vn-verdnaturachat/ios/Pods/boost-for-react-native/boost/regex/concepts.hpp

1129 lines
45 KiB
C++

/*
*
* Copyright (c) 2004
* John Maddock
*
* Use, modification and distribution are subject to the
* Boost Software License, Version 1.0. (See accompanying file
* LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
*
*/
/*
* LOCATION: see http://www.boost.org for most recent version.
* FILE concepts.hpp
* VERSION see <boost/version.hpp>
* DESCRIPTION: Declares regular expression concepts.
*/
#ifndef BOOST_REGEX_CONCEPTS_HPP_INCLUDED
#define BOOST_REGEX_CONCEPTS_HPP_INCLUDED
#include <boost/concept_archetype.hpp>
#include <boost/concept_check.hpp>
#include <boost/type_traits/is_enum.hpp>
#include <boost/type_traits/is_base_and_derived.hpp>
#include <boost/static_assert.hpp>
#ifndef BOOST_TEST_TR1_REGEX
#include <boost/regex.hpp>
#endif
#include <bitset>
#include <vector>
#include <iostream>
namespace boost{
//
// bitmask_archetype:
// this can be either an integer type, an enum, or a std::bitset,
// we use the latter as the architype as it offers the "strictest"
// of the possible interfaces:
//
typedef std::bitset<512> bitmask_archetype;
//
// char_architype:
// A strict model for the character type interface.
//
struct char_architype
{
// default constructable:
char_architype();
// copy constructable / assignable:
char_architype(const char_architype&);
char_architype& operator=(const char_architype&);
// constructable from an integral value:
char_architype(unsigned long val);
// comparable:
bool operator==(const char_architype&)const;
bool operator!=(const char_architype&)const;
bool operator<(const char_architype&)const;
bool operator<=(const char_architype&)const;
bool operator>=(const char_architype&)const;
bool operator>(const char_architype&)const;
// conversion to integral type:
operator long()const;
};
inline long hash_value(char_architype val)
{ return val; }
//
// char_architype can not be used with basic_string:
//
} // namespace boost
namespace std{
template<> struct char_traits<boost::char_architype>
{
// The intent is that this template is not instantiated,
// but this typedef gives us a chance of compilation in
// case it is:
typedef boost::char_architype char_type;
};
}
//
// Allocator architype:
//
template <class T>
class allocator_architype
{
public:
typedef T* pointer;
typedef const T* const_pointer;
typedef T& reference;
typedef const T& const_reference;
typedef T value_type;
typedef unsigned size_type;
typedef int difference_type;
template <class U>
struct rebind
{
typedef allocator_architype<U> other;
};
pointer address(reference r){ return &r; }
const_pointer address(const_reference r) { return &r; }
pointer allocate(size_type n) { return static_cast<pointer>(std::malloc(n)); }
pointer allocate(size_type n, pointer) { return static_cast<pointer>(std::malloc(n)); }
void deallocate(pointer p, size_type) { std::free(p); }
size_type max_size()const { return UINT_MAX; }
allocator_architype(){}
allocator_architype(const allocator_architype&){}
template <class Other>
allocator_architype(const allocator_architype<Other>&){}
void construct(pointer p, const_reference r) { new (p)T(r); }
void destroy(pointer p) { p->~T(); }
};
template <class T>
bool operator == (const allocator_architype<T>&, const allocator_architype<T>&) {return true; }
template <class T>
bool operator != (const allocator_architype<T>&, const allocator_architype<T>&) { return false; }
namespace boost{
//
// regex_traits_architype:
// A strict interpretation of the regular expression traits class requirements.
//
template <class charT>
struct regex_traits_architype
{
public:
regex_traits_architype(){}
typedef charT char_type;
// typedef std::size_t size_type;
typedef std::vector<char_type> string_type;
typedef copy_constructible_archetype<assignable_archetype<> > locale_type;
typedef bitmask_archetype char_class_type;
static std::size_t length(const char_type* ) { return 0; }
charT translate(charT ) const { return charT(); }
charT translate_nocase(charT ) const { return static_object<charT>::get(); }
template <class ForwardIterator>
string_type transform(ForwardIterator , ForwardIterator ) const
{ return static_object<string_type>::get(); }
template <class ForwardIterator>
string_type transform_primary(ForwardIterator , ForwardIterator ) const
{ return static_object<string_type>::get(); }
template <class ForwardIterator>
char_class_type lookup_classname(ForwardIterator , ForwardIterator ) const
{ return static_object<char_class_type>::get(); }
template <class ForwardIterator>
string_type lookup_collatename(ForwardIterator , ForwardIterator ) const
{ return static_object<string_type>::get(); }
bool isctype(charT, char_class_type) const
{ return false; }
int value(charT, int) const
{ return 0; }
locale_type imbue(locale_type l)
{ return l; }
locale_type getloc()const
{ return static_object<locale_type>::get(); }
private:
// this type is not copyable:
regex_traits_architype(const regex_traits_architype&){}
