-//$$CDS-header$$
+/*
+ This file is a part of libcds - Concurrent Data Structures library
-#ifndef __CDS_CONTAINER_SPLIT_LIST_SET_H
-#define __CDS_CONTAINER_SPLIT_LIST_SET_H
+ (C) Copyright Maxim Khizhinsky (libcds.dev@gmail.com) 2006-2017
+
+ Source code repo: http://github.com/khizmax/libcds/
+ Download: http://sourceforge.net/projects/libcds/files/
+
+ Redistribution and use in source and binary forms, with or without
+ modification, are permitted provided that the following conditions are met:
+
+ * Redistributions of source code must retain the above copyright notice, this
+ list of conditions and the following disclaimer.
+
+ * Redistributions in binary form must reproduce the above copyright notice,
+ this list of conditions and the following disclaimer in the documentation
+ and/or other materials provided with the distribution.
+
+ THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
+ AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
+ IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
+ DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE
+ FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
+ DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
+ SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
+ CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
+ OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
+ OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
+*/
+
+#ifndef CDSLIB_CONTAINER_SPLIT_LIST_SET_H
+#define CDSLIB_CONTAINER_SPLIT_LIST_SET_H
#include <cds/intrusive/split_list.h>
#include <cds/container/details/make_split_list_set.h>
+#include <cds/container/details/guarded_ptr_cast.h>
namespace cds { namespace container {
\par Usage
You should decide what garbage collector you want, and what ordered list you want to use as a base. Split-ordered list
- is original data structure based on an ordered list.
+ is original data structure based on an ordered list.
Suppose, you want construct split-list set based on \p gc::DHP GC
and \p LazyList as ordered list implementation. So, you beginning your program with following include:
Now you are ready to declare our set class based on \p %SplitListSet:
\code
- typedef cc::SplitListSet< cds::gc::PTB, foo, foo_set_traits > foo_set;
+ typedef cc::SplitListSet< cds::gc::DHP, foo, foo_set_traits > foo_set;
\endcode
You may use the modern option-based declaration instead of classic traits-based one:
\code
- typedef cc:SplitListSet<
- cs::gc::PTB // GC used
+ typedef cc::SplitListSet<
+ cs::gc::DHP // GC used
,foo // type of data stored
,cc::split_list::make_traits< // metafunction to build split-list traits
cc::split_list::ordered_list<cc::lazy_list_tag> // tag for underlying ordered list implementation
/// Hash functor for \p %value_type and all its derivatives that you use
typedef typename base_class::hash hash;
typedef typename base_class::item_counter item_counter; ///< Item counter type
+ typedef typename base_class::stat stat; ///< Internal statistics
+
+ /// Count of hazard pointer required
+ static CDS_CONSTEXPR const size_t c_nHazardPtrCount = base_class::c_nHazardPtrCount;
protected:
//@cond
- typedef typename maker::cxx_node_allocator cxx_node_allocator;
- typedef typename maker::node_type node_type;
+ typedef typename maker::cxx_node_allocator cxx_node_allocator;
+ typedef typename maker::node_type node_type;
//@endcond
public:
/// Guarded pointer
- typedef cds::gc::guarded_ptr< gc, node_type, value_type, details::guarded_ptr_cast_set<node_type, value_type> > guarded_ptr;
+ typedef typename gc::template guarded_ptr< node_type, value_type, details::guarded_ptr_cast_set<node_type, value_type> > guarded_ptr;
protected:
//@cond
- template <typename Q>
- static node_type * alloc_node(Q const& v )
- {
- return cxx_node_allocator().New( v );
- }
-
- template <typename... Args>
- static node_type * alloc_node( Args&&... args )
- {
- return cxx_node_allocator().MoveNew( std::forward<Args>( args )... );
- }
-
- static void free_node( node_type * pNode )
- {
- cxx_node_allocator().Delete( pNode );
- }
-
- template <typename Q, typename Func>
- bool find_( Q& val, Func f )
- {
- return base_class::find( val, [&f]( node_type& item, Q& val ) { f(item.m_Value, val) ; } );
- }
-
- template <typename Q, typename Less, typename Func>
- bool find_with_( Q& val, Less pred, Func f )
- {
- return base_class::find_with( val, typename maker::template predicate_wrapper<Less>::type(),
- [&f]( node_type& item, Q& val ) { f(item.m_Value, val) ; } );
- }
-
- struct node_disposer {
- void operator()( node_type * pNode )
- {
- free_node( pNode );
- }
- };
- typedef std::unique_ptr< node_type, node_disposer > scoped_node_ptr;
-
- bool insert_node( node_type * pNode )
- {
- assert( pNode != nullptr );
- scoped_node_ptr p(pNode);
-
- if ( base_class::insert( *pNode ) ) {
- p.release();
- return true;
- }
- return false;
- }
-
- //@endcond
-
- protected:
- /// Forward iterator
- /**
- \p IsConst - constness boolean flag
-
- The forward iterator for a split-list has the following features:
- - it has no post-increment operator
- - it depends on underlying ordered list iterator
- - The iterator object cannot be moved across thread boundary since it contains GC's guard that is thread-private GC data.
