/usr/include/ginac/ex.h is in libginac-dev 1.6.6-1.
This file is owned by root:root, with mode 0o644.
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*
* Interface to GiNaC's light-weight expression handles. */
/*
* GiNaC Copyright (C) 1999-2015 Johannes Gutenberg University Mainz, Germany
*
* 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
*/
#ifndef GINAC_EX_H
#define GINAC_EX_H
#include "basic.h"
#include "ptr.h"
#include <functional>
#include <iosfwd>
#include <iterator>
#include <stack>
namespace GiNaC {
#ifdef _MSC_VER
// MSVC produces a different symbol for _ex0 when it is declared inside
// ex::is_zero() than when it is declared at top level as follows
extern const ex _ex0;
#endif
/** Helper class to initialize the library. There must be one static object
* of this class in every object file that makes use of our flyweights in
* order to guarantee proper initialization. Hence we put it into this
* file which is included by every relevant file anyways. This is modeled
* after section 27.4.2.1.6 of the C++ standard, where cout and friends are
* set up.
*
* @see utils.cpp */
class library_init {
static void init_unarchivers();
public:
library_init();
~library_init();
private:
static int count;
};
/** For construction of flyweights, etc. */
static library_init library_initializer;
class scalar_products;
class const_iterator;
class const_preorder_iterator;
class const_postorder_iterator;
/** Lightweight wrapper for GiNaC's symbolic objects. It holds a pointer to
* the other object in order to do garbage collection by the method of
* reference counting. I.e., it is a smart pointer. Also, the constructor
* ex::ex(const basic & other) calls the methods that do automatic
* evaluation. E.g., x-x turns automatically into 0. */
class ex {
friend class archive_node;
friend inline bool are_ex_trivially_equal(const ex &, const ex &);
template<class T> friend inline const T &ex_to(const ex &);
template<class T> friend inline bool is_a(const ex &);
template<class T> friend inline bool is_exactly_a(const ex &);
// default constructor, copy constructor and assignment operator
public:
ex() throw();
// other constructors
public:
ex(const basic & other);
ex(int i);
ex(unsigned int i);
ex(long i);
ex(unsigned long i);
ex(double const d);
/** Construct ex from string and a list of symbols. The input grammar is
* similar to the GiNaC output format. All symbols and indices to be used
* in the expression must be specified in a lst in the second argument.
* Undefined symbols and other parser errors will throw an exception. */
ex(const std::string &s, const ex &l);
public:
// non-virtual functions in this class
public:
/** Efficiently swap the contents of two expressions. */
void swap(ex & other) throw()
{
GINAC_ASSERT(bp->flags & status_flags::dynallocated);
GINAC_ASSERT(other.bp->flags & status_flags::dynallocated);
bp.swap(other.bp);
}
// iterators
const_iterator begin() const throw();
const_iterator end() const throw();
const_preorder_iterator preorder_begin() const;
const_preorder_iterator preorder_end() const throw();
const_postorder_iterator postorder_begin() const;
const_postorder_iterator postorder_end() const throw();
// evaluation
ex eval(int level = 0) const { return bp->eval(level); }
ex evalf(int level = 0) const { return bp->evalf(level); }
ex evalm() const { return bp->evalm(); }
ex eval_ncmul(const exvector & v) const { return bp->eval_ncmul(v); }
ex eval_integ() const { return bp->eval_integ(); }
// printing
void print(const print_context & c, unsigned level = 0) const;
void dbgprint() const;
void dbgprinttree() const;
// info
bool info(unsigned inf) const { return bp->info(inf); }
// operand access
size_t nops() const { return bp->nops(); }
ex op(size_t i) const { return bp->op(i); }
ex operator[](const ex & index) const { return (*bp)[index]; }
ex operator[](size_t i) const { return (*bp)[i]; }
ex & let_op(size_t i);
