1.0e-5,2000); // Lo, tol, maxit
    Aggregates.CreateSubspaceChebyshev(RNG5,HermOpEO,nbasis,95.,0.01,1500); <== last run
    //    Aggregates.CreateSubspaceChebyshevNew(RNG5,HermOpEO,95.); // 176 with refinement
    //    Aggregates.CreateSubspaceChebyshev(RNG5,HermOpEO,nbasis,95.,0.001,3000,1500,200,0.0); // Attempt to resurrect
    SaveBasis(Aggregates,subspace_file);
  }
  std::cout << "**************************************"<<std::endl;
  std::cout << "Building MultiRHS Coarse operator"<<std::endl;
  std::cout << "**************************************"<<std::endl;
  ConjugateGradient<CoarseVector>  coarseCG(4.0e-2,20000,true);
  const int nrhs=vComplex::Nsimd()*3; // 12
  Coordinate mpi=GridDefaultMpi();
  Coordinate rhMpi ({1,1,mpi[0],mpi[1],mpi[2],mpi[3]});
  Coordinate rhLatt({nrhs,1,clatt[0],clatt[1],clatt[2],clatt[3]});
  Coordinate rhSimd({vComplex::Nsimd(),1, 1,1,1,1});
  GridCartesian *CoarseMrhs = new GridCartesian(rhLatt,rhSimd,rhMpi); 
  typedef MultiGeneralCoarsenedMatrix<vSpinColourVector,vTComplex,nbasis> MultiGeneralCoarsenedMatrix_t;
  MultiGeneralCoarsenedMatrix_t mrhs(geom,CoarseMrhs);
  std::cout << "**************************************"<<std::endl;
  std::cout << "         Coarse Lanczos               "<<std::endl;
  std::cout << "**************************************"<<std::endl;
  typedef HermitianLinearOperator<MultiGeneralCoarsenedMatrix_t,CoarseVector> MrhsHermMatrix;
  //  FunctionHermOp<CoarseVector> IRLOpCheby(IRLCheby,CoarseOp);
  //  PlainHermOp<CoarseVector>    IRLOp    (CoarseOp);
  Chebyshev<CoarseVector>      IRLCheby(0.006,42.0,301);  // 1 iter
  MrhsHermMatrix MrhsCoarseOp     (mrhs);
  CoarseVector pm_src(CoarseMrhs);
  pm_src = ComplexD(1.0);
  PowerMethod<CoarseVector>       cPM;   cPM(MrhsCoarseOp,pm_src);
  int Nk=192;
  int Nm=384;
  int Nstop=Nk;
  int Nconv_test_interval=1;
  ImplicitlyRestartedBlockLanczosCoarse<CoarseVector> IRL(MrhsCoarseOp,
 							  Coarse5d,
 							  CoarseMrhs,
 							  nrhs,
 							  IRLCheby,
 							  Nstop,
 							  Nconv_test_interval,
 							  nrhs,
 							  Nk,
 							  Nm,
 							  1e-5,10);
  int Nconv;
  std::vector<RealD>            eval(Nm);
  std::vector<CoarseVector>     evec(Nm,Coarse5d);
  std::vector<CoarseVector>     c_src(nrhs,Coarse5d);
  ///////////////////////
  // Deflation guesser object
  ///////////////////////
  MultiRHSDeflation<CoarseVector> MrhsGuesser;
  //////////////////////////////////////////
  // Block projector for coarse/fine
  //////////////////////////////////////////
  MultiRHSBlockProject<LatticeFermionD> MrhsProjector;
  //////////////////////////
  // Extra HDCG parameters
  //////////////////////////
  int maxit=3000;
  ConjugateGradient<CoarseVector>  CG(5.0e-2,maxit,false);
  RealD lo=2.0;
  int ord = 7;
  DoNothingGuesser<CoarseVector> DoNothing;
  HPDSolver<CoarseVector> HPDSolveMrhs(MrhsCoarseOp,CG,DoNothing);
  HPDSolver<CoarseVector> HPDSolveMrhsRefine(MrhsCoarseOp,CG,DoNothing);
  /////////////////////////////////////////////////
  // Mirs smoother
  /////////////////////////////////////////////////
  RealD MirsShift = lo;
  ShiftedHermOpLinearOperator<LatticeFermionD> ShiftedFineHermOp(HermOpEO,MirsShift);
  CGSmoother<LatticeFermionD> CGsmooth(ord,ShiftedFineHermOp) ;
  if ( load_refine ) {
    LoadBasis(Aggregates,refine_file);
  } else {
 #if 1
    // Make a copy as subspace gets block orthogonalised
    // HDCG used Pcg to refine
    int Refineord = 11;
    // Not as good as refining with shifted CG (169 iters), but 10%
    // Datapoints
    //- refining to 0.001 and shift 0.0 is expensive, but gets to 180 outer iterations
    //- refining to 0.001 and shift 0.001 is cheap, but gets to 240 outer iterations  
    //- refining to 0.0005 and shift 0.0005 is cheap, but gets to 230 outer iterations  
    //- refining to 0.001 and shift 0.0001 220 iterations
    //- refining to 0.001 and shift 0.00003 
    RealD RefineShift = 0.00003;
    RealD RefineTol   = 0.001;
    ShiftedHermOpLinearOperator<LatticeFermionD> RefineFineHermOp(HermOpEO,RefineShift);
    mrhs.CoarsenOperator(RefineFineHermOp,Aggregates,Coarse5d);
    MrhsProjector.Allocate(nbasis,FrbGrid,Coarse5d);
    MrhsProjector.ImportBasis(Aggregates.subspace);
    // Lanczos with random start
    for(int r=0;r<nrhs;r++){
      random(CRNG,c_src[r]);
    }
    IRL.calc(eval,evec,c_src,Nconv,LanczosType::irbl);
    MrhsGuesser.ImportEigenBasis(evec,eval);
    CGSmoother<LatticeFermionD> CGsmooth(Refineord,ShiftedFineHermOp) ;
    TwoLevelADEF2mrhs<LatticeFermion,CoarseVector>
      HDCGmrhsRefine(RefineTol, 500,
 		     RefineFineHermOp,
 		     CGsmooth,
 		     HPDSolveMrhs,    // Used in M1
 		     HPDSolveMrhs,    // Used in Vstart
 		     MrhsProjector,
 		     MrhsGuesser,
 		     CoarseMrhs);
    // Reload the first pass aggregates, because we orthogonalised them
    LoadBasis(Aggregates,subspace_file);
    Aggregates.RefineSubspaceHDCG(HermOpEO,
 				  HDCGmrhsRefine,
 				  nrhs);
 #else     
    Aggregates.RefineSubspace(HermOpEO,0.001,1.0e-3,3000); // 172 iters
 #endif
    SaveBasis(Aggregates,refine_file);
  }
  Aggregates.Orthogonalise();
  /*
  if ( load_mat ) {
    LoadOperator(LittleDiracOp,ldop_file);
  } else {
    LittleDiracOp.CoarsenOperator(FineHermOp,Aggregates);
    SaveOperator(LittleDiracOp,ldop_file);
  }
  */
  std::cout << "**************************************"<<std::endl;
  std::cout << "Coarsen after refine"<<std::endl;
  std::cout << "**************************************"<<std::endl;
  mrhs.CoarsenOperator(FineHermOp,Aggregates,Coarse5d);
  std::cout << "**************************************"<<std::endl;
  std::cout << " Recompute coarse evecs ; use old evecs as source  "<<std::endl;
  std::cout << "**************************************"<<std::endl;
  evec.resize(Nm,Coarse5d);
  eval.resize(Nm);
  for(int r=0;r<nrhs;r++){
    //    c_src[r]=Zero();
    random(CRNG,c_src[r]);
  }
  for(int e=0;e<evec.size();e++){
    //    int r = e%nrhs;
    //    c_src[r] = c_src[r]+evec[r];
  }
 IRL.calc(eval,evec,c_src,Nconv,LanczosType::irbl);
  std::cout << "**************************************"<<std::endl;
  std::cout << " Reimport coarse evecs  "<<std::endl;
  std::cout << "**************************************"<<std::endl;
  MrhsGuesser.ImportEigenBasis(evec,eval);
  std::cout << "**************************************"<<std::endl;
  std::cout << "Calling mRHS HDCG"<<std::endl;
  std::cout << "**************************************"<<std::endl;
  MrhsProjector.Allocate(nbasis,FrbGrid,Coarse5d);
