-//$$CDS-header$$
+/*
+ This file is a part of libcds - Concurrent Data Structures library
+
+ (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_INTRUSIVE_LAZY_LIST_NOGC_H
#define CDSLIB_INTRUSIVE_LAZY_LIST_NOGC_H
typedef typename get_node_traits< value_type, node_type, hook>::type node_traits; ///< node traits
typedef typename lazy_list::get_link_checker< node_type, traits::link_checker >::type link_checker; ///< link checker
- typedef typename traits::item_counter item_counter; ///< Item counting policy used
- typedef typename traits::memory_model memory_model; ///< C++ memory ordering (see lazy_list::traits::memory_model)
+ typedef typename traits::item_counter item_counter; ///< Item counting policy used
+ typedef typename traits::memory_model memory_model; ///< C++ memory ordering (see \p lazy_list::traits::memory_model)
+ typedef typename traits::stat stat; ///< Internal statistics
//@cond
+ static_assert((std::is_same< gc, typename node_type::gc >::value), "GC and node_type::gc must be the same type");
+
// Rebind traits (split-list support)
template <typename... Options>
struct rebind_traits {
, typename cds::opt::make_options< traits, Options...>::type
> type;
};
+
+ // Stat selector
+ template <typename Stat>
+ using select_stat_wrapper = lazy_list::select_stat_wrapper< Stat >;
//@endcond
protected:
node_type m_Head; ///< List head (dummy node)
node_type m_Tail; ///< List tail (dummy node)
item_counter m_ItemCounter; ///< Item counter
+ mutable stat m_Stat; ///< Internal statistics
//@cond
void link_node( node_type * pNode, node_type * pPred, node_type * pCur )
{
+ link_checker::is_empty( pNode );
assert( pPred->m_pNext.load(memory_model::memory_order_relaxed) == pCur );
pNode->m_pNext.store( pCur, memory_model::memory_order_release );
/// Returns a forward const iterator addressing the first element in a list
const_iterator cbegin() const
{
- const_iterator it( const_cast<node_type *>(&m_Head) );
+ const_iterator it( const_cast<node_type *>(&m_Head));
++it; // skip dummy head
return it;
}
/// Returns an const iterator that addresses the location succeeding the last element in a list
const_iterator cend() const
{
- return const_iterator( const_cast<node_type *>(&m_Tail) );
+ return const_iterator( const_cast<node_type *>(&m_Tail));
}
public:
/// Default constructor initializes empty list
LazyList()
{
- static_assert( (std::is_same< gc, typename node_type::gc >::value), "GC and node_type::gc must be the same type" );
m_Head.m_pNext.store( &m_Tail, memory_model::memory_order_relaxed );
}
+ //@cond
+ template <typename Stat, typename = std::enable_if<std::is_same<stat, lazy_list::wrapped_stat<Stat>>::value >>
+ explicit LazyList( Stat& st )
+ : m_Stat( st )
+ {
+ m_Head.m_pNext.store( &m_Tail, memory_model::memory_order_relaxed );
+ }
+ //@endcond
+
/// Destroys the list object
~LazyList()
{
The functor may change non-key fields of the \p item.
While the functor \p f is calling the item \p item is locked.
- Returns <tt> std::pair<bool, bool> </tt> where \p first is \p true if operation is successfull,
+ Returns <tt> std::pair<bool, bool> </tt> where \p first is \p true if operation is successful,
\p second is \p true if new item has been added or \p false if the item with \p key
already is in the list.
*/
return update_at( &m_Head, val, func, bAllowInsert );
}
//@cond
- // Deprecated, use update()
template <typename Func>
+ CDS_DEPRECATED("ensure() is deprecated, use update()")
std::pair<bool, bool> ensure( value_type& val, Func func )
{
- return update( &m_Head, val, func, true );
+ return update( val, func, true );
}
//@endcond
template <typename Q>
value_type * contains( Q const& key )
{
- return find_at( &m_Head, key, key_comparator() );
+ return find_at( &m_Head, key, key_comparator());
}
//@cond
- // Deprecated, use contains()
template <typename Q>
+ CDS_DEPRECATED("deprecated, use contains()")
value_type * find( Q const& key )
{
return contains( key );
typename std::enable_if<Sort, value_type *>::type contains( Q const& key, Less pred )
{
CDS_UNUSED( pred );
- return find_at( &m_Head, key, cds::opt::details::make_comparator_from_less<Less>() );
+ return find_at( &m_Head, key, cds::opt::details::make_comparator_from_less<Less>());
}
//@cond
- // Deprecated, use contains()
template <typename Q, typename Less, bool Sort = c_bSort>
+ CDS_DEPRECATED("deprecated, use contains()")
typename std::enable_if<Sort, value_type *>::type find_with( Q const& key, Less pred )
{
return contains( key, pred );
return find_at( &m_Head, key, equal );
}
//@cond
- // Deprecated, use contains()
template <typename Q, typename Equal, bool Sort = c_bSort>
+ CDS_DEPRECATED("deprecated, use contains()")
typename std::enable_if<!Sort, value_type *>::type find_with( Q const& key, Equal equal )
{
return contains( key, equal );
while ( pHead != &m_Tail ) {
node_type * p = pHead->m_pNext.load(memory_model::memory_order_relaxed);
dispose_node( pHead, disp );
+ --m_ItemCounter;
pHead = p;
}
}
*/
void clear()
{
- clear( disposer() );
+ clear( disposer());
}
/// Checks if the list is empty
return m_ItemCounter.value();
}
+ /// Returns const reference to internal statistics
+ stat const& statistics() const
+ {
+ return m_Stat;
+ }
+
protected:
//@cond
// split-list support
// Hack: convert node_type to value_type.