ex & operator[](const ex & index);
ex & operator[](size_t i);
ex lhs() const;
ex rhs() const;
// function for complex expressions
ex conjugate() const { return bp->conjugate(); }
ex real_part() const { return bp->real_part(); }
ex imag_part() const { return bp->imag_part(); }
// pattern matching
bool has(const ex & pattern, unsigned options = 0) const { return bp->has(pattern, options); }
bool find(const ex & pattern, exset& found) const;
bool match(const ex & pattern) const;
bool match(const ex & pattern, exmap & repls) const { return bp->match(pattern, repls); }
// substitutions
ex subs(const exmap & m, unsigned options = 0) const;
ex subs(const lst & ls, const lst & lr, unsigned options = 0) const;
ex subs(const ex & e, unsigned options = 0) const;
// function mapping
ex map(map_function & f) const { return bp->map(f); }
ex map(ex (*f)(const ex & e)) const;
// visitors and tree traversal
void accept(visitor & v) const { bp->accept(v); }
void traverse_preorder(visitor & v) const;
void traverse_postorder(visitor & v) const;
void traverse(visitor & v) const { traverse_preorder(v); }
// degree/coeff
bool is_polynomial(const ex & vars) const;
int degree(const ex & s) const { return bp->degree(s); }
int ldegree(const ex & s) const { return bp->ldegree(s); }
ex coeff(const ex & s, int n = 1) const { return bp->coeff(s, n); }
ex lcoeff(const ex & s) const { return coeff(s, degree(s)); }
ex tcoeff(const ex & s) const { return coeff(s, ldegree(s)); }
// expand/collect
ex expand(unsigned options=0) const;
ex collect(const ex & s, bool distributed = false) const { return bp->collect(s, distributed); }
// differentiation and series expansion
ex diff(const symbol & s, unsigned nth = 1) const;
ex series(const ex & r, int order, unsigned options = 0) const;
// rational functions
ex normal(int level = 0) const;
ex to_rational(exmap & repl) const;
ex to_rational(lst & repl_lst) const;
ex to_polynomial(exmap & repl) const;
ex to_polynomial(lst & repl_lst) const;
ex numer() const;
ex denom() const;
ex numer_denom() const;
// polynomial algorithms
ex unit(const ex &x) const;
ex content(const ex &x) const;
numeric integer_content() const;
ex primpart(const ex &x) const;
ex primpart(const ex &x, const ex &cont) const;
void unitcontprim(const ex &x, ex &u, ex &c, ex &p) const;
ex smod(const numeric &xi) const { return bp->smod(xi); }
numeric max_coefficient() const;
// indexed objects
exvector get_free_indices() const { return bp->get_free_indices(); }
ex simplify_indexed(unsigned options = 0) const;
ex simplify_indexed(const scalar_products & sp, unsigned options = 0) const;
// comparison
int compare(const ex & other) const;
bool is_equal(const ex & other) const;
bool is_zero() const {
#ifndef _MSC_VER
extern const ex _ex0;
#endif
return is_equal(_ex0);
}
bool is_zero_matrix() const;
// symmetry
ex symmetrize() const;
ex symmetrize(const lst & l) const;
ex antisymmetrize() const;
ex antisymmetrize(const lst & l) const;
ex symmetrize_cyclic() const;
ex symmetrize_cyclic(const lst & l) const;
// noncommutativity
unsigned return_type() const { return bp->return_type(); }
return_type_t return_type_tinfo() const { return bp->return_type_tinfo(); }
unsigned gethash() const { return bp->gethash(); }
private:
static ptr<basic> construct_from_basic(const basic & other);
static basic & construct_from_int(int i);
static basic & construct_from_uint(unsigned int i);
static basic & construct_from_long(long i);
static basic & construct_from_ulong(unsigned long i);
static basic & construct_from_double(double d);
static ptr<basic> construct_from_string_and_lst(const std::string &s, const ex &l);
void makewriteable();
void share(const ex & other) const;
// member variables
private:
mutable ptr<basic> bp; ///< pointer to basic object managed by this
};
// performance-critical inlined method implementations
// This needs to be a basic* because we don't know that numeric is derived