- - Iterator ensures thread-safety even if you delete the item that iterator points to. However, in case of concurrent
- deleting operations it is no guarantee that you iterate all item in the split-list.
-
- Therefore, the use of iterators in concurrent environment is not good idea. Use it for debug purpose only.
- */
template <bool IsConst>
class iterator_type: protected base_class::template iterator_type<IsConst>
{
- //@cond
typedef typename base_class::template iterator_type<IsConst> iterator_base_class;
friend class SplitListSet;
- //@endcond
+
public:
/// Value pointer type (const for const iterator)
typedef typename cds::details::make_const_type<value_type, IsConst>::pointer value_ptr;
{}
protected:
- //@cond
explicit iterator_type( iterator_base_class const& src )
: iterator_base_class( src )
{}
- //@endcond
public:
/// Dereference operator
return iterator_base_class::operator!=(i);
}
};
+ //@endcond
public:
/// Initializes split-ordered list of default capacity
{}
public:
+ ///@name Forward iterators (only for debugging purpose)
+ //@{
/// Forward iterator
+ /**
+ The forward iterator for a split-list has the following features:
+ - it has no post-increment operator
+ - it depends on underlying ordered list iterator
+ - The iterator object cannot be moved across thread boundary because it contains GC's guard that is thread-private GC data.
+ - Iterator ensures thread-safety even if you delete the item that iterator points to. However, in case of concurrent
+ deleting operations it is no guarantee that you iterate all item in the split-list.
+ Moreover, a crash is possible when you try to iterate the next element that has been deleted by concurrent thread.
+
+ @warning Use this iterator on the concurrent container for debugging purpose only.
+
+ The iterator interface:
+ \code
+ class iterator {
+ public:
+ // Default constructor
+ iterator();
+
+ // Copy construtor
+ iterator( iterator const& src );
+
+ // Dereference operator
+ value_type * operator ->() const;
+
+ // Dereference operator
+ value_type& operator *() const;
+
+ // Preincrement operator
+ iterator& operator ++();
+
+ // Assignment operator
+ iterator& operator = (iterator const& src);
+
+ // Equality operators
+ bool operator ==(iterator const& i ) const;
+ bool operator !=(iterator const& i ) const;
+ };
+ \endcode
+ */
typedef iterator_type<false> iterator;
/// Const forward iterator
*/
iterator begin()
{
- return iterator( base_class::begin() );
+ return iterator( base_class::begin());
}
/// Returns an iterator that addresses the location succeeding the last element in a set
*/
iterator end()
{
- return iterator( base_class::end() );
+ return iterator( base_class::end());
}
/// Returns a forward const iterator addressing the first element in a set
const_iterator begin() const
{
- return const_iterator( base_class::begin() );
+ return cbegin();
+ }
+ /// Returns a forward const iterator addressing the first element in a set
+ const_iterator cbegin() const
+ {
+ return const_iterator( base_class::cbegin());
}
/// Returns an const iterator that addresses the location succeeding the last element in a set
const_iterator end() const
{
- return const_iterator( base_class::end() );
+ return cend();
}
+ /// Returns an const iterator that addresses the location succeeding the last element in a set
+ const_iterator cend() const
+ {
+ return const_iterator( base_class::cend());
+ }
+ //@}
public:
/// Inserts new node
Returns \p true if \p val is inserted into the set, \p false otherwise.
