Merge 461cd045c6 into 79ad567dd5

Merge branch 'develop' of https://github.com/paboyle/Grid into develop
More britney logging improvements
2025-10-26 01:29:34 +00:00 · 2024-03-21 22:50:18 +01:00 · 2024-03-19 15:43:42 +00:00 · 2024-03-19 14:36:21 +00:00 · 2024-03-19 14:28:33 +00:00 · 2024-03-13 18:18:44 -04:00
1264 changed files with 165962 additions and 101511 deletions
--- a/.github/ISSUE_TEMPLATE/bug-report.yml
+++ b/.github/ISSUE_TEMPLATE/bug-report.yml
@@ -0,0 +1,54 @@
 name: Bug report
 description: Report a bug.
 title: "<insert title>"
 labels: [bug]
 body:
  - type: markdown
    attributes:
      value: >
        Thank you for taking the time to file a bug report.
        Please check that the code is pointing to the HEAD of develop
        or any commit in master which is tagged with a version number.
  - type: textarea
    attributes:
      label: "Describe the issue:"
      description: >
        Describe the issue and any previous attempt to solve it.
    validations:
      required: true
  - type: textarea
    attributes:
      label: "Code example:"
      description: >
        If relevant, show how to reproduce the issue using a minimal working
        example.
      placeholder: |
        << your code here >>
      render: shell
    validations:
      required: false
  - type: textarea
    attributes:
      label: "Target platform:"
      description: >
        Give a description of the target platform (CPU, network, compiler).
        Please give the full CPU part description, using for example
        `cat /proc/cpuinfo | grep 'model name' | uniq` (Linux)
        or `sysctl machdep.cpu.brand_string` (macOS) and the full output
        the `--version` option of your compiler.
    validations:
      required: true
  - type: textarea
    attributes:
      label: "Configure options:"
      description: >
        Please give the exact configure command used and attach
        `config.log`, `grid.config.summary` and the output of `make V=1`.
      render: shell
    validations:
      required: true
--- a/.gitignore
+++ b/.gitignore
@@ -1,3 +1,7 @@
 # Doxygen stuff
 html/*
 latex/*
 # Compiled Object files #
 #########################
 *.slo
@@ -83,10 +87,12 @@ ltmain.sh
 .Trashes
 ehthumbs.db
 Thumbs.db
 .dirstamp
 # build directory #
 ###################
 build*/*
 Documentation/_build
 # IDE related files #
 #####################
@@ -97,11 +103,8 @@ build.sh
 # Eigen source #
 ################
-lib/Eigen/*
+Grid/Eigen
-
+Eigen/*
 # FFTW source #
 ################
 lib/fftw/*
 # libtool macros #
 ##################
@@ -112,21 +115,8 @@ m4/libtool.m4
 ################
 gh-pages/
 # Buck files #
 ##############
 .buck*
 buck-out
 BUCK
 make-bin-BUCK.sh
 # generated sources #
 #####################
-lib/qcd/spin/gamma-gen/*.h
+Grid/qcd/spin/gamma-gen/*.h
-lib/qcd/spin/gamma-gen/*.cc
+Grid/qcd/spin/gamma-gen/*.cc
-lib/version.h
+Grid/util/Version.h
 # vs code editor files #
 ########################
 .vscode/
 .vscode/settings.json
 settings.json
--- a/.travis.yml
+++ b/.travis.yml
@@ -1,60 +0,0 @@
 language: cpp
 cache:
  directories:
    - clang
 matrix:
  include:
    - os:        osx
      osx_image: xcode8.3
      compiler: clang
 before_install:
    - export GRIDDIR=`pwd`
    - if [[ "$TRAVIS_OS_NAME" == "linux" ]] && [[ "$CC" == "clang" ]] && [ ! -e clang/bin ]; then wget $CLANG_LINK; tar -xf `basename $CLANG_LINK`; mkdir clang; mv clang+*/* clang/; fi
    - if [[ "$TRAVIS_OS_NAME" == "linux" ]] && [[ "$CC" == "clang" ]]; then export PATH="${GRIDDIR}/clang/bin:${PATH}"; fi
    - if [[ "$TRAVIS_OS_NAME" == "linux" ]] && [[ "$CC" == "clang" ]]; then export LD_LIBRARY_PATH="${GRIDDIR}/clang/lib:${LD_LIBRARY_PATH}"; fi
    - if [[ "$TRAVIS_OS_NAME" == "osx" ]]; then brew update; fi
    - if [[ "$TRAVIS_OS_NAME" == "osx" ]]; then brew install libmpc; fi
 install:
    - export CWD=`pwd`
    - echo $CWD
    - export CC=$CC$VERSION
    - export CXX=$CXX$VERSION
    - echo $PATH
    - which autoconf
    - autoconf  --version
    - which automake
    - automake  --version
    - which $CC
    - $CC  --version
    - which $CXX
    - $CXX --version
    - if [[ "$TRAVIS_OS_NAME" == "osx" ]]; then export LDFLAGS='-L/usr/local/lib'; fi
 script:
    - ./bootstrap.sh
    - mkdir build
    - cd build
    - mkdir lime
    - cd lime
    - mkdir build
    - cd build
    - wget http://usqcd-software.github.io/downloads/c-lime/lime-1.3.2.tar.gz
    - tar xf lime-1.3.2.tar.gz
    - cd lime-1.3.2
    - ./configure --prefix=$CWD/build/lime/install
    - make -j4
    - make install
    - cd $CWD/build
    - ../configure --enable-precision=single --enable-simd=SSE4 --enable-comms=none --with-lime=$CWD/build/lime/install
    - make -j4 
    - ./benchmarks/Benchmark_dwf --threads 1 --debug-signals
    - echo make clean
    - ../configure --enable-precision=double --enable-simd=SSE4 --enable-comms=none --with-lime=$CWD/build/lime/install
    - make -j4
    - ./benchmarks/Benchmark_dwf --threads 1 --debug-signals
    - make check
--- a/5
+++ b/5
@@ -0,0 +1,5 @@
 Version : 0.8.0
 - Clang 3.5 and above, ICPC v16 and above, GCC 6.3 and above recommended
 - MPI and MPI3 comms optimisations for KNL and OPA finished
 - Half precision comms
--- a/Grid/DisableWarnings.h
+++ b/Grid/DisableWarnings.h
@@ -0,0 +1,73 @@
 /*************************************************************************************
 Grid physics library, www.github.com/paboyle/Grid
 Source file: ./lib/DisableWarnings.h
 Copyright (C) 2016
 Author: Guido Cossu <guido.cossu@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 DISABLE_WARNINGS_H
 #define DISABLE_WARNINGS_H
 #if defined __GNUC__ && __GNUC__>=6
 #pragma GCC diagnostic ignored "-Wignored-attributes"
 #endif
 //disables and intel compiler specific warning (in json.hpp)
 #ifdef __ICC
 #pragma warning disable 488  
 #endif
 #ifdef __NVCC__
 //disables nvcc specific warning in json.hpp
 #pragma clang diagnostic ignored "-Wdeprecated-register"
 #ifdef __NVCC_DIAG_PRAGMA_SUPPORT__
 //disables nvcc specific warning in json.hpp
 #pragma nv_diag_suppress unsigned_compare_with_zero
 #pragma nv_diag_suppress cast_to_qualified_type
 //disables nvcc specific warning in many files
 #pragma nv_diag_suppress esa_on_defaulted_function_ignored
 #pragma nv_diag_suppress extra_semicolon
 #else
 //disables nvcc specific warning in json.hpp
 #pragma diag_suppress unsigned_compare_with_zero
 #pragma diag_suppress cast_to_qualified_type
 //disables nvcc specific warning in many files
 #pragma diag_suppress esa_on_defaulted_function_ignored
 #pragma diag_suppress extra_semicolon
 #endif
 #endif
 // Disable vectorisation in Eigen on the Power8/9 and PowerPC
 #ifdef  __ALTIVEC__
 #define  EIGEN_DONT_VECTORIZE
 #endif
 #ifdef  __VSX__
 #define  EIGEN_DONT_VECTORIZE
 #endif
 #endif
--- a/Grid/Grid.h
+++ b/Grid/Grid.h
@@ -42,6 +42,7 @@ Author: paboyle <paboyle@ph.ed.ac.uk>
 #include <Grid/GridQCDcore.h>
 #include <Grid/qcd/action/Action.h>
 #include <Grid/qcd/utils/GaugeFix.h>
 #include <Grid/qcd/utils/CovariantSmearing.h>
 #include <Grid/qcd/smearing/Smearing.h>
 #include <Grid/parallelIO/MetaData.h>
 #include <Grid/qcd/hmc/HMC_aggregate.h>
--- a/Grid/GridCore.h
+++ b/Grid/GridCore.h
@@ -38,16 +38,21 @@ Author: paboyle <paboyle@ph.ed.ac.uk>
 #ifndef GRID_BASE_H
 #define GRID_BASE_H
 #include <Grid/GridStd.h>
 #include <Grid/DisableWarnings.h>
 #include <Grid/Namespace.h>
 #include <Grid/GridStd.h>
 #include <Grid/threads/Pragmas.h>
 #include <Grid/perfmon/Timer.h>
-#include <Grid/perfmon/PerfCount.h>
+//#include <Grid/perfmon/PerfCount.h>
 #include <Grid/log/Log.h>
 #include <Grid/allocator/AlignedAllocator.h>
 #include <Grid/simd/Simd.h>
 #include <Grid/serialisation/Serialisation.h>
 #include <Grid/threads/Threads.h>
 #include <Grid/util/Util.h>
 #include <Grid/log/Log.h>
 #include <Grid/perfmon/Tracing.h>
 #include <Grid/allocator/Allocator.h>
 #include <Grid/simd/Simd.h>
 #include <Grid/threads/ThreadReduction.h>
 #include <Grid/serialisation/Serialisation.h>
 #include <Grid/util/Sha.h>
 #include <Grid/communicator/Communicator.h> 
 #include <Grid/cartesian/Cartesian.h>    
 #include <Grid/tensors/Tensors.h>      
@@ -56,5 +61,6 @@ Author: paboyle <paboyle@ph.ed.ac.uk>
 #include <Grid/stencil/Stencil.h>      
 #include <Grid/parallelIO/BinaryIO.h>
 #include <Grid/algorithms/Algorithms.h>   
 NAMESPACE_CHECK(GridCore)
 #endif
--- a/Grid/GridQCDcore.h
+++ b/Grid/GridQCDcore.h
@@ -36,7 +36,9 @@ Author: paboyle <paboyle@ph.ed.ac.uk>
 #include <Grid/GridCore.h>
 #include <Grid/qcd/QCD.h>
 #include <Grid/qcd/spin/Spin.h>
 #include <Grid/qcd/gparity/Gparity.h>
 #include <Grid/qcd/utils/Utils.h>
 #include <Grid/qcd/representations/Representations.h>
 NAMESPACE_CHECK(GridQCDCore);
 #endif
--- a/Grid/GridStd.h
+++ b/Grid/GridStd.h
@@ -6,7 +6,9 @@
 ///////////////////
 #include <cassert>
 #include <complex>
 #include <memory>
 #include <vector>
 #include <array>
 #include <string>
 #include <iostream>
 #include <iomanip>
@@ -14,6 +16,7 @@
 #include <functional>
 #include <stdio.h>
 #include <stdlib.h>
 #include <strings.h>
 #include <stdio.h>
 #include <signal.h>
 #include <ctime>
@@ -26,4 +29,7 @@
 ///////////////////
 #include "Config.h"
 #ifdef TOFU
 #undef GRID_COMMS_THREADS
 #endif
 #endif /* GRID_STD_H */
--- a/Grid/Grid_Eigen_Dense.h
+++ b/Grid/Grid_Eigen_Dense.h
@@ -0,0 +1,75 @@
 #include <Grid/GridCore.h>
 #pragma once
 // Force Eigen to use MKL if Grid has been configured with --enable-mkl
 #ifdef USE_MKL
 #define EIGEN_USE_MKL_ALL
 #endif
 #if defined __GNUC__
 #pragma GCC diagnostic push
 #pragma GCC diagnostic ignored "-Wdeprecated-declarations"
 #endif
 /* NVCC save and restore compile environment*/
 #ifdef __NVCC__
 #pragma push
 #ifdef __NVCC_DIAG_PRAGMA_SUPPORT__
 #pragma nv_diag_suppress code_is_unreachable
 #else
 #pragma diag_suppress code_is_unreachable
 #endif
 #pragma push_macro("__CUDA_ARCH__")
 #pragma push_macro("__NVCC__")
 #pragma push_macro("__CUDACC__")
 #undef __CUDA_ARCH__
 #undef __NVCC__
 #undef __CUDACC__
 #define __NVCC__REDEFINE__
 #endif 
 /* SYCL save and restore compile environment*/
 #ifdef GRID_SYCL
 #pragma push
 #pragma push_macro("__SYCL_DEVICE_ONLY__")
 #undef __SYCL_DEVICE_ONLY__
 #define EIGEN_DONT_VECTORIZE
 #undef EIGEN_USE_SYCL
 #define __SYCL__REDEFINE__
 #endif
 /* HIP save and restore compile environment*/
 #ifdef GRID_HIP
 #pragma push
 #pragma push_macro("__HIP_DEVICE_COMPILE__")
 #endif
 #define EIGEN_NO_HIP
 #include <Grid/Eigen/Dense>
 #include <Grid/Eigen/unsupported/CXX11/Tensor>
 /* NVCC restore */
 #ifdef __NVCC__REDEFINE__
 #pragma pop_macro("__CUDACC__")
 #pragma pop_macro("__NVCC__")
 #pragma pop_macro("__CUDA_ARCH__")
 #pragma pop
 #endif
 /*SYCL restore*/
 #ifdef __SYCL__REDEFINE__
 #pragma pop_macro("__SYCL_DEVICE_ONLY__")
 #pragma pop
 #endif
 /*HIP restore*/
 #ifdef __HIP__REDEFINE__
 #pragma pop_macro("__HIP_DEVICE_COMPILE__")
 #pragma pop
 #endif
 #if defined __GNUC__
 #pragma GCC diagnostic pop
 #endif
--- a/Grid/Grid_Eigen_Tensor.h
+++ b/Grid/Grid_Eigen_Tensor.h
@@ -0,0 +1 @@
 #include <Grid/Grid_Eigen_Dense.h>
--- a/Grid/Makefile.am
+++ b/Grid/Makefile.am
@@ -0,0 +1,81 @@
 extra_sources=
 extra_headers=
 if BUILD_COMMS_MPI3
  extra_sources+=communicator/Communicator_mpi3.cc
  extra_sources+=communicator/Communicator_base.cc
  extra_sources+=communicator/SharedMemoryMPI.cc
  extra_sources+=communicator/SharedMemory.cc
 endif
 if BUILD_COMMS_NONE
  extra_sources+=communicator/Communicator_none.cc
  extra_sources+=communicator/Communicator_base.cc
  extra_sources+=communicator/SharedMemoryNone.cc
  extra_sources+=communicator/SharedMemory.cc
 endif
 if BUILD_HDF5
  extra_sources+=serialisation/Hdf5IO.cc 
  extra_headers+=serialisation/Hdf5IO.h
  extra_headers+=serialisation/Hdf5Type.h
 endif
 all: version-cache Version.h
 version-cache:
 	@if [ `git status --porcelain | grep -v '??' | wc -l` -gt 0 ]; then\
 		a="uncommited changes";\
 	else\
 		a="clean";\
 	fi;\
 	echo "`git log -n 1 --format=format:"#define GITHASH \\"%H:%d $$a\\"%n" HEAD`" > vertmp;\
 	if [ -e version-cache ]; then\
 		d=`diff vertmp version-cache`;\
 		if [ "$${d}" != "" ]; then\
 			mv vertmp version-cache;\
 			rm -f Version.h;\
 		fi;\
 	else\
 		mv vertmp version-cache;\
 		rm -f Version.h;\
 	fi;\
 	rm -f vertmp
 Version.h: version-cache
 	cp version-cache Version.h
 .PHONY: version-cache
 #
 # Libraries
 #
 include Make.inc
 include Eigen.inc
 extra_sources+=$(WILS_FERMION_FILES)
 extra_sources+=$(STAG_FERMION_FILES)
 if BUILD_ZMOBIUS
  extra_sources+=$(ZWILS_FERMION_FILES)
 endif
 if BUILD_GPARITY
  extra_sources+=$(GP_FERMION_FILES)
 endif
 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
 CCFILES += $(extra_sources)
 HFILES  += $(extra_headers) Config.h Version.h
 libGrid_a_SOURCES              = $(CCFILES)
 libGrid_adir                   = $(includedir)/Grid
 nobase_dist_pkginclude_HEADERS = $(HFILES) $(eigen_files) $(eigen_unsupp_files)
--- a/Grid/Namespace.h
+++ b/Grid/Namespace.h
@@ -0,0 +1,38 @@
 /*************************************************************************************
 Grid physics library, www.github.com/paboyle/Grid
 Source file: ./lib/Namespace.h
 Copyright (C) 2016
 Author: Peter Boyle <paboyle@ph.ed.ac.uk>
 This program is free software; you can redistribute it and/or modify
 it under the terms of the GNU General Public License as published by
 the Free Software Foundation; either version 2 of the License, or
 (at your option) any later version.
 This program is distributed in the hope that it will be useful,
 but WITHOUT ANY WARRANTY; without even the implied warranty of
 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 GNU General Public License for more details.
 You should have received a copy of the GNU General Public License along
 with this program; if not, write to the Free Software Foundation, Inc.,
 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
 See the full license in the file "LICENSE" in the top level distribution
 directory
 *************************************************************************************/
 /*  END LEGAL */
 #pragma once
 #include <type_traits>
 #include <cassert>
 #define NAMESPACE_BEGIN(A) namespace A {
 #define NAMESPACE_END(A)   }
 #define GRID_NAMESPACE_BEGIN NAMESPACE_BEGIN(Grid)
 #define GRID_NAMESPACE_END   NAMESPACE_END(Grid)
 #define NAMESPACE_CHECK(x) struct namespaceTEST##x {};  static_assert(std::is_same<namespaceTEST##x, ::namespaceTEST##x>::value,"Not in :: at"  ); 
--- a/Grid/algorithms/Algorithms.h
+++ b/Grid/algorithms/Algorithms.h
@@ -29,33 +29,48 @@ Author: Peter Boyle <paboyle@ph.ed.ac.uk>
 #ifndef GRID_ALGORITHMS_H
 #define GRID_ALGORITHMS_H
 NAMESPACE_CHECK(algorithms);
 #include <Grid/algorithms/SparseMatrix.h>
 #include <Grid/algorithms/LinearOperator.h>
 #include <Grid/algorithms/Preconditioner.h>
 NAMESPACE_CHECK(SparseMatrix);
 #include <Grid/algorithms/approx/Zolotarev.h>
 #include <Grid/algorithms/approx/Chebyshev.h>
 #include <Grid/algorithms/approx/JacobiPolynomial.h>
 #include <Grid/algorithms/approx/Remez.h>
 #include <Grid/algorithms/approx/MultiShiftFunction.h>
 #include <Grid/algorithms/approx/Forecast.h>
-
+#include <Grid/algorithms/approx/RemezGeneral.h>
 #include <Grid/algorithms/approx/ZMobius.h>
 NAMESPACE_CHECK(approx);
 #include <Grid/algorithms/iterative/Deflation.h>
 #include <Grid/algorithms/iterative/ConjugateGradient.h>
 NAMESPACE_CHECK(ConjGrad);
 #include <Grid/algorithms/iterative/BiCGSTAB.h>
 NAMESPACE_CHECK(BiCGSTAB);
 #include <Grid/algorithms/iterative/ConjugateResidual.h>
 #include <Grid/algorithms/iterative/NormalEquations.h>
 #include <Grid/algorithms/iterative/SchurRedBlack.h>
 #include <Grid/algorithms/iterative/ConjugateGradientMultiShift.h>
 #include <Grid/algorithms/iterative/ConjugateGradientMixedPrec.h>
 #include <Grid/algorithms/iterative/ConjugateGradientMultiShiftMixedPrec.h>
 #include <Grid/algorithms/iterative/ConjugateGradientMixedPrecBatched.h>
 #include <Grid/algorithms/iterative/BiCGSTABMixedPrec.h>
 #include <Grid/algorithms/iterative/BlockConjugateGradient.h>
 #include <Grid/algorithms/iterative/ConjugateGradientReliableUpdate.h>
 #include <Grid/algorithms/iterative/MinimalResidual.h>
 #include <Grid/algorithms/iterative/GeneralisedMinimalResidual.h>
 #include <Grid/algorithms/iterative/CommunicationAvoidingGeneralisedMinimalResidual.h>
 #include <Grid/algorithms/iterative/FlexibleGeneralisedMinimalResidual.h>
 #include <Grid/algorithms/iterative/FlexibleCommunicationAvoidingGeneralisedMinimalResidual.h>
 #include <Grid/algorithms/iterative/MixedPrecisionFlexibleGeneralisedMinimalResidual.h>
 #include <Grid/algorithms/iterative/ImplicitlyRestartedLanczos.h>
 #include <Grid/algorithms/iterative/PowerMethod.h>
 NAMESPACE_CHECK(PowerMethod);
 #include <Grid/algorithms/CoarsenedMatrix.h>
 NAMESPACE_CHECK(CoarsendMatrix);
 #include <Grid/algorithms/FFT.h>
 // EigCg
 // Pcg
 // Hdcg
 // GCR
 // etc..
 #endif
--- a/Grid/algorithms/CoarsenedMatrix.h
+++ b/Grid/algorithms/CoarsenedMatrix.h
--- a/Grid/algorithms/FFT.h
+++ b/Grid/algorithms/FFT.h
@@ -0,0 +1,296 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./lib/Cshift.h
    Copyright (C) 2015
 Author: Peter Boyle <paboyle@ph.ed.ac.uk>
    This program is free software; you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation; either version 2 of the License, or
    (at your option) any later version.
    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.
    You should have received a copy of the GNU General Public License along
    with this program; if not, write to the Free Software Foundation, Inc.,
    51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
    See the full license in the file "LICENSE" in the top level distribution directory
 *************************************************************************************/
 /*  END LEGAL */
 #ifndef _GRID_FFT_H_
 #define _GRID_FFT_H_
 #ifdef HAVE_FFTW
 #if defined(USE_MKL) || defined(GRID_SYCL)
 #include <fftw/fftw3.h>
 #else
 #include <fftw3.h>
 #endif
 #endif
 NAMESPACE_BEGIN(Grid);
 template<class scalar> struct FFTW { };
 #ifdef HAVE_FFTW	
 template<> struct FFTW<ComplexD> {
 public:
  typedef fftw_complex FFTW_scalar;
  typedef fftw_plan    FFTW_plan;
  static FFTW_plan fftw_plan_many_dft(int rank, const int *n,int howmany,
 				      FFTW_scalar *in, const int *inembed,		
 				      int istride, int idist,		
 				      FFTW_scalar *out, const int *onembed,		
 				      int ostride, int odist,		
 				      int sign, unsigned flags) {
    return ::fftw_plan_many_dft(rank,n,howmany,in,inembed,istride,idist,out,onembed,ostride,odist,sign,flags);
  }	  
  static void fftw_flops(const FFTW_plan p,double *add, double *mul, double *fmas){
    ::fftw_flops(p,add,mul,fmas);
  }
  inline static void fftw_execute_dft(const FFTW_plan p,FFTW_scalar *in,FFTW_scalar *out) {
    ::fftw_execute_dft(p,in,out);
  }
  inline static void fftw_destroy_plan(const FFTW_plan p) {
    ::fftw_destroy_plan(p);
  }
 };
 template<> struct FFTW<ComplexF> {
 public:
  typedef fftwf_complex FFTW_scalar;
  typedef fftwf_plan    FFTW_plan;
  static FFTW_plan fftw_plan_many_dft(int rank, const int *n,int howmany,
 				      FFTW_scalar *in, const int *inembed,		
 				      int istride, int idist,		
 				      FFTW_scalar *out, const int *onembed,		
 				      int ostride, int odist,		
 				      int sign, unsigned flags) {
    return ::fftwf_plan_many_dft(rank,n,howmany,in,inembed,istride,idist,out,onembed,ostride,odist,sign,flags);
  }	  
  static void fftw_flops(const FFTW_plan p,double *add, double *mul, double *fmas){
    ::fftwf_flops(p,add,mul,fmas);
  }
  inline static void fftw_execute_dft(const FFTW_plan p,FFTW_scalar *in,FFTW_scalar *out) {
    ::fftwf_execute_dft(p,in,out);
  }
  inline static void fftw_destroy_plan(const FFTW_plan p) {
    ::fftwf_destroy_plan(p);
  }
 };
 #endif
 #ifndef FFTW_FORWARD
 #define FFTW_FORWARD (-1)
 #define FFTW_BACKWARD (+1)
 #endif
 class FFT {
 private:
  GridCartesian *vgrid;
  GridCartesian *sgrid;
  int Nd;
  double flops;
  double flops_call;
  uint64_t usec;
  Coordinate dimensions;
  Coordinate processors;
  Coordinate processor_coor;
 public:
  static const int forward=FFTW_FORWARD;
  static const int backward=FFTW_BACKWARD;
  double Flops(void) {return flops;}
  double MFlops(void) {return flops/usec;}
  double USec(void)   {return (double)usec;}    
  FFT ( GridCartesian * grid ) :
    vgrid(grid),
    Nd(grid->_ndimension),
    dimensions(grid->_fdimensions),
    processors(grid->_processors),
    processor_coor(grid->_processor_coor)
  {
    flops=0;
    usec =0;
    Coordinate layout(Nd,1);
    sgrid = new GridCartesian(dimensions,layout,processors,*grid);
  };
  ~FFT ( void)  {
    delete sgrid;
  }
  template<class vobj>
  void FFT_dim_mask(Lattice<vobj> &result,const Lattice<vobj> &source,Coordinate mask,int sign){
    conformable(result.Grid(),vgrid);
    conformable(source.Grid(),vgrid);
    Lattice<vobj> tmp(vgrid);
    tmp = source;
    for(int d=0;d<Nd;d++){
      if( mask[d] ) {
 	FFT_dim(result,tmp,d,sign);
 	tmp=result;
      }
    }
  }
  template<class vobj>
  void FFT_all_dim(Lattice<vobj> &result,const Lattice<vobj> &source,int sign){
    Coordinate mask(Nd,1);
    FFT_dim_mask(result,source,mask,sign);
  }
  template<class vobj>
  void FFT_dim(Lattice<vobj> &result,const Lattice<vobj> &source,int dim, int sign){
 #ifndef HAVE_FFTW
    assert(0);
 #else
    conformable(result.Grid(),vgrid);
    conformable(source.Grid(),vgrid);
    int L = vgrid->_ldimensions[dim];
    int G = vgrid->_fdimensions[dim];
    Coordinate layout(Nd,1);
    Coordinate pencil_gd(vgrid->_fdimensions);
    pencil_gd[dim] = G*processors[dim];
    // Pencil global vol LxLxGxLxL per node
    GridCartesian pencil_g(pencil_gd,layout,processors,*vgrid);
    // Construct pencils
    typedef typename vobj::scalar_object sobj;
    typedef typename sobj::scalar_type   scalar;
    Lattice<sobj> pgbuf(&pencil_g);
    autoView(pgbuf_v , pgbuf, CpuWrite);
    typedef typename FFTW<scalar>::FFTW_scalar FFTW_scalar;
    typedef typename FFTW<scalar>::FFTW_plan   FFTW_plan;
    int Ncomp = sizeof(sobj)/sizeof(scalar);
    int Nlow  = 1;
    for(int d=0;d<dim;d++){
      Nlow*=vgrid->_ldimensions[d];
    }
    int rank = 1;  /* 1d transforms */
    int n[] = {G}; /* 1d transforms of length G */
    int howmany = Ncomp;
    int odist,idist,istride,ostride;
    idist   = odist   = 1;          /* Distance between consecutive FT's */
    istride = ostride = Ncomp*Nlow; /* distance between two elements in the same FT */
    int *inembed = n, *onembed = n;
    scalar div;
    if ( sign == backward ) div = 1.0/G;
    else if ( sign == forward ) div = 1.0;
    else assert(0);
    FFTW_plan p;
    {
      FFTW_scalar *in = (FFTW_scalar *)&pgbuf_v[0];
      FFTW_scalar *out= (FFTW_scalar *)&pgbuf_v[0];
      p = FFTW<scalar>::fftw_plan_many_dft(rank,n,howmany,
 					   in,inembed,
 					   istride,idist,
 					   out,onembed,
 					   ostride, odist,
 					   sign,FFTW_ESTIMATE);
    }
    // Barrel shift and collect global pencil
    Coordinate lcoor(Nd), gcoor(Nd);
    result = source;
    int pc = processor_coor[dim];
    for(int p=0;p<processors[dim];p++) {
      {
 	autoView(r_v,result,CpuRead);
 	autoView(p_v,pgbuf,CpuWrite);
 	thread_for(idx, sgrid->lSites(),{
          Coordinate cbuf(Nd);
          sobj s;
 	  sgrid->LocalIndexToLocalCoor(idx,cbuf);
 	  peekLocalSite(s,r_v,cbuf);
 	  cbuf[dim]+=((pc+p) % processors[dim])*L;
 	  pokeLocalSite(s,p_v,cbuf);
        });
      }
      if (p != processors[dim] - 1) {
 	result = Cshift(result,dim,L);
      }
    }
    // Loop over orthog coords
    int NN=pencil_g.lSites();
    GridStopWatch timer;
    timer.Start();
    thread_for( idx,NN,{
        Coordinate cbuf(Nd);
 	pencil_g.LocalIndexToLocalCoor(idx, cbuf);
 	if ( cbuf[dim] == 0 ) {  // restricts loop to plane at lcoor[dim]==0
 	  FFTW_scalar *in = (FFTW_scalar *)&pgbuf_v[idx];
 	  FFTW_scalar *out= (FFTW_scalar *)&pgbuf_v[idx];
 	  FFTW<scalar>::fftw_execute_dft(p,in,out);
 	}
    });
    timer.Stop();
    // performance counting
    double add,mul,fma;
    FFTW<scalar>::fftw_flops(p,&add,&mul,&fma);
    flops_call = add+mul+2.0*fma;
    usec += timer.useconds();
    flops+= flops_call*NN;
    // writing out result
    {
      autoView(pgbuf_v,pgbuf,CpuRead);
      autoView(result_v,result,CpuWrite);
      thread_for(idx,sgrid->lSites(),{
 	Coordinate clbuf(Nd), cgbuf(Nd);
 	sobj s;
 	sgrid->LocalIndexToLocalCoor(idx,clbuf);
 	cgbuf = clbuf;
 	cgbuf[dim] = clbuf[dim]+L*pc;
 	peekLocalSite(s,pgbuf_v,cgbuf);
 	pokeLocalSite(s,result_v,clbuf);
      });
    }
    result = result*div;
    // destroying plan
    FFTW<scalar>::fftw_destroy_plan(p);
 #endif
  }
 };
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/algorithms/LinearOperator.h
+++ b/Grid/algorithms/LinearOperator.h
@@ -0,0 +1,641 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./lib/algorithms/LinearOperator.h
    Copyright (C) 2015
 Author: Azusa Yamaguchi <ayamaguc@staffmail.ed.ac.uk>
 Author: Peter Boyle <paboyle@ph.ed.ac.uk>
    This program is free software; you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation; either version 2 of the License, or
    (at your option) any later version.
    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.
    You should have received a copy of the GNU General Public License along
    with this program; if not, write to the Free Software Foundation, Inc.,
    51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
    See the full license in the file "LICENSE" in the top level distribution directory
 *************************************************************************************/
 /*  END LEGAL */
 #pragma once 
 NAMESPACE_BEGIN(Grid);
 /////////////////////////////////////////////////////////////////////////////////////////////
 // LinearOperators Take a something and return a something.
 /////////////////////////////////////////////////////////////////////////////////////////////
 //
 // Hopefully linearity is satisfied and the AdjOp is indeed the Hermitian Conjugateugate (transpose if real):
 //SBase
 //   i)  F(a x + b y) = aF(x) + b F(y).
 //  ii)  <x|Op|y> = <y|AdjOp|x>^\ast
 //
 // Would be fun to have a test linearity & Herm Conj function!
 /////////////////////////////////////////////////////////////////////////////////////////////
 template<class Field> class LinearOperatorBase {
 public:
  // Support for coarsening to a multigrid
  virtual void OpDiag (const Field &in, Field &out) = 0; // Abstract base
  virtual void OpDir  (const Field &in, Field &out,int dir,int disp) = 0; // Abstract base
  virtual void OpDirAll  (const Field &in, std::vector<Field> &out) = 0; // Abstract base
  virtual void Op     (const Field &in, Field &out) = 0; // Abstract base
  virtual void AdjOp  (const Field &in, Field &out) = 0; // Abstract base
  virtual void HermOpAndNorm(const Field &in, Field &out,RealD &n1,RealD &n2)=0;
  virtual void HermOp(const Field &in, Field &out)=0;
  virtual ~LinearOperatorBase(){};
 };
 /////////////////////////////////////////////////////////////////////////////////////////////
 // By sharing the class for Sparse Matrix across multiple operator wrappers, we can share code
 // between RB and non-RB variants. Sparse matrix is like the fermion action def, and then
 // the wrappers implement the specialisation of "Op" and "AdjOp" to the cases minimising
 // replication of code.
 //
 // I'm not entirely happy with implementation; to share the Schur code between herm and non-herm
 // while still having a "OpAndNorm" in the abstract base I had to implement it in both cases
 // with an assert trap in the non-herm. This isn't right; there must be a better C++ way to
 // do it, but I fear it required multiple inheritance and mixed in abstract base classes
 /////////////////////////////////////////////////////////////////////////////////////////////
 ////////////////////////////////////////////////////////////////////
 // Construct herm op from non-herm matrix
 ////////////////////////////////////////////////////////////////////
 template<class Matrix,class Field>
 class MdagMLinearOperator : public LinearOperatorBase<Field> {
  Matrix &_Mat;
 public:
  MdagMLinearOperator(Matrix &Mat): _Mat(Mat){};
  // Support for coarsening to a multigrid
  void OpDiag (const Field &in, Field &out) {
    _Mat.Mdiag(in,out);
  }
  void OpDir  (const Field &in, Field &out,int dir,int disp) {
    _Mat.Mdir(in,out,dir,disp);
  }
  void OpDirAll  (const Field &in, std::vector<Field> &out){
    _Mat.MdirAll(in,out);
  };
  void Op     (const Field &in, Field &out){
    _Mat.M(in,out);
  }
  void AdjOp     (const Field &in, Field &out){
    _Mat.Mdag(in,out);
  }
  void HermOpAndNorm(const Field &in, Field &out,RealD &n1,RealD &n2){
    _Mat.MdagM(in,out);
    ComplexD dot = innerProduct(in,out);
    n1=real(dot);
    n2=norm2(out);
  }
  void HermOp(const Field &in, Field &out){
    _Mat.MdagM(in,out);
  }
 };
 ////////////////////////////////////////////////////////////////////
 // Construct herm op and shift it for mgrid smoother
 ////////////////////////////////////////////////////////////////////
 template<class Matrix,class Field>
 class ShiftedMdagMLinearOperator : public LinearOperatorBase<Field> {
  Matrix &_Mat;
  RealD _shift;
 public:
  ShiftedMdagMLinearOperator(Matrix &Mat,RealD shift): _Mat(Mat), _shift(shift){};
  // Support for coarsening to a multigrid
  void OpDiag (const Field &in, Field &out) {
    _Mat.Mdiag(in,out);
    assert(0);
  }
  void OpDir  (const Field &in, Field &out,int dir,int disp) {
    _Mat.Mdir(in,out,dir,disp);
    assert(0);
  }
  void OpDirAll  (const Field &in, std::vector<Field> &out){
    assert(0);
  };
  void Op     (const Field &in, Field &out){
    _Mat.M(in,out);
    assert(0);
  }
  void AdjOp     (const Field &in, Field &out){
    _Mat.Mdag(in,out);
    assert(0);
  }
  void HermOpAndNorm(const Field &in, Field &out,RealD &n1,RealD &n2){
    HermOp(in,out);
    ComplexD dot = innerProduct(in,out);
    n1=real(dot);
    n2=norm2(out);
  }
  void HermOp(const Field &in, Field &out){
    _Mat.MdagM(in,out);
    out = out + _shift*in;
  }
 };
 ////////////////////////////////////////////////////////////////////
 // Wrap an already herm matrix
 ////////////////////////////////////////////////////////////////////
 template<class Matrix,class Field>
 class HermitianLinearOperator : public LinearOperatorBase<Field> {
  Matrix &_Mat;
 public:
  HermitianLinearOperator(Matrix &Mat): _Mat(Mat){};
  // Support for coarsening to a multigrid
  void OpDiag (const Field &in, Field &out) {
    _Mat.Mdiag(in,out);
  }
  void OpDir  (const Field &in, Field &out,int dir,int disp) {
    _Mat.Mdir(in,out,dir,disp);
  }
  void OpDirAll  (const Field &in, std::vector<Field> &out){
    _Mat.MdirAll(in,out);
  };
  void Op     (const Field &in, Field &out){
    _Mat.M(in,out);
  }
  void AdjOp     (const Field &in, Field &out){
    _Mat.M(in,out);
  }
  void HermOpAndNorm(const Field &in, Field &out,RealD &n1,RealD &n2){
    HermOp(in,out);
    ComplexD dot= innerProduct(in,out); n1=real(dot);
    n2=norm2(out);
  }
  void HermOp(const Field &in, Field &out){
    _Mat.M(in,out);
  }
 };
 template<class Matrix,class Field>
 class NonHermitianLinearOperator : public LinearOperatorBase<Field> {
  Matrix &_Mat;
 public:
  NonHermitianLinearOperator(Matrix &Mat): _Mat(Mat){};
  // Support for coarsening to a multigrid
  void OpDiag (const Field &in, Field &out) {
    _Mat.Mdiag(in,out);
  }
  void OpDir  (const Field &in, Field &out,int dir,int disp) {
    _Mat.Mdir(in,out,dir,disp);
  }
  void OpDirAll  (const Field &in, std::vector<Field> &out){
    _Mat.MdirAll(in,out);
  };
  void Op     (const Field &in, Field &out){
    _Mat.M(in,out);
  }
  void AdjOp     (const Field &in, Field &out){
    _Mat.Mdag(in,out);
  }
  void HermOpAndNorm(const Field &in, Field &out,RealD &n1,RealD &n2){
    assert(0);
  }
  void HermOp(const Field &in, Field &out){
    assert(0);
  }
 };
 //////////////////////////////////////////////////////////
 // Even Odd Schur decomp operators; there are several
 // ways to introduce the even odd checkerboarding
 //////////////////////////////////////////////////////////
 template<class Field>
 class SchurOperatorBase :  public LinearOperatorBase<Field> {
 public:
  virtual  void Mpc      (const Field &in, Field &out) =0;
  virtual  void MpcDag   (const Field &in, Field &out) =0;
  virtual  void MpcDagMpc(const Field &in, Field &out) {
    Field tmp(in.Grid());
    tmp.Checkerboard() = in.Checkerboard();
    Mpc(in,tmp);
    MpcDag(tmp,out);
  }
  virtual void HermOpAndNorm(const Field &in, Field &out,RealD &n1,RealD &n2){
    out.Checkerboard() = in.Checkerboard();
    MpcDagMpc(in,out);
    ComplexD dot= innerProduct(in,out); 
    n1=real(dot);
    n2=norm2(out);
  }
  virtual void HermOp(const Field &in, Field &out){
    out.Checkerboard() = in.Checkerboard();
    MpcDagMpc(in,out);
  }
  void Op     (const Field &in, Field &out){
    Mpc(in,out);
  }
  void AdjOp     (const Field &in, Field &out){ 
    MpcDag(in,out);
  }
  // Support for coarsening to a multigrid
  void OpDiag (const Field &in, Field &out) {
    assert(0); // must coarsen the unpreconditioned system
  }
  void OpDir  (const Field &in, Field &out,int dir,int disp) {
    assert(0);
  }
  void OpDirAll  (const Field &in, std::vector<Field> &out){
    assert(0);
  };
 };
 template<class Matrix,class Field>
  class SchurDiagMooeeOperator :  public SchurOperatorBase<Field> {
 public:
    Matrix &_Mat;
    SchurDiagMooeeOperator (Matrix &Mat): _Mat(Mat){};
    virtual  void Mpc      (const Field &in, Field &out) {
      Field tmp(in.Grid());
      tmp.Checkerboard() = !in.Checkerboard();
      _Mat.Meooe(in,tmp);
      _Mat.MooeeInv(tmp,out);
      _Mat.Meooe(out,tmp);
      _Mat.Mooee(in,out);
      axpy(out,-1.0,tmp,out);
    }
    virtual void MpcDag   (const Field &in, Field &out){
      Field tmp(in.Grid());
      _Mat.MeooeDag(in,tmp);
      _Mat.MooeeInvDag(tmp,out);
      _Mat.MeooeDag(out,tmp);
      _Mat.MooeeDag(in,out);
      axpy(out,-1.0,tmp,out);
    }
 };
 template<class Matrix,class Field>
  class SchurDiagOneOperator :  public SchurOperatorBase<Field> {
 protected:
    Matrix &_Mat;
 public:
    SchurDiagOneOperator (Matrix &Mat): _Mat(Mat){};
    virtual void Mpc      (const Field &in, Field &out) {
      Field tmp(in.Grid());
      _Mat.Meooe(in,out);
      _Mat.MooeeInv(out,tmp);
      _Mat.Meooe(tmp,out);
      _Mat.MooeeInv(out,tmp);
      axpy(out,-1.0,tmp,in);
    }
    virtual void MpcDag   (const Field &in, Field &out){
      Field tmp(in.Grid());
      _Mat.MooeeInvDag(in,out);
      _Mat.MeooeDag(out,tmp);
      _Mat.MooeeInvDag(tmp,out);
      _Mat.MeooeDag(out,tmp);
      axpy(out,-1.0,tmp,in);
    }
 };
 template<class Matrix,class Field>
  class SchurDiagTwoOperator :  public SchurOperatorBase<Field> {
 protected:
    Matrix &_Mat;
 public:
    SchurDiagTwoOperator (Matrix &Mat): _Mat(Mat){};
    virtual void Mpc      (const Field &in, Field &out) {
      Field tmp(in.Grid());
      _Mat.MooeeInv(in,out);
      _Mat.Meooe(out,tmp);
      _Mat.MooeeInv(tmp,out);
      _Mat.Meooe(out,tmp);
      axpy(out,-1.0,tmp,in);
    }
    virtual  void MpcDag   (const Field &in, Field &out){
      Field tmp(in.Grid());
      _Mat.MeooeDag(in,out);
      _Mat.MooeeInvDag(out,tmp);
      _Mat.MeooeDag(tmp,out);
      _Mat.MooeeInvDag(out,tmp);
      axpy(out,-1.0,tmp,in);
    }
 };
 template<class Field>
 class NonHermitianSchurOperatorBase :  public LinearOperatorBase<Field> 
 {
 public:
  virtual void  Mpc      (const Field& in, Field& out) = 0;
  virtual void  MpcDag   (const Field& in, Field& out) = 0;
  virtual void  MpcDagMpc(const Field& in, Field& out) {
    Field tmp(in.Grid());
    tmp.Checkerboard() = in.Checkerboard();
    Mpc(in,tmp);
    MpcDag(tmp,out);
  }
  virtual void HermOpAndNorm(const Field& in, Field& out, RealD& n1, RealD& n2) {
    assert(0);
  }
  virtual void HermOp(const Field& in, Field& out) {
    assert(0);
  }
  void Op(const Field& in, Field& out) {
    Mpc(in, out);
  }
  void AdjOp(const Field& in, Field& out) { 
    MpcDag(in, out);
  }
  // Support for coarsening to a multigrid
  void OpDiag(const Field& in, Field& out) {
    assert(0); // must coarsen the unpreconditioned system
  }
  void OpDir(const Field& in, Field& out, int dir, int disp) {
    assert(0);
  }
  void OpDirAll(const Field& in, std::vector<Field>& out){
    assert(0);
  };
 };
 template<class Matrix, class Field>
 class NonHermitianSchurDiagMooeeOperator :  public NonHermitianSchurOperatorBase<Field> 
 {
 public:
  Matrix& _Mat;
 NonHermitianSchurDiagMooeeOperator(Matrix& Mat): _Mat(Mat){};
  virtual void Mpc(const Field& in, Field& out) {
    Field tmp(in.Grid());
    tmp.Checkerboard() = !in.Checkerboard();
    _Mat.Meooe(in, tmp);
    _Mat.MooeeInv(tmp, out);
    _Mat.Meooe(out, tmp);
    _Mat.Mooee(in, out);
    axpy(out, -1.0, tmp, out);
  }
  virtual void MpcDag(const Field& in, Field& out) {
    Field tmp(in.Grid());
    _Mat.MeooeDag(in, tmp);
    _Mat.MooeeInvDag(tmp, out);
    _Mat.MeooeDag(out, tmp);
    _Mat.MooeeDag(in, out);
    axpy(out, -1.0, tmp, out);
  }
 };
 template<class Matrix,class Field>
 class NonHermitianSchurDiagOneOperator : public NonHermitianSchurOperatorBase<Field> 
 {
 protected:
  Matrix &_Mat;
 public:
  NonHermitianSchurDiagOneOperator (Matrix& Mat): _Mat(Mat){};
  virtual void Mpc(const Field& in, Field& out) {
    Field tmp(in.Grid());
    _Mat.Meooe(in, out);
    _Mat.MooeeInv(out, tmp);
    _Mat.Meooe(tmp, out);
    _Mat.MooeeInv(out, tmp);
    axpy(out, -1.0, tmp, in);
  }
  virtual void MpcDag(const Field& in, Field& out) {
    Field tmp(in.Grid());
    _Mat.MooeeInvDag(in, out);
    _Mat.MeooeDag(out, tmp);
    _Mat.MooeeInvDag(tmp, out);
    _Mat.MeooeDag(out, tmp);
    axpy(out, -1.0, tmp, in);
  }
 };
 template<class Matrix, class Field>
 class NonHermitianSchurDiagTwoOperator : public NonHermitianSchurOperatorBase<Field> 
 {
 protected:
  Matrix& _Mat;
 public:
 NonHermitianSchurDiagTwoOperator(Matrix& Mat): _Mat(Mat){};
  virtual void Mpc(const Field& in, Field& out) {
    Field tmp(in.Grid());
    _Mat.MooeeInv(in, out);
    _Mat.Meooe(out, tmp);
    _Mat.MooeeInv(tmp, out);
    _Mat.Meooe(out, tmp);
    axpy(out, -1.0, tmp, in);
  }
  virtual void MpcDag(const Field& in, Field& out) {
    Field tmp(in.Grid());
    _Mat.MeooeDag(in, out);
    _Mat.MooeeInvDag(out, tmp);
    _Mat.MeooeDag(tmp, out);
    _Mat.MooeeInvDag(out, tmp);
    axpy(out, -1.0, tmp, in);
  }
 };
 ///////////////////////////////////////////////////////////////////////////////////////////////////
 // Left  handed Moo^-1 ; (Moo - Moe Mee^-1 Meo) psi = eta  -->  ( 1 - Moo^-1 Moe Mee^-1 Meo ) psi = Moo^-1 eta
 // Right handed Moo^-1 ; (Moo - Moe Mee^-1 Meo) Moo^-1 Moo psi = eta  -->  ( 1 - Moe Mee^-1 Meo Moo^-1) phi=eta ; psi = Moo^-1 phi
 ///////////////////////////////////////////////////////////////////////////////////////////////////
 template<class Matrix,class Field> using SchurDiagOneRH = SchurDiagTwoOperator<Matrix,Field> ;
 template<class Matrix,class Field> using SchurDiagOneLH = SchurDiagOneOperator<Matrix,Field> ;
 ///////////////////////////////////////////////////////////////////////////////////////////////////
 //  Staggered use
 ///////////////////////////////////////////////////////////////////////////////////////////////////
 template<class Matrix,class Field>
 class SchurStaggeredOperator :  public SchurOperatorBase<Field> {
 protected:
  Matrix &_Mat;
  Field tmp;
  RealD mass;
 public:
  SchurStaggeredOperator (Matrix &Mat): _Mat(Mat), tmp(_Mat.RedBlackGrid()) 
  { 
    assert( _Mat.isTrivialEE() );
    mass = _Mat.Mass();
  }
  virtual void HermOpAndNorm(const Field &in, Field &out,RealD &n1,RealD &n2){
    Mpc(in,out);
    ComplexD dot= innerProduct(in,out);
    n1 = real(dot);
    n2 =0.0;
  }
  virtual void HermOp(const Field &in, Field &out){
    Mpc(in,out);
    //    _Mat.Meooe(in,out);
    //    _Mat.Meooe(out,tmp);
    //    axpby(out,-1.0,mass*mass,tmp,in);
  }
  virtual  void Mpc      (const Field &in, Field &out) 
  {
    Field tmp(in.Grid());
    Field tmp2(in.Grid());
    //    _Mat.Mooee(in,out);
    //    _Mat.Mooee(out,tmp);
    _Mat.Meooe(in,out);
    _Mat.Meooe(out,tmp);
    axpby(out,-1.0,mass*mass,tmp,in);
  }
  virtual  void MpcDag   (const Field &in, Field &out){
    Mpc(in,out);
  }
  virtual void MpcDagMpc(const Field &in, Field &out) {
    assert(0);// Never need with staggered
  }
 };
 template<class Matrix,class Field> using SchurStagOperator = SchurStaggeredOperator<Matrix,Field>;
 /////////////////////////////////////////////////////////////
 // Base classes for functions of operators
 /////////////////////////////////////////////////////////////
 template<class Field> class OperatorFunction {
 public:
  virtual void operator() (LinearOperatorBase<Field> &Linop, const Field &in, Field &out) = 0;
  virtual void operator() (LinearOperatorBase<Field> &Linop, const std::vector<Field> &in,std::vector<Field> &out) {
    assert(in.size()==out.size());
    for(int k=0;k<in.size();k++){
      (*this)(Linop,in[k],out[k]);
    }
  };
  virtual ~OperatorFunction(){};
 };
 template<class Field> class LinearFunction {
 public:
  virtual void operator() (const Field &in, Field &out) = 0;
  virtual void operator() (const std::vector<Field> &in, std::vector<Field> &out)
  {
    assert(in.size() == out.size());
    for (unsigned int i = 0; i < in.size(); ++i)
    {
      (*this)(in[i], out[i]);
    }
  }
  virtual ~LinearFunction(){};
 };
 template<class Field> class IdentityLinearFunction : public LinearFunction<Field> {
 public:
  void operator() (const Field &in, Field &out){
    out = in;
  };
 };
 /////////////////////////////////////////////////////////////
 // Base classes for Multishift solvers for operators
 /////////////////////////////////////////////////////////////
 template<class Field> class OperatorMultiFunction {
 public:
  virtual void operator() (LinearOperatorBase<Field> &Linop, const Field &in, std::vector<Field> &out) = 0;
 };
 // FIXME : To think about
 // Chroma functionality list defining LinearOperator
 /*
  virtual void operator() (T& chi, const T& psi, enum PlusMinus isign) const = 0;
  virtual void operator() (T& chi, const T& psi, enum PlusMinus isign, Real epsilon) const
  virtual const Subset& subset() const = 0;
  virtual unsigned long nFlops() const { return 0; }
  virtual void deriv(P& ds_u, const T& chi, const T& psi, enum PlusMinus isign) const
  class UnprecLinearOperator : public DiffLinearOperator<T,P,Q>
  const Subset& subset() const {return all;}
  };
 */
 ////////////////////////////////////////////////////////////////////////////////////////////
 // Hermitian operator Linear function and operator function
 ////////////////////////////////////////////////////////////////////////////////////////////
 template<class Field>
 class HermOpOperatorFunction : public OperatorFunction<Field> {
  void operator() (LinearOperatorBase<Field> &Linop, const Field &in, Field &out) {
    Linop.HermOp(in,out);
  };
 };
 template<typename Field>
 class PlainHermOp : public LinearFunction<Field> {
 public:
  using LinearFunction<Field>::operator();
  LinearOperatorBase<Field> &_Linop;
  PlainHermOp(LinearOperatorBase<Field>& linop) : _Linop(linop) 
  {}
  void operator()(const Field& in, Field& out) {
    _Linop.HermOp(in,out);
  }
 };
 template<typename Field>
 class FunctionHermOp : public LinearFunction<Field> {
 public:
  using LinearFunction<Field>::operator(); 
  OperatorFunction<Field>   & _poly;
  LinearOperatorBase<Field> &_Linop;
  FunctionHermOp(OperatorFunction<Field> & poly,LinearOperatorBase<Field>& linop) 
    : _poly(poly), _Linop(linop) {};
  void operator()(const Field& in, Field& out) {
    _poly(_Linop,in,out);
  }
 };
 template<class Field>
 class Polynomial : public OperatorFunction<Field> {
 private:
  std::vector<RealD> Coeffs;
 public:
  using OperatorFunction<Field>::operator();
  Polynomial(std::vector<RealD> &_Coeffs) : Coeffs(_Coeffs) { };
  // Implement the required interface
  void operator() (LinearOperatorBase<Field> &Linop, const Field &in, Field &out) {
    Field AtoN(in.Grid());
    Field Mtmp(in.Grid());
    AtoN = in;
    out = AtoN*Coeffs[0];
    for(int n=1;n<Coeffs.size();n++){
      Mtmp = AtoN;
      Linop.HermOp(Mtmp,AtoN);
      out=out+AtoN*Coeffs[n];
    }
  };
 };
 NAMESPACE_END(Grid);
--- a/Grid/algorithms/Preconditioner.h
+++ b/Grid/algorithms/Preconditioner.h
@@ -1,4 +1,4 @@
-    /*************************************************************************************
+/*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
@@ -23,24 +23,30 @@ Author: Azusa Yamaguchi <ayamaguc@staffmail.ed.ac.uk>
    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 */
+/*  END LEGAL */
 #ifndef GRID_PRECONDITIONER_H
 #define GRID_PRECONDITIONER_H
-namespace Grid {
+NAMESPACE_BEGIN(Grid);
-  template<class Field> class Preconditioner :  public LinearFunction<Field> { 
+template<class Field> using Preconditioner =  LinearFunction<Field> ;
    virtual void operator()(const Field &src, Field & psi)=0;
  };
-  template<class Field> class TrivialPrecon :  public Preconditioner<Field> { 
+/*
-  public:
+template<class Field> class Preconditioner :  public LinearFunction<Field> {
-    void operator()(const Field &src, Field & psi){
+  using LinearFunction<Field>::operator();
-      psi = src;
+  virtual void operator()(const Field &src, Field & psi)=0;
-    }
+};
-    TrivialPrecon(void){};
+*/
  };
-}
+template<class Field> class TrivialPrecon :  public Preconditioner<Field> { 
 public:
  using Preconditioner<Field>::operator();
  virtual void operator()(const Field &src, Field & psi){
    psi = src;
  }
  TrivialPrecon(void){};
 };
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/algorithms/SparseMatrix.h
+++ b/Grid/algorithms/SparseMatrix.h
@@ -0,0 +1,81 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./lib/algorithms/SparseMatrix.h
    Copyright (C) 2015
 Author: Peter Boyle <paboyle@ph.ed.ac.uk>
    This program is free software; you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation; either version 2 of the License, or
    (at your option) any later version.
    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.
    You should have received a copy of the GNU General Public License along
    with this program; if not, write to the Free Software Foundation, Inc.,
    51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
    See the full license in the file "LICENSE" in the top level distribution directory
 *************************************************************************************/
 /*  END LEGAL */
 #ifndef  GRID_ALGORITHM_SPARSE_MATRIX_H
 #define  GRID_ALGORITHM_SPARSE_MATRIX_H
 NAMESPACE_BEGIN(Grid);
 /////////////////////////////////////////////////////////////////////////////////////////////
 // Interface defining what I expect of a general sparse matrix, such as a Fermion action
 /////////////////////////////////////////////////////////////////////////////////////////////
 template<class Field> class SparseMatrixBase {
 public:
  virtual GridBase *Grid(void) =0;
  // Full checkerboar operations
  virtual void  M    (const Field &in, Field &out)=0;
  virtual void  Mdag (const Field &in, Field &out)=0;
  virtual void  MdagM(const Field &in, Field &out) {
    Field tmp (in.Grid());
    M(in,tmp);
    Mdag(tmp,out);
  }
  virtual  void Mdiag    (const Field &in, Field &out)=0;
  virtual  void Mdir     (const Field &in, Field &out,int dir, int disp)=0;
  virtual  void MdirAll  (const Field &in, std::vector<Field> &out)=0;
  virtual ~SparseMatrixBase() {};
 };
 /////////////////////////////////////////////////////////////////////////////////////////////
 // Interface augmented by a red black sparse matrix, such as a Fermion action
 /////////////////////////////////////////////////////////////////////////////////////////////
 template<class Field> class CheckerBoardedSparseMatrixBase : public SparseMatrixBase<Field> {
 public:
  virtual GridBase *RedBlackGrid(void)=0;
  //////////////////////////////////////////////////////////////////////
  // Query the even even properties to make algorithmic decisions
  //////////////////////////////////////////////////////////////////////
  virtual RealD  Mass(void)        { return 0.0; };
  virtual int    ConstEE(void)     { return 1; }; // Disable assumptions unless overridden
  virtual int    isTrivialEE(void) { return 0; }; // by a derived class that knows better
  // half checkerboard operaions
  virtual  void Meooe    (const Field &in, Field &out)=0;
  virtual  void Mooee    (const Field &in, Field &out)=0;
  virtual  void MooeeInv (const Field &in, Field &out)=0;
  virtual  void MeooeDag    (const Field &in, Field &out)=0;
  virtual  void MooeeDag    (const Field &in, Field &out)=0;
  virtual  void MooeeInvDag (const Field &in, Field &out)=0;
  virtual ~CheckerBoardedSparseMatrixBase() {};
 };
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/algorithms/approx/Chebyshev.h
+++ b/Grid/algorithms/approx/Chebyshev.h
@@ -0,0 +1,395 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./lib/algorithms/approx/Chebyshev.h
    Copyright (C) 2015
 Author: Peter Boyle <paboyle@ph.ed.ac.uk>
 Author: paboyle <paboyle@ph.ed.ac.uk>
 Author: Christoph Lehner <clehner@bnl.gov>
    This program is free software; you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation; either version 2 of the License, or
    (at your option) any later version.
    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.
    You should have received a copy of the GNU General Public License along
    with this program; if not, write to the Free Software Foundation, Inc.,
    51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
    See the full license in the file "LICENSE" in the top level distribution directory
 *************************************************************************************/
 /*  END LEGAL */
 #ifndef GRID_CHEBYSHEV_H
 #define GRID_CHEBYSHEV_H
 #include <Grid/algorithms/LinearOperator.h>
 NAMESPACE_BEGIN(Grid);
 struct ChebyParams : Serializable {
  GRID_SERIALIZABLE_CLASS_MEMBERS(ChebyParams,
 				  RealD, alpha,  
 				  RealD, beta,   
 				  int, Npoly);
 };
 ////////////////////////////////////////////////////////////////////////////////////////////
 // Generic Chebyshev approximations
 ////////////////////////////////////////////////////////////////////////////////////////////
 template<class Field>
 class Chebyshev : public OperatorFunction<Field> {
 private:
  using OperatorFunction<Field>::operator();
  std::vector<RealD> Coeffs;
  int order;
  RealD hi;
  RealD lo;
 public:
  void csv(std::ostream &out){
    RealD diff = hi-lo;
    RealD delta = diff*1.0e-9;
    for (RealD x=lo; x<hi; x+=delta) {
      delta*=1.1;
      RealD f = approx(x);
      out<< x<<" "<<f<<std::endl;
    }
    return;
  }
  // Convenience for plotting the approximation
  void   PlotApprox(std::ostream &out) {
    out<<"Polynomial approx ["<<lo<<","<<hi<<"]"<<std::endl;
    for(RealD x=lo;x<hi;x+=(hi-lo)/50.0){
      out <<x<<"\t"<<approx(x)<<std::endl;
    }
  };
  Chebyshev(){};
  Chebyshev(ChebyParams p){ Init(p.alpha,p.beta,p.Npoly);};
  Chebyshev(RealD _lo,RealD _hi,int _order, RealD (* func)(RealD) ) {Init(_lo,_hi,_order,func);};
  Chebyshev(RealD _lo,RealD _hi,int _order) {Init(_lo,_hi,_order);};
  ////////////////////////////////////////////////////////////////////////////////////////////////////
  // c.f. numerical recipes "chebft"/"chebev". This is sec 5.8 "Chebyshev approximation".
  ////////////////////////////////////////////////////////////////////////////////////////////////////
  // CJ: the one we need for Lanczos
  void Init(RealD _lo,RealD _hi,int _order)
  {
    lo=_lo;
    hi=_hi;
    order=_order;
    if(order < 2) exit(-1);
    Coeffs.resize(order);
    Coeffs.assign(0.,order);
    Coeffs[order-1] = 1.;
  };
  // PB - more efficient low pass drops high modes above the low as 1/x uses all Chebyshev's.
  // Similar kick effect below the threshold as Lanczos filter approach
  void InitLowPass(RealD _lo,RealD _hi,int _order)
  {
    lo=_lo;
    hi=_hi;
    order=_order;
    if(order < 2) exit(-1);
    Coeffs.resize(order);
    for(int j=0;j<order;j++){
      RealD k=(order-1.0);
      RealD s=std::cos( j*M_PI*(k+0.5)/order );
      Coeffs[j] = s * 2.0/order;
    }
  };
  void Init(RealD _lo,RealD _hi,int _order, RealD (* func)(RealD))
  {
    lo=_lo;
    hi=_hi;
    order=_order;
    if(order < 2) exit(-1);
    Coeffs.resize(order);
    for(int j=0;j<order;j++){
      RealD s=0;
      for(int k=0;k<order;k++){
 	RealD y=std::cos(M_PI*(k+0.5)/order);
 	RealD x=0.5*(y*(hi-lo)+(hi+lo));
 	RealD f=func(x);
 	s=s+f*std::cos( j*M_PI*(k+0.5)/order );
      }
      Coeffs[j] = s * 2.0/order;
    }
  };
  void JacksonSmooth(void){
    RealD M=order;
    RealD alpha = M_PI/(M+2);
    RealD lmax = std::cos(alpha);
    RealD sumUsq =0;
    std::vector<RealD> U(M);
    std::vector<RealD> a(M);
    std::vector<RealD> g(M);
    for(int n=0;n<=M;n++){
      U[n] = std::sin((n+1)*std::acos(lmax))/std::sin(std::acos(lmax));
      sumUsq += U[n]*U[n];
    }      
    sumUsq = std::sqrt(sumUsq);
    for(int i=1;i<=M;i++){
      a[i] = U[i]/sumUsq;
    }
    g[0] = 1.0;
    for(int m=1;m<=M;m++){
      g[m] = 0;
      for(int i=0;i<=M-m;i++){
 	g[m]+= a[i]*a[m+i];
      }
    }
    for(int m=1;m<=M;m++){
      Coeffs[m]*=g[m];
    }
  }
  RealD approx(RealD x) // Convenience for plotting the approximation
  {
    RealD Tn;
    RealD Tnm;
    RealD Tnp;
    RealD y=( x-0.5*(hi+lo))/(0.5*(hi-lo));
    RealD T0=1;
    RealD T1=y;
    RealD sum;
    sum = 0.5*Coeffs[0]*T0;
    sum+= Coeffs[1]*T1;
    Tn =T1;
    Tnm=T0;
    for(int i=2;i<order;i++){
      Tnp=2*y*Tn-Tnm;
      Tnm=Tn;
      Tn =Tnp;
      sum+= Tn*Coeffs[i];
    }
    return sum;
  };
  RealD approxD(RealD x)
  {
    RealD Un;
    RealD Unm;
    RealD Unp;
    RealD y=( x-0.5*(hi+lo))/(0.5*(hi-lo));
    RealD U0=1;
    RealD U1=2*y;
    RealD sum;
    sum = Coeffs[1]*U0;
    sum+= Coeffs[2]*U1*2.0;
    Un =U1;
    Unm=U0;
    for(int i=2;i<order-1;i++){
      Unp=2*y*Un-Unm;
      Unm=Un;
      Un =Unp;
      sum+= Un*Coeffs[i+1]*(i+1.0);
    }
    return sum/(0.5*(hi-lo));
  };
  RealD approxInv(RealD z, RealD x0, int maxiter, RealD resid) {
    RealD x = x0;
    RealD eps;
    int i;
    for (i=0;i<maxiter;i++) {
      eps = approx(x) - z;
      if (fabs(eps / z) < resid)
 	return x;
      x = x - eps / approxD(x);
    }
    return std::numeric_limits<double>::quiet_NaN();
  }
  // Implement the required interface
  void operator() (LinearOperatorBase<Field> &Linop, const Field &in, Field &out) {
    GridBase *grid=in.Grid();
    int vol=grid->gSites();
    typedef typename Field::vector_type vector_type;
    Field T0(grid); T0 = in;  
    Field T1(grid); 
    Field T2(grid);
    Field y(grid);
    Field *Tnm = &T0;
    Field *Tn  = &T1;
    Field *Tnp = &T2;
    // Tn=T1 = (xscale M + mscale)in
    RealD xscale = 2.0/(hi-lo);
    RealD mscale = -(hi+lo)/(hi-lo);
    Linop.HermOp(T0,y);
    axpby(T1,xscale,mscale,y,in);
    // sum = .5 c[0] T0 + c[1] T1
    //    out = ()*T0 + Coeffs[1]*T1;
    axpby(out,0.5*Coeffs[0],Coeffs[1],T0,T1);
    for(int n=2;n<order;n++){
      Linop.HermOp(*Tn,y);
      axpby(y,xscale,mscale,y,(*Tn));
      axpby(*Tnp,2.0,-1.0,y,(*Tnm));
      if ( Coeffs[n] != 0.0) {
 	axpy(out,Coeffs[n],*Tnp,out);
      }
      // Cycle pointers to avoid copies
      Field *swizzle = Tnm;
      Tnm    =Tn;
      Tn     =Tnp;
      Tnp    =swizzle;
    }
  }
 };
 template<class Field>
 class ChebyshevLanczos : public Chebyshev<Field> {
 private:
  std::vector<RealD> Coeffs;
  int order;
  RealD alpha;
  RealD beta;
  RealD mu;
 public:
  ChebyshevLanczos(RealD _alpha,RealD _beta,RealD _mu,int _order) :
    alpha(_alpha),
    beta(_beta),
    mu(_mu)
  {
    order=_order;
    Coeffs.resize(order);
    for(int i=0;i<_order;i++){
      Coeffs[i] = 0.0;
    }
    Coeffs[order-1]=1.0;
  };
  void csv(std::ostream &out){
    for (RealD x=-1.2*alpha; x<1.2*alpha; x+=(2.0*alpha)/10000) {
      RealD f = approx(x);
      out<< x<<" "<<f<<std::endl;
    }
    return;
  }
  RealD approx(RealD xx) // Convenience for plotting the approximation
  {
    RealD Tn;
    RealD Tnm;
    RealD Tnp;
    Real aa = alpha * alpha;
    Real bb = beta  *  beta;
    RealD x = ( 2.0 * (xx-mu)*(xx-mu) - (aa+bb) ) / (aa-bb);
    RealD y= x;
    RealD T0=1;
    RealD T1=y;
    RealD sum;
    sum = 0.5*Coeffs[0]*T0;
    sum+= Coeffs[1]*T1;
    Tn =T1;
    Tnm=T0;
    for(int i=2;i<order;i++){
      Tnp=2*y*Tn-Tnm;
      Tnm=Tn;
      Tn =Tnp;
      sum+= Tn*Coeffs[i];
    }
    return sum;
  };
  // shift_Multiply in Rudy's code
  void AminusMuSq(LinearOperatorBase<Field> &Linop, const Field &in, Field &out) 
  {
    GridBase *grid=in.Grid();
    Field tmp(grid);
    RealD aa= alpha*alpha;
    RealD bb= beta * beta;
    Linop.HermOp(in,out);
    out = out - mu*in;
    Linop.HermOp(out,tmp);
    tmp = tmp - mu * out;
    out = (2.0/ (aa-bb) ) * tmp -  ((aa+bb)/(aa-bb))*in;
  };
  // Implement the required interface
  void operator() (LinearOperatorBase<Field> &Linop, const Field &in, Field &out) {
    GridBase *grid=in.Grid();
    int vol=grid->gSites();
    Field T0(grid); T0 = in;  
    Field T1(grid); 
    Field T2(grid);
    Field  y(grid);
    Field *Tnm = &T0;
    Field *Tn  = &T1;
    Field *Tnp = &T2;
    // Tn=T1 = (xscale M )*in
    AminusMuSq(Linop,T0,T1);
    // sum = .5 c[0] T0 + c[1] T1
    out = (0.5*Coeffs[0])*T0 + Coeffs[1]*T1;
    for(int n=2;n<order;n++){
      AminusMuSq(Linop,*Tn,y);
      *Tnp=2.0*y-(*Tnm);
      out=out+Coeffs[n]* (*Tnp);
      // Cycle pointers to avoid copies
      Field *swizzle = Tnm;
      Tnm    =Tn;
      Tn     =Tnp;
      Tnp    =swizzle;
    }
  }
 };
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/algorithms/approx/Forecast.h
+++ b/Grid/algorithms/approx/Forecast.h
@@ -0,0 +1,152 @@
 /*************************************************************************************
 Grid physics library, www.github.com/paboyle/Grid
 Source file: ./lib/algorithms/approx/Forecast.h
 Copyright (C) 2015
 Author: Peter Boyle <paboyle@ph.ed.ac.uk>
 Author: paboyle <paboyle@ph.ed.ac.uk>
 Author: David Murphy <dmurphy@phys.columbia.edu>
 This program is free software; you can redistribute it and/or modify
 it under the terms of the GNU General Public License as published by
 the Free Software Foundation; either version 2 of the License, or
 (at your option) any later version.
 This program is distributed in the hope that it will be useful,
 but WITHOUT ANY WARRANTY; without even the implied warranty of
 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 GNU General Public License for more details.
 You should have received a copy of the GNU General Public License along
 with this program; if not, write to the Free Software Foundation, Inc.,
 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
 See the full license in the file "LICENSE" in the top level distribution directory
 *************************************************************************************/
 			   /*  END LEGAL */
 #ifndef INCLUDED_FORECAST_H
 #define INCLUDED_FORECAST_H
 NAMESPACE_BEGIN(Grid);
 // Abstract base class.
 // Takes a matrix (Mat), a source (phi), and a vector of Fields (chi)
 // and returns a forecasted solution to the system D*psi = phi (psi).
 template<class Matrix, class Field>
 class Forecast
 {
 public:
  virtual Field operator()(Matrix &Mat, const Field& phi, const std::vector<Field>& chi) = 0;
 };
 // Implementation of Brower et al.'s chronological inverter (arXiv:hep-lat/9509012),
 // used to forecast solutions across poles of the EOFA heatbath.
 //
 // Modified from CPS (cps_pp/src/util/dirac_op/d_op_base/comsrc/minresext.C)
 template<class Matrix, class Field>
 class ChronoForecast : public Forecast<Matrix,Field>
 {
 public:
  Field operator()(Matrix &Mat, const Field& phi, const std::vector<Field>& prev_solns)
  {
    int degree = prev_solns.size();
    Field chi(phi); // forecasted solution
    // Trivial cases
    if(degree == 0){ chi = Zero(); return chi; }
    else if(degree == 1){ return prev_solns[0]; }
    //    RealD dot;
    ComplexD xp;
    Field r(phi); // residual
    Field Mv(phi);
    std::vector<Field> v(prev_solns); // orthonormalized previous solutions
    std::vector<Field> MdagMv(degree,phi);
    // Array to hold the matrix elements
    std::vector<std::vector<ComplexD>> G(degree, std::vector<ComplexD>(degree));
    // Solution and source vectors
    std::vector<ComplexD> a(degree);
    std::vector<ComplexD> b(degree);
    // Orthonormalize the vector basis
    for(int i=0; i<degree; i++){
      v[i] *= 1.0/std::sqrt(norm2(v[i]));
      for(int j=i+1; j<degree; j++){ v[j] -= innerProduct(v[i],v[j]) * v[i]; }
    }
    // Perform sparse matrix multiplication and construct rhs
    for(int i=0; i<degree; i++){
      b[i] = innerProduct(v[i],phi);
      Mat.M(v[i],Mv);
      Mat.Mdag(Mv,MdagMv[i]);
      G[i][i] = innerProduct(v[i],MdagMv[i]);
    }
    // Construct the matrix
    for(int j=0; j<degree; j++){
      for(int k=j+1; k<degree; k++){
 	G[j][k] = innerProduct(v[j],MdagMv[k]);
 	G[k][j] = conjugate(G[j][k]);
      }}
    // Gauss-Jordan elimination with partial pivoting
    for(int i=0; i<degree; i++){
      // Perform partial pivoting
      int k = i;
      for(int j=i+1; j<degree; j++){ if(abs(G[j][j]) > abs(G[k][k])){ k = j; } }
      if(k != i){
 	xp = b[k];
 	b[k] = b[i];
 	b[i] = xp;
 	for(int j=0; j<degree; j++){
 	  xp = G[k][j];
 	  G[k][j] = G[i][j];
 	  G[i][j] = xp;
 	}
      }
      // Convert matrix to upper triangular form
      for(int j=i+1; j<degree; j++){
 	xp = G[j][i]/G[i][i];
 	b[j] -= xp * b[i];
 	for(int k=0; k<degree; k++){ G[j][k] -= xp*G[i][k]; }
      }
    }
    // Use Gaussian elimination to solve equations and calculate initial guess
    chi = Zero();
    r = phi;
    for(int i=degree-1; i>=0; i--){
      a[i] = 0.0;
      for(int j=i+1; j<degree; j++){ a[i] += G[i][j] * a[j]; }
      a[i] = (b[i]-a[i])/G[i][i];
      chi += a[i]*v[i];
      r -= a[i]*MdagMv[i];
    }
    RealD true_r(0.0);
    ComplexD tmp;
    for(int i=0; i<degree; i++){
      tmp = -b[i];
      for(int j=0; j<degree; j++){ tmp += G[i][j]*a[j]; }
      tmp = conjugate(tmp)*tmp;
      true_r += std::sqrt(tmp.real());
    }
    RealD error = std::sqrt(norm2(r)/norm2(phi));
    std::cout << GridLogMessage << "ChronoForecast: |res|/|src| = " << error << std::endl;
    return chi;
  };
 };
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/algorithms/approx/JacobiPolynomial.h
+++ b/Grid/algorithms/approx/JacobiPolynomial.h
@@ -0,0 +1,129 @@
 #ifndef GRID_JACOBIPOLYNOMIAL_H
 #define GRID_JACOBIPOLYNOMIAL_H
 #include <Grid/algorithms/LinearOperator.h>
 NAMESPACE_BEGIN(Grid);
 template<class Field>
 class JacobiPolynomial : public OperatorFunction<Field> {
 private:
  using OperatorFunction<Field>::operator();
  int order;
  RealD hi;
  RealD lo;
  RealD alpha;
  RealD beta;
 public:
  void csv(std::ostream &out){
    csv(out,lo,hi);
  }
  void csv(std::ostream &out,RealD llo,RealD hhi){
    RealD diff = hhi-llo;
    RealD delta = diff*1.0e-5;
    for (RealD x=llo-delta; x<=hhi; x+=delta) {
      RealD f = approx(x);
      out<< x<<" "<<f <<std::endl;
    }
    return;
  }
  JacobiPolynomial(){};
  JacobiPolynomial(RealD _lo,RealD _hi,int _order,RealD _alpha, RealD _beta)
  {
      lo=_lo;
      hi=_hi;
      alpha=_alpha;
      beta=_beta;
      order=_order;
  };
  RealD approx(RealD x) // Convenience for plotting the approximation                                                       
  {
    RealD Tn;
    RealD Tnm;
    RealD Tnp;
    RealD y=( x-0.5*(hi+lo))/(0.5*(hi-lo));
    RealD T0=1.0;
    RealD T1=(alpha-beta)*0.5+(alpha+beta+2.0)*0.5*y;
    Tn =T1;
    Tnm=T0;
    for(int n=2;n<=order;n++){
      RealD cnp = 2.0*n*(n+alpha+beta)*(2.0*n-2.0+alpha+beta);
      RealD cny = (2.0*n-2.0+alpha+beta)*(2.0*n-1.0+alpha+beta)*(2.0*n+alpha+beta);
      RealD cn1 = (2.0*n+alpha+beta-1.0)*(alpha*alpha-beta*beta);
      RealD cnm = - 2.0*(n+alpha-1.0)*(n+beta-1.0)*(2.0*n+alpha+beta);
      Tnp= ( cny * y *Tn + cn1 * Tn + cnm * Tnm )/ cnp;
      Tnm=Tn;
      Tn =Tnp;
    }
    return Tnp;
  };
  // Implement the required interface                                                                                       
  void operator() (LinearOperatorBase<Field> &Linop, const Field &in, Field &out) {
    GridBase *grid=in.Grid();
    int vol=grid->gSites();
    Field T0(grid);
    Field T1(grid);
    Field T2(grid);
    Field y(grid);
    Field *Tnm = &T0;
    Field *Tn  = &T1;
    Field *Tnp = &T2;
    //    RealD T0=1.0;                                                                                                     
    T0=in;
    //    RealD y=( x-0.5*(hi+lo))/(0.5*(hi-lo));                                                                           
    //           = x * 2/(hi-lo) - (hi+lo)/(hi-lo)                                                                          
    Linop.HermOp(T0,y);
    RealD xscale = 2.0/(hi-lo);
    RealD mscale = -(hi+lo)/(hi-lo);
    Linop.HermOp(T0,y);
    y=y*xscale+in*mscale;
    // RealD T1=(alpha-beta)*0.5+(alpha+beta+2.0)*0.5*y;
    RealD halfAmB  = (alpha-beta)*0.5;
    RealD halfApBp2= (alpha+beta+2.0)*0.5;
    T1 = halfAmB * in + halfApBp2*y;
    for(int n=2;n<=order;n++){
      Linop.HermOp(*Tn,y);
      y=xscale*y+mscale*(*Tn);
      RealD cnp = 2.0*n*(n+alpha+beta)*(2.0*n-2.0+alpha+beta);
      RealD cny = (2.0*n-2.0+alpha+beta)*(2.0*n-1.0+alpha+beta)*(2.0*n+alpha+beta);
      RealD cn1 = (2.0*n+alpha+beta-1.0)*(alpha*alpha-beta*beta);
      RealD cnm = - 2.0*(n+alpha-1.0)*(n+beta-1.0)*(2.0*n+alpha+beta);
      //      Tnp= ( cny * y *Tn + cn1 * Tn + cnm * Tnm )/ cnp;                                                             
      cny=cny/cnp;
      cn1=cn1/cnp;
      cn1=cn1/cnp;
      cnm=cnm/cnp;
      *Tnp=cny*y + cn1 *(*Tn) + cnm * (*Tnm);
      // Cycle pointers to avoid copies                                                                                     
      Field *swizzle = Tnm;
      Tnm    =Tn;
      Tn     =Tnp;
      Tnp    =swizzle;
    }
    out=*Tnp;
  }
 };
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/algorithms/approx/LICENSE
+++ b/Grid/algorithms/approx/LICENSE
--- a/Grid/algorithms/approx/MultiShiftFunction.cc
+++ b/Grid/algorithms/approx/MultiShiftFunction.cc
@@ -27,7 +27,8 @@ Author: Azusa Yamaguchi <ayamaguc@staffmail.ed.ac.uk>
    /*  END LEGAL */
 #include <Grid/GridCore.h>
-namespace Grid {
+NAMESPACE_BEGIN(Grid);
 double MultiShiftFunction::approx(double x)
 {
  double a = norm;
@@ -53,4 +54,4 @@ void MultiShiftFunction::csv(std::ostream &out)
  }
  return;
 }
-}
+NAMESPACE_END(Grid);
--- a/Grid/algorithms/approx/MultiShiftFunction.h
+++ b/Grid/algorithms/approx/MultiShiftFunction.h
@@ -29,7 +29,7 @@ Author: Peter Boyle <paboyle@ph.ed.ac.uk>
 #ifndef MULTI_SHIFT_FUNCTION
 #define MULTI_SHIFT_FUNCTION
-namespace Grid {
+NAMESPACE_BEGIN(Grid);
 class MultiShiftFunction {
 public:
@@ -63,5 +63,5 @@ public:
  }
 };
-}
+NAMESPACE_END(Grid);
 #endif
--- a/Grid/algorithms/approx/README
+++ b/Grid/algorithms/approx/README
--- a/Grid/algorithms/approx/Remez.cc
+++ b/Grid/algorithms/approx/Remez.cc
@@ -298,7 +298,7 @@ void AlgRemez::stpini(bigfloat *step) {
 // Search for error maxima and minima
 void AlgRemez::search(bigfloat *step) {
  bigfloat a, q, xm, ym, xn, yn, xx0, xx1;
-  int i, j, meq, emsign, ensign, steps;
+  int i, meq, emsign, ensign, steps;
  meq = neq + 1;
  bigfloat *yy = new bigfloat[meq];
@@ -306,7 +306,6 @@ void AlgRemez::search(bigfloat *step) {
  bigfloat eclose = 1.0e30;
  bigfloat farther = 0l;
  j = 1;
  xx0 = apstrt;
  for (i = 0; i < meq; i++) {
--- a/Grid/algorithms/approx/Remez.h
+++ b/Grid/algorithms/approx/Remez.h
--- a/Grid/algorithms/approx/RemezGeneral.cc
+++ b/Grid/algorithms/approx/RemezGeneral.cc
@@ -0,0 +1,473 @@
 #include<math.h>
 #include<stdio.h>
 #include<stdlib.h>
 #include<string>
 #include<iostream>
 #include<iomanip>
 #include<cassert>
 #include<Grid/algorithms/approx/RemezGeneral.h>
 // Constructor
 AlgRemezGeneral::AlgRemezGeneral(double lower, double upper, long precision,
 				 bigfloat (*f)(bigfloat x, void *data), void *data): f(f), 
 										     data(data), 
 										     prec(precision),
 										     apstrt(lower), apend(upper), apwidt(upper - lower),
 										     n(0), d(0), pow_n(0), pow_d(0)
 {
  bigfloat::setDefaultPrecision(prec);
  std::cout<<"Approximation bounds are ["<<apstrt<<","<<apend<<"]\n";
  std::cout<<"Precision of arithmetic is "<<precision<<std::endl;
 }
 //Determine the properties of the numerator and denominator polynomials
 void AlgRemezGeneral::setupPolyProperties(int num_degree, int den_degree, PolyType num_type_in, PolyType den_type_in){
  pow_n = num_degree;
  pow_d = den_degree;
  if(pow_n % 2 == 0 && num_type_in == PolyType::Odd) assert(0);
  if(pow_n % 2 == 1 && num_type_in == PolyType::Even) assert(0);
  if(pow_d % 2 == 0 && den_type_in == PolyType::Odd) assert(0);
  if(pow_d % 2 == 1 && den_type_in == PolyType::Even) assert(0);
  num_type = num_type_in;
  den_type = den_type_in;
  num_pows.resize(pow_n+1);
  den_pows.resize(pow_d+1);
  int n_in = 0;
  bool odd = num_type == PolyType::Full || num_type == PolyType::Odd;
  bool even = num_type == PolyType::Full || num_type == PolyType::Even;
  for(int i=0;i<=pow_n;i++){
    num_pows[i] = -1;
    if(i % 2 == 0 && even) num_pows[i] = n_in++;
    if(i % 2 == 1 && odd) num_pows[i] = n_in++;
  }
  std::cout << n_in << " terms in numerator" << std::endl;
  --n_in; //power is 1 less than the number of terms, eg  pow=1   a x^1  + b x^0
  int d_in = 0;
  odd = den_type == PolyType::Full || den_type == PolyType::Odd;
  even = den_type == PolyType::Full || den_type == PolyType::Even;
  for(int i=0;i<=pow_d;i++){
    den_pows[i] = -1;
    if(i % 2 == 0 && even) den_pows[i] = d_in++;
    if(i % 2 == 1 && odd) den_pows[i] = d_in++;
  }
  std::cout << d_in << " terms in denominator" << std::endl;
  --d_in;
  n = n_in;
  d = d_in;
 }
 //Setup algorithm
 void AlgRemezGeneral::reinitializeAlgorithm(){
  spread = 1.0e37;
  iter = 0;
  neq = n + d + 1; //not +2 because highest-power term in denominator is fixed to 1
  param.resize(neq);
  yy.resize(neq+1);
  //Initialize linear equation temporaries
  A.resize(neq*neq);
  B.resize(neq);
  IPS.resize(neq);
  //Initialize maximum and minimum errors
  xx.resize(neq+2);
  mm.resize(neq+1);
  initialGuess();
  //Initialize search steps
  step.resize(neq+1);
  stpini();
 }
 double AlgRemezGeneral::generateApprox(const int num_degree, const int den_degree, 
 				       const PolyType num_type_in, const PolyType den_type_in, 
 				       const double _tolerance, const int report_freq){
  //Setup the properties of the polynomial
  setupPolyProperties(num_degree, den_degree, num_type_in, den_type_in);
  //Setup the algorithm
  reinitializeAlgorithm();
  bigfloat tolerance = _tolerance;
  //Iterate until convergance
  while (spread > tolerance) { 
    if (iter++ % report_freq==0)
      std::cout<<"Iteration " <<iter-1<<" spread "<<(double)spread<<" delta "<<(double)delta << std::endl; 
    equations();
    if (delta < tolerance) {
      std::cout<<"Iteration " << iter-1 << " delta too small (" << delta << "<" << tolerance << "), try increasing precision\n";
      assert(0);
    };    
    assert( delta>= tolerance );
    search();
  }
  int sign;
  double error = (double)getErr(mm[0],&sign);
  std::cout<<"Converged at "<<iter<<" iterations; error = "<<error<<std::endl;
  // Return the maximum error in the approximation
  return error;
 }
 // Initial values of maximal and minimal errors
 void AlgRemezGeneral::initialGuess(){
  // Supply initial guesses for solution points
  long ncheb = neq;			// Degree of Chebyshev error estimate
  // Find ncheb+1 extrema of Chebyshev polynomial
  bigfloat a = ncheb;
  bigfloat r;
  mm[0] = apstrt;
  for (long i = 1; i < ncheb; i++) {
    r = 0.5 * (1 - cos((M_PI * i)/(double) a));
    //r *= sqrt_bf(r);
    r = (exp((double)r)-1.0)/(exp(1.0)-1.0);
    mm[i] = apstrt + r * apwidt;
  }
  mm[ncheb] = apend;
  a = 2.0 * ncheb;
  for (long i = 0; i <= ncheb; i++) {
    r = 0.5 * (1 - cos(M_PI * (2*i+1)/(double) a));
    //r *= sqrt_bf(r); // Squeeze to low end of interval
    r = (exp((double)r)-1.0)/(exp(1.0)-1.0);
    xx[i] = apstrt + r * apwidt;
  }
 }
 // Initialise step sizes
 void AlgRemezGeneral::stpini(){
  xx[neq+1] = apend;
  delta = 0.25;
  step[0] = xx[0] - apstrt;
  for (int i = 1; i < neq; i++) step[i] = xx[i] - xx[i-1];
  step[neq] = step[neq-1];
 }
 // Search for error maxima and minima
 void AlgRemezGeneral::search(){
  bigfloat a, q, xm, ym, xn, yn, xx1;
  int emsign, ensign, steps;
  int meq = neq + 1;
  bigfloat eclose = 1.0e30;
  bigfloat farther = 0l;
  bigfloat xx0 = apstrt;
  for (int i = 0; i < meq; i++) {
    steps = 0;
    xx1 = xx[i]; // Next zero
    if (i == meq-1) xx1 = apend;
    xm = mm[i];
    ym = getErr(xm,&emsign);
    q = step[i];
    xn = xm + q;
    if (xn < xx0 || xn >= xx1) {	// Cannot skip over adjacent boundaries
      q = -q;
      xn = xm;
      yn = ym;
      ensign = emsign;
    } else {
      yn = getErr(xn,&ensign);
      if (yn < ym) {
 	q = -q;
 	xn = xm;
 	yn = ym;
 	ensign = emsign;
      }
    }
    while(yn >= ym) {		// March until error becomes smaller.
      if (++steps > 10)
      	break;
      ym = yn;
      xm = xn;
      emsign = ensign;
      a = xm + q;
      if (a == xm || a <= xx0 || a >= xx1)
 	break;// Must not skip over the zeros either side.      
      xn = a;
      yn = getErr(xn,&ensign);
    }
    mm[i] = xm;			// Position of maximum
    yy[i] = ym;			// Value of maximum
    if (eclose > ym) eclose = ym;
    if (farther < ym) farther = ym;
    xx0 = xx1; // Walk to next zero.