regex_traits_architype& operator=(const regex_traits_architype&){ return *this; }
};
//
// alter this to std::tr1, to test a std implementation:
//
#ifndef BOOST_TEST_TR1_REGEX
namespace global_regex_namespace = ::boost;
#else
namespace global_regex_namespace = ::std::tr1;
#endif
template <class Bitmask>
struct BitmaskConcept
{
void constraints()
{
function_requires<CopyConstructibleConcept<Bitmask> >();
function_requires<AssignableConcept<Bitmask> >();
m_mask1 = m_mask2 | m_mask3;
m_mask1 = m_mask2 & m_mask3;
m_mask1 = m_mask2 ^ m_mask3;
m_mask1 = ~m_mask2;
m_mask1 |= m_mask2;
m_mask1 &= m_mask2;
m_mask1 ^= m_mask2;
}
Bitmask m_mask1, m_mask2, m_mask3;
};
template <class traits>
struct RegexTraitsConcept
{
RegexTraitsConcept();
// required typedefs:
typedef typename traits::char_type char_type;
// typedef typename traits::size_type size_type;
typedef typename traits::string_type string_type;
typedef typename traits::locale_type locale_type;
typedef typename traits::char_class_type char_class_type;
void constraints()
{
//function_requires<UnsignedIntegerConcept<size_type> >();
function_requires<RandomAccessContainerConcept<string_type> >();
function_requires<DefaultConstructibleConcept<locale_type> >();
function_requires<CopyConstructibleConcept<locale_type> >();
function_requires<AssignableConcept<locale_type> >();
function_requires<BitmaskConcept<char_class_type> >();
std::size_t n = traits::length(m_pointer);
ignore_unused_variable_warning(n);
char_type c = m_ctraits.translate(m_char);
ignore_unused_variable_warning(c);
c = m_ctraits.translate_nocase(m_char);
//string_type::foobar bar;
string_type s1 = m_ctraits.transform(m_pointer, m_pointer);
ignore_unused_variable_warning(s1);
string_type s2 = m_ctraits.transform_primary(m_pointer, m_pointer);
ignore_unused_variable_warning(s2);
char_class_type cc = m_ctraits.lookup_classname(m_pointer, m_pointer);
ignore_unused_variable_warning(cc);
string_type s3 = m_ctraits.lookup_collatename(m_pointer, m_pointer);
ignore_unused_variable_warning(s3);
bool b = m_ctraits.isctype(m_char, cc);
ignore_unused_variable_warning(b);
int v = m_ctraits.value(m_char, 16);
ignore_unused_variable_warning(v);
locale_type l(m_ctraits.getloc());
m_traits.imbue(l);
ignore_unused_variable_warning(l);
}
traits m_traits;
const traits m_ctraits;
const char_type* m_pointer;
char_type m_char;
private:
RegexTraitsConcept& operator=(RegexTraitsConcept&);
};
//
// helper class to compute what traits class a regular expression type is using:
//
template <class Regex>
struct regex_traits_computer;
template <class charT, class traits>
struct regex_traits_computer< global_regex_namespace::basic_regex<charT, traits> >
{
typedef traits type;
};
//
// BaseRegexConcept does not test anything dependent on basic_string,
// in case our charT does not have an associated char_traits:
//
template <class Regex>
struct BaseRegexConcept
{
typedef typename Regex::value_type value_type;
//typedef typename Regex::size_type size_type;
typedef typename Regex::flag_type flag_type;
typedef typename Regex::locale_type locale_type;
typedef input_iterator_archetype<value_type> input_iterator_type;
// derived test types:
typedef const value_type* pointer_type;
typedef bidirectional_iterator_archetype<value_type> BidiIterator;
typedef global_regex_namespace::sub_match<BidiIterator> sub_match_type;
typedef global_regex_namespace::match_results<BidiIterator, allocator_architype<sub_match_type> > match_results_type;
typedef global_regex_namespace::match_results<BidiIterator> match_results_default_type;
typedef output_iterator_archetype<value_type> OutIterator;
typedef typename regex_traits_computer<Regex>::type traits_type;
typedef global_regex_namespace::regex_iterator<BidiIterator, value_type, traits_type> regex_iterator_type;
typedef global_regex_namespace::regex_token_iterator<BidiIterator, value_type, traits_type> regex_token_iterator_type;
void global_constraints()
{
//
// test non-template components:
//
function_requires<BitmaskConcept<global_regex_namespace::regex_constants::syntax_option_type> >();
global_regex_namespace::regex_constants::syntax_option_type opts
= global_regex_namespace::regex_constants::icase
| global_regex_namespace::regex_constants::nosubs
| global_regex_namespace::regex_constants::optimize
| global_regex_namespace::regex_constants::collate
| global_regex_namespace::regex_constants::ECMAScript
| global_regex_namespace::regex_constants::basic
| global_regex_namespace::regex_constants::extended
| global_regex_namespace::regex_constants::awk
| global_regex_namespace::regex_constants::grep
| global_regex_namespace::regex_constants::egrep;
ignore_unused_variable_warning(opts);
function_requires<BitmaskConcept<global_regex_namespace::regex_constants::match_flag_type> >();
global_regex_namespace::regex_constants::match_flag_type mopts
= global_regex_namespace::regex_constants::match_default
| global_regex_namespace::regex_constants::match_not_bol
| global_regex_namespace::regex_constants::match_not_eol
