mapnik/boost/property_tree/detail/ptree_implementation.hpp

1001 lines
32 KiB
C++

// ----------------------------------------------------------------------------
// Copyright (C) 2002-2005 Marcin Kalicinski
//
// Distributed under 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)
//
// For more information, see www.boost.org
// ----------------------------------------------------------------------------
#ifndef BOOST_PROPERTY_TREE_DETAIL_PTREE_IMPLEMENTATION_HPP_INCLUDED
#define BOOST_PROPERTY_TREE_DETAIL_PTREE_IMPLEMENTATION_HPP_INCLUDED
#include <sstream>
#include <locale>
#include <algorithm>
#include <limits>
#include <stdexcept>
#include <functional> // for std::less
#include <memory> // for std::auto_ptr
#include <boost/assert.hpp>
#include <boost/static_assert.hpp>
#include <boost/type_traits.hpp>
#include <boost/utility.hpp> // for boost::prior
#include <boost/property_tree/detail/ptree_utils.hpp>
//////////////////////////////////////////////////////////////////////////////
// Debug macros
#ifdef BOOST_PROPERTY_TREE_DEBUG
// Increment instances counter
#define BOOST_PROPERTY_TREE_DEBUG_INCREMENT_INSTANCES_COUNT() \
{ \
typedef boost::detail::lightweight_mutex::scoped_lock lock; \
lock l(debug_mutex); \
++debug_instances_count; \
}
// Decrement instances counter
#define BOOST_PROPERTY_TREE_DEBUG_DECREMENT_INSTANCES_COUNT() \
{ \
typedef boost::detail::lightweight_mutex::scoped_lock lock; \
lock l(debug_mutex); \
BOOST_ASSERT(debug_instances_count > 0); \
--debug_instances_count; \
}
#else // BOOST_PROPERTY_TREE_DEBUG
#define BOOST_PROPERTY_TREE_DEBUG_INCREMENT_INSTANCES_COUNT() static_cast<void>(0)
#define BOOST_PROPERTY_TREE_DEBUG_DECREMENT_INSTANCES_COUNT() static_cast<void>(0)
#endif // BOOST_PROPERTY_TREE_DEBUG
namespace boost { namespace property_tree
{
namespace detail
{
template<class T>
struct array_to_pointer_decay
{
typedef T type;
};
template<class T, std::size_t N>
struct array_to_pointer_decay<T[N]>
{
typedef const T *type;
};
////////////////////////////////////////////////////////////////////////////
// Extractor and inserter
template<class Ch, class Type>
struct extractor
{
inline bool operator()(const std::basic_string<Ch> &data,
Type &extracted,
const std::locale &loc) const
{
std::basic_istringstream<Ch> stream(data);
stream.imbue(loc);
stream >> extracted >> std::ws;
return stream.eof() && !stream.fail() && !stream.bad();
}
};
template<class Ch>
struct extractor<Ch, std::basic_string<Ch> >
{
inline bool operator()(const std::basic_string<Ch> &data,
std::basic_string<Ch> &extracted,
const std::locale &loc) const
{
extracted = data;
return true;
}
};
template<class Ch, class Type>
struct inserter
{
inline bool operator()(std::basic_string<Ch> &data,
const Type &to_insert,
const std::locale &loc) const
{
typedef typename detail::array_to_pointer_decay<Type>::type Type2;
std::basic_ostringstream<Ch> stream;
stream.imbue(loc);
if (std::numeric_limits<Type2>::is_specialized)
stream.precision(std::numeric_limits<Type2>::digits10 + 1);
stream << to_insert;
data = stream.str();
return !stream.fail() && !stream.bad();
}
};
template<class Ch>
struct inserter<Ch, std::basic_string<Ch> >
{
inline bool operator()(std::basic_string<Ch> &data,
const std::basic_string<Ch> &to_insert,
const std::locale &loc) const
{
data = to_insert;
return true;
}
};
}
///////////////////////////////////////////////////////////////////////////
// Impl
template<class Tr>
struct basic_ptree<Tr>::impl
{
data_type m_data;
container_type m_container;
index_type m_index;
};
////////////////////////////////////////////////////////////////////////////
// Traits
template<class Ch>
struct ptree_traits
{
typedef Ch char_type;
typedef std::basic_string<Ch> key_type;
typedef std::basic_string<Ch> data_type;
template<class Type>
struct extractor: public detail::extractor<Ch, Type> { };
template<class Type>
struct inserter: public detail::inserter<Ch, Type> { };
