Hack - may revert this in future

Gparity and fermion rep optional
Configure options for gparity and fermion reps
2025-10-24 17:54:47 +01:00 · 2020-11-19 05:58:39 -08:00 · 2020-11-19 05:58:08 -08:00 · 2020-11-19 05:57:42 -08:00 · 2020-11-19 05:57:04 -08:00 · 2020-11-19 05:56:32 -08:00
704 changed files with 24040 additions and 73779 deletions
--- a/.github/ISSUE_TEMPLATE/bug-report.yml
+++ b/.github/ISSUE_TEMPLATE/bug-report.yml
@@ -1,54 +0,0 @@
 name: Bug report
 description: Report a bug.
 title: "<insert title>"
 labels: [bug]
 body:
  - type: markdown
    attributes:
      value: >
        Thank you for taking the time to file a bug report.
        Please check that the code is pointing to the HEAD of develop
        or any commit in master which is tagged with a version number.
  - type: textarea
    attributes:
      label: "Describe the issue:"
      description: >
        Describe the issue and any previous attempt to solve it.
    validations:
      required: true
  - type: textarea
    attributes:
      label: "Code example:"
      description: >
        If relevant, show how to reproduce the issue using a minimal working
        example.
      placeholder: |
        << your code here >>
      render: shell
    validations:
      required: false
  - type: textarea
    attributes:
      label: "Target platform:"
      description: >
        Give a description of the target platform (CPU, network, compiler).
        Please give the full CPU part description, using for example
        `cat /proc/cpuinfo | grep 'model name' | uniq` (Linux)
        or `sysctl machdep.cpu.brand_string` (macOS) and the full output
        the `--version` option of your compiler.
    validations:
      required: true
  - type: textarea
    attributes:
      label: "Configure options:"
      description: >
        Please give the exact configure command used and attach
        `config.log`, `grid.config.summary` and the output of `make V=1`.
      render: shell
    validations:
      required: true
--- a/.gitignore
+++ b/.gitignore
@@ -1,7 +1,3 @@
 # Doxygen stuff
 html/*
 latex/*
 # Compiled Object files #
 #########################
 *.slo
@@ -92,7 +88,6 @@ Thumbs.db
 # build directory #
 ###################
 build*/*
 Documentation/_build
 # IDE related files #
 #####################
--- a/.travis.yml
+++ b/.travis.yml
@@ -0,0 +1,56 @@
 language: cpp
 cache:
  directories:
    - clang
 matrix:
  include:
    - os:        osx
      osx_image: xcode8.3
      compiler: clang
 before_install:
    - export GRIDDIR=`pwd`
    - if [[ "$TRAVIS_OS_NAME" == "linux" ]] && [[ "$CC" == "clang" ]] && [ ! -e clang/bin ]; then wget $CLANG_LINK; tar -xf `basename $CLANG_LINK`; mkdir clang; mv clang+*/* clang/; fi
    - if [[ "$TRAVIS_OS_NAME" == "linux" ]] && [[ "$CC" == "clang" ]]; then export PATH="${GRIDDIR}/clang/bin:${PATH}"; fi
    - if [[ "$TRAVIS_OS_NAME" == "linux" ]] && [[ "$CC" == "clang" ]]; then export LD_LIBRARY_PATH="${GRIDDIR}/clang/lib:${LD_LIBRARY_PATH}"; fi
    - if [[ "$TRAVIS_OS_NAME" == "osx" ]]; then brew update; fi
    - if [[ "$TRAVIS_OS_NAME" == "osx" ]]; then brew install libmpc openssl; fi
 install:
    - export CWD=`pwd`
    - echo $CWD
    - export CC=$CC$VERSION
    - export CXX=$CXX$VERSION
    - echo $PATH
    - which autoconf
    - autoconf  --version
    - which automake
    - automake  --version
    - which $CC
    - $CC  --version
    - which $CXX
    - $CXX --version
    - if [[ "$TRAVIS_OS_NAME" == "osx" ]]; then export LDFLAGS='-L/usr/local/lib'; fi
    - if [[ "$TRAVIS_OS_NAME" == "osx" ]]; then export EXTRACONF='--with-openssl=/usr/local/opt/openssl'; fi
 script:
    - ./bootstrap.sh
    - mkdir build
    - cd build
    - mkdir lime
    - cd lime
    - mkdir build
    - cd build
    - wget http://usqcd-software.github.io/downloads/c-lime/lime-1.3.2.tar.gz
    - tar xf lime-1.3.2.tar.gz
    - cd lime-1.3.2
    - ./configure --prefix=$CWD/build/lime/install
    - make -j4
    - make install
    - cd $CWD/build
    - ../configure --enable-simd=SSE4 --enable-comms=none --with-lime=$CWD/build/lime/install ${EXTRACONF}
    - make -j4 
    - ./benchmarks/Benchmark_dwf --threads 1 --debug-signals
    - make check
--- a/Grid/DisableWarnings.h
+++ b/Grid/DisableWarnings.h
@@ -37,29 +37,19 @@ directory
 #endif
 //disables and intel compiler specific warning (in json.hpp)
 #ifdef __ICC
 #pragma warning disable 488  
 #endif
 #ifdef __NVCC__
 //disables nvcc specific warning in json.hpp
 #pragma clang diagnostic ignored "-Wdeprecated-register"
 #ifdef __NVCC_DIAG_PRAGMA_SUPPORT__
 //disables nvcc specific warning in json.hpp
 #pragma nv_diag_suppress unsigned_compare_with_zero
 #pragma nv_diag_suppress cast_to_qualified_type
 //disables nvcc specific warning in many files
 #pragma nv_diag_suppress esa_on_defaulted_function_ignored
 #pragma nv_diag_suppress extra_semicolon
 #else
 //disables nvcc specific warning in json.hpp
 #pragma diag_suppress unsigned_compare_with_zero
 #pragma diag_suppress cast_to_qualified_type
 //disables nvcc specific warning in many files
 #pragma diag_suppress esa_on_defaulted_function_ignored
 #pragma diag_suppress extra_semicolon
-#endif
+
 //Eigen only
 #endif
 // Disable vectorisation in Eigen on the Power8/9 and PowerPC
--- a/Grid/GridCore.h
+++ b/Grid/GridCore.h
@@ -44,10 +44,9 @@ Author: paboyle <paboyle@ph.ed.ac.uk>
 #include <Grid/GridStd.h>
 #include <Grid/threads/Pragmas.h>
 #include <Grid/perfmon/Timer.h>
-//#include <Grid/perfmon/PerfCount.h>
+#include <Grid/perfmon/PerfCount.h>
 #include <Grid/util/Util.h>
 #include <Grid/log/Log.h>
 #include <Grid/perfmon/Tracing.h>
 #include <Grid/allocator/Allocator.h>
 #include <Grid/simd/Simd.h>
 #include <Grid/threads/ThreadReduction.h>
--- a/Grid/GridQCDcore.h
+++ b/Grid/GridQCDcore.h
@@ -36,7 +36,6 @@ Author: paboyle <paboyle@ph.ed.ac.uk>
 #include <Grid/GridCore.h>
 #include <Grid/qcd/QCD.h>
 #include <Grid/qcd/spin/Spin.h>
 #include <Grid/qcd/gparity/Gparity.h>
 #include <Grid/qcd/utils/Utils.h>
 #include <Grid/qcd/representations/Representations.h>
 NAMESPACE_CHECK(GridQCDCore);
--- a/Grid/GridStd.h
+++ b/Grid/GridStd.h
@@ -16,7 +16,6 @@
 #include <functional>
 #include <stdio.h>
 #include <stdlib.h>
 #include <strings.h>
 #include <stdio.h>
 #include <signal.h>
 #include <ctime>
--- a/Grid/Grid_Eigen_Dense.h
+++ b/Grid/Grid_Eigen_Dense.h
@@ -14,11 +14,7 @@
 /* NVCC save and restore compile environment*/
 #ifdef __NVCC__
 #pragma push
 #ifdef __NVCC_DIAG_PRAGMA_SUPPORT__
 #pragma nv_diag_suppress code_is_unreachable
 #else
 #pragma diag_suppress code_is_unreachable
 #endif
 #pragma push_macro("__CUDA_ARCH__")
 #pragma push_macro("__NVCC__")
 #pragma push_macro("__CUDACC__")
@@ -34,7 +30,7 @@
 #pragma push_macro("__SYCL_DEVICE_ONLY__")
 #undef __SYCL_DEVICE_ONLY__
 #define EIGEN_DONT_VECTORIZE
-#undef EIGEN_USE_SYCL
+//#undef EIGEN_USE_SYCL
 #define __SYCL__REDEFINE__
 #endif
--- a/Grid/Makefile.am
+++ b/Grid/Makefile.am
@@ -54,11 +54,9 @@ Version.h: version-cache
 include Make.inc
 include Eigen.inc
 extra_sources+=$(ZWILS_FERMION_FILES)
 extra_sources+=$(WILS_FERMION_FILES)
 extra_sources+=$(STAG_FERMION_FILES)
 if BUILD_ZMOBIUS
  extra_sources+=$(ZWILS_FERMION_FILES)
 endif
 if BUILD_GPARITY
  extra_sources+=$(GP_FERMION_FILES)
 endif
@@ -66,10 +64,6 @@ if BUILD_FERMION_REPS
  extra_sources+=$(ADJ_FERMION_FILES)
  extra_sources+=$(TWOIND_FERMION_FILES)
 endif
 if BUILD_SP
    extra_sources+=$(SP_FERMION_FILES)
    extra_sources+=$(SP_TWOIND_FERMION_FILES)
 endif
 lib_LIBRARIES = libGrid.a
--- a/Grid/algorithms/Algorithms.h
+++ b/Grid/algorithms/Algorithms.h
@@ -54,8 +54,6 @@ NAMESPACE_CHECK(BiCGSTAB);
 #include <Grid/algorithms/iterative/SchurRedBlack.h>
 #include <Grid/algorithms/iterative/ConjugateGradientMultiShift.h>
 #include <Grid/algorithms/iterative/ConjugateGradientMixedPrec.h>
 #include <Grid/algorithms/iterative/ConjugateGradientMultiShiftMixedPrec.h>
 #include <Grid/algorithms/iterative/ConjugateGradientMixedPrecBatched.h>
 #include <Grid/algorithms/iterative/BiCGSTABMixedPrec.h>
 #include <Grid/algorithms/iterative/BlockConjugateGradient.h>
 #include <Grid/algorithms/iterative/ConjugateGradientReliableUpdate.h>
--- a/Grid/algorithms/CoarsenedMatrix.h
+++ b/Grid/algorithms/CoarsenedMatrix.h
@@ -31,7 +31,6 @@ Author: paboyle <paboyle@ph.ed.ac.uk>
 #ifndef  GRID_ALGORITHM_COARSENED_MATRIX_H
 #define  GRID_ALGORITHM_COARSENED_MATRIX_H
 #include <Grid/qcd/QCD.h> // needed for Dagger(Yes|No), Inverse(Yes|No)
 NAMESPACE_BEGIN(Grid);
@@ -60,14 +59,12 @@ inline void blockMaskedInnerProduct(Lattice<CComplex> &CoarseInner,
 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;
+    int base = (_d==5) ? 1:0;
    // make coarse grid stencil for 4d , not 5d
    if ( _d==5 ) _d=4;
@@ -75,51 +72,16 @@ public:
    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>
@@ -262,7 +224,7 @@ public:
 	autoView( Tnp_v , (*Tnp), AcceleratorWrite);
 	autoView( Tnm_v , (*Tnm), AcceleratorWrite);
 	const int Nsimd = CComplex::Nsimd();
-	accelerator_for(ss, FineGrid->oSites(), Nsimd, {
+	accelerator_forNB(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));
        });
@@ -296,7 +258,7 @@ public:
 // Fine Object == (per site) type of fine field
 // nbasis      == number of deflation vectors
 template<class Fobj,class CComplex,int nbasis>
-class CoarsenedMatrix : public CheckerBoardedSparseMatrixBase<Lattice<iVector<CComplex,nbasis > > >  {
+class CoarsenedMatrix : public SparseMatrixBase<Lattice<iVector<CComplex,nbasis > > >  {
 public:
  typedef iVector<CComplex,nbasis >           siteVector;
@@ -306,59 +268,33 @@ public:
  typedef iMatrix<CComplex,nbasis >  Cobj;
  typedef Lattice< CComplex >   CoarseScalar; // used for inner products on fine field
  typedef Lattice<Fobj >        FineField;
  typedef CoarseVector FermionField;
  // enrich interface, use default implementation as in FermionOperator ///////
  void Dminus(CoarseVector const& in, CoarseVector& out) { out = in; }
  void DminusDag(CoarseVector const& in, CoarseVector& out) { out = in; }
  void ImportPhysicalFermionSource(CoarseVector const& input, CoarseVector& imported) { imported = input; }
  void ImportUnphysicalFermion(CoarseVector const& input, CoarseVector& imported) { imported = input; }
  void ExportPhysicalFermionSolution(CoarseVector const& solution, CoarseVector& exported) { exported = solution; };
  void ExportPhysicalFermionSource(CoarseVector const& solution, CoarseVector& exported) { exported = solution; };
  ////////////////////
  // Data members
  ////////////////////
  Geometry         geom;
  GridBase *       _grid; 
  GridBase*        _cbgrid;
  int hermitian;
-  CartesianStencil<siteVector,siteVector,DefaultImplParams> Stencil; 
+  CartesianStencil<siteVector,siteVector,int> Stencil; 
  CartesianStencil<siteVector,siteVector,DefaultImplParams> StencilEven;
  CartesianStencil<siteVector,siteVector,DefaultImplParams> StencilOdd;
  std::vector<CoarseMatrix> A;
-  std::vector<CoarseMatrix> Aeven;
+    
  std::vector<CoarseMatrix> Aodd;
  CoarseMatrix AselfInv;
  CoarseMatrix AselfInvEven;
  CoarseMatrix AselfInvOdd;
  Vector<RealD> dag_factor;
  ///////////////////////
  // Interface
  ///////////////////////
  GridBase * Grid(void)         { return _grid; };   // this is all the linalg routines need to know
  GridBase * RedBlackGrid()     { return _cbgrid; };
  int ConstEE() { return 0; }
  void M (const CoarseVector &in, CoarseVector &out)
  {
    conformable(_grid,in.Grid());
    conformable(in.Grid(),out.Grid());
    out.Checkerboard() = in.Checkerboard();
    SimpleCompressor<siteVector> compressor;
    Stencil.HaloExchange(in,compressor);
    autoView( in_v , in, AcceleratorRead);
    autoView( out_v , out, AcceleratorWrite);
    autoView( Stencil_v  , Stencil, AcceleratorRead);
    int npoint = geom.npoint;
    typedef LatticeView<Cobj> Aview;
    Vector<Aview> AcceleratorViewContainer;
@@ -380,14 +316,14 @@ public:
      int ptype;
      StencilEntry *SE;
-      for(int point=0;point<npoint;point++){
+      for(int point=0;point<geom.npoint;point++){
-	SE=Stencil_v.GetEntry(ptype,point,ss);
+	SE=Stencil.GetEntry(ptype,point,ss);
 	if(SE->_is_local) { 
 	  nbr = coalescedReadPermute(in_v[SE->_offset],ptype,SE->_permute);
 	} else {
-	  nbr = coalescedRead(Stencil_v.CommBuf()[SE->_offset]);
+	  nbr = coalescedRead(Stencil.CommBuf()[SE->_offset]);
 	}
 	acceleratorSynchronise();
@@ -408,74 +344,12 @@ public:
      return M(in,out);
    } else {
      // corresponds to Galerkin coarsening
-      return MdagNonHermitian(in, out);
+      CoarseVector tmp(Grid());
      G5C(tmp, in); 
      M(tmp, out);
      G5C(out, out);
    }
  };
  void MdagNonHermitian(const CoarseVector &in, CoarseVector &out)
  {
    conformable(_grid,in.Grid());
    conformable(in.Grid(),out.Grid());
    out.Checkerboard() = in.Checkerboard();
    SimpleCompressor<siteVector> compressor;
    Stencil.HaloExchange(in,compressor);
    autoView( in_v , in, AcceleratorRead);
    autoView( out_v , out, AcceleratorWrite);
    autoView( Stencil_v  , Stencil, AcceleratorRead);
    int npoint = geom.npoint;
    typedef LatticeView<Cobj> Aview;
    Vector<Aview> AcceleratorViewContainer;
    for(int p=0;p<geom.npoint;p++) AcceleratorViewContainer.push_back(A[p].View(AcceleratorRead));
    Aview *Aview_p = & AcceleratorViewContainer[0];
    const int Nsimd = CComplex::Nsimd();
    typedef decltype(coalescedRead(in_v[0])) calcVector;
    typedef decltype(coalescedRead(in_v[0](0))) calcComplex;
    int osites=Grid()->oSites();
    Vector<int> points(geom.npoint, 0);
    for(int p=0; p<geom.npoint; p++)
      points[p] = geom.points_dagger[p];
    auto points_p = &points[0];
    RealD* dag_factor_p = &dag_factor[0];
    accelerator_for(sss, Grid()->oSites()*nbasis, Nsimd, {
      int ss = sss/nbasis;
      int b  = sss%nbasis;
      calcComplex res = Zero();
      calcVector nbr;
      int ptype;
      StencilEntry *SE;
      for(int p=0;p<npoint;p++){
        int point = points_p[p];
 	SE=Stencil_v.GetEntry(ptype,point,ss);
 	if(SE->_is_local) {
 	  nbr = coalescedReadPermute(in_v[SE->_offset],ptype,SE->_permute);
 	} else {
 	  nbr = coalescedRead(Stencil_v.CommBuf()[SE->_offset]);
 	}
 	acceleratorSynchronise();
 	for(int bb=0;bb<nbasis;bb++) {
 	  res = res + dag_factor_p[b*nbasis+bb]*coalescedRead(Aview_p[point][ss](b,bb))*nbr(bb);
 	}
      }
      coalescedWrite(out_v[ss](b),res);
      });
    for(int p=0;p<geom.npoint;p++) AcceleratorViewContainer[p].ViewClose();
  }
  void MdirComms(const CoarseVector &in)
  {
    SimpleCompressor<siteVector> compressor;
@@ -485,7 +359,6 @@ public:
  {
    conformable(_grid,in.Grid());
    conformable(_grid,out.Grid());
    out.Checkerboard() = in.Checkerboard();
    typedef LatticeView<Cobj> Aview;
    Vector<Aview> AcceleratorViewContainer;
@@ -494,7 +367,6 @@ public:
    autoView( out_v , out, AcceleratorWrite);
    autoView( in_v  , in, AcceleratorRead);
    autoView( Stencil_v  , Stencil, AcceleratorRead);
    const int Nsimd = CComplex::Nsimd();
    typedef decltype(coalescedRead(in_v[0])) calcVector;
@@ -508,12 +380,12 @@ public:
      int ptype;
      StencilEntry *SE;
-      SE=Stencil_v.GetEntry(ptype,point,ss);
+      SE=Stencil.GetEntry(ptype,point,ss);
      if(SE->_is_local) { 
 	nbr = coalescedReadPermute(in_v[SE->_offset],ptype,SE->_permute);
      } else {
-	nbr = coalescedRead(Stencil_v.CommBuf()[SE->_offset]);
+	nbr = coalescedRead(Stencil.CommBuf()[SE->_offset]);
      }
      acceleratorSynchronise();
@@ -541,7 +413,34 @@ public:
    this->MdirComms(in);
-    MdirCalc(in,out,geom.point(dir,disp));
+    int ndim = in.Grid()->Nd();
    //////////////
    // 4D action like wilson
    // 0+ => 0 
    // 0- => 1
    // 1+ => 2 
    // 1- => 3
    // etc..
    //////////////
    // 5D action like DWF
    // 1+ => 0 
    // 1- => 1
    // 2+ => 2 
    // 2- => 3
    // etc..
    auto point = [dir, disp, ndim](){
      if(dir == 0 and disp == 0)
 	return 8;
      else if ( ndim==4 ) { 
 	return (4 * dir + 1 - disp) / 2;
      } else { 
 	return (4 * (dir-1) + 1 - disp) / 2;
      }
    }();
    MdirCalc(in,out,point);
  };
  void Mdiag(const CoarseVector &in, CoarseVector &out)
@@ -550,298 +449,23 @@ public:
    MdirCalc(in, out, point); // No comms
  };
  void Mooee(const CoarseVector &in, CoarseVector &out) {
    MooeeInternal(in, out, DaggerNo, InverseNo);
  }
  void MooeeInv(const CoarseVector &in, CoarseVector &out) {
    MooeeInternal(in, out, DaggerNo, InverseYes);
  }
  void MooeeDag(const CoarseVector &in, CoarseVector &out) {
    MooeeInternal(in, out, DaggerYes, InverseNo);
  }
  void MooeeInvDag(const CoarseVector &in, CoarseVector &out) {
    MooeeInternal(in, out, DaggerYes, InverseYes);
  }
  void Meooe(const CoarseVector &in, CoarseVector &out) {
    if(in.Checkerboard() == Odd) {
      DhopEO(in, out, DaggerNo);
    } else {
      DhopOE(in, out, DaggerNo);
    }
  }
  void MeooeDag(const CoarseVector &in, CoarseVector &out) {
    if(in.Checkerboard() == Odd) {
      DhopEO(in, out, DaggerYes);
    } else {
      DhopOE(in, out, DaggerYes);
    }
  }
  void Dhop(const CoarseVector &in, CoarseVector &out, int dag) {
    conformable(in.Grid(), _grid); // verifies full grid
    conformable(in.Grid(), out.Grid());
    out.Checkerboard() = in.Checkerboard();
    DhopInternal(Stencil, A, in, out, dag);
  }
  void DhopOE(const CoarseVector &in, CoarseVector &out, int dag) {
    conformable(in.Grid(), _cbgrid);    // verifies half grid
    conformable(in.Grid(), out.Grid()); // drops the cb check
    assert(in.Checkerboard() == Even);
    out.Checkerboard() = Odd;
    DhopInternal(StencilEven, Aodd, in, out, dag);
  }
  void DhopEO(const CoarseVector &in, CoarseVector &out, int dag) {
    conformable(in.Grid(), _cbgrid);    // verifies half grid
    conformable(in.Grid(), out.Grid()); // drops the cb check
    assert(in.Checkerboard() == Odd);
    out.Checkerboard() = Even;
    DhopInternal(StencilOdd, Aeven, in, out, dag);
  }
  void MooeeInternal(const CoarseVector &in, CoarseVector &out, int dag, int inv) {
    out.Checkerboard() = in.Checkerboard();
    assert(in.Checkerboard() == Odd || in.Checkerboard() == Even);
    CoarseMatrix *Aself = nullptr;
    if(in.Grid()->_isCheckerBoarded) {
      if(in.Checkerboard() == Odd) {
        Aself = (inv) ? &AselfInvOdd : &Aodd[geom.npoint-1];
        DselfInternal(StencilOdd, *Aself, in, out, dag);
      } else {
        Aself = (inv) ? &AselfInvEven : &Aeven[geom.npoint-1];
        DselfInternal(StencilEven, *Aself, in, out, dag);
      }
    } else {
      Aself = (inv) ? &AselfInv : &A[geom.npoint-1];
      DselfInternal(Stencil, *Aself, in, out, dag);
    }
    assert(Aself != nullptr);
  }
  void DselfInternal(CartesianStencil<siteVector,siteVector,DefaultImplParams> &st, CoarseMatrix &a,
                       const CoarseVector &in, CoarseVector &out, int dag) {
    int point = geom.npoint-1;
    autoView( out_v, out, AcceleratorWrite);
    autoView( in_v,  in,  AcceleratorRead);
    autoView( st_v,  st,  AcceleratorRead);
    autoView( a_v,   a,   AcceleratorRead);
    const int Nsimd = CComplex::Nsimd();
    typedef decltype(coalescedRead(in_v[0])) calcVector;
    typedef decltype(coalescedRead(in_v[0](0))) calcComplex;
    RealD* dag_factor_p = &dag_factor[0];
    if(dag) {
      accelerator_for(sss, in.Grid()->oSites()*nbasis, Nsimd, {
        int ss = sss/nbasis;
        int b  = sss%nbasis;
        calcComplex res = Zero();
        calcVector nbr;
        int ptype;
        StencilEntry *SE;
        SE=st_v.GetEntry(ptype,point,ss);
        if(SE->_is_local) {
          nbr = coalescedReadPermute(in_v[SE->_offset],ptype,SE->_permute);
        } else {
          nbr = coalescedRead(st_v.CommBuf()[SE->_offset]);
        }
        acceleratorSynchronise();
        for(int bb=0;bb<nbasis;bb++) {
          res = res + dag_factor_p[b*nbasis+bb]*coalescedRead(a_v[ss](b,bb))*nbr(bb);
        }
        coalescedWrite(out_v[ss](b),res);
      });
    } else {
      accelerator_for(sss, in.Grid()->oSites()*nbasis, Nsimd, {
        int ss = sss/nbasis;
        int b  = sss%nbasis;
        calcComplex res = Zero();
        calcVector nbr;
        int ptype;
        StencilEntry *SE;
        SE=st_v.GetEntry(ptype,point,ss);
        if(SE->_is_local) {
          nbr = coalescedReadPermute(in_v[SE->_offset],ptype,SE->_permute);
        } else {
          nbr = coalescedRead(st_v.CommBuf()[SE->_offset]);
        }
        acceleratorSynchronise();
        for(int bb=0;bb<nbasis;bb++) {
          res = res + coalescedRead(a_v[ss](b,bb))*nbr(bb);
        }
        coalescedWrite(out_v[ss](b),res);
      });
    }
  }
  void DhopInternal(CartesianStencil<siteVector,siteVector,DefaultImplParams> &st, std::vector<CoarseMatrix> &a,
                    const CoarseVector &in, CoarseVector &out, int dag) {
    SimpleCompressor<siteVector> compressor;
    st.HaloExchange(in,compressor);
    autoView( in_v,  in,  AcceleratorRead);
    autoView( out_v, out, AcceleratorWrite);
    autoView( st_v , st,  AcceleratorRead);
    typedef LatticeView<Cobj> Aview;
    // determine in what order we need the points
    int npoint = geom.npoint-1;
    Vector<int> points(npoint, 0);
    for(int p=0; p<npoint; p++)
      points[p] = (dag && !hermitian) ? geom.points_dagger[p] : p;
    auto points_p = &points[0];
    Vector<Aview> AcceleratorViewContainer;
    for(int p=0;p<npoint;p++) AcceleratorViewContainer.push_back(a[p].View(AcceleratorRead));
    Aview *Aview_p = & AcceleratorViewContainer[0];
    const int Nsimd = CComplex::Nsimd();
    typedef decltype(coalescedRead(in_v[0])) calcVector;
    typedef decltype(coalescedRead(in_v[0](0))) calcComplex;
    RealD* dag_factor_p = &dag_factor[0];
    if(dag) {
      accelerator_for(sss, in.Grid()->oSites()*nbasis, Nsimd, {
        int ss = sss/nbasis;
        int b  = sss%nbasis;
        calcComplex res = Zero();
        calcVector nbr;
        int ptype;
        StencilEntry *SE;
        for(int p=0;p<npoint;p++){
          int point = points_p[p];
          SE=st_v.GetEntry(ptype,point,ss);
          if(SE->_is_local) {
            nbr = coalescedReadPermute(in_v[SE->_offset],ptype,SE->_permute);
          } else {
            nbr = coalescedRead(st_v.CommBuf()[SE->_offset]);
          }
          acceleratorSynchronise();
          for(int bb=0;bb<nbasis;bb++) {
            res = res + dag_factor_p[b*nbasis+bb]*coalescedRead(Aview_p[point][ss](b,bb))*nbr(bb);
          }
        }
        coalescedWrite(out_v[ss](b),res);
      });
    } else {
      accelerator_for(sss, in.Grid()->oSites()*nbasis, Nsimd, {
        int ss = sss/nbasis;
        int b  = sss%nbasis;
        calcComplex res = Zero();
        calcVector nbr;
        int ptype;
        StencilEntry *SE;
        for(int p=0;p<npoint;p++){
          int point = points_p[p];
          SE=st_v.GetEntry(ptype,point,ss);
          if(SE->_is_local) {
            nbr = coalescedReadPermute(in_v[SE->_offset],ptype,SE->_permute);
          } else {
            nbr = coalescedRead(st_v.CommBuf()[SE->_offset]);
          }
          acceleratorSynchronise();
          for(int bb=0;bb<nbasis;bb++) {
            res = res + coalescedRead(Aview_p[point][ss](b,bb))*nbr(bb);
          }
        }
        coalescedWrite(out_v[ss](b),res);
      });
    }
    for(int p=0;p<npoint;p++) AcceleratorViewContainer[p].ViewClose();
  }
-  CoarsenedMatrix(GridCartesian &CoarseGrid, int hermitian_=0) 	:
+ CoarsenedMatrix(GridCartesian &CoarseGrid, int hermitian_=0) 	: 
    _grid(&CoarseGrid),
    _cbgrid(new GridRedBlackCartesian(&CoarseGrid)),
    geom(CoarseGrid._ndimension),
    hermitian(hermitian_),
    Stencil(&CoarseGrid,geom.npoint,Even,geom.directions,geom.displacements),
    StencilEven(_cbgrid,geom.npoint,Even,geom.directions,geom.displacements),
    StencilOdd(_cbgrid,geom.npoint,Odd,geom.directions,geom.displacements),
    A(geom.npoint,&CoarseGrid),
    Aeven(geom.npoint,_cbgrid),
    Aodd(geom.npoint,_cbgrid),
    AselfInv(&CoarseGrid),
    AselfInvEven(_cbgrid),
    AselfInvOdd(_cbgrid),
    dag_factor(nbasis*nbasis)
  {
    fillFactor();
  };
  CoarsenedMatrix(GridCartesian &CoarseGrid, GridRedBlackCartesian &CoarseRBGrid, int hermitian_=0) 	:
    _grid(&CoarseGrid),
    _cbgrid(&CoarseRBGrid),
    geom(CoarseGrid._ndimension),
    hermitian(hermitian_),
-    Stencil(&CoarseGrid,geom.npoint,Even,geom.directions,geom.displacements),
+    Stencil(&CoarseGrid,geom.npoint,Even,geom.directions,geom.displacements,0),
-    StencilEven(&CoarseRBGrid,geom.npoint,Even,geom.directions,geom.displacements),
+      A(geom.npoint,&CoarseGrid)
    StencilOdd(&CoarseRBGrid,geom.npoint,Odd,geom.directions,geom.displacements),
    A(geom.npoint,&CoarseGrid),
    Aeven(geom.npoint,&CoarseRBGrid),
    Aodd(geom.npoint,&CoarseRBGrid),
    AselfInv(&CoarseGrid),
    AselfInvEven(&CoarseRBGrid),
    AselfInvOdd(&CoarseRBGrid),
    dag_factor(nbasis*nbasis)
  {
    fillFactor();
  };
  void fillFactor() {
    Eigen::MatrixXd dag_factor_eigen = Eigen::MatrixXd::Ones(nbasis, nbasis);
    if(!hermitian) {
      const int nb = nbasis/2;
      dag_factor_eigen.block(0,nb,nb,nb) *= -1.0;
      dag_factor_eigen.block(nb,0,nb,nb) *= -1.0;
    }
    // GPU readable prefactor
    thread_for(i, nbasis*nbasis, {
      int j = i/nbasis;
      int k = i%nbasis;
      dag_factor[i] = dag_factor_eigen(j, k);
    });
  }
  void CoarsenOperator(GridBase *FineGrid,LinearOperatorBase<Lattice<Fobj> > &linop,
 		       Aggregation<Fobj,CComplex,nbasis> & Subspace)
  {
    typedef Lattice<typename Fobj::tensor_reduced> FineComplexField;
    typedef typename Fobj::scalar_type scalar_type;
    std::cout << GridLogMessage<< "CoarsenMatrix "<< std::endl;
    FineComplexField one(FineGrid); one=scalar_type(1.0,0.0);
    FineComplexField zero(FineGrid); zero=scalar_type(0.0,0.0);
@@ -872,13 +496,11 @@ public:
    CoarseScalar InnerProd(Grid()); 
    std::cout << GridLogMessage<< "CoarsenMatrix Orthog "<< std::endl;
    // Orthogonalise the subblocks over the basis
    blockOrthogonalise(InnerProd,Subspace.subspace);
    // Compute the matrix elements of linop between this orthonormal
    // set of vectors.
    std::cout << GridLogMessage<< "CoarsenMatrix masks "<< std::endl;
    int self_stencil=-1;
    for(int p=0;p<geom.npoint;p++)
    { 
@@ -917,7 +539,7 @@ public:
      phi=Subspace.subspace[i];
-      std::cout << GridLogMessage<< "CoarsenMatrix vector "<<i << std::endl;
+      //      std::cout << GridLogMessage<< "CoarsenMatrix vector "<<i << std::endl;
      linop.OpDirAll(phi,Mphi_p);
      linop.OpDiag  (phi,Mphi_p[geom.npoint-1]);
@@ -946,18 +568,6 @@ public:
 	    autoView( A_self  , A[self_stencil], AcceleratorWrite);
 	    accelerator_for(ss, Grid()->oSites(), Fobj::Nsimd(),{ coalescedWrite(A_p[ss](j,i),oZProj_v(ss)); });
 	    if ( hermitian && (disp==-1) ) {
 	      for(int pp=0;pp<geom.npoint;pp++){// Find the opposite link and set <j|A|i> = <i|A|j>*
 		int dirp   = geom.directions[pp];
 		int dispp  = geom.displacements[pp];
 		if ( (dirp==dir) && (dispp==1) ){
 		  auto sft = conjugate(Cshift(oZProj,dir,1));
 		  autoView( sft_v    ,  sft  , AcceleratorWrite);
 		  autoView( A_pp     ,  A[pp], AcceleratorWrite);
 		  accelerator_for(ss, Grid()->oSites(), Fobj::Nsimd(),{ coalescedWrite(A_pp[ss](i,j),sft_v(ss)); });
 		}
 	      }
 	    }
 	  }
 	}
@@ -996,54 +606,28 @@ public:
    }
    if(hermitian) {
      std::cout << GridLogMessage << " ForceHermitian, new code "<<std::endl;
      ForceHermitian();
    }
    InvertSelfStencilLink(); std::cout << GridLogMessage << "Coarse self link inverted" << std::endl;
    FillHalfCbs(); std::cout << GridLogMessage << "Coarse half checkerboards filled" << std::endl;
  }
-  void InvertSelfStencilLink() {
+  void ForceHermitian(void) {
-    std::cout << GridLogDebug << "CoarsenedMatrix::InvertSelfStencilLink" << std::endl;
+    CoarseMatrix Diff  (Grid());
-    int localVolume = Grid()->lSites();
+    for(int p=0;p<geom.npoint;p++){
-
+      int dir   = geom.directions[p];
-    typedef typename Cobj::scalar_object scalar_object;
+      int disp  = geom.displacements[p];
-
+      if(disp==-1) {
-    autoView(Aself_v,    A[geom.npoint-1], CpuRead);
+	// Find the opposite link
-    autoView(AselfInv_v, AselfInv,         CpuWrite);
+	for(int pp=0;pp<geom.npoint;pp++){
-    thread_for(site, localVolume, { // NOTE: Not able to bring this to GPU because of Eigen + peek/poke
+	  int dirp   = geom.directions[pp];
-      Eigen::MatrixXcd selfLinkEigen    = Eigen::MatrixXcd::Zero(nbasis, nbasis);
+	  int dispp  = geom.displacements[pp];
-      Eigen::MatrixXcd selfLinkInvEigen = Eigen::MatrixXcd::Zero(nbasis, nbasis);
+	  if ( (dirp==dir) && (dispp==1) ){
-
+	    //	    Diff = adj(Cshift(A[p],dir,1)) - A[pp]; 
-      scalar_object selfLink    = Zero();
+	    //	    std::cout << GridLogMessage<<" Replacing stencil leg "<<pp<<" with leg "<<p<< " diff "<<norm2(Diff) <<std::endl;
-      scalar_object selfLinkInv = Zero();
+	    A[pp] = adj(Cshift(A[p],dir,1));
-
+	  }
-      Coordinate lcoor;
+	}
-
+      }
      Grid()->LocalIndexToLocalCoor(site, lcoor);
      peekLocalSite(selfLink, Aself_v, lcoor);
      for (int i = 0; i < nbasis; ++i)
        for (int j = 0; j < nbasis; ++j)
          selfLinkEigen(i, j) = static_cast<ComplexD>(TensorRemove(selfLink(i, j)));
      selfLinkInvEigen = selfLinkEigen.inverse();
      for(int i = 0; i < nbasis; ++i)
        for(int j = 0; j < nbasis; ++j)
          selfLinkInv(i, j) = selfLinkInvEigen(i, j);
      pokeLocalSite(selfLinkInv, AselfInv_v, lcoor);
    });
  }
  void FillHalfCbs() {
    std::cout << GridLogDebug << "CoarsenedMatrix::FillHalfCbs" << std::endl;
    for(int p = 0; p < geom.npoint; ++p) {
      pickCheckerboard(Even, Aeven[p], A[p]);
      pickCheckerboard(Odd, Aodd[p], A[p]);
    }
    pickCheckerboard(Even, AselfInvEven, AselfInv);
    pickCheckerboard(Odd, AselfInvOdd, AselfInv);
  }
 };
--- 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
-#if defined(USE_MKL) || defined(GRID_SYCL)
+#ifdef USE_MKL
 #include <fftw/fftw3.h>
 #else
 #include <fftw3.h>
@@ -136,7 +136,7 @@ public:
    flops=0;
    usec =0;
    Coordinate layout(Nd,1);
-    sgrid = new GridCartesian(dimensions,layout,processors,*grid);
+    sgrid = new GridCartesian(dimensions,layout,processors);
  };
  ~FFT ( void)  {
@@ -182,7 +182,7 @@ public:
    pencil_gd[dim] = G*processors[dim];
    // Pencil global vol LxLxGxLxL per node
-    GridCartesian pencil_g(pencil_gd,layout,processors,*vgrid);
+    GridCartesian pencil_g(pencil_gd,layout,processors);
    // Construct pencils
    typedef typename vobj::scalar_object sobj;
--- a/Grid/algorithms/LinearOperator.h
+++ b/Grid/algorithms/LinearOperator.h
@@ -52,7 +52,6 @@ public:
  virtual void AdjOp  (const Field &in, Field &out) = 0; // Abstract base
  virtual void HermOpAndNorm(const Field &in, Field &out,RealD &n1,RealD &n2)=0;
  virtual void HermOp(const Field &in, Field &out)=0;
  virtual ~LinearOperatorBase(){};
 };
@@ -508,7 +507,7 @@ class SchurStaggeredOperator :  public SchurOperatorBase<Field> {
  virtual  void MpcDag   (const Field &in, Field &out){
    Mpc(in,out);
  }
-  virtual void MpcDagMpc(const Field &in, Field &out) {
+  virtual void MpcDagMpc(const Field &in, Field &out,RealD &ni,RealD &no) {
    assert(0);// Never need with staggered
  }
 };
@@ -526,23 +525,11 @@ public:
      (*this)(Linop,in[k],out[k]);
    }
  };
  virtual ~OperatorFunction(){};
 };
 template<class Field> class LinearFunction {
 public:
  virtual void operator() (const Field &in, Field &out) = 0;
  virtual void operator() (const std::vector<Field> &in, std::vector<Field> &out)
  {
    assert(in.size() == out.size());
    for (unsigned int i = 0; i < in.size(); ++i)
    {
      (*this)(in[i], out[i]);
    }
  }
  virtual ~LinearFunction(){};
 };
 template<class Field> class IdentityLinearFunction : public LinearFunction<Field> {
@@ -588,7 +575,6 @@ class HermOpOperatorFunction : public OperatorFunction<Field> {
 template<typename Field>
 class PlainHermOp : public LinearFunction<Field> {
 public:
  using LinearFunction<Field>::operator();
  LinearOperatorBase<Field> &_Linop;
  PlainHermOp(LinearOperatorBase<Field>& linop) : _Linop(linop) 
@@ -602,7 +588,6 @@ public:
 template<typename Field>
 class FunctionHermOp : public LinearFunction<Field> {
 public:
  using LinearFunction<Field>::operator(); 
  OperatorFunction<Field>   & _poly;
  LinearOperatorBase<Field> &_Linop;
--- a/Grid/algorithms/Preconditioner.h
+++ b/Grid/algorithms/Preconditioner.h
@@ -30,19 +30,13 @@ Author: Azusa Yamaguchi <ayamaguc@staffmail.ed.ac.uk>
 NAMESPACE_BEGIN(Grid);
-template<class Field> using Preconditioner =  LinearFunction<Field> ;
+template<class Field> class Preconditioner :  public LinearFunction<Field> { 
 /*
 template<class Field> class Preconditioner :  public LinearFunction<Field> {
  using LinearFunction<Field>::operator();
  virtual void operator()(const Field &src, Field & psi)=0;
 };
 */
 template<class Field> class TrivialPrecon :  public Preconditioner<Field> { 
 public:
-  using Preconditioner<Field>::operator();
+  void operator()(const Field &src, Field & psi){
  virtual void operator()(const Field &src, Field & psi){
    psi = src;
  }
  TrivialPrecon(void){};
--- a/Grid/algorithms/SparseMatrix.h
+++ b/Grid/algorithms/SparseMatrix.h
@@ -48,7 +48,6 @@ public:
  virtual  void Mdiag    (const Field &in, Field &out)=0;
  virtual  void Mdir     (const Field &in, Field &out,int dir, int disp)=0;
  virtual  void MdirAll  (const Field &in, std::vector<Field> &out)=0;
  virtual ~SparseMatrixBase() {};
 };
 /////////////////////////////////////////////////////////////////////////////////////////////
@@ -73,7 +72,7 @@ public:
  virtual  void MeooeDag    (const Field &in, Field &out)=0;
  virtual  void MooeeDag    (const Field &in, Field &out)=0;
  virtual  void MooeeInvDag (const Field &in, Field &out)=0;
-  virtual ~CheckerBoardedSparseMatrixBase() {};
+
 };
 NAMESPACE_END(Grid);
--- a/Grid/algorithms/approx/Chebyshev.h
+++ b/Grid/algorithms/approx/Chebyshev.h
@@ -258,12 +258,26 @@ public:
    for(int n=2;n<order;n++){
      Linop.HermOp(*Tn,y);
 #if 0
      auto y_v = y.View();
      auto Tn_v = Tn->View();
      auto Tnp_v = Tnp->View();
      auto Tnm_v = Tnm->View();
      constexpr int Nsimd = vector_type::Nsimd();
      accelerator_forNB(ss, in.Grid()->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));
      });
      if ( Coeffs[n] != 0.0) {
 	axpy(out,Coeffs[n],*Tnp,out);
      }
 #else
      axpby(y,xscale,mscale,y,(*Tn));
      axpby(*Tnp,2.0,-1.0,y,(*Tnm));
      if ( Coeffs[n] != 0.0) {
 	axpy(out,Coeffs[n],*Tnp,out);
      }
-
+#endif
      // Cycle pointers to avoid copies
      Field *swizzle = Tnm;
      Tnm    =Tn;
--- a/Grid/algorithms/approx/Zolotarev.cc
+++ b/Grid/algorithms/approx/Zolotarev.cc
@@ -293,7 +293,7 @@ static void sncndnFK(INTERNAL_PRECISION u, INTERNAL_PRECISION k,
 * Set type = 0 for the Zolotarev approximation, which is zero at x = 0, and
 * type = 1 for the approximation which is infinite at x = 0. */
-zolotarev_data* zolotarev(ZOLO_PRECISION epsilon, int n, int type) {
+zolotarev_data* zolotarev(PRECISION epsilon, int n, int type) {
  INTERNAL_PRECISION A, c, cp, kp, ksq, sn, cn, dn, Kp, Kj, z, z0, t, M, F,
    l, invlambda, xi, xisq, *tv, s, opl;
  int m, czero, ts;
@@ -375,12 +375,12 @@ zolotarev_data* zolotarev(ZOLO_PRECISION epsilon, int n, int type) {
  construct_partfrac(d);
  construct_contfrac(d);
-  /* Converting everything to ZOLO_PRECISION for external use only */
+  /* Converting everything to PRECISION for external use only */
  zd = (zolotarev_data*) malloc(sizeof(zolotarev_data));
-  zd -> A = (ZOLO_PRECISION) d -> A;
+  zd -> A = (PRECISION) d -> A;
-  zd -> Delta = (ZOLO_PRECISION) d -> Delta;
+  zd -> Delta = (PRECISION) d -> Delta;
-  zd -> epsilon = (ZOLO_PRECISION) d -> epsilon;
+  zd -> epsilon = (PRECISION) d -> epsilon;
  zd -> n = d -> n;
  zd -> type = d -> type;
  zd -> dn = d -> dn;
@@ -390,24 +390,24 @@ zolotarev_data* zolotarev(ZOLO_PRECISION epsilon, int n, int type) {
  zd -> deg_num = d -> deg_num;
  zd -> deg_denom = d -> deg_denom;
-  zd -> a = (ZOLO_PRECISION*) malloc(zd -> dn * sizeof(ZOLO_PRECISION));
+  zd -> a = (PRECISION*) malloc(zd -> dn * sizeof(PRECISION));
-  for (m = 0; m < zd -> dn; m++) zd -> a[m] = (ZOLO_PRECISION) d -> a[m];
+  for (m = 0; m < zd -> dn; m++) zd -> a[m] = (PRECISION) d -> a[m];
  free(d -> a);
-  zd -> ap = (ZOLO_PRECISION*) malloc(zd -> dd * sizeof(ZOLO_PRECISION));
+  zd -> ap = (PRECISION*) malloc(zd -> dd * sizeof(PRECISION));
-  for (m = 0; m < zd -> dd; m++) zd -> ap[m] = (ZOLO_PRECISION) d -> ap[m];
+  for (m = 0; m < zd -> dd; m++) zd -> ap[m] = (PRECISION) d -> ap[m];
  free(d -> ap);
-  zd -> alpha = (ZOLO_PRECISION*) malloc(zd -> da * sizeof(ZOLO_PRECISION));
+  zd -> alpha = (PRECISION*) malloc(zd -> da * sizeof(PRECISION));
-  for (m = 0; m < zd -> da; m++) zd -> alpha[m] = (ZOLO_PRECISION) d -> alpha[m];
+  for (m = 0; m < zd -> da; m++) zd -> alpha[m] = (PRECISION) d -> alpha[m];
  free(d -> alpha);
-  zd -> beta = (ZOLO_PRECISION*) malloc(zd -> db * sizeof(ZOLO_PRECISION));
+  zd -> beta = (PRECISION*) malloc(zd -> db * sizeof(PRECISION));
-  for (m = 0; m < zd -> db; m++) zd -> beta[m] = (ZOLO_PRECISION) d -> beta[m];
+  for (m = 0; m < zd -> db; m++) zd -> beta[m] = (PRECISION) d -> beta[m];
  free(d -> beta);
-  zd -> gamma = (ZOLO_PRECISION*) malloc(zd -> n * sizeof(ZOLO_PRECISION));
+  zd -> gamma = (PRECISION*) malloc(zd -> n * sizeof(PRECISION));
-  for (m = 0; m < zd -> n; m++) zd -> gamma[m] = (ZOLO_PRECISION) d -> gamma[m];
+  for (m = 0; m < zd -> n; m++) zd -> gamma[m] = (PRECISION) d -> gamma[m];
  free(d -> gamma);
  free(d);
@@ -426,7 +426,7 @@ void zolotarev_free(zolotarev_data *zdata)
 }
-zolotarev_data* higham(ZOLO_PRECISION epsilon, int n) {
+zolotarev_data* higham(PRECISION epsilon, int n) {
  INTERNAL_PRECISION A, M, c, cp, z, z0, t, epssq;
  int m, czero;
  zolotarev_data *zd;
@@ -481,9 +481,9 @@ zolotarev_data* higham(ZOLO_PRECISION epsilon, int n) {
  /* Converting everything to PRECISION for external use only */
  zd = (zolotarev_data*) malloc(sizeof(zolotarev_data));
-  zd -> A = (ZOLO_PRECISION) d -> A;
+  zd -> A = (PRECISION) d -> A;
-  zd -> Delta = (ZOLO_PRECISION) d -> Delta;
+  zd -> Delta = (PRECISION) d -> Delta;
-  zd -> epsilon = (ZOLO_PRECISION) d -> epsilon;
+  zd -> epsilon = (PRECISION) d -> epsilon;
  zd -> n = d -> n;
  zd -> type = d -> type;
  zd -> dn = d -> dn;
@@ -493,24 +493,24 @@ zolotarev_data* higham(ZOLO_PRECISION epsilon, int n) {
  zd -> deg_num = d -> deg_num;
  zd -> deg_denom = d -> deg_denom;
-  zd -> a = (ZOLO_PRECISION*) malloc(zd -> dn * sizeof(ZOLO_PRECISION));
+  zd -> a = (PRECISION*) malloc(zd -> dn * sizeof(PRECISION));
-  for (m = 0; m < zd -> dn; m++) zd -> a[m] = (ZOLO_PRECISION) d -> a[m];
+  for (m = 0; m < zd -> dn; m++) zd -> a[m] = (PRECISION) d -> a[m];
  free(d -> a);
-  zd -> ap = (ZOLO_PRECISION*) malloc(zd -> dd * sizeof(ZOLO_PRECISION));
+  zd -> ap = (PRECISION*) malloc(zd -> dd * sizeof(PRECISION));
-  for (m = 0; m < zd -> dd; m++) zd -> ap[m] = (ZOLO_PRECISION) d -> ap[m];
+  for (m = 0; m < zd -> dd; m++) zd -> ap[m] = (PRECISION) d -> ap[m];
  free(d -> ap);
-  zd -> alpha = (ZOLO_PRECISION*) malloc(zd -> da * sizeof(ZOLO_PRECISION));
+  zd -> alpha = (PRECISION*) malloc(zd -> da * sizeof(PRECISION));
-  for (m = 0; m < zd -> da; m++) zd -> alpha[m] = (ZOLO_PRECISION) d -> alpha[m];
+  for (m = 0; m < zd -> da; m++) zd -> alpha[m] = (PRECISION) d -> alpha[m];
  free(d -> alpha);
-  zd -> beta = (ZOLO_PRECISION*) malloc(zd -> db * sizeof(ZOLO_PRECISION));
+  zd -> beta = (PRECISION*) malloc(zd -> db * sizeof(PRECISION));
-  for (m = 0; m < zd -> db; m++) zd -> beta[m] = (ZOLO_PRECISION) d -> beta[m];
+  for (m = 0; m < zd -> db; m++) zd -> beta[m] = (PRECISION) d -> beta[m];
  free(d -> beta);
-  zd -> gamma = (ZOLO_PRECISION*) malloc(zd -> n * sizeof(ZOLO_PRECISION));
+  zd -> gamma = (PRECISION*) malloc(zd -> n * sizeof(PRECISION));
-  for (m = 0; m < zd -> n; m++) zd -> gamma[m] = (ZOLO_PRECISION) d -> gamma[m];
+  for (m = 0; m < zd -> n; m++) zd -> gamma[m] = (PRECISION) d -> gamma[m];
  free(d -> gamma);
  free(d);
@@ -523,17 +523,17 @@ NAMESPACE_END(Grid);
 #ifdef TEST
 #undef ZERO
-#define ZERO ((ZOLO_PRECISION) 0)
+#define ZERO ((PRECISION) 0)
 #undef ONE
-#define ONE ((ZOLO_PRECISION) 1)
+#define ONE ((PRECISION) 1)
 #undef TWO
-#define TWO ((ZOLO_PRECISION) 2)
+#define TWO ((PRECISION) 2)
 /* Evaluate the rational approximation R(x) using the factored form */
-static ZOLO_PRECISION zolotarev_eval(ZOLO_PRECISION x, zolotarev_data* rdata) {
+static PRECISION zolotarev_eval(PRECISION x, zolotarev_data* rdata) {
  int m;
-  ZOLO_PRECISION R;
+  PRECISION R;
  if (rdata -> type == 0) {
    R = rdata -> A * x;
@@ -551,9 +551,9 @@ static ZOLO_PRECISION zolotarev_eval(ZOLO_PRECISION x, zolotarev_data* rdata) {
 /* Evaluate the rational approximation R(x) using the partial fraction form */
-static ZOLO_PRECISION zolotarev_partfrac_eval(ZOLO_PRECISION x, zolotarev_data* rdata) {
+static PRECISION zolotarev_partfrac_eval(PRECISION x, zolotarev_data* rdata) {
  int m;
-  ZOLO_PRECISION R = rdata -> alpha[rdata -> da - 1];
+  PRECISION R = rdata -> alpha[rdata -> da - 1];
  for (m = 0; m < rdata -> dd; m++)
    R += rdata -> alpha[m] / (x * x - rdata -> ap[m]);
  if (rdata -> type == 1) R += rdata -> alpha[rdata -> dd] / (x * x);
@@ -568,18 +568,18 @@ static ZOLO_PRECISION zolotarev_partfrac_eval(ZOLO_PRECISION x, zolotarev_data*
 * non-signalling overflow this will work correctly since 1/(1/0) = 1/INF = 0,
 * but with signalling overflow you will get an error message. */
-static ZOLO_PRECISION zolotarev_contfrac_eval(ZOLO_PRECISION x, zolotarev_data* rdata) {
+static PRECISION zolotarev_contfrac_eval(PRECISION x, zolotarev_data* rdata) {
  int m;
-  ZOLO_PRECISION R = rdata -> beta[0] * x;
+  PRECISION R = rdata -> beta[0] * x;
  for (m = 1; m < rdata -> db; m++) R = rdata -> beta[m] * x + ONE / R;
  return R;
 }    
 /* Evaluate the rational approximation R(x) using Cayley form */
-static ZOLO_PRECISION zolotarev_cayley_eval(ZOLO_PRECISION x, zolotarev_data* rdata) {
+static PRECISION zolotarev_cayley_eval(PRECISION x, zolotarev_data* rdata) {
  int m;
-  ZOLO_PRECISION T;
+  PRECISION T;
  T = rdata -> type == 0 ? ONE : -ONE;
  for (m = 0; m < rdata -> n; m++)
@@ -607,7 +607,7 @@ int main(int argc, char** argv) {
  int m, n, plotpts = 5000, type = 0;
  float eps, x, ypferr, ycferr, ycaylerr, maxypferr, maxycferr, maxycaylerr;
  zolotarev_data *rdata;
-  ZOLO_PRECISION y;
+  PRECISION y;
  FILE *plot_function, *plot_error, 
    *plot_partfrac, *plot_contfrac, *plot_cayley;
@@ -626,13 +626,13 @@ int main(int argc, char** argv) {
  }
  rdata = type == 2 
-    ? higham((ZOLO_PRECISION) eps, n) 
+    ? higham((PRECISION) eps, n) 
-    : zolotarev((ZOLO_PRECISION) eps, n, type);
+    : zolotarev((PRECISION) eps, n, type);
  printf("Zolotarev Test: R(epsilon = %g, n = %d, type = %d)\n\t" 
 	 STRINGIFY(VERSION) "\n\t" STRINGIFY(HVERSION)
 	 "\n\tINTERNAL_PRECISION = " STRINGIFY(INTERNAL_PRECISION)
-	 "\tZOLO_PRECISION = " STRINGIFY(ZOLO_PRECISION)
+	 "\tPRECISION = " STRINGIFY(PRECISION)
 	 "\n\n\tRational approximation of degree (%d,%d), %s at x = 0\n"
 	 "\tDelta = %g (maximum error)\n\n"
 	 "\tA = %g (overall factor)\n",
@@ -681,15 +681,15 @@ int main(int argc, char** argv) {
    x = 2.4 * (float) m / plotpts - 1.2;
    if (rdata -> type == 0 || fabs(x) * (float) plotpts > 1.0) {
      /* skip x = 0 for type 1, as R(0) is singular */
-      y = zolotarev_eval((ZOLO_PRECISION) x, rdata);
+      y = zolotarev_eval((PRECISION) x, rdata);
      fprintf(plot_function, "%g %g\n", x, (float) y);
      fprintf(plot_error, "%g %g\n",
 	      x, (float)((y - ((x > 0.0 ? ONE : -ONE))) / rdata -> Delta));
-      ypferr = (float)((zolotarev_partfrac_eval((ZOLO_PRECISION) x, rdata) - y)
+      ypferr = (float)((zolotarev_partfrac_eval((PRECISION) x, rdata) - y)
 		       / rdata -> Delta);
-      ycferr = (float)((zolotarev_contfrac_eval((ZOLO_PRECISION) x, rdata) - y)
+      ycferr = (float)((zolotarev_contfrac_eval((PRECISION) x, rdata) - y)
 		       / rdata -> Delta);
-      ycaylerr = (float)((zolotarev_cayley_eval((ZOLO_PRECISION) x, rdata) - y)
+      ycaylerr = (float)((zolotarev_cayley_eval((PRECISION) x, rdata) - y)
 		       / rdata -> Delta);
      if (fabs(x) < 1.0 && fabs(x) > rdata -> epsilon) {
 	maxypferr = MAX(maxypferr, fabs(ypferr));
--- a/Grid/algorithms/approx/Zolotarev.h
+++ b/Grid/algorithms/approx/Zolotarev.h
@@ -9,10 +9,10 @@ NAMESPACE_BEGIN(Approx);
 #define HVERSION Header Time-stamp: <14-OCT-2004 09:26:51.00 adk@MISSCONTRARY>
 #ifndef ZOLOTAREV_INTERNAL
-#ifndef ZOLO_PRECISION
+#ifndef PRECISION
-#define ZOLO_PRECISION double
+#define PRECISION double
 #endif
-#define ZPRECISION ZOLO_PRECISION
+#define ZPRECISION PRECISION
 #define ZOLOTAREV_DATA zolotarev_data
 #endif
@@ -77,8 +77,8 @@ typedef struct {
 * zolotarev_data structure. The arguments must satisfy the constraints that
 * epsilon > 0, n > 0, and type = 0 or 1. */
-ZOLOTAREV_DATA* higham(ZOLO_PRECISION epsilon, int n) ;
+ZOLOTAREV_DATA* higham(PRECISION epsilon, int n) ;
-ZOLOTAREV_DATA* zolotarev(ZOLO_PRECISION epsilon, int n, int type);
+ZOLOTAREV_DATA* zolotarev(PRECISION epsilon, int n, int type);
 void zolotarev_free(zolotarev_data *zdata);
 #endif
@@ -86,4 +86,3 @@ void zolotarev_free(zolotarev_data *zdata);
 NAMESPACE_END(Approx);
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/algorithms/blas/BatchedBlas.cc
+++ b/Grid/algorithms/blas/BatchedBlas.cc
@@ -1,34 +0,0 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: BatchedBlas.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 */
 #include <Grid/GridCore.h>
 #include <Grid/algorithms/blas/BatchedBlas.h>
 NAMESPACE_BEGIN(Grid);
 gridblasHandle_t GridBLAS::gridblasHandle;
 int              GridBLAS::gridblasInit;
 NAMESPACE_END(Grid);
--- a/Grid/algorithms/blas/BatchedBlas.h
+++ b/Grid/algorithms/blas/BatchedBlas.h
@@ -1,727 +0,0 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: BatchedBlas.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
 #ifdef GRID_HIP
 #include <hipblas/hipblas.h>
 #endif
 #ifdef GRID_CUDA
 #include <cublas_v2.h>
 #endif
 #ifdef GRID_SYCL
 #include <oneapi/mkl.hpp>
 #endif
 #if 0
 #define GRID_ONE_MKL
 #endif
 #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
 ///////////////////////////////////////////////////////////////////////
 NAMESPACE_BEGIN(Grid);
 #ifdef GRID_HIP
  typedef hipblasHandle_t gridblasHandle_t;
 #endif
 #ifdef GRID_CUDA
  typedef cublasHandle_t gridblasHandle_t;
 #endif
 #ifdef GRID_SYCL
  typedef cl::sycl::queue *gridblasHandle_t;
 #endif
 #ifdef GRID_ONE_MKL
  typedef cl::sycl::queue *gridblasHandle_t;
 #endif
 #if !defined(GRID_SYCL) && !defined(GRID_CUDA) && !defined(GRID_HIP) && !defined(GRID_ONE_MKL)
  typedef int32_t gridblasHandle_t;
 #endif
 enum GridBLASOperation_t { GridBLAS_OP_N, GridBLAS_OP_T, GridBLAS_OP_C } ;
 class GridBLAS {
 public:
  static gridblasHandle_t gridblasHandle;
  static int            gridblasInit;
  static void Init(void)
  {
    if ( ! gridblasInit ) {
 #ifdef GRID_CUDA
      std::cout << "cublasCreate"<<std::endl;
      cublasCreate(&gridblasHandle);
      cublasSetPointerMode(gridblasHandle, CUBLAS_POINTER_MODE_DEVICE);
 #endif
 #ifdef GRID_HIP
      std::cout << "hipblasCreate"<<std::endl;
      hipblasCreate(&gridblasHandle);
 #endif
 #ifdef GRID_SYCL
      gridblasHandle = theGridAccelerator;
 #endif
 #ifdef GRID_ONE_MKL
      cl::sycl::cpu_selector selector;
      cl::sycl::device selectedDevice { selector };
      gridblasHandle =new sycl::queue (selectedDevice);
 #endif
      gridblasInit=1;
    }
  }
  // Force construct once
  GridBLAS() { Init(); };
  ~GridBLAS() { };
  /////////////////////////////////////////////////////////////////////////////////////
  // BLAS GEMM conventions:
  /////////////////////////////////////////////////////////////////////////////////////
  // - C = alpha A * B + beta C
  // Dimensions:
  // - C_m.n
  // - A_m.k
  // - B_k.n
  // - Flops = 8 M N K
  // - Bytes = 2*sizeof(word) * (MN+MK+KN)
  // M=60, N=12
  // Flop/Byte = 8 . 60.60.12 / (60.12+60.60+60.12)/16 = 4 so expect about 4 TF/s on a GCD
  /////////////////////////////////////////////////////////////////////////////////////
  void synchronise(void)
  {
 #ifdef GRID_HIP
    auto err = hipDeviceSynchronize();
    assert(err==hipSuccess);