| global_regex_namespace::regex_constants::match_not_bow
| global_regex_namespace::regex_constants::match_not_eow
| global_regex_namespace::regex_constants::match_any
| global_regex_namespace::regex_constants::match_not_null
| global_regex_namespace::regex_constants::match_continuous
| global_regex_namespace::regex_constants::match_prev_avail
| global_regex_namespace::regex_constants::format_default
| global_regex_namespace::regex_constants::format_sed
| global_regex_namespace::regex_constants::format_no_copy
| global_regex_namespace::regex_constants::format_first_only;
ignore_unused_variable_warning(mopts);
BOOST_STATIC_ASSERT((::boost::is_enum<global_regex_namespace::regex_constants::error_type>::value));
global_regex_namespace::regex_constants::error_type e1 = global_regex_namespace::regex_constants::error_collate;
ignore_unused_variable_warning(e1);
e1 = global_regex_namespace::regex_constants::error_ctype;
ignore_unused_variable_warning(e1);
e1 = global_regex_namespace::regex_constants::error_escape;
ignore_unused_variable_warning(e1);
e1 = global_regex_namespace::regex_constants::error_backref;
ignore_unused_variable_warning(e1);
e1 = global_regex_namespace::regex_constants::error_brack;
ignore_unused_variable_warning(e1);
e1 = global_regex_namespace::regex_constants::error_paren;
ignore_unused_variable_warning(e1);
e1 = global_regex_namespace::regex_constants::error_brace;
ignore_unused_variable_warning(e1);
e1 = global_regex_namespace::regex_constants::error_badbrace;
ignore_unused_variable_warning(e1);
e1 = global_regex_namespace::regex_constants::error_range;
ignore_unused_variable_warning(e1);
e1 = global_regex_namespace::regex_constants::error_space;
ignore_unused_variable_warning(e1);
e1 = global_regex_namespace::regex_constants::error_badrepeat;
ignore_unused_variable_warning(e1);
e1 = global_regex_namespace::regex_constants::error_complexity;
ignore_unused_variable_warning(e1);
e1 = global_regex_namespace::regex_constants::error_stack;
ignore_unused_variable_warning(e1);
BOOST_STATIC_ASSERT((::boost::is_base_and_derived<std::runtime_error, global_regex_namespace::regex_error>::value ));
const global_regex_namespace::regex_error except(e1);
e1 = except.code();
typedef typename Regex::value_type regex_value_type;
function_requires< RegexTraitsConcept<global_regex_namespace::regex_traits<char> > >();
function_requires< BaseRegexConcept<global_regex_namespace::basic_regex<char> > >();
}
void constraints()
{
global_constraints();
BOOST_STATIC_ASSERT((::boost::is_same< flag_type, global_regex_namespace::regex_constants::syntax_option_type>::value));
flag_type opts
= Regex::icase
| Regex::nosubs
| Regex::optimize
| Regex::collate
| Regex::ECMAScript
| Regex::basic
| Regex::extended
| Regex::awk
| Regex::grep
| Regex::egrep;
ignore_unused_variable_warning(opts);
function_requires<DefaultConstructibleConcept<Regex> >();
function_requires<CopyConstructibleConcept<Regex> >();
// Regex constructors:
Regex e1(m_pointer);
ignore_unused_variable_warning(e1);
Regex e2(m_pointer, m_flags);
ignore_unused_variable_warning(e2);
Regex e3(m_pointer, m_size, m_flags);
ignore_unused_variable_warning(e3);
Regex e4(in1, in2);
ignore_unused_variable_warning(e4);
Regex e5(in1, in2, m_flags);
ignore_unused_variable_warning(e5);
// assign etc:
Regex e;
e = m_pointer;
e = e1;
e.assign(e1);
e.assign(m_pointer);
e.assign(m_pointer, m_flags);
e.assign(m_pointer, m_size, m_flags);
e.assign(in1, in2);
e.assign(in1, in2, m_flags);
// access:
const Regex ce;
typename Regex::size_type i = ce.mark_count();
ignore_unused_variable_warning(i);
m_flags = ce.flags();
e.imbue(ce.getloc());
e.swap(e1);
global_regex_namespace::swap(e, e1);
// sub_match:
BOOST_STATIC_ASSERT((::boost::is_base_and_derived<std::pair<BidiIterator, BidiIterator>, sub_match_type>::value));
typedef typename sub_match_type::value_type sub_value_type;
typedef typename sub_match_type::difference_type sub_diff_type;
typedef typename sub_match_type::iterator sub_iter_type;
BOOST_STATIC_ASSERT((::boost::is_same<sub_value_type, value_type>::value));
BOOST_STATIC_ASSERT((::boost::is_same<sub_iter_type, BidiIterator>::value));
bool b = m_sub.matched;
ignore_unused_variable_warning(b);
BidiIterator bi = m_sub.first;
ignore_unused_variable_warning(bi);
bi = m_sub.second;
ignore_unused_variable_warning(bi);
sub_diff_type diff = m_sub.length();
ignore_unused_variable_warning(diff);
// match_results tests:
typedef typename match_results_type::value_type mr_value_type;
typedef typename match_results_type::const_reference mr_const_reference;
typedef typename match_results_type::reference mr_reference;
typedef typename match_results_type::const_iterator mr_const_iterator;
typedef typename match_results_type::iterator mr_iterator;
typedef typename match_results_type::difference_type mr_difference_type;
typedef typename match_results_type::size_type mr_size_type;
typedef typename match_results_type::allocator_type mr_allocator_type;