inline bool operator()(const key_type &key1,
const key_type &key2) const
{
return key1 < key2;
}
};
template<class Ch>
struct iptree_traits
{
std::locale loc;
typedef Ch char_type;
typedef std::basic_string<Ch> key_type;
typedef std::basic_string<Ch> data_type;
template<class Type>
struct extractor: public detail::extractor<Ch, Type> { };
template<class Type>
struct inserter: public detail::inserter<Ch, Type> { };
inline bool operator()(Ch c1, Ch c2) const // Helper for comparing characters
{
return std::toupper(c1, loc) < std::toupper(c2, loc);
}
inline bool operator()(const key_type &key1,
const key_type &key2) const
{
return std::lexicographical_compare(key1.begin(), key1.end(), key2.begin(), key2.end(), *this);
}
};
///////////////////////////////////////////////////////////////////////////
// Exceptions
class ptree_error: public std::runtime_error
{
public:
ptree_error(const std::string &what): std::runtime_error(what) { }
~ptree_error() throw() { }
};
class ptree_bad_data: public ptree_error
{
public:
ptree_bad_data(const std::string &what): ptree_error(what) { }
~ptree_bad_data() throw() { }
};
class ptree_bad_path: public ptree_error
{
public:
ptree_bad_path(const std::string &what): ptree_error(what) { }
~ptree_bad_path() throw() { }
};
///////////////////////////////////////////////////////////////////////////
// Construction & destruction
template<class Tr>
basic_ptree<Tr>::basic_ptree()
{
m_impl = new impl;
BOOST_PROPERTY_TREE_DEBUG_INCREMENT_INSTANCES_COUNT();
}
template<class Tr>
basic_ptree<Tr>::basic_ptree(const data_type &rhs)
{
std::auto_ptr<impl> tmp(new impl);
tmp->m_data = rhs;
m_impl = tmp.release();
BOOST_PROPERTY_TREE_DEBUG_INCREMENT_INSTANCES_COUNT();
}
template<class Tr>
basic_ptree<Tr>::basic_ptree(const basic_ptree<Tr> &rhs)
{
std::auto_ptr<impl> tmp(new impl);
tmp->m_data = rhs.data();
m_impl = tmp.get();
insert(end(), rhs.begin(), rhs.end());
tmp.release();
BOOST_PROPERTY_TREE_DEBUG_INCREMENT_INSTANCES_COUNT();
}
template<class Tr>
basic_ptree<Tr>::~basic_ptree()
{
BOOST_PROPERTY_TREE_DEBUG_DECREMENT_INSTANCES_COUNT();
delete m_impl;
}
///////////////////////////////////////////////////////////////////////////
// Iterator access
template<class Tr>
typename basic_ptree<Tr>::iterator
basic_ptree<Tr>::begin()
{
return m_impl->m_container.begin();
}
template<class Tr>
typename basic_ptree<Tr>::const_iterator
basic_ptree<Tr>::begin() const
{
return m_impl->m_container.begin();
}
template<class Tr>
typename basic_ptree<Tr>::iterator
basic_ptree<Tr>::end()
{
return m_impl->m_container.end();
}
template<class Tr>
typename basic_ptree<Tr>::const_iterator
basic_ptree<Tr>::end() const
{
return m_impl->m_container.end();
}
template<class Tr>
typename basic_ptree<Tr>::reverse_iterator
basic_ptree<Tr>::rbegin()
{
return m_impl->m_container.rbegin();
}
template<class Tr>
typename basic_ptree<Tr>::const_reverse_iterator
basic_ptree<Tr>::rbegin() const
{
return m_impl->m_container.rbegin();
}
template<class Tr>
typename basic_ptree<Tr>::reverse_iterator
basic_ptree<Tr>::rend()
{
return m_impl->m_container.rend();
}
template<class Tr>
typename basic_ptree<Tr>::const_reverse_iterator
basic_ptree<Tr>::rend() const
{
return m_impl->m_container.rend();
}
///////////////////////////////////////////////////////////////////////////
// Data access
template<class Tr>
typename basic_ptree<Tr>::size_type
basic_ptree<Tr>::size() const
{
return m_impl->m_index.size();
}
template<class Tr>
bool basic_ptree<Tr>::empty() const
{
return m_impl->m_index.empty();
}
template<class Tr>
typename basic_ptree<Tr>::data_type &
basic_ptree<Tr>::data()
{
return m_impl->m_data;
}
template<class Tr>
const typename basic_ptree<Tr>::data_type &
basic_ptree<Tr>::data() const
{
return m_impl->m_data;
}
template<class Tr>
typename basic_ptree<Tr>::value_type &
basic_ptree<Tr>::front()
{
return m_impl->m_container.front();
}
template<class Tr>