  } // end of search loop
  q = (farther - eclose);	// Decrease step size if error spread increased
  if (eclose != 0.0) q /= eclose; // Relative error spread
  if (q >= spread)
    delta *= 0.5; // Spread is increasing; decrease step size
  spread = q;
  for (int i = 0; i < neq; i++) {
    q = yy[i+1];
    if (q != 0.0) q = yy[i] / q  - (bigfloat)1l;
    else q = 0.0625;
    if (q > (bigfloat)0.25) q = 0.25;
    q *= mm[i+1] - mm[i];
    step[i] = q * delta;
  }
  step[neq] = step[neq-1];
  for (int i = 0; i < neq; i++) {	// Insert new locations for the zeros.
    xm = xx[i] - step[i];
    if (xm <= apstrt)
      continue;
    if (xm >= apend)
      continue;
    if (xm <= mm[i])
      xm = (bigfloat)0.5 * (mm[i] + xx[i]);    
    if (xm >= mm[i+1])
      xm = (bigfloat)0.5 * (mm[i+1] + xx[i]);
    xx[i] = xm;
  }
 }
 // Solve the equations
 void AlgRemezGeneral::equations(){
  bigfloat x, y, z;
  bigfloat *aa;
  for (int i = 0; i < neq; i++) {	// set up the equations for solution by simq()
    int ip = neq * i;		// offset to 1st element of this row of matrix
    x = xx[i];			// the guess for this row
    y = func(x);		// right-hand-side vector
    z = (bigfloat)1l;
    aa = A.data()+ip;
    int t = 0;
    for (int j = 0; j <= pow_n; j++) {
      if(num_pows[j] != -1){ *aa++ = z; t++; }
      z *= x;
    }
    assert(t == n+1);
    z = (bigfloat)1l;
    t = 0;
    for (int j = 0; j < pow_d; j++) {
      if(den_pows[j] != -1){ *aa++ = -y * z; t++; }
      z *= x;
    }
    assert(t == d);
    B[i] = y * z;		// Right hand side vector
  }
  // Solve the simultaneous linear equations.
  if (simq()){
    std::cout<<"simq failed\n";
    exit(0);
  }
 }
 // Evaluate the rational form P(x)/Q(x) using coefficients
 // from the solution vector param
 bigfloat AlgRemezGeneral::approx(const bigfloat x) const{
  // Work backwards toward the constant term.
  int c = n;
  bigfloat yn = param[c--];		// Highest order numerator coefficient
  for (int i = pow_n-1; i >= 0; i--) yn = x * yn  +  (num_pows[i] != -1 ? param[c--] : bigfloat(0l));  
  c = n+d;
  bigfloat yd = 1l; //Highest degree coefficient is 1.0
  for (int i = pow_d-1; i >= 0; i--) yd = x * yd  +  (den_pows[i] != -1 ? param[c--] : bigfloat(0l)); 
  return(yn/yd);
 }
 // Compute size and sign of the approximation error at x
 bigfloat AlgRemezGeneral::getErr(bigfloat x, int *sign) const{
  bigfloat f = func(x);
  bigfloat e = approx(x) - f;
  if (f != 0) e /= f;
  if (e < (bigfloat)0.0) {
    *sign = -1;
    e = -e;
  }
  else *sign = 1;
  return(e);
 }
 // Solve the system AX=B
 int AlgRemezGeneral::simq(){
  int ip, ipj, ipk, ipn;
  int idxpiv;
  int kp, kp1, kpk, kpn;
  int nip, nkp;
  bigfloat em, q, rownrm, big, size, pivot, sum;
  bigfloat *aa;
  bigfloat *X = param.data();
  int n = neq;
  int nm1 = n - 1;
  // Initialize IPS and X
  int ij = 0;
  for (int i = 0; i < n; i++) {
    IPS[i] = i;
    rownrm = 0.0;
    for(int j = 0; j < n; j++) {
      q = abs_bf(A[ij]);
      if(rownrm < q) rownrm = q;
      ++ij;
    }
    if (rownrm == (bigfloat)0l) {
      std::cout<<"simq rownrm=0\n";
      return(1);
    }
    X[i] = (bigfloat)1.0 / rownrm;
  }
  for (int k = 0; k < nm1; k++) {
    big = 0.0;
    idxpiv = 0;
    for (int i = k; i < n; i++) {
      ip = IPS[i];
      ipk = n*ip + k;
      size = abs_bf(A[ipk]) * X[ip];
      if (size > big) {
 	big = size;
 	idxpiv = i;
      }
    }
    if (big == (bigfloat)0l) {
      std::cout<<"simq big=0\n";
      return(2);
    }
    if (idxpiv != k) {
      int j = IPS[k];
      IPS[k] = IPS[idxpiv];
      IPS[idxpiv] = j;
    }
    kp = IPS[k];
    kpk = n*kp + k;
    pivot = A[kpk];
    kp1 = k+1;
    for (int i = kp1; i < n; i++) {
      ip = IPS[i];
      ipk = n*ip + k;
      em = -A[ipk] / pivot;
      A[ipk] = -em;
      nip = n*ip;
      nkp = n*kp;
      aa = A.data()+nkp+kp1;
      for (int j = kp1; j < n; j++) {
 	ipj = nip + j;
 	A[ipj] = A[ipj] + em * *aa++;
      }
    }
  }
  kpn = n * IPS[n-1] + n - 1;	// last element of IPS[n] th row
  if (A[kpn] == (bigfloat)0l) {
    std::cout<<"simq A[kpn]=0\n";
    return(3);
  }
  ip = IPS[0];
  X[0] = B[ip];
  for (int i = 1; i < n; i++) {
    ip = IPS[i];
    ipj = n * ip;
    sum = 0.0;
    for (int j = 0; j < i; j++) {
      sum += A[ipj] * X[j];
      ++ipj;
    }
    X[i] = B[ip] - sum;
  }
  ipn = n * IPS[n-1] + n - 1;
  X[n-1] = X[n-1] / A[ipn];
  for (int iback = 1; iback < n; iback++) {
    //i goes (n-1),...,1
    int i = nm1 - iback;
    ip = IPS[i];
    nip = n*ip;
    sum = 0.0;
    aa = A.data()+nip+i+1;
    for (int j= i + 1; j < n; j++) 
      sum += *aa++ * X[j];
    X[i] = (X[i] - sum) / A[nip+i];
  }
  return(0);
 }
 void AlgRemezGeneral::csv(std::ostream & os) const{
  os << "Numerator" << std::endl;
  for(int i=0;i<=pow_n;i++){
    os << getCoeffNum(i) << "*x^" << i;
    if(i!=pow_n) os << " + ";
  }
  os << std::endl;
  os << "Denominator" << std::endl;
  for(int i=0;i<=pow_d;i++){
    os << getCoeffDen(i) << "*x^" << i;
    if(i!=pow_d) os << " + ";
  }
  os << std::endl;
  //For a true minimax solution the errors should all be equal and the signs should oscillate +-+-+- etc
  int sign;
  os << "Errors at maxima: coordinate, error, (sign)" << std::endl;
  for(int i=0;i<neq+1;i++){ 
    os << mm[i] << " " << getErr(mm[i],&sign) << " (" << sign << ")" << std::endl;
  }
  os << "Scan over range:" << std::endl;
  int npt = 60;
  bigfloat dlt = (apend - apstrt)/bigfloat(npt-1);
  for (bigfloat x=apstrt; x<=apend; x = x + dlt) {
    double f = evaluateFunc(x);
    double r = evaluateApprox(x);
    os<< x<<","<<r<<","<<f<<","<<r-f<<std::endl;
  }
  return;
 }
--- a/Grid/algorithms/approx/RemezGeneral.h
+++ b/Grid/algorithms/approx/RemezGeneral.h
@@ -0,0 +1,170 @@
 /*
  C.Kelly Jan 2020 based on implementation by M. Clark May 2005
  AlgRemezGeneral is an implementation of the Remez algorithm for approximating an arbitrary function by a rational polynomial 
  It includes optional restriction to odd/even polynomials for the numerator and/or denominator
 */
 #ifndef INCLUDED_ALG_REMEZ_GENERAL_H
 #define INCLUDED_ALG_REMEZ_GENERAL_H
 #include <stddef.h>
 #include <Grid/GridStd.h>
 #ifdef HAVE_LIBGMP
 #include "bigfloat.h"
 #else
 #include "bigfloat_double.h"
 #endif
 class AlgRemezGeneral{
 public:
  enum PolyType { Even, Odd, Full };
 private:
  // In GSL-style, pass the function as a function pointer. Any data required to evaluate the function is passed in as a void pointer
  bigfloat (*f)(bigfloat x, void *data);
  void *data;
  // The approximation parameters
  std::vector<bigfloat> param;
  bigfloat norm;
  // The number of non-zero terms in the numerator and denominator
  int n, d;
  // The numerator and denominator degree (i.e.  the largest power)
  int pow_n, pow_d;
  // Specify if the numerator and/or denominator are odd/even polynomials
  PolyType num_type;
  PolyType den_type;
  std::vector<int> num_pows; //contains the mapping, with -1 if not present
  std::vector<int> den_pows;
  // The bounds of the approximation
  bigfloat apstrt, apwidt, apend;
  // Variables used to calculate the approximation
  int nd1, iter;
  std::vector<bigfloat> xx;
  std::vector<bigfloat> mm;
  std::vector<bigfloat> step;
  bigfloat delta, spread;
  // Variables used in search
  std::vector<bigfloat> yy;
  // Variables used in solving linear equations
  std::vector<bigfloat> A;
  std::vector<bigfloat> B;
  std::vector<int> IPS;
  // The number of equations we must solve at each iteration (n+d+1)
  int neq;
  // The precision of the GNU MP library
  long prec;
  // Initialize member variables associated with the polynomial's properties
  void setupPolyProperties(int num_degree, int den_degree, PolyType num_type_in, PolyType den_type_in);
  // Initial values of maximal and minmal errors
  void initialGuess();
  // Initialise step sizes
  void stpini();
  // Initialize the algorithm
  void reinitializeAlgorithm();
  // Solve the equations
  void equations();
  // Search for error maxima and minima
  void search(); 
  // Calculate function required for the approximation
  inline bigfloat func(bigfloat x) const{
    return f(x, data);
  }
  // Compute size and sign of the approximation error at x
  bigfloat getErr(bigfloat x, int *sign) const;
  // Solve the system AX=B   where X = param
  int simq();
  // Evaluate the rational form P(x)/Q(x) using coefficients from the solution vector param
  bigfloat approx(bigfloat x) const;
 public:
  AlgRemezGeneral(double lower, double upper, long prec,
 		  bigfloat (*f)(bigfloat x, void *data), void *data);
  inline int getDegree(void) const{ 
    assert(n==d);
    return n;
  }
  // Reset the bounds of the approximation
  inline void setBounds(double lower, double upper) {
    apstrt = lower;
    apend = upper;
    apwidt = apend - apstrt;
  }
  // Get the bounds of the approximation
  inline void getBounds(double &lower, double &upper) const{ 
    lower=(double)apstrt;
    upper=(double)apend;
  }
  // Run the algorithm to generate the rational approximation
  double generateApprox(int num_degree, int den_degree, 
 			PolyType num_type, PolyType den_type,
 			const double tolerance = 1e-15, const int report_freq = 1000);
  inline double generateApprox(int num_degree, int den_degree, 
 			       const double tolerance = 1e-15, const int report_freq = 1000){
    return generateApprox(num_degree, den_degree, Full, Full, tolerance, report_freq);
  }
  // Evaluate the rational form P(x)/Q(x) using coefficients from the
  // solution vector param
  inline double evaluateApprox(double x) const{
    return (double)approx((bigfloat)x);
  }
  // Evaluate the rational form Q(x)/P(x) using coefficients from the solution vector param
  inline double evaluateInverseApprox(double x) const{
    return 1.0/(double)approx((bigfloat)x);
  }  
  // Calculate function required for the approximation
  inline double evaluateFunc(double x) const{
    return (double)func((bigfloat)x);
  }
  // Calculate inverse function required for the approximation
  inline double evaluateInverseFunc(double x) const{
    return 1.0/(double)func((bigfloat)x);
  }
  // Dump csv of function, approx and error
  void csv(std::ostream &os = std::cout) const;
  // Get the coefficient of the term x^i in the numerator
  inline double getCoeffNum(const int i) const{    
    return num_pows[i] == -1 ? 0. : double(param[num_pows[i]]);
  }
  // Get the coefficient of the term x^i in the denominator
  inline double getCoeffDen(const int i) const{ 
    if(i == pow_d) return 1.0;
    else return den_pows[i] == -1 ? 0. : double(param[den_pows[i]+n+1]); 
  }
 };
 #endif
--- a/Grid/algorithms/approx/ZMobius.cc
+++ b/Grid/algorithms/approx/ZMobius.cc
@@ -0,0 +1,183 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./lib/algorithms/approx/ZMobius.cc
    Copyright (C) 2015
 Author: Christopher Kelly <ckelly@phys.columbia.edu>
    This program is free software; you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation; either version 2 of the License, or
    (at your option) any later version.
    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.
    You should have received a copy of the GNU General Public License along
    with this program; if not, write to the Free Software Foundation, Inc.,
    51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
    See the full license in the file "LICENSE" in the top level distribution directory
 *************************************************************************************/
 /*  END LEGAL */
 #include <Grid/algorithms/approx/ZMobius.h>
 #include <Grid/algorithms/approx/RemezGeneral.h>
 NAMESPACE_BEGIN(Grid);
 NAMESPACE_BEGIN(Approx);
 //Compute the tanh approximation
 inline double epsilonMobius(const double x, const std::vector<ComplexD> &w){
  int Ls = w.size();
  ComplexD fxp = 1., fmp = 1.;
  for(int i=0;i<Ls;i++){
    fxp = fxp * ( w[i] + x );
    fmp = fmp * ( w[i] - x );
  }
  return ((fxp - fmp)/(fxp + fmp)).real();
 }
 inline double epsilonMobius(const double x, const std::vector<RealD> &w){
  int Ls = w.size();
  double fxp = 1., fmp = 1.;
  for(int i=0;i<Ls;i++){
    fxp = fxp * ( w[i] + x );
    fmp = fmp * ( w[i] - x );
  }
  return (fxp - fmp)/(fxp + fmp);
 }
 //Compute the tanh approximation in a form suitable for the Remez
 bigfloat epsilonMobius(bigfloat x, void* data){
  const std::vector<RealD> &omega = *( (std::vector<RealD> const*)data );
  bigfloat fxp(1.0);
  bigfloat fmp(1.0);
  for(int i=0;i<omega.size();i++){
    fxp = fxp * ( bigfloat(omega[i]) + x);
    fmp = fmp * ( bigfloat(omega[i]) - x);
  }
  return (fxp - fmp)/(fxp + fmp);
 }
 //Compute the Zmobius Omega parameters suitable for eigenvalue range   -lambda_bound <= lambda <= lambda_bound
 //Note omega_i = 1/(b_i + c_i)   where b_i and c_i are the Mobius parameters
 void computeZmobiusOmega(std::vector<ComplexD> &omega_out, const int Ls_out,
 			 const std::vector<RealD> &omega_in, const int Ls_in,
 			 const RealD lambda_bound){
  assert(omega_in.size() == Ls_in);
  omega_out.resize(Ls_out);
  //Use the Remez algorithm to generate the appropriate rational polynomial
  //For odd polynomial, to satisfy Haar condition must take either positive or negative half of range (cf https://arxiv.org/pdf/0803.0439.pdf page 6)  
  AlgRemezGeneral remez(0, lambda_bound, 64, &epsilonMobius, (void*)&omega_in); 
  remez.generateApprox(Ls_out-1, Ls_out,AlgRemezGeneral::Odd, AlgRemezGeneral::Even, 1e-15, 100);
  remez.csv(std::cout);
  //The rational approximation has the form  [ f(x) - f(-x) ] / [ f(x) + f(-x) ]  where  f(x) = \Prod_{i=0}^{L_s-1} ( \omega_i + x )
  //cf https://academiccommons.columbia.edu/doi/10.7916/D8T72HD7  pg 102
  //omega_i are therefore the negative of the complex roots of f(x)
  //We can find the roots by recognizing that the eigenvalues of a matrix A are the roots of the characteristic polynomial
  // \rho(\lambda) = det( A - \lambda I )    where I is the unit matrix
  //The matrix whose characteristic polynomial is an arbitrary monic polynomial a0 + a1 x + a2 x^2 + ... x^n   is the companion matrix 
  // A = | 0    1   0    0 0 .... 0 |
  //     | 0    0   1    0 0 .... 0 |
  //     | :    :   :    : :      : |
  //     | 0    0   0    0 0      1
  //     | -a0 -a1 -a2  ...  ... -an|
  //Note the Remez defines the largest power to have unit coefficient
  std::vector<RealD> coeffs(Ls_out+1);
  for(int i=0;i<Ls_out+1;i+=2) coeffs[i] = coeffs[i] = remez.getCoeffDen(i); //even powers
  for(int i=1;i<Ls_out+1;i+=2) coeffs[i] = coeffs[i] = remez.getCoeffNum(i); //odd powers
  std::vector<std::complex<RealD> > roots(Ls_out);
  //Form the companion matrix
  Eigen::MatrixXd compn(Ls_out,Ls_out);
  for(int i=0;i<Ls_out-1;i++) compn(i,0) = 0.;
  compn(Ls_out - 1, 0) = -coeffs[0];
  for(int j=1;j<Ls_out;j++){
    for(int i=0;i<Ls_out-1;i++) compn(i,j) = i == j-1 ? 1. : 0.;
    compn(Ls_out - 1, j) = -coeffs[j];
  }
  //Eigensolve
  Eigen::EigenSolver<Eigen::MatrixXd> slv(compn, false);
  const auto & ev = slv.eigenvalues();
  for(int i=0;i<Ls_out;i++)
    omega_out[i] = -ev(i);
  //Sort ascending (smallest at start of vector!)
  std::sort(omega_out.begin(), omega_out.end(), 
 	    [&](const ComplexD &a, const ComplexD &b){ return a.real() < b.real() || (a.real() == b.real() && a.imag() < b.imag()); });
  //McGlynn thesis pg 122 suggest improved iteration counts if magnitude of omega diminishes towards the center of the 5th dimension
  std::vector<ComplexD> omega_tmp = omega_out;
  int s_low=0, s_high=Ls_out-1, ss=0;
  for(int s_from = Ls_out-1; s_from >= 0; s_from--){ //loop from largest omega
    int s_to;
    if(ss % 2 == 0){
      s_to = s_low++;
    }else{
      s_to = s_high--;
    }
    omega_out[s_to] = omega_tmp[s_from];
    ++ss;
  }
  std::cout << "Resulting omega_i:" << std::endl;  
  for(int i=0;i<Ls_out;i++)
    std::cout << omega_out[i] << std::endl;
  std::cout << "Test result matches the approximate polynomial found by the Remez" << std::endl;
  std::cout << "<x> <remez approx> <poly approx> <diff poly approx remez approx> <exact> <diff poly approx exact>\n";
  int npt = 60;
  double dlt = lambda_bound/double(npt-1);
  for (int i =0; i<npt; i++){
    double x = i*dlt;
    double r = remez.evaluateApprox(x);
    double p = epsilonMobius(x, omega_out);
    double e = epsilonMobius(x, omega_in);
    std::cout << x<< " " << r << " " << p <<" " <<r-p << " " << e << " " << e-p << std::endl;
  }
 }
 //mobius_param = b+c   with b-c=1
 void computeZmobiusOmega(std::vector<ComplexD> &omega_out, const int Ls_out, const RealD mobius_param, const int Ls_in, const RealD lambda_bound){
  std::vector<RealD> omega_in(Ls_in, 1./mobius_param);
  computeZmobiusOmega(omega_out, Ls_out, omega_in, Ls_in, lambda_bound);
 }
 //ZMobius class takes  gamma_i = (b+c) omega_i as its input, where b, c are factored out
 void computeZmobiusGamma(std::vector<ComplexD> &gamma_out, 
 			 const RealD mobius_param_out, const int Ls_out, 
 			 const RealD mobius_param_in, const int Ls_in,
 			 const RealD lambda_bound){
  computeZmobiusOmega(gamma_out, Ls_out, mobius_param_in, Ls_in, lambda_bound);
  for(int i=0;i<Ls_out;i++) gamma_out[i] = gamma_out[i] * mobius_param_out;
 }
 //Assumes mobius_param_out == mobius_param_in
 void computeZmobiusGamma(std::vector<ComplexD> &gamma_out, const int Ls_out, const RealD mobius_param, const int Ls_in, const RealD lambda_bound){
  computeZmobiusGamma(gamma_out, mobius_param, Ls_out, mobius_param, Ls_in, lambda_bound);
 }
 NAMESPACE_END(Approx);
 NAMESPACE_END(Grid);
--- a/Grid/algorithms/approx/ZMobius.h
+++ b/Grid/algorithms/approx/ZMobius.h
@@ -0,0 +1,57 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./lib/algorithms/approx/ZMobius.h
    Copyright (C) 2015
 Author: Christopher Kelly <ckelly@phys.columbia.edu>
    This program is free software; you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation; either version 2 of the License, or
    (at your option) any later version.
    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.
    You should have received a copy of the GNU General Public License along
    with this program; if not, write to the Free Software Foundation, Inc.,
    51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
    See the full license in the file "LICENSE" in the top level distribution directory
 *************************************************************************************/
 /*  END LEGAL */
 #ifndef GRID_ZMOBIUS_APPROX_H
 #define GRID_ZMOBIUS_APPROX_H
 #include <Grid/GridCore.h>
 NAMESPACE_BEGIN(Grid);
 NAMESPACE_BEGIN(Approx);
 //Compute the Zmobius Omega parameters suitable for eigenvalue range   -lambda_bound <= lambda <= lambda_bound
 //Note omega_i = 1/(b_i + c_i)   where b_i and c_i are the Mobius parameters
 void computeZmobiusOmega(std::vector<ComplexD> &omega_out, const int Ls_out,
 			 const std::vector<RealD> &omega_in, const int Ls_in,
 			 const RealD lambda_bound);
 //mobius_param = b+c   with b-c=1
 void computeZmobiusOmega(std::vector<ComplexD> &omega_out, const int Ls_out, const RealD mobius_param, const int Ls_in, const RealD lambda_bound);
 //ZMobius class takes  gamma_i = (b+c) omega_i as its input, where b, c are factored out
 void computeZmobiusGamma(std::vector<ComplexD> &gamma_out, 
 			 const RealD mobius_param_out, const int Ls_out, 
 			 const RealD mobius_param_in, const int Ls_in,
 			 const RealD lambda_bound);
 //Assumes mobius_param_out == mobius_param_in
 void computeZmobiusGamma(std::vector<ComplexD> &gamma_out, const int Ls_out, const RealD mobius_param, const int Ls_in, const RealD lambda_bound);
 NAMESPACE_END(Approx);
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/algorithms/approx/Zolotarev.cc
+++ b/Grid/algorithms/approx/Zolotarev.cc
@@ -58,8 +58,8 @@
 /* Compute the partial fraction expansion coefficients (alpha) from the
 * factored form */
-namespace Grid {
+NAMESPACE_BEGIN(Grid);
-namespace Approx {
+NAMESPACE_BEGIN(Approx);
 static void construct_partfrac(izd *z) {
  int dn = z -> dn, dd = z -> dd, type = z -> type;
@@ -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;
@@ -493,45 +493,47 @@ 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);
  return zd;
 }
-}}
+
 NAMESPACE_END(Approx);
 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;
@@ -549,9 +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);
@@ -566,18 +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++)
@@ -585,6 +587,7 @@ static PRECISION zolotarev_cayley_eval(PRECISION x, zolotarev_data* rdata) {
  return (ONE - T) / (ONE + T);
 }
 /* Test program. Apart from printing out the parameters for R(x) it produces
 * the following data files for plotting (unless NPLOT is defined):
 *
@@ -604,7 +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;
@@ -623,13 +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",
@@ -678,15 +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));
@@ -723,5 +726,5 @@ int main(int argc, char** argv) {
  return EXIT_SUCCESS;
 }
 #endif /* TEST */
--- a/Grid/algorithms/approx/Zolotarev.h
+++ b/Grid/algorithms/approx/Zolotarev.h
@@ -1,18 +1,18 @@
 /* -*- Mode: C; comment-column: 22; fill-column: 79; -*- */
 #ifdef __cplusplus
-namespace Grid {
+#include <Grid/Namespace.h>
-namespace Approx {
+NAMESPACE_BEGIN(Grid);
 NAMESPACE_BEGIN(Approx);
 #endif
 #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
@@ -77,11 +77,13 @@ 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
 #ifdef __cplusplus
-}}
+NAMESPACE_END(Approx);
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/algorithms/approx/bigfloat.h
+++ b/Grid/algorithms/approx/bigfloat.h
@@ -10,10 +10,12 @@
 #ifndef INCLUDED_BIGFLOAT_H
 #define INCLUDED_BIGFLOAT_H
-
+#define __GMP_WITHIN_CONFIGURE
 #include <gmp.h>
 #include <mpf2mpfr.h>
 #include <mpfr.h>
 #undef  __GMP_WITHIN_CONFIGURE
 class bigfloat {
 private:
--- a/Grid/algorithms/approx/bigfloat_double.h
+++ b/Grid/algorithms/approx/bigfloat_double.h
@@ -25,6 +25,10 @@ Author: Peter Boyle <paboyle@ph.ed.ac.uk>
    See the full license in the file "LICENSE" in the top level distribution directory
    *************************************************************************************/
    /*  END LEGAL */
 #ifndef INCLUDED_BIGFLOAT_DOUBLE_H
 #define INCLUDED_BIGFLOAT_DOUBLE_H
 #include <math.h>
 typedef double mfloat; 
@@ -186,4 +190,6 @@ public:
  //  friend bigfloat& random(void);
 };
 #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/algorithms/iterative/AdefGeneric.h
+++ b/Grid/algorithms/iterative/AdefGeneric.h
@@ -90,8 +90,8 @@ class TwoLevelFlexiblePcg : public LinearFunction<Field>
  void operator() (const Field &src, Field &psi){
  void operator() (const Field &src, Field &psi){
-    psi.checkerboard = src.checkerboard;
+    psi.Checkerboard() = src.Checkerboard();
-    grid             = src._grid;
+    grid             = src.Grid();
    RealD f;
    RealD rtzp,rtz,a,d,b;
--- a/Grid/algorithms/iterative/BiCGSTAB.h
+++ b/Grid/algorithms/iterative/BiCGSTAB.h
@@ -0,0 +1,234 @@
 /*************************************************************************************
 Grid physics library, www.github.com/paboyle/Grid
 Source file: ./lib/algorithms/iterative/BiCGSTAB.h
 Copyright (C) 2015
 Author: Azusa Yamaguchi <ayamaguc@staffmail.ed.ac.uk>
 Author: Peter Boyle <paboyle@ph.ed.ac.uk>
 Author: paboyle <paboyle@ph.ed.ac.uk>
 Author: juettner <juettner@soton.ac.uk>
 Author: David Murphy <djmurphy@mit.edu>
 This program is free software; you can redistribute it and/or modify
 it under the terms of the GNU General Public License as published by
 the Free Software Foundation; either version 2 of the License, or
 (at your option) any later version.
 This program is distributed in the hope that it will be useful,
 but WITHOUT ANY WARRANTY; without even the implied warranty of
 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 GNU General Public License for more details.
 You should have received a copy of the GNU General Public License along
 with this program; if not, write to the Free Software Foundation, Inc.,
 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
 See the full license in the file "LICENSE" in the top level distribution
 directory
 *************************************************************************************/
 /*  END LEGAL */
 #ifndef GRID_BICGSTAB_H
 #define GRID_BICGSTAB_H
 NAMESPACE_BEGIN(Grid);
 /////////////////////////////////////////////////////////////
 // Base classes for iterative processes based on operators
 // single input vec, single output vec.
 /////////////////////////////////////////////////////////////
 template <class Field>
 class BiCGSTAB : public OperatorFunction<Field> 
 {
  public:
    using OperatorFunction<Field>::operator();
    bool ErrorOnNoConverge;  // throw an assert when the CG fails to converge.
                             // Defaults true.
    RealD Tolerance;
    Integer MaxIterations;
    Integer IterationsToComplete; //Number of iterations the CG took to finish. Filled in upon completion
    BiCGSTAB(RealD tol, Integer maxit, bool err_on_no_conv = true) : 
      Tolerance(tol), MaxIterations(maxit), ErrorOnNoConverge(err_on_no_conv){};
    void operator()(LinearOperatorBase<Field>& Linop, const Field& src, Field& psi) 
    {
      psi.Checkerboard() = src.Checkerboard();
      conformable(psi, src);
      RealD cp(0), rho(1), rho_prev(0), alpha(1), beta(0), omega(1);
      RealD a(0), bo(0), b(0), ssq(0);
      Field p(src);
      Field r(src);
      Field rhat(src);
      Field v(src);
      Field s(src);
      Field t(src);
      Field h(src);
      v = Zero();
      p = Zero();
      // Initial residual computation & set up
      RealD guess = norm2(psi);
      assert(std::isnan(guess) == 0);
      Linop.Op(psi, v);
      b = norm2(v);
      r = src - v;
      rhat = r;
      a = norm2(r);
      ssq = norm2(src);
      std::cout << GridLogIterative << std::setprecision(8) << "BiCGSTAB: guess " << guess << std::endl;
      std::cout << GridLogIterative << std::setprecision(8) << "BiCGSTAB:   src " << ssq << std::endl;
      std::cout << GridLogIterative << std::setprecision(8) << "BiCGSTAB:    mp " << b << std::endl;
      std::cout << GridLogIterative << std::setprecision(8) << "BiCGSTAB:     r " << a << std::endl;
      RealD rsq = Tolerance * Tolerance * ssq;
      // Check if guess is really REALLY good :)
      if(a <= rsq){ return; }
      std::cout << GridLogIterative << std::setprecision(8) << "BiCGSTAB: k=0 residual " << a << " target " << rsq << std::endl;
      GridStopWatch LinalgTimer;
      GridStopWatch InnerTimer;
      GridStopWatch AxpyNormTimer;
      GridStopWatch LinearCombTimer;
      GridStopWatch MatrixTimer;
      GridStopWatch SolverTimer;
      SolverTimer.Start();
      int k;
      for (k = 1; k <= MaxIterations; k++) 
      {
        rho_prev = rho;
        LinalgTimer.Start();
        InnerTimer.Start();
        ComplexD Crho  = innerProduct(rhat,r);
        InnerTimer.Stop();
        rho = Crho.real();
        beta = (rho / rho_prev) * (alpha / omega);
        LinearCombTimer.Start();
        bo = beta * omega;
 	{
 	  autoView( p_v , p, AcceleratorWrite);
 	  autoView( r_v , r, AcceleratorRead);
 	  autoView( v_v , v, AcceleratorRead);
 	  accelerator_for(ss, p_v.size(), Field::vector_object::Nsimd(),{
 	      coalescedWrite(p_v[ss], beta*p_v(ss) - bo*v_v(ss) + r_v(ss));
 	    });
 	}
        LinearCombTimer.Stop();
        LinalgTimer.Stop();
        MatrixTimer.Start();
        Linop.Op(p,v);
        MatrixTimer.Stop();
        LinalgTimer.Start();
        InnerTimer.Start();
        ComplexD Calpha = innerProduct(rhat,v);
        InnerTimer.Stop();
        alpha = rho / Calpha.real();
        LinearCombTimer.Start();
 	{
 	  autoView( p_v , p, AcceleratorRead);
 	  autoView( r_v , r, AcceleratorRead);
 	  autoView( v_v , v, AcceleratorRead);
 	  autoView( psi_v,psi, AcceleratorRead);
 	  autoView( h_v  ,  h, AcceleratorWrite);
 	  autoView( s_v  ,  s, AcceleratorWrite);
 	  accelerator_for(ss, h_v.size(), Field::vector_object::Nsimd(),{
 	      coalescedWrite(h_v[ss], alpha*p_v(ss) + psi_v(ss));
 	    });
 	  accelerator_for(ss, s_v.size(), Field::vector_object::Nsimd(),{
 	      coalescedWrite(s_v[ss], -alpha*v_v(ss) + r_v(ss));
 	  });
        }
        LinearCombTimer.Stop();
        LinalgTimer.Stop();
        MatrixTimer.Start();
        Linop.Op(s,t);
        MatrixTimer.Stop();
        LinalgTimer.Start();
        InnerTimer.Start();
        ComplexD Comega = innerProduct(t,s);
        InnerTimer.Stop();
        omega = Comega.real() / norm2(t);
        LinearCombTimer.Start();
 	{
 	  autoView( psi_v,psi, AcceleratorWrite);
 	  autoView( r_v , r, AcceleratorWrite);
 	  autoView( h_v , h, AcceleratorRead);
 	  autoView( s_v , s, AcceleratorRead);
 	  autoView( t_v , t, AcceleratorRead);
 	  accelerator_for(ss, psi_v.size(), Field::vector_object::Nsimd(),{
 	      coalescedWrite(psi_v[ss], h_v(ss) + omega * s_v(ss));
 	      coalescedWrite(r_v[ss], -omega * t_v(ss) + s_v(ss));
 	    });
 	}
        LinearCombTimer.Stop();
        cp = norm2(r);
        LinalgTimer.Stop();
        std::cout << GridLogIterative << "BiCGSTAB: Iteration " << k << " residual " << sqrt(cp/ssq) << " target " << Tolerance << std::endl;
        // Stopping condition
        if(cp <= rsq) 
        {
          SolverTimer.Stop();
          Linop.Op(psi, v);
          p = v - src;
          RealD srcnorm = sqrt(norm2(src));
          RealD resnorm = sqrt(norm2(p));
          RealD true_residual = resnorm / srcnorm;
          std::cout << GridLogMessage << "BiCGSTAB Converged on iteration " << k << std::endl;
          std::cout << GridLogMessage << "\tComputed residual " << sqrt(cp/ssq) << std::endl;
          std::cout << GridLogMessage << "\tTrue residual " << true_residual << std::endl;
          std::cout << GridLogMessage << "\tTarget " << Tolerance << std::endl;
          std::cout << GridLogMessage << "Time breakdown " << std::endl;
          std::cout << GridLogMessage << "\tElapsed    " << SolverTimer.Elapsed() << std::endl;
          std::cout << GridLogMessage << "\tMatrix     " << MatrixTimer.Elapsed() << std::endl;
          std::cout << GridLogMessage << "\tLinalg     " << LinalgTimer.Elapsed() << std::endl;
          std::cout << GridLogMessage << "\tInner      " << InnerTimer.Elapsed() << std::endl;
          std::cout << GridLogMessage << "\tAxpyNorm   " << AxpyNormTimer.Elapsed() << std::endl;
          std::cout << GridLogMessage << "\tLinearComb " << LinearCombTimer.Elapsed() << std::endl;
          if(ErrorOnNoConverge){ assert(true_residual / Tolerance < 10000.0); }
          IterationsToComplete = k;	
          return;
        }
      }
      std::cout << GridLogMessage << "BiCGSTAB did NOT converge" << std::endl;
      if(ErrorOnNoConverge){ assert(0); }
      IterationsToComplete = k;
    }
 };
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/algorithms/iterative/BiCGSTABMixedPrec.h
+++ b/Grid/algorithms/iterative/BiCGSTABMixedPrec.h
@@ -0,0 +1,159 @@
 /*************************************************************************************
 Grid physics library, www.github.com/paboyle/Grid 
 Source file: ./lib/algorithms/iterative/BiCGSTABMixedPrec.h
 Copyright (C) 2015
 Author: Christopher Kelly <ckelly@phys.columbia.edu>
 Author: David Murphy <djmurphy@mit.edu>
 This program is free software; you can redistribute it and/or modify
 it under the terms of the GNU General Public License as published by
 the Free Software Foundation; either version 2 of the License, or
 (at your option) any later version.
 This program is distributed in the hope that it will be useful,
 but WITHOUT ANY WARRANTY; without even the implied warranty of
 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 GNU General Public License for more details.
 You should have received a copy of the GNU General Public License along
 with this program; if not, write to the Free Software Foundation, Inc.,
 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
 See the full license in the file "LICENSE" in the top level distribution directory
 *************************************************************************************/
 /*  END LEGAL */
 #ifndef GRID_BICGSTAB_MIXED_PREC_H
 #define GRID_BICGSTAB_MIXED_PREC_H
 NAMESPACE_BEGIN(Grid);
 // Mixed precision restarted defect correction BiCGSTAB
 template<class FieldD, class FieldF, typename std::enable_if< getPrecision<FieldD>::value == 2, int>::type = 0, typename std::enable_if< getPrecision<FieldF>::value == 1, int>::type = 0> 
 class MixedPrecisionBiCGSTAB : public LinearFunction<FieldD> 
 {
  public:
    using LinearFunction<FieldD>::operator();
    RealD   Tolerance;
    RealD   InnerTolerance; // Initial tolerance for inner CG. Defaults to Tolerance but can be changed
    Integer MaxInnerIterations;
    Integer MaxOuterIterations;
    GridBase* SinglePrecGrid; // Grid for single-precision fields
    RealD OuterLoopNormMult; // Stop the outer loop and move to a final double prec solve when the residual is OuterLoopNormMult * Tolerance
    LinearOperatorBase<FieldF> &Linop_f;
    LinearOperatorBase<FieldD> &Linop_d;
    Integer TotalInnerIterations; //Number of inner CG iterations
    Integer TotalOuterIterations; //Number of restarts
    Integer TotalFinalStepIterations; //Number of CG iterations in final patch-up step
    //Option to speed up *inner single precision* solves using a LinearFunction that produces a guess
    LinearFunction<FieldF> *guesser;
    MixedPrecisionBiCGSTAB(RealD tol, Integer maxinnerit, Integer maxouterit, GridBase* _sp_grid, 
        LinearOperatorBase<FieldF>& _Linop_f, LinearOperatorBase<FieldD>& _Linop_d) : 
      Linop_f(_Linop_f), Linop_d(_Linop_d), Tolerance(tol), InnerTolerance(tol), MaxInnerIterations(maxinnerit), 
      MaxOuterIterations(maxouterit), SinglePrecGrid(_sp_grid), OuterLoopNormMult(100.), guesser(NULL) {};
    void useGuesser(LinearFunction<FieldF>& g){
      guesser = &g;
    }
    void operator() (const FieldD& src_d_in, FieldD& sol_d)
    {
      TotalInnerIterations = 0;
      GridStopWatch TotalTimer;
      TotalTimer.Start();
      int cb = src_d_in.Checkerboard();
      sol_d.Checkerboard() = cb;
      RealD src_norm = norm2(src_d_in);
      RealD stop = src_norm * Tolerance*Tolerance;
      GridBase* DoublePrecGrid = src_d_in.Grid();
      FieldD tmp_d(DoublePrecGrid);
      tmp_d.Checkerboard() = cb;
      FieldD tmp2_d(DoublePrecGrid);
      tmp2_d.Checkerboard() = cb;
      FieldD src_d(DoublePrecGrid);
      src_d = src_d_in; //source for next inner iteration, computed from residual during operation
      RealD inner_tol = InnerTolerance;
      FieldF src_f(SinglePrecGrid);
      src_f.Checkerboard() = cb;
      FieldF sol_f(SinglePrecGrid);
      sol_f.Checkerboard() = cb;
      BiCGSTAB<FieldF> CG_f(inner_tol, MaxInnerIterations);
      CG_f.ErrorOnNoConverge = false;
      GridStopWatch InnerCGtimer;
      GridStopWatch PrecChangeTimer;
      Integer &outer_iter = TotalOuterIterations; //so it will be equal to the final iteration count
      for(outer_iter = 0; outer_iter < MaxOuterIterations; outer_iter++)
      {
        // Compute double precision rsd and also new RHS vector.
        Linop_d.Op(sol_d, tmp_d);
        RealD norm = axpy_norm(src_d, -1., tmp_d, src_d_in); //src_d is residual vector
        std::cout << GridLogMessage << "MixedPrecisionBiCGSTAB: Outer iteration " << outer_iter << " residual " << norm << " target " << stop << std::endl;
        if(norm < OuterLoopNormMult * stop){
          std::cout << GridLogMessage << "MixedPrecisionBiCGSTAB: Outer iteration converged on iteration " << outer_iter << std::endl;
          break;
        }
        while(norm * inner_tol * inner_tol < stop){ inner_tol *= 2; } // inner_tol = sqrt(stop/norm) ??
        PrecChangeTimer.Start();
        precisionChange(src_f, src_d);
        PrecChangeTimer.Stop();
        sol_f = Zero();
        //Optionally improve inner solver guess (eg using known eigenvectors)
        if(guesser != NULL){ (*guesser)(src_f, sol_f); }
        //Inner CG
        CG_f.Tolerance = inner_tol;
        InnerCGtimer.Start();
        CG_f(Linop_f, src_f, sol_f);
        InnerCGtimer.Stop();
        TotalInnerIterations += CG_f.IterationsToComplete;
        //Convert sol back to double and add to double prec solution
        PrecChangeTimer.Start();
        precisionChange(tmp_d, sol_f);
        PrecChangeTimer.Stop();
        axpy(sol_d, 1.0, tmp_d, sol_d);
      }
      //Final trial CG
      std::cout << GridLogMessage << "MixedPrecisionBiCGSTAB: Starting final patch-up double-precision solve" << std::endl;
      BiCGSTAB<FieldD> CG_d(Tolerance, MaxInnerIterations);
      CG_d(Linop_d, src_d_in, sol_d);
      TotalFinalStepIterations = CG_d.IterationsToComplete;
      TotalTimer.Stop();
      std::cout << GridLogMessage << "MixedPrecisionBiCGSTAB: Inner CG iterations " << TotalInnerIterations << " Restarts " << TotalOuterIterations << " Final CG iterations " << TotalFinalStepIterations << std::endl;
      std::cout << GridLogMessage << "MixedPrecisionBiCGSTAB: Total time " << TotalTimer.Elapsed() << " Precision change " << PrecChangeTimer.Elapsed() << " Inner CG total " << InnerCGtimer.Elapsed() << std::endl;
  }
 };
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/algorithms/iterative/BlockConjugateGradient.h
+++ b/Grid/algorithms/iterative/BlockConjugateGradient.h
@@ -27,13 +27,11 @@ See the full license in the file "LICENSE" in the top level distribution
 directory
 *************************************************************************************/
 /*  END LEGAL */
-#ifndef GRID_BLOCK_CONJUGATE_GRADIENT_H
+#pragma once
 #define GRID_BLOCK_CONJUGATE_GRADIENT_H
 NAMESPACE_BEGIN(Grid);
-namespace Grid {
+enum BlockCGtype { BlockCG, BlockCGrQ, CGmultiRHS, BlockCGVec, BlockCGrQVec };
 enum BlockCGtype { BlockCG, BlockCGrQ, CGmultiRHS };
 //////////////////////////////////////////////////////////////////////////
 // Block conjugate gradient. Dimension zero should be the block direction
@@ -42,7 +40,6 @@ template <class Field>
 class BlockConjugateGradient : public OperatorFunction<Field> {
 public:
  typedef typename Field::scalar_type scomplex;
  int blockDim ;
@@ -54,21 +51,16 @@ class BlockConjugateGradient : public OperatorFunction<Field> {
  RealD Tolerance;
  Integer MaxIterations;
  Integer IterationsToComplete; //Number of iterations the CG took to finish. Filled in upon completion
  Integer PrintInterval; //GridLogMessages or Iterative
  RealD TrueResidual;
  BlockConjugateGradient(BlockCGtype cgtype,int _Orthog,RealD tol, Integer maxit, bool err_on_no_conv = true)
-    : Tolerance(tol), CGtype(cgtype),   blockDim(_Orthog),  MaxIterations(maxit), ErrorOnNoConverge(err_on_no_conv)
+    : Tolerance(tol), CGtype(cgtype),   blockDim(_Orthog),  MaxIterations(maxit), ErrorOnNoConverge(err_on_no_conv),PrintInterval(100)
  {};
 ////////////////////////////////////////////////////////////////////////////////////////////////////
 // Thin QR factorisation (google it)
 ////////////////////////////////////////////////////////////////////////////////////////////////////
 void ThinQRfact (Eigen::MatrixXcd &m_rr,
 		 Eigen::MatrixXcd &C,
 		 Eigen::MatrixXcd &Cinv,
 		 Field & Q,
 		 const Field & R)
 {
  int Orthog = blockDim; // First dimension is block dim; this is an assumption
  ////////////////////////////////////////////////////////////////////////////////////////////////////
  //Dimensions
  // R_{ferm x Nblock} =  Q_{ferm x Nblock} x  C_{Nblock x Nblock} -> ferm x Nblock
@@ -85,22 +77,20 @@ void ThinQRfact (Eigen::MatrixXcd &m_rr,
  // Cdag C = Rdag R ; passes.
  // QdagQ  = 1      ; passes
  ////////////////////////////////////////////////////////////////////////////////////////////////////
 void ThinQRfact (Eigen::MatrixXcd &m_rr,
 		 Eigen::MatrixXcd &C,
 		 Eigen::MatrixXcd &Cinv,
 		 Field & Q,
 		 const Field & R)
 {
  int Orthog = blockDim; // First dimension is block dim; this is an assumption
  sliceInnerProductMatrix(m_rr,R,R,Orthog);
  // Force manifest hermitian to avoid rounding related
  m_rr = 0.5*(m_rr+m_rr.adjoint());
 #if 0
  std::cout << " Calling Cholesky  ldlt on m_rr "  << m_rr <<std::endl;
  Eigen::MatrixXcd L_ldlt = m_rr.ldlt().matrixL(); 
  std::cout << " Called Cholesky  ldlt on m_rr "  << L_ldlt <<std::endl;
  auto  D_ldlt = m_rr.ldlt().vectorD(); 
  std::cout << " Called Cholesky  ldlt on m_rr "  << D_ldlt <<std::endl;
 #endif
  //  std::cout << " Calling Cholesky  llt on m_rr "  <<std::endl;
  Eigen::MatrixXcd L    = m_rr.llt().matrixL(); 
-  //  std::cout << " Called Cholesky  llt on m_rr "  << L <<std::endl;
+
  C    = L.adjoint();
  Cinv = C.inverse();
  ////////////////////////////////////////////////////////////////////////////////////////////////////
@@ -112,6 +102,25 @@ void ThinQRfact (Eigen::MatrixXcd &m_rr,
  ////////////////////////////////////////////////////////////////////////////////////////////////////
  sliceMulMatrix(Q,Cinv,R,Orthog);
 }
 // see comments above
 void ThinQRfact (Eigen::MatrixXcd &m_rr,
 		 Eigen::MatrixXcd &C,
 		 Eigen::MatrixXcd &Cinv,
 		 std::vector<Field> & Q,
 		 const std::vector<Field> & R)
 {
  InnerProductMatrix(m_rr,R,R);
  m_rr = 0.5*(m_rr+m_rr.adjoint());
  Eigen::MatrixXcd L    = m_rr.llt().matrixL(); 
  C    = L.adjoint();
  Cinv = C.inverse();
  MulMatrix(Q,Cinv,R);
 }
 ////////////////////////////////////////////////////////////////////////////////////////////////////
 // Call one of several implementations
 ////////////////////////////////////////////////////////////////////////////////////////////////////
@@ -119,14 +128,20 @@ void operator()(LinearOperatorBase<Field> &Linop, const Field &Src, Field &Psi)
 {
  if ( CGtype == BlockCGrQ ) {
    BlockCGrQsolve(Linop,Src,Psi);
  } else if (CGtype == BlockCG ) {
    BlockCGsolve(Linop,Src,Psi);
  } else if (CGtype == CGmultiRHS ) {
    CGmultiRHSsolve(Linop,Src,Psi);
  } else {
    assert(0);
  }
 }
 virtual void operator()(LinearOperatorBase<Field> &Linop, const std::vector<Field> &Src, std::vector<Field> &Psi) 
 {
  if ( CGtype == BlockCGrQVec ) {
    BlockCGrQsolveVec(Linop,Src,Psi);
  } else {
    assert(0);
  }
 }
 ////////////////////////////////////////////////////////////////////////////
 // BlockCGrQ implementation:
@@ -138,11 +153,12 @@ void operator()(LinearOperatorBase<Field> &Linop, const Field &Src, Field &Psi)
 void BlockCGrQsolve(LinearOperatorBase<Field> &Linop, const Field &B, Field &X) 
 {
  int Orthog = blockDim; // First dimension is block dim; this is an assumption
-  Nblock = B._grid->_fdimensions[Orthog];
+  Nblock = B.Grid()->_fdimensions[Orthog];
-
+/* FAKE */
  Nblock=8;
  std::cout<<GridLogMessage<<" Block Conjugate Gradient : Orthog "<<Orthog<<" Nblock "<<Nblock<<std::endl;
-  X.checkerboard = B.checkerboard;
+  X.Checkerboard() = B.Checkerboard();
  conformable(X, B);
  Field tmp(B);
@@ -202,15 +218,10 @@ void BlockCGrQsolve(LinearOperatorBase<Field> &Linop, const Field &B, Field &X)
  std::cout << GridLogMessage<<"BlockCGrQ algorithm initialisation " <<std::endl;
  //1.  QC = R = B-AX, D = Q     ; QC => Thin QR factorisation (google it)
  Linop.HermOp(X, AD);
  tmp = B - AD;  
-  //std::cout << GridLogMessage << " initial tmp " << norm2(tmp)<< std::endl;
+
  ThinQRfact (m_rr, m_C, m_Cinv, Q, tmp);
  //std::cout << GridLogMessage << " initial Q " << norm2(Q)<< std::endl;
  //std::cout << GridLogMessage << " m_rr " << m_rr<<std::endl;
  //std::cout << GridLogMessage << " m_C " << m_C<<std::endl;
  //std::cout << GridLogMessage << " m_Cinv " << m_Cinv<<std::endl;
  D=Q;
  std::cout << GridLogMessage<<"BlockCGrQ computed initial residual and QR fact " <<std::endl;
@@ -232,14 +243,12 @@ void BlockCGrQsolve(LinearOperatorBase<Field> &Linop, const Field &B, Field &X)
    MatrixTimer.Start();
    Linop.HermOp(D, Z);      
    MatrixTimer.Stop();
    //std::cout << GridLogMessage << " norm2 Z " <<norm2(Z)<<std::endl;
    //4. M  = [D^dag Z]^{-1}
    sliceInnerTimer.Start();
    sliceInnerProductMatrix(m_DZ,D,Z,Orthog);
    sliceInnerTimer.Stop();
    m_M       = m_DZ.inverse();
    //std::cout << GridLogMessage << " m_DZ " <<m_DZ<<std::endl;
    //5. X  = X + D MC
    m_tmp     = m_M * m_C;
@@ -257,6 +266,7 @@ void BlockCGrQsolve(LinearOperatorBase<Field> &Linop, const Field &B, Field &X)
    //7. D  = Q + D S^dag
    m_tmp = m_S.adjoint();
    sliceMaddTimer.Start();
    sliceMaddMatrix(D,m_tmp,D,Q,Orthog);
    sliceMaddTimer.Stop();
@@ -297,7 +307,8 @@ void BlockCGrQsolve(LinearOperatorBase<Field> &Linop, const Field &B, Field &X)
      Linop.HermOp(X, AD);
      AD = AD-B;
-      std::cout << GridLogMessage <<"\t True residual is " << std::sqrt(norm2(AD)/norm2(B)) <<std::endl;
+      TrueResidual = std::sqrt(norm2(AD)/norm2(B));
      std::cout << GridLogMessage <<"\tTrue residual is " << TrueResidual <<std::endl;
      std::cout << GridLogMessage << "Time Breakdown "<<std::endl;
      std::cout << GridLogMessage << "\tElapsed    " << SolverTimer.Elapsed()     <<std::endl;
@@ -317,163 +328,17 @@ void BlockCGrQsolve(LinearOperatorBase<Field> &Linop, const Field &B, Field &X)
  IterationsToComplete = k;
 }
 //////////////////////////////////////////////////////////////////////////
 // Block conjugate gradient; Original O'Leary Dimension zero should be the block direction
 //////////////////////////////////////////////////////////////////////////
 void BlockCGsolve(LinearOperatorBase<Field> &Linop, const Field &Src, Field &Psi) 
 {
  int Orthog = blockDim; // First dimension is block dim; this is an assumption
  Nblock = Src._grid->_fdimensions[Orthog];
  std::cout<<GridLogMessage<<" Block Conjugate Gradient : Orthog "<<Orthog<<" Nblock "<<Nblock<<std::endl;
  Psi.checkerboard = Src.checkerboard;
  conformable(Psi, Src);
  Field P(Src);
  Field AP(Src);
  Field R(Src);
  Eigen::MatrixXcd m_pAp    = Eigen::MatrixXcd::Identity(Nblock,Nblock);
  Eigen::MatrixXcd m_pAp_inv= Eigen::MatrixXcd::Identity(Nblock,Nblock);
  Eigen::MatrixXcd m_rr     = Eigen::MatrixXcd::Zero(Nblock,Nblock);
  Eigen::MatrixXcd m_rr_inv = Eigen::MatrixXcd::Zero(Nblock,Nblock);
  Eigen::MatrixXcd m_alpha      = Eigen::MatrixXcd::Zero(Nblock,Nblock);
  Eigen::MatrixXcd m_beta   = Eigen::MatrixXcd::Zero(Nblock,Nblock);
  // Initial residual computation & set up
  std::vector<RealD> residuals(Nblock);
  std::vector<RealD> ssq(Nblock);
  sliceNorm(ssq,Src,Orthog);
  RealD sssum=0;
  for(int b=0;b<Nblock;b++) sssum+=ssq[b];
  sliceNorm(residuals,Src,Orthog);
  for(int b=0;b<Nblock;b++){ assert(std::isnan(residuals[b])==0); }
  sliceNorm(residuals,Psi,Orthog);
  for(int b=0;b<Nblock;b++){ assert(std::isnan(residuals[b])==0); }
  // Initial search dir is guess
  Linop.HermOp(Psi, AP);
  /************************************************************************
   * Block conjugate gradient (Stephen Pickles, thesis 1995, pp 71, O Leary 1980)
   ************************************************************************
   * O'Leary : R = B - A X
   * O'Leary : P = M R ; preconditioner M = 1
   * O'Leary : alpha = PAP^{-1} RMR
   * O'Leary : beta  = RMR^{-1}_old RMR_new
   * O'Leary : X=X+Palpha
   * O'Leary : R_new=R_old-AP alpha
   * O'Leary : P=MR_new+P beta
   */
  R = Src - AP;  
  P = R;
  sliceInnerProductMatrix(m_rr,R,R,Orthog);
  GridStopWatch sliceInnerTimer;
  GridStopWatch sliceMaddTimer;
  GridStopWatch MatrixTimer;
  GridStopWatch SolverTimer;
  SolverTimer.Start();
  int k;
  for (k = 1; k <= MaxIterations; k++) {
    RealD rrsum=0;
    for(int b=0;b<Nblock;b++) rrsum+=real(m_rr(b,b));
    std::cout << GridLogIterative << "\titeration "<<k<<" rr_sum "<<rrsum<<" ssq_sum "<< sssum
 	      <<" / "<<std::sqrt(rrsum/sssum) <<std::endl;
    MatrixTimer.Start();
    Linop.HermOp(P, AP);
    MatrixTimer.Stop();
    // Alpha
    sliceInnerTimer.Start();
    sliceInnerProductMatrix(m_pAp,P,AP,Orthog);
    sliceInnerTimer.Stop();
    m_pAp_inv = m_pAp.inverse();
    m_alpha   = m_pAp_inv * m_rr ;
    // Psi, R update
    sliceMaddTimer.Start();
    sliceMaddMatrix(Psi,m_alpha, P,Psi,Orthog);     // add alpha *  P to psi
    sliceMaddMatrix(R  ,m_alpha,AP,  R,Orthog,-1.0);// sub alpha * AP to resid
    sliceMaddTimer.Stop();
    // Beta
    m_rr_inv = m_rr.inverse();
    sliceInnerTimer.Start();
    sliceInnerProductMatrix(m_rr,R,R,Orthog);
    sliceInnerTimer.Stop();
    m_beta = m_rr_inv *m_rr;
    // Search update
    sliceMaddTimer.Start();
    sliceMaddMatrix(AP,m_beta,P,R,Orthog);
    sliceMaddTimer.Stop();
    P= AP;
    /*********************
     * convergence monitor
     *********************
     */
    RealD max_resid=0;
    RealD rr;
    for(int b=0;b<Nblock;b++){
      rr = real(m_rr(b,b))/ssq[b];
      if ( rr > max_resid ) max_resid = rr;
    }
    if ( max_resid < Tolerance*Tolerance ) { 
      SolverTimer.Stop();
      std::cout << GridLogMessage<<"BlockCG converged in "<<k<<" iterations"<<std::endl;
      for(int b=0;b<Nblock;b++){
 	std::cout << GridLogMessage<< "\t\tblock "<<b<<" computed resid "
 		  << std::sqrt(real(m_rr(b,b))/ssq[b])<<std::endl;
      }
      std::cout << GridLogMessage<<"\tMax residual is "<<std::sqrt(max_resid)<<std::endl;
      Linop.HermOp(Psi, AP);
      AP = AP-Src;
      std::cout << GridLogMessage <<"\t True residual is " << std::sqrt(norm2(AP)/norm2(Src)) <<std::endl;
      std::cout << GridLogMessage << "Time Breakdown "<<std::endl;
      std::cout << GridLogMessage << "\tElapsed    " << SolverTimer.Elapsed()     <<std::endl;
      std::cout << GridLogMessage << "\tMatrix     " << MatrixTimer.Elapsed()     <<std::endl;
      std::cout << GridLogMessage << "\tInnerProd  " << sliceInnerTimer.Elapsed() <<std::endl;
      std::cout << GridLogMessage << "\tMaddMatrix " << sliceMaddTimer.Elapsed()  <<std::endl;
      IterationsToComplete = k;
      return;
    }
  }
  std::cout << GridLogMessage << "BlockConjugateGradient did NOT converge" << std::endl;
  if (ErrorOnNoConverge) assert(0);
  IterationsToComplete = k;
 }
 //////////////////////////////////////////////////////////////////////////
 // multiRHS conjugate gradient. Dimension zero should be the block direction
 // Use this for spread out across nodes
 //////////////////////////////////////////////////////////////////////////
 void CGmultiRHSsolve(LinearOperatorBase<Field> &Linop, const Field &Src, Field &Psi) 
 {
  int Orthog = blockDim; // First dimension is block dim
-  Nblock = Src._grid->_fdimensions[Orthog];
+  Nblock = Src.Grid()->_fdimensions[Orthog];
  std::cout<<GridLogMessage<<"MultiRHS Conjugate Gradient : Orthog "<<Orthog<<" Nblock "<<Nblock<<std::endl;
-  Psi.checkerboard = Src.checkerboard;
+  Psi.Checkerboard() = Src.Checkerboard();
  conformable(Psi, Src);
  Field P(Src);
@@ -579,7 +444,8 @@ void CGmultiRHSsolve(LinearOperatorBase<Field> &Linop, const Field &Src, Field &
      Linop.HermOp(Psi, AP);
      AP = AP-Src;
-      std::cout <<GridLogMessage << "\tTrue residual is " << std::sqrt(norm2(AP)/norm2(Src)) <<std::endl;
+      TrueResidual = std::sqrt(norm2(AP)/norm2(Src));
      std::cout <<GridLogMessage << "\tTrue residual is " << TrueResidual <<std::endl;
      std::cout << GridLogMessage << "Time Breakdown "<<std::endl;
      std::cout << GridLogMessage << "\tElapsed    " << SolverTimer.Elapsed()     <<std::endl;
@@ -600,7 +466,233 @@ void CGmultiRHSsolve(LinearOperatorBase<Field> &Linop, const Field &Src, Field &
  IterationsToComplete = k;
 }
 void InnerProductMatrix(Eigen::MatrixXcd &m , const std::vector<Field> &X, const std::vector<Field> &Y){
  for(int b=0;b<Nblock;b++){
  for(int bp=0;bp<Nblock;bp++) {
    m(b,bp) = innerProduct(X[b],Y[bp]);  
  }}
 }
 void MaddMatrix(std::vector<Field> &AP, Eigen::MatrixXcd &m , const std::vector<Field> &X,const std::vector<Field> &Y,RealD scale=1.0){
  // Should make this cache friendly with site outermost, parallel_for
  // Deal with case AP aliases with either Y or X
  std::vector<Field> tmp(Nblock,X[0]);
  for(int b=0;b<Nblock;b++){
    tmp[b]   = Y[b];
    for(int bp=0;bp<Nblock;bp++) {
      tmp[b] = tmp[b] + scomplex(scale*m(bp,b))*X[bp]; 
    }
  }
  for(int b=0;b<Nblock;b++){
    AP[b] = tmp[b];
  }
 }
 void MulMatrix(std::vector<Field> &AP, Eigen::MatrixXcd &m , const std::vector<Field> &X){
  // Should make this cache friendly with site outermost, parallel_for
  for(int b=0;b<Nblock;b++){
    AP[b] = Zero();
    for(int bp=0;bp<Nblock;bp++) {
      AP[b] += scomplex(m(bp,b))*X[bp]; 
    }
  }
 }
 double normv(const std::vector<Field> &P){
  double nn = 0.0;
  for(int b=0;b<Nblock;b++) {
    nn+=norm2(P[b]);
  }
  return nn;
 }
 ////////////////////////////////////////////////////////////////////////////
 // BlockCGrQvec implementation:
 //--------------------------
 // X is guess/Solution
 // B is RHS
 // Solve A X_i = B_i    ;        i refers to Nblock index
 ////////////////////////////////////////////////////////////////////////////
 void BlockCGrQsolveVec(LinearOperatorBase<Field> &Linop, const std::vector<Field> &B, std::vector<Field> &X) 
 {
  Nblock = B.size();
  assert(Nblock == X.size());
  std::cout<<GridLogMessage<<" Block Conjugate Gradient Vec rQ : Nblock "<<Nblock<<std::endl;
  for(int b=0;b<Nblock;b++){ 
    X[b].Checkerboard() = B[b].Checkerboard();
    conformable(X[b], B[b]);
    conformable(X[b], X[0]); 
  }
  Field Fake(B[0]);
  std::vector<Field> tmp(Nblock,Fake);
  std::vector<Field>   Q(Nblock,Fake);
  std::vector<Field>   D(Nblock,Fake);
  std::vector<Field>   Z(Nblock,Fake);
  std::vector<Field>  AD(Nblock,Fake);
  Eigen::MatrixXcd m_DZ     = Eigen::MatrixXcd::Identity(Nblock,Nblock);
  Eigen::MatrixXcd m_M      = Eigen::MatrixXcd::Identity(Nblock,Nblock);
  Eigen::MatrixXcd m_rr     = Eigen::MatrixXcd::Zero(Nblock,Nblock);
  Eigen::MatrixXcd m_C      = Eigen::MatrixXcd::Zero(Nblock,Nblock);
  Eigen::MatrixXcd m_Cinv   = Eigen::MatrixXcd::Zero(Nblock,Nblock);
  Eigen::MatrixXcd m_S      = Eigen::MatrixXcd::Zero(Nblock,Nblock);
  Eigen::MatrixXcd m_Sinv   = Eigen::MatrixXcd::Zero(Nblock,Nblock);
  Eigen::MatrixXcd m_tmp    = Eigen::MatrixXcd::Identity(Nblock,Nblock);
  Eigen::MatrixXcd m_tmp1   = Eigen::MatrixXcd::Identity(Nblock,Nblock);
  // Initial residual computation & set up
  std::vector<RealD> residuals(Nblock);
  std::vector<RealD> ssq(Nblock);
  RealD sssum=0;
  for(int b=0;b<Nblock;b++){ ssq[b] = norm2(B[b]);}
  for(int b=0;b<Nblock;b++) sssum+=ssq[b];
  for(int b=0;b<Nblock;b++){ residuals[b] = norm2(B[b]);}
  for(int b=0;b<Nblock;b++){ assert(std::isnan(residuals[b])==0); }
  for(int b=0;b<Nblock;b++){ residuals[b] = norm2(X[b]);}
  for(int b=0;b<Nblock;b++){ assert(std::isnan(residuals[b])==0); }
  /************************************************************************
   * Block conjugate gradient rQ (Sebastien Birk Thesis, after Dubrulle 2001)
   ************************************************************************
   * Dimensions:
   *
   *   X,B==(Nferm x Nblock)
   *   A==(Nferm x Nferm)
   *  
   * Nferm = Nspin x Ncolour x Ncomplex x Nlattice_site
   * 
   * QC = R = B-AX, D = Q     ; QC => Thin QR factorisation (google it)
   * for k: 
   *   Z  = AD
   *   M  = [D^dag Z]^{-1}
   *   X  = X + D MC
   *   QS = Q - ZM
   *   D  = Q + D S^dag
   *   C  = S C
   */
  ///////////////////////////////////////
  // Initial block: initial search dir is guess
  ///////////////////////////////////////
  std::cout << GridLogMessage<<"BlockCGrQvec algorithm initialisation " <<std::endl;
  //1.  QC = R = B-AX, D = Q     ; QC => Thin QR factorisation (google it)
  for(int b=0;b<Nblock;b++) {
    Linop.HermOp(X[b], AD[b]);
    tmp[b] = B[b] - AD[b];  
  }
  ThinQRfact (m_rr, m_C, m_Cinv, Q, tmp);
  for(int b=0;b<Nblock;b++) D[b]=Q[b];
  std::cout << GridLogMessage<<"BlockCGrQ vec computed initial residual and QR fact " <<std::endl;
  ///////////////////////////////////////
  // Timers
  ///////////////////////////////////////
  GridStopWatch sliceInnerTimer;
  GridStopWatch sliceMaddTimer;
  GridStopWatch QRTimer;
  GridStopWatch MatrixTimer;
  GridStopWatch SolverTimer;
  SolverTimer.Start();
  int k;
  for (k = 1; k <= MaxIterations; k++) {
    //3. Z  = AD
    MatrixTimer.Start();
    for(int b=0;b<Nblock;b++) Linop.HermOp(D[b], Z[b]);      
    MatrixTimer.Stop();
    //4. M  = [D^dag Z]^{-1}
    sliceInnerTimer.Start();
    InnerProductMatrix(m_DZ,D,Z);
    sliceInnerTimer.Stop();
    m_M       = m_DZ.inverse();
    //5. X  = X + D MC
    m_tmp     = m_M * m_C;
    sliceMaddTimer.Start();
    MaddMatrix(X,m_tmp, D,X);     
    sliceMaddTimer.Stop();
    //6. QS = Q - ZM
    sliceMaddTimer.Start();
    MaddMatrix(tmp,m_M,Z,Q,-1.0);
    sliceMaddTimer.Stop();
    QRTimer.Start();
    ThinQRfact (m_rr, m_S, m_Sinv, Q, tmp);
    QRTimer.Stop();
    //7. D  = Q + D S^dag
    m_tmp = m_S.adjoint();
    sliceMaddTimer.Start();
    MaddMatrix(D,m_tmp,D,Q);
    sliceMaddTimer.Stop();
    //8. C  = S C
    m_C = m_S*m_C;
    /*********************
     * convergence monitor
     *********************
     */
    m_rr = m_C.adjoint() * m_C;
    RealD max_resid=0;
    RealD rrsum=0;
    RealD rr;
    for(int b=0;b<Nblock;b++) {
      rrsum+=real(m_rr(b,b));
      rr = real(m_rr(b,b))/ssq[b];
      if ( rr > max_resid ) max_resid = rr;
    }
    std::cout << GridLogIterative << "\t Block Iteration "<<k<<" ave resid "<< std::sqrt(rrsum/sssum) << " max "<< std::sqrt(max_resid) <<std::endl;
    if ( max_resid < Tolerance*Tolerance ) { 
      SolverTimer.Stop();
      std::cout << GridLogMessage<<"BlockCGrQ converged in "<<k<<" iterations"<<std::endl;
      for(int b=0;b<Nblock;b++){
 	std::cout << GridLogMessage<< "\t\tblock "<<b<<" computed resid "<< std::sqrt(real(m_rr(b,b))/ssq[b])<<std::endl;
      }
      std::cout << GridLogMessage<<"\tMax residual is "<<std::sqrt(max_resid)<<std::endl;
      for(int b=0;b<Nblock;b++) Linop.HermOp(X[b], AD[b]);
      for(int b=0;b<Nblock;b++) AD[b] = AD[b]-B[b];
      TrueResidual = std::sqrt(normv(AD)/normv(B));
      std::cout << GridLogMessage << "\tTrue residual is " << TrueResidual <<std::endl;
      std::cout << GridLogMessage << "Time Breakdown "<<std::endl;
      std::cout << GridLogMessage << "\tElapsed    " << SolverTimer.Elapsed()     <<std::endl;
      std::cout << GridLogMessage << "\tMatrix     " << MatrixTimer.Elapsed()     <<std::endl;
      std::cout << GridLogMessage << "\tInnerProd  " << sliceInnerTimer.Elapsed() <<std::endl;
      std::cout << GridLogMessage << "\tMaddMatrix " << sliceMaddTimer.Elapsed()  <<std::endl;
      std::cout << GridLogMessage << "\tThinQRfact " << QRTimer.Elapsed()  <<std::endl;
      IterationsToComplete = k;
      return;
    }
  }
  std::cout << GridLogMessage << "BlockConjugateGradient(rQ) did NOT converge" << std::endl;
  if (ErrorOnNoConverge) assert(0);
  IterationsToComplete = k;
 }
 };
-}
+NAMESPACE_END(Grid);
-#endif
+
--- a/Grid/algorithms/iterative/CommunicationAvoidingGeneralisedMinimalResidual.h
+++ b/Grid/algorithms/iterative/CommunicationAvoidingGeneralisedMinimalResidual.h
@@ -0,0 +1,248 @@
 /*************************************************************************************
 Grid physics library, www.github.com/paboyle/Grid
 Source file: ./lib/algorithms/iterative/CommunicationAvoidingGeneralisedMinimalResidual.h
 Copyright (C) 2015
 Author: Daniel Richtmann <daniel.richtmann@ur.de>
 This program is free software; you can redistribute it and/or modify
 it under the terms of the GNU General Public License as published by
 the Free Software Foundation; either version 2 of the License, or
 (at your option) any later version.
 This program is distributed in the hope that it will be useful,
 but WITHOUT ANY WARRANTY; without even the implied warranty of
 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 GNU General Public License for more details.
 You should have received a copy of the GNU General Public License along
 with this program; if not, write to the Free Software Foundation, Inc.,
 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
 See the full license in the file "LICENSE" in the top level distribution
 directory
 *************************************************************************************/
 /*  END LEGAL */
 #ifndef GRID_COMMUNICATION_AVOIDING_GENERALISED_MINIMAL_RESIDUAL_H
 #define GRID_COMMUNICATION_AVOIDING_GENERALISED_MINIMAL_RESIDUAL_H
 namespace Grid {
 template<class Field>
 class CommunicationAvoidingGeneralisedMinimalResidual : public OperatorFunction<Field> {
 public:
  using OperatorFunction<Field>::operator();
  bool ErrorOnNoConverge; // Throw an assert when CAGMRES fails to converge,
                          // defaults to true
  RealD   Tolerance;
  Integer MaxIterations;
  Integer RestartLength;
  Integer MaxNumberOfRestarts;
  Integer IterationCount; // Number of iterations the CAGMRES took to finish,
                          // filled in upon completion
  GridStopWatch MatrixTimer;
  GridStopWatch LinalgTimer;
  GridStopWatch QrTimer;
  GridStopWatch CompSolutionTimer;
  Eigen::MatrixXcd H;
  std::vector<ComplexD> y;
  std::vector<ComplexD> gamma;
  std::vector<ComplexD> c;
  std::vector<ComplexD> s;
  CommunicationAvoidingGeneralisedMinimalResidual(RealD   tol,
                                                  Integer maxit,
                                                  Integer restart_length,
                                                  bool    err_on_no_conv = true)
      : Tolerance(tol)
      , MaxIterations(maxit)
      , RestartLength(restart_length)
      , MaxNumberOfRestarts(MaxIterations/RestartLength + ((MaxIterations%RestartLength == 0) ? 0 : 1))
      , ErrorOnNoConverge(err_on_no_conv)
      , H(Eigen::MatrixXcd::Zero(RestartLength, RestartLength + 1)) // sizes taken from DD-αAMG code base
      , y(RestartLength + 1, 0.)
      , gamma(RestartLength + 1, 0.)
      , c(RestartLength + 1, 0.)
      , s(RestartLength + 1, 0.) {};
  void operator()(LinearOperatorBase<Field> &LinOp, const Field &src, Field &psi) {
    std::cout << GridLogWarning << "This algorithm currently doesn't differ from regular GMRES" << std::endl;
    psi.Checkerboard() = src.Checkerboard();
    conformable(psi, src);
    RealD guess = norm2(psi);
    assert(std::isnan(guess) == 0);
    RealD cp;
    RealD ssq = norm2(src);
    RealD rsq = Tolerance * Tolerance * ssq;
    Field r(src.Grid());
    std::cout << std::setprecision(4) << std::scientific;
    std::cout << GridLogIterative << "CommunicationAvoidingGeneralisedMinimalResidual: guess " << guess << std::endl;
    std::cout << GridLogIterative << "CommunicationAvoidingGeneralisedMinimalResidual:   src " << ssq   << std::endl;
    MatrixTimer.Reset();
    LinalgTimer.Reset();
    QrTimer.Reset();
    CompSolutionTimer.Reset();
    GridStopWatch SolverTimer;
    SolverTimer.Start();
    IterationCount = 0;
    for (int k=0; k<MaxNumberOfRestarts; k++) {
      cp = outerLoopBody(LinOp, src, psi, rsq);
      // Stopping condition
      if (cp <= rsq) {
        SolverTimer.Stop();
        LinOp.Op(psi,r);
        axpy(r,-1.0,src,r);
        RealD srcnorm       = sqrt(ssq);
        RealD resnorm       = sqrt(norm2(r));
        RealD true_residual = resnorm / srcnorm;
        std::cout << GridLogMessage        << "CommunicationAvoidingGeneralisedMinimalResidual: Converged on iteration " << IterationCount
                  << " computed residual " << sqrt(cp / ssq)
                  << " true residual "     << true_residual
                  << " target "            << Tolerance << std::endl;
        std::cout << GridLogMessage << "CAGMRES Time elapsed: Total   " <<       SolverTimer.Elapsed() << std::endl;
        std::cout << GridLogMessage << "CAGMRES Time elapsed: Matrix  " <<       MatrixTimer.Elapsed() << std::endl;
        std::cout << GridLogMessage << "CAGMRES Time elapsed: Linalg  " <<       LinalgTimer.Elapsed() << std::endl;
        std::cout << GridLogMessage << "CAGMRES Time elapsed: QR      " <<           QrTimer.Elapsed() << std::endl;
        std::cout << GridLogMessage << "CAGMRES Time elapsed: CompSol " << CompSolutionTimer.Elapsed() << std::endl;
        return;
      }
    }
    std::cout << GridLogMessage << "CommunicationAvoidingGeneralisedMinimalResidual did NOT converge" << std::endl;
    if (ErrorOnNoConverge)
      assert(0);
  }
  RealD outerLoopBody(LinearOperatorBase<Field> &LinOp, const Field &src, Field &psi, RealD rsq) {
    RealD cp = 0;
    Field w(src.Grid());
    Field r(src.Grid());
    // this should probably be made a class member so that it is only allocated once, not in every restart
    std::vector<Field> v(RestartLength + 1, src.Grid()); for (auto &elem : v) elem = Zero();
    MatrixTimer.Start();
    LinOp.Op(psi, w);
    MatrixTimer.Stop();
    LinalgTimer.Start();
    r = src - w;
    gamma[0] = sqrt(norm2(r));
    ComplexD scale = 1.0/gamma[0];
    v[0] = scale * r;
    LinalgTimer.Stop();
    for (int i=0; i<RestartLength; i++) {
      IterationCount++;
      arnoldiStep(LinOp, v, w, i);
      qrUpdate(i);
      cp = norm(gamma[i+1]);
      std::cout << GridLogIterative << "CommunicationAvoidingGeneralisedMinimalResidual: Iteration " << IterationCount
                << " residual " << cp << " target " << rsq << std::endl;
      if ((i == RestartLength - 1) || (IterationCount == MaxIterations) || (cp <= rsq)) {
        computeSolution(v, psi, i);
        return cp;
      }
    }
    assert(0); // Never reached
    return cp;
  }
  void arnoldiStep(LinearOperatorBase<Field> &LinOp, std::vector<Field> &v, Field &w, int iter) {
    MatrixTimer.Start();
    LinOp.Op(v[iter], w);
    MatrixTimer.Stop();
    LinalgTimer.Start();
    for (int i = 0; i <= iter; ++i) {
      H(iter, i) = innerProduct(v[i], w);
      w = w - ComplexD(H(iter, i)) * v[i];
    }
    H(iter, iter + 1) = sqrt(norm2(w));
    v[iter + 1] = ComplexD(1. / H(iter, iter + 1)) * w;
    LinalgTimer.Stop();
  }
  void qrUpdate(int iter) {
    QrTimer.Start();
    for (int i = 0; i < iter ; ++i) {
      auto tmp       = -s[i] * ComplexD(H(iter, i)) + c[i] * ComplexD(H(iter, i + 1));
      H(iter, i)     = conjugate(c[i]) * ComplexD(H(iter, i)) + conjugate(s[i]) * ComplexD(H(iter, i + 1));
      H(iter, i + 1) = tmp;
    }
    // Compute new Givens Rotation
    auto nu     = sqrt(std::norm(H(iter, iter)) + std::norm(H(iter, iter + 1)));
    c[iter]     = H(iter, iter) / nu;
    s[iter]     = H(iter, iter + 1) / nu;
    // Apply new Givens rotation
    H(iter, iter)     = nu;
    H(iter, iter + 1) = 0.;
    gamma[iter + 1] = -s[iter] * gamma[iter];
    gamma[iter]     = conjugate(c[iter]) * gamma[iter];
    QrTimer.Stop();
  }
  void computeSolution(std::vector<Field> const &v, Field &psi, int iter) {
    CompSolutionTimer.Start();
    for (int i = iter; i >= 0; i--) {
      y[i] = gamma[i];
      for (int k = i + 1; k <= iter; k++)
        y[i] = y[i] - ComplexD(H(k, i)) * y[k];
      y[i] = y[i] / ComplexD(H(i, i));
    }
    for (int i = 0; i <= iter; i++)
      psi = psi + v[i] * y[i];
    CompSolutionTimer.Stop();
  }
 };
 }
 #endif
--- a/Grid/algorithms/iterative/ConjugateGradient.h
+++ b/Grid/algorithms/iterative/ConjugateGradient.h
@@ -27,11 +27,11 @@ with this program; if not, write to the Free Software Foundation, Inc.,
 See the full license in the file "LICENSE" in the top level distribution
 directory
 *************************************************************************************/
-/*  END LEGAL */
+			   /*  END LEGAL */
 #ifndef GRID_CONJUGATE_GRADIENT_H
 #define GRID_CONJUGATE_GRADIENT_H
-namespace Grid {
+NAMESPACE_BEGIN(Grid);
 /////////////////////////////////////////////////////////////
 // Base classes for iterative processes based on operators
@@ -40,25 +40,31 @@ namespace Grid {
 template <class Field>
 class ConjugateGradient : public OperatorFunction<Field> {
- public:
+public:
  using OperatorFunction<Field>::operator();
  bool ErrorOnNoConverge;  // throw an assert when the CG fails to converge.
