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Expression template engin
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lib/lattice/Grid_lattice_ET.h
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227
lib/lattice/Grid_lattice_ET.h
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#ifndef GRID_LATTICE_ET_H
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#define GRID_LATTICE_ET_H
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#include <iostream>
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#include <vector>
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#include <tuple>
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#include <typeinfo>
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namespace Grid {
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////////////////////////////////////////////
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// recursive evaluation of expressions; Could
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// switch to generic approach with variadics, a la
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// Antonin's Lat Sim but the repack to variadic with popped
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// from tuple is hideous; C++14 introduces std::make_index_sequence for this
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////////////////////////////////////////////
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//leaf eval of lattice ; should enable if protect using traits
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template <typename T> using is_lattice = std::is_base_of<LatticeBase,T >;
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template <typename T> using is_lattice_expr = std::is_base_of<LatticeExpressionBase,T >;
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template<class sobj>
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inline sobj eval(const unsigned int ss, const sobj &arg)
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{
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return arg;
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}
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template<class lobj>
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inline const lobj &eval(const unsigned int ss, const Lattice<lobj> &arg)
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{
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return arg._odata[ss];
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}
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// handle nodes in syntax tree
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template <typename Op, typename T1>
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auto inline eval(const unsigned int ss, const LatticeUnaryExpression<Op,T1 > &expr) // eval one operand
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-> decltype(expr.first.func(eval(ss,std::get<0>(expr.second))))
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{
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return expr.first.func(eval(ss,std::get<0>(expr.second)));
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}
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template <typename Op, typename T1, typename T2>
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auto inline eval(const unsigned int ss, const LatticeBinaryExpression<Op,T1,T2> &expr) // eval two operands
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-> decltype(expr.first.func(eval(ss,std::get<0>(expr.second)),eval(ss,std::get<1>(expr.second))))
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{
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return expr.first.func(eval(ss,std::get<0>(expr.second)),eval(ss,std::get<1>(expr.second)));
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}
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template <typename Op, typename T1, typename T2, typename T3>
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auto inline eval(const unsigned int ss, const LatticeTrinaryExpression<Op,T1,T2,T3 > &expr) // eval three operands
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-> decltype(expr.first.func(eval(ss,std::get<0>(expr.second)),eval(ss,std::get<1>(expr.second)),eval(ss,std::get<2>(expr.second))))
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{
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return expr.first.func(eval(ss,std::get<0>(expr.second)),eval(ss,std::get<1>(expr.second)),eval(ss,std::get<2>(expr.second)) );
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}
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//////////////////////////////////////////////////////////////////////////
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// Obtain the grid from an expression, ensuring conformable. This must follow a tree recursion
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//////////////////////////////////////////////////////////////////////////
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template<class T1, typename std::enable_if<is_lattice<T1>::value, T1>::type * =nullptr >
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inline void GridFromExpression(GridBase * &grid,const T1& lat) // Lattice leaf
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{
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if ( grid ) {
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conformable(grid,lat._grid);
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}
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grid=lat._grid;
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}
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template <typename Op, typename T1>
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inline void GridFromExpression(GridBase * &grid,const LatticeUnaryExpression<Op,T1 > &expr)
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{
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GridFromExpression(grid,std::get<0>(expr.second));// recurse
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}
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template <typename Op, typename T1, typename T2>
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inline void GridFromExpression(GridBase * &grid,const LatticeBinaryExpression<Op,T1,T2> &expr)
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{
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GridFromExpression(grid,std::get<0>(expr.second));// recurse
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GridFromExpression(grid,std::get<1>(expr.second));
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}
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template <typename Op, typename T1, typename T2, typename T3>
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inline void GridFromExpression( GridBase * &grid,const LatticeTrinaryExpression<Op,T1,T2,T3 > &expr)
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{
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GridFromExpression(grid,std::get<0>(expr.second));// recurse
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GridFromExpression(grid,std::get<1>(expr.second));
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GridFromExpression(grid,std::get<2>(expr.second));
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}
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template<class T1,typename std::enable_if<!is_lattice<T1>::value, T1>::type * = nullptr >
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inline void GridFromExpression(GridBase * &grid,const T1& notlat) // non-lattice leaf
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{
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}
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////////////////////////////////////////////
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// Unary operators and funcs
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////////////////////////////////////////////
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#define GridUnopClass(name,ret)\
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template <class arg> struct name\
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{\
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static auto inline func(const arg a)-> decltype(ret) { return ret; } \
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};
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GridUnopClass(UnarySub,-a);
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GridUnopClass(UnaryAdj,adj(a));
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GridUnopClass(UnaryConj,conj(a));
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GridUnopClass(UnaryTrace,trace(a));
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GridUnopClass(UnaryTranspose,transpose(a));
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////////////////////////////////////////////