 #endif
 #ifdef GRID_CUDA
    auto err = cudaDeviceSynchronize();
    assert(err==cudaSuccess);
 #endif
 #ifdef GRID_SYCL
    accelerator_barrier();
 #endif
 #ifdef GRID_ONE_MKL
    gridblasHandle->wait();
 #endif
  }
  void gemmBatched(int m,int n, int k,
 		   ComplexD alpha,
 		   deviceVector<ComplexD*> &Amk,  // pointer list to matrices
 		   deviceVector<ComplexD*> &Bkn,
 		   ComplexD beta,
 		   deviceVector<ComplexD*> &Cmn)
  {
    gemmBatched(GridBLAS_OP_N,GridBLAS_OP_N,
 		m,n,k,
 		alpha,
 		Amk,
 		Bkn,
 		beta,
 		Cmn);
  }
  void gemmBatched(int m,int n, int k,
 		   ComplexF alpha,
 		   deviceVector<ComplexF*> &Amk,  // pointer list to matrices
 		   deviceVector<ComplexF*> &Bkn,
 		   ComplexF beta,
 		   deviceVector<ComplexF*> &Cmn)
  {
    gemmBatched(GridBLAS_OP_N,GridBLAS_OP_N,
 		m,n,k,
 		alpha,
 		Amk,
 		Bkn,
 		beta,
 		Cmn);
  }
  void gemmBatched(int m,int n, int k,
 		   RealD alpha,
 		   deviceVector<RealD*> &Amk,  // pointer list to matrices
 		   deviceVector<RealD*> &Bkn,
 		   RealD beta,
 		   deviceVector<RealD*> &Cmn)
  {
    gemmBatched(GridBLAS_OP_N,GridBLAS_OP_N,
 		m,n,k,
 		alpha,
 		Amk,
 		Bkn,
 		beta,
 		Cmn);
  }
  void gemmBatched(int m,int n, int k,
 		   RealF alpha,
 		   deviceVector<RealF*> &Amk,  // pointer list to matrices
 		   deviceVector<RealF*> &Bkn,
 		   RealF beta,
 		   deviceVector<RealF*> &Cmn)
  {
    gemmBatched(GridBLAS_OP_N,GridBLAS_OP_N,
 		m,n,k,
 		alpha,
 		Amk,
 		Bkn,
 		beta,
 		Cmn);
  }
  void gemmBatched(GridBLASOperation_t OpA,
 		   GridBLASOperation_t OpB,
 		   int m,int n, int k,
 		   ComplexD alpha,
 		   deviceVector<ComplexD*> &Amk,  // pointer list to matrices
 		   deviceVector<ComplexD*> &Bkn,
 		   ComplexD beta,
 		   deviceVector<ComplexD*> &Cmn)
  {
    RealD t2=usecond();
    int32_t batchCount = Amk.size();
    assert(Bkn.size()==batchCount);
    assert(Cmn.size()==batchCount);
    int lda = m; // m x k column major
    int ldb = k; // k x n column major
    int ldc = m; // m x b column major
    if(OpA!=GridBLAS_OP_N)
      lda = k;
    if(OpB!=GridBLAS_OP_N)
      ldb = n;
    static deviceVector<ComplexD> alpha_p(1);
    static deviceVector<ComplexD> beta_p(1);
    // can prestore the 1 and the zero on device
    acceleratorCopyToDevice((void *)&alpha,(void *)&alpha_p[0],sizeof(ComplexD));
    acceleratorCopyToDevice((void *)&beta ,(void *)&beta_p[0],sizeof(ComplexD));
    RealD t0=usecond();
    //    std::cout << "ZgemmBatched mnk  "<<m<<","<<n<<","<<k<<" count "<<batchCount<<std::endl;
 #ifdef GRID_HIP
    hipblasOperation_t hOpA;
    hipblasOperation_t hOpB;
    if ( OpA == GridBLAS_OP_N ) hOpA = HIPBLAS_OP_N;
    if ( OpA == GridBLAS_OP_T ) hOpA = HIPBLAS_OP_T;
    if ( OpA == GridBLAS_OP_C ) hOpA = HIPBLAS_OP_C;
    if ( OpB == GridBLAS_OP_N ) hOpB = HIPBLAS_OP_N;
    if ( OpB == GridBLAS_OP_T ) hOpB = HIPBLAS_OP_T;
    if ( OpB == GridBLAS_OP_C ) hOpB = HIPBLAS_OP_C;
    auto err = hipblasZgemmBatched(gridblasHandle,
 				   hOpA,
 				   hOpB,
 				   m,n,k,
 				   (hipblasDoubleComplex *) &alpha_p[0],
 				   (hipblasDoubleComplex **)&Amk[0], lda,
 				   (hipblasDoubleComplex **)&Bkn[0], ldb,
 				   (hipblasDoubleComplex *) &beta_p[0],
 				   (hipblasDoubleComplex **)&Cmn[0], ldc,
 				   batchCount);
    //	 std::cout << " hipblas return code " <<(int)err<<std::endl;
    assert(err==HIPBLAS_STATUS_SUCCESS);
 #endif
 #ifdef GRID_CUDA
    cublasOperation_t hOpA;
    cublasOperation_t hOpB;
    if ( OpA == GridBLAS_OP_N ) hOpA = CUBLAS_OP_N;
    if ( OpA == GridBLAS_OP_T ) hOpA = CUBLAS_OP_T;
    if ( OpA == GridBLAS_OP_C ) hOpA = CUBLAS_OP_C;
    if ( OpB == GridBLAS_OP_N ) hOpB = CUBLAS_OP_N;
    if ( OpB == GridBLAS_OP_T ) hOpB = CUBLAS_OP_T;
    if ( OpB == GridBLAS_OP_C ) hOpB = CUBLAS_OP_C;
    auto err = cublasZgemmBatched(gridblasHandle,
 				  hOpA,
 				  hOpB,
 				  m,n,k,
 				  (cuDoubleComplex *) &alpha_p[0],
 				  (cuDoubleComplex **)&Amk[0], lda,
 				  (cuDoubleComplex **)&Bkn[0], ldb,
 				  (cuDoubleComplex *) &beta_p[0],
 				  (cuDoubleComplex **)&Cmn[0], ldc,
 				  batchCount);
    assert(err==CUBLAS_STATUS_SUCCESS);
 #endif
 #ifdef GRID_SYCL
    //MKL’s cblas_<T>gemm_batch & OneAPI
 #warning "oneMKL implementation not built "
 #endif
 #if !defined(GRID_SYCL) && !defined(GRID_CUDA) && !defined(GRID_HIP)
    // Need a default/reference implementation
    int sda = lda*k;
    int sdb = ldb*k;
    int sdc = ldc*n;
    for (int p = 0; p < batchCount; ++p) {
      for (int mm = 0; mm < m; ++mm) {
 	for (int nn = 0; nn < n; ++nn) {
 	  ComplexD c_mn(0.0);
 	  for (int kk = 0; kk < k; ++kk)
 	    c_mn += Amk[p][mm + kk*lda ] * Bkn[p][kk + nn*ldb];
 	  Cmn[p][mm + nn*ldc] =  (alpha)*c_mn + (beta)*Cmn[p][mm + nn*ldc ];
 	}
      }
    }
 #endif
    //    synchronise();
     RealD t1=usecond();
     RealD flops = 8.0*m*n*k*batchCount;
     RealD bytes = 1.0*sizeof(ComplexD)*(m*k+k*n+m*n)*batchCount;
     //     std::cout <<GridLogMessage<< " batched Blas copy "<<(t0-t2)/1.e3 <<" ms "<<std::endl;
     //     std::cout <<GridLogMessage<< " batched Blas zGemm call "<<m<<","<<n<<","<<k<<" "<< flops/(t1-t0)/1.e3 <<" GF/s "<<(t1-t0)/1.e3<<" ms "<<std::endl;
     //     std::cout <<GridLogMessage<< " batched Blas zGemm call "<<m<<","<<n<<","<<k<<" "<< bytes/(t1-t0)/1.e3 <<" GB/s "<<(t1-t0)/1.e3<<" ms "<<std::endl;
  }
  void gemmBatched(GridBLASOperation_t OpA,
 		   GridBLASOperation_t OpB,
 		   int m,int n, int k,
 		   ComplexF alpha,
 		   deviceVector<ComplexF*> &Amk,  // pointer list to matrices
 		   deviceVector<ComplexF*> &Bkn,
 		   ComplexF beta,
 		   deviceVector<ComplexF*> &Cmn)
  {
    RealD t2=usecond();
    int32_t batchCount = Amk.size();
    int lda = m; // m x k column major
    int ldb = k; // k x n column major
    int ldc = m; // m x b column major
    if(OpA!=GridBLAS_OP_N)
      lda = k;
    if(OpB!=GridBLAS_OP_N)
      ldb = n;
    static deviceVector<ComplexF> alpha_p(1);
    static deviceVector<ComplexF> beta_p(1);
    // can prestore the 1 and the zero on device
    acceleratorCopyToDevice((void *)&alpha,(void *)&alpha_p[0],sizeof(ComplexF));
    acceleratorCopyToDevice((void *)&beta ,(void *)&beta_p[0],sizeof(ComplexF));
    RealD t0=usecond();
    assert(Bkn.size()==batchCount);
    assert(Cmn.size()==batchCount);
 #ifdef GRID_HIP
    hipblasOperation_t hOpA;
    hipblasOperation_t hOpB;
    if ( OpA == GridBLAS_OP_N ) hOpA = HIPBLAS_OP_N;
    if ( OpA == GridBLAS_OP_T ) hOpA = HIPBLAS_OP_T;
    if ( OpA == GridBLAS_OP_C ) hOpA = HIPBLAS_OP_C;
    if ( OpB == GridBLAS_OP_N ) hOpB = HIPBLAS_OP_N;
    if ( OpB == GridBLAS_OP_T ) hOpB = HIPBLAS_OP_T;
    if ( OpB == GridBLAS_OP_C ) hOpB = HIPBLAS_OP_C;
    auto err = hipblasCgemmBatched(gridblasHandle,
 				   hOpA,
 				   hOpB,
 				   m,n,k,
 				   (hipblasComplex *) &alpha_p[0],
 				   (hipblasComplex **)&Amk[0], lda,
 				   (hipblasComplex **)&Bkn[0], ldb,
 				   (hipblasComplex *) &beta_p[0],
 				   (hipblasComplex **)&Cmn[0], ldc,
 				   batchCount);
    assert(err==HIPBLAS_STATUS_SUCCESS);
 #endif
 #ifdef GRID_CUDA
    cublasOperation_t hOpA;
    cublasOperation_t hOpB;
    if ( OpA == GridBLAS_OP_N ) hOpA = CUBLAS_OP_N;
    if ( OpA == GridBLAS_OP_T ) hOpA = CUBLAS_OP_T;
    if ( OpA == GridBLAS_OP_C ) hOpA = CUBLAS_OP_C;
    if ( OpB == GridBLAS_OP_N ) hOpB = CUBLAS_OP_N;
    if ( OpB == GridBLAS_OP_T ) hOpB = CUBLAS_OP_T;
    if ( OpB == GridBLAS_OP_C ) hOpB = CUBLAS_OP_C;
    auto err = cublasCgemmBatched(gridblasHandle,
 				  hOpA,
 				  hOpB,
 				  m,n,k,
 				  (cuComplex *) &alpha_p[0],
 				  (cuComplex **)&Amk[0], lda,
 				  (cuComplex **)&Bkn[0], ldb,
 				  (cuComplex *) &beta_p[0],
 				  (cuComplex **)&Cmn[0], ldc,
 				  batchCount);
    assert(err==CUBLAS_STATUS_SUCCESS);
 #endif
 #ifdef GRID_SYCL
    //MKL’s cblas_<T>gemm_batch & OneAPI
 #warning "oneMKL implementation not built "
 #endif
 #if !defined(GRID_SYCL) && !defined(GRID_CUDA) && !defined(GRID_HIP)
    int sda = lda*k;
    int sdb = ldb*k;
    int sdc = ldc*n;
    ComplexF alphaf(real(alpha),imag(alpha));
    ComplexF betaf(real(beta),imag(beta));
    // Need a default/reference implementation
    for (int p = 0; p < batchCount; ++p) {
      for (int mm = 0; mm < m; ++mm) {
 	for (int nn = 0; nn < n; ++nn) {
 	  ComplexF c_mn(0.0);
 	  for (int kk = 0; kk < k; ++kk)
 	    c_mn += Amk[p][mm + kk*lda ] * Bkn[p][kk + nn*ldb];
 	  Cmn[p][mm + nn*ldc] =  (alphaf)*c_mn + (betaf)*Cmn[p][mm + nn*ldc ];
 	}
      }
    }
 #endif
     RealD t1=usecond();
     RealD flops = 8.0*m*n*k*batchCount;
     RealD bytes = 1.0*sizeof(ComplexF)*(m*k+k*n+m*n)*batchCount;
  }
  ///////////////////////////////////////////////////////////////////////////
  // Single precision real GEMM
  ///////////////////////////////////////////////////////////////////////////
  void gemmBatched(GridBLASOperation_t OpA,
 		   GridBLASOperation_t OpB,
 		   int m,int n, int k,
 		   RealF alpha,
 		   deviceVector<RealF*> &Amk,  // pointer list to matrices
 		   deviceVector<RealF*> &Bkn,
 		   RealF beta,
 		   deviceVector<RealF*> &Cmn)
  {
    RealD t2=usecond();
    int32_t batchCount = Amk.size();
    int lda = m; // m x k column major
    int ldb = k; // k x n column major
    int ldc = m; // m x b column major
    if(OpA!=GridBLAS_OP_N)
      lda = k;
    if(OpB!=GridBLAS_OP_N)
      ldb = n;
    static deviceVector<RealF> alpha_p(1);
    static deviceVector<RealF> beta_p(1);
    // can prestore the 1 and the zero on device
    acceleratorCopyToDevice((void *)&alpha,(void *)&alpha_p[0],sizeof(RealF));
    acceleratorCopyToDevice((void *)&beta ,(void *)&beta_p[0],sizeof(RealF));
    RealD t0=usecond();
    assert(Bkn.size()==batchCount);
    assert(Cmn.size()==batchCount);
 #ifdef GRID_HIP
    hipblasOperation_t hOpA;
    hipblasOperation_t hOpB;
    if ( OpA == GridBLAS_OP_N ) hOpA = HIPBLAS_OP_N;
    if ( OpA == GridBLAS_OP_T ) hOpA = HIPBLAS_OP_T;
    if ( OpA == GridBLAS_OP_C ) hOpA = HIPBLAS_OP_C;
    if ( OpB == GridBLAS_OP_N ) hOpB = HIPBLAS_OP_N;
    if ( OpB == GridBLAS_OP_T ) hOpB = HIPBLAS_OP_T;
    if ( OpB == GridBLAS_OP_C ) hOpB = HIPBLAS_OP_C;
    auto err = hipblasSgemmBatched(gridblasHandle,
 				   hOpA,
 				   hOpB,
 				   m,n,k,
 				   (float *) &alpha_p[0],
 				   (float **)&Amk[0], lda,
 				   (float **)&Bkn[0], ldb,
 				   (float *) &beta_p[0],
 				   (float **)&Cmn[0], ldc,
 				   batchCount);
    assert(err==HIPBLAS_STATUS_SUCCESS);
 #endif
 #ifdef GRID_CUDA
    cublasOperation_t hOpA;
    cublasOperation_t hOpB;
    if ( OpA == GridBLAS_OP_N ) hOpA = CUBLAS_OP_N;
    if ( OpA == GridBLAS_OP_T ) hOpA = CUBLAS_OP_T;
    if ( OpA == GridBLAS_OP_C ) hOpA = CUBLAS_OP_C;
    if ( OpB == GridBLAS_OP_N ) hOpB = CUBLAS_OP_N;
    if ( OpB == GridBLAS_OP_T ) hOpB = CUBLAS_OP_T;
    if ( OpB == GridBLAS_OP_C ) hOpB = CUBLAS_OP_C;
    auto err = cublasSgemmBatched(gridblasHandle,
 				  hOpA,
 				  hOpB,
 				  m,n,k,
 				  (float *) &alpha_p[0],
 				  (float **)&Amk[0], lda,
 				  (float **)&Bkn[0], ldb,
 				  (float *) &beta_p[0],
 				  (float **)&Cmn[0], ldc,
 				  batchCount);
    assert(err==CUBLAS_STATUS_SUCCESS);
 #endif
 #ifdef GRID_SYCL
    //MKL’s cblas_<T>gemm_batch & OneAPI
 #warning "oneMKL implementation not built "
 #endif
 #if !defined(GRID_SYCL) && !defined(GRID_CUDA) && !defined(GRID_HIP)
    int sda = lda*k;
    int sdb = ldb*k;
    int sdc = ldc*n;
    // Need a default/reference implementation
    for (int p = 0; p < batchCount; ++p) {
      for (int mm = 0; mm < m; ++mm) {
 	for (int nn = 0; nn < n; ++nn) {
 	  RealD c_mn(0.0);
 	  for (int kk = 0; kk < k; ++kk)
 	    c_mn += Amk[p][mm + kk*lda ] * Bkn[p][kk + nn*ldb];
 	  Cmn[p][mm + nn*ldc] =  (alpha)*c_mn + (beta)*Cmn[p][mm + nn*ldc ];
 	}
      }
    }
 #endif
     RealD t1=usecond();
     RealD flops = 2.0*m*n*k*batchCount;
     RealD bytes = 1.0*sizeof(RealF)*(m*k+k*n+m*n)*batchCount;
  }
  ///////////////////////////////////////////////////////////////////////////
  // Double precision real GEMM
  ///////////////////////////////////////////////////////////////////////////
  void gemmBatched(GridBLASOperation_t OpA,
 		   GridBLASOperation_t OpB,
 		   int m,int n, int k,
 		   RealD alpha,
 		   deviceVector<RealD*> &Amk,  // pointer list to matrices
 		   deviceVector<RealD*> &Bkn,
 		   RealD beta,
 		   deviceVector<RealD*> &Cmn)
  {
    RealD t2=usecond();
    int32_t batchCount = Amk.size();
    int lda = m; // m x k column major
    int ldb = k; // k x n column major
    int ldc = m; // m x b column major
    if(OpA!=GridBLAS_OP_N)
      lda = k;
    if(OpB!=GridBLAS_OP_N)
      ldb = n;
    static deviceVector<RealD> alpha_p(1);
    static deviceVector<RealD> beta_p(1);
    // can prestore the 1 and the zero on device
    acceleratorCopyToDevice((void *)&alpha,(void *)&alpha_p[0],sizeof(RealD));
    acceleratorCopyToDevice((void *)&beta ,(void *)&beta_p[0],sizeof(RealD));
    RealD t0=usecond();
    assert(Bkn.size()==batchCount);
    assert(Cmn.size()==batchCount);
 #ifdef GRID_HIP
    hipblasOperation_t hOpA;
    hipblasOperation_t hOpB;
    if ( OpA == GridBLAS_OP_N ) hOpA = HIPBLAS_OP_N;
    if ( OpA == GridBLAS_OP_T ) hOpA = HIPBLAS_OP_T;
    if ( OpA == GridBLAS_OP_C ) hOpA = HIPBLAS_OP_C;
    if ( OpB == GridBLAS_OP_N ) hOpB = HIPBLAS_OP_N;
    if ( OpB == GridBLAS_OP_T ) hOpB = HIPBLAS_OP_T;
    if ( OpB == GridBLAS_OP_C ) hOpB = HIPBLAS_OP_C;
    auto err = hipblasDgemmBatched(gridblasHandle,
 				   HIPBLAS_OP_N,
 				   HIPBLAS_OP_N,
 				   m,n,k,
 				   (double *) &alpha_p[0],
 				   (double **)&Amk[0], lda,
 				   (double **)&Bkn[0], ldb,
 				   (double *) &beta_p[0],
 				   (double **)&Cmn[0], ldc,
 				   batchCount);
    assert(err==HIPBLAS_STATUS_SUCCESS);
 #endif
 #ifdef GRID_CUDA
    cublasOperation_t hOpA;
    cublasOperation_t hOpB;
    if ( OpA == GridBLAS_OP_N ) hOpA = CUBLAS_OP_N;
    if ( OpA == GridBLAS_OP_T ) hOpA = CUBLAS_OP_T;
    if ( OpA == GridBLAS_OP_C ) hOpA = CUBLAS_OP_C;
    if ( OpB == GridBLAS_OP_N ) hOpB = CUBLAS_OP_N;
    if ( OpB == GridBLAS_OP_T ) hOpB = CUBLAS_OP_T;
    if ( OpB == GridBLAS_OP_C ) hOpB = CUBLAS_OP_C;
    auto err = cublasDgemmBatched(gridblasHandle,
 				  hOpA,
 				  hOpB,
 				  m,n,k,
 				  (double *) &alpha_p[0],
 				  (double **)&Amk[0], lda,
 				  (double **)&Bkn[0], ldb,
 				  (double *) &beta_p[0],
 				  (double **)&Cmn[0], ldc,
 				  batchCount);
    assert(err==CUBLAS_STATUS_SUCCESS);
 #endif
 #ifdef GRID_SYCL
    /*
      int64_t m64=m;
      int64_t n64=n;
      int64_t k64=k;
      int64_t batchCount64=batchCount;
      oneapi::mkl::blas::column_major::gemm_batch(*theGridAccelerator,
      onemkl::transpose::N,
      onemkl::transpose::N,
      &m64,&n64,&k64,
      (double *) &alpha_p[0],
      (double **)&Amk[0], lda,
      (double **)&Bkn[0], ldb,
      (double *) &beta_p[0],
      (double **)&Cmn[0], ldc,
      1,&batchCount64);
     */
    //MKL’s cblas_<T>gemm_batch & OneAPI
 #warning "oneMKL implementation not built "
 #endif
 #if !defined(GRID_SYCL) && !defined(GRID_CUDA) && !defined(GRID_HIP)
    int sda = lda*k;
    int sdb = ldb*k;
    int sdc = ldc*n;
    // Need a default/reference implementation
    for (int p = 0; p < batchCount; ++p) {
      for (int mm = 0; mm < m; ++mm) {
 	for (int nn = 0; nn < n; ++nn) {
 	  RealD c_mn(0.0);
 	  for (int kk = 0; kk < k; ++kk)
 	    c_mn += Amk[p][mm + kk*lda ] * Bkn[p][kk + nn*ldb];
 	  Cmn[p][mm + nn*ldc] =  (alpha)*c_mn + (beta)*Cmn[p][mm + nn*ldc ];
 	}
      }
    }
 #endif
     RealD t1=usecond();
     RealD flops = 2.0*m*n*k*batchCount;
     RealD bytes = 1.0*sizeof(RealD)*(m*k+k*n+m*n)*batchCount;
  }
  ////////////////////////////////////////////////////////////////////////////////////////////////
  // Strided case used by benchmark, but generally unused in Grid
  // Keep a code example in double complex, but don't generate the single and real variants for now
  ////////////////////////////////////////////////////////////////////////////////////////////////
  void gemmStridedBatched(int m,int n, int k,
 			  ComplexD alpha,
 			  ComplexD* Amk,  // pointer list to matrices
 			  ComplexD* Bkn,
 			  ComplexD beta,
 			  ComplexD* Cmn,
 			  int batchCount)
  {
    // Use C-row major storage, so transpose calls
    int lda = m; // m x k column major
    int ldb = k; // k x n column major
    int ldc = m; // m x b column major
    int sda = m*k;
    int sdb = k*n;
    int sdc = m*n;
    deviceVector<ComplexD> alpha_p(1);
    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;
 #ifdef GRID_HIP
    auto err = hipblasZgemmStridedBatched(gridblasHandle,
 					  HIPBLAS_OP_N,
 					  HIPBLAS_OP_N,
 					  m,n,k,
 					  (hipblasDoubleComplex *) &alpha_p[0],
 					  (hipblasDoubleComplex *) Amk, lda, sda,
 					  (hipblasDoubleComplex *) Bkn, ldb, sdb,
 					  (hipblasDoubleComplex *) &beta_p[0],
 					  (hipblasDoubleComplex *) Cmn, ldc, sdc,
 					  batchCount);
    assert(err==HIPBLAS_STATUS_SUCCESS);
 #endif
 #ifdef GRID_CUDA
    cublasZgemmStridedBatched(gridblasHandle,
 			      CUBLAS_OP_N,
 			      CUBLAS_OP_N,
 			      m,n,k,
 			      (cuDoubleComplex *) &alpha_p[0],
 			      (cuDoubleComplex *) Amk, lda, sda,
 			      (cuDoubleComplex *) Bkn, ldb, sdb,
 			      (cuDoubleComplex *) &beta_p[0],
 			      (cuDoubleComplex *) Cmn, ldc, sdc,
 			      batchCount);
 #endif
 #if defined(GRID_SYCL) || defined(GRID_ONE_MKL)
    oneapi::mkl::blas::column_major::gemm_batch(*gridblasHandle,
 						oneapi::mkl::transpose::N,
 						oneapi::mkl::transpose::N,
 						m,n,k,
 						alpha,
 						(const ComplexD *)Amk,lda,sda,
 						(const ComplexD *)Bkn,ldb,sdb,
 						beta,
 						(ComplexD *)Cmn,ldc,sdc,
 						batchCount);
 #endif
 #if !defined(GRID_SYCL) && !defined(GRID_CUDA) && !defined(GRID_HIP) && !defined(GRID_ONE_MKL)
     // Need a default/reference implementation
     for (int p = 0; p < batchCount; ++p) {
       for (int mm = 0; mm < m; ++mm) {
 	 for (int nn = 0; nn < n; ++nn) {
 	   ComplexD c_mn(0.0);
 	   for (int kk = 0; kk < k; ++kk)
 	     c_mn += Amk[mm + kk*lda + p*sda] * Bkn[kk + nn*ldb + p*sdb];
 	   Cmn[mm + nn*ldc + p*sdc] =  (alpha)*c_mn + (beta)*Cmn[mm + nn*ldc + p*sdc];
 	 }
       }
     }
 #endif
  }
  double benchmark(int M, int N, int K, int BATCH)
  {
    int32_t N_A = M*K*BATCH;
    int32_t N_B = K*N*BATCH;
    int32_t N_C = M*N*BATCH;
    deviceVector<ComplexD> A(N_A); acceleratorMemSet(&A[0],0,N_A*sizeof(ComplexD));
    deviceVector<ComplexD> B(N_B); acceleratorMemSet(&B[0],0,N_B*sizeof(ComplexD));
    deviceVector<ComplexD> C(N_C); acceleratorMemSet(&C[0],0,N_C*sizeof(ComplexD));
    ComplexD alpha(1.0);
    ComplexD beta (1.0);
    RealD flops = 8.0*M*N*K*BATCH;
    int ncall=10;
    RealD t0 = usecond();
    for(int i=0;i<ncall;i++){
      gemmStridedBatched(M,N,K,
 			 alpha,
 			 &A[0], // m x k 
 			 &B[0], // k x n
 			 beta, 
 			 &C[0], // m x n
 			 BATCH);
    }
    synchronise();
    RealD t1 = usecond();
    RealD bytes = 1.0*sizeof(ComplexD)*(M*N*2+N*K+M*K)*BATCH;
    flops = 8.0*M*N*K*BATCH*ncall;
    flops = flops/(t1-t0)/1.e3;
    return flops; // Returns gigaflops
  }
 };
 NAMESPACE_END(Grid);
--- a/Grid/algorithms/iterative/BiCGSTABMixedPrec.h
+++ b/Grid/algorithms/iterative/BiCGSTABMixedPrec.h
@@ -36,8 +36,7 @@ NAMESPACE_BEGIN(Grid);
 template<class FieldD, class FieldF, typename std::enable_if< getPrecision<FieldD>::value == 2, int>::type = 0, typename std::enable_if< getPrecision<FieldF>::value == 1, int>::type = 0> 
 class MixedPrecisionBiCGSTAB : public LinearFunction<FieldD> 
 {
-  public:
+  public:                                                
    using LinearFunction<FieldD>::operator();
    RealD   Tolerance;
    RealD   InnerTolerance; // Initial tolerance for inner CG. Defaults to Tolerance but can be changed
    Integer MaxInnerIterations;
--- a/Grid/algorithms/iterative/ConjugateGradient.h
+++ b/Grid/algorithms/iterative/ConjugateGradient.h
@@ -58,7 +58,6 @@ public:
  void operator()(LinearOperatorBase<Field> &Linop, const Field &src, Field &psi) {
    GRID_TRACE("ConjugateGradient");
    psi.Checkerboard() = src.Checkerboard();
    conformable(psi, src);
@@ -118,13 +117,9 @@ public:
    GridStopWatch MatrixTimer;
    GridStopWatch SolverTimer;
    RealD usecs = -usecond();
    SolverTimer.Start();
    int k;
    for (k = 1; k <= MaxIterations; k++) {
      GridStopWatch IterationTimer;
      IterationTimer.Start();
      c = cp;
      MatrixTimer.Start();
@@ -157,41 +152,31 @@ public:
      LinearCombTimer.Stop();
      LinalgTimer.Stop();
-      IterationTimer.Stop();
+      std::cout << GridLogIterative << "ConjugateGradient: Iteration " << k
      if ( (k % 500) == 0 ) {
 	std::cout << GridLogMessage << "ConjugateGradient: Iteration " << k
                << " residual " << sqrt(cp/ssq) << " target " << Tolerance << std::endl;
      } else { 
 	std::cout << GridLogIterative << "ConjugateGradient: Iteration " << k
 		  << " residual " << sqrt(cp/ssq) << " target " << Tolerance << " took " << IterationTimer.Elapsed() << std::endl;
      }
      // Stopping condition
      if (cp <= rsq) {
 	usecs +=usecond();
        SolverTimer.Stop();
        Linop.HermOpAndNorm(psi, mmp, d, qq);
        p = mmp - src;
-	GridBase *grid = src.Grid();
+
 	RealD DwfFlops = (1452. )*grid->gSites()*4*k
   	               + (8+4+8+4+4)*12*grid->gSites()*k; // CG linear algebra
        RealD srcnorm = std::sqrt(norm2(src));
        RealD resnorm = std::sqrt(norm2(p));
        RealD true_residual = resnorm / srcnorm;
        std::cout << GridLogMessage << "ConjugateGradient Converged on iteration " << k 
 		  << "\tComputed residual " << std::sqrt(cp / ssq)
 		  << "\tTrue residual " << true_residual
 		  << "\tTarget " << Tolerance << std::endl;
-        std::cout << GridLogMessage << "Time breakdown "<<std::endl;
+        std::cout << GridLogIterative << "Time breakdown "<<std::endl;
-	std::cout << GridLogMessage << "\tElapsed    " << SolverTimer.Elapsed() <<std::endl;
+	std::cout << GridLogIterative << "\tElapsed    " << SolverTimer.Elapsed() <<std::endl;
-	std::cout << GridLogMessage << "\tMatrix     " << MatrixTimer.Elapsed() <<std::endl;
+	std::cout << GridLogIterative << "\tMatrix     " << MatrixTimer.Elapsed() <<std::endl;
-	std::cout << GridLogMessage << "\tLinalg     " << LinalgTimer.Elapsed() <<std::endl;
+	std::cout << GridLogIterative << "\tLinalg     " << LinalgTimer.Elapsed() <<std::endl;
-	std::cout << GridLogMessage << "\tInner      " << InnerTimer.Elapsed() <<std::endl;
+	std::cout << GridLogIterative << "\tInner      " << InnerTimer.Elapsed() <<std::endl;
-	std::cout << GridLogMessage << "\tAxpyNorm   " << AxpyNormTimer.Elapsed() <<std::endl;
+	std::cout << GridLogIterative << "\tAxpyNorm   " << AxpyNormTimer.Elapsed() <<std::endl;
-	std::cout << GridLogMessage << "\tLinearComb " << LinearCombTimer.Elapsed() <<std::endl;
+	std::cout << GridLogIterative << "\tLinearComb " << LinearCombTimer.Elapsed() <<std::endl;
 	std::cout << GridLogDebug << "\tMobius flop rate " << DwfFlops/ usecs<< " Gflops " <<std::endl;
        if (ErrorOnNoConverge) assert(true_residual / Tolerance < 10000.0);
--- a/Grid/algorithms/iterative/ConjugateGradientMixedPrec.h
+++ b/Grid/algorithms/iterative/ConjugateGradientMixedPrec.h
@@ -35,8 +35,7 @@ NAMESPACE_BEGIN(Grid);
    typename std::enable_if< getPrecision<FieldD>::value == 2, int>::type = 0,
    typename std::enable_if< getPrecision<FieldF>::value == 1, int>::type = 0> 
  class MixedPrecisionConjugateGradient : public LinearFunction<FieldD> {
-  public:
+  public:                                                
    using LinearFunction<FieldD>::operator();
    RealD   Tolerance;
    RealD   InnerTolerance; //Initial tolerance for inner CG. Defaults to Tolerance but can be changed
    Integer MaxInnerIterations;
@@ -49,7 +48,6 @@ NAMESPACE_BEGIN(Grid);
    Integer TotalInnerIterations; //Number of inner CG iterations
    Integer TotalOuterIterations; //Number of restarts
    Integer TotalFinalStepIterations; //Number of CG iterations in final patch-up step
    RealD TrueResidual;
    //Option to speed up *inner single precision* solves using a LinearFunction that produces a guess
    LinearFunction<FieldF> *guesser;
@@ -69,7 +67,6 @@ NAMESPACE_BEGIN(Grid);
    }
  void operator() (const FieldD &src_d_in, FieldD &sol_d){
    std::cout << GridLogMessage << "MixedPrecisionConjugateGradient: Starting mixed precision CG with outer tolerance " << Tolerance << " and inner tolerance " << InnerTolerance << std::endl;
    TotalInnerIterations = 0;
    GridStopWatch TotalTimer;
@@ -99,7 +96,6 @@ NAMESPACE_BEGIN(Grid);
    FieldF sol_f(SinglePrecGrid);
    sol_f.Checkerboard() = cb;
    std::cout<<GridLogMessage<<"MixedPrecisionConjugateGradient: Starting initial inner CG with tolerance " << inner_tol << std::endl;
    ConjugateGradient<FieldF> CG_f(inner_tol, MaxInnerIterations);
    CG_f.ErrorOnNoConverge = false;
@@ -108,10 +104,7 @@ NAMESPACE_BEGIN(Grid);
    GridStopWatch PrecChangeTimer;
    Integer &outer_iter = TotalOuterIterations; //so it will be equal to the final iteration count
-
+      
    precisionChangeWorkspace pc_wk_sp_to_dp(DoublePrecGrid, SinglePrecGrid);
    precisionChangeWorkspace pc_wk_dp_to_sp(SinglePrecGrid, DoublePrecGrid);
    for(outer_iter = 0; outer_iter < MaxOuterIterations; outer_iter++){
      //Compute double precision rsd and also new RHS vector.
      Linop_d.HermOp(sol_d, tmp_d);
@@ -126,7 +119,7 @@ NAMESPACE_BEGIN(Grid);
      while(norm * inner_tol * inner_tol < stop) inner_tol *= 2;  // inner_tol = sqrt(stop/norm) ??
      PrecChangeTimer.Start();
-      precisionChange(src_f, src_d, pc_wk_dp_to_sp);
+      precisionChange(src_f, src_d);
      PrecChangeTimer.Stop();
      sol_f = Zero();
@@ -136,7 +129,6 @@ NAMESPACE_BEGIN(Grid);
 	(*guesser)(src_f, sol_f);
      //Inner CG
      std::cout<<GridLogMessage<<"MixedPrecisionConjugateGradient: Outer iteration " << outer_iter << " starting inner CG with tolerance " << inner_tol << std::endl;
      CG_f.Tolerance = inner_tol;
      InnerCGtimer.Start();
      CG_f(Linop_f, src_f, sol_f);
@@ -145,7 +137,7 @@ NAMESPACE_BEGIN(Grid);
      //Convert sol back to double and add to double prec solution
      PrecChangeTimer.Start();
-      precisionChange(tmp_d, sol_f, pc_wk_sp_to_dp);
+      precisionChange(tmp_d, sol_f);
      PrecChangeTimer.Stop();
      axpy(sol_d, 1.0, tmp_d, sol_d);
@@ -157,7 +149,6 @@ NAMESPACE_BEGIN(Grid);
    ConjugateGradient<FieldD> CG_d(Tolerance, MaxInnerIterations);
    CG_d(Linop_d, src_d_in, sol_d);
    TotalFinalStepIterations = CG_d.IterationsToComplete;
    TrueResidual = CG_d.TrueResidual;
    TotalTimer.Stop();
    std::cout<<GridLogMessage<<"MixedPrecisionConjugateGradient: Inner CG iterations " << TotalInnerIterations << " Restarts " << TotalOuterIterations << " Final CG iterations " << TotalFinalStepIterations << std::endl;
--- a/Grid/algorithms/iterative/ConjugateGradientMixedPrecBatched.h
+++ b/Grid/algorithms/iterative/ConjugateGradientMixedPrecBatched.h
@@ -1,213 +0,0 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./lib/algorithms/iterative/ConjugateGradientMixedPrecBatched.h
    Copyright (C) 2015
    Author: Raoul Hodgson <raoul.hodgson@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 */
 #ifndef GRID_CONJUGATE_GRADIENT_MIXED_PREC_BATCHED_H
 #define GRID_CONJUGATE_GRADIENT_MIXED_PREC_BATCHED_H
 NAMESPACE_BEGIN(Grid);
 //Mixed precision restarted defect correction CG
 template<class FieldD,class FieldF, 
  typename std::enable_if< getPrecision<FieldD>::value == 2, int>::type = 0,
  typename std::enable_if< getPrecision<FieldF>::value == 1, int>::type = 0> 
 class MixedPrecisionConjugateGradientBatched : public LinearFunction<FieldD> {
 public:
  using LinearFunction<FieldD>::operator();
  RealD   Tolerance;
  RealD   InnerTolerance; //Initial tolerance for inner CG. Defaults to Tolerance but can be changed
  Integer MaxInnerIterations;
  Integer MaxOuterIterations;
  Integer MaxPatchupIterations;
  GridBase* SinglePrecGrid; //Grid for single-precision fields
  RealD OuterLoopNormMult; //Stop the outer loop and move to a final double prec solve when the residual is OuterLoopNormMult * Tolerance
  LinearOperatorBase<FieldF> &Linop_f;
  LinearOperatorBase<FieldD> &Linop_d;
  //Option to speed up *inner single precision* solves using a LinearFunction that produces a guess
  LinearFunction<FieldF> *guesser;
  bool updateResidual;
  MixedPrecisionConjugateGradientBatched(RealD tol, 
          Integer maxinnerit, 
          Integer maxouterit, 
          Integer maxpatchit,
          GridBase* _sp_grid, 
          LinearOperatorBase<FieldF> &_Linop_f, 
          LinearOperatorBase<FieldD> &_Linop_d,
          bool _updateResidual=true) :
    Linop_f(_Linop_f), Linop_d(_Linop_d),
    Tolerance(tol), InnerTolerance(tol), MaxInnerIterations(maxinnerit), MaxOuterIterations(maxouterit), MaxPatchupIterations(maxpatchit), SinglePrecGrid(_sp_grid),
    OuterLoopNormMult(100.), guesser(NULL), updateResidual(_updateResidual) { };
  void useGuesser(LinearFunction<FieldF> &g){
    guesser = &g;
  }
  void operator() (const FieldD &src_d_in, FieldD &sol_d){
    std::vector<FieldD> srcs_d_in{src_d_in};
    std::vector<FieldD> sols_d{sol_d};
    (*this)(srcs_d_in,sols_d);
    sol_d = sols_d[0];
  }
  void operator() (const std::vector<FieldD> &src_d_in, std::vector<FieldD> &sol_d){
    assert(src_d_in.size() == sol_d.size());
    int NBatch = src_d_in.size();
    std::cout << GridLogMessage << "NBatch = " << NBatch << std::endl;
    Integer TotalOuterIterations = 0; //Number of restarts
    std::vector<Integer> TotalInnerIterations(NBatch,0);     //Number of inner CG iterations
    std::vector<Integer> TotalFinalStepIterations(NBatch,0); //Number of CG iterations in final patch-up step
    GridStopWatch TotalTimer;
    TotalTimer.Start();
    GridStopWatch InnerCGtimer;
    GridStopWatch PrecChangeTimer;
    int cb = src_d_in[0].Checkerboard();
    std::vector<RealD> src_norm;
    std::vector<RealD> norm;
    std::vector<RealD> stop;
    GridBase* DoublePrecGrid = src_d_in[0].Grid();
    FieldD tmp_d(DoublePrecGrid);
    tmp_d.Checkerboard() = cb;
    FieldD tmp2_d(DoublePrecGrid);
    tmp2_d.Checkerboard() = cb;
    std::vector<FieldD> src_d;
    std::vector<FieldF> src_f;
    std::vector<FieldF> sol_f;
    for (int i=0; i<NBatch; i++) {
      sol_d[i].Checkerboard() = cb;
      src_norm.push_back(norm2(src_d_in[i]));
      norm.push_back(0.);
      stop.push_back(src_norm[i] * Tolerance*Tolerance);
      src_d.push_back(src_d_in[i]); //source for next inner iteration, computed from residual during operation
      src_f.push_back(SinglePrecGrid);
      src_f[i].Checkerboard() = cb;
      sol_f.push_back(SinglePrecGrid);
      sol_f[i].Checkerboard() = cb;
    }
    RealD inner_tol = InnerTolerance;
    ConjugateGradient<FieldF> CG_f(inner_tol, MaxInnerIterations);
    CG_f.ErrorOnNoConverge = false;
    Integer &outer_iter = TotalOuterIterations; //so it will be equal to the final iteration count
    for(outer_iter = 0; outer_iter < MaxOuterIterations; outer_iter++){
      std::cout << GridLogMessage << std::endl;
      std::cout << GridLogMessage << "Outer iteration " << outer_iter << std::endl;
      bool allConverged = true;
      for (int i=0; i<NBatch; i++) {
        //Compute double precision rsd and also new RHS vector.
        Linop_d.HermOp(sol_d[i], tmp_d);
        norm[i] = axpy_norm(src_d[i], -1., tmp_d, src_d_in[i]); //src_d is residual vector
        std::cout<<GridLogMessage<<"MixedPrecisionConjugateGradientBatched: Outer iteration " << outer_iter <<" solve " << i << " residual "<< norm[i] << " target "<< stop[i] <<std::endl;
        PrecChangeTimer.Start();
        precisionChange(src_f[i], src_d[i]);
        PrecChangeTimer.Stop();
        sol_f[i] = Zero();
        if(norm[i] > OuterLoopNormMult * stop[i]) {
          allConverged = false;
        }
      }
      if (allConverged) break;
      if (updateResidual) {
        RealD normMax = *std::max_element(std::begin(norm), std::end(norm));
        RealD stopMax = *std::max_element(std::begin(stop), std::end(stop));
        while( normMax * inner_tol * inner_tol < stopMax) inner_tol *= 2;  // inner_tol = sqrt(stop/norm) ??
        CG_f.Tolerance = inner_tol;
      }
      //Optionally improve inner solver guess (eg using known eigenvectors)
      if(guesser != NULL) {
        (*guesser)(src_f, sol_f);
      }
      for (int i=0; i<NBatch; i++) {
        //Inner CG
        InnerCGtimer.Start();
        CG_f(Linop_f, src_f[i], sol_f[i]);
        InnerCGtimer.Stop();
        TotalInnerIterations[i] += CG_f.IterationsToComplete;
        //Convert sol back to double and add to double prec solution
        PrecChangeTimer.Start();
        precisionChange(tmp_d, sol_f[i]);
        PrecChangeTimer.Stop();
        axpy(sol_d[i], 1.0, tmp_d, sol_d[i]);
      }
    }
    //Final trial CG
    std::cout << GridLogMessage << std::endl;
    std::cout<<GridLogMessage<<"MixedPrecisionConjugateGradientBatched: Starting final patch-up double-precision solve"<<std::endl;
    for (int i=0; i<NBatch; i++) {
      ConjugateGradient<FieldD> CG_d(Tolerance, MaxPatchupIterations);
      CG_d(Linop_d, src_d_in[i], sol_d[i]);
      TotalFinalStepIterations[i] += CG_d.IterationsToComplete;
    }
    TotalTimer.Stop();
    std::cout << GridLogMessage << std::endl;
    for (int i=0; i<NBatch; i++) {
      std::cout<<GridLogMessage<<"MixedPrecisionConjugateGradientBatched: solve " << i << " Inner CG iterations " << TotalInnerIterations[i] << " Restarts " << TotalOuterIterations << " Final CG iterations " << TotalFinalStepIterations[i] << std::endl;
    }
    std::cout << GridLogMessage << std::endl;
    std::cout<<GridLogMessage<<"MixedPrecisionConjugateGradientBatched: Total time " << TotalTimer.Elapsed() << " Precision change " << PrecChangeTimer.Elapsed() << " Inner CG total " << InnerCGtimer.Elapsed() << std::endl;
  }
 };
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/algorithms/iterative/ConjugateGradientMultiShift.h
+++ b/Grid/algorithms/iterative/ConjugateGradientMultiShift.h
@@ -44,7 +44,7 @@ public:
  using OperatorFunction<Field>::operator();
-  //  RealD   Tolerance;
+  RealD   Tolerance;
  Integer MaxIterations;
  Integer IterationsToComplete; //Number of iterations the CG took to finish. Filled in upon completion
  std::vector<int> IterationsToCompleteShift;  // Iterations for this shift
@@ -52,7 +52,7 @@ public:
  MultiShiftFunction shifts;
  std::vector<RealD> TrueResidualShift;
-  ConjugateGradientMultiShift(Integer maxit, const MultiShiftFunction &_shifts) : 
+  ConjugateGradientMultiShift(Integer maxit,MultiShiftFunction &_shifts) : 
    MaxIterations(maxit),
    shifts(_shifts)
  { 
@@ -84,7 +84,6 @@ public:
  void operator() (LinearOperatorBase<Field> &Linop, const Field &src, std::vector<Field> &psi)
  {
    GRID_TRACE("ConjugateGradientMultiShift");
    GridBase *grid = src.Grid();
@@ -183,9 +182,6 @@ public:
    for(int s=0;s<nshift;s++) {
      axpby(psi[s],0.,-bs[s]*alpha[s],src,src);
    }
    std::cout << GridLogIterative << "ConjugateGradientMultiShift: initial rn (|src|^2) =" << rn << " qq (|MdagM src|^2) =" << qq << " d ( dot(src, [MdagM + m_0]src) ) =" << d << " c=" << c << std::endl;
  ///////////////////////////////////////
  // Timers
@@ -325,8 +321,8 @@ public:
      std::cout << GridLogMessage << "Time Breakdown "<<std::endl;
      std::cout << GridLogMessage << "\tElapsed    " << SolverTimer.Elapsed()     <<std::endl;
-      std::cout << GridLogMessage << "\tAXPY     " << AXPYTimer.Elapsed()     <<std::endl;
+      std::cout << GridLogMessage << "\tAXPY    " << AXPYTimer.Elapsed()     <<std::endl;
-      std::cout << GridLogMessage << "\tMatrix   " << MatrixTimer.Elapsed()     <<std::endl;
+      std::cout << GridLogMessage << "\tMarix    " << MatrixTimer.Elapsed()     <<std::endl;
      std::cout << GridLogMessage << "\tShift    " << ShiftTimer.Elapsed()     <<std::endl;
      IterationsToComplete = k;	
--- a/Grid/algorithms/iterative/ConjugateGradientMultiShiftCleanup.h
+++ b/Grid/algorithms/iterative/ConjugateGradientMultiShiftCleanup.h
@@ -1,373 +0,0 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./lib/algorithms/iterative/ConjugateGradientMultiShift.h
    Copyright (C) 2015
 Author: Azusa Yamaguchi <ayamaguc@staffmail.ed.ac.uk>
 Author: Peter Boyle <paboyle@ph.ed.ac.uk>
 Author: Christopher Kelly <ckelly@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);
 //CK 2020: A variant of the multi-shift conjugate gradient with the matrix multiplication in single precision. 
 //The residual is stored in single precision, but the search directions and solution are stored in double precision. 
 //Every update_freq iterations the residual is corrected in double precision. 
 //For safety the a final regular CG is applied to clean up if necessary
 //PB Pure single, then double fixup
 template<class FieldD, class FieldF,
 	 typename std::enable_if< getPrecision<FieldD>::value == 2, int>::type = 0,
 	 typename std::enable_if< getPrecision<FieldF>::value == 1, int>::type = 0> 
 class ConjugateGradientMultiShiftMixedPrecCleanup : public OperatorMultiFunction<FieldD>,
 					     public OperatorFunction<FieldD>
 {
 public:                                                
  using OperatorFunction<FieldD>::operator();
  RealD   Tolerance;
  Integer MaxIterationsMshift;
  Integer MaxIterations;
  Integer IterationsToComplete; //Number of iterations the CG took to finish. Filled in upon completion
  std::vector<int> IterationsToCompleteShift;  // Iterations for this shift
  int verbose;
  MultiShiftFunction shifts;
  std::vector<RealD> TrueResidualShift;
  int ReliableUpdateFreq; //number of iterations between reliable updates
  GridBase* SinglePrecGrid; //Grid for single-precision fields
  LinearOperatorBase<FieldF> &Linop_f; //single precision
  ConjugateGradientMultiShiftMixedPrecCleanup(Integer maxit, const MultiShiftFunction &_shifts,
 				       GridBase* _SinglePrecGrid, LinearOperatorBase<FieldF> &_Linop_f,
 				       int _ReliableUpdateFreq) : 
    MaxIterationsMshift(maxit),  shifts(_shifts), SinglePrecGrid(_SinglePrecGrid), Linop_f(_Linop_f), ReliableUpdateFreq(_ReliableUpdateFreq),
    MaxIterations(20000)
  { 
    verbose=1;
    IterationsToCompleteShift.resize(_shifts.order);
    TrueResidualShift.resize(_shifts.order);
  }
  void operator() (LinearOperatorBase<FieldD> &Linop, const FieldD &src, FieldD &psi)
  {
    GridBase *grid = src.Grid();
    int nshift = shifts.order;
    std::vector<FieldD> results(nshift,grid);
    (*this)(Linop,src,results,psi);
  }
  void operator() (LinearOperatorBase<FieldD> &Linop, const FieldD &src, std::vector<FieldD> &results, FieldD &psi)
  {
    int nshift = shifts.order;
    (*this)(Linop,src,results);
    psi = shifts.norm*src;
    for(int i=0;i<nshift;i++){
      psi = psi + shifts.residues[i]*results[i];
    }
    return;
  }
  void operator() (LinearOperatorBase<FieldD> &Linop_d, const FieldD &src_d, std::vector<FieldD> &psi_d)
  { 
    GRID_TRACE("ConjugateGradientMultiShiftMixedPrecCleanup");
    GridBase *DoublePrecGrid = src_d.Grid();
    ////////////////////////////////////////////////////////////////////////
    // Convenience references to the info stored in "MultiShiftFunction"
    ////////////////////////////////////////////////////////////////////////
    int nshift = shifts.order;
    std::vector<RealD> &mass(shifts.poles); // Make references to array in "shifts"
    std::vector<RealD> &mresidual(shifts.tolerances);
    std::vector<RealD> alpha(nshift,1.0);
    //Double precision search directions
    FieldD p_d(DoublePrecGrid);
    std::vector<FieldF> ps_f (nshift, SinglePrecGrid);// Search directions (single precision)
    std::vector<FieldF> psi_f(nshift, SinglePrecGrid);// solutions (single precision)
    FieldD tmp_d(DoublePrecGrid);
    FieldD r_d(DoublePrecGrid);
    FieldF r_f(SinglePrecGrid);
    FieldD mmp_d(DoublePrecGrid);
    assert(psi_d.size()==nshift);
    assert(mass.size()==nshift);
    assert(mresidual.size()==nshift);
    // dynamic sized arrays on stack; 2d is a pain with vector
    RealD  bs[nshift];
    RealD  rsq[nshift];
    RealD  rsqf[nshift];
    RealD  z[nshift][2];
    int     converged[nshift];
    const int       primary =0;
    //Primary shift fields CG iteration
    RealD a,b,c,d;
    RealD cp,bp,qq; //prev
    // Matrix mult fields
    FieldF p_f(SinglePrecGrid);
    FieldF mmp_f(SinglePrecGrid);
    // Check lightest mass
    for(int s=0;s<nshift;s++){
      assert( mass[s]>= mass[primary] );
      converged[s]=0;
    }
    // Wire guess to zero
    // Residuals "r" are src
    // First search direction "p" is also src
    cp = norm2(src_d);
    // Handle trivial case of zero src.
    if( cp == 0. ){
      for(int s=0;s<nshift;s++){
 	psi_d[s] = Zero();
 	psi_f[s] = Zero();
 	IterationsToCompleteShift[s] = 1;
 	TrueResidualShift[s] = 0.;
      }
      return;
    }
    for(int s=0;s<nshift;s++){
      rsq[s] = cp * mresidual[s] * mresidual[s];
      rsqf[s] =rsq[s];
      std::cout<<GridLogMessage<<"ConjugateGradientMultiShiftMixedPrecCleanup: shift "<< s <<" target resid "<<rsq[s]<<std::endl;
      //      ps_d[s] = src_d;
      precisionChange(ps_f[s],src_d);
    }
    // r and p for primary
    p_d = src_d; //primary copy --- make this a reference to ps_d to save axpys
    r_d = p_d;
    //MdagM+m[0]
    precisionChange(p_f,p_d);
    Linop_f.HermOpAndNorm(p_f,mmp_f,d,qq); // mmp = MdagM p        d=real(dot(p, mmp)),  qq=norm2(mmp)
    precisionChange(tmp_d,mmp_f);
    Linop_d.HermOpAndNorm(p_d,mmp_d,d,qq); // mmp = MdagM p        d=real(dot(p, mmp)),  qq=norm2(mmp)
    tmp_d = tmp_d - mmp_d;
    std::cout << " Testing operators match "<<norm2(mmp_d)<<" f "<<norm2(mmp_f)<<" diff "<< norm2(tmp_d)<<std::endl;
    //    assert(norm2(tmp_d)< 1.0e-4);
    axpy(mmp_d,mass[0],p_d,mmp_d);
    RealD rn = norm2(p_d);
    d += rn*mass[0];
    b = -cp /d;
    // Set up the various shift variables
    int       iz=0;
    z[0][1-iz] = 1.0;
    z[0][iz]   = 1.0;
    bs[0]      = b;
    for(int s=1;s<nshift;s++){
      z[s][1-iz] = 1.0;
      z[s][iz]   = 1.0/( 1.0 - b*(mass[s]-mass[0]));
      bs[s]      = b*z[s][iz]; 
    }
    // r += b[0] A.p[0]
    // c= norm(r)
    c=axpy_norm(r_d,b,mmp_d,r_d);
    for(int s=0;s<nshift;s++) {
      axpby(psi_d[s],0.,-bs[s]*alpha[s],src_d,src_d);
      precisionChange(psi_f[s],psi_d[s]);
    }
    ///////////////////////////////////////
    // Timers
    ///////////////////////////////////////
    GridStopWatch AXPYTimer, ShiftTimer, QRTimer, MatrixTimer, SolverTimer, PrecChangeTimer, CleanupTimer;
    SolverTimer.Start();
    // Iteration loop
    int k;
    for (k=1;k<=MaxIterationsMshift;k++){    
      a = c /cp;
      AXPYTimer.Start();
      axpy(p_d,a,p_d,r_d); 
      AXPYTimer.Stop();
      PrecChangeTimer.Start();
      precisionChange(r_f, r_d);
      PrecChangeTimer.Stop();
      AXPYTimer.Start();
      for(int s=0;s<nshift;s++){
 	if ( ! converged[s] ) { 
 	  if (s==0){
 	    axpy(ps_f[s],a,ps_f[s],r_f);
 	  } else{
 	    RealD as =a *z[s][iz]*bs[s] /(z[s][1-iz]*b);
 	    axpby(ps_f[s],z[s][iz],as,r_f,ps_f[s]);
 	  }
 	}
      }
      AXPYTimer.Stop();
      cp=c;
      PrecChangeTimer.Start();
      precisionChange(p_f, p_d); //get back single prec search direction for linop
      PrecChangeTimer.Stop();
      MatrixTimer.Start();  
      Linop_f.HermOp(p_f,mmp_f);
      MatrixTimer.Stop();  
      PrecChangeTimer.Start();
      precisionChange(mmp_d, mmp_f); // From Float to Double
      PrecChangeTimer.Stop();
      d=real(innerProduct(p_d,mmp_d));    
      axpy(mmp_d,mass[0],p_d,mmp_d);
      RealD rn = norm2(p_d);
      d += rn*mass[0];
      bp=b;
      b=-cp/d;
      // Toggle the recurrence history
      bs[0] = b;
      iz = 1-iz;
      ShiftTimer.Start();
      for(int s=1;s<nshift;s++){
 	if((!converged[s])){
 	  RealD z0 = z[s][1-iz];
 	  RealD z1 = z[s][iz];
 	  z[s][iz] = z0*z1*bp
 	    / (b*a*(z1-z0) + z1*bp*(1- (mass[s]-mass[0])*b)); 
 	  bs[s] = b*z[s][iz]/z0; // NB sign  rel to Mike
 	}
      }
      ShiftTimer.Stop();
      //Update single precision solutions
      AXPYTimer.Start();
      for(int s=0;s<nshift;s++){
 	int ss = s;
 	if( (!converged[s]) ) { 
 	  axpy(psi_f[ss],-bs[s]*alpha[s],ps_f[s],psi_f[ss]);
 	}
      }
      c = axpy_norm(r_d,b,mmp_d,r_d);
      AXPYTimer.Stop();
      // Convergence checks
      int all_converged = 1;
      for(int s=0;s<nshift;s++){
 	if ( (!converged[s]) ){
 	  IterationsToCompleteShift[s] = k;
 	  RealD css  = c * z[s][iz]* z[s][iz];
 	  if(css<rsqf[s]){
 	    if ( ! converged[s] )
 	      std::cout<<GridLogMessage<<"ConjugateGradientMultiShiftMixedPrecCleanup k="<<k<<" Shift "<<s<<" has converged"<<std::endl;
 	    converged[s]=1;
 	  } else {
 	    all_converged=0;
 	  }
 	}
      }
      if ( all_converged || k == MaxIterationsMshift-1){
 	SolverTimer.Stop();
 	for(int s=0;s<nshift;s++){
 	  precisionChange(psi_d[s],psi_f[s]);
 	}
 	if ( all_converged ){
 	  std::cout<<GridLogMessage<< "ConjugateGradientMultiShiftMixedPrecCleanup: All shifts have converged iteration "<<k<<std::endl;
 	  std::cout<<GridLogMessage<< "ConjugateGradientMultiShiftMixedPrecCleanup: Checking solutions"<<std::endl;
 	} else {
 	  std::cout<<GridLogMessage<< "ConjugateGradientMultiShiftMixedPrecCleanup: Not all shifts have converged iteration "<<k<<std::endl;
 	}
 	// Check answers 
 	for(int s=0; s < nshift; s++) { 
 	  Linop_d.HermOpAndNorm(psi_d[s],mmp_d,d,qq);
 	  axpy(tmp_d,mass[s],psi_d[s],mmp_d);
 	  axpy(r_d,-alpha[s],src_d,tmp_d);
 	  RealD rn = norm2(r_d);
 	  RealD cn = norm2(src_d);
 	  TrueResidualShift[s] = std::sqrt(rn/cn);
 	  std::cout<<GridLogMessage<<"ConjugateGradientMultiShiftMixedPrecCleanup: shift["<<s<<"] true residual "<< TrueResidualShift[s] << " target " << mresidual[s] << std::endl;
 	  //If we have not reached the desired tolerance, do a (mixed precision) CG cleanup
 	  if(rn >= rsq[s]){
 	    CleanupTimer.Start();
 	    std::cout<<GridLogMessage<<"ConjugateGradientMultiShiftMixedPrecCleanup: performing cleanup step for shift " << s << std::endl;
 	    //Setup linear operators for final cleanup
 	    ConjugateGradientMultiShiftMixedPrecSupport::ShiftedLinop<FieldD> Linop_shift_d(Linop_d, mass[s]);
 	    ConjugateGradientMultiShiftMixedPrecSupport::ShiftedLinop<FieldF> Linop_shift_f(Linop_f, mass[s]);
 	    MixedPrecisionConjugateGradient<FieldD,FieldF> cg(mresidual[s], MaxIterations, MaxIterations, SinglePrecGrid, Linop_shift_f, Linop_shift_d); 
 	    cg(src_d, psi_d[s]);
 	    TrueResidualShift[s] = cg.TrueResidual;
 	    CleanupTimer.Stop();
 	  }
 	}
 	std::cout << GridLogMessage << "ConjugateGradientMultiShiftMixedPrecCleanup: Time Breakdown for body"<<std::endl;
 	std::cout << GridLogMessage << "\tSolver    " << SolverTimer.Elapsed()     <<std::endl;
 	std::cout << GridLogMessage << "\t\tAXPY    " << AXPYTimer.Elapsed()     <<std::endl;
 	std::cout << GridLogMessage << "\t\tMatrix    " << MatrixTimer.Elapsed()     <<std::endl;
 	std::cout << GridLogMessage << "\t\tShift    " << ShiftTimer.Elapsed()     <<std::endl;
 	std::cout << GridLogMessage << "\t\tPrecision Change " << PrecChangeTimer.Elapsed()     <<std::endl;
 	std::cout << GridLogMessage << "\tFinal Cleanup " << CleanupTimer.Elapsed()     <<std::endl;
 	std::cout << GridLogMessage << "\tSolver+Cleanup " << SolverTimer.Elapsed() + CleanupTimer.Elapsed() << std::endl;
 	IterationsToComplete = k;	
 	return;
      }
    }
    std::cout<<GridLogMessage<<"CG multi shift did not converge"<<std::endl;
    assert(0);
  }
 };
 NAMESPACE_END(Grid);
--- a/Grid/algorithms/iterative/ConjugateGradientMultiShiftMixedPrec.h
+++ b/Grid/algorithms/iterative/ConjugateGradientMultiShiftMixedPrec.h
@@ -1,416 +0,0 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./lib/algorithms/iterative/ConjugateGradientMultiShift.h
    Copyright (C) 2015
 Author: Azusa Yamaguchi <ayamaguc@staffmail.ed.ac.uk>
 Author: Peter Boyle <paboyle@ph.ed.ac.uk>
 Author: Christopher Kelly <ckelly@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 */
 #ifndef GRID_CONJUGATE_GRADIENT_MULTI_SHIFT_MIXEDPREC_H
 #define GRID_CONJUGATE_GRADIENT_MULTI_SHIFT_MIXEDPREC_H
 NAMESPACE_BEGIN(Grid);
 //CK 2020: A variant of the multi-shift conjugate gradient with the matrix multiplication in single precision. 
 //The residual is stored in single precision, but the search directions and solution are stored in double precision. 
 //Every update_freq iterations the residual is corrected in double precision. 