// from basic and we need a basic& for the ex default constructor
extern const basic *_num0_bp;
inline
ex::ex() throw() : bp(*const_cast<basic *>(_num0_bp))
{
GINAC_ASSERT(bp->flags & status_flags::dynallocated);
}
inline
ex::ex(const basic & other) : bp(construct_from_basic(other))
{
GINAC_ASSERT(bp->flags & status_flags::dynallocated);
}
inline
ex::ex(int i) : bp(construct_from_int(i))
{
GINAC_ASSERT(bp->flags & status_flags::dynallocated);
}
inline
ex::ex(unsigned int i) : bp(construct_from_uint(i))
{
GINAC_ASSERT(bp->flags & status_flags::dynallocated);
}
inline
ex::ex(long i) : bp(construct_from_long(i))
{
GINAC_ASSERT(bp->flags & status_flags::dynallocated);
}
inline
ex::ex(unsigned long i) : bp(construct_from_ulong(i))
{
GINAC_ASSERT(bp->flags & status_flags::dynallocated);
}
inline
ex::ex(double const d) : bp(construct_from_double(d))
{
GINAC_ASSERT(bp->flags & status_flags::dynallocated);
}
inline
ex::ex(const std::string &s, const ex &l) : bp(construct_from_string_and_lst(s, l))
{
GINAC_ASSERT(bp->flags & status_flags::dynallocated);
}
inline
int ex::compare(const ex & other) const
{
#ifdef GINAC_COMPARE_STATISTICS
compare_statistics.total_compares++;
#endif
if (bp == other.bp) // trivial case: both expressions point to same basic
return 0;
#ifdef GINAC_COMPARE_STATISTICS
compare_statistics.nontrivial_compares++;
#endif
const int cmpval = bp->compare(*other.bp);
#if 1
if (cmpval == 0) {
// Expressions point to different, but equal, trees: conserve
// memory and make subsequent compare() operations faster by
// making both expressions point to the same tree.
share(other);
}
#endif
return cmpval;
}
inline
bool ex::is_equal(const ex & other) const
{
#ifdef GINAC_COMPARE_STATISTICS
compare_statistics.total_is_equals++;
#endif
if (bp == other.bp) // trivial case: both expressions point to same basic
return true;
#ifdef GINAC_COMPARE_STATISTICS
compare_statistics.nontrivial_is_equals++;
#endif
const bool equal = bp->is_equal(*other.bp);
#if 0
if (equal) {
// Expressions point to different, but equal, trees: conserve
// memory and make subsequent compare() operations faster by
// making both expressions point to the same tree.
share(other);
}
#endif
return equal;
}
// Iterators
class const_iterator : public std::iterator<std::random_access_iterator_tag, ex, ptrdiff_t, const ex *, const ex &> {
friend class ex;
friend class const_preorder_iterator;
friend class const_postorder_iterator;
public:
const_iterator() throw() {}
private:
const_iterator(const ex &e_, size_t i_) throw() : e(e_), i(i_) {}
public:
// This should return an ex&, but that would be a reference to a
// temporary value
ex operator*() const
{
return e.op(i);
}
// This should return an ex*, but that would be a pointer to a
// temporary value
std::auto_ptr<ex> operator->() const
{
return std::auto_ptr<ex>(new ex(operator*()));
}
ex operator[](difference_type n) const
{
return e.op(i + n);
}
const_iterator &operator++() throw()
{
++i;
return *this;
}
const_iterator operator++(int) throw()
{
const_iterator tmp = *this;
++i;
return tmp;
}
const_iterator &operator+=(difference_type n) throw()
{
i += n;
return *this;
}
const_iterator operator+(difference_type n) const throw()
{
return const_iterator(e, i + n);
}
inline friend const_iterator operator+(difference_type n, const const_iterator &it) throw()
{
return const_iterator(it.e, it.i + n);
}
const_iterator &operator--() throw()
{
--i;
return *this;
}
const_iterator operator--(int) throw()
{
const_iterator tmp = *this;
--i;
return tmp;
}
const_iterator &operator-=(difference_type n) throw()
{
i -= n;
return *this;
}
const_iterator operator-(difference_type n) const throw()
{
return const_iterator(e, i - n);
}
inline friend difference_type operator-(const const_iterator &lhs, const const_iterator &rhs) throw()
{
return lhs.i - rhs.i;
}
bool operator==(const const_iterator &other) const throw()
{
