/usr/include/root/Math/Expression.h is in libroot-math-smatrix-dev 5.34.14-1build1.
This file is owned by root:root, with mode 0o644.
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// Authors: T. Glebe, L. Moneta 2005
#ifndef ROOT_Math_Expression
#define ROOT_Math_Expression
// ********************************************************************
//
// source:
//
// type: source code
//
// created: 19. Mar 2001
//
// author: Thorsten Glebe
// HERA-B Collaboration
// Max-Planck-Institut fuer Kernphysik
// Saupfercheckweg 1
// 69117 Heidelberg
// Germany
// E-mail: T.Glebe@mpi-hd.mpg.de
//
// Description: Expression Template Elements for SVector
//
// changes:
// 19 Mar 2001 (TG) creation
// 20 Mar 2001 (TG) added rows(), cols() to Expr
// 21 Mar 2001 (TG) added Expr::value_type
// 11 Apr 2001 (TG) rows(), cols() replaced by rows, cols
// 10 Okt 2001 (TG) added print() and operator<<() for Expr class
//
// ********************************************************************
/**
@defgroup Expression Expression Template Classes
@ingroup SMatrixGroup
*/
//==============================================================================
// Expr: class representing SVector expressions
//=============================================================================
// modified BinaryOp with two extension BinaryOpCopyL and BinaryOpCopyR to store the
// object in BinaryOp by value and not reference. When used with constant BinaryOp reference give problems
// on some compilers (like Windows) where a temporary Constant object is ccreated and then destructed
#include <iomanip>
#include <iostream>
namespace ROOT {
namespace Math {
// template <class T, unsigned int D, unsigned int D2> class MatRepStd;
/**
Expression wrapper class for Vector objects
@ingroup Expression
*/
template <class ExprType, class T, unsigned int D >
class VecExpr {
public:
typedef T value_type;
///
VecExpr(const ExprType& rhs) :
rhs_(rhs) {}
///
~VecExpr() {}
///
inline T apply(unsigned int i) const {
return rhs_.apply(i);
}
inline T operator() (unsigned int i) const {
return rhs_.apply(i);
}
#ifdef OLD_IMPL
///
static const unsigned int rows = D;
///
///static const unsigned int cols = D2;
#else
// use enumerations
enum {
kRows = D
};
#endif
/// used by operator<<()
std::ostream& print(std::ostream& os) const {
os.setf(std::ios::right,std::ios::adjustfield);
unsigned int i=0;
os << "[ ";
for(; i<D-1; ++i) {
os << apply(i) << ", ";
}
os << apply(i);
os << " ]";
return os;
}
private:
ExprType rhs_; // cannot be a reference!
};
/**
Expression wrapper class for Matrix objects
@ingroup Expression
*/
template <class T, unsigned int D, unsigned int D2> class MatRepStd;
template <class ExprType, class T, unsigned int D, unsigned int D2 = 1,
class R1=MatRepStd<T,D,D2> >
class Expr {
public:
typedef T value_type;
///
Expr(const ExprType& rhs) :
rhs_(rhs) {}
///
~Expr() {}
///
inline T apply(unsigned int i) const {
return rhs_.apply(i);
}
inline T operator() (unsigned int i, unsigned j) const {
return rhs_(i,j);
}
/**
function to determine if any use operand
is being used (has same memory adress)
*/
inline bool IsInUse (const T * p) const {
return rhs_.IsInUse(p);
}
#ifdef OLD_IMPL
///
static const unsigned int rows = D;
///
static const unsigned int cols = D2;
#else
// use enumerations
enum {
///
kRows = D,
///
kCols = D2
};
#endif
/// used by operator<<()
/// simplify to use apply(i,j)
std::ostream& print(std::ostream& os) const {
os.setf(std::ios::right,std::ios::adjustfield);
os << "[ ";
for (unsigned int i=0; i < D; ++i) {
unsigned int d2 = D2; // to avoid some annoying warnings in case of vectors (D2 = 0)
for (unsigned int j=0; j < D2; ++j) {
os << std::setw(12) << this->operator() (i,j);
if ((!((j+1)%12)) && (j < d2-1))
os << std::endl << " ...";
}
if (i != D - 1)
os << std::endl << " ";
}
os << " ]";
return os;
}
private:
ExprType rhs_; // cannot be a reference!
};
//==============================================================================
// operator<<
//==============================================================================
template <class A, class T, unsigned int D>
inline std::ostream& operator<<(std::ostream& os, const VecExpr<A,T,D>& rhs) {
return rhs.print(os);
}
template <class A, class T, unsigned int D1, unsigned int D2, class R1>
inline std::ostream& operator<<(std::ostream& os, const Expr<A,T,D1,D2,R1>& rhs) {
return rhs.print(os);
}
/**
BinaryOperation class
A class representing binary operators in the parse tree.