// In principle, auxiliary node can be non-reducible to value_type
// We assume that comparator can correctly distinguish aux and regular node.
- return insert_at( pHead, *node_traits::to_value_ptr( pNode ) );
+ return insert_at( pHead, *node_traits::to_value_ptr( pNode ));
}
bool insert_at( node_type * pHead, value_type& val )
{
- link_checker::is_empty( node_traits::to_node_ptr( val ) );
position pos;
key_comparator pred;
{
auto_lock_position alp( pos );
if ( validate( pos.pPred, pos.pCur )) {
- if ( pos.pCur != &m_Tail && equal( *node_traits::to_value_ptr( *pos.pCur ), val, pred ) ) {
+ if ( pos.pCur != &m_Tail && equal( *node_traits::to_value_ptr( *pos.pCur ), val, pred )) {
// failed: key already in list
+ m_Stat.onInsertFailed();
return false;
}
else {
link_node( node_traits::to_node_ptr( val ), pos.pPred, pos.pCur );
- ++m_ItemCounter;
- return true;
+ break;
}
}
}
+
+ m_Stat.onInsertRetry();
}
+
+ ++m_ItemCounter;
+ m_Stat.onInsertSuccess();
+ return true;
}
iterator insert_at_( node_type * pHead, value_type& val )
// key already in the list
func( false, *node_traits::to_value_ptr( *pos.pCur ) , val );
+ m_Stat.onUpdateExisting();
return std::make_pair( iterator( pos.pCur ), false );
}
else {
// new key
- if ( !bAllowInsert )
+ if ( !bAllowInsert ) {
+ m_Stat.onUpdateFailed();
return std::make_pair( end(), false );
-
- link_checker::is_empty( node_traits::to_node_ptr( val ) );
+ }
link_node( node_traits::to_node_ptr( val ), pos.pPred, pos.pCur );
func( true, val, val );
- ++m_ItemCounter;
- return std::make_pair( iterator( node_traits::to_node_ptr( val )), true );
+ break;
}
}
+
+ m_Stat.onUpdateRetry();
}
}
+
+ ++m_ItemCounter;
+ m_Stat.onUpdateNew();
+ return std::make_pair( iterator( node_traits::to_node_ptr( val )), true );
}
template <typename Func>
search( pHead, val, pos, pred );
if ( pos.pCur != &m_Tail ) {
std::unique_lock< typename node_type::lock_type> al( pos.pCur->m_Lock );
- if ( equal( *node_traits::to_value_ptr( *pos.pCur ), val, pred ) )
+ if ( equal( *node_traits::to_value_ptr( *pos.pCur ), val, pred ))
{
f( *node_traits::to_value_ptr( *pos.pCur ), val );
+ m_Stat.onFindSuccess();
return true;
}
}
+
+ m_Stat.onFindFailed();
return false;
}
value_type * find_at( node_type * pHead, Q& val, Pred pred)
{
iterator it = find_at_( pHead, val, pred );
- if ( it != end() )
+ if ( it != end())
return &*it;
return nullptr;
}
search( pHead, val, pos, pred );
if ( pos.pCur != &m_Tail ) {
- if ( equal( *node_traits::to_value_ptr( *pos.pCur ), val, pred ))
+ if ( equal( *node_traits::to_value_ptr( *pos.pCur ), val, pred )) {
+ m_Stat.onFindSuccess();
return iterator( pos.pCur );
+ }
}
+
+ m_Stat.onFindFailed();
return end();
}
node_type * pCur = pHead;
node_type * pPrev = pHead;
- while ( pCur != pTail && ( pCur == pHead || !equal( *node_traits::to_value_ptr( *pCur ), key, eq ) )) {
+ while ( pCur != pTail && ( pCur == pHead || !equal( *node_traits::to_value_ptr( *pCur ), key, eq ))) {
pPrev = pCur;
pCur = pCur->m_pNext.load(memory_model::memory_order_acquire);
}
return cmp(l, r) == 0;
}
- static bool validate( node_type * pPred, node_type * pCur )
+ bool validate( node_type * pPred, node_type * pCur )
{
- return pPred->m_pNext.load(memory_model::memory_order_acquire) == pCur;
+ if ( pPred->m_pNext.load(memory_model::memory_order_acquire) == pCur ) {
+ m_Stat.onValidationSuccess();
+ return true;
+ }
+
+ m_Stat.onValidationFailed();
+ return false;
}
+ // for split-list
+ template <typename Predicate>
+ void erase_for( Predicate pred )
+ {
+ node_type * pPred = nullptr;
+ node_type * pHead = m_Head.m_pNext.load( memory_model::memory_order_relaxed );
+
+ while ( pHead != &m_Tail ) {
+ node_type * p = pHead->m_pNext.load( memory_model::memory_order_relaxed );
+ if ( pred( *node_traits::to_value_ptr( pHead ))) {
+ assert( pPred != nullptr );
+ pPred->m_pNext.store( p, memory_model::memory_order_relaxed );
+ dispose_node( pHead, disposer());
+ }
+ else
+ pPred = pHead;
+ pHead = p;
+ }
+ }
//@endcond
};