  MrhsProjector.ImportBasis(Aggregates.subspace);
  TwoLevelADEF2mrhs<LatticeFermion,CoarseVector>
    HDCGmrhs(1.0e-8, 500,
 	     FineHermOp,
 	     CGsmooth,
 	     HPDSolveMrhs,    // Used in M1
 	     HPDSolveMrhs,          // Used in Vstart
 	     MrhsProjector,
 	     MrhsGuesser,
 	     CoarseMrhs);
  std::vector<LatticeFermionD> src_mrhs(nrhs,FrbGrid);
  std::vector<LatticeFermionD> res_mrhs(nrhs,FrbGrid);
  for(int r=0;r<nrhs;r++){
    random(RNG5,src_mrhs[r]);
    res_mrhs[r]=Zero();
  }
  HDCGmrhs(src_mrhs,res_mrhs);
  // Standard CG
 #if 0
  {
  std::cout << "**************************************"<<std::endl;
  std::cout << "Calling red black CG"<<std::endl;
  std::cout << "**************************************"<<std::endl;
    LatticeFermion result(FrbGrid); result=Zero();
    LatticeFermion    src(FrbGrid); random(RNG5,src);
    result=Zero();
    CGfine(HermOpEO, src, result);
  }
 #endif  
  Grid_finalize();
  return 0;
 }
--- a/tests/debug/Test_general_coarse_hdcg_phys48_mixed.cc
+++ b/tests/debug/Test_general_coarse_hdcg_phys48_mixed.cc
@@ -0,0 +1,388 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./tests/Test_general_coarse_hdcg.cc
    Copyright (C) 2023
 Author: Peter Boyle <pboyle@bnl.gov>
    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.h>
 #include <Grid/algorithms/iterative/ImplicitlyRestartedBlockLanczos.h>
 #include <Grid/algorithms/iterative/ImplicitlyRestartedBlockLanczosCoarse.h>
 #include <Grid/algorithms/iterative/AdefMrhs.h>
 using namespace std;
 using namespace Grid;
 template<class aggregation>
 void SaveBasis(aggregation &Agg,std::string file)
 {
 #ifdef HAVE_LIME
  emptyUserRecord record;
  ScidacWriter WR(Agg.FineGrid->IsBoss());
  WR.open(file);
  for(int b=0;b<Agg.subspace.size();b++){
    WR.writeScidacFieldRecord(Agg.subspace[b],record,0,Grid::BinaryIO::BINARYIO_LEXICOGRAPHIC);
    //    WR.writeScidacFieldRecord(Agg.subspace[b],record);
  }
  WR.close();
 #endif
 }
 template<class aggregation>
 void LoadBasis(aggregation &Agg, std::string file)
 {
 #ifdef HAVE_LIME
  emptyUserRecord record;
  ScidacReader RD ;
  RD.open(file);
  for(int b=0;b<Agg.subspace.size();b++){
    RD.readScidacFieldRecord(Agg.subspace[b],record,Grid::BinaryIO::BINARYIO_LEXICOGRAPHIC);
    //    RD.readScidacFieldRecord(Agg.subspace[b],record,0);
  }    
  RD.close();
 #endif
 }
 template<class CoarseVector>
 void SaveEigenvectors(std::vector<RealD>            &eval,
 		      std::vector<CoarseVector>     &evec,
 		      std::string evec_file,
 		      std::string eval_file)
 {
 #ifdef HAVE_LIME
  emptyUserRecord record;
  ScidacWriter WR(evec[0].Grid()->IsBoss());
  WR.open(evec_file);
  for(int b=0;b<evec.size();b++){
    WR.writeScidacFieldRecord(evec[b],record,0,0);
  }
  WR.close();
  XmlWriter WRx(eval_file);
  write(WRx,"evals",eval);
 #endif
 }
 template<class CoarseVector>
 void LoadEigenvectors(std::vector<RealD>            &eval,
 		      std::vector<CoarseVector>     &evec,
 		      std::string evec_file,
 		      std::string eval_file)
 {
 #ifdef HAVE_LIME
    XmlReader RDx(eval_file);
    read(RDx,"evals",eval);
    emptyUserRecord record;
    Grid::ScidacReader RD ;
    RD.open(evec_file);
    assert(evec.size()==eval.size());
    for(int k=0;k<eval.size();k++) {
      RD.readScidacFieldRecord(evec[k],record);
    }
    RD.close();
 #endif
 }
 // Want Op in CoarsenOp to call MatPcDagMatPc
 template<class Field>
 class HermOpAdaptor : public LinearOperatorBase<Field>
 {
  LinearOperatorBase<Field> & wrapped;
 public:
  HermOpAdaptor(LinearOperatorBase<Field> &wrapme) : wrapped(wrapme)  {};
  void Op     (const Field &in, Field &out)   { wrapped.HermOp(in,out);  }
  void HermOp(const Field &in, Field &out)    { wrapped.HermOp(in,out); }
  void AdjOp     (const Field &in, Field &out){ wrapped.HermOp(in,out);  }
  void OpDiag (const Field &in, Field &out)                  {    assert(0);  }
  void OpDir  (const Field &in, Field &out,int dir,int disp) {    assert(0);  }
  void OpDirAll  (const Field &in, std::vector<Field> &out)  {    assert(0);  };
  void HermOpAndNorm(const Field &in, Field &out,RealD &n1,RealD &n2){    assert(0);  }
 };
 template<class Field> class CGSmoother : public LinearFunction<Field>
 {
 public:
  using LinearFunction<Field>::operator();
  typedef LinearOperatorBase<Field> FineOperator;
  FineOperator   & _SmootherOperator;
  int iters;
  CGSmoother(int _iters, FineOperator &SmootherOperator) :
    _SmootherOperator(SmootherOperator),
    iters(_iters)
  {
    std::cout << GridLogMessage<<" Mirs smoother order "<<iters<<std::endl;
  };
  void operator() (const Field &in, Field &out) 
  {
    ConjugateGradient<Field>  CG(0.0,iters,false); // non-converge is just fine in a smoother
    out=Zero();
    CG(_SmootherOperator,in,out);
  }
 };
 int main (int argc, char ** argv)
 {
  Grid_init(&argc,&argv);
  const int Ls=24;
  const int nbasis = 60;
  const int cb = 0 ;
  RealD mass=0.00078;
  RealD M5=1.8;
  RealD b=1.5;
  RealD c=0.5;
  GridCartesian         * UGrid   = SpaceTimeGrid::makeFourDimGrid(GridDefaultLatt(),
 								   GridDefaultSimd(Nd,vComplex::Nsimd()),
 								   GridDefaultMpi());
  GridRedBlackCartesian * UrbGrid = SpaceTimeGrid::makeFourDimRedBlackGrid(UGrid);
  GridCartesian         * FGrid   = SpaceTimeGrid::makeFiveDimGrid(Ls,UGrid);
  GridRedBlackCartesian * FrbGrid = SpaceTimeGrid::makeFiveDimRedBlackGrid(Ls,UGrid);
  // Construct a coarsened grid with 4^4 cell
  Coordinate Block({4,4,4,4});
  Coordinate clatt = GridDefaultLatt();
  for(int d=0;d<clatt.size();d++){
    clatt[d] = clatt[d]/Block[d];
  }
  GridCartesian *Coarse4d =  SpaceTimeGrid::makeFourDimGrid(clatt,
 							    GridDefaultSimd(Nd,vComplex::Nsimd()),
 							    GridDefaultMpi());;
  GridCartesian *Coarse5d =  SpaceTimeGrid::makeFiveDimGrid(1,Coarse4d);
  ///////////////////////// RNGs /////////////////////////////////
  std::vector<int> seeds4({1,2,3,4});
  std::vector<int> seeds5({5,6,7,8});
  std::vector<int> cseeds({5,6,7,8});
  GridParallelRNG          RNG5(FGrid);   RNG5.SeedFixedIntegers(seeds5);
  GridParallelRNG          RNG4(UGrid);   RNG4.SeedFixedIntegers(seeds4);
  GridParallelRNG          CRNG(Coarse5d);CRNG.SeedFixedIntegers(cseeds);
  ///////////////////////// Configuration /////////////////////////////////
  LatticeGaugeField Umu(UGrid);
  FieldMetaData header;
  std::string file("ckpoint_lat.1000");
  NerscIO::readConfiguration(Umu,header,file);
  //////////////////////// Fermion action //////////////////////////////////