 //For safety the a final regular CG is applied to clean up if necessary
 //Linop to add shift to input linop, used in cleanup CG
 namespace ConjugateGradientMultiShiftMixedPrecSupport{
 template<typename Field>
 class ShiftedLinop: public LinearOperatorBase<Field>{
 public:
  LinearOperatorBase<Field> &linop_base;
  RealD shift;
  ShiftedLinop(LinearOperatorBase<Field> &_linop_base, RealD _shift): linop_base(_linop_base), shift(_shift){}
  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){ assert(0); }
  void AdjOp  (const Field &in, Field &out){ assert(0); }
  void HermOp(const Field &in, Field &out){
    linop_base.HermOp(in, out);
    axpy(out, shift, 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);
  }
 };
 };
 template<class FieldD, class FieldF,
 	 typename std::enable_if< getPrecision<FieldD>::value == 2, int>::type = 0,
 	 typename std::enable_if< getPrecision<FieldF>::value == 1, int>::type = 0> 
 class ConjugateGradientMultiShiftMixedPrec : public OperatorMultiFunction<FieldD>,
 					     public OperatorFunction<FieldD>
 {
 public:                                                
  using OperatorFunction<FieldD>::operator();
  RealD   Tolerance;
  Integer MaxIterationsMshift;
  Integer MaxIterations;
  Integer IterationsToComplete; //Number of iterations the CG took to finish. Filled in upon completion
  std::vector<int> IterationsToCompleteShift;  // Iterations for this shift
  int verbose;
  MultiShiftFunction shifts;
  std::vector<RealD> TrueResidualShift;
  int ReliableUpdateFreq; //number of iterations between reliable updates
  GridBase* SinglePrecGrid; //Grid for single-precision fields
  LinearOperatorBase<FieldF> &Linop_f; //single precision
  ConjugateGradientMultiShiftMixedPrec(Integer maxit, const MultiShiftFunction &_shifts,
 				       GridBase* _SinglePrecGrid, LinearOperatorBase<FieldF> &_Linop_f,
 				       int _ReliableUpdateFreq) : 
    MaxIterationsMshift(maxit),  shifts(_shifts), SinglePrecGrid(_SinglePrecGrid), Linop_f(_Linop_f), ReliableUpdateFreq(_ReliableUpdateFreq),
    MaxIterations(20000)
  { 
    verbose=1;
    IterationsToCompleteShift.resize(_shifts.order);
    TrueResidualShift.resize(_shifts.order);
  }
  void operator() (LinearOperatorBase<FieldD> &Linop, const FieldD &src, FieldD &psi)
  {
    GridBase *grid = src.Grid();
    int nshift = shifts.order;
    std::vector<FieldD> results(nshift,grid);
    (*this)(Linop,src,results,psi);
  }
  void operator() (LinearOperatorBase<FieldD> &Linop, const FieldD &src, std::vector<FieldD> &results, FieldD &psi)
  {
    int nshift = shifts.order;
    (*this)(Linop,src,results);
    psi = shifts.norm*src;
    for(int i=0;i<nshift;i++){
      psi = psi + shifts.residues[i]*results[i];
    }
    return;
  }
  void operator() (LinearOperatorBase<FieldD> &Linop_d, const FieldD &src_d, std::vector<FieldD> &psi_d)
  { 
    GRID_TRACE("ConjugateGradientMultiShiftMixedPrec");
    GridBase *DoublePrecGrid = src_d.Grid();
    precisionChangeWorkspace pc_wk_s_to_d(DoublePrecGrid,SinglePrecGrid);
    precisionChangeWorkspace pc_wk_d_to_s(SinglePrecGrid,DoublePrecGrid);
    ////////////////////////////////////////////////////////////////////////
    // Convenience references to the info stored in "MultiShiftFunction"
    ////////////////////////////////////////////////////////////////////////
    int nshift = shifts.order;
    std::vector<RealD> &mass(shifts.poles); // Make references to array in "shifts"
    std::vector<RealD> &mresidual(shifts.tolerances);
    std::vector<RealD> alpha(nshift,1.0);
    //Double precision search directions
    FieldD p_d(DoublePrecGrid);
    std::vector<FieldD> ps_d(nshift, DoublePrecGrid);// Search directions (double precision)
    FieldD tmp_d(DoublePrecGrid);
    FieldD r_d(DoublePrecGrid);
    FieldD mmp_d(DoublePrecGrid);
    assert(psi_d.size()==nshift);
    assert(mass.size()==nshift);
    assert(mresidual.size()==nshift);
    // dynamic sized arrays on stack; 2d is a pain with vector
    RealD  bs[nshift];
    RealD  rsq[nshift];
    RealD  rsqf[nshift];
    RealD  z[nshift][2];
    int     converged[nshift];
    const int       primary =0;
    //Primary shift fields CG iteration
    RealD a,b,c,d;
    RealD cp,bp,qq; //prev
    // Matrix mult fields
    FieldF p_f(SinglePrecGrid);
    FieldF mmp_f(SinglePrecGrid);
    // Check lightest mass
    for(int s=0;s<nshift;s++){
      assert( mass[s]>= mass[primary] );
      converged[s]=0;
    }
    // Wire guess to zero
    // Residuals "r" are src
    // First search direction "p" is also src
    cp = norm2(src_d);
    // Handle trivial case of zero src.
    if( cp == 0. ){
      for(int s=0;s<nshift;s++){
 	psi_d[s] = Zero();
 	IterationsToCompleteShift[s] = 1;
 	TrueResidualShift[s] = 0.;
      }
      return;
    }
    for(int s=0;s<nshift;s++){
      rsq[s] = cp * mresidual[s] * mresidual[s];
      rsqf[s] =rsq[s];
      std::cout<<GridLogMessage<<"ConjugateGradientMultiShiftMixedPrec: shift "<< s <<" target resid "<<rsq[s]<<std::endl;
      ps_d[s] = src_d;
    }
    // r and p for primary
    p_d = src_d; //primary copy --- make this a reference to ps_d to save axpys
    r_d = p_d;
    //MdagM+m[0]
    precisionChange(p_f, p_d, pc_wk_d_to_s);
    Linop_f.HermOpAndNorm(p_f,mmp_f,d,qq); // mmp = MdagM p        d=real(dot(p, mmp)),  qq=norm2(mmp)
    precisionChange(tmp_d, mmp_f, pc_wk_s_to_d);
    Linop_d.HermOpAndNorm(p_d,mmp_d,d,qq); // mmp = MdagM p        d=real(dot(p, mmp)),  qq=norm2(mmp)
    tmp_d = tmp_d - mmp_d;
    std::cout << " Testing operators match "<<norm2(mmp_d)<<" f "<<norm2(mmp_f)<<" diff "<< norm2(tmp_d)<<std::endl;
    assert(norm2(tmp_d)< 1.0);
    axpy(mmp_d,mass[0],p_d,mmp_d);
    RealD rn = norm2(p_d);
    d += rn*mass[0];
    b = -cp /d;
    // Set up the various shift variables
    int       iz=0;
    z[0][1-iz] = 1.0;
    z[0][iz]   = 1.0;
    bs[0]      = b;
    for(int s=1;s<nshift;s++){
      z[s][1-iz] = 1.0;
      z[s][iz]   = 1.0/( 1.0 - b*(mass[s]-mass[0]));
      bs[s]      = b*z[s][iz]; 
    }
    // r += b[0] A.p[0]
    // c= norm(r)
    c=axpy_norm(r_d,b,mmp_d,r_d);
    for(int s=0;s<nshift;s++) {
      axpby(psi_d[s],0.,-bs[s]*alpha[s],src_d,src_d);
    }
    ///////////////////////////////////////
    // Timers
    ///////////////////////////////////////
    GridStopWatch AXPYTimer, ShiftTimer, QRTimer, MatrixTimer, SolverTimer, PrecChangeTimer, CleanupTimer;
    SolverTimer.Start();
    // Iteration loop
    int k;
    for (k=1;k<=MaxIterationsMshift;k++){    
      a = c /cp;
      AXPYTimer.Start();
      axpy(p_d,a,p_d,r_d); 
      for(int s=0;s<nshift;s++){
 	if ( ! converged[s] ) { 
 	  if (s==0){
 	    axpy(ps_d[s],a,ps_d[s],r_d);
 	  } else{
 	    RealD as =a *z[s][iz]*bs[s] /(z[s][1-iz]*b);
 	    axpby(ps_d[s],z[s][iz],as,r_d,ps_d[s]);
 	  }
 	}
      }
      AXPYTimer.Stop();
      PrecChangeTimer.Start();
      precisionChange(p_f, p_d, pc_wk_d_to_s); //get back single prec search direction for linop
      PrecChangeTimer.Stop();
      cp=c;
      MatrixTimer.Start();  
      Linop_f.HermOp(p_f,mmp_f);
      MatrixTimer.Stop();  
      PrecChangeTimer.Start();
      precisionChange(mmp_d, mmp_f, pc_wk_s_to_d); // From Float to Double
      PrecChangeTimer.Stop();
      AXPYTimer.Start();
      d=real(innerProduct(p_d,mmp_d));    
      axpy(mmp_d,mass[0],p_d,mmp_d);
      AXPYTimer.Stop();
      RealD rn = norm2(p_d);
      d += rn*mass[0];
      bp=b;
      b=-cp/d;
      // Toggle the recurrence history
      bs[0] = b;
      iz = 1-iz;
      ShiftTimer.Start();
      for(int s=1;s<nshift;s++){
 	if((!converged[s])){
 	  RealD z0 = z[s][1-iz];
 	  RealD z1 = z[s][iz];
 	  z[s][iz] = z0*z1*bp
 	    / (b*a*(z1-z0) + z1*bp*(1- (mass[s]-mass[0])*b)); 
 	  bs[s] = b*z[s][iz]/z0; // NB sign  rel to Mike
 	}
      }
      ShiftTimer.Stop();
      //Update double precision solutions
      AXPYTimer.Start();
      for(int s=0;s<nshift;s++){
 	int ss = s;
 	if( (!converged[s]) ) { 
 	  axpy(psi_d[ss],-bs[s]*alpha[s],ps_d[s],psi_d[ss]);
 	}
      }
      //Perform reliable update if necessary; otherwise update residual from single-prec mmp
      c = axpy_norm(r_d,b,mmp_d,r_d);
      AXPYTimer.Stop();
      if(k % ReliableUpdateFreq == 0){
 	RealD c_old = c;
 	//Replace r with true residual
 	MatrixTimer.Start();  
 	Linop_d.HermOp(psi_d[0],mmp_d); 
 	MatrixTimer.Stop();  
 	AXPYTimer.Start();
 	axpy(mmp_d,mass[0],psi_d[0],mmp_d);
 	c = axpy_norm(r_d, -1.0, mmp_d, src_d);
 	AXPYTimer.Stop();
 	std::cout<<GridLogMessage<<"ConjugateGradientMultiShiftMixedPrec k="<<k<< ", replaced |r|^2 = "<<c_old <<" with |r|^2 = "<<c<<std::endl;
      }
      // Convergence checks
      int all_converged = 1;
      for(int s=0;s<nshift;s++){
 	if ( (!converged[s]) ){
 	  IterationsToCompleteShift[s] = k;
 	  RealD css  = c * z[s][iz]* z[s][iz];
 	  if(css<rsqf[s]){
 	    if ( ! converged[s] )
 	      std::cout<<GridLogMessage<<"ConjugateGradientMultiShiftMixedPrec k="<<k<<" Shift "<<s<<" has converged"<<std::endl;
 	    converged[s]=1;
 	  } else {
 	    all_converged=0;
 	  }
 	}
      }
      if ( all_converged || k == MaxIterationsMshift-1){
 	SolverTimer.Stop();
 	if ( all_converged ){
 	  std::cout<<GridLogMessage<< "ConjugateGradientMultiShiftMixedPrec: All shifts have converged iteration "<<k<<std::endl;
 	  std::cout<<GridLogMessage<< "ConjugateGradientMultiShiftMixedPrec: Checking solutions"<<std::endl;
 	} else {
 	  std::cout<<GridLogMessage<< "ConjugateGradientMultiShiftMixedPrec: Not all shifts have converged iteration "<<k<<std::endl;
 	}
 	// Check answers 
 	for(int s=0; s < nshift; s++) { 
 	  Linop_d.HermOpAndNorm(psi_d[s],mmp_d,d,qq);
 	  axpy(tmp_d,mass[s],psi_d[s],mmp_d);
 	  axpy(r_d,-alpha[s],src_d,tmp_d);
 	  RealD rn = norm2(r_d);
 	  RealD cn = norm2(src_d);
 	  TrueResidualShift[s] = std::sqrt(rn/cn);
 	  std::cout<<GridLogMessage<<"ConjugateGradientMultiShiftMixedPrec: shift["<<s<<"] true residual "<< TrueResidualShift[s] << " target " << mresidual[s] << std::endl;
 	  //If we have not reached the desired tolerance, do a (mixed precision) CG cleanup
 	  if(rn >= rsq[s]){
 	    CleanupTimer.Start();
 	    std::cout<<GridLogMessage<<"ConjugateGradientMultiShiftMixedPrec: performing cleanup step for shift " << s << std::endl;
 	    //Setup linear operators for final cleanup
 	    ConjugateGradientMultiShiftMixedPrecSupport::ShiftedLinop<FieldD> Linop_shift_d(Linop_d, mass[s]);
 	    ConjugateGradientMultiShiftMixedPrecSupport::ShiftedLinop<FieldF> Linop_shift_f(Linop_f, mass[s]);
 	    MixedPrecisionConjugateGradient<FieldD,FieldF> cg(mresidual[s], MaxIterations, MaxIterations, SinglePrecGrid, Linop_shift_f, Linop_shift_d); 
 	    cg(src_d, psi_d[s]);
 	    TrueResidualShift[s] = cg.TrueResidual;
 	    CleanupTimer.Stop();
 	  }
 	}
 	std::cout << GridLogMessage << "ConjugateGradientMultiShiftMixedPrec: Time Breakdown for body"<<std::endl;
 	std::cout << GridLogMessage << "\tSolver    " << SolverTimer.Elapsed()     <<std::endl;
 	std::cout << GridLogMessage << "\t\tAXPY    " << AXPYTimer.Elapsed()     <<std::endl;
 	std::cout << GridLogMessage << "\t\tMatrix    " << MatrixTimer.Elapsed()     <<std::endl;
 	std::cout << GridLogMessage << "\t\tShift    " << ShiftTimer.Elapsed()     <<std::endl;
 	std::cout << GridLogMessage << "\t\tPrecision Change " << PrecChangeTimer.Elapsed()     <<std::endl;
 	std::cout << GridLogMessage << "\tFinal Cleanup " << CleanupTimer.Elapsed()     <<std::endl;
 	std::cout << GridLogMessage << "\tSolver+Cleanup " << SolverTimer.Elapsed() + CleanupTimer.Elapsed() << std::endl;
 	IterationsToComplete = k;	
 	return;
      }
    }
    std::cout<<GridLogMessage<<"CG multi shift did not converge"<<std::endl;
    assert(0);
  }
 };
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/algorithms/iterative/ConjugateGradientReliableUpdate.h
+++ b/Grid/algorithms/iterative/ConjugateGradientReliableUpdate.h
@@ -48,7 +48,7 @@ public:
  LinearOperatorBase<FieldF> &Linop_f;
  LinearOperatorBase<FieldD> &Linop_d;
  GridBase* SinglePrecGrid;
-  RealD Delta; //reliable update parameter. A reliable update is performed when the residual drops by a factor of Delta relative to its value at the last update
+  RealD Delta; //reliable update parameter
  //Optional ability to switch to a different linear operator once the tolerance reaches a certain point. Useful for single/half -> single/single
  LinearOperatorBase<FieldF> *Linop_fallback;
@@ -65,9 +65,7 @@ public:
      ErrorOnNoConverge(err_on_no_conv),
      DoFinalCleanup(true),
      Linop_fallback(NULL)
-  {
+  {};
    assert(Delta > 0. && Delta < 1. && "Expect  0 < Delta < 1");
  };
  void setFallbackLinop(LinearOperatorBase<FieldF> &_Linop_fallback, const RealD _fallback_transition_tol){
    Linop_fallback = &_Linop_fallback;
@@ -75,7 +73,6 @@ public:
  }
  void operator()(const FieldD &src, FieldD &psi) {
    GRID_TRACE("ConjugateGradientReliableUpdate");
    LinearOperatorBase<FieldF> *Linop_f_use = &Linop_f;
    bool using_fallback = false;
@@ -118,12 +115,9 @@ public:
    }
    //Single prec initialization
    precisionChangeWorkspace pc_wk_sp_to_dp(src.Grid(), SinglePrecGrid);
    precisionChangeWorkspace pc_wk_dp_to_sp(SinglePrecGrid, src.Grid());
    FieldF r_f(SinglePrecGrid);
    r_f.Checkerboard() = r.Checkerboard();
-    precisionChange(r_f, r, pc_wk_dp_to_sp);
+    precisionChange(r_f, r);
    FieldF psi_f(r_f);
    psi_f = Zero();
@@ -139,8 +133,7 @@ public:
    GridStopWatch LinalgTimer;
    GridStopWatch MatrixTimer;
    GridStopWatch SolverTimer;
-    GridStopWatch PrecChangeTimer;
+
    SolverTimer.Start();
    int k = 0;
    int l = 0;
@@ -179,9 +172,7 @@ public:
      // Stopping condition
      if (cp <= rsq) {
 	//Although not written in the paper, I assume that I have to add on the final solution
-	PrecChangeTimer.Start();
+	precisionChange(mmp, psi_f);
 	precisionChange(mmp, psi_f, pc_wk_sp_to_dp);
 	PrecChangeTimer.Stop();
 	psi = psi + mmp;
@@ -202,10 +193,7 @@ public:
 	std::cout << GridLogMessage << "\tElapsed    " << SolverTimer.Elapsed() <<std::endl;
 	std::cout << GridLogMessage << "\tMatrix     " << MatrixTimer.Elapsed() <<std::endl;
 	std::cout << GridLogMessage << "\tLinalg     " << LinalgTimer.Elapsed() <<std::endl;
 	std::cout << GridLogMessage << "\tPrecChange " << PrecChangeTimer.Elapsed() <<std::endl;
 	std::cout << GridLogMessage << "\tPrecChange avg time " << PrecChangeTimer.Elapsed()/(2*l+1) <<std::endl;
 	IterationsToComplete = k;	
 	ReliableUpdatesPerformed = l;
@@ -225,21 +213,14 @@ public:
      else if(cp < Delta * MaxResidSinceLastRelUp) { //reliable update
 	std::cout << GridLogMessage << "ConjugateGradientReliableUpdate "
 		  << cp << "(residual) < " << Delta << "(Delta) * " << MaxResidSinceLastRelUp << "(MaxResidSinceLastRelUp) on iteration " << k << " : performing reliable update\n";
-	PrecChangeTimer.Start();
+	precisionChange(mmp, psi_f);
 	precisionChange(mmp, psi_f, pc_wk_sp_to_dp);
 	PrecChangeTimer.Stop();
 	psi = psi + mmp;
 	MatrixTimer.Start();
 	Linop_d.HermOpAndNorm(psi, mmp, d, qq);
 	MatrixTimer.Stop();
 	r = src - mmp;
 	psi_f = Zero();
-	PrecChangeTimer.Start();
+	precisionChange(r_f, r);
 	precisionChange(r_f, r, pc_wk_dp_to_sp);
 	PrecChangeTimer.Stop();
 	cp = norm2(r);
 	MaxResidSinceLastRelUp = cp;
--- a/Grid/algorithms/iterative/Deflation.h
+++ b/Grid/algorithms/iterative/Deflation.h
@@ -33,19 +33,16 @@ namespace Grid {
 template<class Field>
 class ZeroGuesser: public LinearFunction<Field> {
 public:
  using LinearFunction<Field>::operator();
    virtual void operator()(const Field &src, Field &guess) { guess = Zero(); };
 };
 template<class Field>
 class DoNothingGuesser: public LinearFunction<Field> {
 public:
  using LinearFunction<Field>::operator();
  virtual void operator()(const Field &src, Field &guess) {  };
 };
 template<class Field>
 class SourceGuesser: public LinearFunction<Field> {
 public:
  using LinearFunction<Field>::operator();
  virtual void operator()(const Field &src, Field &guess) { guess = src; };
 };
@@ -57,24 +54,15 @@ class DeflatedGuesser: public LinearFunction<Field> {
 private:
  const std::vector<Field> &evec;
  const std::vector<RealD> &eval;
  const unsigned int       N;
 public:
  using LinearFunction<Field>::operator();
-  DeflatedGuesser(const std::vector<Field> & _evec,const std::vector<RealD> & _eval)
+  DeflatedGuesser(const std::vector<Field> & _evec,const std::vector<RealD> & _eval) : evec(_evec), eval(_eval) {};
  : DeflatedGuesser(_evec, _eval, _evec.size())
  {}
  DeflatedGuesser(const std::vector<Field> & _evec, const std::vector<RealD> & _eval, const unsigned int _N)
  : evec(_evec), eval(_eval), N(_N)
  {
    assert(evec.size()==eval.size());
    assert(N <= evec.size());
  } 
  virtual void operator()(const Field &src,Field &guess) {
    guess = Zero();
    assert(evec.size()==eval.size());
    auto N = evec.size();
    for (int i=0;i<N;i++) {
      const Field& tmp = evec[i];
      axpy(guess,TensorRemove(innerProduct(tmp,src)) / eval[i],tmp,guess);
@@ -91,7 +79,6 @@ private:
  const std::vector<RealD>       &eval_coarse;
 public:
  using LinearFunction<FineField>::operator();
  LocalCoherenceDeflatedGuesser(const std::vector<FineField>   &_subspace,
 				const std::vector<CoarseField> &_evec_coarse,
 				const std::vector<RealD>       &_eval_coarse)
@@ -113,43 +100,7 @@ public:
    blockPromote(guess_coarse,guess,subspace);
    guess.Checkerboard() = src.Checkerboard();
  };
-
+};
  void operator()(const std::vector<FineField> &src,std::vector<FineField> &guess) {
    int Nevec = (int)evec_coarse.size();
    int Nsrc = (int)src.size();
    // make temp variables
    std::vector<CoarseField> src_coarse(Nsrc,evec_coarse[0].Grid());
    std::vector<CoarseField> guess_coarse(Nsrc,evec_coarse[0].Grid());    
    //Preporcessing
    std::cout << GridLogMessage << "Start BlockProject for loop" << std::endl;
    for (int j=0;j<Nsrc;j++)
    {
    guess_coarse[j] = Zero();
    std::cout << GridLogMessage << "BlockProject iter: " << j << std::endl;
    blockProject(src_coarse[j],src[j],subspace);
    }
    //deflation set up for eigen vector batchsize 1 and source batch size equal number of sources
    std::cout << GridLogMessage << "Start ProjectAccum for loop" << std::endl;
    for (int i=0;i<Nevec;i++)
    {
      std::cout << GridLogMessage << "ProjectAccum Nvec: " << i << std::endl;
      const CoarseField & tmp = evec_coarse[i];
      for (int j=0;j<Nsrc;j++)
      {
        axpy(guess_coarse[j],TensorRemove(innerProduct(tmp,src_coarse[j])) / eval_coarse[i],tmp,guess_coarse[j]);
      }
    }
    //postprocessing
    std::cout << GridLogMessage << "Start BlockPromote for loop" << std::endl;
    for (int j=0;j<Nsrc;j++)
    {
    std::cout << GridLogMessage << "BlockProject iter: " << j << std::endl;
    blockPromote(guess_coarse[j],guess[j],subspace);
    guess[j].Checkerboard() = src[j].Checkerboard();
    }
  };
  };
--- a/Grid/algorithms/iterative/ImplicitlyRestartedBlockLanczos.h
+++ b/Grid/algorithms/iterative/ImplicitlyRestartedBlockLanczos.h
--- a/Grid/algorithms/iterative/ImplicitlyRestartedLanczos.h
+++ b/Grid/algorithms/iterative/ImplicitlyRestartedLanczos.h
@@ -419,15 +419,14 @@ until convergence
 	}
      }
-      if ( Nconv < Nstop ) {
+      if ( Nconv < Nstop )
 	std::cout << GridLogIRL << "Nconv ("<<Nconv<<") < Nstop ("<<Nstop<<")"<<std::endl;
-	std::cout << GridLogIRL << "returning Nstop vectors, the last "<< Nstop-Nconv << "of which might meet convergence criterion only approximately" <<std::endl;
+
      }
      eval=eval2;
      //Keep only converged
-      eval.resize(Nstop);// was Nconv
+      eval.resize(Nconv);// Nstop?
-      evec.resize(Nstop,grid);// was Nconv
+      evec.resize(Nconv,grid);// Nstop?
      basisSortInPlace(evec,eval,reverse);
    }
--- a/Grid/algorithms/iterative/LocalCoherenceLanczos.h
+++ b/Grid/algorithms/iterative/LocalCoherenceLanczos.h
@@ -44,7 +44,6 @@ public:
 				  int, MinRes);    // Must restart
 };
 //This class is the input parameter class for some testing programs
 struct LocalCoherenceLanczosParams : Serializable {
 public:
  GRID_SERIALIZABLE_CLASS_MEMBERS(LocalCoherenceLanczosParams,
@@ -68,7 +67,6 @@ public:
 template<class Fobj,class CComplex,int nbasis>
 class ProjectedHermOp : public LinearFunction<Lattice<iVector<CComplex,nbasis > > > {
 public:
  using LinearFunction<Lattice<iVector<CComplex,nbasis > > >::operator();
  typedef iVector<CComplex,nbasis >           CoarseSiteVector;
  typedef Lattice<CoarseSiteVector>           CoarseField;
  typedef Lattice<CComplex>   CoarseScalar; // used for inner products on fine field
@@ -99,7 +97,6 @@ public:
 template<class Fobj,class CComplex,int nbasis>
 class ProjectedFunctionHermOp : public LinearFunction<Lattice<iVector<CComplex,nbasis > > > {
 public:
  using LinearFunction<Lattice<iVector<CComplex,nbasis > > >::operator();
  typedef iVector<CComplex,nbasis >           CoarseSiteVector;
  typedef Lattice<CoarseSiteVector>           CoarseField;
  typedef Lattice<CComplex>   CoarseScalar; // used for inner products on fine field
@@ -146,24 +143,16 @@ public:
  LinearOperatorBase<FineField> &_Linop;
  RealD                             _coarse_relax_tol;
  std::vector<FineField>        &_subspace;
  int _largestEvalIdxForReport; //The convergence of the LCL is based on the evals of the coarse grid operator, not those of the underlying fine grid operator
                                //As a result we do not know what the eval range of the fine operator is until the very end, making tuning the Cheby bounds very difficult
                                //To work around this issue, every restart we separately reconstruct the fine operator eval for the lowest and highest evec and print these
                                //out alongside the evals of the coarse operator. To do so we need to know the index of the largest eval (i.e. Nstop-1)
                                //NOTE: If largestEvalIdxForReport=-1 (default) then this is not performed
  ImplicitlyRestartedLanczosSmoothedTester(LinearFunction<CoarseField>   &Poly,
 					   OperatorFunction<FineField>   &smoother,
 					   LinearOperatorBase<FineField> &Linop,
 					   std::vector<FineField>        &subspace,
-					   RealD coarse_relax_tol=5.0e3,
+					   RealD coarse_relax_tol=5.0e3) 
 					   int largestEvalIdxForReport=-1) 
    : _smoother(smoother), _Linop(Linop), _Poly(Poly), _subspace(subspace),
-      _coarse_relax_tol(coarse_relax_tol), _largestEvalIdxForReport(largestEvalIdxForReport)
+      _coarse_relax_tol(coarse_relax_tol)  
  {    };
  //evalMaxApprox: approximation of largest eval of the fine Chebyshev operator (suitably wrapped by block projection)
  int TestConvergence(int j,RealD eresid,CoarseField &B, RealD &eval,RealD evalMaxApprox)
  {
    CoarseField v(B);
@@ -186,26 +175,12 @@ public:
 	     <<" |H B[i] - eval[i]B[i]|^2 / evalMaxApprox^2 " << std::setw(25) << vv
 	     <<std::endl;
    if(_largestEvalIdxForReport != -1 && (j==0 || j==_largestEvalIdxForReport)){
      std::cout<<GridLogIRL << "Estimating true eval of fine grid operator for eval idx " << j << std::endl;
      RealD tmp_eval;
      ReconstructEval(j,eresid,B,tmp_eval,1.0); //don't use evalMaxApprox of coarse operator! (cf below)
    }
    int conv=0;
    if( (vv<eresid*eresid) ) conv = 1;
    return conv;
  }
-
+  int ReconstructEval(int j,RealD eresid,CoarseField &B, RealD &eval,RealD evalMaxApprox)
  //This function is called at the end of the coarse grid Lanczos. It promotes the coarse eigenvector 'B' to the fine grid,
  //applies a smoother to the result then computes the computes the *fine grid* eigenvalue (output as 'eval').
  //evalMaxApprox should be the approximation of the largest eval of the fine Hermop. However when this function is called by IRL it actually passes the largest eval of the *Chebyshev* operator (as this is the max approx used for the TestConvergence above)
  //As the largest eval of the Chebyshev is typically several orders of magnitude larger this makes the convergence test pass even when it should not.
  //We therefore ignore evalMaxApprox here and use a value of 1.0 (note this value is already used by TestCoarse)
  int ReconstructEval(int j,RealD eresid,CoarseField &B, RealD &eval,RealD evalMaxApprox)  
  {
    evalMaxApprox = 1.0; //cf above
    GridBase *FineGrid = _subspace[0].Grid();    
    int checkerboard   = _subspace[0].Checkerboard();
    FineField fB(FineGrid);fB.Checkerboard() =checkerboard;
@@ -224,13 +199,13 @@ public:
    eval   = vnum/vden;
    fv -= eval*fB;
    RealD vv = norm2(fv) / ::pow(evalMaxApprox,2.0);
-    if ( j > nbasis ) eresid = eresid*_coarse_relax_tol;
+
    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 << " target " << eresid*eresid
+	     <<" |H B[i] - eval[i]B[i]|^2 / evalMaxApprox^2 " << std::setw(25) << vv
 	     <<std::endl;
    if ( j > nbasis ) eresid = eresid*_coarse_relax_tol;
    if( (vv<eresid*eresid) ) return 1;
    return 0;
  }
@@ -308,10 +283,6 @@ public:
    evals_coarse.resize(0);
  };
  //The block inner product is the inner product on the fine grid locally summed over the blocks
  //to give a Lattice<Scalar> on the coarse grid. This function orthnormalizes the fine-grid subspace
  //vectors under the block inner product. This step must be performed after computing the fine grid
  //eigenvectors and before computing the coarse grid eigenvectors.    
  void Orthogonalise(void ) {
    CoarseScalar InnerProd(_CoarseGrid);
    std::cout << GridLogMessage <<" Gramm-Schmidt pass 1"<<std::endl;
@@ -355,8 +326,6 @@ public:
    }
  }
  //While this method serves to check the coarse eigenvectors, it also recomputes the eigenvalues from the smoothed reconstructed eigenvectors
  //hence the smoother can be tuned after running the coarse Lanczos by using a different smoother here
  void testCoarse(RealD resid,ChebyParams cheby_smooth,RealD relax) 
  {
    assert(evals_fine.size() == nbasis);
@@ -405,31 +374,25 @@ public:
    evals_fine.resize(nbasis);
    subspace.resize(nbasis,_FineGrid);
  }
  //cheby_op: Parameters of the fine grid Chebyshev polynomial used for the Lanczos acceleration
  //cheby_smooth: Parameters of a separate Chebyshev polynomial used after the Lanczos has completed to smooth out high frequency noise in the reconstructed fine grid eigenvectors prior to computing the eigenvalue
  //relax: Reconstructed eigenvectors (post smoothing) are naturally not as precise as true eigenvectors. This factor acts as a multiplier on the stopping condition when determining whether the results satisfy the user provided stopping condition
  void calcCoarse(ChebyParams cheby_op,ChebyParams cheby_smooth,RealD relax,
 		  int Nstop, int Nk, int Nm,RealD resid, 
 		  RealD MaxIt, RealD betastp, int MinRes)
  {
-    Chebyshev<FineField>                          Cheby(cheby_op); //Chebyshev of fine operator on fine grid
+    Chebyshev<FineField>                          Cheby(cheby_op);
-    ProjectedHermOp<Fobj,CComplex,nbasis>         Op(_FineOp,subspace); //Fine operator on coarse grid with intermediate fine grid conversion
+    ProjectedHermOp<Fobj,CComplex,nbasis>         Op(_FineOp,subspace);
-    ProjectedFunctionHermOp<Fobj,CComplex,nbasis> ChebyOp (Cheby,_FineOp,subspace); //Chebyshev of fine operator on coarse grid with intermediate fine grid conversion
+    ProjectedFunctionHermOp<Fobj,CComplex,nbasis> ChebyOp (Cheby,_FineOp,subspace);
    //////////////////////////////////////////////////////////////////////////////////////////////////
    // create a smoother and see if we can get a cheap convergence test and smooth inside the IRL
    //////////////////////////////////////////////////////////////////////////////////////////////////
-    Chebyshev<FineField>                                           ChebySmooth(cheby_smooth); //lower order Chebyshev of fine operator on fine grid used to smooth regenerated eigenvectors
+    Chebyshev<FineField>                                           ChebySmooth(cheby_smooth);
-    ImplicitlyRestartedLanczosSmoothedTester<Fobj,CComplex,nbasis> ChebySmoothTester(ChebyOp,ChebySmooth,_FineOp,subspace,relax,Nstop-1); 
+    ImplicitlyRestartedLanczosSmoothedTester<Fobj,CComplex,nbasis> ChebySmoothTester(ChebyOp,ChebySmooth,_FineOp,subspace,relax);
    evals_coarse.resize(Nm);
    evec_coarse.resize(Nm,_CoarseGrid);
    CoarseField src(_CoarseGrid);     src=1.0; 
    //Note the "tester" here is also responsible for generating the fine grid eigenvalues which are output into the "evals_coarse" array
    ImplicitlyRestartedLanczos<CoarseField> IRL(ChebyOp,ChebyOp,ChebySmoothTester,Nstop,Nk,Nm,resid,MaxIt,betastp,MinRes);
    int Nconv=0;
    IRL.calc(evals_coarse,evec_coarse,src,Nconv,false);
@@ -440,14 +403,6 @@ public:
      std::cout << i << " Coarse eval = " << evals_coarse[i]  << std::endl;
    }
  }
  //Get the fine eigenvector 'i' by reconstruction
  void getFineEvecEval(FineField &evec, RealD &eval, const int i) const{
    blockPromote(evec_coarse[i],evec,subspace);  
    eval = evals_coarse[i];
  }
 };
 NAMESPACE_END(Grid);
--- a/Grid/algorithms/iterative/PowerMethod.h
+++ b/Grid/algorithms/iterative/PowerMethod.h
@@ -29,8 +29,6 @@ template<class Field> class PowerMethod
      RealD vnum = real(innerProduct(src_n,tmp)); // HermOp. 
      RealD vden = norm2(src_n); 
      RealD na = vnum/vden; 
      std::cout << GridLogIterative << "PowerMethod: Current approximation of largest eigenvalue " << na << std::endl;
      if ( (fabs(evalMaxApprox/na - 1.0) < 0.001) || (i==_MAX_ITER_EST_-1) ) { 
 	evalMaxApprox = na; 
--- a/Grid/algorithms/iterative/PrecGeneralisedConjugateResidual.h
+++ b/Grid/algorithms/iterative/PrecGeneralisedConjugateResidual.h
@@ -43,7 +43,7 @@ NAMESPACE_BEGIN(Grid);
 template<class Field>
 class PrecGeneralisedConjugateResidual : public LinearFunction<Field> {
 public:                                                
-  using LinearFunction<Field>::operator();
+
  RealD   Tolerance;
  Integer MaxIterations;
  int verbose;
--- a/Grid/algorithms/iterative/PrecGeneralisedConjugateResidualNonHermitian.h
+++ b/Grid/algorithms/iterative/PrecGeneralisedConjugateResidualNonHermitian.h
@@ -43,7 +43,7 @@ NAMESPACE_BEGIN(Grid);
 template<class Field>
 class PrecGeneralisedConjugateResidualNonHermitian : public LinearFunction<Field> {
 public:                                                
-  using LinearFunction<Field>::operator();
+
  RealD   Tolerance;
  Integer MaxIterations;
  int verbose;
@@ -119,8 +119,7 @@ public:
  RealD GCRnStep(const Field &src, Field &psi,RealD rsq){
    RealD cp;
-    ComplexD a, b;
+    ComplexD a, b, zAz;
    //    ComplexD zAz;
    RealD zAAz;
    ComplexD rq;
@@ -147,7 +146,7 @@ public:
    //////////////////////////////////
    MatTimer.Start();
    Linop.Op(psi,Az);
-    //    zAz = innerProduct(Az,psi);
+    zAz = innerProduct(Az,psi);
    zAAz= norm2(Az);
    MatTimer.Stop();
@@ -171,7 +170,7 @@ public:
    LinalgTimer.Start();
-    //    zAz = innerProduct(Az,psi);
+    zAz = innerProduct(Az,psi);
    zAAz= norm2(Az);
    //p[0],q[0],qq[0] 
@@ -213,7 +212,7 @@ public:
      MatTimer.Start();
      Linop.Op(z,Az);
      MatTimer.Stop();
-      //      zAz = innerProduct(Az,psi);
+      zAz = innerProduct(Az,psi);
      zAAz= norm2(Az);
      LinalgTimer.Start();
--- a/Grid/algorithms/iterative/SchurRedBlack.h
+++ b/Grid/algorithms/iterative/SchurRedBlack.h
@@ -132,31 +132,6 @@ namespace Grid {
      (*this)(_Matrix,in,out,guess);
    }
    void RedBlackSource(Matrix &_Matrix, const std::vector<Field> &in, std::vector<Field> &src_o) 
    {
      GridBase *grid = _Matrix.RedBlackGrid();
      Field tmp(grid);
      int nblock = in.size();
      for(int b=0;b<nblock;b++){
 	RedBlackSource(_Matrix,in[b],tmp,src_o[b]);
      }
    }
    // James can write his own deflated guesser
    // with optimised code for the inner products
    //    RedBlackSolveSplitGrid();
    //    RedBlackSolve(_Matrix,src_o,sol_o); 
    void RedBlackSolution(Matrix &_Matrix, const std::vector<Field> &in, const std::vector<Field> &sol_o, std::vector<Field> &out)
    {
      GridBase *grid = _Matrix.RedBlackGrid();
      Field tmp(grid);
      int nblock = in.size();
      for(int b=0;b<nblock;b++) {
 	pickCheckerboard(Even,tmp,in[b]);
 	RedBlackSolution(_Matrix,sol_o[b],tmp,out[b]);
      }
    }
    template<class Guesser>
    void operator()(Matrix &_Matrix, const std::vector<Field> &in, std::vector<Field> &out,Guesser &guess) 
    {
@@ -175,29 +150,24 @@ namespace Grid {
      ////////////////////////////////////////////////
      // Prepare RedBlack source
      ////////////////////////////////////////////////
-      RedBlackSource(_Matrix,in,src_o);
+      for(int b=0;b<nblock;b++){
-	//      for(int b=0;b<nblock;b++){
+	RedBlackSource(_Matrix,in[b],tmp,src_o[b]);
-	//	RedBlackSource(_Matrix,in[b],tmp,src_o[b]);
+      }
 	//      }
      ////////////////////////////////////////////////
      // Make the guesses
      ////////////////////////////////////////////////
      if ( subGuess ) guess_save.resize(nblock,grid);
-      
+      for(int b=0;b<nblock;b++){
-      if(useSolnAsInitGuess) {
+        if(useSolnAsInitGuess) {
        for(int b=0;b<nblock;b++){
          pickCheckerboard(Odd, sol_o[b], out[b]);
        } else {
          guess(src_o[b],sol_o[b]); 
        }
      } else {
        guess(src_o, sol_o); 
      }
-	    if ( subGuess ) { 
+	if ( subGuess ) { 
-        for(int b=0;b<nblock;b++){
+	  guess_save[b] = sol_o[b];
-          guess_save[b] = sol_o[b];
+	}
        }
      }
      //////////////////////////////////////////////////////////////
      // Call the block solver
--- a/Grid/allocator/AlignedAllocator.h
+++ b/Grid/allocator/AlignedAllocator.h
@@ -173,10 +173,8 @@ template<class T> using cshiftAllocator = devAllocator<T>;
 template<class T> using cshiftAllocator = std::allocator<T>;
 #endif
-template<class T> using Vector        = std::vector<T,uvmAllocator<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 deviceVector  = std::vector<T,devAllocator<T> >;
 template<class T> using cshiftVector = std::vector<T,cshiftAllocator<T> >;
 NAMESPACE_END(Grid);
--- a/Grid/allocator/MemoryManager.cc
+++ b/Grid/allocator/MemoryManager.cc
@@ -4,156 +4,106 @@ NAMESPACE_BEGIN(Grid);
 /*Allocation types, saying which pointer cache should be used*/
 #define Cpu      (0)
-#define CpuHuge  (1)
+#define CpuSmall (1)
-#define CpuSmall (2)
+#define Acc      (2)
-#define Acc      (3)
+#define AccSmall (3)
-#define AccHuge  (4)
+#define Shared   (4)
-#define AccSmall (5)
+#define SharedSmall (5)
 #define Shared   (6)
 #define SharedHuge  (7)
 #define SharedSmall (8)
 #undef GRID_MM_VERBOSE 
 uint64_t total_shared;
 uint64_t total_device;
 uint64_t total_host;;
 void MemoryManager::PrintBytes(void)
 {
-  std::cout << " MemoryManager : ------------------------------------ "<<std::endl;
+  std::cout << " MemoryManager : "<<total_shared<<" shared      bytes "<<std::endl;
-  std::cout << " MemoryManager : PrintBytes "<<std::endl;
+  std::cout << " MemoryManager : "<<total_device<<" accelerator bytes "<<std::endl;
-  std::cout << " MemoryManager : ------------------------------------ "<<std::endl;
+  std::cout << " MemoryManager : "<<total_host  <<" cpu         bytes "<<std::endl;
  std::cout << " MemoryManager : "<<(total_shared>>20)<<" shared      Mbytes "<<std::endl;
  std::cout << " MemoryManager : "<<(total_device>>20)<<" accelerator Mbytes "<<std::endl;
  std::cout << " MemoryManager : "<<(total_host>>20)  <<" cpu         Mbytes "<<std::endl;
  uint64_t cacheBytes;
  cacheBytes = CacheBytes[Cpu];
  std::cout << " MemoryManager : "<<(cacheBytes>>20) <<" cpu cache Mbytes "<<std::endl;
  cacheBytes = CacheBytes[Acc];
  std::cout << " MemoryManager : "<<(cacheBytes>>20) <<" acc cache Mbytes "<<std::endl;
  cacheBytes = CacheBytes[Shared];
  std::cout << " MemoryManager : "<<(cacheBytes>>20) <<" shared cache Mbytes "<<std::endl;
 #ifdef GRID_CUDA
  cuda_mem();
 #endif
 }
 uint64_t MemoryManager::DeviceCacheBytes() { return CacheBytes[Acc] + CacheBytes[AccHuge] + CacheBytes[AccSmall]; }
 uint64_t MemoryManager::HostCacheBytes()   { return CacheBytes[Cpu] + CacheBytes[CpuHuge] + CacheBytes[CpuSmall]; }
 //////////////////////////////////////////////////////////////////////
 // Data tables for recently freed pooiniter caches
 //////////////////////////////////////////////////////////////////////
 MemoryManager::AllocationCacheEntry MemoryManager::Entries[MemoryManager::NallocType][MemoryManager::NallocCacheMax];
 int MemoryManager::Victim[MemoryManager::NallocType];
-int MemoryManager::Ncache[MemoryManager::NallocType] = { 2, 0, 8, 8, 0, 16, 8, 0, 16 };
+int MemoryManager::Ncache[MemoryManager::NallocType] = { 8, 32, 8, 32, 8, 32 };
-uint64_t MemoryManager::CacheBytes[MemoryManager::NallocType];
+
 //////////////////////////////////////////////////////////////////////
 // Actual allocation and deallocation utils
 //////////////////////////////////////////////////////////////////////
 void *MemoryManager::AcceleratorAllocate(size_t bytes)
 {
  total_device+=bytes;
  void *ptr = (void *) Lookup(bytes,Acc);
  if ( ptr == (void *) NULL ) {
    ptr = (void *) acceleratorAllocDevice(bytes);
    total_device+=bytes;
  }
 #ifdef GRID_MM_VERBOSE
  std::cout <<"AcceleratorAllocate "<<std::endl;
  PrintBytes();
 #endif
  return ptr;
 }
 void  MemoryManager::AcceleratorFree    (void *ptr,size_t bytes)
 {
  total_device-=bytes;
  void *__freeme = Insert(ptr,bytes,Acc);
  if ( __freeme ) {
    acceleratorFreeDevice(__freeme);
    total_device-=bytes;
    //    PrintBytes();
  }
 #ifdef GRID_MM_VERBOSE
  std::cout <<"AcceleratorFree "<<std::endl;
  PrintBytes();
 #endif
 }
 void *MemoryManager::SharedAllocate(size_t bytes)
 {
  total_shared+=bytes;
  void *ptr = (void *) Lookup(bytes,Shared);
  if ( ptr == (void *) NULL ) {
    ptr = (void *) acceleratorAllocShared(bytes);
    total_shared+=bytes;
    //    std::cout <<"AcceleratorAllocate: allocated Shared pointer "<<std::hex<<ptr<<std::dec<<std::endl;
    //    PrintBytes();
  }
 #ifdef GRID_MM_VERBOSE
  std::cout <<"SharedAllocate "<<std::endl;
  PrintBytes();
 #endif
  return ptr;
 }
 void  MemoryManager::SharedFree    (void *ptr,size_t bytes)
 {
  total_shared-=bytes;
  void *__freeme = Insert(ptr,bytes,Shared);
  if ( __freeme ) {
    acceleratorFreeShared(__freeme);
    total_shared-=bytes;
    //    PrintBytes();
  }
 #ifdef GRID_MM_VERBOSE
  std::cout <<"SharedFree "<<std::endl;
  PrintBytes();
 #endif
 }
 #ifdef GRID_UVM
 void *MemoryManager::CpuAllocate(size_t bytes)
 {
  total_host+=bytes;
  void *ptr = (void *) Lookup(bytes,Cpu);
  if ( ptr == (void *) NULL ) {
    ptr = (void *) acceleratorAllocShared(bytes);
    total_host+=bytes;
  }
 #ifdef GRID_MM_VERBOSE
  std::cout <<"CpuAllocate "<<std::endl;
  PrintBytes();
 #endif
  return ptr;
 }
 void  MemoryManager::CpuFree    (void *_ptr,size_t bytes)
 {
  total_host-=bytes;
  NotifyDeletion(_ptr);
  void *__freeme = Insert(_ptr,bytes,Cpu);
  if ( __freeme ) { 
    acceleratorFreeShared(__freeme);
    total_host-=bytes;
  }
 #ifdef GRID_MM_VERBOSE
  std::cout <<"CpuFree "<<std::endl;
  PrintBytes();
 #endif
 }
 #else
 void *MemoryManager::CpuAllocate(size_t bytes)
 {
  total_host+=bytes;
  void *ptr = (void *) Lookup(bytes,Cpu);
  if ( ptr == (void *) NULL ) {
    ptr = (void *) acceleratorAllocCpu(bytes);
    total_host+=bytes;
  }
 #ifdef GRID_MM_VERBOSE
  std::cout <<"CpuAllocate "<<std::endl;
  PrintBytes();
 #endif
  return ptr;
 }
 void  MemoryManager::CpuFree    (void *_ptr,size_t bytes)
 {
  total_host-=bytes;
  NotifyDeletion(_ptr);
  void *__freeme = Insert(_ptr,bytes,Cpu);
  if ( __freeme ) { 
    acceleratorFreeCpu(__freeme);
    total_host-=bytes;
  }
 #ifdef GRID_MM_VERBOSE
  std::cout <<"CpuFree "<<std::endl;
  PrintBytes();
 #endif
 }
 #endif
@@ -165,6 +115,7 @@ void MemoryManager::Init(void)
  char * str;
  int Nc;
  int NcS;
  str= getenv("GRID_ALLOC_NCACHE_LARGE");
  if ( str ) {
@@ -176,16 +127,6 @@ void MemoryManager::Init(void)
    }
  }
  str= getenv("GRID_ALLOC_NCACHE_HUGE");
  if ( str ) {
    Nc = atoi(str);
    if ( (Nc>=0) && (Nc < NallocCacheMax)) {
      Ncache[CpuHuge]=Nc;
      Ncache[AccHuge]=Nc;
      Ncache[SharedHuge]=Nc;
    }
  }
  str= getenv("GRID_ALLOC_NCACHE_SMALL");
  if ( str ) {
    Nc = atoi(str);
@@ -206,9 +147,7 @@ void MemoryManager::InitMessage(void) {
  std::cout << GridLogMessage<< "MemoryManager::Init() setting up"<<std::endl;
 #ifdef ALLOCATION_CACHE
-  std::cout << GridLogMessage<< "MemoryManager::Init() cache pool for recent host   allocations: SMALL "<<Ncache[CpuSmall]<<" LARGE "<<Ncache[Cpu]<<" HUGE "<<Ncache[CpuHuge]<<std::endl;
+  std::cout << GridLogMessage<< "MemoryManager::Init() cache pool for recent allocations: SMALL "<<Ncache[CpuSmall]<<" LARGE "<<Ncache[Cpu]<<std::endl;
  std::cout << GridLogMessage<< "MemoryManager::Init() cache pool for recent device allocations: SMALL "<<Ncache[AccSmall]<<" LARGE "<<Ncache[Acc]<<" Huge "<<Ncache[AccHuge]<<std::endl;
  std::cout << GridLogMessage<< "MemoryManager::Init() cache pool for recent shared allocations: SMALL "<<Ncache[SharedSmall]<<" LARGE "<<Ncache[Shared]<<" Huge "<<Ncache[SharedHuge]<<std::endl;
 #endif
 #ifdef GRID_UVM
@@ -240,25 +179,21 @@ void MemoryManager::InitMessage(void) {
 void *MemoryManager::Insert(void *ptr,size_t bytes,int type) 
 {
 #ifdef ALLOCATION_CACHE
-  int cache;
+  bool small = (bytes < GRID_ALLOC_SMALL_LIMIT);
-  if      (bytes < GRID_ALLOC_SMALL_LIMIT) cache = type + 2;
+  int cache = type + small;
-  else if (bytes >= GRID_ALLOC_HUGE_LIMIT) cache = type + 1;
+  return Insert(ptr,bytes,Entries[cache],Ncache[cache],Victim[cache]);  
  else                                     cache = type;
  return Insert(ptr,bytes,Entries[cache],Ncache[cache],Victim[cache],CacheBytes[cache]);  
 #else
  return ptr;
 #endif
 }
-void *MemoryManager::Insert(void *ptr,size_t bytes,AllocationCacheEntry *entries,int ncache,int &victim, uint64_t &cacheBytes) 
+void *MemoryManager::Insert(void *ptr,size_t bytes,AllocationCacheEntry *entries,int ncache,int &victim) 
 {
  assert(ncache>0);
 #ifdef GRID_OMP
  assert(omp_in_parallel()==0);
 #endif 
  if (ncache == 0) return ptr;
  void * ret = NULL;
  int v = -1;
@@ -276,7 +211,6 @@ void *MemoryManager::Insert(void *ptr,size_t bytes,AllocationCacheEntry *entries
  if ( entries[v].valid ) {
    ret = entries[v].address;
    cacheBytes -= entries[v].bytes;
    entries[v].valid = 0;
    entries[v].address = NULL;
    entries[v].bytes = 0;
@@ -285,7 +219,6 @@ void *MemoryManager::Insert(void *ptr,size_t bytes,AllocationCacheEntry *entries
  entries[v].address=ptr;
  entries[v].bytes  =bytes;
  entries[v].valid  =1;
  cacheBytes += bytes;
  return ret;
 }
@@ -293,26 +226,23 @@ void *MemoryManager::Insert(void *ptr,size_t bytes,AllocationCacheEntry *entries
 void *MemoryManager::Lookup(size_t bytes,int type)
 {
 #ifdef ALLOCATION_CACHE
-  int cache;
+  bool small = (bytes < GRID_ALLOC_SMALL_LIMIT);
-  if      (bytes < GRID_ALLOC_SMALL_LIMIT) cache = type + 2;
+  int cache = type+small;
-  else if (bytes >= GRID_ALLOC_HUGE_LIMIT) cache = type + 1;
+  return Lookup(bytes,Entries[cache],Ncache[cache]);
  else                                     cache = type;
  return Lookup(bytes,Entries[cache],Ncache[cache],CacheBytes[cache]);
 #else
  return NULL;
 #endif
 }
-void *MemoryManager::Lookup(size_t bytes,AllocationCacheEntry *entries,int ncache,uint64_t & cacheBytes) 
+void *MemoryManager::Lookup(size_t bytes,AllocationCacheEntry *entries,int ncache) 
 {
  assert(ncache>0);
 #ifdef GRID_OMP
  assert(omp_in_parallel()==0);
 #endif 
  for(int e=0;e<ncache;e++){
    if ( entries[e].valid && ( entries[e].bytes == bytes ) ) {
      entries[e].valid = 0;
      cacheBytes -= entries[e].bytes;
      return entries[e].address;
    }
  }
--- a/Grid/allocator/MemoryManager.h
+++ b/Grid/allocator/MemoryManager.h
@@ -34,13 +34,9 @@ NAMESPACE_BEGIN(Grid);
 // Move control to configure.ac and Config.h?
 #define ALLOCATION_CACHE
 #define GRID_ALLOC_ALIGN (2*1024*1024)
 #define GRID_ALLOC_SMALL_LIMIT (4096)
 #define GRID_ALLOC_HUGE_LIMIT  (2147483648)
 #define STRINGIFY(x) #x
 #define TOSTRING(x) STRINGIFY(x)
 #define FILE_LINE __FILE__ ":" TOSTRING(__LINE__)
 #define AUDIT(a) MemoryManager::Audit(FILE_LINE)
 /*Pinning pages is costly*/
 ////////////////////////////////////////////////////////////////////////////
@@ -71,21 +67,6 @@ enum ViewMode {
  CpuWriteDiscard = 0x10 // same for now
 };
 struct MemoryStatus {
  uint64_t     DeviceBytes;
  uint64_t     DeviceLRUBytes;
  uint64_t     DeviceMaxBytes;
  uint64_t     HostToDeviceBytes;
  uint64_t     DeviceToHostBytes;
  uint64_t     HostToDeviceXfer;
  uint64_t     DeviceToHostXfer;
  uint64_t     DeviceEvictions;
  uint64_t     DeviceDestroy;
  uint64_t     DeviceAllocCacheBytes;
  uint64_t     HostAllocCacheBytes;
 };
 class MemoryManager {
 private:
@@ -99,23 +80,21 @@ private:
  } AllocationCacheEntry;
  static const int NallocCacheMax=128; 
-  static const int NallocType=9;
+  static const int NallocType=6;
  static AllocationCacheEntry Entries[NallocType][NallocCacheMax];
  static int Victim[NallocType];
  static int Ncache[NallocType];
  static uint64_t CacheBytes[NallocType];
  /////////////////////////////////////////////////
  // Free pool
  /////////////////////////////////////////////////
  static void *Insert(void *ptr,size_t bytes,int type) ;
  static void *Lookup(size_t bytes,int type) ;
-  static void *Insert(void *ptr,size_t bytes,AllocationCacheEntry *entries,int ncache,int &victim,uint64_t &cbytes) ;
+  static void *Insert(void *ptr,size_t bytes,AllocationCacheEntry *entries,int ncache,int &victim) ;
-  static void *Lookup(size_t bytes,AllocationCacheEntry *entries,int ncache,uint64_t &cbytes) ;
+  static void *Lookup(size_t bytes,AllocationCacheEntry *entries,int ncache) ;
 public:
  static void PrintBytes(void);
-  static void Audit(std::string s);
+ public:
  static void Init(void);
  static void InitMessage(void);
  static void *AcceleratorAllocate(size_t bytes);
@@ -135,28 +114,7 @@ private:
  static uint64_t     DeviceToHostBytes;
  static uint64_t     HostToDeviceXfer;
  static uint64_t     DeviceToHostXfer;
-  static uint64_t     DeviceEvictions;
+ 
  static uint64_t     DeviceDestroy;
  static uint64_t     DeviceCacheBytes();
  static uint64_t     HostCacheBytes();
  static MemoryStatus GetFootprint(void) {
    MemoryStatus stat;
    stat.DeviceBytes       = DeviceBytes;
    stat.DeviceLRUBytes    = DeviceLRUBytes;
    stat.DeviceMaxBytes    = DeviceMaxBytes;
    stat.HostToDeviceBytes = HostToDeviceBytes;
    stat.DeviceToHostBytes = DeviceToHostBytes;
    stat.HostToDeviceXfer  = HostToDeviceXfer;
    stat.DeviceToHostXfer  = DeviceToHostXfer;
    stat.DeviceEvictions   = DeviceEvictions;
    stat.DeviceDestroy     = DeviceDestroy;
    stat.DeviceAllocCacheBytes = DeviceCacheBytes();
    stat.HostAllocCacheBytes   = HostCacheBytes();
    return stat;
  };
 private:
 #ifndef GRID_UVM
  //////////////////////////////////////////////////////////////////////
@@ -213,8 +171,6 @@ private:
 public:
  static void Print(void);
  static void PrintAll(void);
  static void PrintState( void* CpuPtr);
  static int   isOpen   (void* CpuPtr);
  static void  ViewClose(void* CpuPtr,ViewMode mode);
  static void *ViewOpen (void* CpuPtr,size_t bytes,ViewMode mode,ViewAdvise hint);
--- a/Grid/allocator/MemoryManagerCache.cc
+++ b/Grid/allocator/MemoryManagerCache.cc
@@ -1,16 +1,10 @@
 #include <Grid/GridCore.h>
 #ifndef GRID_UVM
 #warning "Using explicit device memory copies"
 NAMESPACE_BEGIN(Grid);
-
+#define dprintf(...)
 #define MAXLINE 512
 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(...) 
 ////////////////////////////////////////////////////////////
 // For caching copies of data on device
@@ -28,8 +22,6 @@ uint64_t  MemoryManager::HostToDeviceBytes;
 uint64_t  MemoryManager::DeviceToHostBytes;
 uint64_t  MemoryManager::HostToDeviceXfer;
 uint64_t  MemoryManager::DeviceToHostXfer;
 uint64_t  MemoryManager::DeviceEvictions;
 uint64_t  MemoryManager::DeviceDestroy;
 ////////////////////////////////////
 // Priority ordering for unlocked entries
@@ -111,17 +103,15 @@ 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(%llx) %llx\n",(uint64_t)AccCache.CpuPtr,(uint64_t)AccCache.AccPtr); 
  assert(AccCache.accLock==0);
  assert(AccCache.cpuLock==0);
  assert(AccCache.CpuPtr!=(uint64_t)NULL);
  if(AccCache.AccPtr) {
    AcceleratorFree((void *)AccCache.AccPtr,AccCache.bytes);
    DeviceDestroy++;
    DeviceBytes   -=AccCache.bytes;
    LRUremove(AccCache);
-    AccCache.AccPtr=(uint64_t) NULL;
+    //    dprintf("MemoryManager: Free(%llx) LRU %lld Total %lld\n",(uint64_t)AccCache.AccPtr,DeviceLRUBytes,DeviceBytes);  
    dprintf("MemoryManager: Free(%lx) LRU %ld Total %ld\n",(uint64_t)AccCache.AccPtr,DeviceLRUBytes,DeviceBytes);  
  }
  uint64_t CpuPtr = AccCache.CpuPtr;
  EntryErase(CpuPtr);
@@ -130,36 +120,26 @@ void MemoryManager::AccDiscard(AcceleratorViewEntry &AccCache)
 void MemoryManager::Evict(AcceleratorViewEntry &AccCache)
 {
  ///////////////////////////////////////////////////////////////////////////
-  // Make CPU consistent, remove from Accelerator, remove from LRU, LEAVE CPU only entry
+  // Make CPU consistent, remove from Accelerator, remove entry
-  // Cannot be acclocked. If allocated must be in LRU pool.
+  // Cannot be locked. If allocated must be in LRU pool.
  //
  // Nov 2022... Felix issue: Allocating two CpuPtrs, can have an entry in LRU-q with CPUlock.
  //                          and require to evict the AccPtr copy. Eviction was a mistake in CpuViewOpen
  //                          but there is a weakness where CpuLock entries are attempted for erase
  //                          Take these OUT LRU queue when CPU locked?
  //                          Cannot take out the table as cpuLock data is important.