                           // Defaults true.
  RealD Tolerance;
  Integer MaxIterations;
  Integer IterationsToComplete; //Number of iterations the CG took to finish. Filled in upon completion
  RealD TrueResidual;
  ConjugateGradient(RealD tol, Integer maxit, bool err_on_no_conv = true)
-      : Tolerance(tol),
+    : Tolerance(tol),
-        MaxIterations(maxit),
+      MaxIterations(maxit),
-        ErrorOnNoConverge(err_on_no_conv){};
+      ErrorOnNoConverge(err_on_no_conv){};
  void operator()(LinearOperatorBase<Field> &Linop, const Field &src, Field &psi) {
    GRID_TRACE("ConjugateGradient");
    psi.Checkerboard() = src.Checkerboard();
    psi.checkerboard = src.checkerboard;
    conformable(psi, src);
-    RealD cp, c, a, d, b, ssq, qq, b_pred;
+    RealD cp, c, a, d, b, ssq, qq;
    //RealD b_pred;
    Field p(src);
    Field mmp(src);
@@ -67,10 +73,9 @@ class ConjugateGradient : public OperatorFunction<Field> {
    // Initial residual computation & set up
    RealD guess = norm2(psi);
    assert(std::isnan(guess) == 0);
    Linop.HermOpAndNorm(psi, mmp, d, b);
-
+    
    r = src - mmp;
    p = r;
@@ -78,6 +83,14 @@ class ConjugateGradient : public OperatorFunction<Field> {
    cp = a;
    ssq = norm2(src);
    // Handle trivial case of zero src
    if (ssq == 0.){
      psi = Zero();
      IterationsToComplete = 1;
      TrueResidual = 0.;
      return;
    }
    std::cout << GridLogIterative << std::setprecision(8) << "ConjugateGradient: guess " << guess << std::endl;
    std::cout << GridLogIterative << std::setprecision(8) << "ConjugateGradient:   src " << ssq << std::endl;
    std::cout << GridLogIterative << std::setprecision(8) << "ConjugateGradient:    mp " << d << std::endl;
@@ -89,6 +102,9 @@ class ConjugateGradient : public OperatorFunction<Field> {
    // Check if guess is really REALLY good :)
    if (cp <= rsq) {
      TrueResidual = std::sqrt(a/ssq);
      std::cout << GridLogMessage << "ConjugateGradient guess is converged already " << std::endl;
      IterationsToComplete = 0;	
      return;
    }
@@ -102,9 +118,13 @@ class ConjugateGradient : public OperatorFunction<Field> {
    GridStopWatch MatrixTimer;
    GridStopWatch SolverTimer;
    RealD usecs = -usecond();
    SolverTimer.Start();
    int k;
-    for (k = 1; k <= MaxIterations*1000; k++) {
+    for (k = 1; k <= MaxIterations; k++) {
      GridStopWatch IterationTimer;
      IterationTimer.Start();
      c = cp;
      MatrixTimer.Start();
@@ -125,30 +145,43 @@ class ConjugateGradient : public OperatorFunction<Field> {
      b = cp / c;
      LinearCombTimer.Start();
-      parallel_for(int ss=0;ss<src._grid->oSites();ss++){
+      {
-	vstream(psi[ss], a      *  p[ss] + psi[ss]);
+	autoView( psi_v , psi, AcceleratorWrite);
-	vstream(p  [ss], b      *  p[ss] + r[ss]);
+	autoView( p_v   , p,   AcceleratorWrite);
 	autoView( r_v   , r,   AcceleratorWrite);
 	accelerator_for(ss,p_v.size(), Field::vector_object::Nsimd(),{
 	    coalescedWrite(psi_v[ss], a      *  p_v(ss) + psi_v(ss));
 	    coalescedWrite(p_v[ss]  , b      *  p_v(ss) + r_v  (ss));
 	});
      }
      LinearCombTimer.Stop();
      LinalgTimer.Stop();
-      std::cout << GridLogIterative << "ConjugateGradient: Iteration " << k
+      IterationTimer.Stop();
-                << " residual " << cp << " target " << rsq << std::endl;
+      if ( (k % 500) == 0 ) {
 	std::cout << GridLogMessage << "ConjugateGradient: Iteration " << k
                << " residual " << sqrt(cp/ssq) << " target " << Tolerance << std::endl;
      } else { 
 	std::cout << GridLogIterative << "ConjugateGradient: Iteration " << k
 		  << " residual " << sqrt(cp/ssq) << " target " << Tolerance << " took " << IterationTimer.Elapsed() << std::endl;
      }
      // Stopping condition
      if (cp <= rsq) {
 	usecs +=usecond();
        SolverTimer.Stop();
        Linop.HermOpAndNorm(psi, mmp, d, qq);
        p = mmp - src;
-
+	GridBase *grid = src.Grid();
-        RealD srcnorm = sqrt(norm2(src));
+	RealD DwfFlops = (1452. )*grid->gSites()*4*k
-        RealD resnorm = sqrt(norm2(p));
+   	               + (8+4+8+4+4)*12*grid->gSites()*k; // CG linear algebra
        RealD srcnorm = std::sqrt(norm2(src));
        RealD resnorm = std::sqrt(norm2(p));
        RealD true_residual = resnorm / srcnorm;
-
+        std::cout << GridLogMessage << "ConjugateGradient Converged on iteration " << k 
-        std::cout << GridLogMessage << "ConjugateGradient Converged on iteration " << k << std::endl;
+		  << "\tComputed residual " << std::sqrt(cp / ssq)
-        std::cout << GridLogMessage << "\tComputed residual " << sqrt(cp / ssq)<<std::endl;
+		  << "\tTrue residual " << true_residual
-	std::cout << GridLogMessage << "\tTrue residual " << true_residual<<std::endl;
+		  << "\tTarget " << Tolerance << std::endl;
 	std::cout << GridLogMessage << "\tTarget " << Tolerance << std::endl;
        std::cout << GridLogMessage << "Time breakdown "<<std::endl;
 	std::cout << GridLogMessage << "\tElapsed    " << SolverTimer.Elapsed() <<std::endl;
@@ -158,20 +191,28 @@ class ConjugateGradient : public OperatorFunction<Field> {
 	std::cout << GridLogMessage << "\tAxpyNorm   " << AxpyNormTimer.Elapsed() <<std::endl;
 	std::cout << GridLogMessage << "\tLinearComb " << LinearCombTimer.Elapsed() <<std::endl;
 	std::cout << GridLogDebug << "\tMobius flop rate " << DwfFlops/ usecs<< " Gflops " <<std::endl;
        if (ErrorOnNoConverge) assert(true_residual / Tolerance < 10000.0);
 	IterationsToComplete = k;	
 	TrueResidual = true_residual;
        return;
      }
    }
-    std::cout << GridLogMessage << "ConjugateGradient did NOT converge"
+    // Failed. Calculate true residual before giving up                                                         
-              << std::endl;
+    Linop.HermOpAndNorm(psi, mmp, d, qq);
    p = mmp - src;
    TrueResidual = sqrt(norm2(p)/ssq);
    std::cout << GridLogMessage << "ConjugateGradient did NOT converge "<<k<<" / "<< MaxIterations<< std::endl;
    if (ErrorOnNoConverge) assert(0);
    IterationsToComplete = k;
  }
 };
-}
+NAMESPACE_END(Grid);
 #endif
--- a/Grid/algorithms/iterative/ConjugateGradientMixedPrec.h
+++ b/Grid/algorithms/iterative/ConjugateGradientMixedPrec.h
@@ -0,0 +1,170 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./lib/algorithms/iterative/ConjugateGradientMixedPrec.h
    Copyright (C) 2015
 Author: Christopher Kelly <ckelly@phys.columbia.edu>
    This program is free software; you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation; either version 2 of the License, or
    (at your option) any later version.
    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.
    You should have received a copy of the GNU General Public License along
    with this program; if not, write to the Free Software Foundation, Inc.,
    51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
    See the full license in the file "LICENSE" in the top level distribution directory
 *************************************************************************************/
 /*  END LEGAL */
 #ifndef GRID_CONJUGATE_GRADIENT_MIXED_PREC_H
 #define GRID_CONJUGATE_GRADIENT_MIXED_PREC_H
 NAMESPACE_BEGIN(Grid);
  //Mixed precision restarted defect correction CG
  template<class FieldD,class FieldF, 
    typename std::enable_if< getPrecision<FieldD>::value == 2, int>::type = 0,
    typename std::enable_if< getPrecision<FieldF>::value == 1, int>::type = 0> 
  class MixedPrecisionConjugateGradient : public LinearFunction<FieldD> {
  public:
    using LinearFunction<FieldD>::operator();
    RealD   Tolerance;
    RealD   InnerTolerance; //Initial tolerance for inner CG. Defaults to Tolerance but can be changed
    Integer MaxInnerIterations;
    Integer MaxOuterIterations;
    GridBase* SinglePrecGrid; //Grid for single-precision fields
    RealD OuterLoopNormMult; //Stop the outer loop and move to a final double prec solve when the residual is OuterLoopNormMult * Tolerance
    LinearOperatorBase<FieldF> &Linop_f;
    LinearOperatorBase<FieldD> &Linop_d;
    Integer TotalInnerIterations; //Number of inner CG iterations
    Integer TotalOuterIterations; //Number of restarts
    Integer TotalFinalStepIterations; //Number of CG iterations in final patch-up step
    RealD TrueResidual;
    //Option to speed up *inner single precision* solves using a LinearFunction that produces a guess
    LinearFunction<FieldF> *guesser;
    MixedPrecisionConjugateGradient(RealD tol, 
 				    Integer maxinnerit, 
 				    Integer maxouterit, 
 				    GridBase* _sp_grid, 
 				    LinearOperatorBase<FieldF> &_Linop_f, 
 				    LinearOperatorBase<FieldD> &_Linop_d) :
      Linop_f(_Linop_f), Linop_d(_Linop_d),
      Tolerance(tol), InnerTolerance(tol), MaxInnerIterations(maxinnerit), MaxOuterIterations(maxouterit), SinglePrecGrid(_sp_grid),
      OuterLoopNormMult(100.), guesser(NULL){ };
    void useGuesser(LinearFunction<FieldF> &g){
      guesser = &g;
    }
  void operator() (const FieldD &src_d_in, FieldD &sol_d){
    std::cout << GridLogMessage << "MixedPrecisionConjugateGradient: Starting mixed precision CG with outer tolerance " << Tolerance << " and inner tolerance " << InnerTolerance << std::endl;
    TotalInnerIterations = 0;
    GridStopWatch TotalTimer;
    TotalTimer.Start();
    int cb = src_d_in.Checkerboard();
    sol_d.Checkerboard() = cb;
    RealD src_norm = norm2(src_d_in);
    RealD stop = src_norm * Tolerance*Tolerance;
    GridBase* DoublePrecGrid = src_d_in.Grid();
    FieldD tmp_d(DoublePrecGrid);
    tmp_d.Checkerboard() = cb;
    FieldD tmp2_d(DoublePrecGrid);
    tmp2_d.Checkerboard() = cb;
    FieldD src_d(DoublePrecGrid);
    src_d = src_d_in; //source for next inner iteration, computed from residual during operation
    RealD inner_tol = InnerTolerance;
    FieldF src_f(SinglePrecGrid);
    src_f.Checkerboard() = cb;
    FieldF sol_f(SinglePrecGrid);
    sol_f.Checkerboard() = cb;
    std::cout<<GridLogMessage<<"MixedPrecisionConjugateGradient: Starting initial inner CG with tolerance " << inner_tol << std::endl;
    ConjugateGradient<FieldF> CG_f(inner_tol, MaxInnerIterations);
    CG_f.ErrorOnNoConverge = false;
    GridStopWatch InnerCGtimer;
    GridStopWatch PrecChangeTimer;
    Integer &outer_iter = TotalOuterIterations; //so it will be equal to the final iteration count
    precisionChangeWorkspace pc_wk_sp_to_dp(DoublePrecGrid, SinglePrecGrid);
    precisionChangeWorkspace pc_wk_dp_to_sp(SinglePrecGrid, DoublePrecGrid);
    for(outer_iter = 0; outer_iter < MaxOuterIterations; outer_iter++){
      //Compute double precision rsd and also new RHS vector.
      Linop_d.HermOp(sol_d, tmp_d);
      RealD norm = axpy_norm(src_d, -1., tmp_d, src_d_in); //src_d is residual vector
      std::cout<<GridLogMessage<<"MixedPrecisionConjugateGradient: Outer iteration " <<outer_iter<<" residual "<< norm<< " target "<< stop<<std::endl;
      if(norm < OuterLoopNormMult * stop){
 	std::cout<<GridLogMessage<<"MixedPrecisionConjugateGradient: Outer iteration converged on iteration " <<outer_iter <<std::endl;
 	break;
      }
      while(norm * inner_tol * inner_tol < stop) inner_tol *= 2;  // inner_tol = sqrt(stop/norm) ??
      PrecChangeTimer.Start();
      precisionChange(src_f, src_d, pc_wk_dp_to_sp);
      PrecChangeTimer.Stop();
      sol_f = Zero();
      //Optionally improve inner solver guess (eg using known eigenvectors)
      if(guesser != NULL)
 	(*guesser)(src_f, sol_f);
      //Inner CG
      std::cout<<GridLogMessage<<"MixedPrecisionConjugateGradient: Outer iteration " << outer_iter << " starting inner CG with tolerance " << inner_tol << std::endl;
      CG_f.Tolerance = inner_tol;
      InnerCGtimer.Start();
      CG_f(Linop_f, src_f, sol_f);
      InnerCGtimer.Stop();
      TotalInnerIterations += CG_f.IterationsToComplete;
      //Convert sol back to double and add to double prec solution
      PrecChangeTimer.Start();
      precisionChange(tmp_d, sol_f, pc_wk_sp_to_dp);
      PrecChangeTimer.Stop();
      axpy(sol_d, 1.0, tmp_d, sol_d);
    }
    //Final trial CG
    std::cout<<GridLogMessage<<"MixedPrecisionConjugateGradient: Starting final patch-up double-precision solve"<<std::endl;
    ConjugateGradient<FieldD> CG_d(Tolerance, MaxInnerIterations);
    CG_d(Linop_d, src_d_in, sol_d);
    TotalFinalStepIterations = CG_d.IterationsToComplete;
    TrueResidual = CG_d.TrueResidual;
    TotalTimer.Stop();
    std::cout<<GridLogMessage<<"MixedPrecisionConjugateGradient: Inner CG iterations " << TotalInnerIterations << " Restarts " << TotalOuterIterations << " Final CG iterations " << TotalFinalStepIterations << std::endl;
    std::cout<<GridLogMessage<<"MixedPrecisionConjugateGradient: Total time " << TotalTimer.Elapsed() << " Precision change " << PrecChangeTimer.Elapsed() << " Inner CG total " << InnerCGtimer.Elapsed() << std::endl;
  }
 };
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/algorithms/iterative/ConjugateGradientMixedPrecBatched.h
+++ b/Grid/algorithms/iterative/ConjugateGradientMixedPrecBatched.h
@@ -0,0 +1,213 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./lib/algorithms/iterative/ConjugateGradientMixedPrecBatched.h
    Copyright (C) 2015
    Author: Raoul Hodgson <raoul.hodgson@ed.ac.uk>
    This program is free software; you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation; either version 2 of the License, or
    (at your option) any later version.
    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.
    You should have received a copy of the GNU General Public License along
    with this program; if not, write to the Free Software Foundation, Inc.,
    51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
    See the full license in the file "LICENSE" in the top level distribution directory
 *************************************************************************************/
 /*  END LEGAL */
 #ifndef GRID_CONJUGATE_GRADIENT_MIXED_PREC_BATCHED_H
 #define GRID_CONJUGATE_GRADIENT_MIXED_PREC_BATCHED_H
 NAMESPACE_BEGIN(Grid);
 //Mixed precision restarted defect correction CG
 template<class FieldD,class FieldF, 
  typename std::enable_if< getPrecision<FieldD>::value == 2, int>::type = 0,
  typename std::enable_if< getPrecision<FieldF>::value == 1, int>::type = 0> 
 class MixedPrecisionConjugateGradientBatched : public LinearFunction<FieldD> {
 public:
  using LinearFunction<FieldD>::operator();
  RealD   Tolerance;
  RealD   InnerTolerance; //Initial tolerance for inner CG. Defaults to Tolerance but can be changed
  Integer MaxInnerIterations;
  Integer MaxOuterIterations;
  Integer MaxPatchupIterations;
  GridBase* SinglePrecGrid; //Grid for single-precision fields
  RealD OuterLoopNormMult; //Stop the outer loop and move to a final double prec solve when the residual is OuterLoopNormMult * Tolerance
  LinearOperatorBase<FieldF> &Linop_f;
  LinearOperatorBase<FieldD> &Linop_d;
  //Option to speed up *inner single precision* solves using a LinearFunction that produces a guess
  LinearFunction<FieldF> *guesser;
  bool updateResidual;
  MixedPrecisionConjugateGradientBatched(RealD tol, 
          Integer maxinnerit, 
          Integer maxouterit, 
          Integer maxpatchit,
          GridBase* _sp_grid, 
          LinearOperatorBase<FieldF> &_Linop_f, 
          LinearOperatorBase<FieldD> &_Linop_d,
          bool _updateResidual=true) :
    Linop_f(_Linop_f), Linop_d(_Linop_d),
    Tolerance(tol), InnerTolerance(tol), MaxInnerIterations(maxinnerit), MaxOuterIterations(maxouterit), MaxPatchupIterations(maxpatchit), SinglePrecGrid(_sp_grid),
    OuterLoopNormMult(100.), guesser(NULL), updateResidual(_updateResidual) { };
  void useGuesser(LinearFunction<FieldF> &g){
    guesser = &g;
  }
  void operator() (const FieldD &src_d_in, FieldD &sol_d){
    std::vector<FieldD> srcs_d_in{src_d_in};
    std::vector<FieldD> sols_d{sol_d};
    (*this)(srcs_d_in,sols_d);
    sol_d = sols_d[0];
  }
  void operator() (const std::vector<FieldD> &src_d_in, std::vector<FieldD> &sol_d){
    assert(src_d_in.size() == sol_d.size());
    int NBatch = src_d_in.size();
    std::cout << GridLogMessage << "NBatch = " << NBatch << std::endl;
    Integer TotalOuterIterations = 0; //Number of restarts
    std::vector<Integer> TotalInnerIterations(NBatch,0);     //Number of inner CG iterations
    std::vector<Integer> TotalFinalStepIterations(NBatch,0); //Number of CG iterations in final patch-up step
    GridStopWatch TotalTimer;
    TotalTimer.Start();
    GridStopWatch InnerCGtimer;
    GridStopWatch PrecChangeTimer;
    int cb = src_d_in[0].Checkerboard();
    std::vector<RealD> src_norm;
    std::vector<RealD> norm;
    std::vector<RealD> stop;
    GridBase* DoublePrecGrid = src_d_in[0].Grid();
    FieldD tmp_d(DoublePrecGrid);
    tmp_d.Checkerboard() = cb;
    FieldD tmp2_d(DoublePrecGrid);
    tmp2_d.Checkerboard() = cb;
    std::vector<FieldD> src_d;
    std::vector<FieldF> src_f;
    std::vector<FieldF> sol_f;
    for (int i=0; i<NBatch; i++) {
      sol_d[i].Checkerboard() = cb;
      src_norm.push_back(norm2(src_d_in[i]));
      norm.push_back(0.);
      stop.push_back(src_norm[i] * Tolerance*Tolerance);
      src_d.push_back(src_d_in[i]); //source for next inner iteration, computed from residual during operation
      src_f.push_back(SinglePrecGrid);
      src_f[i].Checkerboard() = cb;
      sol_f.push_back(SinglePrecGrid);
      sol_f[i].Checkerboard() = cb;
    }
    RealD inner_tol = InnerTolerance;
    ConjugateGradient<FieldF> CG_f(inner_tol, MaxInnerIterations);
    CG_f.ErrorOnNoConverge = false;
    Integer &outer_iter = TotalOuterIterations; //so it will be equal to the final iteration count
    for(outer_iter = 0; outer_iter < MaxOuterIterations; outer_iter++){
      std::cout << GridLogMessage << std::endl;
      std::cout << GridLogMessage << "Outer iteration " << outer_iter << std::endl;
      bool allConverged = true;
      for (int i=0; i<NBatch; i++) {
        //Compute double precision rsd and also new RHS vector.
        Linop_d.HermOp(sol_d[i], tmp_d);
        norm[i] = axpy_norm(src_d[i], -1., tmp_d, src_d_in[i]); //src_d is residual vector
        std::cout<<GridLogMessage<<"MixedPrecisionConjugateGradientBatched: Outer iteration " << outer_iter <<" solve " << i << " residual "<< norm[i] << " target "<< stop[i] <<std::endl;
        PrecChangeTimer.Start();
        precisionChange(src_f[i], src_d[i]);
        PrecChangeTimer.Stop();
        sol_f[i] = Zero();
        if(norm[i] > OuterLoopNormMult * stop[i]) {
          allConverged = false;
        }
      }
      if (allConverged) break;
      if (updateResidual) {
        RealD normMax = *std::max_element(std::begin(norm), std::end(norm));
        RealD stopMax = *std::max_element(std::begin(stop), std::end(stop));
        while( normMax * inner_tol * inner_tol < stopMax) inner_tol *= 2;  // inner_tol = sqrt(stop/norm) ??
        CG_f.Tolerance = inner_tol;
      }
      //Optionally improve inner solver guess (eg using known eigenvectors)
      if(guesser != NULL) {
        (*guesser)(src_f, sol_f);
      }
      for (int i=0; i<NBatch; i++) {
        //Inner CG
        InnerCGtimer.Start();
        CG_f(Linop_f, src_f[i], sol_f[i]);
        InnerCGtimer.Stop();
        TotalInnerIterations[i] += CG_f.IterationsToComplete;
        //Convert sol back to double and add to double prec solution
        PrecChangeTimer.Start();
        precisionChange(tmp_d, sol_f[i]);
        PrecChangeTimer.Stop();
        axpy(sol_d[i], 1.0, tmp_d, sol_d[i]);
      }
    }
    //Final trial CG
    std::cout << GridLogMessage << std::endl;
    std::cout<<GridLogMessage<<"MixedPrecisionConjugateGradientBatched: Starting final patch-up double-precision solve"<<std::endl;
    for (int i=0; i<NBatch; i++) {
      ConjugateGradient<FieldD> CG_d(Tolerance, MaxPatchupIterations);
      CG_d(Linop_d, src_d_in[i], sol_d[i]);
      TotalFinalStepIterations[i] += CG_d.IterationsToComplete;
    }
    TotalTimer.Stop();
    std::cout << GridLogMessage << std::endl;
    for (int i=0; i<NBatch; i++) {
      std::cout<<GridLogMessage<<"MixedPrecisionConjugateGradientBatched: solve " << i << " Inner CG iterations " << TotalInnerIterations[i] << " Restarts " << TotalOuterIterations << " Final CG iterations " << TotalFinalStepIterations[i] << std::endl;
    }
    std::cout << GridLogMessage << std::endl;
    std::cout<<GridLogMessage<<"MixedPrecisionConjugateGradientBatched: Total time " << TotalTimer.Elapsed() << " Precision change " << PrecChangeTimer.Elapsed() << " Inner CG total " << InnerCGtimer.Elapsed() << std::endl;
  }
 };
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/algorithms/iterative/ConjugateGradientMultiShift.h
+++ b/Grid/algorithms/iterative/ConjugateGradientMultiShift.h
@@ -0,0 +1,346 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./lib/algorithms/iterative/ConjugateGradientMultiShift.h
    Copyright (C) 2015
 Author: Azusa Yamaguchi <ayamaguc@staffmail.ed.ac.uk>
 Author: Peter Boyle <paboyle@ph.ed.ac.uk>
    This program is free software; you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation; either version 2 of the License, or
    (at your option) any later version.
    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.
    You should have received a copy of the GNU General Public License along
    with this program; if not, write to the Free Software Foundation, Inc.,
    51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
    See the full license in the file "LICENSE" in the top level distribution directory
 *************************************************************************************/
 /*  END LEGAL */
 #ifndef GRID_CONJUGATE_MULTI_SHIFT_GRADIENT_H
 #define GRID_CONJUGATE_MULTI_SHIFT_GRADIENT_H
 NAMESPACE_BEGIN(Grid);
 /////////////////////////////////////////////////////////////
 // Base classes for iterative processes based on operators
 // single input vec, single output vec.
 /////////////////////////////////////////////////////////////
 template<class Field> 
 class ConjugateGradientMultiShift : public OperatorMultiFunction<Field>,
 				    public OperatorFunction<Field>
 {
 public:                                                
  using OperatorFunction<Field>::operator();
  //  RealD   Tolerance;
  Integer MaxIterations;
  Integer IterationsToComplete; //Number of iterations the CG took to finish. Filled in upon completion
  std::vector<int> IterationsToCompleteShift;  // Iterations for this shift
  int verbose;
  MultiShiftFunction shifts;
  std::vector<RealD> TrueResidualShift;
  ConjugateGradientMultiShift(Integer maxit, const MultiShiftFunction &_shifts) : 
    MaxIterations(maxit),
    shifts(_shifts)
  { 
    verbose=1;
    IterationsToCompleteShift.resize(_shifts.order);
    TrueResidualShift.resize(_shifts.order);
  }
  void operator() (LinearOperatorBase<Field> &Linop, const Field &src, Field &psi)
  {
    GridBase *grid = src.Grid();
    int nshift = shifts.order;
    std::vector<Field> results(nshift,grid);
    (*this)(Linop,src,results,psi);
  }
  void operator() (LinearOperatorBase<Field> &Linop, const Field &src, std::vector<Field> &results, Field &psi)
  {
    int nshift = shifts.order;
    (*this)(Linop,src,results);
    psi = shifts.norm*src;
    for(int i=0;i<nshift;i++){
      psi = psi + shifts.residues[i]*results[i];
    }
    return;
  }
  void operator() (LinearOperatorBase<Field> &Linop, const Field &src, std::vector<Field> &psi)
  {
    GRID_TRACE("ConjugateGradientMultiShift");
    GridBase *grid = src.Grid();
    ////////////////////////////////////////////////////////////////////////
    // Convenience references to the info stored in "MultiShiftFunction"
    ////////////////////////////////////////////////////////////////////////
    int nshift = shifts.order;
    std::vector<RealD> &mass(shifts.poles); // Make references to array in "shifts"
    std::vector<RealD> &mresidual(shifts.tolerances);
    std::vector<RealD> alpha(nshift,1.0);
    std::vector<Field>   ps(nshift,grid);// Search directions
    assert(psi.size()==nshift);
    assert(mass.size()==nshift);
    assert(mresidual.size()==nshift);
    // dynamic sized arrays on stack; 2d is a pain with vector
    RealD  bs[nshift];
    RealD  rsq[nshift];
    RealD  z[nshift][2];
    int     converged[nshift];
    const int       primary =0;
    //Primary shift fields CG iteration
    RealD a,b,c,d;
    RealD cp,bp,qq; //prev
    // Matrix mult fields
    Field r(grid);
    Field p(grid);
    Field tmp(grid);
    Field mmp(grid);
    // Check lightest mass
    for(int s=0;s<nshift;s++){
      assert( mass[s]>= mass[primary] );
      converged[s]=0;
    }
    // Wire guess to zero
    // Residuals "r" are src
    // First search direction "p" is also src
    cp = norm2(src);
    // Handle trivial case of zero src.
    if( cp == 0. ){
      for(int s=0;s<nshift;s++){
 	psi[s] = Zero();
 	IterationsToCompleteShift[s] = 1;
 	TrueResidualShift[s] = 0.;
      }
      return;
    }
    for(int s=0;s<nshift;s++){
      rsq[s] = cp * mresidual[s] * mresidual[s];
      std::cout<<GridLogMessage<<"ConjugateGradientMultiShift: shift "<<s
 	       <<" target resid "<<rsq[s]<<std::endl;
      ps[s] = src;
    }
    // r and p for primary
    r=src;
    p=src;
    //MdagM+m[0]
    Linop.HermOpAndNorm(p,mmp,d,qq);
    axpy(mmp,mass[0],p,mmp);
    RealD rn = norm2(p);
    d += rn*mass[0];
    // have verified that inner product of 
    // p and mmp is equal to d after this since
    // the d computation is tricky
    //  qq = real(innerProduct(p,mmp));
    //  std::cout<<GridLogMessage << "debug equal ?  qq "<<qq<<" d "<< d<<std::endl;
    b = -cp /d;
    // Set up the various shift variables
    int       iz=0;
    z[0][1-iz] = 1.0;
    z[0][iz]   = 1.0;
    bs[0]      = b;
    for(int s=1;s<nshift;s++){
      z[s][1-iz] = 1.0;
      z[s][iz]   = 1.0/( 1.0 - b*(mass[s]-mass[0]));
      bs[s]      = b*z[s][iz]; 
    }
    // r += b[0] A.p[0]
    // c= norm(r)
    c=axpy_norm(r,b,mmp,r);
    for(int s=0;s<nshift;s++) {
      axpby(psi[s],0.,-bs[s]*alpha[s],src,src);
    }
    std::cout << GridLogIterative << "ConjugateGradientMultiShift: initial rn (|src|^2) =" << rn << " qq (|MdagM src|^2) =" << qq << " d ( dot(src, [MdagM + m_0]src) ) =" << d << " c=" << c << std::endl;
  ///////////////////////////////////////
  // Timers
  ///////////////////////////////////////
  GridStopWatch AXPYTimer;
  GridStopWatch ShiftTimer;
  GridStopWatch QRTimer;
  GridStopWatch MatrixTimer;
  GridStopWatch SolverTimer;
  SolverTimer.Start();
    // Iteration loop
    int k;
    for (k=1;k<=MaxIterations;k++){
      a = c /cp;
    AXPYTimer.Start();
      axpy(p,a,p,r);
    AXPYTimer.Stop();
      // Note to self - direction ps is iterated seperately
      // for each shift. Does not appear to have any scope
      // for avoiding linear algebra in "single" case.
      // 
      // However SAME r is used. Could load "r" and update
      // ALL ps[s]. 2/3 Bandwidth saving
      // New Kernel: Load r, vector of coeffs, vector of pointers ps
    AXPYTimer.Start();
      for(int s=0;s<nshift;s++){
 	if ( ! converged[s] ) { 
 	  if (s==0){
 	    axpy(ps[s],a,ps[s],r);
 	  } else{
 	    RealD as =a *z[s][iz]*bs[s] /(z[s][1-iz]*b);
 	    axpby(ps[s],z[s][iz],as,r,ps[s]);
 	  }
 	}
      }
    AXPYTimer.Stop();
      cp=c;
    MatrixTimer.Start();  
    //Linop.HermOpAndNorm(p,mmp,d,qq); // d is used
    // The below is faster on KNL
    Linop.HermOp(p,mmp); 
    d=real(innerProduct(p,mmp));
    MatrixTimer.Stop();  
    AXPYTimer.Start();
      axpy(mmp,mass[0],p,mmp);
    AXPYTimer.Stop();
      RealD rn = norm2(p);
      d += rn*mass[0];
      bp=b;
      b=-cp/d;
    AXPYTimer.Start();
      c=axpy_norm(r,b,mmp,r);
    AXPYTimer.Stop();
      // Toggle the recurrence history
      bs[0] = b;
      iz = 1-iz;
    ShiftTimer.Start();
      for(int s=1;s<nshift;s++){
 	if((!converged[s])){
 	  RealD z0 = z[s][1-iz];
 	  RealD z1 = z[s][iz];
 	  z[s][iz] = z0*z1*bp
 	    / (b*a*(z1-z0) + z1*bp*(1- (mass[s]-mass[0])*b)); 
 	  bs[s] = b*z[s][iz]/z0; // NB sign  rel to Mike
 	}
      }
    ShiftTimer.Stop();
      for(int s=0;s<nshift;s++){
 	int ss = s;
 	// Scope for optimisation here in case of "single".
 	// Could load psi[0] and pull all ps[s] in.
 	//      if ( single ) ss=primary;
 	// Bandwith saving in single case is Ls * 3 -> 2+Ls, so ~ 3x saving
 	// Pipelined CG gain:
 	//
 	// New Kernel: Load r, vector of coeffs, vector of pointers ps
 	// New Kernel: Load psi[0], vector of coeffs, vector of pointers ps
 	// If can predict the coefficient bs then we can fuse these and avoid write reread cyce
 	//  on ps[s].
 	// Before:  3 x npole  + 3 x npole
 	// After :  2 x npole (ps[s])        => 3x speed up of multishift CG.
 	if( (!converged[s]) ) { 
 	  axpy(psi[ss],-bs[s]*alpha[s],ps[s],psi[ss]);
 	}
      }
      // Convergence checks
      int all_converged = 1;
      for(int s=0;s<nshift;s++){
 	if ( (!converged[s]) ){
 	  IterationsToCompleteShift[s] = k;
 	  RealD css  = c * z[s][iz]* z[s][iz];
 	  if(css<rsq[s]){
 	    if ( ! converged[s] )
 	      std::cout<<GridLogMessage<<"ConjugateGradientMultiShift k="<<k<<" Shift "<<s<<" has converged"<<std::endl;
 	    converged[s]=1;
 	  } else {
 	    all_converged=0;
 	  }
 	}
      }
      if ( all_converged ){
    SolverTimer.Stop();
 	std::cout<<GridLogMessage<< "CGMultiShift: All shifts have converged iteration "<<k<<std::endl;
 	std::cout<<GridLogMessage<< "CGMultiShift: Checking solutions"<<std::endl;
 	// Check answers 
 	for(int s=0; s < nshift; s++) { 
 	  Linop.HermOpAndNorm(psi[s],mmp,d,qq);
 	  axpy(tmp,mass[s],psi[s],mmp);
 	  axpy(r,-alpha[s],src,tmp);
 	  RealD rn = norm2(r);
 	  RealD cn = norm2(src);
 	  TrueResidualShift[s] = std::sqrt(rn/cn);
 	  std::cout<<GridLogMessage<<"CGMultiShift: shift["<<s<<"] true residual "<< TrueResidualShift[s] <<std::endl;
 	}
      std::cout << GridLogMessage << "Time Breakdown "<<std::endl;
      std::cout << GridLogMessage << "\tElapsed    " << SolverTimer.Elapsed()     <<std::endl;
      std::cout << GridLogMessage << "\tAXPY     " << AXPYTimer.Elapsed()     <<std::endl;
      std::cout << GridLogMessage << "\tMatrix   " << MatrixTimer.Elapsed()     <<std::endl;
      std::cout << GridLogMessage << "\tShift    " << ShiftTimer.Elapsed()     <<std::endl;
      IterationsToComplete = k;	
 	return;
      }
    }
    // ugly hack
    std::cout<<GridLogMessage<<"CG multi shift did not converge"<<std::endl;
    //  assert(0);
  }
 };
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/algorithms/iterative/ConjugateGradientMultiShiftCleanup.h
+++ b/Grid/algorithms/iterative/ConjugateGradientMultiShiftCleanup.h
@@ -0,0 +1,373 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./lib/algorithms/iterative/ConjugateGradientMultiShift.h
    Copyright (C) 2015
 Author: Azusa Yamaguchi <ayamaguc@staffmail.ed.ac.uk>
 Author: Peter Boyle <paboyle@ph.ed.ac.uk>
 Author: Christopher Kelly <ckelly@bnl.gov>
    This program is free software; you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation; either version 2 of the License, or
    (at your option) any later version.
    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.
    You should have received a copy of the GNU General Public License along
    with this program; if not, write to the Free Software Foundation, Inc.,
    51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
    See the full license in the file "LICENSE" in the top level distribution directory
 *************************************************************************************/
 /*  END LEGAL */
 #pragma once
 NAMESPACE_BEGIN(Grid);
 //CK 2020: A variant of the multi-shift conjugate gradient with the matrix multiplication in single precision. 
 //The residual is stored in single precision, but the search directions and solution are stored in double precision. 
 //Every update_freq iterations the residual is corrected in double precision. 
 //For safety the a final regular CG is applied to clean up if necessary
 //PB Pure single, then double fixup
 template<class FieldD, class FieldF,
 	 typename std::enable_if< getPrecision<FieldD>::value == 2, int>::type = 0,
 	 typename std::enable_if< getPrecision<FieldF>::value == 1, int>::type = 0> 
 class ConjugateGradientMultiShiftMixedPrecCleanup : public OperatorMultiFunction<FieldD>,
 					     public OperatorFunction<FieldD>
 {
 public:                                                
  using OperatorFunction<FieldD>::operator();
  RealD   Tolerance;
  Integer MaxIterationsMshift;
  Integer MaxIterations;
  Integer IterationsToComplete; //Number of iterations the CG took to finish. Filled in upon completion
  std::vector<int> IterationsToCompleteShift;  // Iterations for this shift
  int verbose;
  MultiShiftFunction shifts;
  std::vector<RealD> TrueResidualShift;
  int ReliableUpdateFreq; //number of iterations between reliable updates
  GridBase* SinglePrecGrid; //Grid for single-precision fields
  LinearOperatorBase<FieldF> &Linop_f; //single precision
  ConjugateGradientMultiShiftMixedPrecCleanup(Integer maxit, const MultiShiftFunction &_shifts,
 				       GridBase* _SinglePrecGrid, LinearOperatorBase<FieldF> &_Linop_f,
 				       int _ReliableUpdateFreq) : 
    MaxIterationsMshift(maxit),  shifts(_shifts), SinglePrecGrid(_SinglePrecGrid), Linop_f(_Linop_f), ReliableUpdateFreq(_ReliableUpdateFreq),
    MaxIterations(20000)
  { 
    verbose=1;
    IterationsToCompleteShift.resize(_shifts.order);
    TrueResidualShift.resize(_shifts.order);
  }
  void operator() (LinearOperatorBase<FieldD> &Linop, const FieldD &src, FieldD &psi)
  {
    GridBase *grid = src.Grid();
    int nshift = shifts.order;
    std::vector<FieldD> results(nshift,grid);
    (*this)(Linop,src,results,psi);
  }
  void operator() (LinearOperatorBase<FieldD> &Linop, const FieldD &src, std::vector<FieldD> &results, FieldD &psi)
  {
    int nshift = shifts.order;
    (*this)(Linop,src,results);
    psi = shifts.norm*src;
    for(int i=0;i<nshift;i++){
      psi = psi + shifts.residues[i]*results[i];
    }
    return;
  }
  void operator() (LinearOperatorBase<FieldD> &Linop_d, const FieldD &src_d, std::vector<FieldD> &psi_d)
  { 
    GRID_TRACE("ConjugateGradientMultiShiftMixedPrecCleanup");
    GridBase *DoublePrecGrid = src_d.Grid();
    ////////////////////////////////////////////////////////////////////////
    // Convenience references to the info stored in "MultiShiftFunction"
    ////////////////////////////////////////////////////////////////////////
    int nshift = shifts.order;
    std::vector<RealD> &mass(shifts.poles); // Make references to array in "shifts"
    std::vector<RealD> &mresidual(shifts.tolerances);
    std::vector<RealD> alpha(nshift,1.0);
    //Double precision search directions
    FieldD p_d(DoublePrecGrid);
    std::vector<FieldF> ps_f (nshift, SinglePrecGrid);// Search directions (single precision)
    std::vector<FieldF> psi_f(nshift, SinglePrecGrid);// solutions (single precision)
    FieldD tmp_d(DoublePrecGrid);
    FieldD r_d(DoublePrecGrid);
    FieldF r_f(SinglePrecGrid);
    FieldD mmp_d(DoublePrecGrid);
    assert(psi_d.size()==nshift);
    assert(mass.size()==nshift);
    assert(mresidual.size()==nshift);
    // dynamic sized arrays on stack; 2d is a pain with vector
    RealD  bs[nshift];
    RealD  rsq[nshift];
    RealD  rsqf[nshift];
    RealD  z[nshift][2];
    int     converged[nshift];
    const int       primary =0;
    //Primary shift fields CG iteration
    RealD a,b,c,d;
    RealD cp,bp,qq; //prev
    // Matrix mult fields
    FieldF p_f(SinglePrecGrid);
    FieldF mmp_f(SinglePrecGrid);
    // Check lightest mass
    for(int s=0;s<nshift;s++){
      assert( mass[s]>= mass[primary] );
      converged[s]=0;
    }
    // Wire guess to zero
    // Residuals "r" are src
    // First search direction "p" is also src
    cp = norm2(src_d);
    // Handle trivial case of zero src.
    if( cp == 0. ){
      for(int s=0;s<nshift;s++){
 	psi_d[s] = Zero();
 	psi_f[s] = Zero();
 	IterationsToCompleteShift[s] = 1;
 	TrueResidualShift[s] = 0.;
      }
      return;
    }
    for(int s=0;s<nshift;s++){
      rsq[s] = cp * mresidual[s] * mresidual[s];
      rsqf[s] =rsq[s];
      std::cout<<GridLogMessage<<"ConjugateGradientMultiShiftMixedPrecCleanup: shift "<< s <<" target resid "<<rsq[s]<<std::endl;
      //      ps_d[s] = src_d;
      precisionChange(ps_f[s],src_d);
    }
    // r and p for primary
    p_d = src_d; //primary copy --- make this a reference to ps_d to save axpys
    r_d = p_d;
    //MdagM+m[0]
    precisionChange(p_f,p_d);
    Linop_f.HermOpAndNorm(p_f,mmp_f,d,qq); // mmp = MdagM p        d=real(dot(p, mmp)),  qq=norm2(mmp)
    precisionChange(tmp_d,mmp_f);
    Linop_d.HermOpAndNorm(p_d,mmp_d,d,qq); // mmp = MdagM p        d=real(dot(p, mmp)),  qq=norm2(mmp)
    tmp_d = tmp_d - mmp_d;
    std::cout << " Testing operators match "<<norm2(mmp_d)<<" f "<<norm2(mmp_f)<<" diff "<< norm2(tmp_d)<<std::endl;
    //    assert(norm2(tmp_d)< 1.0e-4);
    axpy(mmp_d,mass[0],p_d,mmp_d);
    RealD rn = norm2(p_d);
    d += rn*mass[0];
    b = -cp /d;
    // Set up the various shift variables
    int       iz=0;
    z[0][1-iz] = 1.0;
    z[0][iz]   = 1.0;
    bs[0]      = b;
    for(int s=1;s<nshift;s++){
      z[s][1-iz] = 1.0;
      z[s][iz]   = 1.0/( 1.0 - b*(mass[s]-mass[0]));
      bs[s]      = b*z[s][iz]; 
    }
    // r += b[0] A.p[0]
    // c= norm(r)
    c=axpy_norm(r_d,b,mmp_d,r_d);
    for(int s=0;s<nshift;s++) {
      axpby(psi_d[s],0.,-bs[s]*alpha[s],src_d,src_d);
      precisionChange(psi_f[s],psi_d[s]);
    }
    ///////////////////////////////////////
    // Timers
    ///////////////////////////////////////
    GridStopWatch AXPYTimer, ShiftTimer, QRTimer, MatrixTimer, SolverTimer, PrecChangeTimer, CleanupTimer;
    SolverTimer.Start();
    // Iteration loop
    int k;
    for (k=1;k<=MaxIterationsMshift;k++){    
      a = c /cp;
      AXPYTimer.Start();
      axpy(p_d,a,p_d,r_d); 
      AXPYTimer.Stop();
      PrecChangeTimer.Start();
      precisionChange(r_f, r_d);
      PrecChangeTimer.Stop();
      AXPYTimer.Start();
      for(int s=0;s<nshift;s++){
 	if ( ! converged[s] ) { 
 	  if (s==0){
 	    axpy(ps_f[s],a,ps_f[s],r_f);
 	  } else{
 	    RealD as =a *z[s][iz]*bs[s] /(z[s][1-iz]*b);
 	    axpby(ps_f[s],z[s][iz],as,r_f,ps_f[s]);
 	  }
 	}
      }
      AXPYTimer.Stop();
      cp=c;
      PrecChangeTimer.Start();
      precisionChange(p_f, p_d); //get back single prec search direction for linop
      PrecChangeTimer.Stop();
      MatrixTimer.Start();  
      Linop_f.HermOp(p_f,mmp_f);
      MatrixTimer.Stop();  
      PrecChangeTimer.Start();
      precisionChange(mmp_d, mmp_f); // From Float to Double
      PrecChangeTimer.Stop();
      d=real(innerProduct(p_d,mmp_d));    
      axpy(mmp_d,mass[0],p_d,mmp_d);
      RealD rn = norm2(p_d);
      d += rn*mass[0];
      bp=b;
      b=-cp/d;
      // Toggle the recurrence history
      bs[0] = b;
      iz = 1-iz;
      ShiftTimer.Start();
      for(int s=1;s<nshift;s++){
 	if((!converged[s])){
 	  RealD z0 = z[s][1-iz];
 	  RealD z1 = z[s][iz];
 	  z[s][iz] = z0*z1*bp
 	    / (b*a*(z1-z0) + z1*bp*(1- (mass[s]-mass[0])*b)); 
 	  bs[s] = b*z[s][iz]/z0; // NB sign  rel to Mike
 	}
      }
      ShiftTimer.Stop();
      //Update single precision solutions
      AXPYTimer.Start();
      for(int s=0;s<nshift;s++){
 	int ss = s;
 	if( (!converged[s]) ) { 
 	  axpy(psi_f[ss],-bs[s]*alpha[s],ps_f[s],psi_f[ss]);
 	}
      }
      c = axpy_norm(r_d,b,mmp_d,r_d);
      AXPYTimer.Stop();
      // Convergence checks
      int all_converged = 1;
      for(int s=0;s<nshift;s++){
 	if ( (!converged[s]) ){
 	  IterationsToCompleteShift[s] = k;
 	  RealD css  = c * z[s][iz]* z[s][iz];
 	  if(css<rsqf[s]){
 	    if ( ! converged[s] )
 	      std::cout<<GridLogMessage<<"ConjugateGradientMultiShiftMixedPrecCleanup k="<<k<<" Shift "<<s<<" has converged"<<std::endl;
 	    converged[s]=1;
 	  } else {
 	    all_converged=0;
 	  }
 	}
      }
      if ( all_converged || k == MaxIterationsMshift-1){
 	SolverTimer.Stop();
 	for(int s=0;s<nshift;s++){
 	  precisionChange(psi_d[s],psi_f[s]);
 	}
 	if ( all_converged ){
 	  std::cout<<GridLogMessage<< "ConjugateGradientMultiShiftMixedPrecCleanup: All shifts have converged iteration "<<k<<std::endl;
 	  std::cout<<GridLogMessage<< "ConjugateGradientMultiShiftMixedPrecCleanup: Checking solutions"<<std::endl;
 	} else {
 	  std::cout<<GridLogMessage<< "ConjugateGradientMultiShiftMixedPrecCleanup: Not all shifts have converged iteration "<<k<<std::endl;
 	}
 	// Check answers 
 	for(int s=0; s < nshift; s++) { 
 	  Linop_d.HermOpAndNorm(psi_d[s],mmp_d,d,qq);
 	  axpy(tmp_d,mass[s],psi_d[s],mmp_d);
 	  axpy(r_d,-alpha[s],src_d,tmp_d);
 	  RealD rn = norm2(r_d);
 	  RealD cn = norm2(src_d);
 	  TrueResidualShift[s] = std::sqrt(rn/cn);
 	  std::cout<<GridLogMessage<<"ConjugateGradientMultiShiftMixedPrecCleanup: shift["<<s<<"] true residual "<< TrueResidualShift[s] << " target " << mresidual[s] << std::endl;
 	  //If we have not reached the desired tolerance, do a (mixed precision) CG cleanup
 	  if(rn >= rsq[s]){
 	    CleanupTimer.Start();
 	    std::cout<<GridLogMessage<<"ConjugateGradientMultiShiftMixedPrecCleanup: performing cleanup step for shift " << s << std::endl;
 	    //Setup linear operators for final cleanup
 	    ConjugateGradientMultiShiftMixedPrecSupport::ShiftedLinop<FieldD> Linop_shift_d(Linop_d, mass[s]);
 	    ConjugateGradientMultiShiftMixedPrecSupport::ShiftedLinop<FieldF> Linop_shift_f(Linop_f, mass[s]);
 	    MixedPrecisionConjugateGradient<FieldD,FieldF> cg(mresidual[s], MaxIterations, MaxIterations, SinglePrecGrid, Linop_shift_f, Linop_shift_d); 
 	    cg(src_d, psi_d[s]);
 	    TrueResidualShift[s] = cg.TrueResidual;
 	    CleanupTimer.Stop();
 	  }
 	}
 	std::cout << GridLogMessage << "ConjugateGradientMultiShiftMixedPrecCleanup: Time Breakdown for body"<<std::endl;
 	std::cout << GridLogMessage << "\tSolver    " << SolverTimer.Elapsed()     <<std::endl;
 	std::cout << GridLogMessage << "\t\tAXPY    " << AXPYTimer.Elapsed()     <<std::endl;
 	std::cout << GridLogMessage << "\t\tMatrix    " << MatrixTimer.Elapsed()     <<std::endl;
 	std::cout << GridLogMessage << "\t\tShift    " << ShiftTimer.Elapsed()     <<std::endl;
 	std::cout << GridLogMessage << "\t\tPrecision Change " << PrecChangeTimer.Elapsed()     <<std::endl;
 	std::cout << GridLogMessage << "\tFinal Cleanup " << CleanupTimer.Elapsed()     <<std::endl;
 	std::cout << GridLogMessage << "\tSolver+Cleanup " << SolverTimer.Elapsed() + CleanupTimer.Elapsed() << std::endl;
 	IterationsToComplete = k;	
 	return;
      }
    }
    std::cout<<GridLogMessage<<"CG multi shift did not converge"<<std::endl;
    assert(0);
  }
 };
 NAMESPACE_END(Grid);
--- a/Grid/algorithms/iterative/ConjugateGradientMultiShiftMixedPrec.h
+++ b/Grid/algorithms/iterative/ConjugateGradientMultiShiftMixedPrec.h
@@ -0,0 +1,416 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./lib/algorithms/iterative/ConjugateGradientMultiShift.h
    Copyright (C) 2015
 Author: Azusa Yamaguchi <ayamaguc@staffmail.ed.ac.uk>
 Author: Peter Boyle <paboyle@ph.ed.ac.uk>
 Author: Christopher Kelly <ckelly@bnl.gov>
    This program is free software; you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation; either version 2 of the License, or
    (at your option) any later version.
    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.
    You should have received a copy of the GNU General Public License along
    with this program; if not, write to the Free Software Foundation, Inc.,
    51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
    See the full license in the file "LICENSE" in the top level distribution directory
 *************************************************************************************/
 /*  END LEGAL */
 #ifndef GRID_CONJUGATE_GRADIENT_MULTI_SHIFT_MIXEDPREC_H
 #define GRID_CONJUGATE_GRADIENT_MULTI_SHIFT_MIXEDPREC_H
 NAMESPACE_BEGIN(Grid);
 //CK 2020: A variant of the multi-shift conjugate gradient with the matrix multiplication in single precision. 
 //The residual is stored in single precision, but the search directions and solution are stored in double precision. 
 //Every update_freq iterations the residual is corrected in double precision. 
 //For safety the a final regular CG is applied to clean up if necessary
 //Linop to add shift to input linop, used in cleanup CG
 namespace ConjugateGradientMultiShiftMixedPrecSupport{
 template<typename Field>
 class ShiftedLinop: public LinearOperatorBase<Field>{
 public:
  LinearOperatorBase<Field> &linop_base;
  RealD shift;
  ShiftedLinop(LinearOperatorBase<Field> &_linop_base, RealD _shift): linop_base(_linop_base), shift(_shift){}
  void OpDiag (const Field &in, Field &out){ assert(0); }
  void OpDir  (const Field &in, Field &out,int dir,int disp){ assert(0); }
  void OpDirAll  (const Field &in, std::vector<Field> &out){ assert(0); }
  void Op     (const Field &in, Field &out){ assert(0); }
  void AdjOp  (const Field &in, Field &out){ assert(0); }
  void HermOp(const Field &in, Field &out){
    linop_base.HermOp(in, out);
    axpy(out, shift, in, out);
  }    
  void HermOpAndNorm(const Field &in, Field &out,RealD &n1,RealD &n2){
    HermOp(in,out);
    ComplexD dot = innerProduct(in,out);
    n1=real(dot);
    n2=norm2(out);
  }
 };
 };
 template<class FieldD, class FieldF,
 	 typename std::enable_if< getPrecision<FieldD>::value == 2, int>::type = 0,
 	 typename std::enable_if< getPrecision<FieldF>::value == 1, int>::type = 0> 
 class ConjugateGradientMultiShiftMixedPrec : public OperatorMultiFunction<FieldD>,
 					     public OperatorFunction<FieldD>
 {
 public:                                                
  using OperatorFunction<FieldD>::operator();
  RealD   Tolerance;
  Integer MaxIterationsMshift;
  Integer MaxIterations;
  Integer IterationsToComplete; //Number of iterations the CG took to finish. Filled in upon completion
  std::vector<int> IterationsToCompleteShift;  // Iterations for this shift
  int verbose;
  MultiShiftFunction shifts;
  std::vector<RealD> TrueResidualShift;
  int ReliableUpdateFreq; //number of iterations between reliable updates
  GridBase* SinglePrecGrid; //Grid for single-precision fields
  LinearOperatorBase<FieldF> &Linop_f; //single precision
  ConjugateGradientMultiShiftMixedPrec(Integer maxit, const MultiShiftFunction &_shifts,
 				       GridBase* _SinglePrecGrid, LinearOperatorBase<FieldF> &_Linop_f,
 				       int _ReliableUpdateFreq) : 
    MaxIterationsMshift(maxit),  shifts(_shifts), SinglePrecGrid(_SinglePrecGrid), Linop_f(_Linop_f), ReliableUpdateFreq(_ReliableUpdateFreq),
    MaxIterations(20000)
  { 
    verbose=1;
    IterationsToCompleteShift.resize(_shifts.order);
    TrueResidualShift.resize(_shifts.order);
  }
  void operator() (LinearOperatorBase<FieldD> &Linop, const FieldD &src, FieldD &psi)
  {
    GridBase *grid = src.Grid();
    int nshift = shifts.order;
    std::vector<FieldD> results(nshift,grid);
    (*this)(Linop,src,results,psi);
  }
  void operator() (LinearOperatorBase<FieldD> &Linop, const FieldD &src, std::vector<FieldD> &results, FieldD &psi)
  {
    int nshift = shifts.order;
    (*this)(Linop,src,results);
    psi = shifts.norm*src;
    for(int i=0;i<nshift;i++){
      psi = psi + shifts.residues[i]*results[i];
    }
    return;
  }
  void operator() (LinearOperatorBase<FieldD> &Linop_d, const FieldD &src_d, std::vector<FieldD> &psi_d)
  { 
    GRID_TRACE("ConjugateGradientMultiShiftMixedPrec");
    GridBase *DoublePrecGrid = src_d.Grid();
    precisionChangeWorkspace pc_wk_s_to_d(DoublePrecGrid,SinglePrecGrid);
    precisionChangeWorkspace pc_wk_d_to_s(SinglePrecGrid,DoublePrecGrid);
    ////////////////////////////////////////////////////////////////////////
    // Convenience references to the info stored in "MultiShiftFunction"
    ////////////////////////////////////////////////////////////////////////
    int nshift = shifts.order;
    std::vector<RealD> &mass(shifts.poles); // Make references to array in "shifts"
    std::vector<RealD> &mresidual(shifts.tolerances);
    std::vector<RealD> alpha(nshift,1.0);
    //Double precision search directions
    FieldD p_d(DoublePrecGrid);
    std::vector<FieldD> ps_d(nshift, DoublePrecGrid);// Search directions (double precision)
    FieldD tmp_d(DoublePrecGrid);
    FieldD r_d(DoublePrecGrid);
    FieldD mmp_d(DoublePrecGrid);
    assert(psi_d.size()==nshift);
    assert(mass.size()==nshift);
    assert(mresidual.size()==nshift);
    // dynamic sized arrays on stack; 2d is a pain with vector
    RealD  bs[nshift];
    RealD  rsq[nshift];
    RealD  rsqf[nshift];
    RealD  z[nshift][2];
    int     converged[nshift];
    const int       primary =0;
    //Primary shift fields CG iteration
    RealD a,b,c,d;
    RealD cp,bp,qq; //prev
    // Matrix mult fields
    FieldF p_f(SinglePrecGrid);
    FieldF mmp_f(SinglePrecGrid);
    // Check lightest mass
    for(int s=0;s<nshift;s++){
      assert( mass[s]>= mass[primary] );
      converged[s]=0;
    }
    // Wire guess to zero
    // Residuals "r" are src
    // First search direction "p" is also src
    cp = norm2(src_d);
    // Handle trivial case of zero src.
    if( cp == 0. ){
      for(int s=0;s<nshift;s++){
 	psi_d[s] = Zero();
 	IterationsToCompleteShift[s] = 1;
 	TrueResidualShift[s] = 0.;
      }
      return;
    }
    for(int s=0;s<nshift;s++){
      rsq[s] = cp * mresidual[s] * mresidual[s];
      rsqf[s] =rsq[s];
      std::cout<<GridLogMessage<<"ConjugateGradientMultiShiftMixedPrec: shift "<< s <<" target resid "<<rsq[s]<<std::endl;
      ps_d[s] = src_d;
    }
    // r and p for primary
    p_d = src_d; //primary copy --- make this a reference to ps_d to save axpys
    r_d = p_d;
    //MdagM+m[0]
    precisionChange(p_f, p_d, pc_wk_d_to_s);
    Linop_f.HermOpAndNorm(p_f,mmp_f,d,qq); // mmp = MdagM p        d=real(dot(p, mmp)),  qq=norm2(mmp)
    precisionChange(tmp_d, mmp_f, pc_wk_s_to_d);
    Linop_d.HermOpAndNorm(p_d,mmp_d,d,qq); // mmp = MdagM p        d=real(dot(p, mmp)),  qq=norm2(mmp)
    tmp_d = tmp_d - mmp_d;
    std::cout << " Testing operators match "<<norm2(mmp_d)<<" f "<<norm2(mmp_f)<<" diff "<< norm2(tmp_d)<<std::endl;
    assert(norm2(tmp_d)< 1.0);
    axpy(mmp_d,mass[0],p_d,mmp_d);
    RealD rn = norm2(p_d);
    d += rn*mass[0];
    b = -cp /d;
    // Set up the various shift variables
    int       iz=0;
    z[0][1-iz] = 1.0;
    z[0][iz]   = 1.0;
    bs[0]      = b;
    for(int s=1;s<nshift;s++){
      z[s][1-iz] = 1.0;
      z[s][iz]   = 1.0/( 1.0 - b*(mass[s]-mass[0]));
      bs[s]      = b*z[s][iz]; 
    }
    // r += b[0] A.p[0]
    // c= norm(r)
    c=axpy_norm(r_d,b,mmp_d,r_d);
    for(int s=0;s<nshift;s++) {
      axpby(psi_d[s],0.,-bs[s]*alpha[s],src_d,src_d);
    }
    ///////////////////////////////////////
    // Timers
    ///////////////////////////////////////
    GridStopWatch AXPYTimer, ShiftTimer, QRTimer, MatrixTimer, SolverTimer, PrecChangeTimer, CleanupTimer;
    SolverTimer.Start();
    // Iteration loop
    int k;
    for (k=1;k<=MaxIterationsMshift;k++){    
      a = c /cp;
      AXPYTimer.Start();
      axpy(p_d,a,p_d,r_d); 
      for(int s=0;s<nshift;s++){
 	if ( ! converged[s] ) { 
 	  if (s==0){
 	    axpy(ps_d[s],a,ps_d[s],r_d);
 	  } else{
 	    RealD as =a *z[s][iz]*bs[s] /(z[s][1-iz]*b);
 	    axpby(ps_d[s],z[s][iz],as,r_d,ps_d[s]);
 	  }
 	}
      }
      AXPYTimer.Stop();
      PrecChangeTimer.Start();
      precisionChange(p_f, p_d, pc_wk_d_to_s); //get back single prec search direction for linop
      PrecChangeTimer.Stop();
      cp=c;
      MatrixTimer.Start();  
      Linop_f.HermOp(p_f,mmp_f);
      MatrixTimer.Stop();  
      PrecChangeTimer.Start();
      precisionChange(mmp_d, mmp_f, pc_wk_s_to_d); // From Float to Double
      PrecChangeTimer.Stop();
      AXPYTimer.Start();
      d=real(innerProduct(p_d,mmp_d));    
      axpy(mmp_d,mass[0],p_d,mmp_d);
      AXPYTimer.Stop();
      RealD rn = norm2(p_d);
      d += rn*mass[0];
      bp=b;
      b=-cp/d;
      // Toggle the recurrence history
      bs[0] = b;
      iz = 1-iz;
      ShiftTimer.Start();
      for(int s=1;s<nshift;s++){
 	if((!converged[s])){
 	  RealD z0 = z[s][1-iz];
 	  RealD z1 = z[s][iz];
 	  z[s][iz] = z0*z1*bp
 	    / (b*a*(z1-z0) + z1*bp*(1- (mass[s]-mass[0])*b)); 
 	  bs[s] = b*z[s][iz]/z0; // NB sign  rel to Mike
 	}
      }
      ShiftTimer.Stop();
      //Update double precision solutions
      AXPYTimer.Start();
      for(int s=0;s<nshift;s++){
 	int ss = s;
 	if( (!converged[s]) ) { 
 	  axpy(psi_d[ss],-bs[s]*alpha[s],ps_d[s],psi_d[ss]);
 	}
      }
      //Perform reliable update if necessary; otherwise update residual from single-prec mmp
      c = axpy_norm(r_d,b,mmp_d,r_d);
      AXPYTimer.Stop();
      if(k % ReliableUpdateFreq == 0){
 	RealD c_old = c;
 	//Replace r with true residual
 	MatrixTimer.Start();  
 	Linop_d.HermOp(psi_d[0],mmp_d); 
 	MatrixTimer.Stop();  
 	AXPYTimer.Start();
 	axpy(mmp_d,mass[0],psi_d[0],mmp_d);
 	c = axpy_norm(r_d, -1.0, mmp_d, src_d);
 	AXPYTimer.Stop();
 	std::cout<<GridLogMessage<<"ConjugateGradientMultiShiftMixedPrec k="<<k<< ", replaced |r|^2 = "<<c_old <<" with |r|^2 = "<<c<<std::endl;
      }
      // Convergence checks
      int all_converged = 1;
      for(int s=0;s<nshift;s++){
 	if ( (!converged[s]) ){
 	  IterationsToCompleteShift[s] = k;
 	  RealD css  = c * z[s][iz]* z[s][iz];
 	  if(css<rsqf[s]){
 	    if ( ! converged[s] )
 	      std::cout<<GridLogMessage<<"ConjugateGradientMultiShiftMixedPrec k="<<k<<" Shift "<<s<<" has converged"<<std::endl;
 	    converged[s]=1;
 	  } else {
 	    all_converged=0;
 	  }
 	}
      }
      if ( all_converged || k == MaxIterationsMshift-1){
 	SolverTimer.Stop();
 	if ( all_converged ){
 	  std::cout<<GridLogMessage<< "ConjugateGradientMultiShiftMixedPrec: All shifts have converged iteration "<<k<<std::endl;
 	  std::cout<<GridLogMessage<< "ConjugateGradientMultiShiftMixedPrec: Checking solutions"<<std::endl;
 	} else {
 	  std::cout<<GridLogMessage<< "ConjugateGradientMultiShiftMixedPrec: Not all shifts have converged iteration "<<k<<std::endl;
 	}
 	// Check answers 
 	for(int s=0; s < nshift; s++) { 
 	  Linop_d.HermOpAndNorm(psi_d[s],mmp_d,d,qq);
 	  axpy(tmp_d,mass[s],psi_d[s],mmp_d);
 	  axpy(r_d,-alpha[s],src_d,tmp_d);
 	  RealD rn = norm2(r_d);
 	  RealD cn = norm2(src_d);
 	  TrueResidualShift[s] = std::sqrt(rn/cn);
 	  std::cout<<GridLogMessage<<"ConjugateGradientMultiShiftMixedPrec: shift["<<s<<"] true residual "<< TrueResidualShift[s] << " target " << mresidual[s] << std::endl;
 	  //If we have not reached the desired tolerance, do a (mixed precision) CG cleanup
 	  if(rn >= rsq[s]){
 	    CleanupTimer.Start();
 	    std::cout<<GridLogMessage<<"ConjugateGradientMultiShiftMixedPrec: performing cleanup step for shift " << s << std::endl;
 	    //Setup linear operators for final cleanup
 	    ConjugateGradientMultiShiftMixedPrecSupport::ShiftedLinop<FieldD> Linop_shift_d(Linop_d, mass[s]);
 	    ConjugateGradientMultiShiftMixedPrecSupport::ShiftedLinop<FieldF> Linop_shift_f(Linop_f, mass[s]);
 	    MixedPrecisionConjugateGradient<FieldD,FieldF> cg(mresidual[s], MaxIterations, MaxIterations, SinglePrecGrid, Linop_shift_f, Linop_shift_d); 
 	    cg(src_d, psi_d[s]);
 	    TrueResidualShift[s] = cg.TrueResidual;
 	    CleanupTimer.Stop();
 	  }
 	}
 	std::cout << GridLogMessage << "ConjugateGradientMultiShiftMixedPrec: Time Breakdown for body"<<std::endl;
 	std::cout << GridLogMessage << "\tSolver    " << SolverTimer.Elapsed()     <<std::endl;
 	std::cout << GridLogMessage << "\t\tAXPY    " << AXPYTimer.Elapsed()     <<std::endl;
 	std::cout << GridLogMessage << "\t\tMatrix    " << MatrixTimer.Elapsed()     <<std::endl;
 	std::cout << GridLogMessage << "\t\tShift    " << ShiftTimer.Elapsed()     <<std::endl;
 	std::cout << GridLogMessage << "\t\tPrecision Change " << PrecChangeTimer.Elapsed()     <<std::endl;
 	std::cout << GridLogMessage << "\tFinal Cleanup " << CleanupTimer.Elapsed()     <<std::endl;
 	std::cout << GridLogMessage << "\tSolver+Cleanup " << SolverTimer.Elapsed() + CleanupTimer.Elapsed() << std::endl;
 	IterationsToComplete = k;	
 	return;
      }
    }
    std::cout<<GridLogMessage<<"CG multi shift did not converge"<<std::endl;
    assert(0);
  }
 };
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/algorithms/iterative/ConjugateGradientReliableUpdate.h
+++ b/Grid/algorithms/iterative/ConjugateGradientReliableUpdate.h
@@ -0,0 +1,277 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./lib/algorithms/iterative/ConjugateGradientReliableUpdate.h
    Copyright (C) 2015
 Author: Christopher Kelly <ckelly@phys.columbia.edu>
    This program is free software; you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation; either version 2 of the License, or
    (at your option) any later version.
    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.
    You should have received a copy of the GNU General Public License along
    with this program; if not, write to the Free Software Foundation, Inc.,
    51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
    See the full license in the file "LICENSE" in the top level distribution directory
 *************************************************************************************/
 /*  END LEGAL */
 #ifndef GRID_CONJUGATE_GRADIENT_RELIABLE_UPDATE_H
 #define GRID_CONJUGATE_GRADIENT_RELIABLE_UPDATE_H
 NAMESPACE_BEGIN(Grid);
 template<class FieldD,class FieldF, 
 	 typename std::enable_if< getPrecision<FieldD>::value == 2, int>::type = 0,
 	 typename std::enable_if< getPrecision<FieldF>::value == 1, int>::type = 0> 
 class ConjugateGradientReliableUpdate : public LinearFunction<FieldD> {
 public:
  bool ErrorOnNoConverge;  // throw an assert when the CG fails to converge.
  // Defaults true.
  RealD Tolerance;
  Integer MaxIterations;
  Integer IterationsToComplete; //Number of iterations the CG took to finish. Filled in upon completion
  Integer ReliableUpdatesPerformed;
  bool DoFinalCleanup; //Final DP cleanup, defaults to true
  Integer IterationsToCleanup; //Final DP cleanup step iterations
  LinearOperatorBase<FieldF> &Linop_f;
  LinearOperatorBase<FieldD> &Linop_d;
  GridBase* SinglePrecGrid;
  RealD Delta; //reliable update parameter. A reliable update is performed when the residual drops by a factor of Delta relative to its value at the last update
  //Optional ability to switch to a different linear operator once the tolerance reaches a certain point. Useful for single/half -> single/single
  LinearOperatorBase<FieldF> *Linop_fallback;
  RealD fallback_transition_tol;
  ConjugateGradientReliableUpdate(RealD tol, Integer maxit, RealD _delta, GridBase* _sp_grid, LinearOperatorBase<FieldF> &_Linop_f, LinearOperatorBase<FieldD> &_Linop_d, bool err_on_no_conv = true)
    : Tolerance(tol),
      MaxIterations(maxit),
      Delta(_delta),
      Linop_f(_Linop_f),
      Linop_d(_Linop_d),
      SinglePrecGrid(_sp_grid),
      ErrorOnNoConverge(err_on_no_conv),
      DoFinalCleanup(true),
      Linop_fallback(NULL)
  {
    assert(Delta > 0. && Delta < 1. && "Expect  0 < Delta < 1");
  };
  void setFallbackLinop(LinearOperatorBase<FieldF> &_Linop_fallback, const RealD _fallback_transition_tol){
    Linop_fallback = &_Linop_fallback;
    fallback_transition_tol = _fallback_transition_tol;      
  }
  void operator()(const FieldD &src, FieldD &psi) {
    GRID_TRACE("ConjugateGradientReliableUpdate");
    LinearOperatorBase<FieldF> *Linop_f_use = &Linop_f;
    bool using_fallback = false;
    psi.Checkerboard() = src.Checkerboard();
    conformable(psi, src);
    RealD cp, c, a, d, b, ssq, qq, b_pred;
    FieldD p(src);
    FieldD mmp(src);
    FieldD r(src);
    // Initial residual computation & set up
    RealD guess = norm2(psi);
    assert(std::isnan(guess) == 0);
    Linop_d.HermOpAndNorm(psi, mmp, d, b);
    r = src - mmp;
    p = r;
    a = norm2(p);
    cp = a;
    ssq = norm2(src);
    std::cout << GridLogIterative << std::setprecision(4) << "ConjugateGradientReliableUpdate: guess " << guess << std::endl;
    std::cout << GridLogIterative << std::setprecision(4) << "ConjugateGradientReliableUpdate:   src " << ssq << std::endl;
    std::cout << GridLogIterative << std::setprecision(4) << "ConjugateGradientReliableUpdate:    mp " << d << std::endl;
    std::cout << GridLogIterative << std::setprecision(4) << "ConjugateGradientReliableUpdate:   mmp " << b << std::endl;
    std::cout << GridLogIterative << std::setprecision(4) << "ConjugateGradientReliableUpdate:  cp,r " << cp << std::endl;
    std::cout << GridLogIterative << std::setprecision(4) << "ConjugateGradientReliableUpdate:     p " << a << std::endl;
    RealD rsq = Tolerance * Tolerance * ssq;
    // Check if guess is really REALLY good :)
    if (cp <= rsq) {
      std::cout << GridLogMessage << "ConjugateGradientReliableUpdate guess was REALLY good\n";
      std::cout << GridLogMessage << "\tComputed residual " << std::sqrt(cp / ssq)<<std::endl;
      return;
    }
    //Single prec initialization
    precisionChangeWorkspace pc_wk_sp_to_dp(src.Grid(), SinglePrecGrid);
    precisionChangeWorkspace pc_wk_dp_to_sp(SinglePrecGrid, src.Grid());
    FieldF r_f(SinglePrecGrid);
    r_f.Checkerboard() = r.Checkerboard();
    precisionChange(r_f, r, pc_wk_dp_to_sp);
    FieldF psi_f(r_f);
    psi_f = Zero();
    FieldF p_f(r_f);
    FieldF mmp_f(r_f);
    RealD MaxResidSinceLastRelUp = cp; //initial residual    
    std::cout << GridLogIterative << std::setprecision(4)
 	      << "ConjugateGradient: k=0 residual " << cp << " target " << rsq << std::endl;
    GridStopWatch LinalgTimer;
    GridStopWatch MatrixTimer;
    GridStopWatch SolverTimer;
    GridStopWatch PrecChangeTimer;
    SolverTimer.Start();
    int k = 0;
    int l = 0;
    for (k = 1; k <= MaxIterations; k++) {
      c = cp;
      MatrixTimer.Start();
      Linop_f_use->HermOpAndNorm(p_f, mmp_f, d, qq);
      MatrixTimer.Stop();
      LinalgTimer.Start();
      a = c / d;
      b_pred = a * (a * qq - d) / c;
      cp = axpy_norm(r_f, -a, mmp_f, r_f);
      b = cp / c;
      // Fuse these loops ; should be really easy
      psi_f = a * p_f + psi_f;
      //p_f = p_f * b + r_f;
      LinalgTimer.Stop();
      std::cout << GridLogIterative << "ConjugateGradientReliableUpdate: Iteration " << k
 		<< " residual " << cp << " target " << rsq << std::endl;
      std::cout << GridLogDebug << "a = "<< a << " b_pred = "<< b_pred << "  b = "<< b << std::endl;
      std::cout << GridLogDebug << "qq = "<< qq << " d = "<< d << "  c = "<< c << std::endl;
      if(cp > MaxResidSinceLastRelUp){
 	std::cout << GridLogIterative << "ConjugateGradientReliableUpdate: updating MaxResidSinceLastRelUp : " << MaxResidSinceLastRelUp << " -> " << cp << std::endl;
 	MaxResidSinceLastRelUp = cp;
      }
      // Stopping condition
      if (cp <= rsq) {
 	//Although not written in the paper, I assume that I have to add on the final solution
 	PrecChangeTimer.Start();
 	precisionChange(mmp, psi_f, pc_wk_sp_to_dp);
 	PrecChangeTimer.Stop();
 	psi = psi + mmp;
 	SolverTimer.Stop();
 	Linop_d.HermOpAndNorm(psi, mmp, d, qq);
 	p = mmp - src;
 	RealD srcnorm = std::sqrt(norm2(src));
 	RealD resnorm = std::sqrt(norm2(p));
 	RealD true_residual = resnorm / srcnorm;
 	std::cout << GridLogMessage << "ConjugateGradientReliableUpdate Converged on iteration " << k << " after " << l << " reliable updates" << std::endl;
 	std::cout << GridLogMessage << "\tComputed residual " << std::sqrt(cp / ssq)<<std::endl;
 	std::cout << GridLogMessage << "\tTrue residual " << true_residual<<std::endl;
 	std::cout << GridLogMessage << "\tTarget " << Tolerance << std::endl;
 	std::cout << GridLogMessage << "Time breakdown "<<std::endl;
 	std::cout << GridLogMessage << "\tElapsed    " << SolverTimer.Elapsed() <<std::endl;
 	std::cout << GridLogMessage << "\tMatrix     " << MatrixTimer.Elapsed() <<std::endl;
 	std::cout << GridLogMessage << "\tLinalg     " << LinalgTimer.Elapsed() <<std::endl;
 	std::cout << GridLogMessage << "\tPrecChange " << PrecChangeTimer.Elapsed() <<std::endl;
 	std::cout << GridLogMessage << "\tPrecChange avg time " << PrecChangeTimer.Elapsed()/(2*l+1) <<std::endl;
 	IterationsToComplete = k;	
 	ReliableUpdatesPerformed = l;
 	if(DoFinalCleanup){
 	  //Do a final CG to cleanup
 	  std::cout << GridLogMessage << "ConjugateGradientReliableUpdate performing final cleanup.\n";
 	  ConjugateGradient<FieldD> CG(Tolerance,MaxIterations);
 	  CG.ErrorOnNoConverge = ErrorOnNoConverge;
 	  CG(Linop_d,src,psi);
 	  IterationsToCleanup = CG.IterationsToComplete;
 	}
 	else if (ErrorOnNoConverge) assert(true_residual / Tolerance < 10000.0);
 	std::cout << GridLogMessage << "ConjugateGradientReliableUpdate complete.\n";
 	return;
      }
      else if(cp < Delta * MaxResidSinceLastRelUp) { //reliable update
 	std::cout << GridLogMessage << "ConjugateGradientReliableUpdate "
 		  << cp << "(residual) < " << Delta << "(Delta) * " << MaxResidSinceLastRelUp << "(MaxResidSinceLastRelUp) on iteration " << k << " : performing reliable update\n";
 	PrecChangeTimer.Start();
 	precisionChange(mmp, psi_f, pc_wk_sp_to_dp);
 	PrecChangeTimer.Stop();
 	psi = psi + mmp;
 	MatrixTimer.Start();
 	Linop_d.HermOpAndNorm(psi, mmp, d, qq);
 	MatrixTimer.Stop();
 	r = src - mmp;
 	psi_f = Zero();
 	PrecChangeTimer.Start();
 	precisionChange(r_f, r, pc_wk_dp_to_sp);
 	PrecChangeTimer.Stop();
 	cp = norm2(r);
 	MaxResidSinceLastRelUp = cp;
 	b = cp/c;
 	std::cout << GridLogMessage << "ConjugateGradientReliableUpdate new residual " << cp << std::endl;
 	l = l+1;
      }
      p_f = p_f * b + r_f; //update search vector after reliable update appears to help convergence
      if(!using_fallback && Linop_fallback != NULL && cp < fallback_transition_tol){
 	std::cout << GridLogMessage << "ConjugateGradientReliableUpdate switching to fallback linear operator on iteration " << k << " at residual " << cp << std::endl;
 	Linop_f_use = Linop_fallback;
 	using_fallback = true;
      }
    }
    std::cout << GridLogMessage << "ConjugateGradientReliableUpdate did NOT converge"
 	      << std::endl;
    if (ErrorOnNoConverge) assert(0);
    IterationsToComplete = k;
    ReliableUpdatesPerformed = l;      
  }    
 };
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/algorithms/iterative/ConjugateResidual.h
+++ b/Grid/algorithms/iterative/ConjugateResidual.h
@@ -0,0 +1,113 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./lib/algorithms/iterative/ConjugateResidual.h
    Copyright (C) 2015
 Author: Azusa Yamaguchi <ayamaguc@staffmail.ed.ac.uk>
 Author: Peter Boyle <paboyle@ph.ed.ac.uk>
    This program is free software; you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation; either version 2 of the License, or
    (at your option) any later version.
    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.
    You should have received a copy of the GNU General Public License along
    with this program; if not, write to the Free Software Foundation, Inc.,
    51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
    See the full license in the file "LICENSE" in the top level distribution directory
 *************************************************************************************/
 /*  END LEGAL */
 #ifndef GRID_CONJUGATE_RESIDUAL_H
 #define GRID_CONJUGATE_RESIDUAL_H
 NAMESPACE_BEGIN(Grid);
 /////////////////////////////////////////////////////////////
 // Base classes for iterative processes based on operators
 // single input vec, single output vec.
 /////////////////////////////////////////////////////////////
 template<class Field> 
 class ConjugateResidual : public OperatorFunction<Field> {
 public:                                                
  using OperatorFunction<Field>::operator();
  RealD   Tolerance;
  Integer MaxIterations;
  int verbose;
  ConjugateResidual(RealD tol,Integer maxit) : Tolerance(tol), MaxIterations(maxit) { 
    verbose=0;
  };
  void operator() (LinearOperatorBase<Field> &Linop,const Field &src, Field &psi){
    RealD a, b; // c, d;
    RealD cp, ssq,rsq;
    RealD rAr, rAAr, rArp;
    RealD pAp, pAAp;
    GridBase *grid = src.Grid();
    psi=Zero();
    Field r(grid),  p(grid), Ap(grid), Ar(grid);
    r=src;
    p=src;
    Linop.HermOpAndNorm(p,Ap,pAp,pAAp);
    Linop.HermOpAndNorm(r,Ar,rAr,rAAr);
    cp =norm2(r);
    ssq=norm2(src);
    rsq=Tolerance*Tolerance*ssq;
    if (verbose) std::cout<<GridLogMessage<<"ConjugateResidual: iteration " <<0<<" residual "<<cp<< " target"<< rsq<<std::endl;
    for(int k=1;k<MaxIterations;k++){
      a = rAr/pAAp;
      axpy(psi,a,p,psi);
      cp = axpy_norm(r,-a,Ap,r);
      rArp=rAr;
      Linop.HermOpAndNorm(r,Ar,rAr,rAAr);
      b   =rAr/rArp;
      axpy(p,b,p,r);
      pAAp=axpy_norm(Ap,b,Ap,Ar);
      if(verbose) std::cout<<GridLogMessage<<"ConjugateResidual: iteration " <<k<<" residual "<<cp<< " target"<< rsq<<std::endl;
      if(cp<rsq) {
 	Linop.HermOp(psi,Ap);
 	axpy(r,-1.0,src,Ap);
 	RealD true_resid = norm2(r)/ssq;
 	std::cout<<GridLogMessage<<"ConjugateResidual: Converged on iteration " <<k
 		 << " computed residual "<<std::sqrt(cp/ssq)
 		 << " true residual "<<std::sqrt(true_resid)
 		 << " target "       <<Tolerance <<std::endl;
 	return;
      }
    }
    std::cout<<GridLogMessage<<"ConjugateResidual did NOT converge"<<std::endl;
    assert(0);
  }
 };
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/algorithms/iterative/Deflation.h
+++ b/Grid/algorithms/iterative/Deflation.h
@@ -0,0 +1,157 @@
    /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./lib/algorithms/iterative/ImplicitlyRestartedLanczos.h
    Copyright (C) 2015
 Author: Peter Boyle <paboyle@ph.ed.ac.uk>
    This program is free software; you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation; either version 2 of the License, or
    (at your option) any later version.
    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.