*/
template <typename Q>
- bool insert( Q const& val )
+ bool insert( Q&& val )
{
- return insert_node( alloc_node( val ) );
+ return insert_node( alloc_node( std::forward<Q>( val )));
}
/// Inserts new node
synchronization.
*/
template <typename Q, typename Func>
- bool insert( Q const& val, Func f )
+ bool insert( Q&& val, Func f )
{
- scoped_node_ptr pNode( alloc_node( val ));
+ scoped_node_ptr pNode( alloc_node( std::forward<Q>( val )));
if ( base_class::insert( *pNode, [&f](node_type& node) { f( node.m_Value ) ; } )) {
pNode.release();
return insert_node( alloc_node( std::forward<Args>(args)...));
}
- /// Ensures that the \p item exists in the set
+ /// Inserts or updates the node (only for \p IterableList -based set)
/**
The operation performs inserting or changing data with lock-free manner.
- If the \p val key not found in the set, then the new item created from \p val
- is inserted into the set. Otherwise, the functor \p func is called with the item found.
- The functor \p Func should be a function with signature:
- \code
- void func( bool bNew, value_type& item, const Q& val );
- \endcode
- or a functor:
+ If the item \p val is not found in the set, then \p val is inserted iff \p bAllowInsert is \p true.
+ Otherwise, the current element is changed to \p val, the old element will be retired later.
+
+ Returns std::pair<bool, bool> where \p first is \p true if operation is successful,
+ \p second is \p true if \p val has been added or \p false if the item with that key
+ already in the set.
+ */
+ template <typename Q>
+#ifdef CDS_DOXYGEN_INVOKED
+ std::pair<bool, bool>
+#else
+ typename std::enable_if<
+ std::is_same< Q, Q>::value && is_iterable_list< ordered_list >::value,
+ std::pair<bool, bool>
+ >::type
+#endif
+ upsert( Q&& val, bool bAllowInsert = true )
+ {
+ scoped_node_ptr pNode( alloc_node( std::forward<Q>( val )));
+
+ auto bRet = base_class::upsert( *pNode, bAllowInsert );
+
+ if ( bRet.first )
+ pNode.release();
+ return bRet;
+ }
+
+ /// Updates the node
+ /**
+ The operation performs inserting or changing data with lock-free manner.
+
+ If \p key is not found in the set, then \p key is inserted iff \p bAllowInsert is \p true.
+ Otherwise, the functor \p func is called with item found.
+
+ The functor \p func signature depends of ordered list:
+
+ <b>for \p MichaelList, \p LazyList</b>
\code
- struct my_functor {
- void operator()( bool bNew, value_type& item, const Q& val );
+ struct functor {
+ void operator()( bool bNew, value_type& item, Q const& val );
};
\endcode
-
with arguments:
- \p bNew - \p true if the item has been inserted, \p false otherwise
- \p item - item of the set
- - \p val - argument \p val passed into the \p ensure function
+ - \p val - argument \p val passed into the \p %update() function
The functor may change non-key fields of the \p item.
- Returns <tt> std::pair<bool, bool> </tt> where \p first is true if operation is successfull,
+ <b>for \p IterableList</b>
+ \code
+ void func( value_type& val, value_type * old );
+ \endcode
+ where
+ - \p val - a new data constructed from \p key
+ - \p old - old value that will be retired. If new item has been inserted then \p old is \p nullptr.
+
+ Returns <tt> std::pair<bool, bool> </tt> where \p first is true if operation is successful,
\p second is true if new item has been added or \p false if the item with \p key
already is in the set.
