more HOST_NAME_MAX fix

fallback to _POSIX_HOST_NAME_MAX if HOST_NAME_MAX is not defined
Booster update
2025-06-15 06:17:05 +01:00 · 2024-03-07 15:26:01 +09:00 · 2024-03-07 15:22:08 +09:00 · 2024-03-06 19:03:45 +01:00 · 2024-03-06 19:03:35 +01:00 · 2024-03-06 01:32:40 +00:00
192 changed files with 12431 additions and 2572 deletions
--- a/.gitignore
+++ b/.gitignore
@ -1,3 +1,7 @@
 # Doxygen stuff
 html/*
 latex/*
 # Compiled Object files #
 #########################
 *.slo
--- a/Grid/Grid_Eigen_Dense.h
+++ b/Grid/Grid_Eigen_Dense.h
@ -34,7 +34,7 @@
 #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
@ -66,6 +66,10 @@ 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/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(PRECISION epsilon, int n, int type) {
+zolotarev_data* zolotarev(ZOLO_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(PRECISION epsilon, int n, int type) {
  construct_partfrac(d);
  construct_contfrac(d);
-  /* Converting everything to PRECISION for external use only */
+  /* Converting everything to ZOLO_PRECISION for external use only */
  zd = (zolotarev_data*) malloc(sizeof(zolotarev_data));
-  zd -> A = (PRECISION) d -> A;
+  zd -> A = (ZOLO_PRECISION) d -> A;
-  zd -> Delta = (PRECISION) d -> Delta;
+  zd -> Delta = (ZOLO_PRECISION) d -> Delta;
-  zd -> epsilon = (PRECISION) d -> epsilon;
+  zd -> epsilon = (ZOLO_PRECISION) d -> epsilon;
  zd -> n = d -> n;
  zd -> type = d -> type;
  zd -> dn = d -> dn;
@ -390,24 +390,24 @@ zolotarev_data* zolotarev(PRECISION epsilon, int n, int type) {
  zd -> deg_num = d -> deg_num;
  zd -> deg_denom = d -> deg_denom;
-  zd -> a = (PRECISION*) malloc(zd -> dn * sizeof(PRECISION));
+  zd -> a = (ZOLO_PRECISION*) malloc(zd -> dn * sizeof(ZOLO_PRECISION));
-  for (m = 0; m < zd -> dn; m++) zd -> a[m] = (PRECISION) d -> a[m];
+  for (m = 0; m < zd -> dn; m++) zd -> a[m] = (ZOLO_PRECISION) d -> a[m];
  free(d -> a);
-  zd -> ap = (PRECISION*) malloc(zd -> dd * sizeof(PRECISION));
+  zd -> ap = (ZOLO_PRECISION*) malloc(zd -> dd * sizeof(ZOLO_PRECISION));
-  for (m = 0; m < zd -> dd; m++) zd -> ap[m] = (PRECISION) d -> ap[m];
+  for (m = 0; m < zd -> dd; m++) zd -> ap[m] = (ZOLO_PRECISION) d -> ap[m];
  free(d -> ap);
-  zd -> alpha = (PRECISION*) malloc(zd -> da * sizeof(PRECISION));
+  zd -> alpha = (ZOLO_PRECISION*) malloc(zd -> da * sizeof(ZOLO_PRECISION));
-  for (m = 0; m < zd -> da; m++) zd -> alpha[m] = (PRECISION) d -> alpha[m];
+  for (m = 0; m < zd -> da; m++) zd -> alpha[m] = (ZOLO_PRECISION) d -> alpha[m];
  free(d -> alpha);
-  zd -> beta = (PRECISION*) malloc(zd -> db * sizeof(PRECISION));
+  zd -> beta = (ZOLO_PRECISION*) malloc(zd -> db * sizeof(ZOLO_PRECISION));
-  for (m = 0; m < zd -> db; m++) zd -> beta[m] = (PRECISION) d -> beta[m];
+  for (m = 0; m < zd -> db; m++) zd -> beta[m] = (ZOLO_PRECISION) d -> beta[m];
  free(d -> beta);
-  zd -> gamma = (PRECISION*) malloc(zd -> n * sizeof(PRECISION));
+  zd -> gamma = (ZOLO_PRECISION*) malloc(zd -> n * sizeof(ZOLO_PRECISION));
-  for (m = 0; m < zd -> n; m++) zd -> gamma[m] = (PRECISION) d -> gamma[m];
+  for (m = 0; m < zd -> n; m++) zd -> gamma[m] = (ZOLO_PRECISION) d -> gamma[m];
  free(d -> gamma);
  free(d);
@ -426,7 +426,7 @@ void zolotarev_free(zolotarev_data *zdata)
 }
-zolotarev_data* higham(PRECISION epsilon, int n) {
+zolotarev_data* higham(ZOLO_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(PRECISION epsilon, int n) {
  /* Converting everything to PRECISION for external use only */
  zd = (zolotarev_data*) malloc(sizeof(zolotarev_data));
-  zd -> A = (PRECISION) d -> A;
+  zd -> A = (ZOLO_PRECISION) d -> A;
-  zd -> Delta = (PRECISION) d -> Delta;
+  zd -> Delta = (ZOLO_PRECISION) d -> Delta;
-  zd -> epsilon = (PRECISION) d -> epsilon;
+  zd -> epsilon = (ZOLO_PRECISION) d -> epsilon;
  zd -> n = d -> n;
  zd -> type = d -> type;
  zd -> dn = d -> dn;
@ -493,24 +493,24 @@ zolotarev_data* higham(PRECISION epsilon, int n) {
  zd -> deg_num = d -> deg_num;
  zd -> deg_denom = d -> deg_denom;
-  zd -> a = (PRECISION*) malloc(zd -> dn * sizeof(PRECISION));
+  zd -> a = (ZOLO_PRECISION*) malloc(zd -> dn * sizeof(ZOLO_PRECISION));
-  for (m = 0; m < zd -> dn; m++) zd -> a[m] = (PRECISION) d -> a[m];
+  for (m = 0; m < zd -> dn; m++) zd -> a[m] = (ZOLO_PRECISION) d -> a[m];
  free(d -> a);
-  zd -> ap = (PRECISION*) malloc(zd -> dd * sizeof(PRECISION));
+  zd -> ap = (ZOLO_PRECISION*) malloc(zd -> dd * sizeof(ZOLO_PRECISION));
-  for (m = 0; m < zd -> dd; m++) zd -> ap[m] = (PRECISION) d -> ap[m];
+  for (m = 0; m < zd -> dd; m++) zd -> ap[m] = (ZOLO_PRECISION) d -> ap[m];
  free(d -> ap);
-  zd -> alpha = (PRECISION*) malloc(zd -> da * sizeof(PRECISION));
+  zd -> alpha = (ZOLO_PRECISION*) malloc(zd -> da * sizeof(ZOLO_PRECISION));
-  for (m = 0; m < zd -> da; m++) zd -> alpha[m] = (PRECISION) d -> alpha[m];
+  for (m = 0; m < zd -> da; m++) zd -> alpha[m] = (ZOLO_PRECISION) d -> alpha[m];
  free(d -> alpha);
-  zd -> beta = (PRECISION*) malloc(zd -> db * sizeof(PRECISION));
+  zd -> beta = (ZOLO_PRECISION*) malloc(zd -> db * sizeof(ZOLO_PRECISION));
-  for (m = 0; m < zd -> db; m++) zd -> beta[m] = (PRECISION) d -> beta[m];
+  for (m = 0; m < zd -> db; m++) zd -> beta[m] = (ZOLO_PRECISION) d -> beta[m];
  free(d -> beta);
-  zd -> gamma = (PRECISION*) malloc(zd -> n * sizeof(PRECISION));
+  zd -> gamma = (ZOLO_PRECISION*) malloc(zd -> n * sizeof(ZOLO_PRECISION));
-  for (m = 0; m < zd -> n; m++) zd -> gamma[m] = (PRECISION) d -> gamma[m];
+  for (m = 0; m < zd -> n; m++) zd -> gamma[m] = (ZOLO_PRECISION) d -> gamma[m];
  free(d -> gamma);
  free(d);
@ -523,17 +523,17 @@ NAMESPACE_END(Grid);
 #ifdef TEST
 #undef ZERO
-#define ZERO ((PRECISION) 0)
+#define ZERO ((ZOLO_PRECISION) 0)
 #undef ONE
-#define ONE ((PRECISION) 1)
+#define ONE ((ZOLO_PRECISION) 1)
 #undef TWO
-#define TWO ((PRECISION) 2)
+#define TWO ((ZOLO_PRECISION) 2)
 /* Evaluate the rational approximation R(x) using the factored form */
-static PRECISION zolotarev_eval(PRECISION x, zolotarev_data* rdata) {
+static ZOLO_PRECISION zolotarev_eval(ZOLO_PRECISION x, zolotarev_data* rdata) {
  int m;
-  PRECISION R;
+  ZOLO_PRECISION R;
  if (rdata -> type == 0) {
    R = rdata -> A * x;
@ -551,9 +551,9 @@ static PRECISION zolotarev_eval(PRECISION x, zolotarev_data* rdata) {
 /* Evaluate the rational approximation R(x) using the partial fraction form */
-static PRECISION zolotarev_partfrac_eval(PRECISION x, zolotarev_data* rdata) {
+static ZOLO_PRECISION zolotarev_partfrac_eval(ZOLO_PRECISION x, zolotarev_data* rdata) {
  int m;
-  PRECISION R = rdata -> alpha[rdata -> da - 1];
+  ZOLO_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 PRECISION zolotarev_partfrac_eval(PRECISION x, zolotarev_data* rdata) {
 * 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 PRECISION zolotarev_contfrac_eval(PRECISION x, zolotarev_data* rdata) {
+static ZOLO_PRECISION zolotarev_contfrac_eval(ZOLO_PRECISION x, zolotarev_data* rdata) {
  int m;
-  PRECISION R = rdata -> beta[0] * x;
+  ZOLO_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 PRECISION zolotarev_cayley_eval(PRECISION x, zolotarev_data* rdata) {
+static ZOLO_PRECISION zolotarev_cayley_eval(ZOLO_PRECISION x, zolotarev_data* rdata) {
  int m;
-  PRECISION T;
+  ZOLO_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;
-  PRECISION y;
+  ZOLO_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((PRECISION) eps, n) 
+    ? higham((ZOLO_PRECISION) eps, n) 
-    : zolotarev((PRECISION) eps, n, type);
+    : zolotarev((ZOLO_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)
-	 "\tPRECISION = " STRINGIFY(PRECISION)
+	 "\tZOLO_PRECISION = " STRINGIFY(ZOLO_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((PRECISION) x, rdata);
+      y = zolotarev_eval((ZOLO_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((PRECISION) x, rdata) - y)
+      ypferr = (float)((zolotarev_partfrac_eval((ZOLO_PRECISION) x, rdata) - y)
 		       / rdata -> Delta);
-      ycferr = (float)((zolotarev_contfrac_eval((PRECISION) x, rdata) - y)
+      ycferr = (float)((zolotarev_contfrac_eval((ZOLO_PRECISION) x, rdata) - y)
 		       / rdata -> Delta);
-      ycaylerr = (float)((zolotarev_cayley_eval((PRECISION) x, rdata) - y)
+      ycaylerr = (float)((zolotarev_cayley_eval((ZOLO_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 PRECISION
+#ifndef ZOLO_PRECISION
-#define PRECISION double
+#define ZOLO_PRECISION double
 #endif
-#define ZPRECISION PRECISION
+#define ZPRECISION ZOLO_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(PRECISION epsilon, int n) ;
+ZOLOTAREV_DATA* higham(ZOLO_PRECISION epsilon, int n) ;
-ZOLOTAREV_DATA* zolotarev(PRECISION epsilon, int n, int type);
+ZOLOTAREV_DATA* zolotarev(ZOLO_PRECISION epsilon, int n, int type);
 void zolotarev_free(zolotarev_data *zdata);
 #endif
@ -86,3 +86,4 @@ 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
@ -0,0 +1,34 @@
 /*************************************************************************************
    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
@ -0,0 +1,727 @@
 /*************************************************************************************
    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/allocator/AlignedAllocator.h
+++ b/Grid/allocator/AlignedAllocator.h
@ -176,6 +176,7 @@ template<class T> using cshiftAllocator = std::allocator<T>;
 template<class T> using Vector        = std::vector<T,uvmAllocator<T> >;           
 template<class T> using stencilVector = std::vector<T,alignedAllocator<T> >;           
 template<class T> using commVector = std::vector<T,devAllocator<T> >;
 template<class T> using deviceVector  = std::vector<T,devAllocator<T> >;
 template<class T> using cshiftVector = std::vector<T,cshiftAllocator<T> >;
 NAMESPACE_END(Grid);
--- a/Grid/communicator/SharedMemoryMPI.cc
+++ b/Grid/communicator/SharedMemoryMPI.cc
@ -604,8 +604,8 @@ void GlobalSharedMemory::SharedMemoryAllocate(uint64_t bytes, int flags)
 #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::level_zero>(theGridAccelerator->get_device());
+    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::level_zero>(theGridAccelerator->get_context());
+    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;
--- a/Grid/cshift/Cshift_common.h
+++ b/Grid/cshift/Cshift_common.h
@ -29,8 +29,27 @@ Author: Peter Boyle <paboyle@ph.ed.ac.uk>
 NAMESPACE_BEGIN(Grid);
-extern Vector<std::pair<int,int> > Cshift_table; 
+extern std::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 
 ///////////////////////////////////////////////////////////////////
@ -74,8 +93,8 @@ Gather_plane_simple (const Lattice<vobj> &rhs,cshiftVector<vobj> &buffer,int dim
  }
  {
    auto buffer_p = & buffer[0];
-    auto table = &Cshift_table[0];
+    auto table = MapCshiftTable();
-#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]));
@ -225,7 +244,7 @@ template<class vobj> void Scatter_plane_simple (Lattice<vobj> &rhs,cshiftVector<
  {
    auto buffer_p = & buffer[0];
-    auto table = &Cshift_table[0];
+    auto table = MapCshiftTable();
 #ifdef ACCELERATOR_CSHIFT    
    autoView( rhs_v, rhs, AcceleratorWrite);
    accelerator_for(i,ent,vobj::Nsimd(),{
@ -297,30 +316,6 @@ template<class vobj> void Scatter_plane_merge(Lattice<vobj> &rhs,ExtractPointerA
  }
 }
 #if (defined(GRID_CUDA) || defined(GRID_HIP)) && defined(ACCELERATOR_CSHIFT)
 template <typename T>
 T iDivUp(T a, T b) // Round a / b to nearest higher integer value
 { return (a % b != 0) ? (a / b + 1) : (a / b); }
 template <typename T>
 __global__ void populate_Cshift_table(T* vector, T lo, T ro, T e1, T e2, T stride)
 {
    int idx = blockIdx.x*blockDim.x + threadIdx.x;
    if (idx >= e1*e2) return;
    int n, b, o;
    n = idx / e2;
    b = idx % e2;
    o = n*stride + b;
    vector[2*idx + 0] = lo + o;
    vector[2*idx + 1] = ro + o;
 }
 #endif
 //////////////////////////////////////////////////////
 // local to node block strided copies
 //////////////////////////////////////////////////////
@ -345,20 +340,12 @@ template<class vobj> void Copy_plane(Lattice<vobj>& lhs,const Lattice<vobj> &rhs
  int ent=0;
  if(cbmask == 0x3 ){
 #if (defined(GRID_CUDA) || defined(GRID_HIP)) && defined(ACCELERATOR_CSHIFT)
    ent = e1*e2;
    dim3 blockSize(acceleratorThreads());
    dim3 gridSize(iDivUp((unsigned int)ent, blockSize.x));
    populate_Cshift_table<<<gridSize, blockSize>>>(&Cshift_table[0].first, lo, ro, e1, e2, stride);
    accelerator_barrier();
 #else
    for(int n=0;n<e1;n++){
      for(int b=0;b<e2;b++){
        int o =n*stride+b;
 	Cshift_table[ent++] = std::pair<int,int>(lo+o,ro+o);
      }
    }
 #endif
  } else { 
    for(int n=0;n<e1;n++){
      for(int b=0;b<e2;b++){
@ -372,7 +359,7 @@ template<class vobj> void Copy_plane(Lattice<vobj>& lhs,const Lattice<vobj> &rhs
  }
  {
-    auto table = &Cshift_table[0];
+    auto table = MapCshiftTable();
 #ifdef ACCELERATOR_CSHIFT    
    autoView(rhs_v , rhs, AcceleratorRead);
    autoView(lhs_v , lhs, AcceleratorWrite);
@ -409,19 +396,11 @@ template<class vobj> void Copy_plane_permute(Lattice<vobj>& lhs,const Lattice<vo
  int ent=0;
  if ( cbmask == 0x3 ) {
 #if (defined(GRID_CUDA) || defined(GRID_HIP)) && defined(ACCELERATOR_CSHIFT)
    ent = e1*e2;
    dim3 blockSize(acceleratorThreads());
    dim3 gridSize(iDivUp((unsigned int)ent, blockSize.x));
    populate_Cshift_table<<<gridSize, blockSize>>>(&Cshift_table[0].first, lo, ro, e1, e2, stride);
    accelerator_barrier();
 #else
    for(int n=0;n<e1;n++){
    for(int b=0;b<e2;b++){
      int o  =n*stride;
      Cshift_table[ent++] = std::pair<int,int>(lo+o+b,ro+o+b);
    }}
 #endif
  } else {
    for(int n=0;n<e1;n++){
    for(int b=0;b<e2;b++){
@ -432,7 +411,7 @@ template<class vobj> void Copy_plane_permute(Lattice<vobj>& lhs,const Lattice<vo
  }
  {
-    auto table = &Cshift_table[0];
+    auto table = MapCshiftTable();
 #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
@ -52,7 +52,8 @@ 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
@ -63,6 +64,8 @@ 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;
 }
@ -127,16 +130,20 @@ template<class vobj> void Cshift_comms(Lattice<vobj> &ret,const Lattice<vobj> &r
  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;
@ -144,26 +151,39 @@ 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);
-
+      
-      grid->Barrier();
+      tcomms-=usecond();
      //      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();
-      grid->Barrier();
+      tscatter-=usecond();
      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)
@ -190,6 +210,12 @@ 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);
  ///////////////////////////////////////////////
@ -227,7 +253,9 @@ 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++){
@ -252,7 +280,8 @@ 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); 
-	grid->Barrier();
+	tcomms-=usecond();
 	//	grid->Barrier();
 	send_buf_extract_mpi = &send_buf_extract[nbr_lane][0];
 	recv_buf_extract_mpi = &recv_buf_extract[i][0];
@ -262,7 +291,9 @@ template<class vobj> void  Cshift_comms_simd(Lattice<vobj> &ret,const Lattice<vo
 			     recv_from_rank,
 			     bytes);
-	grid->Barrier();
+	xbytes+=bytes;
 	//	grid->Barrier();
 	tcomms+=usecond();
 	rpointers[i] = &recv_buf_extract[i][0];
      } else { 
@ -270,9 +301,17 @@ 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)
@ -292,6 +331,11 @@ 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);
@ -315,7 +359,9 @@ 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 {
@ -324,7 +370,9 @@ 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;
@ -332,7 +380,8 @@ template<class vobj> void Cshift_comms(Lattice<vobj> &ret,const Lattice<vobj> &r
      grid->ShiftedRanks(dimension,comm_proc,xmit_to_rank,recv_from_rank);
-      grid->Barrier();
+      tcomms-=usecond();
      //      grid->Barrier();
      acceleratorCopyDeviceToDevice((void *)&send_buf_v[0],(void *)&send_buf[0],bytes);
      grid->SendToRecvFrom((void *)&send_buf[0],
@ -340,13 +389,24 @@ 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)
@ -372,6 +432,11 @@ 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);
@ -414,8 +479,10 @@ 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++){
@ -440,7 +507,8 @@ 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); 
-	grid->Barrier();
+	tcomms-=usecond();
 	//	grid->Barrier();
 	acceleratorCopyDeviceToDevice((void *)&send_buf_extract[nbr_lane][0],(void *)send_buf_extract_mpi,bytes);
 	grid->SendToRecvFrom((void *)send_buf_extract_mpi,
@ -449,17 +517,28 @@ 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
@ -1,4 +1,5 @@
 #include <Grid/GridCore.h>       
 NAMESPACE_BEGIN(Grid);
-Vector<std::pair<int,int> > Cshift_table; 
+std::vector<std::pair<int,int> > Cshift_table; 
 commVector<std::pair<int,int> > Cshift_table_device; 
 NAMESPACE_END(Grid);
--- a/Grid/lattice/Lattice.h
+++ b/Grid/lattice/Lattice.h
@ -35,6 +35,7 @@ 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>
@ -46,4 +47,4 @@ 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/Lattice_crc.h>
+#include <Grid/lattice/PaddedCell.h>
--- a/Grid/lattice/Lattice_ET.h
+++ b/Grid/lattice/Lattice_ET.h
@ -345,7 +345,9 @@ 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));
@ -456,7 +458,9 @@ 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
@ -270,5 +270,42 @@ RealD axpby_norm(Lattice<vobj> &ret,sobj a,sobj b,const Lattice<vobj> &x,const L
    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_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)) )
+#if ( !(defined(GRID_CUDA) || defined(GRID_HIP) || defined(GRID_SYCL)) )
  int max_threads = thread_max();
  Vector < vobj > Bt(Nm * max_threads);
  thread_region
--- a/Grid/lattice/Lattice_crc.h
+++ b/Grid/lattice/Lattice_crc.h
@ -42,13 +42,13 @@ template<class vobj> void DumpSliceNorm(std::string s,Lattice<vobj> &f,int mu=-1
  }
 }
-template<class vobj> uint32_t crc(Lattice<vobj> & buf)
+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::cout << "FingerPrint "<<__FILE__ <<" "<< __LINE__ <<" "<< #U <<" "<<crc(U)<<std::endl;
+#define CRC(U) std::cerr << "FingerPrint "<<__FILE__ <<" "<< __LINE__ <<" "<< #U <<" "<<crc(U)<<std::endl;
 NAMESPACE_END(Grid);
--- a/Grid/lattice/Lattice_reduction.h
+++ b/Grid/lattice/Lattice_reduction.h
@ -31,6 +31,7 @@ Author: Christoph Lehner <christoph@lhnr.de>
 #if defined(GRID_SYCL)
 #include <Grid/lattice/Lattice_reduction_sycl.h>
 #endif
 #include <Grid/lattice/Lattice_slicesum_core.h>
 NAMESPACE_BEGIN(Grid);
@ -284,6 +285,7 @@ template<class vobj>
 inline ComplexD innerProduct(const Lattice<vobj> &left,const Lattice<vobj> &right) {
  GridBase *grid = left.Grid();
  ComplexD nrm = rankInnerProduct(left,right);
  //  std::cerr<<"flight log " << std::hexfloat << nrm <<" "<<crc(left)<<std::endl;
  grid->GlobalSum(nrm);
  return nrm;
 }
@ -448,19 +450,10 @@ 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
+  
-  // Parallel over orthog direction
+  //Reduce Data down to lvSum
-  autoView( Data_v, Data, CpuRead);
+  sliceSumReduction(Data,lvSum,rd, e1,e2,stride,ostride,Nsimd);
  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);
@ -504,6 +497,7 @@ sliceSum(const Lattice<vobj> &Data,int orthogdim)
  return result;
 }
 template<class vobj>
 static void sliceInnerProductVector( std::vector<ComplexD> & result, const Lattice<vobj> &lhs,const Lattice<vobj> &rhs,int orthogdim) 
 {
--- a/Grid/lattice/Lattice_reduction_gpu.h
+++ b/Grid/lattice/Lattice_reduction_gpu.h
@ -30,7 +30,7 @@ int getNumBlocksAndThreads(const Iterator n, const size_t sizeofsobj, Iterator &
  cudaGetDevice(&device);
 #endif
 #ifdef GRID_HIP
-  hipGetDevice(&device);
+  auto r=hipGetDevice(&device);
 #endif
  Iterator warpSize            = gpu_props[device].warpSize;
--- a/Grid/lattice/Lattice_rng.h
+++ b/Grid/lattice/Lattice_rng.h
@ -152,6 +152,7 @@ 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.
@ -162,9 +163,9 @@ 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;
@ -179,6 +180,9 @@ 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
--- a/Grid/lattice/Lattice_slicesum_core.h
+++ b/Grid/lattice/Lattice_slicesum_core.h
@ -0,0 +1,213 @@
 #pragma once
 #include <type_traits>
 #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);
 }
 template<class vobj> inline void sliceSumReduction_cub_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];
    });
    sliceSumReduction_cub_small(buf,lvSum_small,rd,e1,e2,stride, ostride,Nsimd);
    for (int r = 0; r < rd; r++) {
      lvSum_ptr[w+words*r]=lvSum_small[r];
    }
  }
 }
 template<class vobj> inline void sliceSumReduction_cub(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); //hipcub/cub cannot deal with large vobjs so we split into small/large case.
    if constexpr (sizeof(vobj) <= 256) { 
      sliceSumReduction_cub_small(&Data_v[0], lvSum, rd, e1, e2, stride, ostride, Nsimd);
    }
    else {
      sliceSumReduction_cub_large(&Data_v[0], lvSum, rd, e1, e2, stride, ostride, Nsimd);
    }
 }
 #endif
 #if defined(GRID_SYCL)
 template<class vobj> inline void sliceSumReduction_sycl(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)
 {
  typedef typename vobj::scalar_object sobj;
  size_t subvol_size = e1*e2;
  vobj *mysum = (vobj *) malloc_shared(sizeof(vobj),*theGridAccelerator);
  vobj vobj_zero;
  zeroit(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_v[ss]));
  });
  for (int r = 0; r < rd; r++) {
      mysum[0] = vobj_zero; //dirty hack: cannot pass vobj_zero as identity to sycl::reduction as its not device_copyable
      theGridAccelerator->submit([&](cl::sycl::handler &cgh) {
          auto Reduction = cl::sycl::reduction(mysum,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();
      lvSum[r] = mysum[0];
  }
  free(mysum,*theGridAccelerator);
 }
 #endif
 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)
  sliceSumReduction_cub(Data, lvSum, rd, e1, e2, stride, ostride, Nsimd);
  #elif defined(GRID_SYCL)
  sliceSumReduction_sycl(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
@ -66,6 +66,65 @@ 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
@ -469,15 +469,13 @@ inline void blockSum(Lattice<vobj> &coarseData,const Lattice<vobj> &fineData)
  Coordinate fine_rdimensions = fine->_rdimensions;
  Coordinate coarse_rdimensions = coarse->_rdimensions;
  vobj zz = Zero();
  accelerator_for(sc,coarse->oSites(),1,{
      // One thread per sub block
      Coordinate coor_c(_ndimension);
      Lexicographic::CoorFromIndex(coor_c,sc,coarse_rdimensions);  // Block coordinate
-      vobj cd = zz;
+      vobj cd = Zero();
      for(int sb=0;sb<blockVol;sb++){
@ -697,8 +695,68 @@ 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;
@ -738,6 +796,8 @@ void localCopyRegion(const Lattice<vobj> &From,Lattice<vobj> & To,Coordinate Fro
 #endif
    }
  });
 #endif
 }
@ -830,6 +890,8 @@ 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)
 {
@ -851,6 +913,65 @@ void InsertSliceLocal(const Lattice<vobj> &lowDim, Lattice<vobj> & higherDim,int
    }
  }
 #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);
@ -866,6 +987,7 @@ void InsertSliceLocal(const Lattice<vobj> &lowDim, Lattice<vobj> & higherDim,int
      pokeLocalSite(s,higherDimv,hcoor);
    }
  });
 #endif
 }
--- a/Grid/lattice/Lattice_view.h
+++ b/Grid/lattice/Lattice_view.h
@ -45,6 +45,7 @@ public:
  };
  // Host only
  GridBase * getGrid(void) const { return _grid; };
  vobj* getHostPointer(void) const { return _odata; };
 };
 /////////////////////////////////////////////////////////////////////////////////////////
--- a/Grid/lattice/PaddedCell.h
+++ b/Grid/lattice/PaddedCell.h
@ -26,14 +26,32 @@ Author: Peter Boyle pboyle@bnl.gov
 /*  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();
@ -77,7 +95,7 @@ public:
    }
  };
  template<class vobj>
-  inline Lattice<vobj> Extract(Lattice<vobj> &in)
+  inline Lattice<vobj> Extract(const Lattice<vobj> &in) const
  {
    Lattice<vobj> out(unpadded_grid);
@ -88,19 +106,19 @@ public:
    return out;
  }
  template<class vobj>
-  inline Lattice<vobj> Exchange(Lattice<vobj> &in)
+  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); // rvalue && assignment
+      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,Lattice<vobj> &in)
+  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
@ -112,20 +130,40 @@ public:
    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
-    shifted = Cshift(in,dim,depth);
+    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
-    shifted = Cshift(in,dim,-depth);
+    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;
  }
--- a/Grid/log/Log.h
+++ b/Grid/log/Log.h
@ -179,11 +179,11 @@ 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;
@ -191,6 +191,41 @@ 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/perfmon/Tracing.h
+++ b/Grid/perfmon/Tracing.h
@ -34,7 +34,7 @@ class GridTracer {
 };
 inline void tracePush(const char *name) { roctxRangePushA(name); }
 inline void tracePop(const char *name) { roctxRangePop(); }
-inline int  traceStart(const char *name) { roctxRangeStart(name); }
+inline int  traceStart(const char *name) { return roctxRangeStart(name); }
 inline void traceStop(int ID) { roctxRangeStop(ID); }
 #endif
--- a/Grid/qcd/action/ActionBase.h
+++ b/Grid/qcd/action/ActionBase.h
@ -129,6 +129,22 @@ public:
  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/fermion/CayleyFermion5D.h
+++ b/Grid/qcd/action/fermion/CayleyFermion5D.h
@ -124,11 +124,6 @@ public:
  RealD                _b;
  RealD                _c;
  // possible boost
  std::vector<ComplexD> qmu;
  void set_qmu(std::vector<ComplexD> _qmu) { qmu=_qmu; assert(qmu.size()==Nd);};
  void addQmu(const FermionField &in, FermionField &out, int dag);
  // Cayley form Moebius (tanh and zolotarev)
  Vector<Coeff_t> omega;
  Vector<Coeff_t> bs;    // S dependent coeffs
--- a/Grid/qcd/action/fermion/ContinuedFractionFermion5D.h
+++ b/Grid/qcd/action/fermion/ContinuedFractionFermion5D.h
@ -60,50 +60,6 @@ public:
  //      virtual void   Instantiatable(void)=0;
  virtual void   Instantiatable(void) =0;
  void FreePropagator(const FermionField &in,FermionField &out,RealD mass,std::vector<Complex> boundary, std::vector<double> twist)
  {
    std::cout << "Free Propagator for PartialFraction"<<std::endl;
    FermionField in_k(in.Grid());
    FermionField prop_k(in.Grid());
    FFT theFFT((GridCartesian *) in.Grid());
    //phase for boundary condition
    ComplexField coor(in.Grid());
    ComplexField ph(in.Grid());  ph = Zero();
    FermionField in_buf(in.Grid()); in_buf = Zero();
    typedef typename Simd::scalar_type Scalar;
    Scalar ci(0.0,1.0);
    assert(twist.size() == Nd);//check that twist is Nd
    assert(boundary.size() == Nd);//check that boundary conditions is Nd
    int shift = 0;
    for(unsigned int nu = 0; nu < Nd; nu++)
      {
 	// Shift coordinate lattice index by 1 to account for 5th dimension.
 	LatticeCoordinate(coor, nu + shift);
 	double boundary_phase = ::acos(real(boundary[nu]));
 	ph = ph + boundary_phase*coor*((1./(in.Grid()->_fdimensions[nu+shift])));
 	//momenta for propagator shifted by twist+boundary
 	twist[nu] = twist[nu] + boundary_phase/((2.0*M_PI));
      }
    in_buf = exp(ci*ph*(-1.0))*in;
    theFFT.FFT_all_dim(in_k,in,FFT::forward);
    this->MomentumSpacePropagatorHw(prop_k,in_k,mass,twist);
    theFFT.FFT_all_dim(out,prop_k,FFT::backward);
    //phase for boundary condition
    out = out * exp(ci*ph);
  };
  virtual void FreePropagator(const FermionField &in,FermionField &out,RealD mass) {
    std::vector<double> twist(Nd,0.0); //default: periodic boundarys in all directions
    std::vector<Complex> boundary;
    for(int i=0;i<Nd;i++) boundary.push_back(1);//default: periodic boundary conditions
    FreePropagator(in,out,mass,boundary,twist);
  };
  // Efficient support for multigrid coarsening
  virtual void  Mdir (const FermionField &in, FermionField &out,int dir,int disp);
  virtual void  MdirAll(const FermionField &in, std::vector<FermionField> &out);
--- a/Grid/qcd/action/fermion/Fermion.h
+++ b/Grid/qcd/action/fermion/Fermion.h
@ -126,6 +126,16 @@ typedef WilsonFermion<WilsonTwoIndexSymmetricImplD> WilsonTwoIndexSymmetricFermi
 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<WilsonImplF> WilsonTMFermionF;
--- a/Grid/qcd/action/fermion/PartialFractionFermion5D.h
+++ b/Grid/qcd/action/fermion/PartialFractionFermion5D.h
@ -39,7 +39,7 @@ class PartialFractionFermion5D : public WilsonFermion5D<Impl>
 public:
  INHERIT_IMPL_TYPES(Impl);
-  const int part_frac_chroma_convention=0;
+  const int part_frac_chroma_convention=1;
  void   Meooe_internal(const FermionField &in, FermionField &out,int dag);
  void   Mooee_internal(const FermionField &in, FermionField &out,int dag);
@ -83,63 +83,12 @@ public:
 			   GridRedBlackCartesian &FourDimRedBlackGrid,
 			   RealD _mass,RealD M5,const ImplParams &p= ImplParams());
  PartialFractionFermion5D(GaugeField &_Umu,
 			   GridCartesian         &FiveDimGrid,
 			   GridRedBlackCartesian &FiveDimRedBlackGrid,
 			   GridCartesian         &FourDimGrid,
 			   GridRedBlackCartesian &FourDimRedBlackGrid,
 			   RealD _mass,RealD M5,std::vector<RealD> &_qmu,const ImplParams &p= ImplParams());
  void FreePropagator(const FermionField &in,FermionField &out,RealD mass,std::vector<Complex> boundary, std::vector<double> twist)
  {
    std::cout << "Free Propagator for PartialFraction"<<std::endl;
    FermionField in_k(in.Grid());
    FermionField prop_k(in.Grid());
    FFT theFFT((GridCartesian *) in.Grid());
    //phase for boundary condition
    ComplexField coor(in.Grid());
    ComplexField ph(in.Grid());  ph = Zero();
    FermionField in_buf(in.Grid()); in_buf = Zero();
    typedef typename Simd::scalar_type Scalar;
    Scalar ci(0.0,1.0);
    assert(twist.size() == Nd);//check that twist is Nd
    assert(boundary.size() == Nd);//check that boundary conditions is Nd
    int shift = 0;
    for(unsigned int nu = 0; nu < Nd; nu++)
      {
 	// Shift coordinate lattice index by 1 to account for 5th dimension.