    You should have received a copy of the GNU General Public License along
    with this program; if not, write to the Free Software Foundation, Inc.,
    51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
    See the full license in the file "LICENSE" in the top level distribution directory
    *************************************************************************************/
    /*  END LEGAL */
 #ifndef GRID_DEFLATION_H
 #define GRID_DEFLATION_H
 namespace Grid { 
 template<class Field>
 class ZeroGuesser: public LinearFunction<Field> {
 public:
  using LinearFunction<Field>::operator();
    virtual void operator()(const Field &src, Field &guess) { guess = Zero(); };
 };
 template<class Field>
 class DoNothingGuesser: public LinearFunction<Field> {
 public:
  using LinearFunction<Field>::operator();
  virtual void operator()(const Field &src, Field &guess) {  };
 };
 template<class Field>
 class SourceGuesser: public LinearFunction<Field> {
 public:
  using LinearFunction<Field>::operator();
  virtual void operator()(const Field &src, Field &guess) { guess = src; };
 };
 ////////////////////////////////
 // Fine grid deflation
 ////////////////////////////////
 template<class Field>
 class DeflatedGuesser: public LinearFunction<Field> {
 private:
  const std::vector<Field> &evec;
  const std::vector<RealD> &eval;
  const unsigned int       N;
 public:
  using LinearFunction<Field>::operator();
  DeflatedGuesser(const std::vector<Field> & _evec,const std::vector<RealD> & _eval)
  : DeflatedGuesser(_evec, _eval, _evec.size())
  {}
  DeflatedGuesser(const std::vector<Field> & _evec, const std::vector<RealD> & _eval, const unsigned int _N)
  : evec(_evec), eval(_eval), N(_N)
  {
    assert(evec.size()==eval.size());
    assert(N <= evec.size());
  } 
  virtual void operator()(const Field &src,Field &guess) {
    guess = Zero();
    for (int i=0;i<N;i++) {
      const Field& tmp = evec[i];
      axpy(guess,TensorRemove(innerProduct(tmp,src)) / eval[i],tmp,guess);
    }
    guess.Checkerboard() = src.Checkerboard();
  }
 };
 template<class FineField, class CoarseField>
 class LocalCoherenceDeflatedGuesser: public LinearFunction<FineField> {
 private:
  const std::vector<FineField>   &subspace;
  const std::vector<CoarseField> &evec_coarse;
  const std::vector<RealD>       &eval_coarse;
 public:
  using LinearFunction<FineField>::operator();
  LocalCoherenceDeflatedGuesser(const std::vector<FineField>   &_subspace,
 				const std::vector<CoarseField> &_evec_coarse,
 				const std::vector<RealD>       &_eval_coarse)
    : subspace(_subspace), 
      evec_coarse(_evec_coarse), 
      eval_coarse(_eval_coarse)  
  {
  }
  void operator()(const FineField &src,FineField &guess) { 
    int N = (int)evec_coarse.size();
    CoarseField src_coarse(evec_coarse[0].Grid());
    CoarseField guess_coarse(evec_coarse[0].Grid());    guess_coarse = Zero();
    blockProject(src_coarse,src,subspace);    
    for (int i=0;i<N;i++) {
      const CoarseField & tmp = evec_coarse[i];
      axpy(guess_coarse,TensorRemove(innerProduct(tmp,src_coarse)) / eval_coarse[i],tmp,guess_coarse);
    }
    blockPromote(guess_coarse,guess,subspace);
    guess.Checkerboard() = src.Checkerboard();
  };
  void operator()(const std::vector<FineField> &src,std::vector<FineField> &guess) {
    int Nevec = (int)evec_coarse.size();
    int Nsrc = (int)src.size();
    // make temp variables
    std::vector<CoarseField> src_coarse(Nsrc,evec_coarse[0].Grid());
    std::vector<CoarseField> guess_coarse(Nsrc,evec_coarse[0].Grid());    
    //Preporcessing
    std::cout << GridLogMessage << "Start BlockProject for loop" << std::endl;
    for (int j=0;j<Nsrc;j++)
    {
    guess_coarse[j] = Zero();
    std::cout << GridLogMessage << "BlockProject iter: " << j << std::endl;
    blockProject(src_coarse[j],src[j],subspace);
    }
    //deflation set up for eigen vector batchsize 1 and source batch size equal number of sources
    std::cout << GridLogMessage << "Start ProjectAccum for loop" << std::endl;
    for (int i=0;i<Nevec;i++)
    {
      std::cout << GridLogMessage << "ProjectAccum Nvec: " << i << std::endl;
      const CoarseField & tmp = evec_coarse[i];
      for (int j=0;j<Nsrc;j++)
      {
        axpy(guess_coarse[j],TensorRemove(innerProduct(tmp,src_coarse[j])) / eval_coarse[i],tmp,guess_coarse[j]);
      }
    }
    //postprocessing
    std::cout << GridLogMessage << "Start BlockPromote for loop" << std::endl;
    for (int j=0;j<Nsrc;j++)
    {
    std::cout << GridLogMessage << "BlockProject iter: " << j << std::endl;
    blockPromote(guess_coarse[j],guess[j],subspace);
    guess[j].Checkerboard() = src[j].Checkerboard();
    }
  };
  };
 }
 #endif
--- a/Grid/algorithms/iterative/FlexibleCommunicationAvoidingGeneralisedMinimalResidual.h
+++ b/Grid/algorithms/iterative/FlexibleCommunicationAvoidingGeneralisedMinimalResidual.h
@@ -0,0 +1,258 @@
 /*************************************************************************************
 Grid physics library, www.github.com/paboyle/Grid
 Source file: ./lib/algorithms/iterative/FlexibleCommunicationAvoidingGeneralisedMinimalResidual.h
 Copyright (C) 2015
 Author: Daniel Richtmann <daniel.richtmann@ur.de>
 This program is free software; you can redistribute it and/or modify
 it under the terms of the GNU General Public License as published by
 the Free Software Foundation; either version 2 of the License, or
 (at your option) any later version.
 This program is distributed in the hope that it will be useful,
 but WITHOUT ANY WARRANTY; without even the implied warranty of
 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 GNU General Public License for more details.
 You should have received a copy of the GNU General Public License along
 with this program; if not, write to the Free Software Foundation, Inc.,
 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
 See the full license in the file "LICENSE" in the top level distribution
 directory
 *************************************************************************************/
 /*  END LEGAL */
 #ifndef GRID_FLEXIBLE_COMMUNICATION_AVOIDING_GENERALISED_MINIMAL_RESIDUAL_H
 #define GRID_FLEXIBLE_COMMUNICATION_AVOIDING_GENERALISED_MINIMAL_RESIDUAL_H
 namespace Grid {
 template<class Field>
 class FlexibleCommunicationAvoidingGeneralisedMinimalResidual : public OperatorFunction<Field> {
 public:
  using OperatorFunction<Field>::operator();
  bool ErrorOnNoConverge; // Throw an assert when FCAGMRES fails to converge,
                          // defaults to true
  RealD   Tolerance;
  Integer MaxIterations;
  Integer RestartLength;
  Integer MaxNumberOfRestarts;
  Integer IterationCount; // Number of iterations the FCAGMRES took to finish,
                          // filled in upon completion
  GridStopWatch MatrixTimer;
  GridStopWatch PrecTimer;
  GridStopWatch LinalgTimer;
  GridStopWatch QrTimer;
  GridStopWatch CompSolutionTimer;
  Eigen::MatrixXcd H;
  std::vector<ComplexD> y;
  std::vector<ComplexD> gamma;
  std::vector<ComplexD> c;
  std::vector<ComplexD> s;
  LinearFunction<Field> &Preconditioner;
  FlexibleCommunicationAvoidingGeneralisedMinimalResidual(RealD   tol,
                                                          Integer maxit,
                                                          LinearFunction<Field> &Prec,
                                                          Integer restart_length,
                                                          bool    err_on_no_conv = true)
      : Tolerance(tol)
      , MaxIterations(maxit)
      , RestartLength(restart_length)
      , MaxNumberOfRestarts(MaxIterations/RestartLength + ((MaxIterations%RestartLength == 0) ? 0 : 1))
      , ErrorOnNoConverge(err_on_no_conv)
      , H(Eigen::MatrixXcd::Zero(RestartLength, RestartLength + 1)) // sizes taken from DD-αAMG code base
      , y(RestartLength + 1, 0.)
      , gamma(RestartLength + 1, 0.)
      , c(RestartLength + 1, 0.)
      , s(RestartLength + 1, 0.)
      , Preconditioner(Prec) {};
  void operator()(LinearOperatorBase<Field> &LinOp, const Field &src, Field &psi) {
    std::cout << GridLogWarning << "This algorithm currently doesn't differ from regular FGMRES" << std::endl;
    psi.Checkerboard() = src.Checkerboard();
    conformable(psi, src);
    RealD guess = norm2(psi);
    assert(std::isnan(guess) == 0);
    RealD cp;
    RealD ssq = norm2(src);
    RealD rsq = Tolerance * Tolerance * ssq;
    Field r(src.Grid());
    std::cout << std::setprecision(4) << std::scientific;
    std::cout << GridLogIterative << "FlexibleCommunicationAvoidingGeneralisedMinimalResidual: guess " << guess << std::endl;
    std::cout << GridLogIterative << "FlexibleCommunicationAvoidingGeneralisedMinimalResidual:   src " << ssq   << std::endl;
    PrecTimer.Reset();
    MatrixTimer.Reset();
    LinalgTimer.Reset();
    QrTimer.Reset();
    CompSolutionTimer.Reset();
    GridStopWatch SolverTimer;
    SolverTimer.Start();
    IterationCount = 0;
    for (int k=0; k<MaxNumberOfRestarts; k++) {
      cp = outerLoopBody(LinOp, src, psi, rsq);
      // Stopping condition
      if (cp <= rsq) {
        SolverTimer.Stop();
        LinOp.Op(psi,r);
        axpy(r,-1.0,src,r);
        RealD srcnorm       = sqrt(ssq);
        RealD resnorm       = sqrt(norm2(r));
        RealD true_residual = resnorm / srcnorm;
        std::cout << GridLogMessage        << "FlexibleCommunicationAvoidingGeneralisedMinimalResidual: Converged on iteration " << IterationCount
                  << " computed residual " << sqrt(cp / ssq)
                  << " true residual "     << true_residual
                  << " target "            << Tolerance << std::endl;
        std::cout << GridLogMessage << "FCAGMRES Time elapsed: Total   " <<       SolverTimer.Elapsed() << std::endl;
        std::cout << GridLogMessage << "FCAGMRES Time elapsed: Precon  " <<         PrecTimer.Elapsed() << std::endl;
        std::cout << GridLogMessage << "FCAGMRES Time elapsed: Matrix  " <<       MatrixTimer.Elapsed() << std::endl;
        std::cout << GridLogMessage << "FCAGMRES Time elapsed: Linalg  " <<       LinalgTimer.Elapsed() << std::endl;
        std::cout << GridLogMessage << "FCAGMRES Time elapsed: QR      " <<           QrTimer.Elapsed() << std::endl;
        std::cout << GridLogMessage << "FCAGMRES Time elapsed: CompSol " << CompSolutionTimer.Elapsed() << std::endl;
        return;
      }
    }
    std::cout << GridLogMessage << "FlexibleCommunicationAvoidingGeneralisedMinimalResidual did NOT converge" << std::endl;
    if (ErrorOnNoConverge)
      assert(0);
  }
  RealD outerLoopBody(LinearOperatorBase<Field> &LinOp, const Field &src, Field &psi, RealD rsq) {
    RealD cp = 0;
    Field w(src.Grid());
    Field r(src.Grid());
    // these should probably be made class members so that they are only allocated once, not in every restart
    std::vector<Field> v(RestartLength + 1, src.Grid()); for (auto &elem : v) elem = Zero();
    std::vector<Field> z(RestartLength + 1, src.Grid()); for (auto &elem : z) elem = Zero();
    MatrixTimer.Start();
    LinOp.Op(psi, w);
    MatrixTimer.Stop();
    LinalgTimer.Start();
    r = src - w;
    gamma[0] = sqrt(norm2(r));
    v[0] = (1. / gamma[0]) * r;
    LinalgTimer.Stop();
    for (int i=0; i<RestartLength; i++) {
      IterationCount++;
      arnoldiStep(LinOp, v, z, w, i);
      qrUpdate(i);
      cp = norm(gamma[i+1]);
      std::cout << GridLogIterative << "FlexibleCommunicationAvoidingGeneralisedMinimalResidual: Iteration " << IterationCount
                << " residual " << cp << " target " << rsq << std::endl;
      if ((i == RestartLength - 1) || (IterationCount == MaxIterations) || (cp <= rsq)) {
        computeSolution(z, psi, i);
        return cp;
      }
    }
    assert(0); // Never reached
    return cp;
  }
  void arnoldiStep(LinearOperatorBase<Field> &LinOp, std::vector<Field> &v, std::vector<Field> &z, Field &w, int iter) {
    PrecTimer.Start();
    Preconditioner(v[iter], z[iter]);
    PrecTimer.Stop();
    MatrixTimer.Start();
    LinOp.Op(z[iter], w);
    MatrixTimer.Stop();
    LinalgTimer.Start();
    for (int i = 0; i <= iter; ++i) {
      H(iter, i) = innerProduct(v[i], w);
      w = w - ComplexD(H(iter, i)) * v[i];
    }
    H(iter, iter + 1) = sqrt(norm2(w));
    v[iter + 1] = ComplexD(1. / H(iter, iter + 1)) * w;
    LinalgTimer.Stop();
  }
  void qrUpdate(int iter) {
    QrTimer.Start();
    for (int i = 0; i < iter ; ++i) {
      auto tmp       = -s[i] * ComplexD(H(iter, i)) + c[i] * ComplexD(H(iter, i + 1));
      H(iter, i)     = conjugate(c[i]) * ComplexD(H(iter, i)) + conjugate(s[i]) * ComplexD(H(iter, i + 1));
      H(iter, i + 1) = tmp;
    }
    // Compute new Givens Rotation
    auto nu = sqrt(std::norm(H(iter, iter)) + std::norm(H(iter, iter + 1)));
    c[iter]     = H(iter, iter) / nu;
    s[iter]     = H(iter, iter + 1) / nu;
    // Apply new Givens rotation
    H(iter, iter)     = nu;
    H(iter, iter + 1) = 0.;
    gamma[iter + 1] = -s[iter] * gamma[iter];
    gamma[iter]     = conjugate(c[iter]) * gamma[iter];
    QrTimer.Stop();
  }
  void computeSolution(std::vector<Field> const &z, Field &psi, int iter) {
    CompSolutionTimer.Start();
    for (int i = iter; i >= 0; i--) {
      y[i] = gamma[i];
      for (int k = i + 1; k <= iter; k++)
        y[i] = y[i] - ComplexD(H(k, i)) * y[k];
      y[i] = y[i] / ComplexD(H(i, i));
    }
    for (int i = 0; i <= iter; i++)
      psi = psi + z[i] * y[i];
    CompSolutionTimer.Stop();
  }
 };
 }
 #endif
--- a/Grid/algorithms/iterative/FlexibleGeneralisedMinimalResidual.h
+++ b/Grid/algorithms/iterative/FlexibleGeneralisedMinimalResidual.h
@@ -0,0 +1,256 @@
 /*************************************************************************************
 Grid physics library, www.github.com/paboyle/Grid
 Source file: ./lib/algorithms/iterative/FlexibleGeneralisedMinimalResidual.h
 Copyright (C) 2015
 Author: Daniel Richtmann <daniel.richtmann@ur.de>
 This program is free software; you can redistribute it and/or modify
 it under the terms of the GNU General Public License as published by
 the Free Software Foundation; either version 2 of the License, or
 (at your option) any later version.
 This program is distributed in the hope that it will be useful,
 but WITHOUT ANY WARRANTY; without even the implied warranty of
 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 GNU General Public License for more details.
 You should have received a copy of the GNU General Public License along
 with this program; if not, write to the Free Software Foundation, Inc.,
 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
 See the full license in the file "LICENSE" in the top level distribution
 directory
 *************************************************************************************/
 /*  END LEGAL */
 #ifndef GRID_FLEXIBLE_GENERALISED_MINIMAL_RESIDUAL_H
 #define GRID_FLEXIBLE_GENERALISED_MINIMAL_RESIDUAL_H
 namespace Grid {
 template<class Field>
 class FlexibleGeneralisedMinimalResidual : public OperatorFunction<Field> {
 public:
  using OperatorFunction<Field>::operator();
  bool ErrorOnNoConverge; // Throw an assert when FGMRES fails to converge,
                          // defaults to true
  RealD   Tolerance;
  Integer MaxIterations;
  Integer RestartLength;
  Integer MaxNumberOfRestarts;
  Integer IterationCount; // Number of iterations the FGMRES took to finish,
                          // filled in upon completion
  GridStopWatch MatrixTimer;
  GridStopWatch PrecTimer;
  GridStopWatch LinalgTimer;
  GridStopWatch QrTimer;
  GridStopWatch CompSolutionTimer;
  Eigen::MatrixXcd H;
  std::vector<ComplexD> y;
  std::vector<ComplexD> gamma;
  std::vector<ComplexD> c;
  std::vector<ComplexD> s;
  LinearFunction<Field> &Preconditioner;
  FlexibleGeneralisedMinimalResidual(RealD   tol,
                                     Integer maxit,
                                     LinearFunction<Field> &Prec,
                                     Integer restart_length,
                                     bool    err_on_no_conv = true)
      : Tolerance(tol)
      , MaxIterations(maxit)
      , RestartLength(restart_length)
      , MaxNumberOfRestarts(MaxIterations/RestartLength + ((MaxIterations%RestartLength == 0) ? 0 : 1))
      , ErrorOnNoConverge(err_on_no_conv)
      , H(Eigen::MatrixXcd::Zero(RestartLength, RestartLength + 1)) // sizes taken from DD-αAMG code base
      , y(RestartLength + 1, 0.)
      , gamma(RestartLength + 1, 0.)
      , c(RestartLength + 1, 0.)
      , s(RestartLength + 1, 0.)
      , Preconditioner(Prec) {};
  void operator()(LinearOperatorBase<Field> &LinOp, const Field &src, Field &psi) {
    psi.Checkerboard() = src.Checkerboard();
    conformable(psi, src);
    RealD guess = norm2(psi);
    assert(std::isnan(guess) == 0);
    RealD cp;
    RealD ssq = norm2(src);
    RealD rsq = Tolerance * Tolerance * ssq;
    Field r(src.Grid());
    std::cout << std::setprecision(4) << std::scientific;
    std::cout << GridLogIterative << "FlexibleGeneralisedMinimalResidual: guess " << guess << std::endl;
    std::cout << GridLogIterative << "FlexibleGeneralisedMinimalResidual:   src " << ssq   << std::endl;
    PrecTimer.Reset();
    MatrixTimer.Reset();
    LinalgTimer.Reset();
    QrTimer.Reset();
    CompSolutionTimer.Reset();
    GridStopWatch SolverTimer;
    SolverTimer.Start();
    IterationCount = 0;
    for (int k=0; k<MaxNumberOfRestarts; k++) {
      cp = outerLoopBody(LinOp, src, psi, rsq);
      // Stopping condition
      if (cp <= rsq) {
        SolverTimer.Stop();
        LinOp.Op(psi,r);
        axpy(r,-1.0,src,r);
        RealD srcnorm       = sqrt(ssq);
        RealD resnorm       = sqrt(norm2(r));
        RealD true_residual = resnorm / srcnorm;
        std::cout << GridLogMessage        << "FlexibleGeneralisedMinimalResidual: Converged on iteration " << IterationCount
                  << " computed residual " << sqrt(cp / ssq)
                  << " true residual "     << true_residual
                  << " target "            << Tolerance << std::endl;
        std::cout << GridLogMessage << "FGMRES Time elapsed: Total   " <<       SolverTimer.Elapsed() << std::endl;
        std::cout << GridLogMessage << "FGMRES Time elapsed: Precon  " <<         PrecTimer.Elapsed() << std::endl;
        std::cout << GridLogMessage << "FGMRES Time elapsed: Matrix  " <<       MatrixTimer.Elapsed() << std::endl;
        std::cout << GridLogMessage << "FGMRES Time elapsed: Linalg  " <<       LinalgTimer.Elapsed() << std::endl;
        std::cout << GridLogMessage << "FGMRES Time elapsed: QR      " <<           QrTimer.Elapsed() << std::endl;
        std::cout << GridLogMessage << "FGMRES Time elapsed: CompSol " << CompSolutionTimer.Elapsed() << std::endl;
        return;
      }
    }
    std::cout << GridLogMessage << "FlexibleGeneralisedMinimalResidual did NOT converge" << std::endl;
    if (ErrorOnNoConverge)
      assert(0);
  }
  RealD outerLoopBody(LinearOperatorBase<Field> &LinOp, const Field &src, Field &psi, RealD rsq) {
    RealD cp = 0;
    Field w(src.Grid());
    Field r(src.Grid());
    // these should probably be made class members so that they are only allocated once, not in every restart
    std::vector<Field> v(RestartLength + 1, src.Grid()); for (auto &elem : v) elem = Zero();
    std::vector<Field> z(RestartLength + 1, src.Grid()); for (auto &elem : z) elem = Zero();
    MatrixTimer.Start();
    LinOp.Op(psi, w);
    MatrixTimer.Stop();
    LinalgTimer.Start();
    r = src - w;
    gamma[0] = sqrt(norm2(r));
    v[0] = (1. / gamma[0]) * r;
    LinalgTimer.Stop();
    for (int i=0; i<RestartLength; i++) {
      IterationCount++;
      arnoldiStep(LinOp, v, z, w, i);
      qrUpdate(i);
      cp = norm(gamma[i+1]);
      std::cout << GridLogIterative << "FlexibleGeneralisedMinimalResidual: Iteration " << IterationCount
                << " residual " << cp << " target " << rsq << std::endl;
      if ((i == RestartLength - 1) || (IterationCount == MaxIterations) || (cp <= rsq)) {
        computeSolution(z, psi, i);
        return cp;
      }
    }
    assert(0); // Never reached
    return cp;
  }
  void arnoldiStep(LinearOperatorBase<Field> &LinOp, std::vector<Field> &v, std::vector<Field> &z, Field &w, int iter) {
    PrecTimer.Start();
    Preconditioner(v[iter], z[iter]);
    PrecTimer.Stop();
    MatrixTimer.Start();
    LinOp.Op(z[iter], w);
    MatrixTimer.Stop();
    LinalgTimer.Start();
    for (int i = 0; i <= iter; ++i) {
      H(iter, i) = innerProduct(v[i], w);
      w = w - ComplexD(H(iter, i)) * v[i];
    }
    H(iter, iter + 1) = sqrt(norm2(w));
    v[iter + 1] = ComplexD(1. / H(iter, iter + 1)) * w;
    LinalgTimer.Stop();
  }
  void qrUpdate(int iter) {
    QrTimer.Start();
    for (int i = 0; i < iter ; ++i) {
      auto tmp       = -s[i] * ComplexD(H(iter, i)) + c[i] * ComplexD(H(iter, i + 1));
      H(iter, i)     = conjugate(c[i]) * ComplexD(H(iter, i)) + conjugate(s[i]) * ComplexD(H(iter, i + 1));
      H(iter, i + 1) = tmp;
    }
    // Compute new Givens Rotation
    auto nu = sqrt(std::norm(H(iter, iter)) + std::norm(H(iter, iter + 1)));
    c[iter]     = H(iter, iter) / nu;
    s[iter]     = H(iter, iter + 1) / nu;
    // Apply new Givens rotation
    H(iter, iter)     = nu;
    H(iter, iter + 1) = 0.;
    gamma[iter + 1] = -s[iter] * gamma[iter];
    gamma[iter]     = conjugate(c[iter]) * gamma[iter];
    QrTimer.Stop();
  }
  void computeSolution(std::vector<Field> const &z, Field &psi, int iter) {
    CompSolutionTimer.Start();
    for (int i = iter; i >= 0; i--) {
      y[i] = gamma[i];
      for (int k = i + 1; k <= iter; k++)
        y[i] = y[i] - ComplexD(H(k, i)) * y[k];
      y[i] = y[i] / ComplexD(H(i, i));
    }
    for (int i = 0; i <= iter; i++)
      psi = psi + z[i] * y[i];
    CompSolutionTimer.Stop();
  }
 };
 }
 #endif
--- a/Grid/algorithms/iterative/GeneralisedMinimalResidual.h
+++ b/Grid/algorithms/iterative/GeneralisedMinimalResidual.h
@@ -0,0 +1,244 @@
 /*************************************************************************************
 Grid physics library, www.github.com/paboyle/Grid
 Source file: ./lib/algorithms/iterative/GeneralisedMinimalResidual.h
 Copyright (C) 2015
 Author: Daniel Richtmann <daniel.richtmann@ur.de>
 This program is free software; you can redistribute it and/or modify
 it under the terms of the GNU General Public License as published by
 the Free Software Foundation; either version 2 of the License, or
 (at your option) any later version.
 This program is distributed in the hope that it will be useful,
 but WITHOUT ANY WARRANTY; without even the implied warranty of
 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 GNU General Public License for more details.
 You should have received a copy of the GNU General Public License along
 with this program; if not, write to the Free Software Foundation, Inc.,
 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
 See the full license in the file "LICENSE" in the top level distribution
 directory
 *************************************************************************************/
 /*  END LEGAL */
 #ifndef GRID_GENERALISED_MINIMAL_RESIDUAL_H
 #define GRID_GENERALISED_MINIMAL_RESIDUAL_H
 namespace Grid {
 template<class Field>
 class GeneralisedMinimalResidual : public OperatorFunction<Field> {
 public:
  using OperatorFunction<Field>::operator();
  bool ErrorOnNoConverge; // Throw an assert when GMRES fails to converge,
                          // defaults to true
  RealD   Tolerance;
  Integer MaxIterations;
  Integer RestartLength;
  Integer MaxNumberOfRestarts;
  Integer IterationCount; // Number of iterations the GMRES took to finish,
                          // filled in upon completion
  GridStopWatch MatrixTimer;
  GridStopWatch LinalgTimer;
  GridStopWatch QrTimer;
  GridStopWatch CompSolutionTimer;
  Eigen::MatrixXcd H;
  std::vector<ComplexD> y;
  std::vector<ComplexD> gamma;
  std::vector<ComplexD> c;
  std::vector<ComplexD> s;
  GeneralisedMinimalResidual(RealD   tol,
                             Integer maxit,
                             Integer restart_length,
                             bool    err_on_no_conv = true)
      : Tolerance(tol)
      , MaxIterations(maxit)
      , RestartLength(restart_length)
      , MaxNumberOfRestarts(MaxIterations/RestartLength + ((MaxIterations%RestartLength == 0) ? 0 : 1))
      , ErrorOnNoConverge(err_on_no_conv)
      , H(Eigen::MatrixXcd::Zero(RestartLength, RestartLength + 1)) // sizes taken from DD-αAMG code base
      , y(RestartLength + 1, 0.)
      , gamma(RestartLength + 1, 0.)
      , c(RestartLength + 1, 0.)
      , s(RestartLength + 1, 0.) {};
  void operator()(LinearOperatorBase<Field> &LinOp, const Field &src, Field &psi) {
    psi.Checkerboard() = src.Checkerboard();
    conformable(psi, src);
    RealD guess = norm2(psi);
    assert(std::isnan(guess) == 0);
    RealD cp;
    RealD ssq = norm2(src);
    RealD rsq = Tolerance * Tolerance * ssq;
    Field r(src.Grid());
    std::cout << std::setprecision(4) << std::scientific;
    std::cout << GridLogIterative << "GeneralisedMinimalResidual: guess " << guess << std::endl;
    std::cout << GridLogIterative << "GeneralisedMinimalResidual:   src " << ssq   << std::endl;
    MatrixTimer.Reset();
    LinalgTimer.Reset();
    QrTimer.Reset();
    CompSolutionTimer.Reset();
    GridStopWatch SolverTimer;
    SolverTimer.Start();
    IterationCount = 0;
    for (int k=0; k<MaxNumberOfRestarts; k++) {
      cp = outerLoopBody(LinOp, src, psi, rsq);
      // Stopping condition
      if (cp <= rsq) {
        SolverTimer.Stop();
        LinOp.Op(psi,r);
        axpy(r,-1.0,src,r);
        RealD srcnorm       = sqrt(ssq);
        RealD resnorm       = sqrt(norm2(r));
        RealD true_residual = resnorm / srcnorm;
        std::cout << GridLogMessage        << "GeneralisedMinimalResidual: Converged on iteration " << IterationCount
                  << " computed residual " << sqrt(cp / ssq)
                  << " true residual "     << true_residual
                  << " target "            << Tolerance << std::endl;
        std::cout << GridLogMessage << "GMRES Time elapsed: Total   " <<       SolverTimer.Elapsed() << std::endl;
        std::cout << GridLogMessage << "GMRES Time elapsed: Matrix  " <<       MatrixTimer.Elapsed() << std::endl;
        std::cout << GridLogMessage << "GMRES Time elapsed: Linalg  " <<       LinalgTimer.Elapsed() << std::endl;
        std::cout << GridLogMessage << "GMRES Time elapsed: QR      " <<           QrTimer.Elapsed() << std::endl;
        std::cout << GridLogMessage << "GMRES Time elapsed: CompSol " << CompSolutionTimer.Elapsed() << std::endl;
        return;
      }
    }
    std::cout << GridLogMessage << "GeneralisedMinimalResidual did NOT converge" << std::endl;
    if (ErrorOnNoConverge)
      assert(0);
  }
  RealD outerLoopBody(LinearOperatorBase<Field> &LinOp, const Field &src, Field &psi, RealD rsq) {
    RealD cp = 0;
    Field w(src.Grid());
    Field r(src.Grid());
    // this should probably be made a class member so that it is only allocated once, not in every restart
    std::vector<Field> v(RestartLength + 1, src.Grid()); for (auto &elem : v) elem = Zero();
    MatrixTimer.Start();
    LinOp.Op(psi, w);
    MatrixTimer.Stop();
    LinalgTimer.Start();
    r = src - w;
    gamma[0] = sqrt(norm2(r));
    v[0] = (1. / gamma[0]) * r;
    LinalgTimer.Stop();
    for (int i=0; i<RestartLength; i++) {
      IterationCount++;
      arnoldiStep(LinOp, v, w, i);
      qrUpdate(i);
      cp = norm(gamma[i+1]);
      std::cout << GridLogIterative << "GeneralisedMinimalResidual: Iteration " << IterationCount
                << " residual " << cp << " target " << rsq << std::endl;
      if ((i == RestartLength - 1) || (IterationCount == MaxIterations) || (cp <= rsq)) {
        computeSolution(v, psi, i);
        return cp;
      }
    }
    assert(0); // Never reached
    return cp;
  }
  void arnoldiStep(LinearOperatorBase<Field> &LinOp, std::vector<Field> &v, Field &w, int iter) {
    MatrixTimer.Start();
    LinOp.Op(v[iter], w);
    MatrixTimer.Stop();
    LinalgTimer.Start();
    for (int i = 0; i <= iter; ++i) {
      H(iter, i) = innerProduct(v[i], w);
      w = w - ComplexD(H(iter, i)) * v[i];
    }
    H(iter, iter + 1) = sqrt(norm2(w));
    v[iter + 1] = ComplexD(1. / H(iter, iter + 1)) * w;
    LinalgTimer.Stop();
  }
  void qrUpdate(int iter) {
    QrTimer.Start();
    for (int i = 0; i < iter ; ++i) {
      auto tmp       = -s[i] * ComplexD(H(iter, i)) + c[i] * ComplexD(H(iter, i + 1));
      H(iter, i)     = conjugate(c[i]) * ComplexD(H(iter, i)) + conjugate(s[i]) * ComplexD(H(iter, i + 1));
      H(iter, i + 1) = tmp;
    }
    // Compute new Givens Rotation
    auto nu = sqrt(std::norm(H(iter, iter)) + std::norm(H(iter, iter + 1)));
    c[iter]     = H(iter, iter) / nu;
    s[iter]     = H(iter, iter + 1) / nu;
    // Apply new Givens rotation
    H(iter, iter)     = nu;
    H(iter, iter + 1) = 0.;
    gamma[iter + 1] = -s[iter] * gamma[iter];
    gamma[iter]     = conjugate(c[iter]) * gamma[iter];
    QrTimer.Stop();
  }
  void computeSolution(std::vector<Field> const &v, Field &psi, int iter) {
    CompSolutionTimer.Start();
    for (int i = iter; i >= 0; i--) {
      y[i] = gamma[i];
      for (int k = i + 1; k <= iter; k++)
        y[i] = y[i] - ComplexD(H(k, i)) * y[k];
      y[i] = y[i] / ComplexD(H(i, i));
    }
    for (int i = 0; i <= iter; i++)
      psi = psi + v[i] * y[i];
    CompSolutionTimer.Stop();
  }
 };
 }
 #endif
--- a/Grid/algorithms/iterative/ImplicitlyRestartedBlockLanczos.h
+++ b/Grid/algorithms/iterative/ImplicitlyRestartedBlockLanczos.h
--- a/Grid/algorithms/iterative/ImplicitlyRestartedLanczos.h
+++ b/Grid/algorithms/iterative/ImplicitlyRestartedLanczos.h
@@ -35,120 +35,7 @@ Author: Christoph Lehner <clehner@bnl.gov>
 //#include <zlib.h>
 #include <sys/stat.h>
-namespace Grid { 
+NAMESPACE_BEGIN(Grid); 
  ////////////////////////////////////////////////////////
  // Move following 100 LOC to lattice/Lattice_basis.h
  ////////////////////////////////////////////////////////
 template<class Field>
 void basisOrthogonalize(std::vector<Field> &basis,Field &w,int k) 
 {
  for(int j=0; j<k; ++j){
    auto ip = innerProduct(basis[j],w);
    w = w - ip*basis[j];
  }
 }
 template<class Field>
 void basisRotate(std::vector<Field> &basis,Eigen::MatrixXd& Qt,int j0, int j1, int k0,int k1,int Nm) 
 {
  typedef typename Field::vector_object vobj;
  GridBase* grid = basis[0]._grid;
  parallel_region
  {
    std::vector < vobj , commAllocator<vobj> > B(Nm); // Thread private
    parallel_for_internal(int ss=0;ss < grid->oSites();ss++){
      for(int j=j0; j<j1; ++j) B[j]=0.;
      for(int j=j0; j<j1; ++j){
 	for(int k=k0; k<k1; ++k){
 	  B[j] +=Qt(j,k) * basis[k]._odata[ss];
 	}
      }
      for(int j=j0; j<j1; ++j){
 	  basis[j]._odata[ss] = B[j];
      }
    }
  }
 }
 // Extract a single rotated vector
 template<class Field>
 void basisRotateJ(Field &result,std::vector<Field> &basis,Eigen::MatrixXd& Qt,int j, int k0,int k1,int Nm) 
 {
  typedef typename Field::vector_object vobj;
  GridBase* grid = basis[0]._grid;
  result.checkerboard = basis[0].checkerboard;
  parallel_for(int ss=0;ss < grid->oSites();ss++){
    vobj B = zero;
    for(int k=k0; k<k1; ++k){
      B +=Qt(j,k) * basis[k]._odata[ss];
    }
    result._odata[ss] = B;
  }
 }
 template<class Field>
 void basisReorderInPlace(std::vector<Field> &_v,std::vector<RealD>& sort_vals, std::vector<int>& idx) 
 {
  int vlen = idx.size();
  assert(vlen>=1);
  assert(vlen<=sort_vals.size());
  assert(vlen<=_v.size());
  for (size_t i=0;i<vlen;i++) {
    if (idx[i] != i) {
      //////////////////////////////////////
      // idx[i] is a table of desired sources giving a permutation.
      // Swap v[i] with v[idx[i]].
      // Find  j>i for which _vnew[j] = _vold[i],
      // track the move idx[j] => idx[i]
      // track the move idx[i] => i
      //////////////////////////////////////
      size_t j;
      for (j=i;j<idx.size();j++)
 	if (idx[j]==i)
 	  break;
      assert(idx[i] > i);     assert(j!=idx.size());      assert(idx[j]==i);
      std::swap(_v[i]._odata,_v[idx[i]]._odata); // should use vector move constructor, no data copy
      std::swap(sort_vals[i],sort_vals[idx[i]]);
      idx[j] = idx[i];
      idx[i] = i;
    }
  }
 }
 inline std::vector<int> basisSortGetIndex(std::vector<RealD>& sort_vals) 
 {
  std::vector<int> idx(sort_vals.size());
  std::iota(idx.begin(), idx.end(), 0);
  // sort indexes based on comparing values in v
  std::sort(idx.begin(), idx.end(), [&sort_vals](int i1, int i2) {
    return ::fabs(sort_vals[i1]) < ::fabs(sort_vals[i2]);
  });
  return idx;
 }
 template<class Field>
 void basisSortInPlace(std::vector<Field> & _v,std::vector<RealD>& sort_vals, bool reverse) 
 {
  std::vector<int> idx = basisSortGetIndex(sort_vals);
  if (reverse)
    std::reverse(idx.begin(), idx.end());
  basisReorderInPlace(_v,sort_vals,idx);
 }
 /////////////////////////////////////////////////////////////
 // Implicitly restarted lanczos
@@ -259,7 +146,7 @@ public:
 			    RealD _eresid, // resid in lmdue deficit 
 			    int _MaxIter, // Max iterations
 			    RealD _betastp=0.0, // if beta(k) < betastp: converged
-			    int _MinRestart=1, int _orth_period = 1,
+			    int _MinRestart=0, int _orth_period = 1,
 			    IRLdiagonalisation _diagonalisation= IRLdiagonaliseWithEigen) :
    SimpleTester(HermOp), _PolyOp(PolyOp),      _HermOp(HermOp), _Tester(Tester),
    Nstop(_Nstop)  ,      Nk(_Nk),      Nm(_Nm),
@@ -275,7 +162,7 @@ public:
 			       RealD _eresid, // resid in lmdue deficit 
 			       int _MaxIter, // Max iterations
 			       RealD _betastp=0.0, // if beta(k) < betastp: converged
-			       int _MinRestart=1, int _orth_period = 1,
+			       int _MinRestart=0, int _orth_period = 1,
 			       IRLdiagonalisation _diagonalisation= IRLdiagonaliseWithEigen) :
    SimpleTester(HermOp),  _PolyOp(PolyOp),      _HermOp(HermOp), _Tester(SimpleTester),
    Nstop(_Nstop)  ,      Nk(_Nk),      Nm(_Nm),
@@ -289,7 +176,7 @@ public:
  template<typename T>  static RealD normalise(T& v) 
  {
    RealD nn = norm2(v);
-    nn = sqrt(nn);
+    nn = std::sqrt(nn);
    v = v * (1.0/nn);
    return nn;
  }
@@ -321,10 +208,10 @@ until convergence
 */
  void calc(std::vector<RealD>& eval, std::vector<Field>& evec,  const Field& src, int& Nconv, bool reverse=false)
  {
-    GridBase *grid = src._grid;
+    GridBase *grid = src.Grid();
-    assert(grid == evec[0]._grid);
+    assert(grid == evec[0].Grid());
-    GridLogIRL.TimingMode(1);
+    //    GridLogIRL.TimingMode(1);
    std::cout << GridLogIRL <<"**************************************************************************"<< std::endl;
    std::cout << GridLogIRL <<" ImplicitlyRestartedLanczos::calc() starting iteration 0 /  "<< MaxIter<< std::endl;
    std::cout << GridLogIRL <<"**************************************************************************"<< std::endl;
@@ -349,14 +236,17 @@ until convergence
    {
      auto src_n = src;
      auto tmp = src;
      std::cout << GridLogIRL << " IRL source norm " << norm2(src) << std::endl;
      const int _MAX_ITER_IRL_MEVAPP_ = 50;
      for (int i=0;i<_MAX_ITER_IRL_MEVAPP_;i++) {
 	normalise(src_n);
 	_HermOp(src_n,tmp);
 	//	std::cout << GridLogMessage<< tmp<<std::endl; exit(0);
 	//	std::cout << GridLogIRL << " _HermOp " << norm2(tmp) << std::endl;
 	RealD vnum = real(innerProduct(src_n,tmp)); // HermOp.
 	RealD vden = norm2(src_n);
 	RealD na = vnum/vden;
-	if (fabs(evalMaxApprox/na - 1.0) < 0.05)
+	if (fabs(evalMaxApprox/na - 1.0) < 0.0001)
 	  i=_MAX_ITER_IRL_MEVAPP_;
 	evalMaxApprox = na;
 	std::cout << GridLogIRL << " Approximation of largest eigenvalue: " << evalMaxApprox << std::endl;
@@ -446,7 +336,7 @@ until convergence
      assert(k2<Nm);      assert(k2<Nm);      assert(k1>0);
      basisRotate(evec,Qt,k1-1,k2+1,0,Nm,Nm); /// big constraint on the basis
-      std::cout<<GridLogIRL <<"basisRotated  by Qt"<<std::endl;
+      std::cout<<GridLogIRL <<"basisRotated  by Qt *"<<k1-1<<","<<k2+1<<")"<<std::endl;
      ////////////////////////////////////////////////////
      // Compressed vector f and beta(k2)
@@ -454,7 +344,7 @@ until convergence
      f *= Qt(k2-1,Nm-1);
      f += lme[k2-1] * evec[k2];
      beta_k = norm2(f);
-      beta_k = sqrt(beta_k);
+      beta_k = std::sqrt(beta_k);
      std::cout<<GridLogIRL<<" beta(k) = "<<beta_k<<std::endl;
      RealD betar = 1.0/beta_k;
@@ -477,7 +367,7 @@ until convergence
 	std::cout << GridLogIRL << "Test convergence: rotate subset of vectors to test convergence " << std::endl;
-	Field B(grid); B.checkerboard = evec[0].checkerboard;
+	Field B(grid); B.Checkerboard() = evec[0].Checkerboard();
 	//  power of two search pattern;  not every evalue in eval2 is assessed.
 	int allconv =1;
@@ -515,7 +405,7 @@ until convergence
  converged:
    {
-      Field B(grid); B.checkerboard = evec[0].checkerboard;
+      Field B(grid); B.Checkerboard() = evec[0].Checkerboard();
      basisRotate(evec,Qt,0,Nk,0,Nk,Nm);	    
      std::cout << GridLogIRL << " Rotated basis"<<std::endl;
      Nconv=0;
@@ -529,14 +419,15 @@ until convergence
 	}
      }
-      if ( Nconv < Nstop )
+      if ( Nconv < Nstop ) {
 	std::cout << GridLogIRL << "Nconv ("<<Nconv<<") < Nstop ("<<Nstop<<")"<<std::endl;
-
+	std::cout << GridLogIRL << "returning Nstop vectors, the last "<< Nstop-Nconv << "of which might meet convergence criterion only approximately" <<std::endl;
      }
      eval=eval2;
      //Keep only converged
-      eval.resize(Nconv);// Nstop?
+      eval.resize(Nstop);// was Nconv
-      evec.resize(Nconv,grid);// Nstop?
+      evec.resize(Nstop,grid);// was Nconv
      basisSortInPlace(evec,eval,reverse);
    }
@@ -554,11 +445,11 @@ until convergence
 /* Saad PP. 195
 1. Choose an initial vector v1 of 2-norm unity. Set β1 ≡ 0, v0 ≡ 0
 2. For k = 1,2,...,m Do:
-3. wk:=Avk−βkv_{k−1}      
+3. wk:=Avk - b_k v_{k-1}      
-4. αk:=(wk,vk)       // 
+4. ak:=(wk,vk)       // 
-5. wk:=wk−αkvk       // wk orthog vk 
+5. wk:=wk-akvk       // wk orthog vk 
-6. βk+1 := ∥wk∥2. If βk+1 = 0 then Stop
+6. bk+1 := ||wk||_2. If b_k+1 = 0 then Stop
-7. vk+1 := wk/βk+1
+7. vk+1 := wk/b_k+1
 8. EndDo
 */
  void step(std::vector<RealD>& lmd,
@@ -566,6 +457,7 @@ until convergence
 	    std::vector<Field>& evec,
 	    Field& w,int Nm,int k)
  {
    std::cout<<GridLogIRL << "Lanczos step " <<k<<std::endl;
    const RealD tiny = 1.0e-20;
    assert( k< Nm );
@@ -577,20 +469,20 @@ until convergence
    if(k>0) w -= lme[k-1] * evec[k-1];
-    ComplexD zalph = innerProduct(evec_k,w); // 4. αk:=(wk,vk)
+    ComplexD zalph = innerProduct(evec_k,w);
    RealD     alph = real(zalph);
-    w = w - alph * evec_k;// 5. wk:=wk−αkvk
+    w = w - alph * evec_k;
-    RealD beta = normalise(w); // 6. βk+1 := ∥wk∥2. If βk+1 = 0 then Stop
+    RealD beta = normalise(w); 
    // 7. vk+1 := wk/βk+1
    lmd[k] = alph;
    lme[k] = beta;
-    if (k>0 && k % orth_period == 0) {
+    if ( (k>0) && ( (k % orth_period) == 0 )) {
      std::cout<<GridLogIRL << "Orthogonalising " <<k<<std::endl;
      orthogonalize(w,evec,k); // orthonormalise
-      std::cout<<GridLogIRL << "Orthogonalised " <<std::endl;
+      std::cout<<GridLogIRL << "Orthogonalised " <<k<<std::endl;
    }
    if(k < Nm-1) evec[k+1] = w;
@@ -598,6 +490,8 @@ until convergence
    std::cout<<GridLogIRL << "alpha[" << k << "] = " << zalph << " beta[" << k << "] = "<<beta<<std::endl;
    if ( beta < tiny ) 
      std::cout<<GridLogIRL << " beta is tiny "<<beta<<std::endl;
    std::cout<<GridLogIRL << "Lanczos step complete " <<k<<std::endl;
  }
  void diagonalize_Eigen(std::vector<RealD>& lmd, std::vector<RealD>& lme, 
@@ -807,7 +701,7 @@ void diagonalize_QR(std::vector<RealD>& lmd, std::vector<RealD>& lme,
    // determination of 2x2 leading submatrix
    RealD dsub = lmd[kmax-1]-lmd[kmax-2];
-    RealD dd = sqrt(dsub*dsub + 4.0*lme[kmax-2]*lme[kmax-2]);
+    RealD dd = std::sqrt(dsub*dsub + 4.0*lme[kmax-2]*lme[kmax-2]);
    RealD Dsh = 0.5*(lmd[kmax-2]+lmd[kmax-1] +dd*(dsub/fabs(dsub)));
    // (Dsh: shift)
@@ -838,5 +732,6 @@ void diagonalize_QR(std::vector<RealD>& lmd, std::vector<RealD>& lme,
  abort();
 }
 };
-}
+
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/algorithms/iterative/LocalCoherenceLanczos.h
+++ b/Grid/algorithms/iterative/LocalCoherenceLanczos.h
@@ -1,4 +1,4 @@
-    /*************************************************************************************
+/*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
@@ -24,16 +24,15 @@ Author: paboyle <paboyle@ph.ed.ac.uk>
    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 */
+/*  END LEGAL */
 #ifndef GRID_LOCAL_COHERENCE_IRL_H
 #define GRID_LOCAL_COHERENCE_IRL_H
-namespace Grid { 
+NAMESPACE_BEGIN(Grid); 
 struct LanczosParams : Serializable {
- public:
+public:
  GRID_SERIALIZABLE_CLASS_MEMBERS(LanczosParams,
 				  ChebyParams, Cheby,/*Chebyshev*/
 				  int, Nstop,    /*Vecs in Lanczos must converge Nstop < Nk < Nm*/
@@ -45,8 +44,9 @@ struct LanczosParams : Serializable {
 				  int, MinRes);    // Must restart
 };
 //This class is the input parameter class for some testing programs
 struct LocalCoherenceLanczosParams : Serializable {
- public:
+public:
  GRID_SERIALIZABLE_CLASS_MEMBERS(LocalCoherenceLanczosParams,
 				  bool, saveEvecs,
 				  bool, doFine,
@@ -59,7 +59,7 @@ struct LocalCoherenceLanczosParams : Serializable {
 				  RealD        , coarse_relax_tol,
 				  std::vector<int>, blockSize,
 				  std::string, config,
-				  std::vector < std::complex<double>  >, omega,
+				  std::vector < ComplexD  >, omega,
 				  RealD, mass,
 				  RealD, M5);
 };
@@ -68,6 +68,7 @@ struct LocalCoherenceLanczosParams : Serializable {
 template<class Fobj,class CComplex,int nbasis>
 class ProjectedHermOp : public LinearFunction<Lattice<iVector<CComplex,nbasis > > > {
 public:
  using LinearFunction<Lattice<iVector<CComplex,nbasis > > >::operator();
  typedef iVector<CComplex,nbasis >           CoarseSiteVector;
  typedef Lattice<CoarseSiteVector>           CoarseField;
  typedef Lattice<CComplex>   CoarseScalar; // used for inner products on fine field
@@ -83,14 +84,14 @@ public:
  };
  void operator()(const CoarseField& in, CoarseField& out) {
-    GridBase *FineGrid = subspace[0]._grid;    
+    GridBase *FineGrid = subspace[0].Grid();    
-    int   checkerboard = subspace[0].checkerboard;
+    int   checkerboard = subspace[0].Checkerboard();
-      
+
-    FineField fin (FineGrid);     fin.checkerboard= checkerboard;
+    FineField fin (FineGrid);     fin.Checkerboard()= checkerboard;
-    FineField fout(FineGrid);   fout.checkerboard = checkerboard;
+    FineField fout(FineGrid);   fout.Checkerboard() = checkerboard;
    blockPromote(in,fin,subspace);       std::cout<<GridLogIRL<<"ProjectedHermop : Promote to fine"<<std::endl;
-    _Linop.HermOp(fin,fout);             std::cout<<GridLogIRL<<"ProjectedHermop : HermOp (fine) "<<std::endl;
+    _Linop.HermOp(fin,fout);                   std::cout<<GridLogIRL<<"ProjectedHermop : HermOp (fine) "<<std::endl;
    blockProject(out,fout,subspace);     std::cout<<GridLogIRL<<"ProjectedHermop : Project to coarse "<<std::endl;
  }
 };
@@ -98,6 +99,7 @@ public:
 template<class Fobj,class CComplex,int nbasis>
 class ProjectedFunctionHermOp : public LinearFunction<Lattice<iVector<CComplex,nbasis > > > {
 public:
  using LinearFunction<Lattice<iVector<CComplex,nbasis > > >::operator();
  typedef iVector<CComplex,nbasis >           CoarseSiteVector;
  typedef Lattice<CoarseSiteVector>           CoarseField;
  typedef Lattice<CComplex>   CoarseScalar; // used for inner products on fine field
@@ -117,12 +119,12 @@ public:
  {  };
  void operator()(const CoarseField& in, CoarseField& out) {
    GridBase *FineGrid = subspace[0]._grid;    
    int   checkerboard = subspace[0].checkerboard;
-    FineField fin (FineGrid); fin.checkerboard =checkerboard;
+    GridBase *FineGrid = subspace[0].Grid();    
-    FineField fout(FineGrid);fout.checkerboard =checkerboard;
+    int   checkerboard = subspace[0].Checkerboard();
    FineField fin (FineGrid); fin.Checkerboard() =checkerboard;
    FineField fout(FineGrid);fout.Checkerboard() =checkerboard;
    blockPromote(in,fin,subspace);             std::cout<<GridLogIRL<<"ProjectedFunctionHermop : Promote to fine"<<std::endl;
    _poly(_Linop,fin,fout);                    std::cout<<GridLogIRL<<"ProjectedFunctionHermop : Poly "<<std::endl;
@@ -133,7 +135,7 @@ public:
 template<class Fobj,class CComplex,int nbasis>
 class ImplicitlyRestartedLanczosSmoothedTester  : public ImplicitlyRestartedLanczosTester<Lattice<iVector<CComplex,nbasis > > >
 {
- public:
+public:
  typedef iVector<CComplex,nbasis >           CoarseSiteVector;
  typedef Lattice<CoarseSiteVector>           CoarseField;
  typedef Lattice<CComplex>   CoarseScalar; // used for inner products on fine field
@@ -142,18 +144,26 @@ class ImplicitlyRestartedLanczosSmoothedTester  : public ImplicitlyRestartedLanc
  LinearFunction<CoarseField> & _Poly;
  OperatorFunction<FineField>   & _smoother;
  LinearOperatorBase<FineField> &_Linop;
-  RealD                          _coarse_relax_tol;
+  RealD                             _coarse_relax_tol;
  std::vector<FineField>        &_subspace;
  int _largestEvalIdxForReport; //The convergence of the LCL is based on the evals of the coarse grid operator, not those of the underlying fine grid operator
                                //As a result we do not know what the eval range of the fine operator is until the very end, making tuning the Cheby bounds very difficult
                                //To work around this issue, every restart we separately reconstruct the fine operator eval for the lowest and highest evec and print these
                                //out alongside the evals of the coarse operator. To do so we need to know the index of the largest eval (i.e. Nstop-1)
                                //NOTE: If largestEvalIdxForReport=-1 (default) then this is not performed
  ImplicitlyRestartedLanczosSmoothedTester(LinearFunction<CoarseField>   &Poly,
 					   OperatorFunction<FineField>   &smoother,
 					   LinearOperatorBase<FineField> &Linop,
 					   std::vector<FineField>        &subspace,
-					   RealD coarse_relax_tol=5.0e3) 
+					   RealD coarse_relax_tol=5.0e3,
 					   int largestEvalIdxForReport=-1) 
    : _smoother(smoother), _Linop(Linop), _Poly(Poly), _subspace(subspace),
-      _coarse_relax_tol(coarse_relax_tol)  
+      _coarse_relax_tol(coarse_relax_tol), _largestEvalIdxForReport(largestEvalIdxForReport)
  {    };
  //evalMaxApprox: approximation of largest eval of the fine Chebyshev operator (suitably wrapped by block projection)
  int TestConvergence(int j,RealD eresid,CoarseField &B, RealD &eval,RealD evalMaxApprox)
  {
    CoarseField v(B);
@@ -176,16 +186,30 @@ class ImplicitlyRestartedLanczosSmoothedTester  : public ImplicitlyRestartedLanc
 	     <<" |H B[i] - eval[i]B[i]|^2 / evalMaxApprox^2 " << std::setw(25) << vv
 	     <<std::endl;
    if(_largestEvalIdxForReport != -1 && (j==0 || j==_largestEvalIdxForReport)){
      std::cout<<GridLogIRL << "Estimating true eval of fine grid operator for eval idx " << j << std::endl;
      RealD tmp_eval;
      ReconstructEval(j,eresid,B,tmp_eval,1.0); //don't use evalMaxApprox of coarse operator! (cf below)
    }
    int conv=0;
    if( (vv<eresid*eresid) ) conv = 1;
    return conv;
  }
-  int ReconstructEval(int j,RealD eresid,CoarseField &B, RealD &eval,RealD evalMaxApprox)
+
  //This function is called at the end of the coarse grid Lanczos. It promotes the coarse eigenvector 'B' to the fine grid,
  //applies a smoother to the result then computes the computes the *fine grid* eigenvalue (output as 'eval').
  //evalMaxApprox should be the approximation of the largest eval of the fine Hermop. However when this function is called by IRL it actually passes the largest eval of the *Chebyshev* operator (as this is the max approx used for the TestConvergence above)
  //As the largest eval of the Chebyshev is typically several orders of magnitude larger this makes the convergence test pass even when it should not.
  //We therefore ignore evalMaxApprox here and use a value of 1.0 (note this value is already used by TestCoarse)
  int ReconstructEval(int j,RealD eresid,CoarseField &B, RealD &eval,RealD evalMaxApprox)  
  {
-    GridBase *FineGrid = _subspace[0]._grid;    
+    evalMaxApprox = 1.0; //cf above
-    int checkerboard   = _subspace[0].checkerboard;
+    GridBase *FineGrid = _subspace[0].Grid();    
-    FineField fB(FineGrid);fB.checkerboard =checkerboard;
+    int checkerboard   = _subspace[0].Checkerboard();
-    FineField fv(FineGrid);fv.checkerboard =checkerboard;
+    FineField fB(FineGrid);fB.Checkerboard() =checkerboard;
    FineField fv(FineGrid);fv.Checkerboard() =checkerboard;
    blockPromote(B,fv,_subspace);  
@@ -200,13 +224,13 @@ class ImplicitlyRestartedLanczosSmoothedTester  : public ImplicitlyRestartedLanc
    eval   = vnum/vden;
    fv -= eval*fB;
    RealD vv = norm2(fv) / ::pow(evalMaxApprox,2.0);
-
+    if ( j > nbasis ) eresid = eresid*_coarse_relax_tol;
    std::cout.precision(13);
    std::cout<<GridLogIRL  << "[" << std::setw(3)<<j<<"] "
 	     <<"eval = "<<std::setw(25)<< eval << " (" << eval_poly << ")"
-	     <<" |H B[i] - eval[i]B[i]|^2 / evalMaxApprox^2 " << std::setw(25) << vv
+	     <<" |H B[i] - eval[i]B[i]|^2 / evalMaxApprox^2 " << std::setw(25) << vv << " target " << eresid*eresid
 	     <<std::endl;
    if ( j > nbasis ) eresid = eresid*_coarse_relax_tol;
    if( (vv<eresid*eresid) ) return 1;
    return 0;
  }
@@ -284,10 +308,16 @@ public:
    evals_coarse.resize(0);
  };
  //The block inner product is the inner product on the fine grid locally summed over the blocks
  //to give a Lattice<Scalar> on the coarse grid. This function orthnormalizes the fine-grid subspace
  //vectors under the block inner product. This step must be performed after computing the fine grid
  //eigenvectors and before computing the coarse grid eigenvectors.    
  void Orthogonalise(void ) {
-    CoarseScalar InnerProd(_CoarseGrid); 
+    CoarseScalar InnerProd(_CoarseGrid);
-    blockOrthogonalise(InnerProd,subspace);std::cout << GridLogMessage <<" Gramm-Schmidt pass 1"<<std::endl;
+    std::cout << GridLogMessage <<" Gramm-Schmidt pass 1"<<std::endl;
-    blockOrthogonalise(InnerProd,subspace);std::cout << GridLogMessage <<" Gramm-Schmidt pass 2"<<std::endl;
+    blockOrthogonalise(InnerProd,subspace);
    std::cout << GridLogMessage <<" Gramm-Schmidt pass 2"<<std::endl;
    blockOrthogonalise(InnerProd,subspace);
  };
  template<typename T>  static RealD normalise(T& v) 
@@ -303,11 +333,11 @@ public:
    int Nk = nbasis;
    subspace.resize(Nk,_FineGrid);
    subspace[0]=1.0;
-    subspace[0].checkerboard=_checkerboard;
+    subspace[0].Checkerboard()=_checkerboard;
    normalise(subspace[0]);
    PlainHermOp<FineField>    Op(_FineOp);
    for(int k=1;k<Nk;k++){
-      subspace[k].checkerboard=_checkerboard;
+      subspace[k].Checkerboard()=_checkerboard;
      Op(subspace[k-1],subspace[k]);
      normalise(subspace[k]);
    }
@@ -325,6 +355,8 @@ public:
    }
  }
  //While this method serves to check the coarse eigenvectors, it also recomputes the eigenvalues from the smoothed reconstructed eigenvectors
  //hence the smoother can be tuned after running the coarse Lanczos by using a different smoother here
  void testCoarse(RealD resid,ChebyParams cheby_smooth,RealD relax) 
  {
    assert(evals_fine.size() == nbasis);
@@ -333,7 +365,7 @@ public:
    // create a smoother and see if we can get a cheap convergence test and smooth inside the IRL
    //////////////////////////////////////////////////////////////////////////////////////////////////
    Chebyshev<FineField>                          ChebySmooth(cheby_smooth);
-    ProjectedFunctionHermOp<Fobj,CComplex,nbasis> ChebyOp (ChebySmooth,_FineOp,_subspace);
+    ProjectedFunctionHermOp<Fobj,CComplex,nbasis> ChebyOp (ChebySmooth,_FineOp,subspace);
    ImplicitlyRestartedLanczosSmoothedTester<Fobj,CComplex,nbasis> ChebySmoothTester(ChebyOp,ChebySmooth,_FineOp,subspace,relax);
    for(int k=0;k<evec_coarse.size();k++){
@@ -358,7 +390,11 @@ public:
    ImplicitlyRestartedLanczos<FineField> IRL(ChebyOp,Op,Nstop,Nk,Nm,resid,MaxIt,betastp,MinRes);
-    FineField src(_FineGrid); src=1.0; src.checkerboard = _checkerboard;
+    FineField src(_FineGrid); 
    typedef typename FineField::scalar_type Scalar;
    // src=1.0; 
    src=Scalar(1.0); 
    src.Checkerboard() = _checkerboard;
    int Nconv;
    IRL.calc(evals_fine,subspace,src,Nconv,false);
@@ -369,25 +405,31 @@ public:
    evals_fine.resize(nbasis);
    subspace.resize(nbasis,_FineGrid);
  }
  //cheby_op: Parameters of the fine grid Chebyshev polynomial used for the Lanczos acceleration
  //cheby_smooth: Parameters of a separate Chebyshev polynomial used after the Lanczos has completed to smooth out high frequency noise in the reconstructed fine grid eigenvectors prior to computing the eigenvalue
  //relax: Reconstructed eigenvectors (post smoothing) are naturally not as precise as true eigenvectors. This factor acts as a multiplier on the stopping condition when determining whether the results satisfy the user provided stopping condition
  void calcCoarse(ChebyParams cheby_op,ChebyParams cheby_smooth,RealD relax,
 		  int Nstop, int Nk, int Nm,RealD resid, 
 		  RealD MaxIt, RealD betastp, int MinRes)
  {
-    Chebyshev<FineField>                          Cheby(cheby_op);
+    Chebyshev<FineField>                          Cheby(cheby_op); //Chebyshev of fine operator on fine grid
-    ProjectedHermOp<Fobj,CComplex,nbasis>         Op(_FineOp,_subspace);
+    ProjectedHermOp<Fobj,CComplex,nbasis>         Op(_FineOp,subspace); //Fine operator on coarse grid with intermediate fine grid conversion
-    ProjectedFunctionHermOp<Fobj,CComplex,nbasis> ChebyOp (Cheby,_FineOp,_subspace);
+    ProjectedFunctionHermOp<Fobj,CComplex,nbasis> ChebyOp (Cheby,_FineOp,subspace); //Chebyshev of fine operator on coarse grid with intermediate fine grid conversion
    //////////////////////////////////////////////////////////////////////////////////////////////////
    // create a smoother and see if we can get a cheap convergence test and smooth inside the IRL
    //////////////////////////////////////////////////////////////////////////////////////////////////
-    Chebyshev<FineField>                                           ChebySmooth(cheby_smooth);
+    Chebyshev<FineField>                                           ChebySmooth(cheby_smooth); //lower order Chebyshev of fine operator on fine grid used to smooth regenerated eigenvectors
-    ImplicitlyRestartedLanczosSmoothedTester<Fobj,CComplex,nbasis> ChebySmoothTester(ChebyOp,ChebySmooth,_FineOp,_subspace,relax);
+    ImplicitlyRestartedLanczosSmoothedTester<Fobj,CComplex,nbasis> ChebySmoothTester(ChebyOp,ChebySmooth,_FineOp,subspace,relax,Nstop-1); 
    evals_coarse.resize(Nm);
    evec_coarse.resize(Nm,_CoarseGrid);
    CoarseField src(_CoarseGrid);     src=1.0; 
    //Note the "tester" here is also responsible for generating the fine grid eigenvalues which are output into the "evals_coarse" array
    ImplicitlyRestartedLanczos<CoarseField> IRL(ChebyOp,ChebyOp,ChebySmoothTester,Nstop,Nk,Nm,resid,MaxIt,betastp,MinRes);
    int Nconv=0;
    IRL.calc(evals_coarse,evec_coarse,src,Nconv,false);
@@ -398,7 +440,15 @@ public:
      std::cout << i << " Coarse eval = " << evals_coarse[i]  << std::endl;
    }
  }
  //Get the fine eigenvector 'i' by reconstruction
  void getFineEvecEval(FineField &evec, RealD &eval, const int i) const{
    blockPromote(evec_coarse[i],evec,subspace);  
    eval = evals_coarse[i];
  }
 };
-}
+NAMESPACE_END(Grid);
 #endif
--- a/Grid/algorithms/iterative/MinimalResidual.h
+++ b/Grid/algorithms/iterative/MinimalResidual.h
@@ -0,0 +1,157 @@
 /*************************************************************************************
 Grid physics library, www.github.com/paboyle/Grid
 Source file: ./lib/algorithms/iterative/MinimalResidual.h
 Copyright (C) 2015
 Author: Daniel Richtmann <daniel.richtmann@ur.de>
 This program is free software; you can redistribute it and/or modify
 it under the terms of the GNU General Public License as published by
 the Free Software Foundation; either version 2 of the License, or
 (at your option) any later version.
 This program is distributed in the hope that it will be useful,
 but WITHOUT ANY WARRANTY; without even the implied warranty of
 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 GNU General Public License for more details.
 You should have received a copy of the GNU General Public License along
 with this program; if not, write to the Free Software Foundation, Inc.,
 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
 See the full license in the file "LICENSE" in the top level distribution
 directory
 *************************************************************************************/
 /*  END LEGAL */
 #ifndef GRID_MINIMAL_RESIDUAL_H
 #define GRID_MINIMAL_RESIDUAL_H
 namespace Grid {
 template<class Field> class MinimalResidual : public OperatorFunction<Field> {
 public:
  using OperatorFunction<Field>::operator();
  bool ErrorOnNoConverge; // throw an assert when the MR fails to converge.
                          // Defaults true.
  RealD   Tolerance;
  Integer MaxIterations;
  RealD   overRelaxParam;
  Integer IterationsToComplete; // Number of iterations the MR took to finish.
                                // Filled in upon completion
  MinimalResidual(RealD tol, Integer maxit, Real ovrelparam = 1.0, bool err_on_no_conv = true)
    : Tolerance(tol), MaxIterations(maxit), overRelaxParam(ovrelparam), ErrorOnNoConverge(err_on_no_conv){};
  void operator()(LinearOperatorBase<Field> &Linop, const Field &src, Field &psi) {
    psi.Checkerboard() = src.Checkerboard();
    conformable(psi, src);
    ComplexD a, c;
    RealD    d;
    Field Mr(src);
    Field r(src);
    // Initial residual computation & set up
    RealD guess = norm2(psi);
    assert(std::isnan(guess) == 0);
    RealD ssq = norm2(src);
    RealD rsq = Tolerance * Tolerance * ssq;
    Linop.Op(psi, Mr);
    r = src - Mr;
    RealD cp = norm2(r);
    std::cout << std::setprecision(4) << std::scientific;
    std::cout << GridLogIterative << "MinimalResidual: guess " << guess << std::endl;
    std::cout << GridLogIterative << "MinimalResidual:   src " << ssq << std::endl;
    std::cout << GridLogIterative << "MinimalResidual:  cp,r " << cp << std::endl;
    if (cp <= rsq) {
      return;
    }
    std::cout << GridLogIterative << "MinimalResidual: k=0 residual " << cp << " target " << rsq << std::endl;
    GridStopWatch LinalgTimer;
    GridStopWatch MatrixTimer;
    GridStopWatch SolverTimer;
    SolverTimer.Start();
    int k;
    for (k = 1; k <= MaxIterations; k++) {
      MatrixTimer.Start();
      Linop.Op(r, Mr);
      MatrixTimer.Stop();
      LinalgTimer.Start();
      c = innerProduct(Mr, r);
      d = norm2(Mr);
      a = c / d;
      a = a * overRelaxParam;
      psi = psi + r * a;
      r = r - Mr * a;
      cp = norm2(r);
      LinalgTimer.Stop();
      std::cout << GridLogIterative << "MinimalResidual: Iteration " << k
                << " residual " << cp << " target " << rsq << std::endl;
      std::cout << GridLogDebug << "a = " << a << " c = " << c << " d = " << d << std::endl;
      // Stopping condition
      if (cp <= rsq) {
        SolverTimer.Stop();
        Linop.Op(psi, Mr);
        r = src - Mr;
        RealD srcnorm       = sqrt(ssq);
        RealD resnorm       = sqrt(norm2(r));
        RealD true_residual = resnorm / srcnorm;
        std::cout << GridLogMessage        << "MinimalResidual Converged on iteration " << k
                  << " computed residual " << sqrt(cp / ssq)
                  << " true residual "     << true_residual
                  << " target "            << Tolerance << std::endl;
        std::cout << GridLogMessage << "MR Time elapsed: Total   " << SolverTimer.Elapsed() << std::endl;
        std::cout << GridLogMessage << "MR Time elapsed: Matrix  " << MatrixTimer.Elapsed() << std::endl;
        std::cout << GridLogMessage << "MR Time elapsed: Linalg  " << LinalgTimer.Elapsed() << std::endl;
        if (ErrorOnNoConverge)
          assert(true_residual / Tolerance < 10000.0);
        IterationsToComplete = k;
        return;
      }
    }
    std::cout << GridLogMessage << "MinimalResidual did NOT converge"
              << std::endl;
    if (ErrorOnNoConverge)
      assert(0);
    IterationsToComplete = k;
  }
 };
 } // namespace Grid
 #endif
--- a/Grid/algorithms/iterative/MixedPrecisionFlexibleGeneralisedMinimalResidual.h
+++ b/Grid/algorithms/iterative/MixedPrecisionFlexibleGeneralisedMinimalResidual.h
@@ -0,0 +1,276 @@
 /*************************************************************************************
 Grid physics library, www.github.com/paboyle/Grid
 Source file: ./lib/algorithms/iterative/MixedPrecisionFlexibleGeneralisedMinimalResidual.h
 Copyright (C) 2015
 Author: Daniel Richtmann <daniel.richtmann@ur.de>
 This program is free software; you can redistribute it and/or modify
 it under the terms of the GNU General Public License as published by
 the Free Software Foundation; either version 2 of the License, or
 (at your option) any later version.
 This program is distributed in the hope that it will be useful,
 but WITHOUT ANY WARRANTY; without even the implied warranty of
 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 GNU General Public License for more details.
 You should have received a copy of the GNU General Public License along
 with this program; if not, write to the Free Software Foundation, Inc.,
 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
 See the full license in the file "LICENSE" in the top level distribution
 directory
 *************************************************************************************/
 /*  END LEGAL */
 #ifndef GRID_MIXED_PRECISION_FLEXIBLE_GENERALISED_MINIMAL_RESIDUAL_H
 #define GRID_MIXED_PRECISION_FLEXIBLE_GENERALISED_MINIMAL_RESIDUAL_H
 namespace Grid {
 template<class FieldD, class FieldF, typename std::enable_if<getPrecision<FieldD>::value == 2, int>::type = 0, typename std::enable_if< getPrecision<FieldF>::value == 1, int>::type = 0>
 class MixedPrecisionFlexibleGeneralisedMinimalResidual : public OperatorFunction<FieldD> {
 public:
  using OperatorFunction<FieldD>::operator();
  bool ErrorOnNoConverge; // Throw an assert when MPFGMRES fails to converge,
                          // defaults to true
  RealD   Tolerance;
  Integer MaxIterations;
  Integer RestartLength;
  Integer MaxNumberOfRestarts;
  Integer IterationCount; // Number of iterations the MPFGMRES took to finish,
                          // filled in upon completion
  GridStopWatch MatrixTimer;
  GridStopWatch PrecTimer;
  GridStopWatch LinalgTimer;
  GridStopWatch QrTimer;
  GridStopWatch CompSolutionTimer;
  GridStopWatch ChangePrecTimer;
  Eigen::MatrixXcd H;
  std::vector<ComplexD> y;
  std::vector<ComplexD> gamma;
  std::vector<ComplexD> c;
  std::vector<ComplexD> s;
  GridBase* SinglePrecGrid;
  LinearFunction<FieldF> &Preconditioner;
  MixedPrecisionFlexibleGeneralisedMinimalResidual(RealD   tol,
                                                   Integer maxit,
                                                   GridBase * sp_grid,
                                                   LinearFunction<FieldF> &Prec,
                                                   Integer restart_length,
                                                   bool    err_on_no_conv = true)
      : Tolerance(tol)
      , MaxIterations(maxit)
      , RestartLength(restart_length)
      , MaxNumberOfRestarts(MaxIterations/RestartLength + ((MaxIterations%RestartLength == 0) ? 0 : 1))
      , ErrorOnNoConverge(err_on_no_conv)
      , H(Eigen::MatrixXcd::Zero(RestartLength, RestartLength + 1)) // sizes taken from DD-αAMG code base
      , y(RestartLength + 1, 0.)
      , gamma(RestartLength + 1, 0.)
      , c(RestartLength + 1, 0.)
      , s(RestartLength + 1, 0.)
      , SinglePrecGrid(sp_grid)
      , Preconditioner(Prec) {};
  void operator()(LinearOperatorBase<FieldD> &LinOp, const FieldD &src, FieldD &psi) {
    psi.Checkerboard() = src.Checkerboard();
    conformable(psi, src);
    RealD guess = norm2(psi);
    assert(std::isnan(guess) == 0);
    RealD cp;
    RealD ssq = norm2(src);
    RealD rsq = Tolerance * Tolerance * ssq;
    FieldD r(src.Grid());
    std::cout << std::setprecision(4) << std::scientific;
    std::cout << GridLogIterative << "MPFGMRES: guess " << guess << std::endl;
    std::cout << GridLogIterative << "MPFGMRES:   src " << ssq   << std::endl;
    PrecTimer.Reset();
    MatrixTimer.Reset();
    LinalgTimer.Reset();
    QrTimer.Reset();
    CompSolutionTimer.Reset();
    ChangePrecTimer.Reset();
    GridStopWatch SolverTimer;
    SolverTimer.Start();
    IterationCount = 0;
    for (int k=0; k<MaxNumberOfRestarts; k++) {
      cp = outerLoopBody(LinOp, src, psi, rsq);
      // Stopping condition
      if (cp <= rsq) {
        SolverTimer.Stop();
        LinOp.Op(psi,r);
        axpy(r,-1.0,src,r);
        RealD srcnorm       = sqrt(ssq);
        RealD resnorm       = sqrt(norm2(r));
        RealD true_residual = resnorm / srcnorm;
        std::cout << GridLogMessage        << "MPFGMRES: Converged on iteration " << IterationCount
                  << " computed residual " << sqrt(cp / ssq)
                  << " true residual "     << true_residual
                  << " target "            << Tolerance << std::endl;
        std::cout << GridLogMessage << "MPFGMRES Time elapsed: Total      " <<       SolverTimer.Elapsed() << std::endl;
        std::cout << GridLogMessage << "MPFGMRES Time elapsed: Precon     " <<         PrecTimer.Elapsed() << std::endl;
        std::cout << GridLogMessage << "MPFGMRES Time elapsed: Matrix     " <<       MatrixTimer.Elapsed() << std::endl;
        std::cout << GridLogMessage << "MPFGMRES Time elapsed: Linalg     " <<       LinalgTimer.Elapsed() << std::endl;
        std::cout << GridLogMessage << "MPFGMRES Time elapsed: QR         " <<           QrTimer.Elapsed() << std::endl;
        std::cout << GridLogMessage << "MPFGMRES Time elapsed: CompSol    " << CompSolutionTimer.Elapsed() << std::endl;
        std::cout << GridLogMessage << "MPFGMRES Time elapsed: PrecChange " <<   ChangePrecTimer.Elapsed() << std::endl;
        return;
      }
    }
    std::cout << GridLogMessage << "MPFGMRES did NOT converge" << std::endl;
    if (ErrorOnNoConverge)
      assert(0);
  }
  RealD outerLoopBody(LinearOperatorBase<FieldD> &LinOp, const FieldD &src, FieldD &psi, RealD rsq) {
    RealD cp = 0;
    FieldD w(src.Grid());
    FieldD r(src.Grid());
    // these should probably be made class members so that they are only allocated once, not in every restart
    std::vector<FieldD> v(RestartLength + 1, src.Grid()); for (auto &elem : v) elem = Zero();
    std::vector<FieldD> z(RestartLength + 1, src.Grid()); for (auto &elem : z) elem = Zero();
    MatrixTimer.Start();
    LinOp.Op(psi, w);
    MatrixTimer.Stop();
    LinalgTimer.Start();
    r = src - w;
    gamma[0] = sqrt(norm2(r));
    v[0] = (1. / gamma[0]) * r;
    LinalgTimer.Stop();
    for (int i=0; i<RestartLength; i++) {
      IterationCount++;
      arnoldiStep(LinOp, v, z, w, i);
      qrUpdate(i);
      cp = norm(gamma[i+1]);
      std::cout << GridLogIterative << "MPFGMRES: Iteration " << IterationCount
                << " residual " << cp << " target " << rsq << std::endl;
      if ((i == RestartLength - 1) || (IterationCount == MaxIterations) || (cp <= rsq)) {
        computeSolution(z, psi, i);
        return cp;
      }
    }
    assert(0); // Never reached
    return cp;
  }
  void arnoldiStep(LinearOperatorBase<FieldD> &LinOp, std::vector<FieldD> &v, std::vector<FieldD> &z, FieldD &w, int iter) {
    FieldF v_f(SinglePrecGrid);
    FieldF z_f(SinglePrecGrid);
    ChangePrecTimer.Start();
    precisionChange(v_f, v[iter]);
    precisionChange(z_f, z[iter]);
    ChangePrecTimer.Stop();
    PrecTimer.Start();
    Preconditioner(v_f, z_f);
    PrecTimer.Stop();
    ChangePrecTimer.Start();
    precisionChange(z[iter], z_f);
    ChangePrecTimer.Stop();
    MatrixTimer.Start();
    LinOp.Op(z[iter], w);
    MatrixTimer.Stop();
    LinalgTimer.Start();
    for (int i = 0; i <= iter; ++i) {
      H(iter, i) = innerProduct(v[i], w);
      w = w - ComplexD(H(iter, i)) * v[i];
    }
    H(iter, iter + 1) = sqrt(norm2(w));
    v[iter + 1] = ComplexD(1. / H(iter, iter + 1)) * w;
    LinalgTimer.Stop();
  }
  void qrUpdate(int iter) {
    QrTimer.Start();
    for (int i = 0; i < iter ; ++i) {
      auto tmp       = -s[i] * ComplexD(H(iter, i)) + c[i] * ComplexD(H(iter, i + 1));
      H(iter, i)     = conjugate(c[i]) * ComplexD(H(iter, i)) + conjugate(s[i]) * ComplexD(H(iter, i + 1));
      H(iter, i + 1) = tmp;
    }
    // Compute new Givens Rotation
    auto nu = sqrt(std::norm(H(iter, iter)) + std::norm(H(iter, iter + 1)));
    c[iter]     = H(iter, iter) / nu;
    s[iter]     = H(iter, iter + 1) / nu;
    // Apply new Givens rotation
    H(iter, iter)     = nu;
    H(iter, iter + 1) = 0.;
    gamma[iter + 1] = -s[iter] * gamma[iter];
    gamma[iter]     = conjugate(c[iter]) * gamma[iter];
    QrTimer.Stop();
  }
  void computeSolution(std::vector<FieldD> const &z, FieldD &psi, int iter) {
    CompSolutionTimer.Start();
    for (int i = iter; i >= 0; i--) {
      y[i] = gamma[i];
      for (int k = i + 1; k <= iter; k++)
        y[i] = y[i] - ComplexD(H(k, i)) * y[k];
      y[i] = y[i] / ComplexD(H(i, i));
    }
    for (int i = 0; i <= iter; i++)
      psi = psi + z[i] * y[i];
    CompSolutionTimer.Stop();
  }
 };
 }
 #endif
--- a/Grid/algorithms/iterative/NormalEquations.h
+++ b/Grid/algorithms/iterative/NormalEquations.h
@@ -0,0 +1,112 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./lib/algorithms/iterative/NormalEquations.h
    Copyright (C) 2015
 Author: Peter Boyle <paboyle@ph.ed.ac.uk>
    This program is free software; you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation; either version 2 of the License, or
    (at your option) any later version.
    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.
    You should have received a copy of the GNU General Public License along
    with this program; if not, write to the Free Software Foundation, Inc.,
    51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
    See the full license in the file "LICENSE" in the top level distribution directory
 *************************************************************************************/
 /*  END LEGAL */
 #ifndef GRID_NORMAL_EQUATIONS_H
 #define GRID_NORMAL_EQUATIONS_H
 NAMESPACE_BEGIN(Grid);
 ///////////////////////////////////////////////////////////////////////////////////////////////////////
 // Take a matrix and form an NE solver calling a Herm solver
 ///////////////////////////////////////////////////////////////////////////////////////////////////////
 template<class Field> class NormalEquations {
 private:
  SparseMatrixBase<Field> & _Matrix;
  OperatorFunction<Field> & _HermitianSolver;
  LinearFunction<Field>   & _Guess;
 public:
  /////////////////////////////////////////////////////
  // Wrap the usual normal equations trick
  /////////////////////////////////////////////////////
 NormalEquations(SparseMatrixBase<Field> &Matrix, OperatorFunction<Field> &HermitianSolver,
 		 LinearFunction<Field> &Guess) 
   :  _Matrix(Matrix), _HermitianSolver(HermitianSolver), _Guess(Guess) {}; 
  void operator() (const Field &in, Field &out){
    Field src(in.Grid());
    Field tmp(in.Grid());
    MdagMLinearOperator<SparseMatrixBase<Field>,Field> MdagMOp(_Matrix);
    _Matrix.Mdag(in,src);
    _Guess(src,out);
    _HermitianSolver(MdagMOp,src,out);  // Mdag M out = Mdag in
  }     
 };
 template<class Field> class HPDSolver {
 private:
  LinearOperatorBase<Field> & _Matrix;
  OperatorFunction<Field> & _HermitianSolver;
  LinearFunction<Field>   & _Guess;
 public:
  /////////////////////////////////////////////////////
  // Wrap the usual normal equations trick
  /////////////////////////////////////////////////////
 HPDSolver(LinearOperatorBase<Field> &Matrix,
 	   OperatorFunction<Field> &HermitianSolver,
 	   LinearFunction<Field> &Guess) 
   :  _Matrix(Matrix), _HermitianSolver(HermitianSolver), _Guess(Guess) {}; 
  void operator() (const Field &in, Field &out){
    _Guess(in,out);
    _HermitianSolver(_Matrix,in,out);  // Mdag M out = Mdag in
  }     
 };
 template<class Field> class MdagMSolver {
 private:
  SparseMatrixBase<Field> & _Matrix;
  OperatorFunction<Field> & _HermitianSolver;
  LinearFunction<Field>   & _Guess;
 public:
  /////////////////////////////////////////////////////
  // Wrap the usual normal equations trick
  /////////////////////////////////////////////////////
 MdagMSolver(SparseMatrixBase<Field> &Matrix, OperatorFunction<Field> &HermitianSolver,
 	     LinearFunction<Field> &Guess) 
   :  _Matrix(Matrix), _HermitianSolver(HermitianSolver), _Guess(Guess) {}; 
  void operator() (const Field &in, Field &out){
    MdagMLinearOperator<SparseMatrixBase<Field>,Field> MdagMOp(_Matrix);
    _Guess(in,out);
    _HermitianSolver(MdagMOp,in,out);  // Mdag M out = Mdag in
  }     
 };
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/algorithms/iterative/PowerMethod.h
+++ b/Grid/algorithms/iterative/PowerMethod.h
@@ -0,0 +1,47 @@
 #pragma once
 namespace Grid {
 template<class Field> class PowerMethod  
 { 
 public: 
  template<typename T>  static RealD normalise(T& v) 
  {
    RealD nn = norm2(v);
    nn = sqrt(nn);
    v = v * (1.0/nn);
    return nn;
  }
  RealD operator()(LinearOperatorBase<Field> &HermOp, const Field &src) 
  { 
    GridBase *grid = src.Grid(); 
    // quickly get an idea of the largest eigenvalue to more properly normalize the residuum 
    RealD evalMaxApprox = 0.0; 
    auto src_n = src; 
    auto tmp = src; 
    const int _MAX_ITER_EST_ = 50; 
    for (int i=0;i<_MAX_ITER_EST_;i++) { 
      normalise(src_n); 
      HermOp.HermOp(src_n,tmp); 
      RealD vnum = real(innerProduct(src_n,tmp)); // HermOp. 
      RealD vden = norm2(src_n); 
      RealD na = vnum/vden; 
      std::cout << GridLogIterative << "PowerMethod: Current approximation of largest eigenvalue " << na << std::endl;
      if ( (fabs(evalMaxApprox/na - 1.0) < 0.001) || (i==_MAX_ITER_EST_-1) ) { 
 	evalMaxApprox = na; 
 	std::cout << GridLogMessage << " Approximation of largest eigenvalue: " << evalMaxApprox << std::endl;
 	return evalMaxApprox; 
      } 
      evalMaxApprox = na; 
      src_n = tmp;
    }
    assert(0);
    return 0;
  }
 };
 }
--- a/Grid/algorithms/iterative/PrecConjugateResidual.h
+++ b/Grid/algorithms/iterative/PrecConjugateResidual.h
@@ -0,0 +1,119 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./lib/algorithms/iterative/PrecConjugateResidual.h
    Copyright (C) 2015
 Author: Peter Boyle <paboyle@ph.ed.ac.uk>
    This program is free software; you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation; either version 2 of the License, or
    (at your option) any later version.
    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.
    You should have received a copy of the GNU General Public License along
    with this program; if not, write to the Free Software Foundation, Inc.,
    51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
    See the full license in the file "LICENSE" in the top level distribution directory
 *************************************************************************************/
 /*  END LEGAL */
 #ifndef GRID_PREC_CONJUGATE_RESIDUAL_H
 #define GRID_PREC_CONJUGATE_RESIDUAL_H
 NAMESPACE_BEGIN(Grid);
 /////////////////////////////////////////////////////////////
 // Base classes for iterative processes based on operators
 // single input vec, single output vec.