- @warning For \ref cds_intrusive_MichaelList_hp "MichaelList" as the bucket see \ref cds_intrusive_item_creating "insert item troubleshooting".
+ @warning For \ref cds_intrusive_MichaelList_hp "MichaelList" and \ref cds_nonintrusive_IterableList_gc "IterableList"
+ as the bucket see \ref cds_intrusive_item_creating "insert item troubleshooting".
\ref cds_intrusive_LazyList_hp "LazyList" provides exclusive access to inserted item and does not require any node-level
synchronization.
*/
template <typename Q, typename Func>
- std::pair<bool, bool> ensure( Q const& val, Func func )
+#ifdef CDS_DOXYGEN_INVOKED
+ std::pair<bool, bool>
+#else
+ typename std::enable_if<
+ std::is_same<Q, Q>::value && !is_iterable_list<ordered_list>::value,
+ std::pair<bool, bool>
+ >::type
+#endif
+ update( Q&& val, Func func, bool bAllowInsert = true )
{
- scoped_node_ptr pNode( alloc_node( val ));
+ scoped_node_ptr pNode( alloc_node( std::forward<Q>( val )));
- std::pair<bool, bool> bRet = base_class::ensure( *pNode,
+ auto bRet = base_class::update( *pNode,
[&func, &val]( bool bNew, node_type& item, node_type const& /*val*/ ) {
func( bNew, item.m_Value, val );
- } );
+ }, bAllowInsert );
if ( bRet.first && bRet.second )
pNode.release();
return bRet;
}
+ //@cond
+ template <typename Q, typename Func>
+ typename std::enable_if<
+ std::is_same<Q, Q>::value && is_iterable_list<ordered_list>::value,
+ std::pair<bool, bool>
+ >::type
+ update( Q&& val, Func func, bool bAllowInsert = true )
+ {
+ scoped_node_ptr pNode( alloc_node( std::forward<Q>( val )));
+
+ auto bRet = base_class::update( *pNode,
+ [&func]( node_type& item, node_type* old ) {
+ func( item.m_Value, old ? &old->m_Value : nullptr );
+ }, bAllowInsert );
+
+ if ( bRet.first )
+ pNode.release();
+ return bRet;
+ }
+ //@endcond
+
+ //@cond
+ template <typename Q, typename Func>
+ CDS_DEPRECATED("ensure() is deprecated, use update()")
+ std::pair<bool, bool> ensure( Q const& val, Func func )
+ {
+ return update( val, func, true );
+ }
+ //@endcond
/// Deletes \p key from the set
/** \anchor cds_nonintrusive_SplitListSet_erase_val
template <typename Q, typename Less>
bool erase_with( Q const& key, Less pred )
{
- return base_class::erase_with( key, typename maker::template predicate_wrapper<Less>::type() );
+ CDS_UNUSED( pred );
+ return base_class::erase_with( key, typename maker::template predicate_wrapper<Less>::type());
}
/// Deletes \p key from the set
template <typename Q, typename Less, typename Func>
bool erase_with( Q const& key, Less pred, Func f )
{
+ CDS_UNUSED( pred );
return base_class::erase_with( key, typename maker::template predicate_wrapper<Less>::type(),
[&f](node_type& node) { f( node.m_Value ); } );
}
+ /// Deletes the item pointed by iterator \p iter (only for \p IterableList based set)
+ /**
+ Returns \p true if the operation is successful, \p false otherwise.
+ The function can return \p false if the node the iterator points to has already been deleted
+ by other thread.
+
+ The function does not invalidate the iterator, it remains valid and can be used for further traversing.
+
+ @note \p %erase_at() is supported only for \p %SplitListSet based on \p IterableList.