 	LatticeCoordinate(coor, nu + shift);
 	double boundary_phase = ::acos(real(boundary[nu]));
 	ph = ph + boundary_phase*coor*((1./(in.Grid()->_fdimensions[nu+shift])));
 	//momenta for propagator shifted by twist+boundary
 	twist[nu] = twist[nu] + boundary_phase/((2.0*M_PI));
      }
    in_buf = exp(ci*ph*(-1.0))*in;
    theFFT.FFT_all_dim(in_k,in,FFT::forward);
    this->MomentumSpacePropagatorHw(prop_k,in_k,mass,twist);
    theFFT.FFT_all_dim(out,prop_k,FFT::backward);
    //phase for boundary condition
    out = out * exp(ci*ph);
  };
  virtual void FreePropagator(const FermionField &in,FermionField &out,RealD mass) {
    std::vector<double> twist(Nd,0.0); //default: periodic boundarys in all directions
    std::vector<Complex> boundary;
    for(int i=0;i<Nd;i++) boundary.push_back(1);//default: periodic boundary conditions
    FreePropagator(in,out,mass,boundary,twist);
  };
 protected:
  virtual void SetCoefficientsTanh(Approx::zolotarev_data *zdata,RealD scale);
  virtual void SetCoefficientsZolotarev(RealD zolo_hi,Approx::zolotarev_data *zdata);
  // Part frac
  std::vector<RealD> qmu;
  RealD mass;
  RealD dw_diag;
  RealD R;
--- a/Grid/qcd/action/fermion/WilsonImpl.h
+++ b/Grid/qcd/action/fermion/WilsonImpl.h
@ -261,6 +261,22 @@ typedef WilsonImpl<vComplex,  TwoIndexAntiSymmetricRepresentation, CoeffReal > W
 typedef WilsonImpl<vComplexF, TwoIndexAntiSymmetricRepresentation, CoeffReal > WilsonTwoIndexAntiSymmetricImplF;  // Float
 typedef WilsonImpl<vComplexD, TwoIndexAntiSymmetricRepresentation, CoeffReal > WilsonTwoIndexAntiSymmetricImplD;  // Double
 //sp 2n
 typedef WilsonImpl<vComplex,  SpFundamentalRepresentation, CoeffReal > SpWilsonImplR;  // Real.. whichever prec
 typedef WilsonImpl<vComplexF, SpFundamentalRepresentation, CoeffReal > SpWilsonImplF;  // Float
 typedef WilsonImpl<vComplexD, SpFundamentalRepresentation, CoeffReal > SpWilsonImplD;  // Double
 typedef WilsonImpl<vComplex,  SpTwoIndexAntiSymmetricRepresentation, CoeffReal > SpWilsonTwoIndexAntiSymmetricImplR;  // Real.. whichever prec
 typedef WilsonImpl<vComplexF, SpTwoIndexAntiSymmetricRepresentation, CoeffReal > SpWilsonTwoIndexAntiSymmetricImplF;  // Float
 typedef WilsonImpl<vComplexD, SpTwoIndexAntiSymmetricRepresentation, CoeffReal > SpWilsonTwoIndexAntiSymmetricImplD;  // Double
 typedef WilsonImpl<vComplex,  SpTwoIndexSymmetricRepresentation, CoeffReal > SpWilsonTwoIndexSymmetricImplR;  // Real.. whichever prec
 typedef WilsonImpl<vComplexF, SpTwoIndexSymmetricRepresentation, CoeffReal > SpWilsonTwoIndexSymmetricImplF;  // Float
 typedef WilsonImpl<vComplexD, SpTwoIndexSymmetricRepresentation, CoeffReal > SpWilsonTwoIndexSymmetricImplD;  // Double
 typedef WilsonImpl<vComplex,  SpTwoIndexSymmetricRepresentation, CoeffReal > SpWilsonAdjImplR;  // Real.. whichever prec    // adj = 2indx symmetric for Sp(2N)
 typedef WilsonImpl<vComplexF, SpTwoIndexSymmetricRepresentation, CoeffReal > SpWilsonAdjImplF;  // Float     // adj = 2indx symmetric for Sp(2N)
 typedef WilsonImpl<vComplexD, SpTwoIndexSymmetricRepresentation, CoeffReal > SpWilsonAdjImplD;  // Double    // adj = 2indx symmetric for Sp(2N)
 NAMESPACE_END(Grid);
--- a/Grid/qcd/action/fermion/WilsonTMFermion.h
+++ b/Grid/qcd/action/fermion/WilsonTMFermion.h
@ -63,7 +63,9 @@ public:
  virtual void MooeeDag(const FermionField &in, FermionField &out) ;
  virtual void MooeeInv(const FermionField &in, FermionField &out) ;
  virtual void MooeeInvDag(const FermionField &in, FermionField &out) ;
-
+  virtual void M(const FermionField &in, FermionField &out) ;
  virtual void Mdag(const FermionField &in, FermionField &out) ;
 private:
  RealD mu; // TwistedMass parameter
--- a/Grid/qcd/action/fermion/implementation/CayleyFermion5DImplementation.h
+++ b/Grid/qcd/action/fermion/implementation/CayleyFermion5DImplementation.h
@ -48,8 +48,7 @@ CayleyFermion5D<Impl>::CayleyFermion5D(GaugeField &_Umu,
 			FourDimGrid,
 			FourDimRedBlackGrid,_M5,p),
  mass_plus(_mass), mass_minus(_mass)
-{
+{ 
  // qmu defaults to zero size;
 }
 ///////////////////////////////////////////////////////////////
@ -271,34 +270,6 @@ void CayleyFermion5D<Impl>::MeooeDag5D    (const FermionField &psi, FermionField
  M5Ddag(psi,psi,Din,lower,diag,upper);
 }
 template<class Impl>
 void CayleyFermion5D<Impl>::addQmu(const FermionField &psi,FermionField &chi, int dag)
 {
  if ( qmu.size() ) {
    Gamma::Algebra Gmu [] = {
      Gamma::Algebra::GammaX,
      Gamma::Algebra::GammaY,
      Gamma::Algebra::GammaZ,
      Gamma::Algebra::GammaT
    };
    std::vector<ComplexD> coeff(Nd);
    ComplexD ci(0,1);
    assert(qmu.size()==Nd);
    for(int mu=0;mu<Nd;mu++){
       coeff[mu] = ci*qmu[mu];
       if ( dag ) coeff[mu] = conjugate(coeff[mu]);
    }
    chi = chi + Gamma(Gmu[0])*psi*coeff[0];
    for(int mu=1;mu<Nd;mu++){
      chi = chi + Gamma(Gmu[mu])*psi*coeff[mu];
    }
  }
 }
 template<class Impl>
 void CayleyFermion5D<Impl>::M    (const FermionField &psi, FermionField &chi)
 {
@ -306,12 +277,8 @@ void CayleyFermion5D<Impl>::M    (const FermionField &psi, FermionField &chi)
  // Assemble Din
  Meooe5D(psi,Din);
  this->DW(Din,chi,DaggerNo);
  // add i q_mu gamma_mu here
  addQmu(Din,chi,DaggerNo);
  this->DW(Din,chi,DaggerNo);
  // ((b D_W + D_w hop terms +1) on s-diag
  axpby(chi,1.0,1.0,chi,psi); 
@ -328,9 +295,6 @@ void CayleyFermion5D<Impl>::Mdag (const FermionField &psi, FermionField &chi)
  FermionField Din(psi.Grid());
  // Apply Dw
  this->DW(psi,Din,DaggerYes); 
  // add -i conj(q_mu) gamma_mu here ... if qmu is real, gammm_5 hermitian, otherwise not.
  addQmu(psi,Din,DaggerYes);
  MeooeDag5D(Din,chi);
--- a/Grid/qcd/action/fermion/implementation/ContinuedFractionFermion5DImplementation.h
+++ b/Grid/qcd/action/fermion/implementation/ContinuedFractionFermion5DImplementation.h
@ -42,13 +42,13 @@ template<class Impl>
 void ContinuedFractionFermion5D<Impl>::SetCoefficientsZolotarev(RealD zolo_hi,Approx::zolotarev_data *zdata)
 {
  // How to check Ls matches??
-  std::cout<<GridLogMessage << zdata->n  << " - n"<<std::endl;
+  //      std::cout<<GridLogMessage << Ls << " Ls"<<std::endl;
-  std::cout<<GridLogMessage << zdata->da << " -da "<<std::endl;
+  //      std::cout<<GridLogMessage << zdata->n  << " - n"<<std::endl;
-  std::cout<<GridLogMessage << zdata->db << " -db"<<std::endl;
+  //      std::cout<<GridLogMessage << zdata->da << " -da "<<std::endl;
-  std::cout<<GridLogMessage << zdata->dn << " -dn"<<std::endl;
+  //      std::cout<<GridLogMessage << zdata->db << " -db"<<std::endl;
-  std::cout<<GridLogMessage << zdata->dd << " -dd"<<std::endl;
+  //      std::cout<<GridLogMessage << zdata->dn << " -dn"<<std::endl;
  //      std::cout<<GridLogMessage << zdata->dd << " -dd"<<std::endl;
  int Ls = this->Ls;
  std::cout<<GridLogMessage << Ls << " Ls"<<std::endl;
  assert(zdata->db==Ls);// Beta has Ls coeffs
  R=(1+this->mass)/(1-this->mass);
@ -320,7 +320,7 @@ ContinuedFractionFermion5D<Impl>::ContinuedFractionFermion5D(
      int Ls = this->Ls;
      conformable(solution5d.Grid(),this->FermionGrid());
      conformable(exported4d.Grid(),this->GaugeGrid());
-      ExtractSlice(exported4d, solution5d, Ls-1, 0);
+      ExtractSlice(exported4d, solution5d, Ls-1, Ls-1);
    }
    template<class Impl>
    void ContinuedFractionFermion5D<Impl>::ImportPhysicalFermionSource(const FermionField &input4d,FermionField &imported5d)
@ -330,7 +330,7 @@ ContinuedFractionFermion5D<Impl>::ContinuedFractionFermion5D(
      conformable(input4d.Grid()   ,this->GaugeGrid());
      FermionField tmp(this->FermionGrid());
      tmp=Zero();
-      InsertSlice(input4d, tmp, Ls-1, 0);
+      InsertSlice(input4d, tmp, Ls-1, Ls-1);
      tmp=Gamma(Gamma::Algebra::Gamma5)*tmp;
      this->Dminus(tmp,imported5d);
    }
--- a/Grid/qcd/action/fermion/implementation/PartialFractionFermion5DImplementation.h
+++ b/Grid/qcd/action/fermion/implementation/PartialFractionFermion5DImplementation.h
@ -255,76 +255,15 @@ void   PartialFractionFermion5D<Impl>::M_internal(const FermionField &psi, Fermi
  }
  {
    // The 'conventional' Cayley overlap operator is
    //
    // Dov = (1+m)/2 + (1-m)/2 g5 sgn Hw
    //
    //
    // With massless limit 1/2(1+g5 sgnHw)
    //
    // Luscher shows quite neatly that 1+g5 sgn Hw has tree level propagator i qslash +O(a^2)
    //
    // However, the conventional normalisation has both a leading order factor of 2 in Zq
    // at tree level AND a mass dependent (1-m) that are convenient to absorb.
    //
    // In WilsonFermion5DImplementation.h, the tree level propagator for Hw is
    //
    // num = -i sin kmu gmu
    //
    // denom ( sqrt(sk^2 + (2shk^2 - 1)^2
    //    b_k = sk2 - M5;
    //     
    //    w_k = sqrt(sk + b_k*b_k);
    //
    //    denom= ( w_k + b_k + mass*mass) ;
    //
    //    denom= one/denom;
    //    out = num*denom;
    //
    // Chroma, and Grid define partial fraction via 4d operator
    //
    //   Dpf = 2/(1-m) x Dov = (1+m)/(1-m) + g5 sgn Hw
    //
    // Now since:
    //
    //      (1+m)/(1-m) = (1-m)/(1-m) + 2m/(1-m) = 1 + 2m/(1-m)
    //
    // This corresponds to a modified mass parameter
    //
    // It has an annoying 
    //
    // 
    double R=(1+this->mass)/(1-this->mass);
    //R g5 psi[Ls] + p[0] H
    ag5xpbg5y_ssp(chi,R*scale,psi,p[nblock]*scale/amax,D,Ls-1,Ls-1);
-    
+	
    for(int b=0;b<nblock;b++){
      int s = 2*b+1;
      double pp = p[nblock-1-b];
      axpby_ssp(chi,1.0,chi,-sqrt(amax*pp)*scale*sign,psi,Ls-1,s);
    }
    if ( qmu.size() ) {
      FermionField qslash_psi(psi.Grid());
      Gamma::Algebra Gmu [] = {
 			 Gamma::Algebra::GammaX,
 			 Gamma::Algebra::GammaY,
 			 Gamma::Algebra::GammaZ,
 			 Gamma::Algebra::GammaT
      };
      ComplexD ci(0,1);
      assert(qmu.size()==Nd);
      qslash_psi = Gamma(Gmu[0])*psi;
      for(int mu=1;mu<Nd;mu++){
 	qslash_psi = Gamma(Gmu[mu])*psi;
      }
      //      RealD coeff = 1.0;
      qslash_psi = Gamma(Gamma::Algebra::Gamma5)*qslash_psi*ci ; // i g5 qslash -- 1-m factor???
      axpby_ssp(chi,1.0,chi,1.0, qslash_psi,Ls-1,Ls-1);
    }
  }
 }
@ -472,7 +411,7 @@ void  PartialFractionFermion5D<Impl>::SetCoefficientsZolotarev(RealD zolo_hi,App
      int Ls = this->Ls;
      conformable(solution5d.Grid(),this->FermionGrid());
      conformable(exported4d.Grid(),this->GaugeGrid());
-      ExtractSlice(exported4d, solution5d, Ls-1, 0);
+      ExtractSlice(exported4d, solution5d, Ls-1, Ls-1);
    }
    template<class Impl>
    void PartialFractionFermion5D<Impl>::ImportPhysicalFermionSource(const FermionField &input4d,FermionField &imported5d)
@ -482,8 +421,7 @@ void  PartialFractionFermion5D<Impl>::SetCoefficientsZolotarev(RealD zolo_hi,App
      conformable(input4d.Grid()   ,this->GaugeGrid());
      FermionField tmp(this->FermionGrid());
      tmp=Zero();
-      std::cout << " importing to slice " << Ls-1 <<std::endl;
+      InsertSlice(input4d, tmp, Ls-1, Ls-1);
      InsertSlice(input4d, tmp, Ls-1, 0);
      tmp=Gamma(Gamma::Algebra::Gamma5)*tmp;
      this->Dminus(tmp,imported5d);
    }
@ -504,7 +442,7 @@ PartialFractionFermion5D<Impl>::PartialFractionFermion5D(GaugeField &_Umu,
 {
  int Ls = this->Ls;
-  qmu.resize(0);
+
  assert((Ls&0x1)==1); // Odd Ls required
  int nrational=Ls-1;
@ -522,22 +460,6 @@ PartialFractionFermion5D<Impl>::PartialFractionFermion5D(GaugeField &_Umu,
  Approx::zolotarev_free(zdata);
 }
 template<class Impl>
 PartialFractionFermion5D<Impl>::PartialFractionFermion5D(GaugeField &_Umu,
 							 GridCartesian         &FiveDimGrid,
 							 GridRedBlackCartesian &FiveDimRedBlackGrid,
 							 GridCartesian         &FourDimGrid,
 							 GridRedBlackCartesian &FourDimRedBlackGrid,
 							 RealD _mass,RealD M5,
 							 std::vector<RealD> &_qmu,
 							 const ImplParams &p)
  : PartialFractionFermion5D<Impl>(_Umu,
 			     FiveDimGrid,FiveDimRedBlackGrid,
 			     FourDimGrid,FourDimRedBlackGrid,
 			     _mass,M5,p)
 {
  qmu=_qmu;
 }
 NAMESPACE_END(Grid);
--- a/Grid/qcd/action/fermion/implementation/StaggeredKernelsImplementation.h
+++ b/Grid/qcd/action/fermion/implementation/StaggeredKernelsImplementation.h
@ -280,20 +280,16 @@ void StaggeredKernels<Impl>::DhopImproved(StencilImpl &st, LebesgueOrder &lo,
  if( interior && exterior ) { 
    if (Opt == OptGeneric    ) { KERNEL_CALL(DhopSiteGeneric,1); return;}
 #ifndef GRID_CUDA
    if (Opt == OptHandUnroll ) { KERNEL_CALL(DhopSiteHand,1);    return;}
 #ifndef GRID_CUDA
    if (Opt == OptInlineAsm  ) {  ASM_CALL(DhopSiteAsm);     return;}
 #endif
  } else if( interior ) {
    if (Opt == OptGeneric    ) { KERNEL_CALL(DhopSiteGenericInt,1); return;}
 #ifndef GRID_CUDA
    if (Opt == OptHandUnroll ) { KERNEL_CALL(DhopSiteHandInt,1);    return;}
 #endif
  } else if( exterior ) { 
    if (Opt == OptGeneric    ) { KERNEL_CALL(DhopSiteGenericExt,1); return;}
 #ifndef GRID_CUDA
    if (Opt == OptHandUnroll ) { KERNEL_CALL(DhopSiteHandExt,1);    return;}
 #endif
  }
  assert(0 && " Kernel optimisation case not covered ");
 }
@ -322,19 +318,13 @@ void StaggeredKernels<Impl>::DhopNaive(StencilImpl &st, LebesgueOrder &lo,
  if( interior && exterior ) { 
    if (Opt == OptGeneric    ) { KERNEL_CALL(DhopSiteGeneric,0); return;}
 #ifndef GRID_CUDA
    if (Opt == OptHandUnroll ) { KERNEL_CALL(DhopSiteHand,0);    return;}
 #endif
  } else if( interior ) {
    if (Opt == OptGeneric    ) { KERNEL_CALL(DhopSiteGenericInt,0); return;}
 #ifndef GRID_CUDA
    if (Opt == OptHandUnroll ) { KERNEL_CALL(DhopSiteHandInt,0);    return;}
 #endif
  } else if( exterior ) { 
    if (Opt == OptGeneric    ) { KERNEL_CALL(DhopSiteGenericExt,0); return;}
 #ifndef GRID_CUDA
    if (Opt == OptHandUnroll ) { KERNEL_CALL(DhopSiteHandExt,0);    return;}
 #endif
  }
 }
--- a/Grid/qcd/action/fermion/implementation/WilsonTMFermionImplementation.h
+++ b/Grid/qcd/action/fermion/implementation/WilsonTMFermionImplementation.h
@ -93,5 +93,25 @@ void WilsonTMFermion<Impl>::MooeeInvDag(const FermionField &in, FermionField &ou
  RealD b    = tm /sq;
  axpibg5x(out,in,a,b);
 }
 template<class Impl>
 void WilsonTMFermion<Impl>::M(const FermionField &in, FermionField &out) {
  out.Checkerboard() = in.Checkerboard();
  this->Dhop(in, out, DaggerNo);
  FermionField tmp(out.Grid());
  RealD a = 4.0+this->mass;
  RealD b = this->mu;
  axpibg5x(tmp,in,a,b);
  axpy(out, 1.0, tmp, out);
 }
 template<class Impl>
 void WilsonTMFermion<Impl>::Mdag(const FermionField &in, FermionField &out) {
  out.Checkerboard() = in.Checkerboard();
  this->Dhop(in, out, DaggerYes);
  FermionField tmp(out.Grid());
  RealD a = 4.0+this->mass;
  RealD b = -this->mu;
  axpibg5x(tmp,in,a,b);
  axpy(out, 1.0, tmp, out);
 }
 NAMESPACE_END(Grid);
--- a/Grid/qcd/action/fermion/instantiation/SpWilsonImplD/WilsonCloverFermionInstantiationSpWilsonImplD.cc
+++ b/Grid/qcd/action/fermion/instantiation/SpWilsonImplD/WilsonCloverFermionInstantiationSpWilsonImplD.cc
@ -0,0 +1 @@
 ../WilsonCloverFermionInstantiation.cc.master
--- a/Grid/qcd/action/fermion/instantiation/SpWilsonImplD/WilsonFermionInstantiationSpWilsonImplD.cc
+++ b/Grid/qcd/action/fermion/instantiation/SpWilsonImplD/WilsonFermionInstantiationSpWilsonImplD.cc
@ -0,0 +1 @@
 ../WilsonFermionInstantiation.cc.master
--- a/Grid/qcd/action/fermion/instantiation/SpWilsonImplD/WilsonKernelsInstantiationSpWilsonImplD.cc
+++ b/Grid/qcd/action/fermion/instantiation/SpWilsonImplD/WilsonKernelsInstantiationSpWilsonImplD.cc
@ -0,0 +1 @@
 ../WilsonKernelsInstantiation.cc.master
--- a/Grid/qcd/action/fermion/instantiation/SpWilsonImplD/WilsonTMFermionInstantiationSpWilsonImplD.cc
+++ b/Grid/qcd/action/fermion/instantiation/SpWilsonImplD/WilsonTMFermionInstantiationSpWilsonImplD.cc
@ -0,0 +1 @@
 ../WilsonTMFermionInstantiation.cc.master
--- a/Grid/qcd/action/fermion/instantiation/SpWilsonImplD/impl.h
+++ b/Grid/qcd/action/fermion/instantiation/SpWilsonImplD/impl.h
@ -0,0 +1 @@
 #define IMPLEMENTATION SpWilsonImplD
--- a/Grid/qcd/action/fermion/instantiation/SpWilsonImplF/WilsonCloverFermionInstantiationSpWilsonImplF.cc
+++ b/Grid/qcd/action/fermion/instantiation/SpWilsonImplF/WilsonCloverFermionInstantiationSpWilsonImplF.cc
@ -0,0 +1 @@
 ../WilsonCloverFermionInstantiation.cc.master
--- a/Grid/qcd/action/fermion/instantiation/SpWilsonImplF/WilsonFermionInstantiationSpWilsonImplF.cc
+++ b/Grid/qcd/action/fermion/instantiation/SpWilsonImplF/WilsonFermionInstantiationSpWilsonImplF.cc
@ -0,0 +1 @@
 ../WilsonFermionInstantiation.cc.master
--- a/Grid/qcd/action/fermion/instantiation/SpWilsonImplF/WilsonKernelsInstantiationSpWilsonImplF.cc
+++ b/Grid/qcd/action/fermion/instantiation/SpWilsonImplF/WilsonKernelsInstantiationSpWilsonImplF.cc
@ -0,0 +1 @@
 ../WilsonKernelsInstantiation.cc.master
--- a/Grid/qcd/action/fermion/instantiation/SpWilsonImplF/WilsonTMFermionInstantiationSpWilsonImplF.cc
+++ b/Grid/qcd/action/fermion/instantiation/SpWilsonImplF/WilsonTMFermionInstantiationSpWilsonImplF.cc
@ -0,0 +1 @@
 ../WilsonTMFermionInstantiation.cc.master
--- a/Grid/qcd/action/fermion/instantiation/SpWilsonImplF/impl.h
+++ b/Grid/qcd/action/fermion/instantiation/SpWilsonImplF/impl.h
@ -0,0 +1 @@
 #define IMPLEMENTATION SpWilsonImplF
--- a/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexAntiSymmetricImplD/WilsonCloverFermionInstantiationSpWilsonTwoIndexAntiSymmetricImplD.cc
+++ b/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexAntiSymmetricImplD/WilsonCloverFermionInstantiationSpWilsonTwoIndexAntiSymmetricImplD.cc
@ -0,0 +1 @@
 ../WilsonCloverFermionInstantiation.cc.master
--- a/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexAntiSymmetricImplD/WilsonFermionInstantiationSpWilsonTwoIndexAntiSymmetricImplD.cc
+++ b/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexAntiSymmetricImplD/WilsonFermionInstantiationSpWilsonTwoIndexAntiSymmetricImplD.cc
@ -0,0 +1 @@
 ../WilsonFermionInstantiation.cc.master
--- a/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexAntiSymmetricImplD/WilsonKernelsInstantiationSpWilsonTwoIndexAntiSymmetricImplD.cc
+++ b/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexAntiSymmetricImplD/WilsonKernelsInstantiationSpWilsonTwoIndexAntiSymmetricImplD.cc
@ -0,0 +1 @@
 ../WilsonKernelsInstantiation.cc.master
--- a/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexAntiSymmetricImplD/WilsonTMFermionInstantiationSpWilsonTwoIndexAntiSymmetricImplD.cc
+++ b/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexAntiSymmetricImplD/WilsonTMFermionInstantiationSpWilsonTwoIndexAntiSymmetricImplD.cc
@ -0,0 +1 @@
 ../WilsonTMFermionInstantiation.cc.master
--- a/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexAntiSymmetricImplD/impl.h
+++ b/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexAntiSymmetricImplD/impl.h
@ -0,0 +1 @@
 #define IMPLEMENTATION SpWilsonTwoIndexAntiSymmetricImplD
--- a/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexAntiSymmetricImplF/WilsonCloverFermionInstantiationSpWilsonTwoIndexAntiSymmetricImplF.cc
+++ b/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexAntiSymmetricImplF/WilsonCloverFermionInstantiationSpWilsonTwoIndexAntiSymmetricImplF.cc
@ -0,0 +1 @@
 ../WilsonCloverFermionInstantiation.cc.master
--- a/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexAntiSymmetricImplF/WilsonFermionInstantiationSpWilsonTwoIndexAntiSymmetricImplF.cc
+++ b/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexAntiSymmetricImplF/WilsonFermionInstantiationSpWilsonTwoIndexAntiSymmetricImplF.cc
@ -0,0 +1 @@
 ../WilsonFermionInstantiation.cc.master
--- a/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexAntiSymmetricImplF/WilsonKernelsInstantiationSpWilsonTwoIndexAntiSymmetricImplF.cc
+++ b/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexAntiSymmetricImplF/WilsonKernelsInstantiationSpWilsonTwoIndexAntiSymmetricImplF.cc
@ -0,0 +1 @@
 ../WilsonKernelsInstantiation.cc.master
--- a/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexAntiSymmetricImplF/WilsonTMFermionInstantiationSpWilsonTwoIndexAntiSymmetricImplF.cc
+++ b/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexAntiSymmetricImplF/WilsonTMFermionInstantiationSpWilsonTwoIndexAntiSymmetricImplF.cc
@ -0,0 +1 @@
 ../WilsonTMFermionInstantiation.cc.master
--- a/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexAntiSymmetricImplF/impl.h
+++ b/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexAntiSymmetricImplF/impl.h
@ -0,0 +1 @@
 #define IMPLEMENTATION SpWilsonTwoIndexAntiSymmetricImplF
--- a/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexSymmetricImplD/WilsonCloverFermionInstantiationSpWilsonTwoIndexSymmetricImplD.cc
+++ b/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexSymmetricImplD/WilsonCloverFermionInstantiationSpWilsonTwoIndexSymmetricImplD.cc
@ -0,0 +1 @@
 ../WilsonCloverFermionInstantiation.cc.master
--- a/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexSymmetricImplD/WilsonFermionInstantiationSpWilsonTwoIndexSymmetricImplD.cc
+++ b/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexSymmetricImplD/WilsonFermionInstantiationSpWilsonTwoIndexSymmetricImplD.cc
@ -0,0 +1 @@
 ../WilsonFermionInstantiation.cc.master
--- a/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexSymmetricImplD/WilsonKernelsInstantiationSpWilsonTwoIndexSymmetricImplD.cc
+++ b/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexSymmetricImplD/WilsonKernelsInstantiationSpWilsonTwoIndexSymmetricImplD.cc
@ -0,0 +1 @@
 ../WilsonKernelsInstantiation.cc.master
--- a/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexSymmetricImplD/WilsonTMFermionInstantiationSpWilsonTwoIndexSymmetricImplD.cc
+++ b/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexSymmetricImplD/WilsonTMFermionInstantiationSpWilsonTwoIndexSymmetricImplD.cc
@ -0,0 +1 @@
 ../WilsonTMFermionInstantiation.cc.master
--- a/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexSymmetricImplD/impl.h
+++ b/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexSymmetricImplD/impl.h
@ -0,0 +1 @@
 #define IMPLEMENTATION SpWilsonTwoIndexSymmetricImplD
--- a/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexSymmetricImplF/WilsonCloverFermionInstantiationSpWilsonTwoIndexSymmetricImplF.cc
+++ b/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexSymmetricImplF/WilsonCloverFermionInstantiationSpWilsonTwoIndexSymmetricImplF.cc
@ -0,0 +1 @@
 ../WilsonCloverFermionInstantiation.cc.master
--- a/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexSymmetricImplF/WilsonFermionInstantiationSpWilsonTwoIndexSymmetricImplF.cc
+++ b/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexSymmetricImplF/WilsonFermionInstantiationSpWilsonTwoIndexSymmetricImplF.cc
@ -0,0 +1 @@
 ../WilsonFermionInstantiation.cc.master
--- a/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexSymmetricImplF/WilsonKernelsInstantiationSpWilsonTwoIndexSymmetricImplF.cc
+++ b/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexSymmetricImplF/WilsonKernelsInstantiationSpWilsonTwoIndexSymmetricImplF.cc
@ -0,0 +1 @@
 ../WilsonKernelsInstantiation.cc.master
--- a/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexSymmetricImplF/WilsonTMFermionInstantiationSpWilsonTwoIndexSymmetricImplF.cc
+++ b/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexSymmetricImplF/WilsonTMFermionInstantiationSpWilsonTwoIndexSymmetricImplF.cc
@ -0,0 +1 @@
 ../WilsonTMFermionInstantiation.cc.master
--- a/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexSymmetricImplF/impl.h
+++ b/Grid/qcd/action/fermion/instantiation/SpWilsonTwoIndexSymmetricImplF/impl.h
@ -0,0 +1 @@
 #define IMPLEMENTATION SpWilsonTwoIndexSymmetricImplF
--- a/Grid/qcd/action/fermion/instantiation/generate_instantiations.sh
+++ b/Grid/qcd/action/fermion/instantiation/generate_instantiations.sh
@ -10,12 +10,18 @@ WILSON_IMPL_LIST=" \
 	   WilsonImplF \
 	   WilsonImplD \
 	   WilsonImplD2 \
 	   SpWilsonImplF \
 	   SpWilsonImplD \
 	   WilsonAdjImplF \
 	   WilsonAdjImplD \
 	   WilsonTwoIndexSymmetricImplF \
 	   WilsonTwoIndexSymmetricImplD \
 	   WilsonTwoIndexAntiSymmetricImplF \
 	   WilsonTwoIndexAntiSymmetricImplD \
 	   SpWilsonTwoIndexAntiSymmetricImplF \
 	   SpWilsonTwoIndexAntiSymmetricImplD \
 	   SpWilsonTwoIndexSymmetricImplF \
 	   SpWilsonTwoIndexSymmetricImplD \
 	   GparityWilsonImplF \
 	   GparityWilsonImplD "
--- a/Grid/qcd/action/gauge/Gauge.h
+++ b/Grid/qcd/action/gauge/Gauge.h
@ -39,6 +39,9 @@ NAMESPACE_BEGIN(Grid);
 typedef WilsonGaugeAction<PeriodicGimplR>          WilsonGaugeActionR;
 typedef WilsonGaugeAction<PeriodicGimplF>          WilsonGaugeActionF;
 typedef WilsonGaugeAction<PeriodicGimplD>          WilsonGaugeActionD;
 typedef WilsonGaugeAction<SpPeriodicGimplR>        SpWilsonGaugeActionR;
 typedef WilsonGaugeAction<SpPeriodicGimplF>        SpWilsonGaugeActionF;
 typedef WilsonGaugeAction<SpPeriodicGimplD>        SpWilsonGaugeActionD;
 typedef PlaqPlusRectangleAction<PeriodicGimplR>    PlaqPlusRectangleActionR;
 typedef PlaqPlusRectangleAction<PeriodicGimplF>    PlaqPlusRectangleActionF;
 typedef PlaqPlusRectangleAction<PeriodicGimplD>    PlaqPlusRectangleActionD;
--- a/Grid/qcd/action/gauge/GaugeImplTypes.h
+++ b/Grid/qcd/action/gauge/GaugeImplTypes.h
@ -61,7 +61,7 @@ NAMESPACE_BEGIN(Grid);
  typedef typename Impl::Field Field;
 // hardcodes the exponential approximation in the template
-template <class S, int Nrepresentation = Nc, int Nexp = 12 > class GaugeImplTypes {
+template <class S, int Nrepresentation = Nc, int Nexp = 12, class Group = SU<Nc> > class GaugeImplTypes {
 public:
  typedef S Simd;
  typedef typename Simd::scalar_type scalar_type;
@ -78,8 +78,6 @@ public:
  typedef Lattice<SiteLink>    LinkField; 
  typedef Lattice<SiteField>   Field;
  typedef SU<Nrepresentation> Group;
  // Guido: we can probably separate the types from the HMC functions
  // this will create 2 kind of implementations
  // probably confusing the users
@ -119,6 +117,7 @@ public:
    //
    LinkField Pmu(P.Grid());
    Pmu = Zero();
    for (int mu = 0; mu < Nd; mu++) {
      Group::GaussianFundamentalLieAlgebraMatrix(pRNG, Pmu);
      RealD scale = ::sqrt(HMC_MOMENTUM_DENOMINATOR) ;
@ -126,8 +125,12 @@ public:
      PokeIndex<LorentzIndex>(P, Pmu, mu);
    }
  }
-
+    
-  static inline Field projectForce(Field &P) { return Ta(P); }
+  static inline Field projectForce(Field &P) {
      Field ret(P.Grid());
      Group::taProj(P, ret);
      return ret;
    }
  static inline void update_field(Field& P, Field& U, double ep){
    //static std::chrono::duration<double> diff;
@ -137,14 +140,15 @@ public:
    autoView(P_v,P,AcceleratorRead);
    accelerator_for(ss, P.Grid()->oSites(),1,{
      for (int mu = 0; mu < Nd; mu++) {
-        U_v[ss](mu) = ProjectOnGroup(Exponentiate(P_v[ss](mu), ep, Nexp) * U_v[ss](mu));
+          U_v[ss](mu) = Exponentiate(P_v[ss](mu), ep, Nexp) * U_v[ss](mu);
          U_v[ss](mu) = Group::ProjectOnGeneralGroup(U_v[ss](mu));
      }
    });
   //auto end = std::chrono::high_resolution_clock::now();
   // diff += end - start;
   // std::cout << "Time to exponentiate matrix " << diff.count() << " s\n";
  }
-
+    
  static inline RealD FieldSquareNorm(Field& U){
    LatticeComplex Hloc(U.Grid());
    Hloc = Zero();
@ -157,7 +161,7 @@ public:
  }
  static inline void Project(Field &U) {
-    ProjectSUn(U);
+    Group::ProjectOnSpecialGroup(U);
  }
  static inline void HotConfiguration(GridParallelRNG &pRNG, Field &U) {
@ -171,6 +175,7 @@ public:
  static inline void ColdConfiguration(GridParallelRNG &pRNG, Field &U) {
    Group::ColdConfiguration(pRNG, U);
  }
 };
@ -178,10 +183,17 @@ typedef GaugeImplTypes<vComplex, Nc> GimplTypesR;
 typedef GaugeImplTypes<vComplexF, Nc> GimplTypesF;
 typedef GaugeImplTypes<vComplexD, Nc> GimplTypesD;
 typedef GaugeImplTypes<vComplex, Nc, 12, Sp<Nc> > SpGimplTypesR;
 typedef GaugeImplTypes<vComplexF, Nc, 12, Sp<Nc> > SpGimplTypesF;
 typedef GaugeImplTypes<vComplexD, Nc, 12, Sp<Nc> > SpGimplTypesD;
 typedef GaugeImplTypes<vComplex, SU<Nc>::AdjointDimension> GimplAdjointTypesR;
 typedef GaugeImplTypes<vComplexF, SU<Nc>::AdjointDimension> GimplAdjointTypesF;
 typedef GaugeImplTypes<vComplexD, SU<Nc>::AdjointDimension> GimplAdjointTypesD;
 NAMESPACE_END(Grid);
 #endif // GRID_GAUGE_IMPL_TYPES_H
--- a/Grid/qcd/action/gauge/GaugeImplementations.h
+++ b/Grid/qcd/action/gauge/GaugeImplementations.h
@ -176,7 +176,7 @@ public:
      return PeriodicBC::CshiftLink(Link,mu,shift);
  }
-  static inline void       setDirections(std::vector<int> &conjDirs) { _conjDirs=conjDirs; }
+  static inline void       setDirections(const std::vector<int> &conjDirs) { _conjDirs=conjDirs; }
  static inline std::vector<int> getDirections(void) { return _conjDirs; }
  static inline bool isPeriodicGaugeField(void) { return false; }
 };
@ -193,6 +193,11 @@ typedef ConjugateGaugeImpl<GimplTypesR> ConjugateGimplR; // Real.. whichever pre
 typedef ConjugateGaugeImpl<GimplTypesF> ConjugateGimplF; // Float
 typedef ConjugateGaugeImpl<GimplTypesD> ConjugateGimplD; // Double
 typedef PeriodicGaugeImpl<SpGimplTypesR> SpPeriodicGimplR; // Real.. whichever prec
 typedef PeriodicGaugeImpl<SpGimplTypesF> SpPeriodicGimplF; // Float
 typedef PeriodicGaugeImpl<SpGimplTypesD> SpPeriodicGimplD; // Double
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/qcd/action/gauge/PlaqPlusRectangleAction.h
+++ b/Grid/qcd/action/gauge/PlaqPlusRectangleAction.h
@ -43,7 +43,7 @@ public:
 private:
  RealD c_plaq;
  RealD c_rect;
-
+  typename WilsonLoops<Gimpl>::StapleAndRectStapleAllWorkspace workspace;
 public:
  PlaqPlusRectangleAction(RealD b,RealD c): c_plaq(b),c_rect(c){};
@ -79,27 +79,18 @@ public:
    GridBase *grid = Umu.Grid();
    std::vector<GaugeLinkField> U (Nd,grid);
    std::vector<GaugeLinkField> U2(Nd,grid);
    for(int mu=0;mu<Nd;mu++){
      U[mu] = PeekIndex<LorentzIndex>(Umu,mu);
      WilsonLoops<Gimpl>::RectStapleDouble(U2[mu],U[mu],mu);
    }
    std::vector<GaugeLinkField> RectStaple(Nd,grid), Staple(Nd,grid);
    WilsonLoops<Gimpl>::StapleAndRectStapleAll(Staple, RectStaple, U, workspace);
    GaugeLinkField dSdU_mu(grid);
    GaugeLinkField staple(grid);
    for (int mu=0; mu < Nd; mu++){
-
+      dSdU_mu = Ta(U[mu]*Staple[mu])*factor_p;
-      // Staple in direction mu
+      dSdU_mu = dSdU_mu + Ta(U[mu]*RectStaple[mu])*factor_r;
      WilsonLoops<Gimpl>::Staple(staple,Umu,mu);
      dSdU_mu = Ta(U[mu]*staple)*factor_p;
      WilsonLoops<Gimpl>::RectStaple(Umu,staple,U2,U,mu);
      dSdU_mu = dSdU_mu + Ta(U[mu]*staple)*factor_r;
      PokeIndex<LorentzIndex>(dSdU, dSdU_mu, mu);
    }
--- a/Grid/qcd/hmc/GenericHMCrunner.h
+++ b/Grid/qcd/hmc/GenericHMCrunner.h
@ -225,6 +225,18 @@ template <class RepresentationsPolicy,
 using GenericHMCRunnerHirep =
 				     HMCWrapperTemplate<PeriodicGimplR, Integrator, RepresentationsPolicy>;
 // sp2n
 template <template <typename, typename, typename> class Integrator>
 using GenericSpHMCRunner = HMCWrapperTemplate<SpPeriodicGimplR, Integrator>;
 template <class RepresentationsPolicy,
          template <typename, typename, typename> class Integrator>
 using GenericSpHMCRunnerHirep =
                     HMCWrapperTemplate<SpPeriodicGimplR, Integrator, RepresentationsPolicy>;
 template <class Implementation, class RepresentationsPolicy, 
          template <typename, typename, typename> class Integrator>
 using GenericHMCRunnerTemplate = HMCWrapperTemplate<Implementation, Integrator, RepresentationsPolicy>;
--- a/Grid/qcd/hmc/integrators/Integrator.h
+++ b/Grid/qcd/hmc/integrators/Integrator.h
@ -87,6 +87,8 @@ public:
  const ActionSet<Field, RepresentationPolicy> as;
  ActionSet<Field,RepresentationPolicy> LevelForces;
  //Get a pointer to a shared static instance of the "do-nothing" momentum filter to serve as a default
  static MomentumFilterBase<MomentaField> const* getDefaultMomFilter(){ 
    static MomentumFilterNone<MomentaField> filter;
@ -124,6 +126,9 @@ public:
    // input U actually not used in the fundamental case
    // Fundamental updates, include smearing
    assert(as.size()==LevelForces.size());
    Field level_force(U.Grid()); level_force =Zero();
    for (int a = 0; a < as[level].actions.size(); ++a) {
      double start_full = usecond();
@ -144,7 +149,10 @@ public:
      MomFilter->applyFilter(force);
      std::cout << GridLogIntegrator << " update_P : Level [" << level <<"]["<<a <<"] "<<name<<" dt "<<ep<<  std::endl;
-      
+
      // track the total
      level_force = level_force+force;
      Real force_abs   = std::sqrt(norm2(force)/U.Grid()->gSites()); //average per-site norm.  nb. norm2(latt) = \sum_x norm2(latt[x]) 
      Real impulse_abs = force_abs * ep * HMC_MOMENTUM_DENOMINATOR;    
@ -167,6 +175,16 @@ public:
    }
    {
      // total force
      Real force_abs   = std::sqrt(norm2(level_force)/U.Grid()->gSites()); //average per-site norm.  nb. norm2(latt) = \sum_x norm2(latt[x]) 
      Real impulse_abs = force_abs * ep * HMC_MOMENTUM_DENOMINATOR;    
      Real force_max   = std::sqrt(maxLocalNorm2(level_force));
      Real impulse_max = force_max * ep * HMC_MOMENTUM_DENOMINATOR;    
      LevelForces[level].actions.at(0)->deriv_log(force_abs,force_max,impulse_abs,impulse_max);
    }
    // Force from the other representations
    as[level].apply(update_P_hireps, Representations, Mom, U, ep);
@ -216,6 +234,16 @@ public:
    //Default the momentum filter to "do-nothing"
    MomFilter = getDefaultMomFilter();
    for (int level = 0; level < as.size(); ++level) {
      int multiplier = as.at(level).multiplier;
      ActionLevel<Field, RepresentationPolicy> * Level = new ActionLevel<Field, RepresentationPolicy>(multiplier);
      Level->push_back(new EmptyAction<Field>); 
      LevelForces.push_back(*Level);
      // does it copy by value or reference??