return are_ex_trivially_equal(e, other.e) && i == other.i;
}
bool operator!=(const const_iterator &other) const throw()
{
return !(*this == other);
}
bool operator<(const const_iterator &other) const throw()
{
return i < other.i;
}
bool operator>(const const_iterator &other) const throw()
{
return other < *this;
}
bool operator<=(const const_iterator &other) const throw()
{
return !(other < *this);
}
bool operator>=(const const_iterator &other) const throw()
{
return !(*this < other);
}
protected:
ex e; // this used to be a "const basic *", but in view of object fusion that wouldn't be safe
size_t i;
};
namespace internal {
struct _iter_rep {
_iter_rep(const ex &e_, size_t i_, size_t i_end_) : e(e_), i(i_), i_end(i_end_) {}
bool operator==(const _iter_rep &other) const throw()
{
return are_ex_trivially_equal(e, other.e) && i == other.i;
}
bool operator!=(const _iter_rep &other) const throw()
{
return !(*this == other);
}
ex e;
size_t i;
size_t i_end;
};
} // namespace internal
class const_preorder_iterator : public std::iterator<std::forward_iterator_tag, ex, ptrdiff_t, const ex *, const ex &> {
public:
const_preorder_iterator() throw() {}
const_preorder_iterator(const ex &e, size_t n)
{
s.push(internal::_iter_rep(e, 0, n));
}
public:
reference operator*() const
{
return s.top().e;
}
pointer operator->() const
{
return &(s.top().e);
}
const_preorder_iterator &operator++()
{
increment();
return *this;
}
const_preorder_iterator operator++(int)
{
const_preorder_iterator tmp = *this;
increment();
return tmp;
}
bool operator==(const const_preorder_iterator &other) const throw()
{
return s == other.s;
}
bool operator!=(const const_preorder_iterator &other) const throw()
{
return !(*this == other);
}
private:
std::stack<internal::_iter_rep, std::vector<internal::_iter_rep> > s;
void increment()
{
while (!s.empty() && s.top().i == s.top().i_end) {
s.pop();
if (s.empty())
return;
++s.top().i;
}
internal::_iter_rep & current = s.top();
if (current.i != current.i_end) {
const ex & child = current.e.op(current.i);
s.push(internal::_iter_rep(child, 0, child.nops()));
}
}
};
class const_postorder_iterator : public std::iterator<std::forward_iterator_tag, ex, ptrdiff_t, const ex *, const ex &> {
public:
const_postorder_iterator() throw() {}
const_postorder_iterator(const ex &e, size_t n)
{
s.push(internal::_iter_rep(e, 0, n));
descend();
}
public:
reference operator*() const
{
return s.top().e;
}
pointer operator->() const
{
return &(s.top().e);
}
const_postorder_iterator &operator++()
{
increment();
return *this;
}
const_postorder_iterator operator++(int)
{
const_postorder_iterator tmp = *this;
increment();
return tmp;
}
bool operator==(const const_postorder_iterator &other) const throw()
{
return s == other.s;
}
bool operator!=(const const_postorder_iterator &other) const throw()
{
return !(*this == other);
}
private:
std::stack<internal::_iter_rep, std::vector<internal::_iter_rep> > s;
void descend()
{
while (s.top().i != s.top().i_end) {
internal::_iter_rep & current = s.top();
const ex & child = current.e.op(current.i);
s.push(internal::_iter_rep(child, 0, child.nops()));
}
}
void increment()
{
if (s.top().i == s.top().i_end)
s.pop();
if (!s.empty()) {
++s.top().i;
descend();
}
}
};
inline const_iterator ex::begin() const throw()
{
return const_iterator(*this, 0);
}
inline const_iterator ex::end() const throw()
{
return const_iterator(*this, nops());
}
inline const_preorder_iterator ex::preorder_begin() const
{
return const_preorder_iterator(*this, nops());
}
inline const_preorder_iterator ex::preorder_end() const throw()
{
return const_preorder_iterator();
}
inline const_postorder_iterator ex::postorder_begin() const
{
return const_postorder_iterator(*this, nops());
}
inline const_postorder_iterator ex::postorder_end() const throw()
{
return const_postorder_iterator();
}
// utility functions
/** Compare two objects of class quickly without doing a deep tree traversal.