+ */
+#ifdef CDS_DOXYGEN_INVOKED
+ bool erase_at( iterator const& iter )
+#else
+ template <typename Iterator>
+ typename std::enable_if< std::is_same<Iterator, iterator>::value && is_iterable_list< ordered_list >::value, bool >::type
+ erase_at( Iterator const& iter )
+#endif
+ {
+ return base_class::erase_at( static_cast<typename iterator::iterator_base_class const&>( iter ));
+ }
+
+
/// Extracts the item with specified \p key
/** \anchor cds_nonintrusive_SplitListSet_hp_extract
The function searches an item with key equal to \p key,
- unlinks it from the set, and returns it in \p dest parameter.
- If the item with key equal to \p key is not found the function returns \p false.
+ unlinks it from the set, and returns it as \p guarded_ptr.
+ If \p key is not found the function returns an empty guarded pointer.
Note the compare functor should accept a parameter of type \p Q that may be not the same as \p value_type.
- The extracted item is freed automatically when returned \ref guarded_ptr object will be destroyed or released.
+ The extracted item is freed automatically when returned \p guarded_ptr object will be destroyed or released.
@note Each \p guarded_ptr object uses the GC's guard that can be limited resource.
Usage:
splitlist_set theSet;
// ...
{
- splitlist_set::guarded_ptr gp;
- theSet.extract( gp, 5 );
- // Deal with gp
- // ...
-
+ splitlist_set::guarded_ptr gp(theSet.extract( 5 ));
+ if ( gp ) {
+ // Deal with gp
+ // ...
+ }
// Destructor of gp releases internal HP guard
}
\endcode
*/
template <typename Q>
- bool extract( guarded_ptr& dest, Q const& key )
+ guarded_ptr extract( Q const& key )
{
- return extract_( dest.guard(), key );
+ return extract_( key );
}
/// Extracts the item using compare functor \p pred
/**
- The function is an analog of \ref cds_nonintrusive_SplitListSet_hp_extract "extract(guarded_ptr&, Q const&)"
+ The function is an analog of \ref cds_nonintrusive_SplitListSet_hp_extract "extract(Q const&)"
but \p pred predicate is used for key comparing.
\p Less functor has the semantics like \p std::less but should take arguments of type \ref value_type and \p Q
\p pred must imply the same element order as the comparator used for building the set.
*/
template <typename Q, typename Less>
- bool extract_with( guarded_ptr& dest, Q const& key, Less pred )
+ guarded_ptr extract_with( Q const& key, Less pred )
{
- return extract_with_( dest.guard(), key, pred );
+ return extract_with_( key, pred );
}
/// Finds the key \p key
\endcode
where \p item is the item found, \p key is the <tt>find</tt> function argument.
- You may pass \p f argument by reference using \p std::ref.
-
The functor may change non-key fields of \p item. Note that the functor is only guarantee
that \p item cannot be disposed during functor is executing.
The functor does not serialize simultaneous access to the set's \p item. If such access is
{
return find_( key, f );
}
+ //@cond
+ template <typename Q, typename Func>
+ bool find( Q const& key, Func f )
+ {
+ return find_( key, f );
+ }
+ //@endcond
+
+ /// Finds \p key and returns iterator pointed to the item found (only for \p IterableList -based set)
+ /**
+ If \p key is not found the function returns \p end().
+
+ @note This function is supported only for the set based on \p IterableList
+ */
+ template <typename Q>
+#ifdef CDS_DOXYGEN_INVOKED
+ iterator
+#else
+ typename std::enable_if< std::is_same<Q,Q>::value && is_iterable_list< ordered_list >::value, iterator >::type
+#endif
+ find( Q& key )
+ {
+ return find_iterator_( key );
+ }
+ //@cond
+ template <typename Q>
+ typename std::enable_if< std::is_same<Q, Q>::value && is_iterable_list< ordered_list >::value, iterator >::type
+ find( Q const& key )
+ {
+ return find_iterator_( key );
+ }
+ //@endcond
+
/// Finds the key \p key using \p pred predicate for searching
/**
{
return find_with_( key, pred, f );
}
+ //@cond
+ template <typename Q, typename Less, typename Func>
+ bool find_with( Q const& key, Less pred, Func f )
+ {
+ return find_with_( key, pred, f );
+ }
+ //@endcond
- /// Finds the key \p key
- /** \anchor cds_nonintrusive_SplitListSet_find_val
+ /// Finds \p key using \p pred predicate and returns iterator pointed to the item found (only for \p IterableList -based set)
+ /**
+ The function is an analog of \p find(Q&) but \p pred is used for key comparing.