  ///////////////////////////////////////////////////////////////////////////
  assert(AccCache.state!=Empty);
-  mprintf("MemoryManager: Evict cpu %lx acc %lx cpuLock %ld accLock %ld\n",
+  //  dprintf("MemoryManager: Evict(%llx) %llx\n",(uint64_t)AccCache.CpuPtr,(uint64_t)AccCache.AccPtr); 
-	  (uint64_t)AccCache.CpuPtr,(uint64_t)AccCache.AccPtr,
+  assert(AccCache.accLock==0);
-	  (uint64_t)AccCache.cpuLock,(uint64_t)AccCache.accLock); 
+  assert(AccCache.cpuLock==0);
  if (AccCache.accLock!=0) return;
  if (AccCache.cpuLock!=0) return;
  if(AccCache.state==AccDirty) {
    Flush(AccCache);
  }
  assert(AccCache.CpuPtr!=(uint64_t)NULL);
  if(AccCache.AccPtr) {
    AcceleratorFree((void *)AccCache.AccPtr,AccCache.bytes);
    LRUremove(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);  
+    LRUremove(AccCache);
    //    dprintf("MemoryManager: Free(%llx) footprint now %lld \n",(uint64_t)AccCache.AccPtr,DeviceBytes);  
  }
-  //  uint64_t CpuPtr = AccCache.CpuPtr;
+  uint64_t CpuPtr = AccCache.CpuPtr;
-  DeviceEvictions++;
+  EntryErase(CpuPtr);
  //  EntryErase(CpuPtr);
 }
 void MemoryManager::Flush(AcceleratorViewEntry &AccCache)
 {
@@ -169,7 +149,7 @@ 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);
+  //  dprintf("MemoryManager: Flush  %llx -> %llx\n",(uint64_t)AccCache.AccPtr,(uint64_t)AccCache.CpuPtr); fflush(stdout);
  DeviceToHostBytes+=AccCache.bytes;
  DeviceToHostXfer++;
  AccCache.state=Consistent;
@@ -184,7 +164,7 @@ 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);
+  //  dprintf("MemoryManager: Clone %llx <- %llx\n",(uint64_t)AccCache.AccPtr,(uint64_t)AccCache.CpuPtr); fflush(stdout);
  acceleratorCopyToDevice((void *)AccCache.CpuPtr,(void *)AccCache.AccPtr,AccCache.bytes);
  HostToDeviceBytes+=AccCache.bytes;
  HostToDeviceXfer++;
@@ -210,7 +190,6 @@ void MemoryManager::CpuDiscard(AcceleratorViewEntry &AccCache)
 void MemoryManager::ViewClose(void* Ptr,ViewMode mode)
 {
  if( (mode==AcceleratorRead)||(mode==AcceleratorWrite)||(mode==AcceleratorWriteDiscard) ){
    dprintf("AcceleratorViewClose %lx\n",(uint64_t)Ptr);
    AcceleratorViewClose((uint64_t)Ptr);
  } else if( (mode==CpuRead)||(mode==CpuWrite)){
    CpuViewClose((uint64_t)Ptr);
@@ -222,7 +201,6 @@ void *MemoryManager::ViewOpen(void* _CpuPtr,size_t bytes,ViewMode mode,ViewAdvis
 {
  uint64_t CpuPtr = (uint64_t)_CpuPtr;
  if( (mode==AcceleratorRead)||(mode==AcceleratorWrite)||(mode==AcceleratorWriteDiscard) ){
    dprintf("AcceleratorViewOpen %lx\n",(uint64_t)CpuPtr);
    return (void *) AcceleratorViewOpen(CpuPtr,bytes,mode,hint);
  } else if( (mode==CpuRead)||(mode==CpuWrite)){
    return (void *)CpuViewOpen(CpuPtr,bytes,mode,hint);
@@ -233,16 +211,13 @@ void *MemoryManager::ViewOpen(void* _CpuPtr,size_t bytes,ViewMode mode,ViewAdvis
 }
 void  MemoryManager::EvictVictims(uint64_t bytes)
 {
  assert(bytes<DeviceMaxBytes);
  while(bytes+DeviceLRUBytes > DeviceMaxBytes){
    if ( DeviceLRUBytes > 0){
      assert(LRU.size()>0);
-      uint64_t victim = LRU.back(); // From the LRU
+      uint64_t victim = LRU.back();
      auto AccCacheIterator = EntryLookup(victim);
      auto & AccCache = AccCacheIterator->second;
      Evict(AccCache);
    } else {
      return;
    }
  }
 }
@@ -252,25 +227,18 @@ uint64_t MemoryManager::AcceleratorViewOpen(uint64_t CpuPtr,size_t bytes,ViewMod
  // Find if present, otherwise get or force an empty
  ////////////////////////////////////////////////////////////////////////////
  if ( EntryPresent(CpuPtr)==0 ){
    EvictVictims(bytes);
    EntryCreate(CpuPtr,bytes,mode,hint);
  }
  auto AccCacheIterator = EntryLookup(CpuPtr);
  auto & AccCache = AccCacheIterator->second;
-  if (!AccCache.AccPtr) {
+  
    EvictVictims(bytes); 
  } 
  assert((mode==AcceleratorRead)||(mode==AcceleratorWrite)||(mode==AcceleratorWriteDiscard));
  assert(AccCache.cpuLock==0);  // Programming error
  if(AccCache.state!=Empty) {
    dprintf("ViewOpen found entry %lx %lx : %ld %ld accLock %ld\n",
 		    (uint64_t)AccCache.CpuPtr,
 		    (uint64_t)CpuPtr,
 		    (uint64_t)AccCache.bytes,
 	            (uint64_t)bytes,
 		    (uint64_t)AccCache.accLock);
    assert(AccCache.CpuPtr == CpuPtr);
    assert(AccCache.bytes  ==bytes);
  }
@@ -305,7 +273,6 @@ uint64_t MemoryManager::AcceleratorViewOpen(uint64_t CpuPtr,size_t bytes,ViewMod
      AccCache.state  = Consistent; // Empty + AccRead => Consistent
    }
    AccCache.accLock= 1;
    dprintf("Copied Empty entry into device accLock= %d\n",AccCache.accLock);
  } else if(AccCache.state==CpuDirty ){
    if(mode==AcceleratorWriteDiscard) {
      CpuDiscard(AccCache);
@@ -318,30 +285,28 @@ uint64_t MemoryManager::AcceleratorViewOpen(uint64_t CpuPtr,size_t bytes,ViewMod
      AccCache.state  = Consistent; // CpuDirty + AccRead => Consistent
    }
    AccCache.accLock++;
-    dprintf("CpuDirty entry into device ++accLock= %d\n",AccCache.accLock);
+    //    printf("Copied CpuDirty entry into device accLock %d\n",AccCache.accLock);
  } else if(AccCache.state==Consistent) {
    if((mode==AcceleratorWrite)||(mode==AcceleratorWriteDiscard))
      AccCache.state  = AccDirty;   // Consistent + AcceleratorWrite=> AccDirty
    else
      AccCache.state  = Consistent; // Consistent + AccRead => Consistent
    AccCache.accLock++;
-    dprintf("Consistent entry into device ++accLock= %d\n",AccCache.accLock);
+    //    printf("Consistent entry into device accLock %d\n",AccCache.accLock);
  } else if(AccCache.state==AccDirty) {
    if((mode==AcceleratorWrite)||(mode==AcceleratorWriteDiscard))
      AccCache.state  = AccDirty; // AccDirty + AcceleratorWrite=> AccDirty
    else
      AccCache.state  = AccDirty; // AccDirty + AccRead => AccDirty
    AccCache.accLock++;
-    dprintf("AccDirty entry ++accLock= %d\n",AccCache.accLock);
+    //    printf("AccDirty entry into device accLock %d\n",AccCache.accLock);
  } else {
    assert(0);
  }
-  assert(AccCache.accLock>0);
+  // If view is opened on device remove from LRU
  // If view is opened on device must remove from LRU
  if(AccCache.LRU_valid==1){
    // must possibly remove from LRU as now locked on GPU
    dprintf("AccCache entry removed from LRU \n");
    LRUremove(AccCache);
  }
@@ -362,12 +327,10 @@ void MemoryManager::AcceleratorViewClose(uint64_t CpuPtr)
  assert(AccCache.accLock>0);
  AccCache.accLock--;
  // Move to LRU queue if not locked and close on device
  if(AccCache.accLock==0) {
    dprintf("AccleratorViewClose %lx AccLock decremented to %ld move to LRU queue\n",(uint64_t)CpuPtr,(uint64_t)AccCache.accLock);
    LRUinsert(AccCache);
  } else {
    dprintf("AccleratorViewClose %lx AccLock decremented to %ld\n",(uint64_t)CpuPtr,(uint64_t)AccCache.accLock);
  }
 }
 void MemoryManager::CpuViewClose(uint64_t CpuPtr)
@@ -398,17 +361,13 @@ uint64_t MemoryManager::CpuViewOpen(uint64_t CpuPtr,size_t bytes,ViewMode mode,V
  // Find if present, otherwise get or force an empty
  ////////////////////////////////////////////////////////////////////////////
  if ( EntryPresent(CpuPtr)==0 ){
    EvictVictims(bytes);
    EntryCreate(CpuPtr,bytes,mode,transient);
  }
  auto AccCacheIterator = EntryLookup(CpuPtr);
  auto & AccCache = AccCacheIterator->second;
-
+  
  // CPU doesn't need to free space
  //  if (!AccCache.AccPtr) {
  //    EvictVictims(bytes);
  //  }
  assert((mode==CpuRead)||(mode==CpuWrite));
  assert(AccCache.accLock==0);  // Programming error
@@ -460,29 +419,20 @@ void  MemoryManager::NotifyDeletion(void *_ptr)
 }
 void  MemoryManager::Print(void)
 {
-  PrintBytes();
+  std::cout << GridLogDebug << "--------------------------------------------" << std::endl;
-  std::cout << GridLogMessage << "--------------------------------------------" << std::endl;
+  std::cout << GridLogDebug << "Memory Manager                             " << std::endl;
-  std::cout << GridLogMessage << "Memory Manager                             " << std::endl;
+  std::cout << GridLogDebug << "--------------------------------------------" << std::endl;
-  std::cout << GridLogMessage << "--------------------------------------------" << std::endl;
+  std::cout << GridLogDebug << DeviceBytes   << " bytes allocated on device " << std::endl;
-  std::cout << GridLogMessage << DeviceBytes   << " bytes allocated on device " << std::endl;
+  std::cout << GridLogDebug << DeviceLRUBytes<< " bytes evictable on device " << std::endl;
-  std::cout << GridLogMessage << DeviceLRUBytes<< " bytes evictable on device " << std::endl;
+  std::cout << GridLogDebug << DeviceMaxBytes<< " bytes max on device       " << std::endl;
-  std::cout << GridLogMessage << DeviceMaxBytes<< " bytes max on device       " << std::endl;
+  std::cout << GridLogDebug << HostToDeviceXfer << " transfers        to   device " << std::endl;
-  std::cout << GridLogMessage << HostToDeviceXfer << " transfers        to   device " << std::endl;
+  std::cout << GridLogDebug << DeviceToHostXfer << " transfers        from device " << std::endl;
-  std::cout << GridLogMessage << DeviceToHostXfer << " transfers        from device " << std::endl;
+  std::cout << GridLogDebug << HostToDeviceBytes<< " bytes transfered to   device " << std::endl;
-  std::cout << GridLogMessage << HostToDeviceBytes<< " bytes transfered to   device " << std::endl;
+  std::cout << GridLogDebug << DeviceToHostBytes<< " bytes transfered from device " << std::endl;
-  std::cout << GridLogMessage << DeviceToHostBytes<< " bytes transfered from device " << std::endl;
+  std::cout << GridLogDebug << AccViewTable.size()<< " vectors " << LRU.size()<<" evictable"<< std::endl;
-  std::cout << GridLogMessage << DeviceEvictions  << " Evictions from device " << std::endl;
+  std::cout << GridLogDebug << "--------------------------------------------" << std::endl;
-  std::cout << GridLogMessage << DeviceDestroy    << " Destroyed vectors on device " << std::endl;
+  std::cout << GridLogDebug << "CpuAddr\t\tAccAddr\t\tState\t\tcpuLock\taccLock\tLRU_valid "<<std::endl;
-  std::cout << GridLogMessage << AccViewTable.size()<< " vectors " << LRU.size()<<" evictable"<< std::endl;
+  std::cout << GridLogDebug << "--------------------------------------------" << std::endl;
  std::cout << GridLogMessage << "--------------------------------------------" << std::endl;
 }
 void  MemoryManager::PrintAll(void)
 {
  Print();
  std::cout << GridLogMessage << std::endl;
  std::cout << GridLogMessage << "--------------------------------------------" << std::endl;
  std::cout << GridLogMessage << "CpuAddr\t\tAccAddr\t\tState\t\tcpuLock\taccLock\tLRU_valid "<<std::endl;
  std::cout << GridLogMessage << "--------------------------------------------" << std::endl;
  for(auto it=AccViewTable.begin();it!=AccViewTable.end();it++){
    auto &AccCache = it->second;
@@ -492,13 +442,13 @@ void  MemoryManager::PrintAll(void)
    if ( AccCache.state==AccDirty ) str = std::string("AccDirty");
    if ( AccCache.state==Consistent)str = std::string("Consistent");
-    std::cout << GridLogMessage << "0x"<<std::hex<<AccCache.CpuPtr<<std::dec
+    std::cout << GridLogDebug << "0x"<<std::hex<<AccCache.CpuPtr<<std::dec
 	      << "\t0x"<<std::hex<<AccCache.AccPtr<<std::dec<<"\t" <<str
 	      << "\t" << AccCache.cpuLock
 	      << "\t" << AccCache.accLock
 	      << "\t" << AccCache.LRU_valid<<std::endl;
  }
-  std::cout << GridLogMessage << "--------------------------------------------" << std::endl;
+  std::cout << GridLogDebug << "--------------------------------------------" << std::endl;
 };
 int   MemoryManager::isOpen   (void* _CpuPtr) 
@@ -512,89 +462,6 @@ int   MemoryManager::isOpen   (void* _CpuPtr)
    return 0;
  }
 }
 void MemoryManager::Audit(std::string s)
 {
  uint64_t CpuBytes=0;
  uint64_t AccBytes=0;
  uint64_t LruBytes1=0;
  uint64_t LruBytes2=0;
  uint64_t LruCnt=0;
  std::cout << " Memory Manager::Audit() from "<<s<<std::endl;
  for(auto it=LRU.begin();it!=LRU.end();it++){
    uint64_t cpuPtr = *it;
    assert(EntryPresent(cpuPtr));
    auto AccCacheIterator = EntryLookup(cpuPtr);
    auto & AccCache = AccCacheIterator->second;
    LruBytes2+=AccCache.bytes;
    assert(AccCache.LRU_valid==1);
    assert(AccCache.LRU_entry==it);
  }
  std::cout << " Memory Manager::Audit() LRU queue matches table entries "<<std::endl;
  for(auto it=AccViewTable.begin();it!=AccViewTable.end();it++){
    auto &AccCache = it->second;
    std::string str;
    if ( AccCache.state==Empty    ) str = std::string("Empty");
    if ( AccCache.state==CpuDirty ) str = std::string("CpuDirty");
    if ( AccCache.state==AccDirty ) str = std::string("AccDirty");
    if ( AccCache.state==Consistent)str = std::string("Consistent");
    CpuBytes+=AccCache.bytes;
    if( AccCache.AccPtr )    AccBytes+=AccCache.bytes;
    if( AccCache.LRU_valid ) LruBytes1+=AccCache.bytes;
    if( AccCache.LRU_valid ) LruCnt++;
    if ( AccCache.cpuLock || AccCache.accLock ) {
      assert(AccCache.LRU_valid==0);
      std::cout << GridLogError << s<< "\n\t 0x"<<std::hex<<AccCache.CpuPtr<<std::dec
 		<< "\t0x"<<std::hex<<AccCache.AccPtr<<std::dec<<"\t" <<str
 		<< "\t cpuLock  " << AccCache.cpuLock
 		<< "\t accLock  " << AccCache.accLock
 		<< "\t LRUvalid " << AccCache.LRU_valid<<std::endl;
    }
    assert( AccCache.cpuLock== 0 ) ;
    assert( AccCache.accLock== 0 ) ;
  }
  std::cout << " Memory Manager::Audit() no locked table entries "<<std::endl;
  assert(LruBytes1==LruBytes2);
  assert(LruBytes1==DeviceLRUBytes);
  std::cout << " Memory Manager::Audit() evictable bytes matches sum over table "<<std::endl;
  assert(AccBytes==DeviceBytes);
  std::cout << " Memory Manager::Audit() device bytes matches sum over table "<<std::endl;
  assert(LruCnt == LRU.size());
  std::cout << " Memory Manager::Audit() LRU entry count matches "<<std::endl;
 }
 void MemoryManager::PrintState(void* _CpuPtr)
 {
  uint64_t CpuPtr = (uint64_t)_CpuPtr;
  if ( EntryPresent(CpuPtr) ){
    auto AccCacheIterator = EntryLookup(CpuPtr);
    auto & AccCache = AccCacheIterator->second;
    std::string str;
    if ( AccCache.state==Empty    ) str = std::string("Empty");
    if ( AccCache.state==CpuDirty ) str = std::string("CpuDirty");
    if ( AccCache.state==AccDirty ) str = std::string("AccDirty");
    if ( AccCache.state==Consistent)str = std::string("Consistent");
    if ( AccCache.state==EvictNext) str = std::string("EvictNext");
    std::cout << GridLogMessage << "CpuAddr\t\tAccAddr\t\tState\t\tcpuLock\taccLock\tLRU_valid "<<std::endl;
    std::cout << GridLogMessage << "\tx"<<std::hex<<AccCache.CpuPtr<<std::dec
    << "\tx"<<std::hex<<AccCache.AccPtr<<std::dec<<"\t" <<str
    << "\t" << AccCache.cpuLock
    << "\t" << AccCache.accLock
    << "\t" << AccCache.LRU_valid<<std::endl;
  } else {
    std::cout << GridLogMessage << "No Entry in AccCache table." << std::endl; 
  }
 }
 NAMESPACE_END(Grid);
--- a/Grid/allocator/MemoryManagerShared.cc
+++ b/Grid/allocator/MemoryManagerShared.cc
@@ -1,6 +1,7 @@
 #include <Grid/GridCore.h>
 #ifdef GRID_UVM
 #warning "Grid is assuming unified virtual memory address space"
 NAMESPACE_BEGIN(Grid);
 /////////////////////////////////////////////////////////////////////////////////
 // View management is 1:1 address space mapping
@@ -12,19 +13,11 @@ uint64_t  MemoryManager::HostToDeviceBytes;
 uint64_t  MemoryManager::DeviceToHostBytes;
 uint64_t  MemoryManager::HostToDeviceXfer;
 uint64_t  MemoryManager::DeviceToHostXfer;
 uint64_t  MemoryManager::DeviceEvictions;
 uint64_t  MemoryManager::DeviceDestroy;
 void  MemoryManager::Audit(std::string s){};
 void  MemoryManager::ViewClose(void* AccPtr,ViewMode mode){};
 void *MemoryManager::ViewOpen(void* CpuPtr,size_t bytes,ViewMode mode,ViewAdvise hint){ return CpuPtr; };
 int   MemoryManager::isOpen   (void* CpuPtr) { return 0;}
 void  MemoryManager::PrintState(void* CpuPtr)
 {
 std::cout << GridLogMessage << "Host<->Device memory movement not currently managed by Grid." << std::endl;
 };
 void  MemoryManager::Print(void){};
 void  MemoryManager::PrintAll(void){};
 void  MemoryManager::NotifyDeletion(void *ptr){};
 NAMESPACE_END(Grid);
--- a/Grid/cartesian/Cartesian_red_black.h
+++ b/Grid/cartesian/Cartesian_red_black.h
@@ -36,7 +36,7 @@ static const int CbBlack=1;
 static const int Even   =CbRed;
 static const int Odd    =CbBlack;
-accelerator_inline int RedBlackCheckerBoardFromOindex (int oindex,const Coordinate &rdim,const Coordinate &chk_dim_msk)
+accelerator_inline int RedBlackCheckerBoardFromOindex (int oindex, Coordinate &rdim, Coordinate &chk_dim_msk)
 {
  int nd=rdim.size();
  Coordinate coor(nd);
--- a/Grid/communicator/Communicator_base.cc
+++ b/Grid/communicator/Communicator_base.cc
@@ -33,8 +33,6 @@ Author: Peter Boyle <paboyle@ph.ed.ac.uk>
 NAMESPACE_BEGIN(Grid);
 bool Stencil_force_mpi = true;
 ///////////////////////////////////////////////////////////////
 // Info that is setup once and indept of cartesian layout
 ///////////////////////////////////////////////////////////////
--- a/Grid/communicator/Communicator_base.h
+++ b/Grid/communicator/Communicator_base.h
@@ -1,3 +1,4 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
@@ -35,8 +36,6 @@ Author: Peter Boyle <paboyle@ph.ed.ac.uk>
 NAMESPACE_BEGIN(Grid);
 extern bool Stencil_force_mpi ;
 class CartesianCommunicator : public SharedMemory {
 public:    
@@ -53,11 +52,10 @@ public:
  // Communicator should know nothing of the physics grid, only processor grid.
  ////////////////////////////////////////////
  int              _Nprocessors;     // How many in all
  int              _processor;       // linear processor rank
  unsigned long    _ndimension;
  Coordinate _shm_processors;  // Which dimensions get relayed out over processors lanes.
  Coordinate _processors;      // Which dimensions get relayed out over processors lanes.
  int              _processor;       // linear processor rank
  Coordinate _processor_coor;  // linear processor coordinate
  unsigned long    _ndimension;
  static Grid_MPI_Comm      communicator_world;
  Grid_MPI_Comm             communicator;
  std::vector<Grid_MPI_Comm> communicator_halo;
@@ -98,22 +96,18 @@ public:
  int                      BossRank(void)          ;
  int                      ThisRank(void)          ;
  const Coordinate & ThisProcessorCoor(void) ;
  const Coordinate & ShmGrid(void)  { return _shm_processors; }  ;
  const Coordinate & ProcessorGrid(void)     ;
-  int                ProcessorCount(void)    ;
+  int                      ProcessorCount(void)    ;
  ////////////////////////////////////////////////////////////////////////////////
  // very VERY rarely (Log, serial RNG) we need world without a grid
  ////////////////////////////////////////////////////////////////////////////////
  static int  RankWorld(void) ;
  static void BroadcastWorld(int root,void* data, int bytes);
  static void BarrierWorld(void);
  ////////////////////////////////////////////////////////////
  // Reduction
  ////////////////////////////////////////////////////////////
  void GlobalMax(RealD &);
  void GlobalMax(RealF &);
  void GlobalSum(RealF &);
  void GlobalSumVector(RealF *,int N);
  void GlobalSum(RealD &);
@@ -131,7 +125,7 @@ public:
  template<class obj> void GlobalSum(obj &o){
    typedef typename obj::scalar_type scalar_type;
    int words = sizeof(obj)/sizeof(scalar_type);
-    scalar_type * ptr = (scalar_type *)& o; // Safe alias 
+    scalar_type * ptr = (scalar_type *)& o;
    GlobalSumVector(ptr,words);
  }
@@ -145,17 +139,17 @@ public:
 		      int bytes);
  double StencilSendToRecvFrom(void *xmit,
-			       int xmit_to_rank,int do_xmit,
+			       int xmit_to_rank,
 			       void *recv,
-			       int recv_from_rank,int do_recv,
+			       int recv_from_rank,
 			       int bytes,int dir);
  double StencilSendToRecvFromBegin(std::vector<CommsRequest_t> &list,
 				    void *xmit,
-				    int xmit_to_rank,int do_xmit,
+				    int xmit_to_rank,
 				    void *recv,
-				    int recv_from_rank,int do_recv,
+				    int recv_from_rank,
-				    int xbytes,int rbytes,int dir);
+				    int bytes,int dir);
  void StencilSendToRecvFromComplete(std::vector<CommsRequest_t> &waitall,int i);
--- a/Grid/communicator/Communicator_mpi3.cc
+++ b/Grid/communicator/Communicator_mpi3.cc
@@ -106,7 +106,7 @@ CartesianCommunicator::CartesianCommunicator(const Coordinate &processors)
  // Remap using the shared memory optimising routine
  // The remap creates a comm which must be freed
  ////////////////////////////////////////////////////
-  GlobalSharedMemory::OptimalCommunicator    (processors,optimal_comm,_shm_processors);
+  GlobalSharedMemory::OptimalCommunicator    (processors,optimal_comm);
  InitFromMPICommunicator(processors,optimal_comm);
  SetCommunicator(optimal_comm);
  ///////////////////////////////////////////////////
@@ -124,13 +124,12 @@ CartesianCommunicator::CartesianCommunicator(const Coordinate &processors,const
  int parent_ndimension = parent._ndimension; assert(_ndimension >= parent._ndimension);
  Coordinate parent_processor_coor(_ndimension,0);
  Coordinate parent_processors    (_ndimension,1);
-  Coordinate shm_processors       (_ndimension,1);
+
  // Can make 5d grid from 4d etc...
  int pad = _ndimension-parent_ndimension;
  for(int d=0;d<parent_ndimension;d++){
    parent_processor_coor[pad+d]=parent._processor_coor[d];
    parent_processors    [pad+d]=parent._processors[d];
    shm_processors       [pad+d]=parent._shm_processors[d];
  }
  //////////////////////////////////////////////////////////////////////////////////////////////////////
@@ -155,7 +154,6 @@ CartesianCommunicator::CartesianCommunicator(const Coordinate &processors,const
    ccoor[d] = parent_processor_coor[d] % processors[d];
    scoor[d] = parent_processor_coor[d] / processors[d];
    ssize[d] = parent_processors[d]     / processors[d];
    if ( processors[d] < shm_processors[d] ) shm_processors[d] = processors[d]; // subnode splitting.
  }
  // rank within subcomm ; srank is rank of subcomm within blocks of subcomms
@@ -277,16 +275,6 @@ void CartesianCommunicator::GlobalXOR(uint64_t &u){
  int ierr=MPI_Allreduce(MPI_IN_PLACE,&u,1,MPI_UINT64_T,MPI_BXOR,communicator);
  assert(ierr==0);
 }
 void CartesianCommunicator::GlobalMax(float &f)
 {
  int ierr=MPI_Allreduce(MPI_IN_PLACE,&f,1,MPI_FLOAT,MPI_MAX,communicator);
  assert(ierr==0);
 }
 void CartesianCommunicator::GlobalMax(double &d)
 {
  int ierr = MPI_Allreduce(MPI_IN_PLACE,&d,1,MPI_DOUBLE,MPI_MAX,communicator);
  assert(ierr==0);
 }
 void CartesianCommunicator::GlobalSum(float &f){
  int ierr=MPI_Allreduce(MPI_IN_PLACE,&f,1,MPI_FLOAT,MPI_SUM,communicator);
  assert(ierr==0);
@@ -337,24 +325,23 @@ void CartesianCommunicator::SendToRecvFrom(void *xmit,
 }
 // Basic Halo comms primitive
 double CartesianCommunicator::StencilSendToRecvFrom( void *xmit,
-						     int dest, int dox,
+						     int dest,
 						     void *recv,
-						     int from, int dor,
+						     int from,
 						     int bytes,int dir)
 {
  std::vector<CommsRequest_t> list;
-  double offbytes = StencilSendToRecvFromBegin(list,xmit,dest,dox,recv,from,dor,bytes,bytes,dir);
+  double offbytes = StencilSendToRecvFromBegin(list,xmit,dest,recv,from,bytes,dir);
  StencilSendToRecvFromComplete(list,dir);
  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,
+							 int dest,
 							 void *recv,
-							 int from,int dor,
+							 int from,
-							 int xbytes,int rbytes,int dir)
+							 int bytes,int dir)
 {
  int ncomm  =communicator_halo.size();
  int commdir=dir%ncomm;
@@ -373,37 +360,24 @@ double CartesianCommunicator::StencilSendToRecvFromBegin(std::vector<CommsReques
  double off_node_bytes=0.0;
  int tag;
-  if ( dor ) {
+  if ( gfrom ==MPI_UNDEFINED) {
-    if ( (gfrom ==MPI_UNDEFINED) || Stencil_force_mpi ) {
+    tag= dir+from*32;
-      tag= dir+from*32;
+    ierr=MPI_Irecv(recv, bytes, MPI_CHAR,from,tag,communicator_halo[commdir],&rrq);
-      ierr=MPI_Irecv(recv, rbytes, MPI_CHAR,from,tag,communicator_halo[commdir],&rrq);
+    assert(ierr==0);
-      assert(ierr==0);
+    list.push_back(rrq);
-      list.push_back(rrq);
+    off_node_bytes+=bytes;
      off_node_bytes+=rbytes;
    }
 #ifdef NVLINK_GET
      void *shm = (void *) this->ShmBufferTranslate(from,xmit);
      assert(shm!=NULL);
      acceleratorCopyDeviceToDeviceAsynch(shm,recv,rbytes);
 #endif
  }
-  
+
-  if (dox) {
+  if ( gdest == MPI_UNDEFINED ) {
-    //  rcrc = crc32(rcrc,(unsigned char *)recv,bytes);
+    tag= dir+_processor*32;
-    if ( (gdest == MPI_UNDEFINED) || Stencil_force_mpi ) {
+    ierr =MPI_Isend(xmit, bytes, MPI_CHAR,dest,tag,communicator_halo[commdir],&xrq);
-      tag= dir+_processor*32;
+    assert(ierr==0);
-      ierr =MPI_Isend(xmit, xbytes, MPI_CHAR,dest,tag,communicator_halo[commdir],&xrq);
+    list.push_back(xrq);
-      assert(ierr==0);
+    off_node_bytes+=bytes;
-      list.push_back(xrq);
+  }
-      off_node_bytes+=xbytes;
+
-    } else {
+  if ( CommunicatorPolicy == CommunicatorPolicySequential ) {
-#ifndef NVLINK_GET
+    this->StencilSendToRecvFromComplete(list,dir);
      void *shm = (void *) this->ShmBufferTranslate(dest,recv);
      assert(shm!=NULL);
      acceleratorCopyDeviceToDeviceAsynch(xmit,shm,xbytes);
 #endif
    }
  }
  return off_node_bytes;
@@ -412,8 +386,6 @@ void CartesianCommunicator::StencilSendToRecvFromComplete(std::vector<CommsReque
 {
  int nreq=list.size();
  acceleratorCopySynchronise();
  if (nreq==0) return;
  std::vector<MPI_Status> status(nreq);
@@ -447,10 +419,6 @@ int CartesianCommunicator::RankWorld(void){
  MPI_Comm_rank(communicator_world,&r);
  return r;
 }
 void CartesianCommunicator::BarrierWorld(void){
  int ierr = MPI_Barrier(communicator_world);
  assert(ierr==0);
 }
 void CartesianCommunicator::BroadcastWorld(int root,void* data, int bytes)
 {
  int ierr= MPI_Bcast(data,
--- a/Grid/communicator/Communicator_none.cc
+++ b/Grid/communicator/Communicator_none.cc
@@ -45,14 +45,12 @@ void CartesianCommunicator::Init(int *argc, char *** arv)
 CartesianCommunicator::CartesianCommunicator(const Coordinate &processors,const CartesianCommunicator &parent,int &srank) 
  : CartesianCommunicator(processors) 
 {
  _shm_processors = Coordinate(processors.size(),1);
  srank=0;
  SetCommunicator(communicator_world);
 }
 CartesianCommunicator::CartesianCommunicator(const Coordinate &processors)
 {
  _shm_processors = Coordinate(processors.size(),1);
  _processors = processors;
  _ndimension = processors.size();  assert(_ndimension>=1);
  _processor_coor.resize(_ndimension);
@@ -69,8 +67,6 @@ CartesianCommunicator::CartesianCommunicator(const Coordinate &processors)
 CartesianCommunicator::~CartesianCommunicator(){}
 void CartesianCommunicator::GlobalMax(float &){}
 void CartesianCommunicator::GlobalMax(double &){}
 void CartesianCommunicator::GlobalSum(float &){}
 void CartesianCommunicator::GlobalSumVector(float *,int N){}
 void CartesianCommunicator::GlobalSum(double &){}
@@ -104,7 +100,6 @@ int  CartesianCommunicator::RankWorld(void){return 0;}
 void CartesianCommunicator::Barrier(void){}
 void CartesianCommunicator::Broadcast(int root,void* data, int bytes) {}
 void CartesianCommunicator::BroadcastWorld(int root,void* data, int bytes) { }
 void CartesianCommunicator::BarrierWorld(void) { }
 int  CartesianCommunicator::RankFromProcessorCoor(Coordinate &coor) {  return 0;}
 void CartesianCommunicator::ProcessorCoorFromRank(int rank, Coordinate &coor){  coor = _processor_coor; }
 void CartesianCommunicator::ShiftedRanks(int dim,int shift,int &source,int &dest)
@@ -114,21 +109,21 @@ void CartesianCommunicator::ShiftedRanks(int dim,int shift,int &source,int &dest
 }
 double CartesianCommunicator::StencilSendToRecvFrom( void *xmit,
-						     int xmit_to_rank,int dox,
+						     int xmit_to_rank,
 						     void *recv,
-						     int recv_from_rank,int dor,
+						     int recv_from_rank,
 						     int bytes, int dir)
 {
  return 2.0*bytes;
 }
 double CartesianCommunicator::StencilSendToRecvFromBegin(std::vector<CommsRequest_t> &list,
 							 void *xmit,
-							 int xmit_to_rank,int dox,
+							 int xmit_to_rank,
 							 void *recv,
-							 int recv_from_rank,int dor,
+							 int recv_from_rank,
-							 int xbytes,int rbytes, int dir)
+							 int bytes, int dir)
 {
-  return xbytes+rbytes;
+  return 2.0*bytes;
 }
 void CartesianCommunicator::StencilSendToRecvFromComplete(std::vector<CommsRequest_t> &waitall,int dir)
 {
--- a/Grid/communicator/SharedMemory.cc
+++ b/Grid/communicator/SharedMemory.cc
@@ -40,9 +40,6 @@ 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;
@@ -69,26 +66,6 @@ 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;
@@ -114,59 +91,6 @@ void *SharedMemory::ShmBufferSelf(void)
  //std::cerr << "ShmBufferSelf "<<ShmRank<<" "<<std::hex<< ShmCommBufs[ShmRank] <<std::dec<<std::endl;
  return ShmCommBufs[ShmRank];
 }
 static inline int divides(int a,int b)
 {
  return ( b == ( (b/a)*a ) );
 }
 void GlobalSharedMemory::GetShmDims(const Coordinate &WorldDims,Coordinate &ShmDims)
 {
  ////////////////////////////////////////////////////////////////
  // Allow user to configure through environment variable
  ////////////////////////////////////////////////////////////////
  char* str = getenv(("GRID_SHM_DIMS_" + std::to_string(ShmDims.size())).c_str());
  if ( str ) {
    std::vector<int> IntShmDims;
    GridCmdOptionIntVector(std::string(str),IntShmDims);
    assert(IntShmDims.size() == WorldDims.size());
    long ShmSize = 1;
    for (int dim=0;dim<WorldDims.size();dim++) {
      ShmSize *= (ShmDims[dim] = IntShmDims[dim]);
      assert(divides(ShmDims[dim],WorldDims[dim]));
    }
    assert(ShmSize == WorldShmSize);
    return;
  }
  ////////////////////////////////////////////////////////////////
  // Powers of 2,3,5 only in prime decomposition for now
  ////////////////////////////////////////////////////////////////
  int ndimension = WorldDims.size();
  ShmDims=Coordinate(ndimension,1);
  std::vector<int> primes({2,3,5});
  int dim = 0;
  int last_dim = ndimension - 1;
  int AutoShmSize = 1;
  while(AutoShmSize != WorldShmSize) {
    int p;
    for(p=0;p<primes.size();p++) {
      int prime=primes[p];
      if ( divides(prime,WorldDims[dim]/ShmDims[dim])
        && divides(prime,WorldShmSize/AutoShmSize)  ) {
  AutoShmSize*=prime;
  ShmDims[dim]*=prime;
  last_dim = dim;
  break;
      }
    }
    if (p == primes.size() && last_dim == dim) {
      std::cerr << "GlobalSharedMemory::GetShmDims failed" << std::endl;
      exit(EXIT_FAILURE);
    }
    dim=(dim+1) %ndimension;
  }
 }
 NAMESPACE_END(Grid); 
--- a/Grid/communicator/SharedMemory.h
+++ b/Grid/communicator/SharedMemory.h
@@ -75,9 +75,7 @@ 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;
@@ -95,17 +93,16 @@ public:
  // Create an optimal reordered communicator that makes MPI_Cart_create get it right
  //////////////////////////////////////////////////////////////////////////////////////
  static void Init(Grid_MPI_Comm comm); // Typically MPI_COMM_WORLD
-  // Turns MPI_COMM_WORLD into right layout for Cartesian
+  static void OptimalCommunicator            (const Coordinate &processors,Grid_MPI_Comm & optimal_comm);  // Turns MPI_COMM_WORLD into right layout for Cartesian
-  static void OptimalCommunicator            (const Coordinate &processors,Grid_MPI_Comm & optimal_comm,Coordinate &ShmDims); 
+  static void OptimalCommunicatorHypercube   (const Coordinate &processors,Grid_MPI_Comm & optimal_comm);  // Turns MPI_COMM_WORLD into right layout for Cartesian
-  static void OptimalCommunicatorHypercube   (const Coordinate &processors,Grid_MPI_Comm & optimal_comm,Coordinate &ShmDims); 
+  static void OptimalCommunicatorSharedMemory(const Coordinate &processors,Grid_MPI_Comm & optimal_comm);  // Turns MPI_COMM_WORLD into right layout for Cartesian
  static void OptimalCommunicatorSharedMemory(const Coordinate &processors,Grid_MPI_Comm & optimal_comm,Coordinate &ShmDims); 
  static void GetShmDims(const Coordinate &WorldDims,Coordinate &ShmDims);
  ///////////////////////////////////////////////////
  // Provide shared memory facilities off comm world
  ///////////////////////////////////////////////////
  static void SharedMemoryAllocate(uint64_t bytes, int flags);
  static void SharedMemoryFree(void);
-  static void SharedMemoryCopy(void *dest,void *src,size_t bytes);
+  static void SharedMemoryCopy(void *dest,const void *src,size_t bytes);
  static void SharedMemoryZero(void *dest,size_t bytes);
 };
@@ -122,13 +119,6 @@ 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
@@ -160,10 +150,7 @@ 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
@@ -7,7 +7,6 @@
    Copyright (C) 2015
 Author: Peter Boyle <paboyle@ph.ed.ac.uk>
 Author: Christoph Lehner <christoph@lhnr.de>
    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
@@ -27,8 +26,6 @@ Author: Christoph Lehner <christoph@lhnr.de>
 *************************************************************************************/
 /*  END LEGAL */
 #define Mheader "SharedMemoryMpi: "
 #include <Grid/GridCore.h>
 #include <pwd.h>
@@ -38,122 +35,9 @@ Author: Christoph Lehner <christoph@lhnr.de>
 #ifdef GRID_HIP
 #include <hip/hip_runtime_api.h>
 #endif
 #ifdef GRID_SYCL
 #ifdef ACCELERATOR_AWARE_MPI
 #define GRID_SYCL_LEVEL_ZERO_IPC
 #define SHM_SOCKETS
 #endif 
 #include <syscall.h>
 #endif
 #include <sys/socket.h>
 #include <sys/un.h>
 NAMESPACE_BEGIN(Grid); 
-
+#define header "SharedMemoryMpi: "
 #ifdef SHM_SOCKETS
 /*
 * Barbaric extra intranode communication route in case we need sockets to pass FDs
 * Forced by level_zero not being nicely designed
 */
 static int sock;
 static const char *sock_path_fmt = "/tmp/GridUnixSocket.%d";
 static char sock_path[256];
 class UnixSockets {
 public:
  static void Open(int rank)
  {
    int errnum;
    sock = socket(AF_UNIX, SOCK_DGRAM, 0);  assert(sock>0);
    struct sockaddr_un sa_un = { 0 };
    sa_un.sun_family = AF_UNIX;
    snprintf(sa_un.sun_path, sizeof(sa_un.sun_path),sock_path_fmt,rank);
    unlink(sa_un.sun_path);
    if (bind(sock, (struct sockaddr *)&sa_un, sizeof(sa_un))) {
      perror("bind failure");
      exit(EXIT_FAILURE);
    }
  }
  static int RecvFileDescriptor(void)
  {
    int n;
    int fd;
    char buf[1];
    struct iovec iov;
    struct msghdr msg;
    struct cmsghdr *cmsg;
    char cms[CMSG_SPACE(sizeof(int))];
    iov.iov_base = buf;
    iov.iov_len = 1;
    memset(&msg, 0, sizeof msg);
    msg.msg_name = 0;
    msg.msg_namelen = 0;
    msg.msg_iov = &iov;
    msg.msg_iovlen = 1;
    msg.msg_control = (caddr_t)cms;
    msg.msg_controllen = sizeof cms;
    if((n=recvmsg(sock, &msg, 0)) < 0) {
      perror("recvmsg failed");
      return -1;
    }
    if(n == 0){
      perror("recvmsg returned 0");
      return -1;
    }
    cmsg = CMSG_FIRSTHDR(&msg);
    memmove(&fd, CMSG_DATA(cmsg), sizeof(int));
    return fd;
  }
  static void SendFileDescriptor(int fildes,int xmit_to_rank)
  {
    struct msghdr msg;
    struct iovec iov;
    struct cmsghdr *cmsg = NULL;
    char ctrl[CMSG_SPACE(sizeof(int))];
    char data = ' ';
    memset(&msg, 0, sizeof(struct msghdr));
    memset(ctrl, 0, CMSG_SPACE(sizeof(int)));
    iov.iov_base = &data;
    iov.iov_len = sizeof(data);
    sprintf(sock_path,sock_path_fmt,xmit_to_rank);
    struct sockaddr_un sa_un = { 0 };
    sa_un.sun_family = AF_UNIX;
    snprintf(sa_un.sun_path, sizeof(sa_un.sun_path),sock_path_fmt,xmit_to_rank);
    msg.msg_name = (void *)&sa_un;
    msg.msg_namelen = sizeof(sa_un);
    msg.msg_iov = &iov;
    msg.msg_iovlen = 1;
    msg.msg_controllen =  CMSG_SPACE(sizeof(int));
    msg.msg_control = ctrl;
    cmsg = CMSG_FIRSTHDR(&msg);
    cmsg->cmsg_level = SOL_SOCKET;
    cmsg->cmsg_type = SCM_RIGHTS;
    cmsg->cmsg_len = CMSG_LEN(sizeof(int));
    *((int *) CMSG_DATA(cmsg)) = fildes;
    sendmsg(sock, &msg, 0);
  };
 };
 #endif
 /*Construct from an MPI communicator*/
 void GlobalSharedMemory::Init(Grid_MPI_Comm comm)
 {
@@ -176,8 +60,8 @@ void GlobalSharedMemory::Init(Grid_MPI_Comm comm)
  MPI_Comm_size(WorldShmComm     ,&WorldShmSize);
  if ( WorldRank == 0) {
-    std::cout << Mheader " World communicator of size " <<WorldSize << std::endl;  
+    std::cout << header " World communicator of size " <<WorldSize << std::endl;  
-    std::cout << Mheader " Node  communicator of size " <<WorldShmSize << std::endl;
+    std::cout << header " Node  communicator of size " <<WorldShmSize << std::endl;
  }
  // WorldShmComm, WorldShmSize, WorldShmRank
@@ -185,7 +69,6 @@ void GlobalSharedMemory::Init(Grid_MPI_Comm comm)
  WorldNodes = WorldSize/WorldShmSize;
  assert( (WorldNodes * WorldShmSize) == WorldSize );
  // FIXME: Check all WorldShmSize are the same ?
  /////////////////////////////////////////////////////////////////////
@@ -264,7 +147,7 @@ int Log2Size(int TwoToPower,int MAXLOG2)
  }
  return log2size;
 }
-void GlobalSharedMemory::OptimalCommunicator(const Coordinate &processors,Grid_MPI_Comm & optimal_comm,Coordinate &SHM)
+void GlobalSharedMemory::OptimalCommunicator(const Coordinate &processors,Grid_MPI_Comm & optimal_comm)
 {
  //////////////////////////////////////////////////////////////////////////////
  // Look and see if it looks like an HPE 8600 based on hostname conventions
@@ -277,11 +160,46 @@ void GlobalSharedMemory::OptimalCommunicator(const Coordinate &processors,Grid_M
  gethostname(name,namelen);
  int nscan = sscanf(name,"r%di%dn%d",&R,&I,&N) ;
-  if(nscan==3 && HPEhypercube ) OptimalCommunicatorHypercube(processors,optimal_comm,SHM);
+  if(nscan==3 && HPEhypercube ) OptimalCommunicatorHypercube(processors,optimal_comm);
-  else                          OptimalCommunicatorSharedMemory(processors,optimal_comm,SHM);
+  else                          OptimalCommunicatorSharedMemory(processors,optimal_comm);
 }
 static inline int divides(int a,int b)
 {
  return ( b == ( (b/a)*a ) );
 }
 void GlobalSharedMemory::GetShmDims(const Coordinate &WorldDims,Coordinate &ShmDims)
 {
  ////////////////////////////////////////////////////////////////
  // Powers of 2,3,5 only in prime decomposition for now
  ////////////////////////////////////////////////////////////////
  int ndimension = WorldDims.size();
  ShmDims=Coordinate(ndimension,1);
-void GlobalSharedMemory::OptimalCommunicatorHypercube(const Coordinate &processors,Grid_MPI_Comm & optimal_comm,Coordinate &SHM)
+  std::vector<int> primes({2,3,5});
  int dim = 0;
  int last_dim = ndimension - 1;
  int AutoShmSize = 1;
  while(AutoShmSize != WorldShmSize) {
    int p;
    for(p=0;p<primes.size();p++) {
      int prime=primes[p];
      if ( divides(prime,WorldDims[dim]/ShmDims[dim])
        && divides(prime,WorldShmSize/AutoShmSize)  ) {
 	AutoShmSize*=prime;
 	ShmDims[dim]*=prime;
 	last_dim = dim;
 	break;
      }
    }
    if (p == primes.size() && last_dim == dim) {
      std::cerr << "GlobalSharedMemory::GetShmDims failed" << std::endl;
      exit(EXIT_FAILURE);
    }
    dim=(dim+1) %ndimension;
  }
 }
 void GlobalSharedMemory::OptimalCommunicatorHypercube(const Coordinate &processors,Grid_MPI_Comm & optimal_comm)
 {
  ////////////////////////////////////////////////////////////////
  // Assert power of two shm_size.
@@ -354,8 +272,7 @@ void GlobalSharedMemory::OptimalCommunicatorHypercube(const Coordinate &processo
  Coordinate HyperCoor(ndimension);
  GetShmDims(WorldDims,ShmDims);
-  SHM = ShmDims;
+
  ////////////////////////////////////////////////////////////////
  // Establish torus of processes and nodes with sub-blockings
  ////////////////////////////////////////////////////////////////
@@ -402,7 +319,7 @@ void GlobalSharedMemory::OptimalCommunicatorHypercube(const Coordinate &processo
  int ierr= MPI_Comm_split(WorldComm,0,rank,&optimal_comm);
  assert(ierr==0);
 }
-void GlobalSharedMemory::OptimalCommunicatorSharedMemory(const Coordinate &processors,Grid_MPI_Comm & optimal_comm,Coordinate &SHM)
+void GlobalSharedMemory::OptimalCommunicatorSharedMemory(const Coordinate &processors,Grid_MPI_Comm & optimal_comm)
 {
  ////////////////////////////////////////////////////////////////
  // Identify subblock of ranks on node spreading across dims
@@ -414,8 +331,6 @@ void GlobalSharedMemory::OptimalCommunicatorSharedMemory(const Coordinate &proce
  Coordinate ShmCoor(ndimension);    Coordinate NodeCoor(ndimension);   Coordinate WorldCoor(ndimension);
  GetShmDims(WorldDims,ShmDims);
  SHM=ShmDims;
  ////////////////////////////////////////////////////////////////
  // Establish torus of processes and nodes with sub-blockings
  ////////////////////////////////////////////////////////////////
@@ -454,7 +369,7 @@ void GlobalSharedMemory::OptimalCommunicatorSharedMemory(const Coordinate &proce
 #ifdef GRID_MPI3_SHMGET
 void GlobalSharedMemory::SharedMemoryAllocate(uint64_t bytes, int flags)
 {
-  std::cout << Mheader "SharedMemoryAllocate "<< bytes<< " shmget implementation "<<std::endl;
+  std::cout << header "SharedMemoryAllocate "<< bytes<< " shmget implementation "<<std::endl;
  assert(_ShmSetup==1);
  assert(_ShmAlloc==0);
@@ -513,7 +428,7 @@ void GlobalSharedMemory::SharedMemoryAllocate(uint64_t bytes, int flags)
 ////////////////////////////////////////////////////////////////////////////////////////////
 // Hugetlbfs mapping intended
 ////////////////////////////////////////////////////////////////////////////////////////////
-#if defined(GRID_CUDA) ||defined(GRID_HIP)  || defined(GRID_SYCL)
+#if defined(GRID_CUDA) ||defined(GRID_HIP)
 void GlobalSharedMemory::SharedMemoryAllocate(uint64_t bytes, int flags)
 {
  void * ShmCommBuf ; 
@@ -536,65 +451,28 @@ 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;
    exit(EXIT_FAILURE);  
  }
-  if ( WorldRank == 0 ){
+  //  if ( WorldRank == 0 ){
-    std::cout << WorldRank << Mheader " SharedMemoryMPI.cc acceleratorAllocDevice "<< bytes 
+  if ( 1 ){
-	      << "bytes at "<< std::hex<< ShmCommBuf << " - "<<(bytes-1+(uint64_t)ShmCommBuf) <<std::dec<<" for comms buffers " <<std::endl;
+    std::cout << WorldRank << header " SharedMemoryMPI.cc acceleratorAllocDevice "<< bytes 
 	      << "bytes at "<< std::hex<< ShmCommBuf <<std::dec<<" for comms buffers " <<std::endl;
  }
  SharedMemoryZero(ShmCommBuf,bytes);
-  std::cout<< "Setting up IPC"<<std::endl;
+
  ///////////////////////////////////////////////////////////////////////////////////////////////////////////
  // Loop over ranks/gpu's on our node
  ///////////////////////////////////////////////////////////////////////////////////////////////////////////
 #ifdef SHM_SOCKETS
  UnixSockets::Open(WorldShmRank);
 #endif
  for(int r=0;r<WorldShmSize;r++){
    MPI_Barrier(WorldShmComm);
 #ifndef GRID_MPI3_SHM_NONE
    //////////////////////////////////////////////////
    // If it is me, pass around the IPC access key
    //////////////////////////////////////////////////
    void * thisBuf = ShmCommBuf;
    if(!Stencil_force_mpi) {
 #ifdef GRID_SYCL_LEVEL_ZERO_IPC
    typedef struct { int fd; pid_t pid ; ze_ipc_mem_handle_t ze; } clone_mem_t;
    auto zeDevice    = cl::sycl::get_native<cl::sycl::backend::ext_oneapi_level_zero>(theGridAccelerator->get_device());
    auto zeContext   = cl::sycl::get_native<cl::sycl::backend::ext_oneapi_level_zero>(theGridAccelerator->get_context());
    ze_ipc_mem_handle_t ihandle;
    clone_mem_t handle;
    if ( r==WorldShmRank ) { 
      auto err = zeMemGetIpcHandle(zeContext,ShmCommBuf,&ihandle);
      if ( err != ZE_RESULT_SUCCESS ) {
 	std::cerr << "SharedMemoryMPI.cc zeMemGetIpcHandle failed for rank "<<r<<" "<<std::hex<<err<<std::dec<<std::endl;
 	exit(EXIT_FAILURE);
      } else {
 	std::cout << "SharedMemoryMPI.cc zeMemGetIpcHandle succeeded for rank "<<r<<" "<<std::hex<<err<<std::dec<<std::endl;
      }
      memcpy((void *)&handle.fd,(void *)&ihandle,sizeof(int));
      handle.pid = getpid();
      memcpy((void *)&handle.ze,(void *)&ihandle,sizeof(ihandle));
 #ifdef SHM_SOCKETS
      for(int rr=0;rr<WorldShmSize;rr++){
 	if(rr!=r){
 	  UnixSockets::SendFileDescriptor(handle.fd,rr);
 	}
      }
 #endif
    }
 #endif
 #ifdef GRID_CUDA
    cudaIpcMemHandle_t handle;
    if ( r==WorldShmRank ) { 
@@ -615,12 +493,10 @@ void GlobalSharedMemory::SharedMemoryAllocate(uint64_t bytes, int flags)
      }
    }
 #endif
    //////////////////////////////////////////////////
    // Share this IPC handle across the Shm Comm
    //////////////////////////////////////////////////
    { 
      MPI_Barrier(WorldShmComm);
      int ierr=MPI_Bcast(&handle,
 			 sizeof(handle),
 			 MPI_BYTE,
@@ -632,45 +508,7 @@ void GlobalSharedMemory::SharedMemoryAllocate(uint64_t bytes, int flags)
    ///////////////////////////////////////////////////////////////
    // If I am not the source, overwrite thisBuf with remote buffer
    ///////////////////////////////////////////////////////////////
-
+    void * thisBuf = ShmCommBuf;
 #ifdef GRID_SYCL_LEVEL_ZERO_IPC
    if ( r!=WorldShmRank ) {
      thisBuf = nullptr;
      int myfd;
 #ifdef SHM_SOCKETS
      myfd=UnixSockets::RecvFileDescriptor();
 #else
      std::cout<<"mapping seeking remote pid/fd "
 	       <<handle.pid<<"/"
 	       <<handle.fd<<std::endl;
      int pidfd = syscall(SYS_pidfd_open,handle.pid,0);
      std::cout<<"Using IpcHandle pidfd "<<pidfd<<"\n";
      //      int myfd  = syscall(SYS_pidfd_getfd,pidfd,handle.fd,0);
      myfd  = syscall(438,pidfd,handle.fd,0);
      int err_t = errno;
      if (myfd < 0) {
        fprintf(stderr,"pidfd_getfd returned %d errno was %d\n", myfd,err_t); fflush(stderr);
 	perror("pidfd_getfd failed ");
 	assert(0);
      }
 #endif
      std::cout<<"Using IpcHandle mapped remote pid "<<handle.pid <<" FD "<<handle.fd <<" to myfd "<<myfd<<"\n";
      memcpy((void *)&ihandle,(void *)&handle.ze,sizeof(ihandle));
      memcpy((void *)&ihandle,(void *)&myfd,sizeof(int));
      auto err = zeMemOpenIpcHandle(zeContext,zeDevice,ihandle,0,&thisBuf);
      if ( err != ZE_RESULT_SUCCESS ) {
 	std::cerr << "SharedMemoryMPI.cc "<<zeContext<<" "<<zeDevice<<std::endl;
 	std::cerr << "SharedMemoryMPI.cc zeMemOpenIpcHandle failed for rank "<<r<<" "<<std::hex<<err<<std::dec<<std::endl; 
 	exit(EXIT_FAILURE);
      } else {
 	std::cout << "SharedMemoryMPI.cc zeMemOpenIpcHandle succeeded for rank "<<r<<std::endl;
 	std::cout << "SharedMemoryMPI.cc zeMemOpenIpcHandle pointer is "<<std::hex<<thisBuf<<std::dec<<std::endl;
      }
      assert(thisBuf!=nullptr);
    }
 #endif
 #ifdef GRID_CUDA
    if ( r!=WorldShmRank ) { 
      auto err = cudaIpcOpenMemHandle(&thisBuf,handle,cudaIpcMemLazyEnablePeerAccess);
@@ -692,23 +530,20 @@ void GlobalSharedMemory::SharedMemoryAllocate(uint64_t bytes, int flags)
    ///////////////////////////////////////////////////////////////
    // Save a copy of the device buffers
    ///////////////////////////////////////////////////////////////
    }
    WorldShmCommBufs[r] = thisBuf;
 #else
    WorldShmCommBufs[r] = ShmCommBuf;
 #endif
    MPI_Barrier(WorldShmComm);
  }
  _ShmAllocBytes=bytes;
  _ShmAlloc=1;
 }
 #else 
 #ifdef GRID_MPI3_SHMMMAP
 void GlobalSharedMemory::SharedMemoryAllocate(uint64_t bytes, int flags)
 {
-  std::cout << Mheader "SharedMemoryAllocate "<< bytes<< " MMAP implementation "<< GRID_SHM_PATH <<std::endl;
+  std::cout << header "SharedMemoryAllocate "<< bytes<< " MMAP implementation "<< GRID_SHM_PATH <<std::endl;
  assert(_ShmSetup==1);
  assert(_ShmAlloc==0);
  //////////////////////////////////////////////////////////////////////////////////////////////////////////
@@ -745,7 +580,7 @@ void GlobalSharedMemory::SharedMemoryAllocate(uint64_t bytes, int flags)
    assert(((uint64_t)ptr&0x3F)==0);
    close(fd);
    WorldShmCommBufs[r] =ptr;
-    //    std::cout << Mheader "Set WorldShmCommBufs["<<r<<"]="<<ptr<< "("<< bytes<< "bytes)"<<std::endl;
+    //    std::cout << header "Set WorldShmCommBufs["<<r<<"]="<<ptr<< "("<< bytes<< "bytes)"<<std::endl;
  }
  _ShmAlloc=1;
  _ShmAllocBytes  = bytes;
@@ -755,7 +590,7 @@ void GlobalSharedMemory::SharedMemoryAllocate(uint64_t bytes, int flags)
 #ifdef GRID_MPI3_SHM_NONE
 void GlobalSharedMemory::SharedMemoryAllocate(uint64_t bytes, int flags)
 {
-  std::cout << Mheader "SharedMemoryAllocate "<< bytes<< " MMAP anonymous implementation "<<std::endl;
+  std::cout << header "SharedMemoryAllocate "<< bytes<< " MMAP anonymous implementation "<<std::endl;
  assert(_ShmSetup==1);
  assert(_ShmAlloc==0);
  //////////////////////////////////////////////////////////////////////////////////////////////////////////
@@ -802,7 +637,7 @@ void GlobalSharedMemory::SharedMemoryAllocate(uint64_t bytes, int flags)
 ////////////////////////////////////////////////////////////////////////////////////////////
 void GlobalSharedMemory::SharedMemoryAllocate(uint64_t bytes, int flags)
 { 
-  std::cout << Mheader "SharedMemoryAllocate "<< bytes<< " SHMOPEN implementation "<<std::endl;
+  std::cout << header "SharedMemoryAllocate "<< bytes<< " SHMOPEN implementation "<<std::endl;
  assert(_ShmSetup==1);
  assert(_ShmAlloc==0); 
  MPI_Barrier(WorldShmComm);
@@ -874,16 +709,16 @@ void GlobalSharedMemory::SharedMemoryAllocate(uint64_t bytes, int flags)
 /////////////////////////////////////////////////////////////////////////
 void GlobalSharedMemory::SharedMemoryZero(void *dest,size_t bytes)
 {
-#if defined(GRID_CUDA) || defined(GRID_HIP) || defined(GRID_SYCL)
+#ifdef GRID_CUDA
-  acceleratorMemSet(dest,0,bytes);
+  cudaMemset(dest,0,bytes);
 #else
  bzero(dest,bytes);
 #endif
 }
-void GlobalSharedMemory::SharedMemoryCopy(void *dest,void *src,size_t bytes)
+void GlobalSharedMemory::SharedMemoryCopy(void *dest,const void *src,size_t bytes)
 {
-#if defined(GRID_CUDA) || defined(GRID_HIP) || defined(GRID_SYCL)
+#ifdef GRID_CUDA
-  acceleratorCopyToDevice(src,dest,bytes);
+  cudaMemcpy(dest,src,bytes,cudaMemcpyDefault);
 #else   
  bcopy(src,dest,bytes);
 #endif
@@ -926,12 +761,6 @@ 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)
  /////////////////////////////////////////////////////////////////////
@@ -953,7 +782,7 @@ void SharedMemory::SetCommunicator(Grid_MPI_Comm comm)
  }
 #endif
-  //SharedMemoryTest();
+  SharedMemoryTest();
 }
 //////////////////////////////////////////////////////////////////
 // On node barrier
--- a/Grid/communicator/SharedMemoryNone.cc
+++ b/Grid/communicator/SharedMemoryNone.cc
@@ -29,7 +29,6 @@ Author: Peter Boyle <paboyle@ph.ed.ac.uk>
 #include <Grid/GridCore.h>
 NAMESPACE_BEGIN(Grid); 
 #define header "SharedMemoryNone: "
 /*Construct from an MPI communicator*/
 void GlobalSharedMemory::Init(Grid_MPI_Comm comm)
@@ -48,47 +47,14 @@ void GlobalSharedMemory::Init(Grid_MPI_Comm comm)
  _ShmSetup=1;
 }
-void GlobalSharedMemory::OptimalCommunicator(const Coordinate &processors,Grid_MPI_Comm & optimal_comm,Coordinate &SHM)
+void GlobalSharedMemory::OptimalCommunicator(const Coordinate &processors,Grid_MPI_Comm & optimal_comm)
 {
  optimal_comm = WorldComm;
  SHM = Coordinate(processors.size(),1);
 }
 ////////////////////////////////////////////////////////////////////////////////////////////
 // Hugetlbfs mapping intended, use anonymous mmap
 ////////////////////////////////////////////////////////////////////////////////////////////
 #if 1
 void GlobalSharedMemory::SharedMemoryAllocate(uint64_t bytes, int flags)
 {
  std::cout << header "SharedMemoryAllocate "<< bytes<< " GPU implementation "<<std::endl;
  void * ShmCommBuf ; 
  assert(_ShmSetup==1);
  assert(_ShmAlloc==0);
  ///////////////////////////////////////////////////////////////////////////////////////////////////////////
  // Each MPI rank should allocate our own buffer
  ///////////////////////////////////////////////////////////////////////////////////////////////////////////
  ShmCommBuf = acceleratorAllocDevice(bytes);
  if (ShmCommBuf == (void *)NULL ) {
    std::cerr << " SharedMemoryNone.cc acceleratorAllocDevice failed NULL pointer for " << bytes<<" bytes " << std::endl;
    exit(EXIT_FAILURE);  
  }
  if ( WorldRank == 0 ){
    std::cout << WorldRank << header " SharedMemoryNone.cc acceleratorAllocDevice "<< bytes 
 	      << "bytes at "<< std::hex<< ShmCommBuf <<std::dec<<" for comms buffers " <<std::endl;
  }
  SharedMemoryZero(ShmCommBuf,bytes);
  ///////////////////////////////////////////////////////////////////////////////////////////////////////////
  // Loop over ranks/gpu's on our node
  ///////////////////////////////////////////////////////////////////////////////////////////////////////////
  WorldShmCommBufs[0] = ShmCommBuf;
  _ShmAllocBytes=bytes;
  _ShmAlloc=1;
 }
 #else
 void GlobalSharedMemory::SharedMemoryAllocate(uint64_t bytes, int flags)
 {
  void * ShmCommBuf ; 
@@ -117,15 +83,7 @@ void GlobalSharedMemory::SharedMemoryAllocate(uint64_t bytes, int flags)
  _ShmAllocBytes=bytes;
  _ShmAlloc=1;
 };
-#endif
+
 void GlobalSharedMemory::SharedMemoryZero(void *dest,size_t bytes)
 {
  acceleratorMemSet(dest,0,bytes);
 }
 void GlobalSharedMemory::SharedMemoryCopy(void *dest,void *src,size_t bytes)
 {
  acceleratorCopyToDevice(src,dest,bytes);
 }
 ////////////////////////////////////////////////////////
 // Global shared functionality finished
 // Now move to per communicator functionality
--- a/Grid/cshift/Cshift_common.h
+++ b/Grid/cshift/Cshift_common.h
@@ -29,27 +29,8 @@ Author: Peter Boyle <paboyle@ph.ed.ac.uk>
 NAMESPACE_BEGIN(Grid);
-extern std::vector<std::pair<int,int> > Cshift_table; 
+extern Vector<std::pair<int,int> > Cshift_table; 
 extern commVector<std::pair<int,int> > Cshift_table_device; 
 inline std::pair<int,int> *MapCshiftTable(void)
 {
  // GPU version
 #ifdef ACCELERATOR_CSHIFT    
  uint64_t sz=Cshift_table.size();
  if (Cshift_table_device.size()!=sz )    {
    Cshift_table_device.resize(sz);
  }
  acceleratorCopyToDevice((void *)&Cshift_table[0],
 			  (void *)&Cshift_table_device[0],
 			  sizeof(Cshift_table[0])*sz);
  return &Cshift_table_device[0];
 #else 
  return &Cshift_table[0];
 #endif
  // CPU version use identify map
 }
 ///////////////////////////////////////////////////////////////////
 // Gather for when there is no need to SIMD split 
 ///////////////////////////////////////////////////////////////////
@@ -93,8 +74,8 @@ Gather_plane_simple (const Lattice<vobj> &rhs,cshiftVector<vobj> &buffer,int dim
  }
  {
    auto buffer_p = & buffer[0];
-    auto table = MapCshiftTable();
+    auto table = &Cshift_table[0];
-#ifdef ACCELERATOR_CSHIFT
+#ifdef ACCELERATOR_CSHIFT    
    autoView(rhs_v , rhs, AcceleratorRead);
    accelerator_for(i,ent,vobj::Nsimd(),{
 	coalescedWrite(buffer_p[table[i].first],coalescedRead(rhs_v[table[i].second]));
@@ -129,11 +110,9 @@ Gather_plane_extract(const Lattice<vobj> &rhs,
  int n1=rhs.Grid()->_slice_stride[dimension];
  if ( cbmask ==0x3){
-#ifdef ACCELERATOR_CSHIFT
+#ifdef ACCELERATOR_CSHIFT    
    autoView(rhs_v , rhs, AcceleratorRead);
-    accelerator_for(nn,e1*e2,1,{
+    accelerator_for2d(n,e1,b,e2,1,{
 	int n = nn%e1;
 	int b = nn/e1;
 	int o      =   n*n1;
 	int offset = b+n*e2;
@@ -156,9 +135,7 @@ Gather_plane_extract(const Lattice<vobj> &rhs,
    std::cout << " Dense packed buffer WARNING " <<std::endl; // Does this get called twice once for each cb?
 #ifdef ACCELERATOR_CSHIFT    
    autoView(rhs_v , rhs, AcceleratorRead);
-    accelerator_for(nn,e1*e2,1,{
+    accelerator_for2d(n,e1,b,e2,1,{
 	int n = nn%e1;
 	int b = nn/e1;
 	Coordinate coor;
@@ -244,7 +221,7 @@ template<class vobj> void Scatter_plane_simple (Lattice<vobj> &rhs,cshiftVector<
  {
    auto buffer_p = & buffer[0];
-    auto table = MapCshiftTable();
+    auto table = &Cshift_table[0];
 #ifdef ACCELERATOR_CSHIFT    
    autoView( rhs_v, rhs, AcceleratorWrite);
    accelerator_for(i,ent,vobj::Nsimd(),{
@@ -280,9 +257,7 @@ template<class vobj> void Scatter_plane_merge(Lattice<vobj> &rhs,ExtractPointerA
    int _slice_block = rhs.Grid()->_slice_block[dimension];
 #ifdef ACCELERATOR_CSHIFT    
    autoView( rhs_v , rhs, AcceleratorWrite);
-    accelerator_for(nn,e1*e2,1,{
+    accelerator_for2d(n,e1,b,e2,1,{
 	int n = nn%e1;
 	int b = nn/e1;
 	int o      = n*_slice_stride;
 	int offset = b+n*_slice_block;
 	merge(rhs_v[so+o+b],pointers,offset);
@@ -299,7 +274,7 @@ template<class vobj> void Scatter_plane_merge(Lattice<vobj> &rhs,ExtractPointerA
    // Case of SIMD split AND checker dim cannot currently be hit, except in 
    // Test_cshift_red_black code.