      // - answer it copies by value, BUT the action level contains a reference that is NOT updated.
      // Unsafe code in Guido's area
    }
  };
  virtual ~Integrator() {}
@ -233,10 +261,14 @@ public:
  void reset_timer(void)
  {
    assert(as.size()==LevelForces.size());
    for (int level = 0; level < as.size(); ++level) {
      for (int actionID = 0; actionID < as[level].actions.size(); ++actionID) {
        as[level].actions.at(actionID)->reset_timer();
      }
      int actionID=0;
      assert(LevelForces.at(level).actions.size()==1);
      LevelForces.at(level).actions.at(actionID)->reset_timer();
    }
  }
  void print_timer(void)
@ -298,6 +330,16 @@ public:
 		  <<" calls "     << as[level].actions.at(actionID)->deriv_num
 		  << std::endl;
      }
      int actionID=0;
      std::cout << GridLogMessage 
 		  << LevelForces[level].actions.at(actionID)->action_name()
 		  <<"["<<level<<"]["<< actionID<<"] :\n\t\t "
 		  <<" force max " << LevelForces[level].actions.at(actionID)->deriv_max_average()
 		  <<" norm "      << LevelForces[level].actions.at(actionID)->deriv_norm_average()
 		  <<" Fdt max  "  << LevelForces[level].actions.at(actionID)->Fdt_max_average()
 		  <<" Fdt norm "  << LevelForces[level].actions.at(actionID)->Fdt_norm_average()
 		  <<" calls "     << LevelForces[level].actions.at(actionID)->deriv_num
 		  << std::endl;
    }
    std::cout << GridLogMessage << ":::::::::::::::::::::::::::::::::::::::::"<< std::endl;
  }
@ -319,6 +361,13 @@ public:
 	std::cout << as[level].actions.at(actionID)->LogParameters();
      }
    }
    std::cout << " [Integrator] Total Force loggers: "<< LevelForces.size() <<std::endl;
    for (int level = 0; level < LevelForces.size(); ++level) {
      std::cout << GridLogMessage << "[Integrator] ---- Level: "<< level << std::endl;
      for (int actionID = 0; actionID < LevelForces[level].actions.size(); ++actionID) {
 	std::cout << GridLogMessage << "["<< LevelForces[level].actions.at(actionID)->action_name() << "] ID: " << actionID << std::endl;
      }
    }
    std::cout << GridLogMessage << ":::::::::::::::::::::::::::::::::::::::::"<< std::endl;
  }
@ -400,6 +449,7 @@ public:
  RealD S(Field& U) 
  {  // here also U not used
    assert(as.size()==LevelForces.size());
    std::cout << GridLogIntegrator << "Integrator action\n";
    RealD H = - FieldImplementation::FieldSquareNorm(P)/HMC_MOMENTUM_DENOMINATOR; // - trace (P*P)/denom
--- a/Grid/qcd/representations/fundamental.h
+++ b/Grid/qcd/representations/fundamental.h
@ -13,7 +13,7 @@ NAMESPACE_BEGIN(Grid);
 * Empty since HMC updates already the fundamental representation 
 */
-template <int ncolour>
+template <int ncolour, class group_name>
 class FundamentalRep {
 public:
  static const int Dimension = ncolour;
@ -21,7 +21,7 @@ public:
  // typdef to be used by the Representations class in HMC to get the
  // types for the higher representation fields
-  typedef typename SU<ncolour>::LatticeMatrix LatticeMatrix;
+  typedef typename GaugeGroup<ncolour,group_name>::LatticeMatrix LatticeMatrix;
  typedef LatticeGaugeField LatticeField;
  explicit FundamentalRep(GridBase* grid) {} //do nothing
@ -45,7 +45,8 @@ public:
-typedef	 FundamentalRep<Nc> FundamentalRepresentation;
+typedef	 FundamentalRep<Nc,GroupName::SU> FundamentalRepresentation;
 typedef	 FundamentalRep<Nc,GroupName::Sp> SpFundamentalRepresentation;
 NAMESPACE_END(Grid);  
--- a/Grid/qcd/representations/two_index.h
+++ b/Grid/qcd/representations/two_index.h
@ -20,14 +20,14 @@ NAMESPACE_BEGIN(Grid);
 * in the SUnTwoIndex.h file
 */
-template <int ncolour, TwoIndexSymmetry S>
+template <int ncolour, TwoIndexSymmetry S, class group_name = GroupName::SU>
 class TwoIndexRep {
 public:
  // typdef to be used by the Representations class in HMC to get the
  // types for the higher representation fields
-  typedef typename SU_TwoIndex<ncolour, S>::LatticeTwoIndexMatrix LatticeMatrix;
+  typedef typename GaugeGroupTwoIndex<ncolour, S, group_name>::LatticeTwoIndexMatrix LatticeMatrix;
-  typedef typename SU_TwoIndex<ncolour, S>::LatticeTwoIndexField LatticeField;
+  typedef typename GaugeGroupTwoIndex<ncolour, S, group_name>::LatticeTwoIndexField LatticeField;
-  static const int Dimension = ncolour * (ncolour + S) / 2;
+  static const int Dimension = GaugeGroupTwoIndex<ncolour,S,group_name>::Dimension;
  static const bool isFundamental = false;
  LatticeField U;
@ -43,10 +43,10 @@ public:
    U = Zero();
    LatticeColourMatrix tmp(Uin.Grid());
-    Vector<typename SU<ncolour>::Matrix> eij(Dimension);
+    Vector<typename GaugeGroup<ncolour,group_name>::Matrix> eij(Dimension);
    for (int a = 0; a < Dimension; a++)
-      SU_TwoIndex<ncolour, S>::base(a, eij[a]);
+      GaugeGroupTwoIndex<ncolour, S, group_name>::base(a, eij[a]);
    for (int mu = 0; mu < Nd; mu++) {
      auto Uin_mu = peekLorentz(Uin, mu);
@ -71,7 +71,7 @@ public:
      out_mu = Zero();
-      typename SU<ncolour>::LatticeAlgebraVector h(in.Grid());
+      typename GaugeGroup<ncolour, group_name>::LatticeAlgebraVector h(in.Grid());
      projectOnAlgebra(h, in_mu, double(Nc + 2 * S));  // factor T(r)/T(fund)
      FundamentalLieAlgebraMatrix(h, out_mu);          // apply scale only once
      pokeLorentz(out, out_mu, mu);
@ -80,20 +80,23 @@ public:
  }
 private:
-  void projectOnAlgebra(typename SU<ncolour>::LatticeAlgebraVector &h_out,
+  void projectOnAlgebra(typename GaugeGroup<ncolour, group_name>::LatticeAlgebraVector &h_out,
                        const LatticeMatrix &in, Real scale = 1.0) const {
-    SU_TwoIndex<ncolour, S>::projectOnAlgebra(h_out, in, scale);
+    GaugeGroupTwoIndex<ncolour, S,group_name>::projectOnAlgebra(h_out, in, scale);
  }
  void FundamentalLieAlgebraMatrix(
-				   typename SU<ncolour>::LatticeAlgebraVector &h,
+				   typename GaugeGroup<ncolour, group_name>::LatticeAlgebraVector &h,
-				   typename SU<ncolour>::LatticeMatrix &out, Real scale = 1.0) const {
+				   typename GaugeGroup<ncolour, group_name>::LatticeMatrix &out, Real scale = 1.0) const {
-    SU<ncolour>::FundamentalLieAlgebraMatrix(h, out, scale);
+    GaugeGroup<ncolour,group_name>::FundamentalLieAlgebraMatrix(h, out, scale);
  }
 };
-typedef TwoIndexRep<Nc, Symmetric> TwoIndexSymmetricRepresentation;
+typedef TwoIndexRep<Nc, Symmetric, GroupName::SU> TwoIndexSymmetricRepresentation;
-typedef TwoIndexRep<Nc, AntiSymmetric> TwoIndexAntiSymmetricRepresentation;
+typedef TwoIndexRep<Nc, AntiSymmetric, GroupName::SU> TwoIndexAntiSymmetricRepresentation;
 typedef TwoIndexRep<Nc, Symmetric, GroupName::Sp> SpTwoIndexSymmetricRepresentation;
 typedef TwoIndexRep<Nc, AntiSymmetric, GroupName::Sp> SpTwoIndexAntiSymmetricRepresentation;
 NAMESPACE_END(Grid);
--- a/Grid/qcd/smearing/GaugeConfigurationMasked.h
+++ b/Grid/qcd/smearing/GaugeConfigurationMasked.h
@ -1,3 +1,4 @@
 /*!
  @file GaugeConfiguration.h
  @brief Declares the GaugeConfiguration class
@ -6,6 +7,15 @@
 NAMESPACE_BEGIN(Grid);
 template<class T> void Dump(const Lattice<T> & lat,
 			    std::string s,
 			    Coordinate site = Coordinate({0,0,0,0}))
 {
  typename T::scalar_object tmp;
  peekSite(tmp,lat,site);
  std::cout << " Dump "<<s<<" "<<tmp<<std::endl;
 }
 /*!
  @brief Smeared configuration masked container
  Modified for a multi-subset smearing (aka Luscher Flowed HMC)
@ -28,6 +38,101 @@ private:
  typedef typename SU3Adjoint::LatticeAdjMatrix  AdjMatrixField;
  typedef typename SU3Adjoint::LatticeAdjVector  AdjVectorField;
  void BaseSmearDerivative(GaugeField& SigmaTerm,
 			   const GaugeField& iLambda,
 			   const GaugeField& U,
 			   int mmu, RealD rho)
  {
    // Reference
    // Morningstar, Peardon, Phys.Rev.D69,054501(2004)
    // Equation 75
    // Computing Sigma_mu, derivative of S[fat links] with respect to the thin links
    // Output SigmaTerm
    GridBase *grid = U.Grid();
    WilsonLoops<Gimpl> WL;
    GaugeLinkField staple(grid), u_tmp(grid);
    GaugeLinkField iLambda_mu(grid), iLambda_nu(grid);
    GaugeLinkField U_mu(grid), U_nu(grid);
    GaugeLinkField sh_field(grid), temp_Sigma(grid);
    Real rho_munu, rho_numu;
    rho_munu = rho;
    rho_numu = rho;
    for(int mu = 0; mu < Nd; ++mu){
      U_mu       = peekLorentz(      U, mu);
      iLambda_mu = peekLorentz(iLambda, mu);
      for(int nu = 0; nu < Nd; ++nu){
 	if(nu==mu) continue;
 	U_nu       = peekLorentz(      U, nu);
 	// Nd(nd-1) = 12 staples normally.
 	// We must compute 6 of these
 	// in FTHMC case
 	if ( (mu==mmu)||(nu==mmu) )
 	  WL.StapleUpper(staple, U, mu, nu);
 	if(nu==mmu) {
 	  iLambda_nu = peekLorentz(iLambda, nu);
 	  temp_Sigma = -rho_numu*staple*iLambda_nu;  //ok
 	  //-r_numu*U_nu(x+mu)*Udag_mu(x+nu)*Udag_nu(x)*Lambda_nu(x)
 	  Gimpl::AddLink(SigmaTerm, temp_Sigma, mu);
 	  sh_field = Cshift(iLambda_nu, mu, 1);// general also for Gparity?
 	  temp_Sigma = rho_numu*sh_field*staple; //ok
 	  //r_numu*Lambda_nu(mu)*U_nu(x+mu)*Udag_mu(x+nu)*Udag_nu(x)
 	  Gimpl::AddLink(SigmaTerm, temp_Sigma, mu);
 	}
 	if ( mu == mmu ) { 
 	  sh_field = Cshift(iLambda_mu, nu, 1);
 	  temp_Sigma = -rho_munu*staple*U_nu*sh_field*adj(U_nu); //ok
 	  //-r_munu*U_nu(x+mu)*Udag_mu(x+nu)*Lambda_mu(x+nu)*Udag_nu(x)
 	  Gimpl::AddLink(SigmaTerm, temp_Sigma, mu);
 	}
 	//	staple = Zero();
 	sh_field = Cshift(U_nu, mu, 1);
 	temp_Sigma = Zero();
 	if ( mu == mmu )
 	  temp_Sigma = -rho_munu*adj(sh_field)*adj(U_mu)*iLambda_mu*U_nu;
 	if ( nu == mmu ) {
 	  temp_Sigma += rho_numu*adj(sh_field)*adj(U_mu)*iLambda_nu*U_nu;
 	  u_tmp = adj(U_nu)*iLambda_nu;
 	  sh_field = Cshift(u_tmp, mu, 1);
 	  temp_Sigma += -rho_numu*sh_field*adj(U_mu)*U_nu;
 	}
 	sh_field = Cshift(temp_Sigma, nu, -1);
 	Gimpl::AddLink(SigmaTerm, sh_field, mu);
      }
    }
  }
  void BaseSmear(GaugeLinkField& Cup, const GaugeField& U,int mu,RealD rho) {
    GridBase *grid = U.Grid();
    GaugeLinkField tmp_stpl(grid);
    WilsonLoops<Gimpl> WL;
    Cup = Zero();
    for(int nu=0; nu<Nd; ++nu){
      if (nu != mu) {
 	// get the staple in direction mu, nu
 	WL.Staple(tmp_stpl, U, mu, nu);  //nb staple conventions of IroIro and Grid differ by a dagger
 	Cup += adj(tmp_stpl*rho);
      }
    }
  }
  // Adjoint vector to GaugeField force
  void InsertForce(GaugeField &Fdet,AdjVectorField &Fdet_nu,int nu)
  {
@ -47,27 +152,54 @@ private:
    GaugeLinkField UtaU(PlaqL.Grid());
    GaugeLinkField D(PlaqL.Grid());
    AdjMatrixField Dbc(PlaqL.Grid());
    AdjMatrixField Dbc_opt(PlaqL.Grid());
    LatticeComplex tmp(PlaqL.Grid());
    const int Ngen = SU3Adjoint::Dimension;
    Complex ci(0,1);
    ColourMatrix   ta,tb,tc;
-    
+    RealD t=0;
    RealD tp=0;
    RealD tta=0;
    RealD tpk=0;
    t-=usecond();
    for(int a=0;a<Ngen;a++) {
      tta-=usecond();
      SU3::generator(a, ta);
      ta = 2.0 * ci * ta;
      // Qlat Tb = 2i Tb^Grid
-      UtaU= 2.0*ci*adj(PlaqL)*ta*PlaqR;
+      UtaU= adj(PlaqL)*ta*PlaqR; // 6ms
      tta+=usecond();
      ////////////////////////////////////////////
      // Could add this entire C-loop to a projection routine
      // for performance. Could also pick checkerboard on UtaU
      // and set checkerboard on result for 2x perf
      ////////////////////////////////////////////
      for(int c=0;c<Ngen;c++) {
 	SU3::generator(c, tc);
-	D = Ta( (2.0)*ci*tc *UtaU);
+	tc = 2.0*ci*tc;
 	tp-=usecond(); 
 	D = Ta( tc *UtaU); // 2ms
 #if 1
 	SU3::LieAlgebraProject(Dbc_opt,D,c); // 5.5ms
 #else
 	for(int b=0;b<Ngen;b++){
 	  SU3::generator(b, tb);
 	  tmp =-trace(ci*tb*D); 
 	  PokeIndex<ColourIndex>(Dbc,tmp,b,c);  // Adjoint rep
 	}
 #endif
 	tp+=usecond();
      }
-      tmp = trace(MpInvJx * Dbc);
+      //      Dump(Dbc_opt,"Dbc_opt");
      //      Dump(Dbc,"Dbc");
      tpk-=usecond();
      tmp = trace(MpInvJx * Dbc_opt);
      PokeIndex<ColourIndex>(Fdet2,tmp,a);
      tpk+=usecond();
    }
    t+=usecond();
    std::cout << GridLogPerformance << " Compute_MpInvJx_dNxxdSy " << t/1e3 << " ms  proj "<<tp/1e3<< " ms"
 	      << " ta "<<tta/1e3<<" ms" << " poke "<<tpk/1e3<< " ms"<<std::endl;
  }
  void ComputeNxy(const GaugeLinkField &PlaqL,const GaugeLinkField &PlaqR,AdjMatrixField &NxAd)
@ -79,12 +211,17 @@ private:
    ColourMatrix   tc;
    for(int b=0;b<Ngen;b++) {
      SU3::generator(b, tb);
-      Nx = (2.0)*Ta( adj(PlaqL)*ci*tb * PlaqR );
+      tb = 2.0 * ci * tb;
      Nx = Ta( adj(PlaqL)*tb * PlaqR );
 #if 1
      SU3::LieAlgebraProject(NxAd,Nx,b);
 #else
      for(int c=0;c<Ngen;c++) {
 	SU3::generator(c, tc);
 	auto tmp =closure( -trace(ci*tc*Nx)); 
 	PokeIndex<ColourIndex>(NxAd,tmp,c,b); 
      }
 #endif
    }
  }
  void ApplyMask(GaugeField &U,int smr)
@ -164,8 +301,7 @@ public:
    // Computes ALL the staples -- could compute one only and do it here
    RealD time;
    time=-usecond();
-    this->StoutSmearing->BaseSmear(C, U);
+    BaseSmear(Cmu, U,mu,rho);
    Cmu = peekLorentz(C, mu);
    //////////////////////////////////////////////////////////////////
    // Assemble Luscher exp diff map J matrix 
@ -209,6 +345,36 @@ public:
    // dJ(x)/dxe
    //////////////////////////////////////
    time=-usecond();
 #if 1
    std::vector<AdjMatrixField>  dJdX;    dJdX.resize(8,grid);
    std::vector<AdjMatrix> TRb_s; TRb_s.resize(8);
    AdjMatrixField tbXn(grid);
    AdjMatrixField sumXtbX(grid);
    AdjMatrixField t2(grid);
    AdjMatrixField dt2(grid);
    AdjMatrixField t3(grid);
    AdjMatrixField dt3(grid);
    AdjMatrixField aunit(grid);
    for(int b=0;b<8;b++){
      SU3Adjoint::generator(b, TRb_s[b]);
      dJdX[b] = TRb_s[b];
    }
    aunit = ComplexD(1.0);
    // Could put into an accelerator_for
    X  = (-1.0)*ZxAd; 
    t2 = X;
    for (int j = 12; j > 1; --j) {
      t3  = t2*(1.0 / (j + 1))  + aunit;
      t2  = X * t3;
      for(int b=0;b<8;b++){
 	dJdX[b]= TRb_s[b] * t3 + X * dJdX[b]*(1.0 / (j + 1));
      }
    }
    for(int b=0;b<8;b++){
      dJdX[b] = -dJdX[b];
    }
 #else
    std::vector<AdjMatrixField>  dJdX;    dJdX.resize(8,grid);
    AdjMatrixField tbXn(grid);
    AdjMatrixField sumXtbX(grid);
@ -224,14 +390,15 @@ public:
      X  = (-1.0)*ZxAd; 
      t2 = X;
      dt2 = TRb;
-      for (int j = 20; j > 1; --j) {
+      for (int j = 12; j > 1; --j) {
-	t3 = t2*(1.0 / (j + 1))  + aunit;
+	t3  = t2*(1.0 / (j + 1))  + aunit;
 	dt3 = dt2*(1.0 / (j + 1));
 	t2 = X * t3;
 	dt2 = TRb * t3 + X * dt3;
      }
      dJdX[b] = -dt2; 
    }
 #endif  
    time+=usecond();
    std::cout << GridLogMessage << "dJx took "<<time<< " us"<<std::endl;
    /////////////////////////////////////////////////////////////////
@ -281,8 +448,8 @@ public:
    for(int e =0 ; e<8 ; e++){
      LatticeComplexD tr(grid);
-      ColourMatrix te;
+      //      ColourMatrix te;
-      SU3::generator(e, te);
+      //      SU3::generator(e, te);
      tr = trace(dJdX[e] * nMpInv);
      pokeColour(dJdXe_nMpInv,tr,e);
    }
@ -493,20 +660,25 @@ public:
    //////////////////////////////////////////////////////////////////
    // Assemble the N matrix
    //////////////////////////////////////////////////////////////////
-    // Computes ALL the staples -- could compute one only here
+    double rho=this->StoutSmearing->SmearRho[1];
-    this->StoutSmearing->BaseSmear(C, U);
+    BaseSmear(Cmu, U,mu,rho);
-    Cmu = peekLorentz(C, mu);
+
    Umu = peekLorentz(U, mu);
    Complex ci(0,1);
    for(int b=0;b<Ngen;b++) {
      SU3::generator(b, Tb);
      // Qlat Tb = 2i Tb^Grid
      Nb = (2.0)*Ta( ci*Tb * Umu * adj(Cmu));
      // FIXME -- replace this with LieAlgebraProject
 #if 0
      SU3::LieAlgebraProject(Ncb,tmp,b);
 #else
      for(int c=0;c<Ngen;c++) {
 	SU3::generator(c, Tc);
 	auto tmp = -trace(ci*Tc*Nb); // Luchang's norm: (2Tc) (2Td) N^db = -2 delta cd N^db // - was important
 	PokeIndex<ColourIndex>(Ncb,tmp,c,b); 
      }
 #endif
    }      
    //////////////////////////////////////////////////////////////////
@ -693,15 +865,19 @@ private:
 					  const GaugeField& GaugeK,int level) 
  {
    GridBase* grid = GaugeK.Grid();
-    GaugeField C(grid), SigmaK(grid), iLambda(grid);
+    GaugeField SigmaK(grid), iLambda(grid);
    GaugeField SigmaKPrimeA(grid);
    GaugeField SigmaKPrimeB(grid);
    GaugeLinkField iLambda_mu(grid);
    GaugeLinkField iQ(grid), e_iQ(grid);
    GaugeLinkField SigmaKPrime_mu(grid);
    GaugeLinkField GaugeKmu(grid), Cmu(grid);
-    
+
-    this->StoutSmearing->BaseSmear(C, GaugeK);
+    int mmu= (level/2) %Nd;
    int cb= (level%2);
    double rho=this->StoutSmearing->SmearRho[1];
    // Can override this to do one direction only.
    SigmaK = Zero();
    iLambda = Zero();
@ -712,18 +888,38 @@ private:
    // Could get away with computing only one polarisation here
    // int mu= (smr/2) %Nd;
    // SigmaKprime_A has only one component
-    for (int mu = 0; mu < Nd; mu++)
+#if 0
    BaseSmear(Cmu, GaugeK,mu,rho);
    GaugeKmu = peekLorentz(GaugeK, mu);
    SigmaKPrime_mu = peekLorentz(SigmaKPrimeA, mu);
    iQ = Ta(Cmu * adj(GaugeKmu));
    this->set_iLambda(iLambda_mu, e_iQ, iQ, SigmaKPrime_mu, GaugeKmu);
    pokeLorentz(SigmaK, SigmaKPrime_mu * e_iQ + adj(Cmu) * iLambda_mu, mu);
    pokeLorentz(iLambda, iLambda_mu, mu);
    BaseSmearDerivative(SigmaK, iLambda,GaugeK,mu,rho);  // derivative of SmearBase
 #else
    //    GaugeField C(grid);
    //    this->StoutSmearing->BaseSmear(C, GaugeK);
    //    for (int mu = 0; mu < Nd; mu++)
    int mu =mmu;
    BaseSmear(Cmu, GaugeK,mu,rho);
    {
-      Cmu = peekLorentz(C, mu);
+      // Cmu = peekLorentz(C, mu);
      GaugeKmu = peekLorentz(GaugeK, mu);
      SigmaKPrime_mu = peekLorentz(SigmaKPrimeA, mu);
      iQ = Ta(Cmu * adj(GaugeKmu));
      this->set_iLambda(iLambda_mu, e_iQ, iQ, SigmaKPrime_mu, GaugeKmu);
      pokeLorentz(SigmaK, SigmaKPrime_mu * e_iQ + adj(Cmu) * iLambda_mu, mu);
      pokeLorentz(iLambda, iLambda_mu, mu);
      std::cout << " mu "<<mu<<" SigmaKPrime_mu"<<norm2(SigmaKPrime_mu)<< " iLambda_mu " <<norm2(iLambda_mu)<<std::endl;
    }
-    this->StoutSmearing->derivative(SigmaK, iLambda,GaugeK);  // derivative of SmearBase
+    //    GaugeField SigmaKcopy(grid);
-
+    //    SigmaKcopy = SigmaK;
    BaseSmearDerivative(SigmaK, iLambda,GaugeK,mu,rho);  // derivative of SmearBase
    //    this->StoutSmearing->derivative(SigmaK, iLambda,GaugeK);  // derivative of SmearBase
    //    SigmaKcopy = SigmaKcopy - SigmaK;
    //    std::cout << " BaseSmearDerivative fast path error" <<norm2(SigmaKcopy)<<std::endl;
 #endif
    ////////////////////////////////////////////////////////////////////////////////////
    // propagate the rest of the force as identity map, just add back
    ////////////////////////////////////////////////////////////////////////////////////
--- a/Grid/qcd/smearing/HISQSmearing.h
+++ b/Grid/qcd/smearing/HISQSmearing.h
@ -0,0 +1,389 @@
 /*************************************************************************************
 Grid physics library, www.github.com/paboyle/Grid
 Source file: ./lib/qcd/smearing/HISQSmearing.h
 Copyright (C) 2023
 Author: D. A. Clarke <clarke.davida@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
 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
 *************************************************************************************/
 /*
    @file HISQSmearing.h
    @brief Declares classes related to HISQ smearing 
 */
 #pragma once
 #include <Grid/Grid.h>
 #include <Grid/lattice/PaddedCell.h>
 #include <Grid/stencil/GeneralLocalStencil.h>
 NAMESPACE_BEGIN(Grid);
 // TODO: find a way to fold this into the stencil header. need to access grid to get
 // Nd, since you don't want to inherit from QCD.h
 /*!  @brief append arbitrary shift path to shifts */
 template<typename... Args>
 void appendShift(std::vector<Coordinate>& shifts, int dir, Args... args) {
    Coordinate shift(Nd,0);
    generalShift(shift, dir, args...); 
    // push_back creates an element at the end of shifts and
    // assigns the data in the argument to it.
    shifts.push_back(shift);
 }
 /*!  @brief figure out the stencil index from mu and nu */
 accelerator_inline int stencilIndex(int mu, int nu) {
    // Nshifts depends on how you built the stencil
    int Nshifts = 6;
    return Nshifts*nu + Nd*Nshifts*mu;
 }
 /*!  @brief structure holding the link treatment */
 struct SmearingParameters{
    SmearingParameters(){}
    Real c_1;               // 1 link
    Real c_naik;            // Naik term
    Real c_3;               // 3 link
    Real c_5;               // 5 link
    Real c_7;               // 7 link
    Real c_lp;              // 5 link Lepage
    SmearingParameters(Real c1, Real cnaik, Real c3, Real c5, Real c7, Real clp) 
        : c_1(c1),
          c_naik(cnaik),
          c_3(c3),
          c_5(c5),
          c_7(c7),
          c_lp(clp){}
 };
 /*!  @brief create fat links from link variables */
 template<class Gimpl> 
 class Smear_HISQ : public Gimpl {
 private:
    GridCartesian* const _grid;
    SmearingParameters _linkTreatment;
 public:
    INHERIT_GIMPL_TYPES(Gimpl);
    typedef typename Gimpl::GaugeField     GF;
    typedef typename Gimpl::GaugeLinkField LF;
    typedef typename Gimpl::ComplexField   CF;
    // Don't allow default values here.
    Smear_HISQ(GridCartesian* grid, Real c1, Real cnaik, Real c3, Real c5, Real c7, Real clp) 
        : _grid(grid), 
          _linkTreatment(c1,cnaik,c3,c5,c7,clp) {
        assert(Nc == 3 && "HISQ smearing currently implemented only for Nc==3");
        assert(Nd == 4 && "HISQ smearing only defined for Nd==4");
    }
    // Allow to pass a pointer to a C-style, double array for MILC convenience
    Smear_HISQ(GridCartesian* grid, double* coeff) 
        : _grid(grid), 
          _linkTreatment(coeff[0],coeff[1],coeff[2],coeff[3],coeff[4],coeff[5]) {
        assert(Nc == 3 && "HISQ smearing currently implemented only for Nc==3");
        assert(Nd == 4 && "HISQ smearing only defined for Nd==4");
    }
    ~Smear_HISQ() {}
    // Intent: OUT--u_smr, u_naik
    //          IN--u_thin
    void smear(GF& u_smr, GF& u_naik, GF& u_thin) const {
        SmearingParameters lt = this->_linkTreatment;
        auto grid = this->_grid;
        // Create a padded cell of extra padding depth=1 and fill the padding.
        int depth = 1;
        PaddedCell Ghost(depth,grid);
        GF Ughost = Ghost.Exchange(u_thin);
        // This is where auxiliary N-link fields and the final smear will be stored. 
        GF Ughost_fat(Ughost.Grid());
        GF Ughost_3link(Ughost.Grid());
        GF Ughost_5linkA(Ughost.Grid());
        GF Ughost_5linkB(Ughost.Grid());
        // mu-nu plane stencil. We allow mu==nu to make indexing the stencil easier,
        // but these entries will not be used. 
        std::vector<Coordinate> shifts;
        for(int mu=0;mu<Nd;mu++)
        for(int nu=0;nu<Nd;nu++) {
            appendShift(shifts,mu);
            appendShift(shifts,nu);
            appendShift(shifts,shiftSignal::NO_SHIFT);
            appendShift(shifts,mu,Back(nu));
            appendShift(shifts,Back(nu));
            appendShift(shifts,Back(mu));
        }
        // A GeneralLocalStencil has two indices: a site and stencil index 
        GeneralLocalStencil gStencil(Ughost.Grid(),shifts);
        // This is where contributions from the smearing get added together
        Ughost_fat=Zero();
        // This loop handles 3-, 5-, and 7-link constructs, minus Lepage and Naik.
        for(int mu=0;mu<Nd;mu++) {
            // TODO: This approach is slightly memory inefficient. It uses 25% extra memory 
            Ughost_3link =Zero();
            Ughost_5linkA=Zero();
            Ughost_5linkB=Zero();
            // Create the accessors
            autoView(U_v       , Ughost       , AcceleratorRead);
            autoView(U_fat_v   , Ughost_fat   , AcceleratorWrite);
            autoView(U_3link_v , Ughost_3link , AcceleratorWrite);
            autoView(U_5linkA_v, Ughost_5linkA, AcceleratorWrite);
            autoView(U_5linkB_v, Ughost_5linkB, AcceleratorWrite);
            // We infer some types that will be needed in the calculation.
            typedef decltype(gStencil.GetEntry(0,0)) stencilElement;
            typedef decltype(coalescedReadGeneralPermute(U_v[0](0),gStencil.GetEntry(0,0)->_permute,Nd)) U3matrix;
            int Nsites = U_v.size();
            auto gStencil_v = gStencil.View(); 
            accelerator_for(site,Nsites,Simd::Nsimd(),{ // ----------- 3-link constructs
                stencilElement SE0, SE1, SE2, SE3, SE4, SE5;
                U3matrix U0, U1, U2, U3, U4, U5, W;
                for(int nu=0;nu<Nd;nu++) {
                    if(nu==mu) continue;
                    int s = stencilIndex(mu,nu);
                    // The stencil gives us support points in the mu-nu plane that we will use to
                    // grab the links we need.
                    SE0 = gStencil_v.GetEntry(s+0,site); int x_p_mu      = SE0->_offset;
                    SE1 = gStencil_v.GetEntry(s+1,site); int x_p_nu      = SE1->_offset;
                    SE2 = gStencil_v.GetEntry(s+2,site); int x           = SE2->_offset;
                    SE3 = gStencil_v.GetEntry(s+3,site); int x_p_mu_m_nu = SE3->_offset;
                    SE4 = gStencil_v.GetEntry(s+4,site); int x_m_nu      = SE4->_offset;
                    SE5 = gStencil_v.GetEntry(s+5,site); int x_m_mu      = SE5->_offset;
                    // When you're deciding whether to take an adjoint, the question is: how is the
                    // stored link oriented compared to the one you want? If I imagine myself travelling
                    // with the to-be-updated link, I have two possible, alternative 3-link paths I can
                    // take, one starting by going to the left, the other starting by going to the right.
                    U0 = coalescedReadGeneralPermute(U_v[x_p_mu     ](nu),SE0->_permute,Nd);
                    U1 = coalescedReadGeneralPermute(U_v[x_p_nu     ](mu),SE1->_permute,Nd);
                    U2 = coalescedReadGeneralPermute(U_v[x          ](nu),SE2->_permute,Nd);
                    U3 = coalescedReadGeneralPermute(U_v[x_p_mu_m_nu](nu),SE3->_permute,Nd);
                    U4 = coalescedReadGeneralPermute(U_v[x_m_nu     ](mu),SE4->_permute,Nd);
                    U5 = coalescedReadGeneralPermute(U_v[x_m_nu     ](nu),SE4->_permute,Nd);
                    //  "left"          "right"
                    W = U2*U1*adj(U0) + adj(U5)*U4*U3;
                    // Save 3-link construct for later and add to smeared field.
                    coalescedWrite(U_3link_v[x](nu), W);
                    // The index operator (x) returns the coalesced read on GPU. The view [] index returns 
                    // a reference to the vector object. The [x](mu) returns a reference to the densely 
                    // packed (contiguous in memory) mu-th element of the vector object. On CPU, 
                    // coalescedRead/Write is the identity mapping assigning vector object to vector object.