+ \p Less functor has the interface like \p std::less.
+ \p pred must imply the same element order as the comparator used for building the set.
+
+ If \p key is not found the function returns \p end().
+
+ @note This function is supported only for the set based on \p IterableList
+ */
+ template <typename Q, typename Less>
+#ifdef CDS_DOXYGEN_INVOKED
+ iterator
+#else
+ typename std::enable_if< std::is_same<Q, Q>::value && is_iterable_list< ordered_list >::value, iterator >::type
+#endif
+ find_with( Q& key, Less pred )
+ {
+ return find_iterator_with_( key, pred );
+ }
+ //@cond
+ template <typename Q, typename Less>
+ typename std::enable_if< std::is_same<Q, Q>::value && is_iterable_list< ordered_list >::value, iterator >::type
+ find_with( Q const& key, Less pred )
+ {
+ return find_iterator_with_( key, pred );
+ }
+ //@endcond
+ /// Checks whether the set contains \p key
+ /**
The function searches the item with key equal to \p key
and returns \p true if it is found, and \p false otherwise.
Note the hash functor specified for class \p Traits template parameter
- should accept a parameter of type \p Q that can be not the same as \ref value_type.
+ should accept a parameter of type \p Q that can be not the same as \p value_type.
+ Otherwise, you may use \p contains( Q const&, Less pred ) functions with explicit predicate for key comparing.
*/
template <typename Q>
- bool find( Q const& key )
+ bool contains( Q const& key )
{
- return base_class::find( key );
+ return base_class::contains( key );
}
- /// Finds the key \p key using \p pred predicate for searching
+ /// Checks whether the map contains \p key using \p pred predicate for searching
/**
- The function is an analog of \ref cds_nonintrusive_SplitListSet_find_val "find(Q const&)"
- but \p pred is used for key comparing.
+ The function is similar to <tt>contains( key )</tt> but \p pred is used for key comparing.
\p Less functor has the interface like \p std::less.
- \p Less must imply the same element order as the comparator used for building the set.
+ \p Less must imply the same element order as the comparator used for building the map.
*/
template <typename Q, typename Less>
- bool find_with( Q const& key, Less pred )
+ bool contains( Q const& key, Less pred )
{
- return base_class::find_with( key, typename maker::template predicate_wrapper<Less>::type() );
+ CDS_UNUSED( pred );
+ return base_class::contains( key, typename maker::template predicate_wrapper<Less>::type());
}
/// Finds the key \p key and return the item found
/** \anchor cds_nonintrusive_SplitListSet_hp_get
The function searches the item with key equal to \p key
- and assigns the item found to guarded pointer \p ptr.
- The function returns \p true if \p key is found, and \p false otherwise.
- If \p key is not found the \p ptr parameter is not changed.
+ and returns the item found as \p guarded_ptr.
+ If \p key is not found the function returns an empty guarded pointer.
@note Each \p guarded_ptr object uses one GC's guard which can be limited resource.
splitlist_set theSet;
// ...
{
- splitlist_set::guarded_ptr gp;
- if ( theSet.get( gp, 5 )) {
+ splitlist_set::guarded_ptr gp(theSet.get( 5 ));
+ if ( gp ) {
// Deal with gp
//...
}
should accept a parameter of type \p Q that can be not the same as \p value_type.
*/
template <typename Q>
- bool get( guarded_ptr& ptr, Q const& key )
+ guarded_ptr get( Q const& key )
{
- return get_( ptr.guard(), key );
+ return get_( key );
}
/// Finds \p key and return the item found
/**
- The function is an analog of \ref cds_nonintrusive_SplitListSet_hp_get "get( guarded_ptr&, Q const&)"
+ The function is an analog of \ref cds_nonintrusive_SplitListSet_hp_get "get( Q const&)"
but \p pred is used for comparing the keys.