  MobiusFermionD Ddwf(Umu,*FGrid,*FrbGrid,*UGrid,*UrbGrid,mass,M5,b,c);
  SchurDiagMooeeOperator<MobiusFermionD, LatticeFermion> HermOpEO(Ddwf);
  typedef HermOpAdaptor<LatticeFermionD> HermFineMatrix;
  HermFineMatrix FineHermOp(HermOpEO);
  ////////////////////////////////////////////////////////////
  ///////////// Coarse basis and Little Dirac Operator ///////
  ////////////////////////////////////////////////////////////
  typedef GeneralCoarsenedMatrix<vSpinColourVector,vTComplex,nbasis> LittleDiracOperator;
  typedef LittleDiracOperator::CoarseVector CoarseVector;
  NextToNextToNextToNearestStencilGeometry5D geom(Coarse5d);
  typedef Aggregation<vSpinColourVector,vTComplex,nbasis> Subspace;
  Subspace Aggregates(Coarse5d,FrbGrid,cb);
  ////////////////////////////////////////////////////////////
  // Need to check about red-black grid coarsening
  ////////////////////////////////////////////////////////////
  std::string subspace_file("/lustre/orion/phy157/proj-shared/phy157_dwf/paboyle/Subspace.phys48.mixed.2500.60");
  //  std::string subspace_file("/lustre/orion/phy157/proj-shared/phy157_dwf/paboyle/Subspace.phys48.new.62");
  std::string refine_file("/lustre/orion/phy157/proj-shared/phy157_dwf/paboyle/Refine.phys48.mixed.2500.60");
  std::string ldop_file("/lustre/orion/phy157/proj-shared/phy157_dwf/paboyle/LittleDiracOp.phys48.mixed.60");
  std::string evec_file("/lustre/orion/phy157/proj-shared/phy157_dwf/paboyle/evecs.scidac");
  std::string eval_file("/lustre/orion/phy157/proj-shared/phy157_dwf/paboyle/eval.xml");
  bool load_agg=true;
  bool load_refine=true;
  bool load_mat=false;
  bool load_evec=false;
  int refine=1;
  if ( load_agg ) {
    if ( !(refine) || (!load_refine) ) { 
      LoadBasis(Aggregates,subspace_file);
    }
  } else {
    //    Aggregates.CreateSubspaceMultishift(RNG5,HermOpEO,
    //    					0.0003,1.0e-5,2000); // Lo, tol, maxit
    //    Aggregates.CreateSubspaceChebyshev(RNG5,HermOpEO,nbasis,95.,0.01,1500);// <== last run
    Aggregates.CreateSubspaceChebyshevNew(RNG5,HermOpEO,95.); 
    SaveBasis(Aggregates,subspace_file);
  }
  std::cout << "**************************************"<<std::endl;
  std::cout << "Building MultiRHS Coarse operator"<<std::endl;
  std::cout << "**************************************"<<std::endl;
  ConjugateGradient<CoarseVector>  coarseCG(4.0e-2,20000,true);
  const int nrhs=12;
  Coordinate mpi=GridDefaultMpi();
  Coordinate rhMpi ({1,1,mpi[0],mpi[1],mpi[2],mpi[3]});
  Coordinate rhLatt({nrhs,1,clatt[0],clatt[1],clatt[2],clatt[3]});
  Coordinate rhSimd({vComplex::Nsimd(),1, 1,1,1,1});
  GridCartesian *CoarseMrhs = new GridCartesian(rhLatt,rhSimd,rhMpi); 
  typedef MultiGeneralCoarsenedMatrix<vSpinColourVector,vTComplex,nbasis> MultiGeneralCoarsenedMatrix_t;
  MultiGeneralCoarsenedMatrix_t mrhs(geom,CoarseMrhs);
  std::cout << "**************************************"<<std::endl;
  std::cout << "         Coarse Lanczos               "<<std::endl;
  std::cout << "**************************************"<<std::endl;
  typedef HermitianLinearOperator<MultiGeneralCoarsenedMatrix_t,CoarseVector> MrhsHermMatrix;
  Chebyshev<CoarseVector>      IRLCheby(0.005,42.0,301);  // 1 iter
  MrhsHermMatrix MrhsCoarseOp     (mrhs);
  CoarseVector pm_src(CoarseMrhs);
  pm_src = ComplexD(1.0);
  PowerMethod<CoarseVector>       cPM;   cPM(MrhsCoarseOp,pm_src);
  int Nk=192;
  int Nm=384;
  int Nstop=Nk;
  int Nconv_test_interval=1;
  ImplicitlyRestartedBlockLanczosCoarse<CoarseVector> IRL(MrhsCoarseOp,
 							  Coarse5d,
 							  CoarseMrhs,
 							  nrhs,
 							  IRLCheby,
 							  Nstop,
 							  Nconv_test_interval,
 							  nrhs,
 							  Nk,
 							  Nm,
 							  1e-5,10);
  int Nconv;
  std::vector<RealD>            eval(Nm);
  std::vector<CoarseVector>     evec(Nm,Coarse5d);
  std::vector<CoarseVector>     c_src(nrhs,Coarse5d);
  ///////////////////////
  // Deflation guesser object
  ///////////////////////
  MultiRHSDeflation<CoarseVector> MrhsGuesser;
  //////////////////////////////////////////
  // Block projector for coarse/fine
  //////////////////////////////////////////
  MultiRHSBlockProject<LatticeFermionD> MrhsProjector;
  //////////////////////////
  // Extra HDCG parameters
  //////////////////////////
  int maxit=3000;
  ConjugateGradient<CoarseVector>  CG(5.0e-2,maxit,false);
  RealD lo=2.0;
  int ord = 7;
  DoNothingGuesser<CoarseVector> DoNothing;
  HPDSolver<CoarseVector> HPDSolveMrhs(MrhsCoarseOp,CG,DoNothing);
  HPDSolver<CoarseVector> HPDSolveMrhsRefine(MrhsCoarseOp,CG,DoNothing);
  /////////////////////////////////////////////////
  // Mirs smoother
  /////////////////////////////////////////////////
  RealD MirsShift = lo;
  ShiftedHermOpLinearOperator<LatticeFermionD> ShiftedFineHermOp(HermOpEO,MirsShift);
  CGSmoother<LatticeFermionD> CGsmooth(ord,ShiftedFineHermOp) ;
  if ( load_refine ) {
    LoadBasis(Aggregates,refine_file);
  } else {
    Aggregates.RefineSubspace(HermOpEO,0.001,1.0e-3,3000); // 172 iters
    SaveBasis(Aggregates,refine_file);
  }
  Aggregates.Orthogonalise();
  std::cout << "**************************************"<<std::endl;
  std::cout << "Coarsen after refine"<<std::endl;
  std::cout << "**************************************"<<std::endl;
  mrhs.CoarsenOperator(FineHermOp,Aggregates,Coarse5d);
  std::cout << "**************************************"<<std::endl;
  std::cout << " Recompute coarse evecs  "<<std::endl;
  std::cout << "**************************************"<<std::endl;
  evec.resize(Nm,Coarse5d);
  eval.resize(Nm);
  for(int r=0;r<nrhs;r++){
    random(CRNG,c_src[r]);
  }
 IRL.calc(eval,evec,c_src,Nconv,LanczosType::irbl);
  std::cout << "**************************************"<<std::endl;
  std::cout << " Reimport coarse evecs  "<<std::endl;
  std::cout << "**************************************"<<std::endl;
  MrhsGuesser.ImportEigenBasis(evec,eval);
  std::cout << "**************************************"<<std::endl;
  std::cout << "Calling mRHS HDCG"<<std::endl;
  std::cout << "**************************************"<<std::endl;
  MrhsProjector.Allocate(nbasis,FrbGrid,Coarse5d);
  MrhsProjector.ImportBasis(Aggregates.subspace);
  TwoLevelADEF2mrhs<LatticeFermion,CoarseVector>
    HDCGmrhs(1.0e-8, 500,
 	     FineHermOp,
 	     CGsmooth,
 	     HPDSolveMrhs,    // Used in M1
 	     HPDSolveMrhs,          // Used in Vstart
 	     MrhsProjector,
 	     MrhsGuesser,
 	     CoarseMrhs);
  std::vector<LatticeFermionD> src_mrhs(nrhs,FrbGrid);
  std::vector<LatticeFermionD> res_mrhs(nrhs,FrbGrid);
  for(int r=0;r<nrhs;r++){