typedef typename match_results_type::char_type mr_char_type;
typedef typename match_results_type::string_type mr_string_type;
match_results_type m1;
mr_allocator_type at;
match_results_type m2(at);
match_results_type m3(m1);
m1 = m2;
int ival = 0;
mr_size_type mrs = m_cresults.size();
ignore_unused_variable_warning(mrs);
mrs = m_cresults.max_size();
ignore_unused_variable_warning(mrs);
b = m_cresults.empty();
ignore_unused_variable_warning(b);
mr_difference_type mrd = m_cresults.length();
ignore_unused_variable_warning(mrd);
mrd = m_cresults.length(ival);
ignore_unused_variable_warning(mrd);
mrd = m_cresults.position();
ignore_unused_variable_warning(mrd);
mrd = m_cresults.position(mrs);
ignore_unused_variable_warning(mrd);
mr_const_reference mrcr = m_cresults[ival];
ignore_unused_variable_warning(mrcr);
mr_const_reference mrcr2 = m_cresults.prefix();
ignore_unused_variable_warning(mrcr2);
mr_const_reference mrcr3 = m_cresults.suffix();
ignore_unused_variable_warning(mrcr3);
mr_const_iterator mrci = m_cresults.begin();
ignore_unused_variable_warning(mrci);
mrci = m_cresults.end();
ignore_unused_variable_warning(mrci);
mr_allocator_type at2 = m_cresults.get_allocator();
m_results.swap(m_results);
global_regex_namespace::swap(m_results, m_results);
// regex_match:
b = global_regex_namespace::regex_match(m_in, m_in, m_results, e);
ignore_unused_variable_warning(b);
b = global_regex_namespace::regex_match(m_in, m_in, m_results, e, m_mft);
ignore_unused_variable_warning(b);
b = global_regex_namespace::regex_match(m_in, m_in, e);
ignore_unused_variable_warning(b);
b = global_regex_namespace::regex_match(m_in, m_in, e, m_mft);
ignore_unused_variable_warning(b);
b = global_regex_namespace::regex_match(m_pointer, m_pmatch, e);
ignore_unused_variable_warning(b);
b = global_regex_namespace::regex_match(m_pointer, m_pmatch, e, m_mft);
ignore_unused_variable_warning(b);
b = global_regex_namespace::regex_match(m_pointer, e);
ignore_unused_variable_warning(b);
b = global_regex_namespace::regex_match(m_pointer, e, m_mft);
ignore_unused_variable_warning(b);
// regex_search:
b = global_regex_namespace::regex_search(m_in, m_in, m_results, e);
ignore_unused_variable_warning(b);
b = global_regex_namespace::regex_search(m_in, m_in, m_results, e, m_mft);
ignore_unused_variable_warning(b);
b = global_regex_namespace::regex_search(m_in, m_in, e);
ignore_unused_variable_warning(b);
b = global_regex_namespace::regex_search(m_in, m_in, e, m_mft);
ignore_unused_variable_warning(b);
b = global_regex_namespace::regex_search(m_pointer, m_pmatch, e);
ignore_unused_variable_warning(b);
b = global_regex_namespace::regex_search(m_pointer, m_pmatch, e, m_mft);
ignore_unused_variable_warning(b);
b = global_regex_namespace::regex_search(m_pointer, e);
ignore_unused_variable_warning(b);
b = global_regex_namespace::regex_search(m_pointer, e, m_mft);
ignore_unused_variable_warning(b);
// regex_iterator:
typedef typename regex_iterator_type::regex_type rit_regex_type;
typedef typename regex_iterator_type::value_type rit_value_type;
typedef typename regex_iterator_type::difference_type rit_difference_type;
typedef typename regex_iterator_type::pointer rit_pointer;
typedef typename regex_iterator_type::reference rit_reference;
typedef typename regex_iterator_type::iterator_category rit_iterator_category;
BOOST_STATIC_ASSERT((::boost::is_same<rit_regex_type, Regex>::value));
BOOST_STATIC_ASSERT((::boost::is_same<rit_value_type, match_results_default_type>::value));
BOOST_STATIC_ASSERT((::boost::is_same<rit_difference_type, std::ptrdiff_t>::value));
BOOST_STATIC_ASSERT((::boost::is_same<rit_pointer, const match_results_default_type*>::value));
BOOST_STATIC_ASSERT((::boost::is_same<rit_reference, const match_results_default_type&>::value));
BOOST_STATIC_ASSERT((::boost::is_convertible<rit_iterator_category*, std::forward_iterator_tag*>::value));
// this takes care of most of the checks needed:
function_requires<ForwardIteratorConcept<regex_iterator_type> >();
regex_iterator_type iter1(m_in, m_in, e);
ignore_unused_variable_warning(iter1);
regex_iterator_type iter2(m_in, m_in, e, m_mft);
ignore_unused_variable_warning(iter2);
// regex_token_iterator:
typedef typename regex_token_iterator_type::regex_type rtit_regex_type;
typedef typename regex_token_iterator_type::value_type rtit_value_type;
typedef typename regex_token_iterator_type::difference_type rtit_difference_type;
typedef typename regex_token_iterator_type::pointer rtit_pointer;
typedef typename regex_token_iterator_type::reference rtit_reference;
typedef typename regex_token_iterator_type::iterator_category rtit_iterator_category;
BOOST_STATIC_ASSERT((::boost::is_same<rtit_regex_type, Regex>::value));
BOOST_STATIC_ASSERT((::boost::is_same<rtit_value_type, sub_match_type>::value));
BOOST_STATIC_ASSERT((::boost::is_same<rtit_difference_type, std::ptrdiff_t>::value));
BOOST_STATIC_ASSERT((::boost::is_same<rtit_pointer, const sub_match_type*>::value));
BOOST_STATIC_ASSERT((::boost::is_same<rtit_reference, const sub_match_type&>::value));