                    // But on GPU it's non-trivial and maps scalar object to vector object and vice versa.
                    coalescedWrite(U_fat_v[x](mu), U_fat_v(x)(mu) + lt.c_3*W);
                }
            })
            accelerator_for(site,Nsites,Simd::Nsimd(),{ // ----------- 5-link 
                stencilElement SE0, SE1, SE2, SE3, SE4, SE5;
                U3matrix U0, U1, U2, U3, U4, U5, W;
                int sigmaIndex = 0;
                for(int nu=0;nu<Nd;nu++) {
                    if(nu==mu) continue;
                    int s = stencilIndex(mu,nu);
                    for(int rho=0;rho<Nd;rho++) {
                        if (rho == mu || rho == nu) continue;
                        SE0 = gStencil_v.GetEntry(s+0,site); int x_p_mu      = SE0->_offset;
                        SE1 = gStencil_v.GetEntry(s+1,site); int x_p_nu      = SE1->_offset;
                        SE2 = gStencil_v.GetEntry(s+2,site); int x           = SE2->_offset;
                        SE3 = gStencil_v.GetEntry(s+3,site); int x_p_mu_m_nu = SE3->_offset;
                        SE4 = gStencil_v.GetEntry(s+4,site); int x_m_nu      = SE4->_offset;
                        U0 = coalescedReadGeneralPermute(      U_v[x_p_mu     ](nu ),SE0->_permute,Nd);
                        U1 = coalescedReadGeneralPermute(U_3link_v[x_p_nu     ](rho),SE1->_permute,Nd);
                        U2 = coalescedReadGeneralPermute(      U_v[x          ](nu ),SE2->_permute,Nd);
                        U3 = coalescedReadGeneralPermute(      U_v[x_p_mu_m_nu](nu ),SE3->_permute,Nd);
                        U4 = coalescedReadGeneralPermute(U_3link_v[x_m_nu     ](rho),SE4->_permute,Nd);
                        U5 = coalescedReadGeneralPermute(      U_v[x_m_nu     ](nu ),SE4->_permute,Nd);
                        W  = U2*U1*adj(U0) + adj(U5)*U4*U3;
                        if(sigmaIndex<3) {
                            coalescedWrite(U_5linkA_v[x](rho), W);
                        } else {
                            coalescedWrite(U_5linkB_v[x](rho), W);
                        }    
                        coalescedWrite(U_fat_v[x](mu), U_fat_v(x)(mu) + lt.c_5*W);
                        sigmaIndex++;
                    }
                }
            })
            accelerator_for(site,Nsites,Simd::Nsimd(),{ // ----------- 7-link
                stencilElement SE0, SE1, SE2, SE3, SE4, SE5;
                U3matrix U0, U1, U2, U3, U4, U5, W;
                int sigmaIndex = 0;
                for(int nu=0;nu<Nd;nu++) {
                    if(nu==mu) continue;
                    int s = stencilIndex(mu,nu);
                    for(int rho=0;rho<Nd;rho++) {
                        if (rho == mu || rho == nu) continue;
                        SE0 = gStencil_v.GetEntry(s+0,site); int x_p_mu      = SE0->_offset;
                        SE1 = gStencil_v.GetEntry(s+1,site); int x_p_nu      = SE1->_offset;
                        SE2 = gStencil_v.GetEntry(s+2,site); int x           = SE2->_offset;
                        SE3 = gStencil_v.GetEntry(s+3,site); int x_p_mu_m_nu = SE3->_offset;
                        SE4 = gStencil_v.GetEntry(s+4,site); int x_m_nu      = SE4->_offset;
                        U0 = coalescedReadGeneralPermute(U_v[x_p_mu](nu),SE0->_permute,Nd);
                        if(sigmaIndex<3) {
                            U1 = coalescedReadGeneralPermute(U_5linkB_v[x_p_nu](rho),SE1->_permute,Nd);
                        } else {
                            U1 = coalescedReadGeneralPermute(U_5linkA_v[x_p_nu](rho),SE1->_permute,Nd);
                        }  
                        U2 = coalescedReadGeneralPermute(U_v[x](nu),SE2->_permute,Nd);
                        U3 = coalescedReadGeneralPermute(U_v[x_p_mu_m_nu](nu),SE3->_permute,Nd);
                        if(sigmaIndex<3) {
                            U4 = coalescedReadGeneralPermute(U_5linkB_v[x_m_nu](rho),SE4->_permute,Nd);
                        } else {
                            U4 = coalescedReadGeneralPermute(U_5linkA_v[x_m_nu](rho),SE4->_permute,Nd);
                        }  
                        U5 = coalescedReadGeneralPermute(U_v[x_m_nu](nu),SE4->_permute,Nd);
                        W  = U2*U1*adj(U0) + adj(U5)*U4*U3;
                        coalescedWrite(U_fat_v[x](mu), U_fat_v(x)(mu) + lt.c_7*W);
                        sigmaIndex++;
                    }
                }
            })
        } // end mu loop
        // c1, c3, c5, c7 construct contributions
        u_smr = Ghost.Extract(Ughost_fat) + lt.c_1*u_thin;
        // Load up U and V std::vectors to access thin and smeared links.
        std::vector<LF> U(Nd, grid);
        std::vector<LF> V(Nd, grid);
        std::vector<LF> Vnaik(Nd, grid);
        for (int mu = 0; mu < Nd; mu++) {
            U[mu] = PeekIndex<LorentzIndex>(u_thin, mu);
            V[mu] = PeekIndex<LorentzIndex>(u_smr, mu);
        }
        for(int mu=0;mu<Nd;mu++) {
            // Naik
            Vnaik[mu] = lt.c_naik*Gimpl::CovShiftForward(U[mu],mu,
                                    Gimpl::CovShiftForward(U[mu],mu,
                                      Gimpl::CovShiftIdentityForward(U[mu],mu)));
            // LePage
            for (int nu_h=1;nu_h<Nd;nu_h++) {
                int nu=(mu+nu_h)%Nd;
                                // nu, nu, mu, Back(nu), Back(nu)
                V[mu] = V[mu] + lt.c_lp*Gimpl::CovShiftForward(U[nu],nu,
                                          Gimpl::CovShiftForward(U[nu],nu,
                                            Gimpl::CovShiftForward(U[mu],mu,
                                              Gimpl::CovShiftBackward(U[nu],nu,
                                                Gimpl::CovShiftIdentityBackward(U[nu],nu)))))
                                // Back(nu), Back(nu), mu, nu, nu
                              + lt.c_lp*Gimpl::CovShiftBackward(U[nu],nu,
                                          Gimpl::CovShiftBackward(U[nu],nu,
                                            Gimpl::CovShiftForward(U[mu],mu,
                                              Gimpl::CovShiftForward(U[nu],nu,
                                                Gimpl::CovShiftIdentityForward(U[nu],nu)))));
            }
        }
        // Put V back into u_smr.
        for (int mu = 0; mu < Nd; mu++) {
            PokeIndex<LorentzIndex>(u_smr , V[mu]    , mu);
            PokeIndex<LorentzIndex>(u_naik, Vnaik[mu], mu);
        }
    };
    // Intent: OUT--u_proj
    //          IN--u_mu
    void projectU3(GF& u_proj, GF& u_mu) const {
        auto grid = this->_grid;
        LF V(grid), Q(grid), sqrtQinv(grid), id_3(grid), diff(grid);
        CF c0(grid), c1(grid), c2(grid), g0(grid), g1(grid), g2(grid), S(grid), R(grid), theta(grid), 
           u(grid), v(grid), w(grid), den(grid), f0(grid), f1(grid), f2(grid);
        // Follow MILC 10.1103/PhysRevD.82.074501, eqs (B2-B3) and (C1-C8)
        for (int mu = 0; mu < Nd; mu++) {
            V  = PeekIndex<LorentzIndex>(u_mu, mu);
            Q  = adj(V)*V;
            c0 =        real(trace(Q));
            c1 = (1/2.)*real(trace(Q*Q));
            c2 = (1/3.)*real(trace(Q*Q*Q));
            S  = (1/3.)*c1-(1/18.)*c0*c0;
            if (norm2(S)<1e-28) {
                g0 = (1/3.)*c0; g1 = g0; g2 = g1;
            } else {
                R     = (1/2.)*c2-(1/3. )*c0*c1+(1/27.)*c0*c0*c0;
                theta = acos(R*pow(S,-1.5));
                g0    = (1/3.)*c0+2.*sqrt(S)*cos((1/3.)*theta-2*M_PI/3.);
                g1    = (1/3.)*c0+2.*sqrt(S)*cos((1/3.)*theta          );
                g2    = (1/3.)*c0+2.*sqrt(S)*cos((1/3.)*theta+2*M_PI/3.);
            }
 //            if (fabs(Q.determinant()/(g0*g1*g2)-1.0) > 1e-5) { SVD }
            u     = sqrt(g0) + sqrt(g1) + sqrt(g2);
            v     = sqrt(g0*g1) + sqrt(g0*g2) + sqrt(g1*g2);
            w     = sqrt(g0*g1*g2);
            den   = w*(u*v-w);
            f0    = (-w*(u*u+v)+u*v*v)/den;
            f1    = (-w-u*u*u+2.*u*v)/den;
            f2    = u/den;
            id_3  = 1.;
            sqrtQinv = f0*id_3 + f1*Q + f2*Q*Q;
            PokeIndex<LorentzIndex>(u_proj, V*sqrtQinv, mu);
        }
    };
 //    void derivative(const GaugeField& Gauge) const {
 //    };
 };
 NAMESPACE_END(Grid);
--- a/Grid/qcd/smearing/Smearing.h
+++ b/Grid/qcd/smearing/Smearing.h
@ -5,4 +5,5 @@
 #include <Grid/qcd/smearing/StoutSmearing.h>
 #include <Grid/qcd/smearing/GaugeConfiguration.h>
 #include <Grid/qcd/smearing/WilsonFlow.h>
 #include <Grid/qcd/smearing/HISQSmearing.h>
--- a/Grid/qcd/smearing/StoutSmearing.h
+++ b/Grid/qcd/smearing/StoutSmearing.h
@ -69,7 +69,7 @@ public:
  /*! Construct stout smearing object from explicitly specified rho matrix */
  Smear_Stout(const std::vector<double>& rho_)
    : OwnedBase{new Smear_APE<Gimpl>(rho_)}, SmearBase{OwnedBase.get()} {
-    std::cout << GridLogDebug << "Stout smearing constructor : Smear_Stout(const std::vector<double>& " << rho_ << " )" << std::endl
+    std::cout << GridLogDebug << "Stout smearing constructor : Smear_Stout(const std::vector<double>& " << rho_ << " )" << std::endl;
    assert(Nc == 3 && "Stout smearing currently implemented only for Nc==3");
    }
--- a/Grid/qcd/utils/CovariantCshift.h
+++ b/Grid/qcd/utils/CovariantCshift.h
@ -37,13 +37,14 @@ NAMESPACE_BEGIN(Grid);
 // Make these members of an Impl class for BC's.
 namespace PeriodicBC { 
-
+  //Out(x) = Link(x)*field(x+mu)
  template<class covariant,class gauge> Lattice<covariant> CovShiftForward(const Lattice<gauge> &Link, 
 									   int mu,
 									   const Lattice<covariant> &field)
  {
    return Link*Cshift(field,mu,1);// moves towards negative mu
  }
  //Out(x) = Link^dag(x-mu)*field(x-mu)
  template<class covariant,class gauge> Lattice<covariant> CovShiftBackward(const Lattice<gauge> &Link, 
 									    int mu,
 									    const Lattice<covariant> &field)
@ -52,19 +53,19 @@ namespace PeriodicBC {
    tmp = adj(Link)*field;
    return Cshift(tmp,mu,-1);// moves towards positive mu
  }
-
+  //Out(x) = Link^dag(x-mu)
  template<class gauge> Lattice<gauge>
  CovShiftIdentityBackward(const Lattice<gauge> &Link, int mu) 
  {
    return Cshift(adj(Link), mu, -1);
  }
-
+  //Out(x) = Link(x)
  template<class gauge> Lattice<gauge>
  CovShiftIdentityForward(const Lattice<gauge> &Link, int mu)
  {
    return Link;
  }
-
+  //Link(x) = Link(x+mu)
  template<class gauge> Lattice<gauge>
  ShiftStaple(const Lattice<gauge> &Link, int mu)
  {
--- a/Grid/qcd/utils/GaugeGroup.h
+++ b/Grid/qcd/utils/GaugeGroup.h
@ -0,0 +1,528 @@
 /*************************************************************************************
 Grid physics library, www.github.com/paboyle/Grid
 Source file: ./lib/qcd/utils/GaugeGroup.h
 Copyright (C) 2015
 Author: Azusa Yamaguchi <ayamaguc@staffmail.ed.ac.uk>
 Author: Peter Boyle <paboyle@ph.ed.ac.uk>
 Author: neo <cossu@post.kek.jp>
 Author: paboyle <paboyle@ph.ed.ac.uk>
 This program is free software; you can redistribute it and/or modify
 it under the terms of the GNU General Public License as published by
 the Free Software Foundation; either version 2 of the License, or
 (at your option) any later version.
 This program is distributed in the hope that it will be useful,
 but WITHOUT ANY WARRANTY; without even the implied warranty of
 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 GNU General Public License for more details.
 You should have received a copy of the GNU General Public License along
 with this program; if not, write to the Free Software Foundation, Inc.,
 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
 See the full license in the file "LICENSE" in the top level distribution
 directory
 *************************************************************************************/
 /*  END LEGAL */
 #ifndef QCD_UTIL_GAUGEGROUP_H
 #define QCD_UTIL_GAUGEGROUP_H
 // Important detail: nvcc requires all template parameters to have names.
 // This is the only reason why the second template parameter has a name.
 #define ONLY_IF_SU                                                       \
  typename dummy_name = group_name,                                      \
           typename named_dummy = std::enable_if_t <                                 \
                          std::is_same<dummy_name, group_name>::value && \
                      is_su<dummy_name>::value >
 #define ONLY_IF_Sp                                                       \
  typename dummy_name = group_name,                                      \
           typename named_dummy = std::enable_if_t <                                 \
                          std::is_same<dummy_name, group_name>::value && \
                      is_sp<dummy_name>::value >
 NAMESPACE_BEGIN(Grid);
 namespace GroupName {
 class SU {};
 class Sp {};
 }  // namespace GroupName
 template <typename group_name>
 struct is_su {
  static const bool value = false;
 };
 template <>
 struct is_su<GroupName::SU> {
  static const bool value = true;
 };
 template <typename group_name>
 struct is_sp {
  static const bool value = false;
 };
 template <>
 struct is_sp<GroupName::Sp> {
  static const bool value = true;
 };
 template <typename group_name>
 constexpr int compute_adjoint_dimension(int ncolour);
 template <>
 constexpr int compute_adjoint_dimension<GroupName::SU>(int ncolour) {
  return ncolour * ncolour - 1;
 }
 template <>
 constexpr int compute_adjoint_dimension<GroupName::Sp>(int ncolour) {
  return ncolour / 2 * (ncolour + 1);
 }
 template <int ncolour, class group_name>
 class GaugeGroup {
 public:
  static const int Dimension = ncolour;
  static const int AdjointDimension =
      compute_adjoint_dimension<group_name>(ncolour);
  static const int AlgebraDimension =
      compute_adjoint_dimension<group_name>(ncolour);
  template <typename vtype>
  using iSU2Matrix = iScalar<iScalar<iMatrix<vtype, 2> > >;
  template <typename vtype>
  using iGroupMatrix = iScalar<iScalar<iMatrix<vtype, ncolour> > >;
  template <typename vtype>
  using iAlgebraVector = iScalar<iScalar<iVector<vtype, AdjointDimension> > >;
  template <typename vtype>
  using iSUnAlgebraMatrix =
    iScalar<iScalar<iMatrix<vtype, AdjointDimension> > >;
  static int su2subgroups(void) { return su2subgroups(group_name()); }
  //////////////////////////////////////////////////////////////////////////////////////////////////
  // Types can be accessed as SU<2>::Matrix , SU<2>::vSUnMatrix,
  // SU<2>::LatticeMatrix etc...
  //////////////////////////////////////////////////////////////////////////////////////////////////
  typedef iGroupMatrix<Complex> Matrix;
  typedef iGroupMatrix<ComplexF> MatrixF;
  typedef iGroupMatrix<ComplexD> MatrixD;
  typedef iGroupMatrix<vComplex> vMatrix;
  typedef iGroupMatrix<vComplexF> vMatrixF;
  typedef iGroupMatrix<vComplexD> vMatrixD;
  // For the projectors to the algebra
  // these should be real...
  // keeping complex for consistency with the SIMD vector types
  typedef iAlgebraVector<Complex> AlgebraVector;
  typedef iAlgebraVector<ComplexF> AlgebraVectorF;
  typedef iAlgebraVector<ComplexD> AlgebraVectorD;
  typedef iAlgebraVector<vComplex> vAlgebraVector;
  typedef iAlgebraVector<vComplexF> vAlgebraVectorF;
  typedef iAlgebraVector<vComplexD> vAlgebraVectorD;
  typedef Lattice<vMatrix> LatticeMatrix;
  typedef Lattice<vMatrixF> LatticeMatrixF;
  typedef Lattice<vMatrixD> LatticeMatrixD;
  typedef Lattice<vAlgebraVector> LatticeAlgebraVector;
  typedef Lattice<vAlgebraVectorF> LatticeAlgebraVectorF;
  typedef Lattice<vAlgebraVectorD> LatticeAlgebraVectorD;
  typedef iSUnAlgebraMatrix<vComplex>  vAlgebraMatrix;
  typedef iSUnAlgebraMatrix<vComplexF> vAlgebraMatrixF;
  typedef iSUnAlgebraMatrix<vComplexD> vAlgebraMatrixD;
  typedef Lattice<vAlgebraMatrix>  LatticeAlgebraMatrix;
  typedef Lattice<vAlgebraMatrixF> LatticeAlgebraMatrixF;
  typedef Lattice<vAlgebraMatrixD> LatticeAlgebraMatrixD;
  typedef iSU2Matrix<Complex> SU2Matrix;
  typedef iSU2Matrix<ComplexF> SU2MatrixF;
  typedef iSU2Matrix<ComplexD> SU2MatrixD;
  typedef iSU2Matrix<vComplex> vSU2Matrix;
  typedef iSU2Matrix<vComplexF> vSU2MatrixF;
  typedef iSU2Matrix<vComplexD> vSU2MatrixD;
  typedef Lattice<vSU2Matrix> LatticeSU2Matrix;
  typedef Lattice<vSU2MatrixF> LatticeSU2MatrixF;
  typedef Lattice<vSU2MatrixD> LatticeSU2MatrixD;
  // Private implementation details are specified in the following files:
  // Grid/qcd/utils/SUn.impl
  // Grid/qcd/utils/SUn.impl
  // The public part of the interface follows below and refers to these
  // private member functions.
 #include <Grid/qcd/utils/SUn.impl.h>
 #include <Grid/qcd/utils/Sp2n.impl.h>
 public:
  template <class cplx>
  static void generator(int lieIndex, iGroupMatrix<cplx> &ta) {
    return generator(lieIndex, ta, group_name());
  }
  static accelerator_inline void su2SubGroupIndex(int &i1, int &i2, int su2_index) {
    return su2SubGroupIndex(i1, i2, su2_index, group_name());
  }
  static void testGenerators(void) { testGenerators(group_name()); }
  static void printGenerators(void) {
    for (int gen = 0; gen < AlgebraDimension; gen++) {
      Matrix ta;
      generator(gen, ta);
      std::cout << GridLogMessage << "Nc = " << ncolour << " t_" << gen
                << std::endl;
      std::cout << GridLogMessage << ta << std::endl;
    }
  }
  template <typename LatticeMatrixType>
  static void LieRandomize(GridParallelRNG &pRNG, LatticeMatrixType &out,
                           double scale = 1.0) {
    GridBase *grid = out.Grid();
    typedef typename LatticeMatrixType::vector_type vector_type;
    typedef iSinglet<vector_type> vTComplexType;
    typedef Lattice<vTComplexType> LatticeComplexType;
    typedef typename GridTypeMapper<
        typename LatticeMatrixType::vector_object>::scalar_object MatrixType;
    LatticeComplexType ca(grid);
    LatticeMatrixType lie(grid);
    LatticeMatrixType la(grid);
    ComplexD ci(0.0, scale);
    MatrixType ta;
    lie = Zero();
    for (int a = 0; a < AlgebraDimension; a++) {
      random(pRNG, ca);
      ca = (ca + conjugate(ca)) * 0.5;
      ca = ca - 0.5;
      generator(a, ta);
      la = ci * ca * ta;
      lie = lie + la;  // e^{i la ta}
    }
    taExp(lie, out);
  }
  static void GaussianFundamentalLieAlgebraMatrix(GridParallelRNG &pRNG,
                                                  LatticeMatrix &out,
                                                  Real scale = 1.0) {
    GridBase *grid = out.Grid();
    LatticeReal ca(grid);
    LatticeMatrix la(grid);
    Complex ci(0.0, scale);
    Matrix ta;
    out = Zero();
    for (int a = 0; a < AlgebraDimension; a++) {
      gaussian(pRNG, ca);
      generator(a, ta);
      la = toComplex(ca) * ta;
      out += la;
    }
    out *= ci;
  }
  static void FundamentalLieAlgebraMatrix(const LatticeAlgebraVector &h,
                                          LatticeMatrix &out,
                                          Real scale = 1.0) {
    conformable(h, out);
    GridBase *grid = out.Grid();
    LatticeMatrix la(grid);
    Matrix ta;
    out = Zero();
    for (int a = 0; a < AlgebraDimension; a++) {
      generator(a, ta);
      la = peekColour(h, a) * timesI(ta) * scale;
      out += la;
    }
  }
  // Projects the algebra components a lattice matrix (of dimension ncol*ncol -1
  // ) inverse operation: FundamentalLieAlgebraMatrix
  static void projectOnAlgebra(LatticeAlgebraVector &h_out,
                               const LatticeMatrix &in, Real scale = 1.0) {
    conformable(h_out, in);
    h_out = Zero();
    Matrix Ta;
    for (int a = 0; a < AlgebraDimension; a++) {
      generator(a, Ta);
      pokeColour(h_out, -2.0 * (trace(timesI(Ta) * in)) * scale, a);
    }
  }
  template <class vtype>
  accelerator_inline static iScalar<vtype> ProjectOnGeneralGroup(const iScalar<vtype> &r) {
    return ProjectOnGeneralGroup(r, group_name());
  }
  template <class vtype, int N>
  accelerator_inline static iVector<vtype,N> ProjectOnGeneralGroup(const iVector<vtype,N> &r) {
    return ProjectOnGeneralGroup(r, group_name());
  }
  template <class vtype,int N, typename std::enable_if< GridTypeMapper<vtype>::TensorLevel == 0 >::type * =nullptr>
  accelerator_inline static iMatrix<vtype,N> ProjectOnGeneralGroup(const iMatrix<vtype,N> &arg) {
    return ProjectOnGeneralGroup(arg, group_name());
  }
  template <int N,class vComplex_t>                  // Projects on the general groups U(N), Sp(2N)xZ2 i.e. determinant is allowed a complex phase.
  static void ProjectOnGeneralGroup(Lattice<iVector<iScalar<iMatrix<vComplex_t, N> >, Nd> > &U) {
    for (int mu = 0; mu < Nd; mu++) {
      auto Umu = PeekIndex<LorentzIndex>(U, mu);
      Umu = ProjectOnGeneralGroup(Umu);
    }
  }
  template <int N,class vComplex_t>
  static Lattice<iScalar<iScalar<iMatrix<vComplex_t, N> > > > ProjectOnGeneralGroup(const Lattice<iScalar<iScalar<iMatrix<vComplex_t, N> > > > &Umu) {
    return ProjectOnGeneralGroup(Umu, group_name());
  }
  template <int N,class vComplex_t>       // Projects on SU(N), Sp(2N), with unit determinant, by first projecting on general group and then enforcing unit determinant
  static void ProjectOnSpecialGroup(Lattice<iScalar<iScalar<iMatrix<vComplex_t, N> > > > &Umu) {
       Umu = ProjectOnGeneralGroup(Umu);
       auto det = Determinant(Umu);
       det = conjugate(det);
       for (int i = 0; i < N; i++) {
           auto element = PeekIndex<ColourIndex>(Umu, N - 1, i);
           element = element * det;
           PokeIndex<ColourIndex>(Umu, element, Nc - 1, i);
       }
   }
  template <int N,class vComplex_t>    // reunitarise, resimplectify... previously ProjectSUn
    static void ProjectOnSpecialGroup(Lattice<iVector<iScalar<iMatrix<vComplex_t, N> >, Nd> > &U) {
      // Reunitarise
      for (int mu = 0; mu < Nd; mu++) {
        auto Umu = PeekIndex<LorentzIndex>(U, mu);
        ProjectOnSpecialGroup(Umu);
        PokeIndex<LorentzIndex>(U, Umu, mu);
      }
    }
  template <typename GaugeField>
  static void HotConfiguration(GridParallelRNG &pRNG, GaugeField &out) {
    typedef typename GaugeField::vector_type vector_type;
    typedef iGroupMatrix<vector_type> vMatrixType;
    typedef Lattice<vMatrixType> LatticeMatrixType;
    LatticeMatrixType Umu(out.Grid());
    LatticeMatrixType tmp(out.Grid());
    for (int mu = 0; mu < Nd; mu++) {
      //      LieRandomize(pRNG, Umu, 1.0);
      //      PokeIndex<LorentzIndex>(out, Umu, mu);
      gaussian(pRNG,Umu);
      tmp = Ta(Umu);
      taExp(tmp,Umu);
      ProjectOnSpecialGroup(Umu);
      //      ProjectSUn(Umu);
      PokeIndex<LorentzIndex>(out, Umu, mu);
    }
  }
  template <typename GaugeField>
  static void TepidConfiguration(GridParallelRNG &pRNG, GaugeField &out) {
    typedef typename GaugeField::vector_type vector_type;
    typedef iGroupMatrix<vector_type> vMatrixType;
    typedef Lattice<vMatrixType> LatticeMatrixType;
    LatticeMatrixType Umu(out.Grid());
    for (int mu = 0; mu < Nd; mu++) {
      LieRandomize(pRNG, Umu, 0.01);
      PokeIndex<LorentzIndex>(out, Umu, mu);
    }
  }
  template <typename GaugeField>
  static void ColdConfiguration(GaugeField &out) {
    typedef typename GaugeField::vector_type vector_type;
    typedef iGroupMatrix<vector_type> vMatrixType;
    typedef Lattice<vMatrixType> LatticeMatrixType;
    LatticeMatrixType Umu(out.Grid());
    Umu = 1.0;
    for (int mu = 0; mu < Nd; mu++) {
      PokeIndex<LorentzIndex>(out, Umu, mu);
    }
  }
  template <typename GaugeField>
  static void ColdConfiguration(GridParallelRNG &pRNG, GaugeField &out) {
    ColdConfiguration(out);
  }
  template <typename LatticeMatrixType>
  static void taProj(const LatticeMatrixType &in, LatticeMatrixType &out) {
    taProj(in, out, group_name());
  }
  template <typename LatticeMatrixType>
  static void taExp(const LatticeMatrixType &x, LatticeMatrixType &ex) {
    typedef typename LatticeMatrixType::scalar_type ComplexType;
    LatticeMatrixType xn(x.Grid());
    RealD nfac = 1.0;
    xn = x;
    ex = xn + ComplexType(1.0);  // 1+x
    // Do a 12th order exponentiation
    for (int i = 2; i <= 12; ++i) {
      nfac = nfac / RealD(i);  // 1/2, 1/2.3 ...
      xn = xn * x;             // x2, x3,x4....
      ex = ex + xn * nfac;     // x2/2!, x3/3!....
    }
  }
 // Ta are hermitian (?)
 // Anti herm is i Ta basis
 static void LieAlgebraProject(LatticeAlgebraMatrix &out,const LatticeMatrix &in, int b)
 {
  conformable(in, out);
  GridBase *grid = out.Grid();
  LatticeComplex tmp(grid);
  Matrix ta;
  // Using Luchang's projection convention
  //  2 Tr{Ta Tb} A_b= 2/2 delta ab A_b = A_a
  autoView(out_v,out,AcceleratorWrite);
  autoView(in_v,in,AcceleratorRead);
  int N = ncolour;
  int NNm1 = N * (N - 1);
  int hNNm1= NNm1/2;
  RealD sqrt_2 = sqrt(2.0);
  Complex ci(0.0,1.0);
  for(int su2Index=0;su2Index<hNNm1;su2Index++){
    int i1, i2;
    su2SubGroupIndex(i1, i2, su2Index);
    int ax = su2Index*2;
    int ay = su2Index*2+1;
    accelerator_for(ss,grid->oSites(),1,{
 	// in is traceless ANTI-hermitian whereas Grid generators are Hermitian.
 	// trace( Ta x Ci in)
 	// Bet I need to move to real part with mult by -i
 	out_v[ss]()()(ax,b) = 0.5*(real(in_v[ss]()()(i2,i1)) - real(in_v[ss]()()(i1,i2)));
 	out_v[ss]()()(ay,b) = 0.5*(imag(in_v[ss]()()(i1,i2)) + imag(in_v[ss]()()(i2,i1)));
      });
  }
  for(int diagIndex=0;diagIndex<N-1;diagIndex++){
    int k = diagIndex + 1; // diagIndex starts from 0
    int a = NNm1+diagIndex;
    RealD scale = 1.0/sqrt(2.0*k*(k+1));
    accelerator_for(ss,grid->oSites(),vComplex::Nsimd(),{
 	auto tmp = in_v[ss]()()(0,0);
 	for(int i=1;i<k;i++){
 	  tmp=tmp+in_v[ss]()()(i,i);
 	}
 	tmp = tmp - in_v[ss]()()(k,k)*k;
 	out_v[ss]()()(a,b) =imag(tmp) * scale;
      });
    }
 }
 };
 template <int ncolour>
 using SU = GaugeGroup<ncolour, GroupName::SU>;
 template <int ncolour>
 using Sp = GaugeGroup<ncolour, GroupName::Sp>;
 typedef SU<2> SU2;
 typedef SU<3> SU3;
 typedef SU<4> SU4;
 typedef SU<5> SU5;
 typedef SU<Nc> FundamentalMatrices;
 typedef Sp<2> Sp2;
 typedef Sp<4> Sp4;
 typedef Sp<6> Sp6;
 typedef Sp<8> Sp8;
 template <int N,class vComplex_t>
 static void ProjectSUn(Lattice<iScalar<iScalar<iMatrix<vComplex_t, N> > > > &Umu)
 {
    GaugeGroup<N,GroupName::SU>::ProjectOnSpecialGroup(Umu);
 }
 template <int N,class vComplex_t>
 static void ProjectSUn(Lattice<iVector<iScalar<iMatrix<vComplex_t, N> >,Nd> > &U)
 {
    GaugeGroup<N,GroupName::SU>::ProjectOnSpecialGroup(U);
 }
 template <int N,class vComplex_t>
 static void ProjectSpn(Lattice<iScalar<iScalar<iMatrix<vComplex_t, N> > > > &Umu)
 {
    GaugeGroup<N,GroupName::Sp>::ProjectOnSpecialGroup(Umu);
 }
 template <int N,class vComplex_t>
 static void ProjectSpn(Lattice<iVector<iScalar<iMatrix<vComplex_t, N> >,Nd> > &U)
 {
    GaugeGroup<N,GroupName::Sp>::ProjectOnSpecialGroup(U);
 }
 // Explicit specialisation for SU(3).
 static void ProjectSU3(Lattice<iScalar<iScalar<iMatrix<vComplexD, 3> > > > &Umu)
 {
  GridBase *grid = Umu.Grid();
  const int x = 0;
  const int y = 1;
  const int z = 2;
  // Reunitarise
  Umu = ProjectOnGroup(Umu);
  autoView(Umu_v, Umu, CpuWrite);
  thread_for(ss, grid->oSites(), {
    auto cm = Umu_v[ss];
    cm()()(2, x) = adj(cm()()(0, y) * cm()()(1, z) -
                       cm()()(0, z) * cm()()(1, y));  // x= yz-zy
    cm()()(2, y) = adj(cm()()(0, z) * cm()()(1, x) -
                       cm()()(0, x) * cm()()(1, z));  // y= zx-xz
    cm()()(2, z) = adj(cm()()(0, x) * cm()()(1, y) -
                       cm()()(0, y) * cm()()(1, x));  // z= xy-yx
    Umu_v[ss] = cm;
  });
 }
 static void ProjectSU3(Lattice<iVector<iScalar<iMatrix<vComplexD, 3> >, Nd> > &U)
 {
  GridBase *grid = U.Grid();
  // Reunitarise
  for (int mu = 0; mu < Nd; mu++) {
    auto Umu = PeekIndex<LorentzIndex>(U, mu);
    Umu = ProjectOnGroup(Umu);
    ProjectSU3(Umu);
    PokeIndex<LorentzIndex>(U, Umu, mu);
  }
 }
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/qcd/utils/GaugeGroupTwoIndex.h
+++ b/Grid/qcd/utils/GaugeGroupTwoIndex.h
@ -0,0 +1,371 @@
 ////////////////////////////////////////////////////////////////////////
 //
 // * Two index representation generators
 //
 // * Normalisation for the fundamental generators:
 //   trace ta tb = 1/2 delta_ab = T_F delta_ab
 //   T_F = 1/2  for SU(N) groups
 //
 //
 //   base for NxN two index (anti-symmetric) matrices
 //   normalized to 1 (d_ij is the kroenecker delta)
 //
 //   (e^(ij)_{kl} = 1 / sqrt(2) (d_ik d_jl +/- d_jk d_il)
 //
 //   Then the generators are written as
 //
 //   (iT_a)^(ij)(lk) = i * ( tr[e^(ij)^dag e^(lk) T^trasp_a] +
 //   tr[e^(lk)e^(ij)^dag T_a] )  //
 //
 //
 ////////////////////////////////////////////////////////////////////////
 // Authors: David Preti, Guido Cossu
 #ifndef QCD_UTIL_GAUGEGROUPTWOINDEX_H
 #define QCD_UTIL_GAUGEGROUPTWOINDEX_H
 NAMESPACE_BEGIN(Grid);
 enum TwoIndexSymmetry { Symmetric = 1, AntiSymmetric = -1 };
 constexpr inline Real delta(int a, int b) { return (a == b) ? 1.0 : 0.0; }
 namespace detail {
 template <class cplx, int nc, TwoIndexSymmetry S>
 struct baseOffDiagonalSpHelper;
 template <class cplx, int nc>
 struct baseOffDiagonalSpHelper<cplx, nc, AntiSymmetric> {
  static const int ngroup = nc / 2;
  static void baseOffDiagonalSp(int i, int j, iScalar<iScalar<iMatrix<cplx, nc> > > &eij) {
    eij = Zero();
    RealD tmp;
    if ((i == ngroup + j) && (1 <= j) && (j < ngroup)) {
      for (int k = 0; k < j+1; k++) {
        if (k < j) {
          tmp = 1 / sqrt(j * (j + 1));
          eij()()(k, k + ngroup) = tmp;
          eij()()(k + ngroup, k) = -tmp;
        }
        if (k == j) {
          tmp = -j / sqrt(j * (j + 1));
          eij()()(k, k + ngroup) = tmp;
          eij()()(k + ngroup, k) = -tmp;
        }
      }
    }
    else if (i != ngroup + j) {
      for (int k = 0; k < nc; k++)
        for (int l = 0; l < nc; l++) {
          eij()()(l, k) =
              delta(i, k) * delta(j, l) - delta(j, k) * delta(i, l);
        }
    }
    RealD nrm = 1. / std::sqrt(2.0);
    eij = eij * nrm;
  }
 };
 template <class cplx, int nc>
 struct baseOffDiagonalSpHelper<cplx, nc, Symmetric> {
  static void baseOffDiagonalSp(int i, int j, iScalar<iScalar<iMatrix<cplx, nc> > > &eij) {
    eij = Zero();
    for (int k = 0; k < nc; k++)
      for (int l = 0; l < nc; l++)
        eij()()(l, k) =
            delta(i, k) * delta(j, l) + delta(j, k) * delta(i, l);
    RealD nrm = 1. / std::sqrt(2.0);
    eij = eij * nrm;
  }
 };
 }   // closing detail namespace
 template <int ncolour, TwoIndexSymmetry S, class group_name>
 class GaugeGroupTwoIndex : public GaugeGroup<ncolour, group_name> {
 public:
  // The chosen convention is that we are taking ncolour to be N in SU<N> but 2N
  // in Sp(2N). ngroup is equal to N for SU but 2N/2 = N for Sp(2N).