-    std::cout << "Scatter_plane merge assert(0); think this is buggy FIXME "<< std::endl;// think this is buggy FIXME
+    //    std::cout << "Scatter_plane merge assert(0); think this is buggy FIXME "<< std::endl;// think this is buggy FIXME
    std::cout<<" Unthreaded warning -- buffer is not densely packed ??"<<std::endl;
    assert(0); // This will fail if hit on GPU
    autoView( rhs_v, rhs, CpuWrite);
@@ -359,7 +334,7 @@ template<class vobj> void Copy_plane(Lattice<vobj>& lhs,const Lattice<vobj> &rhs
  }
  {
-    auto table = MapCshiftTable();
+    auto table = &Cshift_table[0];
 #ifdef ACCELERATOR_CSHIFT    
    autoView(rhs_v , rhs, AcceleratorRead);
    autoView(lhs_v , lhs, AcceleratorWrite);
@@ -411,7 +386,7 @@ template<class vobj> void Copy_plane_permute(Lattice<vobj>& lhs,const Lattice<vo
  }
  {
-    auto table = MapCshiftTable();
+    auto table = &Cshift_table[0];
 #ifdef ACCELERATOR_CSHIFT    
    autoView( rhs_v, rhs, AcceleratorRead);
    autoView( lhs_v, lhs, AcceleratorWrite);
--- a/Grid/cshift/Cshift_mpi.h
+++ b/Grid/cshift/Cshift_mpi.h
@@ -52,8 +52,7 @@ template<class vobj> Lattice<vobj> Cshift(const Lattice<vobj> &rhs,int dimension
  int comm_dim        = rhs.Grid()->_processors[dimension] >1 ;
  int splice_dim      = rhs.Grid()->_simd_layout[dimension]>1 && (comm_dim);
-  RealD t1,t0;
+
  t0=usecond();
  if ( !comm_dim ) {
    //std::cout << "CSHIFT: Cshift_local" <<std::endl;
    Cshift_local(ret,rhs,dimension,shift); // Handles checkerboarding
@@ -64,8 +63,6 @@ template<class vobj> Lattice<vobj> Cshift(const Lattice<vobj> &rhs,int dimension
    //std::cout << "CSHIFT: Cshift_comms" <<std::endl;
    Cshift_comms(ret,rhs,dimension,shift);
  }
  t1=usecond();
  //  std::cout << GridLogPerformance << "Cshift took "<< (t1-t0)/1e3 << " ms"<<std::endl;
  return ret;
 }
@@ -125,25 +122,21 @@ template<class vobj> void Cshift_comms(Lattice<vobj> &ret,const Lattice<vobj> &r
  assert(shift<fd);
  int buffer_size = rhs.Grid()->_slice_nblock[dimension]*rhs.Grid()->_slice_block[dimension];
-  static cshiftVector<vobj> send_buf; send_buf.resize(buffer_size);
+  cshiftVector<vobj> send_buf(buffer_size);
-  static cshiftVector<vobj> recv_buf; recv_buf.resize(buffer_size);
+  cshiftVector<vobj> recv_buf(buffer_size);
  int cb= (cbmask==0x2)? Odd : Even;
  int sshift= rhs.Grid()->CheckerBoardShiftForCB(rhs.Checkerboard(),dimension,shift,cb);
-  RealD tcopy=0.0;
+
  RealD tgather=0.0;
  RealD tscatter=0.0;
  RealD tcomms=0.0;
  uint64_t xbytes=0;
  for(int x=0;x<rd;x++){       
    int sx        =  (x+sshift)%rd;
    int comm_proc = ((x+sshift)/rd)%pd;
    if (comm_proc==0) {
-      tcopy-=usecond();
+
      Copy_plane(ret,rhs,dimension,x,sx,cbmask); 
-      tcopy+=usecond();
+
    } else {
      int words = buffer_size;
@@ -151,39 +144,26 @@ template<class vobj> void Cshift_comms(Lattice<vobj> &ret,const Lattice<vobj> &r
      int bytes = words * sizeof(vobj);
      tgather-=usecond();
      Gather_plane_simple (rhs,send_buf,dimension,sx,cbmask);
      tgather+=usecond();
      //      int rank           = grid->_processor;
      int recv_from_rank;
      int xmit_to_rank;
      grid->ShiftedRanks(dimension,comm_proc,xmit_to_rank,recv_from_rank);
-      
+
-      tcomms-=usecond();
+      grid->Barrier();
      //      grid->Barrier();
      grid->SendToRecvFrom((void *)&send_buf[0],
 			   xmit_to_rank,
 			   (void *)&recv_buf[0],
 			   recv_from_rank,
 			   bytes);
      xbytes+=bytes;
      //      grid->Barrier();
      tcomms+=usecond();
-      tscatter-=usecond();
+      grid->Barrier();
      Scatter_plane_simple (ret,recv_buf,dimension,x,cbmask);
      tscatter+=usecond();
    }
  }
  /*
  std::cout << GridLogPerformance << " Cshift copy    "<<tcopy/1e3<<" ms"<<std::endl;
  std::cout << GridLogPerformance << " Cshift gather  "<<tgather/1e3<<" ms"<<std::endl;
  std::cout << GridLogPerformance << " Cshift scatter "<<tscatter/1e3<<" ms"<<std::endl;
  std::cout << GridLogPerformance << " Cshift comm    "<<tcomms/1e3<<" ms"<<std::endl;
  std::cout << GridLogPerformance << " Cshift BW      "<<(2.0*xbytes)/tcomms<<" MB/s "<<2*xbytes<< " Bytes "<<std::endl;
  */
 }
 template<class vobj> void  Cshift_comms_simd(Lattice<vobj> &ret,const Lattice<vobj> &rhs,int dimension,int shift,int cbmask)
@@ -210,12 +190,6 @@ template<class vobj> void  Cshift_comms_simd(Lattice<vobj> &ret,const Lattice<vo
  assert(shift>=0);
  assert(shift<fd);
  RealD tcopy=0.0;
  RealD tgather=0.0;
  RealD tscatter=0.0;
  RealD tcomms=0.0;
  uint64_t xbytes=0;
  int permute_type=grid->PermuteType(dimension);
  ///////////////////////////////////////////////
@@ -224,8 +198,8 @@ template<class vobj> void  Cshift_comms_simd(Lattice<vobj> &ret,const Lattice<vo
  int buffer_size = grid->_slice_nblock[dimension]*grid->_slice_block[dimension];
  //  int words = sizeof(vobj)/sizeof(vector_type);
-  static std::vector<cshiftVector<scalar_object> >  send_buf_extract; send_buf_extract.resize(Nsimd);
+  std::vector<cshiftVector<scalar_object> >  send_buf_extract(Nsimd);
-  static std::vector<cshiftVector<scalar_object> >  recv_buf_extract; recv_buf_extract.resize(Nsimd);
+  std::vector<cshiftVector<scalar_object> >  recv_buf_extract(Nsimd);
  scalar_object *  recv_buf_extract_mpi;
  scalar_object *  send_buf_extract_mpi;
@@ -253,9 +227,7 @@ template<class vobj> void  Cshift_comms_simd(Lattice<vobj> &ret,const Lattice<vo
      pointers[i] = &send_buf_extract[i][0];
    }
    int sx   = (x+sshift)%rd;
    tgather-=usecond();
    Gather_plane_extract(rhs,pointers,dimension,sx,cbmask);
    tgather+=usecond();
    for(int i=0;i<Nsimd;i++){
@@ -280,8 +252,7 @@ template<class vobj> void  Cshift_comms_simd(Lattice<vobj> &ret,const Lattice<vo
      if(nbr_proc){
 	grid->ShiftedRanks(dimension,nbr_proc,xmit_to_rank,recv_from_rank); 
-	tcomms-=usecond();
+	grid->Barrier();
 	//	grid->Barrier();
 	send_buf_extract_mpi = &send_buf_extract[nbr_lane][0];
 	recv_buf_extract_mpi = &recv_buf_extract[i][0];
@@ -291,9 +262,7 @@ template<class vobj> void  Cshift_comms_simd(Lattice<vobj> &ret,const Lattice<vo
 			     recv_from_rank,
 			     bytes);
-	xbytes+=bytes;
+	grid->Barrier();
 	//	grid->Barrier();
 	tcomms+=usecond();
 	rpointers[i] = &recv_buf_extract[i][0];
      } else { 
@@ -301,17 +270,9 @@ template<class vobj> void  Cshift_comms_simd(Lattice<vobj> &ret,const Lattice<vo
      }
    }
    tscatter-=usecond();
    Scatter_plane_merge(ret,rpointers,dimension,x,cbmask);
    tscatter+=usecond();
  }
-  /*
+
  std::cout << GridLogPerformance << " Cshift (s) copy    "<<tcopy/1e3<<" ms"<<std::endl;
  std::cout << GridLogPerformance << " Cshift (s) gather  "<<tgather/1e3<<" ms"<<std::endl;
  std::cout << GridLogPerformance << " Cshift (s) scatter "<<tscatter/1e3<<" ms"<<std::endl;
  std::cout << GridLogPerformance << " Cshift (s) comm    "<<tcomms/1e3<<" ms"<<std::endl;
  std::cout << GridLogPerformance << " Cshift BW      "<<(2.0*xbytes)/tcomms<<" MB/s "<<2*xbytes<< " Bytes "<<std::endl;
  */
 }
 #else 
 template<class vobj> void Cshift_comms(Lattice<vobj> &ret,const Lattice<vobj> &rhs,int dimension,int shift,int cbmask)
@@ -331,15 +292,10 @@ template<class vobj> void Cshift_comms(Lattice<vobj> &ret,const Lattice<vobj> &r
  assert(comm_dim==1);
  assert(shift>=0);
  assert(shift<fd);
  RealD tcopy=0.0;
  RealD tgather=0.0;
  RealD tscatter=0.0;
  RealD tcomms=0.0;
  uint64_t xbytes=0;
  int buffer_size = rhs.Grid()->_slice_nblock[dimension]*rhs.Grid()->_slice_block[dimension];
-  static cshiftVector<vobj> send_buf_v; send_buf_v.resize(buffer_size);
+  cshiftVector<vobj> send_buf_v(buffer_size);
-  static cshiftVector<vobj> recv_buf_v; recv_buf_v.resize(buffer_size);
+  cshiftVector<vobj> recv_buf_v(buffer_size);
  vobj *send_buf;
  vobj *recv_buf;
  {
@@ -359,9 +315,7 @@ template<class vobj> void Cshift_comms(Lattice<vobj> &ret,const Lattice<vobj> &r
    if (comm_proc==0) {
      tcopy-=usecond();
      Copy_plane(ret,rhs,dimension,x,sx,cbmask); 
      tcopy+=usecond();
    } else {
@@ -370,9 +324,7 @@ template<class vobj> void Cshift_comms(Lattice<vobj> &ret,const Lattice<vobj> &r
      int bytes = words * sizeof(vobj);
      tgather-=usecond();
      Gather_plane_simple (rhs,send_buf_v,dimension,sx,cbmask);
      tgather+=usecond();
      //      int rank           = grid->_processor;
      int recv_from_rank;
@@ -380,8 +332,7 @@ template<class vobj> void Cshift_comms(Lattice<vobj> &ret,const Lattice<vobj> &r
      grid->ShiftedRanks(dimension,comm_proc,xmit_to_rank,recv_from_rank);
-      tcomms-=usecond();
+      grid->Barrier();
      //      grid->Barrier();
      acceleratorCopyDeviceToDevice((void *)&send_buf_v[0],(void *)&send_buf[0],bytes);
      grid->SendToRecvFrom((void *)&send_buf[0],
@@ -389,24 +340,13 @@ template<class vobj> void Cshift_comms(Lattice<vobj> &ret,const Lattice<vobj> &r
 			   (void *)&recv_buf[0],
 			   recv_from_rank,
 			   bytes);
      xbytes+=bytes;
      acceleratorCopyDeviceToDevice((void *)&recv_buf[0],(void *)&recv_buf_v[0],bytes);
-      //      grid->Barrier();
+      grid->Barrier();
      tcomms+=usecond();
      tscatter-=usecond();
      Scatter_plane_simple (ret,recv_buf_v,dimension,x,cbmask);
      tscatter+=usecond();
    }
  }
  /*
  std::cout << GridLogPerformance << " Cshift copy    "<<tcopy/1e3<<" ms"<<std::endl;
  std::cout << GridLogPerformance << " Cshift gather  "<<tgather/1e3<<" ms"<<std::endl;
  std::cout << GridLogPerformance << " Cshift scatter "<<tscatter/1e3<<" ms"<<std::endl;
  std::cout << GridLogPerformance << " Cshift comm    "<<tcomms/1e3<<" ms"<<std::endl;
  std::cout << GridLogPerformance << " Cshift BW      "<<(2.0*xbytes)/tcomms<<" MB/s "<<2*xbytes<< " Bytes "<<std::endl;
  */
 }
 template<class vobj> void  Cshift_comms_simd(Lattice<vobj> &ret,const Lattice<vobj> &rhs,int dimension,int shift,int cbmask)
@@ -432,11 +372,6 @@ template<class vobj> void  Cshift_comms_simd(Lattice<vobj> &ret,const Lattice<vo
  assert(simd_layout==2);
  assert(shift>=0);
  assert(shift<fd);
  RealD tcopy=0.0;
  RealD tgather=0.0;
  RealD tscatter=0.0;
  RealD tcomms=0.0;
  uint64_t xbytes=0;
  int permute_type=grid->PermuteType(dimension);
@@ -446,8 +381,8 @@ template<class vobj> void  Cshift_comms_simd(Lattice<vobj> &ret,const Lattice<vo
  int buffer_size = grid->_slice_nblock[dimension]*grid->_slice_block[dimension];
  //  int words = sizeof(vobj)/sizeof(vector_type);
-  static std::vector<cshiftVector<scalar_object> >  send_buf_extract; send_buf_extract.resize(Nsimd);
+  std::vector<cshiftVector<scalar_object> >  send_buf_extract(Nsimd);
-  static std::vector<cshiftVector<scalar_object> >  recv_buf_extract; recv_buf_extract.resize(Nsimd);
+  std::vector<cshiftVector<scalar_object> >  recv_buf_extract(Nsimd);
  scalar_object *  recv_buf_extract_mpi;
  scalar_object *  send_buf_extract_mpi;
  {
@@ -479,10 +414,8 @@ template<class vobj> void  Cshift_comms_simd(Lattice<vobj> &ret,const Lattice<vo
    for(int i=0;i<Nsimd;i++){       
      pointers[i] = &send_buf_extract[i][0];
    }
    tgather-=usecond();
    int sx   = (x+sshift)%rd;
    Gather_plane_extract(rhs,pointers,dimension,sx,cbmask);
    tgather+=usecond();
    for(int i=0;i<Nsimd;i++){
@@ -507,8 +440,7 @@ template<class vobj> void  Cshift_comms_simd(Lattice<vobj> &ret,const Lattice<vo
      if(nbr_proc){
 	grid->ShiftedRanks(dimension,nbr_proc,xmit_to_rank,recv_from_rank); 
-	tcomms-=usecond();
+	grid->Barrier();
 	//	grid->Barrier();
 	acceleratorCopyDeviceToDevice((void *)&send_buf_extract[nbr_lane][0],(void *)send_buf_extract_mpi,bytes);
 	grid->SendToRecvFrom((void *)send_buf_extract_mpi,
@@ -517,28 +449,17 @@ template<class vobj> void  Cshift_comms_simd(Lattice<vobj> &ret,const Lattice<vo
 			     recv_from_rank,
 			     bytes);
 	acceleratorCopyDeviceToDevice((void *)recv_buf_extract_mpi,(void *)&recv_buf_extract[i][0],bytes);
 	xbytes+=bytes;
-	//	grid->Barrier();
+	grid->Barrier();
 	tcomms+=usecond();
 	rpointers[i] = &recv_buf_extract[i][0];
      } else { 
 	rpointers[i] = &send_buf_extract[nbr_lane][0];
      }
    }
    tscatter-=usecond();
    Scatter_plane_merge(ret,rpointers,dimension,x,cbmask);
    tscatter+=usecond();
  }
-  /*
+
  std::cout << GridLogPerformance << " Cshift (s) copy    "<<tcopy/1e3<<" ms"<<std::endl;
  std::cout << GridLogPerformance << " Cshift (s) gather  "<<tgather/1e3<<" ms"<<std::endl;
  std::cout << GridLogPerformance << " Cshift (s) scatter "<<tscatter/1e3<<" ms"<<std::endl;
  std::cout << GridLogPerformance << " Cshift (s) comm    "<<tcomms/1e3<<" ms"<<std::endl;
  std::cout << GridLogPerformance << " Cshift BW      "<<(2.0*xbytes)/tcomms<<" MB/s"<<std::endl;
  */
 }
 #endif
 NAMESPACE_END(Grid); 
--- a/Grid/cshift/Cshift_table.cc
+++ b/Grid/cshift/Cshift_table.cc
@@ -1,5 +1,4 @@
 #include <Grid/GridCore.h>       
 NAMESPACE_BEGIN(Grid);
-std::vector<std::pair<int,int> > Cshift_table; 
+Vector<std::pair<int,int> > Cshift_table; 
 commVector<std::pair<int,int> > Cshift_table_device; 
 NAMESPACE_END(Grid);
--- a/Grid/json/json.hpp
+++ b/Grid/json/json.hpp
--- a/Grid/lattice/Lattice.h
+++ b/Grid/lattice/Lattice.h
@@ -35,7 +35,6 @@ Author: Peter Boyle <paboyle@ph.ed.ac.uk>
 #include <Grid/lattice/Lattice_transpose.h>
 #include <Grid/lattice/Lattice_local.h>
 #include <Grid/lattice/Lattice_reduction.h>
 #include <Grid/lattice/Lattice_crc.h>
 #include <Grid/lattice/Lattice_peekpoke.h>
 #include <Grid/lattice/Lattice_reality.h>
 #include <Grid/lattice/Lattice_real_imag.h>
@@ -47,4 +46,3 @@ Author: Peter Boyle <paboyle@ph.ed.ac.uk>
 #include <Grid/lattice/Lattice_unary.h>
 #include <Grid/lattice/Lattice_transfer.h>
 #include <Grid/lattice/Lattice_basis.h>
 #include <Grid/lattice/PaddedCell.h>
--- a/Grid/lattice/Lattice_ET.h
+++ b/Grid/lattice/Lattice_ET.h
@@ -63,7 +63,7 @@ accelerator_inline vobj predicatedWhere(const iobj &predicate,
  typename std::remove_const<vobj>::type ret;
  typedef typename vobj::scalar_object scalar_object;
-  //  typedef typename vobj::scalar_type scalar_type;
+  typedef typename vobj::scalar_type scalar_type;
  typedef typename vobj::vector_type vector_type;
  const int Nsimd = vobj::vector_type::Nsimd();
@@ -345,9 +345,7 @@ GridUnopClass(UnaryNot, Not(a));
 GridUnopClass(UnaryTrace, trace(a));
 GridUnopClass(UnaryTranspose, transpose(a));
 GridUnopClass(UnaryTa, Ta(a));
 GridUnopClass(UnarySpTa, SpTa(a));
 GridUnopClass(UnaryProjectOnGroup, ProjectOnGroup(a));
 GridUnopClass(UnaryProjectOnSpGroup, ProjectOnSpGroup(a));
 GridUnopClass(UnaryTimesI, timesI(a));
 GridUnopClass(UnaryTimesMinusI, timesMinusI(a));
 GridUnopClass(UnaryAbs, abs(a));
@@ -458,9 +456,7 @@ GRID_DEF_UNOP(operator!, UnaryNot);
 GRID_DEF_UNOP(trace, UnaryTrace);
 GRID_DEF_UNOP(transpose, UnaryTranspose);
 GRID_DEF_UNOP(Ta, UnaryTa);
 GRID_DEF_UNOP(SpTa, UnarySpTa);
 GRID_DEF_UNOP(ProjectOnGroup, UnaryProjectOnGroup);
 GRID_DEF_UNOP(ProjectOnSpGroup, UnaryProjectOnSpGroup);
 GRID_DEF_UNOP(timesI, UnaryTimesI);
 GRID_DEF_UNOP(timesMinusI, UnaryTimesMinusI);
 GRID_DEF_UNOP(abs, UnaryAbs);  // abs overloaded in cmath C++98; DON'T do the
--- a/Grid/lattice/Lattice_arith.h
+++ b/Grid/lattice/Lattice_arith.h
@@ -36,7 +36,6 @@ NAMESPACE_BEGIN(Grid);
 //////////////////////////////////////////////////////////////////////////////////////////////////////
 template<class obj1,class obj2,class obj3> inline
 void mult(Lattice<obj1> &ret,const Lattice<obj2> &lhs,const Lattice<obj3> &rhs){
  GRID_TRACE("mult");
  ret.Checkerboard() = lhs.Checkerboard();
  autoView( ret_v , ret, AcceleratorWrite);
  autoView( lhs_v , lhs, AcceleratorRead);
@@ -54,7 +53,6 @@ void mult(Lattice<obj1> &ret,const Lattice<obj2> &lhs,const Lattice<obj3> &rhs){
 template<class obj1,class obj2,class obj3> inline
 void mac(Lattice<obj1> &ret,const Lattice<obj2> &lhs,const Lattice<obj3> &rhs){
  GRID_TRACE("mac");
  ret.Checkerboard() = lhs.Checkerboard();
  conformable(ret,rhs);
  conformable(lhs,rhs);
@@ -72,7 +70,6 @@ void mac(Lattice<obj1> &ret,const Lattice<obj2> &lhs,const Lattice<obj3> &rhs){
 template<class obj1,class obj2,class obj3> inline
 void sub(Lattice<obj1> &ret,const Lattice<obj2> &lhs,const Lattice<obj3> &rhs){
  GRID_TRACE("sub");
  ret.Checkerboard() = lhs.Checkerboard();
  conformable(ret,rhs);
  conformable(lhs,rhs);
@@ -89,7 +86,6 @@ void sub(Lattice<obj1> &ret,const Lattice<obj2> &lhs,const Lattice<obj3> &rhs){
 }
 template<class obj1,class obj2,class obj3> inline
 void add(Lattice<obj1> &ret,const Lattice<obj2> &lhs,const Lattice<obj3> &rhs){
  GRID_TRACE("add");
  ret.Checkerboard() = lhs.Checkerboard();
  conformable(ret,rhs);
  conformable(lhs,rhs);
@@ -110,7 +106,6 @@ void add(Lattice<obj1> &ret,const Lattice<obj2> &lhs,const Lattice<obj3> &rhs){
 //////////////////////////////////////////////////////////////////////////////////////////////////////
 template<class obj1,class obj2,class obj3> inline
 void mult(Lattice<obj1> &ret,const Lattice<obj2> &lhs,const obj3 &rhs){
  GRID_TRACE("mult");
  ret.Checkerboard() = lhs.Checkerboard();
  conformable(lhs,ret);
  autoView( ret_v , ret, AcceleratorWrite);
@@ -124,7 +119,6 @@ void mult(Lattice<obj1> &ret,const Lattice<obj2> &lhs,const obj3 &rhs){
 template<class obj1,class obj2,class obj3> inline
 void mac(Lattice<obj1> &ret,const Lattice<obj2> &lhs,const obj3 &rhs){
  GRID_TRACE("mac");
  ret.Checkerboard() = lhs.Checkerboard();
  conformable(ret,lhs);
  autoView( ret_v , ret, AcceleratorWrite);
@@ -139,7 +133,6 @@ void mac(Lattice<obj1> &ret,const Lattice<obj2> &lhs,const obj3 &rhs){
 template<class obj1,class obj2,class obj3> inline
 void sub(Lattice<obj1> &ret,const Lattice<obj2> &lhs,const obj3 &rhs){
  GRID_TRACE("sub");
  ret.Checkerboard() = lhs.Checkerboard();
  conformable(ret,lhs);
  autoView( ret_v , ret, AcceleratorWrite);
@@ -153,7 +146,6 @@ void sub(Lattice<obj1> &ret,const Lattice<obj2> &lhs,const obj3 &rhs){
 }
 template<class obj1,class obj2,class obj3> inline
 void add(Lattice<obj1> &ret,const Lattice<obj2> &lhs,const obj3 &rhs){
  GRID_TRACE("add");
  ret.Checkerboard() = lhs.Checkerboard();
  conformable(lhs,ret);
  autoView( ret_v , ret, AcceleratorWrite);
@@ -171,7 +163,6 @@ void add(Lattice<obj1> &ret,const Lattice<obj2> &lhs,const obj3 &rhs){
 //////////////////////////////////////////////////////////////////////////////////////////////////////
 template<class obj1,class obj2,class obj3> inline
 void mult(Lattice<obj1> &ret,const obj2 &lhs,const Lattice<obj3> &rhs){
  GRID_TRACE("mult");
  ret.Checkerboard() = rhs.Checkerboard();
  conformable(ret,rhs);
  autoView( ret_v , ret, AcceleratorWrite);
@@ -186,7 +177,6 @@ void mult(Lattice<obj1> &ret,const obj2 &lhs,const Lattice<obj3> &rhs){
 template<class obj1,class obj2,class obj3> inline
 void mac(Lattice<obj1> &ret,const obj2 &lhs,const Lattice<obj3> &rhs){
  GRID_TRACE("mac");
  ret.Checkerboard() = rhs.Checkerboard();
  conformable(ret,rhs);
  autoView( ret_v , ret, AcceleratorWrite);
@@ -201,7 +191,6 @@ void mac(Lattice<obj1> &ret,const obj2 &lhs,const Lattice<obj3> &rhs){
 template<class obj1,class obj2,class obj3> inline
 void sub(Lattice<obj1> &ret,const obj2 &lhs,const Lattice<obj3> &rhs){
  GRID_TRACE("sub");
  ret.Checkerboard() = rhs.Checkerboard();
  conformable(ret,rhs);
  autoView( ret_v , ret, AcceleratorWrite);
@@ -215,7 +204,6 @@ void sub(Lattice<obj1> &ret,const obj2 &lhs,const Lattice<obj3> &rhs){
 }
 template<class obj1,class obj2,class obj3> inline
 void add(Lattice<obj1> &ret,const obj2 &lhs,const Lattice<obj3> &rhs){
  GRID_TRACE("add");
  ret.Checkerboard() = rhs.Checkerboard();
  conformable(ret,rhs);
  autoView( ret_v , ret, AcceleratorWrite);
@@ -230,7 +218,6 @@ void add(Lattice<obj1> &ret,const obj2 &lhs,const Lattice<obj3> &rhs){
 template<class sobj,class vobj> inline
 void axpy(Lattice<vobj> &ret,sobj a,const Lattice<vobj> &x,const Lattice<vobj> &y){
  GRID_TRACE("axpy");
  ret.Checkerboard() = x.Checkerboard();
  conformable(ret,x);
  conformable(x,y);
@@ -238,13 +225,12 @@ void axpy(Lattice<vobj> &ret,sobj a,const Lattice<vobj> &x,const Lattice<vobj> &
  autoView( x_v , x, AcceleratorRead);
  autoView( y_v , y, AcceleratorRead);
  accelerator_for(ss,x_v.size(),vobj::Nsimd(),{
-    auto tmp = a*coalescedRead(x_v[ss])+coalescedRead(y_v[ss]);
+    auto tmp = a*x_v(ss)+y_v(ss);
    coalescedWrite(ret_v[ss],tmp);
  });
 }
 template<class sobj,class vobj> inline
 void axpby(Lattice<vobj> &ret,sobj a,sobj b,const Lattice<vobj> &x,const Lattice<vobj> &y){
  GRID_TRACE("axpby");
  ret.Checkerboard() = x.Checkerboard();
  conformable(ret,x);
  conformable(x,y);
@@ -260,52 +246,13 @@ void axpby(Lattice<vobj> &ret,sobj a,sobj b,const Lattice<vobj> &x,const Lattice
 template<class sobj,class vobj> inline
 RealD axpy_norm(Lattice<vobj> &ret,sobj a,const Lattice<vobj> &x,const Lattice<vobj> &y)
 {
  GRID_TRACE("axpy_norm");
    return axpy_norm_fast(ret,a,x,y);
 }
 template<class sobj,class vobj> inline
 RealD axpby_norm(Lattice<vobj> &ret,sobj a,sobj b,const Lattice<vobj> &x,const Lattice<vobj> &y)
 {
  GRID_TRACE("axpby_norm");
    return axpby_norm_fast(ret,a,b,x,y);
 }
 /// Trace product
 template<class obj> auto traceProduct(const Lattice<obj> &rhs_1,const Lattice<obj> &rhs_2)
  -> Lattice<decltype(trace(obj()))>
 {
  typedef decltype(trace(obj())) robj;
  Lattice<robj> ret_i(rhs_1.Grid());
  autoView( rhs1 , rhs_1, AcceleratorRead);
  autoView( rhs2 , rhs_2, AcceleratorRead);
  autoView( ret , ret_i, AcceleratorWrite);
  ret.Checkerboard() = rhs_1.Checkerboard();
  accelerator_for(ss,rhs1.size(),obj::Nsimd(),{
      coalescedWrite(ret[ss],traceProduct(rhs1(ss),rhs2(ss)));
  });
  return ret_i;
 }
 template<class obj1,class obj2> auto traceProduct(const Lattice<obj1> &rhs_1,const obj2 &rhs2)
  -> Lattice<decltype(trace(obj1()))>
 {
  typedef decltype(trace(obj1())) robj;
  Lattice<robj> ret_i(rhs_1.Grid());
  autoView( rhs1 , rhs_1, AcceleratorRead);
  autoView( ret , ret_i, AcceleratorWrite);
  ret.Checkerboard() = rhs_1.Checkerboard();
  accelerator_for(ss,rhs1.size(),obj1::Nsimd(),{
      coalescedWrite(ret[ss],traceProduct(rhs1(ss),rhs2));
  });
  return ret_i;
 }
 template<class obj1,class obj2> auto traceProduct(const obj2 &rhs_2,const Lattice<obj1> &rhs_1)
  -> Lattice<decltype(trace(obj1()))>
 {
  return traceProduct(rhs_1,rhs_2);
 }
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/lattice/Lattice_base.h
+++ b/Grid/lattice/Lattice_base.h
@@ -88,13 +88,6 @@ public:
    LatticeView<vobj> accessor(*( (LatticeAccelerator<vobj> *) this),mode);
    accessor.ViewClose();
  }
  // Helper function to print the state of this object in the AccCache
  void PrintCacheState(void)
  {
    MemoryManager::PrintState(this->_odata);
  }
  /////////////////////////////////////////////////////////////////////////////////
  // Return a view object that may be dereferenced in site loops.
  // The view is trivially copy constructible and may be copied to an accelerator device
@@ -117,7 +110,6 @@ public:
  ////////////////////////////////////////////////////////////////////////////////
  template <typename Op, typename T1> inline Lattice<vobj> & operator=(const LatticeUnaryExpression<Op,T1> &expr)
  {
    GRID_TRACE("ExpressionTemplateEval");
    GridBase *egrid(nullptr);
    GridFromExpression(egrid,expr);
    assert(egrid!=nullptr);
@@ -141,7 +133,6 @@ public:
  }
  template <typename Op, typename T1,typename T2> inline Lattice<vobj> & operator=(const LatticeBinaryExpression<Op,T1,T2> &expr)
  {
    GRID_TRACE("ExpressionTemplateEval");
    GridBase *egrid(nullptr);
    GridFromExpression(egrid,expr);
    assert(egrid!=nullptr);
@@ -165,7 +156,6 @@ public:
  }
  template <typename Op, typename T1,typename T2,typename T3> inline Lattice<vobj> & operator=(const LatticeTrinaryExpression<Op,T1,T2,T3> &expr)
  {
    GRID_TRACE("ExpressionTemplateEval");
    GridBase *egrid(nullptr);
    GridFromExpression(egrid,expr);
    assert(egrid!=nullptr);
@@ -291,8 +281,8 @@ public:
    typename std::enable_if<!std::is_same<robj,vobj>::value,int>::type i=0;
    conformable(*this,r);
    this->checkerboard = r.Checkerboard();
    auto him= r.View(AcceleratorRead);
    auto me =   View(AcceleratorWriteDiscard);
    auto him= r.View(AcceleratorRead);
    accelerator_for(ss,me.size(),vobj::Nsimd(),{
      coalescedWrite(me[ss],him(ss));
    });
@@ -306,8 +296,8 @@ public:
  inline Lattice<vobj> & operator = (const Lattice<vobj> & r){
    this->checkerboard = r.Checkerboard();
    conformable(*this,r);
    auto him= r.View(AcceleratorRead);
    auto me =   View(AcceleratorWriteDiscard);
    auto him= r.View(AcceleratorRead);
    accelerator_for(ss,me.size(),vobj::Nsimd(),{
      coalescedWrite(me[ss],him(ss));
    });
--- a/Grid/lattice/Lattice_basis.h
+++ b/Grid/lattice/Lattice_basis.h
@@ -62,7 +62,7 @@ void basisRotate(VField &basis,Matrix& Qt,int j0, int j1, int k0,int k1,int Nm)
    basis_v.push_back(basis[k].View(AcceleratorWrite));
  }
-#if ( !(defined(GRID_CUDA) || defined(GRID_HIP) || defined(GRID_SYCL)) )
+#if ( (!defined(GRID_SYCL)) && (!defined(GRID_CUDA)) )
  int max_threads = thread_max();
  Vector < vobj > Bt(Nm * max_threads);
  thread_region
@@ -125,7 +125,7 @@ void basisRotate(VField &basis,Matrix& Qt,int j0, int j1, int k0,int k1,int Nm)
 	for(int k=k0; k<k1; ++k){
 	  auto tmp = coalescedRead(Bp[ss*nrot+j]);
-	  coalescedWrite(Bp[ss*nrot+j],tmp+ Qt_p[jj*Nm+k] * coalescedRead(basis_vp[k][sss]));
+	  coalescedWrite(Bp[ss*nrot+j],tmp+ Qt_p[jj*Nm+k] * coalescedRead(basis_v[k][sss]));
 	}
      });
@@ -134,7 +134,7 @@ void basisRotate(VField &basis,Matrix& Qt,int j0, int j1, int k0,int k1,int Nm)
 	int jj  =j0+j;
 	int ss =sj/nrot;
 	int sss=ss+s;
-	coalescedWrite(basis_vp[jj][sss],coalescedRead(Bp[ss*nrot+j]));
+	coalescedWrite(basis_v[jj][sss],coalescedRead(Bp[ss*nrot+j]));
      });
  }
 #endif
@@ -164,8 +164,7 @@ void basisRotateJ(Field &result,std::vector<Field> &basis,Eigen::MatrixXd& Qt,in
  auto basis_vp=& basis_v[0];
  autoView(result_v,result,AcceleratorWrite);
  accelerator_for(ss, grid->oSites(),vobj::Nsimd(),{
-    vobj zzz=Zero();
+    auto B=coalescedRead(zz);
    auto B=coalescedRead(zzz);
    for(int k=k0; k<k1; ++k){
      B +=Qt_j[k] * coalescedRead(basis_vp[k][ss]);
    }
--- a/Grid/lattice/Lattice_crc.h
+++ b/Grid/lattice/Lattice_crc.h
@@ -1,55 +0,0 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./lib/lattice/Lattice_crc.h
    Copyright (C) 2021
 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
 NAMESPACE_BEGIN(Grid);
 template<class vobj> void DumpSliceNorm(std::string s,Lattice<vobj> &f,int mu=-1)
 {
  auto ff = localNorm2(f);
  if ( mu==-1 ) mu = f.Grid()->Nd()-1;
  typedef typename vobj::tensor_reduced normtype;
  typedef typename normtype::scalar_object scalar;
  std::vector<scalar> sff;
  sliceSum(ff,sff,mu);
  for(int t=0;t<sff.size();t++){
    std::cout << s<<" "<<t<<" "<<sff[t]<<std::endl;
  }
 }
 template<class vobj> uint32_t crc(const Lattice<vobj> & buf)
 {
  autoView( buf_v , buf, CpuRead);
  return ::crc32(0L,(unsigned char *)&buf_v[0],(size_t)sizeof(vobj)*buf.oSites());
 }
 #define CRC(U) std::cerr << "FingerPrint "<<__FILE__ <<" "<< __LINE__ <<" "<< #U <<" "<<crc(U)<<std::endl;
 NAMESPACE_END(Grid);
--- a/Grid/lattice/Lattice_matrix_reduction.h
+++ b/Grid/lattice/Lattice_matrix_reduction.h
@@ -32,6 +32,7 @@ template<class vobj>
 static void sliceMaddMatrix (Lattice<vobj> &R,Eigen::MatrixXcd &aa,const Lattice<vobj> &X,const Lattice<vobj> &Y,int Orthog,RealD scale=1.0) 
 {    
  typedef typename vobj::scalar_object sobj;
  typedef typename vobj::scalar_type scalar_type;
  typedef typename vobj::vector_type vector_type;
  int Nblock = X.Grid()->GlobalDimensions()[Orthog];
@@ -81,6 +82,7 @@ template<class vobj>
 static void sliceMulMatrix (Lattice<vobj> &R,Eigen::MatrixXcd &aa,const Lattice<vobj> &X,int Orthog,RealD scale=1.0) 
 {    
  typedef typename vobj::scalar_object sobj;
  typedef typename vobj::scalar_type scalar_type;
  typedef typename vobj::vector_type vector_type;
  int Nblock = X.Grid()->GlobalDimensions()[Orthog];
@@ -128,6 +130,7 @@ template<class vobj>
 static void sliceInnerProductMatrix(  Eigen::MatrixXcd &mat, const Lattice<vobj> &lhs,const Lattice<vobj> &rhs,int Orthog) 
 {
  typedef typename vobj::scalar_object sobj;
  typedef typename vobj::scalar_type scalar_type;
  typedef typename vobj::vector_type vector_type;
  GridBase *FullGrid  = lhs.Grid();
--- a/Grid/lattice/Lattice_peekpoke.h
+++ b/Grid/lattice/Lattice_peekpoke.h
@@ -96,6 +96,9 @@ void pokeSite(const sobj &s,Lattice<vobj> &l,const Coordinate &site){
  GridBase *grid=l.Grid();
  typedef typename vobj::scalar_type scalar_type;
  typedef typename vobj::vector_type vector_type;
  int Nsimd = grid->Nsimd();
  assert( l.Checkerboard()== l.Grid()->CheckerBoard(site));
@@ -122,17 +125,14 @@ void pokeSite(const sobj &s,Lattice<vobj> &l,const Coordinate &site){
 //////////////////////////////////////////////////////////
 // Peek a scalar object from the SIMD array
 //////////////////////////////////////////////////////////
 template<class vobj>
 typename vobj::scalar_object peekSite(const Lattice<vobj> &l,const Coordinate &site){
  typename vobj::scalar_object s;
  peekSite(s,l,site);
  return s;
 }        
 template<class vobj,class sobj>
 void peekSite(sobj &s,const Lattice<vobj> &l,const Coordinate &site){
  GridBase *grid=l.Grid();
  typedef typename vobj::scalar_type scalar_type;
  typedef typename vobj::vector_type vector_type;
  int Nsimd = grid->Nsimd();
  assert( l.Checkerboard() == l.Grid()->CheckerBoard(site));
@@ -173,11 +173,11 @@ inline void peekLocalSite(sobj &s,const LatticeView<vobj> &l,Coordinate &site)
  idx= grid->iIndex(site);
  odx= grid->oIndex(site);
-  const vector_type *vp = (const vector_type *) &l[odx];
+  scalar_type * vp = (scalar_type *)&l[odx];
  scalar_type * pt = (scalar_type *)&s;
  for(int w=0;w<words;w++){
-    pt[w] = getlane(vp[w],idx);
+    pt[w] = vp[idx+w*Nsimd];
  }
  return;
@@ -210,10 +210,10 @@ inline void pokeLocalSite(const sobj &s,LatticeView<vobj> &l,Coordinate &site)
  idx= grid->iIndex(site);
  odx= grid->oIndex(site);
-  vector_type * vp = (vector_type *)&l[odx];
+  scalar_type * vp = (scalar_type *)&l[odx];
  scalar_type * pt = (scalar_type *)&s;
  for(int w=0;w<words;w++){
-    putlane(vp[w],pt[w],idx);
+    vp[idx+w*Nsimd] = pt[w];
  }
  return;
 };
--- a/Grid/lattice/Lattice_reduction.h
+++ b/Grid/lattice/Lattice_reduction.h
@@ -28,10 +28,6 @@ Author: Christoph Lehner <christoph@lhnr.de>
 #if defined(GRID_CUDA)||defined(GRID_HIP)
 #include <Grid/lattice/Lattice_reduction_gpu.h>
 #endif
 #if defined(GRID_SYCL)
 #include <Grid/lattice/Lattice_reduction_sycl.h>
 #endif
 #include <Grid/lattice/Lattice_slicesum_core.h>
 NAMESPACE_BEGIN(Grid);
@@ -95,40 +91,17 @@ inline typename vobj::scalar_objectD sumD_cpu(const vobj *arg, Integer osites)
  for(int i=0;i<nthread;i++){
    ssum = ssum+sumarray[i];
  } 
-  return ssum;
+  
  typedef typename vobj::scalar_object ssobj;
  ssobj ret = ssum;
  return ret;
 }
 /*
 Threaded max, don't use for now
 template<class Double>
 inline Double max(const Double *arg, Integer osites)
 {
  //  const int Nsimd = vobj::Nsimd();
  const int nthread = GridThread::GetThreads();
-  std::vector<Double> maxarray(nthread);
+
  thread_for(thr,nthread, {
    int nwork, mywork, myoff;
    nwork = osites;
    GridThread::GetWork(nwork,thr,mywork,myoff);
    Double max=arg[0];
    for(int ss=myoff;ss<mywork+myoff; ss++){
      if( arg[ss] > max ) max = arg[ss];
    }
    maxarray[thr]=max;
  });
  Double tmax=maxarray[0];
  for(int i=0;i<nthread;i++){
    if (maxarray[i]>tmax) tmax = maxarray[i];
  } 
  return tmax;
 }
 */
 template<class vobj>
 inline typename vobj::scalar_object sum(const vobj *arg, Integer osites)
 {
-#if defined(GRID_CUDA)||defined(GRID_HIP)||defined(GRID_SYCL)
+#if defined(GRID_CUDA)||defined(GRID_HIP)
  return sum_gpu(arg,osites);
 #else
  return sum_cpu(arg,osites);
@@ -137,61 +110,25 @@ inline typename vobj::scalar_object sum(const vobj *arg, Integer osites)
 template<class vobj>
 inline typename vobj::scalar_objectD sumD(const vobj *arg, Integer osites)
 {
-#if defined(GRID_CUDA)||defined(GRID_HIP)||defined(GRID_SYCL)
+#if defined(GRID_CUDA)||defined(GRID_HIP)
  return sumD_gpu(arg,osites);
 #else
  return sumD_cpu(arg,osites);
 #endif  
 }
 template<class vobj>
 inline typename vobj::scalar_objectD sumD_large(const vobj *arg, Integer osites)
 {
 #if defined(GRID_CUDA)||defined(GRID_HIP)||defined(GRID_SYCL)
  return sumD_gpu_large(arg,osites);
 #else
  return sumD_cpu(arg,osites);
 #endif  
 }
 template<class vobj>
 inline typename vobj::scalar_object rankSum(const Lattice<vobj> &arg)
 {
  Integer osites = arg.Grid()->oSites();
 #if defined(GRID_CUDA)||defined(GRID_HIP)||defined(GRID_SYCL)
  autoView( arg_v, arg, AcceleratorRead);
  return sum_gpu(&arg_v[0],osites);
 #else
  autoView(arg_v, arg, CpuRead);
  return sum_cpu(&arg_v[0],osites);
 #endif  
 }
 template<class vobj>
 inline typename vobj::scalar_object sum(const Lattice<vobj> &arg)
 {
-  auto ssum = rankSum(arg);
+#if defined(GRID_CUDA)||defined(GRID_HIP)
  arg.Grid()->GlobalSum(ssum);
  return ssum;
 }
 template<class vobj>
 inline typename vobj::scalar_object rankSumLarge(const Lattice<vobj> &arg)
 {
 #if defined(GRID_CUDA)||defined(GRID_HIP)||defined(GRID_SYCL)
  autoView( arg_v, arg, AcceleratorRead);
  Integer osites = arg.Grid()->oSites();
-  return sum_gpu_large(&arg_v[0],osites);
+  auto ssum= sum_gpu(&arg_v[0],osites);
 #else
  autoView(arg_v, arg, CpuRead);
  Integer osites = arg.Grid()->oSites();
-  return sum_cpu(&arg_v[0],osites);
+  auto ssum= sum_cpu(&arg_v[0],osites);
-#endif
+#endif  
 }
 template<class vobj>
 inline typename vobj::scalar_object sum_large(const Lattice<vobj> &arg)
 {
  auto ssum = rankSumLarge(arg);
  arg.Grid()->GlobalSum(ssum);
  return ssum;
 }
@@ -204,36 +141,11 @@ template<class vobj> inline RealD norm2(const Lattice<vobj> &arg){
  return real(nrm); 
 }
 //The global maximum of the site norm2
 template<class vobj> inline RealD maxLocalNorm2(const Lattice<vobj> &arg)
 {
  typedef typename vobj::tensor_reduced vscalar;  //iScalar<iScalar<.... <vPODtype> > >
  typedef typename vscalar::scalar_object  scalar;   //iScalar<iScalar<.... <PODtype> > >
  Lattice<vscalar> inner = localNorm2(arg);
  auto grid = arg.Grid();
  RealD max;
  for(int l=0;l<grid->lSites();l++){
    Coordinate coor;
    scalar val;
    RealD r;
    grid->LocalIndexToLocalCoor(l,coor);
    peekLocalSite(val,inner,coor);
    r=real(TensorRemove(val));
    if( (l==0) || (r>max)){
      max=r;
    }
  }
  grid->GlobalMax(max);
  return max;
 }
 // Double inner product
 template<class vobj>
 inline ComplexD rankInnerProduct(const Lattice<vobj> &left,const Lattice<vobj> &right)
 {
  typedef typename vobj::scalar_type scalar_type;
  typedef typename vobj::vector_typeD vector_type;
  ComplexD  nrm;
@@ -243,67 +155,33 @@ inline ComplexD rankInnerProduct(const Lattice<vobj> &left,const Lattice<vobj> &
  const uint64_t sites = grid->oSites();
  // Might make all code paths go this way.
 #if 0
  typedef decltype(innerProductD(vobj(),vobj())) inner_t;
  Vector<inner_t> inner_tmp(sites);
  auto inner_tmp_v = &inner_tmp[0];
  {
    autoView( left_v , left, AcceleratorRead);
    autoView( right_v,right, AcceleratorRead);
    // This code could read coalesce
    // GPU - SIMT lane compliance...
    accelerator_for( ss, sites, nsimd,{
 	auto x_l = left_v(ss);
 	auto y_l = right_v(ss);
 	coalescedWrite(inner_tmp_v[ss],innerProductD(x_l,y_l));
    });
  }
 #else
  typedef decltype(innerProduct(vobj(),vobj())) inner_t;
  Vector<inner_t> inner_tmp(sites);
  auto inner_tmp_v = &inner_tmp[0];
  {
    autoView( left_v , left, AcceleratorRead);
    autoView( right_v,right, AcceleratorRead);
    // GPU - SIMT lane compliance...
-    accelerator_for( ss, sites, nsimd,{
+    accelerator_for( ss, sites, 1,{
-	auto x_l = left_v(ss);
+	auto x_l = left_v[ss];
-	auto y_l = right_v(ss);
+	auto y_l = right_v[ss];
-	coalescedWrite(inner_tmp_v[ss],innerProduct(x_l,y_l));
+	inner_tmp_v[ss]=innerProductD(x_l,y_l);
    });
  }
-#endif
+
  // This is in single precision and fails some tests
-  auto anrm = sumD(inner_tmp_v,sites);  
+  auto anrm = sum(inner_tmp_v,sites);  
  nrm = anrm;
  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);
  RealD local = real(nrm);
  FlightRecorder::NormLog(real(nrm)); 
  grid->GlobalSum(nrm);
  FlightRecorder::ReductionLog(local,real(nrm)); 
  return nrm;
 }
@@ -327,7 +205,8 @@ axpby_norm_fast(Lattice<vobj> &z,sobj a,sobj b,const Lattice<vobj> &x,const Latt
  conformable(z,x);
  conformable(x,y);
-  //  typedef typename vobj::vector_typeD vector_type;
+  typedef typename vobj::scalar_type scalar_type;
  typedef typename vobj::vector_typeD vector_type;
  RealD  nrm;
  GridBase *grid = x.Grid();
@@ -339,29 +218,17 @@ axpby_norm_fast(Lattice<vobj> &z,sobj a,sobj b,const Lattice<vobj> &x,const Latt
  autoView( x_v, x, AcceleratorRead);
  autoView( y_v, y, AcceleratorRead);
  autoView( z_v, z, AcceleratorWrite);
-#if 0
+
  typedef decltype(innerProductD(x_v[0],y_v[0])) inner_t;
  Vector<inner_t> inner_tmp(sites);
  auto inner_tmp_v = &inner_tmp[0];
-  accelerator_for( ss, sites, nsimd,{
+  accelerator_for( ss, sites, 1,{
-      auto tmp = a*x_v(ss)+b*y_v(ss);
+      auto tmp = a*x_v[ss]+b*y_v[ss];
-      coalescedWrite(inner_tmp_v[ss],innerProductD(tmp,tmp));
+      inner_tmp_v[ss]=innerProductD(tmp,tmp);
-      coalescedWrite(z_v[ss],tmp);
+      z_v[ss]=tmp;
  });
  nrm = real(TensorRemove(sum(inner_tmp_v,sites)));
 #else
  typedef decltype(innerProduct(x_v[0],y_v[0])) inner_t;
  Vector<inner_t> inner_tmp(sites);
  auto inner_tmp_v = &inner_tmp[0];
  accelerator_for( ss, sites, nsimd,{
      auto tmp = a*x_v(ss)+b*y_v(ss);
      coalescedWrite(inner_tmp_v[ss],innerProduct(tmp,tmp));
      coalescedWrite(z_v[ss],tmp);
  });
  nrm = real(TensorRemove(sumD(inner_tmp_v,sites)));
 #endif
  grid->GlobalSum(nrm);
  return nrm; 
 }
@@ -371,6 +238,7 @@ innerProductNorm(ComplexD& ip, RealD &nrm, const Lattice<vobj> &left,const Latti
 {
  conformable(left,right);
  typedef typename vobj::scalar_type scalar_type;
  typedef typename vobj::vector_typeD vector_type;
  Vector<ComplexD> tmp(2);
@@ -441,7 +309,6 @@ template<class vobj> inline void sliceSum(const Lattice<vobj> &Data,std::vector<
  // But easily avoided by using double precision fields
  ///////////////////////////////////////////////////////
  typedef typename vobj::scalar_object sobj;
  typedef typename vobj::scalar_object::scalar_type scalar_type;
  GridBase  *grid = Data.Grid();
  assert(grid!=NULL);
@@ -467,10 +334,19 @@ template<class vobj> inline void sliceSum(const Lattice<vobj> &Data,std::vector<
  int e1=    grid->_slice_nblock[orthogdim];
  int e2=    grid->_slice_block [orthogdim];
  int stride=grid->_slice_stride[orthogdim];
-  int ostride=grid->_ostride[orthogdim];
+
-  
+  // sum over reduced dimension planes, breaking out orthog dir
-  //Reduce Data down to lvSum
+  // Parallel over orthog direction
-  sliceSumReduction(Data,lvSum,rd, e1,e2,stride,ostride,Nsimd);
+  autoView( Data_v, Data, CpuRead);
  thread_for( r,rd, {
    int so=r*grid->_ostride[orthogdim]; // base offset for start of plane 
    for(int n=0;n<e1;n++){
      for(int b=0;b<e2;b++){
 	int ss= so+n*stride+b;
 	lvSum[r]=lvSum[r]+Data_v[ss];
      }
    }
  });
  // Sum across simd lanes in the plane, breaking out orthog dir.
  Coordinate icoor(Nd);
@@ -491,29 +367,21 @@ template<class vobj> inline void sliceSum(const Lattice<vobj> &Data,std::vector<
  }
  // sum over nodes.
  sobj gsum;
  for(int t=0;t<fd;t++){
    int pt = t/ld; // processor plane
    int lt = t%ld;
    if ( pt == grid->_processor_coor[orthogdim] ) {
-      result[t]=lsSum[lt];
+      gsum=lsSum[lt];
    } else {
-      result[t]=Zero();
+      gsum=Zero();
    }
-  }
+    grid->GlobalSum(gsum);
  scalar_type * ptr = (scalar_type *) &result[0];
  int words = fd*sizeof(sobj)/sizeof(scalar_type);
  grid->GlobalSumVector(ptr, words);
 }
 template<class vobj> inline
 std::vector<typename vobj::scalar_object> 
 sliceSum(const Lattice<vobj> &Data,int orthogdim)
 {
  std::vector<typename vobj::scalar_object> result;
  sliceSum(Data,result,orthogdim);
  return result;
 }
    result[t]=gsum;
  }
 }
 template<class vobj>
 static void sliceInnerProductVector( std::vector<ComplexD> & result, const Lattice<vobj> &lhs,const Lattice<vobj> &rhs,int orthogdim) 
@@ -618,8 +486,7 @@ static void sliceNorm (std::vector<RealD> &sn,const Lattice<vobj> &rhs,int Ortho
 template<class vobj>
 static void sliceMaddVector(Lattice<vobj> &R,std::vector<RealD> &a,const Lattice<vobj> &X,const Lattice<vobj> &Y,
 			    int orthogdim,RealD scale=1.0) 
-{
+{    
  // perhaps easier to just promote A to a field and use regular madd
  typedef typename vobj::scalar_object sobj;
  typedef typename vobj::scalar_type scalar_type;
  typedef typename vobj::vector_type vector_type;
@@ -650,7 +517,8 @@ static void sliceMaddVector(Lattice<vobj> &R,std::vector<RealD> &a,const Lattice
    for(int l=0;l<Nsimd;l++){
      grid->iCoorFromIindex(icoor,l);
      int ldx =r+icoor[orthogdim]*rd;
-      av.putlane(scalar_type(a[ldx])*zscale,l);
+      scalar_type *as =(scalar_type *)&av;
      as[l] = scalar_type(a[ldx])*zscale;
    }
    tensor_reduced at; at=av;
@@ -690,6 +558,7 @@ template<class vobj>
 static void sliceMaddMatrix (Lattice<vobj> &R,Eigen::MatrixXcd &aa,const Lattice<vobj> &X,const Lattice<vobj> &Y,int Orthog,RealD scale=1.0) 
 {    
  typedef typename vobj::scalar_object sobj;
  typedef typename vobj::scalar_type scalar_type;
  typedef typename vobj::vector_type vector_type;
  int Nblock = X.Grid()->GlobalDimensions()[Orthog];
@@ -743,6 +612,7 @@ template<class vobj>
 static void sliceMulMatrix (Lattice<vobj> &R,Eigen::MatrixXcd &aa,const Lattice<vobj> &X,int Orthog,RealD scale=1.0) 
 {    
  typedef typename vobj::scalar_object sobj;
  typedef typename vobj::scalar_type scalar_type;
  typedef typename vobj::vector_type vector_type;
  int Nblock = X.Grid()->GlobalDimensions()[Orthog];
@@ -796,6 +666,7 @@ template<class vobj>
 static void sliceInnerProductMatrix(  Eigen::MatrixXcd &mat, const Lattice<vobj> &lhs,const Lattice<vobj> &rhs,int Orthog) 
 {
  typedef typename vobj::scalar_object sobj;
  typedef typename vobj::scalar_type scalar_type;
  typedef typename vobj::vector_type vector_type;
  GridBase *FullGrid  = lhs.Grid();
--- a/Grid/lattice/Lattice_reduction_gpu.h
+++ b/Grid/lattice/Lattice_reduction_gpu.h
@@ -23,27 +23,28 @@ unsigned int nextPow2(Iterator x) {
 }
 template <class Iterator>
-int getNumBlocksAndThreads(const Iterator n, const size_t sizeofsobj, Iterator &threads, Iterator &blocks) {
+void getNumBlocksAndThreads(const Iterator n, const size_t sizeofsobj, Iterator &threads, Iterator &blocks) {
  int device;
 #ifdef GRID_CUDA
  cudaGetDevice(&device);
 #endif
 #ifdef GRID_HIP
-  auto r=hipGetDevice(&device);
+  hipGetDevice(&device);
 #endif
  Iterator warpSize            = gpu_props[device].warpSize;
  Iterator sharedMemPerBlock   = gpu_props[device].sharedMemPerBlock;
  Iterator maxThreadsPerBlock  = gpu_props[device].maxThreadsPerBlock;
  Iterator multiProcessorCount = gpu_props[device].multiProcessorCount;
-  /*  
+  
  std::cout << GridLogDebug << "GPU has:" << std::endl;
  std::cout << GridLogDebug << "\twarpSize            = " << warpSize << std::endl;
  std::cout << GridLogDebug << "\tsharedMemPerBlock   = " << sharedMemPerBlock << std::endl;
  std::cout << GridLogDebug << "\tmaxThreadsPerBlock  = " << maxThreadsPerBlock << std::endl;
  std::cout << GridLogDebug << "\tmaxThreadsPerBlock  = " << warpSize << std::endl;
  std::cout << GridLogDebug << "\tmultiProcessorCount = " << multiProcessorCount << std::endl;
-  */  
+  
  if (warpSize != WARP_SIZE) {
    std::cout << GridLogError << "The warp size of the GPU in use does not match the warp size set when compiling Grid." << std::endl;
    exit(EXIT_FAILURE);
@@ -51,14 +52,10 @@ int getNumBlocksAndThreads(const Iterator n, const size_t sizeofsobj, Iterator &
  // let the number of threads in a block be a multiple of 2, starting from warpSize
  threads = warpSize;
  if ( threads*sizeofsobj > sharedMemPerBlock ) {
    std::cout << GridLogError << "The object is too large for the shared memory." << std::endl;
    return 0;
  }
  while( 2*threads*sizeofsobj < sharedMemPerBlock && 2*threads <= maxThreadsPerBlock ) threads *= 2;
  // keep all the streaming multiprocessors busy
  blocks = nextPow2(multiProcessorCount);
-  return 1;
+  
 }
 template <class sobj, class Iterator>
@@ -198,7 +195,7 @@ __global__ void reduceKernel(const vobj *lat, sobj *buffer, Iterator n) {
 // Possibly promote to double and sum
 /////////////////////////////////////////////////////////////////////////////////////////////////////////
 template <class vobj>
-inline typename vobj::scalar_objectD sumD_gpu_small(const vobj *lat, Integer osites) 
+inline typename vobj::scalar_objectD sumD_gpu(const vobj *lat, Integer osites) 
 {
  typedef typename vobj::scalar_objectD sobj;
  typedef decltype(lat) Iterator;
@@ -207,77 +204,17 @@ inline typename vobj::scalar_objectD sumD_gpu_small(const vobj *lat, Integer osi
  Integer size = osites*nsimd;
  Integer numThreads, numBlocks;
-  int ok = getNumBlocksAndThreads(size, sizeof(sobj), numThreads, numBlocks);
+  getNumBlocksAndThreads(size, sizeof(sobj), numThreads, numBlocks);
  assert(ok);
  Integer smemSize = numThreads * sizeof(sobj);
-  // Move out of UVM
+
  // Turns out I had messed up the synchronise after move to compute stream
  // as running this on the default stream fools the synchronise
 #undef UVM_BLOCK_BUFFER  
 #ifndef UVM_BLOCK_BUFFER  
  commVector<sobj> buffer(numBlocks);
  sobj *buffer_v = &buffer[0];
  sobj result;
  reduceKernel<<< numBlocks, numThreads, smemSize, computeStream >>>(lat, buffer_v, size);
  accelerator_barrier();
  acceleratorCopyFromDevice(buffer_v,&result,sizeof(result));
 #else
  Vector<sobj> buffer(numBlocks);
  sobj *buffer_v = &buffer[0];
-  sobj result;
+  
-  reduceKernel<<< numBlocks, numThreads, smemSize, computeStream >>>(lat, buffer_v, size);
+  reduceKernel<<< numBlocks, numThreads, smemSize >>>(lat, buffer_v, size);
  accelerator_barrier();
-  result = *buffer_v;
+  auto result = buffer_v[0];
 #endif
  return result;
 }
 template <class vobj>
 inline typename vobj::scalar_objectD sumD_gpu_large(const vobj *lat, Integer osites)
 {
  typedef typename vobj::vector_type  vector;
  typedef typename vobj::scalar_typeD scalarD;
  typedef typename vobj::scalar_objectD sobj;
  sobj ret;
  scalarD *ret_p = (scalarD *)&ret;
  const int words = sizeof(vobj)/sizeof(vector);
  Vector<vector> buffer(osites);
  vector *dat = (vector *)lat;
  vector *buf = &buffer[0];
  iScalar<vector> *tbuf =(iScalar<vector> *)  &buffer[0];
  for(int w=0;w<words;w++) {
    accelerator_for(ss,osites,1,{
 	buf[ss] = dat[ss*words+w];
      });
    ret_p[w] = sumD_gpu_small(tbuf,osites);
  }
  return ret;
 }
 template <class vobj>
 inline typename vobj::scalar_objectD sumD_gpu(const vobj *lat, Integer osites)
 {
  typedef typename vobj::scalar_objectD sobj;
  sobj ret;
  Integer nsimd= vobj::Nsimd();
  Integer size = osites*nsimd;
  Integer numThreads, numBlocks;
  int ok = getNumBlocksAndThreads(size, sizeof(sobj), numThreads, numBlocks);
  if ( ok ) {
    ret = sumD_gpu_small(lat,osites);
  } else {
    ret = sumD_gpu_large(lat,osites);
  }
  return ret;
 }
 /////////////////////////////////////////////////////////////////////////////////////////////////////////
 // Return as same precision as input performing reduction in double precision though
 /////////////////////////////////////////////////////////////////////////////////////////////////////////
@@ -290,13 +227,6 @@ inline typename vobj::scalar_object sum_gpu(const vobj *lat, Integer osites)
  return result;
 }
-template <class vobj>
+
 inline typename vobj::scalar_object sum_gpu_large(const vobj *lat, Integer osites)
 {
  typedef typename vobj::scalar_object sobj;
  sobj result;
  result = sumD_gpu_large(lat,osites);
  return result;
 }
 NAMESPACE_END(Grid);
--- a/Grid/lattice/Lattice_reduction_sycl.h
+++ b/Grid/lattice/Lattice_reduction_sycl.h
@@ -1,126 +0,0 @@
 NAMESPACE_BEGIN(Grid);
 /////////////////////////////////////////////////////////////////////////////////////////////////////////
 // Possibly promote to double and sum
 /////////////////////////////////////////////////////////////////////////////////////////////////////////
 template <class vobj>
 inline typename vobj::scalar_objectD sumD_gpu_tensor(const vobj *lat, Integer osites) 
 {
  typedef typename vobj::scalar_object sobj;
  typedef typename vobj::scalar_objectD sobjD;
  sobj *mysum =(sobj *) malloc_shared(sizeof(sobj),*theGridAccelerator);
  sobj identity; zeroit(identity);
  sobj ret ; 
  Integer nsimd= vobj::Nsimd();
  theGridAccelerator->submit([&](cl::sycl::handler &cgh) {
     auto Reduction = cl::sycl::reduction(mysum,identity,std::plus<>());
     cgh.parallel_for(cl::sycl::range<1>{osites},
 		      Reduction,
 		      [=] (cl::sycl::id<1> item, auto &sum) {
      auto osite   = item[0];
      sum +=Reduce(lat[osite]);
     });
   });
  theGridAccelerator->wait();
  ret = mysum[0];
  free(mysum,*theGridAccelerator);
  sobjD dret; convertType(dret,ret);
  return dret;
 }
 template <class vobj>
 inline typename vobj::scalar_objectD sumD_gpu_large(const vobj *lat, Integer osites)
 {
  return sumD_gpu_tensor(lat,osites);
 }
 template <class vobj>
 inline typename vobj::scalar_objectD sumD_gpu_small(const vobj *lat, Integer osites)
 {
  return sumD_gpu_large(lat,osites);
 }
 template <class vobj>
 inline typename vobj::scalar_objectD sumD_gpu(const vobj *lat, Integer osites)
 {
  return sumD_gpu_large(lat,osites);
 }
 /////////////////////////////////////////////////////////////////////////////////////////////////////////
 // Return as same precision as input performing reduction in double precision though
 /////////////////////////////////////////////////////////////////////////////////////////////////////////
 template <class vobj>
 inline typename vobj::scalar_object sum_gpu(const vobj *lat, Integer osites) 
 {
  typedef typename vobj::scalar_object sobj;
  sobj result;
  result = sumD_gpu(lat,osites);
  return result;
 }
 template <class vobj>
 inline typename vobj::scalar_object sum_gpu_large(const vobj *lat, Integer osites)
 {
  typedef typename vobj::scalar_object sobj;
  sobj result;
  result = sumD_gpu_large(lat,osites);
  return result;
 }
 template<class Word> Word svm_xor(Word *vec,uint64_t L)
 {
  Word xorResult; xorResult = 0;
  Word *d_sum =(Word *)cl::sycl::malloc_shared(sizeof(Word),*theGridAccelerator);
  Word identity;  identity=0;
  theGridAccelerator->submit([&](cl::sycl::handler &cgh) {
     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];
     });
   });
  theGridAccelerator->wait();
  Word ret = d_sum[0];
  free(d_sum,*theGridAccelerator);
  return ret;
 }
 NAMESPACE_END(Grid);
 /*
 template <class vobj>
 inline typename vobj::scalar_objectD sumD_gpu_repack(const vobj *lat, Integer osites)
 {
  typedef typename vobj::vector_type  vector;
  typedef typename vobj::scalar_type  scalar;
  typedef typename vobj::scalar_typeD scalarD;
  typedef typename vobj::scalar_objectD sobjD;
  sobjD ret;
  scalarD *ret_p = (scalarD *)&ret;
  const int nsimd = vobj::Nsimd();
  const int words = sizeof(vobj)/sizeof(vector);
  Vector<scalar> buffer(osites*nsimd);
  scalar *buf = &buffer[0];
  vector *dat = (vector *)lat;
  for(int w=0;w<words;w++) {
    accelerator_for(ss,osites,nsimd,{
 	int lane = acceleratorSIMTlane(nsimd);
 	buf[ss*nsimd+lane] = dat[ss*words+w].getlane(lane);
    });
    //Precision change at this point is to late to gain precision
    ret_p[w] = svm_reduce(buf,nsimd*osites);
  }
  return ret;
 }
 */
--- a/Grid/lattice/Lattice_rng.h
+++ b/Grid/lattice/Lattice_rng.h
@@ -152,7 +152,6 @@ public:
 #ifdef RNG_FAST_DISCARD
  static void Skip(RngEngine &eng,uint64_t site)
  {
 #if 0
    /////////////////////////////////////////////////////////////////////////////////////
    // Skip by 2^40 elements between successive lattice sites
    // This goes by 10^12.