    random(RNG5,src_mrhs[r]);
    res_mrhs[r]=Zero();
  }
  HDCGmrhs(src_mrhs,res_mrhs);
  // Standard CG
 #if 1
  {
  std::cout << "**************************************"<<std::endl;
  std::cout << "Calling red black CG"<<std::endl;
  std::cout << "**************************************"<<std::endl;
    LatticeFermion result(FrbGrid); result=Zero();
    LatticeFermion    src(FrbGrid); random(RNG5,src);
    result=Zero();
    ConjugateGradient<LatticeFermionD>  CGfine(1.0e-8,30000,false);
    CGfine(HermOpEO, src, result);
  }
 #endif  
  Grid_finalize();
  return 0;
 }
--- a/tests/debug/Test_general_coarse_pvdagm.cc
+++ b/tests/debug/Test_general_coarse_pvdagm.cc
@@ -0,0 +1,267 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./tests/Test_padded_cell.cc
    Copyright (C) 2023
 Author: Peter Boyle <paboyle@ph.ed.ac.uk>
    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.h>
 #include <Grid/lattice/PaddedCell.h>
 #include <Grid/stencil/GeneralLocalStencil.h>
 #include <Grid/algorithms/iterative/PrecGeneralisedConjugateResidual.h>
 #include <Grid/algorithms/iterative/PrecGeneralisedConjugateResidualNonHermitian.h>
 #include <Grid/algorithms/iterative/BiCGSTAB.h>
 using namespace std;
 using namespace Grid;
 template<class Field>
 class HermOpAdaptor : public LinearOperatorBase<Field>
 {
  LinearOperatorBase<Field> & wrapped;
 public:
  HermOpAdaptor(LinearOperatorBase<Field> &wrapme) : wrapped(wrapme)  {};
  void OpDiag (const Field &in, Field &out) {    assert(0);  }
  void OpDir  (const Field &in, Field &out,int dir,int disp) {    assert(0);  }
  void OpDirAll  (const Field &in, std::vector<Field> &out){    assert(0);  };
  void Op     (const Field &in, Field &out){
    wrapped.HermOp(in,out);
  }
  void AdjOp     (const Field &in, Field &out){
    wrapped.HermOp(in,out);
  }
  void HermOpAndNorm(const Field &in, Field &out,RealD &n1,RealD &n2){    assert(0);  }
  void HermOp(const Field &in, Field &out){
    wrapped.HermOp(in,out);
  }
 };
 template<class Matrix,class Field>
 class PVdagMLinearOperator : public LinearOperatorBase<Field> {
  Matrix &_Mat;
  Matrix &_PV;
 public:
  PVdagMLinearOperator(Matrix &Mat,Matrix &PV): _Mat(Mat),_PV(PV){};
  void OpDiag (const Field &in, Field &out) {    assert(0);  }
  void OpDir  (const Field &in, Field &out,int dir,int disp) {    assert(0);  }
  void OpDirAll  (const Field &in, std::vector<Field> &out){    assert(0);  };
  void Op     (const Field &in, Field &out){
    Field tmp(in.Grid());
    _Mat.M(in,tmp);
    _PV.Mdag(tmp,out);
  }
  void AdjOp     (const Field &in, Field &out){
    Field tmp(in.Grid());
    _PV.M(tmp,out);
    _Mat.Mdag(in,tmp);
  }
  void HermOpAndNorm(const Field &in, Field &out,RealD &n1,RealD &n2){    assert(0);  }
  void HermOp(const Field &in, Field &out){
    std::cout << "HermOp"<<std::endl;
    Field tmp(in.Grid());
    _Mat.M(in,tmp);
    _PV.Mdag(tmp,out);
    _PV.M(out,tmp);
    _Mat.Mdag(tmp,out);
    std::cout << "HermOp done "<<norm2(out)<<std::endl;
  }
 };
 template<class Field> class DumbOperator  : public LinearOperatorBase<Field> {
 public:
  LatticeComplex scale;
  DumbOperator(GridBase *grid) : scale(grid)
  {
    scale = 0.0;
    LatticeComplex scalesft(grid);
    LatticeComplex scaletmp(grid);
    for(int d=0;d<4;d++){
      Lattice<iScalar<vInteger> > x(grid); LatticeCoordinate(x,d+1);
      LatticeCoordinate(scaletmp,d+1);
      scalesft = Cshift(scaletmp,d+1,1);
      scale = 100.0*scale + where( mod(x    ,2)==(Integer)0, scalesft,scaletmp);
    }
    std::cout << " scale\n" << scale << std::endl;
  }
  // Support for coarsening to a multigrid
  void OpDiag (const Field &in, Field &out) {};
  void OpDir  (const Field &in, Field &out,int dir,int disp){};
  void OpDirAll  (const Field &in, std::vector<Field> &out) {};
  void Op     (const Field &in, Field &out){
    out = scale * in;
  }
  void AdjOp  (const Field &in, Field &out){
    out = scale * in;
  }
  void HermOp(const Field &in, Field &out){
    double n1, n2;
    HermOpAndNorm(in,out,n1,n2);
  }
  void HermOpAndNorm(const Field &in, Field &out,double &n1,double &n2){
    ComplexD dot;
    out = scale * in;
    dot= innerProduct(in,out);
    n1=real(dot);
    dot = innerProduct(out,out);
    n2=real(dot);
  }
 };
 int main (int argc, char ** argv)
 {
  Grid_init(&argc,&argv);
  const int Ls=2;
  GridCartesian         * UGrid   = SpaceTimeGrid::makeFourDimGrid(GridDefaultLatt(), GridDefaultSimd(Nd,vComplex::Nsimd()),GridDefaultMpi());
  GridRedBlackCartesian * UrbGrid = SpaceTimeGrid::makeFourDimRedBlackGrid(UGrid);
  GridCartesian         * FGrid   = SpaceTimeGrid::makeFiveDimGrid(Ls,UGrid);
  GridRedBlackCartesian * FrbGrid = SpaceTimeGrid::makeFiveDimRedBlackGrid(Ls,UGrid);
  // Construct a coarsened grid
  Coordinate clatt = GridDefaultLatt();
  for(int d=0;d<clatt.size();d++){
    clatt[d] = clatt[d]/4;
  }
  GridCartesian *Coarse4d =  SpaceTimeGrid::makeFourDimGrid(clatt, GridDefaultSimd(Nd,vComplex::Nsimd()),GridDefaultMpi());;
  GridCartesian *Coarse5d =  SpaceTimeGrid::makeFiveDimGrid(1,Coarse4d);
  std::vector<int> seeds4({1,2,3,4});
  std::vector<int> seeds5({5,6,7,8});
  std::vector<int> cseeds({5,6,7,8});
  GridParallelRNG          RNG5(FGrid);   RNG5.SeedFixedIntegers(seeds5);
  GridParallelRNG          RNG4(UGrid);   RNG4.SeedFixedIntegers(seeds4);
  GridParallelRNG          CRNG(Coarse5d);CRNG.SeedFixedIntegers(cseeds);
  LatticeFermion    src(FGrid); random(RNG5,src);
  LatticeFermion result(FGrid); result=Zero();
  LatticeFermion    ref(FGrid); ref=Zero();
  LatticeFermion    tmp(FGrid);
  LatticeFermion    err(FGrid);
  LatticeGaugeField Umu(UGrid);
  FieldMetaData header;
  std::string file("ckpoint_lat.4000");
  NerscIO::readConfiguration(Umu,header,file);
  //Umu = 1.0;
  RealD mass=0.5;
  RealD M5=1.8;
  DomainWallFermionD Ddwf(Umu,*FGrid,*FrbGrid,*UGrid,*UrbGrid,mass,M5);
  DomainWallFermionD Dpv(Umu,*FGrid,*FrbGrid,*UGrid,*UrbGrid,1.0,M5);
  const int nbasis = 1;
  const int cb = 0 ;
  LatticeFermion prom(FGrid);
  typedef GeneralCoarsenedMatrix<vSpinColourVector,vTComplex,nbasis> LittleDiracOperator;
  typedef LittleDiracOperator::CoarseVector CoarseVector;
  NextToNearestStencilGeometry5D geom(Coarse5d);
  std::cout<<GridLogMessage<<std::endl;
  std::cout<<GridLogMessage<<"*******************************************"<<std::endl;
  std::cout<<GridLogMessage<<std::endl;
  PVdagMLinearOperator<DomainWallFermionD,LatticeFermionD> PVdagM(Ddwf,Dpv);
  HermOpAdaptor<LatticeFermionD> HOA(PVdagM);
  // Run power method on HOA??