  static_assert(std::is_same<group_name, GroupName::SU>::value or
                    std::is_same<group_name, GroupName::Sp>::value,
                "ngroup is only implemented for SU and Sp currently.");
  static const int ngroup =
      std::is_same<group_name, GroupName::SU>::value ? ncolour : ncolour / 2;
  static const int Dimension =
      (ncolour * (ncolour + S) / 2) + (std::is_same<group_name, GroupName::Sp>::value ? (S - 1) / 2 : 0);
  static const int DimensionAS =
      (ncolour * (ncolour - 1) / 2) + (std::is_same<group_name, GroupName::Sp>::value ? (- 1) : 0);
  static const int DimensionS =
      ncolour * (ncolour + 1) / 2;
  static const int NumGenerators =
      GaugeGroup<ncolour, group_name>::AlgebraDimension;
  template <typename vtype>
  using iGroupTwoIndexMatrix = iScalar<iScalar<iMatrix<vtype, Dimension> > >;
  typedef iGroupTwoIndexMatrix<Complex> TIMatrix;
  typedef iGroupTwoIndexMatrix<ComplexF> TIMatrixF;
  typedef iGroupTwoIndexMatrix<ComplexD> TIMatrixD;
  typedef iGroupTwoIndexMatrix<vComplex> vTIMatrix;
  typedef iGroupTwoIndexMatrix<vComplexF> vTIMatrixF;
  typedef iGroupTwoIndexMatrix<vComplexD> vTIMatrixD;
  typedef Lattice<vTIMatrix> LatticeTwoIndexMatrix;
  typedef Lattice<vTIMatrixF> LatticeTwoIndexMatrixF;
  typedef Lattice<vTIMatrixD> LatticeTwoIndexMatrixD;
  typedef Lattice<iVector<iScalar<iMatrix<vComplex, Dimension> >, Nd> >
      LatticeTwoIndexField;
  typedef Lattice<iVector<iScalar<iMatrix<vComplexF, Dimension> >, Nd> >
      LatticeTwoIndexFieldF;
  typedef Lattice<iVector<iScalar<iMatrix<vComplexD, Dimension> >, Nd> >
      LatticeTwoIndexFieldD;
  template <typename vtype>
  using iGroupMatrix = iScalar<iScalar<iMatrix<vtype, ncolour> > >;
  typedef iGroupMatrix<Complex> Matrix;
  typedef iGroupMatrix<ComplexF> MatrixF;
  typedef iGroupMatrix<ComplexD> MatrixD;
 private:
  template <class cplx>
  static void baseDiagonal(int Index, iGroupMatrix<cplx> &eij) {
    eij = Zero();
    eij()()(Index - ncolour * (ncolour - 1) / 2,
            Index - ncolour * (ncolour - 1) / 2) = 1.0;
  }
  template <class cplx>
  static void baseOffDiagonal(int i, int j, iGroupMatrix<cplx> &eij, GroupName::SU) {
    eij = Zero();
    for (int k = 0; k < ncolour; k++)
      for (int l = 0; l < ncolour; l++)
        eij()()(l, k) =
            delta(i, k) * delta(j, l) + S * delta(j, k) * delta(i, l);
    RealD nrm = 1. / std::sqrt(2.0);
    eij = eij * nrm;
  }
  template <class cplx>
  static void baseOffDiagonal(int i, int j, iGroupMatrix<cplx> &eij, GroupName::Sp) {
    detail::baseOffDiagonalSpHelper<cplx, ncolour, S>::baseOffDiagonalSp(i, j, eij);
  }
 public:
  template <class cplx>
  static void base(int Index, iGroupMatrix<cplx> &eij) {
  // returns (e)^(ij)_{kl} necessary for change of base U_F -> U_R
    assert(Index < Dimension);
    eij = Zero();
  // for the linearisation of the 2 indexes
    static int a[ncolour * (ncolour - 1) / 2][2];  // store the a <-> i,j
    static bool filled = false;
    if (!filled) {
      int counter = 0;
      for (int i = 1; i < ncolour; i++) {
      for (int j = 0; j < i; j++) {
        if (std::is_same<group_name, GroupName::Sp>::value)
          {
            if (j==0 && i==ngroup+j && S==-1) {
            //std::cout << "skipping" << std::endl; // for Sp2n this vanishes identically.
              j = j+1;
            }
          }
          a[counter][0] = i;
          a[counter][1] = j;
          counter++;
          }
      }
      filled = true;
    }
    if (Index < ncolour*ncolour - DimensionS)
    {
      baseOffDiagonal(a[Index][0], a[Index][1], eij, group_name());
    } else {
      baseDiagonal(Index, eij);
    }
  }
  static void printBase(void) {
    for (int gen = 0; gen < Dimension; gen++) {
      Matrix tmp;
      base(gen, tmp);
      std::cout << GridLogMessage << "Nc = " << ncolour << " t_" << gen
                << std::endl;
      std::cout << GridLogMessage << tmp << std::endl;
    }
  }
  template <class cplx>
  static void generator(int Index, iGroupTwoIndexMatrix<cplx> &i2indTa) {
    Vector<iGroupMatrix<cplx> > ta(NumGenerators);
    Vector<iGroupMatrix<cplx> > eij(Dimension);
    iGroupMatrix<cplx> tmp;
    for (int a = 0; a < NumGenerators; a++)
      GaugeGroup<ncolour, group_name>::generator(a, ta[a]);
    for (int a = 0; a < Dimension; a++) base(a, eij[a]);
    for (int a = 0; a < Dimension; a++) {
      tmp = transpose(eij[a]*ta[Index]) + transpose(eij[a]) * ta[Index];
      for (int b = 0; b < Dimension; b++) {
        Complex iTr = TensorRemove(timesI(trace(tmp * eij[b])));
        i2indTa()()(a, b) = iTr;
      }
    }
  }
  static void printGenerators(void) {
    for (int gen = 0; gen < NumGenerators; gen++) {
      TIMatrix i2indTa;
      generator(gen, i2indTa);
      std::cout << GridLogMessage << "Nc = " << ncolour << " t_" << gen
                << std::endl;
      std::cout << GridLogMessage << i2indTa << std::endl;
    }
  }
  static void testGenerators(void) {
    TIMatrix i2indTa, i2indTb;
    std::cout << GridLogMessage << "2IndexRep - Checking if traceless"
              << std::endl;
    for (int a = 0; a < NumGenerators; a++) {
      generator(a, i2indTa);
      std::cout << GridLogMessage << a << std::endl;
      assert(norm2(trace(i2indTa)) < 1.0e-6);
    }
    std::cout << GridLogMessage << std::endl;
    std::cout << GridLogMessage << "2IndexRep - Checking if antihermitean"
              << std::endl;
    for (int a = 0; a < NumGenerators; a++) {
      generator(a, i2indTa);
      std::cout << GridLogMessage << a << std::endl;
      assert(norm2(adj(i2indTa) + i2indTa) < 1.0e-6);
    }
    std::cout << GridLogMessage << std::endl;
    std::cout << GridLogMessage
              << "2IndexRep - Checking Tr[Ta*Tb]=delta(a,b)*(N +- 2)/2"
              << std::endl;
    for (int a = 0; a < NumGenerators; a++) {
      for (int b = 0; b < NumGenerators; b++) {
        generator(a, i2indTa);
        generator(b, i2indTb);
        // generator returns iTa, so we need a minus sign here
        Complex Tr = -TensorRemove(trace(i2indTa * i2indTb));
        std::cout << GridLogMessage << "a=" << a << "b=" << b << "Tr=" << Tr
                  << std::endl;
        if (a == b) {
          assert(real(Tr) - ((ncolour + S * 2) * 0.5) < 1e-8);
        } else {
          assert(real(Tr) < 1e-8);
        }
        assert(imag(Tr) < 1e-8);
      }
    }
    std::cout << GridLogMessage << std::endl;
  }
  static void TwoIndexLieAlgebraMatrix(
      const typename GaugeGroup<ncolour, group_name>::LatticeAlgebraVector &h,
      LatticeTwoIndexMatrix &out, Real scale = 1.0) {
    conformable(h, out);
    GridBase *grid = out.Grid();
    LatticeTwoIndexMatrix la(grid);
    TIMatrix i2indTa;
    out = Zero();
    for (int a = 0; a < NumGenerators; a++) {
      generator(a, i2indTa);
      la = peekColour(h, a) * i2indTa;
      out += la;
    }
    out *= scale;
  }
  // Projects the algebra components
  // of a lattice matrix ( of dimension ncol*ncol -1 )
  static void projectOnAlgebra(
      typename GaugeGroup<ncolour, group_name>::LatticeAlgebraVector &h_out,
      const LatticeTwoIndexMatrix &in, Real scale = 1.0) {
    conformable(h_out, in);
    h_out = Zero();
    TIMatrix i2indTa;
    Real coefficient = -2.0 / (ncolour + 2 * S) * scale;
    // 2/(Nc +/- 2) for the normalization of the trace in the two index rep
    for (int a = 0; a < NumGenerators; a++) {
      generator(a, i2indTa);
      pokeColour(h_out, real(trace(i2indTa * in)) * coefficient, a);
    }
  }
  // a projector that keeps the generators stored to avoid the overhead of
  // recomputing them
  static void projector(
      typename GaugeGroup<ncolour, group_name>::LatticeAlgebraVector &h_out,
      const LatticeTwoIndexMatrix &in, Real scale = 1.0) {
    conformable(h_out, in);
    // to store the generators
    static std::vector<TIMatrix> i2indTa(NumGenerators);
    h_out = Zero();
    static bool precalculated = false;
    if (!precalculated) {
      precalculated = true;
      for (int a = 0; a < NumGenerators; a++) generator(a, i2indTa[a]);
    }
    Real coefficient =
        -2.0 / (ncolour + 2 * S) * scale;  // 2/(Nc +/- 2) for the normalization
    // of the trace in the two index rep
    for (int a = 0; a < NumGenerators; a++) {
      auto tmp = real(trace(i2indTa[a] * in)) * coefficient;
      pokeColour(h_out, tmp, a);
    }
  }
 };
 template <int ncolour, TwoIndexSymmetry S>
 using SU_TwoIndex = GaugeGroupTwoIndex<ncolour, S, GroupName::SU>;
 // Some useful type names
 typedef SU_TwoIndex<Nc, Symmetric> TwoIndexSymmMatrices;
 typedef SU_TwoIndex<Nc, AntiSymmetric> TwoIndexAntiSymmMatrices;
 typedef SU_TwoIndex<2, Symmetric> SU2TwoIndexSymm;
 typedef SU_TwoIndex<3, Symmetric> SU3TwoIndexSymm;
 typedef SU_TwoIndex<4, Symmetric> SU4TwoIndexSymm;
 typedef SU_TwoIndex<5, Symmetric> SU5TwoIndexSymm;
 typedef SU_TwoIndex<2, AntiSymmetric> SU2TwoIndexAntiSymm;
 typedef SU_TwoIndex<3, AntiSymmetric> SU3TwoIndexAntiSymm;
 typedef SU_TwoIndex<4, AntiSymmetric> SU4TwoIndexAntiSymm;
 typedef SU_TwoIndex<5, AntiSymmetric> SU5TwoIndexAntiSymm;
 template <int ncolour, TwoIndexSymmetry S>
 using Sp_TwoIndex = GaugeGroupTwoIndex<ncolour, S, GroupName::Sp>;
 typedef Sp_TwoIndex<Nc, Symmetric> SpTwoIndexSymmMatrices;
 typedef Sp_TwoIndex<Nc, AntiSymmetric> SpTwoIndexAntiSymmMatrices;
 typedef Sp_TwoIndex<2, Symmetric> Sp2TwoIndexSymm;
 typedef Sp_TwoIndex<4, Symmetric> Sp4TwoIndexSymm;
 typedef Sp_TwoIndex<4, AntiSymmetric> Sp4TwoIndexAntiSymm;
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/qcd/utils/SUn.h
+++ b/Grid/qcd/utils/SUn.h
@ -1,932 +0,0 @@
 /*************************************************************************************
 Grid physics library, www.github.com/paboyle/Grid
 Source file: ./lib/qcd/utils/SUn.h
 Copyright (C) 2015
 Author: Azusa Yamaguchi <ayamaguc@staffmail.ed.ac.uk>
 Author: Peter Boyle <paboyle@ph.ed.ac.uk>
 Author: neo <cossu@post.kek.jp>
 Author: paboyle <paboyle@ph.ed.ac.uk>
 This program is free software; you can redistribute it and/or modify
 it under the terms of the GNU General Public License as published by
 the Free Software Foundation; either version 2 of the License, or
 (at your option) any later version.
 This program is distributed in the hope that it will be useful,
 but WITHOUT ANY WARRANTY; without even the implied warranty of
 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 GNU General Public License for more details.
 You should have received a copy of the GNU General Public License along
 with this program; if not, write to the Free Software Foundation, Inc.,
 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
 See the full license in the file "LICENSE" in the top level distribution
 directory
 *************************************************************************************/
 			   /*  END LEGAL */
 #ifndef QCD_UTIL_SUN_H
 #define QCD_UTIL_SUN_H
 NAMESPACE_BEGIN(Grid);
 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, class Vec>
 static void ProjectSUn(Lattice<iScalar<iScalar<iMatrix<Vec, N> > > > &Umu)
 {
  Umu      = ProjectOnGroup(Umu);
  auto det = Determinant(Umu);
  det = conjugate(det);
  for(int i=0;i<N;i++){
    auto element = PeekIndex<ColourIndex>(Umu,N-1,i);
    element = element * det;
    PokeIndex<ColourIndex>(Umu,element,Nc-1,i);
  }
 }
 template<int N,class Vec>
 static void ProjectSUn(Lattice<iVector<iScalar<iMatrix<Vec, N> >,Nd> > &U)
 {
  GridBase *grid=U.Grid();
  // Reunitarise
  for(int mu=0;mu<Nd;mu++){
    auto Umu = PeekIndex<LorentzIndex>(U,mu);
    Umu      = ProjectOnGroup(Umu);
    ProjectSUn(Umu);
    PokeIndex<LorentzIndex>(U,Umu,mu);
  }
 }
 template <int ncolour>
 class SU {
 public:
  static const int Dimension = ncolour;
  static const int AdjointDimension = ncolour * ncolour - 1;
  static int su2subgroups(void) { return (ncolour * (ncolour - 1)) / 2; }
  template <typename vtype>
  using iSUnMatrix = iScalar<iScalar<iMatrix<vtype, ncolour> > >;
  template <typename vtype>
  using iSU2Matrix = iScalar<iScalar<iMatrix<vtype, 2> > >;
  template <typename vtype>
  using iSUnAlgebraVector =
    iScalar<iScalar<iVector<vtype, AdjointDimension> > >;
  //////////////////////////////////////////////////////////////////////////////////////////////////
  // Types can be accessed as SU<2>::Matrix , SU<2>::vSUnMatrix,
  // SU<2>::LatticeMatrix etc...
  //////////////////////////////////////////////////////////////////////////////////////////////////
  typedef iSUnMatrix<Complex> Matrix;
  typedef iSUnMatrix<ComplexF> MatrixF;
  typedef iSUnMatrix<ComplexD> MatrixD;
  typedef iSUnMatrix<vComplex> vMatrix;
  typedef iSUnMatrix<vComplexF> vMatrixF;
  typedef iSUnMatrix<vComplexD> vMatrixD;
  // For the projectors to the algebra
  // these should be real...
  // keeping complex for consistency with the SIMD vector types
  typedef iSUnAlgebraVector<Complex> AlgebraVector;
  typedef iSUnAlgebraVector<ComplexF> AlgebraVectorF;
  typedef iSUnAlgebraVector<ComplexD> AlgebraVectorD;
  typedef iSUnAlgebraVector<vComplex> vAlgebraVector;
  typedef iSUnAlgebraVector<vComplexF> vAlgebraVectorF;
  typedef iSUnAlgebraVector<vComplexD> vAlgebraVectorD;
  typedef Lattice<vMatrix> LatticeMatrix;
  typedef Lattice<vMatrixF> LatticeMatrixF;
  typedef Lattice<vMatrixD> LatticeMatrixD;
  typedef Lattice<vAlgebraVector> LatticeAlgebraVector;
  typedef Lattice<vAlgebraVectorF> LatticeAlgebraVectorF;
  typedef Lattice<vAlgebraVectorD> LatticeAlgebraVectorD;
  typedef iSU2Matrix<Complex> SU2Matrix;
  typedef iSU2Matrix<ComplexF> SU2MatrixF;
  typedef iSU2Matrix<ComplexD> SU2MatrixD;
  typedef iSU2Matrix<vComplex> vSU2Matrix;
  typedef iSU2Matrix<vComplexF> vSU2MatrixF;
  typedef iSU2Matrix<vComplexD> vSU2MatrixD;
  typedef Lattice<vSU2Matrix> LatticeSU2Matrix;
  typedef Lattice<vSU2MatrixF> LatticeSU2MatrixF;
  typedef Lattice<vSU2MatrixD> LatticeSU2MatrixD;
  ////////////////////////////////////////////////////////////////////////
  // There are N^2-1 generators for SU(N).
  //
  // We take a traceless hermitian generator basis as follows
  //
  // * Normalisation: trace ta tb = 1/2 delta_ab = T_F delta_ab
  //   T_F = 1/2  for SU(N) groups
  //
  // * Off diagonal
  //    - pairs of rows i1,i2 behaving like pauli matrices signma_x, sigma_y
  //
  //    - there are (Nc-1-i1) slots for i2 on each row [ x  0  x ]
  //      direct count off each row
  //
  //    - Sum of all pairs is Nc(Nc-1)/2: proof arithmetic series
  //
  //      (Nc-1) + (Nc-2)+...  1      ==> Nc*(Nc-1)/2
  //      1+ 2+          +   + Nc-1
  //
  //    - There are 2 x Nc (Nc-1)/ 2 of these = Nc^2 - Nc
  //
  //    - We enumerate the row-col pairs.
  //    - for each row col pair there is a (sigma_x) and a (sigma_y) like
  //    generator
  //
  //
  //   t^a_ij = { in 0.. Nc(Nc-1)/2 -1} =>  1/2(delta_{i,i1} delta_{j,i2} +
  //   delta_{i,i1} delta_{j,i2})
  //   t^a_ij = { in Nc(Nc-1)/2 ... Nc(Nc-1) - 1} =>  i/2( delta_{i,i1}
  //   delta_{j,i2} - i delta_{i,i1} delta_{j,i2})
  //
  // * Diagonal; must be traceless and normalised
  //   - Sequence is
  //   N  (1,-1,0,0...)
  //   N  (1, 1,-2,0...)
  //   N  (1, 1, 1,-3,0...)
  //   N  (1, 1, 1, 1,-4,0...)
  //
  //   where 1/2 = N^2 (1+.. m^2)etc.... for the m-th diagonal generator
  //   NB this gives the famous SU3 result for su2 index 8
  //
  //   N= sqrt(1/2 . 1/6 ) = 1/2 . 1/sqrt(3)
  //
  //   ( 1      )
  //   (    1   ) / sqrt(3) /2  = 1/2 lambda_8
  //   (      -2)
  //
  ////////////////////////////////////////////////////////////////////////
  template <class cplx>
  static void generator(int lieIndex, iSUnMatrix<cplx> &ta) {
    // map lie index to which type of generator
    int diagIndex;
    int su2Index;
    int sigxy;
    int NNm1 = ncolour * (ncolour - 1);
    if (lieIndex >= NNm1) {
      diagIndex = lieIndex - NNm1;
      generatorDiagonal(diagIndex, ta);
      return;
    }
    sigxy = lieIndex & 0x1;  // even or odd
    su2Index = lieIndex >> 1;
    if (sigxy)
      generatorSigmaY(su2Index, ta);
    else
      generatorSigmaX(su2Index, ta);
  }
  template <class cplx>
  static void generatorSigmaY(int su2Index, iSUnMatrix<cplx> &ta) {
    ta = Zero();
    int i1, i2;
    su2SubGroupIndex(i1, i2, su2Index);
    ta()()(i1, i2) = 1.0;
    ta()()(i2, i1) = 1.0;
    ta = ta * 0.5;
  }
  template <class cplx>
  static void generatorSigmaX(int su2Index, iSUnMatrix<cplx> &ta) {
    ta = Zero();
    cplx i(0.0, 1.0);
    int i1, i2;
    su2SubGroupIndex(i1, i2, su2Index);
    ta()()(i1, i2) = i;
    ta()()(i2, i1) = -i;
    ta = ta * 0.5;
  }
  template <class cplx>
  static void generatorDiagonal(int diagIndex, iSUnMatrix<cplx> &ta) {
    // diag ({1, 1, ..., 1}(k-times), -k, 0, 0, ...)
    ta = Zero();
    int k = diagIndex + 1;                  // diagIndex starts from 0
    for (int i = 0; i <= diagIndex; i++) {  // k iterations
      ta()()(i, i) = 1.0;
    }
    ta()()(k, k) = -k;  // indexing starts from 0
    RealD nrm = 1.0 / std::sqrt(2.0 * k * (k + 1));
    ta = ta * nrm;
  }
  ////////////////////////////////////////////////////////////////////////
  // Map a su2 subgroup number to the pair of rows that are non zero
  ////////////////////////////////////////////////////////////////////////
  static void su2SubGroupIndex(int &i1, int &i2, int su2_index) {
    assert((su2_index >= 0) && (su2_index < (ncolour * (ncolour - 1)) / 2));
    int spare = su2_index;
    for (i1 = 0; spare >= (ncolour - 1 - i1); i1++) {
      spare = spare - (ncolour - 1 - i1);  // remove the Nc-1-i1 terms
    }
    i2 = i1 + 1 + spare;
  }
  //////////////////////////////////////////////////////////////////////////////////////////
  // Pull out a subgroup and project on to real coeffs x pauli basis
  //////////////////////////////////////////////////////////////////////////////////////////
  template <class vcplx>
  static void su2Extract(Lattice<iSinglet<vcplx> > &Determinant,
                         Lattice<iSU2Matrix<vcplx> > &subgroup,
                         const Lattice<iSUnMatrix<vcplx> > &source,
                         int su2_index) {
    GridBase *grid(source.Grid());
    conformable(subgroup, source);
    conformable(subgroup, Determinant);
    int i0, i1;
    su2SubGroupIndex(i0, i1, su2_index);
    autoView( subgroup_v , subgroup,AcceleratorWrite);
    autoView( source_v   , source,AcceleratorRead);
    autoView( Determinant_v , Determinant,AcceleratorWrite);
    accelerator_for(ss, grid->oSites(), 1, {
      subgroup_v[ss]()()(0, 0) = source_v[ss]()()(i0, i0);
      subgroup_v[ss]()()(0, 1) = source_v[ss]()()(i0, i1);
      subgroup_v[ss]()()(1, 0) = source_v[ss]()()(i1, i0);
      subgroup_v[ss]()()(1, 1) = source_v[ss]()()(i1, i1);
      iSU2Matrix<vcplx> Sigma = subgroup_v[ss];
      Sigma = Sigma - adj(Sigma) + trace(adj(Sigma));
      subgroup_v[ss] = Sigma;
      // this should be purely real
      Determinant_v[ss] =
 	Sigma()()(0, 0) * Sigma()()(1, 1) - Sigma()()(0, 1) * Sigma()()(1, 0);
    });
  }
  //////////////////////////////////////////////////////////////////////////////////////////
  // Set matrix to one and insert a pauli subgroup
  //////////////////////////////////////////////////////////////////////////////////////////
  template <class vcplx>
  static void su2Insert(const Lattice<iSU2Matrix<vcplx> > &subgroup,
                        Lattice<iSUnMatrix<vcplx> > &dest, int su2_index) {
    GridBase *grid(dest.Grid());
    conformable(subgroup, dest);
    int i0, i1;
    su2SubGroupIndex(i0, i1, su2_index);
    dest = 1.0;  // start out with identity
    autoView( dest_v , dest, AcceleratorWrite);
    autoView( subgroup_v, subgroup, AcceleratorRead);
    accelerator_for(ss, grid->oSites(),1,
    {
      dest_v[ss]()()(i0, i0) = subgroup_v[ss]()()(0, 0);
      dest_v[ss]()()(i0, i1) = subgroup_v[ss]()()(0, 1);
      dest_v[ss]()()(i1, i0) = subgroup_v[ss]()()(1, 0);
      dest_v[ss]()()(i1, i1) = subgroup_v[ss]()()(1, 1);
    });
  }
  ///////////////////////////////////////////////
  // Generate e^{ Re Tr Staple Link} dlink
  //
  // *** Note Staple should be appropriate linear compbination between all
  // staples.
  // *** If already by beta pass coefficient 1.0.
  // *** This routine applies the additional 1/Nc factor that comes after trace
  // in action.
  //
  ///////////////////////////////////////////////
  static void SubGroupHeatBath(GridSerialRNG &sRNG, GridParallelRNG &pRNG,
 			       RealD beta,  // coeff multiplying staple in action (with no 1/Nc)
 			       LatticeMatrix &link,
 			       const LatticeMatrix &barestaple,  // multiplied by action coeffs so th
 			       int su2_subgroup, int nheatbath, LatticeInteger &wheremask) 
  {
    GridBase *grid = link.Grid();
    const RealD twopi = 2.0 * M_PI;
    LatticeMatrix staple(grid);
    staple = barestaple * (beta / ncolour);
    LatticeMatrix V(grid);
    V = link * staple;
    // Subgroup manipulation in the lie algebra space
    LatticeSU2Matrix u(grid);  // Kennedy pendleton "u" real projected normalised Sigma
    LatticeSU2Matrix uinv(grid);
    LatticeSU2Matrix ua(grid);  // a in pauli form
    LatticeSU2Matrix b(grid);   // rotated matrix after hb
    // Some handy constant fields
    LatticeComplex ones(grid);
    ones = 1.0;
    LatticeComplex zeros(grid);
    zeros = Zero();
    LatticeReal rones(grid);
    rones = 1.0;
    LatticeReal rzeros(grid);
    rzeros = Zero();
    LatticeComplex udet(grid);  // determinant of real(staple)
    LatticeInteger mask_true(grid);
    mask_true = 1;
    LatticeInteger mask_false(grid);
    mask_false = 0;
    /*
      PLB 156 P393 (1985) (Kennedy and Pendleton)
      Note: absorb "beta" into the def of sigma compared to KP paper; staple
      passed to this routine has "beta" already multiplied in
      Action linear in links h and of form:
      beta S = beta  Sum_p (1 - 1/Nc Re Tr Plaq )
      Writing Sigma = 1/Nc (beta Sigma') where sum over staples is "Sigma' "
      beta S = const - beta/Nc Re Tr h Sigma'
      = const - Re Tr h Sigma
      Decompose h and Sigma into (1, sigma_j) ; h_i real, h^2=1, Sigma_i complex
      arbitrary.
      Tr h Sigma = h_i Sigma_j Tr (sigma_i sigma_j)  = h_i Sigma_j 2 delta_ij
      Re Tr h Sigma = 2 h_j Re Sigma_j
      Normalised re Sigma_j = xi u_j
      With u_j a unit vector and U can be in SU(2);
      Re Tr h Sigma = 2 h_j Re Sigma_j = 2 xi (h.u)
      4xi^2 = Det [ Sig - Sig^dag  + 1 Tr Sigdag]
      u   = 1/2xi [ Sig - Sig^dag  + 1 Tr Sigdag]
      xi = sqrt(Det)/2;
      Write a= u h in SU(2); a has pauli decomp a_j;
      Note: Product b' xi is unvariant because scaling Sigma leaves
      normalised vector "u" fixed; Can rescale Sigma so b' = 1.
    */
    ////////////////////////////////////////////////////////
    // Real part of Pauli decomposition
    // Note a subgroup can project to zero in cold start
    ////////////////////////////////////////////////////////
    su2Extract(udet, u, V, su2_subgroup);
    //////////////////////////////////////////////////////
    // Normalising this vector if possible; else identity
    //////////////////////////////////////////////////////
    LatticeComplex xi(grid);
    LatticeSU2Matrix lident(grid);
    SU2Matrix ident = Complex(1.0);
    SU2Matrix pauli1;
    SU<2>::generator(0, pauli1);
    SU2Matrix pauli2;
    SU<2>::generator(1, pauli2);
    SU2Matrix pauli3;
    SU<2>::generator(2, pauli3);
    pauli1 = timesI(pauli1) * 2.0;
    pauli2 = timesI(pauli2) * 2.0;
    pauli3 = timesI(pauli3) * 2.0;
    LatticeComplex cone(grid);
    LatticeReal adet(grid);
    adet = abs(toReal(udet));
    lident = Complex(1.0);
    cone = Complex(1.0);
    Real machine_epsilon = 1.0e-7;
    u = where(adet > machine_epsilon, u, lident);
    udet = where(adet > machine_epsilon, udet, cone);
    xi = 0.5 * sqrt(udet);  // 4xi^2 = Det [ Sig - Sig^dag  + 1 Tr Sigdag]
    u = 0.5 * u *
      pow(xi, -1.0);  //  u   = 1/2xi [ Sig - Sig^dag  + 1 Tr Sigdag]
    // Debug test for sanity
    uinv = adj(u);
    b = u * uinv - 1.0;
    assert(norm2(b) < 1.0e-4);
    /*
      Measure: Haar measure dh has d^4a delta(1-|a^2|)
      In polars:
      da = da0 r^2 sin theta dr dtheta dphi delta( 1 - r^2 -a0^2)
      = da0 r^2 sin theta dr dtheta dphi delta( (sqrt(1-a0^) - r)(sqrt(1-a0^) +
      r) )
      = da0 r/2 sin theta dr dtheta dphi delta( (sqrt(1-a0^) - r) )
      Action factor Q(h) dh  = e^-S[h]  dh =  e^{  xi Tr uh} dh    // beta enters
      through xi
      =  e^{2 xi (h.u)} dh
      =  e^{2 xi h0u0}.e^{2 xi h1u1}.e^{2 xi
      h2u2}.e^{2 xi h3u3} dh
      Therefore for each site, take xi for that site
      i) generate  |a0|<1 with dist
      (1-a0^2)^0.5 e^{2 xi a0 } da0
      Take alpha = 2 xi  = 2 xi [ recall 2 beta/Nc unmod staple norm]; hence 2.0/Nc
      factor in Chroma ]
      A. Generate two uniformly distributed pseudo-random numbers R and R', R'',
      R''' in the unit interval;
      B. Set X = -(ln R)/alpha, X' =-(ln R')/alpha;
      C. Set C = cos^2(2pi R"), with R" another uniform random number in [0,1] ;
      D. Set A = XC;
      E. Let d  = X'+A;
      F. If R'''^2 :> 1 - 0.5 d,  go back to A;
      G. Set a0 = 1 - d;
      Note that in step D setting B ~ X - A and using B in place of A in step E will
      generate a second independent a 0 value.
    */
    /////////////////////////////////////////////////////////
    // count the number of sites by picking "1"'s out of hat
    /////////////////////////////////////////////////////////
    Integer hit = 0;
    LatticeReal rtmp(grid);
    rtmp = where(wheremask, rones, rzeros);
    RealD numSites = sum(rtmp);
    RealD numAccepted;
    LatticeInteger Accepted(grid);
    Accepted = Zero();
    LatticeInteger newlyAccepted(grid);
    std::vector<LatticeReal> xr(4, grid);
    std::vector<LatticeReal> a(4, grid);
    LatticeReal d(grid);
    d = Zero();
    LatticeReal alpha(grid);
    //    std::cout<<GridLogMessage<<"xi "<<xi <<std::endl;
    xi = 2.0 *xi;
    alpha = toReal(xi);
    do {
      // A. Generate two uniformly distributed pseudo-random numbers R and R',
      // R'', R''' in the unit interval;
      random(pRNG, xr[0]);
      random(pRNG, xr[1]);
      random(pRNG, xr[2]);
      random(pRNG, xr[3]);
      // B. Set X = - ln R/alpha, X' = -ln R'/alpha
      xr[1] = -log(xr[1]) / alpha;
      xr[2] = -log(xr[2]) / alpha;
      // C. Set C = cos^2(2piR'')
      xr[3] = cos(xr[3] * twopi);
      xr[3] = xr[3] * xr[3];
      LatticeReal xrsq(grid);
      // D. Set A = XC;
      // E. Let d  = X'+A;
      xrsq = xr[2] + xr[1] * xr[3];
      d = where(Accepted, d, xr[2] + xr[1] * xr[3]);
      // F. If R'''^2 :> 1 - 0.5 d,  go back to A;
      LatticeReal thresh(grid);
      thresh = 1.0 - d * 0.5;
      xrsq = xr[0] * xr[0];
      LatticeInteger ione(grid);
      ione = 1;
      LatticeInteger izero(grid);
      izero = Zero();
      newlyAccepted = where(xrsq < thresh, ione, izero);
      Accepted = where(newlyAccepted, newlyAccepted, Accepted);
      Accepted = where(wheremask, Accepted, izero);
      // FIXME need an iSum for integer to avoid overload on return type??
      rtmp = where(Accepted, rones, rzeros);
      numAccepted = sum(rtmp);
      hit++;
    } while ((numAccepted < numSites) && (hit < nheatbath));
    // G. Set a0 = 1 - d;
    a[0] = Zero();
    a[0] = where(wheremask, 1.0 - d, a[0]);
    //////////////////////////////////////////
    //    ii) generate a_i uniform on two sphere radius (1-a0^2)^0.5
    //////////////////////////////////////////
    LatticeReal a123mag(grid);
    a123mag = sqrt(abs(1.0 - a[0] * a[0]));
    LatticeReal cos_theta(grid);
    LatticeReal sin_theta(grid);
    LatticeReal phi(grid);
    random(pRNG, phi);
    phi = phi * twopi;  // uniform in [0,2pi]
    random(pRNG, cos_theta);
    cos_theta = (cos_theta * 2.0) - 1.0;  // uniform in [-1,1]
    sin_theta = sqrt(abs(1.0 - cos_theta * cos_theta));
    a[1] = a123mag * sin_theta * cos(phi);
    a[2] = a123mag * sin_theta * sin(phi);
    a[3] = a123mag * cos_theta;
    ua = toComplex(a[0]) * ident  + toComplex(a[1]) * pauli1 +
         toComplex(a[2]) * pauli2 + toComplex(a[3]) * pauli3;
    b = 1.0;
    b = where(wheremask, uinv * ua, b);
    su2Insert(b, V, su2_subgroup);
    // mask the assignment back based on Accptance
    link = where(Accepted, V * link, link);
    //////////////////////////////
    // Debug Checks
    // SU2 check
    LatticeSU2Matrix check(grid);  // rotated matrix after hb
    u = Zero();
    check = ua * adj(ua) - 1.0;
    check = where(Accepted, check, u);
    assert(norm2(check) < 1.0e-4);
    check = b * adj(b) - 1.0;
    check = where(Accepted, check, u);
    assert(norm2(check) < 1.0e-4);
    LatticeMatrix Vcheck(grid);
    Vcheck = Zero();
    Vcheck = where(Accepted, V * adj(V) - 1.0, Vcheck);
    //    std::cout<<GridLogMessage << "SU3 check " <<norm2(Vcheck)<<std::endl;
    assert(norm2(Vcheck) < 1.0e-4);
    // Verify the link stays in SU(3)
    //    std::cout<<GridLogMessage <<"Checking the modified link"<<std::endl;
    Vcheck = link * adj(link) - 1.0;
    assert(norm2(Vcheck) < 1.0e-4);
    /////////////////////////////////
  }
  static void printGenerators(void) {
    for (int gen = 0; gen < AdjointDimension; gen++) {
      Matrix ta;
      generator(gen, ta);
      std::cout << GridLogMessage << "Nc = " << ncolour << " t_" << gen
                << std::endl;
      std::cout << GridLogMessage << ta << std::endl;
    }
  }
  static void testGenerators(void) {
    Matrix ta;
    Matrix tb;
    std::cout << GridLogMessage
              << "Fundamental - Checking trace ta tb is 0.5 delta_ab"
              << std::endl;
    for (int a = 0; a < AdjointDimension; a++) {
      for (int b = 0; b < AdjointDimension; b++) {
        generator(a, ta);
        generator(b, tb);
        Complex tr = TensorRemove(trace(ta * tb));
        std::cout << GridLogMessage << "(" << a << "," << b << ") =  " << tr
                  << std::endl;
        if (a == b) assert(abs(tr - Complex(0.5)) < 1.0e-6);
        if (a != b) assert(abs(tr) < 1.0e-6);
      }
      std::cout << GridLogMessage << std::endl;
    }
    std::cout << GridLogMessage << "Fundamental - Checking if hermitian"
              << std::endl;
    for (int a = 0; a < AdjointDimension; a++) {
      generator(a, ta);
      std::cout << GridLogMessage << a << std::endl;
      assert(norm2(ta - adj(ta)) < 1.0e-6);
    }
    std::cout << GridLogMessage << std::endl;
    std::cout << GridLogMessage << "Fundamental - Checking if traceless"
              << std::endl;
    for (int a = 0; a < AdjointDimension; a++) {
      generator(a, ta);
      Complex tr = TensorRemove(trace(ta));
      std::cout << GridLogMessage << a << " " << std::endl;
      assert(abs(tr) < 1.0e-6);
    }
    std::cout << GridLogMessage << std::endl;
  }
  // reunitarise??
  template <typename LatticeMatrixType>
  static void LieRandomize(GridParallelRNG &pRNG, LatticeMatrixType &out, double scale = 1.0) 
  {
    GridBase *grid = out.Grid();
    typedef typename LatticeMatrixType::vector_type vector_type;
    typedef iSinglet<vector_type> vTComplexType;
    typedef Lattice<vTComplexType> LatticeComplexType;
    typedef typename GridTypeMapper<typename LatticeMatrixType::vector_object>::scalar_object MatrixType;
    LatticeComplexType ca(grid);
    LatticeMatrixType lie(grid);
    LatticeMatrixType la(grid);
    ComplexD ci(0.0, scale);
    //    ComplexD cone(1.0, 0.0);
    MatrixType ta;
    lie = Zero();
    for (int a = 0; a < AdjointDimension; a++) {
      random(pRNG, ca);
      ca = (ca + conjugate(ca)) * 0.5;
      ca = ca - 0.5;
      generator(a, ta);
      la = ci * ca * ta;
      lie = lie + la;  // e^{i la ta}
    }
    taExp(lie, out);
  }
  static void GaussianFundamentalLieAlgebraMatrix(GridParallelRNG &pRNG,
                                                  LatticeMatrix &out,
                                                  Real scale = 1.0) {
    GridBase *grid = out.Grid();
    LatticeReal ca(grid);
    LatticeMatrix la(grid);
    Complex ci(0.0, scale);
    Matrix ta;
    out = Zero();
    for (int a = 0; a < AdjointDimension; a++) {
      gaussian(pRNG, ca);
      generator(a, ta);
      la = toComplex(ca) * ta;
      out += la;
    }
    out *= ci;
  }
  static void FundamentalLieAlgebraMatrix(const LatticeAlgebraVector &h,
                                          LatticeMatrix &out,
                                          Real scale = 1.0) {
    conformable(h, out);
    GridBase *grid = out.Grid();
    LatticeMatrix la(grid);
    Matrix ta;
    out = Zero();
    for (int a = 0; a < AdjointDimension; a++) {
      generator(a, ta);
      la = peekColour(h, a) * timesI(ta) * scale;
      out += la;
    }
  }
 /*
 * Fundamental rep gauge xform
 */
  template<typename Fundamental,typename GaugeMat>
  static void GaugeTransformFundamental( Fundamental &ferm, GaugeMat &g){
    GridBase *grid = ferm._grid;
    conformable(grid,g._grid);
    ferm = g*ferm;
  }
 /*
 * Adjoint rep gauge xform
 */
  template<typename Gimpl>
  static void GaugeTransform(typename Gimpl::GaugeField &Umu, typename Gimpl::GaugeLinkField &g){
    GridBase *grid = Umu.Grid();
    conformable(grid,g.Grid());
    typename Gimpl::GaugeLinkField U(grid);
    typename Gimpl::GaugeLinkField ag(grid); ag = adj(g);
    for(int mu=0;mu<Nd;mu++){
      U= PeekIndex<LorentzIndex>(Umu,mu);
      U = g*U*Gimpl::CshiftLink(ag, mu, 1); //BC-aware
      PokeIndex<LorentzIndex>(Umu,U,mu);
    }
  }
  template<typename Gimpl>
  static void GaugeTransform( std::vector<typename Gimpl::GaugeLinkField> &U, typename Gimpl::GaugeLinkField &g){
    GridBase *grid = g.Grid();
    typename Gimpl::GaugeLinkField ag(grid); ag = adj(g);
    for(int mu=0;mu<Nd;mu++){
      U[mu] = g*U[mu]*Gimpl::CshiftLink(ag, mu, 1); //BC-aware
    }
  }
  template<typename Gimpl>
  static void RandomGaugeTransform(GridParallelRNG &pRNG, typename Gimpl::GaugeField &Umu, typename Gimpl::GaugeLinkField &g){
    LieRandomize(pRNG,g,1.0);
    GaugeTransform<Gimpl>(Umu,g);
  }
  // Projects the algebra components a lattice matrix (of dimension ncol*ncol -1 )
  // inverse operation: FundamentalLieAlgebraMatrix
  static void projectOnAlgebra(LatticeAlgebraVector &h_out, const LatticeMatrix &in, Real scale = 1.0) {
    conformable(h_out, in);
    h_out = Zero();
    Matrix Ta;
    for (int a = 0; a < AdjointDimension; a++) {
      generator(a, Ta);
      pokeColour(h_out, - 2.0 * (trace(timesI(Ta) * in)) * scale, a);
    }
  }
  template <typename GaugeField>
  static void HotConfiguration(GridParallelRNG &pRNG, GaugeField &out) {
    typedef typename GaugeField::vector_type vector_type;
    typedef iSUnMatrix<vector_type> vMatrixType;
    typedef Lattice<vMatrixType> LatticeMatrixType;
    LatticeMatrixType Umu(out.Grid());
    LatticeMatrixType tmp(out.Grid());
    for (int mu = 0; mu < Nd; mu++) {
      //      LieRandomize(pRNG, Umu, 1.0);
      //      PokeIndex<LorentzIndex>(out, Umu, mu);
      gaussian(pRNG,Umu);
      tmp = Ta(Umu);
      taExp(tmp,Umu);
      ProjectSUn(Umu);
      PokeIndex<LorentzIndex>(out, Umu, mu);
    }
  }
  template<typename GaugeField>
  static void TepidConfiguration(GridParallelRNG &pRNG,GaugeField &out){
    typedef typename GaugeField::vector_type vector_type;
    typedef iSUnMatrix<vector_type> vMatrixType;
    typedef Lattice<vMatrixType> LatticeMatrixType;
    LatticeMatrixType Umu(out.Grid());
    for(int mu=0;mu<Nd;mu++){
      LieRandomize(pRNG,Umu,0.01);
      PokeIndex<LorentzIndex>(out,Umu,mu);
    }
  }
  template<typename GaugeField>
  static void ColdConfiguration(GaugeField &out){
    typedef typename GaugeField::vector_type vector_type;
    typedef iSUnMatrix<vector_type> vMatrixType;
    typedef Lattice<vMatrixType> LatticeMatrixType;
    LatticeMatrixType Umu(out.Grid());
    Umu=1.0;
    for(int mu=0;mu<Nd;mu++){
      PokeIndex<LorentzIndex>(out,Umu,mu);
    }
  }
  template<typename GaugeField>
  static void ColdConfiguration(GridParallelRNG &pRNG,GaugeField &out){
    ColdConfiguration(out);
  }
  template<typename LatticeMatrixType>
  static void taProj( const LatticeMatrixType &in,  LatticeMatrixType &out){
    out = Ta(in);
  }
  template <typename LatticeMatrixType>
  static void taExp(const LatticeMatrixType &x, LatticeMatrixType &ex) {
    typedef typename LatticeMatrixType::scalar_type ComplexType;
    LatticeMatrixType xn(x.Grid());
    RealD nfac = 1.0;
    xn = x;
    ex = xn + ComplexType(1.0);  // 1+x
    // Do a 12th order exponentiation
    for (int i = 2; i <= 12; ++i) {
      nfac = nfac / RealD(i);  // 1/2, 1/2.3 ...
      xn = xn * x;             // x2, x3,x4....
      ex = ex + xn * nfac;     // x2/2!, x3/3!....