 /////////////////////////////////////////////////////////////
 template<class Field> 
 class PrecConjugateResidual : public OperatorFunction<Field> {
 public:                                                
  RealD   Tolerance;
  Integer MaxIterations;
  int verbose;
  LinearFunction<Field> &Preconditioner;
  PrecConjugateResidual(RealD tol,Integer maxit,LinearFunction<Field> &Prec) : Tolerance(tol), MaxIterations(maxit),      Preconditioner(Prec)
  { 
    verbose=1;
  };
  void operator() (LinearOperatorBase<Field> &Linop,const Field &src, Field &psi){
    RealD a, b, c, d;
    RealD cp, ssq,rsq;
    RealD rAr, rAAr, rArp;
    RealD pAp, pAAp;
    GridBase *grid = src.Grid();
    Field r(grid),  p(grid), Ap(grid), Ar(grid), z(grid);
    psi=zero;
    r  = src;
    Preconditioner(r,p);
    Linop.HermOpAndNorm(p,Ap,pAp,pAAp);
    Ar=Ap;
    rAr=pAp;
    rAAr=pAAp;
    cp =norm2(r);
    ssq=norm2(src);
    rsq=Tolerance*Tolerance*ssq;
    if (verbose) std::cout<<GridLogMessage<<"PrecConjugateResidual: iteration " <<0<<" residual "<<cp<< " target"<< rsq<<std::endl;
    for(int k=0;k<MaxIterations;k++){
      Preconditioner(Ap,z);
      RealD rq= real(innerProduct(Ap,z)); 
      a = rAr/rq;
      axpy(psi,a,p,psi);
      cp = axpy_norm(r,-a,z,r);
      rArp=rAr;
      Linop.HermOpAndNorm(r,Ar,rAr,rAAr);
      b   =rAr/rArp;
      axpy(p,b,p,r);
      pAAp=axpy_norm(Ap,b,Ap,Ar);
      if(verbose) std::cout<<GridLogMessage<<"PrecConjugateResidual: iteration " <<k<<" residual "<<cp<< " target"<< rsq<<std::endl;
      if(cp<rsq) {
 	Linop.HermOp(psi,Ap);
 	axpy(r,-1.0,src,Ap);
 	RealD true_resid = norm2(r)/ssq;
 	std::cout<<GridLogMessage<<"PrecConjugateResidual: Converged on iteration " <<k
 		 << " computed residual "<<sqrt(cp/ssq)
 		 << " true residual "<<sqrt(true_resid)
 		 << " target "       <<Tolerance <<std::endl;
 	return;
      }
    }
    std::cout<<GridLogMessage<<"PrecConjugateResidual did NOT converge"<<std::endl;
    assert(0);
  }
 };
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/algorithms/iterative/PrecGeneralisedConjugateResidual.h
+++ b/Grid/algorithms/iterative/PrecGeneralisedConjugateResidual.h
@@ -0,0 +1,239 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./lib/algorithms/iterative/PrecGeneralisedConjugateResidual.h
    Copyright (C) 2015
 Author: Azusa Yamaguchi <ayamaguc@staffmail.ed.ac.uk>
 Author: Peter Boyle <paboyle@ph.ed.ac.uk>
    This program is free software; you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation; either version 2 of the License, or
    (at your option) any later version.
    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.
    You should have received a copy of the GNU General Public License along
    with this program; if not, write to the Free Software Foundation, Inc.,
    51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
    See the full license in the file "LICENSE" in the top level distribution directory
 *************************************************************************************/
 /*  END LEGAL */
 #ifndef GRID_PREC_GCR_H
 #define GRID_PREC_GCR_H
 ///////////////////////////////////////////////////////////////////////////////////////////////////////
 //VPGCR Abe and Zhang, 2005.
 //INTERNATIONAL JOURNAL OF NUMERICAL ANALYSIS AND MODELING
 //Computing and Information Volume 2, Number 2, Pages 147-161
 //NB. Likely not original reference since they are focussing on a preconditioner variant.
 //    but VPGCR was nicely written up in their paper
 ///////////////////////////////////////////////////////////////////////////////////////////////////////
 NAMESPACE_BEGIN(Grid);
 #define GCRLogLevel std::cout << GridLogMessage <<std::string(level,'\t')<< " Level "<<level<<" " 
 template<class Field>
 class PrecGeneralisedConjugateResidual : public LinearFunction<Field> {
 public:                                                
  using LinearFunction<Field>::operator();
  RealD   Tolerance;
  Integer MaxIterations;
  int verbose;
  int mmax;
  int nstep;
  int steps;
  int level;
  GridStopWatch PrecTimer;
  GridStopWatch MatTimer;
  GridStopWatch LinalgTimer;
  LinearFunction<Field>     &Preconditioner;
  LinearOperatorBase<Field> &Linop;
  void Level(int lv) { level=lv; };
  PrecGeneralisedConjugateResidual(RealD tol,Integer maxit,LinearOperatorBase<Field> &_Linop,LinearFunction<Field> &Prec,int _mmax,int _nstep) : 
    Tolerance(tol), 
    MaxIterations(maxit),
    Linop(_Linop),
    Preconditioner(Prec),
    mmax(_mmax),
    nstep(_nstep)
  { 
    level=1;
    verbose=1;
  };
  void operator() (const Field &src, Field &psi){
    psi=Zero();
    RealD cp, ssq,rsq;
    ssq=norm2(src);
    rsq=Tolerance*Tolerance*ssq;
    Field r(src.Grid());
    PrecTimer.Reset();
    MatTimer.Reset();
    LinalgTimer.Reset();
    GridStopWatch SolverTimer;
    SolverTimer.Start();
    steps=0;
    for(int k=0;k<MaxIterations;k++){
      cp=GCRnStep(src,psi,rsq);
      GCRLogLevel <<"PGCR("<<mmax<<","<<nstep<<") "<< steps <<" steps cp = "<<cp<<" target "<<rsq <<std::endl;
      if(cp<rsq) {
 	SolverTimer.Stop();
 	Linop.HermOp(psi,r);
 	axpy(r,-1.0,src,r);
 	RealD tr = norm2(r);
 	GCRLogLevel<<"PGCR: Converged on iteration " <<steps
 		 << " computed residual "<<sqrt(cp/ssq)
 		 << " true residual "    <<sqrt(tr/ssq)
 		 << " target "           <<Tolerance <<std::endl;
 	GCRLogLevel<<"PGCR Time elapsed: Total  "<< SolverTimer.Elapsed() <<std::endl;
 	/*
 	  GCRLogLevel<<"PGCR Time elapsed: Precon "<<   PrecTimer.Elapsed() <<std::endl;
 	  GCRLogLevel<<"PGCR Time elapsed: Matrix "<<    MatTimer.Elapsed() <<std::endl;
 	  GCRLogLevel<<"PGCR Time elapsed: Linalg "<< LinalgTimer.Elapsed() <<std::endl;
 	*/
 	return;
      }
    }
    GCRLogLevel<<"Variable Preconditioned GCR did not converge"<<std::endl;
    //    assert(0);
  }
  RealD GCRnStep(const Field &src, Field &psi,RealD rsq){
    RealD cp;
    RealD a, b;
    RealD zAz, zAAz;
    RealD rq;
    GridBase *grid = src.Grid();
    Field r(grid);
    Field z(grid);
    Field tmp(grid);
    Field ttmp(grid);
    Field Az(grid);
    ////////////////////////////////
    // history for flexible orthog
    ////////////////////////////////
    std::vector<Field> q(mmax,grid);
    std::vector<Field> p(mmax,grid);
    std::vector<RealD> qq(mmax);
    GCRLogLevel<< "PGCR nStep("<<nstep<<")"<<std::endl;
    //////////////////////////////////
    // initial guess x0 is taken as nonzero.
    // r0=src-A x0 = src
    //////////////////////////////////
    MatTimer.Start();
    Linop.HermOpAndNorm(psi,Az,zAz,zAAz); 
    MatTimer.Stop();
    LinalgTimer.Start();
    r=src-Az;
    LinalgTimer.Stop();
    GCRLogLevel<< "PGCR true residual r = src - A psi   "<<norm2(r) <<std::endl;
    /////////////////////
    // p = Prec(r)
    /////////////////////
    PrecTimer.Start();
    Preconditioner(r,z);
    PrecTimer.Stop();
    MatTimer.Start();
    Linop.HermOpAndNorm(z,Az,zAz,zAAz); 
    MatTimer.Stop();
    LinalgTimer.Start();
    //p[0],q[0],qq[0] 
    p[0]= z;
    q[0]= Az;
    qq[0]= zAAz;
    cp =norm2(r);
    LinalgTimer.Stop();
    for(int k=0;k<nstep;k++){
      steps++;
      int kp     = k+1;
      int peri_k = k %mmax;
      int peri_kp= kp%mmax;
      LinalgTimer.Start();
      rq= real(innerProduct(r,q[peri_k])); // what if rAr not real?
      a = rq/qq[peri_k];
      axpy(psi,a,p[peri_k],psi);         
      cp = axpy_norm(r,-a,q[peri_k],r);
      LinalgTimer.Stop();
      GCRLogLevel<< "PGCR step["<<steps<<"]  resid " << cp << " target " <<rsq<<std::endl; 
      if((k==nstep-1)||(cp<rsq)){
 	return cp;
      }
      PrecTimer.Start();
      Preconditioner(r,z);// solve Az = r
      PrecTimer.Stop();
      MatTimer.Start();
      Linop.HermOpAndNorm(z,Az,zAz,zAAz);
      MatTimer.Stop();
      LinalgTimer.Start();
      q[peri_kp]=Az;
      p[peri_kp]=z;
      int northog = ((kp)>(mmax-1))?(mmax-1):(kp);  // if more than mmax done, we orthog all mmax history.
      for(int back=0;back<northog;back++){
 	int peri_back=(k-back)%mmax;   	  assert((k-back)>=0);
 	b=-real(innerProduct(q[peri_back],Az))/qq[peri_back];
 	p[peri_kp]=p[peri_kp]+b*p[peri_back];
 	q[peri_kp]=q[peri_kp]+b*q[peri_back];
      }
      qq[peri_kp]=norm2(q[peri_kp]); // could use axpy_norm
      LinalgTimer.Stop();
    }
    assert(0); // never reached
    return cp;
  }
 };
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/algorithms/iterative/PrecGeneralisedConjugateResidualNonHermitian.h
+++ b/Grid/algorithms/iterative/PrecGeneralisedConjugateResidualNonHermitian.h
@@ -0,0 +1,242 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./lib/algorithms/iterative/PrecGeneralisedConjugateResidual.h
    Copyright (C) 2015
 Author: Azusa Yamaguchi <ayamaguc@staffmail.ed.ac.uk>
 Author: Peter Boyle <paboyle@ph.ed.ac.uk>
    This program is free software; you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation; either version 2 of the License, or
    (at your option) any later version.
    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.
    You should have received a copy of the GNU General Public License along
    with this program; if not, write to the Free Software Foundation, Inc.,
    51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
    See the full license in the file "LICENSE" in the top level distribution directory
 *************************************************************************************/
 /*  END LEGAL */
 #ifndef GRID_PREC_GCR_NON_HERM_H
 #define GRID_PREC_GCR_NON_HERM_H
 ///////////////////////////////////////////////////////////////////////////////////////////////////////
 //VPGCR Abe and Zhang, 2005.
 //INTERNATIONAL JOURNAL OF NUMERICAL ANALYSIS AND MODELING
 //Computing and Information Volume 2, Number 2, Pages 147-161
 //NB. Likely not original reference since they are focussing on a preconditioner variant.
 //    but VPGCR was nicely written up in their paper
 ///////////////////////////////////////////////////////////////////////////////////////////////////////
 NAMESPACE_BEGIN(Grid);
 #define GCRLogLevel std::cout << GridLogMessage <<std::string(level,'\t')<< " Level "<<level<<" " 
 template<class Field>
 class PrecGeneralisedConjugateResidualNonHermitian : public LinearFunction<Field> {
 public:                                                
  using LinearFunction<Field>::operator();
  RealD   Tolerance;
  Integer MaxIterations;
  int verbose;
  int mmax;
  int nstep;
  int steps;
  int level;
  GridStopWatch PrecTimer;
  GridStopWatch MatTimer;
  GridStopWatch LinalgTimer;
  LinearFunction<Field>     &Preconditioner;
  LinearOperatorBase<Field> &Linop;
  void Level(int lv) { level=lv; };
  PrecGeneralisedConjugateResidualNonHermitian(RealD tol,Integer maxit,LinearOperatorBase<Field> &_Linop,LinearFunction<Field> &Prec,int _mmax,int _nstep) : 
    Tolerance(tol), 
    MaxIterations(maxit),
    Linop(_Linop),
    Preconditioner(Prec),
    mmax(_mmax),
    nstep(_nstep)
  { 
    level=1;
    verbose=1;
  };
  void operator() (const Field &src, Field &psi){
    psi=Zero();
    RealD cp, ssq,rsq;
    ssq=norm2(src);
    rsq=Tolerance*Tolerance*ssq;
    Field r(src.Grid());
    PrecTimer.Reset();
    MatTimer.Reset();
    LinalgTimer.Reset();
    GridStopWatch SolverTimer;
    SolverTimer.Start();
    steps=0;
    for(int k=0;k<MaxIterations;k++){
      cp=GCRnStep(src,psi,rsq);
      GCRLogLevel <<"PGCR("<<mmax<<","<<nstep<<") "<< steps <<" steps cp = "<<cp<<" target "<<rsq <<std::endl;
      if(cp<rsq) {
 	SolverTimer.Stop();
 	Linop.Op(psi,r);
 	axpy(r,-1.0,src,r);
 	RealD tr = norm2(r);
 	GCRLogLevel<<"PGCR: Converged on iteration " <<steps
 		 << " computed residual "<<sqrt(cp/ssq)
 		 << " true residual "    <<sqrt(tr/ssq)
 		 << " target "           <<Tolerance <<std::endl;
 	GCRLogLevel<<"PGCR Time elapsed: Total  "<< SolverTimer.Elapsed() <<std::endl;
 	return;
      }
    }
    GCRLogLevel<<"Variable Preconditioned GCR did not converge"<<std::endl;
    //    assert(0);
  }
  RealD GCRnStep(const Field &src, Field &psi,RealD rsq){
    RealD cp;
    ComplexD a, b;
    //    ComplexD zAz;
    RealD zAAz;
    ComplexD rq;
    GridBase *grid = src.Grid();
    Field r(grid);
    Field z(grid);
    Field tmp(grid);
    Field ttmp(grid);
    Field Az(grid);
    ////////////////////////////////
    // history for flexible orthog
    ////////////////////////////////
    std::vector<Field> q(mmax,grid);
    std::vector<Field> p(mmax,grid);
    std::vector<RealD> qq(mmax);
    GCRLogLevel<< "PGCR nStep("<<nstep<<")"<<std::endl;
    //////////////////////////////////
    // initial guess x0 is taken as nonzero.
    // r0=src-A x0 = src
    //////////////////////////////////
    MatTimer.Start();
    Linop.Op(psi,Az);
    //    zAz = innerProduct(Az,psi);
    zAAz= norm2(Az);
    MatTimer.Stop();
    LinalgTimer.Start();
    r=src-Az;
    LinalgTimer.Stop();
    GCRLogLevel<< "PGCR true residual r = src - A psi   "<<norm2(r) <<std::endl;
    /////////////////////
    // p = Prec(r)
    /////////////////////
    PrecTimer.Start();
    Preconditioner(r,z);
    PrecTimer.Stop();
    MatTimer.Start();
    Linop.Op(z,Az);
    MatTimer.Stop();
    LinalgTimer.Start();
    //    zAz = innerProduct(Az,psi);
    zAAz= norm2(Az);
    //p[0],q[0],qq[0] 
    p[0]= z;
    q[0]= Az;
    qq[0]= zAAz;
    cp =norm2(r);
    LinalgTimer.Stop();
    for(int k=0;k<nstep;k++){
      steps++;
      int kp     = k+1;
      int peri_k = k %mmax;
      int peri_kp= kp%mmax;
      LinalgTimer.Start();
      rq= innerProduct(q[peri_k],r); // what if rAr not real?
      a = rq/qq[peri_k];
      axpy(psi,a,p[peri_k],psi);         
      cp = axpy_norm(r,-a,q[peri_k],r);
      LinalgTimer.Stop();
      GCRLogLevel<< "PGCR step["<<steps<<"]  resid " << cp << " target " <<rsq<<std::endl; 
      if((k==nstep-1)||(cp<rsq)){
 	return cp;
      }
      PrecTimer.Start();
      Preconditioner(r,z);// solve Az = r
      PrecTimer.Stop();
      MatTimer.Start();
      Linop.Op(z,Az);
      MatTimer.Stop();
      //      zAz = innerProduct(Az,psi);
      zAAz= norm2(Az);
      LinalgTimer.Start();
      q[peri_kp]=Az;
      p[peri_kp]=z;
      int northog = ((kp)>(mmax-1))?(mmax-1):(kp);  // if more than mmax done, we orthog all mmax history.
      for(int back=0;back<northog;back++){
 	int peri_back=(k-back)%mmax;   	  assert((k-back)>=0);
 	b=-real(innerProduct(q[peri_back],Az))/qq[peri_back];
 	p[peri_kp]=p[peri_kp]+b*p[peri_back];
 	q[peri_kp]=q[peri_kp]+b*q[peri_back];
      }
      qq[peri_kp]=norm2(q[peri_kp]); // could use axpy_norm
      LinalgTimer.Stop();
    }
    assert(0); // never reached
    return cp;
  }
 };
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/algorithms/iterative/QuasiMinimalResidual.h
+++ b/Grid/algorithms/iterative/QuasiMinimalResidual.h
@@ -0,0 +1,371 @@
 /*************************************************************************************
 Grid physics library, www.github.com/paboyle/Grid
 Source file: ./lib/algorithmsf/iterative/QuasiMinimalResidual.h
 Copyright (C) 2019
 Author: Peter Boyle <paboyle@ph.ed.ac.uk>
 This program is free software; you can redistribute it and/or modify
 it under the terms of the GNU General Public License as published by
 the Free Software Foundation; either version 2 of the License, or
 (at your option) any later version.
 This program is distributed in the hope that it will be useful,
 but WITHOUT ANY WARRANTY; without even the implied warranty of
 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 GNU General Public License for more details.
 You should have received a copy of the GNU General Public License along
 with this program; if not, write to the Free Software Foundation, Inc.,
 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
 See the full license in the file "LICENSE" in the top level distribution
 directory
 *************************************************************************************/
 /*  END LEGAL */
 #pragma once
 NAMESPACE_BEGIN(Grid);
 template<class Field> 
 RealD innerG5ProductReal(Field &l, Field &r)
 {
  Gamma G5(Gamma::Algebra::Gamma5);
  Field tmp(l.Grid());
  //  tmp = G5*r;
  G5R5(tmp,r);
  ComplexD ip =innerProduct(l,tmp);
  std::cout << "innerProductRealG5R5 "<<ip<<std::endl;
  return ip.real();
 }
 template<class Field>
 class QuasiMinimalResidual : public OperatorFunction<Field> {
 public:
  using OperatorFunction<Field>::operator();
  bool ErrorOnNoConverge; 
  RealD   Tolerance;
  Integer MaxIterations;
  Integer IterationCount;
  QuasiMinimalResidual(RealD   tol,
 		       Integer maxit,
 		       bool    err_on_no_conv = true)
      : Tolerance(tol)
      , MaxIterations(maxit)
      , ErrorOnNoConverge(err_on_no_conv) 
  {};
 #if 1
  void operator()(LinearOperatorBase<Field> &LinOp, const Field &b, Field &x) 
  {
    RealD resid;
    IterationCount=0;
    RealD  rho, rho_1, xi, gamma, gamma_1, theta, theta_1;
    RealD  eta, delta, ep, beta; 
    GridBase *Grid = b.Grid();
    Field r(Grid), d(Grid), s(Grid);
    Field v(Grid), w(Grid), y(Grid),  z(Grid);
    Field v_tld(Grid), w_tld(Grid), y_tld(Grid), z_tld(Grid);
    Field p(Grid), q(Grid), p_tld(Grid);
    Real normb = norm2(b);
    LinOp.Op(x,r); r = b - r;
    assert(normb> 0.0);
    resid = norm2(r)/normb;
    if (resid <= Tolerance) {
      return;
    }
    v_tld = r;
    y = v_tld;
    rho = norm2(y);
    // Take Gamma5 conjugate
    //    Gamma G5(Gamma::Algebra::Gamma5);
    //    G5R5(w_tld,r);
    //    w_tld = G5* v_tld;
    w_tld=v_tld;
    z = w_tld;
    xi = norm2(z);
    gamma = 1.0;
    eta   = -1.0;
    theta = 0.0;
    for (int i = 1; i <= MaxIterations; i++) {
      // Breakdown tests
      assert( rho != 0.0);
      assert( xi  != 0.0);
      v = (1. / rho) * v_tld;
      y = (1. / rho) * y;
      w = (1. / xi) * w_tld;
      z = (1. / xi) * z;
      ComplexD Zdelta = innerProduct(z, y); // Complex?
      std::cout << "Zdelta "<<Zdelta<<std::endl;
      delta = Zdelta.real();
      y_tld = y; 
      z_tld = z;
      if (i > 1) {
 	p = y_tld - (xi  * delta / ep) * p;
 	q = z_tld - (rho * delta / ep) * q;
      } else {
 	p = y_tld;
 	q = z_tld;
      }
      LinOp.Op(p,p_tld);      //     p_tld = A * p;
      ComplexD Zep = innerProduct(q, p_tld);
      ep=Zep.real();
      std::cout << "Zep "<<Zep <<std::endl;
      // Complex Audit
      assert(abs(ep)>0);
      beta = ep / delta;
      assert(abs(beta)>0);
      v_tld = p_tld - beta * v;
      y = v_tld;
      rho_1 = rho;
      rho   = norm2(y);
      LinOp.AdjOp(q,w_tld);
      w_tld = w_tld - beta * w;
      z = w_tld;
      xi = norm2(z);
      gamma_1 = gamma;
      theta_1 = theta;
      theta   = rho / (gamma_1 * beta);
      gamma   = 1.0 / sqrt(1.0 + theta * theta);
      std::cout << "theta "<<theta<<std::endl;
      std::cout << "gamma "<<gamma<<std::endl;
      assert(abs(gamma)> 0.0);
      eta = -eta * rho_1 * gamma* gamma / (beta * gamma_1 * gamma_1);
      if (i > 1) {
 	d = eta * p + (theta_1 * theta_1 * gamma * gamma) * d;
 	s = eta * p_tld + (theta_1 * theta_1 * gamma * gamma) * s;
      } else {
 	d = eta * p;
 	s = eta * p_tld;
      }
      x =x+d;                            // update approximation vector
      r =r-s;                            // compute residual
      if ((resid = norm2(r) / normb) <= Tolerance) {
 	return;
      }
      std::cout << "Iteration "<<i<<" resid " << resid<<std::endl;
    }
    assert(0);
    return;                            // no convergence
  }
 #else
  // QMRg5 SMP thesis
  void operator()(LinearOperatorBase<Field> &LinOp, const Field &b, Field &x) 
  {
    // Real scalars
    GridBase *grid = b.Grid();
    Field    r(grid);
    Field    p_m(grid), p_m_minus_1(grid), p_m_minus_2(grid);
    Field    v_m(grid), v_m_minus_1(grid), v_m_plus_1(grid);
    Field    tmp(grid);
    RealD    w;
    RealD    z1, z2;
    RealD    delta_m, delta_m_minus_1;
    RealD    c_m_plus_1, c_m, c_m_minus_1;
    RealD    s_m_plus_1, s_m, s_m_minus_1;
    RealD    alpha, beta, gamma, epsilon;
    RealD    mu, nu, rho, theta, xi, chi;
    RealD    mod2r, mod2b;
    RealD    tau2, target2;
    mod2b=norm2(b);
    /////////////////////////
    // Initial residual
    /////////////////////////
    LinOp.Op(x,tmp);
    r = b - tmp;
    /////////////////////////
    // \mu = \rho = |r_0|
    /////////////////////////
    mod2r = norm2(r);
    rho = sqrt( mod2r);
    mu=rho;
    std::cout << "QuasiMinimalResidual rho "<< rho<<std::endl;
    /////////////////////////
    // Zero negative history
    /////////////////////////
    v_m_plus_1  = Zero();
    v_m_minus_1 = Zero();
    p_m_minus_1 = Zero();
    p_m_minus_2 = Zero();
    // v0
    v_m = (1.0/rho)*r;
    /////////////////////////
    // Initial coeffs
    /////////////////////////
    delta_m_minus_1 = 1.0;
    c_m_minus_1     = 1.0;
    c_m             = 1.0;
    s_m_minus_1     = 0.0;
    s_m             = 0.0;
    /////////////////////////
    // Set up convergence check
    /////////////////////////
    tau2    = mod2r;
    target2 = mod2b * Tolerance*Tolerance;
    for(int iter = 0 ; iter < MaxIterations; iter++){
      /////////////////////////
      // \delta_m = (v_m, \gamma_5 v_m) 
      /////////////////////////
      delta_m = innerG5ProductReal(v_m,v_m);
      std::cout << "QuasiMinimalResidual delta_m "<< delta_m<<std::endl;
      /////////////////////////
      // tmp = A v_m
      /////////////////////////
      LinOp.Op(v_m,tmp);
      /////////////////////////
      // \alpha = (v_m, \gamma_5 temp) / \delta_m 
      /////////////////////////
      alpha = innerG5ProductReal(v_m,tmp);
      alpha = alpha/delta_m ;
      std::cout << "QuasiMinimalResidual alpha "<< alpha<<std::endl;
      /////////////////////////
      // \beta = \rho \delta_m / \delta_{m-1}
      /////////////////////////
      beta = rho * delta_m / delta_m_minus_1;
      std::cout << "QuasiMinimalResidual beta "<< beta<<std::endl;
      /////////////////////////
      // \tilde{v}_{m+1} = temp - \alpha v_m - \beta v_{m-1}
      /////////////////////////
      v_m_plus_1 = tmp - alpha*v_m - beta*v_m_minus_1;
      ///////////////////////////////
      // \rho = || \tilde{v}_{m+1} ||
      ///////////////////////////////
      rho = sqrt( norm2(v_m_plus_1) );
      std::cout << "QuasiMinimalResidual rho "<< rho<<std::endl;
      ///////////////////////////////
      //      v_{m+1} = \tilde{v}_{m+1}
      ///////////////////////////////
      v_m_plus_1 = (1.0 / rho) * v_m_plus_1;
      ////////////////////////////////
      // QMR recurrence coefficients.
      ////////////////////////////////
      theta      = s_m_minus_1 * beta;
      gamma      = c_m_minus_1 * beta;
      epsilon    =  c_m * gamma + s_m * alpha;
      xi         = -s_m * gamma + c_m * alpha;
      nu         = sqrt( xi*xi + rho*rho );
      c_m_plus_1 = fabs(xi) / nu;
      if ( xi == 0.0 ) {
 	s_m_plus_1 = 1.0;
      } else {
 	s_m_plus_1 = c_m_plus_1 * rho / xi;
      }
      chi = c_m_plus_1 * xi + s_m_plus_1 * rho;
      std::cout << "QuasiMinimalResidual coeffs "<< theta <<" "<<gamma<<" "<< epsilon<<" "<< xi<<" "<< nu<<std::endl;
      std::cout << "QuasiMinimalResidual coeffs "<< chi   <<std::endl;
      ////////////////////////////////
      //p_m=(v_m - \epsilon p_{m-1} - \theta p_{m-2}) / \chi
      ////////////////////////////////
      p_m = (1.0/chi) * v_m - (epsilon/chi) * p_m_minus_1 - (theta/chi) * p_m_minus_2;
      ////////////////////////////////////////////////////////////////
      //      \psi = \psi + c_{m+1} \mu p_m	
      ////////////////////////////////////////////////////////////////
      x = x + ( c_m_plus_1 * mu ) * p_m;
      ////////////////////////////////////////
      //
      ////////////////////////////////////////
      mu              = -s_m_plus_1 * mu;
      delta_m_minus_1 = delta_m;
      c_m_minus_1     = c_m;
      c_m             = c_m_plus_1;
      s_m_minus_1     = s_m;
      s_m             = s_m_plus_1;
      ////////////////////////////////////
      // Could use pointer swizzle games.
      ////////////////////////////////////
      v_m_minus_1 = v_m;
      v_m         = v_m_plus_1;
      p_m_minus_2 = p_m_minus_1;
      p_m_minus_1 = p_m;
      /////////////////////////////////////
      // Convergence checks
      /////////////////////////////////////
      z1 = RealD(iter+1.0);
      z2 = z1 + 1.0;
      tau2 = tau2 *( z2 / z1 ) * s_m * s_m;
      std::cout << " QuasiMinimumResidual iteration "<< iter<<std::endl;
      std::cout << " QuasiMinimumResidual tau bound "<< tau2<<std::endl;
      // Compute true residual
      mod2r = tau2;
      if ( 1 || (tau2 < (100.0 * target2)) ) {
 	LinOp.Op(x,tmp);
 	r = b - tmp;
 	mod2r = norm2(r);
 	std::cout << " QuasiMinimumResidual true residual is "<< mod2r<<std::endl;
      }
      if ( mod2r < target2 ) { 
 	std::cout << " QuasiMinimumResidual has converged"<<std::endl;
 	return;
      }
    }
  }
 #endif
 };
 NAMESPACE_END(Grid);
--- a/Grid/algorithms/iterative/SchurRedBlack.h
+++ b/Grid/algorithms/iterative/SchurRedBlack.h
@@ -0,0 +1,651 @@
    /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./lib/algorithms/iterative/SchurRedBlack.h
    Copyright (C) 2015
 Author: Peter Boyle <paboyle@ph.ed.ac.uk>
    This program is free software; you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation; either version 2 of the License, or
    (at your option) any later version.
    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.
    You should have received a copy of the GNU General Public License along
    with this program; if not, write to the Free Software Foundation, Inc.,
    51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
    See the full license in the file "LICENSE" in the top level distribution directory
    *************************************************************************************/
    /*  END LEGAL */
 #ifndef GRID_SCHUR_RED_BLACK_H
 #define GRID_SCHUR_RED_BLACK_H
  /*
   * Red black Schur decomposition
   *
   *  M = (Mee Meo) =  (1             0 )   (Mee   0               )  (1 Mee^{-1} Meo)
   *      (Moe Moo)    (Moe Mee^-1    1 )   (0   Moo-Moe Mee^-1 Meo)  (0   1         )
   *                =         L                     D                     U
   *
   * L^-1 = (1              0 )
   *        (-MoeMee^{-1}   1 )   
   * L^{dag} = ( 1       Mee^{-dag} Moe^{dag} )
   *           ( 0       1                    )
   * L^{-d}  = ( 1      -Mee^{-dag} Moe^{dag} )
   *           ( 0       1                    )
   *
   * U^-1 = (1   -Mee^{-1} Meo)
   *        (0    1           )
   * U^{dag} = ( 1                 0)
   *           (Meo^dag Mee^{-dag} 1)
   * U^{-dag} = (  1                 0)
   *            (-Meo^dag Mee^{-dag} 1)
   ***********************
   *     M psi = eta
   ***********************
   *Odd
   * i)                 D_oo psi_o =  L^{-1}  eta_o
   *                        eta_o' = (D_oo)^dag (eta_o - Moe Mee^{-1} eta_e)
   *
   * Wilson:
   *      (D_oo)^{\dag} D_oo psi_o = (D_oo)^dag L^{-1}  eta_o
   * Stag:
   *      D_oo psi_o = L^{-1}  eta =    (eta_o - Moe Mee^{-1} eta_e)
   *
   * L^-1 eta_o= (1              0 ) (e
   *             (-MoeMee^{-1}   1 )   
   *
   *Even
   * ii)  Mee psi_e + Meo psi_o = src_e
   *
   *   => sol_e = M_ee^-1 * ( src_e - Meo sol_o )...
   *
   * 
   * TODO: Other options:
   * 
   * a) change checkerboards for Schur e<->o
   *
   * Left precon by Moo^-1
   * b) Doo^{dag} M_oo^-dag Moo^-1 Doo psi_0 =  (D_oo)^dag M_oo^-dag Moo^-1 L^{-1}  eta_o
   *                              eta_o'     = (D_oo)^dag  M_oo^-dag Moo^-1 (eta_o - Moe Mee^{-1} eta_e)
   *
   * Right precon by Moo^-1
   * c) M_oo^-dag Doo^{dag} Doo Moo^-1 phi_0 = M_oo^-dag (D_oo)^dag L^{-1}  eta_o
   *                              eta_o'     = M_oo^-dag (D_oo)^dag (eta_o - Moe Mee^{-1} eta_e)
   *                              psi_o = M_oo^-1 phi_o
   * TODO: Deflation 
   */
 namespace Grid {
  ///////////////////////////////////////////////////////////////////////////////////////////////////////
  // Use base class to share code
  ///////////////////////////////////////////////////////////////////////////////////////////////////////
  ///////////////////////////////////////////////////////////////////////////////////////////////////////
  // Take a matrix and form a Red Black solver calling a Herm solver
  // Use of RB info prevents making SchurRedBlackSolve conform to standard interface
  ///////////////////////////////////////////////////////////////////////////////////////////////////////
  template<class Field> class SchurRedBlackBase {
  protected:
    typedef CheckerBoardedSparseMatrixBase<Field> Matrix;
    OperatorFunction<Field> & _HermitianRBSolver;
    int CBfactorise;
    bool subGuess;
    bool useSolnAsInitGuess; // if true user-supplied solution vector is used as initial guess for solver
  public:
    SchurRedBlackBase(OperatorFunction<Field> &HermitianRBSolver, const bool initSubGuess = false,
        const bool _solnAsInitGuess = false)  :
    _HermitianRBSolver(HermitianRBSolver),
    useSolnAsInitGuess(_solnAsInitGuess)
    { 
      CBfactorise = 0;
      subtractGuess(initSubGuess);
    };
    void subtractGuess(const bool initSubGuess)
    {
      subGuess = initSubGuess;
    }
    bool isSubtractGuess(void)
    {
      return subGuess;
    }
    /////////////////////////////////////////////////////////////
    // Shared code
    /////////////////////////////////////////////////////////////
    void operator() (Matrix & _Matrix,const Field &in, Field &out){
      ZeroGuesser<Field> guess;
      (*this)(_Matrix,in,out,guess);
    }
    void operator()(Matrix &_Matrix, const std::vector<Field> &in, std::vector<Field> &out) 
    {
      ZeroGuesser<Field> guess;
      (*this)(_Matrix,in,out,guess);
    }
    void RedBlackSource(Matrix &_Matrix, const std::vector<Field> &in, std::vector<Field> &src_o) 
    {
      GridBase *grid = _Matrix.RedBlackGrid();
      Field tmp(grid);
      int nblock = in.size();
      for(int b=0;b<nblock;b++){
 	RedBlackSource(_Matrix,in[b],tmp,src_o[b]);
      }
    }
    // James can write his own deflated guesser
    // with optimised code for the inner products
    //    RedBlackSolveSplitGrid();
    //    RedBlackSolve(_Matrix,src_o,sol_o); 
    void RedBlackSolution(Matrix &_Matrix, const std::vector<Field> &in, const std::vector<Field> &sol_o, std::vector<Field> &out)
    {
      GridBase *grid = _Matrix.RedBlackGrid();
      Field tmp(grid);
      int nblock = in.size();
      for(int b=0;b<nblock;b++) {
 	pickCheckerboard(Even,tmp,in[b]);
 	RedBlackSolution(_Matrix,sol_o[b],tmp,out[b]);
      }
    }
    template<class Guesser>
    void operator()(Matrix &_Matrix, const std::vector<Field> &in, std::vector<Field> &out,Guesser &guess) 
    {
      GridBase *grid = _Matrix.RedBlackGrid();
      GridBase *fgrid= _Matrix.Grid();
      int nblock = in.size();
      std::vector<Field> src_o(nblock,grid);
      std::vector<Field> sol_o(nblock,grid);
      std::vector<Field> guess_save;
      Field resid(fgrid);
      Field tmp(grid);
      ////////////////////////////////////////////////
      // Prepare RedBlack source
      ////////////////////////////////////////////////
      RedBlackSource(_Matrix,in,src_o);
 	//      for(int b=0;b<nblock;b++){
 	//	RedBlackSource(_Matrix,in[b],tmp,src_o[b]);
 	//      }
      ////////////////////////////////////////////////
      // Make the guesses
      ////////////////////////////////////////////////
      if ( subGuess ) guess_save.resize(nblock,grid);
      if(useSolnAsInitGuess) {
        for(int b=0;b<nblock;b++){
          pickCheckerboard(Odd, sol_o[b], out[b]);
        }
      } else {
        guess(src_o, sol_o); 
      }
 	    if ( subGuess ) { 
        for(int b=0;b<nblock;b++){
          guess_save[b] = sol_o[b];
        }
      }
      //////////////////////////////////////////////////////////////
      // Call the block solver
      //////////////////////////////////////////////////////////////
      std::cout<<GridLogMessage << "SchurRedBlackBase calling the solver for "<<nblock<<" RHS" <<std::endl;
      RedBlackSolve(_Matrix,src_o,sol_o);
      ////////////////////////////////////////////////
      // A2A boolean behavioural control & reconstruct other checkerboard
      ////////////////////////////////////////////////
      for(int b=0;b<nblock;b++) {
 	if (subGuess)   sol_o[b] = sol_o[b] - guess_save[b];
 	///////// Needs even source //////////////
 	pickCheckerboard(Even,tmp,in[b]);
 	RedBlackSolution(_Matrix,sol_o[b],tmp,out[b]);
 	/////////////////////////////////////////////////
 	// Check unprec residual if possible
 	/////////////////////////////////////////////////
 	if ( ! subGuess ) {
 	  _Matrix.M(out[b],resid); 
 	  resid = resid-in[b];
 	  RealD ns = norm2(in[b]);
 	  RealD nr = norm2(resid);
 	  std::cout<<GridLogMessage<< "SchurRedBlackBase solver true unprec resid["<<b<<"] "<<std::sqrt(nr/ns) << std::endl;
 	} else {
 	  std::cout<<GridLogMessage<< "SchurRedBlackBase Guess subtracted after solve["<<b<<"] " << std::endl;
 	}
      }
    }
    template<class Guesser>
    void operator() (Matrix & _Matrix,const Field &in, Field &out,Guesser &guess){
      // FIXME CGdiagonalMee not implemented virtual function
      // FIXME use CBfactorise to control schur decomp
      GridBase *grid = _Matrix.RedBlackGrid();
      GridBase *fgrid= _Matrix.Grid();
      Field resid(fgrid);
      Field src_o(grid);
      Field src_e(grid);
      Field sol_o(grid);
      ////////////////////////////////////////////////
      // RedBlack source
      ////////////////////////////////////////////////
      RedBlackSource(_Matrix,in,src_e,src_o);
      ////////////////////////////////
      // Construct the guess
      ////////////////////////////////
      if(useSolnAsInitGuess) {
        pickCheckerboard(Odd, sol_o, out);
      } else {
        guess(src_o,sol_o);
      }
      Field  guess_save(grid);
      guess_save = sol_o;
      //////////////////////////////////////////////////////////////
      // Call the red-black solver
      //////////////////////////////////////////////////////////////
      RedBlackSolve(_Matrix,src_o,sol_o);
      ////////////////////////////////////////////////
      // Fionn A2A boolean behavioural control
      ////////////////////////////////////////////////
      if (subGuess)      sol_o= sol_o-guess_save;
      ///////////////////////////////////////////////////
      // RedBlack solution needs the even source
      ///////////////////////////////////////////////////
      RedBlackSolution(_Matrix,sol_o,src_e,out);
      // Verify the unprec residual
      if ( ! subGuess ) {
        _Matrix.M(out,resid); 
        resid = resid-in;
        RealD ns = norm2(in);
        RealD nr = norm2(resid);
        std::cout<<GridLogMessage << "SchurRedBlackBase solver true unprec resid "<< std::sqrt(nr/ns) << std::endl;
      } else {
        std::cout << GridLogMessage << "SchurRedBlackBase Guess subtracted after solve." << std::endl;
      }
    }     
    /////////////////////////////////////////////////////////////
    // Override in derived. 
    /////////////////////////////////////////////////////////////
    virtual void RedBlackSource  (Matrix & _Matrix,const Field &src, Field &src_e,Field &src_o)                =0;
    virtual void RedBlackSolution(Matrix & _Matrix,const Field &sol_o, const Field &src_e,Field &sol)          =0;
    virtual void RedBlackSolve   (Matrix & _Matrix,const Field &src_o, Field &sol_o)                           =0;
    virtual void RedBlackSolve   (Matrix & _Matrix,const std::vector<Field> &src_o,  std::vector<Field> &sol_o)=0;
  };
  template<class Field> class SchurRedBlackStaggeredSolve : public SchurRedBlackBase<Field> {
  public:
    typedef CheckerBoardedSparseMatrixBase<Field> Matrix;
    SchurRedBlackStaggeredSolve(OperatorFunction<Field> &HermitianRBSolver, const bool initSubGuess = false,
        const bool _solnAsInitGuess = false) 
      :    SchurRedBlackBase<Field> (HermitianRBSolver,initSubGuess,_solnAsInitGuess) 
    {
    }
    //////////////////////////////////////////////////////
    // Override RedBlack specialisation
    //////////////////////////////////////////////////////
    virtual void RedBlackSource(Matrix & _Matrix,const Field &src, Field &src_e,Field &src_o)
    {
      GridBase *grid = _Matrix.RedBlackGrid();
      GridBase *fgrid= _Matrix.Grid();
      Field   tmp(grid);
      Field  Mtmp(grid);
      pickCheckerboard(Even,src_e,src);
      pickCheckerboard(Odd ,src_o,src);
      /////////////////////////////////////////////////////
      // src_o = (source_o - Moe MeeInv source_e)
      /////////////////////////////////////////////////////
      _Matrix.MooeeInv(src_e,tmp);     assert(  tmp.Checkerboard() ==Even);
      _Matrix.Meooe   (tmp,Mtmp);      assert( Mtmp.Checkerboard() ==Odd);     
      tmp=src_o-Mtmp;                  assert(  tmp.Checkerboard() ==Odd);     
      _Matrix.Mooee(tmp,src_o); // Extra factor of "m" in source from dumb choice of matrix norm.
    }
    virtual void RedBlackSolution(Matrix & _Matrix,const Field &sol_o, const Field &src_e_c,Field &sol)
    {
      GridBase *grid = _Matrix.RedBlackGrid();
      GridBase *fgrid= _Matrix.Grid();
      Field   tmp(grid);
      Field   sol_e(grid);
      Field   src_e(grid);
      src_e = src_e_c; // Const correctness
      ///////////////////////////////////////////////////
      // sol_e = M_ee^-1 * ( src_e - Meo sol_o )...
      ///////////////////////////////////////////////////
      _Matrix.Meooe(sol_o,tmp);        assert(  tmp.Checkerboard()   ==Even);
      src_e = src_e-tmp;               assert(  src_e.Checkerboard() ==Even);
      _Matrix.MooeeInv(src_e,sol_e);   assert(  sol_e.Checkerboard() ==Even);
      setCheckerboard(sol,sol_e); assert(  sol_e.Checkerboard() ==Even);
      setCheckerboard(sol,sol_o); assert(  sol_o.Checkerboard() ==Odd );
    }
    virtual void RedBlackSolve   (Matrix & _Matrix,const Field &src_o, Field &sol_o)
    {
      SchurStaggeredOperator<Matrix,Field> _HermOpEO(_Matrix);
      this->_HermitianRBSolver(_HermOpEO,src_o,sol_o);  assert(sol_o.Checkerboard()==Odd);
    };
    virtual void RedBlackSolve   (Matrix & _Matrix,const std::vector<Field> &src_o,  std::vector<Field> &sol_o)
    {
      SchurStaggeredOperator<Matrix,Field> _HermOpEO(_Matrix);
      this->_HermitianRBSolver(_HermOpEO,src_o,sol_o); 
    }
  };
  template<class Field> using SchurRedBlackStagSolve = SchurRedBlackStaggeredSolve<Field>;
  ///////////////////////////////////////////////////////////////////////////////////////////////////////
  // Site diagonal has Mooee on it.
  ///////////////////////////////////////////////////////////////////////////////////////////////////////
  template<class Field> class SchurRedBlackDiagMooeeSolve : public SchurRedBlackBase<Field> {
  public:
    typedef CheckerBoardedSparseMatrixBase<Field> Matrix;
    SchurRedBlackDiagMooeeSolve(OperatorFunction<Field> &HermitianRBSolver, const bool initSubGuess = false,
        const bool _solnAsInitGuess = false)  
      : SchurRedBlackBase<Field> (HermitianRBSolver,initSubGuess,_solnAsInitGuess) {};
    //////////////////////////////////////////////////////
    // Override RedBlack specialisation
    //////////////////////////////////////////////////////
    virtual void RedBlackSource(Matrix & _Matrix,const Field &src, Field &src_e,Field &src_o)
    {
      GridBase *grid = _Matrix.RedBlackGrid();
      GridBase *fgrid= _Matrix.Grid();
      Field   tmp(grid);
      Field  Mtmp(grid);
      pickCheckerboard(Even,src_e,src);
      pickCheckerboard(Odd ,src_o,src);
      /////////////////////////////////////////////////////
      // src_o = Mdag * (source_o - Moe MeeInv source_e)
      /////////////////////////////////////////////////////
      _Matrix.MooeeInv(src_e,tmp);     assert(  tmp.Checkerboard() ==Even);
      _Matrix.Meooe   (tmp,Mtmp);      assert( Mtmp.Checkerboard() ==Odd);     
      tmp=src_o-Mtmp;                  assert(  tmp.Checkerboard() ==Odd);     
      // get the right MpcDag
      SchurDiagMooeeOperator<Matrix,Field> _HermOpEO(_Matrix);
      _HermOpEO.MpcDag(tmp,src_o);     assert(src_o.Checkerboard() ==Odd);       
    }
    virtual void RedBlackSolution(Matrix & _Matrix,const Field &sol_o, const Field &src_e,Field &sol)
    {
      GridBase *grid = _Matrix.RedBlackGrid();
      GridBase *fgrid= _Matrix.Grid();
      Field   tmp(grid);
      Field  sol_e(grid);
      Field  src_e_i(grid);
      ///////////////////////////////////////////////////
      // sol_e = M_ee^-1 * ( src_e - Meo sol_o )...
      ///////////////////////////////////////////////////
      _Matrix.Meooe(sol_o,tmp);          assert(  tmp.Checkerboard()   ==Even);
      src_e_i = src_e-tmp;               assert(  src_e_i.Checkerboard() ==Even);
      _Matrix.MooeeInv(src_e_i,sol_e);   assert(  sol_e.Checkerboard() ==Even);
      setCheckerboard(sol,sol_e); assert(  sol_e.Checkerboard() ==Even);
      setCheckerboard(sol,sol_o); assert(  sol_o.Checkerboard() ==Odd );
    }
    virtual void RedBlackSolve   (Matrix & _Matrix,const Field &src_o, Field &sol_o)
    {
      SchurDiagMooeeOperator<Matrix,Field> _HermOpEO(_Matrix);
      this->_HermitianRBSolver(_HermOpEO,src_o,sol_o);  assert(sol_o.Checkerboard()==Odd);
    };
    virtual void RedBlackSolve   (Matrix & _Matrix,const std::vector<Field> &src_o,  std::vector<Field> &sol_o)
    {
      SchurDiagMooeeOperator<Matrix,Field> _HermOpEO(_Matrix);
      this->_HermitianRBSolver(_HermOpEO,src_o,sol_o); 
    }
  };
  template<class Field> class NonHermitianSchurRedBlackDiagMooeeSolve : public SchurRedBlackBase<Field> 
  {
    public:
      typedef CheckerBoardedSparseMatrixBase<Field> Matrix;
      NonHermitianSchurRedBlackDiagMooeeSolve(OperatorFunction<Field>& RBSolver, const bool initSubGuess = false,
          const bool _solnAsInitGuess = false)  
      : SchurRedBlackBase<Field>(RBSolver, initSubGuess, _solnAsInitGuess) {};
      //////////////////////////////////////////////////////
      // Override RedBlack specialisation
      //////////////////////////////////////////////////////
      virtual void RedBlackSource(Matrix& _Matrix, const Field& src, Field& src_e, Field& src_o)
      {
        GridBase* grid  = _Matrix.RedBlackGrid();
        GridBase* fgrid = _Matrix.Grid();
        Field  tmp(grid);
        Field Mtmp(grid);
        pickCheckerboard(Even, src_e, src);
        pickCheckerboard(Odd , src_o, src);
        /////////////////////////////////////////////////////
        // src_o = Mdag * (source_o - Moe MeeInv source_e)
        /////////////////////////////////////////////////////
        _Matrix.MooeeInv(src_e, tmp);   assert(   tmp.Checkerboard() == Even );
        _Matrix.Meooe   (tmp, Mtmp);    assert(  Mtmp.Checkerboard() == Odd  );     
        src_o -= Mtmp;                  assert( src_o.Checkerboard() == Odd  );     
      }
      virtual void RedBlackSolution(Matrix& _Matrix, const Field& sol_o, const Field& src_e, Field& sol)
      {
        GridBase* grid  = _Matrix.RedBlackGrid();
        GridBase* fgrid = _Matrix.Grid();
        Field     tmp(grid);
        Field   sol_e(grid);
        Field src_e_i(grid);
        ///////////////////////////////////////////////////
        // sol_e = M_ee^-1 * ( src_e - Meo sol_o )...
        ///////////////////////////////////////////////////
        _Matrix.Meooe(sol_o, tmp);         assert(     tmp.Checkerboard() == Even );
        src_e_i = src_e - tmp;             assert( src_e_i.Checkerboard() == Even );
        _Matrix.MooeeInv(src_e_i, sol_e);  assert(   sol_e.Checkerboard() == Even );
        setCheckerboard(sol, sol_e); assert( sol_e.Checkerboard() == Even );
        setCheckerboard(sol, sol_o); assert( sol_o.Checkerboard() == Odd  );
      }
      virtual void RedBlackSolve(Matrix& _Matrix, const Field& src_o, Field& sol_o)
      {
        NonHermitianSchurDiagMooeeOperator<Matrix,Field> _OpEO(_Matrix);
        this->_HermitianRBSolver(_OpEO, src_o, sol_o);  assert(sol_o.Checkerboard() == Odd);
      }
      virtual void RedBlackSolve(Matrix& _Matrix, const std::vector<Field>& src_o, std::vector<Field>& sol_o)
      {
        NonHermitianSchurDiagMooeeOperator<Matrix,Field> _OpEO(_Matrix);
        this->_HermitianRBSolver(_OpEO, src_o, sol_o); 
      }
  };
  ///////////////////////////////////////////////////////////////////////////////////////////////////////
  // Site diagonal is identity, right preconditioned by Mee^inv
  // ( 1 - Meo Moo^inv Moe Mee^inv  ) phi =( 1 - Meo Moo^inv Moe Mee^inv  ) Mee psi =  = eta  = eta
  //=> psi = MeeInv phi
  ///////////////////////////////////////////////////////////////////////////////////////////////////////
  template<class Field> class SchurRedBlackDiagTwoSolve : public SchurRedBlackBase<Field> {
  public:
    typedef CheckerBoardedSparseMatrixBase<Field> Matrix;
    /////////////////////////////////////////////////////
    // Wrap the usual normal equations Schur trick
    /////////////////////////////////////////////////////
  SchurRedBlackDiagTwoSolve(OperatorFunction<Field> &HermitianRBSolver, const bool initSubGuess = false,
      const bool _solnAsInitGuess = false)  
    : SchurRedBlackBase<Field>(HermitianRBSolver,initSubGuess,_solnAsInitGuess) {};
    virtual void RedBlackSource(Matrix & _Matrix,const Field &src, Field &src_e,Field &src_o)
    {
      GridBase *grid = _Matrix.RedBlackGrid();
      GridBase *fgrid= _Matrix.Grid();
      SchurDiagTwoOperator<Matrix,Field> _HermOpEO(_Matrix);
      Field   tmp(grid);
      Field  Mtmp(grid);
      pickCheckerboard(Even,src_e,src);
      pickCheckerboard(Odd ,src_o,src);
      /////////////////////////////////////////////////////
      // src_o = Mdag * (source_o - Moe MeeInv source_e)
      /////////////////////////////////////////////////////
      _Matrix.MooeeInv(src_e,tmp);     assert(  tmp.Checkerboard() ==Even);
      _Matrix.Meooe   (tmp,Mtmp);      assert( Mtmp.Checkerboard() ==Odd);     
      tmp=src_o-Mtmp;                  assert(  tmp.Checkerboard() ==Odd);     
      // get the right MpcDag
      _HermOpEO.MpcDag(tmp,src_o);     assert(src_o.Checkerboard() ==Odd);       
    }
    virtual void RedBlackSolution(Matrix & _Matrix,const Field &sol_o, const Field &src_e,Field &sol)
    {
      GridBase *grid = _Matrix.RedBlackGrid();
      GridBase *fgrid= _Matrix.Grid();
      Field   sol_o_i(grid);
      Field   tmp(grid);
      Field   sol_e(grid);
      ////////////////////////////////////////////////
      // MooeeInv due to pecond
      ////////////////////////////////////////////////
      _Matrix.MooeeInv(sol_o,tmp);
      sol_o_i = tmp;
      ///////////////////////////////////////////////////
      // sol_e = M_ee^-1 * ( src_e - Meo sol_o )...
      ///////////////////////////////////////////////////
      _Matrix.Meooe(sol_o_i,tmp);    assert(  tmp.Checkerboard()   ==Even);
      tmp = src_e-tmp;               assert(  src_e.Checkerboard() ==Even);
      _Matrix.MooeeInv(tmp,sol_e);   assert(  sol_e.Checkerboard() ==Even);
      setCheckerboard(sol,sol_e);    assert(  sol_e.Checkerboard() ==Even);
      setCheckerboard(sol,sol_o_i);  assert(  sol_o_i.Checkerboard() ==Odd );
    };
    virtual void RedBlackSolve   (Matrix & _Matrix,const Field &src_o, Field &sol_o)
    {
      SchurDiagTwoOperator<Matrix,Field> _HermOpEO(_Matrix);
      this->_HermitianRBSolver(_HermOpEO,src_o,sol_o);
    };
    virtual void RedBlackSolve   (Matrix & _Matrix,const std::vector<Field> &src_o,  std::vector<Field> &sol_o)
    {
      SchurDiagTwoOperator<Matrix,Field> _HermOpEO(_Matrix);
      this->_HermitianRBSolver(_HermOpEO,src_o,sol_o); 
    }
  };
  template<class Field> class NonHermitianSchurRedBlackDiagTwoSolve : public SchurRedBlackBase<Field> 
  {
    public:
      typedef CheckerBoardedSparseMatrixBase<Field> Matrix;
      /////////////////////////////////////////////////////
      // Wrap the usual normal equations Schur trick
      /////////////////////////////////////////////////////
      NonHermitianSchurRedBlackDiagTwoSolve(OperatorFunction<Field>& RBSolver, const bool initSubGuess = false,
          const bool _solnAsInitGuess = false)  
      : SchurRedBlackBase<Field>(RBSolver, initSubGuess, _solnAsInitGuess) {};
      virtual void RedBlackSource(Matrix& _Matrix, const Field& src, Field& src_e, Field& src_o)
      {
        GridBase* grid  = _Matrix.RedBlackGrid();
        GridBase* fgrid = _Matrix.Grid();
        Field  tmp(grid);
        Field Mtmp(grid);
        pickCheckerboard(Even, src_e, src);
        pickCheckerboard(Odd , src_o, src);
        /////////////////////////////////////////////////////
        // src_o = Mdag * (source_o - Moe MeeInv source_e)
        /////////////////////////////////////////////////////
        _Matrix.MooeeInv(src_e, tmp);   assert(   tmp.Checkerboard() == Even );
        _Matrix.Meooe   (tmp, Mtmp);    assert(  Mtmp.Checkerboard() == Odd  );     
        src_o -= Mtmp;                  assert( src_o.Checkerboard() == Odd  );     
      }
      virtual void RedBlackSolution(Matrix& _Matrix, const Field& sol_o, const Field& src_e, Field& sol)
      {
        GridBase* grid  = _Matrix.RedBlackGrid();
        GridBase* fgrid = _Matrix.Grid();
        Field sol_o_i(grid);
        Field     tmp(grid);
        Field   sol_e(grid);
        ////////////////////////////////////////////////
        // MooeeInv due to pecond
        ////////////////////////////////////////////////
        _Matrix.MooeeInv(sol_o, tmp);
        sol_o_i = tmp;
        ///////////////////////////////////////////////////
        // sol_e = M_ee^-1 * ( src_e - Meo sol_o )...
        ///////////////////////////////////////////////////
        _Matrix.Meooe(sol_o_i, tmp);    assert(   tmp.Checkerboard() == Even );
        tmp = src_e - tmp;              assert( src_e.Checkerboard() == Even );
        _Matrix.MooeeInv(tmp, sol_e);   assert( sol_e.Checkerboard() == Even );
        setCheckerboard(sol, sol_e);    assert(   sol_e.Checkerboard() == Even );
        setCheckerboard(sol, sol_o_i);  assert( sol_o_i.Checkerboard() == Odd  );
      };
      virtual void RedBlackSolve(Matrix& _Matrix, const Field& src_o, Field& sol_o)
      {
        NonHermitianSchurDiagTwoOperator<Matrix,Field> _OpEO(_Matrix);
        this->_HermitianRBSolver(_OpEO, src_o, sol_o);
      };
      virtual void RedBlackSolve(Matrix& _Matrix, const std::vector<Field>& src_o,  std::vector<Field>& sol_o)
      {
        NonHermitianSchurDiagTwoOperator<Matrix,Field> _OpEO(_Matrix);
        this->_HermitianRBSolver(_OpEO, src_o, sol_o); 
      }
  };
 }
 #endif
--- a/Grid/allocator/AlignedAllocator.h
+++ b/Grid/allocator/AlignedAllocator.h
@@ -0,0 +1,184 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./lib/AlignedAllocator.h
    Copyright (C) 2015
 Author: Azusa Yamaguchi <ayamaguc@staffmail.ed.ac.uk>
 Author: Peter Boyle <paboyle@ph.ed.ac.uk>
    This program is free software; you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation; either version 2 of the License, or
    (at your option) any later version.
    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.
    You should have received a copy of the GNU General Public License along
    with this program; if not, write to the Free Software Foundation, Inc.,
    51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
    See the full license in the file "LICENSE" in the top level distribution directory
 *************************************************************************************/
 /*  END LEGAL */
 #pragma once
 NAMESPACE_BEGIN(Grid);
 template<typename _Tp>
 class alignedAllocator {
 public: 
  typedef std::size_t     size_type;
  typedef std::ptrdiff_t  difference_type;
  typedef _Tp*       pointer;
  typedef const _Tp* const_pointer;
  typedef _Tp&       reference;
  typedef const _Tp& const_reference;
  typedef _Tp        value_type;
  template<typename _Tp1>  struct rebind { typedef alignedAllocator<_Tp1> other; };
  alignedAllocator() throw() { }
  alignedAllocator(const alignedAllocator&) throw() { }
  template<typename _Tp1> alignedAllocator(const alignedAllocator<_Tp1>&) throw() { }
  ~alignedAllocator() throw() { }
  pointer       address(reference __x)       const { return &__x; }
  size_type  max_size() const throw() { return size_t(-1) / sizeof(_Tp); }
  pointer allocate(size_type __n, const void* _p= 0)
  { 
    size_type bytes = __n*sizeof(_Tp);
    profilerAllocate(bytes);
    _Tp *ptr = (_Tp*) MemoryManager::CpuAllocate(bytes);
    assert( ( (_Tp*)ptr != (_Tp *)NULL ) );
    return ptr;
  }
  void deallocate(pointer __p, size_type __n) 
  { 
    size_type bytes = __n * sizeof(_Tp);
    profilerFree(bytes);
    MemoryManager::CpuFree((void *)__p,bytes);
  }
  // FIXME: hack for the copy constructor: it must be avoided to avoid single thread loop
  void construct(pointer __p, const _Tp& __val) { assert(0);};
  void construct(pointer __p) { };
  void destroy(pointer __p) { };
 };
 template<typename _Tp>  inline bool operator==(const alignedAllocator<_Tp>&, const alignedAllocator<_Tp>&){ return true; }
 template<typename _Tp>  inline bool operator!=(const alignedAllocator<_Tp>&, const alignedAllocator<_Tp>&){ return false; }
 //////////////////////////////////////////////////////////////////////////////////////
 // Unified virtual memory
 //////////////////////////////////////////////////////////////////////////////////////
 template<typename _Tp>
 class uvmAllocator {
 public: 
  typedef std::size_t     size_type;
  typedef std::ptrdiff_t  difference_type;
  typedef _Tp*       pointer;
  typedef const _Tp* const_pointer;
  typedef _Tp&       reference;
  typedef const _Tp& const_reference;
  typedef _Tp        value_type;
  template<typename _Tp1>  struct rebind { typedef uvmAllocator<_Tp1> other; };
  uvmAllocator() throw() { }
  uvmAllocator(const uvmAllocator&) throw() { }
  template<typename _Tp1> uvmAllocator(const uvmAllocator<_Tp1>&) throw() { }
  ~uvmAllocator() throw() { }
  pointer       address(reference __x)       const { return &__x; }
  size_type  max_size() const throw() { return size_t(-1) / sizeof(_Tp); }
  pointer allocate(size_type __n, const void* _p= 0)
  { 
    size_type bytes = __n*sizeof(_Tp);
    profilerAllocate(bytes);
    _Tp *ptr = (_Tp*) MemoryManager::SharedAllocate(bytes);
    assert( ( (_Tp*)ptr != (_Tp *)NULL ) );
    return ptr;
  }
  void deallocate(pointer __p, size_type __n) 
  { 
    size_type bytes = __n * sizeof(_Tp);
    profilerFree(bytes);
    MemoryManager::SharedFree((void *)__p,bytes);
  }
  void construct(pointer __p, const _Tp& __val) { new((void *)__p) _Tp(__val); };
  void construct(pointer __p) { };
  void destroy(pointer __p) { };
 };
 template<typename _Tp>  inline bool operator==(const uvmAllocator<_Tp>&, const uvmAllocator<_Tp>&){ return true; }
 template<typename _Tp>  inline bool operator!=(const uvmAllocator<_Tp>&, const uvmAllocator<_Tp>&){ return false; }
 ////////////////////////////////////////////////////////////////////////////////
 // Device memory
 ////////////////////////////////////////////////////////////////////////////////
 template<typename _Tp>
 class devAllocator {
 public: 
  typedef std::size_t     size_type;
  typedef std::ptrdiff_t  difference_type;
  typedef _Tp*       pointer;
  typedef const _Tp* const_pointer;
  typedef _Tp&       reference;
  typedef const _Tp& const_reference;
  typedef _Tp        value_type;
  template<typename _Tp1>  struct rebind { typedef devAllocator<_Tp1> other; };
  devAllocator() throw() { }
  devAllocator(const devAllocator&) throw() { }
  template<typename _Tp1> devAllocator(const devAllocator<_Tp1>&) throw() { }
  ~devAllocator() throw() { }
  pointer       address(reference __x)       const { return &__x; }
  size_type  max_size() const throw() { return size_t(-1) / sizeof(_Tp); }
  pointer allocate(size_type __n, const void* _p= 0)
  { 
    size_type bytes = __n*sizeof(_Tp);
    profilerAllocate(bytes);
    _Tp *ptr = (_Tp*) MemoryManager::AcceleratorAllocate(bytes);
    assert( ( (_Tp*)ptr != (_Tp *)NULL ) );
    return ptr;
  }
  void deallocate(pointer __p, size_type __n) 
  { 
    size_type bytes = __n * sizeof(_Tp);
    profilerFree(bytes);
    MemoryManager::AcceleratorFree((void *)__p,bytes);
  }
  void construct(pointer __p, const _Tp& __val) { };
  void construct(pointer __p) { };
  void destroy(pointer __p) { };
 };
 template<typename _Tp>  inline bool operator==(const devAllocator<_Tp>&, const devAllocator<_Tp>&){ return true; }
 template<typename _Tp>  inline bool operator!=(const devAllocator<_Tp>&, const devAllocator<_Tp>&){ return false; }
 ////////////////////////////////////////////////////////////////////////////////
 // Template typedefs
 ////////////////////////////////////////////////////////////////////////////////
 #ifdef ACCELERATOR_CSHIFT
 // Cshift on device
 template<class T> using cshiftAllocator = devAllocator<T>;
 #else
 // Cshift on host
 template<class T> using cshiftAllocator = std::allocator<T>;
 #endif
 template<class T> using Vector        = std::vector<T,uvmAllocator<T> >;           
 template<class T> using stencilVector = std::vector<T,alignedAllocator<T> >;           
 template<class T> using commVector = std::vector<T,devAllocator<T> >;
 template<class T> using deviceVector  = std::vector<T,devAllocator<T> >;
 template<class T> using cshiftVector = std::vector<T,cshiftAllocator<T> >;
 NAMESPACE_END(Grid);
--- a/Grid/allocator/Allocator.h
+++ b/Grid/allocator/Allocator.h
@@ -0,0 +1,4 @@
 #pragma once
 #include <Grid/allocator/MemoryStats.h>
 #include <Grid/allocator/MemoryManager.h>
 #include <Grid/allocator/AlignedAllocator.h>
--- a/Grid/allocator/MemoryManager.cc
+++ b/Grid/allocator/MemoryManager.cc
@@ -0,0 +1,324 @@
 #include <Grid/GridCore.h>
 NAMESPACE_BEGIN(Grid);
 /*Allocation types, saying which pointer cache should be used*/
 #define Cpu      (0)
 #define CpuHuge  (1)
 #define CpuSmall (2)
 #define Acc      (3)
 #define AccHuge  (4)
 #define AccSmall (5)
 #define Shared   (6)
 #define SharedHuge  (7)
 #define SharedSmall (8)
 #undef GRID_MM_VERBOSE 
 uint64_t total_shared;
 uint64_t total_device;
 uint64_t total_host;;
 void MemoryManager::PrintBytes(void)
 {
  std::cout << " MemoryManager : ------------------------------------ "<<std::endl;
  std::cout << " MemoryManager : PrintBytes "<<std::endl;
  std::cout << " MemoryManager : ------------------------------------ "<<std::endl;
  std::cout << " MemoryManager : "<<(total_shared>>20)<<" shared      Mbytes "<<std::endl;
  std::cout << " MemoryManager : "<<(total_device>>20)<<" accelerator Mbytes "<<std::endl;
  std::cout << " MemoryManager : "<<(total_host>>20)  <<" cpu         Mbytes "<<std::endl;
  uint64_t cacheBytes;
  cacheBytes = CacheBytes[Cpu];
  std::cout << " MemoryManager : "<<(cacheBytes>>20) <<" cpu cache Mbytes "<<std::endl;
  cacheBytes = CacheBytes[Acc];
  std::cout << " MemoryManager : "<<(cacheBytes>>20) <<" acc cache Mbytes "<<std::endl;
  cacheBytes = CacheBytes[Shared];
  std::cout << " MemoryManager : "<<(cacheBytes>>20) <<" shared cache Mbytes "<<std::endl;
 #ifdef GRID_CUDA
  cuda_mem();
 #endif
 }
 uint64_t MemoryManager::DeviceCacheBytes() { return CacheBytes[Acc] + CacheBytes[AccHuge] + CacheBytes[AccSmall]; }
 uint64_t MemoryManager::HostCacheBytes()   { return CacheBytes[Cpu] + CacheBytes[CpuHuge] + CacheBytes[CpuSmall]; }
 //////////////////////////////////////////////////////////////////////
 // Data tables for recently freed pooiniter caches
 //////////////////////////////////////////////////////////////////////
 MemoryManager::AllocationCacheEntry MemoryManager::Entries[MemoryManager::NallocType][MemoryManager::NallocCacheMax];
 int MemoryManager::Victim[MemoryManager::NallocType];
 int MemoryManager::Ncache[MemoryManager::NallocType] = { 2, 0, 8, 8, 0, 16, 8, 0, 16 };
 uint64_t MemoryManager::CacheBytes[MemoryManager::NallocType];
 //////////////////////////////////////////////////////////////////////
 // Actual allocation and deallocation utils
 //////////////////////////////////////////////////////////////////////
 void *MemoryManager::AcceleratorAllocate(size_t bytes)
 {
  total_device+=bytes;
  void *ptr = (void *) Lookup(bytes,Acc);
  if ( ptr == (void *) NULL ) {
    ptr = (void *) acceleratorAllocDevice(bytes);
  }
 #ifdef GRID_MM_VERBOSE
  std::cout <<"AcceleratorAllocate "<<std::endl;
  PrintBytes();
 #endif
  return ptr;
 }
 void  MemoryManager::AcceleratorFree    (void *ptr,size_t bytes)
 {
  total_device-=bytes;
  void *__freeme = Insert(ptr,bytes,Acc);
  if ( __freeme ) {
    acceleratorFreeDevice(__freeme);
  }
 #ifdef GRID_MM_VERBOSE
  std::cout <<"AcceleratorFree "<<std::endl;
  PrintBytes();
 #endif
 }
 void *MemoryManager::SharedAllocate(size_t bytes)
 {
  total_shared+=bytes;
  void *ptr = (void *) Lookup(bytes,Shared);
  if ( ptr == (void *) NULL ) {
    ptr = (void *) acceleratorAllocShared(bytes);
  }
 #ifdef GRID_MM_VERBOSE
  std::cout <<"SharedAllocate "<<std::endl;
  PrintBytes();
 #endif
  return ptr;
 }
 void  MemoryManager::SharedFree    (void *ptr,size_t bytes)
 {
  total_shared-=bytes;
  void *__freeme = Insert(ptr,bytes,Shared);
  if ( __freeme ) {
    acceleratorFreeShared(__freeme);
  }
 #ifdef GRID_MM_VERBOSE
  std::cout <<"SharedFree "<<std::endl;
  PrintBytes();
 #endif
 }
 #ifdef GRID_UVM
 void *MemoryManager::CpuAllocate(size_t bytes)
 {
  total_host+=bytes;
  void *ptr = (void *) Lookup(bytes,Cpu);
  if ( ptr == (void *) NULL ) {
    ptr = (void *) acceleratorAllocShared(bytes);
  }
 #ifdef GRID_MM_VERBOSE
  std::cout <<"CpuAllocate "<<std::endl;
  PrintBytes();
 #endif
  return ptr;
 }
 void  MemoryManager::CpuFree    (void *_ptr,size_t bytes)
 {
  total_host-=bytes;
  NotifyDeletion(_ptr);
  void *__freeme = Insert(_ptr,bytes,Cpu);
  if ( __freeme ) { 
    acceleratorFreeShared(__freeme);
  }
 #ifdef GRID_MM_VERBOSE
  std::cout <<"CpuFree "<<std::endl;
  PrintBytes();
 #endif
 }
 #else
 void *MemoryManager::CpuAllocate(size_t bytes)
 {
  total_host+=bytes;
  void *ptr = (void *) Lookup(bytes,Cpu);
  if ( ptr == (void *) NULL ) {
    ptr = (void *) acceleratorAllocCpu(bytes);
  }
 #ifdef GRID_MM_VERBOSE
  std::cout <<"CpuAllocate "<<std::endl;
  PrintBytes();
 #endif
  return ptr;
 }
 void  MemoryManager::CpuFree    (void *_ptr,size_t bytes)
 {
  total_host-=bytes;
  NotifyDeletion(_ptr);
  void *__freeme = Insert(_ptr,bytes,Cpu);
  if ( __freeme ) { 
    acceleratorFreeCpu(__freeme);
  }
 #ifdef GRID_MM_VERBOSE
  std::cout <<"CpuFree "<<std::endl;
  PrintBytes();
 #endif
 }
 #endif
 //////////////////////////////////////////
 // call only once
 //////////////////////////////////////////
 void MemoryManager::Init(void)
 {
  char * str;
  int Nc;
  str= getenv("GRID_ALLOC_NCACHE_LARGE");
  if ( str ) {
    Nc = atoi(str);
    if ( (Nc>=0) && (Nc < NallocCacheMax)) {
      Ncache[Cpu]=Nc;
      Ncache[Acc]=Nc;
      Ncache[Shared]=Nc;
    }
  }
  str= getenv("GRID_ALLOC_NCACHE_HUGE");
  if ( str ) {
    Nc = atoi(str);
    if ( (Nc>=0) && (Nc < NallocCacheMax)) {
      Ncache[CpuHuge]=Nc;
      Ncache[AccHuge]=Nc;
      Ncache[SharedHuge]=Nc;
    }
  }
  str= getenv("GRID_ALLOC_NCACHE_SMALL");
  if ( str ) {
    Nc = atoi(str);
    if ( (Nc>=0) && (Nc < NallocCacheMax)) {
      Ncache[CpuSmall]=Nc;
      Ncache[AccSmall]=Nc;
      Ncache[SharedSmall]=Nc;
    }
  }
 }
 void MemoryManager::InitMessage(void) {
 #ifndef GRID_UVM
  std::cout << GridLogMessage << "MemoryManager Cache "<< MemoryManager::DeviceMaxBytes <<" bytes "<<std::endl;
 #endif
  std::cout << GridLogMessage<< "MemoryManager::Init() setting up"<<std::endl;
 #ifdef ALLOCATION_CACHE
  std::cout << GridLogMessage<< "MemoryManager::Init() cache pool for recent host   allocations: SMALL "<<Ncache[CpuSmall]<<" LARGE "<<Ncache[Cpu]<<" HUGE "<<Ncache[CpuHuge]<<std::endl;
  std::cout << GridLogMessage<< "MemoryManager::Init() cache pool for recent device allocations: SMALL "<<Ncache[AccSmall]<<" LARGE "<<Ncache[Acc]<<" Huge "<<Ncache[AccHuge]<<std::endl;
  std::cout << GridLogMessage<< "MemoryManager::Init() cache pool for recent shared allocations: SMALL "<<Ncache[SharedSmall]<<" LARGE "<<Ncache[Shared]<<" Huge "<<Ncache[SharedHuge]<<std::endl;
 #endif
 #ifdef GRID_UVM
  std::cout << GridLogMessage<< "MemoryManager::Init() Unified memory space"<<std::endl;
 #ifdef GRID_CUDA
  std::cout << GridLogMessage<< "MemoryManager::Init() Using cudaMallocManaged"<<std::endl;
 #endif
 #ifdef GRID_HIP
  std::cout << GridLogMessage<< "MemoryManager::Init() Using hipMallocManaged"<<std::endl;
 #endif
 #ifdef GRID_SYCL
  std::cout << GridLogMessage<< "MemoryManager::Init() Using SYCL malloc_shared"<<std::endl;
 #endif
 #else
  std::cout << GridLogMessage<< "MemoryManager::Init() Non unified: Caching accelerator data in dedicated memory"<<std::endl;
 #ifdef GRID_CUDA
  std::cout << GridLogMessage<< "MemoryManager::Init() Using cudaMalloc"<<std::endl;
 #endif
 #ifdef GRID_HIP
  std::cout << GridLogMessage<< "MemoryManager::Init() Using hipMalloc"<<std::endl;
 #endif
 #ifdef GRID_SYCL
  std::cout << GridLogMessage<< "MemoryManager::Init() Using SYCL malloc_device"<<std::endl;
 #endif
 #endif
 }
 void *MemoryManager::Insert(void *ptr,size_t bytes,int type) 
 {
 #ifdef ALLOCATION_CACHE
  int cache;
  if      (bytes < GRID_ALLOC_SMALL_LIMIT) cache = type + 2;
  else if (bytes >= GRID_ALLOC_HUGE_LIMIT) cache = type + 1;
  else                                     cache = type;
  return Insert(ptr,bytes,Entries[cache],Ncache[cache],Victim[cache],CacheBytes[cache]);  
 #else
  return ptr;
 #endif
 }
 void *MemoryManager::Insert(void *ptr,size_t bytes,AllocationCacheEntry *entries,int ncache,int &victim, uint64_t &cacheBytes) 
 {
 #ifdef GRID_OMP
  assert(omp_in_parallel()==0);
 #endif 
  if (ncache == 0) return ptr;
  void * ret = NULL;
  int v = -1;
  for(int e=0;e<ncache;e++) {
    if ( entries[e].valid==0 ) {
      v=e; 
      break;
    }
  }
  if ( v==-1 ) {
    v=victim;
    victim = (victim+1)%ncache;
  }
  if ( entries[v].valid ) {
    ret = entries[v].address;
    cacheBytes -= entries[v].bytes;
    entries[v].valid = 0;
    entries[v].address = NULL;
    entries[v].bytes = 0;
  }
  entries[v].address=ptr;
  entries[v].bytes  =bytes;
  entries[v].valid  =1;
  cacheBytes += bytes;
  return ret;
 }
 void *MemoryManager::Lookup(size_t bytes,int type)
 {
 #ifdef ALLOCATION_CACHE
  int cache;
  if      (bytes < GRID_ALLOC_SMALL_LIMIT) cache = type + 2;
  else if (bytes >= GRID_ALLOC_HUGE_LIMIT) cache = type + 1;
  else                                     cache = type;
  return Lookup(bytes,Entries[cache],Ncache[cache],CacheBytes[cache]);
 #else
  return NULL;
 #endif
 }
 void *MemoryManager::Lookup(size_t bytes,AllocationCacheEntry *entries,int ncache,uint64_t & cacheBytes) 
 {
 #ifdef GRID_OMP
  assert(omp_in_parallel()==0);
 #endif 
  for(int e=0;e<ncache;e++){
    if ( entries[e].valid && ( entries[e].bytes == bytes ) ) {
      entries[e].valid = 0;
      cacheBytes -= entries[e].bytes;
      return entries[e].address;
    }
  }
  return NULL;
 }
 NAMESPACE_END(Grid);
--- a/Grid/allocator/MemoryManager.h
+++ b/Grid/allocator/MemoryManager.h
@@ -0,0 +1,226 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./lib/MemoryManager.h
    Copyright (C) 2015
 Author: Azusa Yamaguchi <ayamaguc@staffmail.ed.ac.uk>
 Author: Peter Boyle <paboyle@ph.ed.ac.uk>
    This program is free software; you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation; either version 2 of the License, or
    (at your option) any later version.
    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.
    You should have received a copy of the GNU General Public License along
    with this program; if not, write to the Free Software Foundation, Inc.,
    51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
    See the full license in the file "LICENSE" in the top level distribution directory
 *************************************************************************************/
 /*  END LEGAL */
 #pragma once
 #include <list> 
 #include <unordered_map>  
 NAMESPACE_BEGIN(Grid);
 // Move control to configure.ac and Config.h?
 #define GRID_ALLOC_SMALL_LIMIT (4096)
 #define GRID_ALLOC_HUGE_LIMIT  (2147483648)
 #define STRINGIFY(x) #x
 #define TOSTRING(x) STRINGIFY(x)
 #define FILE_LINE __FILE__ ":" TOSTRING(__LINE__)
 #define AUDIT(a) MemoryManager::Audit(FILE_LINE)
 /*Pinning pages is costly*/
 ////////////////////////////////////////////////////////////////////////////
 // Advise the LatticeAccelerator class
 ////////////////////////////////////////////////////////////////////////////
 enum ViewAdvise {
 AdviseDefault       = 0x0,    // Regular data
 AdviseInfrequentUse = 0x1     // Advise that the data is used infrequently.  This can
                               // significantly influence performance of bulk storage.
 // AdviseTransient      = 0x2,   // Data will mostly be read.  On some architectures
                               // enables read-only copies of memory to be kept on
                               // host and device.
 // AdviseAcceleratorWriteDiscard = 0x4  // Field will be written in entirety on device
 };
 ////////////////////////////////////////////////////////////////////////////
 // View Access Mode
 ////////////////////////////////////////////////////////////////////////////
 enum ViewMode {
  AcceleratorRead  = 0x01,
  AcceleratorWrite = 0x02,
  AcceleratorWriteDiscard = 0x04,
  CpuRead  = 0x08,
  CpuWrite = 0x10,
  CpuWriteDiscard = 0x10 // same for now
 };
 struct MemoryStatus {
  uint64_t     DeviceBytes;
  uint64_t     DeviceLRUBytes;
  uint64_t     DeviceMaxBytes;
  uint64_t     HostToDeviceBytes;
  uint64_t     DeviceToHostBytes;
  uint64_t     HostToDeviceXfer;
  uint64_t     DeviceToHostXfer;
  uint64_t     DeviceEvictions;
  uint64_t     DeviceDestroy;
  uint64_t     DeviceAllocCacheBytes;
  uint64_t     HostAllocCacheBytes;
 };
 class MemoryManager {
 private:
  ////////////////////////////////////////////////////////////
  // For caching recently freed allocations
  ////////////////////////////////////////////////////////////
  typedef struct { 
    void *address;
    size_t bytes;
    int valid;
  } AllocationCacheEntry;
  static const int NallocCacheMax=128; 
  static const int NallocType=9;
  static AllocationCacheEntry Entries[NallocType][NallocCacheMax];
  static int Victim[NallocType];
  static int Ncache[NallocType];
  static uint64_t CacheBytes[NallocType];
  /////////////////////////////////////////////////
  // Free pool
  /////////////////////////////////////////////////
  static void *Insert(void *ptr,size_t bytes,int type) ;
  static void *Lookup(size_t bytes,int type) ;
  static void *Insert(void *ptr,size_t bytes,AllocationCacheEntry *entries,int ncache,int &victim,uint64_t &cbytes) ;
  static void *Lookup(size_t bytes,AllocationCacheEntry *entries,int ncache,uint64_t &cbytes) ;
 public:
  static void PrintBytes(void);
  static void Audit(std::string s);
  static void Init(void);
  static void InitMessage(void);
  static void *AcceleratorAllocate(size_t bytes);
  static void  AcceleratorFree    (void *ptr,size_t bytes);
  static void *SharedAllocate(size_t bytes);
  static void  SharedFree    (void *ptr,size_t bytes);
  static void *CpuAllocate(size_t bytes);
  static void  CpuFree    (void *ptr,size_t bytes);
  ////////////////////////////////////////////////////////
  // Footprint tracking
  ////////////////////////////////////////////////////////
  static uint64_t     DeviceBytes;
  static uint64_t     DeviceLRUBytes;
  static uint64_t     DeviceMaxBytes;
  static uint64_t     HostToDeviceBytes;
  static uint64_t     DeviceToHostBytes;
  static uint64_t     HostToDeviceXfer;
  static uint64_t     DeviceToHostXfer;
  static uint64_t     DeviceEvictions;
  static uint64_t     DeviceDestroy;
  static uint64_t     DeviceCacheBytes();
  static uint64_t     HostCacheBytes();
  static MemoryStatus GetFootprint(void) {
    MemoryStatus stat;
    stat.DeviceBytes       = DeviceBytes;
    stat.DeviceLRUBytes    = DeviceLRUBytes;
    stat.DeviceMaxBytes    = DeviceMaxBytes;
    stat.HostToDeviceBytes = HostToDeviceBytes;
    stat.DeviceToHostBytes = DeviceToHostBytes;
    stat.HostToDeviceXfer  = HostToDeviceXfer;
    stat.DeviceToHostXfer  = DeviceToHostXfer;
    stat.DeviceEvictions   = DeviceEvictions;
    stat.DeviceDestroy     = DeviceDestroy;
    stat.DeviceAllocCacheBytes = DeviceCacheBytes();
    stat.HostAllocCacheBytes   = HostCacheBytes();
    return stat;
  };
 private:
 #ifndef GRID_UVM
  //////////////////////////////////////////////////////////////////////
  // Data tables for ViewCache
  //////////////////////////////////////////////////////////////////////
  typedef std::list<uint64_t> LRU_t;
  typedef typename LRU_t::iterator LRUiterator;
  typedef struct { 
    int        LRU_valid;
    LRUiterator LRU_entry;
    uint64_t CpuPtr;
    uint64_t AccPtr;
    size_t   bytes;
    uint32_t transient;
    uint32_t state;
    uint32_t accLock;
    uint32_t cpuLock;
  } AcceleratorViewEntry;
  typedef std::unordered_map<uint64_t,AcceleratorViewEntry> AccViewTable_t;
  typedef typename AccViewTable_t::iterator AccViewTableIterator ;
  static AccViewTable_t AccViewTable;
  static LRU_t LRU;
  /////////////////////////////////////////////////
  // Device motion
  /////////////////////////////////////////////////
  static void  Create(uint64_t CpuPtr,size_t bytes,ViewMode mode,ViewAdvise hint);
  static void  EvictVictims(uint64_t bytes); // Frees up <bytes>
  static void  Evict(AcceleratorViewEntry &AccCache);
  static void  Flush(AcceleratorViewEntry &AccCache);
  static void  Clone(AcceleratorViewEntry &AccCache);
  static void  AccDiscard(AcceleratorViewEntry &AccCache);
  static void  CpuDiscard(AcceleratorViewEntry &AccCache);
  //  static void  LRUupdate(AcceleratorViewEntry &AccCache);
  static void  LRUinsert(AcceleratorViewEntry &AccCache);
  static void  LRUremove(AcceleratorViewEntry &AccCache);
  // manage entries in the table
  static int                  EntryPresent(uint64_t CpuPtr);
  static void                 EntryCreate(uint64_t CpuPtr,size_t bytes,ViewMode mode,ViewAdvise hint);
  static void                 EntryErase (uint64_t CpuPtr);
  static AccViewTableIterator EntryLookup(uint64_t CpuPtr);
  static void                 EntrySet   (uint64_t CpuPtr,AcceleratorViewEntry &entry);
  static void     AcceleratorViewClose(uint64_t AccPtr);
  static uint64_t AcceleratorViewOpen(uint64_t  CpuPtr,size_t bytes,ViewMode mode,ViewAdvise hint);
  static void     CpuViewClose(uint64_t Ptr);
  static uint64_t CpuViewOpen(uint64_t  CpuPtr,size_t bytes,ViewMode mode,ViewAdvise hint);
 #endif
  static void NotifyDeletion(void * CpuPtr);
 public:
  static void Print(void);
  static void PrintAll(void);
  static void PrintState( void* CpuPtr);
  static int   isOpen   (void* CpuPtr);
  static void  ViewClose(void* CpuPtr,ViewMode mode);
  static void *ViewOpen (void* CpuPtr,size_t bytes,ViewMode mode,ViewAdvise hint);
 };
 NAMESPACE_END(Grid);
--- a/Grid/allocator/MemoryManagerCache.cc
+++ b/Grid/allocator/MemoryManagerCache.cc
@@ -0,0 +1,601 @@
 #include <Grid/GridCore.h>
 #ifndef GRID_UVM
 #warning "Using explicit device memory copies"
 NAMESPACE_BEGIN(Grid);
 #define MAXLINE 512
 static char print_buffer [ MAXLINE ];
 #define mprintf(...) snprintf (print_buffer,MAXLINE, __VA_ARGS__ ); std::cout << GridLogMemory << print_buffer;
 #define dprintf(...) snprintf (print_buffer,MAXLINE, __VA_ARGS__ ); std::cout << GridLogMemory << print_buffer;
 //#define dprintf(...) 