const typename basic_ptree<Tr>::value_type &
basic_ptree<Tr>::front() const
{
return m_impl->m_container.front();
}
template<class Tr>
typename basic_ptree<Tr>::value_type &
basic_ptree<Tr>::back()
{
return m_impl->m_container.back();
}
template<class Tr>
const typename basic_ptree<Tr>::value_type &
basic_ptree<Tr>::back() const
{
return m_impl->m_container.back();
}
///////////////////////////////////////////////////////////////////////////
// Operators
template<class Tr>
basic_ptree<Tr> &
basic_ptree<Tr>::operator =(const basic_ptree<Tr> &rhs)
{
if (&rhs != this)
{
clear();
data() = rhs.data();
insert(end(), rhs.begin(), rhs.end());
}
return *this;
}
template<class Tr>
bool basic_ptree<Tr>::operator ==(const basic_ptree<Tr> &rhs) const
{
// Data and sizes must be equal
if (size() != rhs.size() || data() != rhs.data())
return false;
// Keys and children must be equal
Tr tr;
const_iterator it = begin();
const_iterator it_rhs = rhs.begin();
const_iterator it_end = end();
for (; it != it_end; ++it, ++it_rhs)
if (tr(it->first, it_rhs->first) ||
tr(it_rhs->first, it->first) ||
it->second != it_rhs->second)
return false;
// Equal
return true;
}
template<class Tr>
bool basic_ptree<Tr>::operator !=(const basic_ptree<Tr> &rhs) const
{
return !operator ==(rhs);
}
///////////////////////////////////////////////////////////////////////////
// Container operations
template<class Tr>
typename basic_ptree<Tr>::iterator
basic_ptree<Tr>::find(const key_type &key)
{
typename index_type::iterator it = m_impl->m_index.find(key);
return it == m_impl->m_index.end() ? end() : it->second;
}
template<class Tr>
typename basic_ptree<Tr>::const_iterator
basic_ptree<Tr>::find(const key_type &key) const
{
typename index_type::const_iterator it = m_impl->m_index.find(key);
return it == m_impl->m_index.end() ? end() : it->second;
}
template<class Tr>
typename basic_ptree<Tr>::size_type
basic_ptree<Tr>::count(const key_type &key) const
{
return m_impl->m_index.count(key);
}
template<class Tr>
void basic_ptree<Tr>::clear()
{
m_impl->m_data = data_type();
m_impl->m_container.clear();
m_impl->m_index.clear();
}
template<class Tr>
typename basic_ptree<Tr>::iterator
basic_ptree<Tr>::insert(iterator where,
const value_type &value)
{
// Insert new value into container. If that throws nothing needs to be rolled back
where = m_impl->m_container.insert(where, value);
// Update index. If that throws we need to rollback the insert
try {
m_impl->m_index.insert(typename index_type::value_type(where->first, where));
}
catch (...) {
m_impl->m_container.erase(where); // rollback the insert
throw;
}
return where;
}
template<class Tr>
template<class It>
void basic_ptree<Tr>::insert(iterator where,
It first,
It last)
{
for (; first != last; ++first, ++where)
where = insert(where, value_type(first->first, first->second));
}
template<class Tr>
typename basic_ptree<Tr>::iterator
basic_ptree<Tr>::erase(iterator where)
{
// Remove from index
typename index_type::iterator lo = m_impl->m_index.lower_bound(where->first);
typename index_type::iterator hi = m_impl->m_index.upper_bound(where->first);
for (; lo != hi; ++lo)
if (lo->second == where)
{
m_impl->m_index.erase(lo);
break;
}
// Remove from container
return m_impl->m_container.erase(where);
}
template<class Tr>
typename basic_ptree<Tr>::size_type
basic_ptree<Tr>::erase(const key_type &key)
{
size_type count = 0;
typename index_type::iterator lo = m_impl->m_index.lower_bound(key);
if (lo != m_impl->m_index.end())
{
typename index_type::iterator hi = m_impl->m_index.upper_bound(key);
while (lo != hi)
{
typename index_type::iterator it = lo++;
erase(it->second);
++count;
}
}
return count;
}
template<class Tr>
template<class It>
typename basic_ptree<Tr>::iterator
basic_ptree<Tr>::erase(It first,
It last)
{
while (first != last)
first = erase(first);
return first;
}
template<class Tr>
typename basic_ptree<Tr>::iterator
basic_ptree<Tr>::push_front(const value_type &value)