@@ -163,9 +162,9 @@ public:
    // tens of seconds per trajectory so this is clean in all reasonable cases,
    // and margin of safety is orders of magnitude.
    // We could hack Sitmo to skip in the higher order words of state if necessary
-    //
+      //
-    // Replace with 2^30 ; avoid problem on large volumes
+      // Replace with 2^30 ; avoid problem on large volumes
-    //
+      //
    /////////////////////////////////////////////////////////////////////////////////////
    //      uint64_t skip = site+1;  //   Old init Skipped then drew.  Checked compat with faster init
    const int shift = 30;
@@ -180,9 +179,6 @@ public:
    assert((skip >> shift)==site); // check for overflow
    eng.discard(skip);
 #else
    eng.discardhi(site);
 #endif
    //      std::cout << " Engine  " <<site << " state " <<eng<<std::endl;
  } 
 #endif
@@ -411,7 +407,7 @@ public:
      std::cout << GridLogMessage << "Seed SHA256: " << GridChecksum::sha256_string(seeds) << std::endl;
      SeedFixedIntegers(seeds);
    }
-  void SeedFixedIntegers(const std::vector<int> &seeds, int britney=0){
+  void SeedFixedIntegers(const std::vector<int> &seeds){
    // Everyone generates the same seed_seq based on input seeds
    CartesianCommunicator::BroadcastWorld(0,(void *)&seeds[0],sizeof(int)*seeds.size());
@@ -428,29 +424,22 @@ public:
    // MT implementation does not implement fast discard even though
    // in principle this is possible
    ////////////////////////////////////////////////
    thread_for( lidx, _grid->lSites(), {
-	int gidx;
+    // Everybody loops over global volume.
    thread_for( gidx, _grid->_gsites, {
 	// Where is it?
 	int rank;
 	int o_idx;
 	int i_idx;
-	int rank;
+
 	Coordinate pcoor;
 	Coordinate lcoor;
 	Coordinate gcoor;
-	_grid->LocalIndexToLocalCoor(lidx,lcoor);
+	_grid->GlobalIndexToGlobalCoor(gidx,gcoor);
 	pcoor=_grid->ThisProcessorCoor();
 	_grid->ProcessorCoorLocalCoorToGlobalCoor(pcoor,lcoor,gcoor);
 	_grid->GlobalCoorToGlobalIndex(gcoor,gidx);
 	_grid->GlobalCoorToRankIndex(rank,o_idx,i_idx,gcoor);
 	assert(rank == _grid->ThisRank() );
-	int l_idx=generator_idx(o_idx,i_idx);
+	// If this is one of mine we take it
-	_generators[l_idx] = master_engine;
+	if( rank == _grid->ThisRank() ){
-	if ( britney ) { 
+	  int l_idx=generator_idx(o_idx,i_idx);
-	  Skip(_generators[l_idx],l_idx); // Skip to next RNG sequence
+	  _generators[l_idx] = master_engine;
 	} else { 	
 	  Skip(_generators[l_idx],gidx); // Skip to next RNG sequence
 	}
    });
--- a/Grid/lattice/Lattice_slicesum_core.h
+++ b/Grid/lattice/Lattice_slicesum_core.h
@@ -1,224 +0,0 @@
 #pragma once
 #if defined(GRID_CUDA)
 #include <cub/cub.cuh>
 #define gpucub cub
 #define gpuError_t cudaError_t
 #define gpuSuccess cudaSuccess
 #elif defined(GRID_HIP)
 #include <hipcub/hipcub.hpp>
 #define gpucub hipcub
 #define gpuError_t hipError_t
 #define gpuSuccess hipSuccess
 #endif
 NAMESPACE_BEGIN(Grid);
 #if defined(GRID_CUDA) || defined(GRID_HIP)
 template<class vobj> inline void sliceSumReduction_cub_small(const vobj *Data, Vector<vobj> &lvSum, const int rd, const int e1, const int e2, const int stride, const int ostride, const int Nsimd) {
  size_t subvol_size = e1*e2;
  commVector<vobj> reduction_buffer(rd*subvol_size);
  auto rb_p = &reduction_buffer[0];
  vobj zero_init;
  zeroit(zero_init);
  void *temp_storage_array = NULL;
  size_t temp_storage_bytes = 0;
  vobj *d_out;
  int* d_offsets;
  std::vector<int> offsets(rd+1,0);
  for (int i = 0; i < offsets.size(); i++) {
    offsets[i] = i*subvol_size;
  }
  //Allocate memory for output and offset arrays on device
  d_out = static_cast<vobj*>(acceleratorAllocDevice(rd*sizeof(vobj)));
  d_offsets = static_cast<int*>(acceleratorAllocDevice((rd+1)*sizeof(int)));
  //copy offsets to device
  acceleratorCopyToDeviceAsync(&offsets[0],d_offsets,sizeof(int)*(rd+1),computeStream);
  gpuError_t gpuErr = gpucub::DeviceSegmentedReduce::Reduce(temp_storage_array, temp_storage_bytes, rb_p,d_out, rd, d_offsets, d_offsets+1, ::gpucub::Sum(), zero_init, computeStream);
  if (gpuErr!=gpuSuccess) {
    std::cout << GridLogError << "Lattice_slicesum_gpu.h: Encountered error during gpucub::DeviceSegmentedReduce::Reduce (setup)! Error: " << gpuErr <<std::endl;
    exit(EXIT_FAILURE);
  }
  //allocate memory for temp_storage_array  
  temp_storage_array = acceleratorAllocDevice(temp_storage_bytes);
  //prepare buffer for reduction
  //use non-blocking accelerator_for to avoid syncs (ok because we submit to same computeStream)
  //use 2d accelerator_for to avoid launch latencies found when serially looping over rd 
  accelerator_for2dNB( s,subvol_size, r,rd, Nsimd,{ 
    int n = s / e2;
    int b = s % e2;
    int so=r*ostride; // base offset for start of plane 
    int ss= so+n*stride+b;
    coalescedWrite(rb_p[r*subvol_size+s], coalescedRead(Data[ss]));
  });
  //issue segmented reductions in computeStream
  gpuErr = gpucub::DeviceSegmentedReduce::Reduce(temp_storage_array, temp_storage_bytes, rb_p, d_out, rd, d_offsets, d_offsets+1,::gpucub::Sum(), zero_init, computeStream);
  if (gpuErr!=gpuSuccess) {
    std::cout << GridLogError << "Lattice_slicesum_gpu.h: Encountered error during gpucub::DeviceSegmentedReduce::Reduce! Error: " << gpuErr <<std::endl;
    exit(EXIT_FAILURE);
  }
  acceleratorCopyFromDeviceAsync(d_out,&lvSum[0],rd*sizeof(vobj),computeStream);
  //sync after copy
  accelerator_barrier();
  acceleratorFreeDevice(temp_storage_array);
  acceleratorFreeDevice(d_out);
  acceleratorFreeDevice(d_offsets);
 }
 #endif 
 #if defined(GRID_SYCL)
 template<class vobj> inline void sliceSumReduction_sycl_small(const vobj *Data, Vector <vobj> &lvSum, const int  &rd, const int &e1, const int &e2, const int &stride, const int &ostride, const int &Nsimd)
 {
  size_t subvol_size = e1*e2;
  vobj *mysum = (vobj *) malloc_shared(rd*sizeof(vobj),*theGridAccelerator);
  vobj vobj_zero;
  zeroit(vobj_zero);
  for (int r = 0; r<rd; r++) { 
    mysum[r] = vobj_zero; 
  }
  commVector<vobj> reduction_buffer(rd*subvol_size);    
  auto rb_p = &reduction_buffer[0];
  // autoView(Data_v, Data, AcceleratorRead);
  //prepare reduction buffer 
  accelerator_for2d( s,subvol_size, r,rd, (size_t)Nsimd,{ 
      int n = s / e2;
      int b = s % e2;
      int so=r*ostride; // base offset for start of plane 
      int ss= so+n*stride+b;
      coalescedWrite(rb_p[r*subvol_size+s], coalescedRead(Data[ss]));
  });
  for (int r = 0; r < rd; r++) {
      theGridAccelerator->submit([&](cl::sycl::handler &cgh) {
          auto Reduction = cl::sycl::reduction(&mysum[r],std::plus<>());
          cgh.parallel_for(cl::sycl::range<1>{subvol_size},
          Reduction,
          [=](cl::sycl::id<1> item, auto &sum) {
              auto s = item[0];
              sum += rb_p[r*subvol_size+s];
          });
      });
  }
  theGridAccelerator->wait();
  for (int r = 0; r < rd; r++) {
    lvSum[r] = mysum[r];
  }
  free(mysum,*theGridAccelerator);
 }
 #endif
 template<class vobj> inline void sliceSumReduction_large(const vobj *Data, Vector<vobj> &lvSum, const int rd, const int e1, const int e2, const int stride, const int ostride, const int Nsimd) {
  typedef typename vobj::vector_type vector;
  const int words = sizeof(vobj)/sizeof(vector);
  const int osites = rd*e1*e2;
  commVector<vector>buffer(osites);
  vector *dat = (vector *)Data;
  vector *buf = &buffer[0];
  Vector<vector> lvSum_small(rd);
  vector *lvSum_ptr = (vector *)&lvSum[0];
  for (int w = 0; w < words; w++) {
    accelerator_for(ss,osites,1,{
 	    buf[ss] = dat[ss*words+w];
    });
    #if defined(GRID_CUDA) || defined(GRID_HIP)
      sliceSumReduction_cub_small(buf,lvSum_small,rd,e1,e2,stride, ostride,Nsimd);
    #elif defined(GRID_SYCL)
      sliceSumReduction_sycl_small(buf,lvSum_small,rd,e1,e2,stride, ostride,Nsimd);
    #endif
    for (int r = 0; r < rd; r++) {
      lvSum_ptr[w+words*r]=lvSum_small[r];
    }
  }
 }
 template<class vobj> inline void sliceSumReduction_gpu(const Lattice<vobj> &Data, Vector<vobj> &lvSum, const int rd, const int e1, const int e2, const int stride, const int ostride, const int Nsimd)
 {
  autoView(Data_v, Data, AcceleratorRead); //reduction libraries cannot deal with large vobjs so we split into small/large case.
    if constexpr (sizeof(vobj) <= 256) { 
      #if defined(GRID_CUDA) || defined(GRID_HIP)
        sliceSumReduction_cub_small(&Data_v[0], lvSum, rd, e1, e2, stride, ostride, Nsimd);
      #elif defined (GRID_SYCL)
        sliceSumReduction_sycl_small(&Data_v[0], lvSum, rd, e1, e2, stride, ostride, Nsimd);
      #endif
    }
    else {
      sliceSumReduction_large(&Data_v[0], lvSum, rd, e1, e2, stride, ostride, Nsimd);
    }
 }
 template<class vobj> inline void sliceSumReduction_cpu(const Lattice<vobj> &Data, Vector<vobj> &lvSum, const int &rd, const int &e1, const int &e2, const int &stride, const int &ostride, const int &Nsimd)
 {
  // sum over reduced dimension planes, breaking out orthog dir
  // Parallel over orthog direction
  autoView( Data_v, Data, CpuRead);
  thread_for( r,rd, {
    int so=r*ostride; // base offset for start of plane 
    for(int n=0;n<e1;n++){
      for(int b=0;b<e2;b++){
        int ss= so+n*stride+b;
        lvSum[r]=lvSum[r]+Data_v[ss];
      }
    }
  });
 }
 template<class vobj> inline void sliceSumReduction(const Lattice<vobj> &Data, Vector<vobj> &lvSum, const int &rd, const int &e1, const int &e2, const int &stride, const int &ostride, const int &Nsimd) 
 {
  #if defined(GRID_CUDA) || defined(GRID_HIP) || defined(GRID_SYCL)
  sliceSumReduction_gpu(Data, lvSum, rd, e1, e2, stride, ostride, Nsimd);
  #else
  sliceSumReduction_cpu(Data, lvSum, rd, e1, e2, stride, ostride, Nsimd);
  #endif
 }
 NAMESPACE_END(Grid);
--- a/Grid/lattice/Lattice_trace.h
+++ b/Grid/lattice/Lattice_trace.h
@@ -66,65 +66,6 @@ inline auto TraceIndex(const Lattice<vobj> &lhs) -> Lattice<decltype(traceIndex<
  return ret;
 };
 template<int N, class Vec>
 Lattice<iScalar<iScalar<iScalar<Vec> > > > Determinant(const Lattice<iScalar<iScalar<iMatrix<Vec, N> > > > &Umu)
 {
  GridBase *grid=Umu.Grid();
  auto lvol = grid->lSites();
  Lattice<iScalar<iScalar<iScalar<Vec> > > > ret(grid);
  typedef typename Vec::scalar_type scalar;
  autoView(Umu_v,Umu,CpuRead);
  autoView(ret_v,ret,CpuWrite);
  thread_for(site,lvol,{
    Eigen::MatrixXcd EigenU = Eigen::MatrixXcd::Zero(N,N);
    Coordinate lcoor;
    grid->LocalIndexToLocalCoor(site, lcoor);
    iScalar<iScalar<iMatrix<scalar, N> > > Us;
    peekLocalSite(Us, Umu_v, lcoor);
    for(int i=0;i<N;i++){
      for(int j=0;j<N;j++){
 	scalar tmp= Us()()(i,j);
 	ComplexD ztmp(real(tmp),imag(tmp));
 	EigenU(i,j)=ztmp;
      }}
    ComplexD detD  = EigenU.determinant();
    typename Vec::scalar_type det(detD.real(),detD.imag());
    pokeLocalSite(det,ret_v,lcoor);
  });
  return ret;
 }
 template<int N>
 Lattice<iScalar<iScalar<iMatrix<vComplexD, N> > > > Inverse(const Lattice<iScalar<iScalar<iMatrix<vComplexD, N> > > > &Umu)
 {
  GridBase *grid=Umu.Grid();
  auto lvol = grid->lSites();
  Lattice<iScalar<iScalar<iMatrix<vComplexD, N> > > > ret(grid);
  autoView(Umu_v,Umu,CpuRead);
  autoView(ret_v,ret,CpuWrite);
  thread_for(site,lvol,{
    Eigen::MatrixXcd EigenU = Eigen::MatrixXcd::Zero(N,N);
    Coordinate lcoor;
    grid->LocalIndexToLocalCoor(site, lcoor);
    iScalar<iScalar<iMatrix<ComplexD, N> > > Us;
    iScalar<iScalar<iMatrix<ComplexD, N> > > Ui;
    peekLocalSite(Us, Umu_v, lcoor);
    for(int i=0;i<N;i++){
      for(int j=0;j<N;j++){
 	EigenU(i,j) = Us()()(i,j);
      }}
    Eigen::MatrixXcd EigenUinv = EigenU.inverse();
    for(int i=0;i<N;i++){
      for(int j=0;j<N;j++){
 	Ui()()(i,j) = EigenUinv(i,j);
      }}
    pokeLocalSite(Ui,ret_v,lcoor);
  });
  return ret;
 }
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/lattice/Lattice_transfer.h
+++ b/Grid/lattice/Lattice_transfer.h
@@ -85,76 +85,6 @@ template<class vobj> inline void setCheckerboard(Lattice<vobj> &full,const Latti
  });
 }
 template<class vobj> inline void acceleratorPickCheckerboard(int cb,Lattice<vobj> &half,const Lattice<vobj> &full, int checker_dim_half=0)
 {
  half.Checkerboard() = cb;
  autoView(half_v, half, AcceleratorWrite);
  autoView(full_v, full, AcceleratorRead);
  Coordinate rdim_full             = full.Grid()->_rdimensions;
  Coordinate rdim_half             = half.Grid()->_rdimensions;
  unsigned long ndim_half          = half.Grid()->_ndimension;
  Coordinate checker_dim_mask_half = half.Grid()->_checker_dim_mask;
  Coordinate ostride_half          = half.Grid()->_ostride;
  accelerator_for(ss, full.Grid()->oSites(),full.Grid()->Nsimd(),{
    Coordinate coor;
    int cbos;
    int linear=0;
    Lexicographic::CoorFromIndex(coor,ss,rdim_full);
    assert(coor.size()==ndim_half);
    for(int d=0;d<ndim_half;d++){ 
      if(checker_dim_mask_half[d]) linear += coor[d];
    }
    cbos = (linear&0x1);
    if (cbos==cb) {
      int ssh=0;
      for(int d=0;d<ndim_half;d++) {
        if (d == checker_dim_half) ssh += ostride_half[d] * ((coor[d] / 2) % rdim_half[d]);
        else ssh += ostride_half[d] * (coor[d] % rdim_half[d]);
      }
      coalescedWrite(half_v[ssh],full_v(ss));
    }
  });
 }
 template<class vobj> inline void acceleratorSetCheckerboard(Lattice<vobj> &full,const Lattice<vobj> &half, int checker_dim_half=0)
 {
  int cb = half.Checkerboard();
  autoView(half_v , half, AcceleratorRead);
  autoView(full_v , full, AcceleratorWrite);
  Coordinate rdim_full             = full.Grid()->_rdimensions;
  Coordinate rdim_half             = half.Grid()->_rdimensions;
  unsigned long ndim_half          = half.Grid()->_ndimension;
  Coordinate checker_dim_mask_half = half.Grid()->_checker_dim_mask;
  Coordinate ostride_half          = half.Grid()->_ostride;
  accelerator_for(ss,full.Grid()->oSites(),full.Grid()->Nsimd(),{
    Coordinate coor;
    int cbos;
    int linear=0;
    Lexicographic::CoorFromIndex(coor,ss,rdim_full);
    assert(coor.size()==ndim_half);
    for(int d=0;d<ndim_half;d++){ 
      if(checker_dim_mask_half[d]) linear += coor[d];
    }
    cbos = (linear&0x1);
    if (cbos==cb) {
      int ssh=0;
      for(int d=0;d<ndim_half;d++){
        if (d == checker_dim_half) ssh += ostride_half[d] * ((coor[d] / 2) % rdim_half[d]);
        else ssh += ostride_half[d] * (coor[d] % rdim_half[d]);
      }
      coalescedWrite(full_v[ss],half_v(ssh));
    }
  });
 }
 ////////////////////////////////////////////////////////////////////////////////////////////
 // Flexible Type Conversion for internal promotion to double as well as graceful
 // treatment of scalar-compatible types
@@ -167,20 +97,6 @@ accelerator_inline void convertType(ComplexF & out, const std::complex<float> &
  out = in;
 }
 template<typename T>
 accelerator_inline EnableIf<isGridFundamental<T>> convertType(T & out, const T & in) {
  out = in;
 }
 // This would allow for conversions between GridFundamental types, but is not strictly needed as yet
 /*template<typename T1, typename T2>
 accelerator_inline typename std::enable_if<isGridFundamental<T1>::value && isGridFundamental<T2>::value>::type
 // Or to make this very broad, conversions between anything that's not a GridTensor could be allowed
 //accelerator_inline typename std::enable_if<!isGridTensor<T1>::value && !isGridTensor<T2>::value>::type
 convertType(T1 & out, const T2 & in) {
  out = in;
 }*/
 #ifdef GRID_SIMT
 accelerator_inline void convertType(vComplexF & out, const ComplexF & in) {
  ((ComplexF*)&out)[acceleratorSIMTlane(vComplexF::Nsimd())] = in;
@@ -194,25 +110,25 @@ accelerator_inline void convertType(vComplexD2 & out, const ComplexD & in) {
 #endif
 accelerator_inline void convertType(vComplexF & out, const vComplexD2 & in) {
-  precisionChange(out,in);
+  out.v = Optimization::PrecisionChange::DtoS(in._internal[0].v,in._internal[1].v);
 }
 accelerator_inline void convertType(vComplexD2 & out, const vComplexF & in) {
-  precisionChange(out,in);
+  Optimization::PrecisionChange::StoD(in.v,out._internal[0].v,out._internal[1].v);
 }
-template<typename T1,typename T2>
+template<typename T1,typename T2,int N>
-accelerator_inline void convertType(iScalar<T1> & out, const iScalar<T2> & in) {
+  accelerator_inline void convertType(iMatrix<T1,N> & out, const iMatrix<T2,N> & in);
-  convertType(out._internal,in._internal);
+template<typename T1,typename T2,int N>
-}
+  accelerator_inline void convertType(iVector<T1,N> & out, const iVector<T2,N> & in);
-template<typename T1,typename T2>
+template<typename T1,typename T2, typename std::enable_if<!isGridScalar<T1>::value, T1>::type* = nullptr>
-accelerator_inline NotEnableIf<isGridScalar<T1>> convertType(T1 & out, const iScalar<T2> & in) {
+accelerator_inline void convertType(T1 & out, const iScalar<T2> & in) {
  convertType(out,in._internal);
 }
 template<typename T1,typename T2>
-accelerator_inline NotEnableIf<isGridScalar<T2>> convertType(iScalar<T1> & out, const T2 & in) {
+accelerator_inline void convertType(iScalar<T1> & out, const T2 & in) {
  convertType(out._internal,in);
 }
@@ -229,6 +145,11 @@ accelerator_inline void convertType(iVector<T1,N> & out, const iVector<T2,N> & i
    convertType(out._internal[i],in._internal[i]);
 }
 template<typename T, typename std::enable_if<isGridFundamental<T>::value, T>::type* = nullptr>
 accelerator_inline void convertType(T & out, const T & in) {
  out = in;
 }
 template<typename T1,typename T2>
 accelerator_inline void convertType(Lattice<T1> & out, const Lattice<T2> & in) {
  autoView( out_v , out,AcceleratorWrite);
@@ -288,36 +209,7 @@ inline void blockProject(Lattice<iVector<CComplex,nbasis > > &coarseData,
    blockZAXPY(fineDataRed,ip,Basis[v],fineDataRed); 
  }
 }
 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,
                               const VLattice &Basis)
 {
  int NBatch = fineData.size();
  assert(coarseData.size() == NBatch);
  GridBase * fine  = fineData[0].Grid();
  GridBase * coarse= coarseData[0].Grid();
  Lattice<iScalar<CComplex>> ip(coarse);
  std::vector<Lattice<vobj>> fineDataCopy = fineData;
  autoView(ip_, ip, AcceleratorWrite);
  for(int v=0;v<nbasis;v++) {
    for (int k=0; k<NBatch; k++) {
      autoView( coarseData_ , coarseData[k], AcceleratorWrite);
      blockInnerProductD(ip,Basis[v],fineDataCopy[k]); // ip = <basis|fine>
      accelerator_for( sc, coarse->oSites(), vobj::Nsimd(), {
        convertType(coarseData_[sc](v),ip_[sc]);
      });
      // improve numerical stability of projection
      // |fine> = |fine> - <basis|fine> |basis>
      ip=-ip;
      blockZAXPY(fineDataCopy[k],ip,Basis[v],fineDataCopy[k]); 
    }
  }
 }
 template<class vobj,class vobj2,class CComplex>
  inline void blockZAXPY(Lattice<vobj> &fineZ,
@@ -463,20 +355,16 @@ inline void blockSum(Lattice<vobj> &coarseData,const Lattice<vobj> &fineData)
  autoView( coarseData_ , coarseData, AcceleratorWrite);
  autoView( fineData_   , fineData, AcceleratorRead);
  auto coarseData_p = &coarseData_[0];
  auto fineData_p = &fineData_[0];
  Coordinate fine_rdimensions = fine->_rdimensions;
  Coordinate coarse_rdimensions = coarse->_rdimensions;
-
+  
  accelerator_for(sc,coarse->oSites(),1,{
      // One thread per sub block
      Coordinate coor_c(_ndimension);
      Lexicographic::CoorFromIndex(coor_c,sc,coarse_rdimensions);  // Block coordinate
      coarseData_[sc]=Zero();
      vobj cd = Zero();
      for(int sb=0;sb<blockVol;sb++){
 	int sf;
@@ -486,11 +374,9 @@ 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];
+	coarseData_[sc]=coarseData_[sc]+fineData_[sf];
      }
      coarseData_p[sc] = cd;
    });
  return;
 }
@@ -617,26 +503,6 @@ inline void blockPromote(const Lattice<iVector<CComplex,nbasis > > &coarseData,
 }
 #endif
 template<class vobj,class CComplex,int nbasis,class VLattice>
 inline void batchBlockPromote(const std::vector<Lattice<iVector<CComplex,nbasis>>> &coarseData,
                               std::vector<Lattice<vobj>> &fineData,
                               const VLattice &Basis)
 {
  int NBatch = coarseData.size();
  assert(fineData.size() == NBatch);
  GridBase * fine   = fineData[0].Grid();
  GridBase * coarse = coarseData[0].Grid();
  for (int k=0; k<NBatch; k++)
    fineData[k]=Zero();
  for (int i=0;i<nbasis;i++) {
    for (int k=0; k<NBatch; k++) {
      Lattice<iScalar<CComplex>> ip = PeekIndex<0>(coarseData[k],i);
      blockZAXPY(fineData[k],ip,Basis[i],fineData[k]);
    }
  }
 }
 // Useful for precision conversion, or indeed anything where an operator= does a conversion on scalars.
 // Simd layouts need not match since we use peek/poke Local
 template<class vobj,class vvobj>
@@ -695,68 +561,8 @@ 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
  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;
  autoView(from_v,From,AcceleratorRead);
  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;
      int from_oidx = *tt++;
      int from_lane = *tt++;
      int to_oidx = *tt++;
      int to_lane = *tt;
      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);
      }
    });
  acceleratorFreeDevice(table_d);    
  free(table);
 #else  
  Coordinate ldf = Fg->_ldimensions;
  Coordinate rdf = Fg->_rdimensions;
  Coordinate isf = Fg->_istride;
@@ -765,9 +571,9 @@ void localCopyRegion(const Lattice<vobj> &From,Lattice<vobj> & To,Coordinate Fro
  Coordinate ist = Tg->_istride;
  Coordinate ost = Tg->_ostride;
-  autoView( t_v , To, CpuWrite);
+  autoView( t_v , To, AcceleratorWrite);
-  autoView( f_v , From, CpuRead);
+  autoView( f_v , From, AcceleratorRead);
-  thread_for(idx,Fg->lSites(),{
+  accelerator_for(idx,Fg->lSites(),1,{
    sobj s;
    Coordinate Fcoor(nd);
    Coordinate Tcoor(nd);
@@ -780,24 +586,17 @@ void localCopyRegion(const Lattice<vobj> &From,Lattice<vobj> & To,Coordinate Fro
      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]);
-      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]);
-      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]);
-      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]);
      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);
+	tp[idx_t+w*Nsimd] = fp[idx_f+w*Nsimd];  // FIXME IF RRII layout, type pun no worke
      }
 #else
    peekLocalSite(s,f_v,Fcoor);
    pokeLocalSite(s,t_v,Tcoor);
 #endif
    }
  });
 #endif
 }
@@ -890,8 +689,6 @@ void ExtractSlice(Lattice<vobj> &lowDim,const Lattice<vobj> & higherDim,int slic
 }
 //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)
 {
@@ -908,70 +705,11 @@ void InsertSliceLocal(const Lattice<vobj> &lowDim, Lattice<vobj> & higherDim,int
  for(int d=0;d<nh;d++){
    if ( d!=orthog ) {
-      assert(lg->_processors[d]  == hg->_processors[d]);
+    assert(lg->_processors[d]  == hg->_processors[d]);
-      assert(lg->_ldimensions[d] == hg->_ldimensions[d]);
+    assert(lg->_ldimensions[d] == hg->_ldimensions[d]);
-    }
+  }
  }
 #if 1
  size_t nsite = lg->lSites()/lg->LocalDimensions()[orthog];
  size_t tbytes = 4*nsite*sizeof(int);
  int *table = (int*)malloc(tbytes);
  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);
@@ -987,7 +725,6 @@ void InsertSliceLocal(const Lattice<vobj> &lowDim, Lattice<vobj> & higherDim,int
      pokeLocalSite(s,higherDimv,hcoor);
    }
  });
 #endif
 }
@@ -1031,7 +768,7 @@ void ExtractSliceLocal(Lattice<vobj> &lowDim,const Lattice<vobj> & higherDim,int
 template<class vobj>
-void Replicate(const Lattice<vobj> &coarse,Lattice<vobj> & fine)
+void Replicate(Lattice<vobj> &coarse,Lattice<vobj> & fine)
 {
  typedef typename vobj::scalar_object sobj;
@@ -1256,27 +993,9 @@ vectorizeFromRevLexOrdArray( std::vector<sobj> &in, Lattice<vobj> &out)
  });
 }
-//Very fast precision change. Requires in/out objects to reside on same Grid (e.g. by using double2 for the double-precision field)
+//Convert a Lattice from one precision to another
 template<class VobjOut, class VobjIn>
-void precisionChangeFast(Lattice<VobjOut> &out, const Lattice<VobjIn> &in)
+void precisionChange(Lattice<VobjOut> &out, const Lattice<VobjIn> &in)
 {
  typedef typename VobjOut::vector_type Vout;
  typedef typename VobjIn::vector_type Vin;
  const int N = sizeof(VobjOut)/sizeof(Vout);
  conformable(out.Grid(),in.Grid());
  out.Checkerboard() = in.Checkerboard();
  int nsimd = out.Grid()->Nsimd();
  autoView( out_v  , out, AcceleratorWrite);
  autoView(  in_v ,   in, AcceleratorRead);
  accelerator_for(idx,out.Grid()->oSites(),1,{
      Vout *vout = (Vout *)&out_v[idx];
      Vin  *vin  = (Vin  *)&in_v[idx];
      precisionChange(vout,vin,N);
  });
 }
 //Convert a Lattice from one precision to another (original, slow implementation)
 template<class VobjOut, class VobjIn>
 void precisionChangeOrig(Lattice<VobjOut> &out, const Lattice<VobjIn> &in)
 {
  assert(out.Grid()->Nd() == in.Grid()->Nd());
  for(int d=0;d<out.Grid()->Nd();d++){
@@ -1291,7 +1010,7 @@ void precisionChangeOrig(Lattice<VobjOut> &out, const Lattice<VobjIn> &in)
  int ndim = out.Grid()->Nd();
  int out_nsimd = out_grid->Nsimd();
-  int in_nsimd = in_grid->Nsimd();
+    
  std::vector<Coordinate > out_icoor(out_nsimd);
  for(int lane=0; lane < out_nsimd; lane++){
@@ -1322,128 +1041,6 @@ void precisionChangeOrig(Lattice<VobjOut> &out, const Lattice<VobjIn> &in)
  });
 }
 //The workspace for a precision change operation allowing for the reuse of the mapping to save time on subsequent calls
 class precisionChangeWorkspace{
  std::pair<Integer,Integer>* fmap_device; //device pointer
  //maintain grids for checking
  GridBase* _out_grid;
  GridBase* _in_grid;
 public:
  precisionChangeWorkspace(GridBase *out_grid, GridBase *in_grid): _out_grid(out_grid), _in_grid(in_grid){
    //Build a map between the sites and lanes of the output field and the input field as we cannot use the Grids on the device
    assert(out_grid->Nd() == in_grid->Nd());
    for(int d=0;d<out_grid->Nd();d++){
      assert(out_grid->FullDimensions()[d] == in_grid->FullDimensions()[d]);
    }
    int Nsimd_out = out_grid->Nsimd();
    std::vector<Coordinate> out_icorrs(out_grid->Nsimd()); //reuse these
    for(int lane=0; lane < out_grid->Nsimd(); lane++)
      out_grid->iCoorFromIindex(out_icorrs[lane], lane);
    std::vector<std::pair<Integer,Integer> > fmap_host(out_grid->lSites()); //lsites = osites*Nsimd
    thread_for(out_oidx,out_grid->oSites(),{
 	Coordinate out_ocorr; 
 	out_grid->oCoorFromOindex(out_ocorr, out_oidx);
 	Coordinate lcorr; //the local coordinate (common to both in and out as full coordinate)
 	for(int out_lane=0; out_lane < Nsimd_out; out_lane++){
 	  out_grid->InOutCoorToLocalCoor(out_ocorr, out_icorrs[out_lane], lcorr);
 	  //int in_oidx = in_grid->oIndex(lcorr), in_lane = in_grid->iIndex(lcorr);
 	  //Note oIndex and OcorrFromOindex (and same for iIndex) are not inverse for checkerboarded lattice, the former coordinates being defined on the full lattice and the latter on the reduced lattice
 	  //Until this is fixed we need to circumvent the problem locally. Here I will use the coordinates defined on the reduced lattice for simplicity
 	  int in_oidx = 0, in_lane = 0;
 	  for(int d=0;d<in_grid->_ndimension;d++){
 	    in_oidx += in_grid->_ostride[d] * ( lcorr[d] % in_grid->_rdimensions[d] );
 	    in_lane += in_grid->_istride[d] * ( lcorr[d] / in_grid->_rdimensions[d] );
 	  }
 	  fmap_host[out_lane + Nsimd_out*out_oidx] = std::pair<Integer,Integer>( in_oidx, in_lane );
 	}
      });
    //Copy the map to the device (if we had a way to tell if an accelerator is in use we could avoid this copy for CPU-only machines)
    size_t fmap_bytes = out_grid->lSites() * sizeof(std::pair<Integer,Integer>);
    fmap_device = (std::pair<Integer,Integer>*)acceleratorAllocDevice(fmap_bytes);
    acceleratorCopyToDevice(fmap_host.data(), fmap_device, fmap_bytes); 
  }
  //Prevent moving or copying
  precisionChangeWorkspace(const precisionChangeWorkspace &r) = delete;
  precisionChangeWorkspace(precisionChangeWorkspace &&r) = delete;
  precisionChangeWorkspace &operator=(const precisionChangeWorkspace &r) = delete;
  precisionChangeWorkspace &operator=(precisionChangeWorkspace &&r) = delete;
  std::pair<Integer,Integer> const* getMap() const{ return fmap_device; }
  void checkGrids(GridBase* out, GridBase* in) const{
    conformable(out, _out_grid);
    conformable(in, _in_grid);
  }
  ~precisionChangeWorkspace(){
    acceleratorFreeDevice(fmap_device);
  }
 };
 //We would like to use precisionChangeFast when possible. However usage of this requires the Grids to be the same (runtime check)
 //*and* the precisionChange(VobjOut::vector_type, VobjIn, int) function to be defined for the types; this requires an extra compile-time check which we do using some SFINAE trickery
 template<class VobjOut, class VobjIn>
 auto _precisionChangeFastWrap(Lattice<VobjOut> &out, const Lattice<VobjIn> &in, int dummy)->decltype( precisionChange( ((typename VobjOut::vector_type*)0), ((typename VobjIn::vector_type*)0), 1), int()){
  if(out.Grid() == in.Grid()){
    precisionChangeFast(out,in);
    return 1;
  }else{
    return 0;
  }
 }
 template<class VobjOut, class VobjIn>
 int _precisionChangeFastWrap(Lattice<VobjOut> &out, const Lattice<VobjIn> &in, long dummy){ //note long here is intentional; it means the above is preferred if available
  return 0;
 }
 //Convert a lattice of one precision to another. Much faster than original implementation but requires a pregenerated workspace
 //which contains the mapping data.
 template<class VobjOut, class VobjIn>
 void precisionChange(Lattice<VobjOut> &out, const Lattice<VobjIn> &in, const precisionChangeWorkspace &workspace){
  if(_precisionChangeFastWrap(out,in,0)) return;
  static_assert( std::is_same<typename VobjOut::scalar_typeD, typename VobjIn::scalar_typeD>::value == 1, "precisionChange: tensor types must be the same" ); //if tensor types are same the DoublePrecision type must be the same
  out.Checkerboard() = in.Checkerboard();
  constexpr int Nsimd_out = VobjOut::Nsimd();
  workspace.checkGrids(out.Grid(),in.Grid());
  std::pair<Integer,Integer> const* fmap_device = workspace.getMap();
  //Do the copy/precision change
  autoView( out_v , out, AcceleratorWrite);
  autoView( in_v , in, AcceleratorRead);
  accelerator_for(out_oidx, out.Grid()->oSites(), 1,{
      std::pair<Integer,Integer> const* fmap_osite = fmap_device + out_oidx*Nsimd_out;
      for(int out_lane=0; out_lane < Nsimd_out; out_lane++){      
 	int in_oidx = fmap_osite[out_lane].first;
 	int in_lane = fmap_osite[out_lane].second;
 	copyLane(out_v[out_oidx], out_lane, in_v[in_oidx], in_lane);
      }
    });
 }
 //Convert a Lattice from one precision to another. Much faster than original implementation but slower than precisionChangeFast
 //or precisionChange called with pregenerated workspace, as it needs to internally generate the workspace on the host and copy to device
 template<class VobjOut, class VobjIn>
 void precisionChange(Lattice<VobjOut> &out, const Lattice<VobjIn> &in){
  if(_precisionChangeFastWrap(out,in,0)) return;   
  precisionChangeWorkspace workspace(out.Grid(), in.Grid());
  precisionChange(out, in, workspace);
 }
 ////////////////////////////////////////////////////////////////////////////////
 // Communicate between grids
 ////////////////////////////////////////////////////////////////////////////////
--- a/Grid/lattice/Lattice_view.h
+++ b/Grid/lattice/Lattice_view.h
@@ -45,7 +45,6 @@ public:
  };
  // Host only
  GridBase * getGrid(void) const { return _grid; };
  vobj* getHostPointer(void) const { return _odata; };
 };
 /////////////////////////////////////////////////////////////////////////////////////////
@@ -68,14 +67,9 @@ public:
  accelerator_inline const vobj & operator()(size_t i) const { return this->_odata[i]; }
 #endif
 #if 1
  //  accelerator_inline const vobj & operator[](size_t i) const { return this->_odata[i]; };
  accelerator_inline vobj       & operator[](size_t i) const { return this->_odata[i]; };
 #else
  accelerator_inline const vobj & operator[](size_t i) const { return this->_odata[i]; };
  accelerator_inline vobj       & operator[](size_t i)       { return this->_odata[i]; };
-#endif
+
  accelerator_inline uint64_t begin(void) const { return 0;};
  accelerator_inline uint64_t end(void)   const { return this->_odata_size; };
  accelerator_inline uint64_t size(void)  const { return this->_odata_size; };
--- a/Grid/lattice/Lattice_where.h
+++ b/Grid/lattice/Lattice_where.h
@@ -43,7 +43,7 @@ inline void whereWolf(Lattice<vobj> &ret,const Lattice<iobj> &predicate,Lattice<
  conformable(iftrue,predicate);
  conformable(iftrue,ret);
-  GridBase *grid=iftrue.Grid();
+  GridBase *grid=iftrue._grid;
  typedef typename vobj::scalar_object scalar_object;
  typedef typename vobj::scalar_type scalar_type;
@@ -52,23 +52,22 @@ inline void whereWolf(Lattice<vobj> &ret,const Lattice<iobj> &predicate,Lattice<
  const int Nsimd = grid->Nsimd();
-  autoView(iftrue_v,iftrue,CpuRead);
+  std::vector<Integer> mask(Nsimd);
-  autoView(iffalse_v,iffalse,CpuRead);
+  std::vector<scalar_object> truevals (Nsimd);
-  autoView(predicate_v,predicate,CpuRead);
+  std::vector<scalar_object> falsevals(Nsimd);
-  autoView(ret_v,ret,CpuWrite);
+
-  Integer NN= grid->oSites();
+  parallel_for(int ss=0;ss<iftrue._grid->oSites(); ss++){
-  thread_for(ss,NN,{
+
-    Integer mask;
+    extract(iftrue._odata[ss]   ,truevals);
-    scalar_object trueval;
+    extract(iffalse._odata[ss]  ,falsevals);
-    scalar_object falseval;
+    extract<vInteger,Integer>(TensorRemove(predicate._odata[ss]),mask);
-    for(int l=0;l<Nsimd;l++){
+
-      trueval =extractLane(l,iftrue_v[ss]);
+    for(int s=0;s<Nsimd;s++){
-      falseval=extractLane(l,iffalse_v[ss]);
+      if (mask[s]) falsevals[s]=truevals[s];
      mask    =extractLane(l,predicate_v[ss]);
      if (mask) falseval=trueval;
      insertLane(l,ret_v[ss],falseval);
    }
-  });
+
    merge(ret._odata[ss],falsevals);
  }
 }
 template<class vobj,class iobj>
@@ -77,9 +76,9 @@ inline Lattice<vobj> whereWolf(const Lattice<iobj> &predicate,Lattice<vobj> &ift
  conformable(iftrue,iffalse);
  conformable(iftrue,predicate);
-  Lattice<vobj> ret(iftrue.Grid());
+  Lattice<vobj> ret(iftrue._grid);
-  whereWolf(ret,predicate,iftrue,iffalse);
+  where(ret,predicate,iftrue,iffalse);
  return ret;
 }
--- a/Grid/lattice/PaddedCell.h
+++ b/Grid/lattice/PaddedCell.h
@@ -1,174 +0,0 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./lib/lattice/PaddedCell.h
    Copyright (C) 2019
 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/cshift/Cshift.h>
 NAMESPACE_BEGIN(Grid);
 //Allow the user to specify how the C-shift is performed, e.g. to respect the appropriate boundary conditions
 template<typename vobj>
 struct CshiftImplBase{
  virtual Lattice<vobj> Cshift(const Lattice<vobj> &in, int dir, int shift) const = 0;
  virtual ~CshiftImplBase(){}
 };
 template<typename vobj>
 struct CshiftImplDefault: public CshiftImplBase<vobj>{
  Lattice<vobj> Cshift(const Lattice<vobj> &in, int dir, int shift) const override{ return Grid::Cshift(in,dir,shift); }
 };
 template<typename Gimpl>
 struct CshiftImplGauge: public CshiftImplBase<typename Gimpl::GaugeLinkField::vector_object>{
  typename Gimpl::GaugeLinkField Cshift(const typename Gimpl::GaugeLinkField &in, int dir, int shift) const override{ return Gimpl::CshiftLink(in,dir,shift); }
 };  
 class PaddedCell {
 public:
  GridCartesian * unpadded_grid;
  int dims;
  int depth;
  std::vector<GridCartesian *> grids;
  ~PaddedCell()
  {
    DeleteGrids();
  }
  PaddedCell(int _depth,GridCartesian *_grid)
  {
    unpadded_grid = _grid;
    depth=_depth;
    dims=_grid->Nd();
    AllocateGrids();
    Coordinate local     =unpadded_grid->LocalDimensions();
    for(int d=0;d<dims;d++){
      assert(local[d]>=depth);
    }
  }
  void DeleteGrids(void)
  {
    for(int d=0;d<grids.size();d++){
      delete grids[d];
    }
    grids.resize(0);
  };
  void AllocateGrids(void)
  {
    Coordinate local     =unpadded_grid->LocalDimensions();
    Coordinate simd      =unpadded_grid->_simd_layout;
    Coordinate processors=unpadded_grid->_processors;
    Coordinate plocal    =unpadded_grid->LocalDimensions();
    Coordinate global(dims);
    // expand up one dim at a time
    for(int d=0;d<dims;d++){
      plocal[d] += 2*depth; 
      for(int d=0;d<dims;d++){
 	global[d] = plocal[d]*processors[d];
      }
      grids.push_back(new GridCartesian(global,simd,processors));
    }
  };
  template<class vobj>
  inline Lattice<vobj> Extract(const Lattice<vobj> &in) const
  {
    Lattice<vobj> out(unpadded_grid);
    Coordinate local     =unpadded_grid->LocalDimensions();
    Coordinate fll(dims,depth); // depends on the MPI spread
    Coordinate tll(dims,0); // depends on the MPI spread
    localCopyRegion(in,out,fll,tll,local);
    return out;
  }
  template<class vobj>
  inline Lattice<vobj> Exchange(const Lattice<vobj> &in, const CshiftImplBase<vobj> &cshift = CshiftImplDefault<vobj>()) const
  {
    GridBase *old_grid = in.Grid();
    int dims = old_grid->Nd();
    Lattice<vobj> tmp = in;
    for(int d=0;d<dims;d++){
      tmp = Expand(d,tmp,cshift); // 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
  {
    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;
    // 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;
    std::cout << GridLogPerformance << "PaddedCell::Expand timings: cshift:" << tshift/1000 << "ms, insert-slice:" << tins/1000 << "ms" << std::endl;
    return padded;
  }
 };
 NAMESPACE_END(Grid);
--- a/Grid/log/Log.cc
+++ b/Grid/log/Log.cc
@@ -65,40 +65,29 @@ GridLogger GridLogSolver (1, "Solver", GridLogColours, "NORMAL");
 GridLogger GridLogError  (1, "Error" , GridLogColours, "RED");
 GridLogger GridLogWarning(1, "Warning", GridLogColours, "YELLOW");
 GridLogger GridLogMessage(1, "Message", GridLogColours, "NORMAL");
 GridLogger GridLogMemory (1, "Memory", GridLogColours, "NORMAL");
 GridLogger GridLogTracing(1, "Tracing", GridLogColours, "NORMAL");
 GridLogger GridLogDebug  (1, "Debug", GridLogColours, "PURPLE");
 GridLogger GridLogPerformance(1, "Performance", GridLogColours, "GREEN");
 GridLogger GridLogDslash     (1, "Dslash", GridLogColours, "BLUE");
 GridLogger GridLogIterative  (1, "Iterative", GridLogColours, "BLUE");
 GridLogger GridLogIntegrator (1, "Integrator", GridLogColours, "BLUE");
 GridLogger GridLogHMC (1, "HMC", GridLogColours, "BLUE");
 void GridLogConfigure(std::vector<std::string> &logstreams) {
-  GridLogError.Active(1);
+  GridLogError.Active(0);
  GridLogWarning.Active(0);
  GridLogMessage.Active(1); // at least the messages should be always on
  GridLogMemory.Active(0); 
  GridLogTracing.Active(0); 
  GridLogIterative.Active(0);
  GridLogDebug.Active(0);
  GridLogPerformance.Active(0);
  GridLogDslash.Active(0);
  GridLogIntegrator.Active(1);
  GridLogColours.Active(0);
  GridLogHMC.Active(1);
  for (int i = 0; i < logstreams.size(); i++) {
-    if (logstreams[i] == std::string("Tracing"))     GridLogTracing.Active(1);
+    if (logstreams[i] == std::string("Error"))       GridLogError.Active(1);
    if (logstreams[i] == std::string("Memory"))      GridLogMemory.Active(1);
    if (logstreams[i] == std::string("Warning"))     GridLogWarning.Active(1);
    if (logstreams[i] == std::string("NoMessage"))   GridLogMessage.Active(0);
    if (logstreams[i] == std::string("Iterative"))   GridLogIterative.Active(1);
    if (logstreams[i] == std::string("Debug"))       GridLogDebug.Active(1);
    if (logstreams[i] == std::string("Performance")) GridLogPerformance.Active(1);
-    if (logstreams[i] == std::string("Dslash"))      GridLogDslash.Active(1);
+    if (logstreams[i] == std::string("Integrator"))  GridLogIntegrator.Active(1);
    if (logstreams[i] == std::string("NoIntegrator"))GridLogIntegrator.Active(0);
    if (logstreams[i] == std::string("NoHMC"))       GridLogHMC.Active(0);
    if (logstreams[i] == std::string("Colours"))     GridLogColours.Active(1);
  }
 }
--- a/Grid/log/Log.h
+++ b/Grid/log/Log.h
@@ -138,8 +138,7 @@ public:
        stream << std::setw(log.topWidth);
      }
      stream << log.topName << log.background()<< " : ";
-      //      stream << log.colour() <<  std::left;
+      stream << log.colour() <<  std::left;
      stream <<  std::left;
      if (log.chanWidth > 0)
      {
        stream << std::setw(log.chanWidth);
@@ -154,9 +153,9 @@ public:
 	stream << log.evidence()
 	       << now	       << log.background() << " : " ;
      }
-      //      stream << log.colour();
+      stream << log.colour();
      stream <<  std::right;
      stream.flags(f);
      return stream;
    } else { 
      return devnull;
@@ -179,53 +178,14 @@ extern GridLogger GridLogSolver;
 extern GridLogger GridLogError;
 extern GridLogger GridLogWarning;
 extern GridLogger GridLogMessage;
-extern GridLogger GridLogDebug;
+extern GridLogger GridLogDebug  ;
 extern GridLogger GridLogPerformance;
-extern GridLogger GridLogDslash;
+extern GridLogger GridLogIterative  ;
-extern GridLogger GridLogIterative;
+extern GridLogger GridLogIntegrator  ;
 extern GridLogger GridLogIntegrator;
 extern GridLogger GridLogHMC;
 extern GridLogger GridLogMemory;
 extern GridLogger GridLogTracing;
 extern Colours    GridLogColours;
 std::string demangle(const char* name) ;
 template<typename... Args>
 inline std::string sjoin(Args&&... args) noexcept {
    std::ostringstream msg;
    (msg << ... << args);
    return msg.str();
 }
 /*!  @brief make log messages work like python print */
 template <typename... Args>
 inline void Grid_log(Args&&... args) {
    std::string msg = sjoin(std::forward<Args>(args)...);
    std::cout << GridLogMessage << msg << std::endl;
 }
 /*!  @brief make warning messages work like python print */
 template <typename... Args>
 inline void Grid_warn(Args&&... args) {
    std::string msg = sjoin(std::forward<Args>(args)...);
    std::cout << "\033[33m" << GridLogWarning << msg << "\033[0m" << std::endl;
 }
 /*!  @brief make error messages work like python print */
 template <typename... Args>
 inline void Grid_error(Args&&... args) {
    std::string msg = sjoin(std::forward<Args>(args)...);
    std::cout << "\033[31m" << GridLogError << msg << "\033[0m" << std::endl;
 }
 /*!  @brief make pass messages work like python print */
 template <typename... Args>
 inline void Grid_pass(Args&&... args) {
    std::string msg = sjoin(std::forward<Args>(args)...);
    std::cout << "\033[32m" << GridLogMessage << msg << "\033[0m" << std::endl;
 }
 #define _NBACKTRACE (256)
 extern void * Grid_backtrace_buffer[_NBACKTRACE];
--- a/Grid/parallelIO/IldgIO.h
+++ b/Grid/parallelIO/IldgIO.h
@@ -31,7 +31,6 @@ directory
 #include <fstream>
 #include <iomanip>
 #include <iostream>
 #include <string>
 #include <map>
 #include <pwd.h>
@@ -124,7 +123,7 @@ assert(GRID_FIELD_NORM_CALC(FieldNormMetaData_, n2ck) < 1.0e-5);
 ////////////////////////////////////////////////////////////
 // Helper to fill out metadata
 ////////////////////////////////////////////////////////////
-template<class vobj> void ScidacMetaData(Lattice<vobj> & field,
+ template<class vobj> void ScidacMetaData(Lattice<vobj> & field,
 					  FieldMetaData &header,
 					  scidacRecord & _scidacRecord,
 					  scidacFile   & _scidacFile) 
@@ -577,8 +576,6 @@ class ScidacReader : public GridLimeReader {
    std::string rec_name(ILDG_BINARY_DATA);
    while ( limeReaderNextRecord(LimeR) == LIME_SUCCESS ) { 
      if ( !strncmp(limeReaderType(LimeR), rec_name.c_str(),strlen(rec_name.c_str()) )  ) {
  // in principle should do the line below, but that breaks backard compatibility with old data
  // skipPastObjectRecord(std::string(GRID_FIELD_NORM));
 	skipPastObjectRecord(std::string(SCIDAC_CHECKSUM));
 	return;
      }
@@ -622,12 +619,12 @@ class IldgWriter : public ScidacWriter {
  // Don't require scidac records EXCEPT checksum
  // Use Grid MetaData object if present.
  ////////////////////////////////////////////////////////////////
-  template <class stats = PeriodicGaugeStatistics>
+  template <class vsimd>
-  void writeConfiguration(Lattice<vLorentzColourMatrixD > &Umu,int sequence,std::string LFN,std::string description) 
+  void writeConfiguration(Lattice<iLorentzColourMatrix<vsimd> > &Umu,int sequence,std::string LFN,std::string description) 
  {
    GridBase * grid = Umu.Grid();
-    typedef Lattice<vLorentzColourMatrixD> GaugeField;
+    typedef Lattice<iLorentzColourMatrix<vsimd> > GaugeField;
-    typedef vLorentzColourMatrixD vobj;
+    typedef iLorentzColourMatrix<vsimd> vobj;
    typedef typename vobj::scalar_object sobj;
    ////////////////////////////////////////
@@ -639,9 +636,6 @@ class IldgWriter : public ScidacWriter {
    ScidacMetaData(Umu,header,_scidacRecord,_scidacFile);
    stats Stats;
    Stats(Umu,header);
    std::string format = header.floating_point;
    header.ensemble_id    = description;
    header.ensemble_label = description;
@@ -655,8 +649,7 @@ class IldgWriter : public ScidacWriter {
    // Fill ILDG header data struct
    //////////////////////////////////////////////////////
    ildgFormat ildgfmt ;
-    const std::string stNC = std::to_string( Nc ) ;
+    ildgfmt.field     = std::string("su3gauge");
    ildgfmt.field          = std::string("su"+stNC+"gauge");
    if ( format == std::string("IEEE32BIG") ) { 
      ildgfmt.precision = 32;
@@ -712,10 +705,10 @@ class IldgReader : public GridLimeReader {
  // Else use ILDG MetaData object if present.
  // Else use SciDAC MetaData object if present.
  ////////////////////////////////////////////////////////////////
-  template <class stats = PeriodicGaugeStatistics>
+  template <class vsimd>
-  void readConfiguration(Lattice<vLorentzColourMatrixD> &Umu, FieldMetaData &FieldMetaData_) {
+  void readConfiguration(Lattice<iLorentzColourMatrix<vsimd> > &Umu, FieldMetaData &FieldMetaData_) {
-    typedef Lattice<vLorentzColourMatrixD > GaugeField;
+    typedef Lattice<iLorentzColourMatrix<vsimd> > GaugeField;
    typedef typename GaugeField::vector_object  vobj;
    typedef typename vobj::scalar_object sobj;
@@ -873,8 +866,7 @@ class IldgReader : public GridLimeReader {
    } else { 
      assert(found_ildgFormat);
-      const std::string stNC = std::to_string( Nc ) ;
+      assert ( ildgFormat_.field == std::string("su3gauge") );
      assert ( ildgFormat_.field == std::string("su"+stNC+"gauge") );
      ///////////////////////////////////////////////////////////////////////////////////////
      // Populate our Grid metadata as best we can
@@ -882,7 +874,7 @@ class IldgReader : public GridLimeReader {
      std::ostringstream vers; vers << ildgFormat_.version;
      FieldMetaData_.hdr_version = vers.str();
-      FieldMetaData_.data_type = std::string("4D_SU"+stNC+"_GAUGE_"+stNC+"x"+stNC);
+      FieldMetaData_.data_type = std::string("4D_SU3_GAUGE_3X3");
      FieldMetaData_.nd=4;
      FieldMetaData_.dimension.resize(4);
@@ -929,8 +921,7 @@ class IldgReader : public GridLimeReader {
    if ( found_FieldMetaData || found_usqcdInfo ) {
      FieldMetaData checker;
-      stats Stats;
+      GaugeStatistics(Umu,checker);
      Stats(Umu,checker);
      assert(fabs(checker.plaquette  - FieldMetaData_.plaquette )<1.0e-5);
      assert(fabs(checker.link_trace - FieldMetaData_.link_trace)<1.0e-5);
      std::cout << GridLogMessage<<"Plaquette and link trace match " << std::endl;
--- a/Grid/parallelIO/MetaData.h
+++ b/Grid/parallelIO/MetaData.h
@@ -6,8 +6,8 @@
    Copyright (C) 2015
    Author: Peter Boyle <paboyle@ph.ed.ac.uk>
    Author: Jamie Hudspith <renwick.james.hudspth@gmail.com>
    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
@@ -128,7 +128,7 @@ inline void MachineCharacteristics(FieldMetaData &header)
  std::time_t t = std::time(nullptr);
  std::tm tm_ = *std::localtime(&t);
  std::ostringstream oss; 
-  oss << std::put_time(&tm_, "%c %Z");
+  //      oss << std::put_time(&tm_, "%c %Z");
  header.creation_date = oss.str();
  header.archive_date  = header.creation_date;
@@ -176,18 +176,29 @@ template<class vobj> inline void PrepareMetaData(Lattice<vobj> & field, FieldMet
  GridMetaData(grid,header); 
  MachineCharacteristics(header);
 }
-template<class Impl>
+inline void GaugeStatistics(Lattice<vLorentzColourMatrixF> & data,FieldMetaData &header)
 class GaugeStatistics
 {
-public:
+  // How to convert data precision etc...
-  void operator()(Lattice<vLorentzColourMatrixD> & data,FieldMetaData &header)
+  header.link_trace=WilsonLoops<PeriodicGimplF>::linkTrace(data);
-  {
+  header.plaquette =WilsonLoops<PeriodicGimplF>::avgPlaquette(data);
-    header.link_trace = WilsonLoops<Impl>::linkTrace(data);
+}
-    header.plaquette  = WilsonLoops<Impl>::avgPlaquette(data);
+inline void GaugeStatistics(Lattice<vLorentzColourMatrixD> & data,FieldMetaData &header)
-  }
+{
-};
+  // How to convert data precision etc...