BOOST_STATIC_ASSERT((::boost::is_convertible<rtit_iterator_category*, std::forward_iterator_tag*>::value));
// this takes care of most of the checks needed:
function_requires<ForwardIteratorConcept<regex_token_iterator_type> >();
regex_token_iterator_type ti1(m_in, m_in, e);
ignore_unused_variable_warning(ti1);
regex_token_iterator_type ti2(m_in, m_in, e, 0);
ignore_unused_variable_warning(ti2);
regex_token_iterator_type ti3(m_in, m_in, e, 0, m_mft);
ignore_unused_variable_warning(ti3);
std::vector<int> subs;
regex_token_iterator_type ti4(m_in, m_in, e, subs);
ignore_unused_variable_warning(ti4);
regex_token_iterator_type ti5(m_in, m_in, e, subs, m_mft);
ignore_unused_variable_warning(ti5);
static const int i_array[3] = { 1, 2, 3, };
regex_token_iterator_type ti6(m_in, m_in, e, i_array);
ignore_unused_variable_warning(ti6);
regex_token_iterator_type ti7(m_in, m_in, e, i_array, m_mft);
ignore_unused_variable_warning(ti7);
}
pointer_type m_pointer;
flag_type m_flags;
std::size_t m_size;
input_iterator_type in1, in2;
const sub_match_type m_sub;
const value_type m_char;
match_results_type m_results;
const match_results_type m_cresults;
OutIterator m_out;
BidiIterator m_in;
global_regex_namespace::regex_constants::match_flag_type m_mft;
global_regex_namespace::match_results<
pointer_type,
allocator_architype<global_regex_namespace::sub_match<pointer_type> > >
m_pmatch;
BaseRegexConcept();
BaseRegexConcept(const BaseRegexConcept&);
BaseRegexConcept& operator=(const BaseRegexConcept&);
};
//
// RegexConcept:
// Test every interface in the std:
//
template <class Regex>
struct RegexConcept
{
typedef typename Regex::value_type value_type;
//typedef typename Regex::size_type size_type;
typedef typename Regex::flag_type flag_type;
typedef typename Regex::locale_type locale_type;
// derived test types:
typedef const value_type* pointer_type;
typedef std::basic_string<value_type> string_type;
typedef boost::bidirectional_iterator_archetype<value_type> BidiIterator;
typedef global_regex_namespace::sub_match<BidiIterator> sub_match_type;
typedef global_regex_namespace::match_results<BidiIterator, allocator_architype<sub_match_type> > match_results_type;
typedef output_iterator_archetype<value_type> OutIterator;
void constraints()
{
function_requires<BaseRegexConcept<Regex> >();
// string based construct:
Regex e1(m_string);
ignore_unused_variable_warning(e1);
Regex e2(m_string, m_flags);
ignore_unused_variable_warning(e2);
// assign etc:
Regex e;
e = m_string;
e.assign(m_string);
e.assign(m_string, m_flags);
// sub_match:
string_type s(m_sub);
ignore_unused_variable_warning(s);
s = m_sub.str();
ignore_unused_variable_warning(s);
int i = m_sub.compare(m_string);
ignore_unused_variable_warning(i);
int i2 = m_sub.compare(m_sub);
ignore_unused_variable_warning(i2);
i2 = m_sub.compare(m_pointer);
ignore_unused_variable_warning(i2);
bool b = m_sub == m_sub;
ignore_unused_variable_warning(b);
b = m_sub != m_sub;
ignore_unused_variable_warning(b);
b = m_sub <= m_sub;
ignore_unused_variable_warning(b);
b = m_sub <= m_sub;
ignore_unused_variable_warning(b);
b = m_sub > m_sub;
ignore_unused_variable_warning(b);
b = m_sub >= m_sub;
ignore_unused_variable_warning(b);
b = m_sub == m_pointer;
ignore_unused_variable_warning(b);
b = m_sub != m_pointer;
ignore_unused_variable_warning(b);
b = m_sub <= m_pointer;
ignore_unused_variable_warning(b);
b = m_sub <= m_pointer;
ignore_unused_variable_warning(b);
b = m_sub > m_pointer;
ignore_unused_variable_warning(b);
b = m_sub >= m_pointer;
ignore_unused_variable_warning(b);
b = m_pointer == m_sub;
ignore_unused_variable_warning(b);
b = m_pointer != m_sub;
ignore_unused_variable_warning(b);
b = m_pointer <= m_sub;
ignore_unused_variable_warning(b);
b = m_pointer <= m_sub;
ignore_unused_variable_warning(b);
b = m_pointer > m_sub;
ignore_unused_variable_warning(b);
b = m_pointer >= m_sub;
ignore_unused_variable_warning(b);
b = m_sub == m_char;
ignore_unused_variable_warning(b);
b = m_sub != m_char;
ignore_unused_variable_warning(b);
b = m_sub <= m_char;
ignore_unused_variable_warning(b);
b = m_sub <= m_char;
ignore_unused_variable_warning(b);
b = m_sub > m_char;
ignore_unused_variable_warning(b);
b = m_sub >= m_char;
ignore_unused_variable_warning(b);
b = m_char == m_sub;
ignore_unused_variable_warning(b);
b = m_char != m_sub;
ignore_unused_variable_warning(b);
b = m_char <= m_sub;
ignore_unused_variable_warning(b);
b = m_char <= m_sub;
ignore_unused_variable_warning(b);
b = m_char > m_sub;
ignore_unused_variable_warning(b);
b = m_char >= m_sub;
ignore_unused_variable_warning(b);
b = m_sub == m_string;
ignore_unused_variable_warning(b);
b = m_sub != m_string;
ignore_unused_variable_warning(b);
b = m_sub <= m_string;
ignore_unused_variable_warning(b);
b = m_sub <= m_string;
ignore_unused_variable_warning(b);
b = m_sub > m_string;
ignore_unused_variable_warning(b);
b = m_sub >= m_string;
ignore_unused_variable_warning(b);
b = m_string == m_sub;