{
return insert(begin(), value);
}
template<class Tr>
typename basic_ptree<Tr>::iterator
basic_ptree<Tr>::push_back(const value_type &value)
{
return insert(end(), value);
}
template<class Tr>
void basic_ptree<Tr>::pop_front()
{
erase(begin());
}
template<class Tr>
void basic_ptree<Tr>::pop_back()
{
erase(boost::prior(end()));
}
template<class Tr>
void basic_ptree<Tr>::swap(basic_ptree<Tr> &rhs)
{
std::swap(m_impl, rhs.m_impl);
}
template<class Tr>
void basic_ptree<Tr>::reverse()
{
m_impl->m_container.reverse();
}
template<class Tr>
template<class SortTr>
void basic_ptree<Tr>::sort(SortTr tr)
{
m_impl->m_container.sort(tr);
}
///////////////////////////////////////////////////////////////////////////
// ptree operations
// Get child ptree with custom separator
template<class Tr>
basic_ptree<Tr> &
basic_ptree<Tr>::get_child(char_type separator,
const key_type &path)
{
if (optional<basic_ptree<Tr> &> result = get_child_optional(separator, path))
return result.get();
else
throw ptree_bad_path("key \"" + detail::narrow(path.c_str()) + "\" does not exist");
}
// Get child ptree with custom separator
template<class Tr>
const basic_ptree<Tr> &
basic_ptree<Tr>::get_child(char_type separator,
const key_type &path) const
{
basic_ptree<Tr> *nc_this = const_cast<basic_ptree<Tr> *>(this);
return nc_this->get_child(separator, path);
}
// Get child ptree with custom separator
template<class Tr>
basic_ptree<Tr> &
basic_ptree<Tr>::get_child(char_type separator,
const key_type &path,
basic_ptree<Tr> &default_value)
{
if (optional<basic_ptree<Tr> &> result = get_child_optional(separator, path))
return result.get();
else
return default_value;
}
// Get child ptree with custom separator
template<class Tr>
const basic_ptree<Tr> &
basic_ptree<Tr>::get_child(char_type separator,
const key_type &path,
const basic_ptree<Tr> &default_value) const
{
basic_ptree<Tr> *nc_this = const_cast<basic_ptree<Tr> *>(this);
basic_ptree<Tr> &nc_default_value = const_cast<basic_ptree<Tr> &>(default_value);
return nc_this->get_child(separator, path, nc_default_value);
}
// Get child ptree with custom separator
template<class Tr>
optional<basic_ptree<Tr> &>
basic_ptree<Tr>::get_child_optional(char_type separator,
const key_type &path)
{
typename key_type::size_type n = path.find(separator);
if (n != key_type::npos)
{
key_type head = path.substr(0, n);
key_type tail = path.substr(n + 1, key_type::npos);
iterator it = find(head);
if (it != end())
return it->second.get_child_optional(separator, tail);
else
return optional<basic_ptree<Tr> &>();
}
else
{
iterator it = find(path);
if (it != end())
return it->second;
else
return optional<basic_ptree<Tr> &>();
}
}
// Get child ptree with custom separator
template<class Tr>
optional<const basic_ptree<Tr> &>
basic_ptree<Tr>::get_child_optional(char_type separator, const key_type &path) const
{
basic_ptree<Tr> *nc_this = const_cast<basic_ptree<Tr> *>(this);
optional<basic_ptree<Tr> &> tmp = nc_this->get_child_optional(separator, path);
if (tmp)
return optional<const basic_ptree<Tr> &>(tmp.get());
else
return optional<const basic_ptree<Tr> &>();
}
// Get child ptree with default separator
template<class Tr>
basic_ptree<Tr> &
basic_ptree<Tr>::get_child(const key_type &path)
{
return get_child(char_type('.'), path);
}
// Get child ptree with default separator
template<class Tr>
const basic_ptree<Tr> &
basic_ptree<Tr>::get_child(const key_type &path) const
{
return get_child(char_type('.'), path);
}
// Get child ptree with default separator
template<class Tr>
basic_ptree<Tr> &
basic_ptree<Tr>::get_child(const key_type &path,
basic_ptree<Tr> &default_value)
{
return get_child(char_type('.'), path, default_value);
}
// Get child ptree with default separator
template<class Tr>
const basic_ptree<Tr> &
basic_ptree<Tr>::get_child(const key_type &path,
const basic_ptree<Tr> &default_value) const
{
return get_child(char_type('.'), path, default_value);