 ////////////////////////////////////////////////////////////
 // For caching copies of data on device
 ////////////////////////////////////////////////////////////
 MemoryManager::AccViewTable_t MemoryManager::AccViewTable;
 MemoryManager::LRU_t MemoryManager::LRU;
 ////////////////////////////////////////////////////////
 // Footprint tracking
 ////////////////////////////////////////////////////////
 uint64_t  MemoryManager::DeviceBytes;
 uint64_t  MemoryManager::DeviceLRUBytes;
 uint64_t  MemoryManager::DeviceMaxBytes = 1024*1024*128;
 uint64_t  MemoryManager::HostToDeviceBytes;
 uint64_t  MemoryManager::DeviceToHostBytes;
 uint64_t  MemoryManager::HostToDeviceXfer;
 uint64_t  MemoryManager::DeviceToHostXfer;
 uint64_t  MemoryManager::DeviceEvictions;
 uint64_t  MemoryManager::DeviceDestroy;
 ////////////////////////////////////
 // Priority ordering for unlocked entries
 //  Empty
 //  CpuDirty 
 //  Consistent
 //  AccDirty
 ////////////////////////////////////
 #define Empty         (0x0)  /*Entry unoccupied  */
 #define CpuDirty      (0x1)  /*CPU copy is golden, Acc buffer MAY not be allocated*/
 #define Consistent    (0x2)  /*ACC copy AND CPU copy are valid */
 #define AccDirty      (0x4)  /*ACC copy is golden */
 #define EvictNext     (0x8)  /*Priority for eviction*/
 /////////////////////////////////////////////////
 // Mechanics of data table maintenance
 /////////////////////////////////////////////////
 int   MemoryManager::EntryPresent(uint64_t CpuPtr)
 {
  if(AccViewTable.empty()) return 0;
  auto count = AccViewTable.count(CpuPtr);  assert((count==0)||(count==1));
  return count;
 }
 void  MemoryManager::EntryCreate(uint64_t CpuPtr,size_t bytes,ViewMode mode,ViewAdvise hint)
 {
  assert(!EntryPresent(CpuPtr));
  AcceleratorViewEntry AccCache;
  AccCache.CpuPtr = CpuPtr;
  AccCache.AccPtr = (uint64_t)NULL;
  AccCache.bytes  = bytes;
  AccCache.state  = CpuDirty;
  AccCache.LRU_valid=0;
  AccCache.transient=0;
  AccCache.accLock=0;
  AccCache.cpuLock=0;
  AccViewTable[CpuPtr] = AccCache;
 }
 MemoryManager::AccViewTableIterator MemoryManager::EntryLookup(uint64_t CpuPtr)
 {
  assert(EntryPresent(CpuPtr));
  auto AccCacheIterator = AccViewTable.find(CpuPtr);
  assert(AccCacheIterator!=AccViewTable.end());
  return AccCacheIterator;
 }
 void MemoryManager::EntryErase(uint64_t CpuPtr)
 {
  auto AccCache = EntryLookup(CpuPtr);
  AccViewTable.erase(CpuPtr);
 }
 void  MemoryManager::LRUinsert(AcceleratorViewEntry &AccCache)
 {
  assert(AccCache.LRU_valid==0);
  if (AccCache.transient) { 
    LRU.push_back(AccCache.CpuPtr);
    AccCache.LRU_entry = --LRU.end();
  } else {
    LRU.push_front(AccCache.CpuPtr);
    AccCache.LRU_entry = LRU.begin();
  }
  AccCache.LRU_valid = 1;
  DeviceLRUBytes+=AccCache.bytes;
 }
 void  MemoryManager::LRUremove(AcceleratorViewEntry &AccCache)
 {
  assert(AccCache.LRU_valid==1);
  LRU.erase(AccCache.LRU_entry);
  AccCache.LRU_valid = 0;
  DeviceLRUBytes-=AccCache.bytes;
 }
 /////////////////////////////////////////////////
 // Accelerator cache motion & consistency logic
 /////////////////////////////////////////////////
 void MemoryManager::AccDiscard(AcceleratorViewEntry &AccCache)
 {
  ///////////////////////////////////////////////////////////
  // Remove from Accelerator, remove entry, without flush
  // Cannot be locked. If allocated Must be in LRU pool.
  ///////////////////////////////////////////////////////////
  assert(AccCache.state!=Empty);
  mprintf("MemoryManager: Discard(%lx) %lx\n",(uint64_t)AccCache.CpuPtr,(uint64_t)AccCache.AccPtr); 
  assert(AccCache.accLock==0);
  assert(AccCache.cpuLock==0);
  assert(AccCache.CpuPtr!=(uint64_t)NULL);
  if(AccCache.AccPtr) {
    AcceleratorFree((void *)AccCache.AccPtr,AccCache.bytes);
    DeviceDestroy++;
    DeviceBytes   -=AccCache.bytes;
    LRUremove(AccCache);
    AccCache.AccPtr=(uint64_t) NULL;
    dprintf("MemoryManager: Free(%lx) LRU %ld Total %ld\n",(uint64_t)AccCache.AccPtr,DeviceLRUBytes,DeviceBytes);  
  }
  uint64_t CpuPtr = AccCache.CpuPtr;
  EntryErase(CpuPtr);
 }
 void MemoryManager::Evict(AcceleratorViewEntry &AccCache)
 {
  ///////////////////////////////////////////////////////////////////////////
  // Make CPU consistent, remove from Accelerator, remove from LRU, LEAVE CPU only entry
  // Cannot be acclocked. If allocated must be in LRU pool.
  //
  // Nov 2022... Felix issue: Allocating two CpuPtrs, can have an entry in LRU-q with CPUlock.
  //                          and require to evict the AccPtr copy. Eviction was a mistake in CpuViewOpen
  //                          but there is a weakness where CpuLock entries are attempted for erase
  //                          Take these OUT LRU queue when CPU locked?
  //                          Cannot take out the table as cpuLock data is important.
  ///////////////////////////////////////////////////////////////////////////
  assert(AccCache.state!=Empty);
  mprintf("MemoryManager: Evict cpu %lx acc %lx cpuLock %ld accLock %ld\n",
 	  (uint64_t)AccCache.CpuPtr,(uint64_t)AccCache.AccPtr,
 	  (uint64_t)AccCache.cpuLock,(uint64_t)AccCache.accLock); 
  if (AccCache.accLock!=0) return;
  if (AccCache.cpuLock!=0) return;
  if(AccCache.state==AccDirty) {
    Flush(AccCache);
  }
  if(AccCache.AccPtr) {
    AcceleratorFree((void *)AccCache.AccPtr,AccCache.bytes);
    LRUremove(AccCache);
    AccCache.AccPtr=(uint64_t)NULL;
    AccCache.state=CpuDirty; // CPU primary now
    DeviceBytes   -=AccCache.bytes;
    dprintf("MemoryManager: Free(%lx) footprint now %ld \n",(uint64_t)AccCache.AccPtr,DeviceBytes);  
  }
  //  uint64_t CpuPtr = AccCache.CpuPtr;
  DeviceEvictions++;
  //  EntryErase(CpuPtr);
 }
 void MemoryManager::Flush(AcceleratorViewEntry &AccCache)
 {
  assert(AccCache.state==AccDirty);
  assert(AccCache.cpuLock==0);
  assert(AccCache.accLock==0);
  assert(AccCache.AccPtr!=(uint64_t)NULL);
  assert(AccCache.CpuPtr!=(uint64_t)NULL);
  acceleratorCopyFromDevice((void *)AccCache.AccPtr,(void *)AccCache.CpuPtr,AccCache.bytes);
  mprintf("MemoryManager: Flush  %lx -> %lx\n",(uint64_t)AccCache.AccPtr,(uint64_t)AccCache.CpuPtr); fflush(stdout);
  DeviceToHostBytes+=AccCache.bytes;
  DeviceToHostXfer++;
  AccCache.state=Consistent;
 }
 void MemoryManager::Clone(AcceleratorViewEntry &AccCache)
 {
  assert(AccCache.state==CpuDirty);
  assert(AccCache.cpuLock==0);
  assert(AccCache.accLock==0);
  assert(AccCache.CpuPtr!=(uint64_t)NULL);
  if(AccCache.AccPtr==(uint64_t)NULL){
    AccCache.AccPtr=(uint64_t)AcceleratorAllocate(AccCache.bytes);
    DeviceBytes+=AccCache.bytes;
  }
  mprintf("MemoryManager: Clone %lx <- %lx\n",(uint64_t)AccCache.AccPtr,(uint64_t)AccCache.CpuPtr); fflush(stdout);
  acceleratorCopyToDevice((void *)AccCache.CpuPtr,(void *)AccCache.AccPtr,AccCache.bytes);
  HostToDeviceBytes+=AccCache.bytes;
  HostToDeviceXfer++;
  AccCache.state=Consistent;
 }
 void MemoryManager::CpuDiscard(AcceleratorViewEntry &AccCache)
 {
  assert(AccCache.state!=Empty);
  assert(AccCache.cpuLock==0);
  assert(AccCache.accLock==0);
  assert(AccCache.CpuPtr!=(uint64_t)NULL);
  if(AccCache.AccPtr==(uint64_t)NULL){
    AccCache.AccPtr=(uint64_t)AcceleratorAllocate(AccCache.bytes);
    DeviceBytes+=AccCache.bytes;
  }
  AccCache.state=AccDirty;
 }
 /////////////////////////////////////////////////////////////////////////////////
 // View management
 /////////////////////////////////////////////////////////////////////////////////
 void MemoryManager::ViewClose(void* Ptr,ViewMode mode)
 {
  if( (mode==AcceleratorRead)||(mode==AcceleratorWrite)||(mode==AcceleratorWriteDiscard) ){
    dprintf("AcceleratorViewClose %lx\n",(uint64_t)Ptr);
    AcceleratorViewClose((uint64_t)Ptr);
  } else if( (mode==CpuRead)||(mode==CpuWrite)){
    CpuViewClose((uint64_t)Ptr);
  } else { 
    assert(0);
  }
 }
 void *MemoryManager::ViewOpen(void* _CpuPtr,size_t bytes,ViewMode mode,ViewAdvise hint)
 {
  uint64_t CpuPtr = (uint64_t)_CpuPtr;
  if( (mode==AcceleratorRead)||(mode==AcceleratorWrite)||(mode==AcceleratorWriteDiscard) ){
    dprintf("AcceleratorViewOpen %lx\n",(uint64_t)CpuPtr);
    return (void *) AcceleratorViewOpen(CpuPtr,bytes,mode,hint);
  } else if( (mode==CpuRead)||(mode==CpuWrite)){
    return (void *)CpuViewOpen(CpuPtr,bytes,mode,hint);
  } else { 
    assert(0);
    return NULL;
  }
 }
 void  MemoryManager::EvictVictims(uint64_t bytes)
 {
  assert(bytes<DeviceMaxBytes);
  while(bytes+DeviceLRUBytes > DeviceMaxBytes){
    if ( DeviceLRUBytes > 0){
      assert(LRU.size()>0);
      uint64_t victim = LRU.back(); // From the LRU
      auto AccCacheIterator = EntryLookup(victim);
      auto & AccCache = AccCacheIterator->second;
      Evict(AccCache);
    } else {
      return;
    }
  }
 }
 uint64_t MemoryManager::AcceleratorViewOpen(uint64_t CpuPtr,size_t bytes,ViewMode mode,ViewAdvise hint)
 {
  ////////////////////////////////////////////////////////////////////////////
  // Find if present, otherwise get or force an empty
  ////////////////////////////////////////////////////////////////////////////
  if ( EntryPresent(CpuPtr)==0 ){
    EntryCreate(CpuPtr,bytes,mode,hint);
  }
  auto AccCacheIterator = EntryLookup(CpuPtr);
  auto & AccCache = AccCacheIterator->second;
  if (!AccCache.AccPtr) {
    EvictVictims(bytes); 
  } 
  assert((mode==AcceleratorRead)||(mode==AcceleratorWrite)||(mode==AcceleratorWriteDiscard));
  assert(AccCache.cpuLock==0);  // Programming error
  if(AccCache.state!=Empty) {
    dprintf("ViewOpen found entry %lx %lx : %ld %ld accLock %ld\n",
 		    (uint64_t)AccCache.CpuPtr,
 		    (uint64_t)CpuPtr,
 		    (uint64_t)AccCache.bytes,
 	            (uint64_t)bytes,
 		    (uint64_t)AccCache.accLock);
    assert(AccCache.CpuPtr == CpuPtr);
    assert(AccCache.bytes  ==bytes);
  }
 /*
 *  State transitions and actions
 *
 *  Action  State   StateNext         Flush    Clone
 *
 *  AccRead  Empty   Consistent        -        Y
 *  AccWrite Empty   AccDirty          -        Y
 *  AccRead  CpuDirty Consistent       -        Y
 *  AccWrite CpuDirty AccDirty         -        Y
 *  AccRead  Consistent Consistent     -        - 
 *  AccWrite Consistent AccDirty       -        - 
 *  AccRead  AccDirty   AccDirty       -        - 
 *  AccWrite AccDirty   AccDirty       -        - 
 */
  if(AccCache.state==Empty) {
    assert(AccCache.LRU_valid==0);
    AccCache.CpuPtr = CpuPtr;
    AccCache.AccPtr = (uint64_t)NULL;
    AccCache.bytes  = bytes;
    AccCache.state  = CpuDirty;   // Cpu starts primary
    if(mode==AcceleratorWriteDiscard){
      CpuDiscard(AccCache);
      AccCache.state  = AccDirty;   // Empty + AcceleratorWrite=> AccDirty
    } else if(mode==AcceleratorWrite){
      Clone(AccCache);
      AccCache.state  = AccDirty;   // Empty + AcceleratorWrite=> AccDirty
    } else {
      Clone(AccCache);
      AccCache.state  = Consistent; // Empty + AccRead => Consistent
    }
    AccCache.accLock= 1;
    dprintf("Copied Empty entry into device accLock= %d\n",AccCache.accLock);
  } else if(AccCache.state==CpuDirty ){
    if(mode==AcceleratorWriteDiscard) {
      CpuDiscard(AccCache);
      AccCache.state  = AccDirty;   // CpuDirty + AcceleratorWrite=> AccDirty
    } else if(mode==AcceleratorWrite) {
      Clone(AccCache);
      AccCache.state  = AccDirty;   // CpuDirty + AcceleratorWrite=> AccDirty
    } else {
      Clone(AccCache);
      AccCache.state  = Consistent; // CpuDirty + AccRead => Consistent
    }
    AccCache.accLock++;
    dprintf("CpuDirty entry into device ++accLock= %d\n",AccCache.accLock);
  } else if(AccCache.state==Consistent) {
    if((mode==AcceleratorWrite)||(mode==AcceleratorWriteDiscard))
      AccCache.state  = AccDirty;   // Consistent + AcceleratorWrite=> AccDirty
    else
      AccCache.state  = Consistent; // Consistent + AccRead => Consistent
    AccCache.accLock++;
    dprintf("Consistent entry into device ++accLock= %d\n",AccCache.accLock);
  } else if(AccCache.state==AccDirty) {
    if((mode==AcceleratorWrite)||(mode==AcceleratorWriteDiscard))
      AccCache.state  = AccDirty; // AccDirty + AcceleratorWrite=> AccDirty
    else
      AccCache.state  = AccDirty; // AccDirty + AccRead => AccDirty
    AccCache.accLock++;
    dprintf("AccDirty entry ++accLock= %d\n",AccCache.accLock);
  } else {
    assert(0);
  }
  assert(AccCache.accLock>0);
  // If view is opened on device must remove from LRU
  if(AccCache.LRU_valid==1){
    // must possibly remove from LRU as now locked on GPU
    dprintf("AccCache entry removed from LRU \n");
    LRUremove(AccCache);
  }
  int transient =hint;
  AccCache.transient= transient? EvictNext : 0;
  return AccCache.AccPtr;
 }
 ////////////////////////////////////
 // look up & decrement lock count
 ////////////////////////////////////
 void MemoryManager::AcceleratorViewClose(uint64_t CpuPtr)
 {
  auto AccCacheIterator = EntryLookup(CpuPtr);
  auto & AccCache = AccCacheIterator->second;
  assert(AccCache.cpuLock==0);
  assert(AccCache.accLock>0);
  AccCache.accLock--;
  // Move to LRU queue if not locked and close on device
  if(AccCache.accLock==0) {
    dprintf("AccleratorViewClose %lx AccLock decremented to %ld move to LRU queue\n",(uint64_t)CpuPtr,(uint64_t)AccCache.accLock);
    LRUinsert(AccCache);
  } else {
    dprintf("AccleratorViewClose %lx AccLock decremented to %ld\n",(uint64_t)CpuPtr,(uint64_t)AccCache.accLock);
  }
 }
 void MemoryManager::CpuViewClose(uint64_t CpuPtr)
 {
  auto AccCacheIterator = EntryLookup(CpuPtr);
  auto & AccCache = AccCacheIterator->second;
  assert(AccCache.cpuLock>0);
  assert(AccCache.accLock==0);
  AccCache.cpuLock--;
 }
 /*
 *  Action  State   StateNext         Flush    Clone
 *
 *  CpuRead  Empty   CpuDirty          -        -
 *  CpuWrite Empty   CpuDirty          -        -
 *  CpuRead  CpuDirty CpuDirty         -        -
 *  CpuWrite CpuDirty CpuDirty         -        - 
 *  CpuRead  Consistent Consistent     -        - 
 *  CpuWrite Consistent CpuDirty       -        - 
 *  CpuRead  AccDirty   Consistent     Y        -
 *  CpuWrite AccDirty   CpuDirty       Y        -
 */
 uint64_t MemoryManager::CpuViewOpen(uint64_t CpuPtr,size_t bytes,ViewMode mode,ViewAdvise transient)
 {
  ////////////////////////////////////////////////////////////////////////////
  // Find if present, otherwise get or force an empty
  ////////////////////////////////////////////////////////////////////////////
  if ( EntryPresent(CpuPtr)==0 ){
    EntryCreate(CpuPtr,bytes,mode,transient);
  }
  auto AccCacheIterator = EntryLookup(CpuPtr);
  auto & AccCache = AccCacheIterator->second;
  // CPU doesn't need to free space
  //  if (!AccCache.AccPtr) {
  //    EvictVictims(bytes);
  //  }
  assert((mode==CpuRead)||(mode==CpuWrite));
  assert(AccCache.accLock==0);  // Programming error
  if(AccCache.state!=Empty) {
    assert(AccCache.CpuPtr == CpuPtr);
    assert(AccCache.bytes==bytes);
  }
  if(AccCache.state==Empty) {
    AccCache.CpuPtr = CpuPtr;
    AccCache.AccPtr = (uint64_t)NULL;
    AccCache.bytes  = bytes;
    AccCache.state  = CpuDirty; // Empty + CpuRead/CpuWrite => CpuDirty
    AccCache.accLock= 0;
    AccCache.cpuLock= 1;
  } else if(AccCache.state==CpuDirty ){
    // AccPtr dont care, deferred allocate
    AccCache.state = CpuDirty; // CpuDirty +CpuRead/CpuWrite => CpuDirty
    AccCache.cpuLock++;
  } else if(AccCache.state==Consistent) {
    assert(AccCache.AccPtr != (uint64_t)NULL);
    if(mode==CpuWrite)
      AccCache.state = CpuDirty;   // Consistent +CpuWrite => CpuDirty
    else 
      AccCache.state = Consistent; // Consistent +CpuRead  => Consistent
    AccCache.cpuLock++;
  } else if(AccCache.state==AccDirty) {
    assert(AccCache.AccPtr != (uint64_t)NULL);
    Flush(AccCache);
    if(mode==CpuWrite) AccCache.state = CpuDirty;   // AccDirty +CpuWrite => CpuDirty, Flush
    else            AccCache.state = Consistent; // AccDirty +CpuRead  => Consistent, Flush
    AccCache.cpuLock++;
  } else {
    assert(0); // should be unreachable
  }
  AccCache.transient= transient? EvictNext : 0;
  return AccCache.CpuPtr;
 }
 void  MemoryManager::NotifyDeletion(void *_ptr)
 {
  // Look up in ViewCache
  uint64_t ptr = (uint64_t)_ptr;
  if(EntryPresent(ptr)) {
    auto e = EntryLookup(ptr);
    AccDiscard(e->second);
  }
 }
 void  MemoryManager::Print(void)
 {
  PrintBytes();
  std::cout << GridLogMessage << "--------------------------------------------" << std::endl;
  std::cout << GridLogMessage << "Memory Manager                             " << std::endl;
  std::cout << GridLogMessage << "--------------------------------------------" << std::endl;
  std::cout << GridLogMessage << DeviceBytes   << " bytes allocated on device " << std::endl;
  std::cout << GridLogMessage << DeviceLRUBytes<< " bytes evictable on device " << std::endl;
  std::cout << GridLogMessage << DeviceMaxBytes<< " bytes max on device       " << std::endl;
  std::cout << GridLogMessage << HostToDeviceXfer << " transfers        to   device " << std::endl;
  std::cout << GridLogMessage << DeviceToHostXfer << " transfers        from device " << std::endl;
  std::cout << GridLogMessage << HostToDeviceBytes<< " bytes transfered to   device " << std::endl;
  std::cout << GridLogMessage << DeviceToHostBytes<< " bytes transfered from device " << std::endl;
  std::cout << GridLogMessage << DeviceEvictions  << " Evictions from device " << std::endl;
  std::cout << GridLogMessage << DeviceDestroy    << " Destroyed vectors on device " << std::endl;
  std::cout << GridLogMessage << AccViewTable.size()<< " vectors " << LRU.size()<<" evictable"<< std::endl;
  std::cout << GridLogMessage << "--------------------------------------------" << std::endl;
 }
 void  MemoryManager::PrintAll(void)
 {
  Print();
  std::cout << GridLogMessage << std::endl;
  std::cout << GridLogMessage << "--------------------------------------------" << std::endl;
  std::cout << GridLogMessage << "CpuAddr\t\tAccAddr\t\tState\t\tcpuLock\taccLock\tLRU_valid "<<std::endl;
  std::cout << GridLogMessage << "--------------------------------------------" << std::endl;
  for(auto it=AccViewTable.begin();it!=AccViewTable.end();it++){
    auto &AccCache = it->second;
    std::string str;
    if ( AccCache.state==Empty    ) str = std::string("Empty");
    if ( AccCache.state==CpuDirty ) str = std::string("CpuDirty");
    if ( AccCache.state==AccDirty ) str = std::string("AccDirty");
    if ( AccCache.state==Consistent)str = std::string("Consistent");
    std::cout << GridLogMessage << "0x"<<std::hex<<AccCache.CpuPtr<<std::dec
 	      << "\t0x"<<std::hex<<AccCache.AccPtr<<std::dec<<"\t" <<str
 	      << "\t" << AccCache.cpuLock
 	      << "\t" << AccCache.accLock
 	      << "\t" << AccCache.LRU_valid<<std::endl;
  }
  std::cout << GridLogMessage << "--------------------------------------------" << std::endl;
 };
 int   MemoryManager::isOpen   (void* _CpuPtr) 
 { 
  uint64_t CpuPtr = (uint64_t)_CpuPtr;
  if ( EntryPresent(CpuPtr) ){
    auto AccCacheIterator = EntryLookup(CpuPtr);
    auto & AccCache = AccCacheIterator->second;
    return AccCache.cpuLock+AccCache.accLock;
  } else { 
    return 0;
  }
 }
 void MemoryManager::Audit(std::string s)
 {
  uint64_t CpuBytes=0;
  uint64_t AccBytes=0;
  uint64_t LruBytes1=0;
  uint64_t LruBytes2=0;
  uint64_t LruCnt=0;
  std::cout << " Memory Manager::Audit() from "<<s<<std::endl;
  for(auto it=LRU.begin();it!=LRU.end();it++){
    uint64_t cpuPtr = *it;
    assert(EntryPresent(cpuPtr));
    auto AccCacheIterator = EntryLookup(cpuPtr);
    auto & AccCache = AccCacheIterator->second;
    LruBytes2+=AccCache.bytes;
    assert(AccCache.LRU_valid==1);
    assert(AccCache.LRU_entry==it);
  }
  std::cout << " Memory Manager::Audit() LRU queue matches table entries "<<std::endl;
  for(auto it=AccViewTable.begin();it!=AccViewTable.end();it++){
    auto &AccCache = it->second;
    std::string str;
    if ( AccCache.state==Empty    ) str = std::string("Empty");
    if ( AccCache.state==CpuDirty ) str = std::string("CpuDirty");
    if ( AccCache.state==AccDirty ) str = std::string("AccDirty");
    if ( AccCache.state==Consistent)str = std::string("Consistent");
    CpuBytes+=AccCache.bytes;
    if( AccCache.AccPtr )    AccBytes+=AccCache.bytes;
    if( AccCache.LRU_valid ) LruBytes1+=AccCache.bytes;
    if( AccCache.LRU_valid ) LruCnt++;
    if ( AccCache.cpuLock || AccCache.accLock ) {
      assert(AccCache.LRU_valid==0);
      std::cout << GridLogError << s<< "\n\t 0x"<<std::hex<<AccCache.CpuPtr<<std::dec
 		<< "\t0x"<<std::hex<<AccCache.AccPtr<<std::dec<<"\t" <<str
 		<< "\t cpuLock  " << AccCache.cpuLock
 		<< "\t accLock  " << AccCache.accLock
 		<< "\t LRUvalid " << AccCache.LRU_valid<<std::endl;
    }
    assert( AccCache.cpuLock== 0 ) ;
    assert( AccCache.accLock== 0 ) ;
  }
  std::cout << " Memory Manager::Audit() no locked table entries "<<std::endl;
  assert(LruBytes1==LruBytes2);
  assert(LruBytes1==DeviceLRUBytes);
  std::cout << " Memory Manager::Audit() evictable bytes matches sum over table "<<std::endl;
  assert(AccBytes==DeviceBytes);
  std::cout << " Memory Manager::Audit() device bytes matches sum over table "<<std::endl;
  assert(LruCnt == LRU.size());
  std::cout << " Memory Manager::Audit() LRU entry count matches "<<std::endl;
 }
 void MemoryManager::PrintState(void* _CpuPtr)
 {
  uint64_t CpuPtr = (uint64_t)_CpuPtr;
  if ( EntryPresent(CpuPtr) ){
    auto AccCacheIterator = EntryLookup(CpuPtr);
    auto & AccCache = AccCacheIterator->second;
    std::string str;
    if ( AccCache.state==Empty    ) str = std::string("Empty");
    if ( AccCache.state==CpuDirty ) str = std::string("CpuDirty");
    if ( AccCache.state==AccDirty ) str = std::string("AccDirty");
    if ( AccCache.state==Consistent)str = std::string("Consistent");
    if ( AccCache.state==EvictNext) str = std::string("EvictNext");
    std::cout << GridLogMessage << "CpuAddr\t\tAccAddr\t\tState\t\tcpuLock\taccLock\tLRU_valid "<<std::endl;
    std::cout << GridLogMessage << "\tx"<<std::hex<<AccCache.CpuPtr<<std::dec
    << "\tx"<<std::hex<<AccCache.AccPtr<<std::dec<<"\t" <<str
    << "\t" << AccCache.cpuLock
    << "\t" << AccCache.accLock
    << "\t" << AccCache.LRU_valid<<std::endl;
  } else {
    std::cout << GridLogMessage << "No Entry in AccCache table." << std::endl; 
  }
 }
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/allocator/MemoryManagerShared.cc
+++ b/Grid/allocator/MemoryManagerShared.cc
@@ -0,0 +1,31 @@
 #include <Grid/GridCore.h>
 #ifdef GRID_UVM
 NAMESPACE_BEGIN(Grid);
 /////////////////////////////////////////////////////////////////////////////////
 // View management is 1:1 address space mapping
 /////////////////////////////////////////////////////////////////////////////////
 uint64_t  MemoryManager::DeviceBytes;
 uint64_t  MemoryManager::DeviceLRUBytes;
 uint64_t  MemoryManager::DeviceMaxBytes = 1024*1024*128;
 uint64_t  MemoryManager::HostToDeviceBytes;
 uint64_t  MemoryManager::DeviceToHostBytes;
 uint64_t  MemoryManager::HostToDeviceXfer;
 uint64_t  MemoryManager::DeviceToHostXfer;
 uint64_t  MemoryManager::DeviceEvictions;
 uint64_t  MemoryManager::DeviceDestroy;
 void  MemoryManager::Audit(std::string s){};
 void  MemoryManager::ViewClose(void* AccPtr,ViewMode mode){};
 void *MemoryManager::ViewOpen(void* CpuPtr,size_t bytes,ViewMode mode,ViewAdvise hint){ return CpuPtr; };
 int   MemoryManager::isOpen   (void* CpuPtr) { return 0;}
 void  MemoryManager::PrintState(void* CpuPtr)
 {
 std::cout << GridLogMessage << "Host<->Device memory movement not currently managed by Grid." << std::endl;
 };
 void  MemoryManager::Print(void){};
 void  MemoryManager::PrintAll(void){};
 void  MemoryManager::NotifyDeletion(void *ptr){};
 NAMESPACE_END(Grid);
 #endif
--- a/lib/allocator/AlignedAllocator.cc
+++ b/lib/allocator/AlignedAllocator.cc
@@ -1,70 +1,11 @@
 #include <Grid/GridCore.h>
 #include <fcntl.h>
-namespace Grid {
+NAMESPACE_BEGIN(Grid);
 MemoryStats *MemoryProfiler::stats = nullptr;
 bool         MemoryProfiler::debug = false;
 int PointerCache::victim;
 PointerCache::PointerCacheEntry PointerCache::Entries[PointerCache::Ncache];
 void *PointerCache::Insert(void *ptr,size_t bytes) {
  if (bytes < 4096 ) return ptr;
 #ifdef GRID_OMP
  assert(omp_in_parallel()==0);
 #endif 
  void * ret = NULL;
  int v = -1;
  for(int e=0;e<Ncache;e++) {
    if ( Entries[e].valid==0 ) {
      v=e; 
      break;
    }
  }
  if ( v==-1 ) {
    v=victim;
    victim = (victim+1)%Ncache;
  }
  if ( Entries[v].valid ) {
    ret = Entries[v].address;
    Entries[v].valid = 0;
    Entries[v].address = NULL;
    Entries[v].bytes = 0;
  }
  Entries[v].address=ptr;
  Entries[v].bytes  =bytes;
  Entries[v].valid  =1;
  return ret;
 }
 void *PointerCache::Lookup(size_t bytes) {
 if (bytes < 4096 ) return NULL;
 #ifdef _OPENMP
  assert(omp_in_parallel()==0);
 #endif 
  for(int e=0;e<Ncache;e++){
    if ( Entries[e].valid && ( Entries[e].bytes == bytes ) ) {
      Entries[e].valid = 0;
      return Entries[e].address;
    }
  }
  return NULL;
 }
 void check_huge_pages(void *Buf,uint64_t BYTES)
 {
 #ifdef __linux__
@@ -90,7 +31,7 @@ void check_huge_pages(void *Buf,uint64_t BYTES)
      ++n4ktotal;
      if (pageaddr != baseaddr + j * page_size)
 	++nnothuge;
-      }
+    }
  }
  int rank = CartesianCommunicator::RankWorld();
  printf("rank %d Allocated %d 4k pages, %d not in huge pages\n", rank, n4ktotal, nnothuge);
@@ -106,20 +47,21 @@ std::string sizeString(const size_t bytes)
  double                 count = bytes;
  while (count >= 1024 && s < 7)
-  {
+    {
      s++;
      count /= 1024;
-  }
+    }
  if (count - floor(count) == 0.0)
-  {
+    {
      snprintf(buf, bufSize, "%d %sB", (int)count, suffixes[s]);
-  }
+    }
  else
-  {
+    {
      snprintf(buf, bufSize, "%.1f %sB", count, suffixes[s]);
-  }
+    }
  return std::string(buf);
 }
-}
+NAMESPACE_END(Grid);
--- a/Grid/allocator/MemoryStats.h
+++ b/Grid/allocator/MemoryStats.h
@@ -0,0 +1,95 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./lib/MemoryStats.h
    Copyright (C) 2015
 Author: Azusa Yamaguchi <ayamaguc@staffmail.ed.ac.uk>
 Author: Peter Boyle <paboyle@ph.ed.ac.uk>
    This program is free software; you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation; either version 2 of the License, or
    (at your option) any later version.
    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.
    You should have received a copy of the GNU General Public License along
    with this program; if not, write to the Free Software Foundation, Inc.,
    51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
    See the full license in the file "LICENSE" in the top level distribution directory
 *************************************************************************************/
 /*  END LEGAL */
 #pragma once
 NAMESPACE_BEGIN(Grid);
 std::string sizeString(size_t bytes);
 struct MemoryStats
 {
  size_t totalAllocated{0}, maxAllocated{0}, 
    currentlyAllocated{0}, totalFreed{0};
 };
 class MemoryProfiler
 {
 public:
  static MemoryStats *stats;
  static bool        debug;
 };
 #define memString(bytes) std::to_string(bytes) + " (" + sizeString(bytes) + ")"
 #define profilerDebugPrint						\
  if (MemoryProfiler::stats)						\
    {									\
      auto s = MemoryProfiler::stats;					\
      std::cout << GridLogDebug << "[Memory debug] Stats " << MemoryProfiler::stats << std::endl; \
      std::cout << GridLogDebug << "[Memory debug] total  : " << memString(s->totalAllocated) \
 		<< std::endl;						\
      std::cout << GridLogDebug << "[Memory debug] max    : " << memString(s->maxAllocated) \
 		<< std::endl;						\
      std::cout << GridLogDebug << "[Memory debug] current: " << memString(s->currentlyAllocated) \
 		<< std::endl;						\
      std::cout << GridLogDebug << "[Memory debug] freed  : " << memString(s->totalFreed) \
 		<< std::endl;						\
    }
 #define profilerAllocate(bytes)						\
  if (MemoryProfiler::stats)						\
    {									\
      auto s = MemoryProfiler::stats;					\
      s->totalAllocated     += (bytes);					\
      s->currentlyAllocated += (bytes);					\
      s->maxAllocated        = std::max(s->maxAllocated, s->currentlyAllocated); \
    }									\
  if (MemoryProfiler::debug)						\
    {									\
      std::cout << GridLogDebug << "[Memory debug] allocating " << memString(bytes) << std::endl; \
      profilerDebugPrint;						\
    }
 #define profilerFree(bytes)						\
  if (MemoryProfiler::stats)						\
    {									\
      auto s = MemoryProfiler::stats;					\
      s->totalFreed         += (bytes);					\
      s->currentlyAllocated -= (bytes);					\
    }									\
  if (MemoryProfiler::debug)						\
    {									\
      std::cout << GridLogDebug << "[Memory debug] freeing " << memString(bytes) << std::endl; \
      profilerDebugPrint;						\
    }
 void check_huge_pages(void *Buf,uint64_t BYTES);
 NAMESPACE_END(Grid);
--- a/Grid/cartesian/Cartesian.h
+++ b/Grid/cartesian/Cartesian.h
@@ -1,4 +1,4 @@
-    /*************************************************************************************
+/*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
@@ -23,8 +23,8 @@ Author: Peter Boyle <paboyle@ph.ed.ac.uk>
    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 */
+/*  END LEGAL */
 #ifndef GRID_CARTESIAN_H
 #define GRID_CARTESIAN_H
--- a/Grid/cartesian/Cartesian_base.h
+++ b/Grid/cartesian/Cartesian_base.h
@@ -0,0 +1,291 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./lib/cartesian/Cartesian_base.h
    Copyright (C) 2015
    Author: Peter Boyle <paboyle@ph.ed.ac.uk>
    Author: paboyle <paboyle@ph.ed.ac.uk>
    Author: Guido Cossu <guido.cossu@ed.ac.uk>
    This program is free software; you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation; either version 2 of the License, or
    (at your option) any later version.
    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.
    You should have received a copy of the GNU General Public License along
    with this program; if not, write to the Free Software Foundation, Inc.,
    51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
    See the full license in the file "LICENSE" in the top level distribution directory
 *************************************************************************************/
 /*  END LEGAL */
 #ifndef GRID_CARTESIAN_BASE_H
 #define GRID_CARTESIAN_BASE_H
 NAMESPACE_BEGIN(Grid);
 //////////////////////////////////////////////////////////////////////
 // Commicator provides information on the processor grid
 //////////////////////////////////////////////////////////////////////
 //    unsigned long _ndimension;
 //    Coordinate _processors; // processor grid
 //    int              _processor;  // linear processor rank
 //    Coordinate _processor_coor;  // linear processor rank
 //////////////////////////////////////////////////////////////////////
 class GridBase : public CartesianCommunicator , public GridThread {
 public:
  int dummy;
  // Give Lattice access
  template<class object> friend class Lattice;
  GridBase(const Coordinate & processor_grid) : CartesianCommunicator(processor_grid) { LocallyPeriodic=0;}; 
  GridBase(const Coordinate & processor_grid,
 	   const CartesianCommunicator &parent,
 	   int &split_rank) 
    : CartesianCommunicator(processor_grid,parent,split_rank) {LocallyPeriodic=0;};
  GridBase(const Coordinate & processor_grid,
 	   const CartesianCommunicator &parent) 
    : CartesianCommunicator(processor_grid,parent,dummy) {LocallyPeriodic=0;};
  virtual ~GridBase() = default;
  // Physics Grid information.
  Coordinate _simd_layout;// Which dimensions get relayed out over simd lanes.
  Coordinate _fdimensions;// (full) Global dimensions of array prior to cb removal
  Coordinate _gdimensions;// Global dimensions of array after cb removal
  Coordinate _ldimensions;// local dimensions of array with processor images removed
  Coordinate _rdimensions;// Reduced local dimensions with simd lane images and processor images removed 
  Coordinate _ostride;    // Outer stride for each dimension
  Coordinate _istride;    // Inner stride i.e. within simd lane
  int _osites;                  // _isites*_osites = product(dimensions).
  int _isites;
  int _fsites;                  // _isites*_osites = product(dimensions).
  int _gsites;
  Coordinate _slice_block;// subslice information
  Coordinate _slice_stride;
  Coordinate _slice_nblock;
  Coordinate _lstart;     // local start of array in gcoors _processor_coor[d]*_ldimensions[d]
  Coordinate _lend  ;     // local end of array in gcoors   _processor_coor[d]*_ldimensions[d]+_ldimensions_[d]-1
  bool _isCheckerBoarded; 
  int        LocallyPeriodic;
  Coordinate _checker_dim_mask;
 public:
  ////////////////////////////////////////////////////////////////
  // Checkerboarding interface is virtual and overridden by 
  // GridCartesian / GridRedBlackCartesian
  ////////////////////////////////////////////////////////////////
  virtual int CheckerBoarded(int dim)=0;
  virtual int CheckerBoard(const Coordinate &site)=0;
  virtual int CheckerBoardDestination(int source_cb,int shift,int dim)=0;
  virtual int CheckerBoardShift(int source_cb,int dim,int shift,int osite)=0;
  virtual int CheckerBoardShiftForCB(int source_cb,int dim,int shift,int cb)=0;
  virtual int CheckerBoardFromOindex (int Oindex)=0;
  virtual int CheckerBoardFromOindexTable (int Oindex)=0;
  //////////////////////////////////////////////////////////////////////////////////////////////
  // Local layout calculations
  //////////////////////////////////////////////////////////////////////////////////////////////
  // These routines are key. Subdivide the linearised cartesian index into
  //      "inner" index identifying which simd lane of object<vFcomplex> is associated with coord
  //      "outer" index identifying which element of _odata in class "Lattice" is associated with coord.
  //
  // Compared to, say, Blitz++ we simply need to store BOTH an inner stride and an outer
  // stride per dimension. The cost of evaluating the indexing information is doubled for an n-dimensional
  // coordinate. Note, however, for data parallel operations the "inner" indexing cost is not paid and all
  // lanes are operated upon simultaneously.
  virtual int oIndex(Coordinate &coor)
  {
    int idx=0;
    // Works with either global or local coordinates
    for(int d=0;d<_ndimension;d++) idx+=_ostride[d]*(coor[d]%_rdimensions[d]);
    return idx;
  }
  virtual int iIndex(Coordinate &lcoor)
  {
    int idx=0;
    for(int d=0;d<_ndimension;d++) idx+=_istride[d]*(lcoor[d]/_rdimensions[d]);
    return idx;
  }
  inline int oIndexReduced(Coordinate &ocoor)
  {
    int idx=0; 
    // ocoor is already reduced so can eliminate the modulo operation
    // for fast indexing and inline the routine
    for(int d=0;d<_ndimension;d++) idx+=_ostride[d]*ocoor[d];
    return idx;
  }
  inline void oCoorFromOindex (Coordinate& coor,int Oindex){
    Lexicographic::CoorFromIndex(coor,Oindex,_rdimensions);
  }
  inline void InOutCoorToLocalCoor (Coordinate &ocoor, Coordinate &icoor, Coordinate &lcoor) {
    lcoor.resize(_ndimension);
    for (int d = 0; d < _ndimension; d++)
      lcoor[d] = ocoor[d] + _rdimensions[d] * icoor[d];
  }
  //////////////////////////////////////////////////////////
  // SIMD lane addressing
  //////////////////////////////////////////////////////////
  inline void iCoorFromIindex(Coordinate &coor,int lane)
  {
    Lexicographic::CoorFromIndex(coor,lane,_simd_layout);
  }
  inline int PermuteDim(int dimension){
    return _simd_layout[dimension]>1;
  }
  inline int PermuteType(int dimension){
    int permute_type=0;
    //
    // Best way to encode this would be to present a mask 
    // for which simd dimensions are rotated, and the rotation
    // size. If there is only one simd dimension rotated, this is just 
    // a permute. 
    //
    // Cases: PermuteType == 1,2,4,8
    // Distance should be either 0,1,2..
    //
    if ( _simd_layout[dimension] > 2 ) { 
      for(int d=0;d<_ndimension;d++){
 	if ( d != dimension ) assert ( (_simd_layout[d]==1)  );
      }
      permute_type = RotateBit; // How to specify distance; this is not just direction.
      return permute_type;
    }
    for(int d=_ndimension-1;d>dimension;d--){
      if (_simd_layout[d]>1 ) permute_type++;
    }
    return permute_type;
  }
  ////////////////////////////////////////////////////////////////
  // Array sizing queries
  ////////////////////////////////////////////////////////////////
  inline int iSites(void) const { return _isites; };
  inline int Nsimd(void)  const { return _isites; };// Synonymous with iSites
  inline int oSites(void) const { return _osites; };
  inline int lSites(void) const { return _isites*_osites; }; 
  inline int gSites(void) const { return _isites*_osites*_Nprocessors; }; 
  inline int Nd    (void) const { return _ndimension;};
  inline const Coordinate LocalStarts(void)             { return _lstart;    };
  inline const Coordinate &FullDimensions(void)         { return _fdimensions;};
  inline const Coordinate &GlobalDimensions(void)       { return _gdimensions;};
  inline const Coordinate &LocalDimensions(void)        { return _ldimensions;};
  inline const Coordinate &VirtualLocalDimensions(void) { return _ldimensions;};
  ////////////////////////////////////////////////////////////////
  // Utility to print the full decomposition details 
  ////////////////////////////////////////////////////////////////
  void show_decomposition(){
    std::cout << GridLogMessage << "\tFull Dimensions    : " << _fdimensions << std::endl;
    std::cout << GridLogMessage << "\tSIMD layout        : " << _simd_layout << std::endl;
    std::cout << GridLogMessage << "\tGlobal Dimensions  : " << _gdimensions << std::endl;
    std::cout << GridLogMessage << "\tLocal Dimensions   : " << _ldimensions << std::endl;
    std::cout << GridLogMessage << "\tReduced Dimensions : " << _rdimensions << std::endl;
    std::cout << GridLogMessage << "\tOuter strides      : " << _ostride << std::endl;
    std::cout << GridLogMessage << "\tInner strides      : " << _istride << std::endl;
    std::cout << GridLogMessage << "\tiSites             : " << _isites << std::endl;
    std::cout << GridLogMessage << "\toSites             : " << _osites << std::endl;
    std::cout << GridLogMessage << "\tlSites             : " << lSites() << std::endl;        
    std::cout << GridLogMessage << "\tgSites             : " << gSites() << std::endl;
    std::cout << GridLogMessage << "\tNd                 : " << _ndimension << std::endl;             
  } 
  ////////////////////////////////////////////////////////////////
  // Global addressing
  ////////////////////////////////////////////////////////////////
  void GlobalIndexToGlobalCoor(int gidx,Coordinate &gcoor){
    assert(gidx< gSites());
    Lexicographic::CoorFromIndex(gcoor,gidx,_gdimensions);
  }
  void LocalIndexToLocalCoor(int lidx,Coordinate &lcoor){
    assert(lidx<lSites());
    Lexicographic::CoorFromIndex(lcoor,lidx,_ldimensions);
  }
  void GlobalCoorToGlobalIndex(const Coordinate & gcoor,int & gidx){
    gidx=0;
    int mult=1;
    for(int mu=0;mu<_ndimension;mu++) {
      gidx+=mult*gcoor[mu];
      mult*=_gdimensions[mu];
    }
  }
  void GlobalCoorToProcessorCoorLocalCoor(Coordinate &pcoor,Coordinate &lcoor,const Coordinate &gcoor)
  {
    pcoor.resize(_ndimension);
    lcoor.resize(_ndimension);
    for(int mu=0;mu<_ndimension;mu++){
      int _fld  = _fdimensions[mu]/_processors[mu];
      pcoor[mu] = gcoor[mu]/_fld;
      lcoor[mu] = gcoor[mu]%_fld;
    }
  }
  void GlobalCoorToRankIndex(int &rank, int &o_idx, int &i_idx ,const Coordinate &gcoor)
  {
    Coordinate pcoor;
    Coordinate lcoor;
    GlobalCoorToProcessorCoorLocalCoor(pcoor,lcoor,gcoor);
    rank = RankFromProcessorCoor(pcoor);
    /*
      Coordinate cblcoor(lcoor);
      for(int d=0;d<cblcoor.size();d++){
      if( this->CheckerBoarded(d) ) {
      cblcoor[d] = lcoor[d]/2;
      }
      }
    */
    i_idx= iIndex(lcoor);
    o_idx= oIndex(lcoor);
  }
  void RankIndexToGlobalCoor(int rank, int o_idx, int i_idx , Coordinate &gcoor)
  {
    gcoor.resize(_ndimension);
    Coordinate coor(_ndimension);
    ProcessorCoorFromRank(rank,coor);
    for(int mu=0;mu<_ndimension;mu++) gcoor[mu] = _ldimensions[mu]*coor[mu];
    iCoorFromIindex(coor,i_idx);
    for(int mu=0;mu<_ndimension;mu++) gcoor[mu] += _rdimensions[mu]*coor[mu];
    oCoorFromOindex (coor,o_idx);
    for(int mu=0;mu<_ndimension;mu++) gcoor[mu] += coor[mu];
  }
  void RankIndexCbToFullGlobalCoor(int rank, int o_idx, int i_idx, int cb,Coordinate &fcoor)
  {
    RankIndexToGlobalCoor(rank,o_idx,i_idx ,fcoor);
    if(CheckerBoarded(0)){
      fcoor[0] = fcoor[0]*2+cb;
    }
  }
  void ProcessorCoorLocalCoorToGlobalCoor(Coordinate &Pcoor,Coordinate &Lcoor,Coordinate &gcoor)
  {
    gcoor.resize(_ndimension);
    for(int mu=0;mu<_ndimension;mu++) gcoor[mu] = Pcoor[mu]*_ldimensions[mu]+Lcoor[mu];
  }
 };
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/cartesian/Cartesian_full.h
+++ b/Grid/cartesian/Cartesian_full.h
@@ -0,0 +1,178 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./lib/cartesian/Cartesian_full.h
    Copyright (C) 2015
 Author: Peter Boyle <paboyle@ph.ed.ac.uk>
    This program is free software; you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation; either version 2 of the License, or
    (at your option) any later version.
    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.
    You should have received a copy of the GNU General Public License along
    with this program; if not, write to the Free Software Foundation, Inc.,
    51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
    See the full license in the file "LICENSE" in the top level distribution directory
 *************************************************************************************/
 /*  END LEGAL */
 #ifndef GRID_CARTESIAN_FULL_H
 #define GRID_CARTESIAN_FULL_H
 NAMESPACE_BEGIN(Grid);
 /////////////////////////////////////////////////////////////////////////////////////////
 // Grid Support.
 /////////////////////////////////////////////////////////////////////////////////////////
 class GridCartesian: public GridBase {
 public:
  int dummy;
  Coordinate _checker_dim_mask;
  virtual int  CheckerBoardFromOindexTable (int Oindex) {
    return 0;
  }
  virtual int  CheckerBoardFromOindex (int Oindex)
  {
    return 0;
  }
  virtual int CheckerBoarded(int dim){
    return 0;
  }
  virtual int CheckerBoard(const Coordinate &site){
    return 0;
  }
  virtual int CheckerBoardDestination(int cb,int shift,int dim){
    return 0;
  }
  virtual int CheckerBoardShiftForCB(int source_cb,int dim,int shift, int ocb){
    return shift;
  }
  virtual int CheckerBoardShift(int source_cb,int dim,int shift, int osite){
    return shift;
  }
  /////////////////////////////////////////////////////////////////////////
  // Constructor takes a parent grid and possibly subdivides communicator.
  /////////////////////////////////////////////////////////////////////////
  GridCartesian(const Coordinate &dimensions,
 		const Coordinate &simd_layout,
 		const Coordinate &processor_grid,
 		const GridCartesian &parent) : GridBase(processor_grid,parent,dummy)
  {
    Init(dimensions,simd_layout,processor_grid);
  }
  GridCartesian(const Coordinate &dimensions,
 		const Coordinate &simd_layout,
 		const Coordinate &processor_grid,
 		const GridCartesian &parent,int &split_rank) : GridBase(processor_grid,parent,split_rank)
  {
    Init(dimensions,simd_layout,processor_grid);
  }
  /////////////////////////////////////////////////////////////////////////
  // Construct from comm world
  /////////////////////////////////////////////////////////////////////////
  GridCartesian(const Coordinate &dimensions,
 		const Coordinate &simd_layout,
 		const Coordinate &processor_grid) : GridBase(processor_grid)
  {
    Init(dimensions,simd_layout,processor_grid);
  }
  virtual ~GridCartesian() = default;
  void Init(const Coordinate &dimensions,
 	    const Coordinate &simd_layout,
 	    const Coordinate &processor_grid)
  {
    ///////////////////////
    // Grid information
    ///////////////////////
      _isCheckerBoarded = false;
    _ndimension = dimensions.size();
    _fdimensions.resize(_ndimension);
    _gdimensions.resize(_ndimension);
    _ldimensions.resize(_ndimension);
    _rdimensions.resize(_ndimension);
    _simd_layout.resize(_ndimension);
    _checker_dim_mask.resize(_ndimension);;
    _lstart.resize(_ndimension);
    _lend.resize(_ndimension);
    _ostride.resize(_ndimension);
    _istride.resize(_ndimension);
    _fsites = _gsites = _osites = _isites = 1;
    for (int d = 0; d < _ndimension; d++)
      {
 	_checker_dim_mask[d]=0;
        _fdimensions[d] = dimensions[d];   // Global dimensions
        _gdimensions[d] = _fdimensions[d]; // Global dimensions
        _simd_layout[d] = simd_layout[d];
        _fsites = _fsites * _fdimensions[d];
        _gsites = _gsites * _gdimensions[d];
        // Use a reduced simd grid
        _ldimensions[d] = _gdimensions[d] / _processors[d]; //local dimensions
        //std::cout << _ldimensions[d] << "  " << _gdimensions[d] << "  " << _processors[d] << std::endl;
        assert(_ldimensions[d] * _processors[d] == _gdimensions[d]);
        _rdimensions[d] = _ldimensions[d] / _simd_layout[d]; //overdecomposition
        assert(_rdimensions[d] * _simd_layout[d] == _ldimensions[d]);
        _lstart[d] = _processor_coor[d] * _ldimensions[d];
        _lend[d] = _processor_coor[d] * _ldimensions[d] + _ldimensions[d] - 1;
        _osites *= _rdimensions[d];
        _isites *= _simd_layout[d];
        // Addressing support
        if (d == 0)
 	  {
 	    _ostride[d] = 1;
 	    _istride[d] = 1;
 	  }
        else
 	  {
 	    _ostride[d] = _ostride[d - 1] * _rdimensions[d - 1];
 	    _istride[d] = _istride[d - 1] * _simd_layout[d - 1];
 	  }
      }
    ///////////////////////
    // subplane information
    ///////////////////////
    _slice_block.resize(_ndimension);
    _slice_stride.resize(_ndimension);
    _slice_nblock.resize(_ndimension);
    int block = 1;
    int nblock = 1;
    for (int d = 0; d < _ndimension; d++)
      nblock *= _rdimensions[d];
    for (int d = 0; d < _ndimension; d++)
      {
        nblock /= _rdimensions[d];
        _slice_block[d] = block;
        _slice_stride[d] = _ostride[d] * _rdimensions[d];
        _slice_nblock[d] = nblock;
        block = block * _rdimensions[d];
      }
  };
 };
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/cartesian/Cartesian_red_black.h
+++ b/Grid/cartesian/Cartesian_red_black.h
@@ -0,0 +1,305 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./lib/cartesian/Cartesian_red_black.h
    Copyright (C) 2015
 Author: Azusa Yamaguchi <ayamaguc@staffmail.ed.ac.uk>
 Author: Peter Boyle <paboyle@ph.ed.ac.uk>
    This program is free software; you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation; either version 2 of the License, or
    (at your option) any later version.
    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.
    You should have received a copy of the GNU General Public License along
    with this program; if not, write to the Free Software Foundation, Inc.,
    51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
    See the full license in the file "LICENSE" in the top level distribution directory
 *************************************************************************************/
 /*  END LEGAL */
 #ifndef GRID_CARTESIAN_RED_BLACK_H
 #define GRID_CARTESIAN_RED_BLACK_H
 NAMESPACE_BEGIN(Grid);
 static const int CbRed  =0;
 static const int CbBlack=1;
 static const int Even   =CbRed;
 static const int Odd    =CbBlack;
 accelerator_inline int RedBlackCheckerBoardFromOindex (int oindex,const Coordinate &rdim,const Coordinate &chk_dim_msk)
 {
  int nd=rdim.size();
  Coordinate coor(nd);
  Lexicographic::CoorFromIndex(coor,oindex,rdim);
  int linear=0;
  for(int d=0;d<nd;d++){
    if(chk_dim_msk[d])
      linear=linear+coor[d];
  }
  return (linear&0x1);
 }
 // Specialise this for red black grids storing half the data like a chess board.
 class GridRedBlackCartesian : public GridBase
 {
 public:
  //  Coordinate _checker_dim_mask;
  int              _checker_dim;
  std::vector<int> _checker_board;
  virtual int CheckerBoarded(int dim){
    if( dim==_checker_dim) return 1;
    else return 0;
  }
  virtual int CheckerBoard(const Coordinate &site){
    int linear=0;
    assert(site.size()==_ndimension);
    for(int d=0;d<_ndimension;d++){ 
      if(_checker_dim_mask[d])
 	linear=linear+site[d];
    }
    return (linear&0x1);
  }
  // Depending on the cb of site, we toggle source cb.
  // for block #b, element #e = (b, e)
  // we need 
  virtual int CheckerBoardShiftForCB(int source_cb,int dim,int shift,int ocb){
    if(dim != _checker_dim) return shift;
    int fulldim =_fdimensions[dim];
    shift = (shift+fulldim)%fulldim;
    // Probably faster with table lookup;
    // or by looping over x,y,z and multiply rather than computing checkerboard.
    if ( (source_cb+ocb)&1 ) {
      return (shift)/2;
    } else {
      return (shift+1)/2;
    }
  }
  virtual int  CheckerBoardFromOindexTable (int Oindex) {
    return _checker_board[Oindex];
  }
  virtual int  CheckerBoardFromOindex (int Oindex)
  {
    Coordinate ocoor;
    oCoorFromOindex(ocoor,Oindex);
    return CheckerBoard(ocoor);
  }
  virtual int CheckerBoardShift(int source_cb,int dim,int shift,int osite){
    if(dim != _checker_dim) return shift;
    int ocb=CheckerBoardFromOindex(osite);
    return CheckerBoardShiftForCB(source_cb,dim,shift,ocb);
  }
  virtual int CheckerBoardDestination(int source_cb,int shift,int dim){
    if ( _checker_dim_mask[dim]  ) {
      // If _fdimensions[checker_dim] is odd, then shifting by 1 in other dims
      // does NOT cause a parity hop.
      int add=(dim==_checker_dim) ? 0 : _fdimensions[_checker_dim];
      if ( (shift+add) &0x1) {
 	return 1-source_cb;
      } else {
 	return source_cb;
      }
    } else {
      return source_cb;
    }
  };
  ////////////////////////////////////////////////////////////
  // Create Redblack from original grid; require full grid pointer ?
  ////////////////////////////////////////////////////////////
  GridRedBlackCartesian(const GridBase *base) : GridBase(base->_processors,*base)
  {
    int dims = base->_ndimension;
    Coordinate checker_dim_mask(dims,1);
    int checker_dim = 0;
    Init(base->_fdimensions,base->_simd_layout,base->_processors,checker_dim_mask,checker_dim);
  };
  ////////////////////////////////////////////////////////////
  // Create redblack from original grid, with non-trivial checker dim mask
  ////////////////////////////////////////////////////////////
  GridRedBlackCartesian(const GridBase *base,
 			const Coordinate &checker_dim_mask,
 			int checker_dim
 			) :  GridBase(base->_processors,*base) 
  {
    Init(base->_fdimensions,base->_simd_layout,base->_processors,checker_dim_mask,checker_dim)  ;
  }
  virtual ~GridRedBlackCartesian() = default;
  void Init(const Coordinate &dimensions,
 	    const Coordinate &simd_layout,
 	    const Coordinate &processor_grid,
 	    const Coordinate &checker_dim_mask,
 	    int checker_dim)
  {
      _isCheckerBoarded = true;
    _checker_dim = checker_dim;
    assert(checker_dim_mask[checker_dim] == 1);
    _ndimension = dimensions.size();
    assert(checker_dim_mask.size() == _ndimension);
    assert(processor_grid.size() == _ndimension);
    assert(simd_layout.size() == _ndimension);
    _fdimensions.resize(_ndimension);
    _gdimensions.resize(_ndimension);
    _ldimensions.resize(_ndimension);
    _rdimensions.resize(_ndimension);
    _simd_layout.resize(_ndimension);
    _lstart.resize(_ndimension);
    _lend.resize(_ndimension);
    _ostride.resize(_ndimension);
    _istride.resize(_ndimension);
    _fsites = _gsites = _osites = _isites = 1;
    _checker_dim_mask = checker_dim_mask;
    for (int d = 0; d < _ndimension; d++)
      {
        _fdimensions[d] = dimensions[d];
        _gdimensions[d] = _fdimensions[d];
        _fsites = _fsites * _fdimensions[d];
        _gsites = _gsites * _gdimensions[d];
        if (d == _checker_dim)
 	  {
 	    assert((_gdimensions[d] & 0x1) == 0);
 	    _gdimensions[d] = _gdimensions[d] / 2; // Remove a checkerboard
 	    _gsites /= 2;
 	  }
        _ldimensions[d] = _gdimensions[d] / _processors[d];
        assert(_ldimensions[d] * _processors[d] == _gdimensions[d]);
        _lstart[d] = _processor_coor[d] * _ldimensions[d];
        _lend[d] = _processor_coor[d] * _ldimensions[d] + _ldimensions[d] - 1;
        // Use a reduced simd grid
        _simd_layout[d] = simd_layout[d];
        _rdimensions[d] = _ldimensions[d] / _simd_layout[d]; // this is not checking if this is integer
        assert(_rdimensions[d] * _simd_layout[d] == _ldimensions[d]);
        assert(_rdimensions[d] > 0);
        // all elements of a simd vector must have same checkerboard.
        // If Ls vectorised, this must still be the case; e.g. dwf rb5d
        if (_simd_layout[d] > 1)
 	  {
 	    if (checker_dim_mask[d])
 	      {
 		assert((_rdimensions[d] & 0x1) == 0);
 	      }
 	  }
        _osites *= _rdimensions[d];
        _isites *= _simd_layout[d];
        // Addressing support
        if (d == 0)
 	  {
 	    _ostride[d] = 1;
 	    _istride[d] = 1;
 	  }
        else
 	  {
 	    _ostride[d] = _ostride[d - 1] * _rdimensions[d - 1];
 	    _istride[d] = _istride[d - 1] * _simd_layout[d - 1];
 	  }
      }
    ////////////////////////////////////////////////////////////////////////////////////////////
    // subplane information
    ////////////////////////////////////////////////////////////////////////////////////////////
    _slice_block.resize(_ndimension);
    _slice_stride.resize(_ndimension);
    _slice_nblock.resize(_ndimension);
    int block = 1;
    int nblock = 1;
    for (int d = 0; d < _ndimension; d++)
      nblock *= _rdimensions[d];
    for (int d = 0; d < _ndimension; d++)
      {
        nblock /= _rdimensions[d];
        _slice_block[d] = block;
        _slice_stride[d] = _ostride[d] * _rdimensions[d];
        _slice_nblock[d] = nblock;
        block = block * _rdimensions[d];
      }
    ////////////////////////////////////////////////
    // Create a checkerboard lookup table
    ////////////////////////////////////////////////
    int rvol = 1;
    for (int d = 0; d < _ndimension; d++)
      {
        rvol = rvol * _rdimensions[d];
      }
    _checker_board.resize(rvol);
    for (int osite = 0; osite < _osites; osite++)
      {
        _checker_board[osite] = CheckerBoardFromOindex(osite);
      }
  };
 protected:
  virtual int oIndex(Coordinate &coor)
  {
    int idx = 0;
    for (int d = 0; d < _ndimension; d++)
      {
        if (d == _checker_dim)
 	  {
 	    idx += _ostride[d] * ((coor[d] / 2) % _rdimensions[d]);
 	  }
        else
 	  {
 	    idx += _ostride[d] * (coor[d] % _rdimensions[d]);
 	  }
      }
    return idx;
  };
  virtual int iIndex(Coordinate &lcoor)
  {
    int idx = 0;
    for (int d = 0; d < _ndimension; d++)
      {
        if (d == _checker_dim)
 	  {
 	    idx += _istride[d] * (lcoor[d] / (2 * _rdimensions[d]));
 	  }
        else
 	  {
 	    idx += _istride[d] * (lcoor[d] / _rdimensions[d]);
 	  }
      }
    return idx;
  }
 };
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/communicator/Communicator.h
+++ b/Grid/communicator/Communicator.h
@@ -1,4 +1,4 @@
-    /*************************************************************************************
+/*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
@@ -23,11 +23,12 @@ Author: Peter Boyle <paboyle@ph.ed.ac.uk>
    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 */
+/*  END LEGAL */
 #ifndef GRID_COMMUNICATOR_H
 #define GRID_COMMUNICATOR_H
 #include <Grid/util/Coordinate.h>
 #include <Grid/communicator/SharedMemory.h>
 #include <Grid/communicator/Communicator_base.h>
--- a/Grid/communicator/Communicator_base.cc
+++ b/Grid/communicator/Communicator_base.cc
@@ -1,4 +1,4 @@
-    /*************************************************************************************
+/*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
@@ -23,15 +23,17 @@ Author: Peter Boyle <paboyle@ph.ed.ac.uk>
    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 */
+/*  END LEGAL */
 #include <Grid/GridCore.h>
 #include <fcntl.h>
 #include <unistd.h>
 #include <limits.h>
 #include <sys/mman.h>
-namespace Grid {
+NAMESPACE_BEGIN(Grid);
 bool Stencil_force_mpi = true;
 ///////////////////////////////////////////////////////////////
 // Info that is setup once and indept of cartesian layout
@@ -47,8 +49,8 @@ int                      CartesianCommunicator::Dimensions(void)        { return
 int                      CartesianCommunicator::IsBoss(void)            { return _processor==0; };
 int                      CartesianCommunicator::BossRank(void)          { return 0; };
 int                      CartesianCommunicator::ThisRank(void)          { return _processor; };
-const std::vector<int> & CartesianCommunicator::ThisProcessorCoor(void) { return _processor_coor; };
+const Coordinate & CartesianCommunicator::ThisProcessorCoor(void) { return _processor_coor; };
-const std::vector<int> & CartesianCommunicator::ProcessorGrid(void)     { return _processors; };
+const Coordinate & CartesianCommunicator::ProcessorGrid(void)     { return _processors; };
 int                      CartesianCommunicator::ProcessorCount(void)    { return _Nprocessors; };
 ////////////////////////////////////////////////////////////////////////////////
@@ -72,5 +74,6 @@ void CartesianCommunicator::GlobalSumVector(ComplexD *c,int N)
  GlobalSumVector((double *)c,2*N);
 }
-}
+NAMESPACE_END(Grid);
--- a/Grid/communicator/Communicator_base.h
+++ b/Grid/communicator/Communicator_base.h
@@ -1,5 +1,4 @@
-
+/*************************************************************************************
    /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
@@ -24,8 +23,8 @@ Author: Peter Boyle <paboyle@ph.ed.ac.uk>
    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 */
+/*  END LEGAL */
 #ifndef GRID_COMMUNICATOR_BASE_H
 #define GRID_COMMUNICATOR_BASE_H
@@ -34,7 +33,9 @@ Author: Peter Boyle <paboyle@ph.ed.ac.uk>
 ///////////////////////////////////
 #include <Grid/communicator/SharedMemory.h>
-namespace Grid {
+NAMESPACE_BEGIN(Grid);
 extern bool Stencil_force_mpi ;
 class CartesianCommunicator : public SharedMemory {
@@ -52,10 +53,11 @@ public:
  // Communicator should know nothing of the physics grid, only processor grid.
  ////////////////////////////////////////////
  int              _Nprocessors;     // How many in all
  std::vector<int> _processors;      // Which dimensions get relayed out over processors lanes.
  int              _processor;       // linear processor rank
  std::vector<int> _processor_coor;  // linear processor coordinate
  unsigned long    _ndimension;
  Coordinate _shm_processors;  // Which dimensions get relayed out over processors lanes.
  Coordinate _processors;      // Which dimensions get relayed out over processors lanes.
  Coordinate _processor_coor;  // linear processor coordinate
  static Grid_MPI_Comm      communicator_world;
  Grid_MPI_Comm             communicator;
  std::vector<Grid_MPI_Comm> communicator_halo;
@@ -69,51 +71,56 @@ public:
  // Constructors to sub-divide a parent communicator
  // and default to comm world
  ////////////////////////////////////////////////
-  CartesianCommunicator(const std::vector<int> &processors,const CartesianCommunicator &parent,int &srank);
+  CartesianCommunicator(const Coordinate &processors,const CartesianCommunicator &parent,int &srank);
-  CartesianCommunicator(const std::vector<int> &pdimensions_in);
+  CartesianCommunicator(const Coordinate &pdimensions_in);
  virtual ~CartesianCommunicator();
- private:
+private:
  ////////////////////////////////////////////////
  // Private initialise from an MPI communicator
  // Can use after an MPI_Comm_split, but hidden from user so private
  ////////////////////////////////////////////////
-  void InitFromMPICommunicator(const std::vector<int> &processors, Grid_MPI_Comm communicator_base);
+  void InitFromMPICommunicator(const Coordinate &processors, Grid_MPI_Comm communicator_base);
 public:
 public:
  ////////////////////////////////////////////////////////////////////////////////////////
  // Wraps MPI_Cart routines, or implements equivalent on other impls
  ////////////////////////////////////////////////////////////////////////////////////////
  void ShiftedRanks(int dim,int shift,int & source, int & dest);
-  int  RankFromProcessorCoor(std::vector<int> &coor);
+  int  RankFromProcessorCoor(Coordinate &coor);
-  void ProcessorCoorFromRank(int rank,std::vector<int> &coor);
+  void ProcessorCoorFromRank(int rank,Coordinate &coor);
  int                      Dimensions(void)        ;
  int                      IsBoss(void)            ;
  int                      BossRank(void)          ;
  int                      ThisRank(void)          ;
-  const std::vector<int> & ThisProcessorCoor(void) ;
+  const Coordinate & ThisProcessorCoor(void) ;
-  const std::vector<int> & ProcessorGrid(void)     ;
+  const Coordinate & ShmGrid(void)  { return _shm_processors; }  ;
-  int                      ProcessorCount(void)    ;
+  const Coordinate & ProcessorGrid(void)     ;
  int                ProcessorCount(void)    ;
  ////////////////////////////////////////////////////////////////////////////////
  // very VERY rarely (Log, serial RNG) we need world without a grid
  ////////////////////////////////////////////////////////////////////////////////
  static int  RankWorld(void) ;
  static void BroadcastWorld(int root,void* data, int bytes);
  static void BarrierWorld(void);
  ////////////////////////////////////////////////////////////
  // Reduction
  ////////////////////////////////////////////////////////////
  void GlobalMax(RealD &);
  void GlobalMax(RealF &);
  void GlobalSum(RealF &);
  void GlobalSumVector(RealF *,int N);
  void GlobalSum(RealD &);
  void GlobalSumVector(RealD *,int N);
  void GlobalSum(uint32_t &);
  void GlobalSum(uint64_t &);
  void GlobalSumVector(uint64_t*,int N);
  void GlobalSum(ComplexF &c);
  void GlobalSumVector(ComplexF *c,int N);
  void GlobalSum(ComplexD &c);
@@ -124,7 +131,7 @@ public:
  template<class obj> void GlobalSum(obj &o){
    typedef typename obj::scalar_type scalar_type;
    int words = sizeof(obj)/sizeof(scalar_type);
-    scalar_type * ptr = (scalar_type *)& o;
+    scalar_type * ptr = (scalar_type *)& o; // Safe alias 
    GlobalSumVector(ptr,words);
  }
@@ -137,33 +144,18 @@ public:
 		      int recv_from_rank,
 		      int bytes);
  void SendRecvPacket(void *xmit,
 		      void *recv,
 		      int xmit_to_rank,
 		      int recv_from_rank,
 		      int bytes);
  void SendToRecvFromBegin(std::vector<CommsRequest_t> &list,
 			   void *xmit,
 			   int xmit_to_rank,
 			   void *recv,
 			   int recv_from_rank,
 			   int bytes);
  void SendToRecvFromComplete(std::vector<CommsRequest_t> &waitall);
  double StencilSendToRecvFrom(void *xmit,
-			       int xmit_to_rank,
+			       int xmit_to_rank,int do_xmit,
 			       void *recv,
-			       int recv_from_rank,
+			       int recv_from_rank,int do_recv,
 			       int bytes,int dir);
  double StencilSendToRecvFromBegin(std::vector<CommsRequest_t> &list,
 				    void *xmit,
-				    int xmit_to_rank,
+				    int xmit_to_rank,int do_xmit,
 				    void *recv,
-				    int recv_from_rank,
+				    int recv_from_rank,int do_recv,
-				    int bytes,int dir);
+				    int xbytes,int rbytes,int dir);
  void StencilSendToRecvFromComplete(std::vector<CommsRequest_t> &waitall,int i);
@@ -197,11 +189,12 @@ public:
  void AllToAll(void  *in,void *out,uint64_t words         ,uint64_t bytes);
  template<class obj> void Broadcast(int root,obj &data)
-    {
+  {
-      Broadcast(root,(void *)&data,sizeof(data));
+    Broadcast(root,(void *)&data,sizeof(data));
-    };
+  }
 }; 
-}
+
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/communicator/Communicator_mpi3.cc
+++ b/Grid/communicator/Communicator_mpi3.cc
@@ -1,6 +1,6 @@
 /*************************************************************************************
-    Grid physics library, www.github.com/paboyle/Grid 
+    Grid physics library, www.github.com/paboyle/Grid
    Source file: ./lib/communicator/Communicator_mpi.cc
@@ -23,19 +23,19 @@ Author: Peter Boyle <paboyle@ph.ed.ac.uk>
    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 */
+/*  END LEGAL */
 #include <Grid/GridCore.h>
 #include <Grid/communicator/SharedMemory.h>
-namespace Grid {
+NAMESPACE_BEGIN(Grid);
 Grid_MPI_Comm       CartesianCommunicator::communicator_world;
 ////////////////////////////////////////////
 // First initialise of comms system
 ////////////////////////////////////////////
-void CartesianCommunicator::Init(int *argc, char ***argv) 
+void CartesianCommunicator::Init(int *argc, char ***argv)
 {
  int flag;
@@ -43,22 +43,35 @@ void CartesianCommunicator::Init(int *argc, char ***argv)
  MPI_Initialized(&flag); // needed to coexist with other libs apparently
  if ( !flag ) {
    MPI_Init_thread(argc,argv,MPI_THREAD_MULTIPLE,&provided);
    //If only 1 comms thread we require any threading mode other than SINGLE, but for multiple comms threads we need MULTIPLE
    if( (nCommThreads == 1 && provided == MPI_THREAD_SINGLE) ||
        (nCommThreads > 1 && provided != MPI_THREAD_MULTIPLE) )
      assert(0);
  }
-  Grid_quiesce_nodes();
+#ifndef GRID_COMMS_THREADS
    nCommThreads=1;
    // wrong results here too
    // For now: comms-overlap leads to wrong results in Benchmark_wilson even on single node MPI runs
    // other comms schemes are ok
    MPI_Init_thread(argc,argv,MPI_THREAD_SERIALIZED,&provided);
 #else
    MPI_Init_thread(argc,argv,MPI_THREAD_MULTIPLE,&provided);
 #endif
    //If only 1 comms thread we require any threading mode other than SINGLE, but for multiple comms threads we need MULTIPLE
    if( (nCommThreads == 1) && (provided == MPI_THREAD_SINGLE) ) {
      assert(0);
    }
    if( (nCommThreads > 1) && (provided != MPI_THREAD_MULTIPLE) ) {
      assert(0);
    }
  }
  // Never clean up as done once.
  MPI_Comm_dup (MPI_COMM_WORLD,&communicator_world);
  Grid_quiesce_nodes();
  GlobalSharedMemory::Init(communicator_world);
  GlobalSharedMemory::SharedMemoryAllocate(
 		   GlobalSharedMemory::MAX_MPI_SHM_BYTES,
 		   GlobalSharedMemory::Hugepages);
  Grid_unquiesce_nodes();
 }
 ///////////////////////////////////////////////////////////////////////////
@@ -69,14 +82,14 @@ void CartesianCommunicator::ShiftedRanks(int dim,int shift,int &source,int &dest
  int ierr=MPI_Cart_shift(communicator,dim,shift,&source,&dest);
  assert(ierr==0);
 }
-int CartesianCommunicator::RankFromProcessorCoor(std::vector<int> &coor)
+int CartesianCommunicator::RankFromProcessorCoor(Coordinate &coor)
 {
  int rank;
  int ierr=MPI_Cart_rank  (communicator, &coor[0], &rank);
  assert(ierr==0);
  return rank;
 }
-void  CartesianCommunicator::ProcessorCoorFromRank(int rank, std::vector<int> &coor)
+void  CartesianCommunicator::ProcessorCoorFromRank(int rank, Coordinate &coor)
 {
  coor.resize(_ndimension);
  int ierr=MPI_Cart_coords  (communicator, rank, _ndimension,&coor[0]);
@@ -86,14 +99,14 @@ void  CartesianCommunicator::ProcessorCoorFromRank(int rank, std::vector<int> &c
 ////////////////////////////////////////////////////////////////////////////////////////////////////////
 // Initialises from communicator_world
 ////////////////////////////////////////////////////////////////////////////////////////////////////////
-CartesianCommunicator::CartesianCommunicator(const std::vector<int> &processors) 
+CartesianCommunicator::CartesianCommunicator(const Coordinate &processors)
 {
  MPI_Comm optimal_comm;
  ////////////////////////////////////////////////////
  // Remap using the shared memory optimising routine
  // The remap creates a comm which must be freed
  ////////////////////////////////////////////////////
-  GlobalSharedMemory::OptimalCommunicator    (processors,optimal_comm);
+  GlobalSharedMemory::OptimalCommunicator    (processors,optimal_comm,_shm_processors);
  InitFromMPICommunicator(processors,optimal_comm);
  SetCommunicator(optimal_comm);
  ///////////////////////////////////////////////////
@@ -105,29 +118,27 @@ CartesianCommunicator::CartesianCommunicator(const std::vector<int> &processors)
 //////////////////////////////////
 // Try to subdivide communicator
 //////////////////////////////////
-CartesianCommunicator::CartesianCommunicator(const std::vector<int> &processors,const CartesianCommunicator &parent,int &srank)    
+CartesianCommunicator::CartesianCommunicator(const Coordinate &processors,const CartesianCommunicator &parent,int &srank)
 {
-  _ndimension = processors.size();
+  _ndimension = processors.size();  assert(_ndimension>=1);
  int parent_ndimension = parent._ndimension; assert(_ndimension >= parent._ndimension);
-  std::vector<int> parent_processor_coor(_ndimension,0);
+  Coordinate parent_processor_coor(_ndimension,0);
-  std::vector<int> parent_processors    (_ndimension,1);
+  Coordinate parent_processors    (_ndimension,1);
-
+  Coordinate shm_processors       (_ndimension,1);
  // Can make 5d grid from 4d etc...
  int pad = _ndimension-parent_ndimension;
  for(int d=0;d<parent_ndimension;d++){
    parent_processor_coor[pad+d]=parent._processor_coor[d];
    parent_processors    [pad+d]=parent._processors[d];
    shm_processors       [pad+d]=parent._shm_processors[d];
  }
  //////////////////////////////////////////////////////////////////////////////////////////////////////
  // split the communicator
  //////////////////////////////////////////////////////////////////////////////////////////////////////
-  //  int Nparent = parent._processors ; 
+  //  int Nparent = parent._processors ;
  //  std::cout << " splitting from communicator "<<parent.communicator <<std::endl;
  int Nparent;
  MPI_Comm_size(parent.communicator,&Nparent);
  //  std::cout << " Parent size  "<<Nparent <<std::endl;
  int childsize=1;
  for(int d=0;d<processors.size();d++) {
@@ -136,56 +147,25 @@ CartesianCommunicator::CartesianCommunicator(const std::vector<int> &processors,
  int Nchild = Nparent/childsize;
  assert (childsize * Nchild == Nparent);
-  //  std::cout << " child size  "<<childsize <<std::endl;
+  Coordinate ccoor(_ndimension); // coor within subcommunicator
-
+  Coordinate scoor(_ndimension); // coor of split within parent
-  std::vector<int> ccoor(_ndimension); // coor within subcommunicator
+  Coordinate ssize(_ndimension); // coor of split within parent
  std::vector<int> scoor(_ndimension); // coor of split within parent
  std::vector<int> ssize(_ndimension); // coor of split within parent
  for(int d=0;d<_ndimension;d++){
    ccoor[d] = parent_processor_coor[d] % processors[d];
    scoor[d] = parent_processor_coor[d] / processors[d];
    ssize[d] = parent_processors[d]     / processors[d];
    if ( processors[d] < shm_processors[d] ) shm_processors[d] = processors[d]; // subnode splitting.