  PowerMethod<LatticeFermion>       PM;   PM(HOA,src);
  // Warning: This routine calls PVdagM.Op, not PVdagM.HermOp
  typedef Aggregation<vSpinColourVector,vTComplex,nbasis> Subspace;
  Subspace AggregatesPD(Coarse5d,FGrid,cb);
  AggregatesPD.CreateSubspaceChebyshev(RNG5,
 				       HOA,
 				       nbasis,
 				       5000.0,
 				       0.02,
 				       100,
 				       50,
 				       50,
 				       0.0);
  LittleDiracOperator LittleDiracOpPV(geom,FGrid,Coarse5d);
  LittleDiracOpPV.CoarsenOperator(PVdagM,AggregatesPD);
  std::cout<<GridLogMessage<<std::endl;
  std::cout<<GridLogMessage<<"*******************************************"<<std::endl;
  std::cout<<GridLogMessage<<std::endl;
  std::cout<<GridLogMessage<<"Testing coarsened operator "<<std::endl;
  CoarseVector c_src (Coarse5d);
  CoarseVector c_res (Coarse5d);
  CoarseVector c_proj(Coarse5d);
  std::vector<LatticeFermion> subspace(nbasis,FGrid);
  subspace=AggregatesPD.subspace;
  Complex one(1.0);
  c_src = one;  // 1 in every element for vector 1.
  blockPromote(c_src,err,subspace);
  prom=Zero();
  for(int b=0;b<nbasis;b++){
    prom=prom+subspace[b];
  }
  err=err-prom; 
  std::cout<<GridLogMessage<<"Promoted back from subspace: err "<<norm2(err)<<std::endl;
  std::cout<<GridLogMessage<<"c_src "<<norm2(c_src)<<std::endl;
  std::cout<<GridLogMessage<<"prom  "<<norm2(prom)<<std::endl;
  PVdagM.Op(prom,tmp);
  blockProject(c_proj,tmp,subspace);
  std::cout<<GridLogMessage<<" Called Big Dirac Op "<<norm2(tmp)<<std::endl;
  LittleDiracOpPV.M(c_src,c_res);
  std::cout<<GridLogMessage<<" Called Little Dirac Op c_src "<< norm2(c_src) << "  c_res "<< norm2(c_res) <<std::endl;
  std::cout<<GridLogMessage<<"Little dop : "<<norm2(c_res)<<std::endl;
  //  std::cout<<GridLogMessage<<" Little "<< c_res<<std::endl;
  std::cout<<GridLogMessage<<"Big dop in subspace : "<<norm2(c_proj)<<std::endl;
  //  std::cout<<GridLogMessage<<" Big "<< c_proj<<std::endl;
  c_proj = c_proj - c_res;
  std::cout<<GridLogMessage<<" ldop error: "<<norm2(c_proj)<<std::endl;
  //  std::cout<<GridLogMessage<<" error "<< c_proj<<std::endl;
  std::cout<<GridLogMessage<<std::endl;
  std::cout<<GridLogMessage<<"*******************************************"<<std::endl;
  std::cout<<GridLogMessage<<std::endl;
  std::cout<<GridLogMessage << "Done "<< std::endl;
  Grid_finalize();
  return 0;
 }
Author	SHA1	Message	Date
Peter Boyle	ad14a82742	Working aas good as possible on 48^3 in double	2024-05-16 10:55:45 -04:00
Peter Boyle	14e9d8ed9f	CG improvements for smoother	2024-05-16 10:55:18 -04:00
Peter Boyle	0ac85fa70b	Serialisation removal	2024-05-16 10:49:04 -04:00
Peter Boyle	c371de42b9	Some site tools for sitewise autocorr	2024-05-16 10:48:23 -04:00
Peter Boyle	5c3ace7c3e	Merge branch 'develop' into feature/scidac-wp1	2024-04-30 05:26:06 -04:00
Peter Boyle	aa148455b7	Updated todo list	2024-04-30 05:24:39 -04:00
Peter Boyle	98cf247f33	prepare to switch to mixed precision	2024-04-30 05:23:45 -04:00
Peter Boyle	0cf16522d1	Refine with HDCG choice	2024-04-30 05:22:14 -04:00
Peter Boyle	7b7c75f9e5	Setup	2024-04-30 05:21:02 -04:00
Peter Boyle	aefd255a3c	Verbose	2024-04-30 05:20:41 -04:00
Peter Boyle	1c5aa939fd	Subspace setup changes	2024-04-30 05:19:09 -04:00
Peter Boyle	3a0ff17be0	Verbose changes	2024-04-30 05:17:28 -04:00
Peter Boyle	47829ae5cc	Verbose changes	2024-04-30 05:16:46 -04:00
Peter Boyle	bfa7b69aff	Verbose changes	2024-04-16 15:42:46 -04:00
Peter Boyle	2aaa959b5f	Printing changes	2024-04-16 15:41:25 -04:00
Peter Boyle	ce2970b93a	Printing changes	2024-04-16 15:40:38 -04:00
Peter Boyle	7b76970d10	Verbose changes	2024-04-16 15:40:10 -04:00
Peter Boyle	9fd41882d2	Herm Op update	2024-04-16 15:39:27 -04:00
Peter Boyle	ff2ea5de18	Update Tensor_traits.h	2024-04-11 14:25:45 -04:00
Peter Boyle	5147a42818	Updated hdcg	2024-04-05 01:05:57 -04:00
Peter Boyle	57552d8ca3	Assign from non-lattice made accelerator resident	2024-04-05 01:05:12 -04:00
Peter Boyle	13713b2a76	Much faster little dirac operator calculation	2024-04-05 01:04:40 -04:00
Peter Boyle	36a14e4ee3	Best setup and introduce an HDCG refine method	2024-04-05 01:03:33 -04:00
Peter Boyle	b4cc788b8c	First version used in mrhsHDCG Need to consolidate files. Plan: Make this version able to go virtual base, then absorb chulwoos version when it is proven	2024-04-05 01:02:21 -04:00
Peter Boyle	0f0e7512f3	Keep MRHS in a different file	2024-04-05 00:59:53 -04:00
Peter Boyle	1196b1a161	Less verbose	2024-04-05 00:58:58 -04:00
Peter Boyle	2c8c3be9ee	Adef2Mrhs	2024-04-05 00:57:13 -04:00
Peter Boyle	5b79d51c22	Improvements	2024-04-01 14:18:40 -04:00
Peter Boyle	da890dc293	Verbose changes	2024-04-01 14:18:00 -04:00
Peter Boyle	93d0a1e73a	HISQ view call	2024-04-01 14:16:47 -04:00
Peter Boyle	f0a8c7d045	Playing with chebyshevs	2024-04-01 14:16:11 -04:00
Peter Boyle	db8793777c	Logging/verbose	2024-04-01 14:15:41 -04:00
Peter Boyle	c745484e65	9.5x speed up version	2024-04-01 14:14:30 -04:00
Peter Boyle	da59379612	Large reg file for double	2024-03-26 17:03:20 +00:00
Peter Boyle	3ef2a41518	ifdef guard ommitted	2024-03-26 14:50:32 +00:00
Peter Boyle	aa96f420c6	Acclerator ware MPI guard on the Unix domain sockets	2024-03-26 14:41:25 +00:00
Peter Boyle	49e9e4ed0e	Fences	2024-03-26 14:14:06 +00:00
Peter Boyle	f7b8163016	Deterministic MPI reduce options	2024-03-26 14:11:40 +00:00
Peter Boyle	93769eacd3	Updated configure for bounce through host	2024-03-26 14:10:24 +00:00
Peter Boyle	59b0cc11df	REduce the time in single	2024-03-26 00:42:40 +00:00
Peter Boyle	f32c275376	Updated config options for MPI not being aware of GPU	2024-03-26 00:42:00 +00:00
Peter Boyle	5404fc66ab	Merge needs a fence on SYCL	2024-03-26 00:38:41 +00:00