ignore_unused_variable_warning(b);
b = m_string != m_sub;
ignore_unused_variable_warning(b);
b = m_string <= m_sub;
ignore_unused_variable_warning(b);
b = m_string <= m_sub;
ignore_unused_variable_warning(b);
b = m_string > m_sub;
ignore_unused_variable_warning(b);
b = m_string >= m_sub;
ignore_unused_variable_warning(b);
// match results:
m_string = m_results.str();
ignore_unused_variable_warning(m_string);
m_string = m_results.str(0);
ignore_unused_variable_warning(m_string);
m_out = m_cresults.format(m_out, m_string);
m_out = m_cresults.format(m_out, m_string, m_mft);
m_string = m_cresults.format(m_string);
ignore_unused_variable_warning(m_string);
m_string = m_cresults.format(m_string, m_mft);
ignore_unused_variable_warning(m_string);
// regex_match:
b = global_regex_namespace::regex_match(m_string, m_smatch, e);
ignore_unused_variable_warning(b);
b = global_regex_namespace::regex_match(m_string, m_smatch, e, m_mft);
ignore_unused_variable_warning(b);
b = global_regex_namespace::regex_match(m_string, e);
ignore_unused_variable_warning(b);
b = global_regex_namespace::regex_match(m_string, e, m_mft);
ignore_unused_variable_warning(b);
// regex_search:
b = global_regex_namespace::regex_search(m_string, m_smatch, e);
ignore_unused_variable_warning(b);
b = global_regex_namespace::regex_search(m_string, m_smatch, e, m_mft);
ignore_unused_variable_warning(b);
b = global_regex_namespace::regex_search(m_string, e);
ignore_unused_variable_warning(b);
b = global_regex_namespace::regex_search(m_string, e, m_mft);
ignore_unused_variable_warning(b);
// regex_replace:
m_out = global_regex_namespace::regex_replace(m_out, m_in, m_in, e, m_string, m_mft);
m_out = global_regex_namespace::regex_replace(m_out, m_in, m_in, e, m_string);
m_string = global_regex_namespace::regex_replace(m_string, e, m_string, m_mft);
ignore_unused_variable_warning(m_string);
m_string = global_regex_namespace::regex_replace(m_string, e, m_string);
ignore_unused_variable_warning(m_string);
}
flag_type m_flags;
string_type m_string;
const sub_match_type m_sub;
match_results_type m_results;
pointer_type m_pointer;
value_type m_char;
const match_results_type m_cresults;
OutIterator m_out;
BidiIterator m_in;
global_regex_namespace::regex_constants::match_flag_type m_mft;
global_regex_namespace::match_results<typename string_type::const_iterator, allocator_architype<global_regex_namespace::sub_match<typename string_type::const_iterator> > > m_smatch;
RegexConcept();
RegexConcept(const RegexConcept&);
RegexConcept& operator=(const RegexConcept&);
};
#ifndef BOOST_REGEX_TEST_STD
template <class M>
struct functor1
{
typedef typename M::char_type char_type;
const char_type* operator()(const M&)const
{
static const char_type c = static_cast<char_type>(0);
return &c;
}
};
template <class M>
struct functor1b
{
typedef typename M::char_type char_type;
std::vector<char_type> operator()(const M&)const
{
static const std::vector<char_type> c;
return c;
}
};
template <class M>
struct functor2
{
template <class O>
O operator()(const M& /*m*/, O i)const
{
return i;
}
};
template <class M>
struct functor3
{
template <class O>
O operator()(const M& /*m*/, O i, regex_constants::match_flag_type)const
{
return i;
}
};
//
// BoostRegexConcept:
// Test every interface in the Boost implementation:
//
template <class Regex>
struct BoostRegexConcept
{
typedef typename Regex::value_type value_type;
typedef typename Regex::size_type size_type;
typedef typename Regex::flag_type flag_type;
typedef typename Regex::locale_type locale_type;
// derived test types:
typedef const value_type* pointer_type;
typedef std::basic_string<value_type> string_type;
typedef typename Regex::const_iterator const_iterator;
typedef bidirectional_iterator_archetype<value_type> BidiIterator;
typedef output_iterator_archetype<value_type> OutputIterator;
typedef global_regex_namespace::sub_match<BidiIterator> sub_match_type;
typedef global_regex_namespace::match_results<BidiIterator, allocator_architype<sub_match_type> > match_results_type;
typedef global_regex_namespace::match_results<BidiIterator> match_results_default_type;
void constraints()
{
global_regex_namespace::regex_constants::match_flag_type mopts
= global_regex_namespace::regex_constants::match_default
| global_regex_namespace::regex_constants::match_not_bol
| global_regex_namespace::regex_constants::match_not_eol
| global_regex_namespace::regex_constants::match_not_bow
| global_regex_namespace::regex_constants::match_not_eow
| global_regex_namespace::regex_constants::match_any
| global_regex_namespace::regex_constants::match_not_null
| global_regex_namespace::regex_constants::match_continuous
| global_regex_namespace::regex_constants::match_partial
| global_regex_namespace::regex_constants::match_prev_avail
| global_regex_namespace::regex_constants::format_default
| global_regex_namespace::regex_constants::format_sed
| global_regex_namespace::regex_constants::format_perl
| global_regex_namespace::regex_constants::format_no_copy