  }
  // rank within subcomm ; srank is rank of subcomm within blocks of subcomms
-  int crank;  
+  int crank;
  // Mpi uses the reverse Lexico convention to us; so reversed routines called
  Lexicographic::IndexFromCoorReversed(ccoor,crank,processors); // processors is the split grid dimensions
  Lexicographic::IndexFromCoorReversed(scoor,srank,ssize);      // ssize is the number of split grids
  MPI_Comm comm_split;
-  if ( Nchild > 1 ) { 
+  if ( Nchild > 1 ) {
    if(0){
      std::cout << GridLogMessage<<"Child communicator of "<< std::hex << parent.communicator << std::dec<<std::endl;
      std::cout << GridLogMessage<<" parent grid["<< parent._ndimension<<"]    ";
      for(int d=0;d<parent._ndimension;d++)  std::cout << parent._processors[d] << " ";
      std::cout<<std::endl;
      std::cout << GridLogMessage<<" child grid["<< _ndimension <<"]    ";
      for(int d=0;d<processors.size();d++)  std::cout << processors[d] << " ";
      std::cout<<std::endl;
      std::cout << GridLogMessage<<" old rank "<< parent._processor<<" coor ["<< parent._ndimension <<"]    ";
      for(int d=0;d<parent._ndimension;d++)  std::cout << parent._processor_coor[d] << " ";
      std::cout<<std::endl;
      std::cout << GridLogMessage<<" new split "<< srank<<" scoor ["<< _ndimension <<"]    ";
      for(int d=0;d<processors.size();d++)  std::cout << scoor[d] << " ";
      std::cout<<std::endl;
      std::cout << GridLogMessage<<" new rank "<< crank<<" coor ["<< _ndimension <<"]    ";
      for(int d=0;d<processors.size();d++)  std::cout << ccoor[d] << " ";
      std::cout<<std::endl;
      //////////////////////////////////////////////////////////////////////////////////////////////////////
      // Declare victory
      //////////////////////////////////////////////////////////////////////////////////////////////////////
      std::cout << GridLogMessage<<"Divided communicator "<< parent._Nprocessors<<" into "
 		<< Nchild <<" communicators with " << childsize << " ranks"<<std::endl;
      std::cout << " Split communicator " <<comm_split <<std::endl;
    }
    ////////////////////////////////////////////////////////////////
    // Split the communicator
@@ -208,13 +188,13 @@ CartesianCommunicator::CartesianCommunicator(const std::vector<int> &processors,
  // Take the right SHM buffers
  //////////////////////////////////////////////////////////////////////////////////////////////////////
  SetCommunicator(comm_split);
-  
+
  ///////////////////////////////////////////////
-  // Free the temp communicator 
+  // Free the temp communicator
  ///////////////////////////////////////////////
  MPI_Comm_free(&comm_split);
-  if(0){ 
+  if(0){
    std::cout << " ndim " <<_ndimension<<" " << parent._ndimension << std::endl;
    for(int d=0;d<processors.size();d++){
      std::cout << d<< " " << _processor_coor[d] <<" " <<  ccoor[d]<<std::endl;
@@ -225,7 +205,7 @@ CartesianCommunicator::CartesianCommunicator(const std::vector<int> &processors,
  }
 }
-void CartesianCommunicator::InitFromMPICommunicator(const std::vector<int> &processors, MPI_Comm communicator_base)
+void CartesianCommunicator::InitFromMPICommunicator(const Coordinate &processors, MPI_Comm communicator_base)
 {
  ////////////////////////////////////////////////////
  // Creates communicator, and the communicator_halo
@@ -242,7 +222,7 @@ void CartesianCommunicator::InitFromMPICommunicator(const std::vector<int> &proc
    _Nprocessors*=_processors[i];
  }
-  std::vector<int> periodic(_ndimension,1);
+  Coordinate periodic(_ndimension,1);
  MPI_Cart_create(communicator_base, _ndimension,&_processors[0],&periodic[0],0,&communicator);
  MPI_Comm_rank(communicator,&_processor);
  MPI_Cart_coords(communicator,_processor,_ndimension,&_processor_coor[0]);
@@ -275,7 +255,7 @@ CartesianCommunicator::~CartesianCommunicator()
    for(int i=0;i<communicator_halo.size();i++){
      MPI_Comm_free(&communicator_halo[i]);
    }
-  }  
+  }
 }
 void CartesianCommunicator::GlobalSum(uint32_t &u){
  int ierr=MPI_Allreduce(MPI_IN_PLACE,&u,1,MPI_UINT32_T,MPI_SUM,communicator);
@@ -285,6 +265,10 @@ void CartesianCommunicator::GlobalSum(uint64_t &u){
  int ierr=MPI_Allreduce(MPI_IN_PLACE,&u,1,MPI_UINT64_T,MPI_SUM,communicator);
  assert(ierr==0);
 }
 void CartesianCommunicator::GlobalSumVector(uint64_t* u,int N){
  int ierr=MPI_Allreduce(MPI_IN_PLACE,u,N,MPI_UINT64_T,MPI_SUM,communicator);
  assert(ierr==0);
 }
 void CartesianCommunicator::GlobalXOR(uint32_t &u){
  int ierr=MPI_Allreduce(MPI_IN_PLACE,&u,1,MPI_UINT32_T,MPI_BXOR,communicator);
  assert(ierr==0);
@@ -293,6 +277,16 @@ void CartesianCommunicator::GlobalXOR(uint64_t &u){
  int ierr=MPI_Allreduce(MPI_IN_PLACE,&u,1,MPI_UINT64_T,MPI_BXOR,communicator);
  assert(ierr==0);
 }
 void CartesianCommunicator::GlobalMax(float &f)
 {
  int ierr=MPI_Allreduce(MPI_IN_PLACE,&f,1,MPI_FLOAT,MPI_MAX,communicator);
  assert(ierr==0);
 }
 void CartesianCommunicator::GlobalMax(double &d)
 {
  int ierr = MPI_Allreduce(MPI_IN_PLACE,&d,1,MPI_DOUBLE,MPI_MAX,communicator);
  assert(ierr==0);
 }
 void CartesianCommunicator::GlobalSum(float &f){
  int ierr=MPI_Allreduce(MPI_IN_PLACE,&f,1,MPI_FLOAT,MPI_SUM,communicator);
  assert(ierr==0);
@@ -320,80 +314,48 @@ void CartesianCommunicator::SendToRecvFrom(void *xmit,
 					   int bytes)
 {
  std::vector<CommsRequest_t> reqs(0);
-  //    unsigned long  xcrc = crc32(0L, Z_NULL, 0);
+  unsigned long  xcrc = crc32(0L, Z_NULL, 0);
-  //    unsigned long  rcrc = crc32(0L, Z_NULL, 0);
+  unsigned long  rcrc = crc32(0L, Z_NULL, 0);
-  //    xcrc = crc32(xcrc,(unsigned char *)xmit,bytes);
+
  SendToRecvFromBegin(reqs,xmit,dest,recv,from,bytes);
  SendToRecvFromComplete(reqs);
  //    rcrc = crc32(rcrc,(unsigned char *)recv,bytes);
  //    printf("proc %d SendToRecvFrom %d bytes %lx %lx\n",_processor,bytes,xcrc,rcrc);
 }
 void CartesianCommunicator::SendRecvPacket(void *xmit,
 					   void *recv,
 					   int sender,
 					   int receiver,
 					   int bytes)
 {
  MPI_Status stat;
  assert(sender != receiver);
  int tag = sender;
  if ( _processor == sender ) {
    MPI_Send(xmit, bytes, MPI_CHAR,receiver,tag,communicator);
  }
  if ( _processor == receiver ) { 
    MPI_Recv(recv, bytes, MPI_CHAR,sender,tag,communicator,&stat);
  }
 }
 // Basic Halo comms primitive
 void CartesianCommunicator::SendToRecvFromBegin(std::vector<CommsRequest_t> &list,
 						void *xmit,
 						int dest,
 						void *recv,
 						int from,
 						int bytes)
 {
  int myrank = _processor;
  int ierr;
-  if ( CommunicatorPolicy == CommunicatorPolicyConcurrent ) { 
+  // Enforce no UVM in comms, device or host OK
-    MPI_Request xrq;
+  assert(acceleratorIsCommunicable(xmit));
-    MPI_Request rrq;
+  assert(acceleratorIsCommunicable(recv));
-    ierr =MPI_Irecv(recv, bytes, MPI_CHAR,from,from,communicator,&rrq);
+  // Give the CPU to MPI immediately; can use threads to overlap optionally
-    ierr|=MPI_Isend(xmit, bytes, MPI_CHAR,dest,_processor,communicator,&xrq);
+  //  printf("proc %d SendToRecvFrom %d bytes Sendrecv \n",_processor,bytes);
-    
+  ierr=MPI_Sendrecv(xmit,bytes,MPI_CHAR,dest,myrank,
-    assert(ierr==0);
+		    recv,bytes,MPI_CHAR,from, from,
-    list.push_back(xrq);
+		    communicator,MPI_STATUS_IGNORE);
-    list.push_back(rrq);
+  assert(ierr==0);
-  } else { 
+
-    // Give the CPU to MPI immediately; can use threads to overlap optionally
+  //  xcrc = crc32(xcrc,(unsigned char *)xmit,bytes);
-    ierr=MPI_Sendrecv(xmit,bytes,MPI_CHAR,dest,myrank,
+  //  rcrc = crc32(rcrc,(unsigned char *)recv,bytes);
-		      recv,bytes,MPI_CHAR,from, from,
+  //  printf("proc %d SendToRecvFrom %d bytes xcrc %lx rcrc %lx\n",_processor,bytes,xcrc,rcrc); fflush
 		      communicator,MPI_STATUS_IGNORE);
    assert(ierr==0);
  }
 }
-
+// Basic Halo comms primitive
 double CartesianCommunicator::StencilSendToRecvFrom( void *xmit,
-						     int dest,
+						     int dest, int dox,
 						     void *recv,
-						     int from,
+						     int from, int dor,
 						     int bytes,int dir)
 {
  std::vector<CommsRequest_t> list;
-  double offbytes = StencilSendToRecvFromBegin(list,xmit,dest,recv,from,bytes,dir);
+  double offbytes = StencilSendToRecvFromBegin(list,xmit,dest,dox,recv,from,dor,bytes,bytes,dir);
  StencilSendToRecvFromComplete(list,dir);
  return offbytes;
 }
 double CartesianCommunicator::StencilSendToRecvFromBegin(std::vector<CommsRequest_t> &list,
 							 void *xmit,
-							 int dest,
+							 int dest,int dox,
 							 void *recv,
-							 int from,
+							 int from,int dor,
-							 int bytes,int dir)
+							 int xbytes,int rbytes,int dir)
 {
-  int ncomm  =communicator_halo.size(); 
+  int ncomm  =communicator_halo.size();
  int commdir=dir%ncomm;
  MPI_Request xrq;
@@ -408,36 +370,35 @@ double CartesianCommunicator::StencilSendToRecvFromBegin(std::vector<CommsReques
  assert(from != _processor);
  assert(gme  == ShmRank);
  double off_node_bytes=0.0;
  int tag;
-  if ( gfrom ==MPI_UNDEFINED) {
+  if ( dor ) {
-    ierr=MPI_Irecv(recv, bytes, MPI_CHAR,from,from,communicator_halo[commdir],&rrq);
+    if ( (gfrom ==MPI_UNDEFINED) || Stencil_force_mpi ) {
-    assert(ierr==0);
+      tag= dir+from*32;
-    list.push_back(rrq);
+      ierr=MPI_Irecv(recv, rbytes, MPI_CHAR,from,tag,communicator_halo[commdir],&rrq);
-    off_node_bytes+=bytes;
+      assert(ierr==0);
      list.push_back(rrq);
      off_node_bytes+=rbytes;
    }
  }
-
+  
-  if ( gdest == MPI_UNDEFINED ) {
+  if (dox) {
-    ierr =MPI_Isend(xmit, bytes, MPI_CHAR,dest,_processor,communicator_halo[commdir],&xrq);
+    if ( (gdest == MPI_UNDEFINED) || Stencil_force_mpi ) {
-    assert(ierr==0);
+      tag= dir+_processor*32;
-    list.push_back(xrq);
+      ierr =MPI_Isend(xmit, xbytes, MPI_CHAR,dest,tag,communicator_halo[commdir],&xrq);
-    off_node_bytes+=bytes;
+      assert(ierr==0);
-  }
+      list.push_back(xrq);
-
+      off_node_bytes+=xbytes;
-  if ( CommunicatorPolicy == CommunicatorPolicySequential ) { 
+    } else {
-    this->StencilSendToRecvFromComplete(list,dir);
+      void *shm = (void *) this->ShmBufferTranslate(dest,recv);
      assert(shm!=NULL);
      acceleratorCopyDeviceToDeviceAsynch(xmit,shm,xbytes);
    }
  }
  return off_node_bytes;
 }
-void CartesianCommunicator::StencilSendToRecvFromComplete(std::vector<CommsRequest_t> &waitall,int dir)
+void CartesianCommunicator::StencilSendToRecvFromComplete(std::vector<CommsRequest_t> &list,int dir)
 {
  SendToRecvFromComplete(waitall);
 }
 void CartesianCommunicator::StencilBarrier(void)
 {
  MPI_Barrier  (ShmComm);
 }
 void CartesianCommunicator::SendToRecvFromComplete(std::vector<CommsRequest_t> &list)
 {
  int nreq=list.size();
@@ -448,6 +409,13 @@ void CartesianCommunicator::SendToRecvFromComplete(std::vector<CommsRequest_t> &
  assert(ierr==0);
  list.resize(0);
 }
 void CartesianCommunicator::StencilBarrier(void)
 {
  MPI_Barrier  (ShmComm);
 }
 //void CartesianCommunicator::SendToRecvFromComplete(std::vector<CommsRequest_t> &list)
 //{
 //}
 void CartesianCommunicator::Barrier(void)
 {
  int ierr = MPI_Barrier(communicator);
@@ -462,11 +430,15 @@ void CartesianCommunicator::Broadcast(int root,void* data, int bytes)
 		     communicator);
  assert(ierr==0);
 }
-int CartesianCommunicator::RankWorld(void){ 
+int CartesianCommunicator::RankWorld(void){
-  int r; 
+  int r;
  MPI_Comm_rank(communicator_world,&r);
  return r;
 }
 void CartesianCommunicator::BarrierWorld(void){
  int ierr = MPI_Barrier(communicator_world);
  assert(ierr==0);
 }
 void CartesianCommunicator::BroadcastWorld(int root,void* data, int bytes)
 {
  int ierr= MPI_Bcast(data,
@@ -479,7 +451,7 @@ void CartesianCommunicator::BroadcastWorld(int root,void* data, int bytes)
 void CartesianCommunicator::AllToAll(int dim,void  *in,void *out,uint64_t words,uint64_t bytes)
 {
-  std::vector<int> row(_ndimension,1);
+  Coordinate row(_ndimension,1);
  assert(dim>=0 && dim<_ndimension);
  //  Split the communicator
@@ -496,7 +468,7 @@ void CartesianCommunicator::AllToAll(void  *in,void *out,uint64_t words,uint64_t
  // When 24*4 bytes multiples get 50x 10^9 >>> 2x10^9 Y2K bug.
  // (Turns up on 32^3 x 64 Gparity too)
  MPI_Datatype object;
-  int iwords; 
+  int iwords;
  int ibytes;
  iwords = words;
  ibytes = bytes;
@@ -508,7 +480,4 @@ void CartesianCommunicator::AllToAll(void  *in,void *out,uint64_t words,uint64_t
  MPI_Type_free(&object);
 }
-
+NAMESPACE_END(Grid);
 }
--- a/Grid/communicator/Communicator_none.cc
+++ b/Grid/communicator/Communicator_none.cc
@@ -1,4 +1,4 @@
-    /*************************************************************************************
+/*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
@@ -23,11 +23,11 @@ Author: Peter Boyle <paboyle@ph.ed.ac.uk>
    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 */
+/*  END LEGAL */
 #include <Grid/GridCore.h>
-namespace Grid {
+NAMESPACE_BEGIN(Grid);
 ///////////////////////////////////////////////////////////////////////////////////////////////////
 // Info that is setup once and indept of cartesian layout
@@ -38,21 +38,23 @@ void CartesianCommunicator::Init(int *argc, char *** arv)
 {
  GlobalSharedMemory::Init(communicator_world);
  GlobalSharedMemory::SharedMemoryAllocate(
-		   GlobalSharedMemory::MAX_MPI_SHM_BYTES,
+					   GlobalSharedMemory::MAX_MPI_SHM_BYTES,
-		   GlobalSharedMemory::Hugepages);
+					   GlobalSharedMemory::Hugepages);
 }
-CartesianCommunicator::CartesianCommunicator(const std::vector<int> &processors,const CartesianCommunicator &parent,int &srank) 
+CartesianCommunicator::CartesianCommunicator(const Coordinate &processors,const CartesianCommunicator &parent,int &srank) 
  : CartesianCommunicator(processors) 
 {
  _shm_processors = Coordinate(processors.size(),1);
  srank=0;
  SetCommunicator(communicator_world);
 }
-CartesianCommunicator::CartesianCommunicator(const std::vector<int> &processors)
+CartesianCommunicator::CartesianCommunicator(const Coordinate &processors)
 {
  _shm_processors = Coordinate(processors.size(),1);
  _processors = processors;
-  _ndimension = processors.size();
+  _ndimension = processors.size();  assert(_ndimension>=1);
  _processor_coor.resize(_ndimension);
  // Require 1^N processor grid for fake
@@ -67,24 +69,18 @@ CartesianCommunicator::CartesianCommunicator(const std::vector<int> &processors)
 CartesianCommunicator::~CartesianCommunicator(){}
 void CartesianCommunicator::GlobalMax(float &){}
 void CartesianCommunicator::GlobalMax(double &){}
 void CartesianCommunicator::GlobalSum(float &){}
 void CartesianCommunicator::GlobalSumVector(float *,int N){}
 void CartesianCommunicator::GlobalSum(double &){}
 void CartesianCommunicator::GlobalSumVector(double *,int N){}
 void CartesianCommunicator::GlobalSum(uint32_t &){}
 void CartesianCommunicator::GlobalSum(uint64_t &){}
-void CartesianCommunicator::GlobalSumVector(double *,int N){}
+void CartesianCommunicator::GlobalSumVector(uint64_t *,int N){}
 void CartesianCommunicator::GlobalXOR(uint32_t &){}
 void CartesianCommunicator::GlobalXOR(uint64_t &){}
 void CartesianCommunicator::SendRecvPacket(void *xmit,
 					   void *recv,
 					   int xmit_to_rank,
 					   int recv_from_rank,
 					   int bytes)
 {
  assert(0);
 }
 // Basic Halo comms primitive -- should never call in single node
 void CartesianCommunicator::SendToRecvFrom(void *xmit,
@@ -95,20 +91,6 @@ void CartesianCommunicator::SendToRecvFrom(void *xmit,
 {
  assert(0);
 }
 void CartesianCommunicator::SendToRecvFromBegin(std::vector<CommsRequest_t> &list,
 						void *xmit,
 						int dest,
 						void *recv,
 						int from,
 						int bytes)
 {
  assert(0);
 }
 void CartesianCommunicator::SendToRecvFromComplete(std::vector<CommsRequest_t> &list)
 {
  assert(0);
 }
 void CartesianCommunicator::AllToAll(int dim,void  *in,void *out,uint64_t words,uint64_t bytes)
 {
  bcopy(in,out,bytes*words);
@@ -122,8 +104,9 @@ int  CartesianCommunicator::RankWorld(void){return 0;}
 void CartesianCommunicator::Barrier(void){}
 void CartesianCommunicator::Broadcast(int root,void* data, int bytes) {}
 void CartesianCommunicator::BroadcastWorld(int root,void* data, int bytes) { }
-int  CartesianCommunicator::RankFromProcessorCoor(std::vector<int> &coor) {  return 0;}
+void CartesianCommunicator::BarrierWorld(void) { }
-void CartesianCommunicator::ProcessorCoorFromRank(int rank, std::vector<int> &coor){  coor = _processor_coor; }
+int  CartesianCommunicator::RankFromProcessorCoor(Coordinate &coor) {  return 0;}
 void CartesianCommunicator::ProcessorCoorFromRank(int rank, Coordinate &coor){  coor = _processor_coor; }
 void CartesianCommunicator::ShiftedRanks(int dim,int shift,int &source,int &dest)
 {
  source =0;
@@ -131,35 +114,28 @@ void CartesianCommunicator::ShiftedRanks(int dim,int shift,int &source,int &dest
 }
 double CartesianCommunicator::StencilSendToRecvFrom( void *xmit,
-						     int xmit_to_rank,
+						     int xmit_to_rank,int dox,
 						     void *recv,
-						     int recv_from_rank,
+						     int recv_from_rank,int dor,
 						     int bytes, int dir)
 {
  std::vector<CommsRequest_t> list;
  // Discard the "dir"
  SendToRecvFromBegin   (list,xmit,xmit_to_rank,recv,recv_from_rank,bytes);
  SendToRecvFromComplete(list);
  return 2.0*bytes;
 }
 double CartesianCommunicator::StencilSendToRecvFromBegin(std::vector<CommsRequest_t> &list,
 							 void *xmit,
-							 int xmit_to_rank,
+							 int xmit_to_rank,int dox,
 							 void *recv,
-							 int recv_from_rank,
+							 int recv_from_rank,int dor,
-							 int bytes, int dir)
+							 int xbytes,int rbytes, int dir)
 {
-  // Discard the "dir"
+  return xbytes+rbytes;
  SendToRecvFromBegin(list,xmit,xmit_to_rank,recv,recv_from_rank,bytes);
  return 2.0*bytes;
 }
 void CartesianCommunicator::StencilSendToRecvFromComplete(std::vector<CommsRequest_t> &waitall,int dir)
 {
  SendToRecvFromComplete(waitall);
 }
 void CartesianCommunicator::StencilBarrier(void){};
 NAMESPACE_END(Grid);
 }
--- a/Grid/communicator/SharedMemory.cc
+++ b/Grid/communicator/SharedMemory.cc
@@ -28,10 +28,11 @@ Author: Peter Boyle <paboyle@ph.ed.ac.uk>
 #include <Grid/GridCore.h>
-namespace Grid { 
+NAMESPACE_BEGIN(Grid); 
 // static data
 int                 GlobalSharedMemory::HPEhypercube = 1;
 uint64_t            GlobalSharedMemory::MAX_MPI_SHM_BYTES   = 1024LL*1024LL*1024LL; 
 int                 GlobalSharedMemory::Hugepages = 0;
 int                 GlobalSharedMemory::_ShmSetup;
@@ -73,9 +74,12 @@ void *SharedMemory::ShmBufferMalloc(size_t bytes){
  if (heap_bytes >= heap_size) {
    std::cout<< " ShmBufferMalloc exceeded shared heap size -- try increasing with --shm <MB> flag" <<std::endl;
    std::cout<< " Parameter specified in units of MB (megabytes) " <<std::endl;
-    std::cout<< " Current value is " << (heap_size/(1024*1024)) <<std::endl;
+    std::cout<< " Current alloc is " << (bytes/(1024*1024)) <<"MB"<<std::endl;
    std::cout<< " Current bytes is " << (heap_bytes/(1024*1024)) <<"MB"<<std::endl;
    std::cout<< " Current heap  is " << (heap_size/(1024*1024)) <<"MB"<<std::endl;
    assert(heap_bytes<heap_size);
  }
  //std::cerr << "ShmBufferMalloc "<<std::hex<< ptr<<" - "<<((uint64_t)ptr+bytes)<<std::dec<<std::endl;
  return ptr;
 }
 void SharedMemory::ShmBufferFreeAll(void) { 
@@ -84,9 +88,62 @@ void SharedMemory::ShmBufferFreeAll(void) {
 }
 void *SharedMemory::ShmBufferSelf(void)
 {
  //std::cerr << "ShmBufferSelf "<<ShmRank<<" "<<std::hex<< ShmCommBufs[ShmRank] <<std::dec<<std::endl;
  return ShmCommBufs[ShmRank];
 }
-
+static inline int divides(int a,int b)
-
+{
-
+  return ( b == ( (b/a)*a ) );
 }
 void GlobalSharedMemory::GetShmDims(const Coordinate &WorldDims,Coordinate &ShmDims)
 {
  ////////////////////////////////////////////////////////////////
  // Allow user to configure through environment variable
  ////////////////////////////////////////////////////////////////
  char* str = getenv(("GRID_SHM_DIMS_" + std::to_string(ShmDims.size())).c_str());
  if ( str ) {
    std::vector<int> IntShmDims;
    GridCmdOptionIntVector(std::string(str),IntShmDims);
    assert(IntShmDims.size() == WorldDims.size());
    long ShmSize = 1;
    for (int dim=0;dim<WorldDims.size();dim++) {
      ShmSize *= (ShmDims[dim] = IntShmDims[dim]);
      assert(divides(ShmDims[dim],WorldDims[dim]));
    }
    assert(ShmSize == WorldShmSize);
    return;
  }
  ////////////////////////////////////////////////////////////////
  // Powers of 2,3,5 only in prime decomposition for now
  ////////////////////////////////////////////////////////////////
  int ndimension = WorldDims.size();
  ShmDims=Coordinate(ndimension,1);
  std::vector<int> primes({2,3,5});
  int dim = 0;
  int last_dim = ndimension - 1;
  int AutoShmSize = 1;
  while(AutoShmSize != WorldShmSize) {
    int p;
    for(p=0;p<primes.size();p++) {
      int prime=primes[p];
      if ( divides(prime,WorldDims[dim]/ShmDims[dim])
        && divides(prime,WorldShmSize/AutoShmSize)  ) {
  AutoShmSize*=prime;
  ShmDims[dim]*=prime;
  last_dim = dim;
  break;
      }
    }
    if (p == primes.size() && last_dim == dim) {
      std::cerr << "GlobalSharedMemory::GetShmDims failed" << std::endl;
      exit(EXIT_FAILURE);
    }
    dim=(dim+1) %ndimension;
  }
 }
 NAMESPACE_END(Grid); 
--- a/Grid/communicator/SharedMemory.h
+++ b/Grid/communicator/SharedMemory.h
@@ -25,18 +25,6 @@ Author: Peter Boyle <paboyle@ph.ed.ac.uk>
    See the full license in the file "LICENSE" in the top level distribution directory
 *************************************************************************************/
 /*  END LEGAL */
 // TODO
 // 1) move includes into SharedMemory.cc
 //
 // 2) split shared memory into a) optimal communicator creation from comm world
 // 
 //                             b) shared memory buffers container
 //                                -- static globally shared; init once
 //                                -- per instance set of buffers.
 //                                   
 #pragma once 
 #include <Grid/GridCore.h>
@@ -53,30 +41,33 @@ Author: Peter Boyle <paboyle@ph.ed.ac.uk>
 #include <sys/shm.h>
 #include <sys/mman.h>
 #include <zlib.h>
 #ifdef HAVE_NUMAIF_H
 #include <numaif.h>
 #endif
-namespace Grid {
+NAMESPACE_BEGIN(Grid);
 #if defined (GRID_COMMS_MPI3) 
-  typedef MPI_Comm    Grid_MPI_Comm;
+typedef MPI_Comm    Grid_MPI_Comm;
-  typedef MPI_Request CommsRequest_t;
+typedef MPI_Request CommsRequest_t;
 #else 
-  typedef int CommsRequest_t;
+typedef int CommsRequest_t;
-  typedef int Grid_MPI_Comm;
+typedef int Grid_MPI_Comm;
 #endif
 class GlobalSharedMemory {
- private:
+private:
  static const int     MAXLOG2RANKSPERNODE = 16;            
  // Init once lock on the buffer allocation
  static int      _ShmSetup;
  static int      _ShmAlloc;
  static uint64_t _ShmAllocBytes;
- public:
+public:
  ///////////////////////////////////////
  // HPE 8600 hypercube optimisation
  ///////////////////////////////////////
  static int HPEhypercube;
  static int      ShmSetup(void)      { return _ShmSetup; }
  static int      ShmAlloc(void)      { return _ShmAlloc; }
  static uint64_t ShmAllocBytes(void) { return _ShmAllocBytes; }
@@ -102,12 +93,18 @@ class GlobalSharedMemory {
  // Create an optimal reordered communicator that makes MPI_Cart_create get it right
  //////////////////////////////////////////////////////////////////////////////////////
  static void Init(Grid_MPI_Comm comm); // Typically MPI_COMM_WORLD
-  static void OptimalCommunicator(const std::vector<int> &processors,Grid_MPI_Comm & optimal_comm);  // Turns MPI_COMM_WORLD into right layout for Cartesian
+  // Turns MPI_COMM_WORLD into right layout for Cartesian
  static void OptimalCommunicator            (const Coordinate &processors,Grid_MPI_Comm & optimal_comm,Coordinate &ShmDims); 
  static void OptimalCommunicatorHypercube   (const Coordinate &processors,Grid_MPI_Comm & optimal_comm,Coordinate &ShmDims); 
  static void OptimalCommunicatorSharedMemory(const Coordinate &processors,Grid_MPI_Comm & optimal_comm,Coordinate &ShmDims); 
  static void GetShmDims(const Coordinate &WorldDims,Coordinate &ShmDims);
  ///////////////////////////////////////////////////
  // Provide shared memory facilities off comm world
  ///////////////////////////////////////////////////
  static void SharedMemoryAllocate(uint64_t bytes, int flags);
  static void SharedMemoryFree(void);
  static void SharedMemoryCopy(void *dest,void *src,size_t bytes);
  static void SharedMemoryZero(void *dest,size_t bytes);
 };
@@ -116,14 +113,14 @@ class GlobalSharedMemory {
 //////////////////////////////
 class SharedMemory 
 {
- private:
+private:
  static const int     MAXLOG2RANKSPERNODE = 16;            
  size_t heap_top;
  size_t heap_bytes;
  size_t heap_size;
- protected:
+protected:
  Grid_MPI_Comm    ShmComm; // for barriers
  int    ShmRank; 
@@ -131,7 +128,7 @@ class SharedMemory
  std::vector<void *> ShmCommBufs;
  std::vector<int>    ShmRanks;// Mapping comm ranks to Shm ranks
- public:
+public:
  SharedMemory() {};
  ~SharedMemory();
  ///////////////////////////////////////////////////////////////////////////////////////
@@ -148,6 +145,7 @@ class SharedMemory
  // Call on any instance
  ///////////////////////////////////////////////////
  void SharedMemoryTest(void);
  void *ShmBufferSelf(void);
  void *ShmBuffer    (int rank);
  void *ShmBufferTranslate(int rank,void * local_p);
@@ -162,4 +160,5 @@ class SharedMemory
 };
-}
+NAMESPACE_END(Grid);
--- a/Grid/communicator/SharedMemoryMPI.cc
+++ b/Grid/communicator/SharedMemoryMPI.cc
@@ -7,6 +7,7 @@
    Copyright (C) 2015
 Author: Peter Boyle <paboyle@ph.ed.ac.uk>
 Author: Christoph Lehner <christoph@lhnr.de>
    This program is free software; you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
@@ -26,10 +27,130 @@ Author: Peter Boyle <paboyle@ph.ed.ac.uk>
 *************************************************************************************/
 /*  END LEGAL */
 #define Mheader "SharedMemoryMpi: "
 #include <Grid/GridCore.h>
 #include <pwd.h>
-namespace Grid { 
+#ifdef GRID_CUDA
 #include <cuda_runtime_api.h>
 #endif
 #ifdef GRID_HIP
 #include <hip/hip_runtime_api.h>
 #endif
 #ifdef GRID_SYCL
 #define GRID_SYCL_LEVEL_ZERO_IPC
 #include <syscall.h>
 #define SHM_SOCKETS 
 #endif
 #include <sys/socket.h>
 #include <sys/un.h>
 NAMESPACE_BEGIN(Grid); 
 #ifdef SHM_SOCKETS
 /*
 * Barbaric extra intranode communication route in case we need sockets to pass FDs
 * Forced by level_zero not being nicely designed
 */
 static int sock;
 static const char *sock_path_fmt = "/tmp/GridUnixSocket.%d";
 static char sock_path[256];
 class UnixSockets {
 public:
  static void Open(int rank)
  {
    int errnum;
    sock = socket(AF_UNIX, SOCK_DGRAM, 0);  assert(sock>0);
    struct sockaddr_un sa_un = { 0 };
    sa_un.sun_family = AF_UNIX;
    snprintf(sa_un.sun_path, sizeof(sa_un.sun_path),sock_path_fmt,rank);
    unlink(sa_un.sun_path);
    if (bind(sock, (struct sockaddr *)&sa_un, sizeof(sa_un))) {
      perror("bind failure");
      exit(EXIT_FAILURE);
    }
  }
  static int RecvFileDescriptor(void)
  {
    int n;
    int fd;
    char buf[1];
    struct iovec iov;
    struct msghdr msg;
    struct cmsghdr *cmsg;
    char cms[CMSG_SPACE(sizeof(int))];
    iov.iov_base = buf;
    iov.iov_len = 1;
    memset(&msg, 0, sizeof msg);
    msg.msg_name = 0;
    msg.msg_namelen = 0;
    msg.msg_iov = &iov;
    msg.msg_iovlen = 1;
    msg.msg_control = (caddr_t)cms;
    msg.msg_controllen = sizeof cms;
    if((n=recvmsg(sock, &msg, 0)) < 0) {
      perror("recvmsg failed");
      return -1;
    }
    if(n == 0){
      perror("recvmsg returned 0");
      return -1;
    }
    cmsg = CMSG_FIRSTHDR(&msg);
    memmove(&fd, CMSG_DATA(cmsg), sizeof(int));
    return fd;
  }
  static void SendFileDescriptor(int fildes,int xmit_to_rank)
  {
    struct msghdr msg;
    struct iovec iov;
    struct cmsghdr *cmsg = NULL;
    char ctrl[CMSG_SPACE(sizeof(int))];
    char data = ' ';
    memset(&msg, 0, sizeof(struct msghdr));
    memset(ctrl, 0, CMSG_SPACE(sizeof(int)));
    iov.iov_base = &data;
    iov.iov_len = sizeof(data);
    sprintf(sock_path,sock_path_fmt,xmit_to_rank);
    struct sockaddr_un sa_un = { 0 };
    sa_un.sun_family = AF_UNIX;
    snprintf(sa_un.sun_path, sizeof(sa_un.sun_path),sock_path_fmt,xmit_to_rank);
    msg.msg_name = (void *)&sa_un;
    msg.msg_namelen = sizeof(sa_un);
    msg.msg_iov = &iov;
    msg.msg_iovlen = 1;
    msg.msg_controllen =  CMSG_SPACE(sizeof(int));
    msg.msg_control = ctrl;
    cmsg = CMSG_FIRSTHDR(&msg);
    cmsg->cmsg_level = SOL_SOCKET;
    cmsg->cmsg_type = SCM_RIGHTS;
    cmsg->cmsg_len = CMSG_LEN(sizeof(int));
    *((int *) CMSG_DATA(cmsg)) = fildes;
    sendmsg(sock, &msg, 0);
  };
 };
 #endif
 /*Construct from an MPI communicator*/
 void GlobalSharedMemory::Init(Grid_MPI_Comm comm)
@@ -43,15 +164,26 @@ void GlobalSharedMemory::Init(Grid_MPI_Comm comm)
  /////////////////////////////////////////////////////////////////////
  // Split into groups that can share memory
  /////////////////////////////////////////////////////////////////////
 #ifndef GRID_MPI3_SHM_NONE
  MPI_Comm_split_type(comm, MPI_COMM_TYPE_SHARED, 0, MPI_INFO_NULL,&WorldShmComm);
 #else
  MPI_Comm_split(comm, WorldRank, 0, &WorldShmComm);
 #endif
  MPI_Comm_rank(WorldShmComm     ,&WorldShmRank);
  MPI_Comm_size(WorldShmComm     ,&WorldShmSize);
  if ( WorldRank == 0) {
    std::cout << Mheader " World communicator of size " <<WorldSize << std::endl;  
    std::cout << Mheader " Node  communicator of size " <<WorldShmSize << std::endl;
  }
  // WorldShmComm, WorldShmSize, WorldShmRank
  // WorldNodes
  WorldNodes = WorldSize/WorldShmSize;
  assert( (WorldNodes * WorldShmSize) == WorldSize );
  // FIXME: Check all WorldShmSize are the same ?
  /////////////////////////////////////////////////////////////////////
@@ -130,10 +262,25 @@ int Log2Size(int TwoToPower,int MAXLOG2)
  }
  return log2size;
 }
-void GlobalSharedMemory::OptimalCommunicator(const std::vector<int> &processors,Grid_MPI_Comm & optimal_comm)
+void GlobalSharedMemory::OptimalCommunicator(const Coordinate &processors,Grid_MPI_Comm & optimal_comm,Coordinate &SHM)
 {
  //////////////////////////////////////////////////////////////////////////////
  // Look and see if it looks like an HPE 8600 based on hostname conventions
  //////////////////////////////////////////////////////////////////////////////
  const int namelen = _POSIX_HOST_NAME_MAX;
  char name[namelen];
  int R;
  int I;
  int N;
  gethostname(name,namelen);
  int nscan = sscanf(name,"r%di%dn%d",&R,&I,&N) ;
  if(nscan==3 && HPEhypercube ) OptimalCommunicatorHypercube(processors,optimal_comm,SHM);
  else                          OptimalCommunicatorSharedMemory(processors,optimal_comm,SHM);
 }
 void GlobalSharedMemory::OptimalCommunicatorHypercube(const Coordinate &processors,Grid_MPI_Comm & optimal_comm,Coordinate &SHM)
 {
 #undef HYPERCUBE 
 #ifdef HYPERCUBE
  ////////////////////////////////////////////////////////////////
  // Assert power of two shm_size.
  ////////////////////////////////////////////////////////////////
@@ -174,9 +321,9 @@ void GlobalSharedMemory::OptimalCommunicator(const std::vector<int> &processors,
  }
  std::string hname(name);
-  std::cout << "hostname "<<hname<<std::endl;
+  //  std::cout << "hostname "<<hname<<std::endl;
-  std::cout << "R " << R << " I " << I << " N "<< N<<
+  //  std::cout << "R " << R << " I " << I << " N "<< N
-            << " hypercoor 0x"<<std::hex<<hypercoor<<std::dec<<std::endl;
+  //            << " hypercoor 0x"<<std::hex<<hypercoor<<std::dec<<std::endl;
  //////////////////////////////////////////////////////////////////
  // broadcast node 0's base coordinate for this partition.
@@ -198,17 +345,15 @@ void GlobalSharedMemory::OptimalCommunicator(const std::vector<int> &processors,
  // in a maximally symmetrical way
  ////////////////////////////////////////////////////////////////
  int ndimension              = processors.size();
-  std::vector<int> processor_coor(ndimension);
+  Coordinate processor_coor(ndimension);
-  std::vector<int> WorldDims = processors;   std::vector<int> ShmDims  (ndimension,1);  std::vector<int> NodeDims (ndimension);
+  Coordinate WorldDims = processors;
-  std::vector<int> ShmCoor  (ndimension);    std::vector<int> NodeCoor (ndimension);    std::vector<int> WorldCoor(ndimension);
+  Coordinate ShmDims  (ndimension);  Coordinate NodeDims (ndimension);
-  std::vector<int> HyperCoor(ndimension);
+  Coordinate ShmCoor  (ndimension);    Coordinate NodeCoor (ndimension);    Coordinate WorldCoor(ndimension);
-  int dim = 0;
+  Coordinate HyperCoor(ndimension);
  for(int l2=0;l2<log2size;l2++){
    while ( (WorldDims[dim] / ShmDims[dim]) <= 1 ) dim=(dim+1)%ndimension;
    ShmDims[dim]*=2;
    dim=(dim+1)%ndimension;
  }
  GetShmDims(WorldDims,ShmDims);
  SHM = ShmDims;
  ////////////////////////////////////////////////////////////////
  // Establish torus of processes and nodes with sub-blockings
  ////////////////////////////////////////////////////////////////
@@ -226,7 +371,7 @@ void GlobalSharedMemory::OptimalCommunicator(const std::vector<int> &processors,
     HyperCoor[d]=hcoor & msk;  
     HyperCoor[d]=BinaryToGray(HyperCoor[d]); // Space filling curve magic
     hcoor = hcoor >> bits;
-  } 
+  }
  ////////////////////////////////////////////////////////////////
  // Check processor counts match
  ////////////////////////////////////////////////////////////////
@@ -254,27 +399,20 @@ void GlobalSharedMemory::OptimalCommunicator(const std::vector<int> &processors,
  /////////////////////////////////////////////////////////////////
  int ierr= MPI_Comm_split(WorldComm,0,rank,&optimal_comm);
  assert(ierr==0);
-#else 
+}
-  ////////////////////////////////////////////////////////////////
+void GlobalSharedMemory::OptimalCommunicatorSharedMemory(const Coordinate &processors,Grid_MPI_Comm & optimal_comm,Coordinate &SHM)
-  // Assert power of two shm_size.
+{
  ////////////////////////////////////////////////////////////////
  int log2size = Log2Size(WorldShmSize,MAXLOG2RANKSPERNODE);
  assert(log2size != -1);
  ////////////////////////////////////////////////////////////////
  // Identify subblock of ranks on node spreading across dims
  // in a maximally symmetrical way
  ////////////////////////////////////////////////////////////////
  int ndimension              = processors.size();
-  std::vector<int> processor_coor(ndimension);
+  Coordinate processor_coor(ndimension);
-  std::vector<int> WorldDims = processors;   std::vector<int> ShmDims  (ndimension,1);  std::vector<int> NodeDims (ndimension);
+  Coordinate WorldDims = processors; Coordinate ShmDims(ndimension);  Coordinate NodeDims (ndimension);
-  std::vector<int> ShmCoor  (ndimension);    std::vector<int> NodeCoor (ndimension);    std::vector<int> WorldCoor(ndimension);
+  Coordinate ShmCoor(ndimension);    Coordinate NodeCoor(ndimension);   Coordinate WorldCoor(ndimension);
-  int dim = 0;
+
-  for(int l2=0;l2<log2size;l2++){
+  GetShmDims(WorldDims,ShmDims);
-    while ( (WorldDims[dim] / ShmDims[dim]) <= 1 ) dim=(dim+1)%ndimension;
+  SHM=ShmDims;
    ShmDims[dim]*=2;
    dim=(dim+1)%ndimension;
  }
  ////////////////////////////////////////////////////////////////
  // Establish torus of processes and nodes with sub-blockings
@@ -307,7 +445,6 @@ void GlobalSharedMemory::OptimalCommunicator(const std::vector<int> &processors,
  /////////////////////////////////////////////////////////////////
  int ierr= MPI_Comm_split(WorldComm,0,rank,&optimal_comm);
  assert(ierr==0);
 #endif
 }
 ////////////////////////////////////////////////////////////////////////////////////////////
 // SHMGET
@@ -315,7 +452,7 @@ void GlobalSharedMemory::OptimalCommunicator(const std::vector<int> &processors,
 #ifdef GRID_MPI3_SHMGET
 void GlobalSharedMemory::SharedMemoryAllocate(uint64_t bytes, int flags)
 {
-  std::cout << "SharedMemoryAllocate "<< bytes<< " shmget implementation "<<std::endl;
+  std::cout << Mheader "SharedMemoryAllocate "<< bytes<< " shmget implementation "<<std::endl;
  assert(_ShmSetup==1);
  assert(_ShmAlloc==0);
@@ -338,7 +475,7 @@ void GlobalSharedMemory::SharedMemoryAllocate(uint64_t bytes, int flags)
        int errsv = errno;
        printf("Errno %d\n",errsv);
        printf("key   %d\n",key);
-        printf("size  %lld\n",size);
+        printf("size  %ld\n",size);
        printf("flags %d\n",flags);
        perror("shmget");
        exit(1);
@@ -370,14 +507,244 @@ void GlobalSharedMemory::SharedMemoryAllocate(uint64_t bytes, int flags)
  _ShmAllocBytes  = bytes;
 }
 #endif
- 
+
 ////////////////////////////////////////////////////////////////////////////////////////////
 // Hugetlbfs mapping intended
 ////////////////////////////////////////////////////////////////////////////////////////////
 #if defined(GRID_CUDA) ||defined(GRID_HIP)  || defined(GRID_SYCL)
 //if defined(GRID_SYCL)
 #if 0
 void GlobalSharedMemory::SharedMemoryAllocate(uint64_t bytes, int flags)
 {
  void * ShmCommBuf ; 
  assert(_ShmSetup==1);
  assert(_ShmAlloc==0);
  //////////////////////////////////////////////////////////////////////////////////////////////////////////
  // allocate the pointer array for shared windows for our group
  //////////////////////////////////////////////////////////////////////////////////////////////////////////
  MPI_Barrier(WorldShmComm);
  WorldShmCommBufs.resize(WorldShmSize);
  ///////////////////////////////////////////////////////////////////////////////////////////////////////////
  // Each MPI rank should allocate our own buffer
  ///////////////////////////////////////////////////////////////////////////////////////////////////////////
  ShmCommBuf = acceleratorAllocDevice(bytes);
  if (ShmCommBuf == (void *)NULL ) {
    std::cerr << " SharedMemoryMPI.cc acceleratorAllocDevice failed NULL pointer for " << bytes<<" bytes " << std::endl;
    exit(EXIT_FAILURE);  
  }
  std::cout << WorldRank << Mheader " SharedMemoryMPI.cc acceleratorAllocDevice "<< bytes 
 	    << "bytes at "<< std::hex<< ShmCommBuf <<std::dec<<" for comms buffers " <<std::endl;
  SharedMemoryZero(ShmCommBuf,bytes);
  assert(WorldShmSize == 1);
  for(int r=0;r<WorldShmSize;r++){
    WorldShmCommBufs[r] = ShmCommBuf;
  }
  _ShmAllocBytes=bytes;
  _ShmAlloc=1;
 }
 #endif
 #if defined(GRID_CUDA) ||defined(GRID_HIP) ||defined(GRID_SYCL)  
 void GlobalSharedMemory::SharedMemoryAllocate(uint64_t bytes, int flags)
 {
  void * ShmCommBuf ; 
  assert(_ShmSetup==1);
  assert(_ShmAlloc==0);
  //////////////////////////////////////////////////////////////////////////////////////////////////////////
  // allocate the pointer array for shared windows for our group
  //////////////////////////////////////////////////////////////////////////////////////////////////////////
  MPI_Barrier(WorldShmComm);
  WorldShmCommBufs.resize(WorldShmSize);
  //////////////////////////////////////////////////////////////////////////////////////////////////////////
  // TODO/FIXME : NOT ALL NVLINK BOARDS have full Peer to peer connectivity.
  // The annoyance is that they have partial peer 2 peer. This occurs on the 8 GPU blades.
  // e.g. DGX1, supermicro board, 
  //////////////////////////////////////////////////////////////////////////////////////////////////////////
  //  cudaDeviceGetP2PAttribute(&perfRank, cudaDevP2PAttrPerformanceRank, device1, device2);
  ///////////////////////////////////////////////////////////////////////////////////////////////////////////
  // Each MPI rank should allocate our own buffer
  ///////////////////////////////////////////////////////////////////////////////////////////////////////////
  ShmCommBuf = acceleratorAllocDevice(bytes);
  if (ShmCommBuf == (void *)NULL ) {
    std::cerr << " SharedMemoryMPI.cc acceleratorAllocDevice failed NULL pointer for " << bytes<<" bytes " << std::endl;
    exit(EXIT_FAILURE);  
  }
  if ( WorldRank == 0 ){
    std::cout << WorldRank << Mheader " SharedMemoryMPI.cc acceleratorAllocDevice "<< bytes 
 	      << "bytes at "<< std::hex<< ShmCommBuf << " - "<<(bytes-1+(uint64_t)ShmCommBuf) <<std::dec<<" for comms buffers " <<std::endl;
  }
  SharedMemoryZero(ShmCommBuf,bytes);
  std::cout<< "Setting up IPC"<<std::endl;
  ///////////////////////////////////////////////////////////////////////////////////////////////////////////
  // Loop over ranks/gpu's on our node
  ///////////////////////////////////////////////////////////////////////////////////////////////////////////
 #ifdef SHM_SOCKETS
  UnixSockets::Open(WorldShmRank);
 #endif
  for(int r=0;r<WorldShmSize;r++){
    MPI_Barrier(WorldShmComm);
 #ifndef GRID_MPI3_SHM_NONE
    //////////////////////////////////////////////////
    // If it is me, pass around the IPC access key
    //////////////////////////////////////////////////
    void * thisBuf = ShmCommBuf;
    if(!Stencil_force_mpi) {
 #ifdef GRID_SYCL_LEVEL_ZERO_IPC
    typedef struct { int fd; pid_t pid ; ze_ipc_mem_handle_t ze; } clone_mem_t;
    auto zeDevice    = cl::sycl::get_native<cl::sycl::backend::ext_oneapi_level_zero>(theGridAccelerator->get_device());
    auto zeContext   = cl::sycl::get_native<cl::sycl::backend::ext_oneapi_level_zero>(theGridAccelerator->get_context());
    ze_ipc_mem_handle_t ihandle;
    clone_mem_t handle;
    if ( r==WorldShmRank ) { 
      auto err = zeMemGetIpcHandle(zeContext,ShmCommBuf,&ihandle);
      if ( err != ZE_RESULT_SUCCESS ) {
 	std::cerr << "SharedMemoryMPI.cc zeMemGetIpcHandle failed for rank "<<r<<" "<<std::hex<<err<<std::dec<<std::endl;
 	exit(EXIT_FAILURE);
      } else {
 	std::cout << "SharedMemoryMPI.cc zeMemGetIpcHandle succeeded for rank "<<r<<" "<<std::hex<<err<<std::dec<<std::endl;
      }
      memcpy((void *)&handle.fd,(void *)&ihandle,sizeof(int));
      handle.pid = getpid();
      memcpy((void *)&handle.ze,(void *)&ihandle,sizeof(ihandle));
 #ifdef SHM_SOCKETS
      for(int rr=0;rr<WorldShmSize;rr++){
 	if(rr!=r){
 	  UnixSockets::SendFileDescriptor(handle.fd,rr);
 	}
      }
 #endif
    }
 #endif
 #ifdef GRID_CUDA
    cudaIpcMemHandle_t handle;
    if ( r==WorldShmRank ) { 
      auto err = cudaIpcGetMemHandle(&handle,ShmCommBuf);
      if ( err !=  cudaSuccess) {
 	std::cerr << " SharedMemoryMPI.cc cudaIpcGetMemHandle failed for rank" << r <<" "<<cudaGetErrorString(err)<< std::endl;
 	exit(EXIT_FAILURE);
      }
    }
 #endif
 #ifdef GRID_HIP
    hipIpcMemHandle_t handle;    
    if ( r==WorldShmRank ) { 
      auto err = hipIpcGetMemHandle(&handle,ShmCommBuf);
      if ( err !=  hipSuccess) {
 	std::cerr << " SharedMemoryMPI.cc hipIpcGetMemHandle failed for rank" << r <<" "<<hipGetErrorString(err)<< std::endl;
 	exit(EXIT_FAILURE);
      }
    }
 #endif
    //////////////////////////////////////////////////
    // Share this IPC handle across the Shm Comm
    //////////////////////////////////////////////////
    { 
      MPI_Barrier(WorldShmComm);
      int ierr=MPI_Bcast(&handle,
 			 sizeof(handle),
 			 MPI_BYTE,
 			 r,
 			 WorldShmComm);
      assert(ierr==0);
    }
    ///////////////////////////////////////////////////////////////
    // If I am not the source, overwrite thisBuf with remote buffer
    ///////////////////////////////////////////////////////////////
 #ifdef GRID_SYCL_LEVEL_ZERO_IPC
    if ( r!=WorldShmRank ) {
      thisBuf = nullptr;
      int myfd;
 #ifdef SHM_SOCKETS
      myfd=UnixSockets::RecvFileDescriptor();
 #else
      std::cout<<"mapping seeking remote pid/fd "
 	       <<handle.pid<<"/"
 	       <<handle.fd<<std::endl;
      int pidfd = syscall(SYS_pidfd_open,handle.pid,0);
      std::cout<<"Using IpcHandle pidfd "<<pidfd<<"\n";
      //      int myfd  = syscall(SYS_pidfd_getfd,pidfd,handle.fd,0);
      myfd  = syscall(438,pidfd,handle.fd,0);
      int err_t = errno;
      if (myfd < 0) {
        fprintf(stderr,"pidfd_getfd returned %d errno was %d\n", myfd,err_t); fflush(stderr);
 	perror("pidfd_getfd failed ");
 	assert(0);
      }
 #endif
      std::cout<<"Using IpcHandle mapped remote pid "<<handle.pid <<" FD "<<handle.fd <<" to myfd "<<myfd<<"\n";
      memcpy((void *)&ihandle,(void *)&handle.ze,sizeof(ihandle));
      memcpy((void *)&ihandle,(void *)&myfd,sizeof(int));
      auto err = zeMemOpenIpcHandle(zeContext,zeDevice,ihandle,0,&thisBuf);
      if ( err != ZE_RESULT_SUCCESS ) {
 	std::cerr << "SharedMemoryMPI.cc "<<zeContext<<" "<<zeDevice<<std::endl;
 	std::cerr << "SharedMemoryMPI.cc zeMemOpenIpcHandle failed for rank "<<r<<" "<<std::hex<<err<<std::dec<<std::endl; 
 	exit(EXIT_FAILURE);
      } else {
 	std::cout << "SharedMemoryMPI.cc zeMemOpenIpcHandle succeeded for rank "<<r<<std::endl;
 	std::cout << "SharedMemoryMPI.cc zeMemOpenIpcHandle pointer is "<<std::hex<<thisBuf<<std::dec<<std::endl;
      }
      assert(thisBuf!=nullptr);
    }
 #endif
 #ifdef GRID_CUDA
    if ( r!=WorldShmRank ) { 
      auto err = cudaIpcOpenMemHandle(&thisBuf,handle,cudaIpcMemLazyEnablePeerAccess);
      if ( err !=  cudaSuccess) {
 	std::cerr << " SharedMemoryMPI.cc cudaIpcOpenMemHandle failed for rank" << r <<" "<<cudaGetErrorString(err)<< std::endl;
 	exit(EXIT_FAILURE);
      }
    }
 #endif
 #ifdef GRID_HIP
    if ( r!=WorldShmRank ) { 
      auto err = hipIpcOpenMemHandle(&thisBuf,handle,hipIpcMemLazyEnablePeerAccess);
      if ( err !=  hipSuccess) {
 	std::cerr << " SharedMemoryMPI.cc hipIpcOpenMemHandle failed for rank" << r <<" "<<hipGetErrorString(err)<< std::endl;
 	exit(EXIT_FAILURE);
      }
    }
 #endif
    ///////////////////////////////////////////////////////////////
    // Save a copy of the device buffers
    ///////////////////////////////////////////////////////////////
    }
    WorldShmCommBufs[r] = thisBuf;
 #else
    WorldShmCommBufs[r] = ShmCommBuf;
 #endif
    MPI_Barrier(WorldShmComm);
  }
  _ShmAllocBytes=bytes;
  _ShmAlloc=1;
 }
 #endif
 #else 
 #ifdef GRID_MPI3_SHMMMAP
 void GlobalSharedMemory::SharedMemoryAllocate(uint64_t bytes, int flags)
 {
-  std::cout << "SharedMemoryAllocate "<< bytes<< " MMAP implementation "<< GRID_SHM_PATH <<std::endl;
+  std::cout << Mheader "SharedMemoryAllocate "<< bytes<< " MMAP implementation "<< GRID_SHM_PATH <<std::endl;
  assert(_ShmSetup==1);
  assert(_ShmAlloc==0);
  //////////////////////////////////////////////////////////////////////////////////////////////////////////
@@ -414,7 +781,7 @@ void GlobalSharedMemory::SharedMemoryAllocate(uint64_t bytes, int flags)
    assert(((uint64_t)ptr&0x3F)==0);
    close(fd);
    WorldShmCommBufs[r] =ptr;
-    std::cout << "Set WorldShmCommBufs["<<r<<"]="<<ptr<< "("<< bytes<< "bytes)"<<std::endl;
+    //    std::cout << Mheader "Set WorldShmCommBufs["<<r<<"]="<<ptr<< "("<< bytes<< "bytes)"<<std::endl;
  }
  _ShmAlloc=1;
  _ShmAllocBytes  = bytes;
@@ -424,7 +791,7 @@ void GlobalSharedMemory::SharedMemoryAllocate(uint64_t bytes, int flags)
 #ifdef GRID_MPI3_SHM_NONE
 void GlobalSharedMemory::SharedMemoryAllocate(uint64_t bytes, int flags)
 {
-  std::cout << "SharedMemoryAllocate "<< bytes<< " MMAP anonymous implementation "<<std::endl;
+  std::cout << Mheader "SharedMemoryAllocate "<< bytes<< " MMAP anonymous implementation "<<std::endl;
  assert(_ShmSetup==1);
  assert(_ShmAlloc==0);
  //////////////////////////////////////////////////////////////////////////////////////////////////////////
@@ -456,7 +823,7 @@ void GlobalSharedMemory::SharedMemoryAllocate(uint64_t bytes, int flags)
    assert(((uint64_t)ptr&0x3F)==0);
    close(fd);
    WorldShmCommBufs[r] =ptr;
-    std::cout << "Set WorldShmCommBufs["<<r<<"]="<<ptr<< "("<< bytes<< "bytes)"<<std::endl;
+    //    std::cout << "Set WorldShmCommBufs["<<r<<"]="<<ptr<< "("<< bytes<< "bytes)"<<std::endl;
  }
  _ShmAlloc=1;
  _ShmAllocBytes  = bytes;
@@ -471,7 +838,7 @@ void GlobalSharedMemory::SharedMemoryAllocate(uint64_t bytes, int flags)
 ////////////////////////////////////////////////////////////////////////////////////////////
 void GlobalSharedMemory::SharedMemoryAllocate(uint64_t bytes, int flags)
 { 
-  std::cout << "SharedMemoryAllocate "<< bytes<< " SHMOPEN implementation "<<std::endl;
+  std::cout << Mheader "SharedMemoryAllocate "<< bytes<< " SHMOPEN implementation "<<std::endl;
  assert(_ShmSetup==1);
  assert(_ShmAlloc==0); 
  MPI_Barrier(WorldShmComm);
@@ -500,7 +867,6 @@ void GlobalSharedMemory::SharedMemoryAllocate(uint64_t bytes, int flags)
 #endif
      void * ptr =  mmap(NULL,size, PROT_READ | PROT_WRITE, mmap_flag, fd, 0);
      std::cout << "Set WorldShmCommBufs["<<r<<"]="<<ptr<< "("<< size<< "bytes)"<<std::endl;
      if ( ptr == (void * )MAP_FAILED ) {       
 	perror("failed mmap");     
 	assert(0);    
@@ -537,14 +903,31 @@ void GlobalSharedMemory::SharedMemoryAllocate(uint64_t bytes, int flags)
  _ShmAllocBytes = bytes;
 }
 #endif
 #endif // End NVCC case for GPU device buffers
-
+/////////////////////////////////////////////////////////////////////////
-
+// Routines accessing shared memory should route through for GPU safety
-
+/////////////////////////////////////////////////////////////////////////
-  ////////////////////////////////////////////////////////
+void GlobalSharedMemory::SharedMemoryZero(void *dest,size_t bytes)
-  // Global shared functionality finished
+{
-  // Now move to per communicator functionality
+#if defined(GRID_CUDA) || defined(GRID_HIP) || defined(GRID_SYCL)
-  ////////////////////////////////////////////////////////
+  acceleratorMemSet(dest,0,bytes);
 #else
  bzero(dest,bytes);
 #endif
 }
 void GlobalSharedMemory::SharedMemoryCopy(void *dest,void *src,size_t bytes)
 {
 #if defined(GRID_CUDA) || defined(GRID_HIP) || defined(GRID_SYCL)
  acceleratorCopyToDevice(src,dest,bytes);
 #else   
  bcopy(src,dest,bytes);
 #endif
 }
 ////////////////////////////////////////////////////////
 // Global shared functionality finished
 // Now move to per communicator functionality
 ////////////////////////////////////////////////////////
 void SharedMemory::SetCommunicator(Grid_MPI_Comm comm)
 {
  int rank, size;
@@ -555,7 +938,11 @@ void SharedMemory::SetCommunicator(Grid_MPI_Comm comm)
  /////////////////////////////////////////////////////////////////////
  // Split into groups that can share memory
  /////////////////////////////////////////////////////////////////////
 #ifndef GRID_MPI3_SHM_NONE
  MPI_Comm_split_type(comm, MPI_COMM_TYPE_SHARED, 0, MPI_INFO_NULL,&ShmComm);
 #else
  MPI_Comm_split(comm, rank, 0, &ShmComm);
 #endif
  MPI_Comm_rank(ShmComm     ,&ShmRank);
  MPI_Comm_size(ShmComm     ,&ShmSize);
  ShmCommBufs.resize(ShmSize);
@@ -572,7 +959,6 @@ void SharedMemory::SetCommunicator(Grid_MPI_Comm comm)
    MPI_Allreduce(MPI_IN_PLACE,&wsr,1,MPI_UINT32_T,MPI_SUM,ShmComm);
    ShmCommBufs[r] = GlobalSharedMemory::WorldShmCommBufs[wsr];
    //    std::cout << "SetCommunicator ShmCommBufs ["<< r<< "] = "<< ShmCommBufs[r]<< "  wsr = "<<wsr<<std::endl;
  }
  ShmBufferFreeAll();
@@ -585,6 +971,19 @@ void SharedMemory::SetCommunicator(Grid_MPI_Comm comm)
  std::vector<int> ranks(size);   for(int r=0;r<size;r++) ranks[r]=r;
  MPI_Group_translate_ranks (FullGroup,size,&ranks[0],ShmGroup, &ShmRanks[0]); 
 #ifdef GRID_SHM_FORCE_MPI
  // Hide the shared memory path between ranks
  {
    for(int r=0;r<size;r++){
      if ( r!=rank ) {
 	ShmRanks[r] = MPI_UNDEFINED;
      }
    }
  }
 #endif
  //SharedMemoryTest();
 }
 //////////////////////////////////////////////////////////////////
 // On node barrier
@@ -599,24 +998,26 @@ void SharedMemory::ShmBarrier(void)
 void SharedMemory::SharedMemoryTest(void)
 {
  ShmBarrier();
  uint64_t check[3];
  uint64_t magic = 0x5A5A5A;
  if ( ShmRank == 0 ) {
-    for(int r=0;r<ShmSize;r++){
+    for(uint64_t r=0;r<ShmSize;r++){
-      uint64_t * check = (uint64_t *) ShmCommBufs[r];
+       check[0]=GlobalSharedMemory::WorldNode;
-      check[0] = GlobalSharedMemory::WorldNode;
+       check[1]=r;
-      check[1] = r;
+       check[2]=magic;
-      check[2] = 0x5A5A5A;
+       GlobalSharedMemory::SharedMemoryCopy( ShmCommBufs[r], check, 3*sizeof(uint64_t));
    }
  }
  ShmBarrier();
-  for(int r=0;r<ShmSize;r++){
+  for(uint64_t r=0;r<ShmSize;r++){
-    uint64_t * check = (uint64_t *) ShmCommBufs[r];
+    ShmBarrier();
-    
+    GlobalSharedMemory::SharedMemoryCopy(check,ShmCommBufs[r], 3*sizeof(uint64_t));
    ShmBarrier();
    assert(check[0]==GlobalSharedMemory::WorldNode);
    assert(check[1]==r);
-    assert(check[2]==0x5A5A5A);
+    assert(check[2]==magic);
-    
+    ShmBarrier();
  }
  ShmBarrier();
 }
 void *SharedMemory::ShmBuffer(int rank)
@@ -630,7 +1031,6 @@ void *SharedMemory::ShmBuffer(int rank)
 }
 void *SharedMemory::ShmBufferTranslate(int rank,void * local_p)
 {
  static int count =0;
  int gpeer = ShmRanks[rank];
  assert(gpeer!=ShmRank); // never send to self
  if (gpeer == MPI_UNDEFINED){
@@ -649,4 +1049,5 @@ SharedMemory::~SharedMemory()
  }
 };
-}
+NAMESPACE_END(Grid); 
--- a/Grid/communicator/SharedMemoryNone.cc
+++ b/Grid/communicator/SharedMemoryNone.cc
@@ -28,7 +28,8 @@ Author: Peter Boyle <paboyle@ph.ed.ac.uk>
 #include <Grid/GridCore.h>
-namespace Grid { 
+NAMESPACE_BEGIN(Grid); 
 #define header "SharedMemoryNone: "
 /*Construct from an MPI communicator*/
 void GlobalSharedMemory::Init(Grid_MPI_Comm comm)
@@ -47,14 +48,47 @@ void GlobalSharedMemory::Init(Grid_MPI_Comm comm)
  _ShmSetup=1;
 }
-void GlobalSharedMemory::OptimalCommunicator(const std::vector<int> &processors,Grid_MPI_Comm & optimal_comm)
+void GlobalSharedMemory::OptimalCommunicator(const Coordinate &processors,Grid_MPI_Comm & optimal_comm,Coordinate &SHM)
 {
  optimal_comm = WorldComm;
  SHM = Coordinate(processors.size(),1);
 }
 ////////////////////////////////////////////////////////////////////////////////////////////
 // Hugetlbfs mapping intended, use anonymous mmap
 ////////////////////////////////////////////////////////////////////////////////////////////
 #if 1
 void GlobalSharedMemory::SharedMemoryAllocate(uint64_t bytes, int flags)
 {
  std::cout << header "SharedMemoryAllocate "<< bytes<< " GPU implementation "<<std::endl;
  void * ShmCommBuf ; 
  assert(_ShmSetup==1);
  assert(_ShmAlloc==0);
  ///////////////////////////////////////////////////////////////////////////////////////////////////////////
  // Each MPI rank should allocate our own buffer
  ///////////////////////////////////////////////////////////////////////////////////////////////////////////
  ShmCommBuf = acceleratorAllocDevice(bytes);
  if (ShmCommBuf == (void *)NULL ) {
    std::cerr << " SharedMemoryNone.cc acceleratorAllocDevice failed NULL pointer for " << bytes<<" bytes " << std::endl;
    exit(EXIT_FAILURE);  
  }
  if ( WorldRank == 0 ){
    std::cout << WorldRank << header " SharedMemoryNone.cc acceleratorAllocDevice "<< bytes 
 	      << "bytes at "<< std::hex<< ShmCommBuf <<std::dec<<" for comms buffers " <<std::endl;
  }
  SharedMemoryZero(ShmCommBuf,bytes);
  ///////////////////////////////////////////////////////////////////////////////////////////////////////////
  // Loop over ranks/gpu's on our node
  ///////////////////////////////////////////////////////////////////////////////////////////////////////////
  WorldShmCommBufs[0] = ShmCommBuf;
  _ShmAllocBytes=bytes;
  _ShmAlloc=1;
 }
 #else
 void GlobalSharedMemory::SharedMemoryAllocate(uint64_t bytes, int flags)
 {
  void * ShmCommBuf ; 
@@ -83,11 +117,19 @@ void GlobalSharedMemory::SharedMemoryAllocate(uint64_t bytes, int flags)
  _ShmAllocBytes=bytes;
  _ShmAlloc=1;
 };
-
+#endif
-  ////////////////////////////////////////////////////////
+void GlobalSharedMemory::SharedMemoryZero(void *dest,size_t bytes)
-  // Global shared functionality finished
+{
-  // Now move to per communicator functionality
+  acceleratorMemSet(dest,0,bytes);
-  ////////////////////////////////////////////////////////
+}
 void GlobalSharedMemory::SharedMemoryCopy(void *dest,void *src,size_t bytes)
 {
  acceleratorCopyToDevice(src,dest,bytes);
 }
 ////////////////////////////////////////////////////////
 // Global shared functionality finished
 // Now move to per communicator functionality
 ////////////////////////////////////////////////////////
 void SharedMemory::SetCommunicator(Grid_MPI_Comm comm)
 {
  assert(GlobalSharedMemory::ShmAlloc()==1);
@@ -125,4 +167,5 @@ void *SharedMemory::ShmBufferTranslate(int rank,void * local_p)
 SharedMemory::~SharedMemory()
 {};
-}
+NAMESPACE_END(Grid); 
--- a/Grid/cshift/Cshift.h
+++ b/Grid/cshift/Cshift.h
@@ -1,4 +1,4 @@
-    /*************************************************************************************
+/*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
@@ -23,8 +23,8 @@ Author: Peter Boyle <paboyle@ph.ed.ac.uk>
    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 */
+/*  END LEGAL */
 #ifndef _GRID_CSHIFT_H_
 #define _GRID_CSHIFT_H_
@@ -49,4 +49,14 @@ Author: Peter Boyle <paboyle@ph.ed.ac.uk>
 #ifdef GRID_COMMS_SHMEM
 #include <Grid/cshift/Cshift_mpi.h> // uses same implementation of communicator
 #endif 
 NAMESPACE_BEGIN(Grid);
 template<class Expression,typename std::enable_if<is_lattice_expr<Expression>::value,void>::type * = nullptr> 
 auto Cshift(const Expression &expr,int dim,int shift)  -> decltype(closure(expr)) 
 {
  return Cshift(closure(expr),dim,shift);
 }
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/cshift/Cshift_common.h
+++ b/Grid/cshift/Cshift_common.h
@@ -0,0 +1,515 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./lib/cshift/Cshift_common.h
    Copyright (C) 2015
 Author: Peter Boyle <paboyle@ph.ed.ac.uk>
    This program is free software; you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation; either version 2 of the License, or
    (at your option) any later version.
    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.
    You should have received a copy of the GNU General Public License along
    with this program; if not, write to the Free Software Foundation, Inc.,
    51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
    See the full license in the file "LICENSE" in the top level distribution directory
    *************************************************************************************/
    /*  END LEGAL */
 #pragma once
 NAMESPACE_BEGIN(Grid);
 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 
 ///////////////////////////////////////////////////////////////////
 template<class vobj> void 
 Gather_plane_simple (const Lattice<vobj> &rhs,cshiftVector<vobj> &buffer,int dimension,int plane,int cbmask, int off=0)
 {
  int rd = rhs.Grid()->_rdimensions[dimension];
  if ( !rhs.Grid()->CheckerBoarded(dimension) ) {
    cbmask = 0x3;
  }
  int so=plane*rhs.Grid()->_ostride[dimension]; // base offset for start of plane 
  int e1=rhs.Grid()->_slice_nblock[dimension];
  int e2=rhs.Grid()->_slice_block[dimension];
  int ent = 0;
  if(Cshift_table.size()<e1*e2) Cshift_table.resize(e1*e2); // Let it grow to biggest
  int stride=rhs.Grid()->_slice_stride[dimension];
  if ( cbmask == 0x3 ) { 
    for(int n=0;n<e1;n++){
      for(int b=0;b<e2;b++){
 	int o  = n*stride;
 	int bo = n*e2;
 	Cshift_table[ent++] = std::pair<int,int>(off+bo+b,so+o+b);
      }
    }
  } else { 
     int bo=0;
     for(int n=0;n<e1;n++){
       for(int b=0;b<e2;b++){
 	 int o  = n*stride;
 	 int ocb=1<<rhs.Grid()->CheckerBoardFromOindex(o+b);
 	 if ( ocb &cbmask ) {
 	   Cshift_table[ent++]=std::pair<int,int> (off+bo++,so+o+b);
 	 }
       }
     }
  }
  {
    auto buffer_p = & buffer[0];
    auto table = MapCshiftTable();
 #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]));
    });
 #else
    autoView(rhs_v , rhs, CpuRead);
    thread_for(i,ent,{
      buffer_p[table[i].first]=rhs_v[table[i].second];
    });
 #endif
  }
 }
 ///////////////////////////////////////////////////////////////////
 // Gather for when there *is* need to SIMD split 
 ///////////////////////////////////////////////////////////////////
 template<class vobj> void 
 Gather_plane_extract(const Lattice<vobj> &rhs,
 		     ExtractPointerArray<typename vobj::scalar_object> pointers,
 		     int dimension,int plane,int cbmask)
 {
  int rd = rhs.Grid()->_rdimensions[dimension];
  if ( !rhs.Grid()->CheckerBoarded(dimension) ) {
    cbmask = 0x3;
  }
  int so  = plane*rhs.Grid()->_ostride[dimension]; // base offset for start of plane 
  int e1=rhs.Grid()->_slice_nblock[dimension];
  int e2=rhs.Grid()->_slice_block[dimension];
  int n1=rhs.Grid()->_slice_stride[dimension];
  if ( cbmask ==0x3){
 #ifdef ACCELERATOR_CSHIFT
    autoView(rhs_v , rhs, AcceleratorRead);
    accelerator_for(nn,e1*e2,1,{
 	int n = nn%e1;
 	int b = nn/e1;
 	int o      =   n*n1;
 	int offset = b+n*e2;
 	vobj temp =rhs_v[so+o+b];
 	extract<vobj>(temp,pointers,offset);
      });
 #else
    autoView(rhs_v , rhs, CpuRead);
    thread_for2d(n,e1,b,e2,{
 	int o      =   n*n1;
 	int offset = b+n*e2;
 	vobj temp =rhs_v[so+o+b];
 	extract<vobj>(temp,pointers,offset);
      });
 #endif
  } else { 
    Coordinate rdim=rhs.Grid()->_rdimensions;
    Coordinate cdm =rhs.Grid()->_checker_dim_mask;
    std::cout << " Dense packed buffer WARNING " <<std::endl; // Does this get called twice once for each cb?
 #ifdef ACCELERATOR_CSHIFT    
    autoView(rhs_v , rhs, AcceleratorRead);
    accelerator_for(nn,e1*e2,1,{
 	int n = nn%e1;
 	int b = nn/e1;
 	Coordinate coor;
 	int o=n*n1;
 	int oindex = o+b;
       	int cb = RedBlackCheckerBoardFromOindex(oindex, rdim, cdm);
 	int ocb=1<<cb;
 	int offset = b+n*e2;
 	if ( ocb & cbmask ) {
 	  vobj temp =rhs_v[so+o+b];
 	  extract<vobj>(temp,pointers,offset);
 	}
      });
 #else
    autoView(rhs_v , rhs, CpuRead);
    thread_for2d(n,e1,b,e2,{
 	Coordinate coor;
 	int o=n*n1;
 	int oindex = o+b;
       	int cb = RedBlackCheckerBoardFromOindex(oindex, rdim, cdm);
 	int ocb=1<<cb;
 	int offset = b+n*e2;
 	if ( ocb & cbmask ) {
 	  vobj temp =rhs_v[so+o+b];
 	  extract<vobj>(temp,pointers,offset);
 	}
      });
 #endif
  }
 }
 //////////////////////////////////////////////////////
 // Scatter for when there is no need to SIMD split
 //////////////////////////////////////////////////////
 template<class vobj> void Scatter_plane_simple (Lattice<vobj> &rhs,cshiftVector<vobj> &buffer, int dimension,int plane,int cbmask)
 {
  int rd = rhs.Grid()->_rdimensions[dimension];
  if ( !rhs.Grid()->CheckerBoarded(dimension) ) {
    cbmask=0x3;
  }
  int so  = plane*rhs.Grid()->_ostride[dimension]; // base offset for start of plane 
  int e1=rhs.Grid()->_slice_nblock[dimension];
  int e2=rhs.Grid()->_slice_block[dimension];
  int stride=rhs.Grid()->_slice_stride[dimension];
  if(Cshift_table.size()<e1*e2) Cshift_table.resize(e1*e2); // Let it grow to biggest
  int ent    =0;
  if ( cbmask ==0x3 ) {
    for(int n=0;n<e1;n++){
      for(int b=0;b<e2;b++){
 	int o   =n*rhs.Grid()->_slice_stride[dimension];
 	int bo  =n*rhs.Grid()->_slice_block[dimension];
 	Cshift_table[ent++] = std::pair<int,int>(so+o+b,bo+b);
      }
    }
  } else { 
    int bo=0;
    for(int n=0;n<e1;n++){
      for(int b=0;b<e2;b++){
 	int o   =n*rhs.Grid()->_slice_stride[dimension];
 	int ocb=1<<rhs.Grid()->CheckerBoardFromOindex(o+b);// Could easily be a table lookup
 	if ( ocb & cbmask ) {
 	  Cshift_table[ent++]=std::pair<int,int> (so+o+b,bo++);
 	}
      }
    }
  }
  {
    auto buffer_p = & buffer[0];
    auto table = MapCshiftTable();
 #ifdef ACCELERATOR_CSHIFT    
    autoView( rhs_v, rhs, AcceleratorWrite);
    accelerator_for(i,ent,vobj::Nsimd(),{
 	coalescedWrite(rhs_v[table[i].first],coalescedRead(buffer_p[table[i].second]));
    });
 #else
    autoView( rhs_v, rhs, CpuWrite);
    thread_for(i,ent,{
      rhs_v[table[i].first]=buffer_p[table[i].second];
    });
 #endif
  }
 }
 //////////////////////////////////////////////////////
 // Scatter for when there *is* need to SIMD split
 //////////////////////////////////////////////////////
 template<class vobj> void Scatter_plane_merge(Lattice<vobj> &rhs,ExtractPointerArray<typename vobj::scalar_object> pointers,int dimension,int plane,int cbmask)
 {
  int rd = rhs.Grid()->_rdimensions[dimension];
  if ( !rhs.Grid()->CheckerBoarded(dimension) ) {
    cbmask=0x3;
  }
  int so  = plane*rhs.Grid()->_ostride[dimension]; // base offset for start of plane 
  int e1=rhs.Grid()->_slice_nblock[dimension];
  int e2=rhs.Grid()->_slice_block[dimension];
  if(cbmask ==0x3 ) {
    int _slice_stride = rhs.Grid()->_slice_stride[dimension];
    int _slice_block = rhs.Grid()->_slice_block[dimension];
 #ifdef ACCELERATOR_CSHIFT    
    autoView( rhs_v , rhs, AcceleratorWrite);
    accelerator_for(nn,e1*e2,1,{
 	int n = nn%e1;
 	int b = nn/e1;
 	int o      = n*_slice_stride;
 	int offset = b+n*_slice_block;
 	merge(rhs_v[so+o+b],pointers,offset);
      });
 #else
    autoView( rhs_v , rhs, CpuWrite);
    thread_for2d(n,e1,b,e2,{
 	int o      = n*_slice_stride;
 	int offset = b+n*_slice_block;
 	merge(rhs_v[so+o+b],pointers,offset);
    });
 #endif
  } else { 
    // Case of SIMD split AND checker dim cannot currently be hit, except in 
    // Test_cshift_red_black code.
    std::cout << "Scatter_plane merge assert(0); think this is buggy FIXME "<< std::endl;// think this is buggy FIXME
    std::cout<<" Unthreaded warning -- buffer is not densely packed ??"<<std::endl;
    assert(0); // This will fail if hit on GPU
    autoView( rhs_v, rhs, CpuWrite);
    for(int n=0;n<e1;n++){
      for(int b=0;b<e2;b++){
 	int o      = n*rhs.Grid()->_slice_stride[dimension];
 	int offset = b+n*rhs.Grid()->_slice_block[dimension];
 	int ocb=1<<rhs.Grid()->CheckerBoardFromOindex(o+b);
 	if ( ocb&cbmask ) {
 	  merge(rhs_v[so+o+b],pointers,offset);
 	}
      }
    }
  }
 }
 //////////////////////////////////////////////////////
 // local to node block strided copies
 //////////////////////////////////////////////////////
 template<class vobj> void Copy_plane(Lattice<vobj>& lhs,const Lattice<vobj> &rhs, int dimension,int lplane,int rplane,int cbmask)
 {
  int rd = rhs.Grid()->_rdimensions[dimension];
  if ( !rhs.Grid()->CheckerBoarded(dimension) ) {
    cbmask=0x3;
  }
  int ro  = rplane*rhs.Grid()->_ostride[dimension]; // base offset for start of plane 
  int lo  = lplane*lhs.Grid()->_ostride[dimension]; // base offset for start of plane 
  int e1=rhs.Grid()->_slice_nblock[dimension]; // clearly loop invariant for icpc
  int e2=rhs.Grid()->_slice_block[dimension];
  int stride = rhs.Grid()->_slice_stride[dimension];
  if(Cshift_table.size()<e1*e2) Cshift_table.resize(e1*e2); // Let it grow to biggest
  int ent=0;
  if(cbmask == 0x3 ){
    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);
      }
    }
  } else { 
    for(int n=0;n<e1;n++){
      for(int b=0;b<e2;b++){
        int o =n*stride+b;
        int ocb=1<<lhs.Grid()->CheckerBoardFromOindex(o);
        if ( ocb&cbmask ) {
 	  Cshift_table[ent++] = std::pair<int,int>(lo+o,ro+o);
 	}
      }
    }
  }
  {
    auto table = MapCshiftTable();
 #ifdef ACCELERATOR_CSHIFT    
    autoView(rhs_v , rhs, AcceleratorRead);
    autoView(lhs_v , lhs, AcceleratorWrite);
    accelerator_for(i,ent,vobj::Nsimd(),{
      coalescedWrite(lhs_v[table[i].first],coalescedRead(rhs_v[table[i].second]));
    });
 #else
    autoView(rhs_v , rhs, CpuRead);
    autoView(lhs_v , lhs, CpuWrite);
    thread_for(i,ent,{
      lhs_v[table[i].first]=rhs_v[table[i].second];
    });
 #endif
  }
 }
 template<class vobj> void Copy_plane_permute(Lattice<vobj>& lhs,const Lattice<vobj> &rhs, int dimension,int lplane,int rplane,int cbmask,int permute_type)
 {
  int rd = rhs.Grid()->_rdimensions[dimension];
  if ( !rhs.Grid()->CheckerBoarded(dimension) ) {
    cbmask=0x3;
  }
  int ro  = rplane*rhs.Grid()->_ostride[dimension]; // base offset for start of plane 
  int lo  = lplane*lhs.Grid()->_ostride[dimension]; // base offset for start of plane 
  int e1=rhs.Grid()->_slice_nblock[dimension];
  int e2=rhs.Grid()->_slice_block [dimension];
  int stride = rhs.Grid()->_slice_stride[dimension];
  if(Cshift_table.size()<e1*e2) Cshift_table.resize(e1*e2); // Let it grow to biggest
  int ent=0;
  if ( cbmask == 0x3 ) {
    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);
    }}
  } else {
    for(int n=0;n<e1;n++){
    for(int b=0;b<e2;b++){
      int o  =n*stride;
      int ocb=1<<lhs.Grid()->CheckerBoardFromOindex(o+b);
      if ( ocb&cbmask ) Cshift_table[ent++] = std::pair<int,int>(lo+o+b,ro+o+b);
    }}
  }
  {
    auto table = MapCshiftTable();
 #ifdef ACCELERATOR_CSHIFT    
    autoView( rhs_v, rhs, AcceleratorRead);
    autoView( lhs_v, lhs, AcceleratorWrite);
    accelerator_for(i,ent,1,{
      permute(lhs_v[table[i].first],rhs_v[table[i].second],permute_type);
    });
 #else
    autoView( rhs_v, rhs, CpuRead);
    autoView( lhs_v, lhs, CpuWrite);
    thread_for(i,ent,{
      permute(lhs_v[table[i].first],rhs_v[table[i].second],permute_type);
    });
 #endif
  }
 }
 //////////////////////////////////////////////////////
 // Local to node Cshift
 //////////////////////////////////////////////////////
 template<class vobj> void Cshift_local(Lattice<vobj>& ret,const Lattice<vobj> &rhs,int dimension,int shift)
 {
  int sshift[2];
  sshift[0] = rhs.Grid()->CheckerBoardShiftForCB(rhs.Checkerboard(),dimension,shift,Even);
  sshift[1] = rhs.Grid()->CheckerBoardShiftForCB(rhs.Checkerboard(),dimension,shift,Odd);
  if ( sshift[0] == sshift[1] ) {
    Cshift_local(ret,rhs,dimension,shift,0x3);
  } else {
    Cshift_local(ret,rhs,dimension,shift,0x1);// if checkerboard is unfavourable take two passes
    Cshift_local(ret,rhs,dimension,shift,0x2);// both with block stride loop iteration
  }
 }
 template<class vobj> void Cshift_local(Lattice<vobj> &ret,const Lattice<vobj> &rhs,int dimension,int shift,int cbmask)
 {
  GridBase *grid = rhs.Grid();
  int fd = grid->_fdimensions[dimension];
  int rd = grid->_rdimensions[dimension];
  int ld = grid->_ldimensions[dimension];
  int gd = grid->_gdimensions[dimension];
  int ly = grid->_simd_layout[dimension];
  // Map to always positive shift modulo global full dimension.
  shift = (shift+fd)%fd;
  // the permute type
  ret.Checkerboard() = grid->CheckerBoardDestination(rhs.Checkerboard(),shift,dimension);
  int permute_dim =grid->PermuteDim(dimension);
  int permute_type=grid->PermuteType(dimension);
  int permute_type_dist;
  for(int x=0;x<rd;x++){       
    //    int o   = 0;
    int bo  = x * grid->_ostride[dimension];
    int cb= (cbmask==0x2)? Odd : Even;
    int sshift = grid->CheckerBoardShiftForCB(rhs.Checkerboard(),dimension,shift,cb);
    int sx     = (x+sshift)%rd;
    // wrap is whether sshift > rd.
    //  num is sshift mod rd.