Peter Boyle	1f53458af8	Options to bounce through a host buffer if --disable-accelerator-aware-mpi	2024-03-26 00:37:19 +00:00
Peter Boyle	434c3e7f1d	We have a choice of GET or PUT across NVlink	2024-03-25 14:32:44 +00:00
Peter Boyle	500b119f3d	Deterministic MPI	2024-03-22 15:55:23 +00:00
Peter Boyle	4b87259c1b	New config command for sunspot	2024-03-22 15:43:49 +00:00
Peter Boyle	503dec34ef	This appears working now on Sunspot	2024-03-22 15:43:30 +00:00
Peter Boyle	d1e9fe50d2	Xor csum for repro testing	2024-03-22 15:42:57 +00:00
Peter Boyle	d01e5fa838	Improved FlightRecorder	2024-03-22 15:42:32 +00:00
Peter Boyle	a477c25e8c	Sunspot repro tests	2024-03-22 15:42:11 +00:00
Peter Boyle	1bd20cd9e8	FlightRecorder	2024-03-22 15:40:01 +00:00
Peter Boyle	e49e95b037	Upgrade of the Britney test with flight recorder and fast xor checksum	2024-03-22 15:39:27 +00:00
Peter Boyle	6f59fed563	Flight recorder, resurrecting the "world famous" Britney test	2024-03-22 15:32:32 +00:00
Peter Boyle	60b7f6c99d	Flight recorder, resurrecting the "world famous" Britney test	2024-03-22 15:32:26 +00:00
Peter Boyle	b92dfcc8d3	Flight recorder, resurrecting the "world famous" Britney test	2024-03-22 15:30:27 +00:00
Peter Boyle	f6fd6dd053	Flight recorder, resurrecting the "world famous" Britney test	2024-03-22 15:30:01 +00:00
Peter Boyle	79ad567dd5	Merge branch 'develop' of https://github.com/paboyle/Grid into develop	2024-03-19 15:43:42 +00:00
Peter Boyle	fab1efb48c	More britney logging improvements	2024-03-19 14:36:21 +00:00
Peter Boyle	660eb76d93	FFTW from OneAPI	2024-03-19 14:28:33 +00:00
Peter Boyle	62e7bf024a	Updated flight logging for Britney test	2024-03-12 20:10:04 +00:00
Peter Boyle	95f3d69cf9	Extra hardware test hook	2024-03-12 20:09:37 +00:00
Peter Boyle	89c0519f83	Repro test	2024-03-12 16:11:33 +00:00
Peter Boyle	2704b82084	Merge branch 'develop' of https://github.com/paboyle/Grid into develop	2024-03-12 15:16:24 +00:00
Peter Boyle	cf8632bbac	Britney test option	2024-03-12 15:15:35 +00:00
Peter Boyle	d224297972	PBS scripts	2024-03-12 15:15:16 +00:00
Peter Boyle	a4d11a630f	Merge pull request #458 from paboyle/fix/HOST_NAME_MAX fallback to _POSIX_HOST_NAME_MAX if HOST_NAME_MAX is not defined	2024-03-07 07:50:25 -05:00
Peter Boyle	cc04dc42dc	Merge branch 'develop' into feature/scidac-wp1	2024-03-06 14:55:21 -05:00
Peter Boyle	070b61f08f	Simplifying the MultiRHS solver to make it do SRHS and MRHS	2024-03-06 14:04:33 -05:00
Peter Boyle	ee3b3c4c56	relocate deflation support	2024-02-27 11:52:23 -05:00
Peter Boyle	462d706a63	Move to a blas directory	2024-02-27 11:51:04 -05:00
Peter Boyle	ee0d460c8e	Blas based block project & deflate for multiRHS	2024-02-27 11:41:44 -05:00
Peter Boyle	cd15abe9d1	Mrhs prep	2024-02-27 11:41:13 -05:00
Peter Boyle	9f40467e24	Warning squash	2024-02-27 11:40:36 -05:00
Peter Boyle	d0b6593823	More verbose on checksum	2024-02-27 11:40:14 -05:00
Peter Boyle	79fc821d8d	reorg headers	2024-02-27 11:39:37 -05:00
Peter Boyle	d7fdb9a7e6	Reorg headers	2024-02-27 11:39:06 -05:00
Peter Boyle	b74de51c18	Reorder headers	2024-02-27 11:38:52 -05:00
Peter Boyle	44b466e072	Make InsertSliceFast the default at some point in future. Should I do this now?	2024-02-21 14:51:24 -05:00
Peter Boyle	5e5b471bb2	Put/Get and DEviceToDevice	2024-02-21 14:47:06 -05:00
Peter Boyle	9c2565f64e	Working and faster version	2024-02-21 14:46:43 -05:00
Peter Boyle	e1d0a7cec3	Batched blas	2024-02-21 14:38:20 -05:00
Peter Boyle	b19ae8f465	Nbasis method for convenience	2024-02-21 14:36:19 -05:00
Peter Boyle	cdff2c8e18	Updated mrhs adef	2024-02-21 14:27:19 -05:00
Peter Boyle	eb702f581b	Running on 12 rhs on 18 nodes of frontier	2024-01-22 17:44:15 -05:00
Peter Boyle	3d13fd56c5	Precompute phases, save memory in hermitian	2024-01-22 17:43:35 -05:00
Peter Boyle	6f51b49ef8	Use stderr	2024-01-22 17:41:09 -05:00
Peter Boyle	addc638856	Fast localCopyRegion, blockProjectFast	2024-01-22 17:40:38 -05:00
Peter Boyle	42ae36bc28	WOrking	2024-01-17 16:39:14 -05:00
Peter Boyle	c69f73ff9f	Working	2024-01-17 16:38:46 -05:00
Peter Boyle	ca5ae8a2e6	Revert to working.	2024-01-17 16:32:05 -05:00
Peter Boyle	d967eb53de	Working for first time	2024-01-17 16:31:12 -05:00
Peter Boyle	839f9f1bbe	Don't log memory by default	2024-01-17 16:25:50 -05:00
Peter Boyle	b754a152c6	Flag guard correctly	2024-01-17 16:25:28 -05:00
Peter Boyle	e07cb2b9de	Accelerator memory	2024-01-17 16:24:31 -05:00
Peter Boyle	a1f8bbb078	accelerator memory print	2024-01-17 16:24:09 -05:00
Peter Boyle	7909683f3b	MultiRHS	2024-01-17 16:21:07 -05:00
Peter Boyle	25f71913b7	MultiRHS coarse	2024-01-04 12:01:17 -05:00
Peter Boyle	34ddd2b7b1	MultiRHS coarse space	2024-01-04 12:00:53 -05:00
Peter Boyle	d5fd90b2f3	Add 48^3 rtest	2024-01-04 12:00:01 -05:00
Peter Boyle	b7c7000d0d	Don't need the numerical rounding tolerance in multigrid	2023-12-22 18:10:23 -05:00
Peter Boyle	551f6c4edd	Synchronise changes	2023-12-22 18:09:11 -05:00
Peter Boyle	defd814750	Speed up the coarsened matrix matrix evaluation. It is block project limited. Could be sped up with calls to Batched GEMM and a data layout change.	2023-12-22 18:07:03 -05:00
Peter Boyle	3d517bbd2a	Synchronise decouple from the launch Speeds up multileg stencils	2023-12-22 18:06:13 -05:00
Peter Boyle	78ab955fec	Better padded cell exchange	2023-12-22 18:05:41 -05:00
Peter Boyle	dd13937bb6	Better opt face gather scatter	2023-12-22 18:03:38 -05:00
Peter Boyle	66a1b63aa9	Faster grid/blas layout change. Halo exchange is now the only slow part. Revisit	2023-12-21 20:50:18 -05:00
Peter Boyle	22c611bd1a	Delete temp file	2023-12-21 18:32:31 -05:00
Peter Boyle	c9bb1bf8ea	Passing new BLAs based	2023-12-21 18:31:17 -05:00
Peter Boyle	9e489887cf	General coarse multiRHS move to BLAS implementation	2023-12-21 15:24:48 -05:00