\p Less functor has the semantics like \p std::less but should take arguments of type \ref value_type and \p Q
\p pred must imply the same element order as the comparator used for building the set.
*/
template <typename Q, typename Less>
- bool get_with( guarded_ptr& ptr, Q const& key, Less pred )
+ guarded_ptr get_with( Q const& key, Less pred )
{
- return get_with_( ptr.guard(), key, pred );
+ return get_with_( key, pred );
}
/// Clears the set (not atomic)
return base_class::size();
}
+ /// Returns internal statistics
+ stat const& statistics() const
+ {
+ return base_class::statistics();
+ }
+
+ /// Returns internal statistics for \p ordered_list
+ typename ordered_list::stat const& list_statistics() const
+ {
+ return base_class::list_statistics();
+ }
+
protected:
//@cond
using base_class::extract_;
using base_class::get_;
+ template <typename... Args>
+ static node_type * alloc_node( Args&&... args )
+ {
+ return cxx_node_allocator().MoveNew( std::forward<Args>( args )... );
+ }
+
+ static void free_node( node_type * pNode )
+ {
+ cxx_node_allocator().Delete( pNode );
+ }
+
+ template <typename Q, typename Func>
+ bool find_( Q& val, Func f )
+ {
+ return base_class::find( val, [&f]( node_type& item, Q& v ) { f( item.m_Value, v ); } );
+ }
+
+ template <typename Q>
+ typename std::enable_if< std::is_same<Q,Q>::value && is_iterable_list< ordered_list >::value, iterator>::type
+ find_iterator_( Q& val )
+ {
+ return iterator( base_class::find( val ));
+ }
+
+ template <typename Q, typename Less, typename Func>
+ bool find_with_( Q& val, Less pred, Func f )
+ {
+ CDS_UNUSED( pred );
+ return base_class::find_with( val, typename maker::template predicate_wrapper<Less>::type(),
+ [&f]( node_type& item, Q& v ) { f( item.m_Value, v ); } );
+ }
+
template <typename Q, typename Less>
- bool extract_with_( typename gc::Guard& guard, Q const& key, Less pred )
+ typename std::enable_if< std::is_same<Q, Q>::value && is_iterable_list< ordered_list >::value, iterator>::type
+ find_iterator_with_( Q& val, Less pred )
{
- return base_class::extract_with_( guard, key, typename maker::template predicate_wrapper<Less>::type() );
+ CDS_UNUSED( pred );
+ return iterator( base_class::find_with( val, typename maker::template predicate_wrapper<Less>::type()));
+ }
+
+ struct node_disposer {
+ void operator()( node_type * pNode )
+ {
+ free_node( pNode );
+ }
+ };
+ typedef std::unique_ptr< node_type, node_disposer > scoped_node_ptr;
+
+ bool insert_node( node_type * pNode )
+ {
+ assert( pNode != nullptr );
+ scoped_node_ptr p( pNode );
+
+ if ( base_class::insert( *pNode )) {
+ p.release();
+ return true;
+ }
+ return false;
}
template <typename Q, typename Less>
- bool get_with_( typename gc::Guard& guard, Q const& key, Less pred )
+ guarded_ptr extract_with_( Q const& key, Less pred )
{
- return base_class::get_with_( guard, key, typename maker::template predicate_wrapper<Less>::type() );
+ CDS_UNUSED( pred );
+ return base_class::extract_with_( key, typename maker::template predicate_wrapper<Less>::type());
}
- //@endcond
+ template <typename Q, typename Less>
+ guarded_ptr get_with_( Q const& key, Less pred )
+ {
+ CDS_UNUSED( pred );
+ return base_class::get_with_( key, typename maker::template predicate_wrapper<Less>::type());
+ }
+ //@endcond
};
-
}} // namespace cds::container
-#endif // #ifndef __CDS_CONTAINER_SPLIT_LIST_SET_H
+#endif // #ifndef CDSLIB_CONTAINER_SPLIT_LIST_SET_H
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