* @return "true" if they are equal
* "false" if equality cannot be established quickly (e1 and e2 may
* still be equal, in this case. */
inline bool are_ex_trivially_equal(const ex &e1, const ex &e2)
{
return e1.bp == e2.bp;
}
/* Function objects for STL sort() etc. */
struct ex_is_less : public std::binary_function<ex, ex, bool> {
bool operator() (const ex &lh, const ex &rh) const { return lh.compare(rh) < 0; }
};
struct ex_is_equal : public std::binary_function<ex, ex, bool> {
bool operator() (const ex &lh, const ex &rh) const { return lh.is_equal(rh); }
};
struct op0_is_equal : public std::binary_function<ex, ex, bool> {
bool operator() (const ex &lh, const ex &rh) const { return lh.op(0).is_equal(rh.op(0)); }
};
struct ex_swap : public std::binary_function<ex, ex, void> {
void operator() (ex &lh, ex &rh) const { lh.swap(rh); }
};
// Make it possible to print exvectors and exmaps
std::ostream & operator<<(std::ostream & os, const exvector & e);
std::ostream & operator<<(std::ostream & os, const exset & e);
std::ostream & operator<<(std::ostream & os, const exmap & e);
// wrapper functions around member functions
inline size_t nops(const ex & thisex)
{ return thisex.nops(); }
inline ex expand(const ex & thisex, unsigned options = 0)
{ return thisex.expand(options); }
inline ex conjugate(const ex & thisex)
{ return thisex.conjugate(); }
inline ex real_part(const ex & thisex)
{ return thisex.real_part(); }
inline ex imag_part(const ex & thisex)
{ return thisex.imag_part(); }
inline bool has(const ex & thisex, const ex & pattern, unsigned options = 0)
{ return thisex.has(pattern, options); }
inline bool find(const ex & thisex, const ex & pattern, exset& found)
{ return thisex.find(pattern, found); }
inline bool is_polynomial(const ex & thisex, const ex & vars)
{ return thisex.is_polynomial(vars); }
inline int degree(const ex & thisex, const ex & s)
{ return thisex.degree(s); }
inline int ldegree(const ex & thisex, const ex & s)
{ return thisex.ldegree(s); }
inline ex coeff(const ex & thisex, const ex & s, int n=1)
{ return thisex.coeff(s, n); }
inline ex numer(const ex & thisex)
{ return thisex.numer(); }
inline ex denom(const ex & thisex)
{ return thisex.denom(); }
inline ex numer_denom(const ex & thisex)
{ return thisex.numer_denom(); }
inline ex normal(const ex & thisex, int level=0)
{ return thisex.normal(level); }
inline ex to_rational(const ex & thisex, lst & repl_lst)
{ return thisex.to_rational(repl_lst); }
inline ex to_rational(const ex & thisex, exmap & repl)
{ return thisex.to_rational(repl); }
inline ex to_polynomial(const ex & thisex, exmap & repl)
{ return thisex.to_polynomial(repl); }
inline ex to_polynomial(const ex & thisex, lst & repl_lst)
{ return thisex.to_polynomial(repl_lst); }
inline ex collect(const ex & thisex, const ex & s, bool distributed = false)
{ return thisex.collect(s, distributed); }
inline ex eval(const ex & thisex, int level = 0)
{ return thisex.eval(level); }
inline ex evalf(const ex & thisex, int level = 0)
{ return thisex.evalf(level); }
inline ex evalm(const ex & thisex)
{ return thisex.evalm(); }
inline ex eval_integ(const ex & thisex)
{ return thisex.eval_integ(); }