-typedef GaugeStatistics<PeriodicGimplD> PeriodicGaugeStatistics;
+  header.link_trace=WilsonLoops<PeriodicGimplD>::linkTrace(data);
-typedef GaugeStatistics<ConjugateGimplD> ConjugateGaugeStatistics;
+  header.plaquette =WilsonLoops<PeriodicGimplD>::avgPlaquette(data);
 }
 template<> inline void PrepareMetaData<vLorentzColourMatrixF>(Lattice<vLorentzColourMatrixF> & field, FieldMetaData &header)
 {
  GridBase *grid = field.Grid();
  std::string format = getFormatString<vLorentzColourMatrixF>();
  header.floating_point = format;
  header.checksum = 0x0; // Nersc checksum unused in ILDG, Scidac
  GridMetaData(grid,header); 
  GaugeStatistics(field,header);
  MachineCharacteristics(header);
 }
 template<> inline void PrepareMetaData<vLorentzColourMatrixD>(Lattice<vLorentzColourMatrixD> & field, FieldMetaData &header)
 {
  GridBase *grid = field.Grid();
@@ -195,6 +206,7 @@ template<> inline void PrepareMetaData<vLorentzColourMatrixD>(Lattice<vLorentzCo
  header.floating_point = format;
  header.checksum = 0x0; // Nersc checksum unused in ILDG, Scidac
  GridMetaData(grid,header); 
  GaugeStatistics(field,header);
  MachineCharacteristics(header);
 }
@@ -203,24 +215,20 @@ template<> inline void PrepareMetaData<vLorentzColourMatrixD>(Lattice<vLorentzCo
 //////////////////////////////////////////////////////////////////////
 inline void reconstruct3(LorentzColourMatrix & cm)
 {
-  assert( Nc < 4 && Nc > 1 ) ;
+  const int x=0;
  const int y=1;
  const int z=2;
  for(int mu=0;mu<Nd;mu++){
-    #if Nc == 2
+    cm(mu)()(2,x) = adj(cm(mu)()(0,y)*cm(mu)()(1,z)-cm(mu)()(0,z)*cm(mu)()(1,y)); //x= yz-zy
-      cm(mu)()(1,0) = -adj(cm(mu)()(0,y)) ;
+    cm(mu)()(2,y) = adj(cm(mu)()(0,z)*cm(mu)()(1,x)-cm(mu)()(0,x)*cm(mu)()(1,z)); //y= zx-xz
-      cm(mu)()(1,1) =  adj(cm(mu)()(0,x)) ;
+    cm(mu)()(2,z) = adj(cm(mu)()(0,x)*cm(mu)()(1,y)-cm(mu)()(0,y)*cm(mu)()(1,x)); //z= xy-yx
    #else
      const int x=0 , y=1 , z=2 ; // a little disinenuous labelling
      cm(mu)()(2,x) = adj(cm(mu)()(0,y)*cm(mu)()(1,z)-cm(mu)()(0,z)*cm(mu)()(1,y)); //x= yz-zy
      cm(mu)()(2,y) = adj(cm(mu)()(0,z)*cm(mu)()(1,x)-cm(mu)()(0,x)*cm(mu)()(1,z)); //y= zx-xz
      cm(mu)()(2,z) = adj(cm(mu)()(0,x)*cm(mu)()(1,y)-cm(mu)()(0,y)*cm(mu)()(1,x)); //z= xy-yx
    #endif
  }
 }
 ////////////////////////////////////////////////////////////////////////////////
 // Some data types for intermediate storage
 ////////////////////////////////////////////////////////////////////////////////
-template<typename vtype> using iLorentzColour2x3 = iVector<iVector<iVector<vtype, Nc>, Nc-1>, Nd >;
+template<typename vtype> using iLorentzColour2x3 = iVector<iVector<iVector<vtype, Nc>, 2>, Nd >;
 typedef iLorentzColour2x3<Complex>  LorentzColour2x3;
 typedef iLorentzColour2x3<ComplexF> LorentzColour2x3F;
@@ -282,6 +290,7 @@ struct GaugeSimpleMunger{
 template <class fobj, class sobj>
 struct GaugeSimpleUnmunger {
  void operator()(sobj &in, fobj &out) {
    for (int mu = 0; mu < Nd; mu++) {
      for (int i = 0; i < Nc; i++) {
@@ -320,8 +329,8 @@ template<class fobj,class sobj>
 struct Gauge3x2munger{
  void operator() (fobj &in,sobj &out){
    for(int mu=0;mu<Nd;mu++){
-      for(int i=0;i<Nc-1;i++){
+      for(int i=0;i<2;i++){
-	for(int j=0;j<Nc;j++){
+	for(int j=0;j<3;j++){
 	  out(mu)()(i,j) = in(mu)(i)(j);
 	}}
    }
@@ -333,8 +342,8 @@ template<class fobj,class sobj>
 struct Gauge3x2unmunger{
  void operator() (sobj &in,fobj &out){
    for(int mu=0;mu<Nd;mu++){
-      for(int i=0;i<Nc-1;i++){
+      for(int i=0;i<2;i++){
-	for(int j=0;j<Nc;j++){
+	for(int j=0;j<3;j++){
 	  out(mu)(i)(j) = in(mu)()(i,j);
 	}}
    }
--- a/Grid/parallelIO/NerscIO.h
+++ b/Grid/parallelIO/NerscIO.h
@@ -9,7 +9,6 @@
    Author: Matt Spraggs <matthew.spraggs@gmail.com>
    Author: Peter Boyle <paboyle@ph.ed.ac.uk>
    Author: paboyle <paboyle@ph.ed.ac.uk>
    Author: Jamie Hudspith <renwick.james.hudspth@gmail.com>
    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
@@ -31,8 +30,6 @@
 #ifndef GRID_NERSC_IO_H
 #define GRID_NERSC_IO_H
 #include <string>
 NAMESPACE_BEGIN(Grid);
 using namespace Grid;
@@ -42,10 +39,6 @@ using namespace Grid;
 ////////////////////////////////////////////////////////////////////////////////
 class NerscIO : public BinaryIO { 
 public:
  typedef Lattice<vLorentzColourMatrixD> GaugeField;
  // Enable/disable exiting if the plaquette in the header does not match the value computed (default true)
  static bool & exitOnReadPlaquetteMismatch(){ static bool v=true; return v; }
  static inline void truncate(std::string file){
    std::ofstream fout(file,std::ios::out);
@@ -136,12 +129,12 @@ public:
  // Now the meat: the object readers
  /////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
-  template<class GaugeStats=PeriodicGaugeStatistics>
+  template<class vsimd>
-  static inline void readConfiguration(GaugeField &Umu,
+  static inline void readConfiguration(Lattice<iLorentzColourMatrix<vsimd> > &Umu,
 				       FieldMetaData& header,
-				       std::string file,
+				       std::string file)
 				       GaugeStats GaugeStatisticsCalculator=GaugeStats())
  {
    typedef Lattice<iLorentzColourMatrix<vsimd> > GaugeField;
    GridBase *grid = Umu.Grid();
    uint64_t offset = readHeader(file,Umu.Grid(),header);
@@ -150,35 +143,33 @@ public:
    std::string format(header.floating_point);
-    const int ieee32big = (format == std::string("IEEE32BIG"));
+    int ieee32big = (format == std::string("IEEE32BIG"));
-    const int ieee32    = (format == std::string("IEEE32"));
+    int ieee32    = (format == std::string("IEEE32"));
-    const int ieee64big = (format == std::string("IEEE64BIG"));
+    int ieee64big = (format == std::string("IEEE64BIG"));
-    const int ieee64    = (format == std::string("IEEE64") || \
+    int ieee64    = (format == std::string("IEEE64") || format == std::string("IEEE64LITTLE"));
 			   format == std::string("IEEE64LITTLE"));
    uint32_t nersc_csum,scidac_csuma,scidac_csumb;
    // depending on datatype, set up munger;
    // munger is a function of <floating point, Real, data_type>
-    const std::string stNC = std::to_string( Nc ) ;
+    if ( header.data_type == std::string("4D_SU3_GAUGE") ) {
    if ( header.data_type == std::string("4D_SU"+stNC+"_GAUGE") ) {
      if ( ieee32 || ieee32big ) {
-	BinaryIO::readLatticeObject<vLorentzColourMatrixD, LorentzColour2x3F> 
+	BinaryIO::readLatticeObject<iLorentzColourMatrix<vsimd>, LorentzColour2x3F> 
 	  (Umu,file,Gauge3x2munger<LorentzColour2x3F,LorentzColourMatrix>(), offset,format,
 	   nersc_csum,scidac_csuma,scidac_csumb);
      }
      if ( ieee64 || ieee64big ) {
-	BinaryIO::readLatticeObject<vLorentzColourMatrixD, LorentzColour2x3D> 
+	BinaryIO::readLatticeObject<iLorentzColourMatrix<vsimd>, LorentzColour2x3D> 
 	  (Umu,file,Gauge3x2munger<LorentzColour2x3D,LorentzColourMatrix>(),offset,format,
 	   nersc_csum,scidac_csuma,scidac_csumb);
      }
-    } else if ( header.data_type == std::string("4D_SU"+stNC+"_GAUGE_"+stNC+"x"+stNC) ) {
+    } else if ( header.data_type == std::string("4D_SU3_GAUGE_3x3") ) {
      if ( ieee32 || ieee32big ) {
-	BinaryIO::readLatticeObject<vLorentzColourMatrixD,LorentzColourMatrixF>
+	BinaryIO::readLatticeObject<iLorentzColourMatrix<vsimd>,LorentzColourMatrixF>
 	  (Umu,file,GaugeSimpleMunger<LorentzColourMatrixF,LorentzColourMatrix>(),offset,format,
 	   nersc_csum,scidac_csuma,scidac_csumb);
      }
      if ( ieee64 || ieee64big ) {
-	BinaryIO::readLatticeObject<vLorentzColourMatrixD,LorentzColourMatrixD>
+	BinaryIO::readLatticeObject<iLorentzColourMatrix<vsimd>,LorentzColourMatrixD>
 	  (Umu,file,GaugeSimpleMunger<LorentzColourMatrixD,LorentzColourMatrix>(),offset,format,
 	   nersc_csum,scidac_csuma,scidac_csumb);
      }
@@ -186,7 +177,7 @@ public:
      assert(0);
    }
-    GaugeStats Stats; Stats(Umu,clone);
+    GaugeStatistics(Umu,clone);
    std::cout<<GridLogMessage <<"NERSC Configuration "<<file<<" checksum "<<std::hex<<nersc_csum<< std::dec
 	     <<" header   "<<std::hex<<header.checksum<<std::dec <<std::endl;
@@ -205,40 +196,31 @@ public:
      std::cerr << " nersc_csum  " <<std::hex<< nersc_csum << " " << header.checksum<< std::dec<< std::endl;
      exit(0);
    }
-    if(exitOnReadPlaquetteMismatch()) assert(fabs(clone.plaquette -header.plaquette ) < 1.0e-5 );
+    assert(fabs(clone.plaquette -header.plaquette ) < 1.0e-5 );
    assert(fabs(clone.link_trace-header.link_trace) < 1.0e-6 );
    assert(nersc_csum == header.checksum );
    std::cout<<GridLogMessage <<"NERSC Configuration "<<file<< " and plaquette, link trace, and checksum agree"<<std::endl;
  }
-  // Preferred interface
+  template<class vsimd>
-  template<class GaugeStats=PeriodicGaugeStatistics>
+  static inline void writeConfiguration(Lattice<iLorentzColourMatrix<vsimd> > &Umu,
  static inline void writeConfiguration(Lattice<vLorentzColourMatrixD > &Umu,
 					std::string file, 
 					std::string ens_label = std::string("DWF"),
 					std::string ens_id = std::string("UKQCD"),
 					unsigned int sequence_number = 1)
  {
    writeConfiguration(Umu,file,0,1,ens_label,ens_id,sequence_number);
  }
  template<class GaugeStats=PeriodicGaugeStatistics>
  static inline void writeConfiguration(Lattice<vLorentzColourMatrixD > &Umu,
 					std::string file, 
 					int two_row,
-					int bits32,
+					int bits32)
 					std::string ens_label = std::string("DWF"),
 					std::string ens_id = std::string("UKQCD"),
 					unsigned int sequence_number = 1)
  {
-    typedef vLorentzColourMatrixD vobj;
+    typedef Lattice<iLorentzColourMatrix<vsimd> > GaugeField;
    typedef iLorentzColourMatrix<vsimd> vobj;
    typedef typename vobj::scalar_object sobj;
    FieldMetaData header;
-    header.sequence_number = sequence_number;
+    ///////////////////////////////////////////
-    header.ensemble_id     = ens_id;
+    // Following should become arguments
-    header.ensemble_label  = ens_label;
+    ///////////////////////////////////////////
-    header.hdr_version     = "1.0" ;
+    header.sequence_number = 1;
    header.ensemble_id     = "UKQCD";
    header.ensemble_label  = "DWF";
    typedef LorentzColourMatrixD fobj3D;
    typedef LorentzColour2x3D    fobj2D;
@@ -247,39 +229,28 @@ public:
    GridMetaData(grid,header);
    assert(header.nd==4);
-    GaugeStats Stats; Stats(Umu,header);
+    GaugeStatistics(Umu,header);
    MachineCharacteristics(header);
-    uint64_t offset;
+	uint64_t offset;
-    // Sod it -- always write NcxNc double
+    // Sod it -- always write 3x3 double
-    header.floating_point  = std::string("IEEE64BIG");
+    header.floating_point = std::string("IEEE64BIG");
-    const std::string stNC = std::to_string( Nc ) ;
+    header.data_type      = std::string("4D_SU3_GAUGE_3x3");
-    if( two_row ) {
+    GaugeSimpleUnmunger<fobj3D,sobj> munge;
-      header.data_type = std::string("4D_SU" + stNC + "_GAUGE" );
+	if ( grid->IsBoss() ) { 
-    } else {
+	  truncate(file);
-      header.data_type = std::string("4D_SU" + stNC + "_GAUGE_" + stNC + "x" + stNC );
+    offset = writeHeader(header,file);
-    }
+	}
-    if ( grid->IsBoss() ) { 
+	grid->Broadcast(0,(void *)&offset,sizeof(offset));
      truncate(file);
      offset = writeHeader(header,file);
    }
    grid->Broadcast(0,(void *)&offset,sizeof(offset));
    uint32_t nersc_csum,scidac_csuma,scidac_csumb;
-    if( two_row ) {
+    BinaryIO::writeLatticeObject<vobj,fobj3D>(Umu,file,munge,offset,header.floating_point,
-      Gauge3x2unmunger<fobj2D,sobj> munge;
+					      nersc_csum,scidac_csuma,scidac_csumb);
      BinaryIO::writeLatticeObject<vobj,fobj2D>(Umu,file,munge,offset,header.floating_point,
 						nersc_csum,scidac_csuma,scidac_csumb);
    } else {
      GaugeSimpleUnmunger<fobj3D,sobj> munge;
      BinaryIO::writeLatticeObject<vobj,fobj3D>(Umu,file,munge,offset,header.floating_point,
 						nersc_csum,scidac_csuma,scidac_csumb);
    }
    header.checksum = nersc_csum;
-    if ( grid->IsBoss() ) { 
+	if ( grid->IsBoss() ) { 
-      writeHeader(header,file);
+    writeHeader(header,file);
-    }
+	}
    std::cout<<GridLogMessage <<"Written NERSC Configuration on "<< file << " checksum "
 	     <<std::hex<<header.checksum
@@ -307,7 +278,8 @@ public:
    header.plaquette=0.0;
    MachineCharacteristics(header);
-    uint64_t offset;
+	uint64_t offset;
 #ifdef RNG_RANLUX
    header.floating_point = std::string("UINT64");
    header.data_type      = std::string("RANLUX48");
@@ -347,7 +319,7 @@ public:
    GridBase *grid = parallel.Grid();
-    uint64_t offset = readHeader(file,grid,header);
+	uint64_t offset = readHeader(file,grid,header);
    FieldMetaData clone(header);
--- a/Grid/parallelIO/OpenQcdIO.h
+++ b/Grid/parallelIO/OpenQcdIO.h
@@ -154,7 +154,7 @@ public:
    grid->Barrier(); timer.Stop();
    std::cout << Grid::GridLogMessage << "OpenQcdIO::readConfiguration: redistribute overhead " << timer.Elapsed() << std::endl;
-    PeriodicGaugeStatistics Stats; Stats(Umu, clone);
+    GaugeStatistics(Umu, clone);
    RealD plaq_diff = fabs(clone.plaquette - header.plaquette);
--- a/Grid/parallelIO/OpenQcdIOChromaReference.h
+++ b/Grid/parallelIO/OpenQcdIOChromaReference.h
@@ -208,7 +208,7 @@ public:
    FieldMetaData clone(header);
-    PeriodicGaugeStatistics Stats; Stats(Umu, clone);
+    GaugeStatistics(Umu, clone);
    RealD plaq_diff = fabs(clone.plaquette - header.plaquette);
--- a/Grid/perfmon/PerfCount.cc
+++ b/Grid/perfmon/PerfCount.cc
@@ -27,12 +27,9 @@ Author: paboyle <paboyle@ph.ed.ac.uk>
 /*  END LEGAL */
 #include <Grid/GridCore.h>
 #include <Grid/perfmon/Timer.h>
 #include <Grid/perfmon/PerfCount.h>
 NAMESPACE_BEGIN(Grid);
-GridTimePoint theProgramStart = GridClock::now();
+NAMESPACE_BEGIN(Grid);
 #define CacheControl(L,O,R) ((PERF_COUNT_HW_CACHE_##L)|(PERF_COUNT_HW_CACHE_OP_##O<<8)| (PERF_COUNT_HW_CACHE_RESULT_##R<<16))
 #define RawConfig(A,B) (A<<8|B)
--- a/Grid/perfmon/PerfCount.h
+++ b/Grid/perfmon/PerfCount.h
@@ -30,12 +30,6 @@ Author: paboyle <paboyle@ph.ed.ac.uk>
 #ifndef GRID_PERFCOUNT_H
 #define GRID_PERFCOUNT_H
 #ifndef __SSC_START
 #define __SSC_START
 #define __SSC_STOP
 #endif
 #include <sys/time.h>
 #include <ctime>
 #include <chrono>
@@ -78,9 +72,17 @@ static long perf_event_open(struct perf_event_attr *hw_event, pid_t pid,
 inline uint64_t cyclecount(void){ 
  return 0;
 }
 #define __SSC_MARK(mark) __asm__ __volatile__ ("movl %0, %%ebx; .byte 0x64, 0x67, 0x90 " ::"i"(mark):"%ebx")
 #define __SSC_STOP  __SSC_MARK(0x110)
 #define __SSC_START __SSC_MARK(0x111)
 #else
 #define __SSC_MARK(mark) 
 #define __SSC_STOP  
 #define __SSC_START 
 /*
 * cycle counters arch dependent
 */
--- a/Grid/perfmon/Timer.h
+++ b/Grid/perfmon/Timer.h
@@ -35,8 +35,17 @@ Author: Peter Boyle <paboyle@ph.ed.ac.uk>
 NAMESPACE_BEGIN(Grid)
-//typedef  std::chrono::system_clock          GridClock;
+// Dress the output; use std::chrono
-typedef  std::chrono::high_resolution_clock   GridClock;
+// C++11 time facilities better?
 inline double usecond(void) {
  struct timeval tv;
 #ifdef TIMERS_ON
  gettimeofday(&tv,NULL);
 #endif
  return 1.0*tv.tv_usec + 1.0e6*tv.tv_sec;
 }
 typedef  std::chrono::system_clock          GridClock;
 typedef  std::chrono::time_point<GridClock> GridTimePoint;
 typedef  std::chrono::seconds               GridSecs;
@@ -44,15 +53,6 @@ typedef  std::chrono::milliseconds          GridMillisecs;
 typedef  std::chrono::microseconds          GridUsecs;
 typedef  std::chrono::microseconds          GridTime;
 extern GridTimePoint theProgramStart;
 // Dress the output; use std::chrono
 // C++11 time facilities better?
 inline double usecond(void) {
  auto usecs = std::chrono::duration_cast<GridUsecs>(GridClock::now()-theProgramStart); 
  return 1.0*usecs.count();
 }
 inline std::ostream& operator<< (std::ostream & stream, const GridSecs & time)
 {
  stream << time.count()<<" s";
--- a/Grid/perfmon/Tracing.h
+++ b/Grid/perfmon/Tracing.h
@@ -1,70 +0,0 @@
 #pragma once
 NAMESPACE_BEGIN(Grid);
 #ifdef GRID_TRACING_NVTX
 #include <nvToolsExt.h>
 class GridTracer {
 public:
  GridTracer(const char* name) {
    nvtxRangePushA(name);
  }
  ~GridTracer() {
    nvtxRangePop();
  }
 };
 inline void tracePush(const char *name) { nvtxRangePushA(name); }
 inline void tracePop(const char *name) { nvtxRangePop(); }
 inline int  traceStart(const char *name) {  }
 inline void traceStop(int ID) {  }
 #endif
 #ifdef GRID_TRACING_ROCTX
 #include <roctracer/roctx.h>
 class GridTracer {
 public:
  GridTracer(const char* name) {
    roctxRangePushA(name);
    std::cout << "roctxRangePush "<<name<<std::endl;
  }
  ~GridTracer() {
    roctxRangePop();
    std::cout << "roctxRangePop "<<std::endl;
  }
 };
 inline void tracePush(const char *name) { roctxRangePushA(name); }
 inline void tracePop(const char *name) { roctxRangePop(); }
 inline int  traceStart(const char *name) { return roctxRangeStart(name); }
 inline void traceStop(int ID) { roctxRangeStop(ID); }
 #endif
 #ifdef GRID_TRACING_TIMER
 class GridTracer {
 public:
  const char *name;
  double elapsed;
  GridTracer(const char* _name) {
    name = _name;
    elapsed=-usecond();
  }
  ~GridTracer() {
    elapsed+=usecond();
    std::cout << GridLogTracing << name << " took " <<elapsed<< " us" <<std::endl;
  }
 };
 inline void tracePush(const char *name) {  }
 inline void tracePop(const char *name) {  }
 inline int  traceStart(const char *name) { return 0; }
 inline void traceStop(int ID) {  }
 #endif
 #ifdef GRID_TRACING_NONE
 #define GRID_TRACE(name) 
 inline void tracePush(const char *name) {  }
 inline void tracePop(const char *name) {  }
 inline int  traceStart(const char *name) { return 0;  }
 inline void traceStop(int ID) {  }
 #else
 #define GRID_TRACE(name) GridTracer uniq_name_using_macros##__COUNTER__(name);
 #endif
 NAMESPACE_END(Grid);
--- a/Grid/pugixml/pugixml.cc
+++ b/Grid/pugixml/pugixml.cc
@@ -16,12 +16,8 @@
 #ifdef __NVCC__
 #pragma push
 #ifdef __NVCC_DIAG_PRAGMA_SUPPORT__
 #pragma nv_diag_suppress declared_but_not_referenced // suppress "function was declared but never referenced warning"
 #else
 #pragma diag_suppress declared_but_not_referenced // suppress "function was declared but never referenced warning"
 #endif
 #endif
 #include "pugixml.h"
--- a/Grid/qcd/QCD.h
+++ b/Grid/qcd/QCD.h
@@ -63,7 +63,6 @@ static constexpr int Ngp=2; // gparity index range
 #define ColourIndex  (2)
 #define SpinIndex    (1)
 #define LorentzIndex (0)
 #define GparityFlavourIndex (0)
 // Also should make these a named enum type
 static constexpr int DaggerNo=0;
@@ -81,15 +80,6 @@ template<typename T> struct isSpinor {
 template <typename T> using IfSpinor    = Invoke<std::enable_if< isSpinor<T>::value,int> > ;
 template <typename T> using IfNotSpinor = Invoke<std::enable_if<!isSpinor<T>::value,int> > ;
 const int CoarseIndex = 4;
 template<typename T> struct isCoarsened {
   static constexpr bool value = (CoarseIndex<=T::TensorLevel);
 };
 template <typename T> using IfCoarsened    = Invoke<std::enable_if< isCoarsened<T>::value,int> > ;
 template <typename T> using IfNotCoarsened = Invoke<std::enable_if<!isCoarsened<T>::value,int> > ;
 const int GparityFlavourTensorIndex = 3; //TensorLevel counts from the bottom!
 // ChrisK very keen to add extra space for Gparity doubling.
 //
 // Also add domain wall index, in a way where Wilson operator 
@@ -104,7 +94,6 @@ template<typename vtype> using iSpinMatrix                = iScalar<iMatrix<iSca
 template<typename vtype> using iColourMatrix              = iScalar<iScalar<iMatrix<vtype, Nc> > > ;
 template<typename vtype> using iSpinColourMatrix          = iScalar<iMatrix<iMatrix<vtype, Nc>, Ns> >;
 template<typename vtype> using iLorentzColourMatrix       = iVector<iScalar<iMatrix<vtype, Nc> >, Nd > ;
 template<typename vtype> using iLorentzComplex            = iVector<iScalar<iScalar<vtype> >, Nd > ;
 template<typename vtype> using iDoubleStoredColourMatrix  = iVector<iScalar<iMatrix<vtype, Nc> >, Nds > ;
 template<typename vtype> using iSpinVector                = iScalar<iVector<iScalar<vtype>, Ns> >;
 template<typename vtype> using iColourVector              = iScalar<iScalar<iVector<vtype, Nc> > >;
@@ -114,10 +103,8 @@ template<typename vtype> using iHalfSpinColourVector      = iScalar<iVector<iVec
    template<typename vtype> using iSpinColourSpinColourMatrix  = iScalar<iMatrix<iMatrix<iMatrix<iMatrix<vtype, Nc>, Ns>, Nc>, Ns> >;
 template<typename vtype> using iGparityFlavourVector                = iVector<iScalar<iScalar<vtype> >, Ngp>;
 template<typename vtype> using iGparitySpinColourVector       = iVector<iVector<iVector<vtype, Nc>, Ns>, Ngp >;
 template<typename vtype> using iGparityHalfSpinColourVector   = iVector<iVector<iVector<vtype, Nc>, Nhs>, Ngp >;
 template<typename vtype> using iGparityFlavourMatrix = iMatrix<iScalar<iScalar<vtype> >, Ngp>;
 // Spin matrix
 typedef iSpinMatrix<Complex  >          SpinMatrix;
@@ -127,7 +114,6 @@ typedef iSpinMatrix<ComplexD >          SpinMatrixD;
 typedef iSpinMatrix<vComplex >          vSpinMatrix;
 typedef iSpinMatrix<vComplexF>          vSpinMatrixF;
 typedef iSpinMatrix<vComplexD>          vSpinMatrixD;
 typedef iSpinMatrix<vComplexD2>         vSpinMatrixD2;
 // Colour Matrix
 typedef iColourMatrix<Complex  >        ColourMatrix;
@@ -137,7 +123,6 @@ typedef iColourMatrix<ComplexD >        ColourMatrixD;
 typedef iColourMatrix<vComplex >        vColourMatrix;
 typedef iColourMatrix<vComplexF>        vColourMatrixF;
 typedef iColourMatrix<vComplexD>        vColourMatrixD;
 typedef iColourMatrix<vComplexD2>       vColourMatrixD2;
 // SpinColour matrix
 typedef iSpinColourMatrix<Complex  >    SpinColourMatrix;
@@ -147,7 +132,6 @@ typedef iSpinColourMatrix<ComplexD >    SpinColourMatrixD;
 typedef iSpinColourMatrix<vComplex >    vSpinColourMatrix;
 typedef iSpinColourMatrix<vComplexF>    vSpinColourMatrixF;
 typedef iSpinColourMatrix<vComplexD>    vSpinColourMatrixD;
 typedef iSpinColourMatrix<vComplexD2>   vSpinColourMatrixD2;
 // SpinColourSpinColour matrix
 typedef iSpinColourSpinColourMatrix<Complex  >    SpinColourSpinColourMatrix;
@@ -157,7 +141,6 @@ typedef iSpinColourSpinColourMatrix<ComplexD >    SpinColourSpinColourMatrixD;
 typedef iSpinColourSpinColourMatrix<vComplex >    vSpinColourSpinColourMatrix;
 typedef iSpinColourSpinColourMatrix<vComplexF>    vSpinColourSpinColourMatrixF;
 typedef iSpinColourSpinColourMatrix<vComplexD>    vSpinColourSpinColourMatrixD;
 typedef iSpinColourSpinColourMatrix<vComplexD2>   vSpinColourSpinColourMatrixD2;
 // SpinColourSpinColour matrix
 typedef iSpinColourSpinColourMatrix<Complex  >    SpinColourSpinColourMatrix;
@@ -167,47 +150,24 @@ typedef iSpinColourSpinColourMatrix<ComplexD >    SpinColourSpinColourMatrixD;
 typedef iSpinColourSpinColourMatrix<vComplex >    vSpinColourSpinColourMatrix;
 typedef iSpinColourSpinColourMatrix<vComplexF>    vSpinColourSpinColourMatrixF;
 typedef iSpinColourSpinColourMatrix<vComplexD>    vSpinColourSpinColourMatrixD;
 typedef iSpinColourSpinColourMatrix<vComplexD2>   vSpinColourSpinColourMatrixD2;
 // LorentzColour
 typedef iLorentzColourMatrix<Complex  > LorentzColourMatrix;
 typedef iLorentzColourMatrix<ComplexF > LorentzColourMatrixF;
 typedef iLorentzColourMatrix<ComplexD > LorentzColourMatrixD;
-typedef iLorentzColourMatrix<vComplex >  vLorentzColourMatrix;
+typedef iLorentzColourMatrix<vComplex > vLorentzColourMatrix;
-typedef iLorentzColourMatrix<vComplexF>  vLorentzColourMatrixF;
+typedef iLorentzColourMatrix<vComplexF> vLorentzColourMatrixF;
-typedef iLorentzColourMatrix<vComplexD>  vLorentzColourMatrixD;
+typedef iLorentzColourMatrix<vComplexD> vLorentzColourMatrixD;
 typedef iLorentzColourMatrix<vComplexD2> vLorentzColourMatrixD2;
 // LorentzComplex
 typedef iLorentzComplex<Complex  > LorentzComplex;
 typedef iLorentzComplex<ComplexF > LorentzComplexF;
 typedef iLorentzComplex<ComplexD > LorentzComplexD;
 typedef iLorentzComplex<vComplex > vLorentzComplex;
 typedef iLorentzComplex<vComplexF> vLorentzComplexF;
 typedef iLorentzComplex<vComplexD> vLorentzComplexD;
 // DoubleStored gauge field
 typedef iDoubleStoredColourMatrix<Complex  > DoubleStoredColourMatrix;
 typedef iDoubleStoredColourMatrix<ComplexF > DoubleStoredColourMatrixF;
 typedef iDoubleStoredColourMatrix<ComplexD > DoubleStoredColourMatrixD;
-typedef iDoubleStoredColourMatrix<vComplex >  vDoubleStoredColourMatrix;
+typedef iDoubleStoredColourMatrix<vComplex > vDoubleStoredColourMatrix;
-typedef iDoubleStoredColourMatrix<vComplexF>  vDoubleStoredColourMatrixF;
+typedef iDoubleStoredColourMatrix<vComplexF> vDoubleStoredColourMatrixF;
-typedef iDoubleStoredColourMatrix<vComplexD>  vDoubleStoredColourMatrixD;
+typedef iDoubleStoredColourMatrix<vComplexD> vDoubleStoredColourMatrixD;
 typedef iDoubleStoredColourMatrix<vComplexD2> vDoubleStoredColourMatrixD2;
 //G-parity flavour matrix
 typedef iGparityFlavourMatrix<Complex> GparityFlavourMatrix;
 typedef iGparityFlavourMatrix<ComplexF> GparityFlavourMatrixF;
 typedef iGparityFlavourMatrix<ComplexD> GparityFlavourMatrixD;
 typedef iGparityFlavourMatrix<vComplex>   vGparityFlavourMatrix;
 typedef iGparityFlavourMatrix<vComplexF>  vGparityFlavourMatrixF;
 typedef iGparityFlavourMatrix<vComplexD>  vGparityFlavourMatrixD;
 typedef iGparityFlavourMatrix<vComplexD2> vGparityFlavourMatrixD2;
 // Spin vector
 typedef iSpinVector<Complex >           SpinVector;
@@ -217,7 +177,6 @@ typedef iSpinVector<ComplexD>           SpinVectorD;
 typedef iSpinVector<vComplex >           vSpinVector;
 typedef iSpinVector<vComplexF>           vSpinVectorF;
 typedef iSpinVector<vComplexD>           vSpinVectorD;
 typedef iSpinVector<vComplexD2>          vSpinVectorD2;
 // Colour vector
 typedef iColourVector<Complex >         ColourVector;
@@ -227,7 +186,6 @@ typedef iColourVector<ComplexD>         ColourVectorD;
 typedef iColourVector<vComplex >         vColourVector;
 typedef iColourVector<vComplexF>         vColourVectorF;
 typedef iColourVector<vComplexD>         vColourVectorD;
 typedef iColourVector<vComplexD2>        vColourVectorD2;
 // SpinColourVector
 typedef iSpinColourVector<Complex >     SpinColourVector;
@@ -237,7 +195,6 @@ typedef iSpinColourVector<ComplexD>     SpinColourVectorD;
 typedef iSpinColourVector<vComplex >     vSpinColourVector;
 typedef iSpinColourVector<vComplexF>     vSpinColourVectorF;
 typedef iSpinColourVector<vComplexD>     vSpinColourVectorD;
 typedef iSpinColourVector<vComplexD2>    vSpinColourVectorD2;
 // HalfSpin vector
 typedef iHalfSpinVector<Complex >       HalfSpinVector;
@@ -247,27 +204,15 @@ typedef iHalfSpinVector<ComplexD>       HalfSpinVectorD;
 typedef iHalfSpinVector<vComplex >       vHalfSpinVector;
 typedef iHalfSpinVector<vComplexF>       vHalfSpinVectorF;
 typedef iHalfSpinVector<vComplexD>       vHalfSpinVectorD;
 typedef iHalfSpinVector<vComplexD2>      vHalfSpinVectorD2;
 // HalfSpinColour vector
 typedef iHalfSpinColourVector<Complex > HalfSpinColourVector;
 typedef iHalfSpinColourVector<ComplexF> HalfSpinColourVectorF;
 typedef iHalfSpinColourVector<ComplexD> HalfSpinColourVectorD;
-typedef iHalfSpinColourVector<vComplex >  vHalfSpinColourVector;
+typedef iHalfSpinColourVector<vComplex > vHalfSpinColourVector;
-typedef iHalfSpinColourVector<vComplexF>  vHalfSpinColourVectorF;
+typedef iHalfSpinColourVector<vComplexF> vHalfSpinColourVectorF;
-typedef iHalfSpinColourVector<vComplexD>  vHalfSpinColourVectorD;
+typedef iHalfSpinColourVector<vComplexD> vHalfSpinColourVectorD;
 typedef iHalfSpinColourVector<vComplexD2> vHalfSpinColourVectorD2;
 //G-parity flavour vector
 typedef iGparityFlavourVector<Complex >         GparityFlavourVector;
 typedef iGparityFlavourVector<ComplexF>         GparityFlavourVectorF;
 typedef iGparityFlavourVector<ComplexD>         GparityFlavourVectorD;
 typedef iGparityFlavourVector<vComplex >         vGparityFlavourVector;
 typedef iGparityFlavourVector<vComplexF>         vGparityFlavourVectorF;
 typedef iGparityFlavourVector<vComplexD>         vGparityFlavourVectorD;
 typedef iGparityFlavourVector<vComplexD2>        vGparityFlavourVectorD2;
 // singlets
 typedef iSinglet<Complex >         TComplex;     // FIXME This is painful. Tensor singlet complex type.
@@ -277,7 +222,6 @@ typedef iSinglet<ComplexD>         TComplexD;    // FIXME This is painful. Tenso
 typedef iSinglet<vComplex >        vTComplex ;   // what if we don't know the tensor structure
 typedef iSinglet<vComplexF>        vTComplexF;   // what if we don't know the tensor structure
 typedef iSinglet<vComplexD>        vTComplexD;   // what if we don't know the tensor structure
 typedef iSinglet<vComplexD2>       vTComplexD2;   // what if we don't know the tensor structure
 typedef iSinglet<Real >            TReal;        // Shouldn't need these; can I make it work without?
 typedef iSinglet<RealF>            TRealF;       // Shouldn't need these; can I make it work without?
@@ -295,62 +239,47 @@ typedef iSinglet<Integer >         TInteger;
 typedef Lattice<vColourMatrix>          LatticeColourMatrix;
 typedef Lattice<vColourMatrixF>         LatticeColourMatrixF;
 typedef Lattice<vColourMatrixD>         LatticeColourMatrixD;
 typedef Lattice<vColourMatrixD2>        LatticeColourMatrixD2;
 typedef Lattice<vSpinMatrix>            LatticeSpinMatrix;
 typedef Lattice<vSpinMatrixF>           LatticeSpinMatrixF;
 typedef Lattice<vSpinMatrixD>           LatticeSpinMatrixD;
 typedef Lattice<vSpinMatrixD2>          LatticeSpinMatrixD2;
 typedef Lattice<vSpinColourMatrix>      LatticeSpinColourMatrix;
 typedef Lattice<vSpinColourMatrixF>     LatticeSpinColourMatrixF;
 typedef Lattice<vSpinColourMatrixD>     LatticeSpinColourMatrixD;
 typedef Lattice<vSpinColourMatrixD2>    LatticeSpinColourMatrixD2;
 typedef Lattice<vSpinColourSpinColourMatrix>      LatticeSpinColourSpinColourMatrix;
 typedef Lattice<vSpinColourSpinColourMatrixF>     LatticeSpinColourSpinColourMatrixF;
 typedef Lattice<vSpinColourSpinColourMatrixD>     LatticeSpinColourSpinColourMatrixD;
 typedef Lattice<vSpinColourSpinColourMatrixD2>    LatticeSpinColourSpinColourMatrixD2;
-typedef Lattice<vLorentzColourMatrix>   LatticeLorentzColourMatrix;
+typedef Lattice<vLorentzColourMatrix>  LatticeLorentzColourMatrix;
-typedef Lattice<vLorentzColourMatrixF>  LatticeLorentzColourMatrixF;
+typedef Lattice<vLorentzColourMatrixF> LatticeLorentzColourMatrixF;
-typedef Lattice<vLorentzColourMatrixD>  LatticeLorentzColourMatrixD;
+typedef Lattice<vLorentzColourMatrixD> LatticeLorentzColourMatrixD;
 typedef Lattice<vLorentzColourMatrixD2> LatticeLorentzColourMatrixD2;
 typedef Lattice<vLorentzComplex>  LatticeLorentzComplex;
 typedef Lattice<vLorentzComplexF> LatticeLorentzComplexF;
 typedef Lattice<vLorentzComplexD> LatticeLorentzComplexD;
 // DoubleStored gauge field
-typedef Lattice<vDoubleStoredColourMatrix>   LatticeDoubleStoredColourMatrix;
+typedef Lattice<vDoubleStoredColourMatrix>  LatticeDoubleStoredColourMatrix;
-typedef Lattice<vDoubleStoredColourMatrixF>  LatticeDoubleStoredColourMatrixF;
+typedef Lattice<vDoubleStoredColourMatrixF> LatticeDoubleStoredColourMatrixF;
-typedef Lattice<vDoubleStoredColourMatrixD>  LatticeDoubleStoredColourMatrixD;
+typedef Lattice<vDoubleStoredColourMatrixD> LatticeDoubleStoredColourMatrixD;
 typedef Lattice<vDoubleStoredColourMatrixD2> LatticeDoubleStoredColourMatrixD2;
 typedef Lattice<vSpinVector>            LatticeSpinVector;
 typedef Lattice<vSpinVectorF>           LatticeSpinVectorF;
 typedef Lattice<vSpinVectorD>           LatticeSpinVectorD;
 typedef Lattice<vSpinVectorD2>          LatticeSpinVectorD2;
 typedef Lattice<vColourVector>          LatticeColourVector;
 typedef Lattice<vColourVectorF>         LatticeColourVectorF;
 typedef Lattice<vColourVectorD>         LatticeColourVectorD;
 typedef Lattice<vColourVectorD2>        LatticeColourVectorD2;
 typedef Lattice<vSpinColourVector>      LatticeSpinColourVector;
 typedef Lattice<vSpinColourVectorF>     LatticeSpinColourVectorF;
 typedef Lattice<vSpinColourVectorD>     LatticeSpinColourVectorD;
 typedef Lattice<vSpinColourVectorD2>    LatticeSpinColourVectorD2;
 typedef Lattice<vHalfSpinVector>        LatticeHalfSpinVector;
 typedef Lattice<vHalfSpinVectorF>       LatticeHalfSpinVectorF;
 typedef Lattice<vHalfSpinVectorD>       LatticeHalfSpinVectorD;
 typedef Lattice<vHalfSpinVectorD2>      LatticeHalfSpinVectorD2;
-typedef Lattice<vHalfSpinColourVector>   LatticeHalfSpinColourVector;
+typedef Lattice<vHalfSpinColourVector>  LatticeHalfSpinColourVector;
-typedef Lattice<vHalfSpinColourVectorF>  LatticeHalfSpinColourVectorF;
+typedef Lattice<vHalfSpinColourVectorF> LatticeHalfSpinColourVectorF;
-typedef Lattice<vHalfSpinColourVectorD>  LatticeHalfSpinColourVectorD;
+typedef Lattice<vHalfSpinColourVectorD> LatticeHalfSpinColourVectorD;
 typedef Lattice<vHalfSpinColourVectorD2> LatticeHalfSpinColourVectorD2;
 typedef Lattice<vTReal>            LatticeReal;
 typedef Lattice<vTRealF>           LatticeRealF;
@@ -359,7 +288,6 @@ typedef Lattice<vTRealD>           LatticeRealD;
 typedef Lattice<vTComplex>         LatticeComplex;
 typedef Lattice<vTComplexF>        LatticeComplexF;
 typedef Lattice<vTComplexD>        LatticeComplexD;
 typedef Lattice<vTComplexD2>       LatticeComplexD2;
 typedef Lattice<vTInteger>         LatticeInteger; // Predicates for "where"
@@ -367,42 +295,37 @@ typedef Lattice<vTInteger>         LatticeInteger; // Predicates for "where"
 ///////////////////////////////////////////
 // Physical names for things
 ///////////////////////////////////////////
-typedef LatticeHalfSpinColourVector   LatticeHalfFermion;
+typedef LatticeHalfSpinColourVector  LatticeHalfFermion;
-typedef LatticeHalfSpinColourVectorF  LatticeHalfFermionF;
+typedef LatticeHalfSpinColourVectorF LatticeHalfFermionF;
-typedef LatticeHalfSpinColourVectorD  LatticeHalfFermionD;
+typedef LatticeHalfSpinColourVectorF LatticeHalfFermionD;
 typedef LatticeHalfSpinColourVectorD2 LatticeHalfFermionD2;
 typedef LatticeSpinColourVector      LatticeFermion;
 typedef LatticeSpinColourVectorF     LatticeFermionF;
 typedef LatticeSpinColourVectorD     LatticeFermionD;
 typedef LatticeSpinColourVectorD2    LatticeFermionD2;
 typedef LatticeSpinColourMatrix                LatticePropagator;
 typedef LatticeSpinColourMatrixF               LatticePropagatorF;
 typedef LatticeSpinColourMatrixD               LatticePropagatorD;
 typedef LatticeSpinColourMatrixD2              LatticePropagatorD2;
 typedef LatticeLorentzColourMatrix             LatticeGaugeField;
 typedef LatticeLorentzColourMatrixF            LatticeGaugeFieldF;
 typedef LatticeLorentzColourMatrixD            LatticeGaugeFieldD;
 typedef LatticeLorentzColourMatrixD2           LatticeGaugeFieldD2;
 typedef LatticeDoubleStoredColourMatrix        LatticeDoubledGaugeField;
 typedef LatticeDoubleStoredColourMatrixF       LatticeDoubledGaugeFieldF;
 typedef LatticeDoubleStoredColourMatrixD       LatticeDoubledGaugeFieldD;
 typedef LatticeDoubleStoredColourMatrixD2      LatticeDoubledGaugeFieldD2;
 template<class GF> using LorentzScalar = Lattice<iScalar<typename GF::vector_object::element> >;
 // Uhgg... typing this hurt  ;)
 // (my keyboard got burning hot when I typed this, must be the anti-Fermion)
 typedef Lattice<vColourVector>          LatticeStaggeredFermion;    
 typedef Lattice<vColourVectorF>         LatticeStaggeredFermionF;    
 typedef Lattice<vColourVectorD>         LatticeStaggeredFermionD;    
 typedef Lattice<vColourVectorD2>        LatticeStaggeredFermionD2;    
 typedef Lattice<vColourMatrix>          LatticeStaggeredPropagator; 
 typedef Lattice<vColourMatrixF>         LatticeStaggeredPropagatorF; 
 typedef Lattice<vColourMatrixD>         LatticeStaggeredPropagatorD; 
 typedef Lattice<vColourMatrixD2>        LatticeStaggeredPropagatorD2; 
 //////////////////////////////////////////////////////////////////////////////
 // Peek and Poke named after physics attributes
@@ -521,20 +444,9 @@ template<class vobj> void pokeLorentz(vobj &lhs,const decltype(peekIndex<Lorentz
 // Fermion <-> propagator assignements
 //////////////////////////////////////////////
 //template <class Prop, class Ferm>
 #define FAST_FERM_TO_PROP
 template <class Fimpl>
 void FermToProp(typename Fimpl::PropagatorField &p, const typename Fimpl::FermionField &f, const int s, const int c)
 {
 #ifdef FAST_FERM_TO_PROP
  autoView(p_v,p,CpuWrite);
  autoView(f_v,f,CpuRead);
  thread_for(idx,p_v.oSites(),{
      for(int ss = 0; ss < Ns; ++ss) {
      for(int cc = 0; cc < Fimpl::Dimension; ++cc) {
 	p_v[idx]()(ss,s)(cc,c) = f_v[idx]()(ss)(cc); // Propagator sink index is LEFT, suitable for left mult by gauge link (e.g.)
      }}
    });
 #else
  for(int j = 0; j < Ns; ++j)
    {
      auto pjs = peekSpin(p, j, s);
@@ -546,23 +458,12 @@ void FermToProp(typename Fimpl::PropagatorField &p, const typename Fimpl::Fermio
 	}
      pokeSpin(p, pjs, j, s);
    }
 #endif
 }
 //template <class Prop, class Ferm>
 template <class Fimpl>
 void PropToFerm(typename Fimpl::FermionField &f, const typename Fimpl::PropagatorField &p, const int s, const int c)
 {
 #ifdef FAST_FERM_TO_PROP
  autoView(p_v,p,CpuRead);
  autoView(f_v,f,CpuWrite);
  thread_for(idx,p_v.oSites(),{
      for(int ss = 0; ss < Ns; ++ss) {
      for(int cc = 0; cc < Fimpl::Dimension; ++cc) {
 	f_v[idx]()(ss)(cc) = p_v[idx]()(ss,s)(cc,c); // LEFT index is copied across for s,c right index
      }}
    });
 #else
  for(int j = 0; j < Ns; ++j)
    {
      auto pjs = peekSpin(p, j, s);
@@ -574,7 +475,6 @@ void PropToFerm(typename Fimpl::FermionField &f, const typename Fimpl::Propagato
 	}
      pokeSpin(f, fj, j);
    }
 #endif
 }
 //////////////////////////////////////////////
--- a/Grid/qcd/action/ActionBase.h
+++ b/Grid/qcd/action/ActionBase.h
@@ -34,117 +34,21 @@ directory
 NAMESPACE_BEGIN(Grid);
 ///////////////////////////////////
 // Smart configuration base class
 ///////////////////////////////////
 template< class Field >
 class ConfigurationBase
 {
 public:
  ConfigurationBase() {}
  virtual ~ConfigurationBase() {}
  virtual void set_Field(Field& U) =0;
  virtual void smeared_force(Field&) = 0;
  virtual Field& get_SmearedU() =0;
  virtual Field &get_U(bool smeared = false) = 0;
 };
 template <class GaugeField >
 class Action 
 {
 public:
  bool is_smeared = false;
  RealD deriv_norm_sum;
  RealD deriv_max_sum;
  RealD Fdt_norm_sum;
  RealD Fdt_max_sum;
  int   deriv_num;
  RealD deriv_us;
  RealD S_us;
  RealD refresh_us;
  void  reset_timer(void)        {
    deriv_us = S_us = refresh_us = 0.0;
    deriv_norm_sum = deriv_max_sum=0.0;
    Fdt_max_sum =  Fdt_norm_sum = 0.0;
    deriv_num=0;
  }
  void  deriv_log(RealD nrm, RealD max,RealD Fdt_nrm,RealD Fdt_max) {
    if ( max > deriv_max_sum ) {
      deriv_max_sum=max;
    }
    deriv_norm_sum+=nrm;
    if ( Fdt_max > Fdt_max_sum ) {
      Fdt_max_sum=Fdt_max;
    }
    Fdt_norm_sum+=Fdt_nrm; deriv_num++;
  }
  RealD deriv_max_average(void)       { return deriv_max_sum; };
  RealD deriv_norm_average(void)      { return deriv_norm_sum/deriv_num; };
  RealD Fdt_max_average(void)         { return Fdt_max_sum; };
  RealD Fdt_norm_average(void)        { return Fdt_norm_sum/deriv_num; };
  RealD deriv_timer(void)        { return deriv_us; };
  RealD S_timer(void)            { return S_us; };
  RealD refresh_timer(void)      { return refresh_us; };
  void deriv_timer_start(void)   { deriv_us-=usecond(); }
  void deriv_timer_stop(void)    { deriv_us+=usecond(); }
  void refresh_timer_start(void) { refresh_us-=usecond(); }
  void refresh_timer_stop(void)  { refresh_us+=usecond(); }
  void S_timer_start(void)       { S_us-=usecond(); }
  void S_timer_stop(void)        { S_us+=usecond(); }
  /////////////////////////////
  // Heatbath?
-  /////////////////////////////
+  virtual void refresh(const GaugeField& U, GridParallelRNG& pRNG) = 0; // refresh pseudofermions
  virtual void refresh(const GaugeField& U, GridSerialRNG &sRNG, GridParallelRNG& pRNG) = 0; // refresh pseudofermions
  virtual RealD S(const GaugeField& U) = 0;                             // evaluate the action
  virtual RealD Sinitial(const GaugeField& U) { return this->S(U); } ;  // if the refresh computes the action, can cache it. Alternately refreshAndAction() ?
  virtual void deriv(const GaugeField& U, GaugeField& dSdU) = 0;        // evaluate the action derivative
  /////////////////////////////////////////////////////////////
  // virtual smeared interface through configuration container
  /////////////////////////////////////////////////////////////
  virtual void refresh(ConfigurationBase<GaugeField> & U, GridSerialRNG &sRNG, GridParallelRNG& pRNG)
  {
    refresh(U.get_U(is_smeared),sRNG,pRNG);
  }
  virtual RealD S(ConfigurationBase<GaugeField>& U)
  {
    return S(U.get_U(is_smeared));
  }
  virtual RealD Sinitial(ConfigurationBase<GaugeField>& U) 
  {
    return Sinitial(U.get_U(is_smeared));
  }
  virtual void deriv(ConfigurationBase<GaugeField>& U, GaugeField& dSdU)
  {
    deriv(U.get_U(is_smeared),dSdU); 
    if ( is_smeared ) {
      U.smeared_force(dSdU);
    }
  }
  ///////////////////////////////
  // Logging
  ///////////////////////////////
  virtual std::string action_name()    = 0;                             // return the action name
  virtual std::string LogParameters()  = 0;                             // prints action parameters
  virtual ~Action(){}
 };
 template <class GaugeField >
 class EmptyAction : public Action <GaugeField>
 {
  virtual void refresh(const GaugeField& U, GridSerialRNG &sRNG, GridParallelRNG& pRNG) { assert(0);}; // refresh pseudofermions
  virtual RealD S(const GaugeField& U) { return 0.0;};                             // evaluate the action
  virtual void deriv(const GaugeField& U, GaugeField& dSdU) { assert(0); };        // evaluate the action derivative
  ///////////////////////////////
  // Logging
  ///////////////////////////////
  virtual std::string action_name()    { return std::string("Level Force Log"); };
  virtual std::string LogParameters()  { return std::string("No parameters");};
 };
 NAMESPACE_END(Grid);
 #endif // ACTION_BASE_H
--- a/Grid/qcd/action/ActionCore.h
+++ b/Grid/qcd/action/ActionCore.h
@@ -30,8 +30,6 @@ directory
 #ifndef QCD_ACTION_CORE
 #define QCD_ACTION_CORE
 #include <Grid/qcd/action/gauge/GaugeImplementations.h>
 #include <Grid/qcd/action/ActionBase.h>
 NAMESPACE_CHECK(ActionBase);
 #include <Grid/qcd/action/ActionSet.h>
@@ -39,10 +37,6 @@ NAMESPACE_CHECK(ActionSet);
 #include <Grid/qcd/action/ActionParams.h>
 NAMESPACE_CHECK(ActionParams);
 #include <Grid/qcd/action/filters/MomentumFilter.h>
 #include <Grid/qcd/action/filters/DirichletFilter.h>
 #include <Grid/qcd/action/filters/DDHMCFilter.h>
 ////////////////////////////////////////////
 // Gauge Actions
 ////////////////////////////////////////////
--- a/Grid/qcd/action/ActionParams.h
+++ b/Grid/qcd/action/ActionParams.h
@@ -34,45 +34,27 @@ directory
 NAMESPACE_BEGIN(Grid);
-
+// These can move into a params header and be given MacroMagic serialisation
 struct GparityWilsonImplParams {
  Coordinate twists;
-                     //mu=Nd-1 is assumed to be the time direction and a twist value of 1 indicates antiperiodic BCs
+  GparityWilsonImplParams() : twists(Nd, 0) {};
  Coordinate dirichlet; // Blocksize of dirichlet BCs
  int  partialDirichlet;
  GparityWilsonImplParams() : twists(Nd, 0) {
    dirichlet.resize(0);
    partialDirichlet=0;
  };
 };
 struct WilsonImplParams {
  bool overlapCommsCompute;
  Coordinate dirichlet; // Blocksize of dirichlet BCs
  int  partialDirichlet;
  AcceleratorVector<Real,Nd> twist_n_2pi_L;
  AcceleratorVector<Complex,Nd> boundary_phases;
  WilsonImplParams()  {
    dirichlet.resize(0);
    partialDirichlet=0;
    boundary_phases.resize(Nd, 1.0);
      twist_n_2pi_L.resize(Nd, 0.0);
  };
  WilsonImplParams(const AcceleratorVector<Complex,Nd> phi) : boundary_phases(phi), overlapCommsCompute(false) {
    twist_n_2pi_L.resize(Nd, 0.0);
    partialDirichlet=0;
    dirichlet.resize(0);
  }
 };
 struct StaggeredImplParams {
-  Coordinate dirichlet; // Blocksize of dirichlet BCs
+  StaggeredImplParams()  {};
  int  partialDirichlet;
  StaggeredImplParams()
  {
    partialDirichlet=0;
    dirichlet.resize(0);
  };
 };
  struct OneFlavourRationalParams : Serializable {
@@ -81,11 +63,9 @@ struct StaggeredImplParams {
 				    RealD, hi, 
 				    int,   MaxIter, 
 				    RealD, tolerance, 
 				    RealD, mdtolerance, 
 				    int,   degree, 
 				    int,   precision,
-				    int,   BoundsCheckFreq,
+				    int,   BoundsCheckFreq);
 				    RealD, BoundsCheckTol);
  // MaxIter and tolerance, vectors??
@@ -96,62 +76,16 @@ struct StaggeredImplParams {
 				RealD tol      = 1.0e-8, 
                           	int _degree    = 10,
 				int _precision = 64,
-				int _BoundsCheckFreq=20,
+				int _BoundsCheckFreq=20)
 				RealD mdtol    = 1.0e-6,
 				double _BoundsCheckTol=1e-6)
      : lo(_lo),
 	hi(_hi),
 	MaxIter(_maxit),
 	tolerance(tol),
        mdtolerance(mdtol),
 	degree(_degree),
        precision(_precision),
-        BoundsCheckFreq(_BoundsCheckFreq),
+        BoundsCheckFreq(_BoundsCheckFreq){};
        BoundsCheckTol(_BoundsCheckTol){};
  };
  /*Action parameters for the generalized rational action
    The approximation is for (M^dag M)^{1/inv_pow}
    where inv_pow is the denominator of the fractional power.
    Default inv_pow=2 for square root, making this equivalent to 
    the OneFlavourRational action
  */
    struct RationalActionParams : Serializable {
    GRID_SERIALIZABLE_CLASS_MEMBERS(RationalActionParams, 
 				    int, inv_pow, 
 				    RealD, lo, //low eigenvalue bound of rational approx
 				    RealD, hi, //high eigenvalue bound of rational approx
 				    int,   MaxIter,  //maximum iterations in msCG
 				    RealD, action_tolerance,  //msCG tolerance in action evaluation
 				    int,   action_degree, //rational approx tolerance in action evaluation
 				    RealD, md_tolerance,  //msCG tolerance in MD integration
 				    int,   md_degree, //rational approx tolerance in MD integration
 				    int,   precision, //precision of floating point arithmetic
 				    int,   BoundsCheckFreq); //frequency the approximation is tested (with Metropolis degree/tolerance); 0 disables the check
  // constructor 
  RationalActionParams(int _inv_pow = 2,
 		       RealD _lo      = 0.0, 
 		       RealD _hi      = 1.0, 
 		       int _maxit     = 1000,
 		       RealD _action_tolerance      = 1.0e-8, 
 		       int _action_degree    = 10,
 		       RealD _md_tolerance      = 1.0e-8, 
 		       int _md_degree    = 10,
 		       int _precision = 64,
 		       int _BoundsCheckFreq=20)
    : inv_pow(_inv_pow), 
      lo(_lo),
      hi(_hi),
      MaxIter(_maxit),
      action_tolerance(_action_tolerance),
      action_degree(_action_degree),
      md_tolerance(_md_tolerance),
      md_degree(_md_degree),
      precision(_precision),
      BoundsCheckFreq(_BoundsCheckFreq){};
  };
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/qcd/action/fermion/CayleyFermion5D.h
+++ b/Grid/qcd/action/fermion/CayleyFermion5D.h
@@ -68,17 +68,9 @@ public:
  ///////////////////////////////////////////////////////////////
  // Support for MADWF tricks
  ///////////////////////////////////////////////////////////////
-  RealD Mass(void) { return (mass_plus + mass_minus) / 2.0; };
+  RealD Mass(void) { return mass; };
  RealD MassPlus(void) { return mass_plus; };
  RealD MassMinus(void) { return mass_minus; };
  void  SetMass(RealD _mass) { 
-    mass_plus=mass_minus=_mass; 
+    mass=_mass; 
    SetCoefficientsInternal(_zolo_hi,_gamma,_b,_c);  // Reset coeffs
  } ;
  void  SetMass(RealD _mass_plus, RealD _mass_minus) { 
    mass_plus=_mass_plus;
    mass_minus=_mass_minus;
    SetCoefficientsInternal(_zolo_hi,_gamma,_b,_c);  // Reset coeffs
  } ;
  void  P(const FermionField &psi, FermionField &chi);
@@ -116,7 +108,7 @@ public:
  void   MeooeDag5D    (const FermionField &in, FermionField &out);
  //    protected:
-  RealD mass_plus, mass_minus;
+  RealD mass;
  // Save arguments to SetCoefficientsInternal
  Vector<Coeff_t> _gamma;
@@ -183,6 +175,16 @@ public:
 		  GridRedBlackCartesian &FourDimRedBlackGrid,
 		  RealD _mass,RealD _M5,const ImplParams &p= ImplParams());
  void CayleyReport(void);
  void CayleyZeroCounters(void);
  double M5Dflops;
  double M5Dcalls;
  double M5Dtime;
  double MooeeInvFlops;
  double MooeeInvCalls;
  double MooeeInvTime;
 protected:
  virtual void SetCoefficientsZolotarev(RealD zolohi,Approx::zolotarev_data *zdata,RealD b,RealD c);
--- a/Grid/qcd/action/fermion/CloverHelpers.h
+++ b/Grid/qcd/action/fermion/CloverHelpers.h
@@ -1,334 +0,0 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid
    Source file: ./lib/qcd/action/fermion/WilsonCloverFermionImplementation.h
    Copyright (C) 2017 - 2022
    Author: paboyle <paboyle@ph.ed.ac.uk>
    Author: Daniel Richtmann <daniel.richtmann@gmail.com>
    Author: Mattia Bruno <mattia.bruno@cern.ch>
    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/Grid.h>
 #include <Grid/qcd/spin/Dirac.h>
 #include <Grid/qcd/action/fermion/WilsonCloverHelpers.h>
 ////////////////////////////////////////////
 // Standard Clover
 //   (4+m0) + csw * clover_term
 // Exp Clover
 //   (4+m0) * exp(csw/(4+m0) clover_term)
 //   = (4+m0) + csw * clover_term + ...
 ////////////////////////////////////////////
 NAMESPACE_BEGIN(Grid);
 //////////////////////////////////
 // Generic Standard Clover
 //////////////////////////////////
 template<class Impl>
 class CloverHelpers: public WilsonCloverHelpers<Impl> {
 public:
  INHERIT_IMPL_TYPES(Impl);
  INHERIT_CLOVER_TYPES(Impl);
  typedef WilsonCloverHelpers<Impl> Helpers;
  static void Instantiate(CloverField& CloverTerm, CloverField& CloverTermInv, RealD csw_t, RealD diag_mass) {
    GridBase *grid = CloverTerm.Grid();
    CloverTerm += diag_mass;
    int lvol = grid->lSites();
    int DimRep = Impl::Dimension;
    {
      autoView(CTv,CloverTerm,CpuRead);
      autoView(CTIv,CloverTermInv,CpuWrite);
      thread_for(site, lvol, {
        Coordinate lcoor;
        grid->LocalIndexToLocalCoor(site, lcoor);
        Eigen::MatrixXcd EigenCloverOp = Eigen::MatrixXcd::Zero(Ns * DimRep, Ns * DimRep);
        Eigen::MatrixXcd EigenInvCloverOp = Eigen::MatrixXcd::Zero(Ns * DimRep, Ns * DimRep);
        typename SiteClover::scalar_object Qx = Zero(), Qxinv = Zero();
        peekLocalSite(Qx, CTv, lcoor);
        for (int j = 0; j < Ns; j++)
          for (int k = 0; k < Ns; k++)
            for (int a = 0; a < DimRep; a++)
              for (int b = 0; b < DimRep; b++){
                auto zz =  Qx()(j, k)(a, b);
                EigenCloverOp(a + j * DimRep, b + k * DimRep) = std::complex<double>(zz);
              }
        EigenInvCloverOp = EigenCloverOp.inverse();
        for (int j = 0; j < Ns; j++)
          for (int k = 0; k < Ns; k++)
            for (int a = 0; a < DimRep; a++)
              for (int b = 0; b < DimRep; b++)
                Qxinv()(j, k)(a, b) = EigenInvCloverOp(a + j * DimRep, b + k * DimRep);
               pokeLocalSite(Qxinv, CTIv, lcoor);
      });
    }
  }
  static GaugeLinkField Cmunu(std::vector<GaugeLinkField> &U, GaugeLinkField &lambda, int mu, int nu) {
    return Helpers::Cmunu(U, lambda, mu, nu);
  }
 };
 //////////////////////////////////
 // Generic Exp Clover
 //////////////////////////////////
 template<class Impl>
 class ExpCloverHelpers: public WilsonCloverHelpers<Impl> {
 public:
  INHERIT_IMPL_TYPES(Impl);
  INHERIT_CLOVER_TYPES(Impl);
  template <typename vtype> using iImplClover = iScalar<iMatrix<iMatrix<vtype, Impl::Dimension>, Ns>>;
  typedef WilsonCloverHelpers<Impl> Helpers;
  // Can this be avoided?
  static void IdentityTimesC(const CloverField& in, RealD c) {
    int DimRep = Impl::Dimension;
    autoView(in_v, in, AcceleratorWrite);
    accelerator_for(ss, in.Grid()->oSites(), 1, {
      for (int sa=0; sa<Ns; sa++)
        for (int ca=0; ca<DimRep; ca++)
          in_v[ss]()(sa,sa)(ca,ca) = c;
    });
  }
  static int getNMAX(RealD prec, RealD R) {
    /* compute stop condition for exponential */
    int NMAX=1;
    RealD cond=R*R/2.;
    while (cond*std::exp(R)>prec) {
      NMAX++;
      cond*=R/(double)(NMAX+1);
    }
    return NMAX;
  }
  static int getNMAX(Lattice<iImplClover<vComplexD2>> &t, RealD R) {return getNMAX(1e-12,R);}
  static int getNMAX(Lattice<iImplClover<vComplexD>> &t, RealD R) {return getNMAX(1e-12,R);}
  static int getNMAX(Lattice<iImplClover<vComplexF>> &t, RealD R) {return getNMAX(1e-6,R);}
  static void Instantiate(CloverField& Clover, CloverField& CloverInv, RealD csw_t, RealD diag_mass) {
    GridBase* grid = Clover.Grid();
    CloverField ExpClover(grid);
    int NMAX = getNMAX(Clover, 3.*csw_t/diag_mass);
    Clover *= (1.0/diag_mass);
    // Taylor expansion, slow but generic
    // Horner scheme: a0 + a1 x + a2 x^2 + .. = a0 + x (a1 + x(...))