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// Binary operators
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////////////////////////////////////////////
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#define GridBinOpClass(name,combination)\
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template <class left,class right>\
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struct name\
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{\
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static auto inline func(const left &lhs,const right &rhs)-> decltype(combination) const \
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{\
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return combination;\
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}\
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}
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GridBinOpClass(BinaryAdd,lhs+rhs);
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GridBinOpClass(BinarySub,lhs-rhs);
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GridBinOpClass(BinaryMul,lhs*rhs);
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////////////////////////////////////////////
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// Operator syntactical glue
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////////////////////////////////////////////
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#define GRID_UNOP(name) name<decltype(eval(0, arg))>
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#define GRID_BINOP(name) name<decltype(eval(0, lhs)), decltype(eval(0, rhs))>
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#define GRID_TRINOP(name) name<decltype(eval(0, pred)), decltype(eval(0, lhs)), decltype(eval(0, rhs))>
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#define GRID_DEF_UNOP(op, name)\
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template <typename T1,\
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typename std::enable_if<is_lattice<T1>::value||is_lattice_expr<T1>::value, T1>::type* = nullptr> inline auto op(const T1 &arg) \
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-> decltype(LatticeUnaryExpression<GRID_UNOP(name),const T1&>(std::make_pair(GRID_UNOP(name)(),std::forward_as_tuple(arg)))) \
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{ return LatticeUnaryExpression<GRID_UNOP(name), const T1 &>(std::make_pair(GRID_UNOP(name)(),std::forward_as_tuple(arg))); }
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#define GRID_BINOP_LEFT(op, name)\
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template <typename T1,typename T2,\
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typename std::enable_if<is_lattice<T1>::value||is_lattice_expr<T1>::value, T1>::type* = nullptr>\
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inline auto op(const T1 &lhs,const T2&rhs) \
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-> decltype(LatticeBinaryExpression<GRID_BINOP(name),const T1&,const T2 &>(std::make_pair(GRID_BINOP(name)(),\
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std::forward_as_tuple(lhs, rhs)))) \
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{\
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return LatticeBinaryExpression<GRID_BINOP(name), const T1 &, const T2 &>(std::make_pair(GRID_BINOP(name)(),\
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std::forward_as_tuple(lhs, rhs))); \
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}
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#define GRID_BINOP_RIGHT(op, name)\
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template <typename T1,typename T2,\
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typename std::enable_if<!is_lattice<T1>::value && !is_lattice_expr<T1>::value, T1>::type* = nullptr,\
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typename std::enable_if< is_lattice<T2>::value || is_lattice_expr<T2>::value, T2>::type* = nullptr> \
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inline auto op(const T1 &lhs,const T2&rhs) \
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-> decltype(LatticeBinaryExpression<GRID_BINOP(name),const T1&,const T2 &>(std::make_pair(GRID_BINOP(name)(),\
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std::forward_as_tuple(lhs, rhs)))) \
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{\
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return LatticeBinaryExpression<GRID_BINOP(name), const T1 &, const T2 &>(std::make_pair(GRID_BINOP(name)(),\
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std::forward_as_tuple(lhs, rhs))); \
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}
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#define GRID_DEF_BINOP(op, name)\
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GRID_BINOP_LEFT(op,name);\
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GRID_BINOP_RIGHT(op,name);
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#define GRID_DEF_TRINOP(op, name)\
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template <typename T1,typename T2,typename T3> inline auto op(const T1 &pred,const T2&lhs,const T3 &rhs) \
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-> decltype(LatticeTrinaryExpression<GRID_TRINOP(name),const T1&,const T2 &,const T3&>(std::make_pair(GRID_TRINOP(name)(),\
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std::forward_as_tuple(pred,lhs,rhs)))) \
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{\
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return LatticeTrinaryExpression<GRID_TRINOP(name), const T1 &, const T2 &,const T3&>(std::make_pair(GRID_TRINOP(name)(), \
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std::forward_as_tuple(pred,lhs, rhs))); \
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}
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////////////////////////
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//Operator definitions
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////////////////////////
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GRID_DEF_UNOP(operator -,UnarySub);
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GRID_DEF_UNOP(adj,UnaryAdj);
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GRID_DEF_UNOP(conj,UnaryConj);
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GRID_DEF_UNOP(trace,UnaryTrace);
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GRID_DEF_UNOP(transpose,UnaryTranspose);
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GRID_DEF_BINOP(operator+,BinaryAdd);
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GRID_DEF_BINOP(operator-,BinarySub);
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GRID_DEF_BINOP(operator*,BinaryMul);
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#undef GRID_UNOP
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#undef GRID_BINOP
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#undef GRID_TRINOP
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#undef GRID_DEF_UNOP
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#undef GRID_DEF_BINOP
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#undef GRID_DEF_TRINOP
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}
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#if 0
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using namespace Grid;
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int main(int argc,char **argv){
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Lattice<double> v1(16);
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Lattice<double> v2(16);
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Lattice<double> v3(16);
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BinaryAdd<double,double> tmp;
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LatticeBinaryExpression<BinaryAdd<double,double>,Lattice<double> &,Lattice<double> &>
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expr(std::make_pair(tmp,
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std::forward_as_tuple(v1,v2)));
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tmp.func(eval(0,v1),eval(0,v2));
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auto var = v1+v2;
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std::cout<<typeid(var).name()<<std::endl;
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v3=v1+v2;
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v3=v1+v2+v1*v2;
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};
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void testit(Lattice<double> &v1,Lattice<double> &v2,Lattice<double> &v3)
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{
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v3=v1+v2+v1*v2;
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}
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#endif
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#endif
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