inline ex diff(const ex & thisex, const symbol & s, unsigned nth = 1)
{ return thisex.diff(s, nth); }
inline ex series(const ex & thisex, const ex & r, int order, unsigned options = 0)
{ return thisex.series(r, order, options); }
inline bool match(const ex & thisex, const ex & pattern, exmap& repl_lst)
{ return thisex.match(pattern, repl_lst); }
inline ex simplify_indexed(const ex & thisex, unsigned options = 0)
{ return thisex.simplify_indexed(options); }
inline ex simplify_indexed(const ex & thisex, const scalar_products & sp, unsigned options = 0)
{ return thisex.simplify_indexed(sp, options); }
inline ex symmetrize(const ex & thisex)
{ return thisex.symmetrize(); }
inline ex symmetrize(const ex & thisex, const lst & l)
{ return thisex.symmetrize(l); }
inline ex antisymmetrize(const ex & thisex)
{ return thisex.antisymmetrize(); }
inline ex antisymmetrize(const ex & thisex, const lst & l)
{ return thisex.antisymmetrize(l); }
inline ex symmetrize_cyclic(const ex & thisex)
{ return thisex.symmetrize_cyclic(); }
inline ex symmetrize_cyclic(const ex & thisex, const lst & l)
{ return thisex.symmetrize_cyclic(l); }
inline ex op(const ex & thisex, size_t i)
{ return thisex.op(i); }
inline ex lhs(const ex & thisex)
{ return thisex.lhs(); }
inline ex rhs(const ex & thisex)
{ return thisex.rhs(); }
inline bool is_zero(const ex & thisex)
{ return thisex.is_zero(); }
inline void swap(ex & e1, ex & e2)
{ e1.swap(e2); }
inline ex ex::subs(const exmap & m, unsigned options) const
{
return bp->subs(m, options);
}
inline ex subs(const ex & thisex, const exmap & m, unsigned options = 0)
{ return thisex.subs(m, options); }
inline ex subs(const ex & thisex, const lst & ls, const lst & lr, unsigned options = 0)
{ return thisex.subs(ls, lr, options); }
inline ex subs(const ex & thisex, const ex & e, unsigned options = 0)
{ return thisex.subs(e, options); }
/* Convert function pointer to function object suitable for map(). */
class pointer_to_map_function : public map_function {
protected:
ex (*ptr)(const ex &);
public:
explicit pointer_to_map_function(ex x(const ex &)) : ptr(x) {}
ex operator()(const ex & e) { return ptr(e); }
};
template<class T1>
class pointer_to_map_function_1arg : public map_function {
protected:
ex (*ptr)(const ex &, T1);
T1 arg1;
public:
explicit pointer_to_map_function_1arg(ex x(const ex &, T1), T1 a1) : ptr(x), arg1(a1) {}
ex operator()(const ex & e) { return ptr(e, arg1); }
};
template<class T1, class T2>
class pointer_to_map_function_2args : public map_function {
protected:
ex (*ptr)(const ex &, T1, T2);
T1 arg1;
T2 arg2;
public:
explicit pointer_to_map_function_2args(ex x(const ex &, T1, T2), T1 a1, T2 a2) : ptr(x), arg1(a1), arg2(a2) {}
ex operator()(const ex & e) { return ptr(e, arg1, arg2); }
};
template<class T1, class T2, class T3>
class pointer_to_map_function_3args : public map_function {
protected:
ex (*ptr)(const ex &, T1, T2, T3);
T1 arg1;
T2 arg2;
T3 arg3;
public:
explicit pointer_to_map_function_3args(ex x(const ex &, T1, T2, T3), T1 a1, T2 a2, T3 a3) : ptr(x), arg1(a1), arg2(a2), arg3(a3) {}
ex operator()(const ex & e) { return ptr(e, arg1, arg2, arg3); }
};
template<class C>
class pointer_to_member_to_map_function : public map_function {