    // 
    //  shift 7
    //
    //  XoXo YcYc 
    //  oXoX cYcY
    //  XoXo YcYc
    //  oXoX cYcY
    //
    //  sshift -- 
    //
    //  XX YY ; 3
    //  XX YY ; 0
    //  XX YY ; 3
    //  XX YY ; 0
    //
    int permute_slice=0;
    if(permute_dim){
      int wrap = sshift/rd; wrap=wrap % ly;
      int  num = sshift%rd;
      if ( x< rd-num ) permute_slice=wrap;
      else permute_slice = (wrap+1)%ly;
      if ( (ly>2) && (permute_slice) ) {
 	assert(permute_type & RotateBit);
 	permute_type_dist = permute_type|permute_slice;
      } else {
 	permute_type_dist = permute_type;
      }
    }
    if ( permute_slice ) Copy_plane_permute(ret,rhs,dimension,x,sx,cbmask,permute_type_dist);
    else                 Copy_plane(ret,rhs,dimension,x,sx,cbmask); 
  }
 }
 NAMESPACE_END(Grid);
--- a/Grid/cshift/Cshift_mpi.h
+++ b/Grid/cshift/Cshift_mpi.h
@@ -0,0 +1,546 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./lib/cshift/Cshift_mpi.h
    Copyright (C) 2015
 Author: Peter Boyle <paboyle@ph.ed.ac.uk>
 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 _GRID_CSHIFT_MPI_H_
 #define _GRID_CSHIFT_MPI_H_
 NAMESPACE_BEGIN(Grid); 
 template<class vobj> Lattice<vobj> Cshift(const Lattice<vobj> &rhs,int dimension,int shift)
 {
  typedef typename vobj::vector_type vector_type;
  typedef typename vobj::scalar_type scalar_type;
  Lattice<vobj> ret(rhs.Grid()); 
  int fd = rhs.Grid()->_fdimensions[dimension];
  int rd = rhs.Grid()->_rdimensions[dimension];
  // Map to always positive shift modulo global full dimension.
  shift = (shift+fd)%fd;
  ret.Checkerboard() = rhs.Grid()->CheckerBoardDestination(rhs.Checkerboard(),shift,dimension);
  // the permute type
  int simd_layout     = rhs.Grid()->_simd_layout[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
  } else if ( splice_dim ) {
    //std::cout << "CSHIFT: Cshift_comms_simd call - splice_dim = " << splice_dim << " shift " << shift << " dimension = " << dimension << std::endl;
    Cshift_comms_simd(ret,rhs,dimension,shift);
  } else {
    //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;
 }
 template<class vobj> void Cshift_comms(Lattice<vobj>& ret,const Lattice<vobj> &rhs,int dimension,int shift)
 {
  int sshift[2];
  sshift[0] = rhs.Grid()->CheckerBoardShiftForCB(rhs.Checkerboard(),dimension,shift,Even);
  sshift[1] = rhs.Grid()->CheckerBoardShiftForCB(rhs.Checkerboard(),dimension,shift,Odd);
  //  std::cout << "Cshift_comms dim "<<dimension<<"cb "<<rhs.Checkerboard()<<"shift "<<shift<<" sshift " << sshift[0]<<" "<<sshift[1]<<std::endl;
  if ( sshift[0] == sshift[1] ) {
    //    std::cout << "Single pass Cshift_comms" <<std::endl;
    Cshift_comms(ret,rhs,dimension,shift,0x3);
  } else {
    //    std::cout << "Two pass Cshift_comms" <<std::endl;
    Cshift_comms(ret,rhs,dimension,shift,0x1);// if checkerboard is unfavourable take two passes
    Cshift_comms(ret,rhs,dimension,shift,0x2);// both with block stride loop iteration
  }
 }
 template<class vobj> void Cshift_comms_simd(Lattice<vobj>& ret,const Lattice<vobj> &rhs,int dimension,int shift)
 {
  int sshift[2];
  sshift[0] = rhs.Grid()->CheckerBoardShiftForCB(rhs.Checkerboard(),dimension,shift,Even);
  sshift[1] = rhs.Grid()->CheckerBoardShiftForCB(rhs.Checkerboard(),dimension,shift,Odd);
  //std::cout << "Cshift_comms_simd dim "<<dimension<<"cb "<<rhs.checkerboard<<"shift "<<shift<<" sshift " << sshift[0]<<" "<<sshift[1]<<std::endl;
  if ( sshift[0] == sshift[1] ) {
    //std::cout << "Single pass Cshift_comms" <<std::endl;
    Cshift_comms_simd(ret,rhs,dimension,shift,0x3);
  } else {
    //std::cout << "Two pass Cshift_comms" <<std::endl;
    Cshift_comms_simd(ret,rhs,dimension,shift,0x1);// if checkerboard is unfavourable take two passes
    Cshift_comms_simd(ret,rhs,dimension,shift,0x2);// both with block stride loop iteration
  }
 }
 #define ACCELERATOR_CSHIFT_NO_COPY
 #ifdef ACCELERATOR_CSHIFT_NO_COPY
 template<class vobj> void Cshift_comms(Lattice<vobj> &ret,const Lattice<vobj> &rhs,int dimension,int shift,int cbmask)
 {
  typedef typename vobj::vector_type vector_type;
  typedef typename vobj::scalar_type scalar_type;
  GridBase *grid=rhs.Grid();
  Lattice<vobj> temp(rhs.Grid());
  int fd              = rhs.Grid()->_fdimensions[dimension];
  int rd              = rhs.Grid()->_rdimensions[dimension];
  int pd              = rhs.Grid()->_processors[dimension];
  int simd_layout     = rhs.Grid()->_simd_layout[dimension];
  int comm_dim        = rhs.Grid()->_processors[dimension] >1 ;
  assert(simd_layout==1);
  assert(comm_dim==1);
  assert(shift>=0);
  assert(shift<fd);
  int buffer_size = rhs.Grid()->_slice_nblock[dimension]*rhs.Grid()->_slice_block[dimension];
  static cshiftVector<vobj> send_buf; send_buf.resize(buffer_size);
  static cshiftVector<vobj> recv_buf; recv_buf.resize(buffer_size);
  int cb= (cbmask==0x2)? Odd : Even;
  int sshift= rhs.Grid()->CheckerBoardShiftForCB(rhs.Checkerboard(),dimension,shift,cb);
  RealD tcopy=0.0;
  RealD tgather=0.0;
  RealD tscatter=0.0;
  RealD tcomms=0.0;
  uint64_t xbytes=0;
  for(int x=0;x<rd;x++){       
    int sx        =  (x+sshift)%rd;
    int comm_proc = ((x+sshift)/rd)%pd;
    if (comm_proc==0) {
      tcopy-=usecond();
      Copy_plane(ret,rhs,dimension,x,sx,cbmask); 
      tcopy+=usecond();
    } else {
      int words = buffer_size;
      if (cbmask != 0x3) words=words>>1;
      int bytes = words * sizeof(vobj);
      tgather-=usecond();
      Gather_plane_simple (rhs,send_buf,dimension,sx,cbmask);
      tgather+=usecond();
      //      int rank           = grid->_processor;
      int recv_from_rank;
      int xmit_to_rank;
      grid->ShiftedRanks(dimension,comm_proc,xmit_to_rank,recv_from_rank);
      tcomms-=usecond();
      //      grid->Barrier();
      grid->SendToRecvFrom((void *)&send_buf[0],
 			   xmit_to_rank,
 			   (void *)&recv_buf[0],
 			   recv_from_rank,
 			   bytes);
      xbytes+=bytes;
      //      grid->Barrier();
      tcomms+=usecond();
      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)
 {
  GridBase *grid=rhs.Grid();
  const int Nsimd = grid->Nsimd();
  typedef typename vobj::vector_type vector_type;
  typedef typename vobj::scalar_object scalar_object;
  typedef typename vobj::scalar_type scalar_type;
  int fd = grid->_fdimensions[dimension];
  int rd = grid->_rdimensions[dimension];
  int ld = grid->_ldimensions[dimension];
  int pd = grid->_processors[dimension];
  int simd_layout     = grid->_simd_layout[dimension];
  int comm_dim        = grid->_processors[dimension] >1 ;
  //std::cout << "Cshift_comms_simd dim "<< dimension << " fd "<<fd<<" rd "<<rd
  //    << " ld "<<ld<<" pd " << pd<<" simd_layout "<<simd_layout 
  //    << " comm_dim " << comm_dim << " cbmask " << cbmask <<std::endl;
  assert(comm_dim==1);
  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);
  ///////////////////////////////////////////////
  // Simd direction uses an extract/merge pair
  ///////////////////////////////////////////////
  int buffer_size = grid->_slice_nblock[dimension]*grid->_slice_block[dimension];
  //  int words = sizeof(vobj)/sizeof(vector_type);
  static std::vector<cshiftVector<scalar_object> >  send_buf_extract; send_buf_extract.resize(Nsimd);
  static std::vector<cshiftVector<scalar_object> >  recv_buf_extract; recv_buf_extract.resize(Nsimd);
  scalar_object *  recv_buf_extract_mpi;
  scalar_object *  send_buf_extract_mpi;
  for(int s=0;s<Nsimd;s++){
    send_buf_extract[s].resize(buffer_size);
    recv_buf_extract[s].resize(buffer_size);
  }
  int bytes = buffer_size*sizeof(scalar_object);
  ExtractPointerArray<scalar_object>  pointers(Nsimd); // 
  ExtractPointerArray<scalar_object> rpointers(Nsimd); // received pointers
  ///////////////////////////////////////////
  // Work out what to send where
  ///////////////////////////////////////////
  int cb    = (cbmask==0x2)? Odd : Even;
  int sshift= grid->CheckerBoardShiftForCB(rhs.Checkerboard(),dimension,shift,cb);
  // loop over outer coord planes orthog to dim
  for(int x=0;x<rd;x++){       
    // FIXME call local permute copy if none are offnode.
    for(int i=0;i<Nsimd;i++){       
      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++){
      int inner_bit = (Nsimd>>(permute_type+1));
      int ic= (i&inner_bit)? 1:0;
      int my_coor          = rd*ic + x;
      int nbr_coor         = my_coor+sshift;
      int nbr_proc = ((nbr_coor)/ld) % pd;// relative shift in processors
      int nbr_ic   = (nbr_coor%ld)/rd;    // inner coord of peer
      int nbr_ox   = (nbr_coor%rd);       // outer coord of peer
      int nbr_lane = (i&(~inner_bit));
      int recv_from_rank;
      int xmit_to_rank;
      if (nbr_ic) nbr_lane|=inner_bit;
      assert (sx == nbr_ox);
      if(nbr_proc){
 	grid->ShiftedRanks(dimension,nbr_proc,xmit_to_rank,recv_from_rank); 
 	tcomms-=usecond();
 	//	grid->Barrier();
 	send_buf_extract_mpi = &send_buf_extract[nbr_lane][0];
 	recv_buf_extract_mpi = &recv_buf_extract[i][0];
 	grid->SendToRecvFrom((void *)send_buf_extract_mpi,
 			     xmit_to_rank,
 			     (void *)recv_buf_extract_mpi,
 			     recv_from_rank,
 			     bytes);
 	xbytes+=bytes;
 	//	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 "<<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)
 {
  typedef typename vobj::vector_type vector_type;
  typedef typename vobj::scalar_type scalar_type;
  GridBase *grid=rhs.Grid();
  Lattice<vobj> temp(rhs.Grid());
  int fd              = rhs.Grid()->_fdimensions[dimension];
  int rd              = rhs.Grid()->_rdimensions[dimension];
  int pd              = rhs.Grid()->_processors[dimension];
  int simd_layout     = rhs.Grid()->_simd_layout[dimension];
  int comm_dim        = rhs.Grid()->_processors[dimension] >1 ;
  assert(simd_layout==1);
  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);
  static cshiftVector<vobj> recv_buf_v; recv_buf_v.resize(buffer_size);
  vobj *send_buf;
  vobj *recv_buf;
  {
    grid->ShmBufferFreeAll();
    size_t bytes = buffer_size*sizeof(vobj);
    send_buf=(vobj *)grid->ShmBufferMalloc(bytes);
    recv_buf=(vobj *)grid->ShmBufferMalloc(bytes);
  }
  int cb= (cbmask==0x2)? Odd : Even;
  int sshift= rhs.Grid()->CheckerBoardShiftForCB(rhs.Checkerboard(),dimension,shift,cb);
  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;
      if (cbmask != 0x3) words=words>>1;
      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;
      int xmit_to_rank;
      grid->ShiftedRanks(dimension,comm_proc,xmit_to_rank,recv_from_rank);
      tcomms-=usecond();
      //      grid->Barrier();
      acceleratorCopyDeviceToDevice((void *)&send_buf_v[0],(void *)&send_buf[0],bytes);
      grid->SendToRecvFrom((void *)&send_buf[0],
 			   xmit_to_rank,
 			   (void *)&recv_buf[0],
 			   recv_from_rank,
 			   bytes);
      xbytes+=bytes;
      acceleratorCopyDeviceToDevice((void *)&recv_buf[0],(void *)&recv_buf_v[0],bytes);
      //      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)
 {
  GridBase *grid=rhs.Grid();
  const int Nsimd = grid->Nsimd();
  typedef typename vobj::vector_type vector_type;
  typedef typename vobj::scalar_object scalar_object;
  typedef typename vobj::scalar_type scalar_type;
  int fd = grid->_fdimensions[dimension];
  int rd = grid->_rdimensions[dimension];
  int ld = grid->_ldimensions[dimension];
  int pd = grid->_processors[dimension];
  int simd_layout     = grid->_simd_layout[dimension];
  int comm_dim        = grid->_processors[dimension] >1 ;
  //std::cout << "Cshift_comms_simd dim "<< dimension << " fd "<<fd<<" rd "<<rd
  //    << " ld "<<ld<<" pd " << pd<<" simd_layout "<<simd_layout 
  //    << " comm_dim " << comm_dim << " cbmask " << cbmask <<std::endl;
  assert(comm_dim==1);
  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);
  ///////////////////////////////////////////////
  // Simd direction uses an extract/merge pair
  ///////////////////////////////////////////////
  int buffer_size = grid->_slice_nblock[dimension]*grid->_slice_block[dimension];
  //  int words = sizeof(vobj)/sizeof(vector_type);
  static std::vector<cshiftVector<scalar_object> >  send_buf_extract; send_buf_extract.resize(Nsimd);
  static std::vector<cshiftVector<scalar_object> >  recv_buf_extract; recv_buf_extract.resize(Nsimd);
  scalar_object *  recv_buf_extract_mpi;
  scalar_object *  send_buf_extract_mpi;
  {
    size_t bytes = sizeof(scalar_object)*buffer_size;
    grid->ShmBufferFreeAll();
    send_buf_extract_mpi = (scalar_object *)grid->ShmBufferMalloc(bytes);
    recv_buf_extract_mpi = (scalar_object *)grid->ShmBufferMalloc(bytes);
  }
  for(int s=0;s<Nsimd;s++){
    send_buf_extract[s].resize(buffer_size);
    recv_buf_extract[s].resize(buffer_size);
  }
  int bytes = buffer_size*sizeof(scalar_object);
  ExtractPointerArray<scalar_object>  pointers(Nsimd); // 
  ExtractPointerArray<scalar_object> rpointers(Nsimd); // received pointers
  ///////////////////////////////////////////
  // Work out what to send where
  ///////////////////////////////////////////
  int cb    = (cbmask==0x2)? Odd : Even;
  int sshift= grid->CheckerBoardShiftForCB(rhs.Checkerboard(),dimension,shift,cb);
  // loop over outer coord planes orthog to dim
  for(int x=0;x<rd;x++){       
    // FIXME call local permute copy if none are offnode.
    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++){
      int inner_bit = (Nsimd>>(permute_type+1));
      int ic= (i&inner_bit)? 1:0;
      int my_coor          = rd*ic + x;
      int nbr_coor         = my_coor+sshift;
      int nbr_proc = ((nbr_coor)/ld) % pd;// relative shift in processors
      int nbr_ic   = (nbr_coor%ld)/rd;    // inner coord of peer
      int nbr_ox   = (nbr_coor%rd);       // outer coord of peer
      int nbr_lane = (i&(~inner_bit));
      int recv_from_rank;
      int xmit_to_rank;
      if (nbr_ic) nbr_lane|=inner_bit;
      assert (sx == nbr_ox);
      if(nbr_proc){
 	grid->ShiftedRanks(dimension,nbr_proc,xmit_to_rank,recv_from_rank); 
 	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,
 			     xmit_to_rank,
 			     (void *)recv_buf_extract_mpi,
 			     recv_from_rank,
 			     bytes);
 	acceleratorCopyDeviceToDevice((void *)recv_buf_extract_mpi,(void *)&recv_buf_extract[i][0],bytes);
 	xbytes+=bytes;
 	//	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); 
 #endif
--- a/Grid/cshift/Cshift_none.h
+++ b/Grid/cshift/Cshift_none.h
@@ -1,4 +1,4 @@
-    /*************************************************************************************
+/*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
@@ -23,17 +23,18 @@ Author: Peter Boyle <paboyle@ph.ed.ac.uk>
    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 */
+/*  END LEGAL */
 #ifndef _GRID_CSHIFT_NONE_H_
 #define _GRID_CSHIFT_NONE_H_
-namespace Grid {
+NAMESPACE_BEGIN(Grid);
 template<class vobj> Lattice<vobj> Cshift(const Lattice<vobj> &rhs,int dimension,int shift)
 {
-  Lattice<vobj> ret(rhs._grid);
+  Lattice<vobj> ret(rhs.Grid());
-  ret.checkerboard = rhs._grid->CheckerBoardDestination(rhs.checkerboard,shift,dimension);
+  ret.Checkerboard() = rhs.Grid()->CheckerBoardDestination(rhs.Checkerboard(),shift,dimension);
  Cshift_local(ret,rhs,dimension,shift);
  return ret;
 }
-}
+NAMESPACE_END(Grid);
 #endif
--- a/Grid/cshift/Cshift_table.cc
+++ b/Grid/cshift/Cshift_table.cc
@@ -0,0 +1,5 @@
 #include <Grid/GridCore.h>       
 NAMESPACE_BEGIN(Grid);
 std::vector<std::pair<int,int> > Cshift_table; 
 commVector<std::pair<int,int> > Cshift_table_device; 
 NAMESPACE_END(Grid);
--- a/Grid/json/json.hpp
+++ b/Grid/json/json.hpp
--- a/lib/lattice/Lattice_reality.h
+++ b/lib/lattice/Lattice_reality.h
@@ -2,13 +2,11 @@
    Grid physics library, www.github.com/paboyle/Grid 
-    Source file: ./lib/lattice/Lattice_reality.h
+    Source file: ./lib/Lattice.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>
    This program is free software; you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
@@ -27,31 +25,26 @@ Author: neo <cossu@post.kek.jp>
    See the full license in the file "LICENSE" in the top level distribution directory
    *************************************************************************************/
    /*  END LEGAL */
-#ifndef GRID_LATTICE_REALITY_H
+#pragma once
-#define GRID_LATTICE_REALITY_H
+#include <Grid/lattice/Lattice_view.h>
-
+#include <Grid/lattice/Lattice_base.h>
-
+#include <Grid/lattice/Lattice_conformable.h>
-// FIXME .. this is the sector of the code 
+#include <Grid/lattice/Lattice_ET.h>
-// I am most worried about the directions
+#include <Grid/lattice/Lattice_arith.h>
-// The choice of burying complex in the SIMD
+#include <Grid/lattice/Lattice_trace.h>
-// is making the use of "real" and "imag" very cumbersome
+#include <Grid/lattice/Lattice_transpose.h>
-
+#include <Grid/lattice/Lattice_local.h>
-namespace Grid {
+#include <Grid/lattice/Lattice_reduction.h>
-
+#include <Grid/lattice/Lattice_crc.h>
-    template<class vobj> inline Lattice<vobj> adj(const Lattice<vobj> &lhs){
+#include <Grid/lattice/Lattice_peekpoke.h>
-        Lattice<vobj> ret(lhs._grid);
+#include <Grid/lattice/Lattice_reality.h>
-	parallel_for(int ss=0;ss<lhs._grid->oSites();ss++){
+#include <Grid/lattice/Lattice_real_imag.h>
-            ret._odata[ss] = adj(lhs._odata[ss]);
+#include <Grid/lattice/Lattice_comparison_utils.h>
-        }
+#include <Grid/lattice/Lattice_comparison.h>
-        return ret;
+#include <Grid/lattice/Lattice_coordinate.h>
-    };
+//#include <Grid/lattice/Lattice_where.h>
-
+#include <Grid/lattice/Lattice_rng.h>
-    template<class vobj> inline Lattice<vobj> conjugate(const Lattice<vobj> &lhs){
+#include <Grid/lattice/Lattice_unary.h>
-        Lattice<vobj> ret(lhs._grid);
+#include <Grid/lattice/Lattice_transfer.h>
-	parallel_for(int ss=0;ss<lhs._grid->oSites();ss++){
+#include <Grid/lattice/Lattice_basis.h>
-	  ret._odata[ss] = conjugate(lhs._odata[ss]);
+#include <Grid/lattice/PaddedCell.h>
        }
        return ret;
    };
 }
 #endif
--- a/Grid/lattice/Lattice_ET.h
+++ b/Grid/lattice/Lattice_ET.h
@@ -0,0 +1,534 @@
 /*************************************************************************************
 Grid physics library, www.github.com/paboyle/Grid
 Source file: ./lib/lattice/Lattice_ET.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: Christoph Lehner <christoph@lhnr.de
 This program is free software; you can redistribute it and/or modify
 it under the terms of the GNU General Public License as published by
 the Free Software Foundation; either version 2 of the License, or
 (at your option) any later version.
 This program is distributed in the hope that it will be useful,
 but WITHOUT ANY WARRANTY; without even the implied warranty of
 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 GNU General Public License for more details.
 You should have received a copy of the GNU General Public License along
 with this program; if not, write to the Free Software Foundation, Inc.,
 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
 See the full license in the file "LICENSE" in the top level distribution
 directory
 *************************************************************************************/
 			   /*  END LEGAL */
 #ifndef GRID_LATTICE_ET_H
 #define GRID_LATTICE_ET_H
 #include <iostream>
 #include <tuple>
 #include <typeinfo>
 #include <vector>
 NAMESPACE_BEGIN(Grid);
 ////////////////////////////////////////////////////
 // Predicated where support
 ////////////////////////////////////////////////////
 #ifdef GRID_SIMT
 // drop to scalar in SIMT; cleaner in fact
 template <class iobj, class vobj, class robj>
 accelerator_inline vobj predicatedWhere(const iobj &predicate, 
 					const vobj &iftrue, 
 					const robj &iffalse) 
 {
  Integer mask = TensorRemove(predicate);
  typename std::remove_const<vobj>::type ret= iffalse;
  if (mask) ret=iftrue;
  return ret;
 }
 #else
 template <class iobj, class vobj, class robj>
 accelerator_inline vobj predicatedWhere(const iobj &predicate, 
 					const vobj &iftrue, 
 					const robj &iffalse) 
 {
  typename std::remove_const<vobj>::type ret;
  typedef typename vobj::scalar_object scalar_object;
  //  typedef typename vobj::scalar_type scalar_type;
  typedef typename vobj::vector_type vector_type;
  const int Nsimd = vobj::vector_type::Nsimd();
  ExtractBuffer<Integer> mask(Nsimd);
  ExtractBuffer<scalar_object> truevals(Nsimd);
  ExtractBuffer<scalar_object> falsevals(Nsimd);
  extract(iftrue, truevals);
  extract(iffalse, falsevals);
  extract<vInteger, Integer>(TensorRemove(predicate), mask);
  for (int s = 0; s < Nsimd; s++) {
    if (mask[s]) falsevals[s] = truevals[s];
  }
  merge(ret, falsevals);
  return ret;
 }
 #endif
 /////////////////////////////////////////////////////
 //Specialization of getVectorType for lattices
 /////////////////////////////////////////////////////
 template<typename T>
 struct getVectorType<Lattice<T> >{
  typedef typename Lattice<T>::vector_object type;
 };
 ////////////////////////////////////////////
 //--  recursive evaluation of expressions; --
 // handle leaves of syntax tree
 ///////////////////////////////////////////////////
 template<class sobj,
  typename std::enable_if<!is_lattice<sobj>::value&&!is_lattice_expr<sobj>::value,sobj>::type * = nullptr> 
 accelerator_inline 
 sobj eval(const uint64_t ss, const sobj &arg)
 {
  return arg;
 }
 template <class lobj> accelerator_inline 
 auto eval(const uint64_t ss, const LatticeView<lobj> &arg) -> decltype(arg(ss))
 {
  return arg(ss);
 }
 ////////////////////////////////////////////
 //--  recursive evaluation of expressions; --
 // whole vector return, used only for expression return type inference
 ///////////////////////////////////////////////////
 template<class sobj> accelerator_inline 
 sobj vecEval(const uint64_t ss, const sobj &arg)
 {
  return arg;
 }
 template <class lobj> accelerator_inline 
 const lobj & vecEval(const uint64_t ss, const LatticeView<lobj> &arg) 
 {
  return arg[ss];
 }
 ///////////////////////////////////////////////////
 // handle nodes in syntax tree- eval one operand
 // vecEval needed (but never called as all expressions offloaded) to infer the return type
 // in SIMT contexts of closure.
 ///////////////////////////////////////////////////
 template <typename Op, typename T1> accelerator_inline 
 auto vecEval(const uint64_t ss, const LatticeUnaryExpression<Op, T1> &expr)  
  -> decltype(expr.op.func( vecEval(ss, expr.arg1)))
 {
  return expr.op.func( vecEval(ss, expr.arg1) );
 }
 // vecEval two operands
 template <typename Op, typename T1, typename T2> accelerator_inline
 auto vecEval(const uint64_t ss, const LatticeBinaryExpression<Op, T1, T2> &expr)  
  -> decltype(expr.op.func( vecEval(ss,expr.arg1),vecEval(ss,expr.arg2)))
 {
  return expr.op.func( vecEval(ss,expr.arg1), vecEval(ss,expr.arg2) );
 }
 // vecEval three operands
 template <typename Op, typename T1, typename T2, typename T3> accelerator_inline
 auto vecEval(const uint64_t ss, const LatticeTrinaryExpression<Op, T1, T2, T3> &expr)  
  -> decltype(expr.op.func(vecEval(ss, expr.arg1), vecEval(ss, expr.arg2), vecEval(ss, expr.arg3)))
 {
  return expr.op.func(vecEval(ss, expr.arg1), vecEval(ss, expr.arg2), vecEval(ss, expr.arg3));
 }
 ///////////////////////////////////////////////////
 // handle nodes in syntax tree- eval one operand coalesced
 ///////////////////////////////////////////////////
 template <typename Op, typename T1> accelerator_inline 
 auto eval(const uint64_t ss, const LatticeUnaryExpression<Op, T1> &expr)  
  -> decltype(expr.op.func( eval(ss, expr.arg1)))
 {
  return expr.op.func( eval(ss, expr.arg1) );
 }
 // eval two operands
 template <typename Op, typename T1, typename T2> accelerator_inline
 auto eval(const uint64_t ss, const LatticeBinaryExpression<Op, T1, T2> &expr)  
  -> decltype(expr.op.func( eval(ss,expr.arg1),eval(ss,expr.arg2)))
 {
  return expr.op.func( eval(ss,expr.arg1), eval(ss,expr.arg2) );
 }
 // eval three operands
 template <typename Op, typename T1, typename T2, typename T3> accelerator_inline
 auto eval(const uint64_t ss, const LatticeTrinaryExpression<Op, T1, T2, T3> &expr)  
  -> decltype(expr.op.func(eval(ss, expr.arg1), 
 			   eval(ss, expr.arg2), 
 			   eval(ss, expr.arg3)))
 {
 #ifdef GRID_SIMT
  // Handles Nsimd (vInteger) != Nsimd(ComplexD)
  typedef decltype(vecEval(ss, expr.arg2)) rvobj;
  typedef typename std::remove_reference<rvobj>::type vobj;
  const int Nsimd = vobj::vector_type::Nsimd();
  auto vpred = vecEval(ss,expr.arg1);
  ExtractBuffer<Integer> mask(Nsimd);
  extract<vInteger, Integer>(TensorRemove(vpred), mask);
  int s = acceleratorSIMTlane(Nsimd);
  return expr.op.func(mask[s],
 		      eval(ss, expr.arg2), 
 		      eval(ss, expr.arg3));
 #else
  return expr.op.func(eval(ss, expr.arg1),
 		      eval(ss, expr.arg2), 
 		      eval(ss, expr.arg3));
 #endif
 }
 //////////////////////////////////////////////////////////////////////////
 // Obtain the grid from an expression, ensuring conformable. This must follow a
 // tree recursion; must retain grid pointer in the LatticeView class which sucks
 // Use a different method, and make it void *.
 // Perhaps a conformable method.
 //////////////////////////////////////////////////////////////////////////
 template <class T1,typename std::enable_if<is_lattice<T1>::value, T1>::type * = nullptr>
 accelerator_inline void GridFromExpression(GridBase *&grid, const T1 &lat)  // Lattice leaf
 {
  lat.Conformable(grid);
 }
 template <class T1,typename std::enable_if<!is_lattice<T1>::value, T1>::type * = nullptr>
 accelerator_inline 
 void GridFromExpression(GridBase *&grid,const T1 &notlat)  // non-lattice leaf
 {}
 template <typename Op, typename T1>
 accelerator_inline 
 void GridFromExpression(GridBase *&grid,const LatticeUnaryExpression<Op, T1> &expr) 
 {
  GridFromExpression(grid, expr.arg1);  // recurse
 }
 template <typename Op, typename T1, typename T2>
 accelerator_inline 
 void GridFromExpression(GridBase *&grid, const LatticeBinaryExpression<Op, T1, T2> &expr) 
 {
  GridFromExpression(grid, expr.arg1);  // recurse
  GridFromExpression(grid, expr.arg2);
 }
 template <typename Op, typename T1, typename T2, typename T3>
 accelerator_inline 
 void GridFromExpression(GridBase *&grid, const LatticeTrinaryExpression<Op, T1, T2, T3> &expr) 
 {
  GridFromExpression(grid, expr.arg1);  // recurse
  GridFromExpression(grid, expr.arg2);  // recurse
  GridFromExpression(grid, expr.arg3);  // recurse
 }
 //////////////////////////////////////////////////////////////////////////
 // Obtain the CB from an expression, ensuring conformable. This must follow a
 // tree recursion
 //////////////////////////////////////////////////////////////////////////
 template <class T1,typename std::enable_if<is_lattice<T1>::value, T1>::type * = nullptr>
 inline void CBFromExpression(int &cb, const T1 &lat)  // Lattice leaf
 {
  if ((cb == Odd) || (cb == Even)) {
    assert(cb == lat.Checkerboard());
  }
  cb = lat.Checkerboard();
 }
 template <class T1,typename std::enable_if<!is_lattice<T1>::value, T1>::type * = nullptr>
 inline void CBFromExpression(int &cb, const T1 &notlat) {} // non-lattice leaf
 template <typename Op, typename T1> inline 
 void CBFromExpression(int &cb,const LatticeUnaryExpression<Op, T1> &expr) 
 {
  CBFromExpression(cb, expr.arg1);  // recurse AST
 }
 template <typename Op, typename T1, typename T2> inline 
 void CBFromExpression(int &cb,const LatticeBinaryExpression<Op, T1, T2> &expr) 
 {
  CBFromExpression(cb, expr.arg1);  // recurse AST
  CBFromExpression(cb, expr.arg2);  // recurse AST
 }
 template <typename Op, typename T1, typename T2, typename T3>
 inline void CBFromExpression(int &cb, const LatticeTrinaryExpression<Op, T1, T2, T3> &expr) 
 {
  CBFromExpression(cb, expr.arg1);  // recurse AST
  CBFromExpression(cb, expr.arg2);  // recurse AST
  CBFromExpression(cb, expr.arg3);  // recurse AST
 }
 //////////////////////////////////////////////////////////////////////////
 // ViewOpen
 //////////////////////////////////////////////////////////////////////////
 template <class T1,typename std::enable_if<is_lattice<T1>::value, T1>::type * = nullptr>
 inline void ExpressionViewOpen(T1 &lat)  // Lattice leaf
 {
  lat.ViewOpen(AcceleratorRead);
 }
 template <class T1,typename std::enable_if<!is_lattice<T1>::value, T1>::type * = nullptr>
  inline void ExpressionViewOpen(T1 &notlat) {}
 template <typename Op, typename T1> inline 
 void ExpressionViewOpen(LatticeUnaryExpression<Op, T1> &expr) 
 {  
  ExpressionViewOpen(expr.arg1); // recurse AST
 }
 template <typename Op, typename T1, typename T2> inline 
 void ExpressionViewOpen(LatticeBinaryExpression<Op, T1, T2> &expr) 
 {
  ExpressionViewOpen(expr.arg1);  // recurse AST
  ExpressionViewOpen(expr.arg2);  // rrecurse AST
 }
 template <typename Op, typename T1, typename T2, typename T3>
 inline void ExpressionViewOpen(LatticeTrinaryExpression<Op, T1, T2, T3> &expr) 
 {
  ExpressionViewOpen(expr.arg1);  // recurse AST
  ExpressionViewOpen(expr.arg2);  // recurse AST
  ExpressionViewOpen(expr.arg3);  // recurse AST
 }
 //////////////////////////////////////////////////////////////////////////
 // ViewClose
 //////////////////////////////////////////////////////////////////////////
 template <class T1,typename std::enable_if<is_lattice<T1>::value, T1>::type * = nullptr>
 inline void ExpressionViewClose( T1 &lat)  // Lattice leaf
 {
  lat.ViewClose();
 }
 template <class T1,typename std::enable_if<!is_lattice<T1>::value, T1>::type * = nullptr>
 inline void ExpressionViewClose(T1 &notlat) {}
 template <typename Op, typename T1> inline 
 void ExpressionViewClose(LatticeUnaryExpression<Op, T1> &expr) 
 {  
  ExpressionViewClose(expr.arg1); // recurse AST
 }
 template <typename Op, typename T1, typename T2> inline 
 void ExpressionViewClose(LatticeBinaryExpression<Op, T1, T2> &expr) 
 {
  ExpressionViewClose(expr.arg1);  // recurse AST
  ExpressionViewClose(expr.arg2);  // recurse AST
 }
 template <typename Op, typename T1, typename T2, typename T3>
 inline void ExpressionViewClose(LatticeTrinaryExpression<Op, T1, T2, T3> &expr) 
 {
  ExpressionViewClose(expr.arg1);  // recurse AST
  ExpressionViewClose(expr.arg2);  // recurse AST
  ExpressionViewClose(expr.arg3);  // recurse AST
 }
 ////////////////////////////////////////////
 // Unary operators and funcs
 ////////////////////////////////////////////
 #define GridUnopClass(name, ret)					\
  struct name {								\
    template<class _arg> static auto accelerator_inline func(const _arg a) -> decltype(ret) { return ret; } \
  };
 GridUnopClass(UnarySub, -a);
 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));
 GridUnopClass(UnarySqrt, sqrt(a));
 GridUnopClass(UnarySin, sin(a));
 GridUnopClass(UnaryCos, cos(a));
 GridUnopClass(UnaryAsin, asin(a));
 GridUnopClass(UnaryAcos, acos(a));
 GridUnopClass(UnaryLog, log(a));
 GridUnopClass(UnaryExp, exp(a));
 ////////////////////////////////////////////
 // Binary operators
 ////////////////////////////////////////////
 #define GridBinOpClass(name, combination)			\
  struct name {							\
    template <class _left, class _right>			\
    static auto accelerator_inline				\
    func(const _left &lhs, const _right &rhs)			\
      -> decltype(combination) const				\
    {								\
      return combination;					\
    }								\
  };
 GridBinOpClass(BinaryAdd, lhs + rhs);
 GridBinOpClass(BinarySub, lhs - rhs);
 GridBinOpClass(BinaryMul, lhs *rhs);
 GridBinOpClass(BinaryDiv, lhs /rhs);
 GridBinOpClass(BinaryAnd, lhs &rhs);
 GridBinOpClass(BinaryOr, lhs | rhs);
 GridBinOpClass(BinaryAndAnd, lhs &&rhs);
 GridBinOpClass(BinaryOrOr, lhs || rhs);
 ////////////////////////////////////////////////////
 // Trinary conditional op
 ////////////////////////////////////////////////////
 #define GridTrinOpClass(name, combination)				\
  struct name {								\
    template <class _predicate,class _left, class _right>		\
    static auto accelerator_inline					\
    func(const _predicate &pred, const _left &lhs, const _right &rhs)	\
      -> decltype(combination) const					\
    {									\
      return combination;						\
    }									\
  };
 GridTrinOpClass(TrinaryWhere,
 		(predicatedWhere<
 		 typename std::remove_reference<_predicate>::type, 
 		 typename std::remove_reference<_left>::type,
 		 typename std::remove_reference<_right>::type>(pred, lhs,rhs)));
 ////////////////////////////////////////////
 // Operator syntactical glue
 ////////////////////////////////////////////
 #define GRID_UNOP(name)   name
 #define GRID_BINOP(name)  name
 #define GRID_TRINOP(name) name
 #define GRID_DEF_UNOP(op, name)						\
  template <typename T1, typename std::enable_if<is_lattice<T1>::value||is_lattice_expr<T1>::value,T1>::type * = nullptr> \
  inline auto op(const T1 &arg) ->decltype(LatticeUnaryExpression<GRID_UNOP(name),T1>(GRID_UNOP(name)(), arg)) \
  {									\
    return     LatticeUnaryExpression<GRID_UNOP(name),T1>(GRID_UNOP(name)(), arg); \
  }
 #define GRID_BINOP_LEFT(op, name)					\
  template <typename T1, typename T2,					\
            typename std::enable_if<is_lattice<T1>::value||is_lattice_expr<T1>::value,T1>::type * = nullptr> \
  inline auto op(const T1 &lhs, const T2 &rhs)				\
    ->decltype(LatticeBinaryExpression<GRID_BINOP(name),T1,T2>(GRID_BINOP(name)(),lhs,rhs)) \
  {									\
    return     LatticeBinaryExpression<GRID_BINOP(name),T1,T2>(GRID_BINOP(name)(),lhs,rhs);\
  }
 #define GRID_BINOP_RIGHT(op, name)					\
  template <typename T1, typename T2,					\
            typename std::enable_if<!is_lattice<T1>::value&&!is_lattice_expr<T1>::value,T1>::type * = nullptr, \
            typename std::enable_if< is_lattice<T2>::value|| is_lattice_expr<T2>::value,T2>::type * = nullptr> \
  inline auto op(const T1 &lhs, const T2 &rhs)				\
    ->decltype(LatticeBinaryExpression<GRID_BINOP(name),T1,T2>(GRID_BINOP(name)(),lhs, rhs)) \
  {									\
    return     LatticeBinaryExpression<GRID_BINOP(name),T1,T2>(GRID_BINOP(name)(),lhs, rhs); \
  }
 #define GRID_DEF_BINOP(op, name)		\
  GRID_BINOP_LEFT(op, name);			\
  GRID_BINOP_RIGHT(op, name);
 #define GRID_DEF_TRINOP(op, name)					\
  template <typename T1, typename T2, typename T3>			\
  inline auto op(const T1 &pred, const T2 &lhs, const T3 &rhs)		\
    ->decltype(LatticeTrinaryExpression<GRID_TRINOP(name),T1,T2,T3>(GRID_TRINOP(name)(),pred, lhs, rhs)) \
  {									\
    return LatticeTrinaryExpression<GRID_TRINOP(name),T1,T2,T3>(GRID_TRINOP(name)(),pred, lhs, rhs); \
  }
 ////////////////////////
 // Operator definitions
 ////////////////////////
 GRID_DEF_UNOP(operator-, UnarySub);
 GRID_DEF_UNOP(Not, UnaryNot);
 GRID_DEF_UNOP(operator!, UnaryNot);
 //GRID_DEF_UNOP(adj, UnaryAdj);
 //GRID_DEF_UNOP(conjugate, UnaryConj);
 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
                               // abs-fabs-dabs-labs thing
 GRID_DEF_UNOP(sqrt, UnarySqrt);
 GRID_DEF_UNOP(sin, UnarySin);
 GRID_DEF_UNOP(cos, UnaryCos);
 GRID_DEF_UNOP(asin, UnaryAsin);
 GRID_DEF_UNOP(acos, UnaryAcos);
 GRID_DEF_UNOP(log, UnaryLog);
 GRID_DEF_UNOP(exp, UnaryExp);
 GRID_DEF_BINOP(operator+, BinaryAdd);
 GRID_DEF_BINOP(operator-, BinarySub);
 GRID_DEF_BINOP(operator*, BinaryMul);
 GRID_DEF_BINOP(operator/, BinaryDiv);
 GRID_DEF_BINOP(operator&, BinaryAnd);
 GRID_DEF_BINOP(operator|, BinaryOr);
 GRID_DEF_BINOP(operator&&, BinaryAndAnd);
 GRID_DEF_BINOP(operator||, BinaryOrOr);
 GRID_DEF_TRINOP(where, TrinaryWhere);
 /////////////////////////////////////////////////////////////
 // Closure convenience to force expression to evaluate
 /////////////////////////////////////////////////////////////
 template <class Op, class T1>
 auto closure(const LatticeUnaryExpression<Op, T1> &expr)
  -> Lattice<typename std::remove_const<decltype(expr.op.func(vecEval(0, expr.arg1)))>::type > 
 {
  Lattice<typename std::remove_const<decltype(expr.op.func(vecEval(0, expr.arg1)))>::type > ret(expr);
  return ret;
 }
 template <class Op, class T1, class T2>
 auto closure(const LatticeBinaryExpression<Op, T1, T2> &expr)
  -> Lattice<typename std::remove_const<decltype(expr.op.func(vecEval(0, expr.arg1),vecEval(0, expr.arg2)))>::type >
 {
  Lattice<typename std::remove_const<decltype(expr.op.func(vecEval(0, expr.arg1),vecEval(0, expr.arg2)))>::type > ret(expr);
  return ret;
 }
 template <class Op, class T1, class T2, class T3>
 auto closure(const LatticeTrinaryExpression<Op, T1, T2, T3> &expr)
  -> Lattice<typename std::remove_const<decltype(expr.op.func(vecEval(0, expr.arg1),
 				   vecEval(0, expr.arg2),
 				   vecEval(0, expr.arg3)))>::type >
 {
  Lattice<typename std::remove_const<decltype(expr.op.func(vecEval(0, expr.arg1),
 				vecEval(0, expr.arg2),
 			        vecEval(0, expr.arg3)))>::type >  ret(expr);
  return ret;
 }
 #define EXPRESSION_CLOSURE(function)					\
  template<class Expression,typename std::enable_if<is_lattice_expr<Expression>::value,void>::type * = nullptr> \
    auto function(Expression &expr) -> decltype(function(closure(expr))) \
  {									\
    return function(closure(expr));					\
  }
 #undef GRID_UNOP
 #undef GRID_BINOP
 #undef GRID_TRINOP
 #undef GRID_DEF_UNOP
 #undef GRID_DEF_BINOP
 #undef GRID_DEF_TRINOP
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/lattice/Lattice_arith.h
+++ b/Grid/lattice/Lattice_arith.h
@@ -0,0 +1,311 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./lib/lattice/Lattice_arith.h
    Copyright (C) 2015
 Author: Peter Boyle <paboyle@ph.ed.ac.uk>
 Author: Christoph Lehner <christoph@lhnr.de>
    This program is free software; you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation; either version 2 of the License, or
    (at your option) any later version.
    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.
    You should have received a copy of the GNU General Public License along
    with this program; if not, write to the Free Software Foundation, Inc.,
    51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
    See the full license in the file "LICENSE" in the top level distribution directory
 *************************************************************************************/
 /*  END LEGAL */
 #ifndef GRID_LATTICE_ARITH_H
 #define GRID_LATTICE_ARITH_H
 NAMESPACE_BEGIN(Grid);
 //////////////////////////////////////////////////////////////////////////////////////////////////////
 //  avoid copy back routines for mult, mac, sub, add
 //////////////////////////////////////////////////////////////////////////////////////////////////////
 template<class obj1,class obj2,class obj3> inline
 void mult(Lattice<obj1> &ret,const Lattice<obj2> &lhs,const Lattice<obj3> &rhs){
  GRID_TRACE("mult");
  ret.Checkerboard() = lhs.Checkerboard();
  autoView( ret_v , ret, AcceleratorWrite);
  autoView( lhs_v , lhs, AcceleratorRead);
  autoView( rhs_v , rhs, AcceleratorRead);
  conformable(ret,rhs);
  conformable(lhs,rhs);
  accelerator_for(ss,lhs_v.size(),obj1::Nsimd(),{
    decltype(coalescedRead(obj1())) tmp;
    auto lhs_t = lhs_v(ss);
    auto rhs_t = rhs_v(ss);
    mult(&tmp,&lhs_t,&rhs_t);
    coalescedWrite(ret_v[ss],tmp);
  });
 }
 template<class obj1,class obj2,class obj3> inline
 void mac(Lattice<obj1> &ret,const Lattice<obj2> &lhs,const Lattice<obj3> &rhs){
  GRID_TRACE("mac");
  ret.Checkerboard() = lhs.Checkerboard();
  conformable(ret,rhs);
  conformable(lhs,rhs);
  autoView( ret_v , ret, AcceleratorWrite);
  autoView( lhs_v , lhs, AcceleratorRead);
  autoView( rhs_v , rhs, AcceleratorRead);
  accelerator_for(ss,lhs_v.size(),obj1::Nsimd(),{
    auto lhs_t=lhs_v(ss);
    auto rhs_t=rhs_v(ss);
    auto tmp  =ret_v(ss);
    mac(&tmp,&lhs_t,&rhs_t);
    coalescedWrite(ret_v[ss],tmp);
  });
 }
 template<class obj1,class obj2,class obj3> inline
 void sub(Lattice<obj1> &ret,const Lattice<obj2> &lhs,const Lattice<obj3> &rhs){
  GRID_TRACE("sub");
  ret.Checkerboard() = lhs.Checkerboard();
  conformable(ret,rhs);
  conformable(lhs,rhs);
  autoView( ret_v , ret, AcceleratorWrite);
  autoView( lhs_v , lhs, AcceleratorRead);
  autoView( rhs_v , rhs, AcceleratorRead);
  accelerator_for(ss,lhs_v.size(),obj1::Nsimd(),{
    decltype(coalescedRead(obj1())) tmp;
    auto lhs_t=lhs_v(ss);
    auto rhs_t=rhs_v(ss);
    sub(&tmp,&lhs_t,&rhs_t);
    coalescedWrite(ret_v[ss],tmp);
  });
 }
 template<class obj1,class obj2,class obj3> inline
 void add(Lattice<obj1> &ret,const Lattice<obj2> &lhs,const Lattice<obj3> &rhs){
  GRID_TRACE("add");
  ret.Checkerboard() = lhs.Checkerboard();
  conformable(ret,rhs);
  conformable(lhs,rhs);
  autoView( ret_v , ret, AcceleratorWrite);
  autoView( lhs_v , lhs, AcceleratorRead);
  autoView( rhs_v , rhs, AcceleratorRead);
  accelerator_for(ss,lhs_v.size(),obj1::Nsimd(),{
    decltype(coalescedRead(obj1())) tmp;
    auto lhs_t=lhs_v(ss);
    auto rhs_t=rhs_v(ss);
    add(&tmp,&lhs_t,&rhs_t);
    coalescedWrite(ret_v[ss],tmp);
  });
 }
 //////////////////////////////////////////////////////////////////////////////////////////////////////
 //  avoid copy back routines for mult, mac, sub, add
 //////////////////////////////////////////////////////////////////////////////////////////////////////
 template<class obj1,class obj2,class obj3> inline
 void mult(Lattice<obj1> &ret,const Lattice<obj2> &lhs,const obj3 &rhs){
  GRID_TRACE("mult");
  ret.Checkerboard() = lhs.Checkerboard();
  conformable(lhs,ret);
  autoView( ret_v , ret, AcceleratorWrite);
  autoView( lhs_v , lhs, AcceleratorRead);
  accelerator_for(ss,lhs_v.size(),obj1::Nsimd(),{
    decltype(coalescedRead(obj1())) tmp;
    mult(&tmp,&lhs_v(ss),&rhs);
    coalescedWrite(ret_v[ss],tmp);
  });
 }
 template<class obj1,class obj2,class obj3> inline
 void mac(Lattice<obj1> &ret,const Lattice<obj2> &lhs,const obj3 &rhs){
  GRID_TRACE("mac");
  ret.Checkerboard() = lhs.Checkerboard();
  conformable(ret,lhs);
  autoView( ret_v , ret, AcceleratorWrite);
  autoView( lhs_v , lhs, AcceleratorRead);
  accelerator_for(ss,lhs_v.size(),obj1::Nsimd(),{
    auto tmp  =ret_v(ss);
    auto lhs_t=lhs_v(ss);
    mac(&tmp,&lhs_t,&rhs);
    coalescedWrite(ret_v[ss],tmp);
  });
 }
 template<class obj1,class obj2,class obj3> inline
 void sub(Lattice<obj1> &ret,const Lattice<obj2> &lhs,const obj3 &rhs){
  GRID_TRACE("sub");
  ret.Checkerboard() = lhs.Checkerboard();
  conformable(ret,lhs);
  autoView( ret_v , ret, AcceleratorWrite);
  autoView( lhs_v , lhs, AcceleratorRead);
  accelerator_for(ss,lhs_v.size(),obj1::Nsimd(),{
    decltype(coalescedRead(obj1())) tmp;
    auto lhs_t=lhs_v(ss);
    sub(&tmp,&lhs_t,&rhs);
    coalescedWrite(ret_v[ss],tmp);
  });
 }
 template<class obj1,class obj2,class obj3> inline
 void add(Lattice<obj1> &ret,const Lattice<obj2> &lhs,const obj3 &rhs){
  GRID_TRACE("add");
  ret.Checkerboard() = lhs.Checkerboard();
  conformable(lhs,ret);
  autoView( ret_v , ret, AcceleratorWrite);
  autoView( lhs_v , lhs, AcceleratorRead);
  accelerator_for(ss,lhs_v.size(),obj1::Nsimd(),{
    decltype(coalescedRead(obj1())) tmp;
    auto lhs_t=lhs_v(ss);
    add(&tmp,&lhs_t,&rhs);
    coalescedWrite(ret_v[ss],tmp);
  });
 }
 //////////////////////////////////////////////////////////////////////////////////////////////////////
 //  avoid copy back routines for mult, mac, sub, add
 //////////////////////////////////////////////////////////////////////////////////////////////////////
 template<class obj1,class obj2,class obj3> inline
 void mult(Lattice<obj1> &ret,const obj2 &lhs,const Lattice<obj3> &rhs){
  GRID_TRACE("mult");
  ret.Checkerboard() = rhs.Checkerboard();
  conformable(ret,rhs);
  autoView( ret_v , ret, AcceleratorWrite);
  autoView( rhs_v , lhs, AcceleratorRead);
  accelerator_for(ss,rhs_v.size(),obj1::Nsimd(),{
    decltype(coalescedRead(obj1())) tmp;
    auto rhs_t=rhs_v(ss);
    mult(&tmp,&lhs,&rhs_t);
    coalescedWrite(ret_v[ss],tmp);
  });
 }
 template<class obj1,class obj2,class obj3> inline
 void mac(Lattice<obj1> &ret,const obj2 &lhs,const Lattice<obj3> &rhs){
  GRID_TRACE("mac");
  ret.Checkerboard() = rhs.Checkerboard();
  conformable(ret,rhs);
  autoView( ret_v , ret, AcceleratorWrite);
  autoView( rhs_v , lhs, AcceleratorRead);
  accelerator_for(ss,rhs_v.size(),obj1::Nsimd(),{
    auto tmp  =ret_v(ss);
    auto rhs_t=rhs_v(ss);
    mac(&tmp,&lhs,&rhs_t);
    coalescedWrite(ret_v[ss],tmp);
  });
 }
 template<class obj1,class obj2,class obj3> inline
 void sub(Lattice<obj1> &ret,const obj2 &lhs,const Lattice<obj3> &rhs){
  GRID_TRACE("sub");
  ret.Checkerboard() = rhs.Checkerboard();
  conformable(ret,rhs);
  autoView( ret_v , ret, AcceleratorWrite);
  autoView( rhs_v , lhs, AcceleratorRead);
  accelerator_for(ss,rhs_v.size(),obj1::Nsimd(),{
    decltype(coalescedRead(obj1())) tmp;
    auto rhs_t=rhs_v(ss);
    sub(&tmp,&lhs,&rhs_t);
    coalescedWrite(ret_v[ss],tmp);
  });
 }
 template<class obj1,class obj2,class obj3> inline
 void add(Lattice<obj1> &ret,const obj2 &lhs,const Lattice<obj3> &rhs){
  GRID_TRACE("add");
  ret.Checkerboard() = rhs.Checkerboard();
  conformable(ret,rhs);
  autoView( ret_v , ret, AcceleratorWrite);
  autoView( rhs_v , lhs, AcceleratorRead);
  accelerator_for(ss,rhs_v.size(),obj1::Nsimd(),{
    decltype(coalescedRead(obj1())) tmp;
    auto rhs_t=rhs_v(ss);
    add(&tmp,&lhs,&rhs_t);
    coalescedWrite(ret_v[ss],tmp);
  });
 }
 template<class sobj,class vobj> inline
 void axpy(Lattice<vobj> &ret,sobj a,const Lattice<vobj> &x,const Lattice<vobj> &y){
  GRID_TRACE("axpy");
  ret.Checkerboard() = x.Checkerboard();
  conformable(ret,x);
  conformable(x,y);
  autoView( ret_v , ret, AcceleratorWrite);
  autoView( x_v , x, AcceleratorRead);
  autoView( y_v , y, AcceleratorRead);
  accelerator_for(ss,x_v.size(),vobj::Nsimd(),{
    auto tmp = a*coalescedRead(x_v[ss])+coalescedRead(y_v[ss]);
    coalescedWrite(ret_v[ss],tmp);
  });
 }
 template<class sobj,class vobj> inline
 void axpby(Lattice<vobj> &ret,sobj a,sobj b,const Lattice<vobj> &x,const Lattice<vobj> &y){
  GRID_TRACE("axpby");
  ret.Checkerboard() = x.Checkerboard();
  conformable(ret,x);
  conformable(x,y);
  autoView( ret_v , ret, AcceleratorWrite);
  autoView( x_v , x, AcceleratorRead);
  autoView( y_v , y, AcceleratorRead);
  accelerator_for(ss,x_v.size(),vobj::Nsimd(),{
    auto tmp = a*x_v(ss)+b*y_v(ss);
    coalescedWrite(ret_v[ss],tmp);
  });
 }
 template<class sobj,class vobj> inline
 RealD axpy_norm(Lattice<vobj> &ret,sobj a,const Lattice<vobj> &x,const Lattice<vobj> &y)
 {
  GRID_TRACE("axpy_norm");
    return axpy_norm_fast(ret,a,x,y);
 }
 template<class sobj,class vobj> inline
 RealD axpby_norm(Lattice<vobj> &ret,sobj a,sobj b,const Lattice<vobj> &x,const Lattice<vobj> &y)
 {
  GRID_TRACE("axpby_norm");
    return axpby_norm_fast(ret,a,b,x,y);
 }
 /// Trace product
 template<class obj> auto traceProduct(const Lattice<obj> &rhs_1,const Lattice<obj> &rhs_2)
  -> Lattice<decltype(trace(obj()))>
 {
  typedef decltype(trace(obj())) robj;
  Lattice<robj> ret_i(rhs_1.Grid());
  autoView( rhs1 , rhs_1, AcceleratorRead);
  autoView( rhs2 , rhs_2, AcceleratorRead);
  autoView( ret , ret_i, AcceleratorWrite);
  ret.Checkerboard() = rhs_1.Checkerboard();
  accelerator_for(ss,rhs1.size(),obj::Nsimd(),{
      coalescedWrite(ret[ss],traceProduct(rhs1(ss),rhs2(ss)));
  });
  return ret_i;
 }
 template<class obj1,class obj2> auto traceProduct(const Lattice<obj1> &rhs_1,const obj2 &rhs2)
  -> Lattice<decltype(trace(obj1()))>
 {
  typedef decltype(trace(obj1())) robj;
  Lattice<robj> ret_i(rhs_1.Grid());
  autoView( rhs1 , rhs_1, AcceleratorRead);
  autoView( ret , ret_i, AcceleratorWrite);
  ret.Checkerboard() = rhs_1.Checkerboard();
  accelerator_for(ss,rhs1.size(),obj1::Nsimd(),{
      coalescedWrite(ret[ss],traceProduct(rhs1(ss),rhs2));
  });
  return ret_i;
 }
 template<class obj1,class obj2> auto traceProduct(const obj2 &rhs_2,const Lattice<obj1> &rhs_1)
  -> Lattice<decltype(trace(obj1()))>
 {
  return traceProduct(rhs_1,rhs_2);
 }
 NAMESPACE_END(Grid);
 #endif
--- a/Grid/lattice/Lattice_base.h
+++ b/Grid/lattice/Lattice_base.h
@@ -0,0 +1,382 @@
 /*************************************************************************************
 Grid physics library, www.github.com/paboyle/Grid
 Source file: ./lib/lattice/Lattice_base.h
 Copyright (C) 2015
 Author: Azusa Yamaguchi <ayamaguc@staffmail.ed.ac.uk>
 Author: Peter Boyle <paboyle@ph.ed.ac.uk>
 Author: paboyle <paboyle@ph.ed.ac.uk>
 Author: Christoph Lehner <christoph@lhnr.de>
 This program is free software; you can redistribute it and/or modify
 it under the terms of the GNU General Public License as published by
 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 
 #define STREAMING_STORES
 NAMESPACE_BEGIN(Grid);
 extern int GridCshiftPermuteMap[4][16];
 /////////////////////////////////////////////////////////////////////////////////////////
 // The real lattice class, with normal copy and assignment semantics.
 // This contains extra (host resident) grid pointer data that may be accessed by host code
 /////////////////////////////////////////////////////////////////////////////////////////
 template<class vobj>
 class Lattice : public LatticeAccelerator<vobj>
 {
 public:
  GridBase *Grid(void) const { return this->_grid; }
  ///////////////////////////////////////////////////
  // Member types
  ///////////////////////////////////////////////////
  typedef typename vobj::scalar_type scalar_type;
  typedef typename vobj::vector_type vector_type;
  typedef typename vobj::scalar_object scalar_object;
  typedef vobj vector_object;
 private:
  void dealloc(void)
  {
    if( this->_odata_size ) {
      alignedAllocator<vobj> alloc;
      alloc.deallocate(this->_odata,this->_odata_size);
      this->_odata=nullptr;
      this->_odata_size=0;
    }
  }
  void resize(uint64_t size)
  {
    if ( this->_odata_size != size ) {
      alignedAllocator<vobj> alloc;
      dealloc();
      this->_odata_size = size;
      if ( size )
 	this->_odata      = alloc.allocate(this->_odata_size);
      else 
 	this->_odata      = nullptr;
    }
  }
 public:
  /////////////////////////////////////////////////////////////////////////////////
  // Can use to make accelerator dirty without copy from host ; useful for temporaries "dont care" prev contents
  /////////////////////////////////////////////////////////////////////////////////
  void SetViewMode(ViewMode mode) {
    LatticeView<vobj> accessor(*( (LatticeAccelerator<vobj> *) this),mode);
    accessor.ViewClose();
  }
  // Helper function to print the state of this object in the AccCache
  void PrintCacheState(void)
  {
    MemoryManager::PrintState(this->_odata);
  }
  /////////////////////////////////////////////////////////////////////////////////
  // Return a view object that may be dereferenced in site loops.
  // The view is trivially copy constructible and may be copied to an accelerator device
  // in device lambdas
  /////////////////////////////////////////////////////////////////////////////////
  LatticeView<vobj> View (ViewMode mode) const 
  {
    LatticeView<vobj> accessor(*( (LatticeAccelerator<vobj> *) this),mode);
    return accessor;
  }
  ~Lattice() { 
    if ( this->_odata_size ) {
      dealloc();
    }
   }
  ////////////////////////////////////////////////////////////////////////////////
  // Expression Template closure support
  ////////////////////////////////////////////////////////////////////////////////
  template <typename Op, typename T1> inline Lattice<vobj> & operator=(const LatticeUnaryExpression<Op,T1> &expr)
  {
    GRID_TRACE("ExpressionTemplateEval");
    GridBase *egrid(nullptr);
    GridFromExpression(egrid,expr);
    assert(egrid!=nullptr);
    conformable(this->_grid,egrid);
    int cb=-1;
    CBFromExpression(cb,expr);
    assert( (cb==Odd) || (cb==Even));
    this->checkerboard=cb;
    auto exprCopy = expr;
    ExpressionViewOpen(exprCopy);
    auto me  = View(AcceleratorWriteDiscard);
    accelerator_for(ss,me.size(),vobj::Nsimd(),{
      auto tmp = eval(ss,exprCopy);
      coalescedWrite(me[ss],tmp);
    });
    me.ViewClose();
    ExpressionViewClose(exprCopy);
    return *this;
  }
  template <typename Op, typename T1,typename T2> inline Lattice<vobj> & operator=(const LatticeBinaryExpression<Op,T1,T2> &expr)
  {
    GRID_TRACE("ExpressionTemplateEval");
    GridBase *egrid(nullptr);
    GridFromExpression(egrid,expr);
    assert(egrid!=nullptr);
    conformable(this->_grid,egrid);
    int cb=-1;
    CBFromExpression(cb,expr);
    assert( (cb==Odd) || (cb==Even));
    this->checkerboard=cb;
    auto exprCopy = expr;
    ExpressionViewOpen(exprCopy);
    auto me  = View(AcceleratorWriteDiscard);
    accelerator_for(ss,me.size(),vobj::Nsimd(),{
      auto tmp = eval(ss,exprCopy);
      coalescedWrite(me[ss],tmp);
    });
    me.ViewClose();
    ExpressionViewClose(exprCopy);
    return *this;
  }
  template <typename Op, typename T1,typename T2,typename T3> inline Lattice<vobj> & operator=(const LatticeTrinaryExpression<Op,T1,T2,T3> &expr)
  {
    GRID_TRACE("ExpressionTemplateEval");
    GridBase *egrid(nullptr);
    GridFromExpression(egrid,expr);
    assert(egrid!=nullptr);
    conformable(this->_grid,egrid);
    int cb=-1;
    CBFromExpression(cb,expr);
    assert( (cb==Odd) || (cb==Even));
    this->checkerboard=cb;
    auto exprCopy = expr;
    ExpressionViewOpen(exprCopy);
    auto me  = View(AcceleratorWriteDiscard);
    accelerator_for(ss,me.size(),vobj::Nsimd(),{
      auto tmp = eval(ss,exprCopy);
      coalescedWrite(me[ss],tmp);
    });
    me.ViewClose();
    ExpressionViewClose(exprCopy);
    return *this;
  }
  //GridFromExpression is tricky to do
  template<class Op,class T1>
  Lattice(const LatticeUnaryExpression<Op,T1> & expr) {
    this->_grid = nullptr;
    GridFromExpression(this->_grid,expr);
    assert(this->_grid!=nullptr);
    int cb=-1;
    CBFromExpression(cb,expr);
    assert( (cb==Odd) || (cb==Even));
    this->checkerboard=cb;
    resize(this->_grid->oSites());
    *this = expr;
  }
  template<class Op,class T1, class T2>
  Lattice(const LatticeBinaryExpression<Op,T1,T2> & expr) {
    this->_grid = nullptr;
    GridFromExpression(this->_grid,expr);
    assert(this->_grid!=nullptr);
    int cb=-1;
    CBFromExpression(cb,expr);
    assert( (cb==Odd) || (cb==Even));
    this->checkerboard=cb;
    resize(this->_grid->oSites());
    *this = expr;
  }
  template<class Op,class T1, class T2, class T3>
  Lattice(const LatticeTrinaryExpression<Op,T1,T2,T3> & expr) {
    this->_grid = nullptr;
    GridFromExpression(this->_grid,expr);
    assert(this->_grid!=nullptr);
    int cb=-1;
    CBFromExpression(cb,expr);
    assert( (cb==Odd) || (cb==Even));
    this->checkerboard=cb;
    resize(this->_grid->oSites());
    *this = expr;
  }
  template<class sobj> inline Lattice<vobj> & operator = (const sobj & r){
    auto me  = View(CpuWrite);
    thread_for(ss,me.size(),{
 	me[ss]= r;
    });
    me.ViewClose();
    return *this;
  }
  //////////////////////////////////////////////////////////////////
  // Follow rule of five, with Constructor requires "grid" passed
  // to user defined constructor
  ///////////////////////////////////////////
  // user defined constructor
  ///////////////////////////////////////////
  Lattice(GridBase *grid,ViewMode mode=AcceleratorWriteDiscard) { 
    this->_grid = grid;
    resize(this->_grid->oSites());
    assert((((uint64_t)&this->_odata[0])&0xF) ==0);
    this->checkerboard=0;
    SetViewMode(mode);
  }
  //  virtual ~Lattice(void) = default;
  void reset(GridBase* grid) {
    if (this->_grid != grid) {
      this->_grid = grid;
      this->resize(grid->oSites());
      this->checkerboard = 0;
    }
  }
  ///////////////////////////////////////////
  // copy constructor
  ///////////////////////////////////////////
  Lattice(const Lattice& r){ 
    this->_grid = r.Grid();
    resize(this->_grid->oSites());
    *this = r;
  }
  ///////////////////////////////////////////
  // move constructor
  ///////////////////////////////////////////
  Lattice(Lattice && r){ 
    this->_grid = r.Grid();
    this->_odata      = r._odata;
    this->_odata_size = r._odata_size;
    this->checkerboard= r.Checkerboard();
    r._odata      = nullptr;
    r._odata_size = 0;
  }
  ///////////////////////////////////////////
  // assignment template
  ///////////////////////////////////////////
  template<class robj> inline Lattice<vobj> & operator = (const Lattice<robj> & r){
    typename std::enable_if<!std::is_same<robj,vobj>::value,int>::type i=0;
    conformable(*this,r);
    this->checkerboard = r.Checkerboard();
    auto him= r.View(AcceleratorRead);
    auto me =   View(AcceleratorWriteDiscard);
    accelerator_for(ss,me.size(),vobj::Nsimd(),{
      coalescedWrite(me[ss],him(ss));
    });
    me.ViewClose();    him.ViewClose();
    return *this;
  }
  ///////////////////////////////////////////
  // Copy assignment 
  ///////////////////////////////////////////
  inline Lattice<vobj> & operator = (const Lattice<vobj> & r){
    this->checkerboard = r.Checkerboard();
    conformable(*this,r);
    auto him= r.View(AcceleratorRead);
    auto me =   View(AcceleratorWriteDiscard);
    accelerator_for(ss,me.size(),vobj::Nsimd(),{
      coalescedWrite(me[ss],him(ss));
    });
    me.ViewClose();    him.ViewClose();
    return *this;
  }
  ///////////////////////////////////////////
  // Move assignment possible if same type
  ///////////////////////////////////////////
  inline Lattice<vobj> & operator = (Lattice<vobj> && r){
    resize(0); // deletes if appropriate
    this->_grid       = r.Grid();
    this->_odata      = r._odata;
    this->_odata_size = r._odata_size;
    this->checkerboard= r.Checkerboard();
    r._odata      = nullptr;
    r._odata_size = 0;
    return *this;
  }
  /////////////////////////////////////////////////////////////////////////////
  // *=,+=,-= operators inherit behvour from correspond */+/- operation
  /////////////////////////////////////////////////////////////////////////////
  template<class T> inline Lattice<vobj> &operator *=(const T &r) {
    *this = (*this)*r;
    return *this;
  }
  template<class T> inline Lattice<vobj> &operator -=(const T &r) {
    *this = (*this)-r;
    return *this;
  }
  template<class T> inline Lattice<vobj> &operator +=(const T &r) {
    *this = (*this)+r;
    return *this;
  }
  friend inline void swap(Lattice &l, Lattice &r) { 
    conformable(l,r);
    LatticeAccelerator<vobj> tmp;
    LatticeAccelerator<vobj> *lp = (LatticeAccelerator<vobj> *)&l;
    LatticeAccelerator<vobj> *rp = (LatticeAccelerator<vobj> *)&r;
    tmp = *lp;    *lp=*rp;    *rp=tmp;
  }
 }; // class Lattice
 template<class vobj> std::ostream& operator<< (std::ostream& stream, const Lattice<vobj> &o){
  typedef typename vobj::scalar_object sobj;
  for(int g=0;g<o.Grid()->_gsites;g++){
    Coordinate gcoor;
    o.Grid()->GlobalIndexToGlobalCoor(g,gcoor);
    sobj ss;
    peekSite(ss,o,gcoor);
    stream<<"[";
    for(int d=0;d<gcoor.size();d++){
      stream<<gcoor[d];
      if(d!=gcoor.size()-1) stream<<",";
    }
    stream<<"]\t";
    stream<<ss<<std::endl;
  }
  return stream;
 }
 NAMESPACE_END(Grid);
--- a/Grid/lattice/Lattice_basis.h
+++ b/Grid/lattice/Lattice_basis.h
@@ -0,0 +1,248 @@
 /*************************************************************************************
 Grid physics library, www.github.com/paboyle/Grid
 Source file: ./lib/lattice/Lattice_basis.h
 Copyright (C) 2015
 Author: Peter Boyle <paboyle@ph.ed.ac.uk>
 Author: paboyle <paboyle@ph.ed.ac.uk>
 Author: Christoph Lehner <christoph@lhnr.de>
 This program is free software; you can redistribute it and/or modify
 it under the terms of the GNU General Public License as published by
 the Free Software Foundation; either version 2 of the License, or
 (at your option) any later version.
 This program is distributed in the hope that it will be useful,
 but WITHOUT ANY WARRANTY; without even the implied warranty of
 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 GNU General Public License for more details.
 You should have received a copy of the GNU General Public License along
 with this program; if not, write to the Free Software Foundation, Inc.,
 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
 See the full license in the file "LICENSE" in the top level distribution
 directory
 *************************************************************************************/
 			   /*  END LEGAL */
 #pragma once
 NAMESPACE_BEGIN(Grid);
 template<class Field>
 void basisOrthogonalize(std::vector<Field> &basis,Field &w,int k) 
 {
  // If assume basis[j] are already orthonormal,
  // can take all inner products in parallel saving 2x bandwidth
  // Save 3x bandwidth on the second line of loop.
  // perhaps 2.5x speed up.
  // 2x overall in Multigrid Lanczos  
  for(int j=0; j<k; ++j){
    auto ip = innerProduct(basis[j],w);
    w = w - ip*basis[j];
  }
 }
 template<class VField, class Matrix>
 void basisRotate(VField &basis,Matrix& Qt,int j0, int j1, int k0,int k1,int Nm) 
 {
  typedef decltype(basis[0]) Field;
  typedef decltype(basis[0].View(AcceleratorRead)) View;
  Vector<View> basis_v; basis_v.reserve(basis.size());
  typedef typename std::remove_reference<decltype(basis_v[0][0])>::type vobj;
  typedef typename std::remove_reference<decltype(Qt(0,0))>::type Coeff_t;
  GridBase* grid = basis[0].Grid();
  for(int k=0;k<basis.size();k++){
    basis_v.push_back(basis[k].View(AcceleratorWrite));
  }
 #if ( !(defined(GRID_CUDA) || defined(GRID_HIP) || defined(GRID_SYCL)) )
  int max_threads = thread_max();
  Vector < vobj > Bt(Nm * max_threads);
  thread_region
    {
      vobj* B = &Bt[Nm * thread_num()];
      thread_for_in_region(ss, grid->oSites(),{
 	  for(int j=j0; j<j1; ++j) B[j]=0.;
 	  for(int j=j0; j<j1; ++j){
 	    for(int k=k0; k<k1; ++k){
 	      B[j] +=Qt(j,k) * basis_v[k][ss];
 	    }
 	  }
 	  for(int j=j0; j<j1; ++j){
 	    basis_v[j][ss] = B[j];
 	  }
 	});
    }
 #else
  View *basis_vp = &basis_v[0];
  int nrot = j1-j0;
  if (!nrot) // edge case not handled gracefully by Cuda
    return;
  uint64_t oSites   =grid->oSites();
  uint64_t siteBlock=(grid->oSites()+nrot-1)/nrot; // Maximum 1 additional vector overhead
  Vector <vobj> Bt(siteBlock * nrot); 
  auto Bp=&Bt[0];
  // GPU readable copy of matrix
  Vector<Coeff_t> Qt_jv(Nm*Nm);
  Coeff_t *Qt_p = & Qt_jv[0];
  thread_for(i,Nm*Nm,{
      int j = i/Nm;
      int k = i%Nm;
      Qt_p[i]=Qt(j,k);
  });
  // Block the loop to keep storage footprint down
  for(uint64_t s=0;s<oSites;s+=siteBlock){
    // remaining work in this block
    int ssites=MIN(siteBlock,oSites-s);
    // zero out the accumulators
    accelerator_for(ss,siteBlock*nrot,vobj::Nsimd(),{
 	decltype(coalescedRead(Bp[ss])) z;
 	z=Zero();
 	coalescedWrite(Bp[ss],z);
      });
    accelerator_for(sj,ssites*nrot,vobj::Nsimd(),{
 	int j =sj%nrot;
 	int jj  =j0+j;
 	int ss =sj/nrot;
 	int sss=ss+s;
 	for(int k=k0; k<k1; ++k){
 	  auto tmp = coalescedRead(Bp[ss*nrot+j]);
 	  coalescedWrite(Bp[ss*nrot+j],tmp+ Qt_p[jj*Nm+k] * coalescedRead(basis_vp[k][sss]));
 	}
      });
    accelerator_for(sj,ssites*nrot,vobj::Nsimd(),{
 	int j =sj%nrot;
 	int jj  =j0+j;
 	int ss =sj/nrot;
 	int sss=ss+s;
 	coalescedWrite(basis_vp[jj][sss],coalescedRead(Bp[ss*nrot+j]));
      });
  }
 #endif
  for(int k=0;k<basis.size();k++) basis_v[k].ViewClose();
 }
 // Extract a single rotated vector
 template<class Field>
 void basisRotateJ(Field &result,std::vector<Field> &basis,Eigen::MatrixXd& Qt,int j, int k0,int k1,int Nm) 
 {
  typedef decltype(basis[0].View(AcceleratorRead)) View;
  typedef typename Field::vector_object vobj;
  GridBase* grid = basis[0].Grid();
  result.Checkerboard() = basis[0].Checkerboard();
  Vector<View> basis_v; basis_v.reserve(basis.size());
  for(int k=0;k<basis.size();k++){
    basis_v.push_back(basis[k].View(AcceleratorRead));
  }
  vobj zz=Zero();
  Vector<double> Qt_jv(Nm);
  double * Qt_j = & Qt_jv[0];
  for(int k=0;k<Nm;++k) Qt_j[k]=Qt(j,k);
  auto basis_vp=& basis_v[0];
  autoView(result_v,result,AcceleratorWrite);
  accelerator_for(ss, grid->oSites(),vobj::Nsimd(),{
    vobj zzz=Zero();
    auto B=coalescedRead(zzz);
    for(int k=k0; k<k1; ++k){
      B +=Qt_j[k] * coalescedRead(basis_vp[k][ss]);
    }
    coalescedWrite(result_v[ss], B);
  });
  for(int k=0;k<basis.size();k++) basis_v[k].ViewClose();
 }
 template<class Field>
 void basisReorderInPlace(std::vector<Field> &_v,std::vector<RealD>& sort_vals, std::vector<int>& idx) 
 {
  int vlen = idx.size();
  assert(vlen>=1);
  assert(vlen<=sort_vals.size());
  assert(vlen<=_v.size());
  for (size_t i=0;i<vlen;i++) {
    if (idx[i] != i) {
      //////////////////////////////////////
      // idx[i] is a table of desired sources giving a permutation.
      // Swap v[i] with v[idx[i]].
      // Find  j>i for which _vnew[j] = _vold[i],
      // track the move idx[j] => idx[i]
      // track the move idx[i] => i
      //////////////////////////////////////
      size_t j;
      for (j=i;j<idx.size();j++)
 	if (idx[j]==i)
 	  break;
      assert(idx[i] > i);     assert(j!=idx.size());      assert(idx[j]==i);
      swap(_v[i],_v[idx[i]]); // should use vector move constructor, no data copy
      std::swap(sort_vals[i],sort_vals[idx[i]]);
      idx[j] = idx[i];
      idx[i] = i;
    }
  }
 }
 inline std::vector<int> basisSortGetIndex(std::vector<RealD>& sort_vals) 
 {
  std::vector<int> idx(sort_vals.size());
  std::iota(idx.begin(), idx.end(), 0);
  // sort indexes based on comparing values in v
  std::sort(idx.begin(), idx.end(), [&sort_vals](int i1, int i2) {
    return ::fabs(sort_vals[i1]) < ::fabs(sort_vals[i2]);
  });
  return idx;
 }
 template<class Field>
 void basisSortInPlace(std::vector<Field> & _v,std::vector<RealD>& sort_vals, bool reverse) 
 {
  std::vector<int> idx = basisSortGetIndex(sort_vals);
  if (reverse)
    std::reverse(idx.begin(), idx.end());
  basisReorderInPlace(_v,sort_vals,idx);
 }
 // PAB: faster to compute the inner products first then fuse loops.
 // If performance critical can improve.
 template<class Field>
 void basisDeflate(const std::vector<Field> &_v,const std::vector<RealD>& eval,const Field& src_orig,Field& result) {
  result = Zero();
  assert(_v.size()==eval.size());
  int N = (int)_v.size();
  for (int i=0;i<N;i++) {
    Field& tmp = _v[i];
    axpy(result,TensorRemove(innerProduct(tmp,src_orig)) / eval[i],tmp,result);
  }
 }
 NAMESPACE_END(Grid);
--- a/Grid/lattice/Lattice_comparison.h
+++ b/Grid/lattice/Lattice_comparison.h
@@ -0,0 +1,179 @@
 /*************************************************************************************
    Grid physics library, www.github.com/paboyle/Grid 
    Source file: ./lib/lattice/Lattice_comparison.h
    Copyright (C) 2015
 Author: Azusa Yamaguchi <ayamaguc@staffmail.ed.ac.uk>
 Author: Peter Boyle <paboyle@ph.ed.ac.uk>
    This program is free software; you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation; either version 2 of the License, or
    (at your option) any later version.
    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.
    You should have received a copy of the GNU General Public License along
    with this program; if not, write to the Free Software Foundation, Inc.,
    51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
    See the full license in the file "LICENSE" in the top level distribution directory
 *************************************************************************************/
 /*  END LEGAL */
 #ifndef GRID_LATTICE_COMPARISON_H
 #define GRID_LATTICE_COMPARISON_H
 NAMESPACE_BEGIN(Grid);
 //////////////////////////////////////////////////////////////////////////
 // relational operators
 // 
 // Support <,>,<=,>=,==,!=
 //
 //Query supporting bitwise &, |, ^, !
 //Query supporting logical &&, ||, 
 //////////////////////////////////////////////////////////////////////////
 typedef iScalar<vInteger> vPredicate ;
 //////////////////////////////////////////////////////////////////////////
 // compare lattice to lattice
 //////////////////////////////////////////////////////////////////////////
 template<class vfunctor,class lobj,class robj>  
 inline Lattice<vPredicate> LLComparison(vfunctor op,const Lattice<lobj> &lhs,const Lattice<robj> &rhs)
 {
  Lattice<vPredicate> ret(rhs.Grid());
  autoView( lhs_v, lhs, CpuRead);
  autoView( rhs_v, rhs, CpuRead);
  autoView( ret_v, ret, CpuWrite);
  thread_for( ss, rhs_v.size(), {
      ret_v[ss]=op(lhs_v[ss],rhs_v[ss]);
  });
  return ret;
 }
 //////////////////////////////////////////////////////////////////////////
 // compare lattice to scalar
 //////////////////////////////////////////////////////////////////////////
 template<class vfunctor,class lobj,class robj> 
 inline Lattice<vPredicate> LSComparison(vfunctor op,const Lattice<lobj> &lhs,const robj &rhs)
 {
  Lattice<vPredicate> ret(lhs.Grid());
  autoView( lhs_v, lhs, CpuRead);
  autoView( ret_v, ret, CpuWrite);
  thread_for( ss, lhs_v.size(), {
    ret_v[ss]=op(lhs_v[ss],rhs);
  });
  return ret;
 }
 //////////////////////////////////////////////////////////////////////////
 // compare scalar to lattice
 //////////////////////////////////////////////////////////////////////////
 template<class vfunctor,class lobj,class robj> 
 inline Lattice<vPredicate> SLComparison(vfunctor op,const lobj &lhs,const Lattice<robj> &rhs)
 {
  Lattice<vPredicate> ret(rhs.Grid());
  autoView( rhs_v, rhs, CpuRead);
  autoView( ret_v, ret, CpuWrite);
  thread_for( ss, rhs_v.size(), {
    ret_v[ss]=op(lhs,rhs_v[ss]);
  });
  return ret;
 }
 //////////////////////////////////////////////////////////////////////////
 // Map to functors
 //////////////////////////////////////////////////////////////////////////
 // Less than
 template<class lobj,class robj>
 inline Lattice<vPredicate> operator < (const Lattice<lobj> & lhs, const Lattice<robj> & rhs) {
  return LLComparison(vlt<lobj,robj>(),lhs,rhs);
 }
 template<class lobj,class robj>
 inline Lattice<vPredicate> operator < (const Lattice<lobj> & lhs, const robj & rhs) {
  return LSComparison(vlt<lobj,robj>(),lhs,rhs);
 }
 template<class lobj,class robj>
 inline Lattice<vPredicate> operator < (const lobj & lhs, const Lattice<robj> & rhs) {
  return SLComparison(vlt<lobj,robj>(),lhs,rhs);
 }
 // Less than equal
 template<class lobj,class robj>
 inline Lattice<vPredicate> operator <= (const Lattice<lobj> & lhs, const Lattice<robj> & rhs) {
  return LLComparison(vle<lobj,robj>(),lhs,rhs);
 }
 template<class lobj,class robj>
 inline Lattice<vPredicate> operator <= (const Lattice<lobj> & lhs, const robj & rhs) {
  return LSComparison(vle<lobj,robj>(),lhs,rhs);
 }
 template<class lobj,class robj>
 inline Lattice<vPredicate> operator <= (const lobj & lhs, const Lattice<robj> & rhs) {
  return SLComparison(vle<lobj,robj>(),lhs,rhs);
 }
 // Greater than 
 template<class lobj,class robj>
 inline Lattice<vPredicate> operator > (const Lattice<lobj> & lhs, const Lattice<robj> & rhs) {
  return LLComparison(vgt<lobj,robj>(),lhs,rhs);
 }
 template<class lobj,class robj>
 inline Lattice<vPredicate> operator > (const Lattice<lobj> & lhs, const robj & rhs) {
  return LSComparison(vgt<lobj,robj>(),lhs,rhs);
 }
 template<class lobj,class robj>
 inline Lattice<vPredicate> operator > (const lobj & lhs, const Lattice<robj> & rhs) {
  return SLComparison(vgt<lobj,robj>(),lhs,rhs);
 }
 // Greater than equal
 template<class lobj,class robj>
 inline Lattice<vPredicate> operator >= (const Lattice<lobj> & lhs, const Lattice<robj> & rhs) {
  return LLComparison(vge<lobj,robj>(),lhs,rhs);
 }
 template<class lobj,class robj>
 inline Lattice<vPredicate> operator >= (const Lattice<lobj> & lhs, const robj & rhs) {
  return LSComparison(vge<lobj,robj>(),lhs,rhs);
 }
 template<class lobj,class robj>
 inline Lattice<vPredicate> operator >= (const lobj & lhs, const Lattice<robj> & rhs) {
  return SLComparison(vge<lobj,robj>(),lhs,rhs);
 }
 // equal
 template<class lobj,class robj>
 inline Lattice<vPredicate> operator == (const Lattice<lobj> & lhs, const Lattice<robj> & rhs) {
  return LLComparison(veq<lobj,robj>(),lhs,rhs);
 }
 template<class lobj,class robj>
 inline Lattice<vPredicate> operator == (const Lattice<lobj> & lhs, const robj & rhs) {
  return LSComparison(veq<lobj,robj>(),lhs,rhs);
 }
 template<class lobj,class robj>
 inline Lattice<vPredicate> operator == (const lobj & lhs, const Lattice<robj> & rhs) {
  return SLComparison(veq<lobj,robj>(),lhs,rhs);
 }
 // not equal
 template<class lobj,class robj>
 inline Lattice<vPredicate> operator != (const Lattice<lobj> & lhs, const Lattice<robj> & rhs) {
  return LLComparison(vne<lobj,robj>(),lhs,rhs);
 }
 template<class lobj,class robj>
 inline Lattice<vPredicate> operator != (const Lattice<lobj> & lhs, const robj & rhs) {
  return LSComparison(vne<lobj,robj>(),lhs,rhs);
 }
 template<class lobj,class robj>
 inline Lattice<vPredicate> operator != (const lobj & lhs, const Lattice<robj> & rhs) {
  return SLComparison(vne<lobj,robj>(),lhs,rhs);
 }
 NAMESPACE_END(Grid);
 #endif
--- a/Show More
+++ b/Show More