| global_regex_namespace::regex_constants::format_first_only;
(void)mopts;
function_requires<RegexConcept<Regex> >();
const global_regex_namespace::regex_error except(global_regex_namespace::regex_constants::error_collate);
std::ptrdiff_t pt = except.position();
ignore_unused_variable_warning(pt);
const Regex ce, ce2;
#ifndef BOOST_NO_STD_LOCALE
m_stream << ce;
#endif
unsigned i = ce.error_code();
ignore_unused_variable_warning(i);
pointer_type p = ce.expression();
ignore_unused_variable_warning(p);
int i2 = ce.compare(ce2);
ignore_unused_variable_warning(i2);
bool b = ce == ce2;
ignore_unused_variable_warning(b);
b = ce.empty();
ignore_unused_variable_warning(b);
b = ce != ce2;
ignore_unused_variable_warning(b);
b = ce < ce2;
ignore_unused_variable_warning(b);
b = ce > ce2;
ignore_unused_variable_warning(b);
b = ce <= ce2;
ignore_unused_variable_warning(b);
b = ce >= ce2;
ignore_unused_variable_warning(b);
i = ce.status();
ignore_unused_variable_warning(i);
size_type s = ce.max_size();
ignore_unused_variable_warning(s);
s = ce.size();
ignore_unused_variable_warning(s);
const_iterator pi = ce.begin();
ignore_unused_variable_warning(pi);
pi = ce.end();
ignore_unused_variable_warning(pi);
string_type s2 = ce.str();
ignore_unused_variable_warning(s2);
m_string = m_sub + m_sub;
ignore_unused_variable_warning(m_string);
m_string = m_sub + m_pointer;
ignore_unused_variable_warning(m_string);
m_string = m_pointer + m_sub;
ignore_unused_variable_warning(m_string);
m_string = m_sub + m_string;
ignore_unused_variable_warning(m_string);
m_string = m_string + m_sub;
ignore_unused_variable_warning(m_string);
m_string = m_sub + m_char;
ignore_unused_variable_warning(m_string);
m_string = m_char + m_sub;
ignore_unused_variable_warning(m_string);
// Named sub-expressions:
m_sub = m_cresults[&m_char];
ignore_unused_variable_warning(m_sub);
m_sub = m_cresults[m_string];
ignore_unused_variable_warning(m_sub);
m_sub = m_cresults[""];
ignore_unused_variable_warning(m_sub);
m_sub = m_cresults[std::string("")];
ignore_unused_variable_warning(m_sub);
m_string = m_cresults.str(&m_char);
ignore_unused_variable_warning(m_string);
m_string = m_cresults.str(m_string);
ignore_unused_variable_warning(m_string);
m_string = m_cresults.str("");
ignore_unused_variable_warning(m_string);
m_string = m_cresults.str(std::string(""));
ignore_unused_variable_warning(m_string);
typename match_results_type::difference_type diff;
diff = m_cresults.length(&m_char);
ignore_unused_variable_warning(diff);
diff = m_cresults.length(m_string);
ignore_unused_variable_warning(diff);
diff = m_cresults.length("");
ignore_unused_variable_warning(diff);
diff = m_cresults.length(std::string(""));
ignore_unused_variable_warning(diff);
diff = m_cresults.position(&m_char);
ignore_unused_variable_warning(diff);
diff = m_cresults.position(m_string);
ignore_unused_variable_warning(diff);
diff = m_cresults.position("");
ignore_unused_variable_warning(diff);
diff = m_cresults.position(std::string(""));
ignore_unused_variable_warning(diff);
#ifndef BOOST_NO_STD_LOCALE
m_stream << m_sub;
m_stream << m_cresults;
#endif
//
// Extended formatting with a functor:
//
regex_constants::match_flag_type f = regex_constants::match_default;
OutputIterator out = static_object<OutputIterator>::get();
functor3<match_results_default_type> func3;
functor2<match_results_default_type> func2;
functor1<match_results_default_type> func1;
functor3<match_results_type> func3b;
functor2<match_results_type> func2b;
functor1<match_results_type> func1b;
out = regex_format(out, m_cresults, func3b, f);
out = regex_format(out, m_cresults, func3b);
out = regex_format(out, m_cresults, func2b, f);
out = regex_format(out, m_cresults, func2b);
out = regex_format(out, m_cresults, func1b, f);
out = regex_format(out, m_cresults, func1b);
out = regex_format(out, m_cresults, boost::ref(func3b), f);
out = regex_format(out, m_cresults, boost::ref(func3b));
out = regex_format(out, m_cresults, boost::ref(func2b), f);
out = regex_format(out, m_cresults, boost::ref(func2b));
out = regex_format(out, m_cresults, boost::ref(func1b), f);
out = regex_format(out, m_cresults, boost::ref(func1b));
out = regex_format(out, m_cresults, boost::cref(func3b), f);
out = regex_format(out, m_cresults, boost::cref(func3b));
out = regex_format(out, m_cresults, boost::cref(func2b), f);
out = regex_format(out, m_cresults, boost::cref(func2b));
out = regex_format(out, m_cresults, boost::cref(func1b), f);
out = regex_format(out, m_cresults, boost::cref(func1b));
m_string += regex_format(m_cresults, func3b, f);
m_string += regex_format(m_cresults, func3b);
m_string += regex_format(m_cresults, func2b, f);
m_string += regex_format(m_cresults, func2b);
m_string += regex_format(m_cresults, func1b, f);
m_string += regex_format(m_cresults, func1b);
m_string += regex_format(m_cresults, boost::ref(func3b), f);
m_string += regex_format(m_cresults, boost::ref(func3b));
m_string += regex_format(m_cresults, boost::ref(func2b), f);