    }
  }
 };
 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;
 }
 // Explicit specialisation for SU(3).
 // Explicit specialisation for SU(3).
 static void
 ProjectSU3 (Lattice<iScalar<iScalar<iMatrix<vComplexD, 3> > > > &Umu)
 {
  GridBase *grid=Umu.Grid();
  const int x=0;
  const int y=1;
  const int z=2;
  // Reunitarise
  Umu = ProjectOnGroup(Umu);
  autoView(Umu_v,Umu,CpuWrite);
  thread_for(ss,grid->oSites(),{
      auto cm = Umu_v[ss];
      cm()()(2,x) = adj(cm()()(0,y)*cm()()(1,z)-cm()()(0,z)*cm()()(1,y)); //x= yz-zy
      cm()()(2,y) = adj(cm()()(0,z)*cm()()(1,x)-cm()()(0,x)*cm()()(1,z)); //y= zx-xz
      cm()()(2,z) = adj(cm()()(0,x)*cm()()(1,y)-cm()()(0,y)*cm()()(1,x)); //z= xy-yx
      Umu_v[ss]=cm;
  });
 }
 static void ProjectSU3(Lattice<iVector<iScalar<iMatrix<vComplexD, 3> >,Nd> > &U)
 {
  GridBase *grid=U.Grid();
  // Reunitarise
  for(int mu=0;mu<Nd;mu++){
    auto Umu = PeekIndex<LorentzIndex>(U,mu);
    Umu      = ProjectOnGroup(Umu);
    ProjectSU3(Umu);
    PokeIndex<LorentzIndex>(U,Umu,mu);
  }
 }
 typedef SU<2> SU2;
 typedef SU<3> SU3;
 typedef SU<4> SU4;
 typedef SU<5> SU5;
 typedef SU<Nc> FundamentalMatrices;
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/qcd/utils/SUn.impl.h
+++ b/Grid/qcd/utils/SUn.impl.h
@ -0,0 +1,580 @@
 // This file is #included into the body of the class template definition of
 // GaugeGroup. So, image there to be
 //
 // template <int ncolour, class group_name>
 // class GaugeGroup {
 //
 // around it.
 //
 // Please note that the unconventional file extension makes sure that it
 // doesn't get found by the scripts/filelist during bootstrapping.
 private:
 template <ONLY_IF_SU>
 static int su2subgroups(GroupName::SU) { return (ncolour * (ncolour - 1)) / 2; }
 ////////////////////////////////////////////////////////////////////////
 // There are N^2-1 generators for SU(N).
 //
 // We take a traceless hermitian generator basis as follows
 //
 // * Normalisation: trace ta tb = 1/2 delta_ab = T_F delta_ab
 //   T_F = 1/2  for SU(N) groups
 //
 // * Off diagonal
 //    - pairs of rows i1,i2 behaving like pauli matrices signma_x, sigma_y
 //
 //    - there are (Nc-1-i1) slots for i2 on each row [ x  0  x ]
 //      direct count off each row
 //
 //    - Sum of all pairs is Nc(Nc-1)/2: proof arithmetic series
 //
 //      (Nc-1) + (Nc-2)+...  1      ==> Nc*(Nc-1)/2
 //      1+ 2+          +   + Nc-1
 //
 //    - There are 2 x Nc (Nc-1)/ 2 of these = Nc^2 - Nc
 //
 //    - We enumerate the row-col pairs.
 //    - for each row col pair there is a (sigma_x) and a (sigma_y) like
 //    generator
 //
 //
 //   t^a_ij = { in 0.. Nc(Nc-1)/2 -1} =>  1/2(delta_{i,i1} delta_{j,i2} +
 //   delta_{i,i1} delta_{j,i2})
 //   t^a_ij = { in Nc(Nc-1)/2 ... Nc(Nc-1) - 1} =>  i/2( delta_{i,i1}
 //   delta_{j,i2} - i delta_{i,i1} delta_{j,i2})
 //
 // * Diagonal; must be traceless and normalised
 //   - Sequence is
 //   N  (1,-1,0,0...)
 //   N  (1, 1,-2,0...)
 //   N  (1, 1, 1,-3,0...)
 //   N  (1, 1, 1, 1,-4,0...)
 //
 //   where 1/2 = N^2 (1+.. m^2)etc.... for the m-th diagonal generator
 //   NB this gives the famous SU3 result for su2 index 8
 //
 //   N= sqrt(1/2 . 1/6 ) = 1/2 . 1/sqrt(3)
 //
 //   ( 1      )
 //   (    1   ) / sqrt(3) /2  = 1/2 lambda_8
 //   (      -2)
 //
 ////////////////////////////////////////////////////////////////////////
 template <class cplx, ONLY_IF_SU>
 static void generator(int lieIndex, iGroupMatrix<cplx> &ta, GroupName::SU) {
  // map lie index to which type of generator
  int diagIndex;
  int su2Index;
  int sigxy;
  int NNm1 = ncolour * (ncolour - 1);
  if (lieIndex >= NNm1) {
    diagIndex = lieIndex - NNm1;
    generatorDiagonal(diagIndex, ta);
    return;
  }
  sigxy = lieIndex & 0x1;  // even or odd
  su2Index = lieIndex >> 1;
  if (sigxy)
    generatorSigmaY(su2Index, ta);
  else
    generatorSigmaX(su2Index, ta);
 }
 template <class cplx, ONLY_IF_SU>
 static void generatorSigmaY(int su2Index, iGroupMatrix<cplx> &ta) {
  ta = Zero();
  int i1, i2;
  su2SubGroupIndex(i1, i2, su2Index);
  ta()()(i1, i2) = 1.0;
  ta()()(i2, i1) = 1.0;
  ta = ta * 0.5;
 }
 template <class cplx, ONLY_IF_SU>
 static void generatorSigmaX(int su2Index, iGroupMatrix<cplx> &ta) {
  ta = Zero();
  cplx i(0.0, 1.0);
  int i1, i2;
  su2SubGroupIndex(i1, i2, su2Index);
  ta()()(i1, i2) = i;
  ta()()(i2, i1) = -i;
  ta = ta * 0.5;
 }
 template <class cplx, ONLY_IF_SU>
 static void generatorDiagonal(int diagIndex, iGroupMatrix<cplx> &ta) {
  // diag ({1, 1, ..., 1}(k-times), -k, 0, 0, ...)
  ta = Zero();
  int k = diagIndex + 1;                  // diagIndex starts from 0
  for (int i = 0; i <= diagIndex; i++) {  // k iterations
    ta()()(i, i) = 1.0;
  }
  ta()()(k, k) = -k;  // indexing starts from 0
  RealD nrm = 1.0 / std::sqrt(2.0 * k * (k + 1));
  ta = ta * nrm;
 }
 ////////////////////////////////////////////////////////////////////////
 // Map a su2 subgroup number to the pair of rows that are non zero
 ////////////////////////////////////////////////////////////////////////
 static void su2SubGroupIndex(int &i1, int &i2, int su2_index, GroupName::SU) {
  assert((su2_index >= 0) && (su2_index < (ncolour * (ncolour - 1)) / 2));
  int spare = su2_index;
  for (i1 = 0; spare >= (ncolour - 1 - i1); i1++) {
    spare = spare - (ncolour - 1 - i1);  // remove the Nc-1-i1 terms
  }
  i2 = i1 + 1 + spare;
 }
 public:
 //////////////////////////////////////////////////////////////////////////////////////////
 // Pull out a subgroup and project on to real coeffs x pauli basis
 //////////////////////////////////////////////////////////////////////////////////////////
 template <class vcplx, ONLY_IF_SU>
 static void su2Extract(Lattice<iSinglet<vcplx> > &Determinant,
                       Lattice<iSU2Matrix<vcplx> > &subgroup,
                       const Lattice<iGroupMatrix<vcplx> > &source,
                       int su2_index) {
  GridBase *grid(source.Grid());
  conformable(subgroup, source);
  conformable(subgroup, Determinant);
  int i0, i1;
  su2SubGroupIndex(i0, i1, su2_index);
  autoView(subgroup_v, subgroup, AcceleratorWrite);
  autoView(source_v, source, AcceleratorRead);
  autoView(Determinant_v, Determinant, AcceleratorWrite);
  accelerator_for(ss, grid->oSites(), 1, {
    subgroup_v[ss]()()(0, 0) = source_v[ss]()()(i0, i0);
    subgroup_v[ss]()()(0, 1) = source_v[ss]()()(i0, i1);
    subgroup_v[ss]()()(1, 0) = source_v[ss]()()(i1, i0);
    subgroup_v[ss]()()(1, 1) = source_v[ss]()()(i1, i1);
    iSU2Matrix<vcplx> Sigma = subgroup_v[ss];
    Sigma = Sigma - adj(Sigma) + trace(adj(Sigma));
    subgroup_v[ss] = Sigma;
    // this should be purely real
    Determinant_v[ss] =
        Sigma()()(0, 0) * Sigma()()(1, 1) - Sigma()()(0, 1) * Sigma()()(1, 0);
  });
 }
 //////////////////////////////////////////////////////////////////////////////////////////
 // Set matrix to one and insert a pauli subgroup
 //////////////////////////////////////////////////////////////////////////////////////////
 template <class vcplx, ONLY_IF_SU>
 static void su2Insert(const Lattice<iSU2Matrix<vcplx> > &subgroup,
                      Lattice<iGroupMatrix<vcplx> > &dest, int su2_index) {
  GridBase *grid(dest.Grid());
  conformable(subgroup, dest);
  int i0, i1;
  su2SubGroupIndex(i0, i1, su2_index);
  dest = 1.0;  // start out with identity
  autoView(dest_v, dest, AcceleratorWrite);
  autoView(subgroup_v, subgroup, AcceleratorRead);
  accelerator_for(ss, grid->oSites(), 1, {
    dest_v[ss]()()(i0, i0) = subgroup_v[ss]()()(0, 0);
    dest_v[ss]()()(i0, i1) = subgroup_v[ss]()()(0, 1);
    dest_v[ss]()()(i1, i0) = subgroup_v[ss]()()(1, 0);
    dest_v[ss]()()(i1, i1) = subgroup_v[ss]()()(1, 1);
  });
 }
 ///////////////////////////////////////////////
 // Generate e^{ Re Tr Staple Link} dlink
 //
 // *** Note Staple should be appropriate linear compbination between all
 // staples.
 // *** If already by beta pass coefficient 1.0.
 // *** This routine applies the additional 1/Nc factor that comes after trace
 // in action.
 //
 ///////////////////////////////////////////////
 template <ONLY_IF_SU>
 static void SubGroupHeatBath(
    GridSerialRNG &sRNG, GridParallelRNG &pRNG,
    RealD beta,  // coeff multiplying staple in action (with no 1/Nc)
    LatticeMatrix &link,
    const LatticeMatrix &barestaple,  // multiplied by action coeffs so th
    int su2_subgroup, int nheatbath, LatticeInteger &wheremask) {
  GridBase *grid = link.Grid();
  const RealD twopi = 2.0 * M_PI;
  LatticeMatrix staple(grid);
  staple = barestaple * (beta / ncolour);
  LatticeMatrix V(grid);
  V = link * staple;
  // Subgroup manipulation in the lie algebra space
  LatticeSU2Matrix u(
      grid);  // Kennedy pendleton "u" real projected normalised Sigma
  LatticeSU2Matrix uinv(grid);
  LatticeSU2Matrix ua(grid);  // a in pauli form
  LatticeSU2Matrix b(grid);   // rotated matrix after hb
  // Some handy constant fields
  LatticeComplex ones(grid);
  ones = 1.0;
  LatticeComplex zeros(grid);
  zeros = Zero();
  LatticeReal rones(grid);
  rones = 1.0;
  LatticeReal rzeros(grid);
  rzeros = Zero();
  LatticeComplex udet(grid);  // determinant of real(staple)
  LatticeInteger mask_true(grid);
  mask_true = 1;
  LatticeInteger mask_false(grid);
  mask_false = 0;
  /*
    PLB 156 P393 (1985) (Kennedy and Pendleton)
    Note: absorb "beta" into the def of sigma compared to KP paper; staple
    passed to this routine has "beta" already multiplied in
    Action linear in links h and of form:
    beta S = beta  Sum_p (1 - 1/Nc Re Tr Plaq )
    Writing Sigma = 1/Nc (beta Sigma') where sum over staples is "Sigma' "
    beta S = const - beta/Nc Re Tr h Sigma'
    = const - Re Tr h Sigma
    Decompose h and Sigma into (1, sigma_j) ; h_i real, h^2=1, Sigma_i complex
    arbitrary.
    Tr h Sigma = h_i Sigma_j Tr (sigma_i sigma_j)  = h_i Sigma_j 2 delta_ij
    Re Tr h Sigma = 2 h_j Re Sigma_j
    Normalised re Sigma_j = xi u_j
    With u_j a unit vector and U can be in SU(2);
    Re Tr h Sigma = 2 h_j Re Sigma_j = 2 xi (h.u)
    4xi^2 = Det [ Sig - Sig^dag  + 1 Tr Sigdag]
    u   = 1/2xi [ Sig - Sig^dag  + 1 Tr Sigdag]
    xi = sqrt(Det)/2;
    Write a= u h in SU(2); a has pauli decomp a_j;
    Note: Product b' xi is unvariant because scaling Sigma leaves
    normalised vector "u" fixed; Can rescale Sigma so b' = 1.
  */
  ////////////////////////////////////////////////////////
  // Real part of Pauli decomposition
  // Note a subgroup can project to zero in cold start
  ////////////////////////////////////////////////////////
  su2Extract(udet, u, V, su2_subgroup);
  //////////////////////////////////////////////////////
  // Normalising this vector if possible; else identity
  //////////////////////////////////////////////////////
  LatticeComplex xi(grid);
  LatticeSU2Matrix lident(grid);
  SU2Matrix ident = Complex(1.0);
  SU2Matrix pauli1;
  GaugeGroup<2, GroupName::SU>::generator(0, pauli1);
  SU2Matrix pauli2;
  GaugeGroup<2, GroupName::SU>::generator(1, pauli2);
  SU2Matrix pauli3;
  GaugeGroup<2, GroupName::SU>::generator(2, pauli3);
  pauli1 = timesI(pauli1) * 2.0;
  pauli2 = timesI(pauli2) * 2.0;
  pauli3 = timesI(pauli3) * 2.0;
  LatticeComplex cone(grid);
  LatticeReal adet(grid);
  adet = abs(toReal(udet));
  lident = Complex(1.0);
  cone = Complex(1.0);
  Real machine_epsilon = 1.0e-7;
  u = where(adet > machine_epsilon, u, lident);
  udet = where(adet > machine_epsilon, udet, cone);
  xi = 0.5 * sqrt(udet);        // 4xi^2 = Det [ Sig - Sig^dag  + 1 Tr Sigdag]
  u = 0.5 * u * pow(xi, -1.0);  //  u   = 1/2xi [ Sig - Sig^dag  + 1 Tr Sigdag]
  // Debug test for sanity
  uinv = adj(u);
  b = u * uinv - 1.0;
  assert(norm2(b) < 1.0e-4);
  /*
    Measure: Haar measure dh has d^4a delta(1-|a^2|)
    In polars:
    da = da0 r^2 sin theta dr dtheta dphi delta( 1 - r^2 -a0^2)
    = da0 r^2 sin theta dr dtheta dphi delta( (sqrt(1-a0^) - r)(sqrt(1-a0^) +
    r) )
    = da0 r/2 sin theta dr dtheta dphi delta( (sqrt(1-a0^) - r) )
    Action factor Q(h) dh  = e^-S[h]  dh =  e^{  xi Tr uh} dh    // beta
    enters through xi =  e^{2 xi (h.u)} dh =  e^{2 xi h0u0}.e^{2 xi h1u1}.e^{2
    xi h2u2}.e^{2 xi h3u3} dh
    Therefore for each site, take xi for that site
    i) generate  |a0|<1 with dist
    (1-a0^2)^0.5 e^{2 xi a0 } da0
    Take alpha = 2 xi  = 2 xi [ recall 2 beta/Nc unmod staple norm];
    hence 2.0/Nc factor in Chroma ] A. Generate two uniformly distributed
    pseudo-random numbers R and R', R'', R''' in the unit interval; B. Set X =
    -(ln R)/alpha, X' =-(ln R')/alpha; C. Set C = cos^2(2pi R"), with R"
    another uniform random number in [0,1] ; D. Set A = XC; E. Let d  = X'+A;
    F. If R'''^2 :> 1 - 0.5 d,  go back to A;
    G. Set a0 = 1 - d;
    Note that in step D setting B ~ X - A and using B in place of A in step E
    will generate a second independent a 0 value.
  */
  /////////////////////////////////////////////////////////
  // count the number of sites by picking "1"'s out of hat
  /////////////////////////////////////////////////////////
  Integer hit = 0;
  LatticeReal rtmp(grid);
  rtmp = where(wheremask, rones, rzeros);
  RealD numSites = sum(rtmp);
  RealD numAccepted;
  LatticeInteger Accepted(grid);
  Accepted = Zero();
  LatticeInteger newlyAccepted(grid);
  std::vector<LatticeReal> xr(4, grid);
  std::vector<LatticeReal> a(4, grid);
  LatticeReal d(grid);
  d = Zero();
  LatticeReal alpha(grid);
  //    std::cout<<GridLogMessage<<"xi "<<xi <<std::endl;
  xi = 2.0 * xi;
  alpha = toReal(xi);
  do {
    // A. Generate two uniformly distributed pseudo-random numbers R and R',
    // R'', R''' in the unit interval;
    random(pRNG, xr[0]);
    random(pRNG, xr[1]);
    random(pRNG, xr[2]);
    random(pRNG, xr[3]);
    // B. Set X = - ln R/alpha, X' = -ln R'/alpha
    xr[1] = -log(xr[1]) / alpha;
    xr[2] = -log(xr[2]) / alpha;
    // C. Set C = cos^2(2piR'')
    xr[3] = cos(xr[3] * twopi);
    xr[3] = xr[3] * xr[3];
    LatticeReal xrsq(grid);
    // D. Set A = XC;
    // E. Let d  = X'+A;
    xrsq = xr[2] + xr[1] * xr[3];
    d = where(Accepted, d, xr[2] + xr[1] * xr[3]);
    // F. If R'''^2 :> 1 - 0.5 d,  go back to A;
    LatticeReal thresh(grid);
    thresh = 1.0 - d * 0.5;
    xrsq = xr[0] * xr[0];
    LatticeInteger ione(grid);
    ione = 1;
    LatticeInteger izero(grid);
    izero = Zero();
    newlyAccepted = where(xrsq < thresh, ione, izero);
    Accepted = where(newlyAccepted, newlyAccepted, Accepted);
    Accepted = where(wheremask, Accepted, izero);
    // FIXME need an iSum for integer to avoid overload on return type??
    rtmp = where(Accepted, rones, rzeros);
    numAccepted = sum(rtmp);
    hit++;
  } while ((numAccepted < numSites) && (hit < nheatbath));
  // G. Set a0 = 1 - d;
  a[0] = Zero();
  a[0] = where(wheremask, 1.0 - d, a[0]);
  //////////////////////////////////////////
  //    ii) generate a_i uniform on two sphere radius (1-a0^2)^0.5
  //////////////////////////////////////////
  LatticeReal a123mag(grid);
  a123mag = sqrt(abs(1.0 - a[0] * a[0]));
  LatticeReal cos_theta(grid);
  LatticeReal sin_theta(grid);
  LatticeReal phi(grid);
  random(pRNG, phi);
  phi = phi * twopi;  // uniform in [0,2pi]
  random(pRNG, cos_theta);
  cos_theta = (cos_theta * 2.0) - 1.0;  // uniform in [-1,1]
  sin_theta = sqrt(abs(1.0 - cos_theta * cos_theta));
  a[1] = a123mag * sin_theta * cos(phi);
  a[2] = a123mag * sin_theta * sin(phi);
  a[3] = a123mag * cos_theta;
  ua = toComplex(a[0]) * ident + toComplex(a[1]) * pauli1 +
       toComplex(a[2]) * pauli2 + toComplex(a[3]) * pauli3;
  b = 1.0;
  b = where(wheremask, uinv * ua, b);
  su2Insert(b, V, su2_subgroup);
  // mask the assignment back based on Accptance
  link = where(Accepted, V * link, link);
  //////////////////////////////
  // Debug Checks
  // SU2 check
  LatticeSU2Matrix check(grid);  // rotated matrix after hb
  u = Zero();
  check = ua * adj(ua) - 1.0;
  check = where(Accepted, check, u);
  assert(norm2(check) < 1.0e-4);
  check = b * adj(b) - 1.0;
  check = where(Accepted, check, u);
  assert(norm2(check) < 1.0e-4);
  LatticeMatrix Vcheck(grid);
  Vcheck = Zero();
  Vcheck = where(Accepted, V * adj(V) - 1.0, Vcheck);
  //    std::cout<<GridLogMessage << "SU3 check " <<norm2(Vcheck)<<std::endl;
  assert(norm2(Vcheck) < 1.0e-4);
  // Verify the link stays in SU(3)
  //    std::cout<<GridLogMessage <<"Checking the modified link"<<std::endl;
  Vcheck = link * adj(link) - 1.0;
  assert(norm2(Vcheck) < 1.0e-4);
  /////////////////////////////////
 }
 template <ONLY_IF_SU>
 static void testGenerators(GroupName::SU) {
  Matrix ta;
  Matrix tb;
  std::cout << GridLogMessage
            << "Fundamental - Checking trace ta tb is 0.5 delta_ab"
            << std::endl;
  for (int a = 0; a < AdjointDimension; a++) {
    for (int b = 0; b < AdjointDimension; b++) {
      generator(a, ta);
      generator(b, tb);
      Complex tr = TensorRemove(trace(ta * tb));
      std::cout << GridLogMessage << "(" << a << "," << b << ") =  " << tr
                << std::endl;
      if (a == b) assert(abs(tr - Complex(0.5)) < 1.0e-6);
      if (a != b) assert(abs(tr) < 1.0e-6);
    }
    std::cout << GridLogMessage << std::endl;
  }
  std::cout << GridLogMessage << "Fundamental - Checking if hermitian"
            << std::endl;
  for (int a = 0; a < AdjointDimension; a++) {
    generator(a, ta);
    std::cout << GridLogMessage << a << std::endl;
    assert(norm2(ta - adj(ta)) < 1.0e-6);
  }
  std::cout << GridLogMessage << std::endl;
  std::cout << GridLogMessage << "Fundamental - Checking if traceless"
            << std::endl;
  for (int a = 0; a < AdjointDimension; a++) {
    generator(a, ta);
    Complex tr = TensorRemove(trace(ta));
    std::cout << GridLogMessage << a << " " << std::endl;
    assert(abs(tr) < 1.0e-6);
  }
  std::cout << GridLogMessage << std::endl;
 }
 template <int N, class vtype>
 static Lattice<iScalar<iScalar<iMatrix<vtype, N> > > >
 ProjectOnGeneralGroup(const Lattice<iScalar<iScalar<iMatrix<vtype, N> > > > &Umu, GroupName::SU) {
  return ProjectOnGroup(Umu);
 }
 template <class vtype>
 accelerator_inline static iScalar<vtype> ProjectOnGeneralGroup(const iScalar<vtype> &r, GroupName::SU) {
  return ProjectOnGroup(r);
 }
 template <class vtype, int N>
 accelerator_inline static iVector<vtype,N> ProjectOnGeneralGroup(const iVector<vtype,N> &r, GroupName::SU) {
  return ProjectOnGroup(r);
 }
 template <class vtype,int N, typename std::enable_if< GridTypeMapper<vtype>::TensorLevel == 0 >::type * =nullptr>
 accelerator_inline static iMatrix<vtype,N> ProjectOnGeneralGroup(const iMatrix<vtype,N> &arg, GroupName::SU) {
  return ProjectOnGroup(arg);
 }
 template <typename LatticeMatrixType>
 static void taProj(const LatticeMatrixType &in, LatticeMatrixType &out, GroupName::SU) {
  out = Ta(in);
 }
 /*
 * Fundamental rep gauge xform
 */
 template<typename Fundamental,typename GaugeMat>
 static void GaugeTransformFundamental( Fundamental &ferm, GaugeMat &g){
  GridBase *grid = ferm._grid;
  conformable(grid,g._grid);
  ferm = g*ferm;
 }
 /*
 * Adjoint rep gauge xform
 */
 template<typename Gimpl>
 static void GaugeTransform(typename Gimpl::GaugeField &Umu, typename Gimpl::GaugeLinkField &g){
  GridBase *grid = Umu.Grid();
  conformable(grid,g.Grid());
  typename Gimpl::GaugeLinkField U(grid);
  typename Gimpl::GaugeLinkField ag(grid); ag = adj(g);
  for(int mu=0;mu<Nd;mu++){
    U= PeekIndex<LorentzIndex>(Umu,mu);
    U = g*U*Gimpl::CshiftLink(ag, mu, 1); //BC-aware
    PokeIndex<LorentzIndex>(Umu,U,mu);
  }
 }
 template<typename Gimpl>
 static void GaugeTransform( std::vector<typename Gimpl::GaugeLinkField> &U, typename Gimpl::GaugeLinkField &g){
  GridBase *grid = g.Grid();
  typename Gimpl::GaugeLinkField ag(grid); ag = adj(g);
  for(int mu=0;mu<Nd;mu++){
    U[mu] = g*U[mu]*Gimpl::CshiftLink(ag, mu, 1); //BC-aware
  }
 }
 template<typename Gimpl>
 static void RandomGaugeTransform(GridParallelRNG &pRNG, typename Gimpl::GaugeField &Umu, typename Gimpl::GaugeLinkField &g){
  LieRandomize(pRNG,g,1.0);
  GaugeTransform<Gimpl>(Umu,g);
 }
--- a/Grid/qcd/utils/SUnAdjoint.h
+++ b/Grid/qcd/utils/SUnAdjoint.h
@ -51,6 +51,10 @@ public:
  typedef Lattice<iVector<iScalar<iMatrix<vComplexF, Dimension> >, Nd> > LatticeAdjFieldF;
  typedef Lattice<iVector<iScalar<iMatrix<vComplexD, Dimension> >, Nd> > LatticeAdjFieldD;
  template <typename vtype>
  using iSUnMatrix = iScalar<iScalar<iMatrix<vtype, ncolour> > >;
  typedef Lattice<iScalar<iScalar<iVector<vComplex, Dimension> > > >  LatticeAdjVector;
  template <class cplx>
@ -58,8 +62,8 @@ public:
    // returns i(T_Adj)^index necessary for the projectors
    // see definitions above
    iAdjTa = Zero();
-    Vector<typename SU<ncolour>::template iSUnMatrix<cplx> > ta(ncolour * ncolour - 1);
+    Vector<iSUnMatrix<cplx> > ta(ncolour * ncolour - 1);
-    typename SU<ncolour>::template iSUnMatrix<cplx> tmp;
+    iSUnMatrix<cplx> tmp;
    // FIXME not very efficient to get all the generators everytime
    for (int a = 0; a < Dimension; a++) SU<ncolour>::generator(a, ta[a]);
@ -67,8 +71,7 @@ public:
    for (int a = 0; a < Dimension; a++) {
      tmp = ta[a] * ta[Index] - ta[Index] * ta[a];
      for (int b = 0; b < (ncolour * ncolour - 1); b++) {
-        typename SU<ncolour>::template iSUnMatrix<cplx> tmp1 =
+        iSUnMatrix<cplx> tmp1 = 2.0 * tmp * ta[b];  // 2.0 from the normalization
 	  2.0 * tmp * ta[b];  // 2.0 from the normalization
        Complex iTr = TensorRemove(timesI(trace(tmp1)));
        //iAdjTa()()(b, a) = iTr;
        iAdjTa()()(a, b) = iTr;
@ -134,8 +137,7 @@ public:
    for (int a = 0; a < Dimension; a++) {
      generator(a, iTa);
-      LatticeComplex tmp = real(trace(iTa * in)) * coefficient;
+      pokeColour(h_out, real(trace(iTa * in)) * coefficient, a);
      pokeColour(h_out, tmp, a);
    }
  }
--- a/Grid/qcd/utils/SUnTwoIndex.h
+++ b/Grid/qcd/utils/SUnTwoIndex.h
@ -1,273 +0,0 @@
 ////////////////////////////////////////////////////////////////////////
 //
 // * Two index representation generators
 //
 // * Normalisation for the fundamental generators:
 //   trace ta tb = 1/2 delta_ab = T_F delta_ab
 //   T_F = 1/2  for SU(N) groups
 //
 //
 //   base for NxN two index (anti-symmetric) matrices
 //   normalized to 1 (d_ij is the kroenecker delta)
 //
 //   (e^(ij)_{kl} = 1 / sqrt(2) (d_ik d_jl +/- d_jk d_il)
 //
 //   Then the generators are written as
 //
 //   (iT_a)^(ij)(lk) = i * ( tr[e^(ij)^dag e^(lk) T^trasp_a] +
 //   tr[e^(lk)e^(ij)^dag T_a] )  //
 //   
 //
 ////////////////////////////////////////////////////////////////////////
 // Authors: David Preti, Guido Cossu
 #ifndef QCD_UTIL_SUN2INDEX_H
 #define QCD_UTIL_SUN2INDEX_H
 NAMESPACE_BEGIN(Grid);
 enum TwoIndexSymmetry { Symmetric = 1, AntiSymmetric = -1 };
 inline Real delta(int a, int b) { return (a == b) ? 1.0 : 0.0; }
 template <int ncolour, TwoIndexSymmetry S>
 class SU_TwoIndex : public SU<ncolour> {
 public:
  static const int Dimension = ncolour * (ncolour + S) / 2;
  static const int NumGenerators = SU<ncolour>::AdjointDimension;
  template <typename vtype>
  using iSUnTwoIndexMatrix = iScalar<iScalar<iMatrix<vtype, Dimension> > >;
  typedef iSUnTwoIndexMatrix<Complex> TIMatrix;
  typedef iSUnTwoIndexMatrix<ComplexF> TIMatrixF;
  typedef iSUnTwoIndexMatrix<ComplexD> TIMatrixD;
  typedef iSUnTwoIndexMatrix<vComplex> vTIMatrix;
  typedef iSUnTwoIndexMatrix<vComplexF> vTIMatrixF;
  typedef iSUnTwoIndexMatrix<vComplexD> vTIMatrixD;
  typedef Lattice<vTIMatrix> LatticeTwoIndexMatrix;
  typedef Lattice<vTIMatrixF> LatticeTwoIndexMatrixF;
  typedef Lattice<vTIMatrixD> LatticeTwoIndexMatrixD;
  typedef Lattice<iVector<iScalar<iMatrix<vComplex, Dimension> >, Nd> >
  LatticeTwoIndexField;
  typedef Lattice<iVector<iScalar<iMatrix<vComplexF, Dimension> >, Nd> >
  LatticeTwoIndexFieldF;
  typedef Lattice<iVector<iScalar<iMatrix<vComplexD, Dimension> >, Nd> >
  LatticeTwoIndexFieldD;
  template <typename vtype>
  using iSUnMatrix = iScalar<iScalar<iMatrix<vtype, ncolour> > >;
  typedef iSUnMatrix<Complex> Matrix;
  typedef iSUnMatrix<ComplexF> MatrixF;
  typedef iSUnMatrix<ComplexD> MatrixD;
  template <class cplx>
  static void base(int Index, iSUnMatrix<cplx> &eij) {
    // returns (e)^(ij)_{kl} necessary for change of base U_F -> U_R
    assert(Index < NumGenerators);
    eij = Zero();
    // for the linearisation of the 2 indexes 
    static int a[ncolour * (ncolour - 1) / 2][2]; // store the a <-> i,j
    static bool filled = false;
    if (!filled) {
      int counter = 0;
      for (int i = 1; i < ncolour; i++) {
        for (int j = 0; j < i; j++) {
          a[counter][0] = i;
          a[counter][1] = j;
          counter++;
        }
      }
      filled = true;
    }
    if (Index < ncolour * (ncolour - 1) / 2) {
      baseOffDiagonal(a[Index][0], a[Index][1], eij);
    } else {
      baseDiagonal(Index, eij);
    }
  }
  template <class cplx>
  static void baseDiagonal(int Index, iSUnMatrix<cplx> &eij) {
    eij = Zero();
    eij()()(Index - ncolour * (ncolour - 1) / 2,
            Index - ncolour * (ncolour - 1) / 2) = 1.0;
  }
  template <class cplx>
  static void baseOffDiagonal(int i, int j, iSUnMatrix<cplx> &eij) {
    eij = Zero();
    for (int k = 0; k < ncolour; k++)
      for (int l = 0; l < ncolour; l++)
        eij()()(l, k) = delta(i, k) * delta(j, l) +
 	  S * delta(j, k) * delta(i, l);
    RealD nrm = 1. / std::sqrt(2.0);
    eij = eij * nrm;
  }
  static void printBase(void) {
    for (int gen = 0; gen < Dimension; gen++) {
      Matrix tmp;
      base(gen, tmp);
      std::cout << GridLogMessage << "Nc = " << ncolour << " t_" << gen
                << std::endl;
      std::cout << GridLogMessage << tmp << std::endl;
    }
  }
  template <class cplx>
  static void generator(int Index, iSUnTwoIndexMatrix<cplx> &i2indTa) {
    Vector<typename SU<ncolour>::template iSUnMatrix<cplx> > ta(
 								ncolour * ncolour - 1);
    Vector<typename SU<ncolour>::template iSUnMatrix<cplx> > eij(Dimension);
    typename SU<ncolour>::template iSUnMatrix<cplx> tmp;
    i2indTa = Zero();
    for (int a = 0; a < ncolour * ncolour - 1; a++)
      SU<ncolour>::generator(a, ta[a]);
    for (int a = 0; a < Dimension; a++) base(a, eij[a]);
    for (int a = 0; a < Dimension; a++) {
      tmp = transpose(ta[Index]) * adj(eij[a]) + adj(eij[a]) * ta[Index];
      for (int b = 0; b < Dimension; b++) {
        typename SU<ncolour>::template iSUnMatrix<cplx> tmp1 =
 	  tmp * eij[b]; 
        Complex iTr = TensorRemove(timesI(trace(tmp1)));
        i2indTa()()(a, b) = iTr;
      }
    }
  }
  static void printGenerators(void) {
    for (int gen = 0; gen < ncolour * ncolour - 1; gen++) {
      TIMatrix i2indTa;
      generator(gen, i2indTa);
      std::cout << GridLogMessage << "Nc = " << ncolour << " t_" << gen
                << std::endl;
      std::cout << GridLogMessage << i2indTa << std::endl;
    }
  }
  static void testGenerators(void) {
    TIMatrix i2indTa, i2indTb;
    std::cout << GridLogMessage << "2IndexRep - Checking if traceless"
              << std::endl;
    for (int a = 0; a < ncolour * ncolour - 1; a++) {
      generator(a, i2indTa);
      std::cout << GridLogMessage << a << std::endl;
      assert(norm2(trace(i2indTa)) < 1.0e-6);
    }
    std::cout << GridLogMessage << std::endl;
    std::cout << GridLogMessage << "2IndexRep - Checking if antihermitean"
              << std::endl;
    for (int a = 0; a < ncolour * ncolour - 1; a++) {
      generator(a, i2indTa);
      std::cout << GridLogMessage << a << std::endl;
      assert(norm2(adj(i2indTa) + i2indTa) < 1.0e-6);
    }
    std::cout << GridLogMessage << std::endl;
    std::cout << GridLogMessage
              << "2IndexRep - Checking Tr[Ta*Tb]=delta(a,b)*(N +- 2)/2"
              << std::endl;
    for (int a = 0; a < ncolour * ncolour - 1; a++) {
      for (int b = 0; b < ncolour * ncolour - 1; b++) {
        generator(a, i2indTa);
        generator(b, i2indTb);
        // generator returns iTa, so we need a minus sign here
        Complex Tr = -TensorRemove(trace(i2indTa * i2indTb));
        std::cout << GridLogMessage << "a=" << a << "b=" << b << "Tr=" << Tr
                  << std::endl;
      }
    }
    std::cout << GridLogMessage << std::endl;
  }
  static void TwoIndexLieAlgebraMatrix(
 				       const typename SU<ncolour>::LatticeAlgebraVector &h,
 				       LatticeTwoIndexMatrix &out, Real scale = 1.0) {
    conformable(h, out);
    GridBase *grid = out.Grid();
    LatticeTwoIndexMatrix la(grid);
    TIMatrix i2indTa;
    out = Zero();
    for (int a = 0; a < ncolour * ncolour - 1; a++) {
      generator(a, i2indTa);
      la = peekColour(h, a) * i2indTa;
      out += la;
    }
    out *= scale;
  }
  // Projects the algebra components 
  // of a lattice matrix ( of dimension ncol*ncol -1 )
  static void projectOnAlgebra(
 			       typename SU<ncolour>::LatticeAlgebraVector &h_out,
 			       const LatticeTwoIndexMatrix &in, Real scale = 1.0) {
    conformable(h_out, in);
    h_out = Zero();
    TIMatrix i2indTa;
    Real coefficient = -2.0 / (ncolour + 2 * S) * scale;
    // 2/(Nc +/- 2) for the normalization of the trace in the two index rep
    for (int a = 0; a < ncolour * ncolour - 1; a++) {
      generator(a, i2indTa);
      auto tmp = real(trace(i2indTa * in)) * coefficient;
      pokeColour(h_out, tmp, a);
    }
  }
  // a projector that keeps the generators stored to avoid the overhead of
  // recomputing them
  static void projector(typename SU<ncolour>::LatticeAlgebraVector &h_out,
                        const LatticeTwoIndexMatrix &in, Real scale = 1.0) {
    conformable(h_out, in);
    // to store the generators
    static std::vector<TIMatrix> i2indTa(ncolour * ncolour -1); 
    h_out = Zero();
    static bool precalculated = false;
    if (!precalculated) {
      precalculated = true;
      for (int a = 0; a < ncolour * ncolour - 1; a++) generator(a, i2indTa[a]);
    }
    Real coefficient =
      -2.0 / (ncolour + 2 * S) * scale;  // 2/(Nc +/- 2) for the normalization
    // of the trace in the two index rep
    for (int a = 0; a < ncolour * ncolour - 1; a++) {
      auto tmp = real(trace(i2indTa[a] * in)) * coefficient;
      pokeColour(h_out, tmp, a);
    }
  }
 };
 // Some useful type names
 typedef SU_TwoIndex<Nc, Symmetric> TwoIndexSymmMatrices;
 typedef SU_TwoIndex<Nc, AntiSymmetric> TwoIndexAntiSymmMatrices;
 typedef SU_TwoIndex<2, Symmetric> SU2TwoIndexSymm;
 typedef SU_TwoIndex<3, Symmetric> SU3TwoIndexSymm;
 typedef SU_TwoIndex<4, Symmetric> SU4TwoIndexSymm;
 typedef SU_TwoIndex<5, Symmetric> SU5TwoIndexSymm;
 typedef SU_TwoIndex<2, AntiSymmetric> SU2TwoIndexAntiSymm;
 typedef SU_TwoIndex<3, AntiSymmetric> SU3TwoIndexAntiSymm;
 typedef SU_TwoIndex<4, AntiSymmetric> SU4TwoIndexAntiSymm;
 typedef SU_TwoIndex<5, AntiSymmetric> SU5TwoIndexAntiSymm;
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/qcd/utils/Sp2n.impl.h
+++ b/Grid/qcd/utils/Sp2n.impl.h
@ -0,0 +1,317 @@
 // This file is #included into the body of the class template definition of
 // GaugeGroup. So, image there to be
 //
 // template <int ncolour, class group_name>
 // class GaugeGroup {
 //
 // around it.