    // qN = cN
    // qn = cn + qn+1 X
    std::vector<RealD> cn(NMAX+1);
    cn[0] = 1.0;
    for (int i=1; i<=NMAX; i++)
      cn[i] = cn[i-1] / RealD(i);
    ExpClover = Zero();
    IdentityTimesC(ExpClover, cn[NMAX]);
    for (int i=NMAX-1; i>=0; i--)
      ExpClover = ExpClover * Clover + cn[i];
    // prepare inverse
    CloverInv = (-1.0)*Clover;
    Clover = ExpClover * diag_mass;
    ExpClover = Zero();
    IdentityTimesC(ExpClover, cn[NMAX]);
    for (int i=NMAX-1; i>=0; i--)
      ExpClover = ExpClover * CloverInv + cn[i];
    CloverInv = ExpClover * (1.0/diag_mass);
  }
  static GaugeLinkField Cmunu(std::vector<GaugeLinkField> &U, GaugeLinkField &lambda, int mu, int nu) {
    assert(0);
    return lambda;
  }
 };
 //////////////////////////////////
 // Compact Standard Clover
 //////////////////////////////////
 template<class Impl>
 class CompactCloverHelpers: public CompactWilsonCloverHelpers<Impl>,
                            public WilsonCloverHelpers<Impl> {
 public:
  INHERIT_IMPL_TYPES(Impl);
  INHERIT_CLOVER_TYPES(Impl);
  INHERIT_COMPACT_CLOVER_TYPES(Impl);
  typedef WilsonCloverHelpers<Impl> Helpers;
  typedef CompactWilsonCloverHelpers<Impl> CompactHelpers;
  static void InstantiateClover(CloverField& Clover, CloverField& CloverInv, RealD csw_t, RealD diag_mass) {
    Clover += diag_mass;
  }
  static void InvertClover(CloverField& InvClover,
                            const CloverDiagonalField& diagonal,
                            const CloverTriangleField& triangle,
                            CloverDiagonalField&       diagonalInv,
                            CloverTriangleField&       triangleInv,
                            bool fixedBoundaries) {
    CompactHelpers::Invert(diagonal, triangle, diagonalInv, triangleInv);
  }
  // TODO: implement Cmunu for better performances with compact layout, but don't do it
  // here, but rather in WilsonCloverHelpers.h -> CompactWilsonCloverHelpers
  static GaugeLinkField Cmunu(std::vector<GaugeLinkField> &U, GaugeLinkField &lambda, int mu, int nu) {
    return Helpers::Cmunu(U, lambda, mu, nu);
  }
 };
 //////////////////////////////////
 // Compact Exp Clover
 //////////////////////////////////
 template<class Impl>
 class CompactExpCloverHelpers: public CompactWilsonCloverHelpers<Impl> {
 public:
  INHERIT_IMPL_TYPES(Impl);
  INHERIT_CLOVER_TYPES(Impl);
  INHERIT_COMPACT_CLOVER_TYPES(Impl);
  template <typename vtype> using iImplClover = iScalar<iMatrix<iMatrix<vtype, Impl::Dimension>, Ns>>;
  typedef CompactWilsonCloverHelpers<Impl> CompactHelpers;
  // Can this be avoided?
  static void IdentityTimesC(const CloverField& in, RealD c) {
    int DimRep = Impl::Dimension;
    autoView(in_v, in, AcceleratorWrite);
    accelerator_for(ss, in.Grid()->oSites(), 1, {
      for (int sa=0; sa<Ns; sa++)
        for (int ca=0; ca<DimRep; ca++)
          in_v[ss]()(sa,sa)(ca,ca) = c;
    });
  }
  static int getNMAX(RealD prec, RealD R) {
    /* compute stop condition for exponential */
    int NMAX=1;
    RealD cond=R*R/2.;
    while (cond*std::exp(R)>prec) {
      NMAX++;
      cond*=R/(double)(NMAX+1);
    }
    return NMAX;
  }
  static int getNMAX(Lattice<iImplClover<vComplexD>> &t, RealD R) {return getNMAX(1e-12,R);}
  static int getNMAX(Lattice<iImplClover<vComplexF>> &t, RealD R) {return getNMAX(1e-6,R);}
  static void InstantiateClover(CloverField& Clover, CloverField& CloverInv, RealD csw_t, RealD diag_mass) {
    GridBase* grid = Clover.Grid();
    CloverField ExpClover(grid);
    int NMAX = getNMAX(Clover, 3.*csw_t/diag_mass);
    Clover *= (1.0/diag_mass);
    // Taylor expansion, slow but generic
    // Horner scheme: a0 + a1 x + a2 x^2 + .. = a0 + x (a1 + x(...))
    // qN = cN
    // qn = cn + qn+1 X
    std::vector<RealD> cn(NMAX+1);
    cn[0] = 1.0;
    for (int i=1; i<=NMAX; i++)
      cn[i] = cn[i-1] / RealD(i);
    ExpClover = Zero();
    IdentityTimesC(ExpClover, cn[NMAX]);
    for (int i=NMAX-1; i>=0; i--)
      ExpClover = ExpClover * Clover + cn[i];
    // prepare inverse
    CloverInv = (-1.0)*Clover;
    Clover = ExpClover * diag_mass;
    ExpClover = Zero();
    IdentityTimesC(ExpClover, cn[NMAX]);
    for (int i=NMAX-1; i>=0; i--)
      ExpClover = ExpClover * CloverInv + cn[i];
    CloverInv = ExpClover * (1.0/diag_mass);
  }
  static void InvertClover(CloverField& InvClover,
                            const CloverDiagonalField& diagonal,
                            const CloverTriangleField& triangle,
                            CloverDiagonalField&       diagonalInv,
                            CloverTriangleField&       triangleInv,
                            bool fixedBoundaries) {
    if (fixedBoundaries)
    {
      CompactHelpers::Invert(diagonal, triangle, diagonalInv, triangleInv);
    }
    else
    {
      CompactHelpers::ConvertLayout(InvClover, diagonalInv, triangleInv);
    }
  }
  static GaugeLinkField Cmunu(std::vector<GaugeLinkField> &U, GaugeLinkField &lambda, int mu, int nu) {
    assert(0);
    return lambda;
  }
 };
 NAMESPACE_END(Grid);
--- a/Grid/qcd/action/fermion/CompactWilsonCloverFermion.h
+++ b/Grid/qcd/action/fermion/CompactWilsonCloverFermion.h
@@ -1,241 +0,0 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid
    Source file: ./lib/qcd/action/fermion/CompactWilsonCloverFermion.h
    Copyright (C) 2020 - 2022
    Author: Daniel Richtmann <daniel.richtmann@gmail.com>
    Author: Nils Meyer <nils.meyer@ur.de>
    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/action/fermion/WilsonCloverTypes.h>
 #include <Grid/qcd/action/fermion/WilsonCloverHelpers.h>
 #include <Grid/qcd/action/fermion/CloverHelpers.h>
 NAMESPACE_BEGIN(Grid);
 // see Grid/qcd/action/fermion/WilsonCloverFermion.h for description
 //
 // Modifications done here:
 //
 // Original: clover term = 12x12 matrix per site
 //
 // But: Only two diagonal 6x6 hermitian blocks are non-zero (also true for original, verified by running)
 // Sufficient to store/transfer only the real parts of the diagonal and one triangular part
 // 2 * (6 + 15 * 2) = 72 real or 36 complex words to be stored/transfered
 //
 // Here: Above but diagonal as complex numbers, i.e., need to store/transfer
 // 2 * (6 * 2 + 15 * 2) = 84 real or 42 complex words
 //
 // Words per site and improvement compared to original (combined with the input and output spinors):
 //
 // - Original: 2*12 + 12*12 = 168 words -> 1.00 x less
 // - Minimal:  2*12 + 36    =  60 words -> 2.80 x less
 // - Here:     2*12 + 42    =  66 words -> 2.55 x less
 //
 // These improvements directly translate to wall-clock time
 //
 // Data layout:
 //
 // - diagonal and triangle part as separate lattice fields,
 //   this was faster than as 1 combined field on all tested machines
 // - diagonal: as expected
 // - triangle: store upper right triangle in row major order
 // - graphical:
 //        0  1  2  3  4
 //           5  6  7  8
 //              9 10 11 = upper right triangle indices
 //                12 13
 //                   14
 //     0
 //        1
 //           2
 //              3       = diagonal indices
 //                 4
 //                    5
 //     0
 //     1  5
 //     2  6  9          = lower left triangle indices
 //     3  7 10 12
 //     4  8 11 13 14
 //
 // Impact on total memory consumption:
 // - Original: (2 * 1 + 8 * 1/2) 12x12 matrices = 6 12x12 matrices = 864 complex words per site
 // - Here:     (2 * 1 + 4 * 1/2) diagonal parts = 4 diagonal parts =  24 complex words per site
 //           + (2 * 1 + 4 * 1/2) triangle parts = 4 triangle parts =  60 complex words per site
 //                                                                 =  84 complex words per site
 template<class Impl, class CloverHelpers>
 class CompactWilsonCloverFermion : public WilsonFermion<Impl>,
                                   public WilsonCloverHelpers<Impl>,
                                   public CompactWilsonCloverHelpers<Impl> {
  /////////////////////////////////////////////
  // Sizes
  /////////////////////////////////////////////
 public:
  INHERIT_COMPACT_CLOVER_SIZES(Impl);
  /////////////////////////////////////////////
  // Type definitions
  /////////////////////////////////////////////
 public:
  INHERIT_IMPL_TYPES(Impl);
  INHERIT_CLOVER_TYPES(Impl);
  INHERIT_COMPACT_CLOVER_TYPES(Impl);
  typedef WilsonFermion<Impl>              WilsonBase;
  typedef WilsonCloverHelpers<Impl>        Helpers;
  typedef CompactWilsonCloverHelpers<Impl> CompactHelpers;
  /////////////////////////////////////////////
  // Constructors
  /////////////////////////////////////////////
 public:
  CompactWilsonCloverFermion(GaugeField& _Umu,
 			    GridCartesian& Fgrid,
 			    GridRedBlackCartesian& Hgrid,
 			    const RealD _mass,
 			    const RealD _csw_r = 0.0,
 			    const RealD _csw_t = 0.0,
 			    const RealD _cF = 1.0,
 			    const WilsonAnisotropyCoefficients& clover_anisotropy = WilsonAnisotropyCoefficients(),
 			    const ImplParams& impl_p = ImplParams());
  /////////////////////////////////////////////
  // Member functions (implementing interface)
  /////////////////////////////////////////////
 public:
  virtual void Instantiatable() {};
  int          ConstEE()     override { return 0; };
  int          isTrivialEE() override { return 0; };
  void Dhop(const FermionField& in, FermionField& out, int dag) override;
  void DhopOE(const FermionField& in, FermionField& out, int dag) override;
  void DhopEO(const FermionField& in, FermionField& out, int dag) override;
  void DhopDir(const FermionField& in, FermionField& out, int dir, int disp) override;
  void DhopDirAll(const FermionField& in, std::vector<FermionField>& out) /* override */;
  void M(const FermionField& in, FermionField& out) override;
  void Mdag(const FermionField& in, FermionField& out) override;
  void Meooe(const FermionField& in, FermionField& out) override;
  void MeooeDag(const FermionField& in, FermionField& out) override;
  void Mooee(const FermionField& in, FermionField& out) override;
  void MooeeDag(const FermionField& in, FermionField& out) override;
  void MooeeInv(const FermionField& in, FermionField& out) override;
  void MooeeInvDag(const FermionField& in, FermionField& out) override;
  void Mdir(const FermionField& in, FermionField& out, int dir, int disp) override;
  void MdirAll(const FermionField& in, std::vector<FermionField>& out) override;
  void MDeriv(GaugeField& force, const FermionField& X, const FermionField& Y, int dag) override;
  void MooDeriv(GaugeField& mat, const FermionField& U, const FermionField& V, int dag) override;
  void MeeDeriv(GaugeField& mat, const FermionField& U, const FermionField& V, int dag) override;
  /////////////////////////////////////////////
  // Member functions (internals)
  /////////////////////////////////////////////
  void MooeeInternal(const FermionField&        in,
                     FermionField&              out,
                     const CloverDiagonalField& diagonal,
                     const CloverTriangleField& triangle);
  /////////////////////////////////////////////
  // Helpers
  /////////////////////////////////////////////
  void ImportGauge(const GaugeField& _Umu) override;
  /////////////////////////////////////////////
  // Helpers
  /////////////////////////////////////////////
 private:
  template<class Field>
  const MaskField* getCorrectMaskField(const Field &in) const {
    if(in.Grid()->_isCheckerBoarded) {
      if(in.Checkerboard() == Odd) {
        return &this->BoundaryMaskOdd;
      } else {
        return &this->BoundaryMaskEven;
      }
    } else {
      return &this->BoundaryMask;
    }
  }
  template<class Field>
  void ApplyBoundaryMask(Field& f) {
    const MaskField* m = getCorrectMaskField(f); assert(m != nullptr);
    assert(m != nullptr);
    CompactHelpers::ApplyBoundaryMask(f, *m);
  }
  /////////////////////////////////////////////
  // Member Data
  /////////////////////////////////////////////
 public:
  RealD csw_r;
  RealD csw_t;
  RealD cF;
  bool fixedBoundaries;
  CloverDiagonalField Diagonal,    DiagonalEven,    DiagonalOdd;
  CloverDiagonalField DiagonalInv, DiagonalInvEven, DiagonalInvOdd;
  CloverTriangleField Triangle,    TriangleEven,    TriangleOdd;
  CloverTriangleField TriangleInv, TriangleInvEven, TriangleInvOdd;
  FermionField Tmp;
  MaskField BoundaryMask, BoundaryMaskEven, BoundaryMaskOdd;
 };
 NAMESPACE_END(Grid);
--- a/Grid/qcd/action/fermion/DWFSlow.h
+++ b/Grid/qcd/action/fermion/DWFSlow.h
@@ -1,291 +0,0 @@
 /*************************************************************************************
 Grid physics library, www.github.com/paboyle/Grid
 Source file: ./lib/qcd/action/fermion/DWFSlow.h
 Copyright (C) 2022
 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);
 template <class Impl>
 class DWFSlowFermion : public FermionOperator<Impl>
 {
 public:
  INHERIT_IMPL_TYPES(Impl);
  ///////////////////////////////////////////////////////////////
  // Implement the abstract base
  ///////////////////////////////////////////////////////////////
  GridBase *GaugeGrid(void) { return _grid4; }
  GridBase *GaugeRedBlackGrid(void) { return _cbgrid4; }
  GridBase *FermionGrid(void) { return _grid; }
  GridBase *FermionRedBlackGrid(void) { return _cbgrid; }
  FermionField _tmp;
  FermionField &tmp(void) { return _tmp; }
  //////////////////////////////////////////////////////////////////
  // override multiply; cut number routines if pass dagger argument
  // and also make interface more uniformly consistent
  //////////////////////////////////////////////////////////////////
  virtual void  M(const FermionField &in, FermionField &out)
  {
    FermionField tmp(_grid);
    out = (5.0 - M5) * in;
    Dhop(in,tmp,DaggerNo);
    out = out + tmp;
  }
  virtual void  Mdag(const FermionField &in, FermionField &out)
  {
    FermionField tmp(_grid);
    out = (5.0 - M5) * in;
    Dhop(in,tmp,DaggerYes);
    out = out + tmp;
  };
  /////////////////////////////////////////////////////////
  // half checkerboard operations 5D redblack so just site identiy
  /////////////////////////////////////////////////////////
  void Meooe(const FermionField &in, FermionField &out)
  {
    if ( in.Checkerboard() == Odd ) {
      this->DhopEO(in,out,DaggerNo);
    } else {
      this->DhopOE(in,out,DaggerNo);
    }
  }
  void MeooeDag(const FermionField &in, FermionField &out)
  {
    if ( in.Checkerboard() == Odd ) {
      this->DhopEO(in,out,DaggerYes);
    } else {
      this->DhopOE(in,out,DaggerYes);
    }
  };
  // allow override for twisted mass and clover
  virtual void Mooee(const FermionField &in, FermionField &out)
  {
    out = (5.0 - M5) * in;
  }
  virtual void MooeeDag(const FermionField &in, FermionField &out)
  {
    out = (5.0 - M5) * in;
  }
  virtual void MooeeInv(const FermionField &in, FermionField &out)
  {
    out = (1.0/(5.0 - M5)) * in;
  };
  virtual void MooeeInvDag(const FermionField &in, FermionField &out)
  {
    out = (1.0/(5.0 - M5)) * in;
  };
  virtual void  MomentumSpacePropagator(FermionField &out,const FermionField &in,RealD _mass,std::vector<double> twist) {} ;
  ////////////////////////
  // Derivative interface
  ////////////////////////
  // Interface calls an internal routine
  void DhopDeriv(GaugeField &mat,const FermionField &U,const FermionField &V,int dag)  { assert(0);};
  void DhopDerivOE(GaugeField &mat,const FermionField &U,const FermionField &V,int dag){ assert(0);};
  void DhopDerivEO(GaugeField &mat,const FermionField &U,const FermionField &V,int dag){ assert(0);};
  ///////////////////////////////////////////////////////////////
  // non-hermitian hopping term; half cb or both
  ///////////////////////////////////////////////////////////////
  void Dhop(const FermionField &in, FermionField &out, int dag)
  {
    FermionField tmp(in.Grid());
    Dhop5(in,out,MassField,MassField,dag );
    for(int mu=0;mu<4;mu++){
      DhopDirU(in,Umu[mu],Umu[mu],tmp,mu,dag );    out = out + tmp;
    }
  };
  void DhopOE(const FermionField &in, FermionField &out, int dag)
  {
    FermionField tmp(in.Grid());
    assert(in.Checkerboard()==Even);
    Dhop5(in,out,MassFieldOdd,MassFieldEven,dag);
    for(int mu=0;mu<4;mu++){
      DhopDirU(in,UmuOdd[mu],UmuEven[mu],tmp,mu,dag );    out = out + tmp;
    }
  };
  void DhopEO(const FermionField &in, FermionField &out, int dag)
  {
    FermionField tmp(in.Grid());
    assert(in.Checkerboard()==Odd);
    Dhop5(in,out, MassFieldEven,MassFieldOdd ,dag );  
    for(int mu=0;mu<4;mu++){
      DhopDirU(in,UmuEven[mu],UmuOdd[mu],tmp,mu,dag );    out = out + tmp;
    }
  };
  ///////////////////////////////////////////////////////////////
  // Multigrid assistance; force term uses too
  ///////////////////////////////////////////////////////////////
  void Mdir(const FermionField &in, FermionField &out, int dir, int disp){ assert(0);};
  void MdirAll(const FermionField &in, std::vector<FermionField> &out)   { assert(0);};
  void DhopDir(const FermionField &in, FermionField &out, int dir, int disp) { assert(0);};
  void DhopDirAll(const FermionField &in, std::vector<FermionField> &out)    { assert(0);};
  void DhopDirCalc(const FermionField &in, FermionField &out, int dirdisp,int gamma, int dag) { assert(0);};
  void DhopDirU(const FermionField &in, const GaugeLinkField &U5e, const GaugeLinkField &U5o, FermionField &out, int mu, int dag)
  {
    RealD     sgn= 1.0;
    if (dag ) sgn=-1.0;
    Gamma::Algebra Gmu [] = {
 			 Gamma::Algebra::GammaX,
 			 Gamma::Algebra::GammaY,
 			 Gamma::Algebra::GammaZ,
 			 Gamma::Algebra::GammaT
    };
    //    mass is  1,1,1,1,-m has to multiply the round the world term
    FermionField tmp (in.Grid());
    tmp = U5e * Cshift(in,mu+1,1);
    out = tmp - Gamma(Gmu[mu])*tmp*sgn;
    tmp = Cshift(adj(U5o)*in,mu+1,-1);
    out = out + tmp + Gamma(Gmu[mu])*tmp*sgn;
    out = -0.5*out;
  };
  void Dhop5(const FermionField &in, FermionField &out, ComplexField &massE, ComplexField &massO, int dag)
  {
    // Mass term.... must multiple the round world with mass = 1,1,1,1, -m
    RealD     sgn= 1.0;
    if (dag ) sgn=-1.0;
    Gamma G5(Gamma::Algebra::Gamma5);
    FermionField tmp (in.Grid());
    tmp = massE*Cshift(in,0,1);
    out = tmp - G5*tmp*sgn;
    tmp = Cshift(massO*in,0,-1);
    out = out + tmp + G5*tmp*sgn;
    out = -0.5*out;
  };
  // Constructor
  DWFSlowFermion(GaugeField &_Umu, GridCartesian &Fgrid,
 		 GridRedBlackCartesian &Hgrid, RealD _mass, RealD _M5)
    :
    _grid(&Fgrid),
    _cbgrid(&Hgrid),
    _grid4(_Umu.Grid()),
    Umu(Nd,&Fgrid),
    UmuEven(Nd,&Hgrid),
    UmuOdd(Nd,&Hgrid),
    MassField(&Fgrid),
    MassFieldEven(&Hgrid),
    MassFieldOdd(&Hgrid),
    M5(_M5),
    mass(_mass),
    _tmp(&Hgrid)
    {
      Ls=Fgrid._fdimensions[0];
      ImportGauge(_Umu);
      typedef typename FermionField::scalar_type scalar;
      Lattice<iScalar<vInteger> > coor(&Fgrid);
      LatticeCoordinate(coor, 0); // Scoor
      ComplexField one(&Fgrid);
      MassField =scalar(-mass);
      one       =scalar(1.0);
      MassField =where(coor==Integer(Ls-1),MassField,one);
      for(int mu=0;mu<Nd;mu++){
 	pickCheckerboard(Even,UmuEven[mu],Umu[mu]);
 	pickCheckerboard(Odd ,UmuOdd[mu],Umu[mu]);
      }
      pickCheckerboard(Even,MassFieldEven,MassField);
      pickCheckerboard(Odd ,MassFieldOdd,MassField);
    }
  // DoubleStore impl dependent
  void ImportGauge(const GaugeField &_Umu4)
  {
    GaugeLinkField U4(_grid4);
    for(int mu=0;mu<Nd;mu++){
      U4 = PeekIndex<LorentzIndex>(_Umu4, mu);
      for(int s=0;s<this->Ls;s++){
 	InsertSlice(U4,Umu[mu],s,0);
      }
    }
  }
  ///////////////////////////////////////////////////////////////
  // Data members require to support the functionality
  ///////////////////////////////////////////////////////////////
 public:
  virtual RealD Mass(void) { return mass; }
  virtual int   isTrivialEE(void) { return 1; };
  RealD mass;
  RealD M5;
  int Ls;
  GridBase *_grid4;
  GridBase *_grid;
  GridBase *_cbgrid4;
  GridBase *_cbgrid;
  // Copy of the gauge field , with even and odd subsets
  std::vector<GaugeLinkField> Umu;
  std::vector<GaugeLinkField> UmuEven;
  std::vector<GaugeLinkField> UmuOdd;
  ComplexField MassField;
  ComplexField MassFieldEven;
  ComplexField MassFieldOdd;
  ///////////////////////////////////////////////////////////////
  // Conserved current utilities
  ///////////////////////////////////////////////////////////////
  void ContractConservedCurrent(PropagatorField &q_in_1,
                                PropagatorField &q_in_2,
                                PropagatorField &q_out,
                                PropagatorField &phys_src,
                                Current curr_type,
                                unsigned int mu){}
  void SeqConservedCurrent(PropagatorField &q_in,
                           PropagatorField &q_out,
                           PropagatorField &phys_src,
                           Current curr_type,
                           unsigned int mu,
                           unsigned int tmin,
 			   unsigned int tmax,
 			   ComplexField &lattice_cmplx){}
 };
 typedef DWFSlowFermion<WilsonImplF> DWFSlowFermionF;
 typedef DWFSlowFermion<WilsonImplD> DWFSlowFermionD;
 NAMESPACE_END(Grid);
--- a/Grid/qcd/action/fermion/Fermion.h
+++ b/Grid/qcd/action/fermion/Fermion.h
@@ -47,14 +47,12 @@ Author: Peter Boyle <pabobyle@ph.ed.ac.uk>
 ////////////////////////////////////////////
 // Fermion operators / actions
 ////////////////////////////////////////////
 #include <Grid/qcd/action/fermion/DWFSlow.h>       // Slow DWF
 #include <Grid/qcd/action/fermion/WilsonFermion.h>       // 4d wilson like
 NAMESPACE_CHECK(Wilson);
 #include <Grid/qcd/action/fermion/WilsonTMFermion.h>       // 4d wilson like
 NAMESPACE_CHECK(WilsonTM);
 #include <Grid/qcd/action/fermion/WilsonCloverFermion.h> // 4d wilson clover fermions
 #include <Grid/qcd/action/fermion/CompactWilsonCloverFermion.h> // 4d compact wilson clover fermions
 NAMESPACE_CHECK(WilsonClover);
 #include <Grid/qcd/action/fermion/WilsonFermion5D.h>     // 5d base used by all 5d overlap types
 NAMESPACE_CHECK(Wilson5D);
@@ -113,164 +111,192 @@ NAMESPACE_CHECK(DWFutils);
 // Cayley 5d
 NAMESPACE_BEGIN(Grid);
-typedef WilsonFermion<WilsonImplD2> WilsonFermionD2;
+typedef WilsonFermion<WilsonImplR> WilsonFermionR;
 typedef WilsonFermion<WilsonImplF> WilsonFermionF;
 typedef WilsonFermion<WilsonImplD> WilsonFermionD;
 typedef WilsonFermion<WilsonImplRL> WilsonFermionRL;
 typedef WilsonFermion<WilsonImplFH> WilsonFermionFH;
 typedef WilsonFermion<WilsonImplDF> WilsonFermionDF;
 typedef WilsonFermion<WilsonAdjImplR> WilsonAdjFermionR;
 typedef WilsonFermion<WilsonAdjImplF> WilsonAdjFermionF;
 typedef WilsonFermion<WilsonAdjImplD> WilsonAdjFermionD;
 typedef WilsonFermion<WilsonTwoIndexSymmetricImplR> WilsonTwoIndexSymmetricFermionR;
 typedef WilsonFermion<WilsonTwoIndexSymmetricImplF> WilsonTwoIndexSymmetricFermionF;
 typedef WilsonFermion<WilsonTwoIndexSymmetricImplD> WilsonTwoIndexSymmetricFermionD;
 typedef WilsonFermion<WilsonTwoIndexAntiSymmetricImplR> WilsonTwoIndexAntiSymmetricFermionR;
 typedef WilsonFermion<WilsonTwoIndexAntiSymmetricImplF> WilsonTwoIndexAntiSymmetricFermionF;
 typedef WilsonFermion<WilsonTwoIndexAntiSymmetricImplD> WilsonTwoIndexAntiSymmetricFermionD;
 // Sp(2n)
 typedef WilsonFermion<SpWilsonImplF> SpWilsonFermionF;
 typedef WilsonFermion<SpWilsonImplD> SpWilsonFermionD;
 typedef WilsonFermion<SpWilsonTwoIndexAntiSymmetricImplF> SpWilsonTwoIndexAntiSymmetricFermionF;
 typedef WilsonFermion<SpWilsonTwoIndexAntiSymmetricImplD> SpWilsonTwoIndexAntiSymmetricFermionD;
 typedef WilsonFermion<SpWilsonTwoIndexSymmetricImplF> SpWilsonTwoIndexSymmetricFermionF;
 typedef WilsonFermion<SpWilsonTwoIndexSymmetricImplD> SpWilsonTwoIndexSymmetricFermionD;
 // Twisted mass fermion
-typedef WilsonTMFermion<WilsonImplD2> WilsonTMFermionD2;
+typedef WilsonTMFermion<WilsonImplR> WilsonTMFermionR;
 typedef WilsonTMFermion<WilsonImplF> WilsonTMFermionF;
 typedef WilsonTMFermion<WilsonImplD> WilsonTMFermionD;
 // Clover fermions
-template <typename WImpl> using WilsonClover = WilsonCloverFermion<WImpl, CloverHelpers<WImpl>>;
+typedef WilsonCloverFermion<WilsonImplR> WilsonCloverFermionR;
-template <typename WImpl> using WilsonExpClover = WilsonCloverFermion<WImpl, ExpCloverHelpers<WImpl>>;
+typedef WilsonCloverFermion<WilsonImplF> WilsonCloverFermionF;
 typedef WilsonCloverFermion<WilsonImplD> WilsonCloverFermionD;
-typedef WilsonClover<WilsonImplD2> WilsonCloverFermionD2;
+typedef WilsonCloverFermion<WilsonAdjImplR> WilsonCloverAdjFermionR;
-typedef WilsonClover<WilsonImplF> WilsonCloverFermionF;
+typedef WilsonCloverFermion<WilsonAdjImplF> WilsonCloverAdjFermionF;
-typedef WilsonClover<WilsonImplD> WilsonCloverFermionD;
+typedef WilsonCloverFermion<WilsonAdjImplD> WilsonCloverAdjFermionD;
-typedef WilsonExpClover<WilsonImplD2> WilsonExpCloverFermionD2;
+typedef WilsonCloverFermion<WilsonTwoIndexSymmetricImplR> WilsonCloverTwoIndexSymmetricFermionR;
-typedef WilsonExpClover<WilsonImplF> WilsonExpCloverFermionF;
+typedef WilsonCloverFermion<WilsonTwoIndexSymmetricImplF> WilsonCloverTwoIndexSymmetricFermionF;
-typedef WilsonExpClover<WilsonImplD> WilsonExpCloverFermionD;
+typedef WilsonCloverFermion<WilsonTwoIndexSymmetricImplD> WilsonCloverTwoIndexSymmetricFermionD;
-typedef WilsonClover<WilsonAdjImplF> WilsonCloverAdjFermionF;
+typedef WilsonCloverFermion<WilsonTwoIndexAntiSymmetricImplR> WilsonCloverTwoIndexAntiSymmetricFermionR;
-typedef WilsonClover<WilsonAdjImplD> WilsonCloverAdjFermionD;
+typedef WilsonCloverFermion<WilsonTwoIndexAntiSymmetricImplF> WilsonCloverTwoIndexAntiSymmetricFermionF;
-
+typedef WilsonCloverFermion<WilsonTwoIndexAntiSymmetricImplD> WilsonCloverTwoIndexAntiSymmetricFermionD;
 typedef WilsonClover<WilsonTwoIndexSymmetricImplF> WilsonCloverTwoIndexSymmetricFermionF;
 typedef WilsonClover<WilsonTwoIndexSymmetricImplD> WilsonCloverTwoIndexSymmetricFermionD;
 typedef WilsonClover<WilsonTwoIndexAntiSymmetricImplF> WilsonCloverTwoIndexAntiSymmetricFermionF;
 typedef WilsonClover<WilsonTwoIndexAntiSymmetricImplD> WilsonCloverTwoIndexAntiSymmetricFermionD;
 // Compact Clover fermions
 template <typename WImpl> using CompactWilsonClover = CompactWilsonCloverFermion<WImpl, CompactCloverHelpers<WImpl>>;
 template <typename WImpl> using CompactWilsonExpClover = CompactWilsonCloverFermion<WImpl, CompactExpCloverHelpers<WImpl>>;
 typedef CompactWilsonClover<WilsonImplD2> CompactWilsonCloverFermionD2;
 typedef CompactWilsonClover<WilsonImplF> CompactWilsonCloverFermionF;
 typedef CompactWilsonClover<WilsonImplD> CompactWilsonCloverFermionD;
 typedef CompactWilsonExpClover<WilsonImplD2> CompactWilsonExpCloverFermionD2;
 typedef CompactWilsonExpClover<WilsonImplF> CompactWilsonExpCloverFermionF;
 typedef CompactWilsonExpClover<WilsonImplD> CompactWilsonExpCloverFermionD;
 typedef CompactWilsonClover<WilsonAdjImplF> CompactWilsonCloverAdjFermionF;
 typedef CompactWilsonClover<WilsonAdjImplD> CompactWilsonCloverAdjFermionD;
 typedef CompactWilsonClover<WilsonTwoIndexSymmetricImplF> CompactWilsonCloverTwoIndexSymmetricFermionF;
 typedef CompactWilsonClover<WilsonTwoIndexSymmetricImplD> CompactWilsonCloverTwoIndexSymmetricFermionD;
 typedef CompactWilsonClover<WilsonTwoIndexAntiSymmetricImplF> CompactWilsonCloverTwoIndexAntiSymmetricFermionF;
 typedef CompactWilsonClover<WilsonTwoIndexAntiSymmetricImplD> CompactWilsonCloverTwoIndexAntiSymmetricFermionD;
 // Domain Wall fermions
 typedef DomainWallFermion<WilsonImplR> DomainWallFermionR;
 typedef DomainWallFermion<WilsonImplF> DomainWallFermionF;
 typedef DomainWallFermion<WilsonImplD> DomainWallFermionD;
 typedef DomainWallFermion<WilsonImplD2> DomainWallFermionD2;
-typedef DomainWallEOFAFermion<WilsonImplD2> DomainWallEOFAFermionD2;
+typedef DomainWallFermion<WilsonImplRL> DomainWallFermionRL;
 typedef DomainWallFermion<WilsonImplFH> DomainWallFermionFH;
 typedef DomainWallFermion<WilsonImplDF> DomainWallFermionDF;
 typedef DomainWallEOFAFermion<WilsonImplR> DomainWallEOFAFermionR;
 typedef DomainWallEOFAFermion<WilsonImplF> DomainWallEOFAFermionF;
 typedef DomainWallEOFAFermion<WilsonImplD> DomainWallEOFAFermionD;
-typedef MobiusFermion<WilsonImplD2> MobiusFermionD2;
+typedef DomainWallEOFAFermion<WilsonImplRL> DomainWallEOFAFermionRL;
 typedef DomainWallEOFAFermion<WilsonImplFH> DomainWallEOFAFermionFH;
 typedef DomainWallEOFAFermion<WilsonImplDF> DomainWallEOFAFermionDF;
 typedef MobiusFermion<WilsonImplR> MobiusFermionR;
 typedef MobiusFermion<WilsonImplF> MobiusFermionF;
 typedef MobiusFermion<WilsonImplD> MobiusFermionD;
-typedef MobiusEOFAFermion<WilsonImplD2> MobiusEOFAFermionD2;
+typedef MobiusFermion<WilsonImplRL> MobiusFermionRL;
 typedef MobiusFermion<WilsonImplFH> MobiusFermionFH;
 typedef MobiusFermion<WilsonImplDF> MobiusFermionDF;
 typedef MobiusEOFAFermion<WilsonImplR> MobiusEOFAFermionR;
 typedef MobiusEOFAFermion<WilsonImplF> MobiusEOFAFermionF;
 typedef MobiusEOFAFermion<WilsonImplD> MobiusEOFAFermionD;
-typedef ZMobiusFermion<ZWilsonImplD2> ZMobiusFermionD2;
+typedef MobiusEOFAFermion<WilsonImplRL> MobiusEOFAFermionRL;
 typedef MobiusEOFAFermion<WilsonImplFH> MobiusEOFAFermionFH;
 typedef MobiusEOFAFermion<WilsonImplDF> MobiusEOFAFermionDF;
 typedef ZMobiusFermion<ZWilsonImplR> ZMobiusFermionR;
 typedef ZMobiusFermion<ZWilsonImplF> ZMobiusFermionF;
 typedef ZMobiusFermion<ZWilsonImplD> ZMobiusFermionD;
-typedef ScaledShamirFermion<WilsonImplD2> ScaledShamirFermionD2;
+typedef ZMobiusFermion<ZWilsonImplRL> ZMobiusFermionRL;
 typedef ZMobiusFermion<ZWilsonImplFH> ZMobiusFermionFH;
 typedef ZMobiusFermion<ZWilsonImplDF> ZMobiusFermionDF;
 // Ls vectorised
 typedef ScaledShamirFermion<WilsonImplR> ScaledShamirFermionR;
 typedef ScaledShamirFermion<WilsonImplF> ScaledShamirFermionF;
 typedef ScaledShamirFermion<WilsonImplD> ScaledShamirFermionD;
-typedef MobiusZolotarevFermion<WilsonImplD2> MobiusZolotarevFermionD2;
+typedef MobiusZolotarevFermion<WilsonImplR> MobiusZolotarevFermionR;
 typedef MobiusZolotarevFermion<WilsonImplF> MobiusZolotarevFermionF;
 typedef MobiusZolotarevFermion<WilsonImplD> MobiusZolotarevFermionD;
-typedef ShamirZolotarevFermion<WilsonImplD2> ShamirZolotarevFermionD2;
+typedef ShamirZolotarevFermion<WilsonImplR> ShamirZolotarevFermionR;
 typedef ShamirZolotarevFermion<WilsonImplF> ShamirZolotarevFermionF;
 typedef ShamirZolotarevFermion<WilsonImplD> ShamirZolotarevFermionD;
-typedef OverlapWilsonCayleyTanhFermion<WilsonImplD2> OverlapWilsonCayleyTanhFermionD2;
+typedef OverlapWilsonCayleyTanhFermion<WilsonImplR> OverlapWilsonCayleyTanhFermionR;
 typedef OverlapWilsonCayleyTanhFermion<WilsonImplF> OverlapWilsonCayleyTanhFermionF;
 typedef OverlapWilsonCayleyTanhFermion<WilsonImplD> OverlapWilsonCayleyTanhFermionD;
-typedef OverlapWilsonCayleyZolotarevFermion<WilsonImplD2> OverlapWilsonCayleyZolotarevFermionD2;
+typedef OverlapWilsonCayleyZolotarevFermion<WilsonImplR> OverlapWilsonCayleyZolotarevFermionR;
 typedef OverlapWilsonCayleyZolotarevFermion<WilsonImplF> OverlapWilsonCayleyZolotarevFermionF;
 typedef OverlapWilsonCayleyZolotarevFermion<WilsonImplD> OverlapWilsonCayleyZolotarevFermionD;
 // Continued fraction
-typedef OverlapWilsonContFracTanhFermion<WilsonImplD2> OverlapWilsonContFracTanhFermionD2;
+typedef OverlapWilsonContFracTanhFermion<WilsonImplR> OverlapWilsonContFracTanhFermionR;
 typedef OverlapWilsonContFracTanhFermion<WilsonImplF> OverlapWilsonContFracTanhFermionF;
 typedef OverlapWilsonContFracTanhFermion<WilsonImplD> OverlapWilsonContFracTanhFermionD;
-typedef OverlapWilsonContFracZolotarevFermion<WilsonImplD2> OverlapWilsonContFracZolotarevFermionD2;
+typedef OverlapWilsonContFracZolotarevFermion<WilsonImplR> OverlapWilsonContFracZolotarevFermionR;
 typedef OverlapWilsonContFracZolotarevFermion<WilsonImplF> OverlapWilsonContFracZolotarevFermionF;
 typedef OverlapWilsonContFracZolotarevFermion<WilsonImplD> OverlapWilsonContFracZolotarevFermionD;
 // Partial fraction
-typedef OverlapWilsonPartialFractionTanhFermion<WilsonImplD2> OverlapWilsonPartialFractionTanhFermionD2;
+typedef OverlapWilsonPartialFractionTanhFermion<WilsonImplR> OverlapWilsonPartialFractionTanhFermionR;
 typedef OverlapWilsonPartialFractionTanhFermion<WilsonImplF> OverlapWilsonPartialFractionTanhFermionF;
 typedef OverlapWilsonPartialFractionTanhFermion<WilsonImplD> OverlapWilsonPartialFractionTanhFermionD;
-typedef OverlapWilsonPartialFractionZolotarevFermion<WilsonImplD2> OverlapWilsonPartialFractionZolotarevFermionD2;
+typedef OverlapWilsonPartialFractionZolotarevFermion<WilsonImplR> OverlapWilsonPartialFractionZolotarevFermionR;
 typedef OverlapWilsonPartialFractionZolotarevFermion<WilsonImplF> OverlapWilsonPartialFractionZolotarevFermionF;
 typedef OverlapWilsonPartialFractionZolotarevFermion<WilsonImplD> OverlapWilsonPartialFractionZolotarevFermionD;
 // Gparity cases; partial list until tested
 typedef WilsonFermion<GparityWilsonImplR>     GparityWilsonFermionR;
 typedef WilsonFermion<GparityWilsonImplF>     GparityWilsonFermionF;
 typedef WilsonFermion<GparityWilsonImplD>     GparityWilsonFermionD;
 typedef WilsonFermion<GparityWilsonImplRL>     GparityWilsonFermionRL;
 typedef WilsonFermion<GparityWilsonImplFH>     GparityWilsonFermionFH;
 typedef WilsonFermion<GparityWilsonImplDF>     GparityWilsonFermionDF;
 typedef DomainWallFermion<GparityWilsonImplR> GparityDomainWallFermionR;
 typedef DomainWallFermion<GparityWilsonImplF> GparityDomainWallFermionF;
 typedef DomainWallFermion<GparityWilsonImplD> GparityDomainWallFermionD;
-typedef DomainWallEOFAFermion<GparityWilsonImplR> GparityDomainWallEOFAFermionD2;
+typedef DomainWallFermion<GparityWilsonImplRL> GparityDomainWallFermionRL;
 typedef DomainWallFermion<GparityWilsonImplFH> GparityDomainWallFermionFH;
 typedef DomainWallFermion<GparityWilsonImplDF> GparityDomainWallFermionDF;
 typedef DomainWallEOFAFermion<GparityWilsonImplR> GparityDomainWallEOFAFermionR;
 typedef DomainWallEOFAFermion<GparityWilsonImplF> GparityDomainWallEOFAFermionF;
 typedef DomainWallEOFAFermion<GparityWilsonImplD> GparityDomainWallEOFAFermionD;
-typedef WilsonTMFermion<GparityWilsonImplR> GparityWilsonTMFermionD2;
+typedef DomainWallEOFAFermion<GparityWilsonImplRL> GparityDomainWallEOFAFermionRL;
 typedef DomainWallEOFAFermion<GparityWilsonImplFH> GparityDomainWallEOFAFermionFH;
 typedef DomainWallEOFAFermion<GparityWilsonImplDF> GparityDomainWallEOFAFermionDF;
 typedef WilsonTMFermion<GparityWilsonImplR> GparityWilsonTMFermionR;
 typedef WilsonTMFermion<GparityWilsonImplF> GparityWilsonTMFermionF;
 typedef WilsonTMFermion<GparityWilsonImplD> GparityWilsonTMFermionD;
-typedef MobiusFermion<GparityWilsonImplR> GparityMobiusFermionD2;
+typedef WilsonTMFermion<GparityWilsonImplRL> GparityWilsonTMFermionRL;
 typedef WilsonTMFermion<GparityWilsonImplFH> GparityWilsonTMFermionFH;
 typedef WilsonTMFermion<GparityWilsonImplDF> GparityWilsonTMFermionDF;
 typedef MobiusFermion<GparityWilsonImplR> GparityMobiusFermionR;
 typedef MobiusFermion<GparityWilsonImplF> GparityMobiusFermionF;
 typedef MobiusFermion<GparityWilsonImplD> GparityMobiusFermionD;
-typedef MobiusEOFAFermion<GparityWilsonImplR> GparityMobiusEOFAFermionD2;
+typedef MobiusFermion<GparityWilsonImplRL> GparityMobiusFermionRL;
 typedef MobiusFermion<GparityWilsonImplFH> GparityMobiusFermionFH;
 typedef MobiusFermion<GparityWilsonImplDF> GparityMobiusFermionDF;
 typedef MobiusEOFAFermion<GparityWilsonImplR> GparityMobiusEOFAFermionR;
 typedef MobiusEOFAFermion<GparityWilsonImplF> GparityMobiusEOFAFermionF;
 typedef MobiusEOFAFermion<GparityWilsonImplD> GparityMobiusEOFAFermionD;
 typedef MobiusEOFAFermion<GparityWilsonImplRL> GparityMobiusEOFAFermionRL;
 typedef MobiusEOFAFermion<GparityWilsonImplFH> GparityMobiusEOFAFermionFH;
 typedef MobiusEOFAFermion<GparityWilsonImplDF> GparityMobiusEOFAFermionDF;
 typedef ImprovedStaggeredFermion<StaggeredImplR> ImprovedStaggeredFermionR;
 typedef ImprovedStaggeredFermion<StaggeredImplF> ImprovedStaggeredFermionF;
 typedef ImprovedStaggeredFermion<StaggeredImplD> ImprovedStaggeredFermionD;
 typedef NaiveStaggeredFermion<StaggeredImplR> NaiveStaggeredFermionR;
 typedef NaiveStaggeredFermion<StaggeredImplF> NaiveStaggeredFermionF;
 typedef NaiveStaggeredFermion<StaggeredImplD> NaiveStaggeredFermionD;
 typedef ImprovedStaggeredFermion5D<StaggeredImplR> ImprovedStaggeredFermion5DR;
 typedef ImprovedStaggeredFermion5D<StaggeredImplF> ImprovedStaggeredFermion5DF;
 typedef ImprovedStaggeredFermion5D<StaggeredImplD> ImprovedStaggeredFermion5DD;
 #ifndef GRID_CUDA
 typedef ImprovedStaggeredFermion5D<StaggeredVec5dImplR> ImprovedStaggeredFermionVec5dR;
 typedef ImprovedStaggeredFermion5D<StaggeredVec5dImplF> ImprovedStaggeredFermionVec5dF;
 typedef ImprovedStaggeredFermion5D<StaggeredVec5dImplD> ImprovedStaggeredFermionVec5dD;
 #endif
 NAMESPACE_END(Grid);
 ////////////////////
--- a/Grid/qcd/action/fermion/FermionOperator.h
+++ b/Grid/qcd/action/fermion/FermionOperator.h
@@ -49,8 +49,6 @@ public:
  virtual FermionField &tmp(void) = 0;
  virtual void DirichletBlock(const Coordinate & _Block) { assert(0); };
  GridBase * Grid(void)   { return FermionGrid(); };   // this is all the linalg routines need to know
  GridBase * RedBlackGrid(void) { return FermionRedBlackGrid(); };
--- a/Grid/qcd/action/fermion/FermionOperatorImpl.h
+++ b/Grid/qcd/action/fermion/FermionOperatorImpl.h
@@ -153,8 +153,8 @@ public:
  typedef typename Impl::StencilImpl             StencilImpl;		\
  typedef typename Impl::ImplParams               ImplParams;	        \
  typedef typename Impl::StencilImpl::View_type  StencilView;		\
-  typedef const typename ViewMap<FermionField>::Type      FermionFieldView;	\
+  typedef typename ViewMap<FermionField>::Type      FermionFieldView;	\
-  typedef const typename ViewMap<DoubledGaugeField>::Type DoubledGaugeFieldView;
+  typedef typename ViewMap<DoubledGaugeField>::Type DoubledGaugeFieldView;
 #define INHERIT_IMPL_TYPES(Base)		\
  INHERIT_GIMPL_TYPES(Base)			\
@@ -183,8 +183,7 @@ NAMESPACE_CHECK(ImplStaggered);
 /////////////////////////////////////////////////////////////////////////////
 // Single flavour one component spinors with colour index. 5d vec
 /////////////////////////////////////////////////////////////////////////////
-// Deprecate Vec5d
+#include <Grid/qcd/action/fermion/StaggeredVec5dImpl.h> 
-//#include <Grid/qcd/action/fermion/StaggeredVec5dImpl.h> 
+NAMESPACE_CHECK(ImplStaggered5dVec);  
 //NAMESPACE_CHECK(ImplStaggered5dVec);  
--- a/Grid/qcd/action/fermion/GparityWilsonImpl.h
+++ b/Grid/qcd/action/fermion/GparityWilsonImpl.h
@@ -30,18 +30,6 @@ directory
 NAMESPACE_BEGIN(Grid);
 /*
  Policy implementation for G-parity boundary conditions
  Rather than treating the gauge field as a flavored field, the Grid implementation of G-parity treats the gauge field as a regular
  field with complex conjugate boundary conditions. In order to ensure the second flavor interacts with the conjugate links and the first
  with the regular links we overload the functionality of doubleStore, whose purpose is to store the gauge field and the barrel-shifted gauge field
  to avoid communicating links when applying the Dirac operator, such that the double-stored field contains also a flavor index which maps to
  either the link or the conjugate link. This flavored field is then used by multLink to apply the correct link to a spinor.
  Here the first Nd-1 directions are treated as "spatial", and a twist value of 1 indicates G-parity BCs in that direction. 
  mu=Nd-1 is assumed to be the time direction and a twist value of 1 indicates antiperiodic BCs
 */
 template <class S, class Representation = FundamentalRepresentation, class Options=CoeffReal>
 class GparityWilsonImpl : public ConjugateGaugeImpl<GaugeImplTypes<S, Representation::Dimension> > {
 public:
@@ -109,30 +97,42 @@ public:
    Coordinate icoor;
 #ifdef GRID_SIMT
    _Spinor tmp;
    const int Nsimd =SiteDoubledGaugeField::Nsimd();
    int s = acceleratorSIMTlane(Nsimd);
    St.iCoorFromIindex(icoor,s);
    int mmu = mu % Nd;
    if ( SE->_around_the_world && St.parameters.twists[mmu] ) {
      int permute_lane = (sl==1) 
    	|| ((distance== 1)&&(icoor[direction]==1))
 	|| ((distance==-1)&&(icoor[direction]==0));
-    auto UU0=coalescedRead(U(0)(mu));
+      if ( permute_lane ) { 
-    auto UU1=coalescedRead(U(1)(mu));
+	tmp(0) = chi(1);
-    
+	tmp(1) = chi(0);
-    //Decide whether we do a G-parity flavor twist
+      } else {
-    //Note: this assumes (but does not check) that sl==1 || sl==2 i.e. max 2 SIMD lanes in G-parity dir
+	tmp(0) = chi(0);
-    //It also assumes (but does not check) that abs(distance) == 1
+	tmp(1) = chi(1);
-    int permute_lane = (sl==1) 
+      }
    || ((distance== 1)&&(icoor[direction]==1))
    || ((distance==-1)&&(icoor[direction]==0));
-    permute_lane = permute_lane && SE->_around_the_world && St.parameters.twists[mmu] && mmu < Nd-1; //only if we are going around the world in a spatial direction
+      auto UU0=coalescedRead(U(0)(mu));
      auto UU1=coalescedRead(U(1)(mu));
-    //Apply the links
+      mult(&phi(0),&UU0,&tmp(0));
-    int f_upper = permute_lane ? 1 : 0;
+      mult(&phi(1),&UU1,&tmp(1));
    int f_lower = !f_upper;
-    mult(&phi(0),&UU0,&chi(f_upper));
+    } else {
-    mult(&phi(1),&UU1,&chi(f_lower));
+
      auto UU0=coalescedRead(U(0)(mu));
      auto UU1=coalescedRead(U(1)(mu));
      mult(&phi(0),&UU0,&chi(0));
      mult(&phi(1),&UU1,&chi(1));
    }
 #else
    typedef _Spinor vobj;
@@ -151,10 +151,10 @@ public:
    assert((distance == 1) || (distance == -1));  // nearest neighbour stencil hard code
    assert((sl == 1) || (sl == 2));
-    //If this site is an global boundary site, perform the G-parity flavor twist
+    if ( SE->_around_the_world && St.parameters.twists[mmu] ) {
-    if ( mmu < Nd-1 && SE->_around_the_world && St.parameters.twists[mmu] ) {
+
      if ( sl == 2 ) {
-	//Only do the twist for lanes on the edge of the physical node
+       
 	ExtractBuffer<sobj> vals(Nsimd);
 	extract(chi,vals);
@@ -209,19 +209,6 @@ public:
    reg = memory;
  }
  //Poke 'poke_f0' onto flavor 0 and 'poke_f1' onto flavor 1 in direction mu of the doubled gauge field Uds
  inline void pokeGparityDoubledGaugeField(DoubledGaugeField &Uds, const GaugeLinkField &poke_f0, const GaugeLinkField &poke_f1, const int mu){
    autoView(poke_f0_v, poke_f0, CpuRead);
    autoView(poke_f1_v, poke_f1, CpuRead);
    autoView(Uds_v, Uds, CpuWrite);
    thread_foreach(ss,poke_f0_v,{
 	Uds_v[ss](0)(mu) = poke_f0_v[ss]();
 	Uds_v[ss](1)(mu) = poke_f1_v[ss]();
      });
  }
  inline void DoubleStore(GridBase *GaugeGrid,DoubledGaugeField &Uds,const GaugeField &Umu)
  {
    conformable(Uds.Grid(),GaugeGrid);
@@ -232,19 +219,14 @@ public:
    GaugeLinkField Uconj(GaugeGrid);
    Lattice<iScalar<vInteger> > coor(GaugeGrid);
-
+        
-    //Here the first Nd-1 directions are treated as "spatial", and a twist value of 1 indicates G-parity BCs in that direction. 
+    for(int mu=0;mu<Nd;mu++){
-    //mu=Nd-1 is assumed to be the time direction and a twist value of 1 indicates antiperiodic BCs        
+          
-    for(int mu=0;mu<Nd-1;mu++){
+      LatticeCoordinate(coor,mu);
      if( Params.twists[mu] ){
 	LatticeCoordinate(coor,mu);
      }
      U     = PeekIndex<LorentzIndex>(Umu,mu);
      Uconj = conjugate(U);
      // Implement the isospin rotation sign on the boundary between f=1 and f=0
      // This phase could come from a simple bc 1,1,-1,1 ..
      int neglink = GaugeGrid->GlobalDimensions()[mu]-1;
      if ( Params.twists[mu] ) { 
@@ -259,7 +241,7 @@ public:
 	thread_foreach(ss,U_v,{
 	    Uds_v[ss](0)(mu) = U_v[ss]();
 	    Uds_v[ss](1)(mu) = Uconj_v[ss]();
-	});
+	  });
      }
      U     = adj(Cshift(U    ,mu,-1));      // correct except for spanning the boundary
@@ -290,38 +272,6 @@ public:
        });
      }
    }
    { //periodic / antiperiodic temporal BCs
      int mu = Nd-1;
      int L   = GaugeGrid->GlobalDimensions()[mu];
      int Lmu = L - 1;
      LatticeCoordinate(coor, mu);
      U = PeekIndex<LorentzIndex>(Umu, mu); //Get t-directed links
      GaugeLinkField *Upoke = &U;
      if(Params.twists[mu]){ //antiperiodic
 	Utmp =  where(coor == Lmu, -U, U);
 	Upoke = &Utmp;
      }
      Uconj = conjugate(*Upoke); //second flavor interacts with conjugate links      
      pokeGparityDoubledGaugeField(Uds, *Upoke, Uconj, mu);
      //Get the barrel-shifted field
      Utmp = adj(Cshift(U, mu, -1)); //is a forward shift!
      Upoke = &Utmp;
      if(Params.twists[mu]){
 	U = where(coor == 0, -Utmp, Utmp);  //boundary phase
 	Upoke = &U;
      }
      Uconj = conjugate(*Upoke);
      pokeGparityDoubledGaugeField(Uds, *Upoke, Uconj, mu + 4);
    }
  }
  inline void InsertForce4D(GaugeField &mat, FermionField &Btilde, FermionField &A, int mu) {
@@ -360,48 +310,28 @@ public:
  inline void extractLinkField(std::vector<GaugeLinkField> &mat, DoubledGaugeField &Uds){
    assert(0);
  }
  inline void InsertForce5D(GaugeField &mat, FermionField &Btilde, FermionField &Atilde, int mu) {
    int Ls=Btilde.Grid()->_fdimensions[0];
    {
      GridBase *GaugeGrid = mat.Grid();
      Lattice<iScalar<vInteger> > coor(GaugeGrid);
      if( Params.twists[mu] ){
 	LatticeCoordinate(coor,mu);
      }
      autoView( mat_v , mat, AcceleratorWrite);
      autoView( Btilde_v , Btilde, AcceleratorRead);
      autoView( Atilde_v , Atilde, AcceleratorRead);
      accelerator_for(sss,mat.Grid()->oSites(), FermionField::vector_type::Nsimd(),{	  
  	  int sU=sss;
  	  typedef decltype(coalescedRead(mat_v[sU](mu)() )) ColorMatrixType;
  	  ColorMatrixType sum;
  	  zeroit(sum);
  	  for(int s=0;s<Ls;s++){
  	    int sF = s+Ls*sU;
  	    for(int spn=0;spn<Ns;spn++){ //sum over spin
 	      //Flavor 0
  	      auto bb = coalescedRead(Btilde_v[sF](0)(spn) ); //color vector
  	      auto aa = coalescedRead(Atilde_v[sF](0)(spn) );
  	      sum = sum + outerProduct(bb,aa);
  	      //Flavor 1
  	      bb = coalescedRead(Btilde_v[sF](1)(spn) );
  	      aa = coalescedRead(Atilde_v[sF](1)(spn) );
  	      sum = sum + conjugate(outerProduct(bb,aa));
  	    }
  	  }	    
  	  coalescedWrite(mat_v[sU](mu)(), sum);
  	});
    }
  }
  inline void InsertForce5D(GaugeField &mat, FermionField &Btilde, FermionField &Atilde, int mu) {
    int Ls = Btilde.Grid()->_fdimensions[0];
    GaugeLinkField tmp(mat.Grid());
    tmp = Zero();
    {
      autoView( tmp_v , tmp, CpuWrite);
      autoView( Atilde_v , Atilde, CpuRead);
      autoView( Btilde_v , Btilde, CpuRead);
      thread_for(ss,tmp.Grid()->oSites(),{
 	  for (int s = 0; s < Ls; s++) {
 	    int sF = s + Ls * ss;
 	    auto ttmp = traceIndex<SpinIndex>(outerProduct(Btilde_v[sF], Atilde_v[sF]));
 	    tmp_v[ss]() = tmp_v[ss]() + ttmp(0, 0) + conjugate(ttmp(1, 1));
 	  }
 	});
    }
    PokeIndex<LorentzIndex>(mat, tmp, mu);
    return;
  }
 };
@@ -409,8 +339,8 @@ typedef GparityWilsonImpl<vComplex , FundamentalRepresentation,CoeffReal> Gparit
 typedef GparityWilsonImpl<vComplexF, FundamentalRepresentation,CoeffReal> GparityWilsonImplF;  // Float
 typedef GparityWilsonImpl<vComplexD, FundamentalRepresentation,CoeffReal> GparityWilsonImplD;  // Double
-//typedef GparityWilsonImpl<vComplex , FundamentalRepresentation,CoeffRealHalfComms> GparityWilsonImplRL;  // Real.. whichever prec
+typedef GparityWilsonImpl<vComplex , FundamentalRepresentation,CoeffRealHalfComms> GparityWilsonImplRL;  // Real.. whichever prec
-//typedef GparityWilsonImpl<vComplexF, FundamentalRepresentation,CoeffRealHalfComms> GparityWilsonImplFH;  // Float
+typedef GparityWilsonImpl<vComplexF, FundamentalRepresentation,CoeffRealHalfComms> GparityWilsonImplFH;  // Float
-//typedef GparityWilsonImpl<vComplexD, FundamentalRepresentation,CoeffRealHalfComms> GparityWilsonImplDF;  // Double
+typedef GparityWilsonImpl<vComplexD, FundamentalRepresentation,CoeffRealHalfComms> GparityWilsonImplDF;  // Double
 NAMESPACE_END(Grid);
--- a/Grid/qcd/action/fermion/ImprovedStaggeredFermion.h
+++ b/Grid/qcd/action/fermion/ImprovedStaggeredFermion.h
@@ -47,6 +47,18 @@ public:
  FermionField _tmp;
  FermionField &tmp(void) { return _tmp; }
  ////////////////////////////////////////
  // Performance monitoring
  ////////////////////////////////////////
  void Report(void);
  void ZeroCounters(void);
  double DhopTotalTime;
  double DhopCalls;
  double DhopCommTime;
  double DhopComputeTime;
  double DhopComputeTime2;
  double DhopFaceTime;
  ///////////////////////////////////////////////////////////////
  // Implement the abstract base
  ///////////////////////////////////////////////////////////////
--- a/Grid/qcd/action/fermion/ImprovedStaggeredFermion5D.h
+++ b/Grid/qcd/action/fermion/ImprovedStaggeredFermion5D.h
@@ -52,6 +52,18 @@ public:
  FermionField _tmp;
  FermionField &tmp(void) { return _tmp; }
  ////////////////////////////////////////
  // Performance monitoring
  ////////////////////////////////////////
  void Report(void);
  void ZeroCounters(void);
  double DhopTotalTime;
  double DhopCalls;
  double DhopCommTime;
  double DhopComputeTime;
  double DhopComputeTime2;
  double DhopFaceTime;
  ///////////////////////////////////////////////////////////////
  // Implement the abstract base
  ///////////////////////////////////////////////////////////////
--- a/Grid/qcd/action/fermion/MADWF.h
+++ b/Grid/qcd/action/fermion/MADWF.h
@@ -85,7 +85,7 @@ class MADWF
      maxiter     =_maxiter;
    };
-  void operator() (const FermionFieldo &src,FermionFieldo &sol5)
+  void operator() (const FermionFieldo &src4,FermionFieldo &sol5)
  {
    std::cout << GridLogMessage<< " ************************************************" << std::endl;
    std::cout << GridLogMessage<< "  MADWF-like algorithm                           " << std::endl;
@@ -114,16 +114,8 @@ class MADWF
    ///////////////////////////////////////
    //Import source, include Dminus factors
    ///////////////////////////////////////
-    GridBase *src_grid = src.Grid();
+    Mato.ImportPhysicalFermionSource(src4,b); 
-
+    std::cout << GridLogMessage << " src4 " <<norm2(src4)<<std::endl;
    assert( (src_grid == Mato.GaugeGrid()) || (src_grid == Mato.FermionGrid()));
    if ( src_grid == Mato.GaugeGrid() ) {
      Mato.ImportPhysicalFermionSource(src,b);
    } else {
      b=src;
    }
    std::cout << GridLogMessage << " src " <<norm2(src)<<std::endl;
    std::cout << GridLogMessage << " b    " <<norm2(b)<<std::endl;
    defect = b;
--- a/Grid/qcd/action/fermion/NaiveStaggeredFermion.h
+++ b/Grid/qcd/action/fermion/NaiveStaggeredFermion.h
@@ -47,6 +47,18 @@ public:
  FermionField _tmp;
  FermionField &tmp(void) { return _tmp; }
  ////////////////////////////////////////
  // Performance monitoring
  ////////////////////////////////////////
  void Report(void);
  void ZeroCounters(void);
  double DhopTotalTime;
  double DhopCalls;
  double DhopCommTime;
  double DhopComputeTime;
  double DhopComputeTime2;
  double DhopFaceTime;
  ///////////////////////////////////////////////////////////////
  // Implement the abstract base
  ///////////////////////////////////////////////////////////////
--- a/Show More
+++ b/Show More
Author	SHA1	Message	Date
Peter Boyle	6d25badce5	Hack - may revert this in future	2020-11-19 05:58:39 -08:00
Peter Boyle	adcc97cbbb	Gparity and fermion rep optional	2020-11-19 05:58:08 -08:00
Peter Boyle	bc8c5fb16c	Configure options for gparity and fermion reps	2020-11-19 05:57:42 -08:00
Peter Boyle	845d757bb0	Be able to switch off gparity and fermion reps	2020-11-19 05:57:04 -08:00
Peter Boyle	0d5470c363	Duplicate	2020-11-19 05:56:32 -08:00