}
// Get child ptree with default separator
template<class Tr>
optional<basic_ptree<Tr> &>
basic_ptree<Tr>::get_child_optional(const key_type &path)
{
return get_child_optional(char_type('.'), path);
}
// Get child ptree with default separator
template<class Tr>
optional<const basic_ptree<Tr> &>
basic_ptree<Tr>::get_child_optional(const key_type &path) const
{
return get_child_optional(char_type('.'), path);
}
// Put child ptree with custom separator
template<class Tr>
basic_ptree<Tr> &
basic_ptree<Tr>::put_child(char_type separator,
const key_type &path,
const basic_ptree<Tr> &value,
bool do_not_replace)
{
typename key_type::size_type n = path.find(separator);
if (n == key_type::npos)
{
if (do_not_replace)
return push_back(value_type(path, value))->second;
else
{
iterator it = find(path);
if (it == end())
return push_back(value_type(path, value))->second;
else
{
it->second = value;
return it->second;
}
}
}
else
{
key_type head = path.substr(0, n);
key_type tail = path.substr(n + 1, key_type::npos);
iterator it = find(head);
if (it == end())
it = push_back(value_type(head, basic_ptree<Tr>()));
return it->second.put_child(separator, tail, value, do_not_replace);
}
}
// Put child ptree with default separator
template<class Tr>
basic_ptree<Tr> &
basic_ptree<Tr>::put_child(const key_type &path,
const basic_ptree<Tr> &value,
bool do_not_replace)
{
return put_child(char_type('.'), path, value, do_not_replace);
}
// Get value from data of ptree
template<class Tr>
template<class Type>
Type basic_ptree<Tr>::get_own(const std::locale &loc) const
{
if (optional<Type> result = get_own_optional<Type>(loc))
return result.get();
else
throw ptree_bad_data(std::string("conversion of data into type '") +
typeid(Type).name() + "' failed");
}
// Get value from data of ptree
template<class Tr>
template<class Type>
Type basic_ptree<Tr>::get_own(const Type &default_value,
const std::locale &loc) const
{
if (optional<Type> result = get_own_optional<Type>(loc))
return result.get();
else
return default_value;
}
// Get value from data of ptree
template<class Tr>
template<class CharType>
std::basic_string<CharType>
basic_ptree<Tr>::get_own(const CharType *default_value,
const std::locale &loc) const
{
BOOST_STATIC_ASSERT((boost::is_same<char_type, CharType>::value == true)); // Character types must match
return get_own(std::basic_string<CharType>(default_value), loc);
}
// Get value from data of ptree
template<class Tr>
template<class Type>
optional<Type>
basic_ptree<Tr>::get_own_optional(const std::locale &loc) const
{
BOOST_STATIC_ASSERT(boost::is_pointer<Type>::value == false); // Disallow pointer types, they are unsafe
Type tmp;
if (typename traits_type::template extractor<Type>()(m_impl->m_data, tmp, loc))
{
return optional<Type>(tmp);
}
else
return optional<Type>();
}
// Get value from data of child ptree (custom path separator)
template<class Tr>
template<class Type>
Type basic_ptree<Tr>::get(char_type separator,
const key_type &path,
const std::locale &loc) const
{
return get_child(separator, path).get_own<Type>(loc);
}
// Get value from data of child ptree (custom path separator)
template<class Tr>
template<class Type>
Type basic_ptree<Tr>::get(char_type separator,
const key_type &path,
const Type &default_value,
const std::locale &loc) const
{
if (optional<Type> result = get_optional<Type>(separator, path, loc))
return *result;
else
return default_value;
}
// Get value from data of child ptree (custom path separator)
template<class Tr>
template<class CharType>
std::basic_string<CharType>
basic_ptree<Tr>::get(char_type separator,
const key_type &path,
const CharType *default_value,
const std::locale &loc) const
{
BOOST_STATIC_ASSERT((boost::is_same<char_type, CharType>::value == true)); // Character types must match
return get(separator, path, std::basic_string<CharType>(default_value), loc);
}
// Get value from data of child ptree (custom path separator)