 //
 // Please note that the unconventional file extension makes sure that it
 // doesn't get found by the scripts/filelist during bootstrapping.
 private:
 template <ONLY_IF_Sp>
 static int su2subgroups(GroupName::Sp) { return (ncolour/2 * (ncolour/2 - 1)) / 2; }
 // Sp(2N) has N(2N+1) = 2N^2+N generators
 //
 // normalise the generators such that
 // Trace ( Ta Tb) = 1/2 delta_ab
 //
 // N generators in the cartan, 2N^2 off
 // off diagonal:
 //     there are 6 types named a,b,c,d and w,z
 //     abcd are N(N-1)/2 each while wz are N each
 template <class cplx, ONLY_IF_Sp>
 static void generator(int lieIndex, iGroupMatrix<cplx> &ta, GroupName::Sp) {
  // map lie index into type of generators: diagonal, abcd type, wz type
  const int nsp = ncolour/2;
  int diagIndex;
  int aIndex, bIndex, cIndex, dIndex;
  int wIndex, zIndex;  // a,b,c,d are N(N-1)/2 and w,z are N
  const int mod = nsp * (nsp - 1) * 0.5;
  const int offdiag =
      2 * nsp * nsp;  // number of generators not in the cartan subalgebra
  const int wmod = 4 * mod;
  const int zmod = wmod + nsp;
  if (lieIndex >= offdiag) {
    diagIndex = lieIndex - offdiag;  // 0, ... ,N-1
    // std::cout << GridLogMessage << "diag type " << std::endl;
    generatorDiagtype(diagIndex, ta);
    return;
  }
  if ((lieIndex >= wmod) && (lieIndex < zmod)) {
    // std::cout << GridLogMessage << "w type " << std::endl;
    wIndex = lieIndex - wmod;  // 0, ... ,N-1
    generatorWtype(wIndex, ta);
    return;
  }
  if ((lieIndex >= zmod) && (lieIndex < offdiag)) {
    // std::cout << GridLogMessage << "z type " << std::endl;
    // std::cout << GridLogMessage << "lie index " << lieIndex << std::endl;
    // std::cout << GridLogMessage << "z mod " << zmod << std::endl;
    zIndex = lieIndex - zmod;  // 0, ... ,N-1
    generatorZtype(zIndex, ta);
    return;
  }
  if (lieIndex < mod) {  // atype 0, ... , N(N-1)/2=mod
    // std::cout << GridLogMessage << "a type " << std::endl;
    aIndex = lieIndex;
    // std::cout << GridLogMessage << "a indx " << aIndex << std::endl;
    generatorAtype(aIndex, ta);
    return;
  }
  if ((lieIndex >= mod) && lieIndex < 2 * mod) {  // btype mod, ... , 2mod-1
    // std::cout << GridLogMessage << "b type " << std::endl;
    bIndex = lieIndex - mod;
    generatorBtype(bIndex, ta);
    return;
  }
  if ((lieIndex >= 2 * mod) &&
      lieIndex < 3 * mod) {  // ctype 2mod, ... , 3mod-1
    // std::cout << GridLogMessage << "c type " << std::endl;
    cIndex = lieIndex - 2 * mod;
    generatorCtype(cIndex, ta);
    return;
  }
  if ((lieIndex >= 3 * mod) &&
      lieIndex < wmod) {  // ctype 3mod, ... , 4mod-1 = wmod-1
    // std::cout << GridLogMessage << "d type " << std::endl;
    dIndex = lieIndex - 3 * mod;
    generatorDtype(dIndex, ta);
    return;
  }
 }  // end of generator
 template <class cplx, ONLY_IF_Sp>
 static void generatorDiagtype(int diagIndex, iGroupMatrix<cplx> &ta) {
  // ta(i,i) = - ta(i+N,i+N) = 1/2 for each i index of the cartan subalgebra
  const int nsp=ncolour/2;
  ta = Zero();
  RealD nrm = 1.0 / 2;
  ta()()(diagIndex, diagIndex) = nrm;
  ta()()(diagIndex + nsp, diagIndex + nsp) = -nrm;
 }
 template <class cplx, ONLY_IF_Sp>
 static void generatorAtype(int aIndex, iGroupMatrix<cplx> &ta) {
  // ta(i,j) = ta(j,i) = -ta(i+N,j+N) = -ta(j+N,i+N) = 1 / 2 sqrt(2)
  // with i<j and i=0,...,N-2
  // follows that j=i+1, ... , N
  int i1, i2;
  const int nsp=ncolour/2;
  ta = Zero();
  RealD nrm = 1 / (2 * std::sqrt(2));
  su2SubGroupIndex(i1, i2, aIndex);
  ta()()(i1, i2) = 1;
  ta()()(i2, i1) = 1;
  ta()()(i1 + nsp, i2 + nsp) = -1;
  ta()()(i2 + nsp, i1 + nsp) = -1;
  ta = ta * nrm;
 }
 template <class cplx, ONLY_IF_Sp>
 static void generatorBtype(int bIndex, iGroupMatrix<cplx> &ta) {
  // ta(i,j) = -ta(j,i) = ta(i+N,j+N) = -ta(j+N,i+N) = i / 1/ 2 sqrt(2)
  // with i<j and i=0,...,N-2
  // follows that j=i+1, ... , N-1
  const int nsp=ncolour/2;
  int i1, i2;
  ta = Zero();
  cplx i(0.0, 1.0);
  RealD nrm = 1 / (2 * std::sqrt(2));
  su2SubGroupIndex(i1, i2, bIndex);
  ta()()(i1, i2) = i;
  ta()()(i2, i1) = -i;
  ta()()(i1 + nsp, i2 + nsp) = i;
  ta()()(i2 + nsp, i1 + nsp) = -i;
  ta = ta * nrm;
 }
 template <class cplx, ONLY_IF_Sp>
 static void generatorCtype(int cIndex, iGroupMatrix<cplx> &ta) {
  // ta(i,j+N) = ta(j,i+N) = ta(i+N,j) = ta(j+N,i) = 1 / 2 sqrt(2)
  const int nsp=ncolour/2;
  int i1, i2;
  ta = Zero();
  RealD nrm = 1 / (2 * std::sqrt(2));
  su2SubGroupIndex(i1, i2, cIndex);
  ta()()(i1, i2 + nsp) = 1;
  ta()()(i2, i1 + nsp) = 1;
  ta()()(i1 + nsp, i2) = 1;
  ta()()(i2 + nsp, i1) = 1;
  ta = ta * nrm;
 }
 template <class cplx, ONLY_IF_Sp>
 static void generatorDtype(int dIndex, iGroupMatrix<cplx> &ta) {
  // ta(i,j+N) = ta(j,i+N) = -ta(i+N,j) = -ta(j+N,i) = i /  2 sqrt(2)
  const int nsp=ncolour/2;
  int i1, i2;
  ta = Zero();
  cplx i(0.0, 1.0);
  RealD nrm = 1 / (2 * std::sqrt(2));
  su2SubGroupIndex(i1, i2, dIndex);
  ta()()(i1, i2 + nsp) = i;
  ta()()(i2, i1 + nsp) = i;
  ta()()(i1 + nsp, i2) = -i;
  ta()()(i2 + nsp, i1) = -i;
  ta = ta * nrm;
 }
 template <class cplx, ONLY_IF_Sp>
 static void generatorWtype(int wIndex, iGroupMatrix<cplx> &ta) {
  // ta(i,i+N) =  ta(i+N,i) = 1/2
  const int nsp=ncolour/2;
  ta = Zero();
  RealD nrm = 1.0 / 2;  // check
  ta()()(wIndex, wIndex + nsp) = 1;
  ta()()(wIndex + nsp, wIndex) = 1;
  ta = ta * nrm;
 }
 template <class cplx, ONLY_IF_Sp>
 static void generatorZtype(int zIndex, iGroupMatrix<cplx> &ta) {
  // ta(i,i+N) = - ta(i+N,i) = i/2
  const int nsp=ncolour/2;
  ta = Zero();
  RealD nrm = 1.0 / 2;  // check
  cplx i(0.0, 1.0);
  ta()()(zIndex, zIndex + nsp) = i;
  ta()()(zIndex + nsp, zIndex) = -i;
  ta = ta * nrm;
 }
 ////////////////////////////////////////////////////////////////////////
 // Map a su2 subgroup number to the pair of rows that are non zero
 ////////////////////////////////////////////////////////////////////////
 template <ONLY_IF_Sp>
 static void su2SubGroupIndex(int &i1, int &i2, int su2_index, GroupName::Sp) {
  const int nsp=ncolour/2;
  assert((su2_index >= 0) && (su2_index < (nsp * (nsp - 1)) / 2));
  int spare = su2_index;
  for (i1 = 0; spare >= (nsp - 1 - i1); i1++) {
    spare = spare - (nsp - 1 - i1);  // remove the Nc-1-i1 terms
  }
  i2 = i1 + 1 + spare;
 }
 static void testGenerators(GroupName::Sp) {
  Matrix ta;
  Matrix tb;
  std::cout << GridLogMessage
            << "Fundamental - Checking trace ta tb is 0.5 delta_ab "
            << std::endl;
  for (int a = 0; a < AlgebraDimension; a++) {
    for (int b = 0; b < AlgebraDimension; b++) {
      generator(a, ta);
      generator(b, tb);
      Complex tr = TensorRemove(trace(ta * tb));
      std::cout << GridLogMessage << "(" << a << "," << b << ") =  " << tr
                << std::endl;
      if (a == b) assert(abs(tr - Complex(0.5)) < 1.0e-6);
      if (a != b) assert(abs(tr) < 1.0e-6);
    }
  }
  std::cout << GridLogMessage << std::endl;
  std::cout << GridLogMessage << "Fundamental - Checking if hermitian"
            << std::endl;
  for (int a = 0; a < AlgebraDimension; a++) {
    generator(a, ta);
    std::cout << GridLogMessage << a << std::endl;
    assert(norm2(ta - adj(ta)) < 1.0e-6);
  }
  std::cout << GridLogMessage << std::endl;
  std::cout << GridLogMessage << "Fundamental - Checking if traceless"
            << std::endl;
  for (int a = 0; a < AlgebraDimension; a++) {
    generator(a, ta);
    Complex tr = TensorRemove(trace(ta));
    std::cout << GridLogMessage << a << std::endl;
    assert(abs(tr) < 1.0e-6);
  }
 }
 template <int N>
 static Lattice<iScalar<iScalar<iMatrix<vComplexD, N> > > >
 ProjectOnGeneralGroup(const Lattice<iScalar<iScalar<iMatrix<vComplexD, N> > > > &Umu, GroupName::Sp) {
  return ProjectOnSpGroup(Umu);
 }
 template <class vtype>
 accelerator_inline static iScalar<vtype> ProjectOnGeneralGroup(const iScalar<vtype> &r, GroupName::Sp) {
  return ProjectOnSpGroup(r);
 }
 template <class vtype, int N>
 accelerator_inline static iVector<vtype,N> ProjectOnGeneralGroup(const iVector<vtype,N> &r, GroupName::Sp) {
  return ProjectOnSpGroup(r);
 }
 template <class vtype,int N, typename std::enable_if< GridTypeMapper<vtype>::TensorLevel == 0 >::type * =nullptr>
 accelerator_inline static iMatrix<vtype,N> ProjectOnGeneralGroup(const iMatrix<vtype,N> &arg, GroupName::Sp) {
  return ProjectOnSpGroup(arg);
 }
 template <typename LatticeMatrixType>   
 static void taProj(const LatticeMatrixType &in, LatticeMatrixType &out, GroupName::Sp) {
  out = SpTa(in);
 }
 public:
 template <ONLY_IF_Sp>
 static void Omega(LatticeColourMatrixD &in) {
  const int nsp=ncolour/2;
  LatticeColourMatrixD OmegaLatt(in.Grid());
  LatticeColourMatrixD identity(in.Grid());
  ColourMatrix Omega;
  OmegaLatt = Zero();
  Omega = Zero();
  identity = 1.;
  for (int i = 0; i < nsp; i++) {
    Omega()()(i, nsp + i) = 1.;
    Omega()()(nsp + i, i) = -1;
  }
  OmegaLatt = OmegaLatt + (identity * Omega);
  in = OmegaLatt;
 }
 template <ONLY_IF_Sp, class vtype, int N>
 static void Omega(iScalar<iScalar<iMatrix<vtype, N> > > &in) {
  const int nsp=ncolour/2;
  iScalar<iScalar<iMatrix<vtype, N> > > Omega;
  Omega = Zero();
  for (int i = 0; i < nsp; i++) {
    Omega()()(i, nsp + i) = 1.;
    Omega()()(nsp + i, i) = -1;
  }
  in = Omega;
 }
--- a/Grid/qcd/utils/Utils.h
+++ b/Grid/qcd/utils/Utils.h
@ -8,9 +8,9 @@
 #include <Grid/qcd/utils/ScalarObjs.h>
 // Include representations
-#include <Grid/qcd/utils/SUn.h>
+#include <Grid/qcd/utils/GaugeGroup.h>
 #include <Grid/qcd/utils/SUnAdjoint.h>
-#include <Grid/qcd/utils/SUnTwoIndex.h>
+#include <Grid/qcd/utils/GaugeGroupTwoIndex.h>
 // All-to-all contraction kernels that touch the 
 // internal lattice structure
--- a/Grid/qcd/utils/WilsonLoops.h
+++ b/Grid/qcd/utils/WilsonLoops.h
@ -290,7 +290,7 @@ public:
  }
 */
  //////////////////////////////////////////////////
-  // the sum over all staples on each site
+  // the sum over all nu-oriented staples for nu != mu on each site
  //////////////////////////////////////////////////
  static void Staple(GaugeMat &staple, const GaugeLorentz &Umu, int mu) {
@ -300,6 +300,10 @@ public:
    for (int d = 0; d < Nd; d++) {
      U[d] = PeekIndex<LorentzIndex>(Umu, d);
    }
    Staple(staple, U, mu);
  }
  static void Staple(GaugeMat &staple, const std::vector<GaugeMat> &U, int mu) {
    staple = Zero();
    for (int nu = 0; nu < Nd; nu++) {
@ -335,6 +339,203 @@ public:
    }
  }
  /////////////
  //Staples for each direction mu, summed over nu != mu
  //staple: output staples for each mu (Nd)
  //U: link array (Nd)
  /////////////
  static void StapleAll(std::vector<GaugeMat> &staple, const std::vector<GaugeMat> &U) {
    assert(staple.size() == Nd); assert(U.size() == Nd);
    for(int mu=0;mu<Nd;mu++) Staple(staple[mu], U, mu);
  }
  //A workspace class allowing reuse of the stencil
  class WilsonLoopPaddedStencilWorkspace{
    std::unique_ptr<GeneralLocalStencil> stencil;
    size_t nshift;
    void generateStencil(GridBase* padded_grid){
      double t0 = usecond();
      //Generate shift arrays
      std::vector<Coordinate> shifts = this->getShifts();
      nshift = shifts.size();
      double t1 = usecond();
      //Generate local stencil
      stencil.reset(new GeneralLocalStencil(padded_grid,shifts));
      double t2 = usecond();
      std::cout << GridLogPerformance << " WilsonLoopPaddedWorkspace timings: coord:" << (t1-t0)/1000 << "ms, stencil:" << (t2-t1)/1000 << "ms" << std::endl;   
    }
  public:
    //Get the stencil. If not already generated, or if generated using a different Grid than in PaddedCell, it will be created on-the-fly
    const GeneralLocalStencil & getStencil(const PaddedCell &pcell){
      assert(pcell.depth >= this->paddingDepth());
      if(!stencil || stencil->Grid() != (GridBase*)pcell.grids.back() ) generateStencil((GridBase*)pcell.grids.back());
      return *stencil;
    }
    size_t Nshift() const{ return nshift; }
    virtual std::vector<Coordinate> getShifts() const = 0;
    virtual int paddingDepth() const = 0; //padding depth required
    virtual ~WilsonLoopPaddedStencilWorkspace(){}
  };
  //This workspace allows the sharing of a common PaddedCell object between multiple stencil workspaces
  class WilsonLoopPaddedWorkspace{
    std::vector<WilsonLoopPaddedStencilWorkspace*> stencil_wk;
    std::unique_ptr<PaddedCell> pcell;
    void generatePcell(GridBase* unpadded_grid){
      assert(stencil_wk.size());
      int max_depth = 0;
      for(auto const &s : stencil_wk) max_depth=std::max(max_depth, s->paddingDepth());
      pcell.reset(new PaddedCell(max_depth, dynamic_cast<GridCartesian*>(unpadded_grid)));
    }
  public:
    //Add a stencil definition. This should be done before the first call to retrieve a stencil object.
    //Takes ownership of the pointer
    void addStencil(WilsonLoopPaddedStencilWorkspace *stencil){
      assert(!pcell);
      stencil_wk.push_back(stencil);
    }
    const GeneralLocalStencil & getStencil(const size_t stencil_idx, GridBase* unpadded_grid){
      if(!pcell || pcell->unpadded_grid != unpadded_grid) generatePcell(unpadded_grid);
      return stencil_wk[stencil_idx]->getStencil(*pcell);
    }      
    const PaddedCell & getPaddedCell(GridBase* unpadded_grid){
      if(!pcell || pcell->unpadded_grid != unpadded_grid) generatePcell(unpadded_grid);
      return *pcell;
    }
    ~WilsonLoopPaddedWorkspace(){
      for(auto &s : stencil_wk) delete s;
    }
  };
  //A workspace class allowing reuse of the stencil
  class StaplePaddedAllWorkspace: public WilsonLoopPaddedStencilWorkspace{
  public:
    std::vector<Coordinate> getShifts() const override{
      std::vector<Coordinate> shifts;
      for(int mu=0;mu<Nd;mu++){
 	for(int nu=0;nu<Nd;nu++){
 	  if(nu != mu){
 	    Coordinate shift_0(Nd,0);
 	    Coordinate shift_mu(Nd,0); shift_mu[mu]=1;
 	    Coordinate shift_nu(Nd,0); shift_nu[nu]=1;
 	    Coordinate shift_mnu(Nd,0); shift_mnu[nu]=-1;
 	    Coordinate shift_mnu_pmu(Nd,0); shift_mnu_pmu[nu]=-1; shift_mnu_pmu[mu]=1;
 	    //U_nu(x+mu)U^dag_mu(x+nu) U^dag_nu(x)
 	    shifts.push_back(shift_0);
 	    shifts.push_back(shift_nu);
 	    shifts.push_back(shift_mu);
 	    //U_nu^dag(x-nu+mu) U_mu^dag(x-nu) U_nu(x-nu)
 	    shifts.push_back(shift_mnu);
 	    shifts.push_back(shift_mnu);
 	    shifts.push_back(shift_mnu_pmu);
 	  }
 	}
      }
      return shifts;
    }
    int paddingDepth() const override{ return 1; }
  }; 
  //Padded cell implementation of the staple method for all mu, summed over nu != mu
  //staple: output staple for each mu, summed over nu != mu (Nd)
  //U_padded: the gauge link fields padded out using the PaddedCell class
  //Cell: the padded cell class
  static void StaplePaddedAll(std::vector<GaugeMat> &staple, const std::vector<GaugeMat> &U_padded, const PaddedCell &Cell) {
    StaplePaddedAllWorkspace wk;
    StaplePaddedAll(staple,U_padded,Cell,wk.getStencil(Cell));
  }
  //Padded cell implementation of the staple method for all mu, summed over nu != mu
  //staple: output staple for each mu, summed over nu != mu (Nd)
  //U_padded: the gauge link fields padded out using the PaddedCell class
  //Cell: the padded cell class
  //gStencil: the precomputed generalized local stencil for the staple
  static void StaplePaddedAll(std::vector<GaugeMat> &staple, const std::vector<GaugeMat> &U_padded, const PaddedCell &Cell, const GeneralLocalStencil &gStencil)
  {
    double t0 = usecond();
    assert(U_padded.size() == Nd); assert(staple.size() == Nd);
    assert(U_padded[0].Grid() == (GridBase*)Cell.grids.back());
    assert(Cell.depth >= 1);
    GridBase *ggrid = U_padded[0].Grid(); //padded cell grid
    int shift_mu_off = gStencil._npoints/Nd;
    //Open views to padded gauge links and keep open over mu loop
    typedef LatticeView<typename GaugeMat::vector_object> GaugeViewType;
    size_t vsize = Nd*sizeof(GaugeViewType);
    GaugeViewType* Ug_dirs_v_host = (GaugeViewType*)malloc(vsize);
    for(int i=0;i<Nd;i++) Ug_dirs_v_host[i] = U_padded[i].View(AcceleratorRead);
    GaugeViewType* Ug_dirs_v = (GaugeViewType*)acceleratorAllocDevice(vsize);
    acceleratorCopyToDevice(Ug_dirs_v_host,Ug_dirs_v,vsize);
    GaugeMat gStaple(ggrid);
    int outer_off = 0;
    for(int mu=0;mu<Nd;mu++){
      { //view scope
 	autoView( gStaple_v , gStaple, AcceleratorWrite);
 	auto gStencil_v = gStencil.View();
 	accelerator_for(ss, ggrid->oSites(), (size_t)ggrid->Nsimd(), {
 	    decltype(coalescedRead(Ug_dirs_v[0][0])) stencil_ss;
 	    stencil_ss = Zero();
 	    int off = outer_off;
 	    for(int nu=0;nu<Nd;nu++){
 	      if(nu != mu){	  
 		GeneralStencilEntry const* e = gStencil_v.GetEntry(off++,ss);
 		auto U0 = adj(coalescedReadGeneralPermute(Ug_dirs_v[nu][e->_offset], e->_permute, Nd));
 		e = gStencil_v.GetEntry(off++,ss);
 		auto U1 = adj(coalescedReadGeneralPermute(Ug_dirs_v[mu][e->_offset], e->_permute, Nd));
 		e = gStencil_v.GetEntry(off++,ss);
 		auto U2 = coalescedReadGeneralPermute(Ug_dirs_v[nu][e->_offset], e->_permute, Nd);
 		stencil_ss = stencil_ss + U2 * U1 * U0;
 		e = gStencil_v.GetEntry(off++,ss);
 		U0 = coalescedReadGeneralPermute(Ug_dirs_v[nu][e->_offset], e->_permute, Nd);
 		e = gStencil_v.GetEntry(off++,ss);
 		U1 = adj(coalescedReadGeneralPermute(Ug_dirs_v[mu][e->_offset], e->_permute, Nd));
 		e = gStencil_v.GetEntry(off++,ss);
 		U2 = adj(coalescedReadGeneralPermute(Ug_dirs_v[nu][e->_offset], e->_permute, Nd));
 		stencil_ss = stencil_ss + U2 * U1 * U0;
 	      }
 	    }
 	    coalescedWrite(gStaple_v[ss],stencil_ss);
 	  }
 	  );
      } //ensure views are all closed!
      staple[mu] = Cell.Extract(gStaple);
      outer_off += shift_mu_off;
    }//mu loop
    for(int i=0;i<Nd;i++) Ug_dirs_v_host[i].ViewClose();
    free(Ug_dirs_v_host);
    acceleratorFreeDevice(Ug_dirs_v);
    double t1=usecond();
    std::cout << GridLogPerformance << "StaplePaddedAll timing:" << (t1-t0)/1000 << "ms" << std::endl;   
  }
  //////////////////////////////////////////////////
  // the sum over all staples on each site in direction mu,nu, upper part
  //////////////////////////////////////////////////
@ -707,18 +908,14 @@ public:
  // the sum over all staples on each site
  //////////////////////////////////////////////////
  static void RectStapleDouble(GaugeMat &U2, const GaugeMat &U, int mu) {
-    U2 = U * Cshift(U, mu, 1);
+    U2 = U * Gimpl::CshiftLink(U, mu, 1);
  }
  ////////////////////////////////////////////////////////////////////////////
-  // Hop by two optimisation strategy does not work nicely with Gparity. (could
+  // Hop by two optimisation strategy. Use RectStapleDouble to obtain 'U2'
  // do,
  // but need to track two deep where cross boundary and apply a conjugation).
  // Must differentiate this in Gimpl, and use Gimpl::isPeriodicGaugeField to do
  // so .