This is the default case where objects are kept by reference
@ingroup Expression
@author T. Glebe
*/
//==============================================================================
// BinaryOp
//==============================================================================
template <class Operator, class LHS, class RHS, class T>
class BinaryOp {
public:
///
BinaryOp( Operator /* op */, const LHS& lhs, const RHS& rhs) :
lhs_(lhs), rhs_(rhs) {}
///
~BinaryOp() {}
///
inline T apply(unsigned int i) const {
return Operator::apply(lhs_.apply(i), rhs_.apply(i));
}
inline T operator() (unsigned int i, unsigned int j) const {
return Operator::apply(lhs_(i,j), rhs_(i,j) );
}
inline bool IsInUse (const T * p) const {
return lhs_.IsInUse(p) || rhs_.IsInUse(p);
}
protected:
const LHS& lhs_;
const RHS& rhs_;
};
//LM :: add specialization of BinaryOP when first or second argument needs to be copied
// (maybe it can be doen with a template specialization, but it is not worth, easier to have a separate class
//==============================================================================
/**
Binary Operation class with value storage for the left argument.
Special case of BinaryOp where for the left argument the passed object
is copied and stored by value instead of a reference.
This is used in the case of operations involving a constant, where we cannot store a
reference to the constant (we get a temporary object) and we need to copy it.
@ingroup Expression
*/
//==============================================================================
template <class Operator, class LHS, class RHS, class T>
class BinaryOpCopyL {
public:
///
BinaryOpCopyL( Operator /* op */, const LHS& lhs, const RHS& rhs) :
lhs_(lhs), rhs_(rhs) {}
///
~BinaryOpCopyL() {}
///
inline T apply(unsigned int i) const {
return Operator::apply(lhs_.apply(i), rhs_.apply(i));
}
inline T operator() (unsigned int i, unsigned int j) const {
return Operator::apply(lhs_(i,j), rhs_(i,j) );
}
inline bool IsInUse (const T * p) const {
// no need to check left since we copy it
return rhs_.IsInUse(p);
}
protected:
const LHS lhs_;
const RHS& rhs_;
};
//==============================================================================
/**
Binary Operation class with value storage for the right argument.
Special case of BinaryOp where for the wight argument a copy is stored instead of a reference
This is use in the case for example of constant where we cannot store by reference
but need to copy since Constant is a temporary object
@ingroup Expression
*/
//==============================================================================
template <class Operator, class LHS, class RHS, class T>
class BinaryOpCopyR {
public:
///
BinaryOpCopyR( Operator /* op */, const LHS& lhs, const RHS& rhs) :
lhs_(lhs), rhs_(rhs) {}
///
~BinaryOpCopyR() {}
///
inline T apply(unsigned int i) const {
return Operator::apply(lhs_.apply(i), rhs_.apply(i));
}
inline T operator() (unsigned int i, unsigned int j) const {
return Operator::apply(lhs_(i,j), rhs_(i,j) );
}
inline bool IsInUse (const T * p) const {
// no need for right since we copied
return lhs_.IsInUse(p);
}
protected:
const LHS& lhs_;
const RHS rhs_;
};
/**
UnaryOperation class
A class representing unary operators in the parse tree.
The objects are stored by reference
@ingroup Expression
@author T. Glebe
*/
//==============================================================================
// UnaryOp
//==============================================================================
template <class Operator, class RHS, class T>
class UnaryOp {
public:
///
UnaryOp( Operator /* op */ , const RHS& rhs) :
rhs_(rhs) {}
///
~UnaryOp() {}
///
inline T apply(unsigned int i) const {
return Operator::apply(rhs_.apply(i));
}
inline T operator() (unsigned int i, unsigned int j) const {
return Operator::apply(rhs_(i,j));
}
inline bool IsInUse (const T * p) const {
return rhs_.IsInUse(p);
}
protected:
const RHS& rhs_;
};
/**
Constant expression class
A class representing constant expressions (literals) in the parse tree.
@ingroup Expression
@author T. Glebe
*/
//==============================================================================
// Constant
//==============================================================================
template <class T>
class Constant {
public:
///
Constant( const T& rhs ) :
rhs_(rhs) {}
///
~Constant() {}
///
inline T apply(unsigned int /*i */ ) const { return rhs_; }
inline T operator() (unsigned int /*i */, unsigned int /*j */ ) const { return rhs_; }
//inline bool IsInUse (const T * ) const { return false; }
protected:
const T rhs_; // no need for reference. It is a fundamental type normally
};
} // namespace Math
} // namespace ROOT
#endif /* ROOT_Math_Expression */
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