template<class Tr>
template<class Type>
optional<Type>
basic_ptree<Tr>::get_optional(char_type separator,
const key_type &path,
const std::locale &loc) const
{
if (optional<const basic_ptree<Tr> &> child = get_child_optional(separator, path))
return child.get().get_own_optional<Type>(loc);
else
return optional<Type>();
}
// Get value from data of child ptree (default path separator)
template<class Tr>
template<class Type>
Type basic_ptree<Tr>::get(const key_type &path,
const std::locale &loc) const
{
return get<Type>(char_type('.'), path, loc);
}
// Get value from data of child ptree (default path separator)
template<class Tr>
template<class Type>
Type basic_ptree<Tr>::get(const key_type &path,
const Type &default_value,
const std::locale &loc) const
{
return get(char_type('.'), path, default_value, loc);
}
// Get value from data of child ptree (default path separator)
template<class Tr>
template<class CharType>
std::basic_string<CharType>
basic_ptree<Tr>::get(const key_type &path,
const CharType *default_value,
const std::locale &loc) const
{
return get(char_type('.'), path, default_value, loc);
}
// Get value from data of child ptree (default path separator)
template<class Tr>
template<class Type>
optional<Type>
basic_ptree<Tr>::get_optional(const key_type &path,
const std::locale &loc) const
{
return get_optional<Type>(char_type('.'), path, loc);
}
// Put value in data of ptree
template<class Tr>
template<class Type>
void basic_ptree<Tr>::put_own(const Type &value, const std::locale &loc)
{
using namespace boost;
// Make sure that no pointer other than char_type * is allowed
BOOST_STATIC_ASSERT((is_pointer<Type>::value == false ||
is_same<char_type, typename remove_const<typename remove_pointer<Type>::type>::type>::value == true));
#ifdef __SUNPRO_CC
// For the Sun Studio compiler the declaration needs to be within a statement.
if (typename traits_type::template inserter<Type>()(m_impl->m_data, value, loc)){}
#else
typename traits_type::template inserter<Type>()(m_impl->m_data, value, loc);
#endif
}
// Put value in data of child ptree (custom path separator)
template<class Tr>
template<class Type>
basic_ptree<Tr> &
basic_ptree<Tr>::put(char_type separator,
const key_type &path,
const Type &value,
bool do_not_replace,
const std::locale &loc)
{
optional<basic_ptree<Tr> &> child;
if (!do_not_replace &&
(child = get_child_optional(separator, path)))
{
child.get().put_own(value, loc);
return *child;
}
else
{
basic_ptree<Tr> &child2 = put_child(separator, path, empty_ptree<basic_ptree<Tr> >(), do_not_replace);
child2.put_own(value, loc);
return child2;
}
}
// Put value in data of child ptree (default path separator)
template<class Tr>
template<class Type>
basic_ptree<Tr> &
basic_ptree<Tr>::put(const key_type &path,
const Type &value,
bool do_not_replace,
const std::locale &loc)
{
return put(char_type('.'), path, value, do_not_replace, loc);
}
////////////////////////////////////////////////////////////////////////////
// Debugging
#ifdef BOOST_PROPERTY_TREE_DEBUG
template<class Tr>
typename basic_ptree<Tr>::size_type
basic_ptree<Tr>::debug_get_instances_count()
{
empty_ptree<basic_ptree<Tr> >(); // Make sure empty ptree exists
return debug_instances_count - 1; // Do not count empty ptree
}
template<class Tr>
typename basic_ptree<Tr>::size_type
basic_ptree<Tr>::debug_instances_count;
template<class Tr>
boost::detail::lightweight_mutex
basic_ptree<Tr>::debug_mutex;
#endif
///////////////////////////////////////////////////////////////////////////
// Free functions
template<class Ptree>
inline const Ptree &empty_ptree()
{
static Ptree pt;
return pt;
}
template<class Tr>
inline void swap(basic_ptree<Tr> &pt1, basic_ptree<Tr> &pt2)
{
pt1.swap(pt2);
}
} }
// Undefine debug macros
#ifdef BOOST_PROPERTY_TREE_DEBUG
# undef BOOST_PROPERTY_TREE_DEBUG_INCREMENT_INSTANCES_COUNT
# undef BOOST_PROPERTY_TREE_DEBUG_DECREMENT_INSTANCES_COUNT
#endif
#endif