  ////////////////////////////////////////////////////////////////////////////
-  static void RectStapleOptimised(GaugeMat &Stap, std::vector<GaugeMat> &U2,
+  static void RectStapleOptimised(GaugeMat &Stap, const std::vector<GaugeMat> &U2,
-                                  std::vector<GaugeMat> &U, int mu) {
+                                  const std::vector<GaugeMat> &U, int mu) {
    Stap = Zero();
@ -732,9 +929,9 @@ public:
        // Up staple    ___ ___
        //             |       |
-        tmp = Cshift(adj(U[nu]), nu, -1);
+        tmp = Gimpl::CshiftLink(adj(U[nu]), nu, -1);
        tmp = adj(U2[mu]) * tmp;
-        tmp = Cshift(tmp, mu, -2);
+        tmp = Gimpl::CshiftLink(tmp, mu, -2);
        Staple2x1 = Gimpl::CovShiftForward(U[nu], nu, tmp);
@ -742,14 +939,14 @@ public:
        //             |___ ___|
        //
        tmp = adj(U2[mu]) * U[nu];
-        Staple2x1 += Gimpl::CovShiftBackward(U[nu], nu, Cshift(tmp, mu, -2));
+        Staple2x1 += Gimpl::CovShiftBackward(U[nu], nu, Gimpl::CshiftLink(tmp, mu, -2));
        //              ___ ___
        //             |    ___|
        //             |___ ___|
        //
-        Stap += Cshift(Gimpl::CovShiftForward(U[mu], mu, Staple2x1), mu, 1);
+        Stap += Gimpl::CshiftLink(Gimpl::CovShiftForward(U[mu], mu, Staple2x1), mu, 1);
        //              ___ ___
        //             |___    |
@ -758,7 +955,7 @@ public:
        //  tmp= Staple2x1* Cshift(U[mu],mu,-2);
        //  Stap+= Cshift(tmp,mu,1) ;
-        Stap += Cshift(Staple2x1, mu, 1) * Cshift(U[mu], mu, -1);
+        Stap += Gimpl::CshiftLink(Staple2x1, mu, 1) * Gimpl::CshiftLink(U[mu], mu, -1);
        ;
        //       --
@ -766,10 +963,10 @@ public:
        //
        //      |  |
-        tmp = Cshift(adj(U2[nu]), nu, -2);
+        tmp = Gimpl::CshiftLink(adj(U2[nu]), nu, -2);
        tmp = Gimpl::CovShiftBackward(U[mu], mu, tmp);
-        tmp = U2[nu] * Cshift(tmp, nu, 2);
+        tmp = U2[nu] * Gimpl::CshiftLink(tmp, nu, 2);
-        Stap += Cshift(tmp, mu, 1);
+        Stap += Gimpl::CshiftLink(tmp, mu, 1);
        //      |  |
        //
@ -778,25 +975,12 @@ public:
        tmp = Gimpl::CovShiftBackward(U[mu], mu, U2[nu]);
        tmp = adj(U2[nu]) * tmp;
-        tmp = Cshift(tmp, nu, -2);
+        tmp = Gimpl::CshiftLink(tmp, nu, -2);
-        Stap += Cshift(tmp, mu, 1);
+        Stap += Gimpl::CshiftLink(tmp, mu, 1);
      }
    }
  }
  static void RectStaple(GaugeMat &Stap, const GaugeLorentz &Umu, int mu) {
    RectStapleUnoptimised(Stap, Umu, mu);
  }
  static void RectStaple(const GaugeLorentz &Umu, GaugeMat &Stap,
                         std::vector<GaugeMat> &U2, std::vector<GaugeMat> &U,
                         int mu) {
    if (Gimpl::isPeriodicGaugeField()) {
      RectStapleOptimised(Stap, U2, U, mu);
    } else {
      RectStapleUnoptimised(Stap, Umu, mu);
    }
  }
  static void RectStapleUnoptimised(GaugeMat &Stap, const GaugeLorentz &Umu,
                                    int mu) {
    GridBase *grid = Umu.Grid();
@ -895,6 +1079,288 @@ public:
    }
  }
  static void RectStaple(GaugeMat &Stap, const GaugeLorentz &Umu, int mu) {
    RectStapleUnoptimised(Stap, Umu, mu);
  }
  static void RectStaple(const GaugeLorentz &Umu, GaugeMat &Stap,
                         std::vector<GaugeMat> &U2, std::vector<GaugeMat> &U,
                         int mu) {
    RectStapleOptimised(Stap, U2, U, mu);
  }
  //////////////////////////////////////////////////////
  //Compute the rectangular staples for all orientations
  //Stap : Array of staples (Nd)
  //U: Gauge links in each direction (Nd)
  /////////////////////////////////////////////////////
  static void RectStapleAll(std::vector<GaugeMat> &Stap, const std::vector<GaugeMat> &U){
    assert(Stap.size() == Nd); assert(U.size() == Nd);
    std::vector<GaugeMat> U2(Nd,U[0].Grid());
    for(int mu=0;mu<Nd;mu++) RectStapleDouble(U2[mu], U[mu], mu);
    for(int mu=0;mu<Nd;mu++) RectStapleOptimised(Stap[mu], U2, U, mu);
  }
  //A workspace class allowing reuse of the stencil
  class RectStaplePaddedAllWorkspace: public WilsonLoopPaddedStencilWorkspace{
  public:
    std::vector<Coordinate> getShifts() const override{
      std::vector<Coordinate> shifts;
      for (int mu = 0; mu < Nd; mu++){
 	for (int nu = 0; nu < Nd; nu++) {
 	  if (nu != mu) {
 	    auto genShift = [&](int mushift,int nushift){
 	      Coordinate out(Nd,0); out[mu]=mushift; out[nu]=nushift; return out;
 	    };
 	    //tmp6 = tmp5(x+mu) = U_mu(x+mu)U_nu(x+2mu)U_mu^dag(x+nu+mu) U_mu^dag(x+nu) U_nu^dag(x)
 	    shifts.push_back(genShift(0,0));
 	    shifts.push_back(genShift(0,+1));
 	    shifts.push_back(genShift(+1,+1));
 	    shifts.push_back(genShift(+2,0));
 	    shifts.push_back(genShift(+1,0));
 	    //tmp5 = tmp4(x+mu) = U_mu(x+mu)U^dag_nu(x-nu+2mu)U^dag_mu(x-nu+mu)U^dag_mu(x-nu)U_nu(x-nu)
 	    shifts.push_back(genShift(0,-1));
 	    shifts.push_back(genShift(0,-1));
 	    shifts.push_back(genShift(+1,-1));
 	    shifts.push_back(genShift(+2,-1));
 	    shifts.push_back(genShift(+1,0));
 	    //tmp5 = tmp4(x+mu) = U^dag_nu(x-nu+mu)U^dag_mu(x-nu)U^dag_mu(x-mu-nu)U_nu(x-mu-nu)U_mu(x-mu)
 	    shifts.push_back(genShift(-1,0));
 	    shifts.push_back(genShift(-1,-1));
 	    shifts.push_back(genShift(-1,-1));
 	    shifts.push_back(genShift(0,-1));
 	    shifts.push_back(genShift(+1,-1));
 	    //tmp5 = tmp4(x+mu) = U_nu(x+mu)U_mu^dag(x+nu)U_mu^dag(x-mu+nu)U_nu^dag(x-mu)U_mu(x-mu)
 	    shifts.push_back(genShift(-1,0));
 	    shifts.push_back(genShift(-1,0));
 	    shifts.push_back(genShift(-1,+1));
 	    shifts.push_back(genShift(0,+1));
 	    shifts.push_back(genShift(+1,0));
 	    //tmp6 = tmp5(x+mu) = U_nu(x+mu)U_nu(x+mu+nu)U_mu^dag(x+2nu)U_nu^dag(x+nu)U_nu^dag(x)
 	    shifts.push_back(genShift(0,0));
 	    shifts.push_back(genShift(0,+1));
 	    shifts.push_back(genShift(0,+2));
 	    shifts.push_back(genShift(+1,+1));
 	    shifts.push_back(genShift(+1,0));
 	    //tmp5 = tmp4(x+mu) = U_nu^dag(x+mu-nu)U_nu^dag(x+mu-2nu)U_mu^dag(x-2nu)U_nu(x-2nu)U_nu(x-nu)
 	    shifts.push_back(genShift(0,-1));
 	    shifts.push_back(genShift(0,-2));
 	    shifts.push_back(genShift(0,-2));
 	    shifts.push_back(genShift(+1,-2));
 	    shifts.push_back(genShift(+1,-1));
 	  }
 	}
      }
      return shifts;
    }
    int paddingDepth() const override{ return 2; }
  }; 
  //Padded cell implementation of the rectangular staple method for all mu, summed over nu != mu
  //staple: output staple for each mu, summed over nu != mu (Nd)
  //U_padded: the gauge link fields padded out using the PaddedCell class
  //Cell: the padded cell class
  static void RectStaplePaddedAll(std::vector<GaugeMat> &staple, const std::vector<GaugeMat> &U_padded, const PaddedCell &Cell) {
    RectStaplePaddedAllWorkspace wk;
    RectStaplePaddedAll(staple,U_padded,Cell,wk.getStencil(Cell));
  }
  //Padded cell implementation of the rectangular staple method for all mu, summed over nu != mu
  //staple: output staple for each mu, summed over nu != mu (Nd)
  //U_padded: the gauge link fields padded out using the PaddedCell class
  //Cell: the padded cell class
  //gStencil: the stencil
  static void RectStaplePaddedAll(std::vector<GaugeMat> &staple, const std::vector<GaugeMat> &U_padded, const PaddedCell &Cell, const GeneralLocalStencil &gStencil) {
    double t0 = usecond();
    assert(U_padded.size() == Nd); assert(staple.size() == Nd);
    assert(U_padded[0].Grid() == (GridBase*)Cell.grids.back());
    assert(Cell.depth >= 2);
    GridBase *ggrid = U_padded[0].Grid(); //padded cell grid
    size_t nshift = gStencil._npoints;
    int mu_off_delta = nshift / Nd;
    //Open views to padded gauge links and keep open over mu loop
    typedef LatticeView<typename GaugeMat::vector_object> GaugeViewType;
    size_t vsize = Nd*sizeof(GaugeViewType);
    GaugeViewType* Ug_dirs_v_host = (GaugeViewType*)malloc(vsize);
    for(int i=0;i<Nd;i++) Ug_dirs_v_host[i] = U_padded[i].View(AcceleratorRead);
    GaugeViewType* Ug_dirs_v = (GaugeViewType*)acceleratorAllocDevice(vsize);
    acceleratorCopyToDevice(Ug_dirs_v_host,Ug_dirs_v,vsize);
    GaugeMat gStaple(ggrid); //temp staple object on padded grid
    int offset = 0;
    for(int mu=0; mu<Nd; mu++){
      { //view scope
 	autoView( gStaple_v , gStaple, AcceleratorWrite);
 	auto gStencil_v = gStencil.View();
 	accelerator_for(ss, ggrid->oSites(), (size_t)ggrid->Nsimd(), {
 	    decltype(coalescedRead(Ug_dirs_v[0][0])) stencil_ss;
 	    stencil_ss = Zero();
 	    int s=offset;
 	    for(int nu=0;nu<Nd;nu++){
 	      if(nu != mu){
 		//tmp6 = tmp5(x+mu) = U_mu(x+mu)U_nu(x+2mu)U_mu^dag(x+nu+mu) U_mu^dag(x+nu) U_nu^dag(x)
 		GeneralStencilEntry const* e = gStencil_v.GetEntry(s++,ss);
 		auto U0 = adj(coalescedReadGeneralPermute(Ug_dirs_v[nu][e->_offset], e->_permute, Nd));
 		e = gStencil_v.GetEntry(s++,ss);
 		auto U1 = adj(coalescedReadGeneralPermute(Ug_dirs_v[mu][e->_offset], e->_permute, Nd));
 		e = gStencil_v.GetEntry(s++,ss);
 		auto U2 = adj(coalescedReadGeneralPermute(Ug_dirs_v[mu][e->_offset], e->_permute, Nd));
 		e = gStencil_v.GetEntry(s++,ss);
 		auto U3 = coalescedReadGeneralPermute(Ug_dirs_v[nu][e->_offset], e->_permute, Nd);
 		e = gStencil_v.GetEntry(s++,ss);
 		auto U4 = coalescedReadGeneralPermute(Ug_dirs_v[mu][e->_offset], e->_permute, Nd);
 		stencil_ss = stencil_ss + U4*U3*U2*U1*U0;
 		//tmp5 = tmp4(x+mu) = U_mu(x+mu)U^dag_nu(x-nu+2mu)U^dag_mu(x-nu+mu)U^dag_mu(x-nu)U_nu(x-nu)
 		e = gStencil_v.GetEntry(s++,ss);
 		U0 = coalescedReadGeneralPermute(Ug_dirs_v[nu][e->_offset], e->_permute, Nd);
 		e = gStencil_v.GetEntry(s++,ss);
 		U1 = adj(coalescedReadGeneralPermute(Ug_dirs_v[mu][e->_offset], e->_permute, Nd));
 		e = gStencil_v.GetEntry(s++,ss);
 		U2 = adj(coalescedReadGeneralPermute(Ug_dirs_v[mu][e->_offset], e->_permute, Nd));
 		e = gStencil_v.GetEntry(s++,ss);
 		U3 = adj(coalescedReadGeneralPermute(Ug_dirs_v[nu][e->_offset], e->_permute, Nd));
 		e = gStencil_v.GetEntry(s++,ss);
 		U4 = coalescedReadGeneralPermute(Ug_dirs_v[mu][e->_offset], e->_permute, Nd);
 		stencil_ss = stencil_ss + U4*U3*U2*U1*U0;
 		//tmp5 = tmp4(x+mu) = U^dag_nu(x-nu+mu)U^dag_mu(x-nu)U^dag_mu(x-mu-nu)U_nu(x-mu-nu)U_mu(x-mu)
 		e = gStencil_v.GetEntry(s++,ss);
 		U0 = coalescedReadGeneralPermute(Ug_dirs_v[mu][e->_offset], e->_permute, Nd);
 		e = gStencil_v.GetEntry(s++,ss);
 		U1 = coalescedReadGeneralPermute(Ug_dirs_v[nu][e->_offset], e->_permute, Nd);
 		e = gStencil_v.GetEntry(s++,ss);
 		U2 = adj(coalescedReadGeneralPermute(Ug_dirs_v[mu][e->_offset], e->_permute, Nd));
 		e = gStencil_v.GetEntry(s++,ss);
 		U3 = adj(coalescedReadGeneralPermute(Ug_dirs_v[mu][e->_offset], e->_permute, Nd));
 		e = gStencil_v.GetEntry(s++,ss);
 		U4 = adj(coalescedReadGeneralPermute(Ug_dirs_v[nu][e->_offset], e->_permute, Nd));
 		stencil_ss = stencil_ss + U4*U3*U2*U1*U0;
 		//tmp5 = tmp4(x+mu) = U_nu(x+mu)U_mu^dag(x+nu)U_mu^dag(x-mu+nu)U_nu^dag(x-mu)U_mu(x-mu)
 		e = gStencil_v.GetEntry(s++,ss);
 		U0 = coalescedReadGeneralPermute(Ug_dirs_v[mu][e->_offset], e->_permute, Nd);
 		e = gStencil_v.GetEntry(s++,ss);
 		U1 = adj(coalescedReadGeneralPermute(Ug_dirs_v[nu][e->_offset], e->_permute, Nd));
 		e = gStencil_v.GetEntry(s++,ss);
 		U2 = adj(coalescedReadGeneralPermute(Ug_dirs_v[mu][e->_offset], e->_permute, Nd));
 		e = gStencil_v.GetEntry(s++,ss);
 		U3 = adj(coalescedReadGeneralPermute(Ug_dirs_v[mu][e->_offset], e->_permute, Nd));
 		e = gStencil_v.GetEntry(s++,ss);
 		U4 = coalescedReadGeneralPermute(Ug_dirs_v[nu][e->_offset], e->_permute, Nd);
 		stencil_ss = stencil_ss + U4*U3*U2*U1*U0;
 		//tmp6 = tmp5(x+mu) = U_nu(x+mu)U_nu(x+mu+nu)U_mu^dag(x+2nu)U_nu^dag(x+nu)U_nu^dag(x)
 		e = gStencil_v.GetEntry(s++,ss);
 		U0 = adj(coalescedReadGeneralPermute(Ug_dirs_v[nu][e->_offset], e->_permute, Nd));
 		e = gStencil_v.GetEntry(s++,ss);
 		U1 = adj(coalescedReadGeneralPermute(Ug_dirs_v[nu][e->_offset], e->_permute, Nd));
 		e = gStencil_v.GetEntry(s++,ss);
 		U2 = adj(coalescedReadGeneralPermute(Ug_dirs_v[mu][e->_offset], e->_permute, Nd));
 		e = gStencil_v.GetEntry(s++,ss);
 		U3 = coalescedReadGeneralPermute(Ug_dirs_v[nu][e->_offset], e->_permute, Nd);
 		e = gStencil_v.GetEntry(s++,ss);
 		U4 = coalescedReadGeneralPermute(Ug_dirs_v[nu][e->_offset], e->_permute, Nd);
 		stencil_ss = stencil_ss + U4*U3*U2*U1*U0;   
 		//tmp5 = tmp4(x+mu) = U_nu^dag(x+mu-nu)U_nu^dag(x+mu-2nu)U_mu^dag(x-2nu)U_nu(x-2nu)U_nu(x-nu)
 		e = gStencil_v.GetEntry(s++,ss);
 		U0 = coalescedReadGeneralPermute(Ug_dirs_v[nu][e->_offset], e->_permute, Nd);
 		e = gStencil_v.GetEntry(s++,ss);
 		U1 = coalescedReadGeneralPermute(Ug_dirs_v[nu][e->_offset], e->_permute, Nd);
 		e = gStencil_v.GetEntry(s++,ss);
 		U2 = adj(coalescedReadGeneralPermute(Ug_dirs_v[mu][e->_offset], e->_permute, Nd));
 		e = gStencil_v.GetEntry(s++,ss);
 		U3 = adj(coalescedReadGeneralPermute(Ug_dirs_v[nu][e->_offset], e->_permute, Nd));
 		e = gStencil_v.GetEntry(s++,ss);
 		U4 = adj(coalescedReadGeneralPermute(Ug_dirs_v[nu][e->_offset], e->_permute, Nd));
 		stencil_ss = stencil_ss + U4*U3*U2*U1*U0;   
 	      }
 	    }
 	    coalescedWrite(gStaple_v[ss],stencil_ss);
 	  }
 	  );
 	offset += mu_off_delta;
      }//kernel/view scope
      staple[mu] = Cell.Extract(gStaple);    
    }//mu loop
    for(int i=0;i<Nd;i++) Ug_dirs_v_host[i].ViewClose();
    free(Ug_dirs_v_host);
    acceleratorFreeDevice(Ug_dirs_v);
    double t1 = usecond();
    std::cout << GridLogPerformance << "RectStaplePaddedAll timings:" << (t1-t0)/1000 << "ms" << std::endl;   
  }
  //A workspace for reusing the PaddedCell and GeneralLocalStencil objects
  class StapleAndRectStapleAllWorkspace: public WilsonLoopPaddedWorkspace{
  public:
    StapleAndRectStapleAllWorkspace(){
      this->addStencil(new StaplePaddedAllWorkspace);
      this->addStencil(new RectStaplePaddedAllWorkspace);
    }
  };     
  //////////////////////////////////////////////////////
  //Compute the 1x1 and 1x2 staples for all orientations
  //Stap : Array of staples (Nd)
  //RectStap: Array of rectangular staples (Nd)
  //U: Gauge links in each direction (Nd)
  /////////////////////////////////////////////////////
  static void StapleAndRectStapleAll(std::vector<GaugeMat> &Stap, std::vector<GaugeMat> &RectStap, const std::vector<GaugeMat> &U){
    StapleAndRectStapleAllWorkspace wk;
    StapleAndRectStapleAll(Stap,RectStap,U,wk);
  }
  //////////////////////////////////////////////////////
  //Compute the 1x1 and 1x2 staples for all orientations
  //Stap : Array of staples (Nd)
  //RectStap: Array of rectangular staples (Nd)
  //U: Gauge links in each direction (Nd)
  //wk: a workspace containing stored PaddedCell and GeneralLocalStencil objects to maximize reuse
  /////////////////////////////////////////////////////
  static void StapleAndRectStapleAll(std::vector<GaugeMat> &Stap, std::vector<GaugeMat> &RectStap, const std::vector<GaugeMat> &U, StapleAndRectStapleAllWorkspace &wk){
 #if 0
    StapleAll(Stap, U);
    RectStapleAll(RectStap, U);
 #else
    double t0 = usecond();
    GridCartesian* unpadded_grid = dynamic_cast<GridCartesian*>(U[0].Grid());
    const PaddedCell &Ghost = wk.getPaddedCell(unpadded_grid);
    CshiftImplGauge<Gimpl> cshift_impl;
    std::vector<GaugeMat> U_pad(Nd, Ghost.grids.back());
    for(int mu=0;mu<Nd;mu++) U_pad[mu] = Ghost.Exchange(U[mu], cshift_impl);
    double t1 = usecond();
    StaplePaddedAll(Stap, U_pad, Ghost, wk.getStencil(0,unpadded_grid) );
    double t2 = usecond();
    RectStaplePaddedAll(RectStap, U_pad, Ghost, wk.getStencil(1,unpadded_grid));
    double t3 = usecond();
    std::cout << GridLogPerformance << "StapleAndRectStapleAll timings: pad:" << (t1-t0)/1000 << "ms, staple:" << (t2-t1)/1000 << "ms, rect-staple:" << (t3-t2)/1000 << "ms" << std::endl;
 #endif
  }
  //////////////////////////////////////////////////
  // Wilson loop of size (R1, R2), oriented in mu,nu plane
  //////////////////////////////////////////////////
--- a/Grid/simd/Grid_vector_types.h
+++ b/Grid/simd/Grid_vector_types.h
@ -1133,4 +1133,13 @@ static_assert(sizeof(SIMD_Ftype) == sizeof(SIMD_Itype), "SIMD vector lengths inc
 NAMESPACE_END(Grid);
 #ifdef GRID_SYCL
 template<> struct sycl::is_device_copyable<Grid::vComplexF> : public std::true_type {};
 template<> struct sycl::is_device_copyable<Grid::vComplexD> : public std::true_type {};
 template<> struct sycl::is_device_copyable<Grid::vRealF   > : public std::true_type {};
 template<> struct sycl::is_device_copyable<Grid::vRealD   > : public std::true_type {};
 template<> struct sycl::is_device_copyable<Grid::vInteger > : public std::true_type {};
 #endif
 #endif
--- a/Grid/sitmo_rng/sitmo_prng_engine.hpp
+++ b/Grid/sitmo_rng/sitmo_prng_engine.hpp
@ -218,6 +218,10 @@ public:
    // -------------------------------------------------
    // misc
    // -------------------------------------------------
    void discardhi(uint64_t z) {
      _s[3] += z;
      encrypt_counter();
    }
    // req: 26.5.1.4 Random number engine requirements, p.908 table 117, row 9
    // Advances e’s state ei to ei+z by any means equivalent to z
@ -387,4 +391,4 @@ private:
 #undef MIXK
 #undef MIX2
-#endif
+#endif
--- a/Grid/stencil/GeneralLocalStencil.h
+++ b/Grid/stencil/GeneralLocalStencil.h
@ -43,7 +43,7 @@ class GeneralLocalStencilView {
  int                               _npoints; // Move to template param?
  GeneralStencilEntry*  _entries_p;
-  accelerator_inline GeneralStencilEntry * GetEntry(int point,int osite) { 
+  accelerator_inline GeneralStencilEntry * GetEntry(int point,int osite) const { 
    return & this->_entries_p[point+this->_npoints*osite]; 
  }
@ -79,63 +79,113 @@ public:
    this->_entries.resize(npoints* osites);
    this->_entries_p = &_entries[0];
    thread_for(site, osites, {
 	Coordinate Coor;
 	Coordinate NbrCoor;
-    Coordinate Coor;
+	for(Integer ii=0;ii<npoints;ii++){
-    Coordinate NbrCoor;
+	  Integer lex = site*npoints+ii;
-    for(Integer site=0;site<osites;site++){
+	  GeneralStencilEntry SE;
-      for(Integer ii=0;ii<npoints;ii++){
+	  ////////////////////////////////////////////////
-	Integer lex = site*npoints+ii;
+	  // Outer index of neighbour Offset calculation
-	GeneralStencilEntry SE;
+	  ////////////////////////////////////////////////
-	////////////////////////////////////////////////
+	  grid->oCoorFromOindex(Coor,site);
-	// Outer index of neighbour Offset calculation
+	  for(int d=0;d<Coor.size();d++){
-	////////////////////////////////////////////////
+	    int rd = grid->_rdimensions[d];
-	grid->oCoorFromOindex(Coor,site);
+	    NbrCoor[d] = (Coor[d] + shifts[ii][d] + rd )%rd;
-	for(int d=0;d<Coor.size();d++){
+	  }
-	  int rd = grid->_rdimensions[d];
+	  SE._offset      = grid->oIndexReduced(NbrCoor);
-	  NbrCoor[d] = (Coor[d] + shifts[ii][d] + rd )%rd;
+
 	  ////////////////////////////////////////////////
 	  // Inner index permute calculation
 	  // Simpler version using icoor calculation
 	  ////////////////////////////////////////////////
 	  SE._permute =0;
 	  for(int d=0;d<Coor.size();d++){
 	    int fd = grid->_fdimensions[d];
 	    int rd = grid->_rdimensions[d];
 	    int ly = grid->_simd_layout[d];
 	    assert((ly==1)||(ly==2));
 	    int shift = (shifts[ii][d]+fd)%fd;  // make it strictly positive 0.. L-1
 	    int x = Coor[d];                // x in [0... rd-1] as an oSite 
 	    int permute_dim  = grid->PermuteDim(d);
 	    int permute_slice=0;
 	    if(permute_dim){    
 	      int  num = shift%rd; // Slice within dest osite cell of slice zero
 	      int wrap = shift/rd; // Number of osite local volume cells crossed through
 	      // x+num < rd dictates whether we are in same permute state as slice 0
 	      if ( x< rd-num ) permute_slice=wrap;
 	      else             permute_slice=(wrap+1)%ly;
 	    }
 	    if ( permute_slice ) {
 	      int ptype       =grid->PermuteType(d);
 	      uint8_t mask    =0x1<<ptype;
 	      SE._permute    |= mask;
 	    }
 	  }	
 	  ////////////////////////////////////////////////
 	  // Store in look up table
 	  ////////////////////////////////////////////////
 	  this->_entries[lex] = SE;
 	}
-	SE._offset      = grid->oIndexReduced(NbrCoor);
+      });
 	////////////////////////////////////////////////
 	// Inner index permute calculation
 	// Simpler version using icoor calculation
 	////////////////////////////////////////////////
 	SE._permute =0;
 	for(int d=0;d<Coor.size();d++){
 	  int fd = grid->_fdimensions[d];
 	  int rd = grid->_rdimensions[d];
 	  int ly = grid->_simd_layout[d];
 	  assert((ly==1)||(ly==2));
 	  int shift = (shifts[ii][d]+fd)%fd;  // make it strictly positive 0.. L-1
 	  int x = Coor[d];                // x in [0... rd-1] as an oSite 
 	  int permute_dim  = grid->PermuteDim(d);
 	  int permute_slice=0;
 	  if(permute_dim){    
 	    int  num = shift%rd; // Slice within dest osite cell of slice zero
 	    int wrap = shift/rd; // Number of osite local volume cells crossed through
                                  // x+num < rd dictates whether we are in same permute state as slice 0
 	    if ( x< rd-num ) permute_slice=wrap;
 	    else             permute_slice=(wrap+1)%ly;
 	  }
 	  if ( permute_slice ) {
 	    int ptype       =grid->PermuteType(d);
 	    uint8_t mask    =0x1<<ptype;
 	    SE._permute    |= mask;
 	  }
 	}	
 	////////////////////////////////////////////////
 	// Store in look up table
 	////////////////////////////////////////////////
 	this->_entries[lex] = SE;
      }
    }      
  }
 };
 ////////////////////////////////////////////////
 // Some machinery to streamline making a stencil 
 ////////////////////////////////////////////////
 class shiftSignal {
 public:
    enum {
        BACKWARD_CONST = 16,
        NO_SHIFT       = -1
    };
 };
 // TODO: put a check somewhere that BACKWARD_CONST > Nd!
 /*!  @brief signals that you want to go backwards in direction dir */
 inline int Back(const int dir) {
    // generalShift will use BACKWARD_CONST to determine whether we step forward or 
    // backward. Trick inspired by SIMULATeQCD. 
    return dir + shiftSignal::BACKWARD_CONST;
 }
 /*!  @brief shift one unit in direction dir */
 template<typename... Args>
 void generalShift(Coordinate& shift, int dir) {
    if (dir >= shiftSignal::BACKWARD_CONST) {
        dir -= shiftSignal::BACKWARD_CONST;
        shift[dir]+=-1;
    } else if (dir == shiftSignal::NO_SHIFT) {
        ; // do nothing
    } else {
        shift[dir]+=1;
    }
 }
 /*!  @brief follow a path of directions, shifting one unit in each direction */
 template<typename... Args>
 void generalShift(Coordinate& shift, int dir, Args... args) {
    if (dir >= shiftSignal::BACKWARD_CONST) {
        dir -= shiftSignal::BACKWARD_CONST;
        shift[dir]+=-1;
    } else if (dir == shiftSignal::NO_SHIFT) {
        ; // do nothing
    } else {
        shift[dir]+=1;
    }
    generalShift(shift, args...);
 }
 NAMESPACE_END(Grid);
--- a/Grid/stencil/Stencil.h
+++ b/Grid/stencil/Stencil.h
@ -32,6 +32,7 @@
 #include <Grid/stencil/SimpleCompressor.h>   // subdir aggregate
 #include <Grid/stencil/Lebesgue.h>   // subdir aggregate
 #include <Grid/stencil/GeneralLocalStencil.h>
 //////////////////////////////////////////////////////////////////////////////////////////
 // Must not lose sight that goal is to be able to construct really efficient
@ -705,7 +706,7 @@ public:
 	}
      }
    }
-    std::cout << GridLogDebug << "BuildSurfaceList size is "<<surface_list.size()<<std::endl;
+    //std::cout << "BuildSurfaceList size is "<<surface_list.size()<<std::endl;
  }
  /// Introduce a block structure and switch off comms on boundaries
  void DirichletBlock(const Coordinate &dirichlet_block)
@ -760,7 +761,8 @@ public:
 		   int checkerboard,
 		   const std::vector<int> &directions,
 		   const std::vector<int> &distances,
-		   Parameters p=Parameters())
+		   Parameters p=Parameters(),
 		   bool preserve_shm=false)
  {
    face_table_computed=0;
    _grid    = grid;
@ -854,7 +856,9 @@ public:
    /////////////////////////////////////////////////////////////////////////////////
    const int Nsimd = grid->Nsimd();
-    _grid->ShmBufferFreeAll();
+    // Allow for multiple stencils to exist simultaneously
    if (!preserve_shm)
      _grid->ShmBufferFreeAll();
    int maxl=2;
    u_simd_send_buf.resize(maxl);
--- a/Grid/tensors/Tensor_SIMT.h
+++ b/Grid/tensors/Tensor_SIMT.h
@ -73,6 +73,16 @@ vobj coalescedReadPermute(const vobj & __restrict__ vec,int ptype,int doperm,int
    return vec;
  }
 }
 //'perm_mask' acts as a bitmask
 template<class vobj> accelerator_inline
 vobj coalescedReadGeneralPermute(const vobj & __restrict__ vec,int perm_mask,int nd,int lane=0)
 {
  auto obj = vec, tmp = vec;
  for (int d=0;d<nd;d++)
    if (perm_mask & (0x1 << d)) { permute(obj,tmp,d); tmp=obj;}
  return obj;
 }
 template<class vobj> accelerator_inline
 void coalescedWrite(vobj & __restrict__ vec,const vobj & __restrict__ extracted,int lane=0)
 {
@ -83,7 +93,7 @@ void coalescedWriteNonTemporal(vobj & __restrict__ vec,const vobj & __restrict__
 {
  vstream(vec, extracted);
 }
-#else
+#else //==GRID_SIMT
 //#ifndef GRID_SYCL
@ -166,6 +176,14 @@ typename vobj::scalar_object coalescedReadPermute(const vobj & __restrict__ vec,
  return extractLane(plane,vec);
 }
 template<class vobj> accelerator_inline
 typename vobj::scalar_object coalescedReadGeneralPermute(const vobj & __restrict__ vec,int perm_mask,int nd,int lane=acceleratorSIMTlane(vobj::Nsimd()))
 {
  int plane = lane;
  for (int d=0;d<nd;d++)
    plane = (perm_mask & (0x1 << d)) ? plane ^ (vobj::Nsimd() >> (d + 1)) : plane;
  return extractLane(plane,vec);
 }
 template<class vobj> accelerator_inline
 void coalescedWrite(vobj & __restrict__ vec,const typename vobj::scalar_object & __restrict__ extracted,int lane=acceleratorSIMTlane(vobj::Nsimd()))
 {
  insertLane(lane,vec,extracted);
--- a/Grid/tensors/Tensor_Ta.h
+++ b/Grid/tensors/Tensor_Ta.h
@ -66,13 +66,61 @@ template<class vtype,int N> accelerator_inline iMatrix<vtype,N> Ta(const iMatrix
  return ret;
 }
 template<class vtype> accelerator_inline iScalar<vtype> SpTa(const iScalar<vtype>&r)
 {
  iScalar<vtype> ret;
  ret._internal = SpTa(r._internal);
  return ret;
 }
 template<class vtype,int N> accelerator_inline iVector<vtype,N> SpTa(const iVector<vtype,N>&r)
 {
  iVector<vtype,N> ret;
  for(int i=0;i<N;i++){
    ret._internal[i] = SpTa(r._internal[i]);
  }
  return ret;
 }
 template<class vtype,int N, typename std::enable_if< GridTypeMapper<vtype>::TensorLevel == 0 >::type * =nullptr>
 accelerator_inline iMatrix<vtype,N> SpTa(const iMatrix<vtype,N> &arg)
 {
  // Generalises Ta to Sp2n
  // Applies the following projections
  // P_{antihermitian} P_{antihermitian-Sp-algebra} P_{traceless}
  // where the ordering matters
  // P_{traceless} subtracts the trace
  // P_{antihermitian-Sp-algebra} provides the block structure of the algebra based on U = exp(T) i.e. anti-hermitian generators
  // P_{antihermitian} does in-adj(in) / 2
  iMatrix<vtype,N> ret(arg);
  double factor = (1.0/(double)N);
  vtype nrm;
  nrm = 0.5;
  ret = arg - (trace(arg)*factor);
  for(int c1=0;c1<N/2;c1++)
  {
      for(int c2=0;c2<N/2;c2++)
      {
          ret._internal[c1][c2] = nrm*(conjugate(ret._internal[c1+N/2][c2+N/2]) + ret._internal[c1][c2]); // new[up-left] = old[up-left]+old*[down-right]
          ret._internal[c1][c2+N/2] = nrm*(ret._internal[c1][c2+N/2] - conjugate(ret._internal[c1+N/2][c2])); // new[up-right] = old[up-right]-old*[down-left]
      }
      for(int c2=N/2;c2<N;c2++)
      {
          ret._internal[c1+N/2][c2-N/2] = -conjugate(ret._internal[c1][c2]);  //  reconstructs lower blocks
          ret._internal[c1+N/2][c2] = conjugate(ret._internal[c1][c2-N/2]);   //  from upper blocks
      }
  }
  ret = (ret - adj(ret))*0.5;
  return ret;
 }
 /////////////////////////////////////////////// 
 // ProjectOnGroup function for scalar, vector, matrix 
 // Projects on orthogonal, unitary group
 /////////////////////////////////////////////// 
 template<class vtype> accelerator_inline iScalar<vtype> ProjectOnGroup(const iScalar<vtype>&r)
 {
  iScalar<vtype> ret;
@ -90,10 +138,12 @@ template<class vtype,int N> accelerator_inline iVector<vtype,N> ProjectOnGroup(c
 template<class vtype,int N, typename std::enable_if< GridTypeMapper<vtype>::TensorLevel == 0 >::type * =nullptr> 
 accelerator_inline iMatrix<vtype,N> ProjectOnGroup(const iMatrix<vtype,N> &arg)
 {
  typedef typename iMatrix<vtype,N>::scalar_type scalar;
  // need a check for the group type?
  iMatrix<vtype,N> ret(arg);
  vtype nrm;
  vtype inner;
  scalar one(1.0);
  for(int c1=0;c1<N;c1++){
    // Normalises row c1
@ -102,7 +152,7 @@ accelerator_inline iMatrix<vtype,N> ProjectOnGroup(const iMatrix<vtype,N> &arg)
      inner += innerProduct(ret._internal[c1][c2],ret._internal[c1][c2]);
    nrm = sqrt(inner);
-    nrm = 1.0/nrm;
+    nrm = one/nrm;
    for(int c2=0;c2<N;c2++)
      ret._internal[c1][c2]*= nrm;
@ -127,7 +177,7 @@ accelerator_inline iMatrix<vtype,N> ProjectOnGroup(const iMatrix<vtype,N> &arg)
      inner += innerProduct(ret._internal[c1][c2],ret._internal[c1][c2]);
    nrm = sqrt(inner);
-    nrm = 1.0/nrm;
+    nrm = one/nrm;
    for(int c2=0;c2<N;c2++)
      ret._internal[c1][c2]*= nrm;
  }
@ -135,6 +185,85 @@ accelerator_inline iMatrix<vtype,N> ProjectOnGroup(const iMatrix<vtype,N> &arg)
  return ret;
 }
 // re-do for sp2n
 // Ta cannot be defined here for Sp2n because I need the generators from the Sp class
 // It is defined in gauge impl types
 template<class vtype> accelerator_inline iScalar<vtype> ProjectOnSpGroup(const iScalar<vtype>&r)
 {
  iScalar<vtype> ret;
  ret._internal = ProjectOnSpGroup(r._internal);
  return ret;
 }
 template<class vtype,int N> accelerator_inline iVector<vtype,N> ProjectOnSpGroup(const iVector<vtype,N>&r)
 {
  iVector<vtype,N> ret;
  for(int i=0;i<N;i++){
    ret._internal[i] = ProjectOnSpGroup(r._internal[i]);
  }
  return ret;
 }
 // int N is 2n in Sp(2n)
 template<class vtype,int N, typename std::enable_if< GridTypeMapper<vtype>::TensorLevel == 0 >::type * =nullptr>
 accelerator_inline iMatrix<vtype,N> ProjectOnSpGroup(const iMatrix<vtype,N> &arg)
 {
  // need a check for the group type?
  iMatrix<vtype,N> ret(arg);
  vtype nrm;
  vtype inner;
  for(int c1=0;c1<N/2;c1++)
  {
    for (int b=0; b<c1; b++)                  // remove the b-rows from U_c1
    {
      decltype(ret._internal[b][b]*ret._internal[b][b]) pr;
      decltype(ret._internal[b][b]*ret._internal[b][b]) prn;
      zeroit(pr);
      zeroit(prn);
      for(int c=0; c<N; c++)
      {
        pr += conjugate(ret._internal[c1][c])*ret._internal[b][c];        // <U_c1 | U_b >
        prn += conjugate(ret._internal[c1][c])*ret._internal[b+N/2][c];   // <U_c1 | U_{b+N} >
      }
      for(int c=0; c<N; c++)
      {
        ret._internal[c1][c] -= (conjugate(pr) * ret._internal[b][c] + conjugate(prn) * ret._internal[b+N/2][c] );    //  U_c1 -= (  <U_c1 | U_b > U_b + <U_c1 | U_{b+N} > U_{b+N}  )
      }
    }
    zeroit(inner);
    for(int c2=0;c2<N;c2++)
    {
      inner += innerProduct(ret._internal[c1][c2],ret._internal[c1][c2]);
    }
    nrm = sqrt(inner);
    nrm = 1.0/nrm;
    for(int c2=0;c2<N;c2++)
    {
      ret._internal[c1][c2]*= nrm;
    }
    for(int c2=0;c2<N/2;c2++)
    {
      ret._internal[c1+N/2][c2+N/2] = conjugate(ret._internal[c1][c2]);          // down right in the new matrix = (up-left)* of the old matrix
    }
    for(int c2=N/2;c2<N;c2++)
    {
      ret._internal[c1+N/2][c2-N/2] = -conjugate(ret._internal[c1][c2]);;     // down left in the new matrix = -(up-right)* of the old
    }
  }
  return ret;
 }
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/tensors/Tensor_exp.h
+++ b/Grid/tensors/Tensor_exp.h
@ -53,7 +53,6 @@ template<class vtype, int N> accelerator_inline iVector<vtype, N> Exponentiate(c
 }
 // Specialisation: Cayley-Hamilton exponential for SU(3)
 #if 0
 template<class vtype, typename std::enable_if< GridTypeMapper<vtype>::TensorLevel == 0>::type * =nullptr> 
--- a/Grid/tensors/Tensor_trace.h
+++ b/Grid/tensors/Tensor_trace.h
@ -69,6 +69,35 @@ accelerator_inline auto trace(const iVector<vtype,N> &arg) -> iVector<decltype(t
  }
  return ret;
 }
 ////////////////////////////
 // Fast path traceProduct
 ////////////////////////////
 template<class S1 , class S2, IfNotGridTensor<S1> = 0, IfNotGridTensor<S2> = 0>
 accelerator_inline auto traceProduct( const S1 &arg1,const S2 &arg2)
  -> decltype(arg1*arg2)
 {
  return arg1*arg2;
 }
 template<class vtype,class rtype,int N >
 accelerator_inline auto traceProduct(const iMatrix<vtype,N> &arg1,const iMatrix<rtype,N> &arg2) -> iScalar<decltype(trace(arg1._internal[0][0]*arg2._internal[0][0]))>
 {
  iScalar<decltype( trace(arg1._internal[0][0]*arg2._internal[0][0] )) > ret;
  zeroit(ret._internal);
  for(int i=0;i<N;i++){
  for(int j=0;j<N;j++){
    ret._internal=ret._internal+traceProduct(arg1._internal[i][j],arg2._internal[j][i]);
  }}
  return ret;
 }
 template<class vtype,class rtype >
 accelerator_inline auto traceProduct(const iScalar<vtype> &arg1,const iScalar<rtype> &arg2) -> iScalar<decltype(trace(arg1._internal*arg2._internal))>
 {
  iScalar<decltype(trace(arg1._internal*arg2._internal))> ret;
  ret._internal=traceProduct(arg1._internal,arg2._internal);
  return ret;
 }
 NAMESPACE_END(Grid);
--- a/Show More
+++ b/Show More
		`@ -0,0 +1 @@`
							`../WilsonCloverFermionInstantiation.cc.master`
		`@ -0,0 +1 @@`
							`#define IMPLEMENTATION SpWilsonTwoIndexAntiSymmetricImplD`