protected:
ex (C::*ptr)(const ex &);
C &c;
public:
explicit pointer_to_member_to_map_function(ex (C::*member)(const ex &), C &obj) : ptr(member), c(obj) {}
ex operator()(const ex & e) { return (c.*ptr)(e); }
};
template<class C, class T1>
class pointer_to_member_to_map_function_1arg : public map_function {
protected:
ex (C::*ptr)(const ex &, T1);
C &c;
T1 arg1;
public:
explicit pointer_to_member_to_map_function_1arg(ex (C::*member)(const ex &, T1), C &obj, T1 a1) : ptr(member), c(obj), arg1(a1) {}
ex operator()(const ex & e) { return (c.*ptr)(e, arg1); }
};
template<class C, class T1, class T2>
class pointer_to_member_to_map_function_2args : public map_function {
protected:
ex (C::*ptr)(const ex &, T1, T2);
C &c;
T1 arg1;
T2 arg2;
public:
explicit pointer_to_member_to_map_function_2args(ex (C::*member)(const ex&, T1, T2), C &obj, T1 a1, T2 a2) : ptr(member), c(obj), arg1(a1), arg2(a2) {}
ex operator()(const ex & e) { return (c.*ptr)(e, arg1, arg2); }
};
template<class C, class T1, class T2, class T3>
class pointer_to_member_to_map_function_3args : public map_function {
protected:
ex (C::*ptr)(const ex &, T1, T2, T3);
C &c;
T1 arg1;
T2 arg2;
T3 arg3;
public:
explicit pointer_to_member_to_map_function_3args(ex (C::*member)(const ex &, T1, T2, T3), C &obj, T1 a1, T2 a2, T3 a3) : ptr(member), c(obj), arg1(a1), arg2(a2), arg3(a3) {}
ex operator()(const ex & e) { return (c.*ptr)(e, arg1, arg2, arg3); }
};
inline ex ex::map(ex f(const ex &)) const
{
pointer_to_map_function fcn(f);
return bp->map(fcn);
}
// convenience type checker template functions
/** Check if ex is a handle to a T, including base classes. */
template <class T>
inline bool is_a(const ex &obj)
{
return is_a<T>(*obj.bp);
}
/** Check if ex is a handle to a T, not including base classes. */
template <class T>
inline bool is_exactly_a(const ex &obj)
{
return is_exactly_a<T>(*obj.bp);
}
/** Return a reference to the basic-derived class T object embedded in an
* expression. This is fast but unsafe: the result is undefined if the
* expression does not contain a T object at its top level. Hence, you
* should generally check the type of e first. Also, you shouldn't cache
* the returned reference because GiNaC's garbage collector may destroy
* the referenced object any time it's used in another expression.
*
* @param e expression
* @return reference to object of class T
* @see is_exactly_a<class T>() */
template <class T>
inline const T &ex_to(const ex &e)
{
GINAC_ASSERT(is_a<T>(e));
return static_cast<const T &>(*e.bp);
}
} // namespace GiNaC
// Specializations of Standard Library algorithms
namespace std {
/** Specialization of std::swap() for ex objects. */
template <>
inline void swap(GiNaC::ex &a, GiNaC::ex &b)
{
a.swap(b);
}
/** Specialization of std::iter_swap() for vector<ex> iterators. */
template <>
inline void iter_swap(vector<GiNaC::ex>::iterator i1, vector<GiNaC::ex>::iterator i2)
{
i1->swap(*i2);
}
/** Specialization of std::iter_swap() for list<ex> iterators. */
template <>
inline void iter_swap(list<GiNaC::ex>::iterator i1, list<GiNaC::ex>::iterator i2)
{
i1->swap(*i2);
}
} // namespace std
#endif // ndef GINAC_EX_H
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