Peter Boyle	9feb801bb9	Much simpler GPU implementation	2023-12-21 15:24:06 -05:00
Peter Boyle	c00b495933	Multigrid	2023-12-21 15:23:31 -05:00
Peter Boyle	d22eebe553	BLas options	2023-12-21 15:23:03 -05:00
Peter Boyle	8bcbd82680	BLAS based layout and implementation	2023-12-21 15:21:24 -05:00
Peter Boyle	dfa617c439	Batched SGEMM/DGEMM/ZGEMM/CGEMM Hip, Cuda version and vanilla CPU One MKL stub in comments, to be tested as different.	2023-12-21 14:01:18 -05:00
Peter Boyle	48d1f0df89	Optimised partially, working	2023-12-21 12:33:47 -05:00
Peter Boyle	b75cb7a12c	Blas batched partial implementation on Frontier only for now	2023-12-21 12:31:33 -05:00
Peter Boyle	332563e037	Debugged, reducing verbose	2023-12-21 12:30:57 -05:00
Peter Boyle	0cce97a4fe	verbosity only	2023-12-20 21:30:10 -05:00
Peter Boyle	95a8e4be64	rocblas	2023-12-20 21:27:59 -05:00
Peter Boyle	abcd6b8cb6	Faster version	2023-12-19 15:17:46 -05:00
Peter Boyle	e8f21c9b6d	Memmory verbose control improvement	2023-12-19 15:16:58 -05:00
Peter Boyle	e054078b11	Verbose	2023-12-05 16:15:17 -05:00
Peter Boyle	6835a7f208	Better logging, test on 81 point stencil	2023-11-29 19:20:47 -05:00
Peter Boyle	f59993b979	Nbasis§	2023-11-29 09:47:36 -05:00
Peter Boyle	2290b8f680	Verbose	2023-11-29 09:47:04 -05:00
Peter Boyle	2c54be651c	Further updates	2023-11-29 09:43:29 -05:00
Peter Boyle	e859a199df	Reduce volume to interior for coarse stencil -- worth up to 4x gain	2023-11-28 10:23:16 -05:00
Peter Boyle	0a3682ad0b	MultiRHS work	2023-11-28 07:43:37 -05:00
Peter Boyle	59abaeb5cd	Time stamp	2023-11-24 12:56:45 -05:00
Peter Boyle	3e448435d3	Restrict to interior	2023-11-23 18:23:29 -05:00
Peter Boyle	a294bc3c5b	Relax constraints for multiRHS	2023-11-23 18:20:42 -05:00
Peter Boyle	b302ad3d49	multiRHS test in place, passes Yay!	2023-11-23 18:20:15 -05:00
Peter Boyle	82fc4b1e94	Finalise	2023-11-23 18:19:41 -05:00
Peter Boyle	b4f1740380	Finalise message	2023-11-23 18:19:16 -05:00
Peter Boyle	031f85247c	multRHS initial support -- needs optimisation for multi project/promote. Bug fix in freeing intermediate grids to stop double free	2023-11-23 18:18:35 -05:00
Peter Boyle	639cc6f73a	better support for multiRHS coarse space Still to add restriction of domain of last loop to interior of padded cell (expect about 4.5x on test volume on Crusher)	2023-11-23 18:16:26 -05:00
Peter Boyle	09946cf1ba	Improved, works on 48^3 moving to multiRHS optimisations	2023-11-15 18:03:05 -05:00
Peter Boyle	f4fa95e7cb	Use 5.3.0	2023-11-15 18:01:38 -05:00
Peter Boyle	100e29e35e	Allow expression as argument to norm2	2023-11-15 18:00:44 -05:00
Peter Boyle	4cbe471a83	devVector	2023-11-15 18:00:07 -05:00
Peter Boyle	8bece1f861	Faster to transpose the matrix and apply with column major order	2023-11-15 17:58:38 -05:00
Peter Boyle	a3ca71ec01	Lots more setup options, still working on them	2023-11-15 17:58:04 -05:00
Peter Boyle	e0543e8af5	Implement flexible preconditioned CG	2023-11-15 17:57:39 -05:00
Peter Boyle	c1eb80d01a	Print which have converged	2023-11-15 17:57:08 -05:00
Peter Boyle	a26121d97b	Better printing	2023-11-15 17:56:45 -05:00
Peter Boyle	043031a757	Report resid on failed convergence	2023-11-15 17:56:22 -05:00
Peter Boyle	807aeebe4c	Resize tol in constructor	2023-11-15 17:55:57 -05:00
Peter Boyle	8aa1a37aad	For Mirs preconditioner solver	2023-11-15 17:55:32 -05:00
Peter Boyle	4efa042f50	C++17 change	2023-10-24 10:57:50 -04:00
Peter Boyle	c7cb37e970	c++17 accepted	2023-10-24 10:57:24 -04:00
Peter Boyle	d34b207eab	Avoid HIP warnings	2023-10-24 10:57:04 -04:00
Peter Boyle	0e6fa6f6b8	DOn't need the Cshift for the period optimisation	2023-10-24 10:56:31 -04:00
Peter Boyle	38b87de53f	This works around a stacksize limit on AMD GPU	2023-10-24 10:56:07 -04:00
Peter Boyle	aa5047a9e4	Faster blockProject blockPromote	2023-10-24 10:49:55 -04:00
Peter Boyle	24b6ee0df9	M4 file	2023-10-24 10:36:48 -04:00
Peter Boyle	1e79cc9cbe	Avoid compiler error	2023-10-24 10:36:09 -04:00
Peter Boyle	b3925df9c3	Verbose on CPU-GPU xfer, remove performance by default	2023-10-24 10:25:01 -04:00
Peter Boyle	351795ac3a	Better messaging	2023-10-20 19:33:04 -04:00
Peter Boyle	9c9c42d0df	Tests on frontier with real speed up . 3.5x on 16^3 at mq=0.01	2023-10-20 19:27:13 -04:00
Peter Boyle	b6ad1bafc7	Normal memory SendToRecvFrom asynchronous for use in general stencil code	2023-10-20 19:27:13 -04:00
Peter Boyle	a5ca40f446	Better verbose -- track CPU GPU motion under --log Memory, others go to debug output stream	2023-10-20 19:27:13 -04:00
Peter Boyle	9ab54c5565	Overlap comms & data copy/buffer assembly in Ghost zone exchange	2023-10-20 19:27:13 -04:00
Peter Boyle	4341d96bde	Massively sped up coarse grid mult, comms Save 3ms spend (60% of time !) on cudaMalloc !!	2023-10-20 19:27:13 -04:00
Peter Boyle	5fac47a26d	Faster halo exchange	2023-10-20 19:27:13 -04:00
Peter Boyle	e064f17346	Faster halo exchange	2023-10-20 19:27:13 -04:00
Peter Boyle	afe10ba2a2	More digits	2023-10-20 19:27:13 -04:00
Peter Boyle	7cc3435ba8	Imporved General coarsened matrix	2023-10-20 19:27:13 -04:00
Peter Boyle	541772313c	Verbosity	2023-10-20 19:27:13 -04:00
Peter Boyle	3747494a09	Notify delet public	2023-10-20 19:27:13 -04:00
Peter Boyle	f2b98d0dcc	Const safety	2023-10-20 19:27:13 -04:00
Peter Boyle	80471bf762	Alternate implementation involving face operations	2023-10-20 19:27:13 -04:00
Peter Boyle	a06f63c110	Improved I/O and non-lexico option exposed to SciDAC format	2023-10-20 19:27:13 -04:00
Peter Boyle	0ae4478cd9	Checkpoint the subspace and ldop	2023-10-20 19:27:13 -04:00
Peter Boyle	ae4e705e09	Use random vec as easier for debug	2023-10-20 19:27:13 -04:00
Peter Boyle	f5dcea9dbf	Updates for Frontier	2023-10-20 19:27:12 -04:00
Peter Boyle	2207309f8a	Spack rules	2023-10-16 18:38:24 -04:00