m_string += regex_format(m_cresults, boost::ref(func2b));
m_string += regex_format(m_cresults, boost::ref(func1b), f);
m_string += regex_format(m_cresults, boost::ref(func1b));
m_string += regex_format(m_cresults, boost::cref(func3b), f);
m_string += regex_format(m_cresults, boost::cref(func3b));
m_string += regex_format(m_cresults, boost::cref(func2b), f);
m_string += regex_format(m_cresults, boost::cref(func2b));
m_string += regex_format(m_cresults, boost::cref(func1b), f);
m_string += regex_format(m_cresults, boost::cref(func1b));
out = m_cresults.format(out, func3b, f);
out = m_cresults.format(out, func3b);
out = m_cresults.format(out, func2b, f);
out = m_cresults.format(out, func2b);
out = m_cresults.format(out, func1b, f);
out = m_cresults.format(out, func1b);
out = m_cresults.format(out, boost::ref(func3b), f);
out = m_cresults.format(out, boost::ref(func3b));
out = m_cresults.format(out, boost::ref(func2b), f);
out = m_cresults.format(out, boost::ref(func2b));
out = m_cresults.format(out, boost::ref(func1b), f);
out = m_cresults.format(out, boost::ref(func1b));
out = m_cresults.format(out, boost::cref(func3b), f);
out = m_cresults.format(out, boost::cref(func3b));
out = m_cresults.format(out, boost::cref(func2b), f);
out = m_cresults.format(out, boost::cref(func2b));
out = m_cresults.format(out, boost::cref(func1b), f);
out = m_cresults.format(out, boost::cref(func1b));
m_string += m_cresults.format(func3b, f);
m_string += m_cresults.format(func3b);
m_string += m_cresults.format(func2b, f);
m_string += m_cresults.format(func2b);
m_string += m_cresults.format(func1b, f);
m_string += m_cresults.format(func1b);
m_string += m_cresults.format(boost::ref(func3b), f);
m_string += m_cresults.format(boost::ref(func3b));
m_string += m_cresults.format(boost::ref(func2b), f);
m_string += m_cresults.format(boost::ref(func2b));
m_string += m_cresults.format(boost::ref(func1b), f);
m_string += m_cresults.format(boost::ref(func1b));
m_string += m_cresults.format(boost::cref(func3b), f);
m_string += m_cresults.format(boost::cref(func3b));
m_string += m_cresults.format(boost::cref(func2b), f);
m_string += m_cresults.format(boost::cref(func2b));
m_string += m_cresults.format(boost::cref(func1b), f);
m_string += m_cresults.format(boost::cref(func1b));
out = regex_replace(out, m_in, m_in, ce, func3, f);
out = regex_replace(out, m_in, m_in, ce, func3);
out = regex_replace(out, m_in, m_in, ce, func2, f);
out = regex_replace(out, m_in, m_in, ce, func2);
out = regex_replace(out, m_in, m_in, ce, func1, f);
out = regex_replace(out, m_in, m_in, ce, func1);
out = regex_replace(out, m_in, m_in, ce, boost::ref(func3), f);
out = regex_replace(out, m_in, m_in, ce, boost::ref(func3));
out = regex_replace(out, m_in, m_in, ce, boost::ref(func2), f);
out = regex_replace(out, m_in, m_in, ce, boost::ref(func2));
out = regex_replace(out, m_in, m_in, ce, boost::ref(func1), f);
out = regex_replace(out, m_in, m_in, ce, boost::ref(func1));
out = regex_replace(out, m_in, m_in, ce, boost::cref(func3), f);
out = regex_replace(out, m_in, m_in, ce, boost::cref(func3));
out = regex_replace(out, m_in, m_in, ce, boost::cref(func2), f);
out = regex_replace(out, m_in, m_in, ce, boost::cref(func2));
out = regex_replace(out, m_in, m_in, ce, boost::cref(func1), f);
out = regex_replace(out, m_in, m_in, ce, boost::cref(func1));
functor3<match_results<typename string_type::const_iterator> > func3s;
functor2<match_results<typename string_type::const_iterator> > func2s;
functor1<match_results<typename string_type::const_iterator> > func1s;
m_string += regex_replace(m_string, ce, func3s, f);
m_string += regex_replace(m_string, ce, func3s);
m_string += regex_replace(m_string, ce, func2s, f);
m_string += regex_replace(m_string, ce, func2s);
m_string += regex_replace(m_string, ce, func1s, f);
m_string += regex_replace(m_string, ce, func1s);
m_string += regex_replace(m_string, ce, boost::ref(func3s), f);
m_string += regex_replace(m_string, ce, boost::ref(func3s));
m_string += regex_replace(m_string, ce, boost::ref(func2s), f);
m_string += regex_replace(m_string, ce, boost::ref(func2s));
m_string += regex_replace(m_string, ce, boost::ref(func1s), f);
m_string += regex_replace(m_string, ce, boost::ref(func1s));
m_string += regex_replace(m_string, ce, boost::cref(func3s), f);
m_string += regex_replace(m_string, ce, boost::cref(func3s));
m_string += regex_replace(m_string, ce, boost::cref(func2s), f);
m_string += regex_replace(m_string, ce, boost::cref(func2s));
m_string += regex_replace(m_string, ce, boost::cref(func1s), f);
m_string += regex_replace(m_string, ce, boost::cref(func1s));
}
std::basic_ostream<value_type> m_stream;
sub_match_type m_sub;
pointer_type m_pointer;
string_type m_string;
const value_type m_char;
match_results_type m_results;
const match_results_type m_cresults;
BidiIterator m_in;
BoostRegexConcept();
BoostRegexConcept(const BoostRegexConcept&);
BoostRegexConcept& operator=(const BoostRegexConcept&);
};
#endif // BOOST_REGEX_TEST_STD
}
#endif