Peter Boyle	2111e7ab5f	Run at physical mass	2023-10-06 21:20:21 -04:00
Peter Boyle	d29abfdcaf	Transfer code to Frontier now	2023-10-06 21:03:34 -04:00
Peter Boyle	a751c42cc5	Checkpoint restore the setup	2023-10-06 21:03:08 -04:00
Peter Boyle	6a3bc9865e	Verbose change	2023-10-06 21:02:04 -04:00
Peter Boyle	4d5f7e4377	Verbose change	2023-10-06 21:01:37 -04:00
Peter Boyle	78b117fb78	Comment fix	2023-10-06 21:01:15 -04:00
Peter Boyle	ded63a1319	Verbose change/pretty print	2023-10-06 21:00:53 -04:00
Peter Boyle	df3e4d1e9c	Return fix	2023-10-06 21:00:21 -04:00
Peter Boyle	b58fd80379	I/O for coarse op and reorganise multigrid headers	2023-10-06 13:43:46 -04:00
Peter Boyle	7f6e0f57d0	No IO in file	2023-10-06 13:39:53 -04:00
Peter Boyle	cae27678d8	gpermute	2023-10-06 13:39:19 -04:00
Peter Boyle	48ff655bad	Slightly less verbose	2023-10-06 10:47:52 -04:00
Peter Boyle	2525ad4623	Slight clean up	2023-10-06 10:47:32 -04:00
Peter Boyle	e7020017c5	Reorganise multigrid	2023-10-06 10:47:12 -04:00
Peter Boyle	eacebfad74	Reorganise multigrid into multiple headers	2023-10-06 10:46:21 -04:00
Peter Boyle	3bc2da5321	Merge branch 'feature/scidac-wp1' of https://github.com/paboyle/Grid into feature/scidac-wp1	2023-10-05 16:57:59 -04:00
Peter Boyle	2d710d6bfd	Optimised parameters for 16^3	2023-10-05 16:56:55 -04:00
Peter Boyle	6532b7f32b	Eliminate older inefficient coarsening implementation	2023-10-05 16:56:15 -04:00
Peter Boyle	7b41b92d99	Only need to bad non-local dimensions	2023-10-05 16:55:48 -04:00
Peter Boyle	dd557af84b	ADEF1 and ADEF2 2 level CG	2023-10-05 16:55:19 -04:00
Peter Boyle	59b9d0e030	coalesceRead the blockSum	2023-10-05 16:54:48 -04:00
Peter Boyle	b82eee4733	Hermitian dealing with	2023-10-05 16:54:14 -04:00
Peter Boyle	6a87487544	Running on Frontier, fix RNG big volume y2k, affecting 5D RNG	2023-10-05 16:50:59 -04:00
Peter Boyle	fcf5023845	Running on Frontier	2023-10-05 16:50:59 -04:00
Peter Boyle	c8adad6d8b	First runs on Summit. PopulateAdag needs work	2023-10-05 16:50:54 -04:00
Peter Boyle	737d3ffb98	ADEF1 and 1 hop projection	2023-10-03 14:22:18 -04:00
Peter Boyle	b01e67bab1	coalescedReadGeneralPermute now working	2023-10-02 17:46:57 -04:00
Peter Boyle	8a70314f54	Merge branch 'develop' into feature/scidac-wp1	2023-10-02 17:24:55 -04:00
Peter Boyle	36ae6e5aba	Fastest GPU version. Need to work on the PaddedCell now to make much faster	2023-09-29 18:26:51 -04:00
Peter Boyle	9db585cfeb	Temporary commit while optimisation is carried out	2023-09-29 17:11:35 -04:00
Peter Boyle	c564611ba7	Annoying hack that is useful to preserve for profiling	2023-09-29 17:11:12 -04:00
Peter Boyle	e187bcb85c	Updating	2023-09-29 17:10:17 -04:00
Peter Boyle	be18ffe3b4	Further tuning and lanczos	2023-09-27 16:21:58 -04:00
Peter Boyle	0d63dce4e2	Timing info	2023-09-27 16:21:14 -04:00
Peter Boyle	26b30e1551	Flop count and projection to nearest neighbour (keeps redundant flops)	2023-09-27 16:20:11 -04:00
Peter Boyle	7fc58ac293	Verbose subspace init	2023-09-27 16:19:45 -04:00
Peter Boyle	3a86cce8c1	Compile	2023-09-27 16:19:18 -04:00
Peter Boyle	37884d369f	Coarse space is expensive, but gives a speed up in fine matrix multiplies now. Down to optimisation	2023-09-25 17:24:19 -04:00
Peter Boyle	9246e653cd	Basic non-local coarsening of operator test	2023-09-25 17:20:58 -04:00
Peter Boyle	64283c8673	Normal equations becomes linear function for easy base class pass aroudn	2023-09-25 17:19:39 -04:00
Peter Boyle	755002da9c	Comparison convenience	2023-09-25 17:16:33 -04:00
Peter Boyle	31b8e8b437	Better messaging	2023-09-25 17:16:14 -04:00
Peter Boyle	0ec0de97e6	Adef2 implemented and working in an HDCG like context	2023-09-25 17:15:03 -04:00
Peter Boyle	6c3ade5d89	Improved the coarsening	2023-09-25 17:14:40 -04:00
Peter Boyle	980c5f9a34	Update chebyshev setup	2023-09-25 17:12:22 -04:00
Peter Boyle	471ca5f281	Power method more iterations	2023-09-07 10:55:05 -04:00
Peter Boyle	e82ddcff5d	Working getting closer to HDCG but some low level engineering work still needed + MUCH work on optimisation	2023-09-07 10:53:51 -04:00
Peter Boyle	b9dcad89e8	Test cases for coarsening with non-local stencil	2023-09-07 10:53:22 -04:00
Peter Boyle	993f43ef4a	Even odd use case	2023-09-07 10:53:06 -04:00
Peter Boyle	2b43308208	First cut non-local coarsening	2023-08-25 17:38:07 -04:00
Peter Boyle	04a1ac3a76	First cut for non-local coarsening	2023-08-25 17:37:38 -04:00
Peter Boyle	990b8798bd	Merge remote-tracking branch 'refs/remotes/origin/develop' into develop	2023-08-25 17:36:45 -04:00
Peter Boyle	b334a73a44	Stencil improvement	2023-08-25 17:35:10 -04:00
Peter Boyle	5d113d1c70	Odd address sanitizer complain	2023-08-25 17:34:18 -04:00
Peter Boyle	c14977aeab	Random vector option for test purposes	2023-08-25 17:33:31 -04:00
Peter Boyle	3e94838204	Spread out improvement	2023-08-25 17:31:28 -04:00
Peter Boyle	c0a0b8ca62	NEON and address sanitiser	2023-08-25 17:30:30 -04:00
		`@@ -0,0 +1,2 @@`
							`module load oneapi/eng-compiler/2023.05.15.003`
							`module load mpich/51.2/icc-all-deterministic-pmix-gpu`
`@@ -1,3 +1,2 @@`
	`CXXFLAGS=-I/opt/local/include LDFLAGS=-L/opt/local/lib/ CXX=c++-13 MPICXX=mpicxx ../../configure --enable-simd=GEN --enable-comms=mpi-auto --enable-unified=yes --prefix $HOME/QCD/GridInstall --with-lime=/Users/peterboyle/QCD/SciDAC/install/ --with-openssl=$BREW --disable-fermion-reps --disable-gparity --disable-debug`	`CXXFLAGS=-I/opt/local/include LDFLAGS=-L/opt/local/lib/ CXX=c++-13 MPICXX=mpicxx ../../configure --enable-simd=GEN --enable-comms=mpi-auto --enable-unified=yes --prefix $HOME/QCD/GridInstall --with-lime=/Users/peterboyle/QCD/SciDAC/install/ --with-openssl=$BREW --disable-fermion-reps --disable-